ipc/ipc_sync_channel.h - chromium/src - Git at Google

 // 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.

 #ifndef IPC_IPC_SYNC_CHANNEL_H_
 #define IPC_IPC_SYNC_CHANNEL_H_

 #include <memory>
 #include <string>
 #include <vector>

 #include "base/component_export.h"
 #include "base/containers/circular_deque.h"
 #include "base/macros.h"
 #include "base/memory/ref_counted.h"
 #include "base/synchronization/lock.h"
 #include "base/synchronization/waitable_event_watcher.h"
 #include "ipc/ipc_channel_handle.h"
 #include "ipc/ipc_channel_proxy.h"
 #include "ipc/ipc_sync_message.h"
 #include "ipc/ipc_sync_message_filter.h"
 #include "mojo/public/c/system/types.h"
 #include "mojo/public/cpp/system/simple_watcher.h"

 namespace base {
 class RunLoop;
 class WaitableEvent;
 }  // namespace base

 namespace mojo {
 class SyncHandleRegistry;
 }

 namespace IPC {

 class SyncMessage;

 // This is similar to ChannelProxy, with the added feature of supporting sending
 // synchronous messages.
 //
 // Overview of how the sync channel works
 // --------------------------------------
 // When the sending thread sends a synchronous message, we create a bunch
 // of tracking info (created in Send, stored in the PendingSyncMsg
 // structure) associated with the message that we identify by the unique
 // "MessageId" on the SyncMessage. Among the things we save is the
 // "Deserializer" which is provided by the sync message. This object is in
 // charge of reading the parameters from the reply message and putting them in
 // the output variables provided by its caller.
 //
 // The info gets stashed in a queue since we could have a nested stack of sync
 // messages (each side could send sync messages in response to sync messages,
 // so it works like calling a function). The message is sent to the I/O thread
 // for dispatch and the original thread blocks waiting for the reply.
 //
 // SyncContext maintains the queue in a threadsafe way and listens for replies
 // on the I/O thread. When a reply comes in that matches one of the messages
 // it's looking for (using the unique message ID), it will execute the
 // deserializer stashed from before, and unblock the original thread.
 //
 //
 // Significant complexity results from the fact that messages are still coming
 // in while the original thread is blocked. Normal async messages are queued
 // and dispatched after the blocking call is complete. Sync messages must
 // be dispatched in a reentrant manner to avoid deadlock.
 //
 //
 // Note that care must be taken that the lifetime of the ipc_thread argument
 // is more than this object.  If the message loop goes away while this object
 // is running and it's used to send a message, then it will use the invalid
 // message loop pointer to proxy it to the ipc thread.
 class COMPONENT_EXPORT(IPC) SyncChannel : public ChannelProxy {
  public:
   enum RestrictDispatchGroup {
     kRestrictDispatchGroup_None = 0,
   };

   // Creates and initializes a sync channel. If create_pipe_now is specified,
   // the channel will be initialized synchronously.
   // The naming pattern follows IPC::Channel.
   static std::unique_ptr<SyncChannel> Create(
       const IPC::ChannelHandle& channel_handle,
       IPC::Channel::Mode mode,
       Listener* listener,
       const scoped_refptr<base::SingleThreadTaskRunner>& ipc_task_runner,
       const scoped_refptr<base::SingleThreadTaskRunner>& listener_task_runner,
       bool create_pipe_now,
       base::WaitableEvent* shutdown_event);

   // Creates an uninitialized sync channel. Call ChannelProxy::Init to
   // initialize the channel. This two-step setup allows message filters to be
   // added before any messages are sent or received.
   static std::unique_ptr<SyncChannel> Create(
       Listener* listener,
       const scoped_refptr<base::SingleThreadTaskRunner>& ipc_task_runner,
       const scoped_refptr<base::SingleThreadTaskRunner>& listener_task_runner,
       base::WaitableEvent* shutdown_event);

   void AddListenerTaskRunner(
       int32_t routing_id,
       scoped_refptr<base::SingleThreadTaskRunner> task_runner);

   void RemoveListenerTaskRunner(int32_t routing_id);

   ~SyncChannel() override;

   bool Send(Message* message) override;

   // Sets the dispatch group for this channel, to only allow re-entrant dispatch
   // of messages to other channels in the same group.
   //
   // Normally, any unblocking message coming from any channel can be dispatched
   // when any (possibly other) channel is blocked on sending a message. This is
   // needed in some cases to unblock certain loops (e.g. necessary when some
   // processes share a window hierarchy), but may cause re-entrancy issues in
   // some cases where such loops are not possible. This flags allows the tagging
   // of some particular channels to only re-enter in known correct cases.
   //
   // Incoming messages on channels belonging to a group that is not
   // kRestrictDispatchGroup_None will only be dispatched while a sync message is
   // being sent on a channel of the *same* group.
   // Incoming messages belonging to the kRestrictDispatchGroup_None group (the
   // default) will be dispatched in any case.
   void SetRestrictDispatchChannelGroup(int group);

   // Creates a new IPC::SyncMessageFilter and adds it to this SyncChannel.
   // This should be used instead of directly constructing a new
   // SyncMessageFilter.
   scoped_refptr<IPC::SyncMessageFilter> CreateSyncMessageFilter();

  protected:
   class ReceivedSyncMsgQueue;
   friend class ReceivedSyncMsgQueue;

   // SyncContext holds the per object data for SyncChannel, so that SyncChannel
   // can be deleted while it's being used in a different thread.  See
   // ChannelProxy::Context for more information.
   class SyncContext : public Context {
    public:
     SyncContext(
         Listener* listener,
         const scoped_refptr<base::SingleThreadTaskRunner>& ipc_task_runner,
         const scoped_refptr<base::SingleThreadTaskRunner>& listener_task_runner,
         base::WaitableEvent* shutdown_event);

     // Adds information about an outgoing sync message to the context so that
     // we know how to deserialize the reply.
     bool Push(SyncMessage* sync_msg);

     // Cleanly remove the top deserializer (and throw it away).  Returns the
     // result of the Send call for that message.
     bool Pop();

     // Returns a Mojo Event that signals when a sync send is complete or timed
     // out or the process shut down.
     base::WaitableEvent* GetSendDoneEvent();

     // Returns a Mojo Event that signals when an incoming message that's not the
     // pending reply needs to get dispatched (by calling DispatchMessages.)
     base::WaitableEvent* GetDispatchEvent();

     void DispatchMessages();

     // Checks if the given message is blocking the listener thread because of a
     // synchronous send.  If it is, the thread is unblocked and true is
     // returned. Otherwise the function returns false.
     bool TryToUnblockListener(const Message* msg);

     base::WaitableEvent* shutdown_event() { return shutdown_event_; }

     ReceivedSyncMsgQueue* received_sync_msgs() {
       return received_sync_msgs_.get();
     }

     void set_restrict_dispatch_group(int group) {
       restrict_dispatch_group_ = group;
     }

     int restrict_dispatch_group() const {
       return restrict_dispatch_group_;
     }

     void OnSendDoneEventSignaled(base::RunLoop* nested_loop,
                                  base::WaitableEvent* event);

    private:
     ~SyncContext() override;
     // ChannelProxy methods that we override.

     // Called on the listener thread.
     void Clear() override;

     // Called on the IPC thread.
     bool OnMessageReceived(const Message& msg) override;
     void OnChannelError() override;
     void OnChannelOpened() override;
     void OnChannelClosed() override;

     // Cancels all pending Send calls.
     void CancelPendingSends();

     void OnShutdownEventSignaled(base::WaitableEvent* event);

     using PendingSyncMessageQueue = base::circular_deque<PendingSyncMsg>;
     PendingSyncMessageQueue deserializers_;
     bool reject_new_deserializers_ = false;
     base::Lock deserializers_lock_;

     scoped_refptr<ReceivedSyncMsgQueue> received_sync_msgs_;

     base::WaitableEvent* shutdown_event_;
     base::WaitableEventWatcher shutdown_watcher_;
     base::WaitableEventWatcher::EventCallback shutdown_watcher_callback_;
     int restrict_dispatch_group_;
   };

  private:
   SyncChannel(
       Listener* listener,
       const scoped_refptr<base::SingleThreadTaskRunner>& ipc_task_runner,
       const scoped_refptr<base::SingleThreadTaskRunner>& listener_task_runner,
       base::WaitableEvent* shutdown_event);

   void OnDispatchEventSignaled(base::WaitableEvent* event);

   SyncContext* sync_context() {
     return reinterpret_cast<SyncContext*>(context());
   }

   // Both these functions wait for a reply, timeout or process shutdown.  The
   // latter one also runs a nested run loop in the meantime.
   static void WaitForReply(mojo::SyncHandleRegistry* registry,
                            SyncContext* context,
                            bool pump_messages);

   // Runs a nested run loop until a reply arrives, times out, or the process
   // shuts down.
   static void WaitForReplyWithNestedMessageLoop(SyncContext* context);

   // Starts the dispatch watcher.
   void StartWatching();

   // ChannelProxy overrides:
   void OnChannelInit() override;

   scoped_refptr<mojo::SyncHandleRegistry> sync_handle_registry_;

   // Used to signal events between the IPC and listener threads.
   base::WaitableEventWatcher dispatch_watcher_;
   base::WaitableEventWatcher::EventCallback dispatch_watcher_callback_;

   // Tracks SyncMessageFilters created before complete channel initialization.
   std::vector<scoped_refptr<SyncMessageFilter>> pre_init_sync_message_filters_;

   DISALLOW_COPY_AND_ASSIGN(SyncChannel);
 };

 }  // namespace IPC

 #endif  // IPC_IPC_SYNC_CHANNEL_H_
	// 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.

	#ifndef IPC_IPC_SYNC_CHANNEL_H_
	#define IPC_IPC_SYNC_CHANNEL_H_

	#include <memory>
	#include <string>
	#include <vector>

	#include "base/component_export.h"
	#include "base/containers/circular_deque.h"
	#include "base/macros.h"
	#include "base/memory/ref_counted.h"
	#include "base/synchronization/lock.h"
	#include "base/synchronization/waitable_event_watcher.h"
	#include "ipc/ipc_channel_handle.h"
	#include "ipc/ipc_channel_proxy.h"
	#include "ipc/ipc_sync_message.h"
	#include "ipc/ipc_sync_message_filter.h"
	#include "mojo/public/c/system/types.h"
	#include "mojo/public/cpp/system/simple_watcher.h"

	namespace base {
	class RunLoop;
	class WaitableEvent;
	} // namespace base

	namespace mojo {
	class SyncHandleRegistry;
	}

	namespace IPC {

	class SyncMessage;

	// This is similar to ChannelProxy, with the added feature of supporting sending
	// synchronous messages.
	//
	// Overview of how the sync channel works
	// --------------------------------------
	// When the sending thread sends a synchronous message, we create a bunch
	// of tracking info (created in Send, stored in the PendingSyncMsg
	// structure) associated with the message that we identify by the unique
	// "MessageId" on the SyncMessage. Among the things we save is the
	// "Deserializer" which is provided by the sync message. This object is in
	// charge of reading the parameters from the reply message and putting them in
	// the output variables provided by its caller.
	//
	// The info gets stashed in a queue since we could have a nested stack of sync
	// messages (each side could send sync messages in response to sync messages,
	// so it works like calling a function). The message is sent to the I/O thread
	// for dispatch and the original thread blocks waiting for the reply.
	//
	// SyncContext maintains the queue in a threadsafe way and listens for replies
	// on the I/O thread. When a reply comes in that matches one of the messages
	// it's looking for (using the unique message ID), it will execute the
	// deserializer stashed from before, and unblock the original thread.
	//
	//
	// Significant complexity results from the fact that messages are still coming
	// in while the original thread is blocked. Normal async messages are queued
	// and dispatched after the blocking call is complete. Sync messages must
	// be dispatched in a reentrant manner to avoid deadlock.
	//
	//
	// Note that care must be taken that the lifetime of the ipc_thread argument
	// is more than this object. If the message loop goes away while this object
	// is running and it's used to send a message, then it will use the invalid
	// message loop pointer to proxy it to the ipc thread.
	class COMPONENT_EXPORT(IPC) SyncChannel : public ChannelProxy {
	public:
	enum RestrictDispatchGroup {
	kRestrictDispatchGroup_None = 0,
	};

	// Creates and initializes a sync channel. If create_pipe_now is specified,
	// the channel will be initialized synchronously.
	// The naming pattern follows IPC::Channel.
	static std::unique_ptr<SyncChannel> Create(
	const IPC::ChannelHandle& channel_handle,
	IPC::Channel::Mode mode,
	Listener* listener,
	const scoped_refptr<base::SingleThreadTaskRunner>& ipc_task_runner,
	const scoped_refptr<base::SingleThreadTaskRunner>& listener_task_runner,
	bool create_pipe_now,
	base::WaitableEvent* shutdown_event);

	// Creates an uninitialized sync channel. Call ChannelProxy::Init to
	// initialize the channel. This two-step setup allows message filters to be
	// added before any messages are sent or received.
	static std::unique_ptr<SyncChannel> Create(
	Listener* listener,
	const scoped_refptr<base::SingleThreadTaskRunner>& ipc_task_runner,
	const scoped_refptr<base::SingleThreadTaskRunner>& listener_task_runner,
	base::WaitableEvent* shutdown_event);

	void AddListenerTaskRunner(
	int32_t routing_id,
	scoped_refptr<base::SingleThreadTaskRunner> task_runner);

	void RemoveListenerTaskRunner(int32_t routing_id);

	~SyncChannel() override;

	bool Send(Message* message) override;

	// Sets the dispatch group for this channel, to only allow re-entrant dispatch
	// of messages to other channels in the same group.
	//
	// Normally, any unblocking message coming from any channel can be dispatched
	// when any (possibly other) channel is blocked on sending a message. This is
	// needed in some cases to unblock certain loops (e.g. necessary when some
	// processes share a window hierarchy), but may cause re-entrancy issues in
	// some cases where such loops are not possible. This flags allows the tagging
	// of some particular channels to only re-enter in known correct cases.
	//
	// Incoming messages on channels belonging to a group that is not
	// kRestrictDispatchGroup_None will only be dispatched while a sync message is
	// being sent on a channel of the same group.
	// Incoming messages belonging to the kRestrictDispatchGroup_None group (the
	// default) will be dispatched in any case.
	void SetRestrictDispatchChannelGroup(int group);

	// Creates a new IPC::SyncMessageFilter and adds it to this SyncChannel.
	// This should be used instead of directly constructing a new
	// SyncMessageFilter.
	scoped_refptr<IPC::SyncMessageFilter> CreateSyncMessageFilter();

	protected:
	class ReceivedSyncMsgQueue;
	friend class ReceivedSyncMsgQueue;

	// SyncContext holds the per object data for SyncChannel, so that SyncChannel
	// can be deleted while it's being used in a different thread. See
	// ChannelProxy::Context for more information.
	class SyncContext : public Context {
	public:
	SyncContext(
	Listener* listener,
	const scoped_refptr<base::SingleThreadTaskRunner>& ipc_task_runner,
	const scoped_refptr<base::SingleThreadTaskRunner>& listener_task_runner,
	base::WaitableEvent* shutdown_event);

	// Adds information about an outgoing sync message to the context so that
	// we know how to deserialize the reply.
	bool Push(SyncMessage* sync_msg);

	// Cleanly remove the top deserializer (and throw it away). Returns the
	// result of the Send call for that message.
	bool Pop();

	// Returns a Mojo Event that signals when a sync send is complete or timed
	// out or the process shut down.
	base::WaitableEvent* GetSendDoneEvent();

	// Returns a Mojo Event that signals when an incoming message that's not the
	// pending reply needs to get dispatched (by calling DispatchMessages.)
	base::WaitableEvent* GetDispatchEvent();

	void DispatchMessages();

	// Checks if the given message is blocking the listener thread because of a
	// synchronous send. If it is, the thread is unblocked and true is
	// returned. Otherwise the function returns false.
	bool TryToUnblockListener(const Message* msg);

	base::WaitableEvent* shutdown_event() { return shutdown_event_; }

	ReceivedSyncMsgQueue* received_sync_msgs() {
	return received_sync_msgs_.get();
	}

	void set_restrict_dispatch_group(int group) {
	restrict_dispatch_group_ = group;
	}

	int restrict_dispatch_group() const {
	return restrict_dispatch_group_;
	}

	void OnSendDoneEventSignaled(base::RunLoop* nested_loop,
	base::WaitableEvent* event);

	private:
	~SyncContext() override;
	// ChannelProxy methods that we override.

	// Called on the listener thread.
	void Clear() override;

	// Called on the IPC thread.
	bool OnMessageReceived(const Message& msg) override;
	void OnChannelError() override;
	void OnChannelOpened() override;
	void OnChannelClosed() override;

	// Cancels all pending Send calls.
	void CancelPendingSends();

	void OnShutdownEventSignaled(base::WaitableEvent* event);

	using PendingSyncMessageQueue = base::circular_deque<PendingSyncMsg>;
	PendingSyncMessageQueue deserializers_;
	bool reject_new_deserializers_ = false;
	base::Lock deserializers_lock_;

	scoped_refptr<ReceivedSyncMsgQueue> received_sync_msgs_;

	base::WaitableEvent* shutdown_event_;
	base::WaitableEventWatcher shutdown_watcher_;
	base::WaitableEventWatcher::EventCallback shutdown_watcher_callback_;
	int restrict_dispatch_group_;
	};

	private:
	SyncChannel(
	Listener* listener,
	const scoped_refptr<base::SingleThreadTaskRunner>& ipc_task_runner,
	const scoped_refptr<base::SingleThreadTaskRunner>& listener_task_runner,
	base::WaitableEvent* shutdown_event);

	void OnDispatchEventSignaled(base::WaitableEvent* event);

	SyncContext* sync_context() {
	return reinterpret_cast<SyncContext*>(context());
	}

	// Both these functions wait for a reply, timeout or process shutdown. The
	// latter one also runs a nested run loop in the meantime.
	static void WaitForReply(mojo::SyncHandleRegistry* registry,
	SyncContext* context,
	bool pump_messages);

	// Runs a nested run loop until a reply arrives, times out, or the process
	// shuts down.
	static void WaitForReplyWithNestedMessageLoop(SyncContext* context);

	// Starts the dispatch watcher.
	void StartWatching();

	// ChannelProxy overrides:
	void OnChannelInit() override;

	scoped_refptr<mojo::SyncHandleRegistry> sync_handle_registry_;

	// Used to signal events between the IPC and listener threads.
	base::WaitableEventWatcher dispatch_watcher_;
	base::WaitableEventWatcher::EventCallback dispatch_watcher_callback_;

	// Tracks SyncMessageFilters created before complete channel initialization.
	std::vector<scoped_refptr<SyncMessageFilter>> pre_init_sync_message_filters_;

	DISALLOW_COPY_AND_ASSIGN(SyncChannel);
	};

	} // namespace IPC

	#endif // IPC_IPC_SYNC_CHANNEL_H_