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I was wondering if it is possible to be interrupted by a signal when my program is handling other signal at the same time, I tried to simulate it with:


void sig_output()
    sigset_t set;
    printf("currently blocking:");
    if (sigismember(&set,SIGUSR1))
    return ;

void sig_handler(int sig)
    if (sig==SIGUSR1)
    else if (sig==SIGUSR2)
    return ;

void other_sig_handler(int sig)
    printf("start - other\n");
    if (sig==SIGUSR1)
    else if (sig==SIGUSR2)
    printf("end - other\n");
    return ;

int main()
    struct sigaction a;
    sigset_t set,old;
    //blocking SIGUSR1,SIGUSR2
    printf("blocking SIGUSR1, SIGUSR2\n");
    //adding handles for SIGUSR1,SIGUSR2
    printf("poczatek wysylania \n");
    printf("using sigsuspend\n");
    printf("end of program\n");
    return 0;

and everytime I run this program I get

currently blocking:
blocking SIGUSR1, SIGUSR2
currently blocking:
using sigsuspend
start - other
end - other
end of program

is it always like that?

share|improve this question
It's really processor and OS dependent. In general, many CPUs support different priority levels for interrupts such that a higher priority interrupt could jump in while a lower priority one runs. – TJD Apr 10 '12 at 17:59
POSIX signals are not hardware interrupts, so the processor itself does not come into question here. – torek Apr 10 '12 at 18:02
up vote 6 down vote accepted

Quoting the sigaction(2) manpage:

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 process. The signal mask for a process is initialized from that of its parent (normally empty). It may be changed with a sigprocmask(2) call, or when a signal is delivered to the process.

You can control whether the signal is automatically blocked in its signal handler with the SA_NODEFER flag.

share|improve this answer
Ok, I must missed that bit of info. – Andna Apr 10 '12 at 18:32
It's also worth noting (I think it's not clear from the documentation, although it is quite logical) that the sa_mask you supply to sigaction is a mask of additional signals to block, not a new mask to set. So if you (1) ask to catch signal X with an sa_mask that explicitly blocks signal Y (and implicitly blocks X because you leave SA_NODEFER off), then (2) use sigprocmask to block signal Z, then (3) actually catch a signal X, your handler runs with all of X, Y, and Z blocked. – torek Apr 10 '12 at 19:57
It may not be clear from the Linux documentation; the OS X (via FreeBSD) documentation is pretty clear about how the new mask is formed. – geekosaur Apr 10 '12 at 20:03

The order in which these particular pending signals are delivered is not, as far as I know, defined. However, signals are (mostly; there's an exception for SIGCLD, which is traditionally done by "cheating") "non-queueing", except for real-time signals. The non-queuing aspect means that if you have signal X blocked, and then raise it twice (as you do above for SIGUSR1), you only get it delivered once.

The only ordering documented on at least one system (MacOS) is:

If multiple signals are ready to be delivered at the same time, any signals that
could be caused by traps are delivered first.

(These are things like SIGSEGV and SIGBUS.) In general, you can control the order of delivery by use of the signal blocking masks: unblock any particular signal(s) at some point and those are the ones that can be delivered at that point.

If you do not set SA_NODEFER, the blocking mask at the entry to your handler will always block whatever signal your handler is handling, so that you won't have to worry about recursion.

The special case for SIGCLD comes from System V, which originally implemented this by resetting the handler to SIG_DFL on each SIGCLD delivery. (In fact, SysV did this with all signals, effectively implementing SA_RESETHAND whether you wanted it or not.) The default action was to discard the signal, as if the handler were SIG_IGN. This of course created race conditions when multiple child processes finished before the handler could do its thing. Instead of a block/unblock model, though, the SysV folks put in a hack: at the end of your SIGCLD handler, you would call signal(SIGCLD, handler); to fix up the handler. At that point, if there were any exited children that had not yet been wait-ed for, SysV would immediately generate a new SIGCLD, and your handler would be entered recursively. This made it look as though the signals were queued, without actually queueing them.

For more on Linux signals, see (eg)

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