NAME
sigaction
—
software signal facilities
LIBRARY
library “libc”
SYNOPSIS
#include
<signal.h>
struct sigaction { void (*sa_handler)(int); void (*sa_sigaction)(int, siginfo_t *, void *); int sa_flags; /* see signal options below */ sigset_t sa_mask; /* signal mask to apply */ };
int
sigaction
(int sig,
const struct sigaction * restrict act,
struct sigaction * restrict oact);
DESCRIPTION
The system defines a set of signals that may be delivered to a process. Signal delivery resembles the occurrence of a hardware interrupt: the signal is normally blocked from further occurrence, the current thread context is saved, and a new one is built. A process may specify a handler to which a signal is delivered, or specify that a signal is to be ignored. A process may also specify that a default action is to be taken by the system when a signal occurs. A signal may also be blocked for a thread, in which case it will not be delivered to that thread until it is unblocked. The action to be taken on delivery is determined at the time of delivery. Normally, signal handlers execute on the current stack of the thread. This may be changed, on a per-handler basis, so that signals are taken on a special signal stack.Signal routines normally execute with the signal that caused their invocation blocked, but other signals may yet occur. A global signal mask defines the set of signals currently blocked from delivery to a thread. The signal mask for a thread is initialized from that of its parent (normally empty). It may be changed with a sigprocmask(2) or pthread_sigmask(3) call, or when a signal is delivered to the thread.
When a signal condition arises for a process or thread, the signal is added to a set of signals pending for the process or thread. Whether the signal is directed at the process in general or at a specific thread depends on how it is generated. For signals directed at a specific thread, if the signal is not currently blocked by the thread then it is delivered to the thread. For signals directed at the process, if the signal is not currently blocked by all threads then it is delivered to one thread that does not have it blocked (the selection of which is unspecified). Signals may be delivered any time a thread enters the operating system (e.g., during a system call, page fault or trap, or clock interrupt). If multiple signals are ready to be delivered at the same time, any signals that could be caused by traps are delivered first. Additional signals may be processed at the same time, with each appearing to interrupt the handlers for the previous signals before their first instructions. The set of pending signals is returned by the sigpending(2) system call. When a caught signal is delivered, the current state of the thread is saved, a new signal mask is calculated (as described below), and the signal handler is invoked. The call to the handler is arranged so that if the signal handling routine returns normally the thread will resume execution in the context from before the signal's delivery. If the thread wishes to resume in a different context, then it must arrange to restore the previous context itself.
When a signal is delivered to a thread a new signal mask is installed for the duration of the process' signal handler (or until a sigprocmask(2) system call is made). This mask is formed by taking the union of the current signal mask set, the signal to be delivered, and the signal mask associated with the handler to be invoked.
The
sigaction
()
system call assigns an action for a signal specified by
sig. If act is non-NULL, it
specifies an action (SIG_DFL
,
SIG_IGN
, or a handler routine) and mask to be used
when delivering the specified signal. If oact is
non-NULL, the previous handling information for the signal is returned to
the user.
The above declaration of struct sigaction is
not literal. It is provided only to list the accessible members. See
<sys/signal.h>
for the
actual definition. In particular, the storage occupied by
sa_handler and sa_sigaction
overlaps, and it is nonsensical for an application to attempt to use both
simultaneously.
Once a signal handler is installed, it normally
remains installed until another
sigaction
()
system call is made, or an
execve(2) is performed. A signal-specific default action may be reset
by setting sa_handler to
SIG_DFL
. The defaults are process termination,
possibly with core dump; no action; stopping the process; or continuing the
process. See the signal list below for each signal's default action. If
sa_handler is SIG_DFL
, the
default action for the signal is to discard the signal, and if a signal is
pending, the pending signal is discarded even if the signal is masked. If
sa_handler is set to SIG_IGN
current and pending instances of the signal are ignored and discarded.
Options may be specified by setting sa_flags. The meaning of the various bits is as follows:
SA_NOCLDSTOP
- If this bit is set when installing a catching function for the
SIGCHLD
signal, theSIGCHLD
signal will be generated only when a child process exits, not when a child process stops. SA_NOCLDWAIT
- If this bit is set when calling
sigaction
() for theSIGCHLD
signal, the system will not create zombie processes when children of the calling process exit. If the calling process subsequently issues a wait(2) (or equivalent), it blocks until all of the calling process's child processes terminate, and then returns a value of -1 with errno set toECHILD
. The same effect of avoiding zombie creation can also be achieved by setting sa_handler forSIGCHLD
toSIG_IGN
. SA_ONSTACK
- If this bit is set, the system will deliver the signal to the process on a signal stack, specified by each thread with sigaltstack(2).
SA_NODEFER
- If this bit is set, further occurrences of the delivered signal are not masked during the execution of the handler.
SA_RESETHAND
- If this bit is set, the handler is reset back to
SIG_DFL
at the moment the signal is delivered. SA_RESTART
- See paragraph below.
SA_SIGINFO
- If this bit is set, the handler function is assumed to be pointed to by
the sa_sigaction member of struct
sigaction and should match the prototype shown above or as below in
EXAMPLES. This bit should not be set
when assigning
SIG_DFL
orSIG_IGN
.
If a signal is caught during the system calls listed below, the
call may be forced to terminate with the error
EINTR
, the call may return with a data transfer
shorter than requested, or the call may be restarted. Restart of pending
calls is requested by setting the SA_RESTART
bit in
sa_flags. The affected system calls include
open(2), read(2),
write(2),
sendto(2),
recvfrom(2),
sendmsg(2) and
recvmsg(2) on a communications channel or a slow device (such as a
terminal, but not a regular file) and during a
wait(2) or
ioctl(2). However, calls that have already committed are not
restarted, but instead return a partial success (for example, a short read
count).
After a pthread_create(3) the signal mask is inherited by the new thread and the set of pending signals and the signal stack for the new thread are empty.
After a fork(2) or vfork(2) all signals, the signal mask, the signal stack, and the restart/interrupt flags are inherited by the child.
The execve(2) system call reinstates the default action for all signals which were caught and resets all signals to be caught on the user stack. Ignored signals remain ignored; the signal mask remains the same; signals that restart pending system calls continue to do so.
The following is a list of all signals with names as in the
include file <signal.h>
:
NAME | Default Action | Description |
SIGHUP |
terminate process | terminal line hangup |
SIGINT |
terminate process | interrupt program |
SIGQUIT |
create core image | quit program |
SIGILL |
create core image | illegal instruction |
SIGTRAP |
create core image | trace trap |
SIGABRT |
create core image | abort(3) call (formerly SIGIOT ) |
SIGEMT |
create core image | emulate instruction executed |
SIGFPE |
create core image | floating-point exception |
SIGKILL |
terminate process | kill program |
SIGBUS |
create core image | bus error |
SIGSEGV |
create core image | segmentation violation |
SIGSYS |
create core image | non-existent system call invoked |
SIGPIPE |
terminate process | write on a pipe with no reader |
SIGALRM |
terminate process | real-time timer expired |
SIGTERM |
terminate process | software termination signal |
SIGURG |
discard signal | urgent condition present on socket |
SIGSTOP |
stop process | stop (cannot be caught or ignored) |
SIGTSTP |
stop process | stop signal generated from keyboard |
SIGCONT |
discard signal | continue after stop |
SIGCHLD |
discard signal | child status has changed |
SIGTTIN |
stop process | background read attempted from control terminal |
SIGTTOU |
stop process | background write attempted to control terminal |
SIGIO |
discard signal | I/O is possible on a descriptor (see fcntl(2)) |
SIGXCPU |
terminate process | cpu time limit exceeded (see setrlimit(2)) |
SIGXFSZ |
terminate process | file size limit exceeded (see setrlimit(2)) |
SIGVTALRM |
terminate process | virtual time alarm (see setitimer(2)) |
SIGPROF |
terminate process | profiling timer alarm (see setitimer(2)) |
SIGWINCH |
discard signal | window size change |
SIGINFO |
discard signal | status request from keyboard |
SIGUSR1 |
terminate process | user defined signal 1 |
SIGUSR2 |
terminate process | user defined signal 2 |
NOTE
The sa_mask field specified in
act is not allowed to block
SIGKILL
or SIGSTOP
. Any
attempt to do so will be silently ignored.
The following functions are either reentrant or not interruptible by signals and are async-signal safe. Therefore applications may invoke them, without restriction, from signal-catching functions or from a child process after calling fork(2) in a multi-threaded process:
Base Interfaces:
_Exit
(),
_exit
(),
accept
(),
access
(),
alarm
(),
bind
(),
cfgetispeed
(),
cfgetospeed
(),
cfsetispeed
(),
cfsetospeed
(),
chdir
(),
chmod
(),
chown
(),
close
(),
connect
(),
creat
(),
dup
(),
dup2
(),
execl
(),
execle
(),
execv
(),
execve
(),
faccessat
(),
fchdir
(),
fchmod
(),
fchmodat
(),
fchown
(),
fchownat
(),
fcntl
(),
fork
(),
fstat
(),
fstatat
(),
fsync
(),
ftruncate
(),
getegid
(),
geteuid
(),
getgid
(),
getgroups
(),
getpeername
(),
getpgrp
(),
getpid
(),
getppid
(),
getsockname
(),
getsockopt
(),
getuid
(),
kill
(),
link
(),
linkat
(),
listen
(),
lseek
(),
lstat
(),
mkdir
(),
mkdirat
(),
mkfifo
(),
mkfifoat
(),
mknod
(),
mknodat
(),
open
(),
openat
(),
pause
(),
pipe
(),
poll
(),
pselect
(),
pthread_sigmask
(),
raise
(),
read
(),
readlink
(),
readlinkat
(),
recv
(),
recvfrom
(),
recvmsg
(),
rename
(),
renameat
(),
rmdir
(),
select
(),
send
(),
sendmsg
(),
sendto
(),
setgid
(),
setpgid
(),
setsid
(),
setsockopt
(),
setuid
(),
shutdown
(),
sigaction
(),
sigaddset
(),
sigdelset
(),
sigemptyset
(),
sigfillset
(),
sigismember
(),
signal
(),
sigpending
(),
sigprocmask
(),
sigsuspend
(),
sleep
(),
sockatmark
(),
socket
(),
socketpair
(),
stat
(),
symlink
(),
symlinkat
(),
tcdrain
(),
tcflow
(),
tcflush
(),
tcgetattr
(),
tcgetpgrp
(),
tcsendbreak
(),
tcsetattr
(),
tcsetpgrp
(),
time
(),
times
(),
umask
(),
uname
(),
unlink
(),
unlinkat
(),
utime
(),
wait
(),
waitpid
(),
write
().
X/Open Systems Interfaces:
sigpause
(),
sigset
(),
utimes
().
Realtime Interfaces:
aio_error
(),
clock_gettime
(),
timer_getoverrun
(),
aio_return
(),
fdatasync
(),
sigqueue
(),
timer_gettime
(),
aio_suspend
(),
sem_post
(),
timer_settime
().
Base Interfaces not specified as async-signal safe by POSIX:
fpathconf
(),
pathconf
(),
sysconf
().
Base Interfaces not specified as async-signal safe by POSIX, but planned to be:
ffs
(),
htonl
(),
htons
(),
memccpy
(),
memchr
(),
memcmp
(),
memcpy
(),
memmove
(),
memset
(),
ntohl
(),
ntohs
(),
stpcpy
(),
stpncpy
(),
strcat
(),
strchr
(),
strcmp
(),
strcpy
(),
strcspn
(),
strlen
(),
strncat
(),
strncmp
(),
strncpy
(),
strnlen
(),
strpbrk
(),
strrchr
(),
strspn
(),
strstr
(),
strtok_r
(),
wcpcpy
(),
wcpncpy
(),
wcscat
(),
wcschr
(),
wcscmp
(),
wcscpy
(),
wcscspn
(),
wcslen
(),
wcsncat
(),
wcsncmp
(),
wcsncpy
(),
wcsnlen
(),
wcspbrk
(),
wcsrchr
(),
wcsspn
(),
wcsstr
(),
wcstok
(),
wmemchr
(),
wmemcmp
(),
wmemcpy
(),
wmemmove
(),
wmemset
().
Extension Interfaces:
accept4
(),
bindat
(),
closefrom
(),
connectat
(),
eaccess
(),
ffsl
(),
ffsll
(),
flock
(),
fls
(),
flsl
(),
flsll
(),
futimesat
(),
pipe2
(),
strlcat
().
strlcpy
(),
strsep
().
In addition, reading or writing errno is async-signal safe.
All functions not in the above lists are considered to be unsafe with respect to signals. That is to say, the behaviour of such functions is undefined when they are called from a signal handler that interrupted an unsafe function. In general though, signal handlers should do little more than set a flag; most other actions are not safe.
Also, it is good practice to make a copy of the global variable errno and restore it before returning from the signal handler. This protects against the side effect of errno being set by functions called from inside the signal handler.
RETURN VALUES
The sigaction
() function returns the
value 0 if successful; otherwise the value -1 is returned and
the global variable errno is set to indicate the
error.
EXAMPLES
There are three possible prototypes the handler may match:
- ANSI C:
- void
handler
(int); - Traditional BSD style:
- void
handler
(int, int code, struct sigcontext *scp); - POSIX
SA_SIGINFO
: - void
handler
(int, siginfo_t *info, ucontext_t *uap);
The handler function should match the
SA_SIGINFO
prototype if the
SA_SIGINFO
bit is set in
sa_flags. It then should be pointed to by the
sa_sigaction member of struct
sigaction. Note that you should not assign
SIG_DFL
or SIG_IGN
this
way.
If the SA_SIGINFO
flag is not set, the
handler function should match either the ANSI C or traditional
BSD prototype and be pointed to by the
sa_handler member of struct
sigaction. In practice, FreeBSD always sends
the three arguments of the latter and since the ANSI C prototype is a
subset, both will work. The sa_handler member
declaration in FreeBSD include files is that of ANSI
C (as required by POSIX), so a function pointer of a
BSD-style function needs to be casted to compile
without warning. The traditional BSD style is not
portable and since its capabilities are a full subset of a
SA_SIGINFO
handler, its use is deprecated.
The sig argument is the signal number, one
of the SIG...
values from
<signal.h>
.
The code argument of the
BSD-style handler and the
si_code member of the info
argument to a SA_SIGINFO
handler contain a numeric
code explaining the cause of the signal, usually one of the
SI_...
values from
<sys/signal.h>
or codes
specific to a signal, i.e., one of the FPE_...
values for SIGFPE
.
The scp argument to a BSD-style handler points to an instance of struct sigcontext.
The uap argument to a POSIX
SA_SIGINFO
handler points to an instance of
ucontext_t.
ERRORS
The sigaction
() system call will fail and
no new signal handler will be installed if one of the following occurs:
- [
EINVAL
] - The sig argument is not a valid signal number.
- [
EINVAL
] - An attempt is made to ignore or supply a handler for
SIGKILL
orSIGSTOP
.
SEE ALSO
kill(1), kill(2), ptrace(2), setitimer(2), setrlimit(2), sigaltstack(2), sigpending(2), sigprocmask(2), sigsuspend(2), wait(2), fpsetmask(3), setjmp(3), siginfo(3), siginterrupt(3), sigsetops(3), ucontext(3), tty(4)
STANDARDS
The sigaction
() system call is expected to
conform to IEEE Std 1003.1-1990
(“POSIX.1”). The SA_ONSTACK
and
SA_RESTART
flags are Berkeley extensions, as are the
signals, SIGTRAP
, SIGEMT
,
SIGBUS
, SIGSYS
,
SIGURG
, SIGIO
,
SIGXCPU
, SIGXFSZ
,
SIGVTALRM
, SIGPROF
,
SIGWINCH
, and SIGINFO
. Those
signals are available on most BSD-derived systems.
The SA_NODEFER
and
SA_RESETHAND
flags are intended for backwards
compatibility with other operating systems. The
SA_NOCLDSTOP
, and
SA_NOCLDWAIT
flags are featuring options commonly
found in other operating systems. The flags are approved by
Version 2 of the Single UNIX Specification
(“SUSv2”), along with the option to avoid zombie
creation by ignoring SIGCHLD
.