我的程序设置如下:
有一个线程安全的队列类,一个线程在无限循环中将数据推送到它上面,另一个线程在坐在无限循环中时从中弹出数据。我试图想办法使用Windows事件或其他机制来创建thread_1(下面),在无限循环中等待,并且只在队列深度大于或等于1时进行迭代。
class thread-safe_Queue
{
public:
push();
pop();
};
DWORD thread_1()
{
while(1)
{
// wait for thread-safe queue to have data on it
// pop data off
// process data
}
}
DWORD thread_2()
{
while(1)
{
// when data becomes available, push data onto thread-safe queue
}
}
答案 0 :(得分:2)
我认为这可能会成功。派生类Event并重载Process()函数。
#include <process.h> // Along with all the normal windows includes
//*********************************************
using namespace os;
Mutex globalQueueMutex;
class QueueReader : public Event
{
public:
virtual void Process()
{
// Lock the queue
Locker l(globalQueueMutex);
// pop data off
// process data
return; // queue will automatically unlock
}
};
QueueReader myQueueReader;
//*********************************************
// The queue writer would have functions like :
void StartQueueReader()
{
Thread(QueueReader::StartEventHandler, &myQueueReader);
}
void WriteToQueue()
{
Locker l(globalQueueMutex);
// write to the queue
myQueueReader.SignalProcess(); // tell reader to wake up
}
// When want to shutdown
void Shutdown()
{
myQueueReader.SignalShutdown();
}
以下是执行魔术的类。
namespace os {
// **********************************************************************
/// Windows implementation to spawn a thread.
static uintptr_t Thread (void (*StartAddress)(void *), void *ArgList)
{
return _beginthread(StartAddress, 0, ArgList);
}
// **********************************************************************
/// Windows implementation of a critical section.
class Mutex
{
public:
// Initialize section on construction
Mutex() { InitializeCriticalSection( &cs_ ); }
// Delete section on destruction
~Mutex() { DeleteCriticalSection( &cs_ ); }
// Lock it
void lock() { EnterCriticalSection( &cs_ ); }
// Unlock it
void unlock() { LeaveCriticalSection( &cs_ ); }
private:
CRITICAL_SECTION cs_;
}; // class Mutex
/// Locks/Unlocks a mutex
class Locker
{
public:
// Lock the mutex on construction
Locker( Mutex& mutex ): mutex_( mutex ) { mutex_.lock(); }
// Unlock on destruction
~Locker() { mutex_.unlock(); }
private:
Mutex& mutex_;
}; // class Locker
// **********************************************************************
// Windows implementation of event handler
#define ProcessEvent hEvents[0]
#define SetTimerEvent hEvents[1]
#define ShutdownEvent hEvents[2]
/// Windows implementation of events
class Event
{
/// Flag set when shutdown is complete
bool Shutdown;
/// Max time to wait for events
DWORD Timer;
/// The three events - process, reset timer, and shutdown
HANDLE hEvents[3];
public:
/// Timeout is disabled by default and Events assigned
Event( DWORD timer = INFINITE) : Timer(timer)
{
Shutdown = false;
ProcessEvent = CreateEvent( NULL,TRUE,FALSE,NULL );
SetTimerEvent = CreateEvent( NULL,TRUE,FALSE,NULL );
ShutdownEvent = CreateEvent( NULL,TRUE,FALSE,NULL );
}
/// Close the event handles
virtual ~Event()
{
CloseHandle(ProcessEvent);
CloseHandle(SetTimerEvent);
CloseHandle(ShutdownEvent);
}
/// os::Thread calls this to start the Event handler
static void StartEventHandler(void *pMyInstance)
{ ((Event *)pMyInstance)->EventHandler(); }
/// Call here to Change/Reset the timeout timer
void ResetTimer(DWORD timer) { Timer = timer; SetEvent(SetTimerEvent); }
/// Set the signal to shutdown the worker thread processing events
void SignalShutdown() { SetEvent(ShutdownEvent); while (!Shutdown) Sleep(30);}
/// Set the signal to run the process
void SignalProcess() { SetEvent(ProcessEvent); }
protected:
/// Overload in derived class to process events with worker thread
virtual void Process(){}
/// Override to process timeout- return true to terminate thread
virtual bool Timeout(){ return true;}
/// Monitor thread events
void EventHandler()
{
DWORD WaitEvents;
while (!Shutdown)
{
// Wait here, looking to be signaled what to do next
WaitEvents = WaitForMultipleObjects(3, hEvents, FALSE, Timer);
switch (WaitEvents)
{
// Process event - process event then reset for the next one
case WAIT_OBJECT_0 + 0:
Process();
ResetEvent(ProcessEvent);
break;
// Change timer event - see ResetTimer(DWORD timer)
case WAIT_OBJECT_0 + 1:
ResetEvent(SetTimerEvent);
continue;
// Shutdown requested so exit this thread
case WAIT_OBJECT_0 + 2:
Shutdown = true;
break;
// Timed out waiting for an event
case WAIT_TIMEOUT:
Shutdown = Timeout();
break;
// Failed - should never happen
case WAIT_FAILED:
break;
default:
break;
}
}
}
};
} // namespace os
答案 1 :(得分:0)
这个怎么样(我假设你熟悉事件机制)。
1
thread_safe_Queue::push(something)
{
// lock the queue
...
// push object
// Signal the event
SetEvent(notification);
// unlock the queue
}
2
thread_safe_Queue::pop(something)
{
WaitForSingleObject(notification);
// lock the queue
...
// get object
// reset the event
if (queue is empty)
ResetEvent(notification);
// unlock the queue
}
3。 thread_1只是试图弹出对象并处理它。在推送某些内容时,会启用该事件,因此可以成功调用pop。否则它将在pop内等待。实际上,您可以使用其他同步对象,例如互斥锁或关键部分,而不是这种情况下的事件。
更新。外部事件: 线程1:
void thread_1()
{
while(1)
{
WaitForSingleObject(notification);
if (!pop(object)) // pop should return if there are any objects left in queue
SetEvent(notification);
}
}
thread_2
void thread_2()
{
while(1)
{
// push the object and than signal event
ResetEvent(notification)
}
}
答案 2 :(得分:0)
您可以使用命名事件。每个线程都会调用以相同名称传递的CreateEvent。然后使用WaitForMultipleObjects等待队列相关事件或结束程序事件。 pop线程将等待queue_has_data和end_program事件。 push线程将等待data_available和end_program事件,并在将某些内容放入队列时设置queue_has_data事件。