19 The systemd
daemon #
systemd
initializes the system. It has the process ID 1. systemd
is
started directly by the kernel and resists signal 9, which normally
terminates processes. All other programs are started directly by
systemd
or by one of its child processes. systemd
is a replacement for
the System V init daemon and is fully compatible with System V init (by
supporting init scripts).
The main advantage of systemd
is that it considerably speeds up boot time
by parallelizing service starts. Furthermore, systemd
only starts a
service when it is really needed. Daemons are not started unconditionally
at boot time, but when being required for the first time. systemd
also
supports Kernel Control Groups (cgroups), creating snapshots, and restoring
the system state. For more details see
https://www.freedesktop.org/wiki/Software/systemd/.
systemd
inside WSL
Windows Subsystem for Linux (WSL) enables running Linux applications and distributions under
the Microsoft Windows operating system. WSL uses its init process instead of systemd
. To enable
systemd
in SLED running in WSL, install the wsl_systemd
pattern that automates the process:
>
sudo
zypper in -t pattern wsl_systemd
Alternatively, you can edit /etc/wsl.conf
and add the following lines
manually:
[boot] systemd=true
Keep in mind that the support for systemd
in WSL is partial—systemd
unit files must
have reasonable process management behavior.
19.1 The systemd
concept #
The following section explains the concept behind systemd
.
systemd
is a system and session manager for Linux, compatible with
System V and LSB init scripts. The main features of systemd
include:
parallelization capabilities
socket and D-Bus activation for starting services
on-demand starting of daemons
tracking of processes using Linux cgroups
creating snapshots and restoring of the system state
maintains mount and automount points
implements an elaborate transactional dependency-based service control logic
19.1.1 Unit file #
A unit configuration file contains information about a service, a
socket, a device, a mount point, an automount point, a swap file or
partition, a start-up target, a watched file system path, a timer
controlled and supervised by systemd
, a temporary system state
snapshot, a resource management slice or a group of externally created
processes.
“Unit file” is a generic term used by systemd
for the
following:
Service. Information about a process (for example, running a daemon); file ends with .service
Targets. Used for grouping units and as synchronization points during start-up; file ends with .target
Sockets. Information about an IPC or network socket or a file system FIFO, for socket-based activation (like
inetd
); file ends with .socketPath. Used to trigger other units (for example, running a service when files change); file ends with .path
Timer. Information about a timer controlled, for timer-based activation; file ends with .timer
Mount point. Normally auto-generated by the fstab generator; file ends with .mount
Automount point. Information about a file system automount point; file ends with .automount
Swap. Information about a swap device or file for memory paging; file ends with .swap
Device. Information about a device unit as exposed in the sysfs/udev(7) device tree; file ends with .device
Scope / slice. A concept for hierarchically managing resources of a group of processes; file ends with .scope/.slice
For more information about systemd
unit files, see
https://www.freedesktop.org/software/systemd/man/latest/systemd.unit.html
19.2 Basic usage #
The System V init system uses several commands to handle
services—the init scripts, insserv
,
telinit
and others. systemd
makes it easier to
manage services, because there is only one command to handle most service
related tasks: systemctl
. It uses the “command
plus subcommand” notation like git
or
zypper
:
systemctl GENERAL OPTIONS SUBCOMMAND SUBCOMMAND OPTIONS
See man 1 systemctl
for a complete manual.
If the output goes to a terminal (and not to a pipe or a file, for
example), systemd
commands send long output to a pager by default.
Use the --no-pager
option to turn off paging mode.
systemd
also supports bash-completion, allowing you to enter the
first letters of a subcommand and then press →|.
This feature is only available in the bash
shell and requires the installation of the package
bash-completion
.
19.2.1 Managing services in a running system #
Subcommands for managing services are the same as for managing a
service with System V init (start
,
stop
, ...). The general syntax for service
management commands is as follows:
systemd
systemctl reload|restart|start|status|stop|... MY_SERVICE(S)
- System V init
rcMY_SERVICE(S) reload|restart|start|status|stop|...
systemd
allows you to manage several services in one go. Instead of
executing init scripts one after the other as with System V init,
execute a command like the following:
>
sudo
systemctl start MY_1ST_SERVICE MY_2ND_SERVICE
To list all services available on the system:
>
sudo
systemctl list-unit-files --type=service
The following table lists the most important service management
commands for systemd
and System V init:
Task |
|
System V init Command |
---|---|---|
Starting. |
start |
start |
Stopping. |
stop |
stop |
Restarting. Shuts down services and starts them afterward. If a service is not yet running, it is started. |
restart |
restart |
Restarting conditionally. Restarts services if they are currently running. Does nothing for services that are not running. |
try-restart |
try-restart |
Reloading.
Tells services to reload their configuration files without
interrupting operation. Use case: tell Apache to reload a
modified |
reload |
reload |
Reloading or restarting. Reloads services if reloading is supported, otherwise restarts them. If a service is not yet running, it is started. |
reload-or-restart |
n/a |
Reloading or restarting conditionally. Reloads services if reloading is supported, otherwise restarts them if currently running. Does nothing for services that are not running. |
reload-or-try-restart |
n/a |
Getting detailed status information.
Lists information about the status of services. The
|
status |
status |
Getting short status information. Shows whether services are active or not. |
is-active |
status |
19.2.2 Permanently enabling/disabling services #
The service management commands mentioned in the previous section let
you manipulate services for the current session. systemd
also lets
you permanently enable or disable services, so they are automatically
started when requested or are always unavailable. You can either do
this by using YaST, or on the command line.
19.2.2.1 Enabling/disabling services on the command line #
The following table lists enabling and disabling commands for
systemd
and System V init:
When enabling a service on the command line, it is not started
automatically. It is scheduled to be started with the next system
start-up or runlevel/target change. To immediately start a service
after having enabled it, explicitly run systemctl start
MY_SERVICE
or rc
MY_SERVICE start
.
Task |
|
System V init Command |
---|---|---|
Enabling. |
|
|
Disabling. |
|
|
Checking. Shows whether a service is enabled or not. |
|
|
Re-enabling. Similar to restarting a service, this command first disables and then enables a service. Useful to re-enable a service with its defaults. |
|
n/a |
Masking. After “disabling” a service, it can still be started manually. To disable a service, you need to mask it. Use with care. |
|
n/a |
Unmasking. A service that has been masked can only be used again after it has been unmasked. |
|
n/a |
19.3 System start and target management #
The entire process of starting the system and shutting it down is
maintained by systemd
. From this point of view, the kernel can be
considered a background process to maintain all other processes and
adjust CPU time and hardware access according to requests from other
programs.
19.3.1 Targets compared to runlevels #
With System V init the system was booted into a so-called
“Runlevel”. A runlevel defines how the system is started
and what services are available in the running system. Runlevels are
numbered; the most commonly known ones are 0
(shutting down the system), 3
(multiuser with
network) and 5
(multiuser with network and display
manager).
systemd
introduces a new concept by using so-called “target
units”. However, it remains fully compatible with the runlevel
concept. Target units are named rather than numbered and serve specific
purposes. For example, the targets
local-fs.target
and
swap.target
mount local file systems and swap
spaces.
The target graphical.target
provides a
multiuser system with network and display manager capabilities and is
equivalent to runlevel 5. Complex targets, such as
graphical.target
act as “meta”
targets by combining a subset of other targets. Since systemd
makes
it easy to create custom targets by combining existing targets, it
offers great flexibility.
The following list shows the most important systemd
target units. For
a full list refer to man 7 systemd.special
.
systemd
target units #default.target
The target that is booted by default. Not a “real” target, but rather a symbolic link to another target like
graphic.target
. Can be permanently changed via YaST (see Section 19.4, “Managing services with YaST”). To change it for a session, use the kernel parametersystemd.unit=MY_TARGET.target
at the boot prompt.emergency.target
Starts a minimal emergency
root
shell on the console. Only use it at the boot prompt assystemd.unit=emergency.target
.graphical.target
Starts a system with network, multiuser support and a display manager.
halt.target
Shuts down the system.
mail-transfer-agent.target
Starts all services necessary for sending and receiving mails.
multi-user.target
Starts a multiuser system with network.
reboot.target
Reboots the system.
rescue.target
Starts a single-user
root
session without network. Basic tools for system administration are available. Therescue
target is suitable for solving multiple system problems, for example, failing logins or fixing issues with a display driver.
To remain compatible with the System V init runlevel system, systemd
provides special targets named
runlevelX.target
mapping
the corresponding runlevels numbered X.
To inspect the current target, use the command: systemctl
get-default
systemd
target units #
System V runlevel |
|
Purpose |
---|---|---|
0 |
|
System shutdown |
1, S |
|
Single-user mode |
2 |
|
Local multiuser without remote network |
3 |
|
Full multiuser with network |
4 |
|
Unused/User-defined |
5 |
|
Full multiuser with network and display manager |
6 |
|
System reboot |
systemd
ignores /etc/inittab
The runlevels in a System V init system are configured in
/etc/inittab
. systemd
does
not use this configuration. Refer to
Section 19.5.5, “Creating custom targets” for instructions on
how to create your own bootable target.
19.3.1.1 Commands to change targets #
Use the following commands to operate with target units:
Task |
|
System V init Command |
---|---|---|
Change the current target/runlevel |
|
|
Change to the default target/runlevel |
|
n/a |
Get the current target/runlevel |
With |
or
|
persistently change the default runlevel |
Use the Services Manager or run the following command:
|
Use the Services Manager or change the line
in |
Change the default runlevel for the current boot process |
Enter the following option at the boot prompt
|
Enter the desired runlevel number at the boot prompt. |
Show a target's/runlevel's dependencies |
“Requires” lists the hard dependencies (the ones that must be resolved), whereas “Wants” lists the soft dependencies (the ones that get resolved if possible). |
n/a |
19.3.2 Debugging system start-up #
systemd
offers the means to analyze the system start-up process. You
can review the list of all services and their status (rather than
having to parse /var/log/
). systemd
also allows
you to scan the start-up procedure to find out how much time each
service start-up consumes.
19.3.2.1 Review start-up of services #
To review the complete list of services that have been started since
booting the system, enter the command systemctl
.
It lists all active services like shown below (shortened). To get
more information on a specific service, use systemctl status
MY_SERVICE
.
#
systemctl
UNIT LOAD ACTIVE SUB JOB DESCRIPTION
[...]
iscsi.service loaded active exited Login and scanning of iSC+
kmod-static-nodes.service loaded active exited Create list of required s+
libvirtd.service loaded active running Virtualization daemon
nscd.service loaded active running Name Service Cache Daemon
chronyd.service loaded active running NTP Server Daemon
polkit.service loaded active running Authorization Manager
postfix.service loaded active running Postfix Mail Transport Ag+
rc-local.service loaded active exited /etc/init.d/boot.local Co+
rsyslog.service loaded active running System Logging Service
[...]
LOAD = Reflects whether the unit definition was properly loaded.
ACTIVE = The high-level unit activation state, i.e. generalization of SUB.
SUB = The low-level unit activation state, values depend on unit type.
161 loaded units listed. Pass --all to see loaded but inactive units, too.
To show all installed unit files use 'systemctl list-unit-files'.
To restrict the output to services that failed to start, use the
--failed
option:
#
systemctl --failed
UNIT LOAD ACTIVE SUB JOB DESCRIPTION
apache2.service loaded failed failed apache
NetworkManager.service loaded failed failed Network Manager
plymouth-start.service loaded failed failed Show Plymouth Boot Screen
[...]
19.3.2.2 Debug start-up time #
To debug system start-up time, systemd
offers the
systemd-analyze
command. It shows the total
start-up time, a list of services ordered by start-up time and can
also generate an SVG graphic showing the time services took to start
in relation to the other services.
- Listing the system start-up time
#
systemd-analyze Startup finished in 2666ms (kernel) + 21961ms (userspace) = 24628ms- Listing the services start-up time
#
systemd-analyze blame 15.000s backup-rpmdb.service 14.879s mandb.service 7.646s backup-sysconfig.service 4.940s postfix.service 4.921s logrotate.service 4.640s libvirtd.service 4.519s display-manager.service 3.921s btrfsmaintenance-refresh.service 3.466s lvm2-monitor.service 2.774s plymouth-quit-wait.service 2.591s firewalld.service 2.137s initrd-switch-root.service 1.954s ModemManager.service 1.528s rsyslog.service 1.378s apparmor.service [...]- Services start-up time graphics
#
systemd-analyze plot > jupiter.example.com-startup.svg
19.3.2.3 Review the complete start-up process #
The commands above list the services that are started and their
start-up times. For a more detailed overview, specify the following
parameters at the boot prompt to instruct systemd
to create a
verbose log of the complete start-up procedure.
systemd.log_level=debug systemd.log_target=kmsg
Now systemd
writes its log messages into the kernel ring buffer.
View that buffer with dmesg
:
>
dmesg -T | less
19.3.3 System V compatibility #
systemd
is compatible with System V, allowing you to still use
existing System V init scripts. However, there is at least one known
issue where a System V init script does not work with systemd
out of
the box: starting a service as a different user via
su
or sudo
in init scripts
results in a failure of the script, producing an “Access
denied” error.
When changing the user with su
or
sudo
, a PAM session is started. This session will be
terminated after the init script is finished. As a consequence, the
service that has been started by the init script is also
terminated. To work around this error, proceed as follows:
Create a service file wrapper with the same name as the init script plus the file name extension
.service
:[Unit] Description=DESCRIPTION After=network.target [Service] User=USER Type=forking1 PIDFile=PATH TO PID FILE1 ExecStart=PATH TO INIT SCRIPT start ExecStop=PATH TO INIT SCRIPT stop ExecStopPost=/usr/bin/rm -f PATH TO PID FILE1 [Install] WantedBy=multi-user.target2
Replace all values written in UPPERCASE LETTERS with appropriate values.
Start the daemon with
systemctl start APPLICATION
.
19.4 Managing services with YaST #
Basic service management can also be done with the YaST Services Manager module. It supports starting, stopping, enabling and disabling services. It also lets you show a service's status and change the default target. Start the YaST module with
› › .- Changing the
To change the target the system boots into, choose a target from the
drop-down box. The most often used targets are (starting a graphical login screen) and (starting the system in command line mode).- Starting or stopping a service
Select a service from the table. The
column shows whether it is currently running ( ) or not ( ). Toggle its status by choosing or .Starting or stopping a service changes its status for the currently running session. To change its status throughout a reboot, you need to enable or disable it.
- Defining service start-up behavior
Services can either be started automatically at boot time or manually. Select a service from the table. The
column shows whether it is currently started or . Toggle its status by choosing .To change a service status in the current session, you need to start or stop it as described above.
- View a status messages
To view the status message of a service, select it from the list and choose
. The output is identical to the one generated by the commandsystemctl
-l
status MY_SERVICE.
19.5 Customizing systemd
#
The following sections describe how to customize systemd
unit files.
19.5.1 Where are unit files stored? #
systemd
unit files shipped by SUSE are stored in
/usr/lib/systemd/
. Customized unit files and unit file
drop-ins are stored in
/etc/systemd/
.
When customizing systemd
, always use the directory
/etc/systemd/
instead of /usr/lib/systemd/
.
Otherwise your changes will be overwritten by the next update of systemd
.
19.5.2 Override with drop-in files #
Drop-in files (or drop-ins) are partial unit files that override only
specific settings of the unit file. Drop-ins have higher precedence over main configuration
files. The command
systemctl edit SERVICE
starts the default text editor and creates a directory with an empty
override.conf
file in
/etc/systemd/system/NAME.service.d/
. The
command also ensures that the running systemd
process is notified about the changes.
For example, to change the amount of time that the system waits for MariaDB to start, run
sudo systemctl edit mariadb.service
and edit the opened file to include
the modified lines only:
# Configures the time to wait for start-up/stop TimeoutSec=300
Adjust the TimeoutSec
value and save the changes. To enable the changes,
run sudo systemctl daemon-reload
.
For further information, refer to the man pages that can be evoked with
the man 1 systemctl
command.
If you use the --full
option in the systemctl edit --full
SERVICE
command, a copy of the original unit file is
created where you can modify specific options. We do not recommend such customization
because when the unit file is updated by SUSE, its changes are overridden by the
customized copy in the /etc/systemd/system/
directory. Moreover, if
SUSE provides updates to distribution drop-ins, they override the copy of the unit file
created with --full
. To prevent this confusion and always have your
customization valid, use drop-ins.
19.5.3 Creating drop-in files manually #
Apart from using the systemctl edit
command, you can create drop-ins
manually to have more control over their priority. Such drop-ins let you extend both unit
and daemon configuration files without having to edit or override the files themselves.
They are stored in the following directories:
/etc/systemd/*.conf.d/
,/etc/systemd/system/*.service.d/
Drop-ins added and customized by system administrators.
/usr/lib/systemd/*.conf.d/
,/usr/lib/systemd/system/*.service.d/
Drop-ins installed by customization packages to override upstream settings. For example, SUSE ships systemd-default-settings.
See the man page man 5 systemd.unit
for the full
list of unit search paths.
For example, to disable the rate limiting that is enforced by the
default setting of
systemd-journald
, follow these steps:
Create a directory called
/etc/systemd/journald.conf.d
.>
sudo
mkdir /etc/systemd/journald.conf.dNoteThe directory name must follow the service name that you want to patch with the drop-in file.
In that directory, create a file
/etc/systemd/journald.conf.d/60-rate-limit.conf
with the option that you want to override, for example:>
cat /etc/systemd/journald.conf.d/60-rate-limit.conf
# Disable rate limiting RateLimitIntervalSec=0Save your changes and restart the service of the corresponding
systemd
daemon.>
sudo
systemctl restart systemd-journald
To avoid name conflicts between your drop-ins and files shipped by
SUSE, it is recommended to prefix all drop-ins with a two-digit
number and a dash, for example,
80-override.conf
.
The following ranges are reserved:
0-19
is reserved forsystemd
upstream.20-29
is reserved forsystemd
shipped by SUSE.30-39
is reserved for SUSE packages other thansystemd
.40-49
is reserved for third-party packages.50
is reserved for unit drop-in files created withsystemctl set-property
.
Use a two-digit number above this range to ensure that none of the drop-ins shipped by SUSE can override your own drop-ins.
You can use systemctl cat $UNIT
to list and verify
which files are taken into account in the units configuration.
Because the configuration of systemd
components can be scattered
across different places on the file system, it might be hard to get a
global overview. To inspect the configuration of a systemd
component, use the following commands:
systemctl cat UNIT_PATTERN
prints configuration files related to one or moresystemd
units, for example:>
systemctl cat atd.servicesystemd-analyze cat-config DAEMON_NAME_OR_PATH
copies the contents of a configuration file and drop-ins for asystemd
daemon, for example:>
systemd-analyze cat-config systemd/journald.conf
19.5.4 Converting xinetd
services to systemd
#
Since the release of SUSE Linux Enterprise Desktop 15, the
xinetd
infrastructure has been removed. This
section outlines how to convert existing custom
xinetd
service files to systemd
sockets.
For each xinetd
service file, you need at
least two systemd
unit files: the socket file
(*.socket
) and an associated service file
(*.service
). The socket file tells systemd
which
socket to create, and the service file tells systemd
which executable
to start.
Consider the following example xinetd
service
file:
#
cat /etc/xinetd.d/example
service example
{
socket_type = stream
protocol = tcp
port = 10085
wait = no
user = user
group = users
groups = yes
server = /usr/libexec/example/exampled
server_args = -auth=bsdtcp exampledump
disable = no
}
To convert it to systemd
, you need the following two matching files:
#
cat /usr/lib/systemd/system/example.socket
[Socket]
ListenStream=0.0.0.0:10085
Accept=false
[Install]
WantedBy=sockets.target
#
cat /usr/lib/systemd/system/example.service
[Unit]
Description=example
[Service]
ExecStart=/usr/libexec/example/exampled -auth=bsdtcp exampledump
User=user
Group=users
StandardInput=socket
For a complete list of the systemd
“socket” and
“service” file options, refer to the systemd.socket and
systemd.service manual pages (man 5 systemd.socket
,
man 5 systemd.service
).
19.5.5 Creating custom targets #
On System V init SUSE systems, runlevel 4 is unused to allow
administrators to create their own runlevel configuration. systemd
allows you to create any number of custom targets. It is suggested to
start by adapting an existing target such as
graphical.target
.
Copy the configuration file
/usr/lib/systemd/system/graphical.target
to/etc/systemd/system/MY_TARGET.target
and adjust it according to your needs.The configuration file copied in the previous step already covers the required (“hard”) dependencies for the target. To also cover the wanted (“soft”) dependencies, create a directory
/etc/systemd/system/MY_TARGET.target.wants
.For each wanted service, create a symbolic link from
/usr/lib/systemd/system
into/etc/systemd/system/MY_TARGET.target.wants
.When you have finished setting up the target, reload the
systemd
configuration to make the new target available:>
sudo
systemctl daemon-reload
19.6 Advanced usage #
The following sections cover advanced topics for system administrators.
For even more advanced systemd
documentation, refer to Lennart
Pöttering's series about systemd
for administrators at
https://0pointer.de/blog/projects/.
19.6.1 Cleaning temporary directories #
systemd
supports cleaning temporary directories regularly. The
configuration from the previous system version is automatically
migrated and active. tmpfiles.d
—which is
responsible for managing temporary files—reads its configuration
from /etc/tmpfiles.d/*.conf
,
/run/tmpfiles.d/*.conf
, and
/usr/lib/tmpfiles.d/*.conf
files. Configuration
placed in /etc/tmpfiles.d/*.conf
overrides related
configurations from the other two directories
(/usr/lib/tmpfiles.d/*.conf
is where packages
store their configuration files).
The configuration format is one line per path containing action and path, and optionally mode, ownership, age and argument fields, depending on the action. The following example unlinks the X11 lock files:
Type Path Mode UID GID Age Argument r /tmp/.X[0-9]*-lock
To get the status the tmpfile timer:
>
sudo
systemctl status systemd-tmpfiles-clean.timer systemd-tmpfiles-clean.timer - Daily Cleanup of Temporary Directories Loaded: loaded (/usr/lib/systemd/system/systemd-tmpfiles-clean.timer; static) Active: active (waiting) since Tue 2018-04-09 15:30:36 CEST; 1 weeks 6 days ago Docs: man:tmpfiles.d(5) man:systemd-tmpfiles(8) Apr 09 15:30:36 jupiter systemd[1]: Starting Daily Cleanup of Temporary Directories. Apr 09 15:30:36 jupiter systemd[1]: Started Daily Cleanup of Temporary Directories.
For more information on temporary files handling, see man 5
tmpfiles.d
.
19.6.2 System log #
Section 19.6.9, “Debugging services” explains
how to view log messages for a given service. However, displaying log
messages is not restricted to service logs. You can also access and
query the complete log messages written by systemd
—the
so-called “Journal”. Use the command
journalctl
to display the complete log messages
starting with the oldest entries. Refer to man 1
journalctl
for options such as applying filters or changing
the output format.
19.6.3 Snapshots #
You can save the current state of systemd
to a named snapshot and
later revert to it with the isolate
subcommand. This
is useful when testing services or custom targets, because it allows
you to return to a defined state at any time. A snapshot is only
available in the current session and will automatically be deleted on
reboot. A snapshot name must end in .snapshot
.
- Create a snapshot
>
sudo
systemctl snapshot MY_SNAPSHOT.snapshot- Delete a snapshot
>
sudo
systemctl delete MY_SNAPSHOT.snapshot- View a snapshot
>
sudo
systemctl show MY_SNAPSHOT.snapshot- Activate a snapshot
>
sudo
systemctl isolate MY_SNAPSHOT.snapshot
19.6.4 Loading kernel modules #
With systemd
, kernel modules can automatically be loaded at boot time
via a configuration file in /etc/modules-load.d
.
The file should be named MODULE.conf and
have the following content:
# load module MODULE at boot time MODULE
In case a package installs a configuration file for loading a kernel
module, the file gets installed to
/usr/lib/modules-load.d
. If two configuration
files with the same name exist, the one in
/etc/modules-load.d
tales precedence.
For more information, see the
modules-load.d(5)
man page.
19.6.5 Performing actions before loading a service #
With System V init actions that need to be performed before loading a
service, needed to be specified in /etc/init.d/before.local
. This procedure is no longer supported with systemd
. If
you need to do actions before starting services, do the following:
- Loading kernel modules
Create a drop-in file in
/etc/modules-load.d
directory (seeman modules-load.d
for the syntax)- Creating Files or Directories, Cleaning-up Directories, Changing Ownership
Create a drop-in file in
/etc/tmpfiles.d
(seeman tmpfiles.d
for the syntax)- Other tasks
Create a system service file, for example,
/etc/systemd/system/before.service
, from the following template:[Unit] Before=NAME OF THE SERVICE YOU WANT THIS SERVICE TO BE STARTED BEFORE [Service] Type=oneshot RemainAfterExit=true ExecStart=YOUR_COMMAND # beware, executable is run directly, not through a shell, check the man pages # systemd.service and systemd.unit for full syntax [Install] # target in which to start the service WantedBy=multi-user.target #WantedBy=graphical.target
When the service file is created, you should run the following commands (as
root
):>
sudo
systemctl daemon-reload>
sudo
systemctl enable beforeEvery time you modify the service file, you need to run:
>
sudo
systemctl daemon-reload
19.6.6 Kernel control groups (cgroups) #
On a traditional System V init system, it is not always possible to match a process to the service that spawned it. Certain services, such as Apache, spawn a lot of third-party processes (for example, CGI or Java processes), which themselves spawn more processes. This makes a clear assignment difficult or even impossible. Additionally, a service may not finish correctly, leaving certain children alive.
systemd
solves this problem by placing each service into its own
cgroup. cgroups are a kernel feature that allows aggregating processes
and all their children into hierarchical organized groups. systemd
names each cgroup after its service. Since a non-privileged process is
not allowed to “leave” its cgroup, this provides an
effective way to label all processes spawned by a service with the name
of the service.
To list all processes belonging to a service, use the command
systemd-cgls
, for example:
#
systemd-cgls --no-pager
├─1 /usr/lib/systemd/systemd --switched-root --system --deserialize 20
├─user.slice
│ └─user-1000.slice
│ ├─session-102.scope
│ │ ├─12426 gdm-session-worker [pam/gdm-password]
│ │ ├─15831 gdm-session-worker [pam/gdm-password]
│ │ ├─15839 gdm-session-worker [pam/gdm-password]
│ │ ├─15858 /usr/lib/gnome-terminal-server
[...]
└─system.slice
├─systemd-hostnamed.service
│ └─17616 /usr/lib/systemd/systemd-hostnamed
├─cron.service
│ └─1689 /usr/sbin/cron -n
├─postfix.service
│ ├─ 1676 /usr/lib/postfix/master -w
│ ├─ 1679 qmgr -l -t fifo -u
│ └─15590 pickup -l -t fifo -u
├─sshd.service
│ └─1436 /usr/sbin/sshd -D
[...]
See Chapter 10, Kernel control groups for more information about cgroups.
19.6.7 Terminating services (sending signals) #
As explained in Section 19.6.6, “Kernel control groups (cgroups)”, it is not always possible to assign a process to its parent service process in a System V init system. This makes it difficult to stop a service and its children. Child processes that have not been terminated remain as zombie processes.
systemd
's concept of confining each service into a cgroup makes it
possible to identify all child processes of a service and therefore
allows you to send a signal to each of these processes. Use
systemctl kill
to send signals to services. For a
list of available signals refer to man 7 signals
.
- Sending
SIGTERM
to a service SIGTERM
is the default signal that is sent.>
sudo
systemctl kill MY_SERVICE- Sending SIGNAL to a service
Use the
-s
option to specify the signal that should be sent.>
sudo
systemctl kill -s SIGNAL MY_SERVICE- Selecting processes
By default the
kill
command sends the signal toall
processes of the specified cgroup. You can restrict it to thecontrol
or themain
process. The latter is, for example, useful to force a service to reload its configuration by sendingSIGHUP
:>
sudo
systemctl kill -s SIGHUP --kill-who=main MY_SERVICE
19.6.8 Important notes on the D-Bus service #
The D-Bus service is the message bus for communication between
systemd
clients and the systemd manager that is running as pid 1.
Even though dbus
is a
stand-alone daemon, it is an integral part of the init infrastructure.
Stopping dbus
or restarting it
in the running system is similar to an attempt to stop or restart PID
1. It breaks the systemd
client/server communication and makes most
systemd
functions unusable.
Therefore, terminating or restarting
dbus
is neither
recommended nor supported.
Updating the dbus
or
dbus
-related packages requires a reboot. When
in doubt whether a reboot is necessary, run the sudo zypper ps
-s
. If dbus
appears among the listed
services, you need to reboot the system.
Keep in mind that dbus
is updated even when
automatic updates are configured to skip the packages that require
reboot.
19.6.9 Debugging services #
By default, systemd
is not overly verbose. If a service was started
successfully, no output is produced. In case of a failure, a short
error message is displayed. However, systemctl
status
provides a means to debug the start-up and operation of a
service.
systemd
comes with its own logging mechanism (“The
Journal”) that logs system messages. This allows you to display
the service messages together with status messages. The
status
command works similar to
tail
and can also display the log messages in
different formats, making it a powerful debugging tool.
- Show service start-up failure
Whenever a service fails to start, use
systemctl status MY_SERVICE
to get a detailed error message:#
systemctl start apache2 Job failed. See system journal and 'systemctl status' for details.#
systemctl status apache2 Loaded: loaded (/usr/lib/systemd/system/apache2.service; disabled) Active: failed (Result: exit-code) since Mon, 04 Apr 2018 16:52:26 +0200; 29s ago Process: 3088 ExecStart=/usr/sbin/start_apache2 -D SYSTEMD -k start (code=exited, status=1/FAILURE) CGroup: name=systemd:/system/apache2.service Apr 04 16:52:26 g144 start_apache2[3088]: httpd2-prefork: Syntax error on line 205 of /etc/apache2/httpd.conf: Syntax error on li...alHost>- Show last N service messages
The default behavior of the
status
subcommand is to display the last ten messages a service issued. To change the number of messages to show, use the--lines=N
parameter:>
sudo
systemctl status chronyd>
sudo
systemctl --lines=20 status chronyd- Show service messages in append mode
To display a “live stream” of service messages, use the
--follow
option, which works liketail
-f
:>
sudo
systemctl --follow status chronyd- Messages output format
The
--output=MODE
parameter allows you to change the output format of service messages. The most important modes available are:short
The default format. Shows the log messages with a human readable time stamp.
verbose
Full output with all fields.
cat
Terse output without time stamps.
19.7 systemd
timer units #
Similar to cron, systemd
timer units provide a mechanism for scheduling
jobs on Linux. Although systemd
timer units serve the same purpose as
cron, they offer several advantages.
Jobs scheduled using a timer unit can depend on other
systemd
services.Timer units are treated as regular
systemd
services, so can be managed withsystemctl
.Timers can be realtime and monotonic.
Time units are logged to the
systemd
journal, which makes it easier to monitor and troubleshoot them.
systemd
timer units are identified by the .timer
file name extension.
19.7.1 systemd
timer types #
Timer units can use monotonic and realtime timers.
Similar to cronjobs, realtime timers are triggered on calendar events. Realtime timers are defined using the option
OnCalendar
.Monotonic timers are triggered at a specified time elapsed from a certain starting point. The latter could be a system boot or system unit activation event. There are several options for defining monotonic timers including
OnBootSec
,OnUnitActiveSec
, andOnTypeSec
. Monotonic timers are not persistent, and they are reset after each reboot.
19.7.2 systemd
timers and service units #
Every timer unit must have a corresponding systemd
unit file it
controls. In other words, a .timer
file activates
and manages the corresponding .service
file. When
used with a timer, the .service
file does not
require an [Install]
section, as the service is
managed by the timer.
19.7.3 Practical example #
To understand the basics of systemd
timer units, we set up a timer
that triggers the foo.sh
shell script.
First step is to create a systemd
service unit that controls the
shell script. To do this, open a new text file for editing and add the
following service unit definition:
[Unit] Description="Foo shell script" [Service] ExecStart=/usr/local/bin/foo.sh
Save the file under the name foo.service
in the
directory /etc/systemd/system/
.
Next, open a new text file for editing and add the following timer definition:
[Unit] Description="Run foo shell script" [Timer] OnBootSec=5min OnUnitActiveSec=24h Unit=foo.service [Install] WantedBy=multi-user.target
The [Timer]
section in the example above specifies
what service to trigger (foo.service
) and when to
trigger it. In this case, the option OnBootSec
specifies a monotonic timer that triggers the service five minutes
after the system boot, while the option
OnUnitActiveSec
triggers the service 24 hours after
the service has been activated (that is, the timer triggers the service
once a day). Finally, the option WantedBy
specifies
that the timer should start when the system has reached the multiuser
target.
Instead of a monotonic timer, you can specify a real-time one using the
option OnCalendar
. The following realtime timer
definition triggers the related service unit once a week, starting on
Monday at 12:00.
[Timer] OnCalendar=weekly Persistent=true
The option Persistent=true
indicates that the service
is triggered immediately after the timer activation if the timer missed
the last start time (for example, because of the system being powered
off).
The option OnCalendar
can also be used to define
specific dates times for triggering a service using the following
format: DayOfWeek Year-Month-Day Hour:Minute:Second
.
The example below triggers a service at 5am every day:
OnCalendar=*-*-* 5:00:00
You can use an asterisk to specify any value, and commas to list possible values. Use two values separated by .. to indicate a contiguous range. The following example triggers a service at 6pm on Friday of every month:
OnCalendar=Fri *-*-1..7 18:00:00
To trigger a service at different times, you can specify several
OnCalendar
entries:
OnCalendar=Mon..Fri 10:00 OnCalendar=Sat,Sun 22:00
In the example above, a service is triggered at 10am on week days and at 10pm on weekends.
When you are done editing the timer unit file, save it under the name
foo.timer
in the
/etc/systemd/system/
directory. To check the
correctness of the created unit files, run the following command:
>
sudo
systemd-analyze verify /etc/systemd/system/foo.*
If the command returns no output, the files have passed the verification successfully.
To start the timer, use the command sudo systemctl start
foo.timer
. To enable the timer on boot, run the command
sudo systemctl enable foo.timer
.
19.7.4 Managing systemd
timers #
Since timers are treated as regular systemd
units, you can manage
them using systemctl
. You can start a timer with
systemctl start
, enable a timer with
systemctl enable
, and so on. Additionally, you can
list all active timers using the command systemctl
list-timers
. To list all timers, including inactive ones, run
the command systemctl list-timers --all
.
19.8 More information #
For more information on systemd
refer to the following online
resources:
- Homepage
systemd
for administratorsLennart Pöttering, one of the
systemd
authors, has written a series of blog entries (13 at the time of writing this chapter). Find them at https://0pointer.de/blog/projects/.