/* * Copyright (C) 2008 Apple Inc. All rights reserved. * Copyright (C) 2009 Jian Li * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions * are met: * * 1. Redistributions of source code must retain the above copyright * notice, this list of conditions and the following disclaimer. * 2. Redistributions in binary form must reproduce the above copyright * notice, this list of conditions and the following disclaimer in the * documentation and/or other materials provided with the distribution. * 3. Neither the name of Apple Computer, Inc. ("Apple") nor the names of * its contributors may be used to endorse or promote products derived * from this software without specific prior written permission. * * THIS SOFTWARE IS PROVIDED BY APPLE AND ITS CONTRIBUTORS "AS IS" AND ANY * EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED * WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE * DISCLAIMED. IN NO EVENT SHALL APPLE OR ITS CONTRIBUTORS BE LIABLE FOR ANY * DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES * (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; * LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND * ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT * (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF * THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. */ /* Thread local storage is implemented by using either pthread API or Windows * native API. There is subtle semantic discrepancy for the cleanup function * implementation as noted below: * @ In pthread implementation, the destructor function will be called * repeatedly if there is still non-NULL value associated with the function. * @ In Windows native implementation, the destructor function will be called * only once. * This semantic discrepancy does not impose any problem because nowhere in * WebKit the repeated call bahavior is utilized. */ #ifndef WTF_ThreadSpecific_h #define WTF_ThreadSpecific_h #include #if USE(PTHREADS) #include #elif PLATFORM(QT) #include #elif PLATFORM(GTK) #include #elif OS(WINDOWS) #include #endif namespace WTF { #if !USE(PTHREADS) && !PLATFORM(QT) && !PLATFORM(GTK) && OS(WINDOWS) // ThreadSpecificThreadExit should be called each time when a thread is detached. // This is done automatically for threads created with WTF::createThread. void ThreadSpecificThreadExit(); #endif template class ThreadSpecific : public Noncopyable { public: ThreadSpecific(); T* operator->(); operator T*(); T& operator*(); ~ThreadSpecific(); private: #if !USE(PTHREADS) && !PLATFORM(QT) && !PLATFORM(GTK) && OS(WINDOWS) friend void ThreadSpecificThreadExit(); #endif T* get(); void set(T*); void static destroy(void* ptr); #if USE(PTHREADS) || PLATFORM(QT) || PLATFORM(GTK) || OS(WINDOWS) struct Data : Noncopyable { Data(T* value, ThreadSpecific* owner) : value(value), owner(owner) {} #if PLATFORM(QT) ~Data() { owner->destroy(this); } #endif T* value; ThreadSpecific* owner; #if !USE(PTHREADS) && !PLATFORM(QT) && !PLATFORM(GTK) void (*destructor)(void*); #endif }; #endif #if ENABLE(SINGLE_THREADED) T* m_value; #else #if USE(PTHREADS) pthread_key_t m_key; #elif PLATFORM(QT) QThreadStorage m_key; #elif PLATFORM(GTK) GStaticPrivate m_key; #elif OS(WINDOWS) int m_index; #endif #endif }; #if ENABLE(SINGLE_THREADED) template inline ThreadSpecific::ThreadSpecific() : m_value(0) { } template inline ThreadSpecific::~ThreadSpecific() { } template inline T* ThreadSpecific::get() { return m_value; } template inline void ThreadSpecific::set(T* ptr) { ASSERT(!get()); m_value = ptr; } #else #if USE(PTHREADS) template inline ThreadSpecific::ThreadSpecific() { int error = pthread_key_create(&m_key, destroy); if (error) CRASH(); } template inline ThreadSpecific::~ThreadSpecific() { pthread_key_delete(m_key); // Does not invoke destructor functions. } template inline T* ThreadSpecific::get() { Data* data = static_cast(pthread_getspecific(m_key)); return data ? data->value : 0; } template inline void ThreadSpecific::set(T* ptr) { ASSERT(!get()); pthread_setspecific(m_key, new Data(ptr, this)); } #elif PLATFORM(QT) template inline ThreadSpecific::ThreadSpecific() { } template inline ThreadSpecific::~ThreadSpecific() { // Does not invoke destructor functions. QThreadStorage will do it } template inline T* ThreadSpecific::get() { Data* data = static_cast(m_key.localData()); return data ? data->value : 0; } template inline void ThreadSpecific::set(T* ptr) { ASSERT(!get()); Data* data = new Data(ptr, this); m_key.setLocalData(data); } #elif PLATFORM(GTK) template inline ThreadSpecific::ThreadSpecific() { g_static_private_init(&m_key); } template inline ThreadSpecific::~ThreadSpecific() { g_static_private_free(&m_key); } template inline T* ThreadSpecific::get() { Data* data = static_cast(g_static_private_get(&m_key)); return data ? data->value : 0; } template inline void ThreadSpecific::set(T* ptr) { ASSERT(!get()); Data* data = new Data(ptr, this); g_static_private_set(&m_key, data, destroy); } #elif OS(WINDOWS) // TLS_OUT_OF_INDEXES is not defined on WinCE. #ifndef TLS_OUT_OF_INDEXES #define TLS_OUT_OF_INDEXES 0xffffffff #endif // The maximum number of TLS keys that can be created. For simplification, we assume that: // 1) Once the instance of ThreadSpecific<> is created, it will not be destructed until the program dies. // 2) We do not need to hold many instances of ThreadSpecific<> data. This fixed number should be far enough. const int kMaxTlsKeySize = 256; long& tlsKeyCount(); DWORD* tlsKeys(); template inline ThreadSpecific::ThreadSpecific() : m_index(-1) { DWORD tlsKey = TlsAlloc(); if (tlsKey == TLS_OUT_OF_INDEXES) CRASH(); m_index = InterlockedIncrement(&tlsKeyCount()) - 1; if (m_index >= kMaxTlsKeySize) CRASH(); tlsKeys()[m_index] = tlsKey; } template inline ThreadSpecific::~ThreadSpecific() { // Does not invoke destructor functions. They will be called from ThreadSpecificThreadExit when the thread is detached. TlsFree(tlsKeys()[m_index]); } template inline T* ThreadSpecific::get() { Data* data = static_cast(TlsGetValue(tlsKeys()[m_index])); return data ? data->value : 0; } template inline void ThreadSpecific::set(T* ptr) { ASSERT(!get()); Data* data = new Data(ptr, this); data->destructor = &ThreadSpecific::destroy; TlsSetValue(tlsKeys()[m_index], data); } #else #error ThreadSpecific is not implemented for this platform. #endif #endif template inline void ThreadSpecific::destroy(void* ptr) { #if !ENABLE(SINGLE_THREADED) Data* data = static_cast(ptr); #if USE(PTHREADS) // We want get() to keep working while data destructor works, because it can be called indirectly by the destructor. // Some pthreads implementations zero out the pointer before calling destroy(), so we temporarily reset it. pthread_setspecific(data->owner->m_key, ptr); #elif PLATFORM(GTK) // See comment as above g_static_private_set(&data->owner->m_key, data, 0); #endif #if PLATFORM(QT) // See comment as above data->owner->m_key.setLocalData(data); #endif data->value->~T(); fastFree(data->value); #if USE(PTHREADS) pthread_setspecific(data->owner->m_key, 0); #elif PLATFORM(QT) // Do nothing here #elif PLATFORM(GTK) g_static_private_set(&data->owner->m_key, 0, 0); #elif OS(WINDOWS) TlsSetValue(tlsKeys()[data->owner->m_index], 0); #else #error ThreadSpecific is not implemented for this platform. #endif #if !PLATFORM(QT) delete data; #endif #endif } template inline ThreadSpecific::operator T*() { T* ptr = static_cast(get()); if (!ptr) { // Set up thread-specific value's memory pointer before invoking constructor, in case any function it calls // needs to access the value, to avoid recursion. ptr = static_cast(fastZeroedMalloc(sizeof(T))); set(ptr); new (ptr) T; } return ptr; } template inline T* ThreadSpecific::operator->() { return operator T*(); } template inline T& ThreadSpecific::operator*() { return *operator T*(); } } #endif