Linux C线程池

三个文件 

1 tpool.h

typedef struct tpool_work { 
  void        (*routine)(void *); 
  void        *arg; 
  struct tpool_work  *next; 
} tpool_work_t; 
 
typedef struct tpool { 
  /* pool characteristics */ 
  int         num_threads; 
  int         max_queue_size; 
  /* pool state */ 
  pthread_t      *tpid; 
  tpool_work_t    *queue; 
  int         front, rear; 
  /* 剩下的任务可以做完, 但不能再加新的任务 */ 
  int         queue_closed;   
  /* 剩下的任务都不做了, 直接关闭 */ 
  int         shutdown;     
  /* pool synchronization */ 
  pthread_mutex_t   queue_lock; 
  pthread_cond_t   queue_has_task; 
  pthread_cond_t   queue_has_space; 
  pthread_cond_t   queue_empty; 
} *tpool_t; 
 
void tpool_init(tpool_t *tpoolp,int num_threads, int max_queue_size); 
 
int tpool_add_work(tpool_t tpool,void(*routine)(void *), void *arg); 
 
int tpool_destroy(tpool_t tpool,int finish); 

 2 tpool.c

#include <stdlib.h> 
#include <stdio.h> 
#include <unistd.h> 
#include <sys/types.h> 
#include <string.h> 
#include <pthread.h> 
#include "tpool.h" 
 
#define DEBUG 
 
#if defined(DEBUG) 
#define debug(...) do { \ 
  flockfile(stdout); \ 
  printf("###%p.%s: ", (void *)pthread_self(), __func__); \ 
  printf(__VA_ARGS__); \ 
  putchar('\n'); \ 
  fflush(stdout); \ 
  funlockfile(stdout); \ 
} while (0) 
#else 
#define debug(...) 
#endif 
 
void *tpool_thread(void *); 
 
void tpool_init(tpool_t *tpoolp, int num_worker_threads, int max_queue_size) 
{ 
  int i; 
  tpool_t pool; 
 
  pool = (tpool_t)malloc(sizeof(struct tpool)); 
  if (pool == NULL) { 
    perror("malloc"); 
    exit(0); 
  } 
 
  pool->num_threads = 0; 
  pool->max_queue_size = max_queue_size + 1; 
  pool->num_threads = num_worker_threads; 
  pool->tpid = NULL; 
  pool->front = 0; 
  pool->rear = 0; 
  pool->queue_closed = 0; 
  pool->shutdown = 0; 
 
  if (pthread_mutex_init(&pool->queue_lock, NULL) == -1) { 
    perror("pthread_mutex_init"); 
    free(pool); 
    exit(0); 
  } 
  if (pthread_cond_init(&pool->queue_has_space, NULL) == -1) { 
    perror("pthread_mutex_init"); 
    free(pool); 
    exit(0); 
  } 
  if (pthread_cond_init(&pool->queue_has_task, NULL) == -1) { 
    perror("pthread_mutex_init"); 
    free(pool); 
    exit(0); 
  } 
  if (pthread_cond_init(&pool->queue_empty, NULL) == -1) { 
    perror("pthread_mutex_init"); 
    free(pool); 
    exit(0); 
  } 
 
  if ((pool->queue = malloc(sizeof(struct tpool_work) *  
          pool->max_queue_size)) == NULL) { 
    perror("malloc"); 
    free(pool); 
    exit(0); 
  } 
 
  if ((pool->tpid = malloc(sizeof(pthread_t) * num_worker_threads)) == NULL) { 
    perror("malloc"); 
    free(pool); 
    free(pool->queue); 
    exit(0); 
  } 
 
  for (i = 0; i < num_worker_threads; i++) { 
    if (pthread_create(&pool->tpid[i], NULL, tpool_thread,  
          (void *)pool) != 0) { 
      perror("pthread_create"); 
      exit(0); 
    } 
  } 
 
  *tpoolp = pool; 
} 
 
 
int empty(tpool_t pool) 
{ 
  return pool->front == pool->rear; 
} 
 
int full(tpool_t pool) 
{ 
  return ((pool->rear + 1) % pool->max_queue_size == pool->front); 
} 
 
int size(tpool_t pool) 
{ 
  return (pool->rear + pool->max_queue_size - 
        pool->front) % pool->max_queue_size; 
} 
 
int tpool_add_work(tpool_t tpool, void(*routine)(void *), void *arg) 
{ 
  tpool_work_t *temp; 
 
  pthread_mutex_lock(&tpool->queue_lock); 
 
  while (full(tpool) && !tpool->shutdown && !tpool->queue_closed) { 
    pthread_cond_wait(&tpool->queue_has_space, &tpool->queue_lock); 
  } 
 
  if (tpool->shutdown || tpool->queue_closed) { 
    pthread_mutex_unlock(&tpool->queue_lock); 
    return -1; 
  } 
 
  int is_empty = empty(tpool); 
 
  temp = tpool->queue + tpool->rear; 
  temp->routine = routine; 
  temp->arg = arg; 
  tpool->rear = (tpool->rear + 1) % tpool->max_queue_size; 
 
  if (is_empty) { 
    debug("signal has task"); 
    pthread_cond_broadcast(&tpool->queue_has_task); 
  } 
 
  pthread_mutex_unlock(&tpool->queue_lock);   
 
  return 0; 
} 
 
void *tpool_thread(void *arg) 
{ 
  tpool_t pool = (tpool_t)(arg); 
  tpool_work_t *work; 
 
  for (;;) { 
    pthread_mutex_lock(&pool->queue_lock); 
 
    while (empty(pool) && !pool->shutdown) { 
      debug("I'm sleep"); 
      pthread_cond_wait(&pool->queue_has_task, &pool->queue_lock); 
    } 
    debug("I'm awake"); 
 
    if (pool->shutdown == 1) { 
      debug("exit"); 
      pthread_mutex_unlock(&pool->queue_lock); 
      pthread_exit(NULL); 
    } 
 
    int is_full = full(pool); 
    work = pool->queue + pool->front; 
    pool->front = (pool->front + 1) % pool->max_queue_size; 
 
    if (is_full) { 
      pthread_cond_broadcast(&pool->queue_has_space); 
    } 
 
    if (empty(pool)) { 
      pthread_cond_signal(&pool->queue_empty); 
    } 
 
    pthread_mutex_unlock(&pool->queue_lock);   
 
    (*(work->routine))(work->arg); 
  } 
} 
 
int tpool_destroy(tpool_t tpool, int finish) 
{ 
  int   i; 
 
  pthread_mutex_lock(&tpool->queue_lock); 
 
  tpool->queue_closed = 1; 
 
  if (finish == 1) { 
    debug("wait all work done"); 
    while (!empty(tpool)) { 
      pthread_cond_wait(&tpool->queue_empty, &tpool->queue_lock); 
    } 
  } 
  tpool->shutdown = 1; 
 
  pthread_mutex_unlock(&tpool->queue_lock); 
 
  pthread_cond_broadcast(&tpool->queue_has_task); 
 
  debug("wait worker thread exit"); 
  for (i = 0; i < tpool->num_threads; i++) { 
    pthread_join(tpool->tpid[i], NULL); 
  } 
 
  debug("free thread pool"); 
  free(tpool->tpid); 
  free(tpool->queue); 
  free(tpool); 
} 
 

3 tpooltest.c

#include <stdio.h> 
#include <pthread.h> 
#include "tpool.h" 
 
char *str[]={"string 0", "string 1", "string 2",  
        "string 3", "string 4", "string 5"}; 
 
void job(void * jobstr) 
{ 
  long i, x; 
 
  for (i = 0; i < 100000000; i++) { 
    x = x +i; 
  } 
  printf("%s\n", (char *)jobstr); 
} 
 
int main(void) 
{ 
  int i;  
  tpool_t test_pool; 
 
  tpool_init(&test_pool, 8, 20); 
 
  for ( i = 0; i < 5; i++) { 
    tpool_add_work(test_pool, job, str[i]); 
  } 
 
  tpool_destroy(test_pool, 1); 
 
  return 0; 
} 

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Linux,C线程池,Linux,线程池的实例

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