366 lines
14 KiB
Markdown
366 lines
14 KiB
Markdown
## Index
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- [Description](#description)
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- [Area usage and maximal frequency](#area-usage-and-maximal-frequency)
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- [Dependencies](#dependencies)
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- [CPU generation](#cpu-generation)
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- [Regression tests](#regression-tests)
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- [Interactive debug of the simulated CPU via GDB OpenOCD and Verilator](#interactive-debug-of-the-simulated-cpu-via-gdb-openocd-and-verilator)
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- [Using eclipse to run the software and debug it](#using-eclipse-to-run-the-software-and-debug-it)
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- [Briey SoC](#briey-soc)
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- [Build the RISC-V GCC](#build-the-risc-v-gcc)
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- [CPU parametrization and instantiation example](#cpu-parametrization-and-instantiation-example)
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- [Add a custom instruction to the CPU via the plugin system](#add-a-custom-instruction-to-the-cpu-via-the-plugin-system)
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## Description
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This repository host an RISC-V implementation written in SpinalHDL. There is some specs :
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- RV32IM instruction set
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- Pipelined on 5 stages (Fetch, Decode, Execute, Memory, WriteBack)
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- 1.16 DMIPS/Mhz when all features are enabled
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- Optimized for FPGA
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- Optional MUL/DIV extension
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- Optional instruction and data caches
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- Optional MMU
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- Optional debug extension allowing GDB debugging via an openOCD JTAG connection
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- Optional interrupts and exception handling with the Machine and the User mode from the riscv-privileged-v1.9.1 spec.
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- Two implementation of shift instructions, Single cycle / shiftNumber cycles
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- Each stage could have bypass or interlock hazard logic
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- FreeRTOS port https://github.com/Dolu1990/FreeRTOS-RISCV
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The hardware description of this CPU is done by using an very software oriented approach
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(without any overhead in the generated hardware). There is a list of software concepts used :
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- There is very few fixed things. Nearly everything is plugin based. The PC manager is a plugin, the register file is a plugin, the hazard controller is a plugin ...
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- There is an automatic a tool which allow plugins to insert data in the pipeline at a given stage, and allow other plugins to read it in another stages through automatic pipelining.
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- There is an service system which provide a very dynamic framework. As instance, a plugin could provide an exception service which could then be used by others plugins to emit exceptions from the pipeline.
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## Area usage and maximal frequency
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The following number where obtains by synthesis the CPU as toplevel without any specific synthesis option to save area or to get better maximal frequency (neutral).
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The used CPU corresponding configuration can be find in src/scala/VexRiscv/demo.
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```
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VexRiscv smallest (RV32I, 0.47 DMIPS/Mhz, no datapath bypass, no interrupt) ->
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Artix 7 -> 324 Mhz 478 LUT 539 FF
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Cyclone V -> 187 Mhz 341 ALMs
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Cyclone IV -> 180 Mhz 736 LUT 529 FF
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Cyclone II -> 156 Mhz 740 LUT 528 FF
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VexRiscv smallest (RV32I, 0.47 DMIPS/Mhz, no datapath bypass) ->
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Artix 7 -> 335 Mhz 560 LUT 589 FF
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Cyclone V -> 182 Mhz 420 ALMs
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Cyclone IV -> 160 Mhz 852 LUT 579 FF
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Cyclone II -> 144 Mhz 844 LUT 578 FF
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VexRiscv small and productive (RV32I, 0.78 DMIPS/Mhz) ->
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Artix 7 -> 330 Mhz 719 LUT 557 FF
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Cyclone V -> 153 Mhz 539 ALMs
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Cyclone IV -> 148 Mhz 1,127 LUT 552 FF
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Cyclone II -> 114 Mhz 1,133 LUT 551 FF
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VexRiscv full (RV32IM, 1.14 DMIPS/Mhz, I$, D$, single cycle barrel shifter, debug module, catch exceptions, static branch) ->
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Artix 7 -> 249 Mhz 1862 LUT 1498 FF
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Cyclone V -> 133 Mhz 1272 ALMs
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Cyclone IV -> 116 Mhz 2727 LUT 1759 FF
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Cyclone II -> 105 Mhz 2771 LUT 1758 FF
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VexRiscv full with MMU (RV32IM, 1.16 DMIPS/Mhz, I$, D$, single cycle barrel shifter, debug module, catch exceptions, dynamic branch, MMU) ->
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Artix 7 -> 210 Mhz 2104 LUT 2017 FF
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Cyclone V -> 115 Mhz 1503 ALMs
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Cyclone IV -> 100 Mhz 3145 LUT 2278 FF
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Cyclone II -> 92 Mhz 3195 LUT 2279 FF
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```
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## Dependencies
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On Ubuntu 14 :
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```sh
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# JAVA JDK 7 or 8
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sudo apt-get install openjdk-7-jdk
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# SBT
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echo "deb https://dl.bintray.com/sbt/debian /" | sudo tee -a /etc/apt/sources.list.d/sbt.list
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sudo apt-key adv --keyserver hkp://keyserver.ubuntu.com:80 --recv 2EE0EA64E40A89B84B2DF73499E82A75642AC823
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sudo apt-get update
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sudo apt-get install sbt
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# Verilator (for sim only)
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sudo apt-get install git make autoconf g++ flex bison
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git clone http://git.veripool.org/git/verilator # Only first time
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unsetenv VERILATOR_ROOT # For csh; ignore error if on bash
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unset VERILATOR_ROOT # For bash
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cd verilator
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git pull # Make sure we're up-to-date
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git tag # See what versions exist
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autoconf # Create ./configure script
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./configure
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make
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sudo make install
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```
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## CPU generation
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You can find two example of CPU instantiation in :
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- src/main/scala/VexRiscv/GenFull.scala
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- src/main/scala/VexRiscv/GenSmallest.scala
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To generate the corresponding RTL as a VexRiscv.v file, run (it could take time the first time you run it):
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NOTE :
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The VexRiscv could need the unreleased master-head of SpinalHDL. If it fail to compile, just get the SpinalHDL repository and do a "sbt publish-local" in it.
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```sh
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sbt "run-main VexRiscv.demo.GenFull"
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# or
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sbt "run-main VexRiscv.demo.GenSmallest"
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```
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## Regression tests
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To run tests (need the verilator simulator), go in the src/test/cpp/regression folder and run :
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```sh
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# To test the GenFull CPU
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make clean run
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# To test the GenSmallest CPU
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make clean run IBUS=IBUS_SIMPLE DBUS=DBUS_SIMPLE CSR=no MMU=no DEBUG_PLUGIN=no MUL=no DIV=no
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```
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## Interactive debug of the simulated CPU via GDB OpenOCD and Verilator
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It's as described to run tests, but you just have to add DEBUG_PLUGIN_EXTERNAL=yes in the make arguments.
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Work for the GenFull, but not for the GenSmallest as this configuration has no debug module.
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Then you can use the https://github.com/SpinalHDL/openocd_riscv tool to create a GDB server connected to the target (the simulated CPU)
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```sh
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#in the VexRiscv repository, to run the simulation on which one OpenOCD can connect itself =>
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sbt "run-main VexRiscv.demo.GenFull"
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cd src/test/cpp/regression
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make run DEBUG_PLUGIN_EXTERNAL=yes
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#In the openocd git, after building it =>
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src/openocd -c "set VEXRISCV_YAML PATH_TO_THE_GENERATED_CPU0_YAML_FILE" -f tcl/target/vexriscv_sim.cfg
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#Run a GDB session with an elf RISCV executable (GenFull CPU)
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YourRiscvToolsPath/bin/riscv32-unknown-elf-gdb VexRiscvRepo/src/test/resources/elf/uart.elf
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target remote localhost:3333
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monitor reset halt
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load
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continue
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# Now it should print messages in the Verilator simulation of the CPU
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```
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## Using eclipse to run the software and debug it
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You can use the eclipse + zilin embedded CDT plugin to do it (http://opensource.zylin.com/embeddedcdt.html). Tested with Helios Service Release 2 and the corresponding zylin plugin.
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## Briey SoC
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As a demonstrator, a SoC named Briey is implemented in src/main/scala/VexRiscv/demo/Briey.scala. This SoC is very similar to the Pinsec one :
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<img src="http://cdn.rawgit.com/SpinalHDL/SpinalDoc/dd17971aa549ccb99168afd55aad274bbdff1e88/asset/picture/pinsec_hardware.svg" align="middle" width="300">
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To generate the Briey SoC Hardware :
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```sh
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sbt "run-main VexRiscv.demo.Briey"
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```
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To run the verilator simulation of the Briey SoC which can be then connected to OpenOCD/GDB, first get those dependencies :
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```sh
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sudo apt-get install build-essential xorg-dev libudev-dev libts-dev libgl1-mesa-dev libglu1-mesa-dev libasound2-dev libpulse-dev libopenal-dev libogg-dev libvorbis-dev libaudiofile-dev libpng12-dev libfreetype6-dev libusb-dev libdbus-1-dev zlib1g-dev libdirectfb-dev libsdl2-dev
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```
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Then go in src/test/cpp/briey and run the simulation with (UART TX is printed in the terminal, VGA is displayed in a GUI):
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```sh
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make clean run
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```
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To connect OpenOCD (https://github.com/SpinalHDL/openocd_riscv) to the simulation :
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```sh
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src/openocd -f tcl/interface/jtag_tcp.cfg -c "set BRIEY_CPU0_YAML /home/spinalvm/Spinal/VexRiscv/cpu0.yaml" -f tcl/target/briey.cfg
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```
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You can find multiples software examples and demo there : https://github.com/SpinalHDL/BrieySoftware
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You can find some FPGA project which instantiate the Briey SoC there (DE1-SoC, DE0-Nano): https://drive.google.com/drive/folders/0B-CqLXDTaMbKZGdJZlZ5THAxRTQ?usp=sharing
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## Build the RISC-V GCC
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To install in /opt/ the rv32i and rv32im gcc, do the following (will take hours):
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```sh
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# Be carefull, sometime the git clone has issue to successfully clone riscv-gnu-toolchain.
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sudo apt-get install autoconf automake autotools-dev curl libmpc-dev libmpfr-dev libgmp-dev gawk build-essential bison flex texinfo gperf libtool patchutils bc zlib1g-dev -y
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git clone --recursive https://github.com/riscv/riscv-gnu-toolchain riscv-gnu-toolchain
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cd riscv-gnu-toolchain
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echo "Starting RISC-V Toolchain build process"
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ARCH=rv32im
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rmdir -rf $ARCH
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mkdir $ARCH; cd $ARCH
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../configure --prefix=/opt/$ARCH --with-arch=$ARCH --with-abi=ilp32
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sudo make -j4
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cd ..
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ARCH=rv32i
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rmdir -rf $ARCH
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mkdir $ARCH; cd $ARCH
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../configure --prefix=/opt/$ARCH --with-arch=$ARCH --with-abi=ilp32
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sudo make -j4
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cd ..
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echo -e "\\nRISC-V Toolchain installation completed!"
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```
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## CPU parametrization and instantiation example
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You can find many example of different config in the https://github.com/SpinalHDL/VexRiscv/tree/master/src/main/scala/VexRiscv/demo folder. There is one :
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```scala
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//Instanciate one VexRiscv
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val cpu = new VexRiscv(
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//Provide a configuration instance
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config = VexRiscvConfig(
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//Provide a list of plugins which will futher add their logic into the CPU
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plugins = List(
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new PcManagerSimplePlugin(
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resetVector = 0x00000000l,
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fastPcCalculation = true
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),
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new IBusSimplePlugin(
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interfaceKeepData = false,
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catchAccessFault = false
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),
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new DBusSimplePlugin(
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catchAddressMisaligned = false,
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catchAccessFault = false
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),
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new DecoderSimplePlugin(
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catchIllegalInstruction = false
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),
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new RegFilePlugin(
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regFileReadyKind = Plugin.SYNC,
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zeroBoot = true
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),
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new IntAluPlugin,
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new SrcPlugin(
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separatedAddSub = false,
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executeInsertion = false
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),
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new LightShifterPlugin,
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new HazardSimplePlugin(
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bypassExecute = false,
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bypassMemory = false,
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bypassWriteBack = false,
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bypassWriteBackBuffer = false
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),
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new BranchPlugin(
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earlyBranch = false,
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catchAddressMisaligned = false,
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prediction = NONE
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),
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new YamlPlugin("cpu0.yaml")
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)
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)
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)
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```
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## Add a custom instruction to the CPU via the plugin system
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There is an example of an simple plugin which add an simple SIMD_ADD instruction :
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```scala
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import spinal.core._
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import VexRiscv.Plugin.Plugin
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import VexRiscv.{Stageable, DecoderService, VexRiscv}
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//This plugin example will add a new instruction named SIMD_ADD which do the following :
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//
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//RD : Regfile Destination, RS : Regfile Source
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//RD( 7 downto 0) = RS1( 7 downto 0) + RS2( 7 downto 0)
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//RD(16 downto 8) = RS1(16 downto 8) + RS2(16 downto 8)
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//RD(23 downto 16) = RS1(23 downto 16) + RS2(23 downto 16)
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//RD(31 downto 24) = RS1(31 downto 24) + RS2(31 downto 24)
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//
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//Instruction encoding :
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//0000011----------000-----0110011
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// |RS2||RS1| |RD |
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//
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//Note : RS1, RS2, RD positions follow the RISC-V spec and are common for all instruction of the ISA
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class SimdAddPlugin extends Plugin[VexRiscv]{
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//Define the concept of IS_SIMD_ADD signals, which specify if the current instruction is destined for ths plugin
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object IS_SIMD_ADD extends Stageable(Bool)
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//Callback to setup the plugin and ask for different services
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override def setup(pipeline: VexRiscv): Unit = {
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import pipeline.config._
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//Retrieve the DecoderService instance
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val decoderService = pipeline.service(classOf[DecoderService])
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//Specify the IS_SIMD_ADD default value when instruction are decoded
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decoderService.addDefault(IS_SIMD_ADD, False)
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//Specify the instruction decoding which should be applied when the instruction match the 'key' parttern
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decoderService.add(
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//Bit pattern of the new SIMD_ADD instruction
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key = M"0000011----------000-----0110011",
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//Decoding specification when the 'key' pattern is recognized in the instruction
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List(
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IS_SIMD_ADD -> True,
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REGFILE_WRITE_VALID -> True, //Enable the register file write
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BYPASSABLE_EXECUTE_STAGE -> True, //Notify the hazard management unit that the instruction result is already accessible in the EXECUTE stage (Bypass ready)
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BYPASSABLE_MEMORY_STAGE -> True, //Same as above but for the memory stage
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RS1_USE -> True, //Notify the hazard management unit that this instruction use the RS1 value
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RS2_USE -> True //Same than above but for RS2.
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)
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)
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}
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override def build(pipeline: VexRiscv): Unit = {
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import pipeline._
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import pipeline.config._
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//Define some signals used internally to the plugin
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val rs1 = execute.input(RS1).asUInt //32 bits UInt value of the regfile[RS1]
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val rs2 = execute.input(RS2).asUInt
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val rd = UInt(32 bits)
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//Do some computation
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rd( 7 downto 0) := rs1( 7 downto 0) + rs2( 7 downto 0)
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rd(16 downto 8) := rs1(16 downto 8) + rs2(16 downto 8)
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rd(23 downto 16) := rs1(23 downto 16) + rs2(23 downto 16)
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rd(31 downto 24) := rs1(31 downto 24) + rs2(31 downto 24)
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//When the instruction is a SIMD_ADD one, then write the result into the register file data path.
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when(execute.input(IS_SIMD_ADD)){
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execute.output(REGFILE_WRITE_DATA) := rd.asBits
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}
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}
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}
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```
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Then if you want to add this plugin to a given CPU, you just need to add it in its parameterized plugin list.
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This example is a very simple one, but each plugin can really have access to the whole CPU
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- Halt a given stage of the CPU
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- Unschedule instructions
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- Emit an exception
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- Introduce new instruction decoding specification
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- Ask to jump the PC somewhere
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- Read signals published by other plugins
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- override published signals values
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- Provide an alternative implementation
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- ... |