I think this is an implementation flaw in the glibc implementation of POSIX timers. There is certainly no way the
timer_getoverrun function, which is critical for realtime usage, can work in the glibc implementation, since it returns from the kernel the overrun count for the "current" expiration, but when multiple expiration events are running in parallel, "current" makes no sense. There are also serious issues with resource exhaustion and dropped expiration events which make the implementation unusable for realtime purposes. For example, in
struct thread_start_data *td = malloc (sizeof (*td));
/* There is not much we can do if the allocation fails. */
In the Linux man page for
sigevent, you see for
Among the implementation possibilities here are that each timer notification could result in the creation of a new thread, or that a single thread is created to receive all notifications.
The latter is the only choice that could provide correct realtime semantics, but for some reason, glibc did not take this choice.
Here is a possible workaround:
Choose a realtime signal, block that signal before creating any threads, and setup your timer to use that signal with
SIGEV_SIGNAL. Now, create a thread for handling your timer(s), and loop on
sigwaitinfo, then call your handler function each time it returns. This is actually one possible implementation (and the most-correct implementation) of
SIGEV_THREAD which glibc should be using.
Another possibility: there is exactly one synchronization-related, non-syscall-invoking, async-signal-safe function in POSIX:
sem_post. Thus it may be possible to make a signal handler (as opposed to getting the signal from
sigwaitinfo) synchronize with another thread for the purpose of delivering timer events. But I haven't worked out the details, and it seems like it may be difficult or impossible still.