The /etc/systemd/system.conf
file
contains a set of options to control basic systemd operations. The
default file has all entries commented out with the default
settings indicated. This file is where the log level may be changed
as well as some basic logging settings. See the systemd-system.conf(5)
manual page for details on
each configuration option.
The normal behavior for systemd is to clear the screen at the end of the boot sequence. If desired, this behavior may be changed by running the following command:
mkdir -pv /etc/systemd/system/getty@tty1.service.d
cat > /etc/systemd/system/getty@tty1.service.d/noclear.conf << EOF
[Service]
TTYVTDisallocate=no
EOF
The boot messages can always be reviewed by using the
journalctl -b
command as the root user.
By default, /tmp
is created as a
tmpfs. If this is not desired, it can be overridden by executing
the following command:
ln -sfv /dev/null /etc/systemd/system/tmp.mount
Alternatively, if a a separate partition for /tmp
is desired, specify that partition in a
/etc/fstab
entry.
Do not create the symbolic link above if a separate partition is
used for /tmp
. This will prevent
the root file system (/) from being remounted r/w and make the
system unusable when booted.
There are several services that create or delete files or directories:
systemd-tmpfiles-clean.service
systemd-tmpfiles-setup-dev.service
systemd-tmpfiles-setup.service
The system location for the configuration files is /usr/lib/tmpfiles.d/*.conf
. The local
configuration files are in /etc/tmpfiles.d
. Files in /etc/tmpfiles.d
override files with the same name
in /usr/lib/tmpfiles.d
. See
tmpfiles.d(5)
manual page for file
format details.
Note that the syntax for the /usr/lib/tmpfiles.d/*.conf
files can be
confusing. For example, the default deletion of files in the /tmp
directory is located in /usr/lib/tmpfiles.d/tmp.conf
with the line:
q /tmp 1777 root root 10d
The type field, q, discusses creating a subvolume with quotas which is really only applicable to btrfs filesystems. It references type v which in turn references type d (directory). This then creates the specified directory if is is not present and adjusts the permissions and ownership as specified. Contents of the directory will be subject to time based cleanup if the age argument is specified.
If the default parameters are not desired, then the file should be
copied to /etc/tmpfiles.d
and edited
as desired. For example:
mkdir -p /etc/tmpfiles.d cp /usr/lib/tmpfiles.d/tmp.conf /etc/tmpfiles.d
The parameters of a unit can be overriden by creating a directory
and a configuration file in /etc/systemd/system
. For example:
mkdir -pv /etc/systemd/system/foobar.service.d
cat > /etc/systemd/system/foobar.service.d/foobar.conf << EOF
[Service]
Restart=always
RestartSec=30
EOF
See systemd.unit(5)
manual page for
more information. After creating the configuration file, run
systemctl
daemon-reload
and systemctl restart foobar
to
activate the changes to a service.
Rather than plain shell scripts used in SysVinit or BSD style init systems, systemd uses a unified format for different types of startup files (or units). The command systemctl is used to enable, disable, control state, and obtain status of unit files. Here are some examples of frequently used commands:
systemctl list-units -t
<service>
[--all]: lists loaded unit files of type
service.
systemctl list-units -t
<target>
[--all]: lists loaded unit files of type
target.
systemctl show -p Wants
<multi-user.target>
:
shows all units that depend on the multi-user target. Targets
are special unit files that are anogalous to runlevels under
SysVinit.
systemctl status <servicename.service>
:
shows the status of the servicename service. The .service
extension can be omitted if there are no other unit files
with the same name, such as .socket files (which create a
listening socket that provides similar functionality to
inetd/xinetd).
Logging on a system booted with systemd is handled with systemd-journald (by default), rather than a typical unix syslog daemon. You can also add a normal syslog daemon and have both operate side by side if desired. The systemd-journald program stores journal entries in a binary format rather than a plain text log file. To assist with parsing the file, the command journalctl is provided. Here are some examples of frequently used commands:
journalctl -r: shows all contents of the journal in reverse chronological order.
journalctl -u UNIT
: shows
the journal entries associated with the specified UNIT file.
journalctl -b[=ID] -r: shows the journal entries since last successful boot (or for boot ID) in reverse chronological order.
journalctl -f: provides functionality similar to tail -f (follow).
Core dumps are useful to debug crashed programs, especially when a
daemon process crashes. On systemd booted systems the core dumping
is handled by systemd-coredump. It will log the
core dump in the journal and store the core dump itself in
/var/lib/systemd/coredump
. To
retrieve and process core dumps, the coredumpctl tool is provided.
Here are some examples of frequently used commands:
coredumpctl -r: lists all core dumps in reverse chronological order.
coredumpctl -1 info: shows the information from the last core dump.
coredumpctl -1 debug: loads the last core dump into GDB.
Core dumps may use a lot of disk space. The maximum disk space used
by core dumps can be limited by creating a configuration file in
/etc/systemd/coredump.conf.d
. For
example:
mkdir -pv /etc/systemd/coredump.conf.d
cat > /etc/systemd/coredump.conf.d/maxuse.conf << EOF
[Coredump]
MaxUse=5G
EOF
See the systemd-coredump(8)
,
coredumpctl(1)
, and coredump.conf.d(5)
manual pages for more
information.
Beginning with systemd-230, all user processes are killed when a
user session is ended, even if nohup is used, or the process uses
the daemon()
or setsid()
functions. This is a deliberate change
from a historically permissive environment to a more restrictive
one. The new behavior may cause issues if you depend on long
running programs (e.g., screen or tmux) to remain active after
ending your user session. There are three ways to enable lingering
processes to remain after a user session is ended.
Enable process lingering for only
selected users: Normal users have permission to
enable process lingering with the command loginctl enable-linger for
their own user. System administrators can use the same
command with a user
argument to enable for a user. That user can then use the
systemd-run
command to start long running processes. For example:
systemd-run --scope --user
/usr/bin/screen. If you enable lingering for
your user, the user@.service will remain even after all login
sessions are closed, and will automatically start at system
boot. This has the advantage of explicitly allowing and
disallowing processes to run after the user session has
ended, but breaks backwards compatibility with tools like
nohup and
utilities that use daemon()
.
Enable system-wide process
lingering: You can set KillUserProcesses=no
in
/etc/systemd/logind.conf
to
enable process lingering globally for all users. This has the
benefit of leaving the old method available to all users at
the expense of explicit control.
Disable at build-time:
You can disable lingering by default while building systemd
by adding the switch -Ddefault-kill-user-processes=false
to the meson
command for systemd. This completely disables the ability of
systemd to kill user processes at session end.