systemd is an init system and system manager that has widely become the new standard for Linux distributions. Due to its heavy adoption, familiarizing yourself with
systemd is well worth the trouble, as it will make administering servers considerably easier. Learning about and using the tools and daemons that comprise
systemd will help you better appreciate the power, flexibility, and capabilities it provides, or at least help you to do your job with less hassle.
In this guide, we will be discussing the
systemctl command, which is the central management tool for controlling the init system. We will cover how to manage services, check statuses, change system states, and work with the configuration files.
Please note that although
systemd has become the default init system for many Linux distributions, it isn’t implemented universally across all distros. As you go through this tutorial, if your terminal outputs the error
bash: systemctl is not installed then it is likely that your machine has a different init system installed.
The fundamental purpose of an init system is to initialize the components that must be started after the Linux kernel is booted (traditionally known as “userland” components). The init system is also used to manage services and daemons for the server at any point while the system is running. With that in mind, we will start with some basic service management operations.
systemd, the target of most actions are “units”, which are resources that
systemd knows how to manage. Units are categorized by the type of resource they represent and they are defined with files known as unit files. The type of each unit can be inferred from the suffix on the end of the file.
For service management tasks, the target unit will be service units, which have unit files with a suffix of
.service. However, for most service management commands, you can actually leave off the
.service suffix, as
systemd is smart enough to know that you probably want to operate on a service when using service management commands.
To start a
systemd service, executing instructions in the service’s unit file, use the
start command. If you are running as a non-root user, you will have to use
sudo since this will affect the state of the operating system:
- sudo systemctl start application.service
As we mentioned above,
systemd knows to look for
*.service files for service management commands, so the command could be typed like this:
- sudo systemctl start application
Although you may use the above format for general administration, for clarity, we will use the
.service suffix for the remainder of the commands, to be explicit about the target we are operating on.
To stop a currently running service, you can use the
stop command instead:
- sudo systemctl stop application.service
To restart a running service, you can use the
- sudo systemctl restart application.service
If the application in question is able to reload its configuration files (without restarting), you can issue the
reload command to initiate that process:
- sudo systemctl reload application.service
If you are unsure whether the service has the functionality to reload its configuration, you can issue the
reload-or-restart command. This will reload the configuration in-place if available. Otherwise, it will restart the service so the new configuration is picked up:
- sudo systemctl reload-or-restart application.service
The above commands are useful for starting or stopping services during the current session. To tell
systemd to start services automatically at boot, you must enable them.
To start a service at boot, use the
- sudo systemctl enable application.service
This will create a symbolic link from the system’s copy of the service file (usually in
/etc/systemd/system) into the location on disk where
systemd looks for autostart files (usually
/etc/systemd/system/some_target.target.wants. We will go over what a target is later in this guide).
To disable the service from starting automatically, you can type:
- sudo systemctl disable application.service
This will remove the symbolic link that indicated that the service should be started automatically.
Keep in mind that enabling a service does not start it in the current session. If you wish to start the service and also enable it at boot, you will have to issue both the
To check the status of a service on your system, you can use the
- systemctl status application.service
This will provide you with the service state, the cgroup hierarchy, and the first few log lines.
For instance, when checking the status of an Nginx server, you may see output like this:
Output● nginx.service - A high performance web server and a reverse proxy server Loaded: loaded (/usr/lib/systemd/system/nginx.service; enabled; vendor preset: disabled) Active: active (running) since Tue 2015-01-27 19:41:23 EST; 22h ago Main PID: 495 (nginx) CGroup: /system.slice/nginx.service ├─495 nginx: master process /usr/bin/nginx -g pid /run/nginx.pid; error_log stderr; └─496 nginx: worker process Jan 27 19:41:23 desktop systemd: Starting A high performance web server and a reverse proxy server... Jan 27 19:41:23 desktop systemd: Started A high performance web server and a reverse proxy server.
This gives you a nice overview of the current status of the application, notifying you of any problems and any actions that may be required.
There are also methods for checking for specific states. For instance, to check to see if a unit is currently active (running), you can use the
- systemctl is-active application.service
This will return the current unit state, which is usually
inactive. The exit code will be “0” if it is active, making the result simpler to parse in shell scripts.
To see if the unit is enabled, you can use the
- systemctl is-enabled application.service
This will output whether the service is
disabled and will again set the exit code to “0” or “1” depending on the answer to the command question.
A third check is whether the unit is in a failed state. This indicates that there was a problem starting the unit in question:
- systemctl is-failed application.service
This will return
active if it is running properly or
failed if an error occurred. If the unit was intentionally stopped, it may return
inactive. An exit status of “0” indicates that a failure occurred and an exit status of “1” indicates any other status.
The commands so far have been useful for managing single services, but they are not very helpful for exploring the current state of the system. There are a number of
systemctl commands that provide this information.
To see a list of all of the active units that
systemd knows about, we can use the
- systemctl list-units
This will show you a list of all of the units that
systemd currently has active on the system. The output will look something like this:
OutputUNIT LOAD ACTIVE SUB DESCRIPTION atd.service loaded active running ATD daemon avahi-daemon.service loaded active running Avahi mDNS/DNS-SD Stack dbus.service loaded active running D-Bus System Message Bus dcron.service loaded active running Periodic Command Scheduler dkms.service loaded active exited Dynamic Kernel Modules System email@example.com loaded active running Getty on tty1 . . .
The output has the following columns:
systemd. The configuration of loaded units is kept in memory.
list-units command shows only active units by default, all of the entries above will show
loaded in the LOAD column and
active in the ACTIVE column. This display is actually the default behavior of
systemctl when called without additional commands, so you will see the same thing if you call
systemctl with no arguments:
We can tell
systemctl to output different information by adding additional flags. For instance, to see all of the units that
systemd has loaded (or attempted to load), regardless of whether they are currently active, you can use the
--all flag, like this:
- systemctl list-units --all
This will show any unit that
systemd loaded or attempted to load, regardless of its current state on the system. Some units become inactive after running, and some units that
systemd attempted to load may have not been found on disk.
You can use other flags to filter these results. For example, we can use the
--state= flag to indicate the LOAD, ACTIVE, or SUB states that we wish to see. You will have to keep the
--all flag so that
systemctl allows non-active units to be displayed:
- systemctl list-units --all --state=inactive
Another common filter is the
--type= filter. We can tell
systemctl to only display units of the type we are interested in. For example, to see only active service units, we can use:
- systemctl list-units --type=service
list-units command only displays units that
systemd has attempted to parse and load into memory. Since
systemd will only read units that it thinks it needs, this will not necessarily include all of the available units on the system. To see every available unit file within the
systemd paths, including those that
systemd has not attempted to load, you can use the
list-unit-files command instead:
- systemctl list-unit-files
Units are representations of resources that
systemd knows about. Since
systemd has not necessarily read all of the unit definitions in this view, it only presents information about the files themselves. The output has two columns: the unit file and the state.
OutputUNIT FILE STATE proc-sys-fs-binfmt_misc.automount static dev-hugepages.mount static dev-mqueue.mount static proc-fs-nfsd.mount static proc-sys-fs-binfmt_misc.mount static sys-fs-fuse-connections.mount static sys-kernel-config.mount static sys-kernel-debug.mount static tmp.mount static var-lib-nfs-rpc_pipefs.mount static org.cups.cupsd.path enabled . . .
The state will usually be
masked. In this context, static means that the unit file does not contain an
install section, which is used to enable a unit. As such, these units cannot be enabled. Usually, this means that the unit performs a one-off action or is used only as a dependency of another unit and should not be run by itself.
We will cover what
masked means momentarily.
So far, we have been working with services and displaying information about the unit and unit files that
systemd knows about. However, we can find out more specific information about units using some additional commands.
To display the unit file that
systemd has loaded into its system, you can use the
cat command (this was added in
systemd version 209). For instance, to see the unit file of the
atd scheduling daemon, we could type:
- systemctl cat atd.service
Output[Unit] Description=ATD daemon [Service] Type=forking ExecStart=/usr/bin/atd [Install] WantedBy=multi-user.target
The output is the unit file as known to the currently running
systemd process. This can be important if you have modified unit files recently or if you are overriding certain options in a unit file fragment (we will cover this later).
To see a unit’s dependency tree, you can use the
- systemctl list-dependencies sshd.service
This will display a hierarchy mapping the dependencies that must be dealt with in order to start the unit in question. Dependencies, in this context, include those units that are either required by or wanted by the units above it.
Outputsshd.service ├─system.slice └─basic.target ├─microcode.service ├─rhel-autorelabel-mark.service ├─rhel-autorelabel.service ├─rhel-configure.service ├─rhel-dmesg.service ├─rhel-loadmodules.service ├─paths.target ├─slices.target . . .
The recursive dependencies are only displayed for
.target units, which indicate system states. To recursively list all dependencies, include the
To show reverse dependencies (units that depend on the specified unit), you can add the
--reverse flag to the command. Other flags that are useful are the
--after flags, which can be used to show units that depend on the specified unit starting before and after themselves, respectively.
To see the low-level properties of a unit, you can use the
show command. This will display a list of properties that are set for the specified unit using a
- systemctl show sshd.service
OutputId=sshd.service Names=sshd.service Requires=basic.target Wants=system.slice WantedBy=multi-user.target Conflicts=shutdown.target Before=shutdown.target multi-user.target After=syslog.target network.target auditd.service systemd-journald.socket basic.target system.slice Description=OpenSSH server daemon . . .
If you want to display a single property, you can pass the
-p flag with the property name. For instance, to see the conflicts that the
sshd.service unit has, you can type:
- systemctl show sshd.service -p Conflicts
We saw in the service management section how to stop or disable a service, but
systemd also has the ability to mark a unit as completely unstartable, automatically or manually, by linking it to
/dev/null. This is called masking the unit, and is possible with the
- sudo systemctl mask nginx.service
This will prevent the Nginx service from being started, automatically or manually, for as long as it is masked.
If you check the
list-unit-files, you will see the service is now listed as masked:
- systemctl list-unit-files
Output. . . kmod-static-nodes.service static ldconfig.service static mandb.service static messagebus.service static nginx.service masked quotaon.service static rc-local.service static rdisc.service disabled rescue.service static . . .
If you attempt to start the service, you will see a message like this:
- sudo systemctl start nginx.service
OutputFailed to start nginx.service: Unit nginx.service is masked.
To unmask a unit, making it available for use again, use the
- sudo systemctl unmask nginx.service
This will return the unit to its previous state, allowing it to be started or enabled.
While the specific format for unit files is outside of the scope of this tutorial,
systemctl provides built-in mechanisms for editing and modifying unit files if you need to make adjustments. This functionality was added in
systemd version 218.
edit command, by default, will open a unit file snippet for the unit in question:
- sudo systemctl edit nginx.service
This will be a blank file that can be used to override or add directives to the unit definition. A directory will be created within the
/etc/systemd/system directory which contains the name of the unit with
.d appended. For instance, for the
nginx.service, a directory called
nginx.service.d will be created.
Within this directory, a snippet will be created called
override.conf. When the unit is loaded,
systemd will, in memory, merge the override snippet with the full unit file. The snippet’s directives will take precedence over those found in the original unit file.
If you wish to edit the full unit file instead of creating a snippet, you can pass the
- sudo systemctl edit --full nginx.service
This will load the current unit file into the editor, where it can be modified. When the editor exits, the changed file will be written to
/etc/systemd/system, which will take precedence over the system’s unit definition (usually found somewhere in
To remove any additions you have made, either delete the unit’s
.d configuration directory or the modified service file from
/etc/systemd/system. For instance, to remove a snippet, we could type:
- sudo rm -r /etc/systemd/system/nginx.service.d
To remove a full modified unit file, we would type:
- sudo rm /etc/systemd/system/nginx.service
After deleting the file or directory, you should reload the
systemd process so that it no longer attempts to reference these files and reverts back to using the system copies. You can do this by typing:
- sudo systemctl daemon-reload
Targets are special unit files that describe a system state or synchronization point. Like other units, the files that define targets can be identified by their suffix, which in this case is
.target. Targets do not do much themselves, but are instead used to group other units together.
This can be used in order to bring the system to certain states, much like other init systems use runlevels. They are used as a reference for when certain functions are available, allowing you to specify the desired state instead of the individual units needed to produce that state.
For instance, there is a
swap.target that is used to indicate that swap is ready for use. Units that are part of this process can sync with this target by indicating in their configuration that they are
swap.target. Units that require swap to be available can specify this condition using the
After= specifications to indicate the nature of their relationship.
systemd process has a default target that it uses when booting the system. Satisfying the cascade of dependencies from that single target will bring the system into the desired state. To find the default target for your system, type:
- systemctl get-default
If you wish to set a different default target, you can use the
set-default. For instance, if you have a graphical desktop installed and you wish for the system to boot into that by default, you can change your default target accordingly:
- sudo systemctl set-default graphical.target
You can get a list of the available targets on your system by typing:
- systemctl list-unit-files --type=target
Unlike runlevels, multiple targets can be active at one time. An active target indicates that
systemd has attempted to start all of the units tied to the target and has not tried to tear them down again. To see all of the active targets, type:
- systemctl list-units --type=target
It is possible to start all of the units associated with a target and stop all units that are not part of the dependency tree. The command that we need to do this is called, appropriately,
isolate. This is similar to changing the runlevel in other init systems.
For instance, if you are operating in a graphical environment with
graphical.target active, you can shut down the graphical system and put the system into a multi-user command line state by isolating the
graphical.target depends on
multi-user.target but not the other way around, all of the graphical units will be stopped.
You may wish to take a look at the dependencies of the target you are isolating before performing this procedure to ensure that you are not stopping vital services:
- systemctl list-dependencies multi-user.target
When you are satisfied with the units that will be kept alive, you can isolate the target by typing:
- sudo systemctl isolate multi-user.target
There are targets defined for important events like powering off or rebooting. However,
systemctl also has some shortcuts that add a bit of additional functionality.
For instance, to put the system into rescue (single-user) mode, you can use the
rescue command instead of
- sudo systemctl rescue
This will provide the additional functionality of alerting all logged in users about the event.
To halt the system, you can use the
- sudo systemctl halt
To initiate a full shutdown, you can use the
- sudo systemctl poweroff
A restart can be started with the
- sudo systemctl reboot
These all alert logged in users that the event is occurring, something that only running or isolating the target will not do. Note that most machines will link the shorter, more conventional commands for these operations so that they work properly with
For example, to reboot the system, you can usually type:
- sudo reboot
By now, you should be familiar with some of the basic capabilities of the
systemctl command that allow you to interact with and control your
systemd instance. The
systemctl utility will be your main point of interaction for service and system state management.
systemctl operates mainly with the core
systemd process, there are other components to the
systemd ecosystem that are controlled by other utilities. Other capabilities, like log management and user sessions are handled by separate daemons and management utilities (
loginctl respectively). Taking time to become familiar with these other tools and daemons will make management an easier task.
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