mojo/core/ports/port.h - chromium/src - Git at Google

 // Copyright 2016 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 MOJO_CORE_PORTS_PORT_H_
 #define MOJO_CORE_PORTS_PORT_H_

 #include <memory>
 #include <queue>
 #include <utility>
 #include <vector>

 #include "base/macros.h"
 #include "base/memory/ref_counted.h"
 #include "base/synchronization/lock.h"
 #include "mojo/core/ports/event.h"
 #include "mojo/core/ports/message_queue.h"
 #include "mojo/core/ports/user_data.h"

 namespace mojo {
 namespace core {
 namespace ports {

 class PortLocker;

 // A Port is essentially a node in a circular list of addresses. For the sake of
 // this documentation such a list will henceforth be referred to as a "route."
 // Routes are the fundamental medium upon which all Node event circulation takes
 // place and are thus the backbone of all Mojo message passing.
 //
 // Each Port is identified by a 128-bit address within a Node (see node.h). A
 // Port doesn't really *do* anything per se: it's a named collection of state,
 // and its owning Node manages all event production, transmission, routing, and
 // processing logic. See Node for more details on how Ports may be used to
 // transmit arbitrary user messages as well as other Ports.
 //
 // Ports may be in any of a handful of states (see State below) which dictate
 // how they react to system events targeting them. In the simplest and most
 // common case, Ports are initially created as an entangled pair (i.e. a simple
 // cycle consisting of two Ports) both in the |kReceiving| State. Consider Ports
 // we'll label |A| and |B| here, which may be created using
 // Node::CreatePortPair():
 //
 //     +-----+          +-----+
 //     |     |--------->|     |
 //     |  A  |          |  B  |
 //     |     |<---------|     |
 //     +-----+          +-----+
 //
 // |A| references |B| via |peer_node_name| and |peer_port_name|, while |B| in
 // turn references |A|. Note that a Node is NEVER aware of who is sending events
 // to a given Port; it is only aware of where it must route events FROM a given
 // Port.
 //
 // For the sake of documentation, we refer to one receiving port in a route as
 // the "conjugate" of the other. A receiving port's conjugate is also its peer
 // upon initial creation, but because of proxying this may not be the case at a
 // later time.
 //
 // ALL access to this data structure must be guarded by |lock_| acquisition,
 // which is only possible using a PortLocker. PortLocker ensures that
 // overlapping Port lock acquisitions on a single thread are always acquired in
 // a globally consistent order.
 class Port : public base::RefCountedThreadSafe<Port> {
  public:
   // The state of a given Port. A Port may only exist in one of these states at
   // any given time.
   enum State {
     // The Port is not yet paired with a peer and is therefore unusable. See
     // Node::CreateUninitializedPort and Node::InitializePort for motivation.
     kUninitialized,

     // The Port is publicly visible outside of its Node and may be used to send
     // and receive user messages. There are always AT MOST two |kReceiving|
     // Ports along any given route. A user message event sent from a receiving
     // port is always circulated along the Port's route until it reaches either
     // a dead-end -- in which case the route is broken -- or it reaches the
     // other receiving Port in the route -- in which case it lands in that
     // Port's incoming message queue which can by read by user code.
     kReceiving,

     // The Port has been taken out of the |kReceiving| state in preparation for
     // proxying to a new destination. A Port enters this state immediately when
     // it's attached to a user message and may only leave this state when
     // transitioning to |kProxying|. See Node for more details.
     kBuffering,

     // The Port is forwarding all user messages (and most other events) to its
     // peer without discretion. Ports in the |kProxying| state may never leave
     // this state and only exist temporarily until their owning Node has
     // established that no more events will target them. See Node for more
     // details.
     kProxying,

     // The Port has been closed and is now permanently unusable. Only
     // |kReceiving| ports can be closed.
     kClosed
   };

   // The current State of the Port.
   State state;

   // The Node and Port address to which events should be routed FROM this Port.
   // Note that this is NOT necessarily the address of the Port currently sending
   // events TO this Port.
   NodeName peer_node_name;
   PortName peer_port_name;

   // The next available sequence number to use for outgoing user message events
   // originating from this port.
   uint64_t next_sequence_num_to_send;

   // The sequence number of the last message this Port should ever expect to
   // receive in its lifetime. May be used to determine that a proxying port is
   // ready to be destroyed or that a receiving port's conjugate has been closed
   // and we know the sequence number of the last message it sent.
   uint64_t last_sequence_num_to_receive;

   // The queue of incoming user messages received by this Port. Only non-empty
   // for buffering or receiving Ports. When a buffering port enters the proxying
   // state, it flushes its queue and the proxy then bypasses the queue
   // indefinitely.
   //
   // A receiving port's queue only has elements removed by user code reading
   // messages from the port.
   //
   // Note that this is a priority queue which only exposes messages to consumers
   // in strict sequential order.
   MessageQueue message_queue;

   // In some edge cases, a Node may need to remember to route a single special
   // event upon destruction of this (proxying) Port. That event is stashed here
   // in the interim.
   std::unique_ptr<std::pair<NodeName, ScopedEvent>> send_on_proxy_removal;

   // Arbitrary user data attached to the Port. In practice, Mojo uses this to
   // stash an observer interface which can be notified about various Port state
   // changes.
   scoped_refptr<UserData> user_data;

   // Indicates that this (proxying) Port has received acknowledgement that no
   // new user messages will be routed to it. If |true|, the proxy will be
   // removed once it has received and forwarded all sequenced messages up to and
   // including the one numbered |last_sequence_num_to_receive|.
   bool remove_proxy_on_last_message;

   // Indicates that this Port is aware that its nearest (in terms of forward,
   // non-zero cyclic routing distance) receiving Port has been closed.
   bool peer_closed;

   Port(uint64_t next_sequence_num_to_send,
        uint64_t next_sequence_num_to_receive);

   void AssertLockAcquired() {
 #if DCHECK_IS_ON()
     lock_.AssertAcquired();
 #endif
   }

  private:
   friend class base::RefCountedThreadSafe<Port>;
   friend class PortLocker;

   ~Port();

   base::Lock lock_;

   DISALLOW_COPY_AND_ASSIGN(Port);
 };

 }  // namespace ports
 }  // namespace core
 }  // namespace mojo

 #endif  // MOJO_CORE_PORTS_PORT_H_
	// Copyright 2016 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 MOJO_CORE_PORTS_PORT_H_
	#define MOJO_CORE_PORTS_PORT_H_

	#include <memory>
	#include <queue>
	#include <utility>
	#include <vector>

	#include "base/macros.h"
	#include "base/memory/ref_counted.h"
	#include "base/synchronization/lock.h"
	#include "mojo/core/ports/event.h"
	#include "mojo/core/ports/message_queue.h"
	#include "mojo/core/ports/user_data.h"

	namespace mojo {
	namespace core {
	namespace ports {

	class PortLocker;

	// A Port is essentially a node in a circular list of addresses. For the sake of
	// this documentation such a list will henceforth be referred to as a "route."
	// Routes are the fundamental medium upon which all Node event circulation takes
	// place and are thus the backbone of all Mojo message passing.
	//
	// Each Port is identified by a 128-bit address within a Node (see node.h). A
	// Port doesn't really do anything per se: it's a named collection of state,
	// and its owning Node manages all event production, transmission, routing, and
	// processing logic. See Node for more details on how Ports may be used to
	// transmit arbitrary user messages as well as other Ports.
	//
	// Ports may be in any of a handful of states (see State below) which dictate
	// how they react to system events targeting them. In the simplest and most
	// common case, Ports are initially created as an entangled pair (i.e. a simple
	// cycle consisting of two Ports) both in the \|kReceiving\| State. Consider Ports
	// we'll label \|A\| and \|B\| here, which may be created using
	// Node::CreatePortPair():
	//
	// +-----+ +-----+
	// \| \|--------->\| \|
	// \| A \| \| B \|
	// \| \|<---------\| \|
	// +-----+ +-----+
	//
	// \|A\| references \|B\| via \|peer_node_name\| and \|peer_port_name\|, while \|B\| in
	// turn references \|A\|. Note that a Node is NEVER aware of who is sending events
	// to a given Port; it is only aware of where it must route events FROM a given
	// Port.
	//
	// For the sake of documentation, we refer to one receiving port in a route as
	// the "conjugate" of the other. A receiving port's conjugate is also its peer
	// upon initial creation, but because of proxying this may not be the case at a
	// later time.
	//
	// ALL access to this data structure must be guarded by \|lock_\| acquisition,
	// which is only possible using a PortLocker. PortLocker ensures that
	// overlapping Port lock acquisitions on a single thread are always acquired in
	// a globally consistent order.
	class Port : public base::RefCountedThreadSafe<Port> {
	public:
	// The state of a given Port. A Port may only exist in one of these states at
	// any given time.
	enum State {
	// The Port is not yet paired with a peer and is therefore unusable. See
	// Node::CreateUninitializedPort and Node::InitializePort for motivation.
	kUninitialized,

	// The Port is publicly visible outside of its Node and may be used to send
	// and receive user messages. There are always AT MOST two \|kReceiving\|
	// Ports along any given route. A user message event sent from a receiving
	// port is always circulated along the Port's route until it reaches either
	// a dead-end -- in which case the route is broken -- or it reaches the
	// other receiving Port in the route -- in which case it lands in that
	// Port's incoming message queue which can by read by user code.
	kReceiving,

	// The Port has been taken out of the \|kReceiving\| state in preparation for
	// proxying to a new destination. A Port enters this state immediately when
	// it's attached to a user message and may only leave this state when
	// transitioning to \|kProxying\|. See Node for more details.
	kBuffering,

	// The Port is forwarding all user messages (and most other events) to its
	// peer without discretion. Ports in the \|kProxying\| state may never leave
	// this state and only exist temporarily until their owning Node has
	// established that no more events will target them. See Node for more
	// details.
	kProxying,

	// The Port has been closed and is now permanently unusable. Only
	// \|kReceiving\| ports can be closed.
	kClosed
	};

	// The current State of the Port.
	State state;

	// The Node and Port address to which events should be routed FROM this Port.
	// Note that this is NOT necessarily the address of the Port currently sending
	// events TO this Port.
	NodeName peer_node_name;
	PortName peer_port_name;

	// The next available sequence number to use for outgoing user message events
	// originating from this port.
	uint64_t next_sequence_num_to_send;

	// The sequence number of the last message this Port should ever expect to
	// receive in its lifetime. May be used to determine that a proxying port is
	// ready to be destroyed or that a receiving port's conjugate has been closed
	// and we know the sequence number of the last message it sent.
	uint64_t last_sequence_num_to_receive;

	// The queue of incoming user messages received by this Port. Only non-empty
	// for buffering or receiving Ports. When a buffering port enters the proxying
	// state, it flushes its queue and the proxy then bypasses the queue
	// indefinitely.
	//
	// A receiving port's queue only has elements removed by user code reading
	// messages from the port.
	//
	// Note that this is a priority queue which only exposes messages to consumers
	// in strict sequential order.
	MessageQueue message_queue;

	// In some edge cases, a Node may need to remember to route a single special
	// event upon destruction of this (proxying) Port. That event is stashed here
	// in the interim.
	std::unique_ptr<std::pair<NodeName, ScopedEvent>> send_on_proxy_removal;

	// Arbitrary user data attached to the Port. In practice, Mojo uses this to
	// stash an observer interface which can be notified about various Port state
	// changes.
	scoped_refptr<UserData> user_data;

	// Indicates that this (proxying) Port has received acknowledgement that no
	// new user messages will be routed to it. If \|true\|, the proxy will be
	// removed once it has received and forwarded all sequenced messages up to and
	// including the one numbered \|last_sequence_num_to_receive\|.
	bool remove_proxy_on_last_message;

	// Indicates that this Port is aware that its nearest (in terms of forward,
	// non-zero cyclic routing distance) receiving Port has been closed.
	bool peer_closed;

	Port(uint64_t next_sequence_num_to_send,
	uint64_t next_sequence_num_to_receive);

	void AssertLockAcquired() {
	#if DCHECK_IS_ON()
	lock_.AssertAcquired();
	#endif
	}

	private:
	friend class base::RefCountedThreadSafe<Port>;
	friend class PortLocker;

	~Port();

	base::Lock lock_;

	DISALLOW_COPY_AND_ASSIGN(Port);
	};

	} // namespace ports
	} // namespace core
	} // namespace mojo

	#endif // MOJO_CORE_PORTS_PORT_H_