C/C++ 多线程机制

时间:2023-03-09 01:51:37
C/C++ 多线程机制

一、C/C++多线程操作说明

C/C++多线程基本操作如下: 
1. 线程的建立结束 
2. 线程的互斥和同步 
3. 使用信号量控制线程 
4. 线程的基本属性配置

在C/C++代码编写时,使用多线程机制,首先需要做的事情就是声明引用,具体如下:

#include "pthread.h"

二、线程基本操作方法

基本线程操作:

1. pthread_create():创建线程开始运行相关线程函数,运行结束则线程退出

2. pthread_eixt():因为exit()是用来结束进程的,所以则需要使用特定结束线程的函数

3. pthread_join():挂起当前线程,用于阻塞式地等待线程结束,如果线程已结束则立即返回,0=成功

4. pthread_cancel():发送终止信号给thread线程,成功返回0,但是成功并不意味着thread会终止

5. pthread_testcancel():在不包含取消点,但是又需要取消点的地方创建一个取消点,以便在一个没有包含取消点的执行代码线程中响应取消请求.

6. pthread_setcancelstate():设置本线程对cancle线程的反应

7. pthread_setcanceltype():设置取消状态 继续运行至下一个取消点再退出或者是立即执行取消动作

8. pthread_setcancel():设置取消状态

三、线程互斥与同步机制

基本的互斥与同步的操作方法:

1. pthread_mutex_init():互斥锁的初始化

2. pthread_mutex_lock():锁定互斥锁,如果尝试锁定已经被上锁的互斥锁则阻塞至可用为止

3. pthread_mutex_trylock():非阻塞的锁定互斥锁

4. pthread_mutex_unlock():释放互斥锁

5. pthread_mutex_destory():互斥锁销毁函数

四、多线程实践

1. 基本的线程及建立运行

下面的代码是C/C++开发的基本的线程的运行,使用的就是最基本的pthread.h:

/* thread.c */

#include <stdio.h>

#include <stdlib.h>

#include <pthread.h>

#define THREAD_NUMBER       3                 /*线程数*/

#define REPEAT_NUMBER       5                 /*每个线程中的小任务数*/

#define DELAY_TIME_LEVELS  10.0             /*小任务之间的最大时间间隔*/

//

void *thrd_func(void *arg) {

    /* 线程函数例程 */

    int thrd_num = (int)arg;

    int delay_time = ;

    int count = ;

    printf("Thread %d is starting\n", thrd_num);

    for (count = ; count < REPEAT_NUMBER; count++) {

        delay_time = (int)(rand() * DELAY_TIME_LEVELS/(RAND_MAX)) + ;

        sleep(delay_time);

        printf("\tThread %d: job %d delay = %d\n", thrd_num, count, delay_time);

    }

    printf("Thread %d finished\n", thrd_num);

    pthread_exit(NULL);

}

int main(void) {

     pthread_t thread[THREAD_NUMBER];

     int no = , res;

     void * thrd_ret;

     srand(time(NULL));

     for (no = ; no < THREAD_NUMBER; no++) {

          /* 创建多线程 */

          res = pthread_create(&thread[no], NULL, thrd_func, (void*)no);

          if (res != ) {

               printf("Create thread %d failed\n", no);

               exit(res);

          }

     }

     printf("Create treads success\n Waiting for threads to finish...\n");

     for (no = ; no < THREAD_NUMBER; no++) {

          /* 等待线程结束 */

          res = pthread_join(thread[no], &thrd_ret);

          if (!res) {

            printf("Thread %d joined\n", no);

          } else {

            printf("Thread %d join failed\n", no);

          }

     }

     return ;

}

例程中循环3次建立3条线程,并且使用pthread_join函数依次等待线程结束; 
线程中使用rand()获取随机值随机休眠5次,随意会出现后执行的线程先执行完成; 
运行结果:

$ gcc thread.c -lpthread

$ ./a.out

Create treads success

 Waiting for threads to finish...

Thread  is starting

Thread  is starting

Thread  is starting

Thread : job  delay =

Thread : job  delay =

Thread : job  delay =

Thread : job  delay =

Thread : job  delay =

Thread : job  delay =

Thread : job  delay =

Thread : job  delay =

Thread : job  delay =

Thread : job  delay =

Thread : job  delay =

Thread : job  delay =

Thread  finished

        Thread : job  delay =

        Thread : job  delay =

Thread  finished

Thread  joined

Thread  joined

        Thread : job  delay =

Thread  finished

Thread  joined

可以看到,线程1先于线程0执行,但是pthread_join的调用时间顺序,先等待线程0执行; 
由于线程1已经早结束,所以线程0被pthread_join等到的时候,线程1已结束,就在等待到线程1时,直接返回;

2. 线程执行的互斥和同步pthread_mutex_lock

下面我们在上面的程序中增加互斥锁:

/*thread_mutex.c*/

#include <stdio.h>

#include <stdlib.h>

#include <pthread.h>

#include <unistd.h>

#define THREAD_NUMBER        3            /* 线程数 */

#define REPEAT_NUMBER        3            /* 每个线程的小任务数 */

#define DELAY_TIME_LEVELS 10.0         /*小任务之间的最大时间间隔*/

pthread_mutex_t mutex;

void *thrd_func(void *arg) {

     int thrd_num = (int)arg;

     int delay_time = , count = ;

     int res;

     /* 互斥锁上锁 */

     res = pthread_mutex_lock(&mutex);

     if (res) {

          printf("Thread %d lock failed\n", thrd_num);

          pthread_exit(NULL);

     }

     printf("Thread %d is starting\n", thrd_num);

     for (count = ; count < REPEAT_NUMBER; count++) {

         delay_time = (int)(rand() * DELAY_TIME_LEVELS/(RAND_MAX)) + ;

         sleep(delay_time);

         printf("\tThread %d: job %d delay = %d\n",

                                      thrd_num, count, delay_time);

     }

     printf("Thread %d finished\n", thrd_num);

     /****互斥锁解锁***/

     pthread_mutex_unlock(&mutex);

     pthread_exit(NULL);

}

int main(void) {

     pthread_t thread[THREAD_NUMBER];

     int no = , res;

     void * thrd_ret;

     srand(time(NULL));

     /* 互斥锁初始化 */

     pthread_mutex_init(&mutex, NULL);

     for (no = ; no < THREAD_NUMBER; no++) {

          res = pthread_create(&thread[no], NULL, thrd_func, (void*)no);

          if (res != ) {

              printf("Create thread %d failed\n", no);

              exit(res);

          }

     }

     printf("Create treads success\n Waiting for threads to finish...\n");

     for (no = ; no < THREAD_NUMBER; no++) {

          res = pthread_join(thread[no], &thrd_ret);

          if (!res) {

                printf("Thread %d joined\n", no);

          } else  {

              printf("Thread %d join failed\n", no);

          }

     }

     pthread_mutex_destroy(&mutex);

     return ;

}

在上面的例程中直接添加同步锁pthread_mutex_t; 
在线程中加入,程序在执行线程程序时,调用pthread_mutex_lock上锁,发现上锁时候后进入等待,等待锁再次释放后重新上锁; 
所以线程程序加载到队列中等待,等待成功上锁后继续执行程序代码; 
运行结果如下:

Create treads success

 Waiting for threads to finish...

Thread  is starting

    Thread : job  delay =

    Thread : job  delay =

    Thread : job  delay =

Thread  finished

Thread  is starting

Thread  joined

    Thread : job  delay =

    Thread : job  delay =

    Thread : job  delay =

Thread  finished

Thread  is starting

    Thread : job  delay =

    Thread : job  delay =

    Thread : job  delay =

Thread  finished

Thread  joined

Thread  joined 

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