ipc/ipc_sync_channel.cc - platform/external/libchrome - Gitiles

 // Copyright (c) 2012 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 "ipc/ipc_sync_channel.h"

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

 #include <utility>

 #include "base/bind.h"
 #include "base/lazy_instance.h"
 #include "base/location.h"
 #include "base/logging.h"
 #include "base/memory/ptr_util.h"
 #include "base/synchronization/waitable_event.h"
 #include "base/synchronization/waitable_event_watcher.h"
 #include "base/threading/thread_local.h"
 #include "base/threading/thread_task_runner_handle.h"
 #include "base/trace_event/trace_event.h"
 #include "ipc/ipc_channel_factory.h"
 #include "ipc/ipc_logging.h"
 #include "ipc/ipc_message_macros.h"
 #include "ipc/ipc_sync_message.h"

 using base::TimeDelta;
 using base::TimeTicks;
 using base::WaitableEvent;

 namespace IPC {
 // When we're blocked in a Send(), we need to process incoming synchronous
 // messages right away because it could be blocking our reply (either
 // directly from the same object we're calling, or indirectly through one or
 // more other channels).  That means that in SyncContext's OnMessageReceived,
 // we need to process sync message right away if we're blocked.  However a
 // simple check isn't sufficient, because the listener thread can be in the
 // process of calling Send.
 // To work around this, when SyncChannel filters a sync message, it sets
 // an event that the listener thread waits on during its Send() call.  This
 // allows us to dispatch incoming sync messages when blocked.  The race
 // condition is handled because if Send is in the process of being called, it
 // will check the event.  In case the listener thread isn't sending a message,
 // we queue a task on the listener thread to dispatch the received messages.
 // The messages are stored in this queue object that's shared among all
 // SyncChannel objects on the same thread (since one object can receive a
 // sync message while another one is blocked).

 class SyncChannel::ReceivedSyncMsgQueue :
     public base::RefCountedThreadSafe<ReceivedSyncMsgQueue> {
  public:
   // Returns the ReceivedSyncMsgQueue instance for this thread, creating one
   // if necessary.  Call RemoveContext on the same thread when done.
   static ReceivedSyncMsgQueue* AddContext() {
     // We want one ReceivedSyncMsgQueue per listener thread (i.e. since multiple
     // SyncChannel objects can block the same thread).
     ReceivedSyncMsgQueue* rv = lazy_tls_ptr_.Pointer()->Get();
     if (!rv) {
       rv = new ReceivedSyncMsgQueue();
       ReceivedSyncMsgQueue::lazy_tls_ptr_.Pointer()->Set(rv);
     }
     rv->listener_count_++;
     return rv;
   }

   // Called on IPC thread when a synchronous message or reply arrives.
   void QueueMessage(const Message& msg, SyncChannel::SyncContext* context) {
     bool was_task_pending;
     {
       base::AutoLock auto_lock(message_lock_);

       was_task_pending = task_pending_;
       task_pending_ = true;

       // We set the event in case the listener thread is blocked (or is about
       // to). In case it's not, the PostTask dispatches the messages.
       message_queue_.push_back(QueuedMessage(new Message(msg), context));
       message_queue_version_++;
     }

     dispatch_event_.Signal();
     if (!was_task_pending) {
       listener_task_runner_->PostTask(
           FROM_HERE, base::Bind(&ReceivedSyncMsgQueue::DispatchMessagesTask,
                                 this, base::RetainedRef(context)));
     }
   }

   void QueueReply(const Message &msg, SyncChannel::SyncContext* context) {
     received_replies_.push_back(QueuedMessage(new Message(msg), context));
   }

   // Called on the listener's thread to process any queues synchronous
   // messages.
   void DispatchMessagesTask(SyncContext* context) {
     {
       base::AutoLock auto_lock(message_lock_);
       task_pending_ = false;
     }
     context->DispatchMessages();
   }

   void DispatchMessages(SyncContext* dispatching_context) {
     bool first_time = true;
     uint32_t expected_version = 0;
     SyncMessageQueue::iterator it;
     while (true) {
       Message* message = NULL;
       scoped_refptr<SyncChannel::SyncContext> context;
       {
         base::AutoLock auto_lock(message_lock_);
         if (first_time || message_queue_version_ != expected_version) {
           it = message_queue_.begin();
           first_time = false;
         }
         for (; it != message_queue_.end(); it++) {
           int message_group = it->context->restrict_dispatch_group();
           if (message_group == kRestrictDispatchGroup_None ||
               message_group == dispatching_context->restrict_dispatch_group()) {
             message = it->message;
             context = it->context;
             it = message_queue_.erase(it);
             message_queue_version_++;
             expected_version = message_queue_version_;
             break;
           }
         }
       }

       if (message == NULL)
         break;
       context->OnDispatchMessage(*message);
       delete message;
     }
   }

   // SyncChannel calls this in its destructor.
   void RemoveContext(SyncContext* context) {
     base::AutoLock auto_lock(message_lock_);

     SyncMessageQueue::iterator iter = message_queue_.begin();
     while (iter != message_queue_.end()) {
       if (iter->context.get() == context) {
         delete iter->message;
         iter = message_queue_.erase(iter);
         message_queue_version_++;
       } else {
         iter++;
       }
     }

     if (--listener_count_ == 0) {
       DCHECK(lazy_tls_ptr_.Pointer()->Get());
       lazy_tls_ptr_.Pointer()->Set(NULL);
     }
   }

   WaitableEvent* dispatch_event() { return &dispatch_event_; }
   base::SingleThreadTaskRunner* listener_task_runner() {
     return listener_task_runner_.get();
   }

   // Holds a pointer to the per-thread ReceivedSyncMsgQueue object.
   static base::LazyInstance<base::ThreadLocalPointer<ReceivedSyncMsgQueue> >
       lazy_tls_ptr_;

   // Called on the ipc thread to check if we can unblock any current Send()
   // calls based on a queued reply.
   void DispatchReplies() {
     for (size_t i = 0; i < received_replies_.size(); ++i) {
       Message* message = received_replies_[i].message;
       if (received_replies_[i].context->TryToUnblockListener(message)) {
         delete message;
         received_replies_.erase(received_replies_.begin() + i);
         return;
       }
     }
   }

   base::WaitableEventWatcher* top_send_done_watcher() {
     return top_send_done_watcher_;
   }

   void set_top_send_done_watcher(base::WaitableEventWatcher* watcher) {
     top_send_done_watcher_ = watcher;
   }

  private:
   friend class base::RefCountedThreadSafe<ReceivedSyncMsgQueue>;

   // See the comment in SyncChannel::SyncChannel for why this event is created
   // as manual reset.
   ReceivedSyncMsgQueue() :
       message_queue_version_(0),
       dispatch_event_(true, false),
       listener_task_runner_(base::ThreadTaskRunnerHandle::Get()),
       task_pending_(false),
       listener_count_(0),
       top_send_done_watcher_(NULL) {
   }

   ~ReceivedSyncMsgQueue() {}

   // Holds information about a queued synchronous message or reply.
   struct QueuedMessage {
     QueuedMessage(Message* m, SyncContext* c) : message(m), context(c) { }
     Message* message;
     scoped_refptr<SyncChannel::SyncContext> context;
   };

   typedef std::list<QueuedMessage> SyncMessageQueue;
   SyncMessageQueue message_queue_;
   uint32_t message_queue_version_;  // Used to signal DispatchMessages to rescan

   std::vector<QueuedMessage> received_replies_;

   // Set when we got a synchronous message that we must respond to as the
   // sender needs its reply before it can reply to our original synchronous
   // message.
   WaitableEvent dispatch_event_;
   scoped_refptr<base::SingleThreadTaskRunner> listener_task_runner_;
   base::Lock message_lock_;
   bool task_pending_;
   int listener_count_;

   // The current send done event watcher for this thread. Used to maintain
   // a local global stack of send done watchers to ensure that nested sync
   // message loops complete correctly.
   base::WaitableEventWatcher* top_send_done_watcher_;
 };

 base::LazyInstance<base::ThreadLocalPointer<SyncChannel::ReceivedSyncMsgQueue> >
     SyncChannel::ReceivedSyncMsgQueue::lazy_tls_ptr_ =
         LAZY_INSTANCE_INITIALIZER;

 SyncChannel::SyncContext::SyncContext(
     Listener* listener,
     const scoped_refptr<base::SingleThreadTaskRunner>& ipc_task_runner,
     WaitableEvent* shutdown_event)
     : ChannelProxy::Context(listener, ipc_task_runner),
       received_sync_msgs_(ReceivedSyncMsgQueue::AddContext()),
       shutdown_event_(shutdown_event),
       restrict_dispatch_group_(kRestrictDispatchGroup_None) {
 }

 SyncChannel::SyncContext::~SyncContext() {
   while (!deserializers_.empty())
     Pop();
 }

 // Adds information about an outgoing sync message to the context so that
 // we know how to deserialize the reply.  Returns a handle that's set when
 // the reply has arrived.
 void SyncChannel::SyncContext::Push(SyncMessage* sync_msg) {
   // Create the tracking information for this message. This object is stored
   // by value since all members are pointers that are cheap to copy. These
   // pointers are cleaned up in the Pop() function.
   //
   // The event is created as manual reset because in between Signal and
   // OnObjectSignalled, another Send can happen which would stop the watcher
   // from being called.  The event would get watched later, when the nested
   // Send completes, so the event will need to remain set.
   PendingSyncMsg pending(SyncMessage::GetMessageId(*sync_msg),
                          sync_msg->GetReplyDeserializer(),
                          new WaitableEvent(true, false));
   base::AutoLock auto_lock(deserializers_lock_);
   deserializers_.push_back(pending);
 }

 bool SyncChannel::SyncContext::Pop() {
   bool result;
   {
     base::AutoLock auto_lock(deserializers_lock_);
     PendingSyncMsg msg = deserializers_.back();
     delete msg.deserializer;
     delete msg.done_event;
     msg.done_event = NULL;
     deserializers_.pop_back();
     result = msg.send_result;
   }

   // We got a reply to a synchronous Send() call that's blocking the listener
   // thread.  However, further down the call stack there could be another
   // blocking Send() call, whose reply we received after we made this last
   // Send() call.  So check if we have any queued replies available that
   // can now unblock the listener thread.
   ipc_task_runner()->PostTask(
       FROM_HERE, base::Bind(&ReceivedSyncMsgQueue::DispatchReplies,
                             received_sync_msgs_.get()));

   return result;
 }

 WaitableEvent* SyncChannel::SyncContext::GetSendDoneEvent() {
   base::AutoLock auto_lock(deserializers_lock_);
   return deserializers_.back().done_event;
 }

 WaitableEvent* SyncChannel::SyncContext::GetDispatchEvent() {
   return received_sync_msgs_->dispatch_event();
 }

 void SyncChannel::SyncContext::DispatchMessages() {
   received_sync_msgs_->DispatchMessages(this);
 }

 bool SyncChannel::SyncContext::TryToUnblockListener(const Message* msg) {
   base::AutoLock auto_lock(deserializers_lock_);
   if (deserializers_.empty() ||
       !SyncMessage::IsMessageReplyTo(*msg, deserializers_.back().id)) {
     return false;
   }

   if (!msg->is_reply_error()) {
     bool send_result = deserializers_.back().deserializer->
         SerializeOutputParameters(*msg);
     deserializers_.back().send_result = send_result;
     DVLOG_IF(1, !send_result) << "Couldn't deserialize reply message";
   } else {
     DVLOG(1) << "Received error reply";
   }

   base::WaitableEvent* done_event = deserializers_.back().done_event;
   TRACE_EVENT_FLOW_BEGIN0(
       TRACE_DISABLED_BY_DEFAULT("ipc.flow"),
       "SyncChannel::SyncContext::TryToUnblockListener", done_event);

   done_event->Signal();

   return true;
 }

 void SyncChannel::SyncContext::Clear() {
   CancelPendingSends();
   received_sync_msgs_->RemoveContext(this);
   Context::Clear();
 }

 bool SyncChannel::SyncContext::OnMessageReceived(const Message& msg) {
   // Give the filters a chance at processing this message.
   if (TryFilters(msg))
     return true;

   if (TryToUnblockListener(&msg))
     return true;

   if (msg.is_reply()) {
     received_sync_msgs_->QueueReply(msg, this);
     return true;
   }

   if (msg.should_unblock()) {
     received_sync_msgs_->QueueMessage(msg, this);
     return true;
   }

   return Context::OnMessageReceivedNoFilter(msg);
 }

 void SyncChannel::SyncContext::OnChannelError() {
   CancelPendingSends();
   shutdown_watcher_.StopWatching();
   Context::OnChannelError();
 }

 void SyncChannel::SyncContext::OnChannelOpened() {
   shutdown_watcher_.StartWatching(
       shutdown_event_,
       base::Bind(&SyncChannel::SyncContext::OnWaitableEventSignaled,
                  base::Unretained(this)));
   Context::OnChannelOpened();
 }

 void SyncChannel::SyncContext::OnChannelClosed() {
   CancelPendingSends();
   shutdown_watcher_.StopWatching();
   Context::OnChannelClosed();
 }

 void SyncChannel::SyncContext::CancelPendingSends() {
   base::AutoLock auto_lock(deserializers_lock_);
   PendingSyncMessageQueue::iterator iter;
   DVLOG(1) << "Canceling pending sends";
   for (iter = deserializers_.begin(); iter != deserializers_.end(); iter++) {
     TRACE_EVENT_FLOW_BEGIN0(TRACE_DISABLED_BY_DEFAULT("ipc.flow"),
                             "SyncChannel::SyncContext::CancelPendingSends",
                             iter->done_event);
     iter->done_event->Signal();
   }
 }

 void SyncChannel::SyncContext::OnWaitableEventSignaled(WaitableEvent* event) {
   if (event == shutdown_event_) {
     // Process shut down before we can get a reply to a synchronous message.
     // Cancel pending Send calls, which will end up setting the send done event.
     CancelPendingSends();
   } else {
     // We got the reply, timed out or the process shutdown.
     DCHECK_EQ(GetSendDoneEvent(), event);
     base::MessageLoop::current()->QuitNow();
   }
 }

 base::WaitableEventWatcher::EventCallback
     SyncChannel::SyncContext::MakeWaitableEventCallback() {
   return base::Bind(&SyncChannel::SyncContext::OnWaitableEventSignaled, this);
 }

 // static
 std::unique_ptr<SyncChannel> SyncChannel::Create(
     const IPC::ChannelHandle& channel_handle,
     Channel::Mode mode,
     Listener* listener,
     const scoped_refptr<base::SingleThreadTaskRunner>& ipc_task_runner,
     bool create_pipe_now,
     base::WaitableEvent* shutdown_event) {
   std::unique_ptr<SyncChannel> channel =
       Create(listener, ipc_task_runner, shutdown_event);
   channel->Init(channel_handle, mode, create_pipe_now);
   return channel;
 }

 // static
 std::unique_ptr<SyncChannel> SyncChannel::Create(
     std::unique_ptr<ChannelFactory> factory,
     Listener* listener,
     const scoped_refptr<base::SingleThreadTaskRunner>& ipc_task_runner,
     bool create_pipe_now,
     base::WaitableEvent* shutdown_event) {
   std::unique_ptr<SyncChannel> channel =
       Create(listener, ipc_task_runner, shutdown_event);
   channel->Init(std::move(factory), create_pipe_now);
   return channel;
 }

 // static
 std::unique_ptr<SyncChannel> SyncChannel::Create(
     Listener* listener,
     const scoped_refptr<base::SingleThreadTaskRunner>& ipc_task_runner,
     WaitableEvent* shutdown_event) {
   return base::WrapUnique(
       new SyncChannel(listener, ipc_task_runner, shutdown_event));
 }

 SyncChannel::SyncChannel(
     Listener* listener,
     const scoped_refptr<base::SingleThreadTaskRunner>& ipc_task_runner,
     WaitableEvent* shutdown_event)
     : ChannelProxy(new SyncContext(listener, ipc_task_runner, shutdown_event)) {
   // The current (listener) thread must be distinct from the IPC thread, or else
   // sending synchronous messages will deadlock.
   DCHECK_NE(ipc_task_runner.get(), base::ThreadTaskRunnerHandle::Get().get());
   StartWatching();
 }

 SyncChannel::~SyncChannel() {
 }

 void SyncChannel::SetRestrictDispatchChannelGroup(int group) {
   sync_context()->set_restrict_dispatch_group(group);
 }

 scoped_refptr<SyncMessageFilter> SyncChannel::CreateSyncMessageFilter() {
   scoped_refptr<SyncMessageFilter> filter = new SyncMessageFilter(
       sync_context()->shutdown_event(),
       sync_context()->IsChannelSendThreadSafe());
   AddFilter(filter.get());
   if (!did_init())
     pre_init_sync_message_filters_.push_back(filter);
   return filter;
 }

 bool SyncChannel::Send(Message* message) {
 #ifdef IPC_MESSAGE_LOG_ENABLED
   std::string name;
   Logging::GetInstance()->GetMessageText(message->type(), &name, message, NULL);
   TRACE_EVENT1("ipc", "SyncChannel::Send", "name", name);
 #else
   TRACE_EVENT2("ipc", "SyncChannel::Send",
                "class", IPC_MESSAGE_ID_CLASS(message->type()),
                "line", IPC_MESSAGE_ID_LINE(message->type()));
 #endif
   if (!message->is_sync()) {
     ChannelProxy::Send(message);
     return true;
   }

   // *this* might get deleted in WaitForReply.
   scoped_refptr<SyncContext> context(sync_context());
   if (context->shutdown_event()->IsSignaled()) {
     DVLOG(1) << "shutdown event is signaled";
     delete message;
     return false;
   }

   SyncMessage* sync_msg = static_cast<SyncMessage*>(message);
   context->Push(sync_msg);
   WaitableEvent* pump_messages_event = sync_msg->pump_messages_event();

   ChannelProxy::Send(message);

   // Wait for reply, or for any other incoming synchronous messages.
   // *this* might get deleted, so only call static functions at this point.
   WaitForReply(context.get(), pump_messages_event);

   TRACE_EVENT_FLOW_END0(TRACE_DISABLED_BY_DEFAULT("ipc.flow"),
                         "SyncChannel::Send", context->GetSendDoneEvent());

   return context->Pop();
 }

 void SyncChannel::WaitForReply(
     SyncContext* context, WaitableEvent* pump_messages_event) {
   context->DispatchMessages();
   while (true) {
     WaitableEvent* objects[] = {
       context->GetDispatchEvent(),
       context->GetSendDoneEvent(),
       pump_messages_event
     };

     unsigned count = pump_messages_event ? 3: 2;
     size_t result = WaitableEvent::WaitMany(objects, count);
     if (result == 0 /* dispatch event */) {
       // We're waiting for a reply, but we received a blocking synchronous
       // call.  We must process it or otherwise a deadlock might occur.
       context->GetDispatchEvent()->Reset();
       context->DispatchMessages();
       continue;
     }

     if (result == 2 /* pump_messages_event */)
       WaitForReplyWithNestedMessageLoop(context);  // Run a nested message loop.

     break;
   }
 }

 void SyncChannel::WaitForReplyWithNestedMessageLoop(SyncContext* context) {
   base::WaitableEventWatcher send_done_watcher;

   ReceivedSyncMsgQueue* sync_msg_queue = context->received_sync_msgs();
   DCHECK(sync_msg_queue != NULL);

   base::WaitableEventWatcher* old_send_done_event_watcher =
       sync_msg_queue->top_send_done_watcher();

   base::WaitableEventWatcher::EventCallback old_callback;
   base::WaitableEvent* old_event = NULL;

   // Maintain a local global stack of send done delegates to ensure that
   // nested sync calls complete in the correct sequence, i.e. the
   // outermost call completes first, etc.
   if (old_send_done_event_watcher) {
     old_callback = old_send_done_event_watcher->callback();
     old_event = old_send_done_event_watcher->GetWatchedEvent();
     old_send_done_event_watcher->StopWatching();
   }

   sync_msg_queue->set_top_send_done_watcher(&send_done_watcher);

   send_done_watcher.StartWatching(context->GetSendDoneEvent(),
                                   context->MakeWaitableEventCallback());

   {
     base::MessageLoop::ScopedNestableTaskAllower allow(
         base::MessageLoop::current());
     base::MessageLoop::current()->Run();
   }

   sync_msg_queue->set_top_send_done_watcher(old_send_done_event_watcher);
   if (old_send_done_event_watcher && old_event) {
     old_send_done_event_watcher->StartWatching(old_event, old_callback);
   }
 }

 void SyncChannel::OnWaitableEventSignaled(WaitableEvent* event) {
   DCHECK(event == sync_context()->GetDispatchEvent());
   // The call to DispatchMessages might delete this object, so reregister
   // the object watcher first.
   event->Reset();
   dispatch_watcher_.StartWatching(event, dispatch_watcher_callback_);
   sync_context()->DispatchMessages();
 }

 void SyncChannel::StartWatching() {
   // Ideally we only want to watch this object when running a nested message
   // loop.  However, we don't know when it exits if there's another nested
   // message loop running under it or not, so we wouldn't know whether to
   // stop or keep watching.  So we always watch it, and create the event as
   // manual reset since the object watcher might otherwise reset the event
   // when we're doing a WaitMany.
   dispatch_watcher_callback_ =
       base::Bind(&SyncChannel::OnWaitableEventSignaled,
                   base::Unretained(this));
   dispatch_watcher_.StartWatching(sync_context()->GetDispatchEvent(),
                                   dispatch_watcher_callback_);
 }

 void SyncChannel::OnChannelInit() {
   for (const auto& filter : pre_init_sync_message_filters_) {
     filter->set_is_channel_send_thread_safe(
         context()->IsChannelSendThreadSafe());
   }
   pre_init_sync_message_filters_.clear();
 }

 bool SyncChannel::SendNow(std::unique_ptr<Message> message) {
 #ifdef IPC_MESSAGE_LOG_ENABLED
   std::string name;
   Logging::GetInstance()->GetMessageText(
       message->type(), &name, message.get(), nullptr);
   TRACE_EVENT1("ipc", "SyncChannel::SendNow", "name", name);
 #else
   TRACE_EVENT2("ipc", "SyncChannel::SendNow",
                "class", IPC_MESSAGE_ID_CLASS(message->type()),
                "line", IPC_MESSAGE_ID_LINE(message->type()));
 #endif
   if (!message->is_sync())
     return ChannelProxy::SendNow(std::move(message));
   return Send(message.release());
 }

 bool SyncChannel::SendOnIPCThread(std::unique_ptr<Message> message) {
 #ifdef IPC_MESSAGE_LOG_ENABLED
   std::string name;
   Logging::GetInstance()->GetMessageText(
       message->type(), &name, message.get(), nullptr);
   TRACE_EVENT1("ipc", "SyncChannel::SendOnIPCThread", "name", name);
 #else
   TRACE_EVENT2("ipc", "SyncChannel::SendOnIPCThread",
                "class", IPC_MESSAGE_ID_CLASS(message->type()),
                "line", IPC_MESSAGE_ID_LINE(message->type()));
 #endif
   if (!message->is_sync())
     return ChannelProxy::SendOnIPCThread(std::move(message));
   return Send(message.release());
 }

 }  // namespace IPC
	// Copyright (c) 2012 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 "ipc/ipc_sync_channel.h"

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

	#include <utility>

	#include "base/bind.h"
	#include "base/lazy_instance.h"
	#include "base/location.h"
	#include "base/logging.h"
	#include "base/memory/ptr_util.h"
	#include "base/synchronization/waitable_event.h"
	#include "base/synchronization/waitable_event_watcher.h"
	#include "base/threading/thread_local.h"
	#include "base/threading/thread_task_runner_handle.h"
	#include "base/trace_event/trace_event.h"
	#include "ipc/ipc_channel_factory.h"
	#include "ipc/ipc_logging.h"
	#include "ipc/ipc_message_macros.h"
	#include "ipc/ipc_sync_message.h"

	using base::TimeDelta;
	using base::TimeTicks;
	using base::WaitableEvent;

	namespace IPC {
	// When we're blocked in a Send(), we need to process incoming synchronous
	// messages right away because it could be blocking our reply (either
	// directly from the same object we're calling, or indirectly through one or
	// more other channels). That means that in SyncContext's OnMessageReceived,
	// we need to process sync message right away if we're blocked. However a
	// simple check isn't sufficient, because the listener thread can be in the
	// process of calling Send.
	// To work around this, when SyncChannel filters a sync message, it sets
	// an event that the listener thread waits on during its Send() call. This
	// allows us to dispatch incoming sync messages when blocked. The race
	// condition is handled because if Send is in the process of being called, it
	// will check the event. In case the listener thread isn't sending a message,
	// we queue a task on the listener thread to dispatch the received messages.
	// The messages are stored in this queue object that's shared among all
	// SyncChannel objects on the same thread (since one object can receive a
	// sync message while another one is blocked).

	class SyncChannel::ReceivedSyncMsgQueue :
	public base::RefCountedThreadSafe<ReceivedSyncMsgQueue> {
	public:
	// Returns the ReceivedSyncMsgQueue instance for this thread, creating one
	// if necessary. Call RemoveContext on the same thread when done.
	static ReceivedSyncMsgQueue* AddContext() {
	// We want one ReceivedSyncMsgQueue per listener thread (i.e. since multiple
	// SyncChannel objects can block the same thread).
	ReceivedSyncMsgQueue* rv = lazy_tls_ptr_.Pointer()->Get();
	if (!rv) {
	rv = new ReceivedSyncMsgQueue();
	ReceivedSyncMsgQueue::lazy_tls_ptr_.Pointer()->Set(rv);
	}
	rv->listener_count_++;
	return rv;
	}

	// Called on IPC thread when a synchronous message or reply arrives.
	void QueueMessage(const Message& msg, SyncChannel::SyncContext* context) {
	bool was_task_pending;
	{
	base::AutoLock auto_lock(message_lock_);

	was_task_pending = task_pending_;
	task_pending_ = true;

	// We set the event in case the listener thread is blocked (or is about
	// to). In case it's not, the PostTask dispatches the messages.
	message_queue_.push_back(QueuedMessage(new Message(msg), context));
	message_queue_version_++;
	}

	dispatch_event_.Signal();
	if (!was_task_pending) {
	listener_task_runner_->PostTask(
	FROM_HERE, base::Bind(&ReceivedSyncMsgQueue::DispatchMessagesTask,
	this, base::RetainedRef(context)));
	}
	}

	void QueueReply(const Message &msg, SyncChannel::SyncContext* context) {
	received_replies_.push_back(QueuedMessage(new Message(msg), context));
	}

	// Called on the listener's thread to process any queues synchronous
	// messages.
	void DispatchMessagesTask(SyncContext* context) {
	{
	base::AutoLock auto_lock(message_lock_);
	task_pending_ = false;
	}
	context->DispatchMessages();
	}

	void DispatchMessages(SyncContext* dispatching_context) {
	bool first_time = true;
	uint32_t expected_version = 0;
	SyncMessageQueue::iterator it;
	while (true) {
	Message* message = NULL;
	scoped_refptr<SyncChannel::SyncContext> context;
	{
	base::AutoLock auto_lock(message_lock_);
	if (first_time \|\| message_queue_version_ != expected_version) {
	it = message_queue_.begin();
	first_time = false;
	}
	for (; it != message_queue_.end(); it++) {
	int message_group = it->context->restrict_dispatch_group();
	if (message_group == kRestrictDispatchGroup_None \|\|
	message_group == dispatching_context->restrict_dispatch_group()) {
	message = it->message;
	context = it->context;
	it = message_queue_.erase(it);
	message_queue_version_++;
	expected_version = message_queue_version_;
	break;
	}
	}
	}

	if (message == NULL)
	break;
	context->OnDispatchMessage(*message);
	delete message;
	}
	}

	// SyncChannel calls this in its destructor.
	void RemoveContext(SyncContext* context) {
	base::AutoLock auto_lock(message_lock_);

	SyncMessageQueue::iterator iter = message_queue_.begin();
	while (iter != message_queue_.end()) {
	if (iter->context.get() == context) {
	delete iter->message;
	iter = message_queue_.erase(iter);
	message_queue_version_++;
	} else {
	iter++;
	}
	}

	if (--listener_count_ == 0) {
	DCHECK(lazy_tls_ptr_.Pointer()->Get());
	lazy_tls_ptr_.Pointer()->Set(NULL);
	}
	}

	WaitableEvent* dispatch_event() { return &dispatch_event_; }
	base::SingleThreadTaskRunner* listener_task_runner() {
	return listener_task_runner_.get();
	}

	// Holds a pointer to the per-thread ReceivedSyncMsgQueue object.
	static base::LazyInstance<base::ThreadLocalPointer<ReceivedSyncMsgQueue> >
	lazy_tls_ptr_;

	// Called on the ipc thread to check if we can unblock any current Send()
	// calls based on a queued reply.
	void DispatchReplies() {
	for (size_t i = 0; i < received_replies_.size(); ++i) {
	Message* message = received_replies_[i].message;
	if (received_replies_[i].context->TryToUnblockListener(message)) {
	delete message;
	received_replies_.erase(received_replies_.begin() + i);
	return;
	}
	}
	}

	base::WaitableEventWatcher* top_send_done_watcher() {
	return top_send_done_watcher_;
	}

	void set_top_send_done_watcher(base::WaitableEventWatcher* watcher) {
	top_send_done_watcher_ = watcher;
	}

	private:
	friend class base::RefCountedThreadSafe<ReceivedSyncMsgQueue>;

	// See the comment in SyncChannel::SyncChannel for why this event is created
	// as manual reset.
	ReceivedSyncMsgQueue() :
	message_queue_version_(0),
	dispatch_event_(true, false),
	listener_task_runner_(base::ThreadTaskRunnerHandle::Get()),
	task_pending_(false),
	listener_count_(0),
	top_send_done_watcher_(NULL) {
	}

	~ReceivedSyncMsgQueue() {}

	// Holds information about a queued synchronous message or reply.
	struct QueuedMessage {
	QueuedMessage(Message* m, SyncContext* c) : message(m), context(c) { }
	Message* message;
	scoped_refptr<SyncChannel::SyncContext> context;
	};

	typedef std::list<QueuedMessage> SyncMessageQueue;
	SyncMessageQueue message_queue_;
	uint32_t message_queue_version_; // Used to signal DispatchMessages to rescan

	std::vector<QueuedMessage> received_replies_;

	// Set when we got a synchronous message that we must respond to as the
	// sender needs its reply before it can reply to our original synchronous
	// message.
	WaitableEvent dispatch_event_;
	scoped_refptr<base::SingleThreadTaskRunner> listener_task_runner_;
	base::Lock message_lock_;
	bool task_pending_;
	int listener_count_;

	// The current send done event watcher for this thread. Used to maintain
	// a local global stack of send done watchers to ensure that nested sync
	// message loops complete correctly.
	base::WaitableEventWatcher* top_send_done_watcher_;
	};

	base::LazyInstance<base::ThreadLocalPointer<SyncChannel::ReceivedSyncMsgQueue> >
	SyncChannel::ReceivedSyncMsgQueue::lazy_tls_ptr_ =
	LAZY_INSTANCE_INITIALIZER;

	SyncChannel::SyncContext::SyncContext(
	Listener* listener,
	const scoped_refptr<base::SingleThreadTaskRunner>& ipc_task_runner,
	WaitableEvent* shutdown_event)
	: ChannelProxy::Context(listener, ipc_task_runner),
	received_sync_msgs_(ReceivedSyncMsgQueue::AddContext()),
	shutdown_event_(shutdown_event),
	restrict_dispatch_group_(kRestrictDispatchGroup_None) {
	}

	SyncChannel::SyncContext::~SyncContext() {
	while (!deserializers_.empty())
	Pop();
	}

	// Adds information about an outgoing sync message to the context so that
	// we know how to deserialize the reply. Returns a handle that's set when
	// the reply has arrived.
	void SyncChannel::SyncContext::Push(SyncMessage* sync_msg) {
	// Create the tracking information for this message. This object is stored
	// by value since all members are pointers that are cheap to copy. These
	// pointers are cleaned up in the Pop() function.
	//
	// The event is created as manual reset because in between Signal and
	// OnObjectSignalled, another Send can happen which would stop the watcher
	// from being called. The event would get watched later, when the nested
	// Send completes, so the event will need to remain set.
	PendingSyncMsg pending(SyncMessage::GetMessageId(*sync_msg),
	sync_msg->GetReplyDeserializer(),
	new WaitableEvent(true, false));
	base::AutoLock auto_lock(deserializers_lock_);
	deserializers_.push_back(pending);
	}

	bool SyncChannel::SyncContext::Pop() {
	bool result;
	{
	base::AutoLock auto_lock(deserializers_lock_);
	PendingSyncMsg msg = deserializers_.back();
	delete msg.deserializer;
	delete msg.done_event;
	msg.done_event = NULL;
	deserializers_.pop_back();
	result = msg.send_result;
	}

	// We got a reply to a synchronous Send() call that's blocking the listener
	// thread. However, further down the call stack there could be another
	// blocking Send() call, whose reply we received after we made this last
	// Send() call. So check if we have any queued replies available that
	// can now unblock the listener thread.
	ipc_task_runner()->PostTask(
	FROM_HERE, base::Bind(&ReceivedSyncMsgQueue::DispatchReplies,
	received_sync_msgs_.get()));

	return result;
	}

	WaitableEvent* SyncChannel::SyncContext::GetSendDoneEvent() {
	base::AutoLock auto_lock(deserializers_lock_);
	return deserializers_.back().done_event;
	}

	WaitableEvent* SyncChannel::SyncContext::GetDispatchEvent() {
	return received_sync_msgs_->dispatch_event();
	}

	void SyncChannel::SyncContext::DispatchMessages() {
	received_sync_msgs_->DispatchMessages(this);
	}

	bool SyncChannel::SyncContext::TryToUnblockListener(const Message* msg) {
	base::AutoLock auto_lock(deserializers_lock_);
	if (deserializers_.empty() \|\|
	!SyncMessage::IsMessageReplyTo(*msg, deserializers_.back().id)) {
	return false;
	}

	if (!msg->is_reply_error()) {
	bool send_result = deserializers_.back().deserializer->
	SerializeOutputParameters(*msg);
	deserializers_.back().send_result = send_result;
	DVLOG_IF(1, !send_result) << "Couldn't deserialize reply message";
	} else {
	DVLOG(1) << "Received error reply";
	}

	base::WaitableEvent* done_event = deserializers_.back().done_event;
	TRACE_EVENT_FLOW_BEGIN0(
	TRACE_DISABLED_BY_DEFAULT("ipc.flow"),
	"SyncChannel::SyncContext::TryToUnblockListener", done_event);

	done_event->Signal();

	return true;
	}

	void SyncChannel::SyncContext::Clear() {
	CancelPendingSends();
	received_sync_msgs_->RemoveContext(this);
	Context::Clear();
	}

	bool SyncChannel::SyncContext::OnMessageReceived(const Message& msg) {
	// Give the filters a chance at processing this message.
	if (TryFilters(msg))
	return true;

	if (TryToUnblockListener(&msg))
	return true;

	if (msg.is_reply()) {
	received_sync_msgs_->QueueReply(msg, this);
	return true;
	}

	if (msg.should_unblock()) {
	received_sync_msgs_->QueueMessage(msg, this);
	return true;
	}

	return Context::OnMessageReceivedNoFilter(msg);
	}

	void SyncChannel::SyncContext::OnChannelError() {
	CancelPendingSends();
	shutdown_watcher_.StopWatching();
	Context::OnChannelError();
	}

	void SyncChannel::SyncContext::OnChannelOpened() {
	shutdown_watcher_.StartWatching(
	shutdown_event_,
	base::Bind(&SyncChannel::SyncContext::OnWaitableEventSignaled,
	base::Unretained(this)));
	Context::OnChannelOpened();
	}

	void SyncChannel::SyncContext::OnChannelClosed() {
	CancelPendingSends();
	shutdown_watcher_.StopWatching();
	Context::OnChannelClosed();
	}

	void SyncChannel::SyncContext::CancelPendingSends() {
	base::AutoLock auto_lock(deserializers_lock_);
	PendingSyncMessageQueue::iterator iter;
	DVLOG(1) << "Canceling pending sends";
	for (iter = deserializers_.begin(); iter != deserializers_.end(); iter++) {
	TRACE_EVENT_FLOW_BEGIN0(TRACE_DISABLED_BY_DEFAULT("ipc.flow"),
	"SyncChannel::SyncContext::CancelPendingSends",
	iter->done_event);
	iter->done_event->Signal();
	}
	}

	void SyncChannel::SyncContext::OnWaitableEventSignaled(WaitableEvent* event) {
	if (event == shutdown_event_) {
	// Process shut down before we can get a reply to a synchronous message.
	// Cancel pending Send calls, which will end up setting the send done event.
	CancelPendingSends();
	} else {
	// We got the reply, timed out or the process shutdown.
	DCHECK_EQ(GetSendDoneEvent(), event);
	base::MessageLoop::current()->QuitNow();
	}
	}

	base::WaitableEventWatcher::EventCallback
	SyncChannel::SyncContext::MakeWaitableEventCallback() {
	return base::Bind(&SyncChannel::SyncContext::OnWaitableEventSignaled, this);
	}

	// static
	std::unique_ptr<SyncChannel> SyncChannel::Create(
	const IPC::ChannelHandle& channel_handle,
	Channel::Mode mode,
	Listener* listener,
	const scoped_refptr<base::SingleThreadTaskRunner>& ipc_task_runner,
	bool create_pipe_now,
	base::WaitableEvent* shutdown_event) {
	std::unique_ptr<SyncChannel> channel =
	Create(listener, ipc_task_runner, shutdown_event);
	channel->Init(channel_handle, mode, create_pipe_now);
	return channel;
	}

	// static
	std::unique_ptr<SyncChannel> SyncChannel::Create(
	std::unique_ptr<ChannelFactory> factory,
	Listener* listener,
	const scoped_refptr<base::SingleThreadTaskRunner>& ipc_task_runner,
	bool create_pipe_now,
	base::WaitableEvent* shutdown_event) {
	std::unique_ptr<SyncChannel> channel =
	Create(listener, ipc_task_runner, shutdown_event);
	channel->Init(std::move(factory), create_pipe_now);
	return channel;
	}

	// static
	std::unique_ptr<SyncChannel> SyncChannel::Create(
	Listener* listener,
	const scoped_refptr<base::SingleThreadTaskRunner>& ipc_task_runner,
	WaitableEvent* shutdown_event) {
	return base::WrapUnique(
	new SyncChannel(listener, ipc_task_runner, shutdown_event));
	}

	SyncChannel::SyncChannel(
	Listener* listener,
	const scoped_refptr<base::SingleThreadTaskRunner>& ipc_task_runner,
	WaitableEvent* shutdown_event)
	: ChannelProxy(new SyncContext(listener, ipc_task_runner, shutdown_event)) {
	// The current (listener) thread must be distinct from the IPC thread, or else
	// sending synchronous messages will deadlock.
	DCHECK_NE(ipc_task_runner.get(), base::ThreadTaskRunnerHandle::Get().get());
	StartWatching();
	}

	SyncChannel::~SyncChannel() {
	}

	void SyncChannel::SetRestrictDispatchChannelGroup(int group) {
	sync_context()->set_restrict_dispatch_group(group);
	}

	scoped_refptr<SyncMessageFilter> SyncChannel::CreateSyncMessageFilter() {
	scoped_refptr<SyncMessageFilter> filter = new SyncMessageFilter(
	sync_context()->shutdown_event(),
	sync_context()->IsChannelSendThreadSafe());
	AddFilter(filter.get());
	if (!did_init())
	pre_init_sync_message_filters_.push_back(filter);
	return filter;
	}

	bool SyncChannel::Send(Message* message) {
	#ifdef IPC_MESSAGE_LOG_ENABLED
	std::string name;
	Logging::GetInstance()->GetMessageText(message->type(), &name, message, NULL);
	TRACE_EVENT1("ipc", "SyncChannel::Send", "name", name);
	#else
	TRACE_EVENT2("ipc", "SyncChannel::Send",
	"class", IPC_MESSAGE_ID_CLASS(message->type()),
	"line", IPC_MESSAGE_ID_LINE(message->type()));
	#endif
	if (!message->is_sync()) {
	ChannelProxy::Send(message);
	return true;
	}

	// this might get deleted in WaitForReply.
	scoped_refptr<SyncContext> context(sync_context());
	if (context->shutdown_event()->IsSignaled()) {
	DVLOG(1) << "shutdown event is signaled";
	delete message;
	return false;
	}

	SyncMessage* sync_msg = static_cast<SyncMessage*>(message);
	context->Push(sync_msg);
	WaitableEvent* pump_messages_event = sync_msg->pump_messages_event();

	ChannelProxy::Send(message);

	// Wait for reply, or for any other incoming synchronous messages.
	// this might get deleted, so only call static functions at this point.
	WaitForReply(context.get(), pump_messages_event);

	TRACE_EVENT_FLOW_END0(TRACE_DISABLED_BY_DEFAULT("ipc.flow"),
	"SyncChannel::Send", context->GetSendDoneEvent());

	return context->Pop();
	}

	void SyncChannel::WaitForReply(
	SyncContext* context, WaitableEvent* pump_messages_event) {
	context->DispatchMessages();
	while (true) {
	WaitableEvent* objects[] = {
	context->GetDispatchEvent(),
	context->GetSendDoneEvent(),
	pump_messages_event
	};

	unsigned count = pump_messages_event ? 3: 2;
	size_t result = WaitableEvent::WaitMany(objects, count);
	if (result == 0 /* dispatch event */) {
	// We're waiting for a reply, but we received a blocking synchronous
	// call. We must process it or otherwise a deadlock might occur.
	context->GetDispatchEvent()->Reset();
	context->DispatchMessages();
	continue;
	}

	if (result == 2 /* pump_messages_event */)
	WaitForReplyWithNestedMessageLoop(context); // Run a nested message loop.

	break;
	}
	}

	void SyncChannel::WaitForReplyWithNestedMessageLoop(SyncContext* context) {
	base::WaitableEventWatcher send_done_watcher;

	ReceivedSyncMsgQueue* sync_msg_queue = context->received_sync_msgs();
	DCHECK(sync_msg_queue != NULL);

	base::WaitableEventWatcher* old_send_done_event_watcher =
	sync_msg_queue->top_send_done_watcher();

	base::WaitableEventWatcher::EventCallback old_callback;
	base::WaitableEvent* old_event = NULL;

	// Maintain a local global stack of send done delegates to ensure that
	// nested sync calls complete in the correct sequence, i.e. the
	// outermost call completes first, etc.
	if (old_send_done_event_watcher) {
	old_callback = old_send_done_event_watcher->callback();
	old_event = old_send_done_event_watcher->GetWatchedEvent();
	old_send_done_event_watcher->StopWatching();
	}

	sync_msg_queue->set_top_send_done_watcher(&send_done_watcher);

	send_done_watcher.StartWatching(context->GetSendDoneEvent(),
	context->MakeWaitableEventCallback());

	{
	base::MessageLoop::ScopedNestableTaskAllower allow(
	base::MessageLoop::current());
	base::MessageLoop::current()->Run();
	}

	sync_msg_queue->set_top_send_done_watcher(old_send_done_event_watcher);
	if (old_send_done_event_watcher && old_event) {
	old_send_done_event_watcher->StartWatching(old_event, old_callback);
	}
	}

	void SyncChannel::OnWaitableEventSignaled(WaitableEvent* event) {
	DCHECK(event == sync_context()->GetDispatchEvent());
	// The call to DispatchMessages might delete this object, so reregister
	// the object watcher first.
	event->Reset();
	dispatch_watcher_.StartWatching(event, dispatch_watcher_callback_);
	sync_context()->DispatchMessages();
	}

	void SyncChannel::StartWatching() {
	// Ideally we only want to watch this object when running a nested message
	// loop. However, we don't know when it exits if there's another nested
	// message loop running under it or not, so we wouldn't know whether to
	// stop or keep watching. So we always watch it, and create the event as
	// manual reset since the object watcher might otherwise reset the event
	// when we're doing a WaitMany.
	dispatch_watcher_callback_ =
	base::Bind(&SyncChannel::OnWaitableEventSignaled,
	base::Unretained(this));
	dispatch_watcher_.StartWatching(sync_context()->GetDispatchEvent(),
	dispatch_watcher_callback_);
	}

	void SyncChannel::OnChannelInit() {
	for (const auto& filter : pre_init_sync_message_filters_) {
	filter->set_is_channel_send_thread_safe(
	context()->IsChannelSendThreadSafe());
	}
	pre_init_sync_message_filters_.clear();
	}

	bool SyncChannel::SendNow(std::unique_ptr<Message> message) {
	#ifdef IPC_MESSAGE_LOG_ENABLED
	std::string name;
	Logging::GetInstance()->GetMessageText(
	message->type(), &name, message.get(), nullptr);
	TRACE_EVENT1("ipc", "SyncChannel::SendNow", "name", name);
	#else
	TRACE_EVENT2("ipc", "SyncChannel::SendNow",
	"class", IPC_MESSAGE_ID_CLASS(message->type()),
	"line", IPC_MESSAGE_ID_LINE(message->type()));
	#endif
	if (!message->is_sync())
	return ChannelProxy::SendNow(std::move(message));
	return Send(message.release());
	}

	bool SyncChannel::SendOnIPCThread(std::unique_ptr<Message> message) {
	#ifdef IPC_MESSAGE_LOG_ENABLED
	std::string name;
	Logging::GetInstance()->GetMessageText(
	message->type(), &name, message.get(), nullptr);
	TRACE_EVENT1("ipc", "SyncChannel::SendOnIPCThread", "name", name);
	#else
	TRACE_EVENT2("ipc", "SyncChannel::SendOnIPCThread",
	"class", IPC_MESSAGE_ID_CLASS(message->type()),
	"line", IPC_MESSAGE_ID_LINE(message->type()));
	#endif
	if (!message->is_sync())
	return ChannelProxy::SendOnIPCThread(std::move(message));
	return Send(message.release());
	}

	} // namespace IPC