Hard Processor System Component Reference Manual: Agilex™ 5 SoCs

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ID 813752
Date 11/25/2024
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Document Table of Contents
Document Table of Contents x
1. Introduction to the Agilex™ 5 Hard Processor System Component 2. Configuring the Agilex™ 5 Hard Processor System Component 3. Simulating the Agilex™ 5 HPS Component 4. Design Guidelines 5. Document Revision History for the Hard Processor System Component Reference Manual Agilex™ 5 SoCs
1. Introduction to the Agilex™ 5 Hard Processor System Component x
1.1. Release Notes 1.2. Micro Processor Unit 1.3. Application Processor Subsystem 1.4. Peripheral Subsystem 1.5. CoreSight* Debug Components 1.6. Interconnect 1.7. FPGA Bridges 1.8. Introduction to the Agilex™ 5 Hard Processor System Component Revision History
1.1. Release Notes x
1.1.1. HPS IP 5.1.0 1.1.2. HPS IP 4.0.0
2. Configuring the Agilex™ 5 Hard Processor System Component x
2.1. Parameterizing the HPS Component 2.2. HPS-FPGA Interfaces 2.3. SDRAM 2.4. HPS Clocks, Reset, Power 2.5. I/O Delays 2.6. Pin Mux and Peripherals 2.7. Generating and Compiling the HPS Component 2.8. Using the Address Span Extender Component 2.9. Configuring the Agilex™ 5 Hard Processor System Component Revision History
2.2. HPS-FPGA Interfaces x
2.2.1. General 2.2.2. HPS FPGA Bridges 2.2.3. DMA Controller Interface 2.2.4. Interrupts
2.2.1. General x
2.2.1.1. Enable MPU Standby and Event Signals 2.2.1.2. Enable General Purpose Signals 2.2.1.3. Enable Debug APB* Interface 2.2.1.4. Enable System Trace Macrocell (STM) Hardware Events 2.2.1.5. Enable SWJ-DP JTAG Interface 2.2.1.6. Enable FPGA Cross Trigger Interface 2.2.1.7. Enable AMBA* Trace Bus (ATB)
2.2.2. HPS FPGA Bridges x
2.2.2.1. FPGA to HPS Subordinate 2.2.2.2. FPGA to SDRAM Subordinate 2.2.2.3. HPS to FPGA Manager 2.2.2.4. Lightweight HPS to FPGA Manager
2.2.4. Interrupts x
2.2.4.1. FPGA-to-HPS 2.2.4.2. HPS-to-FPGA
2.3. SDRAM x
2.3.1. Configurations for HPS IP 2.3.2. Configurations for HPS EMIF IP 2.3.3. Graphical Connections of HPS to HPS-EMIF 2.3.4. Configuration when using ECC 2.3.5. Supported Memory Protocols Among Device Families 2.3.6. IO96 Bank and Lane Usage for HPS EMIF 2.3.7. Quartus Report of I/O Bank Usage
2.4. HPS Clocks, Reset, Power x
2.4.1. Input Clocks 2.4.2. PLL Clocks 2.4.3. Power and Resets
2.4.1. Input Clocks x
2.4.1.1. External Clocks 2.4.1.2. FPGA-to-HPS Clocks 2.4.1.3. Peripheral FPGA Clocks
2.4.2. PLL Clocks x
2.4.2.1. Main PLL Output 2.4.2.2. Peripheral PLL Output 2.4.2.3. MPU Clocks 2.4.2.4. NOC Clocks 2.4.2.5. Peripheral Clocks 2.4.2.6. HPS-to-FPGA User Clocks
2.4.3. Power and Resets x
2.4.3.1. Power Configurations 2.4.3.2. Reset Signals
2.6. Pin Mux and Peripherals x
2.6.1. Pin Mux GUI 2.6.2. EMAC PTP Interface 2.6.3. HPS I/O Open Drain 2.6.4. HPS I/O Locations
2.6.1. Pin Mux GUI x
2.6.1.1. Auto-Place IP 2.6.1.2. Advanced
2.6.1.1. Auto-Place IP x
2.6.1.1.1. Options for NAND, SDMMC, TRACE, TPIU, EMAC
2.6.1.1.1. Options for NAND, SDMMC, TRACE, TPIU, EMAC x
2.6.1.1.1.1. HPS IO Placement Priority
2.6.1.2. Advanced x
2.6.1.2.1. Advanced IP Placement 2.6.1.2.2. Advanced FPGA Placement
3. Simulating the Agilex™ 5 HPS Component x
3.1. Simulation Flows 3.2. Running the Simulation of the Design Examples 3.3. Clock and Reset Interface 3.4. FPGA-to-HPS AXI* Subordinate Interface 3.5. FPGA-to-SDRAM AXI* Subordinate Interface 3.6. HPS-to-FPGA AXI* Initiator Interface 3.7. Lightweight HPS-to-FPGA AXI* Initiator Interface 3.8. Simulating the Agilex™ 5 HPS Component Revision History
3.1. Simulation Flows x
3.1.1. Setting Up the HPS Component for Simulation 3.1.2. Generating the HPS Simulation Model in Platform Designer 3.1.3. RTL Simulation Setup Scripts
3.1.3. RTL Simulation Setup Scripts x
3.1.3.1. QuestaSim* Simulation Steps 3.1.3.2. Cadence® Xcelium* Simulation Steps 3.1.3.3. Synopsys* VCS* Simulation Steps 3.1.3.4. Synopsys* VCS* MX Simulation Steps 3.1.3.5. Aldec® Riviera-PRO* Simulation Steps
3.2. Running the Simulation of the Design Examples x
3.2.1. HPS-to-FPGA Bridge (H2F) 3.2.2. Lightweight HPS-to-FPGA (LWH2F) 3.2.3. FPGA-to-HPS Bridge (F2H) 3.2.4. FPGA-to-SDRAM Bridge (F2SDRAM)
3.2.1. HPS-to-FPGA Bridge (H2F) x
3.2.1.1. Steps to run the Simulation in Questa* Intel® FPGA Edition 3.2.1.2. Steps to run the Simulation in Synopsys* VCS*
3.2.2. Lightweight HPS-to-FPGA (LWH2F) x
3.2.2.1. Steps to run the Simulation in Questa* Intel® FPGA Edition 3.2.2.2. Steps to run the Simulation in Synopsys* VCS*
3.2.3. FPGA-to-HPS Bridge (F2H) x
3.2.3.1. Steps to run the Simulation in Questa* Intel® FPGA Edition 3.2.3.2. Steps to run the Simulation in Synopsys* VCS*
3.2.4. FPGA-to-SDRAM Bridge (F2SDRAM) x
3.2.4.1. Steps to run the Simulation in Questa* Intel® FPGA Edition 3.2.4.2. Steps to run the Simulation in Synopsys* VCS*
3.3. Clock and Reset Interface x
3.3.1. Clock Interface 3.3.2. Reset Interface
4. Design Guidelines x
4.1. HPS System Reset Considerations 4.2. Design Guidelines Revision History
1. Introduction to the Agilex™ 5 Hard Processor System Component
2. Configuring the Agilex™ 5 Hard Processor System Component
3. Simulating the Agilex™ 5 HPS Component
4. Design Guidelines
5. Document Revision History for the Hard Processor System Component Reference Manual Agilex™ 5 SoCs

2.4.2.3. MPU Clocks

The default core MPU frequencies are displayed in a table. MPU CCU Clock Divider and MPU Peripheral Clock Divider are not configurable, set to Div2 and Div4 by default.

Turning on Override MPU Clocks exposes the main PLL clocks desired frequency. You can configure the desired frequency by overriding the value of each main PLL frequency.

The clock manager has one ping-pong counter for Core0 and Core1, which goes to Arm* Cortex*-A55 MPU; therefore only a single clock is generated for Core0 and Core1.

Figure 26.  Platform Designer MPU Clocks Sub-window
Level Two Title