Linux平台用C++实现事件对象，同步线程（转）

本文属于转载，原文链接如下:/article/2269252.html

与其相关的一组API包括：pthread_mutex_init，pthread_cond_init，pthread_mutex_lock，pthread_cond_wait，pthread_mutex_unlock，pthread_cond_broadcast，pthread_cond_timedwait，pthread_cond_destroy，pthread_mutex_destroy。

MyEvent.h

#ifndef My_Event_Header
#define My_Event_Header

#include <iostream>
#include <pthread.h>
#include <errno.h>

using namespace std;

//---------------------------------------------------------------

class CEventImpl
{
protected:

/*
动态方式初始化互斥锁,初始化状态变量m_cond
`bAutoReset  true   人工重置
false  自动重置
*/
CEventImpl(bool manualReset);

/*
注销互斥锁,注销状态变量m_cond
*/
~CEventImpl();

/*
将当前事件对象设置为有信号状态
若自动重置，则等待该事件对象的所有线程只有一个可被调度
若人工重置，则等待该事件对象的所有线程变为可被调度
*/
void SetImpl();

/*
以当前事件对象，阻塞线程，将其永远挂起
直到事件对象被设置为有信号状态
*/
bool WaitImpl();

/*
以当前事件对象，阻塞线程，将其挂起指定时间间隔
之后线程自动恢复可调度
*/
bool WaitImpl(long milliseconds);

/*
将当前事件对象设置为无信号状态
*/
void ResetImpl();

private:
bool            m_manual;
volatile bool   m_state;
pthread_mutex_t m_mutex;
pthread_cond_t  m_cond;
};

inline void CEventImpl::SetImpl()
{
if (pthread_mutex_lock(&m_mutex))
cout<<"cannot signal event (lock)"<<endl;

//设置状态变量为true，对应有信号
m_state = true;

//cout<<"CEventImpl::SetImpl m_state = "<<m_state<<endl;

//重新激活所有在等待m_cond变量的线程
if (pthread_cond_broadcast(&m_cond))
{
pthread_mutex_unlock(&m_mutex);
cout<<"cannot signal event"<<endl;
}
pthread_mutex_unlock(&m_mutex);
}

inline void CEventImpl::ResetImpl()
{
if (pthread_mutex_lock(&m_mutex))
cout<<"cannot reset event"<<endl;

//设置状态变量为false，对应无信号
m_state = false;

//cout<<"CEventImpl::ResetImpl m_state = "<<m_state<<endl;

pthread_mutex_unlock(&m_mutex);
}

//---------------------------------------------------------------

class CMyEvent: private CEventImpl
{
public:
CMyEvent(bool bManualReset = true);
~CMyEvent();

void Set();
bool Wait();
bool Wait(long milliseconds);
bool TryWait(long milliseconds);
void Reset();

private:
CMyEvent(const CMyEvent&);
CMyEvent& operator = (const CMyEvent&);
};

inline void CMyEvent::Set()
{
SetImpl();
}

inline bool CMyEvent::Wait()
{
return WaitImpl();
}

inline bool CMyEvent::Wait(long milliseconds)
{
if (!WaitImpl(milliseconds))
{
cout<<"time out"<<endl;
return false;
}
else
{
return true;
}
}

inline bool CMyEvent::TryWait(long milliseconds)
{
return WaitImpl(milliseconds);
}

inline void CMyEvent::Reset()
{
ResetImpl();
}

#endif

MyEvent.cpp

#include "MyEvent.h"
#include <sys/time.h>

CEventImpl::CEventImpl(bool manualReset): m_manual(manualReset), m_state(false)
{
if (pthread_mutex_init(&m_mutex, NULL))
cout<<"cannot create event (mutex)"<<endl;
if (pthread_cond_init(&m_cond, NULL))
cout<<"cannot create event (condition)"<<endl;
}

CEventImpl::~CEventImpl()
{
pthread_cond_destroy(&m_cond);
pthread_mutex_destroy(&m_mutex);
}

bool CEventImpl::WaitImpl()
{
if (pthread_mutex_lock(&m_mutex))
{
cout<<"wait for event failed (lock)"<<endl;
return false;
}
while (!m_state)
{
//cout<<"CEventImpl::WaitImpl while m_state = "<<m_state<<endl;

//对互斥体进行原子的解锁工作,然后等待状态信号
if (pthread_cond_wait(&m_cond, &m_mutex))
{
pthread_mutex_unlock(&m_mutex);
cout<<"wait for event failed"<<endl;
return false;
}
}
if (m_manual)
m_state = false;
pthread_mutex_unlock(&m_mutex);

//cout<<"CEventImpl::WaitImpl end m_state = "<<m_state<<endl;

return true;
}

bool CEventImpl::WaitImpl(long milliseconds)
{
int rc = 0;
struct timespec abstime;
struct timeval tv;
gettimeofday(&tv, NULL);
abstime.tv_sec  = tv.tv_sec + milliseconds / 1000;
abstime.tv_nsec = tv.tv_usec*1000 + (milliseconds % 1000)*1000000;
if (abstime.tv_nsec >= 1000000000)
{
abstime.tv_nsec -= 1000000000;
abstime.tv_sec++;
}

if (pthread_mutex_lock(&m_mutex) != 0)
{
cout<<"wait for event failed (lock)"<<endl;
return false;
}
while (!m_state)
{
//自动释放互斥体并且等待m_cond状态,并且限制了最大的等待时间
if ((rc = pthread_cond_timedwait(&m_cond, &m_mutex, &abstime)))
{
if (rc == ETIMEDOUT) break;
pthread_mutex_unlock(&m_mutex);
cout<<"cannot wait for event"<<endl;
return false;
}
}
if (rc == 0 && m_manual)
m_state = false;
pthread_mutex_unlock(&m_mutex);
return rc == 0;
}

CMyEvent::CMyEvent(bool bManualReset): CEventImpl(bManualReset)
{
}

CMyEvent::~CMyEvent()
{
}

测试代码如下所示：pthread_event.cpp

// pthread_event.cpp : 定义控制台应用程序的入口点。
//

#include <unistd.h>
#include "MyEvent.h"

#define PRINT_TIMES 10

//创建一个人工自动重置事件对象
CMyEvent g_myEvent;
int g_iNum = 0;

//线程函数1
void * ThreadProc1(void *pParam)
{
for (int i = 0; i < PRINT_TIMES; i++)
{
g_iNum++;
cout<<"ThreadProc1 do print, Num = "<<g_iNum<<endl;

//设置事件为有信号状态
g_myEvent.Set();

sleep(1);
}

return (void *)0;
}

//线程函数2
void * ThreadProc2(void *pParam)
{
bool bRet = false;
while ( 1 )
{
if ( g_iNum >= PRINT_TIMES )
{
break;
}

//以当前事件对象阻塞本线程，将其挂起
bRet = g_myEvent.Wait();
if ( bRet )
{
cout<<"ThreadProc2 do print, Num = "<<g_iNum<<endl;

//设置事件为无信号状态
g_myEvent.Reset();
}
else
{
cout<<"ThreadProc2 system exception"<<endl;
}
}

return (void *)0;
}

int main(int argc, char* argv[])
{
pthread_t thread1,thread2;
pthread_attr_t attr1,attr2;

//创建两个工作线程
pthread_attr_init(&attr1);
pthread_attr_setdetachstate(&attr1,PTHREAD_CREATE_JOINABLE);
if (pthread_create(&thread1,&attr1, ThreadProc1,NULL) == -1)
{
cout<<"Thread 1: create failed"<<endl;
}
pthread_attr_init(&attr2);
pthread_attr_setdetachstate(&attr2,PTHREAD_CREATE_JOINABLE);
if (pthread_create(&thread2,&attr2, ThreadProc2,NULL) == -1)
{
cout<<"Thread 2: create failed"<<endl;
}

//等待线程结束
void *result;
pthread_join(thread1,&result);
pthread_join(thread2,&result);

//关闭线程，释放资源
pthread_attr_destroy(&attr1);
pthread_attr_destroy(&attr2);

int iWait;
cin>>iWait;

return 0;
}

编译运行结果如下所示：