AMD-8151TM AGP Tunnel Data Sheet 24888 Rev 3.03 - July 12, 2004 TM AMD-8151 Cover page HyperTransportTM AGP3.0 Graphics Tunnel Data Sheet 1 Overview The AMD-8151TM HyperTransportTM AGP3.0 Graphics Tunnel (referred to as the IC in this document) is a HyperTransportTM technology (referred to as link in this document) tunnel developed by AMD that provides an AGP 3.0 compliant (8x transfer rate) bridge. 1.1 * Device Features HyperTransport technology tunnel with side A and side B. * Side A is 16 bits (input and output); side B is 8 bits. * Either side may connect to the host or to a downstream HyperTransport technology compliant device. * Each side supports HyperTransport technology-defined reduced bit widths: 8-bit, 4-bit, and 2-bit. * Side A supports transfer rates of 1600, 1200, 800, and 400 mega-transfers per second. Side B supports transfer rates of 800 and 400 mega-transfers per second. * Maximum bandwidth is 6.4 gigabytes per second across side A (half upstream and half downstream) and 1.6 gigabytes per second across side B. * Independent transfer rate and bit width selection for each side. * Link disconnect protocol supported. * * * AGP 8x bridge. * Compliance with AGP 3.0 specification signaling, supporting 4x and 8x transfer rates. * Compliance with AGP 2.0 specification 1.5volt signaling, supporting 1x, 2x, and 4x data-transfer modes. * Supports up to 32 outstanding requests. 31 x 31 millimeter, 564-ball BGA package. 1.5 volt AGP signaling; some 3.3 volt IO; 1.2 volt link signaling; 1.8 volt core. AMD-8151TM Device TM Host HyperTransport Link 16 bits upstream, 16 bits downstream Side A Side B tunnel AGP Bridge HyperTransport Link 8 bits upstream, 8 bits downstream Downstream Device AGP Graphics Controller Figure 1: System block diagram. 1 24888 Rev 3.03 - July 12, 2004 AMD-8151TM AGP Tunnel Data Sheet (c) 2004 Advanced Micro Devices, Inc. All rights reserved.The contents of this document are provided in connection with Advanced Micro Devices, Inc. ("AMD") products. AMD makes no representations or warranties with respect to the accuracy or completeness of the contents of this publication and reserves the right to make changes to specifications and product descriptions at any time without notice. No license, whether express, implied, arising by estoppel or otherwise, to any intellectual property rights is granted by this publication. Except as set forth in AMD's Standard Terms and Conditions of Sale, AMD assumes no liability whatsoever, and disclaims any express or implied warranty, relating to its products including, but not limited to, the implied warranty of merchantability, fitness for a particular purpose, or infringement of any intellectual property right. AMD's products are not designed, intended, authorized or warranted for use as components in systems intended for surgical implant into the body, or in other applications intended to support or sustain life, or in any other application in which the failure of AMD's product could create a situation where personal injury, death, or severe property or environmental damage may occur. AMD reserves the right to discontinue or make changes to its products at any time without notice. Trademarks AMD, the AMD Arrow logo, and combinations thereof, and AMD-8151 are trademarks of Advanced Micro Devices, Inc. HyperTransport is a licensed trademark of the HyperTransport Technology Consortium. Other product names used in this publication are for identification purposes only and may be trademarks of their respective companies. 2 24888 Rev 3.03 - July 12, 2004 AMD-8151TM AGP Tunnel Data Sheet Table of Contents 1 Overview . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1 1.1 Device Features. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1 2 Ordering Information. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6 3 Signal Descriptions . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6 3.1 Terminology . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6 3.2 Tunnel Link Signals . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 7 3.3 AGP Signals . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 8 3.4 Test and Miscellaneous Signals . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 10 3.5 Power and Ground . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 10 3.5.1 Power Plane Sequencing . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 10 4 Functional Operation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 11 4.1 Overview. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 11 4.2 Reset And Initialization . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 11 4.3 Clocking . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 11 4.3.1 Clock Gating . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 11 4.4 Tunnel Links . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 12 4.4.1 Link PHY . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 12 4.5 AGP. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 12 4.5.1 Tags, UnitIDs, And Ordering. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 12 4.5.2 Various Behaviors . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 13 4.5.2.1 AGP Compensation And Calibration Cycles . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 13 5 Registers. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5.1 Register Overview. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5.1.1 Configuration Space. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5.1.2 Register Naming and Description Conventions. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5.2 AGP Device Configuration Registers . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5.3 AGP Bridge Configuration Registers . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 14 14 14 14 15 30 6 Electrical Data. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6.1 Absolute Ratings . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6.2 Operating Ranges . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6.3 DC Characteristics . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6.4 AC Characteristics . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 34 34 34 35 37 7 Ball Designations. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 39 8 Package Specification . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 42 9 Test . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 43 9.1 High Impedance Mode . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 43 9.2 NAND Tree Mode . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 43 10 Appendix . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 45 10.1 Revision History . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 45 3 24888 Rev 3.03 - July 12, 2004 AMD-8151TM AGP Tunnel Data Sheet List of Figures Figure 1: Figure 2: Figure 3: Figure 4: Figure 5: System block diagram................................................................................................................... 1 Configuration space. ................................................................................................................... 14 Ball designations. ........................................................................................................................ 39 Package mechanical drawing. ..................................................................................................... 42 NAND tree. ................................................................................................................................. 43 4 24888 Rev 3.03 - July 12, 2004 AMD-8151TM AGP Tunnel Data Sheet List of Tables Table 1: Table 2: Table 3: Table 4: Table 5: Table 6: Table 7: Table 8: Table 9: Table 10: Table 11: Table 12: Table 13: Table 14: Table 15: Table 16: Table 17: IO signal types. ............................................................................................................................. 6 Translation from AGP requests to link requests. ........................................................................ 13 Configuration spaces................................................................................................................... 15 Memory mapped address spaces................................................................................................. 15 Register attributes. ...................................................................................................................... 15 Absolute maximum ratings. ........................................................................................................ 34 Operating ranges. ........................................................................................................................ 34 Current and power consumption. ................................................................................................ 35 DC characteristics for signals on the VDD33 power plane. ....................................................... 35 DC characteristics for signals on the VDD15 power plane, AGP 2.0 signaling......................... 36 DC characteristics for signals on the VDD15 power plane, AGP 3.0 signaling......................... 36 AC data for clocks....................................................................................................................... 37 AC data for common clock operation of AGP signals................................................................ 37 AC data for clock-forwarded operation of AGP signals............................................................. 38 Signal BGA positions.................................................................................................................. 40 Power and ground BGA positions. ............................................................................................. 41 Test modes................................................................................................................................... 43 5 AMD-8151TM AGP Tunnel Data Sheet 24888 Rev 3.03 - July 12, 2004 2 Ordering Information AMD-8151 BL C Case Temperature C = Commercial temperature range Package Type BL = Organic Ball Grid Array with lid Family/Core AMD-8151 3 Signal Descriptions 3.1 Terminology See section 5.1.2 for a description of the register naming convention used in this document. See the AMD-8151TM HyperTransportTM AGP3.0 Graphics Tunnel Design Guide for additional information. Signals with a # suffix are active low. Signals described in this chapter utilize the following IO cell types: Name Notes Input Input signal only. Output Output signal only. This includes outputs that are capable of being in the high-impedance state. OD Open drain output. These signals are driven low and expected to be pulled high by external circuitry. IO Input or output signal. IOD Analog w/PU Input or open-drain output. Analog signal. With pullup. The signal includes a pullup resistor to the signal's power plane. The resistor value is nominally 8K ohms. Table 1: IO signal types. The following provides definitions and reference data about each of the IC's pins. "During Reset" provides the state of the pin while RESET# is asserted. "After Reset" provides the state of the pin immediately after RESET# is deasserted. "Func." means that the pin is functional and operating per its defined function. 6 24888 Rev 3.03 - July 12, 2004 3.2 AMD-8151TM AGP Tunnel Data Sheet Tunnel Link Signals The following are signals associated with the HyperTransportTM links. [B, A] in the signal names below refer to the A and B sides of the tunnel. [P, N] are the positive and negative sides of differential pairs. Pin name and description IO cell Power During After type plane* reset reset LDTCOMP[3:0]. Link compensation pins for both sides of the tunnel. These are designed to be connected through resistors as follows: Analog VDD12B Bit [0] [1] [3, 2] Function External Connection Positive receive compensation Resistor to VDD12B Negative receive compensationResistor to VSS Transmit compensation Resistor from bit [2] to bit [3] These resistors are used by the compensation circuit. The output of this circuit is combined with DevA:0x[E8, E4, E0] to determine compensation values that are passed to the link PHYs. LRACAD_[P, N][15:0]; LRBCAD_[P, N][7:0]. Receive link command-addressdata bus. Link VDD12 input LRACLK[1, 0]_[P, N]; LRBCLK0_[P, N]. Receive link clock. Link VDD12 input LR[B, A]CTL_[P, N]. Receive link control signal. Link VDD12 input LTACAD_[P, N][15:0]; LTBCAD_[P, N][7:0]. Transmit link command-addressdata bus. Link VDD12 Diff Func. output High** LTACLK[1, 0]_[P, N]; LTBCLK0_[P, N]. Transmit link clock. Link VDD12 Func. output Func. LT[B, A]CTL_[P, N]. Transmit link control signal. Link VDD12 Diff output Low** Func. * The signals connected to the A side of the tunnel are powered by VDD12A and the signals connected to the B side of the tunnel are powered by VDD12B. ** Diff High and Diff Low for these link pins specifies differential high and low; e.g., Diff High specifies that the _P signal is high and the _N signal is low. If one of the sides of the tunnel is not used on a platform then the unconnected link should be treated as follows, for every 10 differential pairs: connect all of the _P differential inputs together and through a resistor to VSS; connect all the _N differential inputs together and through a resistor to VDD12; leave the differential outputs unconnected. If there are unused link signals on an active link (because the IC is connected to a device with a reduced bit width), then the unused differential inputs and outputs should also be connected in this way. 7 AMD-8151TM AGP Tunnel Data Sheet 24888 Rev 3.03 - July 12, 2004 3.3 AGP Signals In the table below, "Term" indicates the standard AGP 3.0 termination impedance to ground; "PU" indicates a weak pullup resistor; "PD" indicates a weak pulldown resistor. Pin name and description IO cell Power type plane AGP 3.0 Signaling AGP 2.0 Signaling During After During After reset reset reset reset A_ADSTB0_[P, N]. AGP differential strobe for A_AD[15:0] and A_CBE_L[1:0]. When AGP 3.0 signaling is enabled, A_ADSTB0_P is the first strobe and A_ADSTB0_N is the second strobe. IO VDD15 Term Term _P: PU _P: PU _N: PD _N: PD A_ADSTB1_[P, N]. AGP differential strobe for AD[31:16], A_CBE_L[3:2], and A_DBI[H,L]. When AGP 3.0 signaling is enabled, A_ADSTB1_P is the first strobe and A_ADSTB1_N is the second strobe. IO VDD15 Term Term _P: PU _P: PU _N: PD _N: PD A_AD[31:0]. AGP address-data bus. IO VDD15 Term Term PU Low A_CBE_L[3:0]. AGP command-byte enable bus. IO VDD15 Term Term PU Low A_CAL[D, S] and A_CAL[D, S]#. Compensation pins for matching impedance of system board AGP traces. See DevA:0x[54, 50] for more information. These are designed to be connected through resistors as follows: Signal A_CALD A_CALD# A_CALS A_CALS# Compensation Function Rising edge of data signals Falling edge of data signals Rising edge of strobe signals Falling edge of strobe signals Analog VDD15 External Connection Resistor to VSS Resistor to VDD15 Resistor to VSS Resistor to VDD15 These resistors are used by the compensation circuit. The output of this circuit is combined with DevA:0x[54, 50] to determine compensation values that are passed to the link PHYs. IO VDD15 Term Term PU PU A_DEVSEL#. AGP device select. IO VDD15 Term Term PU PU A_FRAME#. AGP frame signal. IO VDD15 Term Term PU PU PU PU PU A_DBI[H, L]. Data bus inversion [high, low]. When DevA:0xA4[AGP3MD]=1, A_DBIL applies to AD[15:0]; A_DBIH applies to AD[31:16]. 1=AD signals are inverted. 0=A_AD signals are not inverted. The IC uses these signals in determining the polarity of the A_AD signals when they are inputs. These may also be enabled to support the DBI function of the IC output signals by DevA:0x40[DBIEN]. Both A_DBIH and A_DBIL are strobed with A_ADSTB1_[P, N]. When DevA:0xA4[AGP3MD]=0: A_DBIL is pulled low with the AGP termination value and not used by the IC; A_DBIH is pulled up to VDD15 through a weak resistor and becomes the AGP 2.0 PIPE# input signal. A_GC8XDET#. 0=Specifies that the graphics device supports AGP 3.0 signaling. The state of this signal is latched on the rising edge of A_RESET# before being passed to internal logic. Input VDD15 w/PU PU 8 AMD-8151TM AGP Tunnel Data Sheet 24888 Rev 3.03 - July 12, 2004 Pin name and description IO cell Power type plane AGP 3.0 Signaling AGP 2.0 Signaling During After During After reset reset reset reset A_GNT#. AGP master grant signal. Low PU High Term PU PU Low Low Low Low VDD15 Term Term PU Low A_PCLK. 66 MHz AGP clock. Output VDD33 Func. Func. Func. Func. A_PLLCLKO. PLL clock output. See section 4.3 for details. Output VDD33 Func. Func. Func. Func. Term PU PU Low High Low High A_RBF#. AGP read buffer full signal. Input VDD15 Term Term PU PU A_SBSTB_[P, N]. AGP differential side band address strobe. In AGP 3.0 signaling mode, A_SBSTB_P is the first strobe and A_SBSTB_N is the second strobe. Input VDD15 Term Term A_SBA[7:0]. AGP side band address signals. Input VDD15 Term Term PU PU Output VDD15 Term Low PU Low A_IRDY#. AGP master ready signal. Output VDD15 Term IO VDD15 Term A_MB8XDET#. This pin is controlled by DevA:0x40[8XDIS]. It Output VDD15 is designed to be connected to the AGP connector to indicate support for AGP 3.0 signaling. A_PAR. AGP parity signal. A_PLLCLKI. PLL clock input. See section 4.3 for details. IO Input VDD33 A_REFCG. AGP signal reference output. Analog VDD15 output A_REFGC. AGP signal reference input. Analog VDD15 input A_REQ#. AGP master request signal. Input VDD15 Term Output VDD33 A_RESET#. AGP bus reset signal. This is asserted whenever RESET# is asserted or when programmed by DevB:0x3C[SBRST]. Assertion of this pin does not reset any logic internal to the IC. A_ST[2:0]. AGP status signals. _P: PU _P: PU _N: PD _N: PD A_STOP#. AGP target abort signal. IO VDD15 Term Term PU PU A_TRDY#. AGP target ready signal. IO VDD15 Term Term PU PU Term PU PU Input VDD33 A_TYPEDET#. AGP IO voltage level type detect. 0=1.5 volts; 1=3.3 volts (not supported by the IC). The state of this pin is provided in DevA:0x40[TYPEDET]. This pin is also used for testmode selection; see section 9. This signal requires an external pullup resistor to VDD33 on the systemboard. A_WBF#. AGP write buffer full signal. Input VDD15 Term The SERR# and PERR# signals are not supported on the AGP bridge. 9 24888 Rev 3.03 - July 12, 2004 3.4 AMD-8151TM AGP Tunnel Data Sheet Test and Miscellaneous Signals Pin name and description CMPOVR. Link automatic compensation override. 0=Link automatic compensation is enabled. 1=The compensation values stored in DevA:0x[E0, E4, E8] control the compensation circuit. The state of this signal determines the default value for DevA:0x[E0, E4, E8][ACTL and BCTL] at the rising edge of PWROK. IO cell Power During After type plane reset reset Input VDD33 FREE[7:1]. These should be left unconnected. LDTSTOP#. Link disconnect control signal. This pin is also used for test-mode selection; see section 9. Input VDD33 NC[1:0]. These should be left unconnected. PWROK. Power OK. 1=All power planes are valid. The rising edge of this signal is deglitched; it is not observed internally until it is high for more than 6 consecutive REFCLK cycles. See section 4.2 for more details about this signal. Input VDD33 REFCLK. 66 MHz reference clock. This is required to be operational and valid for a minimum of 200 microseconds prior to the rising edge of PWROK and always while PWROK is high. Input VDD33 RESET#. Reset input. See section 4.2 for details. Input VDD33 STRAPL[19:13, 11:0]. Strapping option to be tied low. These pins should be tied to ground. STRAPL0 is used for test-mode selection; see section 9. IO VDD15 3-State 3-State STRAPL[22:20]. Strapping option to be tied low. These pins should be tied to ground. IO VDD33 3-State 3-State TEST. This is required to be tied low for functional operation. See section 9 for details. 3.5 Input VDD33 Power and Ground VDD12[B, A]. 1.2 volt power plane for the HyperTransportTM technology pins. VDD12A provides power to the A side of the tunnel. VDD12B provides power to the B side of the tunnel. VDD15. 1.5 volt power plane for AGP. VDD18. 1.8-volt power plane for the core of the IC. VDDA18. Analog 1.8-volt power plane for the PLLs in the core of the IC. This power plane is required to be filtered from digital noise. VDD33. 3.3-volt power plane for IO. VSS. Ground. 3.5.1 Power Plane Sequencing The following are power plane requirements that may imply power supply sequencing requirements. * VDD33 is required to always be higher than VDD18, VDDA18, VDD15, and VDD12[B, A]. * VDD18 and VDDA18 are required to always be higher than VDD15 and VDD12[B, A]. * VDD15 is required to always be higher than VDD12[B, A]. 10 24888 Rev 3.03 - July 12, 2004 4 Functional Operation 4.1 Overview AMD-8151TM AGP Tunnel Data Sheet The IC connects to the host through either the side A or side B HyperTransportTM link interface. The other side of the tunnel may or may not be connected to another device. Host-initiated transactions that do not target the IC or the bridge flow through the tunnel to the downstream device. Transactions claimed by the device are passed to internal registers or to the AGP bridge. See section 5.1 for details about the software view of the IC. See section 5.1.2 for a description of the register naming convention. See the AMD-8151TM HyperTransportTM AGP3.0 Graphics Tunnel Design Guide for additional information. 4.2 Reset And Initialization RESET# and PWROK are both required to be low while the power planes to the IC are invalid and for at least 1 millisecond after the power planes are valid. Deassertion of PWROK is referred to as a cold reset. After PWROK is brought high, RESET# is required to stay low for at least 1 additional millisecond. After RESET# is brought high, the links go through the initialization sequence. After a cold reset, the IC may be reset by asserting RESET# while PWROK remains high. This is referred to as a warm reset. RESET# must be asserted for no less than 1 millisecond during a warm reset. 4.3 Clocking It is required that REFCLK be valid in order for the IC to operate. Also, the LR[B, A]CLK inputs from the operation links must also be valid at the frequency defined DevA:0xCC[FREQA] and DevA:0xD0[FREQB]. The IC provides A_PCLK as the clock to the AGP device. The systemboard is required to include a connection from A_PLLCLKO to A_PLLCLKI. The length of this connection is required to be approximately the same as length of the A_PCLK trace from the IC to the external AGP devices (including approximately 2.5 inches of etch on the AGP card). The IC uses this loopback to help match the external trace delay. 4.3.1 Clock Gating Internal clocks may be disabled during power-managed system states such as power-on suspend. It is required that all upstream requests initiated by the IC be suspended while in this state. To enable clock gating, DevA:0xF0[ICGSMAF] is programmed to the values in which clock gating will be enabled. Stop Grant cycles and STPCLK deassertion link broadcasts interact to define the window in which the IC is enabled for clock gating during LDTSTOP# assertions. The system is placed into power managed states by steps that include a broadcast over the links of the Stop Grant cycle that includes the System Management Action Field (SMAF) followed by the assertion of LDTSTOP#. When the IC detects the Stop Grant broadcast which is enabled for clock gating, it enables clock gating for the next assertion of LDTSTOP#. While exiting the power-managed state, the system is required to broadcast a STPCLK deassertion message. The IC uses this message to disable clock gating during LDTSTOP# assertions. This is important because an LDTSTOP# assertion is not guaranteed to occur after the Stop Grant broadcast is received. The clock gating window must be closed to insure that clock gating does not occur during Stop Grant for LDTSTOP# assertions that are not associated with the power states specified by DevA:0xF0[ICGSMAF]. 11 24888 Rev 3.03 - July 12, 2004 AMD-8151TM AGP Tunnel Data Sheet In summary, Stop Grant broadcasts with SMAF fields specified by DevA:0xF0[ICGSMAF] enable the clock gating window and STPCLK deassertion broadcasts disable the window. If LDTSTOP# is asserted while the clock gating window is enabled, then clock gating occurs. Also, DevA:0xF0[ECGSMAF] may be used in a similar way to disable A_PCLK and the internal clock grids associated with the AGP bridge. The same rules for the clock gating window that apply to DevA:0xF0[ICGSMAF] also apply to DevA:0xF0[ECGSMAF]. If clock gating is enabled, then A_PCLK is forced low within two clock periods after LDTSTOP# is asserted. It becomes active again within two clock periods after LDTSTOP# is deasserted. It is required that there be no AGP-card-initiated upstream or downstream traffic while A_PCLK is gated. In addition, it is required that there be no host accesses to the bridge or internal registers in progress from the time that LDTSTOP# is asserted for clock gating until the link reconnects after LDTSTOP# is deasserted. 4.4 Tunnel Links HyperTransport link A supports CLK receive and transmit frequencies of 200, 400, 600, and 800 MHz. Link B supports frequencies of 200 and 400 MHz. The side A and side B frequencies are independent of each other. 4.4.1 Link PHY The PHY includes automatic compensation circuitry and a software override mechanism, as specified by DevA:0x[E8, E4, E0]. The IC only implements synchronous mode clock forwarding FIFOs. So only the link receive and transmit frequencies specified in DevA:0x[D0, CC][FREQB, FREQA] are allowed. 4.5 AGP The AGP bridge supports AGP 3.0 signaling at 8x and 4x data rates and 1.5-volt AGP 2.0 signaling at 4x, 2x, and 1x data rates. 64-bit upstream and 32-bit downstream addressing is supported. AGP 3.0 dynamic bus inversion is supported on output signals in 8X mode only, not in 4X mode; dynamic bus inversion on input signals is supported in both 4X and 8X modes. 4.5.1 Tags, UnitIDs, And Ordering The IC requires three HyperTransportTM technology-defined UnitIDs. They are allocated as follows: * First UnitID is not used. This is to avoid a potential conflict with the host (because it may be zero; see DevA:0xC0[BUID]). * Second UnitID is used for PCI-mode upstream requests and responses to host requests. * Third UnitID is used for AGP (high priority and low priority) upstream requests. The SrcTag value that is assigned to upstream non-posted AGP requests increments with each request from 0 to 27 and then rolls over to 0 again; the first SrcTag assigned after reset is 0. Up to 28 non-posted link requests may be outstanding at a time. The SrcTag value that is assigned to non-posted PCI requests is always 28. 12 24888 Rev 3.03 - July 12, 2004 AMD-8151TM AGP Tunnel Data Sheet All AGP transactions are compliant to AGP ordering rules. APG transactions are translated into link transactions as follows: AGP transaction Link transaction High priority write WrSized, posted channel, PassPW = 1 High priority read RdSized, PassPW = 1, response PassPW = 1 Low priority write WrSized, posted channel, PassPW = 0 Low priority read RdSized, PassPW = 0, response PassPW = 1 Low priority flush Flush, PassPW = 0 Low priority fence None (wait for all outstanding read responses) Table 2: Translation from AGP requests to link requests. 4.5.2 Various Behaviors * The AGP bridge does not claim link special cycles. However, special cycles that are encoded in configuration cycles to device 31 of the AGP secondary bus number (per the PCI-to-PCI bridge specification) are translated to AGP bus special cycles. * AGP and PCI read transactions that receive NXA responses from the host complete onto the AGP bus with the data provided by the host (which is required to be all 1's, per the link specification). * In the translation from type 1 link configuration cycles to secondary bus type 0 configuration cycles, the IC converts the device number to IDSEL AD signal as follows: device 0 maps to AD[16]; device 1 maps to AD[17]; and so forth. Device numbers 16 through 31 are not valid. * The compensation values for drive strength and input impedance that are assigned to non-clock forwarded AGP signals are automatically determined and set by the IC during the first compensation cycle after RESET#. Once set, they do not change until the next RESET# assertion. * Per the link protocol, when the COMPAT bit is set in the transaction, the IC does not ever claim the transaction. Such transactions are automatically passed to the other side of the tunnel (or master aborted if the IC is at the end of the chain). This is true of all transactions within address space that is otherwise claimed by the IC, including the space defined by DevB:0x3C[VGAEN]. 4.5.2.1 AGP Compensation And Calibration Cycles The AGP PHY includes one compensation circuit for the clock forwarded data signals, A_AD[31:0], A_CBE_L[3:0], and A_DBI[H, L], and one compensation circuit for the strobes, A_ADSTB[1:0]. Each compensation circuit calculates the required rising-edge (P) and falling-edge (N) signal drive strength through a free-running state machine that generates a new value approximately every four microseconds. These values are provided in DevA:0x[50, 54][NCOMP, PCOMP]. Programmable skew values between data signals and strobes are also provided in DevA:0x58. The compensation values provided to the AGP PHY are software selectable between the calculated compensation values, fixed programmable bypass values, or fixed programmable offsets from the calculated values. Regardless of which value is selected, the value presented to the PHY is never updated until there is a calibration cycle. Calibration cycles consist of taking control of the AGP bus, updating the AGP PHY compensation values, and then releasing (see DevA:0xA8[PCALCYC]). If enabled by DevA:0xB0[CALDIS], they occur periodically with the period specified by DevA:0xA8[PCALCYC]. 13 AMD-8151TM AGP Tunnel Data Sheet 24888 Rev 3.03 - July 12, 2004 The first calibration cycle occurs approximately 4 milliseconds after the deassertion of RESET# (whether AGP 2.0 or 3.0 signaling is enabled). 5 Registers 5.1 Register Overview The IC includes several sets of registers accessed through a variety of address spaces. IO address space refers to register addresses that are accessed through x86 IO instructions such as IN and OUT. PCI configuration space is typically accessed by the host through IO cycles to CF8h and CFCh. There is also memory space and indexed address space in the IC. 5.1.1 Configuration Space The address space for the IC configuration registers is broken up into busses, devices, functions, and, offsets, as defined by the link specification. It is accessed by HyperTransportTM technology-defined type 0 configuration cycles. The device number is mapped into bits[15:11] of the configuration address. The function number is mapped into bits[10:8] of the configuration address. The offset is mapped to bits[7:2] of the configuration address. The following diagram shows the devices in configuration space as viewed by software. Primary bus AGP Device DevA:0xXX Device header First device Function 0 AGP Bridge DevB:0xXX Bridge header Second device Function 0 AGP Slot Secondary bus Figure 2: Configuration space. Device A, above, is programmed to be the link base UnitID and device B is the link base UnitID plus 1. 5.1.2 Register Naming and Description Conventions Configuration register locations are referenced with mnemonics that take the form of Dev[A|B]:[7:0]x[FF:0], where the first set of brackets contain the device number, the second set of brackets contain the function number, and the last set of brackets contain the offset. Other register locations (e.g. memory mapped registers) are referenced with an assigned mnemonic that specifies the address space and offset. These mnemonics start with two or three characters that identify the space followed by characters that identify the offset within the space. Register fields within register locations are also identified with a name or bit group in brackets following the register location mnemonic. 14 AMD-8151TM AGP Tunnel Data Sheet 24888 Rev 3.03 - July 12, 2004 The following are configuration spaces: Device Function Mnemonic Registers "A" 0 DevA:0xXX AGP device header; link and AGP capabilities blocks "B" 0 DevB:0xXX PCI-PCI bridge registers for AGP Table 3: Configuration spaces. The IC does not claim configuration-register accesses to unimplemented functions within its devices (they are forwarded to the other side of the tunnel). Accesses to unimplemented register locations within implemented functions are claimed; such writes are ignored and reads always respond with all zeros. The following are memory mapped spaces: Base address register Size (bytes) Mnemonic Registers DevA:0x10 Variable None Graphic virtual memory aperture; minimum of 32 megabytes. DevA:0xB8 4K None GART block in physical memory. Table 4: Memory mapped address spaces. The following are register attributes found in the register descriptions. Type Description Read or read-only Capable of being read by software. Read-only implies that the register cannot be written to by software. Write Capable of being written by software. Set by hardware Register bit is set high by hardware. Write once After RESET#, these registers may be written to once. After being written, they become read only until the next RESET# assertion. The write-once control is byte based. So, for example, software may write each byte of a write-once DWORD as four individual transactions. As each byte is written, that byte becomes read only. Write 1 to clear Software must write a 1 to the bit in order to clear it. Writing a 0 to these bits has no effect. Write 1 only Software can set the bit high by writing a 1 to it. However subsequent writes of 0 will have no effect. RESET# must be asserted in order to clear the bit. Table 5: Register attributes. 5.2 AGP Device Configuration Registers These registers are located in PCI configuration space, in the first device (device A), function 0. See section 5.1.2 for a description of the register naming convention. AGP Vendor And Device ID Register Default: 7454 1022h Bits Description DevA:0x00 Attribute: Read only. 31:16 AGP device ID. 15:0 Vendor ID. 15 AMD-8151TM AGP Tunnel Data Sheet 24888 Rev 3.03 - July 12, 2004 AGP Device Status And Command Register Default: 0210 0000h Bits Description DevA:0x04 Attribute: See below. 31 DPE: detected parity error. Read only. This bit is fixed in the low state. 30 SSE: signaled system error. Read; set by hardware; write 1 to clear. 1=A system error was signaled (both links were flooded with sync packets) as a result of a CRC error (see DevA:0x[C8:C4][CRCFEN, CRCERR]). Note: this bit is cleared by PWROK reset but not by RESET#. 29 RMA: received master abort. Read; set by hardware; write 1 to clear. 1=A request (AGP or PCI) sent to the host bus received a master abort (an NXA error response). Note: this bit is cleared by PWROK reset but not by RESET#. 28 RTA: received target abort. Read; set by hardware; write 1 to clear. 1=A request (AGP or PCI) sent to the host bus received a target abort (a non-NXA error response). Note: this bit is cleared by PWROK reset but not by RESET#. 27:21 Read only. These bits are fixed in their default state. 20 Capabilities pointer. Read only. This bit is fixed in the high state. 19:3 Read only. These bits are fixed in their default state. 2 MASEN: PCI master enable. Read-write. This bit controls no hardware in the IC. 1 MEMEN: memory enable. Read-write. 1=Enables access to the memory space specified by DevA:0x10. This bit controls no hardware in the IC. 0 IO enable. Read only. This bit is fixed in the low state. AGP Device Revision and Class Code Register Default: 0600 00??h Bits Description DevA:0x08 Attribute: See below. 31:8 CLASSCODE. Read; write once. Provides the AGP bridge class code. 7:0 REVISION. Read only. AGP Device BIST-Header-Latency-Cache Register Default: 0000 0000h Bits Description DevA:0x0C Attribute: Read only. 31:24 BIST. These bits fixed at their default values. 23:16 HEADER. These bits fixed at their default values. 15:8 LATENCY. These bits fixed at their default values. 7:0 CACHE. These bits fixed at their default values. 16 AMD-8151TM AGP Tunnel Data Sheet 24888 Rev 3.03 - July 12, 2004 AGP Device Graphic Virtual Memory Aperture Register DevA:0x10 It is expected that the state of this register is copied into the host by software. This register controls no hardware in the IC. Default: 0000 0000 0000 0008h Bits Description Attribute: See below. 63:32 APBARHI. Read-write. Aperture base address register high. Note: bits[63:40] are required to be programmed low; setting any of these bits high results in undefined behavior. Note: if DevA:0x10[64BIT]=0, then these bits are read only, all zero. 31:22 APBARLO. Aperture base address register low. These bits are a combination of read-write and readonly zero, based on the state of DevA:0xB4[APSIZE]; see that register for details. 21:4 Reserved. 3 Read only. This bit is fixed at its default value to indicate that this register points prefetchable space. 2 64BIT: 64-bit pointer. Read; write once. 1=DevA:0x10 is a 64-bit pointer. 0=DevA:0x10 is a 32-bit pointer; bits[63:32] are reserved. 1:0 Read only. These bits are fixed at their default value to indicate that this register points memory space. AGP Device Subsystem ID and Subsystem Vendor ID Register Default: 0000 0000h Bits Description DevA:0x2C Attribute: Read; write once. 31:16 Subsystem ID. This field controls no hardware. 15:0 Subsystem vendor ID. This field controls no hardware. AGP Capabilities Pointer Default: 0000 00A0h Bits Description DevA:0x34 Attribute: Read only. 31:8 Reserved. 7:0 Capabilities pointer. Specifies the offset in DevA:0 address space for the AGP capabilities block. 17 24888 Rev 3.03 - July 12, 2004 AMD-8151TM AGP Tunnel Data Sheet AGP Miscellaneous Control Register Default: 0000 0000h Bits Description DevA:0x40 Attribute: See below. 31:8 Reserved. 7 Must be low. This bit is required to be low at all times; setting it high results in undefined behavior. 6 Must be low. This bit is required to be low at all times; setting it high results in undefined behavior. 5 Must be low. This bit is required to be low at all times; setting it high results in undefined behavior. 4 Must be low. This bit is required to be low at all times; setting it high results in undefined behavior. 3 FWDIS: fast write disable. Read-write. 1=DevA:0xA4[FWSUP] is low. 0=DevA:0xA4[FWSUP] is high. 2 8XDIS: AGP 3.0 signaling mode disable. Read-write. 0=The IC drives A_MB8XDET# low to indicate support for AGP 3.0 signaling. 1=The IC does not drive A_MB8XDET low. This bit may be used in conjunction with DevB:0x3C[SBRST] to revert back to AGP 2.0 signaling. To do this, software should (1) set DevB:0x3C[SBRST] in order to reset the AGP card, (2) set 8XDIS to cause A_MB8XDET# to float high, and (3) clear DevB:0x3C[SBRST]. 1 TYPEDET: AGP voltage type detection. Read only. This bit reflects the state of the A_TYPEDET# pin. 0=The AGP master supports 1.5 volt signaling. 1=The AGP master requires 3.3 volt signaling and is therefore not compatible with the IC. If this bit is detected high by BIOS, an error should be signaled. 0 DBIEN: dynamic bus inversion enable. Read-write. 1= A_DBI[H, L] enabled to dynamically invert the state of the A_AD signals when the IC is driving these. This only applies to AGP 3.0 transfers in the downstream direction (fast writes and read responses to AGP master requests). For PCI transfers in the downstream direction, A_DBI[H, L] are held inactive and no inversion takes place. 0=When the IC drives the A_AD lines, A_DBI[H, L] are driven low. Note: this bit is only valid when 8x transfer rates are enabled; if (1) DevA:0xA4[AGP3MD]=0 or (2) DevA:0xA4[AGP3MD]=1 and DevA:0xA8[DRATE] is not 010b, then this field is ignored and the DBI is not enabled. 18 24888 Rev 3.03 - July 12, 2004 AMD-8151TM AGP Tunnel Data Sheet AGP PHY Control Register DevA:0x[54, 50] These registers apply to the compensation values of AGP clock-forwarded data and strobe signals as follows: * DevA:0x50: data signals A_AD[31:0], A_CBE_L[3:0], A_DBI[H, L], and A_SBA[7:0]. * DevA:0x54: strobe signals A_ADSTB[1:0]_[P, N] and A_SBSTB_[P, N]. NCTL, NDATA, and NCOMP are related to (1) the falling edge drive strength of the signals as outputs and (2) the impedance of the signals as inputs. PCTL, PDATA, and PCOMP are related to the rising edge drive strength of the signals as outputs only. For the [N, P]DATA and [N, P]COMP fields of these registers, 00h corresponds to the weakest drive strength and the highest receive impedance. For the [N, P]DATA and [N, P]COMP fields of these registers, the highest values corresponds to the strongest drive strength and lowest receive impedance. External compensation resistors are used by the IC to determine the proper drive strength values. The resistors correlate the calculated values as follows: * A_CALD is used to calculate DevA:0x50[PCOMP] (data signal rising edge drive strength). * A_CALD# is used to calculate DevA:0x50[NCOMP] (data signal falling edge drive strength and receive impedance). * A_CALS is used to calculate DevA:0x54[PCOMP] (strobe rising edge drive strength). * A_CALS# is used to calculate DevA:0x54[NCOMP] (strobe falling edge drive strength and receive impedance). Note: when new values are written to these registers, new compensation values are not updated to the AGP PHY automatically; the periodic calibration cycle specified by DevA:0xA8[PCALCYC] must pass in order for the AGP PHY calibration values to take effect. Default: 000? 000?h Bits Description Attribute: See below. 31:30 NCTL: AGP PHY N (falling edge) compensation control. Read-write. These two bits combine to specify the PHY falling edge compensation value that is applied to AGP signals as follows: NCTL 00b 01b 10b 11b Description Apply NCOMP directly as the compensation value. Apply NDATA directly as the compensation value. Apply the sum of NCOMP and NDATA as the compensation value. If the sum exceeds 3Fh, then 3Fh is applied. Apply the difference of NCOMP minus NDATA as the compensation value. If the difference is less than 00h, then 00h is applied. 29:28 Reserved. 27:22 NDATA: AGP falling edge drive strength control. Read-write. This value is applied to the fallingedge (N transistor) PHY compensation as described in NCTL. 21:16 NCOMP: AGP falling edge drive strength. Read only. This provides the calculated value of the falling-edge (N transistor) drive strength of the AGP signals. The default for this field varies. This field is updated by the hardware approximately every 8 microseconds. 19 AMD-8151TM AGP Tunnel Data Sheet 24888 Rev 3.03 - July 12, 2004 15:14 PCTL: AGP PHY P (rising edge) compensation control. Read-write. These two bits combine to specify the PHY rising edge compensation value that is applied to AGP signals as follows: PCTL 00b 01b 10b 11b Description Apply PCOMP directly as the compensation value. Apply PDATA directly as the compensation value. Apply the sum of PCOMP and PDATA as the compensation value. If the sum exceeds 1Fh, then 1Fh is applied. Apply the difference of PCOMP minus PDATA as the compensation value. If the difference is less than 00h, then 00h is applied. 13:12 Reserved. 11 RW: read-write bit. Read-write. This controls no logic. 10:6 PDATA: AGP rising edge drive strength control. Read-write. This value is applied to the risingedge (P transistor) PHY compensation as described in PCTL. 5 4:0 Reserved. PCOMP: AGP rising edge drive strength. Read only. This provides the calculated value of the rising-edge (P transistor) drive strength of the AGP signals. The default for this field varies. This field is updated by the hardware approximately every 8 microseconds. AGP PHY Skew Control Register DevA:0x58 DSKEW and SSKEW are designed such that when they are both programmed to the same value, the AGP output strobes transition near the center of the data eye. To move the strobe to a later point in the data eye, the value of SSKEW is increased. To move the strobe to an earlier point in the data eye, DSKEW is increased. These values translate into skew approximately as follows: For values 0h to 8h, the skew is about: [D, S]SKEW x 80 picoseconds. For values 9h to Fh, the skew is about: 800 + ([D, S]SKEW - 8) x 400 picoseconds. However, these values vary with process, temperature, and voltage. Note that the lower values provide fine resolution and the upper values provide coarse resolution. Default: 0000 0000h. Bits Description Attribute: Read-write. 31:8 Reserved. 7:4 DSKEW: AGP data skew. Read-write. This specifies the alignment of the AGP data signal outputs, A_AD[31:0], A_CBE_L[3:0], and A_DBI[H, L], relative internal clocks. 0h=The strobe transitions earliest. Fh=The strobe transitions latest. 3:0 SSKEW: AGP strobe skew. Read-write. This specifies the alignment of the AGP strobe signal outputs, A_ADSTB[1:0], relative internal clocks. 0h=The strobe transitions earliest. Fh=The strobe transitions latest. 20 AMD-8151TM AGP Tunnel Data Sheet 24888 Rev 3.03 - July 12, 2004 AGP Most Recent Request Register DevA:0x60 As each PIPE mode or SBA mode AGP request is transferred into the IC, the fields are placed into this register. Thus, this register provides the fields of the most recent AGP requests. Any sticky bits from prior requests that have not been updated in the current request are also valid. Note: fences are not captured by this register. Default: 0000 0000 0000 0000h Bits Description Attribute: Read only. 63:44 Reserved. 43:40 MRC: most recent command field. Specifies the command field of the most recent AGP request. 0h=LP (low priority) read. 1h=HP (high priority) read. 4h=LP write. 5h=HP write. 8h=LP long read. 9h=HP long read. Ah=Flush. 39:3 MRA: most recent address. Specifies address bits[39:3] of the most recent AGP request. 2:0 MRL: most recent length field. Specifies the length field of the most recent AGP request. AGP Revision and Capability Register Default: 0030 C002h Bits Description DevA:0xA0 Attribute: Read only. 31:24 Reserved. 23:16 AGP specification. This field is hardwired to indicate that the IC conforms to AGP specification revision 3. 15:8 Next capabilities block. Specifies the offset to the next capabilities block. 7:0 Capabilities type. Specifies the AGP capabilities block. AGP Status Register DevA:0xA4 Default: 1F00 0B2?h (see bit descriptions for bits[3:0])Attribute: Read only. Bits Description 31:24 RQ: maximum number of outstanding requests. This field is set to indicate support for 32 outstanding requests. 23:18 Reserved. 17 Isochronous support. This bit fixed in the low state to indicate that the IC does not support isochronous modes. 16:13 Reserved. 12:10 Calibration cycle. This field is set to indicate a requirement for calibration cycles every 64 milliseconds. 9 SBA support. This field is set to indicate support for SBA. 8 Coherency. This bit fixed high. 7 64-bit GART support. This bit fixed low. 6 Host translation#. This bit fixed low. 5 Greater-than 4 gigabyte support. This bit fixed high. 21 24888 Rev 3.03 - July 12, 2004 AMD-8151TM AGP Tunnel Data Sheet 4 FWSUP: fast write support flag. 0=Fast writes are not supported. 1=Fast writes are supported. The state of this bit is controlled by DevA:0x40[FWDIS]. 3 AGP3MD: AGP 3.0 signaling mode detected. 1=The IC detected connection to an AGP 3.0-capable master and is programmed for AGP 3.0 signaling. 0=The IC detected connection to an AGP 2.0 or earlier capable master or is not programmed for 1.5-volt, AGP 2.0 signaling. If DevA:0x40[8XDIS]=0 and the pin A_GC8XDET#=0, then this bit is high. Otherwise, it is low. 2:0 RATE: data rate. When AGP3MD=1, then this field defaults to 011b to indicate support for 4x and 8x data rates. When AGP3MD=0, this field defaults to 111b to indicate support for 4x, 2x, and 1x data rates. AGP Command Register Default: 0000 0000h Bits Description DevA:0xA8 Attribute: Read-write. 31:13 Reserved. 12:10 PCALCYC: periodic calibration cycle. Specifies the period between calibration cycles as follows: 000b=4 milliseconds; 001b=16 milliseconds; 010=64 milliseconds; 011b=256 milliseconds; all other values are reserved. When DevA:0xA4[AGP3MD]=1, calibration cycles are as specified in the AGP 3.0 specification. When DevA:0xA4[AGP3MD]=0, calibration cycles consist of (1) the internal calibration logic requests the bus; (2) once granted, the calibration values are update in less than 6 A_PCLK cycles while the AGP bus is in a quiescent state. Note: after changing this value, the IC may not perform another calibration cycle until the internal counter rolls over as much as 256 microseconds later; in order to avoid this, DevA:0xB0[CALDIS] should be set high before changing PCALCYC and then DevA:0xB0[CALDIS] should be cleared afterward. 9 SBA_EN: side band address enable. 1=SBA addressing is enabled. Note: when DevA:0xA4[AGP3MD]=1, SBA addressing is enabled and the state of this bit is ignored. 8 AGPEN: AGP operation enable. 1=The IC accepts master-initiated AGP commands. 0=AGP commands are ignored. 7:6 Reserved. 5 R4GEN: receive greater-than 4-gigabyte access enable. 1=The IC accepts AGP accesses to addresses greater than 4 gigabytes. 4 FWEN: fast write enable. 1=Fast writes are enabled. When DevA:0xA4[FWSUP]=0, this bit is required to be programmed low; if, in this case, this bit is programmed high, then undefined behavior results. 3 Reserved. 22 AMD-8151TM AGP Tunnel Data Sheet 24888 Rev 3.03 - July 12, 2004 2:0 DRATE: data transfer mode rate. This field is combined with DevA:0xA4[AGP3MD] to specify the AGP data rate as follows: AGP3MD X 0 0 0 1 1 1 DRATE 000 001 010 100 001 010 100 No AGP mode selected. 1x AGP rate; AGP 2.0 signaling. 2x AGP rate; AGP 2.0 signaling. 4x AGP rate; AGP 2.0 signaling. 4x AGP rate; AGP 3.0 signaling. 8x AGP rate; AGP 3.0 signaling. Reserved. AGP Control Register Default: 0000 0000h Bits Description DevA:0xB0 Attribute: Read-write. 31:10 Reserved. 9 CALDIS: calibration cycle disable. 1=Calibration cycles (as defined in DevA:0xA8[PCALCYC]) are disabled. 8 APEREN: graphics aperture enable. This bit controls no hardware in the IC. It is expected that the state of this bit is copied into the host by software. 7 GTLBEN: graphics translation look-aside buffer enable. This bit controls no hardware in the IC. It is expected that the state of this bit is copied into the host by software. 6:0 Reserved. AGP Aperture Size Register Default: 0001 0F00h Bits Description DevA:0xB4 Attribute: See below. 31:28 PGSZSEL: page size select. Read-write. The only legal value for these bits is 0000b, which specifies a 4-kilobyte page. 27 Reserved. 26:16 Page size support. Read only. These bits are fixed in their default state to indicate that the IC supports 4-kilobyte pages. 15:12 Reserved. 23 AMD-8151TM AGP Tunnel Data Sheet 24888 Rev 3.03 - July 12, 2004 11:0 APSIZE: graphic virtual memory aperture size. Read-write (except bits[11, 7:6, and 2:0] which are read only, fixed at the default value). This field specifies the size of the aperture pointed to by DevA:0x10. This field also controls read only versus read-write control over several bits in DevA:0x10. It is encoded as follows: DevA:0x10 DevA:0x10 Bits[10, 9, 8, 5, 4, 3] Aperture size read-write bits read-only bits 1 1 1 1 1 1 32 MB [63:25] [24:0] 1 1 1 1 1 0 64 MB [63:26] [25:0] 1 1 1 1 0 0 128 MB [63:27] [26:0] 1 1 1 0 0 0 256 MB [63:28] [27:0] 1 1 0 0 0 0 512 MB [63:29] [28:0] 1 0 0 0 0 0 1024 MB [63:30] [29:0] 0 0 0 0 0 0 2048 MB [63:31] [30:0] It is expected that the state of this field is copied into the host by software. Note: DevA:0x10[2] is "read; write once," even though it is shown as read-only above. Also, based on the state of DevA:0x10[2], DevA:0x10[63:32] may be read-only, all zeros. AGP Device GART Pointer DevA:0xB8 This register controls no hardware in the IC. It is expected that the state of this register is copied into the host by software. Default: 0000 0000 0000 0000h Bits Description Attribute: Read-write. 63:32 GARTHI: GART base address register high. 31:12 GARTLO: GART base address register low. 11:0 Reserved. Link Command Register Default: 0060 0008h Bits Description DevA:0xC0 Attribute: See below. 31:29 Slave/primary interface type. Read only. 28 DOUI: drop on uninitialized link. Read-write. This specifies the behavior of transactions that are sent to uninitialized links. 0=Transactions that are received by the IC and forwarded to a side of the tunnel, when DevA:0x[C4/C8][INITCPLT and ENDOCH] for that side of the tunnel are both low, remain in buffers awaiting transmission indefinitely (waiting for INITCPLT to be set high). 1=Transactions that are received by the IC and forwarded to a side of the tunnel, when DevA:0x[C4/C8][INITCPLT and ENDOCH] for that side of the tunnel are both low, behave as if ENDOCH were high. Note: this bit is cleared by PWROK reset but not by RESET#. 27 DEFDIR: default direction. Read-write. 0=Send AGP master requests to the master link host as specified by DevA:0xC0[MASHST]. 1=Send AGP master requests to the opposite side of the tunnel. 24 24888 Rev 3.03 - July 12, 2004 26 AMD-8151TM AGP Tunnel Data Sheet MASHST: master host. Read; set and cleared by hardware. This bit indicates which link is the path to the master (or only) host bridge on the HyperTransportTM technology chain. 1=The hardware set this bit as a result of a write command from the B side of the tunnel to any of the bytes of DevA:0xC0[31:16]. 0=The hardware cleared this bit as a result of a write command from the A side of the tunnel to any of the bytes of DevA:0xC0[31:16]. This bit, along with DEFDIR, is used to determine the side of the tunnel to which AGP master requests are sent. 25:21 UnitID count. Read only. Specifies the number of UnitIDs used by the IC (three). 20:16 BUID: base UnitID. Read-write. This specifies the link-protocol base UnitID. The IC's logic uses this value to determine the UnitIDs for link request and response packets. When a new value is written to this field, the response includes a UnitID that is based on the new value in this register. Note: some legacy operating systems may require that this value be set to zero for normal operation so that the AGP capability block is part of device 0. Since the IC does not use the base unit ID in any link transactions, there is no conflict with the host unit ID. However, at boot, BIOS is required to temporarily change the BUID value of the IC so that the BUID values in downstream devices may be initialized. After downstream BUID values are initialized, this field may be set to zero to be compatible with legacy operating systems. 15:8 Reserved. 7:0 Capabilities ID. Read only. Specifies the capabilities ID for link configuration space. Link Configuration And Control Register DevA:0xC4 and DevA:0xC8 DevA:0xC4 applies side A of the tunnel and DevA:0xC8 applies to side B of the tunnel. The default value for bit[5] may vary (see the definition). Default: ??11 0020h for DevA:0xC4 and ??00 0020h for DevA:0xC8.Attribute: See below. Bits Description 31 Reserved. 30:28 LWO: link width out. Read-write. Specifies the operating width of the outgoing link. Legal values are 001b (16 bits; DevA:0xC4 only), 000b (8 bits), 101b (4 bits), 100b (2 bits), and 111b (not connected). Note: this field is cleared by PWROK reset but not by RESET#; the default value of this field depends on the widths of the links of the connecting device, per the link specification. Note: after this field is updated, the link width does not change until either RESET# is asserted or a link disconnect sequence occurs through or LDTSTOP#. 27 Reserved. 26:24 LWI: link width in. Read-write. Specifies the operating width of the incoming link. Legal values are 001b (16 bits; DevA:0xC4 only), 000b (8 bits), 101b (4 bits), 100b (2 bits), and 111b (not connected). Note: this field is cleared by PWROK reset but not by RESET#; the default value of this field depends on the widths of the links of the connecting device, per the link specification. Note: after this field is updated, the link width does not change until either RESET# is asserted or a link disconnect sequence occurs through an LDTSTOP# assertion. 23 Reserved. 22:20 Max link width out. Read only. This specifies the width of the outgoing link to be 16 bits wide for side A and 8 bits wide for side B. 19 Reserved. 25 24888 Rev 3.03 - July 12, 2004 AMD-8151TM AGP Tunnel Data Sheet 18:16 Max link width in. Read only. This specifies the width of the incoming link to be 16 bits wide for side A and 8 bits wide for side B. 15 Reserved. 14 EXTCTL: extended control time during initialization. Read-write. This specifies the time in which LT[B, A]CTL is held asserted during the initialization sequence that follows an LDTSTOP# deassertion, after LR[B, A]CTL is detected asserted. 0=At least 16 bit times. 1=About 50 microseconds. Note: this bit is cleared by PWROK reset but not by RESET#. 13 LDT3SEN: link three-state enable. Read-write. 1=During the LDTSTOP# disconnect sequence, the link transmitter signals are placed into the high impedance state and the receivers are prepared for the high impedance mode. For the receivers, this includes cutting power to the receiver differential amplifiers and ensuring that there are no resultant high-current paths in the circuits. 0=During the LDTSTOP# disconnect sequence, the link transmitter signals are driven, but in an undefined state, and the link receiver signals are assumed to be driven. Note: this bit is cleared by PWROK reset but not by RESET#. AMD recommends that this bit be set high in single-processor systems and be low in multi-processor systems. 12:10 Reserved. 9:8 CRCERR: CRC Error. Read; set by hardware; write 1 to clear. Bit[9] applies to the upper byte of the link (DevA:0xC4 only) and bit[8] applies to the lower byte. 1=The hardware detected a CRC error on the incoming link. Note: this bit is cleared by PWROK reset but not by RESET#. 7 TXOFF: transmitter off. Read; write 1 only. 1=No output signals on the link toggle; the input link receivers are disabled and the pins may float. 6 ENDOCH: end of chain. Read; write 1 only or set by hardware. 1=The link is not part of the logical HyperTransport technology chain; packets which are issued or forwarded to this link are either dropped or result in an NXA error response, as appropriate; packets received from this link are ignored and CRC is not checked; if the transmitter is still enabled (TXOFF), then it drives only NOP packets with good CRC. ENDOCH may be set by writing a 1 to it or it may be set by hardware if the link is determined to be disconnected at the rising edge of RESET#. 5 INITCPLT: initialization complete. Read only. This bit is set by hardware when low-level link initialization has successfully completed. If there is no device on the other end of the link, or if the device on the other side of the link is unable to properly perform link initialization, then the bit is not set. This bit is cleared when RESET# is asserted or after the link disconnect sequence completes after the assertion of LDTSTOP#. 4 LKFAIL: link failure. Read; set by hardware; write 1 to clear. This bit is set high by the hardware when a CRC error is detected on the link (if enabled by CRCFEN) or if the link is not used in the system. Note: this bit is cleared by PWROK reset, not by RESET#. 3 CRCERRCMD: CRC error command. Read-write. 1=The link transmission logic generates erroneous CRC values. 0=Transmitted CRC values match the values calculated per the link specification. This bit is intended to be used to check the CRC failure detection logic of the device on the other side of the link. 2 Reserved. 1 CRCFEN: CRC flood enable. Read-write. 1=CRC errors (in link A for DevA:0xC4[CRCFEN]; in link B for DevA:0xC8[CRCFEN]) result in sync packets to both outgoing links, DevA:0x04[SSE] is set, and the LKFAIL bit is set. 0=CRC errors do not result in sync packets, setting of DevA:0x04[SSE] or the LKFAIL bit. 0 Reserved. 26 24888 Rev 3.03 - July 12, 2004 AMD-8151TM AGP Tunnel Data Sheet Link Frequency Capability 0 Register Default: 0035 0022h. Bits Description DevA:0xCC Attribute: See below. 31:16 FREQCAPA: link A frequency capability. Read only. These bits indicate that A side of the tunnel supports 200, 400, 600, and 800 MHz link frequencies. 15:12 Reserved. 11:8 FREQA: link A frequency. Read-write. Specifies the link side A frequency. Legal values are 0h (200 MHz), 2h (400 MHz), 4h (600 MHz), and 5h (800 MHz). Note: this bit is cleared by PWROK reset, not by RESET#. Note: after this field is updated, the link frequency does not change until either RESET# is asserted or a link disconnect sequence occurs through LDTSTOP#. 7:0 REVISION. Read only. Revision A of the IC is designed to version 1.02 of the link specification. Link Frequency Capability 1 Register Default: 0035 0002h. Bits Description DevA:0xD0 Attribute: See below. 31:16 FREQCAPB: link B frequency capability. Read only. These bits indicate that that B side of the tunnel supports 200, 400, 600, and 800 MHz link frequencies. 15:12 Reserved. 11:8 FREQB: link B frequency. Read-write. Specifies the link side B frequency. Legal values are 0h (200 MHz), and 2h (400 MHz), 4h (600 MHz), and 5h (800 MHz). Note: although it is possible to program this field for higher frequencies, the B link of the IC is only designed to support 200 and 400 MHz operation. Note: this bit is cleared by PWROK reset, not by RESET#. Note: after this field is updated, the link frequency does not change until either RESET# is asserted or a link disconnect sequence occurs through LDTSTOP#. 7:0 Link device feature capability indicator. Read only. These bits are set to indicate that the IC supports LDTSTOP#. Link Enumeration Scratchpad Register Default: 0000 0000h. Bits Description DevA:0xD4 Attribute: See below. 31:16 Reserved. 15:0 ESP: enumeration scratchpad. Read-write. This field controls no hardware within the IC. Note: this bit is cleared by PWROK reset, not by RESET#. 27 24888 Rev 3.03 - July 12, 2004 AMD-8151TM AGP Tunnel Data Sheet Link PHY Compensation Control Registers DevA:0x[E8, E4, E0] The link PHY circuitry includes automatic compensation that is used to adjust the electrical characteristics for the link transmitters and receivers on both sides of the tunnel. There is one compensation circuit for the receivers and one for each polarity of the transmitters. These registers provide visibility into the calculated output of the compensation circuits, the ability to override the calculated value with software-controlled values, and the ability to offset the calculated values with a fixed difference. The overrides and difference values may be different between sides A and B of the tunnel. These registers specify the compensation parameters as follows: * DevA:0xE0: transmitter rising edge (P) drive strength compensation. * DevA:0xE4: transmitter falling edge (N) drive strength compensation. * DevA:0xE8: receiver impedance compensation. For DevA:0x[E4, E0], higher values represent higher drive strength; the values range from 01h to 13h (19 steps). For DevA:0xE8, higher values represent lower impedance; the values range from 00h to 1Fh (32 steps). Note: the default state of these registers is set by PWROK reset; assertion of RESET# does not alter any of the fields. Default: See below. Bits Description 31 Attribute: See below. Must be low. Read-write. This bit is required to be low at all times; setting it high results in undefined behavior. 30:21 Reserved. 20:16 CALCCOMP: calculated compensation value. Read only. This provides the calculated value from the auto compensation circuitry. The default value of this field is not predictable. 15 Reserved. 14:13 BCTL: link side B PHY control value. Read-write. These two bits combine to specify the PHY compensation value that is applied to side B of the tunnel as follows: BCTL 00b 01b 10b 11b Description Apply CALCCOMP directly as the compensation value. Apply BDATA directly as the compensation value. Apply the sum of CALCCOMP and BDATA as the compensation value. In DevA:0x[E4, E0], if the sum exceeds 13h, then 13h is applied. In DevA:0x[E8], if the sum exceeds 1Fh, then 1Fh is applied. Apply the difference of CALCCOMP minus BDATA as the compensation value. If the difference is less than 01h, then 01h is applied. The default value of this field (from PWROK reset) is controlled by the CMPOVR signal. If CMPOVR = 0, the default is 00b. If CMPOVR = 1, the default is 01b. 12:8 BDATA: link side B data value. Read-write. This value is applied to the side B of the tunnel PHY compensation as described in BCTL. The default for DevA:0x[E4, E0] is 08h. The default for DevA:0xE8 is 0Fh. 7 Reserved. 28 24888 Rev 3.03 - July 12, 2004 6:5 AMD-8151TM AGP Tunnel Data Sheet ACTL: link side A PHY control value. Read-write. These two bits combine to specify the PHY compensation value that is applied to side A of the tunnel as follows: ACTL 00b 01b 10b 11b Description Apply CALCCOMP directly as the compensation value. Apply ADATA directly as the compensation value. Apply the sum of CALCCOMP and ADATA as the compensation value. In DevA:0x[E4, E0], if the sum exceeds 13h, then 13h is applied. In DevA:0x[E8], if the sum exceeds 1Fh, then 1Fh is applied. Apply the difference of CALCCOMP minus ADATA as the compensation value. If the difference is less than 01h, then 01h is applied. The default value of this field (from PWROK reset) is controlled by the CMPOVR signal. If CMPOVR = 0, the default is 00b. If CMPOVR = 1, the default is 01b. 4:0 ADATA: link side A data value. Read-write. This value is applied to the side A of the tunnel PHY compensation as described in ACTL. The default for DevA:0x[E4, E0] is 08h. The default for DevA:0xE8 is 0Fh. Clock Control Register DevA:0xF0 See section 4.3.1 for details on clock gating. AMD system recommendations for System Management Action Field (SMAF) codes are: 0=ACPI C2; 1=ACPI C3; 2=FID/VID change; 3=ACPI S1; 4=ACPI S3; 5=Throttling; 6=ACPI S4/S5. For server and desktop platforms, AMD recommends setting this register to 0004_0008h (to gate clocks during S1). For mobile platforms, AMD recommends setting this register to 0004_0A0Ah (to gate clocks during C3 and S1). Default: 0000 0000h. Bits Description Attribute: Read-write. 31:19 Reserved. 18 CGEN: clock gate enable. 1=Internal clock gating, as specified by bits[7:0] of this register, is enabled. 17 Must be low. This bit is required to be low at all times; setting it high results in undefined behavior. 16 Must be low. This bit is required to be low at all times; setting it high results in undefined behavior. 15:8 ECGSMAF: external clock gating system management action fields. Each of the bits of this field correspond to SMAF values that are captured in Stop Grant cycles from the host. For each bit, 1=When LDTSTOP# is asserted prior to a Stop Grant cycle in which the SMAF field matches the ECGSMAF bit that is asserted, then A_PCLK and internal clock grids associated with the AGP bridges are forced low. 0=A_PCLK and the internal clock grids are active while LDTSTOP# is asserted. For example, if A_PCLK gating is required for SMAF values of 3 and 5, then ECGSMAF[3, 5] must be high. See section 4.3.1 for details. 7:0 ICGSMAF: internal clock gating system management action fields. Each of the bits of this field correspond to SMAF values that are captured in Stop Grant cycles from the host. For each bit, 1=When LDTSTOP# is asserted prior to a Stop Grant cycle in which the SMAF field matches the ICGSMAF bit that is asserted, then the IC power is reduced through gating of internal clocks. 0=No power reduction while LDTSTOP# is asserted. For example, if clock gating is required for SMAF values of 3 and 5, then ICGSMAF[3, 5] must be high. See section 4.3.1 for details. 29 AMD-8151TM AGP Tunnel Data Sheet 24888 Rev 3.03 - July 12, 2004 5.3 AGP Bridge Configuration Registers These registers are located in PCI configuration space, in the second device (device B), function 0. See section 5.1.2 for a description of the register naming convention. AGP Bridge Vendor And Device ID Register Default: 7455 1022h Bits Description DevB:0x00 Attribute: See below. 31:16 AGP bridge device ID. Bits[31:20] are read only; bits[19:16] are write-once. When the LSBs are left at the default value, some operating systems may load a generic graphics driver. System BIOS should program the LSBs to 6h in order to circumvent the loading of such a driver. 15:0 Vendor ID. Read only. AGP Bridge Status And Command Register Default: 0220 0000h Bits Description DevB:0x04 Attribute: See below. 31:9 Read only. These bits are fixed in their default state. 8 7:3 SERREN: SERR# enable. Read-write. This bit controls no hardware. Special cycle enable. Read only. This bit is hardwired low. 2 MASEN: PCI master enable. Read-write. 1=Enables the AGP bus master to initiate PCI cycles to the host. 1 MEMEN: memory enable. Read-write. 1=Enables access to the AGP bus memory space. 0 IOEN: IO enable. Read-write. 1=Enables access to the AGP bus IO space. AGP Bridge Revision and Class Code Register Default: 0604 00??h Bits Description DevB:0x08 Attribute: Read only. 31:8 CLASSCODE. 7:0 REVISION. AGP Bridge BIST-Header-Latency-Cache Register Default: 0001 0000h Bits Description DevB:0x0C Attribute: See below. 31:24 BIST. Read only. These bits fixed at their default values. 23:16 HEADER. Read only. These bits fixed at their default values. 30 AMD-8151TM AGP Tunnel Data Sheet 24888 Rev 3.03 - July 12, 2004 15:8 LATENCY. Read-write. These bits control no hardware. 7:0 CACHE. Read only. These bits fixed at their default values. AGP Bridge Bus Numbers And Secondary Latency Register Default: 0000 0000h Bits Description DevB:0x18 Attribute: Read-write. 31:24 SECLAT. Secondary latency timer. These bits control no hardware. 23:16 SUBBUS. Subordinate bus number. 15:8 SECBUS. Secondary bus number. 7:0 PRIBUS. Primary bus number. AGP Bridge Memory Base-Limit Registers DevB:0x[30:1C] These registers specify the IO-space (DevB:0x1C and DevB:0x30), non-prefetchable memory-space (DevB:0x20), and prefetchable memory-space (DevB:0x24) address windows for transactions that are mapped from the 40-bit link address space to the AGP bus. The links support 25 bits of IO space. AGP supports 32 bits of IO space. Host accesses to the link-defined IO region are mapped to the AGP IO window with the 7 MSB always zero. AGP IO accesses in which any of the 7 MSBs are other than zero are ignored. The AGP IO space window is defined as follow: AGP IO window = {7'h00, DevB:30[24:16], DevB:0x1C[15:12], 12'hFFF} >= address >= {7'h00, DevB:30[8:0], DevB:0x1C[7:4], 12'h000}; The links support 40 bits of memory space. AGP supports 32 bits of non-prefetchable memory space. The AGP non-prefetchable window is defined to be within the lowest 4 gigabytes of link address space. AGP accesses above 4 gigabytes cannot access non-prefetchable memory space. The AGP non-prefetchable memory space window is defined as follows: AGP non-prefetchable memory window = {32'h00, DevB:0x20[31:20], 20'hF_FFFF} >= address >= {32'h00, DevB:0x20[15:4], 20'h0_0000}; The links support 40 bits of memory space. AGP supports 32 bits of prefetchable memory space. The AGP prefetchable window is defined to be within the lowest 4 gigabytes of link address space. The AGP prefetchable memory space window is defined as follows: AGP prefetchable memory window = {32'h00, DevB:0x24[31:20], 20'hF_FFFF} >= address >= {32'h00, DevB:0x24[15:4], 20'h0_0000}; These windows may also be altered by DevB:0x3C[VGAEN, ISAEN]. When the address (from either the host or from an AGP bus master) is inside one of the windows, then the transaction targets the AGP bus. Therefore, the following transactions are possible: 31 AMD-8151TM AGP Tunnel Data Sheet 24888 Rev 3.03 - July 12, 2004 * Host-initiated transactions inside the windows are routed to the AGP bus. * PCI transactions initiated on the AGP bus inside the windows are not claimed by the IC. * Host initiated transactions outside the windows are passed through the tunnel or master aborted if the IC is at the end of a HyperTransport technology chain. * PCI transactions initiated on the AGP bus outside the windows are claimed by the IC using medium decoding and passed to the host. So, for example, if IOBASE > IOLIM, then no host-initiated IO-space transactions are forwarded to the AGP bus and all AGP-bus-initiated IO-space (not configuration) transactions are forwarded to the host. If MEMBASE > MEMLIM and PMEMBASE > PMEMLIM, then no host-initiated memory-space transactions are forwarded to the AGP bus and all AGP-bus-initiated memory-space (not configuration) transactions are forwarded to the host. DevB:0x1C. Default: 0220 01F1h Bits Description Attribute: See below. 31:30 Reserved. 29 RMA: received master abort. Read; set by hardware; write 1 to clear. 1=The IC received a master abort as a PCI master on the AGP bus. Note: this bit is cleared by PWROK reset but not by RESET#. 28 RTA: received target abort. Read; set by hardware; write 1 to clear. 1=The IC received a target abort as a PCI master on the AGP bus. Note: this bit is cleared by PWROK reset but not by RESET#. 27 STA: signaled target abort. Read; set by hardware; write 1 to clear. 1=The IC generated a target abort as a PCI target on the AGP bus. The IC generates target aborts if it receives a target abort (a nonNXA error) response from the host to an AGP bus PCI master transaction request. Note: this bit is cleared by PWROK reset but not by RESET#. 26:16 Read only. These bits are fixed in their default state. 15:12 IOLIM. IO limit address bits[15:12]. See DevB:0x[30:1C] above. 11:8 Reserved. 7:4 IOBASE. IO base address bits[15:12]. See DevB:0x[30:1C] above. 3:0 Reserved. DevB:0x20. Default: 0000 FFF0h Bits Description Attribute: Read-write. 31:20 MEMLIM. Non-prefetchable memory limit address bits[31:20]. See DevB:0x[30:1C] above. 19:16 Reserved. 15:4 MEMBASE. Non-prefetchable memory base address bits[31:20]. See DevB:0x[30:1C] above. 3:0 Reserved. 32 24888 Rev 3.03 - July 12, 2004 DevB:0x24. Default: 0000 FFF0h Bits Description AMD-8151TM AGP Tunnel Data Sheet Attribute: Read-write. 31:20 PMEMLIM. Prefetchable memory limit address bits[31:20]. See DevB:0x[30:1C] above. 19:16 Reserved. 15:4 PMEMBASE. Prefetchable memory base address bits[31:20]. See DevB:0x[30:1C] above. 3:0 Reserved. DevB:0x30. Default: 0000 FFFFh Bits Description Attribute: Read-write. 31:16 IOLIM. IO limit address bits[31:16]. See DevB:0x[30:1C] above. 15:0 IOBASE. IO base address bits[31:16]. See DevB:0x[30:1C] above. AGP Bridge Interrupt and Bridge Control Register Default: 0000 00FFh Bits Description DevB:0x3C Attribute: See below. 31:23 Reserved. 22 SBRST: AGP bus reset. Read-write. 1=A_RESET# asserted; AGP bus placed into reset state. 0=A_RESET# not asserted. 21:20 Reserved. 19 VGAEN: VGA decoding enable. Read-write. 1=Host-initiated commands targeting VGAcompatible address ranges are routed to the AGP bus. These include memory accesses from A0000h to BFFFFh (within the bottom megabyte of memory space only), IO accesses in which address bits[9:0] range from 3B0h to 3BBh or 3C0h to 3DFh (address bits[15:10] are not decoded, regardless of DevB:0x3C[ISAEN]; also this only applies to the first 64K of IO space; i.e., address bits[31:16] must be low). 0=The IC does not decode VGA-compatible address ranges. 18 ISAEN: ISA decoding enable. Read-write. 1=The IO address window specified by DevB:0x1C[15:0] and DevB:0x30 is limited to the first 256 bytes of each 1K byte block specified; this only applies to the first 64K bytes of IO space. 0=The PCI IO window is the whole range specified by DevB:0x1C[15:0] and DevB:0x30. 17:16 Reserved. 15:8 INTERRUPT_PIN. Read; write once. These bits control no internal logic. 7:0 INTERRUPT_LINE. Read-write. These bits control no internal logic. 33 AMD-8151TM AGP Tunnel Data Sheet 24888 Rev 3.03 - July 12, 2004 6 Electrical Data 6.1 Absolute Ratings The IC is not designed to operate beyond the parameters shown in the following table. Parameter Minimum Maximum VDD12[B, A] -0.5 V 1.7 V VDD15 -0.5 V 2.0 V VDD18, VDDA18 -0.5 V 2.3 V VDD33 -0.5 V 3.6 V 85 C TCASE (Under Bias) TSTORAGE Comments -65 C 150 C Table 6: Absolute maximum ratings. 6.2 Operating Ranges The IC is designed to provide functional operation if the voltage and temperature parameters are within the limits defined in the following table. Parameter Minimum Typical Maximum Units VDD12[B, A] 1.14 1.2 1.26 V VDD15 1.425 1.5 1.575 V VDD18, VDDA18 1.71 1.8 1.89 V VDD33 3.135 3.3 3.465 V V 85 deg C TCASE (Under Bias) Comments Table 7: Operating ranges. 34 AMD-8151TM AGP Tunnel Data Sheet 24888 Rev 3.03 - July 12, 2004 6.3 DC Characteristics See the HyperTransportTM Technology Electrical Specification for the DC characteristics of link signals. The following table shows current consumption in amps and power in watts for each power plane. Typical Max Supply Parameter Description Current Power Current Power VDD12 VDD12[B, A] current, power 0.21 A 0.25 W 0.27 A 0.34 W VDD15 VDD15 current, power 0.05 A 0.08 W 0.08 A 0.13 W VDD18 VDD18 current, power; operational 1.30 A 2.34 W 1.75 A 3.30 W VDD18 VDD18 current, power; internal clock gating enabled (DevA:0xF0[ICGSMAF]) 0.40 A 0.72 W 0.50 A 0.95 W VDD18 VDD18 current, power; internal and external clock 0.21 A gating enabled (DevA:0xF0[I/ECGSMAF]) 0.38 W 0.30 A 0.57 W VDDA18 VDDA18 current, power 0.02 A 0.04 W 0.03 A 0.06 W VDD33 0.05 A 0.17 W 0.07 A 0.24 W VDD33 current, power Total power (no clock gating enabled) 2.88 W Comments 4.07 W Table 8: Current and power consumption. The following table shows DC characteristics for signals on the VDD33 power plane. Symbol Parameter Description Min Max Units VIL Input low voltage -0.5 0.3 VDD33 V VIH Input high voltage 0.6 VDD33 0.5 + VDD33 V VOL Output low voltage; IOUT = 1.5 mA VOH Output high voltage; IOUT = -0.5 mA ILI Input leakage current +/- 10 uA CIN Input capacitance 8 pF 0.1 VDD33 0.9 VDD33 Comments V V Table 9: DC characteristics for signals on the VDD33 power plane. 35 AMD-8151TM AGP Tunnel Data Sheet 24888 Rev 3.03 - July 12, 2004 The following table shows DC characteristics for signals on the VDD15 power plane when AGP 2.0 signaling is enabled. Symbol Parameter Description Min Max Units VIL Input low voltage -0.5 0.4 VDD15 V VIH Input high voltage 0.6 VDD15 0.5 + VDD15 V VOL Output low voltage; IOUT = 1.0 mA VOH Output high voltage; IOUT = 0.2 mA 0.85 VDD15 VREFI Input reference voltage on A_REFGC 0.48 VDD15 0.52 VDD15 V VREFO Output reference voltage on A_REFCG 0.48 VDD15 0.52 VDD15 V IIL Input leakage current +/- 10 uA CIN Input capacitance 8 pF 0.15 VDD15 Comments V V Table 10: DC characteristics for signals on the VDD15 power plane, AGP 2.0 signaling. The following table shows DC characteristics for signals on the VDD15 power plane when AGP 3.0 signaling is enabled. Symbol Parameter Description Min Max Units VIL Input low voltage -0.3 VREFI - 0.1 V VIH Input high voltage VREFI + 0.1 VDD15 + 0.3 V VOL Output low voltage; IOUT = 1.5 mA VOH Output high voltage; 50 ohm load to ground VREFI 0.05 V 0.750 0.850 V Input reference voltage on A_REFGC 0.34 0.36 V VREFO Output reference voltage on A_REFCG 0.226 VDD15 0.240 VDD15 V CDIE Input die capacitance 8 pF ZTERM Terminator equivalent impedance; VOH = 45 0.8V; ZTARG = 50 Ohm 55 Ohms ZPU Pull-up equivalent impedance; VOH = 0.8V; ZTARG = 50 Ohm 46.2 Ohms 39.3 Comments Table 11: DC characteristics for signals on the VDD15 power plane, AGP 3.0 signaling. 36 AMD-8151TM AGP Tunnel Data Sheet 24888 Rev 3.03 - July 12, 2004 6.4 AC Characteristics See the HyperTransport Technology Electrical Specification for the AC characteristics of link signals. The following table shows AC specification data for clocks. Symbol Parameter Description Min Max Units tREF REFCLK cycle time 15 18 ns tCYC A_PCLK cycle time 15 ns tHIGH A_PCLK high time 6 ns tLOW A_PCLK low time 6 ns tSLEW A_PCLK slew rate 1 4 Comments Matches REFCLK V/ns Table 12: AC data for clocks. The following table shows AC specification data for common clock (A_PCLK) operation of AGP signals. Symbol Parameter Description Min Max Units tVAL A_PCLK to signal valid delay 1 5.5 ns tON A_PCLK to signal float-to-active delay 1 6 ns tOFF A_PCLK to signal active-to-float delay 1 14 ns tSU Signal input setup time to A_PCLK 6 ns tH AGP signal input hold time after A_PCLK 0 ns tRF Signal output rise and fall slew rate 2 3.5 Notes V/ns Table 13: AC data for common clock operation of AGP signals. 37 AMD-8151TM AGP Tunnel Data Sheet 24888 Rev 3.03 - July 12, 2004 The following table shows AC specification data for clock-forwarded operation of AGP signals. AGP 2X AGP 4X AGP 8X Symbol Parameter Description Min Max Min Max Min Max Units tTSF A_PCLK to transmit strobe first strobe edge tTSR A_PCLK to transmit strobe final strobe edge tDVB Data valid before strobe 1.7 -0.95 0.527 ns tDVA Data valid after strobe 1.9 1.15 0.477 ns tOND A_PCLK to float-to-active delay -1 9 -1 7 -1 7 ns tOFFD A_PCLK to active-to-float delay 1 12 1 14 1 14 ns tONS Strobe active to first edge delay 6 10 4 9 4 9 ns tOFFS Strobe final edge to float delay 6 10 4 9 4 9 ns tRSSU Receive requirement for last strobe setup time to next A_PCLK 6 6 6 ns tRSH Receive requirement for first strobe hold time after A_PCLK 1 0.5 0.5 ns tDSU Receive data setup time to strobe 1 0.4 0.085 ns tDH Receive data hold time after strobe 1 0.7 0.210 ns tRF Transmit rise and fall slew rate 2 2 12 1.9 20 3.5 8 1.5 20 2 3.5 Notes ns 19.5 ns 2 3.5 V/ns Table 14: AC data for clock-forwarded operation of AGP signals. 38 AMD-8151TM AGP Tunnel Data Sheet 24888 Rev 3.03 - July 12, 2004 7 Ball Designations 1 2 A 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 A LTACAD LTACAD LTACAD LTACAD LTACLK0 LTACLK0 LTACAD LTACAD LTACAD LTACAD LRACTL LRACTL LRACAD LRACAD LRACAD LRACAD LRACAD LRACAD LRACAD LRACAD _P0 _N0 _P2 _N2 _P _N _P5 _N5 _P7 _N7 _N _P _N6 _P6 _N4 _P4 _N3 _P3 _N1 _P1 B VDD12A VSS LTACAD VDD18 LTACAD _P1 _P3 C VDD12A D VSS E VDD12A F A_DBIH VDD12A G A_SBA0 A_DBIL VDD12A VDD12A VDD12A H A_SBA2 A_SBA1 STRAPL VDD15 0 J A_SBA3 VSS K A_SB STB_P A_SB STB_N L A_SBA5 A_SBA4 M A_SBA6 N A_AD31 A_SBA7 NC1 A_REQ# P A_AD29 A_AD30 VSS STRAPL STRAPL VDD15 13 7 R A_AD28 FREE2 VDD15 VSS T A_AD26 A_AD27 FREE3 A_ST0 U A_AD25 A_AD24 VSS V A_AD STB1_P A_ST2 W A_AD23 Y A_AD21 A_AD22 VSS VSS VSS LTACLK1 VDD18 LTACAD _P _P13 VSS LTACTL_ VDD18 LRACAD P _N7 LTACAD VDD18 _P15 LTACAD LTACAD LTACAD LTACAD LTACAD LTACAD LTACAD LTACAD FREE7 _P9 _N9 _P11 _N11 _P12 _N12 _P14 _N14 VSS VDD12A VSS VSS STRAPL STRAPL STRAPL 10 1 8 LRACAD VDD18 LRACLK _N5 0_N VSS VSS LRACAD VDD18 LRACAD _N14 _N12 VSS LRACAD VDD18 LRACAD _N11 _N9 VDD18 VSS VDD18 VSS VDD18 VSS VDD18 VSS VDD18 VSS VDD18 VSS VDD18 VSS VDD18 VSS VDD12A VSS VDD18 VSS VDD18 VSS VDD18 VSS VDD18 VSS VDD18 VSS VDD18 VSS VDD18 VSS VDD12A VSS VDD12A VSS VDD18 VSS VDD18 VSS VDD18 VSS VDD18 VSS VDD18 VSS VSS VDD12B VSS VDD18 VSS VDD18 VSS VDD18 VSS VDD12A VSS VSS VDD12A VDD12A VDD12A VDD12A VDD12A VDD12A VSS VDD18 VSS VDD18 VSS VDD12B VSS VDD15 VSS VDD15 VSS VDD18 VSS VDD18 VSS VDD18 VSS VDD18 VSS VSS VDD15 VSS VDD15 VSS VDD18 VSS VDD18 VSS VDD18 VSS VDD18 VSS VDD18 VSS VSS VDD15 VSS VDD15 VSS VDD18 VSS VDD18 VSS VDD18 VSS VDD18 VSS VSS VDD15 VSS VDD18 VSS VDD18 VSS VDD18 VSS VDD18 VSS VDD18 VSS VDD15 VSS VDD15 VSS VDD18 VSS VDD18 VSS VDD18 VSS VDD18 VSS VSS VDD15 VSS VDD15 VSS VDD15 VSS VDD15 VSS VDD15 VSS VDD12B VSS VDD18 A_ST1 VSS VSS VDD15 VSS VDD15 VSS VDD15 VSS VDD15 VSS VSS VDD12B VDD18 VDD15 VSS VDD15 VSS VDD15 VSS VDD15 VSS VDD15 VSS VDD15 VSS VDD12B VSS VDD18 A_AD A_CBE_ A_MB8X STB1_N L3 DET# VSS VSS VDD15 VSS VDD15 VSS VDD15 VSS VDD15 VSS VDD15 VSS VDD12B VSS A_RBF# VSS A_CALS STRAPL STRAPL 5 6 VSS STRAPL STRAPL STRAPL VDD15 STRAPL STRAPL 4 18 19 20 21 VSS VDD12B VSS LDTCOM P3 VSS TEST VSS VDD12B VSS VDD12B A_PLL REFCLK CLKI VSS RESET# VSS CMP OVR LDT- A_PCLK STOP# VSS NC0 AB A_AD19 A_AD17 A_AD18 STRAPL 15 VSS VSS AD STRAPL VDD15 A_WBF# A_CALD VDD15 A_CALS A_ VDD15 A_STOP A_PAR 14 # FRAME# # A_AD16 VSS VSS A_CALD STRAPL A_IRDY# A_DEVS A_TRDY # 16 EL# # A_CBE_ A_AD14 L1 VSS A_AD12 A_AD9 VSS VSS 3 4 5 6 7 8 9 10 A_AD A_AD6 STB0_P 11 VDD15 STRAPL A_PLL STRAPL 3 CLKO 22 A_AD5 STRAPL 2 A_CBE_ STRAPL A_AD15 A_AD13 A_AD11 A_AD10 A_AD8 A_CBE_ A_AD A_AD7 L2 17 L0 STB0_N 2 VDD12A D VSS E VDD12B F VDD12B VDD12B G 12 VSS VSS A_AD2 A_AD1 VSS A_AD4 A_AD3 A_AD0 A_REF GC 13 14 15 16 VSS VSS VSS VSS VSS VSS VSS LTBCAD _P2 L LTBCAD LTBCAD LTBCAD _N3 _P3 _N2 M VDD18 LTBCAD LTBCAD LTBCAD VDD18 LTBCLK0 _P7 _P6 _N6 _P N VDD18 LTBCAD LTBCAD LTBCAD _P5 _P4 _N4 VSS VSS LTBCAD _N5 VSS VSS LTBCAD VDD18 LTBCTL_ LTBCTL_ LTBCLK0 _N7 N P _N 18 P LRBCTL _N R LRBCLK LRBCLK LRBCTL 0_P 0_N _P T VDD18 LRBCAD LRBCAD LRBCAD VDD18 LRBCAD _N4 _N5 _P5 _N3 U VDD18 LRBCAD LRBCAD LRBCAD _N6 _N7 _P7 VSS VSS LRBCAD _P6 VSS VSS LRBCAD VDD18 LRBCAD LRBCAD LRBCAD _P4 _P2 _N2 _P3 W LRBCAD LRBCAD LRBCAD _P0 _N0 _P1 Y VSS VDD12B VDD12B VDD12B VSS VDD33 19 20 21 V LRBCAD _N1 VDD18 LDTCOM LDTCOM LDTCOM P0 P1 P2 VSS VSS VDD12B VSS AA VSS VDD12B AB AC VDD12B AD A_REF PWROK A_ A_TYPE VDD33 VDDA18 CG RESET# DET# 17 H K VDD18 VSS VSS VDD18 LTBCAD LTBCAD LTBCAD _N1 _P1 _N0 VSS VSS C J VDD18 STRAPL VDD15 11 VDD12A VDD18 LTBCAD _P0 VDD12B VDD12B VDD12B VSS A_GNT# STRAPL 9 VSS VSS FREE6 LRACAD LRACAD LRACAD LRACAD LRACLK LRACLK LRACAD LRACAD LRACAD LRACAD VDD12A _N15 _P15 _N13 _P13 1_N 1_P _N10 _P10 _N8 _P8 VDD15 VSS VSS FREE5 B LRACAD VDD18 LRACAD VDD12A _N2 _N0 VSS A_AD20 1 VSS VDD15 VSS FREE1 A_GC8X DET# AA AC LTACAD VDD18 LTACAD _P4 _P6 LTACAD LTACAD LTACAD LTACAD LTACLK1 LTACAD LTACAD LTACAD LTACAD LTACTL_ FREE4 LRACAD LRACAD LRACAD LRACAD LRACLK LRACAD LRACAD LRACAD LRACAD _N8 _N1 _N10 _N3 _N _N4 _N13 _N6 _N15 N _P7 _P14 _P5 _P12 0_P _P11 _P2 _P9 _P0 VDD12A LTACAD VDD18 LTACAD _P8 _P10 VSS VSS 22 23 24 Top side view. Figure 3: Ball designations. 39 AMD-8151TM AGP Tunnel Data Sheet 24888 Rev 3.03 - July 12, 2004 Alphabetical listing of signals and corresponding BGA designators. Signal name A_AD0 A_AD1 A_AD2 A_AD3 A_AD4 A_AD5 A_AD6 A_AD7 A_AD8 A_AD9 A_AD10 A_AD11 A_AD12 A_AD13 A_AD14 A_AD15 A_AD16 A_AD17 A_AD18 A_AD19 A_AD20 A_AD21 A_AD22 A_AD23 A_AD24 A_AD25 A_AD26 A_AD27 A_AD28 A_AD29 A_AD30 A_AD31 A_ADSTB0_N A_ADSTB0_P A_ADSTB1_N A_ADSTB1_P A_CALD A_CALD# A_CALS A_CALS# A_CBE_L0 A_CBE_L1 A_CBE_L2 A_CBE_L3 A_DBIH A_DBIL A_DEVSEL# A_FRAME# A_GC8XDET# A_GNT# A_IRDY# A_MB8XDET# Ball 15AD 15AC 14AC 14AD 13AD 12AB 12AC 12AD 9AD 9AC 8AD 7AD 8AC 6AD 6AC 5AD 3AC 2AB 3AB 1AB 1AA 1Y 2Y 1W 2U 1U 1T 2T 1R 1P 2P 1N 11AD 11AC 2W 1V 6AA 6AB 7Y 8AA 10AD 5AC 3AD 3W 1F 2G 9AB 9AA 4K 4L 8AB 4W Signal name A_PAR A_PCLK A_PLLCLKI A_PLLCLKO A_RBF# A_REFCG A_REFGC A_REQ# A_RESET# A_SBA0 A_SBA1 A_SBA2 A_SBA3 A_SBA4 A_SBA5 A_SBA6 A_SBA7 A_SBSTB_N A_SBSTB_P A_ST0 A_ST1 A_ST2 A_STOP# A_TRDY# A_TYPEDET# A_WBF# CMPOVR FREE1 FREE2 FREE3 FREE4 FREE5 FREE6 FREE7 LDTCOMP0 LDTCOMP1 LDTCOMP2 LDTCOMP3 LDTSTOP# LRACAD_N0 LRACAD_N1 LRACAD_N2 LRACAD_N3 LRACAD_N4 LRACAD_N5 LRACAD_N6 LRACAD_N7 LRACAD_N8 LRACAD_N9 LRACAD_N10 LRACAD_N11 LRACAD_N12 Ball 12AA 19AC 15AB 15AA 5Y 17AD 16AD 4N 19AD 1G 2H 1H 1J 2L 1L 1M 2N 2K 1K 4T 4U 3V 11AA 10AB 20AD 5AA 17AC 3K 3R 3T 13C 13D 12E 11E 20W 21W 22W 20Y 18AC 22B 21A 20B 19A 17A 16B 15A 14B 21E 21D 19E 19D 17D Signal name LRACAD_N13 LRACAD_N14 LRACAD_N15 LRACAD_P0 LRACAD_P1 LRACAD_P2 LRACAD_P3 LRACAD_P4 LRACAD_P5 LRACAD_P6 LRACAD_P7 LRACAD_P8 LRACAD_P9 LRACAD_P10 LRACAD_P11 LRACAD_P12 LRACAD_P13 LRACAD_P14 LRACAD_P15 LRACLK0_N LRACLK0_P LRACLK1_N LRACLK1_P LRACTL_N LRACTL_P LRBCAD_N0 LRBCAD_N1 LRBCAD_N2 LRBCAD_N3 LRBCAD_N4 LRBCAD_N5 LRBCAD_N6 LRBCAD_N7 LRBCAD_P0 LRBCAD_P1 LRBCAD_P2 LRBCAD_P3 LRBCAD_P4 LRBCAD_P5 LRBCAD_P6 LRBCAD_P7 LRBCLK0_N LRBCLK0_P LRBCTL_N LRBCTL_P LTACAD_N0 LTACAD_N1 LTACAD_N2 LTACAD_N3 LTACAD_N4 LTACAD_N5 LTACAD_N6 Ball 15E 15D 13E 22C 22A 20C 20A 18A 16C 16A 14C 22E 21C 20E 19C 17C 16E 15C 14E 18B 18C 17E 18E 13A 14A 23Y 24W 23V 24U 20U 21U 20R 21R 22Y 24Y 22V 24V 20V 22U 20T 22R 23T 22T 24R 24T 4A 4C 6A 6C 8C 10A 10C Signal name LTACAD_N7 LTACAD_N8 LTACAD_N9 LTACAD_N10 LTACAD_N11 LTACAD_N12 LTACAD_N13 LTACAD_N14 LTACAD_N15 LTACAD_P0 LTACAD_P1 LTACAD_P2 LTACAD_P3 LTACAD_P4 LTACAD_P5 LTACAD_P6 LTACAD_P7 LTACAD_P8 LTACAD_P9 LTACAD_P10 LTACAD_P11 LTACAD_P12 LTACAD_P13 LTACAD_P14 LTACAD_P15 LTACLK0_N LTACLK0_P LTACLK1_N LTACLK1_P LTACTL_N LTACTL_P LTBCAD_N0 LTBCAD_N1 LTBCAD_N2 LTBCAD_N3 LTBCAD_N4 LTBCAD_N5 LTBCAD_N6 LTBCAD_N7 LTBCAD_P0 LTBCAD_P1 LTBCAD_P2 LTBCAD_P3 LTBCAD_P4 LTBCAD_P5 LTBCAD_P6 LTBCAD_P7 LTBCLK0_N LTBCLK0_P LTBCTL_N LTBCTL_P NC0 Ball 12A 3C 4E 5C 6E 8E 9C 10E 11C 3A 4B 5A 6B 8B 9A 10B 11A 3D 3E 5D 5E 7E 9D 9E 11D 8A 7A 7C 7D 12C 12B 24K 22K 24M 22M 22L 20M 22N 20P 24J 23K 24L 23M 21L 20L 21N 20N 24P 24N 22P 23P 4Y Signal name NC1 PWROK REFCLK RESET# STRAPL0 STRAPL1 STRAPL2 STRAPL3 STRAPL4 STRAPL5 STRAPL6 STRAPL7 STRAPL8 STRAPL9 STRAPL10 STRAPL11 STRAPL13 STRAPL14 STRAPL15 STRAPL16 STRAPL17 STRAPL18 STRAPL19 STRAPL20 STRAPL21 STRAPL22 TEST Ball 3N 18AD 16AB 18AB 3H 4J 13AB 14AA 11Y 8Y 9Y 5P 5J 5L 3J 3M 4P 3AA 4AB 7AB 4AD 12Y 13Y 15Y 16Y 16AA 17AA Table 15: Signal BGA positions. 40 AMD-8151TM AGP Tunnel Data Sheet 24888 Rev 3.03 - July 12, 2004 Signal name VDD12A VDD12A VDD12A VDD12A VDD12A VDD12A VDD12A VDD12A VDD12A VDD12A VDD12A VDD12A VDD12A VDD12A VDD12A VDD12A VDD12A VDD12A VDD12A VDD12A VDD12A VDD12A VDD12A VDD12B VDD12B VDD12B VDD12B VDD12B VDD12B VDD12B VDD12B VDD12B VDD12B VDD12B VDD12B VDD12B VDD12B VDD12B VDD12B VDD12B VDD12B VDD12B VDD12B VDD12B VDD15 VDD15 VDD15 VDD15 VDD15 VDD15 VDD15 VDD15 Ball 1C 1E 2B 2D 2F 3G 4F 4G 5G 6H 7J 8J 9J 17J 18H 19H 20H 21G 22F 23B 23E 24C 24D 16T 16U 16V 17W 18K 18Y 19J 19AA 20J 20AB 21J 21AA 21AB 22H 22AB 23G 23AA 23AC 24F 24G 24AB 4H 4M 4R 4V 4AA 6K 6M 6P Signal name VDD15 VDD15 VDD15 VDD15 VDD15 VDD15 VDD15 VDD15 VDD15 VDD15 VDD15 VDD15 VDD15 VDD15 VDD15 VDD15 VDD15 VDD15 VDD15 VDD15 VDD15 VDD15 VDD15 VDD15 VDD15 VDD15 VDD15 VDD15 VDD15 VDD15 VDD15 VDD15 VDD18 VDD18 VDD18 VDD18 VDD18 VDD18 VDD18 VDD18 VDD18 VDD18 VDD18 VDD18 VDD18 VDD18 VDD18 VDD18 VDD18 VDD18 VDD18 VDD18 Ball Signal name 6T VDD18 6V VDD18 7L VDD18 7N VDD18 7R VDD18 7U VDD18 7W VDD18 7AA VDD18 8K VDD18 8M VDD18 8P VDD18 8T VDD18 8V VDD18 9L VDD18 9N VDD18 9R VDD18 9U VDD18 9W VDD18 10T VDD18 10V VDD18 10AA VDD18 11U VDD18 11W VDD18 12T VDD18 12V VDD18 13U VDD18 13W VDD18 13AA VDD18 14T VDD18 14V VDD18 14Y VDD18 15W VDD18 4D VDD18 5B VDD18 6F VDD18 7G VDD18 8D VDD18 8F VDD18 8H VDD18 9B VDD18 9G VDD18 10F VDD18 10H VDD18 10K VDD18 10M VDD18 10P VDD18 11G VDD18 11J VDD18 11L VDD18 11N VDD18 11R VDD18 12D VDD18 Ball 12F 12H 12K 12M 12P 13B 13G 13J 13L 13N 13R 14F 14H 14K 14M 14P 15G 15J 15L 15N 15R 16D 16F 16H 16K 16M 16P 17B 17G 17L 17N 17R 17U 18F 18M 18P 18T 18V 19G 19L 19N 19R 19U 19W 20D 20F 21B 21K 21P 21V 23J 23N Signal name VDD18 VDD33 VDD33 VDDA18 VSS VSS VSS VSS VSS VSS VSS VSS VSS VSS VSS VSS VSS VSS VSS VSS VSS VSS VSS VSS VSS VSS VSS VSS VSS VSS VSS VSS VSS VSS VSS VSS VSS VSS VSS VSS VSS VSS VSS VSS VSS VSS VSS VSS VSS VSS VSS VSS Ball Signal name 23U VSS 21AC VSS 21AD VSS 22AD VSS 1D VSS 2C VSS 2E VSS 2J VSS 2M VSS 2R VSS 2V VSS 2AA VSS 2AC VSS 3B VSS 3F VSS 3L VSS 3P VSS 3U VSS 3Y VSS 4AC VSS 5F VSS 5H VSS 5K VSS 5M VSS 5N VSS 5R VSS 5T VSS 5U VSS 5V VSS 5W VSS 5AB VSS 6D VSS 6G VSS 6J VSS 6L VSS 6N VSS 6R VSS 6U VSS 6W VSS 6Y VSS 7B VSS 7F VSS 7H VSS 7K VSS 7M VSS 7P VSS 7T VSS 7V VSS 7AC VSS 8G VSS 8L VSS 8N VSS Ball 8R 8U 8W 9F 9H 9K 9M 9P 9T 9V 10D 10G 10J 10L 10N 10R 10U 10W 10Y 10AC 11B 11F 11H 11K 11M 11P 11T 11V 11AB 12G 12J 12L 12N 12R 12U 12W 13F 13H 13K 13M 13P 13T 13V 13AC 14D 14G 14J 14L 14N 14R 14U 14W Signal name VSS VSS VSS VSS VSS VSS VSS VSS VSS VSS VSS VSS VSS VSS VSS VSS VSS VSS VSS VSS VSS VSS VSS VSS VSS VSS VSS VSS VSS VSS VSS VSS VSS VSS VSS VSS VSS VSS VSS VSS VSS VSS VSS VSS VSS VSS VSS VSS VSS VSS VSS VSS Ball 14AB 15B 15F 15H 15K 15M 15P 15T 15U 15V 16G 16J 16L 16N 16R 16W 16AC 17F 17H 17K 17M 17P 17T 17V 17Y 17AB 18D 18G 18J 18L 18N 18R 18U 18W 18AA 19B 19F 19K 19M 19P 19T 19V 19Y 19AB 20G 20K 20AA 20AC 21F 21H 21M 21T Signal name VSS VSS VSS VSS VSS VSS VSS VSS VSS VSS VSS VSS VSS VSS VSS VSS VSS Ball 21Y 22D 22G 22J 22AA 22AC 23C 23D 23F 23H 23L 23R 23W 23AB 24E 24H 24AA Table 16: Power and ground BGA positions. 41 AMD-8151TM AGP Tunnel Data Sheet 24888 Rev 3.03 - July 12, 2004 8 Package Specification A1 CORNER D A1 CORNER D1 D3 Ob (Nx Plcs) E3 E2 E E1 e D2 BOTTOM VIEW TOP VIEW LID NOT TO SCALE A2 SEE NOTES A SIDE VIEW A1 AMD PACKAGE SYMBOL GENERAL NOTES D/E D1/E1 1. All dimensions are specified in millimeters (mm). 2. Dimensioning and tolerancing per ASME-Y14.5M-1994. 3. This corner which consists of a triangle on both sides of the package identifies ball A1 corner and can be used for handling and orientation purposes. 4. Symbol "M" determines ball matrix size and "N" is number of balls. 5. Dimension "b" is measured at maximum solder ball diameter on a plane parallel to datum C. 6. "x" in front of package variation denotes non-qualified package per AMD 01-002.3. 7. The following features are not shown on drawings: a) Marking on die, label on package b) Laser elements c) Die and passive fudicials VARIATIONS xOLF564 max. 31.2 min. 30.8 29.21 BSC. D2/E2 27.8 28.2 D3/E3 22.8 23.2 A1 3.25 0.5 3.56 0.7 A2 0.9 1.1 A e Ob 1.27 BSC 0.6 0.9 M 24 N 564 aaa 0.2 bbb 0.25 0.125 ccc Figure 4: Package mechanical drawing. 42 AMD-8151TM AGP Tunnel Data Sheet 24888 Rev 3.03 - July 12, 2004 9 Test The IC includes the following test modes. Mode TEST A_TYPEDET LDTSTOP# STRAPL0 Notes Operational 0 X X X High impedance 1 0 0 0 NAND tree 1 0 0 1 Table 17: Test modes. 9.1 High Impedance Mode In high-impedance mode, all the signals of the IC are placed into the high-impedance state. 9.2 NAND Tree Mode There are several NAND trees in the IC. Some of the inputs are differential (e.g., LR[B, A] pins); for these, the _P and _N pairs of signals are converted into a single signal that is part of the NAND tree, as shown in Signal_3 in the following diagram. VDD Signal_1 Signal_2 Signal_3_P Signal_3_N ... ... 1 to output signal + - 0 Signal_41 Output signal NAND Tree Mode Figure 5: NAND tree. 43 AMD-8151TM AGP Tunnel Data Sheet 24888 Rev 3.03 - July 12, 2004 NAND tree 1: output signal is STRAPL[5]. However, the gate connected to the last signal in this NAND tree (LDTCOMP[3]) is an AND gate rather than a NAND gate; so the expected output of this NAND tree is inverted compared to the other NAND trees. 1 LRBCLK0_[P,N] 11 LTBCLK0_P 21 LTBCAD_P[4] 2 LRBCAD_[P,N][0] 12 LTBCLK0_N 22 LTBCAD_N[4] 32 LDTCOMP[3] 3 LRBCAD_[P,N][1] 13 LTBCAD_P[0] 23 LTBCAD_P[5] 4 LRBCAD_[P,N][2] 14 LTBCAD_N[0] 24 LTBCAD_N[5] 5 LRBCAD_[P,N][3] 15 LTBCAD_P[1] 6 LRBCAD_[P,N][4] 16 LTBCAD_N[1] 26 LTBCAD_N[6] 7 LRBCAD_[P,N][5] 17 LTBCAD_P[2] 8 LRBCAD_[P,N][6] 18 LTBCAD_N[2] 28 LTBCAD_N[7] 9 LRBCAD_[P,N][7] 19 LTBCAD_P[3] 10 LRBCTL_[P,N] 31 LDTCOMP[2] 25 LTBCAD_P[6] 27 LTBCAD_P[7] 29 LTBCTL_P 20 LTBCAD_N[3] 30 LTBCTL_N NAND tree 2: output signal is STRAPL[4]. 1 LRACLK0_[P,N] 21 LTACLK0_N 41 LTACAD_N[4] 2 LRACLK1_[P,N] 22 LTACLK1_P 42 LTACAD_P[12] 3 LRACAD_[P,N][0] 23 LTACLK1_N 43 LTACAD_N[12] 4 LRACAD_[P,N][8] 24 LTACAD_P[0] 44 LTACAD_P[5] 5 LRACAD_[P,N][1] 25 LTACAD_N[0] 45 LTACAD_N[5] 6 LRACAD_[P,N][9] 26 LTACAD_P[8] 7 LRACAD_[P,N][2] 27 LTACAD_N[8] 47 LTACAD_N[13] 8 LRACAD_[P,N][10] 28 LTACAD_P[1] 9 LRACAD_[P,N][3] 50 LTACAD_P[14] 31 LTACAD_N[9] 51 LTACAD_N[14] 12 LRACAD_[P,N][12] 32 LTACAD_P[2] 13 LRACAD_[P,N][5] 48 LTACAD_P[6] 29 LTACAD_N[1] 49 LTACAD_N[6] 10 LRACAD_[P,N][11] 30 LTACAD_P[9] 11 LRACAD_[P,N][4] 46 LTACAD_P[13] 52 LTACAD_P[7] 33 LTACAD_N[2] 53 LTACAD_N[7] 14 LRACAD_[P,N][13] 34 LTACAD_P[10] 54 LTACAD_P[15] 15 LRACAD_[P,N][6] 35 LTACAD_N[10] 55 LTACAD_N[15] 16 LRACAD_[P,N][14] 36 LTACAD_P[3] 17 LRACAD_[P,N][7] 56 LTACTL_P 37 LTACAD_N[3] 57 LTACTL_N 18 LRACAD_[P,N][15] 38 LTACAD_P[11] 19 LRACTL_[P,N] 39 LTACAD_N[11] 20 LTACLK0_P 40 LTACAD_P[4] 44 AMD-8151TM AGP Tunnel Data Sheet 24888 Rev 3.03 - July 12, 2004 NAND tree 3: output signal is STRAPL[3]. 1 STRAPL[1] 21 A_DBIL 41 A_CBE_L[2] 61 A_AD[12] 2 STRAPL[8] 22 A_DBIH 42 A_CBE_L[3] 62 A_AD[13] 3 STRAPL[10] 23 A_AD[31] 43 A_ST[0] 63 A_AD[11] 4 STRAPL[9] 24 A_AD[30] 44 A_ST[1] 64 A_AD[10] 5 A_GC8XDET# 25 A_AD[29] 45 A_ST[2] 65 A_AD[9] 6 A_SBA[0] 26 A_AD[28] 46 A_MB8XDET# 66 A_AD[8] 7 A_SBA[1] 27 A_AD[27] 47 A_RBF# 67 A_ADSTB0_N 8 A_SBA[2] 28 A_AD[26] 48 A_WBF# 68 A_ADSTB0_P 9 A_SBA[3] 29 A_AD[25] 49 STRAPL[14] 69 A_CBE_L[0] 10 A_SBSTB_N 30 A_AD[24] 50 STRAPL[15] 70 A_AD[7] 11 A_SBSTB_P 31 A_ADSTB1_N 51 STRAPL[17] 71 A_AD[6] 12 A_SBA[4] 32 A_ADSTB1_P 52 STRAPL[16] 72 A_AD[5] 13 A_SBA[5] 33 A_AD[23] 53 A_IRDY# 73 A_AD[4] 14 A_SBA[6] 34 A_AD[22] 54 A_DEVSEL# 74 A_AD[3] 15 A_SBA[7] 35 A_AD[21] 55 A_FRAME# 75 A_AD[1] 16 A_GNT# 36 A_AD[20] 56 STRAPL[6] 76 A_AD[2] 17 STRAPL[11] 37 A_AD[19] 57 A_TRDY# 77 A_AD[0] 18 A_REQ# 38 A_AD[17] 58 A_CBE_L[1] 78 A_STOP# 19 STRAPL[13] 39 A_AD[18] 59 A_AD[15] 79 A_PAR 20 STRAPL[7] 40 A_AD[16] 60 A_AD[14] 80 STRAPL[18] STRAPL[19] Nand tree 4: output signal is STRAPL[2]. 1 CMPOVR 6 A_PLLCLKI 2 RESET# 7 STRAPL[20] 3 PWROK 8 STRAPL[21] 4 REFCLK 9 STRAPL[22] 5 A_PLLCLKO 10 A_RESET# 11 A_PCLK Notes: * LDTSTOP#, A_TYPEDET#, TEST, STRAPL[0], A_REFCG, A_REFGC, A_CALD, A_CALD#, A_CALS, and A_CALS# are not in the NAND trees. * While in NAND-tree mode, the link and AGP input compensation is placed at a "mid-band" value. * While in NAND-tree mode, the AGP signals operate under AGP 2.0 signaling rules. 10 Appendix 10.1 Revision History Revision 3.02 * Initial release. Revision 3.03 * Removed Preliminary. 45