Mercurial > trustbridge > nss-cmake-static
view nspr/pr/src/md/windows/w95cv.c @ 4:b513267f632f tip
Build DBM module
| author | Andre Heinecke <andre.heinecke@intevation.de> |
|---|---|
| date | Tue, 05 Aug 2014 18:58:03 +0200 |
| parents | 1e5118fa0cb1 |
| children |
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/* -*- Mode: C++; tab-width: 4; indent-tabs-mode: nil; c-basic-offset: 2 -*- */ /* This Source Code Form is subject to the terms of the Mozilla Public * License, v. 2.0. If a copy of the MPL was not distributed with this * file, You can obtain one at http://mozilla.org/MPL/2.0/. */ /* * w95cv.c -- Windows 95 Machine-Dependent Code for Condition Variables * * We implement our own condition variable wait queue. Each thread * has a semaphore object (thread->md.blocked_sema) to block on while * waiting on a condition variable. * * We use a deferred condition notify algorithm. When PR_NotifyCondVar * or PR_NotifyAllCondVar is called, the condition notifies are simply * recorded in the _MDLock structure. We defer the condition notifies * until right after we unlock the lock. This way the awakened threads * have a better chance to reaquire the lock. */ #include "primpl.h" /* * AddThreadToCVWaitQueueInternal -- * * Add the thread to the end of the condition variable's wait queue. * The CV's lock must be locked when this function is called. */ static void AddThreadToCVWaitQueueInternal(PRThread *thred, struct _MDCVar *cv) { PR_ASSERT((cv->waitTail != NULL && cv->waitHead != NULL) || (cv->waitTail == NULL && cv->waitHead == NULL)); cv->nwait += 1; thred->md.inCVWaitQueue = PR_TRUE; thred->md.next = NULL; thred->md.prev = cv->waitTail; if (cv->waitHead == NULL) { cv->waitHead = thred; } else { cv->waitTail->md.next = thred; } cv->waitTail = thred; } /* * md_UnlockAndPostNotifies -- * * Unlock the lock, and then do the deferred condition notifies. * If waitThred and waitCV are not NULL, waitThred is added to * the wait queue of waitCV before the lock is unlocked. * * This function is called by _PR_MD_WAIT_CV and _PR_MD_UNLOCK, * the two places where a lock is unlocked. */ static void md_UnlockAndPostNotifies( _MDLock *lock, PRThread *waitThred, _MDCVar *waitCV) { PRIntn index; _MDNotified post; _MDNotified *notified, *prev = NULL; /* * Time to actually notify any conditions that were affected * while the lock was held. Get a copy of the list that's in * the lock structure and then zero the original. If it's * linked to other such structures, we own that storage. */ post = lock->notified; /* a safe copy; we own the lock */ #if defined(DEBUG) ZeroMemory(&lock->notified, sizeof(_MDNotified)); /* reset */ #else lock->notified.length = 0; /* these are really sufficient */ lock->notified.link = NULL; #endif /* * Figure out how many threads we need to wake up. */ notified = &post; /* this is where we start */ do { for (index = 0; index < notified->length; ++index) { _MDCVar *cv = notified->cv[index].cv; PRThread *thred; int i; /* Fast special case: no waiting threads */ if (cv->waitHead == NULL) { notified->cv[index].notifyHead = NULL; continue; } /* General case */ if (-1 == notified->cv[index].times) { /* broadcast */ thred = cv->waitHead; while (thred != NULL) { thred->md.inCVWaitQueue = PR_FALSE; thred = thred->md.next; } notified->cv[index].notifyHead = cv->waitHead; cv->waitHead = cv->waitTail = NULL; cv->nwait = 0; } else { thred = cv->waitHead; i = notified->cv[index].times; while (thred != NULL && i > 0) { thred->md.inCVWaitQueue = PR_FALSE; thred = thred->md.next; i--; } notified->cv[index].notifyHead = cv->waitHead; cv->waitHead = thred; if (cv->waitHead == NULL) { cv->waitTail = NULL; } else { if (cv->waitHead->md.prev != NULL) { cv->waitHead->md.prev->md.next = NULL; cv->waitHead->md.prev = NULL; } } cv->nwait -= notified->cv[index].times - i; } } notified = notified->link; } while (NULL != notified); if (waitThred) { AddThreadToCVWaitQueueInternal(waitThred, waitCV); } /* Release the lock before notifying */ LeaveCriticalSection(&lock->mutex); notified = &post; /* this is where we start */ do { for (index = 0; index < notified->length; ++index) { PRThread *thred; PRThread *next; thred = notified->cv[index].notifyHead; while (thred != NULL) { BOOL rv; next = thred->md.next; thred->md.prev = thred->md.next = NULL; rv = ReleaseSemaphore(thred->md.blocked_sema, 1, NULL); PR_ASSERT(rv != 0); thred = next; } } prev = notified; notified = notified->link; if (&post != prev) PR_DELETE(prev); } while (NULL != notified); } /* * Notifies just get posted to the protecting mutex. The * actual notification is done when the lock is released so that * MP systems don't contend for a lock that they can't have. */ static void md_PostNotifyToCvar(_MDCVar *cvar, _MDLock *lock, PRBool broadcast) { PRIntn index = 0; _MDNotified *notified = &lock->notified; while (1) { for (index = 0; index < notified->length; ++index) { if (notified->cv[index].cv == cvar) { if (broadcast) { notified->cv[index].times = -1; } else if (-1 != notified->cv[index].times) { notified->cv[index].times += 1; } return; } } /* if not full, enter new CV in this array */ if (notified->length < _MD_CV_NOTIFIED_LENGTH) break; /* if there's no link, create an empty array and link it */ if (NULL == notified->link) { notified->link = PR_NEWZAP(_MDNotified); } notified = notified->link; } /* A brand new entry in the array */ notified->cv[index].times = (broadcast) ? -1 : 1; notified->cv[index].cv = cvar; notified->length += 1; } /* * _PR_MD_NEW_CV() -- Creating new condition variable * ... Solaris uses cond_init() in similar function. * * returns: -1 on failure * 0 when it succeeds. * */ PRInt32 _PR_MD_NEW_CV(_MDCVar *cv) { cv->magic = _MD_MAGIC_CV; /* * The waitHead, waitTail, and nwait fields are zeroed * when the PRCondVar structure is created. */ return 0; } void _PR_MD_FREE_CV(_MDCVar *cv) { cv->magic = (PRUint32)-1; return; } /* * _PR_MD_WAIT_CV() -- Wait on condition variable */ void _PR_MD_WAIT_CV(_MDCVar *cv, _MDLock *lock, PRIntervalTime timeout ) { PRThread *thred = _PR_MD_CURRENT_THREAD(); DWORD rv; DWORD msecs = (timeout == PR_INTERVAL_NO_TIMEOUT) ? INFINITE : PR_IntervalToMilliseconds(timeout); /* * If we have pending notifies, post them now. */ if (0 != lock->notified.length) { md_UnlockAndPostNotifies(lock, thred, cv); } else { AddThreadToCVWaitQueueInternal(thred, cv); LeaveCriticalSection(&lock->mutex); } /* Wait for notification or timeout; don't really care which */ rv = WaitForSingleObject(thred->md.blocked_sema, msecs); EnterCriticalSection(&(lock->mutex)); PR_ASSERT(rv != WAIT_ABANDONED); PR_ASSERT(rv != WAIT_FAILED); PR_ASSERT(rv != WAIT_OBJECT_0 || thred->md.inCVWaitQueue == PR_FALSE); if (rv == WAIT_TIMEOUT) { if (thred->md.inCVWaitQueue) { PR_ASSERT((cv->waitTail != NULL && cv->waitHead != NULL) || (cv->waitTail == NULL && cv->waitHead == NULL)); cv->nwait -= 1; thred->md.inCVWaitQueue = PR_FALSE; if (cv->waitHead == thred) { cv->waitHead = thred->md.next; if (cv->waitHead == NULL) { cv->waitTail = NULL; } else { cv->waitHead->md.prev = NULL; } } else { PR_ASSERT(thred->md.prev != NULL); thred->md.prev->md.next = thred->md.next; if (thred->md.next != NULL) { thred->md.next->md.prev = thred->md.prev; } else { PR_ASSERT(cv->waitTail == thred); cv->waitTail = thred->md.prev; } } thred->md.next = thred->md.prev = NULL; } else { /* * This thread must have been notified, but the * ReleaseSemaphore call happens after WaitForSingleObject * times out. Wait on the semaphore again to make it * non-signaled. We assume this wait won't take long. */ rv = WaitForSingleObject(thred->md.blocked_sema, INFINITE); PR_ASSERT(rv == WAIT_OBJECT_0); } } PR_ASSERT(thred->md.inCVWaitQueue == PR_FALSE); return; } /* --- end _PR_MD_WAIT_CV() --- */ void _PR_MD_NOTIFY_CV(_MDCVar *cv, _MDLock *lock) { md_PostNotifyToCvar(cv, lock, PR_FALSE); return; } void _PR_MD_NOTIFYALL_CV(_MDCVar *cv, _MDLock *lock) { md_PostNotifyToCvar(cv, lock, PR_TRUE); return; } typedef BOOL (WINAPI *INITIALIZECRITICALSECTIONEX)( CRITICAL_SECTION *lpCriticalSection, DWORD dwSpinCount, DWORD Flags); static INITIALIZECRITICALSECTIONEX sInitializeCriticalSectionEx; void _PR_MD_INIT_LOCKS(void) { /* * Starting with Windows Vista, every CRITICAL_SECTION allocates an extra * RTL_CRITICAL_SECTION_DEBUG object. Unfortunately, this debug object is * not reclaimed by DeleteCriticalSection(), causing an apparent memory * leak. This is a debugging "feature", not a bug. If we are running on * Vista or later, use InitializeCriticalSectionEx() to allocate * CRITICAL_SECTIONs without debug objects. */ HMODULE hKernel32 = GetModuleHandle("kernel32.dll"); PR_ASSERT(hKernel32); PR_ASSERT(!sInitializeCriticalSectionEx); sInitializeCriticalSectionEx = (INITIALIZECRITICALSECTIONEX) GetProcAddress(hKernel32, "InitializeCriticalSectionEx"); } /* * By default, CRITICAL_SECTIONs are initialized with a spin count of 0. * Joe Duffy's "Concurrent Programming on Windows" book suggests 1500 is * a "reasonable starting point". On single-processor systems, the spin * count is ignored and the critical section spin count is set to 0. */ #define LOCK_SPIN_COUNT 1500 PRStatus _PR_MD_NEW_LOCK(_MDLock *lock) { CRITICAL_SECTION *cs = &lock->mutex; BOOL ok; if (sInitializeCriticalSectionEx) { ok = sInitializeCriticalSectionEx(cs, LOCK_SPIN_COUNT, CRITICAL_SECTION_NO_DEBUG_INFO); } else { ok = InitializeCriticalSectionAndSpinCount(cs, LOCK_SPIN_COUNT); } if (!ok) { _PR_MD_MAP_DEFAULT_ERROR(GetLastError()); return PR_FAILURE; } lock->notified.length = 0; lock->notified.link = NULL; return PR_SUCCESS; } void _PR_MD_UNLOCK(_MDLock *lock) { if (0 != lock->notified.length) { md_UnlockAndPostNotifies(lock, NULL, NULL); } else { LeaveCriticalSection(&lock->mutex); } }