drd/tests/circular_buffer.c - platform/external/valgrind - Git at Google

 /* Test program that performs producer-consumer style communication through
  * a circular buffer. This test program is a slightly modified version of the
  * test program made available by Miguel Ojeda
  * -- see also http://article.gmane.org/gmane.comp.debugging.valgrind/8782.
  */


 #include <stdio.h>
 #include <string.h>
 #include <stdlib.h>
 #include <unistd.h>
 #include <time.h>
 #include <pthread.h>
 #include <semaphore.h>
 #include <fcntl.h>
 #include "../../config.h"


 /** gcc versions 4.1.0 and later have support for atomic builtins. */

 #ifndef HAVE_BUILTIN_ATOMIC
 #error Sorry, but this test program can only be compiled by a compiler that\
 has built-in functions for atomic memory access.
 #endif


 #define BUFFER_MAX (2)
 #define DATA_SEMAPHORE_NAME "cb-data-semaphore"
 #define FREE_SEMAPHORE_NAME "cb-free-semaphore"


 typedef int data_t;

 typedef struct {
   /* Counting semaphore representing the number of data items in the buffer. */
   sem_t* data;
   /* Counting semaphore representing the number of free elements. */
   sem_t* free;
   /* Position where a new elements should be written. */
   int in;
   /* Position from where an element can be removed. */
   int out;
   /* Mutex that protects 'in'. */
   pthread_mutex_t mutex_in;
   /* Mutex that protects 'out'. */
   pthread_mutex_t mutex_out;
   /* Data buffer. */
   data_t buffer[BUFFER_MAX];
 } buffer_t;

 static int quiet = 0;
 static int use_locking = 1;

 static __inline__
 int fetch_and_add(int* p, int i)
 {
   return __sync_fetch_and_add(p, i);
 }

 static sem_t* create_semaphore(const char* const name, const int value)
 {
 #ifdef VGO_darwin
   char name_and_pid[32];
   snprintf(name_and_pid, sizeof(name_and_pid), "%s-%d", name, getpid());
   sem_t* p = sem_open(name_and_pid, O_CREAT | O_EXCL, 0600, value);
   if (p == SEM_FAILED) {
     perror("sem_open");
     return NULL;
   }
   return p;
 #else
   sem_t* p = malloc(sizeof(*p));
   if (p)
     sem_init(p, 0, value);
   return p;
 #endif
 }

 static void destroy_semaphore(const char* const name, sem_t* p)
 {
 #ifdef VGO_darwin
   sem_close(p);
   sem_unlink(name);
 #else
   sem_destroy(p);
   free(p);
 #endif
 }

 static void buffer_init(buffer_t * b)
 {
   b->data = create_semaphore(DATA_SEMAPHORE_NAME, 0);
   b->free = create_semaphore(FREE_SEMAPHORE_NAME, BUFFER_MAX);

   pthread_mutex_init(&b->mutex_in, NULL);
   pthread_mutex_init(&b->mutex_out, NULL);

   b->in = 0;
   b->out = 0;
 }

 static void buffer_recv(buffer_t* b, data_t* d)
 {
   int out;
   sem_wait(b->data);
   if (use_locking)
     pthread_mutex_lock(&b->mutex_out);
   out = fetch_and_add(&b->out, 1);
   if (out >= BUFFER_MAX)
   {
     fetch_and_add(&b->out, -BUFFER_MAX);
     out -= BUFFER_MAX;
   }
   *d = b->buffer[out];
   if (use_locking)
     pthread_mutex_unlock(&b->mutex_out);
   if (! quiet)
   {
     printf("received %d from buffer[%d]\n", *d, out);
     fflush(stdout);
   }
   sem_post(b->free);
 }

 static void buffer_send(buffer_t* b, data_t* d)
 {
   int in;
   sem_wait(b->free);
   if (use_locking)
     pthread_mutex_lock(&b->mutex_in);
   in = fetch_and_add(&b->in, 1);
   if (in >= BUFFER_MAX)
   {
     fetch_and_add(&b->in, -BUFFER_MAX);
     in -= BUFFER_MAX;
   }
   b->buffer[in] = *d;
   if (use_locking)
     pthread_mutex_unlock(&b->mutex_in);
   if (! quiet)
   {
     printf("sent %d to buffer[%d]\n", *d, in);
     fflush(stdout);
   }
   sem_post(b->data);
 }

 static void buffer_destroy(buffer_t* b)
 {
   destroy_semaphore(DATA_SEMAPHORE_NAME, b->data);
   destroy_semaphore(FREE_SEMAPHORE_NAME, b->free);

   pthread_mutex_destroy(&b->mutex_in);
   pthread_mutex_destroy(&b->mutex_out);
 }

 static buffer_t b;

 static void producer(int* id)
 {
   buffer_send(&b, id);
   pthread_exit(NULL);
 }

 #define MAXSLEEP (100 * 1000)

 static void consumer(int* id)
 {
   int d;
   usleep(rand() % MAXSLEEP);
   buffer_recv(&b, &d);
   if (! quiet)
   {
     printf("%i: %i\n", *id, d);
     fflush(stdout);
   }
   pthread_exit(NULL);
 }

 #define THREADS (10)

 int main(int argc, char** argv)
 {
   pthread_t producers[THREADS];
   pthread_t consumers[THREADS];
   int thread_arg[THREADS];
   int i;
   int optchar;

   while ((optchar = getopt(argc, argv, "nq")) != EOF)
   {
     switch (optchar)
     {
     case 'n':
       use_locking = 0;
       break;
     case 'q':
       quiet = 1;
       break;
     }
   }

   srand(time(NULL));

   buffer_init(&b);

   for (i = 0; i < THREADS; ++i)
   {
     thread_arg[i] = i;
     pthread_create(producers + i, NULL,
                    (void * (*)(void *)) producer, &thread_arg[i]);
   }

   for (i = 0; i < THREADS; ++i)
     pthread_create(consumers + i, NULL,
                    (void * (*)(void *)) consumer, &thread_arg[i]);

   for (i = 0; i < THREADS; ++i)
   {
     pthread_join(producers[i], NULL);
     pthread_join(consumers[i], NULL);
   }

   buffer_destroy(&b);

   return 0;
 }
	/* Test program that performs producer-consumer style communication through
	* a circular buffer. This test program is a slightly modified version of the
	* test program made available by Miguel Ojeda
	* -- see also http://article.gmane.org/gmane.comp.debugging.valgrind/8782.
	*/


	#include <stdio.h>
	#include <string.h>
	#include <stdlib.h>
	#include <unistd.h>
	#include <time.h>
	#include <pthread.h>
	#include <semaphore.h>
	#include <fcntl.h>
	#include "../../config.h"


	/** gcc versions 4.1.0 and later have support for atomic builtins. */

	#ifndef HAVE_BUILTIN_ATOMIC
	#error Sorry, but this test program can only be compiled by a compiler that\
	has built-in functions for atomic memory access.
	#endif


	#define BUFFER_MAX (2)
	#define DATA_SEMAPHORE_NAME "cb-data-semaphore"
	#define FREE_SEMAPHORE_NAME "cb-free-semaphore"


	typedef int data_t;

	typedef struct {
	/* Counting semaphore representing the number of data items in the buffer. */
	sem_t* data;
	/* Counting semaphore representing the number of free elements. */
	sem_t* free;
	/* Position where a new elements should be written. */
	int in;
	/* Position from where an element can be removed. */
	int out;
	/* Mutex that protects 'in'. */
	pthread_mutex_t mutex_in;
	/* Mutex that protects 'out'. */
	pthread_mutex_t mutex_out;
	/* Data buffer. */
	data_t buffer[BUFFER_MAX];
	} buffer_t;

	static int quiet = 0;
	static int use_locking = 1;

	static __inline__
	int fetch_and_add(int* p, int i)
	{
	return __sync_fetch_and_add(p, i);
	}

	static sem_t* create_semaphore(const char* const name, const int value)
	{
	#ifdef VGO_darwin
	char name_and_pid[32];
	snprintf(name_and_pid, sizeof(name_and_pid), "%s-%d", name, getpid());
	sem_t* p = sem_open(name_and_pid, O_CREAT \| O_EXCL, 0600, value);
	if (p == SEM_FAILED) {
	perror("sem_open");
	return NULL;
	}
	return p;
	#else
	sem_t* p = malloc(sizeof(*p));
	if (p)
	sem_init(p, 0, value);
	return p;
	#endif
	}

	static void destroy_semaphore(const char* const name, sem_t* p)
	{
	#ifdef VGO_darwin
	sem_close(p);
	sem_unlink(name);
	#else
	sem_destroy(p);
	free(p);
	#endif
	}

	static void buffer_init(buffer_t * b)
	{
	b->data = create_semaphore(DATA_SEMAPHORE_NAME, 0);
	b->free = create_semaphore(FREE_SEMAPHORE_NAME, BUFFER_MAX);

	pthread_mutex_init(&b->mutex_in, NULL);
	pthread_mutex_init(&b->mutex_out, NULL);

	b->in = 0;
	b->out = 0;
	}

	static void buffer_recv(buffer_t* b, data_t* d)
	{
	int out;
	sem_wait(b->data);
	if (use_locking)
	pthread_mutex_lock(&b->mutex_out);
	out = fetch_and_add(&b->out, 1);
	if (out >= BUFFER_MAX)
	{
	fetch_and_add(&b->out, -BUFFER_MAX);
	out -= BUFFER_MAX;
	}
	*d = b->buffer[out];
	if (use_locking)
	pthread_mutex_unlock(&b->mutex_out);
	if (! quiet)
	{
	printf("received %d from buffer[%d]\n", *d, out);
	fflush(stdout);
	}
	sem_post(b->free);
	}

	static void buffer_send(buffer_t* b, data_t* d)
	{
	int in;
	sem_wait(b->free);
	if (use_locking)
	pthread_mutex_lock(&b->mutex_in);
	in = fetch_and_add(&b->in, 1);
	if (in >= BUFFER_MAX)
	{
	fetch_and_add(&b->in, -BUFFER_MAX);
	in -= BUFFER_MAX;
	}
	b->buffer[in] = *d;
	if (use_locking)
	pthread_mutex_unlock(&b->mutex_in);
	if (! quiet)
	{
	printf("sent %d to buffer[%d]\n", *d, in);
	fflush(stdout);
	}
	sem_post(b->data);
	}

	static void buffer_destroy(buffer_t* b)
	{
	destroy_semaphore(DATA_SEMAPHORE_NAME, b->data);
	destroy_semaphore(FREE_SEMAPHORE_NAME, b->free);

	pthread_mutex_destroy(&b->mutex_in);
	pthread_mutex_destroy(&b->mutex_out);
	}

	static buffer_t b;

	static void producer(int* id)
	{
	buffer_send(&b, id);
	pthread_exit(NULL);
	}

	#define MAXSLEEP (100 * 1000)

	static void consumer(int* id)
	{
	int d;
	usleep(rand() % MAXSLEEP);
	buffer_recv(&b, &d);
	if (! quiet)
	{
	printf("%i: %i\n", *id, d);
	fflush(stdout);
	}
	pthread_exit(NULL);
	}

	#define THREADS (10)

	int main(int argc, char** argv)
	{
	pthread_t producers[THREADS];
	pthread_t consumers[THREADS];
	int thread_arg[THREADS];
	int i;
	int optchar;

	while ((optchar = getopt(argc, argv, "nq")) != EOF)
	{
	switch (optchar)
	{
	case 'n':
	use_locking = 0;
	break;
	case 'q':
	quiet = 1;
	break;
	}
	}

	srand(time(NULL));

	buffer_init(&b);

	for (i = 0; i < THREADS; ++i)
	{
	thread_arg[i] = i;
	pthread_create(producers + i, NULL,
	(void * ()(void )) producer, &thread_arg[i]);
	}

	for (i = 0; i < THREADS; ++i)
	pthread_create(consumers + i, NULL,
	(void * ()(void )) consumer, &thread_arg[i]);

	for (i = 0; i < THREADS; ++i)
	{
	pthread_join(producers[i], NULL);
	pthread_join(consumers[i], NULL);
	}

	buffer_destroy(&b);

	return 0;
	}