SYSTEMD-RUN(1) | systemd-run | SYSTEMD-RUN(1) |
systemd-run - Run programs in transient scope units, service units, or path-, socket-, or timer-triggered service units
systemd-run [OPTIONS...] COMMAND [ARGS...]
systemd-run [OPTIONS...] [PATH OPTIONS...] {COMMAND} [ARGS...]
systemd-run [OPTIONS...] [SOCKET OPTIONS...] {COMMAND} [ARGS...]
systemd-run [OPTIONS...] [TIMER OPTIONS...] {COMMAND} [ARGS...]
systemd-run may be used to create and start a transient .service or .scope unit and run the specified COMMAND in it. It may also be used to create and start a transient .path, .socket, or .timer unit, that activates a .service unit when elapsing.
If a command is run as transient service unit, it will be started and managed by the service manager like any other service, and thus shows up in the output of systemctl list-units like any other unit. It will run in a clean and detached execution environment, with the service manager as its parent process. In this mode, systemd-run will start the service asynchronously in the background and return after the command has begun execution (unless --no-block or --wait are specified, see below).
If a command is run as transient scope unit, it will be executed by systemd-run itself as parent process and will thus inherit the execution environment of the caller. However, the processes of the command are managed by the service manager similar to normal services, and will show up in the output of systemctl list-units. Execution in this case is synchronous, and will return only when the command finishes. This mode is enabled via the --scope switch (see below).
If a command is run with path, socket, or timer options such as --on-calendar= (see below), a transient path, socket, or timer unit is created alongside the service unit for the specified command. Only the transient path, socket, or timer unit is started immediately, the transient service unit will be triggered by the path, socket, or timer unit. If the --unit= option is specified, the COMMAND may be omitted. In this case, systemd-run creates only a .path, .socket, or .timer unit that triggers the specified unit.
By default, services created with systemd-run default to the simple type, see the description of Type= in systemd.service(5) for details. Note that when this type is used the service manager (and thus the systemd-run command) considers service start-up successful as soon as the fork() for the main service process succeeded, i.e. before the execve() is invoked, and thus even if the specified command cannot be started. Consider using the exec service type (i.e. --property=Type=exec) to ensure that systemd-run returns successfully only if the specified command line has been successfully started.
The following options are understood:
--no-ask-password
--scope
--unit=
--property=, -p
--description=
--slice=
-r, --remain-after-exit
--send-sighup
--service-type=
--uid=, --gid=
--nice=
--working-directory=
--same-dir, -d
-E NAME=VALUE, --setenv=NAME=VALUE
--pty, -t
Note that machinectl(1)'s shell command is usually a better alternative for requesting a new, interactive login session on the local host or a local container.
See below for details on how this switch combines with --pipe.
--pipe, -P
When both --pipe and --pty are used in combination the more appropriate option is automatically determined and used. Specifically, when invoked with standard input, output and error connected to a TTY --pty is used, and otherwise --pipe.
When this option is used the original file descriptors systemd-run receives are passed to the service processes as-is. If the service runs with different privileges than systemd-run, this means the service might not be able to re-open the passed file descriptors, due to normal file descriptor access restrictions. If the invoked process is a shell script that uses the echo "hello" > /dev/stderr construct for writing messages to stderr, this might cause problems, as this only works if stderr can be re-opened. To mitigate this use the construct echo "hello" >&2 instead, which is mostly equivalent and avoids this pitfall.
--shell, -S
--quiet, -q
--on-active=, --on-boot=, --on-startup=, --on-unit-active=, --on-unit-inactive=
--on-calendar=
--path-property=, --socket-property=, --timer-property=
--no-block
--wait
-G, --collect
--user
--system
-H, --host=
-M, --machine=
-h, --help
--version
All command line arguments after the first non-option argument become part of the command line of the launched process. If a command is run as service unit, the first argument needs to be an absolute program path.
On success, 0 is returned, a non-zero failure code otherwise.
Example 1. Logging environment variables provided by systemd to services
# systemd-run env Running as unit: run-19945.service # journalctl -u run-19945.service Sep 08 07:37:21 bupkis systemd[1]: Starting /usr/bin/env... Sep 08 07:37:21 bupkis systemd[1]: Started /usr/bin/env. Sep 08 07:37:21 bupkis env[19948]: PATH=/usr/local/sbin:/usr/local/bin:/usr/sbin:/usr/bin Sep 08 07:37:21 bupkis env[19948]: LANG=en_US.UTF-8 Sep 08 07:37:21 bupkis env[19948]: BOOT_IMAGE=/vmlinuz-3.11.0-0.rc5.git6.2.fc20.x86_64
Example 2. Limiting resources available to a command
# systemd-run -p BlockIOWeight=10 updatedb
This command invokes the updatedb(8) tool, but lowers the block I/O weight for it to 10. See systemd.resource-control(5) for more information on the BlockIOWeight= property.
Example 3. Running commands at a specified time
The following command will touch a file after 30 seconds.
# date; systemd-run --on-active=30 --timer-property=AccuracySec=100ms /bin/touch /tmp/foo Mon Dec 8 20:44:24 KST 2014 Running as unit: run-71.timer Will run service as unit: run-71.service # journalctl -b -u run-71.timer -- Logs begin at Fri 2014-12-05 19:09:21 KST, end at Mon 2014-12-08 20:44:54 KST. -- Dec 08 20:44:38 container systemd[1]: Starting /bin/touch /tmp/foo. Dec 08 20:44:38 container systemd[1]: Started /bin/touch /tmp/foo. # journalctl -b -u run-71.service -- Logs begin at Fri 2014-12-05 19:09:21 KST, end at Mon 2014-12-08 20:44:54 KST. -- Dec 08 20:44:48 container systemd[1]: Starting /bin/touch /tmp/foo... Dec 08 20:44:48 container systemd[1]: Started /bin/touch /tmp/foo.
Example 4. Allowing access to the tty
The following command invokes /bin/bash as a service passing its standard input, output and error to the calling TTY.
# systemd-run -t --send-sighup /bin/bash
Example 5. Start screen as a user service
$ systemd-run --scope --user screen Running scope as unit run-r14b0047ab6df45bfb45e7786cc839e76.scope. $ screen -ls There is a screen on:
492..laptop (Detached) 1 Socket in /var/run/screen/S-fatima.
This starts the screen process as a child of the systemd --user process that was started by user@.service, in a scope unit. A systemd.scope(5) unit is used instead of a systemd.service(5) unit, because screen will exit when detaching from the terminal, and a service unit would be terminated. Running screen as a user unit has the advantage that it is not part of the session scope. If KillUserProcesses=yes is configured in logind.conf(5), the default, the session scope will be terminated when the user logs out of that session.
The user@.service is started automatically when the user first logs in, and stays around as long as at least one login session is open. After the user logs out of the last session, user@.service and all services underneath it are terminated. This behavior is the default, when "lingering" is not enabled for that user. Enabling lingering means that user@.service is started automatically during boot, even if the user is not logged in, and that the service is not terminated when the user logs out.
Enabling lingering allows the user to run processes without being logged in, for example to allow screen to persist after the user logs out, even if the session scope is terminated. In the default configuration, users can enable lingering for themselves:
$ loginctl enable-linger
systemd(1), systemctl(1), systemd.unit(5), systemd.service(5), systemd.scope(5), systemd.slice(5), systemd.exec(5), systemd.resource-control(5), systemd.timer(5), systemd-mount(1), machinectl(1)
systemd 241 |