Documentation/Platforms/RISCV

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Description

RISC-V is an open source instruction set. It is a modular with only a small set of mandatory instructions. Every other module might be implemented by vendors allowing RISC-V to be suitable for small embedded systems up to large supercomputers.

Build Directions

For RV64:

 ./configure --target-list=riscv64-softmmu && make

For RV32:

 ./configure --target-list=riscv32-softmmu && make

Booting Linux

Booting 64-bit Debian

Follow the instructions on the Debian wiki to boot Debian on QEMU: https://wiki.debian.org/RISC-V

Booting 64-bit Fedora

Download the Fedora prebuilt images from: https://dl.fedoraproject.org/pub/alt/risc-v/repo/virt-builder-images/images/ You will want to download Fedora-Minimal-Rawhide-*-fw_payload-uboot-qemu-virt-smode.elf and Fedora-Minimal-Rawhide-*-sda.raw.xz images

Decompress the rootFS:

  unxz Fedora-Minimal-Rawhide-*-sda.raw.xz

Boot linux using RV64GC qemu:

  qemu-system-riscv64 \
   -nographic \
   -machine virt \
   -smp 4 \
   -m 2G \
   -kernel Fedora-Minimal-Rawhide-*-fw_payload-uboot-qemu-virt-smode.elf \
   -bios none \
   -object rng-random,filename=/dev/urandom,id=rng0 \
   -device virtio-rng-device,rng=rng0 \
   -device virtio-blk-device,drive=hd0 \
   -drive file=Fedora-Minimal-Rawhide-20200108.n.0-sda.raw,format=raw,id=hd0 \
   -device virtio-net-device,netdev=usernet \
   -netdev user,id=usernet,hostfwd=tcp::10000-:22
  • Login: root
  • Password: riscv

For more details on running Fedora see the Fedora Wiki: https://fedoraproject.org/wiki/Architectures/RISC-V/Installing

Booting 32-bit OpenEmbedded Images

Follow the usual OpenEmbedded build flow using meta-riscv to build for the qemuriscv32 machine.

   MACHINE=qemuriscv32 bitbake core-image-minimal; runqemu qemuriscv32

More details on doing this can be found here: https://github.com/riscv/meta-riscv/#build-image

When using OpenEmbedded it is recommended to use the runqemu script to boot QEMU. It will dynamically handle display options as well as advanced networking.

Booting 64-bit OpenEmbedded Images

Follow the usual OpenEmbedded build flow using meta-riscv to build for the qemuriscv64 machine.

   MACHINE=qemuriscv64 bitbake core-image-minimal; runqemu qemuriscv64

More details on doing this can be found here: https://github.com/riscv/meta-riscv/#build-image

When using OpenEmbedded it is recommended to use the runqemu script to boot QEMU. It will dynamically handle display options as well as advanced networking.

Booting 32-bit Buildroot Images

Clone the Buildroot source code and cd into the directory.

Generate the default config:

 make qemu_riscv32_virt_defconfig

Build the images

 make

Boot the images:

 qemu-system-riscv32 \
   -M virt -nographic \
   -bios output/images/fw_jump.elf \
   -kernel output/images/Image \
   -append "root=/dev/vda ro" \
   -drive file=output/images/rootfs.ext2,format=raw,id=hd0 \
   -device virtio-blk-device,drive=hd0 \
   -netdev user,id=net0 -device virtio-net-device,netdev=net0

Booting 64-bit Buildroot Images

Clone the Buildroot source code and cd into the directory.

Generate the default config:

 make qemu_riscv64_virt_defconfig

Build the images

 make

Boot the images:

 qemu-system-riscv64 \
   -M virt -nographic \
   -bios output/images/fw_jump.elf \
   -kernel output/images/Image \
   -append "root=/dev/vda ro" \
   -drive file=output/images/rootfs.ext2,format=raw,id=hd0 \
   -device virtio-blk-device,drive=hd0 \
   -netdev user,id=net0 -device virtio-net-device,netdev=net0

Microchip PolarFire SoC Icicle Kit

QEMU 5.2.0 supports a new machine: Microchip PolarFire SoC Icicle Kit. The Icicle Kit board integrates a PolarFire SoC, with one SiFive's E51 plus four U54 cores and many on-chip peripherals and an FPGA.

For more details about Microchip PolarFire Soc, please see: https://www.microsemi.com/product-directory/soc-fpgas/5498-polarfire-soc-fpga

The Icicle Kit board information can be found here: https://www.microsemi.com/existing-parts/parts/152514

Boot the images:

 qemu-system-riscv64 -M microchip-icicle-kit -smp 5 \
   -bios path/to/hss.bin -sd path/to/sdcard.img \
   -nic user,model=cadence_gem \
   -nic tap,ifname=tap,model=cadence_gem,script=no \
   -display none -serial stdio \
   -chardev socket,id=serial1,path=serial1.sock,server,wait \
   -serial chardev:serial1

The BIOS image used by this machine is hss.bin, aka Hart Software Services, which can be built from: https://github.com/polarfire-soc/hart-software-services

QEMU does not support eMMC hence the SD configuration shall be used in the HSS and Yocto BSP build. The eMMC configuration is not supported.

Instructions to build HSS:

 $ cp boards/icicle-kit-es/def_config.sdcard .config
 $ make BOARD=icicle-kit-es

The following commit of HSS was tested:

 commit 078ce16d8cb3a89e4c3e93916621b816dbdaa274
 Merge: 76b34dd 2cd45c9
 Author: Cyril-Jean <cyril.jean@microchip.com>
 Date:   Fri Oct 9 17:07:12 2020 +0100
 
   Merge pull request #7 from avpatel/custom_boot_flow_v1
 
   Custom boot flow for PolarFire boards

For Yocto build, "MACHINE=icicle-kit-es-sd" should be specified, otherwise when booting Linux kernel the rootfs cannot be mounted. The generated image is something like: mpfs-dev-cli-icicle-kit-es-sd.rootfs.wic. Resize the file with 'qemu-image' to a power of 2 before passing to QEMU '-sd' command line.

The following commands download the official SD card image released by Microchip and prepare it for QEMU usage:

 $ wget ftp://ftpsoc.microsemi.com/outgoing/core-image-minimal-dev-icicle-kit-es-sd-20201009141623.rootfs.wic.gz
 $ gunzip core-image-minimal-dev-icicle-kit-es-sd-20201009141623.rootfs.wic.gz
 $ qemu-img resize core-image-minimal-dev-icicle-kit-es-sd-20201009141623.rootfs.wic 4G

The memory is set to 1537 MiB by default which is the minimum required high memory size by HSS. A sanity check on ram size is performed in the machine init routine to prompt user to increase the RAM size to > 1537 MiB when less than 1537 MiB ram is detected.

HSS output is on the first serial port (stdio) and U-Boot/Linux outputs on the 2nd serial port. OpenSBI outputs on a random serial port due to the lottery mechanism used during the multi-core boot.

Attaching GDB

To attach GDB to a QEMU RISC-V instance with only a single cluster (every machine except the sifive_u) run these commands from GDB:

 target extended-remote :1234
 info threads

To attach GDB to a QEMU RISC-V instance with multiple clusters (the sifive_u) run these commands from GDB:

 target extended-remote :1234
 add-inferior
 inferior 2
 attach 2
 set schedule-multiple
 info threads

The above commands assume the default GDB port exposed from QEMU of 1234. This will happen when you run QEMU with the '-s' command line argument.

If you would like QEMU to not run the guest until you have connected GDB, you can specify the '-S' command line argument as well.

RISC-V Foundation Extensions

As RISC-V has a range of possible extensions, QEMU has guidelines for supporting them all.

If an extension is frozen or ratified by the RISC-V foundation, it can be supported in QEMU. Generally we will try to support as many versions as feasible, following the usual QEMU deprecation policy to remove old versions.

If an official RISC-V foundation extension is in a reasonable draft state, that is not too many changes are still expected, it can be supported experimentally by QEMU. Experimental support means it must be disabled by default and marked with a "x-" in the CPU/board properties. Draft extensions should also include the version information in the property. Draft extensions can be enabled by specific CPUs or boards if the hardware supports that extension.

QEMU will only support the latest version of patches submitted for a draft extension. A draft extension can also be removed at any time and does not follow QEMU's deprecation policy.

RISC-V Custom Extensions/Instructions

Support for custom instruction set extensions are an important part of RISC-V, with large encoding spaces reserved of vendor extensions.

QEMU follows similar rules to the RISC-V toolchain convention, as described here: https://github.com/riscv-non-isa/riscv-toolchain-conventions/pull/17

QEMU will support vendor extensions. Vendor extensions must be disabled by default, but can be enabled for specific vendor CPUs and boards. The vendor extensions should use prefixes and names as described in https://github.com/riscv-non-isa/riscv-toolchain-conventions

Vendor extensions must be maintained and tested by the vendor. Upstream will take efforts to not break extensions, but testing and bug fixes should be done by the vendor. Patches to add support for open source toolchains are unlikely to be accepted without specification documents being made available publicly.

Vendor extensions can not interfere with other extensions and can not be obtrusive to the core RISC-V target code.

If you are looking to add support for vendor extensions, it is recommended that you get involved in the QEMU review process. It is also recommended that you send your patches as early as possible to get community feedback before they are fully implemented. This is especially important if you are modifying core code.

Links

Contacts

Maintainers: