About
Welcome to the Void Handbook! Please be sure to read the "About This
Handbook" section to learn how to use this
documentation effectively. A local copy of this handbook, in several formats,
can be installed via the void-docs
package and accessed
with the void-docs(1) utility.
Void is an independent, rolling release Linux distribution, developed from scratch rather than as a fork, with a focus on stability over bleeding-edge. In addition, there are several features that make Void unique:
- The XBPS package manager, which is extremely fast, developed in-house, and performs checks when installing updates to ensure that libraries are not changed to incompatible versions which can break dependencies.
- The musl libc, which focuses on standards compliance and correctness, has first class support. This allows us to build certain components for musl systems statically, which would not be practical on glibc systems.
- runit is used for init(8) and service supervision. This allows Void to support musl as a second libc choice, which would not be possible with systemd. A side effect of this decision is a core system with clean and efficient operation, and a small code base.
Void is developed in the spare time of a handful of developers, and is generally considered stable enough for daily use. We do this for fun and hope that our work will be useful to others.
The name "Void" comes from the C literal void
. It was chosen rather randomly,
and is void of any meaning.
History
Knowledge of the ancients, grepped from the Git logs themselves:
- 2008-09-26: first Git import of void-packages
- 2009-08-17: first Git import of xbps
- 2011-06-25: first systemd commit in void-packages
- 2013-03-01: first musl toolchains added
- 2014-07-14: begin switching to LibreSSL
- 2014-07-28: switch from systemd to runit
- 2015-07-09: full aarch64 support with
linux4.1
- 2018-07-06: first use of Terraform for GitHub permissions, for increased transparency
- 2021-03-05: begin switching to OpenSSL
About This Handbook
This handbook is not an extensive guide on how to use and configure common Linux software. The purpose of this document is to explain how to install, configure, and maintain Void Linux systems, and to highlight the differences between common Linux distributions and Void.
To search for a particular term within the Handbook, select the 'magnifying glass' icon, or press 's'.
Those looking for tips and tricks on how to configure a Linux system in general should consult upstream software documentation. Additionally, the Arch Wiki provides a fairly comprehensive outline of common Linux software configuration, and a variety of internet search engines are available for further assistance.
Reading The Manuals
While this handbook does not provide a large amount of copy and paste configuration instructions, it does provide links to the man pages for the referenced software wherever possible.
To learn how to use the man(1) man page
viewer, run the command man man
. It can be configured by editing
/etc/man.conf
; read man.conf(5) for
details.
Void uses the mandoc toolset for man pages. mandoc was
formerly known as "mdocml", and is provided by the mdocml
package.
Example Commands
Examples in this guide may have snippets of commands to be run in your shell.
When you see these, any line beginning with $
is run as your normal user.
Lines beginning with #
are run as root
. After either of these lines, there
may be example output from the command.
Placeholders
Some examples include text with placeholders. Placeholders indicate where you should substitute the appropriate information. For example:
# ln -s /etc/sv/<service_name> /var/service/
This means you need to substitute the text <service_name>
with the actual
service name.
InfraDocs
InfraDocs is the meta-manual for the Void project systems management.
Installation
This section includes general information about the process of installing Void. For specific guides, see the "Advanced Installation" section.
Base system requirements
Void can be installed on very minimalist hardware, though we recommend the following minimums for most installations:
Architecture | CPU | RAM | Storage |
---|---|---|---|
x86_64-glibc | x86_64 | 96MB | 700MB |
x86_64-musl | x86_64 | 96MB | 600MB |
i686-glibc | Pentium 4 (SSE2) | 96MB | 700MB |
Note that xfce image installations require more resources.
Void is not available for the i386, i486, or i586 architectures.
Before installing musl Void, please read the "musl" section of this Handbook, so that you are aware of software incompatibilities.
It is highly recommended to have a network connection available during install to download updates, but this is not required. ISO images contain installation data on-disk and can be installed without network connectivity.
Downloading installation media
The most recent live images and rootfs tarballs can be downloaded from https://repo-default.voidlinux.org/live/current/. They can also be downloaded from other mirrors. Previous releases can be found under https://repo-default.voidlinux.org/live/, organized by date.
Verifying images
Each image release's directory contains two files used to verify the image(s)
you download. First, there is a sha256sum.txt
file containing image checksums
to verify the integrity of the downloaded images. Second is the sha256sum.sig
file, used to verify the authenticity of the checksums.
It is necessary to verify both the image's integrity and authenticity. It is, therefore, recommended that you download both files.
Verifying image integrity
You can verify the integrity of a downloaded file using
sha256sum(1) with the sha256sum.txt
file downloaded above. The following command will check the integrity of only
the image(s) you have downloaded:
$ sha256sum -c --ignore-missing sha256sum.txt
void-live-x86_64-musl-20170220.iso: OK
This verifies that the image is not corrupt.
Verifying digital signature
Prior to using any image you're strongly encouraged to validate the signatures on the image to ensure they haven't been tampered with.
Current images are signed using a minisign key that is specific to the release.
If you're on Void already, you can obtain the keys from the void-release-keys
package, which will be downloaded using your existing XBPS trust relationship
with your mirror and package signatures. You will also need a copy of
minisign(1); on Void, this is provided
by the minisign
package.
The minisign
executable is usually provided by a package of the same name, and
can also be installed on Windows, even without WSL or MinGW.
If you are not currently using Void Linux, it will also be necessary to obtain the appropriate signing key from our Git repository here.
Once you've obtained the key, you can verify your image with the sha256sum.sig
and sha256sum.txt
files. First, you need to verify the authenticity of the
sha256sum.txt
file.
The following example demonstrates the verification of the sha256sum.txt
file
for the 20230628 images with minisign
:
$ minisign -V -p /usr/share/void-release-keys/void-release-20230628.pub -x sha256sum.sig -m sha256sum.txt
Signature and comment signature verified
Trusted comment: This key is only valid for images with date 20230628.
Finally, you need to verify that the checksum for your image matches the one in
the sha256sum.txt
file. This can be done with the
sha256(1) utility from the outils
package,
as demonstrated below for the 20230628 x86_64
base image:
$ sha256 -C sha256sum.txt void-live-x86_64-20230628-base.iso
(SHA256) void-live-x86_64-20230628-base.iso: OK
Alternatively, if the sha256
utility isn't available to you, you can use
sha256sum(1):
$ sha256sum -c sha256sum.txt --ignore-missing
void-live-x86_64-20230628-base.iso: OK
If neither program is available to you, you can compute the SHA256 hash of the
file and compare it to the value contained in sha256sum.txt
.
If the verification process does not produce the expected "OK" status, do not use it! Please alert the Void Linux team of where you got the image and how you verified it, and we will follow up on it.
Live Installers
Void provides live installer images containing a base set of utilities, an installer program, and package files to install a new Void system. These live images are also useful for repairing a system that is not able to boot or function properly.
There are x86_64
images for both glibc
and musl
based systems. There are
also images for i686
, but only glibc
is supported for this architecture.
Live installers are not provided for other architectures. Users of other
architectures will need to use rootfs tarballs, or perform an installation
manually.
Installer images
Void releases two types of images: base images and xfce images. Linux beginners are encouraged to try one of the more full-featured xfce images, but more advanced users may often prefer to start from a base image to install only the packages they need.
Base images
The base images provide only a minimal set of packages to install a usable Void system. These base packages are only those needed to configure a new machine, update the system, and install additional packages from repositories.
Xfce image
The xfce image includes a full desktop environment, web browser, and basic applications configured for that environment. The only difference from the base images is the additional packages and services installed.
The following software is included:
- Window manager: xfwm4
- File manager: Thunar
- Web Browser: Firefox
- Terminal: xfce4-terminal
- Plain text editor: Mousepad
- Image viewer: Ristretto
- Other: Bulk rename, Orage Globaltime, Orage Calendar, Task Manager, Parole Media Player, Audio Mixer, MIME type editor, Application finder
The install process for the xfce image is the same as the base images, except
that you must select the Local
source when installing. If you select
Network
instead, the installer will download and install the latest version of
the base system, without any additional packages included on the live image.
Accessibility support
All Void installer images support the console screenreader
espeakup and the console braille display
driver brltty. These services can be
enabled at boot by pressing s
in the bootloader menu to enable accessibility
support. On UEFI-based systems, GRUB is the bootloader, and it will play a
two-tone chime when the menu is available. On BIOS-based systems and UEFI
systems in legacy/compatibility mode, SYSLINUX is the bootloader, and no chime
is played. SYSLINUX also requires pressing the enter key after pressing s
. The
hotkey r
will also boot with accessibility support, but will load the live ISO
into RAM.
After booting into the installer image with accessibility support enabled, if there are multiple soundcards detected, a short audio menu allows for the selection of the soundcard for the screenreader. Press enter when the beep for the desired soundcard is heard to select it.
If the Local
installation source is selected in the installer, espeakup
and
brltty
will also be installed and enabled on the installed system if enabled
in the live environment.
The xfce image also supports the graphical screenreader
orca. This can be enabled by pressing Win + R
and entering orca -r
. Orca will also be available on the installed system
if the Local
installation source is selected.
Kernel Command-line Parameters
Void installer images support several kernel command-line arguments that can change the behavior of the live system. See the void-mklive README for a full list.
Prepare Installation Media
After downloading a live image, it must be written to bootable media, such as a USB drive, SD card, or CD/DVD.
Create a bootable USB drive or SD card on Linux
Identify the Device
Before writing the image, identify the device you'll write it to. You can do this using fdisk(8). After connecting the storage device, identify the device path by running:
# fdisk -l
Disk /dev/sda: 7.5 GiB, 8036286464 bytes, 15695872 sectors
Disk model: Your USB Device's Model
Units: sectors of 1 * 512 = 512 bytes
Sector size (logical/physical): 512 bytes / 512 bytes
I/O size (minimum/optimal): 512 bytes / 512 bytes
In the example above, the output shows the USB device as /dev/sda
. On Linux,
the path to the device will typically be in the form of /dev/sdX
(where X is a
letter) for USB devices, /dev/mmcblkX
for SD cards, or other variations
depending on the device. You can use the model and size (7.5GiB
above, after
the path) to identify the device if you're not sure what path it will have.
Once you've identified the device you'll use, ensure it's not mounted by unmounting it with umount(8):
# umount /dev/sdX
umount: /dev/sdX: not mounted.
Write the live image
The dd(1) command can be used to copy a
live image to a storage device. Using dd
, write the live image to the device:
Warning: this will destroy any data currently on the referenced device. Exercise caution.
# dd bs=4M if=/path/to/void-live-ARCH-DATE-VARIANT.iso of=/dev/sdX
90+0 records in
90+0 records out
377487360 bytes (377 MB, 360 MiB) copied, 0.461442 s, 818 MB/s
dd
won't print anything until it's completed (or if it failed), so, depending
on the device, this can take a few minutes or longer. You can enable printing by
adding status=progress
to the command if using GNU coreutils dd
.
Finally, ensure all data is flushed before disconnecting the device:
$ sync
The number of records, amount copied, and rates will all vary depending on the device and the live image you chose.
Burning to a CD or DVD
Any disk burning application should be capable of writing the .iso
file to a
CD or DVD. The following free software applications are available
(cross-platform support may vary):
It should be noted that, with a CD or DVD, live sessions will be less responsive than with a USB stick or hard drive.
Partitioning Notes
Partitioning for a modern Linux distribution is generally very simple, however the introduction of GPT and UEFI booting does bring new complexity to the process. When creating your new partition table you will need a partition for the root filesystem, along with a swap partition and possibly another partition or two to facilitate booting, if required.
Note that if the disk has already been initialized, the top of the cfdisk
screen will show the partition layout already present: Label: dos
for the MBR
scheme, Label: gpt
for the GPT scheme. If you just want to erase the partition
table before starting the installer, use wipefs(8)
. Otherwise, you can run
cfdisk(8)
manually with the -z
option to start with an uninitialized disk
layout; cfdisk
will prompt you for the label type before continuing to the
main screen.
The following sections will detail the options for partition configuration.
BIOS system notes
It is recommended that you create an MBR partition table if you are using a BIOS boot system. This will limit the number of partitions you create to four.
It is possible to use a GPT partition table on a BIOS system, but GRUB will
require a special partition to boot properly. This partition should be at the
beginning of your disk and have a size of 1MB, with type BIOS boot
(GUID
21686148-6449-6E6F-744E-656564454649
). Don't create any filesystem in it. GRUB
should then install itself successfully.
UEFI system notes
UEFI users are recommended to create a GPT partition table. UEFI booting with
GRUB also requires a special partition of the type EFI System
with a vfat
filesystem mounted at /boot/efi
. A reasonable size for this partition could be
between 200MB and 1GB. With this partition setup during the live image
installation, the installer should successfully set up the bootloader
automatically.
Swap partitions
A swap partition is not strictly required, but recommended for systems with low RAM. If you want to use hibernation, you will need a swap partition. The following table has recommendations for swap partition size.
System RAM | Recommended swap space | Swap space if using hibernation |
---|---|---|
< 2GB | 2x the amount of RAM | 3x the amount of RAM |
2-8GB | Equal to amount of RAM | 2x the amount of RAM |
8-64GB | At least 4GB | 1.5x the amount of RAM |
64GB | At least 4GB | Hibernation not recommended |
Boot partition (optional)
On most modern systems, a separate /boot
partition is no longer necessary to
boot properly. If you choose to use one, note that Void does not remove old
kernels after updates by default and also that the kernel tends to increase in
size with each new version, so plan accordingly (e.g. /boot
with one Linux 5.x
x86_64
kernel and GRUB occupies about 60MB).
Other partitions
It is fine to install your system with only a large root partition, but you may
create other partitions if you want. One helpful addition could be a separate
partition for your /home
directory. This way if you need to reinstall Void (or
another distribution) you can save the data and configuration files in your home
directory for your new system.
Installation Guide
Once you have downloaded a Void image to install and prepared your install media, you are ready to install Void Linux.
Before you begin installation, you should determine whether your machine boots using BIOS or UEFI. This will affect how you plan partitions. See Partitioning Notes for more detail.
The following features are not supported by the installer script:
Booting
Boot your machine from the install media you created. If you have enough RAM, there is an option on the boot screen to load the entire image into ram, which will take some time but speed up the rest of the install process.
Once the live image has booted, log in as root
with password voidlinux
and
run:
# void-installer
The following sections will detail each screen of the installer.
Keyboard
Select the keymap for your keyboard; standard "qwerty" keyboards will generally use the "us" keymap.
Network
Select your primary network interface. If you do not choose to use DHCP, you will be prompted to provide an IP address, gateway, and DNS servers.
If you choose a wireless network interface, you will be prompted to provide the
SSID, encryption type (wpa
or wep
), and password. If void-installer
fails
to connect to your network, you may need to exit the installer and configure it
manually using wpa_supplicant and
dhcpcd before continuing.
Source
To install packages provided on the install image, select Local
. Otherwise,
you may select Network
to download the latest packages from the Void
repository.
Warning: If you are installing the desktop environment from the xfce image, you MUST choose
Local
for the source!
Hostname
Select a hostname for your computer (that is all lowercase, with no spaces.)
Locale
Select your default locale settings. This option is for glibc only, as musl does not currently support locales.
Timezone
Select your timezone based on standard timezone options.
Root password
Enter and confirm your root
password for the new installation. The password
will not be shown on screen.
User account
Choose a login (default void
) and a descriptive name for that login. Then
enter and confirm the password for the new user. You will then be prompted to
verify the groups for this new user. They are added to the wheel
group by
default and will have sudo
access. Default groups and their descriptions are
listed here.
Login names have some restrictions, as described in useradd(8).
Bootloader
Select the disk to install a bootloader on when Void is installed. You may
select none
to skip this step and install a bootloader manually after
completing the installation process. If installing a bootloader, you will also
be asked whether or not you want a graphical terminal for the GRUB menu.
Partition
Next, you will need to partition your disks. Void does not provide a preset
partition scheme, so you will need to create your partitions manually with
cfdisk(8). You will be prompted with a
list of disks. Select the disk you want to partition and the installer will
launch cfdisk
for that disk. Remember you must write the partition table to
the drive before you exit the partition editor.
If using UEFI, it is recommended you select GPT for the partition table and
create a partition (typically between 200MB-1GB) of type EFI System
, which
will be mounted at /boot/efi
.
If using BIOS, it is recommended you select MBR for the partition table. Advanced users may use GPT but will need to create a special BIOS partition for GRUB to boot.
See the Partitioning Notes for more details about partitioning your disk.
Filesystems
Create the filesystems for each partition you have created. For each partition
you will be prompted to choose a filesystem type, whether you want to create a
new filesystem on the partition, and a mount point, if applicable. When you are
finished, select Done
to return to the main menu.
If using UEFI, create a vfat
filesystem and mount it at /boot/efi
.
Review settings
It is a good idea to review your settings before proceeding. Use the right arrow
key to select the settings button and hit <enter>
. All your selections will be
shown for review.
Install
Selecting Install
from the menu will start the installer. The installer will
create all the filesystems selected, and install the base system packages. It
will then generate an initramfs and install a GRUB2 bootloader to the bootable
partition.
These steps will all run automatically, and after the installation is completed successfully, you can reboot into your new Void Linux install!
Post installation
After booting into your Void installation for the first time, perform a system update.
Advanced Installation Guides
This section contains guides for more specific or complex use-cases.
Section Contents
- Installing Void via chroot (x86 or x86_64)
- Installing Void with Full Disk Encryption
- Installing Void on a ZFS Root
- ARM Devices
Installation via chroot (x86/x86_64/aarch64)
This guide details the process of manually installing Void via a chroot on an x86, x86_64 or aarch64 architecture. It is assumed that you have a familiarity with Linux, but not necessarily with installing a Linux system via a chroot. This guide can be used to create a "typical" setup, using a single partition on a single SATA/IDE/USB disk. Each step may be modified to create less typical setups, such as full disk encryption.
Void provides two options for bootstrapping the new installation. The XBPS method uses the XBPS Package Manager running on a host operating system to install the base system. The ROOTFS method installs the base system by unpacking a ROOTFS tarball.
The XBPS method requires that the host operating system have XBPS installed. This may be an existing installation of Void, an official live image, or any Linux installation running a statically linked XBPS.
The ROOTFS method requires only a host operating system that can enter a Linux chroot and that has both tar(1) and xz(1) installed. This method may be preferable if you wish to install Void using a different Linux distribution.
Prepare Filesystems
Partition your disks and format them using mke2fs(8), mkfs.xfs(8), mkfs.btrfs(8) or whatever tools are necessary for your filesystem(s) of choice.
mkfs.vfat(8) is also available to create FAT32 partitions. However, due to restrictions associated with FAT filesystems, it should only be used when no other filesystem is suitable (such as for the EFI System Partition).
cfdisk(8) and
fdisk(8) are available on the live images
for partitioning, but you may wish to use
gdisk(8) (from the package gptfdisk
) or
parted(8) instead.
For a UEFI booting system, make sure to create an EFI System Partition (ESP).
The ESP should have the partition type "EFI System" (code EF00
) and be
formatted as FAT32 using mkfs.vfat(8).
If you're unsure what partitions to create, create a 1GB partition of type "EFI
System" (code EF00
), then create a second partition of type "Linux Filesystem"
(code 8300
) using the remainder of the drive.
Format these partitions as FAT32 and ext4, respectively:
# mkfs.vfat /dev/sda1
# mkfs.ext4 /dev/sda2
Create a New Root and Mount Filesystems
This guide will assume the new root filesystem is mounted on /mnt
. You may
wish to mount it elsewhere.
If using UEFI, mount the EFI System Partition as /mnt/boot/efi
.
For example, if /dev/sda2
is to be mounted as /
and dev/sda1
is the EFI
System Partition:
# mount /dev/sda2 /mnt/
# mkdir -p /mnt/boot/efi/
# mount /dev/sda1 /mnt/boot/efi/
Initialize swap space, if desired, using mkswap(8).
Base Installation
Follow only one of the two following subsections.
If on aarch64, it will be necessary to install a kernel package in addition to
base-system
. For example, linux
is a kernel package that points to the
latest stable kernel packaged by Void.
The XBPS Method
Select a mirror and use the appropriate URL for the type of system you wish to install. For simplicity, save this URL to a shell variable. A glibc installation, for example, would use:
# REPO=https://repo-default.voidlinux.org/current
XBPS also needs to know what architecture is being installed. Available options
are x86_64
, x86_64-musl
, i686
for PC architecture computers and aarch64
.
For example:
# ARCH=x86_64
This architecture must be compatible with your current operating system, but does not need to be the same. If your host is running an x86_64 operating system, any of the three architectures can be installed (whether the host is musl or glibc), but an i686 host can only install i686 distributions.
Copy the RSA keys from the installation medium to the target root directory:
# mkdir -p /mnt/var/db/xbps/keys
# cp /var/db/xbps/keys/* /mnt/var/db/xbps/keys/
Use xbps-install(1) to bootstrap the
installation by installing the base-system
metapackage:
# XBPS_ARCH=$ARCH xbps-install -S -r /mnt -R "$REPO" base-system
The ROOTFS Method
Download a ROOTFS tarball matching your architecture.
Unpack the tarball into the newly configured filesystems:
# tar xvf void-<...>-ROOTFS.tar.xz -C /mnt
Configuration
With the exception of the section "Install base-system (ROOTFS method only)", the remainder of this guide is common to both the XBPS and ROOTFS installation methods.
Entering the Chroot
xchroot(1) (from xtools
) can be used to
set up and enter the chroot. Alternatively, this can be done
manually.
# xchroot /mnt /bin/bash
Install base-system (ROOTFS method only)
ROOTFS images generally contain out of date software, due to being a snapshot of
the time when they were built, and do not come with a complete base-system
.
Update the package manager and install base-system
:
[xchroot /mnt] # xbps-install -Su xbps
[xchroot /mnt] # xbps-install -u
[xchroot /mnt] # xbps-install base-system
[xchroot /mnt] # xbps-remove base-container-full
Installation Configuration
Specify the hostname in /etc/hostname
. Go through the options in
/etc/rc.conf
. If installing a glibc
distribution, edit /etc/default/libc-locales
, uncommenting desired
locales.
nvi(1) is available in the chroot, but you may wish to install your preferred text editor at this time.
For glibc builds, generate locale files with:
[xchroot /mnt] # xbps-reconfigure -f glibc-locales
Set a Root Password
Configure at least one super user account. Other user accounts can be configured later, but there should either be a root password, or a new user account with sudo(8) privileges.
To set a root password, run:
[xchroot /mnt] # passwd
Configure fstab
The fstab(5) file can be automatically
generated from currently mounted filesystems by copying the file /proc/mounts
:
[xchroot /mnt] # cp /proc/mounts /etc/fstab
Remove lines in /etc/fstab
that refer to proc
, sys
, devtmpfs
and pts
.
Replace references to /dev/sdXX
, /dev/nvmeXnYpZ
, etc. with their respective
UUID, which can be found by running
blkid(8). Referring to filesystems by their
UUID guarantees they will be found even if they are assigned a different name at
a later time. In some situations, such as booting from USB, this is absolutely
essential. In other situations, disks will always have the same name unless
drives are physically added or removed. Therefore, this step may not be strictly
necessary, but is almost always recommended.
Change the last zero of the entry for /
to 1
, and the last zero of every
other line to 2
. These values configure the behaviour of
fsck(8).
For example, the partition scheme used throughout previous examples yields the
following fstab
:
/dev/sda1 /boot/efi vfat rw,relatime,[...] 0 0
/dev/sda2 / ext4 rw,relatime 0 0
The information from blkid
results in the following /etc/fstab
:
UUID=6914[...] /boot/efi vfat rw,relatime,[...] 0 2
UUID=dc1b[...] / ext4 rw,relatime 0 1
Note: The output of /proc/mounts
will have a single space between each field.
The columns are aligned here for readability.
Add an entry to mount /tmp
in RAM:
tmpfs /tmp tmpfs defaults,nosuid,nodev 0 0
If using swap space, add an entry for any swap partitions:
UUID=1cb4[...] swap swap rw,noatime,discard 0 0
Enable services
Services can be enabled
after booting the new system, but you may need to enable some of them (e.g.:
dhcpcd
, sshd
) now in order to access it.
Installing GRUB
Use grub-install to install GRUB onto your boot disk.
On a BIOS computer, install the package grub
, then run grub-install /dev/sdX
, where /dev/sdX
is the drive (not partition) that you wish to
install GRUB to. For example:
[xchroot /mnt] # xbps-install grub
[xchroot /mnt] # grub-install /dev/sda
On a UEFI computer, install either grub-x86_64-efi
, grub-i386-efi
or
grub-arm64-efi
, depending on your architecture, then run grub-install
,
optionally specifying a bootloader label (this label may be used by your
computer's firmware when manually selecting a boot device):
[xchroot /mnt] # xbps-install grub-x86_64-efi
[xchroot /mnt] # grub-install --target=x86_64-efi --efi-directory=/boot/efi --bootloader-id="Void"
Troubleshooting GRUB installation
It may be necessary to mount the efivarfs
filesystem.
[xchroot /mnt] # mount -t efivarfs none /sys/firmware/efi/efivars
If EFI variables are still not available, add the option --no-nvram
to the
grub-install
command.
Installing on removable media or non-compliant UEFI systems
Unfortunately, not all systems have a fully standards compliant UEFI
implementation. In some cases, it is necessary to "trick" the firmware into
booting by using the default fallback location for the bootloader instead of a
custom one. In that case, or if installing onto a removable disk (such as USB),
add the option --removable
to the grub-install
command.
Alternatively, use mkdir(1) to create the
/boot/efi/EFI/boot
directory and copy the installed GRUB executable, usually
located in /boot/efi/EFI/Void/grubx64.efi
(its location can be found using
efibootmgr(8)), into the new folder:
[xchroot /mnt] # mkdir -p /boot/efi/EFI/boot
[xchroot /mnt] # cp /boot/efi/EFI/Void/grubx64.efi /boot/efi/EFI/boot/bootx64.efi
Finalization
Use xbps-reconfigure(1) to ensure all installed packages are configured properly:
[xchroot /mnt] # xbps-reconfigure -fa
This will make dracut(8) generate an initramfs, and will make GRUB generate a working configuration.
At this point, the installation is complete. Exit the chroot and reboot your computer:
[xchroot /mnt] # exit
# umount -R /mnt
# shutdown -r now
After booting into your Void installation for the first time, perform a system update.
Full Disk Encryption
Warning: Your drive's block device and other information may be different, so make sure it is correct.
Partitioning
Boot a live image and login.
Create a single physical partition on the disk using cfdisk, marking it as bootable. For an MBR system, the partition layout should look like the following.
# fdisk -l /dev/sda
Disk /dev/sda: 48 GiB, 51539607552 bytes, 100663296 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: dos
Disk identifier: 0x4d532059
Device Boot Start End Sectors Size Id Type
/dev/sda1 * 2048 100663295 100661248 48G 83 Linux
UEFI systems will need the disk to have a GPT disklabel and an EFI system partition. The required size for this may vary depending on needs, but 100M should be enough for most cases. For an EFI system, the partition layout should look like the following.
# fdisk -l /dev/sda
Disk /dev/sda: 48 GiB, 51539607552 bytes, 100663296 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: EE4F2A1A-8E7F-48CA-B3D0-BD7A01F6D8A0
Device Start End Sectors Size Type
/dev/sda1 2048 264191 262144 128M EFI System
/dev/sda2 264192 100663262 100399071 47.9G Linux filesystem
Encrypted volume configuration
Cryptsetup defaults to LUKS2, yet GRUB releases before 2.06 only had support for LUKS1.
LUKS2 is only partially supported by GRUB; specifically, only the PBKDF2 key derivation function is implemented, which is not the default KDF used with LUKS2, that being Argon2i (GRUB Bug 59409). LUKS encrypted partitions using Argon2i (as well as the other KDF) can not be decrypted. For that reason, this guide only recommends LUKS1 be used.
Keep in mind the encrypted volume will be /dev/sda2
on EFI systems, since
/dev/sda1
is taken up by the EFI partition.
# cryptsetup luksFormat --type luks1 /dev/sda1
WARNING!
========
This will overwrite data on /dev/sda1 irrevocably.
Are you sure? (Type uppercase yes): YES
Enter passphrase:
Verify passphrase:
Once the volume is created, it needs to be opened. Replace voidvm
with an
appropriate name. Again, this will be /dev/sda2
on EFI systems.
# cryptsetup luksOpen /dev/sda1 voidvm
Enter passphrase for /dev/sda1:
Once the LUKS container is opened, create the LVM volume group using that partition.
# vgcreate voidvm /dev/mapper/voidvm
Volume group "voidvm" successfully created
There should now be an empty volume group named voidvm
.
Next, logical volumes need to be created for the volume group. For this example,
I chose 10G for /
, 2G for swap
, and will assign the rest to /home
.
# lvcreate --name root -L 10G voidvm
Logical volume "root" created.
# lvcreate --name swap -L 2G voidvm
Logical volume "swap" created.
# lvcreate --name home -l 100%FREE voidvm
Logical volume "home" created.
Next, create the filesystems. The example below uses XFS as a personal preference of the author. Any filesystem supported by GRUB will work.
# mkfs.xfs -L root /dev/voidvm/root
meta-data=/dev/voidvm/root isize=512 agcount=4, agsize=655360 blks
...
# mkfs.xfs -L home /dev/voidvm/home
meta-data=/dev/voidvm/home isize=512 agcount=4, agsize=2359040 blks
...
# mkswap /dev/voidvm/swap
Setting up swapspace version 1, size = 2 GiB (2147479552 bytes)
System installation
Next, setup the chroot and install the base system.
# mount /dev/voidvm/root /mnt
# mkdir -p /mnt/home
# mount /dev/voidvm/home /mnt/home
On a UEFI system, the EFI system partition also needs to be mounted.
# mkfs.vfat /dev/sda1
# mkdir -p /mnt/boot/efi
# mount /dev/sda1 /mnt/boot/efi
Copy the RSA keys from the installation medium to the target root directory:
# mkdir -p /mnt/var/db/xbps/keys
# cp /var/db/xbps/keys/* /mnt/var/db/xbps/keys/
Before we enter the chroot to finish up configuration, we do the actual install. Do not forget to use the appropriate repository URL for the type of system you wish to install.
# xbps-install -Sy -R https://repo-default.voidlinux.org/current -r /mnt base-system lvm2 cryptsetup grub
[*] Updating `https://repo-default.voidlinux.org/current/x86_64-repodata' ...
x86_64-repodata: 1661KB [avg rate: 2257KB/s]
130 packages will be downloaded:
...
UEFI systems will have a slightly different package selection. The installation command for a UEFI system will be as follows.
# xbps-install -Sy -R https://repo-default.voidlinux.org/current -r /mnt base-system cryptsetup grub-x86_64-efi lvm2
When it's done, we can enter the chroot with
xchroot(1)
(from xtools
) and finish
up the configuration. Alternatively, entering the chroot can be done
manually.
# xchroot /mnt
[xchroot /mnt] # chown root:root /
[xchroot /mnt] # chmod 755 /
[xchroot /mnt] # passwd root
[xchroot /mnt] # echo voidvm > /etc/hostname
and, for glibc systems only:
[xchroot /mnt] # echo "LANG=en_US.UTF-8" > /etc/locale.conf
[xchroot /mnt] # echo "en_US.UTF-8 UTF-8" >> /etc/default/libc-locales
[xchroot /mnt] # xbps-reconfigure -f glibc-locales
Filesystem configuration
The next step is editing /etc/fstab
, which will depend on how you configured
and named your filesystems. For this example, the file should look like this:
# <file system> <dir> <type> <options> <dump> <pass>
tmpfs /tmp tmpfs defaults,nosuid,nodev 0 0
/dev/voidvm/root / xfs defaults 0 0
/dev/voidvm/home /home xfs defaults 0 0
/dev/voidvm/swap swap swap defaults 0 0
UEFI systems will also have an entry for the EFI system partition.
/dev/sda1 /boot/efi vfat defaults 0 0
GRUB configuration
Next, configure GRUB to be able to unlock the filesystem. Add the following line
to /etc/default/grub
:
GRUB_ENABLE_CRYPTODISK=y
Next, the kernel needs to be configured to find the encrypted device. First, find the UUID of the device.
[xchroot /mnt] # blkid -o value -s UUID /dev/sda1
135f3c06-26a0-437f-a05e-287b036440a4
Edit the GRUB_CMDLINE_LINUX_DEFAULT=
line in /etc/default/grub
and add
rd.lvm.vg=voidvm rd.luks.uuid=<UUID>
to it. Make sure the UUID matches the one
for the sda1
device found in the output of the
blkid(8) command above. This will be
/dev/sda2
on EFI systems.
LUKS key setup
And now to avoid having to enter the password twice on boot, a key will be configured to automatically unlock the encrypted volume on boot. First, generate a random key.
[xchroot /mnt] # dd bs=1 count=64 if=/dev/urandom of=/boot/volume.key
64+0 records in
64+0 records out
64 bytes copied, 0.000662757 s, 96.6 kB/s
Next, add the key to the encrypted volume.
[xchroot /mnt] # cryptsetup luksAddKey /dev/sda1 /boot/volume.key
Enter any existing passphrase:
Change the permissions to protect the generated key.
[xchroot /mnt] # chmod 000 /boot/volume.key
[xchroot /mnt] # chmod -R g-rwx,o-rwx /boot
This keyfile also needs to be added to /etc/crypttab
. Again, this will be
/dev/sda2
on EFI systems.
voidvm /dev/sda1 /boot/volume.key luks
And then the keyfile and crypttab
need to be included in the initramfs. Create
a new file at /etc/dracut.conf.d/10-crypt.conf
with the following line:
install_items+=" /boot/volume.key /etc/crypttab "
Complete system installation
Next, install the boot loader to the disk.
[xchroot /mnt] # grub-install /dev/sda
Ensure an initramfs is generated:
[xchroot /mnt] # xbps-reconfigure -fa
Exit the chroot
, unmount the filesystems, and reboot the system.
[xchroot /mnt] # exit
# umount -R /mnt
# reboot
Installing Void on a ZFS Root
Because the Void installer does not support ZFS, it is necessary to install via chroot. Aside from a few caveats regarding bootloader and initramfs support, installing Void on a ZFS root filesystem is not significantly different from any other advanced installation. ZFSBootMenu is a bootloader designed from the ground up to support booting Linux distributions directly from a ZFS pool. However, it is also possible to use traditional bootloaders with a ZFS root.
ZFSBootMenu
Although it will boot (and can be run atop) a wide variety of distributions, ZFSBootMenu officially considers Void a first-class distribution. ZFSBootMenu supports native ZFS encryption, offers a convenient recovery environment that can be used to clone prior snapshots or perform advanced manipulation in a pre-boot environment, and will support booting from any pool that is importable by modern ZFS drivers. The ZFSBootMenu documentation offers, among other content, several step-by-step guides for installing a Void system from scratch. The UEFI guide describes the procedure of bootstrapping a Void system for modern systems. For legacy BIOS systems, the syslinux guide provides comparable instructions.
Traditional bootloaders
For those that wish to forego ZFSBootMenu, it is possible to bootstrap a Void
system with another bootloader. To avoid unnecessary complexity, systems that
use bootloaders other than ZFSBootMenu should plan to use a separate /boot
that is located on an ext4 or xfs filesystem.
Installation media
Installing Void to a ZFS root requires an installation medium with ZFS drivers.
It is possible to build a custom image from the official
void-mklive repository by providing
the command-line option -p zfs
to the mklive.sh
script. However, for
x86_64
systems, it may be more convenient to fetch a pre-built
hrmpf image. These images,
maintained by a Void team member, are extensions of the standard Void live
images that include pre-compiled ZFS modules in addition to other useful tools.
Partition disks
After booting a live image with ZFS support, partition your disks. The considerations in the partitioning guide apply to ZFS installations as well, except that
- The boot partition should be considered necessary unless you intend to use
gummiboot
, which expects that your EFI system partition will be mounted at/boot
. (This alternative configuration will not be discussed here.) - Aside from any EFI system partition, GRUB BIOS boot partition, swap or boot
partitions, the remainder of the disk should typically be a single partition
with type code
BF00
that will be dedicated to a single ZFS pool. There is no benefit to creating separate ZFS pools on a single disk.
As needed, format the EFI system partition using mkfs.vfat(8) and the the boot partition using mke2fs(8) or mkfs.xfs(8). Initialize any swap space using mkswap(8).
It is possible to put Linux swap space on a ZFS zvol, although there may be a risk of deadlocking the kernel when under high memory pressure. This guide takes no position on the matter of swap space on a zvol. However, if you wish to use suspension-to-disk (hibernation), note that the kernel is not capable of resuming from memory images stored on a zvol. You will need a dedicated swap partition to use hibernation. Apart from this caveat, there are no special considerations required to resume a suspended image when using a ZFS root.
Create a ZFS pool
Create a ZFS pool on the partition created for it using
zpool(8). For example, to create a pool on
/dev/disk/by-id/wwn-0x5000c500deadbeef-part3
:
# zpool create -f -o ashift=12 \
-O compression=lz4 \
-O acltype=posixacl \
-O xattr=sa \
-O relatime=on \
-o autotrim=on \
-m none zroot /dev/disk/by-id/wwn-0x5000c500deadbeef-part3
Adjust the pool (-o
) and filesystem (-O
) options as desired, and replace the
partition identifier wwn-0x5000c500deadbeef-part3
with that of the actual
partition to be used.
When adding disks or partitions to ZFS pools, it is generally advisable to refer to them by the symbolic links created in
/dev/disk/by-id
or (on UEFI systems)/dev/disk/by-partuuid
so that ZFS will identify the right partitions even if disk naming should change at some point. Using traditional device nodes like/dev/sda3
may cause intermittent import failures.
Next, export and re-import the pool with a temporary, alternate root path:
# zpool export zroot
# zpool import -N -R /mnt zroot
Create initial filesystems
The filesystem layout on your ZFS pool is flexible. However, it is customary to
put operating system root filesystems ("boot environments") under a ROOT
parent:
# zfs create -o mountpoint=none zroot/ROOT
# zfs create -o mountpoint=/ -o canmount=noauto zroot/ROOT/void
Setting canmount=noauto
on filesystems with mountpoint=/
is useful because
it permits the creation of multiple boot environments (which may be clones of a
common Void installation or contain completely separate distributions) without
fear that ZFS auto-mounting will attempt to mount one over another.
To separate user data from the operating system, create a filesystem to store home directories:
# zfs create -o mountpoint=/home zroot/home
Other filesystems may be created as desired.
Mount the ZFS hierarchy
All ZFS filesystems should be mounted under the /mnt
alternate root
established by the earlier re-import. Mount the manual-only root filesystem
before allowing ZFS to automatically mount everything else:
# zfs mount zroot/ROOT/void
# zfs mount -a
At this point, the entire ZFS hierarchy should be mounted and ready for installation. To improve boot-time import speed, it is useful to record the current pool configuration in a cache file that Void will use to avoid walking the entire device hierarchy to identify importable pools:
# mkdir -p /mnt/etc/zfs
# zpool set cachefile=/mnt/etc/zfs/zpool.cache zroot
Mount non-ZFS filesystems at the appropriate places. For example, if /dev/sda2
holds an ext4 filesystem that should be mounted at /boot
and /dev/sda1
is
the EFI system partition:
# mkdir -p /mnt/boot
# mount /dev/sda2 /mnt/boot
# mkdir -p /mnt/boot/efi
# mount /dev/sda1 /mnnt/boot/efi
Installation
At this point, ordinary installation can proceed from the "Base Installation"
section. of the standard chroot installation
guide. However, before following the "Finalization"
instructions, make sure that the zfs
package has
been installed and dracut
is configured to identify a ZFS root filesystem:
[xchroot /mnt] # mkdir -p /etc/dracut.conf.d
[xchroot /mnt] # cat > /etc/dracut.conf.d/zol.conf <<EOF
nofsck="yes"
add_dracutmodules+=" zfs "
omit_dracutmodules+=" btrfs resume "
EOF
[xchroot /mnt] # xbps-install zfs
Finally, follow the "Finalization" instructions and reboot into your new system.
ARM Devices
Void Linux provides packages and images for several ARM devices. Installing Void on such devices can be done in several ways:
- Pre-built images: images that can be flashed directly onto an SD card or other storage medium, but which give you a limited partition layout, and require manual expansion if you wish to increase the size of the partitions;
- Tarball installation: PLATFORMFS and ROOTFS tarballs that can be extracted to a previously prepared partition scheme; and
- Chroot installation: follows most of the steps outlined in the chroot guide.
This guide also outlines configuration steps that are mostly specific to such devices.
Since most of the commands in this guide will be run on external storage, it is important to run sync(1) before removing the device.
Installation
If you are installing Void Linux on one of the ARM devices covered in the "Supported platforms" page, make sure to read its section thoroughly.
Pre-built images
The pre-built images provided are prepared for 2GB SD cards. After downloading
and verifying an image, it can
be uncompressed with unxz(1) and written to
the relevant media with cat(1),
pv(1), or
dd(1). For example, to flash it onto an SD
card located at /dev/mmcblk0
:
$ unxz -k <image>.img.xz
# dd if=<image>.img of=/dev/mmcblk0 bs=4M status=progress
After flashing, the root partition can optionally be expanded to fit the storage device with cfdisk(8), fdisk(8), or another partitioning tool, and the filesystem can be resized to fit the expanded partition with resize2fs(8).
Custom partition layout
Customizing an installation - for example, with a custom partition layout - requires a more involved process. Two available options are:
To prepare the storage for these installation methods, it is necessary to partition the storage medium and then mount the partitions at the correct mount points.
The usual partitioning scheme for ARM devices requires at least two partitions, on a drive formatted with an MS-DOS partition table:
- one formatted as FAT32 with partition type
0c
, which will be mounted on/boot
; - one that can be formatted as any file system that Linux can boot from, such as
ext4, which will be mounted on
/
. If you're using an SD card, you can create the ext4 file system with the^has_journal
option - this disables journaling, which might increase the drive's life, at the cost of a higher chance of data loss.
There are a variety of tools available for partitioning, e.g. cfdisk(8).
To access the newly created file systems, it is necessary to mount them. This
guide will assume that the second partition will be mounted on /mnt
, but you
may mount it elsewhere. To mount these filesystems, you can use the commands
below, replacing the device names with the appropriate ones for your setup:
# mount /dev/mmcblk0p2 /mnt
# mkdir /mnt/boot
# mount /dev/mmcblk0p1 /mnt/boot
Tarball installation
First, download and verify a PLATFORMFS or ROOTFS tarball for your desired platform and prepare your storage medium. Then, unpack the tarball onto the file system using tar(1):
# tar xvfp <image>.tar.xz -C /mnt
Chroot installation
It is also possible to perform a chroot installation using the appropriate architecture and base packages, some of which are listed in the "Supported Platforms" section. Make sure to prepare your storage medium properly for the device.
If doing this from a computer with an incompatible archtecture (such as x86_64),
install binfmt-support
, enable the binfmt-support
service, and install the
relevant QEMU user emulator (like qemu-user-aarch64
for aarch64 or
qemu-user-arm
for 32-bit ARM) before installing. If binfmt-support
was
installed after the QEMU user emulator, use xbps-reconfigure -f qemu-user-<arch>
to enable the relevant binfmts.
Configuration
Some additional configuration steps need to be followed to guarantee a working system. Configuring a graphical session should work as normal.
Logging in
For the pre-built images and tarball installations, the root
user password is
voidlinux
.
fstab
The /boot
partition should be added to /etc/fstab
, with an entry similar to
the one below. It is possible to boot without that entry, but updating the
kernel package in that situation can lead to breakage, such as being unable to
find kernel modules, which are essential for functionality such as wireless
connectivity. If you aren't using an SD card, replace /dev/mmcblk0p1
with the
appropriate device path.
/dev/mmcblk0p1 /boot vfat defaults 0 0
System time
Several of the ARM devices supported by Void Linux don't have battery powered
real time clocks (RTCs), which means they won't keep track of time once powered
off. This issue can present itself as HTTPS errors when browsing the Web or
using the package manager. It is possible to set the time manually using the
date(1) utility. In order to fix this issue
for subsequent boots, install and enable an NTP
client. Furthermore, it is possible to
install the fake-hwclock
package, which provides the fake-hwclock
service.
fake-hwclock(8) periodically stores
the current time in a configuration file and restores it at boot, leading to a
better initial approximation of the current time, even without a network
connection.
Warning: Images from before 2020-03-16 might have an issue where the
installation of the chrony
package, the default NTP daemon, is incomplete, and
the system will be missing the chrony
user. This can be checked in the output
of the getent(1) command, which will be
empty if it doesn't exist:
$ getent group chrony
chrony:x:997
In order to fix this, it is necessary to reconfigure the chrony
package using
xbps-reconfigure(1).
Graphical session
The xf86-video-fbturbo
package ships a modified version of the DDX Xorg
driver found in the
xf86-video-fbdev
package, which is optimized for ARM devices. This can be used
for devices which lack more specific drivers.
Supported Platforms
Raspberry Pi
The rpi-kernel
packages for all Raspberry Pi variants are built from the
Raspberry Pi Foundation's kernel tree, which should enable all special
functionality that isn't available with mainline kernels. The RPi kernel
packages also have their own header packages, rpi-kernel-headers
. These
packages should be installed if you want to use any DKMS packages. Void ships
rpi-base
meta-packages that install the relevant rpi-kernel
and
rpi-firmware
packages. Together, these packages enable Wi-Fi and Bluetooth
functionality.
The command line parameters passed to the
kernel are in the /boot/cmdline.txt
file. Some of the relevant parameters are
documented in the official
documentation.
Supported Models
Model | Architecture |
---|---|
1 A, 1 B, 1 A+, 1 B+, Zero, Zero W, Zero WH | armv6l |
2 B | armv7l |
3 B, 3 A+, 3 B+, Zero 2W, 4 B, 400, CM4, 5 | aarch64 |
It is possible to run the armv7l images on an RPi 3, as the RPi 3's CPU supports both the Armv8 and Armv7 instruction sets. The difference between these images is that the armv7l image provides a 32-bit system while the aarch64 image provides a 64-bit system.
Raspberry Pi 5 Kernel
The rpi5-kernel
and rpi5-kernel-headers
packages provide a kernel and
headers optimized for the Raspberry Pi 5 with 16KB pages. To switch from the
generic rpi-kernel
, install rpi5-kernel
. This will remove rpi-kernel
and
replace it with rpi5-kernel
.
Note: not all software is compatible with kernels that have larger page-sizes. View any known issues and report any compatibility problems found in the tracking issue.
Enabling hardware RNG device
By default, the
HWRNG device
is not used by the system, which may result in the random devices taking long to
seed on boot. This can be annoying if you want to start sshd
and expect to be
able to connect immediately.
In order to fix this, install the rng-tools
package and
enable the rngd
service, which uses the /dev/hwrng
device to seed /dev/random
.
Graphical session
The mesa-dri
package contains drivers for all the Raspberry Pi variants, and
can be used with the modesetting Xorg
driver or
Wayland.
Hardware
More configuration information can be found in the Raspberry Pi Foundation's
official
documentation.
The raspi-config
utility isn't available for Void Linux, so editing the
/boot/config.txt
file is usually required.
Audio
To enable the soundchip, add dtparam=audio=on
to /boot/config.txt
.
Serial
To enable serial console logins,
enable the
agetty-ttyAMA0
service. See
securetty(5) for interfaces that allow
root login. For configuration of the serial port at startup, refer to the kernel
command line in /boot/cmdline.txt
- in particular, the
console=ttyAMA0,115200
parameter.
I2C
To enable I2C, add
device_tree_param=i2c_arm=on
to /boot/config.txt
, and
bcm2708.vc_i2c_override=1
to /boot/cmdline.txt
. Then create a
modules-load(8) .conf
file with
the following content:
i2c-dev
Finally, install the i2c-tools
package and use
i2cdetect(8) to verify your
configuration. It should show:
$ i2cdetect -l
i2c-1i2c bcm2835 I2C adapter I2C adapter
Memory cgroup
The kernel from the rpi-kernel
package disables the memory cgroup by
default.
This breaks workloads which use containers. Therefore, if you want to use
containers on your Raspberry Pi, you need to enable memory cgroups by adding
cgroup_enable=memory
to /boot/cmdline.txt
.
musl
musl is a libc implementation which strives to be lightweight, fast, simple, and correct.
Void officially supports musl by using it in its codebase for all target platforms (although binary packages are not available for i686). Additionally, all compatible packages in our official repositories are available with musl-linked binaries in addition to their glibc counterparts.
Currently, there are nonfree and debug sub-repositories for musl, but no multilib sub-repo.
Incompatible software
musl practices very strict and minimal standard compliance. Many commonly used platform-specific extensions are not present. Because of this, it is common for software to need modification to compile and/or function properly. Void developers work to patch such software and hopefully get portability/correctness changes accepted into the upstream projects.
Proprietary software usually supports only glibc systems, though sometimes such applications are available as flatpaks and can be run on a musl system. In particular, the proprietary NVIDIA drivers do not support musl, which should be taken into account when evaluating hardware compatibility.
glibc chroot
Software requiring glibc can be run in a glibc chroot.
Configuration
This section and its subsections provide information about configuring your Void system.
Package Documentation
The most common media for documentation in Void Linux are manual pages.
Many packages contain documentation in other formats, like HTML. This
documentation can usually be found in a /usr/share/doc/<package>
directory.
More extensive documentation may be split into separate *-doc
packages, such
as julia-doc
. This is often the case for programming languages, databases and
big software libraries.
In addition to documentation provided by upstream projects, packages may also
contain description of initial setup or usage specific to Void, provided by
distribution contributors. It will be located in
/usr/share/doc/<package>/README.voidlinux
.
Manual Pages
Many Void packages come with manual ('man') pages. The default installation
includes the mandoc manpage toolset, via the mdocml
package.
The man(1) command can be used to show man pages:
$ man chroot
Every man page belongs to a particular section:
- 1: User commands (Programs)
- 2: System calls
- 3: Library calls
- 4: Special files (devices)
- 5: File formats and configuration files
- 6: Games
- 7: Overview, conventions, and miscellaneous
- 8: System management commands
Refer to man-pages(7) for details.
There are some man pages which have the same name, but are used in different
contexts, and are thus in a different section. You can specify which one to use
by including the section number in the call to man
:
$ man 1 printf
man
can be configured via man.conf(5).
The mandoc
toolset contains apropos(1),
which can be used to search for manual pages. apropos
uses a database that can
be generated and updated with the
makewhatis(8) command:
# makewhatis
$ apropos chroot
chroot(1) - run command or interactive shell with special root directory
xbps-uchroot(1) - XBPS utility to chroot and bind mount with Linux namespaces
xbps-uunshare(1) - XBPS utility to chroot and bind mount with Linux user namespaces
chroot(2) - change root directory
The mdocml
package provides a cron job to update the database daily,
/etc/cron.daily/makewhatis
. You will need to install and enable a cron
daemon for this functionality to be activated.
Development and POSIX manuals are not installed by default, but are available
via the man-pages-devel
and man-pages-posix
packages.
Localized manual pages
It is also possible to use localized man pages from packages which provide their
own as well as those provided by the manpages-*
packages. However, this can
require some configuration.
With mdocml
If mdocml
is being used and the settings should be applied for all users, it
is necessary to add the relevant paths to
man.conf(5). For example, German
speakers would add these two lines to their configuration file:
/usr/share/man/de
/usr/share/man/de.UTF-8
Alternatively, each user can export the MANPATH
variable in their environment,
as explained in man(1).
Firmware
Void provides a number of firmware packages in the repositories. Some firmware is only available if you have enabled the nonfree repository.
Microcode
Microcode is loaded onto the CPU or GPU at boot by the BIOS, but can be replaced later by the OS itself. An update to microcode can allow a CPU's or GPU's behavior to be modified to work around certain yet to be discovered bugs, without the need to replace the hardware.
Intel
Install the Intel microcode package, intel-ucode
. This package is in the
nonfree repo, which has to be enabled.
After installing this package, it is necessary to regenerate your
initramfs. For subsequent updates, the microcode
will be added to the initramfs automatically.
AMD
Install the AMD package, linux-firmware-amd
, which contains microcode for both
AMD CPUs and GPUs. AMD CPUs and GPUs will automatically load the microcode, no
further configuration required.
Verification
The /proc/cpuinfo
file has some information under microcode
that can be used
to verify the microcode update.
Removing firmware
By default, linuxX.Y
packages and the base-system
package install a number
of firmware packages. It is not necessary to remove unused firmware packages,
but if you wish to do so, you can configure XBPS to
ignore those packages, then
remove them.
Locales and Translations
glibc
supports setting the system locale whereas musl
does not; both support
setting the language for applications.
Listing locales
For a list of currently enabled locales, run:
$ locale -a
Enabling locales
To enable a certain locale, un-comment or add the relevant lines in
/etc/default/libc-locales
and force-reconfigure the
glibc-locales
package.
Setting the system language
Set LANG=xxxx
in /etc/locale.conf
.
Application locale
Some programs have their translations in a separate package that must be
installed in order to use them. You can
search for the desired language
(e.g. "german" or "portuguese") in the package repositories and install the
packages relevant to the applications you use. An especially relevant case is
when installing individual packages from the LibreOffice suite, such as
libreoffice-writer
, which require installing at least one of the
libreoffice-i18n-*
packages to work properly. This isn't necessary when
installing the libreoffice
meta-package, since doing so will install the most
common translation packages.
Users and Groups
The useradd(8), userdel(8) and usermod(8) commands are used to add, delete and modify users respectively. The passwd(1) command is used to change passwords.
The groupadd(8), groupdel(8) and groupmod(8) commands are used to add, delete and modify groups respectively. The groups(1) command lists all groups a user belongs to.
Default shell
The default shell for a user can be changed with chsh(1):
$ chsh -s <shell> <user_name>
<shell>
must be the path to the shell as specified by /etc/shells
or the
output of chsh -l
, which provides a list of installed shells.
sudo
sudo(8) is installed by default, but might not be configured appropriately for your needs. It is only necessary to configure sudo if you wish to use it.
Use visudo(8) as root to edit the sudoers(5) file.
To create a superuser, uncomment the line
#%wheel ALL=(ALL) ALL
and add users to the wheel
group.
Default Groups
Void Linux defines a number of groups by default.
Group | Description |
---|---|
root | Complete access to the system. |
bin | Unused - present for historical reasons. |
sys | Unused - present for historical reasons. |
kmem | Ability to read from /dev/mem and /dev/port . |
wheel | Elevated privileges for specific system administration tasks. |
tty | Access to TTY-like devices: /dev/tty* , /dev/pts* , /dev/vcs* . |
tape | Access to tape devices. |
daemon | System daemons that need to write to files on disk. |
floppy | Access to floppy drives. |
disk | Raw access to /dev/sd* and /dev/loop* . |
lp | Access to printers. |
dialout | Access to serial ports. |
audio | Access to audio devices. |
video | Access to video devices. |
utmp | Ability to write to /var/run/utmp , /var/log/wtmp and /var/log/btmp . |
adm | Unused - present for historical reasons. This group was traditionally used for system monitoring, such as viewing files in /var/log . |
cdrom | Access to CD devices. |
optical | Access to DVD/CD-RW devices. |
mail | Used by some mail packages, e.g. dma . |
storage | Access to removable storage devices. |
scanner | Ability to access scanners. |
network | Used by some networking-related packages, e.g. connman , NetworkManager , wicd . |
kvm | Ability to use KVM for virtual machines, e.g. via QEMU. |
input | Access to input devices: /dev/mouse* , /dev/event* . |
plugdev | Access to pluggable devices. |
nogroup | System daemons that don't need to own any files. |
usbmon | Access to /dev/usbmon* . |
users | Ordinary users. |
xbuilder | To use xbps-uchroot(1) with xbps-src . |
Services and Daemons - runit
Void uses the runit(8) supervision suite to run system services and daemons.
Some advantages of using runit include:
- a small code base, making it easier to audit for bugs and security issues.
- each service is given a clean process state, regardless of how the service was started or restarted: it will be started with the same environment, resource limits, open file descriptors, and controlling terminals.
- a reliable logging facility for services, where the log service stays up as long as the relevant service is running and possibly writing to the log.
If you don't need a program to be running constantly, but would like it to run at regular intervals, you might like to consider using a cron daemon.
Section Contents
Service Directories
Each service managed by runit has an associated service directory.
A service directory requires only one file: an executable named run
, which is
expected to exec a process in the foreground.
Optionally, a service directory may contain:
- an executable named
check
, which will be run to check whether the service is up and available; it's considered available ifcheck
exits with 0. - an executable named
finish
, which will be run on shutdown/process stop. - a
conf
file; this can contain environment variables to be sourced and referenced inrun
. - a directory named
log
; a pipe will be opened from the output of therun
process in the service directory to the input of therun
process in thelog
directory.
When a new service is created, a supervise
folder will be automatically
created on the first run.
Configuring Services
Most services can take configuration options set by a conf
file in the service
directory. This allows service customization without modifying the service
directory provided by the relevant package.
Check the service file for how to pass configuration parameters. A few services
have a field like OPTS="--value ..."
in their conf
file.
To make more complex customizations, you should edit the service.
Editing Services
To edit a service, first copy its service directory to a different directory name. Otherwise, xbps-install(1) can overwrite the service directory. Then, edit the new service file as needed. Finally, the old service should be stopped and disabled, and the new one should be started.
Managing Services
Runsvdirs
A runsvdir is a directory in /etc/runit/runsvdir
containing enabled
services in the form of symlinks to service directories. On a running system,
the current runsvdir is accessible via the /var/service
symlink.
The runit-void
package comes with two runsvdirs, single
and default
:
single
just runs sulogin(8) and the necessary steps to rescue your system.default
is the default runsvdir on a running system, unless specified otherwise by the kernel command line.
Additional runsvdirs can be created in /etc/runit/runsvdir/
.
See runsvdir(8) and runsvchdir(8) for further information.
Booting A Different runsvdir
To boot a runsvdir other than default
, the name of the desired runsvdir can be
added to the kernel command-line. As an example, adding
single
to the kernel command line will boot the single
runsvdir.
Basic Usage
To start, stop, restart or get the status of a service:
# sv up <services>
# sv down <services>
# sv restart <services>
# sv status <services>
The <services>
placeholder can be:
- Service names (service directory names) inside the
/var/service/
directory. - The full paths to the services.
For example, the following commands show the status of a specific service and of all enabled services:
# sv status dhcpcd
# sv status /var/service/*
See sv(8) for further information.
Enabling Services
Void Linux provides service directories for most daemons in /etc/sv/
.
To enable a service on a booted system, create a symlink to the service
directory in /var/service/
:
# ln -s /etc/sv/<service> /var/service/
If the system is not currently running, the service can be linked directly into
the default
runsvdir:
# ln -s /etc/sv/<service> /etc/runit/runsvdir/default/
This will automatically start the service. Once a service is linked it will always start on boot and restart if it stops, unless administratively downed.
To prevent a service from starting at boot while allowing runit to manage it,
create a file named down
in its service directory:
# touch /etc/sv/<service>/down
The down
file mechanism also makes it possible to disable services that are
enabled by default, such as the agetty(8)
services for ttys 1 to 6. This way, package updates which affect these services
(in this case, the runit-void
package) won't re-enable them.
Disabling Services
To disable a service, remove the symlink from the running runsvdir:
# rm /var/service/<service>
Or, for example, from the default
runsvdir, if either the specific runsvdir,
or the system, is not currently running:
# rm /etc/runit/runsvdir/default/<service>
Testing Services
To check if a service is working correctly when started by the service supervisor, run it once before fully enabling it:
# touch /etc/sv/<service>/down
# ln -s /etc/sv/<service> /var/service/
# sv once <service>
If everything works, remove the down
file to enable the service.
Per-User Services
Sometimes it can be nice to have user-specific runit services. For example, you might want to open an ssh tunnel as the current user, run a virtual machine, or regularly run daemons on your behalf.
runsvdir
The most basic way to do this is to create a system-level service that runs runsvdir(8) as your user, in order to start and monitor the services in a personal services directory. This does have limitations and downsides, though, as per-user services are started at boot and do not have access to things like the user's graphical session or D-Bus session bus.
For example, you could create a service called /etc/sv/runsvdir-<username>
with the following run
script, which should be executable:
#!/bin/sh
export USER="<username>"
export HOME="/home/<username>"
groups="$(id -Gn "$USER" | tr ' ' ':')"
svdir="$HOME/service"
exec chpst -u "$USER:$groups" runsvdir "$svdir"
In this example chpst(8) is used to start a
new runsvdir(8) process as the specified
user. chpst(8) does not read groups on its
own, but expects the user to list all required groups separated by a :
. The
id
and tr
pipe is used to create a list of all the user's groups in a way
chpst(8) understands it. Note that we
export $USER
and $HOME
because some user services may not work without them.
The user can then create new services or symlinks to them in the
/home/<username>/service
directory. To control the services using the
sv(8) command, the user can specify the
services by path, or by name if the SVDIR
environment variable is set to the
user's services directory. This is shown in the following examples:
$ sv status ~/service/*
run: /home/duncan/service/gpg-agent: (pid 901) 33102s
run: /home/duncan/service/ssh-agent: (pid 900) 33102s
$ SVDIR=~/service sv restart gpg-agent
ok: run: gpg-agent: (pid 19818) 0s
It may be convenient to export the SVDIR=~/service
variable in your shell
profile.
turnstile
Turnstile supports running per-user services that start with the user session using either runit or dinit(8).
If using the runit service backend, user services should be placed in
~/.config/service/
.
To ensure that a subset of services are started before login can proceed, these
services can be listed in ~/.config/service/turnstile-ready/conf
, for example:
core_services="dbus foo"
The turnstile-ready
service is created by turnstile on first login.
To give user services access to important environment variables,
chpst(8)'s envdir functionality can be
used. Inside user services, the convenience variable TURNSTILE_ENV_DIR
can be
used to refer to this directory.
To make a service aware of these variables, wrap the exec
line with chpst -e "$TURNSTILE_ENV_DIR"
:
exec chpst -e "$TURNSTILE_ENV_DIR" foo
The helper script turnstile-update-runit-env
can be used to update variables
in this shared envdir:
$ turnstile-update-runit-env DISPLAY XAUTHORITY FOO=bar BAZ=
To run the D-Bus session bus using a turnstile-managed user service:
$ mkdir -p ~/.config/service/dbus
$ ln -s /usr/share/examples/turnstile/dbus.run ~/.config/service/dbus/run
Logging
Syslog
The default installation comes with no syslog daemon. However, there are syslog implementations available in the Void repositories.
Socklog
socklog(8) is a syslog implementation
from the author of runit(8). Use socklog if
you're not sure which syslog implementation to use. To enable it, install the
socklog-void
package and enable the socklog-unix
and nanoklogd
services.
Ensure no other syslog daemon is running.
The logs are saved in sub-directories of /var/log/socklog/
, and svlogtail
can be used to access them conveniently.
The ability to read logs is limited to root
and users who are part of the
socklog
group.
Other syslog daemons
The Void repositories also include packages for rsyslog
and metalog
.
rc.conf, rc.local and rc.shutdown
The files /etc/rc.conf
, /etc/rc.local
and /etc/rc.shutdown
can be used to
configure certain parts of your Void system. rc.conf
is often configured by
void-installer
.
rc.conf
Sourced in runit stages 1 and 3. This file can be used to set variables, including the following:
KEYMAP
Specifies which keymap to use for the Linux console. Available keymaps are
listed in /usr/share/kbd/keymaps
. For example:
KEYMAP=fr
For further details, refer to loadkeys(1).
HARDWARECLOCK
Specifies whether the hardware clock is set to UTC or local time.
By default this is set to utc
. However, Windows sets the hardware clock to
local time, so if you are dual-booting with Windows, you need to either
configure Windows to use UTC, or set this variable to localtime
.
For further details, refer to hwclock(8).
FONT
Specifies which font to use for the Linux console. Available fonts are listed in
/usr/share/kbd/consolefonts
. For example:
FONT=eurlatgr
For further details, refer to setfont(8).
rc.local
Sourced in runit stage 2. A shell script which can be used to specify configuration to be done prior to login.
rc.shutdown
Sourced in runit stage 3. A shell script which can be used to specify tasks to be done during shutdown.
Cron
cron is a daemon for running programs at
regular intervals. The programs and intervals are specified in a crontab
file,
which can be edited with crontab(1).
Running crontab -e
as the superuser will edit the system crontab; otherwise,
it will edit the crontab for the current user.
By default, a cron daemon is not installed. However, multiple cron implementations are available, including cronie, dcron, fcron and more.
Once you have chosen and installed an implementation,
enable the corresponding service. There
is also a generic crond
service which is maintained by the alternatives
system, but there is no real benefit in using it and just makes your setup
harder to follow.
As an alternative to the standard cron implementations, you can use
snooze(1) together with the
snooze-hourly
, snooze-daily
, snooze-weekly
and snooze-monthly
services,
which are provided by the snooze
package for this purpose. Each of these
services execute scripts in the respective /etc/cron.*
directories.
Solid State Drives
Post installation, you will need to enable TRIM for solid state drives. You can check which devices allow TRIM by running:
$ lsblk --discard
If the DISC-GRAN (discard granularity) and DISC-MAX (discard maximum bytes) columns are non-zero, that means the block device has TRIM support. If your solid state drive partition does not show TRIM support, please verify that you chose a file system with TRIM support (ext4, Btrfs, F2FS, etc.). Note that F2FS requires kernel 4.19 or above to support TRIM.
To run TRIM one-shot, you can run
fstrim(8)
manually. For example, if your
/ directory is on an SSD:
# fstrim /
To automate running TRIM, use cron or add the discard
option to /etc/fstab
.
Periodic TRIM with cron
Add the following lines to /etc/cron.weekly/fstrim
:
#!/bin/sh
fstrim /
Finally, make the script executable:
# chmod u+x /etc/cron.weekly/fstrim
Continuous TRIM with fstab discard
You can use either continuous or periodic TRIM, but usage of continuous TRIM is discouraged if you have an SSD that doesn't handle NCQ correctly. Refer to the kernel blacklist.
Edit /etc/fstab
and add the discard
option to block devices that need TRIM.
For example, if /dev/sda1
was an SSD partition, formatted as ext4, and mounted
at /
:
/dev/sda1 / ext4 defaults,discard 0 1
LVM
To enable TRIM for LVM's commands (lvremove
, lvreduce
, etc.), open
/etc/lvm/lvm.conf
, uncomment the issue_discards
option, and set it to 1
:
issue_discards=1
LUKS
Warning: Before enabling discard for your LUKS partition, please be aware of the security implications.
To open an encrypted LUKS device and allow discards to pass through, open the
device with the --allow-discards
option:
# cryptsetup luksOpen --allow-discards /dev/sdaX luks
Non-root devices
Edit /etc/crypttab
and set the discard
option for devices on the SSD. For
example, if you have a LUKS device with the name externaldrive1
, device
/dev/sdb2
, and password none
:
externaldrive1 /dev/sdb2 none luks,discard
Root devices
If your root device is on LUKS, add rd.luks.allow-discards
to
CMDLINE_LINUX_DEFAULT
. In the case of GRUB, edit /etc/default/grub
:
GRUB_CMDLINE_LINUX_DEFAULT="rd.luks.allow-discards"
Then update GRUB:
# update-grub
Verifying configuration
To verify that you have configured TRIM correctly for LUKS, reboot and run:
# dmsetup table /dev/mapper/crypt_dev --showkeys
If this command output contains the string allow_discards
, you have
successfully enabled TRIM on your LUKS device.
ZFS
Before running trim
on a ZFS pool, ensure that all devices in the pool support
it:
# zpool get all | grep trim
If the pool allows autotrim
(set off
by default), you can trim
the pool
periodically or automatically. To one-shot trim
yourpoolname
:
# zpool trim yourpoolname
Periodic TRIM
Add the following lines to /etc/cron.daily/ztrim
:
#!/bin/sh
zpool trim yourpoolname
Finally, make the script executable:
# chmod u+x /etc/cron.daily/ztrim
Autotrim
To set autotrim for yourpoolname
, run:
# zpool set autotrim=on yourpoolname
Security
There are several ways you can make your installation more secure. This section explores some of them.
Section Contents
AppArmor
AppArmor is a mandatory access control mechanism (like SELinux). It can constrain programs based on pre-defined or generated policy definitions.
Void ships with some default profiles for several services, such as dhcpcd
and
wpa_supplicant
. Container runtimes such as LXC and podman integrate with
AppArmor for better security for container payloads.
To use AppArmor on a system, one must:
- Install the
apparmor
package. - Set
apparmor=1 security=apparmor
on the kernel commandline.
To accomplish the second step, consult the documentation on how to modify the kernel cmdline.
The APPARMOR
variable in /etc/default/apparmor
controls how profiles will be
loaded at boot, the value is set to complain
by default and corresponds to
AppArmor modes (disable
, complain
, enforce
).
AppArmor tools aa-genprof(8) and aa-logprof(8) require either configured syslog or a running auditd(8) service.
Date and Time
To view your system's current date and time information, as well as make direct changes to it, use date(1).
Timezone
The default system timezone can be set by linking the timezone file to
/etc/localtime
:
# ln -sf /usr/share/zoneinfo/<timezone> /etc/localtime
Note: If the variable
TIMEZONE
is set in/etc/rc.conf
, it should be removed or commented out, as this will override what has been set withln
on reboot.
To change the timezone on a per user basis, the TZ
variable can be exported
from your shell's profile:
export TZ=<timezone>
Note that setting the timezone does not set the time (or date); instead, it simply specifies an offset from UTC, as described in timezone(3).
Hardware clock
By default, the hardware clock in Void is stored as UTC. Windows does not use
UTC by default, and if you are dual-booting, this will conflict with Void. You
can either change Windows to use UTC, or change Void Linux to use localtime
by
setting the HARDWARECLOCK
variable in /etc/rc.conf
:
export HARDWARECLOCK=localtime
For more details, see hwclock(8).
NTP
To maintain accuracy of your system's clock, you can use the Network Time Protocol (NTP).
Void provides packages for the following NTP daemons: NTP, OpenNTPD, Chrony and ntpd-rs.
Once you have installed an NTP daemon, you can enable the
service for it, either through
its own service or the ntpd
service managed by
xbps-alternatives(1).
NTP
NTP is the official reference implementation of the Network Time Protocol.
The ntp
package provides NTP and the isc-ntpd
service.
For further information, visit the NTP site.
OpenNTPD
OpenNTPD focuses on providing a secure, lean NTP implementation which "just works" with reasonable accuracy for a majority of use-cases.
The openntpd
package provides OpenNTPD and the openntpd
service.
For further information, visit the OpenNTPD site.
Chrony
Chrony is designed to work well in a variety of conditions; it can synchronize faster and with greater accuracy than NTP.
The chrony
package provides Chrony and the chronyd
service.
The Chrony site provides a brief overview of its advantages over NTP, as well as a detailed feature comparison between Chrony, NTP and OpenNTPD.
ntpd-rs
ntpd-rs is a full-featured NTP server and client implementation, including NTS support.
The ntpd-rs
package provides ntpd-rs and the ntpd-rs
service.
For further information and migration guides from other implementations, visit the ntpd-rs docs.
Kernel
Kernel series
Void Linux provides many kernel series in the default repository. These are
named linux<x>.<y>
: for example, linux4.19
. You can query for all available
kernel series by running:
$ xbps-query --regex -Rs '^linux[0-9.]+-[0-9._]+'
The linux
meta package, installed by default, depends on one of the kernel
packages, usually the package containing the latest mainline kernel that works
with all DKMS modules. Newer kernels might be available in the repository, but
are not necessarily considered stable enough to be the default; use these at
your own risk. If you wish to use a more recent kernel and have DKMS modules
that you need to build, install the relevant linux<x>.<y>-headers
package,
then use xbps-reconfigure(1) to
reconfigure the linux<x>.<y>
package you installed. This will build the DKMS
modules.
Removing old kernels
When updating the kernel, old versions are left behind in case it is necessary
to roll back to an older version. Over time, old kernel versions can accumulate,
consuming disk space and increasing the time taken by DKMS module updates.
Furthermore, if /boot
is a separate partition and fills up with old kernels,
updating can fail or result in incomplete initramfs filesystems to be generated
and result in kernel panics if they are being booted. Thus, it may be advisable
to clean old kernels from time to time.
Removing old kernels is done using the
vkpurge(8) utility. vkpurge
comes
pre-installed on every Void Linux system. This utility runs the necessary
hooks when removing old kernels. Note that vkpurge
does not
remove kernel packages, only particular kernels.
Removing the default kernel series
If you've installed a kernel package for a series other than the default, and
want to remove the default kernel packages, you should install the linux-base
package or mark it as a manual package
in case it is already installed. After this procedure, you can remove the
default kernel packages with
xbps-remove(1). It might be necessary
to add linux
and linux-headers
to an ignorepkg
entry in
xbps.d(5), since base packages can depend
on them.
Switching to another kernel series
If you'd like to use the linux-lts
or linux-mainline
kernel series instead
of the default linux
, first install the desired series metapackage (and the
linux-lts-headers
or linux-mainline-headers
metapackage if needed). Then you
can add linux
and linux-headers
to an ignorepkg
entry in
xbps.d(5) and uninstall those packages.
Changing the default initramfs generator
By default, Void Linux uses dracut to
prepare initramfs images for installed kernels. Alternatives such as
mkinitcpio are available. Each
initramfs generator registers an XBPS
alternative in the initramfs
group to link its kernel hooks to be used when creating or
removing initramfs images for a given kernel.
To replace dracut with, e.g., mkinitcpio, install the mkinitcpio
package;
confirm that mkinitcpio
appears in the list of available alternatives by
running
$ xbps-alternatives -l -g initramfs
Issue the command
# xbps-alternatives -s mkinitcpio
to replace the dracut kernel hooks with those provided by mkinitcpio. With subsequent kernel updates (or updates to DKMS packages that trigger initramfs regeneration), mkinitcpio will be used instead of dracut to prepare initramfs images. To force images to regenerate, reconfigure your kernel packages by invoking
# xbps-reconfigure -f linux<x>.<y>
for each linux<x>.<y>
package that is currently installed.
cmdline
The kernel, the initial RAM disk (initrd) and some system programs can be configured at boot by kernel command line arguments. The parameters understood by the kernel are explained in the kernel-parameters documentation and by bootparam(7). Parameters understood by dracut can be found in dracut.cmdline(7).
Once the system is booted, the current kernel command line parameters can be
found in the /proc/cmdline
file. Some system programs can change their
behavior based on the parameters passed in the command line, which is what
happens when booting a different
runsvdir, for example.
There are different ways of setting these parameters, some of which are explained below.
GRUB
Kernel command line arguments can be added through the GRUB bootloader by
editing /etc/default/grub
, changing the GRUB_CMDLINE_LINUX_DEFAULT
variable
and then running update-grub
.
dracut
Dracut offers a kernel_cmdline
configuration
option and --kernel-cmdline
command-line option that will encode
command-line arguments directly in the initramfs image. When dracut is used to
create a UEFI executable, arguments set with these options will be passed to the
kernel. However, when an ordinary initramfs is produced, these options will
not be passed to the kernel at boot. Instead, they will be written to a
configuration file in /etc/cmdline.d
within the image. While dracut parses
this configuration to control its own boot-time behavior, the kernel itself will
not be aware of anything set via this mechanism.
After modifying a dracut configuration, regenerate the initramfs to ensure that it includes the changes.
Kernel hardening
Void Linux ships with some kernel security options enabled by default. This was
originally provided by kernel command line arguments slub_debug=P page_poison=1
, but since kernel series 5.3, these have been replaced with
init_on_alloc
and init_on_free
(see this
commit).
Void's kernels come with the init_on_alloc
option enabled by default where
available (i.e. linux5.4
and greater). In most cases you should usually not
disable it, as it has a fairly minimal impact on performance (within 1%). The
init_on_free
option is more expensive (around 5% on average) and needs to be
enabled manually by passing init_on_free=1
on the kernel command line. If you
need to disable init_on_alloc
, you can do that similarly by passing
init_on_alloc=0
.
There is a chance that your existing system still has the old options enabled.
They still work in newer kernels, but have a performance impact more in line
with init_on_free=1
. On older hardware this can be quite noticeable. If you
are running a kernel series older than 5.4, you can keep them (or add them) for
extra security at the cost of speed; otherwise you should remove them.
Kernel modules
Kernel modules are typically drivers for devices or filesystems.
Loading kernel modules during boot
Normally the kernel automatically loads required modules, but sometimes it may be necessary to explicitly specify modules to be loaded during boot.
To load kernel modules during boot, a .conf
file like
/etc/modules-load.d/virtio.conf
needs to be created with the contents:
# load virtio-net
virtio-net
Blacklisting kernel modules
Blacklisting kernel modules is a method for preventing modules from being loaded by the kernel. There are two different methods for blacklisting kernel modules, one for modules loaded by the initramfs and one for modules loaded after the initramfs process is done. Modules loaded by the initramfs have to be blacklisted in the initramfs configuration.
To blacklist modules loaded after the initramfs process, create a .conf
file,
like /etc/modprobe.d/radeon.conf
, with the contents:
blacklist radeon
Blacklisting modules in the initramfs
After making the necessary changes to the configuration files, the initramfs needs to be regenerated for the changes to take effect on the next boot.
dracut
Dracut can be configured to not include kernel modules through a configuration
file. To blacklist modules from being included in a dracut initramfs, create a
.conf
file, like /etc/dracut.conf.d/radeon.conf
, with the contents:
omit_drivers+=" radeon "
mkinitcpio
To blacklist modules from being included in a mkinitcpio initramfs a .conf
file needs to be created like /etc/modprobe.d/radeon.conf
with the contents:
blacklist radeon
Kernel hooks
Void Linux provides directories for kernel hooks in
/etc/kernel.d/{pre-install,post-install,pre-remove,post-remove}
.
These hooks are used to update the boot menus for bootloaders like grub
,
gummiboot
and lilo
.
Install hooks
The {pre,post}-install
hooks are executed by
xbps-reconfigure(1) when
configuring a Linux kernel, such as building its initramfs. This happens when a
kernel series is installed for the first time or updated, but can also be run
manually:
# xbps-reconfigure --force linux<x>.<y>
If run manually, they serve to apply initramfs configuration changes to the next boot.
Remove hooks
The {pre,post}-remove
hooks are executed by
vkpurge(8) when removing old kernels.
Dynamic Kernel Module Support (DKMS)
There are kernel modules that are not part of the Linux source tree that are
built at install time using DKMS and kernel hooks. The
available modules can be listed by searching for dkms
in the package
repositories.
DKMS build logs are available in /var/lib/dkms/
.
Power Management
acpid
The acpid
service for acpid(8) is
installed and, if Void was installed from a live image using the local source,
will be enabled by default. ACPI events are handled by /etc/acpi/handler.sh
,
which uses zzz(8) for suspend-to-RAM events.
elogind
The elogind
service is provided by the elogind
package. By default,
elogind(8) listens for, and processes,
ACPI events related to lid-switch activation and the power, suspend and
hibernate keys. This will conflict with the acpid
service if it is installed
and enabled. Either disable acpid
when enabling elogind
, or configure
elogind
to ignore
ACPI events in
logind.conf(5). There are several
configuration options, all starting with the keyword Handle
, that should be
set to ignore
to avoid interfering with acpid
.
To run loginctl poweroff
and loginctl reboot
without root privileges,
polkit
must be installed.
Power Saving - tlp
Laptop battery life can be extended by using
tlp(8). To use it, install the tlp
package,
and enable the tlp
service. Refer to
the TLP documentation for details.
Network
Network configuration in Void Linux can be done in several ways. The default installation comes with the dhcpcd(8) service enabled.
Interface Names
Newer versions of udev(7) no longer use the
traditional Linux naming scheme for interfaces (eth0
, eth1
, wlan0
, ...).
This behavior can be reverted by adding net.ifnames=0
to the kernel
cmdline.
Static Configuration
A simple way to configure a static network at boot is to add the necessary
ip(8) commands to the /etc/rc.local
file:
ip link set dev eth0 up
ip addr add 192.168.1.2/24 brd + dev eth0
ip route add default via 192.168.1.1
Bridge Interfaces
To configure bridge interfaces at boot, the /etc/rc.local
file can be used to
run ip(8) commands to add the bridge br0
and
set it as the master for the eth0
interface as example:
ip link add name br0 type bridge
ip link set eth0 master br0
ip link set eth0 up
dhcpcd
To run dhcpcd(8) on all interfaces, enable
the dhcpcd
service.
To run dhcpcd
only on a specific interface, copy the dhcpcd-eth0
service and
modify it to match your interface:
$ ip link show
1: lo: <LOOPBACK,UP,LOWER_UP> mtu 65536 qdisc noqueue state UNKNOWN mode DEFAULT group default qlen 1
link/loopback 00:00:00:00:00:00 brd 00:00:00:00:00:00
2: enp3s0: <BROADCAST,MULTICAST,UP,LOWER_UP> mtu 1500 qdisc pfifo_fast state UP mode DEFAULT group default qlen 1000
link/ether ff:ff:ff:ff:ff:ff brd ff:ff:ff:f
# cp -R /etc/sv/dhcpcd-eth0 /etc/sv/dhcpcd-enp3s0
# sed -i 's/eth0/enp3s0/' /etc/sv/dhcpcd-enp3s0/run
# ln -s /etc/sv/dhcpcd-enp3s0 /var/service/
For more information on configuring dhcpcd
, refer to
dhcpcd.conf(5)
Wireless
Before using wireless networking, use rfkill(8) to check whether the relevant interfaces are soft- or hard-blocked.
Void provides several ways to connect to wireless networks:
Firewalls
iptables
By default, the iptables
package is installed on the base system. It provides
iptables(8)/ip6tables(8). The related
services use the /etc/iptables/iptables.rules
and
/etc/iptables/ip6tables.rules
ruleset files, which must be created by the
system administrator.
Two example rulesets are provided in the /etc/iptables
directory:
empty.rules
and simple_firewall.rules
.
Applying the rules at boot
To apply iptables rules at runit stage 1, install the runit-iptables
package.
This adds a core-service which restores the iptables.rules
and
ip6tables.rules
rulesets.
Alternatively, to apply these rules at stage 2, add the following to
/etc/rc.local
:
if [ -e /etc/iptables/iptables.rules ]; then
iptables-restore /etc/iptables/iptables.rules
fi
if [ -e /etc/iptables/ip6tables.rules ]; then
ip6tables-restore /etc/iptables/ip6tables.rules
fi
After rebooting, check the active firewall rules:
# iptables -L
# ip6tables -L
Applying the rules at runtime
iptables
comes with two runit services, iptables
and ip6tables
, to quickly
flush or restore the iptables.rules
and ip6tables.rules
rulesets. Once these
services are enabled, you can flush
the rulesets by downing the relevant service, e.g.:
# sv down iptables
and restore them by upping the relevant service, e.g.:
# sv up ip6tables
nftables
nftables
replaces iptables
, ip6tables
, arptables
and ebtables
(collectively referred to as xtables
). The nftables
wiki describes
the main
differences
from the iptables
toolset.
To use nftables
, install the nftables
package, which provides
nft(8). It also provides
iptables-translate(8)/ip6tables-translate(8)
and
iptables-restore-translate(8)/ip6tables-restore-translate(8),
which convert iptables
rules to nftables
rules.
Applying the rules at boot
To apply nftables rules at runit stage 1, install the runit-nftables
package.
This adds a core-service which restores the ruleset in /etc/nftables.conf
.
Applying the rules at runtime
The nftables
package provides the nftables
service, which uses rules from
/etc/nftables.conf
. Once you enable
the nftables
service, to load the rules, run:
# sv up nftables
To flush the rules, run:
# sv down nftables
wpa_supplicant
The wpa_supplicant
package is installed by default on the base system. It
includes utilities to configure wireless interfaces and handle wireless security
protocols. To use wpa_supplicant, you will need to enable the wpa_supplicant
service.
wpa_supplicant(8) is a daemon that
manages wireless interfaces based on
wpa_supplicant.conf(5)
configuration files. An extensive overview of configuration options, including
examples, can be found in
/usr/share/examples/wpa_supplicant/wpa_supplicant.conf
.
wpa_passphrase(8) helps create
pre-shared keys for use in configuration files.
wpa_cli(8) provides a CLI for managing
the wpa_supplicant
daemon.
WPA-PSK
To use WPA-PSK, generate a pre-shared key with
wpa_passphrase(8) and append the
output to the relevant wpa_supplicant.conf
file:
# wpa_passphrase <MYSSID> <passphrase> >> /etc/wpa_supplicant/wpa_supplicant.conf
WPA-EAP
WPA-EAP is often used for institutional logins, notably eduroam. This does not use PSK, but a password hash can be generated like this:
$ echo -n <passphrase> | iconv -t utf16le | openssl md4
WEP
For WEP configuration, add the following lines to your device's
wpa-supplicant.conf
:
network={
ssid="MYSSID"
key_mgmt=NONE
wep_key0="YOUR AP WEP KEY"
wep_tx_keyidx=0
auth_alg=SHARED
}
The wpa_supplicant service
The wpa_supplicant
service checks the following options in
/etc/sv/wpa_supplicant/conf
:
OPTS
: Options to be passed to the service. Overrides any other options.CONF_FILE
: Path to file to be used for configuration. Defaults to/etc/wpa_supplicant/wpa_supplicant.conf
.WPA_INTERFACE
: Interface to be matched. May contain a wildcard; defaults to all interfaces.DRIVER
: Driver to use. Seewpa_supplicant -h
for available drivers.
If no conf
file is found, the service searches for the following files in
/etc/wpa_supplicant
:
wpa_supplicant-<interface>.conf
: If found, these files are bound to the named interface.wpa_supplicant.conf
: If found, this file is loaded and binds to all other interfaces found.
Once you are satisfied with your configuration,
enable the wpa_supplicant
service.
Using wpa_cli
When using wpa_cli
to manage wpa_supplicant
from the command line, be sure
to specify which network interface to use via the -i
option, e.g.:
# wpa_cli -i wlp2s0
Not doing so can result in various wpa_cli
commands (for example, scan
and
scan_results
) not producing the expected output.
IWD
IWD (iNet Wireless Daemon) is a wireless daemon for Linux that aims to replace WPA supplicant.
Installation
Install the iwd
package and enable the dbus
and iwd
services.
Usage
The command-line client iwctl(1) can be
used to add, remove, and configure network connections. Commands can be passed
as arguments; when run without arguments, it provides an interactive session. To
list available commands, run iwctl help
, or run iwctl
and enter help
at
the interactive prompt.
By default, only the root user and those in the wheel
group have permission to
operate iwctl
.
Configuration
Daemon configuration
The main configuration file is located in /etc/iwd/main.conf
. If it does not
exist, you may create it. It is documented in
iwd.config(5).
Network configuration
Network configuration, including examples, is documented in
iwd.network(5). IWD stores
information on known networks, and reads information on pre-provisioned networks
from network configuration files located in /var/lib/iwd
; IWD monitors the
directory for changes. Network configuration filenames consist of the encoding
of the SSID followed by .open
, .psk
, or .8021x
as determined by the
security type.
As an example, a basic configuration file for a WPA2/PSK secured network would
be called <ssid>.psk
, and it would contain the plain text password:
[Security]
Passphrase=<password>
Troubleshooting
By default, IWD will create and destroy the wireless interfaces (e.g. wlan0
)
that it manages. This can interfere with udevd
, which may attempt to rename
the interface using its rules for persistent network interface names. The
following messages may be printed to your screen as a symptom of this
interference:
[ 39.441723] udevd[1100]: Error changing net interface name wlan0 to wlp59s0: Device or resource busy
[ 39.442472] udevd[1100]: could not rename interface '3' from 'wlan0' to 'wlp59s0': Device or resource busy
A simple fix is to prevent IWD from manipulating the network interfaces in this
way by adding UseDefaultInterface=true
to the [General]
section of
/etc/iwd/main.conf
.
An alternative approach is to disable the use of persistent network interface
names by udevd
. This may be accomplished either by adding net.ifnames=0
to
your kernel cmdline or by creating a symbolic link to
/dev/null
at /etc/udev/rules.d/80-net-name-slot.rules
to mask the renaming
rule. This alternative approach will affect the naming of all network devices.
NetworkManager
NetworkManager(8) is a daemon that
manages Ethernet, Wi-Fi, and mobile broadband network connections. Install the
NetworkManager
package for the basic NetworkManager utilities.
Starting NetworkManager
Before enabling the NetworkManager daemon, disable any
other network management services, such as dhcpcd,
wpa_supplicant, or wicd
. These services all control
network interface configuration, and will interfere with NetworkManager.
Also ensure that the dbus
service is enabled and
running. NetworkManager uses dbus
to expose networking information and a
control interface to clients, and will fail to start without it.
Finally, enable the NetworkManager
service.
Configuring NetworkManager
Users of NetworkManager must belong to the network
group.
The NetworkManager
package includes a command line tool,
nmcli(1), and a text-based user interface,
nmtui(1), to control network settings.
There are many other front-ends to NetworkManager, including nm-applet
(from
network-manager-applet
) or nm-tray
for system trays, plasma-nm
for KDE
Plasma, and a built-in network configuration tool in GNOME.
Eduroam with NetworkManager
Eduroam is a roaming service providing international, secure Internet access at universities and other academic institutions. More information can be found here.
Dependencies
Install the python3-dbus
package.
Installation
Download the correct eduroam_cat installer for your institution from here and execute it. It will provide a user interface guiding you through the process.
ConnMan
ConnMan(8) is a daemon that manages
network connections, is designed to be slim and to use as few resources as
possible. The connman
package contains the basic utilities to run ConnMan.
Starting ConnMan
To enable the ConnMan daemon, first disable any other
network managing services like dhcpcd,
wpa_supplicant, or wicd
. These services all control
network interface configuration, and interfere with each other.
Finally, enable the connmand
service.
Configuring ConnMan
ConnMan CLI
The connman
package includes a command line tool,
connmanctl(1) to control network
settings. If you do not provide any commands, connmanctl
starts as an
interactive shell.
Establishing a connection to an access point using the connmanctl
interactive
shell might look as follows:
# connmanctl
> enable wifi
> agent on
> scan wifi
> services
> connect wifi_<uniqueid>
> exit
ConnMan Front-End Tools
There are many other front-ends to ConnMan, including connman-ui
for system
trays, connman-gtk
for GTK, cmst
for QT and connman-ncurses
for ncurses
based UI.
Preventing DNS overrides by ConnMan
Create /etc/sv/connmand/conf
with the following content:
OPTS="--nodnsproxy"
Network Filesystems
NFS
Mounting an NFS Share
To mount an NFS share, start by installing the nfs-utils
and sv-netmount
packages.
Before mounting an NFS share, enable
the statd
, rpcbind
, and netmount
services. If the server supports nfs4
,
the statd
service isn't necessary.
To mount an NFS share:
# mount -t <mount_type> <host>:/path/to/sourcedir /path/to/destdir
<mount_type>
should be nfs4
if the server supports it, or nfs
otherwise.
<host>
can be either the hostname or IP address of the server.
Mounting options can be found in mount.nfs(8), while unmounting options can be found in umount.nfs(8).
For example, to connect /volume
on a server at 192.168.1.99
to an existing
/mnt/volume
directory on your local system:
# mount -t nfs 192.168.1.99:/volume /mnt/volume
To have the directory mounted when the system boots, add an entry to fstab(5):
192.168.1.99:/volume /mnt/volume nfs rw,hard 0 0
Refer to nfs(5) for information about the available mounting options.
Setting up a server (NFSv4, Kerberos disabled)
To run an NFS server, start by installing the nfs-utils
package.
Edit /etc/exports
to add a shared volume:
/storage/foo *.local(rw,no_subtree_check,no_root_squash)
This line exports the /storage/foo
directory to any host in the local domain,
with read/write access. For information about the no_subtree_check
and
no_root_squash
options, and available options more generally, refer to
exports(5).
Finally, enable the rpcbind
, statd
,
and nfs-server
services.
This will start your NFS server. To check if the shares are working, use the showmount(8) utility to check the NFS server status:
# showmount -e localhost
You can use nfs.conf(5) to configure your server.
Session and Seat Management
Session and seat management is not necessary for every setup, but it can be used to safely create temporary runtime directories, provide access to hardware devices and multi-seat capabilities, and control system shutdown.
D-Bus
D-Bus is an IPC (inter-process communication) mechanism used by userspace software in Linux. D-Bus can provide a system bus and/or a session bus, the latter being specific to a user session.
- To provide a system bus, you should
enable the
dbus
service. This might require a system reboot to work properly. - To provide a session bus, you can start a given program (usually a window
manager or interactive shell) with
dbus-run-session(1). Most
desktop environments, if launched through an adequate display manager, will
launch a D-Bus session themselves. If a D-Bus session is active for the
current session, the environment variable
DBUS_SESSION_BUS_ADDRESS
should be defined.
Note that some software assumes the presence of a system bus, while other software assumes the presence of a session bus.
elogind
elogind(8) manages user logins and system
power, as a standalone version of systemd-logind
. elogind provides necessary
features for most desktop environments and Wayland compositors. It can also be
one of the mechanisms for rootless Xorg.
Please read the "Power Management" section for things to consider before installing elogind.
To make use of its features, install the elogind
package and make sure the
system D-Bus is enabled. You might need to log out and in again.
If you're having any issues with elogind, enable its service, as waiting for a D-Bus activation can lead to issues.
turnstile
turnstile is an alternative session manager, and can be used with or without elogind.
If using turnstile with elogind, disable rundir (XDG_RUNTIME_DIR
) management
in /etc/turnstile/turnstiled.conf
by setting manage_rundir
to no
. Note
that while elogind and turnstile currently can coexist, this may change in the
future.
If using turnstile without elogind, consider installing and enabling seatd for seat management and acpid for power management.
To use it, enable the turnstiled
service and re-log in.
Turnstile can also manage per-user
services (including running a D-Bus
session bus), removing the need for wrapping graphical sessions with
dbus-run-session
.
seatd
seatd(1) is a minimal seat management daemon and an alternative to elogind primarily for wlroots compositors.
To use it, install the seatd
package and enable its service. If you want
non-root users to be able to access the seatd session, add them to the _seatd
group.
Note that, unlike elogind, seatd doesn't do anything besides managing seats.
XDG_RUNTIME_DIR
XDG_RUNTIME_DIR
is an environment variable defined by the XDG Base Directory
Specification.
Its value sets the path to the base directory where programs should store
user-specific runtime files.
Install elogind or turnstile as your session manager
to automatically set up XDG_RUNTIME_DIR
.
Alternatively, manually set the environment variable through the shell. Make
sure to create a dedicated user directory and set its permissions to 700
. A
good default location is /run/user/$(id -u)
.
Graphical Session
In order to configure a graphical session, you need:
- Graphics drivers
- A basis for your graphical session: Xorg or Wayland
You may also need:
Graphics Drivers
This section covers basic graphics setup depending on the hardware configuration of your system.
Section Contents
AMD or ATI
AMD GPU support requires the linux-firmware-amd
package. If you have installed
the linux
or linux-lts
packages, it will be installed as a dependency. If
you installed a version-specific kernel package (e.g., linux5.4
), it may be
necessary to manually install linux-firmware-amd
.
OpenGL
Install the Mesa DRI package, mesa-dri
. This is already included in the xorg
meta-package, but it is needed when installing Xorg via xorg-minimal
or for
running a Wayland compositor.
Vulkan
Install vulkan-loader
, the Khronos Vulkan Loader. Then install one or both of
the Mesa AMD Vulkan driver, mesa-vulkan-radeon
; or the GPUOpen AMD Vulkan
driver, amdvlk
.
Xorg
Installing the xorg
meta-package will pull in both xf86-video-amdgpu
and,
for older hardware, xf86-video-ati
. If you install xorg-minimal
, choose one
of these Xorg driver packages to match your hardware. The amdgpu
driver should
support cards built on AMD's "Graphics Core Next 1.2" architecture, introduced
circa 2012.
Video acceleration
Install the mesa-vaapi
and mesa-vdpau
packages.
Intel
Intel GPU support requires the linux-firmware-intel
package. If you have
installed the linux
or linux-lts
packages, it will be installed as a
dependency. If you installed a version-specific kernel package (e.g.,
linux5.4
), it may be necessary to manually install linux-firmware-intel
.
OpenGL
OpenGL requires the Mesa DRI package, mesa-dri
. This is provided by the xorg
meta-package, but will need to be installed manually when using the
xorg-minimal
package or running a Wayland compositor.
Vulkan
Install the Khronos Vulkan Loader and the Mesa Intel Vulkan driver packages,
respectively vulkan-loader
and mesa-vulkan-intel
.
Video acceleration
Install the intel-video-accel
meta-package:
This will install all the Intel VA-API drivers. intel-media-driver
will be
used by default, but this choice can be overridden at runtime via the
environment variable LIBVA_DRIVER_NAME
:
Driver Package | Supported GPU Gen | Explicit selection |
---|---|---|
libva-intel-driver | up to Coffee Lake | LIBVA_DRIVER_NAME=i965 |
intel-media-driver | from Broadwell | LIBVA_DRIVER_NAME=iHD |
Troubleshooting
The kernels packaged by Void are configured with
CONFIG_INTEL_IOMMU_DEFAULT_ON=y
, which can lead to issues with their graphics
drivers, as reported by the kernel
documentation.
To fix this, it is necessary to disable IOMMU for the integrated GPU. This can
be done by adding intel_iommu=igfx_off
to your kernel
cmdline. This problem is expected to happen on the
Broadwell generation of internal GPUs. If you have another internal GPU and your
issues are fixed by this kernel option, you should file a bug reporting the
problem to kernel developers.
For newer Intel chipsets, the DDX drivers may interfere with
correct operation. This is characterized by graphical acceleration not working
and general graphical instability. If this is the case, try removing all
xf86-video-*
packages.
On some Intel chipsets, the DDX drivers may be required. If
this is the case, install xf86-video-intel
.
NVIDIA
nouveau (Open Source Driver)
This is a reverse engineered driver largely developed by the community, with some documentation provided by Nvidia. It tends to perform well on older hardware, and is required to use a large portion of the available Wayland compositors.
At the time of writing, graphics cards starting with second generation Maxwell
(GTX 9xx) are unable to perform at their full potential with nouveau
. This is
because the linux-firmware
collection is missing signed firmware blobs needed
to reclock these cards past their boot frequencies.
To use nouveau
with Wayland, you only need the mesa-dri
package, which
provides the accelerated OpenGL driver. On X11, you also need an appropriate
Xorg driver. You can either install xf86-video-nouveau
or use the universal
modesetting
driver bundled with Xorg (this is the only option on Tegra based
ARM boards). The former can make use of GPU-specific 2D acceleration paths,
which is primarily useful on older cards with specialized fixed function
hardware (the modesetting
driver will accelerate 2D using OpenGL via GLAMOR).
When in doubt, it's a good idea to try xf86-video-nouveau
first.
Note: xf86-video-nouveau
is usually installed by default if you use the xorg
metapackage. If you use xorg-minimal
, you will need to install it manually,
either directly or through xorg-video-drivers
.
nvidia (Proprietary Driver)
The proprietary drivers are available in the nonfree repository.
Check if your graphics card belongs to the legacy
branch. If it does not,
install the nvidia
package. Otherwise you should install the appropriate
legacy driver, nvidia470
or nvidia390
. The older legacy driver, nvidia340
,
is no longer available, and users are encouraged to switch to
nouveau.
Brand | Type | Model | Driver Package |
---|---|---|---|
NVIDIA | Proprietary | 800+ | nvidia |
NVIDIA | Proprietary | 600/700 | nvidia470 |
NVIDIA | Proprietary | 400/500 Series | nvidia390 |
The proprietary driver integrates in the kernel through DKMS.
This driver offers better performance and power handling, and is recommended where performance is needed.
32-bit program support (glibc only)
In order to run 32-bit programs with driver support, you need to install additional packages.
If using the nouveau
driver, install the mesa-dri-32bit
package.
If using the nvidia
driver, install the nvidia<x>-libs-32bit
package. <x>
represents the legacy driver version (470
or 390
) or can be left empty for
the main driver.
Reverting from nvidia to nouveau
Uninstalling nvidia
In order to revert to the nouveau
driver, install the nouveau
driver (if it was not installed already), then
remove the nvidia
, nvidia470
, or nvidia390
package, as appropriate.
If you were using the obsolete nvidia340
driver, you might need to install the
libglvnd
package after removing the nvidia340
package.
Keeping both drivers
It is possible to use the nouveau
driver while still having the nvidia
driver installed. To do so, remove the blacklisting of nouveau
in
/etc/modprobe.d/nouveau_blacklist.conf
, /usr/lib/modprobe.d/nvidia.conf
, or
/usr/lib/modprobe.d/nvidia-dkms.conf
by commenting it out:
#blacklist nouveau
For Xorg, specify that it should load the nouveau
driver rather than the
nvidia
driver by creating the file /etc/X11/xorg.conf.d/20-nouveau.conf
with
the following content:
Section "Device"
Identifier "Nvidia card"
Driver "nouveau"
EndSection
You may need to reboot your system for these changes to take effect.
NVIDIA Optimus
NVIDIA Optimus refers to a dual graphics configuration found on laptops consisting of an Intel integrated GPU and a discrete NVIDIA GPU.
There are different methods to take advantage of the NVIDIA GPU, which depend on the driver version supported by your hardware.
In order to determine the correct driver to install, it is not enough to look at
the "Supported Products" list on NVIDIA's website, because they are not
guaranteed to work in an Optimus configuration. So the only way is to try
installing the latest nvidia
, rebooting, and looking at the kernel log. If
your device is not supported, you will see a message like this:
NVRM: The NVIDIA GPU xxxx:xx:xx.x (PCI ID: xxxx:xxxx)
NVRM: installed in this system is not supported by the xxx.xx
NVRM: NVIDIA Linux driver release. Please see 'Appendix
NVRM: A - Supported NVIDIA GPU Products' in this release's
NVRM: README, available on the Linux driver download page
NVRM: at www.nvidia.com.
which means you have to uninstall nvidia
and install the legacy nvidia390
.
A summary of the methods supported by Void, which are mutually exclusive:
- available on
nvidia
andnvidia470
- allows to switch to the NVIDIA GPU on a per-application basis
- more flexible but power saving capabilities depend on the hardware (pre-Turing devices are not shut down completely)
Offloading Graphics Display with RandR 1.4
- available on
nvidia
,nvidia470
, andnvidia390
- allows to choose which GPU to use at the start of the X session
- less flexible, but allows the user to completely shut down the NVIDIA GPU when not in use, thus saving power
- available on
nvidia
,nvidia470
, andnvidia390
- allows to switch to the NVIDIA GPU on a per-application basis
- unofficial method, offers poor performance
- uses the open source driver
nouveau
- allows to switch to the NVIDIA GPU on a per-application basis
nouveau
is a reverse-engineered driver and offers poor performance
You can check the currently used GPU by searching for renderer string
in the
output of the glxinfo
command. It is necessary to install the glxinfo
package for this. For the first two alternatives below, it is also possible to
verify that a process is using the NVIDIA GPU by checking the output of
nvidia-smi
.
PRIME Render Offload
In this method, GPU switching is done by setting environment variables when
executing the application to be rendered on the NVIDIA GPU. The wrapper script
prime-run
is available from the nvidia
package, and can be used as shown
below:
$ prime-run <application>
For more information, see NVIDIA's README
Bumblebee
Enable the bumblebeed
service and add the user to the bumblebee
group. This
requires a re-login to take effect.
Run the application to be rendered on the NVIDIA GPU with optirun
:
$ optirun <application>
Nouveau PRIME
This method uses the open source nouveau
driver. If the NVIDIA drivers are
installed, it is necessary to configure the system to use
nouveau
.
Set DRI_PRIME=1
to run an application on the NVIDIA GPU:
$ DRI_PRIME=1 <application>
Xorg
This section details the manual installation and configuration of the Xorg display server and common related services and utilities. If you would just like to install a full desktop environment, it is recommended to try the xfce image.
Installation
Void provides a comprehensive xorg
package which installs the server and all
of the free video drivers, input drivers, fonts, and base applications. This
package is a safe option, and should be adequate for most systems which don't
require proprietary video drivers.
If you would like to select only the packages you need, the xorg-minimal
package contains the base xorg server only. If you install only
xorg-minimal
, you will likely need to install a font package (like
xorg-fonts
), a terminal emulator (like xterm
), and a window manager to have
a usable graphics system.
Video Drivers
Void provides both open-source and proprietary (non-free) video drivers.
Open Source Drivers
Xorg can use two categories of open source drivers: DDX or modesetting.
DDX
The DDX drivers are installed with the xorg
package by default, or may be
installed individually if the xorg-minimal
package was installed. They are
provided by the xf86-video-*
packages.
For advanced configuration, see the man page corresponding to the vendor name, like intel(4).
Modesetting
Modesetting requires the mesa-dri
package, and no additional vendor-specific
driver package.
Xorg defaults to DDX drivers if they are present, so in this case modesetting must be explicitly selected: see Forcing the modesetting driver.
For advanced configuration, see modesetting(4).
Proprietary Drivers
Void also provides proprietary NVIDIA drivers, which are available in the nonfree repository.
Input Drivers
A number of input drivers are available for Xorg. If xorg-minimal
was
installed and a device is not responding, or behaving unexpectedly, a different
driver may correct the issue. These drivers can grab everything from power
buttons to mice and keyboards. They are provided by the xf86-input-*
packages.
Xorg Configuration
Although Xorg normally auto-detects drivers and configuration is not needed, a
config for a specific keyboard driver may look something like a file
/etc/X11/xorg.conf.d/30-keyboard.conf
with the contents:
Section "InputClass"
Identifier "keyboard-all"
Driver "evdev"
MatchIsKeyboard "on"
EndSection
Forcing the modesetting driver
Create the file /etc/X11/xorg.conf.d/10-modesetting.conf
:
Section "Device"
Identifier "GPU0"
Driver "modesetting"
EndSection
and restart Xorg. Verify that the configuration has been picked up with:
$ grep -E -m1 '\(II\) modeset\([0-9]+\):' /var/log/Xorg.0.log
If there is a match, modesetting is being used.
Starting X Sessions
startx
The xinit
package provides the startx(1)
script as a frontend to xinit(1), which can
be used to start X sessions from the console. For example, to start
i3(1), edit ~/.xinitrc
to contain exec /bin/i3
on the last line.
To start arbitrary programs together with an X session, add them in ~/.xinitrc
before the last line. For example, to start
xscreensaver(1) before starting i3,
add xscreensaver &
before the last line.
A ~/.xinitrc
file which starts xscreensaver
and i3
is shown below:
xscreensaver &
exec /bin/i3
Then call startx
to start a session.
If a D-Bus session bus is required, you can manually start one.
Display Managers
Display managers (DMs) provide a graphical login UI. A number of DMs are
available in the Void repositories, including gdm
(the GNOME DM), sddm
(the
KDE DM) and lightdm
. When setting up a display manager, be sure to test the
service before enabling it.
Wayland
This section details the manual installation and configuration of Wayland compositors and related services and utilities.
Installation
Unlike Xorg, Wayland implementations combine the display server, the window manager and the compositor in a single application.
Desktop Environments
GNOME, KDE Plasma and Enlightenment have Wayland sessions. GNOME uses its Wayland session by default. When using these desktop environments, applications built with GTK+ will automatically choose the Wayland backend, while Qt5 and EFL applications might require setting some environment variables if used outside KDE or Enlightenment, respectively.
Standalone compositors
Void Linux currently packages the following Wayland compositors:
- Weston: reference compositor for Wayland
- Sway: an i3-compatible Wayland compositor
- Wayfire: 3D Wayland compositor
- Hikari: a stacking compositor with some tiling features
- Cage: a Wayland kiosk
- River: a dynamic tiling Wayland compositor
- labwc: a window-stacking compositor, inspired by Openbox
- Qtile: a dynamic tiling Wayland compositor (via qtile-wayland)
Some compositors do not depend on any fonts, which can cause many applications to not work. Install a font package to fix this.
Video drivers
Both GNOME and KDE Plasma have EGLStreams backends for Wayland, which means they
can use the proprietary NVIDIA drivers. Most other Wayland compositors require
drivers that implement the GBM interface. The main driver for this purpose is
provided by the mesa-dri
package. The "Graphics
Drivers" section has more details regarding
setting up graphics in different systems.
Seat management
Wayland compositors require some way of controlling the video display and accessing input devices. In Void systems, this requires a seat manager service, which can be either elogind or seatd. Enabling them is explained in the "Session and Seat Management" session.
Native applications
Qt5-based applications require installing the qt5-wayland
package and setting
the environment variable QT_QPA_PLATFORM=wayland-egl
to enable their Wayland
backend. Some KDE specific applications also require installing the kwayland
package. EFL-based applications require setting the environment variable
ELM_DISPLAY=wl
, and can have issues without it, due to not supporting XWayland
properly. SDL-based applications require setting the
environment variable SDL_VIDEODRIVER=wayland
.
GTK+-based
applications should use the Wayland backend automatically.
Media applications, such as mpv(1),
vlc(1) and imv
work natively on Wayland.
Web browsers
Mozilla Firefox ships with a Wayland backend which is disabled by default. To
enable the Wayland backend, either set the environment variable
MOZ_ENABLE_WAYLAND=1
before running firefox
or use the provided
firefox-wayland
script.
Browsers based on GTK+ or Qt5, such as Midori and qutebrowser(1), should work on Wayland natively.
Running X applications inside Wayland
If an application doesn't support Wayland, it can still be used in a Wayland
context. XWayland is an X server that bridges this gap for most Wayland
compositors, and is installed as a dependency for most of them. Its package is
xorg-server-xwayland
. For Weston, the correct package is weston-xwayland
.
Configuration
The Wayland library requires the
XDG_RUNTIME_DIR
environment
variable to determine the directory for the Wayland socket.
It is also possible that some applications use the XDG_SESSION_TYPE
environment variable in some way, which requires that you set it to wayland
.
Fonts
A number of fonts and font collections are available from
XBPS. dejavu-fonts-ttf
or
xorg-fonts
are a good baseline if you're unsure of what to pick.
noto-fonts-ttf
contains fonts for many languages and scripts. noto-fonts-cjk
extends this with fonts for Chinese, Japanese, and Korean, and
noto-fonts-emoji
provides emojis. nerd-fonts
provides a number of fonts with
special characters like custom icons included.
Fonts not available from XBPS can be manually installed to either
/usr/share/fonts
(system-wide) or ~/.local/share/fonts
(per-user).
To customize font display in your graphical session, you can use configurations
provided in /usr/share/fontconfig/conf.avail/
. To do so, create a symlink to
the relevant .conf
file in /etc/fonts/conf.d/
, then use
xbps-reconfigure(1) to
reconfigure the fontconfig
package.
For example, to disable use of bitmap fonts:
# ln -s /usr/share/fontconfig/conf.avail/70-no-bitmaps.conf /etc/fonts/conf.d/
# xbps-reconfigure -f fontconfig
Use fc-conflist(1) to list which configurations are in effect.
Icons
GTK
By default, GTK-based applications try to use the Adwaita icon theme for
application icons. Consequently, installation of the gtk+3
package will also
install the adwaita-icon-theme
package. If you wish to use a different theme,
install the relevant package, then specify the theme in
/etc/gtk-3.0/settings.ini
or ~/.config/gtk-3.0/settings.ini
.
adwaita-icon-theme
can be removed after
ignoring the package.
For information about how to specify a different GTK icon theme in
settings.ini
, refer to the GtkSettings
documentation,
in particular the
"gtk-icon-theme-name"
property.
XDG Desktop Portals
Some applications, including Flatpak, use XDG Desktop Portals to provide access to various system interfaces, including file open and save dialogs, the clipboard, screencasting, opening URLs, and more.
Installation
XDG Desktop Portals require a user D-Bus session
bus. Install xdg-desktop-portal
and one or
more backends:
Backend | Notes |
---|---|
xdg-desktop-portal-gnome | Provides most common and GNOME-specific interfaces (GTK+ UI) |
xdg-desktop-portal-gtk | Provides most common interfaces (GTK+ UI) |
xdg-desktop-portal-kde | Provides most common and KDE-specific interfaces (Qt/KF5 UI) |
xdg-desktop-portal-lxqt | Only provides a file chooser (based on libfm-qt) |
io.elementary.files | Only provides a file chooser |
xdg-desktop-portal-wlr | Only provides a screenshot and screencasting interface for wlroots compositors |
If unsure what to choose, xdg-desktop-portal-gtk
is a good default choice.
Configuration
In most cases, the default configuration, located at
/usr/share/xdg-desktop-portal/portals.conf
, should suffice. If necessary, this
configuration can be overridden for specific desktop environments and portal
interfaces by creating $XDG_CURRENT_DESKTOP-portals.conf
or portals.conf
at
the system or user level as described in
portals.conf(5).
GNOME
Pre-installation
GNOME supports both X and Wayland sessions. Follow the "Wayland" or "Xorg" sections to setup your preferred environment.
Install the dbus
package, ensure the dbus
service is enabled, and reboot for
the changes to take effect.
Installation
Install the gnome
package for a GNOME environment which includes the base
GNOME desktop and a subset of GNOME applications. Additional applications are
available via the gnome-apps
package.
A minimal GNOME environment can be created by installing the gnome-core
package. Note, however, that not all GNOME features may be present or
functional.
If you require ZeroConf support, install the avahi
package and enable the avahi-daemon
service.
Starting GNOME
The gdm
package provides the gdm
service for the GNOME Display Manager;
test the service before enabling it.
GDM defaults to providing a Wayland session via the mutter
window manager, but
an X session can be chosen instead.
KDE
Installation
Install the kde-plasma
package, and optionally, the kde-baseapps
package.
To use the "Networks" widget, install NetworkManager
and enable the dbus
and
NetworkManager
services. To use the "Volume" widget, set up
PipeWire or PulseAudio.
Installing the kde-plasma
package also installs the sddm
package, which
provides the sddm
service for the Simple Desktop Display Manager. This service
depends on the dbus
service being enabled; test the
service before enabling it. If you are
not intending to run SDDM via a remote X server, you will need to install either
the xorg-minimal
package or the xorg
package. By default, SDDM will start an
X-based Plasma session, but you can request a Wayland-based Plasma session
instead.
If you wish to start an X-based session from the console, use
startx to run startplasma-x11
. For a Wayland-based
session, run startplasma-wayland
directly.
Dolphin
Dolphin is the default file manager of the KDE desktop environment. It can be
installed on its own by installing the dolphin
package, or it can be installed
as part of the kde-baseapps
meta-package.
Thumbnail Previews
To enable thumbnail file previews, install the kdegraphics-thumbnailers
package. If you want video thumbnails, the ffmpegthumbs
package is also
necessary. Enable previews in "Control" -> "Configure Dolphin" -> "General" ->
"Previews" by checking the corresponding boxes. File previews will be shown for
the selected file types after clicking "Preview" in Dolphin's toolbar.
Multimedia
Audio setup
To setup audio on your Void Linux system you have to decide if you want to use PulseAudio, PipeWire or just ALSA. Sndio is also available, but is neither supported nor recommended.
Some applications require PulseAudio, especially closed source programs, but PipeWire provides a drop-in replacement for PulseAudio.
If elogind is not enabled, it is necessary to be in
the audio
group in order to have access to audio devices.
ALSA
To use ALSA, install the alsa-utils
package and make sure your user is a
member of the audio
group.
The alsa-utils
package provides the alsa
service. When enabled, this service
saves and restores the state of ALSA (e.g. volume) at shutdown and boot,
respectively.
To allow use of software requiring PulseAudio, install the apulse
package.
apulse
provides part of the PulseAudio interface expected by applications,
translating calls to that interface into calls to ALSA. For details about using
apulse
, consult the project
README.
Configuration
The default sound card can be specified via ALSA configuration files or via kernel module options.
To obtain information about the order of loaded sound card modules:
$ cat /proc/asound/modules
0 snd_hda_intel
1 snd_hda_intel
2 snd_usb_audio
To set a different card as the default, edit /etc/asound.conf
or the per-user
configuration file ~/.asoundrc
:
defaults.ctl.card 2;
defaults.pcm.card 2;
or specify sound card module order in /etc/modprobe.d/alsa.conf
:
options snd_usb_audio index=0
Dmix
The dmix
ALSA plugin allows playing sound from multiple sources. dmix
is
enabled by default for soundcards which do not support hardware mixing. To
enable it for digital output, edit /etc/asound.conf
:
pcm.dsp {
type plug
slave.pcm "dmix"
}
PipeWire
PipeWire is a modern server for handling audio (and video) streams. It is highly flexible and can interface with applications designed for ALSA, PulseAudio, and JACK audio systems. It is also designed to work well with Flatpak applications and provides a method for screenshotting and screensharing on Wayland via xdg-desktop-portal.
Prerequisites
PipeWire requires an active D-Bus user session
bus. If your desktop environment, window
manager, or Wayland compositor is configured to provide this, no further
configuration should be required. If not, the desktop environment, window
manager, or Wayland compositor may need to be launched with
dbus-run-session(1)
.
PipeWire also requires the
XDG_RUNTIME_DIR
environment
variable to be defined in your environment to work properly.
If not using elogind, it is necessary to be in the
audio
group to access audio devices and the video
group to access video
devices.
Basic Setup
To use PipeWire, install the pipewire
package. This will also install a
PipeWire session manager, wireplumber
.
Session Management
In PipeWire, a session manager assumes responsibility for interconnecting media sources and sinks as well as enforcing routing policy. Without a session manager, PipeWire will not function.
If you have installed an earlier version of the Void
pipewire
package, make sure to update your system to eliminate any stale system configuration that may attempt to launchpipewire-media-session
, the original PipeWire session manager. Users who previously overrode the system configuration to usewireplumber
, e.g. by placing a custompipewire.conf
file in/etc/pipewire
or${XDG_CONFIG_HOME}/pipewire
, may wish to reconcile these overrides with/usr/share/pipewire/pipewire.conf
installed by the most recentpipewire
package. If the sole purpose of a prior override was to disablepipewire-media-session
, deleting the custom configuration may be sufficient.
Currently, there is only one session manager available: WirePlumber. To configure PipeWire to use this session manager and ensure proper startup ordering, PipeWire should be configured to launch the session manager directly. This can be accomplished by running
# mkdir -p /etc/pipewire/pipewire.conf.d
# ln -s /usr/share/examples/wireplumber/10-wireplumber.conf /etc/pipewire/pipewire.conf.d/
for system-wide configuration, or
$ : "${XDG_CONFIG_HOME:=${HOME}/.config}"
$ mkdir -p "${XDG_CONFIG_HOME}/pipewire/pipewire.conf.d"
$ ln -s /usr/share/examples/wireplumber/10-wireplumber.conf "${XDG_CONFIG_HOME}/pipewire/pipewire.conf.d/"
for per-user configuration.
PulseAudio interface
The PulseAudio interface is optional but highly recommended. Most applications cannot speak directly to PipeWire, but instead speak to PipeWire's PulseAudio interface.
If pulseaudio
is installed, uninstall it and ensure pulseaudio
is not
running.
Modify the PipeWire configuration to launch pipewire-pulse
:
# mkdir -p /etc/pipewire/pipewire.conf.d
# ln -s /usr/share/examples/pipewire/20-pipewire-pulse.conf /etc/pipewire/pipewire.conf.d/
for system configurations, or
$ : "${XDG_CONFIG_HOME:=${HOME}/.config}"
$ mkdir -p "${XDG_CONFIG_HOME}/pipewire/pipewire.conf.d"
$ ln -s /usr/share/examples/pipewire/20-pipewire-pulse.conf "${XDG_CONFIG_HOME}/pipewire/pipewire.conf.d/"
for per-user configurations.
Testing
pipewire(1) should be started as your
user. To test that PipeWire works, run the pipewire
command in a terminal
emulator in your session:
$ pipewire
Launching pipewire
should be sufficient to establish a working PipeWire
session that uses wireplumber
for session management.
The status of WirePlumber can be checked with:
$ wpctl status
PipeWire 'pipewire-0' [0.3.82, ...]
[...]
If the PulseAudio interface was configured, use
pactl(1) (provided by the
pulseaudio-utils
package) to ensure it is working properly:
$ pactl info
[...]
Server Name: PulseAudio (on PipeWire 0.3.82)
[...]
Launching Automatically
Once pipewire
works as expected, it can be configured to launch when starting
a graphical session. There are several ways this can be achieved:
- Use the autostarting mechanism of your desktop environment: many desktop environments have a way to configure applications and programs to start automatically.
- Use XDG Desktop Application Autostart: many desktop environments also
support the Desktop Application Autostart
Specification.
The
pipewire
package ships a Desktop Entry file forpipewire
in/usr/share/applications
. If your environment supports the Desktop Application Autostart, you can startpipewire
by symlinking the desktop file to the system (/etc/xdg/autostart
) or user (${XDG_CONFIG_HOME}/autostart
or~/.config/autostart
) autostart directory. If you are using a desktop environment, window manager, or Wayland compositor that does not support this, a tool likedex(1)
can be used to add support for Desktop Application Autostart, for example:dex --environment <window manager> --autostart --search-paths ~/.config/autostart
. - Use your window manager's startup scripts:
pipewire
can be launched directly from your window manager or Wayland compositor's startup script.
Optional Setup
Command-line and Terminal interfaces
A variety of tools for interacting with PipeWire are included in the pipewire
package, including pw-cli(1),
pw-top(1), and
pw-cat(1).
wpctl
can be used to control the WirePlumber session
manager.
If using the PulseAudio interface, PulseAudio
configuration tools like pactl
(from pulseaudio-utils
) and ncpamixer
can
also be used.
Graphical interfaces
qpwgraph
and helvum
provide a node-and-graph-style interface for connecting
applications and devices.
If using the PulseAudio interface, PulseAudio
configuration tools like pavucontrol
, pavucontrol-qt
, and the widgets and
applets integrated into many desktop environments can also be used to configure
PipeWire.
Bluetooth audio
Install the libspa-bluetooth
package.
ALSA integration
Install alsa-pipewire
, then enable the PipeWire ALSA device and make it the
default:
# mkdir -p /etc/alsa/conf.d
# ln -s /usr/share/alsa/alsa.conf.d/50-pipewire.conf /etc/alsa/conf.d
# ln -s /usr/share/alsa/alsa.conf.d/99-pipewire-default.conf /etc/alsa/conf.d
JACK interface
Install libjack-pipewire
.
Use pw-jack(1) to launch JACK clients manually:
$ pw-jack <application>
Alternatively, override the library provided by libjack
(see
ld.so(8)). The following approach will work
on glibc-based systems:
# echo "/usr/lib/pipewire-0.3/jack" > /etc/ld.so.conf.d/pipewire-jack.conf
# ldconfig
then reboot.
Troubleshooting
Common errors
[E][...] mod.rt | [ module-rt.c: 262 pw_rtkit_bus_get()] Failed to connect to system bus: Failed to connect to socket /run/dbus/system_bus_socket: No such file or directory
This indicates the system D-Bus is not running.
Enable the dbus
service.
[E][...] mod.rt | [ module-rt.c: 262 pw_rtkit_bus_get()] Failed to connect to session bus: D-Bus library appears to be incorrectly set up: see the manual page for dbus-uuidgen to correct this issue. (Failed to open "/var/lib/dbus/machine-id": No such file or directory; Failed to open "/etc/machine-id": No such file or directory)
This indicates the user session D-Bus is not running.
[E][...] mod.protocol-native | [module-protocol-: 710 init_socket_name()] server 0x55e09658e9d0: name pipewire-0 is not an absolute path and no runtime dir found. Set one of PIPEWIRE_RUNTIME_DIR, XDG_RUNTIME_DIR or USERPROFILE in the environment
This indicates XDG_RUNTIME_DIR
is
not set up properly.
Only a "dummy" output is found
If a session manager (like wireplumber
) is not running, configure
it and restart PipeWire.
If a session manager is running, check if your user is in the audio
and
video
groups. If not using elogind
, this is necessary for PipeWire to access
devices.
PulseAudio
Depending on which applications you use, you might need to provide PulseAudio
with a D-BUS session bus (e.g. via dbus-run-session
) or a D-BUS system bus
(via the dbus
service).
For applications which use ALSA directly and don't support PulseAudio, the
alsa-plugins-pulseaudio
package can make them use PulseAudio through ALSA.
PulseAudio will automatically start when needed. If it is not starting automatically, it can be started manually by invoking pulseaudio(1) from the terminal as follows:
$ pulseaudio --daemonize=no --exit-idle-time=-1
On the other hand, PulseAudio can also end up being auto activated when it isn't
desired. To inhibit this behavior, the autospawn
directive from
pulse-client.conf(5) can be set
to no
.
There are several methods of allowing PulseAudio to access to audio devices. The
simplest one is to add your user to the audio
group. Alternatively, you can
use a session manager, like elogind
.
Bluetooth
Ensure the Bluetooth controller is not blocked. Use rfkill
to check whether
there are any blocks and to remove soft blocks. If there is a hard block, there
is likely either a physical hardware switch or an option in the BIOS to enable
the Bluetooth controller.
$ rfkill
ID TYPE DEVICE SOFT HARD
0 wlan phy0 unblocked unblocked
1 bluetooth hci0 blocked unblocked
# rfkill unblock bluetooth
Installation
Install the bluez
package and enable the bluetoothd
and dbus
services.
Then, add your user to the bluetooth
group and restart the dbus
service, or
simply reboot the system. Note that restarting the dbus
service may kill
processes making use of it.
To use an audio device such as a wireless speaker or headset, ALSA users need to
install the bluez-alsa
package. PulseAudio users do
not need any additional software. PipeWire users need
libspa-bluetooth
.
Usage
Manage Bluetooth connections and controllers using bluetoothctl
, which
provides a command line interface and also accepts commands on standard input.
Consult the Arch Wiki for an example of how to pair a device.
Configuration
The main configuration file is /etc/bluetooth/main.conf
.
TeX Live
In Void, the texlive-bin
package provides a basic TeX installation, including
the tlmgr
program. Use tlmgr
to install TeX packages and package collections
from CTAN mirrors. Install the gnupg
package to allow tlmgr
to verify TeX
packages.
The texlive-bin
package contains the latest TeX Live version; however, earlier
versions, such as texlive2018-bin
, are also available.
The texlive
package and texlive-*
packages are also available, and provide
TeX packages directly via xbps. TeX packages installed via those packages cannot
interact with TeX packages installed directly from CTAN (via tlmgr
). For
example: pdflatex
from texlive-pdflatex
cannot be used to compile a TeX
document that uses a package installed via tlmgr
; tlmgr install pdflatex
would be required for that.
Configuring TeX Live
After installing TeX Live, update the value of PATH
:
$ source /etc/profile
Check that /opt/texlive/<year>/bin/x86_64-linux
(or
/opt/texlive/<year>/bin/i386-linux
) is in your PATH
:
$ echo $PATH
If required, change the global default paper size:
# tlmgr paper <letter|a4>
Installing/Updating TeX packages
To install all available packages:
# tlmgr install scheme-full
To install specific packages, you can install the collection(s) including them. To list the available collections:
$ tlmgr info collections
To see the list of files owned by a collection:
$ tlmgr info --list collection-<name>
To install the collection:
# tlmgr install collection-<name>
To install a standalone package, first check if the package exists:
$ tlmgr search --global <package>
and then install it:
# tlmgr install <package>
To find the package providing a particular file (for example, a font):
$ tlmgr search --file <filename> --global
To remove a package or a collection:
# tlmgr remove <package>
To update installed packages:
# tlmgr update --all
For a full description, check:
https://www.tug.org/texlive/doc/tlmgr.html
External Applications
Programming Languages
The Void repositories have a number of Python and Lua packages. If possible, install packages from the Void repositories or consider packaging the library or application you need. Packaging your application allows for easier system maintenance and can benefit other Void Linux users, so consider making a pull request for it. The contribution instructions can be found here.
To keep packages smaller, Void has separate devel
packages for header files
and development tools. If you install a library or application via a language's
package manager (e.g. pip
, gem
), or compile one from source, you may need to
install the programming language's -devel
package. This is specially relevant
for musl
libc users, due to pre-built binaries usually targeting glibc
instead.
Language | Package Manager | Void Package |
---|---|---|
Python3 | pip, anaconda, virtualenv, etc | python3-devel |
Python2 | pip, anaconda, virtualenv, etc | python2-devel |
Ruby | gem | ruby-devel |
lua | luarocks | lua-devel |
Java
Void provides LTS versions of the OpenJDK development kits and runtimes. Currently, versions 8, 11, 17, and 21 are available. To run Java-based applications, install the Java Runtime Environment of the desired version. To build Java-based programs, install the Java Development Kit of the desired version (and optionally other components listed below).
Void Package | Description |
---|---|
openjdkX | Java Development Kit |
openjdkX-jre | Java Runtime Environment |
openjdkX-doc | Developer documentation |
openjdkX-src | Java source code |
openjdkX-jmods | Java modules |
openjdkX-static-libs | Java static libraries |
To facilitate installing multiple Java versions in parallel, Void's OpenJDK
packages use
xbps-alternatives(1)
to
select the default JDK and JRE. Each openjdkX
package provides the jdk
alternative group, and each openjdkX-jre
package provides the java
alternative group.
These alternative groups manage the symlinks at /usr/lib/jvm/default-jdk
and
/usr/lib/jvm/default-jre
. These are used to set the JAVA_HOME
environment
variables and add Java utilities to your PATH
via a profile script
(/etc/profile.d/jdk.sh
).
When installing a Java package for the first time, you may need to re-login or
run source /etc/profile.d/jdk.sh
in your terminal session to update these
variables.
Restricted Packages
Some packages have legal restrictions on their distribution (e.g. Discord), may be too large, or have another condition that makes it difficult for Void to distribute. These packages have build templates, but the packages themselves are not built or distributed. As such, they must be built locally. For more information see the page on restricted packages.
Non-x86_64 Architectures
The Void build system runs on x86_64 servers, both for compiling and
cross-compiling packages. However, some packages (e.g. pandoc
) do not support
cross-compilation. These packages have to be built locally on a computer running
the same architecture and libc as the system on which the package is to be used.
To learn how to build packages, refer to the README for the void-packages
repository.
Flatpak
Flatpak is another method for installing external proprietary applications on Linux. For information on using Flatpak with Void Linux, see the official Flatpak documentation.
If sound is not working for programs installed using Flatpak, PulseAudio auto-activation might not be working correctly. Make sure PulseAudio is running before launching the program.
Note that Flatpak's sandboxing will not necessarily protect you from any security and/or privacy-violating features of proprietary software.
Troubleshooting
Some apps may not function properly (e.g. not being able to access the host
system's files). Some of these issues can be fixed by installing one or more of
the xdg-user-dirs
, xdg-user-dirs-gtk
or xdg-utils
packages, and setting up
XDG Desktop Portals.
Some Flatpaks require D-Bus and/or Pulseaudio.
AppImages
An AppImage is a file that bundles an application with everything needed to run it. An AppImage can be used by making it executable and running it; installation is not required. AppImages can be run in a sandbox, such as firejail.
Some of the applications for which an AppImage is available can be found on AppImageHub.
AppImages do not yet work on musl installations.
Octave Packages
Some Octave packages require external dependencies to compile and run. For
example, to build the control package, you must install the openblas-devel
,
libgomp-devel
, libgfortran-devel
, gcc-fortran
, and gcc
packages.
MATLAB
To use MATLAB's help browser, live scripts, add-on installer, and simulink,
install the libselinux
package.
Steam
Steam can be installed either via a native package, which requires enabling the "nonfree" repository, or via Flatpak. The list of dependencies for different platforms and troubleshooting information for the native package can be found in its Void-specific documentation, while this section deals with potential issues faced by Flatpak users.
If you are using a different drive to store your game library, the
--filesystem
option from
flatpak-override(1) can prove
useful.
Printing
CUPS (Common Unix Printing System) is the supported mechanism for connecting to printers on Void Linux.
As prerequisites, install the cups
package and enable the cupsd
service.
Wait until the service is marked available.
Installing Printing Drivers
If the printer is being accessed over the network and supports PostScript or
PCL, CUPS alone should be sufficient. However, additional driver packages are
necessary for local printer support. The cups-filters
package provides driver
support for CUPS.
Depending on the hardware in question, additional drivers may be necessary.
Some CUPS drivers contain proprietary or binary-only extensions. These are available only in the nonfree repository, and sometimes only for specific architectures.
Driverless printing
Most modern network printers support printing driverlessly using the IPP Everywhere standard. See https://www.pwg.org/printers/ for a list of self-certified printers supporting this standard. Even if a printer is not on this list, there is still a high chance it is supported.
Do note that cups-filters
is still required for driverless printing.
Gutenprint drivers
Gutenprint provides support for many printers. These drivers are contained in
the gutenprint
package.
HP drivers
Printers from Hewlett-Packard require the hplip
package.
Running the following command will guide you through the driver installation process. The default configuration selections it suggests are typically sufficient.
# hp-setup -i
Brother drivers
For Brother printer support, install the foomatic drivers, which are contained
in the foomatic-db
and foomatic-db-nonfree
packages. Support for various
laser models is provided by the brother-brlaser
package.
Drivers for Epson Inkjet printers
Install the epson-inkjet-printer-escpr
package for Epson Inkjet printers.
Canon PIXMA/MAXIFY drivers
The cnijfilter2
package contains drivers for various Canon PIXMA and MAXIFY
models. Please note that installing the driver package requires enabling the
"nonfree" repository.
Configuring a New Printer
CUPS provides a web interface and command line tools that can be used to configure printers. Additionally, various native GUI options are available and may be better suited, depending on the use-case.
Automatically
Printers with support for IPP Everywhere can be discovered and configured
automatically using ZeroConf. To enable this,
install the avahi
and nss-mdns
package and enable the avahi-daemon
service.
Web interface
To configure the printer using the CUPS web interface, navigate to
http://localhost:631 in a browser. Under the "Administration" tab, select
"Printers > Add Printer". When asked to log in, use an account that is in the
lpadmin
group.
Command line
The lpadmin(8) tool may be used to configure a printer using the command line.
Graphical interface
The system-config-printer
package offers simple and robust configuration of
new printers. Install and invoke it:
# system-config-printer
Normally this tool requires root privileges. However, if you are using
PolicyKit, you can install the cups-pk-helper
package to allow unprivileged
users to use system-config-printer
.
While system-config-printer
is shown here, your desktop environment may have a
native printer dialog, which may be found by consulting the documentation for
your DE.
Troubleshooting
USB printer not shown
The device URI can be found manually by running:
# /usr/lib/cups/backend/usb
Containers and Virtual Machines
This section describes how to set up some of the container and virtual machine software available on Void.
Section Contents
Creating and using chroots and containers
chroots and containers can be set up and used for many purposes, including:
- running glibc software on musl (and vice versa)
- running software in a more controlled or sandboxed environment
- creating a rootfs for bootstrapping a system
Chroot Creation
xvoidstrap
xvoidstrap(1)
(from xtools
) can be
used to create the chroot:
# mkdir <chroot_dir>
# XBPS_ARCH=<chroot_arch> xvoidstrap <chroot_dir> base-container <other_pkgs>
<other_pkgs>
is only needed if you want to pre-install other packages in the
chroot.
Manual Creation
Alternatively, this process can be done manually.
Create a directory that will contain the chroot, then install a base system in
it via the base-container
package:
# mkdir -p "<chroot_dir>/var/db/xbps/keys"
# cp -a /var/db/xbps/keys/* "<chroot_dir>/var/db/xbps/keys"
# XBPS_ARCH=<chroot_arch> xbps-install -S -r <chroot_dir> -R <repository> base-container <other_pkgs>
The <repository>
may vary depending on
architecture.
<other_pkgs>
is only needed if you want to pre-install other packages in the
chroot.
Chroot Usage
xchroot
xchroot(1)
(from xtools
) can be used
to automatically set up and enter the chroot.
Manual Method
Alternatively, this process can be done manually.
If network access is required, copy /etc/resolv.conf
into the chroot;
/etc/hosts
may need to be copied as well.
Several directories then need to be mounted as follows:
# mount -t proc none <chroot_dir>/proc
# mount -t sysfs none <chroot_dir>/sys
# mount --rbind /dev <chroot_dir>/dev
# mount --rbind /run <chroot_dir>/run
Use chroot(1) to change to the new root, then run programs and do tasks as usual. Once finished with the chroot, unmount the chroot using umount(8). If any destructive actions are taken on the chroot directory without unmounting first, you may need to reboot to repopulate the affected directories.
Alternatives
Bubblewrap
bwrap(1) (from the bubblewrap
package)
has additional features like the ability for sandboxing and does not require
root access.
bwrap
is very flexible and can be used in many ways, for example:
$ bwrap --bind <chroot_dir> / \
--dev /dev \
--proc /proc \
--bind /sys /sys \
--bind /run /run \
--ro-bind /etc/resolv.conf /etc/resolv.conf \
--ro-bind /etc/passwd /etc/passwd \
--ro-bind /etc/group /etc/group \
<command>
In this example, you will not be able to add or edit users or groups. When
running graphical applications with Xorg, you may need to also bind-mount
~/.Xauthority
or other files or directories.
The bwrap(1) manpage and the Arch Wiki
article contain
more examples of bwrap
usage.
Flatpak
Flatpak is a convenient option for running many applications, including graphical or proprietary ones, on both glibc and musl systems.
Application Containers
If a more integrated and polished solution is desired, Void also provides OCI containers that work with tools like docker and podman. These containers do not require the creation of a chroot directory before usage.
libvirt
libvirt is an API and daemon for managing platform virtualization, supporting virtualization technologies such as LXC, KVM, QEMU, Bhyve, Xen, VMWare, and Hyper-V.
To use libvirt, install the libvirt
package, ensure the dbus
package is
installed, and enable the dbus
,
libvirtd
, virtlockd
and virtlogd
services. The libvirtd
daemon can be
reconfigured at runtime via
virt-admin(1).
The libvirt
package provides the virsh(1)
interface to libvirtd. virsh
is an interactive shell and batch-scriptable tool
for performing management tasks, including creating, configuring and running
virtual machines, and managing networks and storage. Note that virsh
usually
needs to be run as root, as described in the virsh
man page:
Most virsh commands require root privileges to run due to the communications channels used to talk to the hypervisor. Running as non root will return an error.
However, if you have the polkit
and dbus
packages installed and you enable
the dbus
service, libvirtd
will grant necessary privileges to any user added
to the libvirt
group.
An alternative to virsh
is provided by the virt-manager
and
virt-manager-tools
packages. The default QEMU/KVM system connection requires
the qemu
package.
For general information on libvirt, refer to the libvirt wiki and the wiki's FAQ. For an introduction to libvirt usage, refer to the "VM lifecycle" page.
LXC
The Linux Containers project includes three subprojects: LXC, LXD and LXCFS. The project also included the CGManager project, which has been deprecated in favor of the CGroup namespace in recent kernels.
Configuring LXC
Install the lxc
package.
Creating and running privileged containers as root
does not require any
configuration; simply use the various lxc-*
commands, such as
lxc-create(1),
lxc-start(1),
lxc-attach(1), etc.
Creating unprivileged containers
User IDs (UIDs) and group IDs (GIDs) normally range from 0 to 65535. Unprivileged containers enhance security by mapping UID and GID ranges inside each container to ranges not in use by the host system. The unused host ranges must be subordinated to the user who will be running the unprivileged containers.
Subordinate UIDs and GIDs are assigned in the subuid(5) and subgid(5) files, respectively.
To create unprivileged containers, first edit /etc/subuid
and /etc/subgid
to
delegate ranges. For example:
root:1000000:65536
user:2000000:65536
In each colon-delimited entry:
- the first field is the user to which a subordinate range will be assigned;
- the second field is the smallest numeric ID defining a subordinate range; and
- the third field is the number of consecutive IDs in the range.
The usermod(8) program may also be used to manipulate suborinated IDs.
Generally, the number of consecutive IDs should be an integer multiple of 65536;
the starting value is not important, except to ensure that the various ranges
defined in the file do not overlap. In this example, root
controls UIDs (or,
from subgid
, GIDs) ranging from 1000000 to 1065535, inclusive; user
controls
IDs ranging from 2000000 to 2065535.
Before creating a container, the user owning the container will need an
lxc.conf(5) file specifying the subuid
and subgid range to use. For root-owned containers, this file resides at
/etc/lxc/default.conf
; for unprivileged users, the file resides at
~/.config/lxc/default.conf
. Mappings are described in lines of the form
lxc.idmap = u 0 1000000 65536
lxc.idmap = g 0 1000000 65536
The isolated u
character indicates a UID mapping, while the isolated g
indicates a GID mapping. The first numeric value should generally always be 0;
this indicates the start of the UID or GID range as seen from within the
container. The second numeric value is the start of the corresponding range as
seen from outside the container, and may be an arbitrary value within the range
delegated in /etc/subuid
or /etc/subgid
. The final value is the number of
consecutive IDs to map.
Note that, although the external range start is arbitrary, care must be taken to ensure that the end of the range implied by the start and number does not extend beyond the range of IDs delegated to the user.
If configuring a non-root user, edit /etc/lxc/lxc-usernet
as root to specify a
network device quota. For example, to allow the user named user
to create up
to 10 veth
devices connected to the lxcbr0
bridge:
user veth lxcbr0 10
The user can now create and use unprivileged containers with the lxc-*
utilities. To create a simple Void container named mycontainer
, use a command
similar to:
lxc-create -n mycontainer -t download -- \
--dist voidlinux --release current --arch amd64
You may substitute another architecture for amd64
, and you may specify a
musl
image by adding --variant musl
to the end of the command. See the LXC
Image Server for a list of available
containers.
By default, configurations and mountpoints for system containers are stored in
/var/lib/lxc
, while configurations for user containers and mountpoints are
stored in ~/.local/share/lxc
. Both of these values can be modified by setting
lxc.lxcpath
in the
lxc.system.conf(5) file. The
superuser may launch unprivileged containers in the system lxc.lxcpath
defined
in /etc/lxc/lxc.conf
; regular users may launch unprivileged containers in the
personal lxc.lxcpath
defined in ~/.config/lxc/lxc.conf
.
All containers will share the same subordinate UID and GID maps by default. This
is permissible, but it means that an attacker who gains elevated access within
one container, and can somehow break out of that container, will have similar
access to other containers. To isolate containers from each other, alter the
lxc.idmap
ranges in default.conf
to point to a unique range before you
create each container. Trying to fix permissions on a container created with the
wrong map is possible, but inconvenient.
LXD
LXD provides an alternative interface to LXC's lxc-*
utilities. However, it
does not require the configuration described in the previous section.
Install the lxd
package, and enable
the lxd
service.
LXD users must belong to the lxd
group.
Use the lxc
command to manage instances, as described
here.
GnuPG
Void ships both GnuPG legacy (as gnupg1
) and GnuPG stable (as gnupg
).
Smartcards
For using smartcards such as Yubikeys with GnuPG, there are two backends for communicating with them through GnuPG: The internal CCID driver of GnuPG's scdaemon, or the PC/SC driver.
scdaemon with internal CCID driver
By default, scdaemon, which is required for using smartcards with GnuPG, uses
its internal CCID driver. For this to work, your smartcard needs to be one of
the smartcards in the udev rules
here
and you need to either be using elogind or be a member of the plugdev group. If
these two condition are fulfilled and you don't have pcscd running, gpg --card-status
should successfully print your current card status.
scdaemon with pcscd backend
If you need to use pcscd for other reasons, run echo disable-ccid >> ~/.gnupg/scdaemon.conf
. Now, assuming your pcscd setup works correctly, gpg --card-status
should print your card status.
OpenPGP Card Tools
As an alternative to GnuPG with smartcards, Void also ships
openpgp-card-tools
, a Rust based utility not reliant on GnuPG. It requires
using pcscd
for interacting with smart cards, so if you want to use it in
parallel with GnuPG, ou need to configure scdaemon
to use the pcscd backend,
as described above in "scdaemon with pcscd
backend".
PHP
There are two ways to install PHP packages with XBPS:
- Using the versioned packages (recommended).
- Using the meta-packages.
Versioned PHP Packages
It is generally recommended to use versioned PHP packages (e.g. php8.1
,
php8.1-apcu
, etc.) for most use cases as this ensures a consistent environment
on updates with minimal or no intervention required.
PHP Meta-packages
In Void, the php
package is a meta-package that points to the latest upstream
PHP version. This convention is followed by all packages prefixed with php-
,
such as php-fpm
, as well as xdebug
and composer
. See the php
template
for a complete list. It is recommended to only use these meta-packages for
development purposes.
When using a PHP meta-package, be warned that updating may require manual
intervention if a new major PHP version has been added to the repository. As a
part of the version change, the configuration location will change to reflect
the new version. For example, upgrading from 8.0 to 8.1 would result in the
configuration path changing from /etc/php8.0
to /etc/php8.1
. Any
customizations that have been made need to be manually applied to the new
configuration directory.
php-fpm
updates require special care since they include a runit service. In
this case, ensure that the new runit service is started and that applications
using the previous version of php-fpm
can access the new php-fpm
instance.
In particular, make sure any applications accessing the FPM instance have the
correct TCP/unix socket address.
XBPS Package Manager
The X Binary Package System (XBPS) is a fast package manager that has been designed and implemented from scratch. XBPS is managed by the Void Linux team and developed at https://github.com/void-linux/xbps.
Most general package management is done with the following commands:
- xbps-query(1) searches for and
displays information about packages installed locally, or, if used with the
-R
flag, packages contained in repositories. - xbps-install(1) installs and updates packages, and syncs repository indexes.
- xbps-remove(1) removes installed packages, and can also remove orphaned packages and cached package files.
- xbps-reconfigure(1) runs the
configuration steps for installed packages, and can be used to reconfigure
certain packages after changes in their configuration files. The latter
usually requires the
--force
flag. - xbps-alternatives(1) lists or sets the alternatives provided by installed packages. Alternatives is a system which allows multiple packages to provide common functionality through otherwise conflicting files, by creating symlinks from the common paths to package-specific versions that are selected by the user.
- xbps-pkgdb(1) can report and fix issues in the package database, as well as modify it.
- xbps-rindex(1) manages local binary package repositories.
Most questions can be answered by consulting the man pages for these tools, together with the xbps.d(5) man page.
To learn how to build packages from source, refer to the README for the void-packages repository.
Updating
Like any other system, it is important to keep Void up-to-date. Use xbps-install(1) to update:
# xbps-install -Su
XBPS must use a separate transaction to update itself. If your update includes
the xbps
package, you will need to run the above command a second time to
apply the rest of the updates.
Restarting Services
XBPS does not restart services when they are updated. This task is left to the administrator, so they can orchestrate maintenance windows, ensure reasonable backup capacity, and generally be present for service upgrades.
To find processes running different versions than are present on disk, use the
xcheckrestart
tool provided by the xtools
package:
$ xcheckrestart
11339 /opt/google/chrome/chrome (deleted) (google-chrome)
xcheckrestart
will print out the PID, path to the executable, status of the
path that was launched (almost always deleted
) and the process name.
xcheckrestart
can and should be run as an unprivileged user.
Kernel Panic After Update
If you get a kernel panic after an update, it is likely your system ran out of
space in /boot
. Refer to "Removing old
kernels" for further information.
Finding Files and Packages
To search available repositories for packages, use xbps-query(1):
$ xbps-query -Rs <search_pattern>
The -R
flag specifies that repositories should be searched. Without it, -s
searches for locally-installed packages.
If you can't find a file or program you expected to find after installing a package, you can use xbps-query(1) to list the files provided by that package:
$ xbps-query -f <package_name>
The xtools
package contains the
xlocate(1) utility. xlocate
works like
locate(1), but for files in the Void
package repositories:
$ xlocate -S
Fetching objects: 11688, done.
From https://repo-default.voidlinux.org/xlocate/xlocate
+ e122c3634...a2659176f master -> master (forced update)
$ xlocate xlocate
xtools-0.59_1 /usr/bin/xlocate
xtools-0.59_1 /usr/share/man/man1/xlocate.1 -> /usr/share/man/man1/xtools.1
It is also possible to use xbps-query(1) to find files, though this is strongly discouraged:
$ xbps-query -Ro /usr/bin/xlocate
xtools-0.46_1: /usr/bin/xlocate (regular file)
This requires xbps-query
to download parts of every package to find the file.
xlocate
, however, queries a locally cached index of all files, so no network
access is required.
To get a list of all installed packages, without their version:
$ xbps-query -l | awk '{ print $2 }' | xargs -n1 xbps-uhelper getpkgname
Advanced Usage
Downgrading
XBPS allows you to downgrade a package to a specific package version.
Via xdowngrade
The easiest way to downgrade is to use xdowngrade
from the xtools
package,
specifying the package version to which you wish to downgrade:
# xdowngrade /var/cache/xbps/pkg-1.0_1.xbps
Via XBPS
XBPS can be used to downgrade to a package version that is no longer available in the repository index.
If the package version had been installed previously, it will be available in
/var/cache/xbps/
. If not, it will need to be obtained from elsewhere; for the
purposes of this example, it will be assumed that the package version has been
added to /var/cache/xbps/
.
First add the package version to your local repository:
# xbps-rindex -a /var/cache/xbps/pkg-1.0_1.xbps
Then downgrade with xbps-install
:
# xbps-install -R /var/cache/xbps/ -f pkg-1.0_1
The -f
flag is necessary to force downgrade/re-installation of an already
installed package.
Holding packages
To prevent a package from being updated during a system update, use xbps-pkgdb(1):
# xbps-pkgdb -m hold <package>
The hold can be removed with:
# xbps-pkgdb -m unhold <package>
Repository-locking packages
If you've used xbps-src
to build and install a package from a customized
template, or with custom build options, you may wish to prevent system updates
from replacing that package with a non-customized version. To ensure that a
package is only updated from the same repository used to install it, you can
repolock it via xbps-pkgdb(1):
# xbps-pkgdb -m repolock <package>
To remove the repolock:
# xbps-pkgdb -m repounlock <package>
Ignoring Packages
Sometimes you may wish to remove a package whose functionality is being provided
by another package, but will be unable to do so due to dependency issues. For
example, you may wish to use doas(1) instead
of sudo(8), but will be unable to remove the
sudo
package due to it being a dependency of the base-system
package. To
remove it, you will need to ignore the sudo
package.
To ignore a package, add an appropriate ignorepkg
entry in an
xbps.d(5) configuration file. For example:
ignorepkg=sudo
You will then be able to remove the sudo
package using
xbps-remove(1).
Virtual Packages
Virtual packages can be created with
xbps.d(5) virtualpkg
entries. Any
request to the virtual package will be resolved to the real package. For
example, to create a linux
virtual package which will resolve to the
linux5.6
package, create an xbps.d
configuration file with the contents:
virtualpkg=linux:linux5.6
Repositories
Repositories are the heart of the XBPS package system. Repositories can be local
or remote. A repository contains binary package files, which may have
signatures, and a data file named $ARCH-repodata
(e.g. x86_64-repodata
),
which may also be signed.
Note that, while local repositories do not require signatures, remote repositories must be signed.
The main repository
The locations of the main repository in relation to a base mirror URL are:
- glibc:
/current
- musl:
/current/musl
- aarch64 and aarch64-musl:
/current/aarch64
Subrepositories
In addition to the main repository, which is enabled upon installation, Void provides other official repositories maintained by the Void project, but not enabled by default:
- nonfree: contains software packages with non-free licenses
- multilib: contains 32-bit libraries for 64-bit systems (glibc only)
- multilib/nonfree: contains non-free multilib packages
- debug: contains debugging symbols for packages
These repositories can be enabled via the installation of the relevant package.
These packages only install a repository configuration file in
/usr/share/xbps.d
.
nonfree
Void has a nonfree
repository for packages that don't have free licenses. It
can be enabled by installing the void-repo-nonfree
package.
Packages can end up in the nonfree
repository for a number of reasons:
- Non-free licensed software with released source-code.
- Software released only as redistributable binary packages.
- Patented technology, which may or may not have an (otherwise) open implementation.
multilib
The multilib
repository provides 32-bit packages as a compatibility layer
inside a 64-bit system. It can be enabled by installing the void-repo-multilib
package.
These repositories are only available for x86_64
systems running the glibc
C
library.
multilib/nonfree
The multilib/nonfree
repository provides additional 32-bit packages which have
non-free licenses. It can be enabled by installing the
void-repo-multilib-nonfree
package.
debug
Void Linux packages come without debugging symbols. If you want to debug
software or look at a core dump you will need the debugging symbols. These
packages are contained in the debug repository. It can be enabled by installing
the void-repo-debug
package.
Once enabled, symbols may be obtained for <package>
by installing
<package>-dbg
.
Finding debug dependencies
The xtools
package contains the xdbg(1)
utility to retrieve a list of debug packages, including dependencies, for a
package:
$ xdbg bash
bash-dbg
glibc-dbg
# xbps-install -S $(xdbg bash)
Mirrors
Void Linux maintains mirrors in several geographic regions for users. A fresh install will default to repo-default.voidlinux.org, which may map to any Tier 1 mirror, but you may have a better experience by selecting a different mirror.
See xmirror.voidlinux.org for more information and a list of available mirrors.
Tor Mirrors
Void Linux is also mirrored on the Tor network. See Using Tor Mirrors for more information.
Changing Mirrors
Each repository has a file defining the URL for the mirror used. For official
repositories, these files are installed by the package manager in
/usr/share/xbps.d
, but if duplicate files are found in /etc/xbps.d
, those
values are used instead.
xmirror
To easily modify the currently selected mirror,
xmirror(1) (from the xmirror
package)
can be used. This utility takes care of all steps for updating the selected
mirror.
Manual Method
Alternatively, this can be done manually:
To modify mirror URLs cleanly, copy all the repository configuration files to
/etc/xbps.d
and change the URLs in each copied repository file.
# mkdir -p /etc/xbps.d
# cp /usr/share/xbps.d/*-repository-*.conf /etc/xbps.d/
# sed -i 's|https://repo-default.voidlinux.org|<repository>|g' /etc/xbps.d/*-repository-*.conf
After changing the URLs, you must synchronize xbps with the new mirrors:
# xbps-install -S
You should see the new repository URLs while synchronizing. You can also use
xbps-query
to verify the repository URLs, but only after they have been
synchronized:
$ xbps-query -L
9970 https://repo-default.voidlinux.org/current (RSA signed)
27 https://repo-default.voidlinux.org/current/multilib/nonfree (RSA signed)
4230 https://repo-default.voidlinux.org/current/multilib (RSA signed)
47 https://repo-default.voidlinux.org/current/nonfree (RSA signed)
5368 https://repo-default.voidlinux.org/current/debug (RSA signed)
Remember that repositories added afterwards will also need to be changed, or they will use the default mirror.
Using Tor Mirrors
Tor is an anonymizing software that bounces traffic via computers all around the world. It can provide access to regular sites on the internet or to hidden sites only available on the network.
The following Void Linux Mirrors are available on the Tor Network:
Repository | Location |
---|---|
http://lysator7eknrfl47rlyxvgeamrv7ucefgrrlhk7rouv3sna25asetwid.onion/pub/voidlinux/ | EU: Sweden |
Using XBPS with Tor
XBPS can be made to connect to mirrors using Tor. These mirrors can be normal mirrors, via exit relays, or, for potentially greater anonymity, hidden service mirrors on the network.
XBPS respects the SOCKS_PROXY
environment variable, which makes it easy to use
via Tor.
Installing Tor
Tor is contained in the tor
package.
After having installed Tor, you can start it as your own user:
$ tor
or enable its system service.
By default, Tor will act as a client and open a SOCKS5 proxy on TCP port 9050 on localhost.
Making XBPS connect via the SOCKS proxy
XBPS reads the SOCKS_PROXY
environment variable and will use any proxy
specified in it. By simply setting the variable to the address and port of the
proxy opened by the Tor client, all XBPS's connections will go over the Tor
network.
An example upgrading your system over Tor:
# export SOCKS_PROXY="socks5://127.0.0.1:9050"
# xbps-install -Su
Using a hidden service mirror
To use a hidden service mirror, the default mirrors need to be overwritten with
configuration files pointing to .onion
-addresses that are used internally on
the Tor network. XBPS allows overriding repository addresses under
/etc/xbps.d
.
Copy your repository files from /usr/share/xbps.d
to /etc/xbps.d
and replace
the addresses with that of an onion service (Lysator's onion used as an
example):
# mkdir -p /etc/xbps.d
# cp /usr/share/xbps.d/*-repository-*.conf /etc/xbps.d/
# sed -i 's|https://repo-default.voidlinux.org|http://lysator7eknrfl47rlyxvgeamrv7ucefgrrlhk7rouv3sna25asetwid.onion/pub/voidlinux|g' /etc/xbps.d/*-repository-*.conf
Tor provides layered end-to-end encryption so HTTPS is not necessary.
When installing packages, with SOCKS_PROXY
set like the earlier example, XBPS
should indicate that it is synchronizing the repositories from the onion address
specified in the override:
# xbps-install -S
[*] Updating `http://lysator7eknrfl47rlyxvgeamrv7ucefgrrlhk7rouv3sna25asetwid.onion/pub/voidlinux/current/aarch64/nonfree/aarch64-repodata' ...
aarch64-repodata: 4030B [avg rate: 54KB/s]
[*] Updating `http://lysator7eknrfl47rlyxvgeamrv7ucefgrrlhk7rouv3sna25asetwid.onion/pub/voidlinux/current/aarch64/aarch64-repodata' ...
aarch64-repodata: 1441KB [avg rate: 773KB/s]
Security consideration
It is advisable to set SOCKS_PROXY
automatically in your environment if you
are using an onion. If the setting is missing, a DNS query for the name of the
hidden service will leak to the configured DNS server.
To automatically set the environment variable, add it to a file in
/etc/profile.d
:
# cat - <<EOF > /etc/profile.d/socksproxy.sh
#!/bin/sh
export SOCKS_PROXY="socks5://127.0.0.1:9050"
EOF
Restricted Packages
Void offers some packages that are officially maintained, but not distributed. These packages are marked as restricted and must be built from their void-packages template locally.
Packages can be restricted from distribution by either the upstream author or Void. Void reserves the right to restrict distribution of any package for effectively any reason, massive size being the most common. Another common reason is restrictive licensing that does not allow third-party redistribution of source or binary packages.
Building manually
You can use xbps-src
in the
void-packages repository to build
the restricted packages from templates. For instructions on building packages
from templates, refer to the
void-packages documentation, and
the "Quick start"
section in particular
.
Remember that the building of restricted packages must be enabled explicitly by
setting XBPS_ALLOW_RESTRICTED=yes
in your xbps-src
configuration (in the
etc/conf
file in the repository.)
Automated building
There is also a tool, xbps-mini-builder which automates the process of building a list of packages. The script can be called periodically and will only rebuild packages if their templates have changed.
Custom Repositories
Void supports user-created repositories, both local and remote. This is only recommended for serving custom packages created personally, or packages from another trusted source. The Void project does not support any third-party package repositories - the use of third-party software packages poses very serious security concerns, and risks serious damage your system.
Adding custom repositories
To add a custom repository, create a file in /etc/xbps.d
, with the contents:
repository=<URL>
where <URL>
is either a local directory or a URL to a remote repository.
For example, to define a remote repository:
# echo 'repository=http://my.domain.com/repo' > /etc/xbps.d/my-remote-repo.conf
Remote repositories need to be signed. xbps-install(1) refuses to install packages from remote repositories if they are not signed.
To define a local repository:
# echo 'repository=/path/to/repo' > /etc/xbps.d/my-local-repo.conf
Signing Repositories
Remote repositories must be signed. Local repositories do not need to be signed.
The xbps-rindex(1) tool is used to sign repositories.
The private key for signing packages needs to be a PEM-encoded RSA key. The key can be generated with either ssh-keygen(1) or openssl(1):
$ ssh-keygen -t rsa -m PEM -f private.pem
$ openssl genrsa -out private.pem
Once the key is generated, the public part of the private key has to be added to the repository metadata. This step is required only once.
$ xbps-rindex --privkey private.pem --sign --signedby "I'm Groot" /path/to/repository/dir
Then sign one or more packages with the following command:
$ xbps-rindex --privkey private.pem --sign-pkg /path/to/repository/dir/*.xbps
Note that future packages will not be automatically signed.
Troubleshooting XBPS
Sometimes the package manager gets in a weird spot and can't fix itself without help. This section documents important fixes and things that can go wrong when working with XBPS.
Section Contents
Common Issues
Verifying RSA keys
If the Void RSA key has changed, xbps-install(1) will report the new key fingerprint and ask you to confirm it:
<repository> repository has been RSA signed by "Void Linux"
Fingerprint: <rsa_fingerprint>
Do you want to import this public key? [Y/n]
To verify the key, ensure the <rsa_fingerprint>
matches one of the
fingerprints in both
void-packages
and void-mklive.
Errors while updating or installing packages
If there are any errors while updating or installing a new package, make sure
that you are using the latest version of the remote repository index. Running
xbps-install(1) with the -S
option
will guarantee that.
"Operation not permitted"
An "Operation not permitted" error, such as:
ERROR: [reposync] failed to fetch file https://repo-default.voidlinux.org/current/nonfree/x86_64-repodata': Operation not permitted
can be caused by your system's date and/or time being incorrect. Ensure your date and time are correct.
"Not Found"
A "Not Found" error, such as:
ERROR: [reposync] failed to fetch file `https://repo-default.voidlinux.org/current/musl/x86_64-repodata': Not Found
usually means your XBPS configuration is pointing to the wrong repositories for your system. Confirm that your xbps.d(5) files refer to the correct repositories.
shlib errors
An "unresolvable shlib" error, such as:
libllvm8-8.0.1_2: broken, unresolvable shlib `libffi.so.6'
is probably due to outdated or orphan packages. To check for outdated packages,
simply try to update your system. Orphan packages, on
the other hand, have been removed from the Void repos, but are still installed
on your system; they can be removed by running
xbps-remove(1) with the -o
option.
If you get an error message saying:
Transaction aborted due to unresolved shlibs
the repositories are in the staging state, which can happen due to large builds. The solution is to wait for the builds to finish. You can view the builds' progress in the Buildbot's web interface.
repodata errors
In March 2020, the compression format used for the repository data (repodata)
was changed from gzip to zstd. If XBPS wasn't updated to version 0.54
(released June 2019) or newer, it is not possible to update the system with it.
Unfortunately, there isn't an error message for this case, but it can be
detected by running xbps-install
with the -Sd
flags. The debug message for
this error is shown below.
[DEBUG] [repo] `//var/db/xbps/https___repo-default_voidlinux_org_current/x86_64-repodata' failed to open repodata archive Invalid or incomplete multibyte or wide character
In this situation, it is necessary to follow the steps in xbps-static.
Broken systems
If your system is for some reason broken and can't perform updates or package installations, using a statically linked version of xbps to update and install packages can help you avoid reinstalling the whole system.
Static XBPS
In rare cases, it is possible to break the system sufficiently that XBPS can no longer function. This usually happens while trying to do unsupported things with libc, but can also happen when an update contains a corrupt glibc archive or otherwise fails to unpack and configure fully.
Another issue that can present itself is in systems with a XBPS version before
0.54
(released June 2019). These systems will be impossible to update from the
official repositories using the regular update procedure, due a change in the
compression format used for repository data, which was made in March 2020.
In these cases it is possible to recover your system with a separate, statically compiled copy of XBPS.
Obtaining static XBPS
Statically compiled versions of XBPS are available on all mirrors in the
static/
directory. The link below points to the static copies on the primary
mirror in the EU:
https://repo-default.voidlinux.org/static
Download and unpack the latest version, or the version that matches the broken copy on your system (with a preference for the latest copy).
Using static XBPS
The tools in the static set are identical to the normal ones found on most
systems. The only difference is that these tools are statically linked to the
musl C library, and should work on systems where nothing else does. On systems
that can no longer boot, it is recommended to chroot in using a Void
installation medium and use the static tools from there, as it is unlikely that
even a shell will work correctly on those systems. When using static XBPS with a
glibc installation, the environment variable XBPS_ARCH
needs to be set.
Contributing
There's more to running a distribution than just writing code.
To contribute to the Void packages repository, start by reading the CONTRIBUTING document in the void-packages GitHub repository.
To contribute to this Handbook, read CONTRIBUTING in the void-docs repository.
If you have any questions, feel free to ask them via IRC in #voidlinux on irc.libera.chat, or in the voidlinux subreddit.
Usage Statistics
If you would like to contribute usage reports, the PopCorn program reports installation statistics back to the Void project. These statistics are purely opt-in - PopCorn is not installed or enabled by default on any Void systems.
PopCorn only reports which packages are installed, their version, and the host
CPU architecture (the output of xuname
). This does not report which services
are enabled, or any other personal information. Individual systems are tracked
persistently by a random (client-generated) UUID, to ensure that each system is
only counted once in each 24-hour sampling period.
The data collected by PopCorn is available to view at http://popcorn.voidlinux.org
Setting up PopCorn
First, install the PopCorn
package. Then, enable the popcorn
service, which
will attempt to report statistics once per day.
Contributing To void-docs
The sources for this handbook are hosted in the void-docs repository on GitHub. If you would like to make a contribution, please read about the purpose of the Handbook, follow our style guide and submit a pull request.