/**************************************************************************** ** ** Copyright (C) 2012 Nokia Corporation and/or its subsidiary(-ies). ** Contact: http://www.qt-project.org/ ** ** This file is part of the QtCore module of the Qt Toolkit. ** ** $QT_BEGIN_LICENSE:LGPL$ ** GNU Lesser General Public License Usage ** This file may be used under the terms of the GNU Lesser General Public ** License version 2.1 as published by the Free Software Foundation and ** appearing in the file LICENSE.LGPL included in the packaging of this ** file. Please review the following information to ensure the GNU Lesser ** General Public License version 2.1 requirements will be met: ** http://www.gnu.org/licenses/old-licenses/lgpl-2.1.html. ** ** In addition, as a special exception, Nokia gives you certain additional ** rights. These rights are described in the Nokia Qt LGPL Exception ** version 1.1, included in the file LGPL_EXCEPTION.txt in this package. ** ** GNU General Public License Usage ** Alternatively, this file may be used under the terms of the GNU General ** Public License version 3.0 as published by the Free Software Foundation ** and appearing in the file LICENSE.GPL included in the packaging of this ** file. Please review the following information to ensure the GNU General ** Public License version 3.0 requirements will be met: ** http://www.gnu.org/copyleft/gpl.html. ** ** Other Usage ** Alternatively, this file may be used in accordance with the terms and ** conditions contained in a signed written agreement between you and Nokia. ** ** ** ** ** ** ** $QT_END_LICENSE$ ** ****************************************************************************/ #include "qplatformdefs.h" #include "qmutex.h" #include #ifndef QT_NO_THREAD #include "qatomic.h" #include "qelapsedtimer.h" #include "qthread.h" #include "qmutex_p.h" #ifndef Q_OS_LINUX #include "private/qfreelist_p.h" #endif QT_BEGIN_NAMESPACE /*! \class QBasicMutex \brief QMutex POD \internal \ingroup thread - Can be used as global static object. - Always non-recursive - Do not use tryLock with timeout > 0, else you can have a leak (see the ~QMutex destructor) */ /*! \class QMutex \brief The QMutex class provides access serialization between threads. \threadsafe \ingroup thread The purpose of a QMutex is to protect an object, data structure or section of code so that only one thread can access it at a time (this is similar to the Java \c synchronized keyword). It is usually best to use a mutex with a QMutexLocker since this makes it easy to ensure that locking and unlocking are performed consistently. For example, say there is a method that prints a message to the user on two lines: \snippet doc/src/snippets/code/src_corelib_thread_qmutex.cpp 0 If these two methods are called in succession, the following happens: \snippet doc/src/snippets/code/src_corelib_thread_qmutex.cpp 1 If these two methods are called simultaneously from two threads then the following sequence could result: \snippet doc/src/snippets/code/src_corelib_thread_qmutex.cpp 2 If we add a mutex, we should get the result we want: \snippet doc/src/snippets/code/src_corelib_thread_qmutex.cpp 3 Then only one thread can modify \c number at any given time and the result is correct. This is a trivial example, of course, but applies to any other case where things need to happen in a particular sequence. When you call lock() in a thread, other threads that try to call lock() in the same place will block until the thread that got the lock calls unlock(). A non-blocking alternative to lock() is tryLock(). \sa QMutexLocker, QReadWriteLock, QSemaphore, QWaitCondition */ /*! \enum QMutex::RecursionMode \value Recursive In this mode, a thread can lock the same mutex multiple times and the mutex won't be unlocked until a corresponding number of unlock() calls have been made. \value NonRecursive In this mode, a thread may only lock a mutex once. \sa QMutex() */ /*! Constructs a new mutex. The mutex is created in an unlocked state. If \a mode is QMutex::Recursive, a thread can lock the same mutex multiple times and the mutex won't be unlocked until a corresponding number of unlock() calls have been made. The default is QMutex::NonRecursive. \sa lock(), unlock() */ QMutex::QMutex(RecursionMode mode) { d_ptr.store(mode == Recursive ? new QRecursiveMutexPrivate : 0); } /*! Destroys the mutex. \warning Destroying a locked mutex may result in undefined behavior. */ QMutex::~QMutex() { QMutexData *d = d_ptr.load(); if (quintptr(d) > 0x3 && d->recursive) { delete static_cast(d); } else if (d) { #ifndef Q_OS_LINUX if (d != dummyLocked() && static_cast(d)->possiblyUnlocked.load() && tryLock()) { unlock(); return; } #endif qWarning("QMutex: destroying locked mutex"); } } /*! \fn void QMutex::lock() Locks the mutex. If another thread has locked the mutex then this call will block until that thread has unlocked it. Calling this function multiple times on the same mutex from the same thread is allowed if this mutex is a \l{QMutex::Recursive}{recursive mutex}. If this mutex is a \l{QMutex::NonRecursive}{non-recursive mutex}, this function will \e dead-lock when the mutex is locked recursively. \sa unlock() */ /*!\fn bool QMutex::trylock() Attempts to lock the mutex. If the lock was obtained, this function returns true. If another thread has locked the mutex, this function returns false immediately. If the lock was obtained, the mutex must be unlocked with unlock() before another thread can successfully lock it. Calling this function multiple times on the same mutex from the same thread is allowed if this mutex is a \l{QMutex::Recursive}{recursive mutex}. If this mutex is a \l{QMutex::NonRecursive}{non-recursive mutex}, this function will \e always return false when attempting to lock the mutex recursively. \sa lock(), unlock() */ /*! \fn bool QMutex::tryLock(int timeout) \overload Attempts to lock the mutex. This function returns true if the lock was obtained; otherwise it returns false. If another thread has locked the mutex, this function will wait for at most \a timeout milliseconds for the mutex to become available. Note: Passing a negative number as the \a timeout is equivalent to calling lock(), i.e. this function will wait forever until mutex can be locked if \a timeout is negative. If the lock was obtained, the mutex must be unlocked with unlock() before another thread can successfully lock it. Calling this function multiple times on the same mutex from the same thread is allowed if this mutex is a \l{QMutex::Recursive}{recursive mutex}. If this mutex is a \l{QMutex::NonRecursive}{non-recursive mutex}, this function will \e always return false when attempting to lock the mutex recursively. \sa lock(), unlock() */ /*! \fn void QMutex::unlock() Unlocks the mutex. Attempting to unlock a mutex in a different thread to the one that locked it results in an error. Unlocking a mutex that is not locked results in undefined behavior. \sa lock() */ /*! \fn void QMutex::isRecursive() \since 5.0 Returns true if the mutex is recursive */ bool QBasicMutex::isRecursive() { QMutexData *d = d_ptr.load(); if (quintptr(d) <= 0x3) return false; return d->recursive; } /*! \class QMutexLocker \brief The QMutexLocker class is a convenience class that simplifies locking and unlocking mutexes. \threadsafe \ingroup thread Locking and unlocking a QMutex in complex functions and statements or in exception handling code is error-prone and difficult to debug. QMutexLocker can be used in such situations to ensure that the state of the mutex is always well-defined. QMutexLocker should be created within a function where a QMutex needs to be locked. The mutex is locked when QMutexLocker is created. You can unlock and relock the mutex with \c unlock() and \c relock(). If locked, the mutex will be unlocked when the QMutexLocker is destroyed. For example, this complex function locks a QMutex upon entering the function and unlocks the mutex at all the exit points: \snippet doc/src/snippets/code/src_corelib_thread_qmutex.cpp 4 This example function will get more complicated as it is developed, which increases the likelihood that errors will occur. Using QMutexLocker greatly simplifies the code, and makes it more readable: \snippet doc/src/snippets/code/src_corelib_thread_qmutex.cpp 5 Now, the mutex will always be unlocked when the QMutexLocker object is destroyed (when the function returns since \c locker is an auto variable). The same principle applies to code that throws and catches exceptions. An exception that is not caught in the function that has locked the mutex has no way of unlocking the mutex before the exception is passed up the stack to the calling function. QMutexLocker also provides a \c mutex() member function that returns the mutex on which the QMutexLocker is operating. This is useful for code that needs access to the mutex, such as QWaitCondition::wait(). For example: \snippet doc/src/snippets/code/src_corelib_thread_qmutex.cpp 6 \sa QReadLocker, QWriteLocker, QMutex */ /*! \fn QMutexLocker::QMutexLocker(QMutex *mutex) Constructs a QMutexLocker and locks \a mutex. The mutex will be unlocked when the QMutexLocker is destroyed. If \a mutex is zero, QMutexLocker does nothing. \sa QMutex::lock() */ /*! \fn QMutexLocker::~QMutexLocker() Destroys the QMutexLocker and unlocks the mutex that was locked in the constructor. \sa QMutex::unlock() */ /*! \fn QMutex *QMutexLocker::mutex() const Returns a pointer to the mutex that was locked in the constructor. */ /*! \fn void QMutexLocker::unlock() Unlocks this mutex locker. You can use \c relock() to lock it again. It does not need to be locked when destroyed. \sa relock() */ /*! \fn void QMutexLocker::relock() Relocks an unlocked mutex locker. \sa unlock() */ #ifndef Q_OS_LINUX //linux implementation is in qmutex_linux.cpp /*! \internal helper for lock() */ bool QBasicMutex::lockInternal(int timeout) { while (!fastTryLock()) { QMutexData *copy = d_ptr.loadAcquire(); if (!copy) // if d is 0, the mutex is unlocked continue; if (copy == dummyLocked()) { if (timeout == 0) return false; QMutexPrivate *newD = QMutexPrivate::allocate(); if (!d_ptr.testAndSetOrdered(dummyLocked(), newD)) { //Either the mutex is already unlocked, or another thread already set it. newD->deref(); continue; } copy = newD; //the d->refCount is already 1 the deref will occurs when we unlock } else if (copy->recursive) { return static_cast(copy)->lock(timeout); } QMutexPrivate *d = static_cast(copy); if (timeout == 0 && !d->possiblyUnlocked.load()) return false; if (!d->ref()) continue; //that QMutexData was already released if (d != d_ptr.loadAcquire()) { //Either the mutex is already unlocked, or relocked with another mutex d->deref(); continue; } int old_waiters; do { old_waiters = d->waiters.load(); if (old_waiters == -QMutexPrivate::BigNumber) { // we are unlocking, and the thread that unlocks is about to change d to 0 // we try to aquire the mutex by changing to dummyLocked() if (d_ptr.testAndSetAcquire(d, dummyLocked())) { // Mutex aquired Q_ASSERT(d->waiters.load() == -QMutexPrivate::BigNumber || d->waiters.load() == 0); d->waiters.store(0); d->deref(); return true; } else { Q_ASSERT(d != d_ptr.load()); //else testAndSetAcquire should have succeeded // Mutex is likely to bo 0, we should continue the outer-loop, // set old_waiters to the magic value of BigNumber old_waiters = QMutexPrivate::BigNumber; break; } } } while (!d->waiters.testAndSetRelaxed(old_waiters, old_waiters + 1)); if (d != d_ptr.loadAcquire()) { // Mutex was unlocked. if (old_waiters != QMutexPrivate::BigNumber) { //we did not break the previous loop Q_ASSERT(d->waiters.load() >= 1); d->waiters.deref(); } d->deref(); continue; } if (d->wait(timeout)) { if (d->possiblyUnlocked.load() && d->possiblyUnlocked.testAndSetRelaxed(true, false)) d->deref(); d->derefWaiters(1); //we got the lock. (do not deref) Q_ASSERT(d == d_ptr.load()); return true; } else { Q_ASSERT(timeout >= 0); //timeout d->derefWaiters(1); //There may be a race in which the mutex is unlocked right after we timed out, // and before we deref the waiters, so maybe the mutex is actually unlocked. if (!d->possiblyUnlocked.testAndSetRelaxed(false, true)) d->deref(); return false; } } Q_ASSERT(d_ptr.load() != 0); return true; } /*! \internal */ void QBasicMutex::unlockInternal() { QMutexData *copy = d_ptr.loadAcquire(); Q_ASSERT(copy); //we must be locked Q_ASSERT(copy != dummyLocked()); // testAndSetRelease(dummyLocked(), 0) failed if (copy->recursive) { static_cast(copy)->unlock(); return; } QMutexPrivate *d = reinterpret_cast(copy); if (d->waiters.fetchAndAddRelease(-QMutexPrivate::BigNumber) == 0) { //there is no one waiting on this mutex anymore, set the mutex as unlocked (d = 0) if (d_ptr.testAndSetRelease(d, 0)) { if (d->possiblyUnlocked.load() && d->possiblyUnlocked.testAndSetRelaxed(true, false)) d->deref(); } d->derefWaiters(0); } else { d->derefWaiters(0); //there are thread waiting, transfer the lock. d->wakeUp(); } d->deref(); } //The freelist managment namespace { struct FreeListConstants : QFreeListDefaultConstants { enum { BlockCount = 4, MaxIndex=0xffff }; static const int Sizes[BlockCount]; }; const int FreeListConstants::Sizes[FreeListConstants::BlockCount] = { 16, 128, 1024, FreeListConstants::MaxIndex - (16-128-1024) }; typedef QFreeList FreeList; Q_GLOBAL_STATIC(FreeList, freelist); } QMutexPrivate *QMutexPrivate::allocate() { int i = freelist()->next(); QMutexPrivate *d = &(*freelist())[i]; d->id = i; Q_ASSERT(d->refCount.load() == 0); Q_ASSERT(!d->recursive); Q_ASSERT(!d->possiblyUnlocked.load()); Q_ASSERT(d->waiters.load() == 0); d->refCount.store(1); return d; } void QMutexPrivate::release() { Q_ASSERT(!recursive); Q_ASSERT(refCount.load() == 0); Q_ASSERT(!possiblyUnlocked.load()); Q_ASSERT(waiters.load() == 0); freelist()->release(id); } // atomically substract "value" to the waiters, and remove the QMutexPrivate::BigNumber flag void QMutexPrivate::derefWaiters(int value) { int old_waiters; int new_waiters; do { old_waiters = waiters.load(); new_waiters = old_waiters; if (new_waiters < 0) { new_waiters += QMutexPrivate::BigNumber; } new_waiters -= value; } while (!waiters.testAndSetRelaxed(old_waiters, new_waiters)); } #endif /*! \internal */ bool QRecursiveMutexPrivate::lock(int timeout) { Qt::HANDLE self = QThread::currentThreadId(); if (owner == self) { ++count; Q_ASSERT_X(count != 0, "QMutex::lock", "Overflow in recursion counter"); return true; } bool success = true; if (timeout == -1) { mutex.lock(); } else { success = mutex.tryLock(timeout); } if (success) owner = self; return success; } /*! \internal */ void QRecursiveMutexPrivate::unlock() { if (count > 0) { count--; } else { owner = 0; mutex.unlock(); } } QT_END_NAMESPACE #endif // QT_NO_THREAD