Stratix V Avalon-ST Interface with SR-IOV PCIe Solutions: User Guide

Download PDF
ID 683488
Date 5/02/2016
Public
Document Table of Contents
Document Table of Contents x
1. Datasheet 2. Getting Started with the SR-IOV DMA Example Design 3. Parameter Settings 4. Interfaces and Signal Descriptions 5. Registers 6. Programming and Testing SR-IOV Bridge MSI Interrupts 7. Error Handling 8. IP Core Architecture 9. Design Implementation 10. Transceiver PHY IP Reconfiguration 11. Debugging A. Frequently Asked Questions for PCI Express B. Transaction Layer Packet (TLP) Header Formats C. Stratix V Avalon-ST with SR-IOV Interface for PCIe Solutions User Guide Archive 12. Document Revision History
1. Datasheet x
1.1. Stratix® V Avalon-ST Interface with SR-IOV for PCIe Datasheet 1.2. Release Information 1.3. Device Family Support 1.4. Design Examples for SR-IOV 1.5. Debug Features 1.6. IP Core Verification 1.7. Performance and Resource Utilization 1.8. Recommended Speed Grades for SR-IOV Interface 1.9. Creating a Design for PCI Express
1.1. Stratix® V Avalon-ST Interface with SR-IOV for PCIe Datasheet x
1.1.1. SR-IOV Features
1.6. IP Core Verification x
1.6.1. Compatibility Testing Environment
2. Getting Started with the SR-IOV DMA Example Design x
2.1. Generating the Example Design Testbench 2.2. Understanding the Generated Files and Directories 2.3. Simulating the SR-IOV Example Design 2.4. Running a Gate-Level Simulation 2.5. Understanding the DMA Functionality 2.6. Compiling the Example Design with the Quartus® Prime Software 2.7. Using the IP Catalog To Generate Your Stratix V Hard IP for PCI Express as a Separate Component
3. Parameter Settings x
3.1. System Settings 3.2. SR-IOV System Settings 3.3. Base Address Register (BAR) Settings 3.4. SR-IOV Device Identification Registers 3.5. Interrupt Capabilities 3.6. PCI Express and PCI Capabilities Parameters 3.7. PHY Characteristics 3.8. Simulation Options
3.6. PCI Express and PCI Capabilities Parameters x
3.6.1. Device Capabilities 3.6.2. Error Reporting 3.6.3. Link Capabilities 3.6.4. Slot Capabilities 3.6.5. Power Management
4. Interfaces and Signal Descriptions x
4.1. Avalon-ST TX Interface 4.2. Component-Specific Avalon-ST Interface Signals 4.3. Avalon-ST RX Interface 4.4. BAR Hit Signals 4.5. Configuration Status Interface 4.6. Clock Signals 4.7. Function-Level Reset Interface 4.8. Interrupt Interface 4.9. Configuration Extension Bus (CEB) Interface 4.10. Implementing MSI-X Interrupts 4.11. Local Management Interface (LMI) Signals 4.12. Reset, Status, and Link Training Signals 4.13. Transceiver Reconfiguration 4.14. Serial Data Signals 4.15. Test Signals 4.16. PIPE Interface Signals
4.9. Configuration Extension Bus (CEB) Interface x
4.9.1. Vital Product Data (VPD) Capability
4.9.1. Vital Product Data (VPD) Capability x
4.9.1.1. Determine the Pointer Address of an External Capability Register 4.9.1.2. VPD Capability Implementation
4.14. Serial Data Signals x
4.14.1. Physical Layout of Hard IP In Stratix V Devices 4.14.2. Channel Placement in Arria V GZ and Stratix V GX/GT/GS Devices
5. Registers x
5.1. Correspondence between Configuration Space Registers and the PCIe Specification 5.2. PCI and PCI Express Configuration Space Registers 5.3. MSI Registers 5.4. MSI-X Capability Structure 5.5. Power Management Capability Structure 5.6. PCI Express Capability Structure 5.7. Advanced Error Reporting (AER) Enhanced Capability Header Register 5.8. Uncorrectable Error Status Register 5.9. Uncorrectable Error Mask Register 5.10. Uncorrectable Error Severity Register 5.11. Correctable Error Status Register 5.12. Correctable Error Mask Register 5.13. Advanced Error Capabilities and Control Register 5.14. Header Log Registers 0-3 5.15. SR-IOV Virtualization Extended Capabilities Registers 5.16. Virtual Function Registers
5.2. PCI and PCI Express Configuration Space Registers x
5.2.1. Type 0 Configuration Space Registers 5.2.2. PCI and PCI Express Configuration Space Register Content 5.2.3. Interrupt Line and Interrupt Pin Register
5.15. SR-IOV Virtualization Extended Capabilities Registers x
5.15.1. SR-IOV Virtualization Extended Capabilities Registers Address Map 5.15.2. ARI Enhanced Capability Header 5.15.3. SR-IOV Enhanced Capability Registers 5.15.4. Initial VFs and Total VFs Registers 5.15.5. VF Device ID Register 5.15.6. Page Size Registers 5.15.7. VF Base Address Registers (BARs) 0-5 5.15.8. Secondary PCI Express Extended Capability Header 5.15.9. Lane Status Registers
6. Programming and Testing SR-IOV Bridge MSI Interrupts x
6.1. Setting Up and Verifying MSI Interrupts 6.2. Masking MSI Interrupts 6.3. Dropping a Pending MSI Interrupt
7. Error Handling x
7.1. Physical Layer Errors 7.2. Data Link Layer Errors 7.3. Transaction Layer Errors 7.4. Error Reporting and Data Poisoning 7.5. Uncorrectable and Correctable Error Status Bits
8. IP Core Architecture x
8.1. Data Link Layer 8.2. Physical Layer 8.3. Top-Level Interfaces 8.4. Physical and Virtual Function Address Assignments 8.5. Stratix V Hard IP for PCI Express with Single-Root I/O Virtualization (SR-IOV)
8.3. Top-Level Interfaces x
8.3.1. Avalon-ST Interface 8.3.2. Clocks and Reset 8.3.3. Transceiver Reconfiguration 8.3.4. Interrupts 8.3.5. PIPE
9. Design Implementation x
9.1. Making Analog QSF Assignments Using the Assignment Editor 9.2. Making Pin Assignments to Assign I/O Standard to Serial Data Pins 9.3. Recommended Reset Sequence to Avoid Link Training Issues 9.4. SDC Timing Constraints
10. Transceiver PHY IP Reconfiguration x
10.1. Connecting the Transceiver Reconfiguration Controller IP Core 10.2. Transceiver Reconfiguration Controller Connectivity for Designs Using CvP
11. Debugging x
11.1. Setting Up Simulation 11.2. Hardware Bring-Up Issues 11.3. Link Training 11.4. Use Third-Party PCIe Analyzer 11.5. BIOS Enumeration Issues
11.1. Setting Up Simulation x
11.1.1. Changing Between Serial and PIPE Simulation 11.1.2. Using the PIPE Interface for Gen1 and Gen2 Variants 11.1.3. Viewing the Important PIPE Interface Signals 11.1.4. Disabling the Scrambler for Gen1 and Gen2 Simulations 11.1.5. Disabling 8B/10B Encoding and Decoding for Gen1 and Gen2 Simulations 11.1.6. Changing between the Hard and Soft Reset Controller
11.3. Link Training x
11.3.1. Debugging Link that Fails To Reach L0
B. Transaction Layer Packet (TLP) Header Formats x
B.1. TLP Packet Formats without Data Payload B.2. TLP Packet Formats with Data Payload
12. Document Revision History x
12.1. Document Revision History for the Intel® Arria® 10 Avalon® Streaming with SR-IOV IP for PCIe* User Guide
1. Datasheet
2. Getting Started with the SR-IOV DMA Example Design
3. Parameter Settings
4. Interfaces and Signal Descriptions
5. Registers
6. Programming and Testing SR-IOV Bridge MSI Interrupts
7. Error Handling
8. IP Core Architecture
9. Design Implementation
10. Transceiver PHY IP Reconfiguration
11. Debugging
A. Frequently Asked Questions for PCI Express
B. Transaction Layer Packet (TLP) Header Formats
C. Stratix V Avalon-ST with SR-IOV Interface for PCIe Solutions User Guide Archive
12. Document Revision History

1.9. Creating a Design for PCI Express

Select the PCIe variant that best meets your design requirements.

  • Is your design an Endpoint or Root Port?
  • What Generation do you intend to implement?
  • What link width do you intend to implement?
  • What bandwidth does your application require?
  • Does your design require Configuration via Protocol (CvP)?
Note: The following steps only provide a high-level overview of the design generation and simulation process. For more details, refer to the Quick Start Guide chapter.
  1. Select parameters for that variant.
  2. For Intel® Arria® 10 devices, you can use the new Example Design tab of the component GUI to generate a design that you specify. Then, you can simulate this example and also download it to an Intel® Arria® 10 FPGA Development Kit. Refer to the Intel® Arria® 10/ Intel® Cyclone® 10 GX PCI Express* IP Core Quick Start Guide for details.
  3. For all devices, you can simulate using an Intel-provided example design. All static PCI Express example designs are available under <install_dir>/ip/altera/altera_pcie/altera_pcie_<dev>_ed/example_design/<dev> . Alternatively, create a simulation model and use your own custom or third-party BFM. The Platform Designer Generate menu generates simulation models. Intel supports ModelSim* - Intel FPGA Edition for all IP. The PCIe cores support the Aldec RivieraPro*, Cadence NCSim*, Mentor Graphics ModelSim*, and Synopsys VCS* and VCS-MX* simulators.
    The Intel testbench and Root Port or Endpoint BFM provide a simple method to do basic testing of the Application Layer logic that interfaces to the variation. However, the testbench and Root Port BFM are not intended to be a substitute for a full verification environment. To thoroughly test your application, Intel suggests that you obtain commercially available PCI Express verification IP and tools, or do your own extensive hardware testing, or both.
  4. Compile your design using the Quartus® Prime software. If the versions of your design and the Quartus® Prime software you are running do not match, regenerate your PCIe design.
  5. Download your design to an Intel development board or your own PCB. Click on the All Development Kits link below for a list of Intel's development boards.
  6. Test the hardware. You can use Intel's Signal Tap Logic Analyzer or a third-party protocol analyzer to observe behavior.
  7. Substitute your Application Layer logic for the Application Layer logic in Intel's testbench. Then repeat Steps 3–6. In Intel's testbenches, the PCIe core is typically called the DUT (device under test). The Application Layer logic is typically called APPS.
Related Information
Level Two Title