webrtc/p2p/base/p2ptransportchannel.h - src - Git at Google

 /*
  *  Copyright 2004 The WebRTC Project Authors. All rights reserved.
  *
  *  Use of this source code is governed by a BSD-style license
  *  that can be found in the LICENSE file in the root of the source
  *  tree. An additional intellectual property rights grant can be found
  *  in the file PATENTS.  All contributing project authors may
  *  be found in the AUTHORS file in the root of the source tree.
  */

 // P2PTransportChannel wraps up the state management of the connection between
 // two P2P clients.  Clients have candidate ports for connecting, and
 // connections which are combinations of candidates from each end (Alice and
 // Bob each have candidates, one candidate from Alice and one candidate from
 // Bob are used to make a connection, repeat to make many connections).
 //
 // When all of the available connections become invalid (non-writable), we
 // kick off a process of determining more candidates and more connections.
 //
 #ifndef WEBRTC_P2P_BASE_P2PTRANSPORTCHANNEL_H_
 #define WEBRTC_P2P_BASE_P2PTRANSPORTCHANNEL_H_

 #include <map>
 #include <memory>
 #include <set>
 #include <string>
 #include <vector>

 #include "webrtc/base/constructormagic.h"
 #include "webrtc/p2p/base/candidate.h"
 #include "webrtc/p2p/base/candidatepairinterface.h"
 #include "webrtc/p2p/base/p2ptransport.h"
 #include "webrtc/p2p/base/portallocator.h"
 #include "webrtc/p2p/base/portinterface.h"
 #include "webrtc/p2p/base/transportchannelimpl.h"
 #include "webrtc/base/asyncpacketsocket.h"
 #include "webrtc/base/sigslot.h"

 namespace cricket {

 // Enum for UMA metrics, used to record whether the channel is
 // connected/connecting/disconnected when ICE restart happens.
 enum class IceRestartState { CONNECTING, CONNECTED, DISCONNECTED, MAX_VALUE };

 extern const int WEAK_PING_INTERVAL;
 extern const int STABILIZING_WRITABLE_CONNECTION_PING_INTERVAL;
 extern const int STABLE_WRITABLE_CONNECTION_PING_INTERVAL;
 static const int MIN_PINGS_AT_WEAK_PING_INTERVAL = 3;

 // Adds the port on which the candidate originated.
 class RemoteCandidate : public Candidate {
  public:
   RemoteCandidate(const Candidate& c, PortInterface* origin_port)
       : Candidate(c), origin_port_(origin_port) {}

   PortInterface* origin_port() { return origin_port_; }

  private:
   PortInterface* origin_port_;
 };

 // P2PTransportChannel manages the candidates and connection process to keep
 // two P2P clients connected to each other.
 class P2PTransportChannel : public TransportChannelImpl,
                             public rtc::MessageHandler {
  public:
   P2PTransportChannel(const std::string& transport_name,
                       int component,
                       PortAllocator* allocator);
   // TODO(mikescarlett): Deprecated. Remove when Chromium's
   // IceTransportChannel does not depend on this.
   P2PTransportChannel(const std::string& transport_name,
                       int component,
                       P2PTransport* transport,
                       PortAllocator* allocator);
   virtual ~P2PTransportChannel();

   // From TransportChannelImpl:
   TransportChannelState GetState() const override;
   void SetIceRole(IceRole role) override;
   IceRole GetIceRole() const override { return ice_role_; }
   void SetIceTiebreaker(uint64_t tiebreaker) override;
   void SetIceParameters(const IceParameters& ice_params) override;
   void SetRemoteIceParameters(const IceParameters& ice_params) override;
   void SetRemoteIceMode(IceMode mode) override;
   // TODO(deadbeef): Deprecated. Remove when Chromium's
   // IceTransportChannel does not depend on this.
   void Connect() {}
   void MaybeStartGathering() override;
   IceGatheringState gathering_state() const override {
     return gathering_state_;
   }
   void AddRemoteCandidate(const Candidate& candidate) override;
   void RemoveRemoteCandidate(const Candidate& candidate) override;
   // Sets the parameters in IceConfig. We do not set them blindly. Instead, we
   // only update the parameter if it is considered set in |config|. For example,
   // a negative value of receiving_timeout will be considered "not set" and we
   // will not use it to update the respective parameter in |config_|.
   // TODO(deadbeef): Use rtc::Optional instead of negative values.
   void SetIceConfig(const IceConfig& config) override;
   const IceConfig& config() const;
   void SetMetricsObserver(webrtc::MetricsObserverInterface* observer) override;

   // From TransportChannel:
   int SendPacket(const char* data,
                  size_t len,
                  const rtc::PacketOptions& options,
                  int flags) override;
   int SetOption(rtc::Socket::Option opt, int value) override;
   bool GetOption(rtc::Socket::Option opt, int* value) override;
   int GetError() override { return error_; }
   bool GetStats(std::vector<ConnectionInfo>* stats) override;

   // TODO(honghaiz): Remove this method once the reference of it in
   // Chromoting is removed.
   const Connection* best_connection() const { return selected_connection_; }

   const Connection* selected_connection() const { return selected_connection_; }
   void set_incoming_only(bool value) { incoming_only_ = value; }

   // Note: These are only for testing purpose.
   // |ports_| and |pruned_ports| should not be changed from outside.
   const std::vector<PortInterface*>& ports() { return ports_; }
   const std::vector<PortInterface*>& pruned_ports() { return pruned_ports_; }

   IceMode remote_ice_mode() const { return remote_ice_mode_; }

   // DTLS methods.
   bool IsDtlsActive() const override { return false; }

   // Default implementation.
   bool GetSslRole(rtc::SSLRole* role) const override { return false; }

   bool SetSslRole(rtc::SSLRole role) override { return false; }

   // Set up the ciphers to use for DTLS-SRTP.
   bool SetSrtpCryptoSuites(const std::vector<int>& ciphers) override {
     return false;
   }

   // Find out which DTLS-SRTP cipher was negotiated.
   bool GetSrtpCryptoSuite(int* cipher) override { return false; }

   // Find out which DTLS cipher was negotiated.
   bool GetSslCipherSuite(int* cipher) override { return false; }

   // Returns null because the channel is not encrypted by default.
   rtc::scoped_refptr<rtc::RTCCertificate> GetLocalCertificate() const override {
     return nullptr;
   }

   std::unique_ptr<rtc::SSLCertificate> GetRemoteSSLCertificate()
       const override {
     return nullptr;
   }

   // Allows key material to be extracted for external encryption.
   bool ExportKeyingMaterial(const std::string& label,
                             const uint8_t* context,
                             size_t context_len,
                             bool use_context,
                             uint8_t* result,
                             size_t result_len) override {
     return false;
   }

   bool SetLocalCertificate(
       const rtc::scoped_refptr<rtc::RTCCertificate>& certificate) override {
     return false;
   }

   // Set DTLS Remote fingerprint. Must be after local identity set.
   bool SetRemoteFingerprint(const std::string& digest_alg,
                             const uint8_t* digest,
                             size_t digest_len) override {
     return false;
   }

   void PruneAllPorts();
   int receiving_timeout() const { return config_.receiving_timeout; }
   int check_receiving_interval() const { return check_receiving_interval_; }

   // Helper method used only in unittest.
   rtc::DiffServCodePoint DefaultDscpValue() const;

   // Public for unit tests.
   Connection* FindNextPingableConnection();
   void MarkConnectionPinged(Connection* conn);

   // Public for unit tests.
   const std::vector<Connection*>& connections() const { return connections_; }

   // Public for unit tests.
   PortAllocatorSession* allocator_session() {
     return allocator_sessions_.back().get();
   }

   // Public for unit tests.
   const std::vector<RemoteCandidate>& remote_candidates() const {
     return remote_candidates_;
   }

  private:
   rtc::Thread* thread() const { return network_thread_; }
   bool IsGettingPorts() { return allocator_session()->IsGettingPorts(); }

   // A transport channel is weak if the current best connection is either
   // not receiving or not writable, or if there is no best connection at all.
   bool weak() const;
   // Returns true if it's possible to send packets on |connection|.
   bool ReadyToSend(Connection* connection) const;
   void UpdateConnectionStates();
   void RequestSortAndStateUpdate();
   // Start pinging if we haven't already started, and we now have a connection
   // that's pingable.
   void MaybeStartPinging();

   // The methods below return a positive value if |a| is preferable to |b|,
   // a negative value if |b| is preferable, and 0 if they're equally preferable.
   // If |receiving_unchanged_threshold| is set, then when |b| is receiving and
   // |a| is not, returns a negative value only if |b| has been in receiving
   // state and |a| has been in not receiving state since
   // |receiving_unchanged_threshold| and sets
   // |missed_receiving_unchanged_threshold| to true otherwise.
   int CompareConnectionStates(
       const cricket::Connection* a,
       const cricket::Connection* b,
       rtc::Optional<int64_t> receiving_unchanged_threshold,
       bool* missed_receiving_unchanged_threshold) const;
   int CompareConnectionCandidates(const cricket::Connection* a,
                                   const cricket::Connection* b) const;
   // Compares two connections based on the connection states
   // (writable/receiving/connected), nomination states, last data received time,
   // and static preferences. Does not include latency. Used by both sorting
   // and ShouldSwitchSelectedConnection().
   // Returns a positive value if |a| is better than |b|.
   int CompareConnections(const cricket::Connection* a,
                          const cricket::Connection* b,
                          rtc::Optional<int64_t> receiving_unchanged_threshold,
                          bool* missed_receiving_unchanged_threshold) const;

   bool PresumedWritable(const cricket::Connection* conn) const;

   void SortConnectionsAndUpdateState();
   void SwitchSelectedConnection(Connection* conn);
   void UpdateState();
   void HandleAllTimedOut();
   void MaybeStopPortAllocatorSessions();
   TransportChannelState ComputeState() const;

   Connection* GetBestConnectionOnNetwork(rtc::Network* network) const;
   bool CreateConnections(const Candidate& remote_candidate,
                          PortInterface* origin_port);
   bool CreateConnection(PortInterface* port,
                         const Candidate& remote_candidate,
                         PortInterface* origin_port);
   bool FindConnection(cricket::Connection* connection) const;

   uint32_t GetRemoteCandidateGeneration(const Candidate& candidate);
   bool IsDuplicateRemoteCandidate(const Candidate& candidate);
   void RememberRemoteCandidate(const Candidate& remote_candidate,
                                PortInterface* origin_port);
   bool IsPingable(const Connection* conn, int64_t now) const;
   bool IsSelectedConnectionPingable(int64_t now);
   int CalculateActiveWritablePingInterval(const Connection* conn,
                                           int64_t now) const;
   void PingConnection(Connection* conn);
   void AddAllocatorSession(std::unique_ptr<PortAllocatorSession> session);
   void AddConnection(Connection* connection);

   void OnPortReady(PortAllocatorSession *session, PortInterface* port);
   void OnPortsPruned(PortAllocatorSession* session,
                      const std::vector<PortInterface*>& ports);
   void OnCandidatesReady(PortAllocatorSession *session,
                          const std::vector<Candidate>& candidates);
   void OnCandidatesRemoved(PortAllocatorSession* session,
                            const std::vector<Candidate>& candidates);
   void OnCandidatesAllocationDone(PortAllocatorSession* session);
   void OnUnknownAddress(PortInterface* port,
                         const rtc::SocketAddress& addr,
                         ProtocolType proto,
                         IceMessage* stun_msg,
                         const std::string& remote_username,
                         bool port_muxed);

   // When a port is destroyed, remove it from both lists |ports_|
   // and |pruned_ports_|.
   void OnPortDestroyed(PortInterface* port);
   // When pruning a port, move it from |ports_| to |pruned_ports_|.
   // Returns true if the port is found and removed from |ports_|.
   bool PrunePort(PortInterface* port);
   void OnRoleConflict(PortInterface* port);

   void OnConnectionStateChange(Connection* connection);
   void OnReadPacket(Connection *connection, const char *data, size_t len,
                     const rtc::PacketTime& packet_time);
   void OnSentPacket(const rtc::SentPacket& sent_packet);
   void OnReadyToSend(Connection* connection);
   void OnConnectionDestroyed(Connection *connection);

   void OnNominated(Connection* conn);

   void OnMessage(rtc::Message* pmsg) override;
   void OnCheckAndPing();
   void OnRegatherOnFailedNetworks();

   uint32_t GetNominationAttr(Connection* conn) const;
   bool GetUseCandidateAttr(Connection* conn, NominationMode mode) const;

   // Returns true if we should switch to the new connection.
   // sets |missed_receiving_unchanged_threshold| to true if either
   // the selected connection or the new connection missed its
   // receiving-unchanged-threshold.
   bool ShouldSwitchSelectedConnection(
       Connection* new_connection,
       bool* missed_receiving_unchanged_threshold) const;
   // Returns true if the new_connection is selected for transmission.
   bool MaybeSwitchSelectedConnection(Connection* new_connection,
                                      const std::string& reason);

   void PruneConnections();
   bool IsBackupConnection(const Connection* conn) const;

   Connection* FindConnectionToPing(int64_t now);
   Connection* FindOldestConnectionNeedingTriggeredCheck(int64_t now);
   // Between |conn1| and |conn2|, this function returns the one which should
   // be pinged first.
   Connection* SelectMostPingableConnection(Connection* conn1,
                                            Connection* conn2);
   // Select the connection which is Relay/Relay. If both of them are,
   // UDP relay protocol takes precedence.
   Connection* MostLikelyToWork(Connection* conn1, Connection* conn2);
   // Compare the last_ping_sent time and return the one least recently pinged.
   Connection* LeastRecentlyPinged(Connection* conn1, Connection* conn2);

   // Returns the latest remote ICE parameters or nullptr if there are no remote
   // ICE parameters yet.
   IceParameters* remote_ice() {
     return remote_ice_parameters_.empty() ? nullptr
                                           : &remote_ice_parameters_.back();
   }
   // Returns the remote IceParameters and generation that match |ufrag|
   // if found, and returns nullptr otherwise.
   const IceParameters* FindRemoteIceFromUfrag(const std::string& ufrag,
                                               uint32_t* generation);
   // Returns the index of the latest remote ICE parameters, or 0 if no remote
   // ICE parameters have been received.
   uint32_t remote_ice_generation() {
     return remote_ice_parameters_.empty()
                ? 0
                : static_cast<uint32_t>(remote_ice_parameters_.size() - 1);
   }

   PortAllocator* allocator_;
   rtc::Thread* network_thread_;
   bool incoming_only_;
   int error_;
   std::vector<std::unique_ptr<PortAllocatorSession>> allocator_sessions_;
   // |ports_| contains ports that are used to form new connections when
   // new remote candidates are added.
   std::vector<PortInterface*> ports_;
   // |pruned_ports_| contains ports that have been removed from |ports_| and
   // are not being used to form new connections, but that aren't yet destroyed.
   // They may have existing connections, and they still fire signals such as
   // SignalUnknownAddress.
   std::vector<PortInterface*> pruned_ports_;

   // |connections_| is a sorted list with the first one always be the
   // |selected_connection_| when it's not nullptr. The combination of
   // |pinged_connections_| and |unpinged_connections_| has the same
   // connections as |connections_|. These 2 sets maintain whether a
   // connection should be pinged next or not.
   std::vector<Connection *> connections_;
   std::set<Connection*> pinged_connections_;
   std::set<Connection*> unpinged_connections_;

   Connection* selected_connection_ = nullptr;

   std::vector<RemoteCandidate> remote_candidates_;
   bool sort_dirty_;  // indicates whether another sort is needed right now
   bool had_connection_ = false;  // if connections_ has ever been nonempty
   typedef std::map<rtc::Socket::Option, int> OptionMap;
   OptionMap options_;
   IceParameters ice_parameters_;
   std::vector<IceParameters> remote_ice_parameters_;
   IceMode remote_ice_mode_;
   IceRole ice_role_;
   uint64_t tiebreaker_;
   IceGatheringState gathering_state_;

   int check_receiving_interval_;
   int64_t last_ping_sent_ms_ = 0;
   int weak_ping_interval_ = WEAK_PING_INTERVAL;
   TransportChannelState state_ = TransportChannelState::STATE_INIT;
   IceConfig config_;
   int last_sent_packet_id_ = -1;  // -1 indicates no packet was sent before.
   bool started_pinging_ = false;
   // The value put in the "nomination" attribute for the next nominated
   // connection. A zero-value indicates the connection will not be nominated.
   uint32_t nomination_ = 0;

   webrtc::MetricsObserverInterface* metrics_observer_ = nullptr;

   RTC_DISALLOW_COPY_AND_ASSIGN(P2PTransportChannel);
 };

 }  // namespace cricket

 #endif  // WEBRTC_P2P_BASE_P2PTRANSPORTCHANNEL_H_
	/*
	* Copyright 2004 The WebRTC Project Authors. All rights reserved.
	*
	* Use of this source code is governed by a BSD-style license
	* that can be found in the LICENSE file in the root of the source
	* tree. An additional intellectual property rights grant can be found
	* in the file PATENTS. All contributing project authors may
	* be found in the AUTHORS file in the root of the source tree.
	*/

	// P2PTransportChannel wraps up the state management of the connection between
	// two P2P clients. Clients have candidate ports for connecting, and
	// connections which are combinations of candidates from each end (Alice and
	// Bob each have candidates, one candidate from Alice and one candidate from
	// Bob are used to make a connection, repeat to make many connections).
	//
	// When all of the available connections become invalid (non-writable), we
	// kick off a process of determining more candidates and more connections.
	//
	#ifndef WEBRTC_P2P_BASE_P2PTRANSPORTCHANNEL_H_
	#define WEBRTC_P2P_BASE_P2PTRANSPORTCHANNEL_H_

	#include <map>
	#include <memory>
	#include <set>
	#include <string>
	#include <vector>

	#include "webrtc/base/constructormagic.h"
	#include "webrtc/p2p/base/candidate.h"
	#include "webrtc/p2p/base/candidatepairinterface.h"
	#include "webrtc/p2p/base/p2ptransport.h"
	#include "webrtc/p2p/base/portallocator.h"
	#include "webrtc/p2p/base/portinterface.h"
	#include "webrtc/p2p/base/transportchannelimpl.h"
	#include "webrtc/base/asyncpacketsocket.h"
	#include "webrtc/base/sigslot.h"

	namespace cricket {

	// Enum for UMA metrics, used to record whether the channel is
	// connected/connecting/disconnected when ICE restart happens.
	enum class IceRestartState { CONNECTING, CONNECTED, DISCONNECTED, MAX_VALUE };

	extern const int WEAK_PING_INTERVAL;
	extern const int STABILIZING_WRITABLE_CONNECTION_PING_INTERVAL;
	extern const int STABLE_WRITABLE_CONNECTION_PING_INTERVAL;
	static const int MIN_PINGS_AT_WEAK_PING_INTERVAL = 3;

	// Adds the port on which the candidate originated.
	class RemoteCandidate : public Candidate {
	public:
	RemoteCandidate(const Candidate& c, PortInterface* origin_port)
	: Candidate(c), origin_port_(origin_port) {}

	PortInterface* origin_port() { return origin_port_; }

	private:
	PortInterface* origin_port_;
	};

	// P2PTransportChannel manages the candidates and connection process to keep
	// two P2P clients connected to each other.
	class P2PTransportChannel : public TransportChannelImpl,
	public rtc::MessageHandler {
	public:
	P2PTransportChannel(const std::string& transport_name,
	int component,
	PortAllocator* allocator);
	// TODO(mikescarlett): Deprecated. Remove when Chromium's
	// IceTransportChannel does not depend on this.
	P2PTransportChannel(const std::string& transport_name,
	int component,
	P2PTransport* transport,
	PortAllocator* allocator);
	virtual ~P2PTransportChannel();

	// From TransportChannelImpl:
	TransportChannelState GetState() const override;
	void SetIceRole(IceRole role) override;
	IceRole GetIceRole() const override { return ice_role_; }
	void SetIceTiebreaker(uint64_t tiebreaker) override;
	void SetIceParameters(const IceParameters& ice_params) override;
	void SetRemoteIceParameters(const IceParameters& ice_params) override;
	void SetRemoteIceMode(IceMode mode) override;
	// TODO(deadbeef): Deprecated. Remove when Chromium's
	// IceTransportChannel does not depend on this.
	void Connect() {}
	void MaybeStartGathering() override;
	IceGatheringState gathering_state() const override {
	return gathering_state_;
	}
	void AddRemoteCandidate(const Candidate& candidate) override;
	void RemoveRemoteCandidate(const Candidate& candidate) override;
	// Sets the parameters in IceConfig. We do not set them blindly. Instead, we
	// only update the parameter if it is considered set in \|config\|. For example,
	// a negative value of receiving_timeout will be considered "not set" and we
	// will not use it to update the respective parameter in \|config_\|.
	// TODO(deadbeef): Use rtc::Optional instead of negative values.
	void SetIceConfig(const IceConfig& config) override;
	const IceConfig& config() const;
	void SetMetricsObserver(webrtc::MetricsObserverInterface* observer) override;

	// From TransportChannel:
	int SendPacket(const char* data,
	size_t len,
	const rtc::PacketOptions& options,
	int flags) override;
	int SetOption(rtc::Socket::Option opt, int value) override;
	bool GetOption(rtc::Socket::Option opt, int* value) override;
	int GetError() override { return error_; }
	bool GetStats(std::vector<ConnectionInfo>* stats) override;

	// TODO(honghaiz): Remove this method once the reference of it in
	// Chromoting is removed.
	const Connection* best_connection() const { return selected_connection_; }

	const Connection* selected_connection() const { return selected_connection_; }
	void set_incoming_only(bool value) { incoming_only_ = value; }

	// Note: These are only for testing purpose.
	// \|ports_\| and \|pruned_ports\| should not be changed from outside.
	const std::vector<PortInterface*>& ports() { return ports_; }
	const std::vector<PortInterface*>& pruned_ports() { return pruned_ports_; }

	IceMode remote_ice_mode() const { return remote_ice_mode_; }

	// DTLS methods.
	bool IsDtlsActive() const override { return false; }

	// Default implementation.
	bool GetSslRole(rtc::SSLRole* role) const override { return false; }

	bool SetSslRole(rtc::SSLRole role) override { return false; }

	// Set up the ciphers to use for DTLS-SRTP.
	bool SetSrtpCryptoSuites(const std::vector<int>& ciphers) override {
	return false;
	}

	// Find out which DTLS-SRTP cipher was negotiated.
	bool GetSrtpCryptoSuite(int* cipher) override { return false; }

	// Find out which DTLS cipher was negotiated.
	bool GetSslCipherSuite(int* cipher) override { return false; }

	// Returns null because the channel is not encrypted by default.
	rtc::scoped_refptr<rtc::RTCCertificate> GetLocalCertificate() const override {
	return nullptr;
	}

	std::unique_ptr<rtc::SSLCertificate> GetRemoteSSLCertificate()
	const override {
	return nullptr;
	}

	// Allows key material to be extracted for external encryption.
	bool ExportKeyingMaterial(const std::string& label,
	const uint8_t* context,
	size_t context_len,
	bool use_context,
	uint8_t* result,
	size_t result_len) override {
	return false;
	}

	bool SetLocalCertificate(
	const rtc::scoped_refptr<rtc::RTCCertificate>& certificate) override {
	return false;
	}

	// Set DTLS Remote fingerprint. Must be after local identity set.
	bool SetRemoteFingerprint(const std::string& digest_alg,
	const uint8_t* digest,
	size_t digest_len) override {
	return false;
	}

	void PruneAllPorts();
	int receiving_timeout() const { return config_.receiving_timeout; }
	int check_receiving_interval() const { return check_receiving_interval_; }

	// Helper method used only in unittest.
	rtc::DiffServCodePoint DefaultDscpValue() const;

	// Public for unit tests.
	Connection* FindNextPingableConnection();
	void MarkConnectionPinged(Connection* conn);

	// Public for unit tests.
	const std::vector<Connection*>& connections() const { return connections_; }

	// Public for unit tests.
	PortAllocatorSession* allocator_session() {
	return allocator_sessions_.back().get();
	}

	// Public for unit tests.
	const std::vector<RemoteCandidate>& remote_candidates() const {
	return remote_candidates_;
	}

	private:
	rtc::Thread* thread() const { return network_thread_; }
	bool IsGettingPorts() { return allocator_session()->IsGettingPorts(); }

	// A transport channel is weak if the current best connection is either
	// not receiving or not writable, or if there is no best connection at all.
	bool weak() const;
	// Returns true if it's possible to send packets on \|connection\|.
	bool ReadyToSend(Connection* connection) const;
	void UpdateConnectionStates();
	void RequestSortAndStateUpdate();
	// Start pinging if we haven't already started, and we now have a connection
	// that's pingable.
	void MaybeStartPinging();

	// The methods below return a positive value if \|a\| is preferable to \|b\|,
	// a negative value if \|b\| is preferable, and 0 if they're equally preferable.
	// If \|receiving_unchanged_threshold\| is set, then when \|b\| is receiving and
	// \|a\| is not, returns a negative value only if \|b\| has been in receiving
	// state and \|a\| has been in not receiving state since
	// \|receiving_unchanged_threshold\| and sets
	// \|missed_receiving_unchanged_threshold\| to true otherwise.
	int CompareConnectionStates(
	const cricket::Connection* a,
	const cricket::Connection* b,
	rtc::Optional<int64_t> receiving_unchanged_threshold,
	bool* missed_receiving_unchanged_threshold) const;
	int CompareConnectionCandidates(const cricket::Connection* a,
	const cricket::Connection* b) const;
	// Compares two connections based on the connection states
	// (writable/receiving/connected), nomination states, last data received time,
	// and static preferences. Does not include latency. Used by both sorting
	// and ShouldSwitchSelectedConnection().
	// Returns a positive value if \|a\| is better than \|b\|.
	int CompareConnections(const cricket::Connection* a,
	const cricket::Connection* b,
	rtc::Optional<int64_t> receiving_unchanged_threshold,
	bool* missed_receiving_unchanged_threshold) const;

	bool PresumedWritable(const cricket::Connection* conn) const;

	void SortConnectionsAndUpdateState();
	void SwitchSelectedConnection(Connection* conn);
	void UpdateState();
	void HandleAllTimedOut();
	void MaybeStopPortAllocatorSessions();
	TransportChannelState ComputeState() const;

	Connection* GetBestConnectionOnNetwork(rtc::Network* network) const;
	bool CreateConnections(const Candidate& remote_candidate,
	PortInterface* origin_port);
	bool CreateConnection(PortInterface* port,
	const Candidate& remote_candidate,
	PortInterface* origin_port);
	bool FindConnection(cricket::Connection* connection) const;

	uint32_t GetRemoteCandidateGeneration(const Candidate& candidate);
	bool IsDuplicateRemoteCandidate(const Candidate& candidate);
	void RememberRemoteCandidate(const Candidate& remote_candidate,
	PortInterface* origin_port);
	bool IsPingable(const Connection* conn, int64_t now) const;
	bool IsSelectedConnectionPingable(int64_t now);
	int CalculateActiveWritablePingInterval(const Connection* conn,
	int64_t now) const;
	void PingConnection(Connection* conn);
	void AddAllocatorSession(std::unique_ptr<PortAllocatorSession> session);
	void AddConnection(Connection* connection);

	void OnPortReady(PortAllocatorSession session, PortInterface port);
	void OnPortsPruned(PortAllocatorSession* session,
	const std::vector<PortInterface*>& ports);
	void OnCandidatesReady(PortAllocatorSession *session,
	const std::vector<Candidate>& candidates);
	void OnCandidatesRemoved(PortAllocatorSession* session,
	const std::vector<Candidate>& candidates);
	void OnCandidatesAllocationDone(PortAllocatorSession* session);
	void OnUnknownAddress(PortInterface* port,
	const rtc::SocketAddress& addr,
	ProtocolType proto,
	IceMessage* stun_msg,
	const std::string& remote_username,
	bool port_muxed);

	// When a port is destroyed, remove it from both lists \|ports_\|
	// and \|pruned_ports_\|.
	void OnPortDestroyed(PortInterface* port);
	// When pruning a port, move it from \|ports_\| to \|pruned_ports_\|.
	// Returns true if the port is found and removed from \|ports_\|.
	bool PrunePort(PortInterface* port);
	void OnRoleConflict(PortInterface* port);

	void OnConnectionStateChange(Connection* connection);
	void OnReadPacket(Connection connection, const char data, size_t len,
	const rtc::PacketTime& packet_time);
	void OnSentPacket(const rtc::SentPacket& sent_packet);
	void OnReadyToSend(Connection* connection);
	void OnConnectionDestroyed(Connection *connection);

	void OnNominated(Connection* conn);

	void OnMessage(rtc::Message* pmsg) override;
	void OnCheckAndPing();
	void OnRegatherOnFailedNetworks();

	uint32_t GetNominationAttr(Connection* conn) const;
	bool GetUseCandidateAttr(Connection* conn, NominationMode mode) const;

	// Returns true if we should switch to the new connection.
	// sets \|missed_receiving_unchanged_threshold\| to true if either
	// the selected connection or the new connection missed its
	// receiving-unchanged-threshold.
	bool ShouldSwitchSelectedConnection(
	Connection* new_connection,
	bool* missed_receiving_unchanged_threshold) const;
	// Returns true if the new_connection is selected for transmission.
	bool MaybeSwitchSelectedConnection(Connection* new_connection,
	const std::string& reason);

	void PruneConnections();
	bool IsBackupConnection(const Connection* conn) const;

	Connection* FindConnectionToPing(int64_t now);
	Connection* FindOldestConnectionNeedingTriggeredCheck(int64_t now);
	// Between \|conn1\| and \|conn2\|, this function returns the one which should
	// be pinged first.
	Connection* SelectMostPingableConnection(Connection* conn1,
	Connection* conn2);
	// Select the connection which is Relay/Relay. If both of them are,
	// UDP relay protocol takes precedence.
	Connection* MostLikelyToWork(Connection* conn1, Connection* conn2);
	// Compare the last_ping_sent time and return the one least recently pinged.
	Connection* LeastRecentlyPinged(Connection* conn1, Connection* conn2);

	// Returns the latest remote ICE parameters or nullptr if there are no remote
	// ICE parameters yet.
	IceParameters* remote_ice() {
	return remote_ice_parameters_.empty() ? nullptr
	: &remote_ice_parameters_.back();
	}
	// Returns the remote IceParameters and generation that match \|ufrag\|
	// if found, and returns nullptr otherwise.
	const IceParameters* FindRemoteIceFromUfrag(const std::string& ufrag,
	uint32_t* generation);
	// Returns the index of the latest remote ICE parameters, or 0 if no remote
	// ICE parameters have been received.
	uint32_t remote_ice_generation() {
	return remote_ice_parameters_.empty()
	? 0
	: static_cast<uint32_t>(remote_ice_parameters_.size() - 1);
	}

	PortAllocator* allocator_;
	rtc::Thread* network_thread_;
	bool incoming_only_;
	int error_;
	std::vector<std::unique_ptr<PortAllocatorSession>> allocator_sessions_;
	// \|ports_\| contains ports that are used to form new connections when
	// new remote candidates are added.
	std::vector<PortInterface*> ports_;
	// \|pruned_ports_\| contains ports that have been removed from \|ports_\| and
	// are not being used to form new connections, but that aren't yet destroyed.
	// They may have existing connections, and they still fire signals such as
	// SignalUnknownAddress.
	std::vector<PortInterface*> pruned_ports_;

	// \|connections_\| is a sorted list with the first one always be the
	// \|selected_connection_\| when it's not nullptr. The combination of
	// \|pinged_connections_\| and \|unpinged_connections_\| has the same
	// connections as \|connections_\|. These 2 sets maintain whether a
	// connection should be pinged next or not.
	std::vector<Connection *> connections_;
	std::set<Connection*> pinged_connections_;
	std::set<Connection*> unpinged_connections_;

	Connection* selected_connection_ = nullptr;

	std::vector<RemoteCandidate> remote_candidates_;
	bool sort_dirty_; // indicates whether another sort is needed right now
	bool had_connection_ = false; // if connections_ has ever been nonempty
	typedef std::map<rtc::Socket::Option, int> OptionMap;
	OptionMap options_;
	IceParameters ice_parameters_;
	std::vector<IceParameters> remote_ice_parameters_;
	IceMode remote_ice_mode_;
	IceRole ice_role_;
	uint64_t tiebreaker_;
	IceGatheringState gathering_state_;

	int check_receiving_interval_;
	int64_t last_ping_sent_ms_ = 0;
	int weak_ping_interval_ = WEAK_PING_INTERVAL;
	TransportChannelState state_ = TransportChannelState::STATE_INIT;
	IceConfig config_;
	int last_sent_packet_id_ = -1; // -1 indicates no packet was sent before.
	bool started_pinging_ = false;
	// The value put in the "nomination" attribute for the next nominated
	// connection. A zero-value indicates the connection will not be nominated.
	uint32_t nomination_ = 0;

	webrtc::MetricsObserverInterface* metrics_observer_ = nullptr;

	RTC_DISALLOW_COPY_AND_ASSIGN(P2PTransportChannel);
	};

	} // namespace cricket

	#endif // WEBRTC_P2P_BASE_P2PTRANSPORTCHANNEL_H_