/* -*- Mode: C++; tab-width: 4; indent-tabs-mode: nil; c-basic-offset: 4 -*- */ /* * This file is part of the LibreOffice project. * * 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/. */ #include #include #include #include #include #include #include #include #include #include #include #include #if defined HAVE_VALGRIND_HEADERS #include #endif #if defined(_WIN32) #define WIN32_LEAN_AND_MEAN #include #elif defined UNX #include #include #endif namespace comphelper { /** prevent waiting for a task from inside a task */ #if defined DBG_UTIL && (defined LINUX || defined _WIN32) static thread_local bool gbIsWorkerThread; #endif // used to group thread-tasks for waiting in waitTillDone() class ThreadTaskTag { std::mutex maMutex; sal_Int32 mnTasksWorking; std::condition_variable maTasksComplete; public: ThreadTaskTag(); bool isDone(); void waitUntilDone(); void onTaskWorkerDone(); void onTaskPushed(); }; class ThreadPool::ThreadWorker : public salhelper::Thread { ThreadPool *mpPool; public: explicit ThreadWorker( ThreadPool *pPool ) : salhelper::Thread("thread-pool"), mpPool( pPool ) { } virtual void execute() override { #if defined DBG_UTIL && (defined LINUX || defined _WIN32) gbIsWorkerThread = true; #endif std::unique_lock< std::mutex > aGuard( mpPool->maMutex ); while( !mpPool->mbTerminate ) { std::unique_ptr pTask = mpPool->popWorkLocked( aGuard, true ); if( pTask ) { aGuard.unlock(); pTask->exec(); pTask.reset(); aGuard.lock(); } } } }; ThreadPool::ThreadPool(sal_Int32 nWorkers) : mbTerminate(true) , mnWorkers(nWorkers) { } ThreadPool::~ThreadPool() { // note: calling shutdown from global variable dtor blocks forever on Win7 // note2: there isn't enough MSVCRT left on exit to call assert() properly // so these asserts just print something to stderr but exit status is // still 0, but hopefully they will be more helpful on non-WNT platforms assert(mbTerminate); assert(maTasks.empty()); } namespace { struct ThreadPoolStatic : public rtl::StaticWithInit< std::shared_ptr< ThreadPool >, ThreadPoolStatic > { std::shared_ptr< ThreadPool > operator () () { const sal_Int32 nThreads = ThreadPool::getPreferredConcurrency(); return std::make_shared< ThreadPool >( nThreads ); }; }; } ThreadPool& ThreadPool::getSharedOptimalPool() { return *ThreadPoolStatic::get(); } sal_Int32 ThreadPool::getPreferredConcurrency() { static sal_Int32 ThreadCount = [&]() { const sal_Int32 nHardThreads = std::max(std::thread::hardware_concurrency(), 1U); sal_Int32 nThreads = nHardThreads; const char *pEnv = getenv("MAX_CONCURRENCY"); if (pEnv != nullptr) { // Override with user/admin preference. nThreads = rtl_str_toInt32(pEnv, 10); } nThreads = std::min(nHardThreads, nThreads); return std::max(nThreads, 1); }(); return ThreadCount; } // Used to order shutdown, and to ensure there are no lingering // threads after LibreOfficeKit pre-init. void ThreadPool::shutdown() { // if (mbTerminate) // return; std::unique_lock< std::mutex > aGuard( maMutex ); shutdownLocked(aGuard); } void ThreadPool::shutdownLocked(std::unique_lock& aGuard) { if( maWorkers.empty() ) { // no threads at all -> execute the work in-line std::unique_ptr pTask; while ( ( pTask = popWorkLocked(aGuard, false) ) ) pTask->exec(); } else { while( !maTasks.empty() ) maTasksChanged.wait( aGuard ); } assert( maTasks.empty() ); // coverity[missing_lock] - on purpose mbTerminate = true; maTasksChanged.notify_all(); decltype(maWorkers) aWorkers; std::swap(maWorkers, aWorkers); aGuard.unlock(); while (!aWorkers.empty()) { rtl::Reference xWorker = aWorkers.back(); aWorkers.pop_back(); assert(std::find(aWorkers.begin(), aWorkers.end(), xWorker) == aWorkers.end()); { xWorker->join(); xWorker.clear(); } } } void ThreadPool::pushTask( std::unique_ptr pTask ) { std::scoped_lock< std::mutex > aGuard( maMutex ); mbTerminate = false; if (maWorkers.size() < mnWorkers && maWorkers.size() <= maTasks.size()) { maWorkers.push_back( new ThreadWorker( this ) ); maWorkers.back()->launch(); } pTask->mpTag->onTaskPushed(); maTasks.insert( maTasks.begin(), std::move(pTask) ); maTasksChanged.notify_one(); } std::unique_ptr ThreadPool::popWorkLocked( std::unique_lock< std::mutex > & rGuard, bool bWait ) { do { if( !maTasks.empty() ) { std::unique_ptr pTask = std::move(maTasks.back()); maTasks.pop_back(); return pTask; } else if (!bWait || mbTerminate) return nullptr; maTasksChanged.wait( rGuard ); } while (!mbTerminate); return nullptr; } void ThreadPool::waitUntilDone(const std::shared_ptr& rTag, bool bJoinAll) { #if defined DBG_UTIL && (defined LINUX || defined _WIN32) assert(!gbIsWorkerThread && "cannot wait for tasks from inside a task"); #endif { std::unique_lock< std::mutex > aGuard( maMutex ); if( maWorkers.empty() ) { // no threads at all -> execute the work in-line while (!rTag->isDone()) { std::unique_ptr pTask = popWorkLocked(aGuard, false); if (!pTask) break; pTask->exec(); } } } rTag->waitUntilDone(); if (bJoinAll) joinAll(); } void ThreadPool::joinAll() { std::unique_lock< std::mutex > aGuard( maMutex ); if (maTasks.empty()) // check if there are still tasks from another tag { shutdownLocked(aGuard); } } std::shared_ptr ThreadPool::createThreadTaskTag() { return std::make_shared(); } bool ThreadPool::isTaskTagDone(const std::shared_ptr& pTag) { return pTag->isDone(); } ThreadTask::ThreadTask(const std::shared_ptr& pTag) : mpTag(pTag) { } void ThreadTask::exec() { std::shared_ptr pTag(mpTag); try { doWork(); } catch (const std::exception &e) { SAL_WARN("comphelper", "exception in thread worker while calling doWork(): " << e.what()); } catch (const css::uno::Exception &e) { SAL_WARN("comphelper", "exception in thread worker while calling doWork(): " << e); } pTag->onTaskWorkerDone(); } ThreadTaskTag::ThreadTaskTag() : mnTasksWorking(0) { } void ThreadTaskTag::onTaskPushed() { std::scoped_lock< std::mutex > aGuard( maMutex ); mnTasksWorking++; assert( mnTasksWorking < 65536 ); // sanity checking } void ThreadTaskTag::onTaskWorkerDone() { std::scoped_lock< std::mutex > aGuard( maMutex ); mnTasksWorking--; assert(mnTasksWorking >= 0); if (mnTasksWorking == 0) maTasksComplete.notify_all(); } bool ThreadTaskTag::isDone() { std::scoped_lock< std::mutex > aGuard( maMutex ); return mnTasksWorking == 0; } void ThreadTaskTag::waitUntilDone() { std::unique_lock< std::mutex > aGuard( maMutex ); while( mnTasksWorking > 0 ) { #if defined DBG_UTIL && !defined NDEBUG // 10 minute timeout in debug mode, unless the code is built with // sanitizers or debugged in valgrind or gdb, in which case the threads // should not time out in the middle of a debugging session int maxTimeout = 10 * 60; #if !ENABLE_RUNTIME_OPTIMIZATIONS maxTimeout = 30 * 60; #endif #if defined HAVE_VALGRIND_HEADERS if( RUNNING_ON_VALGRIND ) maxTimeout = 30 * 60; #endif if( isDebuggerAttached()) maxTimeout = 300 * 60; std::cv_status result = maTasksComplete.wait_for( aGuard, std::chrono::seconds( maxTimeout )); assert(result != std::cv_status::timeout); #else // 10 minute timeout in production so the app eventually throws some kind of error if (maTasksComplete.wait_for( aGuard, std::chrono::seconds( 10 * 60 )) == std::cv_status::timeout) throw std::runtime_error("timeout waiting for threadpool tasks"); #endif } } } // namespace comphelper /* vim:set shiftwidth=4 softtabstop=4 expandtab: */