在多线程程序中,所有线程共享程序中的变量。现在有一全局变量,所有线程都可以使用它,改变它的值。而如果每个线程希望能单独拥有它,那么就需要使用线程存储了。表面上看起来这是一个全局变量,所有线程都可以使用它,而它的值在每一个线程中又是单独存储的。这就是线程存储(Thread-specific Data,或称为 TSD)的意义。
#include <pthread.h>
int pthread_setspecific(pthread_key_t key, const void *value);
void *pthread_getspecific(pthread_key_t key);
int pthread_key_create(pthread_key_t *key, void (*destructor)(void*));
int pthread_key_delete(pthread_key_t key);
pthread_key_create()
用来创建线程私有数据。该函数从 TSD 池中分配一项,将其地址值赋给 key
供以后访问使用。第 2 个参数是一个销毁函数,它是可选的,可以为 NULL
,为 NULL
时,则系统调用默认的销毁函数进行相关的数据注销。如果不为空,则在线程退出时(调用 pthread_exit()
函数)时将以 key
关联的数据作为参数调用它,以释放分配的缓冲区,或是关闭文件流等。测试一:
#include <stdio.h>
#include <stdlib.h>
#include <pthread.h>
#include <unistd.h>
pthread_key_t key;
struct test_struct
{
int i;
float f;
};
void *worker1(void *arg)
{
test_struct test{1, 3.14};
pthread_setspecific(key, &test);
printf("test addr is:%p\n", &test);
test_struct *addr = (test_struct *)pthread_getspecific(key);
printf("worker1 pthread_getpecific(key) addr is:%p\n", addr);
printf("worker1 pthread_getspecific(key) test value is:{%d,%f}\n", addr->i, addr->f);
printf("------------------------------------------------------\n");
}
void *worker2(void *arg)
{
int temp = 20;
sleep(2);
printf("worker2 temp addr is:%p\n", &temp);
pthread_setspecific(key, &temp);
int *addr = (int *)pthread_getspecific(key);
printf("worker2 pthread_getpecific(key) addr is:%p\n", addr);
printf("worker2 pthread_getpecific(key) value is:%d\n", *addr);
}
int main()
{
pthread_t tid1, tid2;
pthread_key_create(&key, NULL);
pthread_create(&tid1, NULL, worker1, NULL);
pthread_create(&tid2, NULL, worker2, NULL);
pthread_join(tid1, NULL);
pthread_join(tid2, NULL);
pthread_key_delete(key);
return 0;
}
测试二:
#include <stdio.h>
#include <stdlib.h>
#include <pthread.h>
#include <unistd.h>
pthread_key_t thread_log_key;
void write_to_thread_log(const char* message)
{
FILE* thread_log = (FILE*)pthread_getspecific(thread_log_key);
fprintf(thread_log,"%s\n",message);
}
void close_thread_log(void* thread_log)
{
fclose((FILE*)thread_log);
}
void *thread_function(void* args)
{
char thread_log_filename[128];
char thread_start_message[128];
FILE* thread_log;
sprintf(thread_log_filename,"thread%u.log",(unsigned int)pthread_self());
thread_log = fopen(thread_log_filename,"w");
pthread_setspecific(thread_log_key,thread_log);
sprintf(thread_start_message,"thread %u starting",(unsigned int)pthread_self());
write_to_thread_log(thread_start_message);
pthread_exit(NULL);
}
int main()
{
int i;
pthread_t threads[5];
pthread_key_create(&thread_log_key,close_thread_log);
for(int i = 0;i < 5;++i)
pthread_create(&threads[i],NULL,thread_function,NULL);
for(i = 0;i < 5;++i)
pthread_join(threads[i],NULL);
return 0;
}
#pragma once
#include "Mutex.h"
#include "NonCopyable.h"
namespace muduo
{
template<typename T>
class ThreadLocal : NonCopyable
{
public:
ThreadLocal()
{
MCHECK(pthread_key_create(&pkey_,&ThreadLocal::destructor));
}
~ThreadLocal()
{
MCHECK(pthread_key_delete(pkey_));
}
T& value()
{
T* per_thread_value = static_cast<T*>(pthread_getspecific(pkey_));
if(!per_thread_value)
{
T* new_obj = new T();
MCHECK(pthread_setspecific(pkey_,new_obj));
per_thread_value = new_obj;
}
return *per_thread_value;
}
private:
static void destructor(void* x)
{
T* obj = static_cast<t*>(x);
typedef char T_must_be_complete_type[sizeof(T) == 0 ? -1 : 1];
T_must_be_complete_type dummy;
(void)dummy;
delete obj;
}
private:
pthread_key_t pkey_;
};
}
原文:https://www.cnblogs.com/xiaojianliu/p/14702040.html