mojo/core/ports/node.h - chromium/src.git - 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_NODE_H_
 #define MOJO_CORE_PORTS_NODE_H_

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

 #include <queue>
 #include <unordered_map>

 #include "base/component_export.h"
 #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/name.h"
 #include "mojo/core/ports/port.h"
 #include "mojo/core/ports/port_ref.h"
 #include "mojo/core/ports/user_data.h"

 namespace mojo {
 namespace core {
 namespace ports {

 enum : int {
   OK = 0,
   ERROR_PORT_UNKNOWN = -10,
   ERROR_PORT_EXISTS = -11,
   ERROR_PORT_STATE_UNEXPECTED = -12,
   ERROR_PORT_CANNOT_SEND_SELF = -13,
   ERROR_PORT_PEER_CLOSED = -14,
   ERROR_PORT_CANNOT_SEND_PEER = -15,
   ERROR_NOT_IMPLEMENTED = -100,
 };

 struct PortStatus {
   bool has_messages;
   bool receiving_messages;
   bool peer_closed;
   bool peer_remote;
   size_t queued_message_count;
   size_t queued_num_bytes;
 };

 class MessageFilter;
 class NodeDelegate;

 // A Node maintains a collection of Ports (see port.h) indexed by unique 128-bit
 // addresses (names), performing routing and processing of events among the
 // Ports within the Node and to or from other Nodes in the system. Typically
 // (and practically, in all uses today) there is a single Node per system
 // process. Thus a Node boundary effectively models a process boundary.
 //
 // New Ports can be created uninitialized using CreateUninitializedPort (and
 // later initialized using InitializePort), or created in a fully initialized
 // state using CreatePortPair(). Initialized ports have exactly one conjugate
 // port which is the ultimate receiver of any user messages sent by that port.
 // See SendUserMessage().
 //
 // In addition to routing user message events, various control events are used
 // by Nodes to coordinate Port behavior and lifetime within and across Nodes.
 // See Event documentation for description of different types of events used by
 // a Node to coordinate behavior.
 class COMPONENT_EXPORT(MOJO_CORE_PORTS) Node {
  public:
   enum class ShutdownPolicy {
     DONT_ALLOW_LOCAL_PORTS,
     ALLOW_LOCAL_PORTS,
   };

   // Does not take ownership of the delegate.
   Node(const NodeName& name, NodeDelegate* delegate);
   ~Node();

   // Returns true iff there are no open ports referring to another node or ports
   // in the process of being transferred from this node to another. If this
   // returns false, then to ensure clean shutdown, it is necessary to keep the
   // node alive and continue routing messages to it via AcceptMessage. This
   // method may be called again after AcceptMessage to check if the Node is now
   // ready to be destroyed.
   //
   // If |policy| is set to |ShutdownPolicy::ALLOW_LOCAL_PORTS|, this will return
   // |true| even if some ports remain alive, as long as none of them are proxies
   // to another node.
   bool CanShutdownCleanly(
       ShutdownPolicy policy = ShutdownPolicy::DONT_ALLOW_LOCAL_PORTS);

   // Lookup the named port.
   int GetPort(const PortName& port_name, PortRef* port_ref);

   // Creates a port on this node. Before the port can be used, it must be
   // initialized using InitializePort. This method is useful for bootstrapping
   // a connection between two nodes. Generally, ports are created using
   // CreatePortPair instead.
   int CreateUninitializedPort(PortRef* port_ref);

   // Initializes a newly created port.
   int InitializePort(const PortRef& port_ref,
                      const NodeName& peer_node_name,
                      const PortName& peer_port_name);

   // Generates a new connected pair of ports bound to this node. These ports
   // are initialized and ready to go.
   int CreatePortPair(PortRef* port0_ref, PortRef* port1_ref);

   // User data associated with the port.
   int SetUserData(const PortRef& port_ref, scoped_refptr<UserData> user_data);
   int GetUserData(const PortRef& port_ref, scoped_refptr<UserData>* user_data);

   // Prevents further messages from being sent from this port or delivered to
   // this port. The port is removed, and the port's peer is notified of the
   // closure after it has consumed all pending messages.
   int ClosePort(const PortRef& port_ref);

   // Returns the current status of the port.
   int GetStatus(const PortRef& port_ref, PortStatus* port_status);

   // Returns the next available message on the specified port or returns a null
   // message if there are none available. Returns ERROR_PORT_PEER_CLOSED to
   // indicate that this port's peer has closed. In such cases GetMessage may
   // be called until it yields a null message, indicating that no more messages
   // may be read from the port.
   //
   // If |filter| is non-null, the next available message is returned only if it
   // is matched by the filter. If the provided filter does not match the next
   // available message, GetMessage() behaves as if there is no message
   // available. Ownership of |filter| is not taken, and it must outlive the
   // extent of this call.
   int GetMessage(const PortRef& port_ref,
                  std::unique_ptr<UserMessageEvent>* message,
                  MessageFilter* filter);

   // Sends a message from the specified port to its peer. Note that the message
   // notification may arrive synchronously (via PortStatusChanged() on the
   // delegate) if the peer is local to this Node.
   int SendUserMessage(const PortRef& port_ref,
                       std::unique_ptr<UserMessageEvent> message);

   // Corresponding to NodeDelegate::ForwardEvent.
   int AcceptEvent(ScopedEvent event);

   // Called to merge two ports with each other. If you have two independent
   // port pairs A <=> B and C <=> D, the net result of merging B and C is a
   // single connected port pair A <=> D.
   //
   // Note that the behavior of this operation is undefined if either port to be
   // merged (B or C above) has ever been read from or written to directly, and
   // this must ONLY be called on one side of the merge, though it doesn't matter
   // which side.
   //
   // It is safe for the non-merged peers (A and D above) to be transferred,
   // closed, and/or written to before, during, or after the merge.
   int MergePorts(const PortRef& port_ref,
                  const NodeName& destination_node_name,
                  const PortName& destination_port_name);

   // Like above but merges two ports local to this node. Because both ports are
   // local this can also verify that neither port has been written to before the
   // merge. If this fails for any reason, both ports are closed. Otherwise OK
   // is returned and the ports' receiving peers are connected to each other.
   int MergeLocalPorts(const PortRef& port0_ref, const PortRef& port1_ref);

   // Called to inform this node that communication with another node is lost
   // indefinitely. This triggers cleanup of ports bound to this node.
   int LostConnectionToNode(const NodeName& node_name);

  private:
   // Helper to ensure that a Node always calls into its delegate safely, i.e.
   // without holding any internal locks.
   class DelegateHolder {
    public:
     DelegateHolder(Node* node, NodeDelegate* delegate);
     ~DelegateHolder();

     NodeDelegate* operator->() const {
       EnsureSafeDelegateAccess();
       return delegate_;
     }

    private:
 #if DCHECK_IS_ON()
     void EnsureSafeDelegateAccess() const;
 #else
     void EnsureSafeDelegateAccess() const {}
 #endif

     Node* const node_;
     NodeDelegate* const delegate_;

     DISALLOW_COPY_AND_ASSIGN(DelegateHolder);
   };

   int OnUserMessage(std::unique_ptr<UserMessageEvent> message);
   int OnPortAccepted(std::unique_ptr<PortAcceptedEvent> event);
   int OnObserveProxy(std::unique_ptr<ObserveProxyEvent> event);
   int OnObserveProxyAck(std::unique_ptr<ObserveProxyAckEvent> event);
   int OnObserveClosure(std::unique_ptr<ObserveClosureEvent> event);
   int OnMergePort(std::unique_ptr<MergePortEvent> event);

   int AddPortWithName(const PortName& port_name, scoped_refptr<Port> port);
   void ErasePort(const PortName& port_name);

   int SendUserMessageInternal(const PortRef& port_ref,
                               std::unique_ptr<UserMessageEvent>* message);
   int MergePortsInternal(const PortRef& port0_ref,
                          const PortRef& port1_ref,
                          bool allow_close_on_bad_state);
   void ConvertToProxy(Port* port,
                       const NodeName& to_node_name,
                       PortName* port_name,
                       Event::PortDescriptor* port_descriptor);
   int AcceptPort(const PortName& port_name,
                  const Event::PortDescriptor& port_descriptor);

   int PrepareToForwardUserMessage(const PortRef& forwarding_port_ref,
                                   Port::State expected_port_state,
                                   bool ignore_closed_peer,
                                   UserMessageEvent* message,
                                   NodeName* forward_to_node);
   int BeginProxying(const PortRef& port_ref);
   int ForwardUserMessagesFromProxy(const PortRef& port_ref);
   void InitiateProxyRemoval(const PortRef& port_ref);
   void TryRemoveProxy(const PortRef& port_ref);
   void DestroyAllPortsWithPeer(const NodeName& node_name,
                                const PortName& port_name);

   const NodeName name_;
   const DelegateHolder delegate_;

   // Guards |ports_|. This must never be acquired while an individual port's
   // lock is held on the same thread. Conversely, individual port locks may be
   // acquired while this one is held.
   //
   // Because UserMessage events may execute arbitrary user code during
   // destruction, it is also important to ensure that such events are never
   // destroyed while this (or any individual Port) lock is held.
   base::Lock ports_lock_;
   std::unordered_map<PortName, scoped_refptr<Port>> ports_;

   DISALLOW_COPY_AND_ASSIGN(Node);
 };

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

 #endif  // MOJO_CORE_PORTS_NODE_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_NODE_H_
	#define MOJO_CORE_PORTS_NODE_H_

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

	#include <queue>
	#include <unordered_map>

	#include "base/component_export.h"
	#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/name.h"
	#include "mojo/core/ports/port.h"
	#include "mojo/core/ports/port_ref.h"
	#include "mojo/core/ports/user_data.h"

	namespace mojo {
	namespace core {
	namespace ports {

	enum : int {
	OK = 0,
	ERROR_PORT_UNKNOWN = -10,
	ERROR_PORT_EXISTS = -11,
	ERROR_PORT_STATE_UNEXPECTED = -12,
	ERROR_PORT_CANNOT_SEND_SELF = -13,
	ERROR_PORT_PEER_CLOSED = -14,
	ERROR_PORT_CANNOT_SEND_PEER = -15,
	ERROR_NOT_IMPLEMENTED = -100,
	};

	struct PortStatus {
	bool has_messages;
	bool receiving_messages;
	bool peer_closed;
	bool peer_remote;
	size_t queued_message_count;
	size_t queued_num_bytes;
	};

	class MessageFilter;
	class NodeDelegate;

	// A Node maintains a collection of Ports (see port.h) indexed by unique 128-bit
	// addresses (names), performing routing and processing of events among the
	// Ports within the Node and to or from other Nodes in the system. Typically
	// (and practically, in all uses today) there is a single Node per system
	// process. Thus a Node boundary effectively models a process boundary.
	//
	// New Ports can be created uninitialized using CreateUninitializedPort (and
	// later initialized using InitializePort), or created in a fully initialized
	// state using CreatePortPair(). Initialized ports have exactly one conjugate
	// port which is the ultimate receiver of any user messages sent by that port.
	// See SendUserMessage().
	//
	// In addition to routing user message events, various control events are used
	// by Nodes to coordinate Port behavior and lifetime within and across Nodes.
	// See Event documentation for description of different types of events used by
	// a Node to coordinate behavior.
	class COMPONENT_EXPORT(MOJO_CORE_PORTS) Node {
	public:
	enum class ShutdownPolicy {
	DONT_ALLOW_LOCAL_PORTS,
	ALLOW_LOCAL_PORTS,
	};

	// Does not take ownership of the delegate.
	Node(const NodeName& name, NodeDelegate* delegate);
	~Node();

	// Returns true iff there are no open ports referring to another node or ports
	// in the process of being transferred from this node to another. If this
	// returns false, then to ensure clean shutdown, it is necessary to keep the
	// node alive and continue routing messages to it via AcceptMessage. This
	// method may be called again after AcceptMessage to check if the Node is now
	// ready to be destroyed.
	//
	// If \|policy\| is set to \|ShutdownPolicy::ALLOW_LOCAL_PORTS\|, this will return
	// \|true\| even if some ports remain alive, as long as none of them are proxies
	// to another node.
	bool CanShutdownCleanly(
	ShutdownPolicy policy = ShutdownPolicy::DONT_ALLOW_LOCAL_PORTS);

	// Lookup the named port.
	int GetPort(const PortName& port_name, PortRef* port_ref);

	// Creates a port on this node. Before the port can be used, it must be
	// initialized using InitializePort. This method is useful for bootstrapping
	// a connection between two nodes. Generally, ports are created using
	// CreatePortPair instead.
	int CreateUninitializedPort(PortRef* port_ref);

	// Initializes a newly created port.
	int InitializePort(const PortRef& port_ref,
	const NodeName& peer_node_name,
	const PortName& peer_port_name);

	// Generates a new connected pair of ports bound to this node. These ports
	// are initialized and ready to go.
	int CreatePortPair(PortRef* port0_ref, PortRef* port1_ref);

	// User data associated with the port.
	int SetUserData(const PortRef& port_ref, scoped_refptr<UserData> user_data);
	int GetUserData(const PortRef& port_ref, scoped_refptr<UserData>* user_data);

	// Prevents further messages from being sent from this port or delivered to
	// this port. The port is removed, and the port's peer is notified of the
	// closure after it has consumed all pending messages.
	int ClosePort(const PortRef& port_ref);

	// Returns the current status of the port.
	int GetStatus(const PortRef& port_ref, PortStatus* port_status);

	// Returns the next available message on the specified port or returns a null
	// message if there are none available. Returns ERROR_PORT_PEER_CLOSED to
	// indicate that this port's peer has closed. In such cases GetMessage may
	// be called until it yields a null message, indicating that no more messages
	// may be read from the port.
	//
	// If \|filter\| is non-null, the next available message is returned only if it
	// is matched by the filter. If the provided filter does not match the next
	// available message, GetMessage() behaves as if there is no message
	// available. Ownership of \|filter\| is not taken, and it must outlive the
	// extent of this call.
	int GetMessage(const PortRef& port_ref,
	std::unique_ptr<UserMessageEvent>* message,
	MessageFilter* filter);

	// Sends a message from the specified port to its peer. Note that the message
	// notification may arrive synchronously (via PortStatusChanged() on the
	// delegate) if the peer is local to this Node.
	int SendUserMessage(const PortRef& port_ref,
	std::unique_ptr<UserMessageEvent> message);

	// Corresponding to NodeDelegate::ForwardEvent.
	int AcceptEvent(ScopedEvent event);

	// Called to merge two ports with each other. If you have two independent
	// port pairs A <=> B and C <=> D, the net result of merging B and C is a
	// single connected port pair A <=> D.
	//
	// Note that the behavior of this operation is undefined if either port to be
	// merged (B or C above) has ever been read from or written to directly, and
	// this must ONLY be called on one side of the merge, though it doesn't matter
	// which side.
	//
	// It is safe for the non-merged peers (A and D above) to be transferred,
	// closed, and/or written to before, during, or after the merge.
	int MergePorts(const PortRef& port_ref,
	const NodeName& destination_node_name,
	const PortName& destination_port_name);

	// Like above but merges two ports local to this node. Because both ports are
	// local this can also verify that neither port has been written to before the
	// merge. If this fails for any reason, both ports are closed. Otherwise OK
	// is returned and the ports' receiving peers are connected to each other.
	int MergeLocalPorts(const PortRef& port0_ref, const PortRef& port1_ref);

	// Called to inform this node that communication with another node is lost
	// indefinitely. This triggers cleanup of ports bound to this node.
	int LostConnectionToNode(const NodeName& node_name);

	private:
	// Helper to ensure that a Node always calls into its delegate safely, i.e.
	// without holding any internal locks.
	class DelegateHolder {
	public:
	DelegateHolder(Node* node, NodeDelegate* delegate);
	~DelegateHolder();

	NodeDelegate* operator->() const {
	EnsureSafeDelegateAccess();
	return delegate_;
	}

	private:
	#if DCHECK_IS_ON()
	void EnsureSafeDelegateAccess() const;
	#else
	void EnsureSafeDelegateAccess() const {}
	#endif

	Node* const node_;
	NodeDelegate* const delegate_;

	DISALLOW_COPY_AND_ASSIGN(DelegateHolder);
	};

	int OnUserMessage(std::unique_ptr<UserMessageEvent> message);
	int OnPortAccepted(std::unique_ptr<PortAcceptedEvent> event);
	int OnObserveProxy(std::unique_ptr<ObserveProxyEvent> event);
	int OnObserveProxyAck(std::unique_ptr<ObserveProxyAckEvent> event);
	int OnObserveClosure(std::unique_ptr<ObserveClosureEvent> event);
	int OnMergePort(std::unique_ptr<MergePortEvent> event);

	int AddPortWithName(const PortName& port_name, scoped_refptr<Port> port);
	void ErasePort(const PortName& port_name);

	int SendUserMessageInternal(const PortRef& port_ref,
	std::unique_ptr<UserMessageEvent>* message);
	int MergePortsInternal(const PortRef& port0_ref,
	const PortRef& port1_ref,
	bool allow_close_on_bad_state);
	void ConvertToProxy(Port* port,
	const NodeName& to_node_name,
	PortName* port_name,
	Event::PortDescriptor* port_descriptor);
	int AcceptPort(const PortName& port_name,
	const Event::PortDescriptor& port_descriptor);

	int PrepareToForwardUserMessage(const PortRef& forwarding_port_ref,
	Port::State expected_port_state,
	bool ignore_closed_peer,
	UserMessageEvent* message,
	NodeName* forward_to_node);
	int BeginProxying(const PortRef& port_ref);
	int ForwardUserMessagesFromProxy(const PortRef& port_ref);
	void InitiateProxyRemoval(const PortRef& port_ref);
	void TryRemoveProxy(const PortRef& port_ref);
	void DestroyAllPortsWithPeer(const NodeName& node_name,
	const PortName& port_name);

	const NodeName name_;
	const DelegateHolder delegate_;

	// Guards \|ports_\|. This must never be acquired while an individual port's
	// lock is held on the same thread. Conversely, individual port locks may be
	// acquired while this one is held.
	//
	// Because UserMessage events may execute arbitrary user code during
	// destruction, it is also important to ensure that such events are never
	// destroyed while this (or any individual Port) lock is held.
	base::Lock ports_lock_;
	std::unordered_map<PortName, scoped_refptr<Port>> ports_;

	DISALLOW_COPY_AND_ASSIGN(Node);
	};

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

	#endif // MOJO_CORE_PORTS_NODE_H_