POSIX
PThreads
General Information
Links:
- POSIX Threads Programming, excellent introduction to pthreads, by Blaise Barney, at Lawrence Livermore National Laboratory.
- Advanced Linux Programming Ch 4 — Threads
- POSIX thread (pthread) libraries
- POSIX Threads (wikipedia)
Manual page:
Portability
- Joinable / detachable state
- For portability, always create joinable or detachable threads by setting explicitly the thread attribute (using
pthread_attr_getdetachstate
). This provides portability as not all implementations may create threads as joinable by default.
Linux vs. POSIX manual pages
Most manual pages on pthreads are available as either standard linux manual pages or as extract from the POSIX programmer manual.
For instance:
Both versions are worth reading.
Create threads
See pthread_create(3).
Conditional variables
See
- pthread_cond_init
- pthread_cond_destroy
- pthread_cond_signal
- pthread_cond_broadcast
- pthread_cond_wait
- pthread_cond_timedwait
Note that these functions are NOT signal-async safe (see [1], [2]). They CANNOT be called safely from a async signal handler (like SIGIO signal handler).
Thread-Local Data
- Using thread-specific data area foreseen by POSIX, which requires first creating a key that is later used to set or get thread-specific data attached to that key (see Advanced Linux Programming - Ch 4)
- Using keyword __thread, see http://www.akkadia.org/drepper/tls.pdf (not available in all compiler, not standard C99 [3]).
// Compile this code with : gcc local.c -o local -lpthread
#include <stdio.h>
#include <unistd.h>
#include <pthread.h>
static __thread int myint;
static int globalint = 0;
void * handler(void *arg)
{
myint = ++globalint; // thread unsafe - should use a mutex
while(1) {
printf("myint is %d\n", myint);
sleep(1);
}
}
int main (int argc, char **argv)
{
pthread_t p1,p2;
pthread_create(&p1, NULL, handler, NULL);
pthread_create(&p2, NULL, handler, NULL);
pause();
return 0;
}
Debugging
See Debugging page.
Signals
Manual pages:
Async-Signal Safety
Async-signal safety is similar to thread safety. Since asynchronous signals (like SIGINT or SIGIO) may happen anytime, and this interrupt any function, it might not be same to call the interrupted function again (concurrently) from with the signal handler. POSIX defines the set of system functions that are async-signal safe (see signal(7)).
Note that pthread functions are not in the list, so it is not quite clear how to wake up another suspended thread from within an async-signal handler.
Some ideas:
- Use signals to wake up the suspended thread. This assumes that the suspended thread is waiting on signals (see sigtimedwait(2), sigtimedwait(3)).
- Calling
pthread_cond_signal
is unsafe from signal handler (see [4]), because handler thread may dead-lock if it interrupts a pthread_cond functions (system may use a semaphore internally). Maybe is it possible to suspend the processing of async-signal before so that they do not interrupt these critical sections? (see for instance sigsuspend(3posix)). - Use sem_post(3posix). This function is async-signal safe. The idea would be to have a separate thread that is just waiting on a semaphore, and which is waken up by the signal handler using
sem_post
. The cost of an additional thread seems a bit heavy weight. - Use sigwait. This follows Butenhof's recommendation (see [5]):
- Always use sigwait to work with asynchronous signals within threaded programs.
- An example from [6]:
High priority I/O thread void* thread_I/O (void * arg)
{
int signal;
sigset_t look_for_these; // this contains the signal we wait for
sigemptyset(&look_for_these);
sigaddset(& look_for_these, SIGALARM);
// create the timer
// initialize the timer (SIGALARM will be sent each time the timer expires!)
while (1) {
sigwait(& look_for_these, &signal); // waits for SIGALARM
if ( signal == SIGALARM) {
do_your_device_I/O();
// use global variables to communicate between I/O
// and worker threads
sem_post (& sync_semaphore);
}
}
}
|
Low priority worker thread sem_t sync_semaphore;
int main()
{
pthread_t thread_id;
sigset_t process_mask; // this is the process mask
sigemptyset(&process_mask);
sigaddset(& process_mask, SIGALARM);
pthread_sigmask(SIG_BLOCK, & process_mask, NULL);
sem_init (&sync_semaphore, 0, 0) // semaphore is initially locked!
// create the I/O thread
pthread_create (&thread_id, NULL, thread_I/O, NULL);
while (1) {
sem_wait (& sync_semaphore);
// sync_semaphore is a shared semaphore that allows
//the worker and I/O threads to synchronize their actions!
read_the_data_from_buffer();
do_your_computation();
put_result_in_output_buffer();
// make the I/O thread code as small as possible to reduce jitter.
}
}
|
Some interesting read
- signal(2) versus sigaction(2)
- Some ideas on how to have multiple threads blocking on I/O and being able to cancel them.
- Book — Programming with POSIX Threads, David R. Butenhof, Ed. Addison Wesley