systemd-sysext, systemd-sysext.service, systemd-confext, systemd-confext.service — Activates System Extension Images
systemd-sysext [OPTIONS...] COMMAND
systemd-confext [OPTIONS...] COMMAND
systemd-sysext activates/deactivates system extension images. System extension
images may – dynamically at runtime — extend the
/opt/ directory hierarchies with additional files. This is particularly useful on
immutable system images where a
residing on a read-only file system shall be extended temporarily at runtime without making any
System extension images should contain files and directories similar in fashion to regular
operating system tree. When one or more system extension images are activated, their
/opt/ hierarchies are combined via
overlayfs" with the same hierarchies of the host OS, and the host
/opt/ overmounted with it ("merging"). When they are
deactivated, the mount point is disassembled — again revealing the unmodified original host version of
the hierarchy ("unmerging"). Merging thus makes the extension's resources suddenly appear below the
/opt/ hierarchies as if they were included in the
base OS image itself. Unmerging makes them disappear again, leaving in place only the files that were
shipped with the base OS image itself.
Files and directories contained in the extension images outside of the
/opt/ hierarchies are not merged, and hence have no effect
when included in a system extension image. In particular, files in the
/var/ included in a system extension image will not appear in
the respective hierarchies after activation.
System extension images are strictly read-only, and the host
/opt/ hierarchies become read-only too while they are activated.
System extensions are supposed to be purely additive, i.e. they are supposed to include only files that do not exist in the underlying basic OS image. However, the underlying mechanism (overlayfs) also allows overlaying or removing files, but it is recommended not to make use of this.
System extension images may be provided in the following formats:
Plain directories or btrfs subvolumes containing the OS tree
Disk images with a GPT disk label, following the Discoverable Partitions Specification
Disk images lacking a partition table, with a naked Linux file system (e.g. erofs, squashfs or ext4)
These image formats are the same ones that
supports via its
--image= switches and those that the
service manager supports via
RootImage=. Similar to
them they may optionally carry Verity authentication information.
System extensions are searched for in the directories
/var/lib/extensions/. The first two listed directories are not suitable for
carrying large binary images, however are still useful for carrying symlinks to them. The primary place
for installing system extensions is
/var/lib/extensions/. Any directories found in
these search directories are considered directory based extension images; any files with the
.raw suffix are considered disk image based extension images. When invoked in the
initrd, the additional directory
/.extra/sysext/ is included in the directories that
are searched for extension images. Note however, that by default a tighter image policy applies to images
found there, though, see below. This directory is populated by
extension images found in the system's EFI System Partition.
During boot OS extension images are activated automatically, if the
systemd-sysext.service is enabled. Note that this service runs only after the
underlying file systems where system extensions may be located have been mounted. This means they are not
suitable for shipping resources that are processed by subsystems running in earliest boot. Specifically,
OS extension images are not suitable for shipping system services or
definitions. See the Portable Services page
for a simple mechanism for shipping system services in disk images, in a similar fashion to OS
extensions. Note the different isolation on these two mechanisms: while system extension directly extend
the underlying OS image with additional files that appear in a way very similar to as if they were
shipped in the OS image itself and thus imply no security isolation, portable services imply service
level sandboxing in one way or another. The
systemd-sysext.service service is
guaranteed to finish start-up before
basic.target is reached; i.e. at the time
regular services initialize (those which do not use
DefaultDependencies=no), the files
and directories system extensions provide are available in
/opt/ and may be accessed.
Note that there is no concept of enabling/disabling installed system extension images: all
installed extension images are automatically activated at boot. However, you can place an empty directory
named like the extension (no
/etc/extensions/ to "mask"
an extension with the same name in a system folder with lower precedence.
A simple mechanism for version compatibility is enforced: a system extension image must carry a
file, which must match its image name, that is compared with the host
file: the contained
ID= fields have to match unless "
_any" is set
for the extension. If the extension
ID= is not "
SYSEXT_LEVEL= field (if defined) has to match. If the latter is not defined, the
VERSION_ID= field has to match instead. If the extension defines the
ARCHITECTURE= field and the value is not "
_any" it has to match the kernel's
architecture reported by uname(2)
but the used architecture identifiers are the same as for
described in systemd.unit(5).
EXTENSION_RELOAD_MANAGER= can be set to 1 if the extension requires a service manager reload after application
of the extension. Note that the for the reasons mentioned earlier:
Portable Services remain
the recommended way to ship system services.
System extensions should not ship a
/usr/lib/os-release file (as that would be merged
into the host
/usr/ tree, overriding the host OS version data, which is not desirable).
extension-release file follows the same format and semantics, and carries the same
content, as the
os-release file of the OS, but it describes the resources carried
in the extension image.
The systemd-confext concept follows the same principle as the
functionality but instead of working on
confext will extend only
/etc. Files and directories contained
in the confext images outside of the
/etc/ hierarchy are not
merged, and hence have no effect when included in the image. Formats for these images are of the
same as sysext images. The merged hierarchy will be mounted with "
(if not disabled via
Confexts are looked for in the directories
/usr/local/lib/confexts/. The first listed directory is not suitable for
carrying large binary images, however is still useful for carrying symlinks to them. The primary place
for installing configuration extensions is
/var/lib/confexts/. Any directories found
in these search directories are considered directory based confext images; any files with the
.raw suffix are considered disk image based confext images.
Again, just like sysext images, the confext images will contain a
file, which must match the image name (with the usual escape hatch of
and again with content being one or more of
CONFEXT_LEVEL. Confext images will then be checked and matched against the base OS
The primary use case for system images are immutable environments where debugging and development tools shall optionally be made available, but not included in the immutable base OS image itself (e.g. strace(1) and gdb(1) shall be an optionally installable addition in order to make debugging/development easier). System extension images should not be misunderstood as a generic software packaging framework, as no dependency scheme is available: system extensions should carry all files they need themselves, except for those already shipped in the underlying host system image. Typically, system extension images are built at the same time as the base OS image — within the same build system.
Another use case for the system extension concept is temporarily overriding OS supplied resources
with newer ones, for example to install a locally compiled development version of some low-level
component over the immutable OS image without doing a full OS rebuild or modifying the nominally
immutable image. (e.g. "install" a locally built package with DESTDIR=/var/lib/extensions/mytest
make install && systemd-sysext refresh, making it available in
/usr/ as if it was installed in the OS image itself.) This case works regardless if
the underlying host
/usr/ is managed as immutable disk image or is a traditional
package manager controlled (i.e. writable) tree.
For the confext case, the OSConfig project aims to perform runtime reconfiguration of OS services. Sometimes, there is a need to swap certain configuration parameter values or restart only a specific service without deployment of new code or a complete OS deployment. In other words, we want to be able to tie the most frequently configured options to runtime updateable flags that can be changed without a system reboot. This will help reduce servicing times when there is a need for changing the OS configuration.
The following commands are understood by both the sysext and confext concepts:
When invoked without any command verb, or when
status is specified
the current merge status is shown, separately (for both
/opt/ of sysext and for
/etc/ of confext).
Merges all currently installed system extension images into
/opt/, by overmounting these hierarchies with an
overlayfs" file system combining the underlying hierarchies with those included in
the extension images. This command will fail if the hierarchies are already merged. For confext, the merge
happens into the
/etc/ directory instead.
Unmerges all currently installed system extension images from
/opt/ for sysext and
for confext, by unmounting the "
overlayfs" file systems created by
A combination of
merge: if already
mounted the existing "
overlayfs" instance is unmounted temporarily, and then
replaced by a new version. This command is useful after installing/removing system extension images,
in order to update the "
overlayfs" file system accordingly. If no system extensions
are installed when this command is executed, the equivalent of
unmerge is executed,
without establishing any new "
Note that currently there's a brief moment where neither the old nor the new "
file system is mounted. This implies that all resources supplied by a system extension will briefly
disappear — even if it exists continuously during the refresh operation.
A brief list of installed extension images is shown.
Operate relative to the specified root directory, i.e. establish the
overlayfs" mount not on the top-level host
/opt/ hierarchies for sysext or
/etc/ for confext,
but below some specified root directory.
When merging system extensions into
/opt/ for sysext and
/etc/ for confext,
ignore version incompatibilities, i.e. force merging regardless of
whether the version information included in the images matches the host or not.
Takes an image policy string as argument, as per
policy is enforced when operating on system extension disk images. If not specified defaults to
for system extensions, i.e. only the root and
/usr/ file systems in the image
are used. For configuration extensions defaults to
root=verity+signed+encrypted+unprotected+absent". When run in the initrd and
operating on a system extension image stored in the
/.extra/sysext/ directory a
slightly stricter policy is used by default: "
see above for details.
When merging configuration extensions into
MS_NOEXEC" mount flag is used by default. This option can be used to disable
When used with merge,
unmerge or refresh, do not reload daemon
after executing the changes even if an extension that is applied requires a reload via the
EXTENSION_RELOAD_MANAGER= set to 1.
Do not pipe output into a pager.
Do not print the legend, i.e. column headers and the footer with hints.
Shows output formatted as JSON. Expects one of "
short" (for the
shortest possible output without any redundant whitespace or line breaks), "
(for a pretty version of the same, with indentation and line breaks) or "
off" (to turn
off JSON output, the default).
On success, 0 is returned.