Hard Processor System Component Reference Manual: Agilex™ 5 SoCs

Download PDF
ID 813752
Date 11/25/2024
Public
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

1.6. Interconnect

The system interconnect supports the following features:

  • Configurable Arm* TrustZone* -compliant firewall and security support.
    • Targets are placed in a secure or non-secure zone.
      • Secure targets can only be accessed by secure transactions.
      • Non-secure targets can be accessed by any transaction.
    • Allows configuration of individual transactions as secure or non-secure at the initiating initiator.
    • All targets are secure at reset.
      • Target secure state can be changed in NOC Security Control Registers (SCR).
    • Some initiators are secure at reset.
      • Initiator Secure state is driven on a per-transaction basis or by system manager.
    • Security Control Registers (SCRs) are strictly secure-only.
  • Multi-tiered bus structure to separate high bandwidth initiators from lower bandwidth targets and control and status ports.
  • Quality of service (QoS) with three programmable levels of service on a per initiator basis.
  • On-chip debugging and tracing capabilities.

The system interconnect is based on the Arteris* FlexNoC network-on-chip (NoC) interconnect technology.

Level Two Title