systemd-oomd.service, systemd-oomd — A userspace out-of-memory (OOM) killer
systemd-oomd.service
/usr/lib/systemd/systemd-oomd
systemd-oomd is a system service that uses cgroups-v2 and pressure stall information (PSI) to monitor and take corrective action before an OOM occurs in the kernel space.
You can enable monitoring and actions on units by setting ManagedOOMSwap=
and
ManagedOOMMemoryPressure=
in the unit configuration, see
systemd.resource-control(5).
systemd-oomd retrieves information about such units from
systemd(1)
when it starts and watches for subsequent changes.
Cgroups of units with ManagedOOMSwap=
or
ManagedOOMMemoryPressure=
set to kill
will be monitored.
systemd-oomd periodically polls PSI statistics for the system and those cgroups to
decide when to take action. If the configured limits are exceeded, systemd-oomd will
select a cgroup to terminate, and send SIGKILL
to all processes in it. Note that
only descendant cgroups are eligible candidates for killing; the unit with its property set to
kill
is not a candidate (unless one of its ancestors set their property to
kill
). Also only leaf cgroups and cgroups with memory.oom.group
set
to 1
are eligible candidates; see OOMPolicy=
in
systemd.service(5).
oomctl(1) can be used to list monitored cgroups and pressure information.
See oomd.conf(5) for more information about the configuration of this service.
See org.freedesktop.oom1(5) and org.freedesktop.LogControl1(5) for a description of the D-Bus API.
The system must be running systemd with a full unified cgroup hierarchy for the expected cgroups-v2 features.
Furthermore, memory accounting must be turned on for all units monitored by systemd-oomd.
The easiest way to turn on memory accounting is by ensuring the value for DefaultMemoryAccounting=
is set to true
in
systemd-system.conf(5).
The kernel must be compiled with PSI support. This is available in Linux 4.20 and above.
It is highly recommended for the system to have swap enabled for systemd-oomd to function optimally. With swap enabled, the system spends enough time swapping pages to let systemd-oomd react. Without swap, the system enters a livelocked state much more quickly and may prevent systemd-oomd from responding in a reasonable amount of time. See "In defence of swap: common misconceptions" for more details on swap. Any swap-based actions on systems without swap will be ignored. While systemd-oomd can perform pressure-based actions on such a system, the pressure increases will be more abrupt and may require more tuning to get the desired thresholds and behavior.
Be aware that if you intend to enable monitoring and actions on user.slice
,
user-$UID.slice
, or their ancestor cgroups, it is highly recommended that your
programs be managed by the systemd user manager to prevent running too many processes under the same
session scope (and thus avoid a situation where memory intensive tasks trigger
systemd-oomd to kill everything under the cgroup). If you're using a desktop
environment like GNOME or KDE, it already spawns many session components with the systemd user manager.
ManagedOOMSwap=
works with the system-wide swap values, so setting it on the root slice
-.slice
, and allowing all descendant cgroups to be eligible candidates may make the most
sense.
ManagedOOMMemoryPressure=
tends to work better on the cgroups below the root
slice. For units which tend to have processes that are less latency sensitive (e.g.
system.slice
), a higher limit like the default of 60% may be acceptable, as those
processes can usually ride out slowdowns caused by lack of memory without serious consequences. However,
something like user@$UID.service
may prefer a much lower value like 40%.