Arria® V Avalon® Memory-Mapped (Avalon-MM) Interface for PCI Express* Solutions: User Guide

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ID 683773
Date 10/25/2024
Public
Document Table of Contents
Document Table of Contents x
1. Datasheet 2. Getting Started with the Avalon-MM Arria V Hard IP for PCI Express 3. Parameter Settings 4. Interfaces and Signal Descriptions 5. Registers 6. Reset and Clocks 7. Interrupts for Endpoints 8. Error Handling A. PCI Express Protocol Stack 9. Design Implementation 10. Additional Features 11. Transceiver PHY IP Reconfiguration 12. Debugging B. Frequently Asked Questions for PCI Express C. Lane Initialization and Reversal D. Document Revision History
1. Datasheet x
1.1. Avalon-MM Interface for PCIe Datasheet 1.2. Features 1.3. Release Information 1.4. Device Family Support 1.5. Configurations 1.6. Example Designs 1.7. IP Core Verification 1.8. Performance and Resource Utilization 1.9. Recommended Speed Grades 1.10. Creating a Design for PCI Express
1.7. IP Core Verification x
1.7.1. Compatibility Testing Environment
2. Getting Started with the Avalon-MM Arria V Hard IP for PCI Express x
2.1. Running Platform Designer 2.2. Generating the Example Design 2.3. Running a Gate-Level Simulation 2.4. Simulating the Single DWord Design 2.5. Understanding Channel Placement Guidelines 2.6. Generating Synthesis Files 2.7. Compiling the Design in the Quartus® Prime Software 2.8. Programming a Device
3. Parameter Settings x
3.1. Avalon-MM System Settings 3.2. Base Address Register (BAR) Settings 3.3. Device Identification Registers 3.4. Device Capabilities 3.5. Error Reporting 3.6. Link Capabilities 3.7. MSI and MSI-X Capabilities 3.8. Power Management 3.9. Avalon Memory‑Mapped System Settings
4. Interfaces and Signal Descriptions x
4.1. 64- or 128-Bit Avalon-MM Interface to the Endpoint Application Layer 4.2. Clock Signals 4.3. Reset Signals 4.4. Hard IP Status 4.5. Interrupts for Endpoints when Multiple MSI/MSI-X Support Is Enabled 4.6. Physical Layer Interface Signals
4.1. 64- or 128-Bit Avalon-MM Interface to the Endpoint Application Layer x
4.1.1. 32-Bit Non-Bursting Avalon-MM Control Register Access (CRA) Slave Signals 4.1.2. Bursting and Non-Bursting Avalon® -MM Module Signals 4.1.3. 64- or 128-Bit Bursting TX Avalon-MM Slave Signals
4.6. Physical Layer Interface Signals x
4.6.1. Transceiver Reconfiguration 4.6.2. Hard IP Status Extension 4.6.3. Serial Interface Signals 4.6.4. PIPE Interface Signals 4.6.5. Test Signals
4.6.2. Hard IP Status Extension x
4.6.2.1. Configuration Space Register Access 4.6.2.2. Configuration Space Register Access Timing
4.6.3. Serial Interface Signals x
4.6.3.1. Physical Layout of Hard IP in Arria V Devices 4.6.3.2. Channel Placement in Arria V Devices
5. Registers x
5.1. Correspondence between Configuration Space Registers and the PCIe Specification 5.2. Type 0 Configuration Space Registers 5.3. Type 1 Configuration Space Registers 5.4. PCI Express Capability Structures 5.5. Intel-Defined VSEC Registers 5.6. CvP Registers 5.7. 64- or 128-Bit Avalon-MM Bridge Register Descriptions 5.8. Programming Model for Avalon-MM Root Port 5.9. Uncorrectable Internal Error Mask Register 5.10. Uncorrectable Internal Error Status Register 5.11. Correctable Internal Error Mask Register 5.12. Correctable Internal Error Status Register
5.7. 64- or 128-Bit Avalon-MM Bridge Register Descriptions x
5.7.1. Avalon-MM to PCI Express Interrupt Registers
5.7.1. Avalon-MM to PCI Express Interrupt Registers x
5.7.1.1. Avalon-MM to PCI Express Interrupt Status Registers 5.7.1.2. Avalon-MM to PCI Express Interrupt Enable Registers 5.7.1.3. PCI Express Mailbox Registers 5.7.1.4. Avalon-MM-to-PCI Express Address Translation Table 5.7.1.5. PCI Express to Avalon-MM Interrupt Status and Enable Registers for Endpoints 5.7.1.6. Avalon-MM Mailbox Registers 5.7.1.7. Control Register Access (CRA) Avalon-MM Slave Port
5.8. Programming Model for Avalon-MM Root Port x
5.8.1. Sending a Write TLP 5.8.2. Sending a Read TLP or Receiving a Non-Posted Completion TLP 5.8.3. Examples of Reading and Writing BAR0 Using the CRA Interface 5.8.4. PCI Express to Avalon-MM Interrupt Status and Enable Registers for Root Ports 5.8.5. Root Port TLP Data Registers
6. Reset and Clocks x
6.1. Reset Sequence for Hard IP for PCI Express IP Core and Application Layer 6.2. Clocks
6.2. Clocks x
6.2.1. Clock Domains 6.2.2. Clock Summary
6.2.1. Clock Domains x
6.2.1.1. pclk 6.2.1.2. coreclkout_hip 6.2.1.3. pld_clk
7. Interrupts for Endpoints x
7.1. Enabling MSI or Legacy Interrupts 7.2. Generation of Avalon-MM Interrupts 7.3. Interrupts for Endpoints Using the Avalon-MM Interface with Multiple MSI/MSI-X Support
8. Error Handling x
8.1. Physical Layer Errors 8.2. Data Link Layer Errors 8.3. Transaction Layer Errors 8.4. Error Reporting and Data Poisoning 8.5. Uncorrectable and Correctable Error Status Bits
A. PCI Express Protocol Stack x
A.1. Top-Level Interfaces A.2. Data Link Layer A.3. Physical Layer A.4. 32-Bit PCI Express Avalon-MM Bridge A.5. Completer Only Single Dword Endpoint
A.1. Top-Level Interfaces x
A.1.1. Avalon-MM Interface A.1.2. Clocks and Reset A.1.3. Transceiver Reconfiguration A.1.4. Interrupts A.1.5. PIPE
A.4. 32-Bit PCI Express Avalon-MM Bridge x
A.4.1. Avalon‑MM Bridge TLPs A.4.2. Avalon-MM-to-PCI Express Write Requests A.4.3. Avalon-MM-to-PCI Express Upstream Read Requests A.4.4. PCI Express-to-Avalon-MM Read Completions A.4.5. PCI Express-to-Avalon-MM Downstream Write Requests A.4.6. PCI Express-to-Avalon-MM Downstream Read Requests A.4.7. Avalon-MM-to-PCI Express Read Completions A.4.8. PCI Express-to-Avalon-MM Address Translation for 32-Bit Bridge A.4.9. Minimizing BAR Sizes and the PCIe Address Space A.4.10. Avalon® -MM-to-PCI Express Address Translation Algorithm for 32-Bit Addressing
A.5. Completer Only Single Dword Endpoint x
A.5.1. RX Block A.5.2. Avalon-MM RX Master Block A.5.3. TX Block A.5.4. Interrupt Handler Block
9. Design Implementation x
9.1. Making Analog QSF Assignments Using the Assignment Editor 9.2. Making Pin Assignments 9.3. Recommended Reset Sequence to Avoid Link Training Issues
10. Additional Features x
10.1. Configuration over Protocol (CvP) 10.2. Autonomous Mode 10.3. ECRC
10.2. Autonomous Mode x
10.2.1. Enabling Autonomous Mode 10.2.2. Enabling CvP Initialization
10.3. ECRC x
10.3.1. ECRC on the RX Path 10.3.2. ECRC on the TX Path
11. Transceiver PHY IP Reconfiguration x
11.1. Connecting the Transceiver Reconfiguration Controller IP Core 11.2. Transceiver Reconfiguration Controller Connectivity for Designs Using CvP
12. Debugging x
12.1. Hardware Bring-Up Issues 12.2. Link Training 12.3. Use Third-Party PCIe Analyzer 12.4. BIOS Enumeration Issues
D. Document Revision History x
D.1. Arria® V and Cyclone® V Avalon® Memory Mapped (Avalon-MM) Interface for PCIe* Solutions User Guide Revision History
1. Datasheet
2. Getting Started with the Avalon-MM Arria V Hard IP for PCI Express
3. Parameter Settings
4. Interfaces and Signal Descriptions
5. Registers
6. Reset and Clocks
7. Interrupts for Endpoints
8. Error Handling
A. PCI Express Protocol Stack
9. Design Implementation
10. Additional Features
11. Transceiver PHY IP Reconfiguration
12. Debugging
B. Frequently Asked Questions for PCI Express
C. Lane Initialization and Reversal
D. Document Revision History

10.1. Configuration over Protocol (CvP)

The Hard IP for PCI Express architecture has an option to configure the FPGA and initialize the PCI Express link. In prior devices, a single Program Object File (.pof) programmed the I/O ring and FPGA fabric before the PCIe link training and enumeration began. The .pof file is divided into two parts:

  • The I/O bitstream contains the data to program the I/O ring, the Hard IP for PCI Express, and other elements that are considered part of the periphery image.
  • The core bitstream contains the data to program the FPGA fabric.

When you select the CvP design flow, the I/O ring and PCI Express link are programmed first, allowing the PCI Express link to reach the L0 state and begin operation independently, before the rest of the core is programmed. After the PCI Express link is established, it can be used to program the rest of the device. The following figure shows the blocks that implement CvP.

Figure 46. CvP in Arria V Devices

CvP has the following advantages:

  • Provides a simpler software model for configuration. A smart host can use the PCIe protocol and the application topology to initialize and update the FPGA fabric.
  • Enables dynamic core updates without requiring a system power down.
  • Improves security for the proprietary core bitstream.
  • Reduces system costs by reducing the size of the flash device to store the .pof.
  • Facilitates hardware acceleration.
  • May reduce system size because a single CvP link can be used to configure multiple FPGAs.
Table 77.  CvP SupportCvP is available for the following configurations.
Data Rate and Application Interface Width Support
Gen1 128-bit interface to Application Layer Supported
Gen2 128-bit interface to Application Layer Contact your Intel sales representative
Note: You cannot use dynamic transceiver reconfiguration for the transceiver channels in the CvP-enabled Hard IP when CvP is enabled.
Note: The Cyclone® 10 GX CvP Initialization over PCI Express User Guide is now available.
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