// 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 relay import ( "crypto/tls" "encoding/json" "net/http" "net/url" "sort" "time" "github.com/syncthing/syncthing/lib/config" "github.com/syncthing/syncthing/lib/events" "github.com/syncthing/syncthing/lib/osutil" "github.com/syncthing/syncthing/lib/relay/client" "github.com/syncthing/syncthing/lib/relay/protocol" "github.com/syncthing/syncthing/lib/sync" "github.com/thejerf/suture" ) const ( eventBroadcasterCheckInterval = 10 * time.Second ) type Svc struct { *suture.Supervisor cfg *config.Wrapper tlsCfg *tls.Config tokens map[string]suture.ServiceToken clients map[string]*client.ProtocolClient mut sync.RWMutex invitations chan protocol.SessionInvitation conns chan *tls.Conn } func NewSvc(cfg *config.Wrapper, tlsCfg *tls.Config) *Svc { conns := make(chan *tls.Conn) svc := &Svc{ Supervisor: suture.New("Svc", suture.Spec{ Log: func(log string) { l.Debugln(log) }, FailureBackoff: 5 * time.Minute, FailureDecay: float64((10 * time.Minute) / time.Second), FailureThreshold: 5, }), cfg: cfg, tlsCfg: tlsCfg, tokens: make(map[string]suture.ServiceToken), clients: make(map[string]*client.ProtocolClient), mut: sync.NewRWMutex(), invitations: make(chan protocol.SessionInvitation), conns: conns, } rcfg := cfg.Raw() svc.CommitConfiguration(rcfg, rcfg) cfg.Subscribe(svc) receiver := &invitationReceiver{ tlsCfg: tlsCfg, conns: conns, invitations: svc.invitations, stop: make(chan struct{}), } eventBc := &eventBroadcaster{ svc: svc, } svc.Add(receiver) svc.Add(eventBc) return svc } func (s *Svc) VerifyConfiguration(from, to config.Configuration) error { for _, addr := range to.Options.RelayServers { _, err := url.Parse(addr) if err != nil { return err } } return nil } func (s *Svc) CommitConfiguration(from, to config.Configuration) bool { existing := make(map[string]*url.URL, len(to.Options.RelayServers)) for _, addr := range to.Options.RelayServers { uri, err := url.Parse(addr) if err != nil { l.Debugln("Failed to parse relay address", addr, err) continue } existing[uri.String()] = uri } // Query dynamic addresses, and pick the closest relay from the ones they provide. for key, uri := range existing { if uri.Scheme != "dynamic+http" && uri.Scheme != "dynamic+https" { continue } delete(existing, key) // Trim off the `dynamic+` prefix uri.Scheme = uri.Scheme[8:] l.Debugln("Looking up dynamic relays from", uri) data, err := http.Get(uri.String()) if err != nil { l.Debugln("Failed to lookup dynamic relays", err) continue } var ann dynamicAnnouncement err = json.NewDecoder(data.Body).Decode(&ann) data.Body.Close() if err != nil { l.Debugln("Failed to lookup dynamic relays", err) continue } var dynRelayAddrs []string for _, relayAnn := range ann.Relays { ruri, err := url.Parse(relayAnn.URL) if err != nil { l.Debugln("Failed to parse dynamic relay address", relayAnn.URL, err) continue } l.Debugln("Found", ruri, "via", uri) dynRelayAddrs = append(dynRelayAddrs, ruri.String()) } if len(dynRelayAddrs) > 0 { dynRelayAddrs = relayAddressesSortedByLatency(dynRelayAddrs) closestRelay := dynRelayAddrs[0] l.Debugln("Picking", closestRelay, "as closest dynamic relay from", uri) ruri, _ := url.Parse(closestRelay) existing[closestRelay] = ruri } else { l.Debugln("No dynamic relay found on", uri) } } s.mut.Lock() for key, uri := range existing { _, ok := s.tokens[key] if !ok { l.Debugln("Connecting to relay", uri) c := client.NewProtocolClient(uri, s.tlsCfg.Certificates, s.invitations) s.tokens[key] = s.Add(c) s.clients[key] = c } } for key, token := range s.tokens { _, ok := existing[key] if !ok { err := s.Remove(token) delete(s.tokens, key) delete(s.clients, key) l.Debugln("Disconnecting from relay", key, err) } } s.mut.Unlock() return true } type Status struct { URL string OK bool Latency int } // Relays return the list of relays that currently have an OK status. func (s *Svc) Relays() []string { if s == nil { // A nil client does not have a status, really. Yet we may be called // this way, for raisins... return nil } s.mut.RLock() relays := make([]string, 0, len(s.clients)) for uri := range s.clients { relays = append(relays, uri) } s.mut.RUnlock() sort.Strings(relays) return relays } // RelayStatus returns the latency and OK status for a given relay. func (s *Svc) RelayStatus(uri string) (time.Duration, bool) { if s == nil { // A nil client does not have a status, really. Yet we may be called // this way, for raisins... return time.Hour, false } s.mut.RLock() client, ok := s.clients[uri] s.mut.RUnlock() if !ok || !client.StatusOK() { return time.Hour, false } return client.Latency(), true } // Accept returns a new *tls.Conn. The connection is already handshaken. func (s *Svc) Accept() *tls.Conn { return <-s.conns } type invitationReceiver struct { invitations chan protocol.SessionInvitation tlsCfg *tls.Config conns chan<- *tls.Conn stop chan struct{} } func (r *invitationReceiver) Serve() { for { select { case inv := <-r.invitations: l.Debugln("Received relay invitation", inv) conn, err := client.JoinSession(inv) if err != nil { l.Debugf("Failed to join relay session %s: %v", inv, err) continue } var tc *tls.Conn if inv.ServerSocket { tc = tls.Server(conn, r.tlsCfg) } else { tc = tls.Client(conn, r.tlsCfg) } err = tc.Handshake() if err != nil { l.Infof("TLS handshake (BEP/relay %s): %v", inv, err) tc.Close() continue } r.conns <- tc case <-r.stop: return } } } func (r *invitationReceiver) Stop() { close(r.stop) } // The eventBroadcaster sends a RelayStateChanged event when the relay status // changes. We need this somewhat ugly polling mechanism as there's currently // no way to get the event feed directly from the relay lib. This may be // somethign to revisit later, possibly. type eventBroadcaster struct { svc *Svc stop chan struct{} } func (e *eventBroadcaster) Serve() { timer := time.NewTicker(eventBroadcasterCheckInterval) defer timer.Stop() var prevOKRelays []string for { select { case <-timer.C: curOKRelays := e.svc.Relays() changed := len(curOKRelays) != len(prevOKRelays) if !changed { for i := range curOKRelays { if curOKRelays[i] != prevOKRelays[i] { changed = true break } } } if changed { events.Default.Log(events.RelayStateChanged, map[string][]string{ "old": prevOKRelays, "new": curOKRelays, }) } prevOKRelays = curOKRelays case <-e.stop: return } } } func (e *eventBroadcaster) Stop() { close(e.stop) } // This is the announcement recieved from the relay server; // {"relays": [{"url": "relay://10.20.30.40:5060"}, ...]} type dynamicAnnouncement struct { Relays []struct { URL string } } // relayAddressesSortedByLatency adds local latency to the relay, and sorts them // by sum latency, and returns the addresses. func relayAddressesSortedByLatency(input []string) []string { relays := make(relayList, len(input)) for i, relay := range input { if latency, err := osutil.GetLatencyForURL(relay); err == nil { relays[i] = relayWithLatency{relay, int(latency / time.Millisecond)} } else { relays[i] = relayWithLatency{relay, int(time.Hour / time.Millisecond)} } } sort.Sort(relays) addresses := make([]string, len(relays)) for i, relay := range relays { addresses[i] = relay.relay } return addresses } type relayWithLatency struct { relay string latency int } type relayList []relayWithLatency func (l relayList) Len() int { return len(l) } func (l relayList) Less(a, b int) bool { return l[a].latency < l[b].latency } func (l relayList) Swap(a, b int) { l[a], l[b] = l[b], l[a] }