sd_event_add_child, sd_event_add_child_pidfd, sd_event_source_get_child_pid, sd_event_source_get_child_pidfd, sd_event_source_get_child_pidfd_own, sd_event_source_set_child_pidfd_own, sd_event_source_get_child_process_own, sd_event_source_set_child_process_own, sd_event_source_send_child_signal, sd_event_child_handler_t — Add a child process state change event source to an event loop
#include <systemd/sd-event.h>
typedef struct sd_event_source sd_event_source;
typedef int (*sd_event_child_handler_t)( | sd_event_source *s, |
const siginfo_t *si, | |
void *userdata) ; |
int sd_event_add_child( | sd_event *event, |
sd_event_source **source, | |
pid_t pid, | |
int options, | |
sd_event_child_handler_t handler, | |
void *userdata) ; |
int sd_event_add_child_pidfd( | sd_event *event, |
sd_event_source **source, | |
int pidfd, | |
int options, | |
sd_event_child_handler_t handler, | |
void *userdata) ; |
int sd_event_source_get_child_pid( | sd_event_source *source, |
pid_t *pid) ; |
int sd_event_source_get_child_pidfd( | sd_event_source *source) ; |
int sd_event_source_get_child_pidfd_own( | sd_event_source *source) ; |
int sd_event_source_set_child_pidfd_own( | sd_event_source *source, |
int own) ; |
int sd_event_source_get_child_process_own( | sd_event_source *source) ; |
int sd_event_source_set_child_process_own( | sd_event_source *source, |
int own) ; |
int sd_event_source_send_child_signal( | sd_event_source *source, |
int sig, | |
const siginfo_t *info, | |
unsigned flags) ; |
sd_event_add_child()
adds a new child process state change event source to an
event loop. The event loop object is specified in the event
parameter, the event
source object is returned in the source
parameter. The pid
parameter specifies the PID of the process to watch, which must be a direct child process of the invoking
process. The options
parameter determines which state changes will be watched for.
It must contain an OR-ed mask of WEXITED
(watch for the child process terminating),
WSTOPPED
(watch for the child process being stopped by a signal), and
WCONTINUED
(watch for the child process being resumed by a signal). See
waitid(2)
for further information.
The handler
must be a function to call when the process changes state or
NULL
. The handler function will be passed the userdata
pointer, which may be chosen freely by the caller. The handler also receives a pointer to a
siginfo_t structure containing information about the child process event. The
handler may return negative to signal an error (see below), other return values are ignored. If
handler
is NULL
, a default handler that calls
sd_event_exit(3) will be
used.
Only a single handler may be installed for a specific child process. The handler is enabled for a
single event (SD_EVENT_ONESHOT
), but this may be changed with
sd_event_source_set_enabled(3).
If the handler function returns a negative error code, it will either be disabled after the invocation,
even if the SD_EVENT_ON
mode was requested before, or it will cause the loop to
terminate, see
sd_event_source_set_exit_on_failure(3).
To destroy an event source object use
sd_event_source_unref(3),
but note that the event source is only removed from the event loop
when all references to the event source are dropped. To make sure
an event source does not fire anymore, even when there's still a
reference to it kept, consider setting the event source to
SD_EVENT_OFF
with
sd_event_source_set_enabled(3).
The SIGCHLD
signal must be blocked in all threads before this function is
called (using sigprocmask(2) or
pthread_sigmask(3)).
If the second parameter of sd_event_add_child()
is passed as
NULL
no reference to the event source object is returned. In this case the event
source is considered "floating", and will be destroyed implicitly when the event loop itself is
destroyed.
Note that the handler
function is
invoked at a time where the child process is not reaped yet (and
thus still is exposed as a zombie process by the kernel). However,
the child will be reaped automatically after the function
returns. Child processes for which no child process state change
event sources are installed will not be reaped by the event loop
implementation.
If the handler
parameter to sd_event_add_child()
is
NULL
, and the event source fires, this will be considered a request to exit the
event loop. In this case, the userdata
parameter, cast to an integer, is passed as
the exit code parameter to
sd_event_exit(3).
If both a child process state change event source and a
SIGCHLD
signal event source is installed in
the same event loop, the configured event source priorities decide
which event source is dispatched first. If the signal handler is
processed first, it should leave the child processes for which
child process state change event sources are installed unreaped.
sd_event_add_child_pidfd()
is similar to
sd_event_add_child()
but takes a file descriptor referencing the process ("pidfd")
instead of the numeric PID. A suitable file descriptor may be acquired via pidfd_open(2) and
related calls. The passed file descriptor is not closed when the event source is freed again, unless
sd_event_source_set_child_pidfd_own()
is used to turn this behaviour on. Note that
regardless which of sd_event_add_child()
and
sd_event_add_child_pidfd()
is used for allocating an event source, the watched
process has to be a direct child process of the invoking process. Also in both cases
SIGCHLD
has to be blocked in the invoking process.
sd_event_source_get_child_pid()
retrieves the configured PID of a child process state change event
source created previously with
sd_event_add_child()
. It takes the event
source object as the source
parameter and a
pointer to a pid_t variable to return the process ID
in.
sd_event_source_get_child_pidfd()
retrieves the file descriptor referencing
the watched process ("pidfd") if this functionality is available. On kernels that support the concept the
event loop will make use of pidfds to watch child processes, regardless if the individual event sources
are allocated via sd_event_add_child()
or
sd_event_add_child_pidfd()
. If the latter call was used to allocate the event
source, this function returns the file descriptor used for allocation. On kernels that do not support the
pidfd concept this function will fail with EOPNOTSUPP
. This call takes the event
source object as the source
parameter and returns the numeric file descriptor.
sd_event_source_get_child_pidfd_own()
may be used to query whether the pidfd
the event source encapsulates shall be closed when the event source is freed. This function returns zero
if the pidfd shall be left open, and positive if it shall be closed automatically. By default this
setting defaults to on if the event source was allocated via sd_event_add_child()
and off if it was allocated via sd_event_add_child_pidfd()
. The
sd_event_source_set_child_pidfd_own()
function may be used to change the setting and
takes a boolean parameter with the new setting.
sd_event_source_get_child_process_own()
may be used to query whether the
process the event source watches shall be killed (with SIGKILL
) and reaped when the
event source is freed. This function returns zero if the process shell be left running, and positive if
it shall be killed and reaped automatically. By default this setting defaults to off. The
sd_event_source_set_child_process_own()
function may be used to change the setting
and takes a boolean parameter with the new setting. Note that currently if the calling process is
terminated abnormally the watched process might survive even thought the event source ceases to
exist. This behaviour might change eventually.
sd_event_source_send_child_signal()
may be used to send a UNIX signal to the
watched process. If the pidfd concept is supported in the kernel, this is implemented via pidfd_send_signal(2)
and otherwise via rt_sigqueueinfo(2)
(or via kill(2) in case
info
is NULL
). The specified parameters match those of these
underlying system calls, except that the info
is never modified (and is thus
declared constant). Like for the underlying system calls, the flags
parameter
currently must be zero.
On success, these functions return 0 or a positive integer. On failure, they return a negative errno-style error code.
Returned errors may indicate the following problems:
-ENOMEM
¶Not enough memory to allocate an object.
-EINVAL
¶An invalid argument has been passed. This includes
specifying an empty mask in options
or a mask
which contains values different than a combination of
WEXITED
, WSTOPPED
, and
WCONTINUED
.
-EBUSY
¶A handler is already installed for this child process, or
SIGCHLD
is not blocked.
-ESTALE
¶The event loop is already terminated.
-ECHILD
¶The event loop has been created in a different process, library or module instance.
-EDOM
¶The passed event source is not a child process event source.
-EOPNOTSUPP
¶A pidfd was requested but the kernel does not support this concept.
Functions described here are available as a shared
library, which can be compiled against and linked to with the
libsystemd
pkg-config(1)
file.
The code described here uses
getenv(3),
which is declared to be not multi-thread-safe. This means that the code calling the functions described
here must not call
setenv(3)
from a parallel thread. It is recommended to only do calls to setenv()
from an early phase of the program when no other threads have been started.
Example 1. Exit loop when the child terminates
/* SPDX-License-Identifier: MIT-0 */ #include <assert.h> #include <stdio.h> #include <unistd.h> #include <sd-event.h> int main(int argc, char **argv) { pid_t pid = fork(); assert(pid >= 0); /* SIGCHLD signal must be blocked for sd_event_add_child to work */ sigset_t ss; sigemptyset(&ss); sigaddset(&ss, SIGCHLD); sigprocmask(SIG_BLOCK, &ss, NULL); if (pid == 0) /* child */ sleep(1); else { /* parent */ sd_event *e = NULL; int r; /* Create the default event loop */ sd_event_default(&e); assert(e); /* We create a floating child event source (attached to 'e'). * The default handler will be called with 666 as userdata, which * will become the exit value of the loop. */ r = sd_event_add_child(e, NULL, pid, WEXITED, NULL, (void*) 666); assert(r >= 0); r = sd_event_loop(e); assert(r == 666); sd_event_unref(e); } return 0; }
systemd(1), sd-event(3), sd_event_new(3), sd_event_now(3), sd_event_add_io(3), sd_event_add_time(3), sd_event_add_signal(3), sd_event_add_inotify(3), sd_event_add_defer(3), sd_event_source_set_enabled(3), sd_event_source_set_priority(3), sd_event_source_set_userdata(3), sd_event_source_set_description(3), sd_event_source_set_floating(3), waitid(2), sigprocmask(2), pthread_sigmask(3), pidfd_open(2), pidfd_send_signal(2), rt_sigqueueinfo(2), kill(2)