From Fedora Project Wiki
(Updates for OpenSBI and new partitioning scheme.)
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This page describes the steps necessary to get Fedora for RISC-V running, either on emulated or real hardware.
This page explains how to get Fedora running on either physical or virtual RISC-V hardware.  


= Obtain and prepare a disk image =
= Disclaimer =


== Tested images ==
riscv64 is currently '''not''' an officially supported Fedora architecture.


You can find them here: https://dl.fedoraproject.org/pub/alt/risc-v/disk-images/fedora/
Most packages are built from unmodified Fedora sources, but in several cases architecture-specific patches are necessary. There is an ongoing effort to reduce (and eventually eliminate) this delta. Check out the [https://abologna.gitlab.io/fedora-riscv-tracker/ tracker] to see the current status.


Download <code>Fedora-Developer-Rawhide-*.raw.xz</code> as well as <code>fw_payload-uboot-qemu-virt-smode.elf</code>.
Hardware support is limited to what mainline Linux provides, and that usually doesn't include the SoC's integrated GPU. Fedora RISC-V is primarily intended to be used as a headless build host / server environment for now.


These disk images:
= Generic instructions =
* contain a partitioned disk;
* have SELinux set to enforcing=1;
* have restored default SELinux security context (<code>restorecon -Rv /</code>);
* kernel, initramfs, config and BBL are available as separate downloads;
* have been booted in QEMU/libvirt a few times to verify.


If you are not sure which image to choose, go with this one.
The following installation steps are applicable to most hardware.


== Nightly builds ==
If your machine is listed in the [[#Machine-specific instructions|machine-specific instructions]] section below, make sure you check out the corresponding page first, as it might contain important information that (partially or completely) supersedes what's written here.


You can find them here: http://fedora.riscv.rocks/koji/tasks?state=closed&view=flat&method=createAppliance&order=-id
== Requirements ==


Select the most recent (top) build and download <code>Fedora-Developer-Rawhide-*.raw.xz</code>.
=== Serial console access ===


These disk images differ from the ones above in that:
While <code>ssh</code> is likely going to be the primary way you'll interact with the machine, it's useful to have serial console access as a fallback. Moreover, it is '''required''' for the initial setup.
* the firmware is inside the disk image, in the <code>/boot</code> directory;
* they are completely untested.


== Uncompress the image ==
The process of connecting the USB to serial adapter is machine-specific and can't be documented in a generic fashion.


Whether you have downloaded a tested image or a nightly build, you'll need to uncompress it before it can be used:
First of all, make sure your user is in the <code>dialout</code> group:


<pre>
<pre>
$ unxz Fedora-Developer-Rawhide-*.raw.xz
$ sudo usermod -a -G dialout $(whoami)
</pre>
</pre>


== Optional: expand the disk image ==
This is necessary to access the serial console. Log out and back in for the change to take effect.


You might want to expand the disk image before setting up the VM. Here is one example:
Now plug the USB to serial adapter into your computer. If you only have one such adapters connected, it should show up as <code>/dev/ttyUSB0</code>.
 
Create a configuration file for <code>minicom</code>, with the name you like, for example <code>~/.minirc.RISCV</code>. The contents should look like this:


<pre>
<pre>
truncate -r Fedora-Developer-Rawhide-*.raw expanded.raw
pu port            /dev/ttyUSB0
truncate -s 40G expanded.raw
pu baudrate        115200
virt-resize -v -x --expand /dev/sda2 Fedora-Developer-Rawhide-*.raw expanded.raw
pu bits            8
virt-filesystems --long -h --all -a expanded.raw
pu parity          N
virt-df -h -a expanded.raw
pu stopbits        1
pu rtscts          No
</pre>
</pre>


The resulting disk image will work with QEMU as well as TinyEMU. Make sure you use <code>expanded.raw</code> instead of <code>Fedora-Developer-Rawhide-*.raw</code> when booting the guest.
You will now be able to connect to the serial console by running:
 
== Optional: create an overlay ==
 
You can also create <code>qcow2</code> disk image with <code>raw</code> Fedora disk as backing one. This way Fedora <code>raw</code> is unmodified and all changes are written to <code>qcow2</code> layer. You will need to install <code>libguestfs-tools-c</code>.


<pre>
<pre>
qemu-img create -f qcow2 -F raw -b Fedora-Developer-Rawhide-*.raw overlay.qcow2 20G
$ minicom RISCV
virt-resize -v -x --expand /dev/sda2 Fedora-Developer-Rawhide-*.raw overlay.qcow2
virt-filesystems --long -h --all -a overlay.qcow2
</pre>
</pre>


The resulting disk image will only work with QEMU. Make sure you use <code>overlay.qcow2</code> instead of <code>Fedora-Developer-Rawhide-*.raw</code> when booting the guest.
For added reliability, you can use a stable device name in the configuration file. For example:
 
== Optional: set the hostname before booting ==
 
If you want to change hostname before the first boot, install <code>libguestfs-tools-c</code> and then run:


<pre>
<pre>
virt-customize -a Fedora-Developer-Rawhide-*.raw --hostname fedora-riscv-mymagicbox
$ ls -l /dev/serial/by-id/*
/dev/serial/by-id/usb-Silicon_Labs_CP2102_USB_to_UART_Bridge_Controller_0001-if00-port0 -> ../../ttyUSB0
</pre>
</pre>


== Nightly builds only: extracting firmware (OpenSBI) ==
This output indicates that you should replace <code>/dev/ttyUSB0</code> with <code>/dev/serial/by-id/usb-Silicon_Labs_CP2102_USB_to_UART_Bridge_Controller_0001-if00-port0</code> in the configuration file.
 
Fedora/RISC-V does not support BLS (Boot Loader Specification - [https://fedoraproject.org/wiki/Changes/BootLoaderSpecByDefault more details]).
 
Disk images contain a <code>/boot</code> directory from where you can copy out the firmware.
 
This is '''only''' necessary for nightly builds, since for tested images these files are provided as separate downloads alongside the image.
 
Example session:
 
<pre>
$ export LIBGUESTFS_BACKEND=direct
$ guestfish \
  add Fedora-Developer-Rawhide-*.raw : run : mount /dev/sda1 / : \
  ls /opensbi/unstable
fw_jump.elf
fw_payload-5.2.0-0.rc7.git0.1.0.riscv64.fc31.riscv64.elf
fw_payload-uboot-qemu-virt-smode.elf
$ guestfish \
  add Fedora-Developer-Rawhide-*.raw : run : mount /dev/sda1 / : \
  download /opensbi/unstable/fw_payload-uboot-qemu-virt-smode.elf fw_payload-uboot-qemu-virt-smode.elf
</pre>


You can also use <code>guestmount</code> or QEMU/NBD to mount disk image. Examples:
== Media preparation ==
<pre>
$ mkdir a
$ guestmount -a $PWD/Fedora-Developer-Rawhide-*.raw -m /dev/sda1 $PWD/a
$ cp a/opensbi/unstable/fw_payload-uboot-qemu-virt-smode.elf .
$ guestunmount $PWD/a
</pre>


<pre>
=== Downloading the disk image ===
$ sudo modprobe nbd max_part=8
$ sudo qemu-nbd -f raw --connect=/dev/nbd1 $PWD/Fedora-Developer-Rawhide-*.raw
$ sudo fdisk -l /dev/nbd1
Disk /dev/nbd1: 7.5 GiB, 8053063680 bytes, 15728640 sectors
Units: sectors of 1 * 512 = 512 bytes
Sector size (logical/physical): 512 bytes / 512 bytes
I/O size (minimum/optimal): 512 bytes / 512 bytes
Disklabel type: gpt
Disk identifier: F0F4268F-1B73-46FF-BABA-D87F075DCCA5


Device      Start      End  Sectors  Size Type
Disk images can be obtained from:
/dev/nbd1p1  2048 15001599 14999552  7.2G Linux filesystem
$ sudo mount /dev/nbd1p1 a
$ sudo cp a/opensbi/unstable/fw_payload-uboot-qemu-virt-smode.elf .
$ sudo umount a
$ sudo qemu-nbd --disconnect /dev/nbd1
</pre>


Note NBD is highly useful if you need to run <code>fdisk</code>,  <code>e2fsck</code> (e.g. after VM crash and filesystem lock up), <code>resize2fs</code>. It might be beneficial to look into <code>nbdkit</code> and <code>nbd</code> packages.
* https://dl.fedoraproject.org/pub/alt/risc-v/release/41/Server/riscv64/images/


= Boot the image on virtual hardware =
As of this writing, the most recent disk image is:


There are several options for booting the image on virtual hardware once you've prepared it following the steps above.
* [https://dl.fedoraproject.org/pub/alt/risc-v/release/41/Server/riscv64/images/Fedora-Server-Host-Generic-41.20250224-1026a2d0e311.riscv64.raw.xz <code>Fedora-Server-Host-Generic-41.20250224-1026a2d0e311.riscv64.raw.xz</code>]


== Boot with libvirt ==
The file you've just downloaded will be referred to as <code>IMAGE.raw.xz</code> below.


Detailed instructions how to install libvirt: https://docs.fedoraproject.org/en-US/quick-docs/getting-started-with-virtualization/
A matching <code>IMAGE.raw.xz.sha256</code> file is also provided: this allows you to validate the integrity of your download.


Quick instructions for libvirt installation (tested on Fedora 30):
=== Writing the disk image to the target media ===


<pre>
The disk image is intended to work regardless of the type of media it's written to: SD cards, USB sticks, NVMe and SATA drives are all known to work. NVMe is preferred, if available on your machine, because it performs the best, but you can choose whatever is more suitable to you. SD cards, for example, are great when you want to test a disk image without affecting your existing installation.
dnf group install --with-optional virtualization
systemctl enable --now libvirtd
</pre>


When running RISC-V guests, it's usually a good idea to use the very latest versions of QEMU, libvirt and virt-manager: the <code>virt-preview</code> repository offers just that for Fedora users. To enable it, simply run:
The disk image comes compressed, so the first step after downloading it is to uncompress it:


<pre>
<pre>
dnf copr enable @virtmaint-sig/virt-preview
$ unxz IMAGE.raw.xz
</pre>
</pre>


and update your system.
The compressed <code>IMAGE.raw.xz</code> file will be replaced by the uncompressed <code>IMAGE.raw</code> file. The latter is the one that can be written to the target media.
 
The steps below assume you have copied both the disk image and the firmware into <code>/var/lib/libvirt/images</code>: this is the location where libvirt usually expects to find disk images, so while using a different location might work it's a good idea to do this and reduce the possibility of issues caused by filesystem permissions and such.


Assuming you have QEMU &ge; 4.0.0, libvirt &ge; 5.3.0 and virt-manager &ge; 2.2.0, the installation will be as simple as:
There are several tools that can be used for writing the disk image. <code>dd</code> is perhaps the most common option:


<pre>
<pre>
# virt-install \
$ sudo dd iflag=fullblock oflag=direct status=progress bs=4M if=IMAGE.raw of=/dev/TARGET
  --name fedora-riscv \
  --arch riscv64 \
  --vcpus 8 \
  --memory 2048 \
  --os-variant fedora30 \
  --boot kernel=/var/lib/libvirt/images/fw_payload-uboot-qemu-virt-smode.elf \
  --import --disk path=/var/lib/libvirt/images/Fedora-Developer-Rawhide-*.raw \
  --network network=default \
  --graphics none
</pre>
</pre>


If you are stuck with older software (QEMU &ge; 2.12.0, libvirt &ge; 4.7.0), then you're going to need a more verbose command line:
Replace `/dev/TARGET` with the name of the actual target device. Please be '''extremely careful''' and ensure that you're using the correct name here: if you get it wrong, you risk '''destroying''' your current OS.
 
<pre>
# virt-install \
  --name fedora-riscv \
  --arch riscv64 \
  --machine virt \
  --vcpus 8 \
  --memory 2048 \
  --os-variant fedora30 \
  --boot kernel=/var/lib/libvirt/images/fw_payload-uboot-qemu-virt-smode.elf \
  --import --disk path=/var/lib/libvirt/images/Fedora-Developer-Rawhide-*.raw,bus=virtio \
  --network network=default,model=virtio \
  --rng device=/dev/urandom,model=virtio \
  --channel name=org.qemu.guest_agent.0 \
  --graphics none
</pre>


Additionally, when using older software components you won't get PCI support, and so enabling graphics will not be possible.
[https://etcher.balena.io/ balenaEtcher] is another popular option. It's a user-friendly GUI that should make it a lot harder to mess things up.


Either one of the commands above will automatically boot you into the console. If you don't want that add <code>--noautoconsole</code> option. You can later use <code>virsh</code> tool to manage your VM and get to console.
== First boot ==


A quick reference of <code>virsh</code> commands:
Once the disk image has been written to the target media, you can pop that into your machine and power it on.
* <code>virsh list --all</code> - list all VMs and their states
* <code>virsh console <name></code> - connect to serial console (remember: <code>Escape character is ^]</code>)
* <code>virsh shutdown <name></code> - power down VM (see above for more details)
* <code>virsh start <name></code> - power up VM
* <code>virsh undefine <name></code> - remove VM
* <code>virsh net-list</code> - list network (useful for the next command)
* <code>virsh net-dhcp-leases <network_name></code> - list DHCP leases, <code><network_name></code> most likely will be <code>default</code>. This is useful when you want to get IPv4 and SSH to the VM.
* <code>virsh domifaddr <name></code> - alternative for the above two commands, only shows IPv4 for one VM
* <code>virsh reset <name></code> - hard reset VM
* <code>virsh destroy <name></code> hard power down of VM


If you want to use <code>ssh user@virtualMachine</code> you can setup libvirt NSS module. See: https://wiki.libvirt.org/page/NSS_module
The process of getting the firmware to boot from the media is machine-specific and can't be documented in a generic fashion. It usually helps if only one media is connected to the machine at any given time.


You might want also to setup logging for serial console (in case kernel panics or something else).
Assuming everything is fine, after a few seconds you should see the usual Linux boot messages scroll by on the serial console.


For this we will be using two commands: <code>virsh edit <name></code> (modifying VM XML) and <code>virsh dumpxml <name></code> (dump VM XML for backup). You need to modify <code><serial></code> node by adding <code><log file='/var/log/libvirt/qemu/fedora-riscv-mymagicbox.serial.log'/></code>. Then power down and power up the VM.
After a short while, you will be presented with a login prompt. You can use login `fedora` and password `linux` to gain access.


Alternatively you can use <code>--serial log.file=/.../whatever.serial.log</code> with <code>virt-install</code> command.
== Post-installation tasks ==


== Boot under QEMU ==
=== Enable the performance CPU governor ===


You will get the best results if your QEMU version is 4.0.0 or newer, but any version since 2.12.0 will work.
The default CPU governor is `schedutils`, which scales the CPU frequency dynamically. If you want to squeeze every last bit of performance out of your machine, you might want to switch to the `performance` CPU governor. To do so, simply run:


<pre>
<pre>
qemu-system-riscv64 \
$ sudo grubby --update-kernel=ALL --args=cpufreq.default_governor=performance
    -nographic \
    -machine virt \
    -smp 8 \
    -m 2G \
    -kernel fw_payload-uboot-qemu-virt-smode.elf \
    -object rng-random,filename=/dev/urandom,id=rng0 \
    -device virtio-rng-device,rng=rng0 \
    -device virtio-blk-device,drive=hd0 \
    -drive file=Fedora-Developer-Rawhide-*.raw,format=raw,id=hd0 \
    -device virtio-net-device,netdev=usernet \
    -netdev user,id=usernet,hostfwd=tcp::10000-:22
</pre>
</pre>


Once machine is booted you can connect via SSH:
A reboot is necessary for the change to take effect.


<pre>
=== Disable use of tmpfs for /tmp ===
ssh -p 10000 -o UserKnownHostsFile=/dev/null -o StrictHostKeyChecking=no -o PreferredAuthentications=password -o PubkeyAuthentication=no root@localhost
</pre>


== Boot under TinyEMU (RISCVEMU) ==
Fedora uses `tmpfs` for `/tmp` by default, but that might cause issues if your machine doesn't have much RAM. If you run into OOMs or other related issues, you can revert to disk-backed `/tmp` by running:
'''Note (2019 March 10):''' This is not supported anymore until TinyEMU is updated to support external initrd file. Please, use QEMU or libvirt/QEMU.
 
RISCVEMU recently (2018-09-23) was renamed to TinyEMU (https://bellard.org/tinyemu/).
 
TinyEMU allow booting Fedora disk images in TUI and GUI modes. You can experiment using JSLinux (no need to download/compile/etc) here: https://bellard.org/jslinux/
 
Below are instructions how to boot Fedora into X11/Fluxbox GUI mode.
 
'''Step 1'''. Compile TinyEMU:


<pre>
<pre>
wget https://bellard.org/tinyemu/tinyemu-2018-09-23.tar.gz
$ sudo systemctl mask tmp.mount
tar xvf tinyemu-2018-09-23.tar.gz
cd tinyemu-2018-09-23
make
</pre>
</pre>


'''Step 2'''. Setup for booting Fedora:
A reboot is necessary for the change to take effect.
 
<pre>
mkdir fedora
cd fedora
cp ../temu .
 
# Download pre-built BBL with embedded kernel
wget https://bellard.org/jslinux/bbl64-4.15.bin


# Create configuration file for TinyEMU
=== Enable haveged ===
cat <<EOF > root-riscv64.cfg
/* VM configuration file */
{
    version: 1,
    machine: "riscv64",
    memory_size: 1400,
    bios: "bbl64-4.15.bin",
    cmdline: "loglevel=3 console=tty0 root=/dev/vda rw TZ=${TZ}",
    drive0: { file: "Fedora-Developer-Rawhide-*-sda1.raw" },
    eth0: { driver: "user" },
    display0: {
        device: "simplefb",
        width: 1920,
        height: 1080,
    },
    input_device: "virtio",
}
EOF
 
# Download disk image and unpack in the same directory
</pre>


'''Step 3'''. Boot it.
If your machine doesn't have a hardware RNG, it might take a long time to boot or accept ssh logins. A possible workaround is to configure a software RNG like so:


<pre>
<pre>
./temu -rw root-riscv64.cfg
$ sudo dnf install -y haveged
$ sudo systemctl enable --now haveged.service
</pre>
</pre>


We need to use <code>-rw</code> if we want our changes to persist in disk image. Otherwise disk image will be loaded as read-only and all changes will not persist after reboot.
= Machine-specific instructions =
 
= Boot the image on physical hardware =
 
== Install on the HiFive Unleashed SD card ==
 
These are instructions for the [https://www.sifive.com/products/hifive-unleashed/ HiFive Unleashed board].
 
The disk image (above) is partitioned, but usually we need an unpartitioned ("naked") filesystem.  There are several ways to get this, but the easiest is:
 
<pre>
$ guestfish -a Fedora-Developer-Rawhide-*-sda.raw \
    run : download /dev/sda1 Fedora-Developer-Rawhide-*-sda1.raw
</pre>
 
This creates a naked ext4 filesystem called <code>*-sda1.raw</code>.  The naked ext4 filesystem can be copied over the second partition of the SD card.
 
You can also build a custom bbl+kernel+initramfs to boot directly into the SD card using [https://github.com/rwmjones/fedora-riscv-kernel these sources].
 
== Install on the HiFive Unleashed using NBD server ==
 
Look at https://github.com/rwmjones/fedora-riscv-kernel in the <code>sifive_u540</code> branch.  This is quite complex to set up so it's best to ask on the <code>#fedora-riscv</code> IRC channel.
 
== Install Fedora GNOME Desktop on SiFive HiFive Unleashed + Microsemi HiFive Unleashed Expansion board ==
 
Detailed instructions are provided by Atish Patra from Western Digital Corporation (WDC). See their GitHub page for details and pictures: https://github.com/westerndigitalcorporation/RISC-V-Linux
 
So far two GPUs are confirmed to be working: Radeon HD 6450 and Radeon HD 5450.


= Use the image =
While the information above is generally applicable, some machines require additional or even completely different steps.


Once the system is booted, login as <code>root</code> with <code>riscv</code> as password.
== Physical hardware ==


X11 with Fluxbox can be started using: <code>startx /usr/bin/startfluxbox</code>. The disk image also includes awesome and i3 for testing. Dillo is available as a basic web browser (no javascript support) and pcmanfm as file manager.
* [[Architectures/RISC-V/StarFive/VisionFive2|StarFive VisionFive 2]]
* [[Architectures/RISC-V/SiFive/HiFiveUnmatched|SiFive HiFive Unmatched]]
* [[Architectures/RISC-V/SiFive/HiFivePremierP550|SiFive HiFive Premier P550]]


To gracefully shutdown just type <code>poweroff</code> into console.
== Virtual hardware ==


If you want more information being displayed during boot, remove <code>quiet</code> from the <code>append</code> line in <code>/boot/extlinux/extlinux.conf</code>.
* [[Architectures/RISC-V/QEMU|QEMU]]

Latest revision as of 10:55, 26 February 2025

This page explains how to get Fedora running on either physical or virtual RISC-V hardware.

Disclaimer

riscv64 is currently not an officially supported Fedora architecture.

Most packages are built from unmodified Fedora sources, but in several cases architecture-specific patches are necessary. There is an ongoing effort to reduce (and eventually eliminate) this delta. Check out the tracker to see the current status.

Hardware support is limited to what mainline Linux provides, and that usually doesn't include the SoC's integrated GPU. Fedora RISC-V is primarily intended to be used as a headless build host / server environment for now.

Generic instructions

The following installation steps are applicable to most hardware.

If your machine is listed in the machine-specific instructions section below, make sure you check out the corresponding page first, as it might contain important information that (partially or completely) supersedes what's written here.

Requirements

Serial console access

While ssh is likely going to be the primary way you'll interact with the machine, it's useful to have serial console access as a fallback. Moreover, it is required for the initial setup.

The process of connecting the USB to serial adapter is machine-specific and can't be documented in a generic fashion.

First of all, make sure your user is in the dialout group: 

$ sudo usermod -a -G dialout $(whoami)

This is necessary to access the serial console. Log out and back in for the change to take effect.

Now plug the USB to serial adapter into your computer. If you only have one such adapters connected, it should show up as /dev/ttyUSB0.

Create a configuration file for minicom, with the name you like, for example ~/.minirc.RISCV. The contents should look like this: 

pu port             /dev/ttyUSB0
pu baudrate         115200
pu bits             8
pu parity           N
pu stopbits         1
pu rtscts           No

You will now be able to connect to the serial console by running: 

$ minicom RISCV

For added reliability, you can use a stable device name in the configuration file. For example: 

$ ls -l /dev/serial/by-id/*
/dev/serial/by-id/usb-Silicon_Labs_CP2102_USB_to_UART_Bridge_Controller_0001-if00-port0 -> ../../ttyUSB0

This output indicates that you should replace /dev/ttyUSB0 with /dev/serial/by-id/usb-Silicon_Labs_CP2102_USB_to_UART_Bridge_Controller_0001-if00-port0 in the configuration file.

Media preparation

Downloading the disk image

Disk images can be obtained from:

As of this writing, the most recent disk image is:

The file you've just downloaded will be referred to as IMAGE.raw.xz below.

A matching IMAGE.raw.xz.sha256 file is also provided: this allows you to validate the integrity of your download.

Writing the disk image to the target media

The disk image is intended to work regardless of the type of media it's written to: SD cards, USB sticks, NVMe and SATA drives are all known to work. NVMe is preferred, if available on your machine, because it performs the best, but you can choose whatever is more suitable to you. SD cards, for example, are great when you want to test a disk image without affecting your existing installation.

The disk image comes compressed, so the first step after downloading it is to uncompress it: 

$ unxz IMAGE.raw.xz

The compressed IMAGE.raw.xz file will be replaced by the uncompressed IMAGE.raw file. The latter is the one that can be written to the target media.

There are several tools that can be used for writing the disk image. dd is perhaps the most common option: 

$ sudo dd iflag=fullblock oflag=direct status=progress bs=4M if=IMAGE.raw of=/dev/TARGET

Replace /dev/TARGET with the name of the actual target device. Please be extremely careful and ensure that you're using the correct name here: if you get it wrong, you risk destroying your current OS.

balenaEtcher is another popular option. It's a user-friendly GUI that should make it a lot harder to mess things up.

First boot

Once the disk image has been written to the target media, you can pop that into your machine and power it on.

The process of getting the firmware to boot from the media is machine-specific and can't be documented in a generic fashion. It usually helps if only one media is connected to the machine at any given time.

Assuming everything is fine, after a few seconds you should see the usual Linux boot messages scroll by on the serial console.

After a short while, you will be presented with a login prompt. You can use login fedora and password linux to gain access.

Post-installation tasks

Enable the performance CPU governor

The default CPU governor is schedutils, which scales the CPU frequency dynamically. If you want to squeeze every last bit of performance out of your machine, you might want to switch to the performance CPU governor. To do so, simply run: 

$ sudo grubby --update-kernel=ALL --args=cpufreq.default_governor=performance

A reboot is necessary for the change to take effect.

Disable use of tmpfs for /tmp

Fedora uses tmpfs for /tmp by default, but that might cause issues if your machine doesn't have much RAM. If you run into OOMs or other related issues, you can revert to disk-backed /tmp by running: 

$ sudo systemctl mask tmp.mount

A reboot is necessary for the change to take effect.

Enable haveged

If your machine doesn't have a hardware RNG, it might take a long time to boot or accept ssh logins. A possible workaround is to configure a software RNG like so: 

$ sudo dnf install -y haveged
$ sudo systemctl enable --now haveged.service

Machine-specific instructions

While the information above is generally applicable, some machines require additional or even completely different steps.

Physical hardware

Virtual hardware

Retrieved from "https://fedoraproject.org/w/index.php?title=Architectures/RISC-V/Installing&oldid=731248"