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

 // Copyright 2014 The Chromium Authors
 // Use of this source code is governed by a BSD-style license that can be
 // found in the LICENSE file.

 #ifndef IPC_IPC_MOJO_BOOTSTRAP_H_
 #define IPC_IPC_MOJO_BOOTSTRAP_H_

 #include <stdint.h>

 #include <memory>

 #include "base/auto_reset.h"
 #include "base/component_export.h"
 #include "base/memory/ref_counted.h"
 #include "base/task/single_thread_task_runner.h"
 #include "build/build_config.h"
 #include "ipc/ipc.mojom.h"
 #include "ipc/ipc_channel.h"
 #include "ipc/ipc_listener.h"
 #include "mojo/public/cpp/bindings/associated_group.h"
 #include "mojo/public/cpp/bindings/associated_remote.h"
 #include "mojo/public/cpp/bindings/pending_associated_receiver.h"
 #include "mojo/public/cpp/system/message_pipe.h"

 namespace IPC {

 class UrgentMessageObserver;

 // Incoming legacy IPCs have always been dispatched to one of two threads: the
 // IO thread (when an installed MessageFilter handles the message), or the
 // thread which owns the corresponding ChannelProxy receiving the message. There
 // were no other places to route legacy IPC messages, so when a message arrived
 // the legacy IPC system would run through its MessageFilters and if the message
 // was still unhandled, it would be posted to the ChannelProxy thread for
 // further processing.
 //
 // Mojo on the other hand allows for mutually associated endpoints (that is,
 // endpoints which locally share the same message pipe) to span any number of
 // threads while still guaranteeing that each endpoint on a given thread
 // preserves FIFO order of messages dispatched there. This means that if a
 // message arrives carrying a PendingAssociatedRemote/Receiver endpoint, and
 // then another message arrives which targets that endpoint, the entire pipe
 // will be blocked from dispatch until the endpoint is bound: otherwise we have
 // no idea where to dispatch the message such that we can uphold the FIFO
 // guarantee between the new endpoint and any other endpoints on the thread it
 // ends up binding to.
 //
 // Channel-associated interfaces share a message pipe with the legacy IPC
 // Channel, and in order to avoid nasty surprises during the migration process
 // we decided to constrain how incoming Channel-associated endpoints could be
 // bound: you must either bind them immediately as they arrive on the IO thread,
 // or you must immediately post a task to the ChannelProxy thread to bind them.
 // This allows all aforementioned FIFO guaratees to be upheld without ever
 // stalling dispatch of legacy IPCs (particularly on the IO thread), because
 // when we see a message targeting an unbound endpoint we can safely post it to
 // the ChannelProxy's task runner before forging ahead to dispatch subsequent
 // messages. No stalling.
 //
 // As there are some cases where a Channel-associated endpoint really wants to
 // receive messages on a different TaskRunner, we want to allow that now. It's
 // safe as long as the application can guarantee that the endpoint in question
 // will be bound to a task runner *before* any messages are received for that
 // endpoint.
 //
 // HOWEVER, it turns out that we cannot simply adhere to the application's
 // wishes when an alternative TaskRunner is provided at binding time: over time
 // we have accumulated application code which binds Channel-associated endpoints
 // to task runners which -- while running tasks exclusively on the ChannelProxy
 // thread -- are not the ChannelProxy's own task runner. Such code now
 // implicitly relies on the behavior of Channel-associated interfaces always
 // dispatching their messages to the ChannelProxy task runner. This is tracked
 // by https://crbug.com/1209188.
 //
 // Finally, the point: if you really know you want to bind your endpoint to an
 // alternative task runner and you can really guarantee that no messages may
 // have already arrived for it on the IO thread, you can do the binding within
 // the extent of a ScopedAllowOffSequenceChannelAssociatedBindings. This will
 // flag the endpoint such that it honors your binding configuration, and its
 // incoming messages will actually dispatch to the task runner you provide.
 class COMPONENT_EXPORT(IPC)
     [[maybe_unused,
       nodiscard]] ScopedAllowOffSequenceChannelAssociatedBindings {
  public:
   ScopedAllowOffSequenceChannelAssociatedBindings();
   ~ScopedAllowOffSequenceChannelAssociatedBindings();

  private:
   const base::AutoReset<bool> resetter_;
 };

 // MojoBootstrap establishes a pair of associated interfaces between two
 // processes in Chrome.
 //
 // Clients should implement MojoBootstrap::Delegate to get the associated pipes
 // from MojoBootstrap object.
 //
 // This lives on IO thread other than Create(), which can be called from
 // UI thread as Channel::Create() can be.
 class COMPONENT_EXPORT(IPC) MojoBootstrap {
  public:
   virtual ~MojoBootstrap() {}

   // Create the MojoBootstrap instance, using |handle| as the message pipe, in
   // mode as specified by |mode|. The result is passed to |delegate|.
   static std::unique_ptr<MojoBootstrap> Create(
       mojo::ScopedMessagePipeHandle handle,
       Channel::Mode mode,
       const scoped_refptr<base::SingleThreadTaskRunner>& ipc_task_runner,
       const scoped_refptr<base::SingleThreadTaskRunner>& proxy_task_runner);

   // Initialize the Channel pipe and interface endpoints. This performs all
   // setup except actually starting to read messages off the pipe.
   virtual void Connect(
       mojo::PendingAssociatedRemote<mojom::Channel>* sender,
       mojo::PendingAssociatedReceiver<mojom::Channel>* receiver) = 0;

   // Enable incoming messages to start being read off the pipe and routed to
   // endpoints. Must not be called until the pending endpoints created by
   // Connect() are actually bound somewhere.
   virtual void StartReceiving() = 0;

   // Stop transmitting messages and start queueing them instead.
   virtual void Pause() = 0;

   // Stop queuing new messages and start transmitting them instead.
   virtual void Unpause() = 0;

   // Flush outgoing messages which were queued before Start().
   virtual void Flush() = 0;

   virtual mojo::AssociatedGroup* GetAssociatedGroup() = 0;

   virtual void SetUrgentMessageObserver(UrgentMessageObserver* observer) = 0;
 };

 }  // namespace IPC

 #endif  // IPC_IPC_MOJO_BOOTSTRAP_H_
	// Copyright 2014 The Chromium Authors
	// Use of this source code is governed by a BSD-style license that can be
	// found in the LICENSE file.

	#ifndef IPC_IPC_MOJO_BOOTSTRAP_H_
	#define IPC_IPC_MOJO_BOOTSTRAP_H_

	#include <stdint.h>

	#include <memory>

	#include "base/auto_reset.h"
	#include "base/component_export.h"
	#include "base/memory/ref_counted.h"
	#include "base/task/single_thread_task_runner.h"
	#include "build/build_config.h"
	#include "ipc/ipc.mojom.h"
	#include "ipc/ipc_channel.h"
	#include "ipc/ipc_listener.h"
	#include "mojo/public/cpp/bindings/associated_group.h"
	#include "mojo/public/cpp/bindings/associated_remote.h"
	#include "mojo/public/cpp/bindings/pending_associated_receiver.h"
	#include "mojo/public/cpp/system/message_pipe.h"

	namespace IPC {

	class UrgentMessageObserver;

	// Incoming legacy IPCs have always been dispatched to one of two threads: the
	// IO thread (when an installed MessageFilter handles the message), or the
	// thread which owns the corresponding ChannelProxy receiving the message. There
	// were no other places to route legacy IPC messages, so when a message arrived
	// the legacy IPC system would run through its MessageFilters and if the message
	// was still unhandled, it would be posted to the ChannelProxy thread for
	// further processing.
	//
	// Mojo on the other hand allows for mutually associated endpoints (that is,
	// endpoints which locally share the same message pipe) to span any number of
	// threads while still guaranteeing that each endpoint on a given thread
	// preserves FIFO order of messages dispatched there. This means that if a
	// message arrives carrying a PendingAssociatedRemote/Receiver endpoint, and
	// then another message arrives which targets that endpoint, the entire pipe
	// will be blocked from dispatch until the endpoint is bound: otherwise we have
	// no idea where to dispatch the message such that we can uphold the FIFO
	// guarantee between the new endpoint and any other endpoints on the thread it
	// ends up binding to.
	//
	// Channel-associated interfaces share a message pipe with the legacy IPC
	// Channel, and in order to avoid nasty surprises during the migration process
	// we decided to constrain how incoming Channel-associated endpoints could be
	// bound: you must either bind them immediately as they arrive on the IO thread,
	// or you must immediately post a task to the ChannelProxy thread to bind them.
	// This allows all aforementioned FIFO guaratees to be upheld without ever
	// stalling dispatch of legacy IPCs (particularly on the IO thread), because
	// when we see a message targeting an unbound endpoint we can safely post it to
	// the ChannelProxy's task runner before forging ahead to dispatch subsequent
	// messages. No stalling.
	//
	// As there are some cases where a Channel-associated endpoint really wants to
	// receive messages on a different TaskRunner, we want to allow that now. It's
	// safe as long as the application can guarantee that the endpoint in question
	// will be bound to a task runner before any messages are received for that
	// endpoint.
	//
	// HOWEVER, it turns out that we cannot simply adhere to the application's
	// wishes when an alternative TaskRunner is provided at binding time: over time
	// we have accumulated application code which binds Channel-associated endpoints
	// to task runners which -- while running tasks exclusively on the ChannelProxy
	// thread -- are not the ChannelProxy's own task runner. Such code now
	// implicitly relies on the behavior of Channel-associated interfaces always
	// dispatching their messages to the ChannelProxy task runner. This is tracked
	// by https://crbug.com/1209188.
	//
	// Finally, the point: if you really know you want to bind your endpoint to an
	// alternative task runner and you can really guarantee that no messages may
	// have already arrived for it on the IO thread, you can do the binding within
	// the extent of a ScopedAllowOffSequenceChannelAssociatedBindings. This will
	// flag the endpoint such that it honors your binding configuration, and its
	// incoming messages will actually dispatch to the task runner you provide.
	class COMPONENT_EXPORT(IPC)
	[[maybe_unused,
	nodiscard]] ScopedAllowOffSequenceChannelAssociatedBindings {
	public:
	ScopedAllowOffSequenceChannelAssociatedBindings();
	~ScopedAllowOffSequenceChannelAssociatedBindings();

	private:
	const base::AutoReset<bool> resetter_;
	};

	// MojoBootstrap establishes a pair of associated interfaces between two
	// processes in Chrome.
	//
	// Clients should implement MojoBootstrap::Delegate to get the associated pipes
	// from MojoBootstrap object.
	//
	// This lives on IO thread other than Create(), which can be called from
	// UI thread as Channel::Create() can be.
	class COMPONENT_EXPORT(IPC) MojoBootstrap {
	public:
	virtual ~MojoBootstrap() {}

	// Create the MojoBootstrap instance, using \|handle\| as the message pipe, in
	// mode as specified by \|mode\|. The result is passed to \|delegate\|.
	static std::unique_ptr<MojoBootstrap> Create(
	mojo::ScopedMessagePipeHandle handle,
	Channel::Mode mode,
	const scoped_refptr<base::SingleThreadTaskRunner>& ipc_task_runner,
	const scoped_refptr<base::SingleThreadTaskRunner>& proxy_task_runner);

	// Initialize the Channel pipe and interface endpoints. This performs all
	// setup except actually starting to read messages off the pipe.
	virtual void Connect(
	mojo::PendingAssociatedRemote<mojom::Channel>* sender,
	mojo::PendingAssociatedReceiver<mojom::Channel>* receiver) = 0;

	// Enable incoming messages to start being read off the pipe and routed to
	// endpoints. Must not be called until the pending endpoints created by
	// Connect() are actually bound somewhere.
	virtual void StartReceiving() = 0;

	// Stop transmitting messages and start queueing them instead.
	virtual void Pause() = 0;

	// Stop queuing new messages and start transmitting them instead.
	virtual void Unpause() = 0;

	// Flush outgoing messages which were queued before Start().
	virtual void Flush() = 0;

	virtual mojo::AssociatedGroup* GetAssociatedGroup() = 0;

	virtual void SetUrgentMessageObserver(UrgentMessageObserver* observer) = 0;
	};

	} // namespace IPC

	#endif // IPC_IPC_MOJO_BOOTSTRAP_H_