October 2020
Revision Number: 3.6
Order No. 333016-010
Intel® Ethernet Controller I210
Datasheet
Networking Division (ND)
Features:
Small package: 9 x 9 mm
PCIe v2.1 (2.5 GT/s) x1, with Switching Voltage Regulator (iSVR)
Integrated Non-Volatile Memory (iNVM)
Three single port SKUs: SerDes, Copper, Copper IT
Value Part (Intel® Ethernet Controller I211)
Platform Power Efficiency
IEEE 802.3az Energy Efficient Ethernet (EEE)
Proxy: ECMA-393 and Windows* logo for proxy offload
Advanced Features:
0 to 70 °C commercial temperature or -40 to 85 °C industrial temperature
Audio-video bridging
IEEE 1588/802.1AS precision time synchronization
IEEE 802.1Qav traffic shaper (with software extensions)
Jumbo frames
Interrupt moderation, VLAN support, IP checksum offload
PCIe OBFF (Optimized Buffer Flush/Fill) for improved system power management
Four transmit and four receive queues
RSS and MSI-X to lower CPU utilization in multi-core systems
Advanced cable diagnostics, auto MDI-X
ECC – error correcting memory in packet buffers
Four Software Definable Pins (SDPs)
Manageability:
NC-SI for greater bandwidth pass through
SMBus low-speed serial bus to pass network traffic
Flexible firmware architecture with secure Flash update
MCTP over SMBus/PCIe
OS2BMC/CEM (optionally enabled via external Flash)
PXE and iSCSI boot
2
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Revision History—Ethernet Controller I210
3
Revision History
Rev Date Notes
3.6 October 2020 Updated Section 8.0 (Programming Interface).
Updated the note below Figure 12-27 (Peak Temperature).
3.5 August 2019 Updated Section 11.3.1 (Power Supply Specification).
3.4 February 2019 Updated Section 11.8.1 (new validated Flash parts).
3.3 June 2018 Updated Section 7.2.2.2.3 [LaunchTime (25)].
3.2 January 2018
Updated Table 2-1 (Pull-Up/Pull-Down Resistors).
Added section 3.3.2.4 (iNVM Structure Version Information).
Updated section 5.5.6 (Timing Guarantees).
Updated section 6.8.2 (Port Identification LED Blinking; Word 0x04).
Updated section 11.8.1 (Flash Parts).
3.1 June 2017 Revised Section:
3.4.3 (iNVM Programming Flows).
3.0 March 2017
Revised Sections:
3.7.8.5.7 (Internal PHY Power-Down State).
11.6.2.7 (MDIO AC Specification).
12.4 (Oscillator Support).
12.11 (XOR Testing).
2.9 January 2016
Revised Table 2-1 (changed JTAG_CLK to show a pull down resistor instead of a pull up).
Updated intra-document cross references.
Revised the description of Section 7.8.3.3.3 (Synchronized Output Clock on SDP Pins).
Revised Section 8.15.13 (TimeSync Auxiliary Control Register - TSAUXC (0xB640; RW), bit 4
and bit 7 description).
2.8 September 2015
Revised Section 6.8.7.2 (added image build information).
Updated Table 11-11 (tDS and tDH descriptions).
Updated Table 11-15 (cload value).
Updated Figure 12.12 (changed pull-up value from 1.9 to 1.5).
Updated Section 12.5.4 (Diff to CMR value).
Added Section 12.5.6.5 (Maximum Trace Lengths Based on Trace Geometry).
Fixed cross references in Section 12.6.
2.7 February 2015
Removed all references to IEEE Std 1149.6-2003, IEEE Standard for Boundary-Scan Testing of
Advanced Digital Networks, IEEE, 2003.
Updated section 8.27.3.37 (Misc Test - Page 6, Register 26).
Removed sections 8.27.3.38 through 8.27.3.43.
Updated section 12-4 (Oscillator Support).
Added section 12.5.5 (Designing the I210 as a 10/100 Mb/s Only Device).
Updated section 12.5.6.4 (Differential Pair Trace Routing for 10/100/1000 Designs).
2.6 June 2014 Revised section 11.8.1 (replaced W25Q16DWSSIG with W25Q16DVSSIG).
2.5 February 2014
Replaced figure 2-2.
Revised section 3.4 (iNVM).
Revised section 3.4.2 (iNVM Structures).
Revised section 3.7.8.5.5.1 (Internal PHY Back-to-Back SPD).
Revised table 8-6 (Register Summary; PQMPRC[0 - 3]).
Revised table 11-11 (Flash I/F Timing Parameters).
Revised table 11-17 (Specification for External Clock Oscillator).
Ethernet Controller I210 —Revision History
4
2.4 July 2013
Updated revision history.
Rev Date Notes
2.3 June 2013
Revised section 1.3.1 (Audio/Video Bridging Support).
Revised section 6.7.1.2 (Common Firmware Parameters 1 - Offset 0x1; bit 15).
Revised section 7.1.2.10 (Receive-Side Scaling (RSS).
Revised section 7.8.3.1 (Capture Timestamp Mechanism).
Revised section 8.21.18 (Flexible Host Filter Table Registers - FHFT (0x9000 + 4*n
[n=0...255]; RW); updated note.
Revised section 8.27.3.23 (MAC Specific Control Register 1 - Page 2, Register 16; bits 9:8).
Revised table 10-37 (Decision Filter Values).
2.2 April 2013
Updated title page (Platform Power Efficiency description).
Revised VPD Area Update Flow description (section 3.3.9.3.2).
Revised iNVM description (section 3.4).
Added line loopback information (section 3.7.6.6).
Revised Acquiring Ownership Over a Shared Resource description (section 4.6.1).
Revised Releasing Ownership Over a Shared Resource description (section 4.6.2).
Revised Dr Disable Mode description (section 5.2.4.1).
Revised Device Rev ID (section 6.2.19).
Revised Common Firmware Parameters 1 - Offset 0x1 (section 6.7.1.2).
Updated Compatibility (Word 0x03) bit 11 description (section 6.8.1).
Updated Setup Options PCIe Function 0 (Word 0x30) bit 5 description (section 6.8.6.1).
Added PXE VLAN Flash settings (Sections 6.8.6.5 through 6.8.6.9).
Updated Software Semaphore - SWSM (0x5B50; R/W)
Removed Firmware Status Register (0x8F0C) entry from Table 8-6.
Revised note (changed . . . has both F and L flags off to on (section 10.5.7.1).
Revised Specification for XTAL1 (In); table 11.16.
Revised Third-Party Magnetics Manufacturers table (section 12.5.3).
Added Power Delivery Solutions (section 12.7.1).
2.1 November 2012
Revised table 11.1 - Absolute Maximum Ratings
Revised section 12.5.3 - Third-Party Magnetics Manufacturers.
Revised table 12.16 - Absolute Maximum Case Temperature.
Revised table 12.17 - Thermal Simulation Results for Various Environmental Conditions.
2.0 November 2012
The following sections were revised:
1.0 Introduction.
3.0 Interconnects.
6.0 Flash Map.
7.0 Inline Functions.
8.0 Programming Interface.
9.0 PCIe Programming Interface.
11.0 Electrical/Mechanical Specification.
12.0 Design Considerations.
14.0 Diagnostics
Added new section 13.0 - Thermal Considerations.
1.9 October 2012 Initial Release (Intel Public).
Introduction—Ethernet Controller I210
5
1.0 Introduction
The Intel® Ethernet Controller I210 (I210) is a single port, compact, low power component that
supports GbE designs. The I210 offers a fully-integrated GbE Media Access Control (MAC), Physical
Layer (PHY) port and a SGMII/SerDes port that can be connected to an external PHY. The I210
supports PCI Express* [PCIe v2.1 (2.5GT/s)].
The I210 enables 1000BASE-T implementations using an integrated PHY. It can be used for server
system configurations such as rack mounted or pedestal servers, in an add-on NIC or LAN on
Motherboard (LOM) design. Another possible system configuration is for blade servers as a LOM or
mezzanine card. It can also be used in embedded applications such as switch add-on cards and network
appliances.
1.1 Scope
This document provides the external architecture (including device operation, pin descriptions, register
definitions, etc.) for the I210.
This document is a reference for software device driver developers, board designers, test engineers,
and others who may need specific technical or programming information.
1.2 Terminology and Acronyms
Table 1-1. Glossary
Definition Meaning
1000BASE-BX 1000BASE-BX is the PICMG 3.1 electrical specification for transmitting
1 Gb/s Ethernet or 1 Gb/s fibre channel encoded data over the backplane.
1000BASE-KX 1000BASE-KX is the IEEE802.3ap electrical specification for transmitting
1 Gb/s Ethernet over the backplane.
1000BASE-CX 1000BASE-X over specialty shielded 150 balanced copper jumper cable assemblies as
specified in IEEE 802.3 Clause 39.
1000BASE-T 1000BASE-T is the specification for 1 Gb/s Ethernet over category 5e twisted pair cables as
defined in IEEE 802.3 clause 40.
AEN Asynchronous Event Notification
b/w Bandwidth.
BIOS Basic Input/Output System.
BMC Baseboard Management Controller - often used interchangeably with Manageability
Controller (MC).
BT Bit Time.
CRC Cyclic redundancy check
DCA Direct Cache Access.
DDOFF Dynamic Device Off
Ethernet Controller I210 —Introduction
6
DFT Design for Testability.
DQ Descriptor Queue.
DMTF Distributed Management Task Force standard body.
DW Double word (4 bytes).
EEE Energy Efficient Ethernet - IEEE802.3az standard
EEPROM Electrically Erasable Programmable Memory. A non-volatile memory located on the LAN
controller that is directly accessible from the host.
EOP End of Packet.
FC Flow Control.
FCS Frame Check Sequence.
Firmware (FW) Embedded code on the LAN controller that is responsible for the implementation of the NC-
SI protocol and pass through functionality.
Host Interface RAM on the LAN controller that is shared between the firmware and the host. RAM is used to
pass commands from the host to firmware and responses from the firmware to the host.
HPC High - Performance Computing.
IPC Inter Processor Communication.
IPG Inter Packet Gap.
IPMI Intelligent Platform Management Interface specification
LAN (auxiliary Power-Up) The event of connecting the LAN controller to a power source (occurs even before system
power-up).
LLDP Link Layer Discovery Protocol defined in IEEE802.1AB used by IEEE802.3az (EEE) for system
wake time negotiation.
LOM LAN on Motherboard.
LPI Low Power Idle - Low power state of Ethernet link as defined in IEEE802.3az.
LSO Large Send Offload.
LTR Latency Tolerance Reporting (PCIe protocol)
iSVR Integrated Switching Voltage Regulator
MAC Media Access Control.
MC Management Controller
MCTP
DMTF Management Component Transport Protocol (MCTP) specification.
A transport protocol to allow communication between a management controller and
controlled device over various transports.
MDIO Management Data Input/Output Interface over MDC/MDIO lines.
MIFS/MIPG Minimum Inter Frame Spacing/Minimum Inter Packet Gap.
MMW Maximum Memory Window.
MSS
Maximum Segment Size.
Largest amount of data, in a packet (without headers) that can be transmitted. Specified in
Bytes.
MPS Maximum Payload Size in PCIe specification.
MTU Maximum Transmit Unit.
Largest packet size (headers and data) that can be transmitted. Specified in Bytes.
NC Network Controller.
NC-SI Network Controller Sideband Interface DMTF Specification
NIC Network Interface Controller.
OBFF Optimized Buffer Flush/Fill (PCIe protocol).
TPH TLP Process Hints (PCIe protocol).
PCS Physical Coding Sub layer.
Table 1-1. Glossary (Continued)
Definition Meaning
Introduction—Ethernet Controller I210
7
1.2.1 External Specification and Documents
The I210 implements features from the following specifications.
1.2.1.1 Network Interface Documents
1. IEEE standard 802.3, 2006 Edition (Ethernet). Incorporates various IEEE Standards previously
published separately. Institute of Electrical and Electronic Engineers (IEEE).
2. IEEE standard 1149.1, 2001 Edition (JTAG). Institute of Electrical and Electronics Engineers (IEEE)
3. IEEE standard 802.1Q for VLAN
4. PICMG3.1 Ethernet/Fibre Channel Over PICMG 3.0 Draft Specification, January 14, 2003, Version
D1.0
5. Serial-GMII Specification, Cisco Systems document ENG-46158, Revision 1.7
6. INF-8074i Specification for SFP (Small Form factor Pluggable) Transceiver (ftp://ftp.seagate.com/
sff)
7. IEEE Std 802.3ap-2007
8. IEEE 1588TM Standard for a Precision Clock Synchronization Protocol for Networked Measurement
and Control Systems, November 8 2002
9. IEEE 802.1AS Timing and Synchronization for Time- Sensitive Applications in Bridged Local Area
Networks Draft 2.0, February 22, 2008
10. IEEE 802.1BF Ethernet Support for the IEEE P802.1AS Time Synchronization Protocol Task Force
11. IEEE 802.3az Energy Efficient Ethernet Draft 1.4, May 2009
12. 802.1BA - Audio Video Bridging (AVB) Systems
13. 802.1Qav - Forwarding and Queuing Enhancements for Time-Sensitive Streams
PHY Physical Layer Device.
PMA Physical Medium Attachment.
PMD Physical Medium Dependent.
SA Source Address.
SDP Software Defined Pins.
SerDes Serializer/deserializer. A transceiver that converts parallel data to serial data and vice-versa.
SFD Start Frame Delimiter.
SGMII Serialized Gigabit Media Independent Interface.
SMBus System Management Bus. A bus that carries various manageability components, including
the LAN controller, BIOS, sensors and remote-control devices.
SVR Switching Voltage Regulator
TCO Total Cost of Ownership (TCO) System Management.
TLP Transaction Layer Packet in the PCI Express specification.
TSO Transmit Segmentation offload - A mode in which a large TCP/UDP I/O is handled to the
device and the device segments it to L2 packets according to the requested MSS.
VLAN Virtual LAN
VPD Vital Product Data (PCI protocol).
Table 1-1. Glossary (Continued)
Definition Meaning
Ethernet Controller I210 —Introduction
8
1.2.1.2 Host Interface Documents
1. PCI-Express 2.1 Base specification
2. PCI Specification, version 3.0
3. PCI Bus Power Management Interface Specification, Rev. 1.2, March 2004
4. Advanced Configuration and Power Interface Specification, Rev 2.0b, October 2002
1.2.1.3 Networking Protocol Documents
1. IPv4 specification (RFC 791)
2. IPv6 specification (RFC 2460)
3. TCP/UDP specification (RFC 793/768)
4. SCTP specification (RFC 2960)
5. ARP specification (RFC 826)
6. Neighbor Discovery for IPv6 (RFC 2461)
7. EUI-64 specification, http://standards.ieee.org/regauth/oui/tutorials/EUI64.html.
1.2.1.4 Manageability Documents
1. DMTF Network Controller Sideband Interface (NC-SI) Specification rev 1.0.0, May 2009
2. Management Component Transport Protocol (MCTP) Base Specification, rev 1.1.0, 4/22/2010 which
specifies the Management Component Transport Protocol (MCTP)
3. Management Component Transport Protocol (MCTP) SMBus/I2C Transport Binding Specification, rev
1.0.0, 7/28/2009 which describes the binding of MCTP over SMBus.
4. Management Component Transport Protocol (MCTP) PCIe VDM Transport Binding Specification, rev
1.0.1, 12/11/2009 which describes the binding of MCTP over PCI Express.
5. Management Component Transport Protocol (MCTP) IDs and Codes, rev 1.1.0, 11/3/2009 which
describes constants used by MCTP specs.
6. Document: dmtf.org/sites/default/files/standards/documents/DSP0236_1.1.0.pdf
7. NC-SI Over MCTP Specification, draft 0.4.3c, 8/2008 which describe the encapsulation of NC-SI
packets in MCTP.
8. System Management Bus (SMBus) Specification, SBS Implementers Forum, Ver. 2.0, August 2000
1.2.1.5 Proxy Documents
1. proxZZZy™ for sleeping hosts, February 2010 (ECMA-393)
2. mDNS Offload - Draft 1.0, May 2010
1.3 Product Overview
The I210 supports a SerDes or SGMII port for a MAC-to-MAC blade server connection or a MAC-to-
external PHY connections. Alternatively, the internal 1000BASE-T PHYs can be used to implement a
single port NIC or LOM design.
The I210 targets server system configurations such as rack mounted or pedestal servers, where the
I210 can be used as add-on NIC or LOM design. Another system configuration is blade servers, where it
can be used on Mezzanine card or LOM. The I210 can also be used in embedded applications such as
switch add-on cards and network appliances.
Introduction—Ethernet Controller I210
9
1.3.1 Audio/Video Bridging Support
The I210 supports IEEE 802.1 Audio Video Bridging (AVB) specifications. The draft AVB standards are
designed to work over widely-used IEEE 802 layer 2 networks. These new standards provide
networking features for tightly controlled media stream synchronization, buffering and reservation. The
IEEE 802.1AVB task group is working on an interoperability standards for systems based on the AVB
document set. This provides a complete list of parameters to plug into the various standards that are
needed to build an AVB system. A simple grid of features versus market has been created as a first cut
to describe four proposed interoperability profiles. Those profiles include Consumer Electronics,
Professional A/V, Industrial, and Automotive. Use of AVB enables higher layer protocols and
applications to realize professional-quality A/V even if there are various lower-layer network links in the
path between endpoint devices.
The I210 implements 4 receive queues and 4 transmit queues, where up to two queues are dedicated
for stream reservation or priority, and up to three queues for strict priority. In Qav mode, the MAC flow
control is disabled. Note that Qav mode is supported only in 100 Mb/s and 1000 Mb/s. Furthermore,
Qav is supported only in full-duplex mode with no option for Jumbo packets transmission.
1.4 External Interface
1.4.1 PCIe Interface
The PCIe v2.1 (2.5GT/s) Interface is used by the I210 as a host interface. The interface only supports
the PCIe v2.1 (2.5GT/s) rate and is configured to x1. The maximum aggregated raw bandwidth for a
typical PCIe v2.1 (2.5GT/s) configuration is 4 Gb/s in each direction. Refer to Section 2.3.1 for a full pin
description. The timing characteristics of this interface are defined in the PCI Express Card
Electromechanical Specification rev 2.0 and in the PCIe v2.1 (2.5GT/s) specification.
1.4.2 Network Interfaces
Three independent interfaces are used to connect the I210 port to external devices. The following
protocols are supported:
MDI (copper) support for standard IEEE 802.3 Ethernet interface for 1000BASE-T, 100BASE-TX, and
10BASE-T applications (802.3, 802.3u, and 802.3ab)
SerDes interface to connect over a backplane to another SerDes compliant device or to an optical
module. The I210 supports both 1000BASE-BX and 1000BASE-KX (Without IEEE802.3ap backplane
auto-negotiation)
SGMII interface to attach to an external PHY, either on board or via an SFP module. The SGMII
interface shares the same pins as the SerDes interface.
Refer to Section 2.3.6 for a full pin description. For additional interface details, refer to Section 11.6.3
and Section 11.6.4.
1.4.3 Internal Non-Volatile Memory (iNVM)
The I210 stores product configuration information in an Internal Non-Volatile Memory (iNVM) and in
Flash memory. The I210 does not support an external EEPROM. The I210 supports a Flash-less mode
where all the setup found normally in Flash memory are either set to their default, configured by
software, or stored into memory.
Ethernet Controller I210 —Introduction
10
Note: When operated in Flash-less mode with an external PHY (such as the I210 SGMII SKU), no
link up is made possible after power up before the driver configures the external PHY. It
means that in such case, WoL is not supported when the system passes through the following
states: G3 --> S5 --> WoL.
1.4.4 Serial Flash Interface
The I210 provides an external SPI serial interface to a Flash for storing product configuration
information and a boot ROM device such as the Winbond W25X80-BVSNIG or compatible Flash device.
Refer to Section 11.8.1 for a list of validated or compatible Flash devices. The I210 supports serial
Flash devices with up to 64 Mb (8 MB) of memory. The size of the Flash used by the I210 can be
configured by the Flash itself. Refer to Section 2.3.2 for full pin description and Section 11.6.2.4 for
timing characteristics of this interface.
Note: Though the I210 supports devices with up to 8 MB of memory, bigger devices can also be
used. Accesses to memory beyond the Flash device size results in access wrapping as only
the lower address bits are used by the Flash device.
1.4.5 SMBus Interface
SMBus is an optional interface for pass-through and/or configuration traffic between a Manageability
Controller (MC) and the I210.
The I210's SMBus interface can be configured to support both slow and fast timing modes (up to
1Mb/s). Refer to Section 2.3.3 for full pin description and Section 11.6.2.2 for timing characteristics of
this interface.
1.4.6 NC-SI Interface
NC-SI and SMBus interfaces are optional for pass-through and/or configuration traffic between a MC
and the I210. The NC-SI interface meets the DMTF NC-SI Specification, Rev. 1.0.0 as an integrated
Network Controller (NC) device.
See Section 2.3.4 for full pin description and Section 11.6.2.5 for timing characteristics of this
interface.
1.4.7 MDIO/I2C 2-Wire Interfaces
The I210 implements a management Interface to control an optional external PHY. The interface can be
either a 2-wire Standard-mode I2C interface used to control an SFP module or an MII Management
Interface (also known as the Management Data Input/Output or MDIO Interface) for control plane
connection between the MAC and PHY devices (master side). This interface provides the MAC and
software with the ability to monitor and control the state of the external PHY. The I210 supports the
data formats defined in IEEE 802.3 clause 22.
Refer to Section 2.3.6 for a full pin description, Section 11.6.2.7 for MDIO timing characteristics, and
Section 11.6.2.3 for I2C timing characteristics of this interface.
The I2C interface can alternatively be run over the SDP 0 and SDP2 pins. This can be useful when the
I210 operates with a copper PHY since the dedicated SFPx_I2C pins are not available in this mode for
the control of other external devices.
Introduction—Ethernet Controller I210
11
1.4.8 Software-Definable Pins (SDP) Interface (General-Purpose I/O)
The I210 has four software-defined pins (SDP pins) that can be used for IEEE1588 auxiliary device
connections, enable/disable of the device, and for other miscellaneous hardware or software-control
purposes. These pins can be individually configurable to act as either standard inputs, General-Purpose
Interrupt (GPI) inputs or output pins (refer to Section 6.2.21, Section 8.2.1 and Section 8.2.3), as well
as the default value of all pins configured as outputs. Information on SDP usage can be found in
Section 3.5 and Section 7.8.3.3. Refer to Section 2.3.7 for pin description of this interface.
1.4.9 LED Interface
The I210 implements three output drivers intended for driving external LED circuits. Each of the three
LED outputs can be individually configured to select the particular event, state, or activity, which is
indicated on that output. In addition, each LED can be individually configured for output polarity as well
as for blinking versus a non-blinking (steady-state) indication.
The configuration for LED outputs is specified via the LEDCTL register. Furthermore, the hardware-
default configuration for all LED outputs can be specified via Flash fields (refer to Section 6.2.18 and
Section 6.2.20), thereby supporting LED displays configurable to a particular OEM preference.
Refer to Section 2.3.6 for full pin description of this interface.
Refer to Section 7.5 for more detailed description of LED behavior.
1.5 Features
Table 1-2 to Table 1-9 list the I210 and I211 features and compares them to other products.
Table 1-2. I210 Features
Feature I210 I211 I350 82574
Number of ports 1 1 4 1
Serial Flash interface Y1
1. Not applicable in Flash-less I210 operation.
N Y Y
Integrated NVM (iNVM) Y2
2. Flash-less I210 operation is supported (with no support for manageability related functionalities). Refer to the note that describes
the limitation in Section 1.4.3.
Y N N
4-wire SPI EEPROM interface N N Y Y
Configurable LED operation for software or OEM custom-tailoring of
LED displays Y Y Y Y
Protected Flash space for private configuration Y1N Y Y
Device disable capability Y Y Y Y
Package size (mm x mm) 9x9 9x9 17x17/25x25 9x9
Embedded thermal sensor N N Y N
Embedded thermal diode N N Y N
Watchdog timer Y Y Y Y
Feature I210 I211 I350 82574
Boundary-Scan IEEE 1149.1 Y Y Y Y
Boundary-Scan IEEE 1149.6 N N Y N
Industrial temp (special SKU) Y N N Y
Ethernet Controller I210 —Introduction
12
Table 1-3. Network Features
Feature I210 I211 I350 82574
Half duplex at 10/100 Mb/s operation and full duplex operation
at all supported speeds Y Y Y Y
10/100/1000 copper PHY integrated on-chip 1 port 1 port 4 ports 1 port
Jumbo frames supported Y Y Y Y
Size of jumbo frames supported 9.5 KB 9.5 KB 9.5 KB 9018B
Flow control support: send/receive PAUSE frames and receive
FIFO thresholds Y Y Y Y
Statistics for management and RMON Y Y Y Y
802.1q VLAN support Y Y Y Y
802.3az EEE support Y Y Y N
MDI flip N N Y N
SerDes interface for external PHY connection or system
interconnect Y N 4 ports N
1000BASE-KX interface for blade server backplane connections Y N Y N
802.3ap Backplane Auto-negotiation N N N N
SGMII interface for external 1000BASE-T PHY connection 1 port N 4 ports N
Fiber/copper auto-sense N N 4 ports N/A
SerDes support of non-auto-negotiation partner Y N Y N
SerDes signal detect Y N Y N
External PHY control I/F
MDC/MDIO 2-wire I/F
Y N Shared or
per function N
Table 1-4. Host Interface Features
Feature I210 I211 I350 82574
PCIe revision 2.1 2.1 2.1 (5 Gb/s
or 2.5 Gb/s) 1.1
PCIe physical layer Gen 1 Gen 1 Gen 2 Gen 1
Bus width x1 x1 x1, x2, x4 x1
64-bit address support for systems using more than
4 GB of physical memory Y Y Y Y
Outstanding requests for Tx buffers per port 6 6 24 per port
and for all
ports 4
Outstanding requests for Tx descriptors per port 1 1 4 per port
and for all
ports 2
Outstanding requests for Rx descriptors per port 1 1 4 per port
and for all
ports 2
Credits for posted writes 4 4 4 4
Max payload size supported 512 B 512 B 512 B 512 B
Max request size supported 2 KB 2 KB 2 KB 2 KB
Link layer retry buffer size 3.2 KB 3.2 KB 3.2 KB 2 KB
Vital Product Data (VPD) Y1N Y Y
Introduction—Ethernet Controller I210
13
VPD size 1024B1N/A 256B 256B
End to End CRC (ECRC) Y Y Y N
OBFF (Optimized Buffer Flush/Fill) Y2NNN
Latency Tolerance Reporting (LTR) Y2NYN
TPH Y Y Y N
CSR access via Configuration space Y Y Y N
Access Control Services (ACS) N N Y N
Audio Video Bridging (AVB) support Y N N N
1. Not supported in Flash-less I210 operation.
2. Disabled by default via Flash.
Table 1-5. LAN Functions Features
Feature I210 I211 I350 82574
Programmable host memory receive buffers Y Y Y Y
Descriptor ring management hardware for transmit and
receive Y Y Y Y
ACPI register set and power down functionality supporting D0
and D3 states Y Y Y Y
Software controlled global reset bit (resets everything except
the configuration registers) Y Y Y Y
Software Definable Pins (SDPs) - per port 4 4 4 N
Four SDP pins can be configured as general purpose interrupts Y Y Y N
Wake up Y Y Y Y
Flexible wake-up filters 8 8 8 6
Flexible filters for queue assignment in normal operation 8 8 8 N
IPv6 wake-up filters Y Y Y Y
Default configuration by the Flash for all LEDs for pre-driver
functionality 3 LEDs 3 LEDs 4 LEDs 3 LEDs
LAN function disable capability Y Y Y Y
Programmable memory transmit buffers Y Y Y Y
Double VLAN Y Y Y N
IEEE 1588 Y Y Y Y
Per-packet timestamp Y Y Y N
Tx rate limiting per queue Y N N N
Table 1-6. LAN Performance Features
Feature I210 I211 I350 82574
TCP segmentation offload
Up to 256 KB Y Y Y Y
iSCSI TCP segmentation offload (CRC) N N N N
IPv6 support for IP/TCP and IP/UDP receive checksum
offload Y Y Y Y
Table 1-4. Host Interface Features (Continued)
Feature I210 I211 I350 82574
Ethernet Controller I210 —Introduction
14
Fragmented UDP checksum offload for packet reassembly Y Y Y Y
Message Signaled Interrupts (MSI) Y Y Y Y
Message Signaled Interrupts (MSI-X) number of vectors 5 5 25 5
Packet interrupt coalescing timers (packet timers) and
absolute-delay interrupt timers for both transmit and receive
operation Y Y Y Y
Interrupt throttling control to limit maximum interrupt rate
and improve CPU utilization Y Y Y Y
Rx packet split header Y Y Y Y
Receive Side Scaling (RSS) number of queues per port Up to 4 Up to 2 Up to 8 Up to 2
Total number of Rx queues per port 4 2 8 2
Total number of TX queues per port 4 2 8 2
RX header replication
Low latency interrupt
DCA support
TCP timer interrupts
No snoop
Relax ordering
Yes to all Yes to all Yes to all
Only No
snoop and
Relax
ordering
TSO interleaving for reduced latency Y Y Y N
Receive Side Coalescing (RSC) N N N N
SCTP receive and transmit checksum offload Y Y Y N
UDP TSO Y Y Y Y
IPSec offload N N N N
Table 1-7. Virtualization Related Features
Feature I210 I211 I350 82574
Support for Virtual Machines Device queues (VMDq) per port N N 8 pools
(single
queue) N
L2 MAC address filters (unicast and multicast) 16 16 32 16
L2 VLAN filters Per port Per port Per pool Per port
PCI-SIG SR-IOV N N 8 VF N
Multicast/broadcast packet replication N N Y N
VM to VM packet forwarding (packet loopback) N N Y N
RSS replication N N N N
Traffic shaping N N N N
MAC and VLAN anti-spoofing N N Y N
Malicious driver detection N N Y N
Per-pool statistics Y Y Y N/A
Per-pool off loads Y Y Y N/A
Per-pool jumbo support Y Y Y N/A
Mirroring rules N N 4 N
Table 1-6. LAN Performance Features (Continued)
Feature I210 I211 I350 82574
Introduction—Ethernet Controller I210
15
External switch VEPA support N N Y N
External switch NIV (VNTAG) support N N N N
Promiscuous modes VLAN, unicast
multicast VLAN, unicast
multicast
VLAN,
unicast
multicast
unicast
multicast
Table 1-8. Manageability Features
Feature I210 I211 I350 82574
Advanced pass-through-compatible management packet
transmit/receive support Y1
1. mDNS is not supported in Flash-less I210 operation.
N Y Y
Managed ports on SMBus interface to external MC 11N 4 1
Auto-ARP reply over SMBus Y1N Y Y
NC-SI Interface to an external MC Y1N Y Y
Standard DMTF NC-SI protocol support Y1N Y Y
DMTF MCTP protocol over SMBus Y1N Y N
NC-SI hardware arbitration Y1N Y N
DMTF MCTP protocol over PCIe Y1N N N
OS to BMC traffic Y1N Y N
Manageability L2 address filters 2 N 2 1
Manageability VLAN L2 filters 8 N 8 4
Manageability EtherType filters 4 N 4 N
Manageability Flex L4 port filters 8 N 8 4
Manageability Flex TCO filters 1 N 1 2
Manageability L3 address filters (IPv4) 4 N 4 1
Manageability L3 address filters (IPv6) 4 N 4 1
Proxying2
2. In Flash-less I210 operation, proxying support requires a dedicated firmware code be loaded to the device via the host interface
(see Section 3.4.6).
1 ARP Offload
2 NS Offloads
MLD support
mDNS1
1 ARP Offload
2 NS Offloads
MLD support
1 ARP Offload
per PF
2 NS Offloads
per PF
N
Table 1-9. Power Management Features
Feature I210 I211 I350 82574
Magic packet wake-up enable with unique MAC address Y Y Y Y
ACPI register set and power down functionality supporting D0
and D3 states Y Y Y Y
Full wake-up support (APM and ACPI 2.0) Y Y Y Y
Smart power down at S0 no link and Sx no link Y Y Y Y
Table 1-7. Virtualization Related Features (Continued)
Feature I210 I211 I350 82574
Ethernet Controller I210 —Introduction
16
1.6 I210 and I211 Options
Table 1-10 lists the main differences between features supported by the I210 and I211.
1.7 Overview of Changes Compared to the I350
The following section describes the modifications designed in the I210 compared to the I350.
1.7.1 Network Interface
1.7.1.1 Energy Efficient Ethernet (IEEE802.3AZ)
The I210 supports negotiation and link transition to a Low Power Idle (LPI) state as defined in the
IEEE802.3az (EEE) standard. Energy Efficient Ethernet (EEE) is supported only in the internal copper
PHY mode and for the following technologies:
1000BASE-T
100BASE-TX
EEE enables reduction of the I210 power consumption as a function of link utilization. In addition, the
I210 enables overall system power reduction as a function of link utilization by reporting increased
latency tolerance values via PCIe LTR messages when link is in the LPI state. For more information,
refer to Section 3.7.7.
LAN disable functionality (equivalent to Static device off
functionality in the I210/I211) Y1Y1Y Y
PCIe function disable Y Y Y Y
Dynamic device off Y2Y2Y Y
EEE Y Y Y N
DMA coalescing Y N Y N
OBFF/PE_WAKE_N Y3N N N
1. Feature not functional if enabled together with dynamic device off.
2. Feature not functional if enabled together with static device off (such as LAN disable).
3. Disabled by default in Flash due to the lack of OBFF enabled platforms at initial release.
Table 1-10. I210 9x9 QFN and I211 9x9 QFN Package Feature
Feature I210 I211
SerDes/SGMII port Yes (for SerDes I210 SKU only) Not supported.
Manageability Yes Not supported
Integrated SVR and LVR control Supported Supported
82574 pinout compatibility Footprint compatibility only Not supported
82583V pinout compatibility Not supported Footprint compatibility only
Table 1-9. Power Management Features
Feature I210 I211 I350 82574
Introduction—Ethernet Controller I210
17
1.7.1.2 OBFF
The I210 support Optimized Buffer Flush Fill (OBFF) for synchronizing platform I/Os and optimizing CPU
sleep states. The support is via the PE_WAKE_N pin only.
1.7.2 Audio and Video Bridging Support
See Section 1.3.1 for details on IEEE 802.1Qav support.
1.7.2.1 Tx Timestamp
The I210 supports three types of transmit timestamps:
1. Reporting back of the timestamp in the transmit descriptor.
2. Inserting the timestamp in the packet sent.
3. Recording the timestamp of selected packet in a register (legacy behavior).
Transmit timestamp is described in Section 7.0, Inline Functions.
1.7.3 Virtualization
SR-IOV and VMDq is not supported in hardware by the I210. The I210 can still be used in virtualized
systems where the VM switching is done in software.
1.7.3.1 Number of Exact Match Filters
The number of RAH/RAL registers is 16.
1.7.4 Host Interface
1.7.4.1 MSI-X Support
The number of MSI-X vectors supported by the I210 changed to 5. For further information, refer to
Section 7.3.
1.7.4.2 Optimized Buffer Flush/FILL (OBFF)
The I210 supports the PCIe OBFF specification, using the PE_WAKE_N signal to enable synchronizing
device activity and optimize power management of memory, CPU and RC internal circuitry. By
synchronizing PCIe activity of PCIe endpoints, the system can stay in lower power states for a longer
duration.
When in buffer fill (DMA coalescing) operating mode, the PCIe link is optionally placed in a L1 power
saving state and DMA activity is placed on hold. The I210 moves into buffer flush mode when internal
receive buffers pass a pre-determined threshold value, a watchdog timer expires, or the PCIe interface
invokes a move out of buffer fill state. Further information can be found in Section 5.9.
Ethernet Controller I210 —Introduction
18
1.7.5 Manageability
1.7.5.1 DMTF MCTP Protocol Over PCIe
The I210 enables reporting and controlling all information exposed in a LOM device via NC-SI using the
MCTP protocol over PCIe in addition to SMBus. The MCTP interface over PCIe is used by the MC to
control the NIC and for pass through traffic. For more information, refer to Section 10.7.
1.7.5.2 Flash Structures
Management related Flash structures were updated. For further information see Chapter 6.0.
1.7.5.3 Improved Support of Shared MAC and Shared IP
The I210 supports better filtering in systems when the MAC or the IP is shared with the host. This
support is achieved using additional filtering capabilities as described in Section 10.3.1 and can be
controlled using a new set of NC-SI OEM commands as the functionality described in Section 10.6.3.14
and Section 10.3.7.
1.7.5.4 Simplified SMBus TCO Status and Filter Setting
The TCO status in SMBus received packet was reduced to eight bytes and most of the information was
removed in order to keep only the information relevant to the MCs. See Section 10.5.9.2.1.1 for
details.
In addition, a generic command is used to set the most common filtering options independently of the
actual filters implementation. See Section 10.5.9.1.7 for details.
1.7.5.5 Diagnostic Commands
Commands were added to the NC-SI and legacy SMBus to query the identity of the I210 and the
firmware versions currently running on the I210. See Section 10.5.9.2.7 and Section 10.6.3.16.1 for
details.
1.7.6 BOM Cost Reduction
1.7.6.1 On-chip 0.9V SVR Control
The I210 includes a fully integrated on-chip Switching Voltage Regulator (SVR) that can be used to
generate a 0.9V power supply without the need for a higher cost on-board 0.9V voltage regulator (refer
to Section 3.6).
1.8 Device Data Flows
1.8.1 Transmit Data Flow
Table 1-11 lists a high level description of all data/control transformation steps needed for sending
Ethernet packets to the line.
Introduction—Ethernet Controller I210
19
1.8.2 Receive Data Flow
Table 1-12 lists a high level description of all data/control transformation steps needed for receiving
Ethernet packets.
Table 1-11. Transmit Data Flow
Step Description
1The host creates a descriptor ring and configures one of the I210's transmit queues with the address location,
length, head and tail pointers of the ring (one of 4 available Tx queues).
2The host is requested by the TCP/IP stack to transmit a packet, it gets the packet data within one or more data
buffers.
3The host initializes descriptor(s) that point to the data buffer(s) and have additional control parameters that
describe the needed hardware functionality. The host places that descriptor in the correct location at the
appropriate Tx ring.
4 The host updates the appropriate queue tail pointer (TDT)
5The I210's DMA senses a change of a specific TDT and as a result sends a PCIe request to fetch the descriptor(s)
from host memory.
6The descriptor(s) content is received in a PCIe read completion and is written to the appropriate location in the
descriptor queue internal cache.
7The DMA fetches the next descriptor from the internal cache and processes its content. As a result, the DMA sends
PCIe requests to fetch the packet data from system memory.
8The packet data is received from PCIe completions and passes through the transmit DMA that performs all
programmed data manipulations (various CPU off loading tasks as checksum off load, TSO off load, etc.) on the
packet data on the fly.
9While the packet is passing through the DMA, it is stored into the transmit FIFO. After the entire packet is stored in
the transmit FIFO, it is forwarded to the transmit switch module.
10 The transmit switch arbitrates between host and management packets and eventually forwards the packet to the
MAC.
11 The MAC appends the L2 CRC to the packet and sends the packet to the line using a pre-configured interface.
12 When all the PCIe completions for a given packet are done, the DMA updates the appropriate descriptor(s).
13 After enough descriptors are gathered for write back or the interrupt moderation timer expires, the descriptors are
written back to host memory using PCIe posted writes. Alternatively, the head pointer can only be written back.
14 After the interrupt moderation timer expires, an interrupt is generated to notify the host device driver that the
specific packet has been read to the I210 and the driver can release the buffers.
Table 1-12. Receive Data Flow
Step Description
1The host creates a descriptor ring and configures one of the I210's receive queues with the address location,
length, head, and tail pointers of the ring (one of 4 available Rx queues).
2The host initializes descriptors that point to empty data buffers. The host places these descriptors in the correct
location at the appropriate Rx ring.
3 The host updates the appropriate queue tail pointer (RDT).
4The I210's DMA senses a change of a specific RDT and as a result sends a PCIe request to fetch the descriptors
from host memory.
5The descriptors content is received in a PCIe read completion and is written to the appropriate location in the
descriptor queue internal cache.
6 A packet enters the Rx MAC. The Rx MAC checks the CRC of the packet.
7 The MAC forwards the packet to an Rx filter.
8If the packet matches the pre-programmed criteria of the Rx filtering, it is forwarded to the Rx FIFO. VLAN and
CRC are optionally stripped from the packet and L3/L4 checksum are checked and the destination queue is fixed.
9The receive DMA fetches the next descriptor from the internal cache of the appropriate queue to be used for the
next received packet.
Ethernet Controller I210 —Introduction
20
10 After the entire packet is placed into the Rx FIFO, the receive DMA posts the packet data to the location indicated
by the descriptor through the PCIe interface. If the packet size is greater than the buffer size, more descriptors are
fetched and their buffers are used for the received packet.
11 When the packet is placed into host memory, the receive DMA updates all the descriptor(s) that were used by
packet data.
12 After enough descriptors are gathered for write back or the interrupt moderation timer expires or the packet
requires immediate forwarding, the receive DMA writes back the descriptor content along with status bits that
indicate the packet information including what off loads were done on that packet.
13 After the interrupt moderation timer completes or an immediate packet is received, the I210 initiates an interrupt
to the host to indicate that a new received packet is already in host memory.
14 Host reads the packet data and sends it to the TCP/IP stack for further processing. The host releases the
associated buffers and descriptors once they are no longer in use.
Table 1-12. Receive Data Flow (Continued)
Step Description
Pin Interface—Ethernet Controller I210
21
2.0 Pin Interface
2.1 Pin Assignments
The I210 supports a 64-pin, 9 x 9 QFN package with an Exposed Pad* (e-Pad*). Note that the e-Pad is
ground.
Figure 2-1. I210 64-Pin, 9 x 9 QFN Package With e-Pad
Copper
RSET
VDD1p5
XTAL1
XTAL2
NC_SI_ARB_OUT
NC_SI_ARB_IN
VDD0p9
VDD3p3
CTOP
VDD1p5_OUT
VDD0p9_OUT
CBOT
SMB_DAT
SMB_ALRT_N
SMB_CLK
LED2
48 47 46 45 44 43 42 41 40 39 38 37 36 35 34 33
SER_N MDI_MINUS[3] 49 32 VDD0p9
SER_P MDI_PLUS[3] 50 31 LED0
VDD1p5 VDD3p3 51 30 LED1
SET_N MDI_MINUS[2] 52 29 JTAG_TDI
SET_P MDI_PLUS[2] 53 28 DEV_OFF_N
SRDS_SIG_DET MDI_MINUS[1] 54 27 VDD3p3
SFP_I2C_CLK MDI_PLUS[1] 55 26 PECLKp
NC VDD1p5 56 25 PECLKn
SFP_12C_DATA MDI_MINUS[0] 57 24 PE_Rp
NC MDI_PLUS[0] 58 23 PE_Rn
VDD0p9 59 22 NC
SDP3 60 21 PE_Tp
SDP1[PCIe_DIS] 61 20 PE_Tn
SDP2 62 19 JTAG_CLK
SDP0 63 18 JTAG_TMS
VDD3p3 64 17 PE_RST_N
12345678910111213141516
LAN_PWR_GOOD
NC_SI_CLK_IN
NC_SI_CRS_DV
JTAG_TDO
NC_SI_RXD1
NC_SI_RXD0
NC_SI_TX_EN
NC_SI_TXD1
NC_SI_TXD0
VDD3p3
VDD0p9
NVM_SI
NVM_SK
NVM_SO
NVM_CS_N
PE_WAKE_N
SerDes
I210
64-Pin QFN
9 mm x 9mm
0.5 mm Pin
Pitch
With e-PAD
Ethernet Controller I210 —Pin Interface
22
2.2 Pull-Up/Pull-Down Resistors
Table 2-1 lists internal and external pull-up/pull-down resistors and their functionality in different
device states.
As stated in the name and function table columns, the internal Pull-Up/Pull-Down (PU/PD) resistor
values are 30 K ± 50%.
Only relevant (digital) pins are listed; analog or bias and power pins have specific considerations
listed in Chapter 11.0.
Note: Refer to Section 12.0 for a list of board design schematic checklists, layout checklists, and
reference design schematics for more details.
The device states are defined as follows:
Power-up = while 3.3V is stable, yet 1.0V isn’t
Active = normal mode (not power up or disable)
Disable = device off or dynamic device off – refer to Section 4.3.3
Table 2-1. Pull-Up/Pull-Down Resistors
Signal Name Power Up1Active Disable2External
PU Comments PU Comments PU Comments
LAN_PWR_GOOD N N N Y
PE_WAKE_N N N N Y
PE_RST_N N N N PU3
NVM_SI N N Y PD/PU4
NVM_SO Y Y Y N
NVM_SK Y N Y N
NVM_CS_N Y N Y N
SMBD N N N Y
SMBCLK N N N Y
SMBALRT_N N N N Y
NCSI_CLK_IN N HiZ N N PD
NCSI_CRS_DV N HiZ N N PD
NCSI_RXD[1:0] N HiZ N N PU
NCSI_TX_EN N HiZ N N PD
NCSI_TXD[1:0] N HiZ N N PU
NCSI_ARB_OUT N N N Stable high
output N
NCSI_ARB_IN N HiZ N 5N5N
SDP0 Y Y Until Flash auto-
load done YMight keep
state by Flash
control N
SDP1 Y Y Until Flash auto-
load done YMight keep
state by Flash
control N
SDP2 Y Y Until Flash auto-
load done YMight keep
state by Flash
control N
Pin Interface—Ethernet Controller I210
23
2.3 Signal Type Definition
SDP3 Y Y Until Flash auto-
load done YMight keep
state by Flash
control N
DEV_OFF_N Y N N PU optional if
NC-SI is not
used.
SRDS_SIG_DET Y N N Must be
connected on
board
SFP_I2C_CLK Y Y
Until Flash auto-
load done or if
I2C disable set in
Flash
Y Y if I2C
SFP_I2C_DATA Y Y
Until Flash auto-
load done or if
I2C disable set in
Flash
Y Y
LED0 Y N N HiZ
LED1 Y N N HiZ
LED2 Y N N HiZ
JTAG_CLK N N N Y6
JTAG_TDI N N N Y
JTAG_TDO N N N Y6
JTAG_TMS N N N Y6
1. Power up - LAN_PWR_GOOD = 0b
2. Refer to Section 5.2.6 for description of disable state.
3. 10 KΩ to 100 KΩ pull up can be used.
4. When pulled up, Flash security features are enabled.
5. If NC-SI hardware arbitration is disabled via the NC-SI ARB Enable Flash bit (refer to Section 6.2.22), NCSI_ARB_IN pin is pulled-
up internally.
6. These pins can be pulled up or pulled down (design dependent) when no clock device is connected to it.
In Input is a standard input-only signal.
Out (O) Totem pole output is a standard active driver.
T/s Tri-State is a bi-directional, tri-state input/output pin.
S/t/s
Sustained tri-state is an active low tri-state signal owned and driven by one and only one agent
at a time. The agent that drives an s/t/s pin low must drive it high for at least one clock before
letting it float. A new agent cannot start driving an s/t/s signal any sooner than one clock after
the previous owner tri-states it.
O/d Open drain enables multiple devices to share as a wire-OR.
A-in Analog input signals.
A-out Analog output signals.
B Input bias.
NCSI_in NCSI input signal.
NCSI-out NCSI output signal.
Table 2-1. Pull-Up/Pull-Down Resistors (Continued)
Signal Name Power Up1Active Disable2External
PU Comments PU Comments PU Comments
Ethernet Controller I210 —Pin Interface
24
2.3.1 PCIe
2.3.2 Flash
Table 2-2. PCIe
Symbol Reserved Lead # Type Op
Mode Name and Function
PECLKp
PECLKn
26
25 A-in Input
PCIe Differential Reference Clock In
This pin receives a 100 MHz differential clock input. This clock
is used as the reference clock for the PCIe Tx/Rx circuitry and
by the PCIe core PLL to generate a 125 MHz clock and
250 MHz clock for the PCIe core logic.
PE_Tp
PE_Tn 21
20 A-out Output
PCIe Serial Data Output
Serial differential output link in the PCIe interface running at
2.5 Gb/s. This output carries both data and an embedded
2.5 GHz clock that is recovered along with data at the
receiving end.
PE_Rp
PE_Rn
24
23 A-in Input
PCIe Serial Data Input
Serial differential input link in the PCIe interface running at
2.5 Gb/s. The embedded clock present in this input is
recovered along with the data.
PE_WAKE_N 16 T/s Bi-dir
Wake
The I210 drives this signal to zero when it detects a wake-up
event and either:
The PME_en bit in PMCSR is 1b or
The APME bit of the Wake Up Control (WUC) register is
1b.
In OBFF mode, OBFF events are signaled using the
PE_WAKE_N pin.
PE_RST_N 17 In Input
Power and Clock Good Indication
The PE_RST_N signal indicates that both PCIe power and
clock are available.
Table 2-3. Flash
Symbol Reserved Lead # Type Op
Mode Name and Function
NVM_SI 12 T/s Output
Serial Data Output
Connect this lead to the input of the Flash.
NVM_SO 14 T/s Input
Serial Data Input
Connect this lead to the output of the Flash.
NVM_SK 13 T/s Output Non-Volatile Memory Serial Clock
NVM_CS_N 15 T/s Output Non-Volatile Memory Chip Select Output
Pin Interface—Ethernet Controller I210
25
2.3.3 System Management Bus (SMBus) Interface
Note: If the SMBus is disconnected, an external pull-up should be used for these pins, unless it is
guaranteed that manageability is disabled in the I210.
2.3.4 NC-SI and Testability
Table 2-4. SMBus Interface
Symbol Reserved Lead # Type Op Mode Name and Function
SMB_DATA 36 T/s, o/d Bi-dir
SMBus Data.
Stable during the high period of the clock (unless
it is a start or stop condition).
SMB_CLK 34 T/s, o/d Bi-dir
SMBus Clock.
One clock pulse is generated for each data bit
transferred.
SMB_ALRT_N 35 T/s, o/d Output
SMBus Alert.
Acts as an interrupt pin of a slave device on the
SMBus in pass-through mode.
Table 2-5. NC-SI and Testability
Symbol Reserved Lead # Type Op
Mode Name and Function
NC_SI_CLK_IN 2 NCSI_in Input
NC-SI Reference Clock Input.
Synchronous clock reference for receive, transmit, and
control interface. This signal is a 50 MHz clock +/- 100 ppm.
NC_SI_CRS_DV 3 NCSI_out Output NC-SI Carrier Sense/Receive Data Valid (CRS/DV).
NC_SI_RXD0 6 NCSI_out Output NC-SI Receive Data 0.
Data signals to the Manageability Controller (MC).
NC_SI_RXD1 5 NCSI_out Output NC-SI Receive Data 1.
Data signals to the MC.
NC_SI_TX_EN 7 NCSI_in Input NC-SI Transmit Enable.
NC_SI_TXD0 9 NCSI_in Input
NC-SI Transmit Data 0.
Data signals from the MC.
NC_SI_ARB_IN 43 NC-SI-in Input NC-SI hardware arbitration token output pin.
NC_SI_ARB_OUT 44 NC-SI-out Output NC-SI hardware arbitration token input pin.
NC_SI_TXD1 8 NCSI_in Input
NC-SI Transmit Data 1.
Data signal from the MC.
JTAG_TDI 29 In Input JTAG TDI Input.
JTAG_CLK 19 In Input JTAG Clock Input.
JTAG_TMS 18 In Input
JTAG Test Mode Select.
This input controls the transitions of the test interface state
machine.
JTAG_TDO 4 O/D JTAG TDO
Ethernet Controller I210 —Pin Interface
26
2.3.5 LEDs
Table 2-6 lists the functionality of each LED output pin. The default activity of each LED can be modified
in the Flash. The LED functionality is reflected and can be further modified in the configuration registers
(LEDCTL).
2.3.6 PHY Pins
Note: The I210 has built in termination resistors. As a result, external termination resistors should
not be used.
Table 2-6. LEDs
Symbol Reserved Lead # Type Op
Mode Name and Function
LED0 31 Out Output Programmable LED number 0.
LED1 30 Out Output Programmable LED number 1.
LED2 33 Out Output Programmable LED number 2.
Table 2-7. PHY Pins
Symbol Lead # Type Op
Mode Name and Function
MDI_PLUS[0]/NC 58 A Bi-dir
In BASE-T:
Media Dependent Interface[0]:
1000BASE-T:
In MDI configuration, MDI[0]+ corresponds to BI_DA+ and in MDI-X
configuration MDI[0]+ corresponds to BI_DB+.
100BASE-TX:
In MDI configuration, MDI[0]+ is used for the transmit pair and in MDIX
configuration MDI[0]+ is used for the receive pair.
10BASE-T:
In MDI configuration, MDI[0]+ is used for the transmit pair and in MDI-X
configuration MDI[0]+ is used for the receive pair.
MDI_MINUS[0]/
SFP_I2C_DATA 57 A Bi-dir
In BASE-T:
Media Dependent Interface[0]:
1000BASE-T:
In MDI configuration, MDI[0]- corresponds to BI_DA- and in MDI-X
configuration MDI[0]- corresponds to BI_DB-.
100BASE-TX:
In MDI configuration, MDI[0]- is used for the transmit pair and in MDIX
configuration MDI[0]- is used for the receive pair.
10BASE-T:
In MDI configuration, MDI[0]- is used for the transmit pair and in MDI-X
configuration MDI[0]- is used for the receive pair.
In SerDes:
SFP 2 wire interface data – connects to Mod-Def2 pin of SFP (O/D). Can also be
used as MDIO pin (T/S).
Pin Interface—Ethernet Controller I210
27
MDI_PLUS[1]/
SFP_I2C_CLK 55 A Bi-dir
In BASE-T:
Media Dependent Interface[1]:
1000BASE-T:
In MDI configuration, MDI[1]+ corresponds to BI_DB+ and in MDI-X
configuration MDI[1]+ corresponds to BI_DA+.
100BASE-TX:
In MDI configuration, MDI[1]+ is used for the receive pair and in MDI-X
configuration MDI[1]+ is used for the transmit pair.
10BASE-T:
In MDI configuration, MDI[1]+ is used for the receive pair and in MDI-X
configuration MDI[1]+ is used for the transmit pair.
In SerDes:
SFP 2 wire interface clock – connects to Mod-Def1 input of SFP (O/D). Can also
be used as MDC pin (Out).
MDI_MINUS[1]/
SRDS_SIG_DET 54 A Bi-dir
In BASE-T:
Media Dependent Interface[1]:
1000BASE-T:
In MDI configuration, MDI[1]- corresponds to BI_DB- and in MDI-X
configuration MDI[1]- corresponds to BI_DA-.
100BASE-TX:
In MDI configuration, MDI[1]- is used for the receive pair and in MDI-X
configuration MDI[1]- is used for the transmit pair.
10BASE-T:
In MDI configuration, MDI[1]- is used for the receive pair and in MDI-X
configuration MDI[1]- is used for the transmit pair.
In SerDes:
Signal Detect: Indicates that signal (light) is detected from the fiber. High for
signal detect, low otherwise.
Polarity of Signal Detect pin is controlled by the CTRL.ILOS bit.
For non-fiber SerDes applications, link indication is internal,
CONNSW.ENRGSRC bit should be 0b and pin should be connected to a pull-up
resistor.
MDI_PLUS[2]
MDI_MINUS[2]/SET_N
MDI_PLUS[3]/SER_P
MDI_MINUS[3]/SER_N
53
52
50
49
A Bi-dir
In BASE-T:
Media Dependent Interface[3:2]:
1000BASE-T:
In MDI and in MDI-X configuration, MDI[2]+/- corresponds to BI_DC+/- and
MDI[3]+/- corresponds to BI_DD+/-.
100BASE-TX: Unused.
10BASE-T: Unused.
In SerDes
SerDes/SGMII Serial Data input/output: Differential SERDES Receive/Transmit
interface.
A serial differential input/output pair running at 1.25Gb/s.
An embedded clock present in this input is recovered along with the data.
This output carries both data and an embedded 1.25 GHz clock that is
recovered along with data at the receiving end.
XTAL1
XTAL2
46
45
A-In
A-Out
Input/
Output
XTAL In/Out
These pins can be driven by an external 25 MHz crystal or driven by an external
MOS level 25 MHz oscillator. Used to drive the PHY.
RSET 48 A Bias PHY Termination
This pin should be connected through a 4.99 K ±1% resister to ground.
Table 2-7. PHY Pins
Symbol Lead # Type Op
Mode Name and Function
Ethernet Controller I210 —Pin Interface
28
2.3.7 Miscellaneous Pins
2.3.8 Power Supplies and Support Pins
2.3.8.1 Power Support
Note: These pins must be connected together by a 39 nF capacitor (refer to capacitor part #
GRM155R61A393KA01).
Table 2-8. Miscellaneous Pins
Symbol Reserved Lead # Type Op
Mode Name and Function
DEV_OFF_N 28 In Input
This is a 3.3V input signal. Asserting DEV_OFF_N puts
the I210 in device disable mode. Note that this pin is
asynchronous.
Functionality of this input can be changed by Flash
bits settings - see Table 2-11 for more details.
SDP0 63 T/s Input/
Output Software defined pin 0.
SDP1
[PCIe_DIS]SDP1 61 T/s Input/
Output Software defined pin 1. See Table 2-11 for PCIe
function disable settings.
SDP2 62 T/s Input/
Output Software defined pin 2.
SDP3 60 T/s Input/
Output Software defined pin 3.
LAN_PWR_GOOD 1 In Input
LAN Power Good: A 3.3V input signal. A transition
from low to high initializes the device into operation.
If the internal Power-on-Reset (POR) circuit is used to
trigger device power-up, this signal should be
connected to VDDO.
NC 22 Voltage Input Optional pin used to connect an external power supply
to the PCIe block in order to replace the internal LDO.
Table 2-9. Power Support
Symbol Reserved Lead # Type /
Voltage Name and Function
CBOT 37 A-in
A-Out Capacitor bottom connection.
CTOP 40
A-In
capacitor
A-Out
Capacitor top connection.
Pin Interface—Ethernet Controller I210
29
2.3.8.2 Power Supply
Table 2-10. Power Supply
Symbol Lead # Type /
Voltage Name and Function
VDD0p9 11, 32, 42, 59 0.9V 0.9V digital power supply.
VDD3p3 10, 27, 41,
51, 64 3.3V
3.3V power supply (for I/O).
Pin 51: In BASE-T, 3.3V analog power supply to GPHY; in
SerDes, 1.5V analog power supply to SGMII SerDes.
VDD1p5 47, 56 1.5V
Pin 47: 1.5V power supply to the crystal oscillator and
bandgap.
Pin 56: In BASE-T, 1.5V analog power supply to GPHY; in
SerDes, not connected.
VDD0p9_OUT 38 0.9V 0.9V power supply output of the switching cap regulator.
VDD1p5_OUT 39 1.5V 1.5V power supply output of the switching cap regulator.
GND e-Pad Ground The e-Pad metal connection on the bottom of the package.
Should be connected to ground.
Ethernet Controller I210 —Pin Interface
30
2.4 Strapping Options
Note: nvm_aux_pwr_en and nvm_alt_aux_pwr_en bits are read as 0b from NVM, AUX_PWR mode
is enabled.
Table 2-11. Strapping Options
Pad NVM PU
0x1E.15
0x29.10
0x29.13
0x29.15
Internal
PU
Function Latch Event
DEV_OFF_N
SDP3
NVM_SK
NVM_SI
SDP1 [PCIe_DIS]
Device Off Enable
nvm_aux_pwr_en
nvm_alt_aux_pwr_en
en_pin_pcie_func_dis
Comments
DEV_OFF_N N/A 0 X X X X 1 X X X Device off mode when the pin is
pulled low.
AUX_PWR (option 1) N/A 1 X X X X 0 1 X X AUX power mode when the pin is
pulled high.
AUX_PWR (option 2) N/A X 1 X X X 0 0 1 X AUX power mode when the pin is
pulled high.
SECURITY_EN LAN_PWR_GOOD X X X 1 X X X X X PU (until
LPG) Flash security is disabled when the
pin is pulled low.
PCIE_DIS_N N/A X X X X 0 X X X 1 Active low, valid on Flash load
complete. Strap logic that requires a
dedicated SDP.
Pin Interface—Ethernet Controller I210
31
2.5 Package
The I210 supports a 64-pin, 9 x 9 QFN package with e-Pad. Figure 2-2 shows the package schematics.
Figure 2-2. I210 QFN 9 x 9 mm Package
Die Pad Size Option
Symbol
Dimension
in inch
Dimension
in mm
Ethernet Controller I210 —Pin Interface
32
NOTE: This page intentionally left blank.
Interconnects—Ethernet Controller I210
33
3.0 Interconnects
3.1 PCIe
3.1.1 PCIe Overview
PCIe is a third generation I/O architecture that enables cost competitive next generation I/O solutions
providing industry leading price/performance and features. It is an industry-driven specification.
PCIe defines a basic set of requirements that encases the majority of the targeted application classes.
Higher-end applications' requirements, such as enterprise class servers and high-end communication
platforms, are encased by a set of advanced extensions that compliment the baseline requirements.
To guarantee headroom for future applications of PCIe, a software-managed mechanism for introducing
new, enhanced, capabilities in the platform is provided. Figure 3-1 shows PCIe architecture.
Figure 3-1. PCIe Stack Structure
2.5+
2.5+ Gb
Gb /s
/s
PCI.sys Compliant
PCI.sys Compliant
Configurable widths 1 .. 32
Configurable widths 1 .. 32
Preserve Driver Model
Preserve Driver Model
Config/OS
S/W
Protocol
Link
Common Base Protocol
Common Base Protocol
Advanced
Advanced XtensionsXtensions
Physical
(electrical
mechanical)
Point to point, serial, differential,
Point to point, serial, differential,
hot
hot -
-plug, inter
plug, inter -
-op
op formfactors
formfactors
Ethernet Controller I210 —Interconnects
34
PCIe's physical layer consists of a differential transmit pair and a differential receive pair. Full-duplex
data on these two point-to-point connections is self-c such that no dedicated clock signals are required.
The bandwidth of this interface increases linearly with frequency.
The packet is the fundamental unit of information exchange and the protocol includes a message space
to replace the various side-band signals found on many buses today. This movement of hard-wired
signals from the physical layer to messages within the transaction layer enables easy and linear
physical layer width expansion for increased bandwidth.
The common base protocol uses split transactions and several mechanisms are included to eliminate
wait states and to optimize the reordering of transactions to further improve system performance.
3.1.1.1 Architecture, Transaction and Link Layer Properties
Split transaction, packet-based protocol
Common flat address space for load/store access (such as PCI addressing model)
Memory address space of 32-bits to allow compact packet header (must be used to access
addresses below 4 GB)
Memory address space of 64-bit using extended packet header
Transaction layer mechanisms:
PCI-X style relaxed ordering
Optimizations for no-snoop transactions
Credit-based flow control
Packet sizes/formats:
Maximum upstream (write) payload size of 512 bytes
Maximum downstream (read) payload size of 512 bytes
Reset/initialization:
Frequency/width/profile negotiation performed by hardware
Data integrity support
Using CRC-32 for transaction layer packets
Link layer retry for recovery following error detection
Using CRC-16 for link layer messages
No retry following error detection
8b/10b encoding with running disparity
Software configuration mechanism:
Uses PCI configuration and bus enumeration model
PCIe-specific configuration registers mapped via PCI extended capability mechanism
Baseline messaging:
In-band messaging of formerly side-band legacy signals (such as interrupts, etc.)
System-level power management supported via messages
Power management:
Full support for PCI-PM
Wake capability from D3cold state
Compliant with ACPI, PCI-PM software model
Interconnects—Ethernet Controller I210
35
Active state power management
Support for PCIe v2.1 (2.5GT/s)
Support for completion time out
Support for additional registers in the PCIe capability structure.
3.1.1.2 Physical Interface Properties
Point to point interconnect
Full-duplex; no arbitration
Signaling technology:
Low Voltage Differential (LVD)
Embedded clock signaling using 8b/10b encoding scheme
Serial frequency of operation: 2.5 Gb/s.
Interface width of x1.
DFT and DFM support for high volume manufacturing
3.1.1.3 Advanced Extensions
PCIe defines a set of optional features to enhance platform capabilities for specific usage modes. The
I210 supports the following optional features:
Extended error reporting - messaging support to communicate multiple types/severity of errors.
Device serial number.
Completion timeout control.
TLP Processing Hints (TPH) - provides hints on a per transaction basis to facilitate optimized
processing of transactions that target memory space.
Latency Tolerance Reporting (LTR) - messaging support to communicate service latency
requirements for memory reads and writes to the root complex.
3.1.2 General Functionality
3.1.2.1 Native/Legacy
All the I210 PCI functions are native PCIe functions.
3.1.2.2 Transactions
The I210 does not support requests as target or master.
3.1.3 Host Interface
3.1.3.1 Tag IDs
PCIe device numbers identify logical devices within the physical device (the I210 is a physical device).
The I210 implements a single logical device with one PCI function. The device number is captured from
the type 0 configuration write transaction.
Ethernet Controller I210 —Interconnects
36
The PCIe function interfaces with the PCIe unit through one or more clients. A client ID identifies the
client and is included in the Tag field of the PCIe packet header. Completions always carry the tag value
included in the request to enable routing of the completion to the appropriate client.
Tag IDs are allocated differently for read and write. Messages are sent with a tag of 0x0.
3.1.3.1.1 TAG ID Allocation for Read Transactions
Table 3-1 lists the Tag ID allocation for read accesses. The tag ID is interpreted by hardware in order to
forward the read data to the required device.
3.1.3.1.2 TAG ID Allocation for Write Transactions
Request tag allocation depends on these system parameters:
DCA supported/not supported in the system (DCA_CTRL.DCA_DIS - refer to Section 8.13.4 for
details)
TPH enabled in the system.
DCA enabled/disabled for each type of traffic (TXCTL.TX Descriptor DCA EN, RXCTL.RX Descriptor
DCA EN, RXCTL.RX Header DCA EN, RXCTL.Rx Payload DCA EN).
TPH enabled or disabled for the specific type of traffic carried by the TLP (TXCTL.TX Descriptor TPH
EN, RXCTL.RX Descriptor TPH EN, RXCTL.RX Header TPH EN, RXCTL.Rx Payload TPH EN).
System type: Legacy DCA vs. DCA 1.0 (DCA_CTRL.DCA_MODE - refer to Section 8.13.4 for
details).
CPU ID (RXCTL.CPUID or TXCTL.CPUID).
See the case studies below for information on different implementations
3.1.3.1.2.1 Case 1 - DCA Disabled in the System
Table 3-2 lists the write requests tags. Unlike read, the values are for debug only, allowing tracing of
requests through the system.
Table 3-1. IDs in Read Transactions
Tag ID Description Comment
0x0 Data request 0
0x1 Data request 1
0x2 Data request 2
0x3 Data request 3
0x4 Data request 4
0x5 Data request 5
0x6-017 Not used
0x18 Descriptor Tx
0x19-0x1B Not used
0x1C Descriptor Rx
0x1D-0x1F Not used
Interconnects—Ethernet Controller I210
37
3.1.3.1.2.2 Case 2 - DCA Enabled in the System, but Disabled for the Request
Legacy DCA platforms - If DCA is disabled for the request, the tags allocation is identical to the case
where DCA is disabled in the system. Refer to Table 3-2.
DCA 1.0 platforms - All write requests have a tag value of 0x00.
Note: When in DCA 1.0 mode, messages and MSI/MSI-X write requests are sent with the no-hint
tag.
3.1.3.1.2.3 Case 3 - DCA Enabled in the System, DCA Enabled for the Request
Legacy DCA platforms: the request tag is constructed as follows:
Bit[0] – DCA Enable
Bits[3:1] - The CPU ID field taken from the CPUID[2:0] bits of the RXCTL or TXCTL registers
Bits[7:4] - Reserved
DCA 1.0 platforms: the request tag (all 8 bits) is taken from the CPUID field of the RXCTL or TXCTL
registers
3.1.3.1.2.4 Case 4 - TPH Enabled in the System, TPH Enabled for the Request
The request tag (all 8 bits) is taken from the CPUID field of the adequate register or context as
listed in Table 7-61.
3.1.3.2 Completion Timeout Mechanism
In any split transaction protocol, there is a risk associated with the failure of a requester to receive an
expected completion. To enable requesters to attempt recovery from this situation in a standard
manner, the completion timeout mechanism is defined.
The completion timeout mechanism is activated for each request that requires one or more completions
when the request is transmitted. The I210 provides a programmable range for the completion timeout,
as well as the ability to disable the completion timeout altogether. The completion timeout is
programmed through an extension of the PCIe capability structure (refer to Section 9.4.6.12).
The I210’s reaction in case of a completion timeout is listed in Table 3-12.
The I210 controls the following aspects of completion timeout:
Table 3-2. IDs in Write Transactions (DCA Disabled Mode)
Tag ID Description
0x0 - 0x1 Reserved
0x2 Tx descriptors write-back / Tx head write-back
0x3 Reserved
0x4 Rx descriptors write-back
0x5 Reserved
0x6 Write data
0x7 - 0x1D Reserved
0x1E MSI and MSI-X
0x1F Reserved
Ethernet Controller I210 —Interconnects
38
Disabling or enabling completion timeout.
Disabling or enabling re-send of a request on completion timeout.
A programmable range of re-sends on completion timeout, if re-send enabled.
A programmable range of timeout values.
Programming the behavior of completion timeout is listed in Table 3-3.
Completion Timeout Enable - Programmed through the PCI Device Control 2 configuration register. The
default is: Completion Timeout Enabled.
Resend Request Enable - The Completion Timeout Resend Flash bit (loaded to the
Completion_Timeout_Resend bit in the PCIe Control (GCR) register enables resending the request
(applies only when completion timeout is enabled). The default is to resend a request that timed out.
Number of re-sends on timeout - Programmed through the Number of resends field in the GCR register.
The default value of resends is 3.
3.1.3.2.1 Completion Timeout Period
Programmed through the PCI Device Control 2 configuration register (refer to Section 9.4.6.12). The
I210 supports all ranges defined by PCIe v2.1 (2.5GT/s).
A memory read request for which there are multiple completions are considered completed only when
all completions have been received by the requester. If some, but not all, requested data is returned
before the completion timeout timer expires, the requestor is permitted to keep or to discard the data
that was returned prior to timer expiration.
Note: The completion timeout value must be programmed correctly in PCIe configuration space (in
the Device Control 2 register); the value must be set above the expected maximum latency
for completions in the system in which the I210 is installed. This ensures that the I210
receives the completions for the requests it sends out, avoiding a completion timeout
scenario. It is expected that the system BIOS sets this value appropriately for the system.
3.1.4 Transaction Layer
The upper layer of the PCIe architecture is the transaction layer. The transaction layer connects to the
I210 core using an implementation specific protocol. Through this core-to-transaction-layer protocol,
the application-specific parts of the I210 interact with the PCIe subsystem and transmit and receive
requests to or from the remote PCIe agent, respectively.
Table 3-3. Completion Timeout Programming
Capability Programming capability
Completion Timeout Enabling Controlled through PCI Device Control 2 configuration register.
Resend Request Enable Loaded from the Flashinto the GCR register.
Number of Re-sends on Timeout Controlled through GCR register.
Completion Timeout Period Controlled through PCI Device Control 2 configuration register.
Interconnects—Ethernet Controller I210
39
3.1.4.1 Transaction Types Accepted by the I210
Flow control types:
PH - Posted request headers
PD - Posted request data payload
NPH - Non-posted request headers
NPD - Non-posted request data payload
CPLH - Completion headers
CPLD - Completion data payload
3.1.4.1.1 Configuration Request Retry Status
PCIe supports devices requiring a lengthy self-initialization sequence to complete before they are able
to service configuration requests. This is the case for the I210 where initialization is long due to the
Flash read operation following reset.
If the read of the PCIe section in the Flash was not completed and the I210 receives a configuration
request, the I210 responds with a configuration request retry completion status to terminate the
request. This effectively stalls the configuration request until the subsystem completes a local
initialization and is ready to communicate with the host.
3.1.4.1.2 Partial Memory Read and Write Requests
The I210 has limited support of read and write requests when only part of the byte enable bits are set
as described later in this section.
Partial writes to the MSI-X table are supported. All other partial writes are ignored and silently dropped.
Zero-length writes have no internal impact (nothing written, no effect such as clear-by-write). The
transaction is treated as a successful operation (no error event).
Partial reads with at least one byte enabled are answered as a full read. Any side effect of the full read
(such as clear by read) is applicable to partial reads also.
Zero-length reads generate a completion, but the register is not accessed and undefined data is
returned.
Table 3-4. Transaction Types Accepted by the Transaction Layer
Transaction Type FC Type Tx Later
Reaction
Hardware Should Keep Data
From Original Packet
Configuration Read Request NPH CPLH + CPLD Requester ID, TAG, Attribute
Configuration Write Request NPH + NPD CPLH Requester ID, TAG, Attribute
Memory Read Request NPH CPLH + CPLD Requester ID, TAG, Attribute
Memory Write Request PH + PD - -
I/O Read Request NPH CPLH + CPLD Requester ID, TAG, Attribute
I/O Write Request NPH + NPD CPLH Requester ID, TAG, Attribute
Read Completions CPLH + CPLD - -
Message PH+ PD1
1. MCTP messages contains a payload.
- -
Ethernet Controller I210 —Interconnects
40
3.1.4.2 Transaction Types Initiated by the I210
3.1.4.2.1 Data Alignment
Requests must never specify an address/length combination that causes a memory space access to
cross a 4 KB boundary. The I210 breaks requests into 4 KB-aligned requests (if needed). This does not
pose any requirement on software. However, if software allocates a buffer across a 4 KB boundary,
hardware issues multiple requests for the buffer. Software should consider limiting buffer sizes and
base addresses to comply with a 4 KB boundary in cases where it improves performance.
The general rules for packet alignment are as follows:
1. The length of a single request should not exceed the PCIe limit of MAX_PAYLOAD_SIZE for write
and MAX_READ_REQ for read.
2. The length of a single request does not exceed the I210’s internal limitation.
3. A single request should not span across different memory pages as noted by the 4 KB boundary
previously mentioned.
Note: The rules apply to all the I210 requests (read/write, snoop and no snoop).
If a request can be sent as a single PCIe packet and still meet rules 1-3, then it is not broken at a
cache-line boundary (as defined in the PCIe Cache Line Size configuration word), but rather, sent as a
single packet (motivation is that the chipset might break the request along cache-line boundaries, but
the I210 should still benefit from better PCIe use). However, if rules 1-3 require that the request is
broken into two or more packets, then the request is broken at a cache-line boundary.
3.1.4.2.2 Multiple Tx Data Read Requests (MULR)
The I210 supports 6 pipelined requests for transmit data on the port. In general, the 6 requests might
belong to the same packet or to consecutive packets to be transmitted on the LAN port. However, the
following restriction applies: all requests for a packet are issued before a request is issued for a
consecutive packet.
Read requests can be issued from any of the supported queues, as long as the restriction is met.
Pipelined requests might belong to the same queue or to separate queues. However, as previously
noted, all requests for a certain packet are issued (from same queue) before a request is issued for a
different packet (potentially from a different queue).
Table 3-5. Transaction Types Initiated by the Transaction Layer
Transaction type Payload Size FC Type From Client
Configuration Read Request Completion Dword CPLH + CPLD Configuration space
Configuration Write Request Completion - CPLH Configuration space
I/O Read Request Completion Dword CPLH + CPLD CSR
I/O Write Request Completion - CPLH CSR
Read Request Completion Dword/Qword CPLH + CPLD CSR
Memory Read Request - NPH DMA
Memory Write Request <= MAX_PAYLOAD_SIZE1
1. MAX_PAYLOAD_SIZE supported is loaded from Flash (128 bytes, 256 bytes or 512 bytes). Effective MAX_PAYLOAD_SIZE is defined
according to configuration space register.
PH + PD DMA
Message 64 bytes2
2. MCTP messages contains payload.
PH INT / PM / Error Unit / LTR
Interconnects—Ethernet Controller I210
41
The PCIe specification does not ensure that completions for separate requests return in-order. Read
completions for concurrent requests are not required to return in the order issued. The I210 handles
completions that arrive in any order. Once all completions arrive for a given request, the I210 might
issue the next pending read data request.
The I210 incorporates a re-order buffer to support re-ordering of completions for all requests. Each
request/completion can be up to 2 KB long. The maximum size of a read request is defined as the
minimum {2 KB, Max_Read_Request_Size}.
In addition to the 6 pipeline requests for transmit data, the I210 can issue up to one read request to
fetch transmit descriptors and one read requests to fetch receive descriptors. The requests for transmit
data, transmit descriptors, and receive descriptors are independently issued. Each descriptor read
request can fetch up to 16 descriptors for reception and 24 descriptors for transmission.
3.1.4.3 Messages
3.1.4.3.1 Message Handling by the I210 (as a Receiver)
Message packets are special packets that carry a message code.
The upstream device transmits special messages to the I210 by using this mechanism.
The transaction layer decodes the message code and responds to the message accordingly.
Table 3-6. Supported Message in the I210 (as a Receiver)
Message
Code [7:0] Routing r2r1r0 Message I210 Response
0x00 011b Unlock Silently drop
0x14 100b PM_Active_State_NAK Accepted
0x19 011b PME_Turn_Off Accepted
0x40
0x41
0x43
0x44
0x45
0x47
0x48
100b Ignored messages (used to be hot-plug messages) Silently drop
0x50 100b Slot power limit support (has one Dword data) Silently drop
0x7E
000b
010b
011b
100b
Vendor_defined type 0 Drop and handle as an
Unsupported Request
0x7F 100b Vendor_defined type 1 Silently drop
0x7F
000b
010b
011b
Vendor_defined type 1
(see Section 3.1.4.3.3)
Send to MCTP reassembly if
Vendor ID = 0x1AB4 (DMTF) and
VDM code - 0000b (MCTP).
Otherwise, silently drop
Ethernet Controller I210 —Interconnects
42
3.1.4.3.2 Message Handling by I210 (as a Transmitter)
The transaction layer is also responsible for transmitting specific messages to report internal/external
events (such as interrupts and PMEs).
3.1.4.3.3 Vendor Defined Messages (VDM)
The following vendor defined messages are supported:
DMTF MCTP
3.1.4.3.3.1 MCTP VDMs
MCTP VDMs are supported as both master and target. The following header fields are involved (see
Figure 3-2):
Fmt - Set to 11b to indicate a 4 Dword header with data
Type
[4:3] set to 10b to indicate a message
[2:0] routing r2r1r0 = 000b, 010b or 011b
Traffic class - Set to 000b
TLP digest - Set to 0b (no ECRC) unless the ECRC Generation for MCTP in PCIe Control 2 Flash word
is set and ECRC generation is enabled.
Error present - Set to 0b
Attributes[1:0] - Set to 01b (no snoop)
Tag field - Indicates this is an MCTP packet and the size of padding to dword alignment added
Message code = 0x7F (Type 1 VDM)
Destination ID - captures the target B/D/F for route by ID. Otherwise, reserved
Vendor ID = 0x1AB4 (DMTF)
Table 3-7. Supported Message in the I210 (as a Transmitter)
Message code
[7:0] Routing r2r1r0 Message
0x20 100 Assert INT A
0x21 100 Not used
0x22 100 Not used
0x23 100 Not used
0x24 100 Deassert INT A
0x25 100 Not used
0x26 100 Not used
0x27 100 Not used
0x30 000 ERR_COR
0x31 000 ERR_NONFATAL
0x33 000 ERR_FATAL
0x18 000 PM_PME
0x1B 101 PME_TO_ACK
0x10 100 Latency Tolerance Reporting (LTR)
0x7F 000, 010, 011, VDM (see Section 3.1.4.3.3)
Interconnects—Ethernet Controller I210
43
Figure 3-2. MCTP over PCIe VDM Header Format
3.1.4.4 Ordering Rules
The I210 meets the PCIe ordering rules (PCI-X rules) by following the PCI simple device model:
Deadlock avoidance - Master and target accesses are independent. The response to a target access
does not depend on the status of a master request to the bus. If master requests are blocked, such
as due to no credits, target completions might still proceed (if credits are available).
Descriptor/data ordering - The I210 does not proceed with some internal actions until respective
data writes have ended on the PCIe link:
The I210 does not update an internal header pointer until the descriptors that the header
pointer relates to are written to the PCIe link.
The I210 does not issue a descriptor write until the data that the descriptor relates to is written
to the PCIe link.
The I210 might issue the following master read request from each of the following clients:
One Rx Descriptor Read
One Tx Descriptor Read
Tx Data Read (up to 6)
Completing separate read requests are not guaranteed to return in order. Completions for a single read
request are guaranteed to return in address order.
3.1.4.4.1 Out of Order Completion Handling
In a split transaction protocol, when using multiple read requests in a multi processor environment,
there is a risk that completions arrive from the host memory out of order and interleaved. In this case,
the I210 sorts the request completions and transfers them to the Ethernet in the correct order.
+0 +1 +2 +3
76543210765432107654321076543210
FMT
011
Type
10r2r1r0 RTC
000 RA
tt
rRT
HT
DE
P
Attr
[1:0] AT
00
Length
00_000x_xxxx
PCI Requester ID
PCI Tag Field Message Code
Vendor Defined = 0111_1111b
RPad
Len MCTP VDM
code - 0000b
PCI Target ID (For Route by ID messages,
otherwise = Reserved) Vendor ID = 0x1AB4 (DMTF)
Ethernet Controller I210 —Interconnects
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3.1.4.5 Transaction Definition and Attributes
3.1.4.5.1 Max Payload Size
The I210 policy to determine Max Payload Size (MPS) is as follows:
Master requests initiated by the I210 (including completions) limits MPS to the value defined for the
function issuing the request.
Target write accesses to the I210 are accepted only with a size of one Dword or two Dwords. Write
accesses in the range of (three Dwords, MPS, etc.) are flagged as UR. Write accesses above MPS
are flagged as malformed.
3.1.4.5.2 Relaxed Ordering
The I210 takes advantage of the relaxed ordering rules in PCIe. By setting the relaxed ordering bit in
the packet header, the I210 enables the system to optimize performance in the following cases:
Relaxed ordering for descriptor and data reads: When the I210 emits a read transaction, its split
completion has no ordering relationship with the writes from the CPUs (same direction). It should
be allowed to bypass the writes from the CPUs.
Relaxed ordering for receiving data writes: When the I210 issues receive DMA data writes, it also
enables them to bypass each other in the path to system memory because software does not
process this data until their associated descriptor writes complete.
The I210 cannot relax ordering for descriptor writes, MSI/MSI-X writes or PCIe messages.
Relaxed ordering can be used in conjunction with the no-snoop attribute to enable the memory
controller to advance non-snoop writes ahead of earlier snooped writes.
Relaxed ordering is enabled in the I210 by clearing the RO_DIS bit in the CTRL_EXT register. Actual
setting of relaxed ordering is done for LAN traffic by the host through the DCA registers.
3.1.4.5.3 Snoop Not Required
The I210 sets the Snoop Not Required attribute bit for master data writes. System logic might provide
a separate path into system memory for non-coherent traffic. The non-coherent path to system
memory provides higher, more uniform, bandwidth for write requests.
Note: The Snoop Not Required attribute does not alter transaction ordering. Therefore, to achieve
maximum benefit from Snoop Not Required transactions, it is advisable to set the relaxed
ordering attribute as well (assuming that system logic supports both attributes). In fact,
some chipsets require that relaxed ordering is set for no-snoop to take effect.
Global no-snoop support is enabled in the I210 by clearing the NS_DIS bit in the CTRL_EXT register.
Actual setting of no snoop is done for LAN traffic by the host through the DCA registers.
3.1.4.5.4 No Snoop and Relaxed Ordering for LAN Traffic
Software might configure non-snoop and relax order attributes for each queue and each type of
transaction by setting the respective bits in the RXCTRL and TXCTRL registers.
Interconnects—Ethernet Controller I210
45
Table 3-8 lists software configuration for the No-Snoop and Relaxed Ordering bits for LAN traffic when
I/OAT 2 is enabled.
3.1.4.5.4.1 No-Snoop Option for Payload
Under certain conditions, which occur when I/OAT is enabled, software knows that it is safe to transfer
(DMA) a new packet into a certain buffer without snooping on the front-side bus. This scenario typically
occurs when software is posting a receive buffer to hardware that the CPU has not accessed since the
last time it was owned by hardware. This might happen if the data was transferred to an application
buffer by the I/OAT DMA engine.
In this case, software should be able to set a bit in the receive descriptor indicating that the I210
should perform a no-snoop DMA transfer when it eventually writes a packet to this buffer.
When a non-snoop transaction is activated, the TLP header has a non-snoop attribute in the
Transaction Descriptor field.
This is triggered by the NSE bit in the receive descriptor. Refer to Section 7.1.4.2.
3.1.4.5.5 TLP Processing Hint (TPH)
The TPH bit can be set to provide information to the root complex about the cache in which the data
should be stored or from which the data should be read as described in Section 7.7.2.
TPH is enabled via the TPH Requester Enable field in the TPH control register of the configuration space
(refer to Section 9.5.3.3). Setting of the TPH bit for different type of traffic is listed in Table 7-61.
Table 3-8. LAN Traffic Attributes
Transaction No-Snoop Relaxed Ordering Comments
Rx Descriptor Read N Y
Rx Descriptor Write-Back N N Relaxed ordering must never be used
for this traffic.
Rx Data Write Y Y Refer to Note 1 and
Section 3.1.4.5.4.1
Rx Replicated Header N Y
Tx Descriptor Read N Y
Tx Descriptor Write-Back N Y
Tx TSO Header Read N Y
Tx Data Read N Y
Note: 1. Rx payload no-snoop is also conditioned by the NSE bit in the receive descriptor. Refer to Section 3.1.4.5.4.1.
Ethernet Controller I210 —Interconnects
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3.1.4.6 Flow Control
3.1.4.6.1 I210 Flow Control Rules
The I210 implements only the default Virtual Channel (VC0). A single set of credits is maintained for
VC0.
Rules for FC updates:
The I210 maintains four credits for NPD at any given time. It increments the credit by one after the
credit is consumed and sends an UpdateFC packet as soon as possible. UpdateFC packets are
scheduled immediately after a resource is available.
The I210 provides four credits for PH (such as for four concurrent target writes) and four credits for
NPH (such as for four concurrent target reads). UpdateFC packets are scheduled immediately after
a resource becomes available.
The I210 follows the PCIe recommendations for frequency of UpdateFC FCPs.
3.1.4.6.2 Upstream Flow Control Tracking
The I210 issues a master transaction only when the required FC credits are available. Credits are
tracked for posted, non-posted, and completions (the later to operate with a switch).
3.1.4.6.3 Flow Control Update Frequency
In any case, UpdateFC packets are scheduled immediately after a resource becomes available.
When the link is in the L0 or L0s link state, Update FCPs for each enabled type of non-infinite FC credit
must be scheduled for transmission at least once every 30 µs (-0%/+50%), except when the Extended
Sync bit of the Control Link register is set, in which case the limit is 120 µs (-0%/+50%).
3.1.4.6.4 Flow Control Timeout Mechanism
The I210 implements the optional FC update timeout mechanism.
The mechanism is activated when the link is in L0 or L0s Link state. It uses a timer with a limit of
200 µs (-0%/+50%), where the timer is reset by the receipt of any Init or Update FCP. Alternately, the
timer can be reset by the receipt of any DLLP.
Table 3-9. Allocation of FC Credits
Credit Type Operations Number Of Credits
Posted Request Header (PH) Target Write (one unit)
Message (one unit) Four units
Posted Request Data (PD) Target Write (Length/16 bytes=1)
Message (one unit) MAX_PAYLOAD_SIZE/16
Non-Posted Request Header (NPH)
Target Read (one unit)
Configuration Read (one unit)
Configuration Write (one unit)
Four units
Non-Posted Request Data (NPD) Configuration Write (one unit) Four units
Completion Header (CPLH) Read Completion (N/A) Infinite (accepted immediately)
Completion Data (CPLD) Read Completion (N/A) Infinite (accepted immediately)
Interconnects—Ethernet Controller I210
47
After timer expiration, the mechanism instructs the PHY to re-establish the link (via the LTSSM
recovery state).
3.1.4.7 Error Forwarding
If a TLP is received with an error-forwarding trailer (poisoned TLP received), the transaction can either
be resent or dropped and not delivered to its destination, depending on the GCR.Completion Timeout
resend enable bit and the GCR.Number of resends field. If the re-sends were unsuccessful or if re-send
is disabled, the I210 does not initiate any additional master requests for that PCI function until it
detects an internal reset or a software reset for the LAN. Software is able to access device registers
after such a fault.
System logic is expected to trigger a system-level interrupt to inform the operating system of the
problem. The operating system can then stop the process associated with the transaction, re-allocate
memory instead of the faulty area, etc.
3.1.5 Data Link Layer
3.1.5.1 ACK/NAK Scheme
The I210 sends an ACK/NAK immediately in the following cases:
1. NAK needs to be sent
2. ACK for duplicate packet
3. ACK/NAK before low power state entry
In all other cases, the I210 schedules an ACK transmission according to time-outs specified in the PCIe
specification (depends on link speed, link width, and max_payload_size).
3.1.5.2 Supported DLLPs
The following DLLPs are supported by the I210 as a receiver:
Table 3-10. DLLPs Received by the I210
DLLP type Remarks
ACK
NAK
PM_Request_ACK
InitFC1-P Virtual Channel 0 only
InitFC1-NP Virtual Channel 0 only
InitFC1-Cpl Virtual Channel 0 only
InitFC2-P Virtual Channel 0 only
InitFC2-NP Virtual Channel 0 only
InitFC2-Cpl Virtual Channel 0 only
UpdateFC-P Virtual Channel 0 only
UpdateFC-NP Virtual Channel 0 only
UpdateFC-Cpl Virtual Channel 0 only
Ethernet Controller I210 —Interconnects
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The following DLLPs are supported by the I210 as a transmitter:
Note: UpdateFC-Cpl is not sent because of the infinite FC-Cpl allocation.
3.1.5.3 Transmit EDB Nullifying
If re-train is necessary, there is a need to guarantee that no abrupt termination of the Tx packet
happens. For this reason, early termination of the transmitted packet is possible. This is done by
appending an End Bad Symbol (EDB) to the packet.
3.1.6 Physical Layer
3.1.6.1 Link Speed
The I210 supports only 2.5GT/s link speeds.
The I210 does not initiate a hardware autonomous speed change and as a result the Hardware
Autonomous Speed Disable bit in the PCIe Link Control 2 register is hardwired to 0b.
The I210 supports entering compliance mode at the speed indicated in the Target Link Speed field in
the PCIe Link Control 2 register. Compliance mode functionality is controlled via the Enter Compliance
bit in the PCIe Link Control 2 register.
3.1.6.2 Link Width
The I210 supports a maximum link width of x1.
During link configuration, the platform and the I210 negotiate on a common link width. The link width
must be x1.
Table 3-11. DLLPs Initiated by the I210
DLLP type Remarks
ACK
NAK
PM_Enter_L1
PM_Enter_L23
PM_Active_State_Request_L1
InitFC1-P Virtual Channel 0 only
InitFC1-NP Virtual Channel 0 only
InitFC1-Cpl Virtual Channel 0 only
InitFC2-P Virtual Channel 0 only
InitFC2-NP Virtual Channel 0 only
InitFC2-Cpl Virtual Channel 0 only
UpdateFC-P Virtual Channel 0 only
UpdateFC-NP Virtual Channel 0 only
Interconnects—Ethernet Controller I210
49
3.1.6.3 Polarity Inversion
If polarity inversion is detected, the receiver must invert the received data.
During the training sequence, the receiver looks at Symbols 6-15 of TS1 and TS2 as the indicator of
lane polarity inversion (D+ and D- are swapped). If lane polarity inversion occurs, the TS1 Symbols 6-
15 received are D21.5 as opposed to the expected D10.2. Similarly, if lane polarity inversion occurs,
Symbols 6-15 of the TS2 ordered set are D26.5 as opposed to the expected D5.2. This provides clear
indication of lane polarity inversion.
3.1.6.4 L0s Exit latency
The number of FTS sequences (N_FTS) sent during L1 exit, can be loaded from the Flash.
3.1.6.5 Reset
The PCIe PHY can supply a core reset to the I210. The reset can be caused by three sources:
1. Upstream move to hot reset - Inband Mechanism (LTSSM).
2. Recovery failure (LTSSM returns to detect).
3. Upstream component moves to disable.
3.1.6.6 Scrambler Disable
The scrambler/de-scrambler functionality in the I210 can be disabled by either one of the two
connected devices according to the PCIe specification.
3.1.7 Error Events and Error Reporting
3.1.7.1 Mechanism in General
PCIe defines two error reporting paradigms: the baseline capability and the Advanced Error Reporting
(AER) capability. The baseline error reporting capabilities are required of all PCIe devices and define the
minimum error reporting requirements. The AER capability is defined for more robust error reporting
and is implemented with a specific PCIe capability structure.
Both mechanisms are supported by the I210.
Also, the SERR# Enable and the Parity Error bits from the Legacy Command register take part in the
error reporting and logging mechanism.
3.1.7.2 Error Events
Table 3-12 lists the error events identified by the I210 and the response in terms of logging, reporting,
and actions taken. Consult the PCIe specification for the effect on the PCI Status register.
Ethernet Controller I210 —Interconnects
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Table 3-12. Response and Reporting of PCIe Error Events
Error Name Error Events Default Severity Action
PHY errors
Receiver error 8b/10b decode errors
Packet framing error
Correctable.
Send ERR_CORR
TLP to initiate NAK and drop data.
DLLP to drop.
Data link errors
Bad TLP
Bad CRC
Not legal EDB
Wrong sequence number
Correctable.
Send ERR_CORR TLP to initiate NAK and drop data.
Bad DLLP Bad CRC Correctable.
Send ERR_CORR DLLP to drop.
Replay timer timeout REPLAY_TIMER expiration Correctable.
Send ERR_CORR Follow LL rules.
REPLAY NUM rollover REPLAY NUM rollover Correctable.
Send ERR_CORR Follow LL rules.
Data link layer
protocol error
Violations of Flow Control
Initialization Protocol
Reception of NACK/ACK with no
corresponding TLP
Uncorrectable.
Send ERR_FATAL Follow LL rules.
TLP errors
Poisoned TLP
received TLP with error forwarding
Uncorrectable.
ERR_NONFATAL
Log header
A poisoned completion is ignored and the
request can be retried after timeout. If
enabled, the error is reported.
Unsupported
Request (UR)
Wrong config access
MRdLk
Configuration request type 1
Unsupported vendor Defined
type 0 message
Not valid MSG code
Not supported TLP type
Wrong function number
Received TLP outside address
range
Uncorrectable.
ERR_NONFATAL
Log header
Send completion with UR.
Completion timeout Completion timeout timer
expired
Uncorrectable.
ERR_NONFATAL
Error is non-fatal (default case):
Send error message if advisory
Retry the request once and send
advisory error message on each
failure
If fails, send uncorrectable error
message
Error is defined as fatal:
Send uncorrectable error message
Completer abort Received target access with
data size > 64-bit
Uncorrectable.
ERR_NONFATAL
Log header
Send completion with CA.
Unexpected
completion Received completion without a
request for it (tag, ID, etc.)
Uncorrectable.
ERR_NONFATAL
Log header
Discard TLP.
Receiver overflow Received TLP beyond allocated
credits
Uncorrectable.
ERR_FATAL Receiver behavior is undefined.
Flow control protocol
error
Minimum initial flow control
advertisements
Flow control update for infinite
credit advertisement
Uncorrectable.
ERR_FATAL
Receiver behavior is undefined. The I210
doesn’t report violations of flow control
initialization protocol
Interconnects—Ethernet Controller I210
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3.1.7.3 Error Forwarding (TLP Poisoning)
If a TLP is received with an error-forwarding trailer, the transaction can be re-sent a number of times as
programmed in the GCR register. If transaction still fails the packet is dropped and is not delivered to
its destination. The I210 then reacts as listed in Table 3-12.
The I210 does not initiate any additional master requests for that PCI function until it detects an
internal software reset for the LAN port. Software is able to access device registers after such a fault.
System logic is expected to trigger a system-level interrupt to inform the operating system of the
problem. Operating systems can then stop the process associated with the transaction, re-allocate
memory instead of the faulty area, etc.
3.1.7.4 ECRC
The I210 supports End to End CRC (ECRC) as defined in the PCIe specification. The following
functionality is provided:
Inserting an ECRC in all transmitted TLPs:
The I210 indicates support for inserting ECRC in the ECRC Generation Capable bit of the PCIe
configuration registers. This bit is loaded from the ECRC Generation Flash bit.
Inserting an ECRC is enabled by the ECRC Generation Enable bit of the PCIe configuration
registers. For MCTP packets, it is also controlled by the ECRC Generation for MCTP in PCIe
Control 2 Flash word.
ECRC is checked on all incoming TLPs. A packet received with an ECRC error is dropped. Note that
for completions, a completion timeout occurs later (if enabled), which would result in re-issuing the
request.
The I210 indicates support for ECRC checking in the ECRC Check Capable bit of the PCIe
configuration registers. This bit is loaded from the ECRC Check Flash bit.
ECRC checking is enabled by the ECRC Check Enable bit of the PCIe configuration registers.
ECRC errors are reported.
Malformed TLP (MP)
Data payload exceed
Max_Payload_Size
Received TLP data size does not
match length field
TD field value does not
correspond with the observed
size
Power management messages
that doesn’t use TC0.
Usage of unsupported VC.
Uncorrectable.
ERR_FATAL
Log header
Drop the packet and free FC credits.
Completion with
unsuccessful
completion status
No action (already done
by originator of
completion). Free FC credits.
Byte count integrity in
completion process.
When byte count isn’t compatible
with the length field and the actual
expected completion length. For
example, length field is 10 (in
Dword), actual length is 40, but the
byte count field that indicates how
many bytes are still expected is
smaller than 40, which is not
reasonable.
No action
The I210 doesn't check for this error and
accepts these packets.
This might cause a completion timeout
condition.
Table 3-12. Response and Reporting of PCIe Error Events (Continued)
Error Name Error Events Default Severity Action
Ethernet Controller I210 —Interconnects
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3.1.7.5 Partial Read and Write Requests
3.1.7.5.1 Partial Memory Accesses
The I210 has limited support of read/write requests with only part of the byte enable bits set:
Partial writes with at least one byte enabled should not be used. If used, the results are
unexpected, either the byte enable request is honored or the entire Dword is written.
Zero-length writes has no internal impact (nothing written, no effect such as clear-by-write). The
transaction is treated as a successful operation (no error event).
Partial reads with at least one byte enabled are handled as a full read. Any side effect of the full
read (such as clear by read) is also applicable to partial reads.
Zero-length reads generate a completion, but the register is not accessed and undefined data is
returned.
The I210 does not generate an error indication in response to any of the above events.
3.1.7.5.2 Partial I/O Accesses
Partial access on address
A write access is discarded
A read access returns 0xFFFF
Partial access on data, where the address access was correct
A write access is discarded
A read access performs the read
3.1.7.6 Error Pollution
Error pollution can occur if error conditions for a given transaction are not isolated on the error's first
occurrence. If the physical layer detects and reports a receiver error, to avoid having this error
propagate and cause subsequent errors at upper layers, the same packet is not signaled at the data
link or transaction layers.
Similarly, when the data link layer detects an error, subsequent errors that occur for the same packet
are not signaled at the transaction layer.
3.1.7.7 Completion with Unsuccessful Completion Status
A completion with unsuccessful completion status is dropped and not delivered to its destination. An
interrupt is generated to indicate unsuccessful completion.
3.1.7.8 Error Reporting Changes
The Rev. 1.1 specification defines two changes to advanced error reporting. A new Role-Based Error
Reporting bit in the Device Capabilities register is set to 1b to indicate that these changes are
supported by the I210. These changes are:
1. Setting the SERR# Enable bit in the PCI Command register also enables UR reporting (in the same
manner that the SERR# Enable bit enables reporting of correctable and uncorrectable errors). In
other words, the SERR# Enable bit overrides the UR Error Reporting Enable bit in the PCIe Device
Control register.
Interconnects—Ethernet Controller I210
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2. Changes in the response to some uncorrectable non-fatal errors, detected in non-posted requests
to the I210. These are called advisory non-fatal error cases. For each of the errors that follow, the
following behavior is defined:
a. The Advisory Non-Fatal Error Status bit is set in the Correctable Error Status register to indicate
the occurrence of the advisory error and the Advisory Non-Fatal Error Mask corresponding bit in
the Correctable Error Mask register is checked to determine whether to proceed further with
logging and signaling.
b. If the Advisory Non-Fatal Error Mask bit is clear, logging proceeds by setting the corresponding
bit in the Uncorrectable Error Status register, based upon the specific uncorrectable error that's
being reported as an advisory error. If the corresponding uncorrectable error bit in the
Uncorrectable Error Mask register is clear, the First Error Pointer and Header Log registers are
updated to log the error, assuming they are not still occupied by a previously unserviced error.
c. An ERR_COR message is sent if the Correctable Error Reporting Enable bit is set in the Device
Control register. An ERROR_NONFATAL message is not sent for this error.
The following uncorrectable non-fatal errors are considered as advisory non-fatal Errors:
A completion with an Unsupported Request or Completer Abort (UR/CA) status that signals an
uncorrectable error for a non-posted request. If the severity of the UR/CA error is non-fatal, the
completer must handle this case as an advisory non-fatal error.
When the requester of a non-posted request times out while waiting for the associated completion,
the requester is permitted to attempt to recover from the error by issuing a separate subsequent
request, or to signal the error without attempting recovery. The requester is permitted to attempt
recovery zero, one, or multiple (finite) times, but must signal the error (if enabled) with an
uncorrectable error message if no further recovery attempts are made. If the severity of the
completion timeout is non-fatal and the requester elects to attempt recovery by issuing a new
request, the requester must first handle the current error case as an advisory non-fatal error.
Reception of a poisoned TLP. Refer to Section 3.1.7.3.
When a receiver receives an unexpected completion and the severity of the unexpected completion
error is non-fatal, the receiver must handle this case as an advisory non-fatal error.
3.1.7.9 Completion with Unsupported Request (UR) or Completer Abort (CA)
A DMA master transaction ending with an Unsupported Request (UR) completion or a Completer Abort
(CA) completion causes all PCIe master transactions to stop, PICAUSE.ABR bit is set and an interrupt is
generated if the appropriate Mask bits are set. To enable PCIe master transactions after receiving an
UR or CA completion, software should issue a Device Reset (CTRL.DEV_RST) and re-initialize the
function.
Note: Asserting CTRL.DEV_RST flushes any pending transactions on the PCIe and reset’s the port.
3.1.8 PCIe Power Management
Described in Section 5.4.1 - Power Management.
3.1.9 PCIe Programming Interface
Described in Chapter 9.0 - PCIe Programming Interface
Ethernet Controller I210 —Interconnects
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3.2 Management Interfaces
The I210 contains three possible interfaces to an external MC.
SMBus
NC-SI
MCTP (over PCIe or SMBus)
3.2.1 SMBus
SMBus is an optional interface for pass-through and/or configuration traffic between an external MC
and the I210. The SMBus channel behavior and the commands used to configure or read status from
the I210 are described in Section 10.5.
The I210 also enables reporting and controlling the device using the MCTP protocol over SMBus. The
MCTP interface is used by the MC to control the NIC and for pass through traffic. For additional
information, refer to Section 10.7.
3.2.1.1 Channel Behavior
The SMBus specification defines a maximum frequency of 100 KHz. However, when acting as a slave,
the I210 can receive transaction with a clock running at up to 1 MHz. When acting as a master, it can
toggle the clock at 100 Khz, 400 Khz or 1 MHz. The speed used is set by the SMBus Connection Speed
field in the SMBus Notification Timeout and Flags Flash word (Section 6.7.3.3).
3.2.2 NC-SI
The NC-SI interface in the I210 is a connection to an external MC defined by the DMTF NC-SI protocol.
It operates as a single interface with an external MC, where all traffic between the I210 and the MC
flows through the interface.
The I210 supports the standard DMTF NC-SI protocol for both pass-through and control traffic as
defined in Section 10.6.
3.2.2.1 Electrical Characteristics
The I210 complies with the electrical characteristics defined in the NC-SI specification.
The I210 NC-SI behavior is configured on power-up in the following manner:
The Multi-Drop NC-SI Flash bit (refer to Section 6.7.1.3) defines the NC-SI topology (point-to-point
or multi-drop; the default is multi-drop).
The I210 dynamically drives its NC-SI output signals (NC-SI_DV and NC-SI_RX) as required by the
sideband protocol:
On power-up, the I210 floats the NC-SI outputs.
If the I210 operates in point-to-point mode, then the I210 starts driving the NC-SI outputs some
time following power-up.
If the I210 operates in a multi-drop mode, the I210 drives the NC-SI outputs as configured by the
MC.
Interconnects—Ethernet Controller I210
55
3.2.2.2 NC-SI Transactions
The NC-SI link supports both pass-through traffic between the MC and the I210 LAN functions, as well
as configuration traffic between the MC and the I210 internal units as defined in the NC-SI protocol.
Refer to Section 10.6.2 for information.
3.2.3 MCTP (over PCIe or SMBus)
The I210 supports MCTP protocol for management. MCTP runs over PCIe or SMBus. The I210
implements NC-SI over MCTP protocol for command and pass through traffic.
3.3 Flash
3.3.1 General Overview
The I210 uses a Flash device for storing product configuration information. The Flash is divided into
four general regions:
Hardware Accessed Loaded by the the I210 hardware after power-up, PCI reset de-assertion, D3
to D0 transition, or software reset. Different hardware sections in the Flash are loaded at different
events. For more details on power-up and reset sequences, see Section 4.0.
Secure Firmware Area — Firmware code and structures used by the firmware for management
configuration in its different modes.
Unsecure Firmware Area Same as above -Firmware code and structures used by the firmware for
management configuration in its different modes. This area is used by the software for updating the
new firmware code and structures.
Software Accessed — used by software only. The meaning of these words as listed here is a
convention for the software only and is ignored by the I210. This region is used by software entities
such as LAN drivers, option ROM software and tools, PCIe bus drivers etc. The content of this area
is listed here as a convenience for software developers only and is ignored by the I210 hardware.
Note: The role played by the secured area and the unsecured area is toggled on every Firmware
update. This is referred as the double bank update policy.
The I210 merges the legacy EEPROM and Flash content in a single Flash device. Flash devices require a
sector erase instruction in case a cell is modified from 0b to 1b. As a result, in order to update a single
byte (or block of data) it is required to erase it first. The I210 supports Flash devices with a sector erase
size of 4 KB. Note that many Flash vendors are using the term sector differently. The I210 EAS uses the
term Flash sector for a logic section of 4 KB.
The I210 supports Flash devices that are either write-protected by default after power-up or not. The
I210 removes the protection by sending the write-protection removal OpCode to the Flash after power
up. For the first programming of a blank Flash, it is the host’s responsibility to remove the write-
protection from the Flash part via bit-banging access. Refer to Section 11.8 for the list of the Flash
devices supported by the I210.
Ethernet Controller I210 —Interconnects
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The following OpCodes must be supported by the I210 as they are common to all the supported Flash
devices:
Name Opcode Description
WREN 0x6 Write Enable
RDID 0x9f Read JEDEC Manufacture ID
WRSR 0x1 Write Status
READ 0x3 Flash Read
RDSR 0x5 Read Flash Status
Sector Erase 0x20 4 KB Sector Erase
Flash Erase 0xc7 Flash Erase
Page Program 0x2 Write to the Flash
Fast Read 0x0b Read data bytes at higher speed
The other OpCodes to be supported are loaded from the firmware secured area into a set of Flash
Opcode registers.
3.3.1.1 EEPROM Image Structures
The first valid 4 KB of the Flash is referred herein as the EEPROM Image or as the shadow RAM.
It contains the pointers to all Flash modules, which can be mapped either inside or outside the EEPROM
image. Flash words in the EEPROM image that do not belong to any pointed module are referred to as
the Flash header.
The Flash mapping is described in Chapter 6.0.
3.3.1.2 Flash Detection, NVM Validity Field, and Non-Secure Mode
The I210 supports detection of Flash existence following power-up and detection of a valid Flash image
via the NVM Validity field in the NVM Validity and Protected Fields Flash word 0x12 (refer to
Section 6.2.8).
The I210 enters non-secure mode (blank Flash programming mode) in the following scenarios:
No Flash device is detected
Invalid NVM Validity field read from Flash word 0x12
The NVM_SEC_EN bit is read as 0b from Flash word 0x12
Device ID field read from firmware image is not the I210's 0x1531 Device ID
The SECURITY_ENABLE strap is off
In non-secure mode, all Flash access interfaces from the host to any Flash area or word are enabled in
full.
In cases of an invalid NVM Validity field contents, or no Flash detection, auto-load from Flash by
hardware or firmware after power-up or reset is not performed.
Interconnects—Ethernet Controller I210
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As a physical recovery method required for manufacturing, the non-secure mode can also be entered
by setting a strapping option. Only host access to Flash and shadow RAM is guaranteed when in this
mode.
Similarly, as a means to recover from an operational error that might occur during Flash programming,
the ROM-based firmware enters the device into non-secure mode if the I210 Blank Flash Device ID field
content read from the firmware image is not 0x1531, which is used by the tools for specific the I210
SKUs.
Unless specified otherwise, secure mode is assumed throughout this document.
3.3.2 Shadow RAM
The I210 maintains the first two 4 KB sectors, Sector 0 and Sector 1, for the hardware configuration
content. At least one of these two sectors must be valid at any given time or else the I210 is set by
hardware default (iNVM). Following a Power On Reset (POR), the I210 copies the valid lower 4 KB
sector of the Flash device into an internal shadow RAM. Any further accesses of the software or
firmware to this section of the Flash are directed to the internal shadow RAM. After a software
command, modifications made to the shadow RAM content are then copied by the I210 manageability
into the other 4 KB sector of the Flash, flipping circularly the valid sector between sector 0 and 1 of
Flash.
Due to Flash security reasons, hardware does not allow any Flash accesses until the Flash is
authenticated and the blocked (protected) sections of the Flash are identified. See more on Flash
security in Section 3.3.10.
This mechanism provides the following advantages:
1. A seamless backward compatible read/write interface for software to the first 4 KB of the Flash as if
an external EEPROM device was connected. This interface is referred as EEPROM-mode access to
the Flash.
2. A way for software to protect image-update procedure from power down events by establishing a
double-image policy. It relies on having pointers to all the other Flash modules mapped in the Flash
sector which is mirrored in the internal shadow RAM.
Figure 3.3 shows the shadow RAM mapping and interface.
Ethernet Controller I210 —Interconnects
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Figure 3.3. Flash Shadow RAM
Following a write access by software or firmware to the shadow RAM, the data should finally be updated
in the Flash as well. The I210 manageability updates the Flash from the shadow RAM when software
requests explicitly to update the Flash by setting the FLUPD bit in the EEC register. For saving Flash
updates, it is expected that software set the FLUPD bit only once it has completed the last write access
to the Flash. The I210 manageability then copies the content of the shadow RAM to the non-valid
configuration sector and makes it the valid one.
Notes: Software should be aware that programming the Flash might require a long latency due to the
Flash update sequence handled by manageability. The sector erase command by itself can
last hundreds of milliseconds. Software must poll the FLUDONE bit in the EEC register to
check whether or not the Flash programming completed.
Each time the Flash content is not valid (blank configuration sectors or wrong NVM Validity
field contents in both sector 0 and 1) EEPROM access mode is turned off. Software should
rather use one of the three flash access means described in Section 3.3.3.
3.3.2.1 Protected Areas and Words
The I210 provides a mechanism to define selected areas (two areas) in the shadow RAM that cannot be
written by the host; however, the protected areas can be read by the host. They can be write accessed
only by the manageability subsystem. The two protected areas are defined via the following registers:
1. The first protected area is a segment defined by words 0x2D and 0x2C that define the start and the
end of this read-only area. They are used to load the 1st Start Address and the 1st End Address
fields in EEBLKBASE and EEBLKEND registers, respectively.
2. The second protected area is located at the end of the 4 KB shadow RAM. Its size from the shadow
RAM’s end is defined in Flash word 0x12. It is used to load the 2nd Start Address field is
EEBLKBASE register.
For security reasons, the following Flash modules must be mapped into one of the protected areas:
SW Reset CSR Auto Configuration Pointer (LAN Base Address + Offset 0x17) - Section 6.3
PCIe Reset CSR Auto Configuration Pointer (LAN Base Address + Offset 0x23) - Section 6.4
CSR Auto Configuration Power-Up Pointer (Offset 0x27) - Section 6.5
Sector 0
Sector 1
Shadow RAM
I210
Flash
EEPROM-
Mode Access
0x000FFF -
0x000000
0x000000
0x000FFF
0x001000
0x001FFF
0x002000
0xFFFFFF
0x000000
0x000FFF
1:1
Physical Byte
address
Flash-Mode
Access
0xFFFFFF -
0x000000
Logical
address
Internal RAM
address
4KB
4KB
Interconnects—Ethernet Controller I210
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Besides these configurable protected areas, some fixed Flash words in the Flash header are also write-
protected from host (RO for host, RW for manageability). It concerns mainly pointers to Flash modules
and other Flash words that are critical for the host to device connectivity over PCIe.
Refer to the right-most column in Table 6-1 for the list of protected words.
Any host attempt to write a protected area or word is silently discarded.
Besides protected areas and words mapped in the shadow RAM, the Secure Firmware Area (pointed by
Flash word 0x10) is always write protected from host. The size of this area is defined in the size field in
the module itself.
3.3.3 Flash Clients and Interfaces
There are several clients that can access the Flash to different address ranges via different access
modes, methods, and interfaces. The various clients to the Flash are software tools (BIOS, etc.),
drivers, MC (via firmware), and VPD software.
Table 3-13 lists the different accesses to the Flash.
Table 3-13. Clients and Access Types to the Flash
Note: Firmware saves words like SMBus Slave Addresses or Signature, which are saved into the Flash at the firmware’s initiative.
Software attempts to write access protected areas or words are silently discarded (access completed but not executed).
Client
Flash
Access
Method
Flash
Access
Mode
Logical Byte
Address
Range
Flash Access Interface (CSRs or Other)
VPD Software Parallel (32-bits) EEPROM 0x000000 -
0x0003FF
VPD Address and Data registers (PCI_E config
space), via shadow RAM logic. Any write access
is pushed by the I210 into the Flash as soon as
possible. VPD module must be located in the first
valid Flash sector.
Software
Parallel (16-bits) EEPROM 0x000000 -
0x000FFF EERD, EEWR, via shadow RAM logic.
Parallel (32-bits)
Flash 0x000000 -
0x001FFF
Memory mapped via BARs.
Write access to this range is not allowed when in
Secure mode. The transaction is completed but
not executed.
Flash 0x002000 -
0xFFFFFF Memory mapped via BARs.
Parallel (32-bits)
Flash 0x000000 -
0x001FFF
FLSW* register set - Software/Flash burst
control.
Write access to this range is not allowed when in
Secure mode. The transaction is completed with
FLSWCTL.CMDV bit cleared and not executed.
Flash 0x002000 -
0xFFFFFF FLSW* register set - Software/Flash burst
control
Software Bit-banging (1-bit) Flash 0x000000 -
0xFFFFFFF
FLA.
Access allowed to Software only when in the
non-secure mode.
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3.3.3.1 Memory Mapped Host Interface
The Flash device can be mapped into memory and/or I/O address space of the PF through the use of
Base Address Registers (BARs).
Clearing the FLBAR_Size and CSR_Size fields in PCIe Control 2 Flash word (Word 0x28) to 0b, disables
Flash mapping to PCI space via the Flash Base Address register.
Setting the LAN Boot Disable bit in the Initialization Control 3 Flash word, disables Flash mapping to the
PCI space via the Expansion ROM Base Address register
Using the legacy Flash transactions, the Flash is read from, or written to (under Flash security rules), by
The I210 each time the host CPU performs a read or a write operation to a memory location that is
within the Flash address mapping or upon boot via accesses in the space indicated by the Expansion
ROM Base Address register. Accesses to the Flash are based on a direct decode of CPU accesses to a
memory window defined in either:
Memory CSR + Flash Base Address Register (PCIe Control Register at offset 0x10). Refer to
Section 9.3.11. Memory BAR accesses are mapped to the Flash, starting from word address 0x0,
and up to the exposed BAR size - never beyond it.
The Expansion ROM Base Address Register (PCIe Control Register at offset 0x30). Refer to
Section 9.3.15. Expansion-ROM BAR accesses are mapped to the Flash, starting from the fixed
word address 0x1000. For example, just after the first 8 KB used for the shadow RAM banks.
a. For BAR_SIZE = 0.5 MB, read accesses to the last 8 KB of the Expansion-ROM BAR returns
unpredictable data. Refer to Figure 3-4.
b. For BAR_SIZE >= 1 MB, read accesses beyond (1 MB - 8 KB) of the Expansion-ROM BAR returns
unpredictable data. Refer to Figure 3-5.
For accesses through any of the two BARs, the following occurs:
If the Flash part is larger than the exposed BAR size (for saving operating system address space),
accesses to the upper Flash addresses are not possible through the BAR.
If the Flash part is smaller than the exposed BAR size (further to a wrong Flash setting or because
of the 128 KB added for CSRs), accesses are (naturally) wrapped around when attempting to
access upper addresses.
The I210 is responsible to map accesses via the Expansion ROM BAR to the physical Flash. The offset in
the Flash of the Expansion ROM module is fixed and starts at word address 0x001000.
If there is no valid Flash Validity field in the two first 4 KB sectors, then Expansion ROM BAR is
disabled.
When present, the Expansion-ROM module must be mapped starting from word address
0x1000. For example, just after the first 8 KB of the Flash.
When no Expansion-ROM module is present, the Flash area starting from word address 0x1000
can be used for other modules mapped outside of the shadow RAM (such as the firmware
image).
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The I210 controls accesses to the Flash when it decodes a valid access. Attempts to out-of-range write
access the PCIe Expansion/Option ROM module (beyond the provisioned 512 KB) is silently ignored,
while read access might return any value. The same is done for out-of-range accesses to the host
memory BAR.
Notes: The I210 supports four byte writes to the Flash. Byte Enable (BE) pins can be set in a
consecutive way (starting from 0) for writing less than four bytes.
Flash read accesses are assembled by the I210 each time the access is greater than a byte-
wide access.
Flash read access times is in the order of 2 s (depending on Flash specification). The device
continues to issue retry accesses during this time.
Flash write access times can be in the order of 2 s to 200 s (depending on Flash
specification). Following a write access to the Flash, software should avoid initiating any read
or write access to the device until the Flash write access completes.
While in the non-secure mode, Flash BAR access while FLA.FL_REQ is asserted (and granted) is
forbidden. It can lead to a PCIe hang as a bit-banging access requires several PCIe accesses.Figure 3-4
and Figure 3-5 show the BARs mapping schemes according to the size of the BAR vs. the Flash memory
sizes supported.
Ethernet Controller I210 —Interconnects
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Figure 3-4. Flash Part Size is Larger Than BAR Size
0x000000
0x00 07 FF
0x00 0FFF
0x00 08 00
Physical Flash
Word Address
FLASH
1
Free Pro visioning
Area Segment
ShadowRAM
Banks
Secu red Area
for FW image
Expan sio n/Option
ROM Mo dule
Expansion -ROM
BAR
0x001000
Memory
BAR
4 KB
4 KB
BAR Ad dress 0x0
128KB
If CSR_SIZE = 0b
BAR Address 0x20000
BAR Address 0x0
BAR_SIZE 1
IF BAR_SIZ E = 0. 5MB: 0.5MB – 8KB 1
IF BAR_SIZ E =1MB: 1MB 8KB 1
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Figure 3-5. Flash Part Size is Smaller Than BAR Size
3.3.3.2 Management Controller (MC) Interface
The MC can issue NC-SI commands that require read/write access to some Flash and/or shadow RAM
words.
3.3.4 Flash Access Contention
The I210 firmware is constantly running from the Flash. Any read or write access to the Flash made by
software must be preceded by acquiring ownership over the Flash semaphore (refer to Section 4.6.1).
This is also useful to avoid the timeout of the PCIe transaction made to a memory mapped Flash
address while the Flash is currently busy with a long sector erase operation.
0x000000
0x00 07 FF
0x00 0FFF
0x00 08 00
Physical Flash
Word Address
FLASH
1
Free Pro vision ing
Area Seg ment
Shadow RAM
Banks
Secu red Area
for FW image
Expan sion/Option
ROM Mo d ule
Expansion-ROM
BAR
0x001000
Memory
BAR
4 KB
4 KB
BAR Add ress 0x0
128KB
If CSR_SIZE = 0b
BAR Address 0x20000
BAR Address 0x0
FLASH_SI ZE – 1
FLASH_SIZE
FLASH_SIZE 1
FL ASH_SIZ
BAR_SIZE
1MB 8KB 1
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Two software entities cannot use the semaphore mechanism: BIOS and VPD software.
Since VPD software accesses only the VPD module, which is located in the first valid sector of the
Flash, VPD accesses are always performed against the shadow RAM first. In this case, firmware
must take/release ownership over the Flash before dumping the VPD changes into the Flash, as if it
was the originator of the Flash access. Shadow RAM dump sequence is described in Section 3.3.2.
No contention can occur between BIOS and any other software entity (VPD included) as it accesses
the Flash while the operating system is down.
Contention between BIOS and firmware can however happen if a system reboot occurs while the
MC is accessing the Flash.
If a system reboot is caused by a user pressing the Standby button, it is required to route the
wake-up signal from the Standby button to the MC and not to the chipset. The MC issues a
system reboot signal to the chipset only after the Flash write access completes. Firmware is
responsible to poll whether the Flash write has completed before sending the response to the
MC NC-SI command.
If a system reboot is issued by a local user on the host, there is no technical way to avoid Flash
access contention between BIOS and the MC.
Caution: It is the user’s responsibility when accessing the Flash remotely via the MC to make sure
another user is not currently initiating a local host reboot there.
Notes:
The MAC auto-load from the Flash device itself occurs only after power-up and before host or
firmware can attempt to access the Flash. The host must wait until PCIe reset is de-asserted
(after ~1 sec, which is enough time for the MAC auto-load to complete).
Software and firmware should avoid holding Flash ownership (via the dedicated semaphore
bit) for more than 2 seconds.
Software erase command can be suspended by firmware until it handles its current tasks and/
or it loads its cache.
3.3.4.1 Arbitration Between Flash Clients
The following lists the relative priority by which the hardware must serve the different Flash clients,
whether the access is performed against the internal shadow RAM or into the Flash device:
1. Hardware auto-load - no semaphore taking.
Pointer to an hardware module must first be invalidated (set to 0xFFFF) by the host/MC before
modifying the module by a sequence of related changes. A sequence of related changes is a
sequence of Flash writes that if interrupted in the middle would leave the hardware module with
non-consistent contents. There is still a risk of inconsistent Flash header words being loaded by
hardware if the auto-load process occurs in the middle of a write sequence performed over the
Flash header. This risk exists in all previous 1 GbE controllers.
2. Hardware cache read for the firmware - no semaphore taking.
This access is served by hardware with a 10:1 ratio relatively to the accesses that follow.
The tens of cache read accesses (8-byte Flash read each) that might be performed before a
memory mapped Flash access is served (see Steps 4 and 6) should not cause a timeout of the PCIe
transaction.
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Cache reads can be delayed by the maximum time duration (300 ms) of a previous erase
command, which was issued by firmware to hardware. Before issuing any sector erase command to
hardware, firmware must complete all its pending tasks and must load from Flash the code pieces
required to manage while the Flash is busy for erasing:
a. For instance, NC-SI commands received are completed with the Package Not Ready status. The
MC must retry after 500 ms the commands that were completed with a Package Not Ready
status. SMBus transactions are handled in a similar way. Refer to Section 3.3.4.2 for the
complete list.
b. Offloads performed by firmware waits until the cache read resumes before being handled by
firmware. Alternatively, before issuing an Erase command to hardware, firmware initiates some
offload tasks that would timeout otherwise.
c. Host interface commands can wait for 500 ms before being completed by firmware.
3. Software or firmware read is performed by hardware in a round robin manner between:
a. Software reads via BAR or CSRs - Software other than BIOS must take a semaphore (even for
reads).
b. Firmware reads via CSRs - no semaphore taking. Firmware is also performing the shadow RAM
reads required for a VPD read.
4. Firmware erase/write for VPD and the MC, before performing a shadow RAM dump into the Flash, or
for its own needs (such as for replacing factory defaults), firmware must take the semaphore here.
5. Software erase/write via BAR or CSRs - Software must take a semaphore.
a. If the access is performed against the Flash, software must release the semaphore after it has
checked the Flash is not busy by the last erase operation performed.
b. If the access is performed against the shadow RAM, software must release the semaphore once
it has asked firmware to dump the shadow RAM in the Flash by setting the FLUPD bit.
6. Bit-banging access - no semaphore taking.
This access is provided to software only when in non-secure mode.Firmware access via the bit-
banging interface might lead to a dead lock if the firmware code required to complete the bit-
banging is not entirely in the firmware cache before starting the access.
3.3.4.2 Firmware Responses When Flash Unavailable
Table 3-14 is organized according to the different events that might occur while the Flash is temporarily
not available (like busy with a pervious Flash erase operation). It defines the expected responses for
each case, assuming the firmware code, which is responsible to properly handle the event cannot be
read from the Flash.
Table 3-14. Events/Responses When Flash is Unavailable
Event Response Comment
NetProxy packet received Ignored Packets or timeouts are processed right after
Flash access is recovered.
MCTP packet received
A response with
ERROR_NOT_READY
(0x04) completion
code is returned.
SMBus read transaction Not ready command
replied
SMBus write transaction Byte count word is
NACKed However, the address and the command are
acknowledged.
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3.3.5 Flash Read, Write, and Erase Sequences
Note: This section describes the low-level Flash procedures handled between software, firmware,
and hardware. The high-level Flash flows are built using these procedures, and include the
semaphore taking/releasing and other high level tasks. Refer to Section 3.3.11.Each time
programming the NVM via CSR accesses, PCIEMISC.DMA Idle Indication bit must be set to
1b.
3.3.5.1 Flash Erase Flow by Software
In this section, software uses FLSW* registers.
Device Erase Flow:
1. Poll the FLSWCTL.DONE bit until it is set.
2. Set FLSWCTL.CMD fields to 0011b.
3. Wait until FLSWCTL.DONE bit is read as 1b and FLSWCTL.FLBUSY bit is read as 0b before releasing
the Flash semaphore.
Hardware sets the DONE bit without executing the operation if software attempts this command while
in Flash secure mode. The CMDV field is cleared in such case.
Sector Erase Flow:
1. Poll the FLSWCTL.DONE bit until it is set.
2. Set FLSWCTL.CMD field to 0010b and set the FLSWCTL.ADDR field to any address that belongs to
the Flash 4 KB sector to be erased.
3. Wait until the FLSWCTL.DONE bit is read as 1b and the FLSWCTL.FLBUSY bit is read as 0b before
releasing the Flash semaphore.
Hardware sets the DONE bit without executing the operation if software attempts to erase a protected
sector while in Flash secure mode. The CMDV field is cleared in such case.
3.3.5.2 Software Flow to the Bit-banging Interface
This section is relevant to software only while in the non-secure mode.
To directly access the Flash, software should follow these steps:
PCIe to SMBus switching in MCTP mode Ignored
SMBus to PCIe switching in MCTP mode Ignored
NC-SI packet received Command completed with
Package Not Ready error
code.
Command validity checks are not performed.
Packets received do not increment the NC-SI
statistics counters.
Note: The command is answered even if
the package was previously un-
selected.
Any event that requires issuing an AEN Ignored All relevant events are processed right after
Flash access is recovered.
Command received in the host interface Ignored Commands are processed right after Flash
access is recovered.
SMBus ARP offload SMBus ARP offload is
performed New SMBus addresses are written to the Flash
right after Flash access is recovered.
VPD write command received Ignored The VPD write is processed (and F bit set)
right after Flash access is recovered.
Event Response Comment
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1. Write a 1b to the Flash Request bit (FLA.FL_REQ).
2. Read the Flash Grant bit (FLA.FL_GNT) until it becomes 1b. It remains 0b as long as there are other
accesses to the Flash.
3. Write or read the Flash using the direct access to the 4-wire interface as defined in the FLA register.
The exact protocol used depends on the Flash placed on the board and can be found in the
appropriate datasheet.
4. Write a 0b to the Flash Request bit (FLA.FL_REQ).
5. Following a write or erase instruction, software should clear the Request bit only after it has
checked that the cycles were completed by the Flash. This can be checked by reading the BUSY bit
in the Flash device Status register. Refer to Flash datasheet for the OpCode to be used for reading
the Status register.
Notes: The bit-banging interface is not expected to be used during normal operation. Software
should instead use the EEPROM-mode when accessing the base sector and the Flash-mode
for other sectors.
If software must use the bit-banging interface in normal operation, it should adhere to the
following rules:
Gain access first to the Flash using the firmware/software semaphore mechanism.
Minimize the FLA.FL_REQ setting for a single byte/word/Dword access or other method
that guarantee fast enough release of the FLA.FL_REQ.
When hardware Flash bit-bang access is aborted due to deadlock avoidance, the
FLA.FLA_ABORT bit is set. To clear the block condition and enable further access to the Flash,
software should write 1b to the FLA.FLA_CLR_ERR bit.
3.3.5.3 Software Word Program Flow to the EEPROM-Mode Interface
Software must take semaphore ownership before executing these flows.
3.3.5.3.1 Read Interface
Software initiates a read cycle to the Flash via the EEPROM-mode as follows:
1. Software writes the address to be read in the EERD register
2. Software polls the EERD.DONE bit until it is asserted.
3. Software reads the EERD.DATA register field.
Hardware executes the following steps:
1. Eventually clears the CMDV bit if the command cannot be currently executed, and goes to step 4.
2. Reads the data from the shadow RAM.
3. Puts the data in DATA field of the EERD register.
4. Sets the DONE bit in the EERD register.
Note: Any word read this way is not loaded into the I210's internal registers. This happens only at a
hardware auto-load event.
3.3.5.3.2 Write Interface
Software initiates a write cycle to the Flash via the EEPROM-mode as follows:
1. Poll the DONE bit in the EEWR register until it is set.
2. Write the data word and its address in the EEWR register.
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As a response, hardware executes the following steps:
1. Eventually clears the CMDV bit if the command cannot be currently executed, and goes to step 3.
2. The I210 writes the data to the shadow RAM.
3. The I210 sets the DONE bit in the EEWR register.
Notes: The VPD area of the Flash can be accessed only via the PCIe VPD capability structure.
EEPROM-mode writes are performed into the internal shadow RAM. Software can instruct
copying of the internal shadow RAM content into the base sector of the Flash device by
setting the EEC.FLUPD bit.
3.3.5.4 Flash Program Flow via the Memory Mapped Interface
Software must take semaphore ownership before executing the flow. Software initiates a write cycle via
the Flash BAR as follows:
1. Write the data byte to the Flash through the Flash BAR. Use the Byte Enable (BE) pins if less than
four bytes has to be written.
2. Poll the FL_BAR_BUSY flag in the FLA register until cleared.
3. Repeat the steps 1 and 2 if multiple bytes should be programmed.
As a response, hardware executes the following steps for each write access:
1. Set the FL_BAR_BUSY bit in the FLA register.
2. Initiate autonomous write enable instruction.
3. Initiate the program instruction right after the enable instruction.
4. Poll the Flash status until programming completes.
5. Clear the FL_BAR_BUSY bit in the FLA register.
Note: Software must erase the sector prior to programming it.
3.3.5.5 Software Flash Program Flow via the Flash-Mode Interface
Software must take semaphore ownership before executing the flow.
1. Poll the FLSWCTL.DONE bit until it is set. This step is only needed if the flow is executed following a
reset event.
2. Write the number of bytes to be written into FLSWCNT.CNT field. The write must not cross a page
(256 byte) boundary.
3. Set the ADDR field with the byte resolution address in the FLSWCTL register and set the CMD field
to 0001b.
4. Write the data to the FLSWDATA register.
5. Hardware starts accessing the Flash and begins writing data bits from the FLSWDATA register. If the
write is not allowed, the CMDV bit is cleared instead.
6. Once hardware completes writing the data to the Flash, the FLSWCTL.DONE register bit is set.
7. Hardware increments FLSWCTL.ADDR field by four (Dword granularity) if byte count left is greater
or equal to 4.
8. Software polls the FLSWCTL.DONE bit until it is set.
9. Steps 4 to 8 are repeated several times until the number of bytes programmed in FLSWCNT.CNT
field has been written.
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10. FLSWCTL.GLDONE bit is set by hardware when the last byte programmed has been written. But
software can stop the transaction in the middle as long as it got the DONE bit read as 1b. In any
case, the FLBUSY bit must be read as 0b before releasing the Flash semaphore.
3.3.5.6 Software Flash Read Flow via the Flash-Mode Interface
The I210 provides an engine for reading the Flash in a burst mode:
1. Poll the FLSWCTL.DONE bit until it is set. This step is only needed if the flow is executed following a
reset event.
2. Set the FLSWCNT.CNT field with the number of bytes to be read from Flash in a burst mode.
3. Set the FLSWCTL.ADDR field with the byte address of the first Dword to be read and set the CMD
field to 0000b. The FLSWCTL.GLDONE bit is cleared by hardware to indicate a burst read has
started.
4. Hardware starts accessing the Flash and clears the FLSWCTL.DONE bit until it writes the read
Dword into the FLSWDATA register.
5. Software polls the FLSWCTL.DONE bit until it is set.
6. Software reads the Dword from FLSWDATA register, which is used by hardware to trigger a clear of
the FLSWCTL.DONE bit again.
7. Hardware increments FLSWCTL.ADDR field by four (Dword granularity) if byte count left is greater
or equal to 4.
8. Steps 5 to 7 are repeated until the number of bytes programmed in FLSWCNT.CNT has been read.
9. Hardware sets the FLSWCTL.GLDONE bit to indicate that all the Flash transactions related to the
command issued at step 3 were completed. However, software can stop the transaction in the
middle as long as it got the DONE bit set.
3.3.6 Flash Validity Field
The only way the I210 can tell if a Flash is present and programmed is by trying to read the Flash
Validity field at Flash word addresses 0x012 and 0x812. If one of the Validity fields is read as 01b, a
programmed lash is assumed to be present.
3.3.7 Flash Deadlock Avoidance
The Flash is a shared resource between the following clients:
1. Hardware auto-read.
2. LAN software accesses.
3. Manageability accesses.
4. Software tools.
All clients can access the Flash using parallel access, on which hardware implements the actual access
to the Flash. Hardware schedules these accesses, avoiding starvation of any client.
However, the software and firmware clients can access the Flash using bit-banging. In this case, there
is a request/grant mechanism that locks the Flash to the exclusive use of one client. If one client is
stuck without releasing the lock, the other clients can no longer access the Flash. To avoid this
deadlock, the I210 implements a timeout mechanism, which releases the grant from a client that holds
the Flash bit-bang interface (FLA.FL_SCK bit) for more than 8 seconds. If any client fails to release the
Flash interface, hardware clears its grant enabling the other clients to use the interface.
Note: The bit-banging interface does not guarantee fairness between the clients, therefore it should
be avoided in normal operation as much as possible. When write accesses to the Flash are
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70
required the software or manageability should access the Flash one word at a time releasing
the interface after each word. Software and firmware should avoid holding the Flash bit-bang
interface for more than 500 ms.
The deadlock timeout mechanism is enabled by the Deadlock Timeout Enable bit in the Control Word 1
in the Flash.
3.3.8 VPD Support
The Flash can contain an area for VPD. This area is managed by the OEM vendor and does not influence
the behavior of hardware. Word 0x2F of the Flash contains a pointer to the VPD area in the Flash. It is
recommended to map the VPD area into the RO area of the shadow RAM. Word 0x0A contains the Flash
VPD_EN bit, which controls whether or not the VPD capability appears in the configuration space
following the next PCI reset event. The VPD_EN bit must be set to 1b only once a valid VPD structure is
programmed in the Flash.
The maximum area size is 1024 bytes but can be smaller. The VPD block is built from a list of resources.
A resource can be either large or small. The structure of these resources are listed in the following
tables.
The I210 firmware parses the VPD structure during the auto-load process following PCIe reset in order
to detect the read only and read/write area boundaries. The I210 assumes the following VPD fields with
the limitations listed:
VPD structure limitations:
The structure must start with a Tag = 0x82.
The structure must end with a Tag = 0x78. The tag must be word aligned.
Table 3.15. Small Resource Structure
Offset 0 1 — n
Content Tag = 0xxx,xyyyb (Type = Small(0), Item Name = xxxx, length = yy
bytes) Data
Table 3.16. Large Resource Structure
Offset 0 1 — 2 3 — n
Content Tag = 1xxx,xxxxb (Type = Large(1), Item Name = xxxxxxxx) Length Data
Table 3.17. VPD Structure
Tag Length
(bytes) Data Resource description
0x82 Length of
identifier string Identifier Identifier string.
0x90 Length of RO
area RO data VPD-R list containing one or more VPD keywords.
0x91 Length of RW
area RW data VPD-W list containing one or more VPD keywords. This part is optional.
0x78 n/a n/a End tag.
Interconnects—Ethernet Controller I210
71
If the I210 does not detect a value of 0x82 in the first byte of the VPD area or if no End tag is
detected, or if the structure does not follow the description of Table 3.17, it assumes the area is not
programmed:
Any read/write access through the VPD registers set are ignored.
The VPD pointer itself remains RO.
The VPD RO area and RW area are both optional and can appear in any order. A single area is
supported per tag type. Refer to Appendix I in the PCI 3.0 specification for details of the different
tags.
If a VPD-W tag is found, the area defined by its size is writable via the VPD structure.
The VPD must be accessed through the PCIe configuration space VPD capability structure listed in
Table 3.17. Write accesses to a read only area or any accesses outside of the VPD area via this
structure are ignored. The VPD area is also accessible for read via the EEPROM-mode access, and
for write via the same access mode - only if the VPD area is mapped to a RW area of the shadow
RAM (not recommended).
VPD area must be mapped to the first valid 4 KB sector of the Flash.
VPD software does not check the semaphores before attempting to access the Flash via dedicated VPD
registers. Even if the Flash is owned by another entity, VPD software read or write access directed to
the VPD area might complete immediately since it is first performed against the shadow RAM. Firmware
is responsible for handling the VPD read and write accesses against the host. Hardware notifies
firmware each time a VPD access was initiated. However, VPD software write access is written into the
Flash device at the firmware’s initiative, which might take up to several seconds. Refer to
Section 3.3.9.3.
3.3.9 Flash Structure and Update Flows
3.3.9.1 Flash Organization
The I210 Flash contains the following three high-level modules:
Legacy EEPROM Modules. These modules correspond to the legacy EEPROM contents, they are
mapped to one of the first two 4 KB sectors of the Flash device, and cannot be extended beyond
these sectors. They are composed of all the Flash modules used by the hardware (such as PCIe
down to MAC blocks, PHYs excluded) or ones used by the manageability firmware. In prevision to
the RO Updates structure 3 (refer to Section 6.9.2.2), the last 4 words of the shadow RAM must
always be left unused, filled with all 1s contents.
Expansion/Option ROM Module. Must fit within 512 KB and shall start at the fixed word address
0x1000. It includes the PXE driver (61 KB), iSCSI boot image (116 KB), FCoE boot image (80 KB),
UEFI network driver (37 KB for x64, 67 KB for IA64), and can also include a CLP module (60 KB).
Refer to Section 3.3.3.1.
Secured Area (Firmware Secured Module). Must fit within 244 KB (or 448 KB) and start at a 4
KB boundary. It is mainly destined to store firmware code, but it can also include other firmware
structures and modules. It is pointed from the Flash word address 0x10, in either sector 0 or 1.
Free Provisioning Area. This area is 244 KB (or 448 KB) in size. Following a firmware update
event, it becomes the new secured area and the old secured area becomes the new free
provisioning area. It is pointed from the NVM word address 0x40, in either sector 0 or 1.
mDNS Records. This module contains the mDNS records used by the firmware for mDNS offload
proxy while the system is in D3. The module must be mapped next to the secured area. The size
provisioned for mDNS records is 16 KB. The module’s offset from the beginning of the secured area
is given by NVM word 0x25, in either sector 0 or 1.
Notes: Flash device size can be read by host from FLA.FL_SIZE register field.
Ethernet Controller I210 —Interconnects
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Update of the PCIe Expansion/Option ROM does not need to be protected by the double
image policy as it is not as critical to the I210 operation as the firmware image module.
Figure 3.6. General Organization of the Flash
Notes: Figure 3.6 shows the general NVM organization. Due to this, both the secured and free
provisioning areas of the firmware, are not mapped to any Flash address in the diagram.
On Flash parts larger than 1 MB, the space from byte address 0x002000 to 0x081FFF is
always reserved to the Expansion/Option ROM module.
The first NVM images produced will fit in 0.5 MB Flash parts (assuming no expansion/option ROM
module). The firmware image and free provisioning area is sized by 244 KB (or 448 KB) each. The
mDNS records might overlap with the beginning of the free provisioning area. In this case, the firmware
code itself has a size budget of up of to 235 KB.
0x 000000
0x000FFF
0x001FFF Legacy EEPROM
(bank 1)
0x 001000
Byte Address
FLASH
1
Free Provisioning
Area
Legacy EEPROM
(bank 0)
Shadow RAM
EEPROM Image
Update
Use
Firmware Image
Use
Update
Expansion/
Option ROM
Module
0x002000
0x082000
448 KB
448 KB
0x081FFF
CSS Header
mDNS Records
Flash Table
RO Update Section
16 KB
Secured Area
4 KB
Interconnects—Ethernet Controller I210
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Figure 3-7. Organization of the NVM That Supports 0.5 MB Flash Parts
3.3.9.2 Flow for Updating the Firmware Secured Module
In order to protect the Flash update procedure from power-down events, a double image policy is
required each time the firmware code is updated. The software should proceed as follows:
1. Take ownership over the Flash via the semaphore bits. Refer to Section 4.6.
2. Read the pointer to the Firmware Secured Module (word 0x10), which is the current location of the
module, and read the pointer to the free provisioning area (word 0x40). Exactly 244 KB (or 448 KB)
must be provided to the free space provisioning area segment, even if the enclosed firmware code
size is smaller. Check that the free provisioning area size read from word 0x41 is greater or equal to
the size of the new firmware image to be loaded in NVM.
a. If not, exit the flow. It is assumed that the Intel person responsible for the update first updates
the free area pointer and size fields so that they define a larger free area.
3. Initiate sector erase instructions to the entire free space provisioning segment.
a. In order to guaranty Flash semaphore ownership time does not exceed the 3 sec timeout, it is
recommended to perform at this step no more than four 4 KB sector erase operations at once in
a burst, releasing semaphore ownership for 10 ms in between. This way, other entities can insert
Flash read accesses in between burst without waiting for completion of the entire update
process, which might take minutes.
4. Write the new firmware secured module at the location pointed by the free space provisioning
segment pointer via Flash-mode access (memory mapped or FLSW* register set).
a. For the same reason as before, it is recommended to write at this step no more than four 4 KB
sectors at once in a burst, releasing semaphore ownership for 10 ms in between.
5. Write the FLFWUPDATE.Update bit to 1b.
Legacy EEPROM
(ba nk 1)
4Mbit FLAS H
1
Free Provisioning
Area
Legacy EEPROM
(ba nk 0)
ShadowRAM
EEPROM Image
Update
Use
Firmw are Image
244 KB
244 KB
C SS Header
Flash Table
RO Update Section
mDNS Records 16 KB
Secured A rea
4 KB
4 KB
4 KB
mD NS offset = 0x803D
16 K B
Ethernet Controller I210 —Interconnects
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6. Release the Flash semaphore.
a. Software must avoid taking the Flash semaphore again until the firmware resets and reloads
from the new image. Any new attempt to write the Flash until then is not performed by the
device.
7. If the NVM_SEC_EN bit is read as 0b (bit 13 in Flash word 0x12) or if the security-disable strapping
pin is set, then firmware enters the device in the non-secured mode.
8. Firmware swaps between the Free Provisioning Area Pointer (word 0x40) and the Firmware Secured
Module pointer located at the shadow RAM word address 0x10, and updates the SW Checksum at
word 0x3FFirmware dumps the shadow RAM into the Flash.Software polls the FLFWUPDATE.AUTH-
DONE bit until it is read as 1b.
a. If FLFWUPDATE.AUT_FAIL bit is read as 1b, it means that the update process failed because of
one of the security checks has failed or because of some defect in the Flash write. In such case
software exits the flow and might decide to rerun it from the beginning.
Note: The device may not reply to requests from the MC during the firmware update process, which
can last up to 3 seconds.
3.3.9.3 VPD Write Flows
3.3.9.3.1 First VPD Area Programming
The VPD capability is exposed on the PCIe interface only if the VPD_EN bit in Flash word 0x0A is set to
1b, regardless of any other sanity check that is performed on the VPD area contents.
The VPD contents and pointer can be written on a blank Flash without any limitation, similar to any
other Flash module when in the blank Flash programming mode. This is the recommended way to map
the VPD area into the RO protected area of the shadow RAM, which is highly advised.
3.3.9.3.2 VPD Area Update Flow
1. The host performs a VPD write - it sets write offset/data into VPD register set of the configuration
space, setting the VPD Flag (bit 15 in VPD Address Register - 0x0E2).
2. Firmware checks the VPD write is allowed - it checks that the write offset points to the VPD-RW
area and not to the RO area of the shadow RAM and nor to the VPD-RO area.
a. If it is not, firmware clears the VPD flag in the configuration space to notify the VPD software
that the transaction completed, and exits the flow.
3. Firmware takes Flash semaphore ownership.
4. Firmware re-starts the 10 ms VPD timer and writes the change into shadow RAM.
5. Firmware completes the VPD access to software - firmware clears the VPD flag in the configuration
space to notify the VPD software that the access completed.
6. Firmware releases Flash semaphore ownership.
7. When the VPD timer expires, firmware dumps the shadow RAM into the Flash.
If VPD write access is attempted by the host when the device has just started a Flash erase
operation, or if Flash ownership is held by software for a long time, then the VPD write
request might time out as the firmware code responsible to handle the request would not be
readable from the Flash. As a result, Intel recommends that a software application that
modifies the VPD area perform back-to-back VPD write accesses within no longer than 10 ms
between two consecutive writes.
Interconnects—Ethernet Controller I210
75
3.3.9.4 Flow for Updating One of the RW Legacy EEPROM Modules
When updating one or several fields from a legacy EEPROM module there is a risk that a hardware auto-
load event occurs in the middle of the operation (due to a sudden PCIe reset for instance), leading to
the auto-load of an invalid or inconsistent content from the internal shadow RAM into the device
registers or memory. Therefore unless the field(s) can be updated by a single EEPROM-mode access,
the updating software must repeatedly use the following procedure for each legacy EEPROM module to
be updated:
1. Take ownership over the Flash via semaphore bits. Refer to Section 4.6.
2. Invalidate the pointer to the module to be modified by setting it to 0xFFFF via EEPROM-mode
access. This way, if a hardware auto-load of the module is attempted, the associated register
defaults are loaded instead. Do not invalidate pointers to firmware modules.
3. Modify the contents of the module via EEPROM-mode access.
4. Restore the pointers to the modified module(s) via EEPROM-mode access.
5. Compute and update the software checksum (word 0x3F) if the contents covered by the software
checksum was modified.
6. Release the Flash semaphore.
7. Set the FLUPD bit in EEC register to ask the device to load the internal shadow RAM into the Flash.
8. Firmware dumps the shadow RAM into the Flash.
9. Poll the FLUDONE bit in EEC register until it is set by the device.
Note: Depending on the modified RO items, a system reset is generally required for loading the
modifications into the device. Refer to the Loading Trigger column in Table 3-18.
3.3.9.5 Flow for Updating the Option ROM Module
Updating software should proceed as follows. If a power cycle occurs in the middle of the flow, the
updating application must rerun the entire flow.
1. Take ownership over the Flash via the semaphore bits. Refer to Section 4.6.
2. Initiate sector erase instructions to the fixed 512 KB area to which the Option ROM module is
mapped.
a. In order to guaranty Flash semaphore ownership, time should not exceed the 3 second / 1
second timeout. It is recommended to perform at this step no more than four / two 4 KB sector
erase operations at once in a burst, releasing semaphore ownership for 10 ms in between. This
way, other entities can insert Flash read accesses in between a burst without waiting for the
entire update process to complete, which may take several minutes.
3. Write the new Option ROM module contents at the same location it was before.
a. For the same reason as before, it is recommended to write at this step no more than four / two
4 KB sectors at once in a burst, releasing semaphore ownership for 10 ms in between.
4. Release the Flash semaphore.
3.3.10 Flash Security
The Flash update integrity feature ensures that only Intel approved firmware code (or another
protected Flash module) is able to be updated on the I210 devices after manufacturing. This procedure
is performed whenever attempting to update one of the protected modules. Refer to Flash update flows
in Section 3.3.9.
Ethernet Controller I210 —Interconnects
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Integrity validation of Flash updates is provided by means of a digital signature. The digital signature is
a SHA256 Hash computed over the protected content (long by 256-bits), which is then encrypted by a
2048-bits RSA encryption using an Intel private key. This digital signature is stored in what is called the
manifest in the Flash module image. Also stored in the manifest is the corresponding RSA Modulus (the
public key) and RSA Exponent parameters to be used for decrypting the digital signature.
To verify the authenticity of the digital signature, firmware must first verify that the RSA Modulus and
RSA Exponent fields in the new firmware image loaded are identical to those in the old FW image. If the
RSA Modulus and Exponent fields are the same, firmware decrypts the digital signature using the 2048-
bit RSA Modulus and Exponent fields stored in the manifest of the old firmware image to extract the
expected SHA256 Hash of content (stored hash). Firmware then performs an independent SHA256
Hash over the protected content (computed hash). If the stored hash matches the computed hash, the
digital signature is accepted, and the Flash update is applied.
Flash updates are validated prior to invalidating the old Flash configuration, such that the old Flash
configuration is still usable if the update fails to validate. After the new Flash is successfully verified, the
firmware switches to the new image.
Figure 3-8. Sign and Verify Procedures for Authenticated Flash Modules
3.3.10.1 Digital Signature Algorithm Details
As previously mentioned, the digital signature generation is a hash computation followed by an RSA
encryption. This is performed within Intel as part of the Flash update image generation process and not
performed by Intel software in the field, nor by the I210.
The algorithms used are described in the following locations:
PKCS #1 v2.1: RSA Cryptography Standard, RSA Laboratories, June 14, 2002 -
SHA family definition -
SHA usage with digital signatures -
SHA validation vectors -
Protected
Module
Contents
Digest
SHA256
Hash
Verify
CSS Header
Digital
Signature
Module’s
Manifest
2048-bits
RSA Modulus
RSA Exponent Private key
RSA encryption
Protected
Module
Contents
Digest
SHA256
Hash
CSS Header
2048-bits
RSA Modulus
RSA Exponent
Public key
RSA decryption
= ?
Sign
New = Old ?
www.rsa.com
http://csrc.nist.gov/publications/fips/fips180-3/fips180-3_final.pdf
http://csrc.nist.gov/publications/nistpubs/800-107/NIST-SP-800-107.pdf
http://csrc.nist.gov/groups/STM/cavp/documents/shs/SHAVS.pdf
Interconnects—Ethernet Controller I210
77
Note: The Protected Module Contents shown in Figure 3-8 starts with the I210 blank Flash Device
ID word of the Flash header described in Section 6.9.1, and ends with the last word of the
Firmware Secured Module - regardless to the size of the firmware code and to the presence
and size of a Flash Devices Table and RO Updates sections at the last two sector of the
Firmware Secured Module area.
3.3.10.2 Protected Modules
Any data that is modified in-the-field (either by the OEM during manufacturing, or by the end user)
cannot be included in the signed region of Flash. The device is incapable of generating a signed image
by itself because the private key is not available to the device to generate the digital signature in Flash.
Only the following Flash module requires authentication in the I210. The module includes its own digital
signature: firmware image and its associated sub-modules.
3.3.11 Flash Init Flow
After a PCIe reset, the I210 reads the global device parameters from the shadow RAM (assuming it has
a valid NVM Validity field contents) including all the parameters impacting the content of the PCIe
configuration space. After a software reset to the port (CTRL.RST set to 1b), a partial load is done of
the parameters relevant to the port where the software reset occurred.
Table 3-18 lists the words read in each auto-load sequence. During full load after power-on all
hardware related Flash words are loaded. Following a software reset, only a subset of the hardware
related Flash words are loaded. For details of the content of each word, see Chapter 6.0.
Table 3-18. Shadow RAM Auto-Load Sequence
Flash Word Name Flash Word
Address
Loading
Order
Full Load
(Power-up)
Full Load
No MGMT
(PCI RST)
Software1
Reset Port
Load
Ethernet Address Byte 2-1 - LAN 0x00 29 Y Y Y
Ethernet Address Byte 4-3 - LAN 0x01 30 Y Y Y
Ethernet Address Byte 6-5 - LAN 0x02 31 Y Y Y
Init Control 1 0x0A 4 Y Y
Subsystem ID20x0B 17 Y Y
Subsystem Vendor ID20x0C 18 Y Y
Device ID - LAN20x0D 19 Y Y
Vendor ID - LAN20x0E 20 Y Y
Init Control 2 LAN 0x0F 28 Y Y Y
Flash Device Size (FL_SIZE only) 0x11 2 Y
Flash Sizing and Protected Fields 0x12 1 Y Y Y
Init Control 4 LAN 0x13 27 Y Y Y
PCIe L1 Exit Latencies 0x14 15 Y Y
PCIe Completion Timeout
Configuration 0x15 16 Y Y
MSI-X Configuration LAN 0x16 21 Y Y
Software Reset CSR Auto
Configuration Pointer and
Software Reset CSR Auto
Configuration structures - LAN
0x17 33 Y Y Y
PCIe Init Configuration 1 0x18 5 Y Y
PCIe Init Configuration 2 0x19 6 Y Y
Ethernet Controller I210 —Interconnects
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3.4 iNVM
The I210 can operate with no Flash attached (Flash-less mode). The I210 incorporates an on-die
internal NVM (iNVM) memory (size 2 Kb) that enables designers to internally program the I210 with a
subset of the default values that are normally associated with an external Flash. iNVM is similar to One
Time Programmable (OTP) memory except that it allows for a limited number of modifications and
corrections after initial programming. The iNVM has a capacity of 64 words, or 32 two-word CSR
entries. A word, once used, cannot be rewritten. The initial programming will take a number of these,
and each new entry takes additional words until the capacity is reached. For example, programming the
MAC address consumes three auto-load word structures.
The last two words of the iNVM (62-63) are used for manufacturing identification information. Word 61
is written with version information when the iNVM is programmed using Intel tools. The contents of
these words do not affect the operation of the device.
Refer to the note in Section 1.4.3 for the functional limitation that exists when the I210 operates
without an external Flash part.
This section describes the iNVM structure for the I210.
3.4.1 iNVM Contents
The iNVM memory is used there to store and program the default values that are otherwise
programmed via auto-load from the external Flash memory. The list of programmable values includes
the following (amongst others):
MAC address - words 0x00, 0x01, 0x02
PCIe Init Configuration 3 0x1A 7 Y Y
PCIe Control 1 0x1B 8 Y Y
LEDCTL 1 Default LAN 0x1C 24 Y Y
Device Rev ID 0x1E 14 Y Y
LEDCTL 0 Default LAN 0x1F 25 Y Y
Software Defined Pins Control -
LAN 0x20 32 Y Y Y
Functions Control 0x21 13 Y Y
LAN Power Consumption 0x22 22 Y Y
PCIe Reset Configuration Pointer
and PCIe Reset CSR Auto
Configuration Structures - LAN 0x23 26 Y Y
Init Control 3 LAN 0x24 23 Y Y
CSR Auto Configuration Power-Up
LAN 0x27 3 Y
PCIe Control 2 0x28 9 Y Y
PCIe Control 3 0x29 10 Y Y
Watchdog Configuration 0x2E 34 Y Y Y
1. After asserting CTRL.DEV_RST by software partial load of parameters relevant to the port is done. Assertion of
CTRL_EXT.EE_RST causes load of port parameters similar to CTRL.RST.
2. Loaded only if load subsystem ID bit is set.
Table 3-18. Shadow RAM Auto-Load Sequence
Flash Word Name Flash Word
Address
Loading
Order
Full Load
(Power-up)
Full Load
No MGMT
(PCI RST)
Software1
Reset Port
Load
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Serial ID (for PCIe) is a derivative of MAC address.
iNVM image revision - word 0x05
Subsystem ID and Subsystem Vendor ID - words 0x0B, 0x0C
Needed only for NIC and for other vendors than Intel.
Device ID - word 0x0D
Device ID: Use a separate device ID for the I211 running with a programmed iNVM (0x1539).
Board Configuration (LEDs, SDPs, etc.) - words 0x1C, 0x1F, 0x20, 0x24
LAN power consumption - word 0x22
PHY/PCIe analog parameters. This information is loaded in the iNVM as it is determined based on
the silicon’s process state.
Other critical PCIe settings that are loaded only at power-up.
Hardware init, workaround/bypass
Initialization Control word 1 - word 0x0A to:
set GPAR_EN bit to 1b (enable global parity check)
optionally set iNVM to 1b (see note in Section 3.4.2.1)
Initialization Control Word 2 to set TX_LPI_EN bit - word 0x0F
Device Off Enable bit to 1b - word 0x1E
PHY disconnect until the software device driver is up and running or WoL setup - words 0x24, 0x29
PHY disconnect is achieved by setting the Go Link Disconnect field (bit 5) in the PHPM register
FLBAR_Size set to 0 - word 0x28
Not Supported in iNVM:
Manageability and manageability parameters
Pointers
VPD
Legacy Option ROM - PXE (PXE driver can reside in BIOS Flash), iSCSI boot (requires external
Flash), etc.
3.4.2 iNVM Structures
The iNVM contains the following three structures:
1. Word auto-load (2 words)
2. CSR auto-load (4 words)
3. PHY register auto-load (2 words)
Each structure starts with a type field. When a non-null unknown type is encountered, the 32-bits are
skipped by hardware as they might contain an item that is relevant to firmware or software.
When invalidating a structure, all its Type field bits should be set to 1b. That way, each time the device
iNVM parser encounters a 111b type it can skip 32-bit words until the next non 111b type is detected.
Table 3-19 lists the different iNVM structure types:
Ethernet Controller I210 —Interconnects
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Table 3-20 lists the iNVM value load condition as a function of the reset types. the reset type value
should be the same as specified in the reset type value of the auto-load table.
3.4.2.1 Word Auto-load Structure
MSB[15] ..............................................................................................................LSB[0]
Figure 3-9. Word Auto-load Structure
3.4.2.1.1 iNVM Programmed Word Structures (Type 001b)
Table 3-19. iNVM Structure Types
Type Description
000b Un-initialized iNVM Dword, stop iNVM parsing.
001b Word auto-load
010b CSR auto-load
011b PHY register auto-load
100b Reserved - do not use this value
111b Invalidated iNVM structure, skip the Dword (16-bits)
Other Reserved for future use, skip the Dword (16-bits)
Table 3-20. iNVM Structure Reset Types (for Auto-load)
Reset Type Description
00b Load on Power-up (LAN_PWR_GOOD) reset
10b Load on PCIe reset and power-up reset
01b Reserved
11b Load on software reset, PCIe reset, and power-up reset
Table 3-21. iNVM Values
Word Address Word Data (16 bits)
0x00 Ethernet Address Low
0x01 Ethernet Address Mid
0x02 Ethernet Address High
0x0A Initialization Control Word 1 (Word 0x0A) - Section 6.2.2
0x0E Vendor ID (Word 0x0E) - Section 6.2.6
0x0F Initialization Control Word 2 (Offset 0x0F) - Section 6.2.7
Type
3b=3'b001
Res et Type
2b
Word Address[6:0]
7b
Word Data[15:0]
16b
RSV
4b=4'b0
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Note: In order to secure the iNVM memory (such as avoiding any further write to it after
manufacturing), a word auto-load structure must be present in iNVM for setting the iNVM bit
to 1b in word address 0x0A.
3.4.2.2 CSR Auto-load Structure
The CSR auto-load structure is defined as follows:
MSB[15] ..............................................................................................................LSB[0]
Figure 3-10. CSR Auto-load Structure
3.4.2.3 PHY Register Auto-load Structure
MSB[15] ..............................................................................................................LSB[0]
Figure 3-11. PHY Register Auto-load Structure
0x1B PCIe Control 1 (Word 0x1B) - Section 6.2.17
0x1C LED1 Configuration Defaults (Word 0x1C) - Section 6.2.18
0x1E Device Rev ID (Word 0x1E) - Section 6.2.19
0x1F LED0,2 Configuration Defaults (Word 0x1F) - Section 6.2.20
0x20 Software Defined Pins Control (Word 0x20) - Section 6.2.21
0x21 Functions Control (Word 0x21) - Section 6.2.22
0x22 LAN Power Consumption (Word 0x22) - Section 6.2.23
0x24 Initialization Control 3 (Word 0x24) - Section 6.2.24
0x29 PCIe Control 3 (Word 0x29) - Section 6.2.26
0x28 PCIe Control 2 (Word 0x28) - Section 6.2.25
0x2E Watchdog Configuration (Word 0x2E) - Section 6.2.29
0x31 Configuration Customization Options PCIe Function (Word 0x31) -
Section 6.8.6.2
Table 3-21. iNVM Values (Continued)
Word Address Word Data (16 bits)
Type
3b=3'b011
Reset Type
2b=2'b11
MDIC REGADD [4: 0]
5b
MDIC DATA[15:0]
16b
RSV
6b=6'b0
Ethernet Controller I210 —Interconnects
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Once the structure is loaded to the PHY, the EEMNGCTL.CFG_DONE bit is set.
3.4.2.4 iNVM Structure (Version Information)
Bit 2:0 = Invalidated
bit 4:3 = Reserved 0x1
bit 8:5 = Reserved 0xF
Bit 31:16 = Version number (number of 1' s show the version number 0x1 = 1, 0x3 =2, 0x7 =3,
etc.)
3.4.3 iNVM Programming Flows
iNVM can be programmed at several occasions and via different means:
1. At the chip manufacturing site (by Intel), via a special pin. It sets the critical PCIe settings required
by the I210 to show up correctly on the PCIe bus with a default device ID.
2. At customer premises (by OEMs), via an Intel provided software tool, which uses a special register
set. This tool enables customers to make some customization to the LEDs, device ID, ASPM, etc.
and it sets the per-controller settings.
For security reasons, the I210 has a lock-out mechanism after the iNVM is programmed at this
stage, to prevent any tampering/retry of the iNVM programming. It is activated by writing a special
iNVM word auto-load structure, iNVM word address 0xA, bit 15 set to 1b. The lock-out is active as
long as the SECURITY-EN strapping option is enabled.
3. By disabling the SECURITY_EN strapping option, the iNVM lines left blank become writable again
like in step 2. This can be useful for fixing iNVM values that were programmed wrongly, or, if boards
are resold to a third party who wants to further customize the iNVM. For example, the third party
might want a different MAC address or device ID to identify the device with their company's custom
software. At the end of this iNVM write cycle, the SECURITY_EN strapping option must be re-
enabled.
3.4.3.1 iNVM Programming Flow via Registers
Writing the iNVM via this flow must be done when the system is idle, with no Rx/Tx traffic running and
with PCIEMISC.DMA Idle Indication bit set to 1b. The iNVM memory is organized in 32 lines of 64 bits
each, for a total of 2 Kb.
1. To be sure the PHY clock used by iNVM programming logic gets stabilized, wait (at least) 15 s after
EEMNGCTL.CFG_DONE bit is read as 1b.
a. Skip this step on devices that have no attached Flash parts with a valid contents
2. To avoid mistakenly writing the iNVM, write the iNVM_PROTECT.CODE register field with
0xABACADA (ALLOW_WRITE bit is set to 1b).
3. Read the iNVM memory line to be programmed, use iNVM_DATA[2n] and iNVM_DATA[2n+1]
register (n=0,...,31), respectively for the lower and higher Dwords of the iNVM line to be
programmed.
4. Write the desired value in iNVM_DATA[2n].
5. Wait 320 s, which is the time required for a complete burning of the 32-bit fuses or poll
iNVM_PROTECT.BUSY until it is cleared.
6. Write the desired value in iNVM_DATA[2n+1].
7. Wait 320 s, which is the time required for a complete burning of the 32-bit fuses.
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8. Read the iNVM line programmed via iNVM_DATA[2n] and iNVM_DATA[2n+1] registers read.
a. If not all the bits were properly written, repeat steps 4 to 8 until all bits are properly written.
9. Optionally, lock the line programmed by setting iNVM_LOCK[n].LOCK register bit to 1b.
a. Wait 10 s for the lock to take effect.
b. Read the iNVM_LOCK[n].LOCK register bit to check it is read as 1b.
c. If it is not read as 1b, repeat step 9 until it reads as 1b.
10. Program a new line if needed by repeating step 3.
11. When the iNVM programming sequence completes, write to the iNVM_PROTECT register with
0x00000000.
Note: Reading the iNVM can be done directly by read access to the iNVM_DATA[0-63] registers.
Locking a programmed line at step 8 avoids any possibility in the future to invalidate the line
by writing the Type field with 111b.
In case no Flash part with a valid contents is attached, the new OTP settings will take effect
either after a power-up cycle or if mirroring the whole OTP contents into the shadow RAM and
initiating a PCIe reset. The later option does not concern items that load only at power-up
(refer to Table 3-27).
3.4.4 Hardware Load of iNVM Values into Internal Structures
After every reset, hardware goes over the iNVM, reading and parsing its structures. If a structure is
valid and its reset type matches the initiated reset, hardware loads the word or CSR from the iNVM
structure into its internal hardware structures.
If an iNVM structure type is read as 111b, hardware skips that Dword, and any following Dword starting
with that type field.
If a type field is read as 000b, hardware stops parsing the iNVM and concludes.
In a 2 Kb iNVM, there is room for programming up to 64 words or 32 CSRs. For example, programming
the MAC address consumes three auto-load word structures.
Once an iNVM structure is written, there is no way to modify its value other than invalidating its type
field (type=111b). iNVM structures can be constructed to rewrite or replace previous iNVM structures, if
such a change is required. For instance, assuming PCI configuration and various workarounds require 5
CSR structures and 5 word auto-load ones, then 68 iNVM words remain un-programmed, which leaves
enough room for additional word and CSR rewrites, if needed.
3.4.5 Software Load of Default Values into Internal Structures
On every reset event of the I210, software is able to re-load new default values into the internal
hardware structures as if the settings were auto-loaded by hardware from the shadow RAM. This ability
is referred to as auto-load bus write by software. It is aimed to avoid wasting iNVM lines with settings
that can be handled by software.
The following flow is used by software:
1. Write the iNVM word address and data to be loaded in the device via EEARBC register write. Refer
to Table 6-1 iNVM words that are used by hardware.
2. Wait until the EEARBC.DONE bit is set by hardware.
3. Load new iNVM words into the hardware structures by repeating steps 1 and 2 as needed.
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Note: Software uses the autoload bus write mechanism because writing into registers is not always
possible to set internal hardware structures.
3.4.6 I210 Init Flow
Once the init flow detects no Flash device is present, a POR or a firmware reset event, the ROM-based
firmware code jumps to this flow from step 2 of the flow described in Section 3.3.11.2.
1. If this is the first time this flow is entered after POR, then ROM-firmware parses the iNVM structure
to handle PHY register auto-load structures (if there are such in iNVM).
2. ROM-firmware parses the iNVM structure to detect the presence of a word auto-load structure for
iNVM word 0x0A:
a. If the structure is found and HI_DISABLE bit is set to 1b, then exit this flow.
3. ROM-firmware sets the HICR.Memory Base Enable bit to 1b, and HICR.Enable to 1b. This has the
effect of enabling the host interface.
4. ROM-firmware sets FWSM.FW_Mode field to 100b (host interface only), the FWSM.FW_Val_Bit to
1b, and issues an ICR.MNG interrupt to the host for notifying it that the device is ready for the
proxy code load.
5. ROM-firmware polls the HICR.C bit until it is set to 1b by the host. This is the indication used by the
host to notify firmware that the proxy code was loaded.
6. When the software device driver is up, it detects it is a the I211 SKU (device ID read as 0x1539)
and it waits until FWSM.FW_Mode is read as 100b (host interface only) and the FWSM.FW_Val_Bit
is read as 1b.
7. The software device driver resets the port by setting CTRL.RST and waits for EEC.AUTO_RD to be
read as 1b.
8. The software device driver resets the firmware by setting HICR.FWRE to 1b first, and then by
setting HICR.FWR to 1b, which has the effect of re-entering the ROM-firmware into step 1.
9. Each time the system exits from a sleep state, or once the software device driver gets the interrupt
issued by firmware at step 2, the software device driver checks whether the FWSM.FW_Mode is
read as 100b (host interface only) and the FWSM.FW_Val_Bit is read as 1b. This is the method used
by firmware to request re-load of the proxy code.
10. If a proxy code has to be loaded, then the software device driver sets its current internal RAM base
address to 0x10000. Otherwise, the software device driver exits the flow.
11. The software device driver copies its current internal RAM base address into the HIBBA register.
12. The software device driver writes consecutive locations from address 0x8800 up to 0x8BFF with the
next 1 KB of the proxy code, in Dwords (32-bit) chunks ordered in little endian.
13. The software device driver increments its current internal RAM base address by 1 KB.
14. The software device driver repeats steps 10 to 12 until the entire proxy code is written (or until the
50 KB limit is reached).
15. The software device driver sets the HICR.C bit to notify the ROM-firmware that the proxy code load
completed.
16. ROM-firmware starts the proxy code execution from internal RAM address 0x10000.
17. Once RAM-firmware completes it’s init sequence and is ready to receive commands from host, it
sets FWSM.FW_Mode to 001b (the I211 mode) and the FW_Val_Bit to 1b, and it clears the HICR.C
bit to notify the host that the host interface is ready to receive commands.
Note: Once loaded, the firmware runs the proxy code even when the system is in a sleep state. It is
the software device driver’s responsibility to reset the firmware prior to entering Sx.
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However, if the system powers up in S3 state or if a firmware reset event occurs while the
system was in S3, no proxy offload is performed until the system resumes S0 and the proxy
code is re-loaded into the device.
After PHY reset events, ROM-firmware (as well as RAM-firmware) is responsible to parse the PHY
register auto-load structures of the iNVM (refer to Section 3.4.2.3) and to perform the required MDIO
accesses accordingly.
3.5 Configurable I/O Pins
3.5.1 General-Purpose I/O (Software-Definable Pins)
The I210 has four software-defined pins (SDP pins) that can be used for miscellaneous hardware or
software-controllable purposes. These pins can each be individually configurable to act as either input
or output pins. The default direction of each of the four pins is configurable via the Flash as well as the
default value of any pins configured as outputs. To avoid signal contention, all four pins are set as input
pins until after the Flash configuration has been loaded.
In addition to all four pins being individually configurable as inputs or outputs, they can be configured
for use as General-Purpose Interrupt (GPI) inputs. To act as GPI pins, the desired pins must be
configured as inputs. A separate GPI interrupt-detection enable is then used to enable rising-edge
detection of the input pin (rising-edge detection occurs by comparing values sampled at the internal
clock rate as opposed to an edge-detection circuit). When detected, a corresponding GPI interrupt is
indicated in the Interrupt Cause register.
The use, direction, and values of SDP pins are controlled and accessed using fields in the Device Control
(CTRL) register and Extended Device Control (CTRL_EXT) register.
The SDPs can be used for special purpose mechanisms such as a watchdog indication (refer to
Section 3.5.3), IEEE 1588 support (refer to Section 7.8) or an I2C interface bus (refer to
Section 3.5.2).
3.5.2 I2C Over SDP
The I2C usage of SDP pins must be enabled by setting the I2C_ON_SDP_EN bit to 1b in Flash word
0x20. This relates to the SDP 0 and SDP 2 pins, which operate as I2C_CLK and I2C_DATA, respectively.
The I2C interface operates via the I2CCMD and I2CPARAMS register set (refer to Section 8.17.8). Since
this register set can be used by either software or firmware in alternation, its ownership must be
acquired/released via the semaphore ownership taking/release flows described in Section 4.6.
Note: I2C over SDP pins mode is mutually exclusive with running I2C over the SFPx_I2C pins.
3.5.3 Software Watchdog
In some situations it might be useful to give an indication to manageability firmware or to external
devices that the I210 hardware or the software device driver is not functional. For example, in a pass-
through NIC, the I210 might be bypassed if it is not functional. In order to provide this functionality, a
watchdog mechanism is used. This mechanism can be enabled by default, according to Flash
configuration.
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Once the host driver is up and it determines that hardware is functional, it might reset the watchdog
timer to indicate that the I210 is functional. The software device driver should then re-arm the timer
periodically. If the timer is not re-armed after pre-programmed timeout, an interrupt is sent to
firmware and a pre-programmed SDP0 pin is asserted. Additionally the ICR.Software WD bit can be set
to give an interrupt to the software device driver when the timeout is reached.
The SDP0 pin on which the watchdog timeout is indicated, is defined via the CTRL.SDP0_WDE bit. In
this mode, the CTRL.SDP0_IODIR should be set to output. The CTRL.SDP0_DATA bit indicates the
polarity of the indication. Setting the CTRL.SDP0_WDE bit causes the watchdog timeout indication to be
routed to this SDP0 pin.
The register controlling the watchdog timeout feature is the WDSTP register. This register enables
defining a time-out period and the activation of this mode. Default watchdog timeout activation and
timeout period can be set in the Flash.
The timer is re-armed by setting the WDSWSTS.Dev_functional bit.
If software needs to trigger the watchdog immediately because it suspects hardware is stuck, it can set
the WDSWSTS.Force_WD bit. It can also supply firmware the cause for the watchdog, by placing
additional information in the WDSWSTS.Stuck Reason field.
Note: The watchdog circuitry has no logic to detect if hardware is not functional. If the hardware is
not functional, the watchdog might expire due to software not being able to access the
hardware, thus indicating there is potential hardware problem.
3.5.3.1 Watchdog Re-arm
After a watchdog indication was received, in order to re-arm the mechanism the following flow should
be used:
1. Clear WD_enable bit in the WDSTP register.
2. Clear SDP0_WDE bit in CTRL register.
3. Set SDP0_WDE bit in CTRL register.
4. Set WD_enable bit in the WDSTP register.
3.5.4 LEDs
The I210 provides three LEDs on the port that can be used to indicate different statuses of the traffic.
The default setup of the LEDs is done via Flash word offsets 0x1C and 0x1F. This setup is reflected in
the LEDCTL register. Each software device driver can change its setup individually. For each of the
LEDs, the following parameters can be defined:
Mode: Defines which information is reflected by this LED. The encoding is described in the LEDCTL
register.
Polarity: Defines the polarity of the LED.
Blink mode: Determines whether or not the LED should blink or be stable.
In addition, the blink rate of all LEDs can be defined. The possible rates are 200 ms or 83 ms for each
phase. There is one rate for all the LEDs.
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3.6 Voltage Regulator
To reduce Bill of Material (BOM) cost, the I210 supports generating the 1.5V and 0.9V power supplies
from the 3.3V supply using an on-chip Switching Capacitor Voltage Regulator (SVR) control circuit,
which requires only an external capacitor component.
Refer to Section 11.6.6 for more details.
3.7 Network Interfaces
3.7.1 Overview
The I210 MAC provides a complete CSMA/CD function supporting IEEE 802.3 (10 Mb/s), 802.3u (100
Mb/s), 802.3z and 802.3ab (1000 Mb/s) implementations. The I210 performs all of the functions
required for transmission, reception, and collision handling called out in the standards.
The I210 supports the following potential configurations:
Internal copper PHY.
External SerDes device such as an optical SerDes (SFP or on board) or backplane (1000BASE-BX or
1000BASE-KX) connections.
External SGMII device. This mode is used for connections to external 10/100/1000 BASE-T PHYs
that support the SGMII MAC/PHY interface.
Selecting between the various configurations is programmable via the MAC's the Extended Device
Control register (CTRL_EXT.LINK_MODE bits) and default is set via Flash settings. Table 3-22 lists the
encoding on the LINK_MODE field for each of the modes.
The GMII/MII interface, used to communicate between the MAC and the external PHY or the SGMII
PCS, supports 10/100/1000 Mb/s operation, with both half- and full-duplex operation at 10/100 Mb/s,
and only full-duplex operation at 1000 Mb/s. Board design link path should include AC coupling
capacitors.
The SerDes function can be used to implement a fiber-optics-based solution or backplane connection
without requiring an external TBI mode transceiver/SerDes.
The SerDes interface can be used to connect to SFP modules. As such, this SerDes interface has the
following limitations:
No Tx clock
AC coupling only
Table 3-22. Link Mode Encoding
Link Mode I210 Mode
00b Internal PHY
01b 1000BASE-KX
10b SGMII
11b SerDes/1000BASE-BX
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The internal copper PHY supports 10/100/1000BASE-T signaling and is capable of performing intelligent
power-management based on both the system power-state and LAN energy-detection (detection of
unplugged cables). Power management includes the ability to shut-down to an extremely low
(powered-down) state when not needed, as well as the ability to auto-negotiate to lower-speed 10/100
Mb/s operation when the system is in low power-states.
3.7.2 MAC Functionality
3.7.2.1 Internal GMII/MII Interface
The I210’s MAC and PHY/PCS communicate through an internal GMII/MII interface that can be
configured for either 1000 Mb/s operation (GMII) or 10/100 Mb/s (MII) mode of operation. For proper
network operation, both the MAC and PHY must be properly configured (either explicitly via software or
via hardware auto-negotiation) to identical speed and duplex settings.
All MAC configuration is performed using Device Control registers mapped into system memory or I/O
space; an internal MDIO/MDC interface, accessible via software, is used to configure the internal PHY.
In addition an external MDIO/MDC interface is available to configure external PHY’s that are connected
to the I210 via the SGMII interface.
3.7.2.2 MDIO/MDC PHY Management Interface
The I210 implements an IEEE 802.3 MII Management Interface, also known as the Management Data
Input/Output (MDIO) or MDIO interface, between the MAC and a PHY. This interface provides the MAC
and software the ability to monitor and control the state of the PHY. The MDIO interface defines a
physical connection, a special protocol that runs across the connection, and an internal set of
addressable registers. The interface consists of a data line (MDIO) and clock line (MDC), which are
accessible by software via the MAC register space.
Management Data Clock (MDC): This signal is used by the PHY as a clock timing reference for
information transfer on the MDIO signal. The MDC is not required to be a continuous signal and can
be frozen when no management data is transferred. The MDC signal has a maximum operating
frequency of 2.5 MHz.
MDIO: This bi-directional signal between the MAC and PHY is used to transfer control and status
information to and from the PHY (to read and write the PHY management registers).
Software can use MDIO accesses to read or write registers of the internal PHY, internal SerDes, or an
external SGMII PHY, by accessing the I210's MDIC register (refer to Section 8.2.4). MDIO configuration
setup (internal/ External PHY, PHY Address and Shared MDIO) is defined in the MDICNFG register (refer
to Section 8.2.5). By selecting Page 26 via PHYREG 22 register, internal SerDes registers can be
accessed.
When working in SGMII/SerDes mode, the external PHY (if it exists) can be accessed either through
MDC/MDIO as previously described, or via a two wire I2C interface bus using the I2CCMD register (refer
to Section 8.17.8). The two wire I2C interface bus or the MDC/MDIO bus are connected via the same
pins, and thus are mutually exclusive. In order to be able to control an external device, either by I2C or
MDC/MDIO, the 2-wires SFP Enable bit in Initialization Control 3 Flash word, that’s loaded into the
CTRL_EXT.I2C Enabled register bit, should be set.
As the MDC/MDIO command can be targeted either to the internal PHY or to an external bus, the
MDICNFG.destination bit is used to define the target of the transaction. Following reset, the value of the
MDICNFG.destination bit is loaded from the External MDIO bit in the Initialization Control 3 Flash word.
When the MDICNFG.destination is clear, the MDIO access is always to the internal PHY and the PHY
address is ignored.
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The external port PHY address is written in the MDICNFG.PHYADD register field, which is loaded from
the Initialization Control 4 Flash word following reset.
Note: When the dedicated SFPx_I2C pins are not used for I2C, an alternative I2C interface bus can
be run over SDP 0 and SDP2 pins, using the I2CCMD register set (refer to Section 3.5.2).
3.7.2.2.1 Detecting an External I2C or MDIO Connection
When the CTRL_EXT.I2C Enabled bit is set to 1b, software can recognize type of external PHY control
bus (MDIO or I2C) connection according to the values loaded from the Flash to the
MDICNFG.Destination bit and the CTRL_EXT.LINK_MODE field in the following manner:
External I2C operating mode - MDICNFG.Destination equals 0b and CTRL_EXT.LINK_MODE is not
equal to 0b.
External MDIO Operating mode - MDICNFG.Destination equals 1b and CTRL_EXT.LINK_MODE is not
equal to 0b.
3.7.2.2.2 MDIC and MDICNFG Register Usage
For a MDIO read cycle, the sequence of events is as follows:
1. If default MDICNFG register values loaded from Flash need to be updated. The processor performs
a PCIe write access to the MDICNFG register to define the:
PHYADD = Address of external PHY.
Destination = Internal or external PHY.
2. The processor performs a PCIe write cycle to the MDIC register with:
Ready = 0b
Interrupt Enable set to 1b or 0b
Opcode = 10b (read)
REGADD = Register address of the specific register to be accessed (0 through 31).
3. The MAC applies the following sequence on the MDIO signal to the PHY:
<PREAMBLE><01><10><PHYADD><REGADD><Z> where Z stands for the MAC tri-stating the
MDIO signal.
4. The PHY returns the following sequence on the MDIO signal<0><DATA><IDLE>.
5. The MAC discards the leading bit and places the following 16 data bits in the MII register.
6. The I210 asserts an interrupt indicating MDIO Done if the Interrupt Enable bit was set.
7. The I210 sets the Ready bit in the MDIC register indicating the read completed.
8. The processor might read the data from the MDIC register and issue a new MDIO command.
For a MDIO write cycle, the sequence of events is as follows:
1. If default MDICNFG register values loaded from Flash need to be updated. The processor performs
a PCIe write cycle to the MDICNFG register to define the:
PHYADD = Address of external PHY.
Destination = Internal or external PHY.
2. The processor performs a PCIe write cycle to the MDIC register with:
Ready = 0b.
Interrupt Enable set to 1b or 0b.
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Opcode = 01b (write).
REGADD = Register address of the specific register to be accessed (0 through 31).
Data = Specific data for desired control of the PHY.
3. The MAC applies the following sequence on the MDIO signal to the PHY:
<PREAMBLE><01><01><PHYADD><REGADD><10><DATA><IDLE>
4. The I210 asserts an interrupt indicating MDIO Done if the Interrupt Enable bit was set.
5. The I210 sets the Ready bit in the MDIC register to indicate that the write operation completed.
6. The CPU might issue a new MDIO command.
Note: A MDIO read or write might take as long as 64 s from the processor write to the Ready bit
assertion.
If an invalid opcode is written by software, the MAC does not execute any accesses to the PHY
registers.
If the PHY does not generate a 0b as the second bit of the turn-around cycle for reads, the MAC aborts
the access, sets the E (error) bit, writes 0xFFFF to the data field to indicate an error condition, and sets
the Ready bit.
Note: After a PHY reset, access through the MDIC register should not be attempted for 300 s.
3.7.2.3 Duplex Operation with Copper PHY
The I210 supports half-duplex and full-duplex 10/100 Mb/s MII mode either through an internal copper
PHY or SGMII interface. However, only full-duplex mode is supported when SerDes/1000BASE-BX or
1000BASE-KX modes are used or in any 1000 Mb/s connection.
Configuring the I210 duplex operation can either be forced or determined via the auto-negotiation
process. Refer to Section 3.7.4.4 for details on link configuration setup and resolution.
3.7.2.3.1 Full Duplex
All aspects of the IEEE 802.3, 802.3u, 802.3z, and 802.3ab specifications are supported in full-duplex
operation. Full-duplex operation is enabled by several mechanisms, depending on the speed
configuration of the I210 and the specific capabilities of the link partner used in the application. During
full-duplex operation, the I210 can transmit and receive packets simultaneously across the link
interface.
In full-duplex, transmission and reception are delineated independently by the GMII/MII control
signals. Transmission starts TX_EN is asserted, which indicates there is valid data on the TX_DATA bus
driven from the MAC to the PHY/PCS. Reception is signaled by the PHY/PCS by the asserting the RX_DV
signal, which indicates valid receive data on the RX_DATA lines to the MAC.
3.7.2.3.2 Half Duplex
In half-duplex operation, the MAC attempts to avoid contention with other traffic on the link by
monitoring the CRS signal provided by the PHY and deferring to passing traffic. When the CRS signal is
de-asserted or after a sufficient Inter-Packet Gap (IPG) has elapsed after a transmission, frame
transmission begins. The MAC signals the PHY/PCS with TX_EN at the start of transmission.
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In the case of a collision, the PHY/SGMII detects the collision and asserts the COL signal to the MAC.
Frame transmission stops within four link clock times and then the I210 sends a JAM sequence onto the
link. After the end of a collided transmission, the I210 backs off and attempts to re-transmit per the
standard CSMA/CD method.
Note: The re-transmissions are done from the data stored internally in the I210 MAC transmit
packet buffer (no re-access to the data in host memory is performed).
The MAC behavior is different if a regular collision or a late collision is detected. If a regular collision is
detected, the MAC always tries to re-transmit until the number of excessive collisions is reached. In
case of late collision, the MAC retransmission is configurable. In addition, statistics are gathered on late
collisions.
In the case of a successful transmission, the I210 is ready to transmit any other frame(s) queued in the
MAC's transmit FIFO, after the minimum inter-frame spacing (IFS) of the link has elapsed.
During transmit, the PHY is expected to signal a carrier-sense (assert the CRS signal) back to the MAC
before one slot time has elapsed. The transmission completes successfully even if the PHY fails to
indicate CRS within the slot time window. If this situation occurs, the PHY can either be configured
incorrectly or be in a link down situation. Such an event is counted in the transmit without CRS statistic
register (refer to Section 8.18.12).
When operating in half duplex mode, the elasticity FIFO in the PHY should be programmed to its
minimum size by setting the Copper Transmit FIFO Depth field to 00b (depth of 16 bits). See
Section 8.27.3.23).
3.7.3 SerDes/1000BASE-BX, SGMII and 1000BASE-KX Support
The I210 can be configured to follow either SGMII, SerDes/1000BASE-BX or 1000BASE-KX standards.
When in SGMII mode, the I210 can be configured to operate in 1 Gb/s, 100 Mb/s or 10 Mb/s speeds.
When in the 10/100 Mb/s speed, the I210 can be configured to half-duplex mode of operation. When
configured for SerDes/1000BASE-BX or 1000BASE-KX operation, the port supports only 1 Gb/s, full-
duplex operation. Since the serial interfaces are defined as differential signals, internally the hardware
has analog and digital blocks. Following is the initialization/configuration sequence for the analog and
digital blocks.
3.7.3.1 SerDes/1000BASE-BX, SGMII and 1000BASE-KX Analog Block
The analog block might require some changes to its configuration registers in order to work properly.
There is no special requirement for designers to do these changes as the hardware internally updates
the configuration using a default sequence or a sequence loaded from the Flash.
3.7.3.2 SerDes/1000BASE-BX, SGMII and 1000BASE-KX PCS Block
The link setup for SerDes/1000BASE-BX, 1000BASE-KX and SGMII are described in sections 3.7.4.1,
3.7.4.2 and 3.7.4.3 respectively.
3.7.3.3 GbE Physical Coding Sub-Layer (PCS)
The I210 integrates the 802.3z PCS function on-chip. The on-chip PCS circuitry is used when the link
interface is configured for SerDes/1000BASE-BX, 1000BASE-KX or SGMII operation and is bypassed for
internal PHY mode.
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The packet encapsulation is based on the Fiber Channel (FC0/FC1) physical layer and uses the same
coding scheme to maintain transition density and DC balance. The physical layer device is the SerDes
and is used for 1000BASE-SX, -L-, or -CX configurations.
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3.7.3.3.1 8B10B Encoding/Decoding
The GbE PCS circuitry uses the same transmission-coding scheme used in the fiber channel physical
layer specification. The 8B10B-coding scheme was chosen by the standards committee in order to
provide a balanced, continuous stream with sufficient transition density to allow for clock recovery at
the receiving station. There is a 25% overhead for this transmission code, which accounts for the data-
signaling rate of 1250 Mb/s with 1000 Mb/s of actual data.
3.7.3.3.2 Code Groups and Ordered Sets
Code group and ordered set definitions are defined in clause 36 of the IEEE 802.3z standard. These
represent special symbols used in the encapsulation of GbE packets. The following table contains a brief
description of defined ordered sets and included for informational purposes only. Refer to clause 36 of
the IEEE 802.3z specification for more details.
Table 3-23. Brief Description of Defined Ordered Sets
Code Ordered_Set # of Code
Groups Usage
/C/ Configuration 4
General reference to configuration ordered sets, either /C1/ or /C2/, which
is used during auto-negotiation to advertise and negotiate link operation
information between link partners. Last 2 code groups contain
configuration base and next page registers.
/C1/ Configuration 1 4 See /C/. Differs from /C2/ in 2nd code group for maintaining proper
signaling disparity1.
1. The concept of running disparity is defined in the standard. In summary, this refers to the 1-0 and 0-1 transitions within 8B10B
code groups.
/C2/ Configuration 2 4 See /C/. Differs from /C1/ in 2nd code group for maintaining proper
signaling disparity1.
/I/ IDLE 2
General reference to idle ordered sets. Idle characters are continually
transmitted by the end stations and are replaced by encapsulated packet
data. The transitions in the idle stream enable the SerDes to maintain
clock and symbol synchronization between link partners.
/I1/ IDLE 1 2 See /I/. Differs from /I2/ in 2nd code group for maintaining proper
signaling disparity1.
/I2/ IDLE 2 2 See /I/. Differs from /I1/ in 2nd code group for maintaining proper
signaling disparity1.
/R/ Carrier_Extend 1 This ordered set is used to indicate carrier extension to the receiving PCS.
It is also used as part of the end_of_packet encapsulation delimiter as well
as IPG for packets in a burst of packets.
/S/ Start_of_Packet 1 The SPD (start_of_packet delimiter) ordered set is used to indicate the
starting boundary of a packet transmission. This symbol replaces the last
byte of the preamble received from the MAC layer.
/T/ End_of_Packet 1 The EPD (end_of_packet delimiter) is comprised of three ordered sets. The
/T/ symbol is always the first of these and indicates the ending boundary
of a packet.
/V/ Error_Propagation 1 The /V/ ordered set is used by the PCS to indicate error propagation
between stations. This is normally intended to be used by repeaters to
indicate collisions.
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3.7.4 Auto-Negotiation and Link Setup Features
The method for configuring the link between two link partners is highly dependent on the mode of
operation as well as the functionality provided by the specific physical layer device (PHY or SerDes). In
SerDes/1000BASE-BX mode, the I210 provides the complete PCS and Auto-negotiation functionality as
defined in IEEE802.3 clause 36 and clause 37. In internal PHY mode, the PCS and IEEE802.3 clause 28
and clause 40 auto-negotiation functions are maintained within the PHY. In SGMII mode, the I210
supports the SGMII link auto-negotiation process, whereas the link auto-negotiation, as defined in
IEEE802.3 clause 28 and clause 40, is done by the external PHY. In 1000BASE-KX mode, the I210
supports only parallel detect of 1000BASE-KX signaling and does not support the full Auto-Negotiation
for Backplane Ethernet protocol as defined in IEEE802.3ap clause 73.
Configuring the link can be accomplished by several methods ranging from software forcing link
settings, software-controlled negotiation, MAC-controlled auto-negotiation, to auto-negotiation initiated
by a PHY. The following sections describe processes of bringing the link up including configuration of the
I210 and the transceiver, as well as the various methods of determining duplex and speed
configuration.
The process of determining link configuration differs slightly based on the specific link mode (internal
PHY, SerDes/1000BASE-BX, SGMII or 1000BASE-KX) being used.
When operating in a SerDes/1000BASE-BX mode, the PCS layer performs auto-negotiation per clause
37 of the 802.3z standard. The transceiver used in this mode does not participate in the auto-
negotiation process as all aspects of auto-negotiation are controlled by the I210.
When operating in internal PHY mode, the PHY performs auto-negotiation per 802.3ab clause 40 and
extensions to clause 28. Link resolution is obtained by the MAC from the PHY after the link has been
established. The MAC accomplishes this via the MDIO interface, via specific signals from the internal
PHY to the MAC, or by MAC auto-detection functions.
When operating in SGMII mode, the PCS layer performs SGMII auto-negotiation per the SGMII
specification. The external PHY is responsible for the Ethernet auto-negotiation process.
When operating in 1000BASE-KX mode the I210 performs parallel detect of 1000BASE-KX operation
but does not implement the full auto-negotiation for backplane Ethernet sequence as defined in
IEEE802.3ap clause 73.
3.7.4.1 SerDes/1000BASE-BX Link Configuration
When using SerDes/1000BASE-BX link mode, link mode configuration can be performed using the PCS
function in the I210. The hardware supports both hardware and software auto-negotiation methods for
determining the link configuration, as well as allowing for a manual configuration to force the link.
Hardware auto-negotiation is the preferred method.
3.7.4.1.1 Signal Detect Indication
When the CONNSW.ENRGSRC bit is set to 1b, the SRDS_SIG_DET pins can be connected to a Signal
Detect or loss-of-signal (LOS) output of the optical module that indicates when no laser light is being
received when the I210 is used in a 1000BASE-SX or -LX implementation (SerDes operation). No
standard polarity for the signal detect or loss-of-signal driven from different manufacturer optical
modules exists. The CTRL.ILOS bit provides the capability to invert the signal from different external
optical module vendors, and should be set when the external optical module provides a negative-true
loss-of-signal.
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Note: In internal PHY, SGMII, 1000BASE-BX and 1000BASE-KX connections, energy detect source is
always internal and value of CONNSW.ENRGSRC bit should be 0b. The CTRL.ILOS bit also
inverts the internal link-up input that provides link status indication and thus should be set to
0b for proper operation.
3.7.4.1.2 MAC Link Speed
SerDes/1000BASE-BX operation is only defined for 1000 Mb/s operation. Other link speeds are not
supported. When configured for the SerDes interface, the MAC speed-determination function is disabled
and the Device Status register bits (STATUS.SPEED) indicate a value of 10b for 1000 Mb/s.
3.7.4.1.3 SerDes/1000BASE-BX Mode Auto-Negotiation
In SerDes/1000BASE-BX mode, after power up or the I210 reset via PE_RST_N, the I210 initiates
IEEE802.3 clause 37 auto-negotiation based on the default settings in the device control and transmit
configuration or PCS Link Control Word registers, as well as settings read from the Flash. If enabled in
the Flash, the I210 immediately performs auto-negotiation.
TBI mode auto-negotiation, as defined in clause 37 of the IEEE 802.3z standard, provides a protocol for
two devices to advertise and negotiate a common operational mode across a GbE link. The I210 fully
supports the IEEE 802.3z auto-negotiation function when using the on-chip PCS and internal SerDes.
TBI mode auto-negotiation is used to determine the following information:
Duplex resolution (even though the I210 MAC only supports full-duplex in SerDes/1000BASE-BX
mode).
Flow control configuration.
Note: Since speed for SerDes/1000BASE-BX modes is fixed at 1000 Mb/s, speed settings in the
Device Control register are unaffected by the auto-negotiation process.
Note: Auto-negotiation can be initiated at power up or by asserting PE_RST_N and enabling specific
bits in the Flash.
The auto-negotiation process is accomplished by the exchange of /C/ ordered sets that contain the
capabilities defined in the PCS_ANADV register in the 3rd and 4th symbols of the ordered sets. Next
page are supported using the PCS_NPTX_AN register.
Bits FD and LU in the Device Status (STATUS) register, and bits in the PCS_LSTS register provide status
information regarding the negotiated link.
Auto-negotiation can be initiated by the following:
PCS_LCTL.AN_ENABLE transition from 0b to 1b
Receipt of /C/ ordered set during normal operation
Receipt of a different value of the /C/ ordered set during the negotiation process
Transition from loss of synchronization to synchronized state (if AN_ENABLE is set).
PCS_LCTL.AN_RESTART transition from 0b to 1b
Resolution of the negotiated link determines device operation with respect to flow control capability and
duplex settings. These negotiated capabilities override advertised and software-controlled device
configuration.
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Software must configure the PCS_ANADV fields to the desired advertised base page. The bits in the
Device Control register are not mapped to the txConfigWord field in hardware until after auto-
negotiation completes. Table 3-24 lists the mapping of the PCS_ANADV fields to the Config_reg Base
Page encoding per clause 37 of the standard.
The partner advertisement can be seen in the PCS_LPAB and PCS_LPABNP registers.
3.7.4.1.4 Forcing Link-up in SerDes/1000BASE-BX Mode
Forcing link can be accomplished by software by writing a 1b to CTRL.SLU, which forces the MAC PCS
logic into a link-up state (enables listening to incoming characters when SRDS_[n]_SIG_DET is
asserted by the external optical module or an equivalent signal is asserted by the internal PHY).
Note: The PCS_LCTL.AN_ENABLE bit must be set to a logic zero to enable forcing link.
When link is forced via the CTRL.SLU bit, the link does not come up unless the
SRDS_[n]_SIG_DET signal is asserted or an internal energy indication is received from the
SerDes receiver, implying that there is a valid signal being received by the optical module or
SerDes circuitry.
The source of the signal detect is defined by the ENRGSRC bit in the CONNSW register.
3.7.4.1.5 Hardware Detection of Non-Auto-Negotiation Partner
Hardware can detect a SerDes link partner that sends idle code groups continuously, but does not
initiate or answer an auto-negotiation process. In this case, hardware initiates an auto-negotiation
process, and if it fails after some timeout, a link up is assumed. To enable this functionality the
PCS_LCTL.AN_TIMEOUT_EN bit should be set. This mode can be used instead of the force link mode as
a way to support a partner that do not support auto-negotiation.
3.7.4.2 1000BASE-KX Link Configuration
When using 1000BASE-KX link mode, link mode configuration is forced manually by software since the
I210 does not support IEEE802.3 clause 73 backplane auto-negotiation.
3.7.4.2.1 MAC Link Speed
1000BASE-KX operation is only defined for 1000 Mb/s operation. Other link speeds are not supported.
When configured for the 1000BASE-KX interface, the MAC speed-determination function is disabled and
the Device Status register bits (STATUS.SPEED) indicate a value of 10b for 1000 Mb/s.
3.7.4.2.2 1000BASE-KX Auto-Negotiation
The I210 only supports parallel detection of the 1000BASE-KX link and does not support the full
IEEE802.3ap clause 73 backplane auto-negotiation protocol.
Table 3-24. 802.3z Advertised Base Page Mapping
15 14 13:12 11:9 8:7 6 5 4:0
Nextp Ack RFLT rsv ASM Hd Fd rsv
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3.7.4.2.3 Forcing Link-up in 1000BASE-KX Mode
In 1000BASE-KX mode (EXT_CTRL.LINK_MODE = 01b) the I210 should always operates in force link
mode (CTRL.SLU bit is set to 1b). The MAC PCS logic is placed in a link-up state once energy indication
is received, implying that a valid signal is being received by the 1000BASE-KX circuitry. When in the
link-up state PCS logic can lock on incoming characters.
Note: In 1000BASE-KX mode energy detect source is internal and value of CONNSW.ENRGSRC bit
should be 0b. Clause 37 auto-negotiation should be disabled and the value of the
PCS_LCTL.AN_ENABLE bit and PCS_LCTL.AN TIMEOUT EN bit should be 0b.
3.7.4.2.4 1000BASE-KX Hardware Detection of Link Partner
In 1000BASE-KX mode, hardware detects a 1000BASE-KX link partner that sends idle or none idle code
groups continuously. In 1000BASE-KX operation force link-up mode is used.
3.7.4.3 SGMII Link Configuration
When working in SGMII mode, the actual link setting is done by the external PHY and is dependent on
the settings of this PHY. The SGMII auto-negotiation process described in the sections that follow is
only used to establish the MAC/PHY connection.
3.7.4.3.1 SGMII Auto-Negotiation
This auto-negotiation process is not dependent on the SRDS_[n]_SIG_DET signal and the
CONNSW.ENRGSRC bit should be 0b, as this signal indicates optical module signal detection and is not
relevant in SGMII mode.
The outcome of this auto-negotiation process includes the following information:
Link status
Speed
Duplex
This information is used by hardware to configure the MAC, when operating in SGMII mode.
Bits FD and LU of the Device Status (STATUS) register and bits in the PCS_LSTS register provide status
information regarding the negotiated link.
Auto-negotiation can be initiated by the following:
PCS_LCTL.AN_ENABLE transition from 0b to 1b.
Receipt of /C/ ordered set during normal operation.
Receipt of different value of the /C/ ordered set during the negotiation process.
Transition from loss of synchronization to a synchronized state (if AN_ENABLE is set).
PCS_LCTL.AN_RESTART transition from 0b to 1b.
Auto-negotiation determines the I210 operation with respect to speed and duplex settings. These
negotiated capabilities override advertised and software controlled device configuration.
When working in SGMII mode, there is no need to set the PCAS_ANADV register, as the MAC
advertisement word is fixed. In SGMII mode the PCS_LCTL.AN TIMEOUT EN bit should be 0b, since
auto-negotiation outcome is required for correct operation. The result of the SGMII level auto-
negotiation can be read from the PCS_LPAB register.
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3.7.4.3.2 Forcing Link in SGMII Mode
In SGMII, forcing of the link cannot be done at the PCS level, only in the external PHY. The forced
speed and duplex settings are reflected by the SGMII auto-negotiation process; the MAC settings are
automatically done according to this functionality.
3.7.4.3.3 MAC Speed Resolution
The MAC speed and duplex settings are always set according to the SGMII auto-negotiation process.
3.7.4.4 Copper PHY Link Configuration
When operating with the internal PHY, link configuration is generally determined by PHY auto-
negotiation. The software device driver must intervene in cases where a successful link is not
negotiated or the designer desires to manually configure the link. The following sections discuss the
methods of link configuration for copper PHY operation.
3.7.4.4.1 PHY Auto-Negotiation (Speed, Duplex, Flow Control)
When using a copper PHY, the PHY performs the auto-negotiation function. The actual operational
details of this operation are described in the IEEE P802.3ab draft standard and are not included here.
Auto-negotiation provides a method for two link partners to exchange information in a systematic
manner in order to establish a link configuration providing the highest common level of functionality
supported by both partners. Once configured, the link partners exchange configuration information to
resolve link settings such as:
Speed: - 10/100/1000 Mb/s
Duplex: - Full or half
Flow control operation
PHY specific information required for establishing the link is also exchanged.
Note: If flow control is enabled in the I210, the settings for the desired flow control behavior must
be set by software in the PHY registers and auto-negotiation restarted. After auto-negotiation
completes, the software device driver must read the PHY registers to determine the resolved
flow control behavior of the link and reflect these in the MAC register settings (CTRL.TFCE
and CTRL.RFCE).
Once PHY auto-negotiation completes, the PHY asserts a link indication (LINK) to the MAC.
Software must have set the Set Link Up bit in the Device Control register (CTRL.SLU) before
the MAC recognizes the LINK indication from the PHY and can consider the link to be up.
3.7.4.4.2 MAC Speed Resolution
For proper link operation, both the MAC and PHY must be configured for the same speed of link
operation. The speed of the link can be determined and set by several methods with the I210. These
include:
Software-forced configuration of the MAC speed setting based on PHY indications, which might be
determined as follows:
Software reads of PHY registers directly to determine the PHY's auto-negotiated speed
Software reads the PHY's internal PHY-to-MAC speed indication (SPD_IND) using the MAC
STATUS.SPEED register
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Software asks the MAC to attempt to auto-detect the PHY speed from the PHY-to-MAC RX_CLK,
then programs the MAC speed accordingly
MAC automatically detects and sets the link speed of the MAC based on PHY indications by using
the PHY's internal PHY-to-MAC speed indication (SPD_IND)
Aspects of these methods are discussed in the sections that follow.
3.7.4.4.2.1 Forcing MAC Speed
There might be circumstances when the software device driver must forcibly set the link speed of the
MAC. This can occur when the link is manually configured. To force the MAC speed, the software device
driver must set the CTRL.FRCSPD (force-speed) bit to 1b and then write the speed bits in the Device
Control register (CTRL.SPEED) to the desired speed setting. Refer to Section 8.2.1 for details.
Note: Forcing the MAC speed using CTRL.FRCSPD overrides all other mechanisms for configuring
the MAC speed and can yield non-functional links if the MAC and PHY are not operating at the
same speed/configuration.
When forcing the I210 to a specific speed configuration, the software device driver must also ensure
the PHY is configured to a speed setting consistent with MAC speed settings. This implies that software
must access the PHY registers to either force the PHY speed or to read the PHY status register bits that
indicate link speed of the PHY.
Note: Forcing speed settings by CTRL.SPEED can also be accomplished by setting the
CTRL_EXT.SPD_BYPS bit. This bit bypasses the MAC's internal clock switching logic and
enables the software device driver complete control of when the speed setting takes place.
The CTRL.FRCSPD bit uses the MAC's internal clock switching logic, which does delay the
effect of the speed change.
3.7.4.4.2.2 Using Internal PHY Direct Link-Speed Indication
The I210’s internal PHY provides a direct internal indication of its speed to the MAC (SPD_IND). When
using the internal PHY, the most direct method for determining the PHY link speed and either manually
or automatically configuring the MAC speed is based on these direct speed indications.
For MAC speed to be set/determined from these direct internal indications from the PHY, the MAC must
be configured such that CTRL.ASDE and CTRL.FRCSPD are both 0b (both auto-speed detection and
forced-speed override disabled). After configuring the Device Control register, MAC speed is re-
configured automatically each time the PHY indicates a new link-up event to the MAC.
When MAC speed is neither forced nor auto-sensed by the MAC, the current MAC speed setting and the
speed indicated by the PHY is reflected in the Device Status register bits STATUS.SPEED.
3.7.4.4.3 MAC Full-/Half- Duplex Resolution
The duplex configuration of the link is also resolved by the PHY during the auto-negotiation process.
The I210’s internal PHY provides an internal indication to the MAC of the resolved duplex configuration
using an internal full-duplex indication (FDX).
When using the internal PHY, this internal duplex indication is normally sampled by the MAC each time
the PHY indicates the establishment of a good link (LINK indication). The PHY's indicated duplex
configuration is applied in the MAC and reflected in the MAC Device Status register (STATUS.FD).
Software can override the duplex setting of the MAC via the CTRL.FD bit when the CTRL.FRCDPLX
(force duplex) bit is set. If CTRL.FRCDPLX is 0b, the CTRL.FD bit is ignored and the PHY's internal
duplex indication is applied.
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3.7.4.4.4 Using PHY Registers
The software device driver might be required under some circumstances to read from, or write to, the
MII management registers in the PHY. These accesses are performed via the MDIC register (refer to
Section 8.2.4). The MII registers enable the software device driver to have direct control over the PHY's
operation, which can include:
Resetting the PHY
Setting preferred link configuration for advertisement during the auto-negotiation process
Restarting the auto-negotiation process
Reading auto-negotiation status from the PHY
Forcing the PHY to a specific link configuration
The set of PHY management registers required for all PHY devices can be found in the IEEE P802.3ab
standard.
3.7.4.4.5 Comments Regarding Forcing Link
Forcing link in GMII/MII mode (internal PHY) requires the software device driver to configure both the
MAC and PHY in a consistent manner with respect to each other as well as the link partner. After
initialization, the software device driver configures the desired modes in the MAC, then accesses the
PHY registers to set the PHY to the same configuration.
Before enabling the link, the speed and duplex settings of the MAC can be forced by software using the
CTRL.FRCSPD, CTRL.FRCDPX, CTRL.SPEED, and CTRL.FD bits. After the PHY and MAC have both been
configured, the software device driver should write a 1b to the CTRL.SLU bit.
3.7.4.5 Loss of Signal/Link Status Indication
For all modes of operation, a LOS/LINK signal provides an indication of physical link status to the MAC.
When the MAC is configured for optical SerDes mode, the input reflects loss-of-signal connection from
the optics. In backplane mode, where there is no LOS external indication, an internal indication from
the SerDes receiver can be used. In SFP systems the LOS indication from the SFP can be used. In
internal PHY mode, this signal from the PHY indicates whether the link is up or down; typically indicated
after successful auto-negotiation. Assuming that the MAC has been configured with CTRL.SLU=1b, the
MAC status bit STATUS.LU, when read, generally reflects whether the PHY or SerDes has link (except
under forced-link setup where even the PHY link indication might have been forced).
When the link indication from the PHY is de-asserted or the loss-of-signal asserted from the SerDes, the
MAC considers this to be a transition to a link-down situation (such as cable unplugged, loss of link
partner, etc.). If the Link Status Change (LSC) interrupt is enabled, the MAC generates an interrupt to
be serviced by the software device driver.
3.7.5 Ethernet Flow Control (FC)
The I210 supports flow control as defined in 802.3x as well as the specific operation of asymmetrical
flow control defined by 802.3z.
Flow control is implemented as a means of reducing the possibility of receive packet buffer overflows,
which result in the dropping of received packets, and allows for local controlling of network congestion
levels. This can be accomplished by sending an indication to a transmitting station of a nearly full
receive buffer condition at a receiving station.
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The implementation of asymmetric flow control allows for one link partner to send flow control packets
while being allowed to ignore their reception. For example, not required to respond to PAUSE frames.
The following registers are defined for the implementation of flow control:
CTRL.RFCE field is used to enable reception of legacy flow control packets and reaction to them
CTRL.TFCE field is used to enable transmission of legacy flow control packets
Flow Control Address Low, High (FCAL/H) - 6-byte flow control multicast address
Flow Control Type (FCT) 16-bit field to indicate flow control type
Flow Control bits in Device Control (CTRL) register - Enables flow control modes
Discard PAUSE Frames (DPF) and Pass MAC Control Frames (PMCF) in RCTL - controls the
forwarding of control packets to the host
Flow Control Receive Threshold High (FCRTH0) - A 13-bit high watermark indicating receive buffer
fullness. A single watermark is used in link FC mode.
DMA Coalescing Receive Threshold High (FCRTC) - A 13-bit high watermark indicating receive
buffer fullness when in DMA coalescing and Tx buffer is empty. The value in this register can be
higher than value placed in the FCRTH0 register since the watermark needs to be set to allow for
only receiving a maximum sized Rx packet before XOFF flow control takes effect and reception is
stopped (refer to Table 3-28 for information on flow control threshold calculation).
Flow Control Receive Threshold Low (FCRTL0) - A 13-bit low watermark indicating receive buffer
emptiness. A single watermark is used in link FC mode.
Flow Control Transmit Timer Value (FCTTV) - a set of 16-bit timer values to include in transmitted
PAUSE frame. A single timer is used in Link FC mode
Flow Control Refresh Threshold Value (FCRTV) - 16-bit PAUSE refresh threshold value
RXPBSIZE.Rxpbsize field is used to control the size of the receive packet buffer
3.7.5.1 MAC Control Frames and Receiving Flow Control Packets
3.7.5.1.1 Structure of 802.3X FC Packets
Three comparisons are used to determine the validity of a flow control frame:
1. A match on the 6-byte multicast address for MAC control frames or to the station address of the
I210 (Receive Address Register 0).
2. A match on the type field.
3. A comparison of the MAC Control Op-Code field.
The 802.3x standard defines the MAC control frame multicast address as 01-80-C2-00-00-01.
The Type field in the FC packet is compared against an IEEE reserved value of 0x8808.
The final check for a valid PAUSE frame is the MAC control op-code. At this time only the PAUSE control
frame op-code is defined. It has a value of 0x0001.
Frame-based flow control differentiates XOFF from XON based on the value of the PAUSE timer field.
Non-zero values constitute XOFF frames while a value of zero constitutes an XON frame. Values in the
Timer field are in units of pause quantum (slot time). A pause quantum lasts 64 byte times, which is
converted in absolute time duration according to the line speed.
Note: XON frame signals the cancellation of the pause from initiated by an XOFF frame - pause for
zero pause quantum.
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Table 3-25 lists the structure of a 802.3X FC packet.
3.7.5.1.2 Operation and Rules
The I210 operates in Link FC.
Link FC is enabled by the RFCE bit in the CTRL register.
Note: Link flow control capability is negotiated between link partners via the auto negotiation
process. It is the software device driver responsibility to reconfigure the link flow control
configuration after the capabilities to be used where negotiated as it might modify the value
of these bits based on the resolved capability between the local device and the link partner.
Once the receiver has validated receiving an XOFF, or PAUSE frame, the I210 performs the following:
Increments the appropriate statistics register(s)
Sets the Flow_Control State bit in the FCSTS0 register.
Initializes the pause timer based on the packet's PAUSE timer field (overwriting any current timer’s
value)
Disables packet transmission or schedules the disabling of transmission after the current packet
completes.
Resumption of transmission might occur under the following conditions:
Expiration of the PAUSE timer
Receiving an XON frame (a frame with its PAUSE timer set to 0b)
Both conditions clear the relevant Flow_Control State bit in the relevant FCSTS0 register and
transmission can resume. Hardware records the number of received XON frames.
3.7.5.1.3 Timing Considerations
When operating at 1 Gb/s line speed, the I210 must not begin to transmit a (new) frame more than two
pause-quantum-bit times after receiving a valid link XOFF frame, as measured at the wires. A pause
quantum is 512-bit times.
When operating in full duplex at 10 Mb/s or at 100 Mb/s line speeds, the I210 must not begin to
transmit a (new) frame more than 576-bit times after receiving a valid link XOFF frame, as measured at
the wire.
Table 3-25. 802.3X Packet Format
DA 01_80_C2_00_00_01 (6 bytes)
SA Port MAC address (6 bytes)
Type 0x8808 (2 bytes)
Op-code 0x0001 (2 bytes)
Time XXXX (2 bytes)
Pad 42 bytes
CRC 4 bytes
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3.7.5.2 PAUSE and MAC Control Frames Forwarding
Two bits in the Receive Control register, control forwarding of PAUSE and MAC control frames to the
host. These bits are Discard PAUSE Frames (DPF) and Pass MAC Control Frames (PMCF):
The DPF bit controls forwarding of PAUSE packets to the host.
The PMCF bit controls forwarding of non-PAUSE packets to the host.
Note: When flow control reception is disabled (CTRL.RFCE = 0b), legacy flow control packets are not
recognized and are parsed as regular packets.
Table 3-26 lists the behavior of the DPF bit.
Table 3-27 defines the behavior of the PMCF bit.
3.7.5.3 Transmission of PAUSE Frames
The I210 generates PAUSE packets to ensure there is enough space in its receive packet buffers to
avoid packet drop. The I210 monitors the fullness of its receive packet buffers and compares it with the
contents of a programmable threshold. When the threshold is reached, the I210 sends a PAUSE frame.
The I210 supports the sending of link Flow Control (FC).
Note: Similar to receiving link flow control packets previously mentioned, link XOFF packets can be
transmitted only if this configuration has been negotiated between the link partners via the
auto-negotiation process or some higher level protocol. The setting of this bit by the software
device driver indicates the desired configuration.
The transmission of flow control frames should only be enabled in full-duplex mode per the
IEEE 802.3 standard. Software should ensure that the transmission of flow control packets is
disabled when the I210 is operating in half-duplex mode.
3.7.5.3.1 Operation and Rules
Transmission of link PAUSE frames is enabled by software writing a 1b to the TFCE bit in the Device
Control register.
Table 3-26. Forwarding of PAUSE Packet to Host (DPF Bit)
RFCE DPF Are FC Packets Forwarded to Host?
0 X Yes if pass the L2 filters (refer to Section 7.1.1.1).1
1. The flow control multicast address is not part of the L2 filtering unless explicitly required.
1 0 Yes.
1 1 No.
Table 3-27. Transfer of Non-PAUSE Control Packets to Host (PMCF Bit)
RFCE PMCF Are Non-FC MAC Control Packets Forwarded to Host?
0 X Yes if pass the L2 filters (refer to Section 7.1.1.1).
1 1 Yes.
1 0 No.
Ethernet Controller I210 —Interconnects
104
The I210 sends a PAUSE frame when Rx packet buffer is full above the high threshold defined in the
Flow Control Receive Threshold High (FCRT0.RTH) register field. When the threshold is reached, the
I210 sends a PAUSE frame with its pause time field equal to FCTTV. The threshold should be large
enough to overcome the worst case latency from the time that crossing the threshold is sensed until
packets are not received from the link partner. The Flow Control Receive Threshold High value should
be calculated as follows:
Flow Control Receive Threshold High = Internal Rx Buffer Size - (Threshold Cross to XOFF Transmission
+ Round-trip Latency + XOFF Reception to Link Partner response)
Parameter values to be used for calculating the FCRT0.RTH value are listed in Table 3-28.
Table 3-28. Flow Control Receive Threshold High (FCRTH0.RTH) Value Calculation
Note: When DMA Coalescing is enabled (DMACR.DMAC_EN = 1b),the value placed in the
FCRTC.RTH_Coal field should be equal or lower than:
FCRTC.RTH_Coal = FCRTH0.RTH + Max packet size * 1.25
The FCRTC.RTH_Coal is used as the high watermark to generate XOFF flow control packets when the
internal Tx buffer is empty and the I210 is executing DMA coalescing. In this case, no delay to
transmission of flow control packet exists so its possible to increase level of watermark before issuing a
XOFF flow control frame.
After transmitting a PAUSE frame, the I210 activates an internal shadow counter that reflects the link
partner pause timeout counter. When the counter reaches the value indicated in the FCRTV register,
then, if the PAUSE condition is still valid (meaning that the buffer fullness is still above the high
watermark), a XOFF message is sent again.
Once the receive buffer fullness reaches the low water mark, the I210 sends a XON message (a PAUSE
frame with a timer value of zero). Software enables this capability with the XONE field of FCRTL.
The I210 sends an additional PAUSE frame if it has previously sent one and the packet buffer overflows.
This is intended to minimize the amount of packets dropped if the first PAUSE frame did not reach its
target.
3.7.5.3.2 Software Initiated PAUSE Frame Transmission
The I210 has the added capability to transmit an XOFF frame via software. This is accomplished by
software writing a 1b to the SWXOFF bit of the Transmit Control register. Once this bit is set, hardware
initiates the transmission of a PAUSE frame in a manner similar to that automatically generated by
hardware.
The SWXOFF bit is self-clearing after the PAUSE frame has been transmitted.
Latency Parameter Affected by Parameter Value
Internal Rx Buffer Size Internal Tx buffer size. 60 KB - Internal Tx Buffer
Size.
Threshold Cross to XOFF
Transmission Max packet size. Max packet size * 1.25.
XOFF Reception to Link Partner
response Max packet size. Max packet size.
Round trip latency The latencies on the wire and the LAN devices at both
sides of the wire. 320-byte (for 1000Base-T
operation).
Interconnects—Ethernet Controller I210
105
Note: The Flow Control Refresh Threshold mechanism does not work in the case of software-
initiated flow control. Therefore, it is the software’s responsibility to re-generate PAUSE
frames before expiration of the pause counter at the other partner's end.
The state of the CTRL.TFCE bit or the negotiated flow control configuration does not affect software
generated PAUSE frame transmission.
Note: Software sends an XON frame by programming a 0b in the PAUSE timer field of the FCTTV
register. Software generating an XON packet is not allowed while the hardware flow control
mechanism is active, as both use the FCTTV registers for different purposes.
XOFF transmission is not supported in 802.3x for half-duplex links. Software should not
initiate an XOFF or XON transmission if the I210 is configured for half-duplex operation.
When flow control is disabled, pause packets (XON, XOFF, and other FC) are not detected as
flow control packets and can be counted in a variety of counters (such as multicast).
3.7.5.4 IPG Control and Pacing
The I210 supports the following modes of controlling IPG duration:
Fixed IPG - the IPG is extended by a fixed duration
3.7.5.4.1 Fixed IPG Extension
The I210 allows controlling of the IPG duration. The IPGT configuration field enables an extension of
IPG in 4-byte increments. One possible use of this capability is to enable inserting bytes into the
transmit packet after it has been transmitted by the I210 without violating the minimum IPG
requirements. For example, a security device connected in series to the I210 might add security
headers to transmit packets before the packets are transmitted on the network.
3.7.6 Loopback Support
3.7.6.1 General
The I210 supports the following types of internal loopback in the LAN interface:
MAC Loopback (Point 1)
PHY Loopback (Point 2)
SerDes, SGMII or 1000BASE-KX Loopback (Point 3)
External PHY Loopback (Point 4)
By setting the device to loopback mode, packets that are transmitted towards the line are looped back
to the host. The I210 is fully functional in these modes, just not transmitting data over the lines.
Figure 3-12 shows the points of loopback.
Ethernet Controller I210 —Interconnects
106
Figure 3-12. I210 Loopback Modes
In addition, The I210’s copper PHY support a far end loopback mode, where incoming traffic is reflected
at the PHy level onto the transmit wires. This mode is entered by setting bit 14 in PHY register Page 2,
Register 21.
3.7.6.2 MAC Loopback
In MAC loopback, the PHY and SerDes blocks are not functional and data is looped back before these
blocks.
3.7.6.2.1 Setting the I210 to MAC loopback Mode
The following procedure should be used to put the I210 in MAC loopback mode:
Set RCTL.LBM to 01b (bits 7:6)
Set CTRL.SLU (bit 6, should be set by default)
Set CTRL.FRCSPD and FRCDPLX (bits 11 and 12)
Set the CTRL.FD bit and program the CTRL.SPEED field to 10b (1 GbE).
Set EEER.EEE_FRC_AN to 1b to enable checking EEE operation in MAC loopback mode.
Filter configuration and other Tx/Rx processes are the same as in normal mode.
3.7.6.3 Internal PHY Loopback
In PHY loopback, the SerDes block is not functional and data is looped back at the end of the PHY
functionality. This means all the design, that is functional in copper mode, is involved in the loopback.
3.7.6.3.1 Setting the I210 to Internal PHY loopback Mode
The following procedure should be used to place the I210 in PHY loopback mode on the LAN port:
Set Link mode to Internal PHY: CTRL_EXT.LINK_MODE = 00b.
In the PHY control register (PHYREG 0,0 - Address 0 in the PHY):
Set duplex mode (bit 8)
Clear auto-negotiation enable bit (bit 12)
MAC
Packet Buffer
and DMA
SerDes
Interface
Internal
PHY
SerDes/
SGMII
1GbT
GMII
1
2
3
PCIe
4
Interconnects—Ethernet Controller I210
107
Set speed using bits 6 and 13. Register values should be:
For 10 Mb/s 0x4100
For 100 Mb/s 0x6100
For 1000 Mb/s 0x4140
Use bits 2:0 in PHYREG 2,21 to control the link speed in MDI loopback
reset the PHY – in PHYREG 0,0 Set Copper Reset bit (bit 15)
In PHYREG 0,0 Set loopback bit (bit 14)
3.7.6.4 SerDes, SGMII and 1000BASE-KX Loopback
In SerDes, SGMII or 1000BASE-KX loopback, the PHY block is not functional and data is looped back at
the end of the relevant functionality. This means all designs that are functional in SerDes/SGMII or
1000BASE-KX mode, are involved in the loopback.
Note: SerDes loopback is functional only if the SerDes link is up.
3.7.6.4.1 Setting the I210 to SerDes/1000BASE-BX, SGMII or 1000BASE-KX Loopback
Mode
The following procedure should be used to place the I210 in SerDes loopback mode:
Set Link mode to either SerDes, SGMII or 1000BASE-KX by:
1000BASE-KX: CTRL_EXT.LINK_MODE = 01b
SGMII: CTRL_EXT.LINK_MODE = 10b
SerDes/1000BASE-BX: CTRL_EXT.LINK_MODE = 11b
Configure SerDes to loopback: RCTL.LBM = 11b
Move to Force mode by setting the following bits:
CTRL.FD (CSR 0x0 bit 0) = 1b
CTRL.SLU (CSR 0x0 bit 6) = 1b
CTRL.RFCE (CSR 0x0 bit 27) = 0b
CTRL.TFCE (CSR 0x0 bit 28) = 0b
PCS_LCTL.FORCE_LINK (CSR 0X4208 bit 5) = 1b
PCS_LCTL.FSD (CSR 0x4208 bit 4) = 1b
PCS_LCTL.FDV (CSR 0x4208 bit 3) = 1b
PCS_LCTL.FLV (CSR 0x4208 bit 0) = 1b
PCS_LCTL.AN_ENABLE (CSR 0x4208 bit 16) = 0b
3.7.6.5 External PHY Loopback
In external PHY loopback, the SerDes block is not functional and data is sent through the MDI interface
and looped back using an external loopback plug. This means that all designs that are functional in
copper mode are involved in the loopback. If connected at 10/100 Mb/s, the loopback operates without
any special setup. For 1000 Mb/s operation, see the section that follows.
Ethernet Controller I210 —Interconnects
108
3.7.6.5.1 Setting the I210 Internal PHY to External Loopback Mode
For 1000 Mb/s, the following procedure should be used to put the I210 internal PHY into external
loopback mode:
Set Link mode to PHY: CTRL_EXT.LINK_MODE = 00b
In the PHY control register (Address 0 in the PHY):
Set duplex mode (bit 8)
Clear loopback bit (bit 14)
Set auto-negotiation enable bit (bit 12)
In the Checker Control (Page 6, PHY Register 18)
Set Enable Stub Test (bit 3)
Restart auto-negotiation (set bit 9)
Reset the PHY (set bit 15).
Wait for auto-negotiation to complete, then transmit and receive normally.
3.7.6.6 Line Loopback
In line loopback (Figure 3-13), MAC and SerDes interfaces are not functional and the data is sent from
a link partner to the PHY to test transmit and receive data paths. Frames that originate from a link
partner are looped back from the PHY and sent out on the wire before reaching the MAC interface pins.
The following should be confirmed before enabling the line loopback feature:
The PHY must first establish a full-duplex link with another PHY link partner, either through auto-
negotiation or through forcing the same link speed.
In order to enable line loopback mode once the link is established, set bit 14 to 1b in the MAC Specific
Control Register 2 - Page 2, Register 21 (see Section 8.27.3.27).
Figure 3-13. Line Loopback
55
Interconnects—Ethernet Controller I210
109
3.7.7 Energy Efficient Ethernet (EEE)
Energy Efficient Ethernet (EEE) Low Power Idle (LPI) mode defined in IEEE802.3az optionally enables
power saving by switching off part of the I210 functionality when no data needs to be transmitted or/
and received. The decision as to whether or not the I210 transmit path should enter LPI mode or exit
LPL mode is done according to transmit needs. Information as to whether or not a link partner has
entered LPI mode is detected by the I210 and is used for power saving in the receive circuitry.
When no data needs to be transmitted, a request to enter transmit LPI is issued on the internal xxMII
Tx interface causing the PHY to transmit sleep symbols for a pre-defined period of time followed by a
quite period. During LPI, the PHY periodically transmits refresh symbols that are used by the link
partner to update adaptive filters and timing circuits in order to maintain link integrity. This quiet-
refresh cycle continues until transmitting normal inter-frame encoding on the internal xxMII interface.
The PHY communicates to the link partner the move to active link state by sending wake symbols for a
pre-defined period of time. The PHY then enters a normal operating state where data or idle symbols
are transmitted.
In the receive direction, entering LPI mode is triggered by receiving sleep symbols from the link
partner. This signals that the link partner is about to enter LPI mode. After sending the sleep symbols,
the link partner ceases transmission. When a link partner enters LPI, the PHY indicates assert low
power idle on the internal xxMII RX interface and the I210’s receiver disables certain functionality to
reduce power consumption.
Figure 3-14 shows and Table 3-29 lists the general principles of EEE LPI operation on the Ethernet Link.
Figure 3-14. Energy Efficient Ethernet Operation
Table 3-29. Energy Efficient Ethernet Parameters
Parameter Description
Sleep Time (Ts) Duration PHY sends sleep symbols before going quiet.
Quiet Duration (Tq) Duration PHY remains quiet before it must wake for refresh period.
Refresh Duration (Tr) Duration PHY sends refresh symbols for timing recovery and coefficient synchronization.
PHY Wake Time (Tw_PHY) Minimum duration PHY takes to resume to an active state after decision to wake.
Receive System Wake Time
(Tw_System_rx) Wait period where no data is expected to be received to give the local receiving system time to
wake up.
Transmit System Wake Time
(Tw_System_tx) Wait period where no data is transmitted to give the remote receiving system time to wake up.
IDLE
Tq Tr Tw_PHY
Ts
Quiet Quiet Quiet
Data/
Idle
Refresh
Refresh
Wake
Sleep
Low-PowerActive Active
Tw_System
Data/
IDLE
IDLE
Tq Tr Tw_PHY
Ts
Quiet Quiet Quiet
Data/
Idle
Refresh
Refresh
Wake
Sleep
Low-PowerActive Active
Tw_System
Data/
IDLE
Ethernet Controller I210 —Interconnects
110
3.7.7.1 Conditions to Enter EEE Tx LPI
In the transmit direction when the network interface is internal copper PHY (CTRL_EXT.LINK_MODE =
00b), entry into to EEE LPI mode of operation is triggered when one of the following conditions exist:
1. No transmission is pending, management does not need to transmit, the internal transmit buffer is
empty, and EEER.TX_LPI_EN is set to 1b.
2. If the EEER.TX_LPI_EN and EEER.LPI_FC bits are set to 1b and a XOFF flow control packet is
received from the link partner, the I210 moves the link into the Tx LPI state for the pause duration
even if a transmission is pending.
3. When EEER.Force_TLPI is set (even if EEER.TX_LPI_EN is cleared).
If EEER.Force_TLPI is set in mid-packet, the I210 completes packet transmission and then
moves Tx to LPI.
Setting the EEER.Force_TLPI bit to 1b only stops transmission of packets from the host. The
I210 moves the link out of Tx LPI to transmit packets from management even when
EEER.Force_TLPI is set to 1b.
4. When a function enters D3 state and there’s no management Tx traffic, internal transmit buffers
are empty and EEER.TX_LPI_EN is set to 1b.
When one of the previous conditions to enter a Tx LPI state is detected, assert low power idle is
transmitted on the internal xxMII interface and the I210 PHY transmits sleep symbols on the network
interface to communicate to the link partner entry into Tx LPI link state. After sleep symbols
transmission, behavior of the PHY differs according to link speed (100BASE-TX or 1000BASE-T):
1. While in 100BASE-TX mode, the PHY enters low power operation in an asymmetric manner. After
sleep symbol transmissions, the PHY immediately enters a low power quiet state.
2. While in 1000BASE-T mode, the PHY entry into a quiet state is symmetric. Only after the PHY
transmits sleep symbols and receives sleep symbols from the remote PHY does the PHY enter the
quiet state.
After entering a quiet link state, the PHY periodically transitions between quiet link state, where link is
idle, to sending refresh symbols until a request to transition the link back to normal (active) mode is
transmitted on the internal xxMII TX interface (see Figure 3-14).
Note: MAC entry into Tx LPI state is always asymmetric (in both 100BASE-TX and 1000BASE-T PHY
operating modes).
3.7.7.2 Exit of TX LPI to Active Link State
The I210 exits Tx LPI link state and transition link into active link state when none of the conditions
defined in Section 3.7.7.1 exist. To transition into active link state, the I210 transmits:
1. Normal inter-frame encoding on the internal xxMII TX interface for a pre-defined link rate
dependant period time of Tw_sys_tx-min. As a result, PHY transmits wake symbols for a Tw_phy
duration followed by idle symbols.
2. If the Tw_System_tx duration defined in the EEER.Tw_system field is longer than Tw_sys_tx-min,
the I210 continues transmitting the inter-frame encoding on the internal xxMII interface until the
time defined in the EEER.Tw_system field has expired, before transmitting the actual data. During
this period the PHY continues transmitting idle symbols.
Note: When moving out of Tx LPI to transmit a 802.3x flow control frame the I210 waits only the
Tw_sys_tx-min duration before transmitting the flow control frame. It should be noted that
even in this scenario, actual data is transmitted only after the Tw_System_tx time defined in
the EEER.Tw_system field has expired.
Interconnects—Ethernet Controller I210
111
3.7.7.3 EEE Auto-Negotiation
Auto-negotiation provides the capability to negotiate EEE capabilities with the link partner using the
next page mechanism defined in IEEE802.3 Annex 28C. IEEE802.3 auto-negotiation is performed at
power up, on command from software, upon detection of a PHY error or following link re-connection.
During the link establishment process, both link partners indicate their EEE capabilities via the
IEEE802.3 auto-negotiation process. If EEE is supported by both link partners for the negotiated PHY
type then the EEE function can be used independently in either direction.
When operating in internal PHY mode (CTRL_EXT.LINK_MODE = 00b), the I210 supports EEE auto-
negotiation. EEE capabilities advertised during auto-negotiation can be modified via the EEE
advertisement field in the internal PHY (refer to Section 8.27.3.15) or via the EEER.EEE_1G_AN and
EEER.EEE_100M_AN bits.
3.7.7.4 EEE Link Level (LLDP) Capabilities Discovery
When operating in internal PHY mode (CTRL_EXT.LINK_MODE = 00b), the I210 supports LLDP
negotiation via software, using the EEE IEEE802.1AB Link Layer Discovery Protocol (LLDP) Type,
Length, Value (TLV) fields defined in IEEE802.3az clause 78 and clause 79. LLDP negotiation enables
negotiation of increased system wake time (Transmit Tw and Receive Tw) to enable improving system
energy efficiency.
After software negotiates a new system wake time via EEE LLDP negotiation, software should update
the:
1. EEER.Tw_system field with the negotiated Transmit Tw time value, to increase the duration where
idle symbols are transmitted following move out of EEE Tx LPI state before actual data can be
transmitted.
Value placed in EEER.Tw_system field does not affect transmission of flow control packets.
Depending on the technology (100BASE-TX or 1000BASE-T) flow control packet transmission is
delayed following move out of EEE TX LPI state only by the minimum Tw_sys_tx time as defined
in IEEE802.3az clause 78.5.
2. The LTRMAXV register with a value:
LTRMINV =< LTRMAXV <= LTRMINV + negotiated Receive Tw Time.
3. Set LTRC.EEEMS_EN bit to 1b (if bit was cleared), so that on detection of EEE RX LPI on the
network an updated LTR message with the value programmed in the LTRMAXV register is sent on
the PCIe interface.
4. Set EEER.TX_LPI_EN bit to 1b (if bit was cleared), to enable entry into EEE LPI on Tx path.
Set EEER.RX_LPI_EN bit to 1b (if bit was cleared), to enable detection of link partner entering EEE LPI
state on Rx path. Once the LTRC.EEEMS_EN bit is set and a port detects link partner entry into the EEE
LPI state on the internal xxMII RX interface, the port increases its reported latency tolerance to the
value programed in the LTRMAXV register. On detection of the Rx EEE LPI state, an updated LTR
message is sent on the PCIe interface.
When wake symbols are detected on the Ethernet link, due to a link partner moving out of EEE Rx LPI
state, the port reports a reduced latency tolerance that equals the value placed in the LTRMINV register
and the I210 sends on the PCIe interface a new LTR message with a reduced latency tolerance value of
LTRMINV.
Ethernet Controller I210 —Interconnects
112
Note: If link is disconnected or auto-negotiation is re-initiated, then the LTRC.EEEMS_EN bit is
cleared by hardware. The bit should be set to 1b by software following re-execution of an EEE
LLDP negotiation.
Figure 3-15 shows the format of the EEE TLV, meaning of the various TLV parameters can be found in
IEEE802.3az clause 78 and clause 79.
3.7.7.5 Programming the I210 for EEE Operation
To activate EEE support when operating in internal PHY mode (CTRL_EXT.LINK_MODE = 00b), software
should program the following fields to enable EEE on the LAN port:
1. IPCNFG register (refer to Section 8.27.1) if default EEE advertised auto-negotiation values need to
be modified.
2. Set the EEER.TX_LPI_EN and EEER.RX_LPI_EN bits (refer to Section 8.25.12) to 1b to enable EEE
LPI support on Tx and Rx paths, respectively, if the result of auto-negotiation at the specified link
speed enables entry to LPI.
3. Set the EEER.LPI_FC bit (refer to Section 8.25.12) if required to enable a move into the EEE Tx LPI
state for the pause duration when a link partner sends a XOFF flow control packet even if internal
transmit buffer is not empty and transmit descriptors are available.
4. Update EEER.Tw_system field (refer to Section 8.25.12) with the new negotiated transmit Tw time
after completing EEE LLDP negotiation.
5. Following the EEE LLDP negotiation program, the LTRMAXV register (refer to Section 8.25.10) with
a value of:
LTRMINV =< LTRMAXV <= LTRMINV + negotiated Receive Tw Time.
Figure 3-15. EEE LLDP TLV
Interconnects—Ethernet Controller I210
113
6. Set the LTRC.EEEMS_EN bit to 1b, to enable sending an updated PCIe LTR message when detecting
a link partner entry into EEE Rx LPI state.
Notes:
1. The LTRC.EEEMS_EN bit is cleared following link disconnect or auto-negotiation and should be set
to 1b by software following EEE LLDP re-negotiation.
2. The I210 waits for at least 1 second following auto-negotiation (due to reset, link disconnect, or link
speed change) and link-up indication (STATUS.LU set to 1b, refer to Section 8.2.2) before enabling
link entry into EEE Tx LPI state to comply with the IEEE802.3az specification.
3.7.7.5.1 PHY Programming for EEE Operation with Cables > 130m
When working with cables long by 130 meters and beyond, it is recommended that the following PHY
register settings be applied by host to improve EEE interoperability with third part vendors:
1. Reg 22 = 0x00FF
2. Reg 17 = 0x0048
3. Reg16 = 0X215D
4. Reg 17 = 0x0027
5. Reg16 = 0X2150
6. Reg 17 = 0xDC0C
7. Reg16 = 0X2159
8. Reg 17 = 0xA42B
9. Reg16 = 0X2151
10. Reg 17 = 0x3024
11. Reg16 = 0X215C
12. Reg 22 = 0x00FC
13. Reg 24 = 0x888E
14. Reg 25 = 0x888E
15. Reg 1 = 0x20B0
These settings can be applied before the link is up when EEE is enabled.
3.7.7.6 EEE Statistics
The I210 supports reporting the number of EEE LPI Tx and Rx events via the RLPIC and TLPIC registers.
3.7.8 Integrated Copper PHY Functionality
The register set used to control the PHY functionality (PHYREG) is described in Section 8.27.3. the
registers can be programmed using the MDIC register (refer to Section 8.2.4).
3.7.8.1 Determining Link State
The PHY and its link partner determine the type of link established through one of three methods:
Auto-negotiation
Parallel detection
Ethernet Controller I210 —Interconnects
114
Forced operation
Auto-negotiation is the only method allowed by the 802.3ab standard for establishing a 1000BASE-T
link, although forced operation could be used for test purposes. For 10/100 links, any of the three
methods can be used. The following sections discuss each in greater detail.
Figure 3-16 provides an overview of link establishment. First the PHY checks if auto-negotiation is
enabled. By default, the PHY supports auto-negotiation, see PHY Register 0, bit 12. If not, the PHY
forces operation as directed. If auto-negotiation is enabled, the PHY begins transmitting Fast Link
Pulses (FLPs) and receiving FLPs from its link partner. If FLPs are received by the PHY, auto-negotiation
proceeds. It also can receive 100BASE-TX MLT3 and 10BASE-T Normal Link Pulses (NLPs). If either
MLT3 or NLPs are received, it aborts FLP transmission and immediately brings up the corresponding
half-duplex link.
3.7.8.1.1 False Link
Figure 3-16. Overview of Link Establishment
Speed?
0.13
A/N Enabled
?
Start
Auto-Negotiate/Parallel Detection
Send NLP
Send FLP
Power-Up, Reset,
Link Failure
Forced Operation
N
Y
0
1
10M
Detect 10 Mbps
?
N
Y
Link
Down
Link
Up
Send IDLES
100M
Detect IDLES
?
N
Y
Take
Down
Link
Bring
Link
Up
Bit 0.8 sets Du
p
lex
Detect
FLP
100M
Half-Duple
x
Link
N
Y
Parallel
Detect
Detect
NLP
Auto
Negotiate
Detect
IDLES
Y
10M
Half-Duple
x
Link
Y
N
Bit 0.8 sets Du
p
lex
N
Interconnects—Ethernet Controller I210
115
The PHY does not falsely establish link with a partner operating at a different speed. For example, the
PHY does not establish a 1 Gb/s or 10 Mb/s link with a 100 Mb/s link partner.
When the PHY is first powered on, reset, or encounters a link down state; it must determine the line
speed and operating conditions to use for the network link.
The PHY first checks the MDIO registers (initialized via the hardware control interface or written by
software) for operating instructions. Using these mechanisms, designers can command the PHY to do
one of the following:
Force twisted-pair link operation to:
1000T, full duplex
1000T, half duplex
100TX, full duplex
100TX, half duplex
10BASE-T, full duplex
10BASE-T, half duplex
Allow auto-negotiation/parallel-detection.
In the first six cases (forced operation), the PHY immediately begins operating the network interface as
commanded. In the last case, the PHY begins the auto-negotiation/parallel-detection process.
3.7.8.1.2 Forced Operation
Forced operation can be used to establish 10 Mb/s and 100 Mb/s links, and 1000 Mb/s links for test
purposes. In this method, auto-negotiation is disabled completely and the link state of the PHY is
determined by MII Register 0.
In forced operation, the designer sets the link speed (10, 100, or 1000 MB/s) and duplex state (full or
half). For GbE (1000 MB/s) links, designers must explicitly designate one side as the master and the
other as the slave.
Note: The paradox (per the standard): If one side of the link is forced to full-duplex operation and
the other side has auto-negotiation enabled, the auto-negotiating partner parallel-detects to
a half-duplex link while the forced side operates as directed in full-duplex mode. The result is
spurious, unexpected collisions on the side configured to auto-negotiate.
Table 3-30 lists link establishment procedures.
Table 3-30. Determining Duplex State Via Parallel Detection
Configuration Result
Both sides set for auto-negotiate Link is established via auto-negotiation.
Both sides set for forced operation No problem as long as duplex settings match.
One side set for auto-negotiation and the other for forced, half-
duplex Link is established via parallel detect.
One side set for auto-negotiation and the other for forced full-
duplex
Link is established; however, sides disagree, resulting in
transmission problems (Forced side is full-duplex, auto-
negotiation side is half-duplex.).
Ethernet Controller I210 —Interconnects
116
3.7.8.1.3 Auto Negotiation
The PHY supports the IEEE 802.3u auto-negotiation scheme with next page capability. Next page
exchange uses Register 7 to send information and Register 8 to receive them. Next page exchange can
only occur if both ends of the link advertise their ability to exchange next pages.
3.7.8.1.4 Parallel Detection
Parallel detection can only be used to establish 10 and 100 Mb/s links. It occurs when the PHY tries to
negotiate (transmit FLPs to its link partner), but instead of sensing FLPs from the link partner, it senses
100BASE-TX MLT3 code or 10BASE-T Normal Link Pulses (NLPs) instead. In this case, the PHY
immediately stops auto-negotiation (terminates transmission of FLPs) and immediately brings up
whatever link corresponds to what it has sensed (MLT3 or NLPs). If the PHY senses both technologies,
the parallel detection fault is detected and the PHY continues sending FLPs.
With parallel detection, it is impossible to determine the true duplex state of the link partner and the
IEEE standard requires the PHY to assume a half-duplex link. Parallel detection also does not allow
exchange of flow-control ability (PAUSE and ASM_DIR) or the master/slave relationship required by
1000BASE-T. This is why parallel detection cannot be used to establish GbE links.
3.7.8.1.5 Auto Cross-Over
Twisted pair Ethernet PHY's must be correctly configured for MDI or MDI-X operation to inter operate.
This has historically been accomplished using special patch cables, magnetics pinouts or Printed Circuit
Board (PCB) wiring. The PHY supports the automatic MDI/MDI-X configuration originally developed for
1000Base-T and standardized in IEEE 802.3u section 40. Manual (non-automatic) configuration is still
possible.
For 1000BASE-T links, pair identification is determined automatically in accordance with the standard.
For 10/100/1000 Mb/s links and during auto-negotiation, pair usage is determined by bits 4 and 5 in
PHYREG 0,21. The PHY activates an automatic cross-over detection function if enabled via bit 0 in
IPCNFG (also see bits 5 and 6 in PHYREG 0,16). When in this mode, the PHY automatically detects
which application is being used and configures itself accordingly.
The automatic MDI/MDI-X state machine facilitates switching the MDI_PLUS[0] and MDI_MINUS[0]
signals with the MDI_PLUS[1] and MDI_MINUS[1] signals, respectively, prior to the auto-negotiation
mode of operation so that FLPs can be transmitted and received in compliance with Clause 28 auto-
negotiation specifications. An algorithm that controls the switching function determines the correct
polarization of the cross-over circuit. This algorithm uses an 11-Bit Linear Feedback Shift Register
(LFSR) to create a pseudo-random sequence that each end of the link uses to determine its proposed
configuration. After making the selection to either MDI or MDI-X, the node waits for a specified amount
of time while evaluating its receive channel to determine whether the other end of the link is sending
link pulses or PHY-dependent data. If link pulses or PHY-dependent data are detected, it remains in that
configuration. If link pulses or PHY-dependent data are not detected, it increments its LFSR and makes
a decision to switch based on the value of the next bit. The state machine does not move from one
state to another while link pulses are being transmitted.
Interconnects—Ethernet Controller I210
117
3.7.8.1.6 10/100 MB/s Mismatch Resolution
It is a common occurrence that a link partner (such as a switch) is configured for forced full-duplex
(FDX) 10/100 Mb/s operation. The normal auto-negotiation sequence would result in the other end
settling for half-duplex (HDX) 10/100 Mb/s operation. The mechanism described in this section resolves
the mismatch automatically and transitions the I210 into FDX mode, enabling it to operate with a
partner configured for FDX operation.
The I210 enables the system software device driver to detect the mismatch event previously described
and sets its duplex mode to the appropriate value without a need to go through another auto-
negotiation sequence or breaking link. Once software detects a possible mismatch, it might instruct the
I210 to change its duplex setting to either HDX or FDX mode. Software sets the Duplex_manual_set bit
to indicate that duplex setting should be changed to the value indicated by the Duplex Mode bit in PHY
Register 0. Any change in the value of the Duplex Mode bit in PHY Register 0 while the
Duplex_manual_set bit is set to 1b would also cause a change in the device duplex setting.
The Duplex_manual_set bit is cleared on all PHY resets, following auto-negotiation, and when the link
goes down. Software might track the change in duplex through the PHY Duplex Mode bit in Register 17
or a MAC indication.
3.7.8.1.7 Link Criteria
Once the link state is determined-via auto-negotiation, parallel detection or forced operation, the PHY
and its link partner bring up the link.
3.7.8.1.7.1 1000BASE-T
For 1000BASE-T links, the PHY and its link partner enter a training phase. They exchange idle symbols
and use the information gained to set their adaptive filter coefficients. These coefficients are used to
equalize the incoming signal, as well as eliminate signal impairments such as echo and cross talk.
Figure 3-17. Cross-Over Function
MDIX (Switch)
MDI (DTE/NIC)
RX
TX
1
2
3
6
Phy
CROSS(1:0) = 00
CROSS(1:0) = 01
A
B
R
J
4
5
-
RX
TX
1
2
3
6
A
B
R
J
4
5
Flat Cable
RX
TX
TX
RX
7
D
5
7
8
D
RX
TX
TX
RX
C
C
4
8
5
4
RX
TX
RX
TX
Ethernet Controller I210 —Interconnects
118
Either side indicates completion of the training phase to its link partner by changing the encoding of the
idle symbols it transmits. When both sides so indicate, the link is up. Each side continues sending idle
symbols each time it has no data to transmit. The link is maintained as long as valid idle, data, or
carrier extension symbols are received.
3.7.8.1.7.2 100BASE-TX
For 100BASE-TX links, the PHY and its link partner immediately begin transmitting idle symbols. Each
side continues sending idle symbols each time it has no data to transmit. The link is maintained as long
as valid idle symbols or data is received.
In 100 Mb/s mode, the PHY establishes a link each time the scrambler becomes locked and remains
locked for approximately 50 ms. Link remains up unless the descrambler receives less than 12
consecutive idle symbols in any 2 ms period. This provides for a very robust operation, essentially
filtering out any small noise hits that might otherwise disrupt the link.
3.7.8.1.7.3 10BASE-T
For 10BASE-T links, the PHY and its link partner begin exchanging Normal Link Pulses (NLPs). The PHY
transmits an NLP every 16 ms and expects to receive one every 10 to 20 ms. The link is maintained as
long as normal link pulses are received.
In 10 Mb/s mode, the PHY establishes link based on the link state machine found in 802.3, clause 14.
Note: 100 Mb/s idle patterns do not bring up a 10 Mb/s link.
3.7.8.2 SmartSpeed
SmartSpeed is an enhancement to auto-negotiation that enables the PHY to react intelligently to
network conditions that prohibit establishment of a 1000BASE-T link, such as cable problems. Such
problems might allow auto-negotiation to complete, but then inhibit completion of the training phase.
Normally, if a 1000BASE-T link fails, the PHY returns to the auto-negotiation state with the same speed
settings indefinitely. With SmartSpeed enabled by setting the Downshift Enable field (bit 11 - refer to
Section 8.27.3.15), after a configurable number of failed attempts, as configured in the Downshift
counter field (bits 14:12 - refer to Section 8.27.3.15) the PHY automatically downgrades the highest
ability it advertises to the next lower speed: from 1000 to 100 to 10 Mb/s. Once a link is established,
and if it is later broken, the PHY automatically upgrades the capabilities advertised to the original
setting. This enables the PHY to automatically recover once the cable plant is repaired.
3.7.8.2.1 Using SmartSpeed
When SmartSpeed downgrades the PHY advertised capabilities, it sets bit Downshift Status (bit 5 -
refer to Section 8.27.3.16). When link is established, its speed is indicated in the Speed field (bits
15:14 - refer to Section 8.27.3.16). SmartSpeed automatically resets the highest-level auto-
negotiation abilities advertised, if link is established and then lost.
Note: SmartSpeed and Master-Slave (M/S) fault - When SmartSpeed is enabled, the M/S number of
Attempts Before Downshift (ABD) is programmed to be less than 7, resolution is not given
seven attempts to try to resolve M/S status (see IEEE 802.3 clause 40.5.2).
Time To Link (TTL) with Smart Speed - in most cases, any attempt duration is approximately
2.5 seconds, in other cases it could take more than 2.5 seconds depending on configuration
and other factors.
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119
3.7.8.3 Flow Control
Flow control is a function that is described in Clause 31 of the IEEE 802.3 standard. It enables
congested nodes to pause traffic. Flow control is essentially a MAC-to-MAC function. MACs indicate their
ability to implement flow control during auto-negotiation. This ability is communicated through two bits
in the auto-negotiation registers (PHYREG 0,4.10 and PHYREG 0,4.11).
The PHY transparently supports MAC-to-MAC advertisement of flow control through its auto-negotiation
process. Prior to auto-negotiation, the MAC indicates its flow control capabilities via PHYREG 0,4.10
(Pause) and PHYREG 0,4.11 (ASM_DIR). After auto-negotiation, the link partner's flow control
capabilities are indicated in PHYREG 0,5.10 and PHYREG 0,5.11.
There are two forms of flow control that can be established via auto-negotiation: symmetric and
asymmetric. Symmetric flow control is for point-to-point links; asymmetric for hub-to-end-node
connections. Symmetric flow control enables either node to flow-control the other. Asymmetric flow-
control enables a repeater or switch to flow-control a DTE, but not vice versa.
Table 3-31 lists the intended operation for the various settings of ASM_DIR and PAUSE. This
information is provided for reference only; it is the responsibility of the MAC to implement the correct
function. The PHY merely enables the two MACs to communicate their abilities to each other.
3.7.8.4 Management Data Interface
The PHY supports the IEEE 802.3 MII Management Interface also known as the Management Data
Input/Output (MDIO) Interface. This interface enables upper-layer devices to monitor and control the
state of the PHY. The MDIO interface consists of a physical connection, a specific protocol that runs
across the connection, and an internal set of addressable registers.
The PHY supports the core 16-bit MDIO registers. Registers 0-10 and 15 are required and their
functions are specified by the IEEE 802.3 specification. Additional registers are included for expanded
functionality. Specific bits in the registers are referenced using an PHY REG X.Y notation, where X is the
register number (0-31) and Y is the bit number (0-15).
3.7.8.5 Internal PHY Low Power Operation and Power Management
The internal PHY incorporates numerous features to maintain the lowest power possible.
The PHY can be entered into a low-power state according to MAC control (Power Management controls)
or via PHY Register 0. In either power down mode, the PHY is not capable of receiving or transmitting
packets.
Table 3-31. Pause And Asymmetric Pause Settings
ASM_DIR Settings Local
(PHYREG 0,4.10) and
Remote (PHYREG 0,5.10)
Pause Setting -
Local (PHYREG
0,4.11)
Pause Setting -
Remote (PHYREG
0,5.11)
Result
Both ASM_DIR = 1b 1b 1b Symmetric - Either side can flow control the other.
1b 0b Asymmetric - Remote can flow control local only.
0b 1b Asymmetric - Local can flow control remote.
0b 0b No flow control.
Either or both ASM_DIR = 0b 1b 1b Symmetric - Either side can flow control the other.
Either or both = 0b No flow control.
Ethernet Controller I210 —Interconnects
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3.7.8.5.1 Power Down via the PHY Register
The PHY can be powered down using the control bit found in PHYREG 0,0.11. This bit powers down a
significant portion of the port but clocks to the register section remain active. This enables the PHY
management interface to remain active during register power down. The power down bit is active high.
When the PHY exits software power-down (PHYREG 0,0.11 = 0b), it re-initializes all analog functions,
but retains its previous configuration settings.
3.7.8.5.2 Power Management State
The internal PHY is aware of the power management state. If the PHY is not in a power down state,
then PHY behavior regarding several features are different depending on the power state, refer to
Section 3.7.8.5.4.
3.7.8.5.3 Disable High Speed Power Saving Options
The I210 supports disabling 1000 Mb/s or both 1000 Mb/s and 100 Mb/s advertisement by the internal
PHY regardless of the values programmed in the PHY ANA Register (address - 4d) and the PHY GCON
Register (address - 9d).
This is for cases where the system doesn't support working in 1000 Mb/s or 100 Mb/s due to power
limitations.
This option is enabled in the following PHPM register bits:
PHPM.Disable 1000 in non-D0a - disable 1000 Mb/s when in non-D0a states only.
PHPM.Disable 100 in non-D0a - disable 1000 Mb/s and 100 Mb/s when in non-D0a states only.
PHPM.Disable 1000 - disable 1000 Mb/s always.
Note: When Value of PHPM.Disable 1000 bit is changed, PHY initiates auto-negotiation without
direct driver command.
3.7.8.5.4 Low Power Link Up - Link Speed Control
Normal internal PHY speed negotiation drives to establish a link at the highest possible speed. The I210
supports an additional mode of operation, where the PHY drives to establish a link at a low speed. The
link-up process enables a link to come up at the lowest possible speed in cases where power is more
important than performance. Different behavior is defined for the D0 state and the other non-D0
states.
Interconnects—Ethernet Controller I210
121
Table 3-32 lists link speed as function of power management state, link speed control, and GbE speed
enabling:
The internal PHY initiates auto-negotiation without a direct driver command in the following cases:
When the PHPM.Disable 1000 in non-D0a bit is set and 1000 Mb/s is disabled on D3 or Dr entry
(but not in D0a), the PHY auto-negotiates on entry.
When the PHPM.Disable 100 in non-D0a is set and 1000 Mb/s and 100 Mb/s are disabled on D3 or
Dr entry (but not in D0a), the PHY auto-negotiates on entry.
When PHPM.LPLU changes state with a change in a power management state. For example, on
transition from D0a without PHPM.LPLU to D3 with PHPM.LPLU. Or, on transition from D3 with
PHPM.LPLU to D0 without LPLU.
On a transition from D0a state to a non-D0a state, or from a non-D0a state to D0a state, and
PHPM.LPLU is set.
Notes:
The Low-Power Link-Up (LPLU) feature previously described should be disabled (in both
D0a state and non-D0a states) when the intended advertisement is anything other than
10 Mb/s only, 10/100 Mb/s only, or 10/100/1000 Mb/s. This is to avoid reaching (through
the LPLU procedure) a link speed that is not advertised by the user.
When the LAN PCIe function is disabled via the LAN_PCI_DIS bit in the Software Defined
Pins Control Flash word, the relevant function is in a Non-D0a state. As a result,
management might operate with reduced link speed if the LPLU, Disable 1000 in Non-
D0a or Disable 100 in Non-D0a Flash bits are set and the MANC.Keep_PHY_Link_Up bit
(also known as “Veto bit”) is cleared.
When the Keep_PHY_Link_Up bit (also known as veto bit) in the MANC register is set,
The PHY does not change its link speed as a result of a change in the device power state
(such as move to D3).
Table 3-32. Link Speed vs. Power State
Power
Management
State
Low
Power
Link Up
(PHPM.1,
PHPM.2)
GbE Disable Bits 100M Disable
Bit
PHY Speed Negotiation
Disable 1000
(PHPM.6)
Disable 1000
in non-D0a
(PHPM.3)
Disable 100
in non-D0a
(PHPM.9)
D0a
0, Xb
0b X X PHY negotiates to highest speed advertised
(normal operation).
1b X X PHY negotiates to highest speed advertised
(normal operation), excluding 1000 Mb/s.
1, Xb
0b X X PHY goes through Low Power Link Up (LPLU)
procedure, starting with advertised values.
1b X X PHY goes through LPLU procedure, starting with
advertised values. Does not advertise 1000 Mb/s.
Non-D0a
X, 0b
0b 0b 0b PHY negotiates to highest speed advertised.
0b 1b 0b PHY negotiates to highest speed advertised,
excluding 1000 Mb/s.
1b X 0b
X X 1b PHY negotiates and advertises only 10 Mb/s
X, 1b
0b 0b 0b PHY goes through LPLU procedure, starting at 10
Mb/s.
0b 1b 0b PHY goes through LPLU procedure, starting at 10
Mb/s. Does not advertise 1000 Mb/s.
X X 1b PHY negotiates and advertises only 10 Mb/s
Ethernet Controller I210 —Interconnects
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3.7.8.5.4.1 D0a State
A power-managed link speed control lowers link speed (and power) when highest link performance is
not required. When enabled (D0 Low Power Link Up mode), any link negotiation tries to establish a low-
link speed, starting with an initial advertisement defined by software.
The D0LPLU configuration bit enables D0 Low Power Link Up. Before enabling this feature, software
must advertise to one of the following speed combinations: 10 Mb/s only, 10/100 Mb/s only, or 10/100/
1000 Mb/s.
When speed negotiation starts, the PHY tries to negotiate at a speed based on the currently advertised
values. If link establishment fails, the PHY tries to negotiate with different speeds; it enables all speeds
up to the lowest speed supported by the partner. For example, PHY advertises 10 Mb/s only, and the
partner supports 1000 Mb/s only. After the first try fails, the PHY enables 10/100/1000 Mb/s and tries
again. The PHY continues to try and establish a link until it succeeds or until it is instructed otherwise.
In the second step (adjusting to partner speed), the PHY also enables parallel detect, if needed.
Automatic MDI/MDI-X resolution is done during the first auto-negotiation stage.
3.7.8.5.4.2 Non-D0a State
The PHY might negotiate to a low speed while in non-D0a states (Dr, D0u, D3). This applies only when
the link is required by one of the following: Manageability, APM Wake, or PME. Otherwise, the PHY is
disabled during the non-D0 state.
The Low Power on Link-Up (register PHPM.LPLU, is also loaded from Flash) bit enables reduction in link
speed:
At power-up entry to Dr state, the PHY advertises supports for 10 Mb/s only and goes through the
link up process.
At any entry to a non-D0a state (Dr, D0u, D3), the PHY advertises support for 10 Mb/s only and
goes through the link up process.
While in a non-D0 state, if auto-negotiation is required, the PHY advertises support for 10 Mb/s only
and goes through the link up process.
Link negotiation begins with the PHY trying to negotiate at 10 Mb/s speed only regardless of user auto-
negotiation advertisement. If link establishment fails, the PHY tries to negotiate at additional speeds; it
enables all speeds up to the lowest speed supported by the partner. For example, the PHY advertises
10 Mb/s only and the partner supports 1000 Mb/s only. After the first try fails, PHY enables 10/100/
1000 Mb/s and tries again. The PHY continues to try and establish a link until it succeeds or until it is
instructed otherwise. In the second step (adjusting to partner speed), the PHY also enables parallel
detect, if needed. Automatic MDI/MDI-X resolution is done during the first auto-negotiation stage.
3.7.8.5.5 Internal PHY Smart Power-Down (SPD)
SPD is a link-disconnect capability applicable to all power management states. SPD combines a power
saving mechanism with the fact that the link might disappear and resume.
SPD is enabled by PHPM.SPD_EN or by SPD Enable bit in the Flash if the following conditions are met:
1. Auto-negotiation is enabled.
2. PHY detects link loss.
While in SPD, the PHY powers down circuits and clocks that are not required for detection of link
activity. The PHY is still be able to detect link pulses (including parallel detect) and wake-up to engage
in link negotiation. The PHY does not send link pulses (NLP) while in SPD state; however, register
accesses are still possible.
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123
When the internal PHY is in SPD and detects link activity, it re-negotiates link speed based on the power
state and the Low Power Link Up bits as defined by the PHPM.D0LPLU and PHPM.LPLU bits.
Note: The PHY does not enter SPD unless auto-negotiation is enabled.
While in SPD, the PHY powers down all circuits not required for detection of link activity. The PHY must
still be able to detect link pulses (including parallel detect) and wake up to engage in link negotiation.
The PHY does not send link pulses (NLP) while in SPD.
Notes: While in the link-disconnect state, the PHY must allow software access to its registers.
The link-disconnect state applies to all power management states (Dr, D0u, D0a, D3).
The link might change status, that is go up or go down, while in any of these states.
3.7.8.5.5.1 Internal PHY Back-to-Back SPD
While in link disconnect, the I210 monitors the link for link pulses to identify when a link is re-
connected. The I210 also periodically transmits pulses (every second) to resolve the case of two I210
devices (or devices with I210-like behavior) connected to each other across the link. Otherwise, two
such devices might be locked in SPD, not capable of identifying that a link was re-connected.
Back-to-back SPD is enabled by the SPD_B2B_EN bit in the PHPM register. The default value is enabled.
The Enable bit applies to SPD.
Note: This bit should not be altered by software once the I210 was set in SPD. If software requires
changing the back-to-back status, it first needs to transition the PHY out of SPD and only then
change the back-to-back bit to the required state.
3.7.8.5.6 Internal PHY Link Energy Detect
The I210 asserts the Link Energy Detect bit (PHPM.Link Energy Detect) each time energy is not
detected on the link. This bit provides an indication of a cable becoming plugged or unplugged.
This bit is valid only if PHPM.Go Link disconnect is set to 1b.
In order to correctly deduce that there is no energy, the bit must read 0b for three consecutive reads
each second.
3.7.8.5.7 Internal PHY Power-Down State
The I210 port enters a power-down state when the port’s clients are disabled and therefore the internal
PHY has no need to maintain a link. This can happen in one of the following cases:
1. D3/Dr state - Internal PHY enters a low-power state if the following conditions are met:
a. The LAN function is in a non-D0 state
b. APM WOL is inactive
c. Manageability doesn't use this port.
d. ACPI PME is disabled for this port.
e. The Dynamic Device Off Enable Flash bit is set (word 0x1E.14)
f. WUC.PPROXYE and MANC.MPROXYE bits are set to 1b
2. SerDes mode - Internal PHY is disabled when its LAN function is configured to SerDes mode.
Ethernet Controller I210 —Interconnects
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3. Device off mode - Internal PHY can be disabled if the DEV_OFF_N pin is asserted. Since the PHY is
shared between the LAN function and manageability, it might not be desirable to power down the
PHY in Device Disable mode. The PHY_in_LAN_Disable Flash bit determines whether the PHY (and
MAC) are powered down when the DEV_OFF_N pin is asserted. The default is to power down.
Note: If the LPLU, Disable 1000 in Non-D0a or the Disable 100 in Non-D0a Flash bits are set and the
MANC.Keep_PHY_Link_Up bit (Veto bit) is cleared, Management may operate with reduced
link speed since the function is in a Non-D0a (uninitialized) state.
3.7.8.6 Advanced Diagnostics
The I210 integrated PHY incorporates hardware support for advanced diagnostics.
The hardware support enables output of internal PHY data to host memory for post processing by the
software device driver.
The current diagnostics supported are described in the sections that follow.
3.7.8.6.1 Time Domain Reflectometry (TDR)
By sending a pulse onto the twisted pair and observing the retuned signal, the following can be
deduced:
1. Is there a short?
2. Is there an open?
3. Is there an impedance mismatch?
4. What is the length to any of these faults?
3.7.8.6.2 Channel Frequency Response
By doing analysis on the Tx and Rx data, it can be established that a channel’s frequency response
(also known as insertion loss) can determine if the channel is within specification limits. (Clause
40.7.2.1 in IEEE 802.3).
3.7.8.7 1000 Mb/s Operation
3.7.8.7.1 Introduction
Figure 3-18 shows an overview of 1000BASE-T functions, followed by discussion and review of the
internal functional blocks.
Interconnects—Ethernet Controller I210
125
3.7.8.7.2 Transmit Functions
This section describes functions used when the MAC transmits data through the PHY and out onto the
twisted-pair connection (see Figure 3-18).
3.7.8.7.2.1 Scrambler
The scrambler randomizes the transmitted data. The purpose of scrambling is twofold:
1. Scrambling eliminates repeating data patterns (also known as spectral lines) from the 4DPAM5
waveform in order to reduce EMI.
2. Each channel (A, B, C, D) has a unique signature that the receiver uses for identification.
Figure 3-18. 1000BASE-T Functions Overview
Side -stream
Scrambler /
Descrambler
Trellis Viterbi
Encoder/ Decoder
8
8
4
4
MAC Interface
AGC, A/D,
Timing Recovery
4DPAM5
Encoder
ECHO, NEXT,
FEXT
Cancellers
Line
Interface
Pulse Shaper,
DAC, Filter
Hybrid Line Driver
DSP
Ethernet Controller I210 —Interconnects
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The scrambler is driven by a 33-bit Linear Feedback Shift Register (LFSR), which is randomly loaded at
power up. The LFSR function used by the master differs from that used by the slave, giving each
direction its own unique signature. The LFSR, in turn, generates twelve mutually uncorrelated outputs.
Eight of these are used to randomize the inputs to the 4DPAM5 and Trellis encoders. The remaining four
outputs randomize the sign of the 4DPAM5 outputs.
3.7.8.7.2.2 Transmit FIFO
The transmit FIFO re-synchronizes data transmitted by the MAC to the transmit reference used by the
PHY. The FIFO is large enough to support a frequency differential of up to +/- 1000 ppm over a packet
size of 10 KB (jumbo frame).
3.7.8.7.2.3 Transmit Phase-Locked Loop PLL
This function generates the 125 MHz timing reference used by the PHY to transmit 4DPAM5 symbols.
When the PHY is the master side of the link, the XI input is the reference for the transmit PLL. When the
PHY is the slave side of the link, the recovered receive clock is the reference for the transmit PLL.
3.7.8.7.2.4 Trellis Encoder
The Trellis encoder uses the two high-order bits of data and its previous output to generate a ninth bit,
which determines if the next 4DPAM5 pattern should be even or odd.
For data, this function is:
Trellisn = Data7n-1 XOR Data6n-2 XOR Trellisn-3
This provides forward error correction and enhances the Signal-To-Noise (SNR) ratio by a factor of 6
dB.
3.7.8.7.2.5 4DPAM5 Encoder
The 4DPAM5 encoder translates 8-byte codes transmitted by the MAC into 4DPAM5 symbols. The
encoder operates at 125 MHz, which is both the frequency of the MAC interface and the baud rate used
by 1000BASE-T.
Each 8-byte code represents one of 28 or 256 data patterns. Each 4DPAM5 symbol consists of one of
five signal levels (-2,-1,0,1,2) on each of the four twisted pair (A,B,C,D) representing 54 or 625
possible patterns per baud period. Of these, 113 patterns are reserved for control codes, leaving 512
patterns for data. These data patterns are divided into two groups of 256 even and 256 odd data
patterns. Thus, each 8-byte octet has two possible 4DPAM5 representations: one even and one odd
pattern.
3.7.8.7.2.6 Spectral Shaper
This function causes the 4DPAM5 waveform to have a spectral signature that is very close to that of the
MLT3 waveform used by 100BASE-TX. This enables 1000BASE-T to take advantage of infrastructure
(cables, magnetics) designed for 100BASE-TX.
The shaper works by transmitting 75% of a 4DPAM5 code in the current baud period, and adding the
remaining 25% into the next baud period.
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3.7.8.7.2.7 Low-Pass Filter
To aid with EMI, this filter attenuates signal components more than 180 MHz. In 1000BASE-T, the
fundamental symbol rate is 125 MHz.
3.7.8.7.2.8 Line Driver
The line driver drives the 4DPAM5 waveforms onto the four twisted-pair channels (A, B, C, D), adding
them onto the waveforms that are simultaneously being received from the link partner.
Figure 3-19. 1000BASE-T Transmit Flow And Line Coding Scheme
Figure 3-20. Transmit/Receive Flow
Scrambler Pol
y
nomials:
1 + x
13
+ x
33
(
Master PHY Mode
)
1 + x
20
+ x
33
(
Slave PHY Mode
)
D0
D1
D2
D3
D4
D5
D6
D7
GMII
Scrambler
Trellis
PAM-5
Encoded Output
to 4-Pair UTP Line
8
PAM-5
Encoder
9
4D
D1
D0
D2
D3
D4
D5
D6
D7
GMII
8Bits
Polynomial
Descrambler
DSP
Receiver
PAM‐5
EncodedInput
From4‐PairUTPLine
8Bits
Ethernet Controller I210 —Interconnects
128
3.7.8.7.3 Receive Functions
This section describes function blocks that are used when the PHY receives data from the twisted pair
interface and passes it back to the MAC (see Figure 3-20).
3.7.8.7.3.1 Hybrid
The hybrid subtracts the transmitted signal from the input signal, enabling the use of simple 100BASE-
TX compatible magnetics.
3.7.8.7.3.2 Automatic Gain Control (AGC)
AGC normalizes the amplitude of the received signal, adjusting for the attenuation produced by the
cable.
3.7.8.7.3.3 Timing Recovery
This function re-generates a receive clock from the incoming data stream which is used to sample the
data. On the slave side of the link, this clock is also used to drive the transmitter.
3.7.8.7.3.4 Analog-to-Digital Converter (ADC)
The ADC function converts the incoming data stream from an analog waveform to digitized samples for
processing by the DSP core.
3.7.8.7.3.5 Digital Signal Processor (DSP)
DSP provides per-channel adaptive filtering, which eliminates various signal impairments including:
Inter-symbol interference (equalization)
Echo caused by impedance mismatch of the cable
Near-end crosstalk (NEXT) between adjacent channels (A, B, C, D)
Far-end crosstalk (FEXT)
Propagation delay variations between channels of up to 120 ns
Extraneous tones that have been coupled into the receive path
The adaptive filter coefficients are initially set during the training phase. They are continuously adjusted
(adaptive equalization) during operation through the decision-feedback loop.
3.7.8.7.3.6 Descrambler
The descrambler identifies each channel by its characteristic signature, removing the signature and re-
routing the channel internally. In this way, the receiver can correct for channel swaps and polarity
reversals. The descrambler uses the same base 33-bit LFSR used by the transmitter on the other side
of the link.
The descrambler automatically loads the seed value from the incoming stream of scrambled idle
symbols. The descrambler requires approximately 15 s to lock, normally accomplished during the
training phase.
Interconnects—Ethernet Controller I210
129
3.7.8.7.3.7 Viterbi Decoder/Decision Feedback Equalizer (DFE)
The Viterbi decoder generates clean 4DPAM5 symbols from the output of the DSP. The decoder includes
a Trellis encoder identical to the one used by the transmitter. The Viterbi decoder simultaneously looks
at the received data over several baud periods. For each baud period, it predicts whether the symbol
received should be even or odd, and compares that to the actual symbol received. The 4DPAM5 code is
organized in such a way that a single level error on any channel changes an even code to an odd one
and vice versa. In this way, the Viterbi decoder can detect single-level coding errors, effectively
improving the signal-to-noise (SNR) ratio by a factor of 6 dB. When an error occurs, this information is
quickly fed back into the equalizer to prevent future errors.
3.7.8.7.3.8 4DPAM5 Decoder
The 4DPAM5 decoder generates 8-byte data from the output of the Viterbi decoder.
3.7.8.7.3.9 100 Mb/s Operation
The MAC passes data to the PHY over the MII. The PHY encodes and scrambles the data, then transmits
it using MLT-3 for 100TX over copper. The PHY de-scrambles and decodes MLT-3 data received from
the network. When the MAC is not actively transmitting data, the PHY sends out idle symbols on the
line.
3.7.8.7.3.10 10 Mb/s Operation
The PHY operates as a standard 10 Mb/s transceiver. Data transmitted by the MAC as 4-bit nibbles is
serialized, Manchester-encoded, and transmitted on the MDI[0]+/- outputs. Received data is decoded,
de-serialized into 4-bit nibbles and passed to the MAC across the internal MII. The PHY supports all the
standard 10 Mb/s functions.
3.7.8.7.3.11 Link Test
In 10 Mb/s mode, the PHY always transmits link pulses. If link test function is enabled, it monitors the
connection for link pulses. Once it detects two to seven link pulses, data transmission are enabled and
remain enabled as long as the link pulses or data reception continues. If the link pulses stop, the data
transmission is disabled.
If the link test function is disabled, the PHY might transmit packets regardless of detected link pulses.
Setting the Port Configuration register bit (PHYREG 0,16.14) can disable the link test function.
3.7.8.7.3.12 10Base-T Link Failure Criteria and Override
Link failure occurs if link test is enabled and link pulses stop being received. If this condition occurs, the
PHY returns to the auto-negotiation phase, if auto-negotiation is enabled. Setting the Port Configuration
register bit (PHYREG 0,16.14) disables the link integrity test function, then the PHY transmits packets,
regardless of link status.
3.7.8.7.3.13 Jabber
If the MAC begins a transmission that exceeds the jabber timer, the PHY disables the transmit and
loopback functions and asserts collision indication to the MAC. The PHY automatically exits jabber mode
after 250-750 ms. This function can be disabled by setting bit PHYREG 0,16.10 = 1b.
Ethernet Controller I210 —Interconnects
130
3.7.8.7.3.14 Polarity Correction
The PHY automatically detects and corrects for the condition where the receive signal (MDI_PLUS[0]/
MDI_MINUS[0]) is inverted. Reversed polarity is detected if eight inverted link pulses or four inverted
end-of-frame markers are received consecutively. If link pulses or data are not received for 96-130 ms,
the polarity state is reset to a non-inverted state.
Automatic polarity correction can be disabled by setting bit PHYREG 0,16 bit 1.
3.7.8.7.3.15 Dribble Bits
The PHY handles dribble bits for all of its modes. If between one and four dribble bits are received, the
nibble is passed across the interface. The data passed across is padded with 1's if necessary. If
between five and seven dribble bits are received, the second nibble is not sent onto the internal MII bus
to the MAC. This ensures that dribble bits between 1-7 do not cause the MAC to discard the frame due
to a CRC error.
3.7.8.7.3.16 PHY Address
The external PHY MDIO Address is defined in the MDICNFG.PHYADD field and is loaded at power-up
from the Flash. If the MDICNFG.Destination bit is cleared (internal PHY), MDIO access is always to the
internal PHY.
Initialization—Ethernet Controller I210
133
4.0 Initialization
4.1 Power Up
4.1.1 Power-Up Sequence
Figure 4-1 shows the power-up sequence from power ramp up and to when the I210 is ready to accept
host commands.
Note: The Keep_PHY_Link_Up bit (Veto bit) is set by firmware when the MC is running IDER or SoL.
Its purpose is to prevent interruption of these processes when power is being turned on.
Figure 4-1. Power-Up - General Flow
Vccpoweron
LAN_PWR_GOODreset
LoadFlash
InitializeFirmware
ConfigureMACandPHY
InitializeManageabilitylink
PE_RST_nreset
InitializePCIe
RunManageabilityFirmware
Drmode
Platform
powered
?
No
Yes
D0mode
Vetobit
on?
ResetMAC
LoadFlash
no
yes
ResetPHY
Hardwareoperation
Firmwareoperation
Ethernet Controller I210 —Initialization
134
4.1.2 Power-Up Timing Diagram
4.2 Reset Operation
The I210 has a number of reset sources described in the sections that follow. After a reset, the software
device driver should verify that the EEMNGCTL.CFG_DONE bit (refer to Section 8.4.18) is set to 1b and
no errors were reported in the FWSM.Ext_Err_Ind (refer to Section 8.7.2) field.
Figure 4-2. Power-Up Timing Diagram
Table 4-1. Notes to Power-Up Timing Diagram
Note
1 Xosc is stable txog after the Power is stable
2 Internal Reset is released after all power supplies are good and tppg after Xosc is stable.
3 A Flash read starts on the rising edge of the internal Reset or LAN_PWR_GOOD.
4 After reading the Flash, the PHY might exit power down mode.
5 APM Wakeup and/or manageability might be enabled based on Flash contents.
6 The PCIe reference clock is valid tPE_RST-CLK before the de-assertion of PE_RST# (according to PCIe specification).
7 PE_RST# is de-asserted tPVPGL after power is stable (according to PCIe specification).
8De-assertion of PE_RST# causes the Flash to be re-read, asserts PHY power-down (except if the Veto bit also known as
Keep_PHY_Link_Up bit is set), and disables Wake Up.
9 After reading the Flash, the PHY exits power-down mode.
10 Link training starts after tpgtrn from PE_RST# de-assertion.
11 A first PCIe configuration access might arrive after tpgcfg from PE_RST# de-assertion.
12 A first PCI configuration response can be sent after tpgres from PE_RST# de-assertion
13 Writing a 1b to the Memory Access Enable bit in the PCI Command Register transitions the device from D0u to D0 state.
D‐State D0u
FlashLoad
D0a
PHYState
PCIeLinkUp L0
Manageability/Wake
4
5
7
Dr
8
9
10
3
Power
Power‐On‐Reset
(internal)
2
PCIe
referenceclock
PERST#
Xos c
1
6
txog
tee tee
11 12
tpgtrn
13
tpgres
tpgcfg
tPWRGDCLK
tPVP GL
tppg
Auto
Read
Ext.
Conf.
Auto
Read
Ext.
Conf.
nwoD/evitcAnwodderewoP
Initialization—Ethernet Controller I210
135
4.2.1 Reset Sources
The I210 reset sources are described in the sections that follow.
4.2.1.1 LAN_PWR_GOOD
The I210 has an internal mechanism for sensing the power pins. Once power is up and stable, the I210
creates an internal reset. This reset acts as a master reset of the entire chip. It is level sensitive, and
while it is zero holds all of the registers in reset. LAN_PWR_GOOD is interpreted to be an indication that
device power supplies are all stable. Note that LAN_PWR_GOOD changes state during system power-
up.
4.2.1.2 PE_RST_N
De-asserting PE_RST_N indicates that both the power and the PCIe clock sources are stable. This pin
asserts an internal reset also after a D3cold exit. Most units are reset on the rising edge of PE_RST_N.
The only exception is the PCIe unit, which is kept in reset while PE_RST_N is asserted (level).
4.2.1.3 In-Band PCIe Reset
The I210 generates an internal reset in response to a physical layer message from the PCIe or when
the PCIe link goes down (entry to polling or detect state). This reset is equivalent to PCI reset in
previous (PCI) GbE LAN controllers.
4.2.1.4 D3hot to D0 Transition
This is also known as ACPI reset. The I210 generates an internal reset on the transition from D3hot
power state to D0 (caused after configuration writes from D3 to D0 power state).
When the PMCSR.No_Soft_Reset bit in the configuration space is set, on transition from D3hot to D0
the I210 resets internal CSRs (similar to CTRL.RST assertion) but doesn’t reset registers in the PCIe
configuration space. If the PMCSR.No_Soft_Reset bit is cleared, the I210 resets all per-function
registers except for registers defined as sticky in the configuration space.
Note: Regardless of the value of the PMCSR.No_Soft_Reset bit, the function is reset (including bits
that are not defined as sticky in PCIe configuration space) if the link state has transitioned to
the L2/L3 ready state, on transition from D3cold to D0, if Function Level Reset (FLR) is
asserted or if transition D3hot to D0 is caused by asserting the PCIe reset (PE_RST pin).
Note: Software device drivers should implement the handshake mechanism defined in
Section 5.2.3.3 to verify that all pending PCIe completions finish, before moving the I210 to
D3.
4.2.1.5 FLR
A FLR function reset is issued by setting bit 15 in the Device Control configuration register (refer to
Section 9.4.6.5), which is equivalent to a D0 D3 D0 transition. The only difference is that this reset
does not require software device driver intervention in order to stop the master transactions of this
function. The Flash content is partially reloaded after a FLR reset. The words read from Flash at FLR are
the same as read following a full software reset. A list of these words can be found in Section 3.3.1.2.
Ethernet Controller I210 —Initialization
136
A FLR reset to a function resets all the queues, interrupts, and statistics registers attached to the
function. It also resets PCIe read/write configuration bits as well as disables transmit and receive flows
for the queues allocated to the function. All pending read requests are dropped and PCIe read
completions to the function might be completed as unexpected completions and silently discarded
(following update of flow control credits) without logging or signaling as an error.
Note: If software initiates a FLR when the Transactions Pending bit in the Device Status
configuration register is set to 1b (refer to Section 9.4.6.6), then software must not initialize
the function until allowing time for any associated completions to arrive. The Transactions
Pending bit is cleared upon completion of the FLR.
4.3 Software Reset
4.3.1 Software Reset (RST)
Software can reset the I210 by setting the Software Reset (CTRL.RST) bit in the Device Control
register. Following reset, the PCI configuration space (configuration and mapping) of the device is
unaffected. Prior to issuing a software reset the software device driver needs to operate the master
disable algorithm as defined in Section 5.2.3.3.
The CTRL.RST bit is provided primarily to recover from an indeterminate or suspected port hung
hardware state. Most registers (receive, transmit, interrupt, statistics, etc.) and state machines in the
port are set to their power-on reset values, approximating the state following a power-on or PCIe reset
(refer to Table 4-3 for further information on affects of software reset). However, PCIe configuration
registers and DMA logic is not reset, leaving the device mapped into system memory space and
accessible by a software device driver.
Note: To ensure that a software reset fully completed and that the I210 responds correctly to
subsequent accesses after setting the CTRL.RST bit, the software device driver should wait at
least 3 ms before accessing any register and then verify that EEC.Auto_RD is set to 1b and
that the STATUS.PF_RST_DONE bit is set to 1b.
When asserting the CTRL.RST software reset bit, only some Flash bits related to the specific function
are re-read (refer to Section 3.3.1.2). Bits re-read from Flash are reset to default values.
4.3.1.1 Bus Master Enable (BME)
Disabling bus master activity of a function by clearing the Configuration Command register.BME bit to
0b, resets all DMA activities and MSI/MSIx operations related to the port. The master disable resets
only the DMA activities related to this function without affecting activity of other functions or LAN ports.
Configuration accesses and target accesses to the function are still enabled and the Management
Controller (MC) can still transmit and receive packets on the port.
A Master Disable resets all the queues and DMA related interrupts. It also disables the transmit and
receive flows. All pending read requests are dropped and PCIe read completions to this function might
be completed as unexpected completions and silently discarded (following update of flow control
credits) without logging or signaling it as an error.
Note: Prior to issuing a master disable the software device driver needs to implement the master
disable algorithm as defined in Section 5.2.3.3. After Master Enable is set back to 1b,the
software device driver should re-initialize the transmit and receive queues.
Initialization—Ethernet Controller I210
137
4.3.1.2 Force TCO
This reset is generated when manageability logic is enabled and the MC detects that the I210 does not
receive or transmit data correctly. Force TCO reset is enabled if the Reset on Force TCO bit in the
Management Control Flash word is set 1b. Table 4-3 describes affects of TCO reset on the I210
functionality.
Force TCO reset is generated in pass through mode when the MC issues a Force TCO command with bit
1 set and the previous conditions exist.
4.3.1.3 Flash Reset
Writing a 1b to the Flash Reset bit of the Extended Device Control Register (CTRL_EXT.EE_RST) causes
the I210 to re-read the per-function configuration from the Flash, setting the appropriate bits in the
registers loaded by the Flash.
4.3.1.4 PHY Reset
Software can write a 1b to the PHY Reset bit of the Device Control Register (CTRL.PHY_RST) to reset
the internal PHY. The PHY is internally configured after a PHY reset.
Note: The internal PHY should not be reset using PHYREG 0,0 bit 15 (Copper Control
Register.Copper Reset), since in this case, the internal PHY configuration process is bypassed
and there is no guarantee the PHY operates correctly.
Because the PHY can be accessed by the internal firmware and software device driver software, the
software device driver software should coordinate any PHY reset with the firmware using the following
procedure:
1. Check that MANC.BLK_Phy_Rst_On_IDE (offset 0x5820 bit 18) is cleared. If set, the MC requires a
stable link and thus the PHY should not be reset at this stage. The software device driver might skip
the PHY reset if not mandatory or wait for MANC.BLK_Phy_Rst_On_IDE to clear. Refer to
Section 4.3.3 for more details.
2. Take ownership of the PHY using the following flow:
a. Get ownership of the software/firmware semaphore SWSM.SWESMBI bit (offset 0x5B50 bit 1):
Set the SWSM.SWESMBI bit.
Read SWSM.
If SWSM.SWESMBI was successfully set (semaphore was acquired); otherwise, go back to
step a.
This step assures that the internal firmware does not access the shared resources register
(SW_FW_SYNC).
b. Software reads the Software-Firmware Synchronization Register (SW_FW_SYNC) and checks the
bit that controls the PHY it wants to own.
If the bit is set (firmware owns the PHY), software tries again later.
c. Release ownership of the software/firmware semaphore by clearing the SWSM.SWESMBI bit.
3. Drive the PHY reset bit in CTRL bit 31.
4. Wait 100 s.
5. Release PHY reset in CTRL bit 31.
6. Release ownership of the relevant PHY to firmware using the following flow:
a. Get ownership of the software/firmware semaphore SWSM.SWESMBI (offset 0x5B50 bit 1):
Ethernet Controller I210 —Initialization
138
Set the SWSM.SWESMBI bit.
Read SWSM.
If SWSM.SWESMBI was successfully set (semaphore was acquired); otherwise, go back to
step a.
Clear the bit in SW_FW_SYNC that control the software ownership of the resource to
indicate this resource is free.
Release ownership of the software/firmware semaphore by clearing the SWSM.SWESMBI
bit.
7. Wait for the CFG_DONE bit (EEMNGCTL.CFG_DONE0).
8. Take ownership of the relevant PHY using the following flow:
a. Get ownership of the software/firmware semaphore SWSM.SWESMBI (offset 0x5B50 bit 1):
Set the SWSM.SWESMBI bit.
Read SWSM.
If SWSM.SWESMBI was successfully set (semaphore was acquired); otherwise, go back to
step a.
This step assures that the internal firmware does not access the shared resources register
(SW_FW_SYNC).
b. Software reads the Software-Firmware Synchronization Register (SW_FW_SYNC) and checks the
bit that controls the PHY it wants to own.
If the bit is set (firmware owns the PHY), software tries again later.
c. Release ownership of the software/firmware semaphore by clearing SWSM.SWESMBI bit.
9. Configure the PHY.
10. Release ownership of the relevant PHY using the flow described in Section 4.6.2.
Note: Software PHY ownership should not exceed 100 ms. If software takes PHY ownership for a
longer duration, firmware might implement a timeout mechanism and take ownership of the
PHY.
4.3.2 Registers and Logic Reset Affects
The resets affect the following registers and logic:
Table 4-2. I210 Reset Affects - Common Resets
Reset Activation LAN_PWR_GOOD PE_
RST_N In-Band PCIe Reset FW
Reset Notes
LTSSM (PCIe Back to Detect/
Polling) X X X
PCIe Link Data Path X X X
Read Flash 16.
Read Flash (Complete Load) X X X
PCI Configuration Registers -
Non Sticky X X X 3.
PCI Configuration Registers -
Sticky X X X 4.
PCIe Local Registers X X X 5.
Data Path X X X
On-die Memories X X X 13.
Initialization—Ethernet Controller I210
139
MAC, PCS, Auto Negotiation and
Other Port Related Logic X X X
DMA X X X
Functions Queue Enable X X X
Function interrupt and Statistics
Registers X X X
Wake Up (PM) Context X 7.
Wake Up Control Register X 8.
Wake Up Status Registers X 9.
Manageability Control Registers X 10.
MMS Unit X X
Wake-Up Management Registers X X X 3.,11.
Memory Configuration Registers X X X 3.
Flash Requests X 14.
PHY/SerDes PHY X X X 2.
Strapping Pins X X X
Table 4-3. I210 Reset Affects - Other Resets
Reset Activation D3hotD0 FLR
Port SW
Reset
(CTRL.RST)
Force
TCO
EE
Reset
PHY
Reset Notes
Port Configuration
Autoload from Flash X X X X X
PCI Configuration
Registers Read Only 3.
PCI Configuration
Registers MSI-X X X 6.
PCI Configuration
Registers Read/Write
PCIe Local Registers 5.
Data Path X X X X
On-die Memories X X X X 13.
MAC, PCS, Auto
Negotiation and Other Port
Related Logic X X X X
DMA X X X 15.
Wake Up (PM) Context 7.
Wake Up Control Register 8.
Wake Up Status Registers 9.
Manageability Control
Registers 10.
Function Queue Enable X X X X
Function Interrupt and
Statistics Registers X X X
Wake-Up Management
Registers X X X X 3.,11.
Memory Configuration
Registers X X X X 3.
Table 4-2. I210 Reset Affects - Common Resets (Continued)
Reset Activation LAN_PWR_GOOD PE_
RST_N In-Band PCIe Reset FW
Reset Notes
Ethernet Controller I210 —Initialization
140
Notes:
1. If AUX_POWER = 0b the Wakeup Context is reset (PME_Status and PME_En bits should be 0b at
reset if the I210 does not support PME from D3cold).
2. The MMS unit must configure the PHY after any PHY reset.
3. The following register fields do not follow the general rules previously described:
a. CTRL.SDP0_IODIR, CTRL.SDP1_IODIR, CTRL_EXT.SDP2_IODIR, CTRL_EXT.SDP3_IODIR,
CONNSW.ENRGSRC field, CTRL_EXT.SFP_Enable, CTRL_EXT.LINK_MODE, CTRL_EXT.EXT_VLAN
and LED configuration registers are reset on LAN_PWR_GOOD only. Any Flash read resets these
fields to the values in the Flash.
b. The Aux Power Detected bit in the PCIe Device Status register is reset on LAN_PWR_GOOD and
PE_RST_N (PCIe reset) assertion only.
c. FLA - reset on LAN_PWR_GOOD only.
d. The bits mentioned in the next note.
4. The following registers are part of this group:
a. VPD registers
b. Max payload size field in PCIe Capability Control register (offset 0xA8).
c. Active State Link PM Control field, Common Clock Configuration field and Extended Synch field
in PCIe Capability Link Control register (Offset 0xB0).
d. Read Completion Boundary in the PCIe Link Control register (Offset 0xB0).
5. The following registers are part of this group:
a. SWSM
b. GCR (only part of the bits - see register description for details)
c. FUNCTAG
d. GSCL_1/2/3/4
e. GSCN_0/1/2/3
f. SW_FW_SYNC - only part of the bits - see register description for details.
6. The following registers are part of this group:
a. MSIX control register, MSIX PBA and MSIX per vector mask.
7. The Wake Up Context is defined in the PCI Bus Power Management Interface Specification (sticky
bits). It includes:
PME_En bit of the Power Management Control/Status Register (PMCSR).
PME_Status bit of the Power Management Control/Status Register (PMCSR).
Aux_En in the PCIe registers
The device Requester ID (since it is required for the PM_PME TLP).
Flash Request X X 14.
PHY/SerDes PHY X X X X 2.
Strapping Pins
Table 4-3. I210 Reset Affects - Other Resets (Continued)
Reset Activation D3hotD0 FLR
Port SW
Reset
(CTRL.RST)
Force
TCO
EE
Reset
PHY
Reset Notes
Initialization—Ethernet Controller I210
141
The shadow copies of these bits in the Wakeup Control register are treated identically.
8. Refers to bits in the Wake Up Control register that are not part of the Wake-Up Context (the
PME_En and PME_Status bits).
9. The Wake Up Status registers include the following:
a. Wake Up Status register
b. Wake Up Packet Length.
c. Wake Up Packet Memory.
10. The Manageability Control registers refer to the following registers:
a. MANC 0x5820
b. MFUTP0-15 0x5030 - 0x504C
c. MNGONLY 0x5864
d. MAVTV0-7 0x5010 - 0x502C
e. MDEF0-7 0x5890 - 0x58AC
f. MDEF_EXT 0x5930 - 0x594C
g. METF0-3 0x5060 - 0x506C
h. MIPAF0-15 0x58B0 - 0x58EC
i. MMAH/MMAL0-1 0x5910 - 0x591C
j. FWSM
11. The Wake-up Management registers include the following:
a. Wake Up Filter Control
b. IP Address Valid
c. IPv4 Address Table
d. IPv6 Address Table
e. Flexible Filter Length Table
f. Flexible Filter Mask Table
12. The other configuration registers include:
a. General Registers
b. Interrupt Registers
c. Receive Registers
d. Transmit Registers
e. Statistics Registers
f. Diagnostic Registers
Of these registers, MTA[n], VFTA[n], WUPM[n], FTFT[n], FHFT[n], FHFT_EXT[n], TDBAH/TDBAL, and
RDBAH/RDVAL registers have no default value. If the functions associated with the registers are
enabled, they must be programmed by software. Once programmed, their value is preserved through
all resets as long as power is applied to the I210.
Note: In situations where the device is reset using the software reset CTRL.RST or CTRL.DEV_RST,
the transmit data lines are forced to all zeros. This causes a substantial number of symbol
errors detected by the link partner. In TBI mode, if the duration is long enough, the link
partner might restart the auto-negotiation process by sending break-link (/C/ codes with the
configuration register value set to all zeros).
13. The contents of the following memories are cleared to support the requirements of PCIe FLR:
Ethernet Controller I210 —Initialization
142
a. The Tx packet buffers
b. The Rx packet buffers
14. Includes EEC.REQ, EEC.GNT, FLA.REQ and FLA.GNT fields.
15. The following DMA registers are cleared only by LAN_PWR_GOOD, PCIe Reset or CTRL.DEV_RST:
DMCTLX, DTPARS, DRPARS and DDPARS.
16. CTRL.DEV_RST assertion causes read of function related sections.
4.3.3 PHY Behavior During a Manageability Session
During some manageability sessions (such as an IDER or SoL session as initiated by an external MC),
the platform is reset so that it boots from a remote media. This reset must not cause the Ethernet link
to drop since the manageability session is lost. Also, the Ethernet link should be kept on continuously
during the session for the same reasons. The I210 therefore limits the cases in which the internal PHY
would restart the link, by masking two types of events from the internal PHY:
PE_RST# and PCIe resets (in-band and link drop) do not reset the PHY during such a manageability
session
The PHY does not change link speed as a result of a change in power management state, to avoid
link loss. For example, the transition to D3hot state is not propagated to the PHY.
Note however that if main power is removed, the PHY is allowed to react to the change in power
state (the PHY might respond in link speed change). The motivation for this exception is to
reduce power when operating on auxiliary power by reducing link speed.
The capability described in this section is disabled by default on LAN_POWER_GOOD reset. The
Keep_PHY_Link_Up_En bit in the Flash must be set to 1b to enable it. Once enabled, the feature is
enabled until the next LAN_POWER_GOOD (the I210 does not revert to the hardware default value on
PE_RST#, PCIe reset or any other reset but LAN_POWER_GOOD).
When the Keep_PHY_Link_Up bit (also known as Veto bit) in the MANC register is set, the following
behaviors are disabled:
The PHY is not reset on PE_RST# and PCIe resets (in-band and link drop). Other reset events are
not affected - LAN_POWER_GOOD reset, Device Disable, Force TCO, and PHY reset by software.
The PHY does not change its power state. As a result link speed does not change.
The I210 does not initiate configuration of the PHY to avoid losing link.
The Keep_PHY_Link_Up bit is set by the MC through the Management Control command (refer to
Section 10.5.9.1.5 for SMBus command and Section 10.6.3.10 for NC-SI command) on the sideband
interface. It is cleared by the external MC (again, through a command on the sideband interface) when
the manageability session ends. Once the Keep_PHY_Link_Up bit is cleared, the PHY updates its Dx
state and acts accordingly (negotiates its speed).
The Keep_PHY_Link_Up bit is a read/write bit and can be accessed by host software, but software is not
expected to clear the bit. The bit is cleared in the following cases:
On LAN_POWER_GOOD.
When the MC resets or initializes it.
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4.4 Device and Function Disable
4.4.1 General
For a LAN on Motherboard (LOM) design, it might be desirable for the system to provide BIOS-setup
capability for selectively enabling or disabling LAN functions. It enables the end-user more control over
system resource-management and avoid conflicts with add-in NIC solutions. The I210 provides support
for selectively enabling or disabling one or more LAN device(s) in the system.
Device presence (or non-presence) must be established early during BIOS execution, in order to ensure
that BIOS resource-allocation (of interrupts, of memory or I/O regions) is done according to devices
that are present only. This is frequently accomplished using a BIOS Configuration Values Driven on
Reset (CVDR) mechanism. The I210 LAN-disable mechanism is implemented in order to be compatible
with such a solution.
4.4.2 Disabling Both LAN Port and PCIe Function (Device Off)
The I210 provides a mechanism to disable its LAN port and the PCIe function. When DEV_OFF_N is
asserted (driven low) and the Device Off Enable Flash bit (in word 0x1E) is set to 1b (refer to
Section 6.2.19).
For a LOM design, it might be desirable for the system to provide BIOS-setup capability for selectively
enabling or disabling LOM devices. This might allow the end-user more control over system resource-
management; avoid conflicts with add-in NIC solutions, etc. The I210 provides support for selectively
enabling or disabling it.
While in device disable mode, the PCIe link is in L3 state. The PHY is in power down mode. Output
buffers are tri-stated.
Asserting or deasserting PCIe PE_RST_N does not have any affect while the device is in device disable
mode (the device stays in the respective mode as long as the right settings on DEV_OFF_N). However,
the device might momentarily exit the device disable mode from the time PCIe PE_RST_N is de-
asserted again and until the Flash is read.
During power-up, the input pin DEV_OFF_N is ignored until the Flash is read. From that point, the
device might enter device disable according to the Flash settings.
4.4.3 Disabling PCIe Function Only
The I210 also supports disabling just the PCIe function but keeping the LAN port that resides on it fully
active (for manageability purposes and BMC pass-through traffic). This functionality can be achieved by
driving SDP1 pin low and setting Flash en_pin_pcie_func_dis bit (word 0x29) to 1b.
Note: In this case when only the PCIe function is disabled, if the PHPM.LPLU register bit is set to 1b,
the internal copper PHY attempts to create a link with its link partner at the lowest common
link speed via Auto-negotiation.
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4.4.4 BIOS Handling of Device Disable
4.4.4.1 Sequence for Entering the (Static) Device Off State
1. BIOS recognizes that the entire device should be disabled. The Device Off Enable Flash bit in word
0x1E should be set to 1b.
a. In order to shut down the PHY together with the rest of the device, the PHY_in_LAN_Disable
Flash bit (refer to Section 6.2.21) should be set to 1b.
2. BIOS asserts the DEV_OFF_N pin (device is on and not in PCIe reset).
3. BIOS issues a PCIe reset
4. PCIe reset sequence ends while the device is already in off state (minimum PCIe reset duration is
100 s).
5. The BIOS places the Link in the Electrical IDLE state (at the other end of the PCIe link) by clearing
the LINK Disable bit in the Link Control register.
6. BIOS might start with the device enumeration procedure (the I210 device function is now invisible).
7. Proceed with normal operation.
4.4.4.2 Sequence for Returning from the (Static) Device Off State
1. Device is in its off state.
2. BIOS de-asserts the DEV_OFF_N pin (while device is off but not while in PCIe reset)
3. BIOS issues a PCIe reset.
4. PCIe reset sequence ends while the device is already in on state (PCIe interface must be operative
within 100 ms).
5. BIOS might start with the device enumeration procedure (the I210 device function is now visible).
6. Proceed with normal operation.
4.5 Software Initialization and Diagnostics
4.5.1 Introduction
This section discusses general software notes for the I210, especially initialization steps. This includes
general hardware, power-up state, basic device configuration, initialization of transmit and receive
operation, link configuration, software reset capability, statistics, and diagnostic hints.
4.5.2 Power Up State
When the I210 powers up it reads the Flash. The Flash contains sufficient information to bring the link
up and configure the I210 for manageability and/or APM wakeup. However, software initialization is
required for normal operation.
The power-up sequence, as well as transitions between power states, are described in Section 4.1.1.
The detailed timing is given in Section 5.5. The next section gives more details on configuration
requirements.
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4.5.3 Initialization Sequence
The following sequence of commands is typically issued to the device by the software device driver in
order to initialize the I210 to normal operation. The major initialization steps are:
Disable Interrupts - see Interrupts during initialization.
Issue Global Reset and perform General Configuration - see Global Reset and General
Configuration.
Setup the PHY and the link - see Link Setup Mechanisms and Control/Status Bit Summary.
Initialize all statistical counters - refer to Section 4.5.8.
Initialize Receive - refer to Section 4.5.9.
Initialize Transmit - refer to Section 4.5.10.
Enable Interrupts - refer to Section 4.5.4.
4.5.4 Interrupts During Initialization
Most drivers disable interrupts during initialization to prevent re-entering the interrupt routine.
Interrupts are disabled by writing to the Extended Interrupt Mask Clear (EIMC) register. Note that
the interrupts need to be disabled also after issuing a global reset, so a typical driver initialization
flow is:
Disable interrupts
Issue a Global Reset
Disable interrupts (again)
After initialization completes, a typical software device driver enables the desired interrupts by writing
to the Extended Interrupt Mask Set (EIMS) register.
4.5.5 Global Reset and General Configuration
Device initialization typically starts with a global reset that places the device into a known state and
enables the software device driver to continue the initialization sequence.
Several values in the Device Control (CTRL) register need to be set, upon power up, or after a device
reset for normal operation.
The FD bit should be set per interface negotiation (if done in software), or is set by the hardware if
the interface is auto-negotiating. This is reflected in the Device Status Register in the auto-
negotiation case.
Speed is determined via auto-negotiation by the PHY, auto-negotiation by the PCS layer in SGMII/
SerDes mode, or forced by software if the link is forced. Status information for speed is also
readable in the STATUS register.
The ILOS bit should normally be set to 0b.
4.5.6 Flow Control Setup
If flow control is enabled, program the FCRTL0, FCRTH0, FCTTV and FCRTV registers. In order to avoid
packet losses, FCRTH should be set to a value equal to at least two maximum size packets below the
receive buffer size (assuming a packet buffer size of 36 KB and the expected maximum size packet of
9.5 KB), the FCRTH0 value should be set to 36 - 2 * 9.5 = 17KB.For example, FCRTH0.RTH should be
set to 0x440.
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The receive buffer size is controlled by RXPBSIZE.Rxpbsize register field. Refer to Section 4.5.9 for its
setting rules.
If DMA coalescing is enabled, to avoid packet loss, the FCRTC.RTH_Coal field should also be
programmed to a value equal to at least a single maximum packet size below the receive buffer size (a
value equal or less than FCRTH0.RTH + max size packet).
4.5.7 Link Setup Mechanisms and Control/Status Bit Summary
The CTRL_EXT.LINK_MODE value should be set to the desired mode prior to the setting of the other
fields in the link setup procedures.
4.5.7.1 PHY Initialization
Refer to the PHY documentation for the initialization and link setup steps. The software device driver
uses the MDIC register to initialize the PHY and setup the link. Section 3.7.4.4 describes the link setup
for the internal copper PHY. Section 3.7.2.2 Section describes the usage of the MDIC register.
4.5.7.2 MAC/PHY Link Setup (CTRL_EXT.LINK_MODE = 00b)
This section summarizes the various means of establishing proper MAC/PHY link setups, differences in
MAC CTRL register settings for each mechanism, and the relevant MAC status bits. The methods are
ordered in terms of preference (the first mechanism being the most preferred).
4.5.7.2.1 MAC Settings Automatically Based on Duplex and Speed Resolved by PHY
(CTRL.FRCDPLX = 0b, CTRL.FRCSPD = 0b,)
CTRL.FD Don't care; duplex setting is established from PHY's internal indication to the
MAC (FDX) after PHY has auto-negotiated a successful link-up.
CTRL.SLU Must be set to 1b by software to enable communications between MAC and PHY.
CTRL.RFCE Must be programmed by software after reading capabilities from PHY registers
and resolving the desired flow control setting.
CTRL.TFCE Must be programmed by software after reading capabilities from PHY registers
and resolving the desired flow control setting.
CTRL.SPEED Don't care; speed setting is established from PHY's internal indication to the MAC
(SPD_IND) after PHY has auto-negotiated a successful link-up.
STATUS.FD Reflects the actual duplex setting (FDX) negotiated by the PHY and indicated to
MAC.
STATUS.LU Reflects link indication (LINK) from PHY qualified with CTRL.SLU (set to 1b).
STATUS.SPEED Reflects actual speed setting negotiated by the PHY and indicated to the MAC
(SPD_IND).
4.5.7.2.2 MAC Duplex and Speed Settings Forced by Software Based on Resolution of PHY
(CTRL.FRCDPLX = 1b, CTRL.FRCSPD = 1b)
CTRL.FD Set by software based on reading PHY status register after PHY has auto-
negotiated a successful link-up.
CTRL.SLU Must be set to 1b by software to enable communications between MAC and PHY.
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CTRL.RFCE Must be programmed by software after reading capabilities from PHY registers
and resolving the desired flow control setting.
CTRL.TFCE Must be programmed by software after reading capabilities from PHY registers
and resolving the desired flow control setting.
CTRL.SPEED Set by software based on reading PHY status register after PHY has auto-
negotiated a successful link-up.
STATUS.FD Reflects the MAC forced duplex setting written to CTRL.FD.
STATUS.LU Reflects link indication (LINK) from PHY qualified with CTRL.SLU (set to 1b).
STATUS.SPEED Reflects MAC forced speed setting written in CTRL.SPEED.
4.5.7.2.3 MAC/PHY Duplex and Speed Settings Both Forced by Software (Fully-Forced
Link Setup) (CTRL.FRCDPLX = 1b, CTRL.FRCSPD = 1b, CTRL.SLU = 1b)
CTRL.FD Set by software to desired full/half duplex operation (must match duplex setting
of PHY).
CTRL.SLU Must be set to 1b by software to enable communications between MAC and PHY.
PHY must also be forced/configured to indicate positive link indication (LINK) to
the MAC.
CTRL.RFCE Must be programmed by software to desired flow-control operation (must match
flow-control settings of PHY).
CTRL.TFCE Must be programmed by software to desired flow-control operation (must match
flow-control settings of PHY).
CTRL.SPEED Set by software to desired link speed (must match speed setting of PHY).
STATUS.FD Reflects the MAC duplex setting written by software to CTRL.FD.
STATUS.LU Reflects 1b (positive link indication LINK from PHY qualified with CTRL.SLU).
Note that since both CTRL.SLU and the PHY link indication LINK are forced, this
bit set does not guarantee that operation of the link has been truly established.
STATUS.SPEED Reflects MAC forced speed setting written in CTRL.SPEED.
4.5.7.3 MAC/SERDES Link Setup (CTRL_EXT.LINK_MODE = 11b)
Link setup procedures using an external SERDES interface mode:
4.5.7.3.1 Hardware Auto-Negotiation Enabled (PCS_LCTL. AN ENABLE = 1b;
CTRL.FRCSPD = 0b; CTRL.FRCDPLX = 0b)
CTRL.FD Ignored; duplex is set by priority resolution of PCS_ANDV and PCS_LPAB.
CTRL.SLU Must be set to 1b by software to enable communications to the SerDes.
CTRL.RFCE Set by hardware according to auto negotiation resolution1.
CTRL.TFCE Set by hardware according to auto negotiation resolution1.
CTRL.SPEED Ignored; speed always 1000 Mb/s when using SerDes mode communications.
STATUS.FD Reflects hardware-negotiated priority resolution.
STATUS.LU Reflects PCS_LSTS.AN COMPLETE (auto-negotiation complete) and link is up.
1. If PCS_LCTL.Force Flow Control is set, the auto-negotiation result is not reflected in the CTRL.RFCE
and CTRL.TFCE registers. In this case, software must set these fields after reading flow control
resolution from PCS registers.
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STATUS.SPEED Reflects 1000Mb/s speed, reporting fixed value of 10b.
PCS_LCTL.FSD Must be zero.
PCS_LCTL.Force Flow Control Must be zero1.
PCS_LCTL.FSV Must be set to 10b. Only 1000 Mb/s is supported in SerDes mode.
PCS_LCTL.FDV Ignored; duplex is set by priority resolution of PCS_ANDV and PCS_LPAB.
PCS_LCTL.AN TIMEOUT EN Must be 1b to enable auto-negotiation time-out.
CONNSW.ENRGSRC Must be 0b on 1000BASE-BX backplane, when source of the signal detect
indication is internal. When connected to an optical module and
SRDS_[n]_SIG_DET pin is connected to the module, should be 1b.
CTRL.ILOS If SRDS_[n]_SIG_DET pin connected to optical module, should be set according
to optical module polarity.
4.5.7.3.2 Auto-Negotiation Skipped (PCS_LCTL. AN ENABLE = 0b; CTRL.FRCSPD = 1b;
CTRL.FRCDPLX = 1b)
CTRL.FD Must be set to 1b. Only full duplex is supported in SerDes mode.
CTRL.SLU Must be set to 1b by software to enable communications to the SerDes.
CTRL.RFCE Must be 0b (No auto-negotiation).
CTRL.TFCE Must be 0b (No auto-negotiation).
CTRL.SPEED Must be set to 10b. Only 1000 Mb/s is supported in SerDes mode.
STATUS.FD Reflects the value written by software to CTRL.FD.
STATUS.LU Reflects whether the PCS is synchronized, qualified with CTRL.SLU (set to 1b).
STATUS.SPEED Reflects 1000 Mb/s speed, reporting fixed value of (10b).
PCS_LCTL.FSD Must be set to 1b by software to enable communications to the SerDes.
PCS_LCTL.Force Flow Control Must be set to 1b.
PCS_LCTL.FSV Must be set to 10b. Only 1000 Mb/s is supported in SerDes mode.
PCS_LCTL.FDV Must be set to 1b Only full duplex is supported in SerDes mode.
PCS_LCTL.AN TIMEOUT EN Must be 0b when auto-negotiation is disabled.
CONNSW.ENRGSRC Must be 0b on 1000BASE-BX backplane, when source of the signal detect
indication is internal. When connected to an optical module and
SRDS_[n]_SIG_DET pin is connected to the module, should be 1b.
CTRL.ILOS If SRDS_[n]_SIG_DET pin connected to optical module, should be set according
to optical module polarity.
4.5.7.4 MAC/SGMII Link Setup (CTRL_EXT.LINK_MODE = 10b)
Link setup procedures using an external SGMII interface mode:
4.5.7.4.1 Hardware Auto-Negotiation Enabled
(PCS_LCTL. AN ENABLE = 1b, CTRL.FRCDPLX = 0b, CTRL.FRCSPD = 0b)
CTRL.FD Ignored; duplex is set by priority resolution of PCS_ANDV and PCS_LPAB.
CTRL.SLU Must be set to 1b by software to enable communications to the SerDes.
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CTRL.RFCE Must be programmed by software after reading capabilities from external PHY
registers and resolving the desired setting.
CTRL.TFCE Must be programmed by software after reading capabilities from external PHY
registers and resolving the desired setting.
CTRL.SPEED Ignored; speed setting is established from SGMII's internal indication to the MAC
after SGMII PHY has auto-negotiated a successful link-up.
STATUS.FD Reflects hardware-negotiated priority resolution.
STATUS.LU Reflects PCS_LSTS.Link OK
STATUS.SPEED Reflects actual speed setting negotiated by the SGMII and indicated to the MAC.
PCS_LCTL.Force Flow Control Ignored.
PCS_LCTL.FSD Should be set to zero.
PCS_LCTL.FSV Ignored; speed is set by priority resolution of PCS_ANDV and PCS_LPAB.
PCS_LCTL.FDV Ignored; duplex is set by priority resolution of PCS_ANDV and PCS_LPAB.
PCS_LCTL.AN TIMEOUT EN Must be 0b. Auto-negotiation time-out should be disabled in SGMII mode.
CONNSW.ENRGSRC Must be 0b. In SGMII mode source of the signal detect indication is internal.
4.5.7.5 MAC/1000BASE-KX Link Setup (CTRL_EXT.LINK_MODE = 01b)
4.5.7.5.1 Auto-Negotiation Skipped (PCS_LCTL. AN ENABLE = 0b; CTRL.FRCSPD = 1b;
CTRL.FRCDPLX = 1b)
Link setup procedures using an external 1000BASE-KX server backplane interface mode:
CTRL.FD Must be set to 1b. 1000BASE-KX always in full duplex mode.
CTRL.SLU Must be set to 1b by software to enable communications to the SerDes.
CTRL.RFCE Must be 0b (no auto-negotiation).
CTRL.TFCE Must be 0b (no auto-negotiation).
CTRL.SPEED Must be set to 10b. Only 1000 Mb/s is supported in 1000BASE-KX mode.
STATUS.FD Reflects the value written by software to CTRL.FD.
STATUS.LU Reflects whether the PCS is synchronized, qualified with CTRL.SLU (set to 1b).
STATUS.SPEED Reflects 1000Mb/s speed, reporting fixed value of (10b).
PCS_LCTL.FSD Must be set to 1b by software to enable communications to the 1000BASE-KX
SerDes.
PCS_LCTL.Force Flow Control Must be set to 1b.
PCS_LCTL.FSV Must be set to 10b. Only 1000 Mb/s is supported in 1000BASE-KX mode.
PCS_LCTL.FDV Must be set to 1b. Only full duplex is supported in 1000BASE-KX mode.
PCS_LCTL.AN TIMEOUT EN Must be 0b. Auto-negotiation not supported in 1000BASE-KX mode.
CONNSW.ENRGSRC Must be 0b. In 1000BASE-KX mode source of the signal detect indication is
internal.
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4.5.8 Initialization of Statistics
Statistics registers are hardware-initialized to values as detailed in each particular register's
description. The initialization of these registers begins upon transition to D0active power state (when
internal registers become accessible, as enabled by setting the Memory Access Enable bit of the PCIe
Command register), and is guaranteed to be completed within 1 s of this transition. Access to
statistics registers prior to this interval might return indeterminate values.
All of the statistical counters are cleared on read and a typical device driver reads them (thus making
them zero) as a part of the initialization sequence.
4.5.9 Receive Initialization
Program the receive address register(s) per the station address. This can come from the Flash or by
any other means (for example, on some machines, this comes from the system PROM not the Flash on
the adapter card).
Set up the Multicast Table Array (MTA) by software. This means zeroing all entries initially and adding
in entries as requested.
Program the RXPBSIZE register so that the total size formed by the receive packet buffer plus the BMC
to OS buffer plus the transmit packet buffer(s) plus the OS to BMC buffer does not exceed 60 KB:
RXPBSIZE.Rxpbsize + RXPBSIZE.Bmc2ospbsize + TXPBSIZE.Txpb0size + TXPBSIZE.Txpb1size +
TXPBSIZE.Txpb2size + TXPBSIZE.Txpb3size + TXPBSIZE.os2Bmcpbsize <= 60 KB
Program RCTL with appropriate values. If initializing it at this stage, it is best to leave the receive logic
disabled (RCTL.RXEN = 0b) until after the receive descriptor rings have been initialized. If VLANs are
not used, software should clear VFE. Then there is no need to initialize the VFTA. Select the receive
descriptor type.
The following should be done once per receive queue needed:
1. Allocate a region of memory for the receive descriptor list.
2. Receive buffers of appropriate size should be allocated and pointers to these buffers should be
stored in the descriptor ring.
3. Program the descriptor base address with the address of the region.
4. Set the length register to the size of the descriptor ring.
5. Program SRRCTL of the queue according to the size of the buffers, the required header handling
and the drop policy.
6. If header split or header replication is required for this queue, program the PSRTYPE register
according to the required headers.
7. Enable the queue by setting RXDCTL.ENABLE. In the case of queue zero, the enable bit is set by
default - so the ring parameters should be set before RCTL.RXEN is set.
8. Poll the RXDCTL register until the ENABLE bit is set. The tail should not be bumped before this bit
was read as one.
9. Program the direction of packets to this queue according to the mode selected in the MRQC register.
Packets directed to a disabled queue are dropped.
Note: The tail register of the queue (RDT[n]) should not be bumped until the queue is enabled.
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4.5.9.1 Initialize the Receive Control Register
To properly receive packets the receiver should be enabled by setting RCTL.RXEN. This should be done
only after all other setup is accomplished. If software uses the Receive Descriptor Minimum Threshold
Interrupt, that value should be set.
4.5.9.2 Dynamic Enabling and Disabling of Receive Queues
Receive queues can be dynamically enabled or disabled given the following procedure is followed:
Enabling a queue:
Follow the per queue initialization sequence described in Section 4.5.9.
Note: If there are still packets in the packet buffer assigned to this queue according to previous
settings, they are received after the queue is re-enabled. In order to avoid this condition, the
software might poll the PBWAC register. Once a an empty condition of the relevant packet
buffer is detected or two wrap around occurrences are detected the queue can be re-enabled.
Disabling a Queue:
1. Disable the packet assignments to this queue.
2. Poll the PBWAC register until an empty condition of the relevant packet buffer is detected or two
wrap around occurrences are detected.
3. Disable the queue by clearing RXDCTL.ENABLE. The I210 stops fetching and writing back
descriptors from this queue immediately. The I210 eventually completes the storage of one buffer
allocated to this queue. Any further packet directed to this queue is dropped. If the currently
processed packet is spread over more than one buffer, all subsequent buffers are not written.
4. The I210 clears RXDCTL.ENABLE only after all pending memory accesses to the descriptor ring or to
the buffers are done. The software device driver should poll this bit before releasing the memory
allocated to this queue.
Note: The Rx path can be disabled only after all Rx queues are disabled.
4.5.10 Transmit Initialization
Program the TCTL register according to the MAC behavior needed.
Program the TXPBSIZE register so any transmit buffer that is in use is at least greater to twice the
maximum packet size that might be stored in it. In addition, comply to the setting rules defined in
Section 4.5.9.
If operation in half duplex mode is expected, program the TCTL_EXT.COLD field. For internal PHY mode
the default value of 0x42 is acceptable. For SGMII mode, a value reflecting the I210 and the PHY SGMII
delays should be used. A suggested value for a typical PHY is 0x46 for 10 Mbps and 0x4C for 100 Mb/s.
The following should be done once per transmit queue:
Allocate a region of memory for the transmit descriptor list.
Program the descriptor base address with the address of the region.
Set the length register to the size of the descriptor ring.
Program the TXDCTL register with the desired Tx descriptor write back policy. Suggested values
are:
WTHRESH = 1b
All other fields 0b.
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If needed, set TDWBAL/TWDBAH to enable head write back.
Enable the queue using TXDCTL.ENABLE (queue zero is enabled by default).
Poll the TXDCTL register until the ENABLE bit is set.
Note: The tail register of the queue (TDT[n]) should not be bumped until the queue is enabled.
Enable transmit path by setting TCTL.EN. This should be done only after all other settings are done.
4.5.10.1 Dynamic Queue Enabling and Disabling
Transmit queues can be dynamically enabled or disabled given the following procedure is followed:
Enabling:
Follow the per queue initialization described in the previous section.
Disabling:
Stop storing packets for transmission in this queue.
Wait until the head of the queue (TDH) is equal to the tail (TDT); the queue is empty.
Disable the queue by clearing TXDCTL.ENABLE.
The Tx path might be disabled only after all Tx queues are disabled.
4.5.11 Alternate MAC Address Support
In some systems, the MAC address used by a port needs to be replaced with a temporary MAC address
in a way that is transparent to the software layer. One possible usage is in blade systems, to enable a
standby blade to use the MAC address of another blade that failed, so that the network image of the
entire blade system does not change.
In order to enable this mode, a management console might change the MAC address in the Flash
image. It is important in this case to be able to keep the original MAC address of the device as
programmed at the factory.
In order to support this mode, the I210 provides the Alternate Ethernet MAC Address Flash structure to
store the original MAC address. This structure is described in Section 6.8.8. When the MAC address is
changed, the port factory MAC address should be written to the Alternate Ethernet MAC Address
structure before writing the new Ethernet MAC address to the ports Ethernet Address Flash words (refer
to Section 6.2.1).
In some systems, it might be advantageous to restore the original MAC address at power on reset, to
avoid conflicts where two network controllers would have the same MAC address. At power up, the I210
restores the LAN MAC addresses stored in the Alternate Ethernet MAC Address Flash structure to the
regular Ethernet MAC address Flash words (refer to Section 6.2.1) if the following conditions are met:
1. The restore MAC address bit in the Common Firmware Parameters Flash word is set
(Section 6.7.1.2).
2. The value in word 0x37 (Section 6.8.8) is not 0xFFFF.
3. The MAC address set in the regular Ethernet MAC Address Flash words is different than the address
stored in the Alternate Ethernet MAC address Flash structure.
4. The address stored in the alternate Ethernet MAC address structure is valid (not all zeros or all
ones).
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If the factory MAC address was restored by the internal firmware, the FWSM.Factory MAC address
restored bit is set.
If the value at word 0x37 is valid, but the MAC addresses in the alternate MAC structure are not valid
(0xFFFFFFFF), the regular MAC address is backed up in the alternate MAC structure.
The I210 supports replacing the MAC address with a BIOS CLP interface.
4.6 Access to Shared Resources
Part of the resources in the I210 are shared between several software entities - namely the driver and
the internal firmware. In order to avoid contentions, a software device driver that needs to access one
of these resources should use the flow described in Section 4.6.1 in order to acquire ownership of this
resource and use the flow described in Section 4.6.2 in order to relinquish ownership of this resource.
The shared resources are:
1. Flash.
2. The PHYs or SerDes port.
3. CSRs accessed by the internal firmware after the initialization process. Currently there are no such
CSRs.
4. SVR/LVR control registers.
5. Management Host Interface
6. I2C register set
Note: Any other software tool that accesses the register set directly should also follow the flow
described in the sections that follow.
4.6.1 Acquiring Ownership Over a Shared Resource
The following flow should be used to acquire a shared resource:
1. Get ownership of the software/software semaphore SWSM.SMBI (offset 0x5B50 bit 0).
a. Read the SWSM register.
b. If SWSM.SMBI is read as zero, the semaphore was taken.
c. Otherwise, go back to step a.
This step assures that other software will not access the shared resources register
(SW_FW_SYNC).
2. Get ownership of the software/firmware semaphore SWSM.SWESMBI (offset 0x5B50 bit 1):
a. Set the SWSM.SWESMBI bit.
b. Read SWSM.
c. If SWSM.SWESMBI was successfully set - the semaphore was acquired - otherwise, go back to
step a.
This step assures that the internal firmware will not access the shared resources register
(SW_FW_SYNC).
3. Software reads the Software-Firmware Synchronization Register (SW_FW_SYNC) and checks both
bits in the pair of bits that control the resource it wants to own.
a. If both bits are cleared (both firmware and other software does not own the resource), software
sets the software bit in the pair of bits that control the resource it wants to own.
Ethernet Controller I210 —Initialization
154
b. If one of the bits is set (firmware or other software owns the resource), software tries again later.
4. Release ownership of the software/software semaphore and the software/firmware semaphore by
clearing SWSM.SMBI and SWSM.SWESMBI bits.
5. At this stage, the shared resources is owned by the software device driver and it might access it.
The SWSM and SW_FW_SYNC registers can now be used to take ownership of another shared
resources.
Note: Software ownership of SWSM.SWESMBI bit should not exceed 100 ms. If software takes
ownership for a longer duration, firmware might implement a timeout mechanism and take
ownership of the SWSM.SWESMBI bit.
Note: Software ownership of bits in the SW_FW_SYNC register should not exceed 1 second. If
software takes ownership for a longer duration, firmware might implement a timeout
mechanism and take ownership of the relevant SW_FW_SYNC bits.
4.6.2 Releasing Ownership Over a Shared Resource
The following flow should be used to release a shared resource:
1. Get ownership of the software/software semaphore SWSM.SMBI (offset 0x5B50 bit 0).
a. Read the SWSM register.
b. If SWSM.SMBI is read as zero, the semaphore was taken.
c. Otherwise, go back to step a.
This step assures that other software will not access the shared resources register
(SW_FW_SYNC).
2. Get ownership of the software/firmware semaphore SWSM.SWESMBI (offset 0x5B50 bit 1):
a. Set the SWSM.SWESMBI bit.
b. Read SWSM.
c. If SWSM.SWESMBI was successfully set - the semaphore was acquired - otherwise, go back to
step a.
This step assures that the internal firmware will not access the shared resources register
(SW_FW_SYNC).
3. Clear the bit in SW_FW_SYNC that controls the software ownership of the resource to indicate this
resource is free.
4. Release ownership of the software/software semaphore and the software/firmware semaphore by
clearing SWSM.SMBI and SWSM.SWESMBI bits.
5. At this stage, the shared resource are released by the driver and it may not access it. The SWSM
and SW_FW_SYNC registers can now be used to take ownership of another shared resource.
Power Management—Ethernet Controller I210
155
5.0 Power Management
This section describes how power management is implemented in the I210. The I210 supports the
Advanced Configuration and Power Interface (ACPI) specification as well as Advanced Power
Management (APM).
Power management can be disabled via the power management bit in the Initialization Control Word 1
Flash word (see Section 6.2.2), which is loaded during power-up reset. Even when disabled, the power
management register set is still present. Power management support is required by the PCIe
specification.
5.1 General Power State Information
5.1.1 PCI Device Power States
The PCIe Specification defines function power states (D-states) that enable the platform to establish
and control power states for the I210 ranging from fully on to fully off (drawing no power) and various
in-between levels of power-saving states, annotated as D0-D3. Similarly, PCIe defines a series of link
power states (L-states) that work specifically within the link layer between the I210 and its upstream
PCIe port (typically in the host chipset).
For a given device D-state, only certain L-states are possible as follows.
D0 (fully on): The I210 is completely active and responsive during this D-state. The link can be in
either L0 or a low-latency idle state referred to as L0s. Minimizing L0s exit latency is paramount for
enabling frequent entry into L0s while facilitating performance needs via a fast exit. A deeper link
power state, L1 state, is supported as well.
D1 and D2: These modes are not supported by the I210.
D3 (off): Two sub-states of D3 are supported:
D3hot, where primary power is maintained.
D3cold, where primary power is removed.
Link states are mapped into device states as follows:
D3hot maps to L1 to support clock removal on mobile platforms
D3cold maps to L2 if auxiliary power is supported on the I210 with wake-capable logic, or to L3
if no power is delivered to the I210. A sideband PE_WAKE_N mechanism is supported to
interface wake-enabled logic on mobile platforms during the L2 state.
5.1.2 PCIe Link Power States
Table 5-1 lists allowable mapping from D-states to L-states on the PCIe link.
Configuring the I210 into a D-state automatically causes the PCIe link to transition to the appropriate
L-state.
Ethernet Controller I210 —Power Management
156
L2/L3 Ready: This link state prepares the PCIe link for the removal of power and clock. The I210 is
in the D3hot state and is preparing to enter D3cold. The power-saving opportunities for this state
include, but are not limited to, clock gating of all PCIe architecture logic, shutdown of the PLL, and
shutdown of all transceiver circuitry.
L2: This link state is intended to comprehend D3cold with auxiliary power support. Note that
sideband PE_WAKE_N signaling exists to cause wake-capable devices to exit this state. The power-
saving opportunities for this state include, but are not limited to, shutdown of all transceiver
circuitry except detection circuitry to support exit, clock gating of all PCIe logic, and shutdown of
the PLL as well as appropriate platform voltage and clock generators.
L3 (link off): Power and clock are removed in this link state, and there is no auxiliary power
available. To bring the I210 and its link back up, the platform must go through a boot sequence
where power, clock, and reset are reapplied appropriately.
5.2 Power States
The I210 supports the D0 and D3 architectural power states as described earlier. Internally, the I210
supports the following power states:
D0u (D0 un-initialized) - an architectural sub-state of D0
D0a (D0 active) - an architectural sub-state of D0
D3 - architecture state D3hot
Dr - internal state that contains the architecture D3cold state. Dr state is entered when PE_RST_N
is asserted or a PCIe in-band reset is received
Figure 5-1 shows the power states and transitions between them.
Figure 5-1. Power Management State Diagram
Dr D0u
D0aD3
PERS T# de- assertion
& Flash read done
PERST# assertion
PERST#
assertion
PERST#
assertion
Write 11b
to Pow er State
Write 00b
to Pow er State
Enable
master or slave
access
Internal Pow er O n
Reset assertion
Hot (in-band)
Reset
Write 11b
to Pow er State
Power Management—Ethernet Controller I210
157
5.2.1 D0 Uninitialized State (D0u)
The D0u state is an architectural low-power state.
When entering D0u, the I210:
Asserts a reset to the PHY while the Flash is being read.
Disables wake up. However APM wake up is enabled (See additional information in Section 5.6.1), if
all of the following register bits are set:
The WUC.APME bit is set to 1b.
The WUC.APMPME bit or the PMCSR.PME_en bits are set to 1b.
The WUC.EN_APM_D0 bit is set to 1b.
5.2.1.1 Entry into D0u state
D0u is reached from either the Dr state (on de-assertion of PE_RST_N) or the D3hot state (by
configuration software writing a value of 00b to the Power State field of the PCI PM registers).
De-asserting PE_RST_N means that the entire state of the I210 is cleared, other than sticky bits. State
is loaded from the Flash, followed by establishment of the PCIe link. Once this is done, configuration
software can access the I210.
On a transition from D3hot state to D0u state, the I210 PCI configuration space is not reset (since the
No_Soft_Reset bit in the PMCSR register is set to 1b). However following move to D0a state, the I210
requires that the software device driver perform a full re-initialization of the function.
5.2.2 D0active State
Once memory space is enabled, the I210 enters the D0 active state. It can transmit and receive
packets if properly configured by the software device driver. The PHY is enabled or re-enabled by the
software device driver to operate/auto-negotiate to full line speed/power if not already operating at full
capability.
Notes:
1. In the I210, if the WUC.EN_APM_D0 is cleared to 0b an APM wake event due to reception of a Magic
packet is not generated when the function is not in D3 (or Dr) state. Any APM wake up previously
active remains active when moving from D3 to D0.
2. If APM wake is required in D3 software device driver should not disable APM wake-up via the
WUC.APME bit on D0 entry. Otherwise APM wake following a system crash and entry into S3, S4 or
S5 system power management state is not enabled.
3. Following entry into D0,the software device driver can activate other wake-up filters by writing to
the Wake Up Filter Control (WUFC) register.
5.2.2.1 Entry to D0a State
D0a is entered from the D0u state by writing a 1b to the Memory Access Enable or the I/O Access
Enable bit of the PCI Command register (See Section 9.3.3). The DMA, MAC, and PHY of the
appropriate LAN function are also enabled.
Ethernet Controller I210 —Power Management
158
5.2.3 D3 State (PCI-PM D3hot)
The I210 transitions to D3 when the system writes a 11b to the Power State field of the Power
Management Control/Status Register (PMCSR). Any wake-up filter settings that were enabled before
entering this state are maintained. If the PMCSR.No_Soft_reset bit is cleared upon completion or during
the transition to D3 state, the I210 clears the Memory Access Enable and I/O Access Enable bits of the
PCI Command register, which disables memory access decode. If the PMCSR.No_Soft_reset bit is set
the I210 doesn’t clear any bit in the PCIe configuration space. While in D3, the I210 does not generate
master cycles.
Configuration and message requests are the only TLPs accepted by a function in the D3hot state. All
other received requests must be handled as unsupported requests, and all received completions are
handled as unexpected completions. If an error caused by a received TLP (such as an unsupported
request) is detected while in D3hot, and reporting is enabled, the link must be returned to L0 if it is not
already in L0 and an error message must be sent. See section 5.3.1.4.1 in The PCIe Base Specification.
5.2.3.1 Entry to D3 State
Transition to D3 state is through a configuration write to the Power State field of the PMCSR PCIe
configuration register.
Prior to transition from D0 to the D3 state, the software device driver disables scheduling of further
tasks to the I210; it masks all interrupts and does not write to the Transmit Descriptor Tail (TDT)
register or to the Receive Descriptor Tail (RDT) register and operates the master disable algorithm as
defined in Section 5.2.3.3.
If wake up capability is needed, the system should enable wake capability by setting to 1b the PME_En
bit in the PMCSR PCIe configuration register. After wake capability has been enabled, the software
device driver should set up the appropriate wake up registers (WUC, WUFC and associated filters) prior
to the D3 transition.
Note: The software device driver can override the PMCSR.PME_En bit setting via the WUC.APMPME
bit.
If Protocol offload (Proxying) capability is required and the MANC.MPROXYE bit is set to 1b,the software
device driver should:
1. Send to the firmware the relevant protocol offload information (type of protocol offloads required,
MAC and IPv4/6 addresses information for protocol offload) via the shared RAM Firmware/Software
Host interface as defined in Section 8.23.1, Section 10.8 and Section 10.8.2.3.
2. Program the PROXYFC register and associated filters according to the protocol offload required.
3. Program the WUC.PPROXYE bit to 1b.
Note: If operation during D3cold is required, even when wake capability is not required (such as for
manageability operation), the system should also set the Auxiliary (AUX) Power PM Enable bit
in the PCIe Device Control register.
As a response to being programmed into D3 state, the I210 transitions its PCIe link into the L1 link
state. As part of the transition into L1 state, the I210 suspends scheduling of new TLPs and waits for
the completion of all previous TLPs it has sent. If the PMCSR.No_Soft_reset bit is cleared, the I210
clears the Memory Access Enable and I/O Access Enable bits of the PCI Command register, which
disables memory access decode. Any receive packets that have not been transferred into system
memory are kept in the I210 (and discarded later on D3 exit). Any transmit packets that have not been
sent can still be transmitted (assuming the Ethernet link is up).
Power Management—Ethernet Controller I210
159
In order to reduce power consumption, if the link is still needed for manageability, wake-up or proxying
functionality, the PHY can auto-negotiate to a lower link speed on D3 entry (See Section 3.7.8.5.4).
5.2.3.2 Exit from D3 State
A D3 state is followed by either a D0u state (in preparation for a D0a state) or by a transition to Dr
state (PCI-PM D3cold state). To transition back to D0u, the system writes a 00b to the Power State field
of the Power Management Control/Status Register (PMCSR). Transition to Dr state is through
PE_RST_N assertion.
The No_Soft_Reset bit in the PMCSR register in the I210 is set to 1b, to indicate that the I210 does not
perform an internal reset on transition from D3hot to D0 so that transition does not disrupt the proper
operation of other active functions. In this case, software is not required to re-initialize the function’s
configuration space after a transition from D3hot to D0 (the function is in the D0initialized state);
however, the software device driver needs to re-initialize internal registers since transition from D3hot
to D0 causes an internal port reset (similar to asserting the CTRL.RST bit).
The I210 can also be configured via Flash to clear the No_Soft_Reset bit in the PMCSR register (see
Section 6.2.17). In this case, an internal reset is generated when transition from D3hot to D0 occurs
and functional context is not maintained also in PCIe configuration bits (except for bits defined as
sticky). In this case, software is required to fully re-initialize the function after a transition to D0 as the
Function is in the D0uninitialized state.
Note: The function is reset if the link state has made a transition to the L2/L3 ready state, on
transition from D3cold to D0, if FLR is asserted or if transition D3hot to D0 is caused by
assertion of PCIe reset (PE_RST pin) regardless of the value of the No_Soft_Reset bit.
5.2.3.3 Master Disable Via CTRL Register
System software can disable master accesses on the PCIe link by either clearing the PCI Bus Master bit
or by bringing the function into a D3 state. From that time on, the I210 must not issue master
accesses. Due to the full-duplex nature of PCIe, and the pipelined design in the I210, it might happen
that multiple requests are pending when the master disable request arrives. The protocol described in
this section insures that a function does not issue master requests to the PCIe link after its Master
Enable bit is cleared (or after entry to D3 state).
Two configuration bits are provided for the handshake between the I210 function and its software
device driver:
GIO Master Disable bit in the Device Control (CTRL) register - When the GIO Master Disable bit is
set, the I210 blocks new master requests by this function. the I210 then proceeds to issue any
pending requests by this function. This bit is cleared on master reset (LAN_PWR_GOOD, PCIe reset
and software reset) to enable master accesses.
GIO Master Enable Status bit in the Device Status (STATUS) register - Cleared by the I210 when
the GIO Master Disable bit is set and no master requests are pending and is set otherwise.
Indicates that no master requests are issued by this function as long as the GIO Master Disable bit
is set. The following activities must end before the I210 clears the GIO Master Enable Status bit:
Master requests by the transmit and receive engines (for both data and MSI/MSI-X interrupts).
All pending completions to the I210 are received.
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160
In the event of a PCIe Master disable (Configuration Command register.BME set to 0b) or LAN port
disabled or if the function is moved into D3 state during a DMA access, the I210 generates an internal
reset to the function and stops all DMA accesses and interrupts. Following a move to normal operating
mode, the software device driver should re-initialize the receive and transmit queues of the relevant
port.
Notes: The software device driver sets the GIO Master Disable bit when notified of a pending master
disable (or D3 entry). the I210 then blocks new requests and proceeds to issue any pending
requests by this function. The software device driver then polls the GIO Master Enable Status
bit. Once the bit is cleared, it is guaranteed that no requests are pending from this function.
The software device driver might time out if the GIO Master Enable Status bit is not cleared
within a given time.
The GIO Master Disable bit must be cleared to enable a master request to the PCIe link. This
can be done either through reset or by the software device driver.
5.2.4 Dr State (D3cold)
Transition to Dr state is initiated on several occasions:
On system power up - Dr state begins with the assertion of the internal power detection circuit and
ends with de-assertion of PE_RST_N.
On transition from a D0a state - During operation the system might assert PE_RST_N at any time.
In an ACPI system, a system transition to the G2/S5 state causes a transition from D0a to Dr state.
On transition from a D3 state - The system transitions the I210 into the Dr state by asserting PCIe
PE_RST_N.
Any wake-up filter settings or proxying filter settings that were enabled before entering this reset state
are maintained.
The system might maintain PE_RST_N asserted for an arbitrary time. The de-assertion (rising edge) of
PE_RST_N causes a transition to D0u state.
While in Dr state, the I210 might enter one of several modes with different levels of functionality and
power consumption. The lower-power modes are achieved when the I210 is not required to maintain
any functionality (see Section 5.2.4.1).
5.2.4.1 Dr Disable Mode
The I210 enters a Dr disable mode on transition to D3cold state when it does not need to maintain any
functionality. The conditions to enter either state are:
The I210 is in Dr state
APM WoL (Wake-on-LAN) is inactive
Proxying is not required (WUC.PPROXYE is cleared to 0b).
Pass-through manageability is disabled
ACPI PME is disabled
The PHY Power Down Enable Flash bit is set (word 0xF, bit 6).
Entering Dr disable mode is usually done by asserting PCIe PE_RST_N. It might also be possible to
enter Dr disable mode by reading the Flash while already in Dr state. The usage model for this later
case is on system power up, assuming that manageability, wake up and proxying are not required.
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161
Once the I210 enters Dr state on power-up, the Flash is read. If the Flash contents determine that the
conditions to enter Dr disable mode are met, the I210 then enters this mode (assuming that PCIe
PE_RST_N is still asserted).
The I210 exits Dr disable mode when Dr state is exited (See Figure 5-1 for conditions to exit Dr state).
Refer to Section 5.2.6 for details about the static/dynamic device off states built on Dr Disable Mode.
5.2.4.2 Entry to Dr State
Dr entry on platform power-up begins with the assertion of the internal power detection circuit. The
Flash is read and determines the I210 configuration. If the APM Enable bit in the Flash's Initialization
Control Word 3 is set, then APM wake up is enabled. PHY and MAC states are redetermined by the state
of manageability and APM wake. To reduce power consumption, if manageability or APM wake is
enabled, the PHY auto-negotiates to a lower link speed on Dr entry (See Section 3.7.8.5.4). The PCIe
link is not enabled in Dr state following system power up (since PE_RST_N is asserted).
Entering Dr state from D0a state is done by asserting PE_RST_N. An ACPI transition to the G2/S5 state
is reflected in the I210 transition from D0a to Dr state. The transition can be orderly (such as user
selecting the shut down option), in which case the software device driver might have a chance to
intervene. Or, it might be an emergency transition (such as power button override), in which case, the
software device driver is not notified.
To reduce power consumption, if any of manageability, APM wake or PCI-PM PME1 is enabled, the PHY
auto-negotiates to a lower link speed on D0a to Dr transition (see Section 3.7.8.5.4).
Transition from D3 (hot) state to Dr state is done by asserting PE_RST_N. Prior to that, the system
initiates a transition of the PCIe link from L1 state to either the L2 or L3 state (assuming all functions
were already in D3 state). The link enters L2 state if PCI-PM PME is enabled.
5.2.4.3 Auxiliary Power Usage
The Flash D3COLD_WAKEUP_ADVEN bit and the AUX_PWR strapping pin determine when D3cold PME is
supported:
D3COLD_WAKEUP_ADVEN denotes that PME wake should be supported
AUX_PWR strapping pin indicates that auxiliary power is provided
D3cold PME is supported as follows:
If the D3COLD_WAKEUP_ADVEN is set to 1b and the AUX_PWR strapping is set to 1b, then D3cold
PME is supported
Else D3cold PME is not supported
The amount of power required for the function (including the entire NIC) is advertised in the Power
Management Data register, which is loaded from the Flash.
If D3cold is supported, the PME_En and PME_Status bits of the PMCSR, as well as their shadow bits in
the Wake Up Control (WUC) register are reset only by the power-up reset (detection of power rising).
1. ACPI 2.0 specifies that “OSPM will not disable wake events before setting the SLP_EN bit when
entering the S5 sleeping state. This provides support for remote management initiatives by
enabling Remote Power On (RPO) capability. This is a change from ACPI 1.0 behavior.”
Ethernet Controller I210 —Power Management
162
5.2.5 Link Disconnect
In any of D0u, D0a, D3, or Dr power states, the I210 enters a link-disconnect state if it detects a link-
disconnect condition on the Ethernet link. Note that the link-disconnect state in the internal PHY is
invisible to software (other than the PHPM.Link Energy Detect bit state). In particular, while in D0 state,
software might be able to access any of the I210 registers as in a link-connect state.
5.2.6 Device Off States
Note: One single device off mode can be enabled in the Flash at the same time, either Static or
Dynamic Device Off mode.
5.2.6.1 (Static) Device Off
The I210 enters a global power-down state when the DEV_OFF_N pin is asserted and the relevant Flash
bits were configured as previously described (see Section 4.4.4 for more details on DEV_OFF_N
functionality).
5.2.6.2 Dynamic Device Off
The I210 enters a global power-down state dynamically, each time all of the following conditions are
met:
The I210 Dynamic Device Off Enable Flashbit (word 0x1E bit 14) was set (default hardware value is
disabled).
WoL and Proxy functionalities are not required
Manageability does not require the link. This occurs if:
Manageability is disabled or
Manageability mode is NC-SI and the conditions described in Section 10.6.2.2 are fulfilled.
When in this state, the direction of SDP pins is either maintained or the pins are moved to High
Impedance according to a setting made in SDP_DDOFF_EN bit in Flash word 0x0A.
Refer also to Section 3.7.8.5.7.
5.3 Power Limits by Certain Form Factors
Table 5-1 lists power limitation introduced by different form factors.
Table 5-1. Power Limits by Form-Factor
Note: This auxiliary current limit only applies when the primary 3.3 V voltage source is not available
(the card is in a low power D3 state).
Form Factor
LOM PCIe add-in card (10 W slot)
Main N/A 3 A @ 3.3 V
Auxiliary (aux enabled) 375 mA @ 3.3 V 375 mA @ 3.3 V
Auxiliary (aux disabled) 20 mA @ 3.3 V 20 mA @ 3.3 V
Power Management—Ethernet Controller I210
163
The I210 exceeds the allocated auxiliary power in some configurations. The I210 must therefore be
configured to meet the previously mentioned requirements. To do so, the I210 implements three Flash
bits to disable operation in certain cases:
1. The PHPM.Disable_1000 PHY register bit disables 1000 Mb/s operation under all conditions.
2. The PHPM.Disable 1000 in non-D0a PHY CSR bit disables 1000 Mb/s operation in non-D0a states1.
If PHPM.Disable 1000 in non-D0a is set, and the I210 is at 1000 Mb/s speed on entry to a non-D0a
state, then the I210 removes advertisement for 1000 Mb/s and auto-negotiates.
3. The PHPM.Disable 100 in non-D0a PHY CSR bit disables 1000 Mb/s and 100 Mb/s operation in non-
D0a states. If PHPM.Disable 100 in non-D0a is set, and the I210 is at 1000 Mb/s or 100 Mb/s
speeds on entry to a non-D0a state, then the I210 removes advertisement for 1000 Mb/s and 100
Mb/s and auto-negotiates.
Note that the I210 restarts link auto-negotiation each time it transitions from a state where
1000 Mb/s or 100 Mb/s speed is enabled to a state where 1000 Mb/s or 100 Mb/s speed is disabled, or
vice versa. For example, if PHPM.Disable 1000 in non-D0a is set but PHPM.Disable_1000 is cleared, the
I210 restarts link auto-negotiation on transition from D0 state to D3 or Dr states.
5.4 Interconnects Power Management
This section describes the power reduction techniques employed by the I210 main interconnects.
5.4.1 PCIe Link Power Management
The I210 supports all PCIe power management link states:
L0 state is used in D0u and D0a states.
The L0s state is used in D0a and D0u states each time link conditions apply.
The L1 state is also used in D0a and D0u states when idle conditions apply for a longer period of
time. The L1 state is also used in the D3 state.
The L2 state is used in the Dr state following a transition from a D3 state if PCI-PM PME is enabled.
The L3 state is used in the Dr state following power up, on transition from D0a, and if PME is not
enabled in other Dr transitions.
The I210 support for active state link power management is reported via the PCIe Active State Link PM
Support register and is loaded from the Flash.
1. The restriction is defined for all non-D0a states to have compatible behavior with previous
products.
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164
While in L0 state, the I210 transitions the transmit lane(s) into L0s state once the idle conditions are
met for a period of time as follows:
L0s configuration fields are:
L0s enable - The default value of the Active State Link PM Control field in the PCIe Link Control
Register is set to 00b (both L0s and L1 disabled). System software might later write a different
value into the Link Control register. The default value is loaded on any reset of the PCI configuration
registers.
L0s exit latency (as published in the L0s Exit Latency field of the Link Capabilities register) is loaded
from Flash. Separate values are loaded when the I210 shares the same reference PCIe clock with
its partner across the link, and when the I210 uses a different reference clock than its partner
across the link. The I210 reports whether it uses the slot clock configuration through the PCIe Slot
Clock Configuration bit loaded from the Slot_Clock_Cfg bit in the PCIe Init Configuration 3 Flash
Word.
Figure 5-2. Link Power Management State Diagram
L3
L1
PERST# de-
assertion
PERST#
assertion
PERST#
assertion
PERST#
assertion
Write 11b
to Power State
Write 00b
to Power State
& (BME = 0 OR
No_Soft_Reset = 0)
Enable
master access
Internal Power On
Reset assertion
L2
L0
L0s
L1
Dr D0u
L0
L0s
L1
D0a
D3
Write 11b
to Power State
Write 00b to Power State
& No_Soft_Reset = 1
& BME = 1
Power Management—Ethernet Controller I210
165
L0s Acceptable Latency (as published in the Endpoint L0s Acceptable Latency field of the Device
Capabilities Register) is loaded from Flash.
The I210 transitions the link into L0s state once the PCIe link has been idle for a period of time defined
in the Latency_To_Enter_L0s field in the CSR Auto Configuration Power-Up NVM section (see
Section 6.3). The I210 will then transition the link into L1 state once the PCIe link has been in L0s state
for a further period as defined in the Latency_To_Enter_L1 field in the CSR Auto Configuration Power-
Up NVM section.
To comply with the PCIe specification, if the link idle time exceeds the Latency_To_Enter_L0s value
defined in the Flash, then the I210 enters L0s.
The following Flash fields control L1 behavior:
Act_Stat_PM_Sup - Indicates support for ASPM L1 in the PCIe configuration space (loaded into the
Active State Link PM Support field)
L1_Act_Ext_Latency - Defines L1 active exit latency
L1_Act_Acc_Latency - Defines L1 active acceptable exit latency
Latency_To_Enter_L1 - Defines the period (in the L0s state) before the transition into L1 state
5.4.2 Internal PHY Power-Management
The PHY power management features are described in Section 3.7.8.5.
5.4.3 SerDes, SGMII and 1000BASE-KX Power Management
The I210 SerDes enters a power-down state when none of its clients is enabled and therefore has no
need to maintain a link. This can happen in one of the following cases. Note that SerDes and
1000BASE-KX power-down must be enabled through the SerDes Low Power Enable bit in Flash word
0x0F.
1. D3/Dr state: SerDes enters a low-power state if the following conditions are met:
a. The LAN function is in a non-D0 state
b. APM WOL is inactive
c. Pass-through manageability is disabled
d. ACPI PME is disabled
e. The Dynamic Device Off Enable Flash bit is set (word 0x1E.14)
2. PHY mode: SerDes is disabled when its LAN function is configured to PHY mode.
3. Device Off: SerDes can be disabled if the DEV_OFF_N pin is asserted. Since the SerDes is shared
between the LAN function and manageability, it might not be desired to power down the SerDes in
device disable. The PHY_in_LAN_Disable Flash bit (also known as Veto bit) determines whether the
SerDes is powered down when the device disable pin is asserted. The default is not to power down.
5.5 Timing of Power-State Transitions
The following sections give detailed timing for the state transitions. In the diagrams, the dotted
connecting lines represent the I210 requirements, while the solid connecting lines represent the I210
guarantees.
The timing diagrams are not to scale. The clocks edges are shown to indicate running clocks only and
are not to be used to indicate the actual number of cycles for any operation.
Ethernet Controller I210 —Power Management
166
5.5.1 Power Up (Off to Dup to D0u to D0a)
Figure 5-3. Power Up (Off to Dup to D0u to D0a)
Table 5-2. Power Up (Off to Dup to D0u to D0a)
Note Description
1 Xosc is stable txog after power is stable.
2 LAN_PWR_GOOD is asserted after all power supplies are good and tppg after Xosc is stable.
3 A Flash read starts on the rising edge of LAN_PWR_GOOD.
4 After reading the Flash, PHY reset is de-asserted.
5 APM wake-up mode can be enabled based on what is read from the Flash.
6 The PCIe reference clock is valid tPE_RST-CLK before de-asserting PE_RST_N (according to PCIe specification).
7 PE_RST_N is de-asserted tPVPGL after power is stable (according to PCIe specification).
8 The internal PCIe clock is valid and stable tppg-clkint from PE_RST_N de-assertion.
9 The PCIe internal PWRGD signal is asserted tclkpr after the external PE_RST_N signal.
10 Asserting internal PCIe PWRGD causes the Flash to be re-read, asserts PHY reset, and disables wake up.
11 After reading the Flash, PHY reset is de-asserted.
12 Link training starts after tpgtrn from PE_RST_N de-assertion.
13 A first PCIe configuration access might arrive after tpgcfg from PE_RST_N de-assertion.
14 A first PCI configuration response can be sent after tpgres from PE_RST_N de-assertion.
15 Writing a 1b to the Memory Access Enable bit in the PCI Command Register transitions the I210 from D0u to D0 state.
InternalPCIeClock
Internal PwrGd(PLL)
DState D0u
ReadingFlash
D0a
PHYReset
PCIeLinkUp L0
WakeUpEnabled
4
5
7
Dr
10
11
12
3
5
APM/SMBusWakeup
Power
InternalPowerOn
Reset 2
PCIeReferenceClock
PE_RSTn
Read
3GIO
Read
rest
Read
3GIO
Read
rest
Xosc
1
6
8
txog
tee tee
9
tppg‐clkint
13 14
PHYPowerState deganamrewoP(FFODD ) DDOFForreducedlinkspeed On
APM/SMBusWakeup
tpgtrn
15
tpgrestpgcfg
tPWRGD‐CLK
tPVPG
L
tppg
tclkpr
Power Management—Ethernet Controller I210
167
5.5.2 Transition from D0a to D3 and Back Without PE_RST_N
Figure 5-4. Transition from D0a to D3 and Back Without PE_RST_N
Table 5-3. Transition from D0a to D3 and Back Without PE_RST_N
Note Description
1Writing 11b to the Power State field of the Power Management Control/Status Register (PMCSR) transitions the I210 to
D3.
2 The system can keep the I210 in D3 state for an arbitrary amount of time.
3 To exit D3 state, the system writes 00b to the Power State field of the PMCSR.
4 APM wake-up or SMBus mode might be enabled based on what is read in the Flash.
5After reading the Flash, reset to the PHY is de-asserted. The PHY operates at reduced-speed if APM wake up or SMBus
is enabled, else powered-down.
6 The system can delay an arbitrary time before enabling memory access.
7Writing a 1b to the Memory Access Enable bit or to the I/O Access Enable bit in the PCI Command Register transitions
the I210 from D0u to D0 state and returns the PHY to full-power/speed operation.
PCIeReference
Clock
PE_RSTn
PHYReset
PCIeLink
ReadingFlash ReadFlash
DState u0D3D D0
WakeUpEnabled
MemoryAccessEnable
L0
D3write
APM /SMBusAnymode
D0Write
D0a
2
L1 L0
PHYPowerState full fulldeganamrewopdeganamrewop
tee
1
3
4
5
6
7
td0mem
Ethernet Controller I210 —Power Management
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5.5.3 Transition From D0a to D3 and Back With PE_RST_N
Figure 5-5. Transition From D0a to D3 and Back With PE_RST_N
Table 5-4. Transition From D0a to D3 and Back With PE_RST_N
Note Description
1 Writing 11b to the Power State field of the PMCSR transitions the I210 to D3. PCIe link transitions to L1 state.
2 The system can delay an arbitrary amount of time between setting D3 mode and moving the link to a L2 or L3 state.
3 Following link transition, PE_RST_N is asserted.
4The system must assert PE_RST_N before stopping the PCIe reference clock. It must also wait tl2clk after link transition
to L2/L3 before stopping the reference clock.
5 On assertion of PE_RST_N, the I210 transitions to Dr state.
6 The system starts the PCIe reference clock tPE_RST-CLK before de-assertion PE_RST_N.
7 The internal PCIe clock is valid and stable tppg-clkint from PE_RST_N de-assertion.
8 The PCIe internal PWRGD signal is asserted tclkpr after the external PE_RST_N signal.
9 Asserting internal PCIe PWRGD causes the Flash to be re-read, asserts PHY reset, and disables wake up.
10 APM wake-up mode might be enabled based on what is read from the Flash.
11 After reading the Flash, PHY reset is de-asserted.
12 Link training starts after tpgtrn from PE_RST_N de-assertion.
13 A first PCIe configuration access might arrive after tpgcfg from PE_RST_N de-assertion.
14 A first PCI configuration response can be sent after tpgres from PE_RST_N de-assertion.
15 Writing a 1b to the Memory Access Enable bit in the PCI Command Register transitions the I210 from D0u to D0 state.
PCIeReferenceClock
PE_RSTn
DState
PHYPowerState
D0u
ReadingFlash ReadFlash
D0a
power‐managed full
ResettoPHY(active
low)
PCIeLink
WakeUpEnabled
Dr
11
Anymode APM/SMBus
full
D3write
D0a D3
15
2L1L0L 0L3L/
12
6
13 14
3
4a
4b
12
InternalPCIeClock
(2.5GHz)
Internal PwrGd(P LL)
9
7
8
10
tee
tppg‐clkint
tpgtrn
tpgres
tpgcfg
tclkpr
tpgdl
tl2clk
tclkpg tPWRGD‐CLK
tl2pg
5
L0
Power Management—Ethernet Controller I210
169
5.5.4 Transition From D0a to Dr and Back Without Transition to D3
Figure 5-6. Transition From D0a to Dr and Back Without Transition to D3
Table 5-5. Transition From D0a to Dr and Back Without Transition to D3
Note Description
1The system must assert PE_RST_N before stopping the PCIe reference clock. It must also wait tl2clk after link transition
to L2/L3 before stopping the reference clock.
2 On assertion of PE_RST_N, the I210 transitions to Dr state and the PCIe link transition to electrical idle.
3 The system starts the PCIe reference clock tPE_RST-CLK before de-assertion PE_RST_N.
4 The internal PCIe clock is valid and stable tppg-clkint from PE_RST_N de-assertion.
5 The PCIe internal PWRGD signal is asserted tclkpr after the external PE_RST_N signal.
6 Asserting internal PCIe PWRGD causes the Flash to be re-read, asserts PHY reset, and disables wake up.
7 APM wake-up mode might be enabled based on what is read from the Flash.
8 After reading the Flash, PHY reset is de-asserted.
9 Link training starts after tpgtrn from PE_RST_N de-assertion.
10 A first PCIe configuration access might arrive after tpgcfg from PE_RST_N de-assertion.
11 A first PCI configuration response can be sent after tpgres from PE_RST_N de-assertion.
12 Writing a 1b to the Memory Access Enable bit in the PCI Command Register transitions the I210 from D0u to D0 state.
PCIeReferenceClock
PE_RSTn
DState
PHYPowerState
D0u
ReadingFlash ReadFlash
D0a
power‐managed full
ResettoPHY
(activelow)
PCIeLink
WakeUpEnabled
Dr
8
Anymode APM/SMBus
full
D0a
12
L0 L0
2
3
10 11
1
9
InternalPCIeClock
(2.5GHz)
Internal PwrGd(PLL)
6
4
5
7
tee
tppg‐clkint
tpgtrn
tpgres
tpgcfg
tclkpr
tpgdl
tclkpg tPWRGD‐CLK
Ethernet Controller I210 —Power Management
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5.5.5 Timing Requirements
The I210 requires the following start-up and power state transitions.
5.5.6 Timing Guarantees
The I210 guarantees the following start-up and power state transition related timing parameters.
5.6 Wake Up
The I210 supports two modes of wake-up management:
1. Advanced Power Management (APM) wake up
2. ACPI/PCIe defined wake up
The usual model is to activate one mode at a time but not both modes together. If both modes are
activated, the I210 might wake up the system on unexpected events. For example, if APM is enabled
together with the ACPI/PCIe Magic packet in the WUFC register, a magic packet might wake up the
system even if APM is disabled (WUC.APME = 0b). Alternatively, if APM is enabled together with some
of the ACPI/PCIe filters (enabled in the WUFC register), packets matching these filters might wake up
the system even if PCIe PME is disabled.
Parameter Description Min. Max. Notes
txog Xosc stable from power stable 56 ms
tPE_RST-CLK PCIe clock valid to PCIe power
good 100 s - According to PCIe spec.
tPVPGL Power rails stable to PCIe PE_RST
active 100 ms - According to PCIe spec.
Tpgcfg External PE_RST signal to first
configuration cycle. 100 ms According to PCIe spec.
td0mem Device programmed from D3h to
D0 state to next device access 10 ms According to PCI power
management spec.
tl2pg L2 link transition to PE_RST de-
assertion 0 ns According to PCIe spec.
tl2clk L2 link transition to removal of
PCIe reference clock 100 ns According to PCIe spec.
Tclkpg PE_RST de-assertion to removal of
PCIe reference clock 0 ns According to PCIe spec.
Tpgdl PE_RST de-assertion time 100 s According to PCIe spec.
Parameter Description Min. Max. Notes
txog Xosc stable from power stable 56 msec
tppg Internal power good delay from valid power
rail 45 msec
tee NVM read duration 20 msec
tppg-clkint PCIe* PE_RST to internal PLL lock - 5 ms
tclkpr Internal PCIe PWGD from external PCIe
PE_RST 50 s
tpgtrn PCIe PE_RST to start of link training 20 ms According to PCIe spec.
tpgres External PE_RST to response to first
configuration cycle 1 s According to PCIe spec.
Power Management—Ethernet Controller I210
171
5.6.1 Advanced Power Management Wake Up
Advanced Power Management Wake Up or APM Wakeup (also known as Wake on LAN) is a feature that
existed in earlier 10/100 Mb/s NICs. This functionality was designed to receive a broadcast or unicast
packet with an explicit data pattern, and then assert a subsequent signal to wake up the system. This
was accomplished by using a special signal that ran across a cable to a defined connector on the
motherboard. The NIC would assert the signal for approximately 50 ms to signal a wake up. The I210
now uses (if configured) an in-band PM_PME message for this functionality.
On power up, the I210 reads the APM Enable bits from the Flash Initialization Control Word 3 into the
APM Enable (APME) bits of the Wakeup Control (WUC) register. These bits control enabling of APM wake
up.
When APM wake up is enabled, the I210 checks all incoming packets for Magic packets. See
Section 5.6.3.1.4 for a definition of Magic packets.
Once the I210 receives a matching Magic packet, and if the WUC.APMPME bit or the PMCSR.PME_En
bits are set to 1b and the WUC.APME bit is set to 1b it:
Sets the PME_Status bit in the PMCSR register and issues a PM_PME message (in some cases, this
might require asserting the PE_WAKE_N signal first to resume power and clock to the PCIe
interface).
Stores the first 128 bytes of the packet in the Wake Up Packet Memory (WUPM) register.
Sets the Magic Packet Received bit in the Wake Up Status (WUS) register.
Sets the packet length in the Wake Up Packet Length (WUPL) register.
The I210 maintains the first Magic packet received in the Wake Up Packet Memory (WUPM) register
until the software device driver writes a 1b to the WUS.MAG bit.
If the WUC.EN_APM_D0 bit is set to 1b, APM wake up is supported in all power states and only disabled
if a subsequent Flash read results in the WUC.APME bit being cleared or software explicitly writes a 0b
to the WUC.APME bit. If the WUC.EN_APM_D0 bit is cleared APM wake-up is supported only in the D3 or
Dr power states.
Notes:
1. When the WUC.APMPME bit is set a wake event is issued (PE_WAKE_N pin is asserted and a
PM_PME PCIe message is issued) even if the PMCSR.PME_En bit in configuration space is cleared.
To enable disabling of system Wake-up when PMCSR.PME_En is cleared, the software device driver
should clear the WUC.APMPME bit after power-up or PCIe reset.
2. If APM is enabled and the I210 is programmed to issue a wake event on the PCIe, each time a
Magic packet is received, a wake event is generated on the PCIe interface even if the WUS.MAG bit
was set as a result of reception of a previous Magic packet. Consecutive magic packets generate
consecutive Wake events.
5.6.2 ACPI Power Management Wake Up
The I210 supports PCIe power management based wake-up. It can generate system wake-up events
from a number of sources:
Reception of a Magic packet.
Reception of a network wake-up packet.
Detection of a change in network link state (cable connected or disconnected).
Wake-up by manageability after receiving an unsupported packets for proxying.
Ethernet Controller I210 —Power Management
172
Activating PCIe power management wake up requires the following:
System software writes at configuration time a 1b to the PCI PMCSR.PME_En bit.
Software device driver clears all pending wake-up status bits in the Wake Up Status (WUS) register.
The software device driver programs the Wake Up Filter Control (WUFC) register to indicate the
packets that should initiate system wake up and programs the necessary data to the IPv4/v6
Address Table (IP4AT, IP6AT) and the Flexible Host Filter Table (FHFT). It can also set the
WUFC.LNKC bit to cause wake up on link status change.
Once the I210 wakes the system, the software device driver needs to clear the WUS and WUFC
registers until the next time the system moves to a low power state with wake up enabled.
Normally, after enabling wake up, system software moves the device to D3 low power state by writing
a 11b to the PCI PMCSR.Power State field.
Once wake up is enabled, the I210 monitors incoming packets, first filtering them according to its
standard address filtering method, then filtering them with all of the enabled wake-up filters. If a
packet passes both the standard address filtering and at least one of the enabled wake-up filters, the
I210:
Sets the PME_Status bit in the PMCSR.
Asserts PE_WAKE_N (if the PME_En bit in the PMCSR configuration register is set).
Stores the first 128 bytes of the packet in the Wakeup Packet Memory (WUPM) register.
Sets one or more bits in the Wake Up Status (WUS) register. Note that the I210 sets more than one
bit if a packet matches more than one filter.
Sets the packet length in the Wake Up Packet Length (WUPL) register.
Note: If enabled, a link state change wake-up causes similar results. Sets the PMCSR.PME_Status
bit, asserts the PE_WAKE_N signal and sets the relevant bit in the WUS register.
The PE_WAKE_N remains asserted until the operating system either writes a 1b to the
PMCSR.PME_Status bit or writes a 0b to the PMCSR.PME_En bit.
After receiving a wake-up packet, the I210 ignores any subsequent wake-up packets until the software
device driver clears all of the received bits in the Wake Up Status (WUS) register. It also ignores link
change events until the software device driver clears the Link Status Changed (LNKC) bit in the Wake
Up Status (WUS) register.
Note: A wake on link change is not supported when configured to SerDes or 1000BASE-KX mode.
5.6.3 Wake-Up and Proxying Filters
The I210 supports issuing wake-up to Host when device is in D3 or protocol offload (proxying) of
packets using two types of filters:
Pre-defined filters
Flexible filters
Each of these filters are enabled if the corresponding bit in the Wake Up Filter Control (WUFC) register
or Proxying Filter Control (PROXYFC) register is set to 1b.
Note: When VLAN filtering is enabled, packets that passed any of the receive wake-up filters should
only cause a wake-up event if they also passed the VLAN filtering.
Power Management—Ethernet Controller I210
173
5.7 Protocol Offload (Proxying)
In order to avoid spurious wake-up events and reduce system power consumption when the device is in
D3 low power state and system is in S3 or S4 low power states, the I210 supports protocol offload
(proxying) of:
1. A single IPv4 Address Resolution Protocol (ARP) request.
Responds to IPv4 address resolution request with the host MAC (L2) address (as defined in RFC
826).
2. Two IPv6 Neighbor Solicitation (NS) requests, where each NS protocol offload request includes two
IPv6 addresses, for a total of four possible IPv6 addresses.
IPv6 NS requests with the host MAC (L2) address (as defined in RFC 4861).
3. When NS protocol offload is enabled, the I210 supports up to two IPv6 Multicast-Address-Specific
Multicast Listener Discovery (MLD) queries (either MLDv1 or MLDv2). In addition, the I210 also
responds to general MLD queries, used to learn which IPv6 multicast addresses have listeners on an
attached link.
MLD protocol offload is supported when NS protocol offload is enabled so that IPv6 routers
discover the presence of multicast listeners (that is, nodes wanting to receive multicast
packets), for packets with the IPv6 NS Solicited-node Multicast Address and continue
forwarding these NS requests on the link.
MLD protocol offload is supported for either MLD Multicast Listener Query packets or MLD
Multicast Address and Source Specific Query packets that check for IPv6 multicast listeners
with the Solicited-node Multicast Address placed in the IPv6 destination address field of the
IPv6 NS packets that are off-loaded by the I210.
Table 5-6. ARP Packet Structure and Processing
Offset # of bytes Field Value Action Comment
0 6 Destination Address Compare MAC header – processed by main
address filter.
6 6 Source Address Skip
12 S=(0/4/8) Possible VLAN Tags (single or
double)
Compare on
internal VLAN
only Processed by main address filter.
12 + S D=(0/8) Possible Length + LLC/SNAP
Header Skip
12 + S + D 2 Ethernet Type 0x0806 Compare ARP
14 + S + D 2 HW Type 0x0001 Compare
16 + S + D 2 Protocol Type 0x0800 Compare
18 + S + D 1 Hardware Size 0x06 Compare
19 + S + D 1 Protocol Address Length 0x04 Compare
20 + S + D 2 Operation 0x0001 Compare
22 + S + D 6 Sender HW Address - Ignore
28 + S + D 4 Sender IP Address - Ignore
32 + S + D 6 Target HW Address - Ignore
38 + S + D 4 Target IP Address IP4AT Compare
Compare if the Directed ARP bit is
set to 1b.
May match any of four values in
IP4AT.
Ethernet Controller I210 —Power Management
174
IPv6 MLD queries, with the Solicited-node Multicast Address placed in the IPv6 destination
address field of the IPv6 NS packets that are off-loaded by the I210 (as defined in RFC 2710
and RFC 3810). The MLDv2 Multicast Listener Report messages returned by firmware to MLDv2
Multicast Listener Query messages which concern the device, contain a Multicast Address
Record for each configured Solicited IPv6 addresses (up to 2). Other fields are returned as
follows:
Number of Sources = 0 (no Source Address fields supplied)
Record Type = 2 (MODE_IS_EXCLUDE)
Aux Data Len = 0 (no Auxiliary Data fields supplied)
4. mDNS proxy offload
Multicast DNS (mDNS) is used to advertise and locate services on the local network. Its proxy
offload requires the I210 to respond to mDNS queries as well as keeping the network
connectivity of a system while the system is in sleep state and wake the system when a service
is requested from the system.
For more information on the I210 functionality and enablement for mDNS Proxy Offload. See
section 5.7.3
In addition to the D3 low power functionality, by setting D0_PROXY bit to 1b, the I210 enables these
features in D0 and enables the system to be in a low power S0x state for longer durations to increase
system power savings.
5.7.1 Protocol Offload Activation in D3
To enable protocol offload, the software device driver should implement the following steps before D3
entry:
1. Read MANC.MPROXYE bit to verify that proxying is supported by management.
2. Clear all pending proxy status bits in the Proxying Status (PROXYS) register.
3. Program the Proxying Filter Control (PROXYFC) register to indicate the type of packets that should
be forwarded to manageability for proxying and then program the necessary data to the IPv4/v6
Address Table (IP4AT, IP6AT) and the Flexible Host Filter Table (FHFT) registers.
4. Set the WUFC.FW_RST_WK bit to 1b to initiate a wake if firmware reset was issued when in D3
state and proxying information was lost.
5. Take ownership of the Management Host interface semaphore (SW_FW_SYNC.SW_MNG_SM
register bit) using the flow defined in Section 4.6.1 to send Protocol Offload information to
Firmware.
6. Read and clear the FWSTS.FWRI firmware reset indication bit.
If a firmware reset was issued as reported in the FWSTS.FWRI bit, the software device driver
should clear the bit and then re-initialize the protocol offload list even if firmware keeps the
protocol offload list on a move from D3 to D0 (See note in Section 10.8.2.4.2.2).
7. Verify that the HICR.En bit (See Section 8.23.2) is set 1b, which indicates that the shared RAM
interface is available.
8. Write proxying information in the shared RAM interface located in addresses 0x8800-0x8EFF using
the format defined in Section 10.8.2.4.2. All addresses should be placed in networking order.
9. Once information is written into the shared RAM software should set the HICR.C bit to 1b.
10. Poll the HICR.C bit until bit is cleared by firmware indicating that the command was processed and
verified that the command completed successfully by checking that the HICR.SV bit was set.
11. Read the firmware response from the shared RAM to verify that data was received correctly.
12. Return to 8. if additional commands need to be sent to Firmware.
Power Management—Ethernet Controller I210
175
13. Release management Host interface semaphore (SW_FW_SYNC.SW_MNG_SM register bit) using
the flow defined in Section 4.6.2.
14. Verify that a firmware reset was not initiated during the proxying configuration process by reading
the FWSTS.FWRI firmware reset indication bit. If a firmware reset was initiated. Return to step 1.
15. Set WUC.PPROXYE bit to 1b and enable entry into D3 low power state.
16. Once the I210 moves back into D0 state, the software device driver needs to clear the
WUC.PPROXYE bit, PROXYS, and PROXYFC registers until the next time the system moves to a low
power state with proxying enabled.
Normally, after enabling wake-up or proxying, system software moves the device to D3 low power state
by writing a 11b to the PCI PMCSR.Power State field.
Once proxying is enabled by setting the WUC.PPROXYE bit to 1b and device is placed in the D3 low
power state, the I210 monitors incoming packets, first filtering them according to its standard address
filtering method, then filtering them with all of the proxying filters enabled in the PROXYFC register. If a
packet passes both the standard address filtering and at least one of the enabled proxying filters and
does not pass any of the enabled wake-up filters, the I210:
1. Executes the relevant protocol offload for the packet and not forward the packet to the host.
2. Set one or more bits in the Proxying Status (PROXYS) register according to the proxying filters
matched.
Note: The I210 sets more than one bit in the PROXYS register if a packet matches more than one
filter.
3. Wakes the system and forwards a packet that matches the proxying filters but can’t be supported
by the host for further processing if configured to do so by the software device driver via the Set
Firmware Proxying Configuration command using the shared RAM interface (See
Section 10.8.2.4.2.2).
Notes:
1. When the device is in D3, a packet that matches both one of the enabled proxying filters as defined
in the PROXYFC register and one of the enabled wake-up filters as defined in the WUFC register
only wakes up the system and protocol offload (proxying) does not occur.
2. Protocol offload is not executed for illegal packets with CRC errors or checksum errors and the
packets are silently discarded.
3. Once a packet that meets the criteria for proxying is received, the I210 should respond to the
request after less than 60 Seconds.
5.7.2 Protocol Offload Activation in D0
To enable protocol offload in D0,the software device driver should implement the following steps:
1. Read MANC.MPROXYE bit to verify that proxying is supported by management.
2. Clear all pending proxy status bits in the Proxying Status (PROXYS) register.
3. Program the Proxying Filter Control (PROXYFC) register to indicate the type of packets that should
be forwarded to manageability for proxying and then program the necessary data to the IPv4/v6
Address Table (IP4AT, IP6AT) and the Flexible Host Filter Table (FHFT) registers.
4. Take ownership of the management host interface semaphore (SW_FW_SYNC.SW_MNG_SM
register bit) using the flow defined in Section 4.6.1 to send protocol offload information to
firmware.
5. Verify that the HICR.En bit is set 1b, which indicates that the shared RAM interface is available.
6. Read and clear the FWSTS.FWRI firmware reset indication bit.
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If a firmware reset was issued as reported in the FWSTS.FWRI bit, the software device driver
should clear the bit and then re-initialize the protocol offload list.
7. Write proxying information in the shared RAM interface located in addresses 0x8800-0x8EFF using
the format defined in Section 10.8.2.4.2. All addresses should be placed in networking order.
8. Once information is written into the shared RAM, software should set the HICR.C bit to 1b.
9. Poll the HICR.C bit until the bit is cleared by firmware indicating that command was processed and
verified that the command completed successfully by checking that the HICR.SV bit was set.
10. Read the firmware response from the shared RAM to verify that data was received correctly.
11. Return to step 7. if additional commands need to be sent to firmware.
12. Release the management host interface semaphore (SW_FW_SYNC.SW_MNG_SM register bit)
using the flow defined in Section 4.6.2.
13. Verify that a firmware reset was not initiated during the proxying configuration process by reading
the FWSTS.FWRI firmware reset indication bit. If a firmware reset was initiated, return to step 1.
14. Set the PROXYFC.D0_PROXY bit to 1b.
15. Set the WUC.PPROXYE bit to 1b to enable protocol offload.
Once proxying is enabled in D0 by setting both the WUC.PPROXYE bit to 1b and the
PROXYFC.D0_PROXY bit to 1b, the I210 monitors incoming packets, first filtering them according to the
standard address filtering method and then filtering them according to the proxying filters enabled in
the PROXYFC register. If a packet passes both the standard address filtering and at least one of the
enabled proxying filters then the I210:
1. Executes the relevant protocol offload for the packet and not forward the packet to the host.
2. Set one or more bits in the Proxying Status (PROXYS) register according to the proxying filter that
detected a match.
Note: The I210 sets more than one bit in the PROXYS register if a packet matches more than one
filter.
3. Discard silently illegal packets with CRC errors or checksum errors without implementing the
protocol offload.
4. Forward a packet that matches the proxying filters but can’t be supported by firmware to the host
for further processing, if configured to do so by the software device driver via the Set Firmware
Proxying Configuration command using the shared RAM interface.
5.7.3 mDNS Proxy Offload
The I210 uses multicast DNS (mDNS) to advertise and locate services on the local network. The mDNS
responder system component holds a database of registered services. When the system is in S0 state,
the mDNS responder and related system components are the sole entities responsible for auto-
configuring the LAN interface, sending service announcements, and handling service query processing.
In contrast, the offload component (the mDNS proxy) causes services (shared printers, iTunes libraries
etc.) to continue to be discovered (and virtually available) when the system is in a low power state.
The mDNS proxy is activated on demand, through a request from the main mDNS responder. This
activity is triggered by the system PM module making the decision to enter a low power state in a
system that supports mDNS proxy. Prior to the Sx entry, the internal mDNS record database is sent to
the mDNS proxy. This configuration is expected to be used by the proxy to respond to queries and
wake the system when a service access is detected. Waking the host causes the proxy function to be
disabled.
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The mDNS proxy architecture is based on the receive filter and the management controller, the filter is
responsible to parse and filter incoming packets and pass the relevant packets to the management
controller or wake the system if a packet matches one of the wake up filters. The host driver is
responsible to properly configure the filter. The host driver is also responsible to configure the
management controller using the Set mDNS Proxy Command for proper operation.
The configuration for proxy includes:
A list of IPv4 and IPv6 addresses for the interface and enablement of their protocol offload (see
Section 5.7.1).
The I210 supports mDNS proxy of up to 1 IPv4 addresses and/or up to 2 IPv6 addresses.
An array of DNS Resource Records (RRs) to be proxyied by firmware
An array of UDP and TCP port numbers for the services
The configuration is loaded to the Flash. Refer to Figure 3.6, Figure 3-7, and to Section 6.8.11, 6.8.12.
In order to prevent Flash wear out, the host driver writes these Flash areas only if, since the last time
the system went into a sleep state, a record has been modified/added, or if the FW image has been
updated. Then, prior to entering a sleep state, the host uses the Set mDNS Proxy command defined in
Section 10.8.2.4.2.5 to activate the mDNS proxy.
When activated, the mDNS proxy must act as a responsible mDNS responder.
It needs to:
Listen for both unicast and multicast DNS queries on UDP port 5353
Respond with a unicast or multicast answer depending on the QU/QM flag
Not respond if the answer it would give is already in the answer section and the RR TTL is over half
the original TTL
Properly handle queries that span multiple packets (truncated bit is set)
Support negative responses for known-missing rrtype “A” and “AAAA” queries
Implement the random delays before responding to non-probe queries, as required to avoid packet
storms
Support merging answers from multiple queries into a single response
Support legacy DNS queries
Respond to ARP and IPv6 neighbor solicitation requests
Respond ICMP PING requests
Wake the system if one of the offload services is requested or a pre-defined wake up/Magic packet
was received. The service wake detection wake up is configured by the host driver using the
WFUTPF[31:0], RFUTPF, RWPFC registers.
Wake the system if the link was lost and re-gained while sleeping
Wake the system if mDNS name conflict was detected
Provide the wakeup-reason to the software device driver that details why the system is being
woken up.
Proposed configuration of the receive and wakeup filters:
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Table 5-7. mDNS Offload Configuration
The host driver is responsible to properly configure the receive filters for mDNS proxy and mDNS wake
on LAN. Setting bits in the PROXYFCEX register to enable filters that redirect packets to the
management controller indicates mDNS proxy offload is required.
The host driver is also responsible to write the mDNS Records into the Flash area provisioned for it (see
Section 6.8.11 and Section 6.8.12). Refer to the mDNS Proxy SAS document for the exact structure of
the mDNS data section to be stored in the Flash.
Note: IP fragments are not supported for mDNS proxy offload, filtering of higher layers (ICMP, TCP/
UDP ports etc.) is not supported on IP fragments.
Note: The mDNS proxy offload will ignore any IPv4 options and silently drop all IPv6 packets with
extensions.
5.8 DMA Coalescing
The I210 supports DMA coalescing to enable synchronizing port activity and optimize power
management of memory, CPU and RC internal circuitry. When conditions to enter DMA coalescing
operating mode as defined in Section 5.8.2 exist, the I210:
Stops initiation of any activity on the PCIe link.
Data received from the Ethernet link is buffered in internal receive buffer.
When executing DMA coalescing, once the internal Tx buffer is empty, the internal Rx buffer
watermark for transmission of XOFF flow control packets on the network is defined by the
FCRTC.RTH_Coal threshold field.
Frame Type Address/Protocol Why Needed I210 Implementation Filter
ARP Request Local IPv4 address/ARP Maintain IPv4 connectivity PROXYFC.ARP /
PROXYFC.ARP_Directed
IGMPv2 224.0.0.251/IGMP Maintain presence in mDNS
group PROXYFCEX.IGMP /
PROXYFCEX.IGMP_mDirected
Multicast mDNS 224.0.0.251/UDP/5353
FF02::FB/UDP/5353
Listen to multicast mDNS
queries and respond when
proper
PROXYFCEX.mDNS /
PROXYFCEX.mDNS_mDirected
Unicast mDNS Local IPv4 address/UDP/5353
Local IPv6 address/UDP/5353
Listen to unicast mDNS
queries and respond when
proper
PROXYFCEX.mDNS /
PROXYFCEX.mDNS_uDirected
ICMP Local IPv4 address/ICMPv4
Local IPv6 address/ICMPv6 PING support
PROXYFCEX.ICMPv4 /
PROXYFCEX.ICMPv4_uDirected
PROXYFCEX.ICMPv6 /
PROXYFCEX.ICMPv6_uDirected
NS/MLD Local IPv6 address/NS
ff02::1/MLD Maintain IPv6 connectivity PROXYFC.NS /
PROXYFC.NS_Directed
mDNS Proxy Wake Frame UDP port
TCP Port/SYN
Wake the system when one of
the offloaded services is
requested
WFUTPF[i].Port/
WFUTPF[i].Port_Control
RWPFC
mDNS Proxy Special
Wake
Non IPSEC keep alive to UDP 4500
TCP SSH data - port 22
UDP 3283 WU packet
Special WU reasons
RWPFC.NonIPsecKA
RWPFC.TCP_SSH_Data
RWPFC.MagicUDP
Magic Packet WoL Magic WoL Part of APM/ACPI WoL
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The I210 exits DMA coalescing once the conditions defined in Section 5.8.3, to exit DMA coalescing,
exist.
5.8.1 DMA Coalescing Activation
To activate DMA coalescing functionality software driver should program the following fields:
1. DMACR.DMACTHR field to set the receive threshold that causes move out of DMA coalescing
operating mode. Receive watermark programmed should take into account latency tolerance
reported (See Section 5.10) and L1 to L0 latency to avoid receive buffer overflow when DMA
coalescing is enabled. A minimum of 70 us equivalent is recommended.
2. DMCTXTH.DMCTTHR field to set transmit threshold that causes move out of DMA coalescing
operating mode. Transmit watermark programmed should take into account latency tolerance
reported (See Section 5.10) and L1 to L0 latency to enable transmission of back-to-back packets
when DMA Coalescing is enabled.
3. DMACR.DMACWT field that defines a maximum timeout value for:
a. A receive packet to be stored in the internal receive buffer before the I210 moves a packet to
host memory.
b. Time to delay an interrupt that is not defined as an immediate interrupt in the IMIR[n],
IMIREXT[n] or IMIRVP registers, when other conditions specified in Section 5.8.3 to exit DMA
coalescing do not exist.
c. DMACR.DMACWT also defines maximum time to delay interrupts, that are not defined as
immediate interrupts when PCIe link is in OBFF state. In PCIe OBFF state System memory path
is available only for Device memory read/write bus master activities, but path for interrupts is
not available.
Each time the I210 enters DMA coalescing, the internal DMA coalescing watchdog timer is re-
armed with the value placed in the DMACR.DMACWT field. When in DMA coalescing, the internal
watchdog timer starts to count when one of the following conditions occurs:
A Rx packet is received in the internal buffer.
An interrupt is pending.
A descriptor write-back is pending.
Once an interval defined in the DMACR.DMACWT field has passed, the I210 exits DMA
coalescing and internal buffers, pending interrupts and pending descriptor write-backs are
flushed.
The DMACR.DC_BMC2OSW_EN bits define if a BMC to OS traffic is delayed by the time defined
in the DMACR.DMACWT field when the I210 is in DMA coalescing state or if the traffic causes
immediate exit out of DMA coalescing.
4. DMCTLX.DCFLUSH_DIS to define if pending descriptor write-back flush and pending interrupt flush
should occur before entry into DMA coalescing state.
When DMCTLX.DCFLUSH_DIS is set to 1b, any pending interrupts or descriptor write-back
operations do not cause the I210 to move out of a DMA coalescing state.
5. FCRTC.RTH_Coal field that defines a flow control receive high watermark for sending flow control
packets. The I210 uses the FCRTC.RTH_Coal threshold when:
Flow control is enabled by setting the CTRL.TFCE bit.
The I210 is in DMA coalescing mode.
Internal transmit buffer is empty.
6. SRRCTL[n].DMACQ_Dis bit to define high priority queues. When a received packet is forwarded to a
queue with the SRRCTL[n].DMACQ_Dis bit set, the I210 moves immediately out of DMA coalescing
mode and executes a DMA operation to store the packet in host memory.
7. DMACR.DMAC_EN bit should be set to 1b to enable activation of DMA coalescing operating mode.
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8. DOBFFCTL.OBFFTHR field to set the low receive threshold that causes move out of DMA coalescing
operating mode when the PCIe is in OBFF or OBFF Active states. Receive watermark programmed
must be lower than DMACR.DMACTHR.
9. DMCTLX.EN_MNG_IND bit should be set to 1b to enable management indication impact on DMA
Coalescing and OBFF operating modes. This bit also enables DMA coalescing and OBFF impact on
MCTP over PCIe traffic.
10. DMCMNGTH.DMCMNGTHR field to set the threshold for the management buffer that causes move
out of DMA coalescing operating mode.
Notes:
1. The values of DMACR.DMACTHR and FCRTC.RTH_Coal should be set so that XOFF packet
generation is avoided. In DMA coalescing mode, when the transmit buffer is empty, the XOFF flow
control threshold (FCRTC.RTH_Coal) value can be increased by the maximum jumbo frame size
compared to normal operation, where the high threshold is set by the FCRTH0 register.
2. When entering DMA coalescing mode, the value written in the FCRTH0 register is used to generate
XOFF flow control frames until the internal transmit buffer is empty. Once the internal transmit
buffer is empty the value written in the FCRTC.RTH_Coal field is used as a watermark for
generation of XOFF flow control frames.
3. The I210 transitions the link into L0s state once the PCIe link has been idle for a period of time
defined in the Latency_To_Enter_L0s field in the CSR Auto Configuration Power-Up Flash section
(see Section 6.3). The I210 will then transition the link into L1 state once the PCIe link has been in
L0s state for a further period as defined in the Latency_To_Enter_L1 field in the CSR Auto
Configuration Power-Up NVM section.
5.8.2 Entering DMA Coalescing Operating Mode
Enabling DMA coalescing operation by setting the DMACR.DMAC_EN bit to 1b. Power saving is achieved
since it increases the duration of these idle intervals. The Power Management Unit (PMU) on the
platform can use these idle intervals to reduce system power. In addition if OBFF is supported on PCIe
link additional system level power saving can be achieved by synchronizing activity of all devices on the
PCIe interface.
5.8.2.1 Entering DMA Coalescing
The I210 enters DMA coalescing when all of the following conditions exist:
1. DMA coalescing is enabled (DMACR.DMAC_EN = 1b).
2. Internal receive buffers (host and management if enabled) are empty.
3. There are no pending DMA operations.
4. None of the conditions defined in Section 5.8.3.1 to move out of DMA coalescing exist.
5. If OBFF is enabled in the PCIe config space and the OBFF state is IDLE or OBFF.
Before entering the DMA coalescing power saving mode, if the DMCTLX.DCFLUSH_DIS bit is
programmed to 0b, the I210:
Flushes all pending interrupts that were delayed due to the Interrupt Throttling (ITR) mechanism.
The I210 flushes all pending receive descriptor and transmit descriptor write backs and pre-fetch
available receive descriptors and transmit descriptors to the internal cache.
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5.8.3 Conditions to Exit DMA Coalescing
5.8.3.1 Exiting DMA Coalescing
When the I210 is in DMA coalescing operating mode, DMA coalescing mode is exited when one of the
following events occurs:
1. Amount of data in the internal receive buffer passed the DMACR.DMACTHR threshold or when OBFF
is enabled and in OBFF or “OBFF Active” states, the amount of data in internal receive buffer passed
the DOBFFCTL.OBFFTHR threshold.
2. Empty space in the internal transmit buffer is above the value defined in the DMCTXTH.DMCTTHR
field and available transmit descriptors exist.
3. A high priority packet was received (see Section 7.3.6 for a definition of high priority packets). A
high priority packet is a packet that generates an immediate interrupt, as defined in the IMIR[n],
IMIREXT[n] or IMIRVP registers.
4. A received packet destined to a high priority queue (SRRCTL[n].DMACQ_Dis =1b) was detected.
5. DMA coalescing watchdog timer defined in the DMACR.DMACWT field expires as a result of the
following occurrences not being serviced for the duration defined in the DMACR.DMACWT field:
An Rx packet was received in the internal buffer.
An interrupt is pending.
A descriptor write-back is pending.
On-chip transmit tail pointer was updated.
6. Received data rate detected is lower than defined in the DMCRTRH.UTRESH field.
7. DMA coalescing is disabled (DMACR.DMAC_EN = 0b).
8. Software initiates a move out of DMA coalescing by writing 1b to the DMACR.EXIT_DC self-clearing
bit.
9. MC to OS traffic if the DMACR.DC_BMC2OSW_EN bit is programmed to 0b.
10. Management indication are enabled through DMCTLX.EN_MNG_IND and the amount of data
buffered in the management buffer exceeds DMCMNGTH.DMCMNGTHR.
Notes:
1. Even when conditions for DMA coalescing do not exist, the I210 continues to be in a low power PCIe
link state (L0s or L1) if there is no requirement for PCIe access.
2. If a PCIe PME wake message needs to be sent, the PCIe link moves from an L1 low power state to
L0 to send the message but DMA remains in the DMA coalescing state.
3. Pending interrupts or pending descriptor write-back operations do not cause the I210 to move out
of the DMA coalescing state.
5.9 OBFF
During active block I/O workloads, devices generate cycles as needed that statistically creates a
random amount of traffic that keeps system busses and resources from efficiently entering their low
power states. OBFF mode attempts to organize this random traffic and make it more orderly and bursty
at a platform level in order to enable system busses and resources to enter low power states even
under moderate to heavy loads. The technique is to organize all devices such that they all flush or fill
their FIFOs at the same time and is referred to as OBFF.
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In systems that don’t support OBFF, asynchronous device activity prevents optimal power management
of memory, CPU, and other Root Complex (RC) internal circuitry because device activity tends to be
misaligned with respect to other devices and with respect to the natural activity of the system. The
PCIe OBFF mechanism implemented in the I210 enables synchronizing device activity and optimizing
system power management.
This OBFF indication is a hint, as all back devices are still permitted to initiate bus mastering and
interrupt traffic at any time, although this negatively impacts the platform power and should be avoided
as much as possible. In such cases, the platform can use OBFF to signal other platform devices so as to
minimize the negative impact.
OBFF states:
Active: The CPU is in C0 with the path to memory open. The I210 should execute all DMA traffic/
activity and interrupts as needed
OBFF: The CPU is not executing instructions (such as CPU is in Cx) but the path to memory is open.
The I210 should execute all opportunistic bus master traffic but hold all opportunistic interrupts
IDLE: The CPU is in Cx with the path to memory closed. The I210 should hold all opportunistic
traffic and interrupts as possible
OBFF events are signaled using the PE_WAKE_N signal on platforms supporting this topology. OBFF
prevents needless link reactivation for a common case where most devices have no need to perform
bus master or interrupts.
Note: The I210 only supports OBFF events signaled using the PE_WAKE_N signal. OBFF pulse timing
can be configured via the PCIEOBFF register (See Section 8.6.18).
Support for OBFF is reported in the PCIe Device Capabilities 2 configuration register. The OBFF
message receiving mechanism (PE_WAKE_N or PCIe message) is defined in the PCIe Device Control 2
configuration register. OBFF support is enabled by the OBFF Supported field in the PCIe Control 1 Flash
word.
5.10 Latency Tolerance Reporting (LTR)
The I210 generates PCIe LTR messages to report service latency requirements for memory reads and
writes to the RC for system power management.
The I210 reports either minimum latency tolerance, maximum latency tolerance or no latency tolerance
requirements as a function of link, LAN port and function status. Minimum and maximum latency
tolerance values are programmed in the LTRMINV and LTRMAXV registers, respectively, per PF by the
software device driver to optimize power consumption without incurring packet loss due to receive
buffer overflow.
5.10.1 LTR Algorithm
The I210 sends LTR messages according to the following algorithm when the capability is enabled in the
LTR capability structure of function 0 located in PCIe configuration space:
1. When link disconnected or port is disabled (transmit and receive activity not enabled) and the
LTRC.LNKDLS_EN and LTRC.PDLS_EN bits are set. respectively, the I210 sends a LTR PCIe message
with LTR requirement bits cleared, to indicate that no latency tolerance requirements exists.
2. If the I210 reported following PCIe link-up latency tolerance requirements with any requirement bit
set in the PCIe LTR message and all enabled functions where placed in D3 low power state via the
PMCSR register, the I210 sends a new LTR message with all the requirement bits clear.
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3. If the I210 reported following PCIe link-up latency tolerance requirements with any requirement bit
set and the LTR Mechanism Enable bit in the PCIe configuration space is cleared, the I210 sends a
new LTR message with all the requirement bits clear.
4. The I210 sends a LTR message with the value placed in the LTRMAXV register when either one of
following conditions exist:
a. Software set the LTRC.LTR_MAX register bit.
b. Rx EEE LPI state is detected on the Ethernet link and LTRC.EEEMS_EN is set (see
Section 3.7.7.4).
5. Otherwise, the I210 sends a LTR message with a minimum value.
Note: In all cases, the maximum LTR value sent by the I210 does not exceed the maximum latency
values in the Max No-Snoop Latency and Max Snoop Latency Registers in the LTR capability
structure of function 0.
Figure 5-7 shows the I210 LTR message generation flow.
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Figure 5-7. PCIe LTR Message Generation Flow
Reset
Port disabled or
disconnected?
Send LTR = Min
Yes No No
Max value
different than last
submitted LTR
value?
No
Min value
different than last
submitted LTR
Value or Min LTR bit
set?
Yes
EEE RX LPI or Send
Max LTR bit set? Yes
Send LTR = Max
Yes
Valid bits cleared in
previous LTR message?
Yes
No
Yes
No
A
A
LTR Enabled ?No
Send LTR message
with Valid bits cleared
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5.10.2 Latency Tolerance Reporting
The PCIe function can request to generate a minimum value LTR, a maximum value LTR, and a LTR
message with the requirement bits cleared. The I210 incorporates latency requirements from the
function, provided it has LTR messaging enabled and sends a single LTR message in the following
manner:
The acceptable latency values for the message sent upstream by the I210 must reflect the lowest
latency tolerance values associated with the function.
If the function has no Latency requirement for a certain type of traffic (snoop/non-snoop), the
message sent by the I210 does not have the requirement bit corresponding to that type of
traffic set.
The I210 transmits a new LTR message upstream when the capability is enabled and when the
function changes the values it has reported internally in such a way as to change the incorporated
value reported previously by the I210.
The PCIe function in the I210 reports support of LTR messaging in the configuration space by:
Setting the LTR Mechanism Supported bit in the PCIe Device Capabilities 2 configuration register
(support defined by LTR_EN bit in Initialization Control Word 1 Flash word, that controls enabling of
the LTR structures).
Supporting the LTR capability structure in the PCIe configuration space.
To enable generating LTR messages, the LTR Mechanism Enable bit in the Device Control 2
configuration register of function 0 should be set.
Note: If the function does not have LTR messaging enabled, it is considered a function that does not
have any latency tolerance requirements.
5.10.2.1 Conditions for Generating LTR Message with the Requirement Bits
Cleared
When LTR messaging is enabled, the I210’s function sends a LTR message with the requirement bits
cleared in the following cases:
1. Following PE_RST_N assertion (PCIe reset) after LTR capability is enabled.
2. LAN port is disabled (both RCTL.RXEN and TCTL.EN are cleared), receive buffer is empty and
LTRC.PDLS_EN is set.
3. LAN port is disconnected, BMC to Host traffic is disabled (MANC.EN_BMC2HOST = 0) and
LTRC.LNKDLS_EN is set.
4. Function is not in D0a state.
5. When the LSNP and LNSNP bits are cleared in the LTRMINV register and minimum LTR value needs
to be sent.
6. When the LSNP and LNSNP bits are cleared in the LTRMAXV register and maximum LTR value needs
to be sent.
7. When the LTR Mechanism Enable bit in the Device Control 2 configuration register of function 0 was
cleared and the I210 sent previously a LTR message with requirement bits set.
When one of the previous conditions exist in the function that is enabled, the I210 sends a LTR
message with the requirement bits cleared.
Note: If the PCIe function is disabled, it does not generate latency tolerance requirements.
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5.10.2.2 Conditions for Generating LTR Message with Maximum LTR Value
When LTR messaging is enabled and conditions to send a LTR message with valid bits cleared do not
exist, the I210 functions send a maximum value LTR message, with the values programmed in the
LTRMAXV register in the following cases:
1. Following a software write of 1b to the LTRC.LTR_MAX bit and the last PCIe LTR message sent had
a latency tolerance value different then the value specified in the LTRMAX register.
2. Rx EEE LPI state is detected on the Ethernet link and LTRC.EEEMS_EN is set.
3. When updated data was written to the LTRMAXV register and conditions defined instep 1. or step 2.
to send a LTR message with a maximum value exists.
When one of the previous conditions exist and the function is enabled and conditions to send a LTR
message with requirement bits cleared (See Section 5.10.2.1) doesn’t exist, the I210 sends a LTR
message with the values programmed in the LTRMAXV register.
Note: When the LTRC.LTR_MAX bit is cleared, the I210 sends a LTR message with the value placed
in the LTRMINV register, if the value is smaller than the value placed in the LTRMAXV register.
5.10.2.3 Conditions for Generating LTR Message with Minimum LTR Value
When LTR messaging is enabled, the I210’s function sends a minimum value LTR message, with the
values programmed in the LTRMINV register in the following cases:
1. Following a software write of 1b to the LTRC.LTR_MIN bit and the last PCIe LTR message sent had a
latency tolerance value different then the value specified in the LTRMINV register.
2. When updated data was written to the LTRMINV register and conditions to send a LTR message with
the requirement bits cleared (see Section 5.10.2.1) or maximum value LTR (see Section 5.10.2.2)
do not exist.
Note: If a LTR message that indicates that best possible service is requested needs to be sent, the
latency tolerance value in the LTRMINV and LTRMAXV registers should be programmed to 0x0
with the appropriate requirement bits set. In this case, the I210 sends a LTR message with
both the value and scale fields cleared to zeros.
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6.0 Flash Map
6.1 Flash General Map
Table 6-1 lists the Flash map used by the I210. This table lists common modules for the Flash
including: hardware pointers, software and firmware. Blocks are detailed in the following sections. All
addresses and pointers in Table 6-1 are absolute in word units.
A detailed list of Flashwords loaded by hardware following power up, hardware reset or software
generated resets (CTRL.RST, CTRL_EXT.EE_RST or CTRL.DEV_RST) can be found in auto load listed in
Table 3-18.
Pointers to modules marked as Read Only (RO) in Table 6-1 means two things:
1. The pointer value cannot be modified by the host.
2. The module pointed to must be mapped in a protected RO area of the Flash or shadow RAM.
Table 6-1. Common Flash Map
Flash Word
Offsets Used By/In High Byte Low Byte RO to Host
0x00:0x02 HW Ethernet Address (Words 0x00-0x02) - Section 6.2.1
0x03 SW Compatibility High - Section 6.8.1 Compatibility Low - Section 6.8.1
0x04 SW Port Identification LED Blinking (Word 0x04) - Section 6.8.2
0x05 SW Flash Map Revision (Word 0x05) - Section 6.8.3
0x06 SW Compatibility High Compatibility Low
0x07 SW Compatibility High Compatibility Low
0x08 SW PBA Number (Words 0x08, 0x09) - Section 6.8.5
0x09 SW
0x0A HW Initialization Control Word 1 (Word 0x0A) - Section 6.2.2
0x0B HW Subsystem ID (Word 0x0B) - Section 6.2.3
0x0C HW Subsystem Vendor ID (Word 0x0C) - Section 6.2.4
0x0D HW Device ID (Word 0x0D) - Section 6.2.5 RO word
0x0E HW Vendor ID (Word 0x0E) - Section 6.2.6 RO word
0x0F HW Initialization Control Word 2 (Word 0x0F) - Section 6.2.7
0x10 HW/SW Firmware Secured Module Pointer (Word 0x10) - Section 6.9 RO pointer
RO module
0x11 HW Flash Device Size (Word 0x11) - Section 6.2.8 RO word
0x12 HW Flash Validity and Protected Fields (Word 0x12) - Section 6.2.9 RO word
0x13 HW Initialization Control 4 (Word 0x13) - Section 6.2.10
0x14 HW PCIe L1 Exit Latencies (Word 0x14) - Section 6.2.11
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0x15 HW PCIe Completion Timeout Configuration (Word 0x15) - Section 6.2.12
0x16 HW MSI-X Configuration (Word 0x16) - Section 6.2.13
0x17 HW Software Reset CSR Auto Configuration Pointer (Offset 0x17) - Section 6.3 RO pointer
RO module
0x18 HW PCIe Init Configuration 1 (Word 0x18) - Section 6.2.14
0x19 HW PCIe Init Configuration 2 Word (Word 0x19) - Section 6.2.15
0x1A HW PCIe Init Configuration 3 Word (Word 0x1A) - Section 6.2.16
0x1B HW PCIe Control 1 (Word 0x1B) - Section 6.2.17
0x1C HW LED1 Configuration Defaults (Word 0x1C) - Section 6.2.18
0x1D HW Reserved
0x1E HW Device Rev ID (Word 0x1E) - Section 6.2.19
0x1F HW LED0, 2 Configuration Defaults (Offset 0x1F) - Section 6.2.20
0x20 HW Software Defined Pins Control (Word 0x20) - Section 6.2.21
0x21 HW Functions Control (Word 0x21) - Section 6.2.22
0x22 HW LAN Power Consumption (Word 0x22) - Section 6.2.23
0x23 HW PCIe Reset CSR Auto Configuration Pointer (LAN Base Address + Offset 0x23) -
Section 6.4 RO pointer
RO module
0x24 HW Initialization Control 3 (Word 0x24) - Section 6.2.24
0x25 SW mDNS Records Area Offset (Word 0x25) - Section 6.8.11
0x26 SW mDNS Records Area Size (Word 0x26) - Section 6.8.12
0x27 HW CSR Auto Configuration Power-Up Pointer (Offset 0x27) - Section 6.5 RO pointer
RO module
0x28 HW PCIe Control 2 (Word 0x28) - Section 6.2.25 RO word
0x29 HW PCIe Control 3 (Word 0x29) - Section 6.2.26
0x2C HW End of RO Area (Word 0x2C) - Section 6.2.29 RO word
RO area
0x2D HW Start of RO Area (Word 0x2D) - Section 6.2.28 RO word
RO area
0x2E HW Watchdog Configuration (Word 0x2E) - Section 6.2.29
0x2F OEM Vital Product Data (VPD) Pointer (Word 0x2F) - Section 6.2.30 RO pointer
0x30 PXE Setup Options PCIe Function (Word 0x30) - Section 6.8.6.1
0x31 PXE Configuration Customization Options PCIe Function (Word 0x31) - Section
6.8.6.2
0x32 PXE PXE Version (Word 0x32) - Section 6.8.6.3
0x33 PXE Option ROM Capabilities (Word 0x33) - Section 6.8.6.4
0x34 HW/SW Reserved
0x35 HW/SW Reserved
0x36 PXE iSCSI Option ROM Version (Word 0x36) - Section 6.8.7.1
0x37 PXE Alternate MAC Address Pointer (Word 0x37) - Section 6.8.8
0x38: 0x3B HW Reserved
0x3C PXE Reserved
0x3D PXE iSCSI Boot Configuration Pointer (Word 0x3D) - Section 6.8.7.2 RO pointer
0x3E PXE Reserved
0x3F SW Checksum Word (Word 0x3F) - Section 6.8.9
0x40 SW Free Provisioning Area Pointer to an 4KB sector. Section 6.9
Flash Word
Offsets Used By/In High Byte Low Byte RO to Host
Flash Map—Ethernet Controller I210
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6.2 Hardware Accessed Words
This section describes the Flash words that are loaded by the I210 hardware. Most of these bits are
located in configuration registers. The words are read and used only if the Flash Validity field in word
0x12 is read as 01b.
Note: When Word is mentioned before a Flash address, the address is the absolute address in the
Flash. When Offset is mentioned before a Flash address, the address is relative to the start
of the relevant Flash section.
6.2.1 Ethernet Address (Words 0x00-0x02)
The Ethernet Individual Address (IA) is a 6-byte field that must be unique for each NIC, and thus
unique for each copy of the Flash image. The first three bytes are vendor specific. The value from this
field is loaded into the Receive Address Register 0 (RAL0/RAH0).
The Ethernet address is loaded from addresses 0x0 to 0x02.
The following table lists the mapping of the Ethernet MAC addresses to the Flash words.
6.2.2 Initialization Control Word 1 (Word 0x0A)
The Initialization Control Word 1 contains initialization values that:
Set defaults for some internal registers
Enable/disable specific features
Determine which PCI configuration space values are loaded from the Flash.
0x41 SW Free Provisioning Area Size, expressed in 4KB sectors. Default is 0x3D.
Section 6.9
0x42 SW Image Unique ID (Words 0x42, 0x43) - Section 6.8.10
0x43 SW Image Unique ID (Words 0x42, 0x43) - Section 6.8.10
0x44:0x4F SW Reserved
0x50 FW RO Updates Version (Word 0x50) - Section 6.6 RO word
0x51 FW Pointer to Firmware module (Word 0x51) - Section 6.7 RO pointer
0x52:0x7F FW Reserved
0x80... Hardware structures, firmware structures, VPD area... all pointed from pointers in preceding
words.
MAC Address 0x00 0x01 0x02
00-A0-C9-00-00-00 0xA000 0x00C9 0x0000
Flash Word
Offsets Used By/In High Byte Low Byte RO to Host
Ethernet Controller I210 —Flash Map
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Bit Name Default HW Mode Description
15 iNVM 0b
14 GPAR_EN 0b1
1. This bit must be set to 1b in every Flash image.
Global Parity Enable
Enables parity checking of all the I210 memories.
0b = Disable parity check
1b = Enable parity check according to the per RAM parity enable bits.
Loaded to the PCIEERRCTL register (refer to Section 8.24.4) only at
LAN_PWR_GOOD events.
13 LTR_EN 1b
LTR Capabilities Reporting Enable
0b = Do not report LTR support in the PCIe configuration Device
Capabilities 2 register.
1b = Report LTR support in the PCIe configuration Device Capabilities 2
register.
Defines the default setting of LTR capabilities reporting (refer to
Section 9.4.6.11).
12 VPD_EN 0b
VPD Capability Enable.
0b - Do not report VPD support.
1b - Report VPD support.
This bit must be set in Flash images only once the VPD area is
programmed with a valid contents.
11 HI_DISABLE 0b
Host Interface Disable.
This bit is meaningful only for the I211 SKU.
1b = Do not allow the host to download firmware code.
0b = The host is allowed to download firmware code using the flow
described in Section 3.4.6.
10:7 Reserved 0x0 Reserved
6 SDP_DDOFF_EN 0b
When set, SDP I/Os keep their value and direction when the I210 enters
Dynamic Device Off mode.
When cleared, SDP I/Os move to HighZ plus pull-up mode in Dynamic
Device Off mode.
This bit is meaningless if Dynamic Device Off mode is disabled in Flash
word 0x1E.
5Deadlock Timeout
Enable 1b
If set, a software device driver granted access to the Flash that does not
toggle the Flash interface for more than eight seconds will have the
grant revoked. Refer to Section 3.3.7. This bit also enables EERD and
EEMNGCTL timeout if the Flash is not responding to status read.
4LAN PLL Shutdown
Enable 0b When set, enables shutting down the PHY PLL in low-power states when
the internal PHY is powered down (such as link disconnect). When
cleared, the PHY PLL is not shut down in a low-power state.
3 Power Management 1b
0b = Power management registers set to read only. In this mode, the
I210 does not execute a hardware transition to D3.
1b = Full support for power management. For normal operation, this bit
must be set to 1b.
See section 9.4.1 .
2DMA Clock Gating
Disabled 1b When set, disables DMA clock gating power saving mode.
1 Load Subsystem IDs 1b When this bit is set to 1b the I210 loads its PCIe subsystem ID and
subsystem vendor ID from the Flash (Subsystem ID and Subsystem
Vendor ID Flash words).
0Load Vendor/Device
IDs 1b When set to 1b the I210 loads its PCIe Device IDs from the Flash
(Device ID Flash words) and the PCIe Vendor ID from the Flash.
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191
6.2.3 Subsystem ID (Word 0x0B)
If the Load Subsystem IDs in Initialization Control Word 1 Flash word is set, the Subsystem ID word in
the Common section is read in to initialize the PCIe Subsystem ID. Default value is 0x0 (refer to
Section 9.3.14).
6.2.4 Subsystem Vendor ID (Word 0x0C)
If the Load Subsystem IDs bit in Initialization Control Word 1 Flash word is set, the Subsystem Vendor
ID word in the Common section is read in to initialize the PCIe Subsystem Vendor ID. The default value
is 0x8086 (refer to Section 9.3.13).
6.2.5 Device ID (Word 0x0D)
If the Load Vendor/Device IDs bit in Initialization Control Word 1 is set, the Device ID Flash word is
read in from the Common section to initialize the device ID of the LAN function. The default value is
0x1533 for the I210 (copper only SKU) (for other SKUs refer to Section 9.3.2).
6.2.6 Vendor ID (Word 0x0E)
If the Load Vendor/Device IDs bit in Initialization Control Word 1 Flash word is set, this word is read in
to initialize the PCIe Vendor ID. The default value is 0x8086 (refer to Section 9.3.1).
Note: If a value of 0xFFFF is placed in the Vendor ID Flash word, the value in the PCIe Vendor ID
register returns to the default 0x8086 value. This functionality is implemented to avoid a
system hang situation.
6.2.7 Initialization Control Word 2 (Word 0x0F)
The Initialization Control Word 2 read by the I210, contains additional initialization values that:
Set defaults for some internal registers
Enable/disable specific features
Bit Name Default HW
Mode Description
15 APM PME# Enable 0b Initial value of the Assert PME On APM Wakeup bit in the Wake Up Control
(WUC.APMPME) register. Refer to Section 8.21.1.
14 PCS Parallel Detect 1b
Enables PCS parallel detect. Mapped to the PCS_LCTL.AN TIMEOUT EN bit. Refer
to Section 8.17.2.
Note: Bit should be 0b only when the port operates in SGMII mode
(CTRL_EXT.LINK_MODE = 10b).
13:12 Pause Capability 11b Desired pause capability for advertised configuration base page. Mapped to
PCS_ANADV.ASM. Refer to Section 8.17.4.
11 ANE 0b
Auto-Negotiation Enable
Mapped to PCS_LCTL.AN_ENABLE. Refer to Section 8.17.2.
Note: Bit should be 0b when the port operates in internal copper PHY mode and
1000BASE-KX modes.
10 FRCSPD 0b
Force Speed
Default setting for the Force Speed bit in the Device Control register
(CTRL[11]). Refer to Section 8.2.1
9 FD 1b Full-Duplex
Default setting for duplex setting. Mapped to CTRL[0]. Refer to Section 8.2.1
Ethernet Controller I210 —Flash Map
192
6.2.8 Flash Device Size (Word 0x11)
8 TX_LPI_EN 0b
Enable entry into EEE LPI on TX path. Refer to Section 8.25.12.
0b = Disable entry into EEE LPI on Tx path.
1b = Enable entry into EEE LPI on Tx path.
7MAC Clock Gating
Enable 0b
Enables the MAC clock gating power saving mode. Mapped to STATUS[31]. This
bit is relevant only if the Enable Dynamic MAC Clock Gating bit is set. Refer to
Section 8.2.2.
6PHY Power Down
Enable 1b When set, enables the internal PHY to enter a low-power state (refer to
Section 3.7.8.5). This bit is mapped to CTRL_EXT[20] (refer to Section 8.2.3).
5 10BASE-TE 0b
Enable Low Amplitude 10BASE-T Operation
Setting this bit enables the I210 to operate in IEEE802.3az 10BASE-Te low
power operation. Bit is loaded to IPCNFG.10BASE-TE register bit (refer to
Section 8.27.1).
0b = 10BASE-Te operation disabled.
1b = 10BASE-Te operation enabled.
Note: When operating in 10BASE-T mode and bit is set supported cable length
is reduced.
4 Reserved 0b Reserved
3Enable Dynamic
MAC Clock Gating 0b
When set, enables dynamic MAC clock gating mechanism. Refer to
Section 8.2.3.
2SerDes Low Power
Enable 0b When set, enables the SerDes to enter a low power state when the function is in
Dr state. Refer to Chapter 5.0 and Section 8.2.3.
1 EEE_1G_AN 1b
Report EEE 1 GbE Capability in Auto-negotiation. Refer to Section 8.27.1.
0b = Do not report EEE 1 GbE capability in auto-negotiation.
1b = Report EEE 1 GbE capability in auto-negotiation.
0 EEE_100M_AN 1b
Report EEE 100 Mb/s Capability in Auto-negotiation. Refer to Section 8.27.1.
0b = Do not report EEE 100 Mb/s capability in auto-negotiation.
1b = Report EEE 100 Mb/s capability in auto-negotiation.
Bit Name Default HW
Mode Description
15:9 Reserved 0b Reserved
8Flash Defaults
from Word 0x11 0b When set, the Flash settings are taken from bits 7:3 of this Flash word - even if
the Flash part was found in the Flash devices table embedded in the firmware
image. This is useful for diagnostics.
7Fast Read
Support 0b
When set, the fast read sequence is used when reading from the Flash part.
Meaningful only when bit 8 is set or when the Flash part was not found in the
Flash devices table embedded in the firmware image.
6:5 Flash Speed 00b
Indicates the frequency of the clock provided to Flash.
00b = Clock is 15.125 MHz,
01b = Clock is 31.25 MHz,
10b = Clock is 62.5 MHz,
11b = Reserved
Meaningful only when bit 8 is set or when the Flash part was not found in the
Flash devices table embedded in the firmware image.
Bit Name Default HW
Mode Description
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193
6.2.9 Flash Validity and Protected Fields (Word 0x12)
6.2.10 Initialization Control 4 (Word 0x13)
These words control general initialization values of the LAN port.
4Unprotect After
Reset 0b When set, the Flash internal protection is removed after reset - operating the
device in the non-secured mode.
3 SST Mode 0b
When set, the device operates the Flash device pins as if it was an SST Flash part.
Meaningful only when bit 8 is set or when the Flash part was not found in the
Flash devices table embedded in the firmware image.
2:0 FL_SIZE 000b
Flash Size.
Indicates the size of the Flash device according to the following equation:
Size = 64 KB * 2 ** “FL_SIZE”.
Supported Flash sizes:
000b = 0 - no Flash device
101b = 2 MB
110b = 4 MB
111b = 8 MB
Bit Name Default HW
Mode Description
15:14 NVM Validity
The Validity field indicates to the I210 that there is a valid Flash present. If the
field is 01b, Flash read is performed, otherwise the other bits in this word are
ignored, no further Flash read is performed, and hardware default values are used
for the configuration space IDs.
13 NVM_SEC_EN 0b
Flash Security Enable.
0b - Operate the device in the blank Flash programming mode (not performing
any of the Flash security checks).
1b - Flash security protection scheme is enabled (provided the device is not
operated in the blank Flash programming mode by another mean). Refer to
Section 3.3.1.2. After writing this bit to 1b, a firmware reset or a power cycle is
required before the Flash security mode is entered.
12:11 Reserved 0x0 Reserved.
10:0 Start of 2nd
Protected Area 0x7FF Defines the start of the 2nd area in the Flash that is RO. The resolution is one
word and can be up to word address 0x7FF. The area’s end coincides with the
shadow RAM’s end.
Bit Name Default HW
Mode Description
15:8 Reserved 0x0 Reserved.
7 SPD Enable 1b
Smart Power Down
When set, enables internal PHY smart power down mode (refer to
Section 3.7.8.5.5).
6 LPLU 1b
Low Power Link Up
Enables a decrease in link speed in non-D0a states when power policy and power
management states dictate it (refer to Section 3.7.8.5.4).
5:1 PHY_ADD 0x00 PHY address. Value loaded to the MDICNFG.PHYADD field. Refer to Section 8.2.5.
0 DEV_RST_EN 1b Enable software reset (CTRL.DEV_RST) generation to the LAN port (refer to
Section 4.3).
Ethernet Controller I210 —Flash Map
194
6.2.11 PCIe L1 Exit Latencies (Word 0x14)
6.2.12 PCIe Completion Timeout Configuration (Word 0x15)
6.2.13 MSI-X Configuration (Word 0x16)
These words configure MSI-X functionality for the LAN.
6.2.14 PCIe Init Configuration 1 (Word 0x18)
This word is used to define L0s exit latencies.
Bits Name Default HW
Mode Description
15 Reserved 1b Reserved.
14:12 L1_Act_Acc_Latency 110b Loaded to the Endpoint L1 Acceptable Latency field in Device
Capabilities in the PCIe Configuration registers at power up.
11:6 Reserved 0b Reserved.
5:3 L1 G1 Sep exit latency 100b L1 exit latency G1S. Loaded to Link Capabilities -> L1 Exit Latency
at PCIe v2.1 (2.5GT/s) system in a separate clock setting.
2:0 L1 G1 Com exit latency 100b L1 exit latency G1C. Loaded to Link Capabilities -> L1 Exit Latency
at PCIe v2.1 (2.5GT/s) system in a common clock setting.
Bit Name Default HW
Mode Description
15:5 Reserved Reserved.
4Completion Timeout
Resend 0b
When set, enables to resend a request once the completion timeout expired.
0b = Do not re-send request on completion timeout.
1b = Re-send request on completion timeout. Refer to Section 8.6.1.
3:0 Reserved 0x0 Reserved.
Bit Name Default HW
Mode Description
15:11 MSI_X_N 0x4 This field specifies the number of entries in MSI-X tables of the relevant LAN.
The range is 0-4. MSI_X_N is equal to the number of entries minus one. Refer to
Section 9.4.3.3.
10 MSI Mask 1b
MSI Per-vector Masking Setting
This bit is loaded to the masking bit (bit 8) in the Message Control word of the
MSI Configuration Capability structure.
9:0 Reserved 0x0 Reserved.
Bits Name Default HW
Mode Description
15 Reserved 0b Reserved.
14:12 L0s Acceptable Latency 011b Loaded to the Endpoint L0s Acceptable Latency field in the Device
Capabilities in the PCIe configuration registers at power up.
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195
6.2.15 PCIe Init Configuration 2 Word (Word 0x19)
This word is used to set defaults for some internal PCIe configuration registers.
11:6 Reserved 0b Reserved.
5:3 L0s G1 Sep Exit Latency 111b
L0s Exit Latency G1S
Loaded to L0s Exit Latency field in the Link Capabilities register in
the PCIe Configuration registers in PCIe v2.1 (2.5GT/s) system at a
separate clock setting.
2:0 L0s G1 Com Exit Latency 101b
L0s Exit Latency G1C
Loaded to L0s Exit Latency field in the Link Capabilities register in
the PCIe Configuration registers in PCIe v2.1 (2.5GT/s) system at a
Common clock setting.
Bit Name Default HW
Mode Description
15 Reserved Reserved.
14 IO_Sup 1b
I/O Support (affects I/O BAR request)
When set to 1b, I/O is supported. When cleared the I/O Access Enable bit in the
Command Reg in the Mandatory PCI Configuration area is RO with a value of 0b.
For additional information on CSR access via I/O address space, see Section 8.1.1.5.
13 CSR_conf_en 1b
Enable CSR Access Via Configuration Space
When set, enables CSR access via the configuration registers located at configuration
address space 0x98 and 0x9C.
For additional information on CSR access via configuration address space, see
Section 8.1.1.6.
12 Serial Number
Enable 1b Serial Number Capability Enable
Should be set to 1b.
11:0 Reserved 0x0 Reserved.
Bits Name Default HW
Mode Description
Ethernet Controller I210 —Flash Map
196
6.2.16 PCIe Init Configuration 3 Word (Word 0x1A)
This word is used to set defaults for some internal PCIe registers.
6.2.17 PCIe Control 1 (Word 0x1B)
This word is used to configure initial settings for PCIe default functionality.
Bit Name Default HW
Mode Description
15:13 AER Capability Version 0x2
AER Capability Version Number
PCIe AER extended capability version number.
Refer to Section 9.5.1.1.
12 Cache_Lsize 0b
Cache Line Size
0b = 64 bytes.
1b = 128 bytes.
This bit defines the cache line size reported in the PCIe Mandatory
Configuration register area. Refer to Section 9.3.7.
11:10 GIO_Cap 10b
PCIe Capability Version
The value of this field is reflected in the two LSBs of the capability version in
the PCIe CAP register (config space – offset 0xA2).
This field must be set to 10b to use extended configuration capability.
Note that this is not the PCIe version. It is the PCIe capability version. This
version is a field in the PCIe capability structure and is not the same as the
PCIe version. It changes only when the content of the capability structure
changes. For example, PCIe 1.0, 1.0a, and 1.1 all have a capability version of
one. PCIe 2.0 has a version of two because it added registers to the
capabilities structures. Refer to Section 9.4.6.3.
9:8 Max Payload Size 10b
Default Packet Size
00b = 128 bytes.
01b = 256 bytes.
10b = 512 bytes.
11b = Reserved.
Loaded to two LSB bits of the Max Payload Size Supported field in the Device
Capabilities register (refer to Section 9.4.6.4).
7:4 Reserved Reserved.
3:2 Act_Stat_PM_Sup 11b
Determines support for active state link power management.
Loaded into the PCIe Active State Link PM Support register. Refer to
Section 9.4.6.7.
1 Slot_Clock_Cfg 1b When set, the I210 uses the PCIe reference clock supplied on the connector
(for add-in solutions).
0 Reserved Reserved.
Bit Name Default HW
Mode Description
15:12 Reserved 0x0 Reserved.
11 Disable ACLs 0b If set, the ACLs on the PCIe VDMs are disabled.
10 No_Soft_Reset 1b
No_Soft_Reset
This bit defines the behavior of the I210 when a transition from the D3hot to D0
power state occurs. When this bit is set, no internal reset is issued when making
a transition from D3hot to D0. Value is loaded to the No_Soft_Reset bit in the
PMCSR register (refer to Section 9.4.1.4).
9:0 Reserved 0 Reserved.
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197
6.2.18 LED1 Configuration Defaults (Word 0x1C)
These Flash words specify the hardware defaults for the LEDCTL register fields controlling the LED1
(ACTIVITY indication) output behavior. These words control the LED behavior of the LAN port.
6.2.19 Device Rev ID (Word 0x1E)
Bit Name Default HW
Mode Description
15:11 Reserved 0x0 Reserved.
7 LED1 Blink 1b
Initial value of LED1_BLINK field.
0b = Non-blinking.
See Section 8.2.8 and Section 7.5.
6 LED1 Invert 0b
Initial value of LED1_IVRT field.
0b = Active-low output.
See Section 8.2.8 and Section 7.5.
5:4 Reserved 00b Reserved.
3:0 LED1 Mode 0100b
Initial value of the LED1_MODE field specifying what event/state/pattern is
displayed on LED1 (LINK/ACTIVITY) output. A value of 0100b (0x4) indicates the
LINK state when active and ACTIVITY when BLINK.
See Section 8.2.8 and Section 7.5.
Bit Name Default HW
Mode Description
15 (Static) Device Off
Enable1
1. One single device off mode can be enabled in NVM/iNVM at the same time, either Static or Dynamic Device Off mode.
0b Enable power down when the DEV_OFF_N pin is asserted. Refer to Section 5.2.6.1
for details.
14 Dynamic Device
Off Enable10b
Enable Dynamic Power Down
The device dynamically powers down when PCIe is in Dr state and the PHY/SerDes
is not used for manageability or WoL. Refer to Section 5.2.6.2 for details.
13:12 Reserved 00b Reserved.
11 LAN iSCSI Enable 0b
When set, the LAN class code is set to 0x010000 (SCSI)
When reset, the LAN class code is set to 0x020000 (LAN)
Refer to Section 9.3.6.
10 Reserved 0b Reserved.
9:8 Lanphy_devoff_p
wrdn_confg 00b
00b = No copper PHY power down in device off states.
01b = Power Down with energy detect in device off state.
1xb = IEEE power down - coming out of power down is immediate, link needs to be
re-negotiated. This is the recommended NVM setting when the device off feature is
enabled.
7:0 DEVREVID 0x0
Device Revision ID
The actual device revision ID is this Flash value XORed with the hardware default of
Rev ID. For any device version the default value in this field is set to zero unless we
need to overwrite the hardware default. Refer to Section 9.3.5.
Ethernet Controller I210 —Flash Map
198
6.2.20 LED0,2 Configuration Defaults (Word 0x1F)
These Flash words specify the hardware defaults for the LEDCTL register fields controlling the LED
(LINK_UP) and LED2 (LINK_100) output behaviors. These words control the LED behavior of the LAN
port.
6.2.21 Software Defined Pins Control (Word 0x20)
These words at offset 0x20 from start of relevant Flash section are used to configure initial settings of
software defined pins (SDPs) for the LAN.
Bit Name Default HW
Mode Description
15 LED2 Blink 0b
Initial value of LED2_BLINK field.
0b = Non-blinking.
Refer to Section 8.2.8 and Section 7.5.
14 LED2 Invert 0b
Initial value of LED2_IVRT field.
0b = Active-low output.
Refer to Section 8.2.8 and Section 7.5.
13:12 Reserved 0x0 Reserved
11:8 LED2 Mode 0111b
Initial value of the LED2_MODE field specifying what event/state/pattern is
displayed on the LED2 (LINK_1000) output. A value of 0111b (0x7) indicates 1000
Mb/s operation.
Refer to Section 8.2.8 and Section 7.5.
7 LED0 Blink 0b
Initial value of LED0_BLINK field.
0b = Non-blinking.
Refer to Section 8.2.8 and Section 7.5.
6 LED0 Invert 0b
Initial value of LED0_IVRT field.
0b = Active-low output.
Refer to Section 8.2.8 and Section 7.5.
5 Global Blink Mode 0b
Global Blink Mode
0b = Blink at 200 ms on and 200 ms off.
1b = Blink at 83 ms on and 83 ms off.
Refer to Section 8.2.8 and Section 7.5.
4 Reserved 0b Reserved. Set to 0b.
3:0 LED0 Mode 0110b
Initial value of the LED0_MODE field specifying what event/state/pattern is
displayed on the LED0 (LINK_100) output. A value of 0100b (0x4) indicates the
LINK_100 state.
Refer to Section 8.2.8 and Section 7.5.
Bit Name Default HW
Mode Description
15 SDPDIR[3] 0b
SDP3 Pin – Initial Direction
This bit configures the initial hardware value of the SDP3_IODIR bit in the
Extended Device Control (CTRL_EXT) register following power up. Refer to
Section 8.2.3.
14 SDPDIR[2] 0b
SDP2 Pin – Initial Direction
This bit configures the initial hardware value of the SDP2_IODIR bit in the
Extended Device Control (CTRL_EXT) register following power up. See section
8.2.3 .
13 PHY_in_LAN_disa
ble 1b
Determines the behavior of the MAC and PHY when the LAN port is disabled
through an external pin.
0b = MAC and PHY are kept functional in device off mode (to support
manageability).
1b = MAC and PHY are powered down in device off mode (manageability cannot
access the network through this port).
Flash Map—Ethernet Controller I210
199
12 Disable 100 in
non-D0a 0b
Disables 1000 Mb/s and 100 Mb/s operation in non-D0a states (refer to
Section 3.7.8.5.4).
Sets default value of PHPM.Disable 100 bit in non-D0a mode.
11 Reserved 0b Reserved.
10 I2C_ON_SDP_EN 0b
When set to 1b, SDP pins 0 and 2 operate as I2C pins controlled by the I2CCMD
and I2CPARAMS registers set.
Used to set the default value of CTRL_EXT.I2C over SDP Enabled. Refer to
Section 8.2.3.
9 SDPDIR[1] 0b
SDP1 Pin – Initial Direction
This bit configures the initial hardware value of the SDP1_IODIR bit in the Device
Control (CTRL) register following power up. See section 8.2.1 .
8 SDPDIR[0] 0b
SDP0 Pin – Initial Direction
This bit configures the initial hardware value of the SDP0_IODIR bit in the Device
Control (CTRL) register following power up. See section 8.2.1 .
7 SDPVAL[3] 0b
SDP3 Pin – Initial Output Value
This bit configures the initial power-on value output on SDP3 (when configured as
an output) by configuring the initial hardware value of the SDP3_DATA bit in the
Extended Device Control (CTRL_EXT) register after power up. See section 8.2.3 .
6 SDPVAL[2] 0b
SDP2 Pin – Initial Output Value
This bit configures the initial power-on value output on SDP2 (when configured as
an output) by configuring the initial hardware value of the SDP2_DATA bit in the
Extended Device Control (CTRL_EXT) register after power up. See section 8.2.3 .
5 WD_SDP0 0b When set, SDP[0] is used as a watchdog timeout indication. When reset, it is used
as an SDP (as defined in bits 8 and 0). See section 8.2.1 .
4 Giga Disable 0b When set, GbE operation is disabled. A usage example for this bit is to disable GbE
operation if system power limits are exceeded (refer to Section 3.7.8.5.4).
3Disable 1000 in
non-D0a 1b Disables 1000 Mb/s operation in non-D0a states (refer to Section 3.7.8.5.4).
2D3COLD_WAKEU
P_ADVEN 1b
Controls reporting of D3 Cold wake-up support in the Power Management
Capabilities (PMC) configuration register (refer to Section 9.4.1.3).
In addition, bit is loaded to CTRL.ADVD3WUC (refer to Section 8.2.1).
When set, D3Cold wake up capability is advertised based on whether AUX_PWR
pin is connected to 3.3V to advertise presence of auxiliary power (yes, if AUX_PWR
is indicated, no otherwise). When set to 0b, D3Cold wake up capability is not
advertised even if AUX_PWR presence is indicated.
If full 1 GbE operation in D3 state is desired but the system's power requirements
in this mode would exceed the D3Cold wake up enabled specification limit (375 mA
at 3.3V), this bit can be used to prevent the capability from being advertised to
the system.
1 SDPVAL[1] 0b
SDP1 Pin – Initial Output Value
This bit configures the initial power-on value output on SDP1 (when configured as
an output) by configuring the initial hardware value of the SDP1_DATA bit in the
Device Control (CTRL) register after power up. See section 8.2.1 .
0 SDPVAL[0] 0b
SDP0 Pin – Initial Output Value
This bit configures the initial power-on value output on SDP0 (when configured as
an output) by configuring the initial hardware value of the SDP0_DATA bit in the
Device Control (CTRL) register after power up. See section 8.2.1 .
Bit Name Default HW
Mode Description
Ethernet Controller I210 —Flash Map
200
6.2.22 Functions Control (Word 0x21)
Bit Name Default HW
Mode Description
15:12 Reserved 0x0 Reserved.
11 NC-SI ARB Enable 0b
NC-SI Hardware Arbitration Enable
0b = NCSI_ARB_IN and NCSI_ARB_OUT pads are not used. NCSI_ARB_IN is
pulled up internally to provide stable input.
1b = NCSI_ARB_IN and NCSI_ARB_OUT pads are used.
10 BAR32 1b
Bit (loaded to the BARCTRL register) preserves the legacy 32-bit BAR mode when
BAR32 is set. When cleared to 0b, 64-bit BAR addressing mode is selected.
Note: If PREFBAR is set, the BAR32 bit should always be 0b (64-bit BAR
addressing mode).
Refer to Section 9.3.11.
9 PREFBAR 0b
0b = BARs are marked as non prefetchable.
1b = BARs are marked as prefetchable.
Refer to Section 9.3.11.
Notes:
1. The I210 implements non-prefetchable space in memory BAR, since it has
read side affects. This bit is loaded from the PREFBAR bit in the Flash.
2. If PREFBAR bit is set then the BAR32 bit should be 0b.
8 drop_os2bmc 1b
0b = Do not drop OS2BMC packets when the management buffer is not available.
1b = Drop OS2BMC packets when the management buffer is not available.
Note: Clearing this bit avoids the loss of OS2BMC traffic but might cause head of
line blocking on traffic to network.
7:3 Reserved 0b Reserved.
2 drop_bmc2os 1b
0b = Do not drop BMC2OS packets when no Rx descriptors are available.
1b = Drop BMC2OS packets when no Rx descriptors are available.
1:0 Reserved 0x0 Reserved.
Flash Map—Ethernet Controller I210
201
6.2.23 LAN Power Consumption (Word 0x22)
6.2.24 Initialization Control 3 (Word 0x24)
These words control the general initialization values of the LAN port.
Bit Name Default HW
Mode Description
15:8 LAN D0 Power 0x0
The value in this field is reflected in the PCI Power Management Data Register of
the PCIe function for D0 power consumption and dissipation (Data_Select = 0 or
4). Power is defined in 100 mW units. The power also includes the external logic
required for the LAN function. Refer to Section 9.4.1.4.
7:5 PCIe Function
Common Power 0x0
The value in this field is reflected in the PCI Power Management Data register of
the PCIe function when the Data_Select field is set to 8 (common function). The
MSBs in the data register that reflects the power values are padded with zeros.
Refer to Section 9.4.1.4.
4:0 LAN D3 Power 0x0
The value in this field is reflected in the PCI Power Management Data register of
the PCIe function for D3 power consumption and dissipation (Data_Select = 3 or
7). Power is defined in 100 mW units. The power also includes the external logic
required for the function. The MSBs in the data register that reflects the power
values are padded with zeros. Refer to Section 9.4.1.4.
Bit Name Default HW
Mode Description
15 SerDes Energy
Source 0b
SerDes Energy Source Detection
When set to 0b, source is internal SerDes Rx circuitry for electrical idle or link-up
indication.
When set to 1b, source is external SRDS_[n]_SIG_DET signal for electrical idle or
Link-up indication.
This bit also indicates the source of the signal detect while establishing a link in
SerDes mode.
This bit sets the default value of the CONNSW.ENRGSRC bit. Refer to Section 8.2.6.
14 2 wires SFP Enable 0b
2-wire SFP Interface Enable
This bit is used to enable interfacing an external PHY either VIA the MDIO or I2C
interface
0b = Disabled. When disabled, the 2-wire I/F pads are isolated.
1b = Enabled.
Used to set the default value of CTRL_EXT.I2C Enabled. Refer to Section 8.2.3.
13 ILOS 0b Invert Loss-of-Signal (LOS/LINK) Signal
Default setting for the loss-of-signal polarity bit (CTRL[7]). Refer to Section 8.2.1.
12:11 Reserved 00b Reserved.
10 APM Enable 0b
Initial value of Advanced Power Management Wake Up Enable bit in the Wake Up
Control (WUC.APME) register. Mapped to CTRL[6] and to WUC[0]. Refer to
Section 8.2.1 and Section 8.21.1.
Note: The disabled port that has the PHY_in_LAN_disable Flash bit (refer to
Section 6.2.21), set to 1b, the APM Enable Flash bit should be 0b.
9Enable Automatic
Crossover 1b
When set, the device automatically determines whether or not it needs to cross over
between pairs so that an external cross-over cable is not required.
Used to set the default value to IPCNFG bit 0.
8 ACBYP 0b
Bypass On-chip AC Coupling in Rx Input Buffers
ACBYP = 0 - Normal mode; on-chip AC coupling present.
ACBYP = 1 - On-chip AC coupling bypassed.
7 LAN Boot Disable 1b A value of 1b disables the Expansion ROM BAR in the PCI configuration space.
6 EN_APM_D0 0b
Enable APM Wake On D0
0b = Enable APM wake only when function is in D3 and WUC.APME is set to 1b.
1b = Always enable APM wake when WUC.APME is set to 1b.
Loaded to the WUC.EN_APM_D0 bit (refer to Section 8.21.1).
Ethernet Controller I210 —Flash Map
202
6.2.25 PCIe Control 2 (Word 0x28)
This word is used to configure the initial settings for the PCIe default functionality.
5:4 Link Mode 00b
Initial value of Link Mode bits of the Extended Device Control
(CTRL_EXT.LINK_MODE) register, specifying which link interface and protocol is
used by the MAC.
00b = MAC operates with internal copper PHY (10/100/1000BASE-T).
01b = MAC and SerDes I/F operate in 1000BASE-KX mode.
10b = MAC and SerDes operate in SGMII mode.
11b = MAC and SerDes I/F operate in SerDes (1000BASE-BX) mode.
See Section 8.2.3.
3 Reserved 0b Reserved.
2 External MDIO 0b When set, the PHY management interface is via the external MDIO interface. Loaded
to MDICNFG.Destination (refer to Section 8.2.5).
1 EXT_VLAN 0b Sets the default for CTRL_EXT[26] bit. Indicates that additional VLAN is expected in
this system (refer to Section 8.2.3).
0Keep_PHY_Link_U
p_En 0b Enables No PHY Reset when the MC indicates that the PHY should be kept on. When
asserted, this bit prevents the PHY reset signal and the power changes reflected to
the PHY according to the MANC.Keep_PHY_Link_Up value.
Bits Name Default HW
Mode Description
15:14 Reserved Reserved
13 ECRC Generation for
MCTP 0b
0b = Add ECRC to MCTP packets if ECRC is enabled via the ECRC Generation
Enable field in PCIe Advanced Error Capabilities and Control register.
1b = Do not add ECRC to MCTP packets even if ECRC is enabled.
Should be cleared in normal operation.
12 ECRC Check 1b
Loaded into the ECRC Check Capable bit of the PCIe Advanced Error Capabilities
and Control register.
0b = Function is not capable of checking ECRC.
1b = Function is capable of checking ECRC.
11 ECRC Generation 1b
Loaded into the ECRC Generation Capable bit of the PCIe Advanced Error
Capabilities and Control register.
0b = Function is not capable of generating ECRC.
1b = Function is capable of generating ECRC.
10 FLR Capability Enable 1b FLR Capability Enable bit is loaded to the PCIe configuration registers -> Device
Capabilities.
9:6 FLR Delay 0x1 Delay in microseconds from D0 to D3 move until a reset assertion.
Meaningless when the FLR delay disable bit is set to 1b.
5 FLR Delay Disable 1b
FLR Delay Disable
0 = Add delay to FLR assertion.
1 = Do not add delay to FLR assertion.
4 Reserved Reserved.
3:1 FLBAR_Size 111b
Indicates the Flash size to be exposed in the host memory BAR according to the
following equation:
Size = 64 KB * 2**(FLBAR_Size field). From 0.5 MB up to 8 MB in powers of 2.
This impacts the requested memory space for the Flash and Expansion ROM BARs
in PCIe configuration space.
Note: When CSR_Size and FLBAR_Size fields in the Flash are set to 0x0, Flash
BAR in the PCI configuration space is disabled.
0 CSR_Size 0b
The CSR_Size and FLBAR_Size fields define the usable Flash size and CSR
mapping window size as shown in BARCTRL register description.
Note: When CSR_Size and FLBAR_size fields in the Flash are set to 0b, Flash BAR
in the PCI configuration space is disabled.
Bit Name Default HW
Mode Description
Flash Map—Ethernet Controller I210
203
6.2.26 PCIe Control 3 (Word 0x29)
This word is used for programming PCIe functionality and function disable control.
1 At most one of these two bits may be set.
6.2.27 End of Read-Only (RO) Area (Word 0x2C)
Defines the end of the area in the Flash that is RO. This is a Read Only (RO) value.
6.2.28 Start of RO Area (Word 0x2D)
Defines the start of the area in the Flash that is RO. This is a Read Only (RO) value.
Bits Name Default HW
Mode Description
15 en_pin_pcie_func_dis 0b
When set to 1b, enables disabling the PCIe function by driving the SDP_1 pin to
0b (refer to Section 4.4.3).
Note: The SDP_1 pin on the port is sampled on power up and during PCIe reset.
14 Reserved 0b Reserved.
13 nvm_alt_aux_pwr_en
10b When set to 1b, SDP_3 pad controls the auxiliary power functionality. When
SDP_3 pad is driven high, it indicates that auxiliary power is provided.
12 Reserved 0b Reserved.
11 Reserved 0b Reserved.
10 nvm_aux_pwr_en10b When set to 1b, DEV_OFF_N pad controls the auxiliary power functionality. When
DEV_OFF_N pad is driven high, it indicates that auxiliary power is provided.
9:7 Reserved 0x0 Reserved
6 Reserved 0b Reserved
5 Wake_pin_enable 0b Enables the use of the WAKE# pin for a PME event in all non-LTSSM L2 power
states. When bit is set to 1b, the WAKE# pin is asserted even when the device is
not in D3cold state, if a wake event is detected.
4:0 Reserved 11100b Reserved.
In NVM/iNVM, set this field like its HW default value.
Bit Name Description
15:11 Reserved Reserved.
10:0 EORO_area (RO) Defines the end of the area in the Flash that is RO. The resolution is one word and can be up to byte
address 0x7FF. A value of zero indicates no RO area.
Bit Name Description
15:11 Reserved Reserved.
10:0 SORO_area (RO) Defines the start of the area in the Flash that is RO. The resolution is one word and can be up to
word address 0x7FF.
Ethernet Controller I210 —Flash Map
204
6.2.29 Watchdog Configuration (Word 0x2E)
6.2.30 Vital Product Data (VPD) Pointer (Word 0x2F)
This word points to the VPD structure. This structure can be used by the NIC vendor to store its own
data. Upon initial programming of the Flash, the VPD pointer must point to a pre-designated VPD area
(a free R/W area in the shadow RAM) - even if no VPD structure is programmed at that time. Once a
VPD structure has been programmed, the VPD_EN bit in Flash word 0x0A must be set to 1b. This
exposes the VPD capability in the device configuration space, following the next PCI reset event.
6.3 SW Reset CSR Auto Configuration Pointer (LAN Base
Address + Offset 0x17)
Word points to the SW Reset CSR auto configuration structure of theLAN. Sections are loaded during
HW auto-load as described in Section 3.3.1.2. If no CSR autoload is required, the word must be set to
0xFFFF.
The SW Reset CSR Auto Configuration structure format is listed in the following tables.
Bit Name Default HW
Mode Description
15 Watchdog Enable 0b
Enable Watchdog Interrupt. Refer to Section 8.14.1.
Note: If this bit is set to 1b the value of Flash Watchdog Timeout field should be 2 or
higher to avoid immediate generation of a watchdog interrupt.
14:11 Watchdog
Timeout 0x2 Watchdog Timeout Period (in seconds). Refer to Section 8.14.1.
Note: Loaded to 4 LSB bits of WDSTP.WD_Timeout field.
10:0 Reserved Reserved.
Bit Name Description
15:0 VPD Offset
Offset in words to the programmed VPD structure or to the free R/W shadow RAM area
into which the VPD structure will be programmed in the future.
Notes:
1. VPD area should be located in the first valid 2 KWords of the Flash.
2. Value of bit 15 is ignored.
Table 6-2. SW Reset CSR Auto Configuration Structure Format
Offset High Byte[15:8] Low Byte[7:0] Section
0x0 Section Length = 3*n (n – number of CSRs to configure) Section 6.3.1
0x1 Block CRC8 Section 6.3.2
0x2 CSR Address Section 6.3.3
0x3 Data LSB Section 6.3.4
0x4 Data MSB Section 6.3.5
3*n - 1 CSR Address Section 6.3.3
3*n Data LSB Section 6.3.4
3*n + 1 Data MSB Section 6.3.5
Flash Map—Ethernet Controller I210
205
6.3.1 SW Reset CSR Configuration Section Length - Offset 0x0
The section length word contains the length of the section in words. Note that section length count does
not include the section length word and Block CRC8 word.
6.3.2 Block CRC8 (Offset 0x1)
6.3.3 CSR Address - (Offset 3*n - 1; [n = 1... Section Length])
6.3.4 CSR Data LSB - (Offset 3*n; [n = 1... Section Length])
6.3.5 CSR Data MSB - (Offset 3*n + 1; [n = 1... Section Length])
6.4 PCIe Reset CSR Auto Configuration Pointer (LAN Base
Address + Offset 0x23)
This word points to the PCIe Reset CSR auto configuration structure of the LAN that is read only
following power-up or PCIe reset. Sections are loaded during HW auto-load as described in
Section 3.3.1.2. If no CSR autoload is required, the word must be set to 0xFFFF.
The PCIe Reset CSR Auto Configuration structure format is listed in the following tables.
Bits Name Default HW
Mode Description
15 Reserved
14:0 Section_length Section length in words (3 * number of CSRs to be configured).
Bit Name Description
15:8 Reserved
7:0 CRC8 CRC8 is computed over the module, header excluded (for example, starting
from word offset 0x2 included).
Bits Name Default HW
Mode Description
15 Reserved
14:0 CSR_ADDR CSR Address in Double Words (4 bytes).
Bits Name Default HW
Mode Description
15:0 CSR_Data_LSB CSR Data LSB.
Bits Name Default HW
Mode Description
15:0 CSR_Data_MSB CSR Data MSB.
Ethernet Controller I210 —Flash Map
206
6.4.1 PCIe Reset CSR Configuration Section Length - Offset 0x0
The section length word contains the length of the section in words. Note that section length count does
not include the section length word and Block CRC8 word.
6.4.2 Block CRC8 (Offset 0x1)
6.4.3 CSR Address - (Offset 3*n - 1; [n = 1... Section Length])
6.4.4 CSR Data LSB - (Offset 3*n; [n = 1... Section Length])
Table 6-3. PCIe Reset CSR Auto Configuration Structure Format
Offset High Byte[15:8] Low Byte[7:0] Section
0x0 Section Length = 3*n (n – number of CSRs to configure) Section 6.4.1
0x1 Block CRC8 Section 6.4.2
0x2 CSR Address Section 6.4.3
0x3 Data LSB Section 6.4.4
0x4 Data MSB Section 6.4.5
3*n - 1 CSR Address Section 6.5.3
3*n Data LSB Section 6.5.4
3*n + 1 Data MSB Section 6.5.5
Bits Name Default HW
Mode Description
15 Reserved
14:0 Section_length Section length in words (3 * number of CSRs to be configured).
Bit Name Description
15:8 Reserved
7:0 CRC8 CRC8 is computed over the module, header excluded (for example starting
from word offset 0x2 included).
Bits Name Default HW
Mode Description
15 Reserved
14:0 CSR_ADDR CSR Address in Double Words (4 bytes).
Bits Name Default HW
Mode Description
15:0 CSR_Data_LSB CSR Data LSB.
Flash Map—Ethernet Controller I210
207
6.4.5 CSR Data MSB - (Offset 3*n + 1; [n = 1... Section Length])
6.5 CSR Auto Configuration Power-Up Pointer (Offset 0x27)
This word points to the CSR auto configuration power-up structure of the LAN that is read only following
power up. Sections are loaded during HW auto-load as described in Section 3.3.1.2. If no CSR autoload
is required, the word must be set to 0xFFFF.
The CSR Auto Configuration Power-Up structure format is listed in the following tables.
6.5.1 CSR Configuration Power-Up Section Length - Offset 0x0
The section length word contains the length of the section in words. Note that section length count does
not include the section length word and Block CRC8 word.
6.5.2 Block CRC8 (Offset 0x1)
Bits Name Default HW
Mode Description
15:0 CSR_Data_MSB CSR Data MSB.
Table 6-4. CSR Auto Configuration Power-Up Structure Format
Offset High Byte[15:8] Low Byte[7:0] Section
0x0 Section Length = 3*n (n – number of CSRs to configure) Section 6.5.1
0x1 Block CRC8 Section 6.5.2
0x2 CSR Address Section 6.5.3
0x3 Data LSB Section 6.5.4
0x4 Data MSB Section 6.5.5
3*n - 1 CSR Address Section 6.5.3
3*n Data LSB Section 6.5.4
3*n + 1 Data MSB Section 6.5.5
Bits Name Default HW
Mode Description
15 Reserved
14:0 Section_length Section length in words (3 * number of CSRs to be configured).
Bit Name Description
15:8 Reserved
7:0 CRC8 CRC8 is computed over the module, header excluded (for example, starting
from word offset 0x2 included).
Ethernet Controller I210 —Flash Map
208
6.5.3 CSR Address - (Offset 3*n - 1; [n = 1... Section Length])
6.5.4 CSR Data LSB - (Offset 3*n; [n = 1... Section Length])
6.5.5 CSR Data MSB - (Offset 3*n + 1; [n = 1... Section Length])
6.6 RO Updates Version (Word 0x50)
This field is copied by firmware from the RO Updates Version field present in the trailer of the firmware
secured module. Refer to Section 6.9.2 and to Section 3.3.10.
6.7 Firmware Module (Word 0x51)
The Firmware Module is formed by a Firmware Module header and sub-modules. Content of the header
is listed in Table 6-5, which holds a list of pointers to all the firmware sub-modules.
The start address (Global Flash Word offset 0x0) of the Firmware Module header depicted in Table 6-5
is pointed to by the Firmware Module Pointer located at word 0x51 of the Flash.
Bits Name Default HW
Mode Description
15 Reserved
14:0 CSR_ADDR CSR Address in Double Words (4 bytes).
Bits Name Default HW
Mode Description
15:0 CSR_Data_LSB CSR Data LSB.
Bits Name Default HW
Mode Description
15:0 CSR_Data_MSB CSR Data MSB.
Table 6-5. Firmware Module Header
Global Flash
Word Offset Description
0x0:0x2 Reserved.
Value should be 0xFFFF.
0x3 Common Firmware Parameters Pointer - Section 6.7.1
0x4 Reserved.
0x5 Pass Through the LAN Configuration Pointer - Section 6.7.2
0x6 Side Band Configuration Pointer - Section 6.7.3
0x7 Flexible TCO Filter Configuration Pointer - Section 6.7.3.20
0x8 Reserved.
0x9 Reserved
Value should be 0xFFFF.
Flash Map—Ethernet Controller I210
209
6.7.1 Common Firmware Parameters – (Global MNG Offset 0x3)
6.7.1.1 Section Header — Offset 0x0
6.7.1.2 Common Firmware Parameters 1 - Offset 0x1
0xA NC-SI Configuration Pointer - Section 6.7.6
0xB Traffic Types Parameters pointer - Section 6.7.7
0xC OEM Flash Structure Pointer.
0xD Reserved.
0xE Reserved.
0xF PHY Configuration Pointer - Section 6.7.8
0x10 SVR/LVR Control Configuration Pointer - Section 6.7.9
Bits Name Default
HW Mode Description Reserved
15:8 Block CRC8 CRC8 is computed over the module, header included (for example,
starting from word offset 0x0 included) where CRC8 field was
zeroed before the computing.
7:0 Block Length 0x2 Block length in words.
Bits Name Default
HW Mode Description Reserved
15 Enable Firmware Reset
0b = Firmware reset via HICR is disabled.
1b = Firmware reset via HICR is enabled.
Setting this bit has no effect when in Flash secure mode.
14:13 Sideband Interface
00b = SMBus.
01b = NC-SI.
10b = Reserved.
11b = MCTP over PCIe and SMBus.
Relevant only if Manageability Mode is set to Pass Through mode
(0x2).
12 Restore MAC Address 0b = Do not restore MAC address at power on.
1b = Restore MAC address at power on.
11 Reserved 1b Reserved.
10:8 Manageability Mode
0x0 = None.
0x1 = Reserved.
0x2 = Pass Through (PT) mode.
0x7:0x3 = Reserved.
7:5 Reserved 111b Reserved.
4LAN Force TCO Reset
Disable 1b 0b = Enable Force TCO reset on the LAN.
1b = Disable Force TCO reset on the LAN.
Table 6-5. Firmware Module Header
Global Flash
Word Offset Description
Ethernet Controller I210 —Flash Map
210
6.7.1.3 Common Firmware Parameters 2 – Offset 0x2
6.7.2 Pass Through the LAN Configuration Modules (Global MNG
Offsets 0x05)
The following sections describe pointers and structures dedicated to pass-through mode.
These sections must be mapped in the non-protected area to enable an IT manager to change
it.
These sections are available only in Legacy SMBus mode.
3 Proxying Capable 1b 0b = Disable Protocol Offload.
1b = Enable Protocol Offload.
2 OS2BMC Capable 0b = Disable.
1b = Enable.
1:0 Reserved 11b Reserved.
Bits Name Default
HW Mode Description Reserved
15:12 Reserved Reserved
11 Multi-Drop NC-SI 1b
Multi-Drop NC-SI Topology.
0b = Point-to-point.
1b = Multi-drop (default).
When this bit is set, the NCSI_CRS_DV and NCSI_RXD[1:0] pins
are High-Z following power-up; otherwise, the pins are driven.
10 PARITY_ERR_RST_EN 1b When set, enables reset of management logic and generation of
internal firmware reset as a result of parity error detected in
management memories.
9 Enable the PHY in D3 0b
0b = The PHY/SERDES behavior in D3 depends on the MNG mode:
In NC-SI mode - The PHY/SERDES can be deactivated in D3 if the
MC has issued a clear initial state command.
In SMBus mode – The PHY/SERDES will stay active in D3 when in
this mode.
1b = The PHY/SERDES stays active in D3.
8:6 Reserved 111b Reserved.
5:1 Semaphore
Backoff Interval 0001b Number of 10 ms ticks that firmware must wait before taking
semaphore ownership again since it has released it. Yes
0 LAN_FTCO_ISOL_DIS 1b
LAN Force TCO Isolate Disable
1b = Disable.
0b = Enable.
Bits Name Default
HW Mode Description Reserved
Flash Map—Ethernet Controller I210
211
6.7.2.1 Section Header — Offset 0x0
6.7.2.2 LAN IPv4 Address 0 LSB; (MIPAF12 LSB) — Offset 0x01
This value is stored in the MIPAF[12] register (0x58E0). Refer to Section 8.22.9 for a description of this
register.
6.7.2.3 LAN IPv4 Address 0 MSB; (MIPAF12 MSB) — Offset 0x02
This value is stored in the MIPAF[12] register (0x58E0). Refer to Section 8.22.9 for a description of this
register.
6.7.2.4 LAN IPv4 Address 1; (MIPAF13) — Offset 0x03-0x04
Same structure as LAN IPv4 Address 0.
These values are stored in the MIPAF[13] register (0x58E4). Refer to Section 8.22.9 for a description of
this register.
6.7.2.5 LAN IPv4 Address 2; (MIPAF14) — Offset 0x05-0x06
Same structure as LAN IPv4 Address 0.
These values are stored in the MIPAF[14] register (0x58E8). Refer to Section 8.22.9 for a description of
this register.
Bits Name Default
HW Mode Description Reserved
15:8 Block CRC8 CRC8 is computed over the module, header included (for example,
starting from word offset 0x0 included) where CRC8 field was
zeroed before the computing.
7:0 Block Length
Block Length in Words
In the initial image the size of this section must be zero, but
enough space should be left to enable all filters to be set up (up to
offset 0x84). Firmware ignores bigger sizes than that to avoid
buffer overflow in case the software writes a value that is out of
bounds.
Bits Name Default
HW Mode Description Reserved
15:8 LAN IPv4 Address 0 Byte
1LAN IPv4 Address 0, Byte 1.
7:0 LAN IPv4 Address 0 Byte
0LAN IPv4 Address 0, Byte 0.
Bits Name Default
HW Mode Description Reserved
15:8 LAN IPv4 Address 0 Byte
3LAN IPv4 Address 0, Byte 3.
7:0 LAN IPv4 Address 0 Byte
2LAN IPv4 Address 0, Byte 2.
Ethernet Controller I210 —Flash Map
212
6.7.2.6 LAN IPv4 Address 3; (MIPAF15) — Offset 0x07-0x08
Same structure as LAN IPv4 Address 0.
These values are stored in the MIPAF[15] register (0x58EC). Refer to Section 8.22.9 for a description of
this register.
Note: This value is ignored if Enable ARP Response in LRXEN1 is set (Section 6.7.2.18).
6.7.2.7 LAN Ethernet MAC Address 0 LSB (MMAL0) — Offset 0x09
This word is loaded by firmware to the 16 LS bits of the MMAL[0] register. Refer to Section 8.22.10 for
a description of the register.
6.7.2.8 LAN Ethernet MAC Address 0 MID; (MMAL0) — Offset 0x0A
This word is loaded by firmware to the 16 MS bits of the MMAL[0] register.
6.7.2.9 LAN Ethernet MAC Address 0 MSB; (MMAH0) — Offset 0x0B
This word is loaded by firmware to the MMAH[0] register.
6.7.2.10 LAN Ethernet MAC Address 1; (MMAL/H1) — Offset 0x0C-0x0E
Same structure as LAN Ethernet MAC Address 0. Loaded to MMAL[1] and MMAH[1] registers.
6.7.2.11 LAN Ethernet MAC Address 2; (MMAL/H2) — Offset 0x0F-0x11
Same structure as LAN Ethernet MAC Address 0. Loaded to MMAL[2] and MMAH[2] registers.
6.7.2.12 LAN Ethernet MAC Address 3; (MMAL/H3) — Offset 0x12-0x14
Same structure as LAN Ethernet MAC Address 0. Loaded to MMAL[3] and MMAH[3] registers.
Bits Name Default
HW Mode Description Reserved
15:8 LAN Ethernet MAC Address 0, Byte 1.
7:0 LAN Ethernet MAC Address 0, Byte 0.
Bits Name Default
HW Mode Description Reserved
15:8 LAN Ethernet MAC Address 0, Byte 3.
7:0 LAN Ethernet MAC Address 0, Byte 2.
Bits Name Default
HW Mode Description Reserved
15:8 LAN Ethernet MAC Address 0, Byte 5.
7:0 LAN Ethernet MAC Address 0, Byte 4.
Flash Map—Ethernet Controller I210
213
6.7.2.13 LAN UDP/TCP Flexible Filter Ports 0 — 15; (MFUTP Registers) — Offset
0x15 - 0x34
The words depicted in Table 6-6 are loaded by Firmware to the MFUTP registers. Refer to
Section 8.22.2 for a description of the register.
Table 6-6. MFUTP Flash Words
Offset Bits Description Reserved
0x15 15:0 LAN UDP/TCP Flexible Filter Value Port0
0x16 15:0 LAN UDP/TCP Port0 Modifier - see the following table.
0x17 15:0 LAN UDP/TCP Flexible Filter Value Port1
0x18 15:0 LAN UDP/TCP Port1 Modifier - see the following table.
0x19 15:0 LAN UDP/TCP Flexible Filter Value Port2
0x1A 15:0 LAN UDP/TCP Port2 Modifier - see the following table.
0x1B 15:0 LAN UDP/TCP Flexible Filter Value Port3
0x1C 15:0 LAN UDP/TCP Port3 Modifier - see the following table.
0x1D 15:0 LAN UDP/TCP Flexible Filter Value Port4
0x1E 15:0 LAN UDP/TCP Port4 Modifier - see the following table.
0x1F 15:0 LAN UDP/TCP Flexible Filter Value Port5
0x20 15:0 LAN UDP/TCP Port5 Modifier - see the following table.
0x21 15:0 LAN UDP/TCP Flexible Filter Value Port6
0x22 15:0 LAN UDP/TCP Port6 Modifier - see the following table.
0x23 15:0 LAN UDP/TCP Flexible Filter Value Port7
0x24 15:0 LAN UDP/TCP Port7 Modifier - see the following table.
0x25 15:0 LAN UDP/TCP Flexible Filter Value Port8
0x26 15:0 LAN UDP/TCP Port8 Modifier - see the following table.
0x27 15:0 LAN UDP/TCP Flexible Filter Value Port9
0x28 15:0 LAN UDP/TCP Port9 Modifier - see the following table.
0x29 15:0 LAN UDP/TCP Flexible Filter Value Port10
0x2A 15:0 LAN UDP/TCP Port10 Modifier - see the following table.
0x2B 15:0 LAN UDP/TCP Flexible Filter Value Port11
0x2C 15:0 LAN UDP/TCP Port11 Modifier - see the following table.
0x2D 15:0 LAN UDP/TCP Flexible Filter Value Port12
0x2E 15:0 LAN UDP/TCP Port12 Modifier - see the following table.
0x2F 15:0 LAN UDP/TCP Flexible Filter Value Port13
0x30 15:0 LAN UDP/TCP Port13 Modifier - see the following table.
0x31 15:0 LAN UDP/TCP Flexible Filter Value Port14
0x32 15:0 LAN UDP/TCP Port14 Modifier - see the following table.
0x33 15:0 LAN UDP/TCP Flexible Filter Value Port15
0x34 15:0 LAN UDP/TCP Port15 Modifier - see the following table.
Ethernet Controller I210 —Flash Map
214
This table lists the port modifiers bits:
6.7.2.14 LAN VLAN Filter 0 - 7; (MAVTV Registers) — Offset 0x35 — 0x3C
The words depicted in Table 6-6 are loaded by firmware to the MAVTV registers. Refer to Section 8.22.1
for a description of the register.
Table 6-7. MAVTV Flash Words
6.7.2.15 Reserved Flash Words - Offset 0x3D and 0x3E
Flash words at offsets 0x3D to 0x3E are reserved.
6.7.2.16 LAN MANC Value LSB; (LMANC LSB) — Offset 0x3F
The value in this Flash word is stored in the LSB word of the MANC register. Refer to Section 8.22.5 for
a description of this register.
Bits Name Default
HW Mode Description Reserved
0 UDP Match if port is UDP.
1 TCP Match if port is TCP.
2 Source/Destination 0 = Compare destination port.
1 = Compare source port.
3:15 Reserved Reserved.
Offset Bits Description Reserved
0x35 15:12 Reserved.
0x35 11:0 LAN VLAN Filter 0 Value.
0x36 15:12 Reserved.
0x36 11:0 LAN VLAN Filter 1 Value.
0x37 15:12 Reserved.
0x37 11:0 LAN VLAN Filter 2 Value.
0x38 15:12 Reserved.
0x38 11:0 LAN VLAN Filter 3 Value.
0x39 15:12 Reserved.
0x39 11:0 LAN VLAN Filter 4 Value.
0x3A 15:12 Reserved.
0x3A 11:0 LAN VLAN Filter 5 Value.
0x3B 15:12 Reserved.
0x3B 11:0 LAN VLAN Filter 6 Value.
0x3C 15:12 Reserved.
0x3C 11:0 LAN VLAN Filter 7 Value.
Bits Name Default
HW Mode Description Reserved
15:0 Reserved 0x0 Reserved.
Flash Map—Ethernet Controller I210
215
6.7.2.17 LAN MANC Value MSB; (LMANC MSB) — Offset 0x40
The value in this Flash word is stored in the MSB word of the MANC register. Refer to Section 8.22.5 for
a description of this register.
6.7.2.18 LAN Receive Enable 1; (LRXEN1) — Offset 0x41
Bits Name Default
HW Mode Description Reserved
15:11 Reserved Reserved.
10 NET_TYPE 0b
NET TYPE:
0b = Pass only un-tagged packets.
1b = Pass only VLAN tagged packets.
Valid only if FIXED_NET_TYPE is set.
9 FIXED_NET_TYPE 0b
Fixed Net Type
If set, only packets matching the net type defined by the NET_TYPE
field passes to manageability. Otherwise, both tagged and un-
tagged packets can be forwarded to the manageability engine.
8 EN_IPv4_FILTER 0b
Enable IPv4 Address Filters
When set, the last 128 bits of the MIPAF register are used to store
4 IPv4 addresses for IPv4 filtering. When cleared, these bits store a
single IPv6 filter.
7 EN_XSUM_FILTER 0b
Enable Checksum Filtering to Manageability
When this bit is set, only packets that pass L3, L4 checksum are
sent to the MC.
6:0 Reserved Reserved.
Value should be 0b.
Bits Name Default
HW Mode Description Reserved
15:9 Receive Enable byte 12 MC SMBus slave address.
8 Reserved Reserved.
7Enable MC Dedicated
MAC
Enable MC Dedicated MAC
0b = Disable MC dedicated MAC.
1b = Enable MC dedicated MAC.
6 Reserved Reserved
Must be set to 1b.
5:4 Notification method
00b = SMBus alert.
01b = Asynchronous notify.
10b = Direct receive.
11b = Reserved.
3 Enable ARP Response
Enable ARP Response
0b = Disable ARP response.
1b = Enable ARP response.
2 Enable Status Reporting
Enable Status Reporting
0b = Disable status reporting.
1b = Enable status reporting.
1 Enable Receive All
Enable Receive All
0b = Disable receive all.
1b = Enable receive all.
0 Enable Receive TCO
Enable Receive TCO
0b = Disable receive TCO.
1b = Enable receive TCO.
Ethernet Controller I210 —Flash Map
216
6.7.2.19 LAN Receive Enable 2; (LRXEN2) — Offset 0x42
6.7.2.20 LAN MNGONLY LSB; (LMNGONLY LSB) - Offset 0x43
The value in this Flash word is stored in the LSB word of the MNGONLY register. Refer to Section 8.22.6
for a description of this register.
6.7.2.21 LAN MNGONLY MSB; (LMNGONLY MSB) - Offset 0x44
The value in this Flash word is stored in the MSB word of the MNGONLY register. Refer to
Section 8.22.6 for a description of this register.
6.7.2.22 Manageability Decision Filters 0 LSB; (MDEF0 LSB) - Offset 0x45
The value in this Flash word is stored in the LSB word of the MDEF[0] register. Refer to Section 8.22.7
for a description of this register.
6.7.2.23 Manageability Decision Filters 0 MSB; (MDEF0 MSB) - Offset 0x46
The value in this Flash word is stored in the MSB word of the MDEF[0] register. Refer to Section 8.22.7
for a description of this register.
Bits Name Default
HW Mode Description Reserved
15:8 Receive Enable byte 14 0x0 Alert value.
7:0 Receive Enable byte 13 0x0 Interface data.
Bits Name Default
HW Mode Description Reserved
15:8 Reserved
7:0 Exclusive to MNG
Exclusive to MNG
When set, indicates that packets forwarded by the manageability
filters to manageability are not sent to the host. Bits 0...7
correspond to decision rules defined in registers MDEF[0...7] and
MDEF_EXT[0...7].
Bits Name Default
HW Mode Description Reserved
15:0 Reserved 0x0 Reserved
Bits Name Default
HW Mode Description Reserved
15:0 MDEF0_L Loaded to 16 LS bits of MDEF[0] register.
Bits Name Default
HW Mode Description Reserved
15:0 MDEF0_M Loaded to 16 MS bits of MDEF[0] register.
Flash Map—Ethernet Controller I210
217
6.7.2.24 Manageability Decision Filters Extend 0 LSB; (MDEF_EXT0 LSB) - Offset
0x47
The value in this Flash word is stored in the LSB word of the MDEF_EXT[0] register. Refer to
Section 8.22.8 for a description of this register.
6.7.2.25 Manageability Decision Filters Extend 0 MSB; (MDEF_EXT0 MSB) -
Offset 0x48
The value in this Flash word is stored in the MSB word of the MDEF_EXT[0] register. Refer to
Section 8.22.8 for a description of this register.
6.7.2.26 Manageability Decision Filters; (MDEF1-6 and MDEF_EXT1-6) - Offset
0x49-0x60
Same as words 0x045...0x48 for MDEF[1] and MDEF_EXT[1]...MDEF[6] and MDEF_EXT[6]
6.7.2.27 Manageability Ethertype Filter 0 LSB; (METF0 LSB) - Offset 0x61
The value in this Flash word is stored in the LSB word of the METF[0] register. Refer to Section 8.22.4
for a description of this register.
6.7.2.28 Manageability Ethertype Filter 0 MSB; (METF0 MSB) - Offset 0x62
The value in this Flash word is stored in the MSB word of the METF[0] register. Refer to Section 8.22.4
for a description of this register.
6.7.2.29 Manageability Ethertype Filter 1...3; (METF1...3) - Offset 0x63...0x68
Same as words 0x61 and 0x62 for METF[1]...METF[3] registers.
Bits Name Default
HW Mode Description Reserved
15:0 MDEFEXT0_L Loaded to 16 LS bits of MDEF_EXT[0] register.
Bits Name Default
HW Mode Description Reserved
15:0 MDEF0EXT_M Loaded to 16 MS bits of MDEF_EXT[0] register.
Bits Name Default
HW Mode Description Reserved
15:0 METF0_L Loaded to 16 LS bits of METF[0] register.
Bits Name Default
HW Mode Description Reserved
15:0 METF0_M Loaded to 16 MS bits of METF[0] register (reserved bits in the METF
registers should be set in the Flash to the register’s default values).
Ethernet Controller I210 —Flash Map
218
6.7.2.30 ARP Response IPv4 Address 0 LSB; (ARP LSB) - Offset 0x69
Note: This value is overrides the value in LAN IPv4 Address 3 (Section 6.7.2.6) if Enable ARP
Response in LRXEN1 is set (Section 6.7.2.18).
6.7.2.31 ARP Response IPv4 Address 0 MSB; (ARP MSB) - Offset 0x6A
6.7.2.32 LAN IPv6 Address 0 LSB; (MIPAF0 LSB) - Offset 0x6B
This value is stored in the MIPAF[0] register (0x58B0). Refer to Section 8.22.9 for a description of this
register.
6.7.2.33 LAN IPv6 Address 0 MSB; (MIPAF0 MSB) - Offset 0x6C
This value is stored in the MIPAF[0] register (0x58B0). Refer to Section 8.22.9 for a description of this
register.
6.7.2.34 LAN IPv6 Address 0 LSB; (MIPAF1 LSB)- Offset 0x6D
This value is stored in the MIPAF[1] register (0x58B4). Refer to Section 8.22.9 for a description of this
register.
Bits Name Default
HW Mode Description Reserved
15:0 ARP Response IPv4
Address 0, Byte 1 ARP Response IPv4 Address 0, Byte 1 (firmware use).
7:0 ARP Response IPv4
Address 0, Byte 0 ARP Response IPv4 Address 0, Byte 0 (firmware use).
Bits Name Default
HW Mode Description Reserved
15:8 ARP Response IPv4
Address 0, Byte 3 ARP Response IPv4 Address 0, Byte 3 (firmware use).
7:0 ARP Response IPv4
Address 0, Byte 2 ARP Response IPv4 Address 0, Byte 2 (firmware use).
Bits Name Default
HW Mode Description Reserved
15:8 LAN IPv6 Address 0 Byte 1 LAN IPv6 Address 0 Byte 1.
7:0 LAN IPv6 Address 0 Byte 0 LAN IPv6 Address 0 Byte 0.
Bits Name Default
HW Mode Description Reserved
15:8 LAN IPv6 Address 0 Byte 3 LAN IPv6 Address 0 Byte 3.
7:0 LAN IPv6 Address 0 Byte 2 LAN IPv6 Address 0 Byte 2.
Flash Map—Ethernet Controller I210
219
6.7.2.35 LAN IPv6 Address 0 MSB; (MIPAF1 MSB) - Offset 0x6E
This value is stored in the MIPAF[1] register (0x58B4). Refer to Section 8.22.9 for a description of this
register.
6.7.2.36 LAN IPv6 Address 0 LSB; (MIPAF2 LSB) - Offset 0x6F
This value is stored in the MIPAF[2] register (0x58B8). See Section 8.22.9 for a description of this
register.
6.7.2.37 LAN IPv6 Address 0 MSB; (MIPAF2 MSB) - Offset 0x70
This value is stored in the MIPAF[2] register (0x58B8). Refer to Section 8.22.9 for a description of this
register.
6.7.2.38 LAN IPv6 Address 0 LSB; (MIPAF3 LSB) - Offset 0x71
This value is stored in the MIPAF[3] register (0x58BC). Refer to Section 8.22.9 for a description of this
register.
Bits Name Default
HW Mode Description Reserved
15:8 LAN IPv6 Address 0 Byte 5 LAN IPv6 Address 0 Byte 5.
7:0 LAN IPv6 Address 0 Byte 4 LAN IPv6 Address 0 Byte 4.
Bits Name Default
HW Mode Description Reserved
15:8 LAN IPv6 Address 0 Byte 7 LAN IPv6 Address 0 Byte 7.
7:0 LAN IPv6 Address 0 Byte 6 LAN IPv6 Address 0 Byte 6.
Bits Name Default
HW Mode Description Reserved
15:8 LAN IPv6 Address 0 Byte 9 LAN IPv6 Address 0 Byte 9.
7:0 LAN IPv6 Address 0 Byte 8 LAN IPv6 Address 0 Byte 8.
Bits Name Default
HW Mode Description Reserved
15:8 LAN IPv6 Address 0 Byte 11 LAN IPv6 Address 0 Byte 11.
7:0 LAN IPv6 Address 0 Byte 10 LAN IPv6 Address 0 Byte 10.
Bits Name Default
HW Mode Description Reserved
15:8 LAN IPv6 Address 0 Byte 13 LAN IPv6 Address 0 Byte 13
7:0 LAN IPv6 Address 0 Byte 12 LAN IPv6 Address 0 Byte 12
Ethernet Controller I210 —Flash Map
220
6.7.2.39 LAN IPv6 Address 0 MSB; (MIPAF3 MSB) - Offset 0x72
This value is stored in the MIPAF[3] register (0x58BC). Refer to Section 8.22.9 for a description of this
register.
6.7.2.40 LAN IPv6 Address 1; MIPAF (Offset 0x73:0x7A)
Same structure as LAN IPv6 Address 0.
These values are stored in the MIPAF[7:4] registers (0x58C0 - 0x58CC).
6.7.2.41 LAN IPv6 Address 2; MIPAF (Offset 0x7B:0x82)
Same structure as LAN IPv6 Address 0.
These values are stored in the MIPAF[11:8] registers (0x58D0 - 0x58DC).
6.7.2.42 Manageability Special Filters Modifier - MSB; (MSFM - LSB) - Offset
0x83
The value in these Flash words are stored in the LSB part of the MSFM register. Refer to Section 8.22.3
for a description of this register.
6.7.2.43 Manageability Special Filters Modifier - LSB; (MSFM - MSB) - Offset
0x84
The value in these Flash words will be stored in the MSB part of the MSFM register. Refer to
Section 8.22.3 for a description of this register.
6.7.3 Sideband Configuration Module (Global MNG Offset 0x06)
This module is pointed to by global offset 0x06 of the manageability control table.
Bits Name Default
HW Mode Description Reserved
15:8 LAN IPv6 Address 0 Byte 15 LAN IPv6 Address 0 Byte 15.
7:0 LAN IPv6 Address 0 Byte 14 LAN IPv6 Address 0 Byte 14.
Bits Name Default
HW Mode Description Reserved
15:0 MSFM_L Loaded to 16 MS bits of MSFM register (reserved bits in the MSFM
registers should be set in the Flash to the register’s default values).
Bits Name Default
HW Mode Description Reserved
15:0 MSFM_M Loaded to 16 MS bits of MSFM register (reserved bits in the MSFM
registers should be set in the Flash to the register’s default values).
Flash Map—Ethernet Controller I210
221
6.7.3.1 Section Header — Offset 0x0
6.7.3.2 SMBus Maximum Fragment Size — Offset 0x01
6.7.3.3 SMBus Notification Timeout and Flags — Offset 0x02
Bits Name Default
HW Mode Description Reserved
15:8 Block CRC8 CRC8 is computed over the module, header included (for example,
starting from word offset 0x0 included) where CRC8 field was
zeroed before the computing.
7:0 Block Length 0x15 Section length in words.
Bits Name Default
HW Mode Description Reserved
15:8 Reserved 0x00 Reserved.
7:0 Max Fragment Size 0x20
SMBus Maximum Fragment Size (bytes)
Note: Value should be in the 32 to 240 byte range.
In MCTP mode, this value should be set to 0x45 (64 bytes payload
+ 5 bytes of MCTP header).
Bits Name Default
HW Mode Description Reserved
15:8 SMBus Notification
Timeout (ms) 0xFF
SMBus Notification Timeout
Timeout value in milliseconds from notification to completion of
packet read by the external MC. When completion of read exceeds
the specified time packet is discarded.
Note: A value 0x0, no discard.
7:6 SMBus Connection Speed 00b
00b = Standard SMBus connection (100 KHz).
01b = 400 KHz connection
10b = 1 MHz connection
11b = Reserved
5SMBus Block Read
Command 0b 0b = Block read command is 0xC0.
1b = Block read command is 0xD0.
4 Reserved 1b Reserved.
3Enable fairness
arbitration 1b 0b = Disable fairness arbitration.
1b = Enable fairness arbitration.
2Disable SMBus ARP
Functionality 1b
Disable SMBus ARP Functionality
0b = Enable SMBus ARP Functionality.
1b = Disable SMBus ARP Functionality.
1 SMBus ARP PEC 1b
SMBus ARP PEC
0b = Disable SMBus ARP PEC.
1b = Enable SMBus ARP PEC.
0 SMBusTransactionsPEC 0b
SMBus TransactionsPEC
0b = Disable SMBus PEC for regular master SMBus transactions and
do not expect PEC in slave accesses.
1b = Enable SMBus PEC for regular master SMBus transactions and
check PEC in slave accesses.
Should be set in MCTP modes only.
Ethernet Controller I210 —Flash Map
222
6.7.3.4 SMBus Slave Addresses — Offset 0x03
6.7.3.5 Reserved — Offset 0x04
6.7.3.6 Reserved — Offset 0x05
6.7.3.7 NC-SI Configuration 1 - Offset 0x06
Bits Name Default
HW Mode Description Reserved
15:8 Reserved 0b Reserved.
7:1 SMBus 0 Slave Address 0x49 SMBus 0 slave address.
0 Reserved 0b Reserved.
Bits Name Default
HW Mode Description Reserved
15:0 Reserved 0x0 Reserved.
Bits Name Default
HW Mode Description Reserved
15:0 Reserved 0x0 Reserved.
Bits Name Default
HW Mode Description Reserved
15:11 Reserved Reserved.
10 Flow Control 0b 0b = NC-SI flow control disable.
1b = NC-SI flow control enable.
9NC-SI HW Arbitration
Support 0b
NC-SI HW Arbitration Support
0b = NC-SI HW arbitration not supported.
1b = NC-SI HW arbitration supported.
Note: If the NC-SI ARB Enable bit (bit 11) in the Functions Control
Flash word is set to 1b and NC-SI hardware arbitration is not
supported in the Firmware Flash bit then NC-SI hardware
arbitration logic operates in bypass mode and the I210 is allowed
to transmit through the NC-SI interface anytime.
8 Reserved Reserved. No
7:5 Package ID 0b Package ID.
4:0 Reserved 0x0 Reserved, must be 0.
Flash Map—Ethernet Controller I210
223
6.7.3.8 NC-SI Configuration 2 - Offset 0x07
6.7.3.9 NC-SI Hardware Arbitration Configuration - Offset 0x08
6.7.3.10 MCTP UUID - Time Low LSB (Offset 0x09)
The value stored in the MCTP UUID register should indicate the creation date of the image or an earlier
arbitrary date.
6.7.3.11 MCTP UUID - Time Low MSB (Offset 0x0A)
6.7.3.12 MCTP UUID - Time MID (Offset 0x0B)
Bits Name Default
HW Mode Description Reserved
15 Read NCSI Package ID
from SDP 0b 0b = Read from Flash.
1b = Read from SDP.
14:4 Reserved Reserved.
3:0 Max XOFF Renewal 0x0
NC-SI Flow Control MAX XOFF Renewal (# of XOFF renewals
allowed).
0x0 = Disabled. Unlimited number of XOFF frames can be sent.
0x1 = Up to 2 consecutive XOFFs frames can be sent by the I210.
0x2 = Up to 3 consecutive XOFFs frames can be sent by the I210.
0xF = Up to 0x10 consecutive XOFFs frames can be sent by the
I210.
Bits Name Default
HW Mode Description Reserved
15:0 Token Timeout 0XFFFF
NC-SI HW-Arbitration TOKEN Timeout (in 16 ns cycles). In order to
get the value in NC-SI REF_CLK cycles, this field should be
multiplied by 4/5.
Notes:
1. Setting value to 0x0 disables the timeout mechanism.
2. The timeout must be no fewer than 32,000 REF_CLK cycles
(for example, the value of the field should be greater or equal
to 0x9C40).
Bits Name Default
HW Mode Description Reserved
15:0 Time Low LSB Byte 0 & 1 of UUID as defined in DSP0236.
Bits Name Default
HW Mode Description Reserved
15:0 Time Low MSB Byte 2 & 3 of UUID as defined in DSP0236.
Bits Name Default
HW Mode Description Reserved
15:0 Time Mid Byte 4 & 5 of UUID as defined in DSP0236.
Ethernet Controller I210 —Flash Map
224
6.7.3.13 MCTP UUID - Time High and Version (Offset 0x0C)
6.7.3.14 MCTP UUID - Clock Seq (Offset 0x0D)
6.7.3.15 MCTP UUID - Node (Offset 0x0E-0x10)
6.7.3.16 OEM IANA (Offset 0x11)
6.7.3.17 NC-SI Over MCTP Message Types (Offset 0x12)
Bits Name Default
HW Mode Description Reserved
15:0 Time High and Version Byte 7 & 8 of UUID as defined in DSP0236.
Bits Name Default
HW Mode Description Reserved
15:0 Clock Seq and Reserved Byte 9 & 10 of UUID as defined in DSP0236.
Bits Name Default
HW Mode Description Reserved
15:0 Node Should contain the same value as the factory station MAC address.
Bits Name Default
HW Mode Description Reserved
15:0 OEM IANA Number 0x0
If not zero and not 0x157, the I210 accepts additional OEM
commands with this IANA number. These commands are accepted
only if the OEM Flash Structure Pointer (Section 6.7) is valid. The
set of commands accepted depends on the IANA value in this
field.
The regular Intel OEM commands are accepted only with IANA
0x157.
Bits Name Default
HW Mode Description Reserved
15:8 NC-SI Command Packet
Type 0x2
Defines the MCTP packet type used to identify NC-SI control
packets.
Note: The most significant bit is the IC bit and should be set to
zero.
No
7:0 NC-SI Pass Through
Packet Type 0x3
Defines the MCTP packet type used to identify NC-SI pass through
packets.
Note: The most significant bit is the IC bit and should be set to
zero.
No
Flash Map—Ethernet Controller I210
225
6.7.3.18 NC-SI Over MCTP Configuration (Offset 0x13)
6.7.3.19 MCTP Rate Limiter Config 1 (Offset 0x14)
6.7.3.20 MCTP Rate Limiter Config 2 (Offset 0x15)
6.7.4 Flexible TCO Filter Configuration Module (Global MNG Offset
0x07)
This module is pointed to by global offset 0x07 of the manageability control section.
6.7.4.1 Section Header — Offset 0x0
Bits Name Default
HW Mode Description Reserved
15:7 Reserved 0x0 Reserved. No
6 Simplified MCTP 0x0 If set, only SOM and EOM bits are used for the re-assembly
process. Relevant only in SMBus mode. No
5:0 Reserved Reserved.
Bits Name Default
HW Mode Description Reserved
15:0 MCTP Rate 0x9C40
Defines the number of cycles between accesses of the MCTP send
client to the memory arbiter.
This value provides a bit rate of 200 Kb/s.
No
Bits Name Default
HW Mode Description Reserved
15 Decision Point 1b
Defines if, when credits are available, a full MCTP message is sent
or a single VDM is sent.
0b = Full packet.
1b = single VDM.
No
14:9 Reserved 0x0 Reserved No
8:0 MCTP Max Credits 0x78
Defines the maximum number of 16 bytes credit that can be
accumulated in the MCTP rate limiter. These credits include the
VDM header line (one line for each 64 byte VDM).
The default represents a full Ethernet packet.
Yes
Bits Name Default
HW Mode Description Reserved
15:8 Block CRC8 CRC8 is computed over the module, header included (for example,
starting from word offset 0x0 included) where CRC8 field was
zeroed before the computing.
7:0 Block Length Section length in words.
Ethernet Controller I210 —Flash Map
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6.7.4.2 Flexible Filter Length and Control — Offset 0x01
6.7.4.3 Flexible Filter Enable Mask — Offset 0x02 – 0x09
6.7.4.4 Flexible Filter Data — Offset 0x0A – Block Length
Note: This section loads all flexible filters. The control + mask + filter data are repeatable as the
number of filters. Section length in offset 0 is for all filters.
6.7.5 Reserved (Global MNG Offset 0x09)
This module is pointed to by the global offset 0x09 pointer in the Firmware Module Header table
(Table 6-5). A pointer with a value of 0XFFFF means the section is reserved.
6.7.6 NC-SI Configuration Module (Global MNG Offset 0x0A)
This module is pointed to by global offset 0x0A of the manageability control table.
Bits Name Default
HW Mode Description Reserved
15:8 Flexible Filter Length
(Bytes) Flexible filter length in bytes.
7 Reserved Reserved.
6 Reserved Reserved.
5 Reserved Reserved.
4 Last Filter 1b Last filter.
3:2 Filter Index (0) 0x0 Filter index.
1 Reserved Reserved.
0 Apply Filter to LAN
Apply Filter to the LAN.
0b = Do not apply flex filter.
1b = Apply flex filter.
Bits Name Default
HW Mode Description Reserved
15:0 Flexible Filter Enable
Mask
Flexible Filter Enable Mask
Up to 128 Flex filter mask bits for Bytes defined in the Flexible Filter
Data
Bits Name Default
HW Mode Description Reserved
15:0 Flexible Filter Data Flexible Filter Data
Up to 128 bytes of data starting at offset 0x0A.
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6.7.6.1 Section Header — Offset 0x0
6.7.6.2 Rx Mode Control1 (RR_CTRL[15:0]) - Offset 0x1
6.7.6.3 Rx Mode Control2 (RR_CTRL[31:16]) - Offset 0x2
6.7.6.4 Tx Mode Control1 (RT_CTRL[15:0]) - Offset 0x3
6.7.6.5 Tx Mode Control2 (RT_CTRL[31:16]) - Offset 0x4
6.7.6.6 MAC Tx Control Reg1 (TxCntrlReg1 (15:0]) - Offset 0x5
Bits Name Default
HW Mode Description Reserved
15:8 Block CRC8
7:0 Block Length 0x9 Section length in words.
Bits Name Default
HW Mode Description Reserved
15:2 Reserved Reserved. Should be set to 0x0.
1 CRC Strip Enable When set, CRC field is stripped from incoming NC-SI packets. Yes
0 NC-SI Loopback Enable When set, enables NC-SI Tx to Rx loop. All data that is transmitted
from NC-SI is returned to it. No data is actually transmitted from
NC-SI.
Bits Name Default
HW Mode Description Reserved
15:0 Reserved Reserved. Should be set to 0x0.
Bits Name Default
HW Mode Description Reserved
15:0 Reserved Reserved. Should be set to 0x0.
Bits Name Default
HW Mode Description Reserved
15:0 Reserved Reserved. Should be set to 0x0.
Bits Name Default
HW Mode Description Reserved
15:0 Reserved Reserved. Should be set to 0x0.
Ethernet Controller I210 —Flash Map
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6.7.6.7 MAC Tx Control Reg2 (TxCntrlReg1 (31:16]) - Offset 0x6
6.7.6.8 Reserved - Offset 0x7
6.7.6.9 NC-SI Flow Control XOFF - Offset 0x8
6.7.6.10 NC-SI Flow Control XON - Offset 0x9
Bits Name Default
HW Mode Description Reserved
15:0 Reserved Reserved. Should be set to 0x0.
Bits Name Default
HW Mode Description Reserved
15:0 Reserved Reserved. Should be set to 0x0.
Bits Name Default
HW Mode Description Reserved
15:0 XOFF Threshold
Tx buffer watermark for sending a XOFF NC-SI flow control packet
in bytes. The XOFF Threshold value refers to the occupied space in
the buffer.
Notes:
1. Field relevant for NC-SI operation mode only.
2. To support a maximum packet size of 1.5 KB, the value
programmed should be:
Tx buffer size (refer to Section 6.7.6.8) - 3,400 bytes.
a. When Tx buffer size is 6 KB value of field should be
0xAB8 (2,744 bytes).
Bits Name Default
HW Mode Description Reserved
15:0 XON Threshold
Tx buffer water mark for sending a XON NC-SI flow control packet
in bytes. The XON Threshold value refers to the available space in
the TX buffer.
Notes:
1. Field relevant for NC-SI operation mode only.
2. To support maximum packet size of 1.5 KB, the value
programmed should be a positive value that equals:
TX Buffer size (refer to Section 6.7.6.8) - XOFF Threshold
(refer to Section 6.7.6.9) + 1536 bytes.
a. When the TX Buffer size is 6 KB and the XOFF Threshold
is 2,744 bytes value of field should be 0x1348 (4,936
bytes).
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229
6.7.7 Traffic Type Parameters – (Global MNG Offset 0xB)
6.7.7.1 Section Header — Offset 0x0
6.7.7.2 Traffic Type Data - Offset 0x1
6.7.8 PHY Configuration Pointer – (Global MNG Offset 0xF)
6.7.8.1 PHY Configuration Structure
This section describes the PHY auto configuration structure used to configure PHY related circuitry. The
programming in this section is made of PHY registers address/data items. Each item includes bits that
define:
The PHY interface to be used - external/internal, register set, pins
The loading event - PHY reset or POR only
The PHY Configuration Pointer (Global MNG Offset 0xF) points to the start (offset 0x0) of this type of
structure to configure PHY registers (internal and external PHYs). If pointer is 0xFFFF then no structure
exists.
When the FW has completed the configuration, it is required to move back the PHY interface mode to
the default loaded from Flash in order to avoid an impact on SW driver.
Bits Name Default
HW Mode Description Reserved
15:8 Block CRC8
7:0 Block Length 0x1 Section length in words.
Bits Name Default
HW Mode Description Reserved
15:2 Reserved Reserved
1:0 Traffic Types
00b = Reserved.
01b = Network to MC traffic only allowed.
10b = OS2BMC traffic only allowed.
11b = Both Network to MC traffic and OS2BMC traffic allowed.
Notes:
1. The traffic types defined by this field are enabled by the
Manageability Mode field and the OS2BMC Capable bit in the
Common Firmware Parameters 1 Flash word (refer to
Section 6.7.1.2).
2. Field loaded to MANC.EN_BMC2NET bit and
MANC.EN_BMC2OS bit (refer to Section 8.22.5).
Bit Name Description
15:0 Pointer Pointer to PHY configuration structure. Refer to Section 6.7.8.1 for
details of the structure. A value of 0xFFFF means the pointer is
invalid.
Ethernet Controller I210 —Flash Map
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6.7.8.1.1 PHY Configuration Section Length - Offset 0x0
The section length word contains the length of the section in words. Note that section length count does
not include the section length word and Block CRC8 word.
6.7.8.1.2 Block CRC8 (Offset 0x1)
6.7.8.1.3 PHY Number and PHY Register Address - (Offset 2*n; [n = 1... Section Length])
Table 6-8. PHY Auto Configuration Structure Format
Offset High Byte[15:8] Low Byte[7:0] Section
0x0 Section length = 2*n (n – number of registers to configure) Section 6.7.8.1.1
0x1 Block CRC8. Section 6.7.8.1.2
0x2 PHY number and PHY register address. Section 6.7.8.1.3
0x3 PHY data (MDIC[15:0] or I2CCMD[15:0]). Section 6.7.8.1.4
2*n PHY number and PHY register address Section 6.7.8.1.3
2*n + 1 PHY data (MDIC[15:0] or I2CCMD[15:0]) Section 6.7.8.1.4
Bits Name Default
HW Mode Description
15 Reserved
14:0 Section_length Section length in words.
Bit Name Description
15:8 Reserved
7:0 CRC8 CRC8 is computed over the module, header excluded (for example, starting
from word offset 0x2 included).
Bits Name Default HW
Mode Description
15:14 Transaction Interface 00b
Defines the PHY interface to be used for the transaction:
00b - Internal PHY, via MDIC register
01b - External PHY over I2C pins, via MDIC register
10b - External PHY over I2C pins, via I2CCMD register
11b - Reserved
13:9 Reserved 0x0 Reserved
8 Loading Event 0b
Defines the loading event:
0b - PHY resets (including POR).
1b - POR only. This mode is not effective for internal copper PHY settings
as a PHY reset event occurs anyway after boot time.
7:0 PHY Register Address
PHY register address to which the data is written.
See Section 8.2.4 and Section 8.17.8 for information on the MDIC and
I2CCMD registers, respectively.
Note: 5 LSB bits define the register address when access is via the MDIC
register.
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6.7.8.1.4 PHY Data (Offset 2*n + 1; [n = 1... Section Length])
6.7.9 SVR Control Pointer – (Global MNG Offset 0x10)
6.7.9.1 SVR/LVR Control Configuration Structure
This section describes the PHY auto configuration structure used to configure SVR/LVR control related
circuitry. The programming in this section is applied after power-up.
The SVR/LVR control Configuration Pointer (Global MNG Offset 0x10) points to the start (offset 0x0) of
this type of structure, to configure SVR/LVR Control registers. If pointer is 0xFFFF then no structure
exists.
6.7.9.1.1 SVR/LVR Control Configuration Section Length - Offset 0x0
The section length word contains the length of the section in words. Note that section length count does
not include the section length word and Block CRC8 word.
Bits Name Default HW
Mode Description
15:0 Reg_Data
MDIC[15:0]/I2CCMD[15:0] value (data).
See Section 8.2.4 and Section 8.17.8 for information MDIC and I2CCMD
registers, respectively.
Bit Name Description
15:0 Pointer Pointer to SVR/LVR control configuration structure. Refer to
Section 6.7.9.1 for details of the structure. A value of 0xFFFF means
the pointer is invalid.
Offset High Byte[15:8] Low Byte[7:0] Section
0x0 Section Length = 2*n (n – number of registers to configure). Section 6.7.9.1.1
0x1 Block CRC8. Section 6.7.9.1.2
0x2 SVR/LVR Control register address. Section 6.7.9.1.3
0x3 SVR/LVR Control data. Section 6.7.9.1.4
2*n SVR/LVR Control register address. Section 6.7.9.1.3
2*n + 1 SVR/LVR Control data. Section 6.7.9.1.4
Bits Name Default
HW Mode Description
15 Reserved
14:0 Section_length Section length in words.
Ethernet Controller I210 —Flash Map
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6.7.9.1.2 Block CRC8 (Offset 0x1)
6.7.9.1.3 SVR/LVR Control Register Address - (Offset 2*n; [n = 1... Section Length])
6.7.9.1.4 SVR/LVR Control Data (Offset 2*n + 1; [n = 1... Section Length])
6.8 Software Accessed Words
Words 0x03 to 0x07 in the Flash image are reserved for compatibility information. New bits within
these fields are defined as the need arises for determining software compatibility between various
hardware revisions.
Words 0x8 and 0x09 are used to indicate the Printed Board Assembly (PBA) number and words 0x42
and 0x43 identifies the Flash iNVM image.
Words 0x30 to 0x3E have been reserved for configuration and version values to be used by PXE code.
The only exceptions are words 0x36 and 0x3D, which are used for the iSCSI boot configuration and
word 0x37 which is used as a pointer to the Alternate MAC address.
6.8.1 Compatibility (Word 0x03)
Bit Name Description
15:8 Reserved
7:0 CRC8 CRC8 is computed over the module, header excluded (for example, starting
from word offset 0x2 included).
Bits Name Default HW
Mode Description
15:5 Reserved 0x0 Reserved
4:0 SVR/LVR Control Register
Address
SVR/LVR Control register address to which the data is written.
Bits Name Default HW
Mode Description
15:0 Reg_Data SVR/LVR Control register data.
Bit Description
15:13 Reserved (set to 000b).
12 IT part - Bit is set to 1b on Industrial Temperature SKU.
11
This bit indicates whether the NVM attached to the LAN silicon contains a dedicated area for storing Option ROM
firmware (sometimes also called a "Boot ROM"). This bit is used by Option ROM software update utilities and
other applications to decide whether or not to allow updating the Option ROM firmware as well as whether or not
to allow enabling/disabling the Option ROM by means of the PCI Expansion ROM Base Address Register (BAR).
0b = NIC (Attached Flash has an area for storing Option ROM firmware).
1b = LOM (Attached Flash does not have an area for storing Option ROM firmware).
Flash Map—Ethernet Controller I210
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6.8.2 Port Identification LED Blinking (Word 0x04)
Default Flash setting for this word must be 0xFFFF.
6.8.3 Flash Map Revision (Word 0x05)
This word is valid only for device starter images and indicates the version of the Flash map.
6.8.4 OEM Specific (Words 0x06, 0x07)
These words are available for OEM use.
6.8.5 PBA Number (Words 0x08, 0x09)
The nine-digit Printed Board Assembly (PBA) number used for Intel manufactured Network Interface
Cards (NICs) is stored in the FlashiNVM.
Note that through the course of hardware ECOs, the suffix field is incremented. The purpose of this
information is to enable customer support (or any user) to identify the revision level of a product.
Network driver software should not rely on this field to identify the product or its capabilities.
10 Reserved.
9
Client/not a Client NIC. This bit is used by DMIX to verify the NIC is server or client. A team is required to have
server NIC or LOM.
0b = Server.
1b = Client.
8:0 Reserved (set to 00b).
Bit Description
15:12 Reserved.
11:8
Control for LED 2
0001b = Default in STATE1 + Default in STATE2.
0010b = Default in STATE1 + LED is ON in STATE2.
0011b = Default in STATE1 + LED is OFF in STATE2.
0100b = LED is ON in STATE1 + Default in STATE2.
0101b = LED is ON in STATE1 + LED is ON in STATE2.
0110b = LED is ON in STATE1 + LED is OFF in STATE2.
0111b = LED is OFF in STATE1 + Default in STATE2.
1000b = LED is OFF in STATE1 + LED is ON in STATE2.
1001b = LED is OFF in STATE1 + LED is OFF in STATE2.
7:4 Control for LED 1 – same encoding as for LED2.
3:0 Control for LED 0 – same encoding as for LED2.
Bit Description
15:12 Flash major version (decimal).
11:8 0x0 (for the decimal point)
7:0 Flash minor version (decimal).
Bit Description
Ethernet Controller I210 —Flash Map
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Current PBA numbers have exceeded the length that can be stored as hex values in these two words.
For these PBA numbers the high word is a flag (0xFAFA) indicating that the PBA is stored in a separate
PBA block. The low word is a pointer to a PBA block.
The PBA block is pointed to by word 0x09.
The PBA block contains the complete PBA number including the dash and the first digit of the 3-digit
suffix. For example:
Note: For Flash images that are not for Intel manufactured Network Interface Cards (NICs) word
0x8 holds the version of the Flash image. The same word format is used as for the Flash map
version in word 0x05.
6.8.6 PXE Configuration Words (Words 0x30:3B)
PXE configuration is controlled by the following words.
6.8.6.1 Setup Options PCIe Function 0 (Word 0x30)
The main setup options are stored in word 0x30. These options are those that can be changed by the
user via the Control-S setup menu. Word 0x30 has the following format:
PBA Number Word 0x08 Word 0x09
G23456-003 FAFA Pointer to PBA Block
Word Offset Description Reserved
0x0 Length in words of the PBA block (default 0x6).
0x1... 0x5 PBA number stored in hexadecimal ASCII values.
PBA Number Word Offset 0 Word Offset 1 Word Offset 2 Word Offset 3 Word Offset 4 Word Offset 5
G23456-003 0006 4732 3334 3536 2D30 3033
Bit(s) Name Function
15:13 RFU Reserved. Must be 0x0.
12:10 FSD
Bits 12-10 control forcing speed and duplex during driver operation.
000b = Auto-negotiate.
001b = 10 Mb/s half duplex.
010b = 100 Mb/s half duplex.
011b = Not valid (treated as 000b).
100b = Not valid (treated as 000b).
101b = 10 Mb/s full duplex.
110b = 100 Mb/s full duplex.
111b = 1000 Mb/s full duplex.
Default value is 000b.
9 RFU Reserved. Must be 0b.
8 DSM
Display Setup Message
If the bit is set to 1b, the “Press Control-S” message is displayed after the title message. Default value is
1b.
Flash Map—Ethernet Controller I210
235
6.8.6.2 Configuration Customization Options PCIe Function (Word 0x31)
Word 0x31 of the Flash contains settings that can be programmed by an OEM or network administrator
to customize the operation of the software. These settings cannot be changed from within the Control-
S setup menu. The lower byte contains settings that would typically be configured by a network
administrator using an external utility; these settings generally control which setup menu options are
changeable. The upper byte is generally settings that would be used by an OEM to control the operation
of the agent in a LOM environment, although there is nothing in the agent to prevent their use on a NIC
implementation. The default value for this word is 0x4000.
7:6 PT
Prompt Time
These bits control how long the CTRL-S setup prompt message is displayed, if enabled by DIM.
00b = 2 seconds (default).
01b = 3 seconds.
10b = 5 seconds.
11b = 0 seconds.
Note: CTRL-S message is not displayed if 0 seconds prompt time is selected.
5Disable
iSCSI
Setup Menu
This controls the iSCSI init message (Ctrl+D menu prompt) when iSCSI is disabled.
When iSCSI option ROM is disabled and this bit is set to 1b, the init message is not displayed for the
port.
When iSCSI option ROM is disabled and this bit is set to 0b, the init message is displayed for the
port.
When iSCSI option ROM is enabled this bit does not matter, as the init message is displayed for the
port.
The default is 0b.
4:3 DBS
Default Boot Selection
These bits select which device is the default boot device. These bits are only used if the agent detects
that the BIOS does not support boot order selection or if the MODE field of word 0x31 is set to
MODE_LEGACY.
00b = Network boot, then local boot (default).
01b = Local boot, then network boot.
10b = Network boot only.
11b = Local boot only.
2:0 PS Protocol Select.
See Table 6-9 for details of this field.
Bit(s) Name Function
15:14 SIG Signature. Must be set to 01b to indicate that this word has been programmed by the agent or other
configuration software.
13 RFU Reserved. Must be 0b.
12 RFU Reserved. Must be 0b.
11 RETRY
Selects Continuous Retry operation.
If this bit is set, IBA does NOT transfer control back to the BIOS if it fails to boot due to a network error
(such as failure to receive DHCP replies). Instead, it restarts the PXE boot process again. If this bit is set,
the only way to cancel PXE boot is for the user to press ESC on the keyboard. Retry is not attempted due
to hardware conditions such as an invalid Flash checksum or failing to establish link.
Default value is 0b.
Bit(s) Name Function
Ethernet Controller I210 —Flash Map
236
6.8.6.3 PXE Version (Word 0x32)
Word 0x32 of the Flash is used to store the version of the boot agent that is stored in the Flash image.
When the Boot Agent loads, it can check this value to determine if any first-time configuration needs to
be performed. The agent then updates this word with its version. Some diagnostic tools also read this
word to report the version of the PXE Boot Agent in the Flash.
The format of this word is:
10:8 MODE
Selects the agent’s boot order setup mode.
This field changes the agent’s default behavior in order to make it compatible with systems that do not
completely support the BBS and PnP Expansion ROM standards. Valid values and their meanings are:
000b = Normal behavior. The agent attempts to detect BBS and PnP Expansion ROM support as it normally
does.
001b = Force Legacy mode. The agent does not attempt to detect BBS or PnP Expansion ROM supports in
the BIOS and assumes the BIOS is not compliant. The user can change the BIOS boot order in the Setup
Menu.
010b = Force BBS mode. The agent assumes the BIOS is BBS-compliant, even though it might not be
detected as such by the agent’s detection code. The user CANNOT change the BIOS boot order in the
Setup Menu.
011b = Force PnP Int18 mode. The agent assumes the BIOS enables boot order setup for PnP Expansion
ROMs and hooks interrupt 0x18 (to inform the BIOS that the agent is a bootable device) in addition to
registering as a BBS IPL device. The user CANNOT change the BIOS boot order in the Setup Menu.
100b = Force PnP Int19 mode. The agent assumes the BIOS enables boot order setup for PnP Expansion
ROMs and hooks interrupt 0x19 (to inform the BIOS that the agent is a bootable device) in addition to
registering as a BBS IPL device. The user CANNOT change the BIOS boot order in the Setup Menu.
101b = Reserved for future use. If specified, is treated as a value of 000b.
110b = Reserved for future use. If specified, is treated as a value of 000b.
111b = Reserved for future use. If specified, is treated as a value of 000b.
7 RFU Reserved. Must be 0b.
6 RFU Reserved. Must be 0b.
5 DFU Disable Flash Update
If this bit is set to 1b, the user is not allowed to update the Flash image using PROSet. Default value is 0b.
4 DLWS
Disable Legacy Wakeup Support
If this bit is set to 1b, the user is not allowed to change the Legacy OS Wakeup Support menu option.
Default value is 0b.
3 DBS Disable Boot Selection
If this bit is set to 1b, the user is not allowed to change the boot order menu option. Default value is 0b.
2 DPS Disable Protocol Select. If set to 1b, the user is not allowed to change the boot protocol. Default value is
0b.
1 DTM
Disable Title Message
If this bit is set to 1b, the title message displaying the version of the Boot Agent is suppressed; the
Control-S message is also suppressed. This is for OEMs who do not wish the boot agent to display any
messages at system boot. Default value is 0b.
0 DSM
Disable Setup Menu.
If this bit is set to 1b, the user is not allowed to invoke the Setup menu by pressing Control-S. In this
case, the Flash might only be changed via an external program. Default value is 0b.
Bit(s) Name Function
15:12 MAJ PXE Boot Agent Major Version.
11:8 MIN PXE Boot Agent Minor Version.
7:0 BLD PXE Boot Agent Build Number.
Bit(s) Name Function
Flash Map—Ethernet Controller I210
237
6.8.6.4 Option ROM Capabilities (Word 0x33)
Word 0x33 of the Flash is used to enumerate the boot technologies that have been programmed into
the Flash. This is updated by Flash configuration tools and is not updated or read by IBA.
6.8.6.5 PXE VLAN Configuration Pointer (0x003C)
6.8.6.5.1 PXE VLAN Configuration Section
6.8.6.5.1.1 VLAN Block Signature - 0x0000
Bit(s) Name Function
15:14 SIG Signature. Must be set to 01b to indicate that this word has been programmed by the agent or other
configuration software.
13:5 RFU Reserved. Must be 0b.
4 ISCSI iSCSI boot is present in Flash if set to 1b.
3 UEFI UEFI UNDI driver is present in Flash if set to 1b.
2 RPL Reserved. Must be 0b.
1 UNDI PXE UNDI driver is present in Flash if set to 1b.
0 BC PXE base code is present in Flash if set to 1b.
Bits Name Default Description
15:0 PXE VLAN Configu-
ration Pointer 0x0 The pointer contains offset of the first Flash word of the PXE VLAN config block.
Word Offset Word Name Description
0x0000 VLAN Block Signature ASCII 'V', 'L'.
0x0001 Version and Size Contains version and size of structure.
0x0002 VLAN Tag VLAN tag value for the I210. Contains PCP, CFI and
VID fields. A value of 0 means no VLAN is configured
for this port.
Bits Field Name Default Description
15:0 VLAN Block Signature 0x4C56 ASCII 'V', 'L'.
Ethernet Controller I210 —Flash Map
238
6.8.6.5.1.2 Version and Size - 0x0001
6.8.6.5.1.3 VLAN Tag - 0x0002
6.8.7 iSCSI Boot Words
6.8.7.1 iSCSI Option ROM Version (Word 0x36)
Word 0x36 is used to store the version of the iSCSI Boot option ROM if present. Values below 0x2000
are reserved and should not be used. This word can be modified by Flash update utilities.
6.8.7.2 iSCSI Boot Configuration Pointer (Word 0x3D)
6.8.7.2.1 iSCSI Module Structure
The following table lists the layout of the iSCSI boot configuration block stored in Flash. Flash word
0x3D previously described stores the offset within the Flash of the configuration block. Software must
first read word 0x3D to determine the offset of the configuration table before attempting to read or
write the configuration block.
The following defined strings are stored in UTF-8 encoding and NULL terminated. All data words are
stored in little-endian (Intel) byte order.
Bits Field Name Default Description
15:8 Size 0x06 Total size in bytes of section.
7:0 Version 0x01 Version of this structure. Should be set to 0x1.
Bits Field Name Default Description
15:13 Priority (0-7) 0x0 Priority 0-7.
12 Reserved 0x0 Always 0.
11:0 VLAN ID (1- 4095) 0x0 VLAN ID (1-4095).
Bit Name Description
15:0 iSCSI Address
iSCSI Configuration Block Flash Offset
Offset of iSCSI configuration block from the start of the Flash, expressed in words. If set
to 0x0000 or 0xFFFF there is no Flash configuration data available for the iSCSI adapter.
In this case, configuration data must be provided by the BIOS through the SM CLP
interface.
Flash Map—Ethernet Controller I210
239
Configuration Item Offset
(Bytes)
Size in
Bytes Comments
Boot Signature 0x1:0x0 2 0x5369 (‘i’, ‘S’)
Block Size 0x3:0x2 2
The structure size is stored in this field and is set depending on the
amount of free Flash space available. The total size of this structure,
including variable length fields, must fit within this space.
0x0384 - single port.
Structure Version 0x4 1 Version of this structure. Should be set to one.
Reserved 0x5 1 Reserved for future use, should be set to zero.
iSCSI Initiator Name 0x105:0x6 255 + 1 iSCSI Initiator Name
This field is optional and can also be built by DHCP.
iSCSI Configuration Block
0x107:0x106 2 Bits 15:8 (Major) - Combo image major version.
Bits 7:0 (Build) - Combo image build number (15:8).
0x109:0x108 2 Bits 15:8 (Build) - Combo image build number (7:0).
Bits 7:0 (Minor) - Combo image minor version.
Reserved 0x127:0x10A 30 Reserved for future use, should be set to zero.
The following fields are for the port
iSCSI Flags 0x129:0x128 2
Bit 0 Enable DHCP:
0 = Use static configurations from this structure.
1 = Overrides configurations retrieved from DHCP.
Bit 01h Enable DHCP for getting iSCSI target information:
0 = Use static target configuration
1 = Use DHCP to get target information.
Bit 0x02:0x03 Authentication Type:
00 = None.
01 = One way chap.
02 = Mutual chap.
Bit 0x04:0x05 Ctrl-D setup menu:
00 = enabled.
03 = disabled.
Bit 0x06:0x07 Reserved.
Bit 0x08:0x09 ARP Retries.
Retry value:
Bit 0x0A:0x0F ARP Timeout.
Timeout value for each retry.
iSCSI Initiator IP 0x12D:0x12A 4 DHCP flag not set This field should contain the configured IP address.
DHCP flag set If DHCP bit is set this field is ignored.
Initiator Subnet Mask 0x131:0x12E 4
DHCP flag not set This field should contain the configured subnet
mask.
DHCP flag set If DHCP bit is set this field is ignored.
Initiator Gateway IP 0x135:0x132 4 DHCP flag not set This field should contain the configured gateway
DHCP flag set If DHCP bit is set this field is ignored.
iSCSI Boot LUN 0x137:0x136 2 DHCP flag not set Target LUN that Initiator will be attached to.
DHCP flag set If DHCP bit is set this field is ignored.
iSCSI Target IP 0x13B:0x138 4 DHCP flag not set IP address of iSCSI target.
DHCP flag set If DHCP bit is set this field is ignored.
iSCSI Target Port 0x13D:0x13C 2 DHCP flag not set IP port of iSCSI target. Default is 3260.
DHCP flag set If DHCP bit is set this field is ignored
iSCSI Target Name 0x23D:0x13E 255 + 1 DHCP flag set If DHCP bit is set this field is ignored
CHAP Password 0x24F:0x23E 16 + 2 The minimum CHAP secret must be 12 octets and maximum CHAP
secret size is 16. 1 byte is reserved for alignment padding and 1 byte
for null.
Ethernet Controller I210 —Flash Map
240
6.8.8 Alternate MAC Address Pointer (Word 0x37)
This word can point to a location in the Flash containing additional MAC addresses used by system
management functions. If the additional MAC addresses are not supported, the word must be set to
0xFFFF. The structure of the alternate MAC address block can be found in Table 6-9.
6.8.9 Checksum Word (Word 0x3F)
The checksum words (Offset 0x3F from start of the Common, LAN 1, LAN 2 and LAN 3 sections) are
used to ensure that the base Flash image is a valid image. The value of this word should be calculated
such that after adding all the words (0x00:0x3F), including the checksum word itself, the sum should
be 0xBABA. The initial value in the 16-bit summing register should be 0x0000 and the carry bit should
be ignored after each addition.
Notes: Hardware does not calculate the checksum word during Flash write; it must be calculated by
software independently and included in the Flash write data. Hardware does not compute a
checksum over words 0x00:0x3F during Flash reads in order to determine validity of the
Flash image; this field is provided strictly for software verification of Flash validity. All
hardware configurations based on word 0x00:0x3F content is based on the validity of the
Signature field of the Flash Sizing & Protected Fields Flash word (Signature must be 01b).
However, firmware is required to recompute and update the checksum word whenever it
restores the MAC address. Refer to Section 4.5.11.
6.8.10 Image Unique ID (Words 0x42, 0x43)
These words contain a unique 32-bit ID for each image generated by Intel to enable tracking of images
and comparison to the original image if testing a customer Flash iNVM image.
6.8.11 mDNS Records Area Offset (Word 0x25)
This word contains the offset to the Flash area provisioned for the storage of the mDNS records.
CHAP User Name 0x2CF:0x250 127 + 1 The user name must be non-null value and maximum size of user name
allowed is 127 characters.
Vlan ID 0x2D1:0x2D0 2 Vlan Id to be used for iSCSI boot traffic. a valid Vlan ID is between 1
and 4094
Mutual CHAP Password 0x2E3:0x2D2 16 + 2 The minimum mutual CHAP secret must be 12 octets and maximum
CHAP secret size is 16. 1 byte is reserved for alignment padding and 1
byte for null.
Reserved 0x323:0x2E4 64 Reserved for FCoE - not relevant in the I210 - should be set to zero.
Reserved 0x383:0x324 96 Reserved for future use, should be set to zero.
Table 6-9. Alternate MAC Address Block
Word Offset Description1
1. An alternate MAC Address value of 0xFFFF-FFFF-FFFF means that no alternate MAC address is present for the port.
0x0...0x2 Alternate MAC Address for the LAN port
0x3...0xB Reserved
Configuration Item Offset
(Bytes)
Size in
Bytes Comments
Flash Map—Ethernet Controller I210
241
The offset is relative to the beginning of the secured firmware image. It is expressed in a 4 KB sector
index, which is indicated by setting to 1b the word’s most significant bit. The offset must be
programmed in such a way that the mDNS records be mapped next tom the FW image. For instance, if
the FW image area is provisioned up to 448 KB, the default value is 0x8070.
This word is an indication to the host driver, which is not expected to modify its content unless a FW
image update occurred.
6.8.12 mDNS Records Area Size (Word 0x26)
This word contains the size in KB units of the Flash area provisioned for the storage of mDNS records.
Recommended default is 16 KB.
This word is an indication to the host driver, which is not expected to modify its content even if less
space is required.
6.9 Firmware Secured Module Pointer (Word 0x10)
This section describes the format of the firmware secured module that contains the authenticated
firmware image (the firmware code). It is pointed from word 0x10 and it is expressed in 4 KB Flash
sector units. The Flash area provisioned to this module must be equal to the size of the Free
Provisioned Area (244 KB in first Flash images produced, and then 448 KB in the future if the FW code
grows beyond 235 KB). It is also referred as the Flash secured area. The free area segment is
provisioned to update this module via a double bank policy, refer to Section 3.3.9.2. The free
provisioning area is pointed by word 0x40. The size of the area is expressed in
4 KB units and is listed in word 0x41. It should not be modified by software.
The firmware secured module includes a header and a trailer that enclose the firmware code.
6.9.1 Header of the Firmware Secured Module
In Table 6-10, fields colored in cyan are protected by the authentication signature.
Table 6-10. Header and Body of the Firmware Secured Module
Number of
Words Field or Segment Name Description and Comments
128 RSA Public Key Refer to Section 3.3.10. This field is skipped for the sake of
SHA256 Hash computing.
2RSA Exponent Refer to Section 3.3.10. This field is skipped for the sake of
SHA256 Hash computing.
128 Encrypted SHA256 Hash Refer to Section 3.3.10. This field is skipped for the sake of
SHA256 Hash computing.
1I210 Blank Flash Device ID A unique Intel-provided device ID that identifies the I210
among other Intel GbE controllers. It must be set to 0x1531 in
the I210, which is the blank Flash Device ID used by the tools.
2Max Module Area It is the maximum Flash area expressed in words that can be
used by the module. It is set to 122 KWords or 224 KWords (i.e.
244 KB or 448 KB).
2Current Module Area It is the Flash area expressed in words that is currently used by
the module. Since a trailer has been added to the module, this
field contains always the same value than the max module area.
Ethernet Controller I210 —Flash Map
242
1
Module Format Version + CRC8
Bit 15 = CRC8 field is used. Set to 1b if a CRC8 is computed
over the module, set to 0b otherwise.
Bits 14:8 = Module format version. Set to 0x02 is this currently
defined format is used.
Bits 7:0 = CRC8 value computed over the parent module only.
CRC8 field is itself zeroed for the sake of CRC8 computing or
when no CRC8 is computed (when bit 15 is set to 0b).
1Firmware Code Revision Bits 15:8 = Major revision number.
Bits 7:0 = Minor revision number.
1 Reserved Spare Word Must be zeroed.
2
Parent Module Length
Length of the parent module contents expressed in words,
module header and Parent Module Length field excluded. It
excludes all the descendant modules. It must be set to N.
Modules read by firmware are NOT size limited to 128 KB.
It excludes the last two 4 KB sectors of the firmware secured
module which are reserved for the Flash devices table and the
RO Updates sections.
N parent word 1
Format of the contents of firmware modules is specific to each
module.
parent word 2
...
parent word N
Remaining
words, up to
225 K - N - 332
- 4 K
Padding words Filled with all 1s, which corresponds to the Flash sector contents
left unwritten after a sector erase operation.
Table 6-10. Header and Body of the Firmware Secured Module (Continued)
Number of
Words Field or Segment Name Description and Comments
Flash Map—Ethernet Controller I210
243
6.9.2 Trailer of the Firmware Secured Module
In Table 6-11, fields colored in cyan are protected by the authentication signature.
The last two 4 KB sectors of the firmware secured module have the following format:
Table 6-11. Trailer Format
Number of
Words Field or Segment Name Description and Comments
1Flash Devices Table Version Default is 0xFFFF, which means the sector is empty and the
remaining words are discarded and filled with all 1s.
1I210 Blank Flash Device ID A unique Intel-provided device ID that identifies the I210
among other Intel GbE controllers. It must be set to 0x1531 in
the I210, which is the blank Flash Device ID used by the Tools.
1
Minimum FW Code Revision
Minimum FW Code Revision number required for being able to
parse the RO Updates section.
It must be lower or equal to the Firmware Code Revision
number read from the module Header listed in Table 6-10.
1Number of Flash Devices Number of Flash Devices (P) described by repeating the 8 words
Flash device description item, starting from next word.
8 Flash Device Item 1 word 1
Format of the Flash Device Item words is described in
Section 6.9.2.1.
Flash Device Item 1 word 2
Flash Device Item 1 word 3
Flash Device Item 1 word 4
Flash Device Item 1 word 5
Flash Device Item 1 word 6
Flash Device Item 1 word 7
Flash Device Item 1 word 8
...
8 Flash Device Item P word 1
Format of the Flash Device Item words is described in
Section 6.9.2.1.
Flash Device Item P word 2
Flash Device Item P word 3
Flash Device Item P word 4
Flash Device Item P word 5
Flash Device Item P word 6
Flash Device Item P word 7
Flash Device Item P word 8
2 K - 8 x P - 4 Padding words Filled with all 1s, which corresponds to the Flash sector contents
left unwritten after a sector erase operation.
1
RO Updates Version
Default is 0xFFFF, which means the sector is empty and the
remaining words are discarded and filled with all 1s.
A null field here indicates that the next words up to the 4 KB
sector's end contain the new Shadow RAM contents, starting
from word 0x000 up to word 0x7F78 included.
1
Device ID
A unique Intel-provided device ID that identifies the I210
among other Intel GbE controllers.
It must be set to 0x1531 in the I210.
Ethernet Controller I210 —Flash Map
244
6.9.2.1 Format of the Flash Device Items
The last entry with JEDEC_ID = 0xFFFFFF is used to define the default setting in case the JEDEC_ID is
not found in the list (or when the JEDEC_ID of the flash part is longer than 24-bits).
Note: Default settings can alternatively be taken by Flash word 0x11, if bit 8 is set to 1b.
1
Minimum FW Code Revision
Minimum firmware code revision number required for being able
to parse the RO updates section.
It must be lower or equal to the Firmware Code Revision
number read from the module Header listed in Table 6-10.
1
RO Updates Length
Number of RO updates words (M), starting from next word.
A null field here indicates that the next words up to the 4 KB
sector's end contain the new shadow RAM contents, starting
from word 0x000 up to word 0x7F78 included.
Shadow RAM words 0x7F7 to 0x7FF are not replaced (they must
be left unused, all 1s).
M RO Updates word 1
Format of the RO updates is described in Section 6.9.2.2.
In case RO Updates Version and Length fields have a null
contents, all the remaining words contains the new contents for
up to the first 2040 words of the Shadow RAM. In this case M =
2040.
RO Updates word 2
...
RO Updates word M
2 K - M - 8 Padding words Filled with all 1s, which corresponds to the Flash sector contents
left unwritten after a sector erase operation.
Flash Device Item Description Default Settings
Word 1 JEDEC_ID[15:0] 0xFFFF
Word 2 0x00, JEDEC_ID[23:16] 0x00, 0xFF
Word 3 FLASHMODE[15:0]
0x0013:
FAST_READ_MODE = 1
NUM_OF_DUMMY = 1
FLASH_SPEED = 62.5 MHz
SUSPEND_SUPPORT = 0
SST_MODE = 0
Word 4 Bit 16: Unprotected flash after reset,
FLASHMODE[30:16]
0x8000:
Unprotected flash = 1
Word 5 FLASHOP[15:0]
0x75C7:
FLASHERASEOP = 0xC7
SUSPENDOP = 0x75
Word 6 FLASHOP[31:16]
0x0B7A:
RESUMEOP = 0x7A
FASTREADOP = 0x0B
Word 7 FLASHTIME[15:0] 0x0008:
CSDESELECT = 56ns
Word 8 FLASHTIME[31:16] 0x00FF:
HOLDTIME = 4us
Table 6-11. Trailer Format (Continued)
Number of
Words Field or Segment Name Description and Comments
Flash Map—Ethernet Controller I210
245
6.9.2.2 Format of the RO Updates
The RO Updates words can contains the following 3 structures:
1. Shadow RAM Word Write Command (2 words)
2. CSR Write Command (4 words)
3. Shadow RAM contents, from word 0x0 to 0x7F8 included
The first two structures start with a Type field. Table 6-12 lists the supported values for the Type field.
Table 6-12. Supported Type Fields
Figure 6-1. Shadow RAM Word Write Command
Figure 6-1 CSR Write Command
Type Description
001b Word autoload.
010b CSR autoload.
Other Invalid type, parsing is stopped here.
Type
3b=3'b001
Word Address[12:0]
13b
Word Data[15:0]
16b
Ethernet Controller I210 —Flash Map
246
NOTE: This page intentionally left blank.
Inline Functions—Ethernet Controller I210
247
7.0 Inline Functions
7.1 Receive Functionality
Typically, packet reception consists of recognizing the presence of a packet on the wire, performing
address filtering, storing the packet in the receive data FIFO, transferring the data to one of the 4
receive queues in host memory, and updating the state of a receive descriptor.
A received packet goes through two stages of filtering.
The first step in queue assignment is to verify that the packet is destined to the port. This is done by a
set of L2 filters as described in Section 7.1.3.
In the second stage, a received packet that successfully passed the Rx filters is associated with one or
more receive descriptor queues as described in Section 7.1.1.
7.1.1 L2 Packet Filtering
The receive packet filtering role is to determine which of the incoming packets are allowed to pass to
the local system and which of the incoming packets should be dropped since they are not targeted to
the local system. Received packets can be destined to the host, to a Manageability Controller (MC), or
to both. This section describes how host filtering is done, and the interaction with management
filtering.
As shown in Figure 7-1, host filtering has three stages:
1. Packets are filtered by L2 filters (MAC address, unicast/multicast/broadcast). See Section 7.1.1.1
for details.
2. Packets are then filtered by VLAN if a VLAN tag is present. See Section 7.1.1.2 for details.
3. Packets are filtered by the manageability filters (IP, flex, other). See Section 10.3.3 for details.
A packet is not forwarded to the host if any of the following takes place:
1. The packet does not pass MAC address filters as described later in this section.
2. The packet does not pass VLAN filtering as described later in this section.
3. The packet passes manageability filtering and then the manageability filters determine that the
packet should be sent only to the MC (see Section 10.3 and the MNGONLY register).
A packet that passes receive filtering as previously described might still be dropped due to other
reasons. Normally, only good packets are received. These are defined as those packets with no Under
Size Error, Over Size Error (see Section 7.1.1.4), Packet Error, Length Error and CRC Error are
detected. However, if the store-bad-packet bit is set (RCTL.SBP), then bad packets that pass the filter
function are stored in host memory. Packet errors are indicated by error bits in the receive descriptor
(RDESC.ERRORS). It is possible to receive all packets, regardless of whether they are bad, by setting
the promiscuous enabled (Unicast and Multicast) and the store-bad-packet bits in the RCTL register.
Ethernet Controller I210 —Inline Functions
248
If there is insufficient space in the receive FIFO, hardware drops the packet and indicates the missed
packet in the appropriate statistics registers.
When the packet is routed to a queue with the SRRCTL.Drop_En bit set to 1b, receive packets are
dropped when insufficient receive descriptors exist to write the packet into system memory.
Note: CRC errors before the SFD are ignored. Any packet must have a valid SFD in order to be
recognized by the I210 (even bad packets).
Figure 7-1. I210 Receive Filtering Flow Chart
Discard
packet
Host VLAN
Filter
MNG
Filter
PASS
Packet Arrived
Host
MAC
Address
Filter
To MNGTo Host
Pass
FAIL
FAIL
MNG
only?
No
Inline Functions—Ethernet Controller I210
249
7.1.1.1 MAC Address Filtering
Figure 7-2 shows the MAC address filtering. A packet passes successfully through the MAC address
filtering if any of the following conditions are met:
1. It is a unicast packet and promiscuous unicast filtering is enabled.
2. It is a multicast packet and promiscuous multicast filtering is enabled.
3. It is a unicast packet and it matches one of the unicast MAC filters.
4. It is a multicast packet and it matches one of the multicast filters.
5. It is a broadcast packet and Broadcast Accept Mode (RCTL.BAM) is enabled.
Figure 7-2. Host MAC Address Receive Filtering Flow Chart
Unicast Packet
type
Start
Promiscuous
Unicast enable
Unicast pass
No
Yes
Yes
No
Broadcast
accept mode
Yes
Promiscuous multicast
enable
Broad cast
Multicast
Yes
VLAN filtering Multicast pass
no
yes
no
Discard packet
No
Ethernet Controller I210 —Inline Functions
250
7.1.1.1.1 Unicast Filter
The entire MAC address is checked against the 16 host unicast addresses. The 16 host unicast
addresses are controlled by the host interface (the MC must not change them). The other 4 addresses
are dedicated to management functions and are only accessed by the MC. The destination address of
an incoming packet must exactly match one of the pre-configured host address filters. These addresses
can be unicast or multicast. Those filters are configured through RAL, and RAH registers.
Promiscuous Unicast Receive all unicasts. Promiscuous unicast mode in the RCTL register can be set/
cleared only through the host interface (not by the MC). This mode is usually used when the I210 is
used as a sniffer.
7.1.1.1.2 Multicast Filter (Inexact)
A 12-bit portion of incoming packet multicast address must exactly match Multicast Filter Address
(MFA) in order to pass multicast filtering. This means that 12 bits out of 48 bits of the destination
address are used and can be selected by the MO field of RCTL (Section 8.10.1). The 12 bits extracted
from the Multicast Destination address are used as an address for a bit in the Multicast Table Array
(MTA). If the value of the bit selected in the MTA table is 1b, the packet is sent to the host (See
Section 8.10.15). These entries can be configured only by the host interface and cannot be controlled
by the MC. Packets received according to this mode have the PIF bit in the descriptor set to indicate
imperfect filtering that should be validated by the software device driver.
Promiscuous Multicast Receive all multicast. Promiscuous multicast mode can be set/cleared in the
RCTL register only through the host interface (not by the MC) and it is usually used when the I210 is
used as a sniffer.
Note: When the promiscuous bit is set and a multicast packet is received, the PIF bit of the packet
status is not set.
7.1.1.2 VLAN Filtering
A receive packet that successfully passed MAC address filtering is then subjected to VLAN header
filtering.
1. If the packet does not have a VLAN header, it passes to the next filtering stage.
Note: If external VLAN is enabled (CTRL_EXT.EXT_VLAN is set), it is assumed that the first VLAN
tag is an external VLAN and it is skipped. All next stages refer to the second VLAN.
2. If VLAN filtering is disabled (RCTL.VFE bit is cleared), the packet is forwarded to the next filtering
stage.
3. If the packet has a VLAN header, and it matches an enabled host VLAN filter (relevant bit in VFTA
table is set), the packet is forwarded to the next filtering stage.
4. Otherwise, the packet is dropped.
Figure 7-3 shows the VLAN filtering flow.
Inline Functions—Ethernet Controller I210
251
7.1.1.3 Manageability Filtering
Manageability filtering is described in Section 10.3.
Figure 7-4 shows the manageability portion of the packet filtering and it is brought here to make the
receive packet filtering functionality description complete.
Note: The manageability engine might decide to block part of the received packets from also being
sent to the host, according to the external MC instructions and the Flash settings.
Figure 7-3. I210 VLAN Filtering
PASS L2
Packet has
VLAN Header
Host VLAN
Filters enable
host VLAN
Filters pass
MNG Only
Check
Yes
Yes
Yes
No
No
MAC address
filtering
Discard
packet
No
Ethernet Controller I210 —Inline Functions
252
7.1.1.4 Size Filtering
A packet is defined as undersize if it is smaller than 64 bytes.
A packet is defined as oversize in the following conditions:
The RCTL.LPE bit cleared and one of the following conditions is met:
The packet is bigger than 1518 bytes and there are no VLAN tags in the packet.
The packet is bigger than 1522 bytes and there is one VLAN tag in the packet.
The packet is bigger than 1526 bytes and there are two VLAN tags in the packet.
Figure 7-4. Manageability Filtering
No
Yes
Yes
No
Yes
No
Yes
Yes
RCV EN
Pass
decision
filters
RCV All
Fixed Net
type
XSUM error
Match Ne t
type
EN XSUM
MNGONLY Send packet to
MNG
Block packet
from Host
Packet
received from
LAN
Yes
No
No
No
Yes
Not considered
For MNG
Yes
No
Inline Functions—Ethernet Controller I210
253
The RCTL.LPE bit is set to 1b and the packet is bigger than RLPML.RLPML bytes.
Note: Even when the RCTL.LPE bit is set, the maximum supported received-packet size is 9.5 KB
(9728 bytes).
7.1.2 Receive Queues Assignment
The following filter mechanisms determines the destination of a receive packet. These are described
briefly in this section and in full details in separate sections:
RSS Receive Side Scaling distributes packet processing between several processor cores by
assigning packets into different descriptor queues. RSS assigns to each received packet an RSS
index. Packets are routed to a queue out of a set of Rx queues based on their RSS index and other
considerations. See Section 7.1.2.7 for details on RSS.
L2 Ether-type filters These filters identify packets by their L2 Ether-type and assign them to
receive queues. Examples of possible uses are LLDP packets and 802.1X packets. See
Section 7.1.2.3 for mode details. The I210 incorporates 4 Ether-type filters.
2-tuple filters These filters identify packets with specific TCP/UDP destination port and/or L4
protocol. Each filter consists of a 2-tuple (protocol and destination TCP/UDP port) and routes
packets into one of the Rx queues. The I210 has 8 such filters. See Section 7.1.2.4 for details.
TCP SYN filters The I210 might route TCP packets with their SYN flag set into a separate queue.
SYN packets are often used in SYN attacks to load the system with numerous requests for new
connections. By filtering such packets to a separate queue, security software can monitor and act
on SYN attacks. The I210 has one such filter. See Section 7.1.2.6 for more details.
Flex Filters - These filters can be either used as WoL filters when the I210 is in D3 state or for
queueing in normal operating mode (D0 state). Filters enable queueing according to a match of any
128 Byte sequence at the beginning of a packet. Each one of the 128 bytes can be either compared
or masked using a dedicated mask field. The I210 has 8 such filters. See Section 7.1.2.5 for details.
VLAN priority filters These filters identify packets by their L2 VLAN priority and assign them to
receive queues. See Section 7.1.2.7 for mode details. The I210 incorporates 8 VLAN priority filters.
MAC address filters These filters identify packets by their L2 MAC address and assign them to
receive queues. See Section 7.1.2.8 for mode details. The I210 incorporates 16 MAC address
filters.
A received packet is allocated to a queue as described in the following sections.
7.1.2.1 Queuing Method
When the MRQC.Multiple Receive Queues Enable field equals 010b (multiple receive queues as defined
by filters and RSS for 4 queues) or 000b (multiple receive queues as defined by filters (2-tuple filters,
L2 Ether-type filters, SYN filter and Flex Filters), the received packet is assigned to a queue in the
following manner (Each filter identifies one of 4 receive queues):
1. Queue by MAC address filters (if a match)
2. Queue by L2 Ether-type filters (if a match)
3. If RFCTL.SYNQFP is 0b (2-tuple filter and Flex filter have priority), then:
a. Queue by Flex filter (if a match)
b. Queue by 2-tuple filter
c. Queue by SYN filter (if a match)
4. If RFCTL.SYNQFP is 1b (SYN filter has priority), then:
a. Queue by SYN filter (if a match)
Ethernet Controller I210 —Inline Functions
254
b. Queue by Flex filter (if a match)
c. Queue by 2-tuple filter (if a match)
5. Queue by VLAN Priority (if a match)
6. Queue by RSS (if RSS enabled) - Identifies one of 1 x 4 queues through the RSS index. The
following modes are supported:
No RSS The default queue as defined in MRQC.DEF_Q is used for packets that do not meet
any of the previous conditions.
RSS only A set of 4 queues is allocated for RSS. The queue is identified through the RSS
index. Note that it is possible to use a subset of the 4 queues.
Note: No RSS here mean either that RSS is disabled (MRQC.Multiple Receive Queues Enable field
equals 000b) or that the packet did not match any of the RSS filters.
Figure 7-7 shows the receive queue assignment flow.
Inline Functions—Ethernet Controller I210
255
Figure 7-5. Receive Queuing Flow
Packet matches
L2 EtherType
Filter?
Packet matches
SYN
Filter?
Packet matches
flex filter?
Use MRQC.Def_Q[2:0]
as Queue number.
Use RSS index
(3 bits)
as Queue number.
END
The L2 EtherType filter
defines the Rx Queue
The SYN filter defines the
Rx Queue
The flex filters define the
Rx Queue
The 2-Tuple filters define
the Rx Queue
Packet matches
2-Tuple
Filter?
RSS enabled
and RSS match
found?
RFCTL.SYNQFP
Yes
Yes
Yes
1b
No
No
Packet matches
flex filter?
The flex filters define the
Rx Queue
The 2-Tuple filters define
the Rx Queue
Packet matches
2-Tuple
Filter?
Yes
Yes
No
No
Packet matches
SYN
Filter?
The SYN filter defines the
Rx Queue Yes
Yes
No
0b
Yes
No
Start
Packet matches
MAC Address
Filter?
No
The MAC Address filter
defines the Rx Queue
Yes
VLAN Priority
enabled and match
found?
No
The VLAN Priority define
the Rx Queue
Yes
Ethernet Controller I210 —Inline Functions
256
7.1.2.2 Queue Configuration Registers
Configuration registers (CSRs) that control queue operation are replicated per queue (total of 4 copies
of each register). Each of the replicated registers correspond to a queue such that the queue index
equals the serial number of the register (such as register 0 corresponds to queue 0, etc.). Registers
included in this category are:
RDBAL and RDBAH Rx Descriptor Base
RDLEN RX Descriptor Length
RDH RX Descriptor Head
RDT RX Descriptor Tail
RXDCTL Receive Descriptor Control
RXCTL Rx DCA Control
SRRCTL Split and Replication Receive Control
PSRTYPE Packet Split Receive Type
7.1.2.3 L2 Ether-type Filters
These filters identify packets by L2 Ether-type and assign them to a receive queue. The following
usages have been identified:
IEEE 802.1X packets Extensible Authentication Protocol over LAN (EAPOL).
Time sync packets (such as IEEE 1588) Identifies Sync or Delay_Req packets
IEEE802.1AB LLDP (Link Layer Discovery Protocol) packets.
IEEE1722 (Layer 2 Transport Protocol for Time Sensitive Applications) packets
IEEE1722 Layer 2 transport protocol for timed sensitive applications.
The I210 incorporates 4 Ether-type filters.
The Packet Type field in the Rx descriptor captures the filter number that matched the L2 Ether-type.
See Section 7.1.4.2 for decoding of the Packet Type field.
The Ether-type filters are configured via the ETQF register as follows:
The EType field contains the 16-bit Ether-type compared against all L2 type fields in the Rx packet.
The Filter Enable bit enables identification of Rx packets by Ether-type according to this filter. If this
bit is cleared, the filter is ignored for all purposes.
The Etype Length and Etype Length Enable are used to enable parsing beyond the Ethertype
defined by the ETQF entry, the Etype Length points to the following Ethertype in the packet to
support extended Rx parsing.
The Rx Queue field contains the absolute destination queue for the packet.
The 1588 Time Stamp field indicates that the packet should be time stamped according to the IEEE
1588 specification.
The Queue Enable field enables forwarding Rx packets based on the Ether-type defined in this
register. Refer to Section 7.1.2.1 on the impact and order of ETQF on the I210 queue selection
algorithm.
The Ethertype length field contains the size of the Ethertype in bytes.
The Ethertype length Enable field enables the parsing of the Rx packets based on the Ethertype
defined in this register.
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Note: Software should not assign the same Ether-type value to different ETQF filters with different
Rx Queue assignments.
Note: The Etype Length and Etype Length Enable should only be used when parsing beyond the
defined Ethertype is required to enable Rx offloading for non L2 only packets.
Note: Queuing and Immediate interrupt decisions for an incoming packet that matches more than a
single ETQF entry are done according to the setting of the last ETQF match.
7.1.2.4 2-Tuple Filters
These filters identify specific packets destined to a certain TCP/UDP port and implement a specific
protocol. Each filter consists of a 2-tuple (protocol and destination TCP/UDP port) and forwards packets
into one of the receive queues.
The I210 incorporates 8 such filters.
The 2-tuple filters are configured via the TTQF (See Section 8.11.3), IMIR (See Section 8.11.1) and
IMIR_EXT (See Section 8.11.2) registers as follows (per filter):
Protocol Identifies the IP protocol, part of the 2-tuple queue filters. Enabled by a bit in the
TTQF.Mask field.
Destination port Identifies the TCP/UDP destination port, part of the 2-tuple queue filters.
Enabled by the IMIR.PORT_BP bit.
Size threshold (IMIREXT.Size_Thresh) Identifies the length of the packet that should trigger the
filter. This is the length as received by the host, not including any part of the packet removed by
hardware. Enabled by the IMIREXT.Size_BP field.
Control Bits Identify TCP flags that might be part of the filtering process. Enabled by the
IMIREXT.CtrlBit_BP field.
Rx queue Determines the Rx queue for packets that match this filter:
The TTQF.Rx Queue field contains the queue serial number.
Queue enable Enables forwarding a packet that uses this filter to the queue defined in the
TTQF.Rx Queue field.
Mask A 1-bit field that masks the L4 protocol check. The filter is a logical AND of the non-masked
2-tuple fields. If all 2-tuple fields are masked, the filter is not used for queue forwarding.
Notes:
If more than one 2-tuple filter with the same priority is matched by the packet, the first
filter (lowest ordinal number) is used in order to define the queue destination of this
packet.
The immediate interrupt and 1588 actions are defined by the OR of all the matching
filters.
7.1.2.5 Flex Filters
The I210 supports a total of 8 flexible filters. Each filter can be configured to recognize any arbitrary
pattern within the first 128 bytes of the packet. To configure the flexible filters, software programs the
mask values (required values and the minimum packet length), into the Flexible Host Filter Table (FHFT
and FHFT_EXT, See Section 8.21.18 and Section 8.21.19). These 8 flexible filters can be used as for
wake-up or proxying when in D3 state or for queueing when in D0 state. Software must enable the
filters in the Wake Up Filter Control (WUFC See Section 8.21.2) register or Proxying Filter Control
(PROXYFC see Section 8.21.6) for operation in D3 low power mode or in the WUFC register in D0 mode.
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In D0 mode these filters enable forwarding of packets that match up to 128 Bytes defined in the filter to
one of the receive queues. In D3 mode these filters can be used for Wake-on-Lan as described in
Section 5.6.3.1.8 or proxying as described in Section 5.7.
Once enabled, the flexible filters scan incoming packets for a match. If the filter encounters any byte in
the packet where the mask bit is one and the byte doesn't match the value programmed in the Flexible
Host Filter Table (FHFT or FHFT_EXT), then the filter fails that packet. If the filter reaches the required
length without failing the packet, it forwards the packet to the appropriate receive queue. It ignores
any mask bits set to one beyond the required length (defined in the Length field in the FHFT or
FHFT_EXT registers).
Note: The flex filters are temporarily disabled when read from or written to by the host. Any packet
received during a read or write operation is dropped. Filter operation resumes once the read
or write access completes.
The flex filters are configured in D0 state via the WUFC, FHFT and FHFT_EXT registers as follows (per
filter):
Byte Sequence to be compared - Program 128 Byte sequence, mask bits and Length field in FHFT
and FHFT_EXT registers.
Filter Priority - Program filter priority in queueing field in FHFT and FHFT_EXT registers.
Receive queue - Program receive queue to forward packet in queueing field in FHFT and FHFT_EXT
registers.
Filter actions - Program immediate interrupt requirement in queueing field in FHFT and FHFT_EXT
registers.
Filter enable - Set WUFC.FLEX_HQ bit to 1 to enable flex filter operation in D0 state. Set
appropriate WUFC.FLX[n] bit to 1 to enable specific flex filter.
Before entering D3 state software device driver programs the FHFT and FHFT_EXT filters for
appropriate wake events and enables relevant filters by setting the WUFC.FLX[n] bit to 1 or the
PROXYFC.FLX[n] bit to 1b. Following move to D0 state the software device driver programs the FHFT
and FHFT_EXT filters for appropriate queueing decisions and enables the relevant filters by setting the
WUFC.FLX[n] bit to 1b and the WUFC.FLEX_HQ bit to 1b.
Notes: If more than one flex filter with the same priority is matched by the packet, the first filter
(lowest address) is used in order to define the queue destination of this packet.
The immediate interrupt action is defined by the OR of all the matching filters.
7.1.2.6 SYN Packet Filters
The I210 might forward TCP packets whose SYN flag is set into a separate queue. SYN packets are
often used in SYN attacks to load the system with numerous requests for new connections. By filtering
such packets to a separate queue, security software can monitor and act on SYN attacks.
SYN filters are configured via the SYNQF registers as follows:
Queue En Enables forwarding of SYN packets to a specific queue.
Rx Queue field Contains the destination queue for the packet.
7.1.2.7 VLAN Priority Filters
The I210 can forward packets according to their VLAN priority to separate queues. The I210 supports
the configuration of the destination queue per VLAN priority.
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VLAN priority filters are configured via the VLANPQF registers as follows:
Queue En Enables forwarding of packets for each VLAN priority to a specific queue.
Rx Queue field Contains the destination queue for each VLAN priority packet.
7.1.2.8 VLAN Tag Filters
The I210 can forward packets according to their VLAN tag to separate queues. The I210 supports the
configuration of the destination queue per VLAN tag.
VLAN tag filters are configured via the VLANTAGQF registers as follows:
VLAN tag value - The VLAN tag value to be filtered
Queue En Enables forwarding of packets for each filtered VLAN tag to a specific queue.
Rx Queue field Contains the destination queue for each filtered VLAN tag packet.
7.1.2.9 MAC Address Filters
The I210 can forward packets according to their MAC address to separate queues. The I210 supports
the configuration of the destination queue per MAC address.
MAC Address filters are configured via the RAL/H registers as follows:
MAC address value - The MAC address value to be filtered
Queue En Enables forwarding of packets for each filtered MAC address to a specific queue.
Rx Queue field Contains the destination queue for each filtered MAC address.
7.1.2.10 Receive-Side Scaling (RSS)
RSS is a mechanism to distribute received packets into several descriptor queues. Software then
assigns each queue to a different processor, sharing the load of packet processing among several
processors.
The I210 uses RSS as one ingredient in its packet assignment policy (the others are the various filters
for Qav). The RSS output is a RSS index. The I210’s global assignment uses these bits (or only some of
the LSB bits) as part of the queue number.
RSS is enabled by the MRQC register. The RSS hash is reported only on the advanced receive descriptor
and it multiplexed with UDP fragmentation parameters. Selection between these two status indications
is done by the RXCSUM.PCSD bit setting.
When RSS is enabled, the I210 provides software with the following information as required by
Microsoft* RSS specification or for device driver assistance:
A Dword result of the Microsoft* RSS hash function, to be used by the stack for flow classification,
is written into the receive packet descriptor (required by Microsoft* RSS).
A 4-bit RSS Type field conveys the hash function used for the specific packet (required by
Microsoft* RSS).
Figure 7-6 shows the process of computing an RSS output:
1. The receive packet is parsed into the header fields used by the hash operation (such as IP
addresses, TCP port, etc.).
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2. A hash calculation is performed. The I210 supports a single hash function, as defined by Microsoft*
RSS. The I210 does not indicate to the software device driver which hash function is used. The 32-
bit result is fed into the packet receive descriptor.
3. The seven LSB bits of the hash result are used as an index into a 128-entry indirection table. Each
entry provides a 3-bit RSS output index.
When RSS is disabled, packets are assigned an RSS output index = zero. System software might
enable or disable RSS at any time. While disabled, system software might update the contents of any of
the RSS-related registers.
When multiple requests queues are enabled in RSS mode, un-decodable packets are assigned an RSS
output index = zero. The 32-bit tag (normally a result of the hash function) equals zero.
Figure 7-6. RSS Block Diagram
RSS Hash
LS
Packet
Descriptor
Parsed
Receive
Packet
7
32
RSS Disable or (RSS
And Not Decodable)
3
0
3
RSS Output Index
Indirection Table
128 x 3
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7.1.2.10.1 RSS Hash Function
Section 7.1.2.10.1 provides a verification suite used to validate that the hash function is computed
according to Microsoft* nomenclature.
The I210 hash function follows Microsoft* definition. A single hash function is defined with several
variations for the following cases:
TcpIPv4 The I210 parses the packet to identify an IPv4 packet containing a TCP segment per the
criteria described later in this section. If the packet is not an IPv4 packet containing a TCP segment,
RSS is not done for the packet.
IPv4 The I210 parses the packet to identify an IPv4 packet. If the packet is not an IPv4 packet,
RSS is not done for the packet.
TcpIPv6 The I210 parses the packet to identify an IPv6 packet containing a TCP segment per the
criteria described later in this section. If the packet is not an IPv6 packet containing a TCP segment,
RSS is not done for the packet.
TcpIPv6Ex The I210 parses the packet to identify an IPv6 packet containing a TCP segment with
extensions per the criteria described later in this section. If the packet is not an IPv6 packet
containing a TCP segment, RSS is not done for the packet. Extension headers should be parsed for
a Home-Address-Option field (for source address) or the Routing-Header-Type-2 field (for
destination address).
IPv6Ex The I210 parses the packet to identify an IPv6 packet. Extension headers should be
parsed for a Home-Address-Option field (for source address) or the Routing-Header-Type-2 field
(for destination address). Note that the packet is not required to contain any of these extension
headers to be hashed by this function. In this case, the IPv6 hash is used. If the packet is not an
IPv6 packet, RSS is not done for the packet.
IPv6 The I210 parses the packet to identify an IPv6 packet. If the packet is not an IPv6 packet,
receive-side-scaling is not done for the packet.
The following additional cases are not part of the Microsoft* RSS specification:
UdpIPV4 The I210 parses the packet to identify a packet with UDP over IPv4.
UdpIPV6 The I210 parses the packet to identify a packet with UDP over IPv6.
UdpIPV6Ex The I210 parses the packet to identify a packet with UDP over IPv6 with extensions.
A packet is identified as containing a TCP segment if all of the following conditions are met:
The transport layer protocol is TCP (not UDP, ICMP, IGMP, etc.).
The TCP segment can be parsed (such as IP options can be parsed, packet not encrypted).
The packet is not fragmented (even if the fragment contains a complete TCP header).
Bits[31:16] of the Multiple Receive Queues Command (MRQC) register enable each of the above hash
function variations (several can be set at a given time). If several functions are enabled at the same
time, priority is defined as follows (skip functions that are not enabled):
IPv4 packet:
1. Try using the TcpIPv4 function.
2. Try using IPV4_UDP function.
3. Try using the IPv4 function.
IPv6 packet:
1. If TcpIPv6Ex is enabled, try using the TcpIPv6Ex function; else if TcpIPv6 is enabled try using the
TcpIPv6 function.
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2. If UdpIPv6Ex is enabled, try using UdpIPv6Ex function; else if UpdIPv6 is enabled try using UdpIPv6
function.
3. If IPv6Ex is enabled, try using the IPv6Ex function, else if IPv6 is enabled, try using the IPv6
function.
The following combinations are currently supported:
Any combination of IPv4, TcpIPv4, and UdpIPv4.
And/or.
Any combination of either IPv6, TcpIPv6, and UdpIPv6 or IPv6Ex, TcpIPv6Ex, and UdpIPv6Ex.
When a packet cannot be parsed by the previously mentioned rules, it is assigned an RSS output index
= zero. The 32-bit tag (normally a result of the hash function) equals zero.
The 32-bit result of the hash computation is written into the packet descriptor and also provides an
index into the indirection table.
The following notation is used to describe the hash functions:
Ordering is little endian in both bytes and bits. For example, the IP address 161.142.100.80
translates into 0xa18e6450 in the signature.
A “^ “denotes bit-wise XOR operation of same-width vectors.
@x-y denotes bytes x through y (including both of them) of the incoming packet, where byte 0 is
the first byte of the IP header. In other words, it is considered that all byte-offsets as offsets into a
packet where the framing layer header has been stripped out. Therefore, the source IPv4 address is
referred to as @12-15, while the destination v4 address is referred to as @16-19.
@x-y, @v-w denotes concatenation of bytes x-y, followed by bytes v-w, preserving the order in
which they occurred in the packet.
All hash function variations (IPv4 and IPv6) follow the same general structure. Specific details for each
variation are described in the following section. The hash uses a random secret key length of 320 bits
(40 bytes); the key is typically supplied through the RSS Random Key Register (RSSRK).
The algorithm works by examining each bit of the hash input from left to right. Intel’s nomenclature
defines left and right for a byte-array as follows: Given an array K with k bytes, Intel’s nomenclature
assumes that the array is laid out as shown:
K[0] K[1] K[2] … K[k-1]
K[0] is the left-most byte, and the MSB of K[0] is the left-most bit. K[k-1] is the right-most byte, and
the LSB of K[k-1] is the right-most bit.
ComputeHash(input[], N)
For hash-input input[] of length N bytes (8N bits) and a random secret key K of 320 bits
Result = 0;
For each bit b in input[] {
if (b == 1) then Result ^= (left-most 32 bits of K);
shift K left 1 bit position;
}
return Result;
The following four pseudo-code examples are intended to help clarify exactly how the hash is to be
performed in four cases, IPv4 with and without ability to parse the TCP header and IPv6 with an without
a TCP header.
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7.1.2.10.1.1 Hash for IPv4 with TCP
Concatenate SourceAddress, DestinationAddress, SourcePort, DestinationPort into one single byte-
array, preserving the order in which they occurred in the packet:
Input[12] = @12-15, @16-19, @20-21, @22-23.
Result = ComputeHash(Input, 12);
7.1.2.10.1.2 Hash for IPv4 with UDP
Concatenate SourceAddress, DestinationAddress, SourcePort, DestinationPort into one single byte-
array, preserving the order in which they occurred in the packet:
Input[12] = @12-15, @16-19, @20-21, @22-23.
Result = ComputeHash(Input, 12);
7.1.2.10.1.3 Hash for IPv4 without TCP
Concatenate SourceAddress and DestinationAddress into one single byte-array
Input[8] = @12-15, @16-19
Result = ComputeHash(Input, 8)
7.1.2.10.1.4 Hash for IPv6 with TCP
Similar to above:
Input[36] = @8-23, @24-39, @40-41, @42-43
Result = ComputeHash(Input, 36)
7.1.2.10.1.5 Hash for IPv6 with UDP
Similar to above:
Input[36] = @8-23, @24-39, @40-41, @42-43
Result = ComputeHash(Input, 36)
7.1.2.10.1.6 Hash for IPv6 without TCP
Input[32] = @8-23, @24-39
Result = ComputeHash(Input, 32)
7.1.2.10.2 Indirection Table
The RETA indirection table is a 128-entry structure, indexed by the seven LSB bits of the hash function
output. Each entry of the table contains the following:
Bits [2:0] - RSS index
Note: In RSS only mode, all 3 bits are used. In VMDq mode RSS is not supported.
System software might update the indirection table during run time. Such updates of the table are not
synchronized with the arrival time of received packets. Therefore, it is not guaranteed that a table
update takes effect on a specific packet boundary.
7.1.2.10.3 RSS Verification Suite
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Assume that the random key byte-stream is:
0x6d, 0x5a, 0x56, 0xda, 0x25, 0x5b, 0x0e, 0xc2,
0x41, 0x67, 0x25, 0x3d, 0x43, 0xa3, 0x8f, 0xb0,
0xd0, 0xca, 0x2b, 0xcb, 0xae, 0x7b, 0x30, 0xb4,
0x77, 0xcb, 0x2d, 0xa3, 0x80, 0x30, 0xf2, 0x0c,
0x6a, 0x42, 0xb7, 0x3b, 0xbe, 0xac, 0x01, 0xfa
7.1.2.10.3.1 IPv4
7.1.2.10.3.2 IPv6
The IPv6 address tuples are only for verification purposes and might not make sense as a tuple.
7.1.2.10.4 Association Through MAC Address
Each of the 16 MAC address filters can be associated with a VM. The POOLSEL field in the Receive
Address High (RAH) register determines the target VM. Packets that do not match any of the MAC filters
(such as promiscuous) are assigned with the default VM as defined in the VT_CTL.DEF_PL field.
Software can program different values to the MAC filters (any bits in RAH or RAL) at any time. The I210
would respond to the change on a packet boundary but does not guarantee the change to take place at
some precise time.
7.1.3 Receive Data Storage
7.1.3.1 Host Buffers
Each descriptor points to a one or more memory buffers that are designated by the software device
driver to store packet data.
The size of the buffer can be set using either the generic RCTL.BSIZE field, or the per queue
SRRCTL[n].BSIZEPACKET field.
Table 7-1. IPv4
Destination Address/Port Source Address/Port IPv4 Only IPv4 With TCP
161.142.100.80:1766 66.9.149.187:2794 0x323e8fc2 0x51ccc178
65.69.140.83:4739 199.92.111.2:14230 0xd718262a 0xc626b0ea
12.22.207.184:38024 24.19.198.95:12898 0xd2d0a5de 0x5c2b394a
209.142.163.6:2217 38.27.205.30:48228 0x82989176 0xafc7327f
202.188.127.2:1303 153.39.163.191:44251 0x5d1809c5 0x10e828a2
Table 7-2. IPv6
Destination Address/Port Source Address/Port IPv6 Only IPv6 With TCP
3ffe:2501:200:3::1 (1766) 3ffe:2501:200:1fff::7 (2794) 0x2cc18cd5 0x40207d3d
ff02::1 (4739) 3ffe:501:8::260:97ff:fe40:efab (14230) 0x0f0c461c 0xdde51bbf
fe80::200:f8ff:fe21:67cf (38024) 3ffe:1900:4545:3:200:f8ff:fe21:67cf
(44251) 0x4b61e985 0x02d1feef
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If SRRCTL[n].BSIZEPACKET is set to zero for any queue, the buffer size defined by RCTL.BSIZE is used.
Otherwise, the buffer size defined by SRRCTL[n].BSIZEPACKET is used.
If the receive buffer size is selected by bit settings in the Receive Control (RCTL.BSIZE) buffer sizes of
256, 512, 1024, and 2048 bytes are supported.
If the receive buffer size is selected by SRRCTL[n].BSIZEPACKET, buffer sizes of 1KB to 127 KB are
supported with a resolution of 1 KB.
In addition, for advanced descriptor usage the SRRCTL.BSIZEHEADER field is used to define the size of
the buffers allocated to headers. Header Buffer sizes of 64 bytes to2048 bytes with a resolution of 64
bytes are supported.
The I210 places no alignment restrictions on receive memory buffer addresses. This is desirable in
situations where the receive buffer was allocated by higher layers in the networking software stack, as
these higher layers might have no knowledge of a specific device's buffer alignment requirements.
Note: When the No-Snoop Enable bit is used in advanced descriptors, the buffer address is 16-bit
(2-byte) aligned.
7.1.3.2 On-Chip Receive Buffer
The I210 allocates by default a 36 KB on-chip packet buffer. The buffer is used to store packets until
they are forwarded to the host. Actual on-chip receive buffer allocated can be controlled the RXPBSIZE
register.
7.1.3.3 On-chip Descriptor Buffers
The I210 contains a 16 descriptor cache for each receive queue used to reduce the latency of packet
processing and to optimize the usage of PCIe bandwidth by fetching and writing back descriptors in
bursts. The fetch and write-back algorithm are described in Section 7.1.4.3 and Section 7.1.4.4.
7.1.4 Receive Descriptors
7.1.4.1 Legacy Receive Descriptor Format
A receive descriptor is a data structure that contains the receive data buffer address and fields for
hardware to store packet information. If SRRCTL[n].DESCTYPE = 000b, the I210 uses the legacy
Receive descriptor listed in Table 7-3. The shaded areas indicate fields that are modified by hardware
upon packet reception (so-called descriptor write-back).
After receiving a packet for the I210, hardware stores the packet data into the indicated buffer and
writes the length, packet checksum, status, errors, and status fields.
Packet Buffer Address (64) - Physical address of the packet buffer.
Table 7-3. Legacy Receive Descriptor (RDESC) Layout
63 48 47 40 39 32 31 16 15 0
0 Buffer Address [63:0]
8VLAN Tag Errors Status Fragment Checksum Length
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Length Field (16)
Length covers the data written to a receive buffer including CRC bytes (if any). Software must read
multiple descriptors to determine the complete length for a packet that spans multiple receive buffers.
Fragment Checksum (16)
This field is used to provide the fragment checksum value. This field equals to the unadjusted 16-bit
ones complement of the packet. Checksum calculation starts at the L4 layer (after the IP header) until
the end of the packet excluding the CRC bytes. In order to use the fragment checksum assist to offload
L4 checksum verification, software might need to back out some of the bytes in the packet. For more
details see Section 7.1.7.2
Status Field (8)
Status information indicates whether the descriptor has been used and whether the referenced buffer is
the last one for the packet. See Table 7-4 for the layout of the Status field. Error status information is
shown in Figure 7-8.
PIF (bit 7) - Passed imperfect filter only
IPCS (bit 6) - IPv4 checksum calculated on packet
L4CS (bit 5) - L4 (UDP or TCP) checksum calculated on packet
UDPCS (bit 4) - UDP checksum or IP payload checksum calculated on packet.
VP (bit 3) - Packet is 802.1Q (matched VET); indicates strip VLAN in 802.1Q packet
RSV (bit 2) - Reserved
EOP (bit 1) - End of packet
DD (bit 0) - Descriptor done
EOP and DD
Table 7-5 lists the meaning of these bits:
Table 7-4. Receive Status (RDESC.STATUS) Layout
7 6 5 4 3 2 1 0
PIF IPCS L4CS UDPCS VP Rsv EOP DD
Table 7-5. Receive Status Bits
DD EOP Description
0b 0b Software setting of the descriptor when it hands it off to the hardware.
0b 1b Reserved (invalid option).
1b 0b A completion status indication for a non-last descriptor of a packet that spans across multiple descriptors. In
a single packet case, DD indicates that the hardware is done with the descriptor and its buffers. Only the
Length fields are valid on this descriptor.
1b 1b A completion status indication of the entire packet. Note that software Might take ownership of its
descriptors. All fields in the descriptor are valid (reported by the hardware).
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VP Field
The VP field indicates whether the incoming packet's type matches the VLAN Ethernet Type
programmed in the VET Register. For example, if the packet is a VLAN (802.1Q) type, it is set if the
packet type matches VET and CTRL.VME is set (VLAN mode enabled). It also indicates that VLAN has
been stripped from the 802.1Q packet. For more details, see Section 7.4.
IPCS (IPv4 Checksum), L4CS (L4 Checksum), and UDPCS (UDP Checksum)
The meaning of these bits is listed in Table 7-6:
Refer to Table 7-18 for a description of supported packet types for receive checksum offloading.
Unsupported packet types do not have the IPCS or L4CS bits set. IPv6 packets do not have the IPCS bit
set, but might have the L4CS bit set if the I210 recognized the TCP or UDP packet.
PIF
Hardware supplies the PIF field to expedite software processing of packets. Software must examine any
packet with PIF bit set to determine whether to accept the packet. If the PIF bit is clear, then the packet
is known to be destined to this station, so software does not need to look at the packet contents.
Multicast packets passing only the Multicast Vector (MTA) set the PIF bit. In addition, the following
condition causes PIF to be cleared:
The DA of the packet is a multicast address and promiscuous multicast is set (RCTL.MPE = 1b).
The DA of the packet is a broadcast address and accept broadcast mode is set (RCTL.BAM = 1b)
A MAC control frame forwarded to the host (RCTL.PMCF = 0b) that does not match any of the exact
filters, has the PIF bit set.
Error Field (8)
Most error information appears only when the store-bad-packet bit (RCTL.SBP) is set and a bad packet
is received. See Table 7-7 for a definition of the possible errors and their bit positions.
RXE (bit 7) - RX Data Error
IPE (bit 6) - IPv4 Checksum Error
L4E (bit 5) - TCP/UDP Checksum Error
Reserved (bit 4:0)
Table 7-6. IPCS, L4CS, and UDPCS
L4CS UDPCS IPCS Functionality
0b 0b 0b Hardware does not provide checksum offload. Special case: Hardware does not provide UDP
checksum offload for IPV4 packet with UDP checksum = 0b
1b 0b 1b / 0b Hardware provides IPv4 checksum offload if IPCS is active and TCP checksum is offload. A
pass/fail indication is provided in the Error field – IPE and L4E.
0b 1b 1b / 0b Hardware provides IPv4 checksum offload if IPCS is active and UDP checksum is offload. A
pass/fail indication is provided in the Error field – IPE and L4E.
Table 7-7. RXE, IPE and L4E
7 6 5 4 3 2 1 0
RXE IPE L4E Reserved
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IPE/L4E
The IP and TCP/UDP checksum error bits from Table 7-7 are valid only when the IPv4 or TCP/UDP
checksum(s) is performed on the received packet as indicated via IPCS and L4CS. These, along with the
other error bits, are valid only when the EOP and DD bits are set in the descriptor.
Note: Receive checksum errors have no effect on packet filtering.
If receive checksum offloading is disabled (RXCSUM.IPOFLD and RXCSUM.TUOFLD), the IPE and L4E
bits are 0b.
RXE
The RXE error bit is asserted in the following case:
1. CRC error is detected. CRC can be a result of reception of /V/ symbol on the TBI interface (see
section 3.7.3.3.2) or assertion of RxERR on the MII/GMII interface or bad EOP or lose of sync
during packet reception. Packets with a CRC error are posted to host memory only when store-bad-
packet bit (RCTL.SBP) is set.
VLAN Tag Field (16)
Hardware stores additional information in the receive descriptor for 802.1Q packets. If the packet type
is 802.1Q (determined when a packet matches VET and CTRL.VME = 1b), then the VLAN Tag field
records the VLAN information and the four-byte VLAN information is stripped from the packet data
storage. Otherwise, the VLAN Tag field contains 0x0000. The rule for VLAN tag is to use network
ordering (also called big endian). It appears in the following manner in the descriptor:
7.1.4.2 Advanced Receive Descriptors
7.1.4.2.1 Advanced Receive Descriptors (RDESC) - Read Format
Table 7-9 shows the receive descriptor. This is the format that software writes to the descriptor queue
and hardware reads from the descriptor queue in host memory. Hardware writes back the descriptor in
a different format, shown in Table 7-10.
Packet Buffer Address (64) - Physical address of the packet buffer. The lowest bit is either A0 (LSB
of address) or NSE (No-Snoop Enable), depending on bit RXCTL.RXdataWriteNSEn of the relevant
queue. See Section 8.13.1.
Header Buffer Address (64) - Physical address of the header buffer. The lowest bit is DD.
Table 7-8. VLAN Tag Field Layout (for 802.1Q Packet)
15 13 12 11 0
PRI CFI VLAN
Table 7-9. RDESC Descriptor Read Format
63 1 0
0Packet Buffer Address [63:1] A0/NSE
8Header Buffer Address [63:1] DD
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Note: The I210 does not support null descriptors (a descriptor with a packet or header address that
is always equal to zero).
When software sets the NSE bit in the receive descriptor, the I210 places the received packet
associated with this descriptor in memory at the packet buffer address with NSE set in the PCIe
attribute fields. NSE does not affect the data written to the header buffer address.
When a packet spans more than one descriptor, the header buffer address is not used for the second,
third, etc. descriptors; only the packet buffer address is used in this case.
NSE is enabled for packet buffers that the software device driver knows have not been touched by the
processor since the last time they were used, so the data cannot be in the processor cache and snoop is
always a miss. Avoiding these snoop misses improves system performance. No-snoop is particularly
useful when the DMA engine is moving the data from the packet buffer into application buffers, and the
software device driver is using the information in the header buffer for its work with the packet.
Note: When No-Snoop Enable is used, relaxed ordering should also be enabled with
CTRL_EXT.RO_DIS.
7.1.4.2.2 Advanced Receive Descriptors (RDESC) - Write-back Format
When the I210 writes back the descriptors, it uses the descriptor format shown in Table 7-10.
Note: SRRCTL[n]. DESCTYPE must be set to a value other than 000b for the I210 to write back the
special descriptors.
RSS Type (4)
Table 7-10. RDESC Descriptor Write-back Format
63 48 47 35 34 32 31 30 21 20 19 18 17 16 4 3 0
0RSS Hash Value/
{Fragment Checksum, IP identification} SPH HDR_LEN[9:0] HDR_LEN[11:10] RSV Packet Type RSS Type
8 VLAN Tag PKT_LEN Extended Error Extended Status
Table 7-11. RSS Type
Packet Type Description
0x0 No hash computation done for this packet.
0x1 HASH_TCP_IPV4
0x2 HASH_IPV4
0x3 HASH_TCP_IPV6
0x4 HASH_IPV6_EX
0x5 HASH_IPV6
0x6 HASH_TCP_IPV6_EX
0x7 HASH_UDP_IPV4
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The I210 must identify the packet type and then choose the appropriate RSS hash function to be used
on the packet. The RSS type reports the packet type that was used for the RSS hash function.
Packet Type (13)
VPKT (bit 12) - VLAN Packet indication
L2 Packet (bit 11) - L2 packet indication (not L3 or L4 packet), if this bit is set along with a higher
layer indication it indicates the ETQF type is valid
L2 Packet (bit 11) - L2 packet indication (not L3 or L4 packet), if this bit is set along with a higher
layer indication it indicates the ETQF type is validL2 Packet (bit 11) - L2 packet indication (not L3 or
L4 packet), if this bit is set along with a higher layer indication it indicates the ETQF type is valid
ETQF Valid (bit 11) - L2 ETQF field in Packet Type is valid. Higher layer indications (bits 7:0) can still
be set.
The 11 LSB bits of the packet type reports the packet type identified by the hardware as follows:
RSV(22):
Reserved.
HDR_LEN (10) - The length (bytes) of the header as parsed by the I210. In split mode when HBO
(Header Buffer Overflow) is set in the Extended error field, the HDR_LEN can be greater then zero
though nothing is written to the header buffer. In header replication mode, the HDR_LEN field does not
0x8 HASH_UDP_IPV6
0x9 HASH_UDP_IPV6_EX
0xA:0xF Reserved
Table 7-12. Packet Type LSB Bits (11:10)
Bit Index Bit 11 = 0b
0IPV4 - Indicates IPv4 header present1
1. On unsupported tunneled frames only packet types of external IP header are set if detected.
1IPV4E - Indicates IPv4 Header includes IP options1
2IPV6 - Indicates IPv6 header present1 2 3
2. When a packet is fragmented then the internal packet type bits on a supported tunneled packet (IPv6 tunneled in IPv4 only) won’t
be set.
3. On supported tunneled frames (IPv6 tunneled in IPv4 only) then all the internal Packet types are set if detected (IPV6, IPV6E, TCP,
UDP, SCTP and NFS)
3IPV6E - Indicates IPv6 Header includes extensions1 2 3
4TCP - Indicates TCP header present1 3 4
4. When a packet is fragmented the TCP, UDP, SCTP and NFS bits won’t be set.
5UDP - Indicates UDP header present1 3 4
6SCTP - Indicates SCTP header present1 3 4
7NFS - Indicates NFS header present1 3 4
10:8
EtherType - ETQF register index that matches the packet. Special types might be defined for 1588, 802.1X, LLDP
or any other requested type.Ethertype - ETQF register index that matches the packet. Special types might be
defined for 1588, 802.1x, 1722, LLDP or other requested EtherTypes
Table 7-11. RSS Type
Packet Type Description
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reflect the size of the data actually stored in the header buffer because the I210 fills the buffer up to
the size configured by SRRCTL[n].BSIZEHEADER, which might be larger than the header size reported
here. This field is only valid in the first descriptor of a packet and should be ignored in all subsequent
descriptors.
Note: When the packet is time stamped and the time stamp is placed at the beginning of the buffer
the RDESC.HDR_LEN field is updated with the additional time stamp bytes (16 bytes). For
further information see Section 7.1.7.
Packet types supported by the header split and header replication are listed in Appendix A.1. Other
packet types are posted sequentially in the host packet buffer. Each line in Table 7-13 has an enable bit
in the PSRTYPE register. When one of the bits is set, the corresponding packet type is split. If the bit is
not set, a packet matching the header layout is not split.
Header split and replication is described in Section 7.1.5 while the packet types for this functionality are
enabled by the PSRTYPE[n] registers (Section 8.10.3).
Note: The header of a fragmented IPv6 packet is defined before the fragmented extension header.
SPH (1) - Split Header - When set, indicates that the HDR_LEN field reflects the length of the header
found by hardware. If cleared, the HDR_LEN field should be ignored.In the case where
SRRCTL[n].DESCTYPE is set to Header replication mode, SPH bit is set but the HDR_LEN field does not
reflect the size of the data actually stored in the header buffer, because the I210 fills the buffer up to
the size configured by SRRCTL[n].BSIZEHEADER.
RSS Hash / {Fragment Checksum, IP identification} (32)
This field has multiplexed functionality according to the received packet type (reported on the Packet
Type field in this descriptor) and device setting.
Fragment Checksum (16-Bit; 63:48)
The fragment checksum word contains the unadjusted one’s complement checksum of the IP
payload and is used to offload checksum verification for fragmented UDP packets as described in
Section 7.1.7.2. This field is mutually exclusive with the RSS hash. It is enabled when the
RXCSUM.PCSD bit is cleared and the RXCSUM.IPPCSE bit is set.
IP identification (16-Bit; 47:32)
The IP identification word identifies the IP packet to whom this fragment belongs and is used to
offload checksum verification for fragmented UDP packets as described in Section 7.1.7.2. This
field is mutually exclusive with the RSS hash. It is enabled when the RXCSUM.PCSD bit is cleared
and the RXCSUM.IPPCSE bit is set.
RSS Hash Value (32)
The RSS hash value is required for RSS functionality as described in Section 7.1.2.7. This bit is
mutually exclusive with the fragment checksum. It is enabled when the RXCSUM.PCSD bit is set.
Extended Status (20)
Status information indicates whether the descriptor has been used and whether the referenced buffer is
the last one for the packet. Table 7-13 lists the extended status word in the last descriptor of a packet
(EOP is set). Table 7-14 lists the extended status word in any descriptor but the last one of a packet
(EOP is cleared).
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MC (19) - Packet received from MC. The MC bit is set to indicate the packet was sent by the local
MC. Bit is cleared if packet arrives from the network. For more details see Section 10.4.
TS (16) - Time Stamped Packet (Time Sync). The Time Stamp bit is set to indicate that the device
recognized a Time Sync packet and time stamped it in the RXSTMPL/H time stamp registers (See
Section 7.8.2.3).
TSIP (15) - Timestamp in packet. The Timestamp In Packet bit is set to indicate that the received
packet arrival time was captured by the hardware and the timestamp was placed in the receive
buffer. For further details see Section 7.1.7.
Reserved (2, 8, 14:13, 17, 18) - Reserved at zero.
PIF (7), IPCS(6), UDPCS(4), VP(3), EOP (1), DD (0) - These bits are described in the legacy
descriptor format in Section 7.1.4.
L4I (5) - This bit indicates that an L4 integrity check was done on the packet, either TCP
checksum, UDP checksum or SCTP CRC checksum. This bit is valid only for the last descriptor of
the packet. An error in the integrity check is indicated by the L4E bit in the error field. The type of
check done can be induced from the packet type bits 4, 5 and 6. If bit 4 is set, a TCP checksum
was done. If bit 5 is set a UDP checksum was done, and if bit 6 is set, a SCTP CRC checksum was
done.
VEXT (9) - First VLAN is found on a double VLAN packet. This bit is valid only when
CTRL_EXT.EXT_VLAN is set. For more details see Section 7.4.5.
UDPV (10) - This bit indicates that the incoming packet contains a valid (non-zero value)
checksum field in an incoming first fragment UDP IPv4 packet. This means that the Fragment
Checksum field in the receive descriptor contains the IP payload checksum as described in
Section 7.1.7.2. When this field is cleared in the first fragment that contains the UDP header,
means that the packet does not contain a valid UDP checksum and the fragment checksum field in
the Rx descriptor should be ignored. This field is always cleared in incoming fragments that do not
contain the UDP header or in non fragmented packet.
LLINT (11) - This bit indicates that the packet caused an immediate interrupt via the low latency
interrupt mechanism.
Strip CRC (12) - This bit indicates that Ethernet CRC has been stripped from incoming packet.
Strip CRC operation is defined by the RCTL.SECRC bit.
Table 7-13. Receive Status (RDESC.STATUS) Layout of the Last Descriptor
19 18 17 16 15 14 13 12 11 10
MC Rsv Rsv TS TSIP Reserved Strip CRC LLINT UDPV
VEXT Rsv PIF IPCS L4I UDPCS VP Rsv EOP DD
9 8 7 6 5 4 3 2 1 0
Table 7-14. Receive Status (RDESC.STATUS) Layout of Non-Last Descriptor
19... ............................ 2 1 0
Reserved EOP = 0b DD
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Extended Error (12)
Table 7-15 and the text that follows describes the possible errors reported by hardware.
RXE (bit 11)
RXE is described in the legacy descriptor format in Section 7.1.4.
IPE (bit 10)
The IPE error indication is described in the legacy descriptor format in Section 7.1.4.
L4E (bit 9)
L4 error indication - When set, indicates that hardware attempted to do an L4 integrity check as
described in the L4I bit, but the check failed.
Reserved (bits 8:7)
Reserved (bits 6:4)
HBO (bit 3) - Header Buffer Overflow
Note: The HBO bit is relevant only if SPH is set.
1. In both header replication modes, HBO is set if the header size (as calculated by hardware) is
bigger than the allocated buffer size (SRRCTL.BSIZEHEADER) but the replication still takes place up
to the header buffer size. Hardware sets this bit in order to indicate to software that it needs to
allocate bigger buffers for the headers.
2. In header split mode, when SRRCTL[n] BSIZEHEADER is smaller than HDR_LEN, then HBO is set to
1b, In this case, the header is not split. Instead, the header resides within the host packet buffer.
The HDR_LEN field is still valid and equal to the calculated size of the header. However, the header
is not copied into the header buffer.
Note: Most error information appears only when the store–bad–packet bit (RCTL.SBP) is set and a
bad packet is received.
Reserved (bits 2:0) - Reserved
PKT_LEN (16)
Number of bytes existing in the host packet buffer
The length covers the data written to a receive buffer including CRC bytes (if any). Software must read
multiple descriptors to determine the complete length for packets that span multiple receive buffers. If
SRRCTL.DESC_TYPE = 4 (advanced descriptor header replication large packet only) and the total
packet length is smaller than the size of the header buffer (no replication is done), this field continues
to reflect the size of the packet, although no data is written to the packet buffer. Otherwise, if the
buffer is not split because the header is bigger than the allocated header buffer, this field reflects the
size of the data written to the first packet buffer (header and data).
Note: When the packet is time stamped and the time stamp is placed at the beginning of the buffer,
the RDESC.PKT_LEN field is updated with the additional time stamp bytes (16 bytes). For
further information see Section 7.1.7.
Table 7-15. Receive Errors (RDESC.ERRORS) Layout
11 10 9 8 7 6 4 3 2 0
RXE IPE L4E Reserved Reserved HBO Reserved
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VLAN Tag (16)
These bits are described in the legacy descriptor format in Section 7.1.4.
7.1.4.3 Receive Descriptor Fetching
The fetching algorithm attempts to make the best use of PCIe bandwidth by fetching a cache-line (or
more) descriptor with each burst. The following paragraphs briefly describe the descriptor fetch
algorithm and the software control provided.
When the RXDCTL[n].ENABLE bit is set and the on-chip descriptor cache is empty, a fetch happens as
soon as any descriptors are made available (Host increments the RDT[n] tail pointer). When the on-
chip buffer is nearly empty (defined by RXDCTL.PTHRESH), a prefetch is performed each time enough
valid descriptors (defined by RXDCTL.HTHRESH) are available in host memory.
When the number of descriptors in host memory is greater than the available on-chip descriptor cache,
the I210 might elect to perform a fetch that is not a multiple of cache-line size. Hardware performs this
non-aligned fetch if doing so results in the next descriptor fetch being aligned on a cache-line boundary.
This enables the descriptor fetch mechanism to be more efficient in the cases where it has fallen behind
software.
All fetch decisions are based on the number of descriptors available and do not take into account any
split of the transaction due to bus access limitations.
7.1.4.4 Receive Descriptor Write-back
Processors have cache-line sizes that are larger than the receive descriptor size (16 bytes).
Consequently, writing back descriptor information for each received packet would cause expensive
partial cache-line updates. A receive descriptor packing mechanism minimizes the occurrence of partial
line write-backs.
To maximize memory efficiency, receive descriptors are packed together and written as a cache-line
whenever possible. Descriptors write-backs accumulate and are opportunistically written out in cache
line-oriented chunks, under the following scenarios:
RXDCTL[n].WTHRESH descriptors have been used (the specified maximum threshold of unwritten
used descriptors has been reached).
The receive timer expires (EITR) - in this case all descriptors are flushed ignoring any cache-line
boundaries.
Explicit software flush (RXDCTL.SWFLS).
Dynamic packets - if at least one of the descriptors that are waiting for write-back are classified as
packets requiring immediate notification the entire queue is flushed out.
When the number of descriptors specified by RXDCTL[n].WTHRESH have been used, they are written
back regardless of cache-line alignment. It is therefore recommended that RXDCTL[n].WTHRESH be a
multiple of cache-line size. When the receive timer (EITR) expires, all used descriptors are forced to be
written back prior to initiating the interrupt, for consistency. Software might explicitly flush
accumulated descriptors by writing the RXDCTL[n] register with the SWFLS bit set.
When the I210 does a partial cache-line write-back, it attempts to recover to cache-line alignment on
the next write-back.
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For applications where the latency of received packets is more important than the bus efficiency and
the CPU utilization, an EITR value of zero can be used. In this case, each receive descriptor are written
to the host immediately. If RXDCTL[n].WTHRESH equals zero, then each descriptor are written back
separately;, otherwise, write back of descriptors can be coalesced if descriptor accumulates in the
internal descriptor ring due to bandwidth constrains.
All write-back decisions are based on the number of descriptors available and do not take into account
any split of the transaction due to bus access limitations.
7.1.4.5 Receive Descriptor Ring Structure
Figure 7-7 shows the structure of each of the 4 receive descriptor rings. Hardware maintains 4 circular
queues of descriptors and writes back used descriptors just prior to advancing the head pointer(s).
Head and tail pointers wrap back to base when size descriptors have been processed.
Figure 7-7. Receive Descriptor Ring Structure
Circular Buffer Queues
Head
Base + Size
Base
Receive
Queue
Tail
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Software inserts receive descriptors by advancing the tail pointer(s) to refer to the address of the entry
just beyond the last valid descriptor. This is accomplished by writing the descriptor tail register(s) with
the offset of the entry beyond the last valid descriptor. The hardware adjusts its internal tail pointer(s)
accordingly. As packets arrive, they are stored in memory and the head pointer(s) is incremented by
hardware. When the head pointer(s) is equal to the tail pointer(s), the queue(s) is empty. Hardware
stops storing packets in system memory until software advances the tail pointer(s), making more
receive buffers available.
The receive descriptor head and tail pointers reference to 16-byte blocks of memory. Shaded boxes in
Figure 7-7 represent descriptors that have stored incoming packets but have not yet been recognized
by software. Software can determine if a receive buffer is valid by reading the descriptors in memory.
Any descriptor with a non-zero DD value has been processed by the hardware and is ready to be
handled by the software.
Note: The head pointer points to the next descriptor that is written back. After the descriptor write-
back operation completes, this pointer is incremented by the number of descriptors written
back. Hardware owns all descriptors between [head... tail]. Any descriptor not in this range is
owned by software.
The receive descriptor rings are described by the following registers:
Receive Descriptor Base Address (RDBA3 to RDBA0) register:
This register indicates the start of the descriptor ring buffer. This 64-bit address is aligned on a 16-
byte boundary and is stored in two consecutive 32-bit registers. Note that hardware ignores the
lower 4 bits.
Receive Descriptor Length (RDLEN3 to RDLEN0) registers:
This register determines the number of bytes allocated to the circular buffer. This value must be a
multiple of 128 (the maximum cache-line size). Since each descriptor is 16 bytes in length, the
total number of receive descriptors is always a multiple of eight.
Receive Descriptor Head (RDH3 to RDH0) registers:
This register holds a value that is an offset from the base and indicates the in-progress descriptor.
There can be up to 64 KB, 8 KB descriptors in the circular buffer. Hardware maintains a shadow
copy that includes those descriptors completed but not yet stored in memory.
Receive Descriptor Tail (RDT3 to RDT0) registers:
This register holds a value that is an offset from the base and identifies the location beyond the last
descriptor hardware can process. This is the location where software writes the first new descriptor.
If software statically allocates buffers, uses legacy receive descriptors, and uses memory read to check
for completed descriptors, it has to zero the status byte in the descriptor before bumping the tail
pointer to make it ready for reuse by hardware. Zeroing the status byte is not a hardware requirement
but is necessary for performing an in-memory scan.
All the registers controlling the descriptor rings behavior should be set before receive is enabled, apart
from the tail registers that are used during the regular flow of data.
7.1.4.5.1 Low Receive Descriptors Threshold
As described above, the size of the receive queues is measured by the number of receive descriptors.
During run time the software processes completed descriptors and then increments the Receive
Descriptor Tail registers (RDT). At the same time, hardware might post new packets received from the
LAN incrementing the Receive Descriptor Head registers (RDH) for each used descriptor.
The number of usable (free) descriptors for the hardware is the distance between Tail and Head
registers. When the Tail reaches the Head, there are no free descriptors and further packets might be
either dropped or block the receive FIFO. In order to avoid this behavior, the I210 might generate a low
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277
latency interrupt (associated with the relevant receive queue) once the amount of free descriptors is
less or equal than the threshold. The threshold is defined in 16 descriptors granularity per queue in the
SRRCTL[n].RDMTS field.
7.1.5 Header Splitting and Replication
7.1.5.1 Purpose
This feature consists of splitting or replicating packet's header to a different memory space. This helps
the host to fetch headers only for processing: headers are replicated through a regular snoop
transaction in order to be processed by the host CPU. It is recommended to perform this transaction
with the DCA feature enabled (see Section 8.13) or in conjunction with a software-prefetch.
The packet (header and payload) is stored in memory through a (optionally) non-snoop transaction.
Later, a transaction moves the payload from the software device driver buffer to application memory or
it is moved using a normal memory copy operation.
The I210 supports header splitting in several modes:
Legacy mode: legacy descriptors are used; headers and payloads are not split.
Advanced mode, no split: advanced descriptors are in use; header and payload are not split.
Advanced mode, split: advanced descriptors are in use; header and payload are split to different
buffers. If the packet cannot be split, only the packet buffer is used.
Advanced mode, replication: advanced descriptors are in use; header is replicated in a separate
buffer and also in a payload buffer.
Advanced mode, replication, conditioned by packet size: advanced descriptors are in use;
replication is performed only if the packet is larger than the header buffer size.
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7.1.5.2 Description
In Figure 7-8 and Figure 7-9, the header splitting and header replication modes are shown.
Figure 7-8. Header Splitting
Figure 7-9. Header Replication
Payload
Header
Buffer 0
Buffer 1
Host Memory
Payload
Header
Packet Buffer Address
Header Buffer Address
0
8
0313263
Payload
Header
Packet
Buffer
Header
Buffer
Host Memory
Header and Payload
Header and First
Part of Payload
Packet Buffer Address
Header Buffer Address
0
8
0313263
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The physical address of each buffer is written in the Buffer Addresses fields. The sizes of these buffers
are statically defined by BSIZEPACKET and BSIZEHEADER fields in the SRRCTL[n] registers.
The packet buffer address includes the address of the buffer assigned to the replicated packet,
including header and data payload portions of the received packet. In the case of a split header, only
the payload is included.
The header buffer address includes the address of the buffer that contains the header information. The
receive DMA module stores the header portion of the received packets into this buffer.
The I210 uses the packet replication or splitting feature when the SRRCTL[n].DESCTYPE is larger than
one. The software device driver must also program the buffer sizes in the SRRCTL[n] registers.
When header split is selected, the packet is split only on selected types of packets. A bit exists for each
option in PSRTYPE[n] registers so several options can be used in conjunction with them. If one or more
bits are set, the splitting is performed for the corresponding packet type. See Appendix A.1 for details
on the possible headers type supported).
Table 7-16 lists the behavior of the I210 in the different modes.
Table 7-16. I210 Split/Replicated Header Behavior
DESCTYPE Condition SPH HBO PKT_LEN HDR_LEN Header and Payload DMA
Split
1. Header can't be
decoded 0b 0b Min(Packet length,
BSIZEPACKET)N/A Header + Payload Packet
buffer
2. Header <=
BSIZEHEADER 1b 0b Min(Payload length,
BSIZEPACKET)1
1. In a header only packet (such as TCP ACK packet), the PKT_LEN is zero.
Header size Header Header buffer
Payload Packet buffer
3. Header >
BSIZEHEADER 1b 1b Min(Packet length,
BSIZEPACKET)Header size2
2. The HDR_LEN doesn't reflect the actual data size stored in the Header buffer. It reflects the header size determined by the parser.
When timestamp in packet is enabled header size reflects the additional 16 bytes of the timestamp.
Header + Payload Packet
buffer
Replicate
1. Header can't be
decoded 0b3
3. In replicate mode if SPH = 0b due to no match to any of the headers selected in the PSRTYPE[n] register, then the header size is
not relevant. In any case, even if SPH = 1b due to match to one of the headers selected in the PSRTYPE[n] register, the HDR_LEN
doesn't reflect the actual data size stored in the header buffer.
0b Min(Packet length,
BSIZEPACKET)N/A
(Header + Payload) (partial5)
Header buffer
Header + Payload Packet
buffer
2. Packet length <=
BSIZEHEADER 1b30b Min(Packet length,
BSIZEPACKET)Header size
Header + Payload Header
buffer
Header + Payload Packet
buffer
3. Packet length >
BSIZEHEADER 1b30b/1b4
4. HBO is 1b if the header size is bigger than BSIZEHEADER and zero otherwise.
Min(Packet length,
BSIZEPACKET)Header size
Header + Payload (partial5)
Header buffer
Header + Payload Packet
buffer
5. Partial means up to BSIZEHEADER.
Replicate
Large
Packet only
1. Header can't be
decoded 0b30b Min(Packet length,
BSIZEPACKET)N/A
(Header + Payload) (partial5)
Header buffer
Header + Payload Packet
buffer
2. Packet length <=
BSIZEHEADER 1b30b Packet length Header size Header + Payload Header
buffer
2. Packet length >
BSIZEHEADER 1b30b/1b5Min(Packet length,
BSIZEPACKET)Header size
(Header + Payload) (partial5)
Header buffer
Header + Payload Packet
buffer
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Software Notes:
If SRRCTL[n].NSE is set, all buffers' addresses in a packet descriptor must be word aligned.
Packet header can't span across buffers, therefore, the size of the header buffer must be larger
than any expected header size. Otherwise, only the part of the header fitting the header buffer is
replicated. In the case of header split mode (SRRCTL[n].DESCTYPE = 010b), a packet with a
header larger than the header buffer is not split.
Section A.1 describes the details of the split/replicate conditions for different types of headers
according to the settings of the PSRTYPE register values.
7.1.6 Receive Packet Timestamp in Buffer
The I210 supports adding an optional tailored header before the MAC header of the packet in the
receive buffer. The 64 MSB bits of the 128 bit tailored header include a timestamp composed of the
packet reception time measured in the SYSTIML (Low DW) and SYSTIMH (High DW) registers (See
Section 7.8.3.1 for further information on SYSTIML/H operation). The 64 LSB bits of the tailored header
are reserved.
The timestamp information is placed in Host order (Little Endian) format as listed in Table 7-17.
The Timestamp in Buffer is enabled by the following settings:
The 1588 logic must not be disabled by the TSAUXC.Disable systime flag (it should be cleared)
The RXPBSIZE.cfg_ts_en flag should be set, allocating the extra 16 bytes in the packet buffer for
the received packets
Specific setting of the relevant receive queues by the SRRCTL[n] registers
The Timestamp flag should be set, instructing the hardware to post the timestamp in the
packet buffer
If the DESCTYPE is set to any of the header split modes then the BSIZEHEADER field should be
set to a larger header buffer than 128 bytes
Packets are received to the queue are time stamped if they meet the criteria listed in Table 7-70 within
Section 7.9.1. Meeting these cases the packet is reported as follow:
Place a 64 bit timestamp, indicating the time a packet was received by the MAC, at the beginning of
the receive buffer before the received packet.
Set the TSIP bit in the RDESC.STATUS field of the last receive descriptor.
Update the RDESC.Packet Type field in the last receive descriptor. Value in this field enables
identifying that this is a PTP (Precision Time Protocol) packet (this indication is only relevant for L2
packets).
Update the RDESC.HDR_LEN and RDESC.PKT_LEN values to include size of timestamp.
Software driver should take into account the additional size of the timestamp when preparing the
receive descriptors for the relevant queue.
While the receive path is disabled, the Timestamp in Buffer mode can be disabled by clearing
RXPBSIZE.cfg_ts_en flag and issuing a Port Software Reset event (CTRL.RST).
Table 7-17. Timestamp Layout in Buffer
0 3 4 7 8 11 12 15 16...
Reserved (0x0) Reserved (0x0) SYSTIML SYSTIMH Received Packet
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7.1.7 Receive Packet Checksum and SCTP CRC Offloading
The I210 supports the off loading of four receive checksum calculations: packet checksum, fragment
payload checksum, the IPv4 header checksum, and the TCP/UDP checksum. In addition, SCTP CRC32
calculation is supported as described in Section 7.1.7.3
The packet checksum and the fragment payload checksum shares the same location as the RSS field
and is reported in the receive descriptor when the RXCSUM.PCSD bit is cleared. If the RXCSUM.IPPCSE
is set, the Packet checksum is aimed to accelerate checksum calculation of fragmented UDP packets.
Please refer to Section 7.1.7.2 for a detailed explanation. If RXCSUM.IPPCSE is cleared (the default
value), the checksum calculation that is reported in the Rx Packet checksum field is the unadjusted 16-
bit one’s complement of the packet.
The packet checksum is the 16-bit one's complement of the received packet, starting from the byte
indicated by RXCSUM.PCSS (zero corresponds to the first byte of the packet), after stripping. For
packets with a VLAN header, the packet checksum includes the header if VLAN striping is not enabled
by the CTRL.VME. If a VLAN header strip is enabled, the packet checksum and the starting offset of the
packet checksum exclude the VLAN header due to masking of VLAN header. For example, for an
Ethernet II frame encapsulated as an 802.3ac VLAN packet and CTRL.VME is set and with
RXCSUM.PCSS set to 14, the packet checksum would include the entire encapsulated frame, excluding
the 14-byte Ethernet header (DA, SA, type/length) and the 4-byte q-tag. The packet checksum does
not include the Ethernet CRC if the RCTL.SECRC bit is set.
Software must make the required offsetting computation (to remove the bytes that should not have
been included and to include the pseudo-header) prior to comparing the packet checksum against the
TCP checksum stored in the packet.
Note: The RXCSUM.PCSS value should point to a field that is before or equal to the IP header start.
Otherwise the IP header checksum or TCP/UDP checksum is not calculated correctly.
For supported packet/frame types, the entire checksum calculation can be off loaded to the I210. If
RXCSUM.IPOFLD is set to 1b, the I210 calculates the IPv4 checksum and indicates a pass/fail indication
to software via the IPv4 Checksum Error bit (RDESC.IPE) in the Error field of the receive descriptor.
Similarly, if RXCSUM.TUOFLD is set to 1b, the I210 calculates the TCP or UDP checksum and indicates a
pass/fail condition to software via the TCP/UDP Checksum Error bit (RDESC.L4E). These error bits are
valid when the respective status bits indicate the checksum was calculated for the packet (RDESC.IPCS
and RDESC.L4CS, respectively).
If neither RXCSUM.IPOFLD nor RXCSUM.TUOFLD are set, the Checksum Error bits (IPE and L4E) are 0b
for all packets.
Supported frame types:
Ethernet II
Ethernet SNAP
Table 7-18. Supported Receive Checksum Capabilities
Packet Type Hardware IP
Checksum Calculation
Hardware TCP/
UDP Checksum
Calculation
Hardware SCTP
CRC Calculation
IPv4 packets. Yes Yes Yes
IPv6 packets. No (n/a) Yes Yes
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7.1.7.1 Filters Details
Table 7-18 lists general details about what packets are processed. In more detail, the packets are
passed through a series of filters to determine if a receive checksum is calculated:
7.1.7.1.1 MAC Address Filter
This filter checks the MAC destination address to be sure it is valid (such as IA match, broadcast,
multicast, etc.). The receive configuration settings determine which MAC addresses are accepted. See
the various receive control configuration registers such as RCTL (RCTL.UPE, RCTL.MPE, RCTL.BAM),
MTA, RAL, and RAH.
7.1.7.1.2 SNAP/VLAN Filter
This filter checks the next headers looking for an IP header. It is capable of decoding Ethernet II,
Ethernet SNAP, and IEEE 802.3ac headers. It skips past any of these intermediate headers and looks
for the IP header. The receive configuration settings determine which next headers are accepted. See
the various receive control configuration registers such as RCTL (RCTL.VFE), VET, and VFTA.
7.1.7.1.3 IPv4 Filter
This filter checks for valid IPv4 headers. The version field is checked for a correct value (4).
IPv6 packet with next header options:
Hop-by-hop options
Destinations options (without Home option)
Destinations options (with Home option)
Routing (with Segments Left zero)
Routing (with Segments Left > zero)
Fragment
No (n/a)
No (n/a)
No (n/a)
No (n/a)
No (n/a)
No (n/a)
Yes
Yes
No
Yes
No
No
Yes
IPv4 tunnels:
IPv4 packet in an IPv4 tunnel.
IPv6 packet in an IPv4 tunnel.
Yes (External - as if L3
only)
Yes (IPv4)
No
Yes1
No
Yes
IPv6 tunnels:
IPv4 packet in an IPv6 tunnel.
IPv6 packet in an IPv6 tunnel.
No
No
No
No
No
No
Packet is an IPv4 fragment. Yes No2 No
Packet is greater than 1518, 1522 or 1526 bytes (LPE=1b)3. Yes Yes Yes
Packet has 802.3ac tag. Yes Yes Yes
IPv4 packet has IP options
(IP header is longer than 20 bytes). Yes Yes Yes
Packet has TCP or UDP options. Yes Yes Yes
IP header’s protocol field contains a protocol number other
than TCP or UDP or SCTP. Yes No No
1. The IPv6 header portion can include supported extension headers as described in the “IPv6 packet with next header options” row.
2. UDP checksum of first fragment is supported.
3. Depends on number of VLAN tags.
Table 7-18. Supported Receive Checksum Capabilities
Packet Type Hardware IP
Checksum Calculation
Hardware TCP/
UDP Checksum
Calculation
Hardware SCTP
CRC Calculation
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IPv4 headers are accepted if they are any size greater than or equal to five (Dwords). If the IPv4
header is properly decoded, the IP checksum is checked for validity. The RXCSUM.IPOFLD bit must be
set for this filter to pass.
7.1.7.1.4 IPv6 Filter
This filter checks for valid IPpv6 headers, which are a fixed size and have no checksum. The IPv6
extension headers accepted are: hop-by-hop, destination options, and routing. The maximum size next
header accepted is 16 Dwords (64 bytes).
7.1.7.1.5 IPv6 Extension Headers
IPv4 and TCP provide header lengths, which enable hardware to easily navigate through these headers
on packet reception for calculating checksum and CRCs, etc. For receiving IPv6 packets; however,
there is no IP header length to help hardware find the packet's ULP (such as TCP or UDP) header. One
or more IPv6 extension headers might exist in a packet between the basic IPv6 header and the ULP
header. The hardware must skip over these extension headers to calculate the TCP or UDP checksum
for received packets.
The IPv6 header length without extensions is 40 bytes. The IPv6 field Next Header Type indicates what
type of header follows the IPv6 header at offset 40. It might be an upper layer protocol header such as
TCP or UDP (Next Header Type of 6 or 17, respectively), or it might indicate that an extension header
follows. The final extension header indicates with its Next Header Type field the type of ULP header for
the packet.
IPv6 extension headers have a specified order. However, destinations must be able to process these
headers in any order. Also, IPv6 (or IPv4) might be tunneled using IPv6, and thus another IPv6 (or
IPv4) header and potentially its extension headers might be found after the extension headers.
The IPv4 Next Header Type is at byte offset nine. In IPv6, the first Next Header Type is at byte offset
six.
All IPv6 extension headers have the Next Header Type in their first eight bits. Most have the length in
the second eight bits (Offset Byte[1]) as listed in Table 7-19:
Table 7-20 lists the encoding of the Next Header Type field and information on determining each
header type's length. The IPv6 extension headers are not otherwise processed by the I210 so their
details are not covered here.
Table 7-19. Typical IPv6 Extended Header Format (Traditional Representation)
0 1 2 3 4 5 6 7
1
8 9 0 1 2 3 4 5
2 3
6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1
Next Header Type Length
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Notes:
1. Hop-by-hop options header is only found in the first Next Header Type of an IPv6 header.
2. When a No Next Header type is encountered, the rest of the packet should not be processed.
3. Encapsulated security payload - the I210 cannot offload packets with this header type.
Note that the I210 hardware acceleration does not support all IPv6 extension header types (refer to
Table 7-18).
7.1.7.1.6 UDP/TCP Filter
This filter checks for a valid UDP or TCP header. The prototype next header values are 0x11 and 0x06,
respectively. The RXCSUM.TUOFLD bit must be set for this filter to pass.
7.1.7.2 Receive UDP Fragmentation Checksum
The I210 might provide receive fragmented UDP checksum offload. The I210 should be configured in
the following manner to enable this mode:
The RXCSUM.PCSD bit should be cleared. The Fragment Checksum and IP Identification fields are
mutually exclusive with the RSS hash. When the RXCSUM.PCSD bit is cleared, Fragment Checksum and
IP Identification are active instead of RSS hash.
The RXCSUM.IPPCSE bit should be set. This field enables the IP payload checksum enable that is
designed for the fragmented UDP checksum.
The RXCSUM.PCSS field must be zero. The packet checksum start should be zero to enable auto-start
of the checksum calculation. Table 7-21 lists the exact description of the checksum calculation.
Table 7-21 also lists the outcome descriptor fields for the following incoming packets types:
Table 7-20. Header Type Encoding and Lengths
Header Next Header Type
Header Length
(Units are Bytes Unless Otherwise
Specified)
IPv6 6 Always 40 bytes
IPv4 4 Offset Bits[7:4]
Unit = 4 bytes
TCP 6 Offset Byte[12].Bits[7:4]
Unit = 4 bytes
UDP 17 Always 8 bytes
Hop by Hop Options 0 (Note 1) 8+Offset Byte[1]
Destination Options 60 8+Offset Byte[1]
Routing 43 8+Offset Byte[1]
Fragment 44 Always 8 bytes
Authentication 51 8+4*(Offset Byte[1])
Encapsulating Security Payload 50 Note 3
No Next Header 59 Note 2
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Note: When the software device driver computes the 16-bit ones complement, the sum on the
incoming packets of the UDP fragments, it should expect a value of 0xFFFF. Refer to
Section 7.1.7 for supported packet formats.
7.1.7.3 SCTP Offload
If a receive packet is identified as SCTP, the I210 checks the CRC32 checksum of this packet if the
RXCSUM.CRCOFL bit is set to 1b and identifies this packet as SCTP. Software is notified on the
execution of the CRC check via the L4I bit in the Extended Status field of the Rx descriptor and is
notified on detection of a CRC error via the L4E bit in the Extended Error field of the RX descriptor. The
detection of a SCTP packet is indicated via the SCTP bit in the packet Type field of the Rx descriptor.
The following SCTP packet format is expected to enable support of the SCTP CRC check:
Table 7-22. SCTP Header
7.2 Transmit Functionality
7.2.1 Packet Transmission
Output packets to be transmitted are created using pointer-length pairs constituting a descriptor chain
(descriptor based transmission). Software forms transmit packets by assembling the list of pointer-
length pairs, storing this information in one of the transmit descriptor rings, and then updating the
adequate on-chip transmit tail pointer. The transmit descriptors and buffers are stored in host memory.
Hardware typically transmits the packet only after it has completely fetched all the packet data from
host memory and stored it into the on-chip transmit FIFO (store and forward architecture). This permits
TCP or UDP checksum computation and avoids problems with PCIe under-runs. Another transmit
feature of the I210 is TCP/UDP segmentation. The hardware has the capability to perform packet
segmentation on large data buffers offloaded from the Network Stack. This feature is discussed in detail
in Section 7.2.4.
Table 7-21. Descriptor Fields
Incoming Packet Type Fragment Checksum (if
RXCSUM.PCSD is cleared) UDPV UDPCS / L4CS /L4I
Non IP Packet Packet checksum 0b 0b / 0b /0b
IPv6 Packet Packet checksum 0b Depends on transport
header.
Non fragmented IPv4 packet Packet checksum 0b Depends on transport
header.
Fragmented IPv4, when not first
fragment The unadjusted one’s complement
checksum of the IP payload. 0b 1b / 0b / 0b
Fragmented IPv4, for the first
fragment
Same as above 1 if the UDP header
checksum is valid (not
zero)
1b / 0b / 0b
0 1 2 3 4 5 6 7
1
8 9 0 1 2 3 4 5
2
6 7 8 9 0 1 2 3
3
4 5 6 7 8 9 0 1
Source Port Destination Port
Verification Tag
Checksum
Chunks 1...n
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In addition, the I210 supports SCTP offloading for transmit requests. See section Section 7.2.5.3 for
details about SCTP.
Table 1-11 provides a high level description of all data/control transformation steps needed for sending
Ethernet packets to the line.
7.2.1.1 Transmit Data Storage
Data is stored in buffers pointed to by the descriptors. The data can be aligned to arbitrary byte
boundary with the maximum size per descriptor limited only to the maximum allowed packet size (9728
bytes). A packet typically consists of two (or more) buffers, one (or more) for the header and one for
the actual data. Each buffer is referenced by a different descriptor. Some software implementations
might copy the header(s) and packet data into one buffer and use only one descriptor per transmitted
packet.
7.2.1.2 On-Chip Transmit Buffers
The I210 allocates by default a 24 KB on-chip packet buffer. The buffers are used to store packets until
they are transmitted on the line. Actual on-chip transmit buffer allocated is controlled by the TXPBSIZE
register.
7.2.1.3 On-Chip descriptor Buffers
The I210 contains a 24 descriptor cache for each transmit queue used to reduce the latency of packet
processing and to optimize the usage of the PCIe bandwidth by fetching and writing back descriptors in
bursts. The fetch and write-back algorithm are described in Section 7.2.2.5 and Section 7.2.2.6.
7.2.1.4 Transmit Contexts
The I210 provides hardware checksum offload and TCP/UDP segmentation facilities. These features
enable TCP and UDP packet types to be handled more efficiently by performing additional work in
hardware, thus reducing the software overhead associated with preparing these packets for
transmission. Part of the parameters used by these features is handled though context descriptors.
A context descriptor refers to a set of device registers loaded or accessed as a group to provide a
particular function. The I210 supports 2x4 context descriptor sets (two per queue) on-chip. The
transmit queues can contain transmit data descriptors (similar to the receive queue) as well as transmit
context descriptors.
The contexts are queue specific and one context cannot be reused from one queue to another. This
differs from the method used in previous devices that supported a pool of contexts to be shared
between queues.
A transmit context descriptor differs from a data descriptor as it does not point to packet data. Instead,
this descriptor provides the ability to write to the on-chip context register sets that support the transmit
checksum offloading and the segmentation features of the I210.
The I210 supports one type of transmit context. This on-chip context is written with a transmit context
descriptor DTYP=2 and is always used as context for transmit data descriptor DTYP=3.
The IDX field contains an index to one of the two queue contexts. Software must track what context is
stored in each IDX location.
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Each advanced data descriptor that uses any of the advanced offloading features must refer to a
context.
Contexts can be initialized with a transmit context descriptor and then used for a series of related
transmit data descriptors. The context, for example, defines the checksum and offload capabilities for a
given type of TCP/IP flow. All packets of this type can be sent using this context.
Software is responsible for ensuring that a context is only overwritten when it is no longer needed.
Hardware does not include any logic to manage the on-chip contexts; it is completely up to software to
populate and then use the on-chip context table.
Note: Software should not queue more than two context descriptors in sequence without an
intervening data descriptor, to achieve adequate performance.
Each context defines information about the packet sent including the total size of the MAC header
(TDESC.MACLEN), the maximum amount of payload data that should be included in each packet
(TDESC.MSS), UDP or TCP header length (TDESC.L4LEN), IP header length (TDESC.IPLEN), and
information about what type of protocol (TCP, IP, etc.) is used. Other than TCP, IP (TDESC.TUCMD),
most information is specific to the segmentation capability.
Because there are dedicated on-chip resources for contexts, they remain constant until they are
modified by another context descriptor. This means that a context can be used for multiple packets (or
multiple segmentation blocks) unless a new context is loaded prior to each new packet. Depending on
the environment, it might be unnecessary to load a new context for each packet. For example, if most
traffic generated from a given node is standard TCP frames, this context could be setup once and used
for many frames. Only when some other frame type is required would a new context need to be loaded
by software. This new context could use a different index or the same index.
This same logic can also be applied to the TCP/UDP segmentation scenario, though the environment is
a more restrictive one. In this scenario, the host is commonly asked to send messages of the same
type, TCP/IP for instance, and these messages also have the same Maximum Segment Size (MSS). In
this instance, the same context could be used for multiple TCP messages that require hardware
segmentation.
7.2.2 Transmit Descriptors
The I210 supports legacy descriptors and the I210 advanced descriptors.
Legacy descriptors are intended to support legacy drivers to enable fast platform power up and to
facilitate debug.
In addition, the I210 supports two types of advanced transmit descriptors:
1. Advanced Transmit Context Descriptor, DTYP = 0010b.
2. Advanced Transmit Data Descriptor, DTYP = 0011b.
Note: DTYP values 0000b and 0001b are reserved.
The transmit data descriptor (both legacy and advanced) points to a block of packet data to be
transmitted. The advanced transmit context descriptor does not point to packet data. It contains
control/context information that is loaded into on-chip registers that affect the processing of packets for
transmission. The following sections describe the descriptor formats.
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7.2.2.1 Legacy Transmit Descriptor Format
Legacy descriptors are identified by having bit 29 of the descriptor (TDESC.DEXT) set to 0b. In this
case, the descriptor format is defined as shown in Table 7-23. Note that the address and length must
be supplied by software. Also note that bits in the command byte are optional, as is the CSO field.
Note: For frames that span multiple descriptors, the VLAN, CSO, CMD.VLE, CMD.IC, and CMD.IFCS
are valid only in the first descriptors and are ignored in the subsequent ones.
7.2.2.1.1 Buffer Address (64)
Physical address of a data buffer in host memory that contains a portion of a transmit packet.
7.2.2.1.2 Length
Length (TDESC.LENGTH) specifies the length in bytes to be fetched from the buffer address provided.
The maximum length associated with any single legacy descriptor is 9728 bytes.
Descriptor length(s) might be limited by the size of the transmit FIFO. All buffers comprising a single
packet must be able to be stored simultaneously in the transmit FIFO. For any individual packet, the
sum of the individual descriptors' lengths must be below 9728 bytes.
Note: The maximum allowable packet size for transmits can change, based on the value written to
the DMA TX Max Allowable packet size (DTXMXPKTSZ) register.
Note: Descriptors with zero length (null descriptors) transfer no data. Null descriptors can only
appear between packets and must have their EOP bits set.
Note: If the TCTL.PSP bit is set, the total length of the packet transmitted, not including FCS should
be at least 17 bytes. If bit is cleared the total length of the packet transmitted, not including
FCS should be at least 60 bytes.
7.2.2.1.3 Checksum Offset and Start - CSO
A Checksum Offset (TDESC.CSO) field indicates where, relative to the start of the packet, to insert a
TCP checksum if this mode is enabled.
Table 7-23. Transmit Descriptor (TDESC) Fetch Layout - Legacy Mode
63 48 47 40 39 36 35 32 31 24 23 16 15 0
0Buffer Address [63:0]
8VLAN Reserved Reserved STA CMD CSO Length
Table 7-24. Transmit Descriptor (TDESC) Write-Back Layout - Legacy Mode
63 48 47 40 39 36 35 32 31 24 23 16 15 0
0Reserved Reserved
8VLAN Reserved Reserved STA CMD CSO Length
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CSO is in a unit of bytes and must be in the range of data provided to the I210 in the descriptors. For
short packets that are not padded by software, CSO must be in the range of the unpadded data length,
not the eventual padded length (64 bytes).
CSO must be set to the location of TCP checksum in the packet. Checksum calculation is not done if
CSO is out of range. This occurs if (CSO > length - 1).
In the case of an 802.1Q header, the offset values depend on the VLAN insertion enable (VLE) bit. If it
is not set (VLAN tagging included in the packet buffers), the offset values should include the VLAN
tagging. If this bit is set (VLAN tagging is taken from the packet descriptor), the offset values should
exclude the VLAN tagging.
Note: UDP checksum calculation is not supported by the legacy descriptors. When using legacy
descriptors the I210 is not aware of the L4 type of the packet and thus, does not support the
translation of a checksum result of 0x0000 to 0xFFFF needed to differentiate between an UDP
packet with a checksum of zero and an UDP packet without checksum.
Because the CSO field is eight bits wide, it puts a limit on the location of the checksum to 255 bytes
from the beginning of the packet.
Hardware adds the checksum to the field at the offset indicated by the CSO field. A value of zero
corresponds to the first byte in the packet.
7.2.2.1.4 Command Byte - CMD
The CMD byte stores the applicable command and has the fields shown in Figure 7-25.
RSV (bit 7) - Reserved
VLE (bit 6) - VLAN Insertion Enable (See Table 7-26).
DEXT (bit 5) - Descriptor Extension (0 for legacy mode)
Reserved (bit 4) - Reserved
RS (bit 3) - Report Status
IC (bit 2) - Insert Checksum
IFCS (bit 1) - Insert FCS
EOP (bit 0) - End of Packet
VLE: Indicates that the packet is a VLAN packet. For example, hardware should add the VLAN
EtherType and an 802.1Q VLAN tag to the packet.
Table 7-25. Transmit Command (TDESC.CMD) Layout
7 6 5 4 3 2 1 0
RSV VLE DEXT Rsv RS IC IFCS EOP
Table 7-26. VLAN Tag Insertion Decision Table
VLE Action
0b Send generic Ethernet packet.
1b Send 802.1Q packet; VLAN data comes from the VLAN field of the TX descriptor.
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RS: Signals the hardware to report the status information. This is used by software that does in-
memory checks of the transmit descriptors to determine which ones are done. For example, if software
queues up 10 packets to transmit, it can set the RS bit in the last descriptor of the last packet. If
software maintains a list of descriptors with the RS bit set, it can look at them to determine if all
packets up to (and including) the one with the RS bit set have been buffered in the output FIFO.
Looking at the status byte and checking the Descriptor Done (DD) bit enables this operation. If DD is
set, the descriptor has been processed. Refer to Table 7-27 for the layout of the status field.
IC: If set, requests hardware to add the checksum of the data from CSS to the end of the packet at the
offset indicated by the CSO field.
IFCS: When set, hardware appends the MAC FCS at the end of the packet. When cleared, software
should calculate the FCS for proper CRC check. There are several cases in which software must set
IFCS:
Transmitting a short packet while padding is enabled by the TCTL.PSP bit.
Checksum offload is enabled by the IC bit in the TDESC.CMD.
VLAN header insertion enabled by the VLE bit in the TDESC.CMD.
EOP: When set, indicates this is the last descriptor making up the packet. Note that more than one
descriptor can be used to form a packet.
Note: VLE, IFCS, CSO, and IC must be set correctly only in the first descriptor of each packet. In
previous silicon generations, some of these bits were required to be set in the last descriptor
of a packet.
7.2.2.1.5 Status – STA
7.2.2.1.6 DD (Bit 0) - Descriptor Done Status
The DD bit provides the transmit status, when RS is set in the command: DD indicates that the
descriptor is done and is written back after the descriptor has been processed.
Note: When head write back is enabled (TDWBAL[n].Head_WB_En = 1), there is no write-back of
the DD bit to the descriptor. When using legacy Tx descriptors, Head writeback should not be
enabled (TDWBAL[n].Head_WB_En = 0).
7.2.2.1.7 VLAN
The VLAN field is used to provide the 802.1Q/802.1ac tagging information. The VLAN field is valid only
on the first descriptor of each packet when the VLE bit is set. The rule for VLAN tag is to use network
ordering. The VLAN field is placed in the transmit descriptor in the following manner:
Table 7-27. Transmit Status (TDESC.STA) Layout
3 2 1 0
Reserved DD
Table 7-28. VLAN Field (TDESC.VLAN) Layout
15 13 12 11 0
PRI CFI VLAN ID
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VLAN ID - the 12-bit tag indicating the VLAN group of the packet.
Canonical Form Indication (CFI) - Set to zero for Ethernet packets.
PRI - indicates the priority of the packet.
Note: The VLAN tag is sent in network order (also called big endian).
7.2.2.2 Advanced Transmit Context Descriptor
7.2.2.2.1 IPLEN (9)
IP header length. If an offload is requested, IPLEN must be greater than or equal to 20 and less than or
equal to 511.
7.2.2.2.2 MACLEN (7)
This field indicates the length of the MAC header. When an offload is requested (either TSE or IXSM or
TXSM is set), MACLEN must be larger than or equal to 14 and less than or equal to 127. This field
should include only the part of the L2 header supplied by the software device driver and not the parts
added by hardware. Table 7-30 lists the value of MACLEN in the different cases.
VLAN (16) - 802.1Q VLAN tag to be inserted in the packet during transmission. This VLAN tag is
inserted and needed only when a packet using this context has its DCMD.VLE bit set. This field should
include the entire 16-bit VLAN field including the CFI and Priority fields as listed in Table 7-28.
Note: The VLAN tag is sent in network order.
Table 7-29. Transmit Context Descriptor (TDESC) Layout - (Type = 0010b)
63 57 56 32 31 16 15 9 8 0
0Reserved LaunchTime VLAN MACLEN IPLEN
63 48 47 40 39 38 36 35 30 29 28 24 23 20 19 9 8 0
8MSS L4LEN RSV1IDX Reserved DEXT RSV1
1. RSV - Reserved
DTYP TUCMD Reserved
Table 7-30. MACLEN Values
SNAP Regular VLAN External VLAN MACLEN
No By hardware or no VLAN No 14
No By hardware or no VLAN Yes 18
No By software No 18
No By software Yes 22
Yes By hardware or no VLAN No 22
Yes By hardware or no VLAN Yes 26
Yes By software No 26
Yes By software Yes 30
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7.2.2.2.3 LaunchTime (25)
The LaunchTime field is only used in Qav mode when a queue is configured as SR queue. The
LaunchTime value is used to
1. calculate the fetch time - this time defines the time to fetch the packet from the host to the packet
buffer, and
2. define the launch time - the time to transmit a packet from the packet buffer.
The LaunchTime is a 25 bit field defined in 32 nsec units (Launch time = LaunchTime * 32). The Launch
time is compared against the SYSTIML register ignoring the SYSTIMH value. It means that the Launch
time is defined relative to the fraction of a second of the SYSTIM.
The Launch time is defined as expired if it is smaller or equal to the SYSTIML.
The Launch time is defined as greater than SYSTIML if it is in the range of [SYSTIML … SYSTIML +
0.5 sec).
It is defined as smaller than SYSTIML if it is in the range of [SYSTIML - 0.5 sec … SYSTIML).
Notes: The operations SYSTIML + 0.5 sec and SYSTIML - 0.5 sec are modulo 1 sec.
For meaningful operation, the Launch time should never be set to larger value than SYSTIML
+ 0.5sec. Otherwise, the Launch time might be misinterpreted.
The LaunchTime parameter is a relative time to the LaunchOffset parameter in the
LAUNCH_OS0 register. So, the actual Launch time equals to 32 * (LaunchOffset +
LaunchTime).
7.2.2.2.4 TUCMD (11)
RSV (bit 10:4) - Reserved
L4T (bit 3:2) - L4 Packet TYPE (00b: UDP; 01b: TCP; 10b: SCTP; 11b: Reserved)
IPV4 (bit 1) - IP Packet Type: When 1b, IPv4; when 0b, IPv6
SNAP (bit 0) - SNAP indication
7.2.2.2.5 DTYP(4)
Always 0010b for this type of descriptor.
7.2.2.2.6 DEXT(1)
Descriptor Extension (1b for advanced mode).
Table 7-31. Transmit Command (TDESC.TUCMD) Layout
10 4 3 2 1 0
Reserved L4T IPV4 SNAP
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7.2.2.2.7 IDX (3)
Index into the hardware context table where this context is stored. In the I210 the 2 available register
context sets per queue are accessed using the LSB bit and the two MSB bits are reserved and should
always be 0.
Note: In Qav mode for the SR queues a valid context descriptor should be placed ahead of any
timed packet pointed by a data descriptor and the IDX field is ignored.
7.2.2.2.8 L4LEN (8)
Layer 4 header length. If TSE is set in the data descriptor pointing to this context, this field must be
greater than or equal to 12 and less than or equal to 255. Otherwise, this field is ignored.
7.2.2.2.9 MSS (16)
Controls the Maximum Segment Size (MSS). This specifies the maximum TCP payload segment sent
per frame, not including any header or trailer. The total length of each frame (or section) sent by the
TCP/UDP segmentation mechanism (excluding Ethernet CRC) as follows:
Total length is equal to:
MACLEN + 4(if VLE set) + IPLEN + L4LEN + MSS
The one exception is the last packet of a TCP/UDP segmentation, which is typically shorter.
MSS is ignored when DCMD.TSE is not set.
Note: The headers lengths must meet the following:
MACLEN + IPLEN + L4LEN <= 512
Note: The MSS value should be larger than 0 and the maximum MSS value should not exceed 9216
bytes (9KB) length.
The context descriptor requires valid data only in the fields used by the specific offload options.
Table 7-32 lists the required valid fields according to the different offload options.
Table 7-32. Valid Field in Context vs. Required Offload
Required Offload Valid Fields in Context
TSE TXSM IXSM VLAN1
1. VLAN field is required only if the VLE bit in Tx descriptor is set.
L4LEN IPLEN MACLEN MSS L4T IPV4
1b2
2. If TSE is set, TXSM must be set to 1b.
1b X3
3. X - don’t care.
VLE Yes Yes Yes Yes Yes Yes
0b 1b X2VLE No Yes Yes No Yes Yes
0b 0b 1b VLE No Yes Yes No No Yes
0b 0b 0b No context required unless VLE is set.
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7.2.2.3 Advanced Transmit Data Descriptor
Note: For frames that span multiple descriptors, all fields apart from DCMD.EOP, DCMD.RS,
DCMD.DEXT, DTALEN, Address and DTYP are valid only in the first descriptor and are ignored
in the subsequent ones.
7.2.2.3.1 Address (64) / DMA Time Stamp
Address: Physical address of a data buffer in host memory that contains a portion of a transmit packet
provided by the software.
DMA Time Stamp: When enabled by the 1588_STAT_EN flag in the TQAVCTRL register, the DMA Time
Stamp is valid and the TS_STAT flag in the STA field is set. Otherwise, this field is undefined and the
TS_STAT flag in the STA field is cleared. The DMA Time Stamp reports the time on which the descriptor
is written back to host memory. In order to minimize the time gap between DMA completion and
descriptor write back, the software could either use the RS bit or set the WTHRESH parameter in the
TXDCTL[n] register (of the queue) to zero. The DMA Time Stamp only part of the time (in the SYSTIM
registers) as follows. Therefore, the software should read the SYSTIMH register (once every ~512 sec)
in order to keep track of the complete time.
DMA Time Stamp bits 31:0 get the value of SYSTIML register
DMA Time Stamp bits 41:32 get the value of the 10 LS bits of the SYSTIMH register
DMA Time Stamp bits 63:42 are set to zero
7.2.2.3.2 DTALEN (16)
Length in bytes of data buffer at the address pointed to by this specific descriptor.
Note: If the TCTL.PSP bit is set, the total length of the packet transmitted, not including FCS, should
be at least 17 bytes. If bit is cleared the total length of the packet transmitted, not including
FCS should be at least 60 bytes.
Note: The maximum allowable packet size for transmits is based on the value written to the DMA TX
Max Allowable packet size (DTXMXPKTSZ) register. Default value is 9,728 bytes.
Table 7-33. Advanced Transmit Data Descriptor (TDESD) Layout - (Type = 0011b)
0 Address[63:0]
8 PAYLEN POPTS RSV1IDX STA DCMD DTYP MAC RSV1
1. RSV - Reserved
DTALEN
63 46 45 40 39 38 36 35 32 31 24 23 20 19 18 17 16 15 0
Table 7-34. Advanced Tx Descriptor Write-back Format
0 DMA Time Stamp
8 Reserved STA Reserved
63 36 35 32 31 0
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7.2.2.3.3 MAC (2)
1STEP_1588 (bit 1) - Sample IEEE1588 Timestamp and post it in the transmitted packet at the
offset defined by the 1588_Offset field in the TSYNCTXCTL register.
2STEP_1588 (bit 1) - Sample IEEE1588 Timestamp at packet transmission in the TXSTMP registers.
Note: The two flags 1STEP_1588 and 2STEP_1588 are mutually.
7.2.2.3.4 DTYP (4)
0011b is the value for this descriptor type.
7.2.2.3.5 DCMD (8)
TSE (bit 7) - TCP/UDP Segmentation Enable
VLE (bit 6) - VLAN Packet Enable
DEXT (bit 5) - Descriptor Extension (1b for advanced mode)
Reserved (bit 4)
RS (bit 3) - Report Status
Reserved (bit 2)
IFCS (bit 1) - Insert FCS
EOP (bit 0) - End Of Packet
TSE indicates a TCP/UDP segmentation request. When TSE is set in the first descriptor of a TCP packet,
hardware must use the corresponding context descriptor in order to perform TCP segmentation. The
type of segmentation applied is defined according to the TUCMD.L4T field in the context descriptor.
Note: It is recommended that TCTL.PSP be enabled when TSE is used since the last frame can be
shorter than 60 bytes - resulting in a bad frame if TCTL.PSP is disabled.
VLE indicates that the packet is a VLAN packet and hardware must add the VLAN EtherType and an
802.1Q VLAN tag to the packet.
DEXT must be 1b to indicate advanced descriptor format (as opposed to legacy).
Table 7-35. Transmit Data (TDESD.MAC) Layout
1 0
2STEP_1588 1STEP_1588
Table 7-36. Transmit Data (TDESD.DCMD) Layout
7 6 5 4 3 2 1 0
TSE VLE DEXT Reserved RS Reserved IFCS EOP
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RS signals hardware to report the status information. This is used by software that does in-memory
checks of the transmit descriptors to determine which ones are done. For example, if software queues
up 10 packets to transmit, it can set the RS bit in the last descriptor of the last packet. If software
maintains a list of descriptors with the RS bit set, it can look at them to determine if all packets up to
(and including) the one with the RS bit set have been buffered in the output FIFO. Looking at the status
byte and checking the DD bit do this. If DD is set, the descriptor has been processed. Refer to the next
section for the layout of the status field.
Note: Descriptors with zero length transfer no data.
IFCS, when set, hardware appends the MAC FCS at the end of the packet. When cleared, software
should calculate the FCS for proper CRC check. There are several cases in which the hardware changes
the packet, and thus the software must set IFCS:
Transmitting a short packet while padding is enabled by the TCTL.PSP bit.
Checksum offload is enabled by the either the TXSM or IXSM bits in the TDESD.POPTS field.
VLAN header insertion enabled by the VLE bit in the TDESD.DCMD descriptor field when the
VMVIR[n].VLANA register field is 0.
TCP/UDP segmentation offload enabled by TSE bit in the TDESD.DCMD.
EOP indicates whether this is the last buffer for an incoming packet.
7.2.2.3.6 STA (4)
Rsv (bits 2-3) - Reserved
TS_STAT (bit 1) - DMA Timestamp is provided in the DMA Time Stamp field. It is enabled by the
1588_STAT_EN flag in the TQAVCTRL register.
DD (bit 0) - Descriptor Done
7.2.2.3.7 IDX (3)
Index into the hardware context table to indicate which context should be used for this request. If no
offload is required, this field is not relevant and no context needs to be initiated before the packet is
sent. See Table 7-32 for details on type of transmit packet offloads that require a context reference.
7.2.2.3.8 POPTS (6)
Reserved (bits 5:2)
TXSM (bit 1) - Insert L4 Checksum
IXSM (bit 0) - Insert IP Checksum
TXSM, when set to 1b, L4 checksum must be inserted. In this case, TUCMD.L4T in the context
descriptor indicates whether the checksum is TCP, UDP, or SCTP.
Table 7-37. Transmit Data (TDESD.POPTS) Layout
5 2 1 0
Reserved TXSM IXSM
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When DCMD.TSE in TDESD is set, TXSM must be set to 1b.
If this bit is set, the packet should at least contain a TCP header.
IXSM, when set to 1b, indicates that IP checksum must be inserted. For IPv6 packets this bit must be
cleared.
If the DCMD.TSE bit is set in data descriptor, and TUCMD.IPV4 is set in context descriptor, POPTS.IXSM
must be set to 1b as well.
If this bit is set, the packet should at least contain an IP header.
7.2.2.3.9 PAYLEN (18)
PAYLEN indicates the size (in byte units) of the data buffer(s) in host memory for transmission. In a
single send packet, PAYLEN defines the entire packet size fetched from host memory. It does not
include the fields that hardware adds such as: optional VLAN tagging, Ethernet CRC or Ethernet
padding. When TCP or UDP segmentation offload is enabled (DCMD.TSE is set), PAYLEN defines the
TCP/UDP payload size fetched from host memory.
Note: When a packet spreads over multiple descriptors, all the descriptor fields are only valid in the
first descriptor of the packet, except for RS, which is always checked, DTALEN that reflects
the size of the buffer in the current descriptor and EOP, which is always set at last descriptor
of the series.
7.2.2.4 Transmit Descriptor Ring Structure
The transmit descriptor ring structure is shown in Figure 7-10. A set of hardware registers maintains
each transmit descriptor ring in the host memory. New descriptors are added to the queue by software
by writing descriptors into the circular buffer memory region and moving the tail pointer associated
with that queue. The tail pointer points to one entry beyond the last hardware owned descriptor.
Transmission continues up to the descriptor where head equals tail at which point the queue is empty.
Descriptors passed to hardware should not be manipulated by software until the head pointer has
advanced past them.
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The shaded boxes in the figure represent descriptors that are not currently owned by hardware that
software can modify.
The transmit descriptor ring is described by the following registers:
Transmit Descriptor Base Address register (TDBA 0-3):
This register indicates the start address of the descriptor ring buffer in the host memory; this 64-bit
address is aligned on a 16-byte boundary and is stored in two consecutive 32-bit registers.
Hardware ignores the lower four bits.
Transmit Descriptor Length register (TDLEN 0-3):
This register determines the number of bytes allocated to the circular buffer. This value must be
zero modulo 128.
Transmit Descriptor Head register (TDH 0-3):
This register holds a value that is an offset from the base and indicates the in-progress descriptor.
There can be up to 64 KB descriptors in the circular buffer. Reading this register returns the value of
head corresponding to descriptors already loaded in the output FIFO. This register reflects the
internal head of the hardware write-back process including the descriptor in the posted write pipe
and might point further ahead than the last descriptor actually written back to the memory.
Transmit Descriptor Tail register (TDT 0-3):
This register holds a value, which is an offset from the base, and indicates the location beyond the
last descriptor hardware can process. This is the location where software writes the first new
descriptor.
The driver should not handle to the I210 descriptors that describe a partial packet. Consequently,
the number of descriptors used to describe a packet can not be larger than the ring size.
Figure 7-10. Transmit Descriptor Ring Structure
Circular Buffer
Head
Base + Size
Base
Transmit
Queue
Tail
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Tx Descriptor Completion Write–Back Address High/Low Registers (TDWBAH/TDWBAL 0-3):
These registers hold a value that can be used to enable operation of head write-back operation.
When TDWBAL.Head_WB_En is set and the RS bit is set in the Tx descriptor, following
corresponding data upload into packet buffer, the I210 writes the Transmit Descriptor Head value
for this queue to the 64 bit address specified by the TDWBAH and TDWBAL registers. The
Descriptor Head value is an offset from the base, and indicates the descriptor location hardware
processed and software can utilize for new Transmit packets. See Section 7.2.3 for additional
information.
The base register indicates the start of the circular descriptor queue and the length register indicates
the maximum size of the descriptor ring. The lower seven bits of length are hard wired to 0b. Byte
addresses within the descriptor buffer are computed as follows: address = base + (ptr * 16), where ptr
is the value in the hardware head or tail register.
The size chosen for the head and tail registers permit a maximum of 65536 (64 KB) descriptors, or
approximately 16 KB packets for the transmit queue given an average of four descriptors per packet.
Once activated, hardware fetches the descriptor indicated by the hardware head register. The hardware
tail register points one descriptor beyond the last valid descriptor. Software can read and detect which
packets have already been processed by hardware as follows:
Read the head register to determine which packets (those logically before the head) have been
transferred to the on-chip FIFO or transmitted. Note that this method is not recommended as races
between the internal update of the head register and the actual write-back of descriptors might
occur.
Read the value of the head as stored at the address pointed by the TDWBAH/TDWBAL pair.
Track the DD bits in the descriptor ring.
All the registers controlling the descriptor rings behavior should be set before transmit is enabled, apart
from the tail registers which are used during the regular flow of data.
Note: Software can determine if a packet has been sent by either of three methods: setting the RS
bit in the transmit descriptor command field or by performing a PIO read of the transmit head
register, or by reading the head value written by the I210 to the address pointed by the
TDWBAL and TDWBAH registers (see Section 7.2.3 for details). Checking the transmit
descriptor DD bit or head value in memory eliminates a potential race condition. All descriptor
data is written to the I/O bus prior to incrementing the head register, but a read of the head
register could pass the data write in systems performing I/O write buffering. Updates to
transmit descriptors use the same I/O write path and follow all data writes. Consequently,
they are not subject to the race.
In general, hardware prefetches packet data prior to transmission. Hardware typically updates the
value of the head pointer after storing data in the transmit FIFO.
7.2.2.5 Transmit Descriptor Fetching
When the TXDCTL[n].ENABLE bit is set and the on-chip descriptor cache is empty, a fetch happens as
soon as any descriptors are made available (Host increments the TDT[n] tail pointer). The descriptor
processing strategy for transmit descriptors is essentially the same as for receive descriptors except
that a different set of thresholds are used. The number of on-chip transmit descriptors per queue is 24.
When there is an on-chip descriptor buffer empty, a descriptor fetch happens as soon as any
descriptors are made available (host writes to the tail pointer). If several on-chip transmit descriptor
queues needs to fetch descriptors, descriptors from queues that are more starved are fetched. If a
number of queues have a starvation level, highest indexed queue is served first and so forth, down to
the lowest indexed queue.
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Note: The starvation level of a queue corresponds to the number of descriptors above the prefetch
threshold (TXDCTL[n].PTHRESH) that are already in the internal queue. The queue is more
starved if there are less descriptors in the internal transmit descriptor cache. Comparing
starvation level might be done roughly, not at the single descriptor level of resolution.
A queue is considered empty for the transmit descriptor fetch algorithm as long as:
There is still no complete packet (single or large send) in its corresponding internal queue.
There is no descriptor already in its way from system memory to the internal cache.
The internal corresponding internal descriptor cache is not full.
Each time a descriptor fetch request is sent for an empty queue, the maximum available number of
descriptor is requested, regardless of cache alignment issues.
When the on-chip buffer is nearly empty (below TXDCTL[n].PTHRESH), a prefetch is performed each
time enough valid descriptors (TXDCTL[n].HTHRESH) are available in host memory and no other DMA
activity of greater priority is pending (descriptor fetches and write-backs or packet data transfers).
When the number of descriptors in host memory is greater than the available on-chip descriptor
storage, the I210 might elect to perform a fetch that is not a multiple of cache-line size. Hardware
performs this non-aligned fetch if doing so results in the next descriptor fetch being aligned on a cache-
line boundary. This enables the descriptor fetch mechanism to be more efficient in the cases where it
has fallen behind software.
Note: The I210 NEVER fetches descriptors beyond the descriptor tail pointer.
7.2.2.6 Transmit Descriptor Write-Back
The descriptor write-back policy for transmit descriptors is similar to that of the receive descriptors
when the TXDCTL[n].WTHRESH value is not 0x0. In this case, all descriptors are written back
regardless of the value of their RS bit.
When the TXDCTL[n].WTHRESH value is 0x0, since transmit descriptor write-backs do not happen for
every descriptor, only transmit descriptors that have the RS bit set are written back.
Any descriptor write-back includes the full 16 bytes of the descriptor.
Since the benefit of delaying and then bursting transmit descriptor write-backs is small at best, it is
likely that the threshold is left at the default value (0x0) to force immediate write-back of transmit
descriptors with their RS bit set and to preserve backward compatibility.
Descriptors are written back in one of three cases:
TXDCTL[n].WTHRESH = 0x0 and a descriptor which has RS set is ready to be written back.
The corresponding EITR counter has reached zero.
Note: When a packet spreads over multiple descriptors, all the descriptor fields are only valid in the
first descriptor of the packet, except for RS, which is always checked, DTALEN that reflects
the size of the buffer in the current descriptor and EOP, which is always set at last descriptor
of the series.
7.2.2.7 Transmit Descriptor Ring Structure
TXDCTL[n].WTHRESH > 0x0 and TXDCTL[n].WTHRESH descriptors have accumulated.
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For the first condition, write-backs are immediate. This is the default operation and is backward
compatible with previous Intel Ethernet controllers.
The other two conditions are only valid if descriptor bursting is enabled (Section 8.12.15). In the
second condition, the EITR counter is used to force timely write-back of descriptors. The first packet
after timer initialization starts the timer. Timer expiration flushes any accumulated descriptors and sets
an interrupt event (TXDW).
For the last condition, if TXDCTL[n].WTHRESH descriptors are ready for write-back, the write-back is
performed.
An additional mode in which transmit descriptors are not written back at all and the head pointer of the
descriptor ring is written instead as described in Section 7.2.3.
Note: When transmit ring is smaller than internal cache size (24 descriptors) then at least one full
packet should be placed in the ring and TXDCTL[n].WTHRESH value should be less than ring
size. If TXDCTL[n].WTHRESH is 0x0 (transmit RS mode) then at least one descriptor should
have the RS bit set inside the ring.
7.2.3 Transmit Completions Head Write Back
In legacy hardware, transmit requests are completed by writing the DD bit to the transmit descriptor
ring. This causes cache thrash since both the software device driver and hardware are writing to the
descriptor ring in host memory. Instead of writing the DD bits to signal that a transmit request
completed, hardware can write the contents of the descriptor queue head to host memory. The
software device driver reads that memory location to determine which transmit requests are complete.
In order to improve the performance of this feature, the software device driver might program DCA
registers to configure which CPU is processing each TX queue to allow pre-fetching of the head write
back value from the right cache.
7.2.3.1 Description
The head counter is reflected in a memory location that is allocated by software, for each queue.
Head write back occurs if TDWBAL[n].Head_WB_En is set for this queue and the RS bit is set in the Tx
descriptor, following corresponding data upload into packet buffer. If the head write-back feature is
enabled, the I210 ignores TXDCTL[n].WTHRESH and takes in account only descriptors with the RS bit
set (as if the TXDCTL[n].WTHRESH field was set to 0x0). In addition, the head write-back occurs upon
EITR expiration for queues where the WB_on_EITR bit in TDWBAL[n] is set.
Software can also enable coalescing of the head write-back operations to reduce traffic on the PCIe bus,
by programming the TXDCTL.HWBTHRESH field to a value greater than zero. In this case, head write-
back operation occurs only after the internal pending write-back count is greater than the
TXDCTL[n].HWBTHRESH value.
The software device driver has control on this feature through Tx queue 0-3 head write-back address,
low (TDWBAL[n]) and high (TDWBAH[n]) registers thus supporting 64-bit address access. See registers
description in Section 8.12.16 and Section 8.12.17.
The 2 low register's LSB bits of the TDWBAL[n] register hold the control bits.
1. The Head_WB_En bit enables activation of the head write back feature. When
TDWBAL[n].Head_WB_En is set to 1 no TX descriptor write-back is executed for this queue.
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2. The WB_on_EITR bit enables head write upon EITR expiration. When Head write back operation is
enabled (TDWBAL[n].Head_WB_En = 1) setting the TDWBAL[n].WB_on_EITR bit to 1b enables
placing an upper limit on delay of head write-back operation.
The 30 upper bits of the TDWBAL[n] register hold the lowest 32 bits of the head write-back address,
assuming that the two last bits are zero. The TDWBAH[n] register holds the high part of the 64-bit
address.
Note: Hardware writes a full Dword when writing this value, so software should reserve enough
space for each head value.
If software enables Head Write-Back, it must also disable PCI Express Relaxed Ordering on
the write-back transactions. This is done by disabling bit 11 in the TXCTL register for each
active transmit queue. See Section 8.13.2.
The I210 might update the Head with values that are larger then the last Head pointer, which
holds a descriptor with the RS bit set; however, the value always points to a free descriptor
(descriptor that is not longer owned by the I210).
Note: Software should program TDWBAL[n], TDWBAH[n] registers when queue is disabled
(TXDCTL[n].Enable = 0).
7.2.4 TCP/UDP Segmentation
Hardware TCP segmentation is one of the offloading options supported by the Windows* and Linux*
TCP/IP stack. This is often referred to as TCP Segmentation Offloading or TSO. This feature enables the
TCP/IP stack to pass to the network device driver a message to be transmitted that is bigger than the
Maximum Transmission Unit (MTU) of medium. It is then the responsibility of the software device driver
and hardware to divide the TCP message into MTU size frames that have appropriate layer 2 (Ethernet),
3 (IP), and 4 (TCP) headers. These headers must include sequence number, checksum fields, options
and flag values as required. Note that some of these values (such as the checksum values) are unique
for each packet of the TCP message and other fields such as the source IP address are constant for all
packets associated with the TCP message.
The I210 supports also UDP segmentation for embedded applications, although this offload is not
supported by the regular Windows* and Linux* stacks. Any reference in this section to TCP
segmentation, should be considered as referring to both TCP and UDP segmentation.
Padding (TCTL.PSP) must be enabled in TCP segmentation mode, since the last frame might be shorter
than 60 bytes, resulting in a bad frame if PSP is disabled.
The offloading of these mechanisms from the software device driver to the I210 saves significant CPU
cycles. Note that the software device driver shares the additional tasks to support these options.
7.2.4.1 Assumptions
The following assumptions apply to the TCP segmentation implementation in the I210:
The RS bit operation is not changed.
Interrupts are set after data in buffers pointed to by individual descriptors is transferred (DMA'd) to
hardware.
7.2.4.2 Transmission Process
The transmission process for regular (non-TCP segmentation packets) involves:
The protocol stack receives from an application a block of data that is to be transmitted.
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The protocol stack calculates the number of packets required to transmit this block based on the
MTU size of the media and required packet headers.
For each packet of the data block:
Ethernet, IP and TCP/UDP headers are prepared by the stack.
The stack interfaces with the software device driver and commands it to send the individual packet.
The software device driver gets the frame and interfaces with the hardware.
The hardware reads the packet from host memory (via DMA transfers).
The software device driver returns ownership of the packet to the Network Operating System (NOS)
when hardware has completed the DMA transfer of the frame (indicated by an interrupt).
The transmission process for the I210 TCP segmentation offload implementation involves:
The protocol stack receives from an application a block of data that is to be transmitted.
The stack interfaces to the software device driver and passes the block down with the appropriate
header information.
The software device driver sets up the interface to the hardware (via descriptors) for the TCP
segmentation context.
Hardware DMA's (transfers) the packet data and performs the Ethernet packet segmentation and
transmission based on offset and payload length parameters in the TCP/IP context descriptor including:
Packet encapsulation
Header generation and field updates including IPv4, IPV6, and TCP/UDP checksum generation
The software device driver returns ownership of the block of data to the NOS when hardware has
completed the DMA transfer of the entire data block (indicated by an interrupt).
7.2.4.2.1 TCP Segmentation Data Fetch Control
To perform TCP Segmentation in the I210, the DMA must be able to fit at least one packet of the
segmented payload into available space in the on-chip Packet Buffer. The DMA does various
comparisons between the remaining payload and the Packet Buffer available space, fetching additional
payload and sending additional packets as space permits.
To support interleaving between descriptor queues at Ethernet frame resolution inside TSO requests,
the frame header pointed to by the so called header descriptors are reread from system memory by
hardware for every LSO segment. The I210 stores in an internal cache only the header’s descriptors
instead of the header’s content.
To limit the internal cache size software should not spread the L3/L4 header (TCP, UDP, IPV4 or IPV6)
on more than 4 descriptors. In the last header buffer it’s allowed to mix header and data. This limitation
stands for up to Layer4 header included, and for IPv4 or IPv6 indifferently.
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7.2.4.2.2 TCP Segmentation Write-Back Modes
Since the TCP segmentation mode uses the buffers that contains the L3/L4 header multiple times, there
are some limitations on the usage of different combinations of writeback and buffer release methods in
order to guarantee the header buffer’s availability until the entire packet is processed. These limitations
are listed in Table 7-38.
7.2.4.3 TCP Segmentation Performance
Performance improvements for a hardware implementation of TCP Segmentation off-load include:
The stack does not need to partition the block to fit the MTU size, saving CPU cycles.
The stack only computes one Ethernet, IP, and TCP header per segment, saving CPU cycles.
The Stack interfaces with the device driver only once per block transfer, instead of once per frame.
Larger PCIe bursts are used which improves bus efficiency (such as lowering transaction overhead).
Interrupts are easily reduced to one per TCP message instead of one per packet.
Fewer I/O accesses are required to command the hardware.
Table 7-38. Write Back Options For Large Send
WTHRESH RS HEAD Write
Back Enable Hardware Behavior Software Expected Behavior for TSO
packets.
0Set in EOP
descriptors
only Disable Hardware writes back
descriptors with RS bit set
one at a time.
Software can retake ownership of all
descriptors up to last descriptor with DD bit
set.
0Set in any
descriptors Disable Hardware writes back
descriptors with RS bit set
one at a time.
Software can retake ownership of entire
packets (EOP bit set) up to last descriptor with
DD bit set.
0 Not set at all Disable Hardware does not write
back any descriptor (since
RS bit is not set)
Software should poll the TDH register. The
TDH register reflects the last descriptor that
software can take ownership of.1
1. Note that polling of the TDH register is a valid method only when the RS bit is never set, otherwise race conditions between
software and hardware accesses to the descriptor ring can occur.
0 Not set at all Enable
Hardware writes back the
head pointer only at EITR
expire event reflecting the
last descriptor that software
can take ownership of.
Software might poll the TDH register or use
the head value written back at EITR expire
event.
The TDH register reflects the last descriptor
that software can take ownership of.
>0 Don't care Disable Hardware writes back all the
descriptors in bursts and set
all the DD bits.
Software can retake ownership of entire
packets up to last descriptor with both DD and
EOP bits set.
Note: The TDH register reflects the last
descriptor that software can take ownership
of1.
Don't care Set in EOP
descriptors
only Enable Hardware writes back the
Head pointer per each
descriptor with RS bit set.2
2. At EITR expire event, the Hardware writes back the head pointer reflecting the last descriptor that software can take ownership of.
Software can retake ownership of all
descriptors up to the descriptor pointed by the
head pointer read from system memory (by
interrupt or polling).
Don't care Set in any
descriptors Enable Hardware writes back the
Head pointer per each
descriptor with RS bit set.
This mode is illegal since software won't
access the descriptor, it cannot tell when the
pointer passed the EOP descriptor.
Inline Functions—Ethernet Controller I210
305
7.2.4.4 Packet Format
Typical TCP/IP transmit window size is 8760 bytes (about 6 full size frames). Today the average size on
corporate Intranets is 12-14 KB, and normally the maximum window size allowed is 64KB (unless
Windows Scaling - RFC 1323 is used). A TCP message can be as large as 256 KB and is generally
fragmented across multiple pages in host memory. The I210 partitions the data packet into standard
Ethernet frames prior to transmission according to the requested MSS. The I210 supports calculating
the Ethernet, IP, TCP, and UDP headers, including checksum, on a frame-by-frame basis.
Frame formats supported by the I210 include:
Ethernet 802.3
IEEE 802.1Q VLAN (Ethernet 802.3ac)
Ethernet Type 2
Ethernet SNAP
IPv4 headers with options
IPv6 headers with extensions
TCP with options
UDP with options.
VLAN tag insertion might be handled by hardware
Note: UDP (unlike TCP) is not a “reliable protocol”, and fragmentation is not supported at the UDP
level. UDP messages that are larger than the MTU size of the given network medium are
normally fragmented at the IP layer. This is different from TCP, where large TCP messages can
be fragmented at either the IP or TCP layers depending on the software implementation. The
I210 has the ability to segment UDP traffic (in addition to TCP traffic), however, because UDP
packets are generally fragmented at the IP layer, the I210's “TCP Segmentation” feature is
not normally useful to handle UDP traffic.
7.2.4.5 TCP/UDP Segmentation Indication
Software indicates a TCP/UDP Segmentation transmission context to the hardware by setting up a TCP/
IP Context Transmit Descriptor (see Section 7.2.2). The purpose of this descriptor is to provide
information to the hardware to be used during the TCP segmentation off-load process.
Setting the TSE bit in the TDESD.DCMD field to 1b indicates that this descriptor refers to the TCP
Segmentation context (as opposed to the normal checksum off loading context). This causes the
checksum off loading, packet length, header length, and maximum segment size parameters to be
loaded from the Context descriptor into the device.
Table 7-39. TCP/IP or UDP/IP Packet Format Sent by Host
L2/L3/L4 Header Data
Ethernet IPv4/IPv6 TCP/UDP DATA (full TCP message)
Table 7-40. TCP/IP or UDP/IP Packet Format Sent by the I210
L2/L3/L4 Header
(updated) Data (first
MSS) FCS ... L2/L3/L4
Header
(updated)
Data (Next
MSS) FCS ...
Ethernet Controller I210 —Inline Functions
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The TCP Segmentation prototype header is taken from the packet data itself. Software must identity
the type of packet that is being sent (IPv4/IPv6, TCP/UDP, other), calculate appropriate checksum off
loading values for the desired checksum, and calculate the length of the header which is pre-appended.
The header might be up to 240 bytes in length.
Once the TCP Segmentation context has been set, the next descriptor provides the initial data to
transfer. This first descriptor(s) must point to a packet of the type indicated. Furthermore, the data it
points to might need to be modified by software as it serves as the prototype header for all packets
within the TCP Segmentation context. The following sections describe the supported packet types and
the various updates which are performed by hardware. This should be used as a guide to determine
what must be modified in the original packet header to make it a suitable prototype header.
The following summarizes the fields considered by the driver for modification in constructing the
prototype header.
IP Header
For IPv4 headers:
Identification Field should be set as appropriate for first packet to be sent
Header Checksum should be zeroed out unless some adjustment is needed by the driver
TCP Header
Sequence Number should be set as appropriate for first packet of send (if not already)
PSH, and FIN flags should be set as appropriate for LAST packet of send
TCP Checksum should be set to the partial pseudo-header sum as follows (there is a more detailed
discussion of this is Section 7.2.4.6):
UDP Header
Checksum should be set as in TCP header, above
The following sections describe the updating process performed by the hardware for each frame sent
using the TCP Segmentation capability.
Table 7-41. TCP Partial Pseudo-Header Sum for IPv4
IP Source Address
IP Destination Address
Zero Layer 4 Protocol ID Zero
Table 7-42. TCP Partial Pseudo-Header Sum for IPv6
IPv6 Source Address
IPv6 Final Destination Address
Zero
Zero Next Header
Inline Functions—Ethernet Controller I210
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7.2.4.6 Transmit Checksum Offloading with TCP/UDP Segmentation
The I210 supports checksum off-loading as a component of the TCP Segmentation off-load feature and
as a standalone capability. Section 7.2.5 describes the interface for controlling the checksum off-
loading feature. This section describes the feature as it relates to TCP Segmentation.
The I210 supports IP and TCP header options in the checksum computation for packets that are derived
from the TCP Segmentation feature.
Note: The I210 is capable of computing one level of IP header checksum and one TCP/UDP header
and payload checksum. In case of multiple IP headers, the driver needs to compute all but
one IP header checksum. The I210 calculates check sums on the fly on a frame-by-frame
basis and inserts the result in the IP/TCP/UDP headers of each frame. TCP and UDP checksum
are a result of performing the checksum on all bytes of the payload and the pseudo header.
Two specific types of checksum are supported by the hardware in the context of the TCP Segmentation
off-load feature:
IPv4 checksum
TCP checksum
See Section 7.2.5 for description of checksum off loading of a single-send packet.
Each packet that is sent via the TCP segmentation off-load feature optionally includes the IPv4
checksum and either the TCP checksum.
All checksum calculations use a 16-bit wide one's complement checksum. The checksum word is
calculated on the outgoing data.
Table 7-44lists the conditions of when checksum off loading can/should be calculated.
Table 7-43. Supported Transmit Checksum Capabilities
Packet Type Hardware IP Checksum
Calculation
Hardware TCP/UDP Checksum
Calculation
IP v4 packets Yes Yes
IP v6 packets
(no IP checksum in IPv6) NA Yes
Packet is greater than 1518, 1522 or 1526 bytes;
(LPE=1b)1
1. Depends on number of VLAN tags.
Yes Yes
Packet has 802.3ac tag Yes Yes
Packet has IP options
(IP header is longer than 20 bytes) Yes Yes
Packet has TCP or UDP options Yes Yes
IP header’s protocol field contains a protocol # other
than TCP or UDP. Yes No
Table 7-44. Conditions for Checksum Offloading
Packet Type IPv4 TCP/UDP Reason
Non TSO Yes No IP Raw packet (non TCP/UDP protocol)
Ethernet Controller I210 —Inline Functions
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7.2.4.7 TCP/UDP/IP Headers Update
IP/TCP or IP/UDP header is updated for each outgoing frame based on the IP/TCP header prototype
which hardware DMA's from the first descriptor(s). The checksum fields and other header information
are later updated on a frame-by-frame basis. The updating process is performed concurrently with the
packet data fetch.
The following sections define what fields are modified by hardware during the TCP Segmentation
process by the I210.
Note: Placing incorrect values in the Context descriptors might cause failure of Large Send. The
indication of Large Send failure can be checked in the TSCTC statistics register.
7.2.4.7.1 TCP/UDP/IP Headers for the First Frames
The hardware makes the following changes to the headers of the first packet that is derived from each
TCP segmentation context.
MAC Header (for SNAP)
Type/Len field = MSS + MACLEN + IPLEN + L4LEN - 14 - 4 (if VLAN added by Software)
IPv4 Header
IP Identification: Value in the IPv4 header of the prototype header in the packet data itself
IP Total Length = MSS + L4LEN + IPLEN
IP Checksum
IPv6 Header
Payload Length = MSS + L4LEN + IPV6_HDR_extension1
TCP Header
Sequence Number: The value is the Sequence Number of the first TCP byte in this frame.
The flag values of the first frame are set by ANDing the flag word in the pseudo header with the
DTXTCPFLGL.TCP_flg_first_seg register field. The default value of the
DTXTCPFLGL.TCP_flg_first_seg are set so that the FIN flag and the PSH flag are cleared in the first
frame.
TCP Checksum
UDP Header
UDP Length = MSS + L4LEN
UDP Checksum
Yes Yes TCP segment or UDP datagram with checksum off-load
No No Non-IP packet or checksum not offloaded
TSO Yes Yes For TSO, checksum off-load must be done
1. IPV6_HDR_extension is calculated as IPLEN - 40 bytes.
Table 7-44. Conditions for Checksum Offloading
Inline Functions—Ethernet Controller I210
309
7.2.4.7.2 TCP/UDP/IP Headers for the Subsequent Frames
The hardware makes the following changes to the headers for subsequent packets that are derived as
part of a TCP segmentation context:
Number of bytes left for transmission = PAYLEN - (N * MSS). Where N is the number of frames that
have been transmitted.
MAC Header (for SNAP Packets)
Type/Len field = MSS + MACLEN + IPLEN + L4LEN - 14 - 4 (if VLAN added by Software)
IPv4 Header
IP Identification: incremented from last value (wrap around based on 16 bit-width)
IP Total Length = MSS + L4LEN + IPLEN
IP Checksum
IPv6 Header
Payload Length = MSS + L4LEN + IPV6_HDR_extension1
TCP Header
Sequence Number update: Add previous TCP payload size to the previous sequence number value.
This is equivalent to adding the MSS to the previous sequence number.
The flag values of the subsequent frames are set by ANDing the flag word in the pseudo header
with the DTXTCPFLGL.TCP_Flg_mid_seg register field. The default value of the
DTXTCPFLGL.TCP_Flg_mid_seg are set so that if the FIN flag and the PSH flag are cleared in these
frames.
TCP Checksum
UDP Header
UDP Length = MSS + L4LEN
UDP Checksum
7.2.4.7.3 TCP/UDP/IP Headers for the Last Frame
The hardware makes the following changes to the headers for the last frame of a TCP segmentation
context:
Last frame payload bytes = PAYLEN - (N * MSS)
MAC Header (for SNAP Packets)
Type/Len field = Last frame payload bytes + MACLEN + IPLEN + L4LEN - 14 - 4 (if VLAN added by
Software)
IPv4 Header
IP Total Length = last frame payload bytes + L4LEN + IPLEN
IP Identification: incremented from last value (wrap around based on 16 bit-width)
IP Checksum
1. IPV6_HDR_extension is calculated as IPLEN - 40 bytes.
Ethernet Controller I210 —Inline Functions
310
IPv6 Header
Payload Length = last frame payload bytes + L4LEN + IPV6_HDR_extension1
TCP Header
Sequence Number update: Add previous TCP payload size to the previous sequence number value.
This is equivalent to adding the MSS to the previous sequence number.
The flag values of the last frames are set by ANDing the flag word in the pseudo header with the
DTXTCPFLGH.TCP_Flg_lst_seg register field. The default value of the DTXTCPFLGH.TCP_Flg_lst_seg
are set so that if the FIN flag and the PSH flag are set in the last frame.
TCP Checksum
UDP Header
UDP Length = Last frame payload bytes + L4LEN
UDP Checksum
7.2.4.8 Data Flow
The flow used by the I210 to do TCP segmentation is as follows:
1. Get a descriptor with a request for a TSO off-load of a TCP packet.
2. First Segment processing:
a. Fetch all the buffers containing the header as calculated by the MACLEN, IPLEN and L4LEN fields.
Save the addresses and lengths of the buffers containing the header (up to 4 buffers). The
header content is not saved.
b. Fetch data up to the MSS from subsequent buffers & calculate the adequate checksum(s).
c. Update the Header accordingly and update internal state of the packet (next data to fetch and
TCP SN).
d. Send the packet to the network.
e. If total packet was sent, go to step 4. else continue.
3. Next segments
a. Wait for next arbitration of this queue.
b. Fetch all the buffers containing the header from the saved addresses. Subsequent reads of the
header might be done with a no snoop attribute.
c. Fetch data up to the MSS or end of packet from subsequent buffers & calculate the adequate
checksum(s).
d. Update the Header accordingly and update internal state of the packet (next data to fetch and
TCP SN).
e. If total packet was sent, request is done, else restart from step 3.
4. Release all buffers (update head pointer).
Note: Descriptors are fetched in a parallel process according to the consumption of the buffers.
7.2.5 Checksum Offloading in Non-Segmentation Mode
The previous section on TCP Segmentation off-load describes the IP/TCP/UDP checksum off loading
mechanism used in conjunction with TCP Segmentation. The same underlying mechanism can also be
applied as a standalone feature. The main difference in normal packet mode (non-TCP Segmentation) is
that only the checksum fields in the IP/TCP/UDP headers need to be updated.
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311
Before taking advantage of the I210's enhanced checksum off-load capability, a checksum context
must be initialized. For the normal transmit checksum off-load feature this is performed by providing
the device with a Descriptor with TSE = 0b in the TDESD.DCMD field and setting either the TXSM or
IXSM bits in the TDESD.POPTS field. Setting TSE = 0b indicates that the normal checksum context is
being set, as opposed to the segmentation context. For additional details on contexts, refer to
Section 7.2.2.4.
Note: Enabling the checksum off loading capability without first initializing the appropriate
checksum context leads to unpredictable results. CRC appending (TDESC.CMD.IFCS) must be
enabled in TCP/IP checksum mode, since CRC must be inserted by hardware after the
checksum has been calculated.
As mentioned in Section 7.2.2, it is not necessary to set a new context for each new packet. In many
cases, the same checksum context can be used for a majority of the packet stream. In this case, some
performance can be gained by only changing the context on an as needed basis or electing to use the
off-load feature only for a particular traffic type, thereby avoiding the need to read all context
descriptors except for the initial one.
Each checksum operates independently. Insertion of the IP and TCP checksum for each packet are
enabled through the Transmit Data Descriptor POPTS.TSXM and POPTS.IXSM fields, respectively.
7.2.5.1 IP Checksum
Three fields in the Transmit Context Descriptor (TDESC) set the context of the IP checksum off loading
feature:
TUCMD.IPv4
IPLEN
MACLEN
TUCMD.IPv4 = 1b specifies that the packet type for this context is IPv4, and that the IP header
checksum should be inserted. TUCMD.IPv4 = 0b indicates that the packet type is IPv6 (or some other
protocol) and that the IP header checksum should not be inserted.
MACLEN specifies the byte offset from the start of the DMA'd data to the first byte to be included in the
checksum, the start of the IP header. The minimal allowed value for this field is 12. Note that the
maximum value for this field is 127. This is adequate for typical applications.
Note: The MACLEN + IPLEN value needs to be less than the total DMA length for a packet. If this is
not the case, the results are unpredictable.
IPLEN specifies the IP header length. Maximum allowed value for this field is 511 Bytes.
MACLEN + IPLEN specify where the IP checksum should stop. This is limited to the first 127 + 511
bytes of the packet and must be less than or equal to the total length of a given packet. If this is not
the case, the result is unpredictable.
The 16-bit IPv4 Header Checksum is placed at the two bytes starting at MACLEN + 10.
As mentioned in Section 7.2.2.2, Transmit Contexts, it is not necessary to set a new context for each
new packet. In many cases, the same checksum context can be used for a majority of the packet
stream. In this case, some performance can be gained by only changing the context on an as needed
basis or electing to use the off-load feature only for a particular traffic type, thereby avoiding all context
descriptor reads except for the initial one.
Ethernet Controller I210 —Inline Functions
312
7.2.5.2 TCP/UDP Checksum
Three fields in the Transmit Context Descriptor (TDESC) set the context of the TCP/UDP checksum off
loading feature:
MACLEN
IPLEN
TUCMD.L4T
TUCMD.L4T = 01b specifies that the packet type is TCP, and that the 16-bit TCP header checksum
should be inserted at byte offset MACLEN + IPLEN +16. TUCMD.L4T = 00b indicates that the packet is
UDP and that the 16-bit checksum should be inserted starting at byte offset MACLEN + IPLEN + 6.
IPLEN + MACLEN specifies the byte offset from the start of the DMA'd data to the first byte to be
included in the checksum, the start of the TCP header. The minimal allowed value for this sum is 32/42
for UDP or TCP respectively.
Note: The IPLEN + MACLEN + L4LEN value needs to be less than the total DMA length for a packet.
If this is not the case, the results are unpredictable.
The TCP/UDP checksum always continues to the last byte of the DMA data.
Note: For non-TSO, software still needs to calculate a full checksum for the TCP/UDP pseudo-
header. This checksum of the pseudo-header should be placed in the packet data buffer at the
appropriate offset for the checksum calculation.
7.2.5.3 SCTP CRC Offloading
For SCTP packets, a CRC32 checksum offload is provided.
Three fields in the Transmit Context Descriptor (TDESC) set the context of the STCP checksum off
loading feature:
MACLEN
IPLEN
TUCMD.L4T
TUCMD.L4T = 10b specifies that the packet type is SCTP, and that the 32-bit STCP CRC should be
inserted at byte offset MACLEN + IPLEN + 8.
IPLEN + MACLEN specifies the byte offset from the start of the DMA'd data to the first byte to be
included in the checksum, the start of the STCP header. The minimal allowed value for this sum is 26.
The SCTP CRC calculation always continues to the last byte of the DMA data.
The SCTP total L3 payload size (TDESCD.PAYLEN - IPLEN - MACLEN) should be a multiple of 4 bytes
(SCTP padding not supported).
Notes:
1. TSO is not available for SCTP packets.
2. The CRC field of the SCTP header must be set to zero prior to requesting a CRC calculation offload.
7.2.5.4 Checksum Supported Per Packet Types
Table 7-45 lists which checksum is supported per packet type.
Inline Functions—Ethernet Controller I210
313
Note: TSO is not supported for packet types for which IP checksum and TCP checksum can not be
calculated.
7.2.6 Multiple Transmit Queues
The number of transmit queues is 4, to support Qav functionality or to support load balancing between
CPUs.
If there are more CPUs cores than queues, then one queue might be used to service more than one
CPU.
For transmission process, each thread might place a queue in the host memory of the CPU it is tied to.
The I210 supports assigning either high or low priority to each transmit queue. High priority is assigned
to by setting the TXDCTL[n].priority bit to 1b. When high priority is assigned to a specific transmit
queue, the I210 always prioritizes transmit data fetch DMA accesses, before servicing transmit data
fetch of lower priority transmit queues. The Audio/Video Bridging (AVB) mechanism described in
Section 7.2.7 provides another arbitration mechanisms between the queues.
Note: Throughput of low priority transmit queues can be significantly impacted if high priority
queues utilize the DMA resources fully.
Table 7-45. Checksum Per Packet Type
Packet Type Hardware IP Checksum
Calculation
Hardware TCP/UDP/SCTP
Checksum Calculation
IPv4 packets Yes Yes
IPv6 packets No (n/a) Yes
IPv6 packet with next header options:
Hop-by-Hop options
Destinations options
Routing (w len 0b)
Routing (w len >0b)
Fragment
Home option
No (n/a)
No (n/a)
No (n/a)
No (n/a)
No (n/a)
No (n/a)
Yes
Yes
Yes
No
No
No
IPv4 tunnels:
IPv4 packet in an IPv4 tunnel
IPv6 packet in an IPv4 tunnel
Either IP or TCP/SCTP1
Either IP or TCP/SCTP1
Either IP or TCP/SCTP 1
Either IP or TCP/SCTP1
1. For the tunneled case, the driver might do only the TCP checksum or IPv4 checksum. If TCP checksum is desired, the driver should
define the IP header length as the combined length of both IP headers in the packet. If an IPv4 checksum is required, the IP header
length should be set to the IPv4 header length.
IPv6 tunnels:
IPv4 packet in an IPv6 tunnel
IPv6 packet in an IPv6 tunnel
No
No
Yes
Yes
Packet is an IPv4 fragment Yes No
Packet is greater than 1518, 1522 or 1526 bytes;
(LPE=1b)2
2. Depends on number of VLAN tags.
Yes Yes
Packet has 802.3ac tag Yes Yes
Packet has TCP or UDP options Yes Yes
IP header’s protocol field contains protocol # other
than TCP or UDP. Yes No
Ethernet Controller I210 —Inline Functions
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7.2.7 Handling Time Sensitive Streams (802.1Qav)
7.2.7.1 Overview
The 802.1Qav is part of the AVB specifications that include Timing and Synchronization for time specific
applications (802.1AS), Stream Reservation (SR) protocol to guarantee the resources needed for
Audio/Video (AV) streams (802.1Qat), Forwarding and queuing enhancements for time sensitive
streams (802.1Qav).
802.1Qav provides a way to guarantee bounded latency and latency variation for time sensitive traffic
as AV. It specifies the priority usage and controlled bandwidth draining algorithms.
Note that when supporting Time Sensitive Streams, EEE should not be enabled (by the EEER register)
due to potential distortions of the time sensitive traffic scheduling.
7.2.7.2 I210 Transmit Modes
The I210 supports two transmit modes, legacy and Qav. The transmit mode is configured in
TQAVCTRL.QavMode register and must be set during the SW initialization cycle. The I210 transmit
mode cannot change during dynamic operation.
The I210 Legacy transmit is defined in Section 7.2. The rest of this sub chapter defines the I210
transmit functionality when configured to operate at Qav mode.
Note: When configured to Qav mode enabling the transmit short packet padding feature and
sending packets shorter than 64 bytes has some impact to the correctness of the credit
shaper arbitration as the arbitration is done based on the non padded transmit packet length.
7.2.7.3 Transmit Architecture in Qav Mode
To enable the proper priority and bandwidth allocation to the time sensitive streams the I210 transmit
architecture includes up to four transmit packet buffers, the transmit traffic is distributed between the
packet buffers based on the packet priority. The I210 software device driver directs the outgoing
packets to the relevant priority packet buffers by submitting them per priority to the proper descriptor
queues.
Legacy Qav
Packet Buffer Single transmit packet buffer Four transmit packet buffers
Queues
Four transmit queues
All enabled queues are associated to the single
transmit packet buffer
Four transmit queues
Each enabled queue is associated with a dedicated
transmit packet buffer
Data fetch arbitration Round robin between the queues Combination of time based and most empty packet
buffer
Data transmit
arbitration None - single packet buffer - first in first out Combination of time based and credit shaper for the
SR queues and strict priority for the BE queues
Inline Functions—Ethernet Controller I210
315
7.2.7.4 Mapping User Priorities to Queues
While in Qav mode each active queue in the I210 represents a single or multiple User Priorities, The
queue priority is pre-assigned such that queue0 has the highest priority and priorities decrease through
queue1, queue2 and queue3 has the lowest priority.
Software is responsible to map the proper Ethernet traffic using the appropriate stream priority to its
hardware destination queue according to the relevant priority it is assigned.
Traffic priority can be assigned according to the VLAN priority field in the VLAN tag.
Figure 7-11. Transmit Architecture Qav Mode
Queue 0 Queue 1 Queue 2 Queue 3
Head
Tail
Head
Tail
Head
Tail
Head
Tail
Fetch
Arbiter
Read
Request
Packet
Buffers
Transmit
MAC
Launch
Arbiter
Read
Completion
DMA
Clock
Clock
Manageability
Traffic
Round
Robin
Transmit
Data Buffers
in host
Memory
Packet
Buffers
Packet
Buffer 0
Ethernet Controller I210 —Inline Functions
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7.2.7.5 Transmission Selection
Transmission selection is the process of selecting the next packet to transmit, in the I210 Qav modes
transmission selection includes three levels of arbitration - descriptor fetch, data fetch and data
transmission.
Descriptor fetch - the transmit descriptor fetch mechanism while in Qav modes is the same as in legacy
mode, the complete description of descriptor fetch is described in Section 7.2.2.5.
Data fetch - the data fetch mechanism while in Qav modes are based on two elements time based and
queue arbitration based on round robin or most empty goes first controlled
byTQAVCTRL.DataFetchARB. A queue is eligible for arbitrations only if it has descriptors pointing to at
least a single packet in host memory. For SR queues with the time based element enabled a queue is
only eligible for arbitration if the fetch time of the up coming packet has been reached. See
Section 7.2.7.5.3 for more details on how to determine if the fetch time has been reached.
When configured to most empty the queue that wins the arbitration is the queue that is targeted to the
most empty packet buffer, for the cases where some packet buffers have the same amount of data
(startup for example) arbitration between these queues are done according to the queue priority
(higher priority goes first).
Data transmission - transmission arbitration flow is described as follows and illustrated in Figure 7-12,
“Data Transmission Arbitration Operation for TransmitMode = Qav” on page 318.
In non Qav mode (TQAVCTRL.TransmitMode = 0b) Arbitration starts from the highest priority queue
(index 0) and up to the lowest priority queue (index 3).
In Qav mode (TQAVCTRL.TransmitMode = 1b) Arbitration starts from the highest priority queue
(index 0) and up to the lowest priority queue (index 3) with the following additions:
Strict reservation queues (indicated as SR queues or Qav queues) are subjected to credit based
shaper criteria (if enabled by the TQAVCTRL.DataTranARB parameter). See credit calculation in
Section 7.2.7.5.2.
Transmission time base criteria (if enabled by the TQAVCTRL.DataTranTIM parameter). See
launch time calculation in Section 7.2.7.5.3.
Any arbitration step is made for a single packet from the selected queue:
If a packet is transmitted, hardware then looks for the next packet to be transmitted from the
highest priority queue (index 0).
If a packet was not transmitted, hardware then looks for the next packet to be transmitted from
the next queue inline.
Note: When in Qav mode, queue0 must be configured as an SR queue, queue1 can be configured as
an SR queue or priority queue and queue2, queue3 is configured by default as a priority
queue with no ability to be configured as SR queues.
Note: the launch time of a packet is specified in the context descriptor. Every SR packet should be
defined using a single context descriptor provided before the packet advanced data
descriptors (legacy descriptors are not supported in Qav mode).
7.2.7.5.1 Data Transmission Arbitration Algorithm
Definition and description of parameters
Priority (QN - Queue number), the I210 in Qav mode implements up to 4 priorities defined by the actual
queue used, see Section 7.2.7.4 for the way priorities are mapped to queues
Inline Functions—Ethernet Controller I210
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Credits - Regulates the bandwidth allocation to user priorities, credits represent a single byte. The
transmission of a queue in SR mode is defined by the amount of credits assigned to that queue
QueueFrames - Each queue has an indication whether there are queued frames for that queue
Launch Time - Defines the time to launch the packet for time based arbitration
Mode - While in Qav mode each queue is configured to be either in priority mode or SR mode
Table 7-46 lists the arbitration modes as controlled by the TQAVCTRL register followed by a flow
diagram that illustrates the arbitration scheme for Qav mode.
Table 7-46. Transmission Arbitration
TransmitMode DataTranARB DataTranTIM Functionality
0 (Legacy) X X Single packet buffer for all 4 queues. Packets are transmitted
at the same order they are fetched from host memory.
1 (Qav) 0 (Strict Priority) 0 Strict priority queuing without any scheduling.
1 (Qav) 0 (Strict Priority) 1 (Launch Time) Strict priority queuing while SR queues are subjected to
launch time policy.
1 (Qav) 1 (Credit Shaper) 0 Strict priority queuing while SR queues are subjected to Credit
Shaper policy.
1 (Qav) 1 (Credit Shaper) 1 (Launch Time) Strict priority queuing while SR queues are subjected to Credit
Shaper policy plus launch time.
Ethernet Controller I210 —Inline Functions
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7.2.7.5.2 Data Transmission Credit Calculation
Definition and description of parameters
IdleSlope - The Idle slop of an SR queue defines the amount of credit accumulation (per byte) while the
queue is blocked from transmission
SendSlope - The Send slop of an SR queue defines the amount of credit consumption (per byte) and is
calculated by the formula SendSlope = IdleSlope - LinkRate
HiCredit - The HiCredit of an SR queue defines the maximum credit accumulation for that queue
Credit calculation pseudo code:
For each Q[i]
If Transmit
Credit = Credit – SendSlope
If !Transmit
If Q[i]QuFrm = 0
Credit = 0
Else If Credit + IdleSlope > HiCredit
Credit = HiCredit
Figure 7-12. Data Transmission Arbitration Operation for TransmitMode = Qav
Start
QN = 0
Q[QN].QueueFrames > 0
?
QN = QN + 1
QN > 3
?
No
Yes
No
Yes
Q[QN].Mode = ?
SP SR
[Q[QN].LnchTime reached
or (DataTranTIM =0)] &&
[(Q[QN].Credits >= Zero)
or (DataTranARB=0)]
?
No
Yes
Send a Packet
from Q[QN]
SP_WAIT_SR &&
Q[0,1].LnchTime minus
MAX_TPKT_SIZE
reached
?
Yes
No
(Qav)
(Best
Effort)
Inline Functions—Ethernet Controller I210
319
Else Credit = Credit + IdleSlope
Note: During QavMode TIPG register value should not be modified from its default value of total 12
bytes IPG between packets.
7.2.7.5.3 Launch Time/Fetch Time Decision
Launch time and Fetch time criteria is defined to be “pass” if either:
The Launch time/Fetch time match exactly the relevant portion of SYSTIML value
It is compared against SYSTIML[29:5], and provides transmission granularity of 0.032 µs
The time passed from (post) Launch time/Fetch time in the SYSTIML is within the allowed Launch
time/Fetch time criteria
The Allowed Fetch time and Allowed Launch time should be calculated such that it is allowed to
Fetch/Transmit a packet if the current time is within Fetch/Launch time + 0.5 second.
Note that the SYSTIML register max value is 999,999,999 dec (0x3B9AC9FF) and it wraps to 0
when reaching this value (representing a full second).
7.2.7.6 Qav Latency
The latency between transmission scheduling (either credit base or launch time) and the time the
packet is transmitted to the network is listed in Table 7-62.
7.2.7.7 Qav Configuration
Context Descriptor Configuration
LaunchTime (25 bits (56:32) based on SYSTIM)
Global Qav configuration:
TXPBSIZE.Tx0pbsize/Tx1pbsize/Tx2pbsize/Tx3pbsize (Tx packet buffer size assignment)
Recommended configuration is 8KB for PB0, PB1 and 4KB for PB2, PB3
RXPBSIZE.Rxpbsize (Rx packet buffer size assignment)
To comply with the Tx recommendation above need to set to 0x20 (32 KB). Refer to the setting rule
defined in Section 4.5.9.
DTXMXPKTSZ.MAX_TPKT_SIZE (DMA Tx maximum packet size)
Table 7-47. Packet Scheduling to its Transmission Latency
Link Speed
Latency between launch time and packet in the MAC (the time on which packet 1588
time stamping is taken). For a complete delay from between launch time and SFD on
the PHY MDI pins, please add the latency defined in Table 7-62 (delay between packet
timestamp and SFD on the MDI pins)
Min Max Comments
Transmit at 10 Mb/s Not measured Assume no interfering
transmission (see also
SP_WAIT_SR setting).
The min/max values represent
possible jitter.
In case of no concurrent
receive, the jitter is reduced by
16 ns.
Transmit at 100 Mb/s 1.184 µs1.360 µs
Transmit at 1 Gb/s 288 ns 304 ns
Ethernet Controller I210 —Inline Functions
320
TQAVCTRL.TransmitMode (Transmit mode configuration: legacy, Qav)
TQAVCTRL.DataFetchArb (Data fetch arbitration configuration: Round Robin, Most empty)
TXDCTL.Priority can be use to prioritize SR queues over SP queues
TQAVCTRL.DataTranArb (Data Transmit arbitration configuration: Strict Priority, Credit Shaper
Algorithm)
TQAVCTRL.DataTrantim (Data Transmit Time Valid configuration - controls time based transmission)
TQAVCTLRL.FetchTimDelta (Fetch Time Delta configuration - the time to reduce from Launch time to
make a SR queue packet eligible for fetch)
Per Queue (0/1) Qav configuration:
TQAVCC.QueueMode (Queue mode configuration: SR, SP)
TQAVCC.IdleSlope (Idle slope configuration credits)
IdleSlope Configuration is calculated using the following equation:
100Mbps: BW*0x7735*0.2
1000Mbps: BW*0x7735*2
BW is the percentage BW out of full line rate.
TQAVHC.HiCredit (Maximum number of credits that can be accumulated per queue)
LinkRate (Not configured and always defaults to 0x7735 credits)
ZeroCredit (not configured and always defaults to 0x80000000)
SW calculations of credit limits for proper setting:
SR0 (Queue0):
HiCredit = 0x80000000 + MAX_TPKT_SIZE*Idle_BW[Queue0]*0x7735
SR1 (Queue1):
HiCredit = Max{(0x80000000 + 2*MAX_TPKT_SIZE*Idle_BW[Queue1]*0x7735),(0x80000000 +
((Idle_BW[Queue0]/Send_BW[Queue0])*MaxFameSize +
MAX_TPKT_SIZE)*Idle_BW[Queue1]*0x7735)}
7.3 Interrupts
7.3.1 Interrupt Modes
The I210 supports the following interrupt modes:
PCI legacy interrupts or MSI - selected when GPIE.Multiple_MSIX is 0b
MSI-X when GPIE.Multiple_MSIX is 1b.
Inline Functions—Ethernet Controller I210
321
7.3.1.1 MSI-X and Vectors
MSI-X defines a separate optional extension to basic MSI functionality. Compared to MSI, MSI-X
supports a larger maximum number of vectors, the ability for software to control aliasing when fewer
vectors are allocated than requested, plus the ability for each vector to use an independent address and
data value, specified by a table that resides in Memory Space. However, most of the other
characteristics of MSI-X are identical to those of MSI. For more information on MSI-X, refer to the PCI
Local Bus Specification, Revision 3.0.
MSI-X maps each of the I210 interrupt causes into an interrupt vector that is conveyed by the I210 as
a posted-write PCIe transaction. Mapping of an interrupt cause into an MSI-X vector is determined by
system software (a device driver) through a translation table stored in the MSI-X Allocation registers.
Each entry of the allocation registers defines the vector for a single interrupt cause.
7.3.2 Mapping of Interrupt Causes
There are 10 extended interrupt causes that exist in the I210:
1. 8 traffic causes 4 Tx, 4 Rx.
2. TCP timer
3. Other causes Summarizes legacy interrupts into one extended cause.
The way the I210 exposes causes to the software is determined by the interrupt mode described in the
text that follows.
Mapping of interrupts causes is different in each of the interrupt modes and is described in the following
sections of this chapter.
Note: If only one MSI-X vector is allocated by the operating system, then the driver might use the
non MSI-X mapping method even in MSI-X mode.
7.3.2.1 Legacy and MSI Interrupt Modes
In legacy and MSI modes, an interrupt cause is reflected by setting a bit in the EICR register. This
section describes the mapping of interrupt causes, like a specific Rx queue event or a Link Status
Change event, to bits in the EICR register.
Mapping of queue-related causes is accomplished through the IVAR register. Each possible queue
interrupt cause (each Rx or Tx queue) is allocated an entry in the IVAR, and each entry in the IVAR
identifies one bit in the EICR register among the bits allocated to queue interrupt causes. It is possible
to map multiple interrupt causes into the same EICR bit.
In this mode, different queue related interrupt causes can be mapped to the first 4 bits of the EICR
register.
Interrupt causes related to non-queue causes are mapped into the ICR legacy register; each cause is
allocated a separate bit. The sum of all causes is reflected in the Other Cause bit in EICR. Figure 7-13
shows the allocation process.
The following configuration and parameters are involved:
The IVAR[3:0] entries map 4 Tx queues and 4 Rx queues into the EICR[3:0] bits.
The IVAR_MISC that maps non-queue causes is not used.
The EICR[30] bit is allocated to the TCP timer interrupt cause.
Ethernet Controller I210 —Inline Functions
322
The EICR[31] bit is allocated to the other interrupt causes summarized in the ICR register.
A single interrupt vector is provided.
Table 7-48 lists the different interrupt causes into the IVAR registers.
7.3.2.2 MSI-X Mode
In MSI-X mode the I210 can request up to 5 vectors.
In MSI-X mode, an interrupt cause is mapped into an MSI-X vector. This section describes the mapping
of interrupt causes, like a specific RX queue event or a Link Status Change event, to MSI-X vectors.
Mapping is accomplished through the IVAR register. Each possible cause for an interrupt is allocated an
entry in the IVAR, and each entry in the IVAR identifies one MSI-X vector. It is possible to map multiple
interrupt causes into the same MSI-X vector.
The EICR also reflects interrupt vectors. The EICR bits allocated for queue causes reflect the MSI-X
vector (bit 2 is set when MSI-X vector 2 is used). Interrupt causes related to non-queue causes are
mapped into the ICR (as in the legacy case). The MSI-X vector for all such causes is reflected in the
EICR.
The following configuration and parameters are involved:
The IVAR[3:0] registers map 4 Tx queues and 4 Rx queues events to up to 23 interrupt vectors
Figure 7-13. Cause Mapping in Legacy Mode
Table 7-48. Cause Allocation in the IVAR Registers - MSI and Legacy Mode
Interrupt Entry Description
Rx_i INT_Alloc[2*i] (i =
0..3) Receive queues i - Associates an interrupt occurring in the Rx queue i with a corresponding
bit in the EICR register.
Tx_i INT_Alloc[2*i+1]
(i = 0..3) Transmit queues i- Associates an interrupt occurring in the Tx queue i with a corresponding
bit in the EICR register.
Cause 0
Cause 7
RSV
Single Vector
Other
TCP timer
.
.
.
0
30
31
Queue
Related
causes
Other
causes
IVAR[0]
IVAR[1]
IVAR[2]
IVAR[3]
ICR
EICR
Reflect
Causes
7
Inline Functions—Ethernet Controller I210
323
The IVAR_MISC register maps a TCP timer and other events to 2 MSI-X vectors
Figure 7-14 shows the allocation process.
Table 7-49 lists which interrupt cause is represented by each entry in the MSI-X Allocation registers.
The software has access to 10 mapping entries to map each cause to one of the 5 MSI-x vectors.
Figure 7-14. Cause Mapping in MSI-X Mode
Table 7-49. Cause Allocation in the IVAR Registers
Interrupt Entry Description
Rx_i INT_Alloc[2*i] (i =
0..3) Receive queues i - Associates an interrupt occurring in the RX queue i with a corresponding
entry in the MSI-X Allocation registers.
Tx_i INT_Alloc[2*i+1]
(i = 0..3) Transmit queues i- Associates an interrupt occurring in the TX queues i with a
corresponding entry in the MSI-X Allocation registers.
TCP timer INT_Alloc[8] TCP Timer - Associates an interrupt issued by the TCP timer with a corresponding entry in
the MSI-X Allocation registers.
Other cause INT_Alloc[9] Other causes - Associates an interrupt issued by the other causes with a corresponding
entry in the MSI-X Allocation registers.
IVAR
0
24
31
0
Interrupt causes
(queues)
MSI-X
Vector
3
EICR
Interrupt causes (Other)
IVAR_Misc
RSV
MSI-X
Vector
Ethernet Controller I210 —Inline Functions
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7.3.3 Legacy Interrupt Registers
The interrupt logic consists of the registers listed in Table 7-50 and Table 7-51, plus the registers
associated with MSI/MSI-X signaling. Table 7-50 lists the use of the registers in legacy mode and
Table 7-50 lists the use of the registers when using the extended interrupts functionality
7.3.3.1 Interrupt Cause Register (ICR)
7.3.3.1.1 Legacy Mode
In Legacy mode, ICR is used as the sole interrupt cause register. Upon reception of an interrupt, the
interrupt handling routine can read this register in order to find out what are the causes of this
interrupt.
Table 7-50. Interrupt Registers - Legacy Mode
Register Acronym Function
Interrupt Cause ICR Records interrupt conditions.
Interrupt Cause Set ICS Allows software to set bits in the ICR.
Interrupt Mask Set/Read IMS Sets or reads bits in the interrupt mask.
Interrupt Mask Clear IMC Clears bits in the interrupt mask.
Interrupt Acknowledge Auto-
mask IAM Under some conditions, the content of this register is copied to the mask
register following read or write of ICR.
Table 7-51. Interrupt Registers - Extended Mode
Register Acronym Function
Extended Interrupt Cause EICR Records interrupt causes from receive and transmit queues. An interrupt
is signaled when unmasked bits in this register are set.
Extended Interrupt Cause Set EICS Allows software to set bits in the Interrupt Cause register.
Extended Interrupt Mask Set/
Read EIMS Sets or read bits in the interrupt mask.
Extended Interrupt Mask Clear EIMC Clears bits in the interrupt mask.
Extended Interrupt Auto Clear EIAC Allows bits in the EICR to be cleared automatically following an MSI-X
interrupt without a read or write of the EICR.
Extended Interrupt
Acknowledge Auto-mask EIAM
This register is used to decide which masks are cleared in the extended
mask register following read or write of EICR or which masks are set
following a write to EICS. In MSI-X mode, this register also controls which
bits in EIMC are cleared automatically following an MSI-X interrupt.
Interrupt Cause ICR Records interrupt conditions for special conditions - a single interrupt from
all the conditions of ICR is reflected in the “other” field of the EICR.
Interrupt Cause Set ICS Allows software to set bits in the ICR.
Interrupt Mask Set/Read IMS Sets or reads bits in the other interrupt mask.
Interrupt Mask Clear IMC Clears bits in the Other interrupt mask.
Interrupt Acknowledge Auto-
mask IAM Under some conditions, the content of this register is copied to the mask
register following read or write of ICR.
General Purpose Interrupt
Enable GPIE Controls different behaviors of the interrupt mechanism.
Inline Functions—Ethernet Controller I210
325
7.3.3.1.2 Advanced Mode
In advanced mode, this register captures the interrupt causes not directly captured by the EICR. These
are infrequent management interrupts and error conditions.
Note that when EICR is used in advanced mode, the Rx /Tx related bits in ICR should be masked.
ICR bits are cleared on register read. If GPIE.NSICR = 0b, then the clear on read occurs only if no bit is
set in the IMS register or at least one bit is set in the IMS register and there is a true interrupt as
reflected in the ICR.INTA bit.
7.3.3.2 Interrupt Cause Set Register (ICS)
This register allows software to set bits in the ICR register. Writing a 1b in an ICS bit causes the
corresponding bit in the ICR register to be set. Used usually to re-arm interrupts the software device
driver didn't have time to handle in the current interrupt routine.
7.3.3.3 Interrupt Mask Set/Read Register (IMS)
An interrupt is enabled if its corresponding mask bit in this register is set to 1b, and disabled if its
corresponding mask bit is set to 0b. A PCIe interrupt is generated whenever one of the bits in this
register is set, and the corresponding interrupt condition occurs. The occurrence of an interrupt
condition is reflected by having a bit set in the Interrupt Cause Register (ICR).
Reading this register returns which bits have an interrupt mask set.
A particular interrupt might be enabled by writing a 1b to the corresponding mask bit in this register.
Any bits written with a 0b are unchanged. Thus, if software desires to disable a particular interrupt
condition that had been previously enabled, it must write to the Interrupt Mask Clear (IMC) Register,
rather than writing a 0b to a bit in this register.
7.3.3.4 Interrupt Mask Clear Register (IMC)
Software blocks interrupts by clearing the corresponding mask bit. This is accomplished by writing a 1b
to the corresponding bit in this register. Bits written with 0b are unchanged (their mask status does not
change).
7.3.3.5 Interrupt Acknowledge Auto-mask register (IAM)
An ICR read or write has the side effect of writing the contents of this register to the IMC register to
auto-mask additional interrupts from the ICR bits in the locations where the IAM bits are set. If
GPIE.NSICR = 0b, then the copy of this register to the IMC register occurs only if at least one bit is set
in the IMS register and there is a true interrupt as reflected in the ICR.INTA bit.
7.3.3.6 Extended Interrupt Cause Registers (EICR)
7.3.3.6.1 MSI/INT-A Mode (GPIE.Multiple_MSIX = 0b)
This register records the interrupts causes, to provide Software with information on the interrupt
source.
Ethernet Controller I210 —Inline Functions
326
The interrupt causes include:
1. The Receive and Transmit queues Each queue (either Tx or Rx) can be mapped to one of the 4
interrupt causes bits (RxTxQ) available in this register according to the mapping in the IVAR
registers
2. Indication for the TCP timer interrupt.
3. Legacy and other indications When any interrupt in the Interrupt Cause register is active.
Writing a 1b clears the corresponding bit in this register. Reading this register auto-clears all bits.
7.3.3.6.2 MSI-X Mode (GPIE.Multiple_MSIX = 1b)
This register records the interrupt vectors currently emitted. In this mode only the first 5 bits are valid.
For all the subsequent registers, in MSI-X mode, each bit controls the behavior of one vector.
Bits in this register can be configured to auto-clear when the MSI-X interrupt message is sent, in order
to minimize driver overhead when using MSI-X interrupt signaling.
Writing a 1b clears the corresponding bit in this register. Reading this register does not clear any bits.
7.3.3.7 Extended Interrupt Cause Set Register (EICS)
This register enables the software device driver to set EICR bits. Writing a 1b in a EICS bit causes the
corresponding bit in the EICR register to be set. Used usually to re-arm interrupts that the software
didn't have time to handle in the current interrupt routine.
7.3.3.8 Extended Interrupt Mask Set and Read Register (EIMS) & Extended
Interrupt Mask Clear Register (EIMC)
Interrupts appear on PCIe only if the interrupt cause bit is a one and the corresponding interrupt mask
bit is a one. Software blocks assertion of an interrupt by clearing the corresponding bit in the mask
register. The cause bit stores the interrupt event regardless of the state of the mask bit. Different Clear
(EIMC) and set (EIMS) registers make this register more “thread safe” by avoiding a read-modify-write
operation on the mask register. The mask bit is set for each bit written as a one in the set register
(EIMS) and cleared for each bit written as a one in the clear register (EIMC). Reading the set register
(EIMS) returns the current mask register value.
7.3.3.9 Extended Interrupt Auto Clear Enable Register (EIAC)
Each bit in this register enables clearing of the corresponding bit in EICR following interrupt generation.
When a bit is set, the corresponding bit in the EICR register is automatically cleared following an
interrupt. This feature should only be used in MSI-X mode.
When used in conjunction with MSI-X interrupt vector, this feature allows interrupt cause recognition,
and selective interrupt cause, without requiring software to read or write the EICR register; therefore,
the penalty related to a PCIe read or write transaction is avoided.
See section 7.3.4 for additional information on the interrupt cause reset process.
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327
7.3.3.10 Extended Interrupt Auto Mask Enable Register (EIAM)
Each bit set in this register enables clearing of the corresponding bit in the extended mask register
following read or write-to-clear to EICR. It also enables setting of the corresponding bit in the extended
mask register following a write-to-set to EICS.
This mode is provided in case MSI-X is not used, and therefore auto-clear through EIAC register is not
available.
In MSI-X mode, the driver software might set the bits of this register to select mask bits that must be
reset during interrupt processing. In this mode, each bit in this register enables clearing of the
corresponding bit in EIMC following interrupt generation.
7.3.3.11 GPIE Register
There are a few bits in the GPIE register that define the behavior of the interrupt mechanism. The
setting of these bits is different in each mode of operation. Table 7-52lists the recommended setting of
these bits in the different modes:
7.3.4 Clearing Interrupt Causes
The I210 has three methods available to clear EICR bits: Auto-clear, clear-on-write, and clear-on-read.
ICR bits might only be cleared with clear-on-write or clear-on-read.
Table 7-52. Settings for Different Interrupt Modes
Field Bit(s) Initial
Value Description
INT-x/
MSI +
Legacy
INT-x/
MSI +
Extend
MSI-X
Multi
Vector
MSI-X
Single
Vector
NSICR 0 0b
Non Selective Interrupt clear on read: When set,
every read of the ICR register clears the ICR
register. When this bit is cleared, an ICR register
read causes the ICR register to be cleared only if
an actual interrupt was asserted or IMS = 0x0.
0b1
1. In systems where interrupt sharing is not expected, the NSICR bit can be set by legacy drivers also.
As this register affects the way the hardware interprets write operations to other interrupt control
registers, it should be set to the correct mode before accessing other interrupt control registers.
1b 1b 1b
Multiple_
MSIX 4 0b
Multiple_MSI-X - multiple vectors:
0b = non-MSI-X or MSI-X with 1 vector IVAR
maps Rx/Tx causes to 4 EICR bits, but MSIX[0]
is asserted for all.
1b = MSIX mode, IVAR maps Rx/Tx causes to 5
EICR bits.
When set, the EICR register is not clear on read.
0b 0b 1b 0b
EIAME 30 0b
EIAME: When set, upon firing of an MSI-X
message, mask bits set in EIAM associated with
this message are cleared. Otherwise, EIAM is
used only upon read or write of EICR/EICS
registers.
0b 0b 1b 1b
PBA_
support 31 0b
PBA support: When set, setting one of the
extended interrupts masks via EIMS causes the
PBA bit of the associated MSI-X vector to be
cleared. Otherwise, the I210 behaves in a way
that supports legacy INT-x interrupts.
Should be cleared when working in INT-x or MSI
mode and set in MSI-X mode.
0b 0b 1b 1b
Ethernet Controller I210 —Inline Functions
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7.3.4.1 Auto-Clear
In systems that support MSI-X, the interrupt vector allows the interrupt service routine to know the
interrupt cause without reading the EICR. With interrupt moderation active, software load from
spurious interrupts is minimized. In this case, the software overhead of a I/O read or write can be
avoided by setting appropriate EICR bits to auto-clear mode by setting the corresponding bits in the
Extended Interrupt Auto-clear Enable Register (EIAC).
When auto-clear is enabled for an interrupt cause, the EICR bit is set when a cause event mapped to
this vector occurs. When the EITR Counter reaches zero, the MSI-X message is sent on PCIe. Then the
EICR bit is cleared and enabled to be set by a new cause event. The vector in the MSI-X message
signals software the cause of the interrupt to be serviced.
It is possible that in the time after the EICR bit is cleared and the interrupt service routine services the
cause, for example checking the transmit and receive queues, that another cause event occurs that is
then serviced by this ISR call, yet the EICR bit remains set. This results in a “spurious interrupt”.
Software can detect this case, for example if there are no entries that require service in the transmit
and receive queues, and exit knowing that the interrupt has been automatically cleared. The use of
interrupt moderations through the EITR register limits the extra software overhead that can be caused
by these spurious interrupts.
7.3.4.2 Write to Clear
In the case where the driver wishes to configure itself in MSI-X mode to not use the “auto-clear”
feature, it might clear the EICR bits by writing to the EICR register. Any bits written with a 1b is
cleared. Any bits written with a 0b remain unchanged.
7.3.4.3 Read to Clear
The EICR and ICR registers are cleared on a read.
Note: The driver should never do a read-to-clear of the EICR when in MSI-X mode, since this might
clear interrupt cause events which are processed by a different interrupt handler (assuming
multiple vectors).
7.3.5 Interrupt Moderation
An interrupt is generated upon receiving of incoming packets, as throttled by the EITR registers (see
Section 8.8.14). There is an EITR register per MSI-X vector.
In MSI-X mode, each active bit in EICR can trigger the interrupt vector it is allocated to. Following the
allocation, the EITR corresponding to the MSI-X vector is tied to one or more bits in EICR.
When multi vector MSI-X is not activated, the interrupt moderation is controlled by register EITR[0].
Software can use EITR to limit the rate of delivery of interrupts to the host CPU. This register provides
a guaranteed inter-interrupt delay between interrupts asserted by the network controller, regardless of
network traffic conditions.
The following formula converts the inter-interrupt interval value to the common 'interrupts/sec.'
performance metric:
interrupts/sec = (1 * 10-6sec x interval)-1
Inline Functions—Ethernet Controller I210
329
Note: In the I210 the interval granularity is 1 s so some of the LSB bits of the interval are used for
the low latency interrupt moderation.
For example, if the interval is programmed to 125d, the network controller guarantees the CPU is not
interrupted by the network controller for at least 125 s from the last interrupt. In this case, the
maximum observable interrupt rate from the adapter should not exceed 8000 interrupts/sec.
Inversely, inter-interrupt interval value can be calculated as:
inter-interrupt interval = (1 * 10-6 sec x interrupt/sec)-1
The optimal performance setting for this register is system and configuration specific.
The Extended Interrupt Throttle Register should default to zero upon initialization and reset. It loads in
the value programmed by the software after software initializes the device.
When software wants to force an immediate interrupt, for example after setting a bit in the EICR with
the Extended Interrupt Cause Set register, a value of 0 can be written to the Counter to generate an
interrupt immediately. This write should include re-writing the Interval field with the desired constant,
as it is used to reload the Counter immediately for the next throttling interval.
The I210 implements interrupt moderation to reduce the number of interrupts software processes. The
moderation scheme is based on the EITR (Interrupt Throttle Register). Each time an interrupt event
happens, the corresponding bit in the EICR is activated. However, an interrupt message is not sent out
Ethernet Controller I210 —Inline Functions
330
on the PCIe interface until the EITR counter assigned to that EICR bit has counted down to zero. As
soon as the interrupt is issued, the EITR counter is reloaded with its initial value and the process
repeats again. The interrupt flow should follow Figure 7-15.
EITR is designed to guarantee the total number of interrupts per second so for cases where the I210 is
connected to a network with low traffic load, if the EITR counter counted down to zero and no interrupt
event has happened, then the EITR counter is not re-armed but stays at zero. Thus, the next interrupt
event triggers an interrupt immediately. That scenario is illustrated as Case B that follows.
Figure 7-15. Interrupt Throttle Flow Diagram
Start count
down
A
ssert Interrupt
Counter = 0
?
Load counter
with interval
Yes
Yes
Interrupt
active
?
Yes
No
Counter
written to
0
No
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7.3.6 Rate Controlled Low Latency Interrupts (LLI)
There are some types of network traffic for which latency is a critical issue. For these types of traffic,
interrupt moderation hurts performance by increasing latency between the time a packet is received by
hardware and the time it is handled to the host operating system. This traffic can be identified by the 2-
tuple value, in conjunction with Control Bits and specific size. In addition packets with specific Ethernet
types, TCP flag or specific VLAN priority might generate an immediate interrupt.
Low latency interrupts shares the filters used by the queueing mechanism described in Section 7.1.1.
Each of these filters, in addition to the queueing action might also indicate matching packets might
generate immediate interrupt.
If a received packet matches one of these filters, hardware should interrupt immediately, overriding the
interrupt moderation by the EITR counter.
Each time a Low Latency Interrupt is fired, the EITR interval is loaded and down-counting starts again.
The logic of the low latency interrupt mechanism is as follows:
There are 8 2-tuple filters. The content of each filter is described in Section 7.1.2.4. The immediate
interrupt action of each filter can be enabled or disabled. If one of the filters detects an adequate
packet, an immediate interrupt is issued.
Figure 7-16. Case A: Heavy Load, Interrupts Moderated
Figure 7-17. Light load, Interrupts Immediately on Packet Receive
Pkt Pkt Pkt Pkt Pkt Pkt
ITR delay ITR delay
Intr Intr Intr
Pkt Pkt
EICR
clear
EICR
clear
EICR
clear
Pkt Pkt
ITR delay
Intr Intr
EICR
clear
EICR
clear
Ethernet Controller I210 —Inline Functions
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There are 8 flex filters. The content of each filter is described in Section 7.1.2.5. The immediate
interrupt action of each filter can be enabled or disabled. If one of the filters detects an adequate
packet, an immediate interrupt is issued.
When VLAN priority filtering is enabled, VLAN packets must trigger an immediate interrupt when
the VLAN Priority is equal to or above the VLAN priority threshold. This is regardless of the status of
the 2-tuple or Flex filters.
The SYN packets filter defined in Section 7.1.2.6 and the ethernet type filters defined in section
Section 7.1.2.3 might also be used to indicate low latency interrupt conditions.
Note: Immediate interrupts are available only when using advanced receive descriptors and not for
legacy descriptors.
Note: Packets that are dropped or have errors do not cause a Low Latency Interrupt.
7.3.6.1 Rate Control Mechanism
In a network with lots of latency sensitive traffics the Low Latency Interrupt can eliminate the Interrupt
throttling capability by flooding the Host with too many interrupts (more than the Host can handle).
In order to mitigate the above, the I210 supports a credit base mechanism to control the rate of the
Low Latency Interrupts.
Rules:
The default value of each counter is 0b (no moderation). This also preserves backward
compatibility.
The counter increments at a configurable rate, and saturates at the maximum value (31d).
The configurable rate granularity is 4 s (250K interrupt/sec. down to 250K/32 ~ 8K interrupts
per sec.).
A LLI might be issued as long as the counter value is strictly positive (> zero).
The credit counter allows bursts of low latency interrupts but the interrupt average are not
more than the configured rate.
Each time a Low Latency Interrupt is fired the credit counter decrements by one.
Once the counter reaches zero, a low latency interrupt cannot be fired
Must wait for the next ITR expired or for the next incrementing of this counter (if the EITR
expired happened first the counter does not decrement).
The EITR and GPIE registers manage rate control of LLI:
The LL Interval field in the GPIE register controls the rate of credits
The 5-bit LL Counter field in the EITR register contains the credits
7.3.7 TCP Timer Interrupt
7.3.7.1 Introduction
The TCP Timer interrupt provides an accurate and efficient way for a periodic timer to be implemented
using hardware. The driver would program a timeout value (usual value of 10 ms), and each time the
timer expires, hardware sets a specific bit in the EICR. When an interrupt occurs (due to normal
interrupt moderation schemes), software reads the EICR and discovers that it needs to process timer
events during that DPC.
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The timeout should be programmable by the driver, and the driver should be able to disable the timer
interrupt if it is not needed.
7.3.7.2 Description
A stand-alone down-counter is implemented. An interrupt is issued each time the value of the counter
is zero.
The software is responsible for setting initial value for the timer in the TCPTIMER.Duration field. Kick-
starting is done by writing a 1b to the TCPTIMER.KickStart bit.
Following the kick-start, an internal counter is set to the value defined by the TCPTIMER.Duration field.
Then during the count operation, the counter is decreased by one each millisecond. When the counter
reaches zero, an interrupt is issued (see EICR register Section 8.8.3). The counter re-starts counting
from its initial value if the TCPTIMER.Loop field is set.
7.3.8 Setting Interrupt Registers
In each mode, the registers controlling the interrupts should be set in a different way to assure the
right behavior.
7.4 802.1Q VLAN Support
The I210 provides several specific mechanisms to support 802.1Q VLANs:
Optional adding (for transmits) and stripping (for receives) of IEEE 802.1Q VLAN tags.
Optional ability to filter packets belonging to certain 802.1Q VLANs.
Double VLAN Support.
Table 7-53. Registers Settings for Different Interrupt Modes
Field Description INT-x/MSI +
Legacy
INT-x/ MSI +
Extend
MSI-X
Multi vector
MSI-X
Single
vector
IMS Legacy Masks Set1
1. According to the requested causes
Set2
2. Only non traffic causes.
Set2Set2
IAM Legacy Auto Mask Register Might be set 0x0 0x0 0x0
EIMS Extended Masks Set Other
Cause only. Set1Set1Set1
EIAC Extended Auto Clear register 0x0 0x0 At least one 3
3. EIAC or EIAM or both should be set for each cause.
0x0
EIAM Extended Auto Mask Register 0x0 Set1Set1
EITR[0] Interrupt Moderation register Might be
enabled Might be
enabled Enable4
4. EITR must be enabled if Auto Mask is disabled. If Auto Mask is enabled, moderation might be disabled for the specific vector.
Enable
EITR[1...n] Extended Interrupt Moderation register Disable Disable Enable4Disable
GPIE Interrupts configuration See Table 7-52 for details
Ethernet Controller I210 —Inline Functions
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7.4.1 802.1Q VLAN Packet Format
The following diagram compares an untagged 802.3 Ethernet packet with an 802.1Q VLAN tagged
packet:
Note: The CRC for the 802.1Q tagged frame is re-computed, so that it covers the entire tagged
frame including the 802.1Q tag header. Also, max frame size for an 802.1Q VLAN packet is
1522 octets as opposed to 1518 octets for a normal 802.3z Ethernet packet.
7.4.2 802.1Q Tagged Frames
For 802.1Q, the Tag Header field consists of four octets comprised of the Tag Protocol Identifier (TPID)
and Tag Control Information (TCI); each taking 2 octets. The first 16 bits of the tag header makes up
the TPID. It contains the “protocol type” which identifies the packet as a valid 802.1Q tagged packet.
The two octets making up the TCI contain three fields:
User Priority (UP)
Canonical Form Indicator (CFI). Should be 0b for transmits. For receives, the device has the
capability to filter out packets that have this bit set. See the CFIEN and CFI bits in the RCTL
described in Section 8.10.1.
VLAN Identifier (VID)
The bit ordering is as follows:
7.4.3 Transmitting and Receiving 802.1Q Packets
7.4.3.1 Adding 802.1Q Tags on Transmits
Software might command the I210 to insert an 802.1Q VLAN tag on a per packet or per flow basis. If
the VLE bit in the transmit descriptor is set to 1b, then the I210 inserts a VLAN tag into the packet that
it transmits over the wire. 802.1Q tag insertion is done in different ways for legacy and advanced Tx
descriptors:
Table 7-54. Comparing Packets
802.3 Packet #Octets 802.1Q VLAN Packet #Octets
DA 6 DA 6
SA 6 SA 6
Type/Length 2 802.1Q Tag 4
Data 46-1500 Type/Length 2
CRC 4 Data 46-1500
CRC* 4
Table 7-55. TCI Bit Ordering
Octet 1 Octet 2
UP CFI VID
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Legacy Transmit Descriptors:, The Tag Control Information (TCI) of the 802.1Q tag comes from the
VLAN field (see Figure 7-8) of the descriptor. Refer to Table 7-26, for more information regarding
hardware insertion of tags for transmits.
Advanced Transmit Descriptor: The Tag Control Information (TCI) of the 802.1Q tag comes from
the VLAN Tag field (see Table 7.2.2.2.1) of the advanced context descriptor. The IDX field of the
advanced Tx descriptor should be set to the adequate context.
7.4.3.2 Stripping 802.1Q Tags on Receives
Software might instruct the I210 to strip 802.1Q VLAN tags from received packets. If VLAN stripping is
enabled and the incoming packet is an 802.1Q VLAN packet (its Ethernet Type field matched the VET),
then the I210 strips the 4 byte VLAN tag from the packet, and stores the TCI in the VLAN Tag field (see
Figure 7-4 and See “Receive UDP Fragmentation Checksum) of the receive descriptor.
The I210 also sets the VP bit in the receive descriptor to indicate that the packet had a VLAN tag that
was stripped. If the CTRL.VME bit is not set, the 802.1Q packets can still be received if they pass the
receive filter, but the VLAN tag is not stripped and the VP bit is not set.
VLAN stripping can be enabled using two different modes:
1. By setting the DVMOLR.STRVLAN for the relevant queue.
2. By setting the CTRL.VME bit.
7.4.4 802.1Q VLAN Packet Filtering
VLAN filtering is enabled by setting the RCTL.VFE bit to 1b. If enabled, hardware compares the type
field of the incoming packet to a 16-bit field in the VLAN Ether Type (VET) register. If the VLAN type
field in the incoming packet matches the VET register, the packet is then compared against the VLAN
Filter Table Array (VFTA[127:0]) for acceptance.
The I210 provides exact VLAN filtering for VLAN tags for host traffic and VLAN tags for manageability
traffic.
7.4.4.1 Host VLAN Filtering:
The Virtual LAN ID field indexes a 4096 bit vector. If the indexed bit in the vector is one; there is a
Virtual LAN match. Software might set the entire bit vector to ones if the node does not implement
802.1Q filtering. The register description of the VLAN Filter Table Array is described in detail in
Section 8.10.18.
In summary, the 4096-bit vector is comprised of 128, 32-bit registers. The VLAN Identifier (VID) field
consists of 12 bits. The upper 7 bits of this field are decoded to determine the 32-bit register in the
VLAN Filter Table Array to address and the lower 5 bits determine which of the 32 bits in the register to
evaluate for matching.
7.4.4.2 Manageability VLAN Filtering:
The MC configures the I210 with eight different manageability VIDs via the Management VLAN TAG
Value [7:0] - MAVTV[7:0] registers and enables each filter in the MDEF register.
Two other bits in the Receive Control register (see Section 8.10.1), CFIEN and CFI, are also used in
conjunction with 802.1Q VLAN filtering operations. CFIEN enables the comparison of the value of the
CFI bit in the 802.1Q packet to the Receive Control register CFI bit as acceptance criteria for the
packet.
Ethernet Controller I210 —Inline Functions
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Note: The VFE bit does not affect whether the VLAN tag is stripped. It only affects whether the
VLAN packet passes the receive filter.
Table 7-56 lists reception actions per control bit settings.
Note: A packet is defined as a VLAN/802.1Q packet if its type field matches the VET.
7.4.5 Double VLAN Support
The I210 supports a mode where most of the received and sent packet have at least one VLAN tag in
addition to the regular tagging which might optionally be added. This mode is used for systems where
the switches add an additional tag containing switching information.
Note: The only packets that might not have the additional VLAN are local packets that does not
have any VLAN tag.
This mode is activated by setting CTRL_EXT.EXT_VLAN bit. The default value of this bit is set according
to the EXT_VLAN (bit 1) in the Initialization Control 3 Flash word.
The type of the VLAN tag used for the additional VLAN is defined in the VET.VET_EXT field.
7.4.5.1 Transmit Behavior With External VLAN
It is expected that the driver include the external VLAN header as part of the transmit data structure.
Software might post the internal VLAN header as part of the transmit data structure or embedded in the
transmit descriptor (see Section 7.2.2 for details). The I210 does not relate to the external VLAN
header other than the capability of “skipping” it for parsing of inner fields.
Notes:
If the CTRL_EXT.EXT_VLAN bit is set the VLAN header in a packet that carries a single
VLAN header is treated as the external VLAN.
If the CTRL_EXT.EXT_VLAN bit is set the I210 expects that any transmitted packet to
have at least the external VLAN added by the software. For those packets where an
external VLAN is not present, any offload that relates to inner fields to the EtherType
might not be provided.
Table 7-56. Packet Reception Decision Table
Is packet
802.1Q?
CTRL.
VME
RCTL.
VFE Action
No X1
1. X - Don’t care
X1Normal packet reception
Yes 0b 0b Receive a VLAN packet if it passes the standard MAC address filters (only). Leave the
packet as received in the data buffer. VP bit in receive descriptor is cleared.
Yes 0b 1b Receive a VLAN packet if it passes the standard filters and the VLAN filter table. Leave
the packet as received in the data buffer (the VLAN tag would not be stripped). VP bit in
receive descriptor is cleared.
Yes 1b 0b Receive a VLAN packet if it passes the standard filters (only). Strip off the VLAN
information (four bytes) from the incoming packet and store in the descriptor. Sets VP
bit in receive descriptor.
Yes 1b 1b Receive a VLAN packet if it passes the standard filters and the VLAN filter table. Strip off
the VLAN information (four bytes) from the incoming packet and store in the descriptor.
Sets VP bit in receive descriptor.
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If the regular VLAN is inserted using the switch based VLAN insertion mechanism or from
the descriptor (see Section 7.4.3.1), and the packet does not contain an external VLAN,
the packet is dropped, and if configured, the queue from which the packet was sent is
disabled.
7.4.5.2 Receive Behavior With External VLAN
When the I210 is working in this mode, it assumes that all packets received have at least one VLAN,
including a packet received or sent on the manageability interface.
One exception to this rule are flow control PAUSE packets which are not expected to have any VLAN.
Other packets might contain no VLAN, however a received packet that does not contain the first VLAN
is forwarded to the host but filtering and offloads are not applied to this packet.
See Table 7-57 for the supported receive processing functions when the device is set to “Double VLAN”
mode.
Stripping of VLAN is done on the second VLAN if it exists. All the filtering functions of the I210 ignore
the first VLAN in this mode.
The presence of a first VLAN tag is indicated it in the RDESC.STATUS.VEXT bit.
Queue assignment of the Rx packets is not affected by the external VLAN header. It might depend on
the internal VLAN, MAC address or any upper layer content as described in Section 7.1.1.
7.5 Configurable LED Outputs
The I210 implements 3 output drivers intended for driving external LED circuits. Each of the 3 LED
outputs can be individually configured to select the particular event, state, or activity, which is
indicated on that output. In addition, each LED can be individually configured for output polarity as well
as for blinking versus non-blinking (steady-state) indication.
The configuration for LED outputs is specified via the LEDCTL register. Furthermore, the hardware-
default configuration for all the LED outputs, can be specified via Flash fields, thereby supporting LED
displays configurable to a particular OEM preference.
Each of the 3 LED's might be configured to use one of a variety of sources for output indication. The
MODE bits control the LED source as described in Table 7-58.
The IVRT bits allow the LED source to be inverted before being output or observed by the blink-control
logic. LED outputs are assumed to normally be connected to the negative side (cathode) of an external
LED.
Table 7-57. Receive Processing in Double VLAN Mode
VLAN Headers Status.VEXT Status.VP Packet Parsing Rx Offload Functions
External and internal 1 1 + +
Internal Only Not supported
V-Ext 1 0 + +
None1
1. A few examples for packets that might not carry any VLAN header might be: Flow control and Priority Flow Control; LACP; LLDP;
GMRP; 802.1x packets
0 0 + (flow control only) -
Ethernet Controller I210 —Inline Functions
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The BLINK bits control whether the LED should be blinked (on for 200ms, then off for 200ms) while the
LED source is asserted. The blink control might be especially useful for ensuring that certain events,
such as ACTIVITY indication, cause LED transitions, which are sufficiently visible by a human eye.
Note: When LED Blink mode is enabled the appropriate LED Invert bit should be set to 0b.
The LINK/ACTIVITY source functions slightly different from the others when BLINK is enabled.
The LED is off if there is no LINK, on if there is LINK and no ACTIVITY, and blinking if there is
LINK and ACTIVITY.
The dynamic LED modes (FILTER_ACTIVITY, LINK/ACTIVITY, COLLISION, ACTIVITY, PAUSED) should
be used with LED Blink mode enabled.
7.5.1 MODE Encoding for LED Outputs
Table 7-58 lists the MODE encoding for LED outputs used to select the desired LED signal source for
each LED output.
7.6 Memory Error Correction and Detection
The I210 main internal memories are protected by error correcting code or parity bits. Large memories
or critical memories are protected by an error correcting code (ECC). Smaller memories are protected
either with an error correcting code (ECC for critical memories) or by parity.
Table 7-58. Mode Encoding for LED Outputs
Mode Selected Mode Source Indication
0000b LINK_10/1000 Asserted when either 10 or 1000 Mb/s link is established and
maintained.
0001b LINK_100/1000 Asserted when either 100 or 1000 Mb/s link is established and
maintained.
0010b LINK_UP Asserted when any speed link is established and maintained.
0011b FILTER_ACTIVITY Asserted when link is established and packets are being transmitted
or received that passed MAC filtering.
0100b LINK/ACTIVITY Asserted when link is established and when there is no transmit or
receive activity. When BLINK, indicates LINK and activity (eIther
receive or transmit)
0101b LINK_10 Asserted when a 10 Mb/s link is established and maintained.
0110b LINK_100 Asserted when a 100 Mb/s link is established and maintained.
0111b LINK_1000 Asserted when a 1000 Mb/s link is established and maintained.
1000b SDP_MODE LED activation is a reflection of the SDP signal. SDP0, SDP1, SDP2
are reflected to LED0, LED1, LED2 respectively.
1001b FULL_DUPLEX Asserted when the link is configured for full duplex operation (de-
asserted in half-duplex).
1010b COLLISION Asserted when a collision is observed.
1011b ACTIVITY Asserted when link is established and packets are being transmitted
or received.
1100b LINK_10/100 Asserted when either 10 or 100 Mb/s link is established and
maintained.
1101b PAUSED Asserted when the I210’s transmitter is flow controlled.
1110b LED_ON Always high (Asserted)
1111b LED_OFF Always low (De-asserted)
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The I210 reports parity errors in the PEIND register according to the region in which the parity error
occurred (PCIe, DMA, LAN Port or Management). An interrupt is issued via the ICR.FER bit on
occurrence of a parity error. Parity error interrupt generation per region can be masked via the PEINDM
register.
Additional per region granularity in parity or ECC enablement and reporting of parity error or ECC parity
correction occurrence is supported in the following registers:
1. PCIe region:
a. The PCIEERRCTL and PCIEECCCTL registers enable parity checks and ECC parity correction
respectively in the various rams in the PCIe region.
b. The PCIEERRSTS and PCIEECCSTS registers report parity error and ECC parity correction
occurrence in the various rams in the PCIe region. Only parity errors that were not corrected by
the ECC circuitry are reported by asserting the PEIND.pcie_parity_fatal_ind bit and the ICR.FER
bit. Parity errors that were corrected by the internal ECC circuit do not generate an interrupt but
are logged in the PCIEECCSTS register.
2. DMA region:
a. The PBECCSTS register enables ECC parity correction in the various rams in the DMA region.
b. The PBECCSTS register reports occurrence of ECC parity correction events in the various rams
in the DMA region. Only parity errors that were not corrected are reported by setting the
PEIND.dma_parity_fatal_ind bit and the ICR.FER bit. Parity errors that were corrected by the
internal ECC circuitry don’t generate an interrupt but are logged in the PBECCSTS register.
3. LAN Port region:
a. The LANPERRCTL register enables parity checks in the various rams in the LAN Port region.
b. The LANPERRSTS register reports detection of parity errors. The parity errors that were not
corrected are reported via the PEIND.lanport_parity_fatal_ind bit and the ICR.FER bit.
Notes:
1. An interrupt to the Host is generated on occurrence of a fatal memory error if the appropriate mask
bits in the PEINDM register are set and the IMS.FER Mask bit is set.
2. All Parity error checking can be disabled via the GPAR_EN bit in the Initialization Control Word 1
Flash word (See Section 6.2.2) or by clearing the PCIEERRCTL.GPAR_EN bit (See Section 8.24.4).
7.6.1 Software Recovery From Parity Error Event
If a parity error was detected in one of the internal control memories of the DMA, PCIe or LAN port
clusters, the consistency of the receive/transmit flow can not be guaranteed any more. In this case the
traffic on the PCIe interface is stopped, since this is considered a fatal error.
To recover from a parity error event software should initiate the following actions depending on the
region in which the parity error occurred.
7.6.1.1 Recovery from PCIe Parity Error Event
To recover from a parity error condition in the PCIe region, the software device driver should:
1. Issue a Device Reset by asserting the CTRL.RST bit.
2. wait at least 3 milliseconds after setting CTRL.RST bit before attempting to check if the bit was
cleared or before attempting to access any other register.
3. Initiate the master disable algorithm as defined in Section 5.2.3.3.
4. Clear the PCIe parity error status bits that were set in the PCIEERRSTS register.
Ethernet Controller I210 —Inline Functions
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5. Re-initialize the port.
7.6.1.2 Recovery from DMA Parity Error Event
To recover from a parity error condition in the DMA region, the software device driver should issue a
software reset by asserting the CTRL.RST bit as specified in Section 4.3.1 and re-initializing the port.
7.6.1.3 Recovery from LAN Port Parity Error Event
To recover from a parity error condition in the LAN port region, the software device driver should take
the actions depicted in Section 8.24.11 (LANPERRSTS register) according to the ram that failed.
7.7 CPU Affinity Features
7.7.1 Direct Cache Access (DCA)
7.7.1.1 DCA Description
Direct Cache Access (DCA) is a method to improve network I/O performance by placing some posted
inbound writes indirectly within CPU cache. DCA requires that memory writes go to host memory and
then the processor prefetch the cache lines specified by the memory write. Through research and
experiments, DCA has been shown to reduce CPU Cache miss rates significantly.
Figure 7-18. Diagram of DCA Implementation on FSB System
CPU
Cache
Memory
NIC
MCH
D
DM
MA
A
W
Wr
ri
it
te
e
B
BI
IL
L-
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DC
CA
A
M
Me
em
mo
or
ry
y
W
Wr
ri
it
te
e
D
DC
CA
A
t
tr
ri
ig
gg
ge
er
re
ed
d
H
HW
W
P
Pr
r
e
e
f
f
e
e
t
t
c
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C
C
P
P
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e
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m
a
a
n
n
d
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r
r
e
e
a
a
d
d
Inline Functions—Ethernet Controller I210
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As shown in Figure 7-18, DCA provides a mechanism where the posted write data from an I/O device,
such as an Ethernet NIC, can be placed into CPU cache with a hardware pre-fetch. This mechanism is
initialized upon a power good reset. A software device driver for the I/O device configures the I/O
device for DCA and sets up the appropriate DCA target ID for the device to send data. The device then
encapsulates that information in PCIe TLP headers, in the TAG field, to trigger a hardware pre-fetch by
the MCH /IOH to the CPU cache.
DCA implementation is controlled by separated registers (RXCTL and TXCTL) for each receive and
transmit queue. In addition, a DCA Enable bit can be found in the DCA_CTRL register, and a DCA_ID
register, in order to make visible the function, device, and bus numbers to the driver.
The RXCTL and TXCTL registers can be written by software on the fly and can be changed at any time.
When software changes the register contents, hardware applies changes only after all the previous
packets in progress for DCA have been completed.
However, in order to implement DCA, the I210 has to be aware of the Crystal Beach version used.
Software driver must initialize the I210 to be aware of the Crystal Beach version. A register named
DCA_CTRL is used in order to properly define the system configuration.
There are 2 modes for DCA implementation:
1. Legacy DCA: The DCA target ID is derived from CPU ID.
2. DCA: The DCA target ID is derived from APIC ID.
The software driver selects one of these modes through the DCA_mode register.
The details of both modes are described in the following sections.
7.7.1.2 Details of Implementation
7.7.1.2.1 PCIe Message Format for DCA
Ethernet Controller I210 —Inline Functions
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Figure 7-19 shows the format of the PCIe message for DCA.
The DCA preferences field has the following formats.
7.7.2 TLP Process Hints (TPH)
The I210 supports the TPH capability defined in the PCI Express specification (See Section 9.5). It does
not support Extended TPH requests.
Figure 7-19. PCIe Message Format for DCA
Table 7-59. Legacy DCA Systems
Bits Name Description
0 DCA indication 0b: DCA disabled
1b: DCA enabled
3:1 DCA Target ID The DCA Target ID specifies the target cache for the
data.
7:4 Reserved Reserved
Table 7-60. DCA Systems
Bits Name Description
7:0 DCA target ID 0000.0000b: DCA is disabled
Other: Target Core ID derived from APIC ID.
TLP digest
Length specific data
Length specific data
Address [32:2] R
Address [63:32]
Requester ID DCA preferences Last DW BE First DW BE
RFmt=
11 Type=00000b RTC Rsv T
D
E
PAttr RLength
+0
6543210765432107654321076543210
+1 +2 +3
Inline Functions—Ethernet Controller I210
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On the PCIe link existence of a TLP Process Hint (TPH) is indicated by setting the TH bit in the TLP
header. Using the PCIe TLP Steering Tag (ST) and Processing Hints (PH) fields, the I210 can provide
hints to the root complex about the destination (socket ID) and about data access patterns (locality in
Cache), when executing DMA memory writes or read operations. Supply of TLP Processing Hints
facilitates optimized processing of transactions that target Memory Space.
The I210 supports a steering table with 8 entries in the PCIe TPH capability structure (See
Section 9.5.3.4). The PCIe Steering table can be used by Software to provide Steering Tag information
to the Device via the TXCTL.CPUID and RXCTL.CPUID fields.
To enable TPH usage:
1. For a given function, the TPH Requester Enable bit in the PCIe configuration TPH Requester Control
Register should be set.
2. Appropriate TPH Enable bits in RXCTL or TXCTL registers should be set.
3. Processing hints should be programmed in the DCA_CTRL.Desc_PH and DCA_CTRL.Data_PH
Processing hints (PH) fields.
4. Steering information should be programed in the CPUID fields in the RXCTL and TXCTL registers.
The Processing Hints (PH) and Steering Tags (ST) are set according to the characteristics of the traffic
as described in Table 7-61.
Note: In order to enable TPH usage, all the memory reads are done without setting any of the byte
enable bits.
Note: Per queue, the DCA and TPH features are exclusive. Software can enable either the DCA
feature or the TPH feature for a given queue.
7.7.2.1 Steering Tag and Processing Hint Programming
Table 7-61 lists how the Steering tag (socket ID) and Processing hints are generated and how TPH
operation is enabled for different types of DMA traffic.
Table 7-61. Steering Tag and Processing Hint Programming
Traffic Type ST Programming PH Value Enable
Transmit descriptor write back or head
write back TXCTL.CPUID1
1. the driver should always set bits [7:3] to zero and place Socket ID in bits [2:0].
DCA_CTRL.Desc_PH2
2. Default is 00b (Bidirectional data structure).
Tx Descriptor Writeback TPH EN field
in TXCTL.
Receive data buffers write RXCTL.CPUID1DCA_CTRL.Data_PH3
3. Default is 10b (Target).
RX Header TPH EN or
Rx Payload TPH EN fields in RXCTL.
Receive descriptor writeback RXCTL.CPUID1DCA_CTRL.Desc_PH2RX Descriptor Writeback TPH EN
field in RXCTL.
Transmit descriptor fetch TXCTL.CPUID4
4. the hints are always zero.
DCA_CTRL.Desc_PH2Tx Descriptor Fetch TPH EN
field in TXCTL.
Receive descriptor fetch RXCTL.CPUID2DCA_CTRL.Desc_PH2Rx Descriptor fetch TPH EN
field in RXCTL.
Transmit packet read TXCTL.CPUID2DCA_CTRL.Data_PH3Tx Packet TPH EN field in TXCTL.
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7.8 Time SYNC (IEEE1588 and IEEE 802.1AS)
7.8.1 Overview
IEEE 1588 addresses the clock synchronization requirements of measurement and control systems. The
protocol supports system-wide synchronization accuracy in the sub-microsecond range with minimal
network and local clock computing resources. The protocol is spatially localized and allows simple
systems to be installed and operate.
The IEEE802.1AS standard specifies the protocol used to ensure that synchronization requirements are
met for time sensitive applications, such as audio and video, across bridged and Virtual Bridged Local
Area Networks (VBLAN) consisting of LAN media where the transmission delays are almost fixed and
symmetrical. For example, IEEE 802.3 full duplex links. This includes the maintenance of synchronized
time during normal operation and following addition, removal, or failure of network components and
network re-configuration. It specifies the use of IEEE 1588 specifications where applicable.
Activation of the I210 Time Sync mechanism is possible in full duplex mode only. No limitations on wire
speed exist, although wire speed might affect the accuracy. Time Sync protocol is tolerant of dropping
packets as well as missing timestamps.
7.8.2 Flow and Hardware/Software Responsibilities
The operation of a PTP (Precision Time Protocol) enabled network is divided into two stages,
initialization and time synchronization. These stages are described in the sections that follow
emphasizing hardware and software roles.
7.8.2.1 Initialization Phase
At the initialization stage the software on every master enabled node starts by sending Sync packets
that include its clock parameters. Upon reception of a Sync packet a node, the software on any
potential master, compares the received clock parameters to its own parameters. If the received clock
parameters of a peer are better, the software transits to Slave state and stops sending Sync packets.
When in slave state, the software selects a particular master. It compares continuously the received
Sync packet to its selected master. If the received Sync packets belong to a different master with better
clock parameters, the software on the slave switches to the new master. Eventually only one master
(with the best clock parameters) remains active while all other nodes act as slaves listening to that
master. Every node has a defined Sync packet time-out interval. If no Sync packet is received from its
chosen master clock source during the interval the software on the master enabled nodes transit back
to master state at initialization phase. Note that there are more than one option for the above flow. For
example, one node could be set statically as the master while all other notes are set as slaves listening
to that master.
7.8.2.2 Time Synchronization Phase
There are two phases to the synchronization flow: At the beginning, the slave calibrates its clock to the
master and then it performs the complete synchronization.
7.8.2.2.1 2-step Clocks Calibration Procedure
The master send SYNC packets periodically (in the order of 10 packets per second). These packets are
followed by Follow_UP packets that indicate the transmission time. The slave captures the reception
time of these SYNC packets. Together with the Follow_UP packets the slave holds the SYNC packet
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transmission time at the master and its reception time at the slave. The slave calculates the time gap
between consecutive SYNC packets defined by the master clock. It then calibrates itself to get the same
time gap defined by its own clock. During this phase the slave also sets its time to be as close as
possible to the master time (as accurate as the transmission delay and software latencies).
In order to minimize sampling inaccuracy, both master and slave sample the packets transmission and
reception time at a location in the hardware that has as much as possible deterministic delay from the
PHY interface.
Packet processing in the master and the Slave
The master software indicates the SYNC packet to the hardware by setting the 2STEP_1588 flag in
the Advanced Transmit Data Descriptor. Setting this flag, the hardware samples its transmission
time by the TXSTMP register. The software reads its value and sends the transmission time in a
Follow_Up packet.
The SYNC packet is received by the slave and its reception time is posted to the “timestamp bytes”
in the packet buffer in host memory. The Follow_Up packet is also received and posted to the
software processing. The software uses these parameters to calculate the time gap between
consecutive packets by its own clock compared to the master clock taking the required corrective
action.
7.8.2.2.2 1-step Clocks Calibration Procedure
The I210 supports the 1-step procedure. In 1-step procedure, the hardware inserts the transmission
time to the sent SYNC packets at the master (as follows). All the rest is the same as the 2-step
procedure described above.
The software indicates the SYNC packets to the hardware by setting the 1STEP_1588 flag in the
Advanced Transmit Data Descriptor. Setting this flag, the hardware does the following:
Samples the packet transmission time
Auto-inserts the packet transmission timestamp at the offset defined by the 1588_Offset field
in the TSYNCTXCTL register
Insert the Ethernet CRC while including the timestamp in the CRC calculation
The UDP checksum is not updated by the inserted timestamp. It means that 1-step is limited
for PTP over L2 or PTP over UDP/IPv4 while the UDP checksum is not used (equals to zero).
7.8.2.2.3 2-step Time Synchronization Phase Procedure
The complete synchronization scheme is shown in Figure 7-20. It relies on measured timestamp of
Sync packets transmission and reception by the master and the slave. The scheme is based on the
following two basic assumptions:
The clocks at both nodes are almost identical (achieved in the first step)
Transmission delays between the master to the slave and backward are symmetric
The master’s software sends periodically Sync packets to each slave followed by the Follow_Up packet
(as explained in the Clocks Calibration (2-step procedure). The responds back by sending Delay_Req
packets which are sampled by the slave and the master. The master provides back its parameters
which are used by the slave to calibrate its time. Following are the detailed software hardware steps.
Packet processing in the master and the slave
The master software sends the SYNC packet and Follow_Up packet as described in the Clocks
Calibration (2-step procedure) procedure.
Processing these packets by the slave is also the same as the Clocks Calibration (2-step procedure)
procedure
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The slave software responds back by sending the Delay_Req packet (for those SYNC packets that
the slave “wish” to respond). The Delay_Req packet is indicated to the hardware by setting the
2STEP_1588 flag in the Advanced Transmit Data Descriptor. The transmission time is extracted
from the TXSTMP register the same as the master processes the transmitted SYNC packets.
The Master receives the Delay_Req packet and its reception time is posted to the “timestamp
bytes” in the packet buffer in host memory.
The master software sends back the received timestamp to the slave which has all required
timestamps.
The slave adjust its time according to the following equation (or a low-pass version of the
equation):
Slave Adjust Time = - [(T2-T1) - (T4-T3)] / 2
While using the following notations:
- T1: Sync packet transmission time in the master (based on master clock)
- T2: Sync packet reception time in the slave (based on slave clock)
- T3: Delay_Request transmission time in the slave (based on slave clock)
- T4: Delay_Request reception time in the master (based on master clock)
7.8.2.2.4 1-step Time Synchronization Phase Procedure
Packet processing in the master and the Slave for 1-step procedure is almost identical to the 2-step
procedure as follow:
The master software sends the SYNC packet while indicating it to the hardware by the 1STEP_1588
flag. Doing so, the hardware inserts the transmission time in the SYNC packet.
The slave samples the reception time of the SYNC and extract its transmission time at the master.
From this point the flow is identical to the 2-step procedure.
Figure 7-20. Sync Flow and Offset Calculation
Sync
Follow_Up (T1)
Delay_Response
(T4)
Dely_Req
Master Slave
T1
T2
T3
T4
T0 + delta TT0
Master to Slave
Transmission delay
Slave to Master
Transmission delay
T1, T2, T3 and T4
are sampled by the HW
Calculated delta T = [(T2-T1)-(T4-T3)]/2
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7.8.2.3 TimeSync Indications in Receive and Transmit Packet Descriptors
Certain indications are transferred between software and hardware regarding PTP packets. These
indications are enabled when the Disable systime bit in the TSAUXC register is cleared. Further more,
transmit timestamping is enabled by the TSYNCTXCTL.EN flag. Received packets for captured time are
identified according to the TSYNCRXCTL.Type and CTRLT and MSGT fields in the TSYNCRXCFG register.
2-step SYNC and Delay_Req packet transmission: The software sets the 2STEP_1588 bit in the
Advanced Transmit Data Descriptor. The hardware samples the transmission time in the TXSTMP
register. The software reads it for every packet and used the transmission time as required.
1-step SYNC packet transmission: On the transmit path the software sets the 1STEP_1588 bit in
the Advanced Transmit Data Descriptor. It should also set previously the 1588_Offset field in the
TSYNCTXCTL register. The hardware samples the transmission time and inserts it in the transmitted
packet at the offset defined by the 1588_Offset field. The software should prepare the space in the
transmitted packet by filling it with zero’s while the hardware replaces these zero’s by the transmission
timestamp. The transmission time stamp is an 80-bit field while the 32 LS bits specify the transmission
time in nsec units and the upper 48 bits specify the time in second units. Note that the 1588 timer in
the I210 contains only 32 bits that specify the second units. The additional upper 16 bits are taken from
the static SYSTIMTM register which is set by software (expected to be zero at all times). Timestamp
transmission on the wire is as follows: The MS byte of the SYSTIMTM register is transmitted first while
the LS byte of the nsec units is transmitted last (as shown in Table 7-67).
Packet reception: PTP packet identification is described in Section 7.8.5. L2 packets that are
identified by the EtherType are indicated by the “packet type” field in the receive descriptor. Those
packets that the hardware samples its reception time are also indicated by the TS or TSIP flags in the
advanced receive descriptors. Selecting between TS or TSIP reporting is controlled by the Timestamp
flag in the SRRCTL[n] register (per receive queue). If the TS flag is set, the packet reception time is
sampled by the hardware in the RXSTMPL/H registers. These registers are locked until the software
reads its value. If the TSIP flag is set, the packet reception time is posted to the packet buffer in host
memory as shown in Section 7.1.6.
7.8.3 Hardware Time Sync Elements
All time sync hardware is initialized as defined in the registers section upon MAC reset. The time sync
logic is enabled if the TSAUXC.Disable systime flag is cleared.
The 1588 logic includes multiple registers larger than 32 bits which are indicated as xxxL (Low portion -
LS) and xxxH (High portion - MS). When software accesses these registers (either read or write) it
should access first the xxxL register (LS) and only then the xxxH register (MS). Accessing the xxxH
might impact the hardware functionality which should be triggered only after both portions of the
register are valid.
7.8.3.1 Capture Timestamp Mechanism
The timestamp logic is located on transmit and receive paths as close as possible to the PHY interface.
The timestamp is captured at the beginning of the packet as shown in the Figure 7-21. These rules
keep the latency between the captured timestamp and transmission time as deterministic as possible.
The 1588 logic is functional at all link speeds; however, the latency parameters characterized at this
time is only for 100 Mb/s. The measured latency parameters in a stand-alone setup are listed in
Table 7-62. When measured against a commercial link partner using an arithmetic mean and
exponential smoothing, a shift of approximately 40 ns is used as listed in Table 7-63.
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Table 7-62. Packet Timestamp Sampling Latency at 100 Mb/s (Stand-alone Setup)
Table 7-63. Packet Timestamp Sampling Latency at 100 Mb/s (Arithmetic Mean and
Exponential Smoothing)
Figure 7-21. Timestamp Point
7.8.3.2 1588 Timer Registers: SYSTIM, TIMADJ and TIMINCA
The SYSTIM is a 96-bit register is composed of: SYSTIMR, SYSTIML and SYSTIMH registers: The
SYSTIMR register holds the sub ns fraction, the SYSTIML register holds the ns fraction and the
SYSTIMH register holds the second fraction of the time (note that the upper two bits of the SYSTIML
register are always zero while the max value of this register is 999,999,999 dec). When synchronized,
the SYSTIM registers defines the absolute time relative to PTP “epoch” which is January 1st 1970
00:00:00 International Atomic Time (TAI).
Initial Setting - Setting the initial time is done by direct write access to the SYSTIM register.
Software should first set the SYSTIML register and then set the SYSTIMH register. Setting the
SYSTIMR register is meaningless while it represents sub ns units. It is recommended to disable the
timer at programming time as follows:
Parameter Min/Max
Latency Comment
Tx timestamp to
start of SFD on
MDI 984/1024 ns
Min/max values represent a possible variance over reset or link up/down events. The latency is
measured with minimal PHY FIFO depth by setting bits 15:14 in the PHY TX FIFO register (MAC
Specific Control Register 1 - Page 2, Register 16). Setting the PHY Tx FIFO to other values
increase the delay by an 8-bit time for each increment of the FIFO size.
Start of SDF on
MDI to Rx
timestamp 2148/2228 ns The min/max numbers represent possible jitter due to synchronization between receive and
transmit clock domains.
Parameter Average Comment
Tx timestamp to start of SFD on MDI 1044 ns The range (max minus min) values measured for the Tx and Rx latency
parameters are similar to the measured parameters in a stand-alone
setup.
Start of SDF on MDI to Rx timestamp 2133 ns
Tx + Rx latency 3177 ns
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Run Time - During run time the SYSTIM timer value in the SYSTIMH, SYSTIML and SYSTIMR
registers, is updated periodically each 8 nS clock cycle according to the following formula:
Define: INC_TIME = 8 nsec +/- TIMINCA.Incvalue * 2-32 nsec. Add or subtract the
TIMINCA.Incvalue is defined by TIMINCA.ISGN (while 0b means Add and 1b means Subtract)
Then: SYSTIM = SYSTIM + INC_TIME
Reading the SYSTIM register by software is done by the following sequence:
Read the SYSTIMRregister
Read the SYSTIMLregister
Read the SYSTIMHregister
Dynamic update of SYSTIM registers can be done by using the TIMADJ registers by the following
flow. It can also be done by adjusting the INC_TIME as described later in this section. Adjusting the
time by TIMADJ are meant to be used only when the time difference between the master and the
slave are small enough (at least smaller than one 8th of the time between consecutive SYNC
cycles). If this assumption is incorrect, than this process might take longer time than the SYNC
cycle to take effect. If this is an issue, software might need to set the SYSTIM by direct access as
described in the “Initial Setting” phase:
Write the Tadjust value and its Sign to the TIMADJ register (the Sign bit indicates if the Tadjust
value should be added or subtracted)
Following the write access to the TIMADJ register, the hardware repeats the following two steps
at each 8 nsec clock as long as the Tadjust > zero.
SYSTIM = SYSTIM + INC_TIME +/- 1 nsec. Add or subtract 1 nsec is defined by
TIMADJ.Sign (while 0bmeans Add and 1b means Subtract)
Tadjust = Tadjust - 1 nsec
Note that the SYSTIM timer is incremented monotonically at all times. When updating the
SYSTIM by the TIMADJ and concurrent non-zero TIMINCA, the SYSTIM is incremented each
clock by steps in the range of 6.5ns up to 9.5ns units.
As shown above, the time adjustment might take multiple clocks. Software might write a new
value to the TIMADJ register before the hardware completed the previous adjustment. In such
a case, the new value written by software, overrides the above equation. If such a race is not
desired, the software could check that the previous adjustment is completed by one of the
following methods:
Wait enough time before accessing the TIMADJ register which guarantees that the previous
update procedure is completed.
Poll the matched TSICR.TADJ flag which is set by the hardware each time the update
procedure is completed.
Enable the TADJ interrupt by setting the TADJ flag in the TSIM register and enable timesync
interrupts by setting the Time_Sync flag in the IMS register. The TADJ interrupt indicates
that the hardware completed the adjustment procedure. This method is unlikely to be used
in nominal operation since the expected adjustments are in the sub s range.
Dynamic update of SYSTIM registers can also be done by updating the INC_TIME. Using INC_TIME,
the time in the slave is updated in a more gradual manner and in most cases it results in a more
accurate timer. INC_TIME should be updated as a function of the required Tadjust and the time gap
between consecutive SYNC cycles that generated this Tadjust value. A possible equation for the
INC_TIME for the next SYNC cycle can be as follows:
INC_TIME (n+1) = INC_TIME (n) * (T4-T1)/(T3-T2) + Factor * (T4 - (T3 + Tdelay)) / Tcycle
while
All time parameters are expressed in ns units
INC_TIME = 8 +/- TIMINCA.Incvalue * 2-32 [ns]
INC_TIME (n) and INC_TIME (n+1) are the INC_TIME used for the current Tcycle and the
calculated INC_TIME that should be used in the next Tcycle respectively
Tcycle is the time between consecutive (Sync request + Delay request) cycles
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Tdelay is the transmission delay from the slave to the master. It can be calculated using T1...T4
as follow: Tdelay = [(T2-T1) + (T4-T3)] / 2
The factor is a parameter that affects the speed of convergence. For a clock frequency of 125
MHz, an optimized factor equals 8. Table 7-65 lists the expected convergence time for some
cases while Tcycle equals 1 second and the slave-to-master clock frequency difference equals
100 ppm.
7.8.3.3 Target Time
The two target time registers TRGTTIML/H0 and TRGTTIML/H1 enable generating a time triggered
event to external hardware using one of the SDP pins according to the setup defined in the TSSDP and
TSAUXC registers (See Section 8.15.13 and Section 8.15.25). Each target time register is structured
the same as the SYSTIML/H registers. If the value of SYSTIML/H is equal or larger than the value of the
TRGTTIML/H registers, a change in level or a pulse is generated on the matched SDP outputs.
7.8.3.3.1 SYSTIM Synchronized Level Change Generation on SDP Pins
To generate a level change on one of the SDP pins when System Time (SYSTIM) reaches a pre-defined
value, the driver should do the following:
1. Select a specific SDP pin by setting the TSSDP.TS_SDPx_EN flag to 1b(while ‘x’ is 0, 1, 2 or 3).
2. Assign a target time register to the selected SDP by setting the TSSDP.TS_SDPx_SEL field to 00b or
01b if level change should occur based on TRGTTIML/H0 or TRGTTIML/H1, respectively.
3. Define the selected SDPx pin as output, by setting the appropriate SDPx_IODIR bit (while ‘x’ is 0, 1,
2, or 3) in the CTRL or CTRL_EXT registers.
4. Program the target time TRGTTIML/Hx (while ‘x’ is 0b or 1b) to the required event time.
5. Program the TRGTTIML/Hx to “Level Change” mode by setting the TSAUXC.PLSG bit to 0b and
TSAUXC.EN_TTx bit to 1b (while ‘x’ is 0b or 1b).
6. When the SYSTIML/H registers becomes equal or larger than the selected TRGTTIML/H registers,
the selected SDP changes its output level.
7.8.3.3.2 SYSTIM Synchronized Pulse Generation on SDP Pins
An output pulse can be generated by using one of the target time registers to define the beginning of
the pulse and the other target time registers to define the pulse completion time. To generate a pulse
on one of the SDP pins when System Time (SYSTIM) reaches a pre-defined value, the driver should do
the following:
1. Select a specific SDP pin by setting the TSSDP.TS_SDPx_EN flag to 1b (while ‘x’ is 0, 1, 2 or 3).
2. Select the target time register for the selected SDP that defines the beginning of the output pulse.
It is done by setting the TSSDP.TS_SDPx_SEL field to 00b or 01b if level change should occur when
SYSTIML/H equals TRGTTIML/H0 or TRGTTIML/H1, respectively.
3. Define the selected SDPx pin as output, by setting the appropriate SDPx_IODIR bit (while ‘x’ is 0, 1,
2, or 3) in the CTRL or CTRL_EXT registers.
4. Program the target time TRGTTIML/Hx (while ‘x’ is 0b or 1b) to the required event time. The
registers indicated by the TSSDP.TS_SDPx_SEL define the leading edge of the pulse and the other
ones define the trailing edge of the pulse.
5. Program the TRGTTIML/Hx defined by the TSSDP.TS_SDPx_SEL to “Start of Pulse” mode by setting
the TSAUXC.PLSG bit to 1b and TSAUXC.EN_TTx bit to 1b (while ‘x’ is 0b or 1b). The other
TRGTTIML/Hx register should be set to Level Change mode by setting the TSAUXC.PLSG bit to 0b
and TSAUXC.EN_TTx bit to 1b (while ‘x’ is 0b or 1b).
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6. When the SYSTIML/H registers becomes equal or larger than the TRGTTIML/H registers that define
the beginning of the pulse, the selected SDP changes its level. Then, when the SYSTIML/H registers
becomes equal or larger than the other TRGTTIML/H registers (that define the trailing edge of the
pulse), the selected SDP changes its level back.
7.8.3.3.3 Synchronized Output Clock on SDP Pins
The I210 supports driving a programmable Clock on the SDP pins (up to two output clocks). The output
clocks generated are synchronized to the global System time registers (SYSTIM). The Target Time
registers (TRGTTIML/H0 or TRGTTIML/H1) can be used for the clock output generation. To start an
clock output on one of the SDP pins when System Time (SYSTIM) reaches a pre-defined value, the
driver should do the following:
1. Select a specific SDP pin by setting the TSSDP.TS_SDPx_EN flag to 1b (while ‘x’ is 0, 1, 2 or 3).
2. Select the target time register for a selected SDP, by setting the TSSDP.TS_SDPx_SEL field to 10b
or 11b if output clock should occur based on TRGTTIML/H0 or TRGTTIML/H1 respectively.
3. Program the matched FREQOUT0/1 register to define clock half cycle time. Note that in the general
case the maximum supported half cycle time of the synchronized output clock is 70 ms. A slower
output clock can be generated by the Synchronized Level Change scheme described in
Section 7.8.3.3.1. In this option, software should trigger the output level change time periodically
for each clock transition. Slower half cycle time than 70msec can be programmed also as long as
the output clock is synchronized to whole seconds as follow (useful specifically for generating a 1Hz
clock):
a. The clock should start at a programmable time (as described in bullet 5 below)
b. The starting time plus 'n' times the value of the programmed FREQOUT0/1 must be whole
number of seconds (for 'specific' values of 'n')
c. Permitted values for the FREQOUT0/1 register that can meet the above conditions are:
125,000,000 decimal, 250,000,000 decimal and 500,000,000 decimal (equals to 125msec,
250msec and 500msec respectively)
4. Define the selected SDPx pin as output, by setting the appropriate SDPx_IODIR bit (while ‘x’ is 0, 1,
2, or 3) in the CTRL or CTRL_EXT registers.
5. TRGTTIML/Hx should be set to the required start time of the low phase of the clock.
6. Enabled the clock operation by setting the relevant TSAUXC.EN_CLK0/1 bit to 1b.
The clock out initially drives a logic zero level on the selected SDP. When SYSTIM reaches TRGTTIM,
hardware begins an endless loop of the following two steps:
1. Increment the used TRGTTIML/Hx by FREQOUT.
2. When SYSTIM is equal or larger than the TRGTTIM, the SDP reverts its output level.
7.8.3.4 Time Stamp Events
Upon a change in the input level of one of the SDP pins that was configured to detect Time stamp
events using the TSSDP register, a time stamp of the system time is captured into one of the two
auxiliary time stamp registers (AUXSTMPL/H0 or AUXSTMPL/H1). Software enables the timestamp of
input event as follow:
1. Define the sampled SDP on AUX time ‘x(‘x’ = 0b or 1b) by setting the TSSDP.AUXx_SDP_SEL field
while setting the matched TSSDP.AUXx_TS_SDP_EN bit to 1b.
2. Set also the TSAUXC.EN_TSx bit (‘x’ = 0b or 1b) to 1b to enable “timestamping”.
Following a transition on the selected SDP, the hardware does the following:
1. The SYSTIM registers (low and high) are latched to the selected AUXSTMP registers (low and high)
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2. The selected AUTT0 or AUTT1 flags are set in the TSICR register. If the AUTT interrupt is enabled by
the TSIM register and the 1588 interrupts are enabled by the Time_Sync flag in the ICR register
then an interrupt is asserted as well.
After the hardware reports that an event time was latched, the software should read the latched time in
the selected AUXSTMP registers. Software should read first the Low register and only then the High
register. Reading the high register releases the registers to sample a new event.
7.8.4 Time SYNC Interrupts
Time Sync related interrupts can be generated by programming the TSICR and TSIM registers. The
TSICR register logs the interrupt cause and the TSIM register enables masking specific TSICR bits.
Detailed description of the Time Sync interrupt registers can be found in Section 8.16. Occurrence of a
Time Sync interrupt sets the ICR.Time_Sync interrupt bit.
7.8.5 PTP Packet Structure
The time sync implementation supports both the 1588 V1 and V2 PTP frame formats. The V1 structure
can come only as UDP payload over IPv4 while the V2 can come over L2 with its Ethertype or as a UDP
payload over IPv4 or IPv6. The 802.1AS uses only the layer 2 V2 format. The PTP frame formats over
L2 and over UDP are listed in the Table 7-64 and Table 7-65. The PTP V1 and V2 message formats are
listed in the Table 7-66 followed by SYNC packet format in Table 7-67. Table 7-68 and Table 7-69 list
the relevant fields that identify the PTP message that are the Control field for V1 message and the
MessageType field for V2 message. Then, Table 7-70 lists the device settings required to identify the
PTP packets.
Table 7-64. PTP Message Over Layer 2
Ethernet (L2) VLAN (Optional) PTP Ethertype PTP message
Table 7-65. PTP Message Over Layer 4
Ethernet (L2) IP (L3) UDP PTP message
Table 7-66. V1 and V2 PTP Message Header
Offset in Bytes V1 Fields V2 Fields
Bits 7 6 5 4 3 2 1 0 7 6 5 4 3 2 1 0
0versionPTP transport Specific1messageType
1 Reserved versionPTP
2version Network message Length
3
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Note: Only the fields with the bold italic format colored red are of interest to the hardware.
4
Subdomain
domain Number
5 Reserved
6flags
7
8
correctionField
9
10
11
12
13
14
15
16
reserved
17
18
19
20 message Type
Source Port Identity
21 Source communication technology
22
Sourceuuid
23
24
25
26
27
28 source port id
29
30 sequenceId sequenceId
31
32 control control
33 reserved Log Message Interval
34 flags PTP message body. The PTP header plus its
message body must be al least 36 bytes long to be
recognized as a PTP message.
35
1. Should be all zero.
Table 7-67. SYNC Message Structure
Offset in Bytes Length in Bytes Fields
0 34 Message Header (as listed in Table 7-66).
34 10
SYNC Timestamp. On 1-step transmission the timestamp is inserted by the hardware:
The first 2 bytes equals to SYSTIMTM.STM while its MS byte is first and its LS byte is last
The next 4 bytes equals to SYSTIMH while its MS byte is first and its LS byte is last
The next 4 bytes equals to SYSTIML while its MS byte is first and its LS byte is last
Table 7-66. V1 and V2 PTP Message Header (Continued)
Offset in Bytes V1 Fields V2 Fields
Bits 7 6 5 4 3 2 1 0 7 6 5 4 3 2 1 0
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The I210 identifies both L2 and L4 PTP packets for timestamp sampling and defining a specific receive
queue as listed in the Table 7-70.
Table 7-68. Message Decoding for V1 (Control Field at Offset 32)
Enumeration Value
PTP_SYNC_MESSAGE 0
PTP_DELAY_REQ_MESSAGE 1
PTP_FOLLOWUP_MESSAGE 2
PTP_DELAY_RESP_MESSAGE 3
PTP_MANAGEMENT_MESSAGE 4
reserved 5–255
Table 7-69. Message Decoding for V2 (MessageType Field at Offset 0)
MessageType Message Type Value (hex)
PTP_SYNC_MESSAGE Event 0
PTP_DELAY_REQ_MESSAGE Event 1
PTP_PATH_DELAY_REQ_MESSAGE Event 2
PTP_PATH_DELAY_RESP_MESSAGE Event 3
Unused Event 4-7
PTP_FOLLOWUP_MESSAGE General 8
PTP_DELAY_RESP_MESSAGE General 9
PTP_PATH_DELAY_FOLLOWUP_MESSAGE General A
PTP_ANNOUNCE_MESSAGE General B
PTP_SIGNALLING_MESSAGE General C
PTP_MANAGEMENT_MESSAGE General D
Unused General E-F
Table 7-70. Enabling Receive Timestamp
Functionality Register Field Setting Options
Enable receive timestamp TSYNCRXCTL En En = 1b (must be set in all the following options).
Sampled V1 Control value TSYNCRXCFG CTRLT The CTRLT defined the recognized V1 Control field. This field
must be defined if V1 packets recognition is required.
Sampled V2 MessageType value TSYNCRXCFG MSGT The MSGT defined the recognized V2 MessageType field. This
field must be defined if V2 packets recognition is required.
Enable all packets for
timestamp TSYNCRXCTL Type Type equals to 100b enables sampling all packets. Useful only
when posting the timestamp to the packet buffer in host
memory, enabled per queue by the SRRCTL[n].Timestamp.
Enable L2 1588 packets for
timestamp sampling
TSYNCRXCTL Type
Type equals to 000b or 010b enable V2 packets with
MessageType equals to MSGT as well as DELAY_REQ and
DELAY_RESP packets.
Type equals to 101b enable all V2 packets with Message Type
bit 3 zero (means any event packets)
ETQF[n] EType
Filter enable The EType on one of the enabled ETQF registers (Filter enable
is ‘1’) should be set to the 1588 EtherType (equals to 0x88F7)
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7.9 Statistic Counters
The I210 supports different statistic counters as described in Section 8.18. The statistic counters can be
used to create statistic reports as required by different standards. The I210 statistic counters allow
support for the following standards:
IEEE 802.3 clause 30 management – DTE section.
NDIS 6.0 OID_GEN_STATISTICS.
RFC 2819 – RMON Ethernet statistics group.
Linux Kernel (version 2.6) net_device_stats
The following section describes the match between the internal the I210 statistic counters and the
counters requested by the different standards.
7.9.1 IEEE 802.3 Clause 30 Management
The I210 supports the Basic and Mandatory Packages defined in clause 30 of the IEEE 802.3
specification. Table 7-71 lists the matching between the internal statistics and the counters requested
by these packages.
In addition, part of the recommended package is also implemented as listed in Table 7-72.
Enable 1588 packets over UDP
for timestamp sampling
TSYNCRXCTL Type
Type equals to 001b enables V1 packets with Control field
equals to CTRLT parameter
Type equals to 010b enables V2 packets with MessageType
fields equals to MSGT parameter as well as DELAY_REQ and
DELAY_RESP packets.
Type equals to 101b enables all V2 packets with Message Type
bit 3 zero (which means any event packets)
TTQF[n] Protocol
1588 time stamp Defines a UDP protocol (Protocol field = 17 dec).
The “1588 time stamp” flag is active
IMIR[n] Destination Port
PORT_BP Define PTP event messages (Destination Port = 319 dec) and
the PORT_BP is cleared
Define specific receive queue for
the L2 1588 packets ETQF[n] Rx Queue
Queue Enable Setting the “Queue Enable” on the same ETQF register as
above, the receive queue is defined by the “Rx Queue” field.
Define specific receive queue for
1588 packets over UDP TTQF[n] Rx Queue
Queue Enable Setting the “Queue Enable” on the same TTQF register as
above, the receive queue is defined by the “Rx Queue” field.
Table 7-71. IEEE 802.3 Mandatory Package Statistics
Mandatory Package Capability I210 Counter Notes and Limitations
FramesTransmittedOK GPTC The I210 doesn’t include flow control packets.
SingleCollisionFrames SCC
MultipleCollisionFrames MCC
FramesReceivedOK GPRC The I210 doesn’t include flow control packets.
FrameCheckSequenceErrors CRCERRS
AlignmentErrors ALGNERRC
Table 7-70. Enabling Receive Timestamp
Functionality Register Field Setting Options
Ethernet Controller I210 —Inline Functions
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Part of the optional package is also implemented as described in Table 7-76.
7.9.2 OID_GEN_STATISTICS
The I210 supports the part of the OID_GEN_STATISTICS as defined by Microsoft* NDIS 6.0
specification. Table 7-74 lists the matching between the internal statistics and the counters requested
by this structure.
Table 7-72. IEEE 802.3 Recommended Package Statistics
Recommended package capability I210 Counter Notes and Limitations
OctetsTransmittedOK GOTCH/GOTCL The I210 counts also the DA/SA/LT/CRC as part of the octets. The
I210 doesn’t count Flow control packets.
FramesWithDeferredXmissions DC
LateCollisions LATECOL
FramesAbortedDueToXSColls ECOL
FramesLostDueToIntMACXmitError HTDMPC The I210 counts the excessive collisions in this counter, while 802.3
increments no other counters, while this counter is incremented
CarrierSenseErrors TNCRS
The I210 doesn’t count cases of CRS de-assertion in the middle of
the packet. However, such cases are not expected when the internal
PHY is used.
In The I210 this counter is not operational in 100 Mbps half duplex
mode.
OctetsReceivedOK TORL+TORH The I210 counts also the DA/SA/LT/CRC as part of the octets.
Doesn’t count Flow control packets.
FramesLostDueToIntMACRcvError RNBC
SQETestErrors N/A
MACControlFramesTransmitted N/A
MACControlFramesReceived N/A
UnsupportedOpcodesReceived FCURC
PAUSEMACCtrlFramesTransmitted XONTXC + XOFFTXC
PAUSEMACCtrlFramesReceived XONRXC +
XOFFRXC
Table 7-73. IEEE 802.3 Optional Package Statistics
Optional package capability I210 Counter Notes
MulticastFramesXmittedOK MPTC The I210 doesn’t count FC packets
BroadcastFramesXmittedOK BPTC
MulticastFramesReceivedOK MPRC The I210 doesn’t count FC packets
BroadcastFramesReceivedOK BPRC
InRangeLengthErrors LENERRS
OutOfRangeLengthField N/A Packets parsed as Ethernet II packets
FrameTooLongErrors ROC + RJC
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7.9.3 RMON
The I210 supports the part of the RMON Ethernet statistics group as defined by IETF RFC 2819.
Table 7-75 lists the matching between the internal statistics and the counters requested by this group.
Table 7-74. Microsoft* OID_GEN_STATISTICS
OID entry I210 Counters Notes
ifInDiscards; CRCERRS + RLEC + RXERRC +
MPC + RNBC + ALGNERRC
ifInErrors; CRCERRS + RLEC + RXERRC +
ALGNERRC
ifHCInOctets; GORCL/GOTCL
ifHCInUcastPkts; GPRC - MPRC - BPRC
ifHCInMulticastPkts; MPRC
ifHCInBroadcastPkts; BPRC
ifHCOutOctets; GOTCL/GOTCH
ifHCOutUcastPkts; GPTC - MPTC - BPTC
ifHCOutMulticastPkts; MPTC
ifHCOutBroadcastPkts; BPTC
ifOutErrors; ECOL + LATECOL
ifOutDiscards; ECOL
ifHCInUcastOctets; N/A
ifHCInMulticastOctets; N/A
ifHCInBroadcastOctets; N/A
ifHCOutUcastOctets; N/A
ifHCOutMulticastOctets; N/A
ifHCOutBroadcastOctets; N/A
Table 7-75. RMON Statistics
RMON statistic I210 Counters Notes
etherStatsDropEvents MPC + RNBC
etherStatsOctets TOTL + TOTH
etherStatsPkts TPR
etherStatsBroadcastPkts BPRC
etherStatsMulticastPkts MPRC The I210 doesn’t count FC packets
etherStatsCRCAlignErrors CRCERRS + ALGNERRC
etherStatsUndersizePkts RUC
etherStatsOversizePkts ROC
etherStatsFragments RFC Should count bad aligned fragments as well
etherStatsJabbers RJC Should count bad aligned jabbers as well
etherStatsCollisions COLC
etherStatsPkts64Octets PRC64 RMON counts bad packets as well
etherStatsPkts65to127Octets PRC127 RMON counts bad packets as well
etherStatsPkts128to255Octets PRC255 RMON counts bad packets as well
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7.9.4 Linux net_device_stats
The I210 supports part of the net_device_stats as defined by Linux Kernel version 2.6 (defined in
<linux/netdevice.h>). Table 7-76 lists the matching between the internal statistics and the counters
requested by this structure.
etherStatsPkts256to511Octets PRC511 RMON counts bad packets as well
etherStatsPkts512to1023Octets PRC1023 RMON counts bad packets as well
etherStatsPkts1024to1518Octets PRC1522 RMON counts bad packets as well
Table 7-76. Linux net_device_stats
net_device_stats field I210 Counters Notes
rx_packets GPRC The I210 doesn’t count flow controls - can be accounted for by
using the XONRXC and XOFFRXC counters
tx_packets GPTC The I210 doesn’t count flow controls - can be accounted for by
using the XONTXC and XOFFTXC counters
rx_bytes GORCL + GORCH
tx_bytes GOTCL + GOTCH
rx_errors CRCERRS + RLEC + RXERRC +
ALGNERRC
tx_errors ECOL + LATECOL
rx_dropped N/A
tx_dropped N/A
multicast MPTC
collisions COLC
rx_length_errors RLEC
rx_over_errors N/A
rx_crc_errors CRCERRS
rx_frame_errors ALGNERRC
rx_fifo_errors HRMPC + Sum (RQDPC)
rx_missed_errors MPC
tx_aborted_errors ECOL
tx_carrier_errors N/A
tx_fifo_errors N/A
tx_heartbeat_errors N/A
tx_window_errors LATECOL
rx_compressed N/A
tx_compressed N/A
Table 7-75. RMON Statistics (Continued)
RMON statistic I210 Counters Notes
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359
7.9.5 Statistics Hierarchy
The following diagram shows the relations between the packet flow and the different statistic counters.
Figure 7-24. Flow Statistics Flow Statistics
L2 filtering
Errors
Error packets
SYMERRS
SCVPC
ALGNERRC
CRCERRS
LENERRS
Good packets received
GPRC, BPRC, MPRC
Manageability filtering
Manageability
only packets
MNGPRC
Queues
Drop of queues
S(RQDPC[7:0])
Packets received by host
RPTHC,
Packet Received by host from BMC
B2OGPRC
Total Packet Received
TPR
Flow control detection
Flow control packets
XONRXC
XOFFRXC
Packet buffer full Missed packet
MPC
Manageability
Rx
BMC 2 OS
traffic
B2OSPC
MAC errors
(excessive collisions
Link down)
GPTC (Only if Tx is enabled)
Manageability
Traffic out
MNGPTC
Packets Sent by host
HGPTC,
Packets Sent to BMC
O2BSPC
Total Packet Sent
TPT
Flow control packets
Flow control packets
XONTXC
XOFFTXC
MAC drops
HTDPMC
OS to BMC packets
OOB Receive
BMNGPRC
O2BGPTC
OOB Transmit
BMNGPTC
Manageability
Tx
MNG Drop packets (Tx)
BMTPDC
MNG Drop Packet (Rx)
BMRPDC
MC
Host
Network
Packet Buffer
Drop of queues
S(TQDPC[7:0])
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Programming Interface — Ethernet Controller I210
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8.0 Programming Interface
8.1 Introduction
This section details the programmer visible state inside the I210. In some cases, it describes hardware
structures invisible to software in order to clarify a concept. The I210's address space is mapped into
four regions with PCI Base Address registers described in Section 9.3.11. These regions are listed in
Table 8-1.
The internal register/memory space is described in the following sections. The PHY registers are
accessed through the MDIO interface.
8.1.1 Memory, I/O Address and Configuration Decoding
8.1.1.1 Memory-Mapped Access to Internal Registers and Memories
The internal registers and memories might be accessed as direct memory-mapped offsets from the
base address register (BAR0 or BAR 0/1; refer to Section 9.3.11). Refer to Section 8.1.3 for the
appropriate offset for each specific internal register.
8.1.1.2 Memory-Mapped Access to Flash
The external Flash can be accessed using direct memory-mapped offsets from the Memory Base
Address register (BAR0 in 32-bit addressing or BAR0/BAR1 in 64-bit addressing; refer to
Section 9.3.11). For accesses, the offset from the Memory BAR minus 128 KB corresponds to the
physical address within the external Flash device. Memory mapped accesses to the external Flash
device are enabled when the value of the FLBAR_Size field in the Flash (refer to Section 6.2.25) is not
000b.
Table 8-1. Address Space Regions
Addressable Content How Mapped Size of Region
Internal registers, memories and Flash (Memory BAR) Direct memory-mapped 128 KB + Flash Size1, 2
1. The Flash size is defined by the BARCTRL register.
2. The Flash space in the Memory CSR and Expansion ROM Base Address are mapped to different Flash memory regions. Accesses
to the Memory BAR at offset 128 KB are mapped to the Flash device at offset 0x0, while accesses to the Expansion ROM at offset
0x0 are mapped to the fixed Flash region that starts at NVM word address 0x001000. See Section 3.3.3.1. The Expansion ROM
region has a fixed provisioned size of 512 KB.
Flash (optional) Direct memory-mapped 64 KB to 8 MB
Expansion ROM (optional) Direct memory-mapped 512 KB 2
Internal registers and memories, Flash (optional) I/O window mapped 32 bytes3
3. The internal registers and memories can be accessed though I/O space indirectly as explained in the sections that follow.
MSI-X (optional) Direct memory-mapped 16 KB
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8.1.1.3 Memory-Mapped Access to MSI-X Tables
The MSI-X tables can be accessed as direct memory-mapped offsets from the base address register
(BAR3; refer to Section 9.3.11). Refer to Section 8.1.3 for the appropriate offset for each specific
internal MSI-X register.
8.1.1.4 Memory-Mapped Access to Expansion ROM
The Expansion/Option ROM module located in the external Flash (refer to Section 3.3.9.1) can be
accessed as a memory-mapped Expansion ROM. Accesses to offsets starting from the Expansion ROM
Base address reference the Flash, provided that access is enabled through the LAN Boot Disable bit in
NVM Initialization Control 3 word, and if the Expansion ROM Base Address register contains a valid
(non-zero) base memory address.
8.1.1.5 I/O-Mapped Access to Internal Registers and Memories
To support pre-boot operation (prior to the allocation of physical memory base addresses), all internal
registers and memories can be accessed using I/O operations. I/O accesses are supported only if an I/
O Base Address is allocated and mapped (BAR2; refer to Section 9.3.11), the BAR contains a valid
(non-zero value), and I/O address decoding is enabled in the PCIe configuration.
When an I/O BAR is mapped, the I/O address range allocated opens a 32-byte window in the system I/
O address map. Within this window, two I/O addressable registers are implemented: IOADDR and
IODATA. The IOADDR register is used to specify a reference to an internal register or memory, and
then the IODATA register is used as a window to the register or memory address specified by IOADDR:
8.1.1.5.1 IOADDR (I/O Offset 0x00)
The IOADDR register must always be written as a Dword access. Writes that are less than 32 bits are
ignored. Reads of any size return a Dword of data; however, the chipset or CPU might only return a
subset of that Dword.
For software programmers, the IN and OUT instructions must be used to cause I/O cycles to be used on
the PCIe bus. Because writes must be to a 32-bit quantity, the source register of the OUT instruction
must be EAX (the only 32-bit register supported by the OUT command). For reads, the IN instruction
can have any size target register, but it is recommended that the 32-bit EAX register be used.
Because only a particular range is addressable, the upper bits of this register are hard coded to zero.
Bits 31 through 20 cannot be written to and are always read back as 0b.
At hardware reset (LAN_PWR_GOOD) or PCI reset, this register value resets to 0x00000000. Once
written, the value is retained until the next write or reset.
Table 8-2. IOADDR and IODATA in I/O Address Space
Offset Abbreviation Name RW Size
0x00 IOADDR
Internal register, internal memory, or Flash location address.
0x00000-0x1FFFF – Internal registers and memories.
0x20000-0xFFFFFFFF – Undefined.
RW 4 bytes
0x04 IODATA Data field for reads or writes to the internal register, internal
memory, or Flash location as identified by the current value in
IOADDR. All 32 bits of this register can be read or written to. RW 4 bytes
0x08 – 0x1F Reserved Reserved. RO 4 bytes
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8.1.1.5.2 IODATA (I/O Offset 0x04)
The IODATA register must always be written as a Dword access when the IOADDR register contains a
value for the internal register and memories (for example, 0x00000-0x1FFFC). In this case, writes that
are less than 32 bits are ignored.
Reads to IODATA of any size returns a Dword of data. However, the chipset or CPU might only return a
subset of that Dword.
For software programmers, the IN and OUT instructions must be used to cause I/O cycles to be used on
the PCIe bus. Where 32-bit quantities are required on writes, the source register of the OUT instruction
must be EAX (the only 32-bit register supported by the OUT command).
Writes and reads to IODATA when the IOADDR register value is in an undefined range (0x20000-
0xFFFFFFFC) should not be performed. Results cannot be determined.
Notes: There are no special software timing requirements on accesses to IOADDR or IODATA. All
accesses are immediate, except when data is not readily available or acceptable. In this case,
the I210 delays the results through normal bus methods (for example, split transaction or
transaction retry).
Because a register/memory read or write takes two I/O cycles to complete, software must
provide a guarantee that the two I/O cycles occur as an atomic operation. Otherwise, results
can be non-deterministic from the software viewpoint.
Software should access CSRs via I/O address space or configuration address space but should
not use both mechanisms at the same time.
8.1.1.5.3 Undefined I/O Offsets
I/O offsets 0x08 through 0x1F are considered to be reserved offsets with the I/O window. Dword reads
from these addresses returns 0xFFFF; writes to these addresses are discarded.
8.1.1.6 Configuration Access to Internal Registers and Memories
To support legacy pre-boot 16-bit operating environments without requiring I/O address space, the
I210 enables accessing CSRs via configuration address space by mapping the IOADDR and IODATA
registers into configuration address space. The registers mapping in this case is listed in Table 8-3.
Note: To enable CSR access via configuration address space the CSR_conf_en Flash bit should be
set (see Section 6.2.15).
Software writes data to an internal CSR via configuration space in the following manner:
1. CSR address is written to the IOADDR register where:
a. Bit 31 (IOADDR.Configuration IO Access Enable) of the IOADDR register should be set to 1b.
Table 8-3. IOADDR and IODATA in Configuration Address Space
Configuration
Address Abbreviation Name RW Size
0x98 IOADDR
Internal register or internal memory location address.
0x00000-0x1FFFF– Internal registers and memories.
0x20000-0x7FFFFF – Undefined.
RW 4 bytes
0x9C IODATA Data field for reads or writes to the internal register or internal memory
location as identified by the current value in IOADDR. All 32 bits of this
register can be read or written to. RW 4 bytes
Ethernet Controller I210 — Programming Interface
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b. Bits 30:0 of IOADDR should hold the actual address of the internal register or memory being
written to.
2. Data to be written is written into the IODATA register.
The IODATA register is used as a window to the register or memory address specified by
IOADDR register. As a result, the data written to the IODATA register is written into the CSR
pointed to by bits 30:0 of the IOADDR register.
3. IOADDR.Configuration IO Access Enable is cleared, to avoid un-intentional CSR read operations
(that might cause a clear by read) by other applications scanning the configuration space.
Software reads data from an internal CSR via configuration space in the following manner:
1. CSR address is written to the IOADDR register where:
a. Bit 31 (IOADDR.Configuration IO Access Enable) of the IOADDR register should be set to 1b.
b. Bits 30:0 of IOADDR should hold the actual address of the internal register or memory being
read.
2. CSR value is read from the IODATA register.
a. The IODATA register is used as a window to the register or memory address specified by IOADDR
register. As a result the data read from the IODATA register is the data of the CSR pointed to by
bits 30:0 of the IOADDR register
3. IOADDR.Configuration IO Access Enable is cleared, to avoid un-intentional CSR read operations
(that might cause a clear by read) by other applications scanning the configuration space.
Notes:
In the event that the CSR_conf_en bit in the PCIe Init Configuration 2 Flash word is
cleared, accesses to the IOADDR and IODATA registers via the configuration address
space are ignored and have no effect on the register and the CSRs referenced by the
IOADDR register. In this case, any read access to these registers returns a value of 0b.
When Function is in D3 state Software should not attempt to access CSRs via the
IOADDR and IODATA configuration registers.
To enable CSR access via configuration space, Software should set bit 31 to 1b
(IOADDR.Configuration IO Access Enable) of the IOADDR register. Software should clear
bit 31 of the IOADDR register after completing CSR access to avoid an unintentional
clear-by-read operation or by another application scanning the configuration address
space.
Bit 31 of the IOADDR register (IOADDR.Configuration IO Access Enable) has no effect
when initiating access via I/O address space.
Software should access CSRs via I/O address space or configuration address space but
should not use both mechanisms at the same time.
8.1.2 Register Conventions
All registers in the I210 are defined to be 32 bits and should be accessed as 32-bit double-words;
however, there are some exceptions to this rule:
Register pairs where two 32-bit registers make up a larger logical size.
Accesses to Flash memory (via Expansion ROM space, secondary BAR space, or the I/O space)
might be byte, word or double word accesses.
Reserved bit positions: Some registers contain certain bits that are marked as reserved. These bits
should never be set to a value of 1b by software. Reads from registers containing reserved bits might
return indeterminate values in the reserved bit-positions unless read values are explicitly stated. When
read, these reserved bits should be ignored by software.
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Reserved and/or undefined addresses: any register address not explicitly declared in this specification
should be considered to be reserved, and should not be written to. Writing to reserved or undefined
register addresses might cause indeterminate behavior. Reads from reserved or undefined
configuration register addresses might return indeterminate values unless read values are explicitly
stated for specific addresses.
Initial values: most registers define the initial hardware values prior to being programmed. In some
cases, hardware initial values are undefined and is listed as such via the text undefined, unknown, or X.
Such configuration values might need to be set via Flash configuration or via software in order for
proper operation to occur; this need is dependent on the function of the bit. Other registers might cite
a hardware default, which is overridden by a higher-precedence operation. Operations that might
supersede hardware defaults might include a valid Flash load, completion of a hardware operation
(such as hardware auto-negotiation), or writing of a different register whose value is then reflected in
another bit.
For registers that should be accessed as 32-bit double words, partial writes (less than a 32- bit double
word) do not take effect (the write is ignored). Partial reads returns all 32 bits of data regardless of
the byte enables.
Note: Partial reads to Read-on-Clear (ICR) registers can have unexpected results since all 32 bits
are actually read regardless of the byte enables. Partial reads should not be done.
All statistics registers are implemented as 32-bit registers. Though some logical statistics
registers represent counters in excess of 32 bits in width, registers must be accessed using
32-bit operations (for example, independent access to each 32-bit field). When reading 64
bits statistics registers, the least significant 32-bit register should be read first.
Refer to the special notes for VLAN Filter Table, Multicast Table Arrays and Packet Buffer Memory,
which appear in the specific register definitions.
The I210 register fields are assigned one of the attributes listed in Table 8-4.
Table 8-4. I210 Register Field Attributes
Attribute Description
RW Read-Write field: Register bits are read-write and can be either set or cleared by software to the desired state.
RWM Read-Write Modified field: Register bits are read-write and can be either set or cleared by software to the desired
state. However, the value of this field might be modified by the hardware to reflect a status change.
RO Read-only register: Register bits are read-only and should not be altered by software. Register bits might be
initialized by hardware mechanisms such as pin strapping, serial Flash or reflect a status of the hardware state.
ROM Read-only Modified field: Register bits are read-only and will be either set or cleared by software upon read
operation. However, the value of this field might be modified by the hardware to reflect a status change.
R/W1C Read-only status, Write-1-to-clear status register: Register bits indicate status when read, a set bit indicating a
status event can be cleared by writing a 1b. Writing a 0b to R/W1C bit has no effect.
Rsv Reserved. Write 0b to these fields and ignore read.
RC Read-only status, Read-to-clear status register: Register bits indicate status when read, a set bit indicating a status
event is cleared by reading it.
SC Self Clear field: a command field that is self clearing. These field are read as zero after the requested operation is
done.
WO Write only field: a command field that can not be read, These field read values are undefined.
RC/W Read-Write status, Read-to-clear status register: Read-to-clear status register. Register bits indicate status when
read. Register bits are read-write and can be either set or cleared by software to the desired state.
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PHY registers use a special nomenclature to define the read/write mode of individual bits in each
register (see Table 8-5).
Note: For all binary equations appearing in the register map, the symbol |” is equivalent to a binary
OR operation.
8.1.2.1 Registers Byte Ordering
This section defines the structure of registers that contain fields carried over the network. Some
examples are L2, L3 and L4 fields.
The following example is used to describe byte ordering over the wire (hex notation):
Last First
...,06, 05, 04, 03, 02, 01, 00
Each byte is sent with the LSbit first. That is, the bit order over the wire for this example is
Last First
..., 0000 0011, 0000 0010, 0000 0001, 0000 0000
The general rule for register ordering is to use host ordering (also called little Endian). Using the
previous example, a 6-byte fields (MAC address) is stored in a CSR in the following manner:
Byte 3 Byte 2 Byte 1 Byte0
DW address (N) 0x03 0x02 0x01 0x00
DW address (N+4) ... ... 0x05 0x04
RC/W1C Read-only status, Write-1-to-clear status register: Read-to-clear status register. Register bits indicate status when
read, a set bit indicating a status event can be cleared by writing a 1b or by reading the register. Writing a 0b to RC/
W1C bit has no effect.
RS Read Set – This is the attribute used for Semaphore bits. These bits are set by read in case the previous values
were 0b. In this case the read value is 0b; otherwise the read value is 1b. Cleared by a write of 0b.
R/W1 Read, Write-1 only register. Once a 1b has been written on a bit, the bit cannot be cleared to 0b.
Table 8-5. PHY Register Nomenclature
Register Mode Description
LH Latched High. Event is latched and erased when read.
LL Latched Low. Event is latched and erased when read. For example, Link Loss is latched when the PHY
Control Register bit 2 = 0b. After read, if the link is good, the PHY Control Register bit 2 is set to 1b.
RO Read Only.
R/W Read and Write.
SC Self-Clear. The bit is set, automatically executed, and then reset to normal operation.
CR Clear after Read. For example, 1000BASE-T Status Register bits 7:0 (Idle Error Counter).
Update Value written to the register bit does not take effect until software PHY reset is executed.
Table 8-4. I210 Register Field Attributes (Continued)
Attribute Description
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The following exceptions use network ordering (also called big Endian). Using the previous example, a
16-bit field (EtherType) is stored in a CSR in the following manner:
Byte 3 Byte 2 Byte 1 Byte0
(DW aligned) ... ... 0x00 0x01
or
(Word aligned) 0x00 0x01 ... ...
The following exceptions use network ordering:
All ETherType fields. For example, the VET EXT field in the VET register, the EType field in the ETQF
register, the EType field in the METF register.
Note: The normal notation as it appears in text books, etc. is to use network ordering. For example,
a MAC address of 00-A0-C9-00-00-00. The order on the network is 00, then A0, then C9, etc;
however, the host ordering presentation would be:
Byte 3 Byte 2 Byte 1 Byte0
DW address (N) 00 C9 A0 00
DW address (N+4) ... ... 00 00
8.1.3 Register Summary
All the I210's non-PCIe configuration registers, except for the MSI-X register, are listed in Table 8-6.
These registers are ordered by grouping and are not necessarily listed in order that they appear in the
address space.
Table 8-6. Register Summary
Offset Alias Offset Abbreviation Name RW
General
0x0000 0x0004 CTRL Device Control Register RW
0x0008 N/A STATUS Device Status Register RO
0x0018 N/A CTRL_EXT Extended Device Control Register RW
0x0020 N/A MDIC MDI Control Register RW
0x0028 N/A FCAL Flow Control Address Low RO
0x002C N/A FCAH Flow Control Address High RO
0x0030 N/A FCT Flow Control Type RW
0x0034 N/A CONNSW Copper/Fiber Switch Control RW
0x0038 N/A VET VLAN Ether Type RW
0x0E04 N/A MDICNFG MDC/MDIO Configuration Register RW
0x0170 N/A FCTTV Flow Control Transmit Timer Value RW
0x0E00 N/A LEDCTL LED Control Register RW
0x1028 N/A I2CCMD SFP I2C Command RW
0x102C N/A I2CPARAMS SFP I2C Parameter RW
0x1040 N/A WDSTP Watchdog Setup Register RW
0x1044 N/A WDSWSTS Watchdog Software RW
0x1048 N/A FRTIMER Free Running Timer RWM
Ethernet Controller I210 — Programming Interface
368
0x104C N/A TCPTimer TCP Timer RW
0x5B70 N/A DCA_ID DCA Requester ID Information Register RO
0x5B50 N/A SWSM Software Semaphore Register RW
0x5B54 N/A FWSM Firmware Semaphore Register RWM
0x5B5C N/A SW_FW_SYNC Software-Firmware Synchronization RWM
0x0E38 N/A IPCNFG Internal PHY Configuration RW
0x0E14 N/A PHPM PHY Power Management RW
Flash-Security Registers
0x12010 0x00010 EEC EEPROM-Mode Control Register RW
0x12014 0x00014 EERD EEPROM-Mode Read Register RW
0x12018 0x1101C EEWR EEPROM-Mode Write Register RW
0x1201C 0x0001C FLA Flash Access Register RW
0x12030 N/A EEMNGCTL Manageability EEPROM-Mode Control Register RW
0x12024 N/A EEARBC EEPROM Block Auto Read Bus Control RW
0x12000 N/A FLASHMODE Flash Mode Register RO
0x12054 N/A FLASHOP Flash OP-Code Register RO
0x12004 N/A FLASHTIME Flash Access Timing Register RO
0x12100 N/A FLBLKBASE Flash Block Base Address RO
0x12104 N/A FLBLKEND Flash Block End Address RO
0x12108 N/A FLFWUPDATE Flash Firmware Code Update RW
0x1210C N/A EEBLKBASE EEPROM Block Base Address RO
0x12110 N/A EEBLKEND EEPROM Block End Address RO
0x12048 N/A FLSWCTL Software Flash Burst Control Register RW
0x1204C N/A FLSWDATA Software Flash Burst Data Register RW
0x12050 N/A FLSWCNT Software Flash Burst Access Counter RW
0x12120 -
0x1221C N/A INVM_DATA[0 - 63] iNVM Data Register R/W1
0x12220 -
0x1229C N/A INVM_LOCK[0 -31] iNVM Lock Register R/W1
0x12324 N/A INVM_PROTECT iNVM Protect Register RW
Interrupts
0x1500 0x00C0 ICR Interrupt Cause Read RC/W1C
0x1504 0x00C8 ICS Interrupt Cause Set WO
0x1508 0x00D0 IMS Interrupt Mask Set/Read RW
0x150C 0x00D8 IMC Interrupt Mask Clear WO
0x1510 0x00E0 IAM Interrupt Acknowledge Auto Mask RW
0x1520 N/A EICS Extended Interrupt Cause Set WO
0x1524 N/A EIMS Extended Interrupt Mask Set/Read RWM
0x1528 N/A EIMC Extended Interrupt Mask Clear WO
0x152C N/A EIAC Extended Interrupt Auto Clear RW
0x1530 N/A EIAM Extended Interrupt Auto Mask RW
0x1580 N/A EICR Extended Interrupt Cause Read RC/W1C
0x1700 -
0x170C N/A IVAR Interrupt Vector Allocation Registers RW
Table 8-6. Register Summary (Continued)
Offset Alias Offset Abbreviation Name RW
Programming Interface — Ethernet Controller I210
369
0x1740 N/A IVAR_MISC Interrupt Vector Allocation Registers - MISC RW
0x1680 -
0x16A0 N/A EITR Extended Interrupt Throttling Rate 0 - 4 RW
0x1514 N/A GPIE General Purpose Interrupt Enable RW
0x5B68 N/A PBACL MSI-X PBA Clear R/W1C
Receive
0x0100 N/A RCTL Rx Control RW
0x2160 0x0168 FCRTL0 Flow Control Receive Threshold Low RW
0x2168 0x0160 FCRTH0 Flow Control Receive Threshold High RW
0x2404 N/A RXPBSIZE Rx Packet Buffer Size RW
0x2460 N/A FCRTV Flow Control Refresh Timer Value RW
0xC000 0x0110,
0x2800 RDBAL[0] Rx Descriptor Base Low Queue 0 RW
0xC004 0x0114,
0x2804 RDBAH[0] Rx Descriptor Base High Queue 0 RW
0xC008 0x0118,
0x2808 RDLEN[0] Rx Descriptor Ring Length Queue 0 RW
0xC00C 0x280C SRRCTL[0] Split and Replication Receive Control Register Queue 0 RW
0xC010 0x0120,
0x2810 RDH[0] Rx Descriptor Head Queue 0 RO
0xC018 0x0128,
0x2818 RDT[0] Rx Descriptor Tail Queue 0 RW
0xC028 0x02828 RXDCTL[0] Receive Descriptor Control Queue 0 RW
0xC014 0x2814 RXCTL[0] Receive Queue 0 DCA CTRL Register RW
0xC040 + 0x40
* (n-1)
0x2900+
0x100 * (n-
1) RDBAL[1 - 3] Rx Descriptor Base Low Queue 1 - 3 RW
0xC044 + 0x40
* (n-1)
0x2904 +
0x100 * (n-
1) RDBAH[1 - 3] Rx Descriptor Base High Queue 1 - 3 RW
0xC048 + 0x40
* (n-1)
0x2908 +
0x100 * (n-
1) RDLEN[1 - 3] Rx Descriptor Ring Length Queue 1 - 3 RW
0xC04C + 0x40
* (n-1)
0x290C +
0x100 * (n-
1) SRRCTL[1 - 3] Split and Replication Receive Control Register Queue 1 - 3 RW
0xC050 + 0x40
* (n-1)
0x2910 +
0x100 * (n-
1) RDH[1 - 3] Rx Descriptor Head Queue 1 - 3 RO
0xC058 + 0x40
* (n-1)
0x2918 +
0x100 * (n-
1) RDT[1 - 3] Rx Descriptor Tail Queue 1 - 3 RW
0xC068 + 0x40
* (n-1)
0x2928 +
0x100 * (n-
1) RXDCTL[1 - 3] Receive Descriptor Control Queue 1 - 3 RW
0xC054 + 0x40
* (n-1)
0x2914 +
0x100 * (n-
1) RXCTL[1 - 3] Receive Queue 1 - 3 DCA CTRL Register RW
0x5000 N/A RXCSUM Receive Checksum Control RW
0x5004 N/A RLPML Receive Long packet maximal length RW
0x5008 N/A RFCTL Receive Filter Control Register RW
Table 8-6. Register Summary (Continued)
Offset Alias Offset Abbreviation Name RW
Ethernet Controller I210 — Programming Interface
370
0x5200- 0x53FC 0x0200-
0x03FC MTA[127:0] Multicast Table Array (n) RW
0x5400 + 8*n 0x0040 +
8*n RAL[0-15] Receive Address Low (15:0) RW
0x5404 + 8 *n 0x0044 + 8
*n RAH[0-15] Receive Address High (15:0) RW
0x5480 –
0x549C N/A PSRTYPE[3:0] Packet Split Receive type (n) RW
0x5600-0x57FC 0x0600-
0x07FC VFTA[127:0] VLAN Filter Table Array (n) RW
0x5818 N/A MRQC Multiple Receive Queues Command RW
0x5C00-0x5C7C N/A RETA Redirection Table RW
0x5C80-0x5CA4 N/A RSSRK RSS Random Key Register RW
0xC038 +
0x40*n N/A DVMOLR[0 - 3] DMA VM Offload Register[0-3] RW
Transmit
0x0400 N/A TCTL Tx Control RW
0x0404 N/A TCTL_EXT Tx Control Extended RW
0x0410 N/A TIPG Tx IPG RW
0x041C N/A RETX_CTL Retry Buffer Control RW
0x3404 N/A TXPBSIZE Transmit Packet Buffer Size RW
0x359C N/A DTXTCPFLGL DMA Tx TCP Flags Control Low RW
0x35A0 N/A DTXTCPFLGH DMA Tx TCP Flags Control High RW
0x3540 N/A DTXMXSZRQ DMA Tx Max Total Allow Size Requests RW
0x355C N/A DTXMXPKTSZ DMA Tx Max Allowable Packet Size RW
0x3590 N/A DTXCTL DMA Tx Control RW
0x35A4 N/A DTXBCTL DMA Tx Behavior Control RW
0xE000 0x0420,
0x3800 TDBAL[0] Tx Descriptor Base Low 0 RW
0xE004 0x0424,
0x3804 TDBAH[0] Tx Descriptor Base High 0 RW
0xE008 0x0428,
0x3808 TDLEN[0] Tx Descriptor Ring Length 0 RW
0xE010 0x0430,
0x3810 TDH[0] Tx Descriptor Head 0 RO
0xE018 0x0438,
0x3818 TDT[0] Tx Descriptor Tail 0 RW
0xE028 0x3828 TXDCTL[0] Transmit Descriptor Control Queue 0 RW
0xE014 0x3814 TXCTL[0] Tx DCA CTRL Register Queue 0 RW
0xE038 0x3838 TDWBAL[0] Transmit Descriptor WB Address Low Queue 0 RW
0xE03C 0x383C TDWBAH[0] Transmit Descriptor WB Address High Queue 0 RW
0xE040 + 0x40
* (n-1)
0x3900 +
0x100 * (n-
1) TDBAL[1-3] Tx Descriptor Base Low Queue 1 - 3 RW
0xE044 + 0x40
* (n-1)
0x3904 +
0x100 * (n-
1) TDBAH[1-3] Tx Descriptor Base High Queue 1 - 3 RW
0xE048 + 0x40
* (n-1)
0x3908 +
0x100 * (n-
1) TDLEN[1-3] Tx Descriptor Ring Length Queue 1 - 3 RW
Table 8-6. Register Summary (Continued)
Offset Alias Offset Abbreviation Name RW
Programming Interface — Ethernet Controller I210
371
0xE050 + 0x40
* (n-1)
0x3910 +
0x100 * (n-
1) TDH[1-3] Tx Descriptor Head Queue 1 - 3 RO
0xE058 + 0x40
* (n-1)
0x3918 +
0x100 * (n-
1) TDT[1-3] Tx Descriptor Tail Queue 1 - 3 RW
0xE068 + 0x40
* (n-1)
0x3928 +
0x100 * (n-
1) TXDCTL[1-3] Transmit Descriptor Control 1 - 3 RW
0xE054 + 0x40
* (n-1)
0x3914 +
0x100 * (n-
1) TXCTL[1-3] Tx DCA CTRL Register Queue 1 - 3 RW
0xE078 + 0x40
* (n-1)
0x3938 +
0x100 * (n-
1) TDWBAL[1-3] Transmit Descriptor WB Address Low Queue 1 - 3 RW
0xE07C + 0x40
* (n-1)
0x393C +
0x100 * (n-
1) TDWBAH[1-3] Transmit Descriptor WB Address High Queue 1 - 3 RW
0x300C + 0x40
*n N/A TQAVHC Transmit Qav High Credits RW
0x3004 +
0x40*n N/A TQAVCC[0-1] Transmit Qav RW
0x3570 N/A TQAVCTRL Transmit Qav Control RW
Filters
0x5CB0 + 4*n N/A ETQF[0 - 7] EType Queue Filter 0 - 7 RW
0x5A80 + 4*n N/A IMIR[0 - 7] Immediate Interrupt Rx 0 - 7 RW
0x5AA0 + 4*n N/A IMIREXT[0 - 7] Immediate Interrupt Rx Extended 0 - 7 RW
0x5AC0 N/A IMIRVP Immediate Interrupt Rx VLAN Priority RW
0x59E0 + 4*n N/A TTQF[0 - 7] Two-Tuple Queue Filter 0 - 7 RW
0x55FC N/A SYNQF SYN Packet Queue Filter RW
Per Queue Statistics
0xC030 + 0x40
* n 0x2830 +
0x100 * n RQDPC[0 - 3] Receive Queue Drop Packet Count Register 0 - 3 RW
0xE030 + 0x40
* n N/A TQDPC[0 - 3] Transmit Queue Drop Packet Count Register 0 - 3 RW
0x10010 +
0x100*n N/A PQGPRC[0 - 3] Per Queue Good Packets Received Count RO
0x10014 +
0x100*n N/A PQGPTC[0 - 3] Per Queue Good Packets Transmitted Count RO
0x10018 +
0x100*n N/A PQGORC[0 - 3] Per Queue Good Octets Received Count RO
0x10034 +
0x100*n N/A PQGOTC[0 - 3] Per Queue Octets Transmitted Count RO
0x10038 +
0x100*n N/A PQMPRC[0 - 3] Per Queue Multicast Packets Received Count RO
Statistics
0x4000 N/A CRCERRS CRC Error Count RC
0x4004 N/A ALGNERRC Alignment Error Count RC
0x4008 N/A SYMERRS Symbol Error Count RC
0x400C N/A RXERRC Rx Error Count RC
0x4010 N/A MPC Missed Packets Count RC
Table 8-6. Register Summary (Continued)
Offset Alias Offset Abbreviation Name RW
Ethernet Controller I210 — Programming Interface
372
0x4014 N/A SCC Single Collision Count RC
0x4018 N/A ECOL Excessive Collisions Count RC
0x401C N/A MCC Multiple Collision Count RC
0x4020 N/A LATECOL Late Collisions Count RC
0x4028 N/A COLC Collision Count RC
0x4030 N/A DC Defer Count RC
0x4034 N/A TNCRS Transmit - No CRS RC
0x403C N/A HTDPMC Host Transmit Discarded Packets by MAC Count RC
0x4040 N/A RLEC Receive Length Error Count RC
0x4048 N/A XONRXC XON Received Count RC
0x404C N/A XONTXC XON Transmitted Count RC
0x4050 N/A XOFFRXC XOFF Received Count RC
0x4054 N/A XOFFTXC XOFF Transmitted Count RC
0x4058 N/A FCRUC FC Received Unsupported Count RC
0x405C N/A PRC64 Packets Received (64 Bytes) Count RC
0x4060 N/A PRC127 Packets Received (65-127 Bytes) Count RC
0x4064 N/A PRC255 Packets Received (128-255 Bytes) Count RC
0x4068 N/A PRC511 Packets Received (256-511 Bytes) Count RC
0x406C N/A PRC1023 Packets Received (512-1023 Bytes) Count RC
0x4070 N/A PRC1522 Packets Received (1024-1522 Bytes) RC
0x4074 N/A GPRC Good Packets Received Count RC
0x4078 N/A BPRC Broadcast Packets Received Count RC
0x407C N/A MPRC Multicast Packets Received Count RC
0x4080 N/A GPTC Good Packets Transmitted Count RC
0x4088 N/A GORCL Good Octets Received Count (Lo) RC
0x408C N/A GORCH Good Octets Received Count (Hi) RC
0x4090 N/A GOTCL Good Octets Transmitted Count (Lo) RC
0x4094 N/A GOTCH Good Octets Transmitted Count (Hi) RC
0x40A0 N/A RNBC Receive No Buffers Count RC
0x40A4 N/A RUC Receive Under Size Count RC
0x40A8 N/A RFC Receive Fragment Count RC
0x40AC N/A ROC Receive Oversize Count RC
0x40B0 N/A RJC Receive Jabber Count RC
0x40B4 N/A MNGPRC Management Packets Receive Count RC
0x40B8 N/A MPDC Management Packets Dropped Count RC
0x40BC N/A MNGPTC Management Packets Transmitted Count RC
0x40C0 N/A TORL Total Octets Received (Lo) RC
0x8FE0 N/A B2OSPC BMC2OS Packets Sent by MC RC
0x4158 N/A B2OGPRC BMC2OS Packets Received by Host RC
0x8FE4 N/A O2BGPTC OS2BMC Packets Received by MC RC
0x415C N/A O2BSPC OS2BMC Packets Transmitted By Host RC
0x40C4 N/A TORH Total Octets Received (Hi) RC
0x40C8 N/A TOTL Total Octets Transmitted (Lo) RC
0x40CC N/A TOTH Total Octets Transmitted (Hi) RC
Table 8-6. Register Summary (Continued)
Offset Alias Offset Abbreviation Name RW
Programming Interface — Ethernet Controller I210
373
0x40D0 N/A TPR Total Packets Received RC
0x40D4 N/A TPT Total Packets Transmitted RC
0x40D8 N/A PTC64 Packets Transmitted (64 Bytes) Count RC
0x40DC N/A PTC127 Packets Transmitted (65-127 Bytes) Count RC
0x40E0 N/A PTC255 Packets Transmitted (128-256 Bytes) Count RC
0x40E4 N/A PTC511 Packets Transmitted (256-511 Bytes) Count RC
0x40E8 N/A PTC1023 Packets Transmitted (512-1023 Bytes) Count RC
0x40EC N/A PTC1522 Packets Transmitted (1024-1522 Bytes) Count RC
0x40F0 N/A MPTC Multicast Packets Transmitted Count RC
0x40F4 N/A BPTC Broadcast Packets Transmitted Count RC
0x40F8 N/A TSCTC TCP Segmentation Context Transmitted Count RC
0x4100 N/A IAC Interrupt Assertion Count RC
0x4104 N/A RPTHC Rx Packets to Host Count RC
0x4148 N/A TLPIC EEE Tx LPI Count RC
0x414C N/A RLPIC EEE Rx LPI Count RC
0x4118 N/A HGPTC Host Good Packets Transmitted Count RC
0x4120 N/A RXDMTC Rx Descriptor Minimum Threshold Count RC
0x4128 N/A HGORCL Host Good Octets Received Count (Lo) RC
0x412C N/A HGORCH Host Good Octets Received Count (Hi) RC
0x4130 N/A HGOTCL Host Good Octets Transmitted Count (Lo) RC
0x4134 N/A HGOTCH Host Good Octets Transmitted Count (Hi) RC
0x4138 N/A LENERRS Length Errors Count Register RC
0x4228 N/A SCVPC SerDes/SGMII/1000BASE-KX Code Violation Packet Count
Register RW
0x4154 N/A MNGFBDPC Management Full Buffer Drop Packet Count RC/W
Manageability Statistics
0x413C N/A BMNGPRC MC Management Packets Receive Count RC
0x4140 N/A BMRPDC MC Management Receive Packets Dropped Count RC
0x8FDC N/A BMTPDC MC Management Transmit Packets Dropped Count RC
0x4144 N/A BMNGPTC MC Management Packets Transmitted Count RC
0x4400 N/A BUPRC MC Total Unicast Packets Received RC
0x4404 N/A BMPRC MC Total Multicast Packets Received RC
0x4408 N/A BBPRC MC Total Broadcast Packets Received RC
0x440C N/A BUPTC MC Total Unicast Packets Transmitted RC
0x4410 N/A BMPTC MC Total Multicast Packets Transmitted RC
0x4414 N/A BBPTC MC Total Broadcast Packets Transmitted RC
0x4418 N/A BCRCERRS MC FCS Receive Errors RC
0x441C N/A BALGNERRC MC Alignment Errors RC
0x4420 N/A BXONRXC MC Pause XON Frames Received RC
0x4424 N/A BXOFFRXC MC Pause XOFF Frames Received RC
0x4428 N/A BXONTXC MC Pause XON Frames Transmitted RC
0x442C N/A BXOFFTXC MC Pause XOFF Frames Transmitted RC
0x4430 N/A BSCC MC Single Collision Transmit Frames RC
0x4434 N/A BMCC MC Multiple Collision Transmit Frames RC
Table 8-6. Register Summary (Continued)
Offset Alias Offset Abbreviation Name RW
Ethernet Controller I210 — Programming Interface
374
Wake Up and Proxying
0x5800 N/A WUC Wake Up Control RW
0x5808 N/A WUFC Wake Up Filter Control RW
0x5810 N/A WUS Wake Up Status R/W1C
0x5F60 N/A PROXYFC Proxying Filter Control RW
0x5F64 N/A PROXYS Proxying Status R/W1C
0x5838 N/A IPAV IP Address Valid RW
0x5840- 0x5858 N/A IP4AT IPv4 Address Table RW
0x5880- 0x588F N/A IP6AT IPv6 Address Table RW
0x5900 N/A WUPL Wake Up Packet Length RO
0x5A00- 0x5A7C N/A WUPM Wake Up Packet Memory RO
0x9000-0x93FC N/A FHFT Flexible Host Filter Table Registers RW
0x9A00-0x9DFC N/A FHFT_EXT Flexible Host Filter Table Registers Extended RW
0x5590 N/A PROXYFCEX Proxy Filter Control Extended RW
0x5594 N/A PROXYEXS Proxy Extended Status R/W1C
0x5500-0x557C N/A WFUTPF[31:0] Wake Flex UDP TCP Port Filter RW
0x5580 N/A RFUTPF Range Flex UDP TCP Port Filter RW
0x5584 N/A RWPFC Range Wake Port Filter Control RW
0x5588 N/A WFUTPS Wake Filter UDP TCP Status R/W1C
0x558C N/A WCS Wake Control Status R/W1C
Manageability
0x5010 -
0x502C N/A MAVTV[7:0] VLAN TAG Value 7 - 0 RW
0x5030 -
0x504C N/A MFUTP[7:0] Management Flex UDP/TCP Ports [0-7] RW
0x5070 -
0x508C N/A MFUTP[15:0] Management Flex UDP/TCP Ports [8-15] RW
0x5060 -
0x506C N/A METF[3:0] Management Ethernet Type Filters RW
0x5820 N/A MANC Management Control RW
0x5864 N/A MNGONLY Management Only Traffic Register RW
0x5870 N/A MSFM Special Filters Modifiers RW
0x5890 -
0x58AC N/A MDEF[7:0] Manageability Decision Filters RW
0x5930 –
0x594C N/A MDEF_EXT[7:0] Manageability Decision Filters RW
0x58B0 -
0x58EC N/A MIPAF[15:0] Manageability IP Address Filter RW
0x5910 + 8*n N/A MMAL[3:0] Manageability MAC Address Low 3:0 RW
0x5914 + 8*n N/A MMAH[3:0] Manageability MAC Address High 3:0 RW
0x9400-0x94FC N/A FTFT Flexible TCO Filter Table RW
0x8800-0x8EFC N/A HOST_INT_MEM Host Interface Memory Address Space RW
0x8F00 N/A HICR HOST Interface Control Register RW
0x8F40 N/A HIBBA Host Interface Buffer Base Address RW
0x8F44 N/A HIBMAXOFF Host Interface Buffer Maximum Offset RO
Table 8-6. Register Summary (Continued)
Offset Alias Offset Abbreviation Name RW
Programming Interface — Ethernet Controller I210
375
PCIe
0x5B00 N/A GCR PCIe Control Register RW
0x5B10 N/A GSCL_1 PCIe Statistics Control #1 RW
0x5B14 N/A GSCL_2 PCIe Statistics Control #2 RW
0x5B90 -
0x5B9C N/A GSCL_5_8 PCIe Statistics Control Leaky Bucket Timer RW
0x5B20 N/A GSCN_0 PCIe Counter Register #0 RW
0x5B24 N/A GSCN_1 PCIe Counter Register #1 RW
0x5B28 N/A GSCN_2 PCIe Counter Register #2 RW
0x5B2C N/A GSCN_3 PCIe Counter Register #3 RW
0x5B30 N/A FACTPS Function Active and Power State RW
0x5B64 N/A MREVID Mirrored Revision ID RO
0x5B6C N/A GCR_EXT PCIe Control Extended Register RW
0x5B74 N/A DCA_CTRL DCA Control Register RW
0x5B88 N/A PICAUSE PCIe Interrupt Cause R/W1C
0x5B8C N/A PIENA PCIe Interrupt Enable RW
0x5BFC N/A BARCTRL PCIe BAR Control RW
0x5BF4 N/A RR2DCDELAY Read Request To Data Completion Delay Register RC
0x5B4C N/A PCIEMCTP PCIe MCTP Register RW to FW
Memory Error Detection
0x1084 N/A PEIND Parity and ECC Indication RC
0x1088 N/A PEINDM Parity and ECC Indication Mask RW
0x245C N/A PBECCSTS Packet Buffer ECC Status RW
0x5BA0 N/A PCIEERRCTL PCIe Parity Control Register RW
0x5BA4 N/A PCIEECCCTL PCIe ECC Control Register RW
0x5BA8 N/A PCIEERRSTS PCIe Parity Status Register R/W1C
0x5BAC N/A PCIEECCSTS PCIe ECC Status Register R/W1C
0x5B7C N/A PCIEACL01 PCIe ACL0 and ACL1 Register RW to FW
0x5B80 N/A PCIEACL23 PCIe ACL2 and ACL3 Register RW to FW
0x5F54 N/A LANPERRCTL LAN Port Parity Error Control Register RW to FW
0x5F58 N/A LANPERRSTS LAN Port Parity Error Status Register R/W1C
0x5F5C N/A LANPERRINJ LAN Port Parity Error Inject Register SC
Power Management Registers
0x2508 N/A DMACR DMA Coalescing Control Register RW
0x2514 N/A DMCTLX DMA Coalescing Time to LX Request RW
0x3550 N/A DMCTXTH DMA Coalescing Transmit Threshold RW
0x5DD4 N/A DMCCNT DMA Coalescing Current Rx Count RO
0x2170 N/A FCRTC Flow Control Receive Threshold Coalescing RW
0x3F24 N/A DOBFFCTL DMA OBFF Control RW
0x5DC8 N/A DMACTC DMA Coalescing Clock Control Time Counter RO
0x5BB0 N/A LTRMINV Latency Tolerance Reporting (LTR) Minimum Values RW
0x5BB4 N/A LTRMAXV Latency Tolerance Reporting (LTR) Maximum Values RW
0x01A0 N/A LTRC Latency Tolerance Reporting (LTR) Control RW
Table 8-6. Register Summary (Continued)
Offset Alias Offset Abbreviation Name RW
Ethernet Controller I210 — Programming Interface
376
0x0E30 N/A EEER Energy Efficient Ethernet (EEE) Register RW
Diagnostic
0x5BB8 N/A PCIEMISC PCIe Misc. Register RW
PCS
0x4200 N/A PCS_CFG PCS Configuration 0 Register RW
0x4208 N/A PCS_LCTL PCS Link Control Register RW
0x420C N/A PCS_LSTS PCS Link Status Register RO
0x4210 N/A PCS_DBG0 PCS Debug 0 Register RO
0x4214 N/A PCS_DBG1 PCS Debug 1 Register RO
0x4218 N/A PCS_ANADV AN Advertisement Register RW
0x421C N/A PCS_LPAB Link Partner Ability Register RO
0x4220 N/A PCS_NPTX AN Next Page Transmit Register RW
0x4224 N/A PCS_LPABNP Link Partner Ability Next Page Register RO
Time Sync
0xB620 N/A TSYNCRXCTL Rx Time Sync Control Register RW
0xB624 N/A RXSTMPL Rx Timestamp Low RO
0xB628 N/A RXSTMPH Rx Timestamp High RO
0xB614 N/A TSYNCTXCTL Tx Time Sync Control Register RW
0xB618 N/A TXSTMPL Tx Timestamp Value Low RO
0xB61C N/A TXSTMPH Tx Timestamp Value High RO
0xB6F8 N/A SYSTIMR System Time Residue Register RW
0xB600 N/A SYSTIML System Time Register Low RW
0xB604 N/A SYSTIMH System Time Register High RW
0xB6FC N/A SYSTIMTM System Time Register Tx MS RW
0xB608 N/A TIMINCA Increment Attributes Register RW
0xB60C N/A TIMADJ Time Adjustment Offset Register RW
0xB640 N/A TSAUXC Auxiliary Control Register RW
0xB644 N/A TRGTTIML0 Target Time Register 0 Low RW
0xB648 N/A TRGTTIMH0 Target Time Register 0 High RW
0xB64C N/A TRGTTIML1 Target Time Register 1 Low RW
0xB650 N/A TRGTTIMH1 Target Time Register 1 High RW
0xB654 N/A FREQOUT0 Frequency Out 0 Control Register RW
0xB658 N/A FREQOUT1 Frequency Out 1 Control Register RW
0xB65C N/A AUXSTMPL0 Auxiliary Timestamp 0 Register Low RO
0xB660 N/A AUXSTMPH0 Auxiliary Timestamp 0 Register High RO
0xB664 N/A AUXSTMPL1 Auxiliary Timestamp 1 Register Low RO
0xB668 N/A AUXSTMPH1 Auxiliary Timestamp 1 Register High RO
0x5F50 N/A TSYNCRXCFG Time Sync Rx Configuration RW
0x003C N/A TSSDP Time Sync SDP Configuration Register RW
0xB66C N/A TSICR Time Sync Interrupt Cause Register RC/W1C
0xB674 N/A TSIM Time Sync Interrupt Mask Register RW
0x3578 N/A LAUNCH_OS0 Launch Time Offset Register 0 RW
Table 8-6. Register Summary (Continued)
Offset Alias Offset Abbreviation Name RW
Programming Interface — Ethernet Controller I210
377
8.1.3.1 Alias Addresses
Certain registers maintain an alias address designed for backward compatibility with software written
for previous GbE controllers. For these registers, the alias address is listed Table 8-6. Those registers
can be accessed by software at either the new offset or the alias offset. It is recommended that
software that is written solely for the I210, use the new address offset.
8.1.4 MSI-X BAR Register Summary
8.2 General Register Descriptions
8.2.1 Device Control Register - CTRL (0x00000; R/W)
This register, as well as the Extended Device Control (CTRL_EXT) register, controls the major
operational modes for the device. While software writes to this register to control device settings,
several bits (such as FD and SPEED) can be overridden depending on other bit settings and the
resultant link configuration determined by the PHY's auto-negotiation resolution. See Section 4.6.7 for
details on the setup of these registers in the different link modes.
Note: This register is also aliased at address 0x0004.
Table 8-7. MSI-X Register Summary
Category Offset Abbreviation Name RW Page
MSI-X Table 0x0000 + n*0x10
[n=0...4] MSIXTADD MSI–X Table Entry Lower
Address RW page 428
MSI-X Table 0x0004 + n*0x10
[n=0...4] MSIXTUADD MSI–X Table Entry Upper
Address RW page 428
MSI-X Table 0x0008 + n*0x10
[n=0...4] MSIXTMSG MSI–X Table Entry Message R/W page 428
MSI-X Table 0x000C + n*0x10
[n=0...4] MSIXTVCTRL MSI–X Table Entry Vector
Control R/W page 429
MSI-X Table 0x02000 MSIXPBA MSIXPBA Bit Description RO page 429
Field Bit(s) Initial Value Description
FD 0 1b1
Full-Duplex
Controls the MAC duplex setting when explicitly set by software.
0b = Half duplex.
1b = Full duplex.
Reserved 1 0b Reserved
Write 0b; ignore on read.
GIO Master
Disable 2 0b
When set to 1b, the function of this bit blocks new master requests including
manageability requests. If no master requests are pending by this function, the
STATUS.GIO Master Enable Status bit is set. See Section 5.2.3.3 for further
information.
Reserved 5:3 0x0 Reserved
Write 0b, ignore on read.
Ethernet Controller I210 — Programming Interface
378
SLU 6 0b1
Set Link Up
Set Link Up must be set to 1b to permit the MAC to recognize the LINK signal from the
PHY, which indicates the PHY has gotten the link up, and is ready to receive and
transmit data.
See Section 3.7.4 for more information about auto-negotiation and link configuration
in the various modes.
Notes:
1. The CTRL.SLU bit is normally initialized to 0b. However, if the APM Enable bit is
set in the Flash then it is initialized to 1b.
2. The CTRL.SLU bit is set to 1b if the Enable All Phys in D3 bit in the Common
Firmware Parameters 2 Flash word is set to 1b (See Section 6.7.1.3).
3. The CTRL.SLU bit is set in NC-SI mode according to the Enable Channel command
to the port.
4. In SerDes and 1000Base-KX modes Link up can be forced by setting this bit as
described in Section 3.7.4.1.4.
ILOS 7 0b1
Invert Loss-of-Signal (LOS/LINK) Signal
This bit controls the polarity of the SRDS_[n]_SIG_DET signal or internal link-up
signal.
0b = Do not invert (active high input signal).
1b = Invert signal (active low input signal).
Notes:
1. Source of the link-up signal (SRDS_[n]_SIG_DET signal or internal link-up signal)
is set via the CONNSW.ENRGSRC bit. When using the internal link-up signal, this
bit should be set to 0b.
2. Should be set to 0b when using an internal copper PHY or when working in
SGMII, 1000BASE-BX or 1000BASE-KX modes.
SPEED 9:8 10b
Speed Selection.
These bits determine the speed configuration and are written by software after reading
the PHY configuration through the MDIO interface.
These signals are ignored when auto-speed detection is enabled.
00b = 10 Mb/s.
01b = 100 Mb/s.
10b = 1000 Mb/s.
11b = Not used.
Reserved 10 0b Reserved.
Write 0b, ignore on read.
FRCSPD 11 0b1
Force Speed
This bit is set when software needs to manually configure the MAC speed settings
according to the SPEED bits.
Note that MAC and PHY must resolve to the same speed configuration or software
must manually set the PHY to the same speed as the MAC.
Software must clear this bit to enable the PHY or ASD function to control the MAC
speed setting. Note that this bit is superseded by the CTRL_EXT.SPD_BYPS bit, which
has a similar function.
FRCDPLX 12 0b
Force Duplex
When set to 1b, software can override the duplex indication from the PHY that is
indicated in the FDX to the MAC. Otherwise, in 10/100/1000Base-T link mode, the
duplex setting is sampled from the PHY FDX indication into the MAC on the asserting
edge of the PHY LINK signal. When asserted, the CTRL.FD bit sets duplex.
Reserved 15:13 0x0 Reserved
Write 0b, ignore on read.
SDP0_GPIEN 16 0b
General Purpose Interrupt Detection Enable for SDP0
If software-controlled I/O pin SDP0 is configured as an input, this bit (when 1b)
enables the use for GPI interrupt detection.
SDP1_GPIEN 17 0b
General Purpose Interrupt Detection Enable for SDP1
If software-controlled I/O pin SDP1 is configured as an input, this bit (when 1b)
enables the use for GPI interrupt detection.
Field Bit(s) Initial Value Description
Programming Interface — Ethernet Controller I210
379
SDP0 DATA
(RWM) 18 0b1
SDP0 Data Value
Used to read or write the value of software-controlled I/O pin SDP0.
If SDP0 is configured as an output (SDP0_IODIR = 1b), this bit controls the value
driven on the pin (initial value Flash-configurable).
If SDP0 is configured as an input, reads return the current value of the pin.
When the SDP0_WDE bit is set, this field indicates the polarity of the watchdog
indication.
Note:
SDP1 DATA
(RWM) 19 0b1
SDP1 Data Value
Used to read or write the value of software-controlled I/O pin SDP1.
If SDP1 is configured as an output (SDP1_IODIR = 1b), this bit controls the value
driven on the pin (initial value Flash-configurable).
If SDP1 is configured as an input, reads return the current value of the pin.
ADVD3WUC 20 1b1
D3Cold Wake up Capability Enable
When this bit is set to 0b, PME (WAKE#) is not generated in D3Cold.
Bit loaded from Flash (refer to Section 6.2.21).
SDP0_WDE 21 0b1
SDP0 used for Watchdog Indication
When set, SDP0 is used as a watchdog indication. When set, the SDP0_DATA bit
indicates the polarity of the watchdog indication. In this mode, SDP0_IODIR must be
set to an output.
SDP0_IODIR 22 0b1
SDP0 Pin Direction
Controls whether software-controllable pin SDP0 is configured as an input or output
(0b = input, 1b = output). Initial value is Flash-configurable. This bit is not affected by
software or system reset, only by initial power-on or direct software writes.
SDP1_IODIR 23 0b1
SDP1 Pin Direction
Controls whether software-controllable pin SDP1 is configured as an input or output
(0b = input, 1b = output). Initial value is Flash-configurable. This bit is not affected by
software or system reset, only by initial power-on or direct software writes.
Reserved 25:24 0x0 Reserved.
Write 0b, ignore on read.
RST (SC) 26 0b
Port Software Reset
This bit performs a reset to the LAN port, resulting in a state nearly approximating the
state following a power-up reset or internal PCIe reset, except for system PCI
configuration and DMA logic.
0b = Normal.
1b = Reset.
This bit is self clearing and is referred to as software reset or global reset.
RFCE 27 1b
Receive Flow Control Enable
When set, indicates that the I210 responds to the reception of flow control packets. If
auto-negotiation is enabled, this bit is set to the negotiated flow control value.
In SerDes mode the resolution is done by the hardware. In internal PHY, SGMII or
1000BASE-KX modes it should be done by the software.
TFCE 28 0b
Transmit Flow Control Enable
When set, indicates that the I210 transmits flow control packets (XON and XOFF
frames) based on the receiver fullness. If auto-negotiation is enabled, this bit is set to
the negotiated duplex value.
In SerDes mode the resolution is done by the hardware. In internal PHY, SGMII or
1000BASE-KX modes it should be done by the software.
Field Bit(s) Initial Value Description
Ethernet Controller I210 — Programming Interface
380
8.2.2 Device Status Register - STATUS (0x0008; RO)
DEV_RST
(SC) 29 0b
Device Reset
This bit performs a reset of the entire controller device, resulting in a state nearly
approximating the state following a power-up reset or internal PCIe reset, except for
system PCI configuration.
0b = Normal.
1b = Reset.
This bit is self clearing.
Notes:
1. Asserting DEV_RST generates an interrupt via the ICR.DRSTA interrupt bit.
2. Device Reset (CTRL.DEV_RST) can be used to globally reset the entire
component if the DEV_RST_EN bit in Initialization Control 4 Flash word is set.
3. Asserting DEV_RST sets the STATUS.DEV_RST_SET bit.
VME 30 0b
VLAN Mode Enable
When set to 1b, VLAN information is stripped from all received 802.1Q packets.
Note: If this bit is set, the RCTL.SECRC bit should also be set as the CRC is not valid
anymore.
PHY_RST 31 0b
PHY Reset
Generates a hardware-level reset to the internal 1000BASE-T PHY.
0b = Normal operation.
1b = Internal PHY reset asserted.
1. These bits are loaded from Flash.
Field Bit(s) Initial Value Description
FD 0 X
Full Duplex.
0b = Half duplex (HD).
1b = Full duplex (FD).
Reflects duplex setting of the MAC and/or link.
FD reflects the actual MAC duplex configuration. This normally reflects the
duplex setting for the entire link, as it normally reflects the duplex
configuration negotiated between the PHY and link partner (copper link) or
MAC and link partner (fiber link).
LU 1 X
Link up.
0b = No link established.
1b = Link established.
For this bit to be valid, the Set Link Up bit of the Device Control (CTRL.SLU)
register must be set.
Link up provides a useful indication of whether something is attached to the
port. Successful negotiation of features/link parameters results in link
activity. The link start-up process (and consequently the duration for this
activity after reset) can be several 100's of ms. When the internal PHY is
used, this reflects whether the PHY's LINK indication is present. When the
SerDes, SGMII or 1000BASE-KX interface is used, this indicates loss-of-
signal; if auto-negotiation is also enabled, this can also indicate successful
auto-negotiation. Refer to Section 3.7.4 for more details.
Note: This bit is valid only when working in internal PHY mode. In SerDes
mode bit is always 0b.
Reserved 3:2 X Reserved
Write 0b, ignore on read.
TXOFF 4 X
Transmission Paused
This bit indicates the state of the transmit function when symmetrical flow
control has been enabled and negotiated with the link partner. This bit is set
to 1b when transmission is paused due to the reception of an XOFF frame.
It is cleared (0b) upon expiration of the pause timer or the receipt of an
XON frame.
Field Bit(s) Initial Value Description
Programming Interface — Ethernet Controller I210
381
8.2.3 Extended Device Control Register - CTRL_EXT (0x0018; R/W)
This register provides extended control of the I210’s functionality beyond that provided by the Device
Control (CTRL) register.
Reserved 5 X Reserved.
Write 0b, ignore on read.
SPEED 7:6 X
Link Speed Setting
Reflects the speed setting of the MAC and/or link when it is operating in 10/
100/1000BASE-T mode (internal PHY).
When the MAC is operating in 10/100/1000BASE-T mode with the internal
PHY, these bits normally reflect the speed of the actual link, negotiated by
the PHY and link partner and reflected internally from the PHY to the MAC
(SPD_IND). These bits also might represent the speed configuration of the
MAC only, if the MAC speed setting has been forced via software
(CTRL.SPEED) or if MAC auto-speed detection is used.
If auto-speed detection is enabled, the I210's speed is configured only once
after the LINK signal is asserted by the PHY.
00b = 10 Mb/s.
01b = 100 Mb/s.
10b = 1000 Mb/s.
11b = 1000 Mb/s.
ASDV 9:8 X
Auto-Speed Detection Value
Speed result sensed by the I210’s MAC auto-detection function.
These bits are provided for diagnostics purposes only. The ASD calculation
can be initiated by software writing a logic 1b to the CTRL_EXT.ASDCHK
bit. The resultant speed detection is reflected in these bits.
Refer to Section 8.2.3 for details.
PHYRA 10 1b
PHY Reset Asserted
This read/write bit is set by hardware following the assertion of an internal
PHY reset; it is cleared by writing a 0b to it. This bit is also used by
firmware indicating a required initialization of the I210’s PHY.
Reserved 18:11 0x0 Reserved.
Write 0b, ignore on read.
GIO Master Enable
Status 19 1b
Cleared by the I210 when the CTRL.GIO Master Disable bit is set and no
master requests are pending by this function and is set otherwise. Indicates
that no master requests are issued by this function as long as the CTRL.GIO
Master Disable bit is set.
DEV_RST_SET (R/
W1C) 20 0b
Device Reset Set
When set, indicates that a device reset (CTRL.DEV_RST) was initiated by
one of the software drivers.
Note: Bit cleared by writing as 1b.
PF_RST_DONE 21 1b
PF _RST_DONE
When set, indicates that software reset (CTRL.RST) or device reset
(CTRL.DEV_RST) has completed and the software device driver can begin
initialization process.
Reserved 30:22 0x0 Reserved.
Write 0b, ignore on read.
MAC clock gating
Enable 31 0b1MAC Clock Gating Enable
This bit is loaded from the Flash indicating that the device supports MAC
clock. gating
1. If the signature bits of the Flash’s Initialization Control Word 1 match (01b), this bit is read from the Flash.
Field Bit(s) Initial Value Description
Ethernet Controller I210 — Programming Interface
382
Field Bit(s) Initial Value Description
Reserved 0 0b Reserved.
Write 0b, ignore on read.
I2C over SDP
Enabled 1 0b1Enable I2C over SDP0 and SDP2 pins.
When set, SDP0 and SDP2 pins functions as an I2C interface operated
through the I2CCMD,I2CPARAMS register set.
SDP2_GPIEN 2 0b
General Purpose Interrupt Detection Enable for SDP2.
If software-controllable I/O pin SDP2 is configured as an input, this bit
(when set to 1b) enables use for GPI interrupt detection.
SDP3_GPIEN 3 0b
General Purpose Interrupt Detection Enable for SDP3.
If software-controllable I/O pin SDP3 is configured as an input, this bit
(when set to 1b) enables use for GPI interrupt detection.
Reserved 5:4 00b Reserved.
Write 0b, ignore on read.
SDP2_DATA 6 0b1
SDP2 Data Value. Used to read (write) the value of software-controllable I/
O pin SDP2. If SDP2 is configured as an output (SDP2_IODIR = 1b), this
bit controls the value driven on the pin (initial value Flash-configurable). If
SDP2 is configured as an input, reads return the current value of the pin.
SDP3_DATA 7 0b1
SDP3 Data Value. Used to read (write) the value of software-controllable I/
O pin SDP3. If SDP3 is configured as an output (SDP3_IODIR = 1b), this
bit controls the value driven on the pin (initial value Flash-configurable). If
SDP3 is configured as an input, reads return the current value of the pin.
Reserved 9:8 0x01Reserved.
Write 0b, ignore on read.
SDP2_IODIR 10 0b1
SDP2 Pin Direction. Controls whether software-controllable pin SDP2 is
configured as an input or output (0b = input, 1b = output). Initial value is
Flash-configurable. This bit is not affected by software or system reset,
only by initial power-on or direct software writes.
SDP3_IODIR 11 0b1
SDP3 Pin Direction. Controls whether software-controllable pin SDP3 is
configured as an input or output (0b = input, 1b = output). Initial value is
Flash-configurable. This bit is not affected by software or system reset,
only by initial power-on or direct software writes.
ASDCHK 12 0b
Auto-Speed-Detection (ASD) Check
Initiates an ASD sequence to sense the frequency of the PHY receive clock
(RX_CLK). The results are reflected in STATUS.ASDV. This bit is self-
clearing.
EE_RST (SC) 13 0b
EEPROM Block Reset
When set, initiates a reset-like event to the EEPROM block function. This
causes an Flash auto-load operation as if a software reset (CTRL.RST) had
occurred. This bit is self-clearing.
Reserved 14 0x0 Reserved.
Write 0b, ignore on read.
SPD_BYPS 15 0b
Speed Select Bypass
When set to 1b, all speed detection mechanisms are bypassed, and the
I210 is immediately set to the speed indicated by CTRL.SPEED. This
provides a method for software to have full control of the speed settings of
the I210 and when the change takes place, by overriding the hardware
clock switching circuitry.
NS_DIS 16 0
No Snoop Disable
When set to 1b, the I210 does not set the no snoop attribute in any PCIe
packet, independent of PCIe configuration and the setting of individual no
snoop enable bits. When set to 0b, behavior of no snoop is determined by
PCIe configuration and the setting of individual no snoop enable bits.
Programming Interface — Ethernet Controller I210
383
The I210 enables up to four externally controlled interrupts. All software-definable pins, these can be
mapped for use as GPI interrupt bits. Mappings are enabled by the SDPx_GPIEN bits only when these
signals are also configured as inputs via SDPx_IODIR. When configured to function as external interrupt
pins, a GPI interrupt is generated when the corresponding pin is sampled in an active-high state.
RO_DIS 17 0b
Relaxed Ordering Disabled
When set to 1b, the I210 does not request any relaxed ordering
transactions on the PCIe interface regardless of the state of bit 4 in the
PCIe Device Control register. When this bit is cleared and bit 4 of the PCIe
Device Control register is set, the I210 requests relaxed ordering
transactions as specified by registers RXCTL and TXCTL (per queue and per
flow).
SerDes Low
Power Enable 18 0b1When set, enables the SerDes to enter a low power state when the function
is in Dr state .
Dynamic MAC
Clock Gating 19 0b1When set, enables dynamic MAC clock gating.
PHY Power
Down Enable 20 1b1When set, enables the PHY to enter a low-power state as described in
Section 5.4.2.
Reserved 21 0b Reserved.
Write 0b, ignore on read.
LINK_MODE 23:22 0x01
Link Mode
Controls interface on the link.
00b = Direct copper (1000Base-T) interface (10/100/1000 BASE-T internal
PHY mode).
01b = 1000BASE-KX.
10b = SGMII.
11b = SerDes interface.
Note:
1. This bit is reset only on power-up or PCIe reset.
Reserved 24 0b Reserved.
Write 0b, ignore on read.
I2C Enabled 25 0b1
Enable I2C
This bit enables the SFPx_I2C pins that can be used to access external SFP
modules or an external 1000BASE-T PHY via the MDIO interface. If cleared,
the SFPx_I2C pads are isolated and accesses to the SFPx_I2C pins through
the I2CCMD register or the MDIC register are ignored.
EXT_VLAN 26 0b1
External VLAN Enable
When set, all incoming Rx packets are expected to have at least one VLAN
with the Ether type as defined in VET.EXT_VET that should be ignored. The
packets can have a second internal VLAN that should be used for all
filtering purposes. All Tx packets are expected to have at least one VLAN
added to them by the host. In the case of an additional VLAN request (VLE
- VLAN Enable is set in transmit descriptor) the second VLAN is added after
the first external VLAN is added by the host. This bit is reset only by a
power up reset or by a full Flash auto load and should only be changed
while Tx and Rx processes are stopped.
Reserved 27 0b Reserved.
Write 0b, ignore on read.
DRV_LOAD 28 0b
Driver Loaded
This bit should be set by the software device driver after it is loaded. This
bit should be cleared when the software device driver unloads or after a
PCIe reset. The Management controller reads this bit to indicate to the
manageability controller (BMC) that the driver has loaded.
Note: Bit is reset on power-up or PCIe reset only.
Reserved 31:29 0b Reserved
Write 0b, Ignore on read.
1. These bits are read from the Flash.
Field Bit(s) Initial Value Description
Ethernet Controller I210 — Programming Interface
384
The bit mappings are listed in Table 8-8 for clarity.
Note: If software uses the EE_RST function and desires to retain current configuration information,
the contents of the control registers should be read and stored by software. Control register
values are changed by a read of the Flash, which occurs after asserting the EE_RST bit.
Note: The Flash reset function can read configuration information out of the Flash, which affects the
configuration of PCIe space BAR settings. The changes to the BARs are not visible unless the
system reboots and the BIOS is allowed to re-map them.
The SPD_BYPS bit performs a similar function to the CTRL.FRCSPD bit in that the I210’s
speed settings are determined by the value software writes to the CRTL.SPEED bits. However,
with the SPD_BYPS bit asserted, the settings in CTRL.SPEED take effect immediately rather
than waiting until after the I210’s clock switching circuitry performs the change.
8.2.4 Media Dependent Interface (MDI) Control Register - MDIC
(0x0020; R/W)
Software uses this register to read or write MDI registers in the internal PHY or an external SGMII PHY.
Table 8-8. Mappings for SDI Pins Used as GPI
SDP Pin Used as GPI CTRL_EXT Field Settings Resulting ICR Bit
(GPI)
Direction Enable as GPI Interrupt
3 SDP3_IODIR SDP3_GPIEN 14
2 SDP2_IODIR SDP2_GPIEN 13
1 SDP1_IODIR SDP1_GPIEN 12
0 SDP0_IODIR SDP0_GPIEN 11
Field Bit(s) Initial Value Description
DATA 15:0 X
Data
In a Write command, software places the data bits and the MAC shifts them
out to the PHY. In a Read command, the MAC reads these bits serially from
the PHY and software can read them from this location.
REGADD 20:16 0x0 PHY Register Address: Reg. 0, 1, 2,...31
Reserved 25:21 0x0 Reserved.
Write 0b, ignore on read.
OP 27:26 0x0
Opcode
01b = MDI write.
10b = MDI read.
All other values are reserved.
R (RWM) 28 1b
Ready Bit
Set to 1b by the I210 at the end of the MDI transaction (for example,
indication of a read or write completion). It should be reset to 0b by
software at the same time the command is written.
Programming Interface — Ethernet Controller I210
385
8.2.5 MDC/MDIO Configuration Register - MDICNFG (0x0E04; R/W)
Note: This register is used to configure the MDIO connection that is accessed via the MDIC register.
Refer to Section 3.7.2.2.2 for details on usage of this register.
MDI_IE 29 0b
Interrupt Enable
When set to 1b an Interrupt is generated at the end of an MDI cycle to
indicate an end of a read or write operation to the PHY.
MDI_ERR (RWM) 30 0b
Error
This bit is set to 1b by hardware when it fails to complete an MDI read.
Software should make sure this bit is clear (0b) before issuing an MDI read
or write command.
Note: This bit is valid only when the Ready bit is set.
Reserved 31 0b Reserved.
Write 0b, ignore on read.
Field Bit(s) Initial Value Description
Reserved 20:0 0x0 Reserved.
Write 0b, ignore on read.
PHYADD1
1. PHYADD is loaded from Initialization Control 4 Flash word to allocate the port address when using an external MDIO port.
25:21 0x00
External PHY Address
When the MDICNFG.Destination bit is 0b, default PHYADD accesses the
internal PHY.
Reserved 30:26 0x0 Reserved.
Write 0b, ignore on read.
Destination2
2. Destination is loaded from Flash Initialization Control 3 word. When an external PHY supports a MDIO interface, this bit is set to
1b; otherwise, this bit is set to 0b.
31 0b
Destination
0b = MDIO transactions using the MDIC register are directed to the internal
PHY.
1b = MDIO transactions using the MDIC register are directed to an external
PHY using the MDC/MDIO protocol.
Note: When using the I2CCMD register to access an external PHY using
the I2C protocol, the Destination field must be set to 0b.
Field Bit(s) Initial Value Description
Ethernet Controller I210 — Programming Interface
386
8.2.6 Copper/Fiber Switch Control - CONNSW (0x0034; R/W)
8.2.7 VLAN Ether Type - VET (0x0038; R/W)
This register is used by hardware to identify 802.1Q (VLAN) Ethernet packets by comparing the Ether
Type field carried by packets with the field contents. To be compliant with the 802.3ac standard, the
VET.VET field has a value of 0x8100.
8.2.8 LED Control - LEDCTL (0x0E00; RW)
This register controls the setup of the LEDs. Refer to Section 7.5.1 for details of the Mode fields
encoding.
Field Bit(s) Initial Value Description
Reserved 1:0 00b Reserved
ENRGSRC 2 0b1
1. The default value of the ENRGSRC bit in this register is defined in the Initialization Control 3 (Offset 0x24) Flash word (bit 15).
SerDes Energy Detect Source
0b = SerDes Energy detect source is internal.
1b = SerDes Energy detect source is from SRDS_[n]_SIG_DET pin.
This bit defines the source of the signal detect indication used to set link up
while in SerDes mode.
Note: In SGMII and 1000BASE-KX modes energy detect source is
internal and value of CONNSW.ENRGSRC bit should be 0b.
Reserved 8:3 0x0 Reserved.
Write 0x0, ignore on read.
SerDesD (RO) 9 X
SerDes Signal Detect Indication
Indicates the SerDes signal detect value according to the selected source
(either external or internal). Valid only if LINK_MODE is SerDes, 1000BASE-
KX or SGMII.
PHYSD (RO) 10 X PHY Signal Detect Indication
Valid only if LINK_MODE is the PHY and the receiver is not in electrical idle.
PHY_PDN (RO) 11 X
This bit indicates that the internal GbE PHY is in power down state.
0b = Internal GbE PHY not in power down.
1b = Internal GbE PHY in power down.
Reserved 31:12 0x0 Reserved.
Write 0x0, ignore on read.
Field Bit(s) Initial Value Description
VET (RO) 15:0 0x8100 VLAN EtherType
VET EXT 31:16 0x8100 External VLAN Ether Type.
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Field Bit(s) Initial
Value Description
LED0_MODE 3:0 0110b1LED0/LINK# Mode
This field specifies the control source for the LED0 output. An initial value of 0110b
selects the LINK100# indication.
LED_PCI_MODE 4 0b
0b = Use LEDs as defined in the other fields of this register.
1b = Use LEDs to indicate PCI3 lanes idle status in SDP mode (only when the
led_mode is set to 0x8 – SDP mode)
LED0 indicates electrical idle status.
GLOBAL_BLINK_
MODE 5 0b1
Global Blink Mode
This field specifies the blink mode of all the LEDs.
0b = Blink at 200 ms on and 200 ms off.
1b = Blink at 83 ms on and 83 ms off.
LED0_IVRT 6 0b1
LED0/LINK# Invert
This field specifies the polarity / inversion of the LED source prior to output or blink
control.
0b = Do not invert LED source (LED active low).
1b = Invert LED source (LED active high).
In mode 0100b (link/activity) this field must be 0. The LED signal must be active low
in mode 0100b (link/activity).
LED0_BLINK 7 0b1
LED0/LINK# Blink
This field specifies whether to apply blink logic to the (possibly inverted) LED control
source prior to the LED output.
0b = Do not blink asserted LED output.
1b = Blink asserted LED output.
LED1_MODE 11:8 0100b1
LED1/LINK/ACTIVITY
This field specifies the control source for the LED1 output. An initial value of 0100b
selects the LINK/ACTIVITY indication. When asserted, means the LINK indication and
when BLINK means LINK and ACTIVITY.
Reserved 13:12 0b Reserved
Write as 0x0,ignore on read.
LED1_IVRT 14 0b1
LED1/ACTIVITY# Invert
This field specifies the polarity / inversion of the LED source prior to output or blink
control.
0b = Do not invert LED source (LED active low).
1b = Invert LED source (LED active high).
In mode 0100b (link/activity) this field must be 0. The LED signal must be active low
in mode 0100b (link/activity).
LED1_BLINK 15 1b1LED1/ACTIVITY# Blink
LED2_MODE 19:16 0111b1LED2/LINK1000# Mode
This field specifies the control source for the LED2 output. An initial value of 0111b
selects the LINK1000# indication.
Reserved 21:20 0x0 Reserved.
Write 0b, ignore on read.
LED2_IVRT 22 0b1
LED2/LINK100# Invert
This field specifies the polarity / inversion of the LED source prior to output or blink
control.
0b = Do not invert LED source (LED active low).
1b = Invert LED source (LED active high).
In mode 0100b (link/activity) this field must be 0. The LED signal must be active low
in mode 0100b (link/activity).
LED2_BLINK 23 0b1LED2/LINK100# Blink
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8.3 Internal Packet Buffer Size Registers
The following registers define the size of the on-chip receive and transmit buffers used to receive and
transmit packets. Refer to Section 4.6.9 for the general setting rule that applies on all these packet
buffers.
The registers in this chapter reset only on power up.
8.3.1 RX Packet Buffer Size - RXPBSIZE (0x2404; R/W)
8.3.2 TX Packet Buffer Size - TXPBSIZE (0x3404; R/W)
8.4 Flash Registers Descriptions
8.4.1 EEPROM-Mode Control Register - EEC (0x12010; RW)
This register provides software direct access to the Flash.
Reserved 27:24 0000b Reserved.
Reserved 29:28 0x0 Reserved.
Write 0x0, ignore on read.
Reserved 31:30 00b Reserved.
1. These bits are read from the Flash.
Field Bit(s) Init. Description
Rxpbsize 5:0 0x22 Rx packet buffer size in KB.
Bmc2ospbsize 11:6 0x02 BMC to OS packet buffer size in KB.
Reserved 30:12 0x0 Reserved.
Write 0b, ignore on read.
cfg_ts_en 31 0x0
If set, a line is saved (16 bytes) per packet in the Rx packet buffer for the timestamp
descriptor.
If not set, no timestamp in packet support.
Field Bit(s) Init, Description
Txpb0size 5:0 0x14 Tx Packet Buffer 0 Size in KB.
In Qav mode, it controls the size in KB of the TXPB0, which is associated to TxQ0.
Txpb1size 11:6 0x0 In Qav mode, it controls the size in KB of the TXPB1, which is associated to TxQ1.
Txpb2size 17:12 0x0 In Qav mode, it controls the size in KB of the TXPB2, which is associated to TxQ2.
Txpb3size 23:18 0x0 In Qav mode, it controls the size in KB of the TXPB3, which is associated to TxQ3.
os2Bmcpbsize 29:24 0x4 OS to BMC packet buffer size in KB.
Reserved 31:30 0x0 Reserved
Write 0b, ignore on read.
Field Bit(s) Initial
Value Description
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Bit banging access to the flash via the FLA register is not protected by this field.
8.4.2 EEPROM-Mode Load Control/Status Register - EELOADCTL
(0x12020; RO to Host, RW to FW)
This register provides software direct access to the EEPROM. Software can control the EEPROM by
successive writes to this register. Data and address information is clocked into the EEPROM by software
toggling the EE_SK and EE_DI bits (0 and 2) of this register with EE_CS set to 0b. Data output from the
EEPROM is latched into the EE_DO bit (bit 3) via the internal 62.5 MHz clock and can be accessed by
software via reads of this register.
Field Bit(s) Init. Description
Reserved 5:0 0x0 Reserved. Reads as 0b.
FLASH_IN_USE (RO) 6 0b
Valid when ee_pres = 1b.
When this bit is set to 1b, it indicates that the Flash is present with a valid signature
and the hardware was programmed from the Flash. The hardware will always first check
the existence of the external Flash.
0b = Flash is not used.
1b = Flash is used.
Reserved 7 0b Reserved.
Ignore on read.
EE_PRES (RO) 8 1b
Valid when auto_rd=1. When this bit is set, it indicates that either a Flash is present
and has the correct signature field or the iNVM is no-empty, and the shadow RAM
contains the auto-load information from one of those sources (no need for software
programming).
Auto_RD (RO) 9 0b Flash Auto-Read Done. When set to 1b, this bit indicates that the auto-read by
hardware from the Flash is done. This bit is also set when the Flash is not found or
when its signature field is not valid. This bit doesn't include MNG autoload status.
Reserved 10 0b Reserved.
EE_Size (RO) 14:11 0101b Flash Size via EEPROM-Mode. This field defines the size of the NVM that is accessible via
EEPROM-mode. This is equal to the size of the internal shadow RAM, fixed to 4 KB. It is
encoded in power of 2 Kb units.
Reserved 18:15 0b Reserved.
FLASH_DETECTED
(RO) 19 0b RO; Flash responded as not busy to a read status and returned a manufacturer ID.
Reserved 22:20 0x0 Reserved. Reads as 0x0.
FLUPD 23 0b
Flash Update.
Writing 1b to this bit causes the content of the internal 4 KB shadow RAM to be written
into one of the first two 4 KB sectors of the Flash device (Sector 0 or Sector 1). The bit
is self-cleared immediately.
Reserved 24 0b Reserved. Reads as 0b.
SEC1VAL (RO) 25 0b
Sector 1 Valid. When set to 1b, indicates that the content of the 4 KB Sector 1 (from
byte address 0x1000 to 0x1FFF) of the Flash device is valid. When set to 0b, indicates
that the content of Sector 0 (from byte address 0x0000 to 0x0FFF) is valid.
Meaningful only when EE_PRES bit and FLASH_IN-USE bit are read as 1b.
FLUDONE (RO) 26 0b
Flash Update Done. When set to 1b, indicates that the Flash update process that was
initiated by setting FLUPD bit has completed.
Reserved 31:27 0x0 Reserved. Reads as 0x0.
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Bit banging access to the flash via the FLA register is not protected by this field.
Field Bit(s) Initial Value Description
EE_SK 0 0b
Clock input to the EEPROM
When EE_GNT = 1b, the EE_SK output signal is mapped to this bit and provides
the serial clock input to the EEPROM. Software clocks the EEPROM via toggling
this bit with successive writes.
EE_CS 1 1b
Chip select input to the EEPROM
When EE_GNT = 1b, the EE_CS output signal is mapped to the chip select of the
EEPROM device. Software enables the EEPROM by writing a 0b to this bit.
EE_DI 2 1b
Data input to the EEPROM
When EE_GNT = 1b, the EE_DI output signal is mapped directly to this bit.
Software provides data input to the EEPROM via writes to this bit.
EE_DO (RO) 3 X1
Data output bit from the EEPROM
The EE_DO input signal is mapped directly to this bit in the register and contains
the EEPROM data output. This bit is RO from a software perspective; writes to
this bit have no effect.
FWE 5:4 01b
Flash Write Enable Control
These two bits, control whether writes to Flash memory are allowed.
00b = Flash erase (along with bit 31 in the FLA register).
01b = Flash writes disabled.
10b = Flash writes enabled.
11b = Reserved.
EE_REQ 6 0b
Request EEPROM Access
The software must write a 1b to this bit to get direct EEPROM access. It has
access when EE_GNT is 1b. When the software completes the access it must
write a 0b.
EE_GNT 7 0b
Grant EEPROM Access
When this bit is 1b the software can access the EEPROM using the SK, CS, DI,
and DO bits.
EE_PRES (RO) 8 X
EEPROM Present and Signature is valid
This bit indicates that an EEPROM is present and the value of the Signature field
in the EEPROM Sizing and Protected Fields EEPROM word (Word 0x12) is 01b
0b = Signature field invalid
1b = EEPROM present and signature is valid.
Auto_RD (RO) 9 0b
EEPROM Auto Read Done
When set to 1b, this bit indicates that the auto read by hardware from the
EEPROM is done. This bit is also set when the EEPROM is not present or when its
signature is not valid.
EE_ADDR_SIZE
(RO) 10 1b
EEPROM Address Size
This field defines the address size of the EEPROM.
This bit is set by the EEPROM size auto-detect mechanism. If no EEPROM is
present or the signature is not valid, a 16-bit address is assumed.
0b = 8- and 9-bit.
1b = 16-bit.
EE_SIZE (RO) 14:1120111b
EEPROM Size
This field defines the size of the EEPROM:
Field Value EEPROM Size EEPROM Address Size
0111b 16 Kbytes 2 bytes
1000b 32 Kbytes 2 bytes
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8.4.3 EEPROM-Mode Read Register - EERD (0x12014; RW)
This register is used by software to read individual words from the internal shadow RAM that reflects
the first valid 4 KB sector of the Flash. To read a word, software writes the address to the Read Address
field. Writing the register sets the Done bit to 0b. The I210 then reads the word from the internal
shadow RAM and places it in the Read Data field, setting the Read Done field to 1b. Software can poll
this register, looking for a 1b in the Read Done field and then using the value in the Read Data field.
This register is used by software to cause the I210 to read individual words in the EEPROM. To read a
word, software writes the address to the Read Address field and simultaneously writes a 1b to the Start
Read field. The I211 reads the word from the EEPROM and places it in the Read Data field, setting the
Read Done field to 1b. Software can poll this register, looking for a 1b in the Read Done field, and then
using the value in the Read Data field.
When this register is used to read a word from the EEPROM, that word does not influence any of the
I210's internal registers even if it is normally part of the auto-read sequence.
EE_BLOCKED (RO) 15 0b
EEPROM access blocked
EEPROM Bit Banging access blocked - Bit is set by HW when detecting an
EEPROM access violation during bit banging access using the EEC register or
detecting an EEPROM access violation when accessing the EPROM using the
EERD register. When bit is set further Bit Banging operations from the function
are disabled until bit is cleared.
Type of violations that can cause the bit to be set are write to read-only sections,
access to a hidden area or any other EEPROM protection violation detected.
Note: Bit is cleared by write one to the EEC.EE_CLR_ERR bit.
EE_ABORT (RO) 16 0b
EEPROM access Aborted
Bit is set by HW when EEPROM access was aborted due to deadlock avoidance,
management reset or EEPROM reset via CTRL_EXT.EE_RST.
When bit is set further Bit Banging operations from the Function are disabled
until bit is cleared.
Note: Bit is cleared by write one to the EEC.EE_CLR_ERR bit.
EE_RD_TIMEOUT
(RO) 17 0b
EERD access timeout
When bit is set to 1b indicates the EEPROM access via EERD register timed out
while trying to read EEPROM status (Can occur when no EEPROM exists).
Note: Bit is cleared by write one to the EEC.EE_CLR_ERR bit.
EE_CLR_ERR (SC) 18 0b
Clear EEPROM Access Error
A write 1b to the EE_CLR_ERR bit clears the EEC.EE_ABORT bit, EE_BLOCKED
bit and EE_RD_TIMEOUT bit.
Note: Clearing the EEC.EE_ABORT bit and EE_BLOCKED bit enables further Bit
Banging access to the EEPROM from the function.
EE_DET (RO) 19 X
EEPROM Detected
Note: Bit is set to 1b when EEPROM responded correctly to a get status
opcode following power-up.
Reserved 31:20 0x0 Reserved
Write 0 ignore on read.
1. Value depends on voltage level on EE_DO pin following initialization
2. These bits are read from the Flash.
Field Bit(s) Initial Value Description
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8.4.4 EEPROM-Mode Write Register – EEWR (0x12018; RW)
This register is used by software to write individual words in the internal shadow RAM that is about to
reflect the first valid 4 KB sector of the Flash. To write a word, software writes the address to the Write
Address field and the data to the Write Data field. The I210 writes the word into the internal shadow
RAM, setting the Write Done field to 1b. Software can poll this register, looking for a 1b in the Write
Done field before the next write. The data is effectively copied into the Flash device by use of the
EEC.FLUPD command.
When this register is used to write a word into the Flash, that word is not written to any of the I210's
internal registers even if it is normally a hardware-accessed word.
8.4.5 Flash Access - FLA (0x1201C; RW)
This register provides software direct access to the Flash. Software can control the Flash by successive
writes to this register. Data and address information is clocked into the Flash by software toggling the
FL_SCK bit (bit 0) of this register with FL_CE set to 0b. Data output from the Flash is latched into the
FL_SO bit (bit 3) of this register via the internal 125 MHz clock and can be accessed by software via
reads of this register.
Field Bit(s) Initial Value Description
START 0 0b
Start Read
Writing a 1b to this bit causes the EEPROM to read a (16-bit) word at the
address stored in the EE_ADDR field and then storing the result in the
EE_DATA field. This bit is self-clearing.
DONE (RO) 1 0b
Read Done
Set to 1b when the EEPROM read completes.
Set to 0b when the EEPROM read is not completed.
Writes by software are ignored. Reset by setting the START bit.
ADDR 15:2 0x0
Read Address
This field is written by software along with Start Read to indicate the word
to read.
DATA (RO) 31:16 X Read Data. Data returned from the EEPROM read.
Field Bit(s) Init. Description
CMDV (RO) 0 0b Command Valid.
This bit is cleared by hardware in case the write request was rejected.
DONE (RO field) 1 1b
Write Done.
Set this bit to 1b when the EEPROM-mode write completes.
Set this bit to 0b when the EEPROM-mode write is in progress.
Note that writes by software are ignored.
ADDR 12:2 0x0 Write Address.
This field is written by software to indicate the address of the word to write.
Reserved 15:13 0x0 Reserved. Reads as 0x0.
DATA 31:16 0x0 Write Data.
Data to be written into the shadow RAM.
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8.4.6 Flash Opcode - FLASHOP (0x12054; R/W)
This register enables the host or the firmware to define the op-code used in order to erase a sector of
the flash or the complete flash. This register is reset only at power on or LAN_PWR_GOOD assertion.
This register is common to all ports and manageability. Register should be programmed according to
the parameters of the flash used.
Field Bit(s) Initial Value Description
FL_SCK 0 0b
Clock Input to the Flash
When FL_GNT is 1b, the FL_SCK out signal is mapped to this bit and provides the
serial clock input to the Flash device. Software clocks the Flash memory via toggling
this bit with successive writes.
FL_CE 1 1b
Chip Select Input to the Flash
When FL_GNT is 1b, the FL_CE output signal is mapped to the chip select of the Flash
device. Software enables the Flash by writing a 0b to this bit.
FL_SI 2 1b
Data Input to the Flash
When FL_GNT is 1b, the FL_SI output signal is mapped directly to this bit. Software
provides data input to the Flash via writes to this bit.
FL_SO 3 X
Data Output Bit from the Flash
The FL_SO input signal is mapped directly to this bit in the register and contains the
Flash memory serial data output. This bit is read only from the software perspective
writes to this bit have no effect.
FL_REQ 4 0b
Request Flash Access
The software must write a 1b to this bit to get direct Flash memory access. It has
access when FL_GNT is 1b. When the software completes the access it must write a
0b.
FL_GNT 5 0b
Grant Flash Access
When this bit is 1b, the software can access the Flash memory using the FL_SCK,
FL_CE, FL_SI, and FL_SO bits.
FLA_add_size 6 0b
Flash Address Size
0b = Flash devices are accessed using 2 bytes of address.
1b = Flash devices (including 64 KB) are accessed using 3 bytes of the address.
Notes:
1. If this bit is set by one of the functions, it is also reflected in all other functions.
2. If value of BARCTRL.FLSize field is greater than 0x0, bit is read as 1b.
FLA_ABORT (RO) 7 0b
Flash Access Aborted
Bit is set by HW when Flash access was aborted due to deadlock avoidance. When bit
is set further Flash Bit Banging access from the function are blocked.
Note: Bit is cleared by write 1b to the FLA.FLA_CLR_ERR bit.
FLA_CLR_ERR (SC) 8 0b
Clear Flash Access Error
A write 1b to the FLA_CLR_ER bit clears the FLA.FLA_ABORT bit and enables further
Bit Banging access to the Flash from the function.
Reserved 28:9 0x0 Reserved
Write 0 ignore on read.
FL_BAR_WR (RO) 29 0b
Flash Write via BAR in Progress
This bit is set to 1b while a write to the Flash memory is in progress or is pending as
a result of a direct Memory access (not bit banging access). When this bit is clear
(read as 0b) software can initiate a byte write operation to the Flash device.
FL_BUSY (RO) 30 0b Flash Busy
When set to 1b indicates that a Flash memory access is in progress.
FL_ER (SC) 31 0b
Flash Erase Command
When bit is set to 1b an erase command is sent to the Flash component only if the
EEC.FWE field is 00b (Flash Erase). This bit is automatically cleared when flash erase
has completed.
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Note: The default values fit to Atmel* Serial Flash Memory devices.
8.4.7 EEPROM Auto Read Bus Control - EEARBC (0x12024; R/W)
In EEPROM-less implementations, this register is used to program the I210 the same way it should be
programmed if an EEPROM was present.
This register is common to all functions and should be accessed only following access coordination with
the other ports.
Field Bit(s) Initial Value Description
DERASE 7:0 0x0062 Flash Device Erase Instruction
The op-code for the Flash erase instruction.
SERASE 15:8 0x0052
Flash Block Erase Instruction
The op-code for the Flash block erase instruction. Relevant only to Flash
access by manageability.
Reserved 31:16 0x0 Reserved
Write 0 ignore on read.
Field Bit(s) Initial Value Description
VALID_CORE0 0 0b
Valid Write Active to Core 0
Write strobe to Core 0. Firmware/software sets this bit for write access to registers
loaded from EEPROM words in LAN0 section. Software should clear this bit to
terminate the write transaction.
VALID_CORE1 1 0b
Valid Write Active to Core 1
Write strobe to Core 1. Firmware/software sets this bit for write access to registers
loaded from EEPROM words in LAN1 section. Software should clear this bit to
terminate the write transaction.
VALID_COMMON 2 0b
Valid Write Active to Common
Write strobe to Common. Firmware/software sets this bit for write access to
registers loaded from EEPROM words that are common to all sections. Software
should clear this bit to terminate the write transaction.
VALID_PCIE 3 0b
Valid Write Active to PCIe PHY
Write strobe to PCI PHY. Firmware/software sets this bit for write access to registers
loaded from EEPROM words pointed by word 0x10 that are directed to the PCIe phy.
Software should clear this bit to terminate the write transaction.
ADDR 12:4 0x0
Write Address
This field specifies the address offset of the EEPROM word from the start of the
EEPROM Section. Sections supported are:
Common and LAN0
LAN1
LAN2
LAN3
VALID_CORE2 13 0b
Valid Write Active to Core 2
Write strobe to Core 2. Firmware/software sets this bit for write access to registers
loaded from EEPROM words in LAN2 section. Software should clear this bit to
terminate the write transaction.
VALID_CORE3 14 0b
Valid Write Active to Core 3
Write strobe to Core 3. Firmware/software sets this bit for write access to registers
loaded from EEPROM words in LAN3 section. Software should clear this bit to
terminate the write transaction.
Reserved 15 0b Reserved
Write 0, ignore on read.
DATA 31:16 0x0 Data written into the EEPROM auto read bus.
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1. Not all EEPROM addresses are part of the auto read. By using this register software can write to the hardware registers that are
configured during auto read only.
2. Host access via EEARBC can be done only when no EEPROM presence is detected. Management can access the internal registers
via EEARBC also when EEPROM presence is detected and EEPROM load is done.
8.4.8 VPD Diagnostic Register - VPDDIAG (0x1060; RO)
This register stores the VPD parameters as parsed by the auto-load process. This register is used for
debug only.
8.4.9 Management-EEPROM CSR I/F
The following registers are reserved for Firmware access to the EEPROM and are not writable by the
host.
8.4.9.1 Management EEPROM Control Register - EEMNGCTL (0x12030; RW)
Field Bit(s) Initial Value Description
ADDR 14:0 0x0 Address - This field is written by MNG along with Start Read or Start write to indicate
the EEPROM word address to read or write.
START 15 0b
Start - Writing a 1b to this bit causes the EEPROM to start the read or write operation
according to the write bit.
Note: Bit is not cleared by Firmware reset.
WRITE 16 0b
Write - This bit tells the EEPROM if the current operation is read or write:
0b = read
1b = write
EEBUSY 17 0b EEPROM Busy - This bit indicates that the Flash is busy processing an Flash transaction
and Flash access will be delayed.
CFG_DONE 0118 0b
Configuration cycle is done for port 0 – This bit indicates that configuration cycle
(configuration of SerDes, PHY, PCIe and PLLs) is done for port 0. This bit is set to 1b to
indicate configuration done, and cleared by hardware on any of the reset sources that
causes initialization of the PHY.
Note: Port 0 driver should not try to access the PHY for configuration before this bit is
set.
CFG_DONE 1119 0b
Configuration cycle is done for port 1 – This bit indicates that configuration cycle
(configuration of SerDes, , PCIe and PLLs) is done for port 1. This bit is set to 1b to
indicate configuration done, and cleared by hardware on any of the reset sources that
cause initialization of the PHY.
Note: Port 1 driver should not try to access the PHY for configuration before this bit is
set.
CFG_DONE 2120 0b
Configuration cycle is done for port 2 – This bit indicates that the configuration cycle
(configuration of SerDes, PCIe and PLLs) is done for port 2. This bit is set to 1b to
indicate configuration done, and cleared by hardware on any of the reset sources that
cause initialization of the PHY.
Note: Port 2 driver should not try to access the PHY for configuration before this bit is
set.
CFG_DONE 3121 0b
Configuration cycle is done for port 3 – This bit indicates that the configuration cycle
(configuration of SerDes, PCIe and PLLs) is done for port 3. This bit is set to 1b to
indicate configuration done, and cleared by hardware on any of the reset sources that
cause initialization of the PHY.
Note: Port 3 driver should not try to access the PHY for configuration before this bit is
set.
Reserved 28:22 0x0 Reserved
Write 0, ignore on read.
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8.4.9.2 Management EEPROM Read/Write data - EEMNGDATA (0x12034; RW)
8.4.10 Management-Flash CSR I/F
The following registers are reserved for firmware access to the serial flash and are not writable by the
host.
8.4.10.1 Management Flash Control Register - FLMNGCTL (0x12038; RW)
8.4.10.2 Management Flash Read Data - FLMNGDATA (0x1203C; RW)
8.4.10.3 Management Flash Read Counter - FLMNGCNT (0x12040; RW)
8.4.11 Manageability EEPROM-Mode Control Register – EEMNGCTL
(0x12030; RO to Host, RW to FW)
Note: The transactions performed through this register are directed to/from the internal shadow
RAM. The write data is effectively copied into the Flash device by use of the EEC.FLUPD
command.
8.4.12 EEPROM-Mode Auto Read Bus Control - EEARBC (0x12024; RO in
Secured Mode)
Note: In iNVM implementations, this register is used to program the I210 the same way it should be
programmed if an NVM was present.
EEMNGCTL_CL
R_ERR (SC) 29 0b
Clear Timeout Error
A write 1b to the EEMNGCTL.EEMNGCTL_CLR_ERR bit clears the error reported in the
EEMNGCTL.TIMEOUT bit.
TIMEOUT 30 0b
When bit is set to 1b indicates that a transaction timed out while trying to read the
Flash status (Occurs when no Flash exists).
Notes:
1. To clear the bit Firmware should write 1b to the EEMNGCTL.EEMNGCTL_CLR_ERR
bit.
2. Bit is not cleared by Firmware reset.
DONE 31 1b
Transaction Done - This bit is cleared after the Start Write or Start Read bit is set by the
MNG and is set back again when the Flash write or read transaction is done.
Note: Bit is not cleared by Firmware reset.
1. Bit relates to physical port. If LAN Function Swap (FACTPS.LAN Function Sel = 1) is done, Software should poll CFG_DONE bit of
original port to detect end of PHY configuration operation.
Field Bit(s) Initial Value Description
WRDATA 15:0 0x0 Write Data
Data to be written to the Flash.
RDDATA (RO) 31:16 – Read Data
Data returned from the Flash read.
Field Bit(s) Initial Value Description
Programming Interface — Ethernet Controller I210
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8.4.13 Flash Mode Register – FLASHMODE (0x12000; RO in Secured
Mode)
This register controls the interface for the Flash device. This register is reset only at power on or during
LAN_PWR_GOOD assertion.
8.4.14 Flash Op-code Register – FLASHOP (0x12054; RO in Secured
Mode)
This register holds the Flash op-codes. This register is reset only at power on or during
LAN_PWR_GOOD assertion.
Field Bit(s) Initial Value Description
VALID 0 0b Valid.
Indicates that the last auto-load bus write request is valid.
DONE 1 1b
Done.
Last auto-load bus write request completed. The register can be written again with
a new auto-load write request.
Reserved 3:2 0x0 Reserved.
Write 0x0, ignore on read.
ADDR 12:4 0x00
Write Address.
This field specifies the address offset of the Flash word from the start of the shadow
RAM section1.
1. Not all shadow RAM addresses are part of the auto read (auto-load). By using this register software can write to the hardware
registers that are configured during auto load only.
Reserved 15:13 0x0 Reserved.
Write 0x0, ignore on read.
DATA 31:16 0x0000 Data written into the Flash auto read bus.
Field Bit(s) Init. Description
FAST_READ_MODE 0 0b When set to 1b, the op-code for a Read command is taken from FLASHOP.FASTREAD
and the number of dummy bytes are asserted as indicated in the NUM_OF_DUMMY
field.
NUM_OF_DUMMY 2:1 01b Indicates the number of dummy bytes that should be provided to the Flash after
providing the address.
FLASH_SPEED 4:3 0b
Indicates the frequency of the clock provided to the Flash.
00b = Clock is 15.125 MHz
01b = Clock is 31.25 MHz.
10b = Clock is 62.5 MHz.
11b = Reserved.
Reserved 5 0 Reserved
SST_MODE 6 1b
When set to 1b,indicates that the current Flash device operates in a 1-byte program for
each Flash access. This mode is the default operating mode as it is supported by all
Flash devices. However, each time the Flash device supports burst writes, clearing this
bit improves Flash write performance.
Reserved 31:7 0x0 Reserved.
Field Bit(s) Init. Description
FLASHERASEOP 7:0 0xC7 Holds the op-code for erasing the entire Flash device.
SUSPENDOP 15:8 0x75 Holds the op-code for suspending the program/erase operation in the Flash.
Ethernet Controller I210 — Programming Interface
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8.4.15 Flash Timing Register – FLASHTIME (0x12004; RO in Secured
Mode)
This register holds the timing parameters for Flash access. This register is reset only at power on or
during LAN_PWR_GOOD assertion. It is loaded by firmware from its own module.
8.4.16 Flash Block Base Address – FLBLKBASE (0x12100; RO)
8.4.17 Flash Block End Address – FLBLKEND (0x12104; RO)
8.4.18 Flash Firmware Code Update – FLFWUPDATE (0x12108; RW)
RESUMEOP 23:16 0x7A Holds the op-code for resuming the program/erase operation that was suspended.
FASTREADOP 31:24 0x0B Holds the op-code that is issued in a Read command when Fast Read Mode Is set.
Field Bit(s) Init. Description
CSDESELECT 3:0 0xB Indicates the time in cycles of 8 ns that CS should be de-asserted between two
commands. Note that an offset of 16 ns is added to the programmed value. The default
is 104 ns.
Reserved 15:04 0x0 Reserved.
HOLDTIME 31:16 0x00FF
The I210 maintains a hold timer that counts the time that CS is asserted and no
command is issued.
When the timer expires, the CS is de-asserted and the next command starts a new
transaction to Flash.
The time is measured in cycles of 16 ns. The default is 4 µs.
Field Bit(s) Init. Description
Start Address 11:0 0x000 The base address expressed in a 4 KB sector index of the Flash section, which is
protected from software writes. Aligned to 4 KB boundaries. Loaded from the secured
section in Flash (word 0x10).
Reserved 30:12 Reserved.
Field Bit(s) Init. Description
End Address 11:0 0x000
The last 4 KB sector index included in the Flash section, which is protected from
software writes. It is derived by firmware from Max Module Area field extracted from
the new firmware image header (refer to Table 6-14).
A null value in this field means no blocked area.
Reserved 31:12 Reserved
Field Bit(s) Init. Description
Reserved 28:0 Reserved.
AUTHEN-DONE (RO) 29 0x0
Authentication Cycle Done.
Set to 1b when done.
This bit is self-cleared once the update request is set to 1b.
Field Bit(s) Init. Description
Programming Interface — Ethernet Controller I210
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8.4.19 EEPROM Block Base Address – EEBLKBASE (0x1210C; RO)
8.4.20 EEPROM Block End Address – EEBLKEND (0x12110; RO)
8.4.21 Software Flash Burst Control Register - FLSWCTL (0x12048; RW)
AUT_FAIL (RO) 30 0x0 Authentication failed. Set to 1b when failed.
Update 31 0b
Request authentication of the new secure section written. If the authentication
succeeds, firmware resets itself to load its new code.
This bit is self-cleared, always read as 0b.
Field Bit(s) Init. Description
1st Start Address 10:0 0x000 The base address expressed in words of the first hardware section (EEPROM map),
which is protected from software writes. Loaded from the secured section in the Flash
(word 0x2D).
Reserved 11 Reserved.
2nd Start Address 22:12 0x000
The base address expressed in words of the second hardware section (EEPROM map),
which is protected from software writes. Loaded from the secured section in Flash (word
0x12). This read-only section ends at the shadow RAM ends.
For legacy reasons, it is cleared to 0x000 when there is no second hardware protected
section in the shadow RAM.
Reserved 31:23 Reserved.
Field Bit(s) Init. Description
1st End Address 10:0 0x000
The last address expressed in words of the first hardware section (EEPROM map), which
is protected from software writes. Loaded from the secured section in the Flash (word
0x2C).
For legacy reasons, it is cleared to 0x000 when there is no first hardware protected
section in the shadow RAM.
Reserved 31:11 Reserved
Field Bit(s) Init. Description
ADDR 23:0 0x0
Address in Bytes.
This field is written by software along with CMD to indicate the Flash address to which
the operation (read/write/erase, etc.) is performed. See the command description
following this table.
CMD 27:24 00b Command.
Indicates which command that should be executed.
CMDV (RO) 28 0b
Last Command was Valid.
When cleared, it indicates that the last command issued was either a reserved
combination (see the following table), or one of the following:
When count reached zero (except for a general purpose status write)
When a write burst crosses a Flash page
When the address to be written is protected (RO)
When the CNT specified is out of the permitted range (see the following table).
FLBUSY (RO) 29 0b
Flash Busy.
This bit indicates that the Flash is busy processing a Flash transaction and should not be
accessed.
Field Bit(s) Init. Description
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8.4.22 Software Flash Burst Data Register - FLSWDATA (0x1204C; RW)
DONE (RO) 30 1b
Single Flash Transaction Done.
This bit clears after the register is written by software and is set back again when the
single Flash transaction was issued to the Flash device.
When writing a burst transaction, the bit is cleared every time software writes
FLSWDATA.
GLDONE (RO) 31 1b
Global Flash Transaction Done.
This bit clears after the register is written by software and is set back again when the all
the Flash transactions were issued to the Flash device. For example, the Flash device
completed all requested read/writes.
CMD{27:24} FLSWCNT.CNT
range Limitations to Host Command Description
0000b 1 B - 4 KB Read
0001b
1 B - 256 B
the write must not
cross a page (256 B)
boundary
When in the Flash Secure mode,
this command is operational
only if applied on un-secured
words.
Write
0010b Don’t Care When in Flash secure mode, this
command is operational only if
applied on un-secured sectors.
Flash sector (4 KB) erase (when no security). The 4
KB sector index to be erased is determined by the
ADDR field.
0011b Don’t Care This command is not operational
when in Flash secure mode. Flash device erase (when no security). The entire
Flash device is erased.
0100b 1 B - 4 B Read Status register of Flash device.
0101b 1 B - 4 B This command is not operational
when in Flash secure mode. Write Status register of Flash device.
0110b Don’t Care This command is not operational
when in Flash secure mode.
Write Enable.
Depending on the Flash device Datasheet, this
command might be needed prior to issuing the
1100b Programmable Write Status register op-
code.
0110b, 0111b Reserved.
1000b 1 B - 4 B Read JEDEC ID.
1001b Reserved.
1010b Reserved.
1011b 1 B - 4 B Op-code cannot be re-
programmed when in Flash
secured mode Programmable Read Status register.
1100 0 B - 4 B This command is not operational
when in Flash secure mode. Programmable Write Status register.
Field Bit(s) Init. Description
DATA 31:0 0x0
Burst Flash Data.
Data written to or read from the Flash.
When FLSWCNT.CNT field is programmed with a number of bytes that is not aligned a
multiple of four (last Dword is a partial), the last valid byte(s) are located in the lower
DATA field bytes.
Field Bit(s) Init. Description
Programming Interface — Ethernet Controller I210
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8.4.23 Software Flash Burst Access Counter - FLSWCNT (0x12050; RW)
8.4.24 Data - INVM_DATA (0x12120 + 4*n [n = 0..63]; R/W1)
These registers holds the iNVM memory content. The iNVM memory is organized in 32 lines of 64-bits
each. INVM_DATA[0] holds the lowest 32 bits of the first iNVM line. INVM_DATA[1] holds the highest
32 bits of the first iNVM line.
8.4.25 Lock - INVM_LOCK (0x12220 + 4*n [n = 0..31]; R/W1)
The iNVM memory is organized in 32 lines of 64-bits each. INVM_LOCK[n] controls iNVM memory line
n.
8.4.26 Protect - INVM_PROTECT (0x12324; RW)
Note: Register bits reset after LAN_PWR_GOOD.
Field Bit(s) Init. Description
Reserved 31:13 0x0 Reserved
CNT 12:0 0x0 Flash Burst Counter.
This counter holds the size in bytes of the Flash burst read or write.
Field Bit(s) Init. Description
DATA 31:0 0x0
Data value programmed or to be programmed in the corresponding iNVM line segment
(high or low order 32-bits).
Once a bit that has been programmed to 1b, it cannot be re-programmed to 0b.
Field Bit(s) Init. Description
LOCK 0 0b When set to 1b, the corresponding iNVM line is locked and cannot be programmed.
Once this bit that has been programmed to 1b, it cannot be re-programmed to 0b.
Reserved 31:1 0x0 Reserved.
Field Bit(s) Init. Description
ALLOW_WRITE (RO) 0 0b When read as 1b, it indicates that the iNVM is enabled for writes.For example, the Code
field was written with the correct value, which enables writing the iNVM (0xABACADA).
WRITE_ERROR (RO) 1 0b
When read as 1b, it indicates an attempt to write the iNVM when the write was locked
(ALLOW_WRITE bit was 0b) or when the iNVM was still busy with a previous write.
This bit is cleared on the next iNVM write operation that was successfully performed.
BUSY (RO) 2 0b When read as 1b, it indicates that the iNVM is still busy with the previous write.
Reserved 3 0b Reserved.
CODE 31:4 0x0
When set to 0xABACADA, the iNVM is enabled for writes. Any other value set in this field
is protected against mistakenly writing the iNVM.
This field is always read as 0x0.
Ethernet Controller I210 — Programming Interface
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8.5 Flow Control Register Descriptions
8.5.1 Flow Control Address Low - FCAL (0x0028; RO)
Flow control packets are defined by 802.3X to be either a unique multicast address or the station
address with the EtherType field indicating PAUSE. The FCA registers provide the value hardware uses
to compare incoming packets against, to determine that it should PAUSE its output.
The FCAL register contains the lower bits of the internal 48-bit Flow Control Ethernet address. All 32
bits are valid. Software can access the High and Low registers as a register pair if it can perform a 64-
bit access to the PCIe bus. The complete flow control multicast address is: 0x01_80_C2_00_00_01;
where 0x01 is the first byte on the wire, 0x80 is the second, etc.
Note: Any packet matching the contents of {FCAH, FCAL, FCT} when CTRL.RFCE is set is acted on
by the I210. Whether flow control packets are passed to the host (software) depends on the
state of the RCTL.DPF bit.
8.5.2 Flow Control Address High - FCAH (0x002C; RO)
This register contains the upper bits of the 48-bit Flow Control Ethernet address. Only the lower 16 bits
of this register have meaning. The complete Flow Control address is {FCAH, FCAL}.
The complete flow control multicast address is: 0x01_80_C2_00_00_01; where 0x01 is the first byte
on the wire, 0x80 is the second, etc.
8.5.3 Flow Control Type - FCT (0x0030; R/W)
This register contains the Type field that hardware matches to recognize a flow control packet. Only the
lower 16 bits of this register have meaning. This register should be programmed with 0x88_08. The
upper byte is first on the wire FCT[15:8].
Field Bit(s) Initial Value Description
FCAL 31:0 0x00C28001 Flow Control Address Low.
Field Bit(s) Initial Value Description
FCAH 15:0 0x0100 Flow Control Address High.
Should be programmed with 0x01_00.
Reserved 31:16 0x0 Reserved.
Write 0x0, ignore on read.
Field Bit(s) Initial Value Description
FCT 15:0 0x8808 Flow Control Type.
Reserved 31:16 0x0 Reserved.
Write 0x0, ignore on read.
Programming Interface — Ethernet Controller I210
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8.5.4 Flow Control Transmit Timer Value - FCTTV (0x0170; R/W)
The 16-bit value in the TTV field is inserted into a transmitted frame (either XOFF frames or any PAUSE
frame value in any software transmitted packets). It counts in units of slot time of 64 bytes. If software
needs to send an XON frame, it must set TTV to 0x0 prior to initiating the PAUSE frame.
8.5.5 Flow Control Receive Threshold Low - FCRTL0 (0x2160; R/W)
This register contains the receive threshold used to determine when to send an XON packet The
complete register reflects the threshold in units of bytes. The lower four bits must be programmed to
0x0 (16 byte granularity). Software must set XONE to enable the transmission of XON frames. Each
time hardware crosses the receive-high threshold (becoming more full), and then crosses the receive-
low threshold and XONE is enabled (1b), hardware transmits an XON frame. When XONE is set, the RTL
field should be programmed to at least 0x3 (at least 48 bytes).
Flow control reception/transmission are negotiated capabilities by the auto-negotiation process. When
the I210 is manually configured, flow control operation is determined by the CTRL.RFCE and CTRL.TFCE
bits.
8.5.6 Flow Control Receive Threshold High - FCRTH0 (0x2168; R/W)
This register contains the receive threshold used to determine when to send an XOFF packet. The
complete register reflects the threshold in units of bytes. This value must be at maximum 48 bytes less
than the maximum number of bytes allocated to the Receive Packet Buffer (RXPBSIZE.RXPbsize), and
the lower four bits must be programmed to 0x0 (16 byte granularity). The value of RTH should also be
bigger than FCRTL0.RTL. Each time the receive FIFO reaches the fullness indicated by RTH, hardware
transmits a PAUSE frame if the transmission of flow control frames is enabled.
Flow control reception/transmission are negotiated capabilities by the auto-negotiation process. When
the I210 is manually configured, flow control operation is determined by the CTRL.RFCE and CTRL.TFCE
bits.
Field Bit(s) Initial Value Description
TTV 15:0 X Transmit Timer Value.
Reserved 31:16 0x0 Reserved.
Write 0x0, ignore on read.
Field Bit(s) Initial Value Description
Reserved 3:0 0x0 Reserved.
Write 0x0, ignore on read.
RTL 16:4 0x0
Receive Threshold Low.
FIFO low water mark for flow control transmission when transmit flow control is
enabled (CTRL.TFCE = 1b).
An XON packet is sent if the occupied space in the packet buffer is smaller or equal
than this watermark.
This field is in 16 bytes granularity.
Reserved 30:17 0x0 Reserved.
Write 0x0, ignore on read.
XONE 31 0b
XON Enable.
0b = Disabled.
1b = Enabled.
Ethernet Controller I210 — Programming Interface
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8.5.7 Flow Control Refresh Threshold Value - FCRTV (0x2460; R/W)
8.5.8 Flow Control Status - FCSTS0 (0x2464; RO)
This register describes the status of the flow control machine.
Field Bit(s) Initial Value Description
Reserved 3:0 0x0 Reserved.
Write 0x0, ignore on read.
RTH 17:4 0x0
Receive Threshold High.
FIFO high water mark for flow control transmission when transmit flow control is
enabled (CTRL.TFCE = 1b). An XOFF packet is sent if the occupied space in the packet
buffer is bigger or equal than this watermark.
This field is in 16 bytes granularity.
Refer to Section 3.7.5.3.1 for calculation of FCRTH0.RTH value.
Notes:
1. When in DMA coalescing operation and the internal transmit buffer is empty, the
threshold high value defined in FCRTC.RTH_Coal is used instead of the
FCRTH0.RTH value to allow an increase of the receive threshold high value by the
maximum supported Jumbo frame size.
2. The value programmed should be greater than the maximum packet size.
Reserved 31:18 0x0 Reserved.
Write 0x0, ignore on read.
Field Bit(s) Initial Value Description
FC_refresh_th 15:0 0x0
Flow Control Refresh Threshold.
This value indicates the threshold value of the flow control shadow counter when
transmit flow control is enabled (CTRL.TFCE = 1b). When the counter reaches this
value, and the conditions for PAUSE state are still valid (buffer fullness above low
threshold value), a PAUSE (XOFF) frame is sent to link partner.
If this field contains zero value, the flow control refresh is disabled.
Reserved 31:16 X Reserved.
Write 0x0, ignore on read.
Field Bit(s) Initial Value Description
Flow_control
state 0 0b
Flow Control State Machine Signal.
0b = XON.
1b = XOFF.
Above high 1 0x0 The size of data in the memory is above the high threshold.
Below low 2 1b The size of data in the memory is below the low threshold.
Reserved 15:3 0x0 Reserved.
Write 0x0, ignore on read.
Refresh
counter 31:16 0x0 Flow Control Refresh Counter.
Programming Interface — Ethernet Controller I210
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8.6 PCIe Register Descriptions
8.6.1 PCIe Control - GCR (0x5B00; RW)
8.6.2 PCIe Statistics Control #1 - GSCL_1 (0x5B10; RW)
Field Bit(s) Initial Value Description
Reserved 1:0 0x0 Reserved.
Discard on BME de-
assertion 2 1b When set and BME deasserted, PCIe discards all requests of this function.
Reserved 8:3 0x0 Reserved.
Write 0x0, ignore on read.
Completion Timeout
Resend Enable 9 0b1
1. Loaded from PCIe Completion Timeout Configuration Flash word (word 0x15).
When set, enables a resend request after the completion timeout expires.
0b = Do not resend request after completion timeout.
1b = Resend request after completion timeout.
Note: This field is loaded from the Completion Timeout Resend bit in the
Flash.
Reserved 10 0b Reserved.
Write 0b, ignore on read.
Number of Resends 12:11 11b The number of resends in case of timeout or poisoned.
Reserved 17:13 0x0 Reserved.
Write 0x0, ignore on read.
PCIe Capability Version
(RO) 18 1b2
2. The default value for this field is read from the PCIe Init Configuration 3 Flash word (address 0x1A) bits 11:10. If these bits are
set to 10b, then this field is set to 1b, otherwise field is reset to zero.
Reports the PCIe capability version supported.
0b = Capability version: 0x1.
1b = Capability version: 0x2.
Reserved 30:19 0x0 Reserved.
DEV_RST In Progress 31 0b
Device Reset in Progress.
This bit is set following device reset assertion (CTRL.DEV_RST = 1b) until
no pending requests exist in PCIe.
The software device driver should wait for this bit to be cleared before re-
initializing the port (Refer to Section 4.3.1).
Field Bit(s) Initial Value Description
GIO_COUNT_EN_0 0 0b Enable PCIe Statistic Counter Number 0.
GIO_COUNT_EN_1 1 0b Enable PCIe Statistic Counter Number 1.
GIO_COUNT_EN_2 2 0b Enable PCIe Statistic Counter Number 2.
GIO_COUNT_EN_3 3 0b Enable PCIe Statistic Counter Number 3.
LBC Enable 0 4 0b When set, statistics counter 0 operates in Leaky Bucket mode.
LBC Enable 1 5 0b When set, statistics counter 1 operates in Leaky Bucket mode.
LBC Enable 2 6 0b When set, statistics counter 2 operates in Leaky Bucket mode.
LBC Enable 3 7 0b When set, statistics counter 3 operates in Leaky Bucket mode.
Reserved 26:8 0x0 Reserved.
Write 0x0, ignore on read.
GIO_COUNT_TEST 27 0b Test Bit.
Forward counters for testability.
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8.6.3 PCIe Statistics Control #2 - GSCL_2 (0x5B14; RW)
This register configures the events counted by the GSCN_0, GSCN_1, GSCN_2 and GSCN_3 counters.
Table 8-9 lists the encoding of possible event types counted by GSCN_0,GSCN_1, GSCN_2 and
GSCN_3.
GIO_64_BIT_EN 28 0b Enable two 64-bit counters instead of four 32-bit counters.
GIO_COUNT_RESET 29 0b Reset indication of PCIe statistical counters.
GIO_COUNT_STOP 30 0b Stop indication of PCIe statistical counters.
GIO_COUNT_START 31 0b Start indication of PCIe statistical counters.
Field Bit(s) Initial Value Description
GIO_EVENT_NUM_0 7:0 0x0 Event type that counter 0 (GSCN_0) counts.
GIO_EVENT_NUM_1 15:8 0x0 Event type that counter 1 (GSCN_1) counts.
GIO_EVENT_NUM_2 23:16 0x0 Event type that counter 2 (GSCN_2) counts.
GIO_EVENT_NUM_3 31:24 0x0 Event type that counter 3 (GSCN_3) counts.
Field Bit(s) Initial Value Description
Programming Interface — Ethernet Controller I210
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Table 8-9. PCIe Statistic Events Encoding
8.6.4 PCIe Statistic Control Register #5...#8 - GSCL_5_8 (0x5B90 +
4*n[n=0...3]; RW)
These registers control the operation of the statistical counters GSCN_0,GSCN_1, GSCN_2 and GSCN_3
when operating in Leaky Bucket mode:
GSCL_5 controls operation of GSCN_0.
GSCL_6 controls operation of GSCN_1.
GSCL_7 controls operation of GSCN_2.
GSCL_8 controls operation of GSCN_3.
Transaction Layer Events
Event
Mapping
(Hex)
Description
Bad TLP From LL 0x0 For each cycle, the counter increases by one, if a bad TLP is received (bad CRC,
error reported by AL, misplaced special char, or reset in thI of received tlp).
Requests That Reached Timeout 0x10 Number of requests that reached time out.
NACK DLLP Received 0x20 For each cycle, the counter increases by one, if a message was transmitted.
Replay Happened in Retry-Buffer 0x21 Occurs when a replay happened due to a timeout (not asserted when replay
initiated due to NACK.
Receive Error 0x22
Set when one of the following occurs:
1. Decoder error occurred during training in the PHY. It is reported only when
training ends.
2. Decoder error occurred during link-up or until the end of the current packet
(if the link failed). This error is masked when entering/exiting EI.
Replay Roll-Over 0x23 Occurs when a replay was initiated for more than three times (threshold is
configurable by the PHY CSRs).
Re-Sending Packets 0x24 Occurs when a TLP is resent in case of a completion timeout.
Surprise Link Down 0x25 Occurs when link is unpredictably down (not because of reset or DFT).
LTSSM in L0s in both Rx & Tx 0x30 Occurs when LTSSM enters L0s state in both Tx and Rx.
LTSSM in L0s in Rx 0x31 Occurs when LTSSM enters L0s state in Rx.
LTSSM in L0s in Tx 0x32 Occurs when LTSSM enters L0s state in Tx.
LTSSM in L1 active 0x33
Occurs when LTSSM enters L1-active state (requested from host side).
Note: In case of RECOVERY entries not due to L1 exit, if the host will NAK the
L1 request, there will be false L1 entry counts.
LTSSM in L1 SW 0x34
Occurs when LTSSM enters L1-switch (requested from switch side).
Note: In case of RECOVERY entries not due to L1 exit, if the host will NAK the
L1 request, there will be false L1 entry counts.
LTSSM in Recovery 0x35 Occurs when LTSSM enters recovery state.
Field Bit(s) Initial Value Description
LBC threshold n 15:0 0x0 Threshold for the Leaky Bucket Counter n.
LBC timer n 31:16 0x0 Time period between decrementing the value in Leaky Bucket Counter n.
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8.6.5 PCIe Counter #0 - GSCN_0 (0x5B20; RC)
8.6.6 PCIe Counter #1 - GSCN_1 (0x5B24; RC)
8.6.7 PCIe Counter #2 - GSCN_2 (0x5B28; RC)
8.6.8 PCIe Counter #3 - GSCN_3 (0x5B2C; RC)
8.6.9 Function Active and Power State to MNG - FACTPS (0x5B30; RO)
Note: Register resets by LAN_PWR_GOOD and PCIe reset.
Field Bit(s) Initial Value Description
EVC 31:0 0x0
Event Counter.
Type of event counted is defined by the GSCL_2.GIO_EVENT_NUM_0 field.
Count value does not wrap around and remains stuck at the maximum
value of 0xFF...F. Value is cleared by read.
Field Bit(s) Initial Value Description
EVC 31:0 0x0
Event Counter.
Type of event counted is defined by the GSCL_2.GIO_EVENT_NUM_1 field.
Count value does not wrap around and remains stuck at the maximum
value of 0xFF...F. Value is cleared by read.
Field Bit(s) Initial Value Description
EVC 31:0 0x0
Event Counter.
Type of event counted is defined by the GSCL_2.GIO_EVENT_NUM_2 field.
Count value does not wrap around and remains stuck at the maximum
value of 0xFF...F. Value is cleared by read.
Field Bit(s) Initial Value Description
EVC 31:0 0x0
Event Counter.
Type of event counted is defined by the GSCL_2.GIO_EVENT_NUM_3 field.
Count value does not wrap around and remains stuck at the maximum
value of 0xFF...F. Value is cleared by read.
Programming Interface — Ethernet Controller I210
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8.6.10 Mirrored Revision ID - MREVID (0x5B64; R/W)
8.6.11 PCIe Control Extended Register - GCR_EXT (0x5B6C; RW)
Field Bit(s) Initial Value Description
Func Power State 1:0 00b
Power state indication of Function.
00b = DR.
01b = D0u.
10b = D0a.
11b = D3.
This field resets only by LAN_PWR_GOOD.
Reserved 2 0b Reserved.
Func Aux_En 3 0b Function Auxiliary (AUX) Power PM Enable bit shadow from the
configuration space.
Reserved 28:4 0x0 Reserved.
Write 0x0, ignore on read.
MNGCG 29 0b MNG Clock Gated.
When set, indicates that the manageability clock is gated.
Reserved 30 0b Reserved.
PM State Changed (RC) 31 0b
Indicates that one or more of the functional power states have changed.
This bit is also a signal to the MC to create an interrupt.
This bit is cleared on read by the MC.
This bit resets only by LAN_PWR_GOOD.
Field Bit(s) Initial Value Description
Flash RevID 7:0 0x0 Mirroring of revision ID loaded from the Flash in PCIe configuration space
(from Device Rev ID word, address 0x1E).
Step REV ID 15:8 0x01 for A1
0x03 for A2 Revision ID from FUNC configuration space.
Reserved 31:16 0x0 Reserved
Write 0x0, ignore on read.
Field Bit(s) Init. Description
Reserved 3:0 0x0 Reserved.
APBACD 4 0b
Auto PBA Clear Disable. When set to 1b, software can clear the PBA only by a direct write to
clear access to the PBA bit. When set to 0b, any active PBA entry is cleared on the falling edge
of the appropriate interrupt request to the PCIe block. The appropriate interrupt request is
cleared when software sets the associated Interrupt Mask bit in the EIMS (re-enabling the
interrupt) or by direct write to clear to the PBA.
Reserved 31:5 0x0 Reserved.
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8.6.12 PCIe BAR Control - BARCTRL (0x5BFC; R/W) Target
8.6.13 Read Request To Data Completion Delay Register - RR2DCDELAY
(0x5BF4; RC)
Note: Register resets by LAN_PWR_GOOD and PCIe reset.
8.6.14 PCIe MCTP Register - PCIEMCTP (0x5B4C; RO to Host)
Note: Reset by PCIe reset.
Field Bit(s) Initial Value Description
Reserved 31:0 0x0 Reserved
Write 0x0, ignore on read.
Table 8-10. Usable Flash Size and CSR Mapping Window Size
FLBARSize CSRSize Resulted CSR + Flash BAR Size Installed Flash Device Usable Flash Space
000b 0 128 KB No Flash 0
000b 1 256 KB 64 KB 64 KB
001b 0 256 KB 128 KB 128 KB
001b 1 n/a n/a Reserved
010b 0 256 KB 256 KB 256 KB minus 128 KB
010b 1 512 KB 256 KB 256 KB
011b 0 512 KB 512 KB 512 KB minus 128 KB
011b 1 1 MB 512 KB 512 KB
100b 0 1 MB 1 MB 1 MB minus 128 KB
100b 1 2 MB 1 MB 1 MB
101b 0 2 MB 2 MB 2 MB minus 128 KB
101b 1 4 MB 2 MB 2 MB
110b 0 4 MB 4 MB 4 MB minus 128 KB
110b 1 8 MB 4MB 4 MB
111b 0 8 MB 8MB 8 MB minus 128 KB
111b 1 16 MB 8MB 8 MB
Field Bit(s) Initial Value Description
Max Split Time 31:0 0x0 This field captures the maximum PCIe split time in 16 ns units, which is the
maximum delay between the read request to the first data completion. This
is giving an estimation of the PCIe round trip time.
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8.7 Semaphore Registers
This section contains registers used to coordinate between firmware and software. The usage of these
registers is described in Section 4.6.11.
8.7.1 Software Semaphore - SWSM (0x5B50; R/W)
Field Bit(s) Initial
Value Description
Disable ACL 0 0b When set, the ACL check on the PCIe VDMs is disabled.
Reserved 31:1 0x0 Reserved
Write 0x0, ignore on read
Field Bit(s) Initial Value Description
SMBI (RS) 0 0b
Software/Software Semaphore Bit
This bit is set by hardware when this register is read by the software device
driver and cleared when the host driver writes a 0b to it.
The first time this register is read, the value is 0b. In the next read the
value is 1b (hardware mechanism). The value remains 1b until the software
device driver clears it.
This bit can be used as a semaphore between all I210 driver threads.
This bit is cleared on PCIe reset.
SWESMBI 1 0x0
Software/Firmware Semaphore Bit.
This bit should be set only by the software device driver (read only to
firmware). The bit is not set if bit zero in the FWSM register is set.
The software device driver should set this bit and then read it to verify that
it was set. If it was set, it means that the software device driver can access
the SW_FW_SYNC register.
The software device driver should clear this bit after modifying the
SW_FW_SYNC register.
Note:
If software takes ownership of the SWSM.SWESMBI bit for a duration
longer than 10 ms, Firmware can take ownership of the bit.
Hardware clears this bit on a PCIe reset.
Reserved 30:2 0x0 Reserved.
Write 0x0, ignore on read.
Reserved 31 0b Reserved.
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8.7.2 Firmware Semaphore - FWSM (0x5B54; RO to Host, RW to FW)
Field1Bit(s) Initial
Value Description
EEP_FW_Semaphore 0 0b
Software/Firmware Semaphore.
Firmware should set this bit to 1b before accessing the SW_FW_SYNC
register. If software is using the SWSM register and does not lock
SW_FW_SYNC, firmware is able to set this bit to 1b. Firmware should set
this bit back to 0b after modifying the SW_FW_SYNC register.
Note: If software takes ownership of the SWSM.SWESMBI bit for a
duration longer than 10 ms, firmware can take ownership of the
bit.
FW_Mode 3:1 0x0
Firmware Mode.
Indicates the firmware mode as follows:
000b = No manageability. Default mode for all SKUs.
001b = The I210 mode. A proxy code was loaded.
010b = PT mode. I210 SKUs only.
011b = Reserved.
100b = Host interface only. In the I210, this bit determines that a valid
firmware code is running from the Flash but PT mode is disabled.
Reserved 5:4 00b Reserved.
Write 0x0, ignore on read.
EEP_Reload_Ind 6 0b
Flash Reloaded Indication.
Set to 1b after firmware reloads the Firmware related sections of the
Flash.
Cleared by firmware at Firmware reset only.
Reserved 14:7 0x0 Reserved
Write 0x0, ignore on read.
FW_Val_Bit 15 0b
Firmware Valid Bit.
Hardware clears this bit in reset de-assertion so software can know
firmware mode (bits 1-3) bits are invalid.
In the I210, firmware should set this bit to 1b when it is ready (end of boot
sequence).
Each time this bit is set to 1b, an ICR.MNG interrupt must be issued to
host.
Reset_Cnt 18:16 0b
Reset Counter.
Firmware increments the count on every firmware reset. After seven
firmware reset events, the counter remains at seven and does not wrap
around.
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Notes:
1. This register should be written only by the manageability firmware. The software device driver should only read this register.
2. Firmware ignores the Flash semaphore in operating system hung states.
3. Bits 15:0 are cleared on firmware reset.
Ext_Err_Ind 24:19 0x0
External Error Indication
Firmware writes here the reason that the firmware operation has stopped.
For example, Flash CRC error, etc.
Possible values:
0x00: No Error.
0x01: Flash CRC error in test configuration module.
Reserved.
0x03: Flash CRC error in common firmware parameters module.
0x04: Flash CRC error in pass through.
0x05: Shadow RAM dump fault.
0x06: Bad Flash contents.
0x07: Reserved.
0x08: Flash CRC error in sideband configuration module.
0x09: Flash CRC error in flexible TCO filter configuration module.
0x0A: Flash CRC Error in NC-SI microcode download module.
0x0B: Flash CRC Error in NC-SI configuration module.
0x0C: Flash CRC Error in traffic type parameters module.
0x0D: Flash CRC Error in inventory Flash structure module.
0x0E: Flash CRC Error in PHY configuration structure module.
0x0F to 0x15: Reserved.
0x16: TLB table exceeded.
0x17: DMA load failed.
0x18: Reserved.
0x19: Flash device not supported.
0x1A: Invalid Flash checksum.
0x1B: Unspecified error.
0x1C to 0x1F: Reserved.
0x20: Flash CRC Error in hardware auto-load.
0x21: No manageability (No Flash).
0x22: TCO isolate mode active.
0x23: Management memory parity error.
0x24: Firmware Flash access failure.
0x25: Other management error detected.
0x26 to 0x03F: Reserved
Note: Following an error detection and FWSM.Ext_Err_ind update, the
ICR.MGMT bit is set and an interrupt is sent to the host. However
when values of 0x00 or 0x21 are placed in the FWSM.Ext_Err_ind
field, the ICR.MGMT bit is not set and an interrupt is not
generated.
PCIe_Config_Err_Ind 25 0b
PCIe Configuration Error Indication.
Set to 1b by firmware when it fails to configure the PCIe interface.
Cleared by firmware after successfully configuring the PCIe interface.
PHY_SERDES0_Config_
Err_Ind 26 0b
PHY/SerDes Configuration Error Indication.
Set to 1b by firmware when it fails to configure LAN PHY/SerDes.
Cleared by firmware after successfully configuring LAN PHY/SerDes.
Reserved 30:27 0b Reserved.
Write 0b, ignore on read.
Factory MAC address
restored 31 0b This bit is set if internal firmware restored the factory MAC address at
power up or if the factory MAC address and the regular MAC address were
the same.
Field1Bit(s) Initial
Value Description
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8.7.3 Software–Firmware Synchronization - SW_FW_SYNC (0x5B5C;
RWM)
This register is intended to synchronize between software and firmware.
Note: If software takes ownership of bits in the SW_FW_SYNC register for a duration longer than 1
second, firmware can take ownership of the bit.
Reset conditions:
The software-controlled bits 15:0 are reset as any other CSR on global resets, D3hot exit and
Forced TCO. Software is expected to clear the bits on entry to D3 state.
The firmware controlled bits (bits 31:16) are reset on LAN_PWR_GOOD (power up) and firmware
reset.
Field Bit(s) Initial
Value Description
SW_FLASH_SM 0 0b When set to 1b, Flash access is owned by software.
SW_PHY_SM 1 0b When set to 1b, SerDes/PHY access is owned by software.
SW_I2C_SM 2 0b When set to 1b, I2C access register set (I2CCMD) is owned by software.
SW_MAC_CSR_SM 3 0b When set to 1b, software owns access to shared CSRs.
Reserved 6:4 0x0 Reserved.
Write 0x0, ignore on read.
SW_SVR_SM 7 0b When set to 1b, the SVR/LVR control registers are owned by the software device
driver.
SW_MB_SM 8 0b When Set to 1b, the SWMBWR mailbox write register, is owned by the software
device driver.
Reserved 9 0b Reserved.
Write 0b, ignore on read.
SW_MNG_SM 10 0b
When set to 1b, the management host interface is owned by the port driver.
This bit can be used by the port driver when updating teaming or proxying
information.
Reserved 15:11 0x0 Reserved.
Write 0x0, ignore on read.
FW_FLASH_SM 16 0b When set to 1b, Flash access is owned by firmware.
FW_PHY_SM 17 0b When set to 1b, PHY access is owned by firmware.
FW_I2C_SM 18 0b When set to 1b, I2C access register set (I2CCMD) is owned by firmware.
FW_MAC_CSR_SM 19 0b When set to 1b, firmware owns access to shared CSRs.
Reserved 22:20 0b Reserved.
Write 0x0, ignore on read.
FW_SVR_SM 23 0b When set to 1b, the SVR/LVR control registers are owned by firmware.
Reserved 31:24 0x0 Reserved
Write 0x0, ignore on read.
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8.8 Interrupt Register Descriptions
8.8.1 PCIe Interrupt Cause - PICAUSE (0x5B88; RW1/C)
8.8.2 PCIe Interrupt Enable - PIENA (0x5B8C; R/W)
8.8.3 Extended Interrupt Cause - EICR (0x1580; RC/W1C)
This register contains the frequent interrupt conditions for the I210. Each time an interrupt causing
event occurs, the corresponding interrupt bit is set in this register. An interrupt is generated each time
one of the bits in this register is set and the corresponding interrupt is enabled via the Interrupt Mask
Set/Read register. The interrupt might be delayed by the selected Interrupt Throttling register.
Note that the software device driver cannot determine from the RxTxQ bits what was the cause of the
interrupt. The possible causes for asserting these bits are: Receive descriptor write back, receive
descriptor minimum threshold hit, low latency interrupt for Rx, and transmit descriptor write back.
Writing a 1b to any bit in the register clears that bit. Writing a 0b to any bit has no effect on that bit.
Register bits are cleared on register read if GPIE.Multiple_MSIX = 0b.
Field Bit(s) Init. Description
CA 0 0b PCI Completion Abort Exception Issued.
UA 1 0b Reserved.
Write 0x0, ignore on read.
BE 2 0b Wrong byte-enable exception in the FUNC unit.
TO 3 0b PCI timeout exception in the FUNC unit.
BMEF 4 0b Asserted when Bus-Master-Enable (BME) of the PF is de-asserted.
ABR 5 0b
PCI Completer Abort Received.
PCI Completer Abort (CA) or Unsupported Request (UR) received (set after receiving CA or
UR).
Note: When this bit is set, all PCIe master activity is stopped. Software should issue a
software (CTRL.RST) reset to enable PCIe activity.
Reserved 31:6 0x0 Reserved.
Write 0x0, ignore on read.
Field Bit(s) Init. Description
CA 0 0b When set to 1b, the PCI completion abort interrupt is enabled.
UA 1 0b Reserved.
Write 0x0, ignore on read.
BE 2 0b When set to 1b, the wrong byte-enable interrupt is enabled.
TO 3 0b When set to 1b, the PCI timeout interrupt is enabled.
BMEF 4 0b When set to 1b, the BME interrupt is enabled.
ABR 5 0b When set to 1b, the PCI completion abort received interrupt is enabled.
Reserved 31:6 0x0 Reserved.
Write 0x0, ignore on read.
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Auto clear can be enabled for any or all of the bits in this register.
Note: Bits are not reset by device reset (CTRL.DEV_RST).
8.8.4 Extended Interrupt Cause Set - EICS (0x1520; WO)
Software uses this register to set an interrupt condition. Any bit written with a 1b sets the
corresponding bit in the Extended Interrupt Cause Read register. An interrupt is then generated if one
of the bits in this register is set and the corresponding interrupt is enabled via the Extended Interrupt
Mask Set/Read register. Bits written with 0b are unchanged.
Note: In order to set bit 31 of the EICR (Other Causes), the ICS and IMS registers should be used in
order to enable one of the legacy causes.
Table 8-11. EICR Register - Non-MSI-X Mode (GPIE.Multiple_MSIX = 0b)
Field Bit(s) Initial Value Description
RxTxQ 3:0 0x0
Receive/Transmit Queue Interrupts.
One bit per queue or a bundle of queues, activated on receive/transmit queue events
for the corresponding bit, such as:
Receive descriptor write back
Receive descriptor minimum threshold hit
Transmit descriptor write back.
The mapping of the actual queue to the appropriate RxTxQ bit is according to the IVAR
registers.
Reserved 29:4 0x0 Reserved.
Write 0x0, ignore on read.
TCP Timer 30 0b TCP Timer Expired.
Activated when the TCP timer reaches its terminal count.
Other Cause 31 0b Interrupt Cause Active.
Activated when any bit in the ICR register is set.
Table 8-12. EICR Register - MSI-X Mode (GPIE.Multiple_MSIX = 1b)
Field Bit(s) Initial Value Description
MSIX 4:0 0x0 Indicates an interrupt cause mapped to MSI-X vectors 4:0.
Note: Bits are not reset by device reset (CTRL.DEV_RST).
Reserved 31:5 0x0 Reserved.
Write 0x0, ignore on read.
Table 8-13. EICS Register - Non MSI-X mode (GPIE.Multiple_MSIX = 0b)
Field Bit(s) Initial Value Description
RxTxQ 3:0 0x0 Sets to corresponding EICR RxTXQ interrupt condition.
Reserved 29:4 0x0 Reserved.
Write 0x0, ignore on read.
TCP Timer 30 0b Sets the corresponding EICR TCP timer interrupt condition.
Reserved 31 0b Reserved.
Write 0b, ignore on read.
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8.8.5 Extended Interrupt Mask Set/Read - EIMS (0x1524; RWM)
Reading this register returns which bits that have an interrupt mask set. An interrupt in EICR is enabled
if its corresponding mask bit is set to 1b and disabled if its corresponding mask bit is set to 0b. A PCI
interrupt is generated each time one of the bits in this register is set and the corresponding interrupt
condition occurs (subject to throttling). The occurrence of an interrupt condition is reflected by having a
bit set in the Extended Interrupt Cause Read register.
An interrupt might be enabled by writing a 1b to the corresponding mask bit location (as defined in the
EICR register) in this register. Any bits written with a 0b are unchanged. As a result, if software needs
to disable an interrupt condition that had been previously enabled, it must write to the Extended
Interrupt Mask Clear register rather than writing a 0b to a bit in this register.
Note: Bits are not reset by device reset (CTRL.DEV_RST).
8.8.6 Extended Interrupt Mask Clear - EIMC (0x1528; WO)
This register provides software a way to disable certain or all interrupts. Software disables a given
interrupt by writing a 1b to the corresponding bit in this register.
On interrupt handling, the software device driver should set all the bits in this register related to the
current interrupt request even though the interrupt was triggered by part of the causes that were
allocated to this vector.
Interrupts are presented to the bus interface only when the mask bit is set to 1b and the cause bit is set
to 1b. The status of the mask bit is reflected in the Extended Interrupt Mask Set/Read register and the
status of the cause bit is reflected in the Interrupt Cause Read register.
Table 8-14. EICS Register - MSI-X Mode (GPIE.Multiple_MSIX = 1b)
Field Bit(s) Initial Value Description
MSI-X 4:0 0x0 Sets the corresponding EICR bit of MSI-X vectors 4:0
Reserved 31:5 0x0 Reserved.
Write 0x0, ignore on read.
Table 8-15. EIMS Register - Non-MSI-X Mode (GPIE.Multiple_MSIX = 0b)
Field Bit(s) Initial Value Description
RxTxQ 3:0 0x0 Set the Mask bit for the corresponding EICR RxTXQ interrupt.
Reserved 29:4 0x0 Reserved.
Write 0x0, ignore on read.
TCP Timer 30 0b Set the Mask bit for the corresponding EICR TCP timer interrupt condition.
Other Cause 31 1b Set the Mask bit for the corresponding EICR other cause interrupt condition.
Table 8-16. EIMS Register - MSI-X Mode (GPIE.Multiple_MSIX = 1b)
Field Bit(s) Initial Value Description
MSI-X 4:0 0x0 Set the Mask bit for the corresponding EICR bit of the MSI-X vectors 4:0.
Note: Bits are not reset by device reset (CTRL.DEV_RST).
Reserved 31:5 0x0 Reserved
Write 0x0, ignore on read.
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Software blocks interrupts by clearing the corresponding mask bit. This is accomplished by writing a 1b
to the corresponding bit location (as defined in the EICR register) of that interrupt in this register. Bits
written with 0b are unchanged (their mask status does not change).
8.8.7 Extended Interrupt Auto Clear - EIAC (0x152C; R/W)
This register is mapped like the EICS, EIMS, and EIMC registers, with each bit mapped to the
corresponding MSI-X vector.
This register is relevant to MSI-X mode only, where read-to-clear can not be used, as it might erase
causes tied to other vectors. If any bits are set in EIAC, the EICR register should not be read. Bits
without auto clear set, need to be cleared with write-to-clear.
Note: EICR bits that have auto clear set are cleared by the internal emission of the corresponding
MSI-X message even if this vector is disabled by the operating system.
The MSI-X message can be delayed by EITR moderation from the time the EICR bit is
activated.
Table 8-19. EIAC Register
8.8.8 Extended Interrupt Auto Mask Enable - EIAM (0x1530; R/W)
Each bit in this register enables clearing of the corresponding bit in EIMS register following read- or
write-to-clear to EICR or setting of the corresponding bit in EIMS following a write-to-set to EICS.
Table 8-17. EIMC Register - Non-MSI-X Mode (GPIE.Multiple_MSIX = 0b)
Field Bit(s) Initial Value Description
RxTxQ 3:0 0x0 Clear the Mask bit for the corresponding EICR RxTXQ interrupt.
Reserved 29:4 0x0 Reserved.
Write 0x0, ignore on read.
TCP Timer 30 0b Clear the Mask bit for the corresponding EICR TCP timer interrupt.
Other Cause 31 1b Clear the Mask bit for the corresponding EICR other cause interrupt.
Table 8-18. EIMC Register - MSI-X Mode (GPIE.Multiple_MSIX = 1b)
Field Bit(s) Initial Value Description
MSI-X 4:0 0x0 Clear the Mask bit for the corresponding EICR bit of MSI-X vectors 4:0.
Reserved 31:5 0x0 Reserved.
Write 0x0, ignore on read.
Field Bit(s) Initial Value Description
MSI-X 4:0 0x0
Auto clear bit for the corresponding EICR bit of the MSI-X vectors 4:0.
Notes:
Bits are not reset by device reset (CTRL.DEV_RST).
When GPIE.Multiple_MSIX = 0b (Non-MSI-X Mode) bits 8 and 9 are read only and
should be ignored.
Reserved 31:5 0x0 Reserved.
Write 0x0, ignore on read.
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In MSI-X mode, this register controls which of the bits in the EIMS register to clear upon interrupt
generation if enabled via the GPIE.EIAME bit.
Note: When operating in MSI mode and setting any bit in the EIAM register causes the clearing of all
bits in the EIMS register and the masking of all interrupts after generating a MSI interrupt.
Note: Bits are not reset by device reset (CTRL.DEV_RST).
8.8.9 Interrupt Cause Read Register - ICR (0x1500; RC/W1C)
This register contains the interrupt conditions for the I210 that are not present directly in the EICR.
Each time an ICR interrupt causing event occurs, the corresponding interrupt bit is set in this register.
The EICR.Other bit reflects the setting of interrupt causes from ICR as masked by the Interrupt Mask
Set/Read register. Each time all un-masked causes in ICR are cleared, the EICR.Other bit is also
cleared.
ICR bits are cleared on register read. Clear-on-read can be enabled/disabled through a general
configuration register bit. Refer to Section 7.3.3 for additional information.
Auto clear is not available for the bits in this register.
In order to prevent unwanted Link Status Change (LSC) interrupts during initialization, software should
disable this interrupt until the end of initialization.
Table 8-20. EIAM Register - Non-MSI-X Mode (GPIE.Multiple_MSIX = 0b)
Field Bit(s) Initial Value Description
RxTxQ 3:0 0x0 Auto Mask bit for the corresponding EICR RxTxQ interrupt.
Reserved 29:4 0x0 Reserved.
Write 0x0, ignore on read.
TCP Timer 30 0b Auto Mask bit for the corresponding EICR TCP timer interrupt condition.
Other Cause 31 0b Auto Mask bit for the corresponding EICR other cause interrupt condition.
Table 8-21. EIAM Register - MSI-X Mode (GPIE.Multiple_MSIX = 1b)
Field Bit(s) Initial Value Description
MSIX 4:0 0x0 Auto Mask bit for the corresponding EICR bit of MSI-X vectors 4:0.
Note: Bits are not reset by device reset (CTRL.DEV_RST).
Reserved 31:5 0x0 Reserved.
Write 0x0, ignore on read.
Field Bit(s) Initial Value Description
TXDW 0 0b Transmit Descriptor Written Back.
Set when the I210 writes back a Tx descriptor to memory.
Reserved 1 0b Reserved.
Write 0x0, ignore on read.
LSC 2 0b
Link Status Change.
This bit is set each time the link status changes (either from up to down, or from
down to up). This bit is affected by the LINK indication from the PHY (internal
PHY mode).
Reserved 3 0b Reserved.
Write 0x0, ignore on read.
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RXDMT0 4 0b
Receive Descriptor Minimum Threshold Reached.
Indicates that the minimum number of receive descriptors are available and
software should load more receive descriptors.
Reserved 5 0b Reserved.
Write 0x0, ignore on read.
Rx Miss 6 0b
Missed packet interrupt is activated for each received packet that overflows the
Rx packet buffer (overrun). Note that the packet is dropped and also increments
the associated MPC counter.
Note: Could be caused by no available receive buffers or because PCIe receive
bandwidth is inadequate.
RXDW 7 0b Receiver Descriptor Write Back.
Set when the I210 writes back an Rx descriptor to memory.
Reserved 9:8 0b Reserved.
Write 0x0, ignore on read.
GPHY 10 0b Internal 1000/100/10BASE-T PHY interrupt.
Refer to Section 8.27 for further information.
GPI_SDP0 11 0b
General Purpose Interrupt on SDP0.
If GPI interrupt detection is enabled on this pin (via CTRL.SDP0_GPIEN), this
interrupt cause is set when the SDP0 is sampled high.
GPI_SDP1 12 0b
General Purpose Interrupt on SDP1.
If GPI interrupt detection is enabled on this pin (via CTRL.SDP1_GPIEN), this
interrupt cause is set when the SDP1 is sampled high.
GPI_SDP2 13 0b
General Purpose Interrupt on SDP2.
If GPI interrupt detection is enabled on this pin (via CTRL_EXT.SDP2_GPIEN),
this interrupt cause is set when the SDP2 is sampled high.
GPI_SDP3 14 0b
General Purpose Interrupt on SDP3.
If GPI interrupt detection is enabled on this pin (via CTRL_EXT.SDP3_GPIEN),
this interrupt cause is set when the SDP3 is sampled high.
Reserved 15 0b Reserved.
Reserved 17:16 00b Reserved.
Write 0x0, ignore on read.
MNG 18 0b
Manageability Event Detected.
Indicates that a manageability event happened. When bit is set due to detection
of error by management, FWSM.Ext_Err_Ind field is updated with the error
cause.
Time_Sync 19 0b
Time_Sync Interrupt.
This interrupt cause is set if the interrupt is generated by the Time Sync
interrupt (See TSICR and TSIM registers).
Reserved 21:20 0b Reserved.
Write 0x0, ignore on read.
FER 22 0b Fatal Error.
This bit is set when a fatal error is detected in one of the memories.
Reserved 23 0b Reserved.
Write 0x0, ignore on read.
PCI Exception 24 0b
The PCI timeout exception is activated by one of the following events when the
specific PCI event is reported in the PICAUSE register and the appropriate bit in
the PIENA register is set:
1. I/O completion abort.
2. Unsupported I/O request (wrong address).
3. Byte-enable error - Access to the client that does not support partial BE
access (All but Flash, MSIX and the PCIe target).
4. Timeout occurred in the FUNC block.
5. BME of the PF is cleared.
Field Bit(s) Initial Value Description
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8.8.10 Interrupt Cause Set Register - ICS (0x1504; WO)
Software uses this register to set an interrupt condition. Any bit written with a 1b sets the
corresponding interrupt. This results in the corresponding bit being set in the Interrupt Cause Read
Register (refer to Section 8.8.9). A PCIe interrupt is generated if one of the bits in this register is set
and the corresponding interrupt is enabled through the Interrupt Mask Set/Read Register (refer to
Section 8.8.11). Bits written with 0b are unchanged. Refer to Section 7.3.3 for additional information.
SCE 25 0b
DMA Coalescing Clock Control Event.
This bit is set when the multicast or broadcast DMA coalescing clock control
mechanism is activated or de-activated.
Software WD 26 0b Software Watchdog.
This bit is set after a software watchdog timer times out.
Reserved 27 0b Reserved.
Write 0x0, ignore on read.
Reserved 28 0b Reserved.
TCP Timer 29 0b TCP Timer Interrupt.
Activated when the TCP timer reaches its terminal count.
DRSTA 30 0b
Device Reset Asserted.
Indicates CTRL.DEV_RST was asserted. When a device reset occurs, the port
should re-initialize registers and descriptor rings.
Note: This bit is not reset by device reset (CTRL.DEV_RST).
INTA 31 0b
Interrupt Asserted.
Indicates that the INT line is asserted. Can be used by the software device driver
in a shared interrupt scenario to decide if the received interrupt was emitted by
the I210. This bit is not valid in MSI/MSI-X environments.
Field Bit(s) Initial Value Description
TXDW 0 0b Sets the Transmit Descriptor Written Back Interrupt.
Reserved 1 0b Reserved.
Write 0b, ignore on read.
LSC 2 0b Sets the Link Status Change Interrupt.
Reserved 3 0b Reserved.
Write 0x0, ignore on read.
RXDMT0 4 0b Sets the Receive Descriptor Minimum Threshold Hit Interrupt.
Reserved 5 0b Reserved.
Write 0x0, ignore on read.
Rx Miss 6 0b Sets the Rx Miss Interrupt.
RXDW 7 0b Sets the Receiver Descriptor Write Back Interrupt.
Reserved 9:8 0b Reserved.
Write 0b, ignore on read.
GPHY 10 0b Sets the internal 1000/100/10BASE-T PHY interrupt.
GPI_SDP0 11 0b Sets the General Purpose interrupt, related to SDP0 pin.
GPI_SDP1 12 0b Sets the General Purpose interrupt, related to SDP1 pin.
GPI_SDP2 13 0b Sets the General Purpose interrupt, related to SDP2 pin.
GPI_SDP3 14 0b Sets the General Purpose interrupt, related to SDP3 pin.
Reserved 17:15 0x0 Reserved.
Write 0x0, ignore on read.
MNG 18 0b Sets the Management Event Interrupt.
Time_Sync 19 0b Sets the Time_Sync interrupt.
Field Bit(s) Initial Value Description
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8.8.11 Interrupt Mask Set/Read Register - IMS (0x1508; R/W)
Reading this register returns bits that have an interrupt mask set. An interrupt is enabled if its
corresponding mask bit is set to 1b and disabled if its corresponding mask bit is set to 0b. A PCIe
interrupt is generated each time one of the bits in this register is set and the corresponding interrupt
condition occurs. The occurrence of an interrupt condition is reflected by having a bit set in the
Interrupt Cause Read register (refer to Section 8.8.9).
A particular interrupt can be enabled by writing a 1b to the corresponding mask bit in this register. Any
bits written with a 0b are unchanged. As a result, if software desires to disable a particular interrupt
condition that had been previously enabled, it must write to the Interrupt Mask Clear Register (refer to
Section 8.8.12) rather than writing a 0b to a bit in this register. Refer to Section 7.3.3 for additional
information.
Reserved 21:20 0x0 Reserved.
Write 0x0, ignore on read.
FER 22 0b Sets the Fatal Error interrupt.
Reserved 23 0b Reserved.
Write 0b, ignore on read.
PCI Exception 24 0b Sets the PCI Exception interrupt.
SCE 25 0b Sets the DMA Coalescing Clock Control Event interrupt.
Software WD 26 0b Sets the Software Watchdog interrupt.
Reserved 27 0b Reserved.
Write 0b, ignore on read.
Reserved 28 0b Reserved.
TCP Timer 29 0b Sets the TCP timer interrupt.
DRSTA 30 0b
Sets the Device Reset Asserted Interrupt.
Note that when setting this bit a DRSTA interrupt is generated on this port
only.
Reserved 31 0b Reserved.
Write 0b, ignore on read.
Field Bit(s) Initial Value Description
TXDW 0 0b Sets/reads the mask for Transmit Descriptor Written Back interrupt.
Reserved 1 0b Reserved.
Write 0b, ignore on read.
LSC 2 0b Sets/Reads the mask for Link Status Change interrupt.
Reserved 3 0b Reserved.
Write 0b, ignore on read.
RXDMT0 4 0b Sets/reads the mask for Receive Descriptor Minimum Threshold Hit interrupt.
Reserved 5 0b Reserved.
Write 0b, ignore on read.
Rx Miss 6 0b Sets/reads the mask for the Rx Miss interrupt.
RXDW 7 0b Sets/reads the mask for Receiver Descriptor Write Back interrupt.
Reserved 9:8 0b Reserved.
Write 0b, ignore on read.
GPHY 10 0b Sets/Reads the mask for Internal 1000/100/10BASE-T PHY interrupt.
GPI_SDP0 11 0b Sets/Reads the mask for General Purpose Interrupt, related to SDP0 pin.
Field Bit(s) Initial Value Description
Programming Interface — Ethernet Controller I210
423
8.8.12 Interrupt Mask Clear Register - IMC (0x150C; WO)
Software uses this register to disable an interrupt. Interrupts are presented to the bus interface only
when the mask bit is set to 1b and the cause bit set to 1b. The status of the mask bit is reflected in the
Interrupt Mask Set/Read register (refer to Section 8.8.11), and the status of the cause bit is reflected in
the Interrupt Cause Read register (refer to Section 8.8.9). Reading this register returns the value of the
IMS register.
Software blocks interrupts by clearing the corresponding mask bit. This is accomplished by writing a 1b
to the corresponding bit in this register. Bits written with 0b are unchanged (their mask status does not
change).
Software device driver should set all the bits in this register related to the current interrupt request
when handling interrupts, even though the interrupt was triggered by part of the causes that were
allocated to this vector. Refer to Section 7.3.3 for additional information.
GPI_SDP1 12 0b Sets/Reads the mask for General Purpose Interrupt, related to SDP1 pin.
GPI_SDP2 13 0b Sets/Reads the mask for General Purpose Interrupt, related to SDP2 pin.
GPI_SDP3 14 0b Sets/Reads the mask for General Purpose Interrupt, related to SDP3 pin.
Reserved 17:15 0x0 Reserved.
Write 0x0, ignore on read.
MNG 18 0b Sets/reads the mask for Management Event interrupt.
Time_Sync 19 0b Sets/reads the mask for Time_Sync interrupt.
Reserved 20 0b Reserved.
Write 0b, ignore on read.
Reserved 21 0b Reserved.
Write 0b, ignore on read.
FER 22 0b Sets/reads the mask for the Fatal Error interrupt.
Reserved 23 0b Reserved.
Write 0b, ignore on read.
PCI Exception 24 0b Sets/reads the mask for the PCI Exception interrupt.
SCE 25 0b Sets/reads the mask for the DMA Coalescing Clock Control Event interrupt.
Software WD 26 0b Sets/reads the mask for the Software Watchdog interrupt.
Reserved 28 0b Reserved.
Write 0b, ignore on read.
TCP Timer 29 0b Sets/reads the mask for TCP timer interrupt.
DRSTA 30 0b Sets/reads the mask for Device Reset Asserted interrupt.
Note: Bit is not reset by device reset (CTRL.DEV_RST).
Reserved 31 0b Reserved.
Write 0b, ignore on read.
Field Bit(s) Initial Value Description
TXDW 0 0b Clears the mask for Transmit Descriptor Written Back interrupt.
Reserved 1 0b Reserved.
Write 0b, ignore on read.
LSC 2 0b Clears the mask for Link Status Change interrupt.
Reserved 3 0b Reserved.
Write 0b, ignore on read.
Field Bit(s) Initial Value Description
Ethernet Controller I210 — Programming Interface
424
8.8.13 Interrupt Acknowledge Auto Mask Register - IAM (0x1510; R/W)
RXDMT0 4 0b Clears the mask for Receive Descriptor Minimum Threshold Hit interrupt.
Reserved 5 0b Reserved.
Write 0b, ignore on read.
Rx Miss 6 0b Clears the mask for the Rx Miss interrupt.
RXDW 7 0b Clears the mask for the Receiver Descriptor Write Back interrupt.
Reserved 9:8 0b Reserved.
Write 0b, ignore on read.
GPHY 10 0b Clears the mask for the Internal 1000/100/10BASE-T PHY interrupt.
GPI_SDP0 11 0b Clears the mask for the General Purpose interrupt, related to SDP0 pin.
GPI_SDP1 12 0b Clears the mask for the General Purpose interrupt, related to SDP1 pin.
GPI_SDP2 13 0b Clears the mask for the General Purpose interrupt, related to SDP2 pin.
GPI_SDP3 14 0b Clears the mask for the General Purpose interrupt, related to SDP3 pin.
Reserved 17:15 0x0 Reserved.
Write 0x0, ignore on read.
MNG 18 0b Clears the mask for the Management Event interrupt.
Time_Sync 19 0b Clears the mask for the Time_Sync interrupt.
Reserved 20 0b Reserved.
Write 0b, ignore on read.
Reserved 21 0b Reserved.
Write 0b, ignore on read.
FER 22 0b Clears the mask for the Fatal Error interrupt.
Reserved 23 0b Reserved.
Write 0b, ignore on read.
PCI Exception 24 0b Clears the mask for the PCI Exception interrupt.
SCE 25 0b Clears the mask for the DMA Coalescing Clock Control Event interrupt.
Software WD 26 0b Clears the mask for Software Watchdog Interrupt.
Reserved 28:27 0b Reserved.
Write 0b, ignore on read.
TCP timer 29 0b Clears the mask for TCP timer interrupt.
DRSTA 30 0b Clears the mask for Device Reset Asserted interrupt.
Reserved 31 0b Reserved.
Write 0b, ignore on read.
Field Bit(s) Initial Value Description
IAM_VALUE 30:0 0x0
An ICR read or write has the side effect of writing the contents of this
register to the IMC register. If GPIE.NSICR = 0b, then the copy of this
register to the IMC register occurs only if at least one bit is set in the IMS
register and there is a true interrupt as reflected in the ICR.INTA bit.
Refer to Section 7.3.3 for additional information.
Note: Note: Bit 30 of this register is not reset by device reset
(CTRL.DEV_RST).
Reserved 31 0b Reserved.
Write 0b, ignore on read.
Field Bit(s) Initial Value Description
Programming Interface — Ethernet Controller I210
425
8.8.14 Interrupt Throttle - EITR (0x1680 + 4*n [n = 0...4]; R/W)
Each EITR is responsible for an interrupt cause (RxTxQ, TCP timer and Other Cause). The allocation of
EITR-to-interrupt cause is through the IVAR registers.
Software uses this register to pace (or even out) the delivery of interrupts to the host processor. This
register provides a guaranteed inter-interrupt delay between interrupts asserted by the I210,
regardless of network traffic conditions. To independently validate configuration settings, software can
use the following algorithm to convert the inter-interrupt interval value to the common interrupts/sec.
performance metric:
interrupts/sec = (1 * 10-6sec x interval)-1
A counter counts in units of 1*10-6 sec. After counting interval number of units, an interrupt is sent to
the software. The previous equation gives the number of interrupts per second. The equation that
follows is the time in seconds between consecutive interrupts.
For example, if the interval is programmed to 125 (decimal), the I210 guarantees the processor does
not receive an interrupt for 125 s from the last interrupt. The maximum observable interrupt rate from
the I210 should never exceed 8000 interrupts/sec.
Inversely, inter-interrupt interval value can be calculated as:
inter-interrupt interval = (1 * 10-6sec x interrupt/sec)-1
The optimum performance setting for this register is very system and configuration specific. An initial
suggested range is 2 to 175 (0x02 to 0xAF).
Note: Setting EITR to a non-zero value can cause an interrupt cause Rx/Tx statistics miscount.
Note: The EITR register and interrupt mechanism is not reset by device reset (CTRL.DEV_RST).
Occurrence of device reset interrupt causes immediate generation of all pending interrupts.
Field Bit(s) Initial Value Description
Reserved 1:0 0x0 Reserved.
Write 0x0, ignore on read.
Interval 14:2 0x0
Minimum Inter-interrupt Interval.
The interval is specified in 1 s increments.
A null value is not a valid setting.
LLI_EN 15 0b LLI moderation enable.
LL Counter
(RWM) 20:16 0x0 Reflects the current credits for that EITR for LL interrupts. If the CNT_INGR is not set,
this counter can be directly written by software at any time to alter the throttles
performance
Moderation
Counter
(RWM) 30:21 0x0
Down counter, exposes only the 10 most significant bits of the real 12-bit counter.
Loaded with interval value each time the associated interrupt is signaled. Counts
down to zero and stops. The associated interrupt is signaled each time this counter is
zero and an associated (via the Interrupt Select register) EICR bit is set.
If the CNT_INGR is not set, this counter can be directly written by software at any
time to alter the throttles performance.
CNT_INGR
(WO) 31 0b
When set, hardware does not override the counters fields (ITR counter and LLI credit
counter), so they keep their previous value.
Relevant for the current write only and is always read as zero.
Ethernet Controller I210 — Programming Interface
426
8.8.15 Interrupt Vector Allocation Registers - IVAR (0x1700 + 4*n
[n=0...1]; RW)
These registers have two modes of operation:
1. In MSI-X mode, these registers define the allocation of the different interrupt causes as defined in
Table 7-50 to one of the MSI-X vectors. Each INT_Alloc[i] (i=0...7) field is a byte indexing an entry
in the MSI-X Table Structure and MSI-X PBA Structure.
2. In non MSI-X mode, these registers define the allocation of the Rx and Tx queues interrupt causes
to one of the RxTxQ bits in the EICR register. Each INT_Alloc[i] (i=...7) field is a byte indexing the
appropriate RxTxQ bit as defined in Table 7-49.
Note: If invalid values are written to the INT_Alloc fields the result is unexpected.
8.8.16 Interrupt Vector Allocation Registers - MISC IVAR_MISC
(0x1740; RW)
This register is used only in MSI-X mode. This register defines the allocation of the Other Cause and
TCP Timer interrupts to one of the MSI-X vectors.
Field Bit(s) Initial Value Description
INT_Alloc[4*n] 2:0 0x0 Defines the MSI-X vector assigned to Rx0 or Rx2 for IVAR[0] or IVAR[1],
respectively. Valid values are 0 to 4 for MSI-X mode and 0 to 3 in non-MSI-X mode.
Reserved 6:3 0x0 Reserved.
Write 0x0, ignore on read.
INT_Alloc[4*n] 7 0b Valid bit for INT_Alloc[4*n].
INT_Alloc[4*n+1] 10:8 0x0 Defines the MSI-X vector assigned to Tx0 or Tx2 for IVAR[0] or IVAR[1],
respectively. Valid values are 0 to 4 for MSI-X mode and 0 to 3 in non-MSI-X mode.
Reserved 14:11 0x0 Reserved.
Write 0x0, ignore on read.
INT_Alloc[4*n+1] 15 0b Valid bit for INT_Alloc[4*n+1].
INT_Alloc[4*n+2] 18:16 0x0 Defines the MSI-X vector assigned to Rx1 or Rx3 for IVAR[0] or IVAR[1],
respectively. Valid values are 0 to 4 for MSI-X mode and 0 to 3 in non-MSI-X mode.
Reserved 22:19 0x0 Reserved.
Write 0x0, ignore on read.
INT_Alloc[4*n+2] 23 0b Valid bit for INT_Alloc[4*n+2].
INT_Alloc[4*n+3] 26:24 0x0 Defines the MSI-X vector assigned to Tx1 or Tx3 for IVAR[0] or IVAR[1],
respectively. Valid values are 0 to 4 for MSI-X mode and 0 to 3 in non-MSI-X mode.
Reserved 30:27 0x0 Reserved.
Write 0x0, ignore on read.
INT_Alloc[4*n+3] 31 0b Valid bit for INT_Alloc[4*n+3].
Field Bit(s) Initial Value Description
INT_Alloc[8] 2:0 0x0 Defines the MSI-X vector assigned to the TCP timer interrupt
cause. Valid values are 0 to 4.
Reserved 6:3 0x0 Reserved.
Write 0x0, ignore on read.
INT_Alloc[8] 7 0b Valid bit for INT_Alloc[8].
Programming Interface — Ethernet Controller I210
427
8.8.17 General Purpose Interrupt Enable - GPIE (0x1514; RW)
8.9 MSI-X Table Register Descriptions
These registers are used to configure the MSI-X mechanism. The Message Address and Message Upper
Address registers set the address for each of the vectors. The message register sets the data sent to
the relevant address. The vector control registers are used to enable specific vectors.
INT_Alloc[9] 10:8 0x0 Defines the MSI-X vector assigned to the Other Cause interrupt.
Valid values are 0 to 4.
Reserved 14:11 0x0 Reserved.
Write 0x0, ignore on read.
INT_Alloc[9] 15 0b Valid bit for INT_Alloc[9].
Reserved 31:16 0x0 Reserved.
Write 0x0, ignore on read.
Field Bit(s) Initial Value Description
NSICR 0 0b
Non Selective Interrupt Clear on Read.
When set, every read of ICR clears it. When this bit is cleared, an ICR read
causes it to be cleared only if an actual interrupt was asserted or IMS =
0x0.
Refer to Section 7.3.3 for additional information.
Reserved 3:1 0x0 Reserved.
Write 0x0, ignore on read.
Multiple MSIX 4 0b
0b = In MSI or MSI-X mode, with a single vector, IVAR maps Rx/Tx causes
to 4 EICR bits but MSIX[0] is asserted for all.
1b = MSIX mode, IVAR maps Rx/Tx causes, TCP Timer and Other Cause
interrupts to 5 MSI-x vectors reflected in 5 EICR bits.
Note: When set, the EICR register is not cleared on read.
Reserved 6:5 0x0 Reserved.
Write 0x0, ignore on read.
LL Interval 11:7 0x0
Low Latency Credits Increment Rate.
The interval is specified in 4 s increments.
Note: When LLI moderation is enabled (LLI_EN bit set), this filed shall
be set with a value different than 0x0.
Reserved 29:12 0x0 Reserved.
Write 0x0, ignore on read.
EIAME 30 0b
Extended Interrupt Auto Mask Enable.
When set (usually in MSI-X mode) and after sending a MSI-X message, if
bits in the EIAM register associated with this message are set, then the
corresponding bits in the EIMS register are cleared. Otherwise, EIAM is
used only after reading or writing the EICR/EICS registers.
Note: When this bit is set in MSI mode, setting of any bit in the EIAM
register causes the clearing of all bits in the EIMS register and
masking of all interrupts after generating a MSI interrupt.
PBA_support 31 0b
PBA Support.
When set, setting one of the extended interrupts masks via EIMS causes
the PBA bit of the associated MSI-X vector to be cleared. Otherwise, the
I210 behaves in a way that supports legacy INT-x interrupts.
Note: Should be cleared when working in INT-x or MSI mode and set in
MSI-X mode.
Field Bit(s) Initial Value Description
Ethernet Controller I210 — Programming Interface
428
The pending bit array register indicates which vectors have pending interrupts. The structure is listed in
Table 8-22.
Note: N = 5.
Note: N = 5. As a result, only Qword0 is implemented.
8.9.1 MSI-X Table Entry Lower Address - MSIXTADD (BAR3: 0x0000 +
0x10*n [n=0...4]; R/W)
8.9.2 MSI-X Table Entry Upper Address - MSIXTUADD (BAR3: 0x0004 +
0x10*n [n=0...4]; R/W)
Table 8-22. MSI-X Table Structure
DWORD3
MSIXTVCTRL
DWORD2
MSIXTMSG
DWORD1
MSIXTUADD
DWORD0
MSIXTADD
Entry
Number BAR 3 - Offset
Vector Control Msg Data Msg Upper Addr Msg Addr Entry 0 Base (0x0000)
Vector Control Msg Data Msg Upper Addr Msg Addr Entry 1 Base + 1*16
Vector Control Msg Data Msg Upper Addr Msg Addr Entry 2 Base + 2*16
... ... ... ... ... ...
Vector Control Msg Data Msg Upper Addr Msg Addr Entry (N-1) Base + (N-1) *16
Table 8-23. MSI-X PBA Structure
MSIXPBA[63:0] Qword
Number BAR 3 - Offset
Pending Bits 0 through 63 QWORD0 Base (0x2000)
Pending Bits 64 through 127 QWORD1 Base+1*8
... ... ...
Pending Bits ((N-1) div 64)*64 through N-1 QWORD((N-1) div 64) BASE + ((N-1) div 64)*8
Field Bit(s) Initial Value Description
Message
Address LSB
(RO) 1:0 0x0 For proper Dword alignment, software must always write 0b’s to these
two bits. Otherwise, the result is undefined.
Message
Address 31:2 0x0
System-Specific Message Lower Address.
For MSI-X messages, the contents of this field from an MSI-X table entry
specifies the lower portion of the Dword-aligned address for the memory
write transaction.
Field Bit(s) Initial Value Description
Message
Address 31:0 0x0 System-Specific Message Upper Address.
Programming Interface — Ethernet Controller I210
429
8.9.3 MSI-X Table Entry Message - MSIXTMSG (BAR3: 0x0008 +
0x10*n [n=0...4]; R/W)
8.9.4 MSI-X Table Entry Vector Control - MSIXTVCTRL (BAR3: 0x000C
+ 0x10*n [n=0...4]; R/W)
8.9.5 MSIXPBA Bit Description – MSIXPBA (BAR3: 0x2000; RO)
8.9.6 MSI-X PBA Clear – PBACL (0x5B68; R/W1C)
Field Bit(s) Initial Value Description
Message
Data 31:0 0x0
System-Specific Message Data.
For MSI-X messages, the contents of this field from an MSI-X table entry
specifies the data written during the memory write transaction.
In contrast to message data used for MSI messages, the low-order
message data bits in MSI-X messages are not modified by the function.
Field Bit(s) Initial Value Description
Mask 0 1b
When this bit is set, the function is prohibited from sending a message
using this MSI-X table entry. However, any other MSI-X table entries
programmed with the same vector are still capable of sending an equivalent
message unless they are also masked.
Reserved 31:1 0x0 Reserved.
Write 0x0, ignore on read.
Field Bit(s) Initial Value Description
Pending Bits 4:0 0x0
For each pending bit that is set, the function has a pending message for
the associated MSI-X table entry.
Pending bits that have no associated MSI-X table entry are reserved.
Reserved 31:5 0x0 Reserved.
Write 0x0, ignore on read.
Field Bit(s) Initial Value Description
PENBITCLR 4:0 0x0
MSI-X Pending bits Clear.
Writing a 1b to any bit clears the corresponding MSIXPBA bit; writing a 0b
has no effect.
Note: Bits are set for a single PCIe clock cycle and then cleared.
Reserved 31:5 0x0 Reserved.
Write 0x0, ignore on read.
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8.10 Receive Register Descriptions
8.10.1 Receive Control Register - RCTL (0x0100; R/W)
Field Bit(s) Initial Value Description
Reserved 0 0b Reserved.
Write 0b, ignore on read.
RXEN 1 0b
Receiver Enable.
The receiver is enabled when this bit is set to 1b. Writing this bit to 0b stops reception
after receipt of any in progress packet. All subsequent packets are then immediately
dropped until this bit is set to 1b.
SBP 2 0b
Store Bad Packets
0b = Do not store.
1b = Store bad packets.
This bit controls the MAC receive behavior. A packet is required to pass the address
(or normal) filtering before the SBP bit becomes effective. If SBP = 0b, then all
packets with layer 1 or 2 errors are rejected. The appropriate statistic would be
incremented. If SBP = 1b, then these packets are received (and transferred to host
memory). The receive descriptor error field (RDESC.ERRORS) should have the
corresponding bit(s) set to signal the software device driver that the packet is erred.
In some operating systems the software device driver passes this information to the
protocol stack. In either case, if a packet only has layer 3+ errors, such as IP or TCP
checksum errors, and passes other filters, the packet is always received (layer 3+
errors are not used as a packet filter).
Note: Symbol errors before the SFD are ignored. Any packet must have a valid SFD
(RX_DV with no RX_ER in 10/100/1000BASE-T mode) in order to be
recognized by the I210 (even bad packets). Also, erred packets are not
routed to the MNG even if this bit is set.
UPE 3 0b
Unicast Promiscuous Enabled.
0b = Disabled.
1b = Enabled.
MPE 4 0b
Multicast Promiscuous Enabled.
0b = Disabled.
1b = Enabled.
LPE 5 0b
Long Packet Reception Enable.
0b = Disabled.
1b = Enabled.
LPE controls whether long packet reception is permitted. If LPE is 0b,hardware
discards long packets over 1518, 1522 or 1526 bytes depending on the
CTRL_EXT.EXT_VLAN bit and the detection of a VLAN tag in the packet. If LPE is
1b,the maximum packet size that the I210 can receive is defined in the RLPML.RLPML
register.
LBM 7:6 00b
Loopback Mode.
Controls the loopback mode of the I210.
00b = Normal operation (or PHY loopback in 10/100/1000BASE-T mode).
01b = MAC loopback (test mode).
10b = Undefined.
11b = Loopback via internal SerDes (SerDes/SGMII/KX mode only).
When using the internal PHY, LBM should remain set to 00b and the PHY instead
configured for loopback through the MDIO interface.
Note: PHY devices require programming for loopback operation using MDIO
accesses.
Reserved 11:8 0x0 Reserved.
Write 0x0, ignore on read.
Programming Interface — Ethernet Controller I210
431
MO 13:12 00b
Multicast Offset.
Determines which bits of the incoming multicast address are used in looking up the bit
vector.
00b = bits [47:36] of received destination multicast address.
01b = bits [46:35] of received destination multicast address.
10b = bits [45:34] of received destination multicast address.
11b = bits [43:32] of received destination multicast address.
Reserved 14 0b Reserved.
Write 0b, ignore on read.
BAM 15 0b
Broadcast Accept Mode.
0b = Ignore broadcast (unless it matches through exact or imperfect filters).
1b = Accept broadcast packets.
BSIZE 17:16 00b
Receive Buffer Size.
BSIZE controls the size of the receive buffers and permits software to trade-off
descriptor performance versus required storage space. Buffers that are 2048 bytes
require only one descriptor per receive packet maximizing descriptor efficiency.
00b = 2048 Bytes.
01b = 1024 Bytes.
10b = 512 Bytes.
11b = 256 Bytes.
Notes:
1. BSIZE should not be modified when RXEN is set to 1b. Set RXEN =0b when
modifying the buffer size by changing this field.
2. BSIZE value only defines receive buffer size of queues with a
SRRCTL.BSIZEPACKET value of 0b.
VFE 18 0b
VLAN Filter Enable.
0b = Disabled (filter table does not decide packet acceptance).
1b = Enabled (filter table decides packet acceptance for 802.1Q packets).
Three bits [20:18] control the VLAN filter table. The first determines whether the
table participates in the packet acceptance criteria. The next two are used to decide
whether the CFI bit found in the 802.1Q packet should be used as part of the
acceptance criteria.
CFIEN 19 0b
Canonical Form Indicator Enable.
0b = Disabled (CFI bit found in received 802.1Q packet’s tag is not compared to
decide packet acceptance).
1b = Enabled (CFI bit found in received 802.1Q packet’s tag must match RCTL.CFI to
accept 802.1Q type packet.
CFI 20 0b
Canonical Form Indicator Bit Value
0b = 802.1Q packets with CFI equal to this field are accepted.
1b = 802.1Q packet is discarded.
PSP 21 0b Pad Small Receive Packets.
If this field is set, RCTL.SECRC should be set.
DPF 22 1b
Discard Pause Frames.
Controls whether pause frames are forwarded to the host.
0b = incoming pause frames are forwarded to the host.
1b = incoming pause frames are discarded.
PMCF 23 0b
Pass MAC Control Frames.
Filters out unrecognized pause and other control frames.
0b = Filter MAC Control frames.
1b = Pass/forward MAC control frames to the Host that are not XON/XOFF flow control
packets.
The PMCF bit controls the DMA function of the MAC control frames (other than flow
control). A MAC control frame in this context must be addressed to either the MAC
control frame multicast address or the station address, match the type field, and NOT
match the PAUSE opcode of 0x0001. If PMCF = 1b then frames meeting this criteria
are transferred to host memory.
Field Bit(s) Initial Value Description
Ethernet Controller I210 — Programming Interface
432
8.10.2 Split and Replication Receive Control - SRRCTL (0xC00C +
0x40*n [n=0...3]; R/W)
Reserved 25:24 0x0 Reserved.
Write 0x0, ignore on read.
SECRC 26 0b
Strip Ethernet CRC From Incoming Packet
Causes the CRC to be stripped from all packets.
0b = Does not strip CRC.
1b = Strips CRC.
This bit controls whether the hardware strips the Ethernet CRC from the received
packet. This stripping occurs prior to any checksum calculations. The stripped CRC is
not transferred to host memory and is not included in the length reported in the
descriptor.
Notes:
1. If the CTRL.VME bit is set the RCTL.SECRC bit should also be set as the CRC is
not valid anymore.
2. Even when this bit is set, CRC strip is not done on runt packets (smaller than 64
bytes).
Reserved 31:27 0x0 Reserved.
Write 0x0, ignore on read.
Field Bit(s) Initial Value Description
BSIZEPACKET 6:0 0x0
Receive Buffer Size for Packet Buffer.
The value is in 1 KB resolution. Valid values can be from 1 KB to 16 KB. Default
buffer size is 0 KB. If this field is equal 0x0, then RCTL.BSIZE determines the packet
buffer size.
DMACQ_Dis 7 0b
DMA Coalescing Disable.
0b= Enable DMA coalescing on this queue if DMACR.DMAC_EN is set to 1b.
1b = Disable DMA coalescing on this queue. When a packet is destined to this queue
and the device is in coalescing mode, coalescing mode is exited immediately and
PCIe moves to the L0 link power management state.
BSIZEHEADER 13:8 0x4
Receive Buffer Size for Header Buffer.
The value is in 64 bytes resolution. Valid value can be from 64 bytes to 2048 bytes
(BSIZEHEADER = 0x1 to 0x20). Default buffer size is 256 bytes. This field must be
greater than 0 if the value of DESCTYPE is greater or equal to 2.
Note: When SRRCTL.Timestamp is set to 1b and the value of SRRCTL.DESCTYPE is
greater or equal to 2, BSIZEHEADER size should be equal or greater than 2
(128 bytes).
Reserved 19:14 0x0 Reserved.
Write 0x0, ignore on read.
RDMTS 24:20 0x0
Receive Descriptor Minimum Threshold Size.
A Low Latency Interrupt (LLI) associated with this queue is asserted each time the
number of free descriptors becomes equal to RDMTS multiplied by 16.
DESCTYPE 27:25 000b
Defines the descriptor in Rx.
000b = Legacy.
001b = Advanced descriptor one buffer.
010b = Advanced descriptor header splitting.
011b = Advanced descriptor header replication - replicate always.
100b = Advanced descriptor header replication large packet only (larger than header
buffer size).
Reserved.
111b = Reserved.
Field Bit(s) Initial Value Description
Programming Interface — Ethernet Controller I210
433
8.10.3 Packet Split Receive Type - PSRTYPE (0x5480 + 4*n [n=0...3];
R/W)
This register enables or disables each type of header that needs to be split or replicated (refer to
Section 7.1.5 for additional information on header split support). Each register controls the behavior of
1 queue.
Packet Split Receive Type Register (queue 0) - PSRTYPE0 (0x5480)
Packet Split Receive Type Register (queue 1) - PSRTYPE1 (0x5484)
Packet Split Receive Type Register (queue 2) - PSRTYPE2 (0x5488)
Packet Split Receive Type Register (queue 3) - PSRTYPE3 (0x548C)
Reserved 29:28 0x0 Reserved.
Write 0x0, ignore on read.
Timestamp 30 0b
Timestamp Received Packet
0b = Do not place timestamp at the beginning of a receive buffer.
1= Place timestamp at the beginning of a receive buffer. Timestamp is placed only in
buffers of received packets that meet the criteria defined in the TSYNCRXCTL.Type
field, 2-tuple filters or ETQF registers.
When set, the timestamp value in SYSTIMH and SYSTIML registers is placed in the
receive buffer before the MAC header of the packets defined in the
TSYNCRXCTL.Type field.
Drop_En 31 0b/1b
Drop Enabled.
If set, packets received to the queue when no descriptors are available to store them
are dropped. The packet is dropped only if there are not enough free descriptors in
the host descriptor ring to store the packet. If there are enough descriptors in the
host, but they are not yet fetched by the I210, then the packet is not dropped and
there are no release of packets until the descriptors are fetched.
Default is 0b for queue 0 and 1b for the other queues.
Field Bit(s) Initial Value Description
PSR_type0 0 0b Header includes MAC (VLAN/SNAP).
PSR_type1 1 1b Header includes MAC, (VLAN/SNAP) Fragmented IPv4 only.
PSR_type2 2 1b Header includes MAC, (VLAN/SNAP) IPv4, TCP only.
PSR_type3 3 1b Header includes MAC, (VLAN/SNAP) IPv4, UDP only.
PSR_type4 4 1b Header includes MAC, (VLAN/SNAP) IPv4, Fragmented IPv6 only.
PSR_type5 5 1b Header includes MAC, (VLAN/SNAP) IPv4, IPv6, TCP only.
PSR_type6 6 1b Header includes MAC, (VLAN/SNAP) IPv4, IPv6, UDP only.
PSR_type7 7 1b Header includes MAC, (VLAN/SNAP) Fragmented IPv6 only.
PSR_type8 8 1b Header includes MAC, (VLAN/SNAP) IPv6, TCP only.
PSR_type9 9 1b Header includes MAC, (VLAN/SNAP) IPv6, UDP only.
Reserved_1 10 1b Reserved.
Write 1b, ignore on read.
PSR_type11 11 1b Header includes MAC, (VLAN/SNAP) IPv4, TCP, NFS only.
PSR_type12 12 1b Header includes MAC, (VLAN/SNAP) IPv4, UDP, NFS only.
Reserved_1 13 1b Reserved.
Write 1b, ignore on read.
PSR_type14 14 1b Header includes MAC, (VLAN/SNAP) IPv4, IPv6, TCP, NFS only.
PSR_type15 15 1b Header includes MAC, (VLAN/SNAP) IPv4, IPv6, UDP, NFS only.
Field Bit(s) Initial Value Description
Ethernet Controller I210 — Programming Interface
434
8.10.4 Receive Descriptor Base Address Low - RDBAL (0xC000 + 0x40*n
[n=0...3]; R/W)
This register contains the lower bits of the 64-bit descriptor base address. The lower four bits are
always ignored. The Receive Descriptor Base Address must point to a 128 byte-aligned block of data.
Note: In order to keep compatibility with previous devices, for queues 0-3, these registers are
aliased to addresses 0x2800, 0x2900, 0x2A00 and 0x2B00, respectively.
8.10.5 Receive Descriptor Base Address High - RDBAH (0xC004 +
0x40*n [n=0...3]; R/W)
This register contains the upper 32 bits of the 64-bit descriptor base address.
Note: In order to keep compatibility with previous devices, for queues 0-3, these registers are
aliased to addresses 0x2804, 0x2904, 0x2A04 and 0x2B04, respectively.
8.10.6 Receive Descriptor Ring Length - RDLEN (0xC008 + 0x40*n
[n=0...3]; R/W)
This register sets the number of bytes allocated for descriptors in the circular descriptor buffer. It must
be 128-byte aligned.
Reserved_1 16 1b Reserved.
Write 1b, ignore on read.
PSR_type17 17 1b Header includes MAC, (VLAN/SNAP) IPv6, TCP, NFS only.
PSR_type18 18 1b Header includes MAC, (VLAN/SNAP) IPv6, UDP, NFS only.
Reserved 31:19 0x0 Reserved.
Write 0b, ignore on read.
Field1
1. Software should program the RDBAL[n] register only when a queue is disabled (RXDCTL[n].Enable = 0b).
Bit(s) Initial Value Description
Lower_0 6:0 0x0 Ignored on writes.
Returns 0x0 on reads.
RDBAL 31:7 X Receive Descriptor Base Address Low.
Field1
1. Software should program the RDBAH[n] register only when a queue is disabled (RXDCTL[n].Enable = 0b).
Bit(s) Initial Value Description
RDBAH 31:0 X Receive Descriptor Base Address [63:32].
Field Bit(s) Initial Value Description
Programming Interface — Ethernet Controller I210
435
Note: In order to keep compatibility with previous devices, for queues 0-3, these registers are
aliased to addresses 0x2808, 0x2908, 0x2A08 and 0x2B08, respectively.
8.10.7 Receive Descriptor Head - RDH (0xC010 + 0x40*n [n=0...3]; RO)
The value in this register might point to descriptors that are still not in host memory. As a result, the
host cannot rely on this value in order to determine which descriptor to process.
Note: In order to keep compatibility with previous devices, for queues 0-3, these registers are
aliased to addresses 0x2810, 0x2910, 0x2A10 and 0x2B10, respectively.
8.10.8 Receive Descriptor Tail - RDT (0xC018 + 0x40*n [n=0...3]; R/W)
This register contains the tail pointers for the receive descriptor buffer. The register points to a 16-byte
datum. Software writes the tail register to add receive descriptors to the hardware free list for the ring.
Note: Writing the RDT register while the corresponding queue is disabled is ignored by the I210.
In order to keep compatibility with previous devices, for queues 0-3, these registers are
aliased to addresses 0x2818, 0x2918, 0x2A18 and 0x2B18, respectively.
Field1
1. Software should program the RDLEN[n] register only when a queue is disabled (RXDCTL[n].Enable = 0b).
Bit(s) Initial Value Description
Zero 6:0 0x0
Ignore on writes.
Bits 6:0 must be set to 0x0.
Bits 4:0 always read as 0x0.
LEN 19:7 0x0
Descriptor Ring Length (number of 8 descriptor sets).
Note: Maximum allowed value in RDLEN field 19:0 is 0x80000 (32K
descriptors).
Reserved 31:20 0x0 Reserved.
Write 0x0, ignore on read.
Field Bit(s) Initial Value Description
RDH 15:0 0x0 Receive Descriptor Head.
Reserved 31:16 0x0 Reserved.
Write 0x0, ignore on read.
Field Bit(s) Initial Value Description
RDT 15:0 0x0 Receive Descriptor Tail.
Reserved 31:16 0x0 Reserved.
Write 0x0, ignore on read.
Ethernet Controller I210 — Programming Interface
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8.10.9 Receive Descriptor Control - RXDCTL (0xC028 + 0x40*n
[n=0...3]; R/W)
This register controls the fetching and write-back of receive descriptors. The three threshold values are
used to determine when descriptors are read from and written to host memory. The values are in units
of descriptors (each descriptor is 16 bytes).
Field Bit(s) Initial Value Description
PTHRESH 4:0 0xC
Prefetch Threshold
PTHRESH is used to control when a prefetch of descriptors is considered.
This threshold refers to the number of valid, unprocessed receive
descriptors the I210 has in its on-chip buffer. If this number drops below
PTHRESH, the algorithm considers pre-fetching descriptors from host
memory. This fetch does not happen unless there are at least HTHRESH
valid descriptors in host memory to fetch.
Note: HTHRESH should be given a non zero value each time PTHRESH is
used.
Possible values for this field are 0 to 16.
Reserved 7:5 0x0 Reserved.
Write 0x0, ignore on read.
HTHRESH 12:8 0xA
Host Threshold.
This field defines when a receive descriptor prefetch is performed. Each
time enough valid descriptors, as defined in the HTHRESH field, are
available in host memory a prefetch is performed.
Possible values for this field are 0 to 16.
Reserved 15:13 0x0 Reserved.
Write 0x0, ignore on read.
WTHRESH 20:16 0x1
Write-back Threshold.
WTHRESH controls the write-back of processed receive descriptors. This
threshold refers to the number of receive descriptors in the on-chip buffer
that are ready to be written back to host memory. In the absence of
external events (explicit flushes), the write-back occurs only after at least
WTHRESH descriptors are available for write-back.
Possible values for this field are 0 to 15.
Note: Since the default value for write-back threshold is 1b, the
descriptors are normally written back as soon as one cache line is
available. WTHRESH must contain a non-zero value to take
advantage of the write-back bursting capabilities of the I210.
Note: It’s recommended not to place a value above 0xC in the WTHRESH
field.
Reserved 24:21 0x0 Reserved.
ENABLE 25 0b
Receive Queue Enable.
When set, the Enable bit enables the operation of the specific receive
queue.
1b =Enables queue.
0b =Disables queue. Setting this bit initializes the Head and Tail registers
(RDH[n] and RDT[n]) of the specific queue. Until then, the state of the
queue is kept and can be used for debug purposes.
When disabling a queue, this bit is cleared only after all activity in the
queue has stopped.
Note: When receive queue is enabled and descriptors exist, descriptors
are fetched immediately. Actual receive activity on the port starts
only if the RCTL.RXEN bit is set.
SWFLUSH 26 0b
Receive Software Flush.
Enables software to trigger a receive descriptor write-back flushing,
independently of other conditions.
This bit shall be written to 1b and then to 0b after a write-back flush is
triggered.
Reserved 31:27 0x0 Reserved.
Programming Interface — Ethernet Controller I210
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Note: In order to keep compatibility with previous devices, for queues 0-3, these registers are
aliased to addresses 0x2828, 0x2928, 0x2A28 and 0x2B28, respectively.
8.10.10 Receive Queue Drop Packet Count - RQDPC (0xC030 + 0x40*n
[n=0...3]; RW)
Note: In order to keep compatibility with previous devices, for queues 0-3, these registers are
aliased to addresses 0x2830, 0x2930, 0x2A30 and 0x2B30, respectively.
Packets dropped due to the queue being disabled might not be counted by this register.
8.10.11 Transmit Queue Drop Packet Count - TQDPC (0xE030 + 0x40*n
[n=0...3]; RW)
8.10.12 Receive Checksum Control - RXCSUM (0x5000; R/W)
The Receive Checksum Control register controls the receive checksum off loading features of the I210.
The I210 supports the off loading of three receive checksum calculations: the Packet Checksum, the IP
Header Checksum, and the TCP/UDP Checksum.
Note: This register should only be initialized (written) when the receiver is not enabled (only write
this register when RCTL.RXEN = 0b)
Field Bit(s) Initial Value Description
RQDPC 31:0 0x0
Receive Queue Drop Packet Count.
Counts the number of packets dropped by a queue due to lack of descriptors
available.
Note: Counter wraps around when reaching a value of 0xFFFFFFFF.
Field Bit(s) Initial Value Description
TQDPC 31:0 0x0
Transmit Queue Drop Packet Count.
Counts the number of packets dropped by a queue due to lack of space in the
loopback buffer or due to security (anti-spoof) issues.
A multicast packet dropped by some of the destinations, but sent to others is counted
by this counter.
Note: Counter wraps around when reaching a value of 0xFFFFFFFF.
Ethernet Controller I210 — Programming Interface
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Field Bit(s) Initial Value Description
PCSS 7:0 0x0
Packet Checksum Start.
Controls the packet checksum calculation. The packet checksum shares the same
location as the RSS field and is reported in the receive descriptor when the
RXCSUM.PCSD bit is cleared.
If the RXCSUM.IPPCSE is set, the Packet checksum is aimed to accelerate checksum
calculation of fragmented UDP packets. Please refer to Section 7.1.7.2 for detailed
explanation. If RXCSUM.IPPCSE is cleared (the default value), the checksum
calculation that is reported in the Rx Packet checksum field is the unadjusted 16-bit
ones complement of the packet.
The packet checksum starts from the byte indicated by RXCSUM.PCSS (0b
corresponds to the first byte of the packet), after VLAN stripping if enabled by the
CTRL.VME. For example, for an Ethernet II frame encapsulated as an 802.3ac VLAN
packet and with RXCSUM.PCSS set to 14, the packet checksum would include the
entire encapsulated frame, excluding the 14-byte Ethernet header (DA, SA, Type/
Length) and the 4-byte VLAN tag. The packet checksum does not include the Ethernet
CRC if the RCTL.SECRC bit is set. Software must make the required offsetting
computation (to back out the bytes that should not have been included and to include
the pseudo-header) prior to comparing the packet checksum against the L4 checksum
stored in the packet checksum. The partial checksum in the descriptor is aimed to
accelerate checksum calculation of fragmented UDP packets.
Note: The PCSS value should point to a field that is before or equal to the IP header
start. Otherwise, the IP header checksum or TCP/UDP checksum is not
calculated correctly.
IPOFLD 8 1b
IP Checksum Off-load Enable.
RXCSUM.IPOFLD is used to enable the IP Checksum off-loading feature. If
RXCSUM.IPOFLD is set to 1b, the I210 calculates the IP checksum and indicates a
pass/fail indication to software via the IP Checksum Error bit (IPE) in the Error field of
the receive descriptor. Similarly, if RXCSUM.TUOFLD is set to 1b, the I210 calculates
the TCP or UDP checksum and indicates a pass/fail indication to software via the TCP/
UDP Checksum Error bit (RDESC.L4E).
This applies to checksum off loading only. Supported frame types:
Ethernet II
Ethernet SNAP
TUOFLD 9 1b TCP/UDP Checksum Off-load Enable.
ICMPv6XSUM 10 1b
ICMPv6 Checksum Enable.
0b = Disable ICMPv6 checksum calculation.
1b = Enable ICMPv6 checksum calculation.
Note: ICMPv6 checksum offload is supported only for packets sent to firmware for
Proxying.
CRCOFL 11 0b
CRC32 Offload Enable.
Enables the SCTP CRC32 checksum off-loading feature. If RXCSUM.CRCOFL is set to
1b, the I210 calculates the CRC32 checksum and indicates a pass/fail indication to
software via the CRC32 Checksum Valid bit (RDESC.L4I) in the Extended Status field
of the receive descriptor.
In non I/OAT, this bit is read only as 0b.
IPPCSE 12 0b IP Payload Checksum Enable.
See PCSS description.
PCSD 13 0b
Packet Checksum Disable.
The packet checksum and IP identification fields are mutually exclusive with the RSS
hash. Only one of the two options is reported in the Rx descriptor.
RXCSUM.PCSD Legacy Rx Descriptor (SRRCTL.DESCTYPE = 000b):
0b (checksum enable) = Packet checksum is reported in the Rx descriptor.
1b (checksum disable) = Not supported.
RXCSUM.PCSD Extended or Header Split Rx Descriptor (SRRCTL.DESCTYPE not equal
000b):
0b (checksum enable) = checksum and IP identification are reported in the Rx
descriptor.
1b (checksum disable) = RSS Hash value is reported in the Rx descriptor.
Reserved 31:14 0x0 Reserved.
Write 0x0, ignore on read.
Programming Interface — Ethernet Controller I210
439
8.10.13 Receive Long Packet Maximum Length - RLPML (0x5004; R/W)
8.10.14 Receive Filter Control Register - RFCTL (0x5008; R/W)
8.10.15 Multicast Table Array - MTA (0x5200 + 4*n [n=0...127]; R/W)
There is one register per 32 bits of the Multicast Address Table for a total of 128 registers. Software
must mask to the desired bit on reads and supply a 32-bit word on writes. The first bit of the address
used to access the table is set according to the RX_CTRL.MO field.
Note: All accesses to this table must be 32 bit.
Field Bit(s) Initial Value Description
RLPML 13:0 0x2600 Maximum allowed long packet length. This length is the global length of the packet
including all the potential headers of suffixes in the packet.
Reserved 31:14 0x0 Reserved.
Write 0x0, ignore on read.
Field Bit(s) Initial Value Description
Reserved 5:0 1b Reserved.
Write 1b, ignore on read.
NFSW_DIS 6 0b NFS Write Disable.
Disables filtering of NFS write request headers.
NFSR_DIS 7 0b NFS Read Disable.
Disables filtering of NFS read reply headers.
NFS_VER 9:8 00b
NFS Version.
00b = NFS version 2.
01b = NFS version 3.
10b = NFS version 4.
11b = Reserved for future use.
Reserved 10 0b Reserved.
IPv6XSUM_DIS 11 0b IPv6 XSUM Disable.
Disables XSUM on IPv6 packets.
Reserved 13:12 0x0 Reserved.
Write 0x0, ignore on read.
IPFRSP_DIS 14 0b IP Fragment Split Disable.
When this bit is set, the header of IP fragmented packets are not set.
Reserved 17:15 0x0 Reserved.
Write 0x0 ignore on read.
LEF 18 0b
Forward Length Error Packet.
0b = Packet with length error are dropped.
1b = Packets with length error are forwarded to the host.
SYNQFP 19 0b
Defines the priority between SYNQF and 2 tuple filter.
0b = 2-tuple filter priority.
1b = SYN filter priority.
Reserved 31:20 0x0 Reserved.
Write 0x0, ignore on read.
Ethernet Controller I210 — Programming Interface
440
Figure 8-1 shows the multicast lookup algorithm. The destination address shown represents the
internally stored ordering of the received DA. Note that bit 0 indicated in this diagram is the first on the
wire.
8.10.16 Receive Address Low - RAL (0x5400 + 8*n [n=0...15]; R/W)
While “n” is the exact unicast/multicast address entry and it is equal to 0,1,...15.
These registers contain the lower bits of the 48 bit Ethernet address. All 32 bits are valid.
These registers are reset by a software reset or platform reset. If a Flash is present, the first register
(RAL0) is loaded from the Flash after a software or platform reset.
Note: The RAL field should be written in network order.
Field Bit(s) Initial Value Description
Bit Vector 31:0 X Word wide bit vector specifying 32 bits in the multicast address filter table.
Figure 8-1. Multicast Table Array
Field Bit(s) Initial Value Description
RAL 31:0 X Receive Address Low.
Contains the lower 32-bit of the 48-bit Ethernet address.
47:40 39:32 31:24 23:16 15:8 7:0
pointer[11:5]
Multicast Table Array
32 x 128
(4096 bit vector)
...
...
pointer[4:0]
word
bit
?
Destination Address
RCTL.MO[1:0]
Programming Interface — Ethernet Controller I210
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8.10.17 Receive Address High - RAH (0x5404 + 8*n [n=0...15]; R/W)
These registers contain the upper bits of the 48-bit Ethernet address. The complete address is [RAH,
RAL]. The RAH.AV bit determines whether this address is compared against the incoming packet.
The RAH.ASEL field enables the I210 to perform special filtering on receive packets.
After reset, if an Flash is present, the first register (Receive Address Register 0) is loaded from the IA
field in the Flash with its Address Select field set to 00b and its Address Valid field set to 1b. If no Flash
is present, the Address Valid field is set to 0b and the Address Valid field for all of the other registers is
set to 0b.
Note: The RAH field should be written in network order.
The first receive address register (RAH[0]) is also used for exact match pause frame checking
(DA matches the first register). As a result, RAH[0] should always be used to store the
individual Ethernet MAC address of the I210.
Field Bit(s) Initial Value Description
RAH 15:0 X Receive address High.
Contains the upper 16 bits of the 48-bit Ethernet address.
ASEL 17:16 X
Address Select.
Selects how the address is to be used in the address filtering.
00b = Destination address (required for normal mode).
01b = Source address.
10b = Reserved.
11b = Reserved.
QSEL 19:18 X
Queue Select.
In Qav mode, indicates which Rx queue should get the packets
matching this MAC address. This field maps to the relevant
queue:
00b = queue0.
01b = queue1.
10b = queue2.
11b = queue3.
Reserved 27:20 0x0 Reserved.
Write 0x0, Ignore on reads
QSEL Enable 28 X
Queue Select Enable.
When set to 1b the value in the QSEL should be used as part of
the queue classification algorithm.
Reserved 30:29 0x0 Reserved.
Write 0x0, ignore on reads.
AV 31 0x0
Address Valid.
Cleared after master reset. If a Flash is present, the Address
Valid field of the Receive Address Register 0 is set to 1b after a
software or PCI reset or Flash read.
In entries 0-15 this bit is cleared by master reset.
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442
8.10.18 VLAN Priority Queue Filter VLAPQF (0x55B0;R/W)
Field Bit(s) Initial Value Description
VP0QSEL 1:0 0x0
VLAN Priority 0 Queue Selection.
This field defines the target queue for packets with VLAN priority value of 0x0 and
are enabled by VLANPV.
Reserved 2 0x0 Reserved.
VLANP0V 3 0x0 VLAN Priority 0 Valid.
This field enables VLAN Priority 0x0 for queue selection.
VP1QSEL 5:4 0x0
VLAN Priority 1Queue Selection.
This field defines the target queue for packets with VLAN priority value of 0x1 and
are enabled by VLANPV.
Reserved 6 0x0 Reserved.
VLANP1V 7 0x0 VLAN Priority 1 Valid.
This field enables VLAN Priority 0x1 for queue selection.
VP2QSEL 9:8 0x0
VLAN Priority 2 Queue Selection.
This field defines the target queue for packets with VLAN priority value of 0x2 and
are enabled by VLANPV.
Reserved 10 0x0 Reserved.
VLANP2V 11 0x0 VLAN Priority 2 Valid.
This field enables VLAN Priority 0x2 for queue selection.
VP3QSEL 13:12 0x0
VLAN Priority 3 Queue Selection.
This field defines the target queue for packets with VLAN priority value of 0x3 and
are enabled by VLANPV.
Reserved 14 0x0 Reserved.
VLANP3V 15 0x0 VLAN Priority 3 Valid.
This field enables VLAN Priority 0x3 for queue selection.
VP4QSEL 17:16 0x0
VLAN Priority 4 Queue Selection.
This field defines the target queue for packets with VLAN priority value of 0x4 and
are enabled by VLANPV.
Reserved 18 0x0 Reserved.
VLANP4V 19 0x0 VLAN Priority 4 Valid.
This field enables VLAN Priority 4 for queue selection.
VP5QSEL 21:20 0x0
VLAN Priority 5 Queue Selection.
This field defines the target queue for packets with VLAN priority value of 0x5 and
are enabled by VLANPV.
Reserved 22 0x0 Reserved.
VLANP5V 23 0x0 VLAN Priority 5 Valid.
This field enables VLAN Priority 0x5 for queue selection.
VP6QSEL 25:24 0x0
VLAN Priority 6 Queue Selection.
This field defines the target queue for packets with VLAN priority value of 0x6 and
are enabled by VLANPV.
Reserved 26 0x0 Reserved.
VLANP6V 27 0x0 VLAN Priority 6 Valid.
This field enables VLAN Priority 0x6 for queue selection.
VP7QSEL 29:28 0x0
VLAN Priority 7 Queue Selection.
This field defines the target queue for packets with VLAN priority value of 0x7 and
are enabled by VLANPV.
Reserved 30 0x0 Reserved.
VLANP7V 31 0x0 VLAN Priority 7 Valid.
This field enables VLAN Priority 0x7 for queue selection.
Programming Interface — Ethernet Controller I210
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8.10.19 VLAN Filter Table Array - VFTA (0x5600 + 4*n [n=0...127]; R/W)
There is one register per 32 bits of the VLAN Filter Table. The size of the word array depends on the
number of bits implemented in the VLAN Filter Table. Software must mask to the desired bit on reads
and supply a 32-bit word on writes.
Note: All accesses to this table must be 32 bit.
The algorithm for VLAN filtering using the VFTA is identical to that used for the Multicast Table Array.
Refer to Section 8.10.15 for a block diagram of the algorithm. If VLANs are not used, there is no need
to initialize the VFTA.
8.10.20 Multiple Receive Queues Command Register - MRQC (0x5818; R/
W)
Field Bit(s) Initial Value Description
Bit Vector 31:0 X Double-word wide bit vector specifying 32 bits in the VLAN Filter table.
Field Bit(s) Initial Value Description
Multiple
Receive
Queues
Enable
2:0 0x0
Multiple Receive Queues Enable.
Enables support for Multiple Receive Queues and defines the mechanism that controls
queue allocation.
000b = Multiple receive queues as defined by filters (2-tuple filters, L2 Ether-type
filters, SYN filter and flex filters).
001b = Reserved.
010b = Multiple receive queues as defined by filters and RSS for 4 queues1.
011b = Reserved.
100b = Reserved.
101b = Reserved.
110b = Reserved.
111b = Reserved.
Allowed values for this field are 000b, 010b. Any other value is ignored.
Ethernet Controller I210 — Programming Interface
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Note: The MRQC.Multiple Receive Queues Enable field is used to enable/disable RSS hashing and
also to enable multiple receive queues. Disabling this feature is not recommended. Model
usage is to reset the I210 after disabling the RSS.
8.10.21 RSS Random Key Register - RSSRK (0x5C80 + 4*n [n=0...9]; R/
W)
The RSS Random Key register stores a 40 byte key used by the RSS hash function.
Def_Q 5:3 0x0
Defines the default queue according to value of the Multiple Receive Queues Enable
field.
If Multiple Receive Queues Enable equals:
000b= Def_Q defines the destination of all packets not forwarded by filters.
001b= Def_Q field is ignored
010b= Def_Q defines the destination of all packets not forwarded by RSS or filters.
011b = Def_Q field is ignored.
100-101b= Def_Q field is ignored.
110b= Def_Q field is ignored.
Reserved 15:6 0x0 Reserved.
Write 0x0, ignore on read.
RSS Field
Enable 31:16 0x0
Each bit, when set, enables a specific field selection to be used by the hash function.
Several bits can be set at the same time.
Bit[16] = Enable TcpIPv4 hash function
Bit[17] = Enable IPv4 hash function
Bit[18] = Enable TcpIPv6Ex hash function
Bit[19] = Enable IPv6Ex hash function
Bit[20] = Enable IPv6 hash function
Bit[21] = Enable TCPIPv6 hash function
Bit[22] = Enable UDPIPv4
Bit[23] = Enable UDPIPv6
Bit[24] = Enable UDPIPv6Ext
Bit[25] = Reserved.
Bits[31:26] = Reserved (zero).
1. Note that the RXCSUM.PCSD bit should be set to enable reception of the RSS hash value in the receive descriptor.
Field Bit(s) Initial Value Description
K0 7:0 0x0 Byte n*4 of the RSS random key (n=0,1,...9).
K1 15:8 0x0 Byte n*4+1 of the RSS random key (n=0,1,...9).
K2 23:16 0x0 Byte n*4+2 of the RSS random key (n=0,1,...9).
K3 31:24 0x0 Byte n*4+3 of the RSS random key (n=0,1,...9).
31 24 23 16 15 8 7 0
K[3] K[2] K[1] K[0]
... ... ... ...
K[39] ... ... K[36]
Field Bit(s) Initial Value Description
Programming Interface — Ethernet Controller I210
445
8.10.22 Redirection Table - RETA (0x5C00 + 4*n [n=0...31]; R/W)
The redirection table is a 128-entry table with each entry being eight bits wide. Only 1 to 3 bits of each
entry are used to store the queue index. The table is configured through the following R/W registers.
Each entry (byte) of the redirection table contains the following:
Bits [7:3] - Reserved.
Bits [2:0] - Queue index for all pools or in regular RSS. In RSS only mode, all bits are used.
The contents of the redirection table are not defined following reset of the Memory Configuration
registers. System software must initialize the table prior to enabling multiple receive queues. It can
also update the redirection table during run time. Such updates of the table are not synchronized with
the arrival time of received packets. Therefore, it is not guaranteed that a table update takes effect on
a specific packet boundary.
Note: In case the operating system provides a redirection table whose size is smaller than 128
bytes, the software usually replicates the operating system-provided redirection table to span
the whole 128 bytes of the hardware's redirection table.
8.10.23 DMA VM Offload Register - DVMOLR (0xC038 + 0x40*n[n=0...3];
RW)
This register controls part of the offload and queueing options applied to each queue.
Field Bit(s) Initial Value Description
Entry 0 7:0 0x0 Determines the tag value and physical queue for index 4*n+0
(n=0...31).
Entry 1 15:8 0x0 Determines the tag value and physical queue for index 4*n+1
(n=0...31).
Entry 2 23:16 0x0 Determines the tag value and physical queue for index 4*n+2
(n=0...31).
Entry 3 31:24 0x0 Determines the tag value and physical queue for index 4*n+3
(n=0...31).
31 24 23 16 15 8 7 0
Tag 3 Tag 2 Tag 1 Tag 0
... ... ... ...
Tag 127 ... ... ...
7:3 2:0
Reserved Queue index
Ethernet Controller I210 — Programming Interface
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8.11 Filtering Register Descriptions
8.11.1 Immediate Interrupt RX - IMIR (0x5A80 + 4*n [n=0...7]; R/W)
This IMIR[n], TTQF[n], and the IMIREXT[n] registers define the filtering required to indicate which
packet triggers a LLI (immediate interrupt). The registers can also be used for queuing and deciding on
the timestamp of a packet.
Notes:
1. The Port field should be written in network order.
2. If one of the actions for this filter is set, then at least one of the IMIR[n].PORT_BP, IMIR[n].Size_BP,
the Mask bits in the TTQF[n] register or the IMIREXT.CtrlBit_BP bits should be cleared.
3. The value of the IMIR and IMIREXT registers after reset is unknown (apart from the
IMIR.Immediate Interrupt bit which is guaranteed to be cleared). Therefore, both registers should
be programmed before an IMIR.Immediate Interrupt is set for a given flow.
Field Bit(s) Initial Value Description
Reserved 28:0 0x0 Reserved.
Write 0x0, ignore on read.
Hide VLAN 29 0b
If this bit is set, a value of zero is written in the RDESC.VLAN tag and in the
RDESC.STATUS.VP fields of the received descriptor.
If this bit is set for a queue, the DVMOLR.STRVLAN bit for this queue should
be set also.
STRVLAN 30 0b
VLAN Strip.
If this bit is set, the VLAN is removed from the packet, and can be inserted
in the receive descriptor (depending on the value of the Hide VLAN field).
Note: If this bit is set the DVMOLR[n].CRC strip bit should be set as the
CRC is not valid anymore.
CRC Strip 31 1b
CRC Strip.
If this bit is set, the CRC is removed from the packet.
Notes:
1. If the DVMOLR[n].STRVLAN bit is set the DVMOLR[n].CRC strip bit
should also be set as the CRC is not valid anymore.
2. Even when this bit is set, CRC strip is not done on runt packets
(smaller than 64 bytes).
Programming Interface — Ethernet Controller I210
447
8.11.2 Immediate Interrupt Rx Ext. - IMIREXT (0x5AA0 + 4*n
[n=0...7]; R/W)
Field Bit(s) Initial Value Description
Destination Port 15:0 0x0
Destination TCP Port
This field is compared with the Destination TCP port in incoming packets. Only a
packet with a matching destination TCP port triggers an immediate interrupt (if
IMIR[n].Immediate Interrupt is set to 1b) and trigger the actions defined in the
appropriate TTQF[n] register if all other filtering conditions are met.
Note: Enabled by the IMIR.PORT_BP bit.
Immediate
Interrupt 16 0b
Enables issuing an immediate interrupt when the following conditions are met:
The 2-tuple filter associated with this register matches.
The length filter associated with this filter matches.
The TCP flags filter associated with this filter matches.
PORT_BP 17 X
Port Bypass.
When set to 1b, the TCP port check is bypassed and only other conditions are
checked.
When set to 0b, the TCP port is checked to fit the port field.
Reserved 28:18 0x0 Reserved.
Write 0x0, ignore on read.
Filter Priority 31:29 000b
Defines the priority of the filter assuming two filters with same priority don’t
match. If two filters with the same priority match the incoming packet, the first
filter (lowest ordinal number) is used in order to define the queue destination of
this packet.
Field Bit(s) Initial Value Description
Size_Thresh 11:0 X
Size Threshold.
These 12 bits define a size threshold. Only a packet with a length below this threshold
triggers an immediate interrupt (if IMIR[n].Immediate Interrupt is set to 1b) and
trigger the actions defined in the appropriate TTQF[n] register (if TTQF[n].Queue
Enable is set to 1b) if all other filtering conditions are met.
Notes:
1. Enabled by the IMIREXT.Size_BP bit.
2. The size used for this comparison is the size of the packet as forwarded to the
host and does not include any of the fields stripped by the MAC (VLAN or CRC).
As a result, setting the RCTL.SECRC and CTRL.VME bits should be taken into
account while calculating the size threshold.
3. When DVMOLR.CRC strip and DVMOLR.STRVLAN are used, the Size_thresh
should include the VLAN and the CRC.
Size_BP 12 X
Size Bypass.
When 1b, the size check is bypassed.
When 0b, the size check is performed.
Ethernet Controller I210 — Programming Interface
448
8.11.3 2-tuples Queue Filter - TTQF (0x59E0 + 4*n[n=0...7]; RW)
CtrlBit 18:13 X
Control Bit.
Defines TCP control bits used to generate immediate interrupt and trigger filter.
Only a received packet with the corresponding TCP control bits set to 1b triggers an
immediate interrupt (if IMIR[n].Immediate Interrupt is set to 1b) and trigger the
actions defined in the appropriate TTQF[n] register (if TTQF[n].Queue Enable is set to
1b) if all other filtering conditions are met.
Bit 13 (URG)= Urgent pointer field significant.
Bit 14 (ACK)= Acknowledgment field.
Bit 15 (PSH):= Push function.
Bit 16 (RST)= Reset the connection.
Bit 17 (SYN)= Synchronize sequence numbers.
Bit 18 (FIN)= No more data from sender.
Note: Enabled by the IMIREXT.CtrlBit_BP bit.
CtrlBit_BP 19 X
Control Bits Bypass.
When set to 1b, the control bits check is bypassed.
When set to 0b, the control bits check is performed.
Reserved 31:20 0x0 Reserved.
Write 0x0, ignore on read.
Field Bit(s) Initial Value Description
Protocol 7:0 0x0
IP L4 protocol, part of the 2-tuple queue filters.
This field is compared with the IP L4 protocol in incoming packets. Only a packet
with a matching IP L4 protocol will trigger an immediate interrupt (if
IMIR[n].Immediate Interrupt is set to 1b) and trigger the actions defined in the
appropriate TTQF[n] register (if TTQF[n].Queue Enable is set to 1b) if all other
filtering conditions are met.
Queue Enable 8 0b When set, enables filtering of Rx packets by the 2-tuples defined in this filter to
the queue indicated in this register.
Reserved 11:9 0x0 Reserved.
Write 0x0, ignore on read.
Reserved 14:9 0x0 Reserved.
Write 0x0, ignore on read.
Reserved_1 15 1b (For
legacy
reasons)
Reserved.
Write 1b, ignore on read.
Rx Queue 18:16 0x0 Identifies the Rx queue associated with this 2-tuple filter. Valid values are 0 to 3.
Reserved 26:19 0x0 Reserved
Write 0x0, ignore on read.
1588 time stamp 27 0b
When set, packets that match this filter are time stamped according to the IEEE
1588 specification.
Note: Packet is time stamped only if it matches IEEE 1588 protocol according
to the definition in the TSYNCRXCTL.Type field.
Mask 31:28 0xF
Mask bits for the 2-tuple fields. The corresponding field participates in the match
if the following bit cleared:
Bit 28 = Mask protocol comparison.
Bits 31:29 = Reserved.
Field Bit(s) Initial Value Description
Programming Interface — Ethernet Controller I210
449
8.11.4 Immediate Interrupt Rx VLAN Priority - IMIRVP (0x5AC0; R/W)
8.11.5 SYN Packet Queue Filter - SYNQF (0x55FC; RW)
8.11.6 EType Queue Filter - ETQF (0x5CB0 + 4*n[n=0...7]; RW)
Field Bit(s) Initial Value Description
Vlan_Pri 2:0 000b
VLAN Priority.
This field includes the VLAN priority threshold. When Vlan_pri_en is set to 1b, then an
incoming packet with a VLAN tag with a priority field equal or higher to VlanPri triggers
an immediate interrupt, regardless of the EITR moderation.
Vlan_pri_en 3 0b
VLAN Priority Enable.
When set to 1b, an incoming packet with VLAN tag with a priority equal or higher to
Vlan_Pri triggers an immediate interrupt, regardless of the EITR moderation.
When set to 0b, the interrupt is moderated by EITR.
Reserved 31:4 0x0 Reserved.
Write 0x0, ignore on read.
Field Bit(s) Initial Value Description
Queue Enable 0 0b When set, enables forwarding of Rx packets to the queue indicated in this
register.
Rx Queue 3:1 0x0 Identifies an Rx queue associated with SYN packets. Valid values are 0 to 3.
Reserved 31:4 0x0 Reserved.
Write 0x0, ignore on read.
Field Bit(s) Initial Value Description
EType 15:0 0x0 Identifies the protocol running on top of IEEE 802. Used to forward Rx packets
containing this EType to a specific Rx queue.
Rx Queue 18:16 0x0 Identifies the receive queue associated with this EType. Valid values are 0 to 3.
Reserved 19 0x0 Reserved.
Write 0x0, ignore on read.
EType Length 24:20 0x0
Ethertype Length. When enabled by Ethertype length enable this field defines the
length of the Ethertype specified by EType and the device continues parsing
incoming packets post this EType. The length includes the Ethertype itself as well
as the data portion that is followed for this Ethertype. The minimal Ethertype
length supported is 4 bytes.
EType Length
Enable 25 0x0 Ethertype Length Enable. When set indicates the Ethertype length defined in
EType Length is valid.
Filter enable 26 0b When set, this filter is valid. Any of the actions controlled by the following fields
are gated by this field.
Reserved 28:27 0x0 Reserved.
Write 0x0, ignore on read.
Ethernet Controller I210 — Programming Interface
450
8.12 Transmit Register Descriptions
8.12.1 Transmit Control Register - TCTL (0x0400; R/W)
Immediate
Interrupt 29 0x0 When set, packets that match this filter generate an immediate interrupt.
1588 time stamp 30 0b
When set, packets with this EType are time stamped according to the IEEE 1588
specification.
Note: The packet is time stamped only if it matches IEEE 1588 protocol
according to the definition in the TSYNCRXCTL.Type field.
Queue Enable 31 0b When set, enables filtering of Rx packets by the EType defined in this register to
the queue indicated in this register.
Field Bit(s) Initial Value Description
Reserved 0 0b Reserved.
Write 0b, ignore on read.
EN 1 0b
Transmit Enable.
The transmitter is enabled when this bit is set to 1b. Writing 0b to this bit stops
transmission after any in progress packets are sent. Data remains in the transmit FIFO
until the device is re-enabled. Software should combine this operation with reset if the
packets in the TX FIFO should be flushed.
Reserved 2 0b Reserved.
Write 0b, ignore on read.
PSP 3 1b
Pad Short Packets.
0b = Do not pad.
1b = Pad.
Padding makes the packet 64 bytes long. This is not the same as the minimum
collision distance.
If padding of short packets is allowed, the total length of a packet not including FCS
should be not less than 17 bytes.
CT 11:4 0xF
Collision Threshold.
This determines the number of attempts at retransmission prior to giving up on the
packet (not including the first transmission attempt). While this can be varied, it
should be set to a value of 15 in order to comply with the IEEE specification requiring
a total of 16 attempts. The Ethernet back-off algorithm is implemented and clamps to
the maximum number of slot-times after 10 retries. This field only has meaning when
in half-duplex operation.
Note: Software can choose to abort packet transmission in less than the Ethernet
mandated 16 collisions. For this reason, hardware provides CT support.
BST 21:12 0x40 Back-Off Slot Time.
This value determines the back-off slot time value in byte time.
SWXOFF 22 0b
Software XOFF Transmission.
When set to 1b, the I210 schedules the transmission of an XOFF (PAUSE) frame using
the current value of the PAUSE timer (FCTTV.TTV). This bit self-clears upon
transmission of the XOFF frame.
Note: While 802.3x flow control is only defined during full duplex operation, the
sending of PAUSE frames via the SWXOFF bit is not gated by the duplex
settings within the I210. Software should not write a 1b to this bit while the
I210 is configured for half-duplex operation.
Field Bit(s) Initial Value Description
Programming Interface — Ethernet Controller I210
451
8.12.2 Transmit Control Extended - TCTL_EXT (0x0404; R/W)
This register controls late collision detection.
The COLD field is used to determine the latest time in which a collision indication is considered as a
valid collision and not a late collision. When using the internal PHY, the default value of 0x40 provides a
behavior consistent with the 802.3 spec requested behavior. However, when using an SGMII connected
external PHY, the SGMII interface adds some delay on top of the time budget allowed by the
specification (collisions in valid network topographies even after 512 bit time can be expected). In order
to accommodate this condition, COLD should be updated to take the SGMII inbound and outbound
delays.
8.12.3 Transmit IPG Register - TIPG (0x0410; R/W)
This register controls the Inter Packet Gap (IPG) timer.
Reserved 23 0b Reserved.
RTLC 24 0b
Re-transmit on Late Collision.
When set, enables the I210 to re-transmit on a late collision event.
Note: RTLC configures the I210 to perform re-transmission of packets when a late
collision is detected. Note that the collision window is speed dependent: 64
bytes for 10/100 Mb/s and 512 bytes for 1000 Mb/s operation. If a late
collision is detected when this bit is disabled, the transmit function assumes
the packet has successfully transmitted. This bit is ignored in full-duplex
mode.
Reserved 31:25 Reserved.
Field Bit(s) Initial Value Description
Reserved 9:0 0x40 Reserved.
Write 0x40, ignore on read.
COLD 19:10 0x42
Collision Distance.
Used to determine the latest time in which a collision indication is considered as a
valid collision and not a late collision.
Reserved 31:20 0x0 Reserved.
Write 0x0, ignore on read.
Field Bit(s) Initial Value Description
Ethernet Controller I210 — Programming Interface
452
8.12.4 Retry Buffer Control – RETX_CTL (0x041C; RW)
This register controls the collision retry buffer.
8.12.5 DMA TX Control - DTXCTL (0x3590; R/W)
This register is used for controlling the DMA Tx behavior.
Field Bit(s) Initial Value Description
IPGT 9:0 0x08
IPG Back to Back.
Specifies the IPG length for back to back transmissions in both full and half duplex.
Measured in increments of the MAC clock:
8 ns MAC clock when operating @ 1 Gb/s.
80 ns MAC clock when operating @ 100 Mb/s.
800 ns MAC clock when operating @ 10 Mb/s.
IPGT specifies the IPG length for back-to-back transmissions in both full duplex and
half duplex. Note that an offset of 4 byte times is added to the programmed value to
determine the total IPG. As a result, a value of 8 is recommended to achieve a 12 byte
time IPG.
IPGR1 19:10 0x04
IPG Part 1.
Specifies the portion of the IPG in which the transmitter defers to receive events.
IPGR1 should be set to 2/3 of the total effective IPG (8).
Measured in increments of the MAC clock:
8 ns MAC clock when operating @ 1 Gb/s.
80 ns MAC clock when operating @ 100 Mb/s
800 ns MAC clock when operating @ 10 Mb/s.
IPGR 29:20 0x06
IPG After Deferral.
Specifies the total IPG time for non back-to-back transmissions (transmission
following deferral) in half duplex.
Measured in increments of the MAC clock:
8 ns MAC clock when operating @ 1 Gb/s.
80 ns MAC clock when operating @ 100 Mb/s
800 ns MAC clock when operating @ 10 Mb/s.
An offset of 5-byte times must be added to the programmed value to determine the
total IPG after a defer event. A value of 7 is recommended to achieve a 12-byte
effective IPG. Note that the IPGR must never be set to a value greater than IPGT. If
IPGR is set to a value equal to or larger that IPGT, it overrides the IPGT IPG setting in
half duplex resulting in inter-packet gaps that are larger then intended by IPGT. In this
case, full duplex is unaffected and always relies on IPGT.
Reserved 31:30 0x0 Reserved.
Write 0x0, ignore on read.
Field Bit(s) Initial Value Description
Water Mark 3:0 0x3 Retry buffer water mark. This parameters defines the minimal number of Qwords that
should be present in the retry buffer before transmission is started.
Reserved 31:4 0x0 Reserved.
Write 0x0, ignore on read.
Programming Interface — Ethernet Controller I210
453
8.12.6 DMA TX TCP Flags Control Low - DTXTCPFLGL (0x359C; RW)
This register holds the buses that AND the control flags in TCP header for the first and middle
segments of a TSO packet. Refer to Section 7.2.4.7.1 and Section 7.2.4.7.2 for details on the use of
this register.
8.12.7 DMA TX TCP Flags Control High - DTXTCPFLGH (0x35A0; RW)
This register holds the buses that AND the control flags in TCP header for the last segment of a TSO
packet. Refer to Section 7.2.4.7.3 for details of use of this register.
Field Bit(s) Initial Value Description
Reserved 1:0 0x0 Reserved.
Write 0x0, ignore on read.
Enable_spoof_queue 2 0b
Enable Spoofing Queue.
0b = Disable queue that exhibited spoofing behavior.
1b = Do not disable port that exhibited spoofing behavior.
Reserved 3 0x0 Reserved.
Write 0x0, ignore on read.
OutOfSyncDisable 4 0b
Disable Out Of Sync Mechanism.
0b = Out Of Sync mechanism is enabled.
1b = Out Of Sync mechanism is disabled.
Reserved 6:5 0 Reserved.
Count CRC 7 1b If set, the CRC is counted as part of the packet bytes statistics in per
Queue statistics (PQGORC, PQGOTC, PQGORLBC and PQGOTLBC).
Reserved 31:8 0x0 Reserved.
Write 0x0, ignore on read.
Field Bit(s) Initial Value Description
TCP_flg_first_seg 11:0 0xFF6
TCP Flags First Segment.
Bits that are used to execute an AND operation with the TCP flags in the TCP
header in the first segment
Reserved 15:12 0x0 Reserved.
Write 0x0, ignore on read.
TCP_Flg_mid_seg 27:16 0xF76
TCP Flags middle segments.
Bits that are used to execute an AND operation with the TCP flags in the TCP
header in the middle segments.
Reserved 31:28 0x0 Reserved.
Write 0x0, ignore on read.
Field Bit(s) Initial Value Description
TCP_Flg_lst_seg 11:0 0xF7F
TCP Flags Last Segment.
Bits that are used to execute an AND operation with the TCP flags at TCP header
in the last segment.
Reserved 31:12 0x0 Reserved.
Write 0x0, ignore on read.
Ethernet Controller I210 — Programming Interface
454
8.12.8 DMA TX Max Total Allow Size Requests - DTXMXSZRQ (0x3540;
RW)
This register limits the allowable size of concurrent outstanding Tx read requests from the host memory
on the PCIe. Limiting the size of concurrent outstanding PCIe requests allows low latency packet read
requests to be serviced in a timely manner, as the low latency request is serviced right after current
outstanding requests are completed.
8.12.9 DMA TX Maximum Packet Size - DTXMXPKTSZ (0x355C; RW)
This register limits the total number of data bytes that might be transmitted in a single frame. Reducing
packet size enables better utilization of transmit buffer.
8.12.10 Transmit Descriptor Base Address Low - TDBAL (0xE000 +
0x40*n [n=0...3]; R/W)
These registers contain the lower 32 bits of the 64-bit descriptor base address. The lower 7 bits are
ignored. The Transmit Descriptor Base Address must point to a 128-byte aligned block of data.
Note: In order to keep compatibility with previous devices, for queues 0-3, these registers are
aliased to addresses 0x3800, 0x3900, 0x3A00 and 0x3B00, respectively.
Field Bit(s) Initial Value Description
Max_bytes_num_req 11:0 0x10
Maximum allowable size of concurrent Tx outstanding requests on PCIe.
Field defines maximum size in 256 byte resolution of outstanding Tx requests
to be sent on PCIe. If total amount of outstanding Tx requests is higher than
defined in this field, no further Tx outstanding requests are sent.
Reserved 31:12 0x0 Reserved.
Field Bit(s) Initial Value Description
MAX_TPKT_SIZE 8:0 0x98
Maximum transmit packet size that is allowed to be transmitted by the driver.
Value entered is in 64 Bytes resolution.
Notes:
1. Default value enables transmission of maximum sized 9,728-byte Jumbo
frames.
2. Values programmed in this field should not exceed 9,728 bytes.
3. Value programmed should not exceed the Tx buffers size programmed in
the TXPBSIZE register.
Reserved 31:9 0x0 Reserved.
Write 0x0, ignore on read.
Field1
1. Software should program the TDBAL[n] register only when a queue is disabled (TXDCTL[n].Enable = 0b).
Bit(s) Initial Value Description
Lower_0 6:0 0x0 Ignored on writes.
Returns 0x0 on reads.
TDBAL 31:7 X Transmit Descriptor Base Address Low.
Programming Interface — Ethernet Controller I210
455
8.12.11 Transmit Descriptor Base Address High - TDBAH (0xE004 +
0x40*n [n=0...3]; R/W)
These registers contain the upper 32 bits of the 64-bit descriptor base address.
Note: In order to keep compatibility with previous devices, for queues 0-3, these registers are
aliased to addresses 0x3804, 0x3904, 0x3A04 and 0x3B04, respectively.
8.12.12 Transmit Descriptor Ring Length - TDLEN (0xE008 + 0x40*n
[n=0...3]; R/W)
These registers contain the descriptor ring length. The registers indicates the length in bytes and must
be 128-byte aligned.
Note: In order to keep compatibility with previous devices, for queues 0-3, these registers are
aliased to addresses 0x3808, 0x3908, 0x3A08 and 0x3B08, respectively.
8.12.13 Transmit Descriptor Head - TDH (0xE010 + 0x40*n [n=0...3];
RO)
These registers contain the head pointer for the transmit descriptor ring. It points to a 16-byte datum.
Hardware controls this pointer.
Note: The values in these registers might point to descriptors that are still not in host memory. As a
result, the host cannot rely on these values in order to determine which descriptor to release.
Note: In order to keep compatibility with previous devices, for queues 0-3, these registers are
aliased to addresses 0x3810, 0x3910, 0x3A10 and 0x3B10, respectively.
Field1
1. Software should program the TDBAH[n] register only when a queue is disabled (TXDCTL[n].Enable = 0b).
Bit(s) Initial Value Description
TDBAH 31:0 X Transmit Descriptor Base Address [63:32].
Field1
1. Software should program the TDLEN[n] register only when a queue is disabled (TXDCTL[n].Enable = 0b).
Bit(s) Initial Value Description
Zero 6:0 0x0 Ignore on writes.
Read back as 0x0.
LEN 19:7 0x0
Descriptor Ring Length (number of 8 descriptor sets).
Note: Maximum allowed value in TDLEN field 19:0 is 0x80000 (32K
descriptors).
Reserved 31:20 0x0 Reserved.
Write 0x0, ignore on read.
Field Bit(s) Initial Value Description
TDH 15:0 0x0 Transmit Descriptor Head.
Reserved 31:16 0x0 Reserved.
Write 0x0, ignore on read.
Ethernet Controller I210 — Programming Interface
456
8.12.14 Transmit Descriptor Tail - TDT (0xE018 + 0x40*n [n=0...3]; R/
W)
These registers contain the tail pointer for the transmit descriptor ring and points to a 16-byte datum.
Software writes the tail pointer to add more descriptors to the transmit ready queue. Hardware
attempts to transmit all packets referenced by descriptors between head and tail.
Note: In order to keep compatibility with previous devices, for queues 0-3, these registers are
aliased to addresses 0x3818, 0x3918, 0x3A18 and 0x3B18, respectively.
8.12.15 Transmit Descriptor Control - TXDCTL (0xE028 + 0x40*n
[n=0...3]; R/W)
These registers control the fetching and write-back operations of transmit descriptors. The three
threshold values are used to determine when descriptors are read from and written to host memory.
The values are in units of descriptors (each descriptor is 16 bytes).
Since write-back of transmit descriptors is optional (under the control of RS bit in the descriptor), not
all processed descriptors are counted with respect to WTHRESH. Descriptors start accumulating after a
descriptor with RS set is processed. In addition, with transmit descriptor bursting enabled, some
descriptors are written back that did not have RS set in their respective descriptors.
Note: When WTHRESH = 0x0, only descriptors with the RS bit set are written back.
Field Bit(s) Initial Value Description
TDT 15:0 0x0 Transmit Descriptor Tail.
Reserved 31:16 0x0 Reserved.
Write 0x0, ignore on read.
Field Bit(s) Initial Value Description
PTHRESH 4:0 0x0
Prefetch Threshold.
Controls when a prefetch of descriptors is considered. This threshold refers to the
number of valid, unprocessed transmit descriptors the I210 has in its on-chip buffer. If
this number drops below PTHRESH, the algorithm considers pre-fetching descriptors
from host memory. However, this fetch does not happen unless there are at least
HTHRESH valid descriptors in host memory to fetch.
Note: When PTHRESH is 0x0 a transmit descriptor fetch operation is done when any
valid descriptors are available in host memory and space is available in
internal buffer.
Reserved 7:5 0x0 Reserved.
Write 0x0, ignore on read.
HTHRESH 12:8 0x0
Host Threshold.
Prefetch of transmit descriptors is considered when number of valid transmit
descriptors in host memory is at least HTHRESH.
Note: HTHRESH should be given a non zero value each time PTHRESH is used.
Reserved 15:13 0x0 Reserved.
Write 0x0, ignore on read.
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Note: In order to keep compatibility with previous devices, for queues 0-3, these registers are
aliased to addresses 0x3828, 0x3928, 0x3A28 and 0x3B28, respectively.
WTHRESH 20:16 0x0
Write-Back Threshold.
Controls the write-back of processed transmit descriptors. This threshold refers to the
number of transmit descriptors in the on-chip buffer that are ready to be written back
to host memory. In the absence of external events (explicit flushes), the write-back
occurs only after at least WTHRESH descriptors are available for write-back.
Possible values for this field are 0 to 23.
Note: Since the default value for write-back threshold is 0b, descriptors are
normally written back as soon as they are processed. WTHRESH must be
written to a non-zero value to take advantage of the write-back bursting
capabilities of the I210.
Reserved 23:21 0x0 Reserved.
Reserved 24 0b Reserved.
Write 0b, ignore on read.
ENABLE 25 0b
Transmit Queue Enable.
When set, this bit enables the operation of a specific transmit queue.Setting this bit
initializes the Tail and Head registers (TDT[n] and TDH[n]) of a specific queue. Until
then, the state of the queue is kept and can be used for debug purposes.
When disabling a queue, this bit is cleared only after all transmit activity on this queue
is stopped.
Note: When transmit queue is enabled and descriptors exist, descriptors and data
are fetched immediately. Actual transmit activity on port starts only if the
TCTL.EN bit is set.
SWFLSH 26 0b
Transmit Software Flush.
This bit enables software to trigger descriptor write-back flushing, independently of
other conditions.
This bit must be written to 1b and then to 0b after a write-back flush is triggered.
Note: When working in head write-back mode (TDWBAL.Head_WB_En = 1b)
TDWBAL.WB_on_EITR bit should be set for a transmit descriptor flush to
occur.
Priority 27 0b
Transmit Queue Priority.
0b = Low priority.
1b = High priority.
When set, transmit DMA resources are always allocated to the queue before low
priority queues. Arbitration between transmit queues with the same priority is done in
a Round Robin (RR) fashion or in most empty fashion set by the
TQAVCTRL.DataFetchARB register.
HWBTHRESH 31:28 0x0
Transmit Head Write-back Threshold.
If the value of field is greater than 0x0, the head write-back to host occurs only when
the amount of internal pending write backs exceeds this threshold. Refer to
Section 7.2.4 for additional information.
Note: When activating this mode the WB_on_EITR bit in the TDWBAL register
should be set to guarantee a write back after a timeout even if the threshold
has not been reached.
Field Bit(s) Initial Value Description
Ethernet Controller I210 — Programming Interface
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8.12.16 Tx Descriptor Completion Write-Back Address Low - TDWBAL
(0xE038 + 0x40*n [n=0...3]; R/W)
Note: In order to keep compatibility with previous devices, for queues 0-3, these registers are
aliased to addresses 0x3838, 0x3938, 0x3A38 and 0x3B38, respectively.
8.12.17 Tx Descriptor Completion Write-Back Address High - TDWBAH
(0xE03C + 0x40*n [n=0...3];R/W)
Note: In order to keep compatibility with previous devices, for queues 0-3, these registers are
aliased to addresses 0x383C, 0x393C, 0x3A3C and 0x3B3C, respectively.
8.12.18 Tx Qav Hi Credit TQAVHC (0x300C+ 0x40*n [n=0...1];R/W)
Field1
1. Software should program the TDWBAL[n] register only when a queue is disabled (TXDCTL[n].Enable = 0b).
Bit(s) Initial Value Description
Head_WB_En 0 0b
Head Write-Back Enable.
1b = Head write back is enabled.
0b = Head write back is disabled.
When head_WB_en is set, TXDCTL.SWFLSH is ignored and no descriptor write back is
executed.
WB_on_EITR 1 0b When set, a head write back is done upon EITR expiration.
HeadWB_Low 31:2 0x0
Bits 31:2 of the head write-back memory location (Dword aligned). The last 2 bits of
this field are ignored and are always interpreted as 00b, meaning that the actual
address is Qword aligned.
Bits 1:0 are always 00b.
Field1
1. Software should program the TDWBAH[n] register only when a queue is disabled (TXDCTL[n].Enable = 0b).
Bit(s) Initial Value Description
HeadWB_High 31:0 0x0 Highest 32 bits of the head write-back memory location.
Field Bit(s) Initial Value Description
HiCredit 31:0 0x0
Hi Credit Value.
Maximum number of credits that this queue can accumulate. See
Section 7.2.7.6 for a description of how this field should be calculated.
Relevant only if TransmitMode is set to 1b (Qav).
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8.12.19 Tx Qav Credit Control TQAVCC (0x3004 + 0x40*n [n=0...1]; R/
W)
8.12.20 Launch Time Offset Register LAUNCH_OS0 (0x3578; R/W)
8.12.21 Tx Qav Control TQAVCTRL (0x3570; R/W)
Field Bit(s) Initial Value Description
IdleSlope 15:0 0x0
IdleSlope.
Idle Slope for this queue Value in credits.
Must be smaller than LinkRate = 0x7735 credits/byte.
See Section 7.2.7.6 for a description of how this field should be calculated.
Relevant only if TransmitMode is set to 1b (Qav).
Reserved 29:16 0x0 Reserved.
Reserved 30 0x0 Reserved.
QueueMode 31 0x0
Queue Mode.
0b = Strict Priority.
1b = Stream Reservation.
Note: Queue0 QueueMode must be set to 1b when TransmitMode is set to
Qav.
Relevant only if TransmitMode is set to 1b (Qav).
Field Bit(s) Initial Value Description
Reserved 4:0 0x0 Reserved.
LaunchOffset 29:5 0x0
Launch Time Offset, defined in 32nsec granularity.
The launch time of a packet is defined by the sum of the LaunchOffset and the
Relative LaunchTime parameter in the transmit context descriptor. Note that the
calculated launch time should not exceed 1 second on which SYSTIML wraps
around.
Reserved 30 0x0 Reserved.
Reserved 31 0x1 Reserved, should be written to 0x1 and ignored on read.
Field Bit(s) Initial Value Description
TransmitMode 0 0b
Transmit Mode Configuration.
0b= Legacy.
1b= Qav.
Note: Any change to this field shall be done while the queue is disabled.
Reserved 1 0b Reserved.
1588_STAT_EN 2 0b When set to 1b, the DMA time of transmitted packets is reported in the transmit
descriptors at its status write back. In this case, the TS_VAL flag is set and the
DMA_TIME field is valid in the transmit descriptor write back.
Reserved 3 0b Reserved.
DataFetchARB 4 0x0
Data Fetch Arbitration.
0b= Round Robin.
1b= Most Empty.
Relevant only if TransmitMode is set to 1 (Qav).
Reserved 7:5 0x0 Reserved.
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8.13 DCA and TPH Register Descriptions
8.13.1 Rx DCA Control Registers - RXCTL (0xC014 + 0x40*n [n=0...3];
R/W)
Note: Rx data write no-snoop is activated when the NSE bit is set in the receive descriptor.
Note: Both the DCA Enable bit and TPH Enable bit should not be set for the same type of traffic.
DataTranARB 8 0x0
Data Transmit Arbitration.
0b = Strict Priority.
1b = Credit Shaper Algorithm.
Relevant only if TransmitMode is set to 1b (Qav).
DataTranTIM 9 0x0 Data Launch Time Valid.
Relevant only if TransmitMode is set to 1b (Qav).
SP_WAIT_SR 10 0x0 When set to 1b, the SP queues wait for the SR queues to make sure the SR
launch time is always guaranteed.
Reserved 15:11 0x0 Reserved.
FetchTimDelta 31:16 0x0
Fetch Time Delta.
This field holds the value to be reduced from the launch time for fetch time
decision. The FetchTimeDelta value is defined in 32 ns granularity.
Relevant only if TransmitMode is set to 1b (Qav).
Field Bit(s) Initial Value Description
Rx Descriptor
Fetch TPH EN 0 0b
Receive Descriptor Fetch TPH Enable.
When set, hardware enables TPH for all Rx descriptors fetch from memory. When
cleared, hardware does not enable TPH for descriptor fetches. This bit is cleared as a
default.
Rx Descriptor
Writeback TPH EN 1 0b
Receive Descriptor Writeback TPH Enable.
When set, hardware enables TPH for all Rx descriptors written back into memory.
When cleared, hardware does not enable TPH for descriptor write-backs. This bit is
cleared as a default. The hint used is the hint set in the Socket ID field.
Rx Header TPH EN 2 0b
Receive Header TPH Enable.
When set, hardware enables TPH for all received header buffers. When cleared,
hardware does not enable TPH for Rx headers. This bit is cleared as a default. The hint
used is the hint set in the Socket ID field.
Rx Payload TPH EN 3 0b
Receive Payload TPH Enable.
When set, hardware enables TPH for all Ethernet payloads written into memory. When
cleared, hardware does not enable TPH for Ethernet payloads. This bit is cleared as a
default. The hint used is the hint set in the Socket ID field.
Reserved 4 0b Reserved.
Write 0b, ignore on read.
Rx Descriptor
DCA EN 5 0b
Descriptor DCA Enable.
When set, hardware enables DCA for all Rx descriptors written back into memory.
When cleared, hardware does not enable DCA for descriptor write-backs. This bit is
cleared as a default.
Rx Header DCA EN 6 0b
Receive Header DCA Enable.
When set, hardware enables DCA for all received header buffers. When cleared,
hardware does not enable DCA for Rx headers. This bit is cleared as a default.
Rx Payload DCA EN 7 0b
Receive Payload DCA Enable.
When set, hardware enables DCA for all Ethernet payloads written into memory. When
cleared, hardware does not enable DCA for Ethernet payloads. This bit is cleared as a
default.
Field Bit(s) Initial Value Description
Programming Interface — Ethernet Controller I210
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Note: In order to keep compatibility withprevious devices, for queues 0-3, these registers are
aliased to addresses 0x2814, 0x2914, 0x2A14 and 0x2B14, respectively.
RXdescRead
NSEn 8 0b
Receive Descriptor Read No Snoop Enable.
This bit must be reset to 0b to ensure correct functionality (except if the software
driver can guarantee the data is present in the main memory before the DMA process
occurs).
Note: When TPH is enabled, the No Snoop bit should be 0b.
RXdescRead
ROEn 9 1b Receive Descriptor Read Relax Order Enable.
RXdescWBNSen 10 0b
Receive Descriptor Write-Back No Snoop Enable.
This bit must be reset to 0b to ensure correct functionality of descriptor write back.
Note: When TPH is enabled No Snoop bit should be 0b.
RXdescWBROen
(RO) 11 0b Receive Descriptor Write-Back Relax Order Enable.
This bit must be reset to 0b to ensure correct functionality of descriptor write back.
RXdataWrite
NSEn 12 0b
Receive Data Write No Snoop Enable (header replication: header and data).
When set to 0b, the last bit of the Packet Buffer Address field in the advanced receive
descriptor is used as the LSB of the packet buffer address (A0), thus enabling Byte
alignment of the buffer.
When set to 1b, the last bit of the Packet Buffer Address field in advanced receive
descriptor is used as the No-Snoop Enabling (NSE) bit (buffer is Word aligned). If also
set to 1b, the NSE bit determines whether the data buffer is snooped or not.
Note: When TPH is enabled No Snoop bit should be 0b.
RXdataWrite
ROEn 13 1b Receive Data Write Relax Order Enable (header replication: header and data).
RxRepHeader
NSEn 14 0b
Receive Replicated/Split Header No Snoop Enable.
This bit must be reset to 0b to ensure correct functionality of header write to host
memory.
Note: When TPH is enabled, the No Snoop bit should be 0b.
RxRepHeader
ROEn 15 1b Receive Replicated/Split Header Relax Order Enable.
Reserved 23:16 0x0 Reserved.
Write 0x0, ignore on read.
CPUID 31:24 0x0
Physical ID.
Legacy DCA capable platforms. The software device driver, upon discovery of the
physical CPU ID and CPU Bus ID, programs the CPUID field with the Physical CPU and
Bus ID associated with this Rx queue.
DCA 1.0 capable platforms. The software device driver programs a value, based on the
relevant APIC ID, associated with this Tx queue.
Refer to Table 3.1.3.1.2.3 for details.
TPH capable platforms. The device driver programs a value, based on the relevant
Socket ID, associated with this receive queue.
Note that for TPH platforms, bits 31:27 of this field should always be set to zero. Refer
to Section 7.7.2 for details.
Field Bit(s) Initial Value Description
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8.13.2 Tx DCA Control Registers - TXCTL (0xE014 + 0x40*n [n=0...3];
R/W)
Field Bit(s) Initial Value Description
Tx Descriptor Fetch
TPH EN1
1. Both the DCA Enable bit and the TPH Enable bit should not be set for the same type of traffic.
0 0b
Transmit Descriptor Fetch TPH Enable.
When set, hardware enables TPH for all Tx descriptors fetch from memory. When
cleared, hardware does not enable TPH for descriptor fetches. This bit is cleared as a
default.
Tx Descriptor
Writeback TPH EN 1 0b
Transmit Descriptor Writeback TPH Enable.
When set, hardware enables TPH for all Tx descriptors written back into memory.
When cleared, hardware does not enable TPH for descriptor write-backs. This bit is
cleared as a default. The hint used is the hint set in the Socket ID field.
Reserved 2 0b Reserved.
Write 0b, ignore on read.
Tx Packet TPH EN 3 0b
Transmit Packet TPH Enable.
When set, hardware enables TPH for all Ethernet payloads read from memory. When
cleared, hardware does not enable TPH for Ethernet payloads. This bit is cleared as a
default.
Reserved 4 0b Reserved.
Write 0b, ignore on read.
Tx Descriptor DCA
EN15 0b
Descriptor DCA Enable.
When set, hardware enables DCA for all Tx descriptors written back into memory.
When cleared, hardware does not enable DCA for descriptor write backs. This bit is
cleared as a default and also applies to head write back when enabled.
Reserved 7:6 00b Reserved.
Write 00b, ignore on read.
TXdescRDNSen 8 0b
Tx Descriptor Read No Snoop Enable.
This bit must be reset to 0b to ensure correct functionality (unless the software
device driver has written this bit with a write-through instruction).
Note: When TPH is enabled No Snoop bit should be 0b.
TXdescRDROEn 9 1b Tx Descriptor Read Relax Order Enable.
TXdescWBNSen 10 0b
Tx Descriptor Write-Back No Snoop Enable.
This bit must be reset to 0b to ensure correct functionality of descriptor write-back.
Also applies to head write-back, when enabled.
Note: When TPH is enabled No Snoop bit should be 0b.
TXdescWBROen 11 1b Tx Descriptor Write Back Relax Order Enable.
Applies to head write back, when enabled.
TXDataReadNSEn 12 0b Tx Data Read No Snoop Enable.
Note: When TPH is enabled No Snoop bit should be 0b.
TXDataReadROEn 13 1b Tx Data Read Relax Order Enable.
Reserved 23:14 0b Reserved
Write 0 ignore on read.
CPUID 31:24 0x0
Physical ID
Legacy DCA capable platforms - the device driver, upon discovery of the physical CPU
ID and CPU Bus ID, programs the CPUID field with the Physical CPU and Bus ID
associated with this Tx queue.
DCA 1.0 capable platforms - the device driver programs a value, based on the
relevant APIC ID, associated with this Tx queue.
Refer to Table 3.1.3.1.2.3 for details
TPH capable platforms - the device driver programs a value, based on the relevant
Socket ID, associated with this transmit queue.
Note that for TPH platforms, bits 31:27 of this field should always be set to zero.
Refer to Section 7.7.2 for details.
Programming Interface — Ethernet Controller I210
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Note: In order to keep compatibility with previous devices, for queues 0-3, these registers are
aliased to addresses 0x3814, 0x3914, 0x3A14 and 0x3B14, respectively.
8.13.3 DCA Requester ID Information - DCA_ID (0x5B70; RO)
The DCA Requester ID field, composed of Device ID, Bus #, and Function # is set up in MMIO space for
software to program the DCA Requester ID Authentication register.
8.13.4 DCA Control - DCA_CTRL (0x5B74; R/W)
This CSR is common to all functions.
Field Bit(s) Initial Value Description
Function
Number 2:0 000b
Function Number.
Function number assigned to the function based on BIOS/operating system
enumeration.
Device
Number 7:3 0x0
Device Number.
Device number assigned to the function based on BIOS/operating system
enumeration.
Bus Number 15:8 0x0 Bus Number.
Bus number assigned to the function based on BIOS/operating system enumeration.
Reserved 31:16 0x0 Reserved.
Write 0x0, ignore on read.
Field Bit(s) Initial Value Description
DCA_DIS 0 1b
DCA Disable.
0b = DCA tagging is enabled.
1b = DCA tagging is disabled.
DCA_MODE 4:1 0x0
DCA Mode.
000b = Legacy DCA is supported. The TAG field in the TLP header is based on the
following coding: bit 0 is DCA enable; bits 3:1 are CPU ID).
001b = DCA 1.0 is supported. When DCA is disabled for a given message, the TAG
field is 0000,0000b. If DCA is enabled, the TAG is set per queue as programmed in the
relevant DCA Control register.
All other values are undefined.
Reserved 8:5 0x0 Reserved.
Write 0x0, ignore on read.
Desc_PH 10:9 00b
Descriptor PH.
Defines the PH field used when a TPH hint is given for descriptor associated traffic
(descriptor fetch, descriptor write back or head write back).
Data_PH 12:11 10b
Data PH.
Defines the PH field used when a TPH hint is given for data associated traffic (Tx data
read, Rx data write).
Reserved 31:13 0x0 Reserved.
Write 0x0, ignore on read.
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8.14 Timer Registers Description
8.14.1 Watchdog Setup - WDSTP (0x1040; R/W)
8.14.2 Watchdog Software Device Status - WDSWSTS (0x1044; R/W)
8.14.3 Free Running Timer - FRTIMER (0x1048; RWM)
This register reflects the value of a free running timer that can be used for various timeout indications.
The register is reset by a PCI reset and/or software reset.
Note: Writing to this register is for DFX purposes only.
Field Bit(s) Initial Value Description
WD_Enable 0 0b1
1. Value read from the Flash.
Enable Watchdog Timer.
WD_Timer_
Load_enable
(SC) 1 0b
Enables the load of the watchdog timer by writing to WD_Timer field. If this bit is not
set, the WD_Timer field is loaded by the value of WD_Timeout.
Note: Writing to this field is only for DFX purposes.
This field resets on software reset events.
Reserved 15:2 0x0 Reserved.
Write 0x0, ignore on read.
WD_Timer
(RWM) 23:16 WD_Timeout
Indicates the current value of the timer. Resets to the timeout value each time the I210
functional bit in Software Device Status register is set. If this timer expires, the WD
interrupt to the firmware and the WD SDP is asserted. As a result, this timer is stuck at
zero until it is re-armed.
Note: Writing to this field is only for DFX purposes.
WD_Timeout 31:24 0x21
Defines the number of seconds until the watchdog expires. The granularity of this timer
is 1 second. The minimal value allowed for this register when the watchdog mechanism
is enabled is two. Setting this field to 1b might cause the watchdog to expire
immediately.
Note: Only 4 LSB bits loaded from Flash.
Field Bit(s) Initial Value Description
Dev_Function
al (SC) 0 0b Each time this bit is set, the watchdog timer is re-armed.
This bit is self clearing.
Force_WD
(SC) 1 0b
Setting this bit causes the WD timer to expire immediately. The WD_timer field is set
to 0b. It can be used by software in order to indicate some fatal error detected in the
software or in the hardware.
This bit is self clearing.
Reserved 23:2 0x0 Reserved.
Write 0x0, ignore on read.
Stuck Reason 31:24 0x0 This field can be used by software to indicate to the firmware the reason the I210 is
malfunctioning. The encoding of this field is software/firmware dependent. A value of
0x0 indicates a functional the I210.
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8.14.4 TCP Timer - TCPTIMER (0x104C; R/W)
Field Bit(s) Initial Value Description
Microsecond 9:0 X Number of microseconds in the current millisecond.
Millisecond 19:10 X Number of milliseconds in the current second.
Seconds 31:20 X Number of seconds from the timer start (up to 4095 seconds).
Field Bit(s) Initial Value Description
Duration 7:0 0x0 Duration.
Duration of the TCP interrupt interval in ms.
KickStart (WO) 8 0b
Counter KickStart.
Writing a 1b to this bit kick starts the counter down count from the initial
value defined in the Duration field. Writing a 0b has no effect.
TCPCountEn 9 0b
TCP Count Enable.
1b = TCP timer counting enabled.
0b = TCP timer counting disabled.
Once enabled, the TCP counter counts from its internal state. If the
internal state is equal to 0b, the down-count does not restart until
KickStart is activated. If the internal state is not 0b, the down-count
continues from internal state.
This enables a pause in the counting for debug purpose.
TCPCountFinish (WO) 10 0b
TCP Count Finish.
This bit enables software to trigger a TCP timer interrupt, regardless of the
internal state.
Writing a 1b to this bit triggers an interrupt and resets the internal counter
to its initial value. Down count does not restart until either KickStart is
activated or Loop is set.
Writing a 0b has no effect.
Loop 11 0b
TCP Loop.
When set to 1b, the TCP counter reloads duration each time it reaches
zero, and continues down-counting from this point without kick starting.
When set to 0b, the TCP counter stops at a zero value and does not re-
start until KickStart is activated.
Note: Setting this bit alone is not enough to start the timer activity. The
KickStart bit should also be set.
Reserved 31:12 0x0 Reserved.
Write 0x0, ignore on read.
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8.15 Time Sync Register Descriptions
8.15.1 Rx Time Sync Control Register - TSYNCRXCTL (0xB620;RW)
8.15.2 Rx Timestamp Low - RXSTMPL (0xB624; RO)
8.15.3 Rx Timestamp High - RXSTMPH (0xB628; RO)
Field Bit(s) Initial Value Description
RXTT(RO) 0 0x0
Rx Timestamp Valid
Bit is set when a valid value for Rx timestamp is captured in the Rx timestamp
registers. Bit is cleared by read of Rx timestamp high register (RXSTMPH)).
Type 3:1 0x0
Type of Packets to Timestamp.
000b = Timestamp L2 (V2) packets with MessageType as defined by MSGT field in the
TSYNCRXCFG register as well as DELAY_REQ and DELAY_RESP packets.
001b = Timestamp L4 (V1) packets with Control as defined by CTRLT field in the
TSYNCRXCFG register.
010b = Timestamp V2 (L2 and L4) packets with MessageType as defined by MSGT
field in the TSYNCRXCFG register as well as DELAY_REQ and DELAY_RESP packets.
100b = timestamp all packets.
101b = Timestamp all V2 packets which have a MessageType bit 3 zero, which means
timestamp all event packets.
011b, 110b and 111b = Reserved
En 4 0b
Enable Rx Timestamp
0b = Timestamping disabled.
1b = Timestamping enabled.
RSV 31:5 0x0 Reserved.
Write 0x0, ignore on read.
Field Bit(s) Initial Value Description
RTSL 29:0 0x0 Rx timestamp LSB value (defined in ns units).
Zero 31:30 0x0 Zero bits.
Field Bit(s) Initial Value Description
RTSH 31:0 0x0 Rx timestamp MSB value (defined in second units).
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8.15.4 Tx Time Sync Control Register - TSYNCTXCTL (0xB614; RW)
8.15.5 Tx Timestamp Value Low - TXSTMPL (0xB618;RO)
8.15.6 Tx Timestamp Value High - TXSTMPH(0xB61C; RO)
8.15.7 System Time Register Residue - SYSTIMR (0xB6F8; RW)
8.15.8 System Time Register Low - SYSTIML (0xB600; RW)
Field Bit(s) Initial Value Description
TXTT(ROM) 0 0b Transmit timestamp valid (equals 1b when a valid value for Tx timestamp is captured
in the Tx timestamp register, clear by read of Tx timestamp register TXSTMPH).
RSV 3:1 0x0 Reserved.
Write 0x0, ignore on read.
EN 4 0b
Enable Transmit timestamp.
0b = time stamping disabled.
1b = time stamping enabled.
RSV 5:7 0x0 Reserved. Write 0x0, ignore on read.
1588_Offset 8:15 0x0 Byte offset of the inserted timestamp to the transmit packet in 1-step flow. The offset
is defined in byte units measured from the beginning of the packet as transmitted to
the network (including the optional inserted VLAN tag).
RSV 31:16 0x0 Reserved.
Write 0x0, ignore on read.
Field Bit(s) Initial Value Description
TTSL 29:0 0x0 Transmit timestamp LSB value (defined in ns units).
Zero 31:30 0x0 Zero bits.
Field Bit(s) Initial Value Description
TTSH 31:0 0x0 Transmit timestamp MSB value (defined in sec units).
Field Bit(s) Initial Value Description
STR 31:0 0x0 System time Residue value (defined in 2-32 nS resolution).
Field Bit(s) Initial Value Description
STL 29:0 0x0 System time LSB value (defined in ns units).
Zero 31:30 0x0 Zero bits.
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8.15.9 System Time Register High - SYSTIMH (0xB604; RW)
8.15.10 System Time Register Tx MS - SYSTIMTM (0xB6FC; RW)
8.15.11 Increment Attributes Register - TIMINCA (0xB608; RW)
8.15.12 Time Adjustment Offset Register - TIMADJ (0xB60C; RW)
Field Bit(s) Initial Value Description
STH 31:0 0x0 System time MSB value (defined in sec units).
Field Bit(s) Initial Value Description
STM 15:0 0x0 Two MS bytes of the system time (defined in 232 sec units). This field is
static, kept at the value programmed by the software. It is used for 1-step
transmission as the two MS bytes inserted to the SYNC packet.
RSV 31:16 0x0 Reserved.
Write 0x0, ignore on read.
Field Bit(s) Initial Value Description
Incvalue 30:0 0x0
Increment value.
Value to be added or subtracted (depending on ISGN value) from 8 nS clock
cycle in resolution of 2-32 nS.
ISGN 31 0b
Increment sign.
0b = Each 8 nS cycle add to SYSTIM a value of 8 nS + Incvalue * 2-32 nS.
1b = Each 8 nS cycle add to SYSTIM a value of 8 nS -Incvalue * 2-32 nS.
Field Bit(s) Initial Value Description
Tadjus 29:0 0x0
Time Adjustment Value.
Low (defined in ns units). The TADJL field can be set to any non-zero value
smaller than 999,999,900 decimal (slightly below 1 second).
Zero 30 0b Zero bit.
Sign 31 0b Sign (0b= “+”1b = “-”).
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8.15.13 TimeSync Auxiliary Control Register - TSAUXC (0xB640; RW)
Field Bit(s) Initial Value Description
EN_TT0 0 0b
Enable target time 0.
Enable bit is set by software to 1b, to enable pulse or level change generation as a
function of the TSAUXC.PLSG bit.
EN_TT1 1 0b
Enable target time 1.
Enable bit is set by software to 1b, to enable a level change.
EN_CLK0 2 0b
Enable Configurable Frequency Clock 0.
Clock is generated according to frequency defined in the FREQOUT0 register on the
SDP pin (0 to 3) that has both:
1. TSSDP.TS_SDPx_SEL field with a value of 10b.
2. TSSDP.TS_SDPx_EN value of 1b.
SAMP_AUT0 3 0b When setting the SAMP_AUT0 flag the SYSTIML/H registers are latched to the
AUXSTMPL0/ AUXSTMPH0 registers. Then the SAMP_AUT0 flag is auto-cleared by the
hardware.
Reserved 4 0b Reserved.
EN_CLK1 5 0b
Enable Configurable Frequency Clock 1.
Clock is generated according to frequency defined in the FREQOUT1 register on the
SDP pin (0 to 3) that has both:
1. TSSDP.TS_SDPx_SEL field with a value of 11b.
2. TSSDP.TS_SDPx_EN value of 1b.
SAMP_AUT1 6 0b When setting the SAMP_AUT1 flag the SYSTIML/H registers are latched to the
AUXSTMPL1/ AUXSTMPH1 registers. Then the SAMP_AUT1 flag is auto-cleared by the
hardware.
Reserved 7 0b Reserved.
EN_TS0 8 0b
Enable hardware timestamp 0.
Enable Timestamping occurrence of change in SDP pin into the AUXSTMPL0 and
AUXSTMPH0 registers.
SDP pin (0 to 3) is selected for time stamping, if the SDP pin is selected via the
TSSDP.AUX0_SDP_SEL field and the TSSDP.AUX0_TS_SDP_EN bit is set to 1b.
AUTT0 9 0b Auxiliary Timestamp Taken.
Cleared when read from auxiliary timestamp 0 occurred.
EN_TS1 10 0b
Enable Hardware Timestamp 1.
Enable timestamping occurrence of change in SDP pin into the AUXSTMPL1 and
AUXSTMPH1 registers.
SDP pin (0 to 3) is selected for time stamping, if the SDP pin is selected via the
TSSDP.AUX1_SDP_SEL field and the TSSDP.AUX1_TS_SDP_EN bit is set to 1b.
AUTT1 11 0b Auxiliary Timestamp Taken.
Cleared when read from auxiliary timestamp 1 occurred.
Reserved 16:12 0x0 Reserved.
Write 0x0, ignore on read.
PLSG 17 0b
Use Target Time 0 to generate start of pulse and Target Time 1 to generate end of
pulse. SDP pin selected to drive pulse or level change is set according to the
TSSDP.TS_SDPx_SEL field with a value of 00b and TSSDP.TS_SDPx_EN bit with a
value of 1b.
0b = Target Time 0 generates change in SDP level.
1b = Target time 0 generates start of pulse on SDP pin.
Note: Pulse or level change is generated when TSAUXC.EN_TT0 is set to 1b.
Ethernet Controller I210 — Programming Interface
470
8.15.14 Target Time Register 0 Low - TRGTTIML0 (0xB644; RW)
8.15.15 Target Time Register 0 High - TRGTTIMH0 (0xB648; RW)
8.15.16 Target Time Register 1 Low - TRGTTIML1 (0xB64C; RW)
8.15.17 Target Time Register 1 High - TRGTTIMH1 (0xB650; RW)
Reserved 29:18 0b Reserved.
Write 0b, ignore on read.
Reserved 30 1b Reserved.
Write 1b, ignore on read.
Disable
systime 31 1b
Disable SYSTIM Count Operation.
0b = SYSTIM timer activated
1b = SYSTIM timer disabled. Value of SYSTIMH, SYSTIML and SYSTIMR remains
constant.
Field Bit(s) Initial Value Description
TTL 29:0 0x0 Target Time 0 LSB register (defined in ns units).
Zero 31:30 0x0 Zero bits.
Field Bit(s) Initial Value Description
TTH 31;0 0x0 Target Time 0 MSB register (defined in second units).
Field Bit(s) Initial Value Description
TTL 29:0 0x0 Target Time 1 LSB register (defined in ns units).
Zero 31:30 0x0 Zero bits.
Field Bit(s) Initial Value Description
TTH 31:0 0x0 Target Time 1 MSB register (defined in second units).
Field Bit(s) Initial Value Description
Programming Interface — Ethernet Controller I210
471
8.15.18 Frequency Out 0 Control Register FREQOUT0 (0xB654; RW)
8.15.19 Frequency Out 1 Control Register - FREQOUT1 (0xB658; RW)
8.15.20 Auxiliary Time Stamp 0 Register Low - AUXSTMPL0 (0xB65C; RO)
8.15.21 Auxiliary Time Stamp 0 Register High -AUXSTMPH0 (0xB660; RO)
Reading this register releases the value stored in AUXSTMPH/L0 and enables timestamping of the next
value.
8.15.22 Auxiliary Time Stamp 1 Register Low AUXSTMPL1 (0xB664; RO)
Field Bit(s) Initial Value Description
CHCT 29:0 0x0
Clock Out Half Cycle Time. Defines the Half Cycle time of Clock 0 in ns
units. When clock output is enabled, permitted values are any value larger
than 8 and up to including 70,000,000 decimal (70 ms). The following
larger values can be used as long as the output clock is synchronized to
whole seconds as described in section "Synchronized Output Clock on SDP
Pins": 125 ms; 250 ms and 500 ms.
Reserved 31:30 0x0 Reserved.
Write 0x0, ignore on read.
Field Bit(s) Initial Value Description
CHCT 29:0 0x0
Clock Out Half Cycle Time defines the Half Cycle time of Clock 1 in ns units.
When clock output is enabled, permitted values are any value larger than 8
and up to including 70,000,000 decimal (70 ms). The following larger
values can be used as long as the output clock is synchronized to whole
seconds as described in section "Synchronized Output Clock on SDP Pins":
125 ms; 250 ms and 500 ms.
Reserved 31:30 0x0 Reserved.
Write 0x0, ignore on read.
Field Bit(s) Initial Value Description
TSTL 29:0 0x0 Auxiliary Time Stamp 0 LSB value (defined in ns units).
Zero 31:30 0x0 Zero bits.
Field Bit(s) Initial Value Description
TSTH 31:0 0x0 Auxiliary Time Stamp 0 MSB value (defined in second units).
Field Bit(s) Initial Value Description
TSTL 29:0 0x0 Auxiliary Time Stamp 1 LSB value (defined in ns units).
Zero 31:30 0x0 Zero bits.
Ethernet Controller I210 — Programming Interface
472
8.15.23 Auxiliary Time Stamp 1 Register High - AUXSTMPH1 (0xB668;
RO)
Reading this register releases the value stored in AUXSTMPH/L1 and enables timestamping of the next
value.
8.15.24 Time Sync RX Configuration - TSYNCRXCFG (0x5F50; R/W)
8.15.25 Time Sync SDP Configuration Register - TSSDP (0x003C; R/W)
This register defines the assignment of SDP pins to the time sync auxiliary capabilities.
Field Bit(s) Initial Value Description
TSTH 31:0 0x0 Auxiliary Time Stamp 1 MSB value (defined in second units).
Field Bit(s) Initial Value Description
CTRLT 7:0 0x0 V1 control to timestamp.
MSGT 15:8 0x0 V2 Message Type to timestamp.
Reserved 31:16 0x0 Reserved.
Write 0x0, ignore on read.
Field Bit(s) Initial Value Description
AUX0_SDP_SEL 1:0 00b
Select one of the SDPs to serve as the trigger for auxiliary time stamp 0
(AUXSTMPL0 and AUXSTMPH0 registers).
00b = SDP0 is assigned.
01b = SDP1 is assigned.
10b = SDP2 is assigned.
11b = SDP3 is assigned.
AUX0_TS_SDP_EN 2 0b When set indicates that one of the SDPs can be used as an external trigger to
Aux timestamp 0 (note that if this bit is set to one of the SDP pins, the
corresponding pin should be configured to input mode using SPD_DIR).
AUX1_SDP_SEL 4:3 00b
Select one of the SDPs to serve as the trigger for auxiliary time stamp 1 (in
AUXSTMPL1 and AUXSTMPH1 registers).
00b = SDP0 is assigned.
01b = SDP1 is assigned.
10b = SDP2 is assigned.
11b = SDP3 is assigned.
AUX1_TS_SDP_EN 5 0b When set indicates that one of the SDPs can be used as an external trigger to
Aux timestamp 1 (note that if this bit is set to one of the SDP pins, the
corresponding pin should be configured to input mode using SPD_DIR).
TS_SDP0_SEL 7:6 00b
SDP0 allocation to Tsync event – when TS_SDP0_EN is set, these bits select the
Tsync event that is routed to SDP0.
00b = Target time 0 is output on SDP0.
01b = Target time 1 is output on SDP0.
10b = Freq clock 0 is output on SDP0.
11b = Freq clock 1 is output on SDP0.
TS_SDP0_EN 8 0b When set indicates that SDP0 is assigned to Tsync.
Programming Interface — Ethernet Controller I210
473
8.16 Time Sync Interrupt Registers
8.16.1 Time Sync Interrupt Cause Register - TSICR (0xB66C; RC/W1C)
Note: Once ICR.Time_Sync is set, the internal value of this register should be cleared by writing 1b
to all bits or cleared by a read to enable receiving an additional ICR.Time_Sync interrupt.
TS_SDP1_SEL 10:9 00b
SDP1 allocation to Tsync event – when TS_SDP1_EN is set, these bits select the
Tsync event that is routed to SDP1.
00b = Target time 0 is output on SDP1.
01b = Target time 1 is output on SDP1.
10b = Freq clock 0 is output on SDP1.
11b = Freq clock 1 is output on SDP1.
TS_SDP1_EN 11 0b When set indicates that SDP1 is assigned to Tsync.
TS_SDP2_SEL 13:12 00b
SDP2 allocation to Tsync event – when TS_SDP2_EN is set, these bits select the
Tsync event that is routed to SDP2.
00b = Target time 0 is output on SDP2.
01b = Target time 1 is output on SDP2.
10b = Freq clock 0 is output on SDP2.
11b = Freq clock 1 is output on SDP2.
TS_SDP2_EN 14 0b When set indicates that SDP2 is assigned to Tsync.
TS_SDP3_SEL 16:15 00b
SDP3 allocation to Tsync event – when TS_SDP3_EN is set, these bits select the
Tsync event that is routed to SDP3.
00b = Target time 0 is output on SDP3.
01b = Target time 1 is output on SDP3.
10b = Freq clock 0 is output on SDP3.
11b = Freq clock 1 is output on SDP3.
TS_SDP3_EN 17 0b When set indicates that SDP3 is assigned to Tsync.
Reserved 31:18 0x0 Reserved.
Write 0x0, ignore on read.
Field Bit(s) Initial Value Description
SYS WARP 0 0b SYSTIM Warp around.
Set when SYSTIML This event should happen every second.
TXTS 1 0b Transmit Timestamp.
Set when new timestamp is loaded into TXSTMP register.
RXTS 2 0b Receive Timestamp.
Set when new timestamp is loaded into RXSTMP register.
TT0 3 0b
Target Time 0 Trigger.
Set when target time 0 (TRGTTIML/H0) trigger occurs. This interrupt is
enabled only if the EN_TT0 flag in the TSAUXC register is set. Note that this
interrupt cause is set also by CLK0 output which is based on TRGTTIM0.
TT1 4 0b
Target Time 1 Trigger.
Set when target time 1 (TRGTTIML/H1) trigger occurs. This interrupt is
enabled only if the EN_TT1 flag in the TSAUXC register is set. Note that this
interrupt cause is set also by CLK1 output which is based on TRGTTIM1.
AUTT0 5 0b
Auxiliary Timestamp 0 Taken.
Set when new timestamp is loaded into AUXSTMP 0 (auxiliary timestamp
0) register.
Field Bit(s) Initial Value Description
Ethernet Controller I210 — Programming Interface
474
8.16.2 Time Sync Interrupt Mask Register - TSIM (0xB674; RW)
8.17 PCS Register Descriptions
These registers are used to configure the SerDes, SGMII and 1000BASE-KX PCS logic. Usage of these
registers is described in Section 3.7.4.1 and Section 3.7.4.3.
AUTT1 6 0b
Auxiliary Timestamp 1 Taken.
Set when new timestamp is loaded into AUXSTMP 1 (auxiliary timestamp
1) register.
TADJ 7 0b Time Adjust Done.
Set when time adjust-to-SYSTIM completes.
Reserved 31:8 0x0 Reserved.
Write 0x0, ignore on read.
Field Bit(s) Initial Value Description
SYS WARP 0 0b
SYSTIM Warp Around Mask.
0b = No interrupt generated when TSICR.SWARP is set.
1b= Interrupt generated when TSICR.SWARP is set.
TXTS 1 0b
Transmit Timestamp Mask.
0b = No interrupt generated when TSICR.TXTS is set.
1b= Interrupt generated when TSICR.TXTS is set.
RXTS 2 0b
Receive Timestamp Mask.
0b = No interrupt generated when TSICR.RXTS is set.
1b= Interrupt generated when TSICR.RXTS is set.
TT0 3 0b
Target time 0 Trigger Mask.
0b = No interrupt generated when TSICR.TT0 is set.
1b= Interrupt generated when TSICR.TT0 is set.
TT1 4 0b
Target time 1 Trigger Mask.
0b = No interrupt generated when TSICR.TT1 is set.
1b= Interrupt generated when TSICR.TT1 is set.
AUTT0 5 0b
Auxiliary Timestamp 0 Taken Mask.
0b = No interrupt generated when TSICR.AUTT0 is set.
1b= Interrupt generated when TSICR.AUTT0 is set.
AUTT1 6 0b
Auxiliary Timestamp 1 Taken Mask.
0b = No interrupt generated when TSICR.AUTT1 is set.
1b = Interrupt generated when TSICR.AUTT1 is set.
TADJ 7 0b
Time Adjust 0 Done Mask.
0b = No interrupt generated when TSICR.TADJ is set.
1b = Interrupt generated when TSICR.TADJ is set.
Reserved 31:8 0x0 Reserved.
Write 0x0, ignore on read.
Field Bit(s) Initial Value Description
Programming Interface — Ethernet Controller I210
475
8.17.1 PCS Configuration - PCS_CFG (0x4200; R/W)
8.17.2 PCS Link Control - PCS_LCTL (0x4208; RW)
Field Bit(s) Initial Value Description
Reserved 2:0 0x0 Reserved.
Write 0x0, ignore on read.
PCS Enable 3 1b
PCS Enable.
Enables the PCS logic of the MAC. Should be set in SGMII, 1000BASE-KX and SerDes
mode for normal operation.
Clearing this bit disables Rx/Tx of both data and control codes. Use this to force link
down at the far end.
Reserved 29:4 0x0 Reserved.
Write 0x0, ignore on read.
PCS Isolate 30 0b
PCS Isolate.
Setting this bit isolates the PCS logic from the MAC's data path. PCS control codes are
still sent and received.
SRESET 31 0b
Soft Reset.
Setting this bit puts all modules within the MAC in reset except the Host Interface.
The Host Interface is reset via HRST. This bit is NOT self clearing; GMAC is in a reset
state until this bit is cleared.
Field Bit(s) Initial Value Description
FLV 0 0b
Forced Link Value.
This bit denotes the link condition when force link is set.
0b = Forced link down.
1b = Forced link up.
FSV 2:1 10b
Forced Speed Value.
These bits denote the speed when force speed and duplex (PCS_LCTL.FSD) bit is set.
This value is also used when AN is disabled or when in SerDes mode.
00b = 10 Mb/s (SGMII).
01b = 100 Mb/s (SGMII).
10b = 1000 Mb/s (SerDes/SGMII/1000BASE-KX).
11b = Reserved.
FDV 3 1b
Forced Duplex Value.
This bit denotes the duplex mode when force speed and duplex (PCS_LCTL.FSD) bit is
set. This value is also used when AN is disabled or when in SerDes mode.
1b = Full duplex (SerDes/SGMII/1000BASE-KX).
0b = Half duplex (SGMII).
FSD 4 0b
Force Speed and Duplex.
If this bit is set, then speed and duplex mode is forced to forced speed value and
forced duplex value, respectively. Otherwise, speed and duplex mode are decided by
internal AN/SYNC state machines.
Force Link 5 0b
Force Link.
If this bit is set, then the internal LINK_OK variable is forced to forced link value (bit 0
of this register).
Otherwise, LINK_OK is decided by internal AN/SYNC state machines.
LINK LATCH
LOW (LL) 6 0b
Link Latch Low Enable.
If this bit is set, then link OK going LOW (negative edge) is latched until a processor
read. Afterwards, link OK is continuously updated until link OK again goes LOW
(negative edge is seen).
Ethernet Controller I210 — Programming Interface
476
8.17.3 PCS Link Status - PCS_LSTS (0x420C; RO)
Force Flow
Control 7 0b
0b = Flow control mode is set according to the AN process by following Table 37-4 in
the IEEE 802.3 specification.
1b = Flow control is set according to FC_TX_EN / FC_RX_EN bits in CTRL register.
Reserved 15:8 0x0 Reserved.
Write 0x0, ignore on read.
AN_ENABLE 16 0b1
AN Enable.
Setting this bit enables the AN process in SerDes operating mode.
Note: When link-up is forced (CTRL.SLU=1b) the AN_ENABLE bit should be 0b.
AN RESTART
(SC) 17 0b
AN Restart.
Used to reset/restart the link auto-negotiation process when using SerDes mode.
Setting this bit restarts the auto-negotiation process.
This bit is self clearing.
AN TIMEOUT
EN 18 1b1
AN Timeout Enable.
This bit enables the AN timeout feature. During AN, if the link partner does not respond
with AN pages, but continues to send good IDLE symbols, then LINK UP is assumed.
(This enables LINK UP condition when link partner is not AN-capable and does not
affect otherwise).
This bit should not be set in SGMII mode.
AN SGMII
BYPASS 19 0b
AN SGMII Bypass.
If this bit is set, then IDLE detect state is bypassed during AN in SGMII mode. This
reduces the acknowledge time in SGMII mode.
AN SGMII
TRIGGER 20 1b
AN SGMII Trigger.
If this bit is cleared, then AN is not automatically triggered in SGMII mode even if
SYNC fails. AN is triggered only in response to PHY messages or by a manual setting
like changing the AN Enable/Restart bits.
Reserved 23:21 0x0 Reserved.
Write 0x0, ignore on read.
FAST LINK
TIMER 24 0b Fast Link Timer.
AN timer is reduced if this bit is set.
LINK OK FIX
EN 25 1b Link OK Fix Enable.
Control for enabling/disabling LinkOK/SyncOK fix. Should be set for normal operation.
Reserved 31: 0x0 Reserved.
Write 0x0, ignore on read.
1. Bit loaded from Flash.
Field Bit(s) Initial Value Description
LINK OK 0 0b
Link OK.
This bit denotes the current link OK status.
0b = Link down.
1b = Link up/OK.
SPEED 2:1 10b
Speed.
This bit denotes the current operating speed.
00b = 10 Mb/s.
01b = 100 Mb/s.
10b = 1000 Mb/s.
11b = Reserved.
DUPLEX 3 1b
Duplex.
This bit denotes the current duplex mode.
1b = Full duplex.
0b = Half duplex.
Field Bit(s) Initial Value Description
Programming Interface — Ethernet Controller I210
477
8.17.4 AN Advertisement - PCS_ANADV (0x4218; R/W)
SYNC OK 4 0b Sync OK.
This bit indicates the current value of Sync OK from the PCS Sync state machine.
Reserved 15:5 0x0 Reserved.
Write 0x0, ignore on read.
AN
COMPLETE 16 0b
AN Complete.
This bit indicates that the AN process has completed.This bit is set when the AN
process reached the Link OK state. It is reset upon AN restart or reset. It is set even if
the AN negotiation failed and no common capabilities were found.
AN PAGE
RECEIVED 17 0b
AN Page Received.
This bit indicates that a link partner's page was received during an AN process.
This bit is cleared on reads.
AN
TIMEDOUT 18 0b AN Timed Out.
This bit indicates an AN process was timed out. Valid after the AN Complete bit is set.
AN REMOTE
FAULT 19 0b
AN Remote Fault.
This bit indicates that an AN page was received with a remote fault indication during
an AN process.
This bit cleared on reads.
AN ERROR
(RWM) 20 0B
AN Error.
This bit indicates that a AN error condition was detected in SerDes/SGMII mode. Valid
after the AN Complete bit is set.
AN error conditions:
SerDes mode: Both nodes not Full Duplex
SGMII mode: PHY is set to 1000 Mb/s Half Duplex mode.
Software can also force a AN error condition by writing to this bit (or can clear a
existing AN error condition).
This bit is cleared at the start of AN.
Reserved 31:21 0x0 Reserved.
Write 0x0, ignore on read.
Field Bit(s) Initial Value Description
Reserved 4:0 0x0 Reserved.
Write 0, ignore on read.
FDCAP 5 1b
Full Duplex.
Setting this bit indicates that the I210 is capable of full duplex operation. This bit
should be set to 1b for normal operation.
HDCAP (RO) 6 0b
Half Duplex.
This bit indicates that the I210 is capable of half duplex operation. This bit is tied to 0b
because the I210 does not support half duplex in SerDes mode.
ASM 8:7 00b1
Local PAUSE Capabilities.
The I210's PAUSE capability is encoded in this field.
00b = No PAUSE.
01b = Symmetric PAUSE.
10b = Asymmetric PAUSE to link partner.
11b = Both symmetric and asymmetric PAUSE to the I210.
Reserved 11:9 0x0 Reserved.
Write 0x0, ignore on read.
Field Bit(s) Initial Value Description
Ethernet Controller I210 — Programming Interface
478
8.17.5 Link Partner Ability - PCS_LPAB (0x421C; RO)
RFLT 13:12 00b
Remote Fault.
The I210's remote fault condition is encoded in this field. The I210 might indicate a
fault by setting a non-zero remote fault encoding and re-negotiating.
00b = No error, link OK.
01b = Link failure.
10b = Offline.
11b = Auto-negotiation error.
Reserved 14 0x0 Reserved.
Write 0x0, ignore on read.
NEXTP 15 0b
Next Page Capable.
The I210 asserts this bit to request a next page transmission.
The I210 clears this bit when no subsequent next pages are requested.
Reserved 31:16 0x0 Reserved.
1. Loaded from Flash word 0x0F, bits 13:12.
Field Bit(s) Initial Value Description
Reserved 4:0 0x0 Reserved.
LPFD 5 0b
LP Full Duplex (SerDes).
When set to 1b, the link partner is capable of full duplex operation. When set to 0b,
the link partner is not capable of full duplex mode.
This bit is reserved while in SGMII mode.
LPHD 6 0b
LP Half Duplex (SerDes).
When set to 1b, the link partner is capable of half duplex operation. When set to 0b,
the link partner is not capable of half duplex mode.
This bit is reserved while in SGMII mode.
LPASM 8:7 00b
LP ASMDR/LP PAUSE (SerDes).
The link partner's PAUSE capability is encoded in this field.
00b = No PAUSE.
01b = Symmetric PAUSE.
10b = Asymmetric PAUSE to link partner.
11b = Both symmetric and asymmetric PAUSE to the I210.
These bits are reserved while in SGMII mode.
Reserved 9 0b Reserved.
Write 0b, ignore on read.
SGMII SPEED 11:10 00b SerDes: Reserved.
Speed (SGMII): Speed indication from the PHY.
PRF 13:12 00b
LP Remote Fault (SerDes).
The link partner's remote fault condition is encoded in this field.
00b = No error, link OK.
10b = Link failure.
01b = Offline.
11b = Auto-negotiation error.
SGMII [13]: Reserved.
SGMII [12]: Duplex mode indication from the PHY.
Field Bit(s) Initial Value Description
Programming Interface — Ethernet Controller I210
479
8.17.6 Next Page Transmit - PCS_NPTX (0x4220; RW)
ACK 14 0b
Acknowledge (SerDes).
The link partner has acknowledged receiving a page.
SGMII: Reserved.
LPNEXTP 15 0b
LP Next Page Capable (SerDes).
The link partner asserts this bit to indicate its ability to accept next pages.
SGMII: Link OK indication from the PHY.
Reserved 31:16 0x0 Reserved.
Write 0x0, ignore on read.
Field Bit(s) Initial Value Description
CODE 10:0 0x0
Message/Unformatted Code Field.
The Message field is an 11-bit wide field that encodes 2048 possible messages. The
Unformatted Code field is an 11-bit wide field that might contain an arbitrary value.
TOGGLE 11 0b
Toggle.
This bit is used to ensure synchronization with the pink partner during next page
exchange. This bit always takes the opposite value of the Toggle bit in the previously
exchanged Link Code word. The initial value of the Toggle bit in the first next page
transmitted is the inverse of bit 11 in the base Link Code word and, therefore, can
assume a value of 0b or 1b. The Toggle bit is set as follows:
0b = Previous value of the transmitted Link Code word when 1b.
1b = Previous value of the transmitted Link Code word when 0b.
ACK2 12 0b
Acknowledge 2.
Used to indicate that a device has successfully received its Link Partners' Link Code
word.
PGTYPE 13 0b
Message/Unformatted Page.
This bit is used to differentiate a message page from an unformatted page. The
encoding is:
0b = Unformatted page.
1b = Message page.
Reserved 14 - Reserved.
Write 0b, ignore on read.
NXTPG 15 0b
Next Page.
Used to indicate whether or not this is the last next page to be transmitted. The
encoding is:
0b = Last page.
1b = Additional next pages follow.
Reserved 31:16 - Reserved.
Write 0x0, ignore on read.
Field Bit(s) Initial Value Description
Ethernet Controller I210 — Programming Interface
480
8.17.7 Link Partner Ability Next Page - PCS_LPABNP (0x4224; RO)
8.17.8 SFP I2C Command- I2CCMD (0x1028; R/W)
This register is used by software or firmware to read or write to the configuration registers in an SFP
module when either the CTRL_EXT.I2C Enabled or the CTRL_EXT.I2C over SDP Enabled bit is set to 1b.
Prior to write accessing this register, the I2C semaphore ownership must be taken, and released at the
end of the access sequence.
Note: According to the SFP specification, only reads are allowed from this interface; however, SFP
vendors also provide a writable register through this interface (for example, PHY registers).
As a result, write capability is also supported.
Field Bit(s) Initial Value Description
CODE 10:0 -
Message/Unformatted Code Field.
The Message field is an 11-bit wide field that encodes 2048 possible messages. The
Unformatted Code field is an 11-bit wide field that might contain an arbitrary value.
TOGGLE 11 -
Toggle.
This bit is used to ensure synchronization with the link partner during next page
exchange. This bit always takes the opposite value of the Toggle bit in the previously
exchanged Link Code word. The initial value of the Toggle bit in the first next page
transmitted is the inverse of bit 11 in the base Link Code word and, therefore, can
assume a value of 0b or 1b. The Toggle bit is set as follows:
0b = Previous value of the transmitted Link Code word when 1b.
1b = Previous value of the transmitted Link Code word when 0b.
ACK2 12 -
Acknowledge 2.
Used to indicate that a device has successfully received its Link Partners' Link Code
word.
MSGPG 13 -
Message Page.
This bit is used to differentiate a message page from an unformatted page. The
encoding is:
0b = Unformatted page.
1b = Message page.
ACK 14 - Acknowledge.
The link partner has acknowledged receiving a next page.
NXTPG 15 -
Next Page.
Used to indicate whether or not this is the last next page to be transmitted. The
encoding is:
0b = Last page.
1b = Additional Next Pages follow.
Reserved 31:16 - Reserved.
Write 0x0, ignore on read.
Programming Interface — Ethernet Controller I210
481
8.17.9 SFP I2C Parameters - I2CPARAMS (0x102C; R/W)
This register is used to set the parameters for the I2C access to the SFP module and to enable bit-
banging access to the I2C interface, when either the CTRL_EXT.I2C Enabled or the CTRL_EXT.I2C over
SDP Enabled bit is set to 1b. Prior to write accessing this register, the I2C semaphore ownership must
be taken, and released at the end of the access sequence.
Field Bit(s) Initial Value Description
DATA 15:0 X
Data.
In a Write command, software places the data bits and then the MAC shifts them out
to the I2C bus. In a Read command, the MAC reads these bits serially from the I2C bus
and then software reads them from this location.
Note: This field is read in byte order and not in word order.
REGADD 23:16 0x0 I2C Register Address.
For example, register 0, 1, 2... 255.
PHYADD 26:24 0x0
Device Address Bits 3 -1.
The actual address used is b{1010, PHYADD[2:0], 0}.
On power up, FW loads a default value from the PHY_ADD field in NVM Initialization
Control 4 (word 0x13).
OP 27 0b
Op-code.
0b = I2C write.
1b = I2C read.
Reset 28 0b
Reset Sequence.
If set, sends a reset sequence before the actual read or write.
This bit is self clearing.
A reset sequence is defined as nine consecutive stop conditions.
R 29 0b
Ready Bit.
Set to 1b by the I210 at the end of the I2C transaction. For example, indicates a read
or write completed.
Reset by a software write of a command.
I 30 0b
Interrupt Enable.
When set to 1b by software, it causes an interrupt to be asserted to indicate the end
of an I2C cycle (ICR.MDAC).
E 31 0b
Error.
This bit set is to 1b by hardware when it fails to complete an I2C read. Reset by a
software write of a command.
Note: Bit is valid only when Ready bit is set.
Field Bit(s) Initial Value Description
Write Time 4:0 110b
Write Time.
Defines the delay between a write access and the next access. The value is in
milliseconds. A value of zero is not valid.
Read Time 7:5 010b
Read Time.
Defines the delay between a read access and the next access. The value is in
microseconds. A value of Zero is not valid
I2CBB_EN 8 0b
I2C Bit-bang Enable.
If set, the I2C_CLK and I2C_DATA lines are controlled via the CLK, DATA and
DATA_OE_N fields of this register. Otherwise, they are controlled by the hardware
machine activated via the I2CCMD or MDIC registers.
CLK 9 0b I2C Clock.
While in bit-bang mode, controls the value driven on the I2C_CLK pad.
Ethernet Controller I210 — Programming Interface
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8.18 Statistics Register Descriptions
All Statistics registers reset when read. In addition, they stick at 0xFFFF_FFFF when the maximum
value is reached.
For the receive statistics it should be noted that a packet is indicated as received if it passes the I210's
filters and is placed into the packet buffer memory. A packet does not have to be transferred to host
memory in order to be counted as received.
Due to divergent paths between interrupt-generation and logging of relevant statistics counts, it might
be possible to generate an interrupt to the system for a noteworthy event prior to the associated
statistics count actually being incremented. This is extremely unlikely due to expected delays
associated with the system interrupt-collection and ISR delay, but might be observed as an interrupt
for which statistics values do not quite make sense. Hardware guarantees that any event noteworthy of
inclusion in a statistics count is reflected in the appropriate count within 1 s; a small time-delay prior
to a read of statistics might be necessary to avoid the potential for receiving an interrupt and observing
an inconsistent statistics count as part of the ISR.
8.18.1 CRC Error Count - CRCERRS (0x4000; RC)
Counts the number of receive packets with CRC errors. In order for a packet to be counted in this
register, it must pass address filtering and must be 64 bytes or greater (from <Destination Address>
through <CRC>, inclusively) in length. If receives are not enabled, then this register does not
increment.
DATA_OUT 10 0b
I2C_DATA.
While in bit-bang mode and when the DATA_OE_N field is zero, controls the value
driven on the I2C_DATA pad.
DATA_OE_N 11 0b
I2C_DATA_OE_N.
While in bit-bang mode, controls the direction of the I2C_DATA pad.
0b = Pad is output.
1b = Pad is input.
DATA_IN (RO) 12 X
I2C_DATA_IN.
Reflects the value of the I2C_DATA pad. While in bit-bang mode when the
DATA_OE_N field is zero, this field reflects the value set in the DATA_OUT field.
CLK_OE_N 13 0b
I2C Clock Output Enable.
While in bit-bang mode, controls the direction of the I2C_CLK pad.
0b = Pad is output.
1b = Pad is input.
CLK_IN (RO) 14 X
I2C Clock In Value.
Reflects the value of the I2C_CLK pad. While in bit-bang mode when the CLK_OE_N
field is zero, this field reflects the value set in the CLK_OUT field.
clk_stretch_dis 15 0b 0b = Enable slave clock stretching support in I2C access.
1b = Disable clock stretching support in I2C access.
Reserved 31:16 0x0 Reserved.
Write 0x0, ignore on read.
Field Bit(s) Initial Value Description
CEC 31:0 0x0 CRC Error Count.
Field Bit(s) Initial Value Description
Programming Interface — Ethernet Controller I210
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8.18.2 Alignment Error Count - ALGNERRC (0x4004; RC)
Counts the number of receive packets with alignment errors (the packet is not an integer number of
bytes in length). In order for a packet to be counted in this register, it must pass address filtering and
must be 64 bytes or greater (from <Destination Address> through <CRC>, inclusive) in length. If
receives are not enabled, then this register does not increment. This register is valid only in MII mode
during 10/100 Mb/s operation.
8.18.3 Symbol Error Count - SYMERRS (0x4008; RC)
Counts the number of symbol errors between reads. The count increases for every bad symbol
received, whether or not a packet is currently being received and whether or not the link is up. When
working in SerDes/SGMII/1000BASE-KX mode these statistics can be read from the SCVPC register.
8.18.4 RX Error Count - RXERRC (0x400C; RC)
Counts the number of packets received in which RX_ER was asserted by the PHY. In order for a packet
to be counted in this register, it must pass address filtering and must be 64 bytes or greater (from
<Destination Address> through <CRC>, inclusive) in length. If receives are not enabled, then this
register does not increment.
This register is not available in SerDes/SGMII/1000BASE-KX modes.
8.18.5 Missed Packets Count - MPC (0x4010; RC)
Counts the number of missed packets. Packets are missed when the receive FIFO has insufficient space
to store the incoming packet. This can be caused because of too few buffers allocated, or because there
is insufficient bandwidth on the PCI bus. Events setting this counter causes ICR.Rx Miss, the Receiver
Overrun interrupt, to be set. This register does not increment if receives are not enabled.
These packets are also counted in the Total Packets Received register as well as in Total Octets
Received register.
Field Bit(s) Initial Value Description
AEC 31:0 0x0 Alignment Error Count.
Field Bit(s) Initial Value Description
SYMERRS 31:0 0x0 Symbol Error Count.
Field Bit(s) Initial Value Description
RXEC 31:0 0x0 Rx Error Count
Field Bit(s) Initial Value Description
MPC 31:0 0x0 Missed Packets Count.
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8.18.6 Single Collision Count - SCC (0x4014; RC)
This register counts the number of times that a successfully transmitted packet encountered a single
collision. This register only increments if transmits are enabled (TCTL.EN is set) and the I210 is in half-
duplex mode.
8.18.7 Excessive Collisions Count - ECOL (0x4018; RC)
When 16 or more collisions have occurred on a packet, this register increments, regardless of the value
of collision threshold. If collision threshold is set below 16, this counter won’t increment. This register
only increments if transmits are enabled (TCTL.EN is set) and the I210 is in half-duplex mode.
8.18.8 Multiple Collision Count - MCC (0x401C; RC)
This register counts the number of times that a transmit encountered more than one collision but less
than 16. This register only increments if transmits are enabled (TCTL.EN is set) and the I210 is in half-
duplex mode.
8.18.9 Late Collisions Count - LATECOL (0x4020; RC)
Late collisions are collisions that occur after one slot time. This register only increments if transmits are
enabled (TCTL.EN is set) and the I210 is in half-duplex mode.
8.18.10 Collision Count - COLC (0x4028; RC)
This register counts the total number of collisions seen by the transmitter. This register only increments
if transmits are enabled (TCTL.EN is set) and the I210 is in half-duplex mode.
Field Bit(s) Initial Value Description
SCC 31:0 0x0 Number of times a transmit encountered a single collision.
Field Bit(s) Initial Value Description
ECC 31:0 0x0 Number of packets with more than 16 collisions.
Field Bit(s) Initial Value Description
MCC 31:0 0x0 Number of times a successful transmit encountered multiple collisions.
Field Bit(s) Initial Value Description
LCC 31:0 0x0 Number of packets with late collisions.
Field Bit(s) Initial Value Description
CCC 31:0 0x0 Total number of collisions experienced by the transmitter.
Programming Interface — Ethernet Controller I210
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8.18.11 Defer Count - DC (0x4030; RC)
This register counts defer events. A defer event occurs when the transmitter cannot immediately send
a packet due to the medium being busy either because another device is transmitting, the IPG timer
has not expired, half-duplex deferral events, reception of XOFF frames, or the link is not up. This
register only increments if transmits are enabled (TCTL.EN is set). This counter does not increment for
streaming transmits that are deferred due to TX IPG.
8.18.12 Transmit with No CRS - TNCRS (0x4034; RC)
This register counts the number of successful packet transmissions in which the CRS input from the PHY
was not asserted within one slot time of start of transmission from the MAC. Start of transmission is
defined as the assertion of TX_EN to the PHY.
The PHY should assert CRS during every transmission. This register only increments if transmits are
enabled (TCTL.EN is set). This register is not valid in SGMII mode, in full-duplex mode, and in 100 Mbps
half-duplex mode .
8.18.13 Host Transmit Discarded Packets by MAC Count - HTDPMC
(0x403C; RC)
This register counts the number of packets sent by the host (and not the manageability engine) that
are dropped by the MAC. This can include packets dropped because of excessive collisions or link fail
events.
8.18.14 Receive Length Error Count - RLEC (0x4040; RC)
This register counts receive length error events. A length error occurs if an incoming packet passes the
filter criteria but is undersized or oversized. Packets less than 64 bytes are undersized. Packets over
1518, 1522 or 1526 bytes (according to the number of VLAN tags present) are oversized if Long Packet
Enable (RCTL.LPE) is 0b. If LPE is 1b, then an incoming, packet is considered oversized if it exceeds the
size defined in RLPML.RLPML field.
If receives are not enabled, this register does not increment. These lengths are based on bytes in the
received packet from <Destination Address> through <CRC>, inclusive. Packets sent to the
manageability engine are included in this counter.
Note: Runt packets smaller than 25 bytes may not be counted by this counter.
Field Bit(s) Initial Value Description
CDC 31:0 0x0 Number of defer events.
Field Bit(s) Initial Value Description
TNCRS 31:0 0x0 Number of transmissions without a CRS assertion from the PHY.
Field Bit(s) Initial Value Description
HTDPMC 31:0 0x0 Number of packets sent by the host but discarded by the MAC.
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8.18.15 XON Received Count - XONRXC (0x4048; RC)
This register counts the number of valid XON packets received. XON packets can use the global
address, or the station address. This register only increments if receives are enabled (RCTL.RXEN is
set).
8.18.16 XON Transmitted Count - XONTXC (0x404C; RC)
This register counts the number of XON packets transmitted. These can be either due to a full queue or
due to software initiated action (using TCTL.SWXOFF). This register only increments if transmits are
enabled (TCTL.EN is set).
8.18.17 XOFF Received Count - XOFFRXC (0x4050; RC)
This register counts the number of valid XOFF packets received. XOFF packets can use the global
address or the station address. This register only increments if receives are enabled (RCTL.RXEN is
set).
8.18.18 XOFF Transmitted Count - XOFFTXC (0x4054; RC)
This register counts the number of XOFF packets transmitted. These can be either due to a full queue or
due to software initiated action (using TCTL.SWXOFF). This register only increments if transmits are
enabled (TCTL.EN is set).
8.18.19 FC Received Unsupported Count - FCRUC (0x4058; RC)
This register counts the number of unsupported flow control frames that are received.
Field Bit(s) Initial Value Description
RLEC 31:0 0x0 Number of packets with receive length errors.
Field Bit(s) Initial Value Description
XONRXC 31:0 0x0 Number of XON packets received.
Field Bit(s) Initial Value Description
XONTXC 31:0 0x0 Number of XON packets transmitted.
Field Bit(s) Initial Value Description
XOFFRXC 31:0 0x0 Number of XOFF packets received.
Field Bit(s) Initial Value Description
XOFFTXC 31:0 0x0 Number of XOFF packets transmitted.
Programming Interface — Ethernet Controller I210
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The FCRUC counter increments when a flow control packet is received that matches either the reserved
flow control multicast address (in the FCAH/L register) or the MAC station address, and has a matching
flow control type field match (value in the FCT register), but has an incorrect op-code field. This register
only increments if receives are enabled (RCTL.RXEN is set).
Note: When the RCTL.PMCF bit is set to 1b then the FCRUC counter increments after receiving
packets that don’t match standard address filtering.
8.18.20 Packets Received [64 Bytes] Count - PRC64 (0x405C; RC)
This register counts the number of good packets received that are exactly 64 bytes (from <Destination
Address> through <CRC>, inclusive) in length. Packets that are counted in the Missed Packet Count
register are not counted in this register. Packets sent to the manageability engine are included in this
counter. This register does not include received flow control packets and increments only if receives are
enabled (RCTL.RXEN is set).
8.18.21 Packets Received [65–127 Bytes] Count - PRC127 (0x4060; RC)
This register counts the number of good packets received that are 65-127 bytes (from <Destination
Address> through <CRC>, inclusive) in length. Packets that are counted in the Missed Packet Count
register are not counted in this register. Packets sent to the manageability engine are included in this
counter. This register does not include received flow control packets and increments only if receives are
enabled (RCTL.RXEN is set).
8.18.22 Packets Received [128–255 Bytes] Count - PRC255 (0x4064; RC)
This register counts the number of good packets received that are 128-255 bytes (from <Destination
Address> through <CRC>, inclusive) in length. Packets that are counted in the Missed Packet Count
register are not counted in this register. Packets sent to the manageability engine are included in this
counter. This register does not include received flow control packets and increments only if receives are
enabled (RCTL.RXEN is set).
Field Bit(s) Initial Value Description
FCRUC 31:0 0x0 Number of unsupported flow control frames received.
Field Bit(s) Initial Value Description
PRC64 31:0 0x0 Number of packets received that are 64 bytes in length.
Field Bit(s) Initial Value Description
PRC127 31:0 0x0 Number of packets received that are 65-127 bytes in length.
Field Bit(s) Initial Value Description
PRC255 31:0 0x0 Number of packets received that are 128-255 bytes in length.
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8.18.23 Packets Received [256–511 Bytes] Count - PRC511 (0x4068; RC)
This register counts the number of good packets received that are 256-511 bytes (from <Destination
Address> through <CRC>, inclusive) in length. Packets that are counted in the Missed Packet Count
register are not counted in this register. Packets sent to the manageability engine are included in this
counter. This register does not include received flow control packets and increments only if receives are
enabled (RCTL.RXEN is set).
8.18.24 Packets Received [512–1023 Bytes] Count - PRC1023 (0x406C;
RC)
This register counts the number of good packets received that are 512-1023 bytes (from <Destination
Address> through <CRC>, inclusive) in length. Packets that are counted in the Missed Packet Count
register are not counted in this register. Packets sent to the manageability engine are included in this
counter. This register does not include received flow control packets and increments only if receives are
enabled (RCTL.RXEN is set).
8.18.25 Packets Received [1024 to Max Bytes] Count - PRC1522
(0x4070; RC)
This register counts the number of good packets received that are from 1024 bytes to the maximum
(from <Destination Address> through <CRC>, inclusive) in length. The maximum is dependent on the
current receiver configuration (for example, RCTL.LPE, etc.) and the type of packet being received. If a
packet is counted in Receive Oversized Count, it is not counted in this register (refer to
Section 8.18.37). This register does not include received flow control packets and only increments if the
packet has passed address filtering and receives are enabled (RCTL.RXEN is set). Packets sent to the
manageability engine are included in this counter.
Due to changes in the standard for maximum frame size for VLAN tagged frames in 802.3, the I210
accepts packets that have a maximum length of 1522 bytes. The RMON statistics associated with this
range has been extended to count 1522 byte long packets. If CTRL_EXT.EXT_VLAN is set, packets up to
1526 bytes are counted by this counter.
8.18.26 Good Packets Received Count - GPRC (0x4074; RC)
This register counts the number of good packets received of any legal length. The legal length for the
received packet is defined by the value of Long Packet Enable (RCTL.LPE) (refer to Section 8.18.37).
This register does not include received flow control packets and only counts packets that pass filtering.
This register only increments if receives are enabled (RCTL.RXEN is set). This register does not count
packets counted by the Missed Packet Count (MPC) register. Packets sent to the manageability engine
(MNGPRC) or dropped by the VMDq queueing process (SDPC) are included in this counter.
Field Bit(s) Initial Value Description
PRC511 31:0 0x0 Number of packets received that are 256-511 bytes in length.
Field Bit(s) Initial Value Description
PRC1023 31:0 0x0 Number of packets received that are 512-1023 bytes in length.
Field Bit(s) Initial Value Description
PRC1522 31:0 0x0 Number of packets received that are 1024-Max bytes in length.
Programming Interface — Ethernet Controller I210
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Note: GPRC can count packets interrupted by a link disconnect although they have a CRC error.
8.18.27 Broadcast Packets Received Count - BPRC (0x4078; RC)
This register counts the number of good (no errors) broadcast packets received. This register does not
count broadcast packets received when the broadcast address filter is disabled. This register only
increments if receives are enabled (RCTL.RXEN is set). This register does not count packets counted by
the Missed Packet Count (MPC) register. Packets sent to the manageability engine (MNGPRC) or
dropped by the VMDq queueing process (SDPC) are included in this counter.
8.18.28 Multicast Packets Received Count - MPRC (0x407C; RC)
This register counts the number of good (no errors) multicast packets received. This register does not
count multicast packets received that fail to pass address filtering nor does it count received flow
control packets. This register only increments if receives are enabled (RCTL.RXEN is set). This register
does not count packets counted by the Missed Packet Count (MPC) register. Packets sent to the
manageability engine (MNGPRC) or dropped by the VMDq queueing process (SDPC) are included in this
counter.
8.18.29 Good Packets Transmitted Count - GPTC (0x4080; RC)
This register counts the number of good (no errors) packets transmitted. A good transmit packet is
considered one that is 64 or more bytes in length (from <Destination Address> through <CRC>,
inclusively) in length. This does not include transmitted flow control packets. This register only
increments if transmits are enabled (TCTL.EN is set).
8.18.30 Good Octets Received Count - GORCL (0x4088; RC)
These registers make up a 64-bit register that counts the number of good (no errors) octets received.
This register includes bytes received in a packet from the <Destination Address> field through the
<CRC> field, inclusive; GORCL must be read before GORCH.
In addition, it sticks at 0xFFFF_FFFF_FFFF_FFFF when the maximum value is reached. Only octets of
packets that pass address filtering are counted in this register. This register does not count octets of
packets counted by the Missed Packet Count (MPC) register. Octets of packets sent to the
manageability engine are included in this counter. This register only increments if receives are enabled
(RCTL.RXEN is set).
Field Bit(s) Initial Value Description
GPRC 31:0 0x0 Number of good packets received (of any length).
Field Bit(s) Initial Value Description
BPRC 31:0 0x0 Number of broadcast packets received.
Field Bit(s) Initial Value Description
MPRC 31:0 0x0 Number of multicast packets received.
Field Bit(s) Initial Value Description
GPTC 31:0 0x0 Number of good packets transmitted.
Ethernet Controller I210 — Programming Interface
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These octets do not include octets of received flow control packets.
8.18.31 Good Octets Received Count - GORCH (0x408C; RC)
8.18.32 Good Octets Transmitted Count - GOTCL (0x4090; RC)
These registers make up a 64-bit register that counts the number of good (no errors) packets
transmitted. This register must be accessed using two independent 32-bit accesses; GOTCL must be
read before GOTCH.
In addition, it sticks at 0xFFFF_FFFF_FFFF_FFFF when the maximum value is reached. This register
includes bytes transmitted in a packet from the <Destination Address> field through the <CRC> field,
inclusive. This register counts octets in successfully transmitted packets that are 64 or more bytes in
length. This register only increments if transmits are enabled (TCTL.EN is set).
These octets do not include octets in transmitted flow control packets.
8.18.33 Good Octets Transmitted Count - GOTCH (0x4094; RC)
8.18.34 Receive No Buffers Count - RNBC (0x40A0; RC)
This register counts the number of times that frames were received when there were no available
buffers in host memory to store those frames (receive descriptor head and tail pointers were equal).
The packet is still received if there is space in the FIFO. This register only increments if receives are
enabled (RCTL.RXEN is set).
Notes:
1. This register does not increment when flow control packets are received.
2. If a packet is replicated, this counter counts each of the packet that is dropped.
Field Bit(s) Initial Value Description
GORCL 31:0 0x0 Number of good octets received – lower 4 bytes.
Field Bit(s) Initial Value Description
GORCH 31:0 0x0 Number of good octets received – upper 4 bytes.
Field Bit(s) Initial Value Description
GOTCL 31:0 0x0 Number of good octets transmitted – lower 4 bytes.
Field Bit(s) Initial Value Description
GOTCH 31:0 0x0 Number of good octets transmitted – upper 4 bytes.
Field Bit(s) Initial Value Description
RNBC 31:0 0x0 Number of receive no buffer conditions.
Programming Interface — Ethernet Controller I210
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8.18.35 Receive Undersize Count - RUC (0x40A4; RC)
This register counts the number of received frames that passed address filtering, and were less than
minimum size (64 bytes from <Destination Address> through <CRC>, inclusive), and had a valid CRC.
This register only increments if receives are enabled (RCTL.RXEN is set). Packets sent to the
manageability engine are included in this counter.
Note: Runt packets smaller than 25 bytes cannot be counted by this counter.
8.18.36 Receive Fragment Count - RFC (0x40A8; RC)
This register counts the number of received frames that passed address filtering, and were less than
minimum size (64 bytes from <Destination Address> through <CRC>, inclusive), but had a bad CRC
(this is slightly different from the Receive Undersize Count register). This register only increments if
receives are enabled (RCTL.RXEN is set). Packets sent to the manageability engine are included in this
counter.
Note: Runt packets smaller than 25 bytes cannot be counted by this counter.
8.18.37 Receive Oversize Count - ROC (0x40AC; RC)
This register counts the number of received frames with valid CRC field that passed address filtering,
and were greater than maximum size. For definition of oversized packets, refer to Section 7.1.1.4.
If receives are not enabled, this register does not increment. These lengths are based on bytes in the
received packet from <Destination Address> through <CRC>, inclusive. Packets sent to the
manageability engine are included in this counter.
8.18.38 Receive Jabber Count - RJC (0x40B0; RC)
This register counts the number of received frames that passed address filtering, and were greater than
maximum size and had a bad CRC (this is slightly different from the Receive Oversize Count register).
For definition of oversized packets, refer to Section 7.1.1.4.
Field Bit(s) Initial Value Description
RUC 31:0 0x0 Number of receive undersize errors.
Field Bit(s) Initial Value Description
RFC 31:0 0x0 Number of receive fragment errors.
Field Bit(s) Initial Value Description
ROC 31:0 0x0 Number of receive oversize errors.
Ethernet Controller I210 — Programming Interface
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If receives are not enabled, this register does not increment. These lengths are based on bytes in the
received packet from <Destination Address> through <CRC>, inclusive. Packets sent to the
manageability engine are included in this counter.
8.18.39 Management Packets Received Count - MNGPRC (0x40B4; RC)
This register counts the total number of packets received that pass the management filters as
described in Section 10.3. Any packets with errors are not counted, except packets that are dropped
because the management receive FIFO is full.
Packets sent to both the host and the management interface are not counted by this counter.
8.18.40 Management Packets Dropped Count - MPDC (0x40B8; RC)
This register counts the total number of packets received that pass the management filters as
described in Section 10.3, that are dropped because the management receive FIFO is full. Management
packets include any packet directed to the manageability console (for example, MC and ARP packets).
8.18.41 Management Packets Transmitted Count - MNGPTC (0x40BC; RC)
This register counts the total number of transmitted packets originating from the manageability path.
8.18.42 BMC2OS Packets Sent by MC - B2OSPC (0x8FE0; RC)
This register counts the total number of transmitted packets sent from the manageability path that
were sent to host. This includes packets received by the host and packet dropped in the I210 due to
congestion conditions.
Counter is cleared when read by driver. Counter is also cleared by PCIe reset and Software reset. When
reaching maximum value counter does not wrap-around.
Field Bit(s) Initial Value Description
RJC 31:0 0x0 Number of receive jabber errors.
Field Bit(s) Initial Value Description
MNGPRC 31:0 0x0 Number of management packets received.
Field Bit(s) Initial Value Description
MPDC 31:0 0x0 Number of management packets dropped.
Field Bit(s) Initial Value Description
MPTC 31:0 0x0 Number of management packets transmitted.
Field Bit(s) Initial Value Description
B2OSPC 31:0 0x0 BMC2OS packets sent by MC.
Programming Interface — Ethernet Controller I210
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8.18.43 BMC2OS Packets Received by Host - B2OGPRC (0x4158;
RC)
This register counts the total number of packets originating from the MC that reached the host.
If a packet is replicated, this counter counts each replication of the packet.
The counter clears when read by the software device driver. The counter also clears by a PCIe reset and
software reset. When reaching the maximum, the value counter does not wrap-around.
8.18.44 OS2BMC Packets Received by MC - O2BGPTC (0x8FE4; RC)
This register counts the total number of packets originating from the host that reached the NC-SI
interface.
The counter clears when read by the software device driver. The counter also clears by a PCIe reset and
software reset. When reaching maximum value, the counter does not wrap-around.
8.18.45 OS2BMC Packets Transmitted by Host - O2BSPC (0x415C; RC)
This register counts the total number of packets originating from the function that were sent to the
manageability path. This includes packets received by the MC and packets dropped in the I210 due to
congestion conditions.
Packets are dropped due to security reasons. For example, anti spoofing is not counted by this counter.
The counter is cleared when read by software device driver. The counter is also cleared by PCIe reset
and software reset. When reaching a maximum value, the counter does not wrap-around.
8.18.46 Total Octets Received - TORL (0x40C0; RC)
These registers make up a logical 64-bit register that counts the total number of octets received. This
register must be accessed using two independent 32-bit accesses; TORL must be read before TORH.
This register sticks at 0xFFFF_FFFF_FFFF_FFFF when the maximum value is reached.
All packets received have their octets summed into this register, regardless of their length, whether
they are erred, or whether they are flow control packets. This register includes bytes received in a
packet from the <Destination Address> field through the <CRC> field, inclusive. This register only
increments if receives are enabled (RCTL.RXEN is set).
Note: Broadcast rejected packets are counted in this counter (as opposed to all other rejected
packets that are not counted).
Field Bit(s) Initial Value Description
B2OGPRC 31:0 0x0 BMC2OS packets received by host.
Field Bit(s) Initial Value Description
O2BGPTC 31:0 0x0 OS2BMC good packets transmitted count.
Field Bit(s) Initial Value Description
OS2BSPC 31:0 0x0 OS2BMC good packets transmit count.
Ethernet Controller I210 — Programming Interface
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8.18.47 Total Octets Received - TORH (0x40C4; RC)
8.18.48 Total Octets Transmitted - TOTL (0x40C8; RC)
These registers make up a 64-bit register that counts the total number of octets transmitted. This
register must be accessed using two independent 32-bit accesses; TOTL must be read before TOTH.
This register sticks at 0xFFFF_FFFF_FFFF_FFFF when the maximum value is reached.
All transmitted packets have their octets summed into this register, regardless of their length or
whether they are flow control packets. This register includes bytes transmitted in a packet from the
<Destination Address> field through the <CRC> field, inclusive.
Octets transmitted as part of partial packet transmissions (for example, collisions in half-duplex mode)
are not included in this register. This register only increments if transmits are enabled (TCTL.EN is set).
8.18.49 Total Octets Transmitted - TOTH (0x40CC; RC)
8.18.50 Total Packets Received - TPR (0x40D0; RC)
This register counts the total number of all packets received. All packets received are counted in this
register, regardless of their length, whether they have errors, or whether they are flow control packets.
This register only increments if receives are enabled (RCTL.RXEN is set).
Notes:
1. Broadcast rejected packets are counted in this counter (as opposed to all other rejected packets
that are not counted).
2. Runt packets smaller than 25 bytes cannot be counted by this counter.
3. TPR can count packets interrupted by a link disconnect although they have a CRC error.
Field Bit(s) Initial Value Description
TORL 31:0 0x0 Number of total octets received - lower 4 bytes.
Field Bit(s) Initial Value Description
TORH 31:0 0x0 Number of total octets received - upper 4 bytes.
Field Bit(s) Initial Value Description
TOTL 31:0 0x0 Number of total octets transmitted - lower 4 bytes.
Field Bit(s) Initial Value Description
TOTH 31:0 0x0 Number of total octets transmitted - upper 4 bytes.
Field Bit(s) Initial Value Description
TPR 31:0 0x0 Number of all packets received.
Programming Interface — Ethernet Controller I210
495
8.18.51 Total Packets Transmitted - TPT (0x40D4; RC)
This register counts the total number of all packets transmitted. All packets transmitted are counted in
this register, regardless of their length, or whether they are flow control packets.
Partial packet transmissions (collisions in half-duplex mode) are not included in this register. This
register only increments if transmits are enabled (TCTL.EN is set). This register counts all packets,
including standard packets, packets received over the SMBus, and packets generated by the PT
function.
8.18.52 Packets Transmitted [64 Bytes] Count - PTC64 (0x40D8; RC)
This register counts the number of packets transmitted that are exactly 64 bytes (from <Destination
Address> through <CRC>, inclusive) in length. Partial packet transmissions (collisions in half-duplex
mode) are not included in this register. This register does not include transmitted flow control packets
(which are 64 bytes in length). This register only increments if transmits are enabled (TCTL.EN is set).
This register counts all packets, including standard packets, packets received over the SMBus, and
packets generated by the PT function.
8.18.53 Packets Transmitted [65-127 Bytes] Count - PTC127 (0x40DC;
RC)
This register counts the number of packets transmitted that are 65-127 bytes (from <Destination
Address> through <CRC>, inclusive) in length. Partial packet transmissions (for example, collisions in
half-duplex mode) are not included in this register. This register only increments if transmits are
enabled (TCTL.EN is set). This register counts all packets, including standard packets, packets received
over the SMBus, and packets generated by the PT function.
8.18.54 Packets Transmitted [128-255 Bytes] Count - PTC255 (0x40E0;
RC)
This register counts the number of packets transmitted that are 128-255 bytes (from <Destination
Address> through <CRC>, inclusive) in length. Partial packet transmissions (collisions in half-duplex
mode) are not included in this register. This register only increments if transmits are enabled (TCTL.EN
is set). This register counts all packets, including standard packets, packets received over the SMBus,
and packets generated by the PT function.
Field Bit(s) Initial Value Description
TPT 31:0 0x0 Number of all packets transmitted.
Field Bit(s) Initial Value Description
PTC64 31:0 0x0 Number of packets transmitted that are 64 bytes in length.
Field Bit(s) Initial Value Description
PTC127 31:0 0x0 Number of packets transmitted that are 65-127 bytes in length.
Field Bit(s) Initial Value Description
PTC255 31:0 0x0 Number of packets transmitted that are 128-255 bytes in length.
Ethernet Controller I210 — Programming Interface
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8.18.55 Packets Transmitted [256-511 Bytes] Count - PTC511 (0x40E4;
RC)
This register counts the number of packets transmitted that are 256-511 bytes (from <Destination
Address> through <CRC>, inclusive) in length. Partial packet transmissions (for example, collisions in
half-duplex mode) are not included in this register. This register only increments if transmits are
enabled (TCTL.EN is set). This register counts all packets. Management packets must never be more
than 200 bytes.
8.18.56 Packets Transmitted [512-1023 Bytes] Count - PTC1023
(0x40E8; RC)
This register counts the number of packets transmitted that are 512-1023 bytes (from <Destination
Address> through <CRC>, inclusive) in length. Partial packet transmissions (for example, collisions in
half-duplex mode) are not included in this register. This register only increments if transmits are
enabled (TCTL.EN is set). This register counts all packets. Management packets must never be more
than 200 bytes.
8.18.57 Packets Transmitted [1024 Bytes or Greater] Count - PTC1522
(0x40EC; RC)
This register counts the number of packets transmitted that are 1024 or more bytes (from <Destination
Address> through <CRC>, inclusive) in length. Partial packet transmissions (for example, collisions in
half-duplex mode) are not included in this register. This register only increments if transmits are
enabled (TCTL.EN is set).
Due to changes in the standard for maximum frame size for VLAN tagged frames in 802.3, the I210
transmits packets that have a maximum length of 1522 bytes. The RMON statistics associated with this
range has been extended to count 1522 byte long packets. This register counts all packets.
Management packets must never be more than 200 bytes. If CTRL.EXT_VLAN is set, packets up to
1526 bytes are counted by this counter.
8.18.58 Multicast Packets Transmitted Count - MPTC (0x40F0; RC)
This register counts the number of multicast packets transmitted. This register does not include flow
control packets and increments only if transmits are enabled (TCTL.EN is set).
Field Bit(s) Initial Value Description
PTC511 31:0 0x0 Number of packets transmitted that are 256-511 bytes in length.
Field Bit(s) Initial Value Description
PTC1023 31:0 0x0 Number of packets transmitted that are 512-1023 bytes in length.
Field Bit(s) Initial Value Description
PTC1522 31:0 0x0 Number of packets transmitted that are 1024 or more bytes in length.
Field Bit(s) Initial Value Description
MPTC 31:0 0x0 Number of multicast packets transmitted.
Programming Interface — Ethernet Controller I210
497
8.18.59 Broadcast Packets Transmitted Count - BPTC (0x40F4; RC)
This register counts the number of broadcast packets transmitted. This register only increments if
transmits are enabled (TCTL.EN is set). This register counts all packets. Management packets must
never be more than 200 bytes.
8.18.60 Interrupt Assertion Count - IAC (0x4100; RC)
This counter counts the total number of LAN interrupts generated in the system. In case of MSI-X
systems, this counter reflects the total number of MSI-X messages that are emitted.
8.18.61 Rx Packets to Host Count - RPTHC (0x4104; RC)
8.18.62 EEE TX LPI Count - TLPIC (0x4148; RC)
This register counts EEE TX LPI entry events. A EEE TX LPI event occurs when the transmitter enters
EEE (IEEE802.3az) LPI state. This register only increments if transmits are enabled (TCTL.EN is set)
and Link Mode is internal Copper PHY (CTRL_EXT.LINK_MODE = 00b).
8.18.63 EEE RX LPI Count - RLPIC (0x414C; RC)
This register counts EEE RX LPI entry events. A EEE RX LPI event occurs when the receiver detects link
partner entry into EEE (IEEE802.3az) LPI state. This register only increments if receives are enabled
(RCTL.RXEN is set) and Link Mode is internal Copper PHY (CTRL_EXT.LINK_MODE = 00b).
Field Bit(s) Initial Value Description
BPTC 31:0 0x0 Number of broadcast packets transmitted count.
Field Bit(s) Initial Value Description
IAC 31:0 0x0 This is a count of all the LAN interrupt assertions that have occurred.
Field Bit(s) Initial Value Description
RPTHC 31:0 0x0 This is a count of all the received packets sent to the host.
Field Bit(s) Initial Value Description
ETLPIC 31:0 0x0 Number of EEE TX LPI events.
Field Bit(s) Initial Value Description
ERLPIC 31:0 0x0 Number of EEE RX LPI events.
Ethernet Controller I210 — Programming Interface
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8.18.64 Host Good Packets Transmitted Count-HGPTC (0x4118; RC)
This register counts the number of good (non-erred) packets transmitted sent by the host. A good
transmit packet is considered one that is 64 or more bytes in length (from <Destination Address>
through <CRC>, inclusively) in length. This does not include transmitted flow control packets or
packets sent by the manageability engine. This register only increments if transmits are enabled
(TCTL.EN is set).
8.18.65 Receive Descriptor Minimum Threshold Count-RXDMTC (0x4120;
RC)
This register counts the number of events where the number of descriptors in one of the Rx queues was
lower than the threshold defined for this queue.
8.18.66 Host Good Octets Received Count - HGORCL (0x4128; RC)
8.18.67 Host Good Octets Received Count - HGORCH (0x412C; RC)
These registers make up a logical 64-bit register that counts the number of good (non-erred) octets
received. This register includes bytes received in a packet from the <Destination Address> field
through the <CRC> field, inclusive. This register must be accessed using two independent 32-bit
accesses.; HGORCL must be read before HGORCH.
In addition, it sticks at 0xFFFF_FFFF_FFFF_FFFF when the maximum value is reached. Only packets that
pass address filtering are counted in this register. This register counts only octets of packets that
reached the host. The only exception is packets dropped by the DMA because of lack of descriptors in
one of the queues. These packets are included in this counter.
This register only increments if receives are enabled (RCTL.RXEN is set).
Field Bit(s) Initial Value Description
HGPTC 31:0 0x0 Number of good packets transmitted by the host.
Field Bit(s) Initial Value Description
RXDMTC 31:0 0x0 This is a count of the receive descriptor minimum threshold events.
Field Bit(s) Initial Value Description
HGORCL 31:0 0x0 Number of good octets received by host – lower 4 bytes.
Field Bit(s) Initial Value Description
HGORCH 31:0 0x0 Number of good octets received by host – upper 4 bytes.
Programming Interface — Ethernet Controller I210
499
8.18.68 Host Good Octets Transmitted Count - HGOTCL (0x4130; RC)
8.18.69 Host Good Octets Transmitted Count - HGOTCH (0x4134; RC)
These registers make up a logical 64-bit register that counts the number of good (non-erred) packets
transmitted. This register must be accessed using two independent 32-bit accesses. This register resets
each time the upper 32 bits are read (HGOTCH).
In addition, it sticks at 0xFFFF_FFFF_FFFF_FFFF when the maximum value is reached. This register
includes bytes transmitted in a packet from the <Destination Address> field through the <CRC> field,
inclusive. This register counts octets in successfully transmitted packets which are 64 or more bytes in
length. This register only increments if transmits are enabled (TCTL.EN is set).
These octets do not include octets in transmitted flow control packets or manageability packets.
8.18.70 Length Error Count - LENERRS (0x4138; RC)
Counts the number of receive packets with Length errors. For example, valid packets (no CRC error)
with a Length/Type field with a value smaller or equal to 1500 greater than the frame size. In order for
a packet to be counted in this register, it must pass address filtering and must be 64 bytes or greater
(from <Destination Address> through <CRC>, inclusive) in length. If receives are not enabled, then
this register does not increment.
8.18.71 SerDes/SGMII/KX Code Violation Packet Count - SCVPC
(0x4228; RW)
This register contains the number of code violation packets received. Code violation is defined as an
invalid received code in the middle of a packet.
Field Bit(s) Initial Value Description
HGOTCL 31:0 0x0 Number of good octets transmitted by host - lower 4 bytes.
Field Bit(s) Initial Value Description
HGOTCH 31:0 0x0 Number of good octets transmitted by host - upper 4 bytes.
Field Bit(s) Initial Value Description
LENERRS 31:0 0x0 Length error count.
Field Bit(s) Initial Value Description
CODEVIO 31:0 0x0
Code Violation Packet Count.
At any point of time this field specifies number of unknown protocol packets received.
Valid only in SGMII/SerDes/1000BASE-KX modes.
Ethernet Controller I210 — Programming Interface
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8.18.72 Management Full Buffer Drop Packet Count - MNGFBDPC
(0x4154; RC/W)
8.19 Statistical Counters
The I210 supports nine statistical counters per queue.
8.19.1 Per Queue Good Packets Received Count - PQGPRC (0x10010 +
n*0x100 [n=0...3]; RW)
This register counts the number of legal length good packets received in queue[n]. The legal length for
the received packet is defined by the value of Long Packet Enable (RCTL.LPE) (refer to
Section 8.18.37). This register does not include received flow control packets and only counts packets
that pass filtering. This register only increments if receive is enabled.
Note: PQGPRC might count packets interrupted by a link disconnect although they have a CRC error.
Unlike some other statistics registers that are not allocated per VM, this register is not cleared
on read. Furthermore, the register wraps around back to 0x0000 on the next increment when
reaching a value of 0xFFFF and then continues normal count operation.
8.19.2 Per Queue Good Packets Transmitted Count - PQGPTC (0x10014
+ n*0x100 [n=0...3]; RW)
This register counts the number of good (no errors) packets transmitted on queue[n]. A good transmit
packet is considered one that is 64 or more bytes in length (from <Destination Address> through
<CRC>, inclusively) in length. This does not include transmitted flow control packets. This register only
increments if transmits are enabled (TCTL.EN is set). This counter includes loopback packets or packets
later dropped by the MAC.
A multicast packet dropped by some of the destinations, but sent to others is counted by this counter
Note: Unlike some other statistic registers that are not allocated per VM, this register is not cleared
on read. Furthermore, the register wraps around back to 0x0000 on the next increment when
reaching a value of 0xFFFFFFFF and then continues normal count operation.
Field Bit(s) Initial Value Description
MNGFDPC 31:0 0x0
Management Buffer Full Drop Packet Count.
Counts the number of packets destined to management that were dropped due to lack
of space in the management buffer.
Note: The counter does not wrap around when reaching a value of 0xFFFFFFFF.
Field Bit(s) Initial Value Description
GPRC 31:0 0x0 Number of good packets received (of any length).
Field Bit(s) Initial Value Description
GPTC 31:0 0x0 Number of good packets transmitted.
Programming Interface — Ethernet Controller I210
501
8.19.3 Per Queue Good Octets Received Count - PQGORC (0x10018 +
n*0x100 [n=0...3]; RW)
This register counts the number of good (no errors) octets received on queue[n]. This register includes
bytes received in a packet from the <Destination Address> field through the <CRC> field, inclusive.
Only octets of packets that pass address filtering are counted in this register. This register only
increments if receive is enabled.
Note: VLAN tag is part of the byte count only if reported to the VM. For example, if the
DVMOLR.HIDE VLAN bit is not set for this VM. CRC is part of the byte count if DTXCTL.Count
CRC is set.
Note: Unlike some other statistic registers that are not allocated per VM, this register is not cleared
on read. Furthermore, the register wraps around back to 0x0000 on the next increment when
reaching a value of 0xFFFF and then continues normal count operation.
8.19.4 Per Queue Good Octets Transmitted Count - PQGOTC (0x10034 +
n*0x100 [n=0...3]; RW)
This register counts the number of good (no errors) packets transmitted on queue[n]. This register
includes bytes transmitted in a packet from the <Destination Address> field through the <CRC> field,
inclusive. Register also counts any padding that were added by the hardware. This register counts
octets in successfully transmitted packets that are 64 or more bytes in length. Octets counted do not
include octets in transmitted flow control packets. This register only increments if transmit is enabled.
A multicast packet dropped by some of the destinations, but sent to others is counted by this counter
Note: CRC is part of the byte count if DTXCTL.Count CRC is set.
Unlike some other statistic registers that are not allocated per VM, this register is not cleared
on read. Furthermore, the register wraps around back to 0x0000 on the next increment when
reaching a value of 0xFFFF and then continues normal count operation.
8.19.5 Per Queue Multicast Packets Received Count - PQMPRC (0x10038
+ n*0x100 [n=0...3]; RO)
This register counts the number of good (no errors) multicast packets received on queue[n]. This
register does not count multicast packets received that fail to pass address filtering nor does it count
received flow control packets. This register only increments if receive is enabled.
Note: Unlike some other statistic registers that are not allocated per VM, this register is not cleared
on read. Furthermore, the register wraps around back to 0x0000 on the next increment when
reaching a value of 0xFFFF and then continues normal count operation.
Field Bit(s) Initial Value Description
GORC 31:0 0x0 Number of good octets received.
Field Bit(s) Initial Value Description
GOTC 31:0 0x0 Number of good octets transmitted – lower 4 bytes.
Ethernet Controller I210 — Programming Interface
502
8.20 Manageability Statistics
This section describes a set of statistics counters used by the NC-SI interface and are not accessible to
the host driver.
8.20.1 MC Management Receive Packets Dropped Count - BMRPDC
(0x4140; RC)
This register counts the total number of packets received that pass the management filters as
described in Section 10.3, that are dropped because the management receive FIFO is full. Management
packets include any packet directed to the manageability console (for example, MC and ARP packets).
This register is available to the firmware only.
8.20.2 MC Management Transmit Packets Dropped Count - BMTPDC
(0x8FDC; RC)
This register counts the total number of packets received from the Out-of-Band Management interface,
that are dropped because the management transmit FIFO is full or if the relevant NC-SI channel is
disabled. This counter increases only if the packet is not sent to any destination (host or network).
Note: This register is available to firmware only and is shared for MC Tx traffic destined to the port.
8.20.3 MC Management Packets Transmitted Count - BMNGPTC
(0x4144; RC)
This register counts the total number of transmitted packets originating from the manageability path.
This counter increases once if the packet is sent to any destination (host or network).
This register is available to the firmware only.
Field Bit(s) Initial Value Description
MPRC 31:0 0x0 Number of multicast packets received.
Field Bit(s) Initial Value Description
MPDC 31:0 0x0 Number of management packets dropped.
Field Bit(s) Initial Value Description
BMTPDC 15:0 0x0 Number of management packets dropped.
Reserved 31:16 - Reserved.
Write 0x0, ignore on read.
Field Bit(s) Initial Value Description
MPTC 31:0 0x0 Number of management packets transmitted.
Programming Interface — Ethernet Controller I210
503
8.20.4 MC Management Packets Received Count - BMNGPRC (0x413C;
RC)
This register counts the total number of packets received that pass the management filters as
described in Section 10.3. Any packets with errors are not counted, except packets that are dropped
because the management receive FIFO is full.
This register is available to the firmware only.
8.20.5 MC Total Unicast Packets Received - BUPRC (0x4400; RC)
This register counts the number of good (no errors) unicast packets received. This register does not
count unicast packets received that fail to pass address filtering. This register does not count packets
counted by the Missed Packet Count (MPC) register. Packets sent to the manageability engine are
included in this counter.
This register is available to the firmware only.
8.20.6 MC Total Multicast Packets Received - BMPRC (0x4404; RC)
This register counts the same events as the MPRC register (Section 8.18.28) for the MC usage.This
register is available to the firmware only.
8.20.7 MC Total Broadcast Packets Received - BBPRC (0x4408; RC)
This register counts the same events as the BPRC register (Section 8.18.27) for the MC usage. This
register is available to the firmware only.
8.20.8 MC Total Unicast Packets Transmitted - BUPTC (0x440C; RC)
This register counts the number of unicast packets transmitted. This register is available to the
firmware only.
8.20.9 MC Total Multicast Packets Transmitted - BMPTC (0x4410; RC)
This register counts the same events as the MPTC register (Section 8.18.58) for the MC usage.This
register is available to the firmware only.
Field Bit(s) Initial Value Description
MNGPRC 31:0 0x0 Number of management packets received.
Field Bit(s) Initial Value Description
BUPRC 31:0 0x0 Number of Unicast packets received.
Field Bit(s) Initial Value Description
BUPTC 31:0 0x0 Number of unicast packets transmitted.
Ethernet Controller I210 — Programming Interface
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8.20.10 MC Total Broadcast Packets Transmitted - BBPTC (0x4414; RC)
This register counts the same events as the BPTC register (Section 8.18.59) for the MC usage. This
register is available to the firmware only.
8.20.11 MC FCS Receive Errors - BCRCERRS (0x4418; RC)
This register counts the same events as the CRCERRS register (Section 8.18.1) for the MC usage. This
register is available to the firmware only.
8.20.12 MC Alignment Errors - BALGNERRC (0x441C; RC)
This register counts the same events as the ALGNERRC register (Section 8.18.2) for the MC usage. This
register is available to the firmware only.
8.20.13 MC Pause XON Frames Received - BXONRXC (0x4420; RC)
This register counts the same events as the XONRXC register (Section 8.18.15) for the MC usage. This
register is available to the firmware only.
8.20.14 MC Pause XOFF Frames Received - BXOFFRXC (0x4424; RC)
This register counts the same events as the XOFFRXC register (Section 8.18.17) for the MC usage. This
register is available to the firmware only.
8.20.15 MC Pause XON Frames Transmitted - BXONTXC (0x4428; RC)
This register counts the same events as the XONTXC register (Section 8.18.16) for the MC usage. This
register is available to the firmware only.
8.20.16 MC Pause XOFF Frames Transmitted - BXOFFTXC (0x442C; RC)
This register counts the same events as the XOFFTXC register (Section 8.18.18) for the MC usage. This
register is available to the firmware only.
8.20.17 MC Single Collision Transmit Frames- BSCC (0x4430; RC)
This register counts the same events as the SCC register (Section 8.18.6) for the MC usage. This
register is available to the firmware only.
8.20.18 MC Multiple Collision Transmit Frames - BMCC (0x4434; RC)
This register counts the same events as the MCC register (Section 8.18.8) for the MC usage. This
register is available to the firmware only.
Programming Interface — Ethernet Controller I210
505
8.21 Wake Up Control Register Descriptions
8.21.1 Wake Up Control Register - WUC (0x5800; R/W)
The PME_En and PME_Status bits of this register are reset when LAN_PWR_GOOD is 0b. When
AUX_PWR = 0b, these register bits also reset by de-asserting PE_RST_N and during a D3 to D0
transition.
Field Bit(s) Initial Value Description
APME 0 0b1
1. Loaded from the Flash.
Advance Power Management Enable.
If set to 1b, APM Wakeup is enabled.
If this bit is set and the APMPME bit is cleared, reception of a magic packet asserts the
WUS.MAG bit but does not assert a PME.
Note: This bit is reset only on power-on reset but its value is auto-loaded from NVM on
PCIe reset.
PME_En 1 0b
PME_En.
This read/write bit is used by the software device driver to enable generation of a PME
event without writing to the Power Management Control / Status Register (PMCSR) in
the PCIe configuration space.
Note: This bit reflects the value of the PMCSR.PME_En bit when the bit in the PMCSR
register is modified. However, when the value of WUC.PME_En bit is modified by
software device driver, the value is not reflected in the PMCSR.PME_En bit.
Note: This bit is reset only on power-on reset When the AUX_PWR = 0b bit is also
reset on de-assertion of PE_RST_N and during D3 to D0 transition.
PME_Status (R/
W1C) 2 0b
PME_Status.
This bit is set when the I210 receives a wakeup event. It is the same as the PME_Status
bit in the Power Management Control / Status Register (PMCSR). Writing a 1b to this bit
clears also the PME_Status bit in the PMCSR.
Note: This bit is reset only on power-on reset When the AUX_PWR = 0b bit is also
reset on de-assertion of PE_RST_N and during D3 to D0 transition.
APMPME 3 0b1
Assert PME On APM Wakeup.
If set to 1b, the I210 sets the PME_Status bit in the Power Management Control / Status
Register (PMCSR) and asserts PE_WAKE_N and sends a PM_PME PCIe message when
APM Wakeup is enabled (WUC.APME = 1b) and the I210 receives a matching Magic
Packet.
Notes:
1. When WUC.APMPME is set PE_WAKE_N is asserted and a PM_PME message is sent
even if PMCSR.PME_En is cleared.
2. This bit is reset only on power-on reset but its value is auto-loaded from NVM on
SW reset.
PPROXYE 4 0b
Port Proxying Enable.
When set to 1b Proxying of packets is enabled when device is in D3 low power state.
Note: Proxy information and requirements is passed by the software device driver to
firmware via the shared RAM host interface (refer to Section 10.8, Section 8.23
and Section 10.8.2.4.5).
EN_APM_D0 5 0b1
Enable APM wake on D0.
0b = Enable APM wake only when function is in D3 and WUC.APME is set to 1b.
1b = Always enable APM wake when WUC.APME is set to 1b.
Note: This bit is reset on power on reset only.
Reserved 31:6 0x0 Reserved.
Write 0x0, ignore on read.
Ethernet Controller I210 — Programming Interface
506
8.21.2 Wakeup Filter Control Register - WUFC (0x5808; R/W)
This register is used to enable each of the pre-defined and flexible filters for wake-up support. A value
of 1b means the filter is turned on; A value of 0b means the filter is turned off.
If the NoTCO bit is set, then any packet that passes the manageability packet filtering as described in
Section 10.3, does not cause a wake-up event.
Field Bit(s) Initial Value Description
LNKC 0 0b Link Status Change Wakeup Enable.
MAG 1 0b Magic Packet Wake-up Enable.
EX 2 0b Directed Exact Wake-up Enable.1
MC 3 0b Directed Multicast Wake-up Enable.
BC 4 0b Broadcast Wake-up Enable.
ARP Directed 5 0b
ARP Request Packet and IP4AT Match Wake-up Enable.
Wake on match of any ARP request packet that passed main filtering and
Target IP address also matches one of the valid IP4AT filters.
IPv4 6 0b Directed IPv4 Packet Wake-up Enable.
IPv6 7 0b Directed IPv6 Packet Wake-up Enable.
Reserved 8 0b Reserved.
Write 0b, ignore on read.
NS 9 0b IPV6 Neighbor Solicitation Wake-up Enable.
Wake on match of any NS packet that passed main filtering.
NS Directed 10 0b
IPV6 Neighbor Solicitation and Directed DA Match Wake-up Enable.
Wake on match of NS packet and target IP address also matches IPV6AT
filter.
ARP 11 0b ARP Request Packet Wake-up Enable.
Wake on match of any ARP request packet that passed main filtering.
Reserved 13:12 0x0 Reserved.
Write 0x0, ignore on read.
FLEX_HQ 14 0b
Flex Filters Host Queuing
0b = Do not use flex filters for queueing decisions in D0 state.
1b = Use flex filters enabled in the WUFC register for queuing decisions in
D0 state.
Note: Should be enabled only when multi queueing is enabled
(MRQC.Multiple Receive Queues = 010b or 000b).
NoTCO 15 0b MPWU=criteriah=h.
FLX0 16 0b Flexible Filter 0 Enable.
FLX1 17 0b Flexible Filter 1 Enable.
FLX2 18 0b Flexible Filter 2 Enable.
FLX3 19 0b Flexible Filter 3 Enable.
FLX4 20 0b Flexible Filter 4 Enable.
FLX5 21 0b Flexible Filter 5 Enable.
FLX6 22 0b Flexible Filter 6 Enable.
FLX7 23 0b Flexible Filter 7 Enable.
FLX0_ACT 24 0b
Flexible Filter 0 Action.
0b= WoL.
1b= Reserved.
FLX1_ACT 25 0b
Flexible Filter 1 Action.
0b= WoL.
1b= Reserved.
Programming Interface — Ethernet Controller I210
507
8.21.3 Wake Up Status Register - WUS (0x5810; R/W1C)
This register is used to record statistics about all wake-up packets received. If a packet matches
multiple criteria then multiple bits could be set. Writing a 1b to any bit clears that bit.
This register is not cleared when PE_RST_N is asserted. It is only cleared when LAN_PWR_GOOD is de-
asserted or when cleared by the software device driver.
Note: If additional packets are received that match one of the wakeup filters, after the original
wake-up packet is received, the WUS register is not updated with the new match detection
until the register is cleared.
FLX2_ACT 26 0b
Flexible Filter 2 Action.
0b= WoL.
1b= Reserved.
FLX3_ACT 27 0b
Flexible Filter 3 Action.
0b= WoL.
1b= Reserved.
Reserved 30:28 0b Reserved.
FW_RST_WK 31 0b
Enable Wake on Firmware Reset Assertion.
When set, a firmware reset causes a system wake so that the software
driver can re-send proxying information to firmware.
1. If the RCTL.UPE is set, and the EX bit is also set, any unicast packet wakes up the system.
Field Bit(s) Initial Value Description
LNKC 0 0b Link Status Change.
MAG 1 0b Magic Packet Received.
EX 2 0b
Directed Exact Packet Received.
The packet’s address matched one of the 32 pre-programmed exact values in the
Receive Address registers (RAL[n]/RAH[n]), the packet was a unicast packet and
RCTL.UPE is set to 1b.
MC 3 0b
Directed Multicast Packet Received.
The packet was a multicast packet hashed to a value that corresponded to a 1 bit in
the Multicast Table Array (MTA) or the packet was a multicast packet and RCTL.MPE is
set to 1b.
BC 4 0b Broadcast Packet Received.
ARP Directed 5 0b
ARP Request Packet with IPVA4AT filter Received.
When set to 1b indicates a match on any ARP request packet that passed main filtering
and Target IP address also matches one of the valid IP4AT filters.
IPv4 6 0b Directed IPv4 Packet Received.
IPv6 7 0b Directed IPv6 Packet Received.
MNG 8 0b Indicates that a manageability event that should cause a PME happened.
NS 9 0b
IPV6 Neighbor Solicitation Received.
When set to 1b indicates a match on any ICMPv6 packet such as Neighbor Solicitation
(NS) packet or Multicast Listener Discovery (MLD) packet that passed main filtering.
NS Directed 10 0b
IPV6 Neighbor Solicitation with Directed DA Match Received.
When set to 1b, indicates a match on any ICMPv6 packet such as a NS packet or MLD
packet that passed main filtering and the field placed in the target IP address of a NS
packet (9th byte to 24th byte of the ICMPv6 header) also matches a valid IPV6AT filter.
ARP 11 0b
ARP Request Packet Received.
When set to 1b, indicates a match on an ARP request packet that passed main
filtering.
Field Bit(s) Initial Value Description
Ethernet Controller I210 — Programming Interface
508
Note: FLX0-7 bits are set only when flex filter match is detected and WUFC.FLEX_HQ is 0b.
8.21.4 Wake Up Packet Length - WUPL (0x5900; RO)
This register indicates the length of the first wake-up packet received. It is valid if one of the bits in the
Wakeup Status register (WUS) is set. It is not cleared by any reset.
8.21.5 Wake Up Packet Memory - WUPM (0x5A00 + 4*n [n=0...31]; RO)
This register is read-only and it is used to store the first 128 bytes of the wake up packet for software
retrieval after system wake up. It is not cleared by any reset.
8.21.6 Proxying Filter Control Register - PROXYFC (0x5F60; R/W)
This register is used to enable each of the pre-defined and flexible filters for proxying support. A value
of 1b means the filter is turned on. A value of 0b means the filter is turned off.
If the NoTCO bit is set, then any packet that passes the manageability packet filtering, as described in
Section 10.3, is not forwarded to management (i.e. firmware) for protocol offload even if it passes one
of the proxying filters.
Reserved 15:12 0x0 Reserved.
Write 0bx0, ignore on read.
FLX0 16 0b Flexible Filter 0 Match.
FLX1 17 0b Flexible Filter 1 Match.
FLX2 18 0b Flexible Filter 2 Match.
FLX3 19 0b Flexible Filter 3 Match.
FLX4 20 0b Flexible Filter 4 Match.
FLX5 21 0b Flexible Filter 5 Match.
FLX6 22 0b Flexible Filter 6 Match.
FLX7 23 0b Flexible Filter 7 Match.
Reserved 30:24 0x0 Reserved.
Write 0x0, ignore on read.
FW_RST_WK 31 0b
Wake Due to Firmware Reset Assertion Event.
When set to 1b, indicates that a firmware reset assertion caused the system wake so
that the software device driver can re-send proxying information to firmware.
Field Bit(s) Initial Value Description
LEN 11:0 X Length of Wake-up Packet. (If jumbo frames are enabled and the packet is longer
than 2047 bytes then this field is 2047.)
Reserved 31:12 0x0 Reserved.
Write 0x0, ignore on read.
Field Bit(s) Initial Value Description
WUPD 31:0 X Wakeup Packet Data.
Field Bit(s) Initial Value Description
Programming Interface — Ethernet Controller I210
509
Field Bit(s) Initial Value Description
D0_PROXY 0 0b
Enable Protocol Offload in D0.
0b = Enable protocol offload only when device is in D3 low power state.
1b = Enable protocol offload always.
Note: Protocol offload is enabled only when the WUC.PPROXYE and
MANC.MPROXYE bits are set to 1b.
Reserved 1 0b Reserved.
Write 0b, ignore on read.
EX 2 0b Directed Exact Proxy Enable.1
1. If the RCTL.UPE is set, and the EX bit is also set, any unicast packet is sent to management for proxying.
MC 3 0b Directed Multicast Proxy Enable.
BC 4 0b Broadcast Proxy Enable.
ARP Directed 5 0b
ARP Request Packet and IP4AT Match Proxy Enable.
If set to 1b forward to Management for proxying on match of any ARP
request packet that passed main filtering and Target IP address also
matches one of the valid IP4AT filters.
IPv4 6 0b Directed IPv4 Packet Proxy Enable.
IPv6 7 0b Directed IPv6 Packet Proxy Enable.
Reserved 8 0b Reserved.
Write 0b, ignore on read.
NS 9 0b
IPV6 Neighbor Solicitation Proxy Enable.
If set to 1b forward to management for proxying on match of any ICMPv6
packet such as a NS packet or MLD packet that passed main filtering.
NS Directed 10 0b
IPV6 Neighbor Solicitation and Directed DA Match Proxy Enable.
If set to 1b forward to Management for proxying on match of any ICMPv6
packet such as a NS packet or MLD packet that passed main filtering and
the field placed in the target IP address of a NS packet (9th byte to 24th
byte of the ICMPv6 header) also matches a valid IPV6AT filter.
ARP 11 0b
ARP Request Packet Proxy Enable.
If set to 1b, forwards to management for proxying on a match of any ARP
request packet that passed main filtering.
Reserved 14:12 0x0 Reserved.
Write 0x0, ignore on read.
NoTCO 15 0b
Ignore TCO/Management Packets for Proxying.
0b = Ignore only TCO/management packets for proxying that meet the
criteria defined in the MNGONLY register (intended only for the MC and not
the host).
1b = Ignore any TCO/management packets for proxying, even if in normal
operation it’s forwarded to the host in addition to the MC.
FLX0 16 0b Flexible Filter 0 Enable.
FLX1 17 0b Flexible Filter 1 Enable.
FLX2 18 0b Flexible Filter 2 Enable.
FLX3 19 0b Flexible Filter 3 Enable.
FLX4 20 0b Flexible Filter 4 Enable.
FLX5 21 0b Flexible Filter 5 Enable.
FLX6 22 0b Flexible Filter 6 Enable.
FLX7 23 0b Flexible Filter 7 Enable.
Reserved 31:24 0x0 Reserved.
Write 0x0, ignore on read.
Ethernet Controller I210 — Programming Interface
510
8.21.7 Proxying Status Register - PROXYS (0x5F64; R/W1C)
This register is used to record statistics about all proxying packets received. If a packet matches
multiple criteria then multiple bits could be set. Writing a 1b to any bit clears that bit.
This register is not cleared when PE_RST_N is asserted. It is only cleared when LAN_PWR_GOOD is de-
asserted or when cleared by the software device driver.
Note: If additional packets are received that matches one of the wake-up filters, after the original
wake-up packet is received, the PROXYS register is updated with the matching filters
accordingly.
Note: FLX0-7 bits are set only when flex filter match is detected and WUFC.FLEX_HQ is 0b.
Field Bit(s) Initial Value Description
Reserved 1:0 0x0 Reserved.
Write 0x0, ignore on read.
EX 2 0b
Directed Exact Packet Received.
The packet’s address matched one of the 32 pre-programmed exact values in the
Receive Address registers, the packet was a unicast packet and RCTL.UPE is set to 1b.
MC 3 0b
Directed Multicast Packet Received.
The packet was a multicast packet hashed to a value that corresponded to a 1 bit in
the Multicast Table Array or the packet was a multicast packet and RCTL.MPE is set to
1b.
BC 4 0b Broadcast Packet Received.
ARP Directed 5 0b
ARP Request Packet with IP4AT Filter Match Received.
When set to 1b indicates a match on any ARP request packet that passed main filtering
and Target IP address also matches one of the valid IP4AT filters.
IPv4 6 0b Directed IPv4 Packet Received.
IPv6 7 0b Directed IPv6 Packet Received.
Reserved 8 0b Reserved.
Write 0b, ignore on read.
NS 9 0b IPV6 Neighbor Solicitation Received.
When set to 1b, indicates a match on a NS packet that passed main filtering.
NS Directed 10 0b
IPV6 Neighbor Solicitation with Directed DA filter Match Received.
When set to 1b, indicates a match on a NS packet and target IP address that also
matches a valid IPV6AT filter.
ARP 11 0b
ARP Request Packet Received.
When set to 1b indicates a match on any ARP request packet that passed main
filtering.
Reserved 15:12 0x0 Reserved.
Write 0x0, ignore on read.
FLX0 16 0b Flexible Filter 0 Match.
FLX1 17 0b Flexible Filter 1 Match.
FLX2 18 0b Flexible Filter 2 Match.
FLX3 19 0b Flexible Filter 3 Match.
FLX4 20 0b Flexible Filter 4 Match.
FLX5 21 0b Flexible Filter 5 Match.
FLX6 22 0b Flexible Filter 6 Match.
FLX7 23 0b Flexible Filter 7 Match.
Reserved 31:24 0b Reserved.
Write 0b, ignore on read.
Programming Interface — Ethernet Controller I210
511
8.21.8 Proxying Filter Control Extended Register - PROXYFCEX (0x5590;
R/W)
This register is an extension to PROXYFC and is used to control and enable the routing to management
(like firmware) of a set of pre-defined and flexible filters and filter combinations for proxying support.
8.21.9 Proxying Extended Status Register - PROXYEXS (0x5594; R/
W1C)
This register is used to record statistics about all proxying packets received. If a packet matches
multiple criteria then multiple bits could be set. Writing a 1b to any bit clears that bit.
This register is not cleared when PE_RST_N is asserted. It is only cleared when LAN_PWR_GOOD is de-
asserted or when cleared by the software device driver.
Field Bit(s) Initial Value Description
mDNS 0 0b Route to management if UDP and UDP port equals 5353.
mDNS_mDirected 1 0b Route to management if UDP and port equals to 5353 and multicast IP
match - if IPv4 224.0.0.251, if IPv6 FF02:FB.
mDNS_uDirected 2 0b Route to management if UDP and port equals to 5353 and unicast IP match
- if IPv4 any entry in IP4AT, if IPv6 any entry in IP6AT.
IPv4_mDirected 3 0b Route to management if multicast IPv4 match 224.0.0.251.
IPv6_mDirected 4 0b Route to management if multicast IPv6 match FF02::FB.
IGMP 5 0b Route to management if IPv4 packet and protocol equals 02.
IGMP_mDirected 6 0b Route to management if multicast IPv4 equals 224.0.0.251 and protocol
equals 02.
ARP_RES 7 0b
ARP Response Packet Proxy Enable.
If set to 1b forward to management for proxying on match of any ARP
response packet that passed main filtering.
ARP_RES_Directed 8 0b
ARP Response Packet and IP4AT match Proxy Enable.
If set to 1b forward to management for proxying on match of any ARP
response packet that passed main filtering and target IP address also
matches one of the valid IP4AT filters.
ICMPv4 9 0b Route to management if IPv4 packet and protocol equals 01.
ICMPv4_Directed 10 0b Route to management if unicast IPv4 equals any of the IP4AT addresses
and the protocol equals 01.
ICMPv6 11 0b Route to management if IPv6 packet and protocol equals 58.
ICMPv6_Directed 12 0b Route to management if unicast IPv6 equals any of the IP6AT addresses
and the protocol equals 58.
DNS 13 0b Route to management if UDP/TCP and source port equals to 53.
Reserved 23:14 0x0 Reserved.
RA8 24 0b Route to management if MAC address matched RA8.
RA9 25 0b Route to management if MAC address matched RA9.
RA10 26 0b Route to management if MAC address matched RA10.
RA11 27 0b Route to management if MAC address matched RA11.
RA12 28 0b Route to management if MAC address matched RA12.
RA13 29 0b Route to management if MAC address matched RA13.
RA14 30 0b Route to management if MAC address matched RA14.
RA15 31 0b Route to management if MAC address matched RA15.
Ethernet Controller I210 — Programming Interface
512
Note: If additional packets are received that matches one of the wake-up filters, after the original
wake-up packet is received, the PROXYS register is updated with the matching filters
accordingly.
8.21.10 Wake Flex UDP/TCP Ports Filter - WFUTPF (0x5500 + 4*n
[n=0...31]; RW)
Each 32-bit register (n=0...31) refers to one UDP/TCP port filters.
Field Bit(s) Initial Value Description
mDNS 0 0b mDNS matched.
mDNS_mDirected 1 0b mDNS_mDirected matched.
mDNS_uDirected 2 0b mDNS_uDirected matched.
IPv4_mDirected 3 0b IPv4_mDirected matched.
IPv6_mDirected 4 0b IPv6_mDirected matched.
IGMP 5 0b IGMP matched.
IGMP_mDirected 6 0b IGMP_mDirected matched.
ARP_RES 7 0b ARP_RES matched.
ARP_RES_Directed 8 0b ARP_RES_Directed matched.
ICMPv4 9 0b ICMPv4 matched.
ICMPv4_Directed 10 0b ICMPv4_Directed matched.
ICMPv6 11 0b ICMPv6 matched.
ICMPv6_Directed 12 0b ICMPv6_Directed matched.
DNS 13 0b DNS matched.
Reserved 23:14 0x0 Reserved.
Write 0x0, ignore on read.
RA8 24 0b RA8 matched.
RA9 25 0b RA9 matched.
RA10 26 0b RA10 matched.
RA11 27 0b RA11 matched.
RA12 28 0b RA12 matched.
RA13 29 0b RA13 matched.
RA14 30 0b RA14 matched.
RA15 31 0b RA15 matched.
Field Bit(s) Initial Value Description
Port 15:0 0x0 Flex TCP/UDP Destination Port Value.
Programming Interface — Ethernet Controller I210
513
8.21.11 Range Flex UDP/TCP Port Filter - RFUTPF (0x5580; RW)
8.21.12 Range and Wake Port Filter Control - RWPFC (0x5584; RW)
Control 17:16 00b
Flex Port Control.
00b = Port filter disabled.
01b = UDP port.
10b =TCP port.
11b = TCP port and TCP flag SYN set, TCP flag RESET clear.
Action 18 0b
The Action bit defines the action to take on a match to an enabled filter.
0b= Host wake up.
1b= Route to the MC. Routing to the MC is only enabled when proxy
functionality is enabled and is not intended for pass through. No host wake
up performed.
Reserved 31:19 0x0 Reserved.
Write 0x0, ignore on read.
Field Bit(s) Initial Value Description
LowPort 15:0 0x0 Range Flex UDP/TCP Ports Filter Low.
This port filter marks the lowest port value for the range port filter.
HighPort 31:16 0x0 Range Flex UDP/TCP Ports Filter High.
This port filter marks the highest port value for the range port filter.
Field Bit(s) Initial Value Description
RangeControl 1:0 00b
Range Port Filter Control.
00b = Port Filter disabled.
01b = UDP port.
10b = TCP port.
11b = TCP port and TCP flag SYN set; TCP flag RESET clear.
RangeAction 2 0b
The Range Action bit defines the action to take on a match to the range
port filter.
0b = Host wake up.
1b = Route to the MC. Routing to the MC is only enabled when proxy
functionality is enabled and is not intended for pass through.
Reserved 7:3 0x0 Reserved.
NonIPsecKA 8 0b
Non IPSEC Keep Alive to UDP 4500.
Packet structure- UDP packet UDP destination port 4500, the first byte after
the UDP header is not 0xFF.
Refer to RFC 3948 for more information.
TCP_SSH_Data 9 0b
TCP SSH Data - port 22 (RESET, SYN, FIN - cleared).
Packet structure- TCP packet with TCP destination port of 22; TCP flags
doesn't have the RESET, SYN and FIN flag set.
MagicUDP 10 0b
UDP 3283 Magic WU Packet.
Packet structure - DP packet UDP destination port 3283, first 2 bytes after
the UDP header are 0x13, 0x88, UDP payload is >=100 bytes, and contains
a Magic Packet structure in it.
Reserved 31:11 0x0 Reserved.
Write 0x0, ignore on read.
Field Bit(s) Initial Value Description
Ethernet Controller I210 — Programming Interface
514
8.21.13 Wake Flex UDP/TCP Ports Status - WFUTPS (0x5588, R/W1C)
8.21.14 Wake Control Status - WCS (0x558C, R/W1C)
Field Bit(s) Initial Value Description
Port0 0 0b Flex Port 0 matched.
Port1 1 0b Flex Port 1 matched.
Port2 2 0b Flex Port 2 matched.
Port3 3 0b Flex Port 3 matched.
Port4 4 0b Flex Port 4 matched.
Port5 5 0b Flex Port 5 matched.
Port6 6 0b Flex Port 6 matched.
Port7 7 0b Flex Port 7 matched.
Port8 8 0b Flex Port 8 matched.
Port9 9 0b Flex Port 9 matched.
Port10 10 0b Flex Port 10 matched.
Port11 11 0b Flex Port 11 matched.
Port12 12 0b Flex Port 12 matched.
Port13 13 0b Flex Port 13 matched.
Port14 14 0b Flex Port 14 matched.
Port15 15 0b Flex Port 15 matched.
Port16 16 0b Flex Port 16 matched.
Port17 17 0b Flex Port 17 matched.
Port18 18 0b Flex Port 18 matched.
Port19 19 0b Flex Port 19 matched.
Port20 20 0b Flex Port 20 matched.
Port21 21 0b Flex Port 21 matched.
Port22 22 0b Flex Port 22 matched.
Port23 23 0b Flex Port 23 matched.
Port24 24 0b Flex Port 24 matched.
Port25 25 0b Flex Port 25 matched.
Port26 26 0b Flex Port 26 matched.
Port27 27 0b Flex Port 27 matched.
Port28 28 0b Flex Port 28 matched.
Port29 29 0b Flex Port 29 matched.
Port30 30 0b Flex Port 30 matched.
Port31 31 0b Flex Port 31 matched.
Field Bit(s) Initial Value Description
RangeControl 0 0b RangeControl Matched.
NonIPsecKA 1 0b NonIPsecKA Matched.
TCP_SSH_Data 2 0b TCP_SSH_Data Matched.
MagicUDP 3 0b MagicUDP Matched.
Programming Interface — Ethernet Controller I210
515
8.21.15 IP Address Valid - IPAV (0x5838; R/W)
The IP address valid indicates whether the IP addresses in the IP address table are valid.
8.21.16 IPv4 Address Table - IP4AT (0x5840 + 8*n [n=0...3]; R/W)
The IPv4 address table is used to store the four IPv4 addresses for the ARP/IPv4 request packet and
directed IP packet wake up.
Reserved 29:4 0x0 Reserved.
Write 0x0, ignore on read.
LocalIPOrNameCo
nflict 30 0b
Local IP Conflict or Name Conflict Detected by Proxy.
A firmware write of 1b sets the field, while a software write of 1b clears the
field. Firmware writes to set are not blocked if other fields of the status are
already set.
mDNS Proxy Error
Recovery 31 0b
mDNS Proxy Error Recovery.
A firmware write of 1b sets the field, while a software write of 1b clears the
field. Firmware writes to set are not blocked if other fields of the status are
already set.
Field Bit(s) Initial Value Description
V40 0 0b IPv4 Address 0 Valid.
V41 1 0b IPv4 Address 1 Valid.
V42 2 0b IPv4 Address 2 Valid.
V43 3 0b IPv4 Address 3 Valid.
Reserved 15:4 0x0 Reserved.
Write 0x0, ignore on read.
V60 16 0b IPv6 Address 0 Valid.
Reserved 31:17 0x0 Reserved.
Write 0x0, ignore on read.
Field Bit(s) Initial Value Description
IP Address 31:0 X
IPv4 Address n.
Note: These registers are written in Big Endian order (LS byte is first on
the wire and is the MS byte of the IPV4 address).
Field Dword # Address Bit(s) Initial Value Description
IPV4ADDR0 0 0x5840 31:0 X IPv4 Address 0.
IPV4ADDR1 2 0x5848 31:0 X IPv4 Address 1.
IPV4ADDR2 4 0x5850 31:0 X IPv4 Address 2.
IPV4ADDR3 6 0x5858 31:0 X IPv4 Address 3.
Field Bit(s) Initial Value Description
Ethernet Controller I210 — Programming Interface
516
8.21.17 IPv6 Address Table - IP6AT (0x5880 + 4*n [n=0...3]; R/W)
The IPv6 address table is used to store the IPv6 addresses for neighbor discovery packet filtering and
directed IP packet wake up.
8.21.18 Flexible Host Filter Table Registers - FHFT (0x9000 + 4*n
[n=0...255]; RW)
Each of the 8 Flexible Host Filters Table registers (FHFT and FHFT_EXT) contains a 128 byte pattern and
a corresponding 128-bit mask array. If enabled, the first 128 bytes of the received packet are
compared against the non-masked bytes in the FHFT register.
Each 128 byte filter is composed of 32 Dword entries, where each 2 Dwords are accompanied by an 8-
bit mask, one bit per filter byte. When a bit in the 8-bit mask field is set the corresponding byte in the
filter is compared.
The 8 LSB bits of the last Dword of each filter contains a length field defining the number of bytes from
the beginning of the packet compared by this filter, the length field should be 8 bytes aligned value. If
actual packet length is less than (length - 8) (length is the value specified by the length field), the filter
fails. Otherwise, it depends on the result of actual byte comparison. The value should not be greater
than 128.
Note: The length field must be 8 bytes aligned. For filtering packets shorter than 8 bytes aligned,
the values should be rounded down to the previous 8 bytes aligned value.
Bits 31:8 of the last Dword of each filter also includes a Queueing field (refer to Section 8.21.18.1).
When the I210 is in the D0 state, the WUFC.FLEX_HQ bit is set to 1b, MRQC.Multiple Receive Queues =
010b or 000b and the packet matches the flex filter, the Queueing field defines the receive queue for
the packet, priority of the filter and actions to be initiated.
Field Bit(s) Initial Value Description
IP Address 31:0 X
IPv6 Address bytes 4*n+1:4*n +4.
Note: These registers appear in Big Endian order (LS byte, LS address is
first on the wire and is the MS byte of the IPV6 address).
Field Dword # Address Bit(s) Initial Value Description
IPV6ADDR0
0 0x5880 31:0 X IPv6 Address 0, bytes 1-4.
1 0x5884 31:0 X IPv6 Address 0, bytes 5-8.
2 0x5888 31:0 X IPv6 Address 0, bytes 9-12.
3 0x588C 31:0 X IPv6 Address 0, bytes 16-13.
Field Bit(s) Initial Value Description
Bit Vector 31:0 X The details of the bit vector are described in Table 8-24.
Programming Interface — Ethernet Controller I210
517
....
Accessing the FHFT registers during filter operation can result in a packet being mis-classified if the
write operation collides with packet reception. It is therefore advised that the flex filters are disabled
prior to changing their setup.
8.21.18.1 Flex Filter Queueing Field
The Queueing field resides in bits 31:8 of last Dword (Dword 63) of flex filter. The Queueing field
defines the receive queue to forward the packet (RQUEUE), the filter priority (FLEX_PRIO) and
additional filter actions. Operations defined in Queueing field are enabled when the I210 is in the D0
state, MRQC.Multiple Receive Queues = 010b or 000b, WUFC.FLEX_HQ is 1b and relevant WUFC.FLX[n]
bit is set.
Table 8-24. FHFT Filter Description
31 0 31 8 7 0 31 0 31 0
Reserved Reserved Mask [7:0] DW 1 Dword 0
Reserved Reserved Mask [15:8] DW 3 Dword 2
Reserved Reserved Mask [23:16] DW 5 Dword 4
Reserved Reserved Mask [31:24] DW 7 Dword 6
31 8 7 0 31 8 7 0 31 0 31 0
Reserved Reserved Reserved Mask [119:112] DW 29 Dword 28
Queueing Length Reserved Mask [127:120] DW 31 Dword 30
Field Bit(s) Initial Value Description
Length 7:0 X
Length.
Filter length in bytes. Should be 8 bytes aligned and not greater than
128 bytes.
RQUEUE 10:8 X
Receive Queue.
Defines receive queue associated with this flex filter. When a match
occurs in D0 state, the packet is forwarded to the receive queue.
Reserved 15:11 X Reserved.
Write 0x0, ignore on read.
FLEX_PRIO 18:16 X
Flex Filter Priority.
Defines the priority of the filter assuming two filters with the same
priority don’t match. If two filters with the same priority match the
incoming packet, the first filter (lowest address) is used in order to
define the queue destination of this packet.
Reserved 23:19 X Reserved.
Write 0x0, ignore on read.
Immediate Interrupt 24 X Enables issuing an immediate interrupt when the flex filter matches the
incoming packet.
Reserved 31:25 X Reserved.
Write 0x0, ignore on read.
Ethernet Controller I210 — Programming Interface
518
8.21.18.2 Flex Filter 0 - Example
8.21.19 Flexible Host Filter Table Extended Registers - FHFT_EXT
(0x9A00 + 4*n [n=0...255]; RW)
Each of the four additional Flexible Host Filters table extended registers (FHFT_EXT) contains a 128
byte pattern and a corresponding 128-bit mask array. If enabled, the first 128 bytes of the received
packet are compared against the non-masked bytes in the FHFT_EXT register. The layout and access
rules of this table are the same as in FHFT.
8.22 Management Register Descriptions
All management registers are controlled by the remote MC for both read and write. Host accesses to
the management registers are blocked for write. The attributes for the fields in this section refer to the
MC access rights.
Note: All the registers described in this section can get their default values from the Flash when
manageability pass through works in legacy SMBus mode. The only exception being the
MANC register where part of the bits are masked. The specific MANC bits that can be loaded
from the Flash are indicated in the register description.
8.22.1 Management VLAN TAG Value - MAVTV (0x5010 +4*n [n=0...7];
RW)
Where “n” is the VLAN filter serial number, equal to 0,1...7.
Field Dword Address Bit(s) Initial Value
Filter 0 DW0 0 0x9000 31:0 X
Filter 0 DW1 1 0x9004 31:0 X
Filter 0 Mask[7:0] 2 0x9008 7:0 X
Reserved 3 0x900C 31:0 X
Filter 0 DW2 4 0x9010 31:0 X
…
Filter 0 DW30 60 0x90F0 31:0 X
Filter 0 DW31 61 0x90F4 31:0 X
Filter 0
Mask[127:120] 62 0x90F8 7:0 X
Length 63 0x90FC 7:0 X
Filter 0 Queueing 63 0x90FC 31:8 X
Field Bit(s) Initial Value Description
bit vector 31:0 X The details of the bit vector are described in Table 8-24.
Field Bit(s) Initial Value Description
VID 11:0 0x0 Contains the VLAN ID that should be compared with the incoming packet if
the corresponding bit in MDEF is set.
Reserved 31:12 0x0 Reserved.
Write 0x0, ignore on read
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The MAVTV registers are written by the MC and are not accessible to the host for writing. The registers
are used to filter manageability packets as described in the manageability chapter.
8.22.2 Management Flex UDP/TCP Ports - MFUTP (0x5030 + 4*n
[n=0...7]; 0x5070 + 4*n [n=0...7]; RW)
Where each 32-bit register (n=0...15) refers to one UDP/TCP port filters.
The MFUTP registers are written by the MC and are not accessible to the host for writing. The registers
are used to filter manageability packets. See Section 10.3.
Reset - The MFUTP registers are cleared on LAN_PWR_GOOD only. The initial values for this register
can be loaded from the Flash after power-up reset.
Note: The MFUTP[even] and MFUTP[odd] registers should be written in network order. MFUTP[0...7]
are at 0x5030+4*[0...7]. MFUTP[8...15] are at 0x5070+4*[0...7].
8.22.3 Manageability Special Filters Modifiers - MSFM (0x5870; RW)
This register contains various modifiers impacting the behavior of the first level filters used as input to
the decision filters.
Field Bit(s) Initial Value Description
MFUTP port 15:0 0x0 Management Flex UDP/TCP port #n.
UDP 16 0b Match if port is UDP.
TCP 17 0b Match if port is TCP.
SOURCE
DESTINATION 18 0b 0b = Compare destination port.
1b = Compare source port.
RESERVED 31:19 0x0 Reserved.
Field Bit(s) Initial Value Description
PORT_26F_UDP 0 1b Port 0x26F match if protocol is UDP.
PORT_26F_TCP 1 1b Port 0x26F match if protocol is TCP.
PORT_298_UDP 2 1b Port 0x298 match if protocol is UDP.
PORT_298_TCP 3 1b Port 0x298 match if protocol is TCP.
IPV6_0_MASK 4 0b Compare only 24 LSB bits of IPv6 Address 0 (MIPAF[0]).
IPV6_1_MASK 5 0b Compare only 24 LSB bits of IPv6 Address 1 (MIPAF[1]).
IPV6_2_MASK 6 0x0 Compare only 24 LSB bits of IPv6 Address 2 (MIPAF[2]).
IPV6_3_MASK 7 0x0 Compare only 24 LSB bits of IPv6 Address 3 (MIPAF[3]).
RESERVED 31:8 0x0 Reserved.
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8.22.4 Management Ethernet Type Filters- METF (0x5060 + 4*n
[n=0...3]; RW)
The METF registers are written by the MC and are not accessible to the host for writing. The registers
are used to filter manageability packets. See Section 10.3.
Reset - The METF registers are cleared on LAN_PWR_GOOD only. The initial values for this register
might be loaded from the Flash after power-up reset.
8.22.5 Management Control Register - MANC (0x5820; RW)
The MANC register can be written by the MC and is not accessible to the host for writing.
Field Bit(s) Initial Value Description
METF 15:0 0x0 EtherType value to be compared against the L2 EtherType field in the Rx packet.
Reserved 29:16 0x0 Reserved.
Write 0x0, ignore on read.
Polarity 30 0b 0b = Positive filter - forward packets matching this filter to the manageability block.
1b = Negative filter - block packets matching this filter from the manageability block.
Reserved 31 0b Reserved.
Write 0b, ignore on read.
Field Bit(s) Initial Value Description
Flow Control Discard 0 0b
0b = Apply filtering rules to packets with Flow Control EtherType.
1b = Discard packets with Flow Control EtherType.
Note: Flow Control EtherType is 0x8808.
NCSI Discard 1 0b
0b = Apply filtering rules to packets with NC-SI EtherType.
1b = Discard packets with NC-SI EtherType.
Note: NC-SI EtherType is 0x88F8.
Reserved 13:2 0x0 Reserved.
Write 0x0, ignore on read.
FW_RESET (R/W1C) 14 0b
Firmware Reset Occurred.
Set to 1b on a TCO firmware reset.
Cleared by write 1b.
TCO_Isolate (RO) 15 0b
Set to 1b on a TCO Isolate command. When the TCO_Isolate bit is set. Host
write cycles are completed successfully on the PCIe but silently ignored by
internal logic.
Note that when firmware initiates the TCO Isolate command it also initiates a
firmware interrupt via the ICR.MNG bit to the host and writes a value of 0x22 to
theFWSM.Ext_Err_Ind field.
This bit is RO and mirrors the value of the Isolate bit in the internal
management registers.
TCO_RESET
(R/W1C) 16 0b
TCO Reset Occurred.
Set to 1b on a TCO reset, to reset LAN port by the MC.
Cleared by write 1b.
RCV_TCO_EN 17 0b1
TCO Receive Traffic Enabled.
When this bit is set, receive traffic to manageability is enabled.
This bit should be set only if either the MANC.EN_BMC2OS or
MANC.EN_BMC2NET bits are set.
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KEEP_PHY_LINK_UP 18 0b1
Block PHY reset and power state changes.
When this bit is set, the PHY reset and power state changes do not effect the
PHY, This bit can not be written to unless the Keep_PHY_Link_Up_En Flash bit is
set.
Reserved 19 0b Reserved.
Reserved 22:20 0b Reserved.
Write 0b, ignore on read.
EN_XSUM_FILTER 23 0b1Enable Checksum Filtering to MNG.
When this bit is set, only packets that pass L3and L4 checksums are sent to the
manageability block.
EN_IPv4_FILTER 24 0b1Enable IPv4 address Filters.
When set, the last 128 bits of the MIPAF register are used to store 4 IPv4
addresses for IPv4 filtering. When cleared, these bits store a single IPv6 filter.
FIXED_NET_TYPE 25 0b1
Fixed Net Type.
If set, only packets matching the net type defined by the NET_TYPE field passes
to manageability. Otherwise, both tagged and un-tagged packets can be
forwarded to the manageability engine.
NET_TYPE 26 0b1
Net Type.
0b = Pass only un-tagged packets.
1b = Pass only VLAN tagged packets.
Valid only if FIXED_NET_TYPE is set.
Reserved 27 0b Reserved.
Write 0b, ignore on read.
EN_BMC2OS (RO) 28 0b1
Enable MC-to-OS and OS-to-MC Traffic.
0b = The MC cannot communicate with the operating system.
1b = The MC can communicate with the operating system.
When cleared, the MC traffic is not forwarded to the operating system, even if
the host is the MAC.
The address filter and VLANs (RAH/L, MTA, VFTA and VLVF registers) indicate
that it should.
When cleared, the operating system traffic is not forwarded to the MC even if
the decision filters indicates it should. This bit does not impact the MC-to-
network traffic.
Notes:
1. Initial value loaded according to value of port n traffic types field in the
Flash(refer to Section 6.7.7.2).
2. Bit reflects the internal management Aux register bit.
Field Bit(s) Initial Value Description
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8.22.6 Management Only Traffic Register - MNGONLY (0x5864; RW)
The MNGONLY register enables exclusive filtering of a certain type of traffic to the MC. Exclusive
filtering enables the MC to define certain packets that are forwarded to the MC but not to the host. The
packets are not be forwarded to the host even if they pass the host L2 filtering process.
Each manageability decision filter (MDEF and MDEF_EXT) has a corresponding bit in the MNGONLY
register. When a manageability decision filter (MDEF and MDEF_EXT) forwards a packet to
manageability, it can also block the packet from being forwarded to the host if the corresponding
MNGONLY bit is set.
8.22.7 Manageability Decision Filters - MDEF (0x5890 + 4*n [n=0...7];
RW)
Where “n” is the decision filter.
EN_BMC2NET (RO) 29 1b1
Enable MC to network and network to MC traffic.
0b = The MC cannot communicate with the network.
1b = The MC can communicate with the network.
When cleared, the MC traffic is not forwarded to the network and the network
traffic is not forwarded to the MC even if the decision filters indicates it should.
This bit does not impact the host-to-MC traffic.
Note:
1. Initial value loaded according to value of Port n traffic types field in Flash
(refer to Section 6.7.7.2).
2.
MPROXYE (RO) 30 0b1
Management Proxying Enable.
When set to 1b, proxying of packets is enabled when the device is in a D3 low
power state.
0b = Manageability does not support proxying.
1b = Manageability supports proxying.
Note: Proxy information and requirements are passed by the software device
driver to firmware via the shared RAM host interface (refer to
Section 10.8, Section 8.23 and Section 10.8.2.4.5).
Note: Proxying traffic from and to firmware is not affected by the
MANC.RCV_TCO_EN bit or the MANC.EN_BMC2NET bit.
Reserved 31 0b Reserved
Write 0b, ignore on read.
1. Bit loaded from Flash.
Field Bit(s) Initial Value1
1. The initial values for this register can be loaded from the Flash after power-up reset or firmware reset.
Description
Exclusive to
MNG 7:0 0x0
Exclusive to MNG.
When set, indicates that packets forwarded by the manageability filters to
manageability are not sent to the host. Bits 0...7 correspond to decision
rules defined in registers MDEF[0...7] and MDEF_EXT[0...7].
Reserved 31:8 0x0 Reserved.
Write 0x0, ignore on read.
Field Bit(s) Initial Value Description
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Field Bit(s) Initial Value1Description
Exact AND 3:0 0x0
Exact.
Controls the inclusion of exact MAC address 0 to 3.
In the manageability filter decision (AND section). Bit 0 corresponds to exact
MAC address 0 (MMAL0 and MMAH0), etc.
Broadcast AND 4 0b
Broadcast.
Controls the inclusion of broadcast address filtering in the manageability filter
decision (AND section).
VLAN AND 12:5 0x0
VLAN.
Controls the inclusion of VLAN tag 0 to 7, respectively.
In the manageability filter decision (AND section). Bit 5 corresponds to VLAN tag
0, etc.
IPv4 Address 16:13 0x0
IPv4 Address.
Controls the inclusion of IPV4 address 0 to3, respectively in the manageability
filter decision (AND section). Bit 13 corresponds to IPV4 address 0, etc.
Note: This field is relevant only if MANC.EN_IPv4_FILTER is set.
IPv6 Address 20:17 0b
IPv6 Address.
Controls the inclusion of IPV6 address 0 to3, respectively in the manageability
filter decision (AND section). Bit 17 corresponds to IPV6 address 0, etc.
Notes:
1. Bit 20 is relevant only if MANC.EN_IPv4_FILTER is cleared.
2. Supported only for network traffic. For host traffic, any IPv6 packet passes
this filter.
Exact OR 24:21 0x0
Exact.
Controls the inclusion of exact MAC address 0 to 3.
In the manageability filter decision (OR section). Bit 21 corresponds to exact
MAC address 0 (MMAL0 and MMAH0), etc.
Broadcast OR 25 0b
Broadcast.
Controls the inclusion of broadcast address filtering in the manageability filter
decision (OR section).
Multicast AND 26 0b
Multicast.
Controls the inclusion of multicast address filtering in the manageability filter
decision (AND section). Broadcast packets are not included by this bit.
ARP Request 27 0b
ARP Request.
Controls the inclusion of ARP request filtering in the manageability filter decision
(OR section).
Note: Supported only for network traffic.
ARP Response 28 0b
ARP Response.
Controls the inclusion of ARP response filtering in the manageability filter
decision (OR section).
Note: Supported only for network traffic.
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8.22.8 Manageability Decision Filters- MDEF_EXT (0x5930 +
4*n[n=0...7]; RW)
Neighbor
Discovery -134
(Router
Advertisement)
29 0b
Router Advertisement Discovery.
Controls the inclusion of router advertisement filtering in the manageability filter
decision (OR section).
Notes:
1. Supported only for network traffic. For host traffic, any IPv6 packet passes
this filter.
2. Neighbor discovery types supported by this bit is 0x86 (134d) - router
advertisement.
Port 0x298 30 0b
Port 0x298.
Controls the inclusion of Port 0x298 filtering in the manageability filter decision
(OR section).
Note: Supported only for network traffic or IPv4 host traffic. For Ipv6 packets
received from host, this filter fails.
Port 0x26F 31 0b
Port 0x26F.
Controls the inclusion of Port 0x26F filtering in the manageability filter decision
(OR section).
Note: Supported only for network traffic or IPv4 host traffic. For Ipv6 packets
received from host, this filter fails.
1. Default values are read from Flash.
Field Bit(s) Initial Value1Description
L2 EtherType AND 3:0 0x0
L2 EtherType.
Controls the inclusion of L2 EtherType filtering in the manageability filter
decision (AND section).
L2 EtherType OR 7:4 0x0
L2 EtherType.
Controls the inclusion of L2 EtherType filtering in the manageability filter
decision (OR section).
Flex port 23:8 0x0
Flex port.
Controls the inclusion of flex port filtering in the manageability filter decision
(OR section). Bit 8 corresponds to flex port 0, etc.
Note: Supported only for network traffic or IPv4 host traffic. For Ipv6
packets received from host, this filter fails.
Flex TCO 24 0b
Flex TCO.
Controls the inclusion of flex TCO filtering in the manageability filter decision
(OR section). Bit 24 corresponds to flex TCO filter 0.
Note: Supported only for network traffic. For packets received from host,
this filter passes.
Neighbor
Discovery -135
(Solicitation)
25 0b
Neighbor Solicitation.
Controls the inclusion of neighbor solicitation filtering in the manageability
filter decision (OR section).
Notes:
1. Supported only for network traffic. For host traffic, any IPv6 packet
passes this filter.
2. Neighbor discovery types supported by this bit is 0x87 (135d) - neighbor
solicitation
Field Bit(s) Initial Value1Description
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8.22.9 Manageability IP Address Filter - MIPAF (0x58B0 + 4*n
[n=0...15]; RW)
The Manageability IP Address Filter register stores IP addresses for manageability filtering. The MIPAF
register can be used in two configurations, depending on the value of the MANC.EN_IPv4_FILTER bit:
EN_IPv4_FILTER = 0b: the last 128 bits of the register store a single IPv6 address (IPV6ADDR3)
EN_IPv4_FILTER = 1b: the last 128 bits of the register store 4 IPv4 addresses (IPV4ADDR[3:0])
MANC.EN_IPv4_FILTER = 0b:
Neighbor
Discovery -136
(Advertisement)
26 0b
Neighbor Advertisement.
Controls the inclusion of neighbor advertisement filtering in the manageability
filter decision (OR section).
Notes:
1. Supported only for network traffic. For host traffic, any IPv6 packet
passes this filter.
2. Neighbor discovery types supported by this bit is 0x88 (136d) - neighbor
advertisement.
Neighbor
Discovery -137
(Redirect) 27 0b
Redirect Neighbor Discovery.
Controls the inclusion of redirect neighbor discovery filtering in the
manageability filter decision (OR section).
Notes:
1. Supported only for network traffic. For host traffic, any IPv6 packet
passes this filter.
2. Neighbor discovery types supported by this bit is 0x89 (137d) - redirect.
ICMPv4_OR 28 0b Controls the inclusion of ICMPv4 filtering in the manageability filter decision
(OR section).
MLD 29 0b
MLD.
Controls the inclusion of MLD packets. These are ICMPv6 packets with the
following types: 130, 131, 132, 143.
Note: Supported only for network traffic. For host traffic, any IPv6 packet
passes this filter.
Apply_to_network
_traffic 30 0b 0b = Do not apply this decision filter to traffic received from the network.
1b = Apply this decision filter to traffic received from the network.
Apply_to_host_traf
fic 31 0b 0b = This decision filter does not apply to traffic received from the host.
1b = This decision filter applies to traffic received from the host.
1. Default values are read from Flash.
Field Bit(s) Initial Value Description
IP Address 31:0 X
IPv4/IPv6 Address n.
Note: These registers are written in Big Endian order (LS byte is first on
the wire and is the MS byte of the IPV4 Address).
Field Bit(s) Initial Value1Description
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Field definitions for 0 setting:
MANC.EN_IPv4_FILTER = 1b:
DWORD# Address 31 0
0 0x58B0
IPV6ADDR0
1 0x58B4
2 0x58B8
3 0x58BC
4 0x58C0
IPV6ADDR1
5 0x58C4
6 0x58C8
7 0x58CC
8 0x58D0
IPV6ADDR2
9 0x58D4
10 0x58D8
11 0x58DC
12 0x58E0
IPV6ADDR3
13 0x58E4
14 0x58E8
15 0x58EC
Field Dword # Address Bit(s) Initial
Value Description
IPV6ADDR0
0 0x58B0 31:0 X* IPv6 Address 0, bytes 1-4 (LS byte is first on the
wire).
1 0x58B4 31:0 X* IPv6 Address 0, bytes 5-8.
2 0x58B8 31:0 X* IPv6 Address 0, bytes 9-12.
3 0x58BC 31:0 X* IPv6 Address 0, bytes 13-16.
IPV6ADDR1
0 0x58C0 31:0 X* IPv6 Address 1, bytes 1-4 (LS byte is first on the
wire).
1 0x58C4 31:0 X* IPv6 Address 1, bytes 5-8.
2 0x58C8 31:0 X* IPv6 Address 1, bytes 9-12.
3 0x58CC 31:0 X* IPv6 Address 1, bytes 13-16.
IPV6ADDR2
0 0x58D0 31:0 X* IPv6 Address 2, bytes 1-4 (LS byte is first on the
wire).
1 0x58D4 31:0 X* IPv6 Address 2, bytes 5-8.
2 0x58D8 31:0 X* IPv6 Address 2, bytes 9-12.
3 0x58DC 31:0 X* IPv6 Address 2, bytes 13-16.
IPV6ADDR3
0 0x58E0 31:0 X* IPv6 Address 3, bytes 1-4 (LS byte is first on the
wire).
1 0x58E4 31:0 X* IPv6 Address 3, bytes 5-8.
2 0x58E8 31:0 X* IPv6 Address 3, bytes 9-12.
3 0x58EC 31:0 X* IPv6 Address 3, bytes 13-16.
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Field definitions for 1 setting:
DWORD# Address 31 0
0 0x58B0
IPV6ADDR0
1 0x58B4
2 0x58B8
3 0x58BC
4 0x58C0
IPV6ADDR1
5 0x58C4
6 0x58C8
7 0x58CC
8 0x58D0
IPV6ADDR2
9 0x58D4
10 0x58D8
11 0x58DC
12 0x58E0 IPV4ADDR0
13 0x58E4 IPV4ADDR1
14 0x58E8 IPV4ADDR2
15 0x58EC IPV4ADDR3
Field Dword # Address Bit(s) Initial
Value1
1. The initial values for these registers can be loaded from the Flash after power-up reset. The registers are written by the MC and
not accessible to the host for writing.
Description
IPV6ADDR0
0 0x58B0 31:0 X IPv6 Address 0, bytes 1-4 (LS byte is first on the
wire).
1 0x58B4 31:0 X IPv6 Address 0, bytes 5-8.
2 0x58B8 31:0 X IPv6 Address 0, bytes 9-12.
3 0x58BC 31:0 X IPv6 Address 0, bytes 16-13.
IPV6ADDR1
0 0x58C0 31:0 X IPv6 Address 1, bytes 1-4 (LS byte is first on the
wire).
1 0x58C4 31:0 X IPv6 Address 1, bytes 5-8.
2 0x58C8 31:0 X IPv6 Address 1, bytes 9-12.
3 0x58CC 31:0 X IPv6 Address 1, bytes 16-13.
IPV6ADDR2
0 0x58D0 31:0 X IPv6 Address 2, bytes 1-4 (LS byte is first on the
wire).
1 0x58D4 31:0 X IPv6 Address 2, bytes 5-8.
2 0x58D8 31:0 X IPv6 Address 2, bytes 9-12.
3 0x58DC 31:0 X IPv6 Address 2, bytes 16-13.
IPV4ADDR0 0 0x58E0 31:0 X IPv4 Address 0 (LS byte is first on the wire).
IPV4ADDR1 1 0x58E4 31:0 X IPv4 Address 1 (LS byte is first on the wire).
IPV4ADDR2 2 0x58E8 31:0 X IPv4 Address 2 (LS byte is first on the wire).
IPV4ADDR3 3 0x58EC 31:0 X IPv4 Address 3 (LS byte is first on the wire).
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Initial value:
Reset - The registers are cleared on LAN_PWR_GOOD only.
Note: These registers should be written in network order.
8.22.10 Manageability MAC Address Low - MMAL (0x5910 + 8*n [n=
0...3]; RW)
Where “n” is the exact unicast/multicast address entry, equal to 0...3.
These registers contain the lower bits of the 48-bit Ethernet address. The MMAL registers are written by
the MC and are not accessible to the host for writing. The registers are used to filter manageability
packets. See Section 10.3.
Reset - The MMAL registers are cleared on LAN_PWR_GOOD only. The initial values for this register can
be loaded from the Flash after power-up reset.
Note: The MMAL.MMAL field should be written in network order.
8.22.11 Manageability MAC Address High - MMAH (0x5914 + 8*n
[n=0...3]; RW)
Where “n” is the exact unicast/multicast address entry, equal to 0...3.
Field Bit(s) Initial Value1
1. The initial values for these registers can be loaded from the Flash after power-up reset. The registers are written by the MC and
not accessible to the host for writing.
Description
IP_ADDR 4 bytes 31:0 X
4 bytes of IP (v6 or v4) address.
i mod 4 = 0 to bytes 1 - 4.
i mod 4 = 1 to bytes 5 - 8.
i mod 4 = 0 to bytes 9 - 12.
i mod 4 = 0 to bytes 13 - 16.
where i div 4 is the index of IP address (0...3).
Field Bit(s) Initial Value1
1. The initial values for these registers can be loaded from the Flash after power-up reset. The registers are written by the MC and
not accessible to the host for writing.
Description
MMAL 31:0 X Manageability MAC Address Low. The lower 32 bits of the 48 bit Ethernet
address.
Field Bit(s) Initial Value1
1. The initial values for these registers can be loaded from the Flash after power-up reset. The registers are written by the MC and
not accessible to the host for writing.
Description
MMAH 15:0 X Manageability MAC Address High.
The upper 16 bits of the 48 bit Ethernet address.
Reserved 31:16 0x0 Reserved.
Write 0x0, ignore on read.
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These registers contain the upper bits of the 48-bit Ethernet address. The complete address is {MMAH,
MMAL}. The MMAH registers are written by the MC and are not accessible to the host for writing. The
registers are used to filter manageability packets. See Section 10.3.
Reset - The MMAL registers are cleared on LAN_PWR_GOOD only. The initial values for this register can
be loaded from the Flash after power-up reset or firmware reset.
Note: The MMAH.MMAH field should be written in network order.
8.22.12 Flexible TCO Filter Table registers - FTFT (0x9400 + 4*n
[n=0...63]; RW)
The Flexible TCO Filter Table registers (FTFT) contains a 128 byte pattern and a corresponding 128-bit
mask array. If enabled, the first 128 bytes of the received packet are compared against the non-
masked bytes in the FTFT register.
The 128 byte filter is composed of 32 Dword entries, where each 2 Dwords are accompanied by an 8-bit
mask, one bit per filter byte. The bytes in each 2 Dwords are written in network order (for example,
byte0 written to bits [7:0], byte1 to bits [15:8] etc.) The mask field is set so that bit0 in the mask
masks byte0, bit 1 masks byte 1 etc. A value of 1 in the mask field means that the appropriate byte in
the filter should be compared to the appropriate byte in the incoming packet.
Note: The mask field must be 8 bytes aligned even if the length field is not 8 bytes aligned, as the
hardware implementation compares 8 bytes at a time so it should get extra masks until the
end of the next Qword. Any mask bit that is located after the length should be set to 0
indicating no comparison should be done.
In case the actual length, which is defined by the length field register and the mask bits, is
not 8 bytes aligned there might be a case that a packet that is shorter than the actual
required length passes the flexible filter. This can occur due to comparison of up to 7 bytes
that come after the packet, but are not a real part of the packet.
The last Dword of the filter contains a length field defining the number of bytes from the beginning of
the packet compared by this filter. If the actual packet length is less than the length specified by this
field, the filter fails. Otherwise, it depends on the result of actual byte comparison. The value should not
be greater than 128.
The initial values for the FTFT registers can be loaded from the Flash after power-up reset. The FTFT
registers are written by the MC and are not accessible to the host for writing. The registers are used to
filter manageability packets as described in Section 10.3.3.6.
Note: The FTFT registers are cleared on LAN_PWR_GOOD and firmware reset only.
Field Bit(s) Initial Value Description
Bit Vector 31:0 X The details of the bit vector are described in Table 8-25.
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....
Field definitions for Filter Table registers:
8.23 Host Interface Memory Registers Description
The software device driver communicates with the manageability block through CSR access.
8.23.1 Host Slave Command Interface to Manageability Firmware
This interface is used by the software device driver for several of commands and for delivering various
types of data structure in both directions (MNG Host, Host MNG).
The address space is separated into two areas:
1. Direct access to the internal ManagementDATA RAM: The internal DATA RAM is mapped to address
0x8800-0x8EFF. Writing to this address space goes directly to the RAM. This section can be limited
by the internal firmware. The firmware reports to the host the maximum size allocated in the
HIBSMAXOFF register. When this section is used for host interface commands (Section 10.8.2.4) it
is usually limited to 512 bytes. When it is used to load firmware in systems (Section 3.4.3), the full
1792 bytes are available.
2. Control registers located at address 0x8F00.
Table 8-25. FTFT Filter Description
31 0 31 8 7 0 31 0 31 0
Reserved Reserved Mask [7:0] Dword 1 Dword 0
Reserved Reserved Mask [15:8] Dword 3 Dword 2
Reserved Reserved Mask [23:16] Dword 5 Dword 4
Reserved Reserved Mask [31:24] Dword 7 Dword 6
31 8 7 0 31 8 7 0 31 0 31 0
Reserved Reserved Reserved Mask [127:120] Dword 29 Dword 28
Reserved Length Reserved Mask [127:120] Dword 31 Dword 30
Field Dword Address Bit(s) Initial Value
Filter 0 Dword0 0 0x9400 31:0 X
Filter 0 Dword1 1 0x9404 31:0 X
Filter 0 Mask[7:0] 2 0x9408 7:0 X
Reserved 3 0x940C X
Filter 0 Dword2 4 0x9410 31:0 X
...
Filter 0 Dword30 60 0x94F0 31:0 X
Filter 0 Dword31 61 0x94F4 31:0 X
Filter 0 Mask[127:120] 62 0x94F8 7:0 X
Length 63 0x94FC 7:0 X
Programming Interface — Ethernet Controller I210
531
8.23.1.1 Host Slave Command I/F Flow
This interface is used for the external host software to access the MMS sub-system. The host software
can write a command block or read data structure directly from the DATA RAM. The host software
controls these transactions through a slave access to the control register.
The following flow describes the process of initiating a command to the MMS:
1. The software device driver takes ownership of the SW_FW_SYNC.SW_MNG_SM bit according to the
flow described in Section 4.7.1.
2. The software device driver reads the HICR register and checks that the enable bit is set.
3. The software device driver writes the relevant command block into the shared RAM area.
4. The software device driver sets the Command bit in the control register. Setting this bit causes an
interrupt to management.
5. The software device driver polls the Control register until the Command bit is cleared by hardware.
6. When the MMS is done with the command, it clears the Command bit (if the MMS should reply with
a data, it should clear the bit only after the data is in the RAM area where the software device driver
can read it).
7. If the software device driver reads the Control register and the SV bit is set, it means that there is
a valid status of the last command in the RAM. If the SV is not set it means that the command has
failed with no status in the RAM.
8.23.2 HOST Interface Control Register - HICR (0x8F00; RW)
Field Bit(s) Initial Value Description
En (RO) 0 0b
Enable.
When set, it indicates that a RAM area is provided for software device driver
accesses.
This bit is read only for the software device driver.
C 1 0b
Command.
The software device driver sets this bit when it has finished putting a
command block in the management internal DATA RAM. This bit should be
cleared by the firmware after the command’s processing completes.
SV (RO) 2 0b
Status Valid.
Indicates that there is a valid status in CSR area that the software device
driver can read.
1b = status valid.
0b = status not valid.
The value of the bit is valid only when the C bit is cleared.
Only the software device driver reads this bit.
Reserved 3 0b Reserved.
Reserved 6:4 0x0 Reserved.
FWR 7 0b
Firmware Reset.
When set by the host, it indicates that the hardware needs to assert a
firmware reset.
This bit is meaningful only when in the non-secured mode.
Reserved 8 0b Reserved.
Memory Base
Enable (RO) 9 0b Enable host access to memory base register. This bit is set by the firmware
and is read only to the software device driver.
Reserved 31:10 0x0 Reserved.
Write 0x9, ignore on read.
Ethernet Controller I210 — Programming Interface
532
8.23.3 Host Interface Buffer Base Address - HIBBA (0x8F40; RW)
Notes:
1. This register is reset by a firmware reset.
2. This resister is accessible to the host driver only if Memory Base Enable is set in HICR; otherwise,
the register is read only to the host driver.
8.23.4 Host Interface Buffer Maximum Offset - HIBMAXOFF (0x8F44;
RO)
The register holds the maximum offset in bytes in the memory buffer that the host can access from
address 0x8800 in its address space. Any access above this value is blocked by hardware.
This register is reset by a firmware reset.
8.24 Memory Error Registers Description
Main internal memories are protected by Error Correcting Code (ECC) or parity bits. The I210 contains
several registers that enable and report detection of internal memory errors. Description and usage of
these registers can be found in Section 7.6.
Field Bit(s) Initial Value Description
BA 19:0 0x17800
Host interface buffer base address in the device internal memory
space (in bytes). Base address for the CSR slave access.
The address must be 1 KB aligned (bits 9:0 are RO hardwired to
zero).
Reserved 31:20 0x0 Reserved.
Write 0x0, ignore on read.
Field Bit(s) Initial Value Description
MAXOFF 9:0 0x3FF Maximum offset in the HIB for the CSR slave access.
The 2 LSBs are always set to 11b.
Reserved 31:10 0x0 Reserved.
Write 0x0, ignore on read.
Programming Interface — Ethernet Controller I210
533
8.24.1 Parity and ECC Error Indication- PEIND (0x1084; RC)
8.24.2 Parity and ECC Indication Mask - PEINDM (0x1088; RW)
Field Bit(s) Initial Value Description
lanport_parity_fatal_ind (LH) 0 0b Fatal Error detected in LAN port memory.
Bit is latched high and cleared on read.
mng_parity_fatal_ind (RC) 1 0b Fatal Error detected in management memory.
Bit is latched high and cleared on read.
pcie_parity_fatal_ind (RC) 2 0b Fatal Error detected in PCIe memory.
Bit is latched high and cleared on read.
dma_parity_fatal_ind (RC) 3 0b Fatal Error detected in DMA memory.
Bit is latched high and cleared on read.
Reserved 31:4 0x0 Reserved.
Write 0x0 ignore on read.
Field Bit(s) Initial Value Description
lanport_parity_fatal_ind 0 1b When set and PEIND.lanport_parity_fatal_ind is set, enable interrupt
generation by setting the ICR.FER bit.
mng_parity_fatal_ind 1 1b When set and PEIND.mng_parity_fatal_ind is set, enable interrupt
generation by setting the ICR.FER bit.
pcie_parity_fatal_ind 2 1b When set and PEIND.pcie_parity_fatal_ind is set, enable interrupt
generation by setting the ICR.FER bit.
dma_parity_fatal_ind 3 1b When set and PEIND.dma_parity_fatal_ind is set, enable interrupt
generation by setting the ICR.FER bit.
Reserved 31:4 0x0 Reserved.
Write 0x0, ignore on read.
Ethernet Controller I210 — Programming Interface
534
8.24.3 Packet Buffer ECC Status - PBECCSTS (0x245c; R/W)
8.24.4 PCIe Parity Control Register - PCIEERRCTL (0x5BA0; RW)
8.24.5 PCIe Parity Status Register - PCIEERRSTS (0x5BA8; R/W1C)
Register logs uncorrectable parity errors detected in PCIe logic.
Field Bit(s) Init. Description
ecc_en 0 0x1 ECC Enable.
Reserved 1 0x0 Reserved
Write 0, ignore on read.
pb_cor_err_sta(R/
W1C) 2 0x0 DBU RAM correctable error indication.
Bit is clean by write 1b.
Reserved 31:3 0x0 Reserved.
Write 0x0, ignore on read.
Field Bit(s) Initial
Value Description
GPAR_EN 0 0b1
1. Bit loaded from Flash.
Global Parity Enable.
When cleared, parity checking of all RAMs is disabled.
Note: This bit resets only at LAN_PWR_GOOD.
Reserved 5:1 01000b Reserved.
Write 0x0, ignore on read.
ERR EN RX CDQ 0 6 1b RX CDQ 0 Parity Check Enable
Reserved 7 0b Reserved.
ERR EN RX CDQ 1 8 1b RX CDQ 1 Parity Check Enable.
Reserved 9 0b Reserved.
ERR EN RX CDQ 2 10 1b RX CDQ 2 Parity Check Enable.
Reserved 11 0b Reserved.
ERR EN RX CDQ 3 12 1b RX CDQ 3 Parity Check Enable.
Reserved 31:13 0x0 Reserved.
Programming Interface — Ethernet Controller I210
535
8.24.6 PCIe ECC Control Register - PCIEECCCTL (0x5BA4; RW)
Field Bit(s) Initial
Value Description
Reserved 2:0 0x0 Reserved.
Write 0x0, ignore on read.
PAR ERR RX CDQ 0 3 0b
Rx CDQ 0 Parity Error.
Indicates detection of parity error in RAM if PCIEERRCTL.ERR EN RX CDQ 0 is set.
When set, stops all PCIe and DMA Rx and Tx activity from the function. To recover from
this condition, the software device driver should issue a software reset by asserting
CTRL.RST and re-initializing the port (refer to Section 7.6.1.1).
Note: PEIND.pcie_parity_fatal_ind and ICR.FER interrupts are asserted if bits are not
masked.
PAR ERR RX CDQ 1 4 0b
Rx CDQ 1 Parity Error.
Indicates detection of parity error in RAM if PCIEERRCTL.ERR EN RX CDQ 1 is set.
When set, stops all PCIe and DMA Rx and Tx activity from the function. To recover from
this condition, the software device driver should issue a software reset by asserting
CTRL.RST and re-initializing the port (refer to Section 7.6.1.1).
Note: PEIND.pcie_parity_fatal_ind and ICR.FER interrupts are asserted if bits are not
masked.
PAR ERR RX CDQ 2 5 0b
RX CDQ 2 Parity Error.
Indicates detection of parity error in RAM if PCIEERRCTL.ERR EN RX CDQ 2 is set.
When set, stops all PCIe and DMA Rx and Tx activity from the function. To recover from
this condition, the software device driver should issue a software reset by asserting
CTRL.RST and re-initializing the port (refer to Section 7.6.1.1).
Note: PEIND.pcie_parity_fatal_ind and ICR.FER interrupts are asserted if bits are not
masked.
PAR ERR RX CDQ 3 6 0b
RX CDQ 3 Parity Error.
Indicates detection of parity error in RAM if PCIEERRCTL.ERR EN RX CDQ 3 is set.
When set, stops all PCIe and DMA Rx and Tx activity from the function. To recover from
this condition, the software device driver should issue a software reset by asserting
CTRL.RST and re-initializing the port (refer to Section 7.6.1.1).
Note: PEIND.pcie_parity_fatal_ind and ICR.FER interrupts are asserted if bits are not
masked.
Reserved 31:7 0x0 Reserved.
Write 0x0, ignore on read.
Field Bit(s) Initial
Value Description
Reserved 11:0 0x511 Reserved.
ERR EN TX WR DATA 12 1b Tx Write Request Data ECC Check Enable.
Reserved 13 0b Reserved.
ERR EN RETRY BUF 14 1b Tx Retry Buffer ECC Check Enable.
Reserved 31:15 0x0 Reserved.
Write 0x0, Ignore on read.
Ethernet Controller I210 — Programming Interface
536
8.24.7 PCIe ECC Status Register - PCIEECCSTS (0x5BAC; R/W1C)
8.24.8 PCIe ACL0 and ACL1 Register - PCIACL01 (0x5B7C; RO to Host)
Note: Reset by PCIe reset.
8.24.9 PCIe ACL2 and ACL3 Register - PCIACL23 (0x5B80; RO to Host)
Note: Reset by PCIe reset.
8.24.10 LAN Port Parity Error Control Register - LANPERRCTL (0x5F54;
RW)
Field Bit(s) Initial
Value Description
Reserved 3:0 0 Reserved
ECC ERR TX WR DATA 4 0b Tx Write Request Data ECC Correctable Error
ECC ERR RETRY BUF 5 0b TX Retry Buffer ECC Correctable Error
Reserved 31:6 0x0 Reserved
Write 0, ignore on read
Field Bit(s) Initial
Value Description
ACL0 15:0 0 One of the four ACLs.
ACL1 31:16 0 One of the four ACLs.
Field Bit(s) Initial
Value Description
ACL2 15:0 0 One of the four ACLs.
ACL3 31:16 0 One of the four ACLs.
Field Bit(s) Initial
Value Description
Reserved 8:0 0x0 Reserved.
Write 0x0, ignore on read.
retx_buf_en 9 1b
Enable retx_buf parity error indication
When set to 1b, enables the RETX buffer (re-transmit buffer) parity error detection and
indication.
Reserved 31:10 0x0 Reserved.
Write 0x0, ignore on read.
Programming Interface — Ethernet Controller I210
537
8.24.11 LAN Port Parity Error Status Register - LANPERRSTS (0x5F58; R/
W1C)
8.25 Power Management Register Description
The following registers are used to control various power saving features.
8.25.1 DMA Coalescing Control Register - DMACR (0x2508; R/W)
Field Bit(s) Initial
Value Description
Reserved 8:0 0x0 Reserved.
Write 0x0, ignore on read.
retx_buf 9 0b
retx_buf Parity Error Indication.
When set to 1b, indicates detection of parity error in the RETX buffer (re-transmit buffer)
RAM if LANPERRCTL.retx_buf_en is set.
When set, disables packet transmission. To recover from this condition, the software
device driver should issue a software reset by asserting CTRL.RST and re-initializing the
port.
Note: PEIND.lanport_parity_fatal_ind and ICR.FER interrupts are asserted if bits are
not masked.
Reserved 31:10 0x0 Reserved.
Write 0x0, ignore on read.
Field Bit(s) Initial Value Description
DMACWT 13:0 0x20
DMA Coalescing Watchdog Timer.
When in DMA coalescing, the value in the DMACR.DMACWT counter sets the upper
limit in 32.768 µs units between receive packet arrival as well as the request to
transmit or issue an interrupt cause to move out of DMA coalescing.
Note: If the value is 0x0, a condition to move out of DMA coalescing is a result of
the watchdog timer expiration being disabled.
Reserved 14 0b Reserved.
DC_BMC2OSW_EN 15 1b
DMA Coalescing MC-to-OS Watchdog Enable.
When set to 1b, MC-to-OS traffic activate the DMA coalescing watchdog timer
(DMACR.DMACWT).
Note: If the DMA coalescing watchdog timer is disabled and this bit is set 1b, any
MC-to-OS traffic causes a move out of the DMA coalescing state.
DMACTHR 23:16 0x0
DMA Coalescing Receive Threshold.
This value defines the DMA coalescing receive threshold in 1 KB units. When the
amount of data in the internal receive buffer exceeds the DMACTHR value, DMA
coalescing is stopped and PCIe moves to the L0 state.
Notes:
1. This value should be lower than the FCRTC.RTH_Coal threshold value to avoid
generating needless flow control packets when in DMA coalescing operating
mode and flow control is enabled.
2. The receive threshold size should be smaller than the internal receive buffer area
reported in the RXPBSIZE.RXPbsize field.
3. If the value is 0x0, condition to move out of DMA coalescing as a result of
passing DMA coalescing receive threshold is disabled.
4. The value programmed should be greater than maximum packet size.
Reserved 24 0b Reserved.
Write 0b, ignore on read.
Ethernet Controller I210 — Programming Interface
538
8.25.2 DMA Coalescing Transmit Threshold - DMCTXTH (0x3550;RW)
EXIT_DC (SC) 25 0b
Exit DMA Coalescing.
Software can initiate a one time move out of the DMA coalescing state by setting this
bit to 1b.
OBFF_STATUS
(RO) 27:26 00b
OBFF Status.
This field reflects the OBFF status as decoded by the PCIe:
00b = OBFF_DISABLE, OBFF is disabled.
01b = OBFF_ACTIVE, OBFF active mode - no coalescing done.
10b = OBFF_IDLE, OBFF idle mode - do not transmit anything.
11b = OBFF_OBFF, OBFF mode - transmit data, but no interrupts.
Reserved 29:28 11b Reserved.
Write 11b, ignore on read.
Reserved 30 0b Reserved.
Write 0b, ignore on read.
DMAC_EN 31 0b
DMA Coalescing Enable.
0b = Disable DMA Coalescing.
1b = Enable DMA Coalescing.
Field Bit(s) Initial Value Description
DMCTTHR 11:0 0xE4
DMA Coalescing Transmit Threshold.
This value defines the DMA coalescing transmit threshold in 64 byte units. When the
amount of empty space in the internal transmit buffer exceeds the DMCTTHR value
and additional transmit data is available in main memory, DMA coalescing is stopped
and PCIe moves to an L0 state.
Notes:
1. If this value is 0x0 or smaller than the maximum transmit packet size, as defined
in the DTXMXPKTSZ.MAX_TPKT_SIZE field, a condition to move out of DMA
coalescing due to the passing of the DMA coalescing transmit threshold level is
disabled.
2. The transmit threshold size should be smaller than the internal transmit buffer
area reported in the TXPBSIZE field.
Reserved 31:12 0b Reserved.
Write 0x0, ignore on read.
Field Bit(s) Initial Value Description
Programming Interface — Ethernet Controller I210
539
8.25.3 DMA Coalescing Management Threshold - DMCMNGTH
(0x8F30;RW)
8.25.4 DMA Coalescing Time to Lx Request - DMCTLX (0x2514;RW)
8.25.5 DMA Coalescing Current Rx Count - DMCCNT (0x5DD4;RO)
Field Bit(s) Initial Value Description
Reserved 3:0 0b Reserved.
Write 0x0, ignore on read.
DMCMNGTHR 19:4 0x100
DMA Coalescing Management Threshold.
This value defines the DMA coalescing management threshold in 16 byte units. When
the amount of empty space in the internal transmit buffer exceeds the DMCMNGTHR
value, DMA coalescing is stopped and PCIe moves to an L0 state.
Note: If this value is 0x0, a condition to move out of DMA coalescing due to the
passing of the DMA coalescing management threshold level is disabled.
Under some conditions, there can be a deviation of up to 16-bytes from the
value written in this field.
Reserved 31:20 0b Reserved.
Write 0x0, ignore on read.
Field Bit(s) Initial Value Description
Reserved 11:0 0x20 Reserved.
Write 0x20, ignore on read.
EN_MNG_IND 12 0b
Enable Management Indications for OBFF Operation.
When set, OBFF and DMA coalescing functionality is affected from the management
buffer status indications.
Reserved 30:13 Reserved.
Write 0x0, ignore on read.
DCFLUSH_DIS 31 0b
Disable DMA Coalescing Flush.
When this bit is set, the flush of pending interrupts and pending descriptor write-back
operations before entry into DMA Coalescing (refer to Section 5.9.2.1) is disabled.
Field Bit(s) Initial Value Description
CCOUNT 24:0 0x0
DMA Coalescing Receive Traffic Current Count.
Represents the count of receive traffic in the current time interval in units of 64-byte
segments. Refer to Section 5.9 for additional information.
Note: Counter does not wrap around.
RSVD 31:25 0x0 Reserved.
Write 0x0, ignore on read.
Ethernet Controller I210 — Programming Interface
540
8.25.6 Flow Control Receive Threshold Coalescing - FCRTC (0x2170; R/
W)
8.25.7 DMA OBFF Control Register - DOBFFCTL (0x3F24;Rw)
8.25.8 DMA Coalescing Clock Control Time Counter - DMACTC (0x5DC8;
RO)
This register keeps track of the number of time units elapsed since the end of last time interval.
Field Bit(s) Initial Value Description
Reserved 3:0 0x0 Reserved.
Write 0x0 ignore on read.
RTH_Coal 17:4 0x0
Flow control receive threshold high watermark value used to generate a XOFF flow
control packet when executing DMA coalescing, internal transmit FIFO is empty and
transmit flow control is enabled (CTRL.TFCE = 1b). When previous conditions exist, a
XOFF packet is sent if the occupied space in the Rx packet buffer is more or equal to
this watermark.
This field is in 16 bytes granularity.
Refer to Section 3.7.5.3.1to calculate the FCRTC.RTH_Coal value.
Notes:
1. To avoid sending XOFF flow control packets needlessly when executing DMA
coalescing and the internal transmit buffer is empty, the value should be higher
than the threshold defined in the DMACR.DMACTHR field. Maximum threshold
value can be up to FCRTH0.RTH + maximum allowable packet size * 1.25.
2. RTH_Coal threshold value is used as a watermark for sending flow control
packets when DMA coalescing is enabled and the internal transmit buffer is
empty.
3. The value programmed should be greater than the maximum packet size.
Reserved 31:18 0x0 Reserved
Write 0 ignore on read.
Field Bit(s) Initial Value Description
OBFFTHR 7:0 0x0
DMA OBFF Threshold.
Defines the low threshold that the Rx buffer needs to pass to initiate a new transaction
when in OBFF mode. It is expressed in KB units.
IDLTO 15:8 0x20 Idle Timeout.
Defines the amount of idle cycles before starting coalescing entry flow
ACTTO 23:16 0x02 Active Timeout.
Defines the amount of non-idle cycles before stopping coalescing entry flow
Reserved 31:24 0x0 Reserved.
Field Bit(s) Initial Value Description
COUNT 9:0 0x0
SC Time Counter.
The counter for the number of time units elapsed since the end of the last time
interval.
RSVD 31:10 0x0 Reserved.
Programming Interface — Ethernet Controller I210
541
8.25.9 Latency Tolerance Reporting (LTR) Minimum Values - LTRMINV
(0x5BB0; R/W)
Field Bit(s) Initial Value Description
LTRV 9:0 0x5
Latency Tolerance Value.
This field indicates the latency tolerance supported when conditions for minimum
latency tolerance exist (Refer to Section 5.11.2.1).
LTRV values are multiplied by 32,768 ns or 1,024 ns depending on the Scale field, to
indicate latency tolerance supported in nanoseconds. A value of 0 indicates that the
device is impacted by any delay and that best possible service is requested.
The I210 reports the same value for both snoop and no snoop requirements. If no
memory latency requirement exists for either snoop or no snoop accesses, the
appropriate Requirement bit is cleared.
Note: Software should subtract time required to move from L1 to L0 from LTR value.
Scale 12:10 011b
Latency Scale.
This field provides a scale for the value contained within the LTRMINV.LTRV field.
Encoding:
010b = LTRV value times 1,024 ns.
011b = LTRV value times 32,768 ns.
Others = Reserved.
Reserved 14:13 0x0 Reserved.
Write 0x0, ignore on read.
LSNP
Requirement 15 0b
LTR Snoop Requirement.
0b = No latency requirements in snoop memory access.
1b = Latency tolerance in snoop memory access specified in LTRMINV.LTRV field.
Reserved 30:16 0x0 Reserved.
Write 0x0, ignore on read.
LNSNP
Requirement 31 0b
LTR Non-snoop Requirement.
0b = No latency requirements in non-snoop memory access.
1b = Latency tolerance in non-snoop memory access specified in LTRMINV.LTRV field.
Ethernet Controller I210 — Programming Interface
542
8.25.10 Latency Tolerance Reporting (LTR) Maximum Values - LTRMAXV
(0x5BB4; R/W)
Field Bit(s) Initial Value Description
LTRV 9:0 0x5
Latency Tolerance Value.
This field indicates the latency tolerance supported when conditions for maximum
latency tolerance exist (Refer to Section 5.11.2.2).
LTRV values are multiplied by 32,768 ns or 1,024 ns depending on the Scale field to
indicate latency tolerance supported in nanoseconds. A value of 0 indicates that the
device is impacted by any delay and that the best possible service is requested.
The I210 reports the same value for both snoop and no snoop requirements. If no
memory latency requirement exists for either snoop or no snoop, accesses the
appropriate Requirement bit is cleared.
Note: Software should subtract the time required to move from L1 to L0 from LTR
value.
Scale 12:10 011b
Latency Scale.
This field provides a scale for the value contained within the LTRMAXV.LTRV field.
Encoding:
010b = LTRV value times 1,024 ns.
011b = LTRV value times 32,768 ns.
Others = Reserved.
Reserved 14:13 0x0 Reserved.
Write 0x0, ignore on read.
LSNP
Requirement 15 0b
LTR Snoop requirement
0b = No latency requirements in snoop memory access.
1b = Latency tolerance in snoop memory access specified in LTRMAXV.LTRV field.
Reserved 30:16 0x0 Reserved.
Write 0x0, ignore on read.
LNSNP
Requirement 31 0b
LTR Non-snoop Requirement.
0b = No latency requirements in non-snoop memory access.
1b = Latency tolerance in non-snoop memory access specified in LTRMAXV.LTRV field.
Programming Interface — Ethernet Controller I210
543
8.25.11 Latency Tolerance Reporting (LTR) Control - LTRC (0x01A0; R/
W)
Field Bit(s) Initial Value Description
Reserved 0 0b Reserved.
Write 0b, ignore on read.
LTR_MIN 1 0b
LTR Send Minimum Values.
When set to 1b, the I210 sends a PCIe LTR message with the LTR snoop value, LTR
no-snoop value and LTR requirement bits as defined in the LTRMINV register.
Notes:
1. To resend a LTR message with the minimum value defined in the LTRMINV
register, this bit should be cleared and set again.
2. LTR_MIN and LTR_MAX bits are exclusive.
3. A new PCIe LTR message is sent only if the last PCIe LTR message sent had a
latency tolerance value different then the value specified in the LTRMINV register.
LTR_MAX 2 0b
LTR Send Maximum Values.
When set to 1b, the I210 sends a PCIe LTR message with the LTR snoop value, LTR
no-snoop value and LTR requirement bits as defined in the LTRMAXV register.
Notes:
1. To resend a LTR message with the maximum value defined in the LTRMAXV
register, this bit should be cleared and set again.
2. LTR_MIN and LTR_MAX bits are exclusive.
3. A new PCIe LTR message is sent only if the last PCIe LTR message sent had a
latency tolerance value different then the value specified in the LTRMAXV
register.
PDLS_EN 3 1b
Port Disable LTR Send Enable.
0b = Do not issue a PCIe LTR message with requirement bits cleared on port disable
(Rx and Tx disabled).
1b = Issue a PCIe LTR message with requirement bits cleared on port disable (Rx and
Tx disabled).
LNKDLS_EN 4 1b
Link Disconnect LTR Send Enable.
0b = Do not issue a PCIe LTR message with requirement bits cleared on link
disconnect.
1b = Issue a PCIe LTR message with requirement bits cleared on link disconnect.
EEEMS_EN 5 0b
EEE LPI LTR Max Send Enable.
When this bit is set and link is in a Rx EEE LPI (Low Power Idle) state, the I210 sends
a PCIe LTR message with the LTR snoop value, LTR no-snoop value and LTR
requirement bits as defined in the LTRMAXV register.
0b = Do not issue a PCIe LTR messages with the LTRMAXV value as a result of Rx link
entering EEE LPI state.
1b=Issue PCIe LTR messages with a LTRMAXV value as a result of Rx link entering EEE
LPI state.
Note: This bit is reset to 0b by hardware following link disconnect to enable
software to re-negotiate Tw_system time and update the LTRMAXV value.
Reserved 31:6 0x0 Reserved.
Write 0x0, ignore on read.
Ethernet Controller I210 — Programming Interface
544
8.25.12 Energy Efficient Ethernet (EEE) Register - EEER (0x0E30; R/W)
Field Bit(s) Initial Value Description
Tw_system 15:0 0x0
Time expressed in microseconds that no data is transmitted following a move
from the EEE TX LPI link state to a link active state. This field holds the transmit
Tw_sys_tx value negotiated during EEE LLDP negotiation.
Notes:
1. If this value is lower than the minimum Tw_sys_tx value defined in
IEEE802.3az clause 78.5 (30 s for 100BASE-TX and 16.5 s for 1000BASE-
T) then the interval where no data is transmitted following a move out of
the EEE TX LPI state defaults to a minimum Tw_sys_tx .
2. Following a link disconnect or auto-negotiation the value of this field returns
to its default value until software re-negotiates a new tw_sys_tx value via
EEE LLDP.
Note: When transmitting flow control frames, the I210 waits the minimum
time defined in the IEEE802.3az standard before transmitting a flow
control packet. The I210 does not wait the Tw_system time following an
exit of LPI before transmitting a flow control frame.
TX_LPI_EN 16 0b1
Enable Entry into EEE LPI on Tx Path.
0b = Disable entry into EEE LPI on Tx path.
1b = Enable entry into EEE LPI on Tx path.
Refer to Section 3.7.7.1 for additional information on EEE Tx LPI entry.
Notes:
1. Even when TX_LPI_EN is set to 1b, the I210 will not enable entry into the
Tx LPI state for at least 1 second following the change of link_status to OK
as defined in IEEE802.3az clause 78.1.2.1.
2. Even if the TX_LPI_EN bit is set, the I210 initiates entry into the Tx EEE LPI
link state only if EEE support at the link speed was negotiated during auto-
negotiation.
RX_LPI_EN 17 1b
Enable Entry into EEE LPI on Rx Path
0b = Disable entry into EEE LPI on Rx path.
1b = Enable entry into EEE LPI on Rx path.
Notes:
1. Even if the RX_LPI_EN bit is set, the I210 recognizes entry into Rx EEE LPI
link state only if EEE support at the link speed was negotiated during auto-
negotiation.
2. When set and link moves into Rx LPI, a LTR message with the value defined
in the LTRMAXV register is sent on the PCIe, if LTRC.EEEMS_EN is set.
LPI_FC 18 1b
Enable EEE Tx LPI Entry on Flow Control.
Enable EEE Tx LPI state entry when the link partner sent a PAUSE flow control
frame, even if the internal transmit buffer is not empty, transmit descriptors are
available or management traffic is pending.
Notes:
1. The I210 enters the Tx LPI state when no data is transmitted and not in
mid-packet.
2. Entry into Tx LPI on flow control is enabled only if either EEER.TX_LPI_EN is
set to 1b or EEER.Force_TLPI is set to 1b.
3. Receiving XON frame causes a move out of LPI if a transmit is pending.
Force_TLPI 19 0b
Force Tx LPI.
When set, the PHY is forced into the EEE Tx LPI state if there is no Tx
management traffic.
Notes:
1. The I210 enters the Tx LPI state when no data is transmitted and not in
mid-packet.
2. When set, the I210 enters Tx LPI even if EEER.TX_LPI_EN is set to 0b.
Reserved 27:20 0x0 Reserved.
Write 0x0, ignore on read.
Programming Interface — Ethernet Controller I210
545
8.26 Diagnostic Registers Description
8.26.1 PCIe Misc. Register - PCIEMISC (0x5BB8; RW)
Note: Reset by PCIe power good reset.
8.27 PHY Software Interface
8.27.1 Internal PHY Configuration - IPCNFG (0x0E38, RW)
The IPCNFG register controls PHY configuration.
EEE_FRC_AN 28 0b
Force EEE Auto-negotiation.
When this bit is set to 1b,it enables EEE operation in the internal MAC logic even
if the link partner does not support EEE. Should be set to 1b to enable testing of
EEE operation via MAC loopback (refer to y).
EEE NEG (RO) 29 X
EEE Support Negotiated on Link.
0b = EEE operation not supported on link.
1b = EEE operation supported on link.
Note: Status reported by this bit shall be ignored when the port is operated in
half duplex mode.
RX LPI Status (RO) 30 X
Rx Link in LPI State.
0b = Rx in active state.
1b = Rx in LPI state.
TX LPI Status (RO) 31 X
Tx Link in LPI State.
0b = Tx in active state.
1b = Tx in LPI state.
1. Loaded from Flash.
Field Bit(s) Initial
Value Description
Reserved 8:0 0x8A Reserved
Ignore on read, write 0x8A.
DMA Idle Indication 9 0b1
1. Value loaded from Flash.
Pulses shorter than the filter width are ignored.
Indication For DMA Idle
This bit indicates when DMA is considered idle (either when the DMA is idle or when PCIe
Link is idle).
0b = DMA is considered idle when there is no Rx or Tx.
1b = DMA is considered idle when there is no Rx or Tx AND when there are no TLPs
indicating that CPU is active detected on the PCIe link (such as the host executes CSR or
Configuration register read or write operation).
Note: The bit must be set to 1b each time programming the Flash via CSR accesses.
Reserved 31:10 0x122 Reserved
Ignore on read, write 122.
Field Bit(s) Initial Value Description
Ethernet Controller I210 — Programming Interface
546
8.27.2 PHY Power Management - PHPM (0x0E14, RW)
The PHPM register controls internal PHY power management operation.
Field Bit(s) Initial Value Description
Enable Automatic
Crossover 0 1b1
1. Bit Loaded from bit 9 in the Initialization Control 3 Flash word at power up.
When set, the device automatically determines whether or not it needs to
cross over between pairs so that an external cross-over cable is not
required.
10BASE-TE 1 0b2
2. Loaded from Flash.
Enable Low Amplitude 10BASE-T Operation.
Setting this bit enables the I210 to operate in IEEE802.3az 10BASE-Te low
power operation.
0b = 10BASE-Te operation disabled.
1b = 10BASE-Te operation enabled.
Note: When operating in 10BASE-T mode and with this bitset,
supported cable length is reduced.
EEE_100M_AN 2 1b2
Report EEE 100 Mb/s Capability in Auto-negotiation
0b = Do not report EEE 100 Mb/s capability in auto-negotiation.
1b = Report EEE 100 Mb/s capability in auto-negotiation.
Note: Changing value of bit causes link drop and re-negotiation.
EEE_1G_AN 3 1b2
Report EEE 1 GbE Capability in Auto-negotiation.
0b = Do not report EEE 1 GbE capability in auto-negotiation.
1b = Report EEE 1 GbE capability in auto-negotiation.
Note: Changing the value of this bit causes link drop and re-
negotiation.
Reserved 31:4 0x0 Reserved.
Write 0x0, ignore on read.
Field Bit(s) Initial Value Description
SPD_EN 0 1b
Smart Power Down.
When set, enables PHY Smart Power Down mode.
This bit is loaded from the SPD Enable bit in the Initialization Control 4
Flash word on reset.
D0LPLU 1 0b
D0 Low Power Link Up (LPLU).
When set, configures the PHY to negotiate for a low speed link in all
states.
LPLU 2 1b
Low Power on Link Up.
When set, enables the decrease in link speed while in non-D0a states
when the power policy and power management state specify it.
This bit is loaded from the LPLU bit in the Initialization Control 4 Flash
word on reset.
Disable 1000 in non-D0a 3 1b
Disables 1000 Mb/s operation in non-D0a states.
This bit is loaded from the Disable 1000 in non-D0a bit in the Software
Defined Pins Control Flash word on reset.
Link Energy Detect (RO,
LH) 4 0b
This bit is set when the PHY detects energy on the link. Note that this bit
is valid only if the PHPM.Go Link disconnect bit is set to 0b.
When PHPM.Go Link disconnect =1b, PHPM.link_energy_detect is fixed at
1b at all the link states.
Go Link disconnect 5 0b Setting this bit causes the PHY to enter link disconnect mode immediately.
Programming Interface — Ethernet Controller I210
547
8.27.3 Internal PHY Software Interface (PHYREG)
1. Base registers (page 0, registers 0 through 10 and 15) are defined in accordance with the
Reconciliation Sub layer and Media Independent Interface and Physical Layer Link Signaling for 10/
100/ 1000 Mb/s Auto-Negotiation sections of the IEEE 802.3 specification.
2. Additional registers are defined in accordance with the IEEE 802.3 specification for adding unique
chip functions.
3. Registers in the following table are accessed using the internal MDIO interface via the MDIC register
(Refer to Section 8.2.4).
Disable 1000 6 0b
When set, disables 1000 Mb/s in all power modes.
This bit is loaded from the Giga Disable bit in the Software Defined Pins
Control Flash word on reset.
SPD_B2B_EN 7 1b SPD Back-to-Back Enable.
rst_compl (RO, LH) 8 0b Indicates PHY internal reset cleared.
Disable 100 in non-D0a 9 0b
Disables 100 Mb/s and 1000 Mb/s operation in non-D0a states.
This bit is loaded from the Disable 100 in non-D0a bit in the Software
Defined Pins Control Flash word on reset.
Reserved 31:10 0x0 Reserved.
Write 0x0, ignore on read.
Register Name Register Address Section and Page
Copper Control Register Page 0, Register 0 section 8.27.3.1 on page 548.
Copper Status Register Page 0, Register 1 section 8.27.3.2 on page 550.
PHY Identifier 1 Page 0, Register 2 section 8.27.3.3 on page 551.
PHY Identifier 2 Page 0, Register 3 section 8.27.3.4 on page 551.
Copper Auto-Negotiation Advertisement Register Page 0, Register 4 section 8.27.3.5 on page 551.
Copper Link Partner Ability Register - Base Page Page 0, Register 5 section 8.27.3.6 on page 553.
Copper Auto-Negotiation Expansion Register Page 0, Register 6 section 8.27.3.7 on page 554.
Copper Next Page Transmit Register Page 0, Register 7 section 8.27.3.8 on page 555.
Copper Link Partner Next Page Register Page 0, Register 8 section 8.27.3.9 on page 555.
1000BASE-T Control Register Page 0, Register 9 section 8.27.3.10 on page 556.
1000BASE-T Status Register Page 0, Register 10 section 8.27.3.11 on page 557.
MMD Access Control Register Page 0, Register 13 section 8.27.3.12 on page 558.
MMD Access Address/Data Register Page 0, Register 14 section 8.27.3.13 on page 558.
Extended Status Register Page 0, Register 15 section 8.27.3.14 on page 558.
Copper Specific Control Register 1 Page 0, Register 16 section 8.27.3.15 on page 558.
Copper Specific Status Register 1 Page 0, Register 17 section 8.27.3.16 on page 560.
Copper Specific Interrupt Enable Register Page 0, Register 18 section 8.27.3.17 on page 561.
Copper Interrupt Status Register Page 0, Register 19 section 8.27.3.18 on page 562.
Copper Specific Control Register 2 Page 0, Register 20 section 8.27.3.19 on page 563.
Copper Specific Receive Error Counter Register Page 0, Register 21 section 8.27.3.20 on page 563.
Page Address Page Any, Register 22 section 8.27.3.21 on page 563.
Copper Specific Control Register 3 Page 0, Register 23 section 8.27.3.22 on page 564.
Field Bit(s) Initial Value Description
Ethernet Controller I210 — Programming Interface
548
8.27.3.1 Copper Control Register - Page 0, Register 0
MAC Specific Control Register 1 Page 2, Register 16 section 8.27.3.23 on page 565.
MAC Specific Interrupt Enable Register Page 2, Register 18 section 8.27.3.24 on page 565.
MAC Specific Status Register Page 2, Register 19 section 8.27.3.25 on page 566.
Copper RX_ER Byte Capture Page 2, Register 20 section 8.27.3.26 on page 566.
MAC Specific Control Register 2 Page 2, Register 21 section 8.27.3.27 on page 567.
jt_led_s[3:0] Function Control Register Page 3, Register 16 section 8.27.3.28 on page 568.
jt_led_s[3:0] Polarity Control Register Page 3, Register 17 section 8.27.3.29 on page 570.
LED Timer Control Register Page 3, Register 18 section 8.27.3.30 on page 570.
jt_led_s[5:4] Function Control and Polarity Register Page 3, Register 19 section 8.27.3.31 on page 571.
1000BASE-T Pair Skew Register Page 5, Register 20 section 8.27.3.32 on page 572.
1000BASE-T Pair Swap and Polarity Page 5, Register 21 section 8.27.3.33 on page 573.
Copper Port Packet Generation Page 6, Register 16 section 8.27.3.34 on page 573.
Copper Port CRC Counters Page 6, Register 17 section 8.27.3.35 on page 574.
Checker Control Page 6, Register 18 section 8.27.3.36 on page 574.
Misc Test Page 6, Register 26 section 8.27.3.37 on page 574.
Bits Field Mode HW Rst SW Rst Description
15 Copper Reset R/W, SC 0x0 SC
Copper Software Reset.
Affects pages 0, 2, 3, 5, and 7. Writing a 1b to this bit causes the
PHY state machines to be reset. When the reset operation
completes, this bit is cleared to 0b automatically. The reset occurs
immediately.
1b = PHY reset.
0b = Normal operation.
14 Loopback R/W 0x0 0x0
When loopback is activated, the transmitter data presented on
TXD is looped back to RXD internally. Link is broken when
loopback is enabled. Loopback speed is determined by Registers
21_2.2:0.
1b = Enable loopback.
0b = Disable loopback.
13 Speed Select
(LSB) R/W 0x0 Update
Changes to this bit are disruptive to the normal operation. As a
result, any changes to these registers must be followed by a
software reset to take effect.
A write to this register bit does not take effect until any one of the
following also occurs:
Software reset is asserted (register 0_0.15).
Restart auto-negotiation is asserted (register 0_0.9).
Power down (register 0_0.11, 16_0.2) transitions from power
down to normal operation.
Bits 6and 13:
11b = Reserved.
10b = 1000 Mb/s.
01b = 100 Mb/s.
00b = 10 Mb/s.
Programming Interface — Ethernet Controller I210
549
12 Auto-Negotiation
Enable R/W 0x1 Update
Changes to this bit are disruptive to the normal operation. A write
to this register bit does not take effect until any one of the
following occurs:
Software reset is asserted (register 0_0.15).
Restart auto-negotiation is asserted (register 0_0.9).
Power down (register 0_0.11, 16_0.2) transitions from power
down to normal operation.
If register 0_0.12 is set to 0b and speed is manually forced to
1000 Mb/s in registers 0.13 and 0.6, then auto-negotiation is still
enabled and only 1000BASE-T full-duplex is advertised if register
0_0.8 is set to 1b, and 1000BASE-T half-duplex is advertised if
0.8 is set to 0.
Registers 4.8:5 and 9.9:8 are ignored. Auto-negotiation is
mandatory per IEEE for proper operation in 1000BASE-T.
1b = Enable auto-negotiation process.
0b = Disable auto-negotiation process.
11 Power Down R/W Retain
Power down is controlled via register 0_0.11 and 16_0.2. Both
bits must be set to 0b before the PHY transitions from power
down to normal operation.
When the port is switched from power down to normal operation,
software reset and restart auto-negotiation are performed even
when bits Reset (0_0.15) and Restart Auto-Negotiation (0_0.9)
are not set by the user.
1b = Power down.
0b = Normal operation.
10 Isolate RO 0x0 0x0 This bit has no effect.
9 Restart Copper
Auto-Negotiation R/W, SC 0x0 SC
Auto-negotiation automatically restarts after hardware or
software reset regardless of whether or not the restart bit (0.9) is
set.
1b = Restart auto-negotiation process.
0b = Normal operation.
8 Copper Duplex
Mode R/W 0x1 Update
Changes to this bit are disruptive to the normal operation.As a
result, any changes to these registers must be followed by a
software reset to take effect.
A write to this register bit does not take effect until any one of the
following also occurs:
Software reset is asserted (Register 0_0.15).
Restart Auto-Negotiation is asserted (Register 0_0.9).
Power down (Register 0_0.11, 16_0.2) transitions from
power down to normal operation.
1 = Full duplex.
0 = Half duplex.
Ethernet Controller I210 — Programming Interface
550
8.27.3.2 Copper Status Register - Page 0, Register 1
7 Collision Test RO 0x0 0x0 This bit has no effect.
6 Speed Selection
(MSB) R/W 0x1 Update
Changes to this bit are disruptive to the normal operation;.As a
result, any changes to these registers must be followed by a
software reset to take effect.
A write to this register bit does not take effect until any one of the
following occurs:
Software reset is asserted (Register 0_0.15).
Restart Auto-Negotiation is asserted (Register 0_0.9).
Power down (Register 0_0.11, 16_0.2) transitions from
power down to normal operation.
Bits 6 and 13:
11b = Reserved.
10b = 1000 Mb/s.
01b = 100 Mb/s.
00b = 10 Mb/s.
5:0 Reserved RO Always 0x0 Always
0x0 Reserved.
Bits Field Mode HW Rst SW Rst Description
15 100BASE-T4 RO Always 0b Always 0b 100BASE-T4. This protocol is not available.
0 = PHY not able to perform 100BASE-T4.
14 100BASE-X Full-
Duplex RO Always 1b Always 1b 1b = PHY able to perform full-duplex 100BASE-X.
13 100BASE-X Half-
Duplex RO Always 1b Always 1b 1b = PHY able to perform half-duplex 100BASE-X.
12 10 Mb/s Full-
Duplex RO Always 1b Always 1b 1b = PHY able to perform full-duplex 10BASE-T.
11 10 Mb/s Half-
Duplex RO Always 1b Always 1b 1b = PHY able to perform half-duplex 10BASE-T.
10 100BASE-T2 Full-
Duplex RO Always 0b Always 0b This protocol is not available.
0b = PHY not able to perform full-duplex.
9 100BASE-T2 Half-
Duplex RO Always 0b Always 0b This protocol is not available.
0b = PHY not able to perform half-duplex.
8 Extended Status RO Always 1b Always 1b 1b = Extended status information in register 15.
7 Reserved RO Always 0b Always 0b Reserved.
6 MF Preamble
Suppression RO Always 1b Always 1b 1b = PHY accepts management frames with preamble
suppressed.
5 Copper Auto-
Negotiation
Complete RO 0x0 0x0 1b = Auto-negotiation process complete.
0b = Auto-negotiation process not complete.
4 Copper Remote
Fault RO,LH 0x0 0x0 1b = Remote fault condition detected.
0b = Remote fault condition not detected.
3 Auto-Negotiation
Ability RO Always 1b Always 1b 1b = PHY able to perform Auto-Negotiation.
Programming Interface — Ethernet Controller I210
551
8.27.3.3 PHY Identifier 1 - Page 0, Register 2
8.27.3.4 PHY Identifier 2 - Page 0, Register 3
8.27.3.5 Copper Auto-Negotiation Advertisement Register - Page 0, Register 4
2 Copper Link
Status RO,LL 0x0 0x0
This register bit indicates when link was lost since the last read.
For the current link status, either read this register back-to-back
or read register 17_0.10 Link Real Time.
1b = Link is up.
0b = Link is down.
1 Jabber Detect RO,LH 0x0 0x0 1b = Jabber condition detected.
0b = Jabber condition not detected.
0 Extended
Capability RO Always 1b Always 1b 1b = Extended register capabilities.
Bits Field Mode HW Rst SW Rst Description
15:0 Organizationally
Unique Identifier
Bit 3:18 RO 0x0141 0x0141
Bits Field Mode HW Rst SW Rst Description
15:10 OUI LSB RO Always
000011b Always
000011b Organizationally Unique Identifier bits 19:24 00 0011.
^.........^
bit 19...bit24.
9:4 Model RO
Number
3:0 Revision Number RO
Bits Field Mode HW Rst SW Rst Description
15 Next Page R/W 0x0 Update
A write to this register bit does not take effect until any one of the
following occurs:
Software reset is asserted (register 0_0.15).
Restart auto-negotiation is asserted (register 0_0.9).
Power down (register 0_0.11, 16_0.2); transitions from power
down to normal operation and the copper link goes down.
If 1000BASE-T is advertised then the required next pages are
automatically transmitted. Register 4.15 should be set to 0b if no
additional next pages are needed.
1b = Advertise.
0b = Not advertised.
14 Ack RO Always
0b Always
0b Must be 0b.
Ethernet Controller I210 — Programming Interface
552
13 Remote Fault R/W 0x0 Update
A write to this register bit does not take effect until any one of the
following occurs:
Software reset is asserted (register 0_0.15).
Restart Auto-Negotiation is asserted (register 0_0.9).
Power down (register 0_0.11, 16_0.2); transitions from power
down to normal operation and the copper link goes down.
1b = Set remote fault bit.
0b= Do not set remote fault bit.
12 Reserved R/W 0x0 Update Reserved.
11 Asymmetric Pause R/W Update
A write to this register bit does not take effect until any one of the
following occurs:
Software reset is asserted (register 0_0.15).
Restart auto-negotiation is asserted (register 0_0.9).
Power down (register 0_0.11, 16_0.2); transitions from power
down to normal operation and the copper link goes down.
1b = Asymmetric pause.
0b = No asymmetric pause.
10 Pause R/W Update
A write to this register bit does not take effect until any one of the
following occurs:
Software reset is asserted (register 0_0.15).
Restart auto-negotiation is asserted (register 0_0.9).
Power down (register 0_0.11, 16_0.2); transitions from power
down to normal operation and the copper link goes down.
1b = Pause.
0b = No pause.
9 100BASE-T4 R/W 0x0 Retain 0b = Not capable of 100BASE-T4.
8 100BASE-TX Full-
Duplex R/W Update
A write to this register bit does not take effect until any one of the
following occurs:
Software reset is asserted (register 0_0.15).
Restart auto-negotiation is asserted (register 0_0.9).
Power down (register 0_0.11and 16_0.2); transitions from
power down to normal operation and the copper link goes
down.
If register 0_0.12 is set to 0b and speed is manually forced to 1000
Mb/s in registers 0_0.13 and 0_0.6, then auto-negotiation will still
be enabled and only 1000BASE-T full-duplex is advertised if
register 0_0.8 is set to 1b, and 1000BASE-T half-duplex is
advertised if 0_0.8 set to 0b.
Registers 4_0.8:5 and 9_0.9:8 are ignored. Auto-negotiation is
mandatory per IEEE for proper operation in 1000BASE-T.
1b = Advertise.
0b = Not advertised.
7 100BASE-TX Half-
Duplex R/W Update
A write to this register bit does not take effect until any one of the
following occurs:
Software reset is asserted (register 0_0.15).
Restart auto-negotiation is asserted (register 0_0.9).
Power down (register 0_0.11, 16_0.2); transitions from power
down to normal operation and the copper link goes down.
If register 0_0.12 is set to 0b and speed is manually forced to 1000
Mb/s in registers 0.13 and 0.6, then auto-negotiation will still be
enabled and only 1000BASE-T full-duplex is advertised if register
0_0.8 is set to 1b, and 1000BASE-T half-duplex is advertised if 0.8
set to 0b.
Registers 4.8:5 and 9.9:8 are ignored.
Auto-negotiation is mandatory per IEEE for proper operation in
1000BASE-T. 1b = Advertise.
0b = Not advertised.
Programming Interface — Ethernet Controller I210
553
8.27.3.6 Copper Link Partner Ability Register (Base Page) - Page 0, Register 5
6 10BASE-TX Full-
Duplex R/W Update
A write to this register bit does not take effect until any one of the
following occurs:
Software reset is asserted (register 0_0.15).
Restart auto-negotiation is asserted (register 0_0.9).
Power down (register 0_0.11, 16_0.2); transitions from power
down to normal operation and the copper link goes down.
If register 0_0.12 is set to 0b and speed is manually forced to 1000
Mb/s in registers 0_0.13 and 0_0.6, then auto-negotiation will still
be enabled and only 1000BASE-T full-duplex is advertised if
register 0_0.8 is set to 1b, and 1000BASE-T half-duplex is
advertised if 0_0.8 set to 0b.
Registers 4_0.8:5 and 9_0.9:8 are ignored.
Auto-negotiation is mandatory per IEEE for proper operation in
1000BASE-T. 1b = Advertise.
0b = Not advertised.
5 10BASE-TX Half-
Duplex R/W Update
A write to this register bit does not take effect until any one of the
following occurs:
Software reset is asserted (register 0_0.15).
Restart auto-negotiation is asserted (register 0_0.9).
Power down (register 0_0.11, 16_0.2); transitions from power
down to normal operation and the copper link goes down.
If register 0_0.12 is set to 0b and speed is manually forced to 1000
Mb/s in registers 0_0.13 and 0_0.6, then auto-negotiation will still
be enabled and only 1000BASE-T full-duplex is advertised if
register 0_0.8 is set to 1b, and 1000BASE-T half-duplex is
advertised if 0_0.8 set to 0b.
Registers 4_0.8:5 and 9_0.9:8 are ignored.
Auto-negotiation is mandatory per IEEE for proper operation in
1000BASE-T. 1b = Advertise.
0b = Not advertised.
4:0 Selector Field R/W 0x01 Retain Selector Field Mode.
00001b = 802.3.
Bits Field Mode HW Rst SW Rst Description
15 Next Page RO 0x0 0x0
Received Code Word Bit 15.
1b = Link partner capable of next page.
0b = Link partner not capable of next page.
14 Acknowledge RO 0x0 0x0
Acknowledge Received Code Word Bit 14.
1b = Link partner received link code word.
0b = Link partner does not have Next Page ability.
13 Remote Fault RO 0x0 0x0
Remote Fault Received Code Word Bit 13.
1b = Link partner detected remote fault.
0b = Link partner has not detected remote fault.
12 Technology Ability
Field RO 0x0 0x0 Received Code Word Bit 12.
11 Asymmetric Pause RO 0x0 0x0
Received Code Word Bit 11.
1b = Link partner requests asymmetric pause.
0b = Link partner does not request asymmetric pause.
10 Pause Capable RO 0x0 0x0
Received Code Word Bit 10.
1b = Link partner is capable of pause operation.
0b = Link partner is not capable of pause operation.
9 100BASE-T4
Capability RO 0x0 0x0
Received Code Word Bit 9.
1b = Link partner is 100BASE-T4 capable.
0b = Link partner is not 100BASE-T4 capable.
Ethernet Controller I210 — Programming Interface
554
8.27.3.7 Copper Auto-Negotiation Expansion Register - Page 0, Register 6
8 100BASE-TX Full-
Duplex Capability RO 0x0 0x0
Received Code Word Bit 8.
1b = Link partner is 100BASE-TX full-duplex capable.
0b = Link partner is not 100BASE-TX full-duplex capable.
7 100BASE-TX Half-
Duplex Capability RO 0x0 0x0
Received Code Word Bit 7.
1b = Link partner is 100BASE-TX half-duplex capable.
0b = Link partner is not 100BASE-TX half-duplex capable.
6 10BASE-T Full-
Duplex Capability RO 0x0 0x0
Received Code Word Bit 6.
1b = Link partner is 10BASE-T full-duplex capable.
0b = Link partner is not 10BASE-T full-duplex capable.
5 10BASE-T Half-
Duplex Capability RO 0x0 0x0
Received Code Word Bit 5.
1b = Link partner is 10BASE-T half-duplex capable.
0b = Link partner is not 10BASE-T half-duplex capable.
4:0 Selector Field RO 0x00 0x00 Selector Field Received Code Word Bit 4:0.
Bits Field Mode HW Rst SW Rst Description
15:5 Reserved RO 0x000 0x000 Reserved.
4 Parallel Detection
Fault RO,LH 0x0 0x0
Register 6_0.4 is not valid until the auto-negotiation complete bit
(Reg 1_0.5) indicates completed.
1b = A fault has been detected via the parallel detection function.
0b = A fault has not been detected via the parallel detection
function.
3 Link Partner Next
page Able RO 0x0 0x0
Register 6_0.3 is not valid until the auto-negotiation complete bit
(Reg 1_0.5) indicates completed.
1b = Link partner is next page able.
0b = Link partner is not next page able.
2 Local Next Page
Able RO 0x1 0x1
Register 6_0.2 is not valid until the auto-negotiation complete bit
(Reg 1_0.5) indicates completed.
1b = Local device is next page able.
0b = Local device is not next page able.
1 Page Received RO, LH 0x0 0x0
Register 6_0.1 is not valid until the auto-negotiation complete bit
(Reg 1_0.5) indicates completed.
1b = A new page has been received.
0b = A new page has not been received.
0 Link Partner Auto-
Negotiation Able RO 0x0 0x0
Register 6_0.0 is not valid until the auto-negotiation complete bit
(Reg 1_0.5) indicates completed.
1b = Link partner is auto-negotiation able.
0b = Link partner is not auto-negotiation able.
Programming Interface — Ethernet Controller I210
555
8.27.3.8 Copper Next Page Transmit Register - Page 0, Register 7
8.27.3.9 Copper Link Partner Next Page Register - Page 0, Register 8
Bits Field Mode HW Rst SW Rst Description
15 Next Page R/W 0x0 0x0 A write to register 7_0 implicitly sets a variable in the auto-
negotiation state machine indicating that the next page has been
loaded. Link fail clears Reg 7_0. Transmit Code Word Bit 15.
14 Reserved RO 0x0 0x0 Reserved.
13 Message Page
Mode R/W 0x1 0x1 Transmit Code Word Bit 13.
12 Acknowledge2 R/W 0x0 0x0 Transmit Code Word Bit 12.
11 Toggle RO 0x0 0x0 Transmit Code Word Bit 11.
10:0 Message/
Unformatted Field R/W 0x001 0x001 Transmit Code Word Bit 10:0.
Bits Field Mode HW Rst SW Rst Description
15 Next Page RO 0x0 0x0 Received Code Word Bit 15.
14 Acknowledge RO 0x0 0x0 Received Code Word Bit 14.
13 Message Page RO 0x0 0x0 Received Code Word Bit 13.
12 Acknowledge2 RO 0x0 0x0 Received Code Word Bit 12.
11 Toggle RO 0x0 0x0 Received Code Word Bit 11.
10:0 Message/
Unformatted Field RO 0x000 0x000 Received Code Word Bit 10:0.
Ethernet Controller I210 — Programming Interface
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8.27.3.10 1000BASE-T Control Register - Page 0, Register 9
Bits Field Mode HW Rst SW Rst Description
15:13 Test Mode R/W 0x0 Retain
TX_CLK comes from the RX_CLK pin for jitter testing in test modes
2 and 3. After exiting the test mode, hardware reset or software
reset (register 0_0.15) should be issued to ensure normal
operation.
A restart of auto-negotiation clears these bits.
000b = Normal mode.
001b = Test Mode 1 - Transmit waveform test.
010b = Test Mode 2 - Transmit jitter test (master mode).
011b = Test Mode 3 - Transmit jitter test (slave mode).
100b = Test Mode 4 - Transmit distortion test.
101b, 110b, and 111b = Reserved.
12
MASTER/SLAVE
Manual
Configuration
Enable
R/W 0x0 Update
A write to this register bit does not take effect until any of the
following also occurs:
Software reset is asserted (register 0_0.15).
Restart auto-negotiation is asserted (register 0_0.9).
Power down (register 0_0.11, 16_0.2); transitions from power
down to normal operation and the copper link goes down.
1b = Manual master/slave configuration.
0b = Automatic master/slave configuration.
11 MASTER/SLAVE
Configuration
Value R/W Update
A write to this register bit does not take effect until any of the
following also occurs:
Software reset is asserted (register 0_0.15).
Restart auto-negotiation is asserted (register 0_0.9).
Power down (register 0_0.11, 16_0.2); transitions from power
down to normal operation and the copper link goes down.
1b = Manual configure as master.
0b = Manual configure as slave.
10 Port Type R/W Update
A write to this register bit does not take effect until any of the
following also occurs:
Software reset is asserted (register 0_0.15).
Restart auto-negotiation is asserted (register 0_0.9).
Power down (register 0_0.11, 16_0.2); transitions from power
down to normal operation and the copper link goes down.
Register 9_0.10 is ignored if register 9_0.12 is equal to 1b.
1b = Prefer multi-port device (master).
0b = Prefer single port device (slave).
Programming Interface — Ethernet Controller I210
557
8.27.3.11 1000BASE-T Status Register - Page 0, Register 10
9 1000BASE-T Full-
Duplex R/W 0x1 Update
A write to this register bit does not take effect until any of the
following also occurs:
Software reset is asserted (register 0_0.15).
Restart auto-negotiation is asserted (register 0_0.9).
Power down (register 0_0.11, 16_0.2); transitions from power
down to normal operation and the copper link goes down.
1b = Advertise.
0b = Not advertised.
8 1000BASE-T Half-
Duplex R/W Update
A write to this register bit does not take effect until any of the
following also occurs:
Software reset is asserted (register 0_0.15).
Restart auto-negotiation is asserted (register 0_0.9).
Power down (register 0_0.11, 16_0.2); transitions from power
down to normal operation and the copper link goes down.
1b = Advertise.
0b = Not advertised.
7:0 Reserved R/W 0x00 Retain Reserved.
Bits Field Mode HW Rst SW Rst Description
15 Master/Slave
Configuration
Fault RO,LH 0x0 0x0
This register bit clears on read.
1b = Master/slave configuration fault detected.
0b = No master/slave configuration fault detected.
14 Master/Slave
Configuration
Resolution RO 0x0 0x0 1b = Local PHY configuration resolved to master.
0 = Local PHY configuration resolved to slave.
13 Local Receiver
Status RO 0x0 0x0 1b = Local receiver OK.
0b = Local receiver is Not OK.
12 Remote Receiver
Status RO 0x0 0x0 1b = Remote receiver OK.
0b = Remote receiver Not OK.
11 Link Partner
1000BASE-T Full-
Duplex Capability RO 0x0 0x0 1b = Link partner is capable of 1000BASE-T full-duplex.
0b = Link partner is not capable of 1000BASE-T full-duplex
10 Link Partner
1000BASE-T Half-
Duplex Capability RO 0x0 0x0 1b = Link partner is capable of 1000BASE-T half-duplex.
0b = Link partner is not capable of 1000BASE-T half-duplex.
9:8 Reserved RO 0x0 0x0 Reserved.
7:0 Idle Error Count RO, SC 0x00 0x00
MSB of Idle Error Counter.
These register bits report the idle error count since the last time
this register was read. The counter reachesit’s maximum count
at 11111111b and does not roll over.
Ethernet Controller I210 — Programming Interface
558
8.27.3.12 MMD Access Control Register (MMDAC) - Page 0, Register 13
8.27.3.13 MMD Access Address/Data Register (MMDAAD) - Page 0, Register 14
8.27.3.14 Extended Status Register - Page 0, Register 15
8.27.3.15 Copper Specific Control Register 1 - Page 0, Register 16
Bits Field Mode HW Rst SW Rst Description
15:14 Function R/W 0x0 0x0
00b = Address.
01b = Data, no post increment.
10b = Data, post increment on reads and writes.
11b = Data, post increment on writes only.
13:5 Reserved RO 0x000 0x000 Reserved.
4:0 DEVAD RO 0x00 0x00 Device Address.
Bits Field Mode HW Rst SW Rst Description
15:0 Address Data R/W 0x0000 0x0000 If 13.15:14 = 00b, MMD DEVAD’s address register. Otherwise,
MMD DEVAD is data register as indicated by the contents of its
address register.
Bits Field Mode HW Rst SW Rst Description
15 1000BASE-X Full-
Duplex RO Always
0b Always
0b 0b = Not 1000BASE-X full-duplex capable.
14 1000BASE-X Half-
Duplex RO Always
0b Always
0b 0b = Not 1000BASE-X half-duplex capable.
13 1000BASE-T Full-
Duplex RO Always
1b Always
1b 1b = 1000BASE-T full-duplex capable.
12 1000BASE-T Half-
Duplex RO Always
1b Always
1b 1b = 1000BASE-T half-duplex capable.
11:0 Reserved RO 0x000 0x000 Reserved.
Bits Field Mode HW Rst SW Rst Description
15 Disable Link Pulses R/W 0x0 0x0 1b = Disable link pulse.
0b = Enable link pulse.
14:12 Downshift counter R/W 0x3 Update
Changes to these bits are disruptive to the normal operation. As a
result, any changes to these registers must be followed by
software reset to take effect. 1x, 2x, ...8x is the number of times
the PHY attempts to establish GbE link before the PHY downshifts
to the next highest speed.
000b = 1x 100 = 5x.
001b = 2x 101 = 6x.
010b = 3x 110 = 7x 011 = 4x.
111b = 8x.
Programming Interface — Ethernet Controller I210
559
11 Downshift Enable R/W 0x0 Update
Changes to these bits are disruptive to the normal operation. As a
result, any changes to these registers must be followed by
software reset to take effect.
1b = Enable downshift.
0b = Disable downshift.
10 Force Copper Link
Good R/W 0x0 Retain
If link is forced to be good, the link state machine is bypassed and
the link is always up. In 1000BASE-T mode this has no effect.
1b = Force link good.
0b = Normal operation.
9:7 Energy Detect R/W Update
0xxb = Off.
100b = Sense only on receiver (energy detect), auto wake up.
101b = Sense only on receiver (energy detect), SW wake up.
110b = Sense and periodically transmit NLP (energy detect and
TM), auto wake up.
111b = Sense and periodically transmit NLP (energy detect and
TM), software wake up.
6:5 MDI Crossover
Mode R/W See
Descr. Update
Changes to these bits are disruptive to the normal operation. As a
result, any changes to these registers must be followed by a
software reset to take effect.
Upon hardware reset or auto-negotiation restart, this field takes its
default value from the setting of IPCNFG.Enable Automatic
Crossover bit, either 00b or 11b.
00b = Manual MDI configuration.
01b = Manual MDIX configuration.
10b = Reserved.
11b = Enable automatic crossover for all modes.
4 Energy Detect
wake up control R/W or
RO, SC 0x0 0x0
This bit controls how PHYG wakes up from the energy detect state.
If 16_0.7 = 0b (software wake up), this register bit is in R/W
mode. When software writes a 1b to this bit , it wakes up the PHYG
from the energy detect state. If 16_0.7 = 1b, PHYG wakes up from
the energy detect state automatically based on the energy
detected from line. This bit self clears after PHYG leaves the energy
detect state.
3 Copper Transmitter
Disable R/W 0x0 Retain 1b = Transmitter disable.
0b = Transmitter enable.
2 Power Down R/W 0x0 Retain
Power down is controlled via register 0_0.11 and 16_0.2. Both bits
must be set to 0b before the PHY transitions from power down to
normal operation.
When the port is switched from power down to normal operation,
software reset and restart auto-negotiation are performed even
when bits Reset (0_0.15) and Restart Auto-Negotiation (0_0.9) are
not set by the user.
1b = Power down.
0b = Normal operation.
1 Polarity Reversal
Disable R/W 0x0 Retain
If polarity is disabled, then the polarity is forced to be normal in
10BASE-T.
1b = Polarity reversal disabled.
0b = Polarity reversal enabled The detected polarity status is
shown in register 17_0.1, or in 1000BASE-T mode, 21_5.3:0.
0 Disable Jabber R/W 0x0 Retain
Jabber has effect only in 10BASE-T half-duplex mode.
1b = Disable jabber function.
0b = Enable jabber function.
Ethernet Controller I210 — Programming Interface
560
8.27.3.16 Copper Specific Status Register 1 - Page 0, Register 17
Bits Field Mode HW Rst SW Rst Description
15:14 Speed RO 0x2 Retain
These status bits are valid only after resolved bit 17_0.11 = 1b.
The resolved bit is set when auto-negotiation completes or auto-
negotiation is disabled.
11b = Reserved.
10b = 1000 Mb/s.
01b = 100 Mb/s.
00b = 10 Mb/s.
13 Duplex RO 0x0 Retain
This status bit is valid only after resolved bit 17_0.11 = 1b. The
resolved bit is set when auto-negotiation completes or auto-
negotiation is disabled.
1b = Full duplex.
0b = Half duplex.
12 Page Received RO, LH 0x0 0x0 1b = Page received.
0b = Page not received.
11 Speed and
Duplex Resolved RO 0x0 0x0
When auto-negotiation is not enabled 17_0.11 = 1b.
1b = Resolved.
0 = Not resolved.
10 Copper Link (real
time) RO 0x0 0x0 1b = Link up.
0b = Link down.
9 Transmit Pause
Enabled RO 0x0 0x0
This is a reflection of the MAC pause resolution. This bit is for
information purposes and is not used by the device. This status bit
is valid only after resolved bit 17_0.11 = 1b. The resolved bit is set
when auto-negotiation completes or auto-negotiation is disabled.
1b = Transmit pause enabled.
0b = Transmit pause disable.
8 Receive Pause
Enabled RO 0x0 0x0
This is a reflection of the MAC pause resolution. This bit is for
information purposes and is not used by the device. This status bit
is valid only after resolved bit 17_0.11 = 1b. The resolved bit is set
when auto-negotiation completes or auto-negotiation is disabled.
1b = Receive pause enabled.
0b = Receive pause disabled.
7 Reserved RO 0x0 0x0 Reserved.
6 MDI Crossover
Status RO 0x1 Retain
This status bit is valid only after resolved bit 17_0.11 = 1b. The
resolved bit is set when auto-negotiation completes or auto-
negotiation is disabled. This bit is 0b or 1b depending on what is
written to 16.6:5 in manual configuration mode. Register 16.6:5
are updated with a software reset.
1b = MDI-X.
0b = MDI.
5 Downshift Status RO 0x0 0x0 1b = Downshift.
0b = No downshift.
4 Copper Energy
Detect Status RO 0x0 0x0 1b = Sleep.
0b = Active.
3 Global Link
Status RO 0x0 0x0 1b = Copper link is up.
0b = Copper link is down.
Programming Interface — Ethernet Controller I210
561
8.27.3.17 Copper Specific Interrupt Enable Register - Page 0, Register 18
2 Reserved RO 0x0 0x0 Reserved for future use.
1 Polarity (real
time) RO 0x0 0x0
1b = Reversed.
0b = Normal polarity reversal can be disabled by writing to register
16_0.1. In 1000BASE-T mode, polarity of all pairs are shown in
register 21_5.3:0.
0 Jabber (real
time) RO 0x0 0x0 1b = Jabber.
0b = No jabber.
Bits Field Mode HW Rst SW Rst Description
15 Auto-Negotiation
Error Interrupt
Enable R/W 0x0 Retain 1b = Interrupt enable.
0b = Interrupt disable.
14 Speed Changed
Interrupt Enable R/W 0x0 Retain 1b = Interrupt enable.
0b = Interrupt disable.
13 Duplex Changed
Interrupt Enable R/W 0x0 Retain 1b = Interrupt enable.
0b = Interrupt disable.
12 Page Received
Interrupt Enable R/W 0x0 Retain 1b = Interrupt enable.
0b = Interrupt disable.
11 Auto-Negotiation
Completed
Interrupt Enable R/W 0x0 Retain 1b = Interrupt enable.
0b = Interrupt disable.
10 Link Status
Changed Interrupt
Enable R/W 0x0 Retain 1b = Interrupt enable.
0b = Interrupt disable.
9 Symbol Error
Interrupt Enable R/W 0x0 Retain 1b = Interrupt enable.
0b = Interrupt disable.
8 False Carrier
Interrupt Enable R/W 0x0 Retain 1b = Interrupt enable.
0b = Interrupt disable.
7 Reserved R/W 0x0 Retain Reserved.
6 MDI Crossover
Changed Interrupt
Enable R/W 0x0 Retain 1b = Interrupt enable.
0b = Interrupt disable.
5 Downshift
Interrupt Enable R/W 0x0 Retain 1b = Interrupt enable.
0b = Interrupt disable.
4 Copper Energy
Detect Interrupt
Enable R/W 0x0 Retain 1b = Interrupt enable.
0b = Interrupt disable.
3
FLP Exchange
Complete but no
Link Interrupt
Enable
R/W 0x0 Retain 1b = Interrupt enable.
0b = Interrupt disable.
Ethernet Controller I210 — Programming Interface
562
8.27.3.18 Copper Interrupt Status Register - Page 0, Register 19
2 Reserved R/W 0x0 Retain Reserved for future use. This bit must be 0.
1 Polarity Changed
Interrupt Enable R/W 0x0 Retain 1b = Interrupt enable.
0b = Interrupt disable.
0 Jabber Interrupt
Enable R/W 0x0 Retain 1b = Interrupt enable.
0b = Interrupt disable.
Bits Field Mode HW Rst SW Rst Description
15 Copper Auto-
Negotiation Error RO,LH 0x0 0x0
An error is said to occur if master/slave does not resolve, parallel
detect fault, no common HCD, or link does not come up after auto-
negotiation completes.
1b = Auto-negotiation error.
0b = No auto-negotiation error.
14 Copper Speed
Changed RO,LH 0x0 0x0 1b = Speed changed.
0b = Speed not changed.
13 Copper Duplex
Changed RO,LH 0x0 0x0 1b = Duplex changed.
0b = Duplex not changed.
12 Copper Page
Received RO,LH 0x0 0x0 1b = Page received.
0b = Page not received.
11 Copper Auto-
Negotiation
Completed RO,LH 0x0 0x0 1b = Auto-negotiation completed.
0b = Auto-negotiation not completed.
10 Copper Link
Status Changed RO,LH 0x0 0x0 1b = Link status changed.
0b = Link status not changed.
9 Copper Symbol
Error RO,LH 0x0 0x0 1b = Symbol error.
0b = No symbol error.
8 Copper False
Carrier RO,LH 0x0 0x0 1b = False carrier.
0b = No false carrier.
7 Reserved RO Always
0b Always
b0 Reserved.
6 MDI Crossover
Changed RO,LH 0x0 0x0 1b = Crossover changed.
0b = Crossover not changed.
5 Downshift
Interrupt RO,LH 0x0 0x0 1b = Downshift detected.
0b = No down shift.
4 Copper Energy
Detect Changed RO,LH 0x0 0x0 1b = Energy detect state changed.
0b = No energy detect state change detected.
3 FLP Exchange
Complete but no
Link RO,LH 0x0 0x0 1b = FLP exchange completed but link not established.
0b = No event detected.
2 Reserved RO,LH 0x0 0x0 Reserved for future use.
1 Polarity Changed RO,LH 0x0 0x0 1b = Polarity changed.
0b = Polarity not changed.
0 Jabber RO,LH 0x0 0x0 1b = Jabber.
0b = No jabber.
Programming Interface — Ethernet Controller I210
563
8.27.3.19 Copper Specific Control Register 2 - Page 0, Register 20
8.27.3.20 Copper Specific Receive Error Counter Register - Page 0, Register 21
8.27.3.21 Page Address - Page Any, Register 22
Bits Field Mode HW Rst SW Rst Description
15:8 Reserved R/W 0x000 Retain Reserved.
7 10Base-Te Enable R/W 0b Retain 0b = Disable 10BASE-Te.
1b = Enable 10BASE-Te.
6 Break Link On
Insufficient IPG R/W 0x0 Retain
0b = Break link on insufficient IPGs in 10BASE-T and 100BASE-TX.
1b = Do not break link on insufficient IPGs in 10BASE-T and
100BASE-TX.
5 100BASE-T
Transmitter Clock
Source R/W 0x1 Update 1b = Local clock.
0b = Recovered clock.
4 Accelerate
100BASE-T Link
Up R/W 0x0 Retain 0b = No acceleration.
1b = Accelerate.
3 Reverse MDIP/
N[3] Transmit
Polarity R/W 0x0 Retain 0b = Normal transmit polarity.
1b = Reverse transmit polarity.
2 Reverse MDIP/
N[2] Transmit
Polarity R/W 0x0 Retain 0b = Normal transmit polarity.
1b = Reverse transmit polarity.
1 Reverse MDIP/
N[1] Transmit
Polarity R/W 0x0 Retain 0b = Normal transmit polarity.
1b = Reverse transmit polarity.
0 Reverse MDIP/
N[0] Transmit
Polarity R/W 0x0 Retain 0b = Normal transmit polarity.
1b = Reverse transmit polarity.
Bits Field Mode HW Rst SW Rst Description
15:0 Receive Error
Count RO, LH 0x0000 Retain Counter reaches its maximum count at 0xFFFF and does not roll
over. Both false carrier and symbol errors are reported.
Bits Field Mode HW Rst SW Rst Description
15:14 Reserved R/W 0x0 Retain Reserved. These bits must be 0x0.
13:8 Reserved RO 0x00 0x00 Reserved.
7:0 Page select for
registers 0 to 28 R/W 0x00 Retain Page Number.
Ethernet Controller I210 — Programming Interface
564
8.27.3.22 Copper Specific Control Register 3 - Page 0, Register 23
Bits Field Mode HW Rst SW Rst Description
15 1000BASE-T
Transmitter type R/W 0 Retain 0 = Class B.
1 = Class A.
14 Disable
1000BASE-T R/W Retain
When set to disabled, 1000BASE-T isnot advertised even if
registers 9_0.9 or 9_0.8 are set to 1b. A write to this register bit
does not take effect until any one of the following occurs:
Software reset is asserted (register 0_0.15).
Restart auto-negotiation is asserted (register 0_0.9).
Power down (register 0_0.11, 16_0.2); transitions from power
down to normal operation and the copper link goes down.
1 = Disable 1000BASE-T advertisement .
0 = Enable 1000BASE-T advertisement.
13 Reverse Autoneg R/W Retain
A write to this register bit does not take effect until any one of the
following occurs:
Software reset is asserted (register 0_0.15).
Restart auto-negotiation is asserted (register 0_0.9).
Power down (register 0_0.11, 16_0.2); transitions from power
down to normal operation and the copper link goes down.
1b = Reverse auto-negotiation.
0b = Normal auto-negotiation.
12 Disable 100BASE-
T R/W Retain
When set to disabled, 100BASE-TX is not advertised even if
registers 4_0.8 or 4_0.7 are set 1b. A write to this register bit does
not take effect until any one of the following occurs:
Software reset is asserted (register 0_0.15).
Restart auto-negotiation is asserted (register 0_0.9).
Power down (register 0_0.11, 16_0.2); transitions from power
down to normal operation and the copper link goes down.
1b = Disable 100BASE-TX advertisement.
0b = Enable 100BASE-TX advertisement.
11:10 Gigabit Link Down
Delay R/W 0x0 Retain
This register only has effect if register 23_0.9 is set to 1b.
00b = 0 ms.
01b = 10 ± 2ms.
10b = 20 ± 2ms.
11b = 40 ± 2ms.
9 Speed Up Gigabit
Link Down Time R/W 0x0 Retain
1b = Enable faster gigabit link down. This mode shall not be
selected if EEE is enabled.
0b = Use IEEE gigabit link down.
8:4 Reserved R/W 0x0 Update Reserved for future use. These bits must be 0x4.
Programming Interface — Ethernet Controller I210
565
8.27.3.23 MAC Specific Control Register 1 - Page 2, Register 16
8.27.3.24 MAC Specific Interrupt Enable Register - Page 2, Register 18
3:2 100 MB test select R/W 0x0 Retain
0xb = Normal 0peration.
10b = Select 112 ns sequence.
11b = Select 16 ns sequence.
1 10 BT polarity
force R/W 0x0 Retain 1b = Force negative polarity for receive only.
0b = Normal operation.
0 Reserved R/W 0x0 Retain Reserved.
Bits Field Mode HW Rst SW Rst Description
15:14 Copper Transmit
FIFO Depth R/W Retain
00b = ± 16 bits.
01b = ± 24 bits.
10b = ± 32 bits.
11b = ± 40 bits.
13:10 Reserved R/W 0x8 Update Reserved.
9 fi_125_clk control R/W Retain
1b = Stop fi_125_clk.
0b = Enable fi_125_clk.
8 fi_50_clk control R/W Retain
1b = Stop fi_50_clk.
0b = Enable fi_50_clk.
7:4 Reserved R/W 0x0 Update Reserved.
3 MAC Interface
Power Down R/W 0x1 Update
Changes to this bit are disruptive to the normal operation.As a
result, any changes to these registers must be followed by a
software reset to take effect.
This bit determines whether the MAC interface powers down when
register 0_0.11, 16_0.2 are used to power down the device or
when the PHY enters the energy detect state.
1b = Always power up.
0b = OK to power down.
2:0 Reserved R/W 0x0 Retain Reserved
Bits Field Mode HW Rst SW Rst Description
15:8 Reserved R/W 0x0 Retain 0x0.
7 FIFO Over/
Underflow
Interrupt Enable R/W 0x0 Retain 1b = Interrupt enable.
0b = Interrupt disable.
6:4 Reserved R/W 0x0 Retain 0x0.
Ethernet Controller I210 — Programming Interface
566
8.27.3.25 MAC Specific Status Register - Page 2, Register 19
8.27.3.26 Copper RX_ER Byte Capture Register - Page 2, Register 20
3 FIFO Idle Inserted
Interrupt Enable R/W 0x0 Retain 1b = Interrupt enable.
0b = Interrupt disable.
2 FIFO Idle Deleted
Interrupt Enable R/W 0x0 Retain 1b = Interrupt enable.
0b = Interrupt disable.
1:0 Reserved R/W 0x0 Retain 0x0.
Bits Field Mode HW Rst SW Rst Description
15:8 Reserved RO Always
0x0 Always
0x0 Reserved.
7 Copper FIFO Over/
Underflow RO,LH 0x0 0x0 1b = Over/underflow error.
0b = No FIFO error.
6:4 Reserved RO Always
0x0 Always
0x0 Reserved.
3 Copper FIFO Idle
Inserted RO,LH 0x0 0x0 1b = Idle inserted.
0b = No idle inserted.
2 Copper FIFO Idle
Deleted RO,LH 0x0 0x0 1b = Idle deleted.
0b = Idle not deleted.
1:0 Reserved RO Always
0x0 Always
0x0 Reserved.
Bits Field Mode HW Rst SW Rst Description
15 Capture Data Valid RO 0x0 0x0 1b = Bits 14:0 valid,
0b = Bits 14:0 invalid.
14 Reserved RO 0x0 0x0 Reserved.
13:12 Byte Number RO 0x0 0x0
00b = 4 bytes before RX_ER asserted,
01b = 3 bytes before RX_ER asserted,
10b = 2 bytes before RX_ER asserted,
11b = 1 byte before RX_ER asserted,
The byte number increments after every read when register
20_2.15 is set to 1b.
11:10 Reserved RO 0x0 0x0 Reserved.
9 RX_ER RO 0x0 0x0
RX Error.
Normally this bit is low since the capture is triggered by RX_ER
being high. However, it is possible to see an RX_ER high when the
capture is re-enabled after reading the fourth byte and there
happens to be a long sequence of RX_ER when the capture
restarts.
8 RX_DV RO 0x0 0x0 RX Data Valid.
7:0 RXD[7:0] RO 0x0 0x0 RX Data.
Programming Interface — Ethernet Controller I210
567
8.27.3.27 MAC Specific Control Register 2 - Page 2, Register 21
Bits Field Mode HW Rst SW Rst Description
15 Reserved R/W 0x0 0x0 Reserved.
14 Copper Line
Loopback R/W 0x0 0x0 1b = Enable loopback of MDI-to-MDI.
0b = Normal operation.
13:12 Reserved R/W 0x1 Update Reserved.
11:7 Reserved R/W 0x0 0x0 Reserved.
6 Reserved R/W 0x1 Update Reserved.
5:4 Reserved R/W 0x0 Retain Reserved.
3 Block Carrier
Extension Bit R/W 0x0 Retain 1b = Enable block carrier extension.
0b = Disable block carrier extension.
2:0 Default MAC
Interface Speed R/W 0x6 Update
Changes to these bits are disruptive to the normal operation. As a
result, any changes to these registers must be followed by
software reset to take effect.
MAC interface speed during link down while auto-negotiation is
enabled.
Bit speed:
0XXb = Reserved.
100b = 10 Mb/s.
101b = 100 Mb/s.
110b = 1000 Mb/s.
111b = Reserved.
Ethernet Controller I210 — Programming Interface
568
8.27.3.28 jt_led_s[3:0] Function Control Register - Page 3, Register 16
Bits Field Mode HW Rst SW Rst Description
15:12 jt_led_s[3] Control R/W 0x1 Retain
If 16_3.11:10 is set to 11b then 16_3.15:12 has no effect.
0000b = On - fiber link, off - else.
0001b = On - link, blink - activity, off - no link.
0010b = On - link, blink - receive, off - no link.
0011b = On - activity, off - no activity.
0100b = Blink - activity, off - no activity.
0101b = Sync-E recovered clock.
0110b = On - 10 Mb/s or 1000 Mb/s master, off - else.
0111b = On - full duplex, off - half duplex.
1000b = Force off.
1001b = Force on.
1010b = Force hi-Z.
1011b = Force blink.
11xxb = Reserved.
Programming Interface — Ethernet Controller I210
569
11:8 jt_led_s[2] Control R/W 0x7 Retain
0000b = On - link, off - no link.
0001b = On - link, blink - activity, off - no link.
0010b = Reserved.
0011b = On - activity, off - no activity.
0100b = Blink - activity, off -no activity.
0101b = On - transmit, off - no transmit.
0110b = On - 10/1000 Mb/s link, off - else.
0111b = On - 10 Mb/s Link, off - else.
1000b = Force off.
1001b = Force on.
1010b = Force hi-Z.
1011b = Force blink.
1100b = MODE 1 (dual LED mode).
1101b = MODE 2 (dual LED mode).
1110b = MODE 3 (dual LED mode).
1111b = MODE 4 (dual LED mode).
7:4 jt_led_s[1] Control R/W 0x7 Retain
If 16_3.3:2 is set to 11b then 16_3.7:4 has no effect.
0000b = On - copper link, off - else.
0001b = On - link, blink - activity, off - no link.
0010b = On - link, blink - receive, off - no link.
0011b = On - activity, off - no activity.
0100b = Blink - activity, off -no activity.
0101b = On - 100 Mb/s link or fiber link, off - else.
0110b = On - 100/1000 Mb/s link, off - else.
0111b = On - 100 Mb/s link, off - else.
1000b = Force off.
1001b = Force on.
1010b = Force hi-Z.
1011b = Force blink.
11xxb = Reserved.
3:0 jt_led_s[0] Control R/W 0x7 Retain
0000b = On - link, off - no link.
0001b = On - link, blink - activity, off - no link.
0010b = 3 blinks - 1000 Mb/s.
2 blinks - 100 Mb/s.
1 blink - 10 Mb/s.
0 blink - No link.
0011b = On - activity, off - no activity.
0100b = Blink - activity, off -no activity.
0101b = On - transmit, off - no transmit.
0110b = On - copper link, off - else.
0111b = On - 1000 Mb/s link, off - else.
1000b = Force off.
1001b = Force on.
1010b = Force hi-Z.
1011b = Force blink.
1100b = MODE 1 (dual LED mode).
1101b = MODE 2 (dual LED mode).
1110b = MODE 3 (dual LED mode).
1111b = MODE 4 (dual LED mode).
Ethernet Controller I210 — Programming Interface
570
8.27.3.29 jt_led_s[3:0] Polarity Control Register - Page 3, Register 17
8.27.3.30 LED Timer Control Register - Page 3, Register 18
Bits Field Mode HW Rst SW Rst Description
15:12
jt_led_s[5],
jt_led_s[3],
jt_led_s[1] Mix
Percentage
R/W 0x8 Retain
When using 2 terminal bi-color LEDs the mixing percentage should
not be set greater than 50%.
0000b = 0%.
0001b = 12.5%, . . ..
0111b = 87.5%.
1000b = 100%.
1001b to 1111b = Reserved.
11:8
jt_led_s[4],
jt_led_s[2],
jt_led_s[0] Mix
Percentage
R/W 0x8 Retain
When using 2 terminal bi-color LEDs the mixing percentage should
not be set greater than 50%.
0000b = 0%.
0001b = 12.5%, . . ..
0111b = 87.5%.
1000b = 100%.
1001b to 1111b = Reserved.
7:6 jt_led_s[3]
Polarity R/W 0x0 Retain
00b = On - drive jt_led_s[3] low, off - drive jt_led_s[3] high.
01b = On - drive jt_led_s[3] high, off - drive jt_led_s[3] low.
10b = On - drive jt_led_s[3] low, off - tristate jt_led_s[3].
11b = On - drive jt_led_s[3] high, off - tristate jt_led_s[3].
5:4 jt_led_s[2]
Polarity R/W 0x0 Retain
00b = On - drive jt_led_s[2] low, off - drive jt_led_s[2] high.
01b = On - drive jt_led_s[2] high, off - drive jt_led_s[2] low.
10b = On - drive jt_led_s[2] low, off - tristate jt_led_s[2].
11b = On - drive jt_led_s[2] high, off - tristate jt_led_s[2].
3:2 jt_led_s[1]
Polarity R/W 0x0 Retain
00b = On - drive jt_led_s[1] low, off - drive jt_led_s[1] high.
01b = On - drive jt_led_s[1] high, off - drive jt_led_s[1] low.
10b = On - drive jt_led_s[1] low, off - tristate jt_led_s[1].
11b = On - drive jt_led_s[1] high, off - tristate jt_led_s[1].
1:0 jt_led_s[0]
Polarity R/W 0x0 Retain
00b = On - drive jt_led_s[0] low, off - drive jt_led_s[0] high.
01b = On - drive jt_led_s[0] high, off - drive jt_led_s[0] low.
10b = On - drive jt_led_s[0] low, off - tristate jt_led_s[0].
11b = On - drive jt_led_s[0] high, off - tristate jt_led_s[0].
Bits Field Mode HW Rst SW Rst Description
15 Force INT R/W 0x0 Retain 1b = jt_int_out_s pin forced to be asserted.
0b = Normal operation.
14:12 Pulse Stretch
Duration R/W 0x4 Retain
000b = no pulse stretching.
001b = 21 ms to 42 ms.
010b = 42 ms to 84 ms.
011b = 84 ms to 170 ms.
100b = 170 ms to 340 ms.
101b = 340 ms to 670 ms.
110b = 670 ms to 1.3 s.
111b = 1.3s to 2.7 s.
11 Interrupt Polarity R/W 0x1 Retain 0b = Interrupt active high.
1b = Interrupt active low.
Programming Interface — Ethernet Controller I210
571
8.27.3.31 jt_led_s[5:4] Function Control and Polarity Register - Page 3, Register
19
10:8 Blink Rate R/W 0x1 Retain
000b = 42 ms.
001b = 84 ms.
010b = 170 ms.
011b = 340 ms.
100b = 670 ms.
101b to 111b = Reserved.
7:4 Reserved R/W 0x0 Retain 0x0.
3:2 Speed Off Pulse
Period R/W 0x1 Retain
00b = 84 ms.
01b= 170 ms.
10b = 340 ms.
11b = 670 ms
1:0 Speed On Pulse
Period R/W 0x1 Retain
00b = 84 ms.
01b = 170 ms.
10b = 340 ms.
11b = 670 ms.
Bits Field Mode HW Rst SW Rst Description
15 jt_led_s[3]
function pin
mapping R/W 0x0 Retain 0b = Map jt_led_s[3] function to jt_led_s3] pin.
1b = Map jt_led_s[5] function to jt_led_s[3] pin.
14 jt_led_s[2]
function pin
mapping R/W 0x0 Retain 0b = Map jt_led_s[2] function to jt_led_s[2] pin.
1b = Map jt_led_s[4] function to jt_led_s[2] pin.
13:12 Reserved R/W 0x0 Retain Reserved.
11:10 jt_led_s[5]
Polarity R/W 0x0 Retain
00b = On - drive jt_led_s[5] low, off - drive jt_led_s[5] high.
01b = On - drive jt_led_s[5] high, off - drive jt_led_s[5] low.
10b= On - drive jt_led_s[5] low, off - tristate jt_led_s[5].
11b = On - drive jt_led_s[5] high, off - tristate jt_led_s[5].
Ethernet Controller I210 — Programming Interface
572
8.27.3.32 1000BASE-T Pair Skew Register - Page 5, Register 20
9:8 jt_led_s[4]
Polarity R/W 0x0 Retain
00b = On - drive jt_led_s[4] low, Off - drive jt_led_s[4] high.
01b = On - drive jt_led_s[4] high, Off - drive jt_led_s[4] low.
10b = On - drive jt_led_s[4] low, Off - tristate jt_led_s[4].
11b = On - drive jt_led_s[4] high, Off - tristate jt_led_s[4].
7:4 jt_led_s[5]
Control R/W 0x7 Retain
If 19_3.3:2 is set to 11b then 19_3.7:4 has no effect.
0000b = On - receive, off - no receive.
0001b = On - link, blink - activity, off - no link.
0010b = On - link, blink - receive, off - no link.
0011b = On - activity, off - no activity.
0100b = Blink - activity, off -no activity.
0101b = On - transmit, off - no transmit.
0110b = On - full duplex, off - half duplex.
0111b = On - full duplex, blink - collision off - half duplex.
1000b = Force off.
1001b = Force on.
1010b = Force hi-Z.
1011b = Force blink.
11xxb = Reserved.
3:0 jt_led_s[4]
Control R/W 0x3 Retain
0000b = On - receive, off - no receive.
0001b = On - link, blink - activity, off - no link.
0010b = On - link, blink - receive, off - no link.
0011b = On - activity, off - no activity.
0100b = Blink - activity, off -no activity.
0101b = On - transmit, off - no transmit.
0110b = On - full duplex, off - half duplex.
0111b = On - full duplex, blink - collision, off - half duplex.
1000b = Force off.
1001b = Force on.
1010b = Force hi-Z.
1011b = Force blink.
1100b = MODE 1 (dual LED mode).
1101b = MODE 2 (dual LED mode).
1110b = MODE 3 (dual LED mode).
1111b = MODE 4 (dual LED mode).
Bits Field Mode HW Rst SW Rst Description
15:12 Pair 7,8
(MDI[3]±) RO 0x0 0x0 Skew = bit value x 8 ns. Value is correct to within ± 8 ns. The
contents of 20_5.15:0 are valid only if register 21_5.6 = 1b.
11:8 Pair 4,5
(MDI[2]±) RO 0x0 0x0 Skew = bit value x 8 ns. Value is correct to within ± 8ns.
7:4 Pair 3,6
(MDI[1]±) RO 0x0 0x0 Skew = bit value x 8 ns. Value is correct to within ± 8ns.
3:0 Pair 1,2
(MDI[0]±) RO 0x0 0x0 Skew = bit value x 8 ns. Value is correct to within ± 8ns.
Programming Interface — Ethernet Controller I210
573
8.27.3.33 1000BASE-T Pair Swap and Polarity - Page 5, Register 21
8.27.3.34 Copper Port Packet Generation - Page 6, Register 16
Bits Field Mode HW Rst SW Rst Description
15:7 Reserved RO 0x0 0x0 Reserved.
6 Register 20_5 and
21_5 Valid RO 0x0 0x0
The contents of 21_5.5:0 and 20_5.15:0 are valid only if Register
21_5.6 = 1b
1b = Valid.
0b = Invalid.
5 C, D Crossover RO 0x0 0x0
1b = Channel C received on MDI[2]± channel D received on
MDI[3]±.
0b = Channel D received on MDI[2]± channel C received on
MDI[3]±.
4 A, B Crossover RO 0x0 0x0
1b = Channel A received on MDI[0]± channel B received on
MDI[1]±.
0b = Channel B received on MDI[0]± channel A received on
MDI[1]±.
3 Pair 7,8 (MDI[3]±)
Polarity RO 0x0 0x0 1b = Negative.
0b = Positive.
2 Pair 4,5 (MDI[2]±)
Polarity 0x0 0x0 1b = Negative.
0b = Positive.
1 Pair 3,6 (MDI[1]±)
Polarity RO 0x0 0x0 1b = Negative.
0b = Positive.
0 Pair 1,2 (MDI[0]±)
Polarity RO 0x0 0x0 1b = Negative.
0b = Positive.
Bits Field Mode HW Rst SW Rst Description
15:8 Packet Burst R/W 0x0 Retain 0x00 = Continuous.
0x01 to 0xFF = burst 1 to 255 packets.
7:6 Reserved R/W 0x0 Retain Reserved.
4 Enable CRC
checker R/W 0x0 Retain 1b = Enable.
3 Enable packet
generator R/W 0x0 Retain 1b = Enable.
2 Payload of packet
to transmit R/W 0x0 Retain 0b = Pseudo random.
1b = 5A,A5,5A,A5,....
1 Length of packet
to transmit R/W 0x0 Retain 1b = 1518 bytes.
0b = 64 bytes.
0 Transmit an
Errored packet R/W 0x0 Retain 1b = Tx packets with CRC errors and symbol error.
0b = No error.
Ethernet Controller I210 — Programming Interface
574
8.27.3.35 Copper Port CRC Counters - Page 6, Register 17
8.27.3.36 Checker Control - Page 6, Register 18
8.27.3.37 Misc Test - Page 6, Register 26
Bits Field Mode HW Rst SW Rst Description
15:8 Packet Count RO 0x0 Retain
0x00 = no packets received.
0xFF = 256 packets received (max count).
Bit 16_6.4 must be set to 1b in order for register to be valid.
7:0 CRC Error Count RO 0x0 Retain
0x00 = no CRC errors detected in the packets received.
0xFF = 256 CRC errors detected in the packets received (max
count).
Bit 16_6.4 must be set to 1b in order for register to be valid.
Bits Field Mode HW Rst SW Rst Description
15:5 Reserved R/W 0x000 Retain Reserved.
4 CRC Counter
Reset R/W, SC 0x0 0x0 1b = Reset.
This bit self clears after write to 1b..
3 Enable Stub Test R 0x0 Retain 1b = Enable stub test.
0b = Normal operation.
2:0 Reserved R/W 0x0 Retain Reserved.
Bits Field Mode HW Rst SW Rst Description
15 TX_TCLK Enable R/W 0x0 0x0
The highest numbered enabled port drives the transmit clock to the
HSDACP/N pin.
1b = Enable.
0b = Disable.
14:13 Reserved R/W 0x0 Retain Reserved.
12:8 Reserved R/W 0x19 Retain Reserved.
7 Reserved R/W 0x0 Retain Reserved.
6 Reserved RO, LH 0x0 0x0 Reserved.
5 Reserved R/W 0x0 Retain Reserved.
4:0 Reserved RO xxxxx xxxxx Reserved.
Programming Interface — Ethernet Controller I210
575
8.27.4 XMDIO Register Description
8.27.4.1 PCS Control 1 Register - Device 3, Register 0
8.27.4.2 PCS Status 1 Register - Device 3, Register 1
Register Name Register Address Table and Page
PCS Control 1 Register Device 3, register 0 section 8.27.4.1 on page 575.
PCS Status 1 Register Device 3, register 1 section 8.27.4.2 on page 575.
PCS EEE Capability Register Device 3, register 20 section 8.27.4.3 on page 576.
PCS EEE Wake Error Counter Device 3, register 22 section 8.27.4.4 on page 576.
EEE Advertisement Register Device 7, register 60 section 8.27.4.5 on page 576.
EEE Link Partner Advertisement Register Device 7, register 61 section 8.27.4.6 on page 577.
Bits Field Mode HW Rst SW Rst Description
15:11 Reserved RO 0x00 Retain Reserved.
10 Clock Stoppable R/W 0x0 Retain 1b = Clock stoppable during LPI.
0b = Clock not stoppable.
9:0 Reserved RO 0x000 Retain Reserved.
Bits Field Mode HW Rst SW Rst Description
15:12 Reserved RO 0x0 Retain Reserved.
11 Tx LP Idle
Received RO/LH 0x0 Retain 1b = Tx PCS has received LP idle.
0b = LP Idle not received.
10 Rx LP Idle
Received RO/LH 0x0 Retain 1b = Rx PCS has received LP idle.
0b = LP Idle not received.
9 Tx LP Idle
Indication RO 0x0 Retain 1b = Tx PCS is currently receiving LP idle.
0b = PCS is not currently receiving LP idle.
8 Rx LP Idle
Indication RO 0x0 Retain 1b = Rx PCS is currently receiving LP idle.
0b = PCS is not currently receiving LP idle.
7:3 Reserved RO 0x0 Retain Reserved.
2 PCS Receive Link
status RO 0x0 Retain 1b = PCS receive link up.
0b = PCS receive link down.
1 Low-power Ability RO 0x0 Retain 1b = PCS supports low-power mode.
0b = PCS does not support low-power mode.
0 Reserved RO 0x0 Retain Reserved.
Ethernet Controller I210 — Programming Interface
576
8.27.4.3 PCS EEE Capability Register - Device 3, Register 20
8.27.4.4 PCS EEE Wake Error Counter - Device 3, Register 22
8.27.4.5 EEE Advertisement Register - Device 7, Register 60
Bits Field Mode HW Rst SW Rst Description
15:7 Reserved RO 0x000 Retain Reserved
6 10GBASE-KR EEE RO 0x0 Retain 1b = EEE is supported for 10GBASE-KR.
0b = EEE is not supported for 10GBASE-KR.
510GBASE-KX4
EEE RO 0x0 Retain 1b = EEE is supported for 10GBASE-KX4.
0b = EEE is not supported for 1000BASE-KX RO.
4 1000BASE-KX RO 0x0 Retain 1b = EEE is supported for 1000BASE-KX.
0b = EEE is not supported for 1000BASE-KX RO.
3 10GBASE-T EEE RO 0x0 Retain 1b = EEE is supported for 10GBASE-T.
0b = EEE is not supported for 10GBASE-T.
2 1000BASE-T EEE RO 0x0 Retain 1b = EEE is supported for 1000BASE-T.
0b = EEE is not supported for 1000BASE-T.
1 100BASE-TX EEE RO 0x0 Retain 1b = EEE is supported for 100BASE-TX.
0b = EEE is not supported for 100BASE-TX.
0 Reserved RO 0x0 Retain Reserved.
Bits Field Mode HW Rst SW Rst Description
15:0 EEE wake error
counter RO,NR 0x0000 Retain
Bits Field Mode HW Rst SW Rst Description
15:7 Reserved RO 0x0 Retain Reserved.
6 10GBASE-KR EEE RO 0x0 Retain 1b = EEE is supported for 10GBASE-KR.
0b = EEE is not supported for 10GBASE-KR.
5 10GBASE-KX4
EEE RO 0x0 Retain 1b = EEE is supported for 10GBASE-KX4.
0b = EEE is not supported for 1000BASE-KX RO.
4 1000BASE-KX RO 0x0 Retain 1b = EEE is supported for 1000BASE-KX.
0b = EEE is not supported for 1000BASE-KX RO.
3 10GBASE-T EEE RO 0x0 Retain 1b = EEE is supported for 10GBASE-T.
0b = EEE is not supported for 10GBASE-T.
Programming Interface — Ethernet Controller I210
577
8.27.4.6 EEE Link Partner Advertisement Register - Device 7, Register 61
8.27.5 PHY Registers
2 1000BASE-T EEE R/W 0x0 Retain 1b = EEE is supported for 1000BASE-T.
0b = EEE is not supported for 1000BASE-T.
1 100BASE-TX EEE R/W 0x0 Retain 1b = EEE is supported for 100BASE-TX.
0b = EEE is not supported for 100BASE-TX.
0 Reserved RO 0x0 Retain Reserved.
Bits Field Mode HW Rst SW Rst Description
15:7 Reserved RO 0x000 Retain Reserved.
6 LP 10GBASE-KR
EEE RO 0x0 Retain 1b = EEE is supported for 10GBASE-KR.
0b = EEE is not supported for 10GBASE-KR.
5 LP 10GBASE-KX4
EEE RO 0x0 Retain 1b = EEE is supported for 10GBASE-KX4.
0b = EEE is not supported for 1000BASE-KX RO.
4 LP 1000BASE-KX RO 0x0 Retain 1b = EEE is supported for 1000BASE-KX.
0b = EEE is not supported for 1000BASE-KX RO.
3 LP 10GBASE-T EEE RO 0x0 Retain 1b = EEE is supported for 10GBASE-T.
0b = EEE is not supported for 10GBASE-T.
2 LP 1000BASE-T
EEE RO 0x0 Retain 1b = EEE is supported for 1000BASE-T.
0b = EEE is not supported for 1000BASE-T.
1 LP 100BASE-TX
EEE RO 0x0 Retain 1b = EEE is supported for 100BASE-TX.
0b = EEE is not supported for 100BASE-TX.
0 Reserved RO 0x0 Retain Reserved.
Register Name Register Address Table and Page
Fiber Control Register Page 26, register 16 section 8.27.5.1 on page 578.
Fiber Control Register Page 26, register 21 section 8.27.5.2 on page 578.
PRBS Control Page 26, register 23 section 8.27.5.3 on page 578.
PRBS Error Counter LSB Page 26, register 24 section 8.27.5.4 on page 579.
PRBS Error Counter MSB Page 26, register 25 section 8.27.5.5 on page 579.
Fiber Specific Control Register 2 Page 26, register 26 section 8.27.5.6 on page 579.
Polarity Control Page 26, register 27 section 8.27.5.7 on page 580.
SERDES TX FIFO Control and Status Page 26, register 28 section 8.27.5.8 on page 580.
Voltage Regulator Control Page 26, register 30 section 8.27.5.9 on page 581.
Ethernet Controller I210 — Programming Interface
578
8.27.5.1 Fiber Control Register - Page 26, Register 16
8.27.5.2 Fiber Control Register - Page 26, Register 21
8.27.5.3 PRBS Control - Page 26, Register 23
Bits Field Mode HW Rst SW Rst Description
15 Fiber Reset R/W 0x0 SC
Fiber Software Reset.
Affects page 1. Writing a 0x1 to this bit causes the PHY state
machines to be reset. When the reset operation completes, this bit
is cleared to 0x0 automatically. The reset occurs immediately.
1b = PHY reset.
0b = Normal operation.
14 Loopback R/W Retain
The latest event that occurs between the register write and pin
control determines the loopback. When loopback is activated, the
transmitter data presented on TXD of the internal bus is looped
back to RXD of the internal bus.
1b = Enable loopback.
0b = Disable loopback.
13:12 Reserved R/W 0x0 SC Always 0x0.
11:10 Power Down R/W 0x0
The latest event that occurs between the register write and pin
control determines the register value.
00b = Total power up.
01b = Power down everything except wire activity detection circuit.
1xb = Total power down.
9:0 Reserved RO Always
0x0 Always
0x0 Always 0x0.
Bits Field Mode HW Rst SW Rst Description
15:0 Receive Error
Count RO, LH 0x0 Retain Counter reaches its maximum count at 0xFFFF and does not roll
over. Both false carrier and symbol errors are reported.
Bits Field Mode HW Rst SW Rst Description
15:8 Reserved R/W 0x0 Retain Set to 0x0.
7 Invert Checker
Polarity R/W 0x0 Retain 0 = Normal.
1 = Invert.
6 Invert Generator
Polarity R/W 0x0 Retain 0 = Normal.
1 = Invert.
5 PRBS Lock R/W 0x0 Retain 0 = Counter free runs.
1 = Do not start counting until PRBS locks first.
4 Clear Counter R/W, SC 0x0 0x0 0 = Normal.
1 = Clear counter.
Programming Interface — Ethernet Controller I210
579
8.27.5.4 PRBS Error Counter LSB- Page 26, Register 24
8.27.5.5 PRBS Error Counter MSB- Page 26, Register 25
8.27.5.6 Fiber Specific Control Register 2 - Page 26, Register 26
3:2 Pattern Select R/W 00 Retain
00b = PRBS 7.
01b = PRBS 23.
10b = PRBS 31.
11b = Generate 1010101010... pattern.
1 PRBS Checker
Enable R/W 0x0 0x0 0b = Disable.
1b = Enable.
0 PRBS Generator
Enable R/W 0x0 0x0 0b = Disable.
1b = Enable.
Bits Field Mode HW Rst SW Rst Description
15:0 PRBS Error Count
LSB RO 0x0 Retain A read to this register freezes register 25_26. Cleared only when
register 23_26.4 is set to 0b.
Bits Field Mode HW Rst SW Rst Description
15:0 PRBS Error Count
MSB RO 0x0 Retain This register does not update unless register 24_26 is read first.
Cleared only when register 23_26.4 is set to 1b.
Bits Field Mode HW Rst SW Rst Description
15:3 Reserved R/W 0x0 Update Must be set to 0x0.
2:0 Output Amplitude R/W 0x2 Retain
Differential voltage peak measured.
The latest event that occurs between the register write and pin
control determines the current output amplitude setting.
000b = 14 mV.
001b = 112 mV.
010b = 210 mV.
011b = 308 mV.
100b = 406 mV.
101b = 504 mV.
110b = 602 mV.
111b = 700 mV.
Ethernet Controller I210 — Programming Interface
580
8.27.5.7 Polarity Control - Page 26, Register 27
8.27.5.8 SerDes TX FIFO Control and Status - Page 26, Register 28
Bits Field Mode HW Rst SW Rst Description
15 Invert rxp/n
Polarity R/W Retain
The latest event that occurs between the register write and pin
control determines the polarity.
0b = Normal.
1b = Invert.
14 Invert txp/n
Polarity R/W Retain
The latest event that occurs between the register write and pin
control determines the polarity.
0b = Normal.
1b = Invert.
13:2 Reserved R/W 0x0 Retain Reserved for future use.
1:0 SQ Control
Selection R/W 0x Retain
Squelch detector threshold control.
00b = 30 mV.
01b = 60 mV.
10b = 90 mV.
11b = 120 mV.
Bits Field Mode HW Rst SW Rst Description
15:14 SerDes Transmit
FIFO Depth R/W 0x0 Retain
00b = Read/write pointers are offset by two cycles.
01b = Read/write pointers are offset by three cycles.
1xb = Reserved.
13:2 Reserved R/W 0x0 Retain 0x0.
1 FIFO Full RC 0b Retain 1b = FIFO full, clear upon read.
0 FIFO Empty RC 0b Retain 1b = FIFO empty, clear upon read.
Programming Interface — Ethernet Controller I210
581
8.27.5.9 Voltage Regulator Control - Page 26, Register 30
Bits Field Mode HW Rst SW Rst Description
15:7 Reserved R/W 0x0 Retain 0x0.
6:3 scr09 Output
Voltage Select R/W Retain
The latest event that occurs between the register write and pin
control determines the current output amplitude setting.
0000b = 0.70V
0001b = 0.725V
0010b = 0.75V
0011b = 0.775V
0100b = 0.80V
0101b = 0.825V
0110b = 0.85V
0111b = 0.875V
1000b = 0.90V (default)
1001b = 0.925V (not recommended)
1010b = 0.95V (not recommended)
1011b = 0.975V (not recommended)
1100b = 1.00V (not recommended)
1101b = 1.025V (not recommended)
1110b = 1.05V (not recommended)
1111b = 1.075V (not recommended)
2:0 scr15 Output
Voltage Select R/W Retain
The latest event that occurs between the register write and pin
control determines the current output amplitude setting.
000b = 1.35V.
001b = 1.40V.
010b = 1.45V.
011b = 1.50V, default.
100b to 111b= Reserved.
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NOTE: This page intentionally left blank.
PCIe Programming Interface—Ethernet Controller I210
587
9.0 PCIe Programming Interface
9.1 PCIe* Compatibility
PCIe is completely compatible with existing deployed PCI software. To achieve this, PCIe hardware
implementations conform to the following requirements:
All devices required to be supported by deployed PCI software must be enumerable as part of a tree
through PCI device enumeration mechanisms.
Devices in their default operating state must conform to PCI ordering and cache coherency rules
from a software viewpoint.
PCIe devices must conform to PCI power management specifications and must not require any
register programming for PCI-compatible power management beyond those available through PCI
power management capabilities registers. Power management is expected to conform to a standard
PCI power management by existing PCI bus drivers.
PCIe devices implement all registers required by the PCI specification as well as the power
management registers and capability pointers specified by the PCI power management
specification. In addition, PCIe defines a PCIe capability pointer to indicate support for PCIe
extensions and associated capabilities.
The function contain the following regions of the PCI configuration space:
Mandatory PCI configuration registers
Power management capabilities
MSI and MSI-X capabilities
PCIe extended capabilities
9.2 PCIe Register Map
9.2.1 Register Attributes
Configuration registers are assigned one of the attributes described in the following table.
Table 9-1. Configuration Registers
Rd/Wr Description
RO Read-only register: Register bits are read-only and cannot be altered by software.
RW Read-write register: Register bits are read-write and can be either set or reset.
R/W1C Read-only status, write-1-to-clear status register, writing a 0b to R/W1C bits has no effect.
ROS Read-only register with sticky bits: Register bits are read-only and cannot be altered by software. Bits are not
cleared by reset and can only be reset with the PWRGOOD signal. Devices that consume AUX power are not
allowed to reset sticky bits when AUX power consumption (either via AUX power or PME enable) is enabled.
Ethernet Controller I210 —PCIe Programming Interface
588
The PCI configuration registers map is listed in Table 9-2. Refer to a detailed description for registers
loaded from the Flash at initialization time. Note that initialization values of the configuration registers
are marked in parenthesis.
9.2.2 PCIe Configuration Space Summary
RWS
Read-write register: Register bits are read-write and can be either set or reset by software to the desired
state. Bits are not cleared by reset and can only be reset with the PWRGOOD signal. Devices that consume
AUX power are not allowed to reset sticky bits when AUX power consumption (either via AUX power or PME
enable) is enabled.
R/W1CS
Read-only status, write-1-to-clear status register: Register bits indicate status when read, a set bit indicating
a status event can be cleared by writing a 1b. Writing a 0b to R/W1C bits has no effect. Bits are not cleared
by reset and can only be reset with the PWRGOOD signal. Devices that consume AUX power are not allowed
to reset sticky bits when AUX power consumption (either via AUX power or PME enable) is enabled.
HwInit Hardware initialized: Register bits are initialized by firmware or hardware mechanisms such as pin strapping
or serial Flash. Bits are read-only after initialization and can only be reset (for write-once by firmware) with
PWRGOOD signal.
RsvdP Reserved and preserved: Reserved for future R/W implementations; software must preserve value read for
writes to bits.
RsvdZ Reserved and zero: Reserved for future R/W1C implementations; software must use 0b for writes to bits.
Table 9-2. PCIe Configuration Registers Map -
Section Byte
Offset Byte 3 Byte 2 Byte 1 Byte 0
Mandatory PCI
register
0x0 Device ID Vendor ID
0x4 Status Register Control Register
0x8 Class Code (0x020000/0x010000) Revision ID
0xC BIST (0x00) Header Type (0x0/
0x80) Latency Timer Cache Line Size (0x10)
0x10 Base Address Register 0
0x14 Base Address Register 1
0x18 Base Address Register 2
0x1C Base Address Register 3
0x20 Base Address Register 4
0x24 Base Address Register 5
0x28 CardBus CIS pointer (0x0000)
0x2C Subsystem Device ID Subsystem Vendor ID
0x30 Expansion ROM Base Address
0x34 Reserved Cap Ptr (0x40)
0x38 Reserved
0x3C Max Latency (0x00) Min Grant (0x00) Interrupt Pin
(0x01...0x04) Interrupt Line (0x00)
Power
management
capability
0x40 Power Management Capabilities Next Pointer (0x50) Capability ID (0x01)
0x44 Data Bridge Support
Extensions Power Management Control & Status
Table 9-1. Configuration Registers (Continued)
PCIe Programming Interface—Ethernet Controller I210
589
MSI capability
0x50 Message Control (0x0080) Next Pointer (0x70) Capability ID (0x05)
0x54 Message Address
0x58 Message Upper Address
0x5C Reserved Message Data
0x60 Mask bits
0x64 Pending bits
MSI-X capability
0x70 Message Control (0x00090) Next Pointer (0xA0) Capability ID (0x11)
0x74 Table Offset
0x78 PBA offset
CSR Access
Registers
0x98 IOADDR
0x9C IODATA
PCIe capability
0xA0 PCIe Capability Register (0x0002) Next Pointer (0xE0) Capability ID (0x10)
0xA4 Device Capability
0xA8 Device Status Device Control
0xAC Link Capabilities
0xB0 Link Status Link Control
0xB4 Reserved
0xB8 Reserved Reserved
0xBC Reserved
0xC0 Reserved Reserved
0xC4 Device Capability 2
0xC8 Reserved Device Control 2
0xCC Reserved
0xD0 Link Status 2 Link Control 2
0xD4 Reserved
0xD8 Reserved Reserved
VPD capability 0xE0 VPD address Next Pointer (0x00) Capability ID (0x03)
0xE4 VPD data
AER capability
0x100 Next Capability Ptr.
(0x140) Version (0x2) AER Capability ID (0x0001)
0x104 Uncorrectable Error Status
0x108 Uncorrectable Error Mask
0x10C Uncorrectable Error Severity
0x110 Correctable Error Status
0x114 Correctable Error Mask
0x118 Advanced Error Capabilities and Control Register
0x11C:
0x128 Header Log
Serial ID
capability
0x140 Next Capability Ptr.
(0x1A0) Version (0x1) Serial ID Capability ID (0x0003)
0x144 Serial Number Register (Lower Dword)
0x148 Serial Number Register (Upper Dword)
Table 9-2. PCIe Configuration Registers Map (Continued)-
Section Byte
Offset Byte 3 Byte 2 Byte 1 Byte 0
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590
A description of the registers is provided in the following sections.
9.3 Mandatory PCI Configuration Registers
9.3.1 Vendor ID (0x0; RO)
This value can be loaded automatically from Flash address 0x0E at power up or reset. A value of
0x8086 is the default for this field at power up if the Flash does not respond or is not programmed.
Note: To avoid a system hang situation, if a value of 0xFFFF is read from the Flash, the value of the
Vendor ID field defaults back to 0x8086.
9.3.2 Device ID (0x2; RO)
This is a read-only register. This field identifies individual I210 functions. It can be auto-loaded from the
Flash during initialization with a different value. The following table lists the possible values according
to the SKU and functionality.
2. CTRL_EXT.Link_Mode field value 00b (10/100/1000 BASE-T internal PHY mode).
3. CTRL_EXT.Link_Mode field value 11b (SerDes).
4. CTRL_EXT.Link_Mode field value either 01b (1000BASE-KX) or 11b (SerDes - 1000BASE-BX). User option to enable Clause 37 Auto-
negotiation.
5. CTRL_EXT.Link_Mode field value 10b (SGMII).
TPH Requester
capability
0x1A0 Next Capability Ptr.
(0x1C0) Version (0x1) TPH Capability ID (0x17)
0x1A4 TPH Requester Capability Register
0x1A8 TPH Requester Control Register
0x1AC:
0x1B8 TPH Steering Table
LTR capability
0x1C0 Next Capability Ptr.
(0x000) Version (0x1) LTR Capability ID (0x18)
0x1C4 Maximum Non-Snooped Platform Latency
Tolerance Register Maximum Snooped Platform Latency Tolerance
Register
PCI
Function
Default
Value
Flash
Address Description
LAN 0
0x1533 for
I210 SKUs
with a
programmed
Flash
0x0D
0x1531 - I210 with a blank Flash (tools only, not for driver)
0x1533 - I210 10/100/1000 Mb/s Ethernet controller, copper only2
0x1534 - Reserved
0x1536 - I210 10/100/1000 Mb/s Ethernet controller, Fiber 3
0x1537 - I210 10/100/1000 Mb/s Ethernet controller, 1000BASE-KX/BX backplane 4
0x1538 - I210 10/100/1000 Mb/s Ethernet controller, External SGMII PHY 5
Table 9-2. PCIe Configuration Registers Map (Continued)-
Section Byte
Offset Byte 3 Byte 2 Byte 1 Byte 0
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591
9.3.3 Command Register (0x4; R/W)
This is a read/write register.
9.3.4 Status Register (0x6; RO)
Bit(s) R/W Initial Value Description
0 R/W1
1. If IO_Sup bit in PCIe Init Configuration 2 Flash Word (0x19) is 0, I/O Access Enable bit is RO with a value of 0.
0b I/O Access Enable
1 R/W 0b Memory Access Enable
2 R/W 0b Bus Master Enable (BME)
3 RO 0b Special Cycle Monitoring
Hardwired to 0b.
4 RO 0b MWI Enable
Hardwired to 0b.
5 RO 0b Palette Snoop Enable
Hardwired to 0b.
6 RW 0b Parity Error Response
7 RO 0b Wait Cycle Enable
Hardwired to 0b.
8 RW 0b SERR# Enable
9 RO 0b Fast Back-to-Back Enable
10 RW 0b Interrupt Disable2
2. The Interrupt Disable register bit is a read-write bit that controls the ability of a PCIe device to generate a legacy interrupt message.
When set, devices are prevented from generating legacy interrupt messages.
15:11 RO 0x0 Reserved
Bits R/W Initial Value Description
2:0 000b Reserved
3 RO 0b Interrupt Status1
1. The Interrupt Status field is a RO field that indicates that an interrupt message is pending internally to the device.
4 RO 1b
New Capabilities
Indicates that a device implements extended capabilities. The I210 sets this bit, and
implements a capabilities list, to indicate that it supports PCI power management, Message
Signaled Interrupts (MSI), Enhanced Message Signaled Interrupts (MSI-X), Vital Product
Data (VPD), and the PCIe extensions.
5 0b 66 MHz Capable
Hardwired to 0b.
6 0b Reserved
7 0b Fast Back-to-Back Capable
Hardwired to 0b.
8 R/W1C 0b Data Parity Reported
10:9 00b DEVSEL Timing
Hardwired to 0b.
11 R/W1C 0b Signaled Target Abort
12 R/W1C 0b Received Target Abort
13 R/W1C 0b Received Master Abort
14 R/W1C 0b Signaled System Error
15 R/W1C 0b Detected Parity Error
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9.3.5 Revision (0x8; RO)
The default revision ID for the I210 A1 stepping is 0x01 and 0x03 for A2 stepping. The value of the rev
ID is a logic XOR between the default value and the value in Flash word 0x1E.
9.3.6 Class Code (0x9; RO)
The class code is a RO hard coded value that identifies the I210’s functionality.
0x020000/0x010000 - Ethernet/SCSI Adapter1
9.3.7 Cache Line Size (0xC; R/W)
This field is implemented by PCIe devices as a read-write field for legacy compatibility purposes but has
no impact on any PCIe device functionality. Field is loaded from the PCIe Init Configuration 3 (Word
0x1A) Flash word and defines cache line size in Dwords. In systems, the value is 0x10.
9.3.8 Latency Timer (0xD; RO)
Not used. Hardwired to zero.
9.3.9 Header Type (0xE; RO)
This indicates if a device is single function or multifunction. If a single LAN function is the only active
one then this field has a value of 0x00 to indicate a single function device.
9.3.10 BIST (0xF; RO)
BIST is not supported in the I210.
9.3.11 Base Address Registers (0x10...0x27; R/W)
The Base Address registers (BARs) are used to map the I210 register space. The I210 has a memory
BAR, IO BAR and MSI-X BAR described in Table 9-3 below.
1. Selected according to bit 11 in Device Rev ID Flash word.
Table 9-3. Base Address Registers Description -
Mapping Windows Mapping Description
Memory BAR
The internal registers memories and external Flash device are accessed as direct memory mapped offsets
from the Base Address register. Software can access a Dword or 64 bits.
The Flash space in this BAR is enabled by the FLBARSize and CSRSize fields in the BARCTRL register.
Address 0 in the Flash device is mapped to address 128K in the Memory BAR. When the usable Flash size
+ CSR space is smaller than the memory BAR, then accessing addresses above the top of the Flash
wraps back to the beginning of the Flash.
IO BAR All internal registers and memories can be accessed using I/O operations. There are two 4-byte registers
in the IO mapping window: Addr Reg and Data Reg accessible as Dword entities. I/O BAR support
depends on the IO_Sup bit in the Flash “PCIe Init Configuration 2” word.
MSI-X BAR The MSI-X vectors and Pending bit array (PBA) structures are accessed as direct memory mapped offsets
from the MSI-X BAR. Software can access Dword entities.
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9.3.11.1 32-bit LAN BARs Mode Mapping
This mapping is selected when bit 10 in the Functions Control Flash word is equal to 1b.
9.3.11.2 64-bit LAN BARs Mode Mapping
This mapping is selected when bit 10 in the Functions Control Flash word is equal to 0b.
9.3.11.3 Base Address Register Fields
All base address registers have the following fields.
Table 9-4. Base Address Setting in 32bit BARs Mode (BARCTRL.BAR32 = 1b)
BAR Addr 31 - - - - - - - - - - - - - - - - - - - - - - - - - - -5 4 3 2 1 0
0 0x10 Memory CSR + FLASH BAR (R/W - 31:17; RO - 16:4 (0x0)) 0/1 0 0 0
1 0x14 Reserved (read as all 0b’s)
2 0x18 IO BAR (R/W - 31:5) 0 0 0 0 1
3 0x1C MSI-X BAR (R/W - 31:14; RO - 13:4 (0x0)) 0/1 0 0 0
4 0x20 Reserved (read as all 0b’s)
5 0x24 Reserved (read as all 0b’s)
Table 9-5. Base Address Setting in 64bit BARs Mode (BARCTRL.BAR32 = 0b)
BAR Addr 31 - - - - - - - - - - - - - - - - - - - - - - - - - - -5 4 3 2 1 0
0 0x10 Memory CSR + FLASH BAR Low (RW - 31:17;RO - 16:4 (0x0)) 0/1 1 0 0
1 0x14 Memory CSR + FLASH BAR High (RW)
2 0x18 IO BAR (R/W - 31:5) 00001
3 0x1C Reserved (RO - 0)
4 0x20 MSI-X BAR Low (RW - 31:14; RO - 13:4 (0x0)) 0/1 1 0 0
5 0x24 MSI-X BAR High (RW)
Table 9-6. Base Address Registers' Fields
Field Bits R/W Description
Mem / IO Space
Indication 0 RO 0b = Indicates memory space.
1b = Indicates I/O.
Memory Type 2:1 RO 00b = 32-bit BAR (BAR32 in the Flash equals 1b)
10b = 64-bit BAR (BAR32 in the Flash equals 0b)
Prefetch Memory 3 RO
0b = Non-prefetchable space.
1b = Prefetchable space (device default).
This bit is loaded from the PREFBAR bit in the Flash. This bit should be set only on systems
that do not generate prefetchable cycles.
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9.3.12 CardBus CIS (0x28; RO)
Not used. Hardwired to zero.
9.3.13 Subsystem Vendor ID (0x2C; RO)
This value can be loaded automatically from Flash address 0x0C at power up or reset. A value of
0x8086 is the default for this field at power up if the Flash does not respond or is not programmed.
9.3.14 Subsystem ID (0x2E; RO)
This value can be loaded automatically from Flash address 0x0B at power up with a default value of
0x0000.
9.3.15 Expansion ROM Base Address (0x30; RW)
This register is used to define the address and size information for boot-time access to the optional
Flash memory. Expansion ROM is enabled by placing 0b in the LAN Boot Disable Flash bit. This register
returns a zero value for function without an Expansion ROM window.
Address Space
(Low register for
64bit Memory
BARs)
31:4 R/W
The length of the RW bits and RO 0b bits depend on the mapping window sizes. Init value of
the RW fields is 0x0.
Mapping Window RO bits
Memory CSR + FLASH BAR size depends on BARCTRL.FLBARSize and
BARCTRL.CSRSize fields.
16:4 for 128KB
17:4 for 256KB
and so on...
MSI-X space is 16KB 13:4
I/O spaces size is 32 bytes 4
Field Bit(s) R/W Initial Value Description
En 0 RO 0b 1b = Enables Expansion ROM access.
0b = Disables Expansion ROM access.
Reserved 10:1 RO 0b Always read as 0b. Writes are ignored.
Address 31:11 R/W 0b
Read-write bits are hard wired to 0b and dependent on the memory mapping
window size. The LAN Expansion ROM spaces can be either 512 KB to 8 MB in
powers of 2. Mapping window size is set by the FLBAR_size Flash field.
Note: Increasing the FLBAR_size beyond 1 MB does not increase the Flash
area that can be accessed through the EXPROM BAR (see Section 3.3.3.1).
Table 9-6. Base Address Registers' Fields
Field Bits R/W Description
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9.3.16 Cap_Ptr (0x34; RO)
The Capabilities Pointer field (Cap_Ptr) is an 8-bit field that provides an offset in the device's PCI
configuration space for the location of the first item in the Capabilities Linked List (CLL). The I210 sets
this bit and implements a capabilities list to indicate that it supports PCI power management, Message
Signaled Interrupts (MSIs), and PCIe extended capabilities. Its value is 0x40, which is the address of
the first entry: PCI power management.
9.3.17 Interrupt Line (0x3C; RW)
Read/write register programmed by software to indicate which of the system interrupt request lines this
I210's interrupt pin is bound to. See the PCIe definition for more details.
9.3.18 Interrupt Pin (0x3D; RO)
Read only register. Always report INTA#.
9.3.19 Max_Lat/Min_Gnt (0x3E; RO)
Not used. Hardwired to zero.
9.4 PCI Capabilities
The first entry of the PCI capabilities link list is pointed by the Cap_Ptr register. The following tables
describes the capabilities supported by the I210.
9.4.1 PCI Power Management Capability
All fields are reset on full power-up. All of the fields except PME_En and PME_Status are reset on exit
from D3cold state. If aux power is not supplied, the PME_En and PME_Status fields also reset on exit
from D3cold state.
See the detailed description for registers loaded from the Flash at initialization time. Behavior of some
fields in this section depend on the Power Management bit in Flash word 0x0A.
Table 9-7. PCI capabilities
Address Item Next Pointer
0x40-47 PCI Power Management 0x50
0x50-67 Message Signaled Interrupt 0x70
0x70-8B Extended Message Signaled Interrupt 0xA0
0xA0-DB PCIe Capabilities 0xE0/0x001
1. Next pointer is 0x00 if the VPD area in the Flash does not exist. In mode, the PCIe capability is the last capabilities section.
0xE0-0xE7 Vital Product Data Capability 0x00
Byte Offset Byte 3 Byte 2 Byte 1 Byte 0
0x40 Power Management Capabilities Next Pointer (0x50) Capability ID (0x01)
0x44 Data Bridge Support
Extensions Power Management Control & Status
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9.4.1.1 Capability ID (0x40; RO)
This field equals 0x01 indicating the linked list item as being the PCI Power Management registers.
9.4.1.2 Next Pointer (0x41; RO)
This field provides an offset to the next capability item in the capability list. In LAN function, a value of
0x50 points to the MSI capability.
9.4.1.3 Power Management Capabilities - PMC (0x42; RO)
This field describes the I210’s functionality at the power management states as described in the
following table. Note that each device function has its own register.
9.4.1.4 Power Management Control / Status Register - PMCSR (0x44; R/W)
This register is used to control and monitor power management events in the I210. Note that each
device function has its own PMCSR register.
Bits Default R/W Description
15:11
01001b
See value in
description
column
RO
PME_Support - This 5-bit field indicates the power states in which the function might assert
PME#. A value of 0b for any bit indicates that the function is not capable of asserting the
PME# signal while in that power state.
bit(11) X XXX1b - PME# can be asserted from D0
bit(12) X XX1Xb - PME# can be asserted from D1
bit(13) X X1XXb - PME# can be asserted from D2
bit(14) X 1XXXb - PME# can be asserted from D3hot
bit(15) 1 XXXXb - PME# can be asserted from D3cold
Value of bit 15 is a function of Aux Pwr availability and Power Management (PM Ena) bit in
Initialization Control Word 1 (word 0x0A) Flash word.
Conditionaaaaaaaaaaa Functionalityaaaaaaaaaaaaa aValue
PM Dis in Flash No PME at all states 00000b
PM Ena & NoAux Pwr PME at D0 and D3hot aaaaaaaaa 01001b
PM Ena & Aux Pwr PME at D0, D3hot and D3coldaa 11001b
Note: Aux Pwr is considered available if AUX_PWR pin is connected to 3.3V and
D3COLD_WAKEUP_ADVEN Flash bit is set to 1b.
10 0b RO D2_Support
The I210 does not support D2 state.
9 0b RO D1_Support
The I210 does not support D1 state.
8:6 000b RO AUX Current – Required current defined in the Data Register.
5 1b RO
DSI
The I210 requires its device driver to be executed following transition to the D0 uninitialized
state.
4 0b RO Reserved
3 0b RO PME_Clock
Disabled. Hardwired to 0b.
2:0 011b RO Version
The I210 complies with the PCI PM specification, revision 1.2.
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9.4.1.5 Bridge Support Extensions - PMCSR_BSE (0x46; RO)
This register is not implemented in the I210. Values are set to 0x00.
9.4.1.6 Data Register (0x47; RO)
This optional register is used to report power consumption and heat dissipation. Reported register is
controlled by the Data_Select field in the PMCSR and the power scale is reported in the Data_Scale field
in the PMCSR. The data of this field is loaded from the Flash if power management is enabled in the
Flash or with a default value of 0x00. The values for the I210 are read from Flash word 0x22.
Bits Default R/W Description
15
0b
(at power
up)
R/W1CS
PME_Status
This bit is set to 1b when the function detects a wake-up event independent of the state of the
PME_En bit. Writing a 1b clears this bit.
14:13 01b RO
Data_Scale
This field indicates the scaling factor to be used when interpreting the value of the Data
register.
This field equals 01b (indicating 0.1 watt units) if power management is enabled in the Power
Management (PM Ena) bit in Initialization Control Word 1 (word 0x0A) Flash word and the
Data_Select field is set to 0, 3, 4, 7, (or 8). Otherwise, this field equals 00b.
12:9 0000b R/W
Data_Select
This four-bit field is used to select which data is to be reported through the Data register and
Data_Scale field. These bits are writable only when power management is enabled by setting
the Power Management (PM Ena) bit in Initialization Control Word 1 (word 0x0A) Flash word.
8
0b
(at power
up)
R/WS
PME_En
If power management is enabled in the Flash, writing a 1b to this register enables wake up.
If power management is disabled in the Flash, writing a 1b to this bit has no effect and does
not set the bit to 1b.
7:4 000000b RO Reserved
3 1b1
1. Loaded from Flash (See Section 6.2.17).
RO
No_Soft_Reset
No_Soft_Reset - When set (“1”), this bit indicates that when the I210 transitions from D3hot to
D0 because of modifying Power State bits in the PMCSR register, no internal reset is issued and
Configuration Context is preserved. Upon transition from the D3hot to the D0 Initialized state,
no additional operating system intervention is required to preserve Configuration Context
beyond writing the Power State bits.
When clear (“0”), the I210 performs an internal reset upon transitioning from D3hot to D0 via
software control of the Power State bits in the PMCSR register. Configuration Context is lost
when performing the soft reset. Upon transition from the D3hot to the D0 state, full re
initialization sequence is needed to return the device to D0 Initialized.
Regardless of this bit, devices that transition from D3hot to D0 by a system or bus segment
reset returns to the device state D0 Uninitialized with only PME context preserved if PME is
supported and enabled.
2 0b RO Reserved for PCIe.
1:0 00b R/W
Power State
This field is used to set and report the power state of a function as follows:
00b = D0
01b = D1 (cycle ignored if written with this value)
10b = D2 (cycle ignored if written with this value)
11b = D3 (cycle ignored if power management is not enabled in the Flash)
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For other Data_Select values, the Data register output is reserved (0x0).
9.4.2 MSI Configuration
This structure is required for PCIe devices.
9.4.2.1 Capability ID (0x50; RO)
This field equals 0x05 indicating the linked list item as being the MSI registers.
9.4.2.2 Next Pointer (0x51; RO)
This field provides an offset to the next capability item in the capability list. Its value of 0x70 points to
the MSI-X capability structure.
9.4.2.3 Message Control (0x52; R/W)
The register fields are described in the following table. There is a dedicated register per PCI function to
separately enable their MSI.
Function D0 (Consume/
Dissipate)
D3 (Consume/
Dissipate) Common
PMCSR.Data Select 0x0 / 0x4 0x3 / 0x7 0x8
Function 0 Flash addr 0x22 Flash addr 0x22 Flash addr 0x22
Byte Offset Byte 3 Byte 2 Byte 1 Byte 0
0x50 Message Control (0x0180) Next Pointer (0x70) Capability ID (0x05)
0x54 Message Address
0x58 Message Upper Address
0x5C Reserved Message Data
0x60 Mask bits
0x64 Pending bits
Bits Default R/W Description
0 0b R/W
MSI Enable
If set to 1b, equals MSI. In this case, the I210 generates an MSI for interrupt assertion instead
of INTx signaling.
3:1 000b RO Multiple Message Capable
The I210 indicates a single requested message.
6:4 000b RO Multiple Message Enable
The I210 returns 000b to indicate that it supports a single message.
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9.4.2.4 Message Address Low (0x54; R/W)
Written by the system to indicate the lower 32 bits of the address to use for the MSI memory write
transaction. The lower two bits always return 0b regardless of the write operation.
9.4.2.5 Message Address High (0x58; R/W)
Written by the system to indicate the upper 32-bits of the address to use for the MSI memory write
transaction.
9.4.2.6 Message Data (0x5C; R/W)
Written by the system to indicate the lower 16 bits of the data written in the MSI memory write Dword
transaction. The upper 16 bits of the transaction are written as 0b.
9.4.2.7 Mask bits (0x60; R/W)
The Mask Bits and Pending Bits registers enable software to disable or defer message sending on a per-
vector basis. As the I210 supports only one message, only bit 0 of these register is implemented.
9.4.2.8 Pending Bits (0x64; R/W)
9.4.3 MSI-X Configuration
More than one MSI-X capability structure is prohibited, but a function is permitted to have both an MSI
and an MSI-X capability structure.
7 1b RO 64-bit capable
A value of 1b indicates that the I210 is capable of generating 64-bit message addresses.
8 1b1RO
MSI per-vector masking.
A value of 1b indicates that the I210 is capable of per-vector masking.
This field is loaded from the MSI-X Configuration (Offset 0x16) Flash word.
15:9 0b RO Reserved
Write 0 ignore on read.
1. Default value is read from the Flash.
Bits Default R/W Description
0 0b R/W MSI Vector 0 Mask
If set, the I210 is prohibited from sending MSI messages.
31:1 000b RO Reserved
Bits Default R/W Description
0 0b RO If set, the I210 has a pending MSI message.
31:1 000b RO Reserved
Bits Default R/W Description
Ethernet Controller I210 —PCIe Programming Interface
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In contrast to the MSI capability structure, which directly contains all of the control/status information
for the function's vectors, the MSI-X capability structure instead points to an MSI-X table structure and
a MSI-X Pending Bit Array (PBA) structure, each residing in memory space.
Each structure is mapped by a Base Address Register (BAR) belonging to the function, located
beginning at 0x10 in configuration space. A BAR Indicator Register (BIR) indicates which BAR, and a
Qword-aligned offset indicates where the structure begins relative to the base address associated with
the BAR. The BAR is permitted to be either 32-bit or 64-bit, but must map to memory space. A function
is permitted to map both structures with the same BAR, or to map each structure with a different BAR.
The MSI-X table structure, listed in Section 8.9, typically contains multiple entries, each consisting of
several fields: message address, message upper address, message data, and vector control. Each entry
is capable of specifying a unique vector.
The PBA structure, described in the same section, contains the function's pending bits, one per Table
entry, organized as a packed array of bits within Qwords. Note that the last Qword might not be fully
populated.
To request service using a given MSI-X table entry, a function performs a Dword memory write
transaction using:
The contents of the Message Data field entry for data.
The contents of the Message Upper Address field for the upper 32 bits of the address.
The contents of the Message Address field entry for the lower 32 bits of the address.
A memory read transaction from the address targeted by the MSI-X message produces undefined
results.
The MSI-X table and MSI-X PBA are permitted to co-reside within a naturally aligned 4 KB address
range, though they must not overlap with each other.
MSI-X table entries and Pending bits are each numbered 0 through N-1, where N-1 is indicated by the
Table Size field in the MSI-X Message Control register. For a given arbitrary MSI-X table entry K, its
starting address can be calculated with the formula:
Entry starting address = Table base + K*16
For the associated Pending bit K, its address for Qword access and bit number within that Qword can be
calculated with the formulas:
Qword address = PBA base + (K div 64)*8
Qword bit# = K mod 64
Software that chooses to read Pending bit K with Dword accesses can use these formulas:
Dword address = PBA base + (K div 32)*4
Dword bit# = K mod 32
The I210 also supports the table-less MSI-X mode, where a single interrupt vector is provided. The
MSI-X table and MSI-X PBA are not used. Instead, the capability structure includes several additional
fields (Message Address, Message Address Upper, and Message Data) for vector configuration. The
I210 embeds the number of the original MSI-X vectors (i.e. the vectors supported if the number of
vectors was not limited to 1) in the LSB bits of the Message Data field.
PCIe Programming Interface—Ethernet Controller I210
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9.4.3.1 Capability ID (0x70; RO)
This field equals 0x11 indicating the linked list item as being the MSI-X registers.
9.4.3.2 Next Pointer (0x71; RO)
This field provides an offset to the next capability item in the capability list. Its value of 0xA0 points to
the PCIe capability.
9.4.3.3 Message Control (0x72; R/W)
The register fields are described in the following table. There is a dedicated register per PCI function to
separately configure their MSI-X functionality.
Table 9-8. MSI-X Capability Structure
Byte Offset Byte 3 Byte 2 Byte 1 Byte 0
0x70 Message Control (0x00090) Next Pointer (0xA0) Capability ID (0x11)
0x74 Table Offset
0x78 PBA offset
Bits Default R/W Description
10:0 0x0041
1. Default value is read from the Flash.
RO
TS - Table Size
System software reads this field to determine the MSI-X Table Size N, which is encoded as N-
1. For example, a returned value of 0x00F indicates a table size of 16.
The I210 supports 5 MSI-X vectors.
This field is loaded from the MSI-X Configuration (Offset 0x16) Flash word.
13:11 000b RO Reserved
Always return 000b on read. Write operation has no effect.
14 0b R/W
FM - Function Mask
If set to 1b, all of the vectors associated with the function are masked, regardless of their per-
vector Mask bit states.
If set to 0b, each vector’s Mask bit determines whether the vector is masked or not.
Setting or clearing the MSI-X Function Mask bit has no effect on the state of the per-vector
Mask bits.
15 0b R/W
En - MSI-X Enable
If set to 1b and the MSI Enable bit in the MSI Message Control (MMC) register is 0b, the
function is permitted to use MSI-X to request service and is prohibited from using its INTx#
pin.
System configuration software sets this bit to enable MSI-X. A software device driver is
prohibited from writing this bit to mask a function’s service request.
If set to 0b, the function is prohibited from using MSI-X to request service.
Ethernet Controller I210 —PCIe Programming Interface
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9.4.3.4 MSI-X Table Offset (0x74; R/W)
9.4.3.5 MSI-X Pending Bit Array - PBA Offset (0x78; R/W)
9.4.4 CSR Access Via Configuration Address Space
9.4.4.1 IOADDR Register (0x98; R/W)
This is a read/write register. Register is cleared at Power-up or PCIe reset.
Note: When function is in D3 state Software should not attempt to access CSRs via the IOADDR and
IODATA registers.
Bits Default Type Description
31:3 0x000 RO
Table Offset
Used as an offset from the address contained by one of the function’s BARs to point to the base
of the MSI-X table. The lower three table BIR bits are masked off (set to zero) by software to
form a 32-bit Qword-aligned offset.
2:0 0x3/0x4 RO
Table BIR
Indicates which one of a function’s BARs, located beginning at 0x10 in configuration space, is
used to map the function’s MSI-X table into memory space.
BIR values: 0...5 correspond to BARs 0x10…0x 24 respectively. A BIR value of 3 indicates that
the table is mapped in BAR 3 (address 0x1C).
When BARCTRL.BAR32 equals 0b (64 bit MMIO mapping) the table BIR equals 0x4. When
BARCTRL.BAR32 equals 1b (32 bit MMIO mapping) the table BIR equals 0x3.
Bits Default Type Description
31:3 0x400 RO
PBA Offset
Used as an offset from the address contained by one of the function’s BARs to point to the base
of the MSI-X PBA. The lower three PBA BIR bits are masked off (set to zero) by software to
form a 32-bit Qword-aligned offset.
2:0 0x3 RO
PBA BIR: Indicates which one of a function’s Base Address registers, located beginning at 10h
in Configuration Space, is used to map the function’s MSI-X PBA into Memory Space.
BIR values: 0...5 correspond to BARs 0x10…0x 24 respectively. A BIR value of 3 indicates that
the table is mapped in BAR 3 (address 0x1C).
When BARCTRL.BAR32 equals 0b (64 bit MMIO mapping) the table BIR equals 0x4. When
BARCTRL.BAR32 equals 1b (32 bit MMIO mapping) the table BIR equals 0x3.
Bit(s) R/W Initial Value Description
30:0 R/W1
1. In the event that the CSR_conf_en bit in the PCIe Init Configuration 2 Flash word is cleared, accesses to the IOADDR register via
configuration address space is ignored and has no effect on the register and the CSRs referenced by the IOADDR register.
0x0
Internal Register or Internal Memory location Address.
0x00000-0x1FFFF – Internal Registers and Memories
0x20000-0x7FFFFFFF – Undefined
31 R/W 0b
Configuration IO Access Enable.
0b - CSR configuration read or write disabled.
1b - CSR Configuration read or write enabled
When bit is set accesses to the IODATA register actually generate transactions to the
device. Otherwise, accesses to the IODATA register are don't-cares (write are discarded
silently, reads return arbitrary results).
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9.4.4.2 IODATA Register (0x9C; R/W)
This is a read/write register. Register is cleared at Power-up or PCIe reset.
9.4.5 Vital Product Data Registers
The I210 supports access to a VPD structure stored in the Flash using the following set of registers.
9.4.5.1 Capability ID (0xE0; RO)
This field equals 0x3 indicating the linked list item as being the VPD registers.
9.4.5.2 Next Pointer (0xE1; RO)
Offset to the next capability item in the capability list. A 0x00 value indicates that it is the last item in
the capability-linked list.
9.4.5.3 VPD Address (0xE2; RW)
Dword-aligned byte address of the VPD area in the Flash to be accessed. The register is read/write with
the initial value at power-up indeterminate.
Bit(s) R/W Initial Value Description
31:0 R/W1
1. In the event that the CSR_conf_en bit in the PCIe Init Configuration 2 Flash word is cleared, access to the IODATA register via
configuration address space is ignored and has no effect on the register and the CSRs referenced by the IOADDR register.
0x0 Data field for reads or writes to the Internal register or internal memory location as
identified by the current value in IOADDR. All 32 bits of this register are read/write-able.
Byte Offset Byte 3 Byte 2 Byte 1 Byte 0
0xE0 VPD address Next Pointer (0x00) Capability ID (0x03)
0xE4 VPD data
Bits Default R/W Description
14:0 X RW
Address
Dword-aligned byte address of the VPD area in the Flash to be accessed. The register is read/
write with the initial value at power-up indeterminate. The two LSBs are RO as zero. This is the
address relative to the start of the VPD area. As the maximal size supported by the I210 is
1024 bytes, bits 14:10 should always be zero.
15 0b RW
F
A flag used to indicate when the transfer of data between the VPD Data register and the
storage component completes. The Flag register is written when the VPD Address register is
written.
0b = Read. Set by the device when data is valid.
1b = Write. Cleared by the device when data is written to the Flash.
The VPD address and data should not be modified before the action completes.
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9.4.5.4 VPD Data (0xE4; RW)
This register contains the VPD read/write data.
9.4.6 PCIe Configuration Registers
PCIe provides two mechanisms to support native features:
PCIe defines a PCI capability pointer indicating support for PCIe.
PCIe extends the configuration space beyond the 256 bytes available for PCI to 4096 bytes.
The I210 implements the PCIe capability structure for endpoint devices as follows:
9.4.6.1 Capability ID (0xA0; RO)
This field equals 0x10 indicating the linked list item as being the PCIe Capabilities registers.
9.4.6.2 Next Pointer (0xA1; RO)
Offset to the next capability item in the capability list. Its value of 0xE0 points to the VPD structure. If
VPD is disabled, or operating in mode, a value of 0x00 value indicates that it is the last item in the
capability-linked list.
Bits Default R/W Description
31:0 X RW
VPD Data
VPD data can be read or written through this register. The LSB of this register (at offset four in
this capability structure) corresponds to the byte of VPD at the address specified by the VPD
Address register. The data read from or written to this register uses the normal PCI byte
transfer capabilities. Four bytes are always transferred between this register and the VPD
storage component. Reading or writing data outside of the VPD space in the storage
component is not allowed.
In a write access, the data should be set before the address and the flag is set.
Byte Offset Byte 3 Byte 2 Byte 1 Byte 0
0xA0 PCI Express Capability Register (0x0002) Next Pointer (0xE0/
0x00) Capability ID (0x10)
0xA4 Device Capability
0xA8 Device Status Device Control
0xAC Link Capabilities
0xB0 Link Status Link Control
0xB4 Reserved
0xB8 Reserved Reserved
0xBC Reserved
0xC0 Reserved Reserved
0xC4 Device Capabilities 2
0xC8 Reserved Device Control 2
0xCC Reserved
0xD0 Link Status 2 Link Control 2
0xD4 Reserved
0xD8 Reserved Reserved
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9.4.6.3 PCIe CAP (0xA2; RO)
The PCIe capabilities register identifies the PCIe device type and associated capabilities. This is a read
only register.
9.4.6.4 Device Capabilities (0xA4; RO)
This register identifies the PCIe device specific capabilities. It is a read only register.
Bits Default R/W Description
3:0 0010b RO
Capability Version
Indicates the PCIe capability structure version number. The I210 supports both version
1 and version 2 as loaded from the PCIe Capability Version bit in the Flash.
7:4 0000b RO Device/Port Type
Indicates the type of PCIe function. a native PCI function with a value of 0000b.
8 0b RO Slot Implemented
The I210 does not implement slot options therefore this field is hardwired to 0b.
13:9 00000b RO
Interrupt Message Number
The I210 does not implement multiple MSI interrupts, therefore this field is hardwired
to 0x0.
15:14 00b RO Reserved
Bits R/W Default Description
2:0 RO 010b
Max Payload Size Supported
This field indicates the maximum payload that the I210 can support for TLPs. It is loaded from
the Flash’s PCIe Init Configuration 3 word, 0x1A (with a default value of 512 bytes. See
Section 6.2.16).
4:3 RO 00b Phantom Function Supported
Not supported by the I210.
5 RO 0b Extended Tag Field Supported
Max supported size of the Tag field. The I210 supported 5-bit Tag field.
8:6 RO 011b
Endpoint L0s Acceptable Latency
This field indicates the acceptable latency that the I210 can withstand due to the transition
from the L0s state to the L0 state. value loaded from the Flash PCIe Init Configuration 1 word,
0x18 (See Section 6.2.14).
11:9 RO 110b
Endpoint L1 Acceptable Latency
This field indicates the acceptable latency that the I210 can withstand due to the transition
from the L1 state to the L0 state. value loaded from the Flash PCIe L1 Exit latencies word,
0x14 (See Section 6.2.11).
12 RO 0b Attention Button Present
Hardwired in the I210 to 0b.
13 RO 0b Attention Indicator Present
Hardwired in the I210 to 0b.
14 RO 0b Power Indicator Present
Hardwired in the I210 to 0b.
15 RO 1b
Role-Based Error Reporting
This bit, when set, indicates that the I210 implements the functionality originally defined in the
Error Reporting ECN for PCIe Base Specification 1.0a and later incorporated into PCIe Base
Specification 1.1. Set to 1b in the I210.
17:16 RO 000b Reserved
25:18 RO 0x00
Slot Power Limit Value
Hardwired in the I210 to 0x00, as the I210 consumes less than the 25 W allowed for its form
factor.
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9.4.6.5 Device Control (0xA8; RW)
This register controls the PCIe specific parameters.
27:26 RO 00b
Slot Power Limit Scale
Hardwired in the I210 to 0b, as the I210 consumes less than the 25 W allowed for its form
factor.
28 RO 1b1Function Level Reset (FLR) Capability
A value of 1b indicates the function supports the optional FLR mechanism.
31:29 RO 000b Reserved
1. Loaded from Flash.
Bits R/W Default Description
0 RW 0b Correctable Error Reporting Enable
Enable report of correctable errors.
1 RW 0b Non-Fatal Error Reporting Enable
Enable report of non fatal errors.
2 RW 0b Fatal Error Reporting Enable
Enable report of fatal errors.
3 RW 0b Unsupported Request Reporting Enable
Enable report of unsupported requests error.
4 RW 1b
Enable Relaxed Ordering
If this bit is set, the I210 is permitted to set the Relaxed Ordering bit in the attribute field of
write transactions that do not need strong ordering. For more details, refer to the description
about the RO_DIS bit in the CTRL_EXT register bit in Section 8.2.3.
7:5 RW 000b (128
bytes)
Max Payload Size
This field sets maximum TLP payload size for the I210. As a receiver, the I210 must handle
TLPs as large as the set value. As a transmitter, the I210 must not generate TLPs exceeding the
set value.
The max payload size supported in the I210 Device capabilities register indicates permissible
values that can be programmed.
Note: According to PCIe spec, this field shall not be reset on FLR.
8 R0 0b Extended Tag field Enable
Not implemented in the I210.
9 R0 0b Phantom Functions Enable
Not implemented in the I210.
10 RWS 0b Auxiliary Power PM Enable
When set, enables the I210 to draw AUX power independent of PME AUX power.
Bits R/W Default Description
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9.4.6.6 Device Status (0xAA; R/W1C)
This register provides information about PCIe device’s specific parameters.
11 RW 1b Enable No Snoop
Snoop is gated by NONSNOOP bits in the GCR register in the CSR space.
14:12 RW 010b
Max Read Request Size - this field sets maximum read request size for the Device as a
requester.
000b = 128 bytes
001b = 256 bytes.
010b = 512 bytes (the default value).
011b = 1 KB.
100b = Reserved.
101b = Reserved.
110b = Reserved.
111b = Reserved.
15 RW 0b
Initiate Function Level Reset
A write of 1b initiates an FLR to the function. The value read by software from this bit is always
0b.
Bits R/W Default Description
0 R/W1C 0b Correctable Error Detected
Indicates status of correctable error detection.
1 R/W1C 0b Non-Fatal Error Detected
Indicates status of non-fatal error detection.
2 R/W1C 0b Fatal Error Detected
Indicates status of fatal error detection.
3 R/W1C 0b Unsupported Request Detected
Indicates that the I210 received an unsupported request.
4 RO 0b
Aux Power Detected
If aux power is detected, this field is set to 1b. It is a strapping signal from the periphery.
Reset on LAN_PWR_GOOD and GIO Power Good only.
5 RO 0b Transactions Pending
Indicates whether the I210 has any transaction pending.
15:6 RO 0x00 Reserved
Bits R/W Default Description
Ethernet Controller I210 —PCIe Programming Interface
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9.4.6.7 Link Capabilities Register (0xAC; RO)
This register identifies PCIe link specific capabilities. This is a read only register
Bits Rd/Wr Default Description
3:0 RO 0010b
Max Link Speed
This field indicates the supported Link speed(s) of the associated link port. Defined
encodings are:
0001b = 2.5 Gb/s Link speed supported.
0010b = Not supported (5 Gb/s and 2.5 Gb/s Link speeds)
9:4 RO 0x01
Max Link Width
Indicates the maximum link width. The I210 can support by 1 link width.
Relevant encoding:
000000b = Reserved.
000001b = x1.
000010b = x2 Not supported.
000100b = x4 Not supported.
11:10 RO 11b
Active State Power Management (ASPM) Support – This field indicates the level of
ASPM supported on the I210 PCI Express Link.
Defined encodings are:
00b = No ASPM Support.
01b = L0s Supported.
10b = L1 Supported.
11b = L0s and L1 Supported.
14:12 RO Usage depended.
See default values in
Section 6.2.14.
L0s Exit Latency
Indicates the exit latency from L0s to L0 state.
000b = Less than 64ns.
001b = 64ns – 128ns.
010b = 128ns – 256ns.
011b = 256ns - 512ns.
100b = 512ns - 1 s.
101b = 1 s – 2 s.
110b = 2 s – 4 s.
111b = Reserved.
Depending on usage of common clock or separate clock the value of this field is
loaded from PCIe Init Config 1 Flash word, 0x18 (See Section 6.2.14).
17:15 RO
Usage depended.
See default values in
Section 6.2.11.
L1 Exit Latency
Indicates the exit latency from L1 to L0 state.
000b = Less than 1 s.
001b = 1 s - 2 s.
010b = 2 s - 4 s.
011b = 4 s - 8 s.
100b = 8 s - 16 s.
101b = 16 s - 32 s.
110b = 32 s - 64 s.
111b = L1 transition not supported.
Depending on usage of common clock or separate clock the value of this field is
loaded from PCIe L1 Exit latencies Flash word, 0x14 (See Section 6.2.11).
18 RO 0b Clock Power Management Status
Not supported in the I210. RO as zero.
19 RO 0b Surprise Down Error Reporting Capable Status
Not supported in the I210. RO as zero
20 RO 0b Data Link Layer Link Active Reporting Capable Status
Not supported in the I210. RO as zero.
PCIe Programming Interface—Ethernet Controller I210
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9.4.6.8 Link Control Register (0xB0; RO)
This register controls PCIe link specific parameters.
21 RO 0b Link Bandwidth Notification Capability Status
Not supported in the I210. RO as zero.
22 RO 1b
ASPM Optionality Compliance
Software is permitted to use the value of this bit to help determine whether to
enable ASPM or whether to run ASPM compliance tests.
23 RO 00b Reserved
31:24 HwInit 0x0 Port Number
The PCIe port number for the given PCIe link. Field is set in the link training phase.
Bits R/W Default Description
1:0 RW 00b
Active State Power Management (ASPM) Control – This field controls the level of Active
State Power Management (ASPM) supported on the I210 PCI Express Link.
Defined encodings are:
00b = PM disabled.
01b = L0s entry supported.
10b = L1 Entry Enabled.
11b = L0s and L1 supported.
Note: “L0s Entry Enabled” enables the Transmitter to enter L0s is supported. If L0s is
supported, the Receiver must be capable of entering L0s even when the
Transmitter is disabled from entering L0s (00b or 10b).
According to PCIe spec, this field shall not be reset on FLR.
2 RO 0b Reserved
3 RW 0b
Read Completion Boundary
Read Completion Boundary (RCB) Optionally Set by configuration software to indicate the
RCB value of the Root Port Upstream from the Endpoint or Bridge.
Defined encodings are:
0b = 64 byte
1b = 128 byte
Configuration software must only Set this bit if the Root Port Upstream from the Endpoint
or Bridge reports an RCB value of 128 bytes (a value of 1b in the Read Completion
Boundary bit).
4 RO 0b Link Disable
Not applicable for endpoint devices; hardwired to 0b.
5 RO 0b Retrain Clock
Not applicable for endpoint devices; hardwired to 0b.
6 RW 0b
Common Clock Configuration
When this bit is set, it indicates that the I210 and the component at the other end of the
link are operating with a common reference clock. A value of 0b indicates that both operate
with an asynchronous clock. This parameter affects the L0s exit latencies.
Note: According to PCIe spec, this field shall not be reset on FLR.
7 RW 0b
Extended Synch
When this bit is set, it forces an extended Tx of a FTS ordered set in FTS and an extra TS1
at exit from L0s prior to enter L0.
Note: According to PCIe spec, this field shall not be reset on FLR.
8 RO 0b Enable Clock Power Management
Not supported in the I210. RO as zero.
9 RO 0b Hardware Autonomous Width Disable
Not supported in the I210. RO as zero.
Bits Rd/Wr Default Description
Ethernet Controller I210 —PCIe Programming Interface
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9.4.6.9 Link Status (0xB2; RO)
This register provides information about PCIe link specific parameters. This is a read only register.
9.4.6.10 Reserved (0xB4-0xC0; RO)
Unimplemented reserved registers not relevant to PCIe endpoint.
The following registers are supported only if the capability version is two and above.
9.4.6.11 Device Capabilities 2 (0xC4; RO)
This register identifies PCIe device specific capabilities.
10 RO 0b Link Bandwidth Management Interrupt Enable
Not supported in the I210. RO as zero.
11 RO 0b Link Autonomous Bandwidth Interrupt Enable
Not supported in the I210. RO as zero.
15:12 RO 0000b Reserved
Bits R/W Default Description
3:0 RO 0001b
Link Speed
This field indicates the negotiated link speed of the given PCIe link.
Defined encodings are:
0001b = 2.5 Gb/s PCIe link.
0010b = Not supported (5 Gb/s PCIe link).
All other encodings are reserved.
9:4 RO 000001b
Negotiated Link Width
Indicates the negotiated width of the link.
Relevant encoding for the I210 are:
000001b = x1
000010b = Not supported (x2)
000100b = Not supported (x4)
10 RO 0b Reserved (was: Link Training Error)
11 RO 0b Link Training
Indicates that link training is in progress.
12 HwInit 1b
Slot Clock Configuration
When set, indicates that the I210 uses the physical reference clock that the platform provides
on the connector. This bit must be cleared if the I210 uses an independent clock. The Slot
Clock Configuration bit is loaded from the Slot_Clock_Cfg bit in PCIe Init Configuration 3 Word
(Word 0x1A) Flash word.
13 RO 0b Data Link Layer Link Active
Not supported in the I210. RO as zero.
14 RO 0b Link Bandwidth Management Status
Not supported in the I210. RO as zero.
15 RO 0b Reserved
Bits R/W Default Description
PCIe Programming Interface—Ethernet Controller I210
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9.4.6.12 Device Control 2 (0xC8; RW)
This register controls PCIe specific parameters.
Bit
Location R/W Default Description
3:0 RO 1111b
Completion Timeout Ranges Supported
This field indicates the I210 support for the optional completion timeout programmability
mechanism. This mechanism enables system software to modify the completion timeout value.
Description of the mechanism can be found in Section 3.1.3.2.
Four time value ranges are defined:
Range A = 50 s to 10 ms
Range B = 10 ms to 250 ms
Range C = 250 ms to 4 s
Range D = 4 s to 64 s
A value of 1111b indicates the I210 supports ranges A, B, C, & D.
4 RO 1b
Completion Timeout Disable Supported
A value of 1b indicates support for the completion timeout disable mechanism.
5 RO 0b
ARI Forwarding Supported
Applicable only to switch downstream ports and root ports; must be set to 0b for other function
types.
6 RO 0b AtomicOp Routing Supported - not supported in the I210.
7 RO 0b 32-bit AtomicOp Completer Supported – not supported in the I210.
8 RO 0b 64-bit AtomicOp Completer Supported – not supported in the I210.
9 RO 0b 128-bit CAS Completer Supported – not supported in the I210.
10 RO 0b No RO-enabled PR-PR Passing – not supported in the I210.
11 RO 1b1
1. Value loaded from Flash word.
LTR Mechanism Supported –
A value of 1b indicates support for the optional Latency Tolerance Requirement Reporting (LTR)
mechanism capability.
Note: Value loaded from LTR_EN bit in Initialization Control Word 1 Flash word.
13:12 RO 00b TPH Completer supported - the I210 does not use the hints as a completer
17:14 RO 0x0 Reserved
19:18 RO 00b1Reserved
31:20 RO 0x0 Reserved
Ethernet Controller I210 —PCIe Programming Interface
612
Bit
location R/W Default Description
3:0 RW 0000b
Completion Timeout Value1
In devices that support completion timeout programmability, this field enables system software to
modify the completion timeout value.
Encoding:
0000b = Allowable default range: 50 s to 50 ms. It is strongly recommended that the
completion timeout mechanism not expire in less than 10 ms. Actual completion timeout range
supported in the I210 is 16 ms to 32 ms.
Values available if Range A (50 s to 10 ms) programmability range is supported:
0001b = Allowable range is 50 s to 100 s. Actual completion timeout range supported in the
I210 is 50 s to 100 s.
0010b = Allowable range is 1 ms to 10 ms. Actual completion timeout range supported in the
I210 is 1 ms to 2 ms.
Values available if Range B (10 ms to 250 ms) programmability range is supported:
0101b = Allowable range is 16 ms to 55 ms. Actual completion timeout range supported in the
I210 is 16 ms to 32 ms.
0110b = Allowable range is 65 ms to 210 ms. Actual completion timeout range supported in
the I210 is 65 ms to 130 ms.
Values available if Range C (250 ms to 4 s) programmability range is supported:
1001b = Allowable range is 260 ms to 900 ms. Actual completion timeout range supported in
the I210 is 260 ms to 520 ms.
1010b = Allowable range is 1 s to 3.5 s. Actual completion timeout range supported in the I210
is 1 s to 2 s.
Values available if the Range D (4 s to 64 s) programmability range is supported:
1101b = Allowable range is 4 s to 13 s. Actual completion timeout range supported in the I210
is 4 s to 8 s.
1110b = Allowable range is 17 s to 64 s. Actual completion timeout range supported in the
I210 is 17s to 34 s.
Values not defined are reserved.
Software is permitted to change the value in this field at any time. For requests already pending
when the completion timeout value is changed, hardware is permitted to use either the new or the
old value for the outstanding requests and is permitted to base the start time for each request
either when this value was changed or when each request was issued.
The default value for this field is 0000b.
4 RW 0b
Completion Timeout Disable
When set to 1b, this bit disables the completion timeout mechanism.
Software is permitted to set or clear this bit at any time. When set, the completion timeout
detection mechanism is disabled. If there are outstanding requests when the bit is cleared, it is
permitted but not required for hardware to apply the completion timeout mechanism to the
outstanding requests. If this is done, it is permitted to base the start time for each request on
either the time this bit was cleared or the time each request was issued.
The default value for this bit is 0b.
5 RO 0b Alternative RID Interpretation (ARI) Forwarding Enable
Applicable only to switch devices.
6 RO 0b AtomicOp Requester Enable - not supported in the I210.
7 RO 0b AtomicOp Egress Blocking - not supported in the I210.
8 RW 0b IDO Request Enable - If this bit is Set, the Function is permitted to set the ID-Based Ordering (IDO)
bit (Attribute[2]) of Requests it initiates
9 RW 0b IDO Completion Enable - If this bit is Set, the Function is permitted to set the ID-Based Ordering
(IDO) bit (Attribute[2]) of Completion it initiates
10 RW 0b
LTR Mechanism Enable – When Set to 1b, this bit enables the Latency Tolerance Requirement
Reporting (LTR) mechanism.
Notes:
If Value of LTR_EN bit in Initialization Control Word 1 Flash word is 0, then bit is RO with a
value of 0b.
PCIe Programming Interface—Ethernet Controller I210
613
9.4.6.13 Link Control 2 (0xD0; RW)
12:11 RO 0x0 Reserved.
14:13 RW/
RO 00b Reserved.
15 RO 0 Reserved.
1. The completion timeout value must be programmed correctly in PCIe configuration space (in Device Control 2 Register); the value
must be set above the expected maximum latency for completions in the system in which the I210 is installed. This ensures that
the I210 receives the completions for the requests it sends out, avoiding a completion timeout scenario. It is expected that the
system BIOS sets this value appropriately for the system.
Bits R/W Default Description
3:0 RWS 0001b
Target Link Speed.
This field is used to set the target compliance mode speed when software is using the Enter
Compliance bit to force a link into compliance mode.
Defined encodings are:
0001b = 2.5 Gb/s Target Link Speed.
0010b = Not supported (5 Gb/s Target Link Speed).
All other encodings are reserved.
If a value is written to this field that does not correspond to a speed included in the Max
Link Speed field, the result is undefined.
The default value of this field is the highest link speed supported by the I210 (as reported
in the Max Link Speed field of the Link Capabilities register).
4 RWS 0b
Enter Compliance.
Software is permitted to force a link to enter compliance mode at the speed indicated in the
Target Link Speed field by setting this bit to 1b in both components on a link and then
initiating a hot reset on the link.
The default value of this field following a fundamental reset is 0b.
5 RO 0b
Hardware Autonomous Speed Disable.
When set to 1b, this bit disables hardware from changing the link speed for reasons other
than attempting to correct unreliable link operation by reducing link speed.
Bit is Hard wired to 0b.
6 RO 0b Selectable De-emphasis
This bit is not applicable and reserved for Endpoints.
9:7 RWS 000b
Transmit Margin
This field controls the value of the non de emphasized voltage level at the Transmitter pins.
Encodings:
000b = Normal operating range
001b = 800-1200 mV for full swing
010b = (n-1) - Values must be monotonic with a non-zero slope. The value of n must be
greater than 3 and less than 7. At least two of these must be below the normal operating
range of n: 200-400 mV for full-swing
n = 111b reserved.
Note: No support to half-swing (low-swing).
10 RWS 0b
Enter Modified Compliance
When this bit is set to 1b, the device transmits modified compliance pattern if the LTSSM
enters Polling.Compliance state.
Bit
location R/W Default Description
Ethernet Controller I210 —PCIe Programming Interface
614
9.4.6.14 Link Status 2 (0xD2; RW)
9.5 PCIe Extended Configuration Space
PCIe extended configuration space is located in a flat memory-mapped address space. PCIe extends
the configuration space beyond the 256 bytes available for PCI to 4096 bytes. The I210 decodes an
additional 4-bits (bits 27:24) to provide the additional configuration space as shown in Table 9-9. PCIe
reserves the remaining 4 bits (bits 31:28) for future expansion of the configuration space beyond 4096
bytes.
The configuration address for a PCIe device is computed using a PCI-compatible bus, device, and
function numbers as follows.
PCIe extended configuration space is allocated using a linked list of optional or required PCIe extended
capabilities following a format resembling PCI capability structures. The first PCIe extended capability is
located at offset 0x100 in the device configuration space. The first Dword of the capability structure
identifies the capability/version and points to the next capability.
The I210 supports the following PCIe extended capabilities.
11 RWS 0b
Compliance SOS
When set to 1b, the LTSSM is required to send SOS periodically in between the (modified)
compliance patterns.
12 RWS 0b
Compliance De-emphasis
This bit sets the de-emphasis level in Polling.Compliance state if the entry occurred due to
the Enter Compliance bit being 1b.
Encodings:
1b -3.5 dB
0b -6 dB
When the Link is operating at 2.5 GT/s, the setting of this bit has no effect.
15:13 RO 0x0 Reserved
Bits R/W Default Description
0 RO 0b
Current De-emphasis Level – When the Link is operating at 5 GT/s speed, this bit reflects
the level of de-emphasis. it is undefined when the Link is operating at 2.5 GT/s speed
Encodings:
1b -3.5 dB
0b -6 dB
15:1 RO 0x0 Reserved
Table 9-9. PCIe Extended Configuration Space
31 28 27 20 19 15 14 12 11 2 1 0
0000b Bus # Device # Fun # Register Address (offset) 00b
Bits R/W Default Description
PCIe Programming Interface—Ethernet Controller I210
615
9.5.1 Advanced Error Reporting (AER) Capability
The PCIe AER capability is an optional extended capability to support advanced error reporting. The
following table lists the PCIe AER extended capability structure for PCIe devices.
9.5.1.1 PCIe CAP ID (0x100; RO)
9.5.1.2 Uncorrectable Error Status (0x104; R/W1CS)
The Uncorrectable Error Status register reports error status of individual uncorrectable error sources on
a PCIe device. An individual error status bit that is set to 1b indicates that a particular error occurred;
software can clear an error status by writing a 1b to the respective bit.
Table 9-10. PCIe Extended Capability Structure
Capability Offset Next Header1
1. Some of the capabilities might be skipped if disabled via Flash.
Advanced Error Reporting 0x100 0x140
Serial Number 0x140 0x1A0
TLP processing hints 0x1A0 0x1C0
Latency Tolerance Requirement Reporting 0x1C0 0x000
Byte Offset Byte 3 Byte 2 Byte 1 Byte 0
0x100 Next Capability Ptr.
(0x140)1
1. This value might change if the SEID capability is disabled. In this case the next header is the next enabled feature.
Version (0x2) AER Capability ID (0x0001)
0x104 Uncorrectable Error Status
0x108 Uncorrectable Error Mask
0x10C Uncorrectable Error Severity
0x110 Correctable Error Status
0x114 Correctable Error Mask
0x118 Advanced Error Capabilities and Control Register
0x11C... 0x128 Header Log
Bit
Location Attribute Default
Value Description
15:0 RO 0x0001 Extended Capability ID
PCIe extended capability ID indicating AER capability.
19:16 RO 0x21
1. Loaded from Flash (See Section 6.2.19).
AER Capability Version
PCIe AER extended capability version number.
31:20 RO 0x140
Next Capability Pointer
Next PCIe extended capability pointer. A value of 0x140 points to the serial ID capability.
Ethernet Controller I210 —PCIe Programming Interface
616
9.5.1.3 Uncorrectable Error Mask (0x108; RWS)
The Uncorrectable Error Mask register controls reporting of individual uncorrectable errors by device to
the host bridge via a PCIe error message. A masked error (respective bit set in mask register) is not
reported to the host bridge by an individual device. There is a mask bit per bit in the Uncorrectable
Error Status register.
Bit
Location Attribute Default
Value Description
3:0 RO 0x0 Reserved
4 R/W1CS 0b Data Link Protocol Error Status
5 RO 0b Surprise Down Error Status (Optional)
Not supported in the I210.
11:6 RO 0x0 Reserved
12 R/W1CS 0b Poisoned TLP Status
13 R/W1CS 0b Flow Control Protocol Error Status
14 R/W1CS 0b Completion Timeout Status
15 R/W1CS 0b Completer Abort Status
16 R/W1CS 0b Unexpected Completion Status
17 R/W1CS 0b Receiver Overflow Status
18 R/W1CS 0b Malformed TLP Status
19 R/W1CS 0b ECRC Error Status
20 R/W1CS 0b Unsupported Request Error Status
21 RO 0b ACS Violation Status
Not supported in the I210.
22 RO 0b Uncorrectable Internal Error Status (Optional)
Not supported in the I210.
23 RO 0b MC Blocked TLP Status (Optional)
Not supported in the I210.
24 RO 0b AtomicOps Egress Blocked Status (Optional)
Not supported in the I210.
25 RO 0b TLP Prefix Blocked Error Status (Optional)
Not supported in the I210.
31:26 RO 0x0 Reserved
Bit
Location Attribute Default
Value Description
3:0 RO 0x0 Reserved
4 RWS 0b Data Link Protocol Error Mask
5 RO 0b Surprise Down Error Mask (Optional)
Not supported in the I210.
11:6 RO 0x0 Reserved
12 RWS 0b Poisoned TLP Mask
13 RWS 0b Flow Control Protocol Error Mask
14 RWS 0b Completion Timeout Mask
15 RWS 0b Completer Abort Mask
16 RWS 0b Unexpected Completion Mask
PCIe Programming Interface—Ethernet Controller I210
617
9.5.1.4 Uncorrectable Error Severity (0x10C; RWS)
The Uncorrectable Error Severity register controls whether an individual uncorrectable error is reported
as a fatal error. An uncorrectable error is reported as fatal when the corresponding error bit in the
severity register is set. If the bit is cleared, the corresponding error is considered non-fatal.
17 RWS 0b Receiver Overflow Mask
18 RWS 0b Malformed TLP Mask
19 RWS 0b ECRC Error Mask
20 RWS 0b Unsupported Request Error Mask
21 RO 0b ACS Violation Mask
Not supported in the I210.
22 RO 0b Uncorrectable Internal Error Mask (Optional)
Not supported in the I210.
23 RO 0b MC Blocked TLP Mask (Optional)
Not supported in the I210.
24 RO 0b AtomicOps Egress Blocked Mask (Optional)
Not supported in the I210.
25 RO 0b TLP Prefix Blocked Error Mask (Optional)
Not supported in the I210.
31:26 RO 0x0 Reserved
Bit
Location Attribute Default
Value Description
3:0 RO 0001b Reserved
4 RWS 1b Data Link Protocol Error Severity
5 RO 1b Surprise Down Error Severity (Optional)
Not supported in the I210.
11:6 RO 0x0 Reserved
12 RWS 0b Poisoned TLP Severity
13 RWS 1b Flow Control Protocol Error Severity
14 RWS 0b Completion Timeout Severity
15 RWS 0b Completer Abort Severity
16 RWS 0b Unexpected Completion Severity
17 RWS 1b Receiver Overflow Severity
18 RWS 1b Malformed TLP Severity
19 RWS 0b ECRC Error Severity
20 RWS 0b Unsupported Request Error Severity
21 RO 0b ACS Violation Severity
Not supported in the I210.
22 RO 1b Uncorrectable Internal Error Severity (Optional)
Not supported in the I210.
23 RO 0b MC Blocked TLP Severity (Optional)
Not supported in the I210.
Bit
Location Attribute Default
Value Description
Ethernet Controller I210 —PCIe Programming Interface
618
9.5.1.5 Correctable Error Status (0x110; R/W1CS)
The Correctable Error Status register reports error status of individual correctable error sources on a
PCIe device. When an individual error status bit is set to 1b, it indicates that a particular error occurred;
software can clear an error status by writing a 1b to the respective bit.
9.5.1.6 Correctable Error Mask (0x114; RWS)
The Correctable Error Mask register controls reporting of individual correctable errors by device to the
host bridge via a PCIe error message. A masked error (respective bit set in mask register) is not
reported to the host bridge by an individual device. There is a mask bit per bit in the Correctable Error
Status register.
24 RO 0b AtomicOps Egress Blocked Severity (Optional)
Not supported in the I210.
25 RO 0b TLP Prefix Blocked Error Severity (Optional)
Not supported in the I210.
31:26 RO 0x0 Reserved
Bit
Location Attribute Default
Value Description
0 R/W1CS 0b Receiver Error Status
5:1 RO 0x0 Reserved
6 R/W1CS 0b Bad TLP Status
7 R/W1CS 0b Bad DLLP Status
8 R/W1CS 0b REPLAY_NUM Rollover Status
11:9 RO 000 Reserved
12 R/W1CS 0b Replay Timer Timeout Status
13 R/W1CS 0b Advisory Non-Fatal Error Status
14 RO 0b Corrected Internal Error Status (Optional)
Not supported in the I210.
15 RO 0b Header Log Overflow Status (Optional)
Not supported in the I210.
31:16 RO 0x0 Reserved
Bit
Location Attribute Default
Value Description
0 RWS 0b Receiver Error Mask
5:1 RO 0x0 Reserved
6 RWS 0b Bad TLP Mask
7 RWS 0b Bad DLLP Mask
8 RWS 0b REPLAY_NUM Rollover Mask
11:9 RO 000b Reserved
12 RWS 0b Replay Timer Timeout Mask
13 RWS 1b
Advisory Non-Fatal Error Mask.
This bit is Set by default to enable compatibility with software that
does not comprehend Role-Based Error Reporting.
Bit
Location Attribute Default
Value Description
PCIe Programming Interface—Ethernet Controller I210
619
9.5.1.7 Advanced Error Capabilities and Control Register (0x118; RWS)
9.5.1.8 Header Log (0x11C:0x128; RO)
The Header Log register captures the header for the transaction that generated an error. This register
is 16 bytes in length.
14 RO 0b Corrected Internal Error Mask (Optional)
Not supported in the I210.
15 RO 0b Header Log Overflow Mask (Optional)
Not supported in the I210.
31:16 RO 0x0 Reserved
Bit
Location Attribute Default
Value Description
4:0 ROS 0x0
First Error Pointer
The First Error Pointer is a field that identifies the bit position of the first error
reported in the Uncorrectable Error Status register.
5 RO 1b
ECRC Generation Capable
This bit indicates that the I210 is capable of generating ECRC.
This bit is loaded from Flash PCIe Control 2 word (Word 0x28).
6 RWS 0b ECRC Generation Enable
When set, enables ECRC generation.
7 RO 1b
ECRC Check Capable
If Set, this bit indicates that the Function is capable of checking ECRC.
This bit is loaded from Flash PCIe Control 2 word (Word 0x28).
8 RWS 0b ECRC Check Enable
When set, enables ECRC checking.
9 RO 0b Multiple Header Recording Capable – If Set, this bit indicates that the Function is capable of
recording more than one error header.
10 RO 0b This bit enables the Function to record more than one error header.
11 RO 0b
TLP Prefix Log Present
If Set and the First Error Pointer is valid, indicates that the TLP Prefix Log register contains
valid information. If Clear or if First Error Pointer is invalid, the TLP Prefix Log register is
undefined.
Default value of this bit is 0b. This bit is RsvdP if the End-End TLP Prefix Supported bit is Clear.
31:12 RO 0x0 Reserved
Bit
Location Attribute Default
Value Description
127:0 ROS 0b Header of the packet in error (TLP or DLLP).
Bit
Location Attribute Default
Value Description
Ethernet Controller I210 —PCIe Programming Interface
620
9.5.2 Serial Number
The PCIe device serial number capability is an optional extended capability that can be implemented by
any PCIe device. The device serial number is a read-only 64-bit value that is unique for a given PCIe
device.
Note: The I210 does not support this capability in an configuration.
9.5.2.1 Device Serial Number Enhanced Capability Header (0x140; RO)
The following table lists the allocation of register fields in the device serial number enhanced capability
header. It also lists the respective bit definitions. The extended capability ID for the device serial
number capability is 0x0003.
9.5.2.2 Serial Number Register (0x144:0x148; RO)
The Serial Number register is a 64-bit field that contains the IEEE defined 64-bit extended unique
identifier (EUI-64™). Table 9-11 lists the allocation of register fields in the Serial Number register.
Table 9-11 also lists the respective bit definitions.
Byte Offset Byte 3 Byte 2 Byte 1 Byte 0
0x140 Next Capability Ptr.
0x1A01
1. This value might change if the TPH capability is disabled. In this case the next header is the next enabled feature.
Version (0x1) Serial ID Capability ID (0x0003)
0x144 Serial Number Register (Lower Dword)
0x148 Serial Number Register (Upper Dword)
Bit(s)
Location
Default
value Attributes Description
15:0 0x0003 RO
PCIe Extended Capability ID
This field is a PCI-SIG defined ID number that indicates the nature and format of the
extended capability.
The extended capability ID for the device serial number capability is 0x0003.
19:16 0x1 RO
Capability Version
This field is a PCI-SIG defined version number that indicates the version of the current
capability structure.
31:20 0x1A0 RO
Next Capability Offset
This field contains the offset to the next PCIe capability structure or 0x000 if no other items
exist in the linked list of capabilities.
Table 9-11. Serial Number Register
31:0
Serial Number Register (Lower Dword)
Serial Number Register (Upper word)
63:32
PCIe Programming Interface—Ethernet Controller I210
621
Serial number definition in the I210:
Serial number uses the MAC address according to the following definition:
The serial number can be constructed from the 48-bit MAC address in the following form:
The MAC label in this case is 0xFFFF.
For example, assume that the company ID is (Intel) 00-A0-C9 and the extension identifier is 23-45-67.
In this case, the 64-bit serial number is:
The MAC address is the MAC address as loaded from the Flash into the RAL and RAH registers.
The translation from Flash words 0 to 2 to the serial number is as follows:
Serial number ADDR+0 = Flash byte 5
Serial number ADDR+1 = Flash byte 4
Serial number ADDR+2 = Flash byte 3
Serial number ADDR+3 and 4 = 0xFF 0xFF
Serial number ADDR+5 = Flash byte 2
Serial number ADDR+6 = Flash byte 1
Table 9-12. SN Definition
Bit(s)
Location Attributes Description
63:0 RO
PCIe Device Serial Number
This field contains the IEEE defined 64-bit extended unique identifier (EUI-64™). This identifier
includes a 24-bit company ID value assigned by IEEE registration authority and a 40-bit extension
identifier assigned by the manufacturer.
Field Extension identifier Company ID
Order Addr+0 Addr+1 Addr+2 Addr+3 Addr+4 Addr+5 Addr+6 Addr+7
Most significant byte Least significant byte
Most significant bit Least significant bit
Field Extension identifier MAC Label Company ID
Order Addr+0 Addr+1 Addr+2 Addr+3 Addr+4 Addr+5 Addr+6 Addr+7
Most significant bytes Least significant byte
Most significant bit Least significant bit
Field Extension identifier MAC Label Company ID
Order Addr+0 Addr+1 Addr+2 Addr+3 Addr+4 Addr+5 Addr+6 Addr+7
67 45 23 FF FF C9 A0 00
Most significant byte Least significant byte
Most significant bit Least significant bit
Ethernet Controller I210 —PCIe Programming Interface
622
Serial number ADDR +7 = Flash byte 0
The official document defining EUI-64 is: http://standards.ieee.org/regauth/oui/tutorials/EUI64.html
9.5.3 TLP Processing Hint Requester (TPH) Capability
The PCIe TPH Requester capability is an optional extended capability to support TLP Processing Hints.
The following table lists the PCIe TPH extended capability structure for PCIe devices.
9.5.3.1 TPH CAP ID (0x1A0; RO)
Byte Offset Byte 3 Byte 2 Byte 1 Byte 0
0x1A0 Next Capability Ptr.
(0x1C01
1.
Version (0x1) TPH Capability ID (0x17)
0x1A4 TPH Requester Capability Register
0x1A8 TPH Requester Control Register
0x1AC-0x1B8 TPH ST Table
Bit
Location Attribute Default
Value Description
15:0 RO 0x17 Extended Capability ID
PCIe extended capability ID indicating TPH capability.
19:16 RO 0x1 Version Number
PCIe TPH extended capability version number.
31:20 RO 0x1C01
1. Depends on Flash settings of the LTR_EN bit in Initialization Control Word 1 Flash word, that controls enabling of the LTR structures.
Next Capability Pointer
This field contains the offset to the next PCIe capability structure.
If LTR is enabled in Flash then value of this field is 0x1C0 to point to the LTR capability
structure.
PCIe Programming Interface—Ethernet Controller I210
623
9.5.3.2 TPH Requester Capabilities (0x1A4; RO)
9.5.3.3 TPH Requester Control (0x1A8; R/W)
Bit
Location Attribute Default
Value Description
0 RO 1 No ST Mode Supported: When set indicates the Function is capable of generating Requests
without using ST.
1 RO 0 Interrupt Vector Mode Supported: Cleared to indicate that the I210 does not support Interrupt
Vector Mode of operation.
2 RO 1 Device Specific Mode: Set to indicate that the I210 supports Device Specific Mode of operation.
7:3 RO 0 Reserved
8 RO 0 Extended TPH Requester Supported – Cleared to indicate that the function is not capable of
generating requests with Extended TPH TLP Prefix.
10:9 RO 01b
ST Table Location – Value indicates if and where the ST Table is located. Defined Encodings
are:
00b: ST Table is not present.
01b: ST Table is located in the TPH Requester Capability structure.
10b: ST Table is located in the MSI-X Table structure.
11b: Reserved
Default value of 01b indicates that function supports ST table that’s located in the TPH
Requester Capability structure.
15:11 RO 0x0 Reserved
26:16 RO 0x7
ST_Table Size – System software reads this field to determine the ST_Table_Size N, which is
encoded as N-1.
The I210 supports a table with 8 entries.
31:27 RO 0x0 Reserved
Bit
Location Attribute Default
Value Description
2:0 RW 0x0
ST Mode Select – Indicates the ST mode of operation
selected. The ST mode encodings are as defined below
000b – No Table Mode
001b – Interrupt Vector Mode (not supported by the I210)
010b – Device Specific Mode
0thers – reserved for future use
The default value of 000 indicates No Table mode of operation.
7:3 RO 0x0 Reserved
9:8 RW 0x0
TPH Requester Enable:
Defined Encodings are:
00b: The I210 is not permitted to issue transactions with TPH or Extended TPH as Requester
01b: The I210 is permitted to issue transactions with TPH as Requester and is not permitted to
issue transactions with Extended TPH as Requester
10b: Reserved
11b: The I210 is permitted to issue transactions with TPH and Extended TPH as Requester (the
I210 does not issue transactions with Extended TPH).
31:10 RO 0x0 Reserved
Ethernet Controller I210 —PCIe Programming Interface
624
9.5.3.4 TPH Steering Table (0x1AC - 0x1B8; R/W)
9.5.4 Latency Tolerance Requirement Reporting (LTR) Capability
The PCI Express Latency Tolerance Requirement Reporting Capability is an optional Extended Capability
that allows software to provide platform latency information to devices with upstream ports (Endpoints
and Switches). This capability structure is required if the device supports Latency Tolerance
Requirement Reporting (LTR).
The following table lists the PCIe LTR extended capability structure for PCIe devices.
Bit
Location Attribute Default
Value Description
7:0 RW 0x0 Steering Table Lower Entry 2*n (n = 0...3). A value of zero indicates the tag is not valid
15:8 RO 0x0 Steering Table Upper Entry 2*n (n = 0...3) - RO zero in the I210, as extended tags are not
supported.
23:16 RW 0x0 Steering Table Entry 2*n + 1 (n = 0...3) - A value of zero indicates the tag is not valid
31:24 RO 0x0 Steering Table Upper Entry 2*n + 1 (n = 0...3) - RO zero in the I210, as extended tags are not
supported.
Byte Offset Byte 3 Byte 2 Byte 1 Byte 0
0x1C0 Next Capability Ptr.
(0x000) Version (0x1) LTR Capability ID (0x18)
0x1C4 Maximum Non-Snooped Platform Latency
Tolerance Register Maximum Snooped Platform Latency Tolerance
Register
PCIe Programming Interface—Ethernet Controller I210
625
9.5.4.1 LTR CAP ID (0x1C0; RO)
9.5.4.2 LTR Capabilities (0x1C4; RW)
Bit
Location Attribute Default
Value Description
15:0 RO 0x18 LTR Capability ID
PCIe extended capability ID indicating LTR capability.
19:16 RO 0x1 Version Number
PCIe LTR extended capability version number.
31:20 RO 0x000 Next Capability Pointer
Bit
Location Attribute Default
Value Description
9:0 RW 0x0
Maximum Snoop Latency Value
Along with the Max Snoop Latency Scale field, this register specifies the maximum nosnoop
latency that a device is permitted to request. Software
should set this to the platform’s maximum supported latency or less.
Field is also an indicator of the platforms maximum latency, should an endpoint send up LTR
Latency Values with the Requirement bit not set.
12:10 RW 0x0
Max Snoop Latency Scale
This field provides a scale for the value contained within the Maximum Snoop Latency Value
field.
Encoding:
000 – Value times 1ns
001 – Value times 32ns
010 – Value times 1,024ns
011 – Value times 32,768ns
100 – Value times 1,048,576ns
101 – Value times 33,554,432ns
110-111 – Not Permitted
15:13 RO 0x0 Reserved
25:16 RW 0x0
Max No-Snoop Latency Value
Along with the Max No-Snoop Latency Scale field, this register specifies the maximum no-
snoop latency that a device is permitted to request. Software should set this to the platform’s
maximum supported latency or less.
Field is also an indicator of the platforms maximum latency, should an
endpoint send up LTR Latency Values with the Requirement bit not set.
28:26 RW 0x0
Max No-Snoop Latency Scale — This register provides a scale for the value contained within
the Maximum Non-Snoop Latency Value field.
Encoding:
000 – Value times 1 ns
001 – Value times 32 ns
010 – Value times 1,024 ns
011 – Value times 32,768 ns
100 – Value times 1,048,576 ns
101 – Value times 33,554,432 ns
110-111 – Not Permitted
31:29 RO 0x0 Reserved.
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10.0 System Manageability
Network management is an important requirement in today's networked computer environment.
Software-based management applications provide the ability to administer systems while the operating
system is functioning in a normal power state (not in a pre-boot state or powered-down state). The
Intel® Out of Band Management fill the management void that exists when the operating system is not
running or fully functional. This is accomplished by providing mechanisms by which manageability
network traffic can be routed to and from a Management Controller (MC).
This chapter describes the supported management interfaces and hardware configurations for platform
system management. It describes the interfaces to an external MC, the partitioning of platform
manageability among system components, and the functionality provided by in each platform
configuration.
10.1 Pass-Through (PT) Functionality
Pass-Through (PT) is the term used when referring to the process of sending and receiving Ethernet
traffic over the sideband interface. The I210 has the ability to route Ethernet traffic to the host
operating system as well as the ability to send Ethernet traffic over the sideband interface to an
external MC. See Figure 10-1.
Figure 10-1. Sideband Interface
MC NIC
Host
Host
Interface
Sideband
Interface Port 3
Port 0
LAN
Interface
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The sideband interface provides a mechanism by which the I210 can be shared between the host and
the MC. By providing this sideband interface, the MC can communicate with the LAN without requiring a
dedicated Ethernet controller. The I210 supports two sideband interfaces:
SMBus
NC-SI
PCIe (together with MCTP) - when the system is up.
The usable bandwidth for either direction is up to 1 Mb/s when using SMBus and 100 Mb/s for the NC-
SI interface. When working over PCIe, the bandwidth is limited by the PCIe bandwidth and the I210
processing capabilities. The I210 should support MCTP over PCIe pass-through traffic at a rate of up to
250 Mb/s. Only one mode of sideband can be active at any given time. The configuration is done using
a Flash setting.
Note: In MCTP mode, the PCIe and SMBus interface can receive MCTP commands in parallel.
However, only one of the interfaces can receive NC-SI commands or pass through traffic.
10.1.1 Supported Topologies
The I210 support the following topologies:
Connection via legacy SMBus (See Section 10.5).
Connection via NC-SI (See Section 10.6)
Connection via NC-SI over MCTP for pass through. This connection can be over SMBus, PCI Express
or both. (See Section 10.7).
Connection via NC-SI over MCTP for control only. This connection can be over SMBus, PCI Express
or both. (See Section 10.7). This connection is not available when device is in D3cold state or when
main power is not available (Dr state).
The topology used is defined in the Redirection Sideband Interface field in the Common Manageability
Parameters Flash word.
10.1.2 Pass Through Packet Routing
When an Ethernet packet reaches the I210, it is examined and compared to a number of configurable
filters. These filters are configurable by the MC and include, but not limited to, filtering on:
MAC Address
IP Address
UDP/IP Ports
VLAN Tags
EtherType
If the incoming packet matches any of the configured filters, it is passed to the MC. Otherwise it is not
passed.
The packet filtering process is described in Section 10.3.
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10.2 Components of the Sideband Interface
There are two components to a sideband interface:
Physical Layer
Logical Layer
The MC and the I210 must be in alignment for both components. An example issue: the NC-SI physical
interface is based on the NC-SI interface, but there are differences between the devices at the physical
level and the protocol layer is completely different.
10.2.1 Physical Layer
This is the electrical connection between the I210 and MC.
10.2.1.1 SMBus
The SMBus physical layer is defined by the SMBus specification. The interface is made up of two
connections: Data and Clock. There is also an optional third connection: the Alert line. This line is used
by the I210 to notify the MC that there is data available for reading. Refer to the SMBus specification for
details.
The SMBus can run at three speeds: 100 KHz (standard SMBus), 400 KHz (I2C fast mode) or 1 MHz
(I2C fast mode plus). The speed used is selected by the SMBus Connection Speed in SMBus Notification
Timeout and Flags Flash word.
10.2.1.1.1 PEC Support
SMBus transactions can be protected by using Packet Error Code (PEC). Packet Error Checking,
whenever applicable, is implemented by appending a PEC byte at the end of each message transfer.
The PEC byte is a CRC8 calculation on all the message bytes.
PEC is added in transmit and expected in receive for the following SMBus packets:
ARP packets
MCTP over SMBus transactions.
For ARA cycles and legacy SMBus transactions, a PEC is not expected.
The following table describes the behavior of the device in each PEC configured mode for transactions
directly handled by the hardware upon reception of packets with or without PEC.
Table 10-1. SMBus PEC Modes1
Target PEC Mode
SMBus transaction
(relative to the I210) I210 PEC Mode PEC Enabled PEC Disabled
Master Write2Enabled (A) Target will ack the PEC
byte (A) Target will nack the PEC
byte
Master Write2Disabled (A) Target will receive stop
before expected PEC byte (A) PEC byte is not expected
Slave Write3Enabled (A) Target will ack last data
byte; PEC byte will be nacked
(A) Target will nack last data
byte; No PEC byte will be
written by Slave
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Note: In both SMBus ARP and MCTP, the spec indicates that PEC must be used. However, if PEC is
not used by the master, the transaction is still accepted and processed by the device.
The PEC behavior is controlled by the SMBus transaction PEC bit in the SMBus Notification Timeout and
Flags Flash word: If this bit is set, PEC is added for master SMBus write transactions. a PEC is added to
slave read transactions and can be received in slave write transaction. If this bit is cleared, PEC is not
added to master write or slave read transactions, a slave write transaction with PEC is dropped. This bit
should be set for MCTP mode and should be cleared in legacy SMBus mode.
10.2.1.2 NC-SI
The I210 uses the DMTF standard Sideband Interface. This interface consists of 6 lines for transmission
and reception of Ethernet packets and two optional lines for arbitration among more than one physical
network controller.
The physical layer of NC-SI is very similar to the RMII interface, although not an exact duplicate. Refer
to the NC-SI specification for details of the differences.
10.2.1.3 PCIe
The I210 uses the VDMs (Vendor Defined Messages) over PCIe defined in the DMTF MCTP spec to
convey pass through traffic or NC-SI control traffic. See Section 3.1 for details of the PCIe interface.
The maximal bandwidth supported for MCTP VDMs over PCIe is 250 Mbps. VDMs that will be received at
a faster rate may be dropped. In any case, there will be no back pressure of the PCIe interface due to
MCTP VDM handling.
Slave Write3Disabled (A) Target will ack last data
byte; PEC byte will be 0xFF
(A) Target will nack last data
byte and will generate Stop
after that
Slave Read4Enabled (A) Target will send PEC byte;
PEC byte will be acked by
Slave
(A) Target will not send PEC
byte and will generate Stop
after that
Slave Read4Disabled (R) Target will send PEC byte;
PEC byte will be nacked by
Slave
(A) Target will not send PEC
byte and will generate Stop
after that
1. (A) - Accept Transaction (R) - Reject Transaction.
2. Used in Legacy SMBus writes commands (Direct receive) and in MCTP over SMBus (Transmitted transactions.
3. Used in Legacy SMBus Read commands.
4. Used in Legacy SMBus mode (Alert/Async-Notify) and in MCTP over SMBus (Received transactions).
Table 10-1. SMBus PEC Modes1
Target PEC Mode
SMBus transaction
(relative to the I210) I210 PEC Mode PEC Enabled PEC Disabled
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10.2.2 Logical Layer
10.2.2.1 Legacy SMBus
The protocol layer for SMBus consists of commands the MC issues to configure filtering for the I210
management traffic and the reading and writing of Ethernet frames over the SMBus interface. There is
no industry standard protocol for sideband traffic over SMBus. The protocol layer for SMBus on the I210
is Intel proprietary. The Legacy SMBus protocol is described in Section 10.5.
10.2.2.2 NC-SI
The DMTF also defines the protocol layer for the NC-SI interface. NC-SI compliant devices are required
to implement a minimum set of commands. The specification also provides a mechanism for vendors to
add additional capabilities through the use of OEM commands. Intel OEM NC-SI commands for the I210
are discussed in this document. For information on base NC-SI commands, see the NC-SI specification.
NC-SI traffic can run on top of three different Physical layers:
1. NC-SI Physical layer as described in Section 10.2.1.2.
2. MCTP over PCIe.This protocol allows control and pass through traffic over PCIe of a NIC or a LOM
device. The NC-SI over MCTP protocol is slightly different than the standard NC-SI as it includes
additional NC-SI commands. This mode is usually paired with an MCTP over SMBus, where this
mode is used in S0 states and the SMBus interface is used in Sx state.The MCTP protocol and the
differences from standard NC-SI is described in Section 10.7.
3. MCTP over SMBus. As described above, this layer is paired with the MCTP over PCIe to support Sx
modes.
The package ID can be set either from the Flash Package ID field in the NC-SI Configuration - Offset
0x06 Flash word (Section 6.7.3.7) or from SDP0/2 pins. In this case, the Package ID is
{0,SDP2,SDP0}. The mode used is set by the Read NCSI Package ID from SDP field in the NC-SI
Configuration - Offset 0x07 Flash word (Section 6.7.3.8). Note that when the package ID is set from
the SDP pins, the used SDPs should be set as input in the relevant Software Defined Pins Control Flash
words.
The I210 supports a single channel, so the internal channel ID is always zero.
10.3 Packet Filtering
Since both the host operating system and MC use the I210 to send and receive Ethernet traffic, there
needs to be a mechanism by which incoming Ethernet packets can be identified as those that should be
sent to the MC rather than the host operating system.
There are two different types of filtering available. The first is filtering based upon the MAC address.
With this filtering, the MC has at least one dedicated MAC address and incoming Ethernet traffic with
the matching MAC address(es) are passed to the MC. This is the simplest filtering mechanism to utilize
and it allows an MC to receive all types traffic (including, but not limited to, IPMI, NFS, HTTP etc).
The other mechanism available utilizes a highly configurable mechanism by which packets can be
filtered using a wide range of parameters. Using this method, an MC can share a MAC address (and IP
address, if desired) with the host OS and receive only specific Ethernet traffic. This method is useful if
the MC is only interested in specific traffic, such as IPMI packets.
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10.3.1 Manageability Receive Filtering
This section describes the manageability receive packet filtering flow. Packet reception by the I210 can
generate one of the following results:
Discarded
Sent to Host memory
Sent to the external MC
Sent to both the MC and Host memory
The decisions regarding forwarding of packets to the Host and to the MC are separate and are
configured through two sets of registers. However, the MC may define some types of traffic as
exclusive. This traffic will be forwarded only to the MC, even if it passes the filtering process of the Host.
These types of traffic are defined using the MNGONLY register.
An example of packets that might be necessary to send exclusively to the MC might be specific TCP/
UDP ports of a shared MAC address or a MAC address dedicated to the MC. If the MC configures the
manageability filters to send these ports to the MC, it should configure the settings to not send them to
the Host, otherwise, these ports will be received and handled by the Host operating system.
The MC controls the types of packets that it receives by programming receive manageability filters. The
following filters are accessible to the MC:
All filtering capabilities are available on both the NC-SI and legacy SMBus interfaces. However, in NC-SI
mode, in order to program part of the capabilities, the Intel OEM commands described in
Section 10.6.2.4 should be used.
All filters are reset only on Internal Power On Reset. Register filters that enable filters or functionality
are also reset by firmware reset in NC-SI mode. These registers can be loaded from the Flash following
a reset in SMBus mode. See Section 6.0 for a description of the location in the Flash map.
The high-level structure of manageability filtering is done using two steps.
1. The packet is parsed and fields in the header are compared to programmed filters.
2. A set of decision filters are applied to the result of the first step.
Table 10-2. Filters Accessible to MC
Filters Functionality When Reset?
Filters Enable General configuration of the
manageability filters LAN_PWR_GOOD
Manageability Only Enables routing of packets exclusively to
the manageability. LAN_PWR_GOOD
Manageability Decision Filters [7:0] Configuration of manageability decision
filters LAN_PWR_GOOD
MAC Address [3:0] Four exact MAC manageability addresses LAN_PWR_GOOD
VLAN Filters [7:0] Eight VLAN tag values LAN_PWR_GOOD
UDP/TCP Port Filters [15:0] 16 destination port values LAN_PWR_GOOD
Flexible 128 bytes TCO Filters Length and values for one flex TCO filter LAN_PWR_GOOD
IPv4 and IPv6 Address Filters [3:0] IP address for manageability filtering LAN_PWR_GOOD
Special Filters Modifiers Updates the behavior of some of the
other filters LAN_PWR_GOOD
Ethertype Filters 4 Ethertype filters LAN_PWR_GOOD
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Some general rules apply:
Fragmented packets are passed to manageability but not parsed beyond the IP header.
Packets with L2 errors (CRC, alignment, etc.) are not forwarded to the MC.
Packets longer than 2KB are filtered out.
The following sections describe the manageability filtering, followed by the final filtering rules.
The filtering rules are created by programming the decision filters as described in Section 10.3.4.
10.3.2 L2 Filters
10.3.2.1 MAC and VLAN Filters
The manageability MAC filters allow comparison of the Destination MAC address to one of 4 filters
defined in the MMAH and MMAL registers.
The VLAN filters allow comparison of the 12 bit VLAN tag to one of 8 filters defined in the MAVTV
registers.
10.3.2.2 EtherType Filters
Manageability L2 EtherType filters allow filtering of received packets based on the Layer 2 EtherType
field. The L2 type field of incoming packets is compared against the EtherType filters programmed in
the Manageability EtherType Filter (METF; up to 4 filters); the result is incorporated into decision filters.
Each Manageability EtherType filter can be configured as pass (positive) or reject (negative) using a
polarity bit. In order for the reverse polarity mode to be effective and block certain type of packets, the
EtherType filter should be part of all the enabled decision filters.
An example for usage of L2 EtherType filters is to determine the destination of 802.1X control packets.
The 802.1X protocol is executed at different times in either the management controller or by the Host.
L2 EtherType filters are used to route these packets to the proper agent.
In addition to the flexible EtherType filters, the I210 supports 2 fixed EtherType filters used to block NC-
SI control traffic (0x88F8) and flow control traffic (0x8808) from reaching the manageability interface.
The NC-SI EtherType is used for communication between the management controller on the NC-SI link
and the I210. Packets coming from the network are not expected to carry this EtherType and such
packets are blocked to prevent attacks on the management controller. Flow control packets should be
consumed by the MAC and as such are not expected to be forwarded to the management interface.
Note: In order to get meaningful filtering of Ethertype packets, negative filters should be in the AND
section. If more than one positive Ethertype filter is needed, then they should be set in the
OR section. A single positive Ethertype filter may be enabled both in the AND or in OR
section.
10.3.3 L3/L4 Filtering
The manageability filtering stage combines checks done at previous stages with additional L3/L4 checks
to make a the decision on whether to route a packet to the MC. The following sections describe the
manageability filtering done at layers L3/L4 and final filtering rules.
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10.3.3.1 ARP Filtering
ARP filtering — The I210 supports filtering of ARP request packets (initiated externally) and ARP
responses (to requests initiated by the MC).
In legacy SMBus mode, the ARP filters can be used as part of the ARP offload described in
Section 10.5.3. ARP offload is not specifically available when using NC-SI. However, the general filtering
mechanism is utilized to filter incoming ARP traffic as requested using the Enable Broadcast Filtering
NC-SI command.
The ARP request or response filters can be bind to specific IP address, by setting both the ARP Request/
Response and the IP AND bits in an MDEF filter, as the IP bit will be set also if there is a match on the
target IP (the TPA field in the ARP packet) of an ARP request or ARP response.
Note: If the OR section of the MDEF is all cleared and one of the IPv4 address are set, then ARP
packets matching the IP address will pass the filter. If these packets should be dropped, then
an OR Ethertype filter with a a value of 0x0800 (IPv4) should be added.
10.3.3.2 Neighbor Discovery Filtering and MLD
The I210 supports filtering of the following ICMPv6 packets.
Neighbor Discovery packets:
1. 0x86 (134d) - Router Advertisement.
2. 0x87 (135d) - Neighbor Solicitation.
3. 0x88 (136d) - Neighbor Advertisement.
4. 0x89 (137d) - Redirect.
MLD packets:
1. 0x82 (130d) - MLD Query
2. 0x83 (131d) - MLDv1 Report
3. 0x84 (132d) - MLD Done
4. 0x8F (143d) - MLDv2 Report
The Neighbor discovery packets has dedicated enables for each type in the decision filters. For MLD, a
single enable controls the forwarding of all the MLD packets. This means that either all the MLD packets
types are selected for reception or none of them.
10.3.3.3 RMCP Filtering
The I210 supports filtering by fixed destination port numbers, port 0x26F and port 0x298. These ports
are IANA reserved for RMCP.
UDP or TCP protocols can be included in the comparison using the MSFM.PORT_26F/298_UDP/TCP
fields.
In SMBus mode, there are filters that can be enabled for these ports. When using NC-SI, they are not
specifically available. However, the general filtering mechanism can be utilized to filter incoming ARP
traffic.
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10.3.3.4 ICMP Filtering
The I210 supports filtering by ICMP. This filter matches if the IP protocol field equals to 1.
10.3.3.5 Flexible Port Filtering
The I210 implements 16 flex destination port filters. The I210 directs packets whose L4 destination port
matches to the MC. The MC must ensure that only valid entries are enabled in the decision filters.
For each flex port filter, filtering can be enabled for UDP, TCP or both. It can be enabled either on source
or destination port.
10.3.3.6 Flexible 128 Byte Filter
The I210 provides one flex TCO filter. This filter looks for a pattern match within the first 128 bytes of
the packet. The MC must ensure that only valid entries are enabled in decision filters.
Flex filters are temporarily disabled when read from or written to by the Host. Any packet received
during a read or write operation is dropped. Filter operation resumes once the read or write access
completes.
10.3.3.6.1 Flexible Filter Structure
The filter is composed of the following fields:
1. Flexible Filter length — This field indicates the number of bytes in the packet header that should be
inspected. The field also indicates the minimal length of packets inspected by the filter. Packet
below that length will not be inspected. Valid values for this field are: 8*n, where n=1…16.
2. Data This is a set of up to 128 bytes comprised of values that header bytes of packets are tested
against.
3. Mask — This is a set of 128 bits corresponding to the 128 data bytes that indicate for each
corresponding byte if is tested against its corresponding byte. The general filter is 128 bytes that
the MC configures; all of these bytes may not be needed or used for the filtering, so the mask is
used to indicate which of the 128 bytes are used for the filter.
Each filter tests the first 128 bytes (or less) of a packet, where not all bytes must necessarily be tested.
10.3.3.6.2 TCO Filter Programming
Programming each filter is done using the following commands (NC-SI or SMBus) in a sequential
manner:
1. Filter Mask and Length — This command configures the following fields:
a. Mask A set of 16 bytes containing the 128 bits of the mask. Bit 0 of the first byte corresponds
to the first byte on the wire.
b. Length — A 1-byte field indicating the length.
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2. Filter Data — The filter data is divided into groups of bytes, described below:
Each group of bytes need to be configured using a separate command, where the group number is
given as a parameter. The command has the following parameters:
a. Group number — A 1-byte field indicating the current group addressed
b. Data bytes — Up to 30 bytes of test-bytes for the current group
10.3.3.7 IP Address Filtering
The I210 supports filtering by destination IP address using IPv4 and IPv6 address filters. These are
dedicated to manageability. Two modes are possible, depending on the value of the MANC.
EN_IPv4_FILTER bit:
EN_IPv4_FILTER = 0b: the I210 provides four IPv6 address filters.
EN_IPv4_FILTER = 1b: the I210 provides three IPv6 address filters and four IPv4 address filters.
For each IPv6 filter, the matching MSFM.IPV6_n_MASK bit defines if all the IP address should be
compared to the MIPAF register or only the 24 LSBits of the address should be compared to the 24
LSBits of the MIPAF register.
The IPv4 match will rise also for ARP packets for which the Target IP matches the IP address in the
MIPAF register.
10.3.3.8 Checksum Filtering
If bit MANC.EN_XSUM_FILTER is set, the I210 directs packets to the MC only if they pass L3/L4
checksum (if they exist) in addition to matching other filters previously described.
Enabling the XSUM filter when using the SMBus interface is accomplished by setting the Enable XSUM
Filtering to Manageability bit within the Manageability Control (MANC) register. This is done using the
Update Management Receive Filter Parameters command. See Section 10.5.9.1.6.
To enable the XSUM filtering when using NC-SI, use the Enable Checksum Offloading command. See
Section 10.6.3.13.
10.3.4 Configuring Manageability Filters
There are a number of pre-defined filters that are available for the MC to enable, such as ARPs and IPMI
ports 298h 26Fh. These are generally enabled by setting the appropriate bit within the MANC register
using specific commands.
For more advanced filtering needs, the MC has the ability to configure a number of configurable filters.
It is a two-step process to use these filters. They must first be configured and then enabled.
Group Test Bytes
0x0 0-29
0x1 30-59
0x2 60-89
0x3 90-119
0x4 120-127
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10.3.4.1 Manageability Decision Filters
Manageability decision filters are a set of eight filters, each with the same structure. The filtering rule
for each decision filter is programmed by the MC and defines which of the L2, VLAN, EtherType and L3/
L4 filters participate in decision making. Any packet that passes at least one rule is directed to
manageability and possibly to the Host.
With the I210, packets can also be filtered by EtherType. This is part of the Extended Manageability
Decision Filters (MDEF_EXT).
The inputs to each decision filter are:
Packet passed a valid management L2 exact address filter.
Packet is a broadcast packet.
Packet has a VLAN header and it passed a valid manageability VLAN filter.
Packet matched one of the valid IPv4 or IPv6 manageability address filters.
Packet is a multicast packet.
Packet passed ARP filtering (request or response).
Packet passed neighbor solicitation filtering.
Packet passed MLD filtering
Packet passed 0x298/0x26F port filter.
Packet passed a valid flex port filter.
Packet passed a valid flex TCO filter.
Packet is an ICMP packet.
Packet passed or failed an L2 EtherType filter.
Packet passed or failed Flow Control or NC-SI L2 EtherType Discard filter.
The structure of each decision filter is shown in Figure 10-1. A boxed number indicates that the input is
conditioned by a mask bit defined in the MDEF register and MDEF_EXT register for this rule. Decision
filter rules are as follows:
At least one bit must be set in a register. If all bits are cleared (MDEF/MDEF_EXT = 0x0000), then
the decision filter is disabled and ignored.
All enabled AND filters must match for the decision filter to match. An AND filter not enabled in the
MDEF/MDEF_EXT registers is ignored.
If no OR filter is enabled in the register, the OR filters are ignored in the decision (the filter might
still match).
If one or more OR filters are enabled in the register, then at least one of the enabled OR filters must
match for the decision filter to match.
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Figure 10-1. Manageability Decision Filters
L2 unicast address 3
0.4Broadcast
VLAN 0
IPv4 address 0
L2 unicast address 3 0.24
0.25
Broadcast
0.26Multicast
0.28
ARP Request
0.30Port 0x298
0.31Port 0x26F
1.8
Flex Port 0
1.23
Flex Port 15
1.24Flex TCO
0.29,
1.25- 1.27
Neighbor Discovery
(134/135/136/137)
0.27
ARP Response
L2 EtherType 3
L2 EtherType 0
1.3
1.7
L2 EtherType 0
L2 EtherType 3
L2 unicast address 0 0.21
IPv4 address 3
IPv6 address 0
IPv6 address 3
VLAN 7
L2 unicast address 0
0.12
0.5
0.16
0.13
0.20
0.17
1.3
1.0
0.0
0.3
MANC[1]
NC-SI L2 EtherType
MANC[0]
Flow Control L2 EtherType
ICMP 1.28
MLD 1.29
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A decision filter (for any of the 8 filters) defines which of the above inputs is enabled as part of a
filtering rule. The MC programs two 32-bit registers per rule (MDEF[7:0] & MDEF_EXT[7:0]) with the
settings as described in Section 8.22.7 and Section 8.22.8. A set bit enables its corresponding filter to
participate in the filtering decision.
10.3.4.2 Exclusive Traffic
The decisions regarding forwarding of packets to the Host for LAN traffic or to the LAN for Host traffic
are independent from the management decision filters. However, the MC may define some types of
traffic as exclusive. The behavior for such traffic is defined by the using the bits corresponding to the
decision filter in the MNGONLY register (one bit per each of the eight decision rules) and the
MDEF_EXT.apply_to_host_traffic and MDEF_EXT.apply_to_network_traffic bits. Table 10-4 describes
the behavior in each case. If one or more filters match the traffic and at least one of the filters is set as
exclusive, the traffic is treated as exclusive.
Any traffic matching any of the configurable filters (see Section 10.3.4.1) can be used as filters to pass
traffic to the Host.
When using the SMBus interface, the MC enables these filters by issuing the Update Management
Receive Filter Parameters command (see Section 10.5.9.1.6) with the parameter of 0x0F.
Table 10-4. Exclusive Traffic Behavior
Filter Match Filter Doesn’t Match
Traffic Source MNGONLY = 0b MNGONLY = 1b N/A
From network
Traffic is forwarded to the
manageability.
Traffic is forwarded to the Host
according to Host filtering
Traffic is forwarded only to
manageability.
Traffic is forwarded to
the Host according to
Host filtering
From Host Traffic is forwarded to the
manageability and to the LAN Traffic is forwarded only to
manageability. Traffic is forwarded to
the LAN
Table 10-5. MNGONLY Register Description and Usage
Bits Description Default
0 Decision Filter 0 Determines if packets that have passed decision filter 0 are sent exclusively to the manageability path.
1 Decision Filter 1 Determines if packets that have passed decision filter 1are sent exclusively to the manageability path.
2 Decision Filter 2 Determines if packets that have passed decision filter 2 are sent exclusively to the manageability path
3 Decision Filter 3 Determines if packets that have passed decision filter 3 are sent exclusively to the manageability path
4 Decision Filter 4 Determines if packets that have passed decision filter 4 are sent exclusively to the manageability path
5 Unicast and Mixed
NC-SI mode: Determines if unicast and mixed packets are sent exclusively to the manageability path
SMBus mode: Determines if packets that have passed decision filter 5 are sent exclusively to the
manageability path
6 Global Multicast
NC-SI mode: Determines if multicast packets are sent exclusively to the manageability path
SMBus mode: Determines if packets that have passed decision filter 6 are sent exclusively to the
manageability path
7 Broadcast NC-SI mode: Determines if broadcast packets are sent exclusively to the manageability path
SMBus mode: Determines if ARP packets are sent exclusively to the manageability path
31:8 Reserved Reserved
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The MNGONLY is also configurable when using NC-SI using the Set Intel Filters — Manageability Only
Command (see Section 10.6.3.5.3).
All manageability filters are controlled by the MC only and not by the LAN device driver.
10.3.5 Possible Configurations
This section describes ways of using management filters. Actual usage may vary.
10.3.5.1 Dedicated MAC Packet Filtering
Select one of the eight rules for dedicated MAC filtering.
Load Host MAC address to one of the management MAC address filters and set the appropriate bit
in field 3:0 of the MDEF register.
Set other bits to qualify which packets are allowed to pass through. For example:
Load one or more management VLAN filters and set the appropriate bits in field 12:5 of the
MDEF register to qualify the relevant manageability VLANs.
Set relevant bits in field 20:13 of the MDEF register to qualify with a match to one of the IP
addresses.
Set any L3/L4 bits (bits 31:27 in the MDEF register and bits 23:16 in the MDEF_EXT register) to
filter using any set of L3/L4 filters.
10.3.5.2 Broadcast Packet Filtering
Select one of the eight rules for broadcast filtering.
Set bit 25 in the MDEF register of the decision rule to enforce broadcast filtering.
Set other bits to qualify which broadcast packets are allowed to pass through. For example:
Set bit 5 in the MDEF register to filter with the first manageability VLAN.
Set relevant bits in field 20:13 of the MDEF register to qualify with a match to one of the IP
addresses.
Set any L3/L4 bits (bits 31:27 in the MDEF register and bits 23:16 in the MDEF_EXT register) to
filter with any set of L3/L4 filters.
10.3.5.3 VLAN Packet Filtering
Select one of the eight rules for VLAN filtering.
Load one or more management VLAN filters and set the appropriate bits in field 12:5 of the MDEF
register to qualify the relevant manageability VLANs.
Set other bits to qualify which VLAN packets are allowed to pass through. For example:
Set any L3/L4 bits (bits 31:27 in the MDEF register and bits 23:16 in the MDEF_EXT register) to
filter using appropriate L3/L4 filter set.
10.3.5.4 IPv6 Filtering
IPv6 filtering is done using the following IPv6-specific filters:
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IP Unicast filtering — requires filtering for Link Local address and a Global address. Filtering setup
might depend on whether or not the MAC address is shared with the Host or dedicated to
manageability:
Dedicated MAC address (for example, dynamic address allocation with DHCP does not support
multiple IP addresses for one MAC address). In this case, filtering can be done at L2 using two
dedicated unicast MAC filters.
Shared MAC address (for example, static address allocation sharing addresses with Host). In
this case, filtering needs to be done at L3, requiring two IPv6 address filters, one per address.
A neighbor Discovery filter — The I210 supports IPv6 neighbor Discovery protocol. Since the
protocol relies on multicast packets, the I210 supports filtering of these packets. IPv6 multicast
addresses are translated into corresponding Ethernet multicast addresses in the form of 33-33-xx-
xx-xx-xx, where the last 32 bits of address are taken from the last 32 bits of the IPv6 multicast
address. As a result, two direct MAC filters can be used to filter IPv6 solicited-node multicast
packets as well as IPv6 all node multicast packets.
10.3.5.5 Receive Filtering with Shared IP
When using the SMBus interface, it is possible to share the Host MAC and IP address with the MC. This
functionality is also available when using NC-SI using Intel OEM commands.
When the MC shares the MAC and IP address with the Host, receive filtering is based on identifying
specific flows through port allocation. The following setting might be used:
Select one of the eight rules for Dedicated MAC filtering.
Load Host MAC address to one of the management MAC address filters and set the appropriate bit
in field 3:0 of the MDEF register to enforce MAC address filtering using the MAC address.
If VLAN is used for management, load one or more management VLAN filters and set the
appropriate bits in field 12:5 of the MDEF register to qualify the relevant manageability VLANs.
ARP filter/Neighbor Discovery filter is enabled when the MC is responsible for handling the ARP
protocol. Set bit 27 or bit 28 in the MDEF register for this functionality.
Set other bits to qualify which packets are allowed to pass through. For example:
Set any L3/L4 bits (bits 31:27 in the MDEF register and bits 23:16 in the MDEF_EXT register) to
filter using the appropriate L3/L4 filters.
10.3.6 Determining Manageability MAC Address
If the MC wishes to use a dedicated MAC address or configure the automatic ARP response mechanism
(only available in SMBus mode), it may be beneficial for the MC to be able to determine the MAC
address used by the Host.
Both the NC-SI and SMBus interfaces provide an Intel OEM command to read the System MAC address.
A possible use for this is that the MAC address programmed at manufacturing time does not increment
by one each time, but rather by two. In this way, the MC can read the System MAC address and add
one to it and be guaranteed of a unique MAC address.
Determining the IP address being used by the Host is beyond the scope of this document.
10.3.7 Filtering Programming Interfaces
The I210 provides multiple options to program the forwarding filters, depending on the interface used
and the level of flexibility needed. The following table describes the different options and points to the
description of the relevant commands.
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10.3.7.1 Dedicated Shared MAC and Shared IP Support
The I210 is planned to works in systems where the same MAC and IP are shared between a platform's
host operating system and its out-of-band management controller. In order to support such systems
the I210 supports additional shared MAC filtering options on top of what was supported in previous
products. This section describes these options and the NC-SI commands used to program them.
Note: All the filtering capabilities are exposed via the regular NC-SI packet reduction and packet
addition commands and via the SMBus Set Filtering command. The interface described in this
section is a more abstract interface.
10.3.7.2 Sharing an IP and MAC Address
NC-SI over MCTP will be used in desktop and mobile platforms. These platforms are typically used in
enterprise environments outside of a data center. IP subnets in these environments are commonly
designed such that more than 50% of their available addresses are assigned.
Hence, assigning a second IP address to an out-of-band management controller would generally
necessitate a subnet redesign. Instead, a single IP address is typically shared between the host
operating system and an out-of-band management controller in these platforms.
Because it's possible to bind multiple IP addresses to a single MAC address, a Network Controller needs
to know the IP address shared by a Management Controller in order to deliver packets to it. A
Management Controller uses the Set IP Address command to communicate its IP address to a Network
Controller. The Set IP Address command is defined in Section 10.6.3.14.1.
In order to notify the Network controller that the BMC intends to use a shared MAC, the Set Shared
Mode command (Section 10.6.3.14.12) should be given before programming any filter using the
regular NC-SI commands (Set MAC address or Set VLAN) or the Intel OEM commands
(Section 10.6.3.14).
Table 10-1 Filtering Programming Interfaces
Interface Flexible/Abstract Description
NC-SI (over
RMII or over
MCTP)
Abstract (dedicated
MAC address)
The regular NC-SI commands can be used to allow forwarding based on a
dedicated MAC address. The list of supported commands can be found in
Section 10.6.2. When using these commands, one of the two other modes can be
used to add finer grain filtering.
Abstract (Shared MAC
and IP)
The Intel OEM commands described in Section 10.3.7.1 and in Section 10.6.3.14
can be used to define which part of the shared MAC or shared IP traffic should be
forwarded. When using these commands, the flexible filtering interface should not
be used. This mode is activated using the Set Shared mode command
(Section 10.6.3.14.12)
Flexible
This interface described in most of the subsections of Section 10.6.2.4. It uses the
packet reduction commands to reduce the forwarding scope of the filters set by
the regular NC-SI commands and the packet addition commands to add new
packet types to the forwarding rules.
SMBus
Abstract
The Set Common filter command (Section 10.5.9.1.7) can be used to set the
most common filters. When using this commands the flexible filtering interface
should not be used. When sending this command, all previous filtering requests
are cleared.
Flexible The Update MNG RCV Filter Parameters (Section 10.5.9.1.6) can be used to define
the exact filtering rules to be applied.
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10.3.7.2.1 Ports Owned by the MC
A small subset of the TCP and UDP ports is dedicated to the out-of-band management controller. The
remaining ports are assigned to the host operating system. Hence, port-based filtering - and
commands to configure it - is required. For example, port-based filtering would be used to route WS-
Management packets to the out-of-band management controller.
A Network Controller needs to know the ports owned by a Management Controller in order to deliver
packets to it. A Management Controller uses the Set Port command to communicate its ports to a
Network Controller. The Set Port command is defined in Section 10.6.3.14.3. The I210 supports 10 port
filters.
The Set Binding (Section 10.6.3.14.10) command is used to define the combination of MAC, VLAN, IP
and ports that should be met to forward packets to the MC.
10.3.7.2.2 Sharing Network Infrastructure Packets
In addition to management traffic, the management controller needs to monitor network infrastructure
traffic along with the host. For each flow it is possible to define if it should include host traffic only, both
host and network or only network.
10.3.7.2.3 ARP Filters Enhancement
ARP request message filtering is controlled by the Enable Broadcast Filter command. However, as
currently defined, this command causes either all or no ARP requests to go to the Management
Controller. For MCTP over SMBus, attempting to forward all ARP requests within a subnet to the
Management Controller can easily overwhelm the available bandwidth. Therefore, an option to have the
Network Controller forward only ARP requests that contain a Target IP Address value that matches the
IP address used by the Management Controller. An amendment to Enable Broadcast Filter is defined
below to address this requirement.
10.4 OS-to-MC Traffic
10.4.1 Overview
Traditionally, the communication between a Host and the local MC is not handled through the network
interface and requires a dedicated interface such as an IPMI KCS interface. The I210 allows the Host
and the local MC communication via the regular pass-through interface, and thus allow management of
a local console using the same interface used to manage any MC in the network.
When this flow is used, the Host will send packets to the MC through the network interface. The I210
will examine these packets and it will then decide if they should be forwarded to the MC. On the inverse
path, when the MC sends a packet on the pass-through interface, the I210 will check if it should be
forwarded to the network, the Host, or both. Figure 10-2 describes the flow for OS-to-MC traffic for the
NC-SI over RMII case. OS2BMC is available also when working over MCTP. It is not available in legacy
SMBus mode.
The OS-to-MC flow can be enabled using the OS2BMC enable field for the relevant port in the OS 2 MC
configuration structure of the Flash.
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Figure 10-2. OS-to-MC Diagram
Note: This flow assumes that the MC does not share a MAC address with the Host.
The OS-to-MC flow is enabled only for ports enabled by the NC-SI “Enable Channel” command
or via the OS-to-MC Enable field for the relevant port in the OS-to-MC configuration structure
of the Flash.
OS2BMC traffic must comply with NC-SI specifications and is therefore limited to maximum
sized frames of 1536 bytes (in both directions).
10.4.2 Filtering
10.4.2.1 OS2BMC Filtering
When OS-to-MC traffic is enabled, the filters used for network to MC traffic are also used for OS-to-MC
traffic. Traffic considered as exclusive to the MC (Relevant bit in MNGONLY is set) is also considered as
exclusive to the MC when sent from the Host and not forwarded to the network.
10.4.2.2 Handling of OS-to-MC Packets
All the regular transmit offloads are available for OS-to-MC packets also.
Network
Controller
Port NPort 0
External
Network
NC-SI
Channel 0
NC-SI
Channel N
MC
MNG/host
mux
MNG/host
mux
Port 0
Driver
Port N
Driver
Networking stack
Aplication
...
...
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10.4.2.3 MC-to-OS Filtering
When OS-to-MC is enabled, as with regular MC transmit traffic, the port (OS or network) to which the
packet is sent is fixed according to the source MAC address of the packet.
After that, the MC traffic will be filtered according to the L2 Host filters of the selected port (as
described in Section 7.1.1). According to the results of the filtering the packet can be forwarded to the
OS, the network or both.
The following rules apply to the forwarding of OS packets:
If MC to net is disabled, all the traffic from the MC is sent to the Host.
If MC to host is disabled, all the traffic from the MC is sent to the network.
The packet will be forwarded only according to the destination MAC address and VLAN tag.
Unicast packets that matches one of the exact filters (RAH/RAL) are sent only to the Host. Other
packets that passes the L2 Host filtering will be sent to both the Host and the network. Packets that do
not pass the L2 filtering are sent only to the network.
10.4.2.4 Queuing of packets received from the MC.
Packets received from the MC are queued in the default queue.
10.4.2.5 Offloads of packets received from the MC.
Packets received from the MC and forwarded to the OS do not pass the same path as regular network
packets. Thus parts of the offloads provided for the network packets are not available for the MC
packets. Packet received from the MC are identified by the RDESC.STATUS.MC bit.
The following list describes which offloads are available for MC packets:
CRC is checked and removed on the MC packets. The RDESC.STATUS.Strip CRC will always be set
for these packets.
The RSS type and RSS hash are not calculated for MC packets and are always set to zero.
The header of MC packets is never split.
A fragmented MC packet will not be detected by the hardware.
The MC packets are not detected as time sync packet. The RDESC.STATUS.TS will always be clear
for these packets.
The L3 and L4 checksum are not performed on these packets. The L4I, IPCS, UDPCS, and UDPV
fields will always be cleared for these packets.
In systems where the double VLAN feature is enabled (CTRL_EXT.EXT_VLAN is set), the VEXT bit is
valid for MC packets.
Note: In systems that uses double VLAN, the MC is expected to send all packets (apart from NC-SI
commands) with the outer VLAN included. Failing to do so may cause corruptions to the
packet received by the OS
The RDESC.ERRORS field is always cleared for these packets.
Note: Traffic sent from the MC will not cause a PME event, even if it matches one of the wake-up
filters set by the port.
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10.4.3 Blocking of network to MC flow
In some systems the MC may have its own private connection to the network and may use the I210
port only for the OS-to-MC traffic. In this case, the MC to network flow should be blocked while enabling
the OS-to-MC and OS to network flows.
This can be done by clearing the MANC.EN_BMC2NET bit for the relevant port. The MC can control this
functionality using the “Enable Network to MC flow” and “Disable Network to MC flow” NC-SI OEM
commands. This can also be controlled using the Network to MC disable field in the Flash “OS2BMC
Configuration Structure”.
Note: When network to MC flow is blocked and OS-to-MC flow is enabled, all the traffic from the MC
is sent to the OS without any check. The OS traffic filtering is still done using the regular
decision filters.
10.4.4 Statistics
Packets sent from the OS to the MC should be counted by all statistical counters as packets sent by the
OS. If they are sent to both the network and to the MC, then they are counted once.
Packets sent from the MC to the Host are counted as packets received by the Host. If they are sent to
the Host and to the network, then they are counted both as received packets and as packet transmitted
to the network.
In addition, the I210 supports the following statistical counters that measure just the MC to OS and OS-
to-MC traffic:
O2BGPTC - OS2BMC packets received by MC
O2BSPC - OS2BMC packets transmitted by OS
B2OSPC - BMC2OS packets sent by MC
B2OGPRC - BMC2OS packets received by OS.
The driver can use these statistics to count packets dropped by the I210 during the transfer between
the OS and the MC.
See Section 7.9.5 for details of the statistics hierarchy.
10.4.5 OS-to-MC Enablement
The I210 supports the unified network software model for OS-to-MC traffic, where the OS-to-MC traffic
is shared with the regular traffic. In this model, there is no need for a special configuration of the OS
networking stack or the MC stack, but if the link is down, then the OS-to-MC communication is stopped.
In order to enable OS-to-MC either:
Enable OS2BMC in the port traffic type field in the Traffic type Parameters Flash word for the
relevant port.
Send an EnableOS2BMC Flow NC-SI OEM Command.
Note: When OS2BMC is enabled, OS shall avoid sending packets longer than 1.5KB to MC. Such
packets will be dropped.
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10.5 SMBus Pass-Through Interface
SMBus is the system management bus defined by Intel. It is used in personal computers and servers
for low-speed system management communications. This section describes how the SMBus interface
operates in pass-through mode.
10.5.1 General
The SMBus sideband interface includes standard SMBus commands used for assigning a slave address
and gathering device information as well as Intel proprietary commands used specifically for the pass-
through interface.
10.5.2 Pass-Through Capabilities
This section details manageability capabilities the I210 provides while in SMBus mode. Pass-through
traffic is carried by the sideband interface as described in Section 10.1.
These services are not available in NC-SI mode.
When operating in SMBus mode, in addition to exposing a communication channel to the LAN for the
MC, the I210 provides the following manageability services to the MC:
ARP handling — The I210 can be programmed to auto-ARP replying for ARP request packets to
reduce the traffic over the MC interconnect.
Default configuration of filters by Flash - When working in SMBus mode, the default values of the
manageability receive filters can be set according to the PT LAN and flex TCO Flash structures.
Padding of short packets. Packets smaller than 60 bytes but larger than 17 bytes will be padded to
a legal Ethernet packet.
CRC calculation - The device adds an Ethernet CRC on all sent packets.
10.5.3 Automatic Ethernet ARP Operation
The I210 can offload the Ethernet Address Resolution Protocol (ARP) for the MC in order to reduce the
bandwidth required on the SMBus link.
Automatic Ethernet ARP parameters are loaded from the Flash when the I210 is powered up or
configured through the sideband management interface. The following parameters should be
configured in order to enable ARP operation:
ARP auto-reply enabled
ARP IP address (to filter ARP packets)
ARP MAC addresses (for ARP responses)
These are all configurable over the sideband interface using the advanced version of the Receive Enable
command.
When an ARP request packet is received and ARP auto-reply is enabled, the I210 checks the targeted IP
address (after the packet has passed L2 checks and ARP checks). If the targeted IP matches the IP
configuration for the I210, it replies with an ARP response.
The I210 responds to ARP request targeted to the ARP IP address with the configured ARP MAC
address. If the I210 is not configured to do auto-ARP response, it can be configured to forward the ARP
packets to the MC (which can respond to ARP requests).
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When the external MC uses the same IP and MAC address of the OS, the ARP operation should be
coordinated with the Host operating system.
Note: If sharing the MAC and IP with the Host operating system is possible, the I210 provides the
ability to read the stem MAC address, allowing the MC to share the MAC address. There is no
mechanism however provided by the I210 to read the IP address. The Host OS (or an agent
within) and MC must coordinate the sharing of IP addresses.
10.5.3.1 ARP Packet Formats
Table 10-6. ARP Request Packet
Offset # Of bytes Field Value (In
Hex) Action
0 6 Destination Address Compare
6 6 Source Address Stored
12 S=(0/4/8) Possible VLAN Tags (single or double) Stored
12 + S D=(0/8) Possible Length + LLC/SNAP Header Stored
12 + S + D 2 Type 0806 Compare
14+ S + D 2 HW Type 0001 Compare
16+ S + D 2 Protocol Type 0800 Compare
18+ S + D 1 Hardware Size 06 Compare
19+ S + D 1 Protocol Address Length 04 Compare
20+ S + D 2 Operation 0001 Compare
22+ S + D 6 Sender HW Address - Stored
28+ S + D 4 Sender IP Address - Stored
32+ S + D 6 Target HW Address - Ignore
38+ S + D 4 Target IP Address ARP IP address Compare
Table 10-7. ARP Response Packet
Offset # of
bytes Field Value
0 6 Destination Address ARP Request Source Address
6 6 Source Address Programmed from Flash or MC
12 S=(0/4/8) Possible VLAN Tags (single or double) From ARP Request
12 + S D=(0/8) Possible Length + LLC/SNAP Header From ARP Request
12 + S + D 2 Type 0x0806
14+ S + D 2 HW Type 0x0001
16+ S + D 2 Protocol Type 0x0800
18+ S + D 1 Hardware Size 0x06
19+ S + D 1 Protocol Address Length 0x04
20+ S + D 2 Operation 0x0002
22+ S + D 6 Sender HW Address Programmed from Flash or MC
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10.5.4 SMBus Transactions
This section gives a brief overview of the SMBus protocol. Following is an example for a format of a
typical SMBus transaction.
The top row of the table identifies the bit length of the field in a decimal bit count. The middle row
(bordered) identifies the name of the fields used in the transaction. The last row appears only with
some transactions, and lists the value expected for the corresponding field. This value can be either
hexadecimal or binary.
The SMBus controller is a master for some transactions and a slave for others. The differences are
identified in this document.
Shorthand field names are listed in Table 10-8 and are fully defined in the SMBus specification.
10.5.4.1 SMBus Addressing
SMBus addresses (enabled from the Flash) can be re-assigned using the SMBus ARP protocol.
In addition to the SMBus address values, all parameters of the SMBus (SMBus channel selection,
address mode, and address enable) can be set only through Flash configuration. Note that the Flash is
read at the I210’s power up and resets.
All SMBus addresses should be in Network Byte Order (NBO); MSB first.
28+ S + D 4 Sender IP Address Programmed from Flash or MC
32 +S + D 6 Target HW Address ARP Request Sender HW Address
38 +S + D 4 Target IP Address ARP Request Sender IP Address
1 7 1 1 8 1 8 1 1
S Slave Address Wr A Command A PEC A P
1100 001 0 0 0000 0010 0 [Data Dependent] 0
Table 10-8. Shorthand Field Names
Field Name Definition
S SMBus START Symbol
P SMBus STOP Symbol
PEC Packet Error Code
A ACK (Acknowledge)
N NACK (Not Acknowledge)
Rd Read Operation (Read Value = 1b)
Wr Write Operation (Write Value = 0b)
Table 10-7. ARP Response Packet (Continued)
Offset
(Continued
# of
bytes Field Value
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10.5.4.2 SMBus ARP Functionality
The I210 supports the SMBus ARP protocol as defined in the SMBus 2.0 specification. The I210 is a
persistent slave address device so its SMBus address is valid after power-up and loaded from the Flash.
The I210 supports all SMBus ARP commands defined in the SMBus specification both general and
directed.
SMBus ARP capability can be disabled through the Flash.
10.5.4.3 SMBus ARP Flow
SMBus ARP flow is based on the status of two flags:
AV (Address Valid): This flag is set when the I210 has a valid SMBus address.
AR (Address Resolved): This flag is set when the I210 SMBus address is resolved (SMBus address
was assigned by the SMBus ARP process).
These flags are internal I210 flags and are not exposed to external SMBus devices.
Since the I210 is a Persistent SMBus Address (PSA) device, the AV flag is always set, while the AR flag
is cleared after power up until the SMBus ARP process completes. Since AV is always set, the I210
always has a valid SMBus address.
When the SMBus master needs to start an SMBus ARP process, it resets (in terms of ARP functionality)
all devices on SMBus by issuing either Prepare to ARP or Reset Device commands. When the I210
accepts one of these commands, it clears its AR flag (if set from previous SMBus ARP process), but not
its AV flag (the current SMBus address remains valid until the end of the SMBus ARP process).
Clearing the AR flag means that the I210 responds to SMBus ARP transactions that are issued by the
master. The SMBus master issues a Get UDID command (general or directed) to identify the devices on
the SMBus. The I210 always responds to the Directed command and to the General command only if its
AR flag is not set.
After the Get UDID, The master assigns the I210 SMBus address by issuing an Assign Address
command. The I210 checks whether the UDID matches its own UDID and if it matches, it switches its
SMBus address to the address assigned by the command (byte 17). After accepting the Assign Address
command, the AR flag is set and from this point (as long as the AR flag is set), the I210 does not
respond to the Get UDID General command. Note that all other commands are processed even if the AR
flag is set. The I210 stores the SMBus address that was assigned in the SMBus ARP process in the
Flash, so at the next power up, it returns to its assigned SMBus address.
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Figure 10-3 shows the I210 SMBus ARP flow.
Figure 10-3. SMBus ARP Flow
Power-Up reset
Set AV flag; Clear AR flag
Load SMB address from
EPROM
SMB packet
received
NO
SMB ARP
address
match
Yes
Prepare to
ARP ?
ACK the comamd and
clear AR flag
YES
Yes
Reset
device
ACK the comamd and
clear AR flag
YES
NO
Assign
Address
command
NO
UDID match NACK packet
ACK packet
Set slave address
Set AR flag.
YES NO
YES
YES AR flag set Return UDIDNO
NO
Illegal command
handling
NO
Process regular
command NO
NACK packetYES
YES Return UDID
NO
Get UDID
command
general
Get UDID
command
directed
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10.5.4.4 SMBus ARP UDID Content
The UDID provides a mechanism to isolate each device for the purpose of address assignment. Each
device has a unique identifier. The 128-bit number is comprised of the following fields:
Where:
Device Capabilities: Dynamic and Persistent Address, PEC Support bit:
Version/Revision: UDID Version 1, Silicon Revision:
1 Byte 1 Byte 2 Bytes 2 Bytes 2 Bytes 2 Bytes 2 Bytes 4 Bytes
Device
Capabilities Version/
Revision Vendor ID Device ID Interface Subsystem
Vendor ID Subsystem
Device ID Vendor
Specific ID
See notes
that follow See notes
that follow 0x8086 0x1531 0x0004/
0x0024 0x0000 0x0000 See notes
that follow
MSB LSB
Vendor ID: The device manufacturer’s ID as assigned by the SBS Implementers’ Forum or the PCI SIG.
Constant value: 0x8086
Device ID: The device ID as assigned by the device manufacturer (identified by the Vendor ID field).
Constant value: 0x1531
Interface:
Identifies the protocol layer interfaces supported over the SMBus connection by the device.
Bits 3:0 = 0x4 indicates SMBus Version 2.0
Bit 5 (ASF bit) = 1 in MCTP mode.
Subsystem Fields: These fields are not supported and return zeros.
76543210
Address Type Reserved (0) Reserved (0) Reserved (0) Reserved (0) Reserved (0) PEC Supported
0b 1b 0b 0b 0b 0b 0b 0/1b1
1. The value is set according to the SMBus Transaction PEC bit in the Flash.
MSB LSB
76543210
Reserved (0) Reserved (0) UDID Version Silicon Revision ID
0b 0b 001b See the following table
MSB LSB
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Silicon Revision ID:
Vendor Specific ID: Four LSB bytes of the device Ethernet MAC address. The device Ethernet address is
taken from words LAN Base Address + Offsets 0x00-0x02 in the Flash.
10.5.4.5 Concurrent SMBus Transactions
The SMBus interface is single threaded. Thus, concurrent SMBus transactions are not permitted. Once a
transaction is started, it must be completed before additional transaction can be initiated.
A transaction is defined as:
All SMBus commands used to receive a packet.
All SMBus commands used to send a packet.
The read and write SMBus commands used as part of read parameters described in
Section 10.5.9.2.
The single write SMBus commands described in Section 10.5.9.1.
10.5.5 SMBus Notification Methods
The I210 supports three methods of notifying the MC that it has information that needs to be read by
the MC:
SMBus alert - Refer to Section 10.5.5.1.
Asynchronous notify - Refer to Section 10.5.5.2.
Direct receive - refer to Section 10.5.5.3.
The notification method used by the I210 can be configured from the SMBus using the Receive Enable
command. The default method is set by the Flash in the Notification method field in LAN Receive Enable
1 (Section 6.7.2.18).
The following events cause the I210 to send a notification event to the MC:
Receiving a LAN packet that is designated to the MC.
The Firmware was reset and requires re-initialization.
Receiving a Request Status command from the MC initiates a status response.
The I210 is configured to notify the MC upon status changes (by setting the EN_STA bit in the
Receive Enable Command) and one of the following events happen:
TCO Command Aborted
Link Status changed
Silicon Version Revision ID
A0 000b
A1 001b
A2 011b
1 Byte 1 Byte 1 Byte 1 Byte
MAC Address, Byte 3 MAC Address, Byte 2 MAC Address, Byte 1 MAC Address, Byte 0
MSB LSB
Ethernet Controller I210 —System Manageability
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Power state change
There can be cases where the MC is hung and not responding to the SMBus notification. The I210 has a
time-out value (defined in the Flash) to avoid hanging while waiting for the notification response. If the
MC does not respond until the time out expires, the notification is de-asserted and all pending data is
silently discarded.
Note that the SMBus notification time-out value can only be set in the Flash. The MC cannot modify this
value.
10.5.5.1 SMBus Alert and Alert Response Method
The SMBus Alert# (SMBALERT_N) signal is an additional SMBus signal that acts as an asynchronous
interrupt signal to an external SMBus master. The I210 asserts this signal each time it has a message
that it needs the MC to read and if the chosen notification method is the SMBus alert method. Note that
the SMBus alert method is an open-drain signal which means that other devices besides the I210 can
be connected on the same alert pin. As a result, the MC needs a mechanism to distinguish between the
alert sources.
The MC can respond to the alert by issuing an ARA Cycle command to detect the alert source device.
The I210 responds to the ARA cycle with its own SMBus slave address (if it was the SMBus alert source)
and de-asserts the alert when the ARA cycle is completes. Following the ARA cycle, the MC issues a
read command to retrieve the I210 message.
Some BMCs do not implement the ARA cycle transaction. These BMCs respond to an alert by issuing a
Read command to the I210 (0xC0/0xD0 or 0xDE). The I210 always responds to a Read command, even
if it is not the source of the notification. The default response is a status transaction. If the I210 is the
source of the SMBus Alert, it replies the read transaction and then de-asserts the alert after the
command byte of the read transaction.
Note: In SMBus Alert mode, the SMBALERT_N pin is used for notification. In multiple-address mode,
all devices generate alerts on events that are independent of each other.
The ARA cycle is an SMBus receive byte transaction to SMBus Address 0001-100b. Note that the ARA
transaction does not support PEC. The ARA transaction format is as follows:
10.5.5.2 Asynchronous Notify Method
When configured using the asynchronous notify method, the I210 acts as a SMBus master and notifies
the MC by issuing a modified form of the write word transaction. The asynchronous notify transaction
SMBus address and data payload is configured using the Receive Enable command or using the Flash
defaults. Note that the asynchronous notify is not protected by a PEC byte.
1 7 1 1 8 1 1 1
S Alert Response Address Rd A Slave Device Address A P
0001 100 1 0 Manageability Slave SMBus
Address 0 1
1 7 1 1 7 1 1
S Target Address Wr A Sending Device Address A ...
MC Slave Address 0 0 MNG Slave SMBus Address 0 0
System Manageability—Ethernet Controller I210
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The target address and data byte low/high is taken from the Receive Enable command or Flash
configuration.
10.5.5.3 Direct Receive Method
If configured, the I210 has the capability to send a message it needs to transfer to the external MC as
a master over the SMBus instead of alerting the MC and waiting for it to read the message.
The message format follows. Note that the command that is used is the same command that is used by
the external MC in the Block Read command. The opcode that the I210 puts in the data is also the same
as it put in the Block Read command of the same functionality. The rules for the F and L flags (bits) are
also the same as in the Block Read command.
10.5.6 Receive TCO Flow
The I210 is used as a channel for receiving packets from the network link and passing them to the
external MC. The MC configures the I210 to pass these specific packets to the MC. Once a full packet is
received from the link and identified as a manageability packet that should be transferred to the MC,
the I210 starts the receive TCO flow to the MC.
The I210 uses the SMBus notification method to notify the MC that it has data to deliver. Since the
packet size might be larger than the maximum SMBus fragment size, the packet is divided into
fragments, where the I210 uses the maximum fragment size allowed in each fragment (configured via
the Flash). The last fragment of the packet transfer is always the status of the packet. As a result, the
packet is transferred in at least two fragments. The data of the packet is transferred as part of the
receive TCO LAN packet transaction.
When SMBus alert is selected as the MC notification method, the I210 notifies the MC on each fragment
of a multi-fragment packet. When asynchronous notify is selected as the MC notification method, the
I210 notifies the MC only on the first fragment of a received packet. It is the MC's responsibility to read
the full packet including all the fragments.
Any timeout on the SMBus notification results in discarding the entire packet. Any NACK by the MC
causes the fragment to be re-transmitted to the MC on the next Receive Packet command.
8 1 8 1 1
Data Byte Low A Data Byte High A P
Interface 0 Alert Value 0
1 7 1 1 1 1 6 1
S Target Address Wr A F L Command A ...
MC Slave Address 0 0 First
Flag Last
Flag
Receive TCO Command
01 0000b 0
8 1 8 1 1 8 1 1
Byte Count A Data Byte 1 A ... A Data Byte N A P
N 0 0 0 0
Ethernet Controller I210 —System Manageability
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The maximum size of the received packet is limited by the I210 hardware to 1536 bytes. Packets larger
then 1536 bytes are silently discarded. Any packet smaller than 1536 bytes is processed.
10.5.7 Transmit TCO Flow
The I210 is used as the channel for transmitting packets from the external MC to the network link. The
network packet is transferred from the MC over the SMBus and then, when fully received by the I210,
is transmitted over the network link.
The I210 supports packets up to an Ethernet packet length of 1536 bytes. Since SMBus transactions
can only be up to 240 bytes in length, packets might need to be transferred over the SMBus in more
than one fragment. This is achieved using the F and L bits in the command number of the transmit TCO
packet Block Write command. When the F bit is set, it is the first fragment of the packet. When the L bit
is set, it is the last fragment of the packet. When both bits are set, the entire packet is in one fragment.
The packet is sent over the network link only after all its fragments are received correctly over the
SMBus. The maximum SMBus fragment size is defined within the Flash and cannot be changed by the
MC.
The minimum packet length defined by the 802.3 spec is 64 bytes. The I210 pads packets that are less
than 64 bytes to meet the specification requirements (there is no need for the external MC to pad
packets less than 64 bytes). If the packet sent by the MC is larger than 1536 bytes, the I210 silently
discards the packet. The minimal packet size that the I210 can handle is 17 bytes.
The I210 calculates the L2 CRC on the transmitted packet and adds its four bytes at the end of the
packet. Any other packet field (such as XSUM or VLAN) must be calculated and inserted by the MC (the
I210 does not change any field in the transmitted packet, other than adding padding and CRC bytes).
If the network link is down when the I210 has received the last fragment of the packet from the MC, it
silently discards the packet. Note that any link down event during the transfer of any packet over the
SMBus does not stop the operation since the I210 waits for the last fragment to end to see whether the
network link is up again.
10.5.7.1 Transmit Errors in Sequence Handling
Once a packet is transferred over the SMBus from the MC to the I210, the F and L flags should follow
specific rules. The F flag defines the first fragment of the packet; the L flag that the transaction contains
the last fragment of the packet. Table 10-9 lists the different flag options in transmit packet
transactions.
Note: Since every other Block Write command in TCO protocol has both F and L flags on, they cause
flushing any pending transmit fragments that were previously received. When running the
TCO transmit flow, no other Block Write transactions are allowed in between the fragments.
Table 10-9. Flag Options During Transmit Packet Transactions
Previous Current Action/Notes
Last First Accept both.
Last Not First Error for the current transaction. Current transaction is discarded and an abort status is
asserted.
Not Last First
Error in previous transaction. Previous transaction (until previous First) is discarded. Current
packet is processed.
No abort status is asserted.
Not Last Not First Process the current transaction.
System Manageability—Ethernet Controller I210
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10.5.7.2 TCO Command Aborted Flow
The I210 indicates to the MC an error or an abort condition by setting the TCO Abort bit (See
Section 10.5.9.2.2) in the general status. The I210 might also be configured to send a notification to
the MC (see Section 10.5.9.1.3.3).
Following is a list of possible error and abort conditions:
Any error in the SMBus protocol (NACK, SMBus timeouts, etc.).
If the MC does not respond until the notification timeout (programmed in the EEPROM) expires
Any error in compatibility between required protocols to specific functionality (for example, RX
Enable command with a byte count not equal to 1/14, as defined in the command specification).
If the I210 does not have space to store the transmitted packet from the MC (in its internal buffer
space) before sending it to the link, the packet is discarded and the external MC is notified via the
Abort bit.
Error in the F/L bit sequence during multi-fragment transactions.
An internal reset to the I210's firmware.
10.5.8 SMBus ARP Transactions
All SMBus ARP transactions include the PEC byte.
10.5.8.1 Prepare to ARP
This command clears the Address Resolved flag (set to false). It does not affect the status or validity of
the dynamic SMBus address and is used to inform all devices that the ARP master is starting the ARP
process:
10.5.8.2 Reset Device (General)
This command clears the Address Resolved flag (set to false). It does not affect the status or validity of
the dynamic SMBus address.
10.5.8.3 Reset Device (Directed)
The Command field is NACKed if bits 7:1 do not match the current SMBus address. This command
clears the Address Resolved flag (set to false) and does not affect the status or validity of the dynamic
SMBus address.
1 7 1 1 8 1 8 1 1
S Slave Address Wr A Command A PEC A P
1100 001 0 0 0000 0001 0 [Data Dependent Value] 0
1 7 1 1 8 1 8 1 1
S Slave Address Wr A Command A PEC A P
1100 001 0 0 0000 0010 0 [Data Dependent Value] 0
Ethernet Controller I210 —System Manageability
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10.5.8.4 Assign Address
This command assigns SMBus address. The address and command bytes are always acknowledged.
The transaction is aborted (NACKed) immediately if any of the UDID bytes is different from I210 UDID
bytes. If successful, the manageability system internally updates the SMBus address. This command
also sets the Address Resolved flag (set to true).
1 7 1 1 8 1 8 1 1
S Slave Address Wr A Command A PEC A P
1100 001 0 0 Targeted Slave
Address | 0 0 [Data Dependent Value] 0
1 7 1 1 8 1 8 1
S Slave Address Wr A Command A Byte Count A · · ·
1100 001 0 0 0000 0100 0 0001 0001 0
8 1 8 1 8 1 8 1
Data 1 A Data 2 A Data 3 A Data 4 A · · ·
UDID Byte 15
(MSB) 0 UDID Byte 14 0 UDID Byte 13 0 UDID Byte 12 0
8 1 8 1 8 1 8 1
Data 5 A Data 6 A Data 7 A Data 8 A · · ·
UDID Byte 11 0 UDID Byte 10 0 UDID Byte 9 0 UDID Byte 8 0
8 1 8 1 8 1
Data 9 A Data 10 A Data 11 A · · ·
UDID Byte 7 0 UDID Byte 6 0 UDID Byte 5 0
8 1 8 1 8 1 8 1
Data 12 A Data 13 A Data 14 A Data 15 A · · ·
UDID Byte 4 0 UDID Byte 3 0 UDID Byte 2 0 UDID Byte 1 0
System Manageability—Ethernet Controller I210
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10.5.8.5 Get UDID (General and Directed)
The general get UDID SMBus transaction supports a constant command value of 0x03 and, if directed,
supports a Dynamic command value equal to the dynamic SMBus address.
If the SMBus address has been resolved (Address Resolved flag set to true), the manageability system
does not acknowledge (NACK) this transaction. If it’s a General command, the manageability system
always acknowledges (ACKs) as a directed transaction.
This command does not affect the status or validity of the dynamic SMBus address or the Address
Resolved flag.
8 1 8 1 8 1 1
Data 16 A Data 17 A PEC A P
UDID Byte 0 (LSB) 0 Assigned Address 0 [Data Dependent Value] 0
SSlave
Address Wr A Command A S
1100 001 0 0 See Below 0
7 1 1 8 1
Slave Address Rd A Byte Count A · · ·
1100 001 1 0 0001 0001 0
8 1 8 1 8 1 8 1
Data 1 A Data 2 A Data 3 A Data 4 A · · ·
UDID Byte 15 (MSB) 0 UDID Byte 14 0 UDID Byte 13 0 UDID Byte 12 0
8 1 8 1 8 1 8 1
Data 5 A Data 6 A Data 7 A Data 8 A · · ·
UDID Byte 11 0 UDID Byte 10 0 UDID Byte 9 0 UDID Byte 8 0
8 1 8 1 8 1
Data 9 A Data 10 A Data 11 A · · ·
UDID Byte 7 0 UDID Byte 6 0 UDID Byte 5 0
Ethernet Controller I210 —System Manageability
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The Get UDID command depends on whether or not this is a Directed or General command.
The General Get UDID SMBus transaction supports a constant command value of 0x03.
The Directed Get UDID SMBus transaction supports a Dynamic command value equal to the dynamic
SMBus address with the LSB bit set.
Note: Bit 0 (LSB) of Data byte 17 is always 1b.
10.5.9 SMBus Pass-Through Transactions
This section details commands (both read and write) that the I210 SMBus interface supports for pass-
through.
10.5.9.1 Write SMBus Transactions
This section details the commands that the MC can send to the I210 over the SMBus interface. The
SMBus write transactions table lists the different SMBus write transactions supported by the I210.
If a write command is received while the internal firmware is not ready, the address and the command
are acknowledged, but the byte count word is NACKed. The controller should retry the command later.
It is recommended to wait 300 ms before retrying the command.
8 1 8 1 8 1 8 1
Data 12 A Data 13 A Data 14 A Data 15 A · · ·
UDID Byte 4 0 UDID Byte 3 0 UDID Byte 2 0 UDID Byte 1 0
8 1 8 1 8 1 1
Data 16 A Data 17 A PEC P
UDID Byte 0 (LSB) 0 Device Slave Address 0 [Data Dependent Value] 1
TCO Command Transaction Command Fragmentation Section
Transmit Packet Block Write
First: 0x84
Middle: 0x04
Last: 0x44
Multiple 10.5.9.1.1
Transmit Packet Block Write Single: 0xC4 Single 10.5.9.1.1
Request Status Block Write Single: 0xDD Single 10.5.9.1.2
Receive Enable Block Write Single: 0xCA Single 10.5.9.1.3
Force TCO Block Write Single: 0xCF Single 10.5.9.1.4
Management Control Block Write Single: 0xC1 Single 10.5.9.1.5
Update MNG RCV Filter
Parameters Block Write Single: 0xCC Single 10.5.9.1.6
Set Common Filters Block Write Single: 0xC2 Single 10.5.9.1.7
Clear All Filters Byte Write Single: 0xC3 Single 10.5.9.1.8
System Manageability—Ethernet Controller I210
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10.5.9.1.1 Transmit Packet Command
The Transmit Packet command behavior is detailed in Section 10.5.7. The Transmit Packet fragments
have the following format.
The payload length is limited to the maximum payload length set in the Flash. If the overall packet
length is bigger than 1536 bytes, the packet is silently discarded.
10.5.9.1.2 Request Status Command
An external MC can initiate a request to read the I210 manageability status by sending a Request
Status command. When received, the I210 initiates a notification to an external MC when status is
ready. After this, the external controller will be able to read the status, by issuing a read status
command (see Section 10.5.9.2.2).
The format is as follows:
10.5.9.1.3 Receive Enable Command
The Receive Enable command is a single fragment command used to configure the I210. This command
has two formats: short, 1-byte legacy format (providing backward compatibility with previous
components) and long, 14-byte advanced format (allowing greater configuration capabilities). The
Receive Enable command format is as follows:
Function Command Byte Count Data 1 Data N
Transmit first fragment 0x84 N Packet data
MSB Packet data LSB
Transmit middle fragment 0x04
Transmit last fragment 0x44
Transmit single fragment 0xC4
Function Command Byte Count Data 1
Request
Status 0xDD 1 0
Function CMD Byte
Count Data 1 Data
2Data
7
Data
8Data
11
Data
12
Data
13
Data
14
Legacy
Receive
Enable 0xCA 1 Receive
Control
Byte - - - - - - -
Advanced
Receive
Enable
14
(0x0E)
MAC
Addr
MSB
MAC
Addr
LSB
IP
Addr
MSB
IP Addr
LSB
MC
SMBus
Addr
I/F Data
Byte
Alert
Value
Byte
Ethernet Controller I210 —System Manageability
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Table 10-10. Receive Control Byte
Field Bit(s) Description
RCV_EN 0
Receive TCO Enable.
0b: Disable receive TCO packets.
1b: Enable Receive TCO packets.
Setting this bit enables all manageability receive filtering operations. Enabling specific filters is
done via the Flash or through special configuration commands.
Note: When the RCV_EN bit is cleared, all receive TCO functionality is disabled, not just the
packets that are directed to the MC (also auto ARP packets).
RCV_ALL 1
Receive All Enable.
0b: Disable receiving all packets.
1b: Enable receiving all packets.
Forwards all packets received over the wire that passed L2 filtering to the external MC. This flag
has no effect if bit 0 (Enable TCO packets) is disabled.
EN_STA 2
Enable Status Reporting.
0b: Disable status reporting.
1b: Enable status reporting.
EN_ARP_RES 3
Enable ARP Response.
0b: Disable the I210 ARP response.
The I210 treats ARP packets as any other packet, for example, packet is forwarded to the MC if it
passed other (non-ARP) filtering.
1b: Enable the I210 ARP response.
The I210 automatically responds to all received ARP requests that match its IP address.
The MC IP address is provided as part of the Receive Enable message (bytes 8:11). If a short
version of the command is used, the I210 uses IP address configured in the most recent long
version of the command in which the EN_ARP_RES bit was set. If no such previous long command
exists, then the I210 uses the IP address configured in the Flash as ARP Response IPv4 Address in
the pass-through LAN configuration structure.
If the CBDM bit is set, the I210 uses the MC dedicated MAC address in ARP response packets. If
the CBDM bit is not set, the MC uses the Host MAC address.
When the Enable ARP Response feature is activated, the I210 uses the following registers to filter
in ARP requests. MC should not modify these registers:
Manageability Decision Filter – MDEF6 (and corresponding bit 6 in Management Only traffic
Register – MNGONLY).
Fourth IPv4 Filter.
NM 5:4
Notification Method. Define the notification method the I210 uses.
00b: SMBUS Alert.
01b: Asynchronous notify.
10b: Direct receive.
11b: Not supported.
Reserved 6 Reserved. Must be set to 1b.
CBDM 7
Configure the MC Dedicated MAC Address.
Note: This bit should be 0b when the RCV_EN bit (bit 0) is not set.
0b: The I210 shares the MAC address for MNG traffic with the Host MAC address, which is specified
in Flash words 0x0-0x2.
1b: The I210 uses the MC dedicated MAC address as a filter for incoming receive packets.
The MC MAC address is set in bytes 2-7 in this command.
If a short version of the command is used, the I210 uses the MAC address configured in the most
recent long version of the command in which the CBDM bit was set.
When the dedicated MAC address feature is activated, the I210 uses the following registers to filter
in all the traffic addressed to the MC MAC. MC should not modify these registers:
Manageability Decision Filter – MDEF7 (and corresponding bit 7 in Management Only traffic
Register – MNGONLY) Manageability MAC Address Low – MMAL[3]
Manageability MAC Address High – MMAH[3]
System Manageability—Ethernet Controller I210
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10.5.9.1.3.1 Management MAC Address (Data Bytes 7:2)
Ignored if the CBDM bit is not set. This MAC address is used to configure the dedicated MAC address. In
addition, it is used in the ARP response packet when the EN_ARP_RES bit is set. This MAC address is
also used when CBDM bit is set in subsequent short versions of this command.
10.5.9.1.3.2 Management IP Address (Data Bytes 11:8)
This IP address is used to filter ARP request packets.
10.5.9.1.3.3 Asynchronous Notification SMBus Address (Data Byte 12)
This address is used for the asynchronous notification SMBus transaction and for direct receive. The
SMBus address is stored in bit 7:1 of this byte. Bit 0 is always 0.
10.5.9.1.3.4 Interface Data (Data Byte 13)
Interface data byte used in asynchronous notification.
10.5.9.1.3.5 Alert Value Data (Data Byte 14)
Alert Value data byte used in asynchronous notification.
10.5.9.1.4 Force TCO Command
This command causes the I210 to perform a TCO reset, TCO isolate, or Firmware Reset
TCO Reset: if Force TCO reset is enabled in the Flash. The force TCO reset clears the data path (Rx/Tx)
of the I210 to enable the MC to transmit/receive packets through the I210. Force TCO reset is asserted
only to the port related to the SMBus address the command. This command should only be used when
the MC is unable to transmit receive and suspects that the I210 is inoperable. The command also
causes the LAN device driver to unload. It is recommended to perform a system restart to resume
normal operation.
TCO isolate: if TCO isolate is enabled in the Flash (See Section 6.7.1). The TCO Isolate command will
disable PCIe write operations to the LAN port. If TCO Isolate is disabled in Flash the I210 does not
execute the command but sends a response to the MC with successful completion. Following TCO
Isolate management sets MANC.TCO_Isolate to 1.
Firmware Reset: This command will cause re-initialization of all the manageability functions and re-load
of manageability related Flash words.
The I210 considers the Force TCO reset command as an indication that the operating system is hung
and clears the DRV_LOAD flag. The Force TCO command format is as follows:
Function Command Byte Count Data 1
Force TCO Reset 0xCF 1 TCO Mode
Ethernet Controller I210 —System Manageability
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Where TCO Mode is:
Note: Only one of the fields should be set in a given command. Setting more than one field may
yield unexpected results.
10.5.9.1.5 Management Control
This command is used to set generic manageability parameters. The parameters list is shown in
Table 10-11. The command is 0xC1 stating that it is a Management Control command. The first data
byte is the parameter number and the data afterwards (length and content) are parameter specific as
shown in Management Control Command Parameters/Content.
Note: If the parameter that the MC sets is not supported by the I210. The I210 does not NACK the
transaction. After the transaction ends, the I210 discards the data and asserts a transaction
abort status.
The Management Control command format is as follows:
Field Bit(s) Description
DO_TCO_RST 0
Perform TCO Reset.
0b: Do nothing.
1b: Perform TCO reset.
DO_TCO_ISOLATE1
1. TCO Isolate Host Write operation enabled in Flash.
1
Do TCO Isolate
0b = Enable PCIe write access to LAN port.
1b = Isolate Host PCIe write operation to the port
Note: Should be used for debug only.
RESET_MGMT 2
Reset manageability; re-load manageability Flash words.
0b = Do nothing
1b = Issue firmware reset to manageability.
Setting this bit generates a one-time firmware reset. Following the reset, management
related data from Flash is loaded.
Reserved 7:3 Reserved (set to 0x00).
Function Command Byte Count Data 1 Data 2 Data N
Management Control 0xC1 N Parameter
Number Parameter Dependent
Table 10-11. Management Control Command Parameters/Content
Parameter # Parameter Data
Keep PHY Link Up 0x00
A single byte parameter:
Data 2:
Bit 0: Set to indicate that the PHY link for this port should be kept up throughout
system resets. This is useful when the server is reset and the MC needs to keep
connectivity for a manageability session.
Bit [7:1] Reserved.
0b: Disabled.
1b: Enabled.
System Manageability—Ethernet Controller I210
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10.5.9.1.6 Update Management Receive Filter Parameters
This command is used to set the manageability receive filters parameters. The command is 0xCC. The
first data byte is the parameter number and the data that follows (length and content) are parameter
specific as listed in management RCV filter parameters.
If the parameter that the MC sets is not supported by the I210, then the I210 does not NACK the
transaction. After the transaction ends, the I210 discards the data and asserts a transaction abort
status.
The update management RCV receive filter parameters command format is as follows:
Table 10-12 lists the different parameters and their content.
Function Command Byte Count Data 1 Data 2 Data N
Update Manageability Filter
Parameters 0xCC N Parameter
Number Parameter Dependent
Table 10-12. Management Receive Filter Parameters
Parameter Number Parameter Data
Filters Enables 0x1
Defines the generic filters configuration. The structure of this parameter is four bytes
as the Manageability Control (MANC) register.
Note: The general filter enable is in the Receive Enable command that enables
receive filtering.
MNGONLY configuration 0xF
This parameter defines which of the packets types identified as manageability
packets in the receive path will never be directed to the Host memory.
Data 2:5: MNGONLY register bytes - Data 2 is the MSB
Flex Filter 0 Enable Mask and
Length 0x10
Flex Filter 0 Mask.
Data 17:2 = Mask. Bit 0 in data 2 is the first bit of the mask.
Data 19:18 = Reserved. Should be set to 00b.
Date 20 = Flexible filter length.
Flex Filter 0 Data 0x11
Data 2 — Group of flex filter’s bytes:
0x0 = bytes 0-29
0x1 = bytes 30-59
0x2 = bytes 60-89
0x3 = bytes 90-119
0x4 = bytes 120-127
Data 3:32 = Flex filter data bytes. Data 3 is LSB.
Group's length is not a mandatory 30 bytes; it might vary according to filter's length
and must NOT be padded by zeros.
Decision Filters 0x61 This command is obsolete. Please use 0x68 instead
VLAN Filters 0x62
Three bytes are required to load the VLAN tag filters.
Data 2: VLAN filter number.
Data 3: MSB of VLAN filter.
Data 4: LSB of VLAN filter.
Ethernet Controller I210 —System Manageability
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Flex Port Filters 0x63
Three bytes are required to load the manageability flex port filters.
Data 2: Flex port filter number.
Data 3: MSB of flex port filter.
Data 4: LSB of flex port filter.
Data 5:
Bit 0: Match UDP ports
Bit 1: Match TCP ports
Bit 2: Match Destination port (0) or Source Port (1).
If Data 5 is not present, the match is done on TCP and UDP destination ports (legacy
behavior).
IPv4 Filters 0x64
Five bytes are required to load the IPv4 address filter.
Data 2: IPv4 address filter number (3:0).
Data 3: LSB of IPv4 address filter.
Data 6: MSB of IPv4 address filter.
IPv6 Filters 0x65
17 bytes are required to load the IPv6 address filter.
Data 2 — IPv6 address filter number (3:0).
Data 3 — LSB of IPv6 address filter.
Data 18 — MSB of IPv6 address filter.
MAC Filters 0x66
Seven bytes are required to load the MAC address filters.
Data 2 — MAC address filters pair number (3:0).
Data 3 — MSB of MAC address.
Data 8: LSB of MAC address.
EtherType Filters 0x67
5 bytes to load Ethertype Filters (METF)
Data 2 — METF filter index (valid values are 0, 1, 2, 3)
Data 3 — MSB of METF
...
Data 6 — LSB of METF
Extended Decision Filter 0x68
9 bytes to load the extended decision filters (MDEF_EXT & MDEF)
Data 2 — MDEF filter index (valid values are 0...5)
Data 3 — MSB of MDEF_EXT (DecisionFilter1)
....
Data 6 — LSB of MDEF_EXT (DecisionFilter1)
Data 7 — MSB of MDEF (DecisionFilter0)
....
Data 10 — LSB of MDEF (DecisionFilter0)
The command shall overwrite any previously stored value
Management Special Filter
Modifiers 0x69
4 bytes to load the Management Special Filter Modifiers
Data 2 - MSB of MSFM Register
...
Data 5- LSB of MSFM Register
Table 10-12. Management Receive Filter Parameters
Parameter Number Parameter Data
System Manageability—Ethernet Controller I210
667
10.5.9.1.7 Set Common Filters Command
The Set Common Filters command is a single fragment command capable of configuring the most
common filters.
Note: If this command is used, all the other commands that programs forwarding filters should not
be used (apart from the Clear All Filters command). When this command is received, an
implied Clear All Filters command is done before the application of this command.
Table 10-13. Filter Enable Parameters
Bit Name Description
16:0 Reserved Reserved
17 RCV_TCO_EN
TCO Receive Traffic Enabled.
When bit is set receive traffic to the manageability block is enabled.
This bit should be set only if at least one of EN_BMC2OS or EN_BMC2NET
bits are set.
This bit is usually set using the receive enable command (see Section
10.5.9.1.3).
18 KEEP_PHY_LINK_UP Block PHY reset and power state changes. When this bit is set the PHY reset
and power state changes does not get to the PHY, This bit can not be written
unless Keep_PHY_Link_Up_En Flash bit is set.
22: Reserved Reserved
23 Enable Xsum Filtering to MNG When this bit is set, only packets that pass the L3 and L4 checksum are send
to the manageability block.
24 Enable IPv4 Address Filters When set, the last 128 bits of the MIPAF register are used to store four IPv4
addresses for IPv4 filtering. When cleared, these bits store a single IPv6
filter.
25 FIXED_NET_TYPE Fixed net type: If set, only packets matching the net type defined by the
NET_TYPE field passes to manageability. Otherwise, both tagged and un-
tagged packets can be forwarded to the manageability engine.
26 NET_TYPE
NET TYPE:
0b = pass only un-tagged packets.
1b = pass only VLAN tagged packets.
Valid only if FIXED_NET_TYPE is set.
31:27 Reserved Reserved.
Function Command Byte
Count Data 1 Data 2:4 5:10 Data 11 Data 12 Data 13 Data
14:17
Set Common
Filters 0xC2 17 Opcode = 0
Receive
Control -
see
Table 10-
14
MAC
Addres
s
MC Alert
Address Interface
Data Byte
Alert
Value
Byte
IPv4
Address
Ethernet Controller I210 —System Manageability
668
Function Command Byte
Count Data 1 Data 2:4 5:10 Data 11 Data 12 Data 13 Data
14:29
Set Common
Filters 0xC2 29 Opcode = 0
Receive
Control -
see
Table 10-
14
MAC
Addres
s
MC Alert
Address Interface
Data Byte
Alert
Value
Byte
IPv6
Address
Table 10-14. Set Common Filters Receive Control Bytes
Byte Bit Description Description
1
0 RCV_EN
Receive TCO Packets Enabled. When this bit is set it enables the receive
flow to the manageability block.
This bit should be set only if at least one of EN_BMC2O or EN_BMC2NET
bits are set.
1 EN_STA
Enable Status Reporting.
0b: Disable status reporting.
1b: Enable status reporting.
2 Auto ARP
Automatically respond to ARP packets. Ignored in IPv6 mode. If this bit
is set, broadcast ARP packets will be handled by the I210 and ARP
requests to the IP address set in the command will be responded.
Note: Mutually exclusive to Configure ARP/ Neighborhood Filter bit.
If this bit is set, the IP address must be valid.
This bit is ignored if RCV_EN is cleared.
3 Enable Xsum Filtering to MNG
When this bit is set, only packets that pass the L3 and L4 checksum are
send to the manageability block.
This bit is ignored if RCV_EN is cleared
4:5 Reserved
6:7 Notification Method
Notification Method. Define the notification method the I210 uses.
00b: SMBUS Alert.
01b: Asynchronous notify.
10b: Direct receive.
11b: Not supported.
System Manageability—Ethernet Controller I210
669
Note: If both bit 2 (AutoARP) and bit 12 (Configure ARP/ Neighborhood Filter) are set, the results
are unexpected.
2
8 CBDM
Configure the MC Dedicated MAC Address.
0b: The I210 shares the MAC address for MNG traffic with the host MAC
address, which is specified in Flash words 0x0-0x2.
1b: The I210 uses the MC dedicated MAC address as a filter for
incoming receive packets.
The MC MAC address is set in bytes 5-10 in this command.
This bit is ignored if RCV_EN is cleared
9 Configure IP Address Filter
Automatically configure an IP Address Filter. If this bit is set, only
packets matching this IP address will be forwarded. If the CBDM bit is
set, only packets matching the MAC and IP address will be forwarded.
This bit is ignored if RCV_EN is cleared
10 Configure RMCP 26Fh Filter
Automatically configure standard IPMI port 26Fh filters. If this bit is set,
only packets matching this port will be forwarded. If the CBDM/
Configure IP address Filter bits are set, only packets matching the MAC
and IP address and this port will be forwarded. The other port enable
bit (11) may add additional forwarding condition.
This bit is ignored if RCV_EN is cleared
11 Configure RMCP 298h Filter
Automatically configure standard IPMI port 298h filter. If this bit is set,
only packets matching this port will be forwarded. If the CBDM/
Configure IP address Filter bits are set, only packets matching the MAC
and IP address and this port will be forwarded. The other port enable
bit (10) may add additional forwarding condition.
This bit is ignored if RCV_EN is cleared
12 Configure ARP/ Neighborhood
Filter
Automatically Configure filters to allow this traffic to MC (mutually
exclusive to Auto ARP bit). If this bit is set, broadcast ARP packets will
be forwarded to MC.
In IPv4 mode, setting this bit will allow forwarding of broadcast ARP
request and response and unicast ARP response. If IP address is set,
only response to this address will be forwarded.
In IPv6 mode, setting this bit will allow forwarding of all types of
neighbor discovery and MLD ICMPv6 packet types:
0x86 (134d) - Router Advertisement.
0x87 (135d) - Neighbor Solicitation.
0x88 (136d) - Neighbor Advertisement.
0x89 (137d) - Redirect
0x82 (130d) - MLD Query
0x83 (131d) - MLDv1 Report
0x84 (132d) - MLD Done
0x8F (143d) - MLDv2 Report
13 Configure DHCP port 44h Filter
Automatically configure DHCP port 44 filter to MC. If this bit is set,
multicast packets matching this port will be forwarded. Otherwise,
multicast packets are not forwarded to the MC.
This bit is ignored if RCV_EN is cleared or in IPv6 mode.
15:14 Reserved
3
16 Disable Host ARP Configure ARP Requests and Network Neighborhood packets not to go
to host. This bit should be cleared in regular operation. Ignored if both
bit 12 and bit 2 are cleared or if RCV_EN is cleared.
17 Disable Host DHCP Configure DHCP packets (port 44h) not to go to host. This bit should be
cleared in regular operation. Ignored if bit 13 is cleared, RCV_EN is
cleared, or in IPv6 mode.
24:18 Reserved
Table 10-14. Set Common Filters Receive Control Bytes (Continued)
Byte Bit Description Description
Ethernet Controller I210 —System Manageability
670
10.5.9.1.8 Clear all Filters Command
The Clear all Filters command is a single fragment command capable of clearing all the receive filters
currently programmed for manageability traffic.
10.5.9.2 Read SMBus Transactions
This section details the pass-through read transactions that the MC can send to the I210 over SMBus.
SMBus read transactions lists the different SMBus read transactions supported by the I210. All the read
transactions are compatible with SMBus read block protocol format.
0xC0 or 0xD0 commands are used for more than one payload. If MC issues these read commands, and
the I210 has no pending data to transfer, it always returns as default opcode 0xDD with the I210 status
and does not NACK the transaction.
If an I2C quick read command is received, it is handled as a I210 Read Status command (See
Section 10.5.9.2.2 for details).
If a read command is received while the internal firmware is not ready, the following answer is
provided:
Function Command Byte Count Data
Clear all Filters 0xC3 1 0x00
Table 10-16. SMBus Read Transactions
TCO Command Transaction Command Opcode Fragments Section
Receive TCO Packet Block Read 0xD0 or 0xC0
First: 0x90
Middle: 0x10
Last1: 0x50
1. The last fragment of the receive TCO packet is the packet status.
Multiple 10.5.9.2.1
Read Status Block Read 0xD0 or 0xC0 or
0xDE Single: 0xDD Single 10.5.9.2.2
Get System MAC Address Block Read 0xD4 Single: 0xD4 Single 10.5.9.2.3
Read Management
Parameters Block Read 0xD1 Single: 0xD1 Single 10.5.9.2.4
Read Management RCV
Filter Parameters Block Read 0xCD Single: 0xCD Single 10.5.9.2.5
Read Receive Enable
Configuration Block Read 0xDA Single: 0xDA Single 10.5.9.2.6
Get Controller Information Block Read 0xD5 Single: 0xD5 Single 10.5.9.2.7
Get Common filters Block Read 0xD3 Single: 0xD3 Single 10.5.9.2.8
Byte Count Data 1 (Error Code)
1 0xFD
System Manageability—Ethernet Controller I210
671
The controller should retry the command later. It is recommended to wait 300 ms before retrying the
command.
10.5.9.2.1 Receive TCO LAN Packet Transaction
The MC uses this command to read packets received on the LAN and its status. When the I210 has a
packet to deliver to the MC, it asserts the SMBus notification for the MC to read the data (or direct
receive). Upon receiving notification of the arrival of a LAN receive packet, the MC begins issuing a
Receive TCO packet command using the block read protocol.
A packet can be transmitted to the MC in at least two fragments (at least one for the packet data and
one for the packet status). As a result, MC should follow the F and L bit of the op-code.
The op-code can have these values:
0x90 — First Fragment
0x10 — Middle Fragment
When the opcode is 0x50, this indicates the last fragment of the packet, which contains packet
status.
If a notification timeout is defined (in the Flash) and the MC does not finish reading the whole packet
within the timeout since the packet has arrived, the packet is silently discarded. The time spent in ARA
cycle or in reading the packet is not counted by the timeout counter.
Following is the receive TCO packet format and the data format returned from the I210.
10.5.9.2.1.1 Receive TCO LAN Status Payload Transaction
This transaction is the last transaction that the I210 issues when a packet received from the LAN is
transferred to the MC. The transaction contains the status of the received packet.
The format of the status transaction is as follows:
Function Command
Receive TCO Packet 0xC0 or 0xD0
Function Byte Count Data 1
(Op-Code) Data 2 Data N
Receive TCO First Fragment
N
0x90 Packet Data
Byte Packet Data
Byte
Receive TCO Middle
Fragment 0x10
Receive TCO Last Fragment 9 0x50 See Section 10.5.9.2.1.1
Function Byte Count Data 1 (Op-
Code) Data 2 – Data 17 (Status Data)
Receive TCO Long Status 9 0x50 See Below
Ethernet Controller I210 —System Manageability
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The status is 8 bytes where byte 0 (bits 7:0) is set in Data 2 of the status and byte 7 in Data 9 of the
status. Table 10-17 lists the content of the status data.
The meaning of the bits inside of each field can be found in Section 7.1.4.2.
10.5.9.2.2 Read Status Command
The MC should use this command after receiving a notification from the I210 (such as SMBus Alert).
The I210 also sends a notification to the MC in either of the following two cases:
The MC asserts a request for reading the status.
The I210 detects a change in one of the Status Data 1 bits (and was set to send status to the MC on
status change) in the Receive Enable command.
Note: Commands 0xC0/0xD0 are for backward compatibility and can be used for other payloads.
The I210 defines these commands in the opcode as well as which payload this transaction is.
When the 0XDE command is set, the I210 always returns opcode 0XDD with the I210 status.
The MC reads the event causing the notification, using the Read Status command as follows.
Table 10-17. TCO LAN Packet Status Data
Name Bits Description
Packet Length 13:0 Packet length including CRC, only 14 LSB bits.
Reserved 15:14 Reserved
Packet status 31:16 See Table 10-18
VLAN 47:32 The two bytes of the VLAN header tag.
MNG status 63:48 See Table 10-20. This field should be ignored if Receive TCO is not enabled,
Table 10-18. Packet Status Info
Field Bit(s) Description
Reserved 15:2 Reserved
VP 1
VLAN Stripped (indicates if the VLAN is part of the packet, or was
removed).
In the I210 this bit is always zero.
CRC stripped 0 Packet doesn’t include CRC.
In the I210 this bit is always one.
Table 10-20. MNG Status
Name Bits Description
Reserved 15:9 Reserved
Decision Filter match 8 Set when there is a match to one of the Decision filters
Decision Filter index 7:4
Indicates which of the decision filters match the packet.
(allows for up to 16 filters - although only 8 are currently
supported)
MNG VLAN Address Match 3 Set when the MNG packet matches one of the MNG VLAN
filters
Pass MNG VLAN Filter Index 2:0 Indicates which of the VLAN filters match the packet.
System Manageability—Ethernet Controller I210
673
The I210 response to one of the commands (0xC0 or 0xD0) in a given time as defined in the
SMBus Notification Timeout and Flags word in the Flash.
This command can also be executed using the I2C quick read format as follow:
Table 10-21 lists the status data byte 1 parameters.
Status data byte 2 is used by the MC to indicate whether the LAN device driver is alive and running.
The LAN device driver valid indication is a bit set by the LAN device driver during initialization; the bit is
cleared when the LAN device driver enters a Dx state or is cleared by the hardware on a PCI reset.
Function Command
Read Status 0XC0 or 0XD0 or 0XDE
Function Byte Count Data 1
(Op-Code)
Data 2
(Status
Data 1)
Data 3
(Status Data 2)
Receive TCO Partial Status 3 0XDD See Below
1 7 1 1 8 1 8 1 8 1 1
Start Slave Address Rd Ack Byte Count Ack Status Data 1 Ack Status Data 2 Ack Stop
10 0000 0002 0 0 1
Table 10-21. Status Data Byte 1
Bit Name Description
7 Reserved Always zero (indicates port number LSB in multi port devices)
6 TCO Command Aborted 1b = A TCO command abort event occurred since the last read status cycle.
0b = A TCO command abort event did not occur since the last read status cycle.
5 Link Status Indication 0b = LAN link down.
1b = LAN link up.
4 PHY Link Forced Up Contains the value of the PHY_Link_Up bit. When set, indicates that the PHY link is
configured to keep the link up.
3 Initialization Indication 0b = An Flash reload event has not occurred since the last Read Status cycle.
1b = An Flash reload event has occurred since the last Read Status cycle1.
1. This indication is asserted when the I210 manageability block reloads the Flash and its internal database is updated to the Flash
default values. This is an indication that the external MC should reconfigure the I210, if other values other than the Flash default
should be configured.
2 Reserved Always zero (indicates port number MSB in multi port devices)
1:0 Power State
00b = Dr state.
01b = D0u state.
10b = D0 state.
11b = D3 state.
Ethernet Controller I210 —System Manageability
674
Bits 2 and 1 indicate that the LAN device driver is stuck. Bit 2 indicates whether the interrupt line of the
LAN function is asserted. Bit 1 indicates whether the LAN device driver dealt with the interrupt line
before the last Read Status cycle. Table 10-22 lists status data byte 2.
Table 10-23 lists the possible values of bits 2 and 1 and what the MC can assume from the bits:
MC reads should consider the time it takes for the LAN device driver to deal with the interrupt (in s).
Note that excessive reads by the MC can give false indications.
10.5.9.2.3 Get System MAC Address Command
The Get System MAC Address returns the system MAC address over to the SMBus. This command is a
single-fragment Read Block transaction that returns the following the MAC address configured in RAL0,
RAH0 registers.
Get system MAC address format:
Data returned from the I210:
Table 10-22. Status Data Byte 2
Bit Name Description
7:5 Reserved Reserved.
4 Reserved Reserved
3 Driver Valid Indication 0b = LAN driver is not alive.
1b = LAN driver is alive.
2 Interrupt Pending Indication 1b = LAN interrupt line is asserted.
0b = LAN interrupt line is not asserted.
1Interrupt Cause Register (ICR0
Read/Write
1b = ICR register was read since the last read status cycle.
0b = ICR register was not read since the last read status cycle.
Reading the ICR indicates that the driver has dealt with the interrupt that was
asserted.
0 Reserved Reserved
Table 10-23. Status Data Byte 2 (Bits 2 and 1)
Previous Current Description
Don’t Care 00b Interrupt is not pending (OK).
00b 01b New interrupt is asserted (OK).
10b 01b New interrupt is asserted (OK).
11b 01b Interrupt is waiting for reading (OK).
01b 01b Interrupt is waiting for reading by the driver for more than one read cycle (not OK).
Possible drive hang state.
Don’t Care 11b Previous interrupt was read and current interrupt is pending (OK).
Don’t Care 10b Interrupt is not pending (OK).
Function Command
Get system MAC address 0xD4
System Manageability—Ethernet Controller I210
675
10.5.9.2.4 Read Management Parameters Command
In order to read the management parameters the MC should execute two SMBus transactions. The first
transaction is a block write that sets the parameter that the MC wants to read. The second transaction
is block read that reads the parameter.
Block write transaction:
Following the block write the MC should issue a block read that reads the parameter that was set in the
Block Write command:
Data returned:
The returned data is in the same format of the MC command.
The returned data is as follow:
Function Byte Count Data 1 (Op-Code) Data 2 Data 7
Get system MAC
address 7 0xD4 MAC address MSB MAC address LSB
Function Command Byte Count Data 1
Management control request 0xC1 1 Parameter number
Function Command
Read management parameter 0xD1
Function Byte Count Data 1 (Op-Code) Data 2 Data 3 Data N
Read management parameter N 0xD1 Parameter number Parameter dependent
Parameter # Parameter Data
Keep PHY Link Up 0x00
A single byte parameter:
Data 2 —
Bit 0 Set to indicate that the PHY link for this port should be kept up. Sets the
keep_PHY_link_up bit. When cleared, clears the keep_PHY_link_up bit.
Bit [7:1] Reserved.
Wrong parameter
request 0xFE Returned by the I210 only. This parameter is returned on read transaction, if in the previous
read command the MC sets a parameter that is not supported by the I210.
The I210 is not ready 0xFF
Returned by the I210 only, on read parameters command when the data that should have been
read is not ready. This parameter has no data. The MC should retry the read transaction.
This value is also returned if the byte count is illegal or if the read command is not preceded by
a write command.
Ethernet Controller I210 —System Manageability
676
The parameter that is returned might not be the parameter requested by the MC. The MC should verify
the parameter number (default parameter to be returned is 0x1).
If the parameter number is 0xFF, it means that the data that was requested from the I210 is not ready
yet.The MC should retry the read transaction.
It is responsibility of the MC to follow the procedure previously defined. When the MC sends a Block
Read command (as previously described) that is not preceded by a Block Write command with
bytecount=1, the I210 sets the parameter number in the read block transaction to be 0xFF.
10.5.9.2.5 Read Management Receive Filter Parameters Command
In order to read the management receive filter parameters, the MC should execute two SMBus
transactions. The first transaction is a block write that sets the parameter that the MC wants to read.
The second transaction is block read that read the parameter.
Block write transaction:
The different parameters supported for this command are the same as the parameters supported for
update Management receive filter parameters.
Following the block write the MC should issue a block read that reads the parameter that was set in the
Block Write command:
Data returned from the I210:
The parameter that is returned might not be the parameter requested by the MC. The MC should verify
the parameter number (default parameter to be returned is 0x1).
If the parameter number is 0xFF, it means that the data that was requested from the I210 should
supply is not ready yet. The MC should retry the read transaction.
It is MC responsibility to follow the procedure previously defined. When the MC sends a Block Read
command (as previously described) that is not preceded by a Block Write command with bytecount=1
or 2, the I210 sets the parameter number in the read block transaction to be 0xFF.
Function Command Byte Count Data 1 Data 2
Read MNG RCV filter parameters 0xCC 1 or 2 Parameter number Parameter data
Function Command
Request MNG RCV filter parameters 0xCD
Function Byte Count Data 1 (Op-
Code) Data 2 Data 3 Data N
Read MNG RCV filter parameters N 0xCD Parameter
number Parameter dependent
System Manageability—Ethernet Controller I210
677
10.5.9.2.6 Read Receive Enable Configuration Command
The MC uses this command to read the receive configuration data. This data can be configured when
using Receive Enable command or through the Flash.
Read Receive Enable Configuration command format (SMBus Read Block) is as follows:
Data returned from the I210:
Parameter # Parameter Data
Filters Enable 0x01 None
MNGONLY Configuration 0x0F None
Flex Filter Enable Mask and Length 0x10 None
Flex Filter Data 0x11
Data 2 — Group of Flex Filter’s Bytes:
0x0 = bytes 0-29
0x1 = bytes 30-59
0x2 = bytes 60-89
0x3 = bytes 90-119
0x4 = bytes 120-127
Decision Filters 0x61 This command is obsolete. Please use 0x68 instead.
VLAN Filters 0x62 One byte to define the accessed VLAN tag filter (MAVTV)
Data 2 — VLAN Filter number
Flex Ports Filters 0x63 One byte to define the accessed manageability flex port filter (MFUTP).
Data 2 — Flex Port Filter number
IPv4 Filter 0x64 One byte to define the accessed IPv4 address filter (MIPAF)
Data 2 — IPv4 address filter number
IPv6 Filters 0x65 One byte to define the accessed IPv6 address filter (MIPAF)
Data 2 — Pv6 address filter number
MAC Filters 0x66 One byte to define the accessed MAC address filters pair (MMAL, MMAH)
Data 2 — MAC address filters pair number (0 - 3)
EtherType Filters 0x67 1 byte to define Ethertype filters (METF)
Data 2 — METF filter index (valid values are 0 - 3)
Extended Decision Filter 0x68 1 byte to define the extended decisions filters (MDEF_EXT & MDEF)
Data 2 — MDEF filter index (valid values are 0 - 6)
Management Special Filter Modifiers 0x69 No data
Wrong parameter request 0xFE Returned by the I210 only. This parameter is returned on read transaction, if
in the previous read command the MC sets a parameter that is not supported
by the I210.
The I210 is not ready 0xFF
Returned by the I210 only, on read parameters command when the data that
should have been read is not ready. This parameter has no data.
This value is also returned if the byte count is illegal or if the read command is
not preceded by a write command.
Function Command
Read Receive Enable 0xDA
Function Byte
Count
Data 1
(Op-
Code)
Data 2 Data
3Data
8
Data
9Data
12
Data
13
Data
14
Data
15
Ethernet Controller I210 —System Manageability
678
The detailed description of each field is specified in the receive enable command description in
Section 10.5.9.1.3.
10.5.9.2.7 Get Controller Information Command
The MC uses this command to get the controller identification. In order to read the controller
information, the MC should execute two SMBus transactions. The first transaction is a block write that
sets the parameter that the MC wants to read. The second transaction is block read that read the
parameter.
Block write transaction:
Following the block write the MC should issue a block read that reads the parameter that was set in the
Block Write command:
Data returned from the I210:
Read
Receive
Enable
15
(0x0F) 0xDA Receive
Control
Byte
MAC
Addr
MSB MAC
Addr
LSB
IP
Addr
MSB IP
Addr
LSB
MC
SMBus
Addr
I/F
Data
Byte
Alert
Value
Byte
Function Command Byte Count Data 1
Get Controller Information 0xD5 1 Parameter number
Function Command
Get Controller Information 0xD5
Function Byte Count Data 1-
Command Data 2 (Op-Code) Data 3 -n
Get Controller Information Per Table 10-25 0xD5 Per Table 10-25 See Table 10-25 for the data
for each opcode
Table 10-25. Get Controller Information data
Opcode Byte Count Description Notes
0x00 5 Data 4:3: Device ID
Data 5: Silicon Revision (RevID)
This is the HW default value, not any value
programmed via Flash.
0x0B 4 Data 4:3 Flash Image version
0x0C 6 Data 6:3: Firmware ROM Internal
version
0x0D 6 Data 6:3: Firmware Flash Internal
version
System Manageability—Ethernet Controller I210
679
10.5.9.2.8 Get Common Filters Command
The MC uses this command to get the common filters setting. This data can be configured when using
Set Common Filters command. The first transaction is a block write that alerts that the MC wants to
read the filters configuration. The second transaction is block read that read the configuration.
Block write transaction:
Following the block write the MC should issue a block read that reads the filter settings:
Data returned from the I210:
0x0E 4 Data 4:3: PXE FW version
MajorVersion.MinorVersion.Build.SubBuild
0x0F 4 Data 4:3: iSCSI FW version
0x10 4 Data 4:3: uEFI FW version
0xFE 2 Wrong parameter request
Returned by the I210 only. This parameter is
returned on read transaction, if in the previous read
command the MC sets a parameter that is not
supported by the I210.
0xFF 2 The I210 is not ready
Returned by the I210 only, on read parameters
command when the data that should have been
read is not ready. This parameter has no data. The
MC should retry the read transaction.
This value is also returned if the byte count is illegal
or if the read command is not preceded by a write
command.
Function Command Byte count Data
Get Common Filters 0xD3 1 0x00
Function Command
Get Common filters 0xD3
Function Byte
Count Command Data 1 Data 2:4 5:10 Data 11 Data 12 Data 13 Data
14:17
Get Common
Filters 18 0xD3 0
Receive
Control -
see
Table 10-
14
MAC
Addres
s
MC Alert
Address Interface
Data Byte
Alert
Value
Byte
IPv4
Address
Table 10-25. Get Controller Information data
Ethernet Controller I210 —System Manageability
680
If case of error the following answers may be returned
This response is by the I210, on read common filter command when the data that should have been
read is not ready. This parameter has no data. The MC should retry the read transaction.
This value is also returned if the byte count is illegal or if the read command is not preceded by a write
command.
10.5.10 Example Configuration Steps
This section provides sample configuration settings for common filtering configurations. Three examples
are presented. The examples are in pseudo code format, with the name of the SMBus command
followed by the parameters for that command and an explanation.
10.5.10.1 Example 1 - Shared MAC, RMCP Only Ports
This example is the most basic configuration. The MAC address filtering is shared with the Host
operating system and only traffic directed the RMCP ports (26Fh & 298h) is filtered. For this example,
the MC must issue gratuitous ARPs because no filter is enabled to pass ARP requests to the MC.
10.5.10.1.1 Example 1 Pseudo Code
Step 1: Disable existing filtering
Receive Enable[00]
Utilizing the simple form of the Receive Enable command, this prevents any packets from
reaching the MC by disabling filtering:
Receive Enable Control 00h:
Bit 0 [0] – Disable Receiving of packets
Step 2: Configure MDEF[0]
Update Manageability Filter Parameters [68, 0, C0000000, 00000000]
Function Byte
Count Command Data 1 Data 2:4 5:10 Data 11 Data 12 Data 13 Data
14:29
Get Common
Filters 30 0xD3 0
Receive
Control -
see
Table 10-
14
MAC
Addres
s
MC Alert
Address Interface
Data Byte
Alert
Value
Byte
IPv6
Address
Function Command Byte
Count Data 1
Get Common
Filters 0xD3 1 0xFF
System Manageability—Ethernet Controller I210
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Use the Update Manageability Filter Parameters command to update Decision Filters (MDEF)
(parameter 68h). This will update MDEF[0], as indicated by the 2nd parameter (0).
MDEF[0] value of C0000000h:
Bit 30 [1] – port 298h
Bit 31 [1] – port 26Fh
MDEF_EXT[0] value of 0000000h:
Step 3: Configure MNGONLY
Update Manageability Filter Parameters [F, 0, 00000001]
Use the Update Manageability Filter Parameters command to update Manageability Only
(MNGONLY) (parameter Fh) so that port 298h and 26Fh would not be sent to the Host.
Bit [0] - MDEF[0] is exclusive to the MC.
Step 4: - Enable Filtering
Receive Enable [05]
Using the simple form of the Receive Enable command:
Receive Enable Control 05h:
Bit 0 [1] – Enable Receiving of packets
Bit 2 [1] – Enable status reporting (such as link lost)
Bit 5:4 [00] – Notification method = SMB Alert
Bit 7 [0] – Use shared MAC
The resulting MDEF filters are as follows:
Table 10-26. Example 1 MDEF Results
Manageability Decision Filter (MDEF)
Filter 0 1 2 3 4 5 6 7
L2 Exact Address[3:0] AND
Broadcast AND
Manageability VLAN[7:0] AND
IPv6 Address[3:0] AND
IPv4 Address[3:0] AND
L2 Exact Address[3:0] OR
Broadcast OR
Multicast AND
ARP Request OR
ARP Response OR
Neighbor Discovery OR
Port 0x298 OR X
Port 0x26F OR X
Flex Port 7:0 OR
Flex TCO OR
Ethernet Controller I210 —System Manageability
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10.5.10.2 Example 2 - Dedicated MAC, Auto ARP Response and RMCP Port
Filtering
This example shows a common configuration; the MC has a dedicated MAC and IP address. Automatic
ARP responses will be enabled as well as RMCP port filtering. By enabling Automatic ARP responses the
MC is not required to send the gratuitous ARPs as it did in Example 1.
For demonstration purposes, the dedicated MAC address will be calculated by reading the System MAC
address and adding 1 do it, assume the System MAC is AABBCCDC. The IP address for this example will
be 1.2.3.4. Additionally, the XSUM filtering will be enabled.
10.5.10.2.1 Example 2 - Pseudo Code
Step 1: Disable existing filtering
Receive Enable[00]
Utilizing the simple form of the Receive Enable command, this prevents any packets from
reaching the MC by disabling filtering:
Receive Enable Control 00h:
Bit 0 [0] – Disable Receiving of packets
Step 2: Read System MAC Address
Get System MAC Address []
Reads the System MAC address. Assume returned AABBCCDC for this example.
Step 3: Configure XSUM Filter
Update Manageability Filter Parameters [01, 00800000]
Use the Update Manageability Filter Parameters command to update Filters Enable settings
(parameter 1). This set the Manageability Control (MANC) Register.
MANC Register 00800000h:
Bit 23 [1] - XSUM Filter enable
Note that some of the following configuration steps manipulate the MANC register indirectly, this
command sets all bits except XSUM to 0. It is important to either do this step before the others,
or to read the value of the MANC and then write it back with only bit 32 changed. Also note that
the XSUM enable bit may differ between Ethernet Controllers, refer to product specific
documentation.
Step 4: Configure MDEF[0]
Update Manageability Filter Parameters [68, 0, C0000000]
Use the Update Manageability Filter Parameters command to update Decision Filters (MDEF)
(parameter 68h). This will update MDEF[0], as indicated by the 2nd parameter (0).
MDEF value of 00000C00h:
Bit 30 [1] – port 298h
Bit 31 [1] – port 26Fh
MDEF_EXT[0] value of 0000000h:
Step 5: Configure MDEF[1]
Update Manageability Filter Parameters [68, 1, 10000000, 00000000]
Use the Update Manageability Filter Parameters command to update Decision Filters (MDEF)
(parameter 68h). This will update MDEF[1], as indicated by the 2nd parameter (1).
System Manageability—Ethernet Controller I210
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MDEF value of 10000000:
Bit 28 [1] – ARP Requests
MDEF_EXT[0] value of 0000000h:
When Enabling Automatic ARP responses, the ARP requests still go into the manageability filtering
system and as such need to be designated as also needing to be sent to the Host. For this reason a
separate MDEF is created with only ARP request filtering enabled.
Refer to the next step for more details.
Step 6: Configure Manageability only
Update Manageability Filter Parameters [F, 0, 00000001]
Use the Update Manageability Filter Parameters command to update Manageability Only
(MNGONLY) (parameter Fh) so that port 298h and 26Fh would not be sent to the Host.
Bit [0] - MDEF[0] is exclusive to the MC.
This allows ARP requests to be passed to both manageability and to the Host. Specified separate
MDEF filter for ARP requests. If ARP requests had been added to MDEF[0] and then MDEF[0]
specified in Management Only configuration then not only would RMCP traffic (ports 26Fh and
298h) be sent only to the MC, ARP requests would have also been sent to the MC only.
Step 7: Enable Filtering
Receive Enable [8D, AABBCCDD, 01020304, 00, 00, 00]
Using the advanced version Receive Enable command, the first parameter:
Receive Enable Control 8Dh:
Bit 0 [1] – Enable Receiving of packets
Bit 2 [1] – Enable status reporting (such as link lost)
Bit 3 [1] – Enable Automatic ARP Responses
Bit 5:4 [00] – Notification method = SMB Alert
Bit 7 [1] - Use dedicated MAC
Second parameter is the MAC address (AABBCCDD).
Third Parameter is the IP address(01020304).
The last three parameters are zero when the notification method is SMB Alert.
The resulting MDEF filters are as follows:
Table 10-27. Example 2 MDEF Results
Manageability Decision Filter (MDEF)
Filter 0 1 2 3 4 5 6 7
L2 Exact Address[3:0] AND
Broadcast AND
Manageability VLAN[7:0] AND
IPv6 Address[3:0] AND
IPv4 Address[3:0] AND
L2 Exact Address[3:0] OR
Broadcast OR
Multicast AND
ARP Request OR X
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10.5.10.3 Example 3 - Dedicated MAC and IP Address
This example provided the MC with a dedicated MAC and IP address and allows it to receive ARP
requests. The MC is then responsible for responding to ARP requests.
For demonstration purposes, the dedicated MAC address will be calculated by reading the System MAC
address and adding 1 do it, assume the System MAC is AABBCCDC. The IP address for this example will
be 1.2.3.4. For this example, the Receive Enable command is used to configure the MAC address filter.
In order for the MC to be able to receive ARP Requests, it will need to specify a filter for this, and that
filter will need to be included in the Manageability To Host filtering so that the Host OS may also receive
ARP Requests.
10.5.10.3.1 Example 3 - Pseudo Code
Step 1: Disable existing filtering
Receive Enable[00]
Utilizing the simple form of the Receive Enable command, this prevents any packets from reaching
the MC by disabling filtering:
Receive Enable Control 00h:
Bit 0 [0] – Disable Receiving of packets
Step 2: Read System MAC Address
Get System MAC Address []
Reads the System MAC address. Assume returned AABBCCDC for this example.
Step 3: Configure IP Address Filter
Update Manageability Filter Parameters [64, 00, 01020304]
Use the Update Manageability Filter Parameters to configure an IPv4 filter.
The 1st parameter (64h) specifies that we are configuring an IPv4 filter.
The 2nd parameter (00h) indicates which IPv4 filter is being configured, in this case filter 0.
The 3rd parameter is the IP address – 1.2.3.4.
Step 4: Configure MAC Address Filter
Update Manageability Filter Parameters [66, 00, AABBCCDD]
Use the Update Manageability Filter Parameters to configure a MAC Address filter.
The 1st parameter (66h) specifies that we are configuring a MAC Address filter.
ARP Response OR
Neighbor Discovery OR
Port 0x298 OR X
Port 0x26F OR X
Flex Port 7:0 OR
Flex TCO OR
Table 10-27. Example 2 MDEF Results
Manageability Decision Filter (MDEF)
Filter 0 1 2 3 4 5 6 7
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The 2nd parameter (00h) indicates which MAC Address filter is being configured, in this case filter
0.
The 3rd parameter is the MAC Address - AABBCCDD
Step 5: Configure MDEF[0] for IP and MAC Filtering
Update Manageability Filter Parameters [68, 0, 00002001, 000000000]
Use the Update Manageability Filter Parameters command to update Decision Filters (MDEF)
(parameter 68h). This will update MDEF[0], as indicated by the 2nd parameter (0).
MDEF value of 00002001:
Bit 0 [1] – MAC[0] Address Filtering
Bit 13 [1] – IP[0] Address Filtering
MDEF_EXT[0] value of 0000000h:
Step 6: Configure MDEF[1]
Update Manageability Filter Parameters [68, 1, 10000000]
Use the Update Manageability Filter Parameters command to update Decision Filters (MDEF)
(parameter 68h). This will update MDEF[1], as indicated by the 2nd parameter (1).
MDEF value of 10000000:
Bit 28 [1] – ARP Requests
MDEF_EXT[0] value of 0000000h:
Step 7: Configure the Management to Host Filter
Update Manageability Filter Parameters [F, 0, 00000001]
Use the Update Manageability Filter Parameters command to update Manageability Only
(MNGONLY) (parameter Fh) so that the dedicated MAC/IP traffic would not be sent to the Host.
Note that given the Host will not program this address in its L2 filtering, this step is not a must,
unless the Host chooses to work in promiscuous mode.
Bit [0] - MDEF[0] is exclusive to the MC.
Step 8: Enable Filtering
Receive Enable [05]
Using the simple form of the Receive Enable command,:
Receive Enable Control 05h:
Bit 0 [1] – Enable Receiving of packets
Bit 2 [1] – Enable status reporting (such as link lost)
Bit 5:4 [00] – Notification method = SMB Alert
The resulting MDEF filters are as follows:
Table 10-28. Example 3 MDEF Results
Manageability Decision Filter (MDEF)
Filter 0 1 2 3 4 5 6 7
L2 Exact Address[3:0] AND 0001
Broadcast AND
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10.5.10.4 Example 4 - Dedicated MAC and VLAN Tag
This example shows an alternate configuration; the MC has a dedicated MAC and IP address, along with
a VLAN tag of 32h will be required for traffic to be sent to the MC. This means that all traffic with VLAN
a matching tag will be sent to the MC.
For demonstration purposes, the dedicated MAC address will be calculated by reading the System MAC
address and adding 1 do it, assume the System MAC is AABBCCDC. The IP address for this example will
be 1.2.3.4 and the VLAN tag will be 0032h.
Additionally, the XSUM filtering will be enabled.
10.5.10.4.1 Example 4 - Pseudo Code
Step 1: Disable existing filtering
Receive Enable[00]
Utilizing the simple form of the Receive Enable command, this prevents any packets from reaching
the MC by disabling filtering:
Receive Enable Control 00h:
Bit 0 [0] – Disable Receiving of packets
Step 2: - Read System MAC Address
Get System MAC Address []
Reads the System MAC address. Assume returned AABBCCDC for this example.
Step 3: Configure XSUM Filter
Update Manageability Filter Parameters [01, 00800000]
Use the Update Manageability Filter Parameters command to update Filters Enable settings
(parameter 1). This set the Manageability Control (MANC) Register.
MANC Register 00800000h:
Bit 23 [1] – XSUM Filter enable
Note: Some of the following configuration steps manipulate the MANC register indirectly, this
command sets all bits except XSUM to 0. It is important to either do this step before the
others, or to read the value of the MANC and then write it back with only bit 32 changed. Also
Manageability VLAN[7:0] AND
IPv6 Address[3:0] AND
IPv4 Address[3:0] AND 0001
L2 Exact Address[3:0] OR
Broadcast OR
Multicast AND
ARP Request OR X
ARP Response OR
Neighbor Discovery OR
Port 0x298 OR
Port 0x26F OR
Flex Port 7:0 OR
Flex TCO OR
Table 10-28. Example 3 MDEF Results
System Manageability—Ethernet Controller I210
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note that the XSUM enable bit may differ between Ethernet Controllers, refer to product
specific documentation.
Step 4: Configure VLAN 0 Filter
Update Manageability Filter Parameters [62, 0, 0032]
Use the Update Manageability Filter Parameters command to configure VLAN filters. Parameter 62h
indicates update to VLAN Filter, the 2nd parameter indicates which VLAN filter (0 in this case), the
last parameter is the VLAN ID (0032h).
Step 5: Configure MDEF[0]
Update Manageability Filter Parameters [68, 0, 00000020]
Use the Update Manageability Filter Parameters command to update Decision Filters (MDEF)
(parameter 68h). This will update MDEF[0], as indicated by the 2nd parameter (0).
MDEF value of 00000020:
Bit 5 [1] – VLAN[0] AND
MDEF_EXT[0] value of 0000000h:
Step 6: Enable Filtering
Receive Enable [85, AABBCCDD, 01020304, 00, 00, 00]
Using the advanced version Receive Enable command, the first parameter:
Receive Enable Control 85h:
Bit 0 [1] – Enable Receiving of packets
Bit 2 [1] – Enable status reporting (such as link lost)
Bit 5:4 [00] – Notification method = SMB Alert
Bit 7 [1] – Use Dedicated MAC
Second parameter is the MAC address: AABBCCDD.
Third Parameter is the IP address: 01020304.
The last three parameters are zero when the notification method is SMBus Alert.
The resulting MDEF filters are as follows:
Table 10-29. Example 4 MDEF Results
Manageability Decision Filter (MDEF)
Filter 0 1 2 3 4 5 6 7
L2 Exact Address[3:0] AND 0001
Broadcast AND
Manageability VLAN[7:0] AND X
IPv6 Address[3:0] AND
IPv4 Address[3:0] AND
L2 Exact Address[3:0] OR
Broadcast OR
Multicast AND
ARP Request OR
ARP Response OR
Neighbor Discovery OR
Port 0x298 OR
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10.6 NC-SI Pass Through Interface
The Network Controller Sideband Interface (NC-SI) is a DMTF industry standard protocol for the
sideband interface. NC-SI uses a modified version of the industry standard RMII interface for the
physical layer as well as defining a new logical layer.
The NC-SI specification can be found at:
http://www.dmtf.org/
10.6.1 Overview
10.6.1.1 Terminology
The terminology in this document is taken from the NC-SI specification.
Port 0x26F OR
Flex Port 7:0 OR
Flex TCO OR
Table 10-30. NC-SI Terminology
Term Definition
Frame Versus Packet Frame is used in reference to Ethernet, whereas packet is used everywhere else.
External Network Interface The interface of the network controller that provides connectivity to the external network
infrastructure (port).
Internal Host Interface The interface of the network controller that provides connectivity to the Host OS running on
the platform.
Management Controller (BMC) An intelligent entity comprising of HW/FW/SW, that resides within a platform and is
responsible for some or all management functions associated with the platform (BMC,
service processor, etc.).
Network Controller (NC) The component within a system that is responsible for providing connectivity to the external
Ethernet network world.
Remote Media The capability to allow remote media devices to appear as if they were attached locally to the
Host.
Network Controller Sideband
Interface The interface of the network controller that provides connectivity to a management
controller. It can be shorten to sideband interface as appropriate in the context.
Interface This refers to the entire physical interface, such as both the transmit and receive interface
between the management controller and the network controller.
Integrated Controller
The term integrated controller refers to a network controller device that supports two or
more channels for NC-SI that share a common NC-SI physical interface. For example, a
network controller that has two or more physical network ports and a single NC-SI bus
connection.
Multi-Drop
Multi-drop commonly refers to the case where multiple physical communication devices
share an electrically common bus and a single device acts as the master of the bus and
communicates with multiple slave or target devices. In NC-SI, a management controller
serves the role as the master, and the network controllers are the target devices.
Table 10-29. Example 4 MDEF Results
Manageability Decision Filter (MDEF)
Filter 0 1 2 3 4 5 6 7
System Manageability—Ethernet Controller I210
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10.6.1.2 System Topology
In NC-SI each physical endpoint (NC package) can have several logical slaves (NC channels).
NC-SI defines that one management controller and up to four network controller packages can be
connected to the same NC-SI link.
Point-to-Point
Point-to-point commonly refers to the case where only two physical communication devices
are interconnected via a physical communication medium. The devices might be in a master/
slave relationship, or could be peers. In NC-SI, point-to-point operation refers to the
situation where only a single management controller and single network controller package
are used on the bus in a master/slave relationship where the management controller is the
master.
Channel The control logic and data paths supporting NC-SI pass-through operation on a single
network interface (port). A network controller that has multiple network interface ports can
support an equivalent number of NC-SI channels.
Package
One or more NC-SI channels in a network controller that share a common set of electrical
buffers and common buffer control for the NC-SI bus. Typically, there will be a single, logical
NC-SI package for a single physical network controller package (chip or module). However,
the specification allows a single physical chip or module to hold multiple NC-SI logical
packages.
Control Traffic/Messages/Packets Command, response and notification packets transmitted between the BMC and the I210 for
the purpose of managing NC-SI.
Pass-Through Traffic/Messages/
Packets Non-control packets passed between the external network and the BMC through the I210.
Channel Arbitration
Refer to operations where more than one of the network controller channels can be enabled
to transmit pass-through packets to the BMC at the same time, where arbitration of access
to the RXD, CRS_DV, and RX_ER signal lines is accomplished either by software of hardware
means.
Logically Enabled/Disabled NC Refers to the state of the network controller wherein pass-through traffic is able/unable to
flow through the sideband interface to and from the management controller, as a result of
issuing Enable/Disable Channel command.
NC RX Defined as the direction of ingress traffic on the external network controller interface
NC TX Defined as the direction of egress traffic on the external network controller interface
NC-SI RX Defined as the direction of ingress traffic on the sideband enhanced NC-SI Interface with
respect to the network controller.
NC-SI TX Defined as the direction of egress traffic on the sideband enhanced NC-SI Interface with
respect to the network controller.
Table 10-30. NC-SI Terminology
Term Definition
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Figure 10-4 shows an example topology for a single BMC and a single NC package. In this example, the
NC package has two NC channels.
Figure 10-5 shows an example topology for a single BMC and two NC packages. In this example, one
NC package has two NC channels and the other has only one NC channel. Scenarios in which the NC-SI
lines are shared by multiple NCs (Figure 10-5) mandate an arbitration mechanism.
Figure 10-4. Single NC Package, Two NC Channels
Figure 10-5. Two NC Packages (Left, with Two NC Channels and Right, with One NC Channel)
NC Package
Package ID = 0x0
NC Channel
Internal
ChannelID=0x0
NC Channel
Internal
ChannelID=0x1
Management Controller
(
MC
)
LAN0 LAN1
NC-SI Link
NC Package
Package ID = 0x0
NC Channel
Internal
ChannelID=0x0
NC Channel
Internal
ChannelID=0x1
Management Controller
(
MC
)
LAN0 LAN1
NC Package
Package ID = 0x1
NC Channel
Internal
ChannelID=0x0
LAN
NC-SI Link
System Manageability—Ethernet Controller I210
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10.6.1.3 Data Transport
Since NC-SI is based upon the RMII transport layer, data is transferred in the form of Ethernet frames.
NC-SI defines two types of transmitted frames:
1. Control frames:
a. Configures and control the interface
b. Identified by a unique EtherType in their L2 header
2. Pass-through frames:
a. Actual LAN pass-through frames transferred from/to the BMC
b. Identified as not being a control frame
c. Attributed to a specific NC channel by their source MAC address (as configured in the NC by the
BMC)
10.6.1.3.1 Control Frames
NC-SI control frames are identified by a unique NC-SI EtherType (0x88F8).
Control frames are used in a single-threaded operation, meaning commands are generated only by the
BMC and can only be sent one at a time. Each command from the BMC is followed by a single response
from the NC (command-response flow), after which the BMC is allowed to send a new command.
The only exception to the command-response flow is the Asynchronous Event Notification (AEN). These
control frames are sent unsolicited from the NC to the BMC.
AEN functionality by the NC must be disabled by default, until activated by the BMC using the Enable
AEN commands.
In order to be considered a valid command, a control frame must:
1. Comply with the NC-SI header format.
2. Be targeted to a valid channel in the package via the Package ID and Channel ID fields. For
example, to target a NC channel with package ID of 0x2 and internal channel ID of 0x5, the BMC
must set the channel ID inside the control frame to 0x45. The channel ID is composed of three bits
of package ID and five bits of internal channel ID.
3. Contain a correct payload checksum (if used).
4. Meet any other condition defined by NC-SI.
There are also commands (such as select package) targeted to the package as a whole. These
commands must use an internal channel ID of 0x1F.
Ethernet Controller I210 —System Manageability
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For details, refer to the NC-SI specification.
10.6.1.3.2 NC-SI Frames Receive Flow
Figure 10-6 shows the flow for frames received on the NC from the BMC.
10.6.2 Supported Features
The I210 supports all the mandatory features of the NC-SI specification (rev 1.0.0). Table 10-31 lists
the supported commands.
Note: If an unsupported command is received, an error is returned with a response = Unsupported
(0x3) and reason = UNKNOWN_COMMAND (0x7ff).
Table 10-32 lists optional features supported.
Figure 10-6. NC-SI Frames Receive Flow for the NC
Table 10-31. Supported NC-SI Commands
Command Supported over
NC-SI
Supported over
MCTP with Pass
Through
Supported over MCTP
without Pass
Through
Clear initial state Yes Yes Yes
Get Version ID Yes Yes Yes
Get Parameters Yes Yes Yes
Get Controller Packet Statistics Yes, partially Yes, partially Yes, partially
Get Link Status Yes Yes Yes
NC-SI frame
received from MC
EtherType ==
NC-SI EtherType?
Process as NC-SI Control Frame Yes
Source MAC address ==
previously configured MAC
address?
No
Send to LAN with matching
configured MAC address Yes
No
Drop frame (belongs to a
different Package)
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Enable Channel Yes Yes Yes
Disable Channel Yes Yes Yes
Reset Channel Yes Yes Yes
Enable VLAN Yes1 Yes1No2
Disable VLAN Yes Yes No2
Enable Broadcast Filter Yes Yes No2
Disable Broadcast Filter Yes Yes No2
Set MAC Address Yes Yes No2
Get NC-SI Statistics Yes Yes Yes, partially
Set NC-SI Flow-Control Yes No No2
Set Link Command Yes3,4 Yes3,4Yes
Enable Global multicast Filter Yes Yes No2
Disable Global multicast Filter Yes Yes No2
Get Capabilities Yes Yes Yes
Set VLAN Filters Yes Yes No2
AEN Enable Yes Yes Yes
Get NC-SI Pass-Through Statistics Yes, partially Yes, partially No2
Select Package Yes Yes No
Deselect Package Yes Yes No
Enable Channel Network TX Yes Yes No
Disable Channel Network TX Yes Yes No
OEM Command5Yes Yes Yes
1. The I210 does not support filtering of User priority/CFI Bits of VLAN
2. In MCTP without pass through mode, only control commands are supported and not pass through traffic - thus many of
the regular NC-SI commands are not supported or are supported in a limited manner, only to allow control and status
reporting for the device.
3. When working with SGMII interface, this command is not supported.
4. When one of the LAN devices is assigned for the sole use of the manageability and its LAN PCI-E function is disabled, using
the NC-SI Set Link command while advertising multiple speeds and enabling Auto-Negotiation, will result in the lowest
possible speed chosen. To enable higher link speed, the MC should not advertise speeds that are below the desired link
speed. When doing it, changing the power state of the LAN device will have no effect and the link speed will not be re-
negotiated.
5. See Section 10.6.2.4 for details.
Table 10-32. Optional NC-SI Features Support
Feature Implement Details
AENs Yes The Driver state AEN may be emitted up to 15 sec.
after actual driver change.
Get Controller Packet Statistics
command Yes, partially Supports the following counters 1:
2-9,13-182
Get NC-SI statistics Yes All counters are supported
Get NC-SI Pass-Through Statistics Yes, partially Support the following counters:
1, 2, 6, 7.
VLAN Modes Yes, partially Support only modes 1, 3.
Buffering Capabilities Yes 8176 bytes
Table 10-31. Supported NC-SI Commands
Command Supported over
NC-SI
Supported over
MCTP with Pass
Through
Supported over MCTP
without Pass
Through
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10.6.2.1 Set Link Error Codes
The following rules are used to define the error code returned for Set Link command in case an invalid
configuration is requested:
1. Host Driver Check: If host device driver is present, return a Command Specific Response (0x9) with
a Set Link Host OS/Driver Conflict Reason (0x1).
2. Speed Present Check: If no speed is selected, return a General Reason Code for a failed command
(0x1) with Parameter Is Invalid, Unsupported, or Out-of-Range Reason (0x2).
3. Parameter Validity:
a. Auto Negotiation Parameter Validation: If Auto Negotiation is requested and none of the selected
parameters are valid for the device, return a General Reason Code for a failed command (0x1)
with a Parameter Is Invalid, Unsupported, or Out-of-Range Reason (0x2).
Note: This means that, for example, a command requesting 10G on a 1G device will succeed
provided that the command requests at least one other supported speed. The same goes for
an unsupported duplex setting (a device with no HD support will accept a command with both
FD and HD set), and also for HD being requested with speeds of 1G and higher as long as a
speed below 1G is also requested (and is supported in HD). The device will simply ignore the
unsupported parameters.
b. Force Mode Parameter Validation:
1. If more than one link speed is being forced, then return a a General Reason Code for a failed
command (0x1) and a Command Specific Reason with a Set Link Speed Conflict Error
(0x0905).
2. If more than one duplex setting is being forced, then return a General Reason Code for a
failed command (0x1) with Parameter Is Invalid, Unsupported, or Out-of-Range Reason
(0x2).
3. If 1G and above is requested with HD, then return a a General Reason Code for a failed
command (0x1) and a Command Specific Reason with Set Link Parameter Conflict Error
(0x0903).
4. Media Type Compatibility Check: If current media type is not compatible for the requested link
parameters, return a a General Reason Code for a failed command (0x1) and a Command Specific
Reason with Set Link Media Conflict Error (0x0902).
MAC Address Filters Yes Supports 2 mixed MAC addresses.
Channel Count Yes Supports 1 channels.
VLAN Filters Yes
Support 8 VLAN filters.
Filtering is ignoring the CFI bit and the 802.1P priority
bits
Broadcast Filters Yes
Support the following filters:
ARP
DHCP
Net BIOS
Multicast Filters Yes
Supports the following filters:
IPv6 Neighbor Advertisement
IPv6 Router Advertisement
DHCPv6 relay and server multicast
Hardware Arbitration Yes Supports NC-SI HW arbitration.
1. TCTL.EN should be set to 1b to activate TX related counters and RCTL.RXEN, MANC.RCV_EN or WUC.APME should be set to enable
RX related counters.
2. As described in the Get Controller Packet Statistics Counter Numbers table in NC-SI spec.
Table 10-32. Optional NC-SI Features Support
Feature Implement Details
System Manageability—Ethernet Controller I210
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5. Power State Compatibility Check: If current power state does not allow for the requested link
parameters, return a a General Reason Code for a failed command (0x1) and a Command Specific
Reason with Set Link Power Mode Conflict Reason (0x0904).
6. If for some reason the hardware cannot perform the flow required for the command, return a a
General Reason Code for a failed command (0x1) and a Command Specific Reason with Link
Command Failed-Hardware Access Error (0x0906).
10.6.2.2 NC-SI PHY Power Down Conditions
In NC-SI mode, the device may dynamically change the PHY power mode according to the NC-SI
channel state assuming no other functionality requires the PHY to be active (host, proxy or wakeup).
The following algorithm is used to define if PHY activity is required:
At init time, if the manageability mode is NC-SI, PHY is required to be active only if the Enable All
PHYs in D3 N bit in Common Firmware Parameters Flash word is set.
Once a channel is enabled via Enable Channel NC-SI command, The PHY is powered up.
If the Channel is disabled either through a Disable Channel command with ALD bit set or via a Reset
Channel command, the PHY power state is set back to the init value as define by the All PHYs in D3
N bit.
10.6.2.3 Error Conditions
In some cases, the I210 may not be ready to react to a received NC-SI command. In these cases, a
response with a Command Failed (0x1) response code and a Package Not Ready (0x0004) reason code.
In this case, it is recommended to wait 300 ms before retrying the command.
10.6.2.4 AEN Handling
Asynchronous events may occur when the device is not allowed to send them. The following rules
defines the behavior of the I210 in these cases:
1. While the device is disabled, for each type of AEN only the last event is kept
2. Outstanding AENs that occurred while package was deselected will be transmitted when package is
selected.
3. On a transition from Channel Disabled to Channel Enabled, all outstanding event are erased to
prevent stale events notifications.
10.6.3 NC-SI Mode — Intel OEM Commands
In addition to regular NC-SI commands, the following Intel vendor specific commands are supported
(OEM command 0x50 with IANA = 0x157). The purpose of these commands is to provide a means for
the MC to access some of the Intel-specific features present in the I210.
10.6.3.1 Overview
The following features are available via the NC-SI OEM specific commands:
Receive filters:
Packet Addition Decision Filters 0x0…0x4
Packet Reduction Decision Filters 0x5…0x7
MNGONLY register (controls the forwarding of manageability packets to the Host)
Ethernet Controller I210 —System Manageability
696
Flex 128 filter
Flex TCP/UDP port filters 0x0...0xA
IPv4/IPv6 filters
Get System MAC Address — This command enables the MC to retrieve the system MAC address
used by the NC. This MAC address can be used for a shared MAC address mode.
Keep PHY Link Up (Veto bit) Enable/Disable — This feature enables the MC to block PHY reset,
which might cause session loss.
TCO Reset — Enables the MC to reset the I210.
Checksum offloading — Offloads IP/UDP/TCP checksum checking from the MC.
OS2BMC control commands.
Firmware Versions Command
Shared MAC and shared IP commands.
These commands are designed to be compliant with their corresponding SMBus commands (if existing).
All of the commands are based on a single DMTF defined NC-SI command, known as OEM Command.
This command is as follows.
10.6.3.1.1 OEM Command (0x50)
The OEM command can be used by the MC to request the sideband interface to provide vendor-specific
information.
10.6.3.1.2 OEM Response (0xD0)
Note: Responses have no command-specific reason code, unless otherwise specified within the
command.
Bits
Bytes 31:24 23:16 15:08 07:00
00...15 NC-SI Header
16...19 Manufacturer ID (Intel 0x157)
20... Intel Command Number Index (optional) Optional Data
Bits
Bytes 31:24 23:16 15:08 07:00
00...15 NC-SI Header
16...19 Response Code Reason Code
20...23 Manufacturer ID (Intel 0x157)
24...27 Intel Command Number Index (optional) Optional Data
System Manageability—Ethernet Controller I210
697
10.6.3.2 Intel OEM Commands Summary
Table 10-33. Intel OEM Specific Command Response and Reason Codes
Response Code Reason Code
Value Description Value Description
0x1 Command Failed
0x5081 Invalid Intel Command Number
0x5082 Invalid Intel Command Parameter Number
0x5087 Invalid Driver State
0x5088 Invalid Flash
0x508D Returned when one of the shared IP commands is received with an out of
range resource (IP, port, binding) index.
0x508E Returned when a request to disable a port used in a active binding is
received.
0x5090 Returned when a binding of a non enabled resource (MAC, VLAN, IP
address, port) is required.
0x5091 Returned when the Set Port command is received with an unsupported
protocol.
0x5092 Not is Shared Mode. Returned when shared mode commends are used
while not in shared MAC/IP mode.
0x008E Returned when a request to disable a VLAN or a MAC address used in an
active binding is received.
Table 10-34. Intel OEM Commands Summary
Intel Command Parameter Command Name
0x00 0x00 Set IP Filters Control
0x01 0x00 Get IP Filters Control
0x02
0x0F Set Manageability Only
0x10 Set Flexible 128 Filter Mask and Length
0x11 Set Flexible 128 Filter Data
0x61 Set Packet Addition Filters (obsolete)
0x63 Set Flex TCP/UDP Port Filters
0x64 Set Flex IPv4 Address Filters
0x65 Set Flex IPv6 Address Filters
0x67 Set EtherType Filter
0x68 Set Packet Addition Extended Filter
0x69 Set Special Modifiers Filter
0x03
0x0F Get Manageability Only
0x10 Get Flexible 128 Filter Mask and Length
0x11 Get Flexible 128 Filter Data
0x61 Get Packet Addition Filters (obsolete)
0x63 Get Flex TCP/UDP Port Filters
0x64 Get Flex IPv4 Address Filters
0x65 Get Flex IPv6 Address Filters
0x67 Get EtherType Filter
0x68 Get Packet Addition Extended Filter
0x69 Get Special Modifiers filter
Ethernet Controller I210 —System Manageability
698
Note: All the commands are supported both over NC-SI and over MCTP with pass through.
Note: If an unsupported command is received, an error is returned with a response = Unsupported
(0x3) and reason = Invalid Intel Command Number (0x5081).
0x04
0x00 Set Unicast Packet Reduction (obsolete)
0x01 Set Multicast Packet Reduction (obsolete)
0x02 Set Broadcast Packet Reduction (obsolete)
0x10 Set Extended Unicast Packet Reduction
0x11 Set Extended Multicast Packet Reduction
0x12 Set Extended Broadcast Packet Reduction
0x05
0x00 Get Unicast Packet Reduction (obsolete)
0x01 Get Multicast Packet Reduction (obsolete)
0x02 Get Broadcast Packet Reduction (obsolete)
0x10 Get Extended Unicast Packet Reduction
0x11 Get Extended Multicast Packet Reduction
0x12 Get Extended Broadcast Packet Reduction
0x06 N/A Get System MAC Address
0x20 N/A Set Intel Management Control
0x21 N/A Get Intel Management Control
0x22 N/A Perform TCO Reset
0x23 N/A Enable IP/UDP/TCP Checksum Offloading
0x24 N/A Disable IP/UDP/TCP Checksum Offloading
0x25
0x0 Set IP Address
0x1 Get IP Address
0x2 Set Port
0x3 Get Port
0x4 Enable Unicast Infrastructure Filter
0x5 Get Shared IP Capabilities Command
0x6 Shared IP Enable Broadcast filtering
0x7 Shared IP Enable Global Multicast filtering
0x8 Get Shared IP parameters
0x9 Set Binding
0xA Get Binding
0xB Set Shared Mode
0x40
0x01 Enable OS2BMC flow
0x02 Enable Network to MC flow
0x03 Enable Both Network to MC and Host to MC flow
0x41 N/A Get OS2BMC parameters
0x48 0x1 Get Controller information
Table 10-34. Intel OEM Commands Summary
Intel Command Parameter Command Name
System Manageability—Ethernet Controller I210
699
10.6.3.3 Set Intel Filters Control IP Filters Control Command (Intel Command
0x00, Filter Control Index 0x00)
This command controls different aspects of the Intel filters.
Where “IP Filters Control” has the following format.
Note: When using shared MAC and shared IP commands (Section 10.6.3.14), the IPv4 mode should
be enabled.
10.6.3.3.1 Set Intel Filters Control — IP Filters Control Response (Intel Command 0x00,
Filter Control Index 0x00)
10.6.3.4 Get Intel Filters Control Commands (Intel Command 0x01)
10.6.3.4.1 Get Intel Filters Control — IP Filters Control Command (Intel Command 0x01,
Filter Control Index 0x00)
This command reflects different aspects of the Intel filters.
Bits
Bytes 31:24 23:16 15:08 07:00
00...15 NC-SI Header
16...19 Manufacturer ID (Intel 0x157)
20...23 0x00 0x00 IP Filters control (3-2)
24...25 IP Filters Control (1-0)
Table 10-35. IP Filters Control
Bit # Name Description Default Value
0 IPv4/IPv6 Mode
IPv6 (0b): There are zero IPv4 filters and
four IPv6 filters
IPv4 (1b): There are four IPv4 filters and
three IPv6 filters.
See Section 8.22.9 or Section 10.3.3.7 for
details.
1b
1...31 Reserved
Bits
Bytes 31:24 23:16 15:08 07:00
00...15 NC-SI Header
16...19 Response Code Reason Code
20...23 Manufacturer ID (Intel 0x157)
24...27 0x00 0x00
Bits
Bytes 31:24 23:16 15:08 07:00
Ethernet Controller I210 —System Manageability
700
10.6.3.4.2 Get Intel Filters Control — IP Filters Control Response (Intel Command 0x01,
Filter Control Index 0x00)
IP Filter Control: See Table 10-35.
10.6.3.5 Set Intel Filters Formats
10.6.3.5.1 Set Intel Filters Command (Intel Command 0x02)
10.6.3.5.2 Set Intel Filters Response (Intel Command 0x02)
10.6.3.5.3 Set Intel Filters — Manageability Only Command (Intel Command 0x02, Filter
Parameter 0x0F)
This command sets the MNGONLY register. The MNGONLY register controls whether pass-through
packets destined to the MC are not forwarded to the Host OS. The MNGONLY register structure is
described in Table 10-5.
00...15 NC-SI Header
16...19 Manufacturer ID (Intel 0x157)
20...21 0x01 0x00
Bits
Bytes 31:24 23:16 15:08 07:00
00...15 NC-SI Header
16...19 Response Code Reason Code
20...23 Manufacturer ID (Intel 0x157)
24...27 0x01 0x00 IP Filters Control (3-2)
28...29 IP Filters Control (1-0)
Bits
Bytes 31:24 23:16 15:08 07:00
00...15 NC-SI Header
16...19 Manufacturer ID (Intel 0x157)
20...21 0x02 Parameter Number Filters Data (optional)
Bits
Bytes 31:24 23:16 15:08 07:00
00...15 NC-SI Header
16...19 Response Code Reason Code
20...23 Manufacturer ID (Intel 0x157)
24... 0x02 Filter Control Index Return Data (Optional)
System Manageability—Ethernet Controller I210
701
10.6.3.5.4 Set Intel Filters — Manageability Only Response (Intel Command 0x02, Filter
Parameter 0x0F)
10.6.3.5.5 Set Intel Filters — Flex Filter Enable Mask and Length Command (Intel
Command 0x02, Filter Parameter 0x10)
The following command sets the Intel flex filters mask and length. See Section 10.3.3.6 for details of
the programming.
10.6.3.5.6 Set Intel Filters — Flex Filter Enable Mask and Length Response (Intel
Command 0x02, Filter Parameter 0x10)
Bits
Bytes 31:24 23:16 15:08 07:00
00...15 NC-SI Header
16...19 Manufacturer ID (Intel 0x157)
20...23 0x02 0x0F Manageability Only (3-2)
24...25 Manageability Only (1-0)
Bits
Bytes 31:24 23:16 15:08 07:00
00...15 NC-SI Header
16...19 Response Code Reason Code
20...23 Manufacturer ID (Intel 0x157)
24...25 0x02 0x0F
Bits
Bytes 31:24 23:16 15:08 07:00
00...15 NC-SI Header
16...19 Manufacturer ID (Intel 0x157)
20...23 0x02 0x10 Mask Byte 1 Mask Byte 2
24...27 ... ... ... ...
28...31 ... ... ... ...
32...35 ... ... ... ...
36...37 ... Mask Byte 16 Reserved Reserved
38 Length
Bits
Bytes 31:24 23:16 15:08 07:00
00...15 NC-SI Header
16...19 Response Code Reason Code
20...23 Manufacturer ID (Intel 0x157)
24...25 0x02 0x10
Ethernet Controller I210 —System Manageability
702
10.6.3.5.7 Set Intel Filters — Flex Filter Data Command (Intel Command 0x02, Filter
Parameter 0x11)
The Filter Data Group parameter defines which bytes of the Flex filter are set by this command:
Note: Using this command to configure the filters data must be done after the flex filter mask
command is issued and the mask is set.
10.6.3.5.8 Set Intel Filters — Flex Filter Data Response (Intel Command 0x02, Filter
Parameter 0x11)
Note: If Filter Data Length is larger than specified in Table 10-36 an Out of Range Reason code is
returned.
10.6.3.5.9 Set Intel Filters — Packet Addition Decision Filter Command (Intel Command
0x02, Filter Parameter 0x61)
This command is not supported anymore. Use the Set Intel Filters - Packet Addition Extended Decision
Filter Command (Intel Command 0x02, Filter parameter 0x68 - Section 10.6.3.5.18) instead.
Bits
Bytes 31:24 23:16 15:08 07:00
00...15 NC-SI Header
16...19 Manufacturer ID (Intel 0x157)
20... 0x02 0x11 Filter Data Group Filter Data 1
... Filter Data N
Table 10-36. Filter Data Group
Code Bytes
programmed
Filter Data
Length
0x0 bytes 0-29 1 - 30
0x1 bytes 30-59 1 - 30
0x2 bytes 60-89 1 - 30
0x3 bytes 90-119 1 - 30
0x4 bytes 120-127 1 - 8
Bits
Bytes 31:24 23:16 15:08 07:00
00...15 NC-SI Header
16...19 Response Code Reason Code
20...23 Manufacturer ID (Intel 0x157)
24...25 0x02 0x11
System Manageability—Ethernet Controller I210
703
10.6.3.5.10 Set Intel Filters — Flex TCP/UDP Port Filter Command (Intel Command 0x02,
Filter Parameter 0x63)
Filter index range: 0x0...0xA.
If the filter index is bigger than 2, a command failed Response Code is returned with Invalid Intel
Parameter Number reason (0x5082).
Port flags is described below:
Bit 0: Match UDP ports
Bit 1: Match TCP ports
Bit 2: Match Destination port (0) or Source Port (1).
Bit 7:3: Reserved
If flags is not present (payload length = 9), the match is done on TCP and UDP destination ports (legacy
behavior).
10.6.3.5.11 Set Intel Filters — Flex TCP/UDP Port Filter Response (Intel Command 0x02,
Filter Parameter 0x63)
10.6.3.5.12 Set Intel Filters IPv4 Filter Command (Intel Command 0x02, Filter Parameter
0x64)
Bits
Bytes 31:24 23:16 15:08 07:00
00...15 NC-SI Header
16...19 Manufacturer ID (Intel 0x157)
20...23 0x02 0x63 Port filter index TCP/UDP Port MSB
24 TCP/UDP Port LSB Port flags
Bits
Bytes 31:24 23:16 15:08 07:00
00...15 NC-SI Header
16...19 Response Code Reason Code
20...23 Manufacturer ID (Intel 0x157)
24...25 0x02 0x63
Bits
Bytes 31:24 23:16 15:08 07:00
00...15 NC-SI Header
16...19 Manufacturer ID (Intel 0x157)
20...23 0x02 0x64 IP filter index IPv4 Address (MSB)
24...25 ... IPv4 Address (LSB)
Ethernet Controller I210 —System Manageability
704
IPv4 Mode: Filter index range: 0x0...0x3.
IPv6 Mode: This command should not be used in IPv6 mode.
10.6.3.5.13 Set Intel Filters IPv4 Filter Response (Intel Command 0x02, Filter Parameter
0x64)
10.6.3.5.14 Set Intel Filters IPv6 Filter Command (Intel Command 0x02, Filter Parameter
0x65)
Note: The filters index range can vary according to the IPv4/IPv6 mode setting in the Filters Control
command.
IPv4 Mode: Filter index range: 0x0...0x2.
IPv6 Mode: Filter index range: 0x0...0x3.
10.6.3.5.15 Set Intel Filters IPv6 Filter Response (Intel Command 0x02, Filter Parameter
0x65)
Bits
Bytes 31:24 23:16 15:08 07:00
00...15 NC-SI Header
16...19 Response Code Reason Code
20...23 Manufacturer ID (Intel 0x157)
24...25 0x02 0x64
Bits
Bytes 31:24 23:16 15:08 07:00
00...15 NC-SI Header
16...19 Manufacturer ID (Intel 0x157)
20...23 0x02 0x65 IP filter index ...IPv6 Address (MSB,
byte 15)
24...27 ... ... ... ...
28...31 ... ... ... ...
32...35 ... ... ... ...
36...37 ... IPv6 Address (LSB, byte
0)
Bits
Bytes 31:24 23:16 15:08 07:00
00...15 NC-SI Header
16...19 Response Code Reason Code
20...23 Manufacturer ID (Intel 0x157)
24...25 0x02 0x65
System Manageability—Ethernet Controller I210
705
If the IP filter index is larger the 3, a command failed Response Code will be returned, with Invalid Intel
Parameter Number reason (0x5082).
10.6.3.5.16 Set Intel Filters - EtherType Filter Command (Intel Command 0x02, Filter
parameter 0x67)
Where the EtherType Filter has the format as described in Section 8.22.4.
10.6.3.5.17 Set Intel Filters - EtherType Filter Response (Intel Command 0x02, Filter
parameter 0x67)
If the Ethertype filter Index is greater than 3, a command failed Response Code is returned with Invalid
Intel Parameter Number reason (0x5082).
10.6.3.5.18 Set Intel Filters - Packet Addition Extended Decision Filter Command (Intel
Command 0x02, Filter parameter 0x68)
See Figure 10-1 for description of the decision filters structure.
The command shall overwrite any previously stored value.
Bits
Bytes 31:24 23:16 15:08 07:00
00...15 NC-SI Header
16...19 Manufacturer ID (Intel 0x157)
20...23 0x02 0x67 EtherType Filter Index EtherType Filter MSB
24...27 ... ... EtherType Filter LSB
Bits
Bytes 31:24 23:16 15:08 07:00
00...15 NC-SI Header
16...19 Response Code Reason Code
20...23 Manufacturer ID (Intel 0x157)
24...25 0x02 0x67
Bits
Bytes 31:24 23:16 15:08 07:00
00...15 NC-SI Header
16...19 Manufacturer ID (Intel 0x157)
Ethernet Controller I210 —System Manageability
706
Extended Decision filter Index Range: 0...4
Decision Filter: See Table 10-37.
Extended Decision filter: See Table 10-38.
20...23 0x02 0x68 Extended Decision filter
Index Extended Decision filter
MSB
24...27 ... ... Extended Decision filter
LSB Decision filter MSB
28...30 ... ... Extended Decision filter
LSB
Table 10-37. Decision Filter Values
Bit # Name Description
1:0 Exact (AND) If set, packets must match exact filter 0 to 1, respectively.
3:2 Reserved Reserved.
4 Broadcast (AND) If set, packets must match the broadcast filter.
12:5 VLAN (AND) If set, packets must match VLAN filter 0 to 7, respectively.
16:13 IPv4 Address (AND) If set, packets must match IPv4 filter 0 to 3, respectively
20:17 IPv6 Address (AND) If set, packets must match IPv4 filter 0 to 3, respectively
22:21 Exact (OR) If set, packets can pass if match exact filter 0 to 1, respectively or a different OR
filter.
24:23 Reserved Reserved.
25 Broadcast (OR) If set, packets can pass if match the broadcast filter or a different OR filter.
26 Multicast (AND) If set, packets must match the multicast filter.
27 ARP Request (OR) If set, packets can pass if match the ARP request filter or a different OR filter.
28 ARP Response (OR) If set, packets can pass if match the ARP response filter or a different OR filter.
29 Neighbor
Discovery - 134 (OR)
If set, packets can pass if match the neighbor discovery filter (type134 - router
advertisement) or a different OR filter.
30 Port 0x298 (OR) If set, packets can pass if match a fixed TCP/UDP port 0x298 filter or a different OR
filter.
31 Port 0x26F (OR) If set, packets can pass if match a fixed TCP/UDP port 0x26F filter or a different OR
filter.
Table 10-38. Extended Decision Filter Values
Bit # Name Description
3:0 Ethertype 0 -3 (AND) If set, packets must match the Ethertype filter 0 to 3 respectively.
7:4 Ethertype 0 -3 (OR) If set, packets can pass if match the Ethertype filter 0 to 3 respectively or a
different OR filter.
18:8 Flex port 10:0 (OR) If set, packets can pass if match the TCP/UDP Port filter 10:0
19 DHCPv6 (OR) If set, packets can pass if match the DHCPv6 port (0x0223)
20 DHCP Client (OR) If set, packets can pass if match the DHCP Client port (0x0044)
21 DHCP Server (OR) If set, packets can pass if match the DHCP Server port (0x0043)
Bits
Bytes 31:24 23:16 15:08 07:00
System Manageability—Ethernet Controller I210
707
10.6.3.5.19 Set Intel Filters – Packet Addition Extended Decision Filter Response (Intel
Command 0x02, Filter parameter 0x68)
If the Extended Decision filter Index is bigger than 5, a command failed Response Code is returned with
Invalid Intel Parameter Number reason (0x5082).
10.6.3.5.20 Set Intel Filters - Special Modifier Command (Intel Command 0x02, Filter
parameter 0x69)
Where the Special Modifier Filter has the format as described in Section 8.22.3.
22 NetBIOS Name Service (OR) If set, packets can pass if match the NetBIOS Name Service port (0x0089)
23 NetBIOS Datagram Service (OR) If set, packets can pass if match the NetBIOS Datagram Service port (0x008A)
24 Flex TCO (OR) If set, packets can pass if match the Flex 128 TCO filter
25 Neighbor
Discovery - 135 (OR)
If set, packets must also match the neighbor discovery filter (type135 - Neighbor
Solicitation. or a different OR filter.
26 Neighbor
Discovery - 136 (OR)
If set, packets must also match the neighbor discovery filter (type136 - Neighbor
Advertisement) or a different OR filter.
27 Neighbor
Discovery - 137 (OR)
If set, packets must also match the neighbor discovery filter (type137 - Redirect)
or a different OR filter.
28 ICMP (OR) Controls the inclusion of ICMP filtering in the manageability filter decision (OR
section).
29 MLD (OR) MLD - control the inclusion of MLD packets. These are ICMPv6 packets with the
following types: 130, 131, 132, 143.
31:30 Reserved
Bits
Bytes 31:24 23:16 15:08 07:00
00...15 NC-SI Header
16...19 Response Code Reason Code
20...23 Manufacturer ID (Intel 0x157)
24...25 0x02 0x68
Bits
Bytes 31:24 23:16 15:08 07:00
00...15 NC-SI Header
16...19 Manufacturer ID (Intel 0x157)
20...23 0x02 0x69 Special Modifier Register MSB
24...27 Special Modifier Register LSB Padding
Table 10-38. Extended Decision Filter Values (Continued)
Bit # Name Description
Ethernet Controller I210 —System Manageability
708
10.6.3.5.21 Set Intel Filters - Special Modifier Response (Intel Command 0x02, Filter
parameter 0x69)
10.6.3.6 Get Intel Filters Formats
10.6.3.6.1 Get Intel Filters Command (Intel Command 0x03)
10.6.3.6.2 Get Intel Filters Response (Intel Command 0x03)
10.6.3.6.3 Get Intel Filters — Manageability Only Command (Intel Command 0x03, Filter
Parameter 0x0F)
This command retrieves the MNGONLY register. The MNGONLY register controls whether pass-through
packets destined to the MC are also be forwarded to the Host OS.
10.6.3.6.4 Get Intel Filters — Manageability Only Response (Intel Command 0x03, Filter
Parameter 0x0F)
Bits
Bytes 31:24 23:16 15:08 07:00
00...15 NC-SI Header
16...19 Response Code Reason Code
20...23 Manufacturer ID (Intel 0x157)
24...25 0x02 0x69
Bits
Bytes 31:24 23:16 15:08 07:00
00...15 NC-SI Header
16...19 Manufacturer ID (Intel 0x157)
20...21 0x03 Parameter Number
Bits
Bytes 31:24 23:16 15:08 07:00
00...15 NC-SI Header
16...19 Response Code Reason Code
20...23 Manufacturer ID (Intel 0x157)
24...25 0x03 Parameter Number Optional Return Data
Bits
Bytes 31:24 23:16 15:08 07:00
00...15 NC-SI Header
16...19 Manufacturer ID (Intel 0x157)
20...21 0x03 0x0F
System Manageability—Ethernet Controller I210
709
The MNGONLY register structure is described in Table 10-5.
10.6.3.6.5 Get Intel Filters — Flex Filter 0 Enable Mask and Length Command (Intel
Command 0x03, Filter Parameter 0x10)
The following command retrieves the Intel flex filters mask and length. See Section 10.3.3.6 for details
of the values returned by this command.
10.6.3.6.6 Get Intel Filters — Flex Filter 0 Enable Mask and Length Response (Intel
Command 0x03, Filter Parameter 0x10)
10.6.3.6.7 Get Intel Filters — Flex Filter 0 Data Command (Intel Command 0x03, Filter
Parameter 0x11)
The following command retrieves the Intel flex filters data.
Bits
Bytes 31:24 23:16 15:08 07:00
00...15 NC-SI Header
16...19 Response Code Reason Code
20...23 Manufacturer ID (Intel 0x157)
24...27 0x03 0x0F Manageability Only (3-2)
28...29 Manageability Only(1-0)
Bits
Bytes 31:24 23:16 15:08 07:00
00...15 NC-SI Header
16...19 Manufacturer ID (Intel 0x157)
20...21 0x03 0x10
Bits
Bytes 31:24 23:16 15:08 07:00
00...15 NC-SI Header
16...19 Response Code Reason Code
20...23 Manufacturer ID (Intel 0x157)
24...27 0x03 0x10 Mask Byte 1 Mask Byte 2
28...31 ... ... ... ...
32...35 ... ... ... ...
36...39 ... ... ... ...
40...43 ... Mask Byte 16 Reserved Reserved
44 Flexible Filter Length
Bits
Bytes 31:24 23:16 15:08 07:00
Ethernet Controller I210 —System Manageability
710
The Filter Data Group parameter defines which bytes of the Flex filter are returned by this command:
10.6.3.6.8 Get Intel Filters — Flex Filter 0 Data Response (Intel Command 0x03, Filter
Parameter 0x11)
10.6.3.6.9 Get Intel Filters — Packet Addition Decision Filter Command (Intel Command
0x03, Filter Parameter 0x61)
This command is not supported anymore. Use the Get Intel Filters - Packet Addition Extended Decision
Filter Command (Intel Command 0x03, Filter parameter 0x68 - Section 10.6.3.6.18) instead.
10.6.3.6.10 Get Intel Filters — Flex TCP/UDP Port Filter Command (Intel Command 0x03,
Filter Parameter 0x63)
Filter index range: 0x0...0x2.
10.6.3.6.11 Get Intel Filters — Flex TCP/UDP Port Filter Response (Intel Command 0x03,
Filter Parameter 0x63)
00...15 NC-SI Header
16...19 Manufacturer ID (Intel 0x157)
20...22 0x03 0x11 Filter Data Group
0...4
Table 10-39. Filter Data Group
Code Bytes Returned
0x0 bytes 0-29
0x1 bytes 30-59
0x2 bytes 60-89
0x3 bytes 90-119
0x4 bytes 120-127
Bits
Bytes 31:24 23:16 15:08 07:00
00...15 NC-SI Header
16...19 Response Code Reason Code
20...23 Manufacturer ID (Intel 0x157)
24... 0x03 0x11 Filter Group Number Filter Data 1
... Filter Data N
Bits
Bytes 31:24 23:16 15:08 07:00
00...15 NC-SI Header
16...19 Manufacturer ID (Intel 0x157)
20...22 0x03 0x63 TCP/UDP Filter Index
System Manageability—Ethernet Controller I210
711
If the TCP/UDP Filter Index is bigger than 0xA, a command failed Response Code is returned with
Invalid Intel Parameter Number reason (0x5082).
Port flags is described below:
Bit 0: Match UDP ports
Bit 1: Match TCP ports
Bit 2: Match Destination port (0) or Source Port (1).
Bit 7:3: Reserved
10.6.3.6.12 Get Intel Filters IPv4 Filter Command (Intel Command 0x03, Filter Parameter
0x64)
Note: The filters index range can vary according to the IPv4/IPv6 mode setting in the Filters Control
command.
IPv4 Mode: Filter index range: 0x0...0x3.
IPv6 Mode: This command should not be used in IPv6 mode.
10.6.3.6.13 Get Intel Filters — IPv4 Filter Response (Intel Command 0x03, Filter Parameter
0x64)
Bits
Bytes 31:24 23:16 15:08 07:00
00...15 NC-SI Header
16...19 Response Code Reason Code
20...23 Manufacturer ID (Intel 0x157)
24...27 0x03 0x63 TCP/UDP Filter Index TCP/UDP Port (1)
28...29 TCP/UDP Port (0) Port flags
Bits
Bytes 31...24 23...16 15...08 07...00
00...15 NC-SI Header
16...19 Manufacturer ID (Intel 0x157)
20...22 0x03 0x64 IPv4 Filter Index
Bits
Bytes 31:24 23:16 15:08 07:00
00...15 NC-SI Header
16...19 Response Code Reason Code
Ethernet Controller I210 —System Manageability
712
10.6.3.6.14 Get Intel Filters IPv6 Filter Command (Intel Command 0x03, Filter Parameter
0x65)
Note: The filters index range can vary according to the IPv4/IPv6 mode setting in the Filters Control
command
IPv4 Mode: Filter index range: 0x0...0x2.
IPv6 Mode: Filter index range: 0x0...0x3.
10.6.3.6.15 Get Intel Filters — IPv6 Filter Response (Intel Command 0x03, Filter parameter
0x65)
If the IPv6 Filter Index is bigger than 3, a command failed Response Code is returned with Invalid Intel
Parameter Number reason (0x5082).
10.6.3.6.16 Get Intel Filters - EtherType Filter Command (Intel Command 0x03, Filter
parameter 0x67)
20...23 Manufacturer ID (Intel 0x157)
24...27 0x03 0x64 IPv4 Filter Index IPv4 Address (3)
28...29 IPv4 Address (2-0)
Bits
Bytes 31:24 23:16 15:08 07:00
00...15 NC-SI Header
16...19 Manufacturer ID (Intel 0x157)
20...22 0x03 0x65 IPv6 Filter Index
Bits
Bytes 31:24 23:16 15:08 07:00
00...15 NC-SI Header
16...19 Response Code Reason Code
20...23 Manufacturer ID (Intel 0x157)
24...27 0x03 0x65 IPv6 Filter Index IPv6 Address (MSB, Byte
16)
28...31 ... ... ... ...
32...35 ... ... ... ...
36...39 ... ... ... ...
40...42 ... ... IPv6 Address (LSB, Byte
0)
System Manageability—Ethernet Controller I210
713
Valid indices: 0...3
10.6.3.6.17 Get Intel Filters - EtherType Filter Response (Intel Command 0x03, Filter
parameter 0x67)
If the Ethertype filter Index is larger than 3, a command failed Response Code is returned with Invalid
Intel Parameter Number reason (0x5082).
10.6.3.6.18 Get Intel Filters – Packet Addition Extended Decision Filter Command (Intel
Command 0x03, Filter parameter 0x68)
This command allows the MC to retrieve the Extended Decision Filter.
10.6.3.6.19 Get Intel Filters – Packet Addition Extended Decision Filter Response (Intel
Command 0x03, Filter parameter 0x68)
Bits
Bytes 31:24 23:16 15:08 07:00
00...15 NC-SI Header
16...19 Manufacturer ID (Intel 0x157)
20...22 0x03 0x67 EtherType Filter
Index
Bits
Bytes 31:24 23:16 15:08 07:00
00...15 NC-SI Header
16...19 Response Code Reason Code
20...23 Manufacturer ID (Intel 0x157)
24...27 0x03 0x67 EtherType Filter
Index EtherType Filter MSB
28...30 .. .. EtherType Filter LSB
Bits
Bytes 31:24 23:16 15:08 07:00
00...15 NC-SI Header
16...19 Manufacturer ID (Intel 0x157)
20...22 0x03 0x68 Extended Decision
Filter Index
Ethernet Controller I210 —System Manageability
714
Where Decision Filter & Extended Decision Filter have the structure as detailed in the respective “Set”
commands.
If the Extended Decision Filter Index is bigger than 4, a command failed Response Code is returned
with Invalid Intel Parameter Number reason (0x5082).
10.6.3.6.20 Get Intel Filters - Special Modifier Command (Intel Command 0x03, Filter
parameter 0x69)
Where the Special Modifier Filter has the format as described in Section 8.22.3.
10.6.3.6.21 Get Intel Filters - Special Modifier Response (Intel Command 0x02, Filter
parameter 0x69)
Bits
Bytes 31:24 23:16 15:08 07:00
00...15 NC-SI Header
16...19 Response Code Reason Code
20...23 Manufacturer ID (Intel 0x157)
24...27 0x03 0x68 Decision Filter Index Extended Decision
Filter MSB
28...31 .. .. Extended Decision
Filter LSB Decision Filter MSB
32...34 .. .. Decision Filter LSB
Bits
Bytes 31:24 23:16 15:08 07:00
00...15 NC-SI Header
16...19 Manufacturer ID (Intel 0x157)
20...23 0x03 0x69 Padding
Bits
Bytes 31:24 23:16 15:08 07:00
00...15 NC-SI Header
16...19 Response Code Reason Code
20...23 Manufacturer ID (Intel 0x157)
24...27 0x03 0x69 Special Modifier Register MSB
28...29 Special Modifier Register LSB Padding
System Manageability—Ethernet Controller I210
715
10.6.3.7 Set Intel Packet Reduction Filters Formats
Note: The non extended commands (Section 10.6.3.7.3 to Section 10.6.3.7.5) are not supported
anymore. Use the extended commands (Section 10.6.3.7.6 to Section 10.6.3.7.11) instead.
10.6.3.7.1 Set Intel Packet Reduction Filters Command (Intel Command 0x04)
10.6.3.7.2 Set Intel Packet Reduction Filters Response (Intel Command 0x04)
The Packet Reduction Data field has the following structure:
Bits
Bytes 31:24 23:16 15:08 07:00
00...15 NC-SI Header
16...19 Manufacturer ID (Intel 0x157)
20...23 0x04 Packet Reduction Index Packet Reduction Data...
Bits
Bytes 31...24 23...16 15...08 07...00
00...15 NC-SI Header
16...19 Response Code Reason Code
20...23 Manufacturer ID (Intel 0x157)
24... 0x04 Packet Reduction Index Optional Return Data
Table 10-40. Packet Reduction Field Description
Bit # Name Description
12:0 Reserved Reserved
16:13 IPv4 Address (AND) If set, packets must match IPv4 filter 0 to 3 respectively
20:17 IPv6 Address (AND) If set, packets must match IPv6 filter 0 to 3 respectively
27:21 Reserved Reserved
28 ARP Response (OR) If set, packets can pass if match the ARP response filter or a different OR filter.
29 Reserved Reserved
30 Port 0x298 If set, packets can pass if match a fixed TCP/UDP port 0x298 filter.
31 Port 0x26F If set, packets can pass if match a fixed TCP/UDP port 0x26F filter.
Table 10-41. Extended Packet Reduction Field Description
Bit # Name Description
3:0 Ethertype 0 -3 (AND) If set, packets must match the Ethertype filter 0 to 3 respectively.
7:4 Ethertype 0-3 (OR) If set, packets can pass if match the Ethertype filter 0 to 3 respectively.
8:18 Flex port 10:0 (OR) If set, packets can pass if match the TCP/UDP Port filter 10:0
23:19 Reserved
Ethernet Controller I210 —System Manageability
716
The filtering is divided into two decisions:
Bit 20:13 in Table 10-40 and Bits 3:2 in Table 10-41 works in an AND manner; it must be true in
order for a packet to pass (if was set).
Bits 28 in Table 10-40 and Bits 24:10 in Table 10-41 work in an OR manner; at least one of them must
be true for a packet to pass (if any were set).
10.6.3.7.3 Set Unicast Packet Reduction Command (Intel Command 0x04, Reduction Filter
Index 0x00)
This command is not supported anymore. Use the Set Unicast Extended Packet Reduction Command
(Intel Command 0x04, Reduction Filter Index 0x10) instead (Section 10.6.3.7.6).
10.6.3.7.4 Set Multicast Packet Reduction Command (Intel Command 0x04, Reduction
Filter Index 0x01)
This command is not supported anymore. Use the Set Multicast Extended Packet Reduction Command
(Intel Command 0x04, Reduction Filter Index 0x11) instead (Section 10.6.3.7.8)
10.6.3.7.5 Set Broadcast Packet Reduction Command (Intel Command 0x04, Reduction
Filter Index 0x02)
This command is not supported anymore. Use the Set Broadcast Extended Packet Reduction Command
(Intel Command 0x04, Reduction Filter Index 0x12) instead (Section 10.6.3.7.10)
10.6.3.7.6 Set Unicast Extended Packet Reduction Command (Intel Command 0x04,
Reduction Filter Index 0x10)
In “Set Intel Reduction Filters” add another parameter “Unicast Extended Packet Reduction (Intel
Command 0x04, Filter parameter 0x10)” such that the byte count is 0xE. The command shall have the
following format:
24 Flex TCO (OR) If set, packets can pass if match the Flex 128 TCO filter
27:25 Reserved
28 ICMP If set, ICMP packets can pass
29 MLD If set, MLD packets can pass
31:30 Reserved Reserved.
Bits
Bytes 31:24 23:16 15:08 07:00
00..15 NC-SI Header
16..19 Manufacturer ID (Intel 0x157)
Table 10-41. Extended Packet Reduction Field Description
Bit # Name Description
System Manageability—Ethernet Controller I210
717
This command causes the NC to filter packets that have passed due to the unicast filter (MAC address
filters, as specified in the DMTF NC-SI). Note that unicast filtering might be affected by other filters, as
specified in the DMTF NC-SI.
The filtering of these packets are done such that the MC might add a logical condition that a packet
must match, or it must be discarded.
Note: Packets that might have been blocked can still pass due to other decision filters.
In order to disable unicast packet reduction, the MC should set all reduction filters to 0b. Following such
a setting the NC must forward, to the MC, all packets that have passed the unicast filters (MAC address
filtering) as specified in the DMTF NC-SI.
The command shall overwrite any previously stored value.
Note: See Table 10-40 and Table 10-41 for description of the Unicast Extended Packet Reduction
format.
10.6.3.7.7 Set Unicast Extended Packet Reduction Response (Intel Command 0x04,
Reduction Filter Index 0x10)
10.6.3.7.8 Set Multicast Extended Packet Reduction Command (Intel Command 0x04,
Reduction Filter Index 0x11)
20..23 0x04 0x10 Extended Unicast
Reduction Filter MSB ..
24..27 .. Extended Unicast
Reduction Filter LSB Unicast Reduction Filter
MSB ..
28..29 .. Unicast Reduction Filter
LSB
Bits
Bytes 31:24 23:16 15:08 07:00
00..15 NC-SI Header
16..19 Response Code Reason Code
20..23 Manufacturer ID (Intel 0x157)
24..25 0x04 0x10
Bits
Bytes 31:24 23:16 15:08 07:00
00..15 NC-SI Header
16..19 Manufacturer ID (Intel 0x157)
20..23 0x04 0x11 Extended Multicast
Reduction Filter MSB ..
24..27 .. Extended Multicast
Reduction Filter LSB Multicast Reduction Filter
MSB ..
28..29 .. Multicast Reduction Filter
LSB
Ethernet Controller I210 —System Manageability
718
Note: See Table 10-40 and Table 10-41 for description of the Multicast Extended Packet Reduction
format.
This command causes the NC to filter packets that have passed due to the multicast filter (MAC address
filters, as specified in the DMTF NC-SI).
The filtering of these packets are done such that the MC might add a logical condition that a packet
must match, or it must be discarded.
Note: Packets that might have been blocked can still pass due to other decision filters.
In order to disable multicast packet reduction, the MC should set all reduction filters to 0b. Following
such a setting, the NC must forward, to the MC, all packets that have passed the multicast filters
(global multicast filtering) as specified in the DMTF NC-SI.
The command shall overwrite any previously stored value.
10.6.3.7.9 Set Multicast Extended Packet Reduction Response (Intel Command 0x04,
Reduction Filter Index 0x11)
10.6.3.7.10 Set Broadcast Extended Packet Reduction Command (Intel Command 0x04,
Reduction Filter Index 0x12)
Note: See Table 10-40 and Table 10-41 for description of the Broadcast Extended Packet Reduction
format.
This command causes the NC to filter packets that have passed due to the broadcast filter (MAC
address filters, as specified in the DMTF NC-SI).
The filtering of these packets are done such that the MC might add a logical condition that a packet
must match, or it must be discarded.
Bits
Bytes 31:24 23:16 15:08 07:00
00..15 NC-SI Header
16..19 Response Code Reason Code
20..23 Manufacturer ID (Intel 0x157)
24..25 0x04 0x11
Bits
Bytes 31:24 23:16 15:08 07:00
00..15 NC-SI Header
16..19 Manufacturer ID (Intel 0x157)
20..23 0x04 0x12 Extended Broadcast
Reduction Filter MSB ..
24..27 .. Extended Broadcast
Reduction Filter LSB Broadcast Reduction
Filter MSB ..
28..29 .. Broadcast Reduction
Filter LSB
System Manageability—Ethernet Controller I210
719
Note: Packets that might have been blocked can still pass due to other decision filters.
In order to disable broadcast packet reduction, the MC should set all reduction filters to 0b. Following
such a setting, the NC must forward, to the MC, all packets that have passed the broadcast filters as
specified in the DMTF NC-SI.
The command shall overwrite any previously stored value.
10.6.3.7.11 Set Broadcast Extended Packet Reduction Response (Intel Command 0x04,
Reduction Filter Index 0x12)
10.6.3.8 Get Intel Packet Reduction Filters Formats
Note: The non extended commands (Section 10.6.3.8.3 to Section 10.6.3.8.6) are not supported
anymore. Use the extended commands (Section 10.6.3.8.6 to Section 10.6.3.8.11) instead.
10.6.3.8.1 Get Intel Packet Reduction Filters Command (Intel Command 0x05)
This command is not supported anymore. Use the Get Unicast Extended Packet Reduction Command
(Intel Command 0x05, Reduction Filter Index 0x10) instead (Section 10.6.3.8.6).
10.6.3.8.2 Get Intel Packet Reduction Filters Response (Intel Command 0x05)
Bits
Bytes 31:24 23:16 15:08 07:00
00..15 NC-SI Header
16..19 Response Code Reason Code
20..23 Manufacturer ID (Intel 0x157)
24..25 0x04 0x12
Bits
Bytes 31:24 23:16 15:08 07:00
00...15 NC-SI Header
16...19 Manufacturer ID (Intel 0x157)
20...21 0x05 Reduction Filter Index
Bits
Bytes 31:24 23:16 15:08 07:00
00...15 NC-SI Header
16...19 Response Code Reason Code
20...23 Manufacturer ID (Intel 0x157)
24... 0x05 Reduction Filter Index Return Data
Ethernet Controller I210 —System Manageability
720
Note: See Table 10-40 and Table 10-41 for description of the Return Data format.
10.6.3.8.3 Get Unicast Packet Reduction Command (Intel Command 0x05, Reduction Filter
Index 0x00)
This command is not supported anymore. Use the Get Unicast Extended Packet Reduction Command
(Intel Command 0x05, Reduction Filter Index 0x10) instead (Section 10.6.3.8.6).
10.6.3.8.4 Get Multicast Packet Reduction Command (Intel Command 0x05, Reduction
Filter Index 0x01)
This command is not supported anymore. Use the Get Multicast Extended Packet Reduction Command
(Intel Command 0x05, Reduction Filter Index 0x11) instead (Section 10.6.3.8.8).
10.6.3.8.5 Get Broadcast Packet Reduction Command (Intel Command 0x05, Reduction
Filter Index 0x02)
This command is not supported anymore. Use the Get Broadcast Extended Packet Reduction Command
(Intel Command 0x05, Reduction Filter Index 0x12) instead (Section 10.6.3.8.10).
10.6.3.8.6 Get Unicast Extended Packet Reduction Command (Intel Command 0x05,
Reduction Filter Index 0x10)
\
10.6.3.8.7 Get Unicast Extended Packet Reduction Response (Intel Command 0x05,
Reduction Filter Index 0x10)
10.6.3.8.8 Get Multicast Extended Packet Reduction Command (Intel Command 0x05,
Reduction Filter Index 0x11)
Bits
Bytes 31:24 23:16 15:08 07:00
00...15 NC-SI Header
16...19 Manufacturer ID (Intel 0x157)
20...21 0x05 0x10
Bits
Bytes 31:24 23:16 15:08 07:00
00...15 NC-SI Header
16...19 Response Code Reason Code
20...23 Manufacturer ID (Intel 0x157)
24...27 0x05 0x10 Extended Unicast Packet Reduction (MSB)
28...31 Extended Unicast Packet Reduction (LSB) Unicast Packet Reduction (MSB)
32...33 Unicast Packet Reduction (LSB)
System Manageability—Ethernet Controller I210
721
10.6.3.8.9 Get Multicast Extended Packet Reduction Response (Intel Command 0x05,
Reduction Filter Index 0x11)
10.6.3.8.10 Get Broadcast Extended Packet Reduction Command (Intel Command 0x05,
Reduction Filter Index 0x12)
10.6.3.8.11 Get Broadcast Extended Packet Reduction Response (Intel Command 0x05,
Reduction Filter Index 0x12)
Bits
Bytes 31:24 23:16 15:08 07:00
00...15 NC-SI Header
16...19 Manufacturer ID (Intel 0x157)
20...21 0x05 0x11
Bits
Bytes 31:24 23:16 15:08 07:00
00...15 NC-SI Header
16...19 Response Code Reason Code
20...23 Manufacturer ID (Intel 0x157)
24...27 0x05 0x11 Extended Multicast Packet Reduction (MSB)
28...31 Extended Multicast Packet Reduction (LSB) Multicast Packet Reduction (MSB)
32...33 Multicast Packet Reduction (LSB)
Bits
Bytes 31:24 23:16 15:08 07:00
00...15 NC-SI Header
16...19 Manufacturer ID (Intel 0x157)
20...21 0x05 0x12
Bits
Bytes 31:24 23:16 15:08 07:00
00...15 NC-SI Header
16...19 Response Code Reason Code
20...23 Manufacturer ID (Intel 0x157)
24...27 0x05 0x12 Extended Broadcast Packet Reduction (MSB)
28...31 Extended Broadcast Packet Reduction (LSB) Broadcast Packet Reduction (MSB)
32...33 Broadcast Packet Reduction (LSB)
Ethernet Controller I210 —System Manageability
722
10.6.3.9 System MAC Address
10.6.3.9.1 Get System MAC Address Command (Intel Command 0x06)
In order to support a system configuration that requires the NC to hold the MAC address for the MC
(such as shared MAC address mode), the following command is provided to enable the MC to query the
NC for a valid MAC address.
The NC must return the system MAC addresses. The MC should use the returned MAC addressing as a
shared MAC address by setting it using the Set MAC Address command as defined in NC-SI 1.0.
It is also recommended that the MC use packet reduction and Manageability-to-Host command to set
the proper filtering method.
10.6.3.9.2 Get System MAC Address Response (Intel Command 0x06)
10.6.3.10 Set Intel Management Control Formats
10.6.3.10.1 Set Intel Management Control Command (Intel Command 0x20)
Bits
Bytes 31:24 23:16 15:08 07:00
00...15 NC-SI Header
16...19 Manufacturer ID (Intel 0x157)
20 0x06
Bits
Bytes 31:24 23:16 15:08 07:00
00...15 NC-SI Header
16...19 Response Code Reason Code
20...23 Manufacturer ID (Intel 0x157)
24...27 0x06 MAC Address
28...30 MAC Address
Bits
Bytes 31:24 23:16 15:08 07:00
00...15 NC-SI Header
16...19 Manufacturer ID (Intel 0x157)
20...22 0x20 0x00 Intel Management
Control 1
System Manageability—Ethernet Controller I210
723
Where Intel Management Control 1 is as follows:
10.6.3.10.2 Set Intel Management Control Response (Intel Command 0x20)
10.6.3.11 Get Intel Management Control Formats
10.6.3.11.1 Get Intel Management Control Command (Intel Command 0x21)
Where Intel Management Control 1 is as described in Section 10.6.3.10.2.
10.6.3.11.2 Get Intel Management Control Response (Intel Command 0x21)
Bit # Default value Description
0 0b
Enable Critical Session Mode (Keep PHY Link Up and Veto Bit)
0b — Disabled
1b — Enabled
When critical session mode is enabled, the following behaviors are disabled:
The PHY is not reset on PE_RST# and PCIe resets (in-band and link drop). Other reset
events are not affected — Internal_Power_On_Reset, device disable, Force TCO, and PHY
reset by software.
The PHY does not change its power state. As a result link speed does not change.
The device does not initiate configuration of the PHY to avoid losing link.
1…7 0x0 Reserved
Bits
Bytes 31:24 23:16 15:08 07:00
00...15 NC-SI Header
16...19 Response Code Reason Code
20...23 Manufacturer ID (Intel 0x157)
24...25 0x20 0x00
Bits
Bytes 31:24 23:16 15:08 07:00
00...15 NC-SI Header
16...19 Manufacturer ID (Intel 0x157)
20...21 0x21 0x00
Bits
Bytes 31:24 23:16 15:08 07:00
00...15 NC-SI Header
Ethernet Controller I210 —System Manageability
724
10.6.3.12 TCO Reset
Depending on the bit set in the TCO mode field this command will cause the I210 to perform either:
1. TCO Reset, if Force TCO reset is enabled in the Flash (see Section 6.7.1). The Force TCO reset will
clear the data-path (RX/TX) of the I210 to enable the MC to transmit/receive packets through the
I210.
If the MC has detected that the OS is hung and has blocked the RX/TX path The Force TCO
reset will clear the data-path (RX/TX) of the Network Controller to enable the MC to transmit/
receive packets through the Network Controller.
When this command is issued to a channel in a package, it applies only to the specific channel.
After successfully performing the command the Network Controller will consider Force TCO
command as an indication that the OS is hung and will clear the DRV_LOAD flag (disable the
driver). If TCO reset is disabled in Flash the I210 clears the CTRL_EXT.DRV_LOAD bit but does
not reset the data-path and notifies MC on successful completion.
Following TCO reset management sets MANC.TCO_RESET to 1.
2. TCO isolate, if TCO isolate is enabled in the Flash (See Section 6.7.1.3). The TCO Isolate command
will disable PCIe write operations to the LAN port.
If TCO Isolate is disabled in Flash the I210 does not execute the command but sends a
response to the MC with successful completion.
Following TCO Isolate management sets MANC.TCO_Isolate to 1.
3. Firmware Reset. This command will cause re-initialization of all the manageability functions and re-
load of manageability related Flash words.
When the MC has loaded new management related Flash image the Firmware Reset command
will load management related Flash information without need to power down the system.
This command is issued to the package and affects all channels. After the Firmware reset the
FW Semaphore register (FWSM) is re-initialized.
Notes: Force TCO reset and TCO Isolate will affect only the channel (port) that the command was
issued to.
Following firmware reset, MC will need to re-initialize the port.
Note: Only one of the fields should be set in a given command. Setting more than one field may
yield unexpected results.
10.6.3.12.1 Perform Intel TCO Reset Command (Intel Command 0x22)
16...19 Response Code Reason Code
20...23 Manufacturer ID (Intel 0x157)
24...26 0x21 0x00 Intel Management
Control 1
Bits
Bytes 31:24 23:16 15:08 07:00
System Manageability—Ethernet Controller I210
725
Where TCO Mode is:
10.6.3.12.2 Perform Intel TCO Reset Response (Intel Command 0x22)
10.6.3.13 Checksum Offloading
This command enables the checksum offloading filters in the NC.
When enabled, these filters block any packets that did not pass IP, UDP and TCP checksums from being
forwarded to the MC.
10.6.3.13.1 Enable Checksum Offloading Command (Intel Command 0x23)
Bits
Bytes 31:24 23:16 15:08 07:00
00...15 NC-SI Header
16...19 Manufacturer ID (Intel 0x157)
20 0x22 TCO Mode
Field Bit(s) Description
DO_TCO_RST 0
Perform TCO Reset.
0b: Do nothing.
1b: Perform TCO reset.
DO_TCO_ISOLATE1
1. TCO Isolate Host Write operation enabled in Flash.
1
Do TCO Isolate
0b = Enable PCIe write access to LAN port.
1b = Isolate Host PCIe write operation to the port
Note: Should be used for debug only.
Note: The TCO Isolate do not impact MCTP traffic
Note: When Isolate is set, the OS2BMC flow is disabled also.
RESET_MGMT 2
Reset manageability; re-load manageability Flash words.
0b = Do nothing
1b = Issue firmware reset to manageability
Setting this bit generates a one-time firmware reset. Following the reset, management
related data from Flash is loaded.
Reserved 7:3 Reserved (set to 0x00).
Note: For compatibility, the TCO reset command without the TCO Mode parameter is accepted (TCO reset is performed).
Bits
Bytes 31:24 23:16 15:08 07:00
00...15 NC-SI Header
16...19 Response Code Reason Code
20...23 Manufacturer ID (Intel 0x157)
24...26 0x22
Ethernet Controller I210 —System Manageability
726
10.6.3.13.2 Enable Checksum Offloading Response (Intel Command 0x23)
10.6.3.13.3 Disable Checksum Offloading Command (Intel Command 0x24)
10.6.3.13.4 Disable Checksum Offloading Response (Intel Command 0x24)
10.6.3.14 Shared MAC and shared IP support commands (Intel Command 0x25)
To meet the requirements introduced by sharing IP addresses, modifications and additions to the NC-SI
command set are required. These changes includes the new commands in this section and the
modifications described in Section 10.3.7.
Note: All the indexes in this command set starts at 1 to match the NC-SI methodology.
Bits
Bytes 31:24 23:16 15:08 07:00
00...15 NC-SI Header
16...19 Manufacturer ID (Intel 0x157)
20 0x23
Bits
Bytes 31:24 23:16 15:08 07:00
00...15 NC-SI Header
16...19 Response Code Reason Code
20...23 Manufacturer ID (Intel 0x157)
24...26 0x23
Bits
Bytes 31:24 23:16 15:08 07:00
00...15 NC-SI Header
16...19 Manufacturer ID (Intel 0x157)
20 0x24
Bits
Bytes 31:24 23:16 15:08 07:00
00...15 NC-SI Header
16...19 Response Code Reason Code
20...23 Manufacturer ID (Intel 0x157)
24...26 0x24
System Manageability—Ethernet Controller I210
727
10.6.3.14.1 Set IP Address Command (Intel Command 0x25, Index = 0x0)
The Set IP Address command is used by the Management Controller to communicate its IP address to a
Network Controller. The format of a Set IP Address command packet is specified in Table 10-42
If at least one IP address filter is enabled, only unicast packets that match one of the enabled filters will
be forwarded through the NC-SI interface. Otherwise, the IP address is ignored in the unicast filtering
process.
This command does not impact the forwarding results. It is used as a preliminary stage to the Set
Binding command
Management Controller IP Address: An IP address that is used by the management controller.If the
IP Version bit of the Flags field is 0 (IPv4), this is a 4-byte unicast IPv4 address in network byte
order. In this case, the address occupies bytes 24-27 of the packet, and bytes 28-39 are ignored. If
the IP Version bit of the Flags field is 1 (IPv6), this is a 16-byte unicast IPv6 address in network
byte order. In this case, the address occupies the full field (bytes 24-39 of the packet).
IP Address Number: Indicates which IP address filter is configured by the command.The value can
relate to one of three pools of filters according to the following table:
Note: The values in this allowed values column refers to the Get Shared IP Capabilities Response
(Section 10.6.3.14.6.1)
Table 10-42. Set IP Address Command Packet Format
Bits
Bytes 31..24 23..16 15..08 07..00
00..15 NC-SI Header
16..19 Manufacturer ID (Intel 0x157)
20..23 0x25 0x0 Reserved
24..27
Management Controller IP Address
28..31
32..35
36..39
40..43 Reserved IP Address Number Set IP Flags
44..47 Checksum
Table 10-43. IP filters pools
Set IP Flag.IP
Version
Set IP Flag.Mixed
Index Pool to use Allowed values
0 0 IPv4 1 to Number of IPv4 only addresses
1 0 IPv6 1 to Number of IPv6 only addresses
X 1 Mixed 1 to Number of Mixed IP addresses
Ethernet Controller I210 —System Manageability
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Table 10-44 describes the bits fields in the Set IP Flags field.
10.6.3.14.1.1Set IP Address Response
The Network Controller shall, in the absence of a checksum error or identifier mismatch, always accept
the Set IP Address command and send a response, using the format specified in Table 10-45.
10.6.3.14.2 Get IP Address Command (Intel Command 0x25, Index = 0x1)
A Management Controller uses the Get IP Address command to determine the IP address programmed
in one of the IP address filters in a Network Controller. The format of a Get IP Address command packet
is specified in Table 10-46.
Table 10-44. Set IP Flag Field
Bit Position Field Description Value Description
0 Enable 0 = Disable the filter
1 = Enable the filter
1 IP version 0 = IPv4
1 = IPv6
2 Mixed index 0 = Index relates to the IPv4 or IPv6 only IP filter sets according to
the IP version field.
1 = Index relates to the mixed IP filter set.
3 MAC based IP
This flags define if the Ipv6 address is derived from a MAC address
and thus only the 24 LSB should be used for the comparison. This
flag is relevant only if the IP version = IPv6.
0 = Filter according to full 128 bit of IPv6 address
1 = Filter according to the 24 least significant bits of the IPv6
address.
7:4 Reserved Reserved
Table 10-45. Set IP Address Response Packet Format
Bits
Bytes 31..24 23..16 15..08 07..00
00..15 NC-SI Header
16..19 Response Code Reason Code
20..23 Manufacturer ID (Intel 0x157)
24..27 0x25 0x0 Reserved
28..31 Checksum
Table 10-46. Get IP Address Command Packet Format
Bits
Bytes 31..24 23..16 15..08 07..00
00..15 NC-SI Header
16..19 Manufacturer ID (Intel 0x157)
20..23 0x25 0x1 Reserved
24..27 Reserved IP Address Number IP filter pool
28..31 Checksum
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IP address number. Defines the index of the IP address in the pool defined by the IP filter pool. The
allowed values are as defined in Table 10-43.
IP filter pool:
0x0: Mixed IP filters
0x1: IPv4 filters
0x2: IPv6 filters
0x3 - 0xFF: Reserved
10.6.3.14.2.1Get IP Address Response
The Network Controller shall, in the absence of a checksum error or identifier mismatch, always accept
the Get IP Address command and send a response, using the format specified in Table 10-47.
Management Controller IP Address: An IP address that is used by the management controller. If the
IP Version bit of the Flags field is 0 (IPv4), this is a 4-byte unicast IPv4 address in network byte
order. In this case, the address occupies bytes 28-31 of the packet, and bytes 32-43 are ignored. If
the IP Version bit of the Flags field is 1 (IPv6), this is a 16-byte unicast IPv6 address in network
byte order. In this case, the address occupies the full field (bytes 28-43 of the packet).
IP Address Number: Indicates which IP address filter is described in the response. Should be equal
to the IP Address Number in the command.
Table 10-48 describes the bits fields in the Get IP Flags field.
Table 10-47. Get IP Address Response Packet Format
Bits
Bytes 31..24 23..16 15..08 07..00
00..15 NC-SI Header
16..19 Response Code Reason Code
20..23 Manufacturer ID (Intel 0x157)
24..27 0x25 0x1 IP Address Number Get IP Flags
28..31
Management Controller IP Address
32..35
36..39
40..43
44..47 Checksum
Table 10-48. Get IP Flag Field
Bit Position Field Description Value Description
0 Enable 0 = Filter is disabled
1 = Filter is enabled
1 IP version 0 = IPv4
1 = IPv6
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10.6.3.14.3 Set Port Command (Intel Command 0x25, Index = 0x2)
A Management Controller uses the Set Port command to communicate one of its TCP or UDP ports to a
Network Controller. The format of a Set Port command packet is specified in Table 10-49.
This command do not impact the forwarding results. It is used as a preliminary stage to the Set Binding
command.
If the Ignore Protocol flag is cleared, the protocol should also match the Protocol field otherwise, the
Protocol field is ignored.
Protocol: The value to match in the IPv4 header Protocol field or IPv6 header Next Header field.
These values are defined by IANA. Allowed values are 0x6 (TCP) and 0x11 (UDP).
Port: The value to match in the Destination Port or Source Port field of the TCP or UDP header. The
legal port range for both TCP and UDP is 0-65,535. The compared field is defined by the Port Type
flag.
Port Index: Indicates which port filter is configured by the command. Allowed values are 1 to n,
where n is the number of port filters supported by the Network Controller.
Table 10-50 describes the fields in the Set Port Flags field.
2 Mixed Index 0 = Index relates to the IPv4 or IPv6 only IP filter sets according to
the IP version field.
1 = Index relates to the mixed IP filter set.
3 MAC based IP
This flags define if the Ipv6 address is derived from a MAC address
and thus only the 24 LSB should be used for the comparison. This
flag is relevant only if the IP version = IPv6.
0 = Filter according to full 128 bit of IPv6 address
1 = Filter according to the 24 least significant bits of the IPv6
address.
7:3 Reserved Reserved
Table 10-49. Set Port Command Packet Format
Bits
Bytes 31..24 23..16 15..08 07..00
00..15 NC-SI header
16..19 Manufacturer ID (Intel 0x157)
20..23 0x25 0x2 Set Port Flags Reserved
24..27 Port Index Protocol Port
28..31 Checksum
Table 10-50. Set Port Flags Field Descriptions
Bit Position Field Description Value Description
0 Enable 0 = Disable the filter
1 = Enable the filter
1Ignore Protocol 0 = Filter by port and Protocol
1 = Filter by port only.
2 Port Type 0 = Compare Destination Port.
1 = Compare Source Port.
7:3 Reserved Reserved
Table 10-48. Get IP Flag Field
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10.6.3.14.3.1Set Port Response
The Network Controller shall, in the absence of a checksum error or identifier mismatch, always accept
the Set Port command and send a response, using the format specified in Table 10-51.
10.6.3.14.4 Get Port Command (Intel Command 0x25, Index = 0x3)
A Management Controller uses the Get Port command to determine the TCP or UDP port programmed in
one of the port filters in a Network Controller. The format of a Get Port command packet is specified in
Table 10-52.
Table 10-53 describes the fields in the Get Port command.
10.6.3.14.4.1Get Port Response
The Network Controller shall, in the absence of a checksum error or identifier mismatch, always accept
the Get Port command and send a response, using the format specified in Table 10-54.
Table 10-51. Set Port Response Packet Format
Bits
Bytes 31..24 23..16 15..08 07..00
12..15 NC-SI Header
16..19 Response Code Reason Code
20..23 Manufacturer ID (Intel 0x157)
24..27 0x25 0x2 Reserved
28..31 Checksum
Table 10-52. Get Port Command Packet Format
Bits
Bytes 31..24 23..16 15..08 07..00
00..15 NC-SI Header
16..19 Manufacturer ID (Intel 0x157)
20..23 0x25 0x3 Reserved
24..27 Reserved Port Index Reserved
28..31 Checksum
Table 10-53. Get Port Command Field Descriptions
Field Field Description Value Description
Port Index Indicates which port filter is
requested by the command. 1 to n, where n is the number of port filters supported by the Network
Controller.
Table 10-54. Get Port Response Packet Format
Bits
Bytes 31..24 23..16 15..08 07..00
00..15 NC-SI Header
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Protocol: The value compared in the IPv4 header Protocol field or IPv6 header Next Header field.
Possible values are 0x6 (TCP) and 0x11 (UDP). This field is relevant only if the Ignore Protocol flag
is cleared.
Port: The value compared in the Destination Port or Source Port field of the TCP or UDP header.
Port Index: Indicates which port filter is reported by the response. Should match the Port Index in
the command.
Table 10-55 describes the fields in the Get Port Flags field.
10.6.3.14.5 Enable Unicast Infrastructure Filter Command (Intel Command 0x25, Index =
0x4)
A Management Controller uses the Enable Unicast Infrastructure Filter command to configure a
Network Controller to forward copies of network infrastructure packets to it. Network infrastructure
packets contain messages that are necessary for operation of the network infrastructure layers (e.g.,
DHCP, ARP, and DNS messages). This is required when the Management Controller shares an IP
address with the Host. In this case, both the Host and the Management Controller need to process the
messages, so the Network Controller must forward the packets to both the Management Controller and
the Host.
This command should be applied only after a MAC address is added using the Set MAC Address NC-SI
command.
All the IP addresses added through the Set IP command before this command is given are considered
as IP addresses of the management controller for the purpose of this command.
If a Set IP command is received after this command was received, the list of IP address is not updated
and this command should be given again.
16..19 Response Code Reason Code
20..23 Manufacturer ID (Intel 0x157)
24..27 0x25 0x3 Get Port Flags Reserved
28..31 Port Index Protocol Port
32..35 Checksum
Table 10-55. Get Port Flags Field Descriptions
Bit Position Field Description Value Description
0 Enable 0 = Filter is disabled
1 = Filter is enabled
1Ignore Protocol 0 = Filter by port and Protocol
1 = Filter by port only.
2 Port Type 0 = Compare Destination Port.
1 = Compare Source Port.
7:3 Reserved Reserved
Table 10-54. Get Port Response Packet Format
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The format of an Enable Unicast Infrastructure Filter command packet is specified in Table 10-56.
Table 10-57 describes the sub fields of the Unicast Infrastructure Filter Settings field.
Table 10-56. Enable Unicast Infrastructure Filter Command
Bits
Bytes 31..24 23..16 15..08 07..00
00..15 NC-SI Header
16..19 Response Code Reason Code
20..23 Manufacturer ID (Intel 0x157)
24..27 0x25 0x4 Reserved
28..31 Unicast Infrastructure Filter Settings
32..35 Checksum
36..29 Padding
Table 10-57. Unicast Infrastructure Packet Filter Settings Field
Bit Position Field Description Value Description
0ARP Response packets
received from wire
0x1 = Forward this packet type to both the Host and the Management Controller
0x0 = Forward this packet type to the Host only
For the purposes of this filter, an ARP response packet is defined to be any packet
that meets all of the following requirements:
The Ethernet Destination Address field contains the MAC address assigned to
the management controller.
The Ethernet Type field contains 0x0806 (ARP).
The ARP Opcode field is set to 0x0002 (Response).
The ARP Target Protocol Address field contains the IP address assigned to the
management controller.
1ICMP Request packets
received from wire
0x1 = Forward this packet type to both the Host and the Management Controller
0x0 = Forward this packet type to the Host only
For the purposes of this filter, an ICMP Request packet is defined to be any packet
that meets all of the following requirements:
The Ethernet Destination Address field contains the MAC address assigned to
the management controller.
The Ethernet Type field contains 0x0800 (IPv4).
The IP Destination Address field contains the IPv4 address assigned to the
management controller.
The IP Protocol field contains 1 (ICMP).
2ICMPv6 Request packets
received from wire
0x1 = Forward this packet type to both the Host and the Management Controller
0x0 = Forward this packet type to the Host only
For the purposes of this filter, an ICMPv6 Request packet is defined to be any packet
that meets all of the following requirements:
The Ethernet Destination Address field contains the MAC address assigned to
the management controller.
The Ethernet Type field contains 0x86DD (IPv6).
The IP Destination Address field contains the IPv6 address assigned to the
management controller.
The IP Next Header field contains 58 (ICMPv6).
Note: This filter is not supported by the I210.
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3DHCP Server unicast
packets received from wire
0x1 = Forward this packet type to both the Host and the Management Controller
0x0 = Forward this packet type to the Host only
For the purposes of this filter, a DHCP Server unicast packet is defined to be any
packet that meets all of the following requirements:
The Ethernet Destination Address field contains the MAC address assigned to
the management controller.
The Ethernet Type field contains 0x0800 (IPv4).
The IP Destination Address field contains either 255.255.255.255 (the local
broadcast address) or the IPv4 address assigned to the management controller.
The IP Protocol field contains 17 (UDP).
The UDP Destination Port field contains 67 (Bootstrap Protocol Client).
4DNS Server packets
received from wire
0x1 = Forward this packet type to both the Host and the Management Controller
0x0 = Forward this packet type to the Host only
For the purposes of this filter, a DNS Server unicast packet is defined to be any
packet that meets all of the following requirements:
The Ethernet Destination Address field contains the MAC address assigned to
the management controller.
The Ethernet Type field contains 0x0800 (IPv4).
The IP Destination Address field contains the IPv4 address assigned to the
management controller.
The IP Protocol field contains 17 (UDP).
The UDP Source Port field contains 53 (Domain Name Server).
5DHCP Client packets
transmitted by Host
0x1 = Forward this packet type to both the Host and the Management Controller
0x0 = Forward this packet type to the wire only
For the purposes of this filter, a DHCP Client unicast packet is defined to be any
packet that meets all of the following requirements:
The Ethernet Source Address field contains the MAC address assigned to the
management controller.
The Ethernet Type field contains 0x0800 (IPv4).
The IP Protocol field contains 17 (UDP).
The UDP Destination Port field contains 68 (Bootstrap Protocol Server).
6DHCPv6 Server unicast
packets received from wire
0x1 = Forward this packet type to both the Host and the Management Controller
0x0 = Forward this packet type to the Host only
For the purposes of this filter, a DHCPv6 Server unicast packet is defined to be any
packet that meets all of the following requirements:
The Ethernet Destination Address field contains the MAC address assigned to
the management controller.
The Ethernet Type field contains 0x86DD (IPv6).
The IPv6 Destination Address field contains the IPv6 address assigned to the
management controller.
The IP Protocol field contains 17 (UDP).
The UDP Destination Port field contains 546 (DHCPv6 Protocol Client).
7RMCP Primary port - UDP
packets received from wire
0x1 = Forward this packet type to the Management Controller only
0x0 = Forward this packet type to the Host
For the purposes of this filter, a RMCP Primary port UDP packet is defined to be any
packet that meets all of the following requirements:
The Ethernet Destination Address field contains the MAC address assigned to
the management controller.
The Ethernet Type field contains 0x86DD (IPv6) 0r 0x0800 (IPv4).
The IP Destination Address field contains the one of the IP address assigned to
the management controller.
The IP Protocol field contains 17 (UDP).
The UDP Destination Port field contains 623 (Aux Bus Shunt (Primary RMCP
Port)).
Table 10-57. Unicast Infrastructure Packet Filter Settings Field
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10.6.3.14.5.1Enable Unicast Infrastructure Filter Response
The Network Controller shall, in the absence of a checksum error or identifier mismatch, always accept
the Enable Unicast Infrastructure Filter command and send a response, using the format specified in
Table 10-58. Currently no command-specific reason codes are identified for this response.
10.6.3.14.6 Get Shared IP Capabilities Command (Intel Command 0x25, Index = 0x5)
8RMCP Primary port - TCP
packets received from wire
0x1 = Forward this packet type to the Management Controller only
0x0 = Forward this packet type to the Host
For the purposes of this filter, a RMCP Primary port TCP packet is defined to be any
packet that meets all of the following requirements:
The Ethernet Destination Address field contains the MAC address assigned to
the management controller.
The Ethernet Type field contains 0x86DD (IPv6) 0r 0x0800 (IPv4).
The IP Destination Address field contains the one of the IP address assigned to
the management controller.
The IP Protocol field contains 6 (TCP).
The TCP Destination Port field contains 623 (Aux Bus Shunt (Primary RMCP
Port)).
9RMCP Secondary port - UDP
packets received from wire
0x1 = Forward this packet type to the Management Controller only
0x0 = Forward this packet type to the Host
For the purposes of this filter, a RMCP Secondary port TCP packet is defined to be
any packet that meets all of the following requirements:
The Ethernet Destination Address field contains the MAC address assigned to
the management controller.
The Ethernet Type field contains 0x86DD (IPv6) 0r 0x0800 (IPv4).
The IP Destination Address field contains the one of the IP address assigned to
the management controller.
The IP Protocol field contains 17 (UDP).
The UDP Destination Port field contains 664 (Secure Aux Bus (Secondary RMCP
Port)).
10 RMCP Secondary port - TCP
packets received from wire
0x1 = Forward this packet type to the Management Controller only
0x0 = Forward this packet type to the Host
For the purposes of this filter, a RMCP Secondary port TCP packet is defined to be
any packet that meets all of the following requirements:
The Ethernet Destination Address field contains the MAC address assigned to
the management controller.
The Ethernet Type field contains 0x86DD (IPv6) 0r 0x0800 (IPv4).
The IP Destination Address field contains the one of the IP address assigned to
the management controller.
The IP Protocol field contains 6 (TCP).
The TCP Destination Port field contains 664 (Secure Aux Bus (Secondary RMCP
Port)).
11..31 Reserved None
Table 10-58. Enable Unicast Infrastructure Filter Response Packet Format
Bits
00..15 NC-SI Header
16..19 Response Code Reason Code
20..23 Manufacturer ID (Intel 0x157)
24..27 0x25 0x4 Reserved
28..29 Checksum
Table 10-57. Unicast Infrastructure Packet Filter Settings Field
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A Management Controller uses the Get Shared IP Capabilities command to determine the level of
support of shared IP of the device. The format of a Get Shared IP Capabilities command packet is
specified in Table 10-59.
10.6.3.14.6.1Get Shared IP Capabilities Response
The Network Controller shall, in the absence of a checksum error or identifier mismatch, always accept
the Get Shared IP Capabilities command and send a response, using the format specified in Table 10-
60. Currently no command-specific reason codes are identified for this response.
Number of mixed IP addresses - The number of supported IP filters that can be used for IPv4 or
IPv6. The I210 do not support mixed IP address filters.
Number of IPv4 only addresses - The number of supported IP filters that can be used for IPv4 only.
The I210 supports four IPv4 address filters.
Number of IPv6 only addresses - The number of supported IP filters that can be used for IPv6 only.
The I210 supports three IPv6 address filters.
Number of Ports - The number of supported Port filters. The I210 supports ten ports.
Number of bindings - Defines the number of IP addresses that can be bound with different ports.
The I210 supports three bindings.
Unicast Infrastructure Filter capabilities - Defines the optional Unicast Infrastructure Filter
capabilities that the channel supports. The bit definitions for this field correspond directly with the
bit definitions for the Unicast Infrastructure Filter Settings field defined for the Unicast
Infrastructure Filter command in Table 10-57. A bit set to 1 indicates that the channel supports the
filter associated with that bit position; otherwise, the channel does not support that filter. The I210
supports all filters except ICMPv6 filtering, as such, the returned value is 0x7FB.
Table 10-59. Get Shared IP Capabilities Command Packet Format
Bits
Bytes 31..24 23..16 15..08 07..00
00..15 NC-SI Header
16..19 Manufacturer ID (Intel 0x157)
20..23 0x25 0x5 Reserved
24..27 Checksum
Table 10-60. Get Shared IP Capabilities Response Packet Format
Bits
Bytes 31..24 23..16 15..08 07..00
00..15 NC-SI Header
16..19 Response Code Reason Code
20..23 Manufacturer ID (Intel 0x157)
24..27 0x25 0x5 Number of Mixed IP
address Number of IPv4 only
addresses
28..31 Number of IPv6 only
addresses Number of Ports Number of bindings Filtering capabilities
32..35 Unicast Infrastructure Filter capabilities
36..30 Checksum
System Manageability—Ethernet Controller I210
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Table 10-61 describes the bits fields in the Filtering Capabilities field.
10.6.3.14.7 Shared IP Enable Broadcast Filtering Command (Intel Command 0x25, Index =
0x6)
A new Shared IP Enable Broadcast Filtering is defined to allow the Management Controller to limit the
flow of ARP requests to those that contain a Target IP Address value that matches the Management
Controller IP Address.
This command should be used instead of the regular NC-SI Enable Broadcast Filtering command.
Note: Reception of a standard NC-SI Enable Broadcast Filtering command will enable the matching
bits in this command. Reception of a standard NC-SI Disable Broadcast Filter Command will
clear the settings in this command.
The format of an Shared IP Enable Broadcast Filtering command packet is specified in Table 10-56.
Table 10-61. Filtering Capabilities Field
Bit Position Field Description Value Description
0 IPv4 support 0 = IPv4 filtering is not supported
1 = IPv4 filtering is supported
1 IPv6 support 0 = IPv6 filtering is not supported
1 = IPv6 filtering is supported
2 Protocol filtering support 0 = Filtering by protocol is not supported
1 = Filtering by protocol is supported
3 Source port filtering support 0 = Port Filtering is supported only for destination port
1 = Port Filtering is supported for destination port or source port.
7:4 Reserved Reserved
Table 10-62. Shared IP Enable Broadcast Filtering Command
Bits
Bytes 31..24 23..16 15..08 07..00
00..15 NC-SI Header
16..19 Manufacturer ID (Intel 0x157)
20..23 0x25 0x6 Reserved
24..27 Shared IP Broadcast Packet Filter Settings
28..31 Checksum
32..35 Padding
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The content of the Shared IP Broadcast Packet Filter Settings field is specified in Table 10-63. Bit 4 has
been added to the standard Enable Broadcast Filtering Command Limit ARP Broadcast Packets to
Management Controller IP Address.
10.6.3.14.7.1Shared IP Enable Broadcast Filtering Response
The Network Controller shall, in the absence of a checksum error or identifier mismatch, always accept
the Shared IP Enable Broadcast Filtering command and send a response, using the format specified in
Table 10-58. Currently no command-specific reason codes are identified for this response.
10.6.3.14.8 Shared IP Enable Global Multicast Filtering Command (Intel Command 0x25,
Index = 0x7)
A new Shared IP Enable Global Multicast Filtering is defined to allow the Management Controller to
enable the forwarding of IEEE 802.1X Extensible Authentication Protocol over LAN (EAPOL) frames to
the Management Controller IP Address. IEEE 802.1X defines methods for port-based network access
control.
This command should be used instead of the regular NC-SI Enable Global Multicast Filtering command.
Note: Reception of a standard NC-SI Enable Global Multicast Filtering command will enable the
matching bits in this command. Reception of a standard NC-SI Disable Global Multicast Filter
Command will clear the settings in this command.
Table 10-63. Shared IP Broadcast Packet Filter Settings Field
Bit Position Field Description Value Description
0:3 As defined in DSP0222 As defined in DSP0222 in 8.4.33 Enable Broadcast Filter Command (0x10) - table
68
4Limit ARP Broadcast
Packets to Management
Controller IP Address.
When bit 0 is set, this bit can be set to limit the flow of ARP packets to the
Management Controller as follows:
0x1 = Forward only ARP broadcast packets that are targeted at IP addresses
bound to the Management Controller.
0x0 = Forward all ARP broadcast packets to the Management Controller.
All the IPs set by the Set IP command before this command is given will be
included in forwarding.
This field is optional. If unsupported, the behavior for ARP packets will be set
according to bit 0 in this structure. The value shall be set to 0 if unsupported.
5:31 Reserved None
Table 10-64. Shared IP Enable Broadcast Filtering Packet Format
Bits
00..15 NC-SI Header
16..19 Response Code Reason Code
20..23 Manufacturer ID (Intel 0x157)
24..27 0x25 0x6 Reserved
28..29 Checksum
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The format of an Shared IP Enable Global Multicast Filtering command packet is specified in Table 10-
65.
The content of the Shared IP Multicast Packet Filter Settings field is specified in Table 10-66. Bit 4 has
been added to the standard Enable Broadcast Filtering Command Limit ARP Broadcast Packets to
Management Controller IP Address.
10.6.3.14.8.1Shared IP Enable Global Multicast Filtering Response
The Network Controller shall, in the absence of a checksum error or identifier mismatch, always accept
the Shared IP Enable Global Multicast Filtering command and send a response, using the format
specified in Table 10-67. Currently no command-specific reason codes are identified for this response.
Table 10-65. Shared IP Enable Global Multicast Filtering Command
Bits
Bytes 31..24 23..16 15..08 07..00
00..15 NC-SI Header
16..19 Manufacturer ID (Intel 0x157)
20..23 0x25 0x7 Reserved
24..27 Shared IP Multicast Packet Filter Settings
28..31 Checksum
32..35 Padding
Table 10-66. Shared IP Multicast Packet Filter Settings Field
Bit Position Field Description Value Description
0:2 As defined in DSP0222 As defined in DSP0222 in 8.4.37 Enable Global Multicast Filter Command (0x12) -
table 74
3 IEEE 802.1X EAPOL
0x1 = Forward this packet type to the Management Controller
0x0 = Filter out this packet type
For the purposes of this filter, a IEEE 802.1X multicast packet is defined to be any
packet that meets all of the following requirements:
The destination MAC address field is set to the layer 2 multicast address
01:80:c2:00:00:03.
The EtherType field is set to 0x888E (802.1X PAE).
This field is optional. If unsupported, multicast 802.1X packets will be blocked
when multicast filtering is enabled, unless they are matched by an address filter
configured using the Set MAC Address command. The value shall be set to 0 if
unsupported.
4:31 Reserved None
Table 10-67. Shared IP Enable Global Multicast Filtering Packet Format
Bits
00..15 NC-SI Header
16..19 Response Code Reason Code
20..23 Manufacturer ID (Intel 0x157)
24..27 0x25 0x7 Reserved
28..29 Checksum
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10.6.3.14.9 Get Shared IP Parameters Command (Intel Command 0x25, Index = 0x8)
The Get Shared IP parameters command can be used by the Management Controller to request that the
channel send the Management Controller a copy of part of the currently stored parameter settings that
have been put into effect by the Management Controller related to shared IP filtering. The format of a
Get Shared IP Capabilities command packet is specified in Table 10-68.
10.6.3.14.9.1Get Shared IP Parameters Response
The Network Controller shall, in the absence of a checksum error or identifier mismatch, always accept
the Get Shared IP Parameters command and send a response, using the format specified in Table 10-
69. Currently no command-specific reason codes are identified for this response.
Number of IP addresses - The number of supported IP filters including all the types of IP addresses
(IPv4 only, IPv6 only and mixed).
IP address flags: The enable/disable state for each supported IP address. See Table 10-70.
Table 10-68. Get Shared IP Parameters Command Packet Format
Bits
Bytes 31..24 23..16 15..08 07..00
00..15 NC-SI Header
16..19 Manufacturer ID (Intel 0x157)
20..23 0x25 0x8 Reserved
24..27 Checksum
Table 10-69. Get Shared IP Parameters Response Packet Format
Bits
Bytes 31..24 23..16 15..08 07..00
00..15 NC-SI Header
16..19 Response Code Reason Code
20..23 Manufacturer ID (Intel 0x157)
24..27 0x25 0x8 Reserved
28..31 Number of IP Addresses IP addresses Flags
32..35 Number of ports Ports Flags
36..39 Unicast Infrastructure Filter Settings
40..43 Broadcast Filtering Settings
44..47 Multicast Filtering Settings
48..51 Checksum
Table 10-70. IP address flags Field
Bit Position Field Description Value Description
0 IP address 1 status 0b = Default or unsupported or disabled
1b = Enabled
1IP address 2 status or
Reserved
0b = Default or unsupported or disabled
1b = Enabled
System Manageability—Ethernet Controller I210
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Note: IP address flags are organized in the following order: IPv4 addresses first, followed by IPv6
addresses, followed by mixed addresses, with the number of each corresponding to those
reported through the Get Shared IP Capabilities command. For example, if the interface
reports four IPv4 filters, two IPv6 filters, and two mixed filters, then IP addresses 1 through 4
are those currently configured through the interface’s IPv4 filters, IP addresses 5 and 6 are
those configured through the IPv6 filters, and 7 and 8 are those configured through the
mixed filters.
Note: The actual settings of each enabled IP address can be found using the Get IP address
command
Number of Ports - The number of supported Port filters.
Port flags: The enable/disable state for each supported ports. See Table 10-70
Note: The actual settings of each enabled port can be found using the Get Port command
Unicast Infrastructure Filter settings - Defines the optional Unicast Infrastructure Filter capabilities
settings. The bit definitions for this field correspond directly with the bit definitions for the Unicast
Infrastructure Filter Settings field defined for the Unicast Infrastructure Filter command in Table 10-
57. A bit set to 1 indicates that the filter associated with that bit position is enabled; otherwise, the
filter is not enabled.
Broadcast Filter settings - Defines the optional Broadcast Filter settings. The bit definitions for this
field correspond directly with the bit definitions for the Broadcast Filter Settings field defined for the
Shared IP Broadcast Filtering command in Table 10-63. A bit set to 1 indicates that the filter
associated with that bit position is enabled; otherwise, the filter is not enabled.
Global Multicast Filter settings - Defines the optional Multicast Filter capabilities settings. The bit
definitions for this field correspond directly with the bit definitions for the Multicast Filter Settings
field defined for the Shared IP Global Multicast Filtering command in Table 10-63. A bit set to 1
indicates that the filter associated with that bit position is enabled; otherwise, the filter is not
enabled.
10.6.3.14.10 Set Binding Command (Intel Command 0x25, Index = 0x9)
2IP address 3 status or
Reserved
0b = Default or unsupported or disabled
1b = Enabled
...
23 IP address 24 status or
Reserved
0b = Default or unsupported or disabled
1b = Enabled
Table 10-71. Port flags Field
Bit Position Field Description Value Description
0 Port 1 status 0b = Default or unsupported or disabled
1b = Enabled
1 Port 2 status or Reserved 0b = Default or unsupported or disabled
1b = Enabled
2 Port 3 status or Reserved 0b = Default or unsupported or disabled
1b = Enabled
...
23 Port 24 status or Reserved 0b = Default or unsupported or disabled
1b = Enabled
Table 10-70. IP address flags Field
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The Set Binding command is used by the Management Controller to define which combination of MAC
addresses, VLAN tags, IP addresses and TCP/UDP ports should be forwarded to the MC. The format of a
Set Binding command packet is specified in Table 10-72.
Once a Set Binding command is activated, all the previous forwarding rules based on the Set MAC
Address or Set VLAN filter commands are disabled and should be re-enabled using the Set Binding
command. Subsequent Set MAC Address or Set VLAN filter commands will be used to enable MAC or
VLAN addresses for the Set Binding command but will not impact the forwarding rules.
Table 10-73 describes the fields in the Set Binding Flags field.
Binding Index: Indicates which binding is configured by the command.The value should be smaller
than the number of supported bindings as reported in the Get Shared IP Capabilities Response in
the Number of Bindings field.
Enabled MAC addresses: The MAC addresses participating in this binding. The numbering of the
MAC addresses is simillar to the one used in the MAC Address Flags in the Get Parameters
Response. Namely, MAC addresses are returned in the following order: unicast filtered addresses
first, followed by multicast filtered addresses, followed by mixed filtered addresses, with the
number of each corresponding to those reported through the Get Capabilities command.A MAC
Table 10-72. Set Binding Command Packet Format
Bits
Bytes 31..24 23..16 15..08 07..00
00..15 NC-SI Header
16...19 Manufacturer ID (Intel 0x157)
20..23 0x25 0x9 Binding Index Set Binding Flags
24..27 Enabled MAC addresses
28..31 Enabled VLAN
32..35 Enabled IP addresses
36..39 Enabled Ports (MSB)
40..43 Enabled Ports (LSB)
44..47 Checksum
Table 10-73. Set Binding Flags Field Descriptions
Bit Position Field Description Value Description
0 Enable 0 = Disable the binding
1 = Enable the binding
1 Exclusive to MC 0 = Traffic matching this filter is sent to MC and to host
1 = Traffic matching this filter is sent to MC only.
2 Apply to network1
1. At least one of the Apply to network/host flags should be set for enabled bindings. Clearing both of them is equivalent to disabling
the filter.
0 = Do not compare traffic received from the network when checking this
binding.
1 = Compare traffic received from the network when checking this binding.
3 Apply to host 0 = Do not compare traffic received from the host when checking this
binding.
1 = Compare traffic received from the host when checking this binding.
7:4 Reserved Reserved
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address can be added to a binding only if previously enabled through a Set MAC Address NC-SI
command
Enabled VLAN: The VLAN IDs participating in this binding. The numbering of the VLAN IDs. A VLAN
tag can be added to a binding only if previously enabled through a Set VLAN Filter NC-SI command.
Enabled IP addresses: The IP addresses participating in this binding. The numbering of the IP
addresses is simillar to the one used in the Get Shared IP Parameters Response
(Section 10.6.3.14.9). An IP address can be added to a binding only if previously enabled through a
Set IP Address Intel OEM command.
Enabled Ports: The ports participating in this binding. A Port can be added to a binding only if
previously enabled through a Set Port Intel OEM command.
10.6.3.14.10.1Set Binding Address Response
The Network Controller shall, in the absence of a checksum error or identifier mismatch, always accept
the Set Binding command and send a response, using the format specified in Table 10-74.
10.6.3.14.11 Get Binding Command (Intel Command 0x25, Index = 0xA)
A Management Controller uses the Get Binding command to determine the current programming of one
of the bindings in a Network Controller. The format of a Get Binding command packet is specified in
Table 10-75.
Binding Index: Indicates which binding is requested by the command.The value should be smaller
than the number of supported bindings as reported in the Get Shared IP Capabilities Response in
the Number of Bindings field.
Table 10-74. Set Binding Response Packet Format
Bits
Bytes 31..24 23..16 15..08 07..00
00..15 NC-SI Header
16..19 Response Code Reason Code
20..23 Manufacturer ID (Intel 0x157)
24..27 0x25 0x9 Reserved
28..31 Checksum
Table 10-75. Get Binding Command Packet Format
Bits
Bytes 31..24 23..16 15..08 07..00
00..15 NC-SI Header
16..19 Manufacturer ID (Intel 0x157)
20..23 0x25 0xA Binding Number Reserved
24..27 Checksum
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10.6.3.14.11.1Get Binding Response
The Network Controller shall, in the absence of a checksum error or identifier mismatch, always accept
the Get Binding command and send a response, using the format specified in Table 10-76.
The fields in the Get Binding response are equivalent to their counterparts in the Set Binding Command.
10.6.3.14.12Set Shared Mode Command (Intel Command 0x25, Index = 0xB)
A Management Controller uses the Set Shared Mode command to indicate to the NIC it intends to work
in shared MAC/IP mode or in dedicated MAC mode.
If used, this command should be sent before any of the regular or OEM NC-SI commands used to set
forwarding filters. When this command is received, all the filters are cleared. This command is only
needed when the Intel OEM commands with command ID 0x25 are used to configure the shared
behavior. If other commands are used, the user should take care of the right configuration of the filters.
When Shared mode is activated, the Set MAC and Set VLAN NC-SI commands will not impact the
receive filtering until a Set Binding, or Enable Unicast Infrastructure Filter command is received.
Any other command from this section (11.6.3.16) received before shared mode is set are failed with a
Not is Shared Mode (0x5092) reason.
The format of a Set Shared Mode command packet is specified in Table 10-77.
Shared Mode:
Table 10-76. Get Binding Response Packet Format
Bits
Bytes 31..24 23..16 15..08 07..00
00..15 NC-SI Header
16..19 Response Code Reason Code
20..23 Manufacturer ID (Intel 0x157)
24..27 0x25 0xA Binding Number Get Binding flags
28..31 Enabled MAC addresses
32..35 Enabled VLAN
36..39 Enabled IP addresses
40..43 Enabled Ports (MSB)
44..47 Enabled Ports (LSB)
48..51 Checksum
Table 10-77. Set Shared Mode Command Packet Format
Bits
Bytes 31..24 23..16 15..08 07..00
00..15 NC-SI Header
16..19 Manufacturer ID (Intel 0x157)
20..23 0x25 0xB Shared Mode Reserved
24..27 Checksum
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0x0: Dedictated MAC mode
0x1: Shared MAC/IP mode.
10.6.3.14.12.1Set Shared Mode Response
The Network Controller shall, in the absence of a checksum error or identifier mismatch, always accept
the Set Shared Mode command and send a response, using the format specified in Table 10-78.
10.6.3.15 OS2BMC Configuration
These commands control enabling of the OS2BMC flow.
10.6.3.15.1 Enable OS2BMC Flow Command (Intel Command 0x40, Index 0x1)
10.6.3.15.2 EnableOS2BMC Flow Response (Intel Command 0x40, Index 0x1)
10.6.3.15.3 Enable Network to MC Flow Command (Intel Command 0x40, Index 0x2)
Table 10-78. Set Shared Mode Response Packet Format
Bits
Bytes 31..24 23..16 15..08 07..00
00..15 NC-SI Header
16..19 Response Code Reason Code
20..23 Manufacturer ID (Intel 0x157)
24..27 0x25 0xB Shared Mode Reserved
48..51 Checksum
Bits
Bytes 31:24 23:16 15:08 07:00
00...15 NC-SI Header
16...19 Manufacturer ID (Intel 0x157)
20...21 0x40 0x01
Bits
Bytes 31:24 23:16 15:08 07:00
00...15 NC-SI Header
16...19 Response Code Reason Code
20...23 Manufacturer ID (Intel 0x157)
24...25 0x40 0x01
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10.6.3.15.4 Enable Network to MC Flow Response (Intel Command 0x40, Index 0x2)
10.6.3.15.5 Enable Both Host and Network to MC Flows Command (Intel Command 0x40,
Index 0x3)
10.6.3.15.6 Enable Both Host and Network to MC Flows Response (Intel Command 0x40,
Index 0x3)
10.6.3.15.7 Get OS2BMC Parameters Command (Intel Command 0x41)
Bits
Bytes 31:24 23:16 15:08 07:00
00...15 NC-SI Header
16...19 Manufacturer ID (Intel 0x157)
20...21 0x40 0x02
Bits
Bytes 31:24 23:16 15:08 07:00
00...15 NC-SI Header
16...19 Response Code Reason Code
20...23 Manufacturer ID (Intel 0x157)
24...25 0x40 0x02
Bits
Bytes 31:24 23:16 15:08 07:00
00...15 NC-SI Header
16...19 Manufacturer ID (Intel 0x157)
20...21 0x40 0x03
Bits
Bytes 31:24 23:16 15:08 07:00
00...15 NC-SI Header
16...19 Response Code Reason Code
20...23 Manufacturer ID (Intel 0x157)
24...25 0x40 0x03
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10.6.3.15.8 Get OS2BMC parameters Response (Intel Command 0x41)
Where the Status byte partition is as follow:
10.6.3.16 Get Controller information Command (Intel Command 0x48, Index 0x1)
This command gather the controller identification information and return it back to the MC.
Bits
Bytes 31:24 23:16 15:08 07:00
00...15 NC-SI Header
16...19 Manufacturer ID (Intel 0x157)
20 0x41
Bits
Bytes 31:24 23:16 15:08 07:00
00...15 NC-SI Header
16...19 Response Code Reason Code
20...23 Manufacturer ID (Intel 0x157)
24...27 0x41 Status
Table 10-79. Status Byte Description
Bits Content
1:0 Reserved
2
Network to MC status
0 = network 2 MC flow is disabled
1 = network 2 MC flow is enabled.
3
OS2BMC status
0 = OS 2 MC flow is disabled
1 = OS 2 MC flow is enabled.
7:4 Reserved.
Bits
Bytes 31:24 23:16 15:08 07:00
00...15 NC-SI Header
16...19 Manufacturer ID (Intel 0x157)
20...23 0x48 0x1
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10.6.3.16.1 Get Controller Information Response (Intel Command 0x48, Index 0x1)
Where the possible information items are as described below. Note that not all the inventory items
would be present in all the implementations of this command.
10.6.4 Basic NC-SI Workflows
10.6.4.1 Package States
A NC package can be in one of the following two states:
1. Selected — The package is allowed to use the NC-SI lines, meaning the NC package might send
data to the BMC.
2. De-selected The package is not allowed to use the NC-SI lines, meaning, the NC package cannot
send data to the BMC.
Bits
Bytes 31:24 23:16 15:08 07:00
00...15 NC-SI Header
16...19 Response Code Reason Code
20...23 Manufacturer ID (Intel 0x157)
24...27 0x48 0x01 Reserved Number of Inventory
entries
28...31 Controller Info Item
1ID Controller Info Item 1
length Controller Info Item 1 Data
... ....
... Controller Info Item 2
ID Controller Info Item 2
length Controller Info Item 2 Data
... ....
... Controller Info Item n
ID Controller Info Item n
length Controller Info Item n Data
... ....
Table 10-80. Controller Info Items
ID Length (in
bytes) Data Notes
0x00 3 Device ID (2 bytes) + RevID This is the HW default value, not any
value programmed via Flash.
0x0B 2 Flash Image Revision
0x0C 4 Internal Firmware ROM version
0x0D 4 Internal Firmware Flash version
0x0E 2 PXE Firmware version
MajorVersion.MinorVersion.Build0x0F 2 iSCSI Firmware version
0x10 2 uEFI Firmware version
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The BMC must select no more than one NC package at any given time. Package selection can be
accomplished in one of two methods:
1. Select Package command — This command explicitly selects the NC package.
2. Any other command targeted to a channel in the package also implicitly selects that NC package.
Package de-select can be accomplished only by issuing the De-Select Package command. The BMC
should always issue the Select Package command as the first command to the package before issuing
channel-specific commands. For further details on package selection, refer to the NC-SI specification.
10.6.4.2 Channel States
A NC channel can be in one of the following states:
1. Initial State The channel only accepts the Clear Initial State command (the package also accepts
the Select Package and De-Select Package commands).
2. Active state — This is the normal operational mode. All commands are accepted.
For normal operation mode, the BMC should always send the Clear Initial State command as the first
command to the channel.
10.6.4.3 Discovery
After interface power-up, the BMC should perform a discovery process to discover the NCs that are
connected to it. This process should include an algorithm similar to the following:
1. For package_id=0x0 to MAX_PACKAGE_ID
a. Issue Select Package command to package ID package_id
b. If a response was received then
For internal_channel_id = 0x0 to MAX_INTERNAL_CHANNEL_ID
Issue a Clear Initial State command for package_id | internal_channel_id (the combination of
package_id and internal_channel_id to create the channel ID).
If a response was received then
Consider internal_channel_id as a valid channel for the package_id package
The BMC can now optionally discover channel capabilities and version ID for the channel
Else (If not a response was not received, then issue a Clear Initial State command three times.
Issue a De-Select Package command to the package (and continue to the next package).
c. Else, if a response was not received, issue a Select Packet command three times.
10.6.4.4 Configurations
This section details different configurations that should be performed by the BMC.
The BMC should not consider any configuration valid unless the BMC has explicitly configured it after
every reset (entry into the initial state). As a result, the BMC should re-configure everything at power-
up and channel/package resets.
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10.6.4.4.1 NC Capabilities Advertisement
NC-SI defines the Get Capabilities command. It is recommended that the BMC use this command and
verify that the capabilities match its requirements before performing any configurations. For example,
the BMC should verify that the NC supports a specific AEN before enabling it.
10.6.4.4.2 Receive Filtering
In order to receive traffic, the BMC must configure the NC with receive filtering rules. These rules are
checked on every packet received on the LAN interface (such as from the network). Only if the rules
matched, will the packet be forwarded to the BMC.
10.6.4.4.2.1 MAC Address Filtering
NC-SI defines three types of MAC address filters: unicast, multicast and broadcast. To be received (not
dropped) a packet must match at least one of these filters. The BMC should set one MAC address using
the Set MAC Address command and enable broadcast and global multicast filtering.
Unicast/Exact Match (Set MAC Address Command)
This filter filters on specific 48-bit MAC addresses. The BMC must configure this filter with a dedicated
MAC address.
The NC might expose three types of unicast/exact match filters (such as MAC filters that match on the
entire 48 bits of the MAC address): unicast, multicast and mixed. The I210 exposes two mixed filters,
which might be used both for unicast and multicast filtering. The BMC should use one mixed filter for its
MAC address.
Note: The MNGONLY bit matching the unicast filter (bit 5) is set by the first set MAC address
command received from the BMC. It will not be cleared by further commands. If the MAC
address is shared with the host and filter reductions are applied, the MNGONLY bit of the
unicast filter should be cleared after each Set MAC address command using the Set Intel
Filters — Manageability Only Command (Section 10.6.3.5.3).
Refer to NC-SI specification — Set MAC Address for further details.
Broadcast (Enable/Disable Broadcast Filter Command)
NC-SI defines a broadcast filtering mechanism which has the following states:
1. Enabled — All broadcast traffic is blocked (not forwarded) to the BMC, except for specific filters
(such as ARP request, DHCP, and NetBIOS).
2. Disabled — All broadcast traffic is forwarded to the BMC, with no exceptions.
Refer to NC-SI specification Enable/Disable Broadcast Filter command.
Global Multicast (Enable/Disable Global Multicast Filter)
NC-SI defines a multicast filtering mechanism which has the following states:
1. Enabled — All multicast traffic is blocked (not forwarded) to the BMC.
2. Disabled — All multicast traffic is forwarded to the BMC, with no exceptions.
The recommended operational mode is Enabled, with specific filters set. Not all multicast filtering
modes are necessarily supported. Refer to NC-SI specification Enable/Disable Global Multicast Filter
command for further details.
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10.6.4.4.3 VLAN
NC-SI defines the following VLAN work modes:
Refer to NC-SI specification — Enable VLAN command for further details.
The I210 only supports modes #1 and #3. Recommendation:
1. Modes:
a. If VLAN is not required — Use the disabled mode.
b. If VLAN is required — Use the enabled #1 mode.
2. If enabling VLAN, The BMC should also set the active VLAN ID filters using the NC-SI Set VLAN
Filter command prior to setting the VLAN mode.
10.6.4.5 Pass-Through Traffic States
The BMC has independent, separate controls for enablement states of the receive (from LAN) and of the
transmit (to LAN) pass-through paths.
10.6.4.6 Channel Enable
This mode controls the state of the receive path:
1. Disabled — The channel does not pass any traffic from the network to the BMC.
2. Enabled The channel passes any traffic from the network (that matched the configured filters) to
the BMC.
This state also affects AENs: AENs is only sent in the enabled state.
The default state is disabled.
It is recommended that the BMC complete all filtering configuration before enabling the channel.
10.6.4.7 Network Transmit Enable
This mode controls the state of the transmit path:
1. Disabled — the channel does not pass any traffic from the BMC to the network.
2. Enabled — the channel passes any traffic from the BMC (that matched the source MAC address
filters) to the network.
The default state is disabled.
Mode Command and Name Descriptions
Disabled Disable VLAN command In this mode, no VLAN frames are received.
Enabled #1 Enable VLAN command with VLAN only In this mode, only packets that matched a VLAN
filter are forwarded to the BMC.
Enabled #2 Enable VLAN command with VLAN only + non-VLAN In this mode, packets from mode 1 + non-VLAN
packets are forwarded.
Enabled #3 Enable VLAN command with Any-VLAN + non-VLAN In this mode, packets are forwarded regardless of
their VLAN state.
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The NC filters pass-through packets according to their source MAC address. The NC tries to match that
source MAC address to one of the MAC addresses configured by the Set MAC Address command. As a
result, the BMC should enable network transmit only after configuring the MAC address.
It is recommended that the BMC complete all filtering configuration (especially MAC addresses) before
enabling the network transmit.
This feature can be used for fail-over scenarios. See Section 10.6.8.3.
10.6.5 Asynchronous Event Notifications
The asynchronous event notifications are unsolicited messages sent from the NC to the BMC to report
status changes (such as link change, operating system state change, etc.).
Recommendations:
The BMC firmware designer should use AENs. To do so, the designer must take into account the
possibility that a NC-SI response frame (such as a frame with the NC-SI EtherType), arrives out-of-
context (not immediately after a command, but rather after an out-of-context AEN).
To enable AENs, the BMC should first query which AENs are supported, using the Get Capabilities
command, then enable desired AEN(s) using the Enable AEN command, and only then enable the
channel using the Enable Channel command.
10.6.6 Querying Active Parameters
The BMC can use the Get Parameters command to query the current status of the operational
parameters.
10.6.7 Resets
In NC-SI there are two types of resets defined:
1. Synchronous entry into the initial state.
2. Asynchronous entry into the initial state.
Recommendations:
It is very important that the BMC firmware designer keep in mind that following any type of reset,
all configurations are considered as lost and thus the BMC must re-configure everything.
As an asynchronous entry into the initial state might not be reported and/or explicitly noticed, the
BMC should periodically poll the NC with NC-SI commands (such as Get Version ID, Get Parameters,
etc.) to verify that the channel is not in the initial state. Should the NC channel respond to the
command with a Clear Initial State Command Expected reason code, the BMC should consider the
channel (and most probably the entire NC package) as if it underwent a (possibly unexpected)
reset event. Thus, the BMC should re-configure the NC. See the NC-SI specification section on
Detecting Pass-through Traffic Interruption.
The Intel recommended polling interval is 2-3 seconds.
For exact details on the resets, refer to NC-SI specification.
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10.6.8 Advanced Workflows
10.6.8.1 Multi-NC Arbitration
As described in Section 10.6.1.2, in a multi-NC environment, there is a need to arbitrate the NC-SI
lines.
Figure 10-7 shows the system topology of such an environment.
See Figure 10-7. The NC-SI Rx lines are shared between the NCs. To enable sharing of the NC-SI Rx
lines, NC-SI has defined an arbitration scheme.
The arbitration scheme mandates that only one NC package can use the NC-SI Rx lines at any given
time. The NC package that is allowed to use these lines is defined as selected. All the other NC
packages are de-selected.
NC-SI has defined two mechanisms for the arbitration scheme:
1. Package selection by the BMC. In this mechanism, the BMC is responsible for arbitrating between
the packages by issuing NC-SI commands (Select/De-Select Package). The BMC is responsible for
having only one package selected at any given time.
2. Hardware arbitration. In this mechanism, two additional pins on each NC package are used to
synchronize the NC package. Each NC package has an ARB_IN and ARB_OUT line and these lines
are used to transfer Tokens. A NC package that has a token is considered selected.
Note: Hardware arbitration is enabled by the NC-SI ARB Enable Flash bit (See Section 6.2.22) and
the NC-SI HW arbitration support Flash bit (see Section 6.8.5.7).
For details on Hardware arbitration, refer to the NC-SI specification.
Figure 10-7. Multi-NC Environment
NC Package1
Channel1: 0x0
Channel2: 0x1
NC Package2
Channel1: 0x0
MC
NC-SI TX lines
HW-Arbitration lines
NC-SI RX lines
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10.6.8.2 Package Selection Sequence Example
Following is an example work flow for a BMC and occurs after the discovery, initialization, and
configuration.
Assuming the BMC needs to share the NC-SI bus between packages, the BMC should:
1. Define a time-slot for each device.
2. Discover, initialize, and configure all the NC packages and channels.
3. Issue a De-Select Package command to all the channels.
4. Set active_package to 0x0 (or the lowest existing package ID).
5. At the beginning of each time slot the BMC should:
a. Issue a De-Select Package to the active_package. The BMC must then wait for a response and
then an additional timeout for the package to become de-selected (200 s). See the NC-SI
specification table 10 — parameter NC Deselect to Hi-Z Interval.
b. Find the next available package (typically active_package = active_package + 1).
c. Issue a Select Package command to active_package.
10.6.8.3 Multiple Channels (Fail-Over)
In order to support a fail-over scenario, it is required from the BMC to operate two or more channels.
These channels might or might not be in the same package.
The key element of a fault-tolerance fail-over scenario is having two (or more) channels identifying to
the switch with the same MAC address, but only one of them being active at any given time (such as
switching the MAC address between channels). To accomplish this, NC-SI provides the following
commands:
1. Enable Network Tx command — This command enables shutting off the network transmit path of a
specific channel. This enables the BMC to configure all the participating channels with the same
MAC address but only enable one of them.
2. Link Status Change AEN or Get Link Status command.
10.6.8.3.1 Fail-Over Algorithm Example
The following is a sample workflow for a fail-over scenario for multiple the I210 GbE controllers
(multiple packages and one channel):
1. BMC initializes and configures all channels after power-up. However, the BMC uses the same MAC
address for all of the channels.
2. The BMC queries the link status of all the participating channels. The BMC should continuously
monitor the link status of these channels. This can be accomplished by listening to AENs (if used)
and/or periodically polling using the Get Link Status command.
3. The BMC then only enables channel 0 for network transmission.
4. The BMC then issues a gratuitous ARP (or any other packet with its source MAC address) to the
network. This packet informs the switch that this specific MAC address is registered to channel 0's
specific LAN port.
5. The BMC begins normal workflow.
6. Should the BMC receive an indication (AEN or polling) that the link status for the active channel
(channel 0) has changed, the BMC should:
a. Disable channel0 for network transmission.
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b. Check if a different channel is available (link is up).
c. If found:
Enable network TX for that specific channel.
Issue a gratuitous ARP (or any other packet with its source MAC address) to the network.
This packet informs the switch that this specific MAC address is registered to channel 0's
specific LAN port.
Resume normal workflow.
If not found, report the error and continue polling until a valid channel is found.
The above algorithm can be generalized such that the start-up and normal workflow are the same. In
addition, the BMC might need to use a specific channel (such as channel 0). In this case, the BMC
should switch the network transmit to that specific channel as soon as that channel becomes valid (link
is up).
Recommendations:
Wait for a link-down-tolerance timeout before a channel is considered invalid. For example, a link
re-negotiation might take a few seconds (normally 2 to 3 or might be up to 9). Thus, the link must
be re-established after a short time.
Typically, this timeout is recommended to be three seconds.
Even when enabling and using AENs, periodically poll the link status, as dropped AENs might not be
detected.
10.6.8.4 Statistics
The BMC might use the statistics commands as defined in NC-SI. These counters are meant mostly for
debug purposes and are not all supported.
The statistics are divided into three commands:
1. Controller statistics — These are statistics on the network interface (to the Host operating system
and pass through traffic). See the NC-SI specification for details.
2. NC-SI statistics These are statistics on the NC-SI control frames (such as commands, responses,
AENs, etc.). See the NC-SI specification for details.
3. NC-SI pass-through statistics — These are statistics on the NC-SI pass-through frames. See the
NC-SI specification for details.
10.6.9 External Link Control
The MC can use the NC-SI Set Link command to control the external interface link settings. This
command enables the MC to set the auto-negotiation, link speed, duplex, and other parameters.
This command is only available when the Host operating system is not present. Indicating the Host
operating system status can be obtained via the Get Link Status command and/or Host OS Status
Change AEN command.
Recommendation:
Unless explicitly needed, it is not recommended to use this feature. The NC-SI Set Link command
does not expose all the possible link settings and/or features. This might cause issues under
different scenarios. Even if you decided to use this feature, use it only if the link is down (trust the
I210 until proven otherwise).
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It is recommended that the MC first query the link status using the Get Link Status command. The
MC should then use this data as a basis and change only the needed parameters when issuing the
Set Link command.
For details, refer to the NC-SI specification.
10.6.9.1 Set Link While LAN PCIe Functionality is Disabled
In cases where the I210 is used solely for manageability and its LAN PCIe function is disabled, using the
NC-SI Set Link command while advertising multiple speeds and enabling auto-negotiation results in the
lowest possible speed chosen.
To enable link of higher a speed, the MC should not advertise speeds that are below the desired link
speed, as the lowest advertised link speed is chosen.
When the I210 is only used for manageability and the link speed advertisement is configured by the
MC, changes in the power state of the LAN device is not affected and the link speed is not re-negotiated
by the LAN device.
10.7 MCTP
10.7.1 MCTP Overview
The Management Component Transport Protocol (MCTP) defines a communication model intended to
facilitate communication between:
Management controllers and other management controllers
Management controllers and management devices
The communication model includes a message format, transport description, message exchange
patterns, and configuration and initialization messages.
The basic MCTP specification is described in DMTF’s DSP0236 document.
MCTP is designed so that it can potentially be used on many bus types. The protocol is intended to be
used for intercommunication between elements of platform management subsystems used in computer
systems, and is suitable for use in mobile, desktop, workstation, and server platforms.
Currently, specifications exists for MCTP over PCI Express (DMTF’s DSP0238) and over SMBus (DMTF’s
DSP0237). A specification for MCTP over USB is also planned.
Management controllers such as a baseboard management controller (MC) can use this protocol for
communication between one another, as well as for accessing management devices within the platform.
10.7.1.1 NC-SI over MCTP
MCTP is a transport layer protocol that do not include the functionality required to control the pass
through traffic required for MC connection to the network. This functionality is provided by
encapsulating NC-SI traffic as defined in DMTF’s DSP0222 document.
The details of NC_SI over MCTP protocol are defined in the NC-SI Over MCTP Specification.
Details of the NC-SI over MCTP can be found in Section 10.7.5.
System Manageability—Ethernet Controller I210
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The NC-SI over MCTP spec defines two types of MCTP message types: NC-SI (0x2) and Ethernet (0x3).
The I210 supports both messages. When used only for control, then only the NC-SI (0x2) message
type is supported.
In addition to the above message types supported by the I210, the PCIe based VDM message type is
also supported over PCIe to support ACL commands.
10.7.1.2 MCTP Usage Model
The I210 supports NC-SI over MCTP protocol over the PCI Express and SMBus busses. The I210 can
connect through MCTP to a MC or the ME engine in the chipset as described in Figure 10-8.
Figure 10-8. MCTP Connections of the I210
10.7.2 NC-SI to MCTP Mapping
The I210 LAN port (mapped as an NC-SI channel) is mapped to a single MCTP endpoint on SMBus and
to the same endpoint over PCIe.
PCIe Bus
SMBus
NIC
External
Network
MCTP over SMBus
BMC/ME
OS
MCTP VDM over PCIe
OS Traffic
Ethernet Controller I210 —System Manageability
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Both endpoints (SMBus and PCIe) may be active concurrently. However, pass through traffic may be
transferred only through one of them. If the PCIe endpoint is active, it will be used for pass through
traffic, otherwise, the SMBus endpoint will be used. Section 10.7.2.2 describes the transition between
the two busses.
For each channel (SMBus or PCIe), the I210 should expect MCTP commands from two sources: the bus
owner and the MC. In addition, it should expect pass through traffic through one interface only. Thus it
should be able to process up to five interleaved commands/data. Each source should not interleave
transactions it sends to the I210.
The topology used for MCTP connection is described in Figure 10-9.
Figure 10-9. MCTP Endpoints Topology
10.7.2.1 Detection of MC EID and Physical Address
In order to allow transactions between the MC and the NIC, the bus physical address (SMBus or PCIe)
and the EID of the partner needs to be discovered. The NICs do not try to discover the MC and assume
the MC will initiate the connection. If the NIC is in NC-SI initial state, then the EID and the physical
Port
NC-SI Channel
NC-SI Package
MCTP Endpoint PCIe
MCTP Endpoint SMBusSMBus I/F
Function
PCIe Bus I/F
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address of the MC are extracted from the Clear Initial State command parameters or any other NC-SI
command received later with a channel ID of the I210. Subsequent pass through traffic will be received
from or sent to this address only.
If the EID or the physical address of the NIC changes, it indicates the changes to bus owner so that the
routing tables can be updated. There is no attempt to directly send an indication to the MC about the
change.
See more details in next section.
10.7.2.2 Bus Transition
The following section defines the transition flow between PCIe and SMBus as the bus on which MCTP
flows. Figure 10-10 describes the flow to transition between PCIe and SMBus. The following parameters
are used to define the flow:
NIC EID on PCie
NIC EID on SMBus
NIC PCIe Target ID
Bus Owner EID on PCie
Bus Owner EID on SMBus
Bus Owner PCIe Target ID
Bus Owner SMBus address
MC EID on PCie
MC EID on SMBus
MC PCIe Target ID
MC SMBus address
NIC SMBus address
All these variables are initialized to zero at power on apart from the SMBus address of the endpoint
(NIC) which may be initialized from Flash value.
Ethernet Controller I210 —System Manageability
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Figure 10-10.MCTP Bus Transition State Machine
10.7.2.2.1 Initial Assignment Flow
At power on, the NIC or MC MCTP channel is connected to the SMBus, is not assigned an EID and is
in “Undiscovered” state.
The Bus Owner may preform an SMBus ARP cycle to assign an SMBus address to the NIC or to the
MC. Otherwise, a fixed address may be used. It is assumed that the SMBus address does not
change after init time.
The Bus Owner performs an EID assignment using a Set Endpoint ID MCTP command. The NIC or
the MC will capture the SMBus address of the Bus Owner from the SMBus Source Slave address
field, the Bus Owner EID from the Source endpoint ID field and the NIC/MC EID from the
Destination endpoint ID field in the MCTP header as described in section 10.3 of DSP0236. The NIC/
MC is now in “discovered” state
The MC may detect the NIC EID using one of the two following modes:
Static configuration of the NIC SMBus address in the MC database and Get Routing Table
Entries command to find the EID matching the SMBus address.
Get all endpoints through a Get Routing Table Entries command and find endpoints supporting
NC-SI using the Get Message Type Support command for each endpoint.
Once the NIC is found, the MC may send a Clear Initial State command to the NIC to start the NC-
SI configuration. The NIC will capture the MC SMBus address and MC EID from any NC-SI command
received.
PCIe
State Machine
SMBus
State Machine
Init
SMBus ARP / Get SMB Addr
SMBus Address in NVM
Reset
Discovered
SMB
Discovered
PCI-E
PCIe BME is cleared /
Stop PT
Any NC-SI over PCIe Command /
Capture PCIe BMC EID
Active PT = PCIe
Un-
discovered
SMB “Set End Point ID” /
Capture Bus owner EID
Enable NC-SI over SMBus reception
Un-discovered
Reset
PCI-E “Set End Point ID” /
Capture PCIe Bus Owner EID
Enable NCSI over PCI-E reception
Any NC-SI over SMBus Command /
Capture SMBus BMC EID
Active PT = SMBus
Any NC-SI command
over PCIe /
Capture PCIe BMC EID
Any NC-SI command over SMBus /
Capture BMC EID
Reset
Init
PCIe BME is set
/Send “Discovery Notify”
On PCIe
PCIe “prepare for
End point discovery” /
If (Active PT==PCIe)
Stop PT
PCIe BME
is cleared
PCIe BME is
cleared
SMB “Set End Point ID” /
Capture Bus owner EID
PCIe Address change /
Send “Discovery Notify
on PCI-E with new address
If (Active PT==PCIe) Stop PT
PCIe “Set End Point ID” /
Capture Bus owner EID
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After the NC-SI channels are enabled, traffic may be sent using the MC and NIC addresses
previously discovered.
The MC may send a Get UUID command to get a unique identifier of the NIC that may be used later
for reconnection upon topology changes.
10.7.2.2.2 SMBus to PCIe Transition
If the NIC or the MC detects that the PCIe bus is available by detecting a setting of the bus master
enable field in the PCIe configuration of one of the functions, it may request a transition using a
Discovery Notify MCTP command on the PCIe bus. This command should be sent with a “Route to
Root-complex” addressing as described in DSP0238 section 6.8.
Upon reception of the Discovery Notify MCTP command on the PCIe bus, the Bus Owner will send a
Set Endpoint ID MCTP command on the PCIe bus and will update the routing table. The Bus Owner
may choose to wait for the Discovery Notify MCTP command of both the MC and the NIC to do the
transition. The Bus Owner should try to keep the EID previously assigned on the SMBus as the EID
on PCIe bus.
Upon reception of the Set Endpoint ID MCTP command, the NIC will wait for an NC-SI command
from the MC indicating it is ready to transition the connection to PCIe. Upon reception of such a
command, the NIC will transition its pass through traffic to the PCIe bus using the newly received
addresses.
Note: If the I210 can not process the command received, it will respond with a Command Failed
(0x1) response code and a Package Not Ready (0x0004) reason code (Section 10.6.2.3). In
this case the transition will not occur and the MC should retry the command later.
The MC on its side, needs to discover the PCIe address of the NIC. This can be done using the
Resolve Endpoint ID command if only the physical address changed or using the Resolve Endpoint
UUID command also if both EID and physical address changed. It can then send an NC-SI
command to the NIC to initiate the transition. The MC should not send any pass through packets
from the moment it sent the first NC-SI command on the PCIe and the moment a response is
received for this command.
The transition of NC-SI traffic (pass through or commands/responses) from SMBus to PCIe should
be done on a packet boundary and should not interrupt a packet fragmentation or reassembly.
Note: The MC and the NIC should keep their MCTP over SMBus connection attributes even while
working over PCIe.
10.7.2.2.3 PCIe Target ID Change
The target ID of one of the endpoints may change, either due to a new enumeration of the PCIe bus or
due to the disabling of one of the functions in the device. In this case the following flow should be used:
The endpoint should send a Discovery Notify MCTP command on the PCIe bus using the new
Requester ID.
Upon reception of the Discovery Notify MCTP command with the new Requester ID, the Bus Owner
will send a Set Endpoint ID MCTP command on the PCIe bus and will update the routing table. The
Bus Owner should try to keep the EID previously assigned on the SMBus as the EID on the previous
Requester ID.
The Bus Owner will send an Update Routing Table command to all endpoints that may then update
the parameters of their counterpart they use.
10.7.2.2.4 PCIe to SMBus Transition
If the NIC or the MC detects that the PCIe bus is not available by detecting that the bus master
enable field in the PCIe configuration of all of the available function is cleared, it will stop pass
through traffic on the PCIe.
Ethernet Controller I210 —System Manageability
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The NIC will then wait for the MC to discover it on the SMBus. The MC then discover the NIC as
described in the SMBus to PCIe transition above.
The transition of NC-SI traffic (pass through or commands/responses) from PCIe to SMBus may
done at any stage and may interrupt a packet fragmentation or reassembly, as it is assumed that
such a transition occurs only when the PCIe bus is not available anymore.
Once any NC-SI command is received by the NIC on SMBus, it will capture the MC SMBus address
and EID. respond to the command and restart the pass through traffic over SMBus. Upon reception
of the response, the MC may restart the pass through traffic to the NIC over SMBus.
Note: If the I210 can not process the command received, it will respond with a Command Failed
(0x1) response code and a Package Not Ready (0x0004) reason code (Section 10.6.2.3). In
this case the transition will not occur and the MC should retry the command later.
10.7.3 MCTP over PCIe
10.7.3.1 Message Format
The message format used for NC-SI over MCTP over PCIe is as follow:
+0 +1 +2 +3
76543210765432107654321076543210
FMT
011
Type
10r2r1r01
1. r2r1r0 =
000b: Route to Root Complex
010b: Route by ID
011b: Broadcast from Root Complex
RTC
000 RA
tt
r2RT
H
2
T
D
2
E
P
2
Attr
[1:0]
2
AT
00
Length
00_000x_xxxx
PCI Requester ID
PCI Tag Field Message Code
Vendor Defined = 0111_1111b
RPad
Len MCTP VDM
code - 0000b
PCI Target ID (For Route by ID messages,
otherwise = Reserved) Vendor ID = 0x1AB4 (DMTF)
MCTP
Reserved Header
version = 1 Destination endpoint ID Source endpoint ID S
O
M
E
O
MSEQ# T
OTag
I
C
2
2. TD = 0, EP = 0, IC = 0,TH = 0, Attr[2:0] = 0 for sent packets and is ignored for received packets.
Message Type = 0x02/
0x03 NC-SI Command/Pass Through data
.....
NC-SI Command/Pass Through data
PCIe TLP header
MCTP header
NC-SI header and payload
System Manageability—Ethernet Controller I210
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10.7.3.2 PCIe Discovery Process
The I210 follows the discovery process described in section 5.9 of the MCTP PCIe VDM Transport
Binding Specification (DSP0238).
Upon reception of an Endpoint Discovery message (while in undiscovered stage), the I210 will expose
the endpoint on the function previously described.
If the bus number of the I210 changes due to a re-enumeration of the bus, the I210 will send a
Discovery Notify message to indicate to the MC that is should do a re-enumeration of the device to
discover the new endpoint.
10.7.3.3 MCTP Over PCIe Special Features
The I210 supports the following optional features of MCTP when running over PCIe:
1. Rate Limiting
2. ACLs.
10.7.3.3.1 MCTP Uplink Rate Limiting
As the PCIe link can carry a traffic bandwidth much higher than what the MC can sustain, in order to
avoid drop of packets, the I210 allows rate limiting of the MCTP pass through traffic. The I210 supports
rate limiting between 10 Mbps and line rate. The rate limiter is defined using the following parameters:
Max rate limit (fixed from Flash via the MCTP rate in the MCTP rate limiter config 1 word).
The max burst size (fixed from Flash via the MCTP max credits field in the in the MCTP rate limiter
config 2 word).To limit the max burst to one VDM, set this parameter to 5.
Decision point (fixed from Flash via the MCTP decision point field in the in the MCTP rate limiter
config 2 word).
10.7.3.3.2 Service Provider MCTP Endpoint ACLs
The I210 supports a set of ACLs that allows reception of sensitive commands only from specific bus
number (in the requester ID). The device and function part of the Requester ID are ignored for this
purpose.
If ACLs are enabled (by clearing the Disable ACLs bit in PCIe Control 1 Flash word) the following flow is
used decide which packets are accepted.
Commands can be divided to 3 types:
1. ACL programming commands: Such commands can be received only from the address that sent the
Prepare For Endpoint Discovery command via broadcast routing.
2. Sensitive commands including all the NC-SI commands and pass through traffic. These commands
can be received only from requesters whose bus number is set in the ACL list. If an MCTP packet is
dropped, then the SPMEACLD counter is increased. This counter can be read by the MCTP bus
owner using the Get ACL Violation Counters command.
3. Regular MCTP commands are received from any requester, however, Set EID command is processed
only if received from the address that sent the Prepare For Endpoint Discovery command via
broadcast routing.
The I210 supports 4 ACL entries.
Ethernet Controller I210 —System Manageability
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10.7.4 MCTP Over SMBus
The message format used for NC-SI over MCTP over SMBus is as follow:
10.7.4.1 SMBus Discovery Process
The I210 follows the discovery process described in section 6.5 of the MCTP SMBus/I2C Transport
Binding Specification (DSP0237). It indicates support for ASF in the SMBus getUID command (see
Section 10.5.8.5). It will respond to any SMBus command using the MCTP command code - so that the
bus owner knows the I210 supports MCTP.
Note: MCTP commands over SMBus are received from any master address and are answered to the
sender. There is no capturing of the bus owner address from any specific command.
10.7.4.2 MCTP Over SMBus Special Features
The I210 supports the following optional feature of MCTP when running over SMBus: Fairness
arbitration.
10.7.4.2.1 Fairness Arbitration
When sending MCTP messages over SMBus and when fairness arbitration is enabled (see
Section 6.7.3.3), the I210 should respect the fairness arbitration as defined in section 5.13 of DSP0237
when sending MCTP messages.
+0 +1 +2 +3
76543210765432107654321076543210
Destination Slave Address 0 Command Code = MCTP = 0Fh Byte count Source Slave Address
MCTP
Reserved Header
version = 1 Destination endpoint ID Source endpoint ID S
O
M
E
O
MSEQ# T
OTag
I
C
1
1. IC = 0
Message Type = 0x02/
0x03 NC-SI Command/Pass Through data
.....
NC-SI Command/Pass Through data
PEC
SMBus header/PEC
MCTP header
NC-SI header and payload
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10.7.5 NC-SI Over MCTP
The I211 support for NC-SI over MCTP is similar to the support for NC-SI over RMII with the following
exceptions:
1. A set of new NC-SI commands used to expose the NC-SI over MCTP capabilities.
2. The format of the packets is modified to account for the new transport layer as described below.
10.7.5.1 NC-SI Packets Format
NC-SI over MCTP defines two different message type for pass through and for control packets.
Packets with a message type equal to the Control packets message type field (default = 0x02) in the
Flash are NC-SI control packets (commands, responses and AENs) and packets with a message type
equal to the Pass through packets message type field (default = 0x03) in the Flash are NC-SI pass
through packets
10.7.5.1.1 Control Packets
The format used for Control packets (Commands, Responses and AENs) is as follow:
+0 +1 +2 +3
76543210765432107654321076543210
SMBus or PCIe header
MCTP
Reserved Header
version = 1 Destination endpoint ID Source endpoint ID S
O
M
E
O
MSEQ#
T
O
=
1
Tag
I
C
Message Type = Control
Packets Message type
(0x02) MC ID = 0x00 Header revision Reserved
IID Command Channel ID1
1. The channel ID is defined as described in Section 10.2.2.2
Reserved Payload
Length[11:8]
Payload Length[7:0] Reserved
Reserved
Reserved Command Data
....
Command Data Checksum
Checksum
SMBus/PCIe header
MCTP header
NC-SI header
NC-SI Data
Ethernet Controller I210 —System Manageability
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Note that the MAC header and MAC FCS present when working over NC-SI are not part of the packet in
MCTP mode.
10.7.5.1.2 Pass Through Packets
The format used for Pass through packets is as follow. This format is the same for either packets
received from the network or packets received from the host.
The CRC is never included in the packet. In receive, the CRC is checked and removed by the I210 in
transmit, the CRC is added by the I210.
The CRC presence depends on the IC bit value. If the IC bit is set, the packet includes a CRC. If it is
cleared the packet doesn’t include it.
For the I210 to MC packets, the IC bit will always be set. For MC to the I210 packets, if the IC bit is set,
the I210 must check the CRC validity.
In any case, if the packet is modified by the I210, then a new CRC must be recalculated.
10.7.6 MCTP Programming
The MCTP programming model is based on:
1. A set of MCTP commands used for the discovery process and for the link management. The list of
supported commands is described in section Section 10.7.6.1.
2. A subset of the NC-SI commands used in the regular NC-SI interface, including all the OEM
commands as described in Section 10.6.2 (NC-SI programming I/F). The specific commands
supported are listed in Table 10-31 and Table 10-34.
Note: For all MCTP commands (both native MCTP commands and NCSI over MCTP), the response
uses the Msg tag received in the request with TO bit cleared.
+0 +1 +2 +3
76543210765432107654321076543210
SMBus or PCIe header
MCTP
Reserved Header
version = 1 Destination endpoint ID Source endpoint ID S
O
M
E
O
MSEQ#
T
O
=
1
Tag
I
C
=
0
Message Type = Pass
Through Packets Control
Type (0x03) DA
DA SA
SA
SA Ether type Ethernet Packet
Ethernet packet
....
....
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10.7.6.1 MCTP Commands Support
Table 10-81 lists the MCTP commands supported by I211.
10.7.6.1.1 Error Conditions
In some cases , the I210 may not be ready to react to a received MCTP command. In these cases, a
response with ERROR_NOT_READY (0x04) completion code. is returned. In this case, it is
recommended to wait 300 ms before retrying the command.
10.7.6.1.2 Get Endpoint ID
Table 10-81. MCTP commands support
Command
Code Command Name General Description
I211
support as
Initiator
I211
support as
Responder
0x00 Reserved Reserved
0x01 Set Endpoint ID Assigns an EID to the endpoint at the given physical
address. N/A Yes
0x02 Get Endpoint ID
Returns the EID presently assigned to an endpoint. Also
returns information about what type the endpoint is and
its level of use of static EIDs. See Section 10.7.6.1.2 for
details.
No Yes
0x03 Get Endpoint UUID Retrieves a per-device unique UUID associated with the
endpoint. See Section 10.7.6.1.3 for details. No Yes
0x04 Get MCTP Version
Support
Lists which versions of the MCTP control protocol are
supported on an endpoint. See Section 10.7.6.1.4 for
details. No Yes
0x05 Get Message Type
Support Lists the message types that an endpoint supports. See
Section 10.7.6.1.5 for details. No Yes
0x06 Get Vendor Defined
Message Support
Used to discover an MCTP endpoint’s vendor specific
MCTP extensions and capabilities. See Section 10.7.6.1.6
for details. No Yes1
0x07 Resolve Endpoint
ID Used to get the physical address associated with a given
EID. No N/A
0x08 Allocate Endpoint
IDs Used by the bus owner to allocate a pool of EIDs to an
MCTP bridge. N/A N/A
0x09 Routing
Information Update Used by the bus owner to extend or update the routing
information that is maintained by an MCTP bridge. N/A N/A
0x0A Get Routing Table
Entries Used to request an MCTP bridge to return data
corresponding to its present routing table entries. No N/A
0x0B Prepare for
Endpoint Discovery
Used to direct endpoints to clear their “discovered” flags
to enable them to respond to the Endpoint Discovery
command. N/A Yes1
1. These commands are supported only for MCTP over PCIe.
0x0C Endpoint Discovery Used to discover MCTP-capable devices on a bus,
provided that another discovery mechanism is not
defined for the particular physical medium. No Yes1
0x0D Discovery Notify Used to notify the bus owner that an MCTP device has
become available on the bus. Yes N/A
0x0E Get Network ID Used to get the MCTP network ID No No
0x0F Query Hop
Used to discover what bridges, if any, are in the path to a
given target endpoint and what transmission unit sizes
the bridges will pass for a given message type when
routing to the target endpoint.
No No
Ethernet Controller I210 —System Manageability
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The Get Endpoint ID response of I211 is described in the following table:
10.7.6.1.3 Get Endpoint UUID
The UUID returned is calculated according to the following function:
Time Low = Read from Flash words at offset 0x9 and 0xA of Sideband Configuration Structure.
Time mid = Read from Flash word at offset 0xB of Sideband Configuration Structure
Time High and version = Read from Flash word at offset 0xC of Sideband Configuration Structure
Clock Sec and Reserved = Read from Flash word at offset 0xD of Sideband Configuration Structure
Node = Read from Flash word at offset 0xE-0x10 of Sideband Configuration Structure.
10.7.6.1.4 Get MCTP Version Support
The following table describes the returned value according to the requested message type
10.7.6.1.5 Get Message Type Support Command
The Get Message type support response of I211 is described in the following table:
Byte Description Value
1 Completion Code
2 Endpoint ID 0x00 - EID not yet assigned
Otherwise - returns EID assigned using Set Endpoint ID command
3 Endpoint Type 0x00 (Dynamic EID, Simple Endpoint)
4 Medium Specific SMBUs: 0x01 - Fairness arbitration protocol supported.
PCIe: 0x00
Byte Description Message type
0xFF(Base)
0x00
(Control
protocol
message)
0x02
(NC-SI over
MCTP)
0x03
(Ethernet)
0x7E
(PCIe based
VDM
messages)
All other or
unsupported
messages
1 Completion Code 0 0x80
2Version Number
entry count 2 21120
6:3 Version number
entry 1 0xF1F0FF00
(1.0) 0xF1F0FF00
(1.0) 0xF1F0FF00
(1.0) 0xF1F0FF00
(1.0) 0xF1F0FF00
(1.0) 0
9:7 Version number
entry 2 0xF1F1F000
(1.1.0) 0xF1F1F000
(1.1.0) 0xF1F1F000
(1.1.0)
Byte Description Value
1 Completion Code 0x00
2 MCTP Message Type Count 0x01/0x02/0x03 - the I210 supports up to three additional message
types, depending on the mode of operation and the bus used.
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10.7.6.1.6 Get Vendor Defined Message Support Command
The Get Vendor Defined Message type support response of I211 is described in the following table if the
Vendor ID Set Selector equals 0x00:
10.7.6.1.7 Set Endpoint ID Command
The I210 supports the Set EID and Force EID operations defined in the Set Endpoint ID command.
When operating over PCIe, the Set Discovered Flag operation is also supported. As endpoints in the
I210 can be set only through their own interface, Set EID and Force EID are equivalent. The Reset EID
operation is not relevant to the I210.
The Set Endpoint ID response of I211 is described in the following table:
10.8 Manageability Host Interface
This section details host interaction with the manageability portion of the I210. The information within
this section is only available to the host driver, the MC does not have access.
10.8.1 HOST CSR Interface
The software device driver of all functions communicates with the manageability block through CSR
access. The manageability is mapped to address space 0x8800 to 0x8FFF on the slave bus of the
function.
3:5 List of Message Type
numbers
0x02 (NC-SI over MCTP)
0x03 (Ethernet). If pass through is supported.
0x7E (PCIe based VDM messages) - over PCIe only
Byte Description Value
1 Completion Code 0x00
2 Vendor ID Set Selector 0xFF = no more capability sets.
3:5 Vendor ID 0x008086 (PCI id indicator + Intel vendor ID)
6:7 Version 0x0100 (Version 1.0)
Byte Description Value
1 Completion Code 0x00
2 Completion Status
[7:6] = 00 - Reserved
[5:4] = 00 - EID assignment accepted
[3:2] = 00 - Reserved
[1:0] = 00 - Device does not use an EID pool.
3 EID Setting If the EID setting was accepted, this value will match the EID passed in
the request. Otherwise, this value returns the present EID setting.
4 EID Pool Size Always return a zero.
Byte Description Value
Ethernet Controller I210 —System Manageability
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10.8.2 Host Slave Command Interface to Manageability
This interface is used by the software device driver for several of the commands and for delivering
various types of data in both directions (Manageability-to-Host and Host-to-Manageability).
The address space is separated into two areas:
Direct access to the internal data RAM: The internal shared (between Firmware and Software) RAM
is mapped to address space 0x8800 to 0x8EFF. Writing/reading to this address space goes directly
to the RAM.
Control register located at address 0x8F00.
10.8.2.1 Host Slave Command Interface Low Level Flow
This interface is used for the external host software to access the manageability subsystem. Host
software writes a command block or read data structure directly from the data RAM. Host software
controls these transactions through a slave access to the control register.
The following flow shows the process of initiating a command to the manageability block:
1. The Software clears the FWSTS.FWRI flag (clear by write one) to car any previous firmware reset
indications.
2. The Software device driver takes ownership of the Management Host interface using the flow
described in Section 4.6.1.
3. The Software device driver reads the HOST Interface Control Register (See Section 8.23.2) and
checks that the Enable (HICR.En) bit is set.
4. The Software device driver writes the relevant command block into the RAM area that is mapped to
addresses 0x8800-0x8EFF.
5. The Software device driver sets the Command (HICR.C) bit in the HOST Interface Control Register
(See Section 8.23.2). Setting this bit causes an interrupt to the ARC (can be masked).
6. The Software checks the FWSTS.FWRI flag to make sure a firmware reset didn’t occur during the
command processing. If this bit is set, the command may have failed.
7. The Software device driver polls the HOST Interface Control register for the Command (HICR.C) bit
to be cleared by Firmware.
8. When Firmware finishes with the command, it clears the Command (HICR.C) bit (if Firmware replies
with data, it should clear the bit only after the data is placed in the shared RAM area where the
software device driver can read it).
If the Software device driver reads the HOST Interface Control register and the HICR.SV bit is set to 1b,
then there is a valid status of the last command in the shared RAM. If the HICR.SV bit is not set, then
the command has failed with no status in the RAM.
On completion of access to the shared RAM Software device driver should release ownership of the
shared RAM using the flow described in Section 4.6.2.
10.8.2.2 Host Slave Command Registers
10.8.2.2.1 Host Interface Control Register (CSR Address 0x8F00)
This register operates along with the host software/firmware interface (See Section 8.23.1).
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10.8.2.3 Host Interface Structure
10.8.2.3.1 Host Interface Command Structure
Table 10-82 describes the structure used by the Software device driver to send a command to Firmware
using the Host slave command interface (shared RAM mapped to addresses 0x8800-0x8EFF).
10.8.2.3.2 Host Interface Status Structure
Table 10-83 lists the structure used by Firmware to return a status to the Software device driver via the
Host slave command interface. A status is returned after a command has been executed.
10.8.2.3.3 Checksum Calculation Algorithm
The Host Command/Status structure is summed with this field cleared to 0b. The calculation is done
using 8-bit unsigned math with no carry. The inverse of this sum is stored in this field (0b minus the
result). Result: The current sum of this buffer (8-bit unsigned math) is 0b.
Table 10-82. Host Driver Command Structure
#Byte Description Bit Value Description
0 Command 7:0 Command Dependent Specifies which host command to process.
1 Buffer Length 7:0 Command Length Command Data Buffer length: 0 to 252, not including 32 bits of
header.
2 Reserved 7:0 Reserved
3 Checksum 7:0 Defined Below Checksum signature.
255:4 Data Buffer 7:0 Command Dependent
Command Specific Data
Minimum buffer size: 0.
Maximum buffer size: 252.
Table 10-83. Status Structure Returned to Host Driver
#Byte Description Bit Value Description
0 Command 7:0 Command Dependent Command ID.
1 Buffer Length 7:0 Status Dependent Status buffer length: 252:0
2 Return Status 7:0 Depends on Command
Executing Results
0x1 Status OK
0x2 Illegal command ID
0x3 Unsupported command
0x4 Illegal payload length
0x5 Checksum failed
0x6 Data Error
0x7 Invalid parameter
0x8 - 0xFF Reserved
3 Checksum 7:0 Defined Below Checksum signature.
255:4 Data Buffer Status Dependent
Status configuration parameters
Minimum Buffer Size: 0.
Maximal Buffer Size: 252.
Ethernet Controller I210 —System Manageability
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10.8.2.4 Host Interface Commands
10.8.2.4.1 Driver Info Host Command
This command is used to provide the driver information in NC-SI mode.
Table 10-84. Driver Info Host Command
Following is the status returned on this command:
Table 10-85. Driver Info Host Status
10.8.2.4.2 Host Proxying Commands
Software Device driver will send to Firmware via shared RAM interface the following Proxying
commands, using the interface described in Section 10.8.2.1:
1. Get Firmware Proxying Capabilities Command (See Table 10-86) to receive information on Protocol
offloads supported.
2. Set Firmware Proxying Configuration Command (See Table 10-88) to define the required proxying
behavior.
3. Send the required Proxying information for the Protocol offloads supported by Firmware via the
following commands:
a. Set ARP Proxy Table Entry (See Table 10-90).
b. Set NS (Neighbor Solicitation) Proxy Table Entry (See Table 10-92).
Following the reception of the commands, Firmware will acknowledge execution of the command via the
shared RAM interface using the following responses according to the command issued:
1. Get Firmware Proxying Capabilities Response (See Table 10-87).
2. Set Firmware Proxying Configuration Response (See Table 10-89).
3. Acknowledge reception of Proxying information via the following responses:
Byte Name Bit Value Description
0 Command 7:0 0xDD Driver info command.
1 Buffer Length 7:0 0x5 Port Number + 4 bytes of the Driver info
2 Reserved 7:0 0x0 Reserved
3 Checksum 7:0 Checksum signature of the Host command.
4 Port Number 7:0 Port Number Indicates the port currently reporting its driver info
8:5 Driver Version 7:0 Driver Version
Numerical for driver version - should be
Byte 8:Major
Byte 7:Minor
Byte 6:Build
Byte 5:SubBuild
Byte Name Bit Value Description
0 Command 7:0 0xDD Driver Info command
1 Buffer Length 7:0 0x0 No data in return status
2 Return Status 7:0 0x1 0x1 for good status
3 Checksum 7:0 Checksum signature
System Manageability—Ethernet Controller I210
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a. Set ARP Proxy Table Entry Response (See Table 10-91).
b. Set NS (Neighbor Solicitation) Proxy Table Entry Response (See Table 10-93)
10.8.2.4.2.1 Get Firmware Proxying Capabilities
This command is used to provide the driver information on protocol offload types supported by the
I210.
Table 10-86. Get Firmware Proxying Capabilities Command
Firmware returns the following status for this command:
Note: The Firmware status reply includes a series of two values
{Protocol offload capability type and version, number of entries for this type of Protocol
offload}
Currently the following capabilities are defined, ARP proxy, NS proxy, MLD proxy and mDNS
proxy. If the structure is too big to transfer in one time the driver can ask for additional pages
by incrementing the page field.
Byte Name Bit Value Description
0 Command 7:0 0xEA GET Firmware Proxying Capabilities
1 Buffer length 7:0 0x2
2 Reserved 7:0 0x0 Must be zeroed by host
3 Checksum 7:0 Checksum signature
4 Port Number 7:0 Port Number Indicates the port number that the command is targeted
at.
5 Page 7:0 0x1
Get capabilities page number
If response exceeds 256 bytes including header
(Maximum page size), Software should issue multiple
Get Firmware Proxying Capabilities commands with
increasing page number until a response with buffer
length smaller than 252 is received or a response with a
Status field with an Unsupported Page Number is
received.
Note: Maximum Page size is 256 Bytes including
Header information.
Table 10-87. Get Firmware Proxying Capabilities Response
Byte Name Bit Value Description
0 Command 7:0 0xEA Get Firmware Proxying Capabilities
1 Buffer length 7:0 0xB
The buffer length can vary according to the capabilities
the FW supports i.e. if the FW supports 4 capabilities it
would be 0xB for less capabilities 2 bytes are reduced
per capability
2 Return Status 7:0 0x1
0x0 - Unsupported Page number
0x1 - Status OK
0x2 to 0xFF - Error
3 Checksum 7:0 Checksum signature
4 Port Number 7:0 Port Number Indicates the port number that the response is for.
5 Page 7:0 0x1 First page of capabilities
6 Total Cap size 7:0 0x8 Size of capability structure in bytes
7 ARP proxy version 1 7:0 0x1
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10.8.2.4.2.2 Set Firmware Proxying Configuration
This command is used to provide information to Firmware on how to implement protocol offloads
supported by the I210.
The Firmware Proxying Configuration command includes a series of two values
{Command type and version, Command Data for this type of command}
Currently only one Configuration command is defined:
1. No Match - Command defines expected behavior when receiving a Proxying packet that’s not
supported.
Note: the I210 keeps its proxy settings after D3 to D0 transition, until they are disabled by host.
However, the proxy filters are reset by PERST assertion/deassertion that occurs when
transiting from D3 to D0 via Dr state. Therefore, FW is required to reconfigure the proxy
filters after PERST deassertion, in the aim to maintain proxying until the driver is up again. To
avoid a race condition between FW and SW while accessing proxy registers, the driver should
first disable proxying via the host interface before modifying the proxy registers.
If the structure is too big to transfer in one time the driver can ask for additional pages by incrementing
the page field.
8 Number of ARP entries 7:0 Number of entries Number of ARP entries supported
9 NS proxy version 1 7:0 0x2
10 Number of NS proxy
entries 7:0 Number of entries Number of NS entries supported
11 MLD proxy version 7:0 0x3
12 MLD support 7:0 Version of MLD
supported
0x0 - not supported
0x1 - MLD version 1 compatibility mode
0x2 - MLD version 2 compatibility mode
0x3 - Both versions supported
0x4 - x0FF: Reserved
13 mDNS proxy version 7:0 0x4
14 mDNS proxy offload
support 7:0 Data buffer Size Size of data buffer allocated for mDNS proxy offload
data in KB
Table 10-87. Get Firmware Proxying Capabilities Response
System Manageability—Ethernet Controller I210
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Table 10-88. Set Firmware Proxying Configuration Command
Firmware returns the following Response for this command:
Byte Name Bit Value Description
0 Command 7:0 0xEB Set Firmware Proxying Configuration
1 Buffer length 7:0 0x6
2 Reserved 7:0 0x0 Must be zeroed by host
3 Checksum 7:0 Checksum signature
4 Port Number 7:0 Port Number
Indicates the port number that the command is targeted
at.
Note: Port number is always set to 0x0 in the I210
5 No Match 7:0 0x1
No Match command
Defines how Firmware handles unsupported proxying
packets.
6 No Match data 7:0 0x0 or 0x1
No Match data
0x0 - Discard unsupported proxying packets
0x1 - Issue Wake on reception of unsupported packets.
Note: 0x0 is the default value if no configuration
command is issued.
7 Reserved 7:0 0x0 Reserved
8 Reserved 7:0 0x0 Reserved
9 Enable MLD 7:0 0x0, 0x1 or 0x2
0x0: Do not enable MLD
0x1: Enable MLD version 1
0x2: Enable MLD version 2
0x3 - x0FF: Reserved
Ethernet Controller I210 —System Manageability
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Table 10-89. Set Firmware Proxying Configuration Response
10.8.2.4.2.3 Set ARP Proxy Table Entry
Note: To set an entry Software driver will post command with Active field set to 0x1. To disable an
entry the driver must post this entry with the Active field set to 0x0. Driver must initially
disable all unused entries.
Byte Name Bit Value Description
0 Command 7:0 0xEB Get Firmware Proxying Capabilities
1 Buffer length 7:0 0x6
2 Return Status 7:0 0x1
0x0 - Undefined Error
0x1 - Status OK
0x2 - Unsupported command
0x3 - Checksum Error
0x4 - Buffer Length Error
0x5 to 0xFF - Error
3 Checksum 7:0 Checksum signature
4 Port Number 7:0 Port Number Indicates the port number that the status is from.
5 No Match 7:0 0x1
No Match command
Defines how Firmware handles unsupported proxying
packets.
6 No Match data 7:0 0x0 or 0x1
No Match Data
0x0 - Discard unsupported proxying packets
0x1 - Issue Wake on reception of unsupported packets.
Note: 0x0 is the default value if no configuration
command is issued.
7 Reserved 7:0 0x0 Reserved
8 Reserved 7:0 0x0 Reserved
9 Enable MLD 7:0 0x0, 0x1 or 0x2 Copied from the Set Firmware Proxying Configuration
Command
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Table 10-90. Set ARP Proxy Table Entry Command
Firmware returns the following status for this command:
Byte Name Bit Value Description
0 Command 7:0 0x77 Set ARP proxy command
1 Buffer length 7:0 0x13
2 Reserved 7:0 0x0 Must be zeroed by host
3 Checksum 7:0 Checksum signature
4 Port Number 7:0 Port Number
Indicates the port number that the command is targeted
at.
Note: Port number is always set to 0x0 in the I210
5 Sub command 7:0 0x3 Set proxy capabilities
6 ARP proxy version 1 7:0 0x1 ARP version 1 entry
7 Table index 7:0 Index
Table index
Each Set proxy command is held in a separate Table
index. Field defines Table Index for current command.
Notes:
1. Table Index values begin at 1.
2. Only a single ARP proxy table entry is supported
and only a Table index value of 1 is valid.
3. To change contents of a table entry the relevant
Table index should be invalidated (Write command
to the Table index with Active field = 0x0) before
writing new content.
8 Active 7:0 0x1 or 0x0
Set to 0x1 to activate table index
Set to 0x0 to invalidate it
If set to 0, values of all following fields are ignored
14:9 MAC Address 7:0 MAC Address to reply to ARP request
18:15 Local IP Address 7:0 Local IP Address of station
22:19 Remote IP Address 7:0 Remote IP Address
A value of 0x0 indicates any remote IP address
Ethernet Controller I210 —System Manageability
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Table 10-91. Set ARP Proxy Table Entry Response
10.8.2.4.2.4 Set NS (Neighbor Solicitation) Proxy Table Entry
Note: To set an entry Software driver will post command with Active field set to 0x1. To disable an
entry the driver must post this entry with the Active field set to 0x0. Driver must initially
disable all unused entries.
Byte Name Bit Value Description
0 Command 7:0 0x77 Set ARP proxy command
1 Buffer length 7:0 0x13
2 Status 7:0 0x1
0x0 - Unsupported Table Index
0x1 - Status OK
0x2 - Table Index in use.
0x3 - Unsupported command
0x4 - Checksum Error
0x5 - Buffer Length Error
0x6 to 0xFF - Error
3 Checksum 7:0 Checksum signature
4 Port Number 7:0 Port Number Indicates the port number that the response is for.
5 Sub command 7:0 0x3 Set proxy capabilities
6 ARP proxy version 1 7:0 0x1 ARP version 1 entry
7 Table index 7:0 Index
8 Active 7:0 0x1 or 0x0 Set if entry is active
14:9 MAC Address 7:0
18:15 Local IP Address 7:0
22:19 Remote IP Address 7:0
System Manageability—Ethernet Controller I210
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Table 10-92. Set NS Proxy Table Entry Command
Firmware returns the following status for this command:
Byte Name Bit Value Description
0 Command 7:0 0x78 Set NS proxy command
1 Buffer length 7:0 0x4B
2 Reserved 7:0 0x0 Must be zeroed by host
3 Checksum 7:0 Checksum signature
4 Port Number 7:0 Port Number
Indicates the port number that the command is targeted
at.
Note: Port number is always set to 0x0 in the I210
5 Sub command 7:0 0x3 Set proxy capabilities
6 NS proxy version 1 7:0 0x2 NS version 1 entry
7 Table index 7:0 Index
Table index
Each Set proxy command is held in a separate Table
index. Field defines Table Index for current command.
Notes:
1. Table Index values begin at 1.
2. Up to two NS proxy table entries are supported and
only Table index values of 1 and 2 are valid.
3. To change contents of a table entry the relevant
Table index should be invalidated (Write command
to the Table index with Active field = 0x0) before
writing new content.
8 Active 7:0 0x1 or 0x0
Set to 0x1 to activate table index
Set to 0x0 to invalidate it
If set to 0, values of all following fields are ignored
14:9 MAC Address 7:0 MAC Address
30:15 Local IPv6 Address 1 7:0 Local IPv6 Address 1.
This address is used by firmware for NS proxying.
46:31 Local IPv6 Address 2 7:0
Local IPv6 Address 2
If there is only one local address value placed here is
0x0.
When not 0x0, this address is used by firmware for NS
proxying.
62:47 Remote IPv6 Address 7:0 Remote IPv6 Address
A value of 0x0 indicates any address.
78:63 Solicited IPv6 Address 7:0 Solicited IPv6 Address.
This address is used by firmware for MLD proxying.
Ethernet Controller I210 —System Manageability
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Table 10-93. Set NS Proxy Table Entry Response
10.8.2.4.2.5 Set mDNS Proxy
To enable mDNS proxy the driver needs to handoff the mDNS data to the FW. The host driver generally
pass the mDNS data in chunks of 128 bytes using the Set mDNS Proxy command. However, in I211, for
saving on-die memory space, the mDNS data is loaded by the driver directly into the flash area
provisioned for it. The exact structure of the mDNS data is specified in the mDNS Proxy SAS document.
The command is issued by the driver whenever the system goes to sleep, after the mDNS data was
updated in the flash if necessary.
Byte Name Bit Value Description
0 Command 7:0 0x78 Set NS proxy command
1 Buffer length 7:0 0x4B
2 Status 7:0 0x1
0x0 - Unsupported Table Index
0x1 - Status OK
0x2 - Table Index in use.
0x3 - Unsupported command
0x4 - Checksum Error
0x5 - Buffer Length Error
0x6 to 0xFF - Error
3 Checksum 7:0 Checksum signature
4 Port Number 7:0 Port Number Indicates the port number that the status is for.
5 Sub command 7:0 0x3 Set proxy capabilities
6 NS proxy version 1 7:0 0x2 NS version 1 entry
7 Table index 7:0 Index
8 Active 7:0 0x1 or 0x0 Set if entry is active
14:9 MAC Address 7:0 MAC Address
30:15 Local IPv6 Address 1 7:0 Local IPv6 Address 1
46:31 Local IPv6 Address 2 7:0 Local IPv6 Address 2
If there is only one local address value placed is 0x0
62:47 Remote IPv6 Address 7:0 Remote IPv6 Address
A value of 0x0 indicates any address.
78:63 Solicited IPv6 Address 7:0 Solicited IPv6 Address
System Manageability—Ethernet Controller I210
781
Table 10-94. Set mDNS Proxy Command
Firmware returns the following status for this command:
Table 10-95. Set mDNS Proxy Response
10.8.3 Host Isolate Support
If a MC decides that a malicious software prevents its usage of the LAN, it may decide to isolate the NIC
from its driver. This is done using the TCO reset command (Section 10.6.3.12).
Byte Name Bit Value Description
0 Command 7:0 0x79 Set mDNS Proxy Command
1 Buffer length 7:0 0x6
2 Reserved 7:0 0x0 Must be zeroed by host
3 Checksum 7:0 Checksum signature
4 Port Number 7:0 0x0 Indicates the port number that the command is targeted
at.
5 Sub command 7:0 0x3 Set proxy capabilities
6 mDNS proxy version 1 7:0 0x4 mDNS version 1 entry
7 DataChunk index 7:0 0x0 Data Chunk index is used to pass all mDNS proxy data in
chunks starting from Chunk[0] till the last chunk
8 Active 7:0 0x0
Bit 0:
Set to 1b to activate chunk index
Set to 0b to invalidate it
If set to 0, values of all following fields are ignored
Bit 1:
Set to 1b to indicate last chunk
Set to 0b to indicate other (non last) chunk
9 Chunk Data Length 7:0 0x0 Set to 0x80 for non last data chunks, for last data chunk
indicates the number of valid bytes in the chunk
Byte Name Bit Value Description
0 Command 7:0 0x79 Set mDNS Proxy Response
1 Buffer length 7:0 0x6
2 Status 7:0 0x1
0x0 - Unsupported Table Index
0x1 - Status OK
0x2 - Table Index in use.
0x3 - Unsupported command
0x4 - Checksum Error
0x5 - Buffer Length Error
0x6 to 0xFF - Error
3 Checksum 7:0 Checksum signature
4 Port Number 7:0 Port Number Indicates the port number that the status is for.
5 Sub command 7:0 0x3 Set proxy capabilities
6 mDNS proxy version 1 7:0 0x4 mDNS version 1 entry
7 DataChunk index 7:0 Index Data Chunk index is used to pass all mDNS proxy data in
chunks starting from Chunk[0] till the last chunk
8 Active 7:0 Reflection of the Active byte from the mDNS proxy
command
9 Chunk Data Length 7:0 Reflection of the Chunk Data Length byte from the
mDNS proxy command
Ethernet Controller I210 —System Manageability
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If TCO isolate is enabled in the Flash (See Section 6.7.1.3), The TCO Isolate command will disable PCIe
write operations to the LAN port. As the driver needs to access the CSR space in order to provide
descriptors to the NIC, this operation will also stop the network traffic including OS2BMC and MC-to-OS
traffic as soon as the existing transmit and receive descriptor queues are exhausted.
Electrical/Mechanical Specification—Ethernet Controller I210
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11.0 Electrical/Mechanical Specification
11.1 Introduction
These specifications are subject to change without notice.
This chapter describes the I210 DC and AC (timing) electrical characteristics. This includes absolute
maximum rating, recommended operating conditions, power sequencing requirements, DC and AC
timing specifications. The DC and AC characteristics include generic digital 3.3V I/O specification as well
as other specifications supported by the I210.
11.2 Operating Conditions
Table 11-1. Absolute Maximum Ratings
Note: Ratings in these tables are those beyond which permanent device damage is likely to occur.
These values should not be used as the limits for normal device operation. Exposure to
absolute maximum rating conditions for extended periods might affect device reliability.
Symbol Parameter
I210 (Commercial
Temperature SKU)
I210 (Industrial
Temperature SKU) Units
Min Max Min Max
Tcase Case Temperature Under
Bias 0 85 -40 105 C
Tstorage Storage Temperature
Range -40 125 -40 125 C
Vi/Vo 3.3V Compatible I/Os
Voltage Vss–0.5 4.0 Vss–0.5 4.0 V
VCC3P3 3.3V DC Supply Voltage Vss – 0.5 4.0 Vss–0.5 4.0 V
Ethernet Controller I210 —Electrical/Mechanical Specification
784
11.2.1 Recommended Operating Conditions
Symbol Parameter
I210 (Commercial
Temperature SKU)
I210 (Industrial
Temperature SKU) Units Notes
Min Max Min Max
Ta Operating Temperature
Range (Ambient; 0 CFS
airflow) 0 70 -40 85 C1, 2, 3
1. For normal device operation, adhere to the limits in this table. Sustained operations of a device at conditions exceeding these
values, even if they are within the absolute maximum rating limits, may result in permanent device damage or impaired device
reliability. Device functionality to stated DC and AC limits is not guaranteed if conditions exceed recommended operating conditions.
2. Recommended operation conditions require accuracy of power supply as defined in Section 11.3.1.
3. With external heat sink. Airflow required for operation in 85 °C ambient temperature.
Electrical/Mechanical Specification—Ethernet Controller I210
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11.3 Power Delivery
11.3.1 Power Supply Specification
VCC3P3 (3.3V) Parameters
Parameter Description Min Max Units
Rise Time Time from 10% to 90% mark 0.1 50 mS
Monotonicity Voltage dip allowed in ramp N/A 0 mV
Slope
Ramp rate at any given time between 10%
and 90%
Min: 0.8*V(min)/Rise time (max)
Max: 0.8*V(max)/Rise time (min)
47.5 27,720 V/S
Operational Range Voltage range for normal operating conditions 2.97 3.465 V
Ripple1Maximum voltage ripple (peak to peak) N/A 70 mV
Overshoot Maximum overshoot allowed N/A 100 mV
Overshoot Settling Time
Maximum overshoot allowed duration.
(At that time delta voltage should be lower
than 5mv from steady state voltage)
N/A 0.05 mS
Decoupling Capacitance Capacitance range 15 μF
Capacitance ESR Equivalent series resistance of output
capacitance N/A 50 M Ω
VCC1P5 (1.5V) Parameters
Parameter Description Min Max Units
Rise Time Time from 10% to 90% mark 0.1 85 mS
Monotonicity Voltage dip allowed in ramp N/A 0 mV
Slope
Ramp rate at any given time between 10%
and 90%
Min: 0.8*V(min)/Rise time (max)
Max: 0.8*V(max)/Rise time (min)
14 12,600 V/S
Operational Range Voltage range for normal operating conditions 1.425 1.575 V
Ripple1Maximum voltage ripple (peak to peak) N/A 40 mV
Overshoot Maximum overshoot allowed N/A 100 mV
Overshoot Settling Time
Maximum overshoot allowed duration.
(At that time delta voltage should be lower
than 5mv from steady state voltage)
N/A 0.1 mS
Decoupling Capacitance Capacitance range 15 μF
Capacitance ESR Equivalent series resistance of output
capacitance N/A 50 mΩ
VCC0P9 (0.9V) Parameters
Parameter Description Min Max Units
Rise Time Time from 10% to 90% mark 0.1 80 mS
Monotonicity Voltage dip allowed in ramp N/A 0 mV
Slope
Ramp rate at any given time between 10%
and 90%
Min: 0.8*V(min)/Rise time (max)
Max: 0.8*V(max)/Rise time (min)
8.6 7,560 V/S
Operational Range Voltage range for normal operating conditions 0.855 0.945 V
Ripple1Maximum voltage ripple (peak to peak) N/A 40 mV
Overshoot Maximum overshoot allowed N/A 100 mV
Ethernet Controller I210 —Electrical/Mechanical Specification
786
11.3.1.1 Power On/Off Sequence
On power-on, after 3.3V reaches 90% of its final value, all voltage rails (1.5V and 0.9V) are allowed 20
ms maximum to reach their final operating values. However, to keep leakage current at a minimum, it
is recommended to turn on power supplies almost simultaneously (with delay between supplies at most
a few milliseconds).
For power-down, it is recommended to turn off all power rails at the same time and let power supply
voltage decay.
Parameter Description Min Max Units
Overshoot Duration
Maximum overshoot allowed duration.
(At that time delta voltage should be lower
than 5mv from steady state voltage)
0.0 0.05 mS
Decoupling Capacitance Capacitance range 15 μF
Capacitance ESR Equivalent series resistance of output
capacitance 50 M Ω
1. Power supply voltage with ripple should not be below minimum power supply operating range.
Table 11-2. Power Sequencing
Symbol Parameter Min Max Units
T3_09 VCC3P3 (3.3V) power supply stable to VCC0P9 (0.9V) power
supply stable 1320 ms
T3_15 VCC3P3 (3.3V) power supply stable to VCC1P5 (1.5V) power
supply stable 1320 ms
Tm-per 3.3V power supply to PE_RST_N de-assertion1
1. If external LAN_PWR_GOOD is used, this time should be kept between LAN_PWR_GOOD assertion and PE_RST_N de-assertion.
2. Parameter relevant only if external LAN_PWR_GOOD used.
3. With external power supplies.
100 ms
Tlpg Power Supplies Stable to LAN_PWR_GOOD assertion 0 ms
Tlpg-per LAN_PWR_GOOD assertion to PE_RST_N de-assertion1100 ms
Tper-m PE_RST_N off before 3.3V power supply down 0 ms
Tlpgw LAN_PWR_GOOD de-assertion time21 ms
Electrical/Mechanical Specification—Ethernet Controller I210
787
11.3.1.2 Power-On Reset Thresholds
The I210 internal power-on reset circuitry initiates a full chip reset when voltage levels of power
supplies reach certain thresholds at power-up.
Note: The POR circuit only generates a reset during the power up but does not monitor the power
levels after power is stable. Therefore, it does not generate any reset in power-down or when
power levels decrease.
11.4 Ball Summary
See Chapter 2.0 for balls description and ball out map.
Figure 11-1. Power and Reset Sequencing
Table 11-3. Power-on Reset Thresholds
Symbol Parameter
Specifications
Units
Min Typ Max
VTh3.3 Threshold for 3.3 V power supply in power-up 0.96 1.2 1.44 V
VTh0.9 Threshold for 0.9 V power supply in power-up 0.52 0.66 0.8 V
VTh1.5 Threshold for 1.5 V power supply in power-up 0.88 1.1 1.32 V
VCC1p5 (1.5V)
INTERNAL_POWER
_ON_RESET
VCCP (3.3V)
Aux power stable
Main power stable
Tlpg
Tlpg-per
Tm-per
Main Power stable
Tper-m
VCC/VCC0p9(0.9V) T3_15
PE_RST_N
T3_09
Tlpgw
Typ 6.5 ms; Max 7.5 ms
Ethernet Controller I210 —Electrical/Mechanical Specification
788
11.5 Current Consumption
Condition Speed (Mb/s) Condition
Total
Power
Internal
SVR (mW)
0.9V
Current-
External
(mA)
1.5V
Current-
External
(mA)
3.3V
Current-
External
(mA)
Total Power
Ext. Regulator
(mW)
D0a - active link
10 Typ 381 48.3 16.3 85.1 348
100 Typ 373 54.4 24.9 75.5 334
1000 copper Typ 612 99.7 52.6 111.2 535
1000 fiber Typ 363 57.9 37.1 61.8 312
1000 copper Max-
Commercial 740 1601
1. Estimated values.
54112216261
1000 fiber Max-
Commercial 490 11113818014211
1000 copper Max-IT 800 190155113216901
1000 fiber Max-IT 510 12113918314411
D0a - idle link
EEE disabled
No link Typ 185 37.1 11.3 33.3 160
10 Typ 242 38.2 16.4 44.6 206
100 Typ 258 43.1 24.9 54.5 227
1000 copper Typ 487 80.6 52.5 82.2 422
1000 fiber Typ 354 52 36.8 61.8 306
D0a - idle link
EEE enabled
No link Typ - - - - -
10 Typ 233 38.1 15.9 44.5 206
100 Typ 198 39.3 16 33.6 170
1000 copper Typ 200 41.1 21.1 33.8 180
D3cold - WoL
enabled
No link Typ 104 28.2 11.3 13.4 87
10 Typ 151 29.4 16.4 24.3 132
100 Typ 162 34.3 24.9 25.4 152
100 EEE enabled Typ 108 30.5 16.1 13.6 97
1000 Typ 404 72.1 52.5 62.1 349
1000 EEE enabled Typ 220 32.2 21.1 14.1 107
D3cold-WoL
disabled (PCIe L3) No link
Max-
Commercial 155
Max-IT 173
D0 uninitialized
disabled through
DEV_OFF_N No link Typ 89 23.3 4.4 13.3 71
Manageability with
MCTP mode in
D3Cold State - WoL
disabled.
100 Typ 312 32.7 21.9 14 108
Notes: Typ = Typical units, nominal voltage and room temperature.
Max = Typical units, high voltage, and hot temperature.
Electrical/Mechanical Specification—Ethernet Controller I210
789
11.6 DC/AC Specification
11.6.1 DC Specifications
11.6.1.1 Digital I/O
Table 11-4. Digital IO DC Electrical Characteristics
Symbol Parameter Conditions Min Max Units Note
VCC3P3 Periphery Supply 2.97 3.465 V 3.3V + 5%/3.3V -10%
VCC Core Supply 0.855 0.945 V 0.9V +/- 5%
VOH Output High Voltage IOH = -8 mA; VCC3P3 = Min 2.4 V 3
IOH = -100 A; VCC3P3 = Min VCC3P3-
0.2
VOL Output Low Voltage IOL = 8 mA; VCC=Min 0.4 V 4, 5
IOL = 100 A; VCC=Min 0.2 V
VIH Input High Voltage 0.7 x
VCC3P3 VCC3P3 +
0.4 V 1
VIL Input Low Voltage -0.4 0.3 x
VCC3P3 V 1
Iil Input Current VCC3P3 = Max; VI =3.6V/GND +/- 10 µA
PU Internal Pull Up VIL = 0V 40 150 K 2
Built-in Hysteresis 150 mV
Cin Input Pin Capacitance 5 pF
Vos Overshoot N/A 4 V
Vus Undershoot N/A -0.4 V
Notes:
1. Applies to PE_RST_N, LAN_PWR_GOOD, DEV_OFF_N, JTAG_CLK, JTAG_TDI, JTAG_TDO, JTAG_TMS, SDP0,SDP1, SDP2, and
SDP3. The input buffer also has hysteresis > 100mV.
2. Internal pull up max characterized at slow corner (125C, VCC3P3=min, process slow); internal pull up min characterized at
fast corner (0C, VCC3P3=max, process fast).
3. JTAG_TDO, NVM_CS_N, NVM_SI, NVM_SK, SDP[0], SDP[1], SDP[2], SDP[3], SFP_I2C_DATA - IOH = -6 mA.
4. JTAG_TDO, NVM_CS_N, NVM_SI, NVM_SK, SDP[0], SDP[1], SDP[2], SDP[3], SFP_I2C_DATA - IOL = 6 mA.
5. SFP_I2C_DATA - VOL Max = 0.43 [V].
Ethernet Controller I210 —Electrical/Mechanical Specification
790
11.6.1.2 LEDs I/O
11.6.1.3 Open Drain I/Os
11.6.1.4 NC-SI Input and Output Pads
Table 11-5. LED IO DC Electrical Characteristics
Symbol Parameter Conditions Min Max Units Note
VCC3P3 Periphery Supply 2.97 3.465 V
VCC Core Supply 0.855 0.945 V
VOH Output High Voltage IOH = -20 mA; VCC3P3 = Min 2.4 V
VOL Output Low Voltage IOL = 20 mA; VCC=Min 0.45 V
VIH Input High Voltage 0.7 x
VCC3P3 VCC3P3 +
0.4 V 1
VIL Input Low Voltage -0.4 0.3 x
VCC3P3 V 1
Iil Input Current VCC3P3 = Max; VI =3.6V/GND +/- 20 µA
Vos Overshoot N/A 4 V
Vus Undershoot N/A -0.4 V
Notes:
1. The input buffer also has hysteresis > 150 mV.
2. Applies to LED0, LED1, and LED2.
Table 11-6. Open Drain DC Specifications (Note 1, 4)
Symbol Parameter Condition Min Max Units Note
VCC3P3 Periphery Supply 2.97 3.465 V
VCC Core Supply 0.855 0.945 V
Vih Input High Voltage 2.0 5.5 V
Vil Input Low Voltage 0.7 V
Ileakage Output Leakage Current 0 < Vin < VCC3P3 +/-10 µA 2
Vol Output Low Voltage @ Ipullup 0.4 V 4
Iol Output Low Current Vol=0.4V 16 mA
Cin Input Pin Capacitance 5 pF 3
Ioffsmb Input Leakage Current VCC3P3 off or floating +/-10 µA 2
Notes:
1. Applies to SMB_DAT, SMB_CLK, SMB_ALRT_N, PE_WAKE_N and VR_EN pads.
2. Device meets this whether powered or not.
3. Characterized, not tested.
4. OD no high output drive. VOL max=0.4V at 6 mA, VOL max=0.2V at 0.1 mA.
Table 11-7. NC-SI Pads DC Specifications
Symbol Parameter Conditions Min Max Units
VCC3P3 Periphery Supply 2.97 3.465 V
VCC Core Supply 0.855 0.945 V
Vabs Signal Voltage Range -0.3 3.765 V
Electrical/Mechanical Specification—Ethernet Controller I210
791
11.6.2 Digital I/F AC Specifications
11.6.2.1 Reset Signals
The timing between the power up sequence and the different reset signals is described in Figure 11-1
and in Table 11-2.
11.6.2.1.1 LAN_PWR_GOOD
The I210 uses an internal power on detection circuit in order to generate the LAN_PWR_GOOD signal.
Reset can also be implemented when the external power on detection circuit determines that the device
is powered up and asserts the LAN_PWR_GOOD signal to reset the device.
11.6.2.2 SMBus
Table 11-8 lists the timing guaranteed when the driver or the agent is performing the action. Where
only a typical value is specified, the actual value will be within 2% of the value indicated.
VOH2Output High Voltage IOH = -4 mA; VCC3P3 = Min VCC3P3 -
0.4 V
VOL Output Low Voltage IOL = 4 mA; VCC3P3 = Min 0.4 V
VIH Input High Voltage 0.7 x
VCC3P3 V
VIL Input Low Voltage 0.3 x
VCC3P3 V
Vihyst Input Hysteresis 100 mV
Iil/Iih Input Current VCC3P3 = Max; Vin =3.6V/GND 20 µA
Cin Input Capacitance 5 pF
1. Applies to the NC_SI_CLK_OUT, NC_SI_CRS_DV, NC_SI_RXD[1:0], NC_SI_ARB_OUT, NC_SI_TX_EN, NC_SI_TXD[1:0],
NC_SI_CLK_IN, NC_SI_ARB_IN.
2. NC_SI_ARB_OUT - VOH Min = VCC3P3-0.65 [V].
Table 11-8. SMBus Timing Parameters (Master Mode)
Symbol Parameter Min Typ 100
Khz
Typ 400
Khz
Typ 1
MHz Max Units
FSMB SMBus Frequency 100 400 1000 1000 kHz
TBUF Time between Stop and Start
condition driven by the I210 0.5 4.7 1.3 0.5 µs
THD:STA
Hold Time After Start Condition.
After this period, the first clock is
generated. 0.26 4 0.6 0.26 µs
TSU:STA Start Condition Setup Time 0.14 2 0.3 0.14 µs
TSU:STO Stop Condition Setup Time 0.26 4 0.6 0.26 µs
THD:DAT Data Hold Time 0 0.3 0 0 µs
TSU:DAT Data Setup Time 0.05 0.25 0.1 0.05 µs
Table 11-7. NC-SI Pads DC Specifications (Continued)
Symbol Parameter Conditions Min Max Units
Ethernet Controller I210 —Electrical/Mechanical Specification
792
Table 11-9 lists the timing requirements of the I210 when it is the receiver of the indicated signal.
TTIMEOUT Detect SMB_CLK Low Timeout 35 35 35 35 35 ms
TLOW SMB_CLK Low Time 0.5 4.7 1.3 0.5 µs
THIGH SMB_CLK High Time 0.26 4 0.6 0.26 µs
Table 11-9. SMBus Timing Parameters (Slave Mode)
Symbol Parameter Min 100
KHz1
1. Specifications based on SMBus specification.
Min 400
KHz2
2. Specifications based on I2C specification for Fast-mode (400 KHz).
Min 1
MHz3
3. Specifications based on I2C specification rev 03 for Fast-mode Plus (1 MHz).
Max Units
FSMB SMBus Frequency 10 10 10 1000 kHz
TBUF Time between Stop and Start condition
driven by partner. 4.7 1.3 0.5 µs
THD:STA Hold Time After Start Condition. After this
period, the first clock is generated. 4 0.6 0.26 µs
TSU:STA Start Condition Setup Time 4.7 0.6 0.26 µs
TSU:STO Stop Condition Setup Time 4 0.6 0.26 µs
THD:DAT Data Hold Time 300 100 0 ns
TSU:DAT Data Setup Time 250 100 50 ns
TLOW SMB_CLK Low Time 4.7 1.3 0.5 µs
THIGH SMB_CLK High Time 4 0.6 0.26 µs
Figure 11-2. SMBus I/F Timing Diagram
Table 11-8. SMBus Timing Parameters (Master Mode) (Continued)
Symbol Parameter Min Typ 100
Khz
Typ 400
Khz
Typ 1
MHz Max Units
P
tBUF
tRtHD;STA
S
tHD;STA
tLOW
tHD;DAT tHIGH
tF
tSU;DAT tSU;STA tSU;STO
SMB_CLK
P
S
SMB_DATA
Electrical/Mechanical Specification—Ethernet Controller I210
793
11.6.2.3 I2C AC Specification
Table 11-10 lists the timing of the I2C_CLK and I2C_DATA pins when operating in I2C mode.
11.6.2.4 Flash AC Specification
The I210 is designed to support a serial Flash. Applicable over the recommended operating range from
Ta = -40 C to +85 C, VCC3P3 = 3.3V, Cload = 1 TTL Gate and 16 pF (unless otherwise noted). For
Flash I/F timing specification Table 11-11 and Figure 11-4.
Table 11-10. I2C Timing Parameters
Symbol Parameter Min Typ Max Units
FSCL I2C_CLK Frequency 100 kHz
TBUF Time between Stop and Start condition driven by
the I210 4.7 µs
THD:STA Hold Time After Start Condition. After this period,
the first clock is generated. 4 µs
TSU:STA Start Condition Setup Time 4.7 µs
TSU:STO Stop Condition Setup Time 4 µs
THD:DAT Data Hold Time 501
1. According to Atmel's AT24C01A/02/04 definition of the 2 wires interface.
ns
TSU:DAT Data Setup Time 0.25 µs
TLOW I2C_CLK Low Time 4.7 µs
THIGH I2C_CLK High Time 4 µs
Figure 11-3. I2C I/F Timing Diagram
Ethernet Controller I210 —Electrical/Mechanical Specification
794
Table 11-11. Flash I/F Timing Parameters
Symbol Parameter Pad Name Min Typ Max Units Note
fSCK Serial Clock (SCK) frequency
for all instructions NVM_SK 3.125 MHz After power on.
fSCK
Serial Clock (SCK) frequency
for all instructions (word
0x11 loaded) NVM_SK 12.5 MHz Dependent on the value of
the Flash Speed field.
fSCK
Serial Clock (SCK) frequency
for all instructions (LAN PLL
operational) NVM_SK 62.5 MHz
Dependent on the value of
the FLASHMODE.FLASH_
SPEED field.
See note [1].
tSCKH SCK high time NVM_SK 7.1 7.8 ns
tSCKL SCK low time NVM_SK 7.1 8.2 ns
tSCKR SCK rise time, peak-to-peak
(Slew Rate) NVM_SK 0.1+0.2 0.7 V/ns
tSCKF SCK fall time, peak-to-peak
(Slew Rate) NVM_SK 0.1+0.2 0.7 V/ns
tCSHS CS high setup time
(relative to SCK)
NVM_CS_N
(NVM_SK) N/A N/A N/A ns Device will not output a clock
when NVM_CS_N is high.
tCSHH CS high hold time
(relative to SCK)
NVM_CS_N
(NVM_SK) N/A N/A N/A ns Device will not output a clock
when NVM_CS_N is high.
tCSLS CS Low setup time NVM_CS_N
(NVM_SK) 6.5 9.2 ns
tCSLH CS Low hold time NVM_CS_N
(NVM_SK) 7 ns
tCSH CS High time NVM_CS_N
(NVM_SK) 16 104 136 ns
tDS Data-out setup time NVM_SI
(NVM_SK) 2+2 7.9 ns
tDH Data-out hold time NVM_SI
(NVM_SK) 5+2 8 ns
tVData-out valid time NVM_SO
(NVM_SK) 0 7 10 ns
Notes:
1. In bit banging mode, the clock is toggled by software at a much lower rate.
Electrical/Mechanical Specification—Ethernet Controller I210
795
11.6.2.5 NC-SI AC Specification
The I210 is designed to support the standard DMTF NC-SI interface. For NC-SI I/F timing specification
see Table 11-12 and Figure 11-5.
Figure 11-4. Flash Timing Diagram
Table 11-12. NC-SI AC Specifications
Symbol Parameter Min Typ Max Units Notes
Tckf NC_SI_CLK_IN Frequency 50 MHz 2
Rdc NC_SI_CLK_IN Duty Cycle 35 65 % 1
Racc NC_SI_CLK_IN accuracy 100 ppm
Tco
Clock-to-out (10 pF =< cload <=50 pF)
NC_SI_RXD[1:0], NCSI_CRS_DV and NCSI_ARB_OUT
Data valid from NC_SI_CLK_IN rising edge
2.5 12.5 ns 4
Tsu NC_SI_TXD[1:0], NC_SI_TX_EN and NC_SI_ARB_IN
Data Setup to NCSI_CLK_IN rising edge 3 ns
Thold NC_SI_TXD[1:0], NC_SI_TX_EN Data hold from
NC_SI_CLK_IN rising edge 1 ns
Tor NC_SI_RXD[1:0], NC_SI_CRS_DV and NC_SI_ARB_OUT
Output Time rise 0.5 6 ns 3
Tof NC_SI_RXD[1:0], NC_SI_CRS_DV and NC_SI_ARB_OUT
Output Time fall 0.5 6 ns 3
Tckr/Tckf NC_SI_CLK_IN Rise/Fall Time 0.5 3.5 ns
Notes:
1. Clock duty cycle measurement: High interval measured from Vih to Vil points, Low from Vil to next Vih.
2. Clock interval measurement from Vih to Vih.
3. Cload = 25 pF.
4. This timing relates to the output pins, while Tsu and Thd relate to timing at the input pins.
5. 10 pF =< Cload <= 30 pF.
Ethernet Controller I210 —Electrical/Mechanical Specification
796
11.6.2.6 JTAG AC Specification
The I210 is designed to support the IEEE 1149.1 standard. Following timing specifications are
applicable over recommended operating range from Ta = 0 oC to +70 oC, VCC3P3 = 3.3V, Cload =
16 pF (unless otherwise noted). For JTAG I/F timing specification see Table 11-13 and Figure 11-6.
Figure 11-5. NC-SI Timing Diagram
Table 11-13. JTAG I/F Timing Parameters
Symbol Parameter Min Typ Max Units Note
tJCLK JTCK clock frequency 10 MHz
tJH JTMS and JTDI hold time 10 nS
tJSU JTMS and JTDI setup time 10 nS
tJPR JTDO propagation Delay 15 nS
Notes:
1. Table 11-13 applies to JTCK, JTMS, JTDI and JTDO.
2. Timing measured relative to JTCK reference voltage of VCC3P3/2.
Tsu
90%
10%
90%
10%
Vckm
Thd
SIGNALS
NC_SI_CLK_IN
gray = signals changing
GND
GND
Tco
Tck
Vm
Electrical/Mechanical Specification—Ethernet Controller I210
797
11.6.2.7 MDIO AC Specification
The I210 is designed to support the MDIO specifications defined in IEEE 802.3 clause 22. Following
timing specifications are applicable over recommended operating range from Ta = 0 oC to +70 oC
(-40 oC to +85 oC for industrial temperature SKUs), VCC3P3 = 3.3V, Cload = 16 pF (unless otherwise
noted). For MDIO I/F timing specification see Table 11-14, Figure 11-7 and Figure 11-8.
Figure 11-6. JTAG AC Timing Diagram
Table 11-14. MDIO I/F Timing Parameters
Symbol Parameter Min Typ Max Units Note
tMCLK MDC clock frequency 2 MHz
tMH MDIO hold time 10 nS
tMSU MDIO setup time 10 nS
tMPR MDIO propagation Delay 10 300 nS
Notes:
1. Table 11-14 applies to MDIO0, MDC0, MDIO1, MDC1, MDIO2, MDC2, MDIO3, and MDC3.
2. Timing measured relative to MDC reference voltage of 2.0V (Vih).
Tjsu
JTMS
JTDI
JTDO
Tjh
Tjclk
JTCK
Tjpr
Ethernet Controller I210 —Electrical/Mechanical Specification
798
11.6.2.8 SFP 2 Wires I/F AC Specification
According to Atmel's AT24C01A/02/04 definition of the 2 wires I/F bus.
Figure 11-7. MDIO Input AC Timing Diagram
Figure 11-8. MDIO Output AC Timing Diagram
Tmsu Tmh
Tmclk
Tmpr
MDIO
Tmclk
MDC
Electrical/Mechanical Specification—Ethernet Controller I210
799
11.6.2.9 PCIe Interface DC/AC Specification
The I210 PCIe Gen 1 interface supports the electrical specifications defined in:
PCI Express* 2.0 Card Electro-Mechanical (CEM) Specification.
PCI Express* 2.1 Base Specification, Chapter 4.
11.6.2.9.1 PCIe Specification - Input Clock
The input clock for PCIe must be a differential input clock in frequency of 100 MHz. For full
specifications please check the PCI Express* 2.0 Card Electro-Mechanical (CEM) Specification (refclk
specifications for Gen 1).
11.6.3 SerDes DC/AC Specification
The SerDes interface supports the following standards:
1. PICMG 3.1 specification Rev 1.0 1000BASE-BX.
2. 1000BASE-KX electrical specification defined IEEE802.3ap clause 70.
3. SGMII on 1000BASE-BX or 1000BASE-KX compliant electrical interface (AC coupling with internal
clock recovery).
4. SFP (Small Form factor Pluggable) Transceiver Rev 1.0
11.6.4 PHY Specification
The specifications define the interface for the back-plane board connection, interface to external
1000BASE-T PHY and the interface to fiber or SFP module.
DC/AC specification is according to Standard 802.3 and 802.3ab version 2008.
100 Base-T parameters are also described in standard ANSI X3.263.
11.6.5 XTAL/Clock Specification
The 25 MHz reference clock of the I210 can be supplied either from a crystal or from an external
oscillator. The recommended solution is to use a crystal.
11.6.5.1 Crystal Specification
Table 11-15. Specification for External Crystal
Parameter Name Symbol Recommended Value Conditions
Frequency fo25.000 [MHz] @25 [°C]
Vibration mode Fundamental
Cut AT
Operating /Calibration Mode Parallel
Frequency Tolerance @25°C f/fo @25°C ±30 [ppm] @25 [°C]
Temperature Tolerance f/fo±30 [ppm]
Ethernet Controller I210 —Electrical/Mechanical Specification
800
11.6.5.2 External Clock Oscillator Specifications
When using an external oscillator the following connection must be used.
Figure 11-9. External Clock Oscillator Connectivity to The I210
Operating Temperature Topr 0 to +70 [°C]
-40 to +85 [°C]
Commercial grade
Industrial grade
Non Operating Temperature Range Topr -30 to +85 [°C]
Equivalent Series Resistance (ESR) Rs50 [] maximum @25 [MHz]
Shunt Capacitance Co6 [pF] maximum
Load Capacitance Cload 16 to 18 pF
Max Drive Level DL0.5 [mW]
Aging f/fo±5 [ppm/year]
External Capacitors C1, C227 [pF]
Table 11-16. Specification for XTAL1 (In)
Parameter Name Symbol Value Conditions
Voltage Input High (minimum) VIH (min) 1.4 [V]
Voltage Input High (maximum) VIH (max) 2.0 [V]
Target XTAL1 (In) amplitude VIH (typ) 1.7 [V]
Voltage Input Low (maximum) VIL (max) 200 [mV]
Input Impedance High impedance
Table 11-17. Specification for External Clock Oscillator
Parameter Name Symbol Value Conditions
Frequency fo25.0 [MHz] @25 [°C]
External OSC Supply Swing Vp-p 2.5 ± 0.25 [V] or 3.3 ± 0.33 [V]
Table 11-15. Specification for External Crystal (Continued)
Parameter Name Symbol Recommended Value Conditions
XTAL1 (In)
XTAL2 (Out)
VCC = 2.5V or 3.3V
External Clock
Oscillator
C1 = 100pF or 51pF
C2 = 47pF
Electrical/Mechanical Specification—Ethernet Controller I210
801
11.6.6 Switching Voltage Regulator (SVR) Capacitor Electrical
Specifications
The following table lists the electrical performance of the 0.9V/1.5V SVR.
11.7 Package
The I210 is assembled in one, single package type: 9 mm x 9 mm 64-pin QFN package.
11.7.1 Mechanical Specification for the 9 x 9 QFN Package
11.7.2 9 x 9 QFN Package Schematics
Refer to Figure 2-2.
11.8 Flash Devices
While Intel does not make recommendations regarding these devices, the following devices might
match to be used successfully. Minimum Flash size required is 8 Mb or 16 Mb, depending if an
Expansion/Option ROM module is needed.
Frequency Tolerance f/fo±50 [ppm] -20 to +70 [°C]
Operating Temperature Topr 0 to +70 [°C]
-40 to +85 [°C]
Commercial grade
Industrial grade
Maximum jitter 12KHz-20 MHz RMS11.5 [ps]
1. At the XTAL1 input.
Parameter Min Typ Max Unit Comments
Regulator input voltage 2.97 3.3 3.465 V
Regulator output voltages 0.9
1.5 V
Output Voltage Accuracy 5 % Not including line and load regulation errors.
Load Current 0 175 mA 175mA (max) for each 0.9V and 1.5V rail.
Startup Time 4 5 6 ms
Load Capacitor 20 µF Ceramic bulk capacitors.
Flying Capacitor 39 nF Located close to package related pins.
Table 11-18. I210 9 x 9 Package Mechanical Specifications
Body Size Pin Count Pin Pitch Ball Matrix Center Matrix Substrate
9 x 9 64 0.5 mm N/A, peripheral N/A, exposed pad N/A, led frame-based
package
Table 11-17. Specification for External Clock Oscillator (Continued)
Ethernet Controller I210 —Electrical/Mechanical Specification
802
11.8.1 Flash Parts
Supported Flash Parts
Winbond* Compatible:1
W25X40BVSNIG
W25X80BVSNIG
W25Q40BVSNIG
W25Q80BVSNIG
Winbond Validated:2
W25Q80BVSSIG
W25Q16CVSSIG
W25Q16JVSNIQ
W25Q32JVSSIQ
W25Q80DVSNIQ
Micron* (Numonyx*) Compatible:1
M25PE40
M25PE80
M25PX80
N25Q032
Micron (Numonyx) Validated:2
M25PX80VMW6G
M25PE80VMW6TG
N25Q032A13ESE40F
Macronix* Compatible:1
MX25L4005
MX25L8005
MX25L1633E
MX25L1633EM2I
Macronix Validated:2
MX25L1633EM2I
MX25V4035F
MX25V8035F
MX25V1635F
Microchip (SST)* Compatible:1
SST25VF032B
SST25VF040B-80-4I-SAE
SST25VF080B-80-4I-SAE
Microchip (SST) Validated:2
SST25VF040B.
Atmel* Compatible:1
AT25DF041A
Atmel Validated:2
AT25DF081A).
AT25DF321A
EON* Validated:2
EN25Q32B
EN25QH16
EN25Q64
Electrical/Mechanical Specification—Ethernet Controller I210
803
Fidelix* Validated:2
FM25S16A
AMIC* Validated:2
A25L040M
Spansion* Validated:2
S25FL008K0XMF
ESMT* Validated:2
F25L04PA
Adesto* Validated2
DS-AT25SF081
DS-AT25SF321
ISSI* Validated2
IS25WP080DNLE
1. Compatible by design but not tested.
2. Validated Flash parts.
Supported Flash Parts
Ethernet Controller I210 —Electrical/Mechanical Specification
804
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Design Considerations—Ethernet Controller I210
805
12.0 Design Considerations
This section provides general design considerations and recommendations when selecting components
and connecting special pins to the I210. Intel recommends that these design considerations be used in
conjunction with the following board design documents:
Intel® Ethernet Controller I210_82574 – Schematics / Diagrams
Intel® Ethernet Controller I210-IS – Schematics / Diagrams
Intel® Ethernet Controller I210-AT_I211-AT – Schematics / Diagrams
Intel® Ethernet Controller I210_82574 – Dual Layout Review Checklist
Intel® Ethernet Controller I210-IS – Layout Review Checklist
Intel® Ethernet Controller I210-AT/IT – Layout Review Checklist
Intel® 82574_82583 Gigabit Ethernet Controller to I210_I211 – Design Guide
12.1 PCIe
12.1.1 Port Connection to the I210
PCIe is a dual simplex point-to-point serial differential low-voltage interconnect with a signaling bit rate
of 2.5 Gb/s per direction. The I210’s PCIe port consists of an integral group of transmitters and
receivers. The link between the PCIe ports of two devices is a x1 lane that also consists of a transmitter
and a receiver pair. Note that each signal is 8b/10b encoded with an embedded clock.
The PCIe topology consists of a transmitter (Tx) located on one device connected through a differential
pair connected to the receiver (Rx) on a second device. The I210 can be located on a LOM or on an
add-in card using a connector specified by PCIe.
The lane is AC-coupled between its corresponding transmitter and receiver. The AC-coupling capacitor
is located on the board close to transmitter side. Each end of the link is terminated on the die into
nominal 100 differential DC impedance. Board termination is not required.
For more information on PCIe, refer to the PCI Express* Base Specification, Revision 1.1, PCI Express*
Card Electromechanical Specification, Revision 1.1RD, and PCIe v2.1 (2.5GT/s) Gen1 x 1.
For information about the I210’s PCIe power management capabilities, see Section 5.0.
12.1.2 PCIe Reference Clock
The I210 uses a 100 MHz differential reference clock, denoted PECLKp and PECLKn. This signal is
typically generated on the system board and routed to the PCIe port. For add-in cards, the clock is
furnished at the PCIe connector.
The frequency tolerance for the PCIe reference clock is +/- 300 ppm.
Ethernet Controller I210 —Design Considerations
806
12.1.3 Other PCIe Signals
The I210 also implements other signals required by the PCIe specification. The I210 signals power
management events to the system using the PE_WAKE_N signal, which operates very similarly to the
familiar PCI PME# signal. Finally, there is a PE_RST_N signal, which serves as the familiar reset
function for the I210.
12.1.4 PCIe Routing
Contact your Intel representative for information regarding the PCIe signal routing.
12.2 Clock Source
All designs require a 25 MHz clock source. The I210 uses the 25 MHz source to generate clocks up to
125 MHz and 1.25 GHz for the PHY circuits. For optimum results with lowest cost, connect a 25 MHz
parallel resonant crystal and appropriate load capacitors at the XTAL1 and XTAL2 leads. The frequency
tolerance of the timing device should be 30 ppm or better. Refer to the Intel® Ethernet Controllers
Timing Device Selection Guide for more information on choosing crystals.
For further information regarding the clock for the I210, refer to the sections about frequency control,
crystals, and oscillators that follow.
12.2.1 Frequency Control Device Design Considerations
This section provides information regarding frequency control devices, including crystals and oscillators,
for use with all Intel Ethernet controllers. Several suitable frequency control devices are available; none
of which present any unusual challenges in selection. The concepts documented herein are applicable to
other data communication circuits, including Platform LAN Connect devices (PHYs).
Intel Ethernet controllers contain amplifiers, which when used with the specific external components,
form the basis for feedback oscillators. These oscillator circuits, which are both economical and reliable,
are described in more detail in Section 12.3.1.
The chosen frequency control device vendor should be consulted early in the design cycle. Crystal and
oscillator manufacturers familiar with networking equipment clock requirements can provide assistance
in selecting an optimum, low-cost solution.
12.2.2 Frequency Control Component Types
Several types of third-party frequency reference components are currently marketed. A discussion of
each follows, listed in preferred order.
12.2.2.1 Quartz Crystal
Quartz crystals are generally considered to be the mainstay of frequency control components due to
their low cost and ease of implementation. They are available from numerous vendors in many package
types and with various specification options.
Design Considerations—Ethernet Controller I210
807
12.2.2.2 Fixed Crystal Oscillator
A packaged fixed crystal oscillator comprises an inverter, a quartz crystal, and passive components
conveniently packaged together. The device renders a strong, consistent square wave output.
Oscillators used with microprocessors are supplied in many configurations and tolerances.
Crystal oscillators should be restricted to use in special situations, such as shared clocking among
devices or multiple controllers. As clock routing can be difficult to accomplish, it is preferable to provide
a separate crystal for each device.
12.2.2.3 Programmable Crystal Oscillators
A programmable oscillator can be configured to operate at many frequencies. The device contains a
crystal frequency reference and a phase lock loop (PLL) clock generator. The frequency multipliers and
divisors are controlled by programmable fuses.
A programmable oscillator’s accuracy depends heavily on the Ethernet device’s differential transmit
lines. The Physical Layer (PHY) uses the clock input from the device to drive a differential Manchester
(for 10 Mb/s operation), an MLT-3 (for 100 Mbps operation) or a PAM-5 (for 1000 Mb/s operation)
encoded analog signal across the twisted pair cable. These signals are referred to as self-clocking,
which means the clock must be recovered at the receiving link partner. Clock recovery is performed
with another PLL that locks onto the signal at the other end.
PLLs are prone to exhibit frequency jitter. The transmitted signal can also have considerable jitter even
with the programmable oscillator working within its specified frequency tolerance. PLLs must be
designed carefully to lock onto signals over a reasonable frequency range. If the transmitted signal has
high jitter and the receiver’s PLL loses its lock, then bit errors or link loss can occur.
PHY devices are deployed for many different communication applications. Some PHYs contain PLLs with
marginal lock range and cannot tolerate the jitter inherent in data transmission clocked with a
programmable oscillator. The American National Standards Institute (ANSI) X3.263-1995 standard test
method for transmit jitter is not stringent enough to predict PLL-to-PLL lock failures, therefore, the use
of programmable oscillators is not recommended.
12.2.2.4 Ceramic Resonator
Similar to a quartz crystal, a ceramic resonator is a piezoelectric device. A ceramic resonator typically
carries a frequency tolerance of ±0.5%, – inadequate for use with Intel Ethernet controllers, and
therefore, should not be utilized.
Ethernet Controller I210 —Design Considerations
808
12.3 Crystal Support
12.3.1 Crystal Selection Parameters
All crystals used with Intel Ethernet controllers are described as AT-cut, which refers to the angle at
which the unit is sliced with respect to the long axis of the quartz stone. Table 12-19 lists crystals which
have been used successfully in other designs (however, no particular product is recommended):
For information about crystal selection parameters, see Section 11.6.5 and Table 11-15.
12.3.1.1 Vibrational Mode
Crystals in the above-referenced frequency range are available in both fundamental and third overtone.
Unless there is a special need for third overtone, use fundamental mode crystals.
At any given operating frequency, third overtone crystals are thicker and more rugged than
fundamental mode crystals. Third overtone crystals are more suitable for use in military or harsh
industrial environments. Third overtone crystals require a trap circuit (extra capacitor and inductor) in
the load circuitry to suppress fundamental mode oscillation as the circuit powers up. Selecting values
for these components is beyond the scope of this document.
12.3.1.2 Nominal Frequency
Intel Ethernet controllers use a crystal frequency of 25.000 MHz. The 25 MHz input is used to generate
a 125 MHz transmit clock for 100BASE-TX and 1000BASE-TX operation – 10 MHz and 20 MHz transmit
clocks, for 10BASE-T operation.
12.3.1.3 Frequency Tolerance
The frequency tolerance for an Ethernet Platform LAN Connect is dictated by the IEEE 802.3
specification as ±50 parts per million (ppm). This measurement is referenced to a standard
temperature of 25° C. Intel recommends a frequency tolerance of ±30 ppm.
12.3.1.4 Temperature Stability and Environmental Requirements
Temperature stability is a standard measure of how the oscillation frequency varies over the full
operational temperature range (and beyond). Several optional temperature ranges are currently
available, including -40° C to +85° C for industrial environments. Some vendors separate operating
temperatures from temperature stability. Manufacturers may also list temperature stability as 50 ppm
in their data sheets.
Table 12-19. Crystal Manufacturers and Part Numbers
Manufacturer Part No.
KDS America DSX321G
NDK America Inc. 41CD25.0F1303018
TXC Corporation - USA 7A25000165
9C25000008
Design Considerations—Ethernet Controller I210
809
Note: Crystals also carry other specifications for storage temperature, shock resistance, and reflow
solder conditions. Crystal vendors should be consulted early in the design cycle to discuss the
application and its environmental requirements.
12.3.1.5 Crystal Oscillation Mode
The terms series-resonant and parallel-resonant are often used to describe crystal oscillator circuits.
Specifying parallel mode is critical to determining how the crystal frequency is calibrated at the factory.
A crystal specified and tested as series resonant oscillates without problem in a parallel-resonant
circuit, but the frequency is higher than nominal by several hundred parts per million. The purpose of
adding load capacitors to a crystal oscillator circuit is to establish resonance at a frequency higher than
the crystal’s inherent series resonant frequency.
Figure 12-10 shows the recommended placement and layout of an internal oscillator circuit. Note that
pin X1 and X2 refers to XTAL1 and XTAL2 in the Ethernet device, respectively. The crystal and the
capacitors form a feedback element for the internal inverting amplifier. This combination is called
parallel-resonant, because it has positive reactance at the selected frequency. In other words, the
crystal behaves like an inductor in a parallel LC circuit. Oscillators with piezoelectric feedback elements
are also known as “Pierce” oscillators.
12.3.1.6 Load Capacitance and Discrete Capacitors
The formula for crystal load capacitance is as follows:
where:
CL is the rated Cload of the crystal component and C1 and C2 are discrete crystal circuit
capacitors.
Cstray allows for additional capacitance from solder pads, traces and the I210 package.
Individual stray capacitance components can be estimated and added as parallel capacitances.
Note that total Cstray is typically 3 pF to 7 pF.
Solve for the discrete capacitor values as follows:
C1 = C2 = 2 * [Cload - Cstray]
For example:
If total Cstray = 4.0 pF and if the Cload rating is 18 pF, then the calculated C1 and C2 = 2 * [18
pF - 4.0 pF] = 28 pF.
Note: Because 28 pF is not a standard value, use 27 pF capacitors for C1 and C2, which is the
closest standard value.
The oscillator frequency should be measured with a precision frequency counter where possible. The
values of C1 and C2 should be fine tuned for the design. As the actual capacitive load increases, the
oscillator frequency decreases.
CLC1C2
C1C2+
------------------- Cstray
+=
Ethernet Controller I210 —Design Considerations
810
Note: Intel recommends COG or NPO capacitors with a tolerance of ±5% (approximately
±1 pF) or smaller.
12.3.1.7 Shunt Capacitance
The shunt capacitance parameter is relatively unimportant compared to load capacitance. Shunt
capacitance represents the effect of the crystal’s mechanical holder and contacts. The shunt
capacitance should equal a maximum of 6 pF.
12.3.1.8 Equivalent Series Resistance
Equivalent Series Resistance (ESR) is the real component of the crystal’s impedance at the calibration
frequency, which the inverting amplifier’s loop gain must overcome. ESR varies inversely with
frequency for a given crystal family. The lower the ESR, the faster the crystal starts up. Use crystals
with an ESR value of 50 or better.
12.3.1.9 Drive Level
Drive level refers to power dissipation in use. The allowable drive level for a Surface Mounted
Technology (SMT) crystal is less than its through-hole counterpart, because surface mount crystals are
typically made from narrow, rectangular AT strips, rather than circular AT quartz blanks.
Some crystal data sheets list crystals with a maximum drive level of 1 mW. However, Intel Ethernet
controllers drive crystals to a level less than the suggested 0.3 mW value. This parameter does not
have much value for on-chip oscillator use.
12.3.1.10 Aging
Aging is a permanent change in frequency (and resistance) occurring over time. This parameter is most
important in its first year because new crystals age faster than old crystals. Use crystals with a
maximum of ±5 ppm per year aging.
12.3.1.11 Reference Crystal
The normal tolerances of the discrete crystal components can contribute to small frequency offsets with
respect to the target center frequency. To minimize the risk of tolerance-caused frequency offsets
causing a small percentage of production line units to be outside of the acceptable frequency range, it
is important to account for those shifts while empirically determining the proper values for the discrete
loading capacitors, C1 and C2.
Even with a perfect support circuit, most crystals will oscillate slightly higher or slightly lower than the
exact center of the target frequency. Therefore, frequency measurements (which determine the correct
value for C1 and C2) should be performed with an ideal reference crystal. When the capacitive load is
exactly equal to the crystal’s load rating, an ideal reference crystal will be perfectly centered at the
desired target frequency.
12.3.1.11.1 Reference Crystal Selection
There are several methods available for choosing the appropriate reference crystal:
If a Saunders and Associates (S&A) crystal network analyzer is available, then discrete crystal
components can be tested until one is found with zero or nearly zero ppm deviation (with the
Design Considerations—Ethernet Controller I210
811
appropriate capacitive load). A crystal with zero or near zero ppm deviation will be a good reference
crystal to use in subsequent frequency tests to determine the best values for C1 and C2.
If a crystal analyzer is not available, then the selection of a reference crystal can be done by
measuring a statistically valid sample population of crystals, which has units from multiple lots and
approved vendors. The crystal, which has an oscillation frequency closest to the center of the
distribution, should be the reference crystal used during testing to determine the best values for C1
and C2.
It may also be possible to ask the approved crystal vendors or manufacturers to provide a
reference crystal with zero or nearly zero deviation from the specified frequency when it has the
specified cload capacitance.
When choosing a crystal, customers must keep in mind that to comply with IEEE specifications for 10/
100 and 10/100/1000Base-T Ethernet LAN, the transmitter reference frequency must be precise within
50 ppm. Intel recommends customers to use a transmitter reference frequency that is accurate to
within 30 ppm to account for variations in crystal accuracy due to crystal manufacturing tolerance.
12.3.1.11.2 Circuit Board
Since the dielectric layers of the circuit board are allowed some reasonable variation in thickness, the
stray capacitance from the printed board (to the crystal circuit) will also vary. If the thickness tolerance
for the outer layers of dielectric are controlled within ±17 percent of nominal, then the circuit board
should not cause more than ±2 pF variation to the stray capacitance at the crystal. When tuning crystal
frequency, it is recommended that at least three circuit boards are tested for frequency. These boards
should be from different production lots of bare circuit boards.
Alternatively, a larger sample population of circuit boards can be used. A larger population will increase
the probability of obtaining the full range of possible variations in dielectric thickness and the full range
of variation in stray capacitance.
Next, the exact same crystal and discrete load capacitors (C1 and C2) must be soldered onto each
board, and the LAN reference frequency should be measured on each circuit board.
The circuit board, which has a LAN reference frequency closest to the center of the frequency
distribution, should be used while performing the frequency measurements to select the appropriate
value for C1 and C2.
12.3.1.11.3 Temperature Changes
Temperature changes can cause the crystal frequency to shift. Therefore, frequency measurements
should be done in the final system chassis across the system’s rated operating temperature range.
12.3.2 Crystal Placement and Layout Recommendations
Crystal clock sources should not be placed near I/O ports or board edges. Radiation from these devices
can be coupled into the I/O ports and radiate beyond the system chassis. Crystals should also be kept
away from the Ethernet magnetics module to prevent interference.
Note: Failure to follow these guidelines could result in the 25 MHz clock failing to start.
When designing the layout for the crystal circuit, the following rules must be used:
Place load capacitors as close as possible (within design-for-manufacturability rules) to the crystal
solder pads. They should be no more than 90 mils away from crystal pads.
Ethernet Controller I210 —Design Considerations
812
The two load capacitors, crystal component, the Ethernet controller device, and the crystal circuit
traces must all be located on the same side of the circuit board (maximum of one via-to-ground
load capacitor on each XTAL trace).
Use 27 pF (5% tolerance) 0402 load capacitors.
Place load capacitor solder pad directly in line with circuit trace (see Figure 12-10, point A).
Use 50 impedance single-ended microstrip traces for the crystal circuit.
Route traces so that electro-magnetic fields from XTAL2 do not couple onto XTAL1. Do not route as
differential traces.
Route XTAL1 and XTAL2 traces to nearest inside corners of crystal pad (see Figure 12-10, point B).
Ensure that the traces from XTAL1 and XTAL2 are symmetrically routed and that their lengths are
matched.
The total trace length of XTAL1 or XTAL2 should be less than 750 mils.
Figure 12-10.Recommended Crystal Placement and Layout
12.4 Oscillator Support
The I210 clock input circuit is optimized for use with an external crystal. However, an oscillator can also
be used in place of the crystal with the proper design considerations (see Table 11-17 for detail clock
oscillator specifications):
The input capacitance introduced by the I210 (approximately 20 pF) is greater than the capacitance
specified by a typical oscillator (approximately 15 pF).
The input clock jitter from the oscillator can impact the I210 clock and its performance.
Crystal Pad Crystal Pad
Ethernet Controller
XTAL1XTAL2
27pF
0402
27pF
0402
Crystal
“B” “B”
“A”
90 mils
90 mils
Capacitor Capacitor
Less than 660 mils
Design Considerations—Ethernet Controller I210
813
Note: The power consumption of additional circuitry equals about 1.5 mW.
Table 12-20 lists oscillators that can be used with the I210. Please note that no particular oscillator is
recommended):
12.4.1 Oscillator Placement and Layout Recommendations
Oscillator clock sources should not be placed near I/O ports or board edges. Radiation from these
devices can be coupled into the I/O ports and radiate beyond the system chassis. Oscillators should
also be kept away from the Ethernet magnetics module to prevent interference.
Table 12-20. Oscillator Manufacturers and Part Numbers
Manufacturer Part No.
NDK AMERICA INC 2560TKA-25M
TXC CORPORATION - USA 6N25000160 or
7W25000025
CITIZEN AMERICA CORP CSX750FJB25.000M-UT
Raltron Electronics Corp CO4305-25.000-T-TR
MtronPTI M214TCN
Kyocera Corporation KC5032C-C3
Ethernet Controller I210 —Design Considerations
814
12.5 Ethernet Interface
12.5.1 Magnetics for 1000 BASE-T
Magnetics for the I210 can be either integrated or discrete.
The magnetics module has a critical effect on overall IEEE and emissions conformance. The device
should meet the performance required for a design with reasonable margin to allow for manufacturing
variation. Occasionally, components that meet basic specifications can cause the system to fail IEEE
testing because of interactions with other components or the printed circuit board itself. Carefully
qualifying new magnetics modules prevents this problem.
When using discrete magnetics it is necessary to use Bob Smith termination: Use four 75 resistors for
cable-side center taps and unused pins. This method terminates pair-to-pair common mode impedance
of the CAT5 cable.
Use an EFT capacitor attached to the termination plane. Suggested values are 1500 pF/2 KV or 1000
pF/3 KV. A minimum of 50-mil spacing from capacitor to traces and components should be maintained.
12.5.2 Magnetics Module Qualification Steps
The steps involved in magnetics module qualification are similar to those for crystal qualification:
1. Verify that the vendor’s published specifications in the component datasheet meet or exceed the
specifications in Section 11.6.
2. Independently measure the component’s electrical parameters on the test bench, checking samples
from multiple lots. Check that the measured behavior is consistent from sample to sample and that
measurements meet the published specifications.
3. Perform physical layer conformance testing and EMC (FCC and EN) testing in real systems. Vary
temperature and voltage while performing system level tests.
12.5.3 Third-Party Magnetics Manufacturers
The following magnetics modules have been used successfully in previous designs.
Manufacturer Type Part Number
Amphenol ICM RJMG2310228A0NRAO3-R
Bel Discrete S588-5999-P3
E&E LP discrete 824-00400R
Foxconn ICM JFM38U1C-L1U1W
Midcom Discrete 7093-37R-LF1
Pulse LP discrete H5019DNL
Tyco ICM 1368398-2
Pulse Standard discrete H5007NL
Design Considerations—Ethernet Controller I210
815
12.5.4 Discrete/Integrated Magnetics Specifications
For 60 seconds 2250 Vdc (min)
Open Circuit
Inductance (OCL) or
OCL (alternate)
With 8 mA DC bias at 25 C 400 H (min)
With 8 mA DC bias at 0 C to 70 C 350 H (min)
Insertion Loss
100 KHz through 999 kHz
1.0 MHz through 60 MHz
60.1 MHz through 80 MHz
80.1 MHz through 100 MHz
100.1 MHz through 125 MHz
1 dB (max)
0.6 dB (max)
0.8 dB (max)
1.0 dB (max)
2.4 dB (max)
Return Loss
1.0 MHz through 40 MHz
40.1 MHz through 100 MHz
When reference impedance is 85 , 100 , and
115 .
Note that return loss values might vary with
MDI trace lengths. The LAN magnetics might
need to be measured in the platform where it is
used.
18 dB (min)
12 to 20 * LOG (frequency in MHz / 80) dB (min)
Crosstalk Isolation
Discrete Modules
1.0 MHz through 29.9 MHz
30 MHz through 250 MHz
250.1 MHz through 375 MHz
-50.3+(8.8*(freq in MHz / 30)) dB (max)
-26-(16.8*(LOG(freq in MHz / 250)))) dB (max)
-26 dB (max)
Crosstalk Isolation
Integrated Modules
1.0 MHz through 10 MHz
10.1 MHz through 100 MHz
100.1 MHz through 375 MHz
-50.8+(8.8*(freq in MHz / 10)) dB (max)
-26-(16.8*(LOG(freq in MHz / 100)))) dB (max)
-26 dB (max)
Diff to CMR 1.0 MHz through 29.9 MHz
30 MHz through 500 MHz
-40.2+(5.3*((freq in MHz / 30)) dB (max)
-22+(14*(LOG((freq in MHz / 250)))) dB (max)
CM to CMR
1.0 MHz through 270 MHz
270.1 MHz through 300 MHz
300.1 MHz through 500 MHz
-57+(38*((freq in MHz / 270)) dB (max)
-17-2*((300-(freq in MHz) / 30) dB (max)
-17 dB (max)
Ethernet Controller I210 —Design Considerations
816
12.5.5 Designing the I210 as a 10/100 Mb/s Only Device
To connect the I210 as a 10/100 Mb/s only device:
1. Set bit 4 of the Software Defined Pins Control (LAN Base Address + Word 0x20) to 0b. Setting bit 4
to 1b disables 1000 Mb/s (GbE) operation in all power modes (see Section 6.2.21).
2. Connect MDI pair 0 (pins 57 and 58) and MDI pair 1 (pins 54 and 55) to your magnetics. MDI pair
2 (pins 52 and 53) and MDI pair 3 (pins 49 and 50) can each be pulled up to 1.9 V dc through a
50 resistor or connected to the magnetics as a GbE device if it is desired at a later time to enable
GbE by altering bit 4 of the Software Defined Pins Control (LAN Base Address + Word 0x20; Giga
Disable). See Figure 12-11 and Figure 12-12 for details.
3. Use one of the approved discrete GbE magnetics that were tested with the I210 (refer to
Section 12.5.3). Note that Intel has not tested any 10/100 magnetics with the I210.
Note: If you must use 10/100 magnetics in your design with the I210, the magnetics must
have a Common Mode Choke (CMC) in the receive path.
The I210 supports auto-MDIX; this feature CANNOT be disabled. If there is no CMC in the receive path,
the system most likely will not pass regulatory radiated emission tests when MDI-X mode is used.
Figure 12-11.I210 Gigabit Magnetics Module Connections
I210
MDI_PLUS (0)
MDI_MINUS (0)
MDI_PLUS (1)
MDI_MINUS (1)
57
58
54
55
MDI_PLUS (2)
MDI_MINUS (2)
MDI_PLUS (3)
MDI_MINUS (3)
52
53
49
50
Gigabit M agnetics
Module
Design Considerations—Ethernet Controller I210
817
Figure 12-12.I210 10/100 Mb/s Magnetics Module Connections (With CMC)
12.5.6 Layout Considerations for the Ethernet Interface
These sections provide recommendations for performing printed circuit board layouts. Good layout
practices are essential to meet IEEE PHY conformance specifications and EMI regulatory requirements.
Critical signal traces should be kept as short as possible to decrease the likelihood of being affected by
high frequency noise from other signals, including noise carried on power and ground planes. Keeping
the traces as short as possible can also reduce capacitive loading.
Since the transmission line medium extends onto the printed circuit board, special attention must be
paid to layout and routing of the differential signal pairs.
Designing for 1000 BASE-T GbE operation is very similar to designing for 10 and 100 Mb/s. For the
I210, system level tests should be performed at all three speeds.
12.5.6.1 Guidelines for Component Placement
Component placement can affect signal quality, emissions, and component operating temperature This
section provides guidelines for component placement.
Careful component placement can:
Decrease potential problems directly related to electromagnetic interference (EMI), which could
cause failure to meet applicable government test specifications.
Simplify the task of routing traces. To some extent, component orientation will affect the
complexity of trace routing. The overall objective is to minimize turns and crossovers between
traces.
I210
MDI_PLUS (0)
MDI_MINUS (0)
MDI_PLUS (1)
MDI_MINUS (1)
57
58
54
55
MDI_PLUS (2)
MDI_MINUS (2)
MDI_PLUS (3)
MDI_MINUS (3)
52
53
49
50
LAN_1.5V
10/100 Magnetics
Module with Common Mode
Choke in Both Rx and Tx
Paths 50 Ohm
Resistors
Ethernet Controller I210 —Design Considerations
818
Minimizing the amount of space needed for the Ethernet LAN interface is important because other
interfaces compete for physical space on a motherboard near the connector. The Ethernet LAN circuits
need to be as close as possible to the connector.
Figure 12-13.General Placement Distances for 1000 BASE-T Designs
Figure 12-13 shows some basic placement distance guidelines. Figure 12-13 shows two differential
pairs, but can be generalized for a GbE system with four analog pairs. The ideal placement for the
Ethernet silicon would be approximately one inch behind the magnetics module.
While it is generally a good idea to minimize lengths and distances, Figure 12-13 also illustrates the
need to keep the LAN silicon away from the edge of the board and the magnetics module for best EMI
performance.
12.5.6.2 Layout Guidelines for Use with Integrated and Discrete Magnetics
Layout requirements are slightly different when using discrete magnetics.
These include:
Ground cut for HV installation (not required for integrated magnetics)
A maximum of two (2) vias
Turns less than 45°
Discrete terminators
Figure 12-14 shows a reference layout for discrete magnetics.
LAN
Silicon
Integrated
RJ-45
w/LAN
Magnetics
Keep LAN silicon 1" - 4" from LAN connector.
Keep silicon traces at least 1" from edge of
PB (2" is preferred).
Keep minimum distance between differential pairs
more than seven times the dielectric thickness away
from each other and other traces, including NVM
traces and parallel digital traces.
Note: Figure 12-13 represents a 10/100 diagram. Use the same design considerations for the two
differential pairs not shown for gigabit implementations.
Design Considerations—Ethernet Controller I210
819
Figure 12-14.Layout for Discrete Magnetics
RJ-45
Magnetics Module
I211
Integrated I210
Connector
Module
Ethernet Controller I210 —Design Considerations
820
12.5.6.3 Board Stack-Up Recommendations
Printed circuit boards for these designs typically have four, six, eight, or more layers. Although, the
I210 does not dictate the stack up, here is an example of a typical six-layer board stack up:
Layer 1 is a signal layer. It can contain the differential analog pairs from the Ethernet device to the
magnetics module.
Layer 2 is a signal ground layer. Chassis ground may also be fabricated in Layer 2 under the
connector side of the magnetics module.
Layer 3 is used for power planes.
Layer 4 is a signal layer.
Layer 5 is an additional ground layer.
Layer 6 is a signal layer. For 1000 BASE-T (copper) GbE designs, it is common to route two of the
differential pairs (per port) on this layer.
This board stack up configuration can be adjusted to conform to specific OEM design rules.
Design Considerations—Ethernet Controller I210
821
12.5.6.4 Differential Pair Trace Routing for 10/100/1000 Designs
Trace routing considerations are important to minimize the effects of crosstalk and propagation delays
on sections of the board where high-speed signals exist. Signal traces should be kept as short as
possible to decrease interference from other signals, including those propagated through power and
ground planes. Observe the following suggestions to help optimize board performance:
Maintain constant symmetry and spacing between the traces within a differential pair.
Minimize the difference in signal trace lengths of a differential pair.
Keep the total length of each differential pair under four inches. Although possible, designs with
differential traces longer than five inches are much more likely to have degraded receive Bit Error
Rate (BER) performance, IEEE PHY conformance failures, and/or excessive Electromagnetic
Interference (EMI) radiation.
Consider using a second I210 instead of a LAN switch and long MDI traces. It is difficult to
achieve excellent performance with long traces and analog LAN switches. An optimization effort
is required to tune the system and magnetics modules.
Keep differential pairs more than seven times the dielectric thickness away from each other and
other traces, including Flash traces and parallel digital traces or other disturbing traces.
Keep in-pair trace separation to 7 mils to maintain highly-coupled signaling.
For high-speed signals, the number of corners and vias should be kept to a minimum. If a 90° bend
is required, it is recommended to use two 45° bends instead. Refer to Figure 12-15.
Note: In manufacturing, vias are required for testing and troubleshooting purposes. The via size
should be a 17-mil (±2 mils for manufacturing variance) finished hole size (FHS).
Traces should be routed away from board edges by a distance greater than the trace height above
the reference plane. This allows the field around the trace to couple more easily to the ground plane
rather than to adjacent wires or boards.
Do not route traces and vias under crystals or oscillators. This prevents coupling to or from the
clock. And as a general rule, place traces from clocks and drives at a minimum distance from
apertures by a distance that is greater than the largest aperture dimension.
.
Figure 12-15.Trace Routing
The reference plane for the differential pairs should be continuous and low impedance. It is
recommended that the reference plane be either ground or 0.9 Vdc (the voltage used by the PHY).
This provides an adequate return path for and high frequency noise currents.
Do not route differential pairs over splits in the associated reference plane as it might cause
discontinuity in impedances.
45°
45°
Ethernet Controller I210 —Design Considerations
822
12.5.6.5 Maximum Trace Lengths Based on Trace Geometry
Note:
1. Longer MDI trace lengths might be achievable, but might make it more difficult to achieve IEEE conformance. Simulations have
shown deviations are possible if traces are kept short. Longer traces are possible; use cost considerations and stack-up
tolerance for differential pairs to determine length requirements.
2. Deviations from 100 Ω nominal and/or tolerances greater than 15% decrease the maximum length for IEEE conformance.
Use the MDI differential trace calculator to determine the maximum MDI trace length for board-specific
trace geometry and board stack-up. Contact your Intel representative for access.
The following factors can limit the maximum MDI differential trace lengths for IEEE conformance:
Dielectric thickness
Dielectric constant
Nominal differential trace impedance
Trace impedance tolerance
Copper trace losses
Additional devices, such as switches, in the MDI path may impact IEEE conformance.
Board geometry should also be factored in when setting trace length.
Table 12-21. Maximum Trace Lengths Based on Trace Geometry and Board Stack-Up
Dielectric
Thickness
(mils)
Dielectric
Constant (DK)
at
1 MHz
Width /
Space/ Width
(mils)
Pair-to-Pair
Space (mils)
Nominal
Impedance (Ω)
Impedance
Tolerance (±%)
Maximum Trace
Length
(inches)1
2.7 4.05 4/10/4 19 9521723.5
2.7 4.05 4/10/4 19 9521524
2.7 4.05 4/10/4 19 95 10 5
3.3 4.1 4.2/9/4.2 23 10021724
3.3 4.1 4.2/9/4.2 23 100 15 4.6
3.3 4.1 4.2/9/4.2 23 100 10 6
4 4.2 5/9/5 28 10021724.5
4 4.2 5/9/5 28 100 15 5.3
4 4.2 5/9/5 28 100 10 7
4 4.2 5/7/5 28 95 10 5.4
4 4.2 5/7/5 28 95 15 4.8
4 4.2 5/7/5 28 95 17 4.3
Design Considerations—Ethernet Controller I210
823
12.5.6.6 Signal Termination and Coupling
The I210 has internal termination on the MDI signals. External resistors are not needed. Adding pads
for external resistors can degrade signal integrity.
12.5.6.7 Signal Trace Geometry for 1000 BASE-T Designs
The key factors in controlling trace EMI radiation are the trace length and the ratio of trace-width to
trace-height above the reference plane. To minimize trace inductance, high-speed signals and signal
layers that are close to a reference or power plane should be as short and wide as practical. Ideally, this
trace width to height above the ground plane ratio is between 1:1 and 3:1. To maintain trace
impedance, the width of the trace should be modified when changing from one board layer to another if
the two layers are not equidistant from the neighboring planes.
Each pair of signal should have a differential impedance of 100 ± 15%. Refer to the Intel® 1G
Servers and Client LANs – Copper Loss Calculator for more details.
When performing a board layout, do not allow the CAD tool auto-router to route the differential pairs
without intervention. In most cases, the differential pairs will have to be routed manually.
Note: Measuring trace impedance for layout designs targeting 100 often results in lower actual
impedance. Designers should verify actual trace impedance and adjust the layout accordingly.
If the actual impedance is consistently low, a target of 105 – 110 should compensate for
second order effects.
It is necessary to compensate for trace-to-trace edge coupling, which can lower the differential
impedance by up to 10 , when the traces within a pair are closer than 30 mils (edge to edge).
Figure 12-16.MDI Trace Geometry
Ethernet Controller I210 —Design Considerations
824
12.5.6.8 Trace Length and Symmetry for 1000 BASE-T Designs
As indicated earlier, the overall length of differential pairs should be less than four inches measured
from the Ethernet device to the magnetics.
The differential traces (within each pair) should be equal in total length to within 50 mils (1.25 mm)
and as symmetrical as possible. Asymmetrical and unequal length traces in the differential pairs
contribute to common mode noise. If a choice has to be made between matching lengths and fixing
symmetry, more emphasis should be placed on fixing symmetry. Common mode noise can degrade the
receive circuit’s performance and contribute to radiated emissions.
12.5.6.9 Magnetics Center Tap
The I210 includes a voltage mode driver so it doesn’t require an analog powered center tap. The
decoupling capacitors for the central tap pins should be placed as close as possible to the magnetic
component. This improves EMI compliance.
12.5.6.10 Impedance Discontinuities
Impedance discontinuities cause unwanted signal reflections. Minimize vias (signal through holes) and
other transmission line irregularities. If vias must be used, a reasonable budget is two per differential
trace. Unused pads and stub traces should also be avoided.
12.5.6.11 Reducing Circuit Inductance
Traces should be routed over a continuous reference plane with no interruptions. If there are vacant
areas on a reference or power plane, the signal conductors should not cross the vacant area. This
causes impedance mismatches and associated radiated noise levels. Noisy logic grounds should be
separated from analog signal grounds to reduce coupling. Noisy logic grounds can sometimes affect
sensitive DC subsystems such as analog to digital conversion, operational amplifiers, etc. All ground
vias should be connected to every ground plane; and similarly, every power via, to all power planes at
equal potential. This helps reduce circuit inductance. Another recommendation is to physically locate
grounds to minimize the loop area between a signal path and its return path. Rise and fall times should
be as slow as possible. Because signals with fast rise and fall times contain many high frequency
harmonics, which can radiate significantly. The most sensitive signal returns closest to the chassis
ground should be connected together. This will result in a smaller loop area and reduce the likelihood of
crosstalk. The effect of different configurations on the amount of crosstalk can be studied using
electronics modeling software.
12.5.6.12 Signal Isolation
To maintain best signal integrity, keep digital signals far away from the analog traces. A good rule of
thumb is no digital signal should be within 300 mils (7.5 mm) of the differential pairs. If digital signals
on other board layers cannot be separated by a ground plane, they should be routed perpendicular to
the differential pairs. If there is another LAN controller on the board, take care to keep the differential
pairs from that circuit away.
Some rules to follow for signal isolation:
Separate and group signals by function on separate layers if possible. Keep a minimum distance
between differential pairs more than seven times the dielectric thickness away from each other and
other traces, including NVM traces and parallel digital traces.
Design Considerations—Ethernet Controller I210
825
Physically group together all components associated with one clock trace to reduce trace length and
radiation.
Isolate I/O signals from high-speed signals to minimize crosstalk, which can increase EMI emission
and susceptibility to EMI from other signals.
Avoid routing high-speed LAN traces near other high-frequency signals associated with a video
controller, cache controller, processor, or other similar devices.
12.5.6.13 Traces for Decoupling Capacitors
Traces between decoupling and I/O filter capacitors should be as short and wide as practical. Long and
thin traces are more inductive and would reduce the intended effect of decoupling capacitors. Also for
similar reasons, traces to I/O signals and signal terminations should be as short as possible. Vias to the
decoupling capacitors should be sufficiently large in diameter to decrease series inductance.
12.5.6.14 Light Emitting Diodes for Designs Based on the I210
The I210 provides three programmable high-current push-pull (default active low) outputs to directly
drive LEDs for link activity and speed indication. Each LAN device provides an independent set of LED
outputs. Each of the four LED outputs can be individually configured to select the particular event,
state, or activity, which is indicated on that output. In addition, each LED can be individually configured
for output polarity, as well as for blinking versus non-blinking (steady-state) indication.
Since the LEDs are likely to be integral to a magnetics module, take care to route the LED traces away
from potential sources of EMI noise. In some cases, it might be desirable to attach filter capacitors.
The LED ports are fully programmable through the Flash interface.
12.5.7 Physical Layer Conformance Testing
Physical layer conformance testing (also known as IEEE testing) is a fundamental capability for all
companies with Ethernet LAN products. PHY testing is the final determination that a layout has been
performed successfully. If your company does not have the resources and equipment to perform these
tests, consider contracting the tests to an outside facility.
12.5.7.1 Conformance Tests for 10/100/1000 Mb/s Designs
Crucial tests are as follows, listed in priority order:
Bit Error Rate (BER). Good indicator of real world network performance. Perform bit error rate
testing with long and short cables and many link partners. The test limit is 10-11 errors.
Output Amplitude, Rise and Fall Time (10/100 Mb/s), Symmetry and Droop (1 GbE). For the I210,
use the appropriate PHY test waveform.
Return Loss. Indicator of proper impedance matching, measured through the RJ-45 connector back
toward the magnetics module.
Jitter Test (10/100 Mb/s) or Unfiltered Jitter Test (1000 Mb/s). Indicator of clock recovery ability
(master and slave for a GbE controller).
12.5.8 Troubleshooting Common Physical Layout Issues
The following is a list of common physical layer design and layout mistakes in LAN On Motherboard
(LOM) designs.
Ethernet Controller I210 —Design Considerations
826
1. Lack of symmetry between the two traces within a differential pair. Asymmetry can create common-
mode noise and distort the waveforms. For each component and/or via that one trace encounters,
the other trace should encounter the same component or a via at the same distance from the
Ethernet silicon.
2. Unequal length of the two traces within a differential pair. Inequalities create common-mode noise
and will distort the transmit or receive waveforms.
3. Excessive distance between the Ethernet silicon and the magnetics. Long traces on FR4 fiberglass
epoxy substrate attenuates the analog signals. In addition, any impedance mismatch in the traces
will be aggravated if they are longer than the four inch guideline.
4. Routing any other trace parallel to and close to one of the differential traces. Crosstalk getting onto
the receive channel causes degraded long cable BER. Crosstalk getting onto the transmit channel
can cause excessive EMI emissions and can cause poor transmit BER on long cables. At a minimum,
other signals should be kept 0.3 inches from the differential traces.
5. Routing one pair of MDI differential traces too close to another pair of differential traces. After
exiting the Ethernet silicon, the spacing between the trace pairs should be kept about 6 times the
dielectric height for stripline and 7 times the dielectric height for microstrip. Refer to the
appropriate design layout checklist for more details. The only possible exceptions are in the
vicinities where the traces enter or exit the magnetics, the RJ-45 connector, and the Ethernet
silicon.
6. Use of a low-quality magnetics module.
7. Re-use of an out-of-date physical layer schematic in a Ethernet silicon design. The terminations and
decoupling can be different from one PHY to another.
Design Considerations—Ethernet Controller I210
827
8. Incorrect differential trace impedances. It is important to have ~100 impedance between the two
traces within a differential pair. This becomes even more important as the differential traces
become longer. To calculate differential impedance, many impedance calculators only multiply the
single-ended impedance by two. This does not take into account edge-to-edge capacitive coupling
between the two traces. When the two traces within a differential pair are kept close to each other,
the edge coupling can lower the effective differential impedance by 5 to 20 . Short traces have
fewer problems if the differential impedance is slightly off target.
12.6 SMBus and NC-SI
SMBus and NC-SI are optional interfaces for pass-through and/or configuration traffic between the MC
and I210. See Section 3.2.1 and Section 3.2.2 for more details.
This section describes the hardware implementation requirements necessary to meet the NC-SI
physical layer standard. Board-level design requirements are included for connecting I210 Ethernet
solution to an external MC. The layout and connectivity requirements are addressed in low-level detail.
This section, in conjunction with the Network Controller Sideband Interface (NC-SI) Specification
Version 1.0 RMII Specification, also provides the complete board-level requirements for the NC-SI
solution.
The I210’s on-board System Management Bus (SMBus) port enables network manageability
implementations required for remote control and alerting via the LAN. With SMBus, management
packets can be routed to or from an MC. Enhanced pass-through capabilities also enable system remote
control over standardized interfaces. Also included is a new manageability interface, NC-SI that
supports the DMTF preOS sideband protocol. An internal management interface called MDIO enables
the MAC (and software) to monitor and control the PHY.
12.6.1 NC-SI Electrical Interface Requirements
12.6.1.1 External MC
The external MC is required to meet the latest NC-SI specification as it relates to the RMII electrical
interface.
12.6.1.2 NC-SI Reference Schematics
Figure 12-17 shows the single-drop application connectivity requirements. Figure 12-18 shows the
multi-drop application connectivity requirements Figure 11-16 shows the hardware arbitration
connectivity requirements. Refer to the latest NC-SI specification for any additional connectivity
requirements.
Ethernet Controller I210 —Design Considerations
828
Figure 12-17.NC-SI Connection Requirements - Single-Drop Configuration
I210
NC-SI
Interface
Signals
NC-SI_CLK_IN
NC-SI_CRS_DV
NC-SI_RXD_0
NC-SI_RXD_1
NC-SI_TX_EN
NC-SI_TXD_0
NC-SI_TXD_1
DMTF Compliant
MC Device
REF_CLK
CRS_DV
RXD_0
RXD_1
TX_EN
TXD_0
TXD_1
50 MHz Reference
Clock Buffer
50 MHz
33 Ω 33 Ω
22 Ω
22 Ω
10k Ω
10k Ω
3.3V
10k Ω 10k Ω
10k Ω 10k Ω
10k Ω
Design Considerations—Ethernet Controller I210
829
Figure 12-18.NC-SI Connection Requirements - Multi-Drop Configuration
REF_CLK
CRS_DV
RXD_0
RXD_1
TX_EN
TXD_0
TXD_1
50 MHz Reference
Clock Buffer
50 MHz
33 Ω 33 Ω
22 Ω
22 Ω
10k Ω
10k Ω
3.3V
10k Ω 10k Ω
10k Ω 10k Ω
10k Ω
I210
NC-SI
Interface
Signals
NC-SI_CLK_IN
NC-SI_CRS_DV
NC-SI_RXD_0
NC-SI_RXD_1
NC-SI_TX_EN
NC-SI_TXD_0
NC-SI_TXD_1
33 Ω
DMTF
Compliant MC
Device
NC-SI_CLK_IN
NC-SI_CRS_DV
NC-SI_RXD_0
NC-SI_RXD_1
NC-SI_TX_EN
NC-SI_TXD_0
NC-SI_TXD_1
I210 NC-SI Interface
Signals
Ethernet Controller I210 —Design Considerations
830
Figure 12-19.NC-SI Connection Requirements - Hardware Arbitration
12.6.1.3 Resets
It is important to ensure that the resets for the MC and I210 are generated within a specific time
interval. The important requirement here is ensuring that the NC-SI link is established within two
seconds of the MC receiving the power good signal from the platform. Both I210 and the external MC
need to receive power good signals from the platform within one second of each other.
This causes an internal power on reset within I210 and then initialization as well as a triggering and
initialization sequence for the MC. Once these power good signals are received by both I210 and the
external MC, the NC-SI interface can be initialized. The NC-SI specification calls out a requirement of
link establishment within two seconds. The MC should poll this interface and establish a link for two
seconds to ensure specification compliance.
12.6.1.4 Layout Requirements
12.6.1.4.1 Board Impedance
The NC-SI signaling interface is a single-ended signaling environment with a target board and trace
impedance of 50  plus 20% and minus 10% is recommended. This target impedance ensures optimal
signal integrity and signal quality.
12.6.1.4.2 Trace Length Restrictions
Intel recommends a trace length maximum value from a board placement and routing topology
perspective of eight inches for direct connect applications (Figure 12-20). This ensures that signal
integrity and quality is preserved from a design perspective and that compliance is met for the NC-SI
electrical requirements.
Design Considerations—Ethernet Controller I210
831
Figure 12-20.NC-SI Trace Length Requirement for Direct Connect
For multi-drop applications (Figure 12-21) the spacing recommendation is a maximum of four inches.
This keeps the overall length between the MC and I210 within the specification.
Figure 12-21.NC-SI Trace Length Requirement for Multi-Drop
8 inches
I210 External
MC
NC-SI_CLK_IN
NC-SI_TXD(1:0)
NC-SI_RXD(1:0)
NC-SI_CRS_DV
NC-SI_TX_EN
8 inches
I210
External
MC
NC-SI_CLK_IN
NC-SI_TXD(1:0)
NC-SI_RXD(1:0)
I210
4 inches
NC-SI_CRS_DV
NC-SI_TX_EN
. . . . .
Ethernet Controller I210 —Design Considerations
832
12.7 I210 Power Supplies
The I210 requires three power rails: 3.3 Vdc, 1.5 Vdc, and 0.9 Vdc. Intel recommends that board
designers use the integrated switching voltage regulators derived from a single 3.3 Vdc supply to
reduce Bill of Material (BOM) costs. A central power supply can provide the required voltage sources
designed by a system power engineer. If the LAN wake capability is used, all voltages must remain
present during system power down. External voltage regulators need to generate the proper voltage,
supply current requirements (with adequate margin), and provide the proper power sequencing.
Refer to Section 12.7.2 for detailed information about power supply sequencing rules.
12.7.1 Power Delivery Solutions
Table 12-22 shows the intended design options for power delivery solutions. See Section 11.3 for more
details.
Note: Follow the power sequencing instructions described in Section 12.7.2.
Table 12-22. I210 Power Supply Pinouts ( SerDes )
Symbol Lead # Type /
Voltage Name and Function
VDD3p3 51 3.3V Pin 51: In BASE-T, 3.3V analog power supply to GPHY; in
SerDes, 1.5V analog power supply to SGMII SerDes.
VDD1p5 56 1.5V Pin 56: In BASE-T, 1.5V analog power supply to GPHY; in
SerDes, not connected.
Design Considerations—Ethernet Controller I210
833
Figure 12-22.Power Delivery Solutions
OPTION A:
Fully Integrated 0.09 Vdc
and 1.5 Vdc Regulator
47
E_PAD_GND
I210
VDD1p5_OUT
VDD0p9_OUT
CTOP
CBOT
OPTION B:
External 0.09 Vdc and
1.5 Vdc Regulator
15 uF
39
11, 32
42, 59
15 uF
38
Keep close to I210.
Use short wide traces.
Connect to ground plane
using mulitple vias
V3p3_LAN
15 uF
10, 27,
41, 64
40
37
65
Note: Use multiple vias to connect output
to sub layer shape to feed VDD input.
E_PAD_GND
I210
EXTERNAL V1p5
EXTERNAL V0p9
Connect to ground plane
using mulitple vias
V3p3_LAN
15 uF
65
15 uF
VDD0p9
VDD1p5
15 uF
10, 27,
41, 64
VDD3p3
Note: One decoupling
capacitor per
VDD pin (distributed)
0.039 uF
Keep close to I210.
Use short wide traces.
CTOP
CBOT
40
37 0.039 uF
VDD3p3
VDD1p5_OUT
VDD0p9_OUT
39
38
OPT
o
o
OPT
o
o
Ethernet Controller I210 —Design Considerations
834
12.7.2 Ethernet Controller I210 Power Sequencing
Designs must comply with power sequencing requirements to avoid latch-up and forward-biased
internal diodes (see Figure 12-23).
The general guideline for sequencing is:
1. Power up the 3.3 Vdc rail.
2. Power up the 1.5 Vdc next.
3. Power up the 0.9 Vdc rail last.
For power down, there is no requirement (only charge that remains is stored in the decoupling
capacitors).
Figure 12-23.Power Sequencing Guideline
12.7.2.1 Power Up Sequence (External Voltage Regulator)
The board designer controls the power up sequence with the following stipulations (see Figure 12-24):
1.5 Vdc must not exceed 3.3 Vdc by more than 0.3 Vdc.
0.9 Vdc must not exceed 1.5 Vdc by more than 0.3 Vdc.
0.9 Vdc must not exceed 3.3 Vdc by more than 0.3 Vdc.
VDD3p3
VDD1p5
VDD0p9
Design Considerations—Ethernet Controller I210
835
Figure 12-24.External Voltage Regulator Power-up Sequence
12.7.2.2 Power Up-Sequence (Internal SVR)
The I210 controls the power-up sequence internally and automatically with the following conditions
(see Figure 12-25):
3.3 Vdc must be the source for the internal LVR.
1.5 Vdc never exceeds 3.3 Vdc.
0.9 Vdc never exceeds 3.3 Vdc or 1.5 Vdc.
The ramp is delayed internally, with Tdelay depending on the rising slope of the 3.3 Vdc ramp (see Table
11-2).
Figure 12-25.Internal SVR Power-Up Sequence
VDD3p3
VDD1p5
VDD0p9
VDD1p5
VDD0p9
VDD3p3
Ethernet Controller I210 —Design Considerations
836
12.7.3 Power and Ground Planes
Good grounding requires minimizing inductance levels in the interconnections and keeping ground
returns short, signal loop areas small, and power inputs bypassed to signal return, will significantly
reduce EMI radiation.
The following guidelines help reduce circuit inductance in both backplanes and motherboards:
Route traces over a continuous plane with no interruptions. Do not route over a split power or
ground plane. If there are vacant areas on a ground or power plane, avoid routing signals over the
vacant area. This increases inductance and EMI radiation levels.
Separate noisy digital grounds from analog grounds to reduce coupling. Noisy digital grounds may
affect sensitive DC subsystems.
All ground vias should be connected to every ground plane; and every power via should be
connected to all power planes at equal potential. This helps reduce circuit inductance.
Physically locate grounds between a signal path and its return. This minimizes the loop area.
Avoid fast rise/fall times as much as possible. Signals with fast rise and fall times contain many
high frequency harmonics, which can radiate EMI.
The ground plane beneath a magnetics module should be split. The RJ45 connector side of the
transformer module should have chassis ground beneath it.
Power delivery traces should be a minimum of 20 mils wide at all places from the source to the
destination with neck down at package pins. The distribution of power is better done with a copper
plane or shape under the PHY. This provides low inductance connectivity to decoupling capacitors.
Decoupling capacitors should be placed as close as possible to the point of use and should avoid
sharing vias with other decoupling capacitors. Decoupling capacitor placement control should be
done for the PHY as well as any external regulators if used.
An SVR fly capacitor should be preferentially placed near pin 37 and 40 with wide traces to limit in-
line inductance.
SVR output routing: AVDD09_VR_O (pin 38) should be connected with wide traces and plane shape
using more than one via for a layer change to VDD09 pins. The net should have recommended bulk
and decoupling capacitance strongly joined into this route. AVDD15_VR_O (pin 39) has similar
requirements but has lower currents so it might require only wide traces and a single via for any
layer change.
12.8 Device Disable
For a LOM design, it might be desirable for the system to provide BIOS-setup capability for selectively
enabling or disabling LOM devices. This enables designers more control over system resource-
management, avoid conflicts with add-in NIC solutions, etc. The I210 provides support for selectively
enabling or disabling it.
Device disable is initiated by asserting the asynchronous DEV_OFF_N pin. The DEV_OFF_N pin has an
internal pull-up resistor, so that it can be left not connected to enable device operation.
While in device disable mode, the PCIe link is in L3 state. The PHY is in power down mode. Output
buffers are tri-stated.
Assertion or deassertion of PCIe PE_RST_N does not have any effect while the I210 is in device disable
mode (that is, the I210 stays in the respective mode as long as DEV_OFF_N is asserted). However, the
I210 might momentarily exit the device disable mode from the time PCIe PE_RST_N is de-asserted
again and until the Flash is read.
During power-up, the DEV_OFF_N pin is ignored until the NVM is read. From that point, the I210 might
enter device disable if DEV_OFF_N is asserted.
Design Considerations—Ethernet Controller I210
837
Note: The DEV_OFF_N pin should maintain its state during system reset and system sleep states. It
should also insure the proper default value on system power up. For example, a designer
could use a GPIO pin that defaults to 1b (enable) and is on system suspend power. For
example, it maintains the state in S0-S5 ACPI states).
12.8.1 BIOS Handling of Device Disable
Assume that in the following power-up sequence the DEV_OFF_N signal is driven high (or it is already
disabled)
1. The PCIe is established following the GIO_PWR_GOOD.
2. BIOS recognizes that the entire I210 should be disabled.
3. The BIOS drives the DEV_OFF_N signal to the low level.
4. As a result, the I210 samples the DEV_OFF_N signals and enters either the device disable mode.
5. The BIOS could put the link in the Electrical IDLE state (at the other end of the PCIe link) by
clearing the Link Disable bit in the Link Control register.
6. BIOS might start with the device enumeration procedure (the entire I210 functions are invisible).
7. Proceed with normal operation
8. Re-enable could be done by driving high the DEV_OFF_N signal, followed later by bus enumeration.
Ethernet Controller I210 —Design Considerations
838
12.9 Assembly Process Flow
Figure 12-26 shows the typical process flow for mounting packages to the PCB.
Figure 12-26.Assembly Flow
12.10 Reflow Guidelines
The typical reflow profile consists of four sections. In the preheat section, the PCB assembly should be
preheated at the rate of 1 to 2 °C/sec to start the solvent evaporation and to avoid thermal shock. The
assembly should then be thermally soaked for 60 to 120 seconds to remove any volatile solder paste
and for activation of flux. The reflow section of the profile, the time above liquidus should be between
45 to 60 seconds with a peak temperature in the range of 245 to 250 °C, and the duration at the peak
should not exceed 30 seconds. Finally, the assembly should undergo cool down in the fourth section of
the profile. A typical profile band is provided in Figure 12-27, in which 220 °C is referred to as an
approximation of the liquidus point. The actual profile parameters depend upon the solder paste used
and specific recommendations from the solder paste manufacturers should be followed.
Design Considerations—Ethernet Controller I210
839
Figure 12-27.Typical Profile Band
Note:
1. Preheat: 125 °C -220 °C, 150 - 210 s at 0.4 k/s to 1.0 k/s
2. Time at T > 220 °C: 60 - 90 s
3. Peak Temperature: 245-260 °C
4. Peak time: 10 - 30 s
5. Cooling rate: <= 6 k/s
6. Time from 25 °C to Peak: 240 – 360 s
Ethernet Controller I210 —Design Considerations
840
12.11 XOR Testing
A common board or system-level manufacturing test for proper electrical continuity between the I210
and the board is some type of cascaded-XOR or NAND tree test. The I210 implements an XOR tree
spanning most I/O signals. The component XOR tree consists of a series of cascaded XOR logic gates,
each stage feeding in the electrical value from a unique pin. The output of the final stage of the tree is
visible on an output pin from the component.
Figure 12-28.XOR Tree Concept
By connecting to a set of test-points or bed-of-nails fixture, a manufacturing test fixture can test
connectivity to each of the component pins included in the tree by sequentially testing each pin, testing
each pin when driven both high and low, and observing the output of the tree for the expected signal
value and/or change.
Note: Some of the pins that are inputs for the XOR test are listed as “may be left disconnected” in
the pin descriptions. If XOR test is used, all inputs to the XOR tree must be connected.
When the XOR tree test is selected, the following behaviors occur:
Output drivers for the pins listed as “tested” are all placed in high-impedance (tri-state) state to
ensure that board/system test fixture can drive the tested inputs without contention.
Internal pull-up and pull-down devices for pins listed as “tested” are also disabled to further ensure
no contention with the board/system test fixture.
The XOR tree is output on the LED1 pin.
To enter the XOR tree mode, a specific JTAG pattern must be sent to the test interface. This pattern is
described by the following TDF pattern: (dh = Drive High, dl = Drive Low)
dh (JTAG_TDI) dl(JTAG_TCK,JTAG_TMS);
dh(JTAG_TCK);
dl(JTAG_TCK);
dh(JTAG_TMS);
loop 2
dh(JTAG_TCK);
dl(JTAG_TCK);
end loop
dl(JTAG_TMS);
loop 2
dh(JTAG_TCK);
dl(JTAG_TCK);
end loop
Design Considerations—Ethernet Controller I210
841
dl(JTAG_TDI);
dh(JTAG_TCK);
dl(JTAG_TCK);
dh(JTAG_TDI);
dh(JTAG_TCK);
dl(JTAG_TCK);
dl(JTAG_TDI);
dh(JTAG_TCK);
dl(JTAG_TCK);
dh(JTAG_TDI);
dh(JTAG_TCK);
dl(JTAG_TCK);
dl(JTAG_TDI);
dh(JTAG_TCK);
dl(JTAG_TCK);
dh(JTAG_TDI)
dh(JTAG_TMS);
dh(JTAG_TCK);
dl(JTAG_TCK);
dl(JTAG_TMS);
dh(JTAG_TCK);
dl(JTAG_TCK);
dh(JTAG_TMS);
dh(JTAG_TCK);
dl(JTAG_TCK);
dh(JTAG_TCK);
dl(JTAG_TCK);
dl(JTAG_TMS);
dh(JTAG_TCK);
dl(JTAG_TCK);
hold(JTAG_TMS,JTAG_TCK,JTAG_TDI);
Note: XOR tree reads left-to-right top-to-bottom.
Ethernet Controller I210 —Design Considerations
842
Table 12-23. I210 Tested Pins Included in XOR Tree (17 pins)
Pin Name Pin Name Pin Name
LED2 SMB_DAT SMB_ALRT_N
SMB_CLK NC_SI_TXD1 NC_SI_TXD0
NC_SI_RXD1 NC_SI_RXD0 NC_SI_CRS_DV
NC_SI_CLK_IN NVM_SI NC_SI_TX_EN
NVM_SK NVM_SO NVM_CS_N
LED0 LED1 (output of the XOR tree)
Thermal Considerations—Ethernet Controller I210
843
13.0 Thermal Considerations
This section helps design a thermal solution for systems implementing the I210. It details the
maximum allowable operating junction and case temperatures and provides the methodology
necessary to measure these values. It also outlines the results of thermal simulations of the I210 in a
standard JEDEC test environment with a 2s2p board using various thermal solutions.
13.1 Intended Audience
The intended audience for this section is system design engineers using the I210. System designers are
required to address component and system-level thermal challenges as the market continues to adopt
products with higher speeds and port densities. New designs might be required to provide more
effective cooling solutions for silicon devices depending on the type of system and target operating
environment
13.2 Considerations
In a system environment, the temperature of a component is a function of both the system and
component thermal characteristics. System-level thermal constraints consist of the local ambient
temperature at the component, the airflow over the component and surrounding board, and the
physical constraints at, above, and surrounding the component that might limit the size of a thermal
solution.
The component's case and die temperature are the result of:
Component power dissipation
Component size
Component packaging materials
Type of interconnection to the substrate and motherboard
Presence of a thermal cooling solution
Power density of the substrate, nearby components, and motherboard
All of these parameters are pushed by the continued trend of technology to increase performance levels
(higher operating speeds, MHz) and power density (more transistors). As operating frequencies
increase and package size decreases, the power density increases and the thermal cooling solution
space and airflow become more constrained. The result is an increased emphasis on optimizing system
design to ensure that thermal design requirements are met for each component in the system.
Ethernet Controller I210 —Thermal Considerations
844
13.3 Thermal Management Importance
The objective of thermal management is to ensure that all system component temperatures are
maintained within their functional limits. The functional temperature limit is the range in which the
electrical circuits are expected to meet specified performance requirements. Operation outside the
functional limit can degrade system performance, cause logic errors, or cause device and/or system
damage. Temperatures exceeding the maximum operating limits can result in irreversible changes in
the device operating characteristics. Also note that sustained operation at a component maximum
temperature limit can affect long-term device reliability.
13.4 Terminology and Definitions
The following is a list of the terminology that is used in this section and their definitions:
QFN: Quad Flatpack No leads: A surface-mount package using a QFN structure whose PCB-
interconnect method consists of Pb-free perimeter lands and an exposed thermal pad on the
interconnect side of the package that are attached to a near chip-scale size substrate.
2s2p: A 4-layer board with two signal layers on the outside and two internal plane layers.
Thermal Resistance: The resulting change in temperature per watt of heat that passes from one
reference point to another.
Junction: Refers to a P-N (diode) junction on the silicon. In this document, it is used as a temperature
reference point (for example, өJA refers to the "junction" to "ambient" thermal resistance).
Ambient: Refers to the local ambient temperature of the bulk air approaching the component. It can
be measured by placing a thermocouple approximately 1 inch upstream from the component edge.
Lands: The pads on the PCB to which BGA balls are soldered.
PCB: Printed circuit board.
Printed Circuit Assembly (PCA): A PCB that has components assembled on it.
Thermal Design Power (TDP): The estimated maximum possible/expected power generated in a
component by a realistic application. TDP is a system design target associated with the maximum
component operating temperature specifications. Maximum power values are determined based on
typical DC electrical specification and maximum ambient temperature for a worst-case realistic
application running at maximum utilization.
LFM: A measure of airflow velocity in Linear Feet per Minute.
өJA (Theta JA): Thermal resistance from component junction to ambient, °C/W.
ΨJT (Psi JT): Junction-to-top (of package) thermal characterization parameter, °C/W. ΨJT does not
represent thermal resistance, but instead is a characteristic parameter that can be used to convert
between Tj and Tcase when knowing the total TDP. ΨJT is easy to characterize in simulations or
measurements and is defined as follows: This parameter can vary with environmental
conditions, such as airflow, thermal solution presence, and design
Thermal Considerations—Ethernet Controller I210
845
13.5 Package Thermal/Mechanical Specifications and Limit
13.5.1 Thermal Limits - Max Junction/Case
To ensure proper operation of the I210, the thermal solution must dissipate the heat generated by the
component and maintain a case temperature at or below the values listed in Table 13-24.
The I211 is designed to operate properly as long as the Tcase rating is not exceeded. Section 13.7.1
discusses proper guidelines for measuring the case temperature.
Table 13-24. Absolute Maximum Case Temperature
The thermal limits listed in Table 13-24 are based on simulated results of the package assembled on a
standard multi-layer, 2s2p board with 1oz internal planes and 2oz external trace layers in a forced
convection environment. The maximum case temperature is based on the maximum junction
temperature and defined by the relationship, Tcase-max = Tj-max - (ΨJT * PTDP) where ΨJT is the
junction-to-top (of package) thermal characterization parameter. If the case temperature exceeds the
specified Tcase max, thermal enhancements such as heat sinks or forced air is required.
Analysis indicates that real applications are unlikely to cause the I210 to be at Tcase-max for sustained
periods of time, given a properly designed thermal solution. Sustained operation at Tcase-max might
affect long-term reliability of the I210 and the system and thus should be avoided.
13.5.2 Thermal Specifications
The following table lists the package specific parameters under different conditions and environments.
The values өJA and ΨJT should be used as reference only as they will vary by system environment and
thermal solution. Unless otherwise noted, the simulations were run in a JEDEC environment with a four
layer (2s2p), 76.2 mm x 114.3 mm board with no heat sink.
Measured TDP (W) Tcase-max (°C)
0.74 W @ 70 °C Ambient Temperature 85
0.80 W @ 85 °C Ambient Temperature 105
Parameter Equation Conditions No Heat Sink
(°C/W)
ΘJA
P = TDP
No Airflow 30.7
1 m/s 20.9
2 m/s 19.1
3 m/s 18.2
ΨJT
P = TDP
No Airflow 0.06
1 m/s 0.31
2 m/s 0.48
3 m/s 0.63
Ethernet Controller I210 —Thermal Considerations
846
13.5.3 Simulation Setup
A simulation environment conforming to the JEDEC JESD51-2 standard was developed using a 101.5
mm x 114.5 mm, 2s2p board according to JEDEC JESD 51-9. Simulations were run with different
combinations of ambient temperature and airflow speed one solution scenario, as follows:
No heat sink
Note: Keep the following in mind when reviewing the data that is included in this section:
All data is preliminary and is not validated against physical samples.
Your system design might be significantly different.
A larger board with more than four copper layers might improve the I210 thermal performance.
13.6 Simulation Results
Table 1 lists the Tcase as a function of airflow and ambient temperature with the component operating
at the Thermal Design Power (TDP) in the environment previously listed. This table can be used as an
aid in determining a starting point for the optimum airflow for the I210.
Again, your system design might vary considerably from the environment used to generate these
values.
Note: Thermal models are available upon request (Flotherm: Detailed Model). Contact your local
Intel sales representative for the I210 thermal models.
Table 13-25. Thermal Simulation Results for Various Environmental Conditions
Note: The red value(s) indicate airflow/ambient combinations that exceed the allowable case
temperature.
 Airflow(LFM)
T
C
0 50 100 150 200 250 300 350 400
45 68.49 65.06 65.06 65.06 65.06 65.06 65.06 65.06
65.06
50 73.33 69.98 69.24 69.24 69.24 69.24 69.24 69.24 69.24
55 78.16 74.89 74.18 73.74 73.42 73.17 72.97 72.79 72.64
60 83 79.82 79.13 78.7 78.38 78.14 77.94 77.77 77.61
65 87.74 84.74 84.07 83.65 83.35 83.11 82.91 82.74 82.59
70 92.68 89.66 89.02 88.61 88.31 88.08 87.88 87.71 87.56
75 99.3 96.17 95.5 95.07 94.76 94.51 94.3 94.12 93.96
80 104.1 101.1 100.4 100 99.72 99.47 99.27 99.09 98.93
85 109 106 105.4 105 104.7 104.4 104.2 104.1 103.9
No Heat Sink
0.74W
0.80W
Ambient Temperature (C)
Thermal Considerations—Ethernet Controller I210
847
13.7 Component Measurement Methodology
Measurement methodologies for determining the case and junction temperature are outlined in the
sections that follow.
13.7.1 Case Temperature Measurements
Special care is required when measuring the Tcase temperature to ensure an accurate temperature
measurement is produced. Use the following guidelines when measuring Tcase:
Use 36-gauge (maximum) K-type thermocouples.
Calibrate the thermocouple before making temperature measurements.
Measure the surface temperature of the case in the geometric center of the case top.
Note: It is critical that the thermocouple bead be completely in contact with the package surface.
Use thermally conductive epoxies, as necessary (again, ensuring the thermocouple bead is in
contact with the package surface).
Care must be taken in order to avoid introducing error into the measurements when measuring a
surface temperature. Measurement error might be induced by:
Poor thermal contact between the thermocouple junction and the surface of the package.
Contact between the thermocouple cement and the heat-sink base (if used).
Heat loss through thermocouple leads.
13.7.1.1 Attaching the Thermocouple (No Heat Sink)
Following the guidelines listed, attach the thermocouple at a angle if there is no interference with the
thermocouple attach location or leads (see Figure 2).
Figure 13-29.Technique for Measuring Tcase with 0° Angle Attachment, No Heat Sink
Ethernet Controller I210 —Thermal Considerations
848
13.8 PCB Layout Guidelines
The following general PCB design guidelines are recommended to maximize the thermal performance of
QFN packages:
When connecting ground (thermal) vias to the ground planes, do not use thermal-relief patterns.
Thermal-relief patterns are designed to limit heat transfer between the vias and the copper planes,
thus constricting the heat flow path from the component to the ground planes in the PCB.
As board temperature also has an effect on the thermal performance of the package, avoid placing
the I210 adjacent to high-power dissipation devices.
If airflow exists, locate the components in the mainstream of the airflow path for maximum thermal
performance. Avoid placing the components downstream, behind larger devices or devices with
heat sinks that obstruct or significantly preheat the air flow.
Note: The previous information is provided as a general guideline to help maximize the thermal
performance of the components.
13.9 Conclusion
Increasingly complex systems require more robust and well thought out thermal solutions. The use of
system air, ducting, passive or active heat sinks, or any combination thereof can help lead to a low cost
solution that meets your environmental constraints.
The simplest and most cost-effective method is to improve the inherent system cooling characteristics
through careful design and placement of fans, vents, and ducts. When additional cooling is required,
thermal enhancements can be implemented in conjunction with enhanced system cooling. The size of
the fan or heat sink can be varied to balance size and space constraints with acoustic noise.
Use the data and methodologies in this section as a starting point when designing and validating a
thermal solution for the I210. By maintaining the I210’s case temperature below those recommended
in this section, the I210 functions properly and reliably.
Diagnostics—Ethernet Controller I210
849
14.0 Diagnostics
14.1 Customer Visible Features
14.1.1 JTAG Test Mode Description
The I210 includes a JTAG (TAP) port that is compliant with the IEEE standard 1149.1, 2001 Edition
(JTAG). Institute of Electrical and Electronics Engineers (IEEE).
The TAP controller is accessed serially through the four dedicated pins TCK, TMS, TDI, and TDO. TMS,
TDI, and TDO operate synchronously with TCK which is independent of all other clock within the I210.
This interface can be used for test and debug purposes. System board interconnects can be DC tested
using the boundary scan logic in pads. Table 14-1 shows TAP controller related pin descriptions.
Table 14-2 describes the TAP instructions supported by the I210. The default instruction after JTAG
reset is IDCODE.
Table 14-1. TAP Controller Pins
Signal I/O Description
TCK In Test clock input for the test logic defined by IEEE1149.1.
Note: Signal should be connected to ground through a 3.3 K pull-down resistor.
TDI In Test Data Input. Serial test instructions and data are received by the test logic at this pin.
Note: Signal should be connected to VCC33 through a 3.3 K pull-up resistor.
TDO O/D Test Data Output. The serial output for the test instructions and data from the test logic defined in IEEE1149.1.
Note: Signal should be connected to VCC33 through a 3.3 K pull-up resistor.
TMS In
Test Mode Select input. The signal received at TMS is decoded by the
TAP controller to control test operations.
Note: Signal should be connected to VCC33 through a 3.3 K pull-up resistor.
Ethernet Controller I210 —Diagnostics
850
Table 14-2. TAP Instructions Supported
Instruction Description Comment
BYPASS The BYPASS command selects the Bypass Register, a single bit register
connected between TDI and TDO pins. This allows more rapid movement of
test data to and from other components in the system. IEEE 1149.1 Std. Instruction
EXTEST The EXTEST Instruction allows circuitry or wiring external to the devices to
be tested. Boundary-scan Register Cells at outputs are used to apply
stimulus while Boundary-scan cells at input pins are used to capture data. IEEE 1149.1 Std. Instruction
SAMPLE /
PRELOAD
The SAMPLE/PRELOAD instruction is used to allow scanning of the
boundary scan register without causing interference to the normal
operation of the device. Two functions can be performed by use of the
Sample/Preload instruction.
SAMPLE – allows a snapshot of the data flowing into
and out of a device to be taken without affecting the normal operation of
the device.
PRELOAD – allows an initial pattern to be placed into the boundary scan
register cells. This allows initial known data to be present prior to the
selection of another boundary-scan test operation.
IEEE 1149.1 Std. Instruction
IDCODE
The IDCODE instruction is forced into the parallel output latches of the
instruction register during the Test-Logic-Reset TAP state. This allows the
device identification register to be selected by manipulation of the
broadcast TMS and TCK signals for testing purposes, as well as by a
conventional instruction register scan operation.
The ID code value for all the I210 A0 SKUs is 0x01531013 (Intel's Vendor
ID = 0x13, Device ID = 0x1531, Rev ID = 0x0).
The ID code value for all the I210 A1 SKUs is 0x11531013 (Intel's Vendor
ID = 0x13, Device ID = 0x1531, Rev ID = 0x1).
The ID code value for all the I210 A2 SKUs is 0x31531013 (Intel's Vendor
ID = 0x13, Device ID = 0x1531, Rev ID = 0x3).
IEEE 1149.1 Std. Instruction
USERCODE
After device reset and before the Device ID is read from Flash:
For the I210 A0 it is 0x01531013 (Intel's Vendor ID = 0x13, Device ID =
0x1531, Rev ID = 0x0).
For the I210 A1 it is 0x11531013 (Intel's Vendor ID = 0x13, Device ID =
0x1531, Rev ID = 0x1).
For the I210 A2 it is 0x31531013 (Intel's Vendor ID = 0x13, Device ID =
0x1531, Rev ID = 0x3).
Once the Flash is read, the 16 Device ID bits, which are embedded in the
USER code value reflect the device SKU.
IEEE 1149.1 Std. Instruction
HIGHZ
The HIGHZ instruction is used to force all outputs of the device (except
TDO) into a high impedance state. This instruction shall select the Bypass
Register to be connected between TDI and TDO in the Shift-DR controller
state.
IEEE 1149.1 Std. Instruction
Packet Types—Ethernet Controller I210
851
Appendix A. Packet Types
This section describes the packet types supported by the header split/replication and other features.
A.1 Packet Types for Header Split/Replication
The following packet types describe the different formats of the packets that are supported by the
packet split or replicate feature in the I210. It describes the packets in the split-header point of view.
This means that when describing the different fields that are checked and compared, the Header Split/
Replication feature emphasizes only the fields that are needed to calculate the header length. This
section describes the checks that are done after the decision to pass the packet to the host memory
was made.
A.1.1 Terminology
Compare - The field values are compared to the values that are specified in this section. For a
positive result to the compare the values must be equal.
Checked - The value of the field is compared to the recalculated value (header length …), as
opposed to values specified here.
Ignore - The field value is ignored but the field is counted to be part of the header.
A.1.2 Type 0 Ethernet (VLAN/SNAP)
This packet type contains an Ethernet header. If only PSRTYPE.PSR_TYPE0 bit is set, the packet is split
at the Ethernet header, even if additional headers are present. If other types are set, the header buffer
might contain higher level headers.
Offset # of bytes Field Value Action Comment
06 Destination Address Ignore
MAC Header processed
by main address filter, or
broadcast
66 Source Address Ignore
12 S=(0/4/8) Possible VLAN Tags (single or
double) 0x8100 **** Compare on
internal VLAN
only
12+S D=(0/8) Possible LLC/SNAP Header Length +
0xAAAA030000 Compare Length means a value
smaller than 0x600.
12+D+S 2 Type Ignore IP
Ethernet Controller I210 —Packet Types
852
A.1.3 Type 1 Ethernet (VLAN/SNAP) IP Packets
A.1.3.1 Type 1.1 Ethernet, IP, Data
This packet type contains only Ethernet and IPv4 headers while the payload header of the IP is not
IPv6/TCP/UDP. The header of this type of packet is split/replicated only if PSRTYPE.PSR_TYPE1 is set.
In this case the packet will be cut after (34+D+S+N) bytes.
The header of the packet is split only if the packet is a fragmented packet.
N = (IP HDR length 5) * 4
Offset # of bytes Field Value Action Comment
06 Destination Address Ignore
MAC Header processed
by main address filter, or
broadcast
66 Source Address Ignore
12 S=(0/4/8) Possible VLAN Tags (single or
double) 0x8100 **** Compare on
internal VLAN
only
12+S D=(0/8) Possible LLC/SNAP Header Length +
0xAAAA030000 Compare Length means a value
smaller than 0x600.
12+D+S 2 Type 0x0800 Compare IP
IPv4 Header
14+D+S 1 Version/ HDR length 0x4X Compare Check IPv4 and header
length
15+D+S 1 Type of Service - Ignore
16+D+S 2 Packet Length - Ignore
18+D+S 2 Identification - Ignore
20+D+S 2 Fragment Info >0 or
MF bit is set Check Check that the packet is
fragmented
22+D+S 1 Time to live - Ignore
23+D+S 1 Protocol Ignore Has no meaning if the
packet is fragmented
24+D+S 2 Header Checksum - Ignore
26+D+S 4 Source IP Address - Ignore
30+D+S 4 Destination IP Address - Ignore
34+D+S N Possible IP Options Ignore
Packet Types—Ethernet Controller I210
853
A.1.3.2 Type 1.2: Ethernet (VLAN/snap), IPv4, TCP
This packet type contains all three Ethernet, IPv4, and TCP headers. The header of this type of packet
is split/replicated only if PSRTYPE.PSR_TYPE2 is set
In this case the packet is split after (54+D+S+N+F) bytes.
Offset # of bytes Field Value Action Comment
06 Destination Address Ignore MAC Header –
processed by
main address
filter, or
broadcast
66 Source Address Ignore
12 S=(0/4/8) Possible VLAN Tags (single or
double) 0x8100 **** Compare on
internal VLAN
only
12+S D=(0/8) Possible LLC/SNAP Header Length +
0xAAAA030000 Compare Length means a
value smaller
than 0x600.
12+D+S 2 Type 0x0800 Compare IP
IPv4 Header
14+D+S 1 Version/ HDR length 0x4X Compare Check IPv4 and
header length
15+D+S 1 Type of Service - Ignore
16+D+S 2 Packet Length - Ignore
18+D+S 2 Identification - Ignore
20+D+S 2 Fragment Info 0x00 Compare
22+D+S 1 Time to live - Ignore
23+D+S 1 Protocol 0x06 Compare TCP header
24+D+S 2 Header Checksum - Ignore
26+D+S 4 Source IP Address - Ignore
30+D+S 4 Destination IP Address - Ignore
34+D+S N Possible IP Options Ignore
TCP Header
34+D+S+N 2 Source Port Not (0x801) Check Not NFS packet
36+D+S+N 2 Destination Port Not (0x801) Check Not NFS packet
38+D+S+N 4 Sequence number - Ignore
42+D+S+N 4 Acknowledge number - Ignore
46+D+S+N 1/2 Header Length Check
46.5+D+S+N 1.5 Different bits - Ignore
48+D+S+N 2 Window size - Ignore
50+D+S+N 2 TCP checksum - Ignore
52+D+S+N 2 Urgent pointer - Ignore
54+D+S+N F TCP options - Ignore
Ethernet Controller I210 —Packet Types
854
N = (IP HDR length 5) * 4.
F = (TCP header length 5) * 4.
A.1.3.3 Type 1.3: Ethernet (SNAP/VLAN), IPv4, UDP
This packet type contains all three Ethernet, IPv4, and UDP headers. The header of this type of packet
is split/replicated only if PSRTYPE.PSR_TYPE3 is set.
In this case the packet is split after (42+D+S+N) bytes.
Offset # of bytes Field Value Action Comment
06 Destination Address Ignore
MAC Header –
processed by main
address filter, or
broadcast
66 Source Address Ignore
12 S=(0/4/8) Possible VLAN Tags (single or double) 0x8100 **** Compare on
internal VLAN
only
12+S D=(0/8) Possible LLC/SNAP Header Length +
0xAAAA030000 Compare Length means a
value smaller than
0x600.
12+D+S 2 Type 0x0800 Compare IP
IP Header
14+D+S 1 Version/ HDR length 0x4X Compare Check IPv4 and
header length
15+D+S 1 Type of Service - Ignore
16+D+S 2 Packet Length - Ignore
18+D+S 2 Identification - Ignore
20+D+S 2 Fragment Info (xx00)
000h Compare
22+D+S 1 Time to live - Ignore
23+D+S 1 Protocol 0x11 Compare UDP header
24+D+S 2 Header Checksum - Ignore
26+D+S 4 Source IP Address - Ignore
30+D+S 4 Destination IP Address - Ignore
34+D+S N Possible IP Options Ignore
UDP Header
34+D+S+N 2 Source Port Not (0x801) Check Not NFS packet
36+D+S+N 2 Destination Port Not (0x801) Check Not NFS packet
38+D+S+N 2 Length - Ignore
40+D+S+N 2 Checksum - Ignore
Packet Types—Ethernet Controller I210
855
A.1.3.4 Type 1.4: Ethernet, IPv4, IPv6
A.1.3.4.1 Ipv6 Header Options Processing
If the next header field in the IPv6 header is equal to 0x00/0x2B/0x2C/0x3B/0x3c then the next header
is an IPv6 option header with the following structure:
Header Len determines the length of the header while the next header field determines the identity of
the next header (could be any IPv6 extension header or another IPv6 header option).
A.1.3.4.2 The header of this type of packet is split/replicated only if PSRTYPE.PSR_TYPE
is set.
A.1.3.4.3 IPv6 Next Header Values
When parsing an IPv6 header, the I210 does not parse every kind of extension header. Packets
containing an extension header that are not supported by the I210 is treated as an unknown payload
after the IPv6 header. The next header in a fragment header is ignored and this extension header is
expected to be the last header.
A.1.3.4.4 Type 1.4.1: Ethernet (VLAN/SNAP), IPv4, IPv6, data
This packet type contains all three Ethernet, IPv4, and IPv6 headers. The header of this type of packet
is split/replicated only if PSRTYPE.PSR_TYPE4 is set.
Next Header (8 bit) Header Len (8 bit
Option Header Parameters
Value Header Type
0x00 Hop by Hop
0x2B Routing
0x2C Fragment
0x3B No next header (EOL)
0x3C Destination option header
Offset # of Bytes Field Value Action Comment
06 Destination Address Ignore
MAC Header – processed
by main address filter, or
broadcast
66 Source Address Ignore
12 S=(0/4/8) Possible VLAN Tags (single
or double) 0x8100 **** Compare on
internal VLAN
only
12+S D=(0/8) Possible LLC/SNAP Header Length +
0xAAAA030000 Compare Length means a value
smaller than 0x600.
12+D+S 2 Type 0x0800 Compare IP
IPv4 Header
14+D+S 1 Version/ DR length 0x4X Compare Check IPv4 and header
length
15+D+S 1 Type of Service - Ignore
16+D+S 2 Packet Length - Ignore
Ethernet Controller I210 —Packet Types
856
In this case the packet is split after (74+D+S+N+B) bytes.
N = (IP HDR length 5) * 4.
One of the extension headers of the IPv6 packets must be a fragment header in order for the packet to
be parsed.
A.1.3.4.5 Type 1.4.2: Ethernet (VLAN/SNAP), IPv4, IPv6, TCP
This packet type contains all four Ethernet, IPv4, IPv6, and TCP headers. The header of this type of
packet is split/replicated only if PSRTYPE.PSR_TYPE5 is set.
18+D+S 2 Identification - Ignore
20+D+S 2 Fragment Info 0x00 Compare
22+D+S 1 Time to live - Ignore
23+D+S 1 Protocol 0x29 Compare Ipv6
24+D+S 2 Header Checksum - Ignore
26+D+S 4 Source IP Address - Ignore
30+D+S 4 Destination IP Address - Ignore
34+D+S N Possible IP Options Ignore
Ipv6 Header
34+D+S+N 1 Version/ Traffic Class 0x6X Compare Check IPv6
35+D+S+N 3 Traffic Class/Flow Label - Ignore
38+D+S+N 2 Payload Length - Ignore
40+D+S+N 1 Next Header IPv6 extension
headers Check
41+D+S+N 1 Hop Limit - Ignore
42+D+S+N 16 Source Address - Ignore
48+D+S+N 16 Destination Address Ignore
74+D+S+N BPossible IPv6 Next
Headers - Ignore
Offset # of Bytes Field Value Action Comment
06 Destination Address Ignore
MAC Header –
processed by main
address filter, or
broadcast
66 Source Address Ignore
12 S=(0/4/8) Possible VLAN Tags (single or
double) 0x8100 **** Compare on
internal
VLAN only
12+S D=(0/8) Possible LLC/SNAP Header Length +
0xAAAA030000 Compare Length means a
value smaller than
0x600.
12+D+S 2 Type 0x0800 Compare IP
IPv4 Header
Offset # of Bytes Field Value Action Comment
Packet Types—Ethernet Controller I210
857
In this case the packet is split after (94+D+S+N+B+F) bytes.
14+D+S 1 Version/ HDR length 0x4X Compare Check IPv4 and
header length
15+D+S 1 Type of Service - Ignore
16+D+S 2 Packet Length - Ignore
18+D+S 2 Identification - Ignore
20+D+S 2 Fragment Info 0x00 Compare
22+D+S 1 Time to live - Ignore
23+D+S 1 Protocol 0x29 Compare Ipv6
24+D+S 2 Header Checksum - Ignore
26+D+S 4 Source IP Address - Ignore
30+D+S 4 Destination IP Address - Ignore
34+D+S N Possible IP Options Ignore
Ipv6 Header
34+D+S+N 1 Version/ Traffic Class 0x6X Compare Check IPv6
35+D+S+N 3 Traffic Class/Flow Label - Ignore
38+D+S+N 2 Payload Length - Ignore
40+D+S+N 1 Next Header
Ipv6 extension
header
Or 0x06 (TCP)
Check IPv6 extension
headers
41+D+S+N 1 Hop Limit - Ignore
42+D+S+N 16 Source Address - Ignore
58+D+S+N 16 Destination Address Ignore
74+D+S+N B Possible IPv6 Next Headers - Ignore
TCP Header
74+T 2 Source Port Not (0x801) Check Not NFS packet
76+T 2 Destination Port Not (0x801) Check Not NFS packet
78+T 4 Sequence number - Ignore
82+T 4 Acknowledge number - Ignore
86+T 1/2 Header Length Check
86.5+T 1.5 Different bits - Ignore
88+T 2 Window size - Ignore
90+T 2 TCP checksum - Ignore
92+T 2 Urgent pointer - Ignore
94+T F TCP options - Ignore
Offset # of Bytes Field Value Action Comment
Ethernet Controller I210 —Packet Types
858
T = D+S+N+B
N = (IP HDR length 5) * 4.
F = (TCP HDR length 5)*4
A.1.3.4.6 Type 1.4.3: Ethernet (VLAN/SNAP), IPv4, IPv6, UDP
This packet type contains all four Ethernet, IPv4, IPv6, and UDP headers. The header of this type of
packet is split/replicated only if PSRTYPE.PSR_TYPE6 is set.
Offset # of Bytes Field Value Action Comment
06 Destination Address Ignore
MAC Header processed
by main address filter, or
broadcast
66 Source Address Ignore
12 S=(0/4/8) Possible VLAN Tags (single or
double) 0x8100 **** Compare on
internal VLAN
only
12+S D=(0/8) Possible LLC/SNAP Header Length +
0xAAAA030000 Compare Length means a value
smaller than 0x600.
12+D+S 2 Type 0x0800 Compare IP
IPv4 Header
14+D+S 1 Version/ HDR length 0x4X Compare Check IPv4 and header
length
15+D+S 1 Type of Service - Ignore
16+D+S 2 Packet Length - Ignore
18+D+S 2 Identification - Ignore
20+D+S 2 Fragment Info 0x00 Compare
22+D+S 1 Time to live - Ignore
23+D+S 1 Protocol 0x29 Compare Ipv6
24+D+S 2 Header Checksum - Ignore
26+D+S 4 Source IP Address - Ignore
30+D+S 4 Destination IP Address - Ignore
34+D+S N Possible IP Options Ignore
Ipv6 Header
34+D+S+N 1 Version/ Traffic Class 0x6X Compare Check IPv6
35+D+S+N 3 Traffic Class/Flow Label - Ignore
38+D+S+N 2 Payload Length - Ignore
40+D+S+N 1 Next Header
IPv6 extension
header
or 0x11 (UDP)
Check IPv6 extension headers:
41+D+S+N 1 Hop Limit - Ignore
42+D+S+N 16 Source Address - Ignore
58+D+S+N 16 Destination Address Ignore
74+D+S+N B Possible IPv6 Next Headers - Ignore
Packet Types—Ethernet Controller I210
859
In this case the packet is split after (82+D+S+N+B) bytes.
N = (IP HDR length 5) * 4.
A.1.4 Type 2: Ethernet, IPv6
A.1.4.1 Type 2.1: Ethernet (VLAN/SNAP), IPv6, Data
This packet type contains both Ethernet and IPv6 headers while the packet should be a fragmented
packet. If the packet is not fragmented and the next header is not one of the supported types from
Section A.1.3.4 then the header is not split. The header of this type of packet is split/replicated only if
PSRTYPE.PSR_TYPE7 is set.
In this case the packet is split after (54+D+S+N) bytes.
UDP Header
74+D+S+N+B 2 Source Port Not (0x801) Check Not NFS packet
76+D+S+N+B 2 Destination Port Not (0x801) Check Not NFS packet
78+D+S+N+B 2 Length - Ignore
80+D+S+N+B 2 Checksum - Ignore
Offset # of Bytes Field Value
(hex) Action Comment
06 Destination Address Ignore
MAC Header processed by
main address filter, or
broadcast
66 Source Address Ignore
12 S=(0/4/8) Possible VLAN Tags (single or double) 0x8100
****
Compare on
internal VLAN
only
12+S D=(0/8) Possible LLC/SNAP Header Length +
0xAAAA03
0000 Compare Length means a value
smaller than 0x600.
12+D+S 2 Type 0x86DD Compare IP
IPv6 Header
14+D+S 1 Version/ Traffic Class 0x6X Compare Check IPv6
15+D+S 3 Traffic Class/Flow Label - Ignore
18+D+S 2 Payload Length - Ignore
20+D+S 1 Next Header IPv6 next
header
types Check The last header must be
fragmented header in order
for the header to be split.
21+D+S 1 Hop Limit - Ignore
22+D+S 16 Source Address - Ignore
38+D+S 16 Destination Address Ignore
54+D+S N Possible IPv6 Next Headers - Ignore
Offset # of Bytes Field Value Action Comment
Ethernet Controller I210 —Packet Types
860
The last next header field of the IP section field should not be 0x11/0x06 (TCP/UDP).
A.1.4.2 Type 2.2: Ethernet (VLAN/SNAP) IPv6 TCP
This packet type contains all three Ethernet, IPv6, and TCP headers. The header of this type of packet
is split/replicated only if PSRTYPE.PSR_TYPE8 is set.
Offset # of Bytes Field Value
(hex) Action Comment
06 Destination Address Ignore
MAC Header processed by
main address filter, or
broadcast
66 Source Address Ignore
12 S=(0/4/8) Possible VLAN Tags (single or
double) 0x8100
****
Compare on
internal VLAN
only
12+S D=(0/8) Possible LLC/SNAP Header Length +
0xAAAA030
000 Compare Length means a value
smaller than 0x600.
12+D+S 2 Type 0x86DD Compare IP
IPv6 Header
14+D+S 1 Version/ Traffic Class 0x6X Compare Check IPv6
15+D+S 3 Traffic Class/Flow Label - Ignore
18+D+S 2 Payload Length - Ignore
20+D+S 1 Next Header
IPv6 next
header
types or
0x06 (TCP)
Check
21+D+S 1 Hop Limit - Ignore
22+D+S 16 Source Address - Ignore
38+D+S 16 Destination Address Ignore
54+D+S N Possible IPv6 Next Headers - Ignore
TCP Header
54+D+S+N 2 Source Port Not (0x801) Check Not NFS packet
56+D+S+N 2 Destination Port Not (0x801) Check Not NFS packet
58+D+S+N 4 Sequence number - Ignore
62+D+S+N 4 Acknowledge number - Ignore
66+D+S+N 1/2 Header Length Check
66.5+D+S+N 1.5 Different bits - Ignore
68+D+S+N 2 Window size - Ignore
70+D+S+N 2 TCP checksum - Ignore
72+D+S+N 2 Urgent pointer - Ignore
74+D+S+N F TCP options - Ignore
Packet Types—Ethernet Controller I210
861
In this case the packet is split after (54+D+S+N+F) bytes.
F = (TCP header length 5) * 4
The last Next-header field of the last header of the IP section must be 0x11.
A.1.4.3 Type 2.3: Ethernet (VLAN/SNAP) IPv6 UDP
This packet type contains all three Ethernet, IPv6, and UDP headers. The header of this type of packet
is split/replicated only if PSRTYPE.PSR_TYPE9 is set.
In this case the packet is split after (62+D+S+N) bytes.
The last Next-header field of the last header of the IP section must be 0x06.
Offset # of Bytes Field Value
(hex) Action Comment
06 Destination Address Ignore
MAC Header processed by
main address filter, or
broadcast
66 Source Address Ignore
12 S=(0/4/8) Possible VLAN Tags (single or
double) 0x8100
****
Compare on
internal
VLAN only
12+S D=(0/8) Possible LLC/SNAP Header Length +
0xAAAA030
000 Compare Length means a value
smaller than 0x600.
12+D+S 2 Type 0x86DD Compare IP
IPv6 Header
14+D+S 1 Version/ Traffic Class 0x6X Compare Check IPv6
15+D+S 3 Traffic Class/Flow Label - Ignore
18+D+S 2 Payload Length - Ignore
20+D+S 1 Next Header
IPv6 next
header
types
Or
0x11 (UDP)
Check
21+D+S 1 Hop Limit - Ignore
22+D+S 16 Source Address - Ignore
38+D+S 16 Destination Address Ignore
54+D+S N Possible IPv6 Next Headers - Ignore
UDP Header
54+D+S+N 2 Source Port Not (0x801) Check Not NFS packet
56+D+S+N 2 Destination Port Not (0x801) Check Not NFS packet
58+D+S+N 2 Length - Ignore
60+D+S+N 2 Checksum - Ignore
Ethernet Controller I210 —Packet Types
862
A.1.5 Type 3: NFS Packets
NFS headers can come in all the frames that contain a UDP/TCP header. The NFS (and RPC headers)
are extensions to these types of packets. All of the packets previously described in sections A.1.3.2,
A.1.3.2, A.1.3.4.5, A.1.3.4.5, A.1.4.3, and A.1.4.2, can accommodate NFS headers.
PSRTYPE.PSR_TYPE11/12/14/15/18/19 controls the split/replication behavior of NFS packets. See
Section 8.10.3 for details.
In this section, only the NFS (and RPC) header is described. The length of this header should be added
to the length of the primary type of the packet.
The I210 starts looking within the UDP/TCP payload to check whether it contains an NFS header. This is
determined when either the source or destination port of the TCP/UDP is equal to 0x801.
Destination port equal 0x801 => NFS write request (as received by the NFS server).
Source port equal 0x801 => NFS read response (as received by the NFS client).
The VSZ/CSZ fields are each 4 bytes long but their actual values are less than 2 words by definition so
hardware only checks the lower 2 bytes of these size fields.
RPC read requests are not described in this document since they contain only headers and no data
therefore there is no need to split them.
Note: NFS over TCP is problematic – due to the fact that the RPC header might appear in the middle
of the frame. It remains to be checked if software always supports putting the RPC right next
to the UDP/TCP header.
A.1.5.1 Type 3.1: NFS Write Request
In all write requests, the destination port of the TCP/UDP header must be 0x801.
Packet Types—Ethernet Controller I210
863
A.1.5.1.1 Type 3.1.1: NFS Write Request (NFSv2)
In this case the NFS header size is (80+D+B+F) bytes. This length should be added to the UDP/TCP
type that was already parsed.
Offset # of Bytes Field Value (hex) Action Comment
RPC Header
0 D =(0/4) Record Header - Ignore If the previous header was
TCP header than this field
contain 4 bytes
0+D 4 Message type 0x00 Compare
4+D 4 RPC version 0x02 Compare
8+D 4 RPC program 0x18A63 Compare
12+D 4 Program version 0x02 Compare
16+D 4 Procedure 0x08 Compare
20+D 4 Credentials Size (CSZ) <400 Check
24+D B Credentials Data (CSZ) - Ignore B = (CSZ pad 4)
24+D+B 4 Verifier Flavor - Ignore
28+D+B 4 Verifier Size (VSZ) <400 Check
32+D+B F Verifier Data Ignore F = (VSZ pad 4)
NFS Header
32+D+B+F 32 handle Ignore
64+D+B+F 4 begin offset Ignore
68+D+B+F 4 Offset Ignore
72+D+B+F 4 Total count Ignore
76+D+B_F 4 Data len Ignore
Ethernet Controller I210 —Packet Types
864
A.1.5.1.2 Type 3.1.2: NFS Write Request (NFSv3)
In this case the NFS header size is (56+D+B+F+S) bytes. This length should be added to the UDP/TCP
type that was already parsed.
Offset # of Bytes Field Value (hex) Action Comment
RPC Header
0 D =(0/4) Record Header - Ignore If the previous header was
TCP header than this field
contain 4 bytes
0+D 4 Message type 0x00 Compare
4+D 4 RPC version 0x02 Compare
8+D 4 RPC program 0x18A63 Compare
12+D 4 Program version 0x03 Compare
16+D 4 Procedure 0x07 Compare
20+D 4 Credentials Size (CSZ) <400 Check
24+D B Credentials Data (CSZ) - Ignore B = (CSZ padded to 4)
24+D+B 4 Verifier Flavor - Ignore
28+D+B 4 Verifier Size (VSZ) <400 Check
32+D+B F Verifier Data Ignore F = (VSZ padded to 4)
NFS Header
32+D+B+F 4 Fhandle_size <64 Check
36+D+B+F S fhandle Ignore S = (Fhandle_size padded to
4)
36+D+B+F+S 8 Offset Ignore
44+D+B+F+S 4 Count Ignore
48+D+B+F+S 4 Stable_how Ignore
52+D+B+F+S 4 Data len Ignore
Packet Types—Ethernet Controller I210
865
A.1.5.1.3 Type 3.1.3: NFS Write Request (NFSv4)
In this case the NFS header size is (56+D+B+F) bytes. This length should be added to the UDP/TCP
type that was already parsed.
Offset # of Bytes Field Value (hex) Action Comment
RPC Header
0 D =(0/4) Record Header - Ignore If the previous header was
TCP header than this field
contain 4 bytes
0+D 4 Message type 0x00 Compare
4+D 4 RPC version 0x02 Compare
8+D 4 RPC program 0x18A63 Compare
12+D 4 Program version 0x04 Compare
16+D 4 Procedure 0x26 Compare
20+D 4 Credentials Size (CSZ) <400 Check
24+D B Credentials Data (CSZ) - Ignore B = (CSZ pad 4)
24+D+B 4 Verifier Flavor - Ignore
28+D+B 4 Verifier Size (VSZ) <400 Check
32+D+B F Verifier Data Ignore F = (VSZ pad 4)
NFS Header
32+D+B+F 8 State id Ignore
40+D+B+F 8 Offset Ignore
48+D+B+F 4 Stable_how Ignore
52+D+B+F 4 Data len Ignore
Ethernet Controller I210 —Packet Types
866
A.1.5.2 Type 3.2: NFS Read Response
A.1.5.2.1 The I210 should be configured to the right version via its configuration space.
A.1.5.2.2 Type 3.2.1: NFS Read Response (NFSv2)
In this case the NFS header size is (100+D+F) bytes. This length should be added to the UDP/TCP type
that was already parsed.
Offset # of Bytes Field Value (hex) Action Comment
RPC Header
0 D =(0/4) Record Header - Ignore If the previous header was
TCP header than this field
contain 4 bytes
0+D 4 XID Ignore
4+D 4 Message type 0x01 Compare
8+D 4 Reply status 0x00 Ignore ‘0’ means O.K and only if this
value is ‘0’ there will be
additional data
12+D 4 Verifier Flavor - Ignore
16+D 4 Verifier Size (VSZ) <400 Check
20+D F Verifier Data - Ignore F = (VSZ pad 4)
20+D+F 4 Accept status 0x00 Ignore ‘0’ means O.K
NFS Header
24+D+F 4 Status 0x00 Ignore
28+D+F 68 Attributes - Ignore
96+D+F 4 Data len - Ignore
Packet Types—Ethernet Controller I210
867
A.1.5.2.3 Type 3.2.1: NFS Read Response (NFSv3)
In this case the NFS header size is (40+D+F+S) bytes. This length should be added to the UDP/TCP
type that was already parsed.
Offset # of Bytes Field Value (hex) Action Comment
RPC Header
0 D =(0/4) Record Header - Ignore If the previous header was
TCP header than this field
contain 4 bytes
0+D 4 XID - Ignore
4+D 4 Message type 0x01 Compare
8+D 4 Reply status 0x00 Ignore ‘0’ means O.K and only if
this value is ‘0’ there will be
additional data
12+D 4 Verifier Flavor - Ignore
16+D 4 Verifier Size (VSZ) <400 Check
20+D F Verifier Data - Ignore F = (VSZ pad 4)
20+D+F 4 Accept status 0x00 Ignore ‘0’ means O.K
NFS Header
24+D+F 4 Status 0x00 Ignore
4 Attr_follow - Check
28+D+F S Attributes - Ignore Attr_flow=1 ? S=84:
S=0
28+D+F+S 4 Count - Ignore
32+D+F+S 4 Eof - Ignore
36+D+F+S 4 Data len - Ignore
Ethernet Controller I210 —Packet Types
868
A.1.5.2.4 Type 3.2.1: NFS Read Response (NFSv4)
In this case the NFS header size is (36+D+F) bytes. This length should be added to the UDP/TCP type
that was already parsed.
A.2 IP and TCP/UDP Headers for TSO
This section outlines the format and content for the IP, TCP and UDP headers. The I210 requires
baseline information from the software device driver in order to construct the appropriate header
information during the segmentation process.
Header fields that are modified by the I210 are highlighted in the figures that follow.
Note: IPv4 requires the use of a checksum for the header. IPv6 does not use a header checksum.
IPv4 length includes the TCP and IP headers, and data. IPv6 length does not include the IPv6 header.
Note: The IP header is first shown in the traditional (such as RFC 791) representation, and because
byte and bit ordering is confusing in that representation, the IP header is also shown in little
endian format. The actual data is fetched from memory in little endian format.
Offset # of Bytes Field Value (hex) Action Comment
RPC Header
0 D =(0/4) Record Header - Ignore If the previous header was
TCP header than this field
contain 4 bytes
0+D 4 XID - Ignore
4+D 4 Message type 0x01 Compare
8+D 4 Reply status 0x00 Ignore ‘0’ means O.K and only if
this value is ‘0’ there will be
additional data
12+D 4 Verifier Flavor - Ignore
16+D 4 Verifier Size (VSZ) <400 Check
20+D F Verifier Data - Ignore F = (VSZ pad 4)
20+D+F 4 Accept status 0x00 Ignore ‘0’ means O.K
NFS Header
24+D+F 4 Status 0x00 Ignore ‘0’ means O.K
28+D+F 4 eof - Ignore
32+D+F 4 Data len - Ignore
Table A-1. IPv4 Header (Traditional Representation)
1 2 3
0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1
Version IP Hdr Length TYPE of service Total length
Identification Flags Fragment Offset
Time to Live Layer 4 Protocol ID Header Checksum
Packet Types—Ethernet Controller I210
869
Identification is incremented on each packet.
Flags Field Definition:
The Flags field is defined as follows. Note that hardware does not evaluate or change these bits.
MF - More Fragments
NF - No Fragments
Reserved
The I210 does TCP segmentation, not IP fragmentation. IP fragmentation might occur in transit through
a network's infrastructure.
Source Address
Destination Address
Options
Table A-2. IPv4 Header (Little Endian Order)
Byte3 Byte2 Byte1 Byte0
7 6 5 4 3 2 1 0 7 6 5 4 3 2 1 0 7 6 5 4 3 2 1 0 7 6 5 4 3 2 1 0
LSB Total length MSB TYPE of service Version IP Hdr Length
Fragment Offset Low R
ES N
FM
FFragment Offset
High LSB Identification MSB
Header Checksum Layer 4 Protocol ID Time to Live
Source Address
Destination Address
Options
Table A-3. IPv6 Header (Traditional Representation)
1 2 3
0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1
Version Priority Flow Label
Payload Length Next Header Type Hop Limit
Source Address
Destination Address
Extensions (if any)
Table A-1. IPv4 Header (Traditional Representation)
Ethernet Controller I210 —Packet Types
870
A TCP or UDP frame uses a 16 bit wide one's complement checksum. The checksum word is computed
on the outgoing TCP or UDP header and payload, and on the pseudo header. Details on checksum
computations are provided in Section 7.2.4.
Note: TCP and UDP over IPv6 requires the use of checksum, where it is optional for UDP over IPv4.
The TCP header is first shown in the traditional (such as RFC 793) representation, and
because byte and bit ordering is confusing in that representation, the TCP header is also
shown in little endian format. The actual data is fetched from memory in little endian format.
Table A-4. IPv6 Header (Little Endian Order)
Byte3 Byte2 Byte1 Byte0
7 6 5 4 3 2 1 0 7 6 5 4 3 2 1 0 7 6 5 4 3 2 1 0 7 6 5 4 3 2 1 0
Flow Label Version Priority
Hop Limit Next Header Type LSB Payload Length MSB
Source Address
Destination Address
Extensions
Table A-5. TCP Header (Traditional Representation)
1 2 3
0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1
Source Port Destination Port
Sequence Number
Acknowledgement Number
TCP Header
Length Reserved U
R
G
A
C
K
P
S
H
R
S
T
S
Y
N
FI
NWindow
Checksum Urgent Pointer
Options
Table A-6. TCP Header (Little Endian)
Byte3 Byte2 Byte1 Byte0
7 6 5 4 3 2 1 0 7 6 5 4 3 2 1 0 7 6 5 4 3 2 1 0 7 6 5 4 3 2 1 0
Destination Port Source Port
LSB Sequence Number MSB
Acknowledgement Number
Window RE S U
R
G
A
C
K
PS
HR
ST SY
NFIN TCP Header
Length Reserved
Urgent Pointer Checksum
Options
Packet Types—Ethernet Controller I210
871
The TCP header is always a multiple of 32-bit words. TCP options might occupy space at the end of the
TCP header and are a multiple of 8 bits in length. All options are included in the checksum.
The checksum also covers a 96-bit pseudo header conceptually prefixed to the TCP Header (see
Table A-7). For IPv4 packets, this pseudo header contains the IP Source Address, the IP Destination
Address, the IP Protocol field, and TCP Length. Software pre-calculates the partial pseudo header sum,
which includes IPv4 SA, DA and protocol types, but NOT the TCP length, and stores this value into the
TCP checksum field of the packet. For both IPv4 and IPv6, hardware needs to factor in the TCP length
to the software supplied pseudo header partial checksum.
Note: When calculating the TCP pseudo header, the byte ordering can be tricky. One common
question is whether the Protocol ID field is added to the “lower” or “upper” byte of the 16- bit
sum.
The Protocol ID field should be added to the least significant byte (LSB) of the 16-bit pseudo
header sum, where the most significant byte (MSB) of the 16-bit sum is the byte that
corresponds to the first checksum byte out on the wire.
The TCP Length field is the TCP Header Length including option fields plus the data length in bytes,
which is calculated by hardware on a frame-by-frame basis. The TCP Length does not count the 12
bytes of the pseudo header. The TCP length of the packet is determined by hardware as:
TCP Length = min(MSS, PAYLOADLEN) + L5_LEN
The two flags that may be modified are defined as:
PSH: receiver should pass this data to the application without delay
FIN: sender is finished sending data
The handling of these flags is described in Section 7.2.4.
Payload is normally MSS except for the last packet where it represents the remainder of the payload.
Note: From RFC2460:
If the IPv6 packet contains a Routing header, the Destination Address used in the pseudo-header is
that of the final destination. At the originating node, that address will be in the last element of the
Routing header; at the recipient(s), that address will be in the Destination Address field of the IPv6
header.
The Next Header value in the pseudo-header identifies the upper-layer protocol (e.g., 6 for TCP, or
17 for UDP). It will differ from the Next Header value in the IPv6 header if there are extension
headers between the IPv6 header and the upper-layer header.
Table A-7. TCP/UDP Pseudo Header Content for IPv4 (Traditional Representation)
IPv4 Source Address
IPv4 Destination Address
Zero Layer 4 Protocol ID TCP/UDP Length
Table A-8. TCP/UDP Pseudo Header Content for IPv6 (Traditional Representation)
IPv6 Source Address
IPv6 Final Destination Address
TCP/UDP Packet Length
Zero Next Header
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The Upper-Layer Packet Length in the pseudo-header is the length of the upper-layer header and
data (e.g., TCP header plus TCP data). Some upper-layer protocols carry their own length
information (e.g., the Length field in the UDP header); for such protocols, that is the length used in
the pseudo- header. Other protocols (such as TCP) do not carry their own length information, in
which case the length used in the pseudo-header is the Payload Length from the IPv6 header,
minus the length of any extension headers present between the IPv6 header and the upper-layer
header.
Unlike IPv4, when UDP packets are originated by an IPv6 node, the UDP checksum is not optional.
That is, whenever originating a UDP packet, an IPv6 node must compute a UDP checksum over the
packet and the pseudo-header, and, if that computation yields a result of zero, it must be changed
to hex FFFF for placement in the UDP header. IPv6 receivers must discard UDP packets containing a
zero checksum, and should log the error.
A type 0 Routing header has the following format:
Next Header - 8-bit selector.
Identifies the type of header immediately following the Routing header.
Uses the same values as the IPv4 Protocol field [RFC-1700 et seq.].
Hdr Ext Len - 8-bit unsigned integer. Length of the Routing header in 8-octet units, not including
the first 8 octets. For the Type 0 Routing header, Hdr Ext Len is equal to two times the number of
addresses in the header.
Routing Type - 0.
Segments Left - 8-bit unsigned integer. Number of route segments remaining, i.e., number of
explicitly listed intermediate nodes still to be visited before reaching the final destination. Equal to
“n” at the source node.
Reserved - 32-bit reserved field. Initialized to zero for transmission; ignored on reception.
Address[1...n] - Vector of 128-bit addresses, numbered 1 to n.
The UDP header is always 8 bytes in size with no options.
Table A-9. IPv6 Routing Header (Traditional Representation)
Next Header Hdr Ext Len Routing Type
“0”
Segments Left
“n”
Reserved
Address[1]
Address[2]
Final Destination Address[n]
Table A-10. UDP Header (Traditional Representation)
1 2 3
0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1
Source Port Destination Port
Length Checksum
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UDP pseudo header has the same format as the TCP pseudo header. The pseudo header conceptually
prefixed to the UDP header contains the IPv4 source address, the IPv4 destination address, the IPv4
protocol field, and the UDP length (same as the TCP Length discussed above). This checksum procedure
is the same as is used in TCP.
Unlike the TCP checksum, the UDP checksum is optional (for IPv4). Software must set the TXSM bit in
the TCP/IP Context Transmit Descriptor to indicate that a UDP checksum should be inserted. Hardware
will not overwrite the UDP checksum unless the TXSM bit is set.
Table A-11. UDP Header (Little Endian Order)
Byte3 Byte2 Byte1 Byte0
0 1 2 3 4 5 6 7 0 1 2 3 4 5 6 7 0 1 2 3 4 5 6 7 0 1 2 3 4 5 6 7
Destination Port Source Port
Checksum Length
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