AU1000266MCD - Advanced Micro Devices, Inc.

AMD Alchemy™ Au1000™ Processor Data Book

AMD Alchemy™

Au1000™ Processor

Data Book

June 2006

Publication ID: 30360E

2AMD Alchemy™ Au1000™ Processor Data Book

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 mer-

chantability, 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, AMD Alchemy, and combinations thereof, and Au1000 are trademarks of

Advanced Micro Devices, Inc.

MIPS32 is a trademark of MIPS Technologies.

Microsoft and Windows are registered trademarks of Microsoft Corporation in the United States and/or

other jurisdictions.

Other product names used in this publication are for identification purposes only and may be trademarks

of their respective companies.

AMD Alchemy™ Au1000™ Processor Data Book 3

Contents 30360E

Contents

List of Figures . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5

List of Tables . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 7

1.0 Overview . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 11

1.1 Product Description . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 11

1.2 Features . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 12

2.0 CPU . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 13

2.1 Core . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 13

2.2 Caches . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 15

2.3 Write Buffer . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 21

2.4 Virtual Memory . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 24

2.5 Exceptions . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 25

2.6 MIPS32™ Instruction Set . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 27

2.7 Coprocessor 0 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 28

2.8 System Bus (SBUS) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 40

2.9 EJTAG . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 41

3.0 Memory Controllers . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 43

3.1 SDRAM Memory Controller . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 44

3.2 Static Bus Controller . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 53

4.0 DMA Controller . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 73

4.1 DMA Configuration Registers . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 73

4.2 Using GPIO as External DMA Requests (DMA_REQn) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 78

4.3 Programming Considerations . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 79

5.0 Interrupt Controller . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 81

5.1 Interrupt Controller Sources . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 81

5.2 Register Definitions . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 83

5.3 Hardware Considerations . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 86

5.4 Programming Considerations . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 86

6.0 Peripheral Devices . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 87

6.1 AC97 Controller . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 87

6.2 USB Host Controller . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 93

6.3 USB Device Controller . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 95

6.4 IrDA . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 107

6.5 Ethernet MAC Controller . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 122

4AMD Alchemy™ Au1000™ Processor Data Book

Contents

30360E

6.6 I2S Controller . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 145

6.7 UART Interfaces . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 150

6.8 SSI Interfaces . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 159

7.0 System Control . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 167

7.1 Clocks . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 168

7.2 Time of Year Clock and Real Time Clock . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 178

7.3 General Purpose I/O and Pin Functionality . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 183

7.4 Power Management . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 188

8.0 Power-up, Reset and Boot . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 195

8.1 Power-up Sequence . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 195

8.2 Reset . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 195

8.3 Boot . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 197

9.0 EJTAG . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 199

9.1 EJTAG Instructions . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 199

9.2 Debug Exceptions . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 199

9.3 Coprocessor 0 Registers . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 200

9.4 EJTAG Memory Range . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 202

10.0 Signal Descriptions . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 215

11.0 Electrical and Thermal Specifications . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 231

11.1 Absolute Maximum Ratings . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 231

11.2 Thermal Characteristics . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 232

11.3 DC Parameters . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 233

11.4 AC Parameters . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 235

11.5 Power-up and Reset Timing . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 246

11.6 Asynchronous Signals . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 249

11.7 External Clock Specifications . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 249

11.8 Crystal Specifications . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 250

11.9 System Design Considerations . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 251

12.0 Packaging, Pin Assignment and Ordering Information . . . . . . . . . . . . . . . . . . 253

12.1 Mechanical Package . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 254

12.2 Pin Assignments. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 256

12.3 Ordering Information . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 266

Appendix A Support Documentation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 267

A.1 Memory Map . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 267

A.2 Data Book Notations . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 274

A.3 Data Book Revision History . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 275

AMD Alchemy™ Au1000™ Processor Data Book 5

List of Figures 30360E

List of Figures

Figure 1-1. Au1000™ Processor Block Diagram . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .11

Figure 2-1. Au1 Core Diagram . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 13

Figure 2-2. Cache Organization . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 15

Figure 2-3. Au1 Write Buffer . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 21

Figure 2-4. SBUS Arbitration . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 40

Figure 3-1. SDRAM Typical Read Timing . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 50

Figure 3-2. SDRAM Typical Write Timing . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 51

Figure 3-3. SDRAM Refresh Timing . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 51

Figure 3-4. Static Memory Read Timing (Single Read Followed by Burst) . . . . . . . . . . . . . . . . . . . . . . . 61

Figure 3-5. Static Memory Read EWAIT# Timing . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .61

Figure 3-6. Static Memory Write Timing . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 62

Figure 3-7. Static Memory Write EWAIT# Timing . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .62

Figure 3-8. One Card PCMCIA Interface . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 64

Figure 3-9. Two Card PCMCIA Interface . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 65

Figure 3-10. PCMCIA Memory Read Timing . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 66

Figure 3-11. PCMCIA Memory Read PWAIT# Timing . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 66

Figure 3-12. PCMCIA Memory Write Timing . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 67

Figure 3-13. PCMCIA Memory Write PWAIT# Timing . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 67

Figure 3-14. PCMCIA I/O Read Timing . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 67

Figure 3-15. PCMCIA I/O Read PWAIT# Timing . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .68

Figure 3-16. PCMCIA I/O Write Timing . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 68

Figure 3-17. PCMCIA I/O Write PWAIT# Timing . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 68

Figure 3-18. LCD Controller Timing . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 70

Figure 3-19. LCD Read LWAIT# Timing . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 70

Figure 3-20. LCD Write LWAIT# Timing . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 70

Figure 3-21. 16-Bit Chip Select Little-Endian Data Format (Default) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 71

Figure 3-22. Big-Endian Au1 Core and Little-Endian 16-Bit Chip Select . . . . . . . . . . . . . . . . . . . . . . . . . . 72

Figure 3-23. Big-Endian Au1 Core and Big-Endian 16-Bit Chip Select . . . . . . . . . . . . . . . . . . . . . . . . . . . 72

Figure 5-1. Interrupt Controller Logic . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 83

Figure 6-1. Endpoint Configuration Data Structure . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 97

Figure 6-2. Transmit Ring Buffer Entry Format . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 118

Figure 6-3. Receive Ring Buffer Entry Format . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 120

Figure 6-4. Typical Write Transaction Timing . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 159

Figure 6-5. Typical Read Transaction Timing . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 159

Figure 7-1. Clocking Topology . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 168

Figure 7-2. Frequency Generator and Clock Source Block Diagram . . . . . . . . . . . . . . . . . . . . . . . . . . . 170

Figure 7-3. Frequency Generator and Clock Source Mapping . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 171

Figure 7-4. TOY and RTC Block Diagram . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 178

Figure 7-5. GPIO Logic Diagram . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 185

Figure 7-6. Sleep and Idle Flow Diagram . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 188

Figure 7-7. Sleep Sequence . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 191

Figure 8-1. Power-up Sequence . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 195

Figure 8-2. Hardware Reset Sequence . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 196

Figure 8-3. Runtime Reset Sequence . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 196

Figure 10-1. Au1000™ Processor External Signals . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 216

6AMD Alchemy™ Au1000™ Processor Data Book

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Figure 11-1. Voltage Undershoot Tolerances for Input and I/O Pins . . . . . . . . . . . . . . . . . . . . . . . . . . . . 232

Figure 11-2. Voltage Overshoot Tolerances for Input and I/O Pins . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 232

Figure 11-3. SDRAM Timing . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 236

Figure 11-4. Static RAM, I/O Device and Flash Timing . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 237

Figure 11-5. PCMCIA Host Adapter Timing . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 238

Figure 11-6. LCD Interface Timing . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 239

Figure 11-7. GPIO Interrupt Timing . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 240

Figure 11-8. Ethernet MII Timing Diagram . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 241

Figure 11-9. I2S Timing Diagram . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 242

Figure 11-10. AC-Link Timing Diagram . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 243

Figure 11-11. SSI Timing Diagram . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 244

Figure 11-12. EJTAG Timing Diagram . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 245

Figure 11-13. Power-up Sequence . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 246

Figure 11-14. Hardware Reset Sequence . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 247

Figure 11-15. Runtime Reset Sequence . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 248

Figure 12-1. Package Dimensions . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 254

Figure 12-2. Connection Diagram — Top View . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 256

Figure 12-3. OPN Example . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 266

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List of Tables

Table 2-1. Cache Line Allocation Behavior . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 16

Table 2-2. Cache Operations . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 17

Table 2-3. Cache Coherency Attributes (CCA) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 17

Table 2-4. Values for Page Size and PageMask Register . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 24

Table 2-5. Cause[ExcCode] Encodings . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 25

Table 2-6. CPU Interrupt Sources . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 26

Table 2-7. Coprocessor 0 Register Definitions . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 28

Table 3-1. Memory Controller Block Base Address . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 43

Table 3-2. SDRAM Configuration Registers . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 45

Table 3-3. SDRAM Signals . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 52

Table 3-4. Static Bus Controller Configuration Registers . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .53

Table 3-5. Device Type Encoding . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 55

Table 3-6. Burst Size Mapping . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 55

Table 3-7. Actual Number of Clocks for Timing Parameters (Except Tcsh) . . . . . . . . . . . . . . . . . . . . . . 56

Table 3-8. Actual Number of Clocks for Tcsh . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 56

Table 3-9. Static RAM, I/O Device and Flash Control Signals . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 60

Table 3-10. PCMCIA Memory Mapping . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 63

Table 3-11. PCMCIA Interface Signals . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 63

Table 3-12. LCD Controller Interface Signals . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 69

Table 4-1. DMA Channel Base Addresses . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 73

Table 4-2. DMA Channel Configuration Registers . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .74

Table 4-3. Peripheral Addresses and Selectors . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 74

Table 5-1. Interrupt Controller Connections to the CPU . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 81

Table 5-2. Interrupt Sources . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 82

Table 5-3. Interrupt Controller Base Addresses . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 83

Table 5-4. Interrupt Controller Registers . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 84

Table 5-5. Interrupt Configuration Register Function . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 86

Table 6-1. AC97 Base Address . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 87

Table 6-2. AC97 Registers . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 87

Table 6-3. AC-Link Signals . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 91

Table 6-4. USB Host Base Address . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 93

Table 6-5. USB Host Signals . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 94

Table 6-6. USB Device Base Address . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 95

Table 6-7. USB Device Register Block . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 95

Table 6-8. Endpoint Configuration Field Descriptions . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .98

Table 6-9. Example Endpoint Configuration Data Block . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 99

Table 6-10. USB Device Signals . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 106

Table 6-11. IrDA Modes Supported . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 107

Table 6-12. IrDA Base Address . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 107

Table 6-13. IrDA Registers . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 107

Table 6-14. IrDA Hardware Connections . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 115

Table 6-15. IrDA PHY Configuration Table . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 116

Table 6-16. Fast Infrared Mode (FIR) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 116

Table 6-17. Medium Infrared Mode (MIR) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 117

Table 6-18. Slow Infrared Mode (SIR) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 118

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Table 6-19. Transmit Ring Buffer Entry Format Description . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 119

Table 6-20. Receive Ring Buffer Entry Format Description . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 120

Table 6-21. Ethernet Base Addresses . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 123

Table 6-22. MAC Configuration Register Descriptions . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 123

Table 6-23. MAC DMA Entries . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 133

Table 6-24. MAC DMA Receive Entry Registers . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 133

Table 6-25. MAC DMA Transmit Entry Registers . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 133

Table 6-26. MAC DMA Block Indexed Address Bit Definitions . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 134

Table 6-27. Ethernet Signals . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 142

Table 6-28. I2S Base Address . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 145

Table 6-29. I2S Interface Register Block . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 145

Table 6-30. I2S Signals . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 148

Table 6-31. UART Register Base Addresses . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 150

Table 6-32. UART Registers . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 150

Table 6-33. Interrupt Cause Encoding . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 152

Table 6-34. UART Signals . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 158

Table 6-35. SSI Base Addresses . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 160

Table 6-36. SSI Registers . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 160

Table 6-37. SSI Signals . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 165

Table 7-1. System Control Block Base Address . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 167

Table 7-2. Clock Generation Registers . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 169

Table 7-3. Clock Mux Input Select Values . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 175

Table 7-4. Programmable Counter Registers . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 179

Table 7-5. GPIO Control Registers . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 185

Table 7-6. Peripheral Power Management . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 189

Table 7-7. Power Management Registers . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 191

Table 8-1. ROMSEL and ROMSIZE Boot Device . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 197

Table 9-1. Coprocessor 0 registers for EJTAG . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 200

Table 9-2. EJTAG Memory Mapped Registers at 0xFF300000 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 203

Table 9-3. EJTAG Instruction Register Values . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 208

Table 9-4. EJTAG Signals . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 214

Table 10-2. Signal State Abbreviations for Table 10-3 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 217

Table 10-1. Signal Type Abbreviations for Table 10-3 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 217

Table 10-3. Signal Descriptions . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 218

Table 11-1. Absolute Maximum Ratings . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 231

Table 11-2. Thermal Characteristics . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 232

Table 11-3. DC Parameters . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 233

Table 11-4. Voltage and Power Parameters for 266 MHz Part . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 233

Table 11-5. Voltage and Power Parameters for 400 MHz Part . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 234

Table 11-6. Voltage and Power Parameters for 500 MHz Part . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 234

Table 11-7. SDRAM Controller Interface . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 236

Table 11-8. Static RAM, I/O Device and Flash Timing . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 237

Table 11-9. PCMCIA Timing . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 238

Table 11-10. LCD Timing . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 239

Table 11-11. GPIO Timing for Interrupts . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 240

Table 11-12. Ethernet MII Timing . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 241

Table 11-13. I2S Interface Timing . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 242

Table 11-14. AC-Link Interface Timing . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 243

Table 11-15. Synchronous Serial Interface Timing . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 244

Table 11-16. EJTAG Interface Timing . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 245

Table 11-17. Power-up Timing Parameters . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 246

Table 11-18. Hardware Reset Timing Parameters . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 247

Table 11-19. Runtime Reset Timing Parameters . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 248

Table 11-20. External Clock EXTCLK[1:0] Specifications . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 249

Table 11-21. 12 MHz Crystal Specification . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 250

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List of Tables 30360E

Table 11-22. 32.768 kHz Crystal Specification . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 250

Table 12-1. Pin Assignment — Sorted by Pin Number . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 258

Table 12-2. Pin Assignment — Sorted Alphabetically by Default Signal . . . . . . . . . . . . . . . . . . . . . . . . 262

Table 12-3. Pin Assignment — Alternate Signals Sorted Alphabetically . . . . . . . . . . . . . . . . . . . . . . . . 265

Table 12-4. Valid OPN Combinations . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 266

Table A-1. Basic Au1000™ Processor Physical Memory Map . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 267

Table A-2. System Bus Devices Physical Memory Map . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 267

Table A-3. Peripheral Bus Devices Physical Memory Map . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 268

Table A-4. Device Memory Map . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 269

Table A-5. Revision History . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 275

10 AMD Alchemy™ Au1000™ Processor Data Book

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AMD Alchemy™ Au1000™ Processor Data Book 11

Overview 30360E

1.0Overview

The Au1000™ processor is a high performance, low power

system-on-a-chip (SOC) designed for use in the Internet

edge device market. These devices are customer premise

equipment (CPE) products, including both wireless, hand-

held enterprise PDAs and remote Internet access prod-

ucts, as well as Internet infrastructure products such as

routers and line cards.

1.1 Product Description

The Au1000™ processor is a complete SOC based on the

MIPS32™ instruction set. Designed for maximum perfor-

mance at low power, the processor runs up to 500 MHz.

Power dissipation is less than a half watt for the 400 MHz

version. Highly integrated with on-chip memory controllers

and Internet access peripherals, the Au1000 processor

runs a variety of operating systems, including Windows®

CE, Linux and VxWorks. Moreover, the integration of

peripherals with the unique, high performance, MIPS-com-

patible core provides low system cost, small form factor,

low system power requirement, simple designs at multiple

performance points and thus, short design cycles.

Figure 1-1. Au1000™ Processor Block Diagram

DMA Controller

Enhanced

MIPS32™

CPU Core

SDRAM

Controller

32x16 MAC

Bus Unit

16 KB

Data Cache

SRAM

Controller

System Bus (SBUS)

Peripheral Bus

Fast IrDA

EJTAG

Ethernet MAC

USB 1.1 Host

USB 1.1 Device

Interrupt Controller

GPIO (32)

I2S

UART (4)

SDRAM

RTC (2)

Power Mgmt

SSI

AC97

Controller

16 KB

Inst. Cache

SRAM

LCD

Controller

PCMCIA

ROM

Expansion

Bus

Flash

12 AMD Alchemy™ Au1000™ Processor Data Book

Overview

30360E

1.2 Features

High Speed MIPS CPU Core

■266, 400, or 500 MHz

■MIPS32 instruction set 32-bit architecture

■16 KB instruction and 16 KB data caches

■High speed multiply-accumulate (MAC) and divide unit

■1.5V core @ 266 MHz and 400 MHz

1.8V core @ 500 MHz

■3.3V I/O

Highly-Integrated System Peripherals

■GPIO (32 total, 5 dedicated for system use)

■Two 10/100 Ethernet MAC controllers

■USB 1.1 device and host controllers

■Four UARTs

■IrDA controller

■AC97 controller

■I2S controller

■Two SSI controllers

■PCMCIA interface

High-Bandwidth Memory Buses

■100 MHz SDRAM controller (@ 400 MHz)

■SRAM/Flash EPROM controller

Caches

■16 KB non-blocking data cache

■16 KB instruction cache

■Instruction and data caches are 4-way

set associative

■Write-back with read-allocate

■Cache Management Features:

— Programmable allocation policy

— Line locking

■Prefetch instructions (instruction and data)

■High speed access to on-chip buses

Core Microarchitecture Highlights

■Pipeline

— Scalar 5-stage pipeline

— Load/store adder in I-stage (instr decode)

— Scalar branch techniques optimized: Pipelined

— Zero penalty branch

■Multiply-Accumulate (MAC) and Divide Unit

— Max issue rate of one 32x16 MAC per clock

— Max issue rate of one 32x32 MAC per every other

clock

— Operates in parallel to CPU pipeline

— Executes all integer multiply and divide instructions

— 32 x 16-bit MAC hardware

MMU

■Instruction and data watch registers for software break-

points

■Separate interrupt exception vector

■TLB Features:

— 32 dual-entry fully-associative

— Variable page sizes: 4 KB to 16 MB

—4-entry ITB

Low System Power

■Core / Power

— 266 MHz / < 300 mW

400 MHz / 500 mW

500 MHz / 900 mW

■Power-Saving Modes:

—Idle

—Sleep

■Pseudo-static design to 0 Hz

Package

■324 BGA, 23 mm x 23 mm

Operating System Support

■Microsoft® Windows® CE

■Linux

■VxWorks

Development Tool Support

■Complete MIPS32™ Compatible Tool Set

■Numerous 3rd-Party Compilers, Assemblers and

Debuggers

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2.0CPU

The Au1000 CPU core is a unique implementation of the MIPS32 instruction set architecture (ISA) designed for high fre-

quency and low power. This chapter provides information on the implementation details of this MIPS32 compliant core.

The full description of the MIPS32 architecture is provided in the “MIPS32TM Architecture For Programmers” documenta-

tion, available from MIPS Technologies, Inc. The information contained in this chapter supplements the MIPS32 architec-

ture documentation.

2.1 Core

The Au1000 CPU core (Au1) is a high performance, low power implementation of the MIPS32 architecture. Figure 2-1

shows a block diagram of the core.

The Au1 core contains a five-stage pipeline. All stages complete in a single cycle when data is present. All pipeline hazards

and dependencies are enforced by hardware interlocks so that any sequence of instructions is guaranteed to execute cor-

rectly. Therefore, it is not necessary to pad legacy MIPS hazards (such as load delay slots and coprocessor accesses) with

NOPs.

The general purpose register file has two read ports and one write port. The write port is shared with data cache loads and

the pipeline Writeback stage.

Figure 2-1. Au1 Core Diagram

mini-ITLB

Instruction

Cache

Fetch

Decode

Execute

Cache

Writeback

CP0 Registers

TLB

Data

Cache

Write

Buffer

SBUS Interface

MAC

Miss

Hit

EJTAG

SBUS

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2.1.1 Fetch Stage

The Fetch stage retrieves the next instruction from the instruction cache, where it is passed to the Decode stage. If the

instruction is not present in the instruction cache, then the fetch address is forwarded to the virtual memory unit in order to

fulfill the request. Instruction fetch stalls until the next instruction is available.

2.1.2 Decode Stage

The Decode stage prepares the pipeline for executing the instruction. In the Decode stage, the following occur in parallel:

•The instruction is decoded.

•Control for the instruction is generated.

•Register data is read.

•The branch target address is generated.

•The load/store address is generated.

Instructions stall in the Decode stage if dependent data or resources are not yet available. At the end of the Decode stage

a new program counter value is sent to the Fetch stage for the next instruction fetch cycle.

2.1.3 Execute Stage

In the Execute stage, instructions that do not access memory are processed in hardware (shifters, adders, logical, compar-

ators, etc.). Most instructions complete in a single cycle, but a few require multiple cycles (CLO, CLZ, MUL).

The virtual address calculation begins in the Decode stage so that physical address calculation can complete in the Exe-

cute stage, in time to initiate the access to the data cache in the Execute stage. If the physical address misses in the TLB, a

TLB exception is posted.

Multiplies and divides are forwarded to the Multiply Accumulate unit. These instructions require multiple cycles to execute

and operate mostly independent of the main five-stage pipeline.

All exception conditions (arithmetic, TLB, interrupt, etc.) are posted by the end of the Execute stage so that exceptions can

be signalled in the Cache stage.

2.1.4 Cache Stage

In the Cache stage, load and store accesses complete.

Loads that hit in the data cache obtain the data in the Cache stage. If a load misses in the data cache, or is to a non-cache-

able location, then the request is sent to the System Bus (SBUS) to be fulfilled. Load data is forwarded to dependent

instructions in the pipeline.

Stores that hit in the data cache are written into the cache array. If a store misses in the data cache, or is to a non-cache-

able location, then the store is sent to the write buffer.

If any exceptions are posted, an exception is signaled and the Au1 core is directed to fetch instructions at the appropriate

exception vector address.

2.1.5 Writeback Stage

In the Writeback stage, results are posted to the general purpose register file, and forwarded to other stages as needed.

2.1.6 Multiply Accumulate Unit

The Multiply Accumulate unit (MAC) executes all multiply and divide instructions. The MAC is composed of a 32x16 bit

pipelined array multiplier that supports early out detection, divide block, and the HI and LO registers used in calculations.

The MAC operates in parallel with the main five-stage pipeline. Instructions in the main pipeline that do not have dependen-

cies on the MAC calculations execute simultaneously with instructions in the MAC unit.

A multiply calculation of 16x16 or 32x16 bits can complete in one cycle. The 32x16 bit multiply must have the sign-extended

16-bit value in register operand rt of the instruction.

32x32 bit multiplies may be started every other CPU cycle. The 32x32 multiplies will complete in two cycles if the results are

written to the general purpose registers.

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If the results are written to the HI/LO registers then three cycles are required for 16x16 and 32x16 bits multiplies. 32x32 bit

multiplies that use HI/LO will complete in 4 cycles.

Divide instructions complete in a maximum of 35 cycles.

2.2 Caches

The Au1 core contains independent, on-chip 16 KB instruction and data caches. As shown in Figure 2-2, each cache con-

tains 128 sets and is four-way set associative with 32 bytes per way (cache line).

Figure 2-2. Cache Organization

A cache line is tagged with a 20-bit physical address, a lock bit, and a valid bit. Data cache lines also include coherency and

dirty status bits. The physical address tag contains bits 31:12 of the physical address; as such, physical addresses in which

bits 35:32 are non-zero must be mapped non-cacheable.

A cache line address is always 32-byte aligned. The cache is indexed with the lower, untranslated bits (bits [11:5]) of the

virtual address, allowing the virtual-to-physical address translation and the cache access to occur in parallel.

2.2.1 Cache Line Replacement Policy

In general, the caches implement a least recently used (LRU) replacement policy. Each cache set maintains true LRU sta-

tus bits (MRU, nMRU and LRU) to determine which cache line is selected for replacement. However, software can influence

which cache line is replaced by marking memory pages as streaming, or by locking lines in the cache.

2.2.2 Cache Line Locking Support

The CACHE instruction is used to lock individual lines in the cache. A locked line is not subject to replacement. All four lines

in a set can not be locked at once; at least one line is always available for replacement. To unlock individual cache lines use

the CACHE instruction with a ‘hit invalidate’ command opcode. See Section 2.2.5 "Cache Management" on page 17 for fur-

ther discussion of the CACHE instruction.

2.2.3 Cache Streaming Support

Streaming is typically characterized as the processing of a large amount of transient instructions and/or data. In traditional

cache implementations (without explicit support for streaming), transient instructions and/or data quickly displace useful,

recently used items in the cache. This yields poor utilization of the cache and results in poor system performance.

The Au1 caches explicitly support streaming by placing instructions and/or data marked as streaming into way 0 of the

cache. This method ensures that streaming does not purge the cache(s) of useful, recently used items, while permitting

transient instructions and/or data to be cached. The CCA bits in the TLB entry indicate if a page contains streaming instruc-

tions and/or data. In addition, the PREF instruction is available to software to allow data to be placed in the data cache in

advance of its use.

Cache Line State

Bit31302928272625242322212019181716151413121110 9 8 7 6 5 4 3 2 1 0

Physical Address Tag D S L V

Cache Address Decode

Bit31302928272625242322212019181716151413121110 9 8 7 6 5 4 3 2 1 0

Virtual/Physical Address Set Select Byte Select

Way 3

Word 0 Word 1 Word 2 Word 3 Word 4 Word 5 Word 6 Word 7

Address Tag & State

Word 0 Word 1 Word 2 Word 3 Word 4 Word 5 Word 6 Word 7

Way 2

Way 1

Way 0

128 Sets

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2.2.4 Cache Line Allocation Behavior

When an instruction fetch misses in the instruction cache, or a data load misses in the data cache, a burst fill operation is

performed to fill the cache line from memory. The cache line is selected by the following algorithm:

MRU is most recently used

nMRU is next most recently used

nLRU is next least recently used

LRU is least recently used

Cache Miss:

if (Streaming CCA=6) then Replacement = 0,

else if (LRU is !Valid or !Locked) then Replacement = LRU

else if (nLRU is !Valid or !Locked) then Replacement = nLRU

else if (nMRU is !Valid or !Locked) then Replacement = nMRU

else Replacement = MRU

Cache Hit:

new MRU = Hit Way

In short, the LRU selection is true LRU but with the following priorities:

1) Streaming: cache misses are forced to way 0.

2) Locking: cache misses follow policy above and set Lock bit.

3) Normal: true LRU replacement.

Table 2-1 summarizes cache line allocation for misses, as well as cache hit behavior. The table also shows how prefetching

and cache locking affect the cache for hits and misses.

Table 2-1. Cache Line Allocation Behavior

Operation Hit Miss

NORMAL

Data load, Instruction fetch Read data from whichever cache line

contains the address.

Allocate and fill cache line; clear Lock

bit; return read data.

Data store Write data to whichever cache line

contains the address.

Send to the write buffer.

STREAMING (CCA = 6)

Data load, Instruction fetch Read data from whichever cache line

contains the address.

Allocate and fill cache line in Way 0;

maintain Lock bit; return read data.

Data store Write data to whichever cache line

contains the address.

Send to the write buffer.

PREF (data prefetch instruction with

0x4 hint)

No action taken—data remains in

current cache line.

Allocate and fill cache line in Way 0;

maintain Lock bit.

LOCKING

CACHE 0x1D/0x1C (cache manage-

ment instruction with Lock opcode)

Set Lock bit in whichever cache line

contains the address.

Allocate and fill cache line; set Lock

bit.

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2.2.5 Cache Management

The caches are managed with the CACHE instruction. The effect of the CACHE instruction is immediately visible to subse-

quent data accesses. Table 2-2 shows the cache operations, including the opcode to direct the operation to either the

instruction cache or data cache. (An “n/a” indicates that the operation is not applicable.)

These cache operations permit initialization, locking/unlocking and management of the caches.

2.2.6 Cache Coherency Attributes (CCA)

The cache coherency attributes (CCA) field in Config0[K0] and in the TLB determine the cache-ability of accesses to mem-

ory. Cached accesses are performed critical-word-first to improve performance. The Au1 implements the following:

Table 2-2. Cache Operations

Operation

CACHE[20..18]

Encoding

Opcode for

Instruction Cache

Opcode for

Data Cache

Index Invalidate 000 0x00 0x01 (with writeback)

Index Load Tag 001 0x04 0x05

Index Store Tag 010 0x08 0x09

Hit Invalidate 100 0x10 0x11

Fill 1010x14N/A

Hit Writeback and Invalidate 101 N/A 0x15

Hit Writeback 110 N/A 0x19

Fetch and Lock 111 0x1C 0x1D

Table 2-3. Cache Coherency Attributes (CCA)

CCA

(3 Bits) Description

0, 1 00x Reserved (undefined).

2 010 Uncached, non-mergeable, non-gatherable.

Required by the MIPS32 architecture. In addition, data is not merged within the write buffer to

achieve a truly uncached effect.

3 011 Cached, mergeable, gatherable.

4 100 Reserved (undefined).

5 101 Cached, mergeable, gatherable.

6 110 Cached, mergeable, gatherable, streaming.

Instructions and/or data are placed into way 0.

7 111 Uncached, mergeable, gatherable.

Even though data is not cached, data stores sent to the write buffer are subject to merging and

gathering in the write buffer.

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2.2.7 Instruction Cache

The instruction cache is a 16 KB, four-way set associative cache. The instruction cache services instruction fetch requests

from the Fetch stage of the pipeline.

An instruction cache line state consists of a 20-bit physical address tag, a lock bit (L) and a valid bit (V).

2.2.7.1 Instruction Cache Initialization and Invalidation

Out of reset, all instruction cache lines are invalidated; thus the instruction cache is ready for use.

To invalidate the instruction cache in software, a loop of index invalidate CACHE instructions for each of the lines in the

cache invalidates the cache.

li t0,(16*1024) # Cache size

li t1,32 # Line size

li t2,0x80000000 # First KSEG0 address

addu t3,t0,t2 # terminate address of loop

loop:

cache 0,0(t2) # Icache indexed invalidate tag

addu t2,t1 # compute next address

bne t2,t3,loop

nop

2.2.7.2 Instruction Cache Line Fills

If an instruction fetch address hits in the instruction cache, the instruction word is returned to the Fetch stage. If the fetch

address misses in the cache, and the address is cacheable, then the instruction cache performs a burst transfer from the

memory subsystem to fill a cache line, and returns the instruction word to the Fetch stage.

The instruction cache line is selected by the replacement policy described in Section 2.2.1 "Cache Line Replacement Pol-

icy" on page 15.

2.2.7.3 Instruction Cache Coherency

The instruction cache does not maintain coherency with the data cache. Coherency between the instruction cache and the

data cache is the responsibility of software. However, the data cache snoops during instruction cache line fills.

Maintaining coherency is important when loading programs into memory, creating exception vector tables, or for self-modi-

fying code. In these circumstances, memory is updated with new instructions using store instructions which places the new

instructions in the data cache, but not in the instruction cache (thus the instruction cache may contain old instructions).

To maintain coherency, software must use the CACHE instruction to invalidate the modified range of program addresses in

the instruction cache. Because the data cache snoops during instruction cache line fills, it is not necessary to writeback the

data cache prior to invalidating the instruction cache. An instruction fetch to the newly loaded/modified program correctly

fetches the new instructions.

2.2.7.4 Instruction Cache Control

The cache-ability of instructions is controlled by three mechanisms:

•Config0[K0] field

•The CCA bits in the TLB

•The CACHE instruction

The Config0[K0] field contains a cache coherency attribute (CCA) setting to control the cache-ability of KSEG0 region. At

reset, this field defaults to CCA=3 (cacheable).

The CCA bits in the TLB entry control the cache-ability of the KUSEG, KSEG2, and KSEG3 regions. Each TLB entry spec-

ifies a CCA setting for the pages mapped by the TLB.

Instruction Cache line state

Bit31302928272625242322212019181716151413121110 9 8 7 6 5 4 3 2 1 0

Physical Address Tag LV

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The CACHE instruction manages the caches, including the ability to lock lines in the cache. Valid instruction cache opera-

tions are the following:

•Index Invalidate

•Index Load Tag

•Index Store Tag

•Hit Invalidate

•Fill

•Fetch and Lock

The effect of the CACHE instruction is visible to subsequent instructions not already in the pipeline. Instructions already in

the fetch and decode stages of the pipeline are not affected by a cache operation on the instruction cache.

2.2.8 Data Cache

The data cache is a 16KB four-way set associative write-back cache. Data cache accesses are distributed across the Exe-

cute and Cache pipeline stages.

A data cache line state consists the 20-bit physical address tag, a dirty bit (D), a coherency bit (S), a lock bit (L) and a valid

bit (V).

The data cache employs a read-allocate policy. Cache lines can be replaced on loads, but not on stores. Stores that miss in

the data cache are forwarded to the write buffer.

The data cache supports hit-under-miss for one outstanding miss. If an access misses in the data cache, the data cache

services the next access while the memory subsystem provides the data for the missed access. If the next access hits in

the data cache, the data is available immediately; otherwise the cache stalls the access until the first access completes.

2.2.8.1 Data Cache Initialization and Invalidation

Out of reset, all data cache lines are invalidated; thus the data cache is ready for use.

To invalidate the data cache in software, a loop of indexed writeback invalidate CACHE instructions for each of the lines in

the cache invalidates the cache.

li t0,(16*1024) # Cache size

li t1,32 # Line size

li t2,0x80000000 # First KSEG0 address

addu t3,t0,t2 # terminate address of loop

loop:

cache 1,0(t2) # Dcache indexed invalidate tag

addu t2,t1 # compute next address

bne t2,t3,loop

nop

2.2.8.2 Data Cache Line Fills

A data cache access is initiated in the Execute stage which allows a cache hit or miss indication and all exceptions to be

signaled early in the Cache stage. If the data address hits in the data cache, the data is available in the Cache stage. If the

data address misses in the data cache, and the address is cacheable, the data cache performs a burst fill to a cache line,

forwarding the critical word to the Cache stage.

The data cache line is selected by the replacement policy described in Section 2.2.1 "Cache Line Replacement Policy" on

page 15. If the line selected contains modified data (cache line is valid and has its dirty bit set by a store hit), then the cache

line is moved to a cast-out buffer, the cache line is filled from memory and the load request fulfilled, and then the cast-out

buffer is written to memory.

Data cache line state

Bit31302928272625242322212019181716151413121110 9 8 7 6 5 4 3 2 1 0

Physical Address Tag DSLV

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2.2.8.3 Data Cache Coherency

The data cache snoops coherent SBUS transactions to maintain data coherency with other SBUS masters (i.e. DMA). If a

coherent read transaction on the SBUS hits in the data cache, the data cache provides the data. If a coherent write transac-

tion on the SBUS hits in the data cache, the data cache updates its internal array with the data. If a coherent transaction

(read or write) misses in the data cache, the data cache array is unchanged by the transaction.

Loads and stores which hit in the data cache can bypass previous stores in cacheable regions. The read-allocate data

cache policy forwards store-misses to the write buffer. Subsequent loads and stores which hit in the data cache, and to a

different cache line address than store-misses, are fulfilled immediately (while store-misses may still be in the write buffer).

However, if a load address hits in a cache-line address of an item in the write buffer, the load is stalled until the write buffer

commits the corresponding store.

The data cache also maintains coherency with other caching masters. When a load is serviced from another caching mas-

ter, both caching masters set the shared bit for the affected cache line. Then if a store occurs to a data cache line with the

shared bit set, the cache line address is broadcast on the SBUS to invalidate cache lines in other caching masters that con-

tain the same address.

The data cache is single-ported; therefore transactions on the SBUS are prioritized over accesses by the core. However,

the data cache design prevents the SBUS from saturating the data cache indefinitely, which ensures that the core can make

forward progress.

When changing the CCA encoding in Config0[K0] or the TLB to a different CCA encoding, software must ensure that data

integrity is not compromised by first pushing modified (dirty) data to memory within the page. This is especially important

when changing from a coherent CCA encoding to a non-coherent CCA encoding.

2.2.8.4 Data Cache Control

The cache-ability of data accesses is controlled by four mechanisms:

•Config0[K0] field

•The CCA bits in the TLB

•The CACHE instruction

•The PREF instruction

The Config0[K0] field contains a cache coherency attribute (CCA) setting to control the cache-ability of KSEG0 region. At

reset, this field defaults to 011b, cacheable.

The CCA bits in the TLB entry control the cache-ability of the KUSEG, KSEG2, and KSEG3 regions. Each TLB entry spec-

ifies a CCA setting for the pages mapped by the TLB.

The CACHE instruction manages the caches; including the ability to lock lines in the cache. Valid data cache operations

are:

•Index Writeback Invalidate

•Index Load Tag

•Index Store Tag

•Hit Invalidate (unlocks)

•Hit Writeback and Invalidate

•Hit Writeback

•Fetch and Lock

The effect of the CACHE instruction is immediately visible to subsequent data accesses.

The PREF instruction places data into the data cache. The following prefetch hints are implemented:

•0x00 - Normal load

•0x04 - Streaming load

The streaming load hint directs the data be placed into way 0 of the data cache (even if the line is locked), thus permitting

transient data to be cached and non-transient data to remain in the cache for improved performance. Data cache streaming

support combined with the PREF instruction enhances multimedia processing.

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2.3 Write Buffer

The Au1 write buffer is depicted in Figure 2-3. All non-cacheable processor stores and data cache store-misses (the data

cache is a read-allocate policy) are routed through the write buffer.

Figure 2-3. Au1 Write Buffer

The write buffer is a 16-word deep first-in-first-out (FIFO) queue. All processor stores arrive first at the merge latch, where

merging and gathering decisions are performed, and then travel through the queue. The write buffer arbitrates for the SBUS

to perform consolidated transfers to the main memory.

A write buffer FIFO entry contains the address (word address), the data and associated byte masks (BM), and two control

bits. The four BM bits indicate which bytes within the word contain valid data. The two control bits are the Valid bit which

indicates if the entry is valid, and the Closed (C) bit. When a C bit is set, the write buffer initiates a request to the SBUS so

that it can transfer data to memory. The circumstances for which the C bit is set are described below.

The write buffer is capable of variable-length burst writes to memory. The length can vary from one word to eight words, and

is determined by the C bits in the write buffer. During each beat of the burst, the appropriate bytes to write are selected from

the corresponding byte masks. As each entry is written to memory, it is popped from the FIFO, advancing each entry in the

FIFO by one. In other words, entry 0 is always presented to the SBUS for writing.

When the write buffer has at least one empty entry, processor stores do not stall, thus improving processor performance.

The write buffer is disabled by setting Config0[WD] to 1. In this instance, all non-cacheable and data cache store-misses

stall until the write completes. The remaining description of the write buffer operation assumes Config0[WD] is 0. Out of

reset, Config0[WD] is 0.

SBUS

DataAddress

Merge Latch

CV35 0 BM31 0

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2.3.1 Merge Latch

All processor stores first arrive at the merge latch. Logic within the merge latch decides what action to take with the incom-

ing data.

1) The incoming address is the same word address as the merge latch address. This case is for Merging, which occurs

within the merge latch itself.

2) The incoming word address is sequentially adjacent to the merge latch word address (incoming address is merge latch

address + 4). This case is for Gathering. The merge latch contents are propagated to the FIFO with the C bit cleared

for this entry.

3) Neither 1 nor 2 is true. The merge latch contents are propagated to the FIFO with the C bit set for this entry.

If the merge latch contents are propagated to the FIFO, the incoming address and data are placed in the merge latch for

future comparisons. Furthermore, if the incoming address is the last word address of the maximum burst line size (the least

significant 5 bits are 0x1C), then the C bit is set.

2.3.2 Write Buffer Merging

Write buffer merging combines stores destined for the same word address. Merging places the incoming data into the

appropriate data byte(s) within the merge latch.

Write buffer merging is particularly useful for sequential, incremental address write operations, such as string operations.

With write buffer merging, the writes are merged into 32-bit writes which reduces the number of accesses to the memory

and increases the effective throughput to main memory.

This example demonstrates merging: these five byte writes occur in sequence:

0x00001000 = 0xAB

0x00001001 = 0xCD

0x00001002 = 0xDE

0x00001003 = 0xEF

0x00001002 = 0xBE

After the first four writes, the data in the merge latch contains 0xABCDDEEF. However, after the fifth write, the merge latch

data now contains 0xABCDBEEF.

So long as the incoming word address is the same as the merge latch word address, the data can change without a proces-

sor stall or access to memory.

Write buffer merging is controlled by the Config[NM] bit and the TLB[CCA] setting. When Config0[NM] is 1 or TLB[CCA] is

2, the merge latch does not perform merging. Conversely, Config0[NM] is 0 or TLB[CCA] is not 2 enables merging. Out of

reset, Config0[NM] is 0.

Note: Merging takes place only in the merge latch. As such, writes to an address which are in the FIFO (but not in the

merge latch) do not merge. In the example below, writes to 0x00001000 and 0x00001002 do not merge because

the intervening write to address 0x_0000_1005 is not in the same word address which caused 0x00001000 to

leave the merge latch.

0x00001000 = 0xAB

0x00001005 = 0xCD

0x00001002 = 0xDE

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2.3.3 Write Buffer Gathering

Write buffer gathering combines sequentially adjacent word addresses for burst transfers to the main memory. When a C bit

is set, all queue entries from zero (0) up to and including the entry with its C bit set (N) are written to main memory in a sin-

gle burst.

Write buffer gathering is particularly useful for sequential, incremental address store operations, such as string operations.

With write buffer gathering, the stores are combined into bursts up to 32-bytes (eight words) in length which reduces the

number of accesses to the memory and increases effective throughput.

Here is an example of an eight-word burst. The burst could result from code which sequentially writes words (optimized

memcpy(), for example). These eight word writes occur in sequence:

0x00001000

0x00001004

0x00001008

0x0000100C

0x00001010

0x00001014

0x00001018

0x0000101C

The entries corresponding to word addresses 0x00001000 through 0x00001018 have C bit set to zero. When address

0x0000101C arrives, its C bit is set. When the write buffer is granted the SBUS, it bursts all eight entries to main memory.

Here is an example of two-word burst. This burst may be typical of application software. These four word writes occur in

sequence:

0x00001000

0x00001004

0x0000100C

0x00001008

The C bit is cleared for the 0x00001000 entry and is set for the 0x00001004 entry. These two words are then burst to main

memory. The 0x0000100C entry also has its C bit set, and is written to memory. The 0x00001008 will reside in the merge

latch until displaced by a subsequent store.

2.3.4 Write Buffer Reads

When a read from memory is initiated, the read cache-line address (A35..A5) is compared against all cache-line addresses

in the write buffer. If the read cache-line address matches a write buffer cache-line address, the read is stalled. The write

buffer then flushes entries to memory until the read address no longer matches a write buffer cache-line address. The read

is then allowed to complete. The write buffer ensures data integrity by not allowing reads to bypass writes.

2.3.5 Write Buffer Coherency

Non-cacheable stores and/or data cache store-misses reside in the write buffer, possibly indefinitely. Furthermore, the write

buffer does not snoop SBUS transactions (e.g. integrated peripheral DMA engines). To ensure the write buffer contents are

committed to memory, a SYNC instruction must be issued.

Issuing a SYNC instruction prior to enabling each DMA transfer from memory buffers and/or structures is necessary. With-

out the SYNC, the DMA engine may retrieve incomplete buffers and/or structures (the remainder of which may be in the

write buffer).

Issuing a SYNC instruction after a store to an I/O region where stores have side effects is necessary. Without the SYNC

instruction, the store may not leave the write buffer to achieve the side effects (e.g., clearing an interrupt acknowledge bit).

Note that a read access does not guarantee a complete write buffer flush since the write buffer flushes as few entries as

necessary until the read address no longer matches an address in the write buffer.

24 AMD Alchemy™ Au1000™ Processor Data Book

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30360E

2.4 Virtual Memory

The Au1 implements a TLB-based virtual address translation unit which is compliant with the MIPS32 specification. This

scheme is similar to the R4000 TLB and CP0 implementation. The “MIPS32 Architecture For Programmers Volume III” con-

tains all the information relevant to a TLB-based virtual address translation unit.

The virtual address translation architecture is composed of a main 32-entry fully associative TLB array. To improve instruc-

tion fetch performance, a 4-entry fully associative instruction TLB is implemented. This miniature instruction TLB is fully

coherent with the main TLB array and is completely transparent to software.

Each TLB entry maps a 32-bit virtual address to a pair of 36-bit physical addresses. The page size of a TLB entry is vari-

able under software control, from 4 KB to 16 MB.

A TLB entry is described below.

The size of the page(s) that the TLB entry translates is determined by PageMask. The valid values for PageMask range

from 4 KB to 16 MB, according to Table 2-4.

The PageMask determines the number of significant bits in the 32-bit address generated by the program (either as a load/

store address or an instruction fetch address). The upper, significant bits of the program address are compared against the

upper, significant bits of VPN2. When an address match occurs, the even/odd PFN select bit of the program address

selects either PFN0 (even) or PFN1 (odd) as the upper bits of the resulting 36-bit physical address.

The TLB mechanism permits mapping a larger, 36-bit physical address space into the smaller 32-bit program address

space. The Au1 implements an internal 36-bit physical address SBUS which is then decoded by integrated peripherals, and

by chip-selects for external memories and peripherals.

The cache coherency attributes (CCA) of the physical page are controlled by the TLB entry. The valid values are described

in Table 2-3. In general, I/O spaces require a non-cacheable setting, whereas memory can utilize a cacheable setting.

Note: Physical addresses in which address bits [35:32] are non-zero must be mapped non-cached (CCA = 2).

The TLB array is managed completely by software. Software can implement a TLB replacement algorithm that is either ran-

dom (via the TLBWR instruction) or deterministic (via the TLBWI instruction). Hardware is available to segment the TLB via

the Wired register so different replacement strategies can be used for different areas of the TLB.

TLB Entry

Bit313029282726252423222120191817161514131211109876543210

PageMask 0 PageMask 0

EntryHi VPN2 0 ASID

EntryLo0 0 0 PFN0 C0 D0 V0 G

EntryLo1 0 0 PFN1 C1 D1 V1 G

Table 2-4. Values for Page Size and PageMask Register

Page Size PageMask Register Bits 28:13 PFN Select Bit

4 KB 0x00000000 0000000000000000 12

16 KB 0x00006000 0000000000000011 14

64 KB 0x0001E000 0000000000001111 16

256 KB 0x0007E000 0000000000111111 18

1 MB 0x001FE000 0000000011111111 20

4 MB 0x007FE000 0000001111111111 22

16 MB 0x01FFE000 0000111111111111 24

AMD Alchemy™ Au1000™ Processor Data Book 25

CPU 30360E

2.5 Exceptions

The Au1 core implements a MIPS32 compliant exception scheme. The scheme consists of the exception vector entry

points in both KSEG0 and KSEG1, and the exception code (ExcCode) encodings to determine the nature of the exception.

2.5.1 Exception Causes

The nature of an exception is reported in the Cause[ExcCode] field. The Au1 core can generate the following exceptions:

The Au1 core does not implement hardware floating-point. As a result, all floating-point instructions generate the Reserved

Instruction (RI) exception, which permits floating-point operations to be emulated in software.

In addition, the Au1 core does not recognize Soft Reset, Non-Maskable Interrupt (NMI), or Cache Error exception condi-

tions.

Table 2-5. Cause[ExcCode] Encodings

ExcCode Mnemonic Description

0 Int Interrupt

1 Mod TLB modification exception

2 TLBL TLB exception (load or instruction fetch)

3 TLBS TLB exception (store)

4 AdEL Address error exception (load or instruction fetch)

5 AdES Address error exception (store)

6 IBE Bus error exception (instruction fetch)

7 DBE Bus error exception (data reference: load or store)

8 Sys Syscall exception

9 Bp Breakpoint exception

10 RI Reserved instruction exception

11 CpU Coprocessor Unusable exception

12 Ov Arithmetic Overflow exception

13 Tr Trap exception

23 WATCH Reference to Watchpoint address

24 MCheck Machine Check (duplicate TLB entry)

26 AMD Alchemy™ Au1000™ Processor Data Book

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30360E

2.5.2 Interrupt Architecture

The Au1 core implements a MIPS32 compliant interrupt mechanism in which eight interrupt sources are presented to the

core. Each interrupt source is individually maskable to either enable or disable the core from detecting the interrupt. Inter-

rupts are generated by software, integrated interrupt controllers, performance counters and timers, as noted in Table 2-6.

All interrupt sources are equal in priority; that is, the interrupt sources are not prioritized in hardware. As a result, software

determines the relative priority of the interrupt sources. When Cause[ExcCode]=0, software must examine the Cause[IP]

bits to determine which interrupt source is requesting the interrupt.

For more information on Interrupt Controller 0 and 1 see Section 5.0 on page 81.

Table 2-6. CPU Interrupt Sources

Interrupt Source CP0 Cause Register Bit CP0 Status Register Bit

Software Interrupt 0 8 8

Software Interrupt 1 9 9

Interrupt Controller 0:

Request 0

Request 1

Interrupt Controller 1:

Request 0

Request 1

Performance Counters 14 14

Count/Compare 15 15

AMD Alchemy™ Au1000™ Processor Data Book 27

CPU 30360E

2.6 MIPS32™ Instruction Set

The Au1 core implements the instruction set defined in “MIPS32 Architecture For Programmers Volume II: The MIPS32

Instruction Set”. The floating-point instructions are not implemented in the Au1 core, but may be emulated in software.

The MIPS32 ISA is characterized as a combination of the R3000 user level instructions (MIPSII) and the R4000 memory

management and kernel mode instructions (32-bit MIPSIII).

2.6.1 CACHE Instruction

The CACHE instruction permits management of the Au1 instruction and data caches. The valid operations are listed in

Table 2-2 "Cache Operations" on page 17.

For data cache operations, the effect of the CACHE instruction is immediately visible to subsequent data accesses. How-

ever, for instruction cache operations, the effect of the CACHE instruction is not visible to subsequent instructions already in

the Au1 core pipeline. Therefore, care should be exercised if modifying instruction cache lines containing the CACHE and

subsequent instructions.

When issuing the CACHE instruction with indexed operations (Index Invalidate, Index Load Tag and Index Store Tag) the

format of the effective address is as follows:

The effective address base should be 0x80000000 (KSEG0) to avoid possible TLB exceptions, and place zeros in the

remainder of the effective address. The format correlates to a 16KB cache that is 4-way set associative with 128 sets and

32-byte line size.

Software must not use the Index Store Tag CACHE operation to change the Dirty, Lock and Shared state bits. To set the

Lock bit, software must use the Fetch and Lock CACHE operation.

The Index Load Tag and Index Store Tag CACHE operations utilize CP0 registers DTag, DData, ITag and IData. The format

of data for Index Tag operations is depicted in the description of these registers.

CACHE operations that require an effective address (i.e. not the Index operations) do not generate the Address Error

Exception or trigger data watchpoint exceptions.

2.6.2 PREF Instruction

The PREF instruction prefetches data into the data cache. Data is prefetched to improve algorithm performance by placing

the data in the cache in advance of its use, thus minimizing stalls due to data cache load misses. See also Section 2.2.8.4

"Data Cache Control" on page 20 for more on how to use PREF.

If the effective address computed by the PREF instruction does not translate in the TLB (i.e. the address would cause a

TLBL exception), no exception is generated and the cache is unchanged.

The Au1 core implements the following PREF instruction hints:

•0x00 - Normal load

•0x04 - Streaming load

A PREF instruction using any other hint value becomes a NOP for the Au1 core.

2.6.3 WAIT Instruction

The WAIT instruction places the Au1 core in one of two low power modes: IDLE0 and IDLE1. The low power mode is

encoded in the WAIT instruction bits 24:6 (implementation-dependent code). A value of 0 selects IDLE0, and the value 1

selects IDLE1. Other values are not supported and must not be used.

In the IDLE0 low power mode, the Au1 core stops clocks to all possible core units but continues to snoop the SBUS to

maintain data coherency.

In the IDLE1 low power mode, the Au1 core stops clocks to all possible core units, including the data cache, so data coher-

ency is no longer maintained.

CACHE Index Operation Address Decode

Bit31302928272625242322212019181716151413121110 9 8 7 6 5 4 3 2 1 0

0x8000 Way Set/Index Byte Select

28 AMD Alchemy™ Au1000™ Processor Data Book

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30360E

In either Idle mode, the general purpose registers and the CP0 registers are preserved, so that when Idle mode is exited by

an appropriate event, the Au1 core resumes processing instructions in exactly the same context as prior to entering Idle

mode.

To enter the low power mode, the WAIT instruction must be followed by at least four NOPs, and the entire instruction

sequence must be fetched from the instruction cache. More specifically, if the core fetches the WAIT and NOP instructions

from main memory, then the mechanisms for accessing memory will prevent the core from entering low power mode. This

is the recommended code sequence:

.global au1_wait

au1_wait:

la t0,au1_wait # obtain address of au1_wait

cache 0x14,0(t0) # fill icache with first 8 insns

cache 0x14,32(t0) # fill icache with next 8 insns

sync

nop

wait 0

nop

j ra

When the Au1 core is in Idle mode, the Count register increments at an unpredictable rate; therefore the Count/Compare

registers can not be used as the system timer tick when using the WAIT instruction to enter an Idle mode.

2.7 Coprocessor 0

Coprocessor 0 (CP0) is responsible for virtual memory, cache and system control.

The MIPS32 ISA provides for differentiation of the CP0 implementation. The Au1 core has a unique CP0 that is compliant

with MIPS32 specification.

The Au1 CP0 registers are listed in Table 2-7.

Table 2-7. Coprocessor 0 Register Definitions

Number Sel

Name Description

Compliance

(Note 1)

0 0 Index Pointer into TLB array Required

1 0 Random Pseudo-random TLB pointer Required

2 0 EntryLo0 Low half of TLB entry for even pages Required

3 0 EntryLo1 Low half of TLB entry of odd pages Required

4 0 Context Pointer to a page table entry Required

5 0 PageMask Variable page size select Required

6 0 Wired Number of locked TLB entries Required

7 0 Reserved Reserved

8 0 BadVAddr Bad virtual address Required

9 0 Count CPU cycle count Required

10 0 EntryHi High half of TLB entries Required

11 0 Compare CPU cycle count interrupt comparator Required

12 0 Status Status Required

13 0 Cause Reason for last exception Required

14 0 EPC Program Counter of last exception Required

15 0 PRId Processor ID and Revision Required

AMD Alchemy™ Au1000™ Processor Data Book 29

CPU 30360E

2.7.1 Index Register (CP0 Register 0, Select 0)

The Index register is required for TLB-based virtual address translation units.

16 0 Config Configuration Registers (aka Config0) Required

16 1 Config1 Configuration Register 1 Required

17 0 LLAddr Load Link Address Optional

18 0 WatchLo Data memory break point low bits Optional

18 1 IWatchLo Instruction fetch breakpoint low bits Optional

19 0 WatchHi Data memory break point high bits Optional

19 1 IWatchHi Instruction fetch breakpoint high bits Optional

20 0 Reserved Reserved

21 0 Reserved Reserved

22 0 Scratch Scratch register Au1

23 0 Debug EJTAG control register Optional

24 0 DEPC PC of EJTAG debug exception Optional

25 0 Reserved Reserved Au1 Reserved

25 1 Reserved Reserved Au1 Reserved

26 0 Reserved Reserved

27 0 Reserved Reserved

28 0 DTag Data cache tag value Au1

28 1 DData Data cache data value Au1

29 0 ITag Instruction cache tag value Au1

29 1 IData Instruction cache data value Au1

30 0 ErrorEPC Program counter at last error Required

31 0 DESave EJTAG debug exception save register Optional

Note 1. A compliance of “Required” denotes a register required by the MIPS32 architecture. “Optional” denotes an optional

to the Au1 core. “Reserved” denotes a register that is not implemented.

Index CP0 Register 0, Select 0

Bit31302928272625242322212019181716151413121110 9 8 7 6 5 4 3 2 1 0

P0 Index

Def.X00000000000000000000000000XXXXX

Bits Name Description R/W Default

31 P Probe Failure. R UNPRED

30:5 Reserved Reserved. Must always write zeros, always reads zeros R 0

4:0 Index TLB Index R/W UNPRED

Table 2-7. Coprocessor 0 Register Definitions (Continued)

Number Sel

Name Description

Compliance

(Note 1)

30 AMD Alchemy™ Au1000™ Processor Data Book

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30360E

2.7.2 Random Register (CP0 Register 1, Select 0)

The Random register is required for TLB-based virtual address translation units.

2.7.3 EntryLo0, EntryLo1 Register (CP0 Registers 2 and 3, Select 0)

The EntryLo0 and EntryLo1 registers are required for TLB-based virtual address translation units.

2.7.4 Context Register (CP0 Register 4, Select 0)

The Context register is required for TLB-based virtual address translation units.

2.7.5 PageMask Register (CP0 Register 5, Select 0)

The PageMask register is required for TLB-based virtual address translation units.

Random CP0 Register 1, Select 0

Bit31302928272625242322212019181716151413121110 9 8 7 6 5 4 3 2 1 0

0Random

Def.00000000000000000000000000011111

Bits Name Description R/W Default

31:5 Reserved Reserved. Must always write zeros, always reads zeros R 0

4:0 Random TLB Random Index R 31

EntryLo0, EntryLo1 CP0 Registers 2 and 3, Select 0

Bit31302928272625242322212019181716151413121110 9 8 7 6 5 4 3 2 1 0

0PFN CDVG

Def.0 0XXXXXXXXXXXXXXXXXXXXXXXXXXXXXX

Bits Name Description R/W Default

31:30 Reserved Reserved. Ignored on writes, returns zero on read R 0

29:6 PFN Page Frame Number. Corresponds to physical address bits 35..12. R/W UNPRED

5:3 C Cache coherency attribute of the page. See Table 2-3 "Cache Coher-

ency Attributes (CCA)" on page 17.

R/W UNPRED

2 D Dirty bit. R/W UNPRED

1 V Valid bit R/W UNPRED

0 G Global bit R/W UNPRED

Context CP0 Register 4, Select 0

Bit31302928272625242322212019181716151413121110 9 8 7 6 5 4 3 2 1 0

PTEBase BadVPN2 0

Def.XXXXXXXXXXXXXXXXXXXXXXXXXXXX00 0 0

Bits Name Description R/W Default

31:23 PTEBase Used by the operating system as a pointer into the current PTA array

in memory.

R/W UNPRED

22:4 BadVPN2 Contains virtual address bits 31..13 upon a TLB exception. R UNPRED

3:0 Reserved Reserved. R 0

PageMask CP0 Register 5, Select 0

Bit31302928272625242322212019181716151413121110 9 8 7 6 5 4 3 2 1 0

0Mask 0

Def.0 0 0XXXXXXXXXXXXXXXX0 00 0 0 0 00 00 0 0 0

AMD Alchemy™ Au1000™ Processor Data Book 31

CPU 30360E

2.7.6 Wired Register (CP0 Register 6, Select 0)

The Wired register is required for TLB-based virtual address translation units.

2.7.7 BadVAddr Register (CP0 Register 8, Select 0)

The BadVAddr register is required for TLB-based virtual address translation units.

2.7.8 Count Register (CP0 Register 9, Select 0)

The Count register is a required register for a constant rate timer. This counter increments 1:1 with the core frequency.

During IDLE0 or IDLE1 mode, the Count register increments at an unpredictable rate; therefore the Count/Compare regis-

ters can not be used as the system timer tick when using the WAIT instruction to enter an Idle mode.

During Sleep mode, this register will not increment.

Bits Name Description R/W Default

31:29 Reserved Reserved. Ignored on write, returns zero on read. R 0

28:13 Mask The Mask field is a bit mask in which a “1” bit indicates that the corre-

sponding bit of the virtual address should not participate in the TLB

match. See Table 2-4 "Values for Page Size and PageMask Register"

on page 24.

R/W UNPRED

12:0 Reserved Reserved. Ignored on write, returns zero on read. R 0

Wired CP0 Register 6, Select 0

Bit31302928272625242322212019181716151413121110 9 8 7 6 5 4 3 2 1 0

0Wired

Def.00000000000000000000000000000000

Bits Name Description R/W Default

31:5 Reserved Reserved. Ignored on write, returns zero on read. R 0

4:0 Wired TLB wired boundary R/W 0

BadVAddr CP0 Register 8, Select 0

Bit31302928272625242322212019181716151413121110 9 8 7 6 5 4 3 2 1 0

BadVAddr

Def.XXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXX

Bits Name Description R/W Default

31:0 BadVAddr Bad virtual address R UNPRED

Count CP0 Register 9, Select 0

Bit31302928272625242322212019181716151413121110 9 8 7 6 5 4 3 2 1 0

Count

Def.00000000000000000000000000000000

Bits Name Description R/W Default

31:0 Count Interval counter R/W 0

32 AMD Alchemy™ Au1000™ Processor Data Book

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30360E

2.7.9 EntryHi Register (CP0 Register 10, Select 0)

The Index register is required for TLB-based virtual address translation units.

2.7.10 Compare Register (CP0 Register 11, Select 0)

The Compare register is a required register for generating an interrupt from the constant rate timer.

2.7.11 Status Register (CP0 Register 12, Select 0)

The Status register is a required register for general control of the processor.

EntryHi CP0 Register 10, Select 0

Bit31302928272625242322212019181716151413121110 9 8 7 6 5 4 3 2 1 0

VPN2 0 ASID

Def.XXXXXXXXXXXXXXXXXXX0 00 0 0XXXXXXXX

Bits Name Description R/W Default

31:13 VPN2 Virtual address bits 31..13. R/W UNPRED

12:8 Reserved Reserved. Ignored on write, returns zero on read. R 0

7:0 ASID Address space identifier R/W UNPRED

Compare CP0 Register 11, Select 0

Bit31302928272625242322212019181716151413121110 9 8 7 6 5 4 3 2 1 0

Compare

Def.XXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXX

Bits Name Description R/W Default

31:0 Compare Interval counter compare value R/W UNPRED

Status CP0 Register 12, Select 0

Bit31302928272625242322212019181716151413121110 9 8 7 6 5 4 3 2 1 0

000CU0RP0RE 0 0 BEV 0 SR NMI 0 0 0IM00 0 UM 0 ERL EXL IE

Def.00000000010000000000000000000100

Bits Name Description R/W Default

31 CU3 This bit is zero. Coprocessor 3 is not implemented. R 0

30 CU2 This bit is zero. Coprocessor 2 is not implemented. R 0

29 CU1 This bit is zero. Coprocessor 1 is not implemented. R 0

28 CU0 Controls access to coprocessor 0. R/W 0

27 RP Reduced power. This bit has no effect. R/W 0

25 RE Reverse-endian. R/W 0

22 BEV Boot exception vectors. R/W 1

20 SR Soft reset. R/W 0

19 NMI Non-maskable interrupt R/W 0

15:8 IM Interrupt mask R/W 0

4 UM User-mode. R/W 0

3 R0 This bit is zero; Supervisor-mode not implemented R 0

2ERL Error Level R/W 1

1 EXL Exception Level R/W 0

0 IE Interrupt Enable R/W 0

AMD Alchemy™ Au1000™ Processor Data Book 33

CPU 30360E

2.7.12 Cause Register (CP0 Register 13, Select 0)

The Cause register is a required register for general exception processing.

2.7.13 Exception Program Counter (CP0 Register 14, Select 0)

The Exception Program Counter (EPC) register is a required register for general exception processing.

2.7.14 Processor Identification (CP0 Register 15, Select 0)

The PRId register is a required register for processor identification.

Cause CP0 Register 13, Select 0

Bit31302928272625242322212019181716151413121110 9 8 7 6 5 4 3 2 1 0

BD 0 CE 0 IV WP 0 IP 0 ExcCode 0

Def.00000000000000001000000000000000

Bits Name Description R/W Default

31 BD Exception in branch delay slot R 0

29:28 CE Coprocessor error R 0

23 IV Interrupt vector R/W 0

22 WP Watchpoint exception deferred R/W 0

15:10 IP[7:2] Hardware interrupts pending R 0x20

9:8 IP[1:0] Software interrupts pending R/W 0

6:2 ExcCode Exception Code R 0

EPC CP0 Register 14, Select 0

Bit31302928272625242322212019181716151413121110 9 8 7 6 5 4 3 2 1 0

EPC

Def.XXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXX

Bits Name Description R/W Default

31:0 EPC Exception Program Counter R/W UNPRED

PRId CP0 Register 15, Select 0

Bit31302928272625242322212019181716151413121110 9 8 7 6 5 4 3 2 1 0

Company Options Company ID Processor ID Revision

Def.00000000000000110000001000000000

Bits Name Description R/W Default

31:24 Company Options System-on-a-chip (SOC) identification:

0 Au1000

1 Au1500

2 Au1100

23:16 Company ID Company ID assigned by MIPS Technologies. AMD’s ID = 3. R 3

15:8 Processor Core ID Identifies the core revision:

0 Reserved

1 Au1 revision 1

2 Au1 revision 2

7:0 Revision Contains a manufacturing-specific revision level.

0 Silicon stepping DA; silicon revision 1.1

1 Silicon stepping HA; silicon revision 2.1

2 Silicon stepping HB; silicon revision 2.2

3 Silicon stepping HC; silicon revision 2.3

4 Silicon stepping HD; silicon revision 2.4

RSOC

Specific

34 AMD Alchemy™ Au1000™ Processor Data Book

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30360E

2.7.15 Configuration Register 0 (CP0 Register 16, Select 0)

The Config0 register is a required register for various processor configuration and capability.

2.7.16 Configuration Register 1 (CP0 Register 16, Select 1)

The Config1 register is a required register for various processor configuration and capability.

Config0 CP0 Register 16, Select 0

Bit31302928272625242322212019181716151413121110 9 8 7 6 5 4 3 2 1 0

MCT

DD CD UM WD NM SM OD 0 0 TM BE AT AR MT 0K0

Def.10000000000000001000000010000011

Bits Name Description R/W Default

31 M Denotes Config1 register available at select 1 R 1

30:26 CT Reserved. Must write 0. R/W 0

25 DD Reserved. Must write 0. R/W 0

24 CD Reserved. Must write 0. R/W 0

23 UM Reserved. Must write 0. R/W 0

22 WD Reserved. Must write 0. R/W 0

21 NM Reserved. Must write 0. R/W 0

20 SM Reserved. Must write 0. R/W 0

19 OD Reserved. Must write 0. R/W 0

16 TM Reserved. Must write 0. R/W 0

15 BE Indicates the endian mode. R 1

14:13 AT Architecture type is MIPS32. R 0

12:10 AR Architecture revision is Revision 1. R 0

9:7 MT MMU type is standard TLB. R 1

2:0 K0 KSEG0 is cacheable, coherent. R/W 3

Config1 CP0 Register 16, Select 1

Bit31302928272625242322212019181716151413121110 9 8 7 6 5 4 3 2 1 0

0 MMU Size - 1 IS IL IA DS DL DA C2 MD PC WR CA EP FP

Def.00111110011000110011000110001010

Bits Name Description R/W Default

30:25 MMU Size - 1 Number of entries in the TLB minus one. The TLB has 32 entries. R 31

24:22 IS Instruction cache sets per way is 128. R 1

21:19 IL Instruction cache line size is 32 bytes. R 4

18:16 IA Instruction cache associativity is 4-way. R 3

15:13 DS Data cache sets per way is 128. R 1

12:10 DL Data cache line size is 32 bytes. R 4

9:7 DA Data cache associativity is 4-way. R 3

6 C2 Coprocessor 2 is not implemented. R 0

5 MD Always returns zero on read. R 0

4 PC Performance Counter registers are not implemented. R 0

3 WR Watchpoint registers are implemented. R 1

2 CA Code compression is not implemented. R 0

1 EP EJTAG is implemented. R 1

0 FP FPU is not implemented. R 0

AMD Alchemy™ Au1000™ Processor Data Book 35

CPU 30360E

2.7.17 Load Linked Address Register (CP0 Register 17, Select 0)

The LLAddr register provides the physical address of the most recent Load Linked instruction.

2.7.18 Data WatchLo Register (CP0 Register 18, Select 0)

The WatchLo and WatchHi registers are the interface to the data watchpoint facility.

2.7.19 Instruction WatchLo Register (CP0 Register 18, Select 1)

The IWatchLo and IWatchHi registers are the interface to the instruction watchpoint facility.

LLAddr CP0 Register 17, Select 0

Bit31302928272625242322212019181716151413121110 9 8 7 6 5 4 3 2 1 0

LLAddr

Def.XXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXX

Bits Name Description R/W Default

31:0 LLAddr Load Linked Address R UNPRED

WatchLo CP0 Register 18, Select 0

Bit31302928272625242322212019181716151413121110 9 8 7 6 5 4 3 2 1 0

VAddr 0 R W

Def.XXXXXXXXXXXXXXXXXXXXXXXXXXXXX0 0 0

Bits Name Description R/W Default

31:3 VAddr The virtual address to match R/W UNPRED

1 R If this bit is a one, then watch exceptions are enabled for loads that

match the address.

R/W 0

0 W If this bit is a one, then watch exceptions are enabled for stores that

match the address.

R/W 0

IWatchLo CP0 Register 18, Select 1

Bit31302928272625242322212019181716151413121110 9 8 7 6 5 4 3 2 1 0

VAddr I 0 0

Def.XXXXXXXXXXXXXXXXXXXXXXXXXXXXX0 0 0

Bits Name Description R/W Default

31:3 VAddr The virtual address to match R/W UNPRED

2 I If this bit is a one, then watch exceptions are enabled for instruction

accesses that match the address.

R/W 0

36 AMD Alchemy™ Au1000™ Processor Data Book

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2.7.20 Data WatchHi Register (CP0 Register 19, Select 0)

The WatchLo and WatchHi registers are the interface to the data watchpoint facility.

2.7.21 Instruction WatchHi Register (CP0 Register 19, Select 1)

The IWatchLo and IWatchHi registers are the interface to the instruction watchpoint facility.

2.7.22 Scratch Register (CP0 Register 22, Select 0)

The Scratch register exists for the convenience of software. Upon a read, this register returns the value last written into it.

WatchHi CP0 Register 19, Select 0

Bit31302928272625242322212019181716151413121110 9 8 7 6 5 4 3 2 1 0

MG 0 ASID 0 Mask 0

Def.1X000000XXXXXXXX0000XXXXXXXXX000

Bits Name Description R/W Default

31 M Another pair of Watch registers is implemented at the next Select

index.

30 G If this bit is one, then the ASID field is ignored and any address that

matches causes a watch exception.

R UNPRED

23:16 ASID ASID value which is required to match that in the EntryHi register if

the G bit is zero in the WatchHi register.

R/W UNPRED

11:3 Mask Any bit in this field that is a one inhibits the corresponding address bit

from participating in the address match.

R/W UNPRED

IWatchHi CP0 Register 19, Select 1

Bit31302928272625242322212019181716151413121110 9 8 7 6 5 4 3 2 1 0

0G 0 ASID 0 Mask 0

Def.0X000000XXXXXXXX0000XXXXXXXXX000

Bits Name Description R/W Default

30 G If this bit is one, then the ASID field is ignored and any address that

matches causes a watch exception.

R UNPRED

23:16 ASID ASID value which is required to match that in the EntryHi register if

the G bit is zero in the WatchHi register.

R/W UNPRED

11:3 Mask Any bit in this field that is a one inhibits the corresponding address bit

from participating in the address match.

R/W UNPRED

Scratch CP0 Register 22, Select 0

Bit31302928272625242322212019181716151413121110 9 8 7 6 5 4 3 2 1 0

Scratch

Def.XXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXX

Bits Name Description R/W Default

31:0 Scratch This register is present for the convenience of software. R/W UNPRED

AMD Alchemy™ Au1000™ Processor Data Book 37

CPU 30360E

2.7.23 Debug Register (CP0 Register 23, Select 0)

The Debug register is part of the interface to the EJTAG facility.

2.7.24 DEPC Register (CP0 Register 24, Select 0)

The DEPC register is part of the interface to the EJTAG facility.

2.7.25 Data Cache Tag Register (CP0 Register 28, Select 0)

The DTag and DData registers are the interface to the data cache array. This cache interface is unique to the Au1.

Note: This register corresponds to the TagLo register in the MIPS32 ISA specification.

Debug CP0 Register 23, Select 0

Bit313029282726252423222120191817161514131211109876 5 43210

DBD DM 0 LSNM 0 001 DExcCode 0SSt 0 0DINT 0DBpDSS

Def.0 0 0 0 000000000000 1XXXXX000 0 0 0 0000

Bits Name Description R/W Default

31 DBD Debug exception in branch delay slot. R UNPRED

30 DM If this bit is a one, then in debug mode. R 0

28 LSNM Load/stores are performed in the normal fashion when in debug

mode.

R/W 0

17:15 001 EJTAG version 2.5 R 001

14:10 DExcCode Cause[ExcCode] for normal exceptions in debug mode. R UNPRED

8 SSt Enable single step mode R/W 0

5 DINT Last debug exception was asynchronous debug interrupt R 0

1 DBp Last debug exception was an SDBPP instruction R 0

0 DSS Last debug exception was a single step R 0

DEPC CP0 Register 24, Select 0

Bit31302928272625242322212019181716151413121110 9 8 7 6 5 4 3 2 1 0

DEPC

Def.XXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXX

Bits Name Description R/W Default

31:0 DEPC Debug exception program counter. R/W UNPRED

DTag CP0 Register 28, Select 0

Bit31302928272625242322212019181716151413121110 9 8 7 6 5 4 3 2 1 0

TAG MRU NMRU LRU 00DSLV

Def.XXXXXXXXXXXXXXXXXXXXXXXXXX00XXXX

Bits Name Description R/W Default

31:12 TAG TAG represents bits [31:12] of a physical memory address. Bits

[35:32] of the physical address are always zero.

R/W UNPRED

11:10 MRU Most recently used way. R/W UNPRED

9:8 NMRU Next most recently used way. R/W UNPRED

7:6 LRU Least recently used way. R/W UNPRED

3 D Cache line is dirty (modified). R/W UNPRED

2 S Cache line is shared (for data cache snoops). R/W UNPRED

1 L Locked. This bit is set by the user to prevent overwriting of the cache

line.

R/W UNPRED

0 V Cache line valid. R/W UNPRED

38 AMD Alchemy™ Au1000™ Processor Data Book

CPU

30360E

2.7.26 Data Cache Data Register (CP0 Register 28, Select 1)

The DTag and DData registers are the interface to the data cache array.

Note: This register corresponds to the DataLo register in the MIPS32 ISA specification.

2.7.27 Instruction Cache Tag Register (CP0 Register 29, Select 0)

The ITag and IData registers are the interface to the instruction cache array. This cache interface is unique to the Au1.

Note: This register corresponds to the TagHi register in the MIPS32 ISA specification.

DData CP0 Register 28, Select 1

Bit31302928272625242322212019181716151413121110 9 8 7 6 5 4 3 2 1 0

Data

Def.XXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXX

Bits Name Description R/W Default

31:0 Data Data from the data cache line. R UNPRED

ITag CP0 Register 29, Select 0

Bit31302928272625242322212019181716151413121110 9 8 7 6 5 4 3 2 1 0

TAG MRU NMRU LRU 0LV

Def.XXXXXXXXXXXXXXXXXXXXXXXXXX000 0XX

Bits Name Description R/W Default

31:12 TAG TAG represents bits [31:12] of a physical memory address. Bits

[35:32] of the physical address are always zero.

R/W UNPRED

11:10 MRU Most recently used way. R/W UNPRED

9:8 NMRU Next most recently used way. R/W UNPRED

7:6 LRU Least recently used way. R/W UNPRED

1 L Locked. This bit is set by the user to prevent overwriting of the cache

line.

R/W UNPRED

0 V Cache line valid. R/W UNPRED

AMD Alchemy™ Au1000™ Processor Data Book 39

CPU 30360E

2.7.28 Instruction Cache Data Register (CP0 Register 29, Select 1)

The ITag and IData registers are the interface to the instruction cache array.

Note: This register corresponds to the DataHi register in the MIPS32 ISA specification.

2.7.29 ErrorEPC Register (CP0 Register 30, Select 0)

The ErrorEPC register is a required register for exception processing.

2.7.30 DESAVE Register (CP0 Register 31, Select 0)

The DESAVE register is part of the interface to the EJTAG facility.

IData CP0 Register 29, Select 1

Bit31302928272625242322212019181716151413121110 9 8 7 6 5 4 3 2 1 0

Data

Def.XXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXX

Bits Name Description R/W Default

31:0 Data Data from the instruction cache line. R UNPRED

ErrorEPC CP0 Register 30, Select 0

Bit31302928272625242322212019181716151413121110 9 8 7 6 5 4 3 2 1 0

ErrorEPC

Def.XXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXX

Bits Name Description R/W Default

31:0 ErrorEPC Error Exception Program Counter R/W UNPRED

DESAVE CP0 Register 31, Select 0

Bit31302928272625242322212019181716151413121110 9 8 7 6 5 4 3 2 1 0

DESAVE

Def.XXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXX

Bits Name Description R/W Default

31:0 DESAVE Debug save scratch register, for debug handlers. R/W UNPRED

40 AMD Alchemy™ Au1000™ Processor Data Book

CPU

30360E

2.8 System Bus (SBUS)

The Au1 core communicates with memories and peripherals via the System Bus (SBUS). The SBUS is a 36-bit physical

address and 32-bit data bus which is internal to the Au1000 processor. The SBUS is the coherency point within the Au1000

processor.

2.8.1 SBUS Arbitration

The SBUS supports multiple masters—the Au1 core and peripheral DMA engines. The SBUS is granted to the masters in a

least-recently-used/fair scheme. This scheme prevents two or more masters from consuming the entire SBUS bandwidth,

while permitting low latency access to the SBUS for masters which request the bus infrequently (such as peripherals).

•The SBUS requestors in the Au1000 processor are:

•Au1 core

•Ethernet MAC controller (2)

•USB Host controller

•IrDA controller

•DMA controller

The Au1 presents a single request to the SBUS arbiter for the three possible requestors: the data cache, the instruction

cache and the write buffer. The data cache has the highest priority and the write buffer the lowest priority among the three

requests. However, the write buffer priority becomes the highest when the data cache requests a load to an address in the

write buffer to allow the write buffer to empty prior to fulfilling the data cache load.

The SBUS arbiter has four bus arbitration slots for handling the SBUS masters:

•Slot 0: Au1 core (data cache, instruction cache, write buffer)

•Slot 1: Ethernet MAC controllers

•Slot 2: DMA controller

•Slot 3: USB host controller and IrDA controller

The arbitration scheme for the SBUS is round-robin; that is, each bus master slot has an equal opportunity to obtain access

to the SBUS. For a particular SBUS master X, if no other SBUS masters request the bus, then bus master X immediately

wins the SBUS. By contrast, if all other SBUS masters request the bus, then bus master X must wait for three other SBUS

master slots to transfer before it wins the SBUS, as shown in Figure 2-4 on page 40.

Figure 2-4. SBUS Arbitration

When a SBUS master wins arbitration of the SBUS, it performs transfers to/from the integrated peripherals, SDRAM, or the

Static bus.

A B C X

Req A

Req B

Req C

Req X

SBUS

AMD Alchemy™ Au1000™ Processor Data Book 41

CPU 30360E

2.8.2 SBUS Coherency Model

The SBUS is the coherency point within the Au1000 processor. An SBUS master (i.e. Au1 core or peripheral DMA engine)

marks each SBUS transaction as either coherent or non-coherent. SBUS transactions marked as coherent are then

snooped by all caching masters (i.e. Au1 data cache). An SBUS transaction that is marked non-coherent is not snooped by

caching masters.

The Au1 core is a coherent, caching master. The Au1 data cache snoops SBUS transactions; if a read transaction hits in

the data cache then the data cache provides the data, if a write transaction hits in the data cache then the data cache array

is updated with the new data.

The integrated peripherals (with DMA engines) can be configured for coherent or non-coherent operation. The ‘C’ bit in the

peripheral/module enable register directs whether peripheral SBUS transactions are to be marked coherent or non-coher-

ent. If a peripheral is configured for coherent operation, then it is not necessary to writeback and invalidate Au1 data cache

lines which hit in the memory buffers used by DMA engines. If, on the other hand, the peripheral is configured for non-

coherent operation, then software must ensure that memory buffers used by the DMA engines are not in the data cache

(else the data cache and/or the memory buffer may contain old, stale data).

The decision to use, or not use, coherent SBUS transactions is left to the application. However, peripheral device drivers

using coherent SBUS transactions will perform better than drivers not using coherent SBUS transactions since the need to

writeback the data cache is eliminated.

2.9 EJTAG

EJTAG is supported per the MIPS EJTAG Rev. 2.5 specification. EJTAG provides for CPU and board level bring-up and

debug.

42 AMD Alchemy™ Au1000™ Processor Data Book

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30360E

AMD Alchemy™ Au1000™ Processor Data Book 43

Memory Controllers 30360E

3.0Memory Controllers

The Au1000 processor contains two memory controllers, one for SDRAM and one for static devices.

The SDRAM controller supports SDRAM, SMROM, and Sync Flash.

The static device controller supports SRAM, Flash, ROM, page mode ROM, PCMCIA/Compact Flash devices, and an

external LCD controller interface.

Both memory controllers support software configurable memory address spaces. This allows designers to keep memory

regions contiguous. For example, a system with 4 MB initially installed would locate the memory at physical address 0. Nor-

mally, adding 16 MB would create a 12 MB gap in the memory map. With the address configuration options in the Au1000

the 4 MB can be relocated to start at 16 MB, and the new memory can be located at 0 to allow a 20 MB contiguous memory

pool.

All registers in the Memory Controller block are located off of the base address shown in Table 3-1.

The system designer has the choice of booting from 32-bit Flash, 16-bit Flash, 32-bit SMROM, and 32-bit SyncFlash. The

ROMSEL and ROMSIZE configuration is discussed in more detail in Section 8.3 "Boot" on page 197. Table 8-1 "ROMSEL

and ROMSIZE Boot Device" on page 197 shows how the state of ROMSEL and ROMSIZE determines where the processor

boots from.

Table 3-1. Memory Controller Block Base Address

Name Physical Base Address KSEG1 Base Address

mem 0x0 1400 0000 0xB400 0000

44 AMD Alchemy™ Au1000™ Processor Data Book

SDRAM Memory Controller

30360E

3.1 SDRAM Memory Controller

The SDRAM memory controller of the Au1000 processor is designed for glueless interface to one, two, or three ranks of

SDRAM or SMROM. SDRAM and SyncFlash are run at 1/2 the internal System Bus (SBUS) speed. The SBUS defaults to

1/2 the processor clock speed so that SDRAM or SyncFlash will run at 99 MHz with a 396 MHz Au1000. SMROM operates

at 1/4 the speed of the SBUS. The SBUS divider is programmable, see Section 7.4.3 "Device Power Management - Sleep"

on page 190 for more information.

The SDRAM interface supports three chip selects (SDCS[2:0]#), corresponding to three ranks of SDRAM. Each chip select

can be configured to support either SDRAM or SMROM. In addition, chip select 0 can be configured for SyncFlash (no

other chip selects can be used to support SyncFlash). For chip selects configured as SDRAM or SyncFlash (on chip select

0) the controller keeps one row open for up to four banks per chip select allowing fast accesses and reducing the need to

issue precharge cycles.

Note: The SDRAM memory controller supports a maximum of two loads per chip select.

When RESETIN# is negated, code is fetched from SMROM/SyncFlash if SMROM/SyncFlash boot is selected. When using

SMROM or SyncFlash for boot, the SMROMCKE signal should be used for the SMROM/SyncFlash CKE. If SMROM or

SyncFlash are being used (but not for boot), SDCKE should be used for the clock enable.

After boot internal configuration registers can be written to enable SDRAM chip selects. When a chip select is enabled the

SDCKE is driven asserted and clocks are started. Software must wait 10 µs for the SDRAM clock to stabilize before any

device specific initialization steps.

All SDRAM/SMROM ranks must be 32 bits wide. Support is included for SDRAM with 2 or 4 banks, 11 to 13 row address

bits, and 7 to 11 column address bits. It is also possible to send explicit commands to the SDRAM, under software control,

for diagnostic, initialization, or power management purposes.

SDRAM clocks keep running during a runtime reset to allow any transaction in progress to complete. This avoids the possi-

bility of bus contention when the part is brought out of reset.

Note that the SDRAM controller assumes the following external SDRAM configuration:

•Burst Length = 8

•Addressing Mode = Sequential

•Write Mode = Burst Read and Write

AMD Alchemy™ Au1000™ Processor Data Book 45

SDRAM Memory Controller 30360E

3.1.1 SDRAM Controller Programming Model

The SDRAM controller contains a number of registers which configure the operation of the interface. All registers in the

SDRAM controller block are located off of the base address shown in Table 3-1 "Memory Controller Block Base Address"

on page 43. Table 3-2 shows the memory map of the register block.

3.1.2 SDRAM Registers

Each chip select is configured by two registers, a mode register and an address configuration register.

3.1.2.1 Chip Select Mode Configuration Registers

The format and reset values of the chip select mode configuration registers is shown in the following figure. The timing

parameters (Tcl, Tcrd, Trp, Twr, Tmrd, and Tras) correspond directly to times shown in the SDRAM timing diagrams. Times

are measured in SDRAM/SMROM clock cycles.

The default values for chip select zero correspond to values for SMROM operation. Chip select 1 and 2 are configured with

the slowest timing values at reset.

Reserved fields should be written as zeros and ignored on read to preserve compatibility with future versions of the prod-

uct.

Table 3-2. SDRAM Configuration Registers

Offset (Note 1)

Note 1. See Table 3-1 "Memory Controller Block Base Address" on page 43 for base address.

0x0000 mem_sdmode0 SDRAM chip select n (SDCSn#) mode configuration register (tim-

ing and functionality)

0x0004 mem_sdmode1

0x0008 mem_sdmode2

0x000C mem_sdaddr0 SDCSn# address configuration and enable

0x0010 mem_sdaddr1

0x0014 mem_sdaddr2

0x0018 mem_sdrefcfg Refresh Configuration and Timing

0x001C mem_sdprecmd Issue PRECHARGE to all enabled SDRAM chip selects

0x0020 mem_sdautoref Issue AUTO REFRESH to all enabled SDRAM chip selects

0x0024 mem_sdwrmd0 Write data to SDCSn# SDRAM mode configuration register

0x0028 mem_sdwrmd1

0x002C mem_sdwrmd2

0x0030 mem_sdsleep Force SDRAM into self refresh mode

0x0034 mem_sdsmcke Toggle SMROMCKE pin

mem_sdmode0 - CS0 Mode Configuration Offset = 0x0000

Bit31302928272625242322212019181716151413121110 9 8 7 6 5 4 3 2 1 0

SF F SR BS RS CS Tras Tmrd Twr Trp Trcd Tcl

Def.00000000001010000111111111101100

mem_sdmode1 - CS1 Mode Configuration Offset = 0x0004

mem_sdmode2 - CS2 Mode Configuration Offset = 0x0008

Bit31302928272625242322212019181716151413121110 9 8 7 6 5 4 3 2 1 0

FSRBS RS CS Tras Tmrd Twr Trp Trcd Tcl

Def.00000000000101001111111111111111

46 AMD Alchemy™ Au1000™ Processor Data Book

SDRAM Memory Controller

30360E

Bits Name Description R/W Default

31:24 — Reserved. Should be cleared. R 0

23 SF Selects SyncFlash operation. SyncFlash is available only on SDCS0#. For

other chip selects, this bit is reserved and should be cleared.

0 SyncFlash is not being used.

1 SyncFlash is being used.

Note: SyncFlash support is available starting with silicon revision 2.3, also

known as silicon stepping ‘HC’. For silicon revisions 2.2 and earlier, this bit is

reserved and should be cleared.

R/W 0

22 F Setting the F bit allows the SDRAM controller to assume that no caching

master except the core will access this memory space. This allows accesses

to begin sooner.

Note that the CPU core is the only possible caching master, so it is safe for

the system designer to set this bit.

R/W 0

21 SR Chip select operating mode

0 SDRAM/SyncFlash Operation

1 SMROM Operation

R/W See above

20 BS Select Number of Banks

0 Chip select controls 2-bank SDRAM

1 Chip select controls 4-bank SDRAM

Note: This bit must be cleared for SMROM support.

R/W See above

19:18 RS This field sets the number of bits in the row address as shown below:

RS Row Address Size

00 11

01 12

10 13

11 Reserved

R/W See above

17:15 CS This field sets the number of bits in the column address as shown below:

CS Column Size

000 7

001 8

010 9

011 10

100 11

All other values are reserved.

R/W See above

14:11 Tras This field designates the minimum delay from a activate to a precharge com-

mand.

(Tras + 1) is the actual number of clock cycles.

R/W 15

10:9 Tmrd This field sets the required delay from an external load of the SDRAM mode

(Tmrd + 1) is the actual number of clock cycles.

R/W 3

8:7 Twr The Twr field sets the write recovery time. This is the last data for a write to a

precharge. This field is sometimes referred to a Tdpl.

(Twr + 1) is the actual number of clock cycles.

R/W 3

6:5 Trp This field sets the time from precharge to the next activate command.

(Trp + 1) is the actual number of clock cycles.

R/W 3

4:3 Trcd This field sets the RAS to CAS delay.

(Trcd + 1) is the actual number of clock cycles.

R/W See Above

2:0 Tcl This field sets the minimum CAS latency timing. This is the time from CAS to

DATA on reads.

(Tcl + 1) is the actual number of clock cycles.

R/W See Above

AMD Alchemy™ Au1000™ Processor Data Book 47

SDRAM Memory Controller 30360E

3.1.2.2 SDRAM Chip Select Address Configuration Registers (mem_sdaddrn)

The SDRAM chip-select address configuration registers (mem_sdaddrn) assign an address range for each chip select. As

shown below, each register contains a base address, an address comparison mask, and an enable bit.

Once enabled (E bit set), a chip select is asserted when the following condition is met:

(phys_addr & addr_mask) == base_addr

where

phys_addr: 32-bit physical address output on the internal SBUS (from the TLB for memory-mapped regions) (Bits

[35:32] of the physical address are zeros.)

addr_mask: address comparison mask taken from CSMASK

base_addr: chip select base address taken from CSBA

Chip select regions must be programmed so that each chip select occupies a unique area of the physical address space.

Programming overlapping chip select regions results in undefined operation.

mem_sdaddr0 - SDCS0# Address Configuration Offset = 0x000C

Bit31302928272625242322212019181716151413121110 9 8 7 6 5 4 3 2 1 0

E CSBA CSMASK

Def.00000000000Rs00011111111111111111

mem_sdaddr1 - SDCS1# Address Configuration

mem_sdaddr2 - SDCS2# Address Configuration

Offset = 0x0010

Offset = 0x0014

Bit31302928272625242322212019181716151413121110 9 8 7 6 5 4 3 2 1 0

E CSBA CSMASK

Def.00000000000011111111111111111111

Bits Name Description R/W Default

31:21 — Reserved. Should be cleared. R 0

20 E Enable.

0 Chip select is disabled.

1 Chip select is enabled.

R/W 0, except for

mem_sdaddr0

(Note 1)

Note 1. The E bits for the chip selects SDCS1# and SDCS2# are automatically cleared (disabled) coming out of a runtime or hardware

reset. For SDCS0, however, the reset value of the E bit depends on ROMSEL and ROMSIZE: SDCS0#’s E bit is set when the

ROMSEL and ROMSIZE pins indicate that the SMROM/SyncFlash should be used for the boot vector (ROMSEL==1, ROM-

SIZE==0). See also Section 8.3 "Boot" on page 197.

19:10 CSBA Chip select base address.

Specifies bits 31:22 of the physical base address for this chip

select. (The lower bits of the base address are zero.)

R/W 0x3FF, except for

mem_sdaddr0 where

the default value is

0x7F.

9:0 CSMASK Chip select address mask.

Specifies which bits of CSBA are used to decode this chip select.

R/W 0x3FF

48 AMD Alchemy™ Au1000™ Processor Data Book

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30360E

3.1.2.3 Refresh Configuration Register

The refresh configuration register sets the timing of SDRAM refresh for all chip selects. Since the timing for these signals

apply to all chip selects, if different types of SDRAM is used the worst case timing must be applied. The format of the

refresh configuration register is as follows:

3.1.2.4 Precharge All Command Register

Writing any value to the mem_sdprecmd register issues a precharge all command to all enabled SDRAM chip selects.

This can be used for initialization sequences that require certain operations to be performed in a deterministic order.

Reading from the mem_sdprecmd register is unpredictable.

mem_sdrefcfg - Refresh Configuration Offset = 0x0018

Bit31302928272625242322212019181716151413121110 9 8 7 6 5 4 3 2 1 0

Tr c Tr p r E R I

Def.11111101111111111111111111111111

Bits Name Description R/W Default

31:28 Trc The Trc field specifies the minimum time from the start of an auto refresh

cycle to an activate command for all SDRAM chip selects.

(Trc + 1) is the actual number of clock cycles.

R/W 0xf

27:26 Trpm This field specifies the minimum time from a precharge to the start of a

refresh cycle for all SDRAM chip selects. This is used because a precharge

all command is automatically initiated before an auto refresh command. This

value should be programmed with the worst case Trp from the

sdr_csmoden registers.

(Trpm + 1) is the actual number of clock cycles.

R/W 3

25 E When this bit is set, refresh is enabled for all chip selects configured as

SDRAM.

R/W 0

24:0 RI Refresh Interval - This field specifies the maximum refresh interval in SBUS

clocks for all SDRAM ranks.

The refresh interval is for each individual refresh so for a system with a row

address size of 12 (4096 rows) and memory with a refresh time of 64 ms (all

rows), the individual refresh interval will be 15.7 µs (64 ms/4096). With a

SBUS clock of 198 MHz, the RI value should be 0xC24 (15.7 µs / (1/198

MHz).

R/W 0x1FFFFFF

mem_sdprecmd - Precharge All Command Reg Offset = 0x001C

Bit31302928272625242322212019181716151413121110 9 8 7 6 5 4 3 2 1 0

Def.XXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXX

Bits Name Description R/W Default

31:0 PA Writing any value to PA will cause a precharge command to be issued to all

enabled SDRAM chip selects.

W UNPRED

AMD Alchemy™ Au1000™ Processor Data Book 49

SDRAM Memory Controller 30360E

3.1.2.5 Auto Refresh Command Register

Writing to the mem_sdautoref register performs an auto refresh command on all enabled SDRAM chip selects. This can

be used for initialization sequences that require specific operations to be performed in a deterministic order. To insure future

compatibility the value written should always be zero.

Reading from the mem_sdautoref register will return the current value of the refresh timer.

3.1.2.6 External SDRAM Mode Register Access

The mem_sdwrmd0, mem_sdwrmd1, and mem_sdwrmd2 command registers allow software to directly write to the

mode registers in SDRAM connected to each chip select. This can be used in initialization sequences that require certain

operations be performed in a deterministic order.

3.1.2.7 SDRAM Sleep/Self Refresh Command Register

Writing any value to this register performs sends a self refresh command on all enabled SDRAM chip selects. This com-

mand can be used for the SDRAM power-down sequence which requires specific commands to be performed in a deter-

ministic order.

After performing self refresh the SDRAM controller will hold SDCKE low and wait until a Sleep exit sequence or reset is per-

formed. For this reason nothing should access the SDRAM after this command has been issued.

mem_sdautoref - Auto Refresh Command Offset = 0x0020

Bit31302928272625242322212019181716151413121110 9 8 7 6 5 4 3 2 1 0

Def.XXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXX

Bits Name Description R/W Default

31:0 AR Writing a value to AR causes an auto refresh command to be issued to all

enabled SDRAM chip selects.

R/W UNPRED

mem_sdwrmd0 - Write CS0 SDRAM Mode Offset = 0x0024

mem_sdwrmd1 - Write CS1 SDRAM Mode Offset = 0x0028

mem_sdwrmd2 - Write CS2 SDRAM Mode Offset = 0x002C

Bit31302928272625242322212019181716151413121110 9 8 7 6 5 4 3 2 1 0

BA WM

Def.XXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXX

Bits Name Description R/W Default

31:30 BA[1:0] Bank address. These bits are reflected on the SDBA[1:0] signals. They can

be used to write to the extended mode register (for synchronous Flash and

battery RAM, for example). These bits must be cleared otherwise.

W UNPRED

29:0 WM The value written to this register is written to the external SDRAM mode reg-

ister for the corresponding chip select.

W UNPRED

mem_sdsleep -SDRAM Sleep Offset = 0x0030

Bit31302928272625242322212019181716151131211109876543210

Def.XXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXX

Bits Name Description R/W Default

31:0 SL Writing any value to SL will issue a self refresh command on all enabled chip

selects.

W UNPRED

50 AMD Alchemy™ Au1000™ Processor Data Book

SDRAM Memory Controller

30360E

3.1.2.8 SMROMCKE Toggle Register

Writing to this register causes the state of the SMROMCKE signal to change. SMROMCKE will default to high when booting

from SMROM or Sync Flash. This is used during power-up configuration to change the SMROM burst size from 4 to 8

beats. This command register does not affect the SDRAM SDCKE signal.

3.1.3 SDRAM Timing

The following figures show examples of typical read, typical write and refresh timing.

Figure 3-1. SDRAM Typical Read Timing

mem_sdsmcke -SMROMCKE Toggle Offset = 0x0034

Bit31302928272625242322212019181716151413121110 9 8 7 6 5 4 3 2 1 0

Def.XXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXX

Bits Name Description R/W Default

31:0 ST Writing to ST (regardless of the value written) inverts the current state of

SMROMCKE.

W UNPRED

row col (a) col (b) row (c) col (c) row (d)

a1 b1 b2 c1 c2 c3 c4

ACTIVATE READREAD PRECHARGE

ACTIVATE

READ

SDCLK[n]

SDCKE

SDCS[n]#

SDRAS#

SDCAS#

SDWE#

SDBA[1:0]

SDA[12:0]

SDQM#

SDD[31:0]

(a/b)

Tr a s

Trcd

ACTIVATE

Tr p

Tcl

(1 beat) (2 beat) (4 beat)

The above timing represents the following:

1) Tras = 4 (5 SDRAM clock cycles)

2) Trp = 0 (1 SDRAM clock cycles)

3) Trcd = 1 (2 SDRAM clock cycles)

4) Tcl = 1 (2 SDRAM clock cycles)

5) Tmrd = 0 (2 SDRAM clock cycles)

The above timing is presented to concisely display the different SDRAM timing parameters. The functional bus behavior

may differ from that displayed.

Tmrd

Mode

Set

AMD Alchemy™ Au1000™ Processor Data Book 51

SDRAM Memory Controller 30360E

Figure 3-2. SDRAM Typical Write Timing

Figure 3-3. SDRAM Refresh Timing

row col (a) col (b) row (c) col (c) row (d)

a1 b1 b2 c1 c2

ACTIVATE WRITE

(1 beat)

WRITE

(2 beat)

ACTIVATE WRITE

(2 beat)

PRECHARGE

ACTIVATE

SDCLK[n]

SDCKE

SDCS[n]#

SDRAS#

SDCAS#

SDWE#

SDBA[1:0]

SDA[12:0]

SDQM#

Tra s

Tr c d

Tw r

Tr p

Mode

Tmrd

Set

The above timing represents the following:

1) Tras = 4 (5 SDRAM clock cycles)

2) Trp = 0 (1 SDRAM clock cycles)

3) Trcd = 1 (2 SDRAM clock cycles)

4) Tmrd = 0 (1 SDRAM clock cycles)

The above timing is presented to concisely display the different SDRAM timing parameters. The functional bus behavior

may differ from that displayed.

(a/b)

SDD[31:0]

SDCLK[2:0]

SDCKE

SDCS[2:0]#

CMD auto refresh activate

precharge all

Tr c

Tr p m

This example assumes that all SDCLK ranks ([2:0]) are enabled.

The above timing represents the following:

1) Trpm = 3 (4 SDRAM clock cycles)

2) Trc = 3 (4 SDRAM clock cycles)

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3.1.4 SDRAM Hardware Considerations

Table 3-3 shows the signals associated with the SDRAM interface.

Table 3-3. SDRAM Signals

Signal

Input/

Output Description

SDA[12:0] O Address Outputs. A0-A12 are driven during the ACTIVE command (row-address A0-

A12) and READ/WRITE command to select one location out of the memory array in the

respective bank. The address outputs also provide the opcode during a LOAD MODE

SDBA[1:0] O Bank Address Outputs. SDBA1 and SDBA0 define to which bank the ACTIVE, READ,

WRITE or PRECHARGE command is being applied. The SDBA signal values are pro-

grammed in mem_sdwrmdn[BA].

SDD[31:0] IO SDRAM data bus

SDQM[3:0]# O Input/Output Mask. SDQM# is a mask signal for write accesses and an output enable

signal for read accesses. SDQM0# masks SDD[7:0], SDQM1# masks SDD[15:8],

SDQM2# masks SDD[23:16], SDQM3# masks SDD[31:24].

SDRAS# O Command Outputs. SDRAS#, SDCAS# and SDWE# (along with SDCSn#) define the

command being sent to the SDRAM rank.

SDCAS# O

SDWE# O

SDCLK[2:0] O Clock output corresponding to each of the three chip selects. Clock speed is 1/2 SBUS

frequency when corresponding SDCSn# is set to SDRAM or SyncFlash, 1/4 SBUS

frequency when corresponding SDCSn# is set to SMROM.

SDCS[2:0]# O Programmable chip selects (3 ranks).

SDCKE O Clock enable for SDRAM.

SMROMCKE O Synchronous Mask ROM Clock Enable. This signal must be pulled high if the system

is booting from SMROM.

Muxed with GPIO[6]. If ROMSEL and ROMSIZE are configured to boot from Synchro-

nous Mask ROM, SMROMCKE will control the pin out of reset, else GPIO[6] will con-

trol the pin out of reset.

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Static Bus Controller 30360E

3.2 Static Bus Controller

The static bus controller provides a general purpose interface to a variety of external peripherals and memory devices.

Each of the four static bus chip selects may be programmed to support standard Flash memory, ROM, Page Mode Flash/

ROM, SRAM, I/O peripherals, PCMCIA/Compact Flash devices, or an LCD controller. Because of the similarity of Compact

Flash and PCMCIA, references to PCMCIA should be taken as applicable to Compact Flash except where noted.

The Au1000 processor allows control of different device types by reconfiguring what control signals chip select n manages

based on how the device type field (DTY) is encoded in the mem_stcfgn register. All device types use the same address

and data bus signals, RAD[31:0] and RD[31:0].

Descriptions of all device types are provided in Section 3.2.2 "Static RAM, I/O Device and Flash Device Types" on page 60,

Section 3.2.3 "PCMCIA/Compact Flash Device Type" on page 63, and Section 3.2.4 "LCD Controller Device Type" on page

69.

A read to the static bus causes a 32-bit access. This can cause a potential problem with volatile devices because a single

16-bit read results in two 16-bit reads on the external bus.

Chip selects may be programmed for fixed access times or an external wait signal may be used to provide a variable delay

per access.

While the static bus controller is a synchronous device internally, no external clock is available to reference the control sig-

nals. The internal clock comes from the System Bus (SBUS) clock. Configuring the SBUS clock determines the internal ref-

erence for the static controller and associated timings.

3.2.1 Static Controller Programming Model

The properties of each static controller chip select are determined by a set of registers. All registers in the Static Controller

block are located off of the base address shown in Table 3-1 "Memory Controller Block Base Address" on page 43. Table 3-

4 shows the registers and offsets for the static bus controller.

After modifying the configuration of a chip select, software must issue a SYNC instruction before write accesses to the chip

select are allowed.

Table 3-4. Static Bus Controller Configuration Registers

Offset (Note 1)

Note 1. See Table 3-1 "Memory Controller Block Base Address" on page 43 for base address.

0x1000 mem_stcfg0 Configuration for RCS0#.

0x1004 mem_sttime0 Timing parameters for RCS0#.

0x1008 mem_staddr0 Address region control for RCS0#.

0x1010 mem_stcfg1 Configuration for RCS1#.

0x1014 mem_sttime1 Timing parameters for RCS1#.

0x1018 mem_staddr1 Address region control for RCS1#.

0x1020 mem_stcfg2 Configuration for RCS2#.

0x1024 mem_sttime2 Timing parameters for RCS2#.

0x1028 mem_staddr2 Address region control for RCS2#.

0x1030 mem_stcfg3 Configuration for RCS3#.

0x1034 mem_sttime3 Timing parameters for RCS3#.

0x1038 mem_staddr3 Address region control for RCS3#.

54 AMD Alchemy™ Au1000™ Processor Data Book

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3.2.1.1 Static Bus Configuration Registers

The static bus configuration registers (mem_stcfgn) configure the basic properties of each chip select. Support is included

for static RAM, Flash, ROM, PCMCIA, LCD, and other types of I/O devices.

When programming a chip select as an I/O, LCD, or PCMCIA device the address comparison mask will expect an address

with the upper nibble set as shown in Table 3-5 "Device Type Encoding" on page 55 for the different device types. The TLB

must be set up accordingly to map addresses to the memory region captured by the associated chip select.

For example, to configure the TLB for use with an LCD controller, bits 29:26 of CoProcessor register Entry Lo must be

0b1110 (in addition to the other steps necessary to set up the TLB). These bits represent address bits 35:32 of the physical

address which must be 0xE in order for the address to match successfully when a chip select is enabled as an LCD device.

Since the RAM and Flash have an upper nibble of zero, it is not necessary to use the TLB to access devices set up with

these types.

mem_stcfg0 Offset = 0x1000

Bit31302928272625242322212019181716151413121110 9 8 7 6 5 4 3 2 1 0

BV D5 AV BE TS EW H BS PM RO DTY

Def.0000000000000000000000000Rs000011

mem_stcfg1

mem_stcfg2

mem_stcfg3

Offset = 0x1010

Offset = 0x1020

Offset = 0x1030

Bit31302928272625242322212019181716151413121110 9 8 7 6 5 4 3 2 1 0

BE TS EW H BS PM RO DTY

Def.00000000000000000000000000000000

Bits Name Description R/W Default

31:13 — Reserved. Should be cleared. R 0

12 BV Burst size visible. When this bit is set the burst size for static

transfers will be output for chip selects not configured as LCD

or PCMCIA. The burst size output is one less than the number

of 32-bit words to be transferred. For 16-bit chip selects twice

as many beats will occur. The mapping of the burst size to pins

is shown in Table 3-6 "Burst Size Mapping" on page 55.

This bit is a global attribute and is present only in mem_stcfg0.

R/W 0

11 D5 Divide by 5. Setting this bit will divide the SBUS clock by 5 to

generate LCLK. When D5 is cleared the SBUS clock is divided

by 4 to generate LCLK.

This bit is a global attribute and is present only in mem_stcfg0.

R/W 0

10 AV Address visible. Setting this bit will place the address for all

internal accesses to the SBUS on the static address bus. This

is intended to be used as a debug aid and should not be used

during normal operation as it will increase system power

usage.

This bit is a global attribute and is present only in mem_stcfg0.

R/W 0

9 BE Endianness.

0 Little Endian

1 Big Endian

Program this bit to match the endianness of the processor. This

bit should not be set for PCMCIA.

R/W 0

8 TS Time scale for chip select timing parameters.

0 Do not scale the timing parameters.

1 Multiply the timing parameters by a factor of four. This

option allows for longer access times.

R/W 0

AMD Alchemy™ Au1000™ Processor Data Book 55

Static Bus Controller 30360E

7 EW When the EW bit is set the EWAIT# input is allowed to stretch

the bus access time. The EW bit does not apply to chip selects

operating in LCD or PCMCIA mode because they have differ-

ent wait mechanisms.

R/W 0

6 H Half Bus. Selects the data bus width for the chip select.

0 32-bit bus

1 16-bit bus using bits 15:0 of the data bus.

NOTE: The H bit does not apply for PCMCIA and LCD device

types and must be cleared for these device types.

R/W 0, except for

mem_stcfg0 where

the default value is

determined by

ROMSEL and

ROMSIZE out of

reset. See Table 8-

1 on page 197.

5 BS Burst Size for Page Mode Accesses. Selects the burst size for

page mode accesses. Valid only in page mode (PM=1).

0 4 beats

1 8 beats

R/W 0

4 PM If the PM bit is set the chip select will operate in page mode.

This allows quick access to sequential locations in memory.

Page mode applies only to reads.

See Section 3.2.5.1 "Page Mode Transfers" on page 71.

R/W 0

3 RO If the RO bit is set the chip select will operate in read only

mode. This will inhibit the generation of write cycles to the chip

select. Any attempt to write to the address region controlled by

a read only chip select will be ignored.

R/W 0

2:0 DTY Device type. Selects the type of device controlled by the static

controller chip select. A list of device types and encodings is

shown in Table 3-5 "Device Type Encoding".

Programming multiple chip selects as LCD or PCMCIA is ille-

gal. Only one of each is supported.

R/W 0 (SRAM), except

for mem_stcfg0

where the default

value is 3 (Flash).

Table 3-5. Device Type Encoding

DTY Chip Select Function

PFN[35:32]

(upper nibble of physical address) Reference

0 Static RAM 0x0 Section 3.2.2

1 I/O Device 0xD Section 3.2.2

2 PCMCIA Device/Compact Flash 0xF Section 3.2.3

3 Flash Memory 0x0 Section 3.2.2

4 LCD Device 0xE Section 3.2.4

5–7 Reserved

Table 3-6. Burst Size Mapping

Signal Pin

burst_size[2] LWR0#

burst_size[1] LRD1#

burst_size[0] LRD0#

Bits Name Description R/W Default

56 AMD Alchemy™ Au1000™ Processor Data Book

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3.2.1.2 Static Timing Registers

The static timing registers allow software to control the timing of each phase of a static bus access. The names of the timing

parameters correspond directly to timing parameters shown on the timing diagrams.

All timing parameters are expressed as a number of clock cycles. The base clock frequency is the SBUS clock.

The actual number of clocks for each timing parameter (Tparameter) is shown in Table 3-7. Note that the timing behavior for

Tcsh is different and is shown in Table 3-8.

Table 3-7. Actual Number of Clocks for Timing Parameters (Except Tcsh)

Device Type TS = 0 TS = 1

Static RAM, I/O, Flash Tparameter + 1 (4 * Tparameter) + 1

PCMCIA Device/Compact Flash Tparameter + 2 (4 * Tparameter) + 2

Table 3-8. Actual Number of Clocks for Tcsh

Tcsh Value TS=0 TS=1

0000 3 3

0001 3 6

0010 6 12

0011 6 15

0100 6 18

0101 9 24

0110 9 27

0111 9 30

1000 12 36

1001 12 39

1010 12 42

1011 15 48

1100 15 51

1101 15 54

1110 18 60

1111 18 63

AMD Alchemy™ Au1000™ Processor Data Book 57

Static Bus Controller 30360E

mem_sttime0 (I/O, Flash, SRAM config) Offset = 0x1004

Bit31302928272625242322212019181716151413121110 9 8 7 6 5 4 3 2 1 0

Twcs Tcsh Tw p T c s w T p m Ta

Def.11111111111111111111111111011101

mem_sttime1 (I/O, Flash, SRAM config)

mem_sttime2 (I/O, Flash, SRAM config)

mem_sttime3 (I/O, Flash, SRAM config)

Offset = 0x1014

Offset = 0x1024

Offset = 0x1034

Bit31302928272625242322212019181716151413121110 9 8 7 6 5 4 3 2 1 0

Twcs Tcsh Tw p T c s w T p m Ta

Def.11111111111111111111111111111111

Bits Name Description R/W Default

31 — Reserved. Should be cleared. R 0

30:28 Twcs This field specifies the required chip select hold time after a

write pulse.

See Table 3-7 on page 56 for the actual number of clock cycles.

This field applies only to chip selects configured to support

Flash memory. For all other modes this timing parameter is one

cycle regardless of the value in the Twcs field.

R/W 0x3

27:24 Tcsh Chip select hold-off. Specifies the minimum number of cycles

that the chip select must remain inactive between accesses.

The next transaction through the static bus controller is held off

until the Tcsh parameter is satisfied. If this next access falls

within another chip select’s memory region, the new set of tim-

ing parameters associated with the controlling chip select take

effect once the new transaction begins.

Note that the SBUS can arbitrarily extend the time between

accesses for internal operations. This can add up to about five

additional clocks to the programmed time.

See Table 3-8 on page 56 for the actual number of clock cycles.

R/W 0xF

23:20 — Reserved. Should be cleared. R 0

19:14 Twp This field specifies the duration of the write enable.

See Table 3-7 on page 56 for the actual number of clock cycles.

R/W 0x3F

13:10 Tcsw Chip select to write. Defines the delay from the assertion of chip

select until the write strobe and byte enables are asserted.

See Table 3-7 on page 56 for the actual number of clock cycles.

R/W 0xF

9:6 Tpm This field determines the number of cycles required from a burst

address change until read data is valid if the PM bit is set in the

mem_stcfgn register.

See Table 3-7 on page 56 for the actual number of clock cycles.

Ta determines the access time for the first beat of each burst.

R/W 0xF

5:0 Ta The Ta parameter determines the number of cycles required for

the assertion of the chip select.

For page mode accesses Ta determines the access time up to

the first beat of each burst, or the first beat after a page mode

wrap.

See Table 3-7 on page 56 for the actual number of clock cycles.

R/W 0x3F, except for

mem_sttime0

where the default

value is 0x1D.

58 AMD Alchemy™ Au1000™ Processor Data Book

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mem_sttime0 (LCD, PCMCIA config) Offset = 0x1004

Bit31302928272625242322212019181716151413121110 9 8 7 6 5 4 3 2 1 0

Tmst Tmsu Tmih Tist Tisu

Def.11111111111111111111111111011101

mem_sttime1 (LCD, PCMCIA config)

mem_sttime2 (LCD, PCMCIA config)

mem_sttime3 (LCD, PCMCIA config)

Offset = 0x1014

Offset = 0x1024

Offset = 0x1034

Bit31302928272625242322212019181716151413121110 9 8 7 6 5 4 3 2 1 0

Tmst Tmsu Tmih Tist Tisu

Def.11111111111111111111111111111111

Bits Name Description R/W Default

31:24 Tmst This field specifies the strobe width during memory accesses to

PCMCIA or LCD chip selects.

The timing duration depends on the time-scale option

mem_stcfgn[TS]:

When TS=0, (Tmst + 2) is the number of cycles to the end of the

strobe; however, the read occurs at (Tmst + 1).

When TS=1, [(4 * Tmst) + 2] is the number of cycles to the end of

the strobe; however, the read occurs at [(4 * Tmst) + 1].

R/W 0xFF

23:17 Tmsu This field specifies the setup time from chip select to strobe dur-

ing memory accesses to PCMCIA or LCD chip selects.

See Table 3-7 on page 56 for the actual number of clock cycles.

R/W 0x7F

16:11 Tmih This field specifies the hold time for address, data, and chip

selects from the end of the strobe for both memory and I/O cycles

to PCMCIA or LCD chip selects.

See Table 3-7 on page 56 for the actual number of clock cycles.

R/W 0x3F

10:5 Tist This field specifies the strobe width for I/O accesses for a chip

select configured for PCMCIA.

This is a don’t care for LCD timing diagram.

The timing duration depends on the time-scale option

mem_stcfgn[TS]:

When TS=0, (Tmst + 2) is the number of cycles to the end of the

strobe; however, the read occurs at (Tmst + 1).

When TS=1, [(4 * Tmst) + 2] is the number of cycles to the end of

the strobe; however, the read occurs at [(4 * Tmst) + 1].

R/W 0x3F, except for

mem_sttime0

where the default

value is 0x3E.

4:0 Tisu This field specifies the setup time from chip select to strobe dur-

ing I/O accesses for PCMCIA.

This is a don’t care for LCD timing diagram.

See Table 3-7 on page 56 for the actual number of clock cycles.

R/W 0x1F, except for

mem_sttime0

where the default

value is 0x1D.

AMD Alchemy™ Au1000™ Processor Data Book 59

Static Bus Controller 30360E

3.2.1.3 Static Chip Select Address Configuration Registers (mem_staddrn)

The static memory chip-select address configuration registers (mem_staddrn) assign an address range for each chip

select. As shown below, each register contains a base address, an address comparison mask, and an enable bit.

Once enabled, a chip select is asserted when the following condition is met:

(phys_addr & addr_mask) == base_addr

where:

phys_addr: 36-bit physical address output on the internal SBUS (from the TLB for memory-mapped

regions)

addr_mask: address comparison mask taken from CSMASK

base_addr: chip select base address taken from CSBA

Note that chip select regions must be programmed so that each chip select occupies a unique area of the physical address

space. Programming overlapping chip select regions results in undefined operation.

mem_staddr0 - RCS0# Address Configuration Offset = 0x1008

Bit31302928272625242322212019181716151413121110 9 8 7 6 5 4 3 2 1 0

E CSBA CSMASK

Def.000Rs0001111111000011111111111111

mem_staddr1 - RCS1# Address Configuration

mem_staddr2 - RCS2# Address Configuration

mem_staddr3 - RCS3# Address Configuration

Offset = 0x1018

Offset = 0x1028

Offset = 0x1038

Bit31302928272625242322212019181716151413121110 9 8 7 6 5 4 3 2 1 0

E CSBA CSMASK

Def.00001111111111111111111111111111

Bits Name Description R/W Default

31:29 — Reserved. Should be cleared. R 0

28 E Enable.

0 Chip select is disabled.

1 Chip select is enabled.

R/W 0, except for

mem_staddr0

(Note 1)

Note 1. The enable (E) bits for chip selects RCS1#, RCS2#, and RCS3# are automatically cleared (disabled) coming out of a runtime or

hardware reset. For RCS0#, however, the reset value of the E bit depends on ROMSEL: Holding ROMSEL low indicates that ROM

should be used for the boot vector (and RCS0#’s E bit is set); otherwise, RCS0# is disabled. See also Section 8.3 "Boot" on page

197.

27:14 CSBA Chip select base address.

Specifies bits 31:18 of the physical base address for this chip

select. The upper nibble of the chip select address is determined

by the device type selected in mem_stcfgn[DTY]. The lower bits

of the base address are zeros.

R/W 0x3FFF, except

for mem_staddr0

where the default

value is 0x7F0.

13:0 CSMASK Chip select address mask.

Specifies bits 31:18 of the address comparison mask used to

decode this chip select. (The upper nibble of the address com-

parison mask is determined by mem_stcfgn[DTY]. The lower

bits of the mask are zeros.)

R/W 0x3FFF

60 AMD Alchemy™ Au1000™ Processor Data Book

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3.2.2 Static RAM, I/O Device and Flash Device Types

This section describes the static RAM interface which is implemented when the device type (mem_stcfgn[DTY]) is pro-

grammed to 0, 1 or 3. (See Section 3.2.1.1 "Static Bus Configuration Registers" on page 54.)

The static RAM, I/O device and Flash device types are all similar. The I/O device type is identical to the static RAM type

except that it expects the upper nibble of the system address (bits 35:32) to be 0xD. The only difference between the Flash

device type and the static RAM device type is that the Flash timing allows for a chip select hold time after a write pulse

using mem_sttimen[Twcs].

Other than these differences, the static RAM, I/O device and Flash device types share the same timing and control signals.

The control signals are shown in Table 3-9.

3.2.2.1 Static Memory Timing

The following figures show static memory timing. Figure 3-4 on page 61 illustrates static memory read timing, and Figure 3-

6 on page 62 illustrates static memory write timing. The EWAIT# timing diagrams are presented to show how EWAIT# will

hold the cycle past Ta for reads and Twp for writes.

Setup, hold, and delay timing specifications (electrical switching characteristics) are presented in Section 11.0 "Electrical

and Thermal Specifications" on page 231. (See Section 11.4.2 "Static Bus Controller Timing" on page 237.)

Timing parameters do not take into account SBUS overhead which may add inter-access delays. These delays are depen-

dent on system design and are affected by the number of bus masters and the ability of other devices to hold the bus.

Table 3-9. Static RAM, I/O Device and Flash Control Signals

Signal

Input/

Output Description

RAD[31:0] O Address bus

RD[31:0] IO Data bus

RBEN[3:0]# O Byte enables:

RBEN0# corresponds to RD[7:0].

RBEN1# is for RD[15:8].

RBEN2# is for RD[23:16].

RBEN3# is for RD[31:24].

RWE# O Write enable

ROE# O Output enable

RCS[3:0]# O Programmable Chip Selects (4 banks). RCSn# is not used when configured as a

PCMCIA device.

EWAIT# I Can be used to stretch the bus access time when enabled through mem_stcfgn[EW].

AMD Alchemy™ Au1000™ Processor Data Book 61

Static Bus Controller 30360E

Read Timing

Read accesses to the static bus always retrieve 32-bits of data. As such, all four byte enables are asserted during the 32-bit

access or the two 16-bit beats. The control signals (RCSn#, ROE#, and RBEN[1:0]#) span both accesses. The only signal

that changes state to indicate the start of the second beat is RADDR[1].

Figure 3-4. Static Memory Read Timing (Single Read Followed by Burst)

Figure 3-5. Static Memory Read EWAIT# Timing

addr1 addr2 addr2+4 addr2+8 addr2+12

data1 data2a data2b data2c data2d

TpmTa

Tcsh

RCSn#

RBEN[3:0]#

RWE#

ROE#

RAD[31:0]

RD[31:0]

Tpm Tpm

Tcs_oe

BurstSize[2:0]

ROE#

EWAIT#

RCSn#

62 AMD Alchemy™ Au1000™ Processor Data Book

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Write Timing

The timing diagrams below show the static bus write timing for I/O and SRAM device types. Figure 3-6 shows a single 32-

bit write on a 32-bit chip select.

Figure 3-6. Static Memory Write Timing

Figure 3-7. Static Memory Write EWAIT# Timing

addr

data

Tw pTcsw

Tw c s

RCSn#

RBEN[3:0#]

RWE#

ROE#

RAD[31:0]

RD[31:0]

Twp

RWE#

EWAIT#

Tw c s

RCSn#

AMD Alchemy™ Au1000™ Processor Data Book 63

Static Bus Controller 30360E

3.2.3 PCMCIA/Compact Flash Device Type

Because of the similarity of Compact Flash and PCMCIA, references to PCMCIA should be taken as applicable to Compact

Flash except where noted. The PCMCIA peripheral is designed to the PCMCIA2.1 specification—but only for the bus trans-

actions as described in this section.

The Au1000 processor provides a PCMCIA host adapter when the device type is programmed for PCMCIA. The static con-

troller interface provides the required bus signals necessary to control a PCMCIA interface. Auxiliary signals, such as card

detect and voltage sense, can be implemented with GPIOs if desired.

The PCMCIA host interface adapter will support memory, attribute and I/O transactions. External logic can be added to sup-

port DMA transfers. The Au1000 processor supports only 8- and 16-bit load and store instructions (byte and halfword

instructions) to PCMCIA devices. 32-bit accesses are not supported.

The PCMCIA interface provides control signals defined for PCMCIA devices. If two devices are required then external logic

must be added to allow for both cards to share the bus. Note that when a chip select is programmed as a PCMCIA device

that the associated RCSn# is not used.

The PCMCIA interface occupies a 36-bit address space with the upper 4 bits equal to 0xF. The TLB is required to generate

addresses that will activate a chip select with a device type of “PCMCIA”.

I/O, Memory and Attribute spaces are differentiated by addr[31:30]. Table 3-10 shows the mapping.

Note: Each of the PCMCIA physical address spaces have a maximum size of 64 MBytes. Any access beyond the 64-MByte

space will alias back into the defined region.

Table 3-11 enumerates the signals to support the PCMCIA interface.

Table 3-10. PCMCIA Memory Mapping

Physical Address PCMCIA Mapping

0xF 0xxx xxxx I/O

0xF 4xxx xxxx Attribute Memory

0xF 8xxx xxxx Memory

Table 3-11. PCMCIA Interface Signals

Signal

Input/

Output Description

RAD[31:0] O Address bus.

RD[15:0] IO Data bus.

PREG# O When this signal is asserted card access is limited to attribute memory when a mem-

ory access occurs and to I/O ports when an I/O access occurs.

PCE[2:1]# O Card Enables.

POE# O Memory Output Enable.

PWE# O Memory Write Enable.

PIOR# O I/O Read Cycle Indication.

PIOW# O I/O Write Cycle Indication.

PWAIT# I This signal is asserted by the card to delay completion of a pending cycle. Note that

this signal should be tied high through a resistor when the PCMCIA interface is not

used.

PIOS16# I 16-bit port select. Note that this signal should be tied high through a resistor when

the PCMCIA interface is not used.

64 AMD Alchemy™ Au1000™ Processor Data Book

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Figure 3-8 and Figure 3-9 on page 65 show a one and two card PCMCIA implementation. For the two card implementation

RAD26 is used as a card select signal. Both figures assume that the PCMCIA card can be hot swapped at any time—note

the use of isolation buffers on the shared bus. If the card is fixed in the system much of the interface logic can be removed.

A Compact Flash implementation is very similar to the PCMCIA implementation except that the number of address lines

used is fewer.

Figure 3-8. One Card PCMCIA Interface

ROE# O Output Enable. This output enable is intended to be used as a data transceiver con-

trol. During a PCMCIA transaction, ROE# remains asserted (low) as configured in

the timing registers (mem_sttimen) for reads and negated (high) for writes.

Table 3-11. PCMCIA Interface Signals (Continued)

Signal

Input/

Output Description

RD[15:0]

ROE#

PCE[2:1]#

RAD[25:0]

PREG#

POE#

PWE#

PIOR#

PIOW#

PIOS16#

PWAIT#

GPIO[w]

GPIO[y] DETO#

DETO#

Buffer

OE#

PCE1#

PCE2#

OE#

CE[2:1]#

ADDR[25:0]

REG#

OE#

WE#

IOR#

IOW#

IOIS16#

WAIT#

RDY/BSY#

CD1#

CD2#

16-bit

transceiver

with bus

hold

DIR

PCMCIA

Socket 0

Au1000™

Processor

PCMCIA

Host

(If an extra GPIO is available,

this gate can be eliminated.)

Adapter

AMD Alchemy™ Au1000™ Processor Data Book 65

Static Bus Controller 30360E

Figure 3-9. Two Card PCMCIA Interface

RD[15:0]

ROE#

PCE1#

RAD[25:0]

PREG#

POE#

PWE#

PIOR#

PIOW#

PIOS16

PWAIT#

GPIO[w]

GPIO[y] DETO#

DETO#

Buffer

OE#

S0CE1#

S0CE2#

OE#

CE1#

ADDR[25:0]

REG#

OE#

WE#

IOR#

IOW#

IOIS16#

WAIT

RDY/BSY#

CD1#

CD2#

16-bit

transceiver

with bus

hold

DIR

PCMCIA

Socket 0

Au1000™

OE#

16-bit

transceiver

with bus

hold

DIR

CE1#

ADDR[25:0]

REG#

OE#

WE#

IOR#

IOW#

WAIT#

CE2#

CD1#

CD2#

PCMCIA

Socket 1

S1CE1#

S1CE2#

32 bit

GPIO[x]

GPIO[z] DETO#

CE2#

DETO#

Buffer

OE#

32 bit

PCE2#

RAD26

S0CE1#

S0CE2#

S1CE1#

S1CE2#

Processor

PCMCIA

Host

IOIS16#

RDY/BSY#

Adapter

66 AMD Alchemy™ Au1000™ Processor Data Book

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3.2.3.1 PCMCIA/CompactFlash Interface

The figures on the following pages illustrate the functional timing of the PCMCIA interface, including memory read timing,

memory write timing, I/O read timing, and I/O write timing. The PWAIT# timing diagrams are presented to show how

PWAIT# will hold the cycle past Tmst for memory reads and writes and Tist for I/O reads and writes.

Setup and hold time requirements are presented in Section 11.4.2 "Static Bus Controller Timing" on page 237.

Figure 3-10. PCMCIA Memory Read Timing

Figure 3-11. PCMCIA Memory Read PWAIT# Timing

read data

TmstTmsu

Tmih

PCE[2:1]#

PREG#

POE#

PWE#

PIOR#

PIOW#

PIOS16#

PWAIT#

RAD[31:0]

RD[15:0]

ROE# Tmih

Tmst

POE#

PWAIT#

Tmih

PCE[2:1]#

AMD Alchemy™ Au1000™ Processor Data Book 67

Static Bus Controller 30360E

Figure 3-12. PCMCIA Memory Write Timing

Figure 3-13. PCMCIA Memory Write PWAIT# Timing

Figure 3-14. PCMCIA I/O Read Timing

write data

Tmst

Tmsu

Tmih

PCE[2:1]#

PREG#

POE#

PWE#

PIOR#

PIOW#

PIOS16#

PWAIT#

RAD[31:0]

RD[15:0]

Tmst

PWE#

PWAIT#

Tmih

PCE[2:1]#

TistTisu

Tmih

read data

PCE[2:1]#

PREG#

POE#

PWE#

PIOR#

PIOW#

PIOS16#

PWAIT#

RAD[31:0]

RD[15:0]

68 AMD Alchemy™ Au1000™ Processor Data Book

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Figure 3-15. PCMCIA I/O Read PWAIT# Timing

Figure 3-16. PCMCIA I/O Write Timing

Figure 3-17. PCMCIA I/O Write PWAIT# Timing

Tist

PIOR#

PWAIT#

Tmih

PCE[2:1]#

write data

TistTisu

Tmih

PCE[2:1]#

PREG#

POE#

PWE#

PIOR#

PIOW#

PIOS16#

PWAIT#

RAD[31:0]

RD[15:0]

Tist

PIOW#

PWAIT#

Tmih

PCE[2:1]#

AMD Alchemy™ Au1000™ Processor Data Book 69

Static Bus Controller 30360E

3.2.4 LCD Controller Device Type

The Au1000 processor provides a LCD controller host adapter when the device type is programmed for an LCD. The static

controller interface provides the bus signals necessary to interface to most LCD controllers.

A dedicated clock LCLK is provided for the LCD interface. The LCLK rate is the SBUS rate divided by a factor programmed

in mem_stcfg0[D5]; see Section 3.2 "Static Bus Controller" on page 53.

The Au1000 supports only 8- and 16-bit load and store instructions (byte and halfword instructions) to the LCD controller

interface; 32-bit accesses are not supported.

The LCD controller occupies 36 bit address space with the upper 4 bits equal to 0xE. The MMU is required to generate

addresses that will generate a chip select with a device type of “LCD”.

Table 3-12 lists the control signals to support the LCD controller.

Table 3-12. LCD Controller Interface Signals

Signal Input/Output Description

RAD[31:0] O Address bus

RD[15:0] IO Data bus

RCS[3:0]# O Chip Selects

LCLK O Interface Clock

LWAIT# I Extend Cycle

LRD[1:0]# O Read Indicators

LWR[1:0]# O Write Indicators

70 AMD Alchemy™ Au1000™ Processor Data Book

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3.2.4.1 LCD Controller Interface Timing

The following figures shows the LCD timing. The LWAIT# timing diagrams are presented to show how LWAIT# will hold the

cycle past Tmst for memory reads and writes and Tist for I/O reads and writes.

LWAIT# timing requirements as well as setup and hold times are presented in Section 11.4.2 "Static Bus Controller Timing"

on page 237.

Figure 3-18. LCD Controller Timing

Figure 3-19. LCD Read LWAIT# Timing

Figure 3-20. LCD Write LWAIT# Timing

input output

LCLK

RAD[31:0]

RCSn#

LRD[1:0]#

LWR[1:0#]

RD[15:0]

Tcsh

Tcsw

Tw c h

Twp

LRD[1:0#]

LWAIT#

RCSn#

Tw p

LWR[1:0]

LWAIT#

Tw c s

RCSn#

AMD Alchemy™ Au1000™ Processor Data Book 71

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3.2.5 Static Bus Controller Programming Considerations

3.2.5.1 Page Mode Transfers

The static bus controller provides a page mode for quick read access to sequential locations in memory. Setting

mem_stcfgn[PM] selects page mode operation for the chip select. The burst size (4 or 8 beats) for page mode transfers is

programmed in mem_stcfgn[BS].

Depending on the speed of the external memory device, the system designer can adjust two timing parameters in

mem_sttimen for page mode transfers:

•Ta is the time from chip select assertion to the first beat of valid data. Ta is the time required for the initial access to a

peripheral device. Ta must allow time for the peripheral device to load its read buffer or activate the next page. Note that

the page size depends on the peripheral device.

•Tpm is the time between beats.

Figure 3-4 "Static Memory Read Timing (Single Read Followed by Burst)" on page 61 shows an example page mode read

with the timing parameters Ta and Tpm.

The static bus controller does not check for page boundaries during page mode reads. The addressing is sequential

regardless of alignment. An access which crosses a page boundary may return invalid data if Tpm does not allow enough

time for the external memory device to update its read buffer or activate the next page. If the system designer cannot

ensure adequate address alignment to avoid crossing page boundaries, Tpm must be long enough to accommodate poten-

tial page updates.

In general, page-boundary timing issues do not arise for instruction fetches because they are always accessed first-word-

first and therefore are properly aligned. Data fetches, however, may have page-boundary timing issues because they are

accessed critical-word-first.

Note that EWAIT# can delay only the start of the burst (extend the Ta timing). That is, EWAIT# cannot be used to account

for varying timing between beats (extend the Tpm timing) that may occur even for transfers within a page.

Halfword Ordering and 16-bit Chip Selects

Because the static bus controller is not aware of the endian mode of the Au1 core, potential halfword swapping conflicts can

arise. Upon reset, chip selects default to little-endian byte ordering (mem_stcfg[BE] = 0). Figure 3-21 shows the data for-

mats for the 32-bit SBUS and for a little-endian 16-bit chip select.

Figure 3-21. 16-Bit Chip Select Little-Endian Data Format (Default)

When a 16-bit chip select is in little-endian mode, the static bus controller accesses the least-significant halfword CD at

physical offset 0 and accesses the most-significant halfword AB at physical offset 2. When the Au1 core is also in little-

endian mode, the requested Au1 core offsets match the physical offsets of the 16-bit device. That is, the static bus control-

ler and the Au1 core have the same view of memory. However, when the processor core is in big-endian mode, the default

ordering of the static bus controller effectively reverses the ordering of the halfwords from what the big-endian Au1 core

expects, as shown in Figure 3-22.

A DBC

C D

A B

32-Bit SBUS Format

16-Bit Static Bus Little-Endian Format

Physical Offset 0

Physical Offset 2

Little Endian Offset

0Big Endian Offset

31 24 23 16 15 8 7 0

15 8 7 0

72 AMD Alchemy™ Au1000™ Processor Data Book

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Figure 3-22. Big-Endian Au1 Core and Little-Endian 16-Bit Chip Select

For RAM memories, the halfword swapping has no side-effects because reads and writes are consistent. However, for

ROM, Flash memories, and peripherals, be aware of the following side effects:

•For ROM and Flash, the memory contents are halfword-swapped throughout the entire 16-bit device memory.

•For Flash and peripherals, the programming register offsets are also halfword-swapped.

To prevent halfword swapping, configure the chip select for big-endian mode (mem_stcfg[BE] = 1) before accessing the

memory. (If booting from static memory, see Section 8.3.1 "Endianness and 16-Bit Static Bus Boot" on page 197.) The

static bus controller inverts RAD1 for transfers on 16-bit chip selects in big-endian mode, as shown in Figure 3-23.

Figure 3-23. Big-Endian Au1 Core and Big-Endian 16-Bit Chip Select

Processor Big-Endian Offset Device Physical Offset

AB2

C D

A B

C D

A B

C D

Little Endian Offset

0Big Endian Offset

15 8 7 0

A DBC

32-Bit SBUS Format

31 24 23 16 15 8 7 0

Processor Big-Endian Offset Device Physical Offset

AB0

C D

A B

C D

A B

C D

Little Endian Offset

0Big Endian Offset

A DBC

32-Bit SBUS Format

31 24 23 16 15 8 7 0

15 8 7 0

AMD Alchemy™ Au1000™ Processor Data Book 73

DMA Controller 30360E

4.0DMA Controller

The Au1000 processor contains an eight-channel DMA controller. Each channel is capable of transferring data between

memory and any of the integrated peripherals or between memory and a memory-mapped FIFO through the Static Control-

ler using a GPIO as a request.

Note that memory-to-memory transfers are not supported by the DMA controller. That is, one side of the DMA transfer must

have an incrementing address (memory buffer), while the other side must have a fixed address (FIFO).

GPIO[4] and GPIO[5] can be programmed to act as external DMA request signals. When configured for this special system

function, the pins are labeled as follows:

•GPIO[4] becomes DMA_REQ0.

•GPIO[5] becomes DMA_REQ1.

See Section 4.2, "Using GPIO as External DMA Requests (DMA_REQn)" to configure these GPIO signals to act as DMA

requests.

4.1 DMA Configuration Registers

Each channel of the DMA is configured by a register block. A channel register block contains seven registers. The 36-bit

physical base address of the register block for each channel is shown in Table 4-1.

Table 4-1. DMA Channel Base Addresses

DMA Channel Physical Base Address KSEG1 Base Address Priority

dma0 0x0 1400 2000 0xB400 2000 0 (highest)

dma1 0x0 1400 2100 0xB400 2100 1

dma2 0x0 1400 2200 0xB400 2200 2

dma3 0x0 1400 2300 0xB400 2300 3

dma4 0x0 1400 2400 0xB400 2400 4

dma5 0x0 1400 2500 0xB400 2500 5

dma6 0x0 1400 2600 0xB400 2600 6

dma7 0x0 1400 2700 0xB400 2700 7 (lowest)

74 AMD Alchemy™ Au1000™ Processor Data Book

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Each register block contains the registers shown in Table 4-2.

Table 4-3 shows the different peripherals that are capable of DMA. The device ID, transfer size, and transfer width (device

FIFO width) are configurable fields in the dma_mode register. The FIFO address is a physical address whose address

should be programmed in the dma_peraddr register and in the DAH field of the dma_mode register.

Enabling multiple DMA channels with the same device ID is undefined.

Table 4-2. DMA Channel Configuration Registers

Offset Register Name Description

0x0000 dma_moderead Read channel mode register

0x0000 dma_modeset Set bits in channel mode register

0x0004 dma_modeclr Clear bits in channel mode register

0x0008 dma_peraddr Address of peripheral FIFO

0x000C dma_buf0addr Starting address of buffer 0

0x0010 dma_buf0size Transfer size and remaining transfer count for buffer 0

0x0014 dma_buf1addr Starting address of buffer 1

0x0018 dma_buf1size Transfer Size and remaining transfer count for buffer 1

Table 4-3. Peripheral Addresses and Selectors

Peripheral Device Device ID Transfer Size

Device FIFO

Width

FIFO Physical

Address

UART 0 Transmit 0 Programmable 8 0x0 1110 0004

UART 0 Receive 1 Programmable 8 0x0 1110 0000

DMA_REQ0 (GPIO[4]) 2 Programmable Programmable programmable

DMA_REQ1 (GPIO[5]) 3 Programmable Programmable programmable

AC97 Transmit 4 4 16 0x0 1000 0008

AC97 Receive 5 4 16 0x0 1000 0008

UART3 Transmit 6 Programmable 8 0x0 1140 0004

UART3 Receive 7 Programmable 8 0x0 1140 0000

USB Device Endpoint 0 Receive 8 4 8 0x0 1020 0000

USB Device Endpoint 0 Transmit 9 4 8 0x0 1020 0004

USB Device Endpoint 1 Transmit 10 4 8 0x0 1020 0008

USB Device Endpoint 2 Transmit 11 4 8 0x0 1020 000C

USB Device Endpoint 3 Receive 12 4 8 0x0 1020 0010

USB Device Endpoint 4 Receive 13 4 8 0x0 1020 0014

I2S Transmit 14 4 Programmable 0x0 1100 000

I2S Receive 15 4 Programmable 0x0 1100 0000

AMD Alchemy™ Au1000™ Processor Data Book 75

DMA Controller 30360E

4.1.1 DMA Channel Mode Registers

Each DMA channel is controlled by a mode register. The current value of the register can be read from the dma_moderead

register but can not be set to an arbitrary value in a single operation. Instead, the configuration register is controlled by two

registers: dma_modeset and dma_modeclr.

•The dma_modeset register sets bits in the channel mode register when the corresponding bit is written as a one. (Bits

written as zero do not affect the corresponding mode bit.)

•The dma_modeclr register clears bits in the channel mode register when the corresponding bit is written as a one. (Bits

written as zero do not affect the corresponding mode bit.)

The Au1000 processor has been designed to simplify the DMA control process by removing the need for a semaphore to

control access to the registers. This is because there is no need to read, modify, write, as there are separate registers for

setting and clearing a bit. In this way a function can freely manipulate the DMA channels associated with that function.

An arbitrary value may be written to a field within the register with the following sequence:

dma_modeset = new_value & field_mask;

dma_modeclr = ~new_value & field_mask;

The Transfer Size and Device Width fields must be programmed to match the FIFO of the peripheral chosen with the DID

field according to Table 4-3.

For the UART FIFOs the transfer size is programmable. It is the programmers responsibility to insure that the Transfer Size

matches the trigger depth set in the UART FIFO control register. See Section 6.7 "UART Interfaces" on page 150 for more

information.

For the I2S FIFOs the transfer width is programmable. It is the programmers responsibility to insure that the Transfer Width

field matches the word size in the I2S configuration register and that memory is packed accordingly. See Section 6.6 "I2S

Controller" on page 145 for more information.

For external DMA using GPIO signals as requests (DMA_REQn), the system designer must ensure that the Transfer Size

and Device Width match the external FIFO and that memory is packed accordingly.

Note that before issuing a DMA request, the receiving or transmitting FIFO must be prepared to complete a full transaction

(4 or 8 datums, depending on dma_mode[TS]) without risking overflow or underflow.

dma_moderead - Read DMA Mode Register Offset = 0x0000

dma_modeset - Set DMA Mode Register Offset = 0x0000

dma_modeclr - Clear DMA Mode Register Offset = 0x0004

Bit31302928272625242322212019181716151413121110 9 8 7 6 5 4 3 2 1 0

DAH DID BE DR TS DW NC IE H G AB D1 BE1 D0 BE0

Def.00000000000000000000000000000000

Bits Name Description R/W Default

31:24 — Reserved. Should be cleared. R 0

23:20 DAH Device Address High. Provides the most significant 4 bits of physical

device address.

R/W 0

19:16 DID Device ID. Identifies the peripheral device to act as source or destination;

see Table 4-3.

R/W 0

15:14 — Reserved. Should be cleared. R 0

13 BE Big Endian.

0 Little Endian byte order

1 Big Endian byte order

R/W 0

12 DR Device Read.

0 Data is transferred from memory to device.

1 Data is transferred from device to memory.

R/W 0

11 TS Transfer Size. Number of datums transferred per transaction. The device

width is programmed in DW.

0 4 datums. (Valid for all device widths.)

1 8 datums. (Valid for 8-bit and 16-bit device widths only.)

R/W 0

76 AMD Alchemy™ Au1000™ Processor Data Book

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10:9 DW Device FIFO Width.

00 Transfer width is 8 bits.

01 Transfer width is 16 bits.

10 Transfer width is 32 bits. (Not valid for TS=1.)

11 Reserved

RW 0

8 NC Not Coherent.

0 Memory reads and writes are marked coherent on the SBUS.

1 Memory reads and writes are marked non coherent on the SBUS.

For more information on coherency see Section 2.8.2 "SBUS Coherency

Model" on page 41 for more information on coherency.

R/W 0

7 IE Interrupt Enable.

0 No interrupts will be generated.

1 Interrupts are generated when either D1 or D0 is set.

R/W 0

6 H Channel Halted.

0 Channel is active.

1 Channel is halted.

This bit should be used to determine if the channel has been halted after

the G bit has been cleared.

5 G Channel Go. Setting the channel go bit enables the channel. When this bit

is cleared the DMA controller does not arbitrate for this channel regardless

of the state of the buffer enable bits. When the go bit is cleared by software

the channel configuration should not be modified until the DMA controller

sets the halt bit to indicate that the channel is inactive and therefore safe to

be reconfigured.

R/W 0

4 AB Active Buffer.

0 Buffer 0 is currently in use by the DMA.

1 Buffer 1 is currently in use by the DMA.

This field can be read to determine what buffer the DMA will service next if

there is not a DMA transaction in progress. During a DMA transaction this

bit will reflect the buffer currently being used.

Note that the DMA alternates between the two buffers. In other words, it is

not possible to only use one buffer, DMA transactions must be switched

between each buffer.

3 D1 Done 1. The D1 bit is set by the DMA controller to indicate that a transfer

to or from buffer 1 is complete. This bit must be cleared by the processor.

R/W 0

2 BE1 The BE1 bit enables buffer 1. This bit is set by the processor and cleared

by the DMA controller when the buffer has been filled or emptied. This bit

may be cleared by the processor only when the H bit is set.

R/W 0

1 D0 Done 0. The D0 bit is set by the DMA controller to indicate that a transfer

to or from buffer 0 is complete. This bit must be cleared by the processor.

R/W 0

0 BE0 The BE0 bit enables buffer 0. This bit is set by the processor and cleared

by the DMA controller when the buffer has been filled or emptied. This bit

may be cleared by the processor only when the H bit is set.

R/W 0

Bits Name Description R/W Default

AMD Alchemy™ Au1000™ Processor Data Book 77

DMA Controller 30360E

4.1.2 DMA Peripheral Device Address

The peripheral device address register contains a pointer to the peripheral FIFO to be used as a source or destination. Soft-

ware is responsible for matching the peripheral address to the correct value of the Device ID (DID) field in the mode regis-

ter. The correspondence between FIFO address and DID values is shown in Table 4-3. The physical address of the FIFO

must be used.

The DAH field from the dma_mode register is used as the most significant four bits of the FIFO physical address.

4.1.3 DMA Buffer Starting Address Registers

Each DMA channel has two buffers, labeled buffer0 and buffer1. The starting address of each buffer should be written to

the dma_buf0addr and dma_buf0addr registers respectively. The starting address must be cache line (32 bytes) aligned.

The 4 most significant bits of the buffer address are held in the BAH field of the dma_buf0size and dma_buf1size regis-

ters.

The starting address must explicitly be written before each DMA transaction, even if the address has not changed from the

previous, as dma_bufnaddr will change during the DMA transaction.

Note that the DMA alternates between the two buffers. In other words, it is not possible to use only one buffer—DMA trans-

actions must be switched between each buffer. The AB bit in the dma_mode register can be used to determine the active

buffer.

dma_peraddr - DMA Peripheral Address Register Offset = 0x0008

Bit31302928272625242322212019181716151413121110 9 8 7 6 5 4 3 2 1 0

ADDR

Def.00000000000000000000000000000000

Bits Name Description R/W Default

31:0 ADDR Peripheral FIFO address. R/W 0

dma_buf0addr - Buffer0 Starting Address

dma_buf1addr - Buffer1 Starting Address

Offset = 0x000C

Offset = 0x0014

Bit31302928272625242322212019181716151413121110 9 8 7 6 5 4 3 2 1 0

ADDR

Def.00000000000000000000000000000000

Bits Name Description R/W Default

31:0 ADDR Lower 32 bits of the physical starting address of the DMA memory buffer. R/W 0

78 AMD Alchemy™ Au1000™ Processor Data Book

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4.1.4 DMA Channel Buffer Size Registers

The size of each DMA buffer is given by the dma_buf0size and dma_buf1size registers. The buffer size registers also con-

tributes the most significant four bits of the buffer physical address.

This register should be programmed with the block size of the buffer in datums. While a DMA transaction is in progress, it

indicates the number of datums remaining in the transfer.

Note that the DMA alternates between the two buffers. In other words, it is not possible to only use one buffer, DMA trans-

actions must be switched between each buffer. The active-buffer bit dma_mode[AB] can be used to determine which buffer

is active at a given time.

4.2 Using GPIO as External DMA Requests (DMA_REQn)

To use GPIO[4] or GPIO[5] as an external DMA request (DMA_REQn) follow these steps:

1) Write the sys_pininputen to enable the GPIO to be used as an input. See Section 7.3 "General Purpose I/O and Pin

Functionality" on page 183 for more information.

2) TRI-STATE the GPIO to make it an input through the sys_triout register. See Section 7.3 "General Purpose I/O and

Pin Functionality" on page 183 for more information.

3) Set the dma_peraddr register to point to the external device data port. The Static Bus Controller must be configured

correctly to recognize this address.

4) Program the mode register to match the direction of transfer and peripheral attributes.

The DMA_REQn signal must be driven high to request a DMA transfer and must remain high until the DMA transaction is

started. Once started, the DMA transaction continues until finished regardless of the DMA request signal state. A DMA

transaction refers to a DMA transfer of one transfer size as defined in the DMA mode register (dma_mode[TS]).

DMA_REQn should be tied to the external FIFO threshold indicator. In this way the DMA_REQn signal asserts when the

FIFO threshold is reached and remains asserted until the FIFO fills or empties past the threshold (after the DMA transac-

tion starts). DMA_REQn should then negate after the FIFO threshold is met from the opposite direction (approaches full for

a transmit or approaches empty for a read). The threshold should be designed such that a complete DMA transaction (4 or

8 datums) can occur without risking overflow or underflow.

dma_buf0size - Buffer 0 Size

dma_buf1size - Buffer 1 Size

Offset = 0x0010

Offset = 0x0018

Bit31302928272625242322212019181716151413121110 9 8 7 6 5 4 3 2 1 0

BAH SIZE

Def.00000000000000000000000000000000

Bits Name Description R/W Default

31:20 — Reserved. Should be cleared. R/W 0

19:16 BAH Buffer Address High. Provides the 4 most significant bits of the buffer

address.

R/W 0

15:0 SIZE Buffer Size and Count Remaining. Indicates the number of datums

remaining in the current transfer.

R/W 0

AMD Alchemy™ Au1000™ Processor Data Book 79

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4.3 Programming Considerations

The following pseudo code is for setting up and servicing a DMA channel:

SetupDMA() {

Make sure interrupts are enabled globally (CP0 Reg 12, bit 0)

Enable interrupt controller for this DMA channel, high/level

Program the DMA controller {

dma_modeclr = 0xFFFFFFFF

dma_buf0size = buffer size (up to 65535)

dma_buf1size = buffer size (up to 65535)

dma_peraddr = Address of peripheral FIFO

dma_buf0addr = physical base address of buffer

dma_buf1addr = physical base address of next buffer

Write the dma_modeset register {

Enable interrupt

Enable both buffers

Set endianness

Set data width, 8-bit, 16-bit, 32-bit

Set Device ID

Set transfer size, 4-datum burst, 8-datum burst

Set coherency = 0 (memory is coherent)

Set go = 1

}

InterruptHandler() {

Note: This routine assumes it is called from context save/

restore routine at 0x80000200.

Check for hardware interrupt from interrupt controller 0,

request 0: (CP0 Reg 13, bit 10) = 1

Read interrupt controller 0 ic_req0int (interrupt status)

and check if source is from this DMA channel, bits[13:6]

if it is this DMA channel {

Check dma_moderead to see which buffer is done: D0 or D1

if (D0 is set) {

write dma_modeclr bit D0 = 1 to clear interrupt

if there is another buffer to send {

dma_buf0addr = physical base address of buffer

dma_buf0size = buffer size (up to 65535)

write dma_modeset bit BE0 = 1 to enable buffer

}

if (D1 is set) {

write dma_modeclr bit D1 = 1 to clear interrupt

if there is another buffer to send {

dma_buf1addr = physical base address of buffer

dma_buf1size = buffer size (up to 65535)

write dma_modeset bit BE1 = 1 to enable buffer

}

Issue sync

}

80 AMD Alchemy™ Au1000™ Processor Data Book

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5.0Interrupt Controller

There are two interrupt controllers in the Au1000 processor. Each interrupt controller supports 32 interrupt sources. Inter-

rupts can generate a signal to bring the Au1000 processor out of an IDLE0 or IDLE1 state and generate a CPU interrupt.

Each interrupt controller has two outputs referred to as requests 0 and 1. Each of these outputs are connected to the CPU

core. See Section 2.5 "Exceptions" on page 25 for a complete Au1000 processor interrupt architecture discussion. Table 5-

1 shows the interrupt controller connections to the CPU.

5.1 Interrupt Controller Sources

Table 5-2 on page 82 shows the mapping of interrupt sources for Interrupt Controller 0 and 1. As shown, interrupt controller

1 sources are a linear mapping of the 32 GPIOs.

Care should be taken to select the correct interrupt type (level or edge triggered) so that an interrupt is not missed. In gen-

eral, level interrupts are chosen when multiple sources from a single peripheral might cause an interrupt. In this way the

programmer will not miss a subsequent interrupt from a particular source while servicing the previous one.

Edge triggered interrupts can be used when there is only a single source for an interrupt. Edge triggered interrupts must be

used when an interrupt is caused by an internal event and not tied to a register bit where it is latched and held until cleared

by the programmer.

Details about the interrupt sources can be found in the respective peripheral sections.

Table 5-1. Interrupt Controller Connections to the CPU

Interrupt Source CP0 Cause Register Bit

Interrupt Controller 0:

Request 0

Request 1

Interrupt Controller 1:

Request 0

Request 1

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Table 5-2. Interrupt Sources

Controller Interrupt Number Source Type

0 0 UART0 High Level

0 1 UART1 High Level

0 2 UART2 High Level

0 3 UART3 High Level

0 4 SSI0 High Level

0 5 SSI1 High Level

0 6 DMA0 High Level

0 7 DMA1 High Level

0 8 DMA2 High Level

0 9 DMA3 High Level

0 10 DMA4 High Level

0 11 DMA5 High Level

0 12 DMA6 High Level

0 13 DMA7 High Level

0 14 TOY (tick) Rising Edge

0 15 TOY Match 0 Rising Edge

0 16 TOY Match 1 Rising Edge

0 17 TOY Match 2 Rising Edge

0 18 RTC (tick) Rising Edge

0 19 RTC Match 0 Rising Edge

0 20 RTC Match 1 Rising Edge

0 21 RTC Match 2 Rising Edge

0 22 IrDA Transmit High Level

0 23 IrDA Receive High Level

0 24 USB Device Interrupt Request High Level

0 25 USB Device Suspend Interrupt Rising/Falling edge

0 26 USB Host Low Level

0 27 AC97 ACSYNC Rising Edge

0 28 MAC 0 DMA Done High Level

0 29 MAC 1 DMA Done High Level

0 30 Reserved N/A

0 31 AC97 Command Done Rising Edge

1 n = 0..31 GPIO[n] System Dependent

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Figure 5-1 shows the Interrupt Controller logic diagram. Where applicable, the names in the diagram correspond to bit n in

the relative control register.

Figure 5-1. Interrupt Controller Logic

5.2 Register Definitions

The design of the software interface to the interrupt controller is based on the premise that software tasks should be able to

access the value and control of an individual port without blocking other tasks from accessing ports of interest to them. This

interrupt controller design removes the need to arbitrate via a semaphore access to the interrupt controller registers. The

result is faster and simpler interrupt controller accessing.

Table 5-3 shows the base address for each interrupt controller.

Each interrupt controller has an identical set of registers that controls its set of 32 interrupts. Table 5-4 on page 84 shows

the interrupt controller registers and their associated offsets. Certain offsets are shared but address different internal regis-

ters depending on whether the access is a read or a write. The register description details the functionality of the register.

Bit n of a particular register is associated with interrupt n of the corresponding controller.

Table 5-3. Interrupt Controller Base Addresses

Name Physical Base Address KSEG1 Base Address

ic0_base 0x0 1040 0000 0xB040 0000

ic1_base 0x0 1180 0000 0xB180 0000

ic_testbit[TB]

Interrupt

ic_src[n]

ic_cfg2[n]

ic_cfg1[n]

ic_cfg0[n]

Level/Edge

Logic

Edge

Detection

ic_rising[n] (rising edge detect)

ic_falling[n] (falling edge detect)

High Level

Low Level

ic_assign[n]

ic_mask[n]

ic_req1int[n]

CPU

Request 1

32 total

CPU

Request 0

ic_req0int[n]

(source select)

Decision

Number n

Source

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Table 5-4. Interrupt Controller Registers

Offset

(Note 1)

Note 1. See Table 5-3 "Interrupt Controller Base Addresses" on page 83 for base address.

Name Type Register Description Default

0x0040 ic_cfg0rd R Configuration 0 register

Configuration 1 register

Configuration 2 register

The combined field consisting of ic_cfg2[n], ic_cfg1[n],

and ic_cfg0[n] specifies the trigger characteristics for

interrupt n as shown in Table 5-5.

UNPRED

0x0040 ic_cfg0set W

0x0044 ic_cfg0clr W

0x0048 ic_cfg1rd R UNPRED

0x0048 ic_cfg1set W

0x004C ic_cfg1clr W

0x0050 ic_cfg2rd R UNPRED

0x0050 ic_cfg2set W

0x0054 ic_cfg2clr W

0x0054 ic_req0int R Shows active interrupts on request 0.

Used by host software to determine the source of the

interrupt.

0x0000 0000

0x0058 ic_srcrd R Selects the source of the interrupt between a test bit and

the designated source.

0 The test bit (ic_testbit[TB]) is used as interrupt

source.

1 Peripheral interrupt (controller 0) or GPIO signal

(controller 1) is used for interrupt source.

UNPRED

0x0058 ic_srcset W

0x005C ic_srcclr W

0x005C ic_req1int R Shows active interrupts on request 1.

Used by host software to determine the source of the

interrupt.

0x0000 0000

0x0060 ic_assignrd R Assigns the interrupt to one of the CPU requests.

0 Assign interrupt to request 1.

1 Assign interrupt to request 0.

UNPRED

0x0060 ic_assignset W

0x0064 ic_assignclr W

0x0068 ic_wakerd R Controls whether the interrupt can cause a wakeup from

IDLE0 or IDLE1.

0 No wakeup from Idle

1 Interrupt will cause wakeup from Idle.

The associated interrupt must still be enabled to wake

from Idle.

0x0000 0000

0x0068 ic_wakeset W

0x006C ic_wakeclr W

0x0070 ic_maskrd R Interrupt enable.

0 Disable the interrupt.

1 Enable the interrupt.

0x0000 0000

0x0070 ic_maskset W

0x0074 ic_maskclr W

0x0078 ic_risingrd R Designates active rising edge interrupts. If an interrupt is

generated off of a rising edge, the associated rising edge

detection bit must be cleared after detection.

UNPRED

0x0078 ic_risingclr W

0x007C ic_fallingrd R Designates active falling edge interrupts. If an interrupt is

generated off of a falling edge, the associated falling

edge detection bit must be cleared after detection.

UNPRED

0x007C ic_fallingclr W

0x0080 ic_testbit R/W This is a single bit register that is mapped to all the

source select inputs for testing purposes.

UNPRED

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5.2.1 Interrupt Controller Registers

Each register (except the test-bit register) is 32 bits wide with bit n in each register affecting interrupt n in the corresponding

controller.

The test-bit register contains the test bit which can be used as a test source for each interrupt. Figure 5-1 on page 83

shows how the test bit connects to the interrupt source-select logic.

Certain interrupt controller registers have the same offset but offer different functionality. This is by design. Care should be

taken when programming the registers because a read from one location may reference something different from a write to

the same location.

Registers ending in *rd, *set and *clr have the following functionality:

•*rd registers are read only registers will read back the current value of the register.

•*set registers are write only registers and will set to 1 all bits that are written 1. Writing a value of 0 will have no impact on

the corresponding bit.

•*clr registers are write only registers and will clear to zero all bits that are written 1. Writing a value of 0 will have no

impact on the corresponding bit.

The three configuration registers have a special functionality in that the value associated with ic_cfg2[n], ic_cfg1[n],

ic_cfg0[n] uniquely control interrupt n’s functionality as shown in Table 5-5 on page 86.

*rd

*set

*clr

Bit31302928272625242322212019181716151413121110 9 8 7 6 5 4 3 2 1 0

FUNC[31:0]

Def.XXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXX

Bits Name Description R/W Default

31:0 FUNC[n] The function of each register is given in Table 5-4. FUNC[n] con-

trols the functionality of interrupt n in the corresponding control-

ler.

*rd - read only

*set - write only

*clr - write only

See the following

explanation.

See Table 5-4 on

page 84.

ic_testbit Offset = 0x0080

Bit31302928272625242322212019181716151413121110 9 8 7 6 5 4 3 2 1 0

Def.XXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXX

Bits Name Description R/W Default

31:1 — Reserved. Should be cleared. R/W UNPRED

0 TB Test bit value used as an alternate interrupt source. R/W UNPRED

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5.3 Hardware Considerations

When using a GPIO or peripheral as an interrupt source, it is important that the associated pin functionality has been

enabled in the sys_pinfunc register. In addition when using a GPIO, the GPIO must first be enabled as an input. See Sec-

tion 7.3 "General Purpose I/O and Pin Functionality" on page 183 for more information.

5.4 Programming Considerations

The Au1000 has been designed to simplify the interrupt control process by removing the need for a semaphore to control

access to the registers. This is because there is no need to read, modify, write, as there are separate registers for setting

and clearing a bit. In this way a function can freely manipulate the interrupts associated with that function.

If using edge triggered interrupts, it is important to clear the associated edge detection bit or future interrupts will not be

seen.

Programming an interrupt controller can be broken into the following steps (the set, clr, and rd portion of the register name

has been omitted):

1) Identify the interrupt number, n, with the associated peripheral or GPIO.

2) Use ic_src[n] to assign the interrupt to the associated peripheral/GPIO (or the test bit can be used if testing the inter-

rupt).

3) Set the ic_cfg2[n], ic_cfg1[n] and ic_cfg0[n] bits to the correct configuration for the corresponding interrupt (edge,

level, polarity).

4) Assign the interrupt to a CPU request using ic_assign[n].

5) Use ic_wake[n] to assign the interrupt to wake the processor from Idle if necessary or clear this register bit to keep the

interrupt from waking the processor from Idle.

6) If the interrupt is an edge triggered interrupt, clear the edge detect register (ic_risingclr or ic_fallingclr) before

enabling.

7) Finally, enable the interrupt through ic_mask[n].

When taking an interrupt the following steps should be taken:

1) Read ic_req0int and ic_req1int to determine the interrupt number n.

2) Use ic_fallingrd and ic_risingrd to determine if the interrupt was edge triggered. If the interrupt is edge triggered, use

ic_fallingclr[n] or ic_risingclr[n] to clear the edge detection circuitry.

3) If the interrupt is to be disabled write ic_maskclr[n].

4) Service the interrupt.

Table 5-5. Interrupt Configuration Register Function

ic_cfg2[n] ic_cfg1[n] ic_cfg0[n] Function

0 0 0 Interrupts Disabled

0 0 1 Rising Edge Enabled

0 1 0 Falling Edge Enabled

0 1 1 Rising and Falling Edge Enabled

1 0 0 Interrupts Disabled

1 0 1 High Level Enabled

1 1 0 Low Level Enabled

1 1 1 Both Levels and Both Edges Enabled

AMD Alchemy™ Au1000™ Processor Data Book 87

Peripheral Devices 30360E

6.0Peripheral Devices

This section provides descriptions of the peripheral devices of the Au1000 processor. This includes an AC97 controller,

USB Host and Device interfaces, IrDA, two 10/100 Ethernet MACs, I2S, four UARTs and two synchronous serial interfaces.

Each peripheral contains an enable register. All other registers within each peripheral’s register block should not be

accessed until the enable register is written the correct sequence to bring the peripheral out of reset. Accessing the periph-

eral register block before a peripheral is enabled will result in undefined results.

6.1 AC97 Controller

The Au1000 processor contains an AC97 controller which incorporates an AC-link capable of bridging to an AC97 compli-

ant codec.

All data being sent and received through the AC97 controller must be 48 kHz.

6.1.1 AC97 Registers

The AC97 controller is controlled by a register block whose physical base address is shown in Table 6-1.

The register block consists of 5 registers as shown in Table 6-2.

Table 6-1. AC97 Base Address

Name Physical Base Address KSEG1 Base Address

ac97_base 0x0 1000 0000 0xB000 0000

Table 6-2. AC97 Registers

Offset (Note 1)

Note 1. See Table 6-1 "AC97 Base Address" for base address.

0x0000 ac97_config AC-link Configuration

0x0004 ac97_status Controller Status

0x0008 ac97_data TX/RX Data

0x000C ac97_cmmd Codec Command

0x000C ac97_cmmdresp Codec Command Response

0x0010 ac97_enable AC97 Block Control

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6.1.1.1 AC-Link Configuration Register

The configuration register contains bits necessary to configure and reset the AC-link and codec.

6.1.1.2 AC97 Controller Status

The AC97 Controller Status register contains status bits for the transmit and receive FIFOs, command status and the

codec.

ac97_config - AC-link Configuration Offset = 0x0000

Bit31302928272625242322212019181716151413121110 9 8 7 6 5 4 3 2 1 0

RC XS SG SN RS

Def.00000000000000000000000000000000

Bits Name Description R/W Default

31:23 — Reserved. Should be cleared. R 0

22:13 RC Receive Slots. The bits set in RC will control what data from valid slots are

put into the input buffer.

The corresponding valid bits in the AC97 tag (slot 0 of SDATA_IN) must be

marked valid for the incoming PCM data to be put in the input buffer.

Slot 3 is mapped to bit 13, slot 4 to 14 and so on.

Note: The programmer must ensure that the CODEC is configured such

that there will be valid data in the slots corresponding to what receive slots

are enabled.

R/W 0

12:3 XS Transmit Slots. The bits making up XMIT_SLOTS map to the valid bits in

the AC97 tag (slot 0 on SDATA_OUT) and indicate which outgoing slots

have valid PCM data. Bit 3 maps to slot 3, bit 4 to slot 4 and so on. Setting

the corresponding bit indicates to the CODEC that valid data will be in the

respective slot. The number of valid bits will designate how many words

will be pulled out of the FIFO per audio frame.

R/W 0

2 SG SYNC Gate. Setting this bit to 1 will gate the clock from being driven on

SYNC. This allows the SN bit to control the value on SYNC. In combina-

tion with SN, the SG bit can be used to initiate a warm reset.

R/W 0

1 SN SYNC Control. This bit controls the value of the SYNC signal when SG

(SYNC gate) is set. In combination with SG, the SN bit can be used to ini-

tiate a warm reset.

R/W 0

0 RS AC-link Reset (ACRST#) Control. To initiate a cold AC97 reset, set the RS

bit to drive the ACRST# signal low. After satisfying the ACRST# low time

for the CODEC, clear this bit to negate ACRST#.

R/W 0

ac97_status - Controller Status Offset = 0x0004

Bit31302928272625242322212019181716151413121110 9 8 7 6 5 4 3 2 1 0

XU XO RU RO RD CP TE TF RE RF

Def.00000000000000000000000000110010

Bits Name Description R/W Default

31:12 — These bits are reserved. R UNPRED

11 XU Transmit Underflow. When set, this bit indicates that the transmit

FIFO has experienced an underflow. This sticky bit is cleared when

written (0 or 1).

10 XO Transmit Overflow. When set, this bit indicates that the transmit FIFO

has experienced an overflow. This sticky bit is cleared when written

(0 or 1).

9 RU Receive Underflow. When set, this bit indicates that the receive FIFO

has experienced an underflow. This sticky bit is cleared when written

(0 or 1).

8 RO Receive Overflow. When set, this bit indicates that the receive FIFO

has experienced an overflow. This sticky bit is cleared when written (0

or 1).

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6.1.1.3 TX/RX Data

The TX/RX Data register is the transmit FIFO’s input to the when written to and the receive FIFO’s output when read from.

Each FIFO has twelve 16-bit entries. Care should be taken to monitor the status register to insure that there is room for data

in the FIFO for a read or write transaction. This will be taken care of automatically if using DMA (see Section 6.1.3, "Pro-

gramming Considerations").

The number of bits set in XMIT_SLOTS will correspond with how many samples are pulled out of the FIFO and aligned in

the respective slots. The number of bits set in RECV_SLOTS will correspond with the number of samples placed in the

FIFO from the respective slots in SDATA_IN.

7 RD Ready. This bit is mapped from the CODEC_READY bit in the

SDATA_IN tag word. It indicates that the CODEC is properly booted

and ready for normal operation.

6 CP Command Pending. This bit indicates that there is a command pend-

ing on the AC-link. A write to the CODEC command register will

cause this bit to be set until the command is completed. The com-

mand is completed for a write when the data has been written out on

slot 2. The command is completed for a read request when the status

data has been read from the corresponding read request. (This

means that a read request could be pending for more than 1 cycle

depending on the latency of the read.)

The command register should not be written until the CP bit is clear.

An interrupt can be enabled to indicate when a command is done.

The source of this interrupt is an internal pulse so either rising edge

or falling edge interrupt should be used for this interrupt.

5 — Reserved. R UNPRED

4 TE Transmit Empty. When set this bit indicates that the transmit FIFO is

empty.

3 TF Transmit Full. When set this bit indicates the transmit FIFO is full. R 0

2 — Reserved. R UNPRED

1 RE Receive Empty. When set this bit indicates that the receive FIFO is

empty.

0 RF Receive Full. When set this bit indicates that the receive FIFO is full. R 0

ac97_data - TX/RX Data Offset = 0x0008

Bit31302928272625242322212019181716151413121110 9 8 7 6 5 4 3 2 1 0

DATA_WORD[15:0]

Def.00000000000000000000000000000000

Bits Name Description R/W Default

31:16 — Reserved. Should be cleared. R 0

15:0 DATA_WORD Data Word. This is where data is written to or read from the FIFO.

Each data word is 16 bits.

R/W 0

Bits Name Description R/W Default

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6.1.1.4 Codec Command

The Codec Command and Command Response registers share the same physical address.

The Codec Command register is used to send read and write commands to the codec. For write commands, the DATA field

will be written to the register indicated by the INDEX field. For read commands, the DATA field should be written zero. The

value read from the register indicated by INDEX will appear in the Codec Response register when the Command Pending

bit in the status register (ac97_status[CP]) returns to 0.

The Codec Command register should only be written if ac97_status[CP] is 0.

6.1.1.5 Codec Command Response

The Codec Command and Response registers share the same physical address.

After a read command is sent through the Codec Command register, the response can be read from the Codec Response

is cleared; however, the response remains valid for only one AC97 frame length in duration (20.8 µs).

ac97_cmmd - Codec Command Offset = 0x000C

Bit31302928272625242322212019181716151413121110 9 8 7 6 5 4 3 2 1 0

DATA RW INDEX

Def.00000000000000000000000000000000

Bits Name Description R/W Default

31:16 DATA DATA. These bits will be the actual 16-bit word written to the register

indicated by INDEX if RW is a 0. If RW is set (indicating a read),

these bits should be written 0.

15:8 — Reserved. Should be cleared. W 0

7 RW Read/Write Bit (1=read, 0=write). This bit maps to the Read/Write bit

in the command address and designates whether the current opera-

tion will be a read or a write.

6:0 INDEX Codec Register Index. These bits will address the specific register to

be read or written to inside the Codec.

ac97_cmmdresp - Codec Command Response Offset = 0x000C

Bit31302928272625242322212019181716151413121110 9 8 7 6 5 4 3 2 1 0

READ_DATA

Def.00000000000000000000000000000000

Bits Name Description R/W Default

31:16 — Reserved. Should be cleared. R 0

15:0 READ_DATA READ_DATA. These bits will be the response to the last read com-

mand sent to the codec. The read data becomes valid after the read

command is completed (ac97_status[CP] = 0).

Note that READ_DATA remains valid for only one AC97 frame (20.8

µs) and should therefore be read immediately after ac97_status[CP]

is cleared.

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6.1.1.6 AC97 Enable

The AC97 Enable register is used to enable and reset the entire AC97 Controller block. The routine for bringing the AC97

controller out of reset is as follows:

1) Set the CE bit to enable clocks while leaving the block disabled (D=1).

2) Clear the D bit to enable the peripheral.

6.1.2 Hardware Considerations

The AC-link consists of the signals listed in Table 6-3.

For changing pin functionality please refer to the sys_pinfunc register in Section 7.3 "General Purpose I/O and Pin Func-

tionality" on page 183.

ac97_enable - AC97 Block Control Offset = 0x0010

Bit31302928272625242322212019181716151413121110 9 8 7 6 5 4 3 2 1 0

DCE

Def.00000000000000000000000000000010

Bits Name Description R/W Default

31:2 — Reserved. Should be cleared. W 0

1 D AC97 Controller Disable. Setting this bit will reset the AC97 block.

After enabling the clock with CE, this bit should be cleared for normal

operation.

0 CE Clock Enable. This bit should be set to enable the clock driving the

AC97 Controller. It can be cleared to disable the clock for power con-

siderations.

Table 6-3. AC-Link Signals

Signal

Input/

Output Definition

ACSYNC O Fixed rate sample sync; muxed with S1DOUT.

ACBCLK I Serial data clock; muxed with S1DIN.

ACDO O TDM output stream; muxed with S1CLK.

ACDI I TDM input stream.

ACRST# O Codec reset; muxed with S1DEN.

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6.1.3 Programming Considerations

To use the AC97 controller the AC97 bit in the sys_pinfunc[A97] register (see Section 7.3 "General Purpose I/O and Pin

Functionality" on page 183) must be cleared. This enables the associated pins for AC97 use.

The AC97 block supports DMA transfers and interrupts. The use of the DMA or interrupts is program dependent and is not

required to use the AC97 controller.

To use DMA for AC97 memory transfers the transmit and receive functions will each need a dedicated DMA channel. The

DMA peripheral address register (dma_peraddr) in the DMA configuration registers will be set to point to the AC97

ac97_data register. The DMA mode register (dma_mode) will need to be set up with the correct Device ID (DID). The

Device Read bit (DR) will depend on whether the channel is being used for receive or transmit. Typically the Device Width

(DW) should be set to 16 bits and the transfer size bit (TS) should be cleared because the FIFO threshold indicators corre-

spond to four-datum transfers. This assumes that the audio samples are aligned in memory on a 16-bit audio sample

boundary. The DMA will automatically monitor the transmit and receive request bits and feed data accordingly.

An interrupt (“AC97 Command Done” in interrupt controller 0) can be enabled to indicate when a command is completed.

The source of this interrupt is an internal pulse so either rising edge or falling edge interrupt should be used for this inter-

rupt.

When the AC97 ACSYNC interrupt is enabled in interrupt controller 0, an interrupt will occur corresponding to the rising

edge of the ACSYNC signal. Internally a pulse is generated from the rising edge of the ACSYNC signal and fed to the inter-

rupt controller. Regardless of the edge enabled in the interrupt controller the interrupt will come after the rising edge of

ACSYNC. Enabling a rising edge interrupt will interrupt the processor closest to the rising edge of ACSYNC.

The output FIFO for the AC-link is shared for all slots so care should be taken that there is a correspondence with the num-

ber of valid bits being set and the number of valid samples written to the transmit FIFO or aligned in memory for DMA or

erroneous results will occur. It is the programmer’s responsibility to ensure that the number of samples written to the FIFO

corresponds with the number of valid slots enabled. Data will automatically be pulled out of the FIFO in the order of what

slots are enabled. In other words if slots 3, 4, 6 and 9 are enabled, the programmer should write samples corresponding to

data for slots 3, 4, 6, and 9, in that order, to the FIFO.

To insure against underflow at least x words should be written per audio frame where x is the number of slots enabled. This

is a mean rate over time and the actual write rate may differ depending on latency requirements, DMA buffer size, and the

number of slots enabled.

Care should be taken that there is a correspondence with the number of valid bits that have been set and the number of

valid samples read from the receive FIFO or erroneous results will occur.

The input FIFO for the AC-link is shared for all slots so care should be taken that there is a correspondence with the number

of valid bits that are set and the number of samples read from the receive FIFO or erroneous results will occur. It is the pro-

grammer’s responsibility to ensure that the number of samples read from the FIFO corresponds with the number of valid

slots enabled. Data will automatically be put in the FIFO in the order of what slots are enabled. In other words if slots 3 and

4, are enabled, the programmer should read samples corresponding to data for slots 3 and 4, in that order, from the FIFO.

To insure against overflow at least x words should be read per audio frame where x is the number of slots enabled. This is

a mean rate over time and the actual read rate may differ depending on latency requirements, DMA buffer size, and the

number of slots enabled.

AMD Alchemy™ Au1000™ Processor Data Book 93

USB Host Controller 30360E

6.2 USB Host Controller

The Au1000 processor USB host controller conforms to the Open HCI interface specification, revision 1.0, and is USB 1.1

compliant. Two root hub ports, port 0 and port 1, are provided. The base of the Open HCI register block is shown in Table 6-

Only 32-bit accesses are allowed to the Open HCI registers.

All interrupts as described in the Open HCI specification are supported. These interrupts are combined when brought to the

interrupt controller into one active-low interrupt (negative-edge triggered does not work). The interrupt controller should be

programmed to reflect this by setting the USB Host interrupt to low level. See Section 5.0 "Interrupt Controller" on page 81

for details.

6.2.1 USB Host Enable Register

This register is not part of the OpenHCI registers; however, it shares the same base address. The usbh_enable register

controls the reset and clocks to the USB Host controller. When initializing the USB Host controller the programmer should

first enable clocks, then enable the module (remove from reset), then wait for the RD bit to be set before performing Open-

HCI initialization.

The correct routine for bringing the USB Host Controller out of reset is as follows:

1) Set the CE bit to enable clocks.

2) Set the E bit to enable the peripheral (at this time the C and BE bits should be configured appropriately for the system).

3) Clear the HCFS bit in the HcControl register to reset the OHCI state.

4) Wait for the RD bit to be set before issuing any commands to the OpenHCI controller.

To put the USB Host Controller into reset the following steps should be taken:

1) Set the HCFS bit in the HcControl register.

2) Clear the E and CE bits.

Table 6-4. USB Host Base Address

Name Physical Base Address KSEG1 Base Address

usbh_base 0x0 1010 0000 0xB010 0000

usbh_enable Offset = 0x7FFFC

Bit31302928272625242322212019181716151413121110 9 8 7 6 5 4 3 2 1 0

RD CE E C BE

Def.00000000000000000000000000000000

Bits Name Description R/W Default

31:5 — Reserved. Must be cleared. R/W 0

4 RD Reset Done. Wait for this bit to be set before issuing any commands to the

OpenHCI controller.

Note: When writing to the usbh_enable register, this bit position must be

3 CE Clock Enable. When this bit is set, clocks are enabled to the USB Host

controller.

R/W 0

2 E Enable. This bit enables the USB Host controller. When this bit is clear the

controller is held in reset.

R/W 0

1 C Coherent. If this bit is set memory accesses by the controller will be

marked coherent on the SBUS. When this bit is clear memory accesses by

the USB Host controller are non coherent.

For more information on coherency see Section 2.8.2 "SBUS Coherency

Model" on page 41 for more information on coherency.

R/W 0

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6.2.2 USB Host Signals

Table 6-5 shows the signals associated with the two USB host root hub ports. The USB root hub port pins have USB 1.1

compliant drivers with the addition of the external circuitry noted in the signal description.

For changing pin functionality refer to the sys_pinfunc register in Section 7.3 "General Purpose I/O and Pin Functionality"

on page 183.

0 BE Big Endian. When this bit is set the controller interprets data buffers in Big

Endian byte order. When this bit is clear the controller interprets data buff-

ers in Little Endian byte order.

Setting the BE bit does not swap the control structures defined in the OHCI

specification. Endpoint descriptors (section 4.2), transfer descriptors (sec-

tion 4.3), and the HCCA (host controller communications area, section 4.4)

should always be written as words to ensure proper operation.

R/W 0

Table 6-5. USB Host Signals

Signal Input/Output Description

USBH0P IO Positive signal of differential USB host port 0 driver. Requires an external 15

kohm pull-down resistor and ESD protection diode (transient voltage suppressor)

to be USB 1.1 compliant.

Termination Note: Requires an external 20 ohm resistor placed in series within

0.5 inches of the part.

Muxed with USBDP which controls the pin out of reset.

USBH0M IO Negative signal of differential USB host port 0 driver. Requires an external 15

kohm pull-down resistor and ESD protection diode (transient voltage suppressor)

to be USB 1.1 compliant.

Termination Note: Requires an external 20 ohm resistor placed in series within

0.5 inches of the part.

Muxed with USBDM which controls the pin out of reset.

USBH1P IO Positive signal of differential USB host port 1 driver. Requires an external 15

kohm pull-down resistor and ESD protection diode (transient voltage suppressor)

to be USB 1.1 compliant.

Termination Note: Requires an external 20 ohm resistor placed in series within

0.5 inches of the part.

USBH1M IO Negative signal of differential USB host port 1 driver. Requires an external 15

kohm pull-down resistor and ESD protection diode (transient voltage suppressor)

to be USB 1.1 compliant.

Termination Note: Requires an external 20 ohm resistor placed in series within

0.5 inches of the part.

Bits Name Description R/W Default

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6.3 USB Device Controller

The Au1000 processor USB device controller supports endpoints 0, 1, 2, 3, and 4. Endpoint 0 is always configured as a

bidirectional control endpoint. Endpoints 1 and 2 are always IN endpoints and endpoints 3 and 4 are always OUT end-

points.

IN is from device to host. From the device perspective these endpoints are written, so the associated registers are tagged

with write or wr.

OUT is from host to device. From the device perspective these endpoints are read, so the associated registers are tagged

with read or rd.

The USB device registers are located off of the base address shown in Table 6-6.

Table 6-7 shows the offsets of each register.

Table 6-6. USB Device Base Address

Name Physical Base Address KSEG1 Base Address

usbd_base 0x0 1020 0000 0xB020 0000

Table 6-7. USB Device Register Block

Offset (Note 1)

Note 1. See Table 6-6 "USB Device Base Address" for base address.

Name Description

0x0000 usbd_ep0rd Read from Endpoint 0

0x0004 usbd_ep0wr Write to Endpoint 0

0x0008 usbd_ep1wr Write to Endpoint 1

0x000C usbd_ep2wr Write to Endpoint 2

0x0010 usbd_ep3rd Read from Endpoint 3

0x0014 usbd_ep4rd Read from Endpoint 4

0x0018 usbd_inten Interrupt Enable Register

0x001c usbd_intstat Interrupt Status Register

0x0020 usbd_config Write Configuration Data

0x0024 usbd_ep0cs Endpoint 0 Control and Status

0x0028 usbd_ep1cs Endpoint 1 Control and Status

0x002C usbd_ep2cs Endpoint 2 Control and Status

0x0030 usbd_ep3cs Endpoint 3 Control and Status

0x0034 usbd_ep4cs Endpoint 4 Control and Status

0x0038 usbd_framenum Current Frame Number

0x0040 usbd_ep0rdstat EP0 Read FIFO Status

0x0044 usbd_ep0wrstat EP0 Write FIFO Status

0x0048 usbd_ep1wrstat EP1 Write FIFO Status

0x004C usbd_ep2wrstat EP2 Write FIFO Status

0x0050 usbd_ep3rdstat EP3 Read FIFO Status

0x0054 usbd_ep4rdstat EP4 Read FIFO Status

0x0058 usbd_enable USB Device Controller Enable

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6.3.1 Endpoint FIFO Read and Write Registers

The endpoint FIFO read and write registers provide access to the endpoint FIFOs. Each endpoint FIFO is unidirectional.

FIFO read registers may not be written, and FIFO write registers return unpredictable results if read.

Only the least significant byte of the FIFO registers contain data

6.3.2 Interrupt Registers

Each endpoint has an interrupt enable register and an interrupt status register. The two registers have identical formats.

When a condition becomes true the corresponding bit is set in the usbd_intstat register. If a bit is set in the interrupt enable

register and the corresponding condition becomes true, then an interrupt is issued. The interrupt for the USB device should

be programmed to high level.

Interrupts and pending conditions must be cleared by writing a 1 to the corresponding bit in the usbd_intstat register.

usbd_ep0rd Offset = 0x0000

usbd_ep0wr Offset = 0x0004

usbd_ep1wr Offset = 0x0008

usbd_ep2wr Offset = 0x000C

usbd_ep3rd Offset = 0x0010

usbd_ep4rd Offset = 0x0014

Bit31302928272625242322212019181716151413121110 9 8 7 6 5 4 3 2 1 0

DATA

Def.00000000000000000000000000000000

Bits Name Description R/W Default

31:8 — Reserved. Should be cleared. R/W 0

7:0 DATA Data. Byte of data to be written to, or read from the endpoint FIFO. R/W 0

usbd_inten Offset = 0x0018

usbd_intstat Offset = 0x001C

Bit31302928272625242322212019181716151413121110 9 8 7 6 5 4 3 2 1 0

SF H5 H4 H3 H2 H1 H0 C5 C4 C3 C2 C1 C0

Def.00000000000000000000000000000000

Bits Name Description R/W Default

31:13 — Reserved. Should be cleared. R/W 0

12 SF Start of Frame. This interrupt issues when an SOF token is received. R/W 0

11:6 H5:H0 FIFO Half Full. These interrupts issue when the corresponding FIFO

reaches the half full/half empty mark.

The bits correspond as follows:

H0 - ep0rd

H1 - ep0wr

H2 - ep1wr

H3 - ep2wr

H4 - ep3rd

H5 - ep4rd

R/W 0

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6.3.3 Device Configuration Register

The device configuration register allows configuration data to be loaded to the controller after reset.

The device configuration data is a 25-byte block which contains the configuration information for the five supported end-

points. Each endpoint requires five configuration bytes in the format shown in Figure 6-1.

Figure 6-1. Endpoint Configuration Data Structure

5:0 C5:C0 Complete

These interrupts issue when a transmission or reception completes on the

corresponding FIFO. For the read FIFOs (ep0rd, ep3rd, and ep4rd) these

interrupts indicate the reception of a DATA0 or DATA1 packet, or a

SETUP packet (ep0rd FIFO only). For the write FIFOs (ep0wr, ep1wr, and

ep2wr) these interrupts indicate the transmission of a DATA0 or DATA1

packet.

The bits correspond as follows:

C0 - ep0rd

C1 - ep0wr

C2 - ep1wr

C3 - ep2wr

C4 - ep3rd

C5 - ep4rd

R/W 0

usbd_config Offset = 0x0020

Bit31302928272625242322212019181716151413121110 9 8 7 6 5 4 3 2 1 0

CFGDATA

Def.00000000000000000000000000000000

Bits Name Description R/W Default

31:8 — Reserved. Should be cleared. R/W 0

7:0 CFGDATA Configuration data byte. Use this field to write the configuration data

block to the controller one byte at a time.

R/W 0

Bit:7654 3 210

Byte 0 Endpoint number 0 1 0 0

Byte 1 00 Type Direction Max packet size[9:7]

Byte 2 Max packet size[6:0] 0

Byte 3 0 0 0 0 0 0 0 0

Byte 4 0000 FIFO number

Bits Name Description R/W Default

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The configuration fields are described in Table 6-8.

After the controller is removed from reset, the device configuration data must be written to the usbd_config register in

order beginning with byte 0. Bytes are written individually using unsigned 32-bit words, as shown the following example

code:

for (i=0; i<25; i++)

*usbd_config = (unsigned int) cfg_data_bytes[i];

Table 6-8. Endpoint Configuration Field Descriptions

Field Description

Endpoint number Although the endpoint number ranges from 0 to 15, only endpoints 0, 1, 2, 3, and 4 are sup-

ported. It is highly recommended that the example values in Table 6-9 be used for this field.

Type Endpoint type.

00 Control

01 Isochronous

10 Bulk

11 Interrupt

Direction Endpoint direction. (Does not apply to control endpoints.)

0 Out

1 In

Max packet size Maximum packet size (in bytes). Note that for control, bulk, and interrupt endpoints, the maximum

packet size is limited to 64 bytes. Only isochronous endpoints can accept packets up to 1023

bytes.

000 0000 000 = 0 bytes

000 0000 001 = 1 byte

...

111 1111 111 = 1023 bytes

FIFO number This field designates which FIFO the endpoint uses. For endpoint 0 this field is ignored since end-

point 0 always uses FIFOs 0 and 1. It is highly recommended that the example values in Table 6-

9 be used for this field.

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An example configuration data block is shown in Table 6-9.

Table 6-9. Example Endpoint Configuration Data Block

Byte Value Description

0 0000_0100 Endpoint number = 0

Type = control

Direction = bidirectional

Max packet size = 64 bytes

FIFOs 0 and 1

1 0000_0000

2 1000_0000

3 0000_0000

4 0000_0000

5 0001_0100 Endpoint number = 1

Type = interrupt

Direction = in

Max packet size = 64 bytes

FIFO 2

6 0011_1000

7 1000_0000

8 0000_0000

9 0000_0010

10 0010_0100 Endpoint number = 2

Ty p e = bu l k

Direction = in

Max packet size = 64 bytes

FIFO 3

11 0010_1000

12 1000_0000

13 0000_0000

14 0000_0011

15 0011_0100 Endpoint number = 3

Ty p e = bu l k

Direction = out

Max packet size = 64 bytes

FIFO 4

16 0010_0000

17 1000_0000

18 0000_0000

19 0000_0100

20 0100_0100 Endpoint number = 4

Ty p e = bu l k

Direction = out

Max packet size = 64 bytes

FIFO 5

21 0010_0000

22 1000_0000

23 0000_0000

24 0000_0101

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6.3.4 Endpoint Control Registers

The endpoint control registers define parameters and reflect operational conditions for each endpoint.

usbd_ep0cs Offset = 0x0024

Bit31302928272625242322212019181716151413121110 9 8 7 6 5 4 3 2 1 0

SU N A B SZ FS

Def.00000000000000000000000000000000

usbd_ep1cs Offset = 0x0028

usbd_ep2cs Offset = 0x002C

Bit31302928272625242322212019181716151413121110 9 8 7 6 5 4 3 2 1 0

SU N A SZ FS

Def.00000000000000000000000000000000

usbd_ep3cs Offset = 0x0030

usbd_ep4cs Offset = 0x0034

Bit31302928272625242322212019181716151413121110 9 8 7 6 5 4 3 2 1 0

SU N A FS

Def.00000000000000000000000000000000

Bits Name Description R/W Default

31:15 — Reserved. Should be cleared. R/W 0

14 SU Setup Received. This bit is set when a SETUP packet is received from the

host. It is only valid for EP 0.

13 N NAK. This bit is set when an operation does not complete successfully or

when data in a receive FIFO should be ignored. For most cases this

implies a returned NAK in response to a DATA packet or an incorrect

CRC.

12 A ACK. This bit is set when an operation completes successfully. Most of the

time this means that the Host returned an ACK to a DATA (or SETUP)

packet or that a packet was received correctly and an ACK returned to the

Host.

Isochronous DATA and SETUP packets deviate from this model. For

these types of packets the A bit indicates successful transmission or

reception but no ACK is returned or expected.

11 B Alternate ACK. Set when a DATA frame is correctly received on endpoint

0. (B is not present on other endpoints.)

10:1 SZ Size. The SZ field specifies the data size of an IN transfer. The SZ field

applies only to endpoints 0, 1, and 2.

R/W 0

0 FS Force Stall. Setting this bit places the endpoint in a stalled condition. Any

transaction directed to the endpoint is answered with a STALL response.

STALL is typically used to indicate that the endpoint has halted. Note that

a Clear Feature command received via the USB does not clear a stall con-

dition forced by this bit.

R/W 0

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6.3.5 Current Frame Number

This register provides the current frame number from the start of frame packet.

6.3.6 FIFO Status Registers

Each FIFO has a status register that indicates the current state and any error conditions. The USB FIFOs are 1-byte wide

and eight bytes deep.

usbd_framenum - Current Frame Number Offset = 0x0038

Bit31302928272625242322212019181716151413121110 9 8 7 6 5 4 3 2 1 0

Def.00000000000000000000000000000000

Bits Name Description R/W Default

31:11 — Reserved. Should be cleared. R 0

10:0 FN Frame Number. This field contains the frame number from the start of

frame packet.

usbd_ep0rdstat Offset = 0x0040

usbd_ep0wrstat Offset = 0x0044

usbd_ep1wrstat Offset = 0x0048

usbd_ep2wrstat Offset = 0x004C

usbd_ep3rdstat Offset = 0x0050

usbd_ep4rdstat Offset = 0x0054

Bit31302928272625242322212019181716151413121110 9 8 7 6 5 4 3 2 1 0

FL UF OF FCNT

Def.00000000000000000000000000000000

Bits Name Description R/W Default

31:7 — Reserved. Should be cleared. R/W 0

6 FL Flush FIFO. Setting this bit flushes the corresponding FIFO and discards

any data contained in it.

5 UF Underflow Flag. Set when attempting a read from an empty FIFO. Clear

this flag by writing a 1 to it.

R/W 0

4 OF Overflow Flag. Set if a byte is written to a full FIFO. Clear this flag by writ-

ing a 1 to it.

R/W 0

3:0 FCNT FIFO Count. Reflects the current number of bytes (0 to 8) in the corre-

sponding FIFO.

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6.3.7 Device Controller Enable Register

The USB device controller enable register (usbd_enable) controls the clocks and reset to the device controller. The pro-

grammer should first enable clocks before enabling the device controller. To bring the USB device out of reset, follow these

steps:

1) Set the CE bit to enable clocks.

2) Delay for a period greater than or equal to 1 µs.

3) Set the E bit to enable the peripheral.

4) Delay at least 1 µs before programming any registers in the peripheral.

6.3.8 Programming Considerations

6.3.8.1 Removing the Controller from Reset

The following sequence of operations must be applied to remove the controller from reset.

1) Write a 0x0002 to the usbd_enable register to enable the clocks.

2) Wait 1 µs.

3) Write a 0x0003 to the usbd_enable register to remove the controller from reset.

4) Wait 1µs.

5) Write 25 bytes of configuration data to the usbd_config register.

There are no special constraints on entering the reset state: One write to the usbd_enable register may be used to turn the

clocks off and reset the controller.

Note: Accessing the endpoint control registers (usbd_epncs), frame number register (usbd_framenum) or configuration

data register (usbd_config) while the USB device is in suspend mode will result in a System Bus (SBUS) deadlock. This

will inhibit any further operation of the CPU, including EJTAG debugger operation.

6.3.8.2 Latency Requirements

The time from reception of a token such as IN or OUT until the controller must source the corresponding DATA frame is very

short. It is not practical to wait for a token before preparing the buffer for the response. Buffers must be posted before the

token is received.

The token itself is not passed to the buffer—only DATA and SETUP frames are transferred. When a DATA or SETUP frame

is received the difference between an OUT and a SETUP can be determined by examining the SU bit in the usbd_ep0cs

If an IN endpoint is enabled and no data is available in the FIFO the endpoint will NAK. Underrunning the FIFO during a

transfer (after the first byte has been written to the FIFO) will result in a bit stuff error.

usbd_enable Offset = 0x0058

Bit31302928272625242322212019181716151413121110 9 8 7 6 5 4 3 2 1 0

CE E

Def.00000000000000000000000000000000

Bits Name Description R/W Default

31:2 — Reserved. Should be cleared. W 0

1 CE Clock Enable. Clearing this bit disables all clocks to the USB Device core.

Setting this bit allows normal operation.

0 E Enable. When this bit is cleared the Device Controller will be held in reset.

Setting this bit enables normal operation.

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6.3.8.3 Using DMA

DMA should be used for all transfers with the exception of the FIFO cleanout described below for OUT transactions.

For IN transactions the size in the usbd_epncs register should be set to MAXPACKET for all but the last buffer and to the

actual remaining transfer size for the last packet. The DMA size must be set to match usbd_epncs before the DMA is

enabled for proper frame transmission.

If the last buffer of an IN series is a full MAXPACKET in length it may be necessary to set the size in the usbd_epncs reg-

ister to zero and write a byte to the FIFO to enable the transmission of a zero length DATA frame since this is often the indi-

cator for end-of-transfer. In this case the FIFO must be cleared before the next buffer is set up.

For OUT endpoints the DMA may be programmed to a larger size than a transfer will use. When the endpoint completes the

FIFO should be examined to see if there are any remaining bytes available. These bytes must be read from the FIFO under

program control since the DMA will not receive a request when less than 4 bytes are in the FIFO.

For endpoint zero it is necessary to keep a DMA buffer enabled at all times since SETUP and OUT transactions can come

at any time. The user should implement a circular buffer and extract transactions from this buffer in software, rather than try-

ing to have the DMA place transactions into separate buffers.

6.3.8.4 Servicing Interrupts

When an interrupt is received the usbd_intstat register should be read to determine the cause of the interrupt. Once the

interrupt has been serviced the usbd_intstat register should be written with the same value to clear the interrupt.

When an IN or OUT transaction is completed the device controller will NAK all further IN/OUT tokens until the interrupt is

cleared by writing the usbd_intstat register. This allows the interrupt service routine time to drain the FIFO and set up for

the next transaction rather than concatenating data from separate transactions. SETUP packets can never be delayed with

NAK.

For bulk, isochronous, and interrupt endpoints the A and N flags are somewhat redundant. Only one of them should be set

for a given transaction.

For the control endpoint the flags are broken out to provide separate feedback for various phases of control transactions.

This is necessary since only the IN and OUT phases can be paused with NAKs. SETUP packets must be absorbed grace-

fully at all times.

The A flag (ACK) is set to indicate successful reception of OUT or SETUP packets. The B flag (alternate ACK) is set to indi-

cate successful reception of OUT data only. (SETUP packets do not affect this flag.) The N flag (NAK) is set to indicate an

unsuccessful attempt to send data in response to an IN token.

This combination of flags allows all situations to be decoded. The most complex of these is when a SETUP packet immedi-

ately follows an OUT phase used to acknowledge the previous transaction. Without this separation the acknowledgement

would be lost.

6.3.8.5 Automatic Execution of Commands

Some standard setup commands directed at endpoint zero are automatically serviced by the USB device hardware. These

commands are still passed to the memory buffer. No further action is required to service these commands although they

may be used to signal state changes within the software.

The following commands are automatically serviced:

•Set Address

•Set/Clear Feature

•Set/Get Configuration

•Set/Get Interface

•Get Status

6.3.8.6 Detecting USB Reset

The USB device controller does not provide a way to detect reset on the USB. It is recommended that if a device needs to

change state on reset it should use the reception of a Set Address command to indicate that a reset has occurred.

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6.3.8.7 Automatic Suspension

If the USB device is Idle for more than 5 ms, the device controller enters a suspend state. In this state the device controller

does not consume data. A rising edge suspend interrupt is provided to inform the CPU when this occurs. The suspend

interrupt may also be used to detect the exit from suspend by using the falling edge of the interrupt.

Note: Because the USB device controller will suspend itself if left Idle, the USB device configuration routine (including pro-

gramming the interrupt controller to recognize request and suspend interrupts from the USB device) must be fully com-

pleted within 5 ms of bringing the peripheral out of its reset state.

6.3.8.8 Re-establishing a Connection after Reset

During software initialization of the USB device controller, the USBDP and USBDM signals do not automatically enter a dis-

connect-bus state in which both signals go low for more than 2.5 µs. Instead, after a runtime or hardware reset of the sys-

tem, the signals stay in a connect-bus state in which USBDP remains high and USBDM remains low. This prevents the USB

host from recognizing the need to establish a new bus enumeration, and the logical communication flow remains disrupted.

To re-establish logical communication after reset, system initialization software can control a GPIO signal to temporarily

(more than 2.5 µs) disable power to USBDP. It is recommended to use the GPIO to toggle an LDO (low drop-out) voltage

regulator placed between the USB power supply (VBUS) and the pull-up resistor attached to USBDP.

6.3.9 Programming Examples for USB Device

6.3.9.1 Initialization

1) Configure 48 MHz USB device clock from AUX PLL.

sys_auxpll = 16; // set the AUX PLL to 192 MHz (12 MHz x 16)

sys_freqctrl0 |= 0x3; // enable FREQ0 and select AUX PLL as the FREQ0 source

sys_clksrc |= 0xB; // divide FREQ0 by 4 to obtain 48 MHz, and select FREQ0

as the USB clock

2) Enable USB Device controller.

usbd_enable = 0x02; // enable USBD clocks

wait at least 1 µs;

usbd_enable = 0x03; // remove reset from USBD Controller

wait at least 1 µs;

3) Write 25-byte configuration data to the Configuration register.

for( i = 0; i < 25; ++i )

{

usbd_config = (unsigned int) config_data_bytes[i];

}

wait at least 1 µs;

4) Set up Endpoint Control registers (example).

usbd_ep0cs = 64 << 1; // set endpoint 0 MAXPACKET

usbd_ep1cs = 8 << 1; // set endpoint 1 MAXPACKET

usbd_ep2cs = 8 << 1; // set endpoint 2 MAXPACKET

usbd_ep3cs = 8 << 1; // set endpoint 3 MAXPACKET

usbd_ep4cs = 8 << 1; // set endpoint 4 MAXPACKET

5) Clear FIFO Status registers.

// clear Overflow Flag, Underflow Flag, Flush FIFO

usbd_ep0rdstat = 0x70;

usbd_ep0wrstat = 0x70;

usbd_ep1wrstat = 0x70;

usbd_ep2wrstat = 0x70;

usbd_ep3rdstat = 0x70;

usbd_ep4rdstat = 0x70;

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6) Configure DMA channels.

// assign a DMA channel for endpoint 0 receive and build

multiple buffer descriptors

// assign a DMA channel for endpoint 0 transmit and build

multiple buffer descriptors

// assign a DMA channel for endpoint 1 transmit and build

multiple buffer descriptors, if necessary

// assign a DMA channel for endpoint 2 transmit and build

multiple buffer descriptors, if necessary

// assign a DMA channel for endpoint 3 receive and build

multiple buffer descriptors, if necessary

// assign a DMA channel for endpoint 4 receive and build

multiple buffer descriptors, if necessary

7) Configure the interrupt type for the USB device request (interrupt controller 0, number 24) as high-level.

8) Configure the interrupt type for the USB device suspend (interrupt controller 0, number 25) as rising-edge.

9) Start the Endpoint 0 receive DMA.

10) Enable USB interrupts.

usbd_inten = 0x0000003F; // enable transfer-complete interrupts

6.3.9.2 Interrupt Handler

The steps to handle an interrupt are shown below. This example handler is for a general USB application and may not be

sufficient for a specific application. The handler must be installed before interrupts are enabled.

1) Obtain the USBD interrupt status.

status = usbd_intstat// obtain usbd_intstat

2) Execute each interrupt condition.

// check if endpoint transfer complete

{

// if ep0rd completed, execute the process for ep0rd.

// if ep0wr completed, execute the process for ep0wr.

// if ep1wr completed, execute the process for ep1wr.

// if ep2wr completed, execute the process for ep2wr.

// if ep3rd completed, execute the process for ep3rd.

// if ep4rd completed, execute the process for ep4rd.

}

3) Clear the USBD interrupt status.

usbd_intstat = status; // clear interrupts

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6.3.10 Hardware Considerations

Table 6-10 shows the signals associated with the USB device. The USB root hub port pins have USB 1.1 compliant drivers

with the addition of the external circuitry noted in the signal description. The USB device implementation is full speed with

the required termination noted in Table 6-10. Low speed is not supported.

For changing pin functionality please refer to the sys_pinfunc register in Section 7.3 "General Purpose I/O and Pin Func-

tionality" on page 183.

Table 6-10. USB Device Signals

Signal Input/Output Description

USBDP IO Positive signal of differential USB device driver. Requires a 1.5 kohm pull-up

resistor to denote a full speed device. Also requires an external ESD protection

diode (transient voltage suppressor) to be USB 1.1 compliant.

Termination Note: Requires an external 20 ohm resistor placed in series within

0.5 inches of the part.

Muxed with USBH0P.

USBDM IO Negative signal of differential USB device driver. Requires an external ESD pro-

tection diode (transient voltage suppressor) to be USB 1.1 compliant.

Termination Note: Requires an external 20 ohm resistor placed in series within

0.5 inches of the part.

Muxed with USBH0M.

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6.4 IrDA

The IrDA (Infrared Data Association) peripheral is a serial device that uses an infrared serial bus. Features of this peripheral

are:

•FIR, MIR, and SIR modes supported

•Integrated physical layer (PHY) implementation - only an infrared transceiver is needed.

•Integrated DMA for block transfer of packet data to/from memory

•Support for both Big Endian and Little Endian memory addressing

•16-bit or 32-bit hardware CRC generation and detection

•Interrupt support on send and receive of buffer

The operating modes and standards supported are listed in Table 6-11.

6.4.1 IrDA Registers

The IrDA peripheral is programmed via a block of registers with a base address as shown in Table 6-12. The register set

index is described in Table 6-13.

Table 6-11. IrDA Modes Supported

Mode Speed Compliance

SIR 2.4 to 115.2 kbps IrDA 1.0

MIR 1.152 Mbps IrDA 1.1 with error detection

FIR 4.0 Mbps IrDA 1.1 with error detection

Table 6-12. IrDA Base Address

Name Physical Base Address KSEG1 Base Address

irda_base 0x0 1030 0000 0xB030 0000

Table 6-13. IrDA Registers

Offset Register Name Description

0x0000 ir_rngptrstat Infrared Ring Pointer Status

0x0004 ir_rngbsadrh Infrared Ring Base Address High Register

0x0008 ir_rngbsadrl Infrared Ring Base Address Low Register

0x000C ir_ringsize Infrared Ring Size Register

0x0010 ir_rngprompt Infrared Ring Prompt Register

0x0014 ir_rngadrcmp Infrared Ring Address Compare Register

0x0018 ir_intclear IrDA interrupt clear register

0x0020 ir_config1 Infrared Configuration 1 Register

0x0024 ir_sirflags Infrared SIR Flags Register

0x0028 ir_statusen Infrared Status/Enable Register

0x002C ir_rdphycfg Infrared Read PHY Configuration Register

0x0030 ir_wrphycfg Infrared Write PHY Configuration Register

0x0034 ir_maxpktlen Infrared Maximum Packet Length Register

0x0038 ir_rxbytecnt Infrared Received Byte Count Register

0x003C ir_config2 Infrared Configuration Register 2

0x0040 ir_enable Infrared Interface Configuration Register

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6.4.1.1 Infrared Ring Pointer Status Register

This read-only register gives the current indices for both the transmit and receive ring buffer pointers. The ring buffers form

one contiguous memory block with the receive ring buffer beginning at the ring base address and the transmit ring buffer

following afterward.

6.4.1.2 Infrared Ring Base Address High Register

This register defines the base address of the transmit and receive ring buffers. The receive ring buffer begins at the speci-

fied base address; the transmit ring buffer begins at base address + 512 bytes.

6.4.1.3 Infrared Ring Base Address Low Register

This register defines the base address of the transmit and receive ring buffers. The receive ring buffer begins at the speci-

fied base address; the transmit ring buffer begins at base address + 512 bytes.

ir_rngptrstat - Infrared Ring Pointer Status Offset = 0x0000

Bit31302928272625242322212019181716151413121110 9 8 7 6 5 4 3 2 1 0

TRPI RRPI

Def.00000000000000000100000000000000

Bits Name Description R/W Default

31:15 — Reserved. Read as 0. R 0

14 — Reserved. Read as 1. R 1

13:8 TRPI Transmit Ring Pointer Index. Gives the current pointer location in the

transmit ring buffer.

7:6 — Reserved. Always read as 0. R 0

5:0 RRPI Receive Ring Pointer Index. Gives the current pointer location in the

receive ring buffer.

ir_rngbsadrh - Infrared Ring Base Address High Register Offset = 0x0004

Bit31302928272625242322212019181716151413121110 9 8 7 6 5 4 3 2 1 0

RBAH

Def.00000000000000000000000000000000

Bits Name Description R/W Default

31:6 — Reserved. Read/written as 0. R/W 0

5:0 RBAH Ring buffer base address bits [31:26]. R/W 0

ir_rngbsadrl - Infrared Ring Base Address Low Register Offset = 0x0008

Bit31302928272625242322212019181716151413121110 9 8 7 6 5 4 3 2 1 0

RBAL

Def.00000000000000000000000000000000

Bits Name Description R/W Default

31:16 — Reserved. Read/written as 0. R/W 0

15:0 RBAL Ring buffer base address bits [25:10]. R/W 0

AMD Alchemy™ Au1000™ Processor Data Book 109

IrDA 30360E

6.4.1.4 Infrared Ring Size Register

This register defines the size for both the transmit and receive ring buffers.

6.4.1.5 Infrared Ring Prompt Register

Writing this register forces the infrared controller to read the ownership bits of the transmit and receive ring buffers. Reading

this register returns a value of 0x0000FFFF.

6.4.1.6 Infrared Ring Address Compare Register

Setting the address field in this register will define which IrDA packets to accept.

Note: This feature must be enabled by setting EN = 1.

ir_ringsize - Infrared Ring Size Register Offset = 0x000C

Bit31302928272625242322212019181716151413121110 9 8 7 6 5 4 3 2 1 0

TRBS RRBS

Def.00000000000000000000000000000000

Bits Name Description R/W Default

31:16 — Reserved. Read/written as 0. R/W 0

15:12 TRBS Transmit ring buffer size and Receive ring buffer size. Each ring buffer size

is programmed as follows:

0000 4 entries (default)

0001 8 entries

0011 16 entries

0111 32 entries

1111 64 entries

All other values are not valid.

R/W 0

11:8 RRBS R/W 0

7:0 — Reserved. Read/written as 0. R/W 0

ir_rngprompt - Infrared Ring Prompt Register Offset = 0x0010

Bit31302928272625242322212019181716151413121110 9 8 7 6 5 4 3 2 1 0

D/C

Def.XXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXX

Bits Name Description R/W Default

31:16 — Reserved. Should be written as 0. W UNPRED

15:0 D/C Don’t care. W UNPRED

ir_rngadrcmp - Infrared Ring Address Compare Register Offset = 0x0014

Bit31302928272625242322212019181716151413121110 9 8 7 6 5 4 3 2 1 0

EN ADDR

Def.00000000000000000000000000000000

Bits Name Description R/W Default

31:16 — Reserved. Read/written as 0. R 0

15 EN Address comparison enable.

0 Comparison disabled.

1 Comparison enabled.

R/W 0

14:8 — Reserved. Read/written as 0. R/W 0

7:0 ADDR IrDA packet address to compare. R/W 0

110 AMD Alchemy™ Au1000™ Processor Data Book

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30360E

6.4.1.7 IrDA Interrupt Clear

Writing to this register will clear all pending IrDA interrupts.

6.4.1.8 Infrared Configuration Register 1

This register defines general setup parameters for the IrDA controller.

ir_intclear - IrDA Interrupt Clear Offset = 0x0018

Bit31302928272625242322212019181716151413121110 9 8 7 6 5 4 3 2 1 0

Def.XXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXX

Bits Name Description R/W Default

31:0 IC Interrupt Clear. Any write to this register will clear all pending IrDA

interrupts.

W UNPRED

ir_config1 - Infrared Configuration Register 1 Offset = 0x0020

Bit31302928272625242322212019181716151413121110 9 8 7 6 5 4 3 2 1 0

EL IL TE RE ME RA TD CM FI MI SI SF ST TI RI

Def.00000000000000000000000000000000

Bits Name Description R/W Default

31:16 — Reserved. Read/written as 0. R/W 0

15 EL Enable external transmit while in loopback. R/W 0

14 IL Enable internal loopback (FIR only). R/W 0

13 — Reserved. Read/written as 0. R/W 0

12 TE Transmit Enable. Unless in loopback mode, only one transfer direction

(transmit or receive) can be enabled at one time.

R/W 0

11 RE Receive Enable. Unless in loopback mode, only one transfer direction

(transmit or receive) can be enabled at one time.

R/W 0

10 ME DMA Enable. When set ME allows DMA access to system memory by the

IrDA controller. The IrDA has its own DMA controller.

This bit should always be set for normal operation.

R/W 0

9 RA Receive all small/runt packets of size less than 4 bytes (SIR mode only). R/W 0

8 TD Transparency destuffing disable for SIR receive filter.

0 Destuffing enabled.

1 Destuffing disabled.

R/W 0

7 CM Cyclical Redundancy Check (CRC) mode.

0 32-bit CRC

1 16-bit CRC

R/W 0

6 FI Fast infrared mode enable (FIR). When this bit is set the IRFIRSEL output

will be a 1

R/W 0

5 MI Medium infrared mode enable (MIR). When this bit is set the IRFIRSEL

output will be a 1

R/W 0

4 SI Slow infrared mode enable (SIR). When this bit is set the IRFIRSEL output

will be a 0

R/W 0

3 SF Enable SIR byte filter on the receiver (SIR mode only). R/W 0

2 ST Enable SIR filter when not in SIR mode (test). R/W 0

1 TI Invert transmit LED signal. R/W 0

0 RI Invert receive LED signal. R/W 0

AMD Alchemy™ Au1000™ Processor Data Book 111

IrDA 30360E

6.4.1.9 Infrared SIR Flags Register

This register returns bit sequences for start-of-frame and end-of-frame of an IrDA packet.

6.4.1.10 Infrared Status/Enable Register

This register defines enabling/disabling of the physical (PHY) layer and gives programming status for the IrDA controller as

defined by Infrared Configuration Register 1 (ir_config1).

ir_sirflags - Infrared SIR Flags Register Offset = 0x0024

Bit31302928272625242322212019181716151413121110 9 8 7 6 5 4 3 2 1 0

FS HS

Def.00000000000000001100000111000000

Bits Name Description R/W Default

31:16 — Reserved. Read as 0. R 0

15:8 FS Footer bit sequence for end-of-frame. R 0xC1

7:0 HS Header bit sequence for start-of-frame. R 0xC0

ir_statusen - Infrared Status/Enable Register Offset = 0x0028

Bit31302928272625242322212019181716151413121110 9 8 7 6 5 4 3 2 1 0

ECE FV MV SV TS RS CS

Def.00000000000000000000000011111111

Bits Name Description R/W Default

31:16 — Reserved. Read/written as 0. R/W 0

15 E Enable PHY layer. R/W 0

14 CE Configuration Error. This bit is set when more than one operating mode

(SIR, MIR, or FIR) is enabled simultaneously.

13 FV Valid FIR mode configuration. R 0

12 MV Valid MIR mode configuration. R 0

11 SV Valid SIR mode configuration. R 0

10 TS Status of transmit enable (TE) bit. R 0

9 RS Status of receive enable. R 0

8 CS Status of Cyclical Redundancy Check mode (CM) bit. R 0

7:0 — Reserved. Read as 1. R 0xFF

112 AMD Alchemy™ Au1000™ Processor Data Book

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30360E

6.4.1.11 Infrared Read PHY Configuration Register

This register returns the settings of the last value in ir_wrphycfg when bit 15 (Enable) of the ir_statusen register is 0.

When Enable is set, a write to ir_wrphycfg will not update into ir_rdphycfg until enable is 0 again.

6.4.1.12 Infrared Write PHY Configuration Register

This register defines the settings of the physical layer (PHY) interface. When read this register returns the last value written

to it.

The status of these values may be read by the Infrared Read PHY Configuration Register, ir_rdphycfg when bit 15

(Enable) of the ir_statusen register is 0.

ir_rdphycfg - Infrared Read PHY Configuration Register Offset = 0x002C

Bit31302928272625242322212019181716151413121110 9 8 7 6 5 4 3 2 1 0

BR PW P

Def.00000000000000000100000000000000

Bits Name Description R/W Default

31:16 — Reserved. Read as 0. R 0

15:10 BR Baud rate (see “Programming Considerations” on page 115). R 0

9:5 PW Pulse width (see “Programming Considerations” on page 115). R 0

4:0 P This register will determine the number of preamble bytes to send for FIR,

or start flags for MIR.

It should be interpreted as 1 less than the actual number of preamble

bytes/start flags required (i.e. setting this field to 1 will cause 2 start flags

to be sent in MIR mode).

This field does not apply to SIR.

ir_wrphycfg - Infrared Write PHY Configuration Register Offset = 0x0030

Bit31302928272625242322212019181716151413121110 9 8 7 6 5 4 3 2 1 0

BR PW P

Def.00000000000000000100000000000000

Bits Name Description R/W Default

31:16 — Reserved. Read/written as 0. R/W 0

15:10 BR Baud rate (see “Programming Considerations” on page 115). R/W 0

9:5 PW Pulse width (see “Programming Considerations” on page 115). R/W 0

4:0 P This register will determine the number of preamble bytes to send for FIR,

or start flags for MIR.

It should be interpreted as 1 less than the actual number of preamble

bytes/start flags required (i.e. setting this field to 1 will cause 2 start flags

to be sent in MIR mode).

This field does not apply to SIR.

R/W 0

AMD Alchemy™ Au1000™ Processor Data Book 113

IrDA 30360E

6.4.1.13 Infrared Maximum Packet Length Register

This register defines the maximum length of a received IrDA packet.

6.4.1.14 Infrared Receive Byte Count Register

This register returns the current number of received bytes.

6.4.1.15 Infrared Configuration Register 2

This register defines general setup parameters for the IrDA controller.

ir_maxpktlen - Infrared Maximum Packet Length Register Offset = 0x0034

Bit31302928272625242322212019181716151413121110 9 8 7 6 5 4 3 2 1 0

Def.00000000000000000000000000000000

Bits Name Description R/W Default

31:13 — Reserved. Read/written as 0. R/W 0

12:0 ML Maximum received packet length. R/W 0

ir_rxbytecnt - Infrared Receive Byte Count Register Offset = 0x0038

Bit31302928272625242322212019181716151413121110 9 8 7 6 5 4 3 2 1 0

RBCR

Def.00000000000000000000000000000000

Bits Name Description R/W Default

31:13 — Reserved. Read as 0. R 0

12:0 RBCR Received byte count. R 0

ir_config2 - Infrared Configuration Register 2 Offset = 0x003C

Bit31302928272625242322212019181716151413121110 9 8 7 6 5 4 3 2 1 0

IE FS DA DP CS PMI

Def.00000000000000001111111000000011

Bits Name Description R/W Default

31:16 — Reserved. Read/written as 0. R/W 0

15:9 — Reserved. Read as 1. R 0x7F

8 IE Interrupt Enable. Setting this bit will allow interrupts to be generated when

a ring buffer has been transmitted or received. Writing to the ir_intclear

R/w 0

7:6 FS Filter selection for finite impulse response DPLL.

00 Highest filter

01 Medium high filter

10 Medium low filter

11 Lowest filter

R/W 0x0

5 DA Disable adjacent pulse width packet circuit in the FIR DPLL.

0 Circuit enabled

1 Circuit disabled

R/W 0

4 DP Disable pulse width adjustment circuit in the FIR DPLL. R/W 0

114 AMD Alchemy™ Au1000™ Processor Data Book

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30360E

6.4.1.16 Infrared Enable Register

This register defines the IrDA peripheral interface setup and has a bit to enable clocks to the IrDA module.

The correct routine for bringing the IrDA out of reset is as follows:

1) Set the CE bit to enable clocks with the HC, C, and E bit set appropriately.

3:2 CS PHY layer clock speed.

00 40 MHz

01 48 MHz

10 56 MHz

11 64 MHz

Note that the IrDA clock must be configured to match value set in CS. The

IrDA clock is programmed from the clock generator; see Section 7.1

"Clocks" on page 168.

R/W 0x0

1 P One receive pin mode.

0 Two pins for receive

1 One pin each for receive and speed select (slow or fast)

R/W 0

0 MI Mode inversion (when P=1).

0 Fast speed is chosen by asserting speed select low.

1 Fast speed is chosen by asserting speed select high.

R/W 0

ir_enable - Infrared Enable Register Offset = 0x0040

Bit31302928272625242322212019181716151413121110 9 8 7 6 5 4 3 2 1 0

HC CE C E

Def.00000000000000000000000000000000

Bits Name Description R/W Default

31:4 — Reserved. Read/written as 0. R/W 0

3 HC Half clock speed for IrDA clock.

0 Clock runs at full SBUS frequency.

1 Clock runs at one-half SBUS frequency.

Note that HC is not just for power savings. HC must be set when the SBUS

is greater than 100 MHz.

R/W 0

2 CE Clock enable for the IrDA module.

0 Disable clocks.

1 Enable clocks.

R/W 0

1 C Coherent.

0 Memory accesses are marked non coherent

1 Memory accesses are marked coherent

For more information on coherency see Section 2.8.2 "SBUS Coherency

Model" on page 41 for more information on coherency.

R/W 1

0 E Endian mode.

0 Little Endian

1 Big Endian

R/W 1

Bits Name Description R/W Default

AMD Alchemy™ Au1000™ Processor Data Book 115

IrDA 30360E

6.4.2 Hardware Considerations

Table 6-14 describes the connection between the IrDA peripheral and the external transceiver.

For changing pin functionality refer to the sys_pinfunc register in Section 7.3 "General Purpose I/O and Pin Functionality"

on page 183.

6.4.3 Programming Considerations

6.4.3.1 Initialization

First the IrDA clock must be set to match the CS setting in the ir_config2 register. Please see Section 7.1 "Clocks" on page

168 for more information.

Second, enable peripheral logic by programming the ir_enable register: HC should be set to 1 for low power or if the Sys-

tem Bus (SBUS) is greater than 100 MHz, CE must be set to 1 to enable the peripheral logic, C should be set to 1 for

Dcache to respond to IrDA accesses on the SBUS if it has the data, and E should be set for the appropriate endianess.

Next, the sys_pinfunc register bits must be set to the alternate (IrDA) function: IRF can optionally be set to 1 to enable

IrDA to drive the FIRSEL pin (this pin is not required if external logic takes care of setting the transceiver speed). IRD must

be set to 0 to enable data transmission through the IRTXD pin.

6.4.3.2 Power Management

The HC bit in the ir_enable register can be used to run the IRDA at half the SBUS. The CE should be disabled when not

using the IRDA to gate clocks from this peripheral.

Table 6-14. IrDA Hardware Connections

Signal Input/Output Description

IRDATX O Serial IrDA output. Muxed with GPIO[19].

IRDARX I Serial IrDA input.

IRFIRSEL O Output which will signal at which speed the IrDA is currently set. This signal is not

necessary for IrDA operation. This pin will be driven high when IrDA is configured

for FIR or MIR. This pin will be driven low for SIR mode.

Muxed with GPIO[15] which controls the pin out of hardware reset, runtime reset

and Sleep.

116 AMD Alchemy™ Au1000™ Processor Data Book

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30360E

6.4.3.3 Programming Notes

IrDA can be operated at speeds ranging from 2400 bps to 4 Mbps. Table 6-15 shows the proper parameters to configure

communications speed and IrDA mode.

Table 6-16, Table 6-17 and Table 6-18 show the ordered steps for programming the IrDA peripheral for each mode.

Table 6-15. IrDA PHY Configuration Table

Mode Speed (bps) Baud Rate

Pulse Width

Preamble/Start

FlagsMin Nom Max

SIR 2400 47 0 12 12 N/A

SIR 9600 11 0 12 12 N/A

SIR 19200 5 1 12 12 N/A

SIR 38400 2 3 12 14 N/A

SIR 57600 1 5 12 16 N/A

SIR 115200 0 11 12 20 N/A

MIR 1150000 0 N/A 8 N/A 2 (P field = 1)

FIR 4000000 0 N/A N/A N/A 16 (P field = 15)

Table 6-16. Fast Infrared Mode (FIR)

Step Register Value Notes

1 ir_enable 0x000E Enable half clock speed (HC), clocks (CE), coherency (C), and little

endian (E).

2 ir_statusen 0x0000 Clear bit E to allow peripheral programming (disable IrDA).

3 ir_maxpktlen 0x0020 32 bytes maximum per packet

4 ir_wrphycfg 0x000F 16 preamble bytes (P field requires 1 less than number needed)

5 ir_config1 0x1C40 Enable transmitter (TE), receiver (RE), memory scheduler (ME),

and fast infrared mode (FI).

NOTE: set pin inversion bits (TI and/or RI) accordingly for proper

transceiver operation.

6 ir_rngbsadrl User Defined Write the physical address of ring buffer memory.

NOTE: The final address must have zeros for address bits 9:0 (i.e.

the address must reside on a 1 KByte boundary).

7 ir_rngbsadrh User Defined Write the physical address of ring buffer memory.

NOTE: The final address must have zeros for address bits 9:0 (i.e.

the address must reside on a 1 KByte boundary).

8 ir_ringsize User Defined Write the desired ring size.

9 ir_config2 0x0004 Set the PHY clock speed to 48 MHz.

10 ir_statusen 0x8000 Set bit E to enable the peripheral, then read register again for cor-

rect status (should equal 0xA6FF).

11 ir_rngprompt 0x0000 Write a zero to this register to start the IrDA transfers.

AMD Alchemy™ Au1000™ Processor Data Book 117

IrDA 30360E

Table 6-17. Medium Infrared Mode (MIR)

Step Register Value Notes

1 ir_enable 0x000E Enable half clock speed (HC), clocks (CE), coherency (C), and little

endian (E).

2 ir_statusen 0x0000 Clear bit E to allow peripheral programming (disable IrDA).

3 ir_maxpktlen 0x0020 32 bytes maximum per packet

4 ir_wrphycfg 0x0101 1 preamble byte (P field requires one less than number needed),

Pulse Width = 8

5 ir_config1 0x1C20 Enable transmitter (TE), receiver (RE), memory scheduler (ME),

and medium infrared mode (MI).

NOTE: Set pin inversion bits (TI and/or RI) accordingly for proper

transceiver operation.

6 ir_rngbsadrl User Defined Write the physical address of ring buffer memory.

Note: The final address must have zeros for address bits [9:0]

(i.e., the address must reside on a 1 KByte boundary).

7 ir_rngbsadrh User Defined Write the physical address of ring buffer memory.

Note: The final address must have zeros for address bits [9:0]

(i.e., the address must reside on a 1 KByte boundary).

8 ir_ringsize User Defined Write the desired ring size.

9 ir_config2 0x0004 Set the PHY clock speed to 48 MHz.

10 ir_statusen 0x8000 Set bit E to enable the peripheral, then read register again for cor-

rect status (should equal 0x96FF).

11 ir_rngprompt 0x0000 Write a zero to this register to start the IrDA transfers.

118 AMD Alchemy™ Au1000™ Processor Data Book

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30360E

Ring Buffers

The IrDA controller is designed to allow the CPU to access the IR media through a system of “rings” set up in memory.

Each ring entry corresponds to a LAN packet and stores information and status about that packet as well as the physical

address of where the data for that packet is stored. The ring area is split into two areas: Transmit and Receive. The receive

ring starts at the Base Address location (specified by the contents of the ring base address registers) and the transmit ring

starts at the Base Address + 512 bytes (decimal). Each ring entry contains 8 bytes with a maximum of 64 ring entries in

each of the transmit and/or receive ring areas. The actual number of entries used is programmed via the ir_ringsize regis-

ter.

The format for each transmit ring entry is shows in Figure 6-2.

Figure 6-2. Transmit Ring Buffer Entry Format

Table 6-18. Slow Infrared Mode (SIR)

Step Register Value Notes

1 ir_enable 0x000E Enable half clock speed (HC), clocks (CE), coherency (C), and little

endian (E).

2 ir_statusen 0x0000 Clear bit E to allow peripheral programming (disable IrDA).

3 ir_maxpktlen 0x0020 32 bytes maximum per packet.

4 ir_wrphycfg 0x0180 Baudrate = 0 (115200), Pulse width = 12.

5 ir_config1 0x1E10 Enable transmitter (TE), receiver (RE), memory scheduler (ME),

receive all runt packets (RA), and slow infrared mode (SI). Note: set

pin inversion bits (TI and/or RI) accordingly for proper transceiver

operation.

6 ir_rngbsadrl User Defined Write the physical address of ring buffer memory.

NOTE: The final address must have zeros for address bits 9:0 (i.e.

the address must reside on a 1 KByte boundary).

7 ir_rngbsadrh User Defined Write the physical address of ring buffer memory.

NOTE: The final address must have zeros for address bits 9:0 (i.e.

the address must reside on a 1 KByte boundary).

8 ir_ringsize User Defined Write the desired ring size.

9 ir_config2 0x0004 Set the PHY clock speed to 48 MHz.

10 ir_statusen 0x8000 Set bit E to enable the peripheral, then read register again for cor-

rect status (should equal 0x8EFF).

11 ir_rngprompt 0x0000 Write a zero to this register to start the IrDA transfers.

76543210Bit:

URFUNPBC RDCO

COUNT[7:0]

COUNT[11:8]

ADDR[7:0]

ADDR[15:8]

ADDR[23:16]

ADDR[31:24]

Byte 0

Byte 1

Byte 2

Byte 3

Byte 4

Byte 5

Byte 6

Byte 7

AMD Alchemy™ Au1000™ Processor Data Book 119

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Table 6-19. Transmit Ring Buffer Entry Format Description

Bits Name Description R/W Default

Byte 0

bits 7:0

COUNT[7:0] Number of bytes to transmit (lowest 8 bits) R/W User

Assigned

Byte 1:

bits 7:4

— Reserved. Read/written as 0. R/W 0

Byte 1:

bits 3:0

COUNT[11:8] Number of bytes to transmit (upper 4 bits) R/W User

Assigned

Byte 2:

bits 7:0

— Reserved. Read/written as 0. R/W 0

Byte 3:

bit 7

O Ownership flag.

0 User has ownership of the packet.

1 Hardware has ownership of the packet and is sending the

packet data to the transmitter.

Hardware clears this bit when the packet has been sent.

R/W User

Assigned

Byte 3:

bit 6

DC Disable the transmit CRC.

0 Used for synchronous packet operation.

1 Used by IrDA SIR mode.

Hardware clears this bit when the packet has been sent.

R/W User

Assigned

Byte 3:

bit 5

BC Force a bad CRC.

0 Normal CRC operation.

1 Send an ‘invalid’ CRC flag in the packet. Used to test receiver

CRC checking.

Hardware clears this bit when the packet has been sent.

R/W User

Assigned

Byte 3:

bit 4

NP Need an indication pulse.

0 Normal operation.

1 Transmit an indication pulse after the packet has been transmit-

ted.

Hardware clears this bit when the packet has been sent.

R/W User

Assigned

Byte 3:

bit 3

FU Force an underrun condition.

0 Normal operation.

1 Force an underrun on this packet. Packet size must be greater

than 18 bytes. Used for testing only.

R/W User

Assigned

Byte 3:

bit 2

R Request to disable transmitter.

0 Normal operation.

1 Hardware will clear ir_config1 transmit enable (TE) bit after this

packet has been transmitted. Used to shut down the transmitter

immediately after the last packet.

R/W User

Assigned

Byte 3:

bit 1

— Reserved. Read/written as 0. R/W 0

Byte 3:

bit 0

UR Hardware Underrun error. This bit is set if a hardware underrun

occurs during transmission of a packet. Used only to find hardware

errors.

Byte 4:

bits 7:0

ADDR[7:0] Address of data to transmit (bits 7:0). R/W User

Assigned

Byte 5:

bits 7:0

ADDR[15:8] Address of data to transmit (bits 15:8). R/W User

Assigned

Byte 6:

bits 7:0

ADDR[23:16] Address of data to transmit (bits 23:16). R/W User

Assigned

Byte 7:

bits 7:0

ADDR[31:24] Address of data to transmit (bits 31:24). R/W User

Assigned

120 AMD Alchemy™ Au1000™ Processor Data Book

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30360E

The format for each receive ring entry is described in Figure 6-3.

Figure 6-3. Receive Ring Buffer Entry Format

Table 6-20. Receive Ring Buffer Entry Format Description

Bits Name Description R/W Default

Byte 0

bits 7:0

COUNT[7:0] Number of bytes received (lowest 8 bits) R/W User

Assigned

Byte 1:

bits 7:5

— Reserved. Read/written as 0. R/W 0

Byte 1:

bits 4:0

COUNT[12:8] Number of bytes received (upper 5 bits) R/W User

Assigned

Byte 2:

bits 7:0

— Reserved. Read/written as 0. R/W 0

Byte 3:

bit 7

O Ownership flag.

0 User has ownership of the packet.

1 Hardware has ownership of the packet and is writing packet

data from the receiver to memory.

Hardware clears this bit when the packet has been received.

R/W User

Assigned

Byte 3:

bit 6

PE PHY layer error detected. R/W User

Assigned

Byte 3:

bit 5

CE CRC error detected. Valid for FIR and MIR modes only. R/W User

Assigned

Byte 3:

bit 4

ML Maximum packet length reached. For SIR mode, data will continue to

be received in adjacent packets. However, for FIR and MIR modes,

subsequent data will be dropped.

R/W User

Assigned

Byte 3:

bit 3

FO Internal hardware FIFO overflow. This should not occur under normal

operation.

R/W User

Assigned

Byte 3:

bit 2

SE SIR error detected. If the SIR filter is enabled, this flag will be set if an

end flag is not received.

R/W User

Assigned

Byte 3:

bits 1:0

— Reserved. Read/written as 0. R/W 0

Byte 4:

bits 7:0

ADDR[7:0] Address of data to receive (bits 7:0). R/W User

Assigned

Byte 5:

bits 7:0

ADDR[15:8] Address of data to receive (bits 15:8). R/W User

Assigned

Byte 6:

bits 7:0

ADDR[23:16] Address of data to receive (bits 23:16). R/W User

Assigned

Byte 7:

bits 7:0

ADDR[31:24] Address of data to receive (bits 31:24). R/W User

Assigned

76543210Bit:

FOMLCE SEPEO

COUNT[7:0]

COUNT[12:8]

ADDR[7:0]

ADDR[15:8]

ADDR[23:16]

ADDR[31:24]

Byte 0

Byte 1

Byte 2

Byte 3

Byte 4

Byte 5

Byte 6

Byte 7

AMD Alchemy™ Au1000™ Processor Data Book 121

IrDA 30360E

On the transmit side the descriptors are set up and point to the data associated with them. Each buffer has an ownership bit

that tells the hardware it has been given control of that buffer. When the hardware has finished with a buffer it will clear the

‘O’ bit. If polling this is how software can tell whether a receive or transit is done. When using interrupts, when the hardware

is finished either transmitting or receiving an interrupt will be generated if they are enabled in the ir_config2 register. See

Section 5.0 "Interrupt Controller" on page 81.

Buffers are in a ring structure and are always accessed in sequence. Once the controller reaches a buffer in which the own-

ership bit is not set, it will stop the chaining at that point and will require the processor to "PROMPT" it to look at the buffer

again and restart the chaining.

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6.5 Ethernet MAC Controller

The Au1000 processor contains two Ethernet MAC devices. The MAC provides the interface between the host application

and the PHY layer through the Media Independent Interface (MII). The PHY layer device is external to the processor.

The MAC supports the protocol requirements to meet the Ethernet/IEEE 802.3 specification. The MAC operates in both half

and full duplex modes. In half duplex mode the MAC is compliant with section 4 of ISO/IEC 8802-3 (ANSI/IEEE Standard)

and ANSI/IEEE 802.3.

The MAC provides programmable enhanced features designed to minimize host supervision, bus utilization and pre/post

message processing. These features include ability to disable retries after a collision, dynamic FCS generation on a frame

by frame basis, automatic pad field insertion and deletion to enforce minimum frame size attributes, automatic retransmis-

sion and detection of collision frames. The MAC can sustain transmission or reception of minimal size back to back packets

at full line speed with an inter-packet gap of 9.6 µs for 10 Mbps and 0.96 µs for 100 Mbps.

A dedicated DMA engine is implemented to support the MAC so that the general purpose DMA is not required.

The primary attributes of the MAC are:

•Transmit and receive message data encapsulation with framing and error detection.

•Frame boundaries are delimited and frames are synchronized. Error detection is done at the physical medium transmis-

sion level.

•Media access management is supported through medium allocation and contention resolution. This is accomplished

through collision avoidance and handling. The MAC handles collision per the ISO 8802.3 specification.

•Support for flow control during full duplex mode is accomplished by decoding of control frames and disabling the trans-

mitter in conjunction with generation of control frames.

•The serial control interface supports the MII protocol to interface to an MII based PHY.

The MAC features are:

•IEEE 802.3, 802.3u, 803.3x specification compliance

•10/100 Mbps data transfer rates

•IEEE 802.3 compliant MII interface to talk to an external PHY

•Full and half duplex

•CSMA/CD in half duplex

•Flow control support for full duplex

•Collision detection and auto retransmit on collisions in half duplex

•Preamble generation and removal

•Automatic 32 bit CRC generation and checking

•Optional automatic Pad stripping on the receive packets.

•Loopback support on the MII

•Filtering modes supported on the Ethernet side:

— One 48 bit perfect address

— 64 hash-filtered multicast addresses

— Pass all multicast addresses

— Promiscuous Mode

— Pass all incoming packets with a status report

— Toss bad packets

•Separate 32 bit status returned for transmit and receive packets

— Jumbo packet (0x2800 bytes)

— Big/Little Endian data format support

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The following PHY interfaces are supported:

•MII - Ethernet 4bit parallel PHY per IEEE 802.3u spec

•MII Management - 2 wire bus to control and receive status from PHY

•HPNA 1.0 support across MII

The control registers for the MAC are used for address filtering, packet filter for good and bad frames, 48-bit MAC address

with a local station address, a multicast table for filtering multicast frames and more. Each register is 32 bits wide.

6.5.1 Ethernet Base Address Registers

The two Ethernet MACs contained in the Au1000 processor are located at the base addresses shown in Table 6-21. In

addition, the base addresses for the enable registers and the MAC DMA registers are shown.

6.5.2 MAC Configuration Registers

The Ethernet MAC registers are listed in Table 6-22. Each Ethernet MAC has an identical register set with identical offsets

from mac0_base and mac1_base.

Table 6-21. Ethernet Base Addresses

Name Physical Base Address KSEG1 Base Address

mac0_base 0x0 1050 0000 0xB050 0000

mac1_base 0x0 1051 0000 0xB051 0000

macen_base 0x0 1052 0000 0xB052 0000

macdma0_base 0x0 1400 4000 0xB400 4000

macdma1_base 0x0 1400 4200 0xB400 4200

Table 6-22. MAC Configuration Register Descriptions

Offset Register Name Description

0x0000 mac_control Operation Mode and address filter

0x0004 mac_addrhigh High 16 bits of the MAC physical address

0x0008 mac_addrlow Lower 32 bits of the MAC physical address

0x000C mac_hashhigh High 32 bits of the Multicast hash address

0x0010 mac_hashlow Low 32 bits of the Multicast hash address

0x0014 mac_miictrl Control of PHY management interface

0x0018 mac_miidata Data to be written or read from PHY over control interface

0x001C mac_flowctrl Control Frame Generation Control

0x0020 mac_vlan1 VLAN1 Tag

0x0024 mac_vlan2 VLAN2 Tag

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6.5.2.1 MAC Control Register

The MAC Control Register establishes the receive and transmit operating modes and controls for address filtering and

packet filtering.

Note that the PM, PR, IF, HP and HO bits in the MAC Control register will determine the address filtering mode. The RA,

DB, PC and PB bits will determine the packet filter mode. The first bit of the destination address will determine if the

address is a physical address (first bit = 0) or a multicast address (first bit = 1). If all bits in the destination address are set

to 1 then the address is a broadcast address.

mac_control Offset = 0x0000

Bit31302928272625242322212019181716151413121110 9 8 7 6 5 4 3 2 1 0

RA EM DO LM FPM PR IF PB HO HP LC DB DR AP BL DC TE RE

Def.00000000000000000000000000000000

Bits Name Description R/W Default

31 RA Receive All.

0 Normal Operation

1 All incoming packets will be received regardless of the destination

address.

The address filter status is reported in Receive Status bit Filtering Fail.

The Packet Filter bit in the Receive Status is set for all error-free frames

regardless of the Destination Address field.

R/W 0

30 EM Endian mode for data buffers.

0 Little endian

1 Big endian

R/W 0

29:24 — Reserved. Should be cleared. R 0

23 DO Disable Receive Own.

0 The MAC receives all packets that are given by the PHY.

1 The MAC disables reception of frames when the TXEN is asserted.

The MAC ignores any loop backed receive packets.

This bit should be cleared when the full duplex mode bit is set or the Oper-

ating Mode is set to other than Normal Mode.

R/W 0

22:21 LM Loopback Operating Mode.

00 Normal Mode

01 Internal Loopback

10 External Loopback

11 Reserved

R/W 00

20 F Full Duplex Mode.

0 Half duplex mode

1 Full duplex mode

Note: Be sure to disable both the transmitter and receiver before changing

duplex modes.

R/W 0

19 PM Pass All Multicast.

0Normal

1 All incoming frames with a multicast destination address (first bit in

the destination address field is ‘1’) are received and the Filter Fail bit

reset.

Incoming frames with physical address destinations are filtered according

to HP (bit 13) and HO (bit 15).

R/W 0

18 PR Promiscuous Mode.

0Normal

1 Any incoming valid frame is received regardless of its destination

address.

The Filter Fail bit is always cleared in Promiscuous Mode.

R/W 1

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17 IF Inverse Filtering.

0Normal.

1 Physical addresses are checked with inverse filtering. In other words

if the address passes a perfect address filter, the frame is not passed;

if the address fails a perfect filter, the frame is passed.

This is valid only during perfect filtering mode.

R/W 0

16 PB Pass Bad Frames.

0Normal.

1 All incoming frames that passed the address filtering are received

including runt frames, collided frames, or truncated frames caused by

buffer overflow.

The Packet Filter bit is set for error frames that pass the Address filtering.

If all received bad frames are required, promiscuous mode (bit 18) should

be set.

R/W 0

15 HO Hash Only Filtering Mode.

0 Perfect address filtering mode for physical addresses.

1 Imperfect address filtering mode both for physical and multicast

addresses.

Setting this bit is valid only if HP=1.

R/W 0

14 — Reserved. Should be cleared. R 0

13 HP Hash/Perfect Filtering Mode.

0 Address Check block does a perfect address filter of incoming frames

according the address specified in the MAC Address register.

1 Address Check block does imperfect address filtering of multicast

incoming frames according to the hash table specified in the multicast

Hash Table Register. If the Hash Only (HO) bit is set, then physical

addresses are imperfectly filtered too. If the Hash Only bit (HO) is

reset, then physical addresses are perfect address filtered according

to the MAC Address Register.

R/W 0

12 LC Late Collision Control.

0 Abort frame transmission on a late collision.

1 Enable the retransmission of the collided frame even after the colli-

sion period (late collision).

In either case the Late Collision Status is appropriately updated in the

Transmit Packet Status.

This bit is valid only when operating in half duplex mode.

R/W 0

11 DB Disable Broadcast Frames.

0 Forward all the broadcast frames to the application. (Packet Filter bit

is set.)

1 Disable the reception of broadcast frames. (Packet Filter bit is

cleared.)

R/W 0

10 DR Disable Retry.

0 The MAC will attempt 16 transmissions before signaling a retry error.

1 The MAC will attempt transmission of a frame only once. When a col-

lision is seen on the bus, the MAC will ignore the current frame and

go to the next frame and a retry error will be reported in the Transmit

Status.

This bit is valid only when operating in half duplex mode.

R/W 0

9 — Reserved. Should be cleared. R 0

Bits Name Description R/W Default

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8 AP Automatic Pad Stripping.

0 Pass all the incoming frames to the host unmodified.

1 Strip the pad field on all the incoming frames if the length field is less

than 46 bytes. The FCS field is also stripped, because it is computed

at the transmitting station based on the data and pad field characters

and will therefore be invalid for a receive frame that has had the pad

characters stripped. Receive frames which have a length field of 46

bytes or greater will be passed to the host unmodified (FCS is not

stripped).

Pad stripping is done only on the IEEE 802.3 formatted frames (frames

with Length field).

R/W 0

7:6 BL Backoff Limit. The Backoff limit determines the integer number of slot

times the MAC waits before rescheduling a transmission attempt (during

retries after a collision).

R/W 00

5 DC Deferral Check.

0 The deferral check is disabled in the MAC and the MAC defers indef-

initely.

1 The deferral check is enabled in the MAC. The MAC will abort the

transmission attempt if it has deferred for more than 24,288 bit times.

Deferring starts when the transmitter is ready to transmit, but is pre-

vented from doing so because CRS is active. Defer time is not cumu-

lative. In other words, if the transmitter defers, then transmits,

collides, backs off, and then has to defer again after completion of

backoff, the deferral timer resets to 0 and restarts.

This bit is valid only when operating in half duplex mode.

R/W 0

4 — Reserved. Should be cleared. R 0

3 TE Transmitter Enable.

0 The MAC transmitter is disabled and will not transmit any frames on

the MII interface.

1 The MAC transmitter is enabled and it will transmit frames from the

buffer on to the MII interface.

R/W 0

2 RE Receiver Enable.

0 The MAC receiver is disabled and will not receive any frames from

the MII interface.

1 The MAC receiver is enabled and will receive frames from the MII

interface.

R/W 0

1:0 — Reserved. Should be cleared. R 0

Bits Name Description R/W Default

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6.5.2.2 MAC Address High and Low Registers

The MAC Address High Register contains the upper 16 bits of the physical address of the MAC. The MAC Address Low

It is the responsibility of the system designer to provide the MAC address for the system.

The MAC address will be compared with the destination address from the incoming frame with PADR[0] (bit 0 of the Mac

Address Low register) being compared with the first bit of the destination address and PADR[47] (bit 15 of the MAC

Address High register) compared with the 48th bit of the destination address.

Example: To program the MAC address 00.50.c2.0c.20.10 the MAC address registers should be programmed as follows:

mac_addrhigh = 0x00001020

mac_addrlow = 0x0CC25000

mac_addrhigh Offset = 0x0004

Bit31302928272625242322212019181716151413121110 9 8 7 6 5 4 3 2 1 0

PADR[47:32]

Def.00000000000000001111111111111111

Bits Name Description R/W Default

31:16 — Reserved. Should be cleared. R 0

15:0 PADR[47:32] Physical Address [47:32]. Contains the upper 16 bits (47 to 32) of the

Physical Address of the MAC.

R/W 0xFFFF

mac_addrlow Offset = 0x0008

Bit31302928272625242322212019181716151413121110 9 8 7 6 5 4 3 2 1 0

PADR[31:0]

Def.11111111111111111111111111111111

Bits Name Description R/W Default

31:0 PADR[31:0] Physical Address [31:0]. Contains the lower 32 bits (31 to 0) of the Phys-

ical Address of the MAC.

R/W 0xFFFFFFFF

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6.5.2.3 Multicast Address High Hash Table and Low Hash Table Register

The 64-bit multicast address hash table is used for group address filtering. For hash filtering, the contents of the destination

address in the incoming frame is passed through the CRC logic and the upper 6 bits of the CRC register are used to index

the contents of the Hash table. The most significant bit determines the register to be used (1 = Hi, 0 = Low), while the other

five bits determine the bit within the register. A value of ‘00000’ selects the bit 0 of the selected register and a value of

‘11111’ selects the bit 31 of the selected register.

If the corresponding bit in the hash table is '1', then the multicast frame is accepted, otherwise it is rejected. If the Pass All

Multicast is set, then all multi-cast frames are accepted regardless of the multi-cast hash values. The Multi Cast Hash Table

High Register contains the higher 32 bits of the hash table and the Multi Cast Hash Table Low Register contains the lower

32 bits of the hash table.

mac_hashhigh Offset = 0x000C

Bit31302928272625242322212019181716151413121110 9 8 7 6 5 4 3 2 1 0

MCH[63:32]

Def.00000000000000000000000000000000

Bits Name Description R/W Default

31:0 MCH[63:32] Multicast Address Hash Table High. These bits map to the upper 32 bits of

the 64-bit hash table.

R/W 0x00000000

mac_hashlow Offset = 0x0010

Bit31302928272625242322212019181716151413121110 9 8 7 6 5 4 3 2 1 0

MCH[31:0]

Def.00000000000000000000000000000000

Bits Name Description R/W Default

31:0 MCH[31:0] Multicast Address Hash Table Low. These bits map to the lower 32 bits of

the 64-bit hash table.

R/W 0x00000000

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6.5.2.4 MII Control Register

The MII Address Register is used to control and generate the Management cycles to the External PHY Controller chip. A

write to this register will generate a read/write access on the MII Management Interface (MDIO/MDC) bus to an external

PHY device.

6.5.2.5 MII Data Register

The MII Data Register contains the data to be written to the PHY register specified in the MII address register, or it contains

the read data from the PHY register whose address is specified in the MII address register.

mac_miictrl Offset = 0x0014

Bit31302928272625242322212019181716151413121110 9 8 7 6 5 4 3 2 1 0

PHYADDR[4:0] MIIREG[4:0] MW MB

Def.00000000000000000000000000000000

Bits Name Description R/W Default

31:16 — Reserved. Should be cleared. R 0

15:11 PHYADDR PHY Address. These bits tell which of the 32 possible PHY devices are

being accessed.

R/W 00000

10:6 MIIREG MII register. These bits select the desired MII register in the selected PHY

device.

R/W 00000

5:2 — Reserved. Should be cleared. R 0

1 MW MII Write.

0 Operation will be a read (data read is placed in MII Data Register)

1 Operation will be a write (data to be written is taken from MII Data

R/W 0

0 MB MII Busy. This bit should read a logic 0 before writing to the MII address

and MII data registers. This bit should be reset to 0 when writing to the MII

address register.

This bit will be set by the MAC to signify that a read or write access to the

external PHY is in progress. For a write operation the data register should

be kept valid until this bit is cleared by the MAC. For a read operation the

MII data register is invalid until this bit is cleared by the MAC.

The MII address register should not be modified until this bit is cleared.

The MAC clears this bit after the PHY access is done.

R/W 0

mac_miidata Offset = 0x0018

Bit31302928272625242322212019181716151413121110 9 8 7 6 5 4 3 2 1 0

MIIDATA[15:0]

Def.00000000000000000000000000000000

Bits Name Description R/W Default

31:16 — Reserved. Should be cleared. R 0

15:0 MIIDATA MII Data. 16-bit value read from the PHY after a MII read operation, or the

16-bit data value to be written to the PHY before a MII write operation.

R/W 0x0000

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6.5.2.6 Flow Control Register

This register is used to control the generation and reception of the Control (PAUSE Command) frames by the MAC’s Flow

control block. A write to this register with the busy bit set to ‘1’ triggers the Flow Control block to generate a PAUSE Control

frame. The fields of the control frame are selected as specified in the 802.3x specification with the Pause Time field from

this register used in the “Pause Time” field of the control frame. The Busy bit will remain set until the control frame is trans-

mitted. The Host has to insure that the Busy bit is cleared before writing to the register. The Pass Control Frames bit indi-

cates to the MAC whether or not to pass the control frame to the Host. The Flow Control Enable bit enables the receive

portion of the Flow Control block.

mac_flowctrl Offset = 0x001C

Bit31302928272625242322212019181716151413121110 9 8 7 6 5 4 3 2 1 0

PT[15:0] PC FE FB

Def.00000000000000000000000000000000

Bits Name Description R/W Default

31:16 PT Pause Time. This field will be used in the PAUSE TIME field in the genera-

tion of the PAUSE control frame.

R/W 0x0000

15:3 — Reserved. Should be cleared. R 0

2 PC Pass Control Frame.

0 The MAC decodes the control frames but does not pass the frames to

the Host. The Control Frame bit in the Receive Status (bit 25) is set

and the Transmitter Pause Mode signal gives the current status of

the Transmitter, but the PacketFilter bit in the Receive Status is reset

to signal the application to flush the frame.

1 Control frames are passed to the Host. The MAC decodes the control

frame (PAUSE) and disables the transmitter for the specified amount

of time. The Control Frame bit in the Receive Status (bit 25) is set,

and the Transmitter Pause Mode signal indicates the current state of

the MAC Transmitter.

R/W 0

1 FE Flow Control Enable.

0 The flow control operation in the MAC is disabled, and the MAC does

not decode the frames for control frames.

1 The MAC is enabled for flow control operation and it will decode all

the incoming frames for control frames. If the MAC receives a valid

control frame (PAUSE command), it will disable the transmitter for the

specified time.

This bit is valid only in full duplex mode.

R/W 0

0 FB Flow Control Busy Status. This bit should read a logic 0 before writing to

the Flow Control register. To initiate a PAUSE control frame the host must

set this bit. During a transfer of Control Frame, this bit remains set to sig-

nify that a frame transmission is in progress. After the completion of

PAUSE control frame transmission, the MAC clears FB.

R/W 0

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6.5.2.7 VLAN1 Tag Register

6.5.2.8 VLAN2 Tag Register

mac_vlan1 Offset = 0x0020

Bit31302928272625242322212019181716151413121110 9 8 7 6 5 4 3 2 1 0

VL1TAG[15:0]

Def.00000000000000001111111111111111

Bits Name Description R/W Default

31:16 — Reserved. Should be cleared. R 0

15:0 VL1TAG VLAN 1 Tag Identifier. This field will be compared with the 13th and 14th

bytes of the incoming frame. If a nonzero match occurs the VLAN 1 Frame

bit will be set in the receiver status packet. In addition, the legal length of a

frame is increased from 1518 bytes to 1522 bytes.

R/W 0xFFFF

mac_vlan2 Offset = 0x0024

Bit31302928272625242322212019181716151413121110 9 8 7 6 5 4 3 2 1 0

VL2TAG[15:0]

Def.00000000000000001111111111111111

Bits Name Description R/W Default

31:16 — Reserved. Should be cleared. R 0

15:0 VL2TAG VLAN 2 Tag Identifier. This field will be compared with the 13th and 14th

bytes of the incoming frame. If a nonzero match occurs the VLAN 2 Frame

bit will be set in the receiver status packet. In addition the legal length of a

frame is increased from 1518 bytes to 1538 bytes.

R/W 0xFFFF

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6.5.3 MAC Enable Registers

Each Ethernet MAC has an identical enable register. Both enable registers are located off of the macen_base shown in

Table 6-21.

6.5.3.1 MAC0 and MAC1 Enable

The enable register for each MAC contains a bit that enables the entire block. The block should be disabled if not in use to

minimize power consumption. In addition, each enable register contains a toss bit (TS) which prevents frames that do not

pass the address filter from being put into memory.

The process for bringing the MAC out of reset is as follows:

1) Enable clocks (CE=1).

2) Bring E[2:0] high together with the other bits configured as desired (keeping clocks enabled).

Note: MAC clocks must be running before the internal MAC registers are accessed.

macen_mac0 Offset = 0x0000

macen_mac1 Offset = 0x0004

Bit31302928272625242322212019181716151413121110 9 8 7 6 5 4 3 2 1 0

JP E2 E1 C TS E0 CE

Def.00000000000000000000000000000000

Bits Name Description R/W Default

31:7 — Reserved. Should be cleared. W 0

6 JP Jumbo Packet Enable.

0 Normal (Max packet length = 0x800 bytes)

1 Enable Jumbo Packet (Max packet length = 0x2800 bytes)

5:4 E[2:1] Enable field bits 2 and 1. Together with E0, this field resets and enables

the MAC.

000 Reset

111 Enable

All other combinations are invalid.

W00

3 C Coherent.

0 Memory accesses are marked coherent on SBUS

1 Memory accesses are marked non coherent on SBUS

For more information on coherency see Section 2.8.2 "SBUS Coherency

Model" on page 41.

2TS Disable Toss.

0 Only frames passing the address filter are passed to memory.

Frames which fail length error, CRC error, or other non-address filter

failures are still passed to memory.

Frames are not passed to memory if the filter fail bit is set, or the

frame is a broadcast frame and broadcast frames have been dis-

abled.

In promiscuous mode all frames are passed to memory unless the

disable broadcast bit is set which prevents broadcast frames from

being passed to memory.

Frames that are not passed to memory are transparent to software—

no status or indication informs software.

1 All frames are passed to memory, regardless of address filter result.

W UNPRED

1 E[0] Enable field bit 0. See description for E[2:1]. W 0

0 CE Clock Enable.

0 Clocks disabled to MAC

1 Clocks enabled to MAC

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6.5.4 MAC DMA Registers

Each MAC has four DMA buffers for both receive and transmit (4 for RX, 4 for TX). The DMA buffers are serviced in a

round-robin fashion. Each MAC has a 32-word FIFO for both transmit and receive. The transfer size for the MAC DMA is 8

words. Both the FIFO size and transfer size are taken care of automatically by the MAC DMA and are transparent to the

programmer except that all memory buffers must be implemented on a cache line boundary (32 bytes).

The MAC DMA registers can be described as a set of transmit and receive entries off of the MAC DMA base addresses

shown in Table 6-21.

Each MAC DMA base address contains 8 entries which correspond to 4 transmit buffer entries and 4 receive buffer entries

as shown in Table 6-23.

Within each receive entry there are 2 registers implemented as shown in Table 6-24. (The third and fourth reserved entries

are shown for completeness but are not used.)

Within each transmit entry, there are three registers implemented as shown in Table 6-25. (The fourth reserved entry is

shown for completeness but is not used.)

Table 6-23. MAC DMA Entries

Offset Entry Prefix Entry Name

0x000 tx0 Transmit Buffer 0

0x010 tx1 Transmit Buffer 1

0x020 tx2 Transmit Buffer 2

0x030 tx3 Transmit Buffer 3

0x100 rx0 Receive Buffer 0

0x110 rx1 Receive Buffer 1

0x120 rx2 Receive Buffer 2

0x130 rx3 Receive Buffer 3

Table 6-24. MAC DMA Receive Entry Registers

Offset Receive Entry Register Description

0x0 stat Status register

0x4 addr Address/enable register

0x8 Reserved Nothing is implemented at this offset.

0xC Reserved Nothing is implemented at this offset.

Table 6-25. MAC DMA Transmit Entry Registers

Offset Transmit Entry Register Description

0x0 stat Status register

0x4 addr Address/enable register

0x8 len Length register

0xC Reserved Nothing is implemented at this offset.

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To calculate the address of a specific MAC DMA buffer all offsets should be combined. For example the physical address of

the MAC1 receive buffer 3 address register is calculated as follows:

macdma1_rx3addr = macdma1_base + rx3 + addr

= 0x0 1400 4200 + 0x130 + 0x4

= 0x0 1400 4334

Another way to look at the DMA register addresses is to view them as built off of the base address using an indexed

approach to build the address for each unique register within the block. In other words, each bit (or set of bits) within the

address will select a parameter of the DMA Register (TX/RX, Buffer number, Status/Address/Length register) until a unique

address is formed selecting a single register.

To build the address for a unique register the bits should be set according to the definitions in Table 6-26.

The enumerated DMA registers are shown in Section A.1 "Memory Map" on page 267.

Table 6-26. MAC DMA Block Indexed Address Bit Definitions

Address Bits Description

8TX/RX.

0 Transmit Block

1 Receive Block

7:6 These bits should be cleared.

5:4 MAC DMA Buffer.

00 Buffer 0

01 Buffer 1

10 Buffer 2

11 Buffer 3

3:2 Register Select.

00 Status Register

01 Address/Enable Register

10 Length Register (valid for transmit only)

11 Reserved

1:0 These bits should be cleared because the registers are aligned on a word boundary.

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MAC DMA Receive Registers

There are two receive registers for each DMA channel associated with each MAC: the status register and the address/

enable register. The length register is not applicable to the receive DMA channel, as the length will be determined by the

size of the received packet (typically the size of a frame for a complete, successful reception). The receive memory buffers

should be 0x800 bytes when Jumbo Packets are not enabled and to 0x2800 when Jumbo packets are enabled. This will

allow for the worst case maximum reception length.

In the naming of the receive registers dummy variables m and n have been inserted into the name to designate MAC num-

ber (m) and buffer number (n).

6.5.4.1 Receive Status

This register contains the receive packet status bits sent by the MAC after receiving a frame. This register is only valid after

a receive transaction has been enabled by the host and the done bit has been set by the MAC in the Address/Enable Reg-

ister to indicate that the transaction is complete.

The MI bit should be checked by software after receiving a frame to verify that the received frame is valid.

macdma0_rxnstat offset = 0x0

Bit313029282726252423222120191817161514131211109876543210

MI PF FF BF MF UC CF LE V2 V1 CR DB ME FT CS FL RF WT L[13:0]

Def.XXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXX

Bits Name Description R/W Default

31 MI Missed Frame.

0 The frame is received normally by the Application without any latency

or error violations

1 Indicates that a frame was missed due to an internal FIFO overrun.

R UNPRED

30 PF Packet Filter.

0 Indicates that the current frame failed the packet filter.

1 Indicates that the current frame passed the packet filter that is imple-

mented in the MAC.

Packet Filter will indicate failed frame when any of the following conditions

happens.

a. FF = 0 and frame is not a Broadcast or RA is 1

b. Frame is Broadcast and DB is 0

c. Frame is not Control Frame or PC is 1

d. No Error Status or PB Frames is 1

e. Unsupported Control Frame is 0

The Application can use this bit to decide whether to keep the packet in

the memory or flush the packet from the memory.

Note that frames with length greater than max Ethernet size (1500 bytes-

normal, 1518 bytes - VLAN1, 1538 bytes - VLAN2) will create an error sta-

tus thus failing the packet filter. The frames may still be valid with failure

only due to frame size.

R UNPRED

29 FF Filtering Fail.

0 Current frame passed address filtering

1 Destination Address field in the current frame failed the Address filter-

ing.

R UNPRED

28 BF Broadcast Frame.

0 Destination address is not Broadcast.

1 Destination address is all 1’s indicating broadcast address.

R UNPRED

27 MF Multicast Frame.

0 Destination address is not multicast.

1 Destination address is multicast (the first bit is 1).

R UNPRED

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26 UC Unsupported Control Frame.

0 If the Control Frame bit is set, this bit indicates a supported control

frame has been received (Pause Frame).

1 The MAC observed an unsupported Control Frame. This is set when

a control frame is received and the opcode field is unsupported, or

the length is not equal to minFrameSize (64 bytes). This bit is set only

when the MAC is operating in the full-duplex mode.

R UNPRED

25 CF Control Frame.

0 Current frame is not a control frame.

1 Current frame is a control frame. This bit is only set when operating in

Full Duplex mode.

R UNPRED

24 LE Length Error.

0 No length error occurred.

1 The current frame Length value is inconsistent with the total number

of bytes received in the current frame. When the number of bytes

received in the data field are more than what indicated in the Length/

Type field, the additional bytes are assumed to be PAD bytes and the

Length Error bit is not set. When the number of bytes received in the

data field is less than what was indicated in the Length/Type field, the

Length Error bit is set. This is valid when the Frame Type is set to ’0’

(802.3 Frame).

This bit is not applicable for frame lengths greater than max Ethernet size

(1500 bytes- normal, 1518 bytes - VLAN1, 1538 bytes - VLAN2).

R UNPRED

23 V2 VLAN2 ID.

0 No match with VLAN2 tag.

1 The current frame is tagged with a VLAN2 ID. The thirteenth and

fourteenth bytes of the frame were a nonzero match with the VLAN2

tag register.

R UNPRED

22 V1 VLAN1 ID.

0 No match with VLAN1 tag.

1 The current frame is tagged with a VLAN1 ID. The thirteenth and

fourteenth bytes of the frame were a nonzero match with the VLAN1

tag register.

R UNPRED

21 CR CRC Error.

0 No CRC error in current frame.

1 CRC error occurred in received frame.

This bit is not applicable for frame lengths greater than max Ethernet size

(1500 bytes- normal, 1518 bytes - VLAN1, 1538 bytes - VLAN2). If a CRC

check is required it must be done in software.

R UNPRED

20 DB Dribbling Bit.

0 An integer multiple of eight bits was received.

1 A non-integer multiple of eight bits was received. This bit is not valid if

either the Collision Seen bit or Runt Frame bit is set. If this bit is set

and the CRC Error bit is 0, then the packet is still valid.

R UNPRED

19 ME MII Error.

0 No MII error.

1 MII error during frame reception.

R UNPRED

18 FT Frame Type.

0 IEEE 802.3 Frame.

1 Ethernet-type frame (frame length field is greater than max Ethernet

size (1500 bytes- normal, 1518 bytes - VLAN1, 1538 bytes - VLAN2).

This bit is still applicable when Jumbo packets are enabled.

This bit is not valid for runt frames of less than 14 bytes.

R UNPRED

Bits Name Description R/W Default

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17 CS Collision Seen.

0 No collision seen during frame reception.

1 The frame was damaged by a collision that occurred after the 64

bytes following the start of frame delimiter (SFD). This is a late colli-

sion.

R UNPRED

16 FL Frame Too Long.

0 Frame size is less than or equal to max Ethernet frame size (1500

bytes- normal, 1518 bytes - VLAN1, 1538 bytes - VLAN2).

1 Frame size is greater than the maximum Ethernet specified size

(1500 bytes- normal, 1518 bytes - VLAN1, 1538 bytes - VLAN2). This

also applies when Jumbo packets are enabled.

Frame too long is only a length indication and does not cause frame trun-

cation.

R UNPRED

15 RF Runt Frame.

0 Frame was not damaged in collision window.

1 Frame was damaged by a collision or premature termination before

the collision window passed.

R UNPRED

14 WT Watchdog Timeout.

0 Frame was received before timeout occurred.

1 The receive watchdog timer expired while receiving the frame. The

watchdog timer inside the MAC is programmed to be twice the Max-

FrameLength. When set, the Frame Length field is invalid.

Any time the max frame length is exceeded (0x800 bytes for normal mode,

0x2800 with Jumbo packets enabled) the WT bit will be set.

R UNPRED

13:0 L[13:0] Frame Length. Indicates length in bytes of the received frame. The host

should take into account how the Automatic Pad Stripping (AP) bit in the

corresponding MAC control register is set, as this will affect how the length

field and frame contents should be interpreted.

R UNPRED

Bits Name Description R/W Default

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6.5.4.2 Receive Buffer Address/Enable Register

This register contains the starting address for the receive buffer. The host should ensure that the memory buffer is set up to

accommodate the worst case largest frame size to be able to handle all received packets. At worst case the MAC will

receive 0x800 bytes before aborting a receive in normal mode or 0x2800 bytes when Jumbo packets have been enabled in

the macen_macn register.

After the transaction has been enabled this register should not be written until the DN bit has been set.

The buffer for the DMA must be cache line aligned so the lowest 5 bits are not used as part of the address. These bits have

been employed as done and enable bits that are exclusive of the address.

macdma0_rxnaddr offset = 0x4

Bit313029282726252423222120191817161514131211109876543210

ADDR[31:5] CB DN EN

Def.0000000000000000000000000000XXXX

Bits Name Description R/W Default

31:5 ADDR Buffer Address. Upper 27 bits of the starting physical address for the DMA

buffer. This address must be cache line (32 bytes) aligned so only 27 bits

are used. This address must be written for each DMA transaction (the

address will not remain after the transaction is enabled)

R/W 0

4 — Reserved. Should be cleared. R 0

3:2 CB Current Buffer. Current DMA Receive Buffer R UNPRED

1 DN Transaction Done. This bit will be set by hardware to indicate that the

receive transaction has been completed and that the receive packet status

is valid.

If the respective MAC DMA interrupt is enabled (see Section 5.0 "Interrupt

Controller" on page 81), an interrupt will be generated when this bit is set.

Done bits for all TX and RX buffers are or’ed together for this interrupt so a

high level interrupt should be used.

This bit must be cleared explicitly by software after checking for done. This

will also clear the interrupt.

R/W UNPRED

0 EN MAC DMA Enable. When set, this bit enables a DMA receive transaction

to the memory location designated in ADDR.

R/W UNPRED

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Ethernet MAC Controller 30360E

MAC DMA Transmit Registers

There are three transmit registers, including the status register, the address/enable register, and the length register. In the

naming of the receive registers dummy variables m and n have been inserted into the name to designate MAC number (m)

and buffer number (n).

6.5.4.3 Transmit Packet Status Register

This register contains the transmit packet status bits sent by the MAC after transmitting a frame. This register is valid after a

transmit transaction has been enabled by the host and the done bit has been set by the MAC in the Address/Enable Regis-

ter to signify that the transmit transaction is complete.

If either PR (bit 31) or FA (bit 0) is set then the frame was not sent successfully and the application should resend the frame.

macdmam_txnstat offset = 0x0

Bit31302928272625242322212019181716151413121110 9 8 7 6 5 4 3 2 1 0

PR CC LO DF UR EC LC ED LS NC JT FA

Def.XXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXX

Bits Name Description R/W Default

31 PR Packet Retry.

0 Transmission of current packet is complete.

1 The Application has to restart the transmission of the frame (packet)

when this bit is set to ‘1’. The successful/unsuccessful completion of

the frame’s transmission is indicated by the Frame Aborted bit (bit 0).

R UNPRED

30:14 — These bits are reserved. R UNPRED

13:10 CC Collision Count. This 4-bit count indicates the number of collisions that

occurred before the frame was transmitted. This bit is not valid when the

Excessive Collisions bit is set.

This bit is valid only when the MAC is operating in half-duplex mode.

R UNPRED

9 LO Late Collision Observed

0 No late collision observed during transmission.

1 Indicates that the MAC observed a late collision (collision after 64

bytes into transmission of frame), but retransmitted the frame in the

next retransmission attempt. This bit will be set when the Late Colli-

sion bit is set.

This bit is valid only when the MAC is operating in half-duplex mode.

R UNPRED

8 DF Deferred.

0 Transmitter did not defer when transmitting.

1 The transmitter had to defer while ready to transmit a frame.

This bit is valid only when operating in half-duplex mode.

R UNPRED

7 UR Under Run.

0 No data under run.

1 The transmitter aborted the message because of data under run dur-

ing the frame’s transmission.

R UNPRED

6 EC Excessive Collisions.

0 Transmission did not abort due to excessive collisions.

1 Transmission aborted after 16 successive collisions. If the Disable

Retry bit is set, this bit is set after the first collision and the transmis-

sion of the frame will be aborted.

This bit is valid only when operating in half-duplex mode.

R UNPRED

5 LC Late Collision.

0 No late collision.

1 Transmission was aborted due to collision occurring after the collision

window of 64 bytes. This bit is not valid if under run error is set.

This bit is valid only when operating in half-duplex mode.

R UNPRED

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4 ED Excessive Deferral.

0 No excessive deferral.

1 Transmission has ended because of excessive deferral of over

24,288 bit times during the transmission, if the defer bit is set high in

the control register.

This bit is valid only when operating in half-duplex mode.

R UNPRED

3 LS Loss of Carrier.

0 No loss of carrier.

1 The loss of carrier occurred during the frame's transmission (i.e., the

CRS input was inactive for one or more bit times when the frame is

being transmitted).

This bit is valid only when operating in half-duplex mode.

R UNPRED

2NC No Carrier.

0 Carrier present.

1 The carrier signal from the transceiver was not present during trans-

mission.

This bit is valid only when operating in half-duplex mode.

R UNPRED

1 JT Jabber Timeout.

0 No jabber timeout.

1 The MAC transmitter has been active for an abnormally long time

(twice the Ethernet maxFrameLength size).

R UNPRED

0 FA Frame Aborted.

0 Current frame was successfully transmitted.

1 The transmission of the current frame has been aborted by the MAC

because of one or more of the following conditions:

Jabber Timeout (bit 1)

No Carrier (bit 2)

Loss of Carrier (bit 3)

Excessive Deferral (bit 4)

Late Collision (bit 5)

Retry Count exceeds the attempt limit (bit 6).

Data under run (bit 7)

R UNPRED

Bits Name Description R/W Default

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6.5.4.4 Transmit Buffer Address/Enable Register

This register contains the starting address for the transmit memory buffer. The MAC DMA transfers the number of bytes

designated in the Length register.

The buffer for the DMA must be cache line aligned so the lowest 5 bits are not used as part of the address. These bits have

been employed as done and enable bits and are exclusive of the address.

6.5.4.5 Transmit Buffer Length Register

This register contains the length of the memory buffer in bytes to be transmitted.

macdmam_txnaddr offset = 0x4

Bit313029282726252423222120191817161514131211109876543210

ADDR[31:5] CB DN EN

Def.0000000000000000000000000000XXX0

Bits Name Description R/W Default

31:5 ADDR Buffer Address. Upper 27 bits of the starting physical address for the DMA

buffer—but not including the most significant nibble address bits 35:32.

This address must be cache line (32 bytes) aligned so only 27 bits are

used.

Note: This address must be written for each DMA transaction (the address

will not remain after the transaction is enabled).

R/W 0

4 — Reserved. Should be cleared. R 0

3:2 CB Current Buffer. Current DMA Transmit Buffer R UNPRED

1 DN Transaction Done. This bit will be set by hardware to indicate that the

transmit transaction has been completed and that the transmit packet sta-

tus is valid.

If the respective MAC DMA interrupt is enabled (see Section 5.0 "Interrupt

Controller" on page 81), an interrupt will be generated when this bit is set.

Done bits for all TX and RX buffers are or’ed together for this interrupt so a

high level interrupt should be used.

This bit must be cleared explicitly by software after checking for done. This

will also clear the interrupt.

R/W UNPRED

0 EN MAC DMA Enable. When set, this bit enables a DMA transmit transaction

from the memory location designated in ADDR.

R/W

macdmam_txnlen offset = 0x8

Bit313029282726252423222120191817161514131211109876543210

LEN[13:0]

Def.00000000000000000000000000000000

Bits Name Description R/W Default

31:14 — Reserved. Should be cleared. R 0

13:0 LEN Buffer Length. This field sets the length of the memory buffer (in bytes).

When the normal bit is set, the length can only be up to 0x800 bytes.

When the Jumbo packets are enabled in the enable register, the length

can be set up to 0x2800 bytes.

R/W 0

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6.5.5 Hardware Connections

Table 6-27 shows the signals associated with the two Ethernet MAC MII interfaces.

Table 6-27. Ethernet Signals

Signal Input/Output Description

Ethernet Controller 0 (MAC0)

N0TXCLK I Continuous clock input for synchronization of transmit data. 25 MHz when operating

at 100-Mbps and 2.5 MHz when operating at 10 Mbps.

N0TXEN O Indicates that the data nibble on N0TXD[3:0] is valid.

N0TXD[3:0] O Nibble wide data bus synchronous to N0TXCLK. For each N0TXCLK period in

which N0TXEN is asserted, TXD[3:0] will have the data to be accepted by the PHY.

While N0TXEN is de-asserted the data presented on TXD[3:0] should be ignored.

N0RXCLK I Continuous clock that provides the timing reference for the data transfer from the

PHY to the MAC. N0RXCLK is sourced by the PHY. The N0RXCLK shall have a

frequency equal to 25% of the data rate of the received signal data stream (typically

25 MHz at 100 Mb/s and 2.5 MHz at 10 Mb/s).

N0RXDV I Active high. Indicates that a receive frame is in process and that the data on

N0RXD[3:0] is valid.

N0RXD[3:0] I RXD[3:0] is a nibble wide data bus driven by the PHY to the MAC synchronous with

N0RXCLK. For each N0RXCLK period in which N0RXDV is asserted, RXD[3:0] will

transfer four bits of recovered data from the PHY to the MAC. While N0RXDV is de-

asserted, RXD[3:0] will have no effect on the MAC.

N0CRS I N0CRS shall be asserted by the PHY when either transmit or receive medium is

non Idle. N0CRS shall be de-asserted by the PHY when both the transmit and

receive medium are Idle. N0CRS is an asynchronous input.

N0COL I N0COL shall be asserted by the PHY upon detection of a collision on the medium,

and shall remain asserted while the collision condition persists. N0COL is an asyn-

chronous input. The N0COL signal is ignored by the MAC when operating in the full

duplex mode.

N0MDC O N0MDC is sourced by the MAC to the PHY as the timing reference for transfer of

information on the N0MDIO signal. N0MDC is an aperiodic signal that has no maxi-

mum high or low times. The N0MDC frequency is fixed at SBUS clock divided by

160.

N0MDIO IO N0MDIO is the bidirectional data signal between the MAC and the PHY that is

clocked by N0MDC.

Ethernet Controller 1 (MAC1)

N1TXCLK I Continuous clock input for synchronization of transmit data. 25 MHz when operating

at 100 Mbps and 2.5 MHz when operating at 10 Mbps.

N1TXEN O Indicates that the data nibble on N1TXD[3:0] is valid.

Muxed with GPIO[24]. N1TXEN is the default signal coming out of hardware reset,

runtime reset, and Sleep.

N1TXD[3:0] O Nibble wide data bus synchronous to N1TXCLK. For each N1TXCLK period in

which N1TXEN is asserted, TXD[3:0] will have the data to be accepted by the PHY.

While N1TXEN is de-asserted the data presented on TXD[3:0] should be ignored.

Muxed with GPIO[28:25]. N1TXD[3:0] are the default signals coming out of hard-

ware reset, runtime reset, and Sleep.

N1RXCLK I Continuous clock that provides the timing reference for the data transfer from the

PHY to the MAC. N1RXCLK is sourced by the PHY. The N1RXCLK shall have a

frequency equal to 25% of the data rate of the received signal data stream (typically

25 MHz at 100 Mbps and 2.5 MHz at 10 Mbps)

AMD Alchemy™ Au1000™ Processor Data Book 143

Ethernet MAC Controller 30360E

MAC1 shares its pins with GPIO[28:24]; these pins must be assigned to MAC1 in order to use MAC1. See Section 7.3

"General Purpose I/O and Pin Functionality" on page 183 for more information.

N1RXDV I Indicates that a receive frame is in process and that the data on N1RXD[3:0] is

valid.

N1RXD[3:0] I RXD[3:0] is a nibble wide data bus driven by the PHY to the MAC synchronous with

N1RXCLK. For each N1RXCLK period in which N1RXDV is asserted, RXD[3:0] will

transfer four bits of recovered data from the PHY to the MAC. While N1RXDV is de-

asserted, RXD[3:0] will have no effect on the MAC.

N1CRS I N1CRS shall be asserted by the PHY when either transmit or receive medium is

non Idle. N1CRS shall be de-asserted by the PHY when both the transmit and

receive medium are Idle. N1CRS is an isochronous input.

N1COL I N1COL shall be asserted by the PHY upon detection of a collision on the medium,

and shall remain asserted while the collision condition persists. N1COL is an asyn-

chronous input. The N1COL signal is ignored by the MAC when operating in the full

duplex mode.

N1MDC O N1MDC is sourced by the MAC to the PHY as the timing reference for transfer of

information on the N1MDIO signal. N1MDC is an aperiodic signal that has no maxi-

mum high or low times. The N1MDC frequency is fixed at SBUS clock divided by

160.

N1MDIO IO N1MDIO is the bidirectional data signal between the MAC and the PHY that is

clocked by N1MDC.

Table 6-27. Ethernet Signals (Continued)

Signal Input/Output Description

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30360E

6.5.6 Programming Considerations

The Ethernet MAC is designed such that the application could use a pool of memory buffers for both the transmit and

receive functions.

The lowest level device driver would respond to the MAC DMA interrupt and swap out the filled DMA buffers for those that

are empty for the receive case. For the transmit case the driver should provide ready to transmit buffers to the DMA while

reclaiming empty buffers. Four transmit and receive DMA buffers are allocated for each MAC to allow for latency to service

the lowest level MAC DMA interrupt.

At the next level in software the device driver can parse the valid data out of the frame for receive, or build the frame for

transmit. The number of memory buffers needed in the pool will depend on how fast the parsing can occur for worst case

receive bursts, and any minimum transmit latency requirements.

From this level the application or protocol stack can take the data and apply it as needed.

6.5.6.1 Initialization

This section demonstrates the functional requirements for getting the MAC running. This assumes that the programmer has

already performed the Au1000 bringup.

1) Interrupt Controller - a high level interrupt should be used as the interrupt is triggered with an OR’ing of the DN (Done)

bits.

2) DMA Controller Setup

3) MAC Registers - It is the system designer’s responsibility to set up addresses.

4) Memory - Depending on how the system is built, there could be a pool of memory buffers which can be used for pars-

ing and building of frames. Individual buffers would be swapped in and out of the 4 active receive and transmit DMA

buffers as needed. This strategy would require some sort of minimal memory management within the Ethernet driver to

insure chronology of Ethernet frames.

The following is a transmit example in a basic form. Typically this would be split between an interrupt handler and another

higher layer.

1) Construct Frame

2) Set length in macdmam_txnlen register

3) Set address of memory buffer and enable transmit. During this time the physical memory buffer and address and

length registers should not be disrupted or transmit contents will be undefined.

4) Wait for done. This can be done by waiting for the interrupt handler or polling the done signal in the

macdmam_txnaddr register.

5) Read status. Its validity is signaled by the reception of the done signal.

The following is a basic receive example:

1) Enable all receive buffers with four different memory buffer addresses.

2) Wait for interrupt. Conversely the done bit could be polled. During this time the physical memory buffer and address

registers should not be disrupted or receive contents will be undefined.

3) Replace all full buffers with empty memory buffers.

4) Read Status for full buffers.

5) Parse frames.

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I2S Controller 30360E

6.6 I2S Controller

The Au1000 contains an I2S controller capable of interfacing with a codec or a discreet DAC and ADC. The I2S interface

works in two different modes: unidirectional data mode and bidirectional data mode.

In unidirectional data mode the I2SDI signal is not used. In this mode the I2SDIO signal can be configured as an input or an

output and can be used with either an ADC or a DAC at any one time.

In bidirectional mode the I2SDIO signal is configured as an output and used in conjunction with I2SDI to interface the port

to a CODEC or discreet ADC and DAC.

The port will only support one input at any one time. In other words, I2SDIO can not be enabled as an input at the same

time I2SDI is being used.

6.6.1 I2S Register Descriptions

The I2S interface is controlled by a register block whose physical base address is shown in Table 6-28.

The I2S register block consists of 3 registers as shown in Table 6-29 with the base address from Table 6-28.

6.6.1.1 I2S Data

The I2S Data register is the input to the transmit FIFO when written to and the output from the receive FIFO when read

from. Each FIFO is 12 words deep.

Care should be taken to monitor the status register to insure that there is room for data for a write or data in the FIFO for a

read transaction.

The FIFO is for both the left and the right channels. For this reason data should be read from and written to the FIFO in

pairs. The programmer should insure that data is written to the FIFO corresponding to how the Justification, Initial Channel,

and Size is configured. If the sample size being written or read is different than the size being configured, the programmer

should justify the data accordingly.

Table 6-28. I2S Base Address

Name Physical Base Address KSEG1 Base Address

i2s_base 0x0 1100 0000 0xB100 0000

Table 6-29. I2S Interface Register Block

Offset Register Name Type Description

0x0000 i2s_data R/W Input and output from data FIFOs

0x0004 i2s_config R/W Configuration and status register

0x0008 i2s_enable R/W Allows port to be enabled and disabled

i2s_data - TX/RX Data Offset = 0x0000

Bit 313029282726252423222120191817161514131211109876543210

DATA[23:0]

Def. 00000000000000000000000000000000

Bits Name Description R/W Default

31:24 — Reserved. Should be cleared. R 0

23:0 DATA Data word up to 24 bits. When written, this field is the transmit data. When

read, this field is the receive data.

R/W

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6.6.1.2 Configuration and Status Register

The I2S Interface Configuration and Status register contains status bits for the transmit and receive FIFOs, and configura-

tion bits for the interface.

i2s_config - Configuration and Status Offset = 0x0004

Bit 313029282726252423222120191817161514131211109876543210

XU XO RU RO TR TE TF RR RE RF ICK PD LB IC FM TN RN SZ

Def. 00000000000000000000000000000000

Bits Name Description R/W Default

31:26 — Reserved. Should be cleared. R 0

25 XU Transmit FIFO underflow status.

0 No underflow.

1 Underflow error condition.

This sticky bit is cleared by writing a ‘0’ to it. Because this register is also

used for configuration, mask this bit with a ‘1’ to preserve its value if

needed.

R/W 0

24 XO Transmit FIFO overflow status.

0 No overflow.

1 Overflow error condition.

This sticky bit is cleared by writing a ‘0’ to it. Because this register is also

used for configuration, mask this bit with a ‘1’ to preserve its value if

needed.

R/W 0

23 RU Receive FIFO underflow status.

0 No underflow.

1 Underflow error condition.

This sticky bit is cleared by writing a ‘0’ to it. Because this register is also

used for configuration, mask this bit with a ‘1’ to preserve its value if

needed.

R/W 0

22 RO Receive FIFO overflow status.

0 No overflow.

1 Overflow error condition.

This sticky bit is cleared by writing a ‘0’ to it. Because this register is also

used for configuration, mask this bit with a ‘1’ to preserve its value if

needed.

R/W 0

21 TR Transmit Request. This bit indicates that the transmit FIFO has at least 4

samples of space to accommodate a burst write.

20 TE Transmit Empty. This bit indicates that the transmit FIFO is empty. R 0

19 TF Transmit Full. This bit indicates the transmit FIFO is full. R 0

18 RR Receive Request. This bit indicates that the receive FIFO has at least 4

samples in it to accommodate a burst read.

17 RE Receive Empty. This bit indicates that the receive FIFO is empty. R 0

16 RF Receive Full. This bit indicates that the receive FIFO is full. R 0

15:13 — Reserved. Should be cleared. R 0

12 ICK Invert Clock.

0 Data is valid on falling edge.

1 Data is valid on rising edge.

R/W 0

11 PD Pin Direction. Configures the direction of the I2SDIO signal.

0 I2SDIO is an output—for unidirectional or bidirectional operation. For

the unidirectional transmit case, do not use I2SDI. Note also in this

case that the GPIO[8] function (which is muxed with I2SDI) can be

used only as an output unless the I2S receive function is disabled

(RN=0).

1 I2SDIO is an input—for unidirectional operation only. Do not use

I2SDI. Note also in this unidirectional receive case that the GPIO[8]

function (which is muxed with I2SDI) can be used only as an output.

R/W 0

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I2S Controller 30360E

10 LB Loopback. When set this bit will enable a loop back mode where data com-

ing on the input will be presented on the output.

R/W 0

9 IC Initial Channel.

0 The left sub channel is the first presented. This means that data will

not be presented until the word clock is the correct polarity for left as

described in Format.

1 The right sub channel is the first presented. This means that data will

not be presented until the word clock is the correct polarity for right

(as described in the Format section of this table).

R/W 0

8:7 FM Format. The following formats are supported:

00 I2S mode. In this mode the first bit of a sample word will be presented

after one I2SCLK delay from the transition of I2SWORD. The left

sample data will be presented when the word clock is low. The data is

presented MSB first.

01 Left Justified mode. In this mode the first bit of a sample word will be

presented on the first I2SCLK after an I2SWORD transition. The left

sample data will be presented when the word clock is high. The data

is presented MSB first.

10 Right Justified mode. In this mode the first bit of a sample word will be

presented on the first I2SCLK after an I2SWORD transition. The left

sample data will be presented when the word clock is high. The data

is presented LSB first.

11 Reserved.

R/W 00

6 TN Transmit Enable. This will enable the transmit FIFO and must be enabled

if the output is being used.

0 Disable transmit FIFO.

1 Enable transmit FIFO.

R/W 0

5 RN Receive Enable. This will enable the receive FIFO and must be enabled if

either of the inputs are being used.

0 Disable receive FIFO.

1 Enable receive FIFO.

R/W 1

4:0 SZ Size. These bits will set the size of the sample word. The following combi-

nations are valid:

01000 8-bit words

10000 16-bit words

10010 18-bit words

10100 20-bit words

11000 24-bit words

If using DMA it is important that memory is packed consistently with the

transfer width programmed for the DMA channel and the Size field.

R/W 10010

Bits Name Description R/W Default

148 AMD Alchemy™ Au1000™ Processor Data Book

I2S Controller

30360E

6.6.1.3 I2S Enable

The I2S Block Control register is used to enable clocks to and reset the entire I2S block.

The suggested power on reset is as follows:

1) Set both CE and D.

2) Clear D for to enable the peripheral.

6.6.2 Hardware Considerations

Table 6-30 shows the signals associated with this port.

i2s_enable - I2S Block Control Offset = 0x0008

Bit 313029282726252423222120191817161514131211109876543210

DCE

Def. 00000000000000000000000000000010

Bits Name Description R/W Default

31:2 — Reserved. Should be cleared. W 0

1 D Disable. Setting this bit will disable the I2S block. After enabling the clock

with CE, this bit should be cleared for normal operation.

0 CE Clock Enable. This bit should be set to enable the clock driving the I2S

block. It can cleared to disable the clock for power considerations.

Table 6-30. I2S Signals

Signal Input/Output Description

I2SCLK O Serial bit clock.

Muxed with GPIO[30]. I2SCLK is the default signal coming out of hardware reset,

runtime reset, and Sleep.

I2SWORD O Word clock typically configured to the sampling frequency (Fs).

Muxed with GPIO[31]. I2SWORD is the default signal coming out of hardware

reset, runtime reset, and Sleep.

I2SDI I Serial data input sampled on the rising edge of I2SCLK. Note that I2SDI is used as

the input for bidirectional operation only, in which case it is used in conjunction with

I2SDIO as the output (i2s_config[PD]=0).

Muxed with GPIO[8]. GPIO[8] is the default signal coming out of hardware reset,

runtime reset, and Sleep.

System Note: For systems that use the I2S interface for unidirectional operation

(I2SDI not used), the GPIO[8] function is available but with the following restric-

tions:

When I2SDIO is configured as an input, GPIO[8] can be used only as an output.

When I2SDIO is configured as an output, the I2S receive function must be dis-

abled if GPIO[8] is to be used as an input.

I2SDIO IO Configurable as input or output. As input, data should be presented on rising edge.

As output, data is valid on the rising edge.

Muxed with GPIO[29]. I2SDIO is the default signal coming out of hardware reset,

runtime reset, and Sleep.

EXTCLKnO This is the system audio clock and typically is programmed to 256 * Fs (where Fs is

the sampling frequency for the system). The system audio clock should be taken

from EXTCLK0 or EXTCLK1 because these signals are synchronous to I2SCLK

and I2SWORD. These clocks are programmed individually; see Section 7.1

"Clocks" on page 168.

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For changing pin functionality, see the sys_pinfunc register description in Section 7.3 "General Purpose I/O and Pin Func-

tionality" on page 183.

6.6.3 Programming Considerations

It is the programmer’s responsibility to set up DMA channels, and the clocks (I2SCLK and the EXTCLKn) to be used with

the system.

The I2SWORD clock, which is typically equal to the sampling frequency, is a function of the word width and the I2SCLK fre-

quency. I2SCLK and EXTCLKn are programmable as described in Section 7.1 "Clocks" on page 168. The EXTCLKn sig-

nals are the external clocks available on the pins shared with GPIO[2] and GPIO[3].

150 AMD Alchemy™ Au1000™ Processor Data Book

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6.7 UART Interfaces

The Au1000 contains four UART interfaces. Each UART has the following features:

•5 - 8 Data Bits

•1 - 2 Stop Bits

•Even, Odd, Mark, or No Parity

•16 Byte Transmit and Receive FIFOs

•Interrupts for Receive FIFO Full, Half Full, and Not Empty

•Interrupts for Transmit FIFO Empty

•False Start Bit Detection

•Full Modem Control Signals on UART3

•Capable of speeds up to 1.5 Mbps to enable connections with Bluetooth and other peripherals through a UART interface

•Similar to personal computer industry standard 16550 UART

6.7.1 Programming Model

Each UART is controlled by a register block. Table 6-31 lists the base address for each UART register block.

UART0 and UART3 are capable of being used with DMA. See Section 4.0 "DMA Controller" on page 73 for more informa-

tion.

6.7.2 UART Registers

Each register block contains the registers listed in Table 6-32 from the base address shown in Table 6-31.

Table 6-31. UART Register Base Addresses

Name Physical Base Address KSEG1 Base Address

uart0_base 0x0 1110 0000 0xB110 0000

uart1_base 0x0 1120 0000 0xB120 0000

uart2_base 0x0 1130 0000 0xB130 0000

uart3_base 0x0 1140 0000 0xB140 0000

Table 6-32. UART Registers

Offset Register Name Description

0x0000 uart_rxdata Received Data FIFO

0x0004 uart_txdata Transmit Data FIFO

0x0008 uart_inten Interrupt Enable Register

0x000C uart_intcause Pending Interrupt Cause Register

0x0010 uart_fifoctrl FIFO Control Register

0x0014 uart_linectrl Line Control Register

0x0018 uart_mdmctrl Modem Line Control Register (UART3 only)

0x001C uart_linestat Line Status Register

0x0020 uart_mdmstat Modem Line Status Register (UART3 only)

0x0024 uart_autoflow Automatic Hardware Flow Control (UART3 only)

0x0028 uart_clkdiv Baud Rate Clock Divider

0x0100 uart_enable Module Enable Register

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6.7.3 Received Data FIFO

The uart_rxdata register contains the next entry in the received data FIFO. This register is read only.

6.7.4 Transmit Data FIFO

The uart_txdata register provides access to the transmit data FIFO. This register is write only.

6.7.5 Interrupt Enable Register

The uart_inten register contains bits which enable interrupts under certain operational conditions.

uart_rxdata - Received Data FIFO Offset = 0x0000

Bit313029282726252423222120191817161514131211109876543210

RXDATA

Def.00000000000000000000000000000000

Bits Name Description R/W Default

31:8 — Reserved. Should be cleared. R 0

7:0 RXDATA Receive Data R 0

uart_txdata - Transmit Data FIFO Offset = 0x0004

Bit313029282726252423222120191817161514131211109876543210

TXDATA

Def.00000000000000000000000000000000

Bits Name Description R/W Default

31:8 — Reserved, should be cleared. R 0

7:0 TXDATA Transmit Data R 0

uart_inten - Interrupt Enable Register Offset = 0x0008

Bit313029282726252423222120191817161514131211109876543210

MIE LIE TIE RIE

Def.00000000000000000000000000000000

Bits Name Description R/W Default

31:4 — Reserved. Should be cleared. R 0

3 MIE Modem Status Interrupt Enable (UART3 only). When the MIE bit is set an

interrupt is generated when changes occur in the state of the optional

modem control signals available with UART3.

System Note: For systems that use the UART3 interface but do not use

the optional modem control signals (sys_pinfunc[UR3]=0), the modem

status interrupts must be disabled (MIE=0) to avoid false UART3 interrupts

when using GPIO[9], GPIO[10], GPIO[11], or GPIO[12] as a general-pur-

pose system input.

R/W 0

2 LIE Line Status Interrupt Enable. When the LIE bit is set an interrupt is gener-

ated when errors (overrun, framing, stop bits) or break conditions occur.

R/W 0

1 TIE Transmit Interrupt Enable. When the TIE bit is set an interrupt is generated

when the transmit FIFO is not full.

R/W 0

0 RIE Receive Interrupt Enable. When the RIE bit is set the UART will generate

an interrupt on received data ready (DR bit in the uart_linestat register) or

a character time out.

R/W 0

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6.7.6 Interrupt Cause Register

The uart_intcause register contains information about the cause of the current interrupt.

Table 6-33 contains information about the interrupt cause encoding.

uart_intcause - Interrupt Cause Register Offset = 0x000c

Bit313029282726252423222120191817161514131211109876543210

IID IP

Def.00000000000000000000000000000001

Bits Name Description R/W Default

31:4 — Reserved. Should be cleared. R 0

3:1 IID Interrupt Identifier. The IID field identifies the highest priority current inter-

rupt condition. Table 6-33 lists the priorities and encodings of each inter-

rupt condition.

0 IP No interrupt pending.

0 An interrupt is pending.

1 No interrupts are pending.

Table 6-33. Interrupt Cause Encoding

IID Priority Type Source

0 5 (lowest) Modem Status DD, TRI, DR or DC of uart_mdmstat

1 4 Transmit Buffer Available TT of uart_linestat

2 3 Receive Data Available The receive FIFO having greater than RFT (of

uart_fifoctrl) bytes in it if FIFOs are enabled.

DR of uart_linestat if FIFOs are disabled.

3 1 (highest) Receive Line Status OE, PE, FE, BI in uart_linestat register

4Reserved

5Reserved

6 2 Character Time Out Character has been in receive FIFO for 0x300

UART clocks (set by uart_clkdiv)

7Reserved

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6.7.7 FIFO Control Register

The uart_fifoctrl register provides control of character buffering options.

uart_fifoctrl - FIFO Control Register Offset = 0x0010

Bit313029282726252423222120191817161514131211109876543210

RFT TFT MS TR RR FE

Def.00000000000000000000000000000000

Bits Name Description R/W Default

31:8 — Reserved. Should be cleared. R 0

7:6 RFT Receive FIFO Threshold. A receive threshold interrupt is generated when

the number of characters in the receiver FIFO is greater than or equal to

the trigger level listed below:

00 Trigger depth = 1

01 Trigger depth = 4

10 Trigger depth = 8

11 Trigger depth = 14

If using DMA it is important that the receive FIFO threshold and transmit

FIFO threshold are the same and programmed consistently with the trans-

fer size for the DMA channel being used. See Section 4.0 "DMA Control-

ler" on page 73 for more information.

R/W 0

5:4 TFT Transmit FIFO Threshold. A transmit threshold interrupt is generated if the

number of valid characters contained in the transmit FIFO is less than or

equal to the trigger depth. The encoding of trigger depth for each value of

TFT is shown below:

00 Trigger depth = 0

01 Trigger depth = 4

10 Trigger depth = 8

11 Trigger depth = 12

If using DMA it is important that the receive FIFO threshold and transmit

FIFO threshold are the same and programmed consistently with the trans-

fer size for the DMA channel being used. See Section 4.0 "DMA Control-

ler" on page 73 for more information.

R/W 0

3 MS Mode Select. If the MS bit is clear interrupts are generated by the receiver

when any data is available and by the transmitter when there is no data to

transmit. Setting the MS bit causes interrupts to be generated based on

FIFO threshold levels.

R/W 0

2 TR Transmitter Reset. Writing a one to the TR bit will clear the transmit FIFO

and reset the transmitter. The transmit shift register is not cleared.

R/W 0

1 RR Receiver Reset. Writing a one to the RR bit will clear the receiver FIFO

and reset the receiver. The receiver shift register is not cleared.

R/W 0

0 FE FIFO Enable. The FE bit enables the 16 byte FIFOs on transmit and

receive. When the FE bit is clear both FIFOs will have an effective depth of

1 byte.

R/W 0

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6.7.8 Line Control Register

The uart_linectrl register provides control over the data format and parity options.

6.7.9 Modem Control Register

The uart_mdmctrl register allows the state of the output modem control signals to be set. The external modem signals are

only available on UART3.

uart_linectrl - Line Control Register Offset = 0x0014

Bit313029282726252423222120191817161514131211109876543210

SB PAR PE ST WLS

Def.00000000000000000000000000000000

Bits Name Description R/W Default

31:7 — Reserved. Should be cleared. R 0

6 SB Send Break. Setting the SB bit will force the transmitter output to zero. R/W 0

5:4 PAR Parity Select. Selects the parity encoding for the transmitter and receiver.

00 Odd parity

01 Even parity

10 Mark parity

11 Zero parity

R/W 0

3 PE Parity Enable. If the PE bit is clear parity will not be sent or expected. If the

PE bit is set parity is selected according to the PAR field.

R/W 0

2 ST Stop Bits. If the ST bit is clear one stop bit is sent and expected. Setting

the ST bit selects 1.5 stop bits for 5 bit characters and 2 stop bits for all

other character lengths.

R/W 0

1:0 WLS Word Length Select. The WLS field selects the number of data bits in each

character. The number of bits is WLS+5.

R/W 0

uart_mdmctrl - Modem Control Register Offset = 0x0018

Bit313029282726252423222120191817161514131211109876543210

LB I1 I0 RT DT

Def.00000000000000000000000000000000

Bits Name Description R/W Default

31:5 — Reserved. Should be cleared. R 0

4 LB Loop Back.

0 No loopback (normal operation)

1 Enable loopback for self-test. Establish the internal connections

shown below:

Output Signal Looped Back To

TXD RXD

DTR DSR

RTS CTS

I0 RIN

I1 DCD

R/W 0

3 I1 Internal Line 1 State. When the I1 bit is set the internal I1 line for this port

is driven low. This can be used in loopback mode.

R/W 0

2 I0 Internal Line 0 State. When the I0 bit is set the external I0 line for this port

is driven low.This can be used in loopback mode.

R/W 0

1 RT Request To Send. When the RT bit is set the external RTS line for this port

is driven low.

Note: This bit has no effect if uart_autoflow[AE] is set.

R/W 0

0 DT Data Terminal Ready. When the DT bit is set the external DTR line for this

port is driven low.

R/W 0

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6.7.10 Line Status Register

The uart_linestat register reflects the state of the interface.

Bits in this register are set when the listed condition and cleared when this register is read.

uart_linestat - Line Status Register Offset = 0x001C

Bit313029282726252423222120191817161514131211109876543210

RF TE TT BI FE PE OE DR

Def.00000000000000000000000000000000

Bits Name Description R/W Default

31:8 — Reserved. Should be cleared. R 0

7 RF Receiver FIFO Contains Error. This bit is set when one of the characters in

the receive FIFO contains a parity error, framing error, or break indication.

6 TE Transmit Shift Register Empty. This bit is set when the transmit shift regis-

ter is empty and there are no more characters in the FIFO.

5 TT Transmit Threshold. This bit is set when the transmitter FIFO depth is less

than or equal to the value of the TFT field in the FIFO control register.

When FIFOs are not enabled this bit is set when the transmitter data regis-

ter is empty

4 BI Break Indication. This bit is set if a break is received. When a break is

detected a single zero character is received. The BI bit is valid when the

zero character is at the top of the receive FIFO. This bit must be cleared

with a read to uart_linestat before more characters are received.

3 FE Framing Error. The FE bit is set when a valid stop bit is not detected. This

bit reflects the state of the character at the top of the receive FIFO. The FE

bit is cleared by a read to uart_linestat.

2 PE Parity Error. The PE bit is set when the received character at the top of the

FIFO contains a parity error. This bit is cleared by reading uart_linestat.

1 OE Overrun Error. The OE bit is set when a receiver overrun occurs. This bit is

cleared when uart_linestat is read.

0 DR Data Ready. The DR bit is set when the receive FIFO contains valid char-

acters.

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6.7.11 Modem Status Register

The uart_mdmstat register reflects the state of the external modem signals. Reading this register will clear any delta indi-

cations and the corresponding interrupt. The external modem signals are optional and are present only on UART3.

6.7.12 Automatic Hardware Flow Control Register

The uart_autoflow register controls automatic hardware flow control using modem control signals CTS and RTS. Upon

enabling this mode, internal logic controls the output signal RTS based upon the data register state and threshold levels.

The internal logic asserts RTS (low) to request data until the internal receive FIFO reaches its preset threshold. In this

mode RTS cannot be controlled with the uart_mdmctrl[RT] bit. The input signal CTS controls the transmission of data by

loading the transmit shift register from the data register only while CTS is asserted (low). Once the transmit shift register is

loaded with data, it sends the entire character regardless of the CTS signal state.

uart3_mdmstat - Modem Status Register Offset = 0x0020

Bit313029282726252423222120191817161514131211109876543210

CD RI DS CT DD TRI DR DC

Def.00000000000000000000000000000000

Bits Name Description R/W Default

31:8 — Reserved, should be cleared. R 0

7 CD Data Carrier Detect. The CD bit reflects the status of the external DCD pin. R 0

6 RI Ring Indication. The RI bit reflects the status of the external RI pin. R 0

5 DS Data Set Ready. The DS bit reflects the status of the external DSR pin. R 0

4 CT Clear To Send. The CT bit reflects the status of the external CTS pin. R 0

3 DD Delta DCD. The DD bit is set when a change occurs in the state of the

external DCD pin.

2 TRI TRI - Terminate Ring Indication. The TRI bit is set when a positive edge

occurs in the state of the external RI pin.

1 DR Delta DSR. The DR bit is set when a change occurs in the state of the

external DSR pin.

0 DC Delta CTS. The DC bit is set when a change occurs in the state of the

external CTS pin.

uart_autoflow - Automatic Hardware Flow Control Register Offset = 0x0024

Bit313029282726252423222120191817161514131211109876543210

Def.00000000000000000000000000000000

Bits Name Description R/W Default

31:1 — Reserved. Should be cleared. R 0

0 AE Autoflow Enable. Setting this bit enables automatic hardware flow control

on UART3. Enabling this mode overrides software control of the signals.

R/W 0

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6.7.13 Clock Divider Register

The uart_clkdiv contains the divider used to generate the baud rate clock. The input to the UART clock divider is the inter-

nal peripheral bus clock. The actual baud rate of the interface is as follows:

Baud rate = CPU / (SD * 2 * CLKDIV * 16)

CPU = CPU clock

SD = System Bus (SBUS) divider (see Section 7.4 "Power Management" on page 188 information on changing SD.)

6.7.14 UART Enable

The uart_enable register controls reset and clock enable to the UART

The correct routine for bringing the USB Device out of reset is as follows:

1) Set the CE bit to enable clocks.

2) Set the E bit to enable the peripheral.

uart_clkdiv - Clock Divider Register Offset = 0x0028

Bit313029282726252423222120191817161514131211109876543210

CLKDIV

Def.00000000000000000000000000000001

uart_enable - UART Enable Register Offset = 0x0100

Bit313029282726252423222120191817161514131211109876543210

ECE

Def.00000000000000000000000000000000

Bits Name Description R/W Default

31:2 — Reserved. Should be cleared. R 0

1 E Enable. When the E bit is clear the entire module is held in reset. After

enabling clocks, this bit should be set to enable normal operation.

R/W 0

0 CE Clock Enable. When the CE bit is clear the module clock source is inhib-

ited. This can be used to place the module in a low power Standby state.

The CE bit should be set before the module is enabled for proper bringup.

R/W 0

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6.7.15 Hardware Considerations

The UART signals are listed in Table 6-34. For changing pin functionality please refer to the sys_pinfunc register in Section

7.3 "General Purpose I/O and Pin Functionality" on page 183.

Table 6-34. UART Signals

Signal Input/Output Definition

UART0

U0TXD O UART0 transmit. Muxed with GPIO[20]. U0TXD is the default signal coming out of

hardware reset, runtime reset, and Sleep.

U0RXD I UART0 receive.

UART1

U1TXD O UART1 transmit. Muxed with GPIO[21]. U1TXD is the default signal coming out of

hardware reset, runtime reset, and Sleep.

U1RXD I UART1 receive.

UART2

U2TXD O UART2 transmit. Muxed with GPIO[22]. U2TXD is the default signal coming out of

hardware reset, runtime reset, and Sleep.

U2RXD I UART2 receive.

UART3

U3TXD O UART3 transmit. Muxed with GPIO[23]. U3TXD is the default signal coming out of

hardware reset, runtime reset, and Sleep.

U3RXD I UART3 receive.

U3CTS I Clear to Send (optional). Muxed with GPIO[9]. GPIO[9] is the default signal coming

out of hardware reset, runtime reset, and Sleep.

System Note: For systems that use the UART3 interface without the optional

modem control signals (sys_pinfunc[UR3]=0), the modem status interrupts must

be disabled (uart3_inten[MIE]=0) to avoid false UART3 interrupts when using

GPIO[9], GPIO[10], GPIO[11], or GPIO[12] as an input.

U3DSR I Data Set Ready (optional). Muxed with GPIO[10]. GPIO[10] is the default signal

coming out of hardware reset, runtime reset, and Sleep.

System Note: For systems that use the UART3 interface without the optional

modem control signals (sys_pinfunc[UR3]=0), the modem status interrupts must

be disabled (uart3_inten[MIE]=0) to avoid false UART3 interrupts when using

GPIO[9], GPIO[10], GPIO[11], or GPIO[12] as an input.

U3DCD I Data Carrier Detect (optional). Muxed with GPIO[11]. GPIO[11] is the default signal

coming out of hardware reset, runtime reset, and Sleep.

System Note: For systems that use the UART3 interface without the optional

modem control signals (sys_pinfunc[UR3]=0), the modem status interrupts must

be disabled (uart3_inten[MIE]=0) to avoid false UART3 interrupts when using

GPIO[9], GPIO[10], GPIO[11], or GPIO[12] as an input.

U3RI I Ring Indication (optional). Muxed with GPIO[12]. GPIO[12] is the default signal

coming out of hardware reset, runtime reset, and Sleep.

System Note: For systems that use the UART3 interface without the optional

modem control signals (sys_pinfunc[UR3]=0), the modem status interrupts must

be disabled (uart3_inten[MIE]=0) to avoid false UART3 interrupts when using

GPIO[9], GPIO[10], GPIO[11], or GPIO[12] as an input.

U3RTS O Request to Send (optional). Muxed with GPIO[13]. GPIO[13] is the default signal

coming out of hardware reset, runtime reset, and Sleep.

U3DTR O Data Terminal Ready (optional). Muxed with GPIO[14]. GPIO[14] is the default sig-

nal coming out of hardware reset, runtime reset, and Sleep.

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6.8 SSI Interfaces

The Au1000 processor contains two synchronous serial interfaces (SSIs) designed to provide a simple connection to exter-

nal serial devices. These serial channels support the SSI protocol and a subset of the SPI protocol.

Each serial channel is independently programmable for various address and data lengths, clock rates, and behavior.

Each channel has a data in pin, data out pin, a clock pin, and an enable pin. Only master mode is supported. The Au1000

processor drives the clock and enable pins when the interface is enabled.

The data out pin will TRI-STATE during a read, thus the data out pin and data in pin can be tied together for a bidirectional

data pin.

6.8.1 Operation

The SSI generates the clock output SCLK. The clock is derived from the peripheral bus clock by a divider controlled by the

ssi_clkdiv register. The clock only transitions when a transaction is in progress.

The SSI contains a status register that reflects the current state. A busy bit is set when a transfer is initiated and cleared

when SSI returns to Idle. A done bit is set when the transfer is complete. The done bit may be used to signal an interrupt.

6.8.1.1 Write Transactions

Write transactions transfer data from the Au1000 processor to a peripheral device attached to the SSI. The transaction con-

sists of a data field and optional address and direction fields. The order of the address and direction fields is configurable.

The address and direction fields may also be omitted from the transaction. The data field is always the last field transmitted.

The order of bit transmission within a field (MSb first or LSb first) is also configurable.

The SDEN output presents an envelope around the transaction. Figure 6-4 shows a typical write transaction. For this trans-

action the address field is 3 bits long, data is 8 bits, and direction precedes address.

Figure 6-4. Typical Write Transaction Timing

6.8.1.2 Read Transactions

A read transaction is initiated by writing the address and direction to the ssi_adata register (the data field is ignored). The

busy status bit will be set and will remain set until the done bit is set to indicate completion. Once the transaction is com-

plete the data may be read from the data field in ssi_adata.

An extra clock cycle is inserted between the direction/address transmission by the processor and the data field transmis-

sion by the external device to avoid contention. The behavior of SCLK may be changed during this extra cycle by program-

ming the BM field in the ssi_config register.

Figure 6-5 shows a typical read transaction where the bus mode is set to hold SCLK high during the bus turnaround.

Figure 6-5. Typical Read Transaction Timing

SCLK

SDEN

0A0 A1 A2 D0 D1 D2 D3 D5 D6 D7

SDOUT

Write transaction: ALEN = 2, DLEN = 7, DP=1, DL = 0, CE = 0, EP = 0, AO = 0, DO = 0

SCLK

SDEN

1A0 A1 A2

SDIN

Read transaction: ALEN = 2, DLEN = 7, DP=1, DL = 0, CE = 0, EP = 0, AO = 0, DO = 0, BM = 00

D0 D1 D2 D3 D4 D5 D6 D7

SDOUT

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6.8.2 Register Description

Each SSI contains a register block used to configure the interface and to pass data. All registers must be written and read

as 32 bit words. The locations of the register blocks for each SSI are shown in the table below.

Table 6-36 shows the offset and function of each register from the base address listed in Table 6-35.

6.8.2.1 SSI Interface Status Register

The ssi_status register reflects the current status of the interface.

Table 6-35. SSI Base Addresses

Name Physical Base Address KSEG1 Base Address

ssi0_base 0x0 1160 0000 0xB160 0000

ssi1_base 0x0 1168 0000 0xB168 0000

Table 6-36. SSI Registers

Offset Register Name Description

0x0000 ssi_status SSI Status Register

0x0004 ssi_int SSI Interrupt Pending Register

0x0008 ssi_inten SSI Interrupt Enable Register

0x0020 ssi_config SSI Configuration Register

0x0024 ssi_adata SSI Address/Data Register

0x0028 ssi_clkdiv SSI Clock Divider Register

0x0100 ssi_enable SSI Channel Enable Register

ssi_status - SSI Interface Status Offset = 0x0000

Bit313029282726252423222120191817161514131211109876543210

BF OF UF D B

Def.00000000000000000000000000000000

Bits Name Description R/W Default

31:5 — Reserved. Should be cleared. R 0

4 BF Buffer Full. This bit indicates that the data buffer is currently full. It is set by

either receiving a buffer from the serial interface or a write by the proces-

sor. It is cleared by either a transmit on the serial interface or a read by the

processor.

3 OF Overflow. This bit is set when the serial data register is written multiple

times without completing an intervening transfer.

This bit is sticky. Once set high it must be written a ‘1’ to clear the bit.

R/W 0

2 UF Underflow. This bit is set when the serial data register is read multiple

times without an intervening serial transfer.

This bit is sticky. Once set high it must be written a ‘1’ to clear the bit.

R/W 0

1 D Done. This bit is set at the completion of an SSI transfer.

This bit is sticky. Once set high it must be written a ‘1’ to clear the bit.

R/W 0

0 B Busy. This bit is set if an SSI transfer is in progress R 0

AMD Alchemy™ Au1000™ Processor Data Book 161

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6.8.2.2 Interrupt Pending Register

The ssi_int register shows which interrupt indications are currently active.

6.8.2.3 SSI Interrupt Enable Register

The ssi_inten register is writable by the processor and enables certain conditions on the SSI to generate an interrupt. The

interrupt will be generated (and indicated in ssi_int) when the corresponding bits are both set in ssi_inten and ssi_status.

ssi_int - SSI Interrupt Pending Register Offset = 0x0004

Bit313029282726252423222120191817161514131211109876543210

OI UI DI

Def.00000000000000000000000000000000

Bits Name Description R/W Default

31:4 — Reserved, should be cleared. R 0

3 OI The OI bit indicates that the current interrupt is being generated by an

overflow condition.

This bit is sticky. Once set high it must be written a ‘1’ to clear the bit.

2 UI The UI bit indicates that the current interrupt is being generated by an

underflow condition.

This bit is sticky. Once set high it must be written a ‘1’ to clear the bit.

1 DI The DI bit indicates that the current interrupt is being generated by a done

condition.

This bit is sticky. Once set high it must be written a ‘1’ to clear the bit.

0 — Reserved, should be cleared. R 0

ssi_inten - SSI Interrupt Enable Register Offset = 0x0008

Bit313029282726252423222120191817161514131211109876543210

OIE UIE DIE

Def.00000000000000000000000000000000

Bits Name Description R/W Default

31:4 — Reserved. Should be cleared. R 0

3 OIE This bit enables interrupts on an overflow condition. R/W 0

2 UIE This bit enables interrupts on an underflow condition. R/W 0

1 DIE This bit enables interrupts on a done condition. R/W 0

0 — Reserved. Should be cleared. R 0

162 AMD Alchemy™ Au1000™ Processor Data Book

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6.8.2.4 SSI Configuration Register

The ssi_config register contains fields which configure the operational parameters of the serial interface.

ssi_config - SSI Configuration Register Offset = 0x0020

Bit313029282726252423222120191817161514131211109876543210

AO DO ALEN DLEN DD AD BM CE DP DL EP

Def.00000000000000000000000000000000

Bits Name Description R/W Default

31:25 — These bits are reserved and should be written as 0. R 0

24 AO Address Field Order. The AO bit selects the bit order of the address field. If

AO is cleared the address field is set LSB first. If AO is set the address

field is sent MSB first.

R/W 0

23 DO Data Field Order. The DO field selects the transmission order for the data

field. If DO is cleared the data field is sent LSB first. If DO is set the data

field is sent MSB first.

R/W 0

22:20 ALEN Address Field Length. The ALEN field selects the length of the address

field in the serial stream. The number of bits in the address field will be

ALEN+1.

R/W 0

19:16 DLEN Data Field Length. The DLEN field selects the length of the data field in the

serial stream. The number of bits in the data field will be DLEN+1. Values

of DLEN that result in a length greater than 12 are reserved and will result

in undefined behavior.

R/W 0

15:12 — These bits are reserved and should be written as 0. R/W 0

11 DD Direction Bit Disable. If the DD bit is set the direction bit will not be sent. R/W 0

10 AD Address Field Disable. If the AD bit is set the address field will not be sent. R/W 0

9:8 BM Bus Mode. Determines the turnaround behavior for read cycles.

00 SCLK held high during turnaround.

01 SCLK held low during turnaround.

10 SCLK cycles during turnaround.

11 Reserved

R/W 0

7 CE The CE bit determines which clock edge is active for SCLK. If CE is

cleared data and address will be clocked out on the negative edge and

captured at the positive edge. If CE is set data and address will be clocked

out on the positive edge and captured on the negative edge.

R/W 0

6 DP Direction Polarity. Determines whether a write is indicated by an active-

high or active-low direction bit.

0 A write is indicated by an active-high direction bit.

1 A write is indicated by an active-low direction bit.

R/W 0

5 DL Direction Bit Location. If the DL bit is clear the direction bit is sent before

the address bits in the serial stream. If DL is set the direction bit will follow

the address field.

R/W 0

4 EP Enable Polarity. Selects the polarity of the enable signal on the interface.

0 Enable is active high.

1 Enable is active low.

R/W 0

3:0 — Reserved. Should be cleared. R/W 0

AMD Alchemy™ Au1000™ Processor Data Book 163

SSI Interfaces 30360E

6.8.3 SSI Address/Data Register

The ssi_adata register contains the address, data, and direction fields. Writing to ssi_adata will initiate a transfer. The type

of transfer (read or write) is determined by the D (direction) bit.

6.8.3.1 SSI Clock Divider Register

The ssi_clkdiv register determines the baud rate of the serial port. The baud rate is defined as follows:

Baudrate = CPU / (SD * 4 * (CLKDIV + 1))

CPU = CPU clock

SD = System Bus (SBUS) divider (See Section 7.4 "Power Management" on page 188 for information on SD.)

ssi_adata - SSI address/data Register Offset = 0x0024

Bit313029282726252423222120191817161514131211109876543210

D ADDR DATA

Def.00000000000000000000000000000000

Bits Name Description R/W Default

31:25 — Reserved. Should be cleared. R 0

24 D Direction Bit.

0 The transaction is a read, and the data field contains the value of the

serial input at the end of the transaction.

1 The transaction is a write.

R/W 0

23:16 ADDR Address Field. R/W 0

15:12 — Reserved. Should be cleared. R 0

11:0 DATA Data Field. R/W 0

ssi_clkdiv - SSI clock divider Offset = 0x0028

Bit313029282726252423222120191817161514131211109876543210

CLKDIV

Def.00000000000000000000000000000000

Bits Name Description R/W Default

31:16 — Reserved. Should be cleared. R 0

15:0 CLKDIV The CLKDIV field determines the baud rate of the interface. R/W 0

164 AMD Alchemy™ Au1000™ Processor Data Book

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6.8.3.2 SSI Enable Register

The ssi_enable register allows the serial interface to be disabled or placed in a low power mode. The correct routine for

bringing the SSI block out of reset is as follows:

1) Clear the CD bit to enable clocks.

2) Set the E bit to enable the peripheral.

ssi_enable - SSI Enable Register Offset = 0x0100

Bit313029282726252423222120191817161514131211109876543210

CD E

Def.00000000000000000000000000000010

Bits Name Description R/W Default

31:2 — Reserved. Should be cleared. R 0

1CD Clock Disable.

0 Enable the clock to the SSI block.

1 Disable (disconnect) the clock to the SSI block.

0E Enable.

0 Hold the SSI block in reset.

1 Enable the SSI block.

AMD Alchemy™ Au1000™ Processor Data Book 165

SSI Interfaces 30360E

6.8.4 Hardware Considerations

The SSI ports consist of the signals listed in Table 6-37. For changing pin functionality please refer to the sys_pinfunc reg-

ister in Section 7.3 "General Purpose I/O and Pin Functionality" on page 183.

Table 6-37. SSI Signals

Signal Input/Output Definition

SSI0

S0CLK O Master only clock output. The speed and polarity of clock edge is programmable.

Muxed with GPIO[17].

S0DIN I Serial Data Input. This signal may be tied with S0DOUT to create a single bidirec-

tional data signal.

S0DOUT O Serial Data Output. This signal is in TRI-STATE during a read and thus may be tied

to S0DIN to create a single bidirectional data signal.

Muxed with GPIO[16].

S0DEN O Enable signal which frames transaction. The polarity is programmable.

Muxed with GPIO[18].

SSI1

S1CLK O Master only clock output. The speed and polarity of clock edge is programmable.

Muxed with ACDO which controls the pin out of hardware reset, runtime reset and

Sleep.

S1DIN I Serial Data Input. This signal may be tied with S1DOUT to create a single bidirec-

tional data signal.

Muxed with ACBCLK which controls the pin out of hardware reset, runtime reset

and Sleep.

S1DOUT O Serial Data Output. This signal is in TRI-STATE during a read and thus may be tied

to S1DIN to create a single bidirectional data signal.

Muxed with ACSYNC which controls the pin out of hardware reset, runtime reset

and Sleep.

S1DEN O Enable signal which frames transaction. The polarity is programmable.

Muxed with ACRST# which controls the pin out of hardware reset, runtime reset

and Sleep.

166 AMD Alchemy™ Au1000™ Processor Data Book

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AMD Alchemy™ Au1000™ Processor Data Book 167

System Control 30360E

7.0System Control

The Au1000 processor contains a robust system control strategy that includes the means to control the following:

•Clocking (See Section 7.1 "Clocks" on page 168.)

•Time of Year and Real Time Clock counters (See Section 7.2 "Time of Year Clock and Real Time Clock" on page 178.)

•GPIO control (See Section 7.3 "General Purpose I/O and Pin Functionality" on page 183.)

•Power management (See Section 7.4 "Power Management" on page 188.)

All registers in the system control block are located off of the base address shown in Table 7-1.

The registers in the system control block are affected differently by events such as power-on hardware reset, Sleep and

runtime reset (see Section 8.0 "Power-up, Reset and Boot" on page 195 for a discussion on the different reset types). Each

designer to observe what registers will and will not revert to defaults when the different events occur.

Table 7-1. System Control Block Base Address

Name Physical Base Address KSEG1 Base Address

sys_base 0x0 1190 0000 0xB190 0000

168 AMD Alchemy™ Au1000™ Processor Data Book

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7.1 Clocks

The Au1000 processor supports two oscillator inputs: 12 MHz and 32.768 kHz. This section documents the clock domains

driven directly and indirectly by the 12 MHz input. The 32.768 kHz clock input drives the two programmable counters

intended for use as a real time clock (RTC) and time of year clock (TOY). The programmable counters are documented in

Section 7.2 "Time of Year Clock and Real Time Clock" on page 178. (See Section 11.8 "Crystal Specifications" on page 250

for the specifications of both crystals.)

The Au1000 processor contains two PLLs driven by the 12 MHz oscillator and a clocking block from which the following are

derived:

•CPU Clock

•Core Cycle Counter Register clocked by the CPU Clock

•System Bus (SBUS) Clock

•Peripheral Bus Clock

•SDRAM Bus Clock

•Programmable clocks needed by certain peripherals

•Programmable clocks EXTCLK[1:0] for external use (provided on pins shared with the GPIO[3:2] signals)

Figure 7-1 shows the basic clocking topology and the relationship between the CPU Clock, the SBUS clock and the Periph-

eral Clock. As shown, the SBUS frequency is derived by dividing the CPU Clock by the value SD programmed in the

sys_powerctrl register. (See Section 7.4 "Power Management" on page 188 for the sys_powerctrl register definition.) The

Peripheral Bus clock and the SDRAM bus are fixed at the SBUS frequency divided by 2. Figure 7-1 also shows the periph-

eral blocks driven by clock sources derived from the programmable clock generator logic (as described in Section 7.1.2,

"Clock Generation").

Figure 7-1. Clocking Topology

12.000 MHz CPU Clock SBUS Clock Peripheral Bus Clock

/SD*CPU_PLL

AUX_PLL CLock Generator

IrDA

USB Device

USB Host

I2SCLK

EXTCLK0

EXTCLK1

SDRAM Bus Clock

Auxiliary

Clock

*SD is a programmable field in the sys_powerctrl

agement Registers" on page 191. SD can be 2, 3,

or 4.

AMD Alchemy™ Au1000™ Processor Data Book 169

Clocks 30360E

7.1.1 Clock Register Descriptions

The clock manager registers and their associated offsets are listed in Table 7-2.

7.1.2 Clock Generation

This section documents registers for the clock generation block which provides clocks to some peripheral devices and as

well as two externally available clocks. The clock generation subsystem is split into two sets of distinct blocks which allows

up to six distinct frequencies to drive up to six clock sources. Figure 7-2 shows a logical representation of one of the six

identical frequency generators and how the six frequency sources are mapped to one of the six identical internal clock

sources. The names in the figure correspond to the bit names in the control registers. Figure 7-3 shows a pictorial repre-

sentation of the relationship between the frequency generator blocks to the clock source blocks.

Each peripheral has clock restrictions as follows. If these restrictions are not met, the peripheral will not operate correctly.

The IrDA Clock must be programmed to match value set in CS. CS is the PHY Layer clock speed field in the ir_config2

The USB Device Clock must be programmed to 48 MHz.

The USB Host Clocks must be programmed to 48 MHz.

The I2SCLK must be set to match the effective bit rate which will be determined by the sampling frequency (system depen-

dent) times the bit rate (2 * SZ). SZ is the Size field in the i2s_config register.

The EXTCLK[1:0] clocks can be programmed for system use. If the I2S peripheral is being used, typically one of these

clocks will be programmed to provide the system oversampling clock for the CODEC (i.e. 128Fs, 256Fs, or 512Fs where Fs

is the system sampling frequency).

Note that the EXTCLK[1:0] clocks have a maximum frequency rating of (Fmax / 16), where Fmax is the maximum frequency

rating for the part. For example, for a 400 MHz part be sure the EXTCLK[1:0] clocks are programmed to run at no more than

25 MHz. (See also Section 11.7 "External Clock Specifications" on page 249.)

Note also that the EXTCLK[1:0] clocks are multiplexed signals and require programming of the sys_pinfunc register (see

Section 7.3.1.1 "Pin Function" on page 183) as follows:

•EXTCLK0 shares a pin with GPIO[2]. If EXTCLK0 is to be used, sys_pinfunc[EX0] must be set to allow the clock to

drive this pin. In addition, sys_pinfunc[CS] must be cleared.

•EXTCLK1 shares a pin with GPIO[3]. If EXTCLK1 is to be used, sys_pinfunc[EX1] must be set to allow the clock to

drive this pin.

Table 7-2. Clock Generation Registers

Offset (Note 1)

Note 1. See Table 7-1 "System Control Block Base Address" on page 167 for base address.

0x0020 sys_freqctrl0 Controls (source, enable, and divider) frequency

generators 0, 1, and 2

Hardware

0x0024 sys_freqctrl1 Controls (source, enable, and divider) frequency

generators 3, 4, and 5

Hardware

0x0028 sys_clksrc Controls (source and divider) the derived clocks Hardware

0x0060 sys_cpupll Changes CPU PLL frequency Hardware

0x0064 sys_auxpll Changes Auxiliary PLL frequency Hardware &

Runtime

170 AMD Alchemy™ Au1000™ Processor Data Book

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30360E

Figure 7-2. Frequency Generator and Clock Source Block Diagram

Auxiliary Clock

CPU Clock FREQn

FSnFEn

Divide =

(FRDIVn + 1) * 2

Auxiliary Clock

FREQ0

FREQ1

FREQ2

FREQ3

FREQ4

FREQ5

Peripheral

MXX

DXX

CXX

Frequency Generator Block

Clock Source Block

Reserved

XX denotes the abbreviated peripheral name

Clock Out

AMD Alchemy™ Au1000™ Processor Data Book 171

Clocks 30360E

Figure 7-3. Frequency Generator and Clock Source Mapping

Freq. Gen. Block 1

CPU

AUX FREQ1

Freq. Gen. Block 2

CPU

AUX FREQ2

Freq. Gen. Block 3

CPU

AUX FREQ3

Freq. Gen. Block 4

CPU

AUX FREQ4

Freq. Gen. Block 0

CPU

AUX FREQ0

Freq. Gen. Block 5

CPU

AUX FREQ5

AUX

FREQ1

FREQ2

FREQ3

FREQ4

FREQ5

IrDA Clock Source IrDA Clock

AUX

FREQ1

FREQ2

FREQ3

FREQ4

FREQ5

USB Device Clock USB Dev Clock

AUX

FREQ1

FREQ2

FREQ3

FREQ4

FREQ5

USB Host Clock USB Host Clock

AUX

FREQ1

FREQ2

FREQ3

FREQ4

FREQ5

I2SCLK Clock I2SCLK

AUX

FREQ1

FREQ2

FREQ3

FREQ4

FREQ5

GPIO[2] Clock EXTCLK0

AUX

FREQ1

FREQ2

FREQ3

FREQ4

FREQ5

GPIO[3] Clock EXTCLK1

Block

Source Block

FREQ0

172 AMD Alchemy™ Au1000™ Processor Data Book

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7.1.2.1 Frequency Control 0

This register controls the frequency generator block for output frequencies 0, 1, and 2. This register will reset to defaults

only on a hardware reset. During a runtime reset and during Sleep this register will retain its value.

sys_freqctrl0 Offset = 0x0020

Bit313029282726252423222120191817161514131211109876543210

FRDIV2[7:0] FE2FS2 FRDIV1[7:0] FE1FS1 FRDIV0[7:0] FE0FS0

Def.00000000000000000000000000000000

Bits Name Description R/W Default

31:30 — Reserved. Should be cleared. R 0

29:22 FRDIV2 Divider for Frequency Generator 2. The frequency divider is (FRDIV + 1) *

2, where FRDIV is the value programmed in this field.

R/W 0

21 FE2 Frequency Generator Output Enable 2.

0 Disable output.

1 Enable output.

R/W 0

20 FS2 Frequency Generator 2 Source.

0CPU Core clock.

1 Auxiliary clock.

R/W 0

19:12 FRDIV1 Divider for Frequency Generator 1. The frequency divider is (FRDIV + 1) *

2, where FRDIV is the value programmed in this field.

R/W 0

11 FE1 Frequency Generator 1 Output Enable.

0 Disable output.

1 Enable output.

R/W 0

10 FS1 Frequency Generator 1 Source.

0CPU Core clock.

1 Auxiliary clock.

R/W 0

9:2 FRDIV0 Divider for Frequency Generator 0. The frequency divider is (FRDIV + 1) *

2, where FRDIV is the value programmed in this field.

R/W 0

1 FE0 Frequency Generator 0 Output Enable.

0 Disable output.

1 Enable output.

R/W 0

0 FS0 Frequency Generator 0 Source.

0CPU Core clock.

1 Auxiliary clock.

R/W 0

AMD Alchemy™ Au1000™ Processor Data Book 173

Clocks 30360E

7.1.2.2 Frequency Control 1

This register controls the frequency generator block for output frequencies 3, 4, and 5. This register will reset to defaults

only on a hardware reset. During a runtime reset and during Sleep this register will retain its value.

sys_freqctrl1 Offset = 0x0024

Bit313029282726252423222120191817161514131211109876543210

FRDIV5[7:0] FE5FS5 FRDIV4[7:0] FE4FS4 FRDIV3[7:0] FE3FS3

Def.00000000000000000000000000000000

Bits Name Description R/W Default

31:30 — Reserved. Should be cleared. R 0

29:22 FRDIV5 Divider for Frequency Generator 5. The frequency divider is (FRDIV + 1) *

2, where FRDIV is the value programmed in this field.

R/W 0

21 FE5 Frequency Generator 5 Output Enable.

0 Disable output.

1 Enable output.

R/W 0

20 FS5 Frequency Generator 5 Source.

0CPU Core clock.

1 Auxiliary clock.

R/W 0

19:12 FRDIV4 Divider for Frequency Generator 4. The frequency divider is (FRDIV + 1) *

2, where FRDIV is the value programmed in this field.

R/W 0

11 FE4 Frequency Generator 4 Output Enable.

0 Disable output.

1 Enable output.

R/W 0

10 FS4 Frequency Generator 4 Source.

0CPU Core clock.

1 Auxiliary clock.

R/W 0

9:2 FRDIV3 Divider for Frequency Generator 3. The frequency divider is (FRDIV + 1) *

2, where FRDIV is the value programmed in this field.

R/W 0

1 FE3 Frequency Generator 3 Output Enable.

0 Disable output.

1 Enable output.

R/W 0

0 FS3 Frequency Generator 3 Source.

0CPU Core clock.

1 Auxiliary clock.

R/W 0

174 AMD Alchemy™ Au1000™ Processor Data Book

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7.1.2.3 Clock Source Control

This register controls the clock source for all output clocks. This register will reset to defaults only on a hardware reset. Dur-

ing a runtime reset and during Sleep this register will retain its value.

sys_clksrc Offset = 0x0028

Bit313029282726252423222120191817161514131211109876543210

ME1[2:0] DE1 CG3 ME0[2:0] DE0 CE0 MI2[2:0] DI2 CI2 MUH[2:0] DUH CUH MUD[2:0] DUD CUD MIR[2:0] DIR CIR

Def.00000000000000000000000000000000

Bits Name Description R/W Default

31:30 — Reserved. Should be cleared. R 0

29:27 ME1 EXTCLK1 Clock Mux input select. See Table 7-3 on page 175. R/W 000

26 DE1 EXTCLK1 Clock Divider.

0 Divide by 4.

1 Divide by 2.

R/W 0

25 CE1 EXTCLK1 Clock Select.

0 Clock is taken directly from mux. (The divider select bit DE1 has no

effect.)

1 Clock is taken from 2/4 divider.

R/W 0

24:22 ME0 EXTCLK0 Clock Mux input select. See Table 7-3 on page 175. R/W 000

21 DE0 EXTCLK0 Clock Divider Select.

0 Divide by 4

1 Divide by 2

R/W 0

20 CE0 EXTCLK0 Clock Select.

0 Clock is taken directly from mux. (The divider select bit DE0 has no

effect.)

1 Clock is taken from 2/4 divider.

R/W 0

19:17 MI2 I2S Clock Mux input select. See Table 7-3 on page 175. R/W 000

16 DI2 I2S Clock Divider Select.

0 Divide by 4.

1 Divide by 2.

R/W 0

15 CI2 I2S Clock Select.

0 Clock is taken directly from mux. (The divider select bit DI2 has no

effect.)

1 Clock is taken from 2/4 divider

R/W 0

14:12 MUH USB Host Clock Mux input select. See Table 7-3 on page 175. R/W 000

11 DUH USB Host Clock Divider Select.

0 Divide by 4.

1 Divide by 2.

R/W 0

10 CUH USB Host Clock Select.

0 Clock is taken directly from mux. (The divider select bit DUH has no

effect.)

1 Clock is taken from 2/4 divider.

R/W 0

9:7 MUD USB Device Clock Mux input select. See Table 7-3 on page 175. R/W 000

6 DUD USB Device Clock Divider Select.

0 Divide by 4

1 Divide by 2

R/W 0

5 CUD USB Device Clock Select.

0 Clock is taken directly from mux. (The divider select bit DUD has no

effect.)

1 Clock is taken from 2/4 divider.

R/W 0

4:2 MIR IrDA Clock Mux input select. See Table 7-3 on page 175. R/W 000

AMD Alchemy™ Au1000™ Processor Data Book 175

Clocks 30360E

The specific values written to the 3-bit clock-mux-input-select fields are shown in Table 7-3. The FREQn selections come

from the output of the corresponding frequency generators, as shown in Figure 7-2.

7.1.3 PLL Control

There are two registers for controlling the two PLLs integrated into the Au1000 processor. Each PLL is independently pro-

grammable. Note that when programming the PLL control registers, the system designer must not violate the rated fre-

quency limits of the Au1000 processor. Configuring the PLLs outside this frequency range causes undefined behavior.

For higher frequencies the Au1000 processor core requires a higher core voltage (VDDI). Care should be taken that the sys-

tem is providing the correct voltage for the operating frequency before changing the CPU clock. See Section 11.3 "DC

Parameters" on page 233, for full information about the voltage/frequency requirements of the Au1000 processor.

The Core Cycle Counter register located at CP0 register 9 can be used to count core cycles. Please see Section 2.7

"Coprocessor 0" on page 28, for more information.

The two PLLs in the Au1000 processor drive the CPU clock and the auxiliary clock. The default PLL multiplier value is 16 for

the CPU clock and 0 for the AUXPLL which has the following implications assuming a 12 MHz crystal on XTI12 and XTO12:

•CPU Clock = 192 MHz

•Auxiliary Clock = Disabled

•SBUS Clock = 96 MHz (SD - SBUS divider - defaults to 2)

•Peripheral Bus = 48 MHz

•SDRAM Bus = 48 MHz.

When modifying the CPU clock frequency approximately 20 µs elapse while the CPU and bus clocks shut off and the CPU

PLL locks to the new frequency. During this period instructions are not executed and interrupts are not serviced. Interrupts

are serviced once execution begins again at the new frequency.

1 DIR IrDA Clock Divider Select.

0 Divide by 4.

1 Divide by 2.

R/W 0

0 CIR IrDA Clock Select.

0 Clock is taken directly from mux. (The divider select bit DIR has no

effect.)

1 Clock is taken from 2/4 divider.

R/W 0

Table 7-3. Clock Mux Input Select Values

Value Meaning

000 No clocking

001 Auxiliary Clock

010 FREQ0

011 FREQ1

100 FREQ2

101 FREQ3

110 FREQ4

111 FREQ5

Bits Name Description R/W Default

176 AMD Alchemy™ Au1000™ Processor Data Book

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7.1.3.1 CPU PLL Control

The CPU PLL control register (sys_cpupll) resets to its default value only for a hardware reset. That is, after Sleep, and

during a runtime reset the CPU PLL retains its frequency.

Note that when programming the CPU PLL control register the system designer must not violate the rated frequency limits

of the Au1000 processor. Configuring the PLL outside this frequency range causes undefined behavior.

This register is read/write, but the value read is valid only after initialization. After coming out of reset, hardware reset or

Sleep, this register must first be written for the value read back to be valid. For this reason it is suggested that this register

be initialized at boot time regardless if the value is changed from default.

After writing to the sys_cpupll register, the system automatically halts for 20 µs to allow for the PLL to relock and clocks to

become stable.

sys_cpupll Offset = 0x0060

Bit313029282726252423222120191817161514131211109876543210

PLL[5:0]

Def.00000000000000000000000000010000

Bits Name Description R/W Default

31:6 — Reserved. Should be cleared. R/W 0

5:0 PLL CPU PLL Multiplier. Determines the integer multiplier used to multiply the

CPU PLL to generate the CPU clock.

For example, with the default of 16 and a 12 MHz OSC frequency, the

CPU clock frequency is 192 MHz.

Note that PLL multiplier values that place the clock frequency outside of

rated limits are invalid.

0–15: Reserved and undefined

16–(n-1): Valid PLL multiplier

n–63: Reserved and undefined

Where n is the smallest PLL multiplier that would cause the CPU clock fre-

quency to exceed the rated frequency limits of the part.

R/W 0x10

AMD Alchemy™ Au1000™ Processor Data Book 177

Clocks 30360E

7.1.3.2 Auxiliary PLL Control

The auxiliary PLL control register (sys_auxpll) resets to its default value on hardware reset, after Sleep, and during a runt-

ime reset. This register is read/write, but the value read is valid only after initialization. For this reason it is recommended

that system software initialize this register at hardware reset, runtime reset and Sleep, even if programming its default

value.

Note that when programming the auxiliary PLL control register the system designer must not violate the rated frequency

limits of the Au1000 processor. Configuring the PLL outside this frequency range causes undefined behavior.

Unlike the sys_cpupll register, writing sys_auxpll does not cause the system to halt. As a consequence, clocks taken from

the AUX PLL may be unstable for up to 20 µs. To ensure stable clocks during AUX PLL lock time, the sys_cpupll register

can be written with its current value to force the system to halt for 20 µs.

7.1.4 Hardware Considerations

Note also that the EXTCLK[1:0] clocks are multiplexed signals and require programming of the sys_pinfunc register (see

Section 7.3.1.1 "Pin Function" on page 183) as follows:

When using the external clocks from the clock generation block, the sys_pinfunc register must be programmed such that

GPIO[2] and/or GPIO[3] are configured to be driven by EXTCLK0 and/or EXTCLK1.

Section 11.8 "Crystal Specifications" on page 250, define the crystal specifications.

7.1.5 Programming Considerations

When changing the CPU PLL value through the sys_cpupll register, the system automatically halts for 20 µs to allow

clocks to stabilize. During this time no interrupts are serviced, potentially affecting real-time systems. However, modifying

the sys_auxpll register does not cause the system to halt, and therefore clocks taken from the AUX PLL may be unstable

for up to 20 µs. To ensure stable clocks while the AUX PLL locks, the sys_cpupll register can be written with its current

value to force the system to halt for 20 µs.

sys_auxpll Offset = 0x0064

Bit313029282726252423222120191817161514131211109876543210

PLL[5:0]

Def.00000000000000000000000000000000

Bits Name Description R/W Default

31:6 — Reserved. Should be cleared. R/W 0

5:0 PLL Auxiliary PLL Multiplier. Determines the integer multiplier used to multiply

the auxiliary PLL to generate the auxiliary clock.

For example, with a value of 12 and a 12 MHz OSC frequency, the auxil-

iary clock frequency will be 144 MHz.

Note that PLL multiplier values that place the clock frequency outside of

rated limits are invalid.

0: Disable the auxiliary PLL.

1–7: Reserved and undefined

8–(n-1): Valid PLL multiplier

n–63: Reserved and undefined

Where n is the smallest PLL multiplier that would cause the auxiliary clock

frequency to exceed the rated frequency limits of the part.

R/W 0x00

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7.2 Time of Year Clock and Real Time Clock

The Au1000 processor contains two programmable counters designed for use as a time of year clock (TOY) and real time

clock (RTC). Because the TOY continues counting through Sleep, a TOY counter match can be used as a wake-up source.

The RTC, however, will power-down in Sleep mode.

Note that both the TOY and RTC counters are driven by the 32.768-kHz clock input. The clock input source can be a crystal

or external clock. (See Section 11.8 "Crystal Specifications" on page 250 for crystal details.)

Each programmable counter employs a register to initialize the counter or load a new value, a trim divider to adjust the

incoming 32.768-kHz clock, and three match registers which have associated interrupts that trigger on a match. Each

counter is also able to generate an interrupt on every tick. All interrupts are maintained through the interrupt controller. Both

programmable counters share a status register.

Figure 7-4 shows the functional block diagram of both the TOY and the RTC. The registers used to implement the block,

including the counter control register (sys_cntrctrl), are described in the following section.

Figure 7-4. TOY and RTC Block Diagram

Divide =

TRIM + 1

TOY Counter

Match0

Match1

Match2

Comparators

Interrupt

32.768 kHz

sys_cntrctrl[EO]

sys_cntrctrl[BTT]

GPIO[8]

sys_cntrctrl[BP]

Divide =

TRIM + 1

RTC Counter

Match0

Match1

Match2

Comparators

Interrupt

sys_cntrctrl[BRT]

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7.2.1 Time of Year Clock and Real Time Clock Registers

Each counter operates identically with the only difference being that the TOY continues counting through Sleep and the

RTC does not.

The programmable counter control registers and their associated offsets are listed in Table 7-4. When functionality is iden-

tical for registers in the different programmable counters, only one general register description is presented with offsets

pointing to the specific registers.

7.2.1.1 Trim Register

The TOY trim write status bit (sys_cntrctrl[TTS]) must be clear before writing sys_toytrim. It is set upon writing this regis-

ter and is cleared by hardware when the write takes effect.

The RTC trim write status bit (sys_cntrctrl[RTS]) must be clear before writing sys_rtctrim. It is set upon writing this regis-

ter and is cleared by hardware when the write takes effect.

This register is unpredictable at power-on. During a runtime reset and during Sleep this register retains its value.

Table 7-4. Programmable Counter Registers

Offset (Note 1)

Note 1. See Table 7-1 "System Control Block Base Address" on page 167 for base address.

0x0000 sys_toytrim Trim value for 32.768-kHz clock source for TOY Hardware

0x0004 sys_toywrite TOY counter value is written through this register. Hardware

0x0008 sys_toymatch0 TOY match 0 value for interrupt generation Hardware

0x000C sys_toymatch1 TOY match 1 value for interrupt generation Hardware

0x0010 sys_toymatch2 TOY match 2 value for interrupt generation Hardware

0x0014 sys_cntrctrl Control register for TOY and RTC Hardware

0x0040 sys_toyread TOY counter value is read from this register Hardware

0x0044 sys_rtctrim Trim value for 32.768-kHz clock source for RTC Hardware

0x0048 sys_rtcwrite RTC counter value is written through this register. Hardware

0x004C sys_rtcmatch0 RTC match 0 value for interrupt generation Hardware

0x0050 sys_rtcmatch1 RTC match 1 value for interrupt generation Hardware

0x0054 sys_rtcmatch2 RTC match 2 value for interrupt generation Hardware

0x0058 sys_rtcread RTC counter value is read from this register. Hardware

sys_toytrim - TOY Trim Offset = 0x0000

sys_rtctrim - RTC Trim Offset = 0x0044

Bit313029282726252423222120191817161514131211109876543210

TRIM[15:0]

Def.0000000000000000XXXXXXXXXXXXXXXX

Bits Name Description R/W Default

31:16 — Reserved. Should be cleared. R 0

15:0 TRIM Divide value for 32.768kHz input. Divide = TRIM + 1 R/W UNPRED

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7.2.1.2 Counter Write

The TOY value write status bit (sys_cntrctrl[TS]) must be clear before writing sys_toywrite. It is set upon writing this reg-

ister and is cleared by hardware when the write takes effect.

The RTC value write status bit (sys_cntrctrl[RS]) must be clear before writing sys_rtcwrite. It is set upon writing this reg-

ister and is cleared by hardware when the write takes effect.

This register is unpredictable at power-on. During a runtime reset and during Sleep this register retains its value.

7.2.1.3 Match Registers

The corresponding write status bit (sys_cntrctrl[TMn] or sys_cntrctrl[RMn]) must be clear before writing the below regis-

ters. It is set upon writing the register and is cleared by hardware when the write takes effect.

Each match register is capable of causing an interrupt as shown in Section 5.0 "Interrupt Controller" on page 81. The

sys_toymatch2 can be used to wake up from Sleep; see Section 7.4.4.2 "Wakeup Source Mask Register" on page 192.

See also Section 7.2.2.

These registers are unpredictable at power-on. During a runtime reset and during Sleep these registers retain their value.

sys_toywrite - TOY counter value write Offset = 0x0004

sys_rtcwrite - RTC counter value write Offset = 0x0048

Bit313029282726252423222120191817161514131211109876543210

COUNT[31:0]

Def.XXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXX

Bits Name Description R/W Default

31:0 COUNT Counter Write. The respective counter will be updated with the value writ-

ten to this register at the next trimmed clock.

W UNPRED

sys_toymatch0 - TOY Match 0 Offset = 0x0008

sys_toymatch1 - TOY Match 1 Offset = 0x000C

sys_toymatch2 - TOY Match 2 Offset = 0x0010

sys_rtcmatch0 - RTC Match 0 Offset = 0x004C

sys_rtcmatch1 - RTC Match 1 Offset = 0x0050

sys_rtcmatch2 - RTC Match 2 Offset = 0x0054

Bit313029282726252423222120191817161514131211109876543210

MATCH[31:0]

Def.XXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXX

Bits Name Description R/W Default

31:0 MATCH A match with the counter and the value in this register causes an interrupt. R/W UNPRED

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7.2.1.4 TOY and RTC Counter Control

The TOY and RTC counter control register (sys_cntrctrl) contains control bits and status bits to configure and control both

programmable counters.

Write Status Bits: These bits indicate the status of the latest update to the respective register/field. When the corresponding

register/field is written, this bit is set indicating that there is a write pending. When this bit is cleared the write has taken

place. Software should poll the correct bit and insure that it is 0 before updating the respective register/field.

This register resets to default values only on a hardware reset. During a runtime reset and during Sleep this register retains

its value.

sys_cntrctrl Offset = 0x0014

Bit313029282726252423222120191817161514131211109876543210

RTSRM2RM1RM0 RS BP BRT BTT EO CCS 32S TTS TM2 TM1 TM0 TS

Def.00000000000000000000000000X00000

Bits Name Description R/W Default

31:21 — Reserved. Should be cleared. R 0

20 RTS sys_rtctrim Write Status.

sys_rtcmatch2 Write Status.

sys_rtcmatch1 Write Status.

sys_rtcmatch0 Write Status.

sys_rtcwrite Write Status.

0 No write is pending. It is safe to write to the register.

1 A write is pending. Do not write to the register.

19 RM2 R0

18 RM1 R0

17 RM0 R0

16 RS RR

15 — Reserved. Should be cleared. R 0

14 BP Bypass the 32.768-kHz OSC.

0 Select Oscillator Input (XTI32, XTO32)

1 GPIO[8] drives the counters. This is a test mode where GPIO[8] can

drive the counters from an external source or through software using

the GPIO controller.

R/W 0

13 — Reserved. Should be cleared. R/W 0

12 BRT Bypass RTC Trim.

0 Normal operation

1 The RTC is driven directly by the 32.768 kHz clock, bypassing the

trim.

R/W 0

11 — Reserved. Should be cleared. R/W 0

10 BTT Bypass TOY Trim.

0 Normal operation

1 The TOY is driven directly by the 32.768 kHz clock, bypassing the

trim.

R/W 0

9 — Reserved. Should be cleared. R 0

8 EO Enable 32.768-kHz Oscillator. Enables the clock for the RTC/TOY block.

0 Disable the clock.

1 Enable the clock.

Regardless of the clock source (crystal or overdriven clock through XTI32/

XTO32, or bypass through GPIO[8]), the EO bit must be set to enable the

RTC/TOY counters. After enabling the clock by setting EO, poll the oscilla-

tor status bit (32S) until it returns a ‘1’. Once 32S is set, wait an additional

one second to allow for frequency stabilization within the block before

accessing other RTC/TOY registers (not including sys_cntrctrl).

Note: If the oscillator is being overdriven or bypassed through GPIO[8], be

sure to set EO only after a stable clock is being driven into the part.

R/W 0

7 CCS sys_cntrcntrl Write Status. R 0

6 — Reserved. Should be cleared. R 0

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7.2.2 Programming Considerations

To change the values of the counter and match registers, software must poll the state of the corresponding status bit in

sys_cntrctrl. When the corresponding write status bit (sys_cntrctrl[TTS,TMn,TS] or sys_cntrctrl[RTS,RMn,RS]) is 0 it is

okay to write a new value. Once the new value is written to the register the status bit will change to a 1. When the write sta-

tus bit is 1 the new value is being updated in supporting hardware. When the write status changes to a 0 then the new value

is active in the device.

5 32S 32.768 kHz Oscillator Status. Detects two consecutive 32 kHz cycles from

the clock source for the RTC/TOY block.

0 Clock is not running.

1 Clock is running.

Note: Be sure to wait 1 second after 32S is set to allow for frequency stabi-

lization within the block before accessing RTC/TOY registers.

R UNPRED

4 TTS sys_toytrim Write Status.

sys_toymatch2 Write Status.

sys_toymatch1 Write Status.

sys_toymatch0 Write Status.

sys_toywrite Write Status.

0 No write is pending. It is safe to write to the register.

1 A write is pending. Do not write to the register.

3TM2 R0

2TM1 R0

1TM0 R0

0TS R0

Bits Name Description R/W Default

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7.3 General Purpose I/O and Pin Functionality

This section covers the programming model for the general purpose I/O (GPIO) signals. The Au1000 processor supports

32 GPIOs.

This section also documents how to change the functionality of multiplexed pins. These pins can function at the system

level as a GPIO signal, or they can be assigned a signal function dedicated to an integrated peripheral device.

Each GPIO can be configured as either an input or an output. The GPIO ports also can be connected to the internal inter-

rupt controllers to generate an interrupt from input signals. See Section 5.0 "Interrupt Controller" on page 81 for information

on interrupts.

7.3.1 Pin Functionality

To maximize the functionality of the Au1000 processor, many of the pins have multiple uses. Note that if a pin is pro-

grammed for a certain use, any other functionality associated with that pin can not be utilized at the same time. In other

words, a pin can not be used as a GPIO at the same time it is assigned to a peripheral device.

(For reference, Figure 10-1 "Au1000™ Processor External Signals" on page 216 shows a block diagram of all external sig-

nals. Signals that are multiplexed on one pin will show the shared function in parentheses.)

7.3.1.1 Pin Function

This register resets to its default state at hardware reset, runtime reset and Sleep.

sys_pinfunc Offset = 0x002C

Bit313029282726252423222120191817161514131211109876543210

CS USB U3 U2 U1 SRC EX1 EX0 RF UR3 I2D I2S NI2 U0 RD A97 S0

Def.00000000000000000000000000000000

Bits Name Description R/W Default

31:17 — Reserved. Should be cleared. R 0

16 CS Clock Select. Applies only when EX0 = 1.

0 EXTCLK0 will drive pin.

1 32-kHz OSC clock will drive pin.

R/W 0

15 USB USB Functionality.

0 USBDP and USBDM will drive pins (pins are connected to USB

device module).

1 USBH0P and USBH0M will drive pins (pins are connected to USB

host port 0).

R/W 0

14 U3 UART3/GPIO[23].

0 U3TXD drives pin.

1 Pin is configured for GPIO[23].

R/W 0

13 U2 UART2/GPIO[22].

0 U2TXD drives pin.

1 Pin is configured for GPIO[22].

R/W 0

12 U1 UART1/GPIO[21].

0 U1TXD drives pin.

1 Pin is configured for GPIO[21].

R/W 0

11 SRC GPIO[6]/SMROMCKE.

0 Pin is configured for GPIO[6].

1 SMROMCKE drives pin.

R/W 0

10 EX1 GPIO[3]/EXTCLK1.

0 Pin is configured for GPIO[3].

1 EXTCLK1 will drive pin.

R/W 0

9 EX0 GPIO[2] / (EXTCLK0 or 32kHz OSC).

0 Pin is configured for GPIO[2].

1 Pin is configured for EXTCLK0 or 32 kHz OSC. CS (bit 16) selects

whether EXTCLK0 or the 32 kHz OSC drives the pin.

R/W 0

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8 IRF GPIO[15]/IRFIRSEL.

0 Pin is configured for GPIO[15].

1 IRFIRSEL will drive pin.

R/W 0

7 UR3 GPIO[14:9]/UART3.

0 Pins are configured as GPIO[14:9].

1 Pins are configured for optional UART3 flow control. U3DTR, U3RTS,

U3RI, U3DCD, U3DSR, and U3CTS will drive pins.

System Note: For systems that use the UART3 interface but do not use

the optional modem control signals (UR3=0), the modem status interrupts

must be disabled (uart3_inten[MIE]=0) to avoid false UART3 interrupts

when using GPIO[9], GPIO[10], GPIO[11], or GPIO[12] as an input.

R/W 0

6 I2D GPIO[8]/I2SDI.

0 Pin is configured for GPIO[8].

1 Pin is configured as I2SDI.

System Note: For systems that use the I2S interface for unidirectional

operation (I2SDI not used), the GPIO[8] function is available but with the

following restrictions:

1) When I2SDIO is configured as an input, GPIO[8] can be used only as

an output.

2) When I2SDIO is configured as an output, the I2S receive function

must be disabled if GPIO[8] is to be used as an input.

R/W 0

5 I2S I2S/GPIO[31:29].

0 Pins are configured for I2S mode. I2SWORD, I2SCLK, I2SDIO will

drive pins.

1 Pins are configured as GPIO[31:29].

R/W 0

4 NI2 MAC1/GPIO[28:24].

0 Pins are configured as Ethernet port 1. N1TXD[3:0], and N1TXEN will

drive port.

1 Pins are configured as GPIO[28:24].

R/W 0

3 U0 UART0/GPIO[20].

0 Pin is configured for U0TXD (necessary for UART0 operation).

1 Pin is configured as GPIO[20].

R/W 0

2 IRD IrDA/GPIO[19].

0 Pin is configured for IRTXD (necessary for IrDA operation).

1 Pin is configured as GPIO[19].

R/W 0

1 A97 AC97/SSI_1.

0 Pins are configured for AC97 mode. ACSYNC, ACBCLK, ACDO,

ACRST# will drive pins.

1 Pins are configured for SSI_1 mode. S1DOUT, S1DIN, S1CLK and

S1DEN will drive pins.

R/W 0

0 S0 SSI_0/GPIO[16:18].

0 Pins are configured for SSI_0 mode. S0CLK, S0DOUT and S0DEN

will drive pins.

1 Pins are configured as GPIO[16:18].

R/W 0

Bits Name Description R/W Default

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7.3.2 GPIO Control Registers

The GPIOs on the Au1000 processor have been designed to simplify the GPIO control process by removing the need for a

semaphore to control access to the registers. This is because there is no need to read, modify, write, as there are separate

registers for setting and clearing a bit. In this way a function can freely manipulate its associated GPIOs without interfering

with other functions.

Figure 7-5 shows the logical implementation of each GPIO. The names represent bit n of the corresponding register which

affect GPIO[n].

Figure 7-5. GPIO Logic Diagram

The following table shows the GPIO control registers and the associated offsets from sys_base. Certain registers share

offsets and have different functionality depending on whether the access is a read or a write. The register descriptions

detail the functionality of each register. Bit n of a particular register should be associated with GPIO[n] for all registers

except sys_pininputen.

Table 7-5. GPIO Control Registers

Offset (Note 1) Register Name Register Description Default

0x0100 sys_trioutrd The TRI-STATE/Output state register shows the current

state of the GPIO.

0 GPIO[n] is in TRI-STATE. To TRI-STATE GPIO[n] is

accomplished by setting the corresponding bit in the

sys_trioutclr register.

1 Output is enabled. Enabling GPIO[n] as an output is

accomplished by programming GPIO[n] as a 0 or 1 using

the sys_outputclr[n] or sys_outputset[n] registers.

If the pin is not an output it should be in TRI-STATE.

0x00000000

(all GPIOs are

TRI-STATE)

0x0100 sys_trioutclr

0x0108 sys_outputrd Controls the state of the GPIO[n] as an output.

0 To output a low level, set sys_outputclr[n].

1 To output a high level, set sys_outputset[n].

Programming a bit value in the output register brings the pin

out of TRI-STATE mode and enables the output.

UNPRED

0x0108 sys_outputset

0x010C sys_outputclr

sys_outputrd[n]

sys_outputset[n]

sys_outputclr[n]

S-R

sys_trioutrd[n]

sys_pinstaterd[n]

sys_trioutclr[n]

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7.3.2.1 GPIO Control Registers

Each GPIO control register is 32 bits wide with bit n in each register affecting GPIO[n].

These registers will reset to defaults only on a hardware reset. During a runtime reset and during Sleep this register will

retain its value.

See Table 7-5 for the default values at hardware reset.

Certain registers in the list have the same offset but offer different functionality depending on whether a read or a write is

being performed.

Registers ending in *rd, *set and *clr have the following functionality:

•*rd registers are read only registers will read back the current value of the register.

•*set registers are write only registers and will set to 1 all bits that are written 1. Writing a value of 0 will have no impact on

the corresponding bit.

•*clr registers are write only registers and will clear to zero all bits that are written 1. Writing a value of 0 will have no

impact on the corresponding bit.

0x0110 sys_pinstaterd Allows the pin state to be read when an input. This register

will also give the output state.

UNPRED

0x0110 sys_pininputen Any write to this register allows GPIO[31:0] to be used as

inputs. This register must be written before any GPIO can

be used as an input, an interrupt source, or for use as a

wake up source.

UNPRED

Note 1. See Table 7-1 "System Control Block Base Address" on page 167 for base address.

*rd

*set

*clr

Bit313029282726252423222120191817161514131211109876543210

FUNC[31:0]

Bits Name Description R/W Default

31:0 FUNC[n] The function of each register is given in the previous table.

FUNC[n] controls the functionality of GPIO[n].

*_read - read only

*_set - write only

*_clear - write only

See the following text.

Table 7-5. GPIO Control Registers (Continued)

Offset (Note 1) Register Name Register Description Default

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7.3.2.2 GPIO Input Enable

The sys_pininputen is a 32-bit, write-only register. When this register is written, the input functionality of all GPIOs is

enabled. This register enables GPIOs for use as an input but does not explicitly configure all GPIOs as inputs. The value of

the GPIO control registers and the pin function register will define the state of each GPIO.

GPIOs cannot be used as inputs until this register is written. This write is required only once per hardware reset (i.e. Sleep

and a runtime reset will not require another write to this register).

7.3.3 Hardware Considerations

The system pin function register (sys_pinfunc) controls the functionality of many GPIO/peripheral pins. If a pin is pro-

grammed for a certain functionality, all other functionality associated with that pin is disabled.

For example, if sys_pinfunc[U3] is cleared configuring the pin as U3TXD, GPIO[23] can not be used as a GPIO nor can

the GPIO be configured as an interrupt. Conversely if sys_pinfunc[U3] is set configuring the pin as GPIO[23], U3TXD (and

thus the UART3 interface) is not usable. GPIO[23] can be used as a GPIO and to generate interrupts.

7.3.4 Using GPIO for External DMA Requests

See Section 4.2 "Using GPIO as External DMA Requests (DMA_REQn)" on page 78 for information.

sys_pininputen Offset = 0x0110

Bit313029282726252423222120191817161514131211109876543210

Def.XXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXX

Bits Name Description R/W Default

31:1 — Reserved. Should be cleared. W N/A

0 EN A write to this bit (0 or 1) enables all GPIOs to be used as inputs. W N/A

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7.4 Power Management

The Au1000 processor contains a robust power management scheme allowing multiple levels of power conservation to

enable the system designer options depending on whether power conservation or system responsiveness is more critical.

In the Au1000 processor, power management can be broken into three different areas:

•CPU

•Peripherals

•Device

The lowest power state consists of putting the entire device into a Sleep state. The CPU also supports two Idle states that

differ as to whether bus snooping is supported. In addition each peripheral can have its clocks disabled when not in use

thus significantly reducing the power draw by those blocks not in use.

The flow chart in Figure 7-6 shows the different stages of power management for the CPU (IDLE0,1) and the device

(SLEEP) and how each state is entered and left. Note that any interrupt can be used to bring the CPU out of either Idle

state while only a GPIO[7:0] or sys_toymatch2 interrupt can be enabled (in sys_wakemsk) to bring the device out of

Sleep.

Figure 7-6. Sleep and Idle Flow Diagram

Prepare to Sleep

- Flush Cache

- SDRAM Sleep

- Turn off Peripherals

- Enable Sleep Power

- Set Sleep bit

Execute WAIT0

SLEEP

IDLE0 IDLE1

Execute WAIT1

Wakeup

Enabled

Interrupt

Wakeup

Enabled

Interrupt

Ye s

Ye s Ye s

Normal Operation

(No Snoop)(Snoop)

REBOOT

TOY Match

GPIO[7:0]

Interrupt

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7.4.1 CPU Power Management - Idle

The CPU can be put into 2 different low-power Idle modes (IDLE0 and IDLE1) by using the wait instruction:

•In the IDLE0 state the CPU snoops the bus and cache coherency is maintained.

•In the IDLE1 state the CPU does not snoop the bus and cache coherency is lost.

The wait instruction and at least 4 instructions following it must be in the cache for the wait to occur. See Section 2.6.3

"WAIT Instruction" on page 27 for more information.

At all times the MMU, data cache, execution and multiply-and-accumulate blocks are placed in a low power state if they are

not being used.

7.4.1.1 Returning from Idle

The processor wakes from the Idle state (IDLE0 or IDLE1) upon receiving an interrupt. The time required for the processor

core to return to normal execution is as follows:

•Five to ten CPU clocks are needed to restart clocks to the CPU.

•It takes an additional ten CPU clocks for the core to recognize the interrupt and begin fetching the interrupt service

routine.

Therefore, a maximum of 20 CPU clocks are required to resume normal instruction pipeline execution. If the interrupt ser-

vice routine is in the instruction cache, the instruction returns immediately; otherwise, there is an additional delay while

fetching the instruction from memory.

7.4.2 Peripheral Power Management

Peripheral power management is handled through clock management and disabling of unused peripherals. Table 7-6 lists

the peripherals and their related power management registers. The actual register descriptions should be referred to for

programming details.

Note that when separate reset/peripheral enable and clock-enable bits are provided, the reset must be applied first, and

then the clocks should be disabled. This will simplify programming, as the suggested bring up sequence is typically to first

enable clocks and then subsequently to bring the peripheral out of reset.

Table 7-6. Peripheral Power Management

Peripheral

Power

Management

USB Host usbh_enable When the USB host is not in use the E bit can be cleared to disable the

host. The CE bit should also be cleared to disable clocks to the block.

USB Device usbd_enable When the USB device is not in use the E bit can be cleared to disable

the host. The CE bit should also be cleared to disable clocks to the

block.

Ethernet MACnmacen_macnWhen either block is not being used, the respective E[2:0] bits should

be cleared to disable the MAC, and the CE bit should be cleared to gate

clocks to the MAC.

UARTnuartn_enable When a UART is not being used, the E bit should be cleared to hold the

part in reset and the CE bit should be cleared to disable clocks to the

block.

SSInssin_enable When an SSI is not being used, clear the E bit to hold the block in reset,

and set the CD bit to disable clocks to the block.

IrDA ir_enable The HC bit can be used to run the IrDA at half the SBUS. The CE bit

should be disabled when not using the IrDA to disable clocks to this

peripheral.

General-Purpose I/O

(GPIO) Controller

sys_trioutclr Although there is not a specific low-power configuration for the GPIOs,

putting the unused GPIOs into TRI-STATE minimizes their power usage.

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7.4.3 Device Power Management - Sleep

The Sleep state of the Au1000 processor puts the entire device into a low-power state. Sleep is the lowest power state of

the part and requires a complete system initialization on wakeup. There are multiple steps to take when going into Sleep

and waking up to insure data integrity. During this state all registers values outside the system control block are lost and

cache coherency is not maintained.

The programmable counter 0 (intended for TOY) continues clocking and remains functional during Sleep. However, the pro-

grammable counter 1, as well as other clocks throughout the Au1000, are disabled during Sleep.

When coming out of Sleep there is a programmable delay defined by sys_powerctrl[VPUT]. This is the time that the sys-

tem designer has to ensure VDDI is stable from the rising edge of PWR_EN.

To enter Sleep the following steps should be taken. This code should be run from Flash, or conversely the system program-

mer should guarantee that this code will run from cache because after SDRAM is put into auto-refresh mode, memory

accesses will no longer work.

1) Enable Sleep Power by writing to the sys_slppwr register.

2) Turn off all peripherals. (Explicitly turning off all peripherals in use ensures a graceful transition to Sleep mode.)

3) Push dirty data out of the cache. (During Sleep cached data is lost.)

4) If SDRAM contents are to be kept through Sleep, SDRAM should be put into auto-refresh mode. See Section 3.1

"SDRAM Memory Controller" on page 44 for more information.

If SDRAM is not needed to be maintained through Sleep, disable the SDRAM.

5) If using one of GPIO[7:0] as a wakeup source, sys_pininputen must be written to enable the GPIO as an input if this

has not already been done at system startup.

6) The sys_wakemsk register should be set with the appropriate value according to what signal(s) should wake the pro-

cessor.

7) The sys_wakesrc register should be written to explicitly clear any pending wake interrupts.

8) Enable Sleep by writing to the sys_sleep register. This step puts the system to Sleep.

9) As the system enters Sleep mode, the PWR_EN signal is negated. This can be used to disable VDDI if needed.

When the processor takes a Sleep interrupt to wake up, the following steps should be taken:

1) After the Sleep interrupt is taken, the PWR_EN signal is asserted by hardware. Within the time indicated by

sys_powerctrl[VPUT], the system must ensure that VDDI is stable.

2) The processor will then boot from physical address 0x1FC00000 as normal.

3) If Sleep is to be used by the system and a different flow should be followed when coming out of Sleep the

sys_wakesrc should be read to determine if the processor is coming out of Sleep and what caused the wakeup. The

system should then write the sys_wakesrc register to clear this information.

4) The processor will need to perform complete system initialization. All registers except those described as otherwise in

the System Control Block will be at their default values.

Programmable Counters

(TOY and RTC)

sys_cntrctrl If both the TOY and RTC are not being used, then disable the oscillator.

AC97 Controller ac97_enable If the AC97 block is not in use, the D bit should be used to disable the

module and the CE bit should be disabled to gate clocks from the block.

I2S i2s_enable If the I2S block is not in use, the E bit should be used to place the block

in reset and the CE bit should be disabled to gate clocks from the block.

Table 7-6. Peripheral Power Management (Continued)

Peripheral

Power

Management

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7.4.3.1 Sleep Sequence and Timing

As the processor enters Sleep mode, the system designer has the option of disabling VDDI to conserve power. The

PWR_EN signal defines the Sleep window. Figure 7-7 shows the Sleep sequence.

Figure 7-7. Sleep Sequence

The system designer must ensure VDDI is stable from the rising edge of PWR_EN within the time period as programmed in

sys_powerctrl[VPUT]. Note that VDDXOK (not shown) remains asserted during the Sleep sequence.

7.4.4 Power Management Registers

The power management registers and their associated offsets are listed in Table 7-7. These registers are located off of the

base shown in Table 7-1.

7.4.4.1 Scratch Registers

The scratch registers keep their values through Sleep and runtime resets. These registers allow the system programmer to

save user-defined state information or a pointer to a context so that the previous context can be restored when coming out

of Sleep, if needed. Note that the scratch registers have unpredictable default values after a hardware reset.

Table 7-7. Power Management Registers

Offset (Note 1)

Note 1. See Table 7-1 "System Control Block Base Address" on page 167 for base address.

0x0018 sys_scratch0 User-defined register that retains its value

through Sleep.

Hardware

0x001C sys_scratch1 User-defined register that retains its value

through Sleep.

Hardware

0x0034 sys_wakemsk Sets which GPIO or whether TOY match

can cause Sleep wakeup.

Hardware

0x0038 sys_endian Sets Big or Little Endian. Hardware & Runtime

0x003C sys_powerctrl Sets SBUS divider and power-up time. Mixed - See Register Description

0x005C sys_wakesrc Gives source of Sleep wakeup. Hardware

0x0078 sys_slppwr Initiates power state for Sleep mode. Hardware

0x007C sys_sleep Initiates Sleep mode. Hardware

sys_scratch0 Offset = 0x0018

sys_scratch1 Offset = 0x001C

Bit313029282726252423222120191817161514131211109876543210

SCRATCH[31:0]

Def.XXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXX

Bits Name Description R/W Default

31:0 SCRATCH User-defined information. R/W UNPRED

PWR_EN

DDI

VPUT

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7.4.4.2 Wakeup Source Mask Register

For each individual bit that is set, the corresponding signal or event (for the case of the TOY match) can be used to cause a

Sleep wakeup.

A high level on the enabled GPIO will cause the interrupt to trigger.

This register will reset to defaults only on a hardware reset. During a runtime reset and during Sleep this register retains its

value.

7.4.4.3 Endianness Register

To change the endianness of the Au1000 processor is a three step process as follows:

1) Program the endianness bit in the system endianness register (sys_endian[EN]).

2) Read the sys_endian register. (This is required to ensure the final write to the CP0 register will update the endian

value.)

3) Read the CP0 register Config0. (See Section 2.7.15 "Configuration Register 0 (CP0 Register 16, Select 0)" on page

34.)

4) Write the value read back into the CP0 Config0 register. The act of writing the CP0 register will put the processor into

the endian state as programmed in sys_endian[EN].

This register as well as the processor endianness will reset to big endian after a hardware reset, runtime reset and after

Sleep.

sys_wakemsk Offset = 0x0034

Bit313029282726252423222120191817161514131211109876543210

M2 GPIO[7:0]

Def.00000000000000000000000000000000

Bits Name Description R/W Default

31:9 — Reserved. Should be cleared. R 0

8 M2 Setting this bit enables the programmable TOY Counter Match Register 2

(sys_toymatch2) to cause a wakeup interrupt. See Section 7.2.1.3

"Match Registers" on page 180.

R/W 0

7:0 GPIO[7:0] Setting bit n causes GPIO[n] to cause a Sleep wakeup. R/W 0

sys_endian Offset = 0x0038

Bit313029282726252423222120191817161514131211109876543210

Def.XXXXXXXXXXXXXXXXXXXXXXXXXXXXXXX0

Bits Name Description R/W Default

31:1 — Reserved. Should be cleared. R UNPRED

0 EN Endianness.

0 Big Endian

1 Little Endian

R/W 0

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7.4.4.4 Power Control Register

Bits[6:5] of this register are reset to default values for a hardware reset, runtime reset and after Sleep.

Bits[4:0] of this register reset to default values only on a hardware reset. During a runtime reset and during Sleep these bits

retain their values.

7.4.4.5 Wakeup Cause Register

Before setting the Sleep bit this register should be cleared. This register will retain pending interrupts according to the set-

ting in the sys_wakemsk register even if those events did not occur during Sleep. In other words if a GPIO’s functionality is

multiplexed between multiple functions, a high level could cause the associated sys_wakesrc bit to be set even if the action

did not occur during Sleep.

The bits in this register must be explicitly cleared as they will hold their values through Sleep and a runtime reset.

All bits in this register are set by hardware and cleared by any write to this register.

sys_powerctrl Offset = 0x003C

Bit313029282726252423222120191817161514131211109876543210

SI SB VPUT SD

Def.00000000000000000000000000000000

Bits Name Description R/W Default

31:7 — Reserved. Should be cleared. R 0

6 SI Idle State SBUS Clock Divider Enable.

0 The Idle state SBUS clock divider is disabled.

1 Enable the SBUS clock to be divided by an additional factor of 2

when the processor is in an IDLE state (taken through the WAIT instruc-

tion). All peripheral bus clocks (such as the SDRAM and UART controllers)

will be internally compensated with no programmer intervention required.

NOTE: SD must be programmed to 00 (divide by two) when SI is set.

R/W 0

5 SB SBUS Clock Divider Enable.

0 The SBUS clock divider is disabled.

1 Enable the SBUS clock to be divided by an additional factor of 2

when there is no bus activity. All clocks derived from the peripheral bus

clock (such as the SDRAM and UART controllers) will be internally com-

pensated with no programmer intervention required.

Note: SD must be programmed to 00 (divide by two) when SB is set.

R/W 0

4 — Reserved. Should be cleared. R 0

3:2 VPUT VDDI Power-up Time.

00 20 ms

01 5 ms

10 100 ms

11 2 µs

R/W Hardware

Reset

1:0 SD SBUS Clock Divider.

00 2

01 3

10 4

11 Reserved

R/W Hardware

Reset

sys_wakesrc Offset = 0x005C

Bit313029282726252423222120191817161514131211109876543210

M2 GP7GP6GP5GP4GP3 GP2 GP1 GP0 SW IP

Def.000000Rs0000000000000000000000Rs

Bits Name Description R/W Default

31:25 — Reserved. Should be cleared. R/W 0

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7.4.4.6 Sleep Power Register

7.4.4.7 Sleep Register

24 M2 Programmable TOY Match 2 caused wakeup from Sleep.

Set by hardware on Sleep wakeup due to TOY match.

Cleared by hardware on VDDXOK assertion.

This bit must be explicitly cleared by software (any write) because it holds

its value through Sleep and runtime reset.

R/W 0

23 GP7 GPIO[n] caused wakeup from Sleep.

Set by hardware on Sleep wakeup due to GPIO[n].

This bit must be explicitly cleared by software (any write) because it holds

its value through Sleep and runtime reset.

R/W 0

22 GP6 R/W 0

21 GP5 R/W 0

20 GP4 R/W 0

19 GP3 R/W 0

18 GP2 R/W 0

17 GP1 R/W 0

16 GP0 R/W 0

15:2 — Reserved, should be cleared. R/W 0

1 SW Sleep Wakeup. This bit is set by hardware on a Sleep wakeup and cleared

by software by a write to this register.

A runtime reset can be detected if both SW and IP are 0 at boot.

This bit must be explicitly cleared by software (any write) because it holds

its value through Sleep and runtime reset.

R/W 0

0 IP Initial Power-up. This bit is set by hardware on a hardware reset and

cleared by software by a write to this register.

A runtime reset can be detected if both SW and IP are 0 at boot.

This bit must be explicitly cleared by software (any write) because it holds

its value through Sleep and runtime reset.

R/W 1

sys_slppwr Offset = 0x0078

Bit313029282726252423222120191817161514131211109876543210

Def.XXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXX

Bits Name Description R/W Default

31:0 SP A write to this register prepares the internal power supply for going to

Sleep.

W UNPRED

sys_sleep Offset = 0x007C

Bit313029282726252423222120191817161514131211109876543210

Def.XXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXX

Bits Name Description R/W Default

31:0 SL A write to this register puts system to Sleep. W UNPRED

Bits Name Description R/W Default

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8.0Power-up, Reset and

Boot

This section presents the power-up, hardware reset and runtime reset sequence for the Au1000 processor. In addition the

boot vector is described.

8.1 Power-up Sequence

The Au1000 processor power structure is designed such that the external I/O voltage (VDDX) is driven separately from the

core voltage (VDDI). In this way the core voltage can be sourced at lower voltages saving power. In addition the Au1000 pro-

cessor is designed to allow the system designer to remove the core voltage during Sleep to maximize power efficiency.

Two signals VDDXOK and PWR_EN are used to facilitate this power strategy. VDDXOK is used as a signal to the processor

that power on VDDX is stable. Stable is defined as having reached 90% of its nominal value. PWR_EN is an output from the

Au1000 that is asserted after VDDXOK is asserted and can be used as an enable to the regulator that is providing the core

voltage, VDDI.

The following describes the power-up sequence for the Au1000 processor:

1) Apply VDDX (3.3V I/O power).

2) When VDDX has reached 90% of nominal, assert VDDXOK.

3) The Au1000 processor then asserts PWR_EN which can be used to enable the regulator driving VDDI (CPU power).

Figure 8-1 shows the power-up sequence, including arrows representing causal dependencies. For the timing specifica-

tions of this sequence, refer to Section 11.5.1 "Power-up Sequence Timing" on page 246.

Figure 8-1. Power-up Sequence

8.2 Reset

A hardware reset is defined as a reset in which both VDDXOK and RESETIN# are toggled. Typically this happens only at

power-on, but a system designer can choose to tie VDDXOK and RESETIN# together in which case all resets will be hard-

ware resets.

For a runtime reset, power remains applied and only the RESETIN# signal is toggled. Note that certain registers, specifi-

cally some of those in the system control block, are not affected by this type of reset. See the register description for the

register in question for more information. If a register is not reset to defaults by both hardware reset and runtime reset, it is

noted in the register description.

VDDX

VDDXOK

PWR_EN

VDDI

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8.2.1 Hardware Reset

For a hardware reset, VDDXOK makes a transition from low to high followed by RESETIN# negating (transitioning from low

to high). The following sequence describes a hardware reset:

1) ROMSEL and ROMSIZE should be terminated in the design so the appropriate boot type occurs. These values should

not change during runtime.

2) At the same time or after VDDXOK is asserted, RESETIN# can be negated. In other words, RESETIN# can not be

negated before VDDXOK is asserted. This allows VDDXOK and RESETIN# to be tied together.

3) RESETOUT# is negated after RESETIN# is negated.

Figure 8-2 shows the hardware reset sequence, including arrows representing causal dependencies. For the timing specifi-

cations of this sequence, refer to Section 11.5.2 "Hardware Reset Timing" on page 247.

Figure 8-2. Hardware Reset Sequence

8.2.2 Runtime Reset

During runtime (after power is stable) the reset sequence can be broken down as follows:

1) During a runtime reset it is assumed that VDDX and VDDI remain at their nominal voltage. In addition, VDDXOK must

remain asserted; otherwise, a hardware reset will occur. PWR_EN remains asserted by the Au1000 processor.

2) RESETIN# is held asserted long enough to be recognized as a valid reset.

3) The processor acknowledges the reset by asserting RESETOUT#.

4) After RESETIN# is released, the processor signals the end of the reset by negating RESETOUT#.

Note that certain registers (specifically those in the system control block) are not affected by a runtime reset. Note also that

ROMSEL and ROMSIZE should already be terminated in the design so the appropriate boot type occurs—these values

should not change during runtime.

Figure 8-3 shows the runtime reset sequence, including arrows representing causal dependencies. For the timing specifica-

tions of this sequence, refer to Section 11.5.3 "Runtime Reset Timing" on page 248.

Figure 8-3. Runtime Reset Sequence

VDDXOK

RESETIN#

RESETOUT#

VDDX (at nominal voltage)

VDDXOK (asserted high)

PWR_EN (remains asserted)

VDDI (at nominal voltage)

RESETIN#

RESETOUT#

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8.3 Boot

For both hardware and runtime resets, the CPU boots from KSEG1 address 0xBFC00000 which is translated to physical

address 0x0 1FC0 0000; therefore, the system designer should place the start of the boot code at 0x1FC00000.

The ROMSEL and ROMSIZE signals determine the boot device type and width according to Table 8-1. The system

designer should configure ROMSEL and ROMSIZE appropriately. Note that ROMSEL and ROMSIZE should not change

during runtime.

RCS0# is configured to be enabled for 0x1FC00000 at default when booting from a ROM device (ROMSEL = 0, ROMSIZE

= x). See Section 3.2 "Static Bus Controller" on page 53, for more information about the default timing and size of the

address enabled at reset.

SDCS0# is configured to be enabled for 0x1FC00000 at default when booting from a SMROM device (ROMSEL = 1, ROM-

SIZE = 0). See Section 3.1 "SDRAM Memory Controller" on page 44, for more information about the default timing and size

of the address enabled at reset.

8.3.1 Endianness and 16-Bit Static Bus Boot

When booting from a 16-bit chip select on the static bus, the system designer must be sure the data format (endianness) is

consistent across the Au1 core, the static bus controller, and the software image itself. This section describes how to make

endianness consistent for both little- and big-endian systems.

For more on how the endian mode affects the behavior of 16-bit static bus chip selects, see "Halfword Ordering and 16-bit

Chip Selects" on page 71.

Note: When programming ROM or Flash devices with a part programmer, take care to ensure that the programmer is not

swapping bytes or halfwords erroneously. The configuration of the part programmer is often a source of error when

initially bringing-up a new design.

8.3.1.1 16-Bit Boot for Little-Endian System

Booting from 16-bit ROM or Flash in a system that is intended to run the Au1 core in little-endian mode is very straightfor-

ward. Generally speaking, the boot code and/or the application is compiled for little-endian. Because the Au1 core defaults

to big-endian mode, the boot code must change the Au1 core endianness to little-endian before any data accesses (to the

16-bit chip-select). The resulting boot code and/or application image is placed in the ROM/Flash memory in the little-endian

format.

Even though the Au1 core starts in big-endian mode, the static bus controller properly retrieves instructions needed to boot

the system since the application image is in little-endian format and the static bus controller defaults to little-endian ordering

out of reset.

Table 8-1. ROMSEL and ROMSIZE Boot Device

ROMSEL ROMSIZE Boot Device Type and Width

0 0 Boot from 32-bit ROM interface

0 1 Boot from 16-bit ROM interface

1 0 Boot from 32-bit SMROM interface and Sync Flash boot

11Reserved

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8.3.1.2 16-Bit Boot for Big-Endian System

Booting from 16-bit ROM or Flash in a system that is intended to run the Au1 core in big-endian mode is very straightfor-

ward, but does need one extra, important step.

Generally speaking, the boot code and/or the application is compiled for big-endian. The boot code must set the

mem_stcfg[BE] bit before it can properly fetch/reference the big-endian image. The resulting boot code and/or application

image is placed in the ROM/Flash memory in the big-endian format.

In this situation, there is the dilemma that, out of reset, the Static Bus controller defaults to little-endian ordering, but the

application image itself is in big-endian format. The solution is to place the following code at the reset exception vector

(KSEG1 address 0xBFC00000, physical address 0x1FC00000):

.long 0xb4003c08 # lui t0,0xb400

.long 0x10003508 # ori t0,t0,0x1000

.long 0x00008d09 # lw t1,0(t0)

.long 0x02003529 # ori t1,t1,0x200

.long 0x0000ad09 # sw t1,0(t0)

.long 0x00000000 # nop

The code does a read-modify-write of register mem_stcfg0 to set the BE bit. The values in the .long statements above are

the halfword-swapped opcodes of the instructions in the comments to the right. With this technique, these first few instruc-

tions are actually in the little-endian format to match the static bus controller out of reset, and set mem_stcfg[BE] which in

turns allows the remainder of the big-endian memory contents to be accessed properly. The NOPs are necessary to ensure

that the Au1 core pipeline does not contain incorrectly [halfword swapped] prefetched instructions. Note too that the NOP

opcode 0x00000000 is the same instruction regardless of endian ordering.

Note: The boot code should set mem_stcfg0[BE] as early as possible, preferably as the first activity. It is especially

important to ensure that no cachable accesses take place to the 16-bit device, else the cache will contain the half-

word swapped contents of the 16-bit memory.

8.3.2 System Boot

For system debug, the processor can be configured to boot from the EJTAG probe through the EJTAG port; see Section 9.0

"EJTAG" on page 199 for more information.

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9.0EJTAG

The Au1000 processor implements EJTAG following the MIPS’ EJTAG 2.5 Specification. This section presents the EJTAG

implementation on the Au1000 processor while concentrating on those features from the EJTAG 2.5 specification which are

implementation specific. In addition, those features which have not been implemented or any differences in the Au1000 pro-

cessor implementation of EJTAG from the rev 2.5 specification are also noted.

It is assumed that the EJTAG 2.5 specification will be referenced for implementation details not covered here. If a particular

bit is not implemented it can be assumed that the functionality associated with the bit is not implemented or not applicable

unless otherwise noted.

The following features comprise the EJTAG implementation on the Au1000 processor:

•Extended instructions SDBBP and DERET

•Debug exceptions

•Extended CP0 registers DEBUG, DEPC and DESAVE

•EJTAG memory range 0xFF200000 - 0xFF3FFFFF

•Instruction/data breakpoints through the watch exception (specific to Au1000)

•Processor bus breakpoints (from EJTAG 2.0)

•Memory overlay (from EJTAG 2.0)

•EJTAG tap per IEEE1149.1

Note: The optional data and instruction breakpoint features from the EJTAG 2.5 specification are not implemented.

9.1 EJTAG Instructions

Both SDBBP and DERET are supported by the Au1000 processor:

•SDBBP causes a Debug Breakpoint exception.

•DERET is used to return from a Debug Exception.

9.2 Debug Exceptions

The following exceptions will cause entry into debug mode.

•DSS - debug single step

•DINT - debug interrupt, processor bus break

•DBp - execution of SDBBP instruction

•DWATCH - debug watch exception. Au1000 processor-specific implementation allowing CPU watch exception to cause

debug exception. See description of the “EJWatch Register (TAP Instruction EJWATCH)” on page 213 register.

Note that other normal exceptions, when taken in debug mode, are handled by the debug exception handler.

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9.3 Coprocessor 0 Registers

The Coprocessor 0 Registers for EJTAG are shown in Table 9-1.

9.3.1 Debug Register (CP0 Register 23, Select 0)

The Debug register contains the cause of the most recent debug exception and exception in Debug Mode. It also controls

single stepping. Only the DM bit and the EJTAGver field are valid when read from the Debug register in Non-Debug Mode;

the value of all other bits and fields is UNPREDICTABLE.

The following bits and fields are updated only on debug exceptions and/or exceptions in Debug Mode:

•DSS, DBp, DINT are updated on both debug exceptions and on exceptions in Debug Modes.

•DExcCode is updated on normal exceptions in Debug Mode, and is undefined after a debug exception.

•DBD is updated on both debug and on normal exceptions in Debug Modes.

Table 9-1. Coprocessor 0 registers for EJTAG

Number Select Name Description

23 0 debug Debug indications and controls for the processor

24 0 depc Program Counter at last debug exception or exception in debug mode

31 0 desave Debug exception save register

debug CP0 Register 23, Select 0

Bit313029282726252423222120191817161514131211109876543210

DD DM ND LS CD VER DEXCOSE NS SS DI DB DS

Def.x0000000000000001xxxxx0000x000xx

Bits Name Description R/W Default

31 DD DBD. Indicates whether the last debug exception or exception in Debug

Mode occurred in a branch or jump delay slot.

0 Not in delay slot.

1 In delay slot.

R UNPRED

30 DM Indicates that the processor is operating in Debug Mode.

0 Processor is operating in Non-Debug Mode.

1 Processor is operating in Debug Mode.

29 ND NoDCR.

0 DSEG is present.

1 DSEG is not present.

28 LS LSNM. Controls access of loads/stores between dseg and remaining

memory when dseg is present and while in debug mode.

0 Loads/stores in dseg address range go to dseg.

1 Loads/stores in dseg address range go to system memory.

R/W 0

27 — Reserved. Should be cleared. This bit is called Doze in the EJTAG 2.5

specification and is not implemented.

26 — Reserved. Should be cleared. This bit is called Halt in the EJTAG 2.5

specification and is not implemented.

25 CD CountDM. This bit is 0, indicating that the counter will be stopped in debug

mode.

24 — Reserved. Should be cleared. This bit is called IBusEP in the EJTAG 2.5

specification and is not implemented.

23 — Reserved. Should be cleared. This bit is called MCheckP in the EJTAG 2.5

specification and is not implemented.

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22 — Reserved. Should be cleared. This bit is called CacheEP in the EJTAG 2.5

specification and is not implemented.

21 — Reserved. Should be cleared. This bit is called DBusEP in the EJTAG 2.5

specification and is not implemented.

20 — Reserved. Should be cleared. This bit is called IEXI in the EJTAG 2.5

specification and is not implemented.

19 — Reserved. Should be cleared. This bit is called DDBSImpr in the EJTAG

2.5 specification and is not implemented.

18 — Reserved. Should be cleared. This bit is called DDBLImpr in the EJTAG

2.5 specification and is not implemented.

17:15 VER EJTAGver.

1 EJTAG Version 2.5

14:10 DEXCODE DExcCode. Indicates the cause of the latest exception in Debug Mode.

The field is encoded as the ExcCode field in the Cause register for those

exceptions that can occur in Debug Mode (the encoding is shown in the

MIPS32 specification), with addition of code 30 with the mnemonic

CacheErr for cache errors.

This value is undefined after a debug exception.

R UNPRED

9 NS NoSSt.

0 Single step is implemented.

1 Single step is not implemented.

8 SS SSt. Controls whether single-step feature is enabled:

0 No enable of single-step feature

1 Single-step feature enabled

R/W 0

7:6 — Reserved. Should be cleared. R 0

5 DI DINT. Indicates that a Debug Interrupt exception occurred. This could be

either a Processor Bus Break (indicated by BS0 in the Processor Bus

Break Status Register) or EJTAG break. The BS0 bit should be checked to

see what caused the exception.

Cleared on exception in Debug Mode.

0 No Debug Interrupt exception

1 Debug Interrupt exception

R UNPRED

4 — Reserved. Should be cleared. This bit is called DIB in the EJTAG 2.5 spec-

ification and is not implemented.

3 — Reserved. Should be cleared. This bit is called DDBS in the EJTAG 2.5

specification and is not implemented.

2 — Reserved. Should be cleared. This bit is called DDBL in the EJTAG 2.5

specification and is not implemented.

1 DB DBp. Indicates that a Debug Breakpoint exception occurred. Cleared on

exception in Debug Mode.

0 No Debug Breakpoint exception.

1 Debug Breakpoint exception.

R UNPRED

0 DS DSS. Indicates that a Debug Single Step exception occurred. Cleared on

exception in Debug Mode.

0 No debug single-step exception.

1 Debug single-step exception.

R UNPRED

Bits Name Description R/W Default

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9.3.2 Debug Exception Program Counter Register

The Debug Exception Program Counter (DEPC) register is a read/write register that contains the address at which process-

ing resumes after the exception has been serviced.

Hardware updates this register on debug exceptions and exceptions in Debug Mode.

For precise debug exceptions and precise exceptions in Debug Mode, the DEPC register contains either:

•the virtual address of the instruction that was the direct cause of the exception; or

•the virtual address of the immediately preceding branch or jump instruction, when the exception-causing instruction is in

a branch delay slot, and the Debug Branch Delay (BDB) bit in the Debug register is set.

For imprecise debug exceptions and imprecise exceptions in Debug Mode, the DEPC register contains the address at

which execution is resumed when returning to Non-Debug Mode.

9.3.3 Debug Exception Save Register - DESAVE

The Debug Exception Save (DESAVE) register is a read/write register that functions as a simple scratchpad register.

The debug exception handler uses this to save one of the GPRs, which is then used to save the rest of the context to a pre-

determined memory area, for example, in the dmseg. This register allows the safe debugging of exception handlers and

other types of code where the existence of a valid stack for context saving cannot be assumed.

9.4 EJTAG Memory Range

In debug mode accesses to virtual 0xFF200000 to 0xFF3FFFFF bypass translation.

The debug memory is split into two logical divisions:

•dmseg: 0xFF200000 to 0xFF2FFFFF

•drseg: 0xFF30000 to 0xFF3FFFFF

Note that the physical address ADDR[35:32] of this range is zero.

Dmseg is the memory range that will be serviced by the probe TAP in debug mode for all instruction accesses to this virtual

address range and for data accesses if the LSNM in the Debug Register is 0.

Drseg is the memory range containing the EJTAG memory mapped registers and is accessible when LSNM in the Debug

depc - Debug Exception Program Counter CP0 Register 24, Select 0

Bit313029282726252423222120191817161514131211109876543210

DEPC[31:0]

Def.00000000000000000000000000000000

Bits Name Description R/W Default

31:0 DEPC Debug Exception Program Counter. R/W UNPRED

desave - Debug Exception Save Register CP0 Register 31, Select 0

Bit313029282726252423222120191817161514131211109876543210

DESAVE[31:0]

Def.xxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxx

Bits Name Description R/W Default

31:0 DESAVE Debug Exception Save contents. R/W UNPRED

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9.4.1 EJTAG Memory Mapped Registers

Table 9-2 shows the EJTAG memory mapped registers located in drseg.

The EJTAG implementation in the Au1000 processor does not employ data breakpoints and instruction breakpoints as

described in the EJTAG 2.5 specification. Instead it offers Processor breakpoints as described in the EJTAG 2.0.0 specifica-

tion.

The Processor Bus Match registers monitor the bus interface of the MIPS CPU and provide debug exception or trace trigger

for a given physical address and data.

In addition, the implementation allows the CPU watchpoints to cause a debug exception. This functionality is enabled

through the EJTAG TAP port. Please see “EJWatch Register (TAP Instruction EJWATCH)” on page 213 for details.

9.4.1.1 Debug Control Register

The Debug Control Register (DCR) controls and provides information about debug issues. The width of the register is 32

bits. The DCR is located in the drseg at offset 0x0000.

Table 9-2. EJTAG Memory Mapped Registers at 0xFF300000

Offset Register Description

0x0000 dcr Debug Control Register

0x000C pbs Processor Break Status

0x0300 pab Processor Address Bus Break

0x0304 pdb Processor Data Break

0x0308 pdm Processor Data Mask

0x030C pbcam Processor Control/Address Mask

0x0310 phab Processor High Address Break

0x0314 pham Processor High Address Mask

dcr - Debug Control Register Offset = 0x0000

Bit313029282726252423222120191817161514131211109876543210

EN DB IB IE NE NP SR PE

Def.00100000000000000000000000011010

Bits Name Description R/W Default

31:30 — Reserved. Should be cleared. R 0

29 EN ENM.

1 Processor is big Endian in both debug and kernel mode.

28:18 — Reserved. Should be cleared. R 0

17 DB DataBrk.

0 No data hardware breakpoints implemented.

16 IB InstBrk.

0 No instruction hardware breakpoints implemented.

15:5 — Reserved. Should be cleared. R 0

4IE IntE.

1 Interrupt enabled in debug mode depending on other enabling mech-

anisms.

3NE NMIE.

1 Non-Maskable Interrupt is enable for non-debug mode.

The NMI is not implemented in the Au1000 so this bit has no applicability.

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9.4.1.2 Processor Bus Break Status Register

9.4.1.3 Processor Address Bus Break

This register contains the bits of the physical Processor Address Bus Break.

2 NP NMIPend.

0 No NMI pending

The NMI is not implemented in the Au1000 so this bit has no applicability.

1SR SRstE.

1 Soft reset is fully enabled.

Soft Reset is not implemented in the Au1000 so this bit has no applicabil-

ity.

0 PE ProbEn. Indicates value of the ProbEn value in the ECR register.

0 No access should occur to dmseg

1 Probe services accesses to dmseg

R Same value

as ProbEN

in ECR

pbs - Processor Bus Break Status Offset = 0x000C

Bit313029282726252423222120191817161514131211109876543210

OLP BCN BS

Def.01000001000000000000000000000000

Bits Name Description R/W Default

31 — Reserved. Should be cleared. R 0

30 OLP 1 Memory overlay functionality is implemented for processor breaks. R 1

29:28 — Reserved. Should be cleared. R 0

27:24 BCN Number of Processor Breaks.

1 One Channel has been implemented for the Processor Bus Break.

23:15 — Reserved. Should be cleared. R 0

14:1 — Reserved. Should be cleared. These bits are the Bsn bits in the EJTAG

2.0.0 specification and are not needed since only one break is imple-

mented.

0 BS Break Status. This bit, when set, indicates that a processor bus break or

processor bus trigger has occurred. BS can be cleared by activating PrRst

(EJTAG CONTROL Register), hard reset and also by writing a ‘0’ to it.

The Debug handler must clear this bit before returning from debug mode.

R/W 0

pab - Processor Address Bus Break Offset = 0x0300

Bit313029282726252423222120191817161514131211109876543210

PAB[31:0]

Def.xxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxx

Bits Name Description R/W Default

31:0 PAB Processor Address Bus Break 0. This index contains the lower 32 bits of

the physical address. In combination with the high order address bits,

these bits make up the break address.

R UNPRED

Bits Name Description R/W Default

AMD Alchemy™ Au1000™ Processor Data Book 205

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9.4.1.4 Processor Data Bus Break

This register specifies the data value for the Processor Data Bus match.

9.4.1.5 Processor Data Mask/Upper Overlay Address Mask

This register is dual purpose depending on the value of the Overlay Enable bit in the Bus Break Control and Address Mask.

This register specifies the mask value for the Processor Data Mask register. Each bit corresponds to a bit in the data regis-

ter.

9.4.1.6 Processor Bus Break Control and Address Mask

This register selects the Processor Bus match function to enable debug break or trace trigger. It also includes control bits to

enable comparison as well as mask bits to exclude address bits from comparison.

Note that all processor break exceptions are imprecise.

pdb - Processor Data Bus Break Offset = 0x0304

Bit313029282726252423222120191817161514131211109876543210

PDB[31:0]

Def.xxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxx

Bits Name Description R/W Default

31:0 PDB Processor Data Bus Break 0. This index contains the 32 bits of the data

bus match.

R UNPRED

pdm_uoam - Processor Data Mask Offset = 0x0308

Bit313029282726252423222120191817161514131211109876543210

PDM[31:0]

Def.xxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxx

Bits Name Description R/W Default

31:0 PDM Processor Data Mask 0. When OE in the pbcam register is not enabled.

0 Data bit is not masked, data bit is compared.

1 Data bit is masked, data bit is not compared.

Note: Applies only when OE not enabled.

R UNPRED

31:24 UOAM Upper Overlay Address Mask. These bits represent bits 31:24 of the

address mask and are combined with the LAM and HAM fields to create a

complete 36 bit address mask.

0 Address bit is not masked, address bit is compared.

1 Address bit is masked, address bit is not compared.

Bits 23:0 are not used when OE is set and should be written 0.

Note: Applies only when OE is enabled.

R/W UNPRED

pbcam - Bus Break Control and Address Mask Offset = 0x030C

Bit313029282726252423222120191817161514131211109876543210

LAM[31:8] DC DU DIU OE BE

Def.xxxxxxxxxxxxxxxxxxxxxxxxxxxx0000

Bits Name Description R/W Default

31:8 LAM Address Mask. These bits specify the mask value for the 24 lower bits of

the Processor Address register (PBA0[23..0]). Each bit corresponds to the

same bit in PBA0.

0 Address bit is not masked, address bit is compared.

1 Address bit is masked, address bit is not compared.

R/W UNPRED

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7 DC Data Store to Cached Area. This bit enables the comparison on Processor

Address and Data Bus for Data Store to the Cached area.

0 Processor Address and Data is not compared for storing data to the

Cached area.

1 Processor Address and Data is compared for storing data to the

Cached area.

R/W UNPRED

6 DU Data Store To Uncached Area. This bit enables the comparison on Pro-

cessor Address and Data Bus for Data Store to the uncached area.

0 Processor Address and Data is not compared for storing data into the

un-cached area.

1 Processor Address and Data is compared for storing data into the un-

cached area.

R/W UNPRED

5:4 DIU Data or Instruction fetch or load from Uncached Area. These bits enable

the comparison on Processor Address and Data Bus for Data or Instruc-

tion load and fetch from the un-cached area.

00 Processor Address and Data is not compared for loading data or

fetching instruction from the un-cached area.

11 Processor Address and Data is compared for loading data or fetching

instruction from the un-cached area.

Bits 5 and 4 were named ILUC and DFUC in the EJTAG 2.0.0 specification

and were implemented separately for instruction and data fetches.

R UNPRED

3 OE Overlay Enable. When this bit is 1 and the processor physical address,

masked by the HAM, UOAM and the LAM fields (all 36 bits of the address

mask), matches the PHAB and PAB registers, then the memory request is

redirected to the EJTAG Probe.

The processor bus break can not be used for normal break, function if the

OLE bit is set, so BE must be set to 0. The behavior is otherwise unde-

fined.

Overlay is only valid for memory regions. It is not valid for I/O or debug

space and the behavior is unpredictable if addresses within this space are

used.

R/W 0

2 — Reserved. Should be cleared. This bit is called TE in the EJTAG 2.0.0

specification and is not implemented.

1 — Reserved. Should be cleared. This bit is called CBE in the EJTAG 2.0.0

specification and is not implemented.

0 BE Break Enable. This bit enables the Processor Bus break function.

0 Processor Bus break function is disabled.

1 Processor Bus break function is enabled.

If Break Enable is set and the processor physical address, masked by the

HAM and the LAM fields (UOAM is only for overlay so bits 31:24 are not

masked here), matches the PHAB and PAB registers, and the processor

data bus matches the PDB register (masked by PDM), then a debug

exception to the processor is generated.

The BS bit in the Processor Bus Break Status register is set and the DINT

bit in the Debug Register is set. If the debug exception handler is already

running (DM=‘1’), then the debug exception will not be taken until DM = 0.

This functionality is mutually exclusive to OLE so only one of OLE or BE

should be set at any time.

R/W 0

Bits Name Description R/W Default

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9.4.1.7 Processor High Address Bus Break

This register specifies the high order address for the processor address bus break.

9.4.1.8 Processor High Address Mask

This register specifies the high order address mask for the processor address bus break.

pha - Processor High Address Bus Break Offset = 0x0310

Bit313029282726252423222120191817161514131211109876543210

HA[3:0]

Def.0000000000000000000000000000XXXX

Bits Name Description R/W Default

31:4 — Reserved. Should be cleared. R 0

3:0 HA These bits map to the high physical address bits 35:31. R/W UNPRED

pham - Processor High Address Mask Offset = 0x0314

Bit313029282726252423222120191817161514131211109876543210

HAM[3:0]

Def.0000000000000000000000000000XXXX

Bits Name Description R/W Default

31:4 — Reserved. Should be cleared. R 0

3:0 HAM High Address Mask for address bits 35:31.

0 Data bit is not masked, data bit is compared

1 Data bit is masked, data bit is not compared

R/W UNPRED

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9.4.2 EJTAG Test Access Port (TAP)

The EJTAG TAP contains the 5 TAP pins and a 16 state controller with a 5 bit instruction register.

Table 9-3 shows the 5-bit instructions supported by the Au1000.

9.4.2.1 Device Identification (ID) Register

The Device ID register is a 32-bit read-only register that identifies the specific device implementing EJTAG.

Table 9-3. EJTAG Instruction Register Values

Hex Value Instruction Function

0x00 EXTEST Boundary Scan.

0x01 IDCODE Selects ID register.

0x02 SAMPLE Boundary Scan Sample/Preload (IEEE JTAG Instruction).

0x03 IMPCODE Selects Implementation register.

0x04 — Reserved.

0x05 — This reserved register is for test mode HIZ - TRI-STATE all output pins

and Select Bypass register.

0x06 — This reserved register is for test mode CLAMP - IEEE Clamp pins and

select bypass register.

0x07 — Reserved.

0x08 ADDRESS Selects Address register.

0x09 DATA Selects Data register.

0x0A CONTROL Selects EJTAG Control register.

0x0B ALL Selects the Address, Data and EJTAG Control registers.

0x0C EJTAGBOOT Makes the processor take a debug exception after reset.

0x0D NORMALBOOT Makes the processor execute the reset handler after reset.

0x0E-0x1B — Reserved.

0x1C EJWATCH Selects Watch register.

0x1D-0x1E — Reserved.

0x1F BYPASS Bypass mode.

IDCODE - Device Identification TAP Instruction IDCODE

Bit313029282726252423222120191817161514131211109876543210

VER PNUM MANID

Def.00000000001111101000001010001111

Bits Name Description R/W Default

31:28 VER Identifies the version of the device. R 0

27:12 PNUM Identifies the part number of the device. R 0x03E8

11:1 MANID Identifies the manufacturer ID code for the device. MANID[6:0] are derived

from the last byte of the JEDEC code with the parity bit discarded.

MANID[10:7] provides a binary count of the number of bytes in the JEDEC

code that contain the continuation character (0x7F). When the number of

continuations characters exceeds 15, these four bits contain the modulo-

16 count.

R0x147

0 — Reserved. Should be written a 1. R 1

AMD Alchemy™ Au1000™ Processor Data Book 209

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9.4.2.2 Implementation Register

The Implementation register is a 32-bit read-only register that identifies features implemented in this EJTAG compliant pro-

cessor, mainly those accessible from the TAP.

9.4.2.3 Data Register

The read/write Data register is used for opcode and data transfers during processor accesses. The width of the Data regis-

ter is 32 bits.

The value read in the Data register is valid only if a processor access for a write is pending, in which case the data register

holds the store value. The value written to the Data register is only used if a processor access for a pending read is finished

afterwards, in which case the data value written is the value for the fetch or load. This behavior implies that the Data register

is not a memory location where a previously written value can be read afterwards.

IMPCODE - Implementation TAP Instruction IMPCODE

Bit313029282726252423222120191817161514131211109876543210

VER R3 DI AS M16 ND M32

Def.00100000010000000100000000000000

Bits Name Description R/W Default

31:29 EJTAGver 1 EJTAG version 2.5 R 1

28 R3 0 R3k privileged environment. R 0

27:25 — Reserved. Should be cleared. R 0

24 DI 0 DINT signal from the probe is not supported. R 0

23 — Reserved. Should be cleared. R 0

22:21 AS 10 8-bit ASID. R 10

20:17 — Reserved. Should be cleared. R 0

16 M16 0 No MIPS16 support. R 0

15 — Reserved. Should be cleared. R 0

14 ND 1 No EJTAG DMA support R 1

13:1 — Reserved. Should be cleared. R 0

0 MIPS32/64 0 32-bit processor. R 0

DATA TAP Instruction DATA or ALL

Bit313029282726252423222120191817161514131211109876543210

DATA[31:0]

Def.XXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXX

Bits Name Description R/W Default

31:0 DATA Data used by processor access. R/W UNPRED

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9.4.2.4 Address Register

The read-only Address register provides the address for a processor access. The width of the register is 36 bits.

The value read in the register is valid if a processor access is pending, otherwise the value is undefined. The two LSBs of

the register are used with the Psz field from the EJTAG Control register to indicate the size and data position of the pending

processor access transfer. These bits are not taken directly from the address referenced by the load/store (i.e. these bits

are encoded with Psz).

9.4.2.5 EJTAG Control Register (ECR)

The 32-bit EJTAG Control Register (ECR) handles processor reset, Debug Mode indication, access start, finish, and size

and read/write indication. The ECR also:

•Controls debug vector location and indication of serviced processor accesses.

•Allows debug interrupt request.

•Indicates processor low-power mode.

The EJTAG Control register is not updated/written in the Update-DR state unless the Reset occurred; that is RO (bit 31) is

either already 0 or is written to 0 at the same time. This condition ensures proper handling of processor accesses after a

reset.

Bits that are R/W in the register return their written value on a subsequent read, unless other behavior is defined. Internal

synchronization hardware thus ensures that a written value is updated for reading immediately afterwards, even when the

TAP controller takes the shortest path from the Update-DR to Capture-DR state.

Note: To ensure a write is successful to the PE, PT and EB bits when the processor is undergoing a clock change (for

PLL lock/relock), the host must continue writing these bits until the write is verified by reading the change. Failure

to do this could result in the write of these bits being lost.

Reset of the processor can be indicated in the TCK domain a number of TCK cycles after it is removed in the processor

clock domain in order to allow for proper synchronization between the two clock domains.

ADDRESS TAP Instruction ADDRESS or ALL

Bit3534333231302928272625242322212019181716151413121110 9 8 7 6 5 4 3 2 1 0

ADDRESS[36:0]

Def.XXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXX

Bits Name Description R/W Default

35:0 Address Address used by processor access R UNPRED

ECR - EJTAG Control Register TAP Instruction CONTROL or ALL

Bit313029282726252423222120191817161514131211109876543210

RO PSZ DZ PRW PA PR PE PT EB DM

Def.1xx000000000x0000000000000000000

Bits Name Description R/W Default

31 RO Indicates if a processor reset has occurred since the bit was cleared:

0 No reset occurred.

1 Reset occurred.

The RO bit stays set as long as reset is applied.

This bit must be cleared to acknowledge that the reset was detected. The

EJTAG Control register is not updated in the Update-DR state unless RO

is 0 or written to 0 at the same time. This is in order to ensure correct han-

dling of the processor access after reset.

R/W0 1

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30:29 PSZ Indicates the size of a pending processor access, in combination with the

Address register.

00 Byte

01 Halfword

10 Word

11 Triple

This field is valid only when a processor access is pending; otherwise, the

read value is undefined.

R UNPRED

28:23 — Reserved. Should be cleared. R 0

22 DZ Doze. Indicates if the processor is in a WAIT state:

0 Processor is not in a wait state.

1 Processor is in a wait state.

21 — Reserved. Should be cleared. This bit is called Halt in the EJTAG 2.0.0

specification and is not implemented.

20 — Reserved. Should be cleared. This bit is called PerRst in the EJTAG 2.0.0

specification and is not implemented.

19 PRW Indicates read or write of a pending processor access.

0 Read processor access, for a fetch/load access.

1 Write processor access, for a store access.

This value is defined only when a processor access is pending.

R UNPRED

18 PA Indicates a pending processor access and controls finishing of a pending

processor access. When read:

0 No pending processor access.

1 Pending processor access.

A write of 0 finishes a processor access if pending; otherwise operation of

the processor is UNDEFINED if the bit is written to 0 when no processor

access is pending. A write of 1 is ignored.

R/W0 0

17 — Reserved. Should be cleared. R 0

16 PR Controls the processor reset.

0 No processor reset applied.

1 Processor reset applied.

Setting this bit to 1 will apply a processor reset. When this bit is read back

it will always read a 0. Note that startup latencies should be observed

when applying reset.

R/W 0

15 PE Controls indication to the processor of whether the probe expects to han-

dle accesses to EJTAG memory through servicing of processor accesses.

0 Probe does not service processor accesses.

1 Probe will service processor accesses.

The ProbEn bit is reflected as a read-only bit in the Debug Control Regis-

ter (DCR) bit 0.

When a read from this bit shows a change, the new value has taken effect

in the DCR. This handshake mechanism ensures that the setting from the

TCK clock domain takes effect in the processor clock domain.

However, a change of the ProbEn prior to setting the EjtagBrk bit is

ensured to affect execution of the debug handler due to the debug excep-

tion.

Not all combinations of ProbEn and ProbTrap are allowed.

Please see the previous note about writing this bit (in “EJTAG Control Reg-

ister (ECR)” on page 210).

R/W Determined

by EJTAG-

BOOT

Bits Name Description R/W Default

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14 PT Controls location of the debug exception vector:

0 Normal memory 0xBFC00480

1 EJTAG memory 0xFF200200

When a read from this bit shows a change, the new value has taken effect

in the DCR. This handshake mechanism ensures that the setting from the

TCK clock domain takes effect in the processor clock domain.

However, a change of the ProbTrap prior to setting the EjtagBrk bit is

ensured to affect execution of the debug handler due to the debug excep-

tion.

Not all combinations of ProbEn and ProbTrap are allowed.

Please see the previous note about writing this bit (in “EJTAG Control Reg-

ister (ECR)” on page 210).

R/W Determined

by EJTAG-

BOOT

13 — Reserved. Should be cleared. R 0

12 EB Requests a debug interrupt exception to the processor when this bit is writ-

ten as 1. This bit is cleared by hardware when the processor enters debug

mode. If software then sets EB while the processor is already in debug, the

request is not ignored but is delayed. That is, once the processor returns

to normal mode, the pending debug exception request immediately sends

the processor back into debug.

A write of 0 is ignored. The debug request restarts the processor clock if

the processor was in a wait mode, which stopped the processor clock. The

read value indicates a pending Debug Interrupt exception requested

through this bit:

0 No pending Debug Interrupt exception requested through this bit

1 Pending Debug Interrupt exception

The read value can, but is not required to, indicate other pending DINT

debug requests (for example, through the DINT signal).

Please see the previous note about writing this bit (in “EJTAG Control Reg-

ister (ECR)” on page 210).

R/W1 Determined

by EJTAG-

BOOT

11:4 — Reserved. Should be cleared R 0

3 DM Indicates if the processor is in Debug Mode:

0 Processor is in Non-Debug Mode.

1 Processor is in Debug Mode.

2:0 — Reserved. Should be cleared. R 0

Bits Name Description R/W Default

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9.4.2.6 EJWatch Register (TAP Instruction EJWATCH)

The EJWatch register is used to enable CPU watchpoints to cause a debug exception. This functionality is unique to the

Au1000.

9.4.2.7 Bypass Register (TAP Instruction BYPASS)

The Bypass register is a one-bit read-only register, which provides a minimum shift path through the TAP. This register is

also defined in IEEE 1149.1.

EJWATCH TAP Instruction EJWATCH

Bit76543210

WATCH

Def.00000000

Bits Name Description R/W Default

7:3 — Reserved. Should be cleared. R 0

2 — Reserved. Should be cleared. This bit is the Global Scan test bit. R 0

1 — Reserved. Should be cleared. This bit is a Test Mode bit. R 0

0 WATCH This bit controls the debug functionality of the CPU watch register.

0 Normal Watch Exception Mode.

1 Debug Watch Exception Mode.

Blocks writes to Watch register in non-debug mode

Watch Exception will become debug exceptions with DEXCODE=23

The PC will be saved in the DEPC (not in the EPC as with a normal watch

exception).

Note that the Status, Cause, and EPC will not be affected by a debug

watch exception when this bit is enabled.

R/W 0

BYPASS TAP Instruction BYPASS

Bit 0

Def. 0

Bits Name Description R/W Default

0 BP Ignored on writes; returns zeros on reads. R 0

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9.4.3 EJTAG TAP Hardware Considerations

The EJTAG interface consists of the signals listed in Table 9-4.

Note that the EJTAG TAP signal TCK must always be less than 1/4 the System Bus (SBUS) clock speed for proper opera-

tion. In addition, termination as shown in EJTAG 2.5 spec must be followed.

Table 9-4. EJTAG Signals

Signal Input/Output Definition

TRST# I Asynchronous TAP reset

TDI I Test data input to the instruction or selected data registers. This signal will be sam-

pled on the rising edge of TCK

TDO O Test data output from the instruction or data register. This signal will transition on

the falling edge (valid on rising edge) of TCK

TMS I Control signal for TAP controller. This signal is sampled on the wising edge of TCK.

TCK I Control clock for updating TAP controller and shifting data through instruction or

selected data register.

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10.0Signal Descriptions

This section describes the external signals on the Au1000 processor.

In order to maximize the functionality of the Au1000 processor, many of the pins have multiple uses. Note that if a pin is

configured for one use, any other functionality associated with that pin can not be utilized at the same time. In other words

a pin can not be used as a general-purpose I/O signal at the same time it is assigned to a peripheral device. (See Section

7.3.1 "Pin Functionality" on page 183.)

Figure 10-1 shows the external signals of the Au1000 processor. All signals are grouped according to their functional block.

Signals that share a pin are listed with the multiplexed signal name in parentheses—the signal name shown in bold is the

default.

Note: :A signal with an “#” is active-low; that is, the signal is considered asserted (active) when low and negated when

high. Active-high signals (no #) are considered asserted when high and negated when low.

216 AMD Alchemy™ Au1000™ Processor Data Book

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Figure 10-1. Au1000™ Processor External Signals

Table 10-3 gives a description of all external signals on the Au1000 processor. The signals have been grouped by functional

block. Signals that require external termination are noted in the description. Table 10-3 also defines the default state of the

signals during a hardware reset, a runtime reset, and Sleep. The abbreviations used for the signal types and the signal

states are defined in Table 10-1 and Table 10-2.

SDA[12:0]

Static

Bus

Controller

SDBA[1:0]

SDD[31:0]

SDQM[3:0]#

SDRAS#

SDCAS#

SDWE#

SDCLK[2:0]

SDCS[2:0]#

SDCKE

RAD[31:0]

RD[31:0]

RBEN[3:0]#

RWE#

ROE#

RCS[3:0]#

EWAIT#

PCE[2:1]#

POE#

PWE#

PIOR#

PIOW#

PWAIT#

PREG#

PIOS16#

LCLK

LWAIT#

LRD[1:0]#

LWR[1:0]#

USBH1P

USBH1M

USBDP

(USBH0P)

USBDM

(USBH0M)

S0CLK

(GPIO[17])

S0DIN

S0DOUT

(GPIO[16])

S0DEN

(GPIO[18])

S1CLK (

ACDO

)

S1DIN (

ACBCLK

)

S1DOUT (

ACSYNC

)

S1DEN (

ACRST#

)

IRDATX

(GPIO[19])

IRFIRSEL (

GPIO[15]

)

U1TXD

(GPIO[21])

U1RXD

U2TXD

(GPIO[22])

U2RXD

U3TXD

(GPIO[23])

U3RXD

U3CTS (

GPIO[9]

)

U3DSR (

GPIO[10]

)

U3DCD (

GPIO[11]

)

U3RI (

GPIO[12]

)

U3RTS (

GPIO[13]

)

U3DTR (

GPIO[14]

)

N0TXCLK

N0TXEN

N0TXD[3:0]

N0RXCLK

N0RXDV

N0RXD[3:0]

N0CRS

N0COL

N0MDC

N0MDIO

N1TXCLK

N1TXEN

(GPIO[24])

N1TXD[3:0]

(GPIO[28:25])

N1RXCLK

N1RXDV

N1RXD[3:0]

N1CRS

N1COL

N1MDC

N1MDIO

ACSYNC

(S1DOUT)

ACBCLK

(S1DIN)

ACDO

(S1CLK)

ACDI

ACRST#

(S1DEN)

TRST#

TDI

TDO

TMS

TCK

GPIO[31:0]

TESTEN

XTI12

XTO12

XTI32

XTO32

RESETIN#

RESETOUT#

PWR_EN

VDDXOK

DDI

[12:0], V

DDX

[25:0], V

[35:0]

TC[3:0]

UART0

UART1

UART2

U0TXD

(GPIO[20])

U0RXD

UART3

MAC0

MAC1

GPIO

Power

Mgmt.

Test &

Debug

Power

Clocks

& Reset

USB Host

USB Device

SSI0

SSI1

IrDA

AC97

PCMCIA

Link

MII

EJTAG

LCD

XPWR12, XAGND12

XPWR32,

XAGND32

ROMSEL

ROMSIZE

I2SCLK

(GPIO[30])

I2SWORD

(GPIO[31])

I2SDI (

GPIO[8]

)

I2SDIO

(GPIO[29])

I2S

SMROMCKE (

GPIO[6]

)

MII

IRDARX

EXTCLK[1:0] (

GPIO[3:2]

)

USBH0P (

USBDP

)

USBH0M (

USBDM

)

DMA_REQ0 (

GPIO[4]

)

DMA_REQ1 (

GPIO[5]

)

DMA DMA

REQs

SDRAM

Controller

Au1000™

Processor

AMD Alchemy™ Au1000™ Processor Data Book 217

Signal Descriptions 30360E

Note for Table 10-3 that the signal states shown in the far-right column are valid during Sleep. When waking from Sleep, the

processor performs an internal system reset that produces the same signal behavior as a runtime reset with two excep-

tions:

•SDRAM interface behavior. During and after a runtime reset the SDRAM configuration mode registers retain their values

to allow a transaction in progress to complete; the remaining SDRAM configuration registers revert to their default

values. Waking from Sleep, however, all SDRAM configuration registers revert to their default values, and the interface

behaves the same as when coming out of a hardware reset.

•PWR_EN behavior. During a runtime reset PWR_EN remains asserted. During Sleep, PWR_EN is negated. Waking

from Sleep, PWR_EN is asserted according to the timing specified in Section 7.4.3.1 "Sleep Sequence and Timing" on

page 191.

Table 10-1. Signal Type Abbreviations for Table 10-3

Signal Type Definition

I Input. Note that all unused input pins should be terminated low or high via direct connection to either

ground or power.

O Output

IO Bidirectional

Z Tristatable

P Power

G Ground

Table 10-2. Signal State Abbreviations for Table 10-3

Signal State Definition

0 Driven low

1 Driven high

IN Signal is a input.

LV If driven, an output signal continues to be driven at the last value before a reset or entering Sleep.

HIZ TRI-STATE

ON Clock remains on if already enabled.

DEP Depends (Signal-specific explanations are provided in table footnotes.)

UN Unpredictable

NC Not connected

NA Does not apply because this signal is not the default function coming out of a hardware or runtime

reset.

218 AMD Alchemy™ Au1000™ Processor Data Book

Signal Descriptions

30360E

Table 10-3. Signal Descriptions

Signal Type Description

Reset

During

SleepHardware Run Time

SDRAM Interface

SDA[12:0] O Address Outputs. A0-A12 are sampled during the

ACTIVE command (row-address A0-A12) and READ/

WRITE command to select one location out of the

memory array in the respective bank. The address

outputs also provide the opcode during a LOAD MODE

UN UN LV

SDBA[1:0] O Bank Address Outputs. SDBA1 and SDBA0 define to

which bank the ACTIVE, READ, WRITE, or PRECHARGE

command is being applied.

UN UN LV

SDD[31:0] IO SDRAM Data Bus. During a hardware reset the

SDRAM data bus cycles from low voltage to hi-Z and

then low as follows:

1. 0 after VDDXOK is asserted.

2. TRI-STATE when VDDI is on and RESETOUT# is

asserted.

3. 0 after hardware reset sequence is complete.

(See

descrip-

tion at

left.)

HIZ LV

SDQM[3:0]# O Input/Output Mask: SDQM# is an input mask signal for

write accesses and an output enable signal for read

accesses.

SDQM0# masks SDD[7:0].

SDQM1# masks SDD[15:8].

SDQM2# masks SDD[23:16].

SDQM33 masks SDD[31:24].

11LV

SDRAS# O Command Outputs. SDRAS#, SDCAS#, and SDWE#

(along with SDCSn#) define the command being sent

to the SDRAM rank.

11LV

SDCAS# O 1 1 LV

SDWE# O 1 1 LV

SDCLK[2:0] O Clock output corresponding to each of the three chip

selects. Clock speed is 1/2 SBUS frequency when

corresponding SDCSn# is set to SDRAM, 1/4 SBUS

frequency when corresponding SDCSn# is set to

SMROM.

0ONLV

SDCS[2:0]# O Programmable chip selects. 1 1 LV

SDCKE O Clock enable for SDRAM. 0 1 LV

SMROMCKE O Synchronous Mask ROM Clock Enable. Valid only

when ROMSEL=1 and ROMSIZE=0. Must be pulled

high if the system is booting from SMROM.

Muxed with GPIO[6]. If ROMSEL and ROMSIZE are

configured to boot from synchronous mask ROM, the

SMROMCKE signal is selected for the pin coming out

of reset; otherwise, GPIO[6] is selected.

11LV

AMD Alchemy™ Au1000™ Processor Data Book 219

Signal Descriptions 30360E

Static Bus (SRAM/IO/PCMCIA/Flash/ROM/LCD) Interface - Common Signals

RAD[31:0] O Address bus. UN UN LV

RD[31:0] IO Data bus 0 UN LV

RBEN[3:0]# O Byte Enable. RBEN0# corresponds to RD[7:0],

RBEN1# corresponds to RD[15:8], RBEN2# corre-

sponds to RD[23:16], RBEN3# corresponds to

RD[31:24].

11LV

RWE# O Write enable. 1 1 LV

ROE# O Output enable. 1 1 LV

RCS[3:0]# O Programmable Chip Selects. RCSn# is not used when

configured as a PCMCIA device.

11LV

EWAIT# I Can be used to stretch the bus access time when

enabled. This input is not recognized for chip selects

configured as LCD or PCMCIA because these buses

have their own wait mechanisms.

IN IN LV

PCMCIA

PREG# O Register-only access signal. 1 1 LV

PCE[2:1]# O Card Enables. 1 1 LV

POE# O Output Enable. 1 1 LV

PWE# O Write Enable. 1 1 LV

PIOR# O Read Cycle Indication. 1 1 LV

PIOW# O Write Cycle Indication 1 1 LV

PWAIT# Extend Cycle. This signal should be tied high through

a resistor when the PCMCIA interface is not used.

IN IN LV

PIOS16# 16-bit Port Select. This signal should be tied high

through a resistor when the PCMCIA interface is not

used.

IN IN LV

LCD Controller Chip Interface

LCLK O Interface Clock. 0 0 LV

LWAIT# I Extend Cycle. This signal should be tied high through

a resistor when not used.

IN IN LV

LRD[1:0]# O Read Indicators. 1 1 LV

LWR[1:0]# O Write Indicators. 1 1 LV

USB Host

USBH1P IO Positive signal of differential USB host port 1 driver.

Requires an external 15 kohm pull-down resistor and

ESD protection diode (transient voltage suppressor) to

be USB 1.1 compliant.

Termination Note: Requires an external 27 ohm series

resistor placed within 0.5 inches of the part.

IN IN LV

Table 10-3. Signal Descriptions (Continued)

Signal Type Description

Reset

During

SleepHardware Run Time

220 AMD Alchemy™ Au1000™ Processor Data Book

Signal Descriptions

30360E

USBH1M IO Negative signal of differential USB host port 1 driver.

Requires an external 15 kohm pull-down resistor and

ESD protection diode (transient voltage suppressor) to

be USB 1.1 compliant.

Termination Note: Requires an external 27 ohm series

resistor placed within 0.5 inches of the part.

IN IN LV

USBH0P IO Positive signal of differential USB host port 0 driver

Requires an external 15 kohm pull-down resistor and

ESD protection diode (transient voltage suppressor) to

be USB 1.1 compliant.

Termination Note: Requires an external 27 ohm series

resistor placed within 0.5 inches of the part.

Muxed with USBDP. USBDP is the default signal com-

ing out of hardware reset, runtime reset, and Sleep.

NA NA LV

USBH0M IO Negative signal of differential USB host port 0 driver

Requires an external 15 kohm pull-down resistor and

ESD protection diode (transient voltage suppressor) to

be USB 1.1 compliant.

Termination Note: Requires an external 27 ohm series

resistor placed within 0.5 inches of the part.

Muxed with USBDM. USBDM is the default signal

coming out of hardware reset, runtime reset, and

Sleep.

NA NA LV

USB Device

USBDP IO Positive signal of differential USB device driver.

Requires a 1.5 kohm pull-up resistor to denote a full

speed device. Also requires an external ESD protec-

tion diode (transient voltage suppressor) to be USB

1.1 compliant.

Termination Note: Requires an external 27 ohm series

resistor placed within 0.5 inches of the part.

Muxed with USBH0P. USBDP is the default signal

coming out of hardware reset, runtime reset, and

Sleep.

IN IN LV

USBDM IO Negative signal of differential USB device driver.

Requires an external ESD protection diode (transient

voltage suppressor) to be USB 1.1 compliant.

Termination Note: Requires an external 27 ohm series

resistor placed within 0.5 inches of the part.

Muxed with USBH0M. USBDM is the default signal

coming out of hardware reset, runtime reset, and

Sleep

IN IN LV

Table 10-3. Signal Descriptions (Continued)

Signal Type Description

Reset

During

SleepHardware Run Time

AMD Alchemy™ Au1000™ Processor Data Book 221

Signal Descriptions 30360E

SSI0

S0CLK O Master only clock output. The speed and polarity of

clock edge is programmable.

Muxed with GPIO[17]. S0CLK is the default signal

coming out of hardware reset, runtime reset, and

Sleep.

00LV

S0DIN I Serial Data Input. This signal may be tied to S0DOUT

to create a single bidirectional data signal.

IN IN LV

S0DOUT O Serial Data Output. This signal is in TRI-STATE during

a read and thus may be tied to S0DIN to create a sin-

gle bidirectional data signal.

Muxed with GPIO[16]. S0DOUT is the default signal

coming out of hardware reset, runtime reset, and

Sleep.

0UNLV

S0DEN O Enable signal which frames transaction. The polarity is

programmable.

Muxed with GPIO[18]. S0DEN is the default signal

coming out of hardware reset, runtime reset, and

Sleep.

0UNLV

SSI1

S1CLK O Master only clock output. The speed and polarity of

clock edge is programmable.

Muxed with ACDO. ACDO is the default signal coming

out of hardware reset, runtime reset, and Sleep.

NA NA LV

S1DIN I Serial Data Input. This signal may be tied to S1DOUT

to create a single bidirectional data signal.

Muxed with ACBCLK. ACBCLK is the default signal

coming out of hardware reset, runtime reset, and

Sleep.

NA NA LV

S1DOUT O Serial Data Output. This signal is in TRI-STATE during

a read and thus may be tied to S1DIN to create a sin-

gle bidirectional data signal.

Muxed with ACSYNC. ACSYNC is the default signal

coming out of hardware reset, runtime reset, and

Sleep.

NA NA LV

S1DEN O Enable signal which frames transaction. The polarity is

programmable.

Muxed with ACRST#. ACRST# is the default signal

coming out of hardware reset, runtime reset, and

Sleep.

NA NA LV

IrDA

IRDATX O Serial IrDA Output. Muxed with GPIO[19]. IRDATX is

the default signal coming out of hardware reset, runt-

ime reset, and Sleep

0UNLV

IRDARX I Serial IrDA input. IN IN LV

Table 10-3. Signal Descriptions (Continued)

Signal Type Description

Reset

During

SleepHardware Run Time

222 AMD Alchemy™ Au1000™ Processor Data Book

Signal Descriptions

30360E

IRFIRSEL O Output which will signal at which speed the IrDA is

currently set. This signal is not necessary for IrDA

operation. This pin will be driven high when IrDA is

configured for FIR or MIR. This pin will be driven low

for SIR mode.

Muxed with GPIO[15]. GPIO[15] is the default signal

coming out of hardware reset, runtime reset, and

Sleep.

NA NA LV

UART0

U0TXD O UART0 Transmit. Muxed with GPIO[20]. U0TXD is the

default signal coming out of hardware reset, runtime

reset, and Sleep.

0UNLV

U0RXD I UART0 Receive. IN IN IN

UART1

U1TXD O UART1 Transmit. Muxed with GPIO[21]. U1TXD is the

default signal coming out of hardware reset, runtime

reset, and Sleep.

0UNLV

U1RXD I UART1 Receive. IN IN IN

UART2

U2TXD O UART2 Transmit. Muxed with GPIO[22]. U2TXD is the

default signal coming out of hardware reset, runtime

reset, and Sleep.

0UNLV

U2RXD I UART2 Receive. IN IN IN

UART3

U3TXD O UART3 Transmit. Muxed with GPIO[23]. U3TXD is the

default signal coming out of hardware reset, runtime

reset, and Sleep.

0UNLV

U3RXD I UART3 Receive. IN IN IN

U3CTS I Clear to Send. Muxed with GPIO[9]. GPIO[9] is the

default signal coming out of hardware reset, runtime

reset, and Sleep.

System Note: For systems that use the UART3 inter-

face without the optional modem control signals

(sys_pinfunc[UR3]=0), the modem status interrupts

must be disabled (uart3_inten[MIE]=0) to avoid false

UART3 interrupts when using GPIO[9], GPIO[10],

GPIO[11], or GPIO[12] as an input.

NA NA LV

U3DSR I Data Set Ready. Muxed with GPIO[10]. GPIO[10] is

the default signal coming out of hardware reset, runt-

ime reset, and Sleep.

System Note: For systems that use the UART3 inter-

face without the optional modem control signals

(sys_pinfunc[UR3]=0), the modem status interrupts

must be disabled (uart3_inten[MIE]=0) to avoid false

UART3 interrupts when using GPIO[9], GPIO[10],

GPIO[11], or GPIO[12] as an input.

NA NA LV

Table 10-3. Signal Descriptions (Continued)

Signal Type Description

Reset

During

SleepHardware Run Time

AMD Alchemy™ Au1000™ Processor Data Book 223

Signal Descriptions 30360E

U3DCD I Data Carrier Detect. Muxed with GPIO[11]. GPIO[11]

is the default signal coming out of hardware reset,

runtime reset, and Sleep.

System Note: For systems that use the UART3 inter-

face without the optional modem control signals

(sys_pinfunc[UR3]=0), the modem status interrupts

must be disabled (uart3_inten[MIE]=0) to avoid false

UART3 interrupts when using GPIO[9], GPIO[10],

GPIO[11], or GPIO[12] as an input.

NA NA LV

U3RI I Ring Indication. Muxed with GPIO[12]. GPIO[12] is the

default signal coming out of hardware reset, runtime

reset, and Sleep.

System Note: For systems that use the UART3 inter-

face without the optional modem control signals

(sys_pinfunc[UR3]=0), the modem status interrupts

must be disabled (uart3_inten[MIE]=0) to avoid false

UART3 interrupts when using GPIO[9], GPIO[10],

GPIO[11], or GPIO[12] as an input.

NA NA LV

U3RTS O Request to Send. Muxed with GPIO[13]. GPIO[13] is

the default signal coming out of hardware reset, runt-

ime reset, and Sleep.

NA NA LV

U3DTR O Data Terminal Ready. Muxed with GPIO[14].

GPIO[14] is the default signal coming out of hardware

reset, runtime reset, and Sleep.

NA NA LV

Ethernet Controller 0

N0TXCLK I Continuous clock input for synchronization of transmit

data. 25 MHz when operating at 100 Mbps and 2.5

MHz when operating at 10 Mbps.

IN IN LV

N0TXEN O Indicates that the data nibble on N0TXD[3:0] is valid. 0 UN LV

N0TXD[3:0] O Nibble wide data bus synchronous to N0TXCLK. For

each N0TXCLK period in which N0TXEN is asserted,

TXD[3:0] will have the data to be accepted by the

PHY. While N0TXEN is de-asserted the data pre-

sented on TXD[3:0] should be ignored.

0UNLV

N0RXCLK I Continuous clock that provides the timing reference

for the data transfer from the PHY to the MAC.

N0RXCLK is sourced by the PHY. The N0RXCLK

shall have a frequency equal to 25% of the data rate of

the received signal data stream (typically 25 MHz at

100 Mbps and 2.5 MHz at 10 Mbps).

IN IN LV

N0RXDV I Indicates that a receive frame is in process and that

the data on N0RXD[3:0] is valid.

IN IN LV

N0RXD[3:0] I RXD[3:0] is a nibble wide data bus driven by the PHY

to the MAC synchronous with N0RXCLK. For each

N0RXCLK period in which N0RXDV is asserted,

RXD[3:0] will transfer four bits of recovered data from

the PHY to the MAC. While N0RXDV is de-asserted,

RXD[3:0] will have no effect on the MAC.

IN IN LV

Table 10-3. Signal Descriptions (Continued)

Signal Type Description

Reset

During

SleepHardware Run Time

224 AMD Alchemy™ Au1000™ Processor Data Book

Signal Descriptions

30360E

N0CRS I N0CRS shall be asserted by the PHY when either

transmit or receive medium is non Idle. N0CRS shall

be de-asserted by the PHY when both the transmit

and receive medium are Idle. N0CRS is an asynchro-

nous input.

IN IN LV

N0COL I N0COL shall be asserted by the PHY upon detection

of a collision on the medium, and shall remain

asserted while the collision condition persists. N0COL

is an asynchronous input. The N0COL signal is

ignored by the MAC when operating in the full duplex

mode.

IN IN LV

N0MDC O N0MDC is sourced by the MAC to the PHY as the tim-

ing reference for transfer of information on the

N0MDIO signal. N0MDC is an aperiodic signal that

has no maximum high or low times. The minimum high

and low times for N0MDC will be 160 ns each, and the

minimum period for N0MDC will be 400 ns.

0UNLV

N0MDIO IO N0MDIO is the bidirectional data signal between the

MAC and the PHY that is clocked by N0MDC.

HIZ UN LV

Ethernet Controller 1

N1TXCLK I Continuous clock input for synchronization of transmit

data. 25 MHz when operating at 100 Mb/s and 2.5

MHz when operating at 10 Mb/s.

IN IN LV

N1TXEN O Indicates that the data nibble on N1TXD[3:0] is valid.

Muxed with GPIO[24]. N1TXEN is the default signal

coming out of hardware reset, runtime reset, and

Sleep.

0UNLV

N1TXD[3:0] O Nibble wide data bus synchronous to N1TXCLK. For

each N1TXCLK period in which N1TXEN is asserted,

TXD[3:0] will have the data to be accepted by the

PHY. While N1TXEN is de-asserted the data pre-

sented on TXD[3:0] should be ignored.

Muxed with GPIO[28:25]. N1TXD[3:0] are the default

signals coming out of hardware reset, runtime reset,

and Sleep.

0UNLV

N1RXCLK I Continuous clock that provides the timing reference

for the data transfer from the PHY to the MAC.

N1RXCLK is sourced by the PHY. The N1RXCLK

shall have a frequency equal to 25% of the data rate of

the received signal data stream (typically 25 MHz at

100 Mb/s and 2.5 MHz at 10 Mb/s)

IN IN LV

N1RXDV I Indicates that a receive frame is in process and that

the data on N1RXD[3:0] is valid.

IN IN LV

N1RXD[3:0] I RXD[3:0] is a nibble wide data bus driven by the PHY

to the MAC synchronous with N1RXCLK. For each

N1RXCLK period in which N1RXDV is asserted,

RXD[3:0] will transfer four bits of recovered data from

the PHY to the MAC. While N1RXDV is de-asserted,

RXD[3:0] will have no effect on the MAC.

IN IN LV

Table 10-3. Signal Descriptions (Continued)

Signal Type Description

Reset

During

SleepHardware Run Time

AMD Alchemy™ Au1000™ Processor Data Book 225

Signal Descriptions 30360E

N1CRS I N1CRS is asserted by the PHY when either transmit

or receive medium is non Idle. N1CRS is de-asserted

by the PHY when both the transmit and receive

medium are Idle. N1CRS is an asynchronous input.

IN IN LV

N1COL I N1COL is asserted by the PHY upon detection of a

collision on the medium, and remains asserted while

the collision condition persists. N1COL is an asyn-

chronous input. The N1COL signal is ignored by the

MAC when operating in the full duplex mode.

IN IN LV

N1MDC O N1MDC is sourced by the MAC to the PHY as the tim-

ing reference for transfer of information on the

N1MDIO signal. N1MDC is an aperiodic signal that

has no maximum high or low times. The minimum high

and low times for N1MDC will be 160 ns each, and the

minimum period for N1MDC will be 400 ns.

0UNLV

N1MDIO IO N1MDIO is the bidirectional data signal between the

MAC and the PHY that is clocked by N1MDC.

0UNLV

I2S

I2SCLK O Serial bit clock. Muxed with GPIO[30]. I2SCLK is the

default signal coming out of hardware reset, runtime

reset, and Sleep.

0UNLV

I2SWORD O Word clock typically configured to the sampling fre-

quency (Fs).

Muxed with GPIO[31]. I2SWORD is the default signal

coming out of hardware reset, runtime reset, and

Sleep.

0UNLV

I2SDI I Serial data input sampled on the rising edge of

I2SCLK. Note that I2SDI is used as the input for bidi-

rectional operation only, in which case it is used in

conjunction with I2SDIO as the output

(i2s_config[PD]=0).

Muxed with GPIO[8]. GPIO[8] is the default signal

coming out of hardware reset, runtime reset, and

Sleep.

System Note: For systems that use the I2S interface

for unidirectional operation (I2SDI not used), the

GPIO[8] function is available but with the following

restrictions:

When I2SDIO is configured as an input, GPIO[8]

can be used only as an output.

When I2SDIO is configured as an output, the I2S

receive function must be disabled if GPIO[8] is to

be used as an input.

NA NA LV

I2SDIO IO Configurable as input or output. As input data should

be presented on rising edge. As output, data will be

valid on rising edge.

Muxed with GPIO[29]. I2SDIO is the default signal

coming out of hardware reset, runtime reset, and

Sleep.

0UNLV

Table 10-3. Signal Descriptions (Continued)

Signal Type Description

Reset

During

SleepHardware Run Time

226 AMD Alchemy™ Au1000™ Processor Data Book

Signal Descriptions

30360E

AC-Link

ACSYNC O Fixed rate sample sync. Muxed with S1DOUT.

ACSYNC is the default signal coming out of hardware

reset, runtime reset, and Sleep.

00LV

ACBCLK I Serial data clock. Muxed with S1DIN. ACBCLK is the

default signal coming out of hardware reset, runtime

reset, and Sleep.

IN IN LV

ACDO O TDM output stream. Muxed with S1CLK. ACDO is the

default signal coming out of hardware reset, runtime

reset, and Sleep.

00LV

ACDI I TDM input stream. IN IN LV

ACRST# O CODEC reset. Muxed with S1DEN. ACRST# is the

default signal coming out of hardware reset, runtime

reset, and Sleep.

10LV

EJTAG

TRST# I Asynchronous TAP reset. IN IN LV

TDI I Test data input to the instruction or selected data reg-

isters. Sampled on the rising edge of TCK.

IN IN LV

TDO O Test data output from the instruction or data register.

Transitions occur on the falling edge (valid on rising

edge) of TCK.

HIZ UN LV

TMS I Control signal for TAP controller. Sampled on the ris-

ing edge of TCK.

IN IN LV

TCK I Control clock for updating TAP controller and shifting

data through instruction or selected data register.

IN IN LV

Test

TC[3:0] I Test clock inputs (not used in typical application).

Should be pulled low for normal operation.

IN IN LV

TESTEN I Test Enable (not used in typical applications). Should

be pulled low for normal operation.

IN IN LV

GPIO

GPIO[1:0] IOZ General Purpose IO. HIZ DEP

(Note 1)

GPIO[3:2] IOZ General Purpose IO. Muxed with EXTCLK[1:0].

GPIO[3:2] are the default signals coming out of hard-

ware reset, runtime reset, and Sleep.

HIZ DEP

(Note 1)

GPIO[4] IOZ General Purpose IO. Can be configured as

DMA_REQ0.

HIZ DEP

(Note 1)

GPIO[5] IOZ General Purpose IO. Can be configured as

DMA_REQ1.

HIZ DEP

(Note 1)

GPIO[6] IOZ General Purpose IO. Muxed with SMROMCKE. If

ROMSEL and ROMSIZE are configured to boot from

synchronous mask ROM, the SMROMCKE signal is

selected for the pin coming out of reset; otherwise,

GPIO[6] is selected.

HIZ DEP

(Note 1)

Table 10-3. Signal Descriptions (Continued)

Signal Type Description

Reset

During

SleepHardware Run Time

AMD Alchemy™ Au1000™ Processor Data Book 227

Signal Descriptions 30360E

GPIO[7] IOZ General Purpose IO. HIZ DEP

(Note 1)

GPIO[8] IOZ General Purpose IO. Muxed with I2SDI. GPIO[8] is the

default signal coming out of hardware reset, runtime

reset, and Sleep.

System Note: For systems that use the I2S interface

for unidirectional operation (I2SDI not used), the

GPIO[8] function is available but with the following

restrictions:

When I2SDIO is configured as an input, GPIO[8]

can be used only as an output.

When I2SDIO is configured as an output, the I2S

receive function must be disabled if GPIO[8] is to

be used as an input.

HIZ DEP

(Note 1)

GPIO[9] IOZ General Purpose IO. Muxed with U3CTS. GPIO[9] is

the default signal coming out of hardware reset, runt-

ime reset, and Sleep.

System Note: For systems that use the UART3 inter-

face without the optional modem control signals

(sys_pinfunc[UR3]=0), the modem status interrupts

must be disabled (uart3_inten[MIE]=0) to avoid false

UART3 interrupts when using GPIO[9], GPIO[10],

GPIO[11], or GPIO[12] as an input.

HIZ DEP

(Note 1)

GPIO[10] IOZ General Purpose IO. Muxed with U3DSR. GPIO[10] is

the default signal coming out of hardware reset, runt-

ime reset, and Sleep.

System Note: For systems that use the UART3 inter-

face without the optional modem control signals

(sys_pinfunc[UR3]=0), the modem status interrupts

must be disabled (uart3_inten[MIE]=0) to avoid false

UART3 interrupts when using GPIO[9], GPIO[10],

GPIO[11], or GPIO[12] as an input.

HIZ DEP

(Note 1)

GPIO[11] IOZ General Purpose IO. Muxed with U3DCD. GPIO[11] is

the default signal coming out of hardware reset, runt-

ime reset, and Sleep.

System Note: For systems that use the UART3 inter-

face without the optional modem control signals

(sys_pinfunc[UR3]=0), the modem status interrupts

must be disabled (uart3_inten[MIE]=0) to avoid false

UART3 interrupts when using GPIO[9], GPIO[10],

GPIO[11], or GPIO[12] as an input.

HIZ DEP

(Note 1)

GPIO[12] IOZ General Purpose IO. Muxed with U3RI. GPIO[12] is

the default signal coming out of hardware reset, runt-

ime reset, and Sleep.

System Note: For systems that use the UART3 inter-

face without the optional modem control signals

(sys_pinfunc[UR3]=0), the modem status interrupts

must be disabled (uart3_inten[MIE]=0) to avoid false

UART3 interrupts when using GPIO[9], GPIO[10],

GPIO[11], or GPIO[12] as an input.

HIZ DEP

(Note 1)

Table 10-3. Signal Descriptions (Continued)

Signal Type Description

Reset

During

SleepHardware Run Time

228 AMD Alchemy™ Au1000™ Processor Data Book

Signal Descriptions

30360E

GPIO[13] IOZ General Purpose IO. Muxed with U3RTS. GPIO[13] is

the default signal coming out of hardware reset, runt-

ime reset, and Sleep.

HIZ DEP

(Note 1)

GPIO[14] IOZ General Purpose IO. Muxed with U3DTR. GPIO[14] is

the default signal coming out of hardware reset, runt-

ime reset, and Sleep.

HIZ DEP

(Note 1)

GPIO[15] IOZ General Purpose IO. Muxed with IRFIRSEL. GPIO[15]

is the default signal coming out of hardware reset,

runtime reset, and Sleep.

HIZ DEP

(Note 1)

GPIO[16] IOZ General Purpose IO. Muxed with S0DOUT. S0DOUT

is the default signal coming out of hardware reset,

runtime reset, and Sleep.

NA NA LV

GPIO[17] IOZ General Purpose IO. Muxed with S0CLK. S0CLK is

the default signal coming out of hardware reset, runt-

ime reset, and Sleep.

NA NA LV

GPIO[18] IOZ General Purpose IO. Muxed with S0DEN. S0DEN is

the default signal coming out of hardware reset, runt-

ime reset, and Sleep.

NA NA LV

GPIO[19] IOZ General Purpose IO. Muxed with IRDATX. IRDATX is

the default signal coming out of hardware reset, runt-

ime reset, and Sleep.

NA NA LV

GPIO[20] IOZ General Purpose IO. Muxed with U0TXD. U0TXD is

the default signal coming out of hardware reset, runt-

ime reset, and Sleep.

NA NA LV

GPIO[21] IOZ General Purpose IO. Muxed with U1TXD. U1TXD is

the default signal coming out of hardware reset, runt-

ime reset, and Sleep.

NA NA LV

GPIO[22] IOZ General Purpose IO. Muxed with U2TXD. U2TXD is

the default signal coming out of hardware reset, runt-

ime reset, and Sleep.

NA NA LV

GPIO[23] IOZ General Purpose IO. Muxed with U3TXD. U3TXD is

the default signal coming out of hardware reset, runt-

ime reset, and Sleep.

NA NA LV

GPIO[24] IOZ General Purpose IO. Muxed with N1TXEN. N1TXEN

is the default signal coming out of hardware reset,

runtime reset, and Sleep.

NA NA LV

GPIO[28:25] IOZ General Purpose IO. Muxed with N1TXD[3:0].

N1TXD[3:0] are the default signals coming out of

hardware reset, runtime reset, and Sleep.

NA NA LV

GPIO[29] IOZ General Purpose IO. Muxed with I2SDIO. I2SDIO is

the default signal coming out of hardware reset, runt-

ime reset, and Sleep.

NA NA LV

GPIO[30] IOZ General Purpose IO. Muxed with I2SCLK. I2SCLK is

the default signal coming out of hardware reset, runt-

ime reset, and Sleep.

NA NA LV

GPIO[31] IOZ General Purpose IO. Muxed with I2SWORD.

I2SWORD is the default signal coming out of hard-

ware reset, runtime reset, and Sleep.

NA NA LV

Table 10-3. Signal Descriptions (Continued)

Signal Type Description

Reset

During

SleepHardware Run Time

AMD Alchemy™ Au1000™ Processor Data Book 229

Signal Descriptions 30360E

External Clocks

EXTCLK[1:0] O General-purpose external clocks. One of these clock

outputs can be used as an oversampled audio clock

(AUDCLK or MCLK) output with I2S port as it is syn-

chronous to I2SCLK and I2SWORD. Typically it

should be programmed to 128*Fs, 256*Fs, 384*Fs or

512*Fs for this application.

Muxed with GPIO[3:2]. GPIO[3:2] are the default sig-

nals coming out of hardware reset, runtime reset, and

Sleep.

NA NA LV

System DMA Requests

DMA_REQ0

(GPIO[4])

I GPIO[4] can be configured as an external, system

DMA request input.

HIZ HIZ LV

DMA_REQ1

(GPIO[5])

I GPIO[5] can be configured as an external, system

DMA request input.

HIZ HIZ LV

System Clocks and Reset

XTI12 I Internally compensated 12 MHz (typical) crystal input.

Termination Note: The termination depends on the

application as follows:

Crystal—Connect crystal between XTI12 and XTO12.

Overdriven—Connect to external 12 MHz clock

source and drive complementary to XTO12.

XTO12 O Internally compensated 12 MHz (typical) crystal out-

put.

Termination Note: The termination depends on the

application as follows:

Crystal—Connect crystal between XTI12 and XTO12.

Overdriven—Connect to external 12-MHz clock

source and drive complementary to XTI12.

XTI32 I Internally compensated 32.768-kHz (typical) crystal

input.

Termination Note: The termination depends on the

application as follows:

Crystal—Connect crystal between XTI32 and XTO32.

Overdriven—Connect to external 32.768-kHz clock

source through a series 10-kΩ resistor and drive com-

plementary to XTO32.

Not used—Connect to VDDX.

Table 10-3. Signal Descriptions (Continued)

Signal Type Description

Reset

During

SleepHardware Run Time

230 AMD Alchemy™ Au1000™ Processor Data Book

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30360E

XTO32 O Internally compensated 32.768 kHz (typical) crystal

output.

Termination Note: The termination depends on the

application as follows:

Crystal—Connect crystal between XTI32 and XTO32.

Overdriven—Connect to external 32.768 kHz clock

source through a series 10 kohm resistor and drive

complementary to XTI32.

Not used—Connect to VDDX.

RESETIN# I CPU reset input. IN IN LV

RESETOUT# O Buffered output of CPU reset input (RESETIN#). 0 0 0

ROMSEL I Determines if boot is from ROM or SMROM. ROMSEL

should be terminated appropriately as these signals

should not change during runtime.

IN IN LV

ROMSIZE I Latched at the rising edge of reset to determine if

ROM width is 16 or 32 bits.

ROMSIZE should be terminated appropriately as

these signals should not change during runtime.

IN IN LV

Power Management

PWR_EN O Power enable output. This signal is intended to be

used as the regulator enable for VDDI (core power).

110

VDDXOK I Input to signal that VDDX is stable. IN IN LV

Power/Ground

VDDI P Internal core voltage. Follow the power supply layout

guidelines in Section 11.9.2 "Decoupling Recommen-

dations" on page 251.

VDDX P External I/O voltage. Follow the power supply layout

guidelines in Section 11.9.2 "Decoupling Recommen-

dations" on page 251.

VSS G Ground.

XPWR12 P 12 MHz (typical) oscillator and PLL power. Connect to

VDDX through a 10 ohm resistor. In addition a 22 µF

capacitor in parallel with a 0.01 µF capacitor should be

placed from this pin to XAGND12.

XAGND12 G 12 MHz (typical) oscillator and PLL ground.

XPWR32 P 32.768 kHz (typical) oscillator and PLL power.

Because XPWR32 powers other circuitry also, it

should be connected even if the oscillator is not used.

Connect to VDDX through a 10 ohm resistor. In addi-

tion a 22 µF capacitor in parallel with a 0.01 µF capac-

itor should be placed from this pin to XAGND32.

XAGND32 G 32.768kHz (typical) oscillator and PLL ground.

Note 1. Depends on sys_trioutrd and sys_outputset. During a runtime reset, sys_pinfunc returns to its default value,

but the GPIO control registers sys_trioutrd and sys_outputset remain unchanged.

Table 10-3. Signal Descriptions (Continued)

Signal Type Description

Reset

During

SleepHardware Run Time

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Electrical and Thermal Specifications 30360E

11.0Electrical and Thermal

Specifications

This chapter provides preliminary electrical specifications for the Au1000 processor, including the following:

•Absolute Maximum Ratings

•Thermal Characteristics

•DC Parameters

•AC Parameters

•Power-up, Reset, Sleep, and Idle Timing

•External Clock Specifications

•Crystal Specifications

•System Design Considerations

11.1 Absolute Maximum Ratings

Table 11-1 shows the absolute maximum ratings for the Au1000 processor. These ratings are stress ratings, operating at or

beyond these ratings for extended periods of time may result in damage to the Au1000 processor.

Unless otherwise designated all voltages are relative to VSS.

Table 11-1. Absolute Maximum Ratings

Parameter Description Min Max Unit

VDDI Core Voltage VSS - 0.5 2 V

VDDX I/O Voltage VSS - 0.5 3.6 V

XPWR12, XPWR32 Oscillator Voltage VSS - 0.5 3.6 V

VIN Voltage Applied to Any Pin VSS - 0.5 VDDX + 0.5 V

TCASE Commercial Package Operating Temperature 0 85 °C

TCASE Industrial

(266 MHz part only)

Package Operating Temperature -40 100 °C

TSStorage Temperature -40 125 °C

232 AMD Alchemy™ Au1000™ Processor Data Book

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11.1.1 Undershoot

The minimum DC voltage on input or I/O pins is -0.5V. However, during voltage transitions, the device can tolerate under-

shoot to -2.0V for up to 20 ns, as shown in Figure 11-1.

Figure 11-1. Voltage Undershoot Tolerances for Input and I/O Pins

11.1.2 Overshoot

The maximum DC voltage on input or I/O pins is (VDDX + 0.5) V. However, during voltage transitions, the device can tolerate

overshooting VDDX to (VDDX + 2.0) V for up to 20 ns, as shown in Figure 11-2.

Figure 11-2. Voltage Overshoot Tolerances for Input and I/O Pins

11.2 Thermal Characteristics

Table 11-2 shows the thermal characteristics for the Au1000 processor.

Table 11-2. Thermal Characteristics

Parameter Description Value Unit

ΘJA Thermal resistance from device junction to ambient. 28.0 (Note 1)

Note 1. Measured without forced air—natural convection only.

°C/W

YJT Thermal characterization parameter measured from device junction to

top center of package. (See JESD51-2, Sec. 4.)

4.4 °C/W

20 ns

–2.0V

–0.5V

VIL Allowed

Voltages

20 ns

VDDX,Y + 2.0V

VDDX,Y + 0.5V

VDDX,Y

Allowed

Voltages

20 ns

20 ns 20 ns

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11.3 DC Parameters

Table 11-3 shows the DC parameters for the Au1000 processor. Unless otherwise designated all voltages are relative to

VSS.

The operating requirements for the power supply voltages (VDDX and VDDI) are given in the sections describing the DC

characteristics for the different operating frequencies, beginning with Section 11.3.1 "Power and Voltage for 266, 400, and

500 MHz Rated Parts" on page 233.

11.3.1 Power and Voltage for 266, 400, and 500 MHz Rated Parts

The tables that follow give the voltage and power parameters for the individual MHz rated parts.

Table 11-3. DC Parameters

Symbol Parameter Min Nominal Max Unit

VIHx Input High Voltage 2.4 V

VILx Input Low Voltage 0.2 * VDDX V

VOHx @ 2 mA Output High Voltage 0.8 * VDDX V

VOLx @ 2 mA Output Low Voltage 0.2 * VDDX V

LIInput Leakage Current 5 µA

CIN Input Capacitance (Note 1)

Note 1. This parameter is by design and not tested.

5pF

IXPWR12 (Note 2)

Note 2. Does not apply during Sleep.

XPWR12 Current 1 3 mA

IXPWR32 (Note 2) XPWR32 Current 1 3 mA

Table 11-4. Voltage and Power Parameters for 266 MHz Part

Parameter Min Typ Max Unit

VDDI 1.4 1.5 1.6 V

VDDX, XPWR12, XPWR32 (Note 1)

Note 1. XPWR12 and XPWR32 should be connected to VDDX. For a description of this circuit connection, see the entries

for XPWR12 and XPWR32 in Table 10-3 "Signal Descriptions" on page 218.

3.0 3.3 3.6 V

Power: VDDI 195 525 (Note 2)

Note 2. While the maximum power numbers should be used when specifying a regulator for a system, the numbers are well

above the typical power consumption because none of the power-saving design features (such as Idle, or the au-

tomatic SBUS divider) are enabled. Note that because the particular application software and external loading af-

fect the power consumption on a given system design, certain conditions may exist which could cause the

maximum power consumption to be different than shown.

Power: VDDX 105 325 (Note 2) mW

Idle Power (Note 3)

Note 3. Idle power is the power measured when the processor core is in the IDLE0 state. (IDLE0 maintains cache coher-

ency by snooping the SBUS; IDLE1 does not snoop the bus. Because caches are turned off during the IDLE1 state,

IDLE1 consumes less power than IDLE0.) Typically the Idle state is entered during an operating system’s wait loop

in which the core has no processes to run. While the processor core is in Idle, clocks to the core are gated off; how-

ever, all registers retain their values, and the peripherals, DMA engine, and the interrupts remain active so that the

system is still functional.

210 mW

Sleep Current (VDDI = VSS)50uA

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Electrical and Thermal Specifications

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Table 11-5. Voltage and Power Parameters for 400 MHz Part

Parameter Min Typ Max Unit

VDDI 1.4 1.5 1.6 V

VDDX, XPWR12, XPWR32 (Note 1)

Note 1. XPWR12 and XPWR32 should be connected to VDDX. For a description of this circuit connection, see the entries

for XPWR12 and XPWR32 in Table 10-3 "Signal Descriptions" on page 218.

3.0 3.3 3.6 V

Power: VDDI 365 725 (Note 2)

Note 2. While the maximum power numbers should be used when specifying a regulator for a system, the numbers are well

above the typical power consumption because none of the power-saving design features (such as Idle, or the au-

tomatic SBUS divider) are enabled. Note that because the particular application software and external loading af-

fect the power consumption on a given system design, certain conditions may exist which could cause the

maximum power consumption to be different than shown.

Power: VDDX 135 465 (Note 2) mW

Idle Power (Note 3)

Note 3. Idle power is the power measured when the processor core is in the IDLE0 state. (IDLE0 maintains cache coher-

ency by snooping the SBUS; IDLE1 does not snoop the bus. Because caches are turned off during the IDLE1 state,

IDLE1 consumes less power than IDLE0.) Typically the Idle state is entered during an operating system’s wait loop

in which the core has no processes to run. While the processor core is in Idle, clocks to the core are gated off; how-

ever, all registers retain their values, and the peripherals, DMA engine, and the interrupts remain active so that the

system is still functional.

222 mW

Sleep Current (VDDI = VSS)50µA

Table 11-6. Voltage and Power Parameters for 500 MHz Part

Parameter Min Typ Max Unit

VDDI 1.71 1.8 1.89 V

VDDX, XPWR12, XPWR32 (Note 1)

Note 1. XPWR12 and XPWR32 should be connected to VDDX. For a description of this circuit connection, see the entries

for XPWR12 and XPWR32 in Table 10-3 "Signal Descriptions" on page 218.

3.0 3.3 3.6 V

Power: VDDI 750 1300 (Note 2)

Note 2. While the maximum power numbers should be used when specifying a regulator for a system, the numbers are well

above the typical power consumption because none of the power-saving design features (such as Idle, or the au-

tomatic SBUS divider) are enabled. Note that because the particular application software and external loading af-

fect the power consumption on a given system design, certain conditions may exist which could cause the

maximum power consumption to be different than shown.

Power: VDDX 150 575 (Note 2) mW

Idle Power (Note 3)

Note 3. Idle power is the power measured when the processor core is in the IDLE0 state. (IDLE0 maintains cache coher-

ency by snooping the SBUS; IDLE1 does not snoop the bus. Because caches are turned off during the IDLE1 state,

IDLE1 consumes less power than IDLE0.) Typically the Idle state is entered during an operating system’s wait loop

in which the core has no processes to run. While the processor core is in Idle, clocks to the core are gated off; how-

ever, all registers retain their values, and the peripherals, DMA engine, and the interrupts remain active so that the

system is still functional.

347 mW

Sleep Current (VDDI = VSS)50µA

AMD Alchemy™ Au1000™ Processor Data Book 235

Electrical and Thermal Specifications 30360E

11.4 AC Parameters

This section describes the AC parameters for I/O devices in the Au1000 processor. Each class of output signal has different

capacitive loads. As the capacitance on the load increases the propagation delay will increase. These specifications

assume the maximum capacitive load to be 50 pF for all I/O signals other than the SDRAM interface.

The timing of those signals which have synchronous relationships or have a defined requirement are given. The timing dia-

grams are shown to illustrate the timing only and should not necessarily be interpreted as the functional timing of the port.

It is assumed that the timing and/or functionality of the protocol related to the port is adhered to by the external system. The

protocol timing is not necessarily presented here and the appropriate section or specification should be referenced for com-

plete functional timing parameters.

Timing measurements are made from 50% threshold to 50% threshold.

Certain timing parameters are based off of the internal System Bus (SBUS) clock. When this is the case the symbol Tsys is

used. Tsys is defined in nanoseconds as:

Tsys = SD/CPU

The symbol CPU should be interpreted as the CPU clock speed in MHz as set by the CPU PLL. See Section 7.1 "Clocks"

on page 168 for details. The symbol SD is the SBUS divider. See Section 7.4 "Power Management" on page 188 for details.

236 AMD Alchemy™ Au1000™ Processor Data Book

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30360E

11.4.1 SDRAM Timing and Loading

The SDRAM controller loading limits are as follows:

•SDRAM outputs excluding the clocks and chip-selects can support a maximum capacitive load of 35 pF (six 5 pF gate

loads and 5 pF representing the trace).

•Each clock and each chip-select supports a maximum capacitive load of 15 pF (two 5 pF gate loads and 5 pF repre-

senting the trace).

The SDRAM is a high speed interface. Reflection and propagation delays should be accounted for in the system design. As

a general rule of thumb, unterminated etches should be kept to 6 inches or less.

Figure 11-3. SDRAM Timing

Table 11-7. SDRAM Controller Interface

Signal Symbol Parameter Min Max Unit

SDCLK[n] Tsdclk SDCLK[n] Clock Cycle ns

SDCS[n#], SDRAS#,

SDCAS#, SDWE#,

SDBA[1:0], SDA[12:0],

SDQM[3:0]#, SDD[31:0]

(output)

Tsdd Delay from SDCLK[n] ns

SDD[31:0] (input) Tsdsu Data setup to SDCLK[n] 3 ns

SDD[31:0] (input) Tsdh Data hold from SDCLK[n] 2 ns

2Tsys

Tsdclk

-------------- 1.5–

Tsdclk

-------------- 2+

Tsdh

Tsdsu

Tsdd

Tsdclk

SDCLK

SDCS[n]#, SDRAS#,

SDCAS#, SDWE#,

SDBA[1:0], SDA[12:0],

SDQM[3:0]#, SDD[31:0]

(output)

SDD[31:0]

(input)

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11.4.2 Static Bus Controller Timing

The timing presented in registers mem_sttimen are not presented here. The parameters in these registers are presented

in a certain number of clock cycles and are accurate to within ± 2 ns.

Figure 11-4. Static RAM, I/O Device and Flash Timing

Table 11-8. Static RAM, I/O Device and Flash Timing

Signal Symbol Parameter Min Max Unit

RBEN[3:0]#, ROE#,

RAD[31:0], burstsize[2:0]

Trcd Delay from RCSn#. -2 +2 ns

RD[31:0] (read) Trsu Data setup to RCSn# Trsu

does not apply when EWAIT#

is used to extend the cycle.

15 ns

RD[31:0] (read) Trsue Data setup to EWAIT#. Note that

Trsue applies only when EWAIT#

is used to extend the cycle.

0ns

RD[31:0] (read) Trh Data hold from RCSn#. 0 ns

RD[31:0] (write) Trod Delay from RWE# to data out. -2 2 ns

EWAIT# Trwsu EWAIT# setup to RCSn# for

reads, or RWE# for writes. If

EWAIT# does not meet this setup

time the cycle will not be held.

3 * TSYS + 15 ns

RCS# (reads), RWE#

(writes)

Trwd Delay from EWAIT#. 2 * TSYS 3 * TSYS + 15

burstsize[2:0] Trbd Delay from RCSn#. TSYS + 2

RBEN[3:0]#,

ROE#,

RAD[31:0]

Tr c d Tr c d

Tr s u

Tr h

Trwsu

Trwd

RCSn#

Tr w s u

Tr w d

RWE#

EWAIT#

RD[31:0]

(input)

burstsize[2:0]

RD[31:0]

(output)

Tr c d Trbd

Tr o d

Trsue

238 AMD Alchemy™ Au1000™ Processor Data Book

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30360E

Figure 11-5. PCMCIA Host Adapter Timing

Table 11-9. PCMCIA Timing

Signal Symbol Parameter Min Max Unit

PREG#, RAD[31:0],

RD[31:0] (output)

Tpcd Delay from PCE[n]#. -2 +2 ns

PIOS16# Tpios PIOS16# setup to PIOR#, PIOW#. 4 * Tsys + 15 ns

PIOS16# Tpioh PIOS16# hold from PIOR#,

PIOW#.

0ns

ROE# Tpoed ROE# delay from POE#, PIOR#. -2 +2 ns

RD[15:0] (input) Tpsu Data setup to POE#, PIOR#. Note

that Tpsu does not apply when

PWAIT# is used to extend the

cycle.

Tsys + 15 ns

RD[15:0] (input) Tpsup Data setup to PWAIT#. Note that

Tpsup applies only when PWAIT#

is used to extend the cycle.

0ns

RD[31:0] Tph Data hold from POE#, PIOR#. 0 ns

PWAIT# Tpwsu PWAIT# setup to POE#, PWE#,

PIOR#, PIOW#. If PWAIT# does

not meet this setup time the cycle

will not be held.

4 * Tsys + 15 ns

POE#, PWE#, PIOR#,

PIOW#

Tpwd POE#, PWE#, PIOR#, PIOW#

delay from PWAIT#.

3 * Tsys 4 * Tsys + 15 ns

PREG#,

RAD[31:0],

RD[15:0] (output)

Tpcd Tpcd

PWE#, PIOW#

POE#, PIOR#

PIOS16#

PWAIT#

ROE# Tpcd

Tph

Tpsu

Tpwsu

Tpwd

Tpios

Tpioh

Tpoed

PCE[n]#

RD[15:0]

(input)

Tpsup

AMD Alchemy™ Au1000™ Processor Data Book 239

Electrical and Thermal Specifications 30360E

Figure 11-6. LCD Interface Timing

Table 11-10. LCD Timing

Signal Symbol Parameter Min Max Unit

LCLK Tlclk LCLK Period. This parameter is

programmed in mem_stcfg0[D5].

Tsys * 4 Tsys * 5 ns

RCSn#, RAD[31:0],

RD[15:0] (output)

Tlcd Delay from LCLK. -2 2 ns

RD[15:0] (input) Tlsu Data setup to LRD[n]#. Tsys + 15 ns

RD[15:0] (input) Tlh Data hold from LRD[n]#. 0 ns

LWAIT# Tlwsu LWAIT# setup to LRD[n] for

reads, or LWR[n]# for writes.

If LWAIT# does not meet this

setup time the cycle will not be

held.

4 * Tsys +

Tlclk + 15

LRD[n]# (reads), LWR[n]#

(writes)

Tlwd Delay from LWAIT#. 4 * Tsys +

Tlclk + 15

RCSn#

RAD[31:0], RD[15:0]

(output)

Tlcd Tlcd

Tlh

Tlsu

LWR[n]#

LRD[n]#

LWAIT#

RD[15:0]

(input)

Tlwsu

Tlwd

Tlclk

LCLK

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11.4.3 GPIO Input Timing Requirements

11.4.3.1 GPIO Input Edge Rate

For level-sensitive GPIO inputs, edge rates as slow as 5 ms can be used. Note that no hysteresis is used on the inputs so

for edge-sensitive inputs (such as clocks and edge-triggered interrupts) use a 20 ns (or faster) edge rate to ensure that

noise does not cause false edges as the signal transitions through the threshold region.

11.4.3.2 GPIO Interrupt Timing

For system designs using GPIO signals as level-triggered interrupts, the signal level must be stable for at least 10 ns in

order for a signal state change to be detected. See Table 11-11 and Figure 11-7.

Figure 11-7. GPIO Interrupt Timing

Table 11-11. GPIO Timing for Interrupts

Signal Symbol Parameter Min Max Unit

GPIO[n] Tmin Minimum high or low time for interrupt. The level is

programmable. This timing reflects the minimum

active period for the level programmed.

10 ns

Tmin

GPIO[n]

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11.4.4 Peripheral Timing

This section contains the electrical timing specifications for the integrated peripherals.

11.4.4.1 Ethernet MII Timing

Figure 11-8. Ethernet MII Timing Diagram

Table 11-12. Ethernet MII Timing

Signal Symbol Parameter Min Max Unit

N0TXCLK, N0RXCLK,

N1TXCLK, N1RXCLK

Teth Ethernet transmit/receive clock cycle time (25%

of data rate)

40 ± 100 ppm (100 Mbps)

400 ± 100 ppm (10 Mbps)

Ethernet transmit/ receive clock duty cycle 35 65 %

N0TXEN, N0TXD[3:0],

N1TXEN, N1TXD[3:0]

Ted Delay from TXCLK to TXEN, TXD[3:0] 0 25 ns

N0RXD[3:0], N0RXDV,

N1RXD[3:0], N1RXDV

Tesu Setup time before RXCCLK for RXD, and RXDV 10 ns

Teh Hold time from RXCLK for RXD, and RXDV 10 ns

N0MDC, N1MDC Tmdc MDC cycle time SBUS clock / 160

MDC duty cycle 40 60 %

N0MDIO, N1MDIO Tmdd Delay from MDC to MDIO 0 300 ns

Tmsu Setup time before MDC for MDIO 10 ns

Tmh Hold time from MDC for MDIO 10 ns

Tmz Delay from MDC to MDIO TRI-STATE 0 300 ns

N0CRS, N0COL, N1CRS,

N1COL

Ta Minimum active time

Ted

Teth

NnTXD[3:0], NnTXEN

NnTXCLK

Teth

Teh

Tesu

NnRXCLK

NnRXD[3:0], NnRXDV

Tmz

Tmdd Tmh

Tmsu

Tmdc

NnMDC

NnMDIO

NnCRS,

NnCOL

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11.4.4.2 I2S Timing

Note: I2SDI and I2SDIO (as an input) are shown to have a 0 ns hold time relative to the falling edge. This design allows

for the data source to transition data from the falling edge to the next data value. I2SDIO input and output timing is

shown on the same signal. In practice, the signal direction can be programmed as only one or the other.

Figure 11-9. I2S Timing Diagram

Table 11-13. I2S Interface Timing

Signal Symbol Parameter Min Max Unit

I2SCLK Ti2s I2S interface clock cycle time 40 ns

I2S clock duty cycle 40 60 %

I2SDI, I2SDIO,

I2SWORD

Tid Delay from I2SCLK to I2SDIO and I2SWORD on

output (I2SDIO programmed as output)

010ns

Tisu Setup before I2SCLK on input

(I2SDIO programmed as input)

20 ns

Tih Hold after I2SCLK on input

(I2SDIO programmed as input)

0ns

Tid

Ti2s

Tih

Tisu

I2SCLK

I2SWORD

I2SDIO

I2SDI

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11.4.4.3 AC97 Timing

Note: ACRST# is an asynchronous signal controlled by software through the register ac97_config. It has no relationship

to the other AC97 signals.

Figure 11-10. AC-Link Timing Diagram

Table 11-14. AC-Link Interface Timing

Signal Symbol Parameter Min Max Unit

ACBCLK Tabc AC97 bit clock cycle time 12.288 (typical) MHz

Tabh AC97 bit clock high time 36 45 ns

Tabl AC97 bit clock low time 36 45 ns

ACSYNC Tacs AC97 sync cycle 48 (typical) kHz

Tacsh AC97 sync high time 1.3 (typical) µs

Tacsl AC97 sync low time 19.5 (typical) µs

ACSYNC

ACDO

ACDI

Tad Delay from ACBCLK to ACSYNC and

ACDO on output

15 ns

Tasu Setup before ACBCLK for ACDI 10 ns

Tah Hold after ACBCLK for ACDI 10 ns

Tad

Tacsl

Tacs

Tacsh

Tabh

Tabc

Tabl

Tah

Tasu

ACBCLK

ACSYNC

ACDO

ACDI

ACSYNC

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11.4.4.4 SSI Timing

Note: The timing diagrams shown are for rising edge active SnCLK and active low SnDEN. Both parameters are pro-

grammable. Timing will apply to the relative active or inactive edge as stated in the timing table.

The timing diagram is to represent timing only, it is not intended to represent the functionality of the port.

Timing parameters for both SSI ports are identical. Only one set of timing is presented with the n representing

either 0 or 1.

Figure 11-11. SSI Timing Diagram

Table 11-15. Synchronous Serial Interface Timing

Signal Symbol Parameter Min Max Unit

SnCLK Tclk Clock Period. This period is programmable.

See Section 6.8 "SSI Interfaces" on page

159 for more information.

200 ns

SnCLK Tscd SnDEN to clock delay Tclk + 10 ns

SnDEN Tsed SnCLK to SnDEN delay Tclk + 10 ns

SnDIN Tssu SnDIN setup to active edge of SnCLK 30 ns

SnDIN Tsh SnDIN hold from active edge of SnCLK 10 ns

SnDOUT Tsd SnDOUT delay from inactive edge of

SnCLK

20 ns

Tclk

Tssu

Tsh

Tsd

SnDEN

SnCLK

SnDOUT

SnDIN

Tscd

Tsed

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11.4.4.5 EJTAG Interface Timing

Figure 11-12. EJTAG Timing Diagram

Table 11-16. EJTAG Interface Timing

Signal Symbol Parameter Min Max Unit

TCK Tec EJTAG TCK cycle time 40 ns

Tech TCK high time 10 ns

Tecl TCK low time 10 ns

TMS, TDI Tesu Setup before TCK for TMS and TDI 5 ns

Teh Hold after TCK for TMS and TDI 3 ns

TDO Teco Delay from TCK to TDO on output 15 ns

Tecz Delay from TCK to TDO TRI-STATE 15 ns

TRST# Trstl TRST# low time 25 ns

TeczTeco

Trstl

TeclTechTec

Teh

Tesu

TCK

TMS, TDI

TDO

TRST#

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11.5 Power-up and Reset Timing

This section provides the timing specifications for the power-up sequence, and the hardware and runtime reset sequences.

(See Section 8, "Power-up, Reset and Boot" for functional descriptions of the sequences.)

11.5.1 Power-up Sequence Timing

Figure 11-13. Power-up Sequence

Table 11-17. Power-up Timing Parameters

Parameter Description Min Max Unit

Tvo VDDX at 90% of nominal to VDDXOK asserted 0 ns

Tpen VDDXOK asserted to PWR_EN driven high 30 ns

Tvi PWR_EN to VDDI stable 20 ms

Tvi

Tpen

Tvo

VDDX

VDDXOK

PWR_EN

VDDI

AMD Alchemy™ Au1000™ Processor Data Book 247

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11.5.2 Hardware Reset Timing

Figure 11-14. Hardware Reset Sequence

Table 11-18. Hardware Reset Timing Parameters

Parameter Description Min Typ Max

Tvxr VDDXOK asserted to RESETIN# de-asserted 0 ns System

Dependent

Tvl VDDXOK low time 1 µs

Trstl RESETIN# low time 1 µs

Tvro RESETIN# to RESETOUT# delay

MAX = max[750 ns, 170 ms - Tvxr]

600 ns See

Description

Trocs RESETOUT# to RCS0#/SDCS0# asserted. 135 ns 1 µs

Tvro

Tvxr

VDDXOK

RESETIN#

RESETOUT#

Tvl

Trstl

Trocs

RCS0#/SDCS0#

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11.5.3 Runtime Reset Timing

Figure 11-15. Runtime Reset Sequence

Table 11-19. Runtime Reset Timing Parameters

Parameter Description Min Typ Max

Trstl RESETIN# low time 1 µs

Trof RESETIN# falling to RESETOUT# falling

Max: 25 ns + (0.5 * (CPU Clock/2))

See

Description

Tror RESETIN# rising to RESETOUT# rising

Max: 25 ns + (0.5 * (CPU Clock/2)) + (120 * CPU Clock)

120 CPU

clocks

See

Description

Trocs RESETOUT# to RCS0#/SDCS0# asserted. Note that the

timing values shown assume a 400 MHz CPU clock.

65 ns 500 ns

Trof

Trstl

VDDX (at nominal voltage)

VDDXOK (asserted high)

WR_EN (remains asserted)

VDDI (at nominal voltage)

RESETIN#

RESETOUT# Tror

Troc s

RCS0#/SDCS0#

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Electrical and Thermal Specifications 30360E

11.6 Asynchronous Signals

GPIO - The GPIO signals are driven by software. Note, however, when GPIO signals are used as inputs, there are timing

requirements to ensure signal state changes are recognized cleanly; see Section 11.4.3, "GPIO Input Timing Require-

ments".

UART - All UART signals are asynchronous to other external signals.

USB- All USB signals are asynchronous to other external signals. The USB protocol should be followed for appropriate

operation.

11.7 External Clock Specifications

The EXTCLK[1:0] external clocks have a maximum frequency rating of (Fmax / 16), where Fmax is the maximum frequency

rating for the part. Table 11-20 provides the EXTCLK[1:0] specifications.

Table 11-20. External Clock EXTCLK[1:0] Specifications

Characteristic

266 MHz 400 MHz 500 MHz

UnitMin Max Min Max Min Max

Frequency 16.63 25 31.25 MHz

Frequency jitter 4 4 4 %

Duty cycle 40 60 40 60 40 60 %

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11.8 Crystal Specifications

Note that load capacitors for the external oscillators are integrated into the Au1000 processor so no external circuitry is

required when using the specified crystal. For design layout considerations concerning the crystals, see Section 11.9.1,

Crystal Layout.

Table 11-21 provides the specification for the parallel resonant 12 MHz crystal to be placed between XTI12 and XTO12 and

Table 11-22 provides the specification for the parallel resonant 32 kHz crystal to be placed between XTI32 and XTO32.

Table 11-21. 12 MHz Crystal Specification

Specification Min Typ Max Unit

Resonant Frequency 11 12 15 MHz

Frequency Stability ±100 ppm

Motional Resistance 60 ohms

Shunt Capacitance <5 7 pF

Load Capacitance (Note 1)

Note 1. This capacitance is integrated on the Au1000.

81220pF

Drive Level 100 µW

Crystal Type AT Cut

Table 11-22. 32.768 kHz Crystal Specification

Specification Min Typ Max Unit

Resonant Frequency 32.768 kHz

Equivalent Series Resistance 50k Ohms

Shunt Capacitance 1.5 2.0 pF

Load Capacitance (Note 1)

Note 1. This capacitance is integrated on the Au1000.

612pF

Motional Capacitance 3 4 fF

Drive Level 1µW

Quality Factor 40k

Crystal Type Tuning Fork

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11.9 System Design Considerations

This section provides information for system-level design issues.

11.9.1 Crystal Layout

The crystal layouts are critical. Without using vias, place traces directly over a ground plane on the top layer with keep-outs

on all surrounding sides. Trace lengths should be less than 0.5 inches, and trace widths should be set to the minimum sig-

nal trace width for the design. Be sure not to allow other signals to come within 0.025 inches of these sensitive analog sig-

nals.

11.9.2 Decoupling Recommendations

This section provides recommendations for minimizing noise in a system. Note that specific decoupling requirements are

system dependent.

To filter noise on the power supplies, VDDX and VDDI, as well as XPWR12 and XPWR32, should be bypassed to ground

using 10 µF capacitors: For each of the four sides of the package, place a capacitor within 0.5 inches.

To filter high-frequency noise, capacitors in the 10 nF range should be placed under the package:

•For minimal high-frequency decoupling, use six to eight 10 nF capacitors.

•For systems requiring a broader spectrum of high-frequency noise be filtered, use four 15 nF and four 6.8 nF capacitors.

252 AMD Alchemy™ Au1000™ Processor Data Book

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Packaging, Pin Assignment and Ordering Information 30360E

12.0Packaging, Pin Assignment

and Ordering Information

This chapter provides information about the Au1000 processor package and pinout, as well as providing ordering informa-

tion. The contents of the chapter are organized as follows:

•The package dimensions are shown in Figure 12-1 "Package Dimensions" on page 254. The Au1000 is packaged in a

324-pin LF-PBGA device.

•Table 12-2 "Connection Diagram — Top View" on page 256 (and continued on page 257) is the connection diagram

showing the pin and signal placement on the package. For pins that provide multiple signal functions, the default signal is

shown first followed by the alternate signal in parentheses. Note that the black square in the upper-left hand corner indi-

cates where the device is keyed.

•The pin assignment list sorted by pin number is Table 12-1 on page 258

•The pin assignment list sorted alphabetically by default signal is Table 12-2 on page 262.

•The pin assignment listing for the alternate signals is Table 12-3 on page 265 (alphabetically sorted by alternate signal)

•Ordering information is supplied on page 266.

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12.1 Mechanical Package

Figure 12-1. Package Dimensions

TOP VIEW

SIDE VIEW

PIN 1 I.D.

DETAIL K

NOTES

1. DIMENSIONING AND TOLERANCING PER ASME Y14.5M-1994 .

2. ALL DIMENSIONS ARE IN MILLIMETERS .

3. BALL POSITION DESIGNATION PER JESD 95-1, SPP-010.

4. BALL DIAMETER IS MEASURED AT ITS MAXIMUM DIMENSION IN A

PLANE PARALLEL TO DATUM C.

5. THIS PACKAGE MEETS JEDEC OUTLINE MO-192 REV E, VARIATION

DAJ-1, WITH THE EXCEPTION OF THE BALL DIAMETER SIZE

TOLERANCE AND COPLANARITY.

AMD Alchemy™ Au1000™ Processor Data Book 255

Packaging, Pin Assignment and Ordering Information 30360E

Figure 12-1. Package Dimensions (Continued)

Ø0.10 M C

Ø0.25 M C A B

BOTTOM VIEW

1.0 A1 CORNER

1.0

324 x Ø 0.5 +/-0.1

0.5

0.15 C

0.10 C

0.25

MIN

1.50

MAX

0.87

MIN

SEATING PLANE

DETAIL K

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12.2 Pin Assignments.

Figure 12-2. Connection Diagram — Top View

1 2 3 4 5 6 7 8 9 10 11 12

AS0DOUT

(GPIO[16]) U2RXD S0CLK

(GPIO[17])

I2SDIO

(GPIO[29])

ACSYNC

(S1DOUT) N0RXD1 N0RXD2 U0TXD

(GPIO[20])

U2TXD

(GPIO[22]) N0RXDV N0TXEN N1TXCLK

BUSBH1M USBDM

(USBH0M) U1RXD N0TXCLK ACBCLK

(S1DIN) N0RXD0 I2SCLK

(GPIO[30])

I2SWORD

(GPIO[31])

U1TXD

(GPIO[21]) N0RXCLK N0COL N0TXD1

CGPIO[12]

(U3RI) TCK USBH1P S0DEN

(GPIO[18])

IRDATX

(GPIO[19]) N0CRS ACRST#

(S1DEN)

ACDO

(S1CLK) N0RXD3 U3TXD

(GPIO[23]) N0TXD0 N0TXD2

DTDI GPIO[11]

(U3DCD) U0RXD USBDP

(USBH0P) U3RXD ACDI VDDX VDDX VDDX VDDI VDDI VDDI

ETDO GPIO[9]

(U3CTS)

GPIO[10]

(U3DSR) IRDARX

FRCS2# RCS3# GPIO[8]

(I2SDI) S0DIN

GROE# RCS0# RCS1# VDDX

HRBEN2# RBEN3# RWE# VDDX

JRAD31 RBEN0# RBEN1# VDDX VSS VSS VSS VSS

KRAD28 RAD29 RAD30 VDDI VSS VSS VSS VSS

LRAD25 RAD27 RAD26 VDDI VSS VSS VSS VSS

MRAD23 RAD24 RAD22 VDDI VSS VSS VSS VSS

NRAD21 RAD20 RAD18 VDDX VSS VSS VSS VSS

PRAD19 RAD17 RAD15 VDDX VSS VSS VSS VSS

RRAD16 RAD14 RAD10 VDDX

TRAD13 RAD12 RAD7 VDDX

URAD11 RAD9 RAD4 RAD0

VRAD8 RAD6 RAD2 RD23

WRAD5 RAD3 RD30 RD22 RD19 VDDX VDDX VDDX VDDI LCLK VDDI VDDI

YRAD1 RD31 RD26 RD20 RD16 RD13 RD10 RD7 RD3 LWR1# LRD1# PCE1#

AA RD29 RD27 RD25 RD18 RD15 RD12 RD9 RD6 RD4 RD0 LWAIT# LRD0#

AB RD28 RD24 RD21 RD17 RD14 RD11 RD8 RD5 RD2 RD1 EWAIT# LWR0#

1 2 3 4 5 6 7 8 9 10 11 12

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Figure 12-2. Connection Diagram — Top View (Continued)

13 14 15 16 17 18 19 20 21 22

N0TXD3 N1RXD0 N1RXD1 N0MDIO GPIO[15]

(IRFIRSEL)

N1TXEN

(GPIO[24])

N1TXD3

(GPIO[28]) SDD0 SDD3 SDD5 A

N1CRS N0MDC GPIO[14]

(U3DTR) N1RXD3 N1TXD0

(GPIO[25]) N1RXDV N1MDC SDD1 SDD4 SDD6 B

GPIO[13]

(U3RTS) N1RXD2 N1RXCLK N1TXD2

(GPIO[27])

N1TXD1

(GPIO[26]) N1COL N1MDIO SDD2 SDD10 SDD11 C

VDDI VDDX VDDX VDDX SDD9 SDD8 SDD7 SDD12 SDD13 SDD14 D

VDDX SDD15 SDD16 SDD17 E

VDDX SDD18 SDD19 SDD20 F

VDDX SDD21 SDD22 SDD23 G

VDDI SDD24 SDD25 SDD26 H

VSS VSS VDDI SDD27 SDD28 SDD29 J

VSS VSS SDCLK0 SDD30 SDD31 SDCS0# K

VSS VSS SDCLK1 SDCS1# SDCS2# SDWE# L

VSS VSS SDCLK2 SDCAS# SDCKE SDRAS# M

VSS VSS VDDI SDQM2# SDQM1# SDQM0# N

VSS VSS VDDX SDBA1 SDBA0 SDQM3# P

VDDX SDA2 SDA1 SDA0 R

VDDX SDA5 SDA4 SDA3 T

VDDX SDA8 SDA7 SDA6 U

SDA12 SDA11 SDA10 SDA9 V

GPIO[7] GPIO[6]

(SMROMCKE) VDDX VDDX VDDX ROMSIZE ROMSEL TMS VDDXOK RESETOUT# W

PWE# PIOR# GPIO[5]

(DMA_REQ1) TC1 PWR_EN GPIO[0] XAGND12 XPWR12 TESTEN TRST# Y

PWAIT# POE# TC3 TC2 GPIO[3]

(EXTCLK1) TC0 GPIO[1] RESETIN# XAGND32 XPWR32 AA

PCE2# PREG# PIOS16# PIOW# GPIO[4]

(DMA_REQ0)

GPIO[2]

(EXTCLK0) XTI12 XTO12 XTI32 XTO32 AB

13 14 15 16 17 18 19 20 21 22

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Table 12-1. Pin Assignment — Sorted by Pin Number

Pin Number Default Signal Alternate Signal

A1 S0DOUT GPIO[16]

A2 U2RXD

A3 S0CLK GPIO[17]

A4 I2SDIO GPIO[29]

A5 ACSYNC S1DOUT

A6 N0RXD1

A7 N0RXD2

A8 U0TXD GPIO[20]

A9 U2TXD GPIO[22]

A10 N0RXDV

A11 N0TXEN

A12 N1TXCLK

A13 N0TXD3

A14 N1RXD0

A15 N1RXD1

A16 N0MDIO

A17 GPIO[15] IRFIRSEL

A18 N1TXEN GPIO[24]

A19 N1TXD3 GPIO[28]

A20 SDD0

A21 SDD3

A22 SDD5

B1 USBH1M

B2 USBDM USBH0M

B3 U1RXD

B4 N0TXCLK

B5 ACBCLK S1DIN

B6 N0RXD0

B7 I2SCLK GPIO[30]

B8 I2SWORD GPIO[31]

B9 U1TXD GPIO[21]

B10 N0RXCLK

B11 N0COL

B12 N0TXD1

B13 N1CRS

B14 N0MDC

B15 GPIO[14] U3DTR

B16 N1RXD3

B17 N1TXD0 GPIO[25]

B18 N1RXDV

B19 N1MDC

B20 SDD1

B21 SDD4

B22 SDD6

C1 GPIO[12] U3RI

C2 TCK

C3 USBH1P

C4 S0DEN GPIO[18]

C5 IRDATX GPIO[19]

C6 N0CRS

C7 ACRST# S1DEN

C8 ACDO S1CLK

C9 N0RXD3

C10 U3TXD GPIO[23]

C11 N0TXD0

C12 N0TXD2

C13 GPIO[13] U3RTS

C14 N1RXD2

C15 N1RXCLK

C16 N1TXD2 GPIO[27]

C17 N1TXD1 GPIO[26]

C18 N1COL

C19 N1MDIO

C20 SDD2

C21 SDD10

C22 SDD11

D1 TDI

D2 GPIO[11] U3DCD

D3 U0RXD

D4 USBDP USBH0P

D5 U3RXD

D6 ACDI

D7 VDDX

D8 VDDX

D9 VDDX

D10 VDDI

D11 VDDI

D12 VDDI

D13 VDDI

D14 VDDX

D15 VDDX

D16 VDDX

D17 SDD9

D18 SDD8

D19 SDD7

D20 SDD12

D21 SDD13

D22 SDD14

E1 TDO

E2 GPIO[9] U3CTS

E3 GPIO[10] U3DSR

E4 IRDARX

E19 VDDX

E20 SDD15

E21 SDD16

Pin Number Default Signal Alternate Signal

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Packaging, Pin Assignment and Ordering Information 30360E

E22 SDD17

F1 RCS2#

F2 RCS3#

F3 GPIO[8] I2SDI

F4 S0DIN

F19 VDDX

F20 SDD18

F21 SDD19

F22 SDD20

G1 ROE#

G2 RCS0#

G3 RCS1#

G4 VDDX

G19 VDDX

G20 SDD21

G21 SDD22

G22 SDD23

H1 RBEN2#

H2 RBEN3#

H3 RWE#

H4 VDDX

H19 VDDI

H20 SDD24

H21 SDD25

H22 SDD26

J1 RAD31

J2 RBEN0#

J3 RBEN1#

J4 VDDX

J9 VSS

J10 VSS

J11 VSS

J12 VSS

J13 VSS

J14 VSS

J19 VDDI

J20 SDD27

J21 SDD28

J22 SDD29

K1 RAD28

K2 RAD29

K3 RAD30

K4 VDDI

K9 VSS

K10 VSS

K11 VSS

Pin Number Default Signal Alternate Signal

K12 VSS

K13 VSS

K14 VSS

K19 SDCLK0

K20 SDD30

K21 SDD31

K22 SDCS0#

L1 RAD25

L2 RAD27

L3 RAD26

L4 VDDI

L9 VSS

L10 VSS

L11 VSS

L12 VSS

L13 VSS

L14 VSS

L19 SDCLK1

L20 SDCS1#

L21 SDCS2#

L22 SDWE#

M1 RAD23

M2 RAD24

M3 RAD22

M4 VDDI

M9 VSS

M10 VSS

M11 VSS

M12 VSS

M13 VSS

M14 VSS

M19 SDCLK2

M20 SDCAS#

M21 SDCKE

M22 SDRAS#

N1 RAD21

N2 RAD20

N3 RAD18

N4 VDDX

N9 VSS

N10 VSS

N11 VSS

N12 VSS

N13 VSS

N14 VSS

Pin Number Default Signal Alternate Signal

Table 12-1. Pin Assignment — Sorted by Pin Number (Continued)

260 AMD Alchemy™ Au1000™ Processor Data Book

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30360E

N19 VDDI

N20 SDQM2#

N21 SDQM1#

N22 SDQM0#

P1 RAD19

P2 RAD17

P3 RAD15

P4 VDDX

P9 VSS

P10 VSS

P11 VSS

P12 VSS

P13 VSS

P14 VSS

P19 VDDX

P20 SDBA1

P21 SDBA0

P22 SDQM3#

R1 RAD16

R2 RAD14

R3 RAD10

R4 VDDX

R19 VDDX

R20 SDA2

R21 SDA1

R22 SDA0

T1 RAD13

T2 RAD12

T3 RAD7

T4 VDDX

T19 VDDX

T20 SDA5

T21 SDA4

T22 SDA3

U1 RAD11

U2 RAD9

U3 RAD4

U4 RAD0

U19 VDDX

U20 SDA8

U21 SDA7

U22 SDA6

V1 RAD8

V2 RAD6

V3 RAD2

V4 RD23

V19 SDA12

Pin Number Default Signal Alternate Signal

V20 SDA11

V21 SDA10

V22 SDA9

W1 RAD5

W2 RAD3

W3 RD30

W4 RD22

W5 RD19

W6 VDDX

W7 VDDX

W8 VDDX

W9 VDDI

W10 LCLK

W11 VDDI

W12 VDDI

W13 GPIO[7]

W14 GPIO[6] SMROMCKE

W15 VDDX

W16 VDDX

W17 VDDX

W18 ROMSIZE

W19 ROMSEL

W20 TMS

W21 VDDXOK

W22 RESETOUT#

Y1 RAD1

Y2 RD31

Y3 RD26

Y4 RD20

Y5 RD16

Y6 RD13

Y7 RD10

Y8 RD7

Y9 RD3

Y10 LWR1#

Y11 LRD1#

Y12 PCE1#

Y13 PWE#

Y14 PIOR#

Y15 GPIO[5] DMA_REQ1

Y16 TC1

Y17 PWR_EN

Y18 GPIO[0]

Y19 XAGND12

Y20 XPWR12

Y21 TESTEN

Y22 TRST#

Pin Number Default Signal Alternate Signal

Table 12-1. Pin Assignment — Sorted by Pin Number (Continued)

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AA1 RD29

AA2 RD27

AA3 RD25

AA4 RD18

AA5 RD15

AA6 RD12

AA7 RD9

AA8 RD6

AA9 RD4

AA10 RD0

AA11 LWAIT#

AA12 LRD0#

AA13 PWAIT#

AA14 POE#

AA15 TC3

AA16 TC2

AA17 GPIO[3] EXTCLK1

AA18 TC0

AA19 GPIO[1]

AA20 RESETIN#

AA21 XAGND32

AA22 XPWR32

Pin Number Default Signal Alternate Signal

AB1 RD28

AB2 RD24

AB3 RD21

AB4 RD17

AB5 RD14

AB6 RD11

AB7 RD8

AB8 RD5

AB9 RD2

AB10 RD1

AB11 EWAIT#

AB12 LWR0#

AB13 PCE2#

AB14 PREG#

AB15 PIOS16

AB16 PIOW#

AB17 GPIO[4] DMA_REQ0

AB18 GPIO[2] EXTCLK0

AB19 XTI12

AB20 XTO12

AB21 XTI32

AB22 XTO32

Pin Number Default Signal Alternate Signal

Table 12-1. Pin Assignment — Sorted by Pin Number (Continued)

262 AMD Alchemy™ Au1000™ Processor Data Book

Packaging, Pin Assignment and Ordering Information

30360E

Table 12-2. Pin Assignment — Sorted Alphabetically by Default Signal

Default Signal Alternate Signal Pin Number

ACBCLK S1DIN B5

ACDI D6

ACDO S1CLK C8

ACRST# S1DEN C7

ACSYNC S1DOUT A5

EWAIT# AB11

GPIO[0] Y18

GPIO[1] AA19

GPIO[2] EXTCLK0 AB18

GPIO[3] EXTCLK1 AA17

GPIO[4] DMA_REQ0 AB17

GPIO[5] DMA_REQ1 Y15

GPIO[6] SMROMCKE W14

GPIO[7] W13

GPIO[8] I2SDI F3

GPIO[9] U3CTS E2

GPIO[10] U3DSR E3

GPIO[11] U3DCD D2

GPIO[12] U3RI C1

GPIO[13] U3RTS C13

GPIO[14] U3DTR B15

GPIO[15] IRFIRSEL A17

I2SCLK GPIO[30] B7

I2SDIO GPIO[29] A4

I2SWORD GPIO[31] B8

IRDARX E4

IRDATX GPIO[19] C5

LCLK W10

LRD0# AA12

LRD1# Y11

LWAIT# AA11

LWR0# AB12

LWR1# Y10

N0COL B11

N0CRS C6

N0MDC B14

N0MDIO A16

N0RXCLK B10

N0RXD0 B6

N0RXD1 A6

N0RXD2 A7

N0RXD3 C9

N0RXDV A10

N0TXCLK B4

N0TXD0 C11

N0TXD1 B12

N0TXD2 C12

N0TXD3 A13

N0TXEN A11

N1COL C18

N1CRS B13

N1MDC B19

N1MDIO C19

N1RXCLK C15

N1RXD0 A14

N1RXD1 A15

N1RXD2 C14

N1RXD3 B16

N1RXDV B18

N1TXCLK A12

N1TXD0 GPIO[25] B17

N1TXD1 GPIO[26] C17

N1TXD2 GPIO[27] C16

N1TXD3 GPIO[28] A19

N1TXEN GPIO[24] A18

PCE1# Y12

PCE2# AB13

PIOR# Y14

PIOS16# AB15

PIOW# AB16

POE# AA14

PREG# AB14

PWAIT# AA13

PWE# Y13

PWR_EN Y17

RAD0 U4

RAD1 Y1

RAD2 V3

RAD3 W2

RAD4 U3

RAD5 W1

RAD6 V2

RAD7 T3

RAD8 V1

RAD9 U2

RAD10 R3

RAD11 U1

RAD12 T2

RAD13 T1

RAD14 R2

RAD15 P3

RAD16 R1

RAD17 P2

RAD18 N3

RAD19 P1

RAD20 N2

Default Signal Alternate Signal Pin Number

AMD Alchemy™ Au1000™ Processor Data Book 263

Packaging, Pin Assignment and Ordering Information 30360E

RAD21 N1

RAD22 M3

RAD23 M1

RAD24 M2

RAD25 L1

RAD26 L3

RAD27 L2

RAD28 K1

RAD29 K2

RAD30 K3

RAD31 J1

RBEN0# J2

RBEN1# J3

RBEN2# H1

RBEN3# H2

RCS0# G2

RCS1# G3

RCS2# F1

RCS3# F2

RD0 AA10

RD1 AB10

RD2 AB9

RD3 Y9

RD4 AA9

RD5 AB8

RD6 AA8

RD7 Y8

RD8 AB7

RD9 AA7

RD10 Y7

RD11 AB6

RD12 AA6

RD13 Y6

RD14 AB5

RD15 AA5

RD16 Y5

RD17 AB4

RD18 AA4

RD19 W5

RD20 Y4

RD21 AB3

RD22 W4

RD23 V4

RD24 AB2

RD25 AA3

RD26 Y3

RD27 AA2

RD28 AB1

Default Signal Alternate Signal Pin Number

RD29 AA1

RD30 W3

RD31 Y2

RESETIN# AA20

RESETOUT# W22

ROE# G1

ROMSEL W19

ROMSIZE W18

RWE# H3

S0CLK GPIO[17] A3

S0DEN GPIO[18] C4

S0DIN F4

S0DOUT GPIO[16] A1

SDA0 R22

SDA1 R21

SDA2 R20

SDA3 T22

SDA4 T21

SDA5 T20

SDA6 U22

SDA7 U21

SDA8 U20

SDA9 V22

SDA10 V21

SDA11 V20

SDA12 V19

SDBA0 P21

SDBA1 P20

SDCAS# M20

SDCKE M21

SDCLK0 K19

SDCLK1 L19

SDCLK2 M19

SDCS0# K22

SDCS1# L20

SDCS2# L21

SDD0 A20

SDD1 B20

SDD2 C20

SDD3 A21

SDD4 B21

SDD5 A22

SDD6 B22

SDD7 D19

SDD8 D18

SDD9 D17

SDD10 C21

SDD11 C22

Default Signal Alternate Signal Pin Number

Table 12-2. Pin Assignment — Sorted Alphabetically by Default Signal (Continued)

264 AMD Alchemy™ Au1000™ Processor Data Book

Packaging, Pin Assignment and Ordering Information

30360E

SDD12 D20

SDD13 D21

SDD14 D22

SDD15 E20

SDD16 E21

SDD17 E22

SDD18 F20

SDD19 F21

SDD20 F22

SDD21 G20

SDD22 G21

SDD23 G22

SDD24 H20

SDD25 H21

SDD26 H22

SDD27 J20

SDD28 J21

SDD29 J22

SDD30 K20

SDD31 K21

SDQM0# N22

SDQM1# N21

SDQM2# N20

SDQM3# P22

SDRAS# M22

SDWE# L22

TC0 AA18

TC1 Y16

TC2 AA16

TC3 AA15

TCK C2

TDI D1

TDO E1

TESTEN Y21

TMS W20

TRST# Y22

U0RXD D3

U0TXD GPIO[20] A8

U1RXD B3

Default Signal Alternate Signal Pin Number

U1TXD GPIO[21] B9

U2RXD A2

U2TXD GPIO[22] A9

U3RXD D5

U3TXD GPIO[23] C10

USBDM USBH0M B2

USBDP USBH0P D4

USBH1M B1

USBH1P C3

VDDI

(Total of 13)

D10, D11, D12,

D13, H19, J19,

K4, L4, M4, N19,

W9, W11, W12

VDDX

(Total of 26)

D7, D8, D9,

D14, D15, D16,

E19, F19, G4,

G19, H4, J4, N4,

P4, P19, R4,

R19, T4, T19,

U19, W6, W7,

W8, W15, W16,

W17

VDDXOK W21

VSS

(Total of 36)

J9, J10, J11,

J12, J13, J14,

K9, K10, K11,

K12, K13, K14,

L9, L10, L11,

L12, L13, L14,

M9, M10, M11,

M12, M13, M14,

N9, N10, N11,

N12, N13, N14,

P9, P10, P11,

P12, P13, P14

XAGND12 Y19

XAGND32 AA21

XPWR12 Y20

XPWR32 AA22

XTI12 AB19

XTI32 AB21

XTO12 AB20

XTO32 AB22

Default Signal Alternate Signal Pin Number

Table 12-2. Pin Assignment — Sorted Alphabetically by Default Signal (Continued)

AMD Alchemy™ Au1000™ Processor Data Book 265

Packaging, Pin Assignment and Ordering Information 30360E

Table 12-3. Pin Assignment — Alternate Signals Sorted Alphabetically

Alternate Signal Default Signal Pin Number

DMA_REQ0 GPIO[4] AB17

DMA_REQ1 GPIO[5] Y15

EXTCLK0 GPIO[2] AB18

EXTCLK1 GPIO[3] AA17

GPIO[16] S0DOUT A1

GPIO[17] S0CLK A3

GPIO[18] S0DEN C4

GPIO[19] IRDATX C5

GPIO[20] U0TXD A8

GPIO[21] U1TXD B9

GPIO[22] U2TXD A9

GPIO[23] U3TXD C10

GPIO[24] N1TXEN A18

GPIO[25] N1TXD0 B17

GPIO[26] N1TXD1 C17

GPIO[27] N1TXD2 C16

GPIO[28] N1TXD3 A19

GPIO[29] I2SDIO A4

GPIO[30] I2SCLK B7

GPIO[31] I2SWORD B8

I2SDI GPIO[8] F3

IRFIRSEL GPIO[15] A17

S1CLK ACDO C8

S1DEN ACRST# C7

S1DIN ACBCLK B5

S1DOUT ACSYNC A5

SMROMCKE GPIO[6] W14

U3CTS GPIO[9] E2

U3DCD GPIO[11] D2

U3DSR GPIO[10] E3

U3DTR GPIO[14] B15

U3RI GPIO[12] C1

U3RTS GPIO[13] C13

USBH0M USBDM B2

USBH0P USBDP D4

266 AMD Alchemy™ Au1000™ Processor Data Book

Packaging, Pin Assignment and Ordering Information

30360E

12.3 Ordering Information

Ordering information for the AMD Alchemy™ Au1000™ processor is contained in this section. The ordering part number

(OPN) is formed by a combination of elements. An example of the OPN is shown in Figure 12-3. Valid OPN combinations

are provided in Table 12-4.

Figure 12-3. OPN Example

Table 12-4. Valid OPN Combinations

Device Number Speed Option Package Type Temperature Range

Au1000 266 MC C

Au1000 400 MC C

Au1000 500 MC C

Note: Consult your local AMD sales office to confirm availability of specific valid combinations and to check on newly

released combinations possibly not listed.

Au1000 333 MC

OPN (Note)

Note: Spaces are added to the ordering number shown above for viewing clarity only.

Temperature Range

C = Commercial (TCASE = 0°C to +85°C)

D = Commercial Lead-Free (TCASE = 0°C to +85°C)

Package Type

MC = Low profile PBGA package (1.0 mm ball-pitch)

Speed Option

266 = 266 MHz

400 = 400 MHz

500 = 500 MHz

Device Number

I = Industrial (TCASE = -40°C to +100°C)

F = Industrial Lead-Free (TCASE = -40°C to +100°C)

AMD Alchemy™ Au1000™ Processor Data Book 267

Appendix A: Support Documentation 30360E

Appendix ASupport Documentation

A.1 Memory Map

The peripheral devices on the Au1000 processor contain memory-mapped registers visible to software. Table A-1 contains

the memory map for the peripheral devices and physical memory. The addresses are 36 bits wide.

The Au1000 processor system bus devices are mapped at the addresses based at 0x0 1400 0000. See Table A-2 for com-

plete addresses.

Table A-1. Basic Au1000™ Processor Physical Memory Map

Start Address End Address Size (MB) Function

0x0 0000 0000 0x0 0FFF FFFF 256 Memory KSEG 0/1

0x0 1000 0000 0x0 11FF FFFF 32 I/O Devices on Peripheral Bus

0x0 1200 0000 0x0 13FF FFFF 32 Reserved

0x0 1400 0000 0x0 17FF FFFF 64 I/O Devices on System Bus

0x0 1800 0000 0x0 1FFF FFFF 128 Memory Mapped. 0x0 1FC0 0000 must contain the boot

vector so this is typically where Flash or ROM is located.

0x0 2000 0000 0x0 7FFF FFFF 1536 Memory Mapped

0x0 8000 0000 0x0 EFFF FFFF 1792 Memory Mapped. Currently this space is memory

mapped, but it should be considered reserved for future

use.

0x0 F000 0000 0x0 FFFF FFFF 256 Debug Probe

0x1 0000 0000 0xC FFFF FFFF 4096 * 12 Reserved

0xD 0000 0000 0xD FFFF FFFF 4096 I/O Device

0xE 0000 0000 0xE FFFF FFFF 4096 External LCD Controller Interface

0xF 0000 0000 0xF FFFF FFFF 4096 PCMCIA Interface

Table A-2. System Bus Devices Physical Memory Map

Start Address End Address Size Function

0x0 1400 0000 0x0 14000 FFF 4 KB SDRAM Memory Controller

0x0 1400 1000 0x0 1400 1FFF 4 KB SRAM/FLASH Memory Controller

0x0 1400 2000 0x0 1400 2FFF 4 KB DMA

0x0 1400 4000 0x0 1400 4FFF 4 KB Ethernet DMA

268 AMD Alchemy™ Au1000™ Processor Data Book

Appendix A: Memory Map

30360E

The Au1000 processor peripheral bus devices are based at 0x0 1100 0000. The individual memory spaces of the devices

are defined in Table A-3.

Table A-3. Peripheral Bus Devices Physical Memory Map

Start Address End Address Size Function

0x0 1000 0000 0x0 100F FFFF 1 MB AC97 Controller

0x0 1010 0000 0x0 101F FFFF 1 MB USB Host

0x0 1020 0000 0x0 102F FFFF 1 MB USB Device

0x0 1030 0000 0x0 103F FFFF 1 MB IrDA

0x0 1040 0000 0x0 104F FFFF 1 MB Interrupt Controller 0

0x0 1050 0000 0x0 105F FFFF 1 MB Ethernet MAC

0x0 1060 0000 0x0 10FF FFFF 10 MB

0x0 1100 0000 0x0 110F FFFF 1 MB I2S

0x0 1110 0000 0x0 111F FFFF 1 MB UART0

0x0 1120 0000 0x0 112F FFFF 1 MB UART1

0x0 1130 0000 0x0 113F FFFF 1 MB UART2

0x0 1140 0000 0x0 114F FFFF 1 MB UART3

0x0 1150 0000 0x0 115F FFFF 1 MB

0x0 1160 0000 0x0 116F FFFF 1 MB SSI

0x0 1170 0000 0x0 117F FFFF 1 MB

0x0 1180 0000 0x0 118F FFFF 1 MB Interrupt Controller 1

0x0 1190 0000 0x0 119F FFFF 1 MB System Control. RTC, TOY, Timers, Primary GPIO,

Power Management

AMD Alchemy™ Au1000™ Processor Data Book 269

Appendix A: Memory Map 30360E

A.1.1 Device Memory Map

Table A-4 lists all of the devices that are memory mapped to the Au1000 processor core. These devices are all mapped

within KSEG1 (non-cached, non-TLB). All 32-bit addresses are translated into 36-bit addresses by changing bits 31:29 to

zero and adding bits 35:32 which are set to zero.

Table A-4. Device Memory Map

KSEG1

Address

Physical

Address

AC97 Controller - Section 6.1.1 on page 87

ac97_config 0xB000 0000 0x0 1000 0000

ac97_status 0xB000 0004 0x0 1000 0004

ac97_data 0xB000 0008 0x0 1000 0008

ac97_cmmd 0xB000 000C 0x0 1000 000C

ac97_cmmdresp 0xB000 000C 0x0 1000 000C

ac97_control 0xB000 0010 0x0 1000 0010

USB Host Controller - Section 6.2 on page 93

Open HCI Register Set

Base

0xB010 0000 0x0 1010 0000

usbh_enable 0xB017 FFFC 0x0 1017 FFFC

USB Device Controller - Section 6.3 on page 95

usbd_ep0rd 0xB020 0000 0x0 1020 0000

usbd_ep0wr 0xB020 0004 0x0 1020 0004

usbd_ep1wr 0xB020 0008 0x0 1020 0008

usbd_ep2wr 0xB020 000C 0x0 1020 000c

usbd_ep3rd 0xB020 0010 0x0 1020 0010

usbd_ep4rd 0xB020 0014 0x0 1020 0014

usbd_inten 0xB020 0018 0x0 1020 0018

usbd_intstat 0xB020 001C 0x0 1020 001C

usbd_config 0xB020 0020 0x0 1020 0020

usbd_ep0cs 0xB020 0024 0x0 1020 0024

usbd_ep1cs 0xB020 0028 0x0 1020 0028

usbd_ep2cs 0xB020 002C 0x0 1020 002C

usbd_ep3cs 0xB020 0030 0x0 1020 0030

usbd_ep4cs 0xB020 0034 0x0 1020 0034

usbd_ep0rdstat 0xB020 0040 0x0 1020 0040

usbd_ep0wrstat 0xB020 0044 0x0 1020 0044

usbd_ep1wrstat 0xB020 0048 0x0 1020 0048

usbd_ep2wrstat 0xB020 004c 0x0 1020 004c

usbd_ep3rdstat 0xB020 0050 0x0 1020 0050

usbd_ep4rdstat 0xB020 0054 0x0 1020 0054

usbd_enable 0xB020 0058 0x0 1020 0058

IrDA Controller - Section 6.4.1 on page 107

ir_rngptrstat 0xB030 0000 0x0 1030 0000

ir_rngbsadrh 0xB030 0004 0x0 1030 0004

ir_rngbsadrl 0xB030 0008 0x0 1030 0008

ir_ringsize 0xB030 000C 0x0 1030 000C

ir_rngprompt 0xB030 0010 0x0 1030 0010

ir_rngadrcmp 0xB030 0014 0x0 1030 0014

ir_intclear 0xB030 0018 0x0 1030 0018

ir_config1 0xB030 0020 0x0 1030 0020

ir_sirflags 0xB030 0024 0x0 1030 0024

ir_statusen 0xB030 0028 0x0 1030 0028

ir_rdphycfg 0xB030 002C 0x0 1030 002C

ir_wrphycfg 0xB030 0030 0x0 1030 0030

ir_maxpktlen 0xB030 0034 0x0 1030 0034

ir_rxbytecnt 0xB030 0038 0x0 1030 0038

ir_config2 0xB030 003C 0x0 1030 003C

ir_enable 0xB030 0040 0x0 1030 0040

Interrupt Controller 0 - Section 5.2 on page 83

ic0_cfg0rd 0xB040 0040 0x0 1040 0040

ic0_cfg0set 0xB040 0040 0x0 1040 0040

ic0_cfg0clr 0xB040 0044 0x0 1040 0044

ic0_cfg1rd 0xB040 0048 0x0 1040 0048

ic0_cfg1set 0xB040 0048 0x0 1040 0048

ic0_cfg1clr 0xB040 004C 0x0 1040 004C

ic0_cfg2rd 0xB040 0050 0x0 1040 0050

ic0_cfg2set 0xB040 0050 0x0 1040 0050

ic0_cfg2clr 0xB040 0054 0x0 1040 0054

ic0_req0int 0xB040 0054 0x0 1040 0054

ic0_srcrd 0xB040 0058 0x0 1040 0058

ic0_srcset 0xB040 0058 0x0 1040 0058

ic0_srcclr 0xB040 005C 0x0 1040 005C

ic0_req1int 0xB040 005C 0x0 1040 005C

ic0_assignrd 0xB040 0060 0x0 1040 0060

ic0_assignset 0xB040 0060 0x0 1040 0060

ic0_assignclr 0xB040 0064 0x0 1040 0064

ic0_wakerd 0xB040 0068 0x0 1040 0068

ic0_wakeset 0xB040 006C 0x0 1040 006C

ic0_wakeclr 0xB040 0070 0x0 1040 0070

ic0_maskrd 0xB040 0070 0x0 1040 0070

ic0_maskset 0xB040 0074 0x0 1040 0074

ic0_maskclr 0xB040 0078 0x0 1040 0078

ic0_risingrd 0xB040 0078 0x0 1040 0078

ic0_risingclr 0xB040 007C 0x0 1040 007C

ic0_fallingrd 0xB040 007C 0x0 1040 007C

ic0_fallingclr 0xB040 0080 0x0 1040 0080

Ethernet Controller MAC0 - Section 6.5.2 on page 123

mac0_control 0xB050 0000 0x0 1050 0000

mac0_addrhigh 0xB050 0004 0x0 1050 0004

mac0_addrlow 0xB050 0008 0x0 1050 0008

mac0_hashhigh 0xB050 000C 0x0 1050 000C

mac0_hashlow 0xB050 0010 0x0 1050 0010

mac0_miictrl 0xB050 0014 0x0 1050 0014

mac0_miidata 0xB050 0018 0x0 1050 0018

KSEG1

Address

Physical

Address

270 AMD Alchemy™ Au1000™ Processor Data Book

Appendix A: Memory Map

30360E

mac0_flowctrl 0xB050 001C 0x0 1050 001C

mac0_vlan1 0xB050 0020 0x0 1050 0020

mac0_vlan2 0xB050 0024 0x0 1050 0024

Ethernet Controller MAC1 - Section 6.5.2 on page 123

mac1_control 0xB051 0000 0x0 1051 0000

mac1_addrhigh 0xB051 0004 0x0 1051 0004

mac1_addrlow 0xB051 0008 0x0 1051 0008

mac1_hashhigh 0xB051 000C 0x0 1051 000C

mac1_hashlow 0xB051 0010 0x0 1051 0010

mac1_miictrl 0xB051 0014 0x0 1051 0014

mac1_miidata 0xB051 0018 0x0 1051 0018

mac1_flowctrl 0xB051 001C 0x0 1051 001C

mac1_vlan1 0xB051 0020 0x0 1051 0020

mac1_vlan2 0xB051 0024 0x0 1051 0024

Ethernet Controller Enable - Section 6.5.4 on page 133

macen_mac0 0xB052 0000 0x0 1052 0000

macen_mac1 0xB052 0004 0x0 1052 0004

I2S Controller - Section 6.6.1 on page 145

i2s_data 0xB100 0000 0x0 1100 0000

i2s_config 0xB100 0004 0x0 1100 0004

i2s_enable 0xB100 0008 0x0 1100 0008

UART0 - Section 6.7.2 on page 150

uart0_rxdata 0xB110 0000 0x0 1110 0000

uart0_txdata 0xB110 0004 0x0 1110 0004

uart0_inten 0xB110 0008 0x0 1110 0008

uart0_intcause 0xB110 000C 0x0 1110 000C

uart0_fifoctrl 0xB110 0010 0x0 1110 0010

uart0_linectrl 0xB110 0014 0x0 1110 0014

— 0xB110 0018 0x0 1110 0018

uart0_linestat 0xB110 001C 0x0 1110 001C

— 0xB110 0020 0x0 1110 0020

uart0_clkdiv 0xB110 0028 0x0 1110 0028

uart0_enable 0xB110 0100 0x0 1110 0100

UART1 - Section 6.7.2 on page 150

uart1_rxdata 0xB120 0000 0x0 1120 0000

uart1_txdata 0xB120 0004 0x0 1120 0004

uart1_inten 0xB120 0008 0x0 1120 0008

uart1_intcause 0xB120 000C 0x0 1120 000C

uart1_fifoctrl 0xB120 0010 0x0 1120 0010

uart1_linectrl 0xB120 0014 0x0 1120 0014

— 0xB120 0018 0x0 1120 0018

uart1_linestat 0xB120 001C 0x0 1120 001C

— 0xB120 0020 0x0 1120 0020

uart1_clkdiv 0xB120 0028 0x0 1120 0028

uart1_enable 0xB120 0100 0x0 1120 0100

UART2 - Section 6.7.2 on page 150

uart2_rxdata 0xB130 0000 0x0 1130 0000

uart2_txdata 0xB130 0004 0x0 1130 0004

KSEG1

Address

Physical

Address

uart2_inten 0xB130 0008 0x0 1130 0008

uart2_intcause 0xB130 000C 0x0 1130 000C

uart2_fifoctrl 0xB130 0010 0x0 1130 0010

uart2_linectrl 0xB130 0014 0x0 1130 0014

— 0xB130 0018 0x0 1130 0018

uart2_linestat 0xB130 001C 0x0 1130 001C

— 0xB130 0020 0x0 1130 0020

uart2_clkdiv 0xB130 0028 0x0 1130 0028

uart2_enable 0xB130 0100 0x0 1130 0100

UART3 - Section 6.7.2 on page 150

uart3_rxdata 0xB140 0000 0x0 1140 0000

uart3_txdata 0xB140 0004 0x0 1140 0004

uart3_inten 0xB140 0008 0x0 1140 0008

uart3_intcause 0xB140 000C 0x0 1140 000C

uart3_fifoctrl 0xB140 0010 0x0 1140 0010

uart3_linectrl 0xB140 0014 0x0 1140 0014

uart3_mdmctrl 0xB140 0018 0x0 1140 0018

uart3_linestat 0xB140 001C 0x0 1140 001C

uart3_mdmstat 0xB140 0020 0x0 1140 0020

uart3_autoflow 0xB140 0024 0x0 1140 0024

uart3_clkdiv 0xB140 0028 0x0 1140 0028

uart3_enable 0xB140 0100 0x0 1140 0100

SSI0 - Section 6.8.2 on page 160

ssi0_status 0xB160 0000 0x0 1160 0000

ssi0_int 0xB160 0004 0x0 1160 0004

ssi0_inten 0xB160 0008 0x0 1160 0008

ssi0_config 0xB160 0020 0x0 1160 0020

ssi0_adata 0xB160 0024 0x0 1160 0024

ssi0_clkdiv 0xB160 0028 0x0 1160 0028

ssi0_enable 0xB160 0100 0x0 1160 0100

SSI1- Section 6.8.2 on page 160

ssi1_status 0xB168 0000 0x0 1168 0000

ssi1_int 0xB168 0004 0x0 1168 0004

ssi1_inten 0xB168 0008 0x0 1168 0008

ssi1_config 0xB168 0020 0x0 1168 0020

ssi1_adata 0xB168 0024 0x0 1168 0024

ssi1_clkdiv 0xB168 0028 0x0 1168 0028

ssi1_enable 0xB168 0100 0x0 1168 0100

Interrupt Controller 1 - Section 5.2 on page 83

ic1_cfg0rd 0xB180 0040 0x0 1180 0040

ic1_cfg0set 0xB180 0040 0x0 1180 0040

ic1_cfg0clr 0xB180 0044 0x0 1180 0044

ic1_cfg1rd 0xB180 0048 0x0 1180 0048

ic1_cfg1set 0xB180 0048 0x0 1180 0048

ic1_cfg1clr 0xB180 004C 0x0 1180 004C

ic1_cfg2rd 0xB180 0050 0x0 1180 0050

ic1_cfg2set 0xB180 0050 0x0 1180 0050

ic1_cfg2clr 0xB180 0054 0x0 1180 0054

KSEG1

Address

Physical

Address

Table A-4. Device Memory Map (Continued)

AMD Alchemy™ Au1000™ Processor Data Book 271

Appendix A: Memory Map 30360E

ic1_req0int 0xB180 0054 0x0 1180 0054

ic1_srcrd 0xB180 0058 0x0 1180 0058

ic1_srcset 0xB180 0058 0x0 1180 0058

ic1_srcclr 0xB180 005C 0x0 1180 005C

ic1_req1int 0xB180 005C 0x0 1180 005C

ic1_assignrd 0xB180 0060 0x0 1180 0060

ic1_assignset 0xB180 0060 0x0 1180 0060

ic1_assignclr 0xB180 0064 0x0 1180 0064

ic1_wakerd 0xB180 0068 0x0 1180 0068

ic1_wakeset 0xB180 006C 0x0 1180 006C

ic1_wakeclr 0xB180 0070 0x0 1180 0070

ic1_maskrd 0xB180 0070 0x0 1180 0070

ic1_maskset 0xB180 0074 0x0 1180 0074

ic1_maskclr 0xB180 0078 0x0 1180 0078

ic1_risingrd 0xB180 0078 0x0 1180 0078

ic1_risingclr 0xB180 007C 0x0 1180 007C

ic1_fallingrd 0xB180 007C 0x0 1180 007C

ic1_fallingclr 0xB180 0080 0x0 1180 0080

Clock Controller - Section 7.1.1 on page 169

sys_freqctrl0 0xB190 0020 0x0 1190 0020

sys_freqctrl1 0xB190 0024 0x0 1190 0024

sys_clksrc 0xB190 0028 0x0 1190 0028

sys_cpupll 0xB190 0060 0x0 1190 0060

sys_auxpll 0xB190 0064 0x0 1190 0064

TOY & RTC - Section 7.2.1 on page 179

sys_toytrim 0xB190 0000 0x0 1190 0000

sys_toywrite 0xB190 0004 0x0 1190 0004

sys_matchtoy0 0xB190 0008 0x0 1190 0008

sys_matchtoy1 0xB190 000C 0x0 1190 000C

sys_matchtoy2 0xB190 0010 0x0 1190 0010

sys_cntrctrl 0xB190 0014 0x0 1190 0014

sys_toyread 0xB190 0040 0x0 1190 0040

sys_rtctrim 0xB190 0044 0x0 1190 0044

sys_rtcwrite 0xB190 0048 0x0 1190 0048

sys_rtcmatch0 0xB190 004C 0x0 1190 004C

sys_rtcmatch1 0xB190 0050 0x0 1190 0050

sys_rtcmatch2 0xB190 0054 0x0 1190 0054

sys_rtcread 0xB190 0058 0x0 1190 0058

GPIO - Section 7.3.1 on page 183

sys_pinfunc 0xB190 002C 0x0 1190 002C

sys_trioutrd 0xB190 0100 0x0 1190 0100

sys_trioutclr 0xB190 0100 0x0 1190 0100

sys_outputrd 0xB190 0108 0x0 1190 0108

sys_outputset 0xB190 0108 0x0 1190 0108

sys_outputclr 0xB190 010C 0x0 1190 010C

sys_pinstaterd 0xB190 0110 0x0 1190 0110

sys_pininputen 0xB190 0110 0x0 1190 0110

KSEG1

Address

Physical

Address

Power Management - Section 7.4.4 on page 191

sys_scratch0 0xB190 0018 0x0 1190 0018

sys_scratch1 0xB190 001C 0x0 1190 001C

sys_wakemsk 0xB190 0034 0x0 1190 0034

sys_endian 0xB190 0038 0x0 1190 0038

sys_powerctrl 0xB190 003C 0x0 1190 003C

sys_wakesrc 0xB190 005C 0x0 1190 005C

sys_slppwr 0xB190 0078 0x0 1190 0078

sys_sleep 0xB190 007C 0x0 1190 007C

SDRAM Controller - Section 3.1.2 on page 45

mem_sdmode0 0xB400 0000 0x0 1400 0000

mem_sdmode1 0xB400 0004 0x0 1400 0004

mem_sdmode2 0xB400 0008 0x0 1400 0008

mem_sdaddr0 0xB400 000C 0x0 1400 000C

mem_sdaddr1 0xB400 0010 0x0 1400 0010

mem_sdaddr2 0xB400 0014 0x0 1400 0014

mem_sdrefcfg 0xB400 0018 0x0 1400 0018

mem_sdprecmd 0xB400 001C 0x0 1400 001C

mem_sdautoref 0xB400 0020 0x0 1400 0020

mem_sdwrmd0 0xB400 0024 0x0 1400 0024

mem_sdwrmd1 0xB400 0028 0x0 1400 0028

mem_sdwrmd2 0xB400 002C 0x0 1400 002C

mem_sdsleep 0xB400 0030 0x0 1400 0030

mem_sdsmcke 0xB400 0034 0x0 1400 0034

Static Bus Controller - Section 3.2.2 on page 60

mem_stcfg0 0xB400 1000 0x0 1400 1000

mem_sttime0 0xB400 1004 0x0 1400 1004

mem_staddr0 0xB400 1008 0x0 1400 1008

mem_stcfg1 0xB400 1010 0x0 1400 1010

mem_sttime1 0xB400 1014 0x0 1400 1014

mem_staddr1 0xB400 1018 0x0 1400 1018

mem_stcfg2 0xB400 1020 0x0 1400 1020

mem_sttime2 0xB400 1024 0x0 1400 1024

mem_staddr2 0xB400 1028 0x0 1400 1028

mem_stcfg3 0xB400 1030 0x0 1400 1030

mem_sttime3 0xB400 1034 0x0 1400 1034

mem_staddr3 0xB400 1038 0x0 1400 1038

DMA Controller 0 - Section 4.1 on page 73

dma0_moderead 0xB400 2000 0x0 1400 2000

dma0_modeset 0xB400 2000 0x0 1400 2000

dma0_modeclr 0xB400 2004 0x0 1400 2004

dma0_peraddr 0xB400 2008 0x0 1400 2008

dma0_buf0addr 0xB400 200C 0x0 1400 200C

dma0_buf0size 0xB400 2010 0x0 1400 2010

dma0_buf1addr 0xB400 2014 0x0 1400 2014

dma0_buf1size 0xB400 2018 0x0 1400 2018

KSEG1

Address

Physical

Address

Table A-4. Device Memory Map (Continued)

272 AMD Alchemy™ Au1000™ Processor Data Book

Appendix A: Memory Map

30360E

DMA Controller 1 - Section 4.1 on page 73

dma1_moderead 0xB400 2100 0x0 1400 2100

dma1_modeset 0xB400 2100 0x0 1400 2100

dma1_modeclr 0xB400 2104 0x0 1400 2104

dma1_peraddr 0xB400 2108 0x0 1400 2108

dma1_buf0addr 0xB400 210c 0x0 1400 210c

dma1_buf0size 0xB400 2110 0x0 1400 2110

dma1_buf1addr 0xB400 2114 0x0 1400 2114

dma1_buf1size 0xB400 2118 0x0 1400 2118

DMA Controller 2 - Section 4.1 on page 73

dma2_moderead 0xB400 2200 0x0 1400 2200

dma2_modeset 0xB400 2200 0x0 1400 2200

dma2_modeclr 0xB400 2204 0x0 1400 2204

dma2_peraddr 0xB400 2208 0x0 1400 2208

dma2_buf0addr 0xB400 220c 0x0 1400 220c

dma2_buf0size 0xB400 2210 0x0 1400 2210

dma2_buf1addr 0xB400 2214 0x0 1400 2214

dma2_buf1size 0xB400 2218 0x0 1400 2218

DMA Controller 3 - Section 4.1 on page 73

dma3_moderead 0xB400 2300 0x0 1400 2300

dma3_modeset 0xB400 2300 0x0 1400 2300

dma3_modeclr 0xB400 2304 0x0 1400 2304

dma3_peraddr 0xB400 2308 0x0 1400 2308

dma3_buf0addr 0xB400 230c 0x0 1400 230c

dma3_buf0size 0xB400 2310 0x0 1400 2310

dma3_buf1addr 0xB400 2314 0x0 1400 2314

dma3_buf1size 0xB400 2318 0x0 1400 2318

DMA Controller 4 - Section 4.1 on page 73

dma4_moderead 0xB400 2400 0x0 1400 2400

dma4_modeset 0xB400 2400 0x0 1400 2400

dma4_modeclr 0xB400 2404 0x0 1400 2404

dma4_peraddr 0xB400 2408 0x0 1400 2408

dma4_buf0addr 0xB400 240c 0x0 1400 240c

dma4_buf0size 0xB400 2410 0x0 1400 2410

dma4_buf1addr 0xB400 2414 0x0 1400 2414

dma4_buf1size 0xB400 2418 0x0 1400 2418

DMA Controller 5 - Section 4.1 on page 73

dma5_moderead 0xB400 2500 0x0 1400 2500

dma5_modeset 0xB400 2500 0x0 1400 2500

dma5_modeclr 0xB400 2504 0x0 1400 2504

dma5_peraddr 0xB400 2508 0x0 1400 2508

dma5_buf0addr 0xB400 250C 0x0 1400 250C

dma5_buf0size 0xB400 2510 0x0 1400 2510

dma5_buf1addr 0xB400 2514 0x0 1400 2514

dma5_buf1size 0xB400 2518 0x0 1400 2518

DMA Controller 6 - Section 4.1 on page 73

dma6_moderead 0xB400 2600 0x0 1400 2600

dma6_modeset 0xB400 2600 0x0 1400 2600

KSEG1

Address

Physical

Address

dma6_modeclr 0xB400 2604 0x0 1400 2604

dma6_peraddr 0xB400 2608 0x0 1400 2608

dma6_buf0addr 0xB400 260c 0x0 1400 260c

dma6_buf0size 0xB400 2610 0x0 1400 2610

dma6_buf1addr 0xB400 2614 0x0 1400 2614

dma6_buf1size 0xB400 2618 0x0 1400 2618

DMA Controller 7 - Section 4.1 on page 73

dma7_moderead 0xB400 2700 0x0 1400 2700

dma7_modeset 0xB400 2700 0x0 1400 2700

dma7_modeclr 0xB400 2704 0x0 1400 2704

dma7_peraddr 0xB400 2708 0x0 1400 2708

dma7_buf0addr 0xB400 270C 0x0 1400 270C

dma7_buf0size 0xB400 2710 0x0 1400 2710

dma7_buf1addr 0xB400 2714 0x0 1400 2714

dma7_buf1size 0xB400 2718 0x0 1400 2718

Ethernet Controller DMA Channels - Section 6.5.4 on page 133

macdma0_tx0stat 0xB400 4000 0x0 1400 4000

macdma0_tx0addr 0xB400 4004 0x0 1400 4004

macdma0_tx0len 0xB400 4008 0x0 1400 4008

macdma0_tx1stat 0xB400 4010 0x0 1400 4010

macdma0_tx1addr 0xB400 4014 0x0 1400 4014

macdma0_tx1len 0xB400 4018 0x0 1400 4018

macdma0_tx2stat 0xB400 4020 0x0 1400 4020

macdma0_tx2addr 0xB400 4024 0x0 1400 4024

macdma0_tx2len 0xB400 4028 0x0 1400 4028

macdma0_tx3stat 0xB400 4030 0x0 1400 4030

macdma0_tx3addr 0xB400 4034 0x0 1400 4034

macdma0_tx3len 0xB400 4038 0x0 1400 4038

macdma0_rx0stat 0xB400 4100 0x0 1400 4100

macdma0_rx0addr 0xB400 4104 0x0 1400 4104

macdma0_rx1stat 0xB400 4110 0x0 1400 4110

macdma0_rx1addr 0xB400 4114 0x0 1400 4114

macdma0_rx2stat 0xB400 4120 0x0 1400 4120

macdma0_rx2addr 0xB400 4124 0x0 1400 4124

macdma0_rx3stat 0xB400 4130 0x0 1400 4130

macdma0_rx3addr 0xB400 4134 0x0 1400 4134

macdma1_tx0stat 0xB400 4200 0x0 1400 4200

macdma1_tx0addr 0xB400 4204 0x0 1400 4204

macdma1_tx0len 0xB400 4208 0x0 1400 4208

macdma1_tx1stat 0xB400 4210 0x0 1400 4210

macdma1_tx1addr 0xB400 4214 0x0 1400 4214

macdma1_tx1len 0xB400 4218 0x0 1400 4218

macdma1_tx2stat 0xB400 4220 0x0 1400 4220

macdma1_tx2addr 0xB400 4224 0x0 1400 4224

macdma1_tx2len 0xB400 4228 0x0 1400 4228

macdma1_tx3stat 0xB400 4230 0x0 1400 4230

macdma1_tx3addr 0xB400 4234 0x0 1400 4234

macdma1_tx3len 0xB400 4238 0x0 1400 4238

KSEG1

Address

Physical

Address

Table A-4. Device Memory Map (Continued)

AMD Alchemy™ Au1000™ Processor Data Book 273

Appendix A: Memory Map 30360E

A.1.2 Programming Tips

A.1.2.1 Memory Mapped Registers

Peripheral, or system device registers should all be marked

with the CCA bits to non-cacheable. Access must be on 32-

bit boundaries, one 32-bit value at a time. See Section 2.2

"Caches" on page 15 for more information.

macdma1_rx0stat 0xB400 4300 0x0 1400 4300

macdma1_rx0addr 0xB400 4304 0x0 1400 4304

macdma1_rx1stat 0xB400 4310 0x0 1400 4310

macdma1_rx1addr 0xB400 4314 0x0 1400 4314

macdma1_rx2stat 0xB400 4320 0x0 1400 4320

macdma1_rx2addr 0xB400 4324 0x0 1400 4324

macdma1_rx3stat 0xB400 4330 0x0 1400 4330

macdma1_rx3addr 0xB400 4334 0x0 1400 4334

KSEG1

Address

Physical

Address

Table A-4. Device Memory Map (Continued)

274 AMD Alchemy™ Au1000™ Processor Data Book

Appendix A: Data Book Notations

30360E

A.2 Data Book Notations

This section addresses some of the terminology used in this book.

12.3.1 Unpredictable and Undefined

The terms UNPREDICTABLE and UNDEFINED are used throughout this book to describe the behavior of the processor in

certain cases. UNDEFINED behavior or operations can occur only as the result of executing instructions in a privileged

mode (i.e., in Kernel Mode or Debug Mode, or with the CP0 usable bit set in the Status register). Unprivileged software can

never cause UNDEFINED behavior or operations. Conversely, both privileged and unprivileged software can cause

UNPREDICTABLE results or operations.

12.3.2 Unpredictable

UNPREDICTABLE results may vary from processor implementation to implementation, instruction to instruction, or as a

function of time on the same implementation or instruction. Software can never depend on results that are UNPREDICT-

ABLE. UNPREDICTABLE operations may cause a result to be generated or not. If a result is generated, it is UNPREDICT-

ABLE. UNPREDICTABLE operations may cause arbitrary exceptions.

UNPREDICTABLE results or operations have several implementation restrictions:

•Implementations of operations generating UNPREDICTABLE results must not depend on any data source (memory or

internal state) which is inaccessible in the current processor mode

•UNPREDICTABLE operations must not read, write, or modify the contents of memory or internal state which is inacces-

sible in the current processor mode. For example, UNPREDICTABLE operations executed in user mode must not access

memory or internal state that is only accessible in Kernel Mode or Debug Mode or in another process

•UNPREDICTABLE operations must not halt or hang the processor

UNPRED used to describe the default state of registers should be taken as meaning UNPREDICATABLE.

12.3.3 Undefined

UNDEFINED operations or behavior may vary from processor implementation to implementation, instruction to instruction,

or as a function of time on the same implementation or instruction. UNDEFINED operations or behavior may vary from

nothing to creating an environment in which execution can no longer continue. UNDEFINED operations or behavior may

cause data loss.

UNDEFINED operations or behavior has one implementation restriction:

•UNDEFINED operations or behavior must not cause the processor to hang (that is, enter a state from which there is no

exit other than powering down the processor). The assertion of any of the reset signals must restore the processor to an

operational state.

12.3.4 Register Fields

In general, fields marked as reserved should be considered unpredictable. In other words, these fields should be written

zeros and ignored on read to preserve future compatibility.

AMD Alchemy™ Au1000™ Processor Data Book 275

Appendix A: Data Book Revision History 30360E

A.3 Data Book Revision History

This document is a report of the revision/creation process of the data book for the Au1000 processor. Any revisions (i.e.,

additions, deletions, parameter corrections, etc.) are recorded in the table(s) below.

Table A-5. Revision History

Revision (Date) Description

A See the AMD Alchemy™ Au1000™ Processor Specification Update (publication ID 27348).

(June 2005)

See revision C for details.

(September 2005)

Reformatted to bring page count down (from 374 to 281) and correct some minor errors. See revi-

sion D for details.

(June 2006)

Updated OPNs (see Section 12.3 "Ordering Information" on page 266). Also corrected other minor

errors for consistency among Au processor data books.

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