What kernel is arch linux

Kernel

According to Wikipedia:

The Linux kernel is an open-source monolithic Unix-like computer operating system kernel.

Arch Linux is based on the Linux kernel. There are various alternative Linux kernels available for Arch Linux in addition to the latest stable kernel. This article lists some of the options available in the repositories with a brief description of each. There is also a description of patches that can be applied to the system’s kernel. The article ends with an overview of custom kernel compilation with links to various methods.

Kernel packages are installed onto the file system under /boot/ . To be able to boot into kernels, the boot loader has to be configured appropriately.

Contents

Officially supported kernels

Community support on forum and bug reporting is available for officially supported kernels.

• Stable — Vanilla Linux kernel and modules, with a few patches applied.

https://www.kernel.org/ || linux

• Hardened — A security-focused Linux kernel applying a set of hardening patches to mitigate kernel and userspace exploits. It also enables more upstream kernel hardening features than linux .

https://github.com/anthraxx/linux-hardened || linux-hardened

• Longterm — Long-term support (LTS) Linux kernel and modules.

https://www.kernel.org/ || linux-lts

• Zen Kernel — Result of a collaborative effort of kernel hackers to provide the best Linux kernel possible for everyday systems. Some more details can be found on https://liquorix.net (which provides kernel binaries based on Zen for Debian).

https://github.com/zen-kernel/zen-kernel || linux-zen

Compilation

Following methods can be used to compile your own kernel:

/Arch Build System Takes advantage of the high quality of existing linux PKGBUILD and the benefits of package management. /Traditional compilation Involves manually downloading a source tarball, and compiling in your home directory as a normal user.

Some of the listed packages may also be available as binary packages via Unofficial user repositories.

kernel.org kernels

• Git — Linux kernel and modules built using sources from Linus Torvalds’ Git repository

https://git.kernel.org/cgit/linux/kernel/git/torvalds/linux.git || linux-gitAUR

• Mainline — Kernels where all new features are introduced, released every 2-3 months.

https://www.kernel.org/ || linux-mainlineAUR

• Next — Bleeding edge kernels with features pending to be merged into next mainline release.

https://www.kernel.org/doc/man-pages/linux-next.html || linux-next-gitAUR

• Longterm 4.4 — Long-term support (LTS) Linux 4.4 kernel and modules.

https://www.kernel.org/ || linux-lts44AUR

• Longterm 4.9 — Long-term support (LTS) Linux 4.9 kernel and modules.

https://www.kernel.org/ || linux-lts49AUR

• Longterm 4.14 — Long-term support (LTS) Linux 4.14 kernel and modules.

https://www.kernel.org/ || linux-lts414AUR

• Longterm 4.19 — Long-term support (LTS) Linux 4.19 kernel and modules.

https://www.kernel.org/ || linux-lts419AUR

• Longterm 5.4 — Long-term support (LTS) Linux 5.4 kernel and modules.

https://www.kernel.org/ || linux-lts54AUR

Unofficial kernels

• Aufs — The aufs-compatible linux kernel and modules, useful when using docker.

http://aufs.sourceforge.net/ || linux-aufsAUR

• Ck — Contains patches by Con Kolivas (including the MuQSS scheduler) designed to improve system responsiveness with specific emphasis on the desktop, but they are suitable to any workload.

http://ck.kolivas.org/ || linux-ckAUR

• Clear — Patches from Intel’s Clear Linux project. Provides performance and security optimizations.

https://github.com/clearlinux-pkgs/linux || linux-clearAUR

• GalliumOS — The Linux kernel and modules with GalliumOS patches for Chromebooks.

https://github.com/GalliumOS/linux || linux-galliumosAUR

• Libre — Without propietary or obfuscated device drivers.

https://www.fsfla.org/ikiwiki/selibre/linux-libre/ || linux-libreAUR

• Liquorix — Kernel replacement built using Debian-targeted configuration and the Zen kernel sources. Designed for desktop, multimedia, and gaming workloads, it is often used as a Debian Linux performance replacement kernel. Damentz, the maintainer of the Liquorix patchset, is a developer for the Zen patchset as well.

https://liquorix.net || linux-lqxAUR

• MultiPath TCP — The Linux Kernel and modules with Multipath TCP support.

https://multipath-tcp.org/ || linux-mptcpAUR

• pf-kernel — Provides a handful of awesome features which are not merged into a kernel mainline. Maintained by a kernel engineer. If the port for the included patch for new kernels was not released officially, the patchset provides and supports patch ports to new kernels. The current most prominent patches of linux-pf are PDS CPU scheduler and UKSM.

https://gitlab.com/post-factum/pf-kernel/wikis/README || Packages:

• Repository by pf-kernel developer post-factum
• Repository, linux-pfAUR , linux-pf-preset-defaultAUR by pf-kernel fork developer Thaodan
• linux-pf-gitAUR by yurikoles

• Realtime kernel — Maintained by a small group of core developers led by Ingo Molnar. This patch allows nearly all of the kernel to be preempted, with the exception of a few very small regions of code («raw_spinlock critical regions»). This is done by replacing most kernel spinlocks with mutexes that support priority inheritance, as well as moving all interrupt and software interrupts to kernel threads.

https://wiki.linuxfoundation.org/realtime/start || linux-rtAUR , linux-rt-ltsAUR

• tkg — A highly customizable kernel build system that provides a selection of patches and tweaks aiming for better desktop and gaming performance. It is maintained by Etienne Juvigny. Amongst other patches, it offers various CPU schedulers: CFS, Project C PDS, Project C BMQ, MuQSS and CacULE.

https://github.com/Frogging-Family/linux-tkg || not packaged? search in AUR

• VFIO — The Linux kernel and a few patches written by Alex Williamson (acs override and i915) to enable the ability to do PCI Passthrough with KVM on some machines.

https://lwn.net/Articles/499240/ || linux-vfioAUR , linux-vfio-ltsAUR

• XanMod — Aiming to take full advantage in high-performance workstations, gaming desktops, media centers and others and built to provide a more rock-solid, responsive and smooth desktop experience. This kernel uses the MuQSS or CacULE scheduler, BFQ I/O scheduler, UKSM realtime memory data deduplication, TCP BBR congestion control, x86_64 advanced instruction set support, and other default changes.

https://xanmod.org/ || linux-xanmodAUR , linux-xanmod-caculeAUR

Debugging regressions

Try linux-mainline AUR to check if the issue is already fixed upstream. The stickied comment also mentions a repository which contains already built kernels, so it may not be necessary to build it manually, which can take some time.

It may also be worth considering trying the LTS kernel ( linux-lts ) to debug issues which did not appear recently. Older versions of the LTS kernel can be found in the Arch Linux Archive.

If the issue still persists, bisect linux-git AUR and report the bug on the kernel bugzilla. It is important to try the «vanilla» version without any patches to make sure it is not related to them. If a patch causes the issue, report it to the author of the patch.

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Kernel/Arch Build System

See Kernels for the main article.

The Arch Build System can be used to build a custom kernel based on the official linux package. This compilation method can automate the entire process, and is based on a very well tested package. You can edit the PKGBUILD to use a custom kernel configuration or add additional patches.

Contents

Getting the ingredients

Since you will be using makepkg, follow the best practices outlined there first. For example, you cannot run makepkg as root/sudo. Therefore, create a build directory in your user home first.

Install the asp package and the base-devel package group.

You need a clean kernel to start your customization from. Retrieve PKGBUILD source using Git and few other files into your build directory by running:

At this point, the directory tree looks like (there may be a few other files):

Then, get any other file you need (e.g. custom configuration files, patches, etc.) from the respective sources.

Modifying the PKGBUILD

Edit PKGBUILD and look for the pkgbase parameter. Change this to your custom package name, e.g.:

Avoid creating the doc

A large portion of the lengthy compiling effort is devoted to creating the documentation. As of June 16. 2021, the following patch to PKGBUILD avoids its creation:

This patch deletes line #63, and changes line #194. You might have to edit the PKGBUILD file manually if it does not apply cleanly.

Changing prepare()

In prepare() function, you can apply needed kernel patches or change kernel build configuration.

If you need to change a few config options you can edit config file in the source.

Or you can use a GUI tool to tweak the options. Comment make olddefconfig in the prepare() function of the PKGBUILD, and add your favorite tool:

Generate new checksums

#Changing prepare() suggests a possible modification to $_srcname/.config . Since this path is not where downloading the package files ended, its checksum was not checked by makepkg (which actually checked $_srcname/../../config ).

If you replaced the downloaded config with another config file before running makepkg, install the pacman-contrib package and generate new checksums by running:

Compiling

You can now proceed to compile your kernel by the usual command makepkg .

If you have chosen an interactive program for configuring the kernel parameters (like menuconfig), you need to be there during the compilation.

The -s parameter will download any additional dependencies used by recent kernels such as xml and docs.

Installing

The compile step will leave two packages in the

/build/linux folder, one for the kernel and one for the kernel headers. They might have names like:

Best practice is to install both packages together as they might be both needed (e.g. DKMS):

(substitute the actual names of the files you have in the folder)

Boot loader

If you have modified pkgbase in order to have your new kernel installed alongside the default kernel you will need to update your bootloader configuration file and add new entries (‘default’ and ‘fallback’) for your custom kernel and the associated initramfs images.

Updating

Assuming one has an arch kernel source that they want to update, one method to do that is with https://github.com/archlinux/linux. In what follows, the top kernel source directory is assumed at

In general, arch sets an arch kernel source with two local git repositories. The one at archlinux-linux/ is a local bare git repository pointing to https://github.com/archlinux/linux.git . The other one is at src/archlinux-linux/ , pulling from the bare repository. Possible local patches, and building, are expected at src/archlinux-linux/ .

For this example, the HEAD of the locally installed bare git repository source at archlinux-linux/ was initially pointing to

which is somewhere between v5.2.5-arch1 and v5.2.6-arch1.

One can see it fetched v5.2.7-arch1, which was the newest archlinux tag, because it prints what new tags were obtained. If no new tags were obtained then there is no newer archlinux source available.

Now the source can be updated where the actual build will take place.

You can verify you are on track with something like

This shows few specific archlinux patches between Arch Linux kernel v5.2.7-arch1 and Linux 5.2.7 .

The up to date PKGBUILD, as well archlinux kernel configuration file, can be pulled in by the asp command:

Now you should merge files located in

/build/linux/ . Merging can also done manually, or with specific utilities. Review #Changing prepare(), and run manually most, if not all, the shell commands of PKGBUILD::prepare().

At this point, makepkg —verifysource should succeed. While #Compiling, make sure to also add —noextract option to the makepkg command, since it should be able to build the packages as if the source was extracted by makepkg —nobuild . And you are back to #Installing.

Cleanup

One will probably want to remove

/build/linux/linux/ after merging. In addition,

/build/linux/src/archlinux will accumulate branches in the form of 5.2.7-arch1 if more recent updates are done in this fashion. These can be deleted with

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Kernel/Traditional compilation

This article is an introduction to building custom kernels from kernel.org sources. This method of compiling kernels is the traditional method common to all distributions. It can be, depending on your background, more complicated than using the Kernels/Arch Build System. Consider the Arch Build System tools are developed and maintained to make repeatable compilation tasks efficient and safe.

Contents

Preparation

It is not necessary (or recommended) to use the root account or root privileges (i.e. via Sudo) for kernel preparation.

Install the core packages

Install the base-devel package group, which contains necessary packages such as make and gcc . It is also recommended to install the following packages, as listed in the default Arch kernel PKGBUILD: xmlto , kmod , inetutils , bc , libelf , git , cpio , perl , tar , xz .

Create a kernel compilation directory

It is recommended to create a separate build directory for your kernel(s). In this example, the directory kernelbuild will be created in the home directory:

Download the kernel source

Download the kernel source from https://www.kernel.org. This should be the tarball ( tar.xz ) file for your chosen kernel.

It can be downloaded by simply right-clicking the tar.xz link in your browser and selecting Save Link As. , or any other number of ways via alternative graphical or command-line tools that utilise HTTP, TFTP, Rsync, or Git.

In the following command-line example, wget has been installed and is used inside the

/kernelbuild directory to obtain kernel 4.8.6:

You should also verify the correctness of the download before trusting it. First grab the signature, then use that to grab the fingerprint of the signing key, then use the fingerprint to obtain the actual signing key:

Note the signature was generated for the tar archive (i.e. extension .tar ), not the compressed .tar.xz file that you have downloaded. You need to decompress the latter without untarring it. Verify that you have xz installed, then you can proceed like so:

Do not proceed if this does not result in output that includes the string «Good signature».

If wget was not used inside the build directory, it will be necessary to move the tarball into it, e.g.

Unpack the kernel source

Within the build directory, unpack the kernel tarball:

To finalise the preparation, ensure that the kernel tree is absolutely clean; do not rely on the source tree being clean after unpacking. To do so, first change into the new kernel source directory created, and then run the make mrproper command:

Kernel configuration

This is the most crucial step in customizing the default kernel to reflect your computer’s precise specifications. Kernel configuration is set in its .config file, which includes the use of Kernel modules. By setting the options in .config properly, your kernel and computer will function most efficiently.

You can do a mixture of two things:

• Use the default Arch settings from an official kernel (recommended)
• Manually configure the kernel options (optional, advanced and not recommended)

Default Arch configuration

This method will create a .config file for the custom kernel using the default Arch kernel settings. If a stock Arch kernel is running, you can use the following command inside the custom kernel source directory:

Otherwise, the default configuration can be found online in the official Arch Linux kernel package.

Advanced configuration

There are several tools available to fine-tune the kernel configuration, which provide an alternative to otherwise spending hours manually configuring each and every one of the options available during compilation.

Those tools are:

• make menuconfig : Command-line ncurses interface superseded by nconfig
• make nconfig : Newer ncurses interface for the command-line
• make xconfig : User-friendly graphical interface that requires packagekit-qt5 to be installed as a dependency. This is the recommended method — especially for less experienced users — as it is easier to navigate, and information about each option is also displayed.
• make gconfig : Graphical configuration similar to xconfig but using gtk. This requires gtk2 , glib2 and libgladeAUR .

The chosen method should be run inside the kernel source directory, and all will either create a new .config file, or overwrite an existing one where present. All optional configurations will be automatically enabled, although any newer configuration options (i.e. with an older kernel .config ) may not be automatically selected.

Once the changes have been made save the .config file. It is a good idea to make a backup copy outside the source directory. You may need to do this multiple times before you get all the options right.

If unsure, only change a few options between compilations. If you cannot boot your newly built kernel, see the list of necessary config items here.

Running lspci -k # from liveCD lists names of kernel modules in use. Most importantly, you must maintain cgroups support. This is necessary for systemd. For more detailed information, see Gentoo:Kernel/Gentoo Kernel Configuration Guide and Gentoo:Intel#Kernel or Gentoo:Ryzen#Kernel for Intel or AMD Ryzen processors.

Compilation

Compilation time will vary from as little as fifteen minutes to over an hour, depending on your kernel configuration and processor capability. Once the .config file has been set for the custom kernel, within the source directory run the following command to compile:

Installation

Install the modules

Once the kernel has been compiled, the modules for it must follow. First build the modules:

Then install the modules. As root or with root privileges, run the following command to do so:

This will copy the compiled modules into /lib/modules/ — . For example, for kernel version 4.8 installed above, they would be copied to /lib/modules/4.8.6-ARCH . This keeps the modules for individual kernels used separated.

Copy the kernel to /boot directory

The kernel compilation process will generate a compressed bzImage (big zImage) of that kernel, which must be copied to the /boot directory and renamed in the process. Provided the name is prefixed with vmlinuz- , you may name the kernel as you wish. In the examples below, the installed and compiled 4.8 kernel has been copied over and renamed to vmlinuz-linux48 :

Make initial RAM disk

If you do not know what making an initial RAM disk is, see Initramfs on Wikipedia and mkinitcpio.

Automated preset method

An existing mkinitcpio preset can be copied and modified so that the custom kernel initramfs images can be generated in the same way as for an official kernel. This is useful where intending to recompile the kernel (e.g. where updated). In the example below, the preset file for the stock Arch kernel will be copied and modified for kernel 4.8, installed above.

First, copy the existing preset file, renaming it to match the name of the custom kernel specified as a suffix to /boot/vmlinuz- when copying the bzImage (in this case, linux48 ):

Second, edit the file and amend for the custom kernel. Note (again) that the ALL_kver= parameter also matches the name of the custom kernel specified when copying the bzImage :

Finally, generate the initramfs images for the custom kernel in the same way as for an official kernel:

Manual method

Rather than use a preset file, mkinitcpio can also be used to generate an initramfs file manually. The syntax of the command is:

• -k ( —kernel ): Specifies the modules to use when generating the initramfs image. The name will be the same as the name of the custom kernel source directory (and the modules directory for it, located in /usr/lib/modules/ ).
• -g ( —generate ): Specifies the name of the initramfs file to generate in the /boot directory. Again, using the naming convention mentioned above is recommended.

For example, the command for the 4.8 custom kernel installed above would be:

Copy System.map

The System.map file is not required for booting Linux. It is a type of «phone directory» list of functions in a particular build of a kernel. The System.map contains a list of kernel symbols (i.e function names, variable names etc) and their corresponding addresses. This «symbol-name to address mapping» is used by:

• Some processes like klogd, ksymoops, etc.
• By OOPS handler when information has to be dumped to the screen during a kernel crash (i.e info like in which function it has crashed).

If your /boot is on a filesystem which supports symlinks (i.e., not FAT32), copy System.map to /boot , appending your kernel’s name to the destination file. Then create a symlink from /boot/System.map to point to /boot/System.map- :

After completing all steps above, you should have the following 3 files and 1 soft symlink in your /boot directory along with any other previously existing files:

• Kernel: vmlinuz-
• Initramfs: Initramfs- .img
• System Map: System.map-
• System Map kernel symlink

Bootloader configuration

Add an entry for your new kernel in your bootloader’s configuration file. See Arch boot process#Feature comparison for possible boot loaders, their wiki articles and other information.

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