kc3-lang/angle/src/common/WorkerThread.cpp

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• Hash : 2bc9f1f4
  Author :
  Date : 2022-10-26T10:38:02
  

  Lazily create threads in the thread pool
  
  The Vulkan backend doesn't use thread pools normally, so creating
  threads is a waste of CPU time. Additionally, creating threads early
  causes issues with some sandboxing strategies.
  
  Bug: b/250688943
  Change-Id: I33f1b73bdc62f6a0c0b2277ce99ba78a87464486
  Reviewed-on: https://chromium-review.googlesource.com/c/angle/angle/+/3982174
  Reviewed-by: Geoff Lang <geofflang@chromium.org>
  Commit-Queue: Shahbaz Youssefi <syoussefi@chromium.org>
  

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• src/common/WorkerThread.cpp

• //
  // Copyright 2016 The ANGLE Project Authors. All rights reserved.
  // Use of this source code is governed by a BSD-style license that can be
  // found in the LICENSE file.
  //
  // WorkerThread:
  //   Task running thread for ANGLE, similar to a TaskRunner in Chromium.
  //   Might be implemented differently depending on platform.
  //
  
  #include "common/WorkerThread.h"
  
  // Controls if our threading code uses std::async or falls back to single-threaded operations.
  // Note that we can't easily use std::async in UWPs due to UWP threading restrictions.
  #if !defined(ANGLE_STD_ASYNC_WORKERS) && !defined(ANGLE_ENABLE_WINDOWS_UWP)
  #    define ANGLE_STD_ASYNC_WORKERS ANGLE_ENABLED
  #endif  // !defined(ANGLE_STD_ASYNC_WORKERS) && & !defined(ANGLE_ENABLE_WINDOWS_UWP)
  
  #if (ANGLE_DELEGATE_WORKERS == ANGLE_ENABLED) || (ANGLE_STD_ASYNC_WORKERS == ANGLE_ENABLED)
  #    include <condition_variable>
  #    include <future>
  #    include <mutex>
  #    include <queue>
  #    include <thread>
  #endif  // (ANGLE_DELEGATE_WORKERS == ANGLE_ENABLED) || (ANGLE_STD_ASYNC_WORKERS == ANGLE_ENABLED)
  
  namespace angle
  {
  
  WaitableEvent::WaitableEvent()  = default;
  WaitableEvent::~WaitableEvent() = default;
  
  void WaitableEventDone::wait() {}
  
  bool WaitableEventDone::isReady()
  {
      return true;
  }
  
  // A waitable event that can be completed asynchronously
  class AsyncWaitableEvent final : public WaitableEvent
  {
    public:
      AsyncWaitableEvent()           = default;
      ~AsyncWaitableEvent() override = default;
  
      void wait() override;
      bool isReady() override;
  
      void markAsReady();
  
    private:
      // To protect the concurrent accesses from both main thread and background
      // threads to the member fields.
      std::mutex mMutex;
  
      bool mIsReady = false;
      std::condition_variable mCondition;
  };
  
  void AsyncWaitableEvent::markAsReady()
  {
      std::lock_guard<std::mutex> lock(mMutex);
      mIsReady = true;
      mCondition.notify_all();
  }
  
  void AsyncWaitableEvent::wait()
  {
      std::unique_lock<std::mutex> lock(mMutex);
      mCondition.wait(lock, [this] { return mIsReady; });
  }
  
  bool AsyncWaitableEvent::isReady()
  {
      std::lock_guard<std::mutex> lock(mMutex);
      return mIsReady;
  }
  
  WorkerThreadPool::WorkerThreadPool()  = default;
  WorkerThreadPool::~WorkerThreadPool() = default;
  
  class SingleThreadedWorkerPool final : public WorkerThreadPool
  {
    public:
      std::shared_ptr<WaitableEvent> postWorkerTask(std::shared_ptr<Closure> task) override;
      bool isAsync() override;
  };
  
  // SingleThreadedWorkerPool implementation.
  std::shared_ptr<WaitableEvent> SingleThreadedWorkerPool::postWorkerTask(
      std::shared_ptr<Closure> task)
  {
      // Thread safety: This function is thread-safe because the task is run on the calling thread
      // itself.
      (*task)();
      return std::make_shared<WaitableEventDone>();
  }
  
  bool SingleThreadedWorkerPool::isAsync()
  {
      return false;
  }
  
  #if (ANGLE_STD_ASYNC_WORKERS == ANGLE_ENABLED)
  
  class AsyncWorkerPool final : public WorkerThreadPool
  {
    public:
      AsyncWorkerPool(size_t numThreads);
  
      ~AsyncWorkerPool() override;
  
      std::shared_ptr<WaitableEvent> postWorkerTask(std::shared_ptr<Closure> task) override;
  
      bool isAsync() override;
  
    private:
      void createThreads();
  
      using Task = std::pair<std::shared_ptr<AsyncWaitableEvent>, std::shared_ptr<Closure>>;
  
      // Thread's main loop
      void threadLoop();
  
      bool mTerminated = false;
      std::mutex mMutex;                 // Protects access to the fields in this class
      std::condition_variable mCondVar;  // Signals when work is available in the queue
      std::queue<Task> mTaskQueue;
      std::deque<std::thread> mThreads;
      size_t mDesiredThreadCount;
  };
  
  // AsyncWorkerPool implementation.
  
  AsyncWorkerPool::AsyncWorkerPool(size_t numThreads) : mDesiredThreadCount(numThreads)
  {
      ASSERT(numThreads != 0);
  }
  
  AsyncWorkerPool::~AsyncWorkerPool()
  {
      {
          std::unique_lock<std::mutex> lock(mMutex);
          mTerminated = true;
      }
      mCondVar.notify_all();
      for (auto &thread : mThreads)
      {
          ASSERT(thread.get_id() != std::this_thread::get_id());
          thread.join();
      }
  }
  
  void AsyncWorkerPool::createThreads()
  {
      if (mDesiredThreadCount == mThreads.size())
      {
          return;
      }
      ASSERT(mThreads.empty());
  
      for (size_t i = 0; i < mDesiredThreadCount; ++i)
      {
          mThreads.emplace_back(&AsyncWorkerPool::threadLoop, this);
      }
  }
  
  std::shared_ptr<WaitableEvent> AsyncWorkerPool::postWorkerTask(std::shared_ptr<Closure> task)
  {
      // Thread safety: This function is thread-safe because access to |mTaskQueue| is protected by
      // |mMutex|.
      auto waitable = std::make_shared<AsyncWaitableEvent>();
      {
          std::lock_guard<std::mutex> lock(mMutex);
  
          // Lazily create the threads on first task
          createThreads();
  
          mTaskQueue.push(std::make_pair(waitable, task));
      }
      mCondVar.notify_one();
      return waitable;
  }
  
  void AsyncWorkerPool::threadLoop()
  {
      while (true)
      {
          Task task;
          {
              std::unique_lock<std::mutex> lock(mMutex);
              mCondVar.wait(lock, [this] { return !mTaskQueue.empty() || mTerminated; });
              if (mTerminated)
              {
                  return;
              }
              task = mTaskQueue.front();
              mTaskQueue.pop();
          }
  
          auto &waitable = task.first;
          auto &closure  = task.second;
  
          // Note: always add an ANGLE_TRACE_EVENT* macro in the closure.  Then the job will show up
          // in traces.
          (*closure)();
          waitable->markAsReady();
      }
  }
  
  bool AsyncWorkerPool::isAsync()
  {
      return true;
  }
  
  #endif  // (ANGLE_STD_ASYNC_WORKERS == ANGLE_ENABLED)
  
  #if (ANGLE_DELEGATE_WORKERS == ANGLE_ENABLED)
  
  class DelegateWorkerPool final : public WorkerThreadPool
  {
    public:
      DelegateWorkerPool(PlatformMethods *platform) : mPlatform(platform) {}
      ~DelegateWorkerPool() override = default;
  
      std::shared_ptr<WaitableEvent> postWorkerTask(std::shared_ptr<Closure> task) override;
  
      bool isAsync() override;
  
    private:
      PlatformMethods *mPlatform;
  };
  
  // A function wrapper to execute the closure and to notify the waitable
  // event after the execution.
  class DelegateWorkerTask
  {
    public:
      DelegateWorkerTask(std::shared_ptr<Closure> task, std::shared_ptr<AsyncWaitableEvent> waitable)
          : mTask(task), mWaitable(waitable)
      {}
      DelegateWorkerTask()                     = delete;
      DelegateWorkerTask(DelegateWorkerTask &) = delete;
  
      static void RunTask(void *userData)
      {
          DelegateWorkerTask *workerTask = static_cast<DelegateWorkerTask *>(userData);
          (*workerTask->mTask)();
          workerTask->mWaitable->markAsReady();
  
          // Delete the task after its execution.
          delete workerTask;
      }
  
    private:
      ~DelegateWorkerTask() = default;
  
      std::shared_ptr<Closure> mTask;
      std::shared_ptr<AsyncWaitableEvent> mWaitable;
  };
  
  std::shared_ptr<WaitableEvent> DelegateWorkerPool::postWorkerTask(std::shared_ptr<Closure> task)
  {
      // Thread safety: This function is thread-safe because the |postWorkerTask| platform method is
      // expected to be thread safe.  For Chromium, that forwards the call to the |TaskTracker| class
      // in base/task/thread_pool/task_tracker.h which is thread-safe.
      auto waitable = std::make_shared<AsyncWaitableEvent>();
  
      // The task will be deleted by DelegateWorkerTask::RunTask(...) after its execution.
      DelegateWorkerTask *workerTask = new DelegateWorkerTask(task, waitable);
      mPlatform->postWorkerTask(mPlatform, DelegateWorkerTask::RunTask, workerTask);
  
      return waitable;
  }
  
  bool DelegateWorkerPool::isAsync()
  {
      return true;
  }
  #endif
  
  // static
  std::shared_ptr<WorkerThreadPool> WorkerThreadPool::Create(size_t numThreads,
                                                             PlatformMethods *platform)
  {
      const bool multithreaded = numThreads != 1;
      std::shared_ptr<WorkerThreadPool> pool(nullptr);
  
  #if (ANGLE_DELEGATE_WORKERS == ANGLE_ENABLED)
      const bool hasPostWorkerTaskImpl = platform->postWorkerTask != nullptr;
      if (hasPostWorkerTaskImpl && multithreaded)
      {
          pool = std::shared_ptr<WorkerThreadPool>(new DelegateWorkerPool(platform));
      }
  #endif
  #if (ANGLE_STD_ASYNC_WORKERS == ANGLE_ENABLED)
      if (!pool && multithreaded)
      {
          pool = std::shared_ptr<WorkerThreadPool>(new AsyncWorkerPool(
              numThreads == 0 ? std::thread::hardware_concurrency() : numThreads));
      }
  #endif
      if (!pool)
      {
          return std::shared_ptr<WorkerThreadPool>(new SingleThreadedWorkerPool());
      }
      return pool;
  }
  }  // namespace angle
  

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