linux——线程

在 Linux 系统中，进程和线程是两种重要的并发执行单元。本文将详细介绍它们的区别、使用场景、以及多线程编程中的关键API和示例代码。

进程与线程的区别

进程

• 进程是程序运行的一个实例，承担分配系统资源的基本单位。
• 每个进程都有独立的地址空间，一个进程崩溃不会影响其他进程。
• 进程的创建和切换消耗较多资源。

线程

• 线程是进程中的一个执行路径，是CPU调度的基本单位。
• 线程共享进程的地址空间，但每个线程有自己的堆栈和局部变量。
• 线程的创建和切换开销较小。
• 如果一个线程崩溃，会导致整个进程崩溃。

使用线程的理由

1. 节省资源：创建进程需要分配独立的地址空间，建立多个数据表来维护其代码段、数据段和堆栈段，这种方式十分昂贵。线程共享同一进程的地址空间和大部分数据，启动一个线程比启动一个进程要快很多。一个进程的开销大约是一个线程的30倍。
2. 方便的通信机制：不同进程之间的数据传递需要通过通信机制，如管道、信号等，这种方式耗时且复杂。而线程共享进程的数据空间，数据共享非常方便和快捷，但需要注意数据同步的问题。

多线程开发及API

多线程开发主要包含三点：线程、互斥锁、条件变量。以下是具体的操作和API介绍：

线程操作

线程的创建

#include <pthread.h>
int pthread_create(pthread_t *restrict tidp, const pthread_attr_t *restrict attr, void *(*start_rtn)(void *), void *restrict arg);
// 返回：若成功返回0，否则返回错误编号

线程的获取和比较

#include <pthread.h>
pthread_t pthread_self(void);

线程的等待

#include <pthread.h>
int pthread_join(pthread_t thread, void **rval_ptr);
// 参数：
// pthread_t thread：等待的线程
// void **rval：线程退出状态的收回，NULL表示不收回

线程的退出

#include <pthread.h>
int pthread_exit(void *rval_ptr);

线程的创建、退出、等待示例

#include <stdio.h>
#include <pthread.h>void *func1(void *arg)
{static int ret = 10;printf("t1:%ld thread is created\n", (unsigned long)pthread_self());printf("t1: parameter is %d\n", *((int *)arg));pthread_exit((void*)&ret); // 线程退出
}int main()
{int ret;int param = 100;int *pret = NULL;pthread_t t1;ret = pthread_create(&t1, NULL, func1, (void*)&param); // 创建线程if(ret == 0){printf("main: create t1 success\n");}printf("main: %ld\n", (unsigned long)pthread_self()); // 获取线程IDpthread_join(t1, (void**)&pret); // 等待线程退出printf("main: t1 quit with %d\n", *pret);return 0;
}

传入一个结构体的线程创建示例

#include <stdio.h>
#include <pthread.h>
#include <stdlib.h>struct data
{int a;char *s;
};void *func1(void *arg)
{static char *x = "t1 run out";struct data *temp;temp = (struct data*)arg;printf("t1:%ld pthread is created\n", (unsigned long)pthread_self());printf("t1: %d\n", temp->a);printf("t1: %s\n", temp->s);pthread_exit((void*)x);
}int main()
{int ret;pthread_t t1;char *pret = NULL;struct data *p = (struct data*)malloc(sizeof(struct data));p->a = 1;p->s = "xiancheng";ret = pthread_create(&t1, NULL, func1, (void*)p);if(ret == 0){printf("main: create t1 success\n");}printf("main: %ld\n", (unsigned long)pthread_self());pthread_join(t1, (void**)&pret);printf("main: t1 quit with %s\n", pret);free(p);return 0;
}

线程共享空间验证示例

#include <stdio.h>
#include <pthread.h>
#include <unistd.h>int g_data = 10;void *func1(void *arg)
{printf("t1:%ld thread is created\n", (unsigned long)pthread_self());printf("t1: parameter is %d\n", *((int*)arg));while(1){printf("%d\n", g_data++);sleep(1);if(g_data == 3){pthread_exit(NULL);}}
}void *func2(void *arg)
{printf("t2:%ld thread is created\n", (unsigned long)pthread_self());printf("t2: parameter is %d\n", *((int*)arg));while(1){printf("%d\n", g_data++);sleep(1);}
}int main()
{int ret;int param = 100;pthread_t t1;pthread_t t2;ret = pthread_create(&t1, NULL, func1, (void*)&param);if(ret == 0){printf("main: create t1 success\n");}ret = pthread_create(&t2, NULL, func2, (void*)&param);if(ret == 0){printf("main: create t2 success\n");}printf("main: %ld\n", (unsigned long)pthread_self());while(1){printf("%d\n", g_data++);sleep(1);} pthread_join(t1, NULL);pthread_join(t2, NULL);return 0;
}

互斥锁（Mutex）

互斥锁API

创建及销毁互斥锁

#include <pthread.h>
int pthread_mutex_init(pthread_mutex_t *restrict mutex, const pthread_mutexattr_t *restrict attr);
int pthread_mutex_destroy(pthread_mutex_t *restrict mutex);

加锁及解锁

#include <pthread.h>
int pthread_mutex_lock(pthread_mutex_t *restrict mutex);
int pthread_mutex_trylock(pthread_mutex_t *restrict mutex);
int pthread_mutex_unlock(pthread_mutex_t *restrict mutex);

使用互斥锁的示例

#include <stdio.h>
#include <pthread.h>
#include <unistd.h>int g_data = 0;
pthread_mutex_t mutex; // 定义锁void *func1(void *arg)
{pthread_mutex_lock(&mutex); // 加锁for(int i = 0; i < 5; i++){printf("t1: %ld thread is created\n", (unsigned long)pthread_self());printf("t1: parameter is %d\n", *((int*)arg));sleep(1);}pthread_mutex_unlock(&mutex); // 解锁
}void *func2(void *arg)
{pthread_mutex_lock(&mutex);for(int i = 0; i < 5; i++){printf("t2: %ld thread is created\n", (unsigned long)pthread_self());printf("t2: parameter is %d\n", *((int*)arg));sleep(1);}pthread_mutex_unlock(&mutex);
}void *func3(void *arg)
{pthread_mutex_lock(&mutex);for(int i = 0; i < 5; i++){printf("t3: %ld thread is created\n", (unsigned long)pthread_self());printf("t3: parameter is %d\n", *((int*)arg));sleep(1);}pthread_mutex_unlock(&mutex);
}int main()
{int ret;int param = 100;pthread_t t1;pthread_t t2;pthread_t t3;pthread_mutex_init(&mutex, NULL); // 初始化锁ret = pthread_create(&t1, NULL, func1, (void*)&param);if(ret == 0){printf("main: create t1 success\n");}ret = pthread_create(&t2, NULL, func2, (void*)&param);if(ret == 0){printf("main: create t2 success\n");}ret = pthread_create(&t3, NULL, func3, (void*)&param);if(ret == 0){printf("main: create t3 success\n");}printf("main: %ld\n", (unsigned long)pthread_self());pthread_join(t1, NULL);pthread_join(t2, NULL);pthread_join(t3, NULL);pthread_mutex_destroy(&mutex); // 收回锁return 0;
}

互斥锁限制共享资源的访问示例

#include <stdio.h>
#include <pthread.h>
#include <unistd.h>int g_data = 0;
pthread_mutex_t mutex;void *func1(void *arg)
{printf("t1: %ld pthread is created\n", (unsigned long)pthread_self());printf("t1: parameter is %d\n", *((int*)arg));while(1){pthread_mutex_lock(&mutex);printf("%d\n", g_data++);sleep(1);if(g_data == 3){pthread_mutex_unlock(&mutex);pthread_exit(NULL);}}
}void *func2(void *arg)
{printf("t2: %ld pthread is created\n", (unsigned long)pthread_self());printf("t2: parameter is %d\n", *((int*)arg));while(1){printf("%d\n", g_data);pthread_mutex_lock(&mutex);g_data++;pthread_mutex_unlock(&mutex);sleep(1); }
}int main()
{int ret;int param = 100;pthread_t t1;pthread_t t2;pthread_mutex_init(&mutex, NULL);ret = pthread_create(&t1, NULL, func1, (void*)&param);if(ret == 0){printf("main: create t1 success\n");}ret = pthread_create(&t2, NULL, func2, (void*)&param);if(ret == 0){printf("main: create t2 success\n");}printf("main: %ld\n", (unsigned long)pthread_self());pthread_join(t1, NULL);pthread_join(t2, NULL);pthread_mutex_destroy(&mutex);return 0;
}

死锁示例

#include <stdio.h>
#include <pthread.h>
#include <unistd.h>pthread_mutex_t mutex;
pthread_mutex_t mutex2;void *func1(void *arg)
{pthread_mutex_lock(&mutex);sleep(1);pthread_mutex_lock(&mutex2);for(int i = 0; i < 5; i++){printf("t1: %ld\n", (unsigned long)pthread_self());printf("t1: parameter is %d\n", *((int *)arg));sleep(1);}pthread_mutex_unlock(&mutex);pthread_mutex_unlock(&mutex2);
}void *func2(void *arg)
{pthread_mutex_lock(&mutex2);sleep(1);pthread_mutex_lock(&mutex);for(int i = 0; i < 5; i++){printf("t2: %ld\n", (unsigned long)pthread_self());printf("t2: parameter is %d\n", *((int *)arg));sleep(1);}pthread_mutex_unlock(&mutex2);pthread_mutex_unlock(&mutex);
}void *func3(void *arg)
{pthread_mutex_lock(&mutex);for(int i = 0; i < 5; i++){printf("t3: %ld\n", (unsigned long)pthread_self());printf("t3: parameter is %d\n", *((int *)arg));sleep(1);}pthread_mutex_unlock(&mutex);
}int main()
{int ret;int param = 100;pthread_t t1;pthread_t t2;pthread_t t3;pthread_mutex_init(&mutex, NULL);pthread_mutex_init(&mutex2, NULL);ret = pthread_create(&t1, NULL, func1, (void*)&param);if(ret == 0){printf("main: create t1 success\n");}ret = pthread_create(&t2, NULL, func2, (void*)&param);if(ret == 0){printf("main: create t2 success\n");}ret = pthread_create(&t3, NULL, func3, (void*)&param);if(ret == 0){printf("main: create t3 success\n");}printf("main: %ld\n", (unsigned long)pthread_self());pthread_join(t1, NULL);pthread_join(t2, NULL);pthread_join(t3, NULL);pthread_mutex_destroy(&mutex);pthread_mutex_destroy(&mutex2);return 0;
}

条件变量实现线程同步

条件变量API

创建及销毁条件变量

#include <pthread.h>
int pthread_cond_init(pthread_cond_t *restrict cond, const pthread_condattr_t *restrict attr);
int pthread_cond_destroy(pthread_cond_t cond);

等待

#include <pthread.h>
int pthread_cond_wait(pthread_cond_t *restrict cond, pthread_mutex_t *restrict mutex);
int pthread_cond_timedwait(pthread_cond_t *restrict cond, pthread_mutex_t *restrict mutex, const struct timespec *restrict timeout);

触发

#include <pthread.h>
int pthread_cond_signal(pthread_cond_t *restrict cond);
int pthread_cond_broadcast(pthread_cond_t cond);

使用条件变量的示例

#include <stdio.h>
#include <pthread.h>
#include <unistd.h>
#include <stdlib.h>int g_data = 0;
pthread_mutex_t mutex;
pthread_cond_t cond;void *func1(void *arg)
{static int cnt = 10;printf("t1: %ld pthread is created\n", (unsigned long)pthread_self());printf("t1: parameter is %d\n", *((int*)arg));while(1){pthread_cond_wait(&cond, &mutex); // 等待if(g_data == 3){printf("t1 run=========================\n");}printf("t1: %d\n", g_data);g_data = 0;sleep(1);if(cnt++ == 10){exit(1);}}
}void *func2(void *arg)
{printf("t2: %ld pthread is created\n", (unsigned long)pthread_self());printf("t2: parameter is %d\n", *((int*)arg));while(1){printf("t2: %d\n", g_data);pthread_mutex_lock(&mutex);printf("%d\n", g_data++);if(g_data == 3){pthread_cond_signal(&cond); // 触发}pthread_mutex_unlock(&mutex);sleep(1);}
}int main()
{int ret;int param = 100;pthread_t t1;pthread_t t2;pthread_cond_init(&cond, NULL);pthread_mutex_init(&mutex, NULL);ret = pthread_create(&t1, NULL, func1, (void *)&param);if(ret == 0){printf("main: create t1 success\n");}ret = pthread_create(&t2, NULL, func2, (void *)&param);if(ret == 0){printf("main: create t2 success\n");}pthread_join(t1, NULL);pthread_join(t2, NULL);pthread_mutex_destroy(&mutex);pthread_cond_destroy(&cond);return 0;
}

通过上述示例和API的讲解，本文详细介绍了Linux下进程与线程的区别、多线程开发的基本操作以及常见问题和解决方案。希望能够帮助大家更好地理解和使用多线程编程。