framework/delibs/deutil/deTimer.c - third_party/vulkan-cts - Git at Google

 /*-------------------------------------------------------------------------
  * drawElements Utility Library
  * ----------------------------
  *
  * Copyright 2014 The Android Open Source Project
  *
  * Licensed under the Apache License, Version 2.0 (the "License");
  * you may not use this file except in compliance with the License.
  * You may obtain a copy of the License at
  *
  *      http://www.apache.org/licenses/LICENSE-2.0
  *
  * Unless required by applicable law or agreed to in writing, software
  * distributed under the License is distributed on an "AS IS" BASIS,
  * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
  * See the License for the specific language governing permissions and
  * limitations under the License.
  *
  *//*!
  * \file
  * \brief Periodic timer.
  *//*--------------------------------------------------------------------*/

 #include "deTimer.h"
 #include "deMemory.h"
 #include "deThread.h"

 #if (DE_OS == DE_OS_WIN32)

 #define VC_EXTRALEAN
 #define WIN32_LEAN_AND_MEAN
 #include <windows.h>

 struct deTimer_s
 {
 	deTimerCallback		callback;
 	void*				callbackArg;

 	HANDLE				timer;
 };

 static void CALLBACK timerCallback (PVOID lpParameter, BOOLEAN timerOrWaitFired)
 {
 	const deTimer* timer = (const deTimer*)lpParameter;
 	DE_UNREF(timerOrWaitFired);

 	timer->callback(timer->callbackArg);
 }

 deTimer* deTimer_create (deTimerCallback callback, void* arg)
 {
 	deTimer* timer = (deTimer*)deCalloc(sizeof(deTimer));

 	if (!timer)
 		return DE_NULL;

 	timer->callback		= callback;
 	timer->callbackArg	= arg;
 	timer->timer		= 0;

 	return timer;
 }

 void deTimer_destroy (deTimer* timer)
 {
 	DE_ASSERT(timer);

 	if (deTimer_isActive(timer))
 		deTimer_disable(timer);

 	deFree(timer);
 }

 deBool deTimer_isActive (const deTimer* timer)
 {
 	return timer->timer != 0;
 }

 deBool deTimer_scheduleSingle (deTimer* timer, int milliseconds)
 {
 	BOOL ret;

 	DE_ASSERT(timer && milliseconds > 0);

 	if (deTimer_isActive(timer))
 		return DE_FALSE;

 	ret = CreateTimerQueueTimer(&timer->timer, NULL, timerCallback, timer, (DWORD)milliseconds, 0, WT_EXECUTEDEFAULT);

 	if (!ret)
 	{
 		DE_ASSERT(!timer->timer);
 		return DE_FALSE;
 	}

 	return DE_TRUE;
 }

 deBool deTimer_scheduleInterval (deTimer* timer, int milliseconds)
 {
 	BOOL ret;

 	DE_ASSERT(timer && milliseconds > 0);

 	if (deTimer_isActive(timer))
 		return DE_FALSE;

 	ret = CreateTimerQueueTimer(&timer->timer, NULL, timerCallback, timer, (DWORD)milliseconds, (DWORD)milliseconds, WT_EXECUTEDEFAULT);

 	if (!ret)
 	{
 		DE_ASSERT(!timer->timer);
 		return DE_FALSE;
 	}

 	return DE_TRUE;
 }

 void deTimer_disable (deTimer* timer)
 {
 	if (timer->timer)
 	{
 		const int	maxTries	= 100;
 		HANDLE		waitEvent	= CreateEvent(NULL, FALSE, FALSE, NULL);
 		int			tryNdx		= 0;
 		DE_ASSERT(waitEvent);

 		for (tryNdx = 0; tryNdx < maxTries; tryNdx++)
 		{
 			BOOL success = DeleteTimerQueueTimer(NULL, timer->timer, waitEvent);
 			if (success)
 			{
 				/* Wait for all callbacks to complete. */
 				DWORD res = WaitForSingleObject(waitEvent, INFINITE);
 				DE_ASSERT(res == WAIT_OBJECT_0);
 				DE_UNREF(res);
 				break;
 			}
 			else
 			{
 				DWORD err = GetLastError();
 				if (err == ERROR_IO_PENDING)
 					break; /* \todo [2013-03-21 pyry] Does this mean that callback is still in progress? */
 				deYield();
 			}
 		}

 		DE_ASSERT(tryNdx < maxTries);

 		CloseHandle(waitEvent);
 		timer->timer = 0;
 	}
 }

 #elif (DE_OS == DE_OS_UNIX || DE_OS == DE_OS_ANDROID || DE_OS == DE_OS_SYMBIAN || DE_OS == DE_OS_QNX)

 #include <signal.h>
 #include <time.h>

 struct deTimer_s
 {
 	deTimerCallback		callback;
 	void*				callbackArg;

 	timer_t				timer;

 	deBool				isActive;
 };

 static void timerCallback (union sigval val)
 {
 	const deTimer* timer = (const deTimer*)val.sival_ptr;
 	timer->callback(timer->callbackArg);
 }

 deTimer* deTimer_create (deTimerCallback callback, void* arg)
 {
 	deTimer*		timer = (deTimer*)deCalloc(sizeof(deTimer));
 	struct sigevent	sevp;

 	if (!timer)
 		return DE_NULL;

 	deMemset(&sevp, 0, sizeof(sevp));
 	sevp.sigev_notify			= SIGEV_THREAD;
 	sevp.sigev_value.sival_ptr	= timer;
 	sevp.sigev_notify_function	= timerCallback;

 	if (timer_create(CLOCK_REALTIME, &sevp, &timer->timer) != 0)
 	{
 		deFree(timer);
 		return DE_NULL;
 	}

 	timer->callback		= callback;
 	timer->callbackArg	= arg;
 	timer->isActive		= DE_FALSE;

 	return timer;
 }

 void deTimer_destroy (deTimer* timer)
 {
 	DE_ASSERT(timer);

 	timer_delete(timer->timer);
 	deFree(timer);
 }

 deBool deTimer_isActive (const deTimer* timer)
 {
 	return timer->isActive;
 }

 deBool deTimer_scheduleSingle (deTimer* timer, int milliseconds)
 {
 	struct itimerspec tspec;

 	DE_ASSERT(timer && milliseconds > 0);

 	if (timer->isActive)
 		return DE_FALSE;

 	tspec.it_value.tv_sec		= milliseconds / 1000;
 	tspec.it_value.tv_nsec		= (milliseconds % 1000) * 1000;
 	tspec.it_interval.tv_sec	= 0;
 	tspec.it_interval.tv_nsec	= 0;

 	if (timer_settime(timer->timer, 0, &tspec, DE_NULL) != 0)
 		return DE_FALSE;

 	timer->isActive = DE_TRUE;
 	return DE_TRUE;
 }

 deBool deTimer_scheduleInterval (deTimer* timer, int milliseconds)
 {
 	struct itimerspec tspec;

 	DE_ASSERT(timer && milliseconds > 0);

 	if (timer->isActive)
 		return DE_FALSE;

 	tspec.it_value.tv_sec		= milliseconds / 1000;
 	tspec.it_value.tv_nsec		= (milliseconds % 1000) * 1000;
 	tspec.it_interval.tv_sec	= tspec.it_value.tv_sec;
 	tspec.it_interval.tv_nsec	= tspec.it_value.tv_nsec;

 	if (timer_settime(timer->timer, 0, &tspec, DE_NULL) != 0)
 		return DE_FALSE;

 	timer->isActive = DE_TRUE;
 	return DE_TRUE;
 }

 void deTimer_disable (deTimer* timer)
 {
 	struct itimerspec tspec;

 	DE_ASSERT(timer);

 	tspec.it_value.tv_sec		= 0;
 	tspec.it_value.tv_nsec		= 0;
 	tspec.it_interval.tv_sec	= 0;
 	tspec.it_interval.tv_nsec	= 0;

 	timer_settime(timer->timer, 0, &tspec, DE_NULL);

 	/* \todo [2012-07-10 pyry] How to wait until all pending callbacks have finished? */

 	timer->isActive = DE_FALSE;
 }

 #else

 /* Generic thread-based implementation for OSes that lack proper timers. */

 #include "deThread.h"
 #include "deMutex.h"
 #include "deClock.h"

 typedef enum TimerState_e
 {
 	TIMERSTATE_INTERVAL = 0,	/*!< Active interval timer.		*/
 	TIMERSTATE_SINGLE,			/*!< Single callback timer.		*/
 	TIMERSTATE_DISABLED,		/*!< Disabled timer.			*/

 	TIMERSTATE_LAST
 } TimerState;

 typedef struct deTimerThread_s
 {
 	deTimerCallback		callback;		/*!< Callback function.		*/
 	void*				callbackArg;	/*!< User pointer.			*/

 	deThread			thread;			/*!< Thread.				*/
 	int					interval;		/*!< Timer interval.		*/

 	deMutex				lock;			/*!< State lock.			*/
 	volatile TimerState	state;			/*!< Timer state.			*/
 } deTimerThread;

 struct deTimer_s
 {
 	deTimerCallback		callback;		/*!< Callback function.		*/
 	void*				callbackArg;	/*!< User pointer.			*/
 	deTimerThread*		curThread;		/*!< Current timer thread.	*/
 };

 static void timerThread (void* arg)
 {
 	deTimerThread*	thread			= (deTimerThread*)arg;
 	int				numCallbacks	= 0;
 	deBool			destroy			= DE_TRUE;
 	deInt64			lastCallback	= (deInt64)deGetMicroseconds();

 	for (;;)
 	{
 		int sleepTime = 0;

 		deMutex_lock(thread->lock);

 		if (thread->state == TIMERSTATE_SINGLE && numCallbacks > 0)
 		{
 			destroy = DE_FALSE; /* Will be destroyed by deTimer_disable(). */
 			thread->state = TIMERSTATE_DISABLED;
 			break;
 		}
 		else if (thread->state == TIMERSTATE_DISABLED)
 			break;

 		deMutex_unlock(thread->lock);

 		sleepTime = thread->interval - (int)(((deInt64)deGetMicroseconds()-lastCallback)/1000);
 		if (sleepTime > 0)
 			deSleep(sleepTime);

 		lastCallback = (deInt64)deGetMicroseconds();
 		thread->callback(thread->callbackArg);
 		numCallbacks += 1;
 	}

 	/* State lock is held when loop is exited. */
 	deMutex_unlock(thread->lock);

 	if (destroy)
 	{
 		/* Destroy thread except thread->thread. */
 		deMutex_destroy(thread->lock);
 		deFree(thread);
 	}
 }

 static deTimerThread* deTimerThread_create (deTimerCallback callback, void* arg, int interval, TimerState state)
 {
 	deTimerThread* thread = (deTimerThread*)deCalloc(sizeof(deTimerThread));

 	DE_ASSERT(state == TIMERSTATE_INTERVAL || state == TIMERSTATE_SINGLE);

 	if (!thread)
 		return DE_NULL;

 	thread->callback	= callback;
 	thread->callbackArg	= arg;
 	thread->interval	= interval;
 	thread->lock		= deMutex_create(DE_NULL);
 	thread->state		= state;

 	thread->thread		= deThread_create(timerThread, thread, DE_NULL);
 	if (!thread->thread)
 	{
 		deMutex_destroy(thread->lock);
 		deFree(thread);
 		return DE_NULL;
 	}

 	return thread;
 }

 deTimer* deTimer_create (deTimerCallback callback, void* arg)
 {
 	deTimer* timer = (deTimer*)deCalloc(sizeof(deTimer));

 	if (!timer)
 		return DE_NULL;

 	timer->callback		= callback;
 	timer->callbackArg	= arg;

 	return timer;
 }

 void deTimer_destroy (deTimer* timer)
 {
 	if (timer->curThread)
 		deTimer_disable(timer);
 	deFree(timer);
 }

 deBool deTimer_isActive (const deTimer* timer)
 {
 	if (timer->curThread)
 	{
 		deBool isActive = DE_FALSE;

 		deMutex_lock(timer->curThread->lock);
 		isActive = timer->curThread->state != TIMERSTATE_LAST;
 		deMutex_unlock(timer->curThread->lock);

 		return isActive;
 	}
 	else
 		return DE_FALSE;
 }

 deBool deTimer_scheduleSingle (deTimer* timer, int milliseconds)
 {
 	if (timer->curThread)
 		deTimer_disable(timer);

 	DE_ASSERT(!timer->curThread);
 	timer->curThread = deTimerThread_create(timer->callback, timer->callbackArg, milliseconds, TIMERSTATE_SINGLE);

 	return timer->curThread != DE_NULL;
 }

 deBool deTimer_scheduleInterval (deTimer* timer, int milliseconds)
 {
 	if (timer->curThread)
 		deTimer_disable(timer);

 	DE_ASSERT(!timer->curThread);
 	timer->curThread = deTimerThread_create(timer->callback, timer->callbackArg, milliseconds, TIMERSTATE_INTERVAL);

 	return timer->curThread != DE_NULL;
 }

 void deTimer_disable (deTimer* timer)
 {
 	if (!timer->curThread)
 		return;

 	deMutex_lock(timer->curThread->lock);

 	if (timer->curThread->state != TIMERSTATE_DISABLED)
 	{
 		/* Just set state to disabled and destroy thread handle. */
 		/* \note Assumes that deThread_destroy() can be called while thread is still running
 		 *       and it will not terminate the thread.
 		 */
 		timer->curThread->state = TIMERSTATE_DISABLED;
 		deThread_destroy(timer->curThread->thread);
 		timer->curThread->thread = 0;
 		deMutex_unlock(timer->curThread->lock);

 		/* Thread will destroy timer->curThread. */
 	}
 	else
 	{
 		/* Single timer has expired - we must destroy whole thread structure. */
 		deMutex_unlock(timer->curThread->lock);
 		deThread_destroy(timer->curThread->thread);
 		deMutex_destroy(timer->curThread->lock);
 		deFree(timer->curThread);
 	}

 	timer->curThread = DE_NULL;
 }

 #endif
	/*-------------------------------------------------------------------------
	* drawElements Utility Library
	* ----------------------------
	*
	* Copyright 2014 The Android Open Source Project
	*
	* Licensed under the Apache License, Version 2.0 (the "License");
	* you may not use this file except in compliance with the License.
	* You may obtain a copy of the License at
	*
	* http://www.apache.org/licenses/LICENSE-2.0
	*
	* Unless required by applicable law or agreed to in writing, software
	* distributed under the License is distributed on an "AS IS" BASIS,
	* WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
	* See the License for the specific language governing permissions and
	* limitations under the License.
	*
	//!
	* \file
	* \brief Periodic timer.
	//--------------------------------------------------------------------*/

	#include "deTimer.h"
	#include "deMemory.h"
	#include "deThread.h"

	#if (DE_OS == DE_OS_WIN32)

	#define VC_EXTRALEAN
	#define WIN32_LEAN_AND_MEAN
	#include <windows.h>

	struct deTimer_s
	{
	deTimerCallback callback;
	void* callbackArg;

	HANDLE timer;
	};

	static void CALLBACK timerCallback (PVOID lpParameter, BOOLEAN timerOrWaitFired)
	{
	const deTimer* timer = (const deTimer*)lpParameter;
	DE_UNREF(timerOrWaitFired);

	timer->callback(timer->callbackArg);
	}

	deTimer* deTimer_create (deTimerCallback callback, void* arg)
	{
	deTimer* timer = (deTimer*)deCalloc(sizeof(deTimer));

	if (!timer)
	return DE_NULL;

	timer->callback = callback;
	timer->callbackArg = arg;
	timer->timer = 0;

	return timer;
	}

	void deTimer_destroy (deTimer* timer)
	{
	DE_ASSERT(timer);

	if (deTimer_isActive(timer))
	deTimer_disable(timer);

	deFree(timer);
	}

	deBool deTimer_isActive (const deTimer* timer)
	{
	return timer->timer != 0;
	}

	deBool deTimer_scheduleSingle (deTimer* timer, int milliseconds)
	{
	BOOL ret;

	DE_ASSERT(timer && milliseconds > 0);

	if (deTimer_isActive(timer))
	return DE_FALSE;

	ret = CreateTimerQueueTimer(&timer->timer, NULL, timerCallback, timer, (DWORD)milliseconds, 0, WT_EXECUTEDEFAULT);

	if (!ret)
	{
	DE_ASSERT(!timer->timer);
	return DE_FALSE;
	}

	return DE_TRUE;
	}

	deBool deTimer_scheduleInterval (deTimer* timer, int milliseconds)
	{
	BOOL ret;

	DE_ASSERT(timer && milliseconds > 0);

	if (deTimer_isActive(timer))
	return DE_FALSE;

	ret = CreateTimerQueueTimer(&timer->timer, NULL, timerCallback, timer, (DWORD)milliseconds, (DWORD)milliseconds, WT_EXECUTEDEFAULT);

	if (!ret)
	{
	DE_ASSERT(!timer->timer);
	return DE_FALSE;
	}

	return DE_TRUE;
	}

	void deTimer_disable (deTimer* timer)
	{
	if (timer->timer)
	{
	const int maxTries = 100;
	HANDLE waitEvent = CreateEvent(NULL, FALSE, FALSE, NULL);
	int tryNdx = 0;
	DE_ASSERT(waitEvent);

	for (tryNdx = 0; tryNdx < maxTries; tryNdx++)
	{
	BOOL success = DeleteTimerQueueTimer(NULL, timer->timer, waitEvent);
	if (success)
	{
	/* Wait for all callbacks to complete. */
	DWORD res = WaitForSingleObject(waitEvent, INFINITE);
	DE_ASSERT(res == WAIT_OBJECT_0);
	DE_UNREF(res);
	break;
	}
	else
	{
	DWORD err = GetLastError();
	if (err == ERROR_IO_PENDING)
	break; /* \todo [2013-03-21 pyry] Does this mean that callback is still in progress? */
	deYield();
	}
	}

	DE_ASSERT(tryNdx < maxTries);

	CloseHandle(waitEvent);
	timer->timer = 0;
	}
	}

	#elif (DE_OS == DE_OS_UNIX \|\| DE_OS == DE_OS_ANDROID \|\| DE_OS == DE_OS_SYMBIAN \|\| DE_OS == DE_OS_QNX)

	#include <signal.h>
	#include <time.h>

	struct deTimer_s
	{
	deTimerCallback callback;
	void* callbackArg;

	timer_t timer;

	deBool isActive;
	};

	static void timerCallback (union sigval val)
	{
	const deTimer* timer = (const deTimer*)val.sival_ptr;
	timer->callback(timer->callbackArg);
	}

	deTimer* deTimer_create (deTimerCallback callback, void* arg)
	{
	deTimer* timer = (deTimer*)deCalloc(sizeof(deTimer));
	struct sigevent sevp;

	if (!timer)
	return DE_NULL;

	deMemset(&sevp, 0, sizeof(sevp));
	sevp.sigev_notify = SIGEV_THREAD;
	sevp.sigev_value.sival_ptr = timer;
	sevp.sigev_notify_function = timerCallback;

	if (timer_create(CLOCK_REALTIME, &sevp, &timer->timer) != 0)
	{
	deFree(timer);
	return DE_NULL;
	}

	timer->callback = callback;
	timer->callbackArg = arg;
	timer->isActive = DE_FALSE;

	return timer;
	}

	void deTimer_destroy (deTimer* timer)
	{
	DE_ASSERT(timer);

	timer_delete(timer->timer);
	deFree(timer);
	}

	deBool deTimer_isActive (const deTimer* timer)
	{
	return timer->isActive;
	}

	deBool deTimer_scheduleSingle (deTimer* timer, int milliseconds)
	{
	struct itimerspec tspec;

	DE_ASSERT(timer && milliseconds > 0);

	if (timer->isActive)
	return DE_FALSE;

	tspec.it_value.tv_sec = milliseconds / 1000;
	tspec.it_value.tv_nsec = (milliseconds % 1000) * 1000;
	tspec.it_interval.tv_sec = 0;
	tspec.it_interval.tv_nsec = 0;

	if (timer_settime(timer->timer, 0, &tspec, DE_NULL) != 0)
	return DE_FALSE;

	timer->isActive = DE_TRUE;
	return DE_TRUE;
	}

	deBool deTimer_scheduleInterval (deTimer* timer, int milliseconds)
	{
	struct itimerspec tspec;

	DE_ASSERT(timer && milliseconds > 0);

	if (timer->isActive)
	return DE_FALSE;

	tspec.it_value.tv_sec = milliseconds / 1000;
	tspec.it_value.tv_nsec = (milliseconds % 1000) * 1000;
	tspec.it_interval.tv_sec = tspec.it_value.tv_sec;
	tspec.it_interval.tv_nsec = tspec.it_value.tv_nsec;

	if (timer_settime(timer->timer, 0, &tspec, DE_NULL) != 0)
	return DE_FALSE;

	timer->isActive = DE_TRUE;
	return DE_TRUE;
	}

	void deTimer_disable (deTimer* timer)
	{
	struct itimerspec tspec;

	DE_ASSERT(timer);

	tspec.it_value.tv_sec = 0;
	tspec.it_value.tv_nsec = 0;
	tspec.it_interval.tv_sec = 0;
	tspec.it_interval.tv_nsec = 0;

	timer_settime(timer->timer, 0, &tspec, DE_NULL);

	/* \todo [2012-07-10 pyry] How to wait until all pending callbacks have finished? */

	timer->isActive = DE_FALSE;
	}

	#else

	/* Generic thread-based implementation for OSes that lack proper timers. */

	#include "deThread.h"
	#include "deMutex.h"
	#include "deClock.h"

	typedef enum TimerState_e
	{
	TIMERSTATE_INTERVAL = 0, /!< Active interval timer. /
	TIMERSTATE_SINGLE, /!< Single callback timer. /
	TIMERSTATE_DISABLED, /!< Disabled timer. /

	TIMERSTATE_LAST
	} TimerState;

	typedef struct deTimerThread_s
	{
	deTimerCallback callback; /!< Callback function. /
	void* callbackArg; /!< User pointer. /

	deThread thread; /!< Thread. /
	int interval; /!< Timer interval. /

	deMutex lock; /!< State lock. /
	volatile TimerState state; /!< Timer state. /
	} deTimerThread;

	struct deTimer_s
	{
	deTimerCallback callback; /!< Callback function. /
	void* callbackArg; /!< User pointer. /
	deTimerThread* curThread; /!< Current timer thread. /
	};

	static void timerThread (void* arg)
	{
	deTimerThread* thread = (deTimerThread*)arg;
	int numCallbacks = 0;
	deBool destroy = DE_TRUE;
	deInt64 lastCallback = (deInt64)deGetMicroseconds();

	for (;;)
	{
	int sleepTime = 0;

	deMutex_lock(thread->lock);

	if (thread->state == TIMERSTATE_SINGLE && numCallbacks > 0)
	{
	destroy = DE_FALSE; /* Will be destroyed by deTimer_disable(). */
	thread->state = TIMERSTATE_DISABLED;
	break;
	}
	else if (thread->state == TIMERSTATE_DISABLED)
	break;

	deMutex_unlock(thread->lock);

	sleepTime = thread->interval - (int)(((deInt64)deGetMicroseconds()-lastCallback)/1000);
	if (sleepTime > 0)
	deSleep(sleepTime);

	lastCallback = (deInt64)deGetMicroseconds();
	thread->callback(thread->callbackArg);
	numCallbacks += 1;
	}

	/* State lock is held when loop is exited. */
	deMutex_unlock(thread->lock);

	if (destroy)
	{
	/* Destroy thread except thread->thread. */
	deMutex_destroy(thread->lock);
	deFree(thread);
	}
	}

	static deTimerThread* deTimerThread_create (deTimerCallback callback, void* arg, int interval, TimerState state)
	{
	deTimerThread* thread = (deTimerThread*)deCalloc(sizeof(deTimerThread));

	DE_ASSERT(state == TIMERSTATE_INTERVAL \|\| state == TIMERSTATE_SINGLE);

	if (!thread)
	return DE_NULL;

	thread->callback = callback;
	thread->callbackArg = arg;
	thread->interval = interval;
	thread->lock = deMutex_create(DE_NULL);
	thread->state = state;

	thread->thread = deThread_create(timerThread, thread, DE_NULL);
	if (!thread->thread)
	{
	deMutex_destroy(thread->lock);
	deFree(thread);
	return DE_NULL;
	}

	return thread;
	}

	deTimer* deTimer_create (deTimerCallback callback, void* arg)
	{
	deTimer* timer = (deTimer*)deCalloc(sizeof(deTimer));

	if (!timer)
	return DE_NULL;

	timer->callback = callback;
	timer->callbackArg = arg;

	return timer;
	}

	void deTimer_destroy (deTimer* timer)
	{
	if (timer->curThread)
	deTimer_disable(timer);
	deFree(timer);
	}

	deBool deTimer_isActive (const deTimer* timer)
	{
	if (timer->curThread)
	{
	deBool isActive = DE_FALSE;

	deMutex_lock(timer->curThread->lock);
	isActive = timer->curThread->state != TIMERSTATE_LAST;
	deMutex_unlock(timer->curThread->lock);

	return isActive;
	}
	else
	return DE_FALSE;
	}

	deBool deTimer_scheduleSingle (deTimer* timer, int milliseconds)
	{
	if (timer->curThread)
	deTimer_disable(timer);

	DE_ASSERT(!timer->curThread);
	timer->curThread = deTimerThread_create(timer->callback, timer->callbackArg, milliseconds, TIMERSTATE_SINGLE);

	return timer->curThread != DE_NULL;
	}

	deBool deTimer_scheduleInterval (deTimer* timer, int milliseconds)
	{
	if (timer->curThread)
	deTimer_disable(timer);

	DE_ASSERT(!timer->curThread);
	timer->curThread = deTimerThread_create(timer->callback, timer->callbackArg, milliseconds, TIMERSTATE_INTERVAL);

	return timer->curThread != DE_NULL;
	}

	void deTimer_disable (deTimer* timer)
	{
	if (!timer->curThread)
	return;

	deMutex_lock(timer->curThread->lock);

	if (timer->curThread->state != TIMERSTATE_DISABLED)
	{
	/* Just set state to disabled and destroy thread handle. */
	/* \note Assumes that deThread_destroy() can be called while thread is still running
	* and it will not terminate the thread.
	*/
	timer->curThread->state = TIMERSTATE_DISABLED;
	deThread_destroy(timer->curThread->thread);
	timer->curThread->thread = 0;
	deMutex_unlock(timer->curThread->lock);

	/* Thread will destroy timer->curThread. */
	}
	else
	{
	/* Single timer has expired - we must destroy whole thread structure. */
	deMutex_unlock(timer->curThread->lock);
	deThread_destroy(timer->curThread->thread);
	deMutex_destroy(timer->curThread->lock);
	deFree(timer->curThread);
	}

	timer->curThread = DE_NULL;
	}

	#endif