mojo/message_pump/handle_watcher.cc - chromium/src - Git at Google

 // Copyright 2013 The Chromium 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 "mojo/message_pump/handle_watcher.h"

 #include <stddef.h>
 #include <stdint.h>

 #include <map>

 #include "base/atomic_sequence_num.h"
 #include "base/bind.h"
 #include "base/lazy_instance.h"
 #include "base/logging.h"
 #include "base/macros.h"
 #include "base/memory/singleton.h"
 #include "base/memory/weak_ptr.h"
 #include "base/message_loop/message_loop.h"
 #include "base/single_thread_task_runner.h"
 #include "base/synchronization/lock.h"
 #include "base/threading/thread.h"
 #include "base/threading/thread_task_runner_handle.h"
 #include "base/time/time.h"
 #include "mojo/message_pump/message_pump_mojo.h"
 #include "mojo/message_pump/message_pump_mojo_handler.h"
 #include "mojo/message_pump/time_helper.h"
 #include "mojo/public/c/system/message_pipe.h"

 namespace mojo {
 namespace common {

 typedef int WatcherID;

 namespace {

 const char kWatcherThreadName[] = "handle-watcher-thread";

 base::TimeTicks MojoDeadlineToTimeTicks(MojoDeadline deadline) {
   return deadline == MOJO_DEADLINE_INDEFINITE ? base::TimeTicks() :
       internal::NowTicks() + base::TimeDelta::FromMicroseconds(deadline);
 }

 // Tracks the data for a single call to Start().
 struct WatchData {
   WatchData()
       : id(0), handle_signals(MOJO_HANDLE_SIGNAL_NONE), task_runner(NULL) {}

   WatcherID id;
   Handle handle;
   MojoHandleSignals handle_signals;
   base::TimeTicks deadline;
   base::Callback<void(MojoResult)> callback;
   scoped_refptr<base::SingleThreadTaskRunner> task_runner;
 };

 // WatcherBackend --------------------------------------------------------------

 // WatcherBackend is responsible for managing the requests and interacting with
 // MessagePumpMojo. All access (outside of creation/destruction) is done on the
 // thread WatcherThreadManager creates.
 class WatcherBackend : public MessagePumpMojoHandler {
  public:
   WatcherBackend();
   ~WatcherBackend() override;

   void StartWatching(const WatchData& data);
   void StopWatching(WatcherID watcher_id);

  private:
   typedef std::map<Handle, WatchData> HandleToWatchDataMap;

   // Invoked when a handle needs to be removed and notified.
   void RemoveAndNotify(const Handle& handle, MojoResult result);

   // Searches through |handle_to_data_| for |watcher_id|. Returns true if found
   // and sets |handle| to the Handle. Returns false if not a known id.
   bool GetMojoHandleByWatcherID(WatcherID watcher_id, Handle* handle) const;

   // MessagePumpMojoHandler overrides:
   void OnHandleReady(const Handle& handle) override;
   void OnHandleError(const Handle& handle, MojoResult result) override;

   // Maps from assigned id to WatchData.
   HandleToWatchDataMap handle_to_data_;

   DISALLOW_COPY_AND_ASSIGN(WatcherBackend);
 };

 WatcherBackend::WatcherBackend() {
 }

 WatcherBackend::~WatcherBackend() {
 }

 void WatcherBackend::StartWatching(const WatchData& data) {
   RemoveAndNotify(data.handle, MOJO_RESULT_CANCELLED);

   DCHECK_EQ(0u, handle_to_data_.count(data.handle));

   handle_to_data_[data.handle] = data;
   MessagePumpMojo::current()->AddHandler(this, data.handle,
                                          data.handle_signals,
                                          data.deadline);
 }

 void WatcherBackend::StopWatching(WatcherID watcher_id) {
   // Because of the thread hop it is entirely possible to get here and not
   // have a valid handle registered for |watcher_id|.
   Handle handle;
   if (!GetMojoHandleByWatcherID(watcher_id, &handle))
     return;

   handle_to_data_.erase(handle);
   MessagePumpMojo::current()->RemoveHandler(handle);
 }

 void WatcherBackend::RemoveAndNotify(const Handle& handle,
                                      MojoResult result) {
   if (handle_to_data_.count(handle) == 0)
     return;

   const WatchData data(handle_to_data_[handle]);
   handle_to_data_.erase(handle);
   MessagePumpMojo::current()->RemoveHandler(handle);

   data.task_runner->PostTask(FROM_HERE, base::Bind(data.callback, result));
 }

 bool WatcherBackend::GetMojoHandleByWatcherID(WatcherID watcher_id,
                                               Handle* handle) const {
   for (HandleToWatchDataMap::const_iterator i = handle_to_data_.begin();
        i != handle_to_data_.end(); ++i) {
     if (i->second.id == watcher_id) {
       *handle = i->second.handle;
       return true;
     }
   }
   return false;
 }

 void WatcherBackend::OnHandleReady(const Handle& handle) {
   RemoveAndNotify(handle, MOJO_RESULT_OK);
 }

 void WatcherBackend::OnHandleError(const Handle& handle, MojoResult result) {
   RemoveAndNotify(handle, result);
 }

 // WatcherThreadManager --------------------------------------------------------

 // WatcherThreadManager manages the background thread that listens for handles
 // to be ready. All requests are handled by WatcherBackend.
 class WatcherThreadManager {
  public:
   ~WatcherThreadManager();

   // Returns the shared instance.
   static WatcherThreadManager* GetInstance();

   // Starts watching the requested handle. Returns a unique ID that is used to
   // stop watching the handle. When the handle is ready |callback| is notified
   // on the thread StartWatching() was invoked on.
   // This may be invoked on any thread.
   WatcherID StartWatching(const Handle& handle,
                           MojoHandleSignals handle_signals,
                           base::TimeTicks deadline,
                           const base::Callback<void(MojoResult)>& callback);

   // Stops watching a handle.
   // This may be invoked on any thread.
   void StopWatching(WatcherID watcher_id);

  private:
   enum RequestType {
     REQUEST_START,
     REQUEST_STOP,
   };

   // See description of |requests_| for details.
   struct RequestData {
     RequestData() : type(REQUEST_START), stop_id(0) {}

     RequestType type;
     WatchData start_data;
     WatcherID stop_id;
   };

   typedef std::vector<RequestData> Requests;

   friend struct base::DefaultSingletonTraits<WatcherThreadManager>;

   WatcherThreadManager();

   // Schedules a request on the background thread. See |requests_| for details.
   void AddRequest(const RequestData& data);

   // Processes requests added to |requests_|. This is invoked on the backend
   // thread.
   void ProcessRequestsOnBackendThread();

   base::Thread thread_;

   base::AtomicSequenceNumber watcher_id_generator_;

   WatcherBackend backend_;

   // Protects |requests_|.
   base::Lock lock_;

   // Start/Stop result in adding a RequestData to |requests_| (protected by
   // |lock_|). When the background thread wakes up it processes the requests.
   Requests requests_;

   DISALLOW_COPY_AND_ASSIGN(WatcherThreadManager);
 };

 WatcherThreadManager::~WatcherThreadManager() {
   thread_.Stop();
 }

 WatcherThreadManager* WatcherThreadManager::GetInstance() {
   return base::Singleton<WatcherThreadManager>::get();
 }

 WatcherID WatcherThreadManager::StartWatching(
     const Handle& handle,
     MojoHandleSignals handle_signals,
     base::TimeTicks deadline,
     const base::Callback<void(MojoResult)>& callback) {
   RequestData request_data;
   request_data.type = REQUEST_START;
   request_data.start_data.id = watcher_id_generator_.GetNext();
   request_data.start_data.handle = handle;
   request_data.start_data.callback = callback;
   request_data.start_data.handle_signals = handle_signals;
   request_data.start_data.deadline = deadline;
   request_data.start_data.task_runner = base::ThreadTaskRunnerHandle::Get();
   AddRequest(request_data);
   return request_data.start_data.id;
 }

 void WatcherThreadManager::StopWatching(WatcherID watcher_id) {
   // Handle the case of StartWatching() followed by StopWatching() before
   // |thread_| woke up.
   {
     base::AutoLock auto_lock(lock_);
     for (Requests::iterator i = requests_.begin(); i != requests_.end(); ++i) {
       if (i->type == REQUEST_START && i->start_data.id == watcher_id) {
         // Watcher ids are not reused, so if we find it we can stop.
         requests_.erase(i);
         return;
       }
     }
   }

   RequestData request_data;
   request_data.type = REQUEST_STOP;
   request_data.stop_id = watcher_id;
   AddRequest(request_data);
 }

 void WatcherThreadManager::AddRequest(const RequestData& data) {
   {
     base::AutoLock auto_lock(lock_);
     const bool was_empty = requests_.empty();
     requests_.push_back(data);
     if (!was_empty)
       return;
   }

   // We outlive |thread_|, so it's safe to use Unretained() here.
   thread_.task_runner()->PostTask(
       FROM_HERE,
       base::Bind(&WatcherThreadManager::ProcessRequestsOnBackendThread,
                  base::Unretained(this)));
 }

 void WatcherThreadManager::ProcessRequestsOnBackendThread() {
   DCHECK(thread_.task_runner()->BelongsToCurrentThread());

   Requests requests;
   {
     base::AutoLock auto_lock(lock_);
     requests_.swap(requests);
   }
   for (size_t i = 0; i < requests.size(); ++i) {
     if (requests[i].type == REQUEST_START) {
       backend_.StartWatching(requests[i].start_data);
     } else {
       backend_.StopWatching(requests[i].stop_id);
     }
   }
 }

 WatcherThreadManager::WatcherThreadManager()
     : thread_(kWatcherThreadName) {
   base::Thread::Options thread_options;
   thread_options.message_pump_factory = base::Bind(&MessagePumpMojo::Create);
   thread_.StartWithOptions(thread_options);
 }

 }  // namespace

 // HandleWatcher::StateBase and subclasses -------------------------------------

 // The base class of HandleWatcher's state. Owns the user's callback and
 // monitors the current thread's MessageLoop to know when to force the callback
 // to run (with an error) even though the pipe hasn't been signaled yet.
 class HandleWatcher::StateBase : public base::MessageLoop::DestructionObserver {
  public:
   StateBase(HandleWatcher* watcher,
             const base::Callback<void(MojoResult)>& callback)
       : watcher_(watcher),
         callback_(callback),
         got_ready_(false) {
     base::MessageLoop::current()->AddDestructionObserver(this);
   }

   ~StateBase() override {
     base::MessageLoop::current()->RemoveDestructionObserver(this);
   }

  protected:
   void NotifyHandleReady(MojoResult result) {
     got_ready_ = true;
     NotifyAndDestroy(result);
   }

   bool got_ready() const { return got_ready_; }

  private:
   void WillDestroyCurrentMessageLoop() override {
     // The current thread is exiting. Simulate a watch error.
     NotifyAndDestroy(MOJO_RESULT_ABORTED);
   }

   void NotifyAndDestroy(MojoResult result) {
     base::Callback<void(MojoResult)> callback = callback_;
     watcher_->Stop();  // Destroys |this|.

     callback.Run(result);
   }

   HandleWatcher* watcher_;
   base::Callback<void(MojoResult)> callback_;

   // Have we been notified that the handle is ready?
   bool got_ready_;

   DISALLOW_COPY_AND_ASSIGN(StateBase);
 };

 // If the thread on which HandleWatcher is used runs MessagePumpMojo,
 // SameThreadWatchingState is used to directly watch the handle on the same
 // thread.
 class HandleWatcher::SameThreadWatchingState : public StateBase,
                                                public MessagePumpMojoHandler {
  public:
   SameThreadWatchingState(HandleWatcher* watcher,
                           const Handle& handle,
                           MojoHandleSignals handle_signals,
                           MojoDeadline deadline,
                           const base::Callback<void(MojoResult)>& callback)
       : StateBase(watcher, callback),
         handle_(handle) {
     DCHECK(MessagePumpMojo::IsCurrent());

     MessagePumpMojo::current()->AddHandler(
         this, handle, handle_signals, MojoDeadlineToTimeTicks(deadline));
   }

   ~SameThreadWatchingState() override {
     if (!got_ready())
       MessagePumpMojo::current()->RemoveHandler(handle_);
   }

  private:
   // MessagePumpMojoHandler overrides:
   void OnHandleReady(const Handle& handle) override {
     StopWatchingAndNotifyReady(handle, MOJO_RESULT_OK);
   }

   void OnHandleError(const Handle& handle, MojoResult result) override {
     StopWatchingAndNotifyReady(handle, result);
   }

   void StopWatchingAndNotifyReady(const Handle& handle, MojoResult result) {
     DCHECK_EQ(handle.value(), handle_.value());
     MessagePumpMojo::current()->RemoveHandler(handle_);
     NotifyHandleReady(result);
   }

   Handle handle_;

   DISALLOW_COPY_AND_ASSIGN(SameThreadWatchingState);
 };

 // If the thread on which HandleWatcher is used runs a message pump different
 // from MessagePumpMojo, SecondaryThreadWatchingState is used to watch the
 // handle on the handle watcher thread.
 class HandleWatcher::SecondaryThreadWatchingState : public StateBase {
  public:
   SecondaryThreadWatchingState(HandleWatcher* watcher,
                                const Handle& handle,
                                MojoHandleSignals handle_signals,
                                MojoDeadline deadline,
                                const base::Callback<void(MojoResult)>& callback)
       : StateBase(watcher, callback),
         weak_factory_(this) {
     watcher_id_ = WatcherThreadManager::GetInstance()->StartWatching(
         handle,
         handle_signals,
         MojoDeadlineToTimeTicks(deadline),
         base::Bind(&SecondaryThreadWatchingState::NotifyHandleReady,
                    weak_factory_.GetWeakPtr()));
   }

   ~SecondaryThreadWatchingState() override {
     // If we've been notified the handle is ready (|got_ready()| is true) then
     // the watch has been implicitly removed by
     // WatcherThreadManager/MessagePumpMojo and we don't have to call
     // StopWatching(). To do so would needlessly entail posting a task and
     // blocking until the background thread services it.
     if (!got_ready())
       WatcherThreadManager::GetInstance()->StopWatching(watcher_id_);
   }

  private:
   WatcherID watcher_id_;

   // Used to weakly bind |this| to the WatcherThreadManager.
   base::WeakPtrFactory<SecondaryThreadWatchingState> weak_factory_;

   DISALLOW_COPY_AND_ASSIGN(SecondaryThreadWatchingState);
 };

 // HandleWatcher ---------------------------------------------------------------

 HandleWatcher::HandleWatcher() {
 }

 HandleWatcher::~HandleWatcher() {
 }

 void HandleWatcher::Start(const Handle& handle,
                           MojoHandleSignals handle_signals,
                           MojoDeadline deadline,
                           const base::Callback<void(MojoResult)>& callback) {
   DCHECK(handle.is_valid());
   DCHECK_NE(MOJO_HANDLE_SIGNAL_NONE, handle_signals);

   // Need to clear the state before creating a new one.
   state_.reset();
   if (MessagePumpMojo::IsCurrent()) {
     state_.reset(new SameThreadWatchingState(
         this, handle, handle_signals, deadline, callback));
   } else {
 #if !defined(OFFICIAL_BUILD)
     // Just for making debugging non-transferable message pipes easier. Since
     // they can't be sent after they're read/written/listened to,
     // MessagePipeDispatcher saves the callstack of when it's "bound" to a
     // pipe id. Triggering a read here, instead of later in the PostTask, means
     // we have a callstack that is useful to check if the pipe is erronously
     // attempted to be sent.
     uint32_t temp = 0;
     MojoReadMessage(handle.value(), nullptr, &temp, nullptr, nullptr,
                     MOJO_READ_MESSAGE_FLAG_NONE);
 #endif
     state_.reset(new SecondaryThreadWatchingState(
         this, handle, handle_signals, deadline, callback));
   }
 }

 void HandleWatcher::Stop() {
   state_.reset();
 }

 }  // namespace common
 }  // namespace mojo
	// Copyright 2013 The Chromium 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 "mojo/message_pump/handle_watcher.h"

	#include <stddef.h>
	#include <stdint.h>

	#include <map>

	#include "base/atomic_sequence_num.h"
	#include "base/bind.h"
	#include "base/lazy_instance.h"
	#include "base/logging.h"
	#include "base/macros.h"
	#include "base/memory/singleton.h"
	#include "base/memory/weak_ptr.h"
	#include "base/message_loop/message_loop.h"
	#include "base/single_thread_task_runner.h"
	#include "base/synchronization/lock.h"
	#include "base/threading/thread.h"
	#include "base/threading/thread_task_runner_handle.h"
	#include "base/time/time.h"
	#include "mojo/message_pump/message_pump_mojo.h"
	#include "mojo/message_pump/message_pump_mojo_handler.h"
	#include "mojo/message_pump/time_helper.h"
	#include "mojo/public/c/system/message_pipe.h"

	namespace mojo {
	namespace common {

	typedef int WatcherID;

	namespace {

	const char kWatcherThreadName[] = "handle-watcher-thread";

	base::TimeTicks MojoDeadlineToTimeTicks(MojoDeadline deadline) {
	return deadline == MOJO_DEADLINE_INDEFINITE ? base::TimeTicks() :
	internal::NowTicks() + base::TimeDelta::FromMicroseconds(deadline);
	}

	// Tracks the data for a single call to Start().
	struct WatchData {
	WatchData()
	: id(0), handle_signals(MOJO_HANDLE_SIGNAL_NONE), task_runner(NULL) {}

	WatcherID id;
	Handle handle;
	MojoHandleSignals handle_signals;
	base::TimeTicks deadline;
	base::Callback<void(MojoResult)> callback;
	scoped_refptr<base::SingleThreadTaskRunner> task_runner;
	};

	// WatcherBackend --------------------------------------------------------------

	// WatcherBackend is responsible for managing the requests and interacting with
	// MessagePumpMojo. All access (outside of creation/destruction) is done on the
	// thread WatcherThreadManager creates.
	class WatcherBackend : public MessagePumpMojoHandler {
	public:
	WatcherBackend();
	~WatcherBackend() override;

	void StartWatching(const WatchData& data);
	void StopWatching(WatcherID watcher_id);

	private:
	typedef std::map<Handle, WatchData> HandleToWatchDataMap;

	// Invoked when a handle needs to be removed and notified.
	void RemoveAndNotify(const Handle& handle, MojoResult result);

	// Searches through \|handle_to_data_\| for \|watcher_id\|. Returns true if found
	// and sets \|handle\| to the Handle. Returns false if not a known id.
	bool GetMojoHandleByWatcherID(WatcherID watcher_id, Handle* handle) const;

	// MessagePumpMojoHandler overrides:
	void OnHandleReady(const Handle& handle) override;
	void OnHandleError(const Handle& handle, MojoResult result) override;

	// Maps from assigned id to WatchData.
	HandleToWatchDataMap handle_to_data_;

	DISALLOW_COPY_AND_ASSIGN(WatcherBackend);
	};

	WatcherBackend::WatcherBackend() {
	}

	WatcherBackend::~WatcherBackend() {
	}

	void WatcherBackend::StartWatching(const WatchData& data) {
	RemoveAndNotify(data.handle, MOJO_RESULT_CANCELLED);

	DCHECK_EQ(0u, handle_to_data_.count(data.handle));

	handle_to_data_[data.handle] = data;
	MessagePumpMojo::current()->AddHandler(this, data.handle,
	data.handle_signals,
	data.deadline);
	}

	void WatcherBackend::StopWatching(WatcherID watcher_id) {
	// Because of the thread hop it is entirely possible to get here and not
	// have a valid handle registered for \|watcher_id\|.
	Handle handle;
	if (!GetMojoHandleByWatcherID(watcher_id, &handle))
	return;

	handle_to_data_.erase(handle);
	MessagePumpMojo::current()->RemoveHandler(handle);
	}

	void WatcherBackend::RemoveAndNotify(const Handle& handle,
	MojoResult result) {
	if (handle_to_data_.count(handle) == 0)
	return;

	const WatchData data(handle_to_data_[handle]);
	handle_to_data_.erase(handle);
	MessagePumpMojo::current()->RemoveHandler(handle);

	data.task_runner->PostTask(FROM_HERE, base::Bind(data.callback, result));
	}

	bool WatcherBackend::GetMojoHandleByWatcherID(WatcherID watcher_id,
	Handle* handle) const {
	for (HandleToWatchDataMap::const_iterator i = handle_to_data_.begin();
	i != handle_to_data_.end(); ++i) {
	if (i->second.id == watcher_id) {
	*handle = i->second.handle;
	return true;
	}
	}
	return false;
	}

	void WatcherBackend::OnHandleReady(const Handle& handle) {
	RemoveAndNotify(handle, MOJO_RESULT_OK);
	}

	void WatcherBackend::OnHandleError(const Handle& handle, MojoResult result) {
	RemoveAndNotify(handle, result);
	}

	// WatcherThreadManager --------------------------------------------------------

	// WatcherThreadManager manages the background thread that listens for handles
	// to be ready. All requests are handled by WatcherBackend.
	class WatcherThreadManager {
	public:
	~WatcherThreadManager();

	// Returns the shared instance.
	static WatcherThreadManager* GetInstance();

	// Starts watching the requested handle. Returns a unique ID that is used to
	// stop watching the handle. When the handle is ready \|callback\| is notified
	// on the thread StartWatching() was invoked on.
	// This may be invoked on any thread.
	WatcherID StartWatching(const Handle& handle,
	MojoHandleSignals handle_signals,
	base::TimeTicks deadline,
	const base::Callback<void(MojoResult)>& callback);

	// Stops watching a handle.
	// This may be invoked on any thread.
	void StopWatching(WatcherID watcher_id);

	private:
	enum RequestType {
	REQUEST_START,
	REQUEST_STOP,
	};

	// See description of \|requests_\| for details.
	struct RequestData {
	RequestData() : type(REQUEST_START), stop_id(0) {}

	RequestType type;
	WatchData start_data;
	WatcherID stop_id;
	};

	typedef std::vector<RequestData> Requests;

	friend struct base::DefaultSingletonTraits<WatcherThreadManager>;

	WatcherThreadManager();

	// Schedules a request on the background thread. See \|requests_\| for details.
	void AddRequest(const RequestData& data);

	// Processes requests added to \|requests_\|. This is invoked on the backend
	// thread.
	void ProcessRequestsOnBackendThread();

	base::Thread thread_;

	base::AtomicSequenceNumber watcher_id_generator_;

	WatcherBackend backend_;

	// Protects \|requests_\|.
	base::Lock lock_;

	// Start/Stop result in adding a RequestData to \|requests_\| (protected by
	// \|lock_\|). When the background thread wakes up it processes the requests.
	Requests requests_;

	DISALLOW_COPY_AND_ASSIGN(WatcherThreadManager);
	};

	WatcherThreadManager::~WatcherThreadManager() {
	thread_.Stop();
	}

	WatcherThreadManager* WatcherThreadManager::GetInstance() {
	return base::Singleton<WatcherThreadManager>::get();
	}

	WatcherID WatcherThreadManager::StartWatching(
	const Handle& handle,
	MojoHandleSignals handle_signals,
	base::TimeTicks deadline,
	const base::Callback<void(MojoResult)>& callback) {
	RequestData request_data;
	request_data.type = REQUEST_START;
	request_data.start_data.id = watcher_id_generator_.GetNext();
	request_data.start_data.handle = handle;
	request_data.start_data.callback = callback;
	request_data.start_data.handle_signals = handle_signals;
	request_data.start_data.deadline = deadline;
	request_data.start_data.task_runner = base::ThreadTaskRunnerHandle::Get();
	AddRequest(request_data);
	return request_data.start_data.id;
	}

	void WatcherThreadManager::StopWatching(WatcherID watcher_id) {
	// Handle the case of StartWatching() followed by StopWatching() before
	// \|thread_\| woke up.
	{
	base::AutoLock auto_lock(lock_);
	for (Requests::iterator i = requests_.begin(); i != requests_.end(); ++i) {
	if (i->type == REQUEST_START && i->start_data.id == watcher_id) {
	// Watcher ids are not reused, so if we find it we can stop.
	requests_.erase(i);
	return;
	}
	}
	}

	RequestData request_data;
	request_data.type = REQUEST_STOP;
	request_data.stop_id = watcher_id;
	AddRequest(request_data);
	}

	void WatcherThreadManager::AddRequest(const RequestData& data) {
	{
	base::AutoLock auto_lock(lock_);
	const bool was_empty = requests_.empty();
	requests_.push_back(data);
	if (!was_empty)
	return;
	}

	// We outlive \|thread_\|, so it's safe to use Unretained() here.
	thread_.task_runner()->PostTask(
	FROM_HERE,
	base::Bind(&WatcherThreadManager::ProcessRequestsOnBackendThread,
	base::Unretained(this)));
	}

	void WatcherThreadManager::ProcessRequestsOnBackendThread() {
	DCHECK(thread_.task_runner()->BelongsToCurrentThread());

	Requests requests;
	{
	base::AutoLock auto_lock(lock_);
	requests_.swap(requests);
	}
	for (size_t i = 0; i < requests.size(); ++i) {
	if (requests[i].type == REQUEST_START) {
	backend_.StartWatching(requests[i].start_data);
	} else {
	backend_.StopWatching(requests[i].stop_id);
	}
	}
	}

	WatcherThreadManager::WatcherThreadManager()
	: thread_(kWatcherThreadName) {
	base::Thread::Options thread_options;
	thread_options.message_pump_factory = base::Bind(&MessagePumpMojo::Create);
	thread_.StartWithOptions(thread_options);
	}

	} // namespace

	// HandleWatcher::StateBase and subclasses -------------------------------------

	// The base class of HandleWatcher's state. Owns the user's callback and
	// monitors the current thread's MessageLoop to know when to force the callback
	// to run (with an error) even though the pipe hasn't been signaled yet.
	class HandleWatcher::StateBase : public base::MessageLoop::DestructionObserver {
	public:
	StateBase(HandleWatcher* watcher,
	const base::Callback<void(MojoResult)>& callback)
	: watcher_(watcher),
	callback_(callback),
	got_ready_(false) {
	base::MessageLoop::current()->AddDestructionObserver(this);
	}

	~StateBase() override {
	base::MessageLoop::current()->RemoveDestructionObserver(this);
	}

	protected:
	void NotifyHandleReady(MojoResult result) {
	got_ready_ = true;
	NotifyAndDestroy(result);
	}

	bool got_ready() const { return got_ready_; }

	private:
	void WillDestroyCurrentMessageLoop() override {
	// The current thread is exiting. Simulate a watch error.
	NotifyAndDestroy(MOJO_RESULT_ABORTED);
	}

	void NotifyAndDestroy(MojoResult result) {
	base::Callback<void(MojoResult)> callback = callback_;
	watcher_->Stop(); // Destroys \|this\|.

	callback.Run(result);
	}

	HandleWatcher* watcher_;
	base::Callback<void(MojoResult)> callback_;

	// Have we been notified that the handle is ready?
	bool got_ready_;

	DISALLOW_COPY_AND_ASSIGN(StateBase);
	};

	// If the thread on which HandleWatcher is used runs MessagePumpMojo,
	// SameThreadWatchingState is used to directly watch the handle on the same
	// thread.
	class HandleWatcher::SameThreadWatchingState : public StateBase,
	public MessagePumpMojoHandler {
	public:
	SameThreadWatchingState(HandleWatcher* watcher,
	const Handle& handle,
	MojoHandleSignals handle_signals,
	MojoDeadline deadline,
	const base::Callback<void(MojoResult)>& callback)
	: StateBase(watcher, callback),
	handle_(handle) {
	DCHECK(MessagePumpMojo::IsCurrent());

	MessagePumpMojo::current()->AddHandler(
	this, handle, handle_signals, MojoDeadlineToTimeTicks(deadline));
	}

	~SameThreadWatchingState() override {
	if (!got_ready())
	MessagePumpMojo::current()->RemoveHandler(handle_);
	}

	private:
	// MessagePumpMojoHandler overrides:
	void OnHandleReady(const Handle& handle) override {
	StopWatchingAndNotifyReady(handle, MOJO_RESULT_OK);
	}

	void OnHandleError(const Handle& handle, MojoResult result) override {
	StopWatchingAndNotifyReady(handle, result);
	}

	void StopWatchingAndNotifyReady(const Handle& handle, MojoResult result) {
	DCHECK_EQ(handle.value(), handle_.value());
	MessagePumpMojo::current()->RemoveHandler(handle_);
	NotifyHandleReady(result);
	}

	Handle handle_;

	DISALLOW_COPY_AND_ASSIGN(SameThreadWatchingState);
	};

	// If the thread on which HandleWatcher is used runs a message pump different
	// from MessagePumpMojo, SecondaryThreadWatchingState is used to watch the
	// handle on the handle watcher thread.
	class HandleWatcher::SecondaryThreadWatchingState : public StateBase {
	public:
	SecondaryThreadWatchingState(HandleWatcher* watcher,
	const Handle& handle,
	MojoHandleSignals handle_signals,
	MojoDeadline deadline,
	const base::Callback<void(MojoResult)>& callback)
	: StateBase(watcher, callback),
	weak_factory_(this) {
	watcher_id_ = WatcherThreadManager::GetInstance()->StartWatching(
	handle,
	handle_signals,
	MojoDeadlineToTimeTicks(deadline),
	base::Bind(&SecondaryThreadWatchingState::NotifyHandleReady,
	weak_factory_.GetWeakPtr()));
	}

	~SecondaryThreadWatchingState() override {
	// If we've been notified the handle is ready (\|got_ready()\| is true) then
	// the watch has been implicitly removed by
	// WatcherThreadManager/MessagePumpMojo and we don't have to call
	// StopWatching(). To do so would needlessly entail posting a task and
	// blocking until the background thread services it.
	if (!got_ready())
	WatcherThreadManager::GetInstance()->StopWatching(watcher_id_);
	}

	private:
	WatcherID watcher_id_;

	// Used to weakly bind \|this\| to the WatcherThreadManager.
	base::WeakPtrFactory<SecondaryThreadWatchingState> weak_factory_;

	DISALLOW_COPY_AND_ASSIGN(SecondaryThreadWatchingState);
	};

	// HandleWatcher ---------------------------------------------------------------

	HandleWatcher::HandleWatcher() {
	}

	HandleWatcher::~HandleWatcher() {
	}

	void HandleWatcher::Start(const Handle& handle,
	MojoHandleSignals handle_signals,
	MojoDeadline deadline,
	const base::Callback<void(MojoResult)>& callback) {
	DCHECK(handle.is_valid());
	DCHECK_NE(MOJO_HANDLE_SIGNAL_NONE, handle_signals);

	// Need to clear the state before creating a new one.
	state_.reset();
	if (MessagePumpMojo::IsCurrent()) {
	state_.reset(new SameThreadWatchingState(
	this, handle, handle_signals, deadline, callback));
	} else {
	#if !defined(OFFICIAL_BUILD)
	// Just for making debugging non-transferable message pipes easier. Since
	// they can't be sent after they're read/written/listened to,
	// MessagePipeDispatcher saves the callstack of when it's "bound" to a
	// pipe id. Triggering a read here, instead of later in the PostTask, means
	// we have a callstack that is useful to check if the pipe is erronously
	// attempted to be sent.
	uint32_t temp = 0;
	MojoReadMessage(handle.value(), nullptr, &temp, nullptr, nullptr,
	MOJO_READ_MESSAGE_FLAG_NONE);
	#endif
	state_.reset(new SecondaryThreadWatchingState(
	this, handle, handle_signals, deadline, callback));
	}
	}

	void HandleWatcher::Stop() {
	state_.reset();
	}

	} // namespace common
	} // namespace mojo