// Copyright (C) 2015 The Syncthing Authors. // // This Source Code Form is subject to the terms of the Mozilla Public // License, v. 2.0. If a copy of the MPL was not distributed with this file, // You can obtain one at http://mozilla.org/MPL/2.0/. package connections import ( "crypto/tls" "fmt" "io" "net" "net/url" "sync" "time" "github.com/juju/ratelimit" "github.com/syncthing/syncthing/lib/config" "github.com/syncthing/syncthing/lib/discover" "github.com/syncthing/syncthing/lib/events" "github.com/syncthing/syncthing/lib/model" "github.com/syncthing/syncthing/lib/protocol" "github.com/syncthing/syncthing/lib/relay" "github.com/syncthing/syncthing/lib/relay/client" "github.com/thejerf/suture" ) type DialerFactory func(*url.URL, *tls.Config) (*tls.Conn, error) type ListenerFactory func(*url.URL, *tls.Config, chan<- model.IntermediateConnection) var ( dialers = make(map[string]DialerFactory, 0) listeners = make(map[string]ListenerFactory, 0) ) type Model interface { protocol.Model AddConnection(conn model.Connection) ConnectedTo(remoteID protocol.DeviceID) bool IsPaused(remoteID protocol.DeviceID) bool } // The connection service listens on TLS and dials configured unconnected // devices. Successful connections are handed to the model. type connectionSvc struct { *suture.Supervisor cfg *config.Wrapper myID protocol.DeviceID model Model tlsCfg *tls.Config discoverer discover.Finder conns chan model.IntermediateConnection relaySvc *relay.Svc bepProtocolName string tlsDefaultCommonName string lans []*net.IPNet writeRateLimit *ratelimit.Bucket readRateLimit *ratelimit.Bucket lastRelayCheck map[protocol.DeviceID]time.Time mut sync.RWMutex connType map[protocol.DeviceID]model.ConnectionType relaysEnabled bool } func NewConnectionSvc(cfg *config.Wrapper, myID protocol.DeviceID, mdl Model, tlsCfg *tls.Config, discoverer discover.Finder, relaySvc *relay.Svc, bepProtocolName string, tlsDefaultCommonName string, lans []*net.IPNet) suture.Service { svc := &connectionSvc{ Supervisor: suture.NewSimple("connectionSvc"), cfg: cfg, myID: myID, model: mdl, tlsCfg: tlsCfg, discoverer: discoverer, relaySvc: relaySvc, conns: make(chan model.IntermediateConnection), bepProtocolName: bepProtocolName, tlsDefaultCommonName: tlsDefaultCommonName, lans: lans, connType: make(map[protocol.DeviceID]model.ConnectionType), relaysEnabled: cfg.Options().RelaysEnabled, lastRelayCheck: make(map[protocol.DeviceID]time.Time), } cfg.Subscribe(svc) if svc.cfg.Options().MaxSendKbps > 0 { svc.writeRateLimit = ratelimit.NewBucketWithRate(float64(1000*svc.cfg.Options().MaxSendKbps), int64(5*1000*svc.cfg.Options().MaxSendKbps)) } if svc.cfg.Options().MaxRecvKbps > 0 { svc.readRateLimit = ratelimit.NewBucketWithRate(float64(1000*svc.cfg.Options().MaxRecvKbps), int64(5*1000*svc.cfg.Options().MaxRecvKbps)) } // There are several moving parts here; one routine per listening address // to handle incoming connections, one routine to periodically attempt // outgoing connections, one routine to the the common handling // regardless of whether the connection was incoming or outgoing. // Furthermore, a relay service which handles incoming requests to connect // via the relays. // // TODO: Clean shutdown, and/or handling config changes on the fly. We // partly do this now - new devices and addresses will be picked up, but // not new listen addresses and we don't support disconnecting devices // that are removed and so on... svc.Add(serviceFunc(svc.connect)) for _, addr := range svc.cfg.Options().ListenAddress { uri, err := url.Parse(addr) if err != nil { l.Infoln("Failed to parse listen address:", addr, err) continue } listener, ok := listeners[uri.Scheme] if !ok { l.Infoln("Unknown listen address scheme:", uri.String()) continue } l.Debugln("listening on", uri) svc.Add(serviceFunc(func() { listener(uri, svc.tlsCfg, svc.conns) })) } svc.Add(serviceFunc(svc.handle)) if svc.relaySvc != nil { svc.Add(serviceFunc(svc.acceptRelayConns)) } return svc } func (s *connectionSvc) handle() { next: for c := range s.conns { cs := c.Conn.ConnectionState() // We should have negotiated the next level protocol "bep/1.0" as part // of the TLS handshake. Unfortunately this can't be a hard error, // because there are implementations out there that don't support // protocol negotiation (iOS for one...). if !cs.NegotiatedProtocolIsMutual || cs.NegotiatedProtocol != s.bepProtocolName { l.Infof("Peer %s did not negotiate bep/1.0", c.Conn.RemoteAddr()) } // We should have received exactly one certificate from the other // side. If we didn't, they don't have a device ID and we drop the // connection. certs := cs.PeerCertificates if cl := len(certs); cl != 1 { l.Infof("Got peer certificate list of length %d != 1 from %s; protocol error", cl, c.Conn.RemoteAddr()) c.Conn.Close() continue } remoteCert := certs[0] remoteID := protocol.NewDeviceID(remoteCert.Raw) // The device ID should not be that of ourselves. It can happen // though, especially in the presence of NAT hairpinning, multiple // clients between the same NAT gateway, and global discovery. if remoteID == s.myID { l.Infof("Connected to myself (%s) - should not happen", remoteID) c.Conn.Close() continue } // If we have a relay connection, and the new incoming connection is // not a relay connection, we should drop that, and prefer the this one. s.mut.RLock() ct, ok := s.connType[remoteID] s.mut.RUnlock() if ok && !ct.IsDirect() && c.Type.IsDirect() { l.Debugln("Switching connections", remoteID) s.model.Close(remoteID, fmt.Errorf("switching connections")) } else if s.model.ConnectedTo(remoteID) { // We should not already be connected to the other party. TODO: This // could use some better handling. If the old connection is dead but // hasn't timed out yet we may want to drop *that* connection and keep // this one. But in case we are two devices connecting to each other // in parallel we don't want to do that or we end up with no // connections still established... l.Infof("Connected to already connected device (%s)", remoteID) c.Conn.Close() continue } else if s.model.IsPaused(remoteID) { l.Infof("Connection from paused device (%s)", remoteID) c.Conn.Close() continue } for deviceID, deviceCfg := range s.cfg.Devices() { if deviceID == remoteID { // Verify the name on the certificate. By default we set it to // "syncthing" when generating, but the user may have replaced // the certificate and used another name. certName := deviceCfg.CertName if certName == "" { certName = s.tlsDefaultCommonName } err := remoteCert.VerifyHostname(certName) if err != nil { // Incorrect certificate name is something the user most // likely wants to know about, since it's an advanced // config. Warn instead of Info. l.Warnf("Bad certificate from %s (%v): %v", remoteID, c.Conn.RemoteAddr(), err) c.Conn.Close() continue next } // If rate limiting is set, and based on the address we should // limit the connection, then we wrap it in a limiter. limit := s.shouldLimit(c.Conn.RemoteAddr()) wr := io.Writer(c.Conn) if limit && s.writeRateLimit != nil { wr = NewWriteLimiter(c.Conn, s.writeRateLimit) } rd := io.Reader(c.Conn) if limit && s.readRateLimit != nil { rd = NewReadLimiter(c.Conn, s.readRateLimit) } name := fmt.Sprintf("%s-%s (%s)", c.Conn.LocalAddr(), c.Conn.RemoteAddr(), c.Type) protoConn := protocol.NewConnection(remoteID, rd, wr, s.model, name, deviceCfg.Compression) l.Infof("Established secure connection to %s at %s", remoteID, name) l.Debugf("cipher suite: %04X in lan: %t", c.Conn.ConnectionState().CipherSuite, !limit) s.model.AddConnection(model.Connection{ c.Conn, protoConn, c.Type, }) s.mut.Lock() s.connType[remoteID] = c.Type s.mut.Unlock() continue next } } if !s.cfg.IgnoredDevice(remoteID) { events.Default.Log(events.DeviceRejected, map[string]string{ "device": remoteID.String(), "address": c.Conn.RemoteAddr().String(), }) } l.Infof("Connection from %s (%s) with ignored device ID %s", c.Conn.RemoteAddr(), c.Type, remoteID) c.Conn.Close() } } func (s *connectionSvc) connect() { delay := time.Second for { nextDevice: for deviceID, deviceCfg := range s.cfg.Devices() { if deviceID == s.myID { continue } if s.model.IsPaused(deviceID) { continue } connected := s.model.ConnectedTo(deviceID) s.mut.RLock() ct, ok := s.connType[deviceID] relaysEnabled := s.relaysEnabled s.mut.RUnlock() if connected && ok && ct.IsDirect() { continue } var addrs []string var relays []discover.Relay for _, addr := range deviceCfg.Addresses { if addr == "dynamic" { if s.discoverer != nil { if t, r, err := s.discoverer.Lookup(deviceID); err == nil { addrs = append(addrs, t...) relays = append(relays, r...) } } } else { addrs = append(addrs, addr) } } for _, addr := range addrs { uri, err := url.Parse(addr) if err != nil { l.Infoln("Failed to parse connection url:", addr, err) continue } dialer, ok := dialers[uri.Scheme] if !ok { l.Infoln("Unknown address schema", uri) continue } l.Debugln("dial", deviceCfg.DeviceID, uri) conn, err := dialer(uri, s.tlsCfg) if err != nil { l.Debugln("dial failed", deviceCfg.DeviceID, uri, err) continue } if connected { s.model.Close(deviceID, fmt.Errorf("switching connections")) } s.conns <- model.IntermediateConnection{ conn, model.ConnectionTypeDirectDial, } continue nextDevice } // Only connect via relays if not already connected // Also, do not set lastRelayCheck time if we have no relays, // as otherwise when we do discover relays, we might have to // wait up to RelayReconnectIntervalM to connect again. // Also, do not try relays if we are explicitly told not to. if connected || len(relays) == 0 || !relaysEnabled { continue nextDevice } reconIntv := time.Duration(s.cfg.Options().RelayReconnectIntervalM) * time.Minute if last, ok := s.lastRelayCheck[deviceID]; ok && time.Since(last) < reconIntv { l.Debugln("Skipping connecting via relay to", deviceID, "last checked at", last) continue nextDevice } else { l.Debugln("Trying relay connections to", deviceID, relays) } s.lastRelayCheck[deviceID] = time.Now() for _, addr := range relays { uri, err := url.Parse(addr.URL) if err != nil { l.Infoln("Failed to parse relay connection url:", addr, err) continue } inv, err := client.GetInvitationFromRelay(uri, deviceID, s.tlsCfg.Certificates) if err != nil { l.Debugf("Failed to get invitation for %s from %s: %v", deviceID, uri, err) continue } else { l.Debugln("Succesfully retrieved relay invitation", inv, "from", uri) } conn, err := client.JoinSession(inv) if err != nil { l.Debugf("Failed to join relay session %s: %v", inv, err) continue } else { l.Debugln("Sucessfully joined relay session", inv) } var tc *tls.Conn if inv.ServerSocket { tc = tls.Server(conn, s.tlsCfg) } else { tc = tls.Client(conn, s.tlsCfg) } err = tc.Handshake() if err != nil { l.Infof("TLS handshake (BEP/relay %s): %v", inv, err) tc.Close() continue } s.conns <- model.IntermediateConnection{ tc, model.ConnectionTypeRelayDial, } continue nextDevice } } time.Sleep(delay) delay *= 2 if maxD := time.Duration(s.cfg.Options().ReconnectIntervalS) * time.Second; delay > maxD { delay = maxD } } } func (s *connectionSvc) acceptRelayConns() { for { conn := s.relaySvc.Accept() s.conns <- model.IntermediateConnection{ Conn: conn, Type: model.ConnectionTypeRelayAccept, } } } func (s *connectionSvc) shouldLimit(addr net.Addr) bool { if s.cfg.Options().LimitBandwidthInLan { return true } tcpaddr, ok := addr.(*net.TCPAddr) if !ok { return true } for _, lan := range s.lans { if lan.Contains(tcpaddr.IP) { return false } } return !tcpaddr.IP.IsLoopback() } func (s *connectionSvc) VerifyConfiguration(from, to config.Configuration) error { return nil } func (s *connectionSvc) CommitConfiguration(from, to config.Configuration) bool { s.mut.Lock() s.relaysEnabled = to.Options.RelaysEnabled s.mut.Unlock() // We require a restart if a device as been removed. newDevices := make(map[protocol.DeviceID]bool, len(to.Devices)) for _, dev := range to.Devices { newDevices[dev.DeviceID] = true } for _, dev := range from.Devices { if !newDevices[dev.DeviceID] { return false } } return true } // serviceFunc wraps a function to create a suture.Service without stop // functionality. type serviceFunc func() func (f serviceFunc) Serve() { f() } func (f serviceFunc) Stop() {}