daemon — Writing and packaging system daemons
A daemon is a service process that runs in the background and supervises the system or provides functionality to other processes. Traditionally, daemons are implemented following a scheme originating in SysV Unix. Modern daemons should follow a simpler yet more powerful scheme (here called "new-style" daemons), as implemented by systemd(1). This manual page covers both schemes, and in particular includes recommendations for daemons that shall be included in the systemd init system.
When a traditional SysV daemon starts, it should execute the following steps as part of the initialization. Note that these steps are unnecessary for new-style daemons (see below), and should only be implemented if compatibility with SysV is essential.
Close all open file descriptors except
standard input, output, and error (i.e. the first three file
descriptors 0, 1, 2). This ensures that no accidentally passed
file descriptor stays around in the daemon process. On Linux,
this is best implemented by iterating through
/proc/self/fd, with a fallback of
iterating from file descriptor 3 to the value returned by
getrlimit() for
RLIMIT_NOFILE.
Reset all signal handlers to their default.
This is best done by iterating through the available signals
up to the limit of _NSIG and resetting
them to SIG_DFL.
Reset the signal mask
using
sigprocmask().
Sanitize the environment block, removing or resetting environment variables that might negatively impact daemon runtime.
Call fork(), to create a
background process.
In the child, call
setsid() to detach from any terminal and
create an independent session.
In the child, call fork()
again, to ensure that the daemon can never re-acquire a
terminal again.
Call exit() in the first
child, so that only the second child (the actual daemon
process) stays around. This ensures that the daemon process is
re-parented to init/PID 1, as all daemons should
be.
In the daemon process, connect
/dev/null to standard input, output, and
error.
In the daemon process, reset the umask to 0,
so that the file modes passed to open(),
mkdir() and suchlike directly control the
access mode of the created files and
directories.
In the daemon process, change the current directory to the root directory (/), in order to avoid that the daemon involuntarily blocks mount points from being unmounted.
In the daemon process, write the daemon PID
(as returned by getpid()) to a PID file,
for example /run/foobar.pid (for a
hypothetical daemon "foobar") to ensure that the daemon cannot
be started more than once. This must be implemented in
race-free fashion so that the PID file is only updated when it
is verified at the same time that the PID previously stored in
the PID file no longer exists or belongs to a foreign
process.
In the daemon process, drop privileges, if possible and applicable.
From the daemon process, notify the original
process started that initialization is complete. This can be
implemented via an unnamed pipe or similar communication
channel that is created before the first
fork() and hence available in both the
original and the daemon process.
Call exit() in the
original process. The process that invoked the daemon must be
able to rely on that this exit() happens
after initialization is complete and all external
communication channels are established and
accessible.
The BSD daemon() function should not
be used, as it implements only a subset of these steps.
A daemon that needs to provide compatibility with SysV systems should implement the scheme pointed out above. However, it is recommended to make this behavior optional and configurable via a command line argument to ease debugging as well as to simplify integration into systems using systemd.
Modern services for Linux should be implemented as new-style daemons. This makes it easier to supervise and control them at runtime and simplifies their implementation.
For developing a new-style daemon, none of the initialization steps recommended for SysV daemons need to be implemented. New-style init systems such as systemd make all of them redundant. Moreover, since some of these steps interfere with process monitoring, file descriptor passing and other functionality of the init system, it is recommended not to execute them when run as new-style service.
Note that new-style init systems guarantee execution of daemon processes in a clean process context: it is
guaranteed that the environment block is sanitized, that the signal handlers and mask is reset and that no
left-over file descriptors are passed. Daemons will be executed in their own session, with standard input
connected to /dev/null and standard output/error connected to the
systemd-journald.service(8)
logging service, unless otherwise configured. The umask is reset.
It is recommended for new-style daemons to implement the following:
If SIGTERM is received,
shut down the daemon and exit cleanly.
If SIGHUP is received,
reload the configuration files, if this
applies.
Provide a correct exit code from the main daemon process, as this is used by the init system to detect service errors and problems. It is recommended to follow the exit code scheme as defined in the LSB recommendations for SysV init scripts.
If possible and applicable, expose the daemon's control interface via the D-Bus IPC system and grab a bus name as last step of initialization.
For integration in systemd, provide a
.service unit file that carries
information about starting, stopping and otherwise maintaining
the daemon. See
systemd.service(5)
for details.
As much as possible, rely on the init system's functionality to limit the access of the daemon to files, services and other resources, i.e. in the case of systemd, rely on systemd's resource limit control instead of implementing your own, rely on systemd's privilege dropping code instead of implementing it in the daemon, and similar. See systemd.exec(5) for the available controls.
If D-Bus is used, make your daemon bus-activatable by supplying a D-Bus service activation configuration file. This has multiple advantages: your daemon may be started lazily on-demand; it may be started in parallel to other daemons requiring it — which maximizes parallelization and boot-up speed; your daemon can be restarted on failure without losing any bus requests, as the bus queues requests for activatable services. See below for details.
If your daemon provides services to other local processes or remote clients via a socket, it should be made socket-activatable following the scheme pointed out below. Like D-Bus activation, this enables on-demand starting of services as well as it allows improved parallelization of service start-up. Also, for state-less protocols (such as syslog, DNS), a daemon implementing socket-based activation can be restarted without losing a single request. See below for details.
If applicable, a daemon should notify the init system about startup completion or status updates via the sd_notify(3) interface.
Instead of using the
syslog() call to log directly to the
system syslog service, a new-style daemon may choose to simply
log to standard error via fprintf(),
which is then forwarded to syslog by the init system. If log
levels are necessary, these can be encoded by prefixing
individual log lines with strings like
"<4>" (for log level 4 "WARNING" in the
syslog priority scheme), following a similar style as the
Linux kernel's printk() level system. For
details, see
sd-daemon(3)
and
systemd.exec(5).
These recommendations are similar but not identical to the Apple MacOS X Daemon Requirements.
New-style init systems provide multiple additional
mechanisms to activate services, as detailed below. It is common
that services are configured to be activated via more than one
mechanism at the same time. An example for systemd:
bluetoothd.service might get activated either
when Bluetooth hardware is plugged in, or when an application
accesses its programming interfaces via D-Bus. Or, a print server
daemon might get activated when traffic arrives at an IPP port, or
when a printer is plugged in, or when a file is queued in the
printer spool directory. Even for services that are intended to be
started on system bootup unconditionally, it is a good idea to
implement some of the various activation schemes outlined below,
in order to maximize parallelization. If a daemon implements a
D-Bus service or listening socket, implementing the full bus and
socket activation scheme allows starting of the daemon with its
clients in parallel (which speeds up boot-up), since all its
communication channels are established already, and no request is
lost because client requests will be queued by the bus system (in
case of D-Bus) or the kernel (in case of sockets) until the
activation is completed.
Old-style daemons are usually activated exclusively on boot (and manually by the administrator) via SysV init scripts, as detailed in the LSB Linux Standard Base Core Specification. This method of activation is supported ubiquitously on Linux init systems, both old-style and new-style systems. Among other issues, SysV init scripts have the disadvantage of involving shell scripts in the boot process. New-style init systems generally employ updated versions of activation, both during boot-up and during runtime and using more minimal service description files.
In systemd, if the developer or administrator wants to
make sure that a service or other unit is activated
automatically on boot, it is recommended to place a symlink to
the unit file in the .wants/ directory of
either multi-user.target or
graphical.target, which are normally used
as boot targets at system startup. See
systemd.unit(5)
for details about the .wants/ directories,
and
systemd.special(7)
for details about the two boot targets.
In order to maximize the possible parallelization and robustness and simplify configuration and development, it is recommended for all new-style daemons that communicate via listening sockets to employ socket-based activation. In a socket-based activation scheme, the creation and binding of the listening socket as primary communication channel of daemons to local (and sometimes remote) clients is moved out of the daemon code and into the init system. Based on per-daemon configuration, the init system installs the sockets and then hands them off to the spawned process as soon as the respective daemon is to be started. Optionally, activation of the service can be delayed until the first inbound traffic arrives at the socket to implement on-demand activation of daemons. However, the primary advantage of this scheme is that all providers and all consumers of the sockets can be started in parallel as soon as all sockets are established. In addition to that, daemons can be restarted with losing only a minimal number of client transactions, or even any client request at all (the latter is particularly true for state-less protocols, such as DNS or syslog), because the socket stays bound and accessible during the restart, and all requests are queued while the daemon cannot process them.
New-style daemons which support socket activation must be able to receive their sockets from the init system instead of creating and binding them themselves. For details about the programming interfaces for this scheme provided by systemd, see sd_listen_fds(3) and sd-daemon(3). For details about porting existing daemons to socket-based activation, see below. With minimal effort, it is possible to implement socket-based activation in addition to traditional internal socket creation in the same codebase in order to support both new-style and old-style init systems from the same daemon binary.
systemd implements socket-based activation via
.socket units, which are described in
systemd.socket(5).
When configuring socket units for socket-based activation, it is
essential that all listening sockets are pulled in by the
special target unit sockets.target. It is
recommended to place a
WantedBy=sockets.target directive in the
"[Install]" section to automatically add such a
dependency on installation of a socket unit. Unless
DefaultDependencies=no is set, the necessary
ordering dependencies are implicitly created for all socket
units. For more information about
sockets.target, see
systemd.special(7).
It is not necessary or recommended to place any additional
dependencies on socket units (for example from
multi-user.target or suchlike) when one is
installed in sockets.target.
When the D-Bus IPC system is used for communication with
clients, new-style daemons should employ bus activation so that
they are automatically activated when a client application
accesses their IPC interfaces. This is configured in D-Bus
service files (not to be confused with systemd service unit
files!). To ensure that D-Bus uses systemd to start-up and
maintain the daemon, use the SystemdService=
directive in these service files to configure the matching
systemd service for a D-Bus service. e.g.: For a D-Bus service
whose D-Bus activation file is named
org.freedesktop.RealtimeKit.service, make
sure to set
SystemdService=rtkit-daemon.service in that
file to bind it to the systemd service
rtkit-daemon.service. This is needed to
make sure that the daemon is started in a race-free fashion when
activated via multiple mechanisms simultaneously.
Often, daemons that manage a particular type of hardware
should be activated only when the hardware of the respective
kind is plugged in or otherwise becomes available. In a
new-style init system, it is possible to bind activation to
hardware plug/unplug events. In systemd, kernel devices
appearing in the sysfs/udev device tree can be exposed as units
if they are tagged with the string "systemd".
Like any other kind of unit, they may then pull in other units
when activated (i.e. plugged in) and thus implement device-based
activation. systemd dependencies may be encoded in the udev
database via the SYSTEMD_WANTS= property. See
systemd.device(5)
for details. Often, it is nicer to pull in services from devices
only indirectly via dedicated targets. Example: Instead of
pulling in bluetoothd.service from all the
various bluetooth dongles and other hardware available, pull in
bluetooth.target from them and
bluetoothd.service from that target. This
provides for nicer abstraction and gives administrators the
option to enable bluetoothd.service via
controlling a bluetooth.target.wants/
symlink uniformly with a command like enable
of
systemctl(1)
instead of manipulating the udev ruleset.
Often, runtime of daemons processing spool files or
directories (such as a printing system) can be delayed until
these file system objects change state, or become non-empty.
New-style init systems provide a way to bind service activation
to file system changes. systemd implements this scheme via
path-based activation configured in .path
units, as outlined in
systemd.path(5).
Some daemons that implement clean-up jobs that are
intended to be executed in regular intervals benefit from
timer-based activation. In systemd, this is implemented via
.timer units, as described in
systemd.timer(5).
Other forms of activation have been suggested and
implemented in some systems. However, there are often simpler or
better alternatives, or they can be put together of combinations
of the schemes above. Example: Sometimes, it appears useful to
start daemons or .socket units when a
specific IP address is configured on a network interface,
because network sockets shall be bound to the address. However,
an alternative to implement this is by utilizing the Linux
IP_FREEBIND socket option, as accessible
via FreeBind=yes in systemd socket files (see
systemd.socket(5)
for details). This option, when enabled, allows sockets to be
bound to a non-local, not configured IP address, and hence
allows bindings to a particular IP address before it actually
becomes available, making such an explicit dependency to the
configured address redundant. Another often suggested trigger
for service activation is low system load. However, here too, a
more convincing approach might be to make proper use of features
of the operating system, in particular, the CPU or I/O scheduler
of Linux. Instead of scheduling jobs from userspace based on
monitoring the OS scheduler, it is advisable to leave the
scheduling of processes to the OS scheduler itself. systemd
provides fine-grained access to the CPU and I/O schedulers. If a
process executed by the init system shall not negatively impact
the amount of CPU or I/O bandwidth available to other processes,
it should be configured with
CPUSchedulingPolicy=idle and/or
IOSchedulingClass=idle. Optionally, this may
be combined with timer-based activation to schedule background
jobs during runtime and with minimal impact on the system, and
remove it from the boot phase itself.
When writing systemd unit files, it is recommended to consider the following suggestions:
If possible, do not use the
Type=forking setting in service files. But
if you do, make sure to set the PID file path using
PIDFile=. See
systemd.service(5)
for details.
If your daemon registers a D-Bus name on the
bus, make sure to use Type=dbus in the
service file if possible.
Make sure to set a good human-readable
description string with
Description=.
Do not disable
DefaultDependencies=, unless you really
know what you do and your unit is involved in early boot or
late system shutdown.
Normally, little if any dependencies should need to be defined explicitly. However, if you do configure explicit dependencies, only refer to unit names listed on systemd.special(7) or names introduced by your own package to keep the unit file operating system-independent.
Make sure to include an
"[Install]" section including installation
information for the unit file. See
systemd.unit(5)
for details. To activate your service on boot, make sure to
add a WantedBy=multi-user.target or
WantedBy=graphical.target directive. To
activate your socket on boot, make sure to add
WantedBy=sockets.target. Usually, you also
want to make sure that when your service is installed, your
socket is installed too, hence add
Also=foo.socket in your service file
foo.service, for a hypothetical program
foo.
At the build installation time (e.g. make install during package build), packages are recommended to install their systemd unit files in the directory returned by pkg-config systemd --variable=systemdsystemunitdir (for system services) or pkg-config systemd --variable=systemduserunitdir (for user services). This will make the services available in the system on explicit request but not activate them automatically during boot. Optionally, during package installation (e.g. rpm -i by the administrator), symlinks should be created in the systemd configuration directories via the enable command of the systemctl(1) tool to activate them automatically on boot.
Packages using autoconf(1) are recommended to use a configure script excerpt like the following to determine the unit installation path during source configuration:
PKG_PROG_PKG_CONFIG
AC_ARG_WITH([systemdsystemunitdir],
[AS_HELP_STRING([--with-systemdsystemunitdir=DIR], [Directory for systemd service files])],,
[with_systemdsystemunitdir=auto])
AS_IF([test "x$with_systemdsystemunitdir" = "xyes" -o "x$with_systemdsystemunitdir" = "xauto"], [
def_systemdsystemunitdir=$($PKG_CONFIG --variable=systemdsystemunitdir systemd)
AS_IF([test "x$def_systemdsystemunitdir" = "x"],
[AS_IF([test "x$with_systemdsystemunitdir" = "xyes"],
[AC_MSG_ERROR([systemd support requested but pkg-config unable to query systemd package])])
with_systemdsystemunitdir=no],
[with_systemdsystemunitdir="$def_systemdsystemunitdir"])])
AS_IF([test "x$with_systemdsystemunitdir" != "xno"],
[AC_SUBST([systemdsystemunitdir], [$with_systemdsystemunitdir])])
AM_CONDITIONAL([HAVE_SYSTEMD], [test "x$with_systemdsystemunitdir" != "xno"])This snippet allows automatic installation of the unit files on systemd machines, and optionally allows their installation even on machines lacking systemd. (Modification of this snippet for the user unit directory is left as an exercise for the reader.)
Additionally, to ensure that
make distcheck continues to
work, it is recommended to add the following
to the top-level Makefile.am
file in
automake(1)-based
projects:
DISTCHECK_CONFIGURE_FLAGS = \ --with-systemdsystemunitdir=$$dc_install_base/$(systemdsystemunitdir)
Finally, unit files should be installed in the system with an automake excerpt like the following:
if HAVE_SYSTEMD systemdsystemunit_DATA = \ foobar.socket \ foobar.service endif
In the
rpm(8)
.spec file, use snippets like the following
to enable/disable the service during
installation/deinstallation. This makes use of the RPM macros
shipped along systemd. Consult the packaging guidelines of your
distribution for details and the equivalent for other package
managers.
At the top of the file:
BuildRequires: systemd
%{?systemd_requires}And as scriptlets, further down:
%post %systemd_post foobar.service foobar.socket %preun %systemd_preun foobar.service foobar.socket %postun %systemd_postun
If the service shall be restarted during upgrades, replace
the "%postun" scriptlet above with the
following:
%postun %systemd_postun_with_restart foobar.service
Note that "%systemd_post" and
"%systemd_preun" expect the names of all units
that are installed/removed as arguments, separated by spaces.
"%systemd_postun" expects no arguments.
"%systemd_postun_with_restart" expects the
units to restart as arguments.
To facilitate upgrades from a package version that shipped only SysV init scripts to a package version that ships both a SysV init script and a native systemd service file, use a fragment like the following:
%triggerun -- foobar < 0.47.11-1 if /sbin/chkconfig --level 5 foobar ; then /bin/systemctl --no-reload enable foobar.service foobar.socket >/dev/null 2>&1 || : fi
Where 0.47.11-1 is the first package version that includes the native unit file. This fragment will ensure that the first time the unit file is installed, it will be enabled if and only if the SysV init script is enabled, thus making sure that the enable status is not changed. Note that chkconfig is a command specific to Fedora which can be used to check whether a SysV init script is enabled. Other operating systems will have to use different commands here.
Since new-style init systems such as systemd are compatible with traditional SysV init systems, it is not strictly necessary to port existing daemons to the new style. However, doing so offers additional functionality to the daemons as well as simplifying integration into new-style init systems.
To port an existing SysV compatible daemon, the following steps are recommended:
If not already implemented, add an optional command line switch to the daemon to disable daemonization. This is useful not only for using the daemon in new-style init systems, but also to ease debugging.
If the daemon offers interfaces to other
software running on the local system via local
AF_UNIX sockets, consider implementing
socket-based activation (see above). Usually, a minimal patch is
sufficient to implement this: Extend the socket creation in the
daemon code so that
sd_listen_fds(3)
is checked for already passed sockets first. If sockets are
passed (i.e. when sd_listen_fds() returns a
positive value), skip the socket creation step and use the
passed sockets. Secondly, ensure that the file system socket
nodes for local AF_UNIX sockets used in the
socket-based activation are not removed when the daemon shuts
down, if sockets have been passed. Third, if the daemon normally
closes all remaining open file descriptors as part of its
initialization, the sockets passed from the init system must be
spared. Since new-style init systems guarantee that no left-over
file descriptors are passed to executed processes, it might be a
good choice to simply skip the closing of all remaining open
file descriptors if sockets are passed.
Write and install a systemd unit file for the service (and the sockets if socket-based activation is used, as well as a path unit file, if the daemon processes a spool directory), see above for details.
If the daemon exposes interfaces via D-Bus, write and install a D-Bus activation file for the service, see above for details.
It is recommended to follow the general guidelines for placing package files, as discussed in file-hierarchy(7).