csci4061/notes/11-threads-code/pthreads_producer_consumer.c

/******************************************************************************
 * FILE: condvar.c
 * DESCRIPTION:
 *   Example code for using Pthreads condition variables.  The main thread
 *   creates three threads.  Two of those threads increment a "count" variable,
 *   while the third thread watches the value of "count".  When "count" 
 *   reaches a predefined limit, the waiting thread is signaled by one of the
 *   incrementing threads. The waiting thread "awakens" and then modifies
 *   count. The program continues until the incrementing threads reach
 *   TCOUNT. The main program prints the final value of count.
 * SOURCE: Adapted from example code in "Pthreads Programming", B. Nichols
 *   et al. O'Reilly and Associates. 
 * LAST REVISED: 10/14/10  Blaise Barney
 ******************************************************************************/
#include <pthread.h>
#include <stdio.h>
#include <stdlib.h>
#include <unistd.h>

#define NUM_THREADS  3
#define TCOUNT 10
#define COUNT_LIMIT 12

int     count = 0;
pthread_mutex_t count_mutex;
pthread_cond_t count_threshold_cv;

// Run by two child threads
void *inc_count(void *t) 
{
  int i;
  long my_id = (long)t;

  for (i=0; i < TCOUNT; i++) {
    pthread_mutex_lock(&count_mutex);
    count++;

    /* Check the value of count and signal waiting thread when
       condition is reached.  Note that this occurs while mutex is
       locked. */
    if (count == COUNT_LIMIT) {
      printf("inc_count(): thread %ld, count = %d  Threshold reached. ",
             my_id, count);
      pthread_cond_signal(&count_threshold_cv);
      printf("Just sent signal.\n");
    }
    printf("inc_count(): thread %ld, count = %d, unlocking mutex\n", 
	   my_id, count);
    pthread_mutex_unlock(&count_mutex);

    /* Do some work so threads can alternate on mutex lock */
    sleep(1);
  }
  pthread_exit(NULL);
}

// Run by 1 child thread
void *watch_count(void *t) 
{
  long my_id = (long)t;

  printf("Starting watch_count(): thread %ld\n", my_id);

  /* Lock mutex and wait for signal.  Note that the pthread_cond_wait
     routine will automatically and atomically unlock mutex while it
     waits. Also, note that if COUNT_LIMIT is reached before this
     routine is run by the waiting thread, the loop will be skipped to
     prevent pthread_cond_wait from never returning. */
  pthread_mutex_lock(&count_mutex);
  while (count < COUNT_LIMIT) {
    printf("watch_count(): thread %ld Count= %d. Going into wait...\n", my_id,count);
    pthread_cond_wait(&count_threshold_cv, &count_mutex);
    printf("watch_count(): thread %ld Condition signal received. Count= %d\n", my_id,count);
    printf("watch_count(): thread %ld Updating the value of count...\n", my_id,count);
    //    count += 125;
    printf("watch_count(): thread %ld count now = %d.\n", my_id, count);
  }
  printf("watch_count(): thread %ld Unlocking mutex.\n", my_id);
  pthread_mutex_unlock(&count_mutex);
  pthread_exit(NULL);
}

int main(int argc, char *argv[])
{
  int i, rc; 
  long t1=1, t2=2, t3=3;
  pthread_t threads[3];
  pthread_attr_t attr;

  /* Initialize mutex and condition variable objects */
  pthread_mutex_init(&count_mutex, NULL);
  pthread_cond_init (&count_threshold_cv, NULL);

  /* For portability, explicitly create threads in a joinable state */
  pthread_attr_init(&attr);
  pthread_attr_setdetachstate(&attr, PTHREAD_CREATE_JOINABLE);
  pthread_create(&threads[0], &attr, watch_count, (void *)t1);
  pthread_create(&threads[1], &attr, inc_count, (void *)t2);
  pthread_create(&threads[2], &attr, inc_count, (void *)t3);

  /* Wait for all threads to complete */
  for (i = 0; i < NUM_THREADS; i++) {
    pthread_join(threads[i], NULL);
  }
  printf ("Main(): Waited and joined with %d threads. Final value of count = %d. Done.\n", 
          NUM_THREADS, count);

  /* Clean up and exit */
  pthread_attr_destroy(&attr);
  pthread_mutex_destroy(&count_mutex);
  pthread_cond_destroy(&count_threshold_cv);
  pthread_exit (NULL);

}