线程按照其调度者可以分为用户级线程和核心级线程两种
用户级线程主要解决的是上下文切换的问题,它的调度算法和调度过程全部由用户自行选择决定,在运行时不需要特定的内核支持;
我们常用基本就是用户级线程,所以就只总结一下POSIX提供的用户级线程接口;
基本线程操作相关的函数:
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
基本线程操作:
函数 | 说明 |
---|---|
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 |
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 |
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 |
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 |
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. |
pthread_setcancelstate() | 设置本线程对Cancel信号的反应 |
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 |
pthread_setcancel() | 设置取消状态 |
互斥与同步机制基本函数
函数 | 说明 |
---|---|
pthread_mutex_init() | 互斥锁的初始化 |
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 |
pthread_mutex_trylock() | 非阻塞的锁定互斥锁 |
pthread_mutex_unlock() | 释放互斥锁 |
pthread_mutex_destory() | 互斥锁销毁函数 |
信号量线程控制(默认无名信号量)
函数 | 说明 |
---|---|
sem_init(sem) | 初始化一个定位在sem的匿名信号量 |
sem_wait() | 把信号量减1操作,如果信号量的当前值为0则进入阻塞,为原子操作 |
sem_trywait() | 如果信号量的当前值为0则返回错误而不是阻塞调用(errno=EAGAIN),其实是sem_wait()的非阻塞版本 |
sem_post() | 给信号量的值加1,它是一个“原子操作”,即同时对同一个信号量做加1,操作的两个线程是不会冲突的 |
sem_getvalue(sval) | 把sem指向的信号量当前值放置在sval指向的整数上 |
sem_destory(sem) | 销毁由sem指向的匿名信号量 |
线程属性配置相关函数
函数 | 说明 |
---|---|
pthread_attr_init() | 初始化配置一个线程对象的属性,需要用pthread_attr_destroy函数去除已有属性 |
pthread_attr_setscope() | 设置线程属性 |
pthread_attr_setschedparam() | 设置线程优先级 |
pthread_attr_getschedparam() | 获取线程优先级 |
/* thread.c */
#include
#include
#include
#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 = 0;
int count = 0;
printf("Thread %d is starting\n", thrd_num);
for (count = 0; count < REPEAT_NUMBER; count++) {
delay_time = (int)(rand() * DELAY_TIME_LEVELS/(RAND_MAX)) + 1;
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 = 0, res;
void * thrd_ret;
srand(time(NULL));
for (no = 0; no < THREAD_NUMBER; no++) {
/* 创建多线程 */
res = pthread_create(&thread[no], NULL, thrd_func, (void*)no);
if (res != 0) {
printf("Create thread %d failed\n", no);
exit(res);
}
}
printf("Create treads success\n Waiting for threads to finish...\n");
for (no = 0; 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 0;
}
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 0 is starting
Thread 1 is starting
Thread 2 is starting
Thread 1: job 0 delay = 2
Thread 1: job 1 delay = 2
Thread 0: job 0 delay = 8
Thread 2: job 0 delay = 10
Thread 2: job 1 delay = 3
Thread 1: job 2 delay = 10
Thread 0: job 1 delay = 8
Thread 0: job 2 delay = 3
Thread 0: job 3 delay = 1
Thread 2: job 2 delay = 8
Thread 1: job 3 delay = 8
Thread 1: job 4 delay = 1
Thread 1 finished
Thread 2: job 3 delay = 6
Thread 0: job 4 delay = 7
Thread 0 finished
Thread 0 joined
Thread 1 joined
Thread 2: job 4 delay = 10
Thread 2 finished
Thread 2 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;
在上面的程序中增加互斥锁
/*thread_mutex.c*/
#include
#include
#include
#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 = 0, count = 0;
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 = 0; count < REPEAT_NUMBER; count++) {
delay_time = (int)(rand() * DELAY_TIME_LEVELS/(RAND_MAX)) + 1;
sleep(delay_time);
printf("\tThread %d: job %d delay = %d\n",
thrd_num, count, delay_time);
}
printf("Thread %d finished\n", thrd_num);
pthread_mutex_unlock(&mutex);
pthread_exit(NULL);
}
int main(void) {
pthread_t thread[THREAD_NUMBER];
int no = 0, res;
void * thrd_ret;
srand(time(NULL));
/* 互斥锁初始化 */
pthread_mutex_init(&mutex, NULL);
for (no = 0; no < THREAD_NUMBER; no++) {
res = pthread_create(&thread[no], NULL, thrd_func, (void*)no);
if (res != 0) {
printf("Create thread %d failed\n", no);
exit(res);
}
}
printf("Create treads success\n Waiting for threads to finish...\n");
for (no = 0; 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);
}
}
/****互斥锁解锁***/
//pthread_mutex_unlock(&mutex); // 互斥锁需要在线程中进行解锁
pthread_mutex_destroy(&mutex);
return 0;
}
在上面的例程中直接添加同步锁pthread_mutex_t;
在线程中加入,于是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
$gcc thread_mutex.c -lpthread
$ ./a.out
Create treads success
Waiting for threads to finish...
Thread 0 is starting
Thread 0: job 0 delay = 9
Thread 0: job 1 delay = 4
Thread 0: job 2 delay = 7
Thread 0 finished
Thread 0 joined
Thread 1 is starting
Thread 1: job 0 delay = 6
Thread 1: job 1 delay = 4
Thread 1: job 2 delay = 7
Thread 1 finished
Thread 1 joined
Thread 2 is starting
Thread 2: job 0 delay = 3
Thread 2: job 1 delay = 1
Thread 2: job 2 delay = 6
Thread 2 finished
Thread 2 joined
跟例程1中执行结果不同,线程程序被加载到队列中而不能马上执行,需要等到能够成功上锁;
上锁后,继续执行线程程序,上锁执行;
这样线程被依次执行的情况在实际使用场景中经常出现;
使用场景:
当用户登录后获取秘钥才能继续获取该用户的基本信息时;需要等待登录线程结束后才能继续执行获取用户信息的线程时,
需要调用两条线程,假如是:threadLogin(),threadGetInfo(); 则可以有2种方法实现:
1 此时可以使用互斥锁同时一次性调用完threadLogin()和threadGetInfo();
2 当然也可以不使用互斥锁直接在threadLogin()中登录验证成功后调用threadGetInfo();
相比之下,方式1更加清晰的显示逻辑关系,增加代码可读性可扩展性。
修改上面例程,上面的是使用pthread_mutex_lock互斥锁控制线程执行顺序,
使用另外一种线程执行顺序的控制;
/* thread_sem.c */
#include
#include
#include
#include
#define THREAD_NUMBER 3
#define REPEAT_NUMBER 3
#define DELAY_TIME_LEVELS 10.0
sem_t sem[THREAD_NUMBER];
void * thrd_func(void *arg) {
int thrd_num = (int)arg;
int delay_time = 0;
int count = 0;
sem_wait(&sem[thrd_num]);
printf("Thread %d is starting\n", thrd_num);
for (count = 0; count < REPEAT_NUMBER; count++) {
delay_time = (int)(rand() * DELAY_TIME_LEVELS/(RAND_MAX)) + 1;
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 = 0, res;
void * thrd_ret;
srand(time(NULL));
for (no = 0; no < THREAD_NUMBER; no++) {
sem_init(&sem[no], 0, 0);
res = pthread_create(&thread[no], NULL, thrd_func, (void*)no);
if (res != 0) {
printf("Create thread %d failed\n", no);
exit(res);
}
}
printf("Create treads success\n Waiting for threads to finish...\n");
sem_post(&sem[THREAD_NUMBER - 1]);
for (no = THREAD_NUMBER - 1; no >= 0; no--) {
res = pthread_join(thread[no], &thrd_ret);
if (!res) {
printf("Thread %d joined\n", no);
} else {
printf("Thread %d join failed\n", no);
}
sem_post(&sem[(no + THREAD_NUMBER - 1) % THREAD_NUMBER]);
}
for (no = 0; no < THREAD_NUMBER; no++) {
sem_destroy(&sem[no]);
}
return 0;
}
执行结果,仍然是建立3条线程,每条线程执行时休眠随机时长:
$ gcc thread_sem.c -lpthread
$ ./a.out
Create treads success
Waiting for threads to finish...
Thread 2 is starting
Thread 2: job 0 delay = 9
Thread 2: job 1 delay = 9
Thread 2: job 2 delay = 5
Thread 2 finished
Thread 2 joined
Thread 1 is starting
Thread 1: job 0 delay = 5
Thread 1: job 1 delay = 7
Thread 1: job 2 delay = 4
Thread 1 finished
Thread 1 joined
Thread 0 is starting
Thread 0: job 0 delay = 3
Thread 0: job 1 delay = 9
Thread 0: job 2 delay = 8
Thread 0 finished
Thread 0 joined
执行结果与第2个例程非常相似,只不过教材中进行倒序执行而已;
那么这种方式其实与使用互斥锁相比,代码量可读性基本持平不相上下;
设置属性一般有:
1 绑定属性
2 分离属性
3 堆栈地址
4 堆栈大小
5 优先级
关于绑定属性就是绑定于内核线程;
分离属性主要是讲线程结束后是否马上释放相应的内存;
/* thread_attr.c */
#include
#include
#include
#define THREAD_NUMBER 1
#define REPEAT_NUMBER 3
#define DELAY_TIME_LEVELS 10.0
int finish_flag = 0;
void * thrd_func(void * arg){
int delay_time = 0;
int count = 0;
printf("Thread is starting\n");
for (count = 0; count < REPEAT_NUMBER; count++) {
delay_time = (int)(rand() * DELAY_TIME_LEVELS/(RAND_MAX)) + 1;
sleep(delay_time);
printf("\tThread : job %d delay = %d\n", count, delay_time);
}
printf("Thread finished\n");
finish_flag = 1;
pthread_exit(NULL);
}
int main(void) {
pthread_t thread;
pthread_attr_t attr;
int res = 0;
srand(time(NULL));
res = pthread_attr_init(&attr);
if (res != 0) {
printf("Create attribute failed\n");
exit(res);
}
res = pthread_attr_setscope(&attr, PTHREAD_SCOPE_SYSTEM);
res += pthread_attr_setdetachstate(&attr, PTHREAD_CREATE_DETACHED);
if (res != 0) {
printf("Setting attribute failed\n");
exit(res);
}
res = pthread_create(&thread, &attr, thrd_func, NULL);
if (res != 0) {
printf("Create thread failed\n");
exit(res);
}
pthread_attr_destroy(&attr);
printf("Create tread success\n");
while(!finish_flag){
printf("Waiting for thread to finish...\n");
sleep(2);
}
return 0;
}
在运行前后使用 $ free 命令查看内存前后的使用情况发现:
在线程结束后内存马上被释放;
其实,一般线程的属性直接使用系统默认属性即可;
关于线程的使用,基本如此;
所有例程来自:《嵌入式Linux应用程序开发标准教程》