Take the 2-minute tour ×
Stack Overflow is a question and answer site for professional and enthusiast programmers. It's 100% free, no registration required.

I am running a phread test program until it fails. Here is the main skeleton of the code:

int authSessionListMutexUnlock()
{
    int rc = 0;
    int rc2 = 0;

    rc2 = pthread_mutex_trylock(&mutex);
    ERR_IF( rc2 != EBUSY && rc2 != 0 );

    rc2 = pthread_mutex_unlock(&mutex);
    ERR_IF( rc2 != 0 );

    cleanup:

    return rc;  
}

static void cleanup_handler(void *arg)
{
    int rc = 0;

    (void)arg;

    rc = authSessionListMutexUnlock();
    if (rc != 0)
        AUTH_DEBUG5("authSessionListMutexUnlock() failed\n");
}


static void *destroy_expired_sessions(void *t)
{
    int rc2 = 0;

    (void)t;

    pthread_cleanup_push(cleanup_handler, NULL);

    rc2 = pthread_setcancelstate(PTHREAD_CANCEL_ENABLE, NULL);
    if (rc2 != 0)
        AUTH_DEBUG5("pthread_setcancelstate(): rc2 == %d\n", rc2);

    rc2 = pthread_setcanceltype(PTHREAD_CANCEL_ASYNCHRONOUS, NULL);
    if (rc2 != 0)
        AUTH_DEBUG5("pthread_setcanceltype(): rc2 == %d\n", rc2);

    while (1)
    {
        ... // destroy expired session
        sleep(min_timeout);
    }
    pthread_cleanup_pop(0);
}

int authDeinit( char *path )
{
    ...
    rc2 = authSessionListDeInit();
    ERR_IF( rc2 != 0 );

    rc2 = pthread_cancel(destroy_thread);
    ERR_IF( rc2 != 0 );

    rc2 = pthread_join(destroy_thread, &status);
    ERR_IF( rc2 != 0 || (int *)status != PTHREAD_CANCELED );

    ...
    return 0
}

It runs well with the test program, but the test program hangs at round #53743 with pthread_join():

(gdb) bt
#0  0x40000410 in __kernel_vsyscall ()
#1  0x0094aa77 in pthread_join () from /lib/libpthread.so.0
#2  0x08085745 in authDeinit ()
    at /users/qixu/src/moja/auth/src//app/libauth/authAPI.c:1562
#3  0x0807e747 in main ()
    at /users/qixu/src/moja/auth/src//app/tests/test_session.c:45

Looks like pthread_join() caused a deadlock. But looking at the code, I feel there is no reason that a dead lock be caused by pthread_join(). When pthread_join() gets the chance to run, the only mutex operation is of the thread itself. Should be no conflict, right? Really confused here...

share|improve this question
    
maybe your thread tries to join itself? That would deadlock surely ^) –  Victor Sorokin Mar 19 '12 at 20:21
    
@VictorSorokin: This shouldn't be the case, because the thread destroy_thread was created in a function other than authDeinit(). And if the thread tries to join itself, it will be deadlock in the first run, not after a long time, right? –  Qiang Xu Mar 19 '12 at 20:26
    
What is ERR_IF? is this changing control flow? –  Jens Gustedt Mar 19 '12 at 21:34
    
@JensGustedt: Yeah, it is a error handling macro and it will change the control flow. –  Qiang Xu Mar 19 '12 at 23:02
    
The answers and comments to those answers for this question are gold. –  Michael Burr Mar 20 '12 at 18:35

2 Answers 2

up vote 5 down vote accepted

At least one "oddity" shows in your code; your cleanup handler will always unlock the mutex even if you're not the thread holding it.

From the manual;

Calling pthread_mutex_unlock() with a mutex that the calling thread does not hold will result in undefined behavior.

share|improve this answer
3  
@QiangXu The problem is if the mutex is locked by another thread (if it can't be, there's not much use for a mutex), in which case you'll trylock, not get a lock and unlock the mutex while another thread owns it. –  Joachim Isaksson Mar 19 '12 at 20:46
2  
@QiangXu: There's nothing dangerous about unlocking a mutex in a cancellation handler. What's dangerous is having the wrong cancellation handlers installed at the wrong time. The scope of a cancelation handler that unlocks a mutex should be exactly the duration for which the mutex is locked and you're calling functions that are cancellation points. Its scope should end before the mutex is unlocked. –  R.. Mar 19 '12 at 21:59
2  
Note that the same issue would apply if your cancellation handler were calling free on a pointer that was not valid at the time the cancellation handler runs (e.g. because it was already freed). –  R.. Mar 19 '12 at 22:00
2  
@QiangXu You need to push an extra cleanup handler every time you lock the mutex and pop it at unlock, all pushed handlers will run if cancelled. The problem with async cancel is that you may cancel anywhere, including when you just popped the cleanup handler but didn't unlock. You can call pthread_cleanup_pop() with a non zero parameter which will execute the cleanup handler when popping (and so unlock your mutex) but I'm not aware of any guarantee that that handler itself can't be cancelled. I'm sure someone else knows if that's the case :) –  Joachim Isaksson Mar 19 '12 at 22:50
2  
@JoachimIsaksson: The cleanup handler can't be cancelled when called with pop(1) unless it calls a cancellation point, or unless asynchronous cancellation is enabled. And if asynchronous cancellation is enabled, you are not permitted to call any functions in the standard library whatsoever except pthread_setcancelstate, pthread_setcanceltype, and pthread_cancel, so you certainly can't lock or unlock mutexes. –  R.. Mar 20 '12 at 2:03

A bigger problem with your code, and probably the cause of the deadlocks, is your use of asynchronous cancellation mode (I missed this before). Only 3 functions in POSIX are async-cancel-safe:

  • pthread_cancel()
  • pthread_setcancelstate()
  • pthread_setcanceltype()

Source: http://pubs.opengroup.org/onlinepubs/9699919799/functions/V2_chap02.html#tag_15_09_05_04

You certainly cannot lock and unlock mutexes while async cancel mode is enabled.

For async cancellation to be usable, you have to do one of the following things:

  • Use it only with code that's purely computational, e.g. doing heavy math without any library calls at all, just arithmetic operations, or
  • Constantly toggle it off and back on around each library call you make.

Edit: Based on the comments, I think you have a misunderstanding of what asynchronous cancellation type means. It has nothing to do with the manner in which cleanup handlers run. It's purely a matter of what point the thread can catch the cancellation request and begin acting on it.

When the target is in deferred cancellation mode, calling pthread_cancel on it will not necessarily do anything right away, unless it's already blocked in a function (like read or select) that's a cancellation point. Instead it will just set a flag, and the next time a function which is a cancellation point is called, the thread will instead block any further cancellation attempts, run the cancellation cleanup handlers in the reverse order they were pushed, and exit with a special status indicating that the thread was cancelled.

When the target is in asynchronous cancellation mode, calling pthread_cancel on it will interrupt the thread immediately (possibly between any pair of adjacent machine code instructions). If you don't see why this is potentially dangerous, think about it for a second. Any function that has internal state (static/global variables, file descriptors or other resources being allocated/freed, etc.) could be in inconsistent state at the point of the interruption: a variable partially modified, a lock halfway obtained, a resource obtained but with no record of it having been obtained, or freed but with no record of it having been freed, etc.

At the point of the asynchronous interruption, further cancellation requests are blocked, so there's no danger of calling whatever function you like from your cleanup handlers. When the cleanup handlers finish running, the thread of course ceases to exist.

One other potential source of confusion: cleanup handlers do not run in parallel with the thread being cancelled. When cancellation is acted upon, the cancelled thread stops running the normal flow of code, and instead runs the cleanup handlers then exits.

share|improve this answer
1  
And note that even in the purely mathematical case, you'll eventually have to switch async cancellation off so you can inform other threads that the result is ready. –  R.. Mar 20 '12 at 5:42
1  
Async cancellation must not be enabled until after you lock the mutex (you cannot call any library functions except the above 3 while it's enabled!) and must be disabled before you unlock the mutex. If you're in the cleanup handler due to cancellation, then async cancellability was already disabled by acting on a cancellation request (you won't get another cancellation during processing of the first one). –  R.. Mar 20 '12 at 15:11
1  
No, the the cancellation type you use has nothing to do with cleanup handlers. It pertains to what you can do in the main flow of code. With deferred cancellation mode, cancellation is only acted upon at certain particular function calls (mostly system calls that can block waiting for an event). If you're just stuck in a loop doing math, it will never be acted upon. On the other hand, async cancellation can be acted upon at any time, but this means you are not allowed to call any library functions because interrupting them asynchronously could leave the whole program in an inconsistent state. –  R.. Mar 20 '12 at 16:16
1  
Either way, if cancellation is acted upon, further cancellation requests will be blocked before the cleanup handlers are run, so you can use any functions you like from a cancellation cleanup handler. –  R.. Mar 20 '12 at 16:17
1  
Also note that pthread_cleanup_push and pthread_cleanup_pop are not legal to use while cancellation type is async. You must switch to deferred to use either of them; you can switch back to async afterwards if you like. –  R.. Mar 20 '12 at 16:19

Your Answer

 
discard

By posting your answer, you agree to the privacy policy and terms of service.

Not the answer you're looking for? Browse other questions tagged or ask your own question.