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'm trying to work with producer/consumer threads in a bounded buffer. The buffer length is 5. I have 1 mutex and 2 semaphores, empty which starts out at the size of the buffer, and full, which starts out at 0.

When I run my code without sleep() at the end, it continually produces until the buffer is completely fully, the consumes until it's empty, so the output looks like this:

Placed 1 in the buffer at position 0.
Placed 2 in the buffer at position 1.
Placed 3 in the buffer at position 2.
Placed 4 in the buffer at position 3.
Placed 5 in the buffer at position 4.
The buffer now contains 0 at position 0.
The buffer now contains 0 at position 1.
The buffer now contains 0 at position 2.
The buffer now contains 0 at position 3.
The buffer now contains 0 at position 4.

However, when i run with sleep() at the end, it prints out:

Placed 1 in the buffer at position 0.
The buffer now contains 0 at position 0.

Then it appears to lock up, but I'm not really sure why it behaves the way it does regardless of whether or not sleep is there. Any suggestions? My main method essentially just makes some declarations then creates 1 thread to produce and 1 to consume, those methods are below.

void *producer()
{
        int k = 0; //producer index
        while (1)
        {
                sem_wait(&empty);
                pthread_mutex_lock(&mutex);
                buffer[k] = k+1;
                sem_post(&full);
                pthread_mutex_unlock(&mutex);
                printf("Placed %d in the buffer at position %d.\n", buffer[k], k);
                k = (k + 1) % BUFFER_SIZE;
                sleep(rand() * 10);
        }
}

void *consumer()
{
        int j = 0;   //consumer index
        while(1)
        {
                sem_wait(&full);
                pthread_mutex_lock(&mutex);
                buffer[j] = 0;
                sem_post(&empty);
                pthread_mutex_unlock(&mutex);
                printf("The buffer now contains %d at position %d.\n", buffer[j], j);
                j = (j + 1) % BUFFER_SIZE;
                sleep(rand() * 10);

        }
}
share|improve this question
    
I suggest you to throw your code away and rewrite the task in pseudocode. Or you may rewrite it in C again, that usually helps me to find such hard bugs. –  Lavir the Whiolet Nov 5 '10 at 19:15
    
One (unrelated) problem I can see, the consumer index j should be shared amongst consumers. It doesn't help if it's local to each thread. Make j global. –  Jeff Mercado Nov 5 '10 at 19:16
    
Thanks, I was actually planning on doing that for when I implement multiple threads, but for now I only have 1 producer and 1 consumer each. –  john Nov 5 '10 at 19:19

4 Answers 4

up vote 3 down vote accepted

The parameter to sleep() is the number of seconds to sleep for. rand() returns an integer between 0 and RAND_MAX (typically 32767 or 231-1), and when you multiply that by 10, you're sleeping for an absurdly large amount of time. You're not deadlocking, just sleeping for a very long time.

share|improve this answer
    
Hmmm, for some reason I thought rand() was in between 0 and 1. Thanks, I'll try adjusting it. –  john Nov 5 '10 at 19:21
    
That worked, thanks. Do you have any idea why when I don't include sleep it always produces and consumes in blocks instead of every other? –  john Nov 5 '10 at 19:32

I don't know if that is the reason for your deadlock, but you have to be careful with sem_t functions they are subject to interrupts, in particular due to IO and things like that.

Never ignore returns from system functions. Here, you'd have to check the return and then errno for EINTR.

Then, I don't know if you are forced to use sem_t, but I think more natural here would be to use a pthread_cond_t. You have a mutex anyhow, so this would fit more easily. pthread_cond_t as pthread_mutex_t functions will never be interrupted.

share|improve this answer

Do you have any idea why when I don't include sleep it always produces and consumes in blocks instead of every other?

Thats probably because the ~30 ms time slice each thread is given is more than enough to have the producer produce everything, before a context switch had a chance to occur.

share|improve this answer

I assume both your threads have the same priority? And is this on a machine with multiple cores, or just one? Just signaling a semaphore will not preempt your current thread, so it is to be expected for the current thread to carry on until its slice expires.

Also, I would definitely unlock the mutex before signaling the mutex.

share|improve this answer
    
The machine I'm on is dual core. If the consumer thread is running at the same time, constantly checking for the condition that it can start consuming, and the producer thread signals a semaphore after 1 production, shouldn't the consumer start running after the producer has run once? –  john Nov 5 '10 at 19:39
    
It should. Btw, what is the mutex for? Since you signal the semaphore after you're done writing (like you should), you're guaranteed to never write to the same address that the consumer thread is reading from. –  EboMike Nov 5 '10 at 19:41
    
Well, a lot of code I looked at used it and for this lab I thought I was supposed to treat accessing the buffer as a critical section. If I had multiple consumers and producers wouldn't I need the mutex anyway? –  john Nov 5 '10 at 19:48
    
A mutex needs to have a reason. You need to have a shared resource. In this particular example, I don't see a shared resource - the producer will only ever write to memory that the consumer will only ever access AFTER the producer has signaled the semaphore. Of course, if there's more to your code than what you posted, you may need a mutex. In any case, did you try taking the mutex out? –  EboMike Nov 5 '10 at 21:34

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.