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1. Cyclone® V Hard Processor System Technical Reference Manual Revision History
2. Introduction to the Hard Processor System
3. Clock Manager
4. Reset Manager
5. FPGA Manager
6. System Manager
7. Scan Manager
8. System Interconnect
9. HPS-FPGA Bridges
10. Cortex®-A9 Microprocessor Unit Subsystem
11. CoreSight* Debug and Trace
12. SDRAM Controller Subsystem
13. On-Chip Memory
14. NAND Flash Controller
15. SD/MMC Controller
16. Quad SPI Flash Controller
17. DMA Controller
18. Ethernet Media Access Controller
19. USB 2.0 OTG Controller
20. SPI Controller
21. I2C Controller
22. UART Controller
23. General-Purpose I/O Interface
24. Timer
25. Watchdog Timer
26. CAN Controller
27. Introduction to the HPS Component
28. Instantiating the HPS Component
29. HPS Component Interfaces
30. Simulating the HPS Component
31. Register Address Map for Cyclone V HPS
A. Booting and Configuration
8.3.1. Master to Slave Connectivity Matrix
8.3.2. System Interconnect Address Spaces
8.3.3. Master Caching and Buffering Overrides
8.3.4. Security
8.3.5. Configuring the Quality of Service Logic
8.3.6. Cyclic Dependency Avoidance Schemes
8.3.7. System Interconnect Master Properties
8.3.8. Interconnect Slave Properties
8.3.9. Upsizing Data Width Function
8.3.10. Downsizing Data Width Function
8.3.11. Lock Support
8.3.12. FIFO Buffers and Clock Crossing
8.3.13. System Interconnect Resets
10.3.1. Functional Description
10.3.2. Implementation Details
10.3.3. Cortex®-A9 Processor
10.3.4. Interactive Debugging Features
10.3.5. L1 Caches
10.3.6. Preload Engine
10.3.7. Floating Point Unit
10.3.8. NEON* Multimedia Processing Engine
10.3.9. Memory Management Unit
10.3.10. Performance Monitoring Unit
10.3.11. Arm* Cortex* -A9 MPCore* Timers
10.3.12. Generic Interrupt Controller
10.3.13. Global Timer
10.3.14. Snoop Control Unit
10.3.15. Accelerator Coherency Port
11.1. Features of CoreSight* Debug and Trace
11.2. Arm* CoreSight* Documentation
11.3. CoreSight Debug and Trace Block Diagram and System Integration
11.4. Functional Description of CoreSight Debug and Trace
11.5. CoreSight* Debug and Trace Programming Model
11.6. CoreSight Debug and Trace Address Map and Register Definitions
11.4.1. Debug Access Port
11.4.2. System Trace Macrocell
11.4.3. Trace Funnel
11.4.4. CoreSight Trace Memory Controller
11.4.5. AMBA* Trace Bus Replicator
11.4.6. Trace Port Interface Unit
11.4.7. Embedded Cross Trigger System
11.4.8. Program Trace Macrocell
11.4.9. HPS Debug APB* Interface
11.4.10. FPGA Interface
11.4.11. Debug Clocks
11.4.12. Debug Resets
12.1. Features of the SDRAM Controller Subsystem
12.2. SDRAM Controller Subsystem Block Diagram
12.3. SDRAM Controller Memory Options
12.4. SDRAM Controller Subsystem Interfaces
12.5. Memory Controller Architecture
12.6. Functional Description of the SDRAM Controller Subsystem
12.7. SDRAM Power Management
12.8. DDR PHY
12.9. Clocks
12.10. Resets
12.11. Port Mappings
12.12. Initialization
12.13. SDRAM Controller Subsystem Programming Model
12.14. Debugging HPS SDRAM in the Preloader
12.15. SDRAM Controller Address Map and Register Definitions
14.1. NAND Flash Controller Features
14.2. NAND Flash Controller Block Diagram and System Integration
14.3. NAND Flash Controller Signal Descriptions
14.4. Functional Description of the NAND Flash Controller
14.5. NAND Flash Controller Programming Model
14.6. NAND Flash Controller Address Map and Register Definitions
15.1. Features of the SD/MMC Controller
15.2. SD/MMC Controller Block Diagram and System Integration
15.3. SD/MMC Controller Signal Description
15.4. Functional Description of the SD/MMC Controller
15.5. SD/MMC Controller Programming Model
15.6. SD/MMC Controller Address Map and Register Definitions
16.1. Features of the Quad SPI Flash Controller
16.2. Quad SPI Flash Controller Block Diagram and System Integration
16.3. Interface Signals
16.4. Functional Description of the Quad SPI Flash Controller
16.5. Quad SPI Flash Controller Programming Model
16.6. Quad SPI Flash Controller Address Map and Register Definitions
16.4.1. Overview
16.4.2. Data Slave Interface
16.4.3. SPI Legacy Mode
16.4.4. Register Slave Interface
16.4.5. Local Memory Buffer
16.4.6. DMA Peripheral Request Controller
16.4.7. Arbitration between Direct/Indirect Access Controller and STIG
16.4.8. Configuring the Flash Device
16.4.9. XIP Mode
16.4.10. Write Protection
16.4.11. Data Slave Sequential Access Detection
16.4.12. Clocks
16.4.13. Resets
16.4.14. Interrupts
18.6.1. System Level EMAC Configuration Registers
18.6.2. EMAC FPGA Interface Initialization
18.6.3. EMAC HPS Interface Initialization
18.6.4. DMA Initialization
18.6.5. EMAC Initialization and Configuration
18.6.6. Performing Normal Receive and Transmit Operation
18.6.7. Stopping and Starting Transmission
18.6.8. Programming Guidelines for Energy Efficient Ethernet
18.6.9. Programming Guidelines for Flexible Pulse-Per-Second (PPS) Output
19.1. Features of the USB OTG Controller
19.2. USB OTG Controller Block Diagram and System Integration
19.3. USB 2.0 ULPI PHY Signal Description
19.4. Functional Description of the USB OTG Controller
19.5. USB OTG Controller Programming Model
19.6. USB 2.0 OTG Controller Address Map and Register Definitions
26.3.1.1.1. Message Valid (MsgVal)
26.3.1.1.2. New Data (NewDat)
26.3.1.1.3. Message Lost (MsgLst)
26.3.1.1.4. Interrupt Pending (IntPnd)
26.3.1.1.5. Transmit Interrupt Enable (TxIE)
26.3.1.1.6. Receive Interrupt Enable (RxIE)
26.3.1.1.7. Remote Enable (RmtEn)
26.3.1.1.8. Transmit Request (TxRqst)
26.3.1.1.9. End of Block (EoB)
30.1. Simulation Flows
30.2. Clock and Reset Interfaces
30.3. FPGA-to-HPS AXI Slave Interface
30.4. HPS-to-FPGA AXI Master Interface
30.5. Lightweight HPS-to-FPGA AXI Master Interface
30.6. FPGA-to-HPS SDRAM Interface
30.7. HPS-to-FPGA MPU Event Interface
30.8. Interrupts Interface
30.9. HPS-to-FPGA Debug APB* Interface
30.10. FPGA-to-HPS System Trace Macrocell Hardware Event Interface
30.11. HPS-to-FPGA Cross-Trigger Interface
30.12. HPS-to-FPGA Trace Port Interface
30.13. FPGA-to-HPS DMA Handshake Interface
30.14. Boot from FPGA Interface
30.15. General Purpose Input Interface
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10.3.15.6. Avoiding ACP Dependency Lockup
Certain coherent access scenarios can create deadlock through the ACP and the CPU. However, you can avoid this type of deadlock with a simple access strategy.
In the following example, the CPU creates deadlock by initiating an access to the HPS through the FPGA fabric:
- The CPU initiates a device memory access to the FPGA fabric. The CPU pipeline must stall until this type of access is complete.
- Before the FPGA fabric state machine can respond to the device memory access, it must access the HPS coherently. It initiates a coherent access, which requires the ACP.
- The ACP must perform a cache maintenance operation before it can complete the access. However, the CPU’s pipeline stall prevents it from performing the cache maintenance operation. The system deadlocks.
You can implement the desired access without deadlock, by breaking it into smaller pieces. For example, you can initiate the operation with one access, then determine the operation status with a second access.