test/time_controller/simulated_time_controller.cc - src - Git at Google

 /*
  *  Copyright 2019 The WebRTC 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 in the root of the source
  *  tree. An additional intellectual property rights grant can be found
  *  in the file PATENTS.  All contributing project authors may
  *  be found in the AUTHORS file in the root of the source tree.
  */
 #include "test/time_controller/simulated_time_controller.h"

 #include <algorithm>
 #include <deque>
 #include <list>
 #include <memory>
 #include <string>
 #include <thread>
 #include <vector>

 #include "absl/strings/string_view.h"
 #include "test/time_controller/simulated_process_thread.h"
 #include "test/time_controller/simulated_task_queue.h"
 #include "test/time_controller/simulated_thread.h"

 namespace webrtc {
 namespace {
 // Helper function to remove from a std container by value.
 template <class C>
 bool RemoveByValue(C* vec, typename C::value_type val) {
   auto it = std::find(vec->begin(), vec->end(), val);
   if (it == vec->end())
     return false;
   vec->erase(it);
   return true;
 }
 }  // namespace

 namespace sim_time_impl {

 SimulatedTimeControllerImpl::SimulatedTimeControllerImpl(Timestamp start_time)
     : thread_id_(rtc::CurrentThreadId()), current_time_(start_time) {}

 SimulatedTimeControllerImpl::~SimulatedTimeControllerImpl() = default;

 std::unique_ptr<TaskQueueBase, TaskQueueDeleter>
 SimulatedTimeControllerImpl::CreateTaskQueue(
     absl::string_view name,
     TaskQueueFactory::Priority priority) const {
   // TODO(srte): Remove the const cast when the interface is made mutable.
   auto mutable_this = const_cast<SimulatedTimeControllerImpl*>(this);
   auto task_queue = std::unique_ptr<SimulatedTaskQueue, TaskQueueDeleter>(
       new SimulatedTaskQueue(mutable_this, name));
   ;
   mutable_this->Register(task_queue.get());
   return task_queue;
 }

 std::unique_ptr<ProcessThread> SimulatedTimeControllerImpl::CreateProcessThread(
     const char* thread_name) {
   auto process_thread =
       std::make_unique<SimulatedProcessThread>(this, thread_name);
   Register(process_thread.get());
   return process_thread;
 }

 std::unique_ptr<rtc::Thread> SimulatedTimeControllerImpl::CreateThread(
     const std::string& name,
     std::unique_ptr<rtc::SocketServer> socket_server) {
   auto thread =
       std::make_unique<SimulatedThread>(this, name, std::move(socket_server));
   Register(thread.get());
   return thread;
 }

 void SimulatedTimeControllerImpl::YieldExecution() {
   if (rtc::CurrentThreadId() == thread_id_) {
     TaskQueueBase* yielding_from = TaskQueueBase::Current();
     // Since we might continue execution on a process thread, we should reset
     // the thread local task queue reference. This ensures that thread checkers
     // won't think we are executing on the yielding task queue. It also ensure
     // that TaskQueueBase::Current() won't return the yielding task queue.
     TokenTaskQueue::CurrentTaskQueueSetter reset_queue(nullptr);
     // When we yield, we don't want to risk executing further tasks on the
     // currently executing task queue. If there's a ready task that also yields,
     // it's added to this set as well and only tasks on the remaining task
     // queues are executed.
     auto inserted = yielded_.insert(yielding_from);
     RTC_DCHECK(inserted.second);
     RunReadyRunners();
     yielded_.erase(inserted.first);
   }
 }

 void SimulatedTimeControllerImpl::RunReadyRunners() {
   // Using a dummy thread rather than nullptr to avoid implicit thread creation
   // by Thread::Current().
   SimulatedThread::CurrentThreadSetter set_current(dummy_thread_.get());
   MutexLock lock(&lock_);
   RTC_DCHECK_EQ(rtc::CurrentThreadId(), thread_id_);
   Timestamp current_time = CurrentTime();
   // Clearing |ready_runners_| in case this is a recursive call:
   // RunReadyRunners -> Run -> Event::Wait -> Yield ->RunReadyRunners
   ready_runners_.clear();

   // We repeat until we have no ready left to handle tasks posted by ready
   // runners.
   while (true) {
     for (auto* runner : runners_) {
       if (yielded_.find(runner->GetAsTaskQueue()) == yielded_.end() &&
           runner->GetNextRunTime() <= current_time) {
         ready_runners_.push_back(runner);
       }
     }
     if (ready_runners_.empty())
       break;
     while (!ready_runners_.empty()) {
       auto* runner = ready_runners_.front();
       ready_runners_.pop_front();
       lock_.Unlock();
       // Note that the RunReady function might indirectly cause a call to
       // Unregister() which will grab |lock_| again to remove items from
       // |ready_runners_|.
       runner->RunReady(current_time);
       lock_.Lock();
     }
   }
 }

 Timestamp SimulatedTimeControllerImpl::CurrentTime() const {
   MutexLock lock(&time_lock_);
   return current_time_;
 }

 Timestamp SimulatedTimeControllerImpl::NextRunTime() const {
   Timestamp current_time = CurrentTime();
   Timestamp next_time = Timestamp::PlusInfinity();
   MutexLock lock(&lock_);
   for (auto* runner : runners_) {
     Timestamp next_run_time = runner->GetNextRunTime();
     if (next_run_time <= current_time)
       return current_time;
     next_time = std::min(next_time, next_run_time);
   }
   return next_time;
 }

 void SimulatedTimeControllerImpl::AdvanceTime(Timestamp target_time) {
   MutexLock time_lock(&time_lock_);
   RTC_DCHECK_GE(target_time, current_time_);
   current_time_ = target_time;
 }

 void SimulatedTimeControllerImpl::Register(SimulatedSequenceRunner* runner) {
   MutexLock lock(&lock_);
   runners_.push_back(runner);
 }

 void SimulatedTimeControllerImpl::Unregister(SimulatedSequenceRunner* runner) {
   MutexLock lock(&lock_);
   bool removed = RemoveByValue(&runners_, runner);
   RTC_CHECK(removed);
   RemoveByValue(&ready_runners_, runner);
 }

 void SimulatedTimeControllerImpl::StartYield(TaskQueueBase* yielding_from) {
   auto inserted = yielded_.insert(yielding_from);
   RTC_DCHECK(inserted.second);
 }

 void SimulatedTimeControllerImpl::StopYield(TaskQueueBase* yielding_from) {
   yielded_.erase(yielding_from);
 }

 }  // namespace sim_time_impl

 GlobalSimulatedTimeController::GlobalSimulatedTimeController(
     Timestamp start_time)
     : sim_clock_(start_time.us()), impl_(start_time), yield_policy_(&impl_) {
   global_clock_.SetTime(start_time);
   auto main_thread = std::make_unique<SimulatedMainThread>(&impl_);
   impl_.Register(main_thread.get());
   main_thread_ = std::move(main_thread);
 }

 GlobalSimulatedTimeController::~GlobalSimulatedTimeController() = default;

 Clock* GlobalSimulatedTimeController::GetClock() {
   return &sim_clock_;
 }

 TaskQueueFactory* GlobalSimulatedTimeController::GetTaskQueueFactory() {
   return &impl_;
 }

 std::unique_ptr<ProcessThread>
 GlobalSimulatedTimeController::CreateProcessThread(const char* thread_name) {
   return impl_.CreateProcessThread(thread_name);
 }

 std::unique_ptr<rtc::Thread> GlobalSimulatedTimeController::CreateThread(
     const std::string& name,
     std::unique_ptr<rtc::SocketServer> socket_server) {
   return impl_.CreateThread(name, std::move(socket_server));
 }

 rtc::Thread* GlobalSimulatedTimeController::GetMainThread() {
   return main_thread_.get();
 }

 void GlobalSimulatedTimeController::AdvanceTime(TimeDelta duration) {
   rtc::ScopedYieldPolicy yield_policy(&impl_);
   Timestamp current_time = impl_.CurrentTime();
   Timestamp target_time = current_time + duration;
   RTC_DCHECK_EQ(current_time.us(), rtc::TimeMicros());
   while (current_time < target_time) {
     impl_.RunReadyRunners();
     Timestamp next_time = std::min(impl_.NextRunTime(), target_time);
     impl_.AdvanceTime(next_time);
     auto delta = next_time - current_time;
     current_time = next_time;
     sim_clock_.AdvanceTimeMicroseconds(delta.us());
     global_clock_.AdvanceTime(delta);
   }
   // After time has been simulated up until |target_time| we also need to run
   // tasks meant to be executed at |target_time|.
   impl_.RunReadyRunners();
 }

 }  // namespace webrtc
	/*
	* Copyright 2019 The WebRTC 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 in the root of the source
	* tree. An additional intellectual property rights grant can be found
	* in the file PATENTS. All contributing project authors may
	* be found in the AUTHORS file in the root of the source tree.
	*/
	#include "test/time_controller/simulated_time_controller.h"

	#include <algorithm>
	#include <deque>
	#include <list>
	#include <memory>
	#include <string>
	#include <thread>
	#include <vector>

	#include "absl/strings/string_view.h"
	#include "test/time_controller/simulated_process_thread.h"
	#include "test/time_controller/simulated_task_queue.h"
	#include "test/time_controller/simulated_thread.h"

	namespace webrtc {
	namespace {
	// Helper function to remove from a std container by value.
	template <class C>
	bool RemoveByValue(C* vec, typename C::value_type val) {
	auto it = std::find(vec->begin(), vec->end(), val);
	if (it == vec->end())
	return false;
	vec->erase(it);
	return true;
	}
	} // namespace

	namespace sim_time_impl {

	SimulatedTimeControllerImpl::SimulatedTimeControllerImpl(Timestamp start_time)
	: thread_id_(rtc::CurrentThreadId()), current_time_(start_time) {}

	SimulatedTimeControllerImpl::~SimulatedTimeControllerImpl() = default;

	std::unique_ptr<TaskQueueBase, TaskQueueDeleter>
	SimulatedTimeControllerImpl::CreateTaskQueue(
	absl::string_view name,
	TaskQueueFactory::Priority priority) const {
	// TODO(srte): Remove the const cast when the interface is made mutable.
	auto mutable_this = const_cast<SimulatedTimeControllerImpl*>(this);
	auto task_queue = std::unique_ptr<SimulatedTaskQueue, TaskQueueDeleter>(
	new SimulatedTaskQueue(mutable_this, name));
	;
	mutable_this->Register(task_queue.get());
	return task_queue;
	}

	std::unique_ptr<ProcessThread> SimulatedTimeControllerImpl::CreateProcessThread(
	const char* thread_name) {
	auto process_thread =
	std::make_unique<SimulatedProcessThread>(this, thread_name);
	Register(process_thread.get());
	return process_thread;
	}

	std::unique_ptr<rtc::Thread> SimulatedTimeControllerImpl::CreateThread(
	const std::string& name,
	std::unique_ptr<rtc::SocketServer> socket_server) {
	auto thread =
	std::make_unique<SimulatedThread>(this, name, std::move(socket_server));
	Register(thread.get());
	return thread;
	}

	void SimulatedTimeControllerImpl::YieldExecution() {
	if (rtc::CurrentThreadId() == thread_id_) {
	TaskQueueBase* yielding_from = TaskQueueBase::Current();
	// Since we might continue execution on a process thread, we should reset
	// the thread local task queue reference. This ensures that thread checkers
	// won't think we are executing on the yielding task queue. It also ensure
	// that TaskQueueBase::Current() won't return the yielding task queue.
	TokenTaskQueue::CurrentTaskQueueSetter reset_queue(nullptr);
	// When we yield, we don't want to risk executing further tasks on the
	// currently executing task queue. If there's a ready task that also yields,
	// it's added to this set as well and only tasks on the remaining task
	// queues are executed.
	auto inserted = yielded_.insert(yielding_from);
	RTC_DCHECK(inserted.second);
	RunReadyRunners();
	yielded_.erase(inserted.first);
	}
	}

	void SimulatedTimeControllerImpl::RunReadyRunners() {
	// Using a dummy thread rather than nullptr to avoid implicit thread creation
	// by Thread::Current().
	SimulatedThread::CurrentThreadSetter set_current(dummy_thread_.get());
	MutexLock lock(&lock_);
	RTC_DCHECK_EQ(rtc::CurrentThreadId(), thread_id_);
	Timestamp current_time = CurrentTime();
	// Clearing \|ready_runners_\| in case this is a recursive call:
	// RunReadyRunners -> Run -> Event::Wait -> Yield ->RunReadyRunners
	ready_runners_.clear();

	// We repeat until we have no ready left to handle tasks posted by ready
	// runners.
	while (true) {
	for (auto* runner : runners_) {
	if (yielded_.find(runner->GetAsTaskQueue()) == yielded_.end() &&
	runner->GetNextRunTime() <= current_time) {
	ready_runners_.push_back(runner);
	}
	}
	if (ready_runners_.empty())
	break;
	while (!ready_runners_.empty()) {
	auto* runner = ready_runners_.front();
	ready_runners_.pop_front();
	lock_.Unlock();
	// Note that the RunReady function might indirectly cause a call to
	// Unregister() which will grab \|lock_\| again to remove items from
	// \|ready_runners_\|.
	runner->RunReady(current_time);
	lock_.Lock();
	}
	}
	}

	Timestamp SimulatedTimeControllerImpl::CurrentTime() const {
	MutexLock lock(&time_lock_);
	return current_time_;
	}

	Timestamp SimulatedTimeControllerImpl::NextRunTime() const {
	Timestamp current_time = CurrentTime();
	Timestamp next_time = Timestamp::PlusInfinity();
	MutexLock lock(&lock_);
	for (auto* runner : runners_) {
	Timestamp next_run_time = runner->GetNextRunTime();
	if (next_run_time <= current_time)
	return current_time;
	next_time = std::min(next_time, next_run_time);
	}
	return next_time;
	}

	void SimulatedTimeControllerImpl::AdvanceTime(Timestamp target_time) {
	MutexLock time_lock(&time_lock_);
	RTC_DCHECK_GE(target_time, current_time_);
	current_time_ = target_time;
	}

	void SimulatedTimeControllerImpl::Register(SimulatedSequenceRunner* runner) {
	MutexLock lock(&lock_);
	runners_.push_back(runner);
	}

	void SimulatedTimeControllerImpl::Unregister(SimulatedSequenceRunner* runner) {
	MutexLock lock(&lock_);
	bool removed = RemoveByValue(&runners_, runner);
	RTC_CHECK(removed);
	RemoveByValue(&ready_runners_, runner);
	}

	void SimulatedTimeControllerImpl::StartYield(TaskQueueBase* yielding_from) {
	auto inserted = yielded_.insert(yielding_from);
	RTC_DCHECK(inserted.second);
	}

	void SimulatedTimeControllerImpl::StopYield(TaskQueueBase* yielding_from) {
	yielded_.erase(yielding_from);
	}

	} // namespace sim_time_impl

	GlobalSimulatedTimeController::GlobalSimulatedTimeController(
	Timestamp start_time)
	: sim_clock_(start_time.us()), impl_(start_time), yield_policy_(&impl_) {
	global_clock_.SetTime(start_time);
	auto main_thread = std::make_unique<SimulatedMainThread>(&impl_);
	impl_.Register(main_thread.get());
	main_thread_ = std::move(main_thread);
	}

	GlobalSimulatedTimeController::~GlobalSimulatedTimeController() = default;

	Clock* GlobalSimulatedTimeController::GetClock() {
	return &sim_clock_;
	}

	TaskQueueFactory* GlobalSimulatedTimeController::GetTaskQueueFactory() {
	return &impl_;
	}

	std::unique_ptr<ProcessThread>
	GlobalSimulatedTimeController::CreateProcessThread(const char* thread_name) {
	return impl_.CreateProcessThread(thread_name);
	}

	std::unique_ptr<rtc::Thread> GlobalSimulatedTimeController::CreateThread(
	const std::string& name,
	std::unique_ptr<rtc::SocketServer> socket_server) {
	return impl_.CreateThread(name, std::move(socket_server));
	}

	rtc::Thread* GlobalSimulatedTimeController::GetMainThread() {
	return main_thread_.get();
	}

	void GlobalSimulatedTimeController::AdvanceTime(TimeDelta duration) {
	rtc::ScopedYieldPolicy yield_policy(&impl_);
	Timestamp current_time = impl_.CurrentTime();
	Timestamp target_time = current_time + duration;
	RTC_DCHECK_EQ(current_time.us(), rtc::TimeMicros());
	while (current_time < target_time) {
	impl_.RunReadyRunners();
	Timestamp next_time = std::min(impl_.NextRunTime(), target_time);
	impl_.AdvanceTime(next_time);
	auto delta = next_time - current_time;
	current_time = next_time;
	sim_clock_.AdvanceTimeMicroseconds(delta.us());
	global_clock_.AdvanceTime(delta);
	}
	// After time has been simulated up until \|target_time\| we also need to run
	// tasks meant to be executed at \|target_time\|.
	impl_.RunReadyRunners();
	}

	} // namespace webrtc