summaryrefslogtreecommitdiff
path: root/pthread_once.c
diff options
context:
space:
mode:
authorrpj <rpj>2005-04-25 14:42:37 +0000
committerrpj <rpj>2005-04-25 14:42:37 +0000
commit3ef98898333255b8000e9ab4801652c42fd5aacc (patch)
tree58fbe722c2011a392ffb47ad56b97fe44e2fe59c /pthread_once.c
parent75a3015fd7412637a02b1b016b367f5deadfde94 (diff)
''
Diffstat (limited to 'pthread_once.c')
-rw-r--r--pthread_once.c806
1 files changed, 403 insertions, 403 deletions
diff --git a/pthread_once.c b/pthread_once.c
index fad9dcc..eb355dd 100644
--- a/pthread_once.c
+++ b/pthread_once.c
@@ -1,403 +1,403 @@
-/*
- * pthread_once.c
- *
- * Description:
- * This translation unit implements miscellaneous thread functions.
- *
- * --------------------------------------------------------------------------
- *
- * Pthreads-win32 - POSIX Threads Library for Win32
- * Copyright(C) 1998 John E. Bossom
- * Copyright(C) 1999,2005 Pthreads-win32 contributors
- *
- * Contact Email: rpj@callisto.canberra.edu.au
- *
- * The current list of contributors is contained
- * in the file CONTRIBUTORS included with the source
- * code distribution. The list can also be seen at the
- * following World Wide Web location:
- * http://sources.redhat.com/pthreads-win32/contributors.html
- *
- * This library is free software; you can redistribute it and/or
- * modify it under the terms of the GNU Lesser General Public
- * License as published by the Free Software Foundation; either
- * version 2 of the License, or (at your option) any later version.
- *
- * This library is distributed in the hope that it will be useful,
- * but WITHOUT ANY WARRANTY; without even the implied warranty of
- * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
- * Lesser General Public License for more details.
- *
- * You should have received a copy of the GNU Lesser General Public
- * License along with this library in the file COPYING.LIB;
- * if not, write to the Free Software Foundation, Inc.,
- * 59 Temple Place - Suite 330, Boston, MA 02111-1307, USA
- */
-
-/*
- * NOTES:
- * pthread_once() performs a very simple task. So why is this implementation
- * so complicated?
- *
- * The original implementation WAS very simple, but it relied on Windows random
- * priority boosting to resolve starvation problems. Windows priority boosting
- * does not occur for realtime priority classes (levels 16 to 31).
- *
- * You can check back to previous versions of code in the CVS repository or
- * search the mailing list archives for discussion.
- *
- * Version A
- * ---------
- * Waiting threads would resume and suspend again using Sleep(0) until the
- * init_routine had completed, but a higher priority waiter could hog the CPU and
- * starve the initter thread until Windows randomly boosted it's priority, or forever
- * for realtime applications.
- *
- * Version B
- * ---------
- * This was fixed by introducing a per once_control manual-reset event that is
- * created and destroyed dynamically only if there are waiters. The design did not
- * need global critical sections. Each once_control remained independent. A waiter
- * could be confident that if the event was not null then it did not need to create
- * the event.
- *
- * Version C
- * ---------
- * Since a change in ABI would result from version B, it was decided to take
- * the opportunity and make pthread_once() fully compliant with the Single Unix
- * Specification (version 3 at the time). This required allowing the init_routine
- * to be a cancelation point. A cancelation meant that at least some waiting threads
- * if any had to be woken so that one might become the new initter thread.
- * Waiters could no longer simply assume that, if the event was not null, it did
- * not need to create an event. Some real critical sections were needed, and in the
- * current library, a global CRITICAL_SECTION is probably more efficient than a per
- * once_control PTHREAD_MUTEX_INITIALIZER that should be somehow destroyed on exit from
- * pthread_once(). Also, the cancelled init thread needed to set the event, and the
- * new init thread (the winner of the race between any newly arriving threads and
- * waking waiters) would need to reset it again. In the meantime, threads could be
- * happily looping around until they either suspended on the reset event, or exited
- * because the init thread had completed. It was also once again possible for a higher
- * priority waiter to starve the init thread.
- *
- * Version D
- * ---------
- * There were now two options considered:
- * - use an auto-reset event; OR
- * - add our own priority boosting.
- *
- * An auto-reset event would stop threads from looping ok, but it makes threads
- * dependent on earlier threads to successfully set the event in turn when it's time
- * to wake up, and this serialises threads unecessarily on MP systems. It also adds
- * an extra kernel call for each waking thread. If one waiter wakes and dies (async
- * cancelled or killed) before it can set the event, then all remaining waiters are
- * stranded.
- *
- * Priority boosting is a standard method for solving priority inversion and
- * starvation problems. Furthermore, all of the priority boost logic can
- * be restricted to the post cancellation tracks. That is, it need not slow
- * the normal cancel-free behaviour. Threads remain independent of other threads.
- *
- * The implementation below adds only a few local (to the thread) integer comparisons
- * to the normal track through the routine and additional bus locking/cache line
- * syncing operations have been avoided altogether in the uncontended track.
- */
-
-#include "pthread.h"
-#include "implement.h"
-
-
-static void PTW32_CDECL
-ptw32_once_init_routine_cleanup(void * arg)
-{
- pthread_once_t * once_control = (pthread_once_t *) arg;
-
- (void) PTW32_INTERLOCKED_EXCHANGE((LPLONG)&once_control->state, (LONG)PTW32_ONCE_CANCELLED);
- (void) PTW32_INTERLOCKED_EXCHANGE((LPLONG)&once_control->started, (LONG)PTW32_FALSE);
-
-// EnterCriticalSection(&ptw32_once_event_lock);
- if (InterlockedExchangeAdd((LPLONG)&once_control->event, 0L)) /* MBR fence */
- {
- int lasterror = GetLastError ();
- int lastWSAerror = WSAGetLastError ();
-
- /*
- * There are waiters, wake some up.
- */
- if (!SetEvent(once_control->event))
- {
- SetLastError (lasterror);
- WSASetLastError (lastWSAerror);
- }
- }
-// LeaveCriticalSection(&ptw32_once_event_lock);
-}
-
-
-int
-pthread_once (pthread_once_t * once_control, void (*init_routine) (void))
- /*
- * ------------------------------------------------------
- * DOCPUBLIC
- * If any thread in a process with a once_control parameter
- * makes a call to pthread_once(), the first call will summon
- * the init_routine(), but subsequent calls will not. The
- * once_control parameter determines whether the associated
- * initialization routine has been called. The init_routine()
- * is complete upon return of pthread_once().
- * This function guarantees that one and only one thread
- * executes the initialization routine, init_routine when
- * access is controlled by the pthread_once_t control
- * key.
- *
- * pthread_once() is not a cancelation point, but the init_routine
- * can be. If it's cancelled then the effect on the once_control is
- * as if pthread_once had never been entered.
- *
- *
- * PARAMETERS
- * once_control
- * pointer to an instance of pthread_once_t
- *
- * init_routine
- * pointer to an initialization routine
- *
- *
- * DESCRIPTION
- * See above.
- *
- * RESULTS
- * 0 success,
- * EINVAL once_control or init_routine is NULL
- *
- * ------------------------------------------------------
- */
-{
- int result;
- int lasterror;
- int lastWSAerror;
- int restoreLastError;
- LONG state;
- pthread_t self;
- HANDLE w32Thread = 0;
-
- if (once_control == NULL || init_routine == NULL)
- {
- result = EINVAL;
- goto FAIL0;
- }
- else
- {
- result = 0;
- }
-
- /*
- * We want to be invisible to GetLastError() outside of this routine.
- */
- lasterror = GetLastError ();
- lastWSAerror = WSAGetLastError ();
- restoreLastError = PTW32_FALSE;
-
- while (!((state = InterlockedExchangeAdd((LPLONG)&once_control->state, 0L)) /* Atomic Read */
- & (LONG)PTW32_ONCE_DONE))
- {
- LONG cancelled = (state & PTW32_ONCE_CANCELLED);
-
- if (cancelled)
- {
- /* Boost priority momentarily */
- if (!w32Thread)
- {
- self = pthread_self();
- w32Thread = ((ptw32_thread_t *)self.p)->threadH;
- }
- /*
- * Prevent pthread_setschedparam() from changing our priority while we're boosted.
- */
- pthread_mutex_lock(&((ptw32_thread_t *)self.p)->threadLock);
- SetThreadPriority(w32Thread, THREAD_PRIORITY_HIGHEST);
- }
-
- if (!PTW32_INTERLOCKED_EXCHANGE((LPLONG)&once_control->started, (LONG)PTW32_TRUE))
- {
- if (cancelled)
- {
- /*
- * The previous initter was cancelled.
- * We now have a new initter (us) and we need to make the rest wait again.
- * Furthermore, we're running at max priority until after we've reset the event
- * so we will not be starved by any other threads that may now be looping
- * around.
- */
-// EnterCriticalSection(&ptw32_once_event_lock);
- if (InterlockedExchangeAdd((LPLONG)&once_control->event, 0L)) /* MBR fence */
- {
- if (!ResetEvent(once_control->event))
- {
- restoreLastError = PTW32_TRUE;
- }
- }
-// LeaveCriticalSection(&ptw32_once_event_lock);
-
- /*
- * Any threads entering the wait section and getting out again before
- * the event is reset and the CANCELLED state is cleared will, at worst,
- * just go around again or, if they suspend and we (the initter) completes before
- * they resume, they will see state == DONE and leave immediately.
- */
- PTW32_INTERLOCKED_EXCHANGE((LPLONG)&once_control->state, (LONG)PTW32_ONCE_CLEAR);
-
- /*
- * Restore priority. We catch any changes to this thread's priority
- * only if they were done through the POSIX API (i.e. pthread_setschedparam)
- */
- SetThreadPriority(w32Thread, ((ptw32_thread_t *)self.p)->sched_priority);
- pthread_mutex_unlock(&((ptw32_thread_t *)self.p)->threadLock);
- }
-
-#ifdef _MSC_VER
-#pragma inline_depth(0)
-#endif
-
- pthread_cleanup_push(ptw32_once_init_routine_cleanup, (void *) once_control);
- (*init_routine)();
- pthread_cleanup_pop(0);
-
-#ifdef _MSC_VER
-#pragma inline_depth()
-#endif
-
- (void) PTW32_INTERLOCKED_EXCHANGE((LPLONG)&once_control->state, (LONG)PTW32_ONCE_DONE);
-
- /*
- * we didn't create the event.
- * it is only there if there is someone waiting.
- * Avoid using the global event_lock but still prevent SetEvent
- * from overwriting any 'lasterror' if the event is closed before we
- * are done with it.
- */
- if (InterlockedExchangeAdd((LPLONG)&once_control->event, 0L)) /* MBR fence */
- {
- if (!SetEvent(once_control->event))
- {
- restoreLastError = PTW32_TRUE;
- }
- }
- }
- else
- {
- HANDLE tmpEvent;
-
- if (cancelled)
- {
- /*
- * Restore priority. We catch any changes to this thread's priority
- * only if they were done through the POSIX API (i.e. pthread_setschedparam.
- */
- SetThreadPriority(w32Thread, ((ptw32_thread_t *)self.p)->sched_priority);
- pthread_mutex_unlock(&((ptw32_thread_t *)self.p)->threadLock);
- }
-
- /*
- * wait for init.
- * while waiting, create an event to wait on
- */
-
-// EnterCriticalSection(&ptw32_once_event_lock);
- if (1 == InterlockedIncrement((LPLONG)&once_control->eventUsers))
- {
- /*
- * RE CANCELLATION:
- * If we are the first thread after the initter thread, and the init_routine is cancelled
- * while we're suspended at this point in the code:-
- * - state will not get set to PTW32_ONCE_DONE;
- * - cleanup will not see an event and cannot set it;
- * - therefore, we will eventually resume, create an event and wait on it;
- * cleanup will set state == CANCELLED before checking for an event, so that
- * we will see it and avoid waiting (as for state == DONE). We will go around again and
- * we may then become the initter.
- * If we are still the only other thread when we get to the end of this block, we will
- * have closed the event (good). If another thread beats us to be initter, then we will
- * re-enter here (good). In case the old event is reused, the event is always reset by
- * the new initter before clearing the CANCELLED state, causing any threads that are
- * cycling around the loop to wait again.
- * The initter thread is guaranteed to be at equal or higher priority than any waiters
- * so no waiters will starve the initter, which might otherwise cause us to loop
- * forever.
- */
- tmpEvent = CreateEvent(NULL, PTW32_TRUE, PTW32_FALSE, NULL);
- if (PTW32_INTERLOCKED_COMPARE_EXCHANGE((PTW32_INTERLOCKED_LPLONG)&once_control->event,
- (PTW32_INTERLOCKED_LONG)tmpEvent,
- (PTW32_INTERLOCKED_LONG)0))
- {
- CloseHandle(tmpEvent);
- }
- }
-// LeaveCriticalSection(&ptw32_once_event_lock);
-
- /*
- * Check 'state' again in case the initting thread has finished or cancelled
- * and left before seeing that there was an event to trigger.
- */
-
- switch (InterlockedExchangeAdd((LPLONG)&once_control->state, 0L))
- {
- case PTW32_ONCE_CLEAR:
- {
- /* Neither DONE nor CANCELLED */
- if (WAIT_FAILED == WaitForSingleObject(once_control->event, INFINITE))
- {
- restoreLastError = PTW32_TRUE;
- /*
- * If the wait failed it's probably because the event is invalid.
- * That's possible after a cancellation (but rare) if we got through the
- * event create block above while a woken thread was suspended between
- * the decrement and exchange below and then resumed before we could wait.
- * So we'll yield.
- */
- Sleep(0);
- }
- break;
- }
- case PTW32_ONCE_CANCELLED:
- {
- if (once_control->started)
- {
- /* The new initter hasn't cleared the cancellation yet, so give the
- * processor to a more productive thread. */
- Sleep(0);
- }
- break;
- }
- }
-
- /* last one out shut off the lights */
-// EnterCriticalSection(&ptw32_once_event_lock);
- if (0 == InterlockedDecrement((LPLONG)&once_control->eventUsers))
- {
- /* we were last */
- if ((tmpEvent = (HANDLE)
- PTW32_INTERLOCKED_EXCHANGE((LPLONG)&once_control->event,
- (LONG)0)))
- {
- CloseHandle(tmpEvent);
- }
- }
-// LeaveCriticalSection(&ptw32_once_event_lock);
- }
- }
-
- if (restoreLastError)
- {
- SetLastError (lasterror);
- WSASetLastError (lastWSAerror);
- }
-
- /*
- * ------------
- * Failure Code
- * ------------
- */
-FAIL0:
- return (result);
-
-} /* pthread_once */
+/*
+ * pthread_once.c
+ *
+ * Description:
+ * This translation unit implements miscellaneous thread functions.
+ *
+ * --------------------------------------------------------------------------
+ *
+ * Pthreads-win32 - POSIX Threads Library for Win32
+ * Copyright(C) 1998 John E. Bossom
+ * Copyright(C) 1999,2005 Pthreads-win32 contributors
+ *
+ * Contact Email: rpj@callisto.canberra.edu.au
+ *
+ * The current list of contributors is contained
+ * in the file CONTRIBUTORS included with the source
+ * code distribution. The list can also be seen at the
+ * following World Wide Web location:
+ * http://sources.redhat.com/pthreads-win32/contributors.html
+ *
+ * This library is free software; you can redistribute it and/or
+ * modify it under the terms of the GNU Lesser General Public
+ * License as published by the Free Software Foundation; either
+ * version 2 of the License, or (at your option) any later version.
+ *
+ * This library is distributed in the hope that it will be useful,
+ * but WITHOUT ANY WARRANTY; without even the implied warranty of
+ * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
+ * Lesser General Public License for more details.
+ *
+ * You should have received a copy of the GNU Lesser General Public
+ * License along with this library in the file COPYING.LIB;
+ * if not, write to the Free Software Foundation, Inc.,
+ * 59 Temple Place - Suite 330, Boston, MA 02111-1307, USA
+ */
+
+/*
+ * NOTES:
+ * pthread_once() performs a very simple task. So why is this implementation
+ * so complicated?
+ *
+ * The original implementation WAS very simple, but it relied on Windows random
+ * priority boosting to resolve starvation problems. Windows priority boosting
+ * does not occur for realtime priority classes (levels 16 to 31).
+ *
+ * You can check back to previous versions of code in the CVS repository or
+ * search the mailing list archives for discussion.
+ *
+ * Version A
+ * ---------
+ * Waiting threads would resume and suspend again using Sleep(0) until the
+ * init_routine had completed, but a higher priority waiter could hog the CPU and
+ * starve the initter thread until Windows randomly boosted it's priority, or forever
+ * for realtime applications.
+ *
+ * Version B
+ * ---------
+ * This was fixed by introducing a per once_control manual-reset event that is
+ * created and destroyed dynamically only if there are waiters. The design did not
+ * need global critical sections. Each once_control remained independent. A waiter
+ * could be confident that if the event was not null then it did not need to create
+ * the event.
+ *
+ * Version C
+ * ---------
+ * Since a change in ABI would result from version B, it was decided to take
+ * the opportunity and make pthread_once() fully compliant with the Single Unix
+ * Specification (version 3 at the time). This required allowing the init_routine
+ * to be a cancelation point. A cancelation meant that at least some waiting threads
+ * if any had to be woken so that one might become the new initter thread.
+ * Waiters could no longer simply assume that, if the event was not null, it did
+ * not need to create an event. Some real critical sections were needed, and in the
+ * current library, a global CRITICAL_SECTION is probably more efficient than a per
+ * once_control PTHREAD_MUTEX_INITIALIZER that should be somehow destroyed on exit from
+ * pthread_once(). Also, the cancelled init thread needed to set the event, and the
+ * new init thread (the winner of the race between any newly arriving threads and
+ * waking waiters) would need to reset it again. In the meantime, threads could be
+ * happily looping around until they either suspended on the reset event, or exited
+ * because the init thread had completed. It was also once again possible for a higher
+ * priority waiter to starve the init thread.
+ *
+ * Version D
+ * ---------
+ * There were now two options considered:
+ * - use an auto-reset event; OR
+ * - add our own priority boosting.
+ *
+ * An auto-reset event would stop threads from looping ok, but it makes threads
+ * dependent on earlier threads to successfully set the event in turn when it's time
+ * to wake up, and this serialises threads unecessarily on MP systems. It also adds
+ * an extra kernel call for each waking thread. If one waiter wakes and dies (async
+ * cancelled or killed) before it can set the event, then all remaining waiters are
+ * stranded.
+ *
+ * Priority boosting is a standard method for solving priority inversion and
+ * starvation problems. Furthermore, all of the priority boost logic can
+ * be restricted to the post cancellation tracks. That is, it need not slow
+ * the normal cancel-free behaviour. Threads remain independent of other threads.
+ *
+ * The implementation below adds only a few local (to the thread) integer comparisons
+ * to the normal track through the routine and additional bus locking/cache line
+ * syncing operations have been avoided altogether in the uncontended track.
+ */
+
+#include "pthread.h"
+#include "implement.h"
+
+
+static void PTW32_CDECL
+ptw32_once_init_routine_cleanup(void * arg)
+{
+ pthread_once_t * once_control = (pthread_once_t *) arg;
+
+ (void) PTW32_INTERLOCKED_EXCHANGE((LPLONG)&once_control->state, (LONG)PTW32_ONCE_CANCELLED);
+ (void) PTW32_INTERLOCKED_EXCHANGE((LPLONG)&once_control->started, (LONG)PTW32_FALSE);
+
+// EnterCriticalSection(&ptw32_once_event_lock);
+ if (InterlockedExchangeAdd((LPLONG)&once_control->event, 0L)) /* MBR fence */
+ {
+ int lasterror = GetLastError ();
+ int lastWSAerror = WSAGetLastError ();
+
+ /*
+ * There are waiters, wake some up.
+ */
+ if (!SetEvent(once_control->event))
+ {
+ SetLastError (lasterror);
+ WSASetLastError (lastWSAerror);
+ }
+ }
+// LeaveCriticalSection(&ptw32_once_event_lock);
+}
+
+
+int
+pthread_once (pthread_once_t * once_control, void (*init_routine) (void))
+ /*
+ * ------------------------------------------------------
+ * DOCPUBLIC
+ * If any thread in a process with a once_control parameter
+ * makes a call to pthread_once(), the first call will summon
+ * the init_routine(), but subsequent calls will not. The
+ * once_control parameter determines whether the associated
+ * initialization routine has been called. The init_routine()
+ * is complete upon return of pthread_once().
+ * This function guarantees that one and only one thread
+ * executes the initialization routine, init_routine when
+ * access is controlled by the pthread_once_t control
+ * key.
+ *
+ * pthread_once() is not a cancelation point, but the init_routine
+ * can be. If it's cancelled then the effect on the once_control is
+ * as if pthread_once had never been entered.
+ *
+ *
+ * PARAMETERS
+ * once_control
+ * pointer to an instance of pthread_once_t
+ *
+ * init_routine
+ * pointer to an initialization routine
+ *
+ *
+ * DESCRIPTION
+ * See above.
+ *
+ * RESULTS
+ * 0 success,
+ * EINVAL once_control or init_routine is NULL
+ *
+ * ------------------------------------------------------
+ */
+{
+ int result;
+ int lasterror;
+ int lastWSAerror;
+ int restoreLastError;
+ LONG state;
+ pthread_t self;
+ HANDLE w32Thread = 0;
+
+ if (once_control == NULL || init_routine == NULL)
+ {
+ result = EINVAL;
+ goto FAIL0;
+ }
+ else
+ {
+ result = 0;
+ }
+
+ /*
+ * We want to be invisible to GetLastError() outside of this routine.
+ */
+ lasterror = GetLastError ();
+ lastWSAerror = WSAGetLastError ();
+ restoreLastError = PTW32_FALSE;
+
+ while (!((state = InterlockedExchangeAdd((LPLONG)&once_control->state, 0L)) /* Atomic Read */
+ & (LONG)PTW32_ONCE_DONE))
+ {
+ LONG cancelled = (state & PTW32_ONCE_CANCELLED);
+
+ if (cancelled)
+ {
+ /* Boost priority momentarily */
+ if (!w32Thread)
+ {
+ self = pthread_self();
+ w32Thread = ((ptw32_thread_t *)self.p)->threadH;
+ }
+ /*
+ * Prevent pthread_setschedparam() from changing our priority while we're boosted.
+ */
+ pthread_mutex_lock(&((ptw32_thread_t *)self.p)->threadLock);
+ SetThreadPriority(w32Thread, THREAD_PRIORITY_HIGHEST);
+ }
+
+ if (!PTW32_INTERLOCKED_EXCHANGE((LPLONG)&once_control->started, (LONG)PTW32_TRUE))
+ {
+ if (cancelled)
+ {
+ /*
+ * The previous initter was cancelled.
+ * We now have a new initter (us) and we need to make the rest wait again.
+ * Furthermore, we're running at max priority until after we've reset the event
+ * so we will not be starved by any other threads that may now be looping
+ * around.
+ */
+// EnterCriticalSection(&ptw32_once_event_lock);
+ if (InterlockedExchangeAdd((LPLONG)&once_control->event, 0L)) /* MBR fence */
+ {
+ if (!ResetEvent(once_control->event))
+ {
+ restoreLastError = PTW32_TRUE;
+ }
+ }
+// LeaveCriticalSection(&ptw32_once_event_lock);
+
+ /*
+ * Any threads entering the wait section and getting out again before
+ * the event is reset and the CANCELLED state is cleared will, at worst,
+ * just go around again or, if they suspend and we (the initter) completes before
+ * they resume, they will see state == DONE and leave immediately.
+ */
+ PTW32_INTERLOCKED_EXCHANGE((LPLONG)&once_control->state, (LONG)PTW32_ONCE_CLEAR);
+
+ /*
+ * Restore priority. We catch any changes to this thread's priority
+ * only if they were done through the POSIX API (i.e. pthread_setschedparam)
+ */
+ SetThreadPriority(w32Thread, ((ptw32_thread_t *)self.p)->sched_priority);
+ pthread_mutex_unlock(&((ptw32_thread_t *)self.p)->threadLock);
+ }
+
+#ifdef _MSC_VER
+#pragma inline_depth(0)
+#endif
+
+ pthread_cleanup_push(ptw32_once_init_routine_cleanup, (void *) once_control);
+ (*init_routine)();
+ pthread_cleanup_pop(0);
+
+#ifdef _MSC_VER
+#pragma inline_depth()
+#endif
+
+ (void) PTW32_INTERLOCKED_EXCHANGE((LPLONG)&once_control->state, (LONG)PTW32_ONCE_DONE);
+
+ /*
+ * we didn't create the event.
+ * it is only there if there is someone waiting.
+ * Avoid using the global event_lock but still prevent SetEvent
+ * from overwriting any 'lasterror' if the event is closed before we
+ * are done with it.
+ */
+ if (InterlockedExchangeAdd((LPLONG)&once_control->event, 0L)) /* MBR fence */
+ {
+ if (!SetEvent(once_control->event))
+ {
+ restoreLastError = PTW32_TRUE;
+ }
+ }
+ }
+ else
+ {
+ HANDLE tmpEvent;
+
+ if (cancelled)
+ {
+ /*
+ * Restore priority. We catch any changes to this thread's priority
+ * only if they were done through the POSIX API (i.e. pthread_setschedparam.
+ */
+ SetThreadPriority(w32Thread, ((ptw32_thread_t *)self.p)->sched_priority);
+ pthread_mutex_unlock(&((ptw32_thread_t *)self.p)->threadLock);
+ }
+
+ /*
+ * wait for init.
+ * while waiting, create an event to wait on
+ */
+
+// EnterCriticalSection(&ptw32_once_event_lock);
+ if (1 == InterlockedIncrement((LPLONG)&once_control->eventUsers))
+ {
+ /*
+ * RE CANCELLATION:
+ * If we are the first thread after the initter thread, and the init_routine is cancelled
+ * while we're suspended at this point in the code:-
+ * - state will not get set to PTW32_ONCE_DONE;
+ * - cleanup will not see an event and cannot set it;
+ * - therefore, we will eventually resume, create an event and wait on it;
+ * cleanup will set state == CANCELLED before checking for an event, so that
+ * we will see it and avoid waiting (as for state == DONE). We will go around again and
+ * we may then become the initter.
+ * If we are still the only other thread when we get to the end of this block, we will
+ * have closed the event (good). If another thread beats us to be initter, then we will
+ * re-enter here (good). In case the old event is reused, the event is always reset by
+ * the new initter before clearing the CANCELLED state, causing any threads that are
+ * cycling around the loop to wait again.
+ * The initter thread is guaranteed to be at equal or higher priority than any waiters
+ * so no waiters will starve the initter, which might otherwise cause us to loop
+ * forever.
+ */
+ tmpEvent = CreateEvent(NULL, PTW32_TRUE, PTW32_FALSE, NULL);
+ if (PTW32_INTERLOCKED_COMPARE_EXCHANGE((PTW32_INTERLOCKED_LPLONG)&once_control->event,
+ (PTW32_INTERLOCKED_LONG)tmpEvent,
+ (PTW32_INTERLOCKED_LONG)0))
+ {
+ CloseHandle(tmpEvent);
+ }
+ }
+// LeaveCriticalSection(&ptw32_once_event_lock);
+
+ /*
+ * Check 'state' again in case the initting thread has finished or cancelled
+ * and left before seeing that there was an event to trigger.
+ */
+
+ switch (InterlockedExchangeAdd((LPLONG)&once_control->state, 0L))
+ {
+ case PTW32_ONCE_CLEAR:
+ {
+ /* Neither DONE nor CANCELLED */
+ if (WAIT_FAILED == WaitForSingleObject(once_control->event, INFINITE))
+ {
+ restoreLastError = PTW32_TRUE;
+ /*
+ * If the wait failed it's probably because the event is invalid.
+ * That's possible after a cancellation (but rare) if we got through the
+ * event create block above while a woken thread was suspended between
+ * the decrement and exchange below and then resumed before we could wait.
+ * So we'll yield.
+ */
+ Sleep(0);
+ }
+ break;
+ }
+ case PTW32_ONCE_CANCELLED:
+ {
+ if (once_control->started)
+ {
+ /* The new initter hasn't cleared the cancellation yet, so give the
+ * processor to a more productive thread. */
+ Sleep(0);
+ }
+ break;
+ }
+ }
+
+ /* last one out shut off the lights */
+// EnterCriticalSection(&ptw32_once_event_lock);
+ if (0 == InterlockedDecrement((LPLONG)&once_control->eventUsers))
+ {
+ /* we were last */
+ if ((tmpEvent = (HANDLE)
+ PTW32_INTERLOCKED_EXCHANGE((LPLONG)&once_control->event,
+ (LONG)0)))
+ {
+ CloseHandle(tmpEvent);
+ }
+ }
+// LeaveCriticalSection(&ptw32_once_event_lock);
+ }
+ }
+
+ if (restoreLastError)
+ {
+ SetLastError (lasterror);
+ WSASetLastError (lastWSAerror);
+ }
+
+ /*
+ * ------------
+ * Failure Code
+ * ------------
+ */
+FAIL0:
+ return (result);
+
+} /* pthread_once */