Nios V/g CRC Custom Instruction
Introduction¶
Nios® V/g CRC Custom Instruction Example Design Overview¶
This design demonstrates a custom CRC processing engine blocks with Nios® V/g processor custom instruction in Agilex® 7 FPGA F-Series Development Kit. The design is built with basic peripherals required for simple application execution:
- JTAG UART for serial output.
Prerequisites¶
- Agilex® 7 FPGA F-Series Development Kit, ordering code DK-DEV-AGF014EA. Refer to the board documentation for more information about the development kit.
- Mini and Micro USB Cable. Included with the development kit.
- Host PC with 64 GB of RAM. Less will be fine for only exercising the prebuilt binaries, and not rebuilding the design.
- Quartus® Prime Pro Edition Software version 25.1.1
- Ashling* RiscFree* IDE for Altera® FPGAs
Release Contents¶
Every Nios V processor design example is maintained based on this folder structure. Here is the Github link to root directory of this design example: Nios® V/g CRC Custom Instruction Example Design Github link
---
title: Release Contents File Structure
config:
flowchart:
curve: linear
---
graph LR
A[ci_crc] --> B[docs]
A --> C[img]
A --> D[ready_to_test]
A --> E[sources]
B -->|contains| F{{Design Example MD file}}
C -->|contains| G{{Figures or Illustrations}}
D -->|contains| H{{Prebuilt Binary Files}}
E --> L[custom_logic]
E --> I[hw]
E --> J[scripts]
E --> K[sw]
I -->|contains| M{{Custom Hardware Design Files}}
J -->|contains| N{{Scripts to Generate Hardware Design}}
K -->|contains| P{{Custom Software Source Code}}
L -->|contains| Q{{Custom Processing Engines}}
Nios® V/g CRC Custom Instruction Design Architecture¶
This example design includes a Nios® V/g processor connected to a custom CRC processing engine blocks (CRC PE), a On-Chip RAM II, JTAG UART IP, and System ID peripheral core. The objective of the design is to execute the CRC calculation instruction supported within the PE.
---
title: Design Block Diagram
config:
flowchart:
curve: linear
---
flowchart LR
subgraph top-level-subsystem
Z[Clock Source]
Y[Reset Source]
subgraph processor-subsystem
A[Nios V/g Processor]
A <--> C[On-Chip RAM II]
A <--> D[JTAG UART]
A ---> F[System ID]
A <--->|custom instruction interface| E[CRC PE]
end
end
Z --> processor-subsystem
Y --> processor-subsystemNios® V/g Processor IP¶
- General-purpose 32-bit CPU for high performance applications with larger logic area utilization.
- Implements RV32IMZicsr_Zicbom instruction set (optionally with “F” and "Smclic" extension) instruction set.
- Supports five-stages pipelined datapath.
- It is a customizable soft-core processor, that can be tailored to meet specific application requirements, providing flexibility and scalability in embedded system designs.
Embedded Peripheral IP Cores¶
The following embedded peripheral IPs are used in this design:
- On-Chip RAM II IP
- JTAG UART IP
- System ID IP
System Components¶
The following components are used in this design:
- Clock Source (Clock Bridge connected to PIN_G26)
- Reset Source (Reset Release IP)
Nios® V Processor Address Map Details¶
| Address Offset | Size (Bytes) | Peripheral | Description |
|---|---|---|---|
| 0x0000_0000 | 650KB | On-Chip RAM | To store application |
| 0x0011_0040 | 8 | JTAG UART | Communication between a host PC and the Nios V processor system |
| 0x0021_2040 | 8 | System ID | Hardware configuration system ID (0xA6B7C8D9) |
Development Kit Setup¶
Refer to Agilex® 7 FPGA F-Series Development Kit User Guide to setup the development kit.
Exercising Prebuilt Binaries¶
Program Hardware Binary SOF¶
- Connect the development kit to the host PC using USB Blaster II.
- Change the JTAG clock frequency to 6 MHz, and probe the JTAGServer to get the JTAG scan chain.
- Execute the quartus_pgm command to program the SOF file with the correct device number. Based on the JTAG scan chain below, the FPGA is at device number 1. You may require to provide a different device number if your JTAG chain is different from the given example.
jtagconfig --setparam 1 JtagClock 6M
jtagconfig -d
quartus_pgm --cable=1 -m jtag -o 'p;ready_to_test/ci_crc.sof@1'
For example:
1) AGF FPGA Development Kit
C341A0DD AGFB014R24A(.|R1|R2)/.. (IR=10)
020D10DD VTAP10 (IR=10)
Design hash 5FDC6B667C01E6ADD7A4
+ Node 0C206E00 JTAG PHY #0
Captured DR after reset = (4BA064770364F0DD020D10DD) [96]
Captured IR after reset = (100555) [24]
Captured Bypass after reset = (0) [3]
Captured Bypass chain = (0) [3]
JTAG clock speed auto-adjustment is enabled. To disable, set JtagClockAutoAdjust parameter to 0
JTAG clock speed 6 MHz
Program Software Image ELF¶
- Ensure that the development kit is successfully configured with the Hardware Binary SOF file.
- Launch the Nios V Command Shell. You may skip this if the shell is active.
- Execute the following command to download the ELF file.
Run Serial Console¶
You may proceed to to display the application printouts, and verify the design.
For example, you should see similar display at the start of the application.
Rebuilding the Design¶
Generate Hardware Binary SOF¶
Run the following command in the terminal from the source directory. Copy the custom IP in the hw directory, and execute the build script. The script performs the following tasks, which generates the hardware binary SOF file of this design.
- Create a new project
- Create a new Platform Designer system
- Configure assignments and constraints
- Compile the project
- Generate a hardware binary SOF file
Generate Software Image ELF¶
After the hardware binary SOF file is ready, you may begin building the software design. It consists of the following steps:
- Create a board support package (BSP) project.
- Create a Nios® V processor application project with the example source codes.
- Build the CRC custom instruction application.
- Generate a software image ELF file.
Launch the Nios V Command Shell. You may skip this if the shell is active. Run the following command in the shell from the source directory.
niosv-shell
niosv-bsp -c --quartus-project=hw/ci_crc.qpf --qsys=hw/sys.qsys --type=hal sw/bsp_crc/settings.bsp
niosv-app --bsp-dir=sw/bsp_crc --app-dir=sw/app_crc --srcs=sw/app_crc/srcs/
cmake -S ./sw/app_crc -G "Unix Makefiles" -B sw/app_crc/build
make -C sw/app_crc/build
Program Hardware Binary SOF¶
- Connect the development kit to the host PC using USB Blaster II.
- Change the JTAG clock frequency to 6 MHz, and probe the JTAGServer to get the JTAG scan chain.
- Execute the quartus_pgm command to program the SOF file with the correct device number. Based on the JTAG scan chain below, the FPGA is at device number 1. You may require to provide a different device number if your JTAG chain is different from the given example.
jtagconfig --setparam 1 JtagClock 6M
jtagconfig -d
quartus_pgm --cable=1 -m jtag -o 'p;hw/output_files/ci_crc.sof@1'
For example:
1) AGF FPGA Development Kit
C341A0DD AGFB014R24A(.|R1|R2)/.. (IR=10)
020D10DD VTAP10 (IR=10)
Design hash 5FDC6B667C01E6ADD7A4
+ Node 0C206E00 JTAG PHY #0
Captured DR after reset = (4BA064770364F0DD020D10DD) [96]
Captured IR after reset = (100555) [24]
Captured Bypass after reset = (0) [3]
Captured Bypass chain = (0) [3]
JTAG clock speed auto-adjustment is enabled. To disable, set JtagClockAutoAdjust parameter to 0
JTAG clock speed 6 MHz
Program Software Image ELF¶
- Ensure that the development kit is successfully configured with the Hardware Binary SOF file.
- Launch the Nios V Command Shell. You may skip this if the shell is active.
- Execute the following command to download the ELF file.
Run Serial Console¶
You may proceed to to display the application printouts, and verify the design.
For example, you should see similar display at the start of the application.
Created: December 12, 2024