func (nn *netNotifiee) Disconnected(n inet.Network, v inet.Conn) { // undo the setting of addresses to peer.ConnectedAddrTTL we did ids := nn.IDService() ps := ids.Host.Peerstore() addrs := ps.Addrs(v.RemotePeer()) ps.SetAddrs(v.RemotePeer(), addrs, peer.RecentlyConnectedAddrTTL) }
func (nn *netNotifiee) Disconnected(n inet.Network, v inet.Conn) { dht := nn.DHT() select { case <-dht.Process().Closing(): return default: } dht.routingTable.Remove(v.RemotePeer()) }
func (nn *netNotifiee) Connected(n inet.Network, v inet.Conn) { dht := nn.DHT() select { case <-dht.Process().Closing(): return default: } dht.Update(dht.Context(), v.RemotePeer()) }
func (ids *IDService) consumeObservedAddress(observed []byte, c inet.Conn) { if observed == nil { return } maddr, err := ma.NewMultiaddrBytes(observed) if err != nil { log.Debugf("error parsing received observed addr for %s: %s", c, err) return } // we should only use ObservedAddr when our connection's LocalAddr is one // of our ListenAddrs. If we Dial out using an ephemeral addr, knowing that // address's external mapping is not very useful because the port will not be // the same as the listen addr. ifaceaddrs, err := ids.Host.Network().InterfaceListenAddresses() if err != nil { log.Infof("failed to get interface listen addrs", err) return } log.Debugf("identify identifying observed multiaddr: %s %s", c.LocalMultiaddr(), ifaceaddrs) if !addrInAddrs(c.LocalMultiaddr(), ifaceaddrs) { // not in our list return } // ok! we have the observed version of one of our ListenAddresses! log.Debugf("added own observed listen addr: %s --> %s", c.LocalMultiaddr(), maddr) ids.observedAddrs.Add(maddr, c.RemoteMultiaddr()) }
func (ids *IDService) populateMessage(mes *pb.Identify, c inet.Conn) { // set protocols this node is currently handling protos := ids.Host.Mux().Protocols() mes.Protocols = make([]string, len(protos)) for i, p := range protos { mes.Protocols[i] = string(p) } // observed address so other side is informed of their // "public" address, at least in relation to us. mes.ObservedAddr = c.RemoteMultiaddr().Bytes() // set listen addrs, get our latest addrs from Host. laddrs := ids.Host.Addrs() mes.ListenAddrs = make([][]byte, len(laddrs)) for i, addr := range laddrs { mes.ListenAddrs[i] = addr.Bytes() } log.Debugf("%s sent listen addrs to %s: %s", c.LocalPeer(), c.RemotePeer(), laddrs) // set protocol versions pv := LibP2PVersion av := ClientVersion mes.ProtocolVersion = &pv mes.AgentVersion = &av }
func logProtocolMismatchDisconnect(c inet.Conn, protocol, agent string) { lm := make(lgbl.DeferredMap) lm["remotePeer"] = func() interface{} { return c.RemotePeer().Pretty() } lm["remoteAddr"] = func() interface{} { return c.RemoteMultiaddr().String() } lm["protocolVersion"] = protocol lm["agentVersion"] = agent log.Event(context.TODO(), "IdentifyProtocolMismatch", lm) log.Debug("IdentifyProtocolMismatch %s %s %s (disconnected)", c.RemotePeer(), protocol, agent) }
func (ids *IDService) IdentifyConn(c inet.Conn) { ids.currmu.Lock() if wait, found := ids.currid[c]; found { ids.currmu.Unlock() log.Debugf("IdentifyConn called twice on: %s", c) <-wait // already identifying it. wait for it. return } ch := make(chan struct{}) ids.currid[c] = ch ids.currmu.Unlock() defer close(ch) s, err := c.NewStream() if err != nil { log.Debugf("error opening initial stream for %s: %s", ID, err) log.Event(context.TODO(), "IdentifyOpenFailed", c.RemotePeer()) c.Close() return } bwc := ids.Host.GetBandwidthReporter() s = mstream.WrapStream(s, ID, bwc) // ok give the response to our handler. if err := msmux.SelectProtoOrFail(ID, s); err != nil { log.Debugf("error writing stream header for %s", ID) log.Event(context.TODO(), "IdentifyOpenFailed", c.RemotePeer()) s.Close() return } ids.ResponseHandler(s) ids.currmu.Lock() _, found := ids.currid[c] delete(ids.currid, c) ids.currmu.Unlock() if !found { log.Debugf("IdentifyConn failed to find channel (programmer error) for %s", c) return } }
func (ids *IDService) consumeMessage(mes *pb.Identify, c inet.Conn) { p := c.RemotePeer() // mes.Protocols // mes.ObservedAddr ids.consumeObservedAddress(mes.GetObservedAddr(), c) // mes.ListenAddrs laddrs := mes.GetListenAddrs() lmaddrs := make([]ma.Multiaddr, 0, len(laddrs)) for _, addr := range laddrs { maddr, err := ma.NewMultiaddrBytes(addr) if err != nil { log.Debugf("%s failed to parse multiaddr from %s %s", ID, p, c.RemoteMultiaddr()) continue } lmaddrs = append(lmaddrs, maddr) } lmaddrs = append(lmaddrs, c.RemoteMultiaddr()) // update our peerstore with the addresses. here, we SET the addresses, clearing old ones. // We are receiving from the peer itself. this is current address ground truth. ids.Host.Peerstore().SetAddrs(p, lmaddrs, peer.ConnectedAddrTTL) log.Debugf("%s received listen addrs for %s: %s", c.LocalPeer(), c.RemotePeer(), lmaddrs) // get protocol versions pv := mes.GetProtocolVersion() av := mes.GetAgentVersion() // version check. if we shouldn't talk, bail. // TODO: at this point, we've already exchanged information. // move this into a first handshake before the connection can open streams. if !protocolVersionsAreCompatible(pv, LibP2PVersion) { logProtocolMismatchDisconnect(c, pv, av) c.Close() return } ids.Host.Peerstore().Put(p, "ProtocolVersion", pv) ids.Host.Peerstore().Put(p, "AgentVersion", av) }
func (nn *netNotifiee) Disconnected(n inet.Network, v inet.Conn) { nn.impl().receiver.PeerDisconnected(v.RemotePeer()) }