Building and Running Benchmarks
This section recommends a development environment setup. The subsequent sections will assume that this setup is used. Please change according to your personal preferences.
📦~ (or any working directory)
┣ 📂gem5
┗ 📂riscv
┣ 📂bin: RISC-V tool binaries (e.g. GNU-toolchain, QEMU etc.)
┣ 📂logs: gem5 simulation logs
┣ 📂out: build outputs (kernel / bootloader / devicetree / disk image)
┗ 📂src
┣ 📂linux: Linux kernel repo
┣ 📂pk: RISC-V proxy kernel (bbl bootloader)
┣ 📂qemu: QEMU emulator
┣ 📂toolchain: RISC-V GNU toolchain
┗ 📂ucanlinux: UCanLinux disk image
┗ 📂benchmarks
┗ 📂parsec: PARSEC 3.0 benchmark for RISC-V
Add these environment variables for easier navigation:
# Add to ~/.bashrc, replace paths if desired
export RISCV=~/riscv
export PATH=$RISCV/bin:$PATH
export G5=~/gem5
export SRC=$RISCV/src
export OUT=$RISCV/outSetup by running:
mkdir -p $RISCV/bin
mkdir -p $RISCV/out
mkdir -p $RISCV/srcThe RISC-V GNU Toolchain is used for cross-compiling and debugging RISC-V code.
sudo apt-get install -y autoconf automake autotools-dev curl python3 libmpc-dev libmpfr-dev libgmp-dev gawk build-essential bison flex texinfo gperf libtool patchutils bc zlib1g-dev libexpat-dev
git clone https://github.com/riscv/riscv-gnu-toolchain $SRC/toolchain
cd $SRC/toolchain
./configure --prefix=$RISCV --enable-multilib
make linux -j$(nproc)
# You will need this to compile things like PARSEC and riscv-tests
make newlib -j$(nproc)If you encounter problems building the RISC-V toolchain (e.g. failure to download riscv-newlib due to proxy), replace
url = git://sourceware.org/git/newlib-cygwin.gitin.gitmoduleswithurl = ../riscv-newlib
QEMU can be used to quickly verify that binaries / disk images / kernels are valid before running / debugging in gem5.
sudo apt-get install -y git libglib2.0-dev libfdt-dev libpixman-1-dev zlib1g-dev ninja-build
git clone https://git.qemu.org/git/qemu.git $SRC/qemu
cd $SRC/qemu
./configure --target-list=riscv64-softmmu --prefix=$RISCV
make -j$(nproc)
make installUbuntu 18.04:
sudo apt install build-essential git m4 scons zlib1g zlib1g-dev libprotobuf-dev protobuf-compiler libprotoc-dev libgoogle-perftools-dev python-dev python-six python libboost-all-dev pkg-config python3 python3-dev python3-sixUbuntu 20.04:
sudo apt install -y build-essential git m4 scons zlib1g zlib1g-dev libprotobuf-dev protobuf-compiler libprotoc-dev libgoogle-perftools-dev python3-dev python3-six python-is-python3 libboost-all-dev pkg-configRefer to the official documentation for more advanced options.
The syntax for building gem5 binaries is LIKELY TO CHANGE soon, please refer to the official website (and raise an issue here!) if any problems are encountered.
git clone https://gem5.googlesource.com/public/gem5 $G5
# Uncomment if you want to contribute to gem5
# cd $G5 && git checkout develop
# Uncomment if you have anaconda3 installed (or non-deault python interpreter)
# export PATH=/usr/bin:$PATH
cd $G5 && scons build/RISCV/gem5.opt -j$(nproc)You can download the prebuilt binaries from the prebuilt folder. They should work out of the box (copy them in $OUT directory). In case you want to build them yourself, follow the instructions below:
- Personally, I manually edit the
kernel.configfile to setCONFIG_DEBUG_KERNEL=y. I am not sure if that has any effect on the Linux kernel but just in case. - UCanLinux repo has a pre-built disk image, which is the same as this
- The other disk in this repo contains the PARSEC 3.0
blackscholesbenchmark, see Benchmark Guide.md for more info.
git clone https://github.com/UCanLinux/riscv64-sample.git $SRC/ucanlinux
cp $SRC/ucanlinux/riscv_disk $OUTFeel free to use newer versions of the kernel, but v5.10 has been tested to work.
git clone https://github.com/torvalds/linux.git $SRC/linux
cd $SRC/linux
git checkout v5.10
cp $SRC/ucanlinux/kernel.config .config
make ARCH=riscv CROSS_COMPILE=riscv64-unknown-linux-gnu- olddefconfig
make ARCH=riscv CROSS_COMPILE=riscv64-unknown-linux-gnu- all -j$(nproc)
cp vmlinux $OUT- The Berkeley Bootloader is used to load the Linux kernel, see the SiFive blog for its inner workings.
- bbl expects the hart uid and devicetree address to be stored in registers
a0anda1respectively when loaded. The devicetree generation and register value settings are handled by gem5, see Full System Linux Guide.md for more info.
sudo apt-get install -y device-tree-compiler
git clone https://github.com/riscv/riscv-pk.git $SRC/pk
mkdir -p $SRC/pk/build
cd $SRC/pk/build
../configure --host=riscv64-unknown-linux-gnu --with-payload=$OUT/vmlinux --prefix=$RISCV
CFLAGS="-g" make -j$(nproc)
make install
cp bbl $OUTHere are the commands for running QEMU full system for verification:
# Single core
# Multicore
qemu-system-riscv64 -nographic -smp 2 -machine virt -bios none -kernel $OUT/bbl2 -append 'root=/dev/vda ro console=ttyS0' -drive file=$OUT/riscv_disk,format=raw,id=hd0 -device virtio-blk-device,drive=hd0
# Dump DTB for inspection
qemu-system-riscv64 -nographic -machine virt -machine dumpdtb=dtb.dtbAppend -s -S to the commands to wait for remote GDB connection, then run:
riscv64-unknown-linux-gnu-gdb $OUT/bbl
# In GDB shell
add-symbol-file ~/riscv/out/vmlinux
target remote :1234# DTB to DTS
dtc -I dtb -O dts xxx.dtb > xxx.dts
# DTS to DTB
dtc -I dts -O dtb xxx.dts > xxx.dtb- Use
fdtdumpto check dtb header info - Use
hexcurseor other hex editors to edit dtb header info (e.g. some libraries might have bugs that require manually changing thelast_comp_versionto 2)
There are two scripts in scripts that can be placed into $RISCV/bin. They are examples (templates) of helper scripts to avoid repeatedly typing long commands and settings. Remember to do your chmod +x.
bg5: build gem5 binaryrg5: run gem5 RISC-V full system