func callUp(peerId *govpn.PeerId) (string, error) { result, err := govpn.ScriptCall(confs[*peerId].Up, "") if err != nil { log.Println("Script", confs[*peerId].Up, "call failed", err) return "", err } sepIndex := bytes.Index(result, []byte{'\n'}) if sepIndex < 0 { sepIndex = len(result) } ifaceName := string(result[:sepIndex]) return ifaceName, nil }
func main() { flag.Parse() timeout := *timeoutP var err error log.SetFlags(log.Ldate | log.Lmicroseconds | log.Lshortfile) govpn.MTU = *mtu id, err := govpn.IDDecode(*IDRaw) if err != nil { log.Fatalln(err) } if *egdPath != "" { log.Println("Using", *egdPath, "EGD") govpn.EGDInit(*egdPath) } pub, priv := govpn.NewVerifier(id, govpn.StringFromFile(*keyPath)) conf := &govpn.PeerConf{ Id: id, Timeout: time.Second * time.Duration(timeout), NoiseEnable: *noisy, CPR: *cpr, DSAPub: pub, DSAPriv: priv, } govpn.PeersInitDummy(id, conf) var conn io.Writer var sink chan []byte var ready chan struct{} switch *proto { case "udp": conn, sink, ready = startUDP() case "tcp": if *proxyAddr != "" { conn, sink, ready = proxyTCP() } else { conn, sink, ready = startTCP() } default: log.Fatalln("Unknown protocol specified") } tap, ethSink, ethReady, _, err := govpn.TAPListen( *ifaceName, time.Second*time.Duration(timeout), *cpr, ) if err != nil { log.Fatalln("Can not listen on TAP interface:", err) } timeouts := 0 firstUpCall := true var peer *govpn.Peer var ethPkt []byte var pkt []byte knownPeers := govpn.KnownPeers(map[string]**govpn.Peer{*remoteAddr: &peer}) log.Println(govpn.VersionGet()) log.Println("Connected to", *proto, *remoteAddr) log.Println("Max MTU on TAP interface:", govpn.TAPMaxMTU()) if *stats != "" { log.Println("Stats are going to listen on", *stats) statsPort, err := net.Listen("tcp", *stats) if err != nil { log.Fatalln("Can not listen on stats port:", err) } go govpn.StatsProcessor(statsPort, &knownPeers) } termSignal := make(chan os.Signal, 1) signal.Notify(termSignal, os.Interrupt, os.Kill) log.Println("Starting handshake") handshake := govpn.HandshakeStart(*remoteAddr, conn, conf) MainCycle: for { if peer != nil && (peer.BytesIn+peer.BytesOut) > govpn.MaxBytesPerKey { peer.Zero() peer = nil handshake = govpn.HandshakeStart(*remoteAddr, conn, conf) log.Println("Rehandshaking") } select { case <-termSignal: break MainCycle case ethPkt = <-ethSink: if peer == nil { if len(ethPkt) > 0 { ethReady <- struct{}{} } continue } peer.EthProcess(ethPkt, ethReady) case pkt = <-sink: timeouts++ if timeouts >= timeout { break MainCycle } if pkt == nil { ready <- struct{}{} continue } if peer == nil { if govpn.IDsCache.Find(pkt) == nil { log.Println("Invalid identity in handshake packet") ready <- struct{}{} continue } if p := handshake.Client(pkt); p != nil { log.Println("Handshake completed") if firstUpCall { go govpn.ScriptCall(*upPath, *ifaceName) firstUpCall = false } peer = p handshake.Zero() handshake = nil } ready <- struct{}{} continue } if peer == nil { ready <- struct{}{} continue } if peer.PktProcess(pkt, tap, ready) { timeouts = 0 } } } govpn.ScriptCall(*downPath, *ifaceName) }
func main() { flag.Parse() timeout := time.Second * time.Duration(govpn.TimeoutDefault) log.SetFlags(log.Ldate | log.Lmicroseconds | log.Lshortfile) log.Println(govpn.VersionGet()) govpn.MTU = *mtu govpn.PeersInit(*peersPath) if *egdPath != "" { log.Println("Using", *egdPath, "EGD") govpn.EGDInit(*egdPath) } sink := make(chan Pkt) switch *proto { case "udp": startUDP(sink) case "tcp": startTCP(sink) case "all": startUDP(sink) startTCP(sink) default: log.Fatalln("Unknown protocol specified") } termSignal := make(chan os.Signal, 1) signal.Notify(termSignal, os.Interrupt, os.Kill) hsHeartbeat := time.Tick(timeout) go func() { <-hsHeartbeat }() var state *govpn.Handshake var peerState *PeerState var peer *govpn.Peer var exists bool states := make(map[string]*govpn.Handshake) peers := make(map[string]*PeerState) peerReadySink := make(chan PeerReadyEvent) knownPeers := govpn.KnownPeers(make(map[string]**govpn.Peer)) var peerReady PeerReadyEvent var pkt Pkt var ethEvent EthEvent var peerId *govpn.PeerId var peerConf *govpn.PeerConf var handshakeProcessForce bool ethSink := make(chan EthEvent) log.Println("Max MTU on TAP interface:", govpn.TAPMaxMTU()) if *stats != "" { log.Println("Stats are going to listen on", *stats) statsPort, err := net.Listen("tcp", *stats) if err != nil { log.Fatalln("Can not listen on stats port:", err) } go govpn.StatsProcessor(statsPort, &knownPeers) } if *proxy != "" { go proxyStart(sink) } log.Println("Server started") MainCycle: for { select { case <-termSignal: break MainCycle case <-hsHeartbeat: now := time.Now() for addr, hs := range states { if hs.LastPing.Add(timeout).Before(now) { log.Println("Deleting handshake state", addr) hs.Zero() delete(states, addr) } } for addr, state := range peers { if state.peer.LastPing.Add(timeout).Before(now) { log.Println("Deleting peer", state.peer) delete(peers, addr) delete(knownPeers, addr) downPath := path.Join( govpn.PeersPath, state.peer.Id.String(), "down.sh", ) go govpn.ScriptCall(downPath, state.tap.Name) state.terminate <- struct{}{} state.peer.Zero() } } case peerReady = <-peerReadySink: for addr, state := range peers { if state.tap.Name != peerReady.iface { continue } delete(peers, addr) delete(knownPeers, addr) state.terminate <- struct{}{} state.peer.Zero() break } state := NewPeerState(peerReady.peer, peerReady.iface) if state == nil { continue } peers[peerReady.peer.Addr] = state knownPeers[peerReady.peer.Addr] = &peerReady.peer states[peerReady.peer.Addr].Zero() delete(states, peerReady.peer.Addr) log.Println("Registered interface", peerReady.iface, "with peer", peer) go func(state *PeerState) { for data := range state.sink { ethSink <- EthEvent{ peer: state.peer, data: data, ready: state.ready, } } }(state) case ethEvent = <-ethSink: if s, exists := peers[ethEvent.peer.Addr]; !exists || s.peer != ethEvent.peer { continue } ethEvent.peer.EthProcess(ethEvent.data, ethEvent.ready) case pkt = <-sink: if pkt.data == nil { pkt.ready <- struct{}{} continue } handshakeProcessForce = false HandshakeProcess: if _, exists = peers[pkt.addr]; handshakeProcessForce || !exists { peerId = govpn.IDsCache.Find(pkt.data) if peerId == nil { log.Println("Unknown identity from", pkt.addr) pkt.ready <- struct{}{} continue } peerConf = peerId.Conf() if peerConf == nil { log.Println("Can not get peer configuration", peerId.String()) pkt.ready <- struct{}{} continue } state, exists = states[pkt.addr] if !exists { state = govpn.HandshakeNew(pkt.addr, pkt.conn, peerConf) states[pkt.addr] = state } peer = state.Server(pkt.data) if peer != nil { log.Println("Peer handshake finished", peer) if _, exists = peers[pkt.addr]; exists { go func() { peerReadySink <- PeerReadyEvent{ peer, peers[pkt.addr].tap.Name, } }() } else { go func() { upPath := path.Join(govpn.PeersPath, peer.Id.String(), "up.sh") result, err := govpn.ScriptCall(upPath, "") if err != nil { return } sepIndex := bytes.Index(result, []byte{'\n'}) if sepIndex < 0 { sepIndex = len(result) } ifaceName := string(result[:sepIndex]) peerReadySink <- PeerReadyEvent{peer, ifaceName} }() } } if !handshakeProcessForce { pkt.ready <- struct{}{} } continue } peerState, exists = peers[pkt.addr] if !exists { pkt.ready <- struct{}{} continue } // If it fails during processing, then try to work with it // as with handshake packet if !peerState.peer.PktProcess(pkt.data, peerState.tap, pkt.ready) { handshakeProcessForce = true goto HandshakeProcess } } } }
func handleTCP(conn *net.TCPConn, timeouted, rehandshaking, termination chan struct{}) { hs := govpn.HandshakeStart(*remoteAddr, conn, conf) buf := make([]byte, govpn.MTU) var n int var err error var prev int var peer *govpn.Peer var terminator chan struct{} HandshakeCycle: for { select { case <-termination: break HandshakeCycle default: } if prev == govpn.MTU { log.Println("Timeouted waiting for the packet") timeouted <- struct{}{} break HandshakeCycle } conn.SetReadDeadline(time.Now().Add(time.Duration(timeout) * time.Second)) n, err = conn.Read(buf[prev:]) if err != nil { log.Println("Connection timeouted") timeouted <- struct{}{} break HandshakeCycle } prev += n peerId := idsCache.Find(buf[:prev]) if peerId == nil { continue } peer = hs.Client(buf[:prev]) prev = 0 if peer == nil { continue } log.Println("Handshake completed") knownPeers = govpn.KnownPeers(map[string]**govpn.Peer{*remoteAddr: &peer}) if firstUpCall { go govpn.ScriptCall(*upPath, *ifaceName) firstUpCall = false } hs.Zero() terminator = make(chan struct{}) go func() { heartbeat := time.NewTicker(peer.Timeout) var data []byte Processor: for { select { case <-heartbeat.C: peer.EthProcess(nil) case <-terminator: break Processor case data = <-tap.Sink: peer.EthProcess(data) } } heartbeat.Stop() peer.Zero() }() break HandshakeCycle } if hs != nil { hs.Zero() } if peer == nil { return } nonceExpectation := make([]byte, govpn.NonceSize) peer.NonceExpectation(nonceExpectation) prev = 0 var i int TransportCycle: for { select { case <-termination: break TransportCycle default: } if prev == govpn.MTU { log.Println("Timeouted waiting for the packet") timeouted <- struct{}{} break TransportCycle } conn.SetReadDeadline(time.Now().Add(time.Duration(timeout) * time.Second)) n, err = conn.Read(buf[prev:]) if err != nil { log.Println("Connection timeouted") timeouted <- struct{}{} break TransportCycle } prev += n CheckMore: if prev < govpn.MinPktLength { continue } i = bytes.Index(buf[:prev], nonceExpectation) if i == -1 { continue } if !peer.PktProcess(buf[:i+govpn.NonceSize], tap, false) { log.Println("Unauthenticated packet, dropping connection") timeouted <- struct{}{} break TransportCycle } if atomic.LoadInt64(&peer.BytesIn)+atomic.LoadInt64(&peer.BytesOut) > govpn.MaxBytesPerKey { log.Println("Need rehandshake") rehandshaking <- struct{}{} break TransportCycle } peer.NonceExpectation(nonceExpectation) copy(buf, buf[i+govpn.NonceSize:prev]) prev = prev - i - govpn.NonceSize goto CheckMore } if terminator != nil { terminator <- struct{}{} } peer.Zero() conn.Close() }
func main() { flag.Parse() timeout = *timeoutP var err error log.SetFlags(log.Ldate | log.Lmicroseconds | log.Lshortfile) govpn.MTU = *mtu if *egdPath != "" { log.Println("Using", *egdPath, "EGD") govpn.EGDInit(*egdPath) } verifier, err := govpn.VerifierFromString(*verifierRaw) if err != nil { log.Fatalln(err) } priv := verifier.PasswordApply(govpn.StringFromFile(*keyPath)) conf = &govpn.PeerConf{ Id: verifier.Id, Timeout: time.Second * time.Duration(timeout), Noise: *noisy, CPR: *cpr, Verifier: verifier, DSAPriv: priv, } idsCache = govpn.NewCipherCache([]govpn.PeerId{*verifier.Id}) log.Println(govpn.VersionGet()) tap, err = govpn.TAPListen(*ifaceName) if err != nil { log.Fatalln("Can not listen on TAP interface:", err) } log.Println("Max MTU on TAP interface:", govpn.TAPMaxMTU()) if *stats != "" { log.Println("Stats are going to listen on", *stats) statsPort, err := net.Listen("tcp", *stats) if err != nil { log.Fatalln("Can not listen on stats port:", err) } go govpn.StatsProcessor(statsPort, &knownPeers) } termSignal := make(chan os.Signal, 1) signal.Notify(termSignal, os.Interrupt, os.Kill) MainCycle: for { timeouted := make(chan struct{}) rehandshaking := make(chan struct{}) termination := make(chan struct{}) if *proxyAddr != "" { *proto = "tcp" } switch *proto { case "udp": go startUDP(timeouted, rehandshaking, termination) case "tcp": if *proxyAddr != "" { go proxyTCP(timeouted, rehandshaking, termination) } else { go startTCP(timeouted, rehandshaking, termination) } default: log.Fatalln("Unknown protocol specified") } select { case <-termSignal: log.Fatalln("Finishing") termination <- struct{}{} break MainCycle case <-timeouted: break MainCycle case <-rehandshaking: } close(timeouted) close(rehandshaking) close(termination) } govpn.ScriptCall(*downPath, *ifaceName) }
func main() { flag.Parse() timeout := time.Second * time.Duration(govpn.TimeoutDefault) log.SetFlags(log.Ldate | log.Lmicroseconds | log.Lshortfile) log.Println(govpn.VersionGet()) govpn.MTU = *mtu confInit() knownPeers = govpn.KnownPeers(make(map[string]**govpn.Peer)) if *egdPath != "" { log.Println("Using", *egdPath, "EGD") govpn.EGDInit(*egdPath) } switch *proto { case "udp": startUDP() case "tcp": startTCP() case "all": startUDP() startTCP() default: log.Fatalln("Unknown protocol specified") } termSignal := make(chan os.Signal, 1) signal.Notify(termSignal, os.Interrupt, os.Kill) hsHeartbeat := time.Tick(timeout) go func() { <-hsHeartbeat }() log.Println("Max MTU on TAP interface:", govpn.TAPMaxMTU()) if *stats != "" { log.Println("Stats are going to listen on", *stats) statsPort, err := net.Listen("tcp", *stats) if err != nil { log.Fatalln("Can not listen on stats port:", err) } go govpn.StatsProcessor(statsPort, &knownPeers) } if *proxy != "" { go proxyStart() } log.Println("Server started") var needsDeletion bool MainCycle: for { select { case <-termSignal: break MainCycle case <-hsHeartbeat: now := time.Now() hsLock.Lock() for addr, hs := range handshakes { if hs.LastPing.Add(timeout).Before(now) { log.Println("Deleting handshake state", addr) hs.Zero() delete(handshakes, addr) } } peersLock.Lock() peersByIdLock.Lock() kpLock.Lock() for addr, ps := range peers { ps.peer.BusyR.Lock() needsDeletion = ps.peer.LastPing.Add(timeout).Before(now) ps.peer.BusyR.Unlock() if needsDeletion { log.Println("Deleting peer", ps.peer) delete(peers, addr) delete(knownPeers, addr) delete(peersById, *ps.peer.Id) go govpn.ScriptCall( confs[*ps.peer.Id].Down, ps.tap.Name, ) ps.terminator <- struct{}{} } } hsLock.Unlock() peersLock.Unlock() peersByIdLock.Unlock() kpLock.Unlock() } } }
func startUDP(timeouted, rehandshaking, termination chan struct{}) { remote, err := net.ResolveUDPAddr("udp", *remoteAddr) if err != nil { log.Fatalln("Can not resolve remote address:", err) } conn, err := net.DialUDP("udp", nil, remote) if err != nil { log.Fatalln("Can not listen on UDP:", err) } log.Println("Connected to UDP:" + *remoteAddr) hs := govpn.HandshakeStart(*remoteAddr, conn, conf) buf := make([]byte, govpn.MTU) var n int var timeouts int var peer *govpn.Peer var terminator chan struct{} MainCycle: for { select { case <-termination: break MainCycle default: } conn.SetReadDeadline(time.Now().Add(time.Second)) n, err = conn.Read(buf) if timeouts == timeout { log.Println("Timeouted") timeouted <- struct{}{} break } if err != nil { timeouts++ continue } if peer != nil { if peer.PktProcess(buf[:n], tap, true) { timeouts = 0 } else { log.Println("Unauthenticated packet") timeouts++ } if atomic.LoadInt64(&peer.BytesIn)+atomic.LoadInt64(&peer.BytesOut) > govpn.MaxBytesPerKey { log.Println("Need rehandshake") rehandshaking <- struct{}{} break MainCycle } continue } if idsCache.Find(buf[:n]) == nil { log.Println("Invalid identity in handshake packet") continue } timeouts = 0 peer = hs.Client(buf[:n]) if peer == nil { continue } log.Println("Handshake completed") knownPeers = govpn.KnownPeers(map[string]**govpn.Peer{*remoteAddr: &peer}) if firstUpCall { go govpn.ScriptCall(*upPath, *ifaceName) firstUpCall = false } hs.Zero() terminator = make(chan struct{}) go func() { heartbeat := time.NewTicker(peer.Timeout) var data []byte Processor: for { select { case <-heartbeat.C: peer.EthProcess(nil) case <-terminator: break Processor case data = <-tap.Sink: peer.EthProcess(data) } } heartbeat.Stop() peer.Zero() }() } if terminator != nil { terminator <- struct{}{} } if hs != nil { hs.Zero() } conn.Close() }