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1. Introduction
2. IP Architecture and Functional Description
3. Advanced Features
4. Interfaces
5. Parameters
6. Testbench
7. Troubleshooting/Debugging
8. Intel® P-tile Avalon® Streaming IP for PCI Express* User Guide Archives
9. Document Revision History for the P-Tile Avalon® Streaming Intel® FPGA IP for PCI Express* User Guide
A. Configuration Space Registers
B. Root Port Enumeration
C. Implementation of Address Translation Services (ATS) in Endpoint Mode
D. Packets Forwarded to the User Application in TLP Bypass Mode
E. Using the Avery BFM for Intel P-Tile PCI Express Gen4 x16 Simulations
F. Bifurcated Endpoint Support for Independent Warm Resets
3.2.2.5.1. VirtIO Common Configuration Capability Register (Address: 0x012)
3.2.2.5.2. VirtIO Common Configuration BAR Indicator Register (Address: 0x013)
3.2.2.5.3. VirtIO Common Configuration BAR Offset Register (Address: 0x014)
3.2.2.5.4. VirtIO Common Configuration Structure Length Register (Address 0x015)
3.2.2.5.5. VirtIO Notifications Capability Register (Address: 0x016)
3.2.2.5.6. VirtIO Notifications BAR Indicator Register (Address: 0x017)
3.2.2.5.7. VirtIO Notifications BAR Offset Register (Address: 0x018)
3.2.2.5.8. VirtIO Notifications Structure Length Register (Address: 0x019)
3.2.2.5.9. VirtIO Notifications Notify Off Multiplier Register (Address: 0x01A)
3.2.2.5.10. VirtIO ISR Status Capability Register (Address: 0x02F)
3.2.2.5.11. VirtIO ISR Status BAR Indicator Register (Address: 0x030)
3.2.2.5.12. VirtIO ISR Status BAR Offset Register (Address: 0x031)
3.2.2.5.13. VirtIO ISR Status Structure Length Register (Address: 0x032)
3.2.2.5.14. VirtIO Device Specific Capability Register (Address: 0x033)
3.2.2.5.15. VirtIO Device Specific BAR Indicator Register (Address: 0x034)
3.2.2.5.16. VirtIO Device Specific BAR Offset Register (Address 0x035 )
3.2.2.5.17. VirtIO Device Specific Structure Length Register (Address: 0x036)
3.2.2.5.18. VirtIO PCI Configuration Access Capability Register (Address: 0x037)
3.2.2.5.19. VirtIO PCI Configuration Access BAR Indicator Register (Address: 0x038)
3.2.2.5.20. VirtIO PCI Configuration Access BAR Offset Register (Address: 0x039)
3.2.2.5.21. VirtIO PCI Configuration Access Structure Length Register (Address: 0x03A)
3.2.2.5.22. VirtIO PCI Configuration Access Data Register (Address: 0x03B)
4.1. Overview
4.2. Clocks and Resets
4.3. Serial Data Interface
4.4. Avalon-ST Interface
4.5. Hard IP Status Interface
4.6. Interrupt Interface
4.7. Error Interface
4.8. Hot Plug Interface (RP Only)
4.9. Power Management Interface
4.10. Configuration Output Interface
4.11. Configuration Intercept Interface (EP Only)
4.12. Hard IP Reconfiguration Interface
4.13. PHY Reconfiguration Interface
4.14. Page Request Service (PRS) Interface (EP Only)
4.4.1. TLP Header and Data Alignment for the Avalon-ST RX and TX Interfaces
4.4.2. Avalon® -ST RX Interface
4.4.3. Avalon® -ST RX Interface rx_st_ready Behavior
4.4.4. RX Flow Control Interface
4.4.5. Avalon® -ST TX Interface
4.4.6. Avalon® -ST TX Interface tx_st_ready Behavior
4.4.7. TX Flow Control Interface
4.4.8. Tag Allocation
5.2.3.1. Device Capabilities
5.2.3.2. VirtIO Parameters
5.2.3.3. Link Capabilities
5.2.3.4. Legacy Interrupt Pin Register
5.2.3.5. MSI Capabilities
5.2.3.6. MSI-X Capabilities
5.2.3.7. Slot Capabilities
5.2.3.8. Latency Tolerance Reporting (LTR)
5.2.3.9. Process Address Space ID (PASID)
5.2.3.10. Device Serial Number Capability
5.2.3.11. Page Request Service (PRS)
5.2.3.12. Access Control Service (ACS) Capabilities
5.2.3.13. Power Management
5.2.3.14. Vendor Specific Extended Capability (VSEC) Registers
5.2.3.15. TLP Processing Hints (TPH)
5.2.3.16. Address Translation Services (ATS) Capabilities
6.3.5.1. ebfm_barwr Procedure
6.3.5.2. ebfm_barwr_imm Procedure
6.3.5.3. ebfm_barrd_wait Procedure
6.3.5.4. ebfm_barrd_nowt Procedure
6.3.5.5. ebfm_cfgwr_imm_wait Procedure
6.3.5.6. ebfm_cfgwr_imm_nowt Procedure
6.3.5.7. ebfm_cfgrd_wait Procedure
6.3.5.8. ebfm_cfgrd_nowt Procedure
6.3.5.9. BFM Configuration Procedures
6.3.5.10. BFM Shared Memory Access Procedures
6.3.5.11. BFM Log and Message Procedures
6.3.5.12. Verilog HDL Formatting Functions
6.3.5.11.1. ebfm_display Verilog HDL Function
6.3.5.11.2. ebfm_log_stop_sim Verilog HDL Function
6.3.5.11.3. ebfm_log_set_suppressed_msg_mask Task
6.3.5.11.4. ebfm_log_set_stop_on_msg_mask Verilog HDL Task
6.3.5.11.5. ebfm_log_open Verilog HDL Function
6.3.5.11.6. ebfm_log_close Verilog HDL Function
A.3.1. Intel-Defined VSEC Capability Header (Offset 00h)
A.3.2. Intel-Defined Vendor Specific Header (Offset 04h)
A.3.3. Intel Marker (Offset 08h)
A.3.4. JTAG Silicon ID (Offset 0x0C - 0x18)
A.3.5. User Configurable Device and Board ID (Offset 0x1C - 0x1D)
A.3.6. General Purpose Control and Status Register (Offset 0x30)
A.3.7. Uncorrectable Internal Error Status Register (Offset 0x34)
A.3.8. Uncorrectable Internal Error Mask Register (Offset 0x38)
A.3.9. Correctable Internal Error Status Register (Offset 0x3C)
A.3.10. Correctable Internal Error Mask Register (Offset 0x40)
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4.6.3.1. Implementing MSI-X Interrupts
Section 6.8.2 of the PCI Local Bus Specification describes the MSI-X capability and table structures. The MSI-X capability structure points to the MSI-X Table structure and MSI-X Pending Bit Array (PBA) registers. The BIOS sets up the starting address offsets and BAR associated with the pointer to the starting address of the MSI-X Table and PBA registers.
MSI-X Interrupt Components
- Host software sets up the MSI-X interrupts in the Application Layer by completing the following steps:
- Host software reads the Message Control register at 0x050 register to determine the MSI-X Table size. The number of table entries is the <value read> + 1.
The maximum table size is 2048 entries. Each 16-byte entry is divided in 4 fields as shown in the figure below. The MSI-X table can be accessed on any BAR configured. The base address of the MSI-X table must be aligned to a 4 KB boundary.
- The host sets up the MSI-X table. It programs MSI-X address, data, and masks bits for each entry as shown in the figure below.
Figure 35. Format of MSI-X Table
- The host calculates the address of the <n th > entry using the following formula:
nth_address = base address[BAR] + 16<n>
- Host software reads the Message Control register at 0x050 register to determine the MSI-X Table size. The number of table entries is the <value read> + 1.
- When Application Layer has an interrupt, it drives an interrupt request to the IRQ Source module.
- The IRQ Source sets appropriate bit in the MSI-X PBA table.
The PBA can use qword or dword accesses. For qword accesses, the IRQ Source calculates the address of the <m th > bit using the following formulas:
qword address = <PBA base addr> + 8(floor(<m>/64)) qword bit = <m> mod 64
Figure 36. MSI-X PBA Table - The IRQ Processor reads the entry in the MSI-X table.
- If the interrupt is masked by the Vector_Control field of the MSI-X table, the interrupt remains in the pending state.
- If the interrupt is not masked, IRQ Processor sends Memory Write Request to the TX slave interface. It uses the address and data from the MSI-X table. If Message Upper Address = 0, the IRQ Processor creates a three-dword header. If the Message Upper Address > 0, it creates a 4-dword header.
- The host interrupt service routine detects the TLP as an interrupt and services it.