/* ============================================================================== This file is part of the JUCE library. Copyright (c) 2017 - ROLI Ltd. JUCE is an open source library subject to commercial or open-source licensing. The code included in this file is provided under the terms of the ISC license http://www.isc.org/downloads/software-support-policy/isc-license. Permission To use, copy, modify, and/or distribute this software for any purpose with or without fee is hereby granted provided that the above copyright notice and this permission notice appear in all copies. JUCE IS PROVIDED "AS IS" WITHOUT ANY WARRANTY, AND ALL WARRANTIES, WHETHER EXPRESSED OR IMPLIED, INCLUDING MERCHANTABILITY AND FITNESS FOR PURPOSE, ARE DISCLAIMED. ============================================================================== */ namespace juce { //============================================================================== /** Automatically locks and unlocks a mutex object. Use one of these as a local variable to provide RAII-based locking of a mutex. The templated class could be a CriticalSection, SpinLock, or anything else that provides enter() and exit() methods. e.g. @code CriticalSection myCriticalSection; for (;;) { const GenericScopedLock myScopedLock (myCriticalSection); // myCriticalSection is now locked ...do some stuff... // myCriticalSection gets unlocked here. } @endcode @see GenericScopedUnlock, CriticalSection, SpinLock, ScopedLock, ScopedUnlock @tags{Core} */ template class GenericScopedLock { public: //============================================================================== /** Creates a GenericScopedLock. As soon as it is created, this will acquire the lock, and when the GenericScopedLock object is deleted, the lock will be released. Make sure this object is created and deleted by the same thread, otherwise there are no guarantees what will happen! Best just to use it as a local stack object, rather than creating one with the new() operator. */ inline explicit GenericScopedLock (const LockType& lock) noexcept : lock_ (lock) { lock.enter(); } /** Destructor. The lock will be released when the destructor is called. Make sure this object is created and deleted by the same thread, otherwise there are no guarantees what will happen! */ inline ~GenericScopedLock() noexcept { lock_.exit(); } private: //============================================================================== const LockType& lock_; JUCE_DECLARE_NON_COPYABLE (GenericScopedLock) }; //============================================================================== /** Automatically unlocks and re-locks a mutex object. This is the reverse of a GenericScopedLock object - instead of locking the mutex for the lifetime of this object, it unlocks it. Make sure you don't try to unlock mutexes that aren't actually locked! e.g. @code CriticalSection myCriticalSection; for (;;) { const GenericScopedLock myScopedLock (myCriticalSection); // myCriticalSection is now locked ... do some stuff with it locked .. while (xyz) { ... do some stuff with it locked .. const GenericScopedUnlock unlocker (myCriticalSection); // myCriticalSection is now unlocked for the remainder of this block, // and re-locked at the end. ...do some stuff with it unlocked ... } // myCriticalSection gets unlocked here. } @endcode @see GenericScopedLock, CriticalSection, ScopedLock, ScopedUnlock @tags{Core} */ template class GenericScopedUnlock { public: //============================================================================== /** Creates a GenericScopedUnlock. As soon as it is created, this will unlock the CriticalSection, and when the ScopedLock object is deleted, the CriticalSection will be re-locked. Make sure this object is created and deleted by the same thread, otherwise there are no guarantees what will happen! Best just to use it as a local stack object, rather than creating one with the new() operator. */ inline explicit GenericScopedUnlock (const LockType& lock) noexcept : lock_ (lock) { lock.exit(); } /** Destructor. The CriticalSection will be unlocked when the destructor is called. Make sure this object is created and deleted by the same thread, otherwise there are no guarantees what will happen! */ inline ~GenericScopedUnlock() noexcept { lock_.enter(); } private: //============================================================================== const LockType& lock_; JUCE_DECLARE_NON_COPYABLE (GenericScopedUnlock) }; //============================================================================== /** Automatically locks and unlocks a mutex object. Use one of these as a local variable to provide RAII-based locking of a mutex. The templated class could be a CriticalSection, SpinLock, or anything else that provides enter() and exit() methods. e.g. @code CriticalSection myCriticalSection; for (;;) { const GenericScopedTryLock myScopedTryLock (myCriticalSection); // Unlike using a ScopedLock, this may fail to actually get the lock, so you // should test this with the isLocked() method before doing your thread-unsafe // action.. if (myScopedTryLock.isLocked()) { ...do some stuff... } else { ..our attempt at locking failed because another thread had already locked it.. } // myCriticalSection gets unlocked here (if it was locked) } @endcode @see CriticalSection::tryEnter, GenericScopedLock, GenericScopedUnlock @tags{Core} */ template class GenericScopedTryLock { public: //============================================================================== /** Creates a GenericScopedTryLock. If acquireLockOnInitialisation is true then as soon as this ScopedTryLock is created, it will attempt to acquire the lock with tryEnter. You can retry acquiring the lock by calling retryLock. When GenericScopedTryLock is deleted, the lock will be released (if the lock was successfully acquired). Make sure this object is created and deleted by the same thread, otherwise there are no guarantees what will happen! Best just to use it as a local stack object, rather than creating one with the new() operator. @see retryLock, isLocked */ inline explicit GenericScopedTryLock (const LockType& lock, bool acquireLockOnInitialisation = true) noexcept : lock_ (lock), lockWasSuccessful (acquireLockOnInitialisation && lock.tryEnter()) {} /** Destructor. The mutex will be unlocked (if it had been successfully locked) when the destructor is called. Make sure this object is created and deleted by the same thread, otherwise there are no guarantees what will happen! */ inline ~GenericScopedTryLock() noexcept { if (lockWasSuccessful) lock_.exit(); } /** Returns true if the mutex was successfully locked. */ bool isLocked() const noexcept { return lockWasSuccessful; } /** Retry gaining the lock by calling tryEnter on the underlying lock. */ bool retryLock() const noexcept { lockWasSuccessful = lock_.tryEnter(); return lockWasSuccessful; } private: //============================================================================== const LockType& lock_; mutable bool lockWasSuccessful; JUCE_DECLARE_NON_COPYABLE (GenericScopedTryLock) }; } // namespace juce