third_party/fuchsia-sdk/pkg/fit/single_threaded_executor.cc - fuchsia-benchmarks - Git at Google

 // Copyright 2018 The Fuchsia Authors. All rights reserved.
 // Use of this source code is governed by a BSD-style license that can be
 // found in the LICENSE file.

 #include <condition_variable>
 #include <mutex>

 #include <lib/fit/single_threaded_executor.h>
 #include <lib/fit/thread_safety.h>

 namespace fit {

 // The dispatcher runs tasks and provides the suspended task resolver.
 //
 // The lifetime of this object is somewhat complex since there are pointers
 // to it from multiple sources which are released in different ways.
 //
 // - |single_threaded_executor| holds a pointer in |dispatcher_| which it releases
 //   after calling |shutdown()| to inform the dispatcher of its own demise
 // - |suspended_task| holds a pointer to the dispatcher's resolver
 //   interface and the number of outstanding pointers corresponds to the
 //   number of outstanding suspended task tickets tracked by |scheduler_|.
 //
 // The dispatcher deletes itself once all pointers have been released.
 class single_threaded_executor::dispatcher_impl final : public suspended_task::resolver {
  public:
   dispatcher_impl();

   void shutdown();
   void schedule_task(pending_task task);
   void run(context_impl& context);
   suspended_task suspend_current_task();

   suspended_task::ticket duplicate_ticket(suspended_task::ticket ticket) override;
   void resolve_ticket(suspended_task::ticket ticket, bool resume_task) override;

  private:
   ~dispatcher_impl() override;

   void wait_for_runnable_tasks(fit::subtle::scheduler::task_queue* out_tasks);
   void run_task(pending_task* task, context& context);

   suspended_task::ticket current_task_ticket_ = 0;
   std::condition_variable wake_;

   // A bunch of state that is guarded by a mutex.
   struct {
     std::mutex mutex_;
     bool was_shutdown_ FIT_GUARDED(mutex_) = false;
     bool need_wake_ FIT_GUARDED(mutex_) = false;
     fit::subtle::scheduler scheduler_ FIT_GUARDED(mutex_);
   } guarded_;
 };

 single_threaded_executor::single_threaded_executor()
     : context_(this), dispatcher_(new dispatcher_impl()) {}

 single_threaded_executor::~single_threaded_executor() { dispatcher_->shutdown(); }

 void single_threaded_executor::schedule_task(pending_task task) {
   assert(task);
   dispatcher_->schedule_task(std::move(task));
 }

 void single_threaded_executor::run() { dispatcher_->run(context_); }

 single_threaded_executor::context_impl::context_impl(single_threaded_executor* executor)
     : executor_(executor) {}

 single_threaded_executor::context_impl::~context_impl() = default;

 single_threaded_executor* single_threaded_executor::context_impl::executor() const {
   return executor_;
 }

 suspended_task single_threaded_executor::context_impl::suspend_task() {
   return executor_->dispatcher_->suspend_current_task();
 }

 single_threaded_executor::dispatcher_impl::dispatcher_impl() = default;

 single_threaded_executor::dispatcher_impl::~dispatcher_impl() {
   std::lock_guard<std::mutex> lock(guarded_.mutex_);
   assert(guarded_.was_shutdown_);
   assert(!guarded_.scheduler_.has_runnable_tasks());
   assert(!guarded_.scheduler_.has_suspended_tasks());
   assert(!guarded_.scheduler_.has_outstanding_tickets());
 }

 void single_threaded_executor::dispatcher_impl::shutdown() {
   fit::subtle::scheduler::task_queue tasks;  // drop outside of the lock
   {
     std::lock_guard<std::mutex> lock(guarded_.mutex_);
     assert(!guarded_.was_shutdown_);
     guarded_.was_shutdown_ = true;
     guarded_.scheduler_.take_all_tasks(&tasks);
     if (guarded_.scheduler_.has_outstanding_tickets()) {
       return;  // can't delete self yet
     }
   }

   // Must destroy self outside of the lock.
   delete this;
 }

 void single_threaded_executor::dispatcher_impl::schedule_task(pending_task task) {
   {
     std::lock_guard<std::mutex> lock(guarded_.mutex_);
     assert(!guarded_.was_shutdown_);
     guarded_.scheduler_.schedule_task(std::move(task));
     if (!guarded_.need_wake_) {
       return;  // don't need to wake
     }
     guarded_.need_wake_ = false;
   }

   // It is more efficient to notify outside the lock.
   wake_.notify_one();
 }

 void single_threaded_executor::dispatcher_impl::run(context_impl& context) {
   fit::subtle::scheduler::task_queue tasks;
   for (;;) {
     wait_for_runnable_tasks(&tasks);
     if (tasks.empty()) {
       return;  // all done!
     }

     do {
       run_task(&tasks.front(), context);
       tasks.pop();  // the task may be destroyed here if it was not suspended
     } while (!tasks.empty());
   }
 }

 // Must only be called while |run_task()| is running a task.
 // This happens when the task's continuation calls |context::suspend_task()|
 // upon the context it received as an argument.
 suspended_task single_threaded_executor::dispatcher_impl::suspend_current_task() {
   std::lock_guard<std::mutex> lock(guarded_.mutex_);
   assert(!guarded_.was_shutdown_);
   if (current_task_ticket_ == 0) {
     current_task_ticket_ = guarded_.scheduler_.obtain_ticket(2 /*initial_refs*/);
   } else {
     guarded_.scheduler_.duplicate_ticket(current_task_ticket_);
   }
   return suspended_task(this, current_task_ticket_);
 }

 // Unfortunately std::unique_lock does not support thread-safety annotations
 void single_threaded_executor::dispatcher_impl::wait_for_runnable_tasks(
     fit::subtle::scheduler::task_queue* out_tasks) FIT_NO_THREAD_SAFETY_ANALYSIS {
   std::unique_lock<std::mutex> lock(guarded_.mutex_);
   for (;;) {
     assert(!guarded_.was_shutdown_);
     guarded_.scheduler_.take_runnable_tasks(out_tasks);
     if (!out_tasks->empty()) {
       return;  // got some tasks
     }
     if (!guarded_.scheduler_.has_suspended_tasks()) {
       return;  // all done!
     }
     guarded_.need_wake_ = true;
     wake_.wait(lock);
     guarded_.need_wake_ = false;
   }
 }

 void single_threaded_executor::dispatcher_impl::run_task(pending_task* task, context& context) {
   assert(current_task_ticket_ == 0);
   const bool finished = (*task)(context);
   assert(!*task == finished);
   (void)finished;
   if (current_task_ticket_ == 0) {
     return;  // task was not suspended, no ticket was produced
   }

   std::lock_guard<std::mutex> lock(guarded_.mutex_);
   assert(!guarded_.was_shutdown_);
   guarded_.scheduler_.finalize_ticket(current_task_ticket_, task);
   current_task_ticket_ = 0;
 }

 suspended_task::ticket single_threaded_executor::dispatcher_impl::duplicate_ticket(
     suspended_task::ticket ticket) {
   std::lock_guard<std::mutex> lock(guarded_.mutex_);
   guarded_.scheduler_.duplicate_ticket(ticket);
   return ticket;
 }

 void single_threaded_executor::dispatcher_impl::resolve_ticket(suspended_task::ticket ticket,
                                                                bool resume_task) {
   pending_task abandoned_task;  // drop outside of the lock
   bool do_wake = false;
   {
     std::lock_guard<std::mutex> lock(guarded_.mutex_);
     if (resume_task) {
       guarded_.scheduler_.resume_task_with_ticket(ticket);
     } else {
       abandoned_task = guarded_.scheduler_.release_ticket(ticket);
     }
     if (guarded_.was_shutdown_) {
       assert(!guarded_.need_wake_);
       if (guarded_.scheduler_.has_outstanding_tickets()) {
         return;  // can't shutdown yet
       }
     } else if (guarded_.need_wake_ && (guarded_.scheduler_.has_runnable_tasks() ||
                                        !guarded_.scheduler_.has_suspended_tasks())) {
       guarded_.need_wake_ = false;
       do_wake = true;
     } else {
       return;  // nothing else to do
     }
   }

   // Must do this outside of the lock.
   if (do_wake) {
     wake_.notify_one();
   } else {
     delete this;
   }
 }

 }  // namespace fit
	// Copyright 2018 The Fuchsia Authors. All rights reserved.
	// Use of this source code is governed by a BSD-style license that can be
	// found in the LICENSE file.

	#include <condition_variable>
	#include <mutex>

	#include <lib/fit/single_threaded_executor.h>
	#include <lib/fit/thread_safety.h>

	namespace fit {

	// The dispatcher runs tasks and provides the suspended task resolver.
	//
	// The lifetime of this object is somewhat complex since there are pointers
	// to it from multiple sources which are released in different ways.
	//
	// - \|single_threaded_executor\| holds a pointer in \|dispatcher_\| which it releases
	// after calling \|shutdown()\| to inform the dispatcher of its own demise
	// - \|suspended_task\| holds a pointer to the dispatcher's resolver
	// interface and the number of outstanding pointers corresponds to the
	// number of outstanding suspended task tickets tracked by \|scheduler_\|.
	//
	// The dispatcher deletes itself once all pointers have been released.
	class single_threaded_executor::dispatcher_impl final : public suspended_task::resolver {
	public:
	dispatcher_impl();

	void shutdown();
	void schedule_task(pending_task task);
	void run(context_impl& context);
	suspended_task suspend_current_task();

	suspended_task::ticket duplicate_ticket(suspended_task::ticket ticket) override;
	void resolve_ticket(suspended_task::ticket ticket, bool resume_task) override;

	private:
	~dispatcher_impl() override;

	void wait_for_runnable_tasks(fit::subtle::scheduler::task_queue* out_tasks);
	void run_task(pending_task* task, context& context);

	suspended_task::ticket current_task_ticket_ = 0;
	std::condition_variable wake_;

	// A bunch of state that is guarded by a mutex.
	struct {
	std::mutex mutex_;
	bool was_shutdown_ FIT_GUARDED(mutex_) = false;
	bool need_wake_ FIT_GUARDED(mutex_) = false;
	fit::subtle::scheduler scheduler_ FIT_GUARDED(mutex_);
	} guarded_;
	};

	single_threaded_executor::single_threaded_executor()
	: context_(this), dispatcher_(new dispatcher_impl()) {}

	single_threaded_executor::~single_threaded_executor() { dispatcher_->shutdown(); }

	void single_threaded_executor::schedule_task(pending_task task) {
	assert(task);
	dispatcher_->schedule_task(std::move(task));
	}

	void single_threaded_executor::run() { dispatcher_->run(context_); }

	single_threaded_executor::context_impl::context_impl(single_threaded_executor* executor)
	: executor_(executor) {}

	single_threaded_executor::context_impl::~context_impl() = default;

	single_threaded_executor* single_threaded_executor::context_impl::executor() const {
	return executor_;
	}

	suspended_task single_threaded_executor::context_impl::suspend_task() {
	return executor_->dispatcher_->suspend_current_task();
	}

	single_threaded_executor::dispatcher_impl::dispatcher_impl() = default;

	single_threaded_executor::dispatcher_impl::~dispatcher_impl() {
	std::lock_guard<std::mutex> lock(guarded_.mutex_);
	assert(guarded_.was_shutdown_);
	assert(!guarded_.scheduler_.has_runnable_tasks());
	assert(!guarded_.scheduler_.has_suspended_tasks());
	assert(!guarded_.scheduler_.has_outstanding_tickets());
	}

	void single_threaded_executor::dispatcher_impl::shutdown() {
	fit::subtle::scheduler::task_queue tasks; // drop outside of the lock
	{
	std::lock_guard<std::mutex> lock(guarded_.mutex_);
	assert(!guarded_.was_shutdown_);
	guarded_.was_shutdown_ = true;
	guarded_.scheduler_.take_all_tasks(&tasks);
	if (guarded_.scheduler_.has_outstanding_tickets()) {
	return; // can't delete self yet
	}
	}

	// Must destroy self outside of the lock.
	delete this;
	}

	void single_threaded_executor::dispatcher_impl::schedule_task(pending_task task) {
	{
	std::lock_guard<std::mutex> lock(guarded_.mutex_);
	assert(!guarded_.was_shutdown_);
	guarded_.scheduler_.schedule_task(std::move(task));
	if (!guarded_.need_wake_) {
	return; // don't need to wake
	}
	guarded_.need_wake_ = false;
	}

	// It is more efficient to notify outside the lock.
	wake_.notify_one();
	}

	void single_threaded_executor::dispatcher_impl::run(context_impl& context) {
	fit::subtle::scheduler::task_queue tasks;
	for (;;) {
	wait_for_runnable_tasks(&tasks);
	if (tasks.empty()) {
	return; // all done!
	}

	do {
	run_task(&tasks.front(), context);
	tasks.pop(); // the task may be destroyed here if it was not suspended
	} while (!tasks.empty());
	}
	}

	// Must only be called while \|run_task()\| is running a task.
	// This happens when the task's continuation calls \|context::suspend_task()\|
	// upon the context it received as an argument.
	suspended_task single_threaded_executor::dispatcher_impl::suspend_current_task() {
	std::lock_guard<std::mutex> lock(guarded_.mutex_);
	assert(!guarded_.was_shutdown_);
	if (current_task_ticket_ == 0) {
	current_task_ticket_ = guarded_.scheduler_.obtain_ticket(2 /initial_refs/);
	} else {
	guarded_.scheduler_.duplicate_ticket(current_task_ticket_);
	}
	return suspended_task(this, current_task_ticket_);
	}

	// Unfortunately std::unique_lock does not support thread-safety annotations
	void single_threaded_executor::dispatcher_impl::wait_for_runnable_tasks(
	fit::subtle::scheduler::task_queue* out_tasks) FIT_NO_THREAD_SAFETY_ANALYSIS {
	std::unique_lock<std::mutex> lock(guarded_.mutex_);
	for (;;) {
	assert(!guarded_.was_shutdown_);
	guarded_.scheduler_.take_runnable_tasks(out_tasks);
	if (!out_tasks->empty()) {
	return; // got some tasks
	}
	if (!guarded_.scheduler_.has_suspended_tasks()) {
	return; // all done!
	}
	guarded_.need_wake_ = true;
	wake_.wait(lock);
	guarded_.need_wake_ = false;
	}
	}

	void single_threaded_executor::dispatcher_impl::run_task(pending_task* task, context& context) {
	assert(current_task_ticket_ == 0);
	const bool finished = (*task)(context);
	assert(!*task == finished);
	(void)finished;
	if (current_task_ticket_ == 0) {
	return; // task was not suspended, no ticket was produced
	}

	std::lock_guard<std::mutex> lock(guarded_.mutex_);
	assert(!guarded_.was_shutdown_);
	guarded_.scheduler_.finalize_ticket(current_task_ticket_, task);
	current_task_ticket_ = 0;
	}

	suspended_task::ticket single_threaded_executor::dispatcher_impl::duplicate_ticket(
	suspended_task::ticket ticket) {
	std::lock_guard<std::mutex> lock(guarded_.mutex_);
	guarded_.scheduler_.duplicate_ticket(ticket);
	return ticket;
	}

	void single_threaded_executor::dispatcher_impl::resolve_ticket(suspended_task::ticket ticket,
	bool resume_task) {
	pending_task abandoned_task; // drop outside of the lock
	bool do_wake = false;
	{
	std::lock_guard<std::mutex> lock(guarded_.mutex_);
	if (resume_task) {
	guarded_.scheduler_.resume_task_with_ticket(ticket);
	} else {
	abandoned_task = guarded_.scheduler_.release_ticket(ticket);
	}
	if (guarded_.was_shutdown_) {
	assert(!guarded_.need_wake_);
	if (guarded_.scheduler_.has_outstanding_tickets()) {
	return; // can't shutdown yet
	}
	} else if (guarded_.need_wake_ && (guarded_.scheduler_.has_runnable_tasks() \|\|
	!guarded_.scheduler_.has_suspended_tasks())) {
	guarded_.need_wake_ = false;
	do_wake = true;
	} else {
	return; // nothing else to do
	}
	}

	// Must do this outside of the lock.
	if (do_wake) {
	wake_.notify_one();
	} else {
	delete this;
	}
	}

	} // namespace fit