package nebula import ( "context" "encoding/binary" "errors" "fmt" "net" "net/netip" "sync" "sync/atomic" "time" "github.com/rcrowley/go-metrics" "github.com/sirupsen/logrus" "github.com/slackhq/nebula/cidr" "github.com/slackhq/nebula/config" "github.com/slackhq/nebula/header" "github.com/slackhq/nebula/iputil" "github.com/slackhq/nebula/udp" "github.com/slackhq/nebula/util" ) //TODO: if a lighthouse doesn't have an answer, clients AGGRESSIVELY REQUERY.. why? handshake manager and/or getOrHandshake? //TODO: nodes are roaming lighthouses, this is bad. How are they learning? var ErrHostNotKnown = errors.New("host not known") type netIpAndPort struct { ip net.IP port uint16 } type LightHouse struct { //TODO: We need a timer wheel to kick out vpnIps that haven't reported in a long time sync.RWMutex //Because we concurrently read and write to our maps ctx context.Context amLighthouse bool myVpnIp iputil.VpnIp myVpnZeros iputil.VpnIp myVpnNet *net.IPNet punchConn udp.Conn punchy *Punchy // Local cache of answers from light houses // map of vpn Ip to answers addrMap map[iputil.VpnIp]*RemoteList // filters remote addresses allowed for each host // - When we are a lighthouse, this filters what addresses we store and // respond with. // - When we are not a lighthouse, this filters which addresses we accept // from lighthouses. remoteAllowList atomic.Pointer[RemoteAllowList] // filters local addresses that we advertise to lighthouses localAllowList atomic.Pointer[LocalAllowList] // used to trigger the HandshakeManager when we receive HostQueryReply handshakeTrigger chan<- iputil.VpnIp // staticList exists to avoid having a bool in each addrMap entry // since static should be rare staticList atomic.Pointer[map[iputil.VpnIp]struct{}] lighthouses atomic.Pointer[map[iputil.VpnIp]struct{}] interval atomic.Int64 updateCancel context.CancelFunc ifce EncWriter nebulaPort uint32 // 32 bits because protobuf does not have a uint16 advertiseAddrs atomic.Pointer[[]netIpAndPort] // IP's of relays that can be used by peers to access me relaysForMe atomic.Pointer[[]iputil.VpnIp] queryChan chan iputil.VpnIp calculatedRemotes atomic.Pointer[cidr.Tree4[[]*calculatedRemote]] // Maps VpnIp to []*calculatedRemote metrics *MessageMetrics metricHolepunchTx metrics.Counter l *logrus.Logger } // NewLightHouseFromConfig will build a Lighthouse struct from the values provided in the config object // addrMap should be nil unless this is during a config reload func NewLightHouseFromConfig(ctx context.Context, l *logrus.Logger, c *config.C, myVpnNet *net.IPNet, pc udp.Conn, p *Punchy) (*LightHouse, error) { amLighthouse := c.GetBool("lighthouse.am_lighthouse", false) nebulaPort := uint32(c.GetInt("listen.port", 0)) if amLighthouse && nebulaPort == 0 { return nil, util.NewContextualError("lighthouse.am_lighthouse enabled on node but no port number is set in config", nil, nil) } // If port is dynamic, discover it if nebulaPort == 0 && pc != nil { uPort, err := pc.LocalAddr() if err != nil { return nil, util.NewContextualError("Failed to get listening port", nil, err) } nebulaPort = uint32(uPort.Port) } ones, _ := myVpnNet.Mask.Size() h := LightHouse{ ctx: ctx, amLighthouse: amLighthouse, myVpnIp: iputil.Ip2VpnIp(myVpnNet.IP), myVpnZeros: iputil.VpnIp(32 - ones), myVpnNet: myVpnNet, addrMap: make(map[iputil.VpnIp]*RemoteList), nebulaPort: nebulaPort, punchConn: pc, punchy: p, queryChan: make(chan iputil.VpnIp, c.GetUint32("handshakes.query_buffer", 64)), l: l, } lighthouses := make(map[iputil.VpnIp]struct{}) h.lighthouses.Store(&lighthouses) staticList := make(map[iputil.VpnIp]struct{}) h.staticList.Store(&staticList) if c.GetBool("stats.lighthouse_metrics", false) { h.metrics = newLighthouseMetrics() h.metricHolepunchTx = metrics.GetOrRegisterCounter("messages.tx.holepunch", nil) } else { h.metricHolepunchTx = metrics.NilCounter{} } err := h.reload(c, true) if err != nil { return nil, err } c.RegisterReloadCallback(func(c *config.C) { err := h.reload(c, false) switch v := err.(type) { case *util.ContextualError: v.Log(l) case error: l.WithError(err).Error("failed to reload lighthouse") } }) h.startQueryWorker() return &h, nil } func (lh *LightHouse) GetStaticHostList() map[iputil.VpnIp]struct{} { return *lh.staticList.Load() } func (lh *LightHouse) GetLighthouses() map[iputil.VpnIp]struct{} { return *lh.lighthouses.Load() } func (lh *LightHouse) GetRemoteAllowList() *RemoteAllowList { return lh.remoteAllowList.Load() } func (lh *LightHouse) GetLocalAllowList() *LocalAllowList { return lh.localAllowList.Load() } func (lh *LightHouse) GetAdvertiseAddrs() []netIpAndPort { return *lh.advertiseAddrs.Load() } func (lh *LightHouse) GetRelaysForMe() []iputil.VpnIp { return *lh.relaysForMe.Load() } func (lh *LightHouse) getCalculatedRemotes() *cidr.Tree4[[]*calculatedRemote] { return lh.calculatedRemotes.Load() } func (lh *LightHouse) GetUpdateInterval() int64 { return lh.interval.Load() } func (lh *LightHouse) reload(c *config.C, initial bool) error { if initial || c.HasChanged("lighthouse.advertise_addrs") { rawAdvAddrs := c.GetStringSlice("lighthouse.advertise_addrs", []string{}) advAddrs := make([]netIpAndPort, 0) for i, rawAddr := range rawAdvAddrs { fIp, fPort, err := udp.ParseIPAndPort(rawAddr) if err != nil { return util.NewContextualError("Unable to parse lighthouse.advertise_addrs entry", m{"addr": rawAddr, "entry": i + 1}, err) } if fPort == 0 { fPort = uint16(lh.nebulaPort) } if ip4 := fIp.To4(); ip4 != nil && lh.myVpnNet.Contains(fIp) { lh.l.WithField("addr", rawAddr).WithField("entry", i+1). Warn("Ignoring lighthouse.advertise_addrs report because it is within the nebula network range") continue } advAddrs = append(advAddrs, netIpAndPort{ip: fIp, port: fPort}) } lh.advertiseAddrs.Store(&advAddrs) if !initial { lh.l.Info("lighthouse.advertise_addrs has changed") } } if initial || c.HasChanged("lighthouse.interval") { lh.interval.Store(int64(c.GetInt("lighthouse.interval", 10))) if !initial { lh.l.Infof("lighthouse.interval changed to %v", lh.interval.Load()) if lh.updateCancel != nil { // May not always have a running routine lh.updateCancel() } lh.StartUpdateWorker() } } if initial || c.HasChanged("lighthouse.remote_allow_list") || c.HasChanged("lighthouse.remote_allow_ranges") { ral, err := NewRemoteAllowListFromConfig(c, "lighthouse.remote_allow_list", "lighthouse.remote_allow_ranges") if err != nil { return util.NewContextualError("Invalid lighthouse.remote_allow_list", nil, err) } lh.remoteAllowList.Store(ral) if !initial { //TODO: a diff will be annoyingly difficult lh.l.Info("lighthouse.remote_allow_list and/or lighthouse.remote_allow_ranges has changed") } } if initial || c.HasChanged("lighthouse.local_allow_list") { lal, err := NewLocalAllowListFromConfig(c, "lighthouse.local_allow_list") if err != nil { return util.NewContextualError("Invalid lighthouse.local_allow_list", nil, err) } lh.localAllowList.Store(lal) if !initial { //TODO: a diff will be annoyingly difficult lh.l.Info("lighthouse.local_allow_list has changed") } } if initial || c.HasChanged("lighthouse.calculated_remotes") { cr, err := NewCalculatedRemotesFromConfig(c, "lighthouse.calculated_remotes") if err != nil { return util.NewContextualError("Invalid lighthouse.calculated_remotes", nil, err) } lh.calculatedRemotes.Store(cr) if !initial { //TODO: a diff will be annoyingly difficult lh.l.Info("lighthouse.calculated_remotes has changed") } } //NOTE: many things will get much simpler when we combine static_host_map and lighthouse.hosts in config if initial || c.HasChanged("static_host_map") || c.HasChanged("static_map.cadence") || c.HasChanged("static_map.network") || c.HasChanged("static_map.lookup_timeout") { // Clean up. Entries still in the static_host_map will be re-built. // Entries no longer present must have their (possible) background DNS goroutines stopped. if existingStaticList := lh.staticList.Load(); existingStaticList != nil { lh.RLock() for staticVpnIp := range *existingStaticList { if am, ok := lh.addrMap[staticVpnIp]; ok && am != nil { am.hr.Cancel() } } lh.RUnlock() } // Build a new list based on current config. staticList := make(map[iputil.VpnIp]struct{}) err := lh.loadStaticMap(c, lh.myVpnNet, staticList) if err != nil { return err } lh.staticList.Store(&staticList) if !initial { //TODO: we should remove any remote list entries for static hosts that were removed/modified? if c.HasChanged("static_host_map") { lh.l.Info("static_host_map has changed") } if c.HasChanged("static_map.cadence") { lh.l.Info("static_map.cadence has changed") } if c.HasChanged("static_map.network") { lh.l.Info("static_map.network has changed") } if c.HasChanged("static_map.lookup_timeout") { lh.l.Info("static_map.lookup_timeout has changed") } } } if initial || c.HasChanged("lighthouse.hosts") { lhMap := make(map[iputil.VpnIp]struct{}) err := lh.parseLighthouses(c, lh.myVpnNet, lhMap) if err != nil { return err } lh.lighthouses.Store(&lhMap) if !initial { //NOTE: we are not tearing down existing lighthouse connections because they might be used for non lighthouse traffic lh.l.Info("lighthouse.hosts has changed") } } if initial || c.HasChanged("relay.relays") { switch c.GetBool("relay.am_relay", false) { case true: // Relays aren't allowed to specify other relays if len(c.GetStringSlice("relay.relays", nil)) > 0 { lh.l.Info("Ignoring relays from config because am_relay is true") } relaysForMe := []iputil.VpnIp{} lh.relaysForMe.Store(&relaysForMe) case false: relaysForMe := []iputil.VpnIp{} for _, v := range c.GetStringSlice("relay.relays", nil) { lh.l.WithField("relay", v).Info("Read relay from config") configRIP := net.ParseIP(v) if configRIP != nil { relaysForMe = append(relaysForMe, iputil.Ip2VpnIp(configRIP)) } } lh.relaysForMe.Store(&relaysForMe) } } return nil } func (lh *LightHouse) parseLighthouses(c *config.C, tunCidr *net.IPNet, lhMap map[iputil.VpnIp]struct{}) error { lhs := c.GetStringSlice("lighthouse.hosts", []string{}) if lh.amLighthouse && len(lhs) != 0 { lh.l.Warn("lighthouse.am_lighthouse enabled on node but upstream lighthouses exist in config") } for i, host := range lhs { ip := net.ParseIP(host) if ip == nil { return util.NewContextualError("Unable to parse lighthouse host entry", m{"host": host, "entry": i + 1}, nil) } if !tunCidr.Contains(ip) { return util.NewContextualError("lighthouse host is not in our subnet, invalid", m{"vpnIp": ip, "network": tunCidr.String()}, nil) } lhMap[iputil.Ip2VpnIp(ip)] = struct{}{} } if !lh.amLighthouse && len(lhMap) == 0 { lh.l.Warn("No lighthouse.hosts configured, this host will only be able to initiate tunnels with static_host_map entries") } staticList := lh.GetStaticHostList() for lhIP, _ := range lhMap { if _, ok := staticList[lhIP]; !ok { return fmt.Errorf("lighthouse %s does not have a static_host_map entry", lhIP) } } return nil } func getStaticMapCadence(c *config.C) (time.Duration, error) { cadence := c.GetString("static_map.cadence", "30s") d, err := time.ParseDuration(cadence) if err != nil { return 0, err } return d, nil } func getStaticMapLookupTimeout(c *config.C) (time.Duration, error) { lookupTimeout := c.GetString("static_map.lookup_timeout", "250ms") d, err := time.ParseDuration(lookupTimeout) if err != nil { return 0, err } return d, nil } func getStaticMapNetwork(c *config.C) (string, error) { network := c.GetString("static_map.network", "ip4") if network != "ip" && network != "ip4" && network != "ip6" { return "", fmt.Errorf("static_map.network must be one of ip, ip4, or ip6") } return network, nil } func (lh *LightHouse) loadStaticMap(c *config.C, tunCidr *net.IPNet, staticList map[iputil.VpnIp]struct{}) error { d, err := getStaticMapCadence(c) if err != nil { return err } network, err := getStaticMapNetwork(c) if err != nil { return err } lookup_timeout, err := getStaticMapLookupTimeout(c) if err != nil { return err } shm := c.GetMap("static_host_map", map[interface{}]interface{}{}) i := 0 for k, v := range shm { rip := net.ParseIP(fmt.Sprintf("%v", k)) if rip == nil { return util.NewContextualError("Unable to parse static_host_map entry", m{"host": k, "entry": i + 1}, nil) } if !tunCidr.Contains(rip) { return util.NewContextualError("static_host_map key is not in our subnet, invalid", m{"vpnIp": rip, "network": tunCidr.String(), "entry": i + 1}, nil) } vpnIp := iputil.Ip2VpnIp(rip) vals, ok := v.([]interface{}) if !ok { vals = []interface{}{v} } remoteAddrs := []string{} for _, v := range vals { remoteAddrs = append(remoteAddrs, fmt.Sprintf("%v", v)) } err := lh.addStaticRemotes(i, d, network, lookup_timeout, vpnIp, remoteAddrs, staticList) if err != nil { return err } i++ } return nil } func (lh *LightHouse) Query(ip iputil.VpnIp) *RemoteList { if !lh.IsLighthouseIP(ip) { lh.QueryServer(ip) } lh.RLock() if v, ok := lh.addrMap[ip]; ok { lh.RUnlock() return v } lh.RUnlock() return nil } // QueryServer is asynchronous so no reply should be expected func (lh *LightHouse) QueryServer(ip iputil.VpnIp) { // Don't put lighthouse ips in the query channel because we can't query lighthouses about lighthouses if lh.amLighthouse || lh.IsLighthouseIP(ip) { return } lh.queryChan <- ip } func (lh *LightHouse) QueryCache(ip iputil.VpnIp) *RemoteList { lh.RLock() if v, ok := lh.addrMap[ip]; ok { lh.RUnlock() return v } lh.RUnlock() lh.Lock() defer lh.Unlock() // Add an entry if we don't already have one return lh.unlockedGetRemoteList(ip) } // queryAndPrepMessage is a lock helper on RemoteList, assisting the caller to build a lighthouse message containing // details from the remote list. It looks for a hit in the addrMap and a hit in the RemoteList under the owner vpnIp // If one is found then f() is called with proper locking, f() must return result of n.MarshalTo() func (lh *LightHouse) queryAndPrepMessage(vpnIp iputil.VpnIp, f func(*cache) (int, error)) (bool, int, error) { lh.RLock() // Do we have an entry in the main cache? if v, ok := lh.addrMap[vpnIp]; ok { // Swap lh lock for remote list lock v.RLock() defer v.RUnlock() lh.RUnlock() // vpnIp should also be the owner here since we are a lighthouse. c := v.cache[vpnIp] // Make sure we have if c != nil { n, err := f(c) return true, n, err } return false, 0, nil } lh.RUnlock() return false, 0, nil } func (lh *LightHouse) DeleteVpnIp(vpnIp iputil.VpnIp) { // First we check the static mapping // and do nothing if it is there if _, ok := lh.GetStaticHostList()[vpnIp]; ok { return } lh.Lock() //l.Debugln(lh.addrMap) delete(lh.addrMap, vpnIp) if lh.l.Level >= logrus.DebugLevel { lh.l.Debugf("deleting %s from lighthouse.", vpnIp) } lh.Unlock() } // AddStaticRemote adds a static host entry for vpnIp as ourselves as the owner // We are the owner because we don't want a lighthouse server to advertise for static hosts it was configured with // And we don't want a lighthouse query reply to interfere with our learned cache if we are a client // NOTE: this function should not interact with any hot path objects, like lh.staticList, the caller should handle it func (lh *LightHouse) addStaticRemotes(i int, d time.Duration, network string, timeout time.Duration, vpnIp iputil.VpnIp, toAddrs []string, staticList map[iputil.VpnIp]struct{}) error { lh.Lock() am := lh.unlockedGetRemoteList(vpnIp) am.Lock() defer am.Unlock() ctx := lh.ctx lh.Unlock() hr, err := NewHostnameResults(ctx, lh.l, d, network, timeout, toAddrs, func() { // This callback runs whenever the DNS hostname resolver finds a different set of IP's // in its resolution for hostnames. am.Lock() defer am.Unlock() am.shouldRebuild = true }) if err != nil { return util.NewContextualError("Static host address could not be parsed", m{"vpnIp": vpnIp, "entry": i + 1}, err) } am.unlockedSetHostnamesResults(hr) for _, addrPort := range hr.GetIPs() { switch { case addrPort.Addr().Is4(): to := NewIp4AndPortFromNetIP(addrPort.Addr(), addrPort.Port()) if !lh.unlockedShouldAddV4(vpnIp, to) { continue } am.unlockedPrependV4(lh.myVpnIp, to) case addrPort.Addr().Is6(): to := NewIp6AndPortFromNetIP(addrPort.Addr(), addrPort.Port()) if !lh.unlockedShouldAddV6(vpnIp, to) { continue } am.unlockedPrependV6(lh.myVpnIp, to) } } // Mark it as static in the caller provided map staticList[vpnIp] = struct{}{} return nil } // addCalculatedRemotes adds any calculated remotes based on the // lighthouse.calculated_remotes configuration. It returns true if any // calculated remotes were added func (lh *LightHouse) addCalculatedRemotes(vpnIp iputil.VpnIp) bool { tree := lh.getCalculatedRemotes() if tree == nil { return false } ok, calculatedRemotes := tree.MostSpecificContains(vpnIp) if !ok { return false } var calculated []*Ip4AndPort for _, cr := range calculatedRemotes { c := cr.Apply(vpnIp) if c != nil { calculated = append(calculated, c) } } lh.Lock() am := lh.unlockedGetRemoteList(vpnIp) am.Lock() defer am.Unlock() lh.Unlock() am.unlockedSetV4(lh.myVpnIp, vpnIp, calculated, lh.unlockedShouldAddV4) return len(calculated) > 0 } // unlockedGetRemoteList assumes you have the lh lock func (lh *LightHouse) unlockedGetRemoteList(vpnIp iputil.VpnIp) *RemoteList { am, ok := lh.addrMap[vpnIp] if !ok { am = NewRemoteList(func(a netip.Addr) bool { return lh.shouldAdd(vpnIp, a) }) lh.addrMap[vpnIp] = am } return am } func (lh *LightHouse) shouldAdd(vpnIp iputil.VpnIp, to netip.Addr) bool { switch { case to.Is4(): ipBytes := to.As4() ip := iputil.Ip2VpnIp(ipBytes[:]) allow := lh.GetRemoteAllowList().AllowIpV4(vpnIp, ip) if lh.l.Level >= logrus.TraceLevel { lh.l.WithField("remoteIp", vpnIp).WithField("allow", allow).Trace("remoteAllowList.Allow") } if !allow || ipMaskContains(lh.myVpnIp, lh.myVpnZeros, ip) { return false } case to.Is6(): ipBytes := to.As16() hi := binary.BigEndian.Uint64(ipBytes[:8]) lo := binary.BigEndian.Uint64(ipBytes[8:]) allow := lh.GetRemoteAllowList().AllowIpV6(vpnIp, hi, lo) if lh.l.Level >= logrus.TraceLevel { lh.l.WithField("remoteIp", to).WithField("allow", allow).Trace("remoteAllowList.Allow") } // We don't check our vpn network here because nebula does not support ipv6 on the inside if !allow { return false } } return true } // unlockedShouldAddV4 checks if to is allowed by our allow list func (lh *LightHouse) unlockedShouldAddV4(vpnIp iputil.VpnIp, to *Ip4AndPort) bool { allow := lh.GetRemoteAllowList().AllowIpV4(vpnIp, iputil.VpnIp(to.Ip)) if lh.l.Level >= logrus.TraceLevel { lh.l.WithField("remoteIp", vpnIp).WithField("allow", allow).Trace("remoteAllowList.Allow") } if !allow || ipMaskContains(lh.myVpnIp, lh.myVpnZeros, iputil.VpnIp(to.Ip)) { return false } return true } // unlockedShouldAddV6 checks if to is allowed by our allow list func (lh *LightHouse) unlockedShouldAddV6(vpnIp iputil.VpnIp, to *Ip6AndPort) bool { allow := lh.GetRemoteAllowList().AllowIpV6(vpnIp, to.Hi, to.Lo) if lh.l.Level >= logrus.TraceLevel { lh.l.WithField("remoteIp", lhIp6ToIp(to)).WithField("allow", allow).Trace("remoteAllowList.Allow") } // We don't check our vpn network here because nebula does not support ipv6 on the inside if !allow { return false } return true } func lhIp6ToIp(v *Ip6AndPort) net.IP { ip := make(net.IP, 16) binary.BigEndian.PutUint64(ip[:8], v.Hi) binary.BigEndian.PutUint64(ip[8:], v.Lo) return ip } func (lh *LightHouse) IsLighthouseIP(vpnIp iputil.VpnIp) bool { if _, ok := lh.GetLighthouses()[vpnIp]; ok { return true } return false } func NewLhQueryByInt(VpnIp iputil.VpnIp) *NebulaMeta { return &NebulaMeta{ Type: NebulaMeta_HostQuery, Details: &NebulaMetaDetails{ VpnIp: uint32(VpnIp), }, } } func NewIp4AndPort(ip net.IP, port uint32) *Ip4AndPort { ipp := Ip4AndPort{Port: port} ipp.Ip = uint32(iputil.Ip2VpnIp(ip)) return &ipp } func NewIp4AndPortFromNetIP(ip netip.Addr, port uint16) *Ip4AndPort { v4Addr := ip.As4() return &Ip4AndPort{ Ip: binary.BigEndian.Uint32(v4Addr[:]), Port: uint32(port), } } func NewIp6AndPort(ip net.IP, port uint32) *Ip6AndPort { return &Ip6AndPort{ Hi: binary.BigEndian.Uint64(ip[:8]), Lo: binary.BigEndian.Uint64(ip[8:]), Port: port, } } func NewIp6AndPortFromNetIP(ip netip.Addr, port uint16) *Ip6AndPort { ip6Addr := ip.As16() return &Ip6AndPort{ Hi: binary.BigEndian.Uint64(ip6Addr[:8]), Lo: binary.BigEndian.Uint64(ip6Addr[8:]), Port: uint32(port), } } func NewUDPAddrFromLH4(ipp *Ip4AndPort) *udp.Addr { ip := ipp.Ip return udp.NewAddr( net.IPv4(byte(ip&0xff000000>>24), byte(ip&0x00ff0000>>16), byte(ip&0x0000ff00>>8), byte(ip&0x000000ff)), uint16(ipp.Port), ) } func NewUDPAddrFromLH6(ipp *Ip6AndPort) *udp.Addr { return udp.NewAddr(lhIp6ToIp(ipp), uint16(ipp.Port)) } func (lh *LightHouse) startQueryWorker() { if lh.amLighthouse { return } go func() { nb := make([]byte, 12, 12) out := make([]byte, mtu) for { select { case <-lh.ctx.Done(): return case ip := <-lh.queryChan: lh.innerQueryServer(ip, nb, out) } } }() } func (lh *LightHouse) innerQueryServer(ip iputil.VpnIp, nb, out []byte) { if lh.IsLighthouseIP(ip) { return } // Send a query to the lighthouses and hope for the best next time query, err := NewLhQueryByInt(ip).Marshal() if err != nil { lh.l.WithError(err).WithField("vpnIp", ip).Error("Failed to marshal lighthouse query payload") return } lighthouses := lh.GetLighthouses() lh.metricTx(NebulaMeta_HostQuery, int64(len(lighthouses))) for n := range lighthouses { lh.ifce.SendMessageToVpnIp(header.LightHouse, 0, n, query, nb, out) } } func (lh *LightHouse) StartUpdateWorker() { interval := lh.GetUpdateInterval() if lh.amLighthouse || interval == 0 { return } clockSource := time.NewTicker(time.Second * time.Duration(interval)) updateCtx, cancel := context.WithCancel(lh.ctx) lh.updateCancel = cancel go func() { defer clockSource.Stop() for { lh.SendUpdate() select { case <-updateCtx.Done(): return case <-clockSource.C: continue } } }() } func (lh *LightHouse) SendUpdate() { var v4 []*Ip4AndPort var v6 []*Ip6AndPort for _, e := range lh.GetAdvertiseAddrs() { if ip := e.ip.To4(); ip != nil { v4 = append(v4, NewIp4AndPort(e.ip, uint32(e.port))) } else { v6 = append(v6, NewIp6AndPort(e.ip, uint32(e.port))) } } lal := lh.GetLocalAllowList() for _, e := range *localIps(lh.l, lal) { if ip4 := e.To4(); ip4 != nil && ipMaskContains(lh.myVpnIp, lh.myVpnZeros, iputil.Ip2VpnIp(ip4)) { continue } // Only add IPs that aren't my VPN/tun IP if ip := e.To4(); ip != nil { v4 = append(v4, NewIp4AndPort(e, lh.nebulaPort)) } else { v6 = append(v6, NewIp6AndPort(e, lh.nebulaPort)) } } var relays []uint32 for _, r := range lh.GetRelaysForMe() { relays = append(relays, (uint32)(r)) } m := &NebulaMeta{ Type: NebulaMeta_HostUpdateNotification, Details: &NebulaMetaDetails{ VpnIp: uint32(lh.myVpnIp), Ip4AndPorts: v4, Ip6AndPorts: v6, RelayVpnIp: relays, }, } lighthouses := lh.GetLighthouses() lh.metricTx(NebulaMeta_HostUpdateNotification, int64(len(lighthouses))) nb := make([]byte, 12, 12) out := make([]byte, mtu) mm, err := m.Marshal() if err != nil { lh.l.WithError(err).Error("Error while marshaling for lighthouse update") return } for vpnIp := range lighthouses { lh.ifce.SendMessageToVpnIp(header.LightHouse, 0, vpnIp, mm, nb, out) } } type LightHouseHandler struct { lh *LightHouse nb []byte out []byte pb []byte meta *NebulaMeta l *logrus.Logger } func (lh *LightHouse) NewRequestHandler() *LightHouseHandler { lhh := &LightHouseHandler{ lh: lh, nb: make([]byte, 12, 12), out: make([]byte, mtu), l: lh.l, pb: make([]byte, mtu), meta: &NebulaMeta{ Details: &NebulaMetaDetails{}, }, } return lhh } func (lh *LightHouse) metricRx(t NebulaMeta_MessageType, i int64) { lh.metrics.Rx(header.MessageType(t), 0, i) } func (lh *LightHouse) metricTx(t NebulaMeta_MessageType, i int64) { lh.metrics.Tx(header.MessageType(t), 0, i) } // This method is similar to Reset(), but it re-uses the pointer structs // so that we don't have to re-allocate them func (lhh *LightHouseHandler) resetMeta() *NebulaMeta { details := lhh.meta.Details lhh.meta.Reset() // Keep the array memory around details.Ip4AndPorts = details.Ip4AndPorts[:0] details.Ip6AndPorts = details.Ip6AndPorts[:0] details.RelayVpnIp = details.RelayVpnIp[:0] lhh.meta.Details = details return lhh.meta } func lhHandleRequest(lhh *LightHouseHandler, f *Interface) udp.LightHouseHandlerFunc { return func(rAddr *udp.Addr, vpnIp iputil.VpnIp, p []byte) { lhh.HandleRequest(rAddr, vpnIp, p, f) } } func (lhh *LightHouseHandler) HandleRequest(rAddr *udp.Addr, vpnIp iputil.VpnIp, p []byte, w EncWriter) { n := lhh.resetMeta() err := n.Unmarshal(p) if err != nil { lhh.l.WithError(err).WithField("vpnIp", vpnIp).WithField("udpAddr", rAddr). Error("Failed to unmarshal lighthouse packet") //TODO: send recv_error? return } if n.Details == nil { lhh.l.WithField("vpnIp", vpnIp).WithField("udpAddr", rAddr). Error("Invalid lighthouse update") //TODO: send recv_error? return } lhh.lh.metricRx(n.Type, 1) switch n.Type { case NebulaMeta_HostQuery: lhh.handleHostQuery(n, vpnIp, rAddr, w) case NebulaMeta_HostQueryReply: lhh.handleHostQueryReply(n, vpnIp) case NebulaMeta_HostUpdateNotification: lhh.handleHostUpdateNotification(n, vpnIp, w) case NebulaMeta_HostMovedNotification: case NebulaMeta_HostPunchNotification: lhh.handleHostPunchNotification(n, vpnIp, w) case NebulaMeta_HostUpdateNotificationAck: // noop } } func (lhh *LightHouseHandler) handleHostQuery(n *NebulaMeta, vpnIp iputil.VpnIp, addr *udp.Addr, w EncWriter) { // Exit if we don't answer queries if !lhh.lh.amLighthouse { if lhh.l.Level >= logrus.DebugLevel { lhh.l.Debugln("I don't answer queries, but received from: ", addr) } return } //TODO: we can DRY this further reqVpnIp := n.Details.VpnIp //TODO: Maybe instead of marshalling into n we marshal into a new `r` to not nuke our current request data found, ln, err := lhh.lh.queryAndPrepMessage(iputil.VpnIp(n.Details.VpnIp), func(c *cache) (int, error) { n = lhh.resetMeta() n.Type = NebulaMeta_HostQueryReply n.Details.VpnIp = reqVpnIp lhh.coalesceAnswers(c, n) return n.MarshalTo(lhh.pb) }) if !found { return } if err != nil { lhh.l.WithError(err).WithField("vpnIp", vpnIp).Error("Failed to marshal lighthouse host query reply") return } lhh.lh.metricTx(NebulaMeta_HostQueryReply, 1) w.SendMessageToVpnIp(header.LightHouse, 0, vpnIp, lhh.pb[:ln], lhh.nb, lhh.out[:0]) // This signals the other side to punch some zero byte udp packets found, ln, err = lhh.lh.queryAndPrepMessage(vpnIp, func(c *cache) (int, error) { n = lhh.resetMeta() n.Type = NebulaMeta_HostPunchNotification n.Details.VpnIp = uint32(vpnIp) lhh.coalesceAnswers(c, n) return n.MarshalTo(lhh.pb) }) if !found { return } if err != nil { lhh.l.WithError(err).WithField("vpnIp", vpnIp).Error("Failed to marshal lighthouse host was queried for") return } lhh.lh.metricTx(NebulaMeta_HostPunchNotification, 1) w.SendMessageToVpnIp(header.LightHouse, 0, iputil.VpnIp(reqVpnIp), lhh.pb[:ln], lhh.nb, lhh.out[:0]) } func (lhh *LightHouseHandler) coalesceAnswers(c *cache, n *NebulaMeta) { if c.v4 != nil { if c.v4.learned != nil { n.Details.Ip4AndPorts = append(n.Details.Ip4AndPorts, c.v4.learned) } if c.v4.reported != nil && len(c.v4.reported) > 0 { n.Details.Ip4AndPorts = append(n.Details.Ip4AndPorts, c.v4.reported...) } } if c.v6 != nil { if c.v6.learned != nil { n.Details.Ip6AndPorts = append(n.Details.Ip6AndPorts, c.v6.learned) } if c.v6.reported != nil && len(c.v6.reported) > 0 { n.Details.Ip6AndPorts = append(n.Details.Ip6AndPorts, c.v6.reported...) } } if c.relay != nil { n.Details.RelayVpnIp = append(n.Details.RelayVpnIp, c.relay.relay...) } } func (lhh *LightHouseHandler) handleHostQueryReply(n *NebulaMeta, vpnIp iputil.VpnIp) { if !lhh.lh.IsLighthouseIP(vpnIp) { return } lhh.lh.Lock() am := lhh.lh.unlockedGetRemoteList(iputil.VpnIp(n.Details.VpnIp)) am.Lock() lhh.lh.Unlock() certVpnIp := iputil.VpnIp(n.Details.VpnIp) am.unlockedSetV4(vpnIp, certVpnIp, n.Details.Ip4AndPorts, lhh.lh.unlockedShouldAddV4) am.unlockedSetV6(vpnIp, certVpnIp, n.Details.Ip6AndPorts, lhh.lh.unlockedShouldAddV6) am.unlockedSetRelay(vpnIp, certVpnIp, n.Details.RelayVpnIp) am.Unlock() // Non-blocking attempt to trigger, skip if it would block select { case lhh.lh.handshakeTrigger <- iputil.VpnIp(n.Details.VpnIp): default: } } func (lhh *LightHouseHandler) handleHostUpdateNotification(n *NebulaMeta, vpnIp iputil.VpnIp, w EncWriter) { if !lhh.lh.amLighthouse { if lhh.l.Level >= logrus.DebugLevel { lhh.l.Debugln("I am not a lighthouse, do not take host updates: ", vpnIp) } return } //Simple check that the host sent this not someone else if n.Details.VpnIp != uint32(vpnIp) { if lhh.l.Level >= logrus.DebugLevel { lhh.l.WithField("vpnIp", vpnIp).WithField("answer", iputil.VpnIp(n.Details.VpnIp)).Debugln("Host sent invalid update") } return } lhh.lh.Lock() am := lhh.lh.unlockedGetRemoteList(vpnIp) am.Lock() lhh.lh.Unlock() certVpnIp := iputil.VpnIp(n.Details.VpnIp) am.unlockedSetV4(vpnIp, certVpnIp, n.Details.Ip4AndPorts, lhh.lh.unlockedShouldAddV4) am.unlockedSetV6(vpnIp, certVpnIp, n.Details.Ip6AndPorts, lhh.lh.unlockedShouldAddV6) am.unlockedSetRelay(vpnIp, certVpnIp, n.Details.RelayVpnIp) am.Unlock() n = lhh.resetMeta() n.Type = NebulaMeta_HostUpdateNotificationAck n.Details.VpnIp = uint32(vpnIp) ln, err := n.MarshalTo(lhh.pb) if err != nil { lhh.l.WithError(err).WithField("vpnIp", vpnIp).Error("Failed to marshal lighthouse host update ack") return } lhh.lh.metricTx(NebulaMeta_HostUpdateNotificationAck, 1) w.SendMessageToVpnIp(header.LightHouse, 0, vpnIp, lhh.pb[:ln], lhh.nb, lhh.out[:0]) } func (lhh *LightHouseHandler) handleHostPunchNotification(n *NebulaMeta, vpnIp iputil.VpnIp, w EncWriter) { if !lhh.lh.IsLighthouseIP(vpnIp) { return } empty := []byte{0} punch := func(vpnPeer *udp.Addr) { if vpnPeer == nil { return } go func() { time.Sleep(lhh.lh.punchy.GetDelay()) lhh.lh.metricHolepunchTx.Inc(1) lhh.lh.punchConn.WriteTo(empty, vpnPeer) }() if lhh.l.Level >= logrus.DebugLevel { //TODO: lacking the ip we are actually punching on, old: l.Debugf("Punching %s on %d for %s", IntIp(a.Ip), a.Port, IntIp(n.Details.VpnIp)) lhh.l.Debugf("Punching on %d for %s", vpnPeer.Port, iputil.VpnIp(n.Details.VpnIp)) } } for _, a := range n.Details.Ip4AndPorts { punch(NewUDPAddrFromLH4(a)) } for _, a := range n.Details.Ip6AndPorts { punch(NewUDPAddrFromLH6(a)) } // This sends a nebula test packet to the host trying to contact us. In the case // of a double nat or other difficult scenario, this may help establish // a tunnel. if lhh.lh.punchy.GetRespond() { queryVpnIp := iputil.VpnIp(n.Details.VpnIp) go func() { time.Sleep(lhh.lh.punchy.GetRespondDelay()) if lhh.l.Level >= logrus.DebugLevel { lhh.l.Debugf("Sending a nebula test packet to vpn ip %s", queryVpnIp) } //NOTE: we have to allocate a new output buffer here since we are spawning a new goroutine // for each punchBack packet. We should move this into a timerwheel or a single goroutine // managed by a channel. w.SendMessageToVpnIp(header.Test, header.TestRequest, queryVpnIp, []byte(""), make([]byte, 12, 12), make([]byte, mtu)) }() } } // ipMaskContains checks if testIp is contained by ip after applying a cidr // zeros is 32 - bits from net.IPMask.Size() func ipMaskContains(ip iputil.VpnIp, zeros iputil.VpnIp, testIp iputil.VpnIp) bool { return (testIp^ip)>>zeros == 0 }