LXC is the well-known and heavily tested low-level Linux container runtime. It is in active development since 2008 and has proven itself in critical production environments world-wide. Some of its core contributors are the same people that helped to implement various well-known containerization features inside the Linux kernel.
Type | Service | Status |
---|---|---|
CI (Linux) | GitHub | |
CI (Linux) | Jenkins | |
Project status | CII Best Practices | |
Fuzzing | OSS-Fuzz | |
Fuzzing | CIFuzz |
LXC's main focus is system containers. That is, containers which offer an environment as close as possible as the one you'd get from a VM but without the overhead that comes with running a separate kernel and simulating all the hardware.
This is achieved through a combination of kernel security features such as namespaces, mandatory access control and control groups.
Unprivileged containers are containers that are run without any privilege. This requires support for user namespaces in the kernel that the container is run on. LXC was the first runtime to support unprivileged containers after user namespaces were merged into the mainline kernel.
In essence, user namespaces isolate given sets of UIDs and GIDs. This is achieved by establishing a mapping between a range of UIDs and GIDs on the host to a different (unprivileged) range of UIDs and GIDs in the container. The kernel will translate this mapping in such a way that inside the container all UIDs and GIDs appear as you would expect from the host whereas on the host these UIDs and GIDs are in fact unprivileged. For example, a process running as UID and GID 0 inside the container might appear as UID and GID 100000 on the host. The implementation and working details can be gathered from the corresponding user namespace man page.
Since unprivileged containers are a security enhancement they naturally come with a few restrictions enforced by the kernel. In order to provide a fully functional unprivileged container LXC interacts with 3 pieces of setuid code:
Everything else is run as your own user or as a uid which your user owns.
In general, LXC's goal is to make use of every security feature available in the kernel. This means LXC's configuration management will allow experienced users to intricately tune LXC to their needs.
A more detailed introduction into LXC security can be found under the following link
In principle LXC can be run without any of these tools provided the correct configuration is applied. However, the usefulness of such containers is usually quite restricted. Just to highlight the two most common problems:
Network: Without relying on a setuid helper to setup appropriate network
devices for an unprivileged user (see LXC's lxc-user-nic
binary) the only
option is to share the network namespace with the host. Although this should
be secure in principle, sharing the host's network namespace is still one
step of isolation less and increases the attack vector.
Furthermore, when host and container share the same network namespace the
kernel will refuse any sysfs mounts. This usually means that the init binary
inside of the container will not be able to boot up correctly.
User Namespaces: As outlined above, user namespaces are a big security enhancement. However, without relying on privileged helpers users who are unprivileged on the host are only permitted to map their own UID into a container. A standard POSIX system however, requires 65536 UIDs and GIDs to be available to guarantee full functionality.
LXC is configured via a simple set of keys. For example,
lxc.rootfs.path
lxc.mount.entry
LXC namespaces configuration keys by using single dots. This means complex
configuration keys such as lxc.net.0
expose various subkeys such as
lxc.net.0.type
, lxc.net.0.link
, lxc.net.0.ipv6.address
, and others for
even more fine-grained configuration.
LXC is used as the default runtime for Incus, a container hypervisor exposing a well-designed and stable REST-api on top of it.
LXC runs on any kernel from 2.6.32 onwards. All it requires is a functional C compiler. LXC works on all architectures that provide the necessary kernel features. This includes (but isn't limited to):
LXC also supports at least the following C standard libraries:
LXC has always focused on strong backwards compatibility. In fact, the API
hasn't been broken from release 1.0.0
onwards. Main LXC is currently at
version 4.*.*
.
The LXC project has a good reputation in handling security issues quickly and efficiently. If you think you've found a potential security issue, please report it by e-mail to security (at) linuxcontainers (dot) org.
For further details please have a look at
We always welcome new contributors and are happy to provide guidance when
necessary. LXC follows the kernel coding conventions. This means we only
require that each commit includes a Signed-off-by
line. The coding style we
use is identical to the one used by the Linux kernel. You can find a detailed
introduction at:
and should also take a look at the CONTRIBUTING file in this repo.
If you want to become more active it is usually also a good idea to show up in the LXC IRC channel #lxc-dev on irc.libera.chat. We try to do all development out in the open and discussion of new features or bugs is done either in appropriate GitHub issues or on IRC.
When thinking about making security critical contributions or substantial changes it is usually a good idea to ping the developers first and ask whether a PR would be accepted.
LXC and its related projects strictly adhere to a semantic versioning scheme.
Source for the latest released version can always be downloaded from
You can browse the up to the minute source code and change history online
Without considering distribution specific details a simple
meson setup -Dprefix=/usr build
meson compile -C build
is usually sufficient.
When you find you need help, the LXC projects provides you with several options.
We maintain a discuss forum at
where you can get support.
You can find us in #lxc on irc.libera.chat.
You can check out one of the two LXC mailing list archives and register if interested: