package hscontrol import ( "context" "crypto/tls" "errors" "fmt" "io" "net" "net/http" "os" "os/signal" "sort" "strconv" "strings" "sync" "syscall" "time" "github.com/coreos/go-oidc/v3/oidc" "github.com/gorilla/mux" grpcMiddleware "github.com/grpc-ecosystem/go-grpc-middleware" "github.com/grpc-ecosystem/grpc-gateway/v2/runtime" "github.com/juanfont/headscale" v1 "github.com/juanfont/headscale/gen/go/headscale/v1" "github.com/juanfont/headscale/hscontrol/db" "github.com/juanfont/headscale/hscontrol/policy" "github.com/juanfont/headscale/hscontrol/types" "github.com/juanfont/headscale/hscontrol/util" "github.com/patrickmn/go-cache" zerolog "github.com/philip-bui/grpc-zerolog" "github.com/prometheus/client_golang/prometheus/promhttp" "github.com/puzpuzpuz/xsync/v2" zl "github.com/rs/zerolog" "github.com/rs/zerolog/log" "golang.org/x/crypto/acme" "golang.org/x/crypto/acme/autocert" "golang.org/x/oauth2" "golang.org/x/sync/errgroup" "google.golang.org/grpc" "google.golang.org/grpc/codes" "google.golang.org/grpc/credentials" "google.golang.org/grpc/credentials/insecure" "google.golang.org/grpc/metadata" "google.golang.org/grpc/peer" "google.golang.org/grpc/reflection" "google.golang.org/grpc/status" "tailscale.com/tailcfg" "tailscale.com/types/dnstype" "tailscale.com/types/key" ) var ( errSTUNAddressNotSet = errors.New("STUN address not set") errUnsupportedDatabase = errors.New("unsupported DB") errUnsupportedLetsEncryptChallengeType = errors.New( "unknown value for Lets Encrypt challenge type", ) ) const ( AuthPrefix = "Bearer " updateInterval = 5000 HTTPReadTimeout = 30 * time.Second HTTPShutdownTimeout = 3 * time.Second privateKeyFileMode = 0o600 registerCacheExpiration = time.Minute * 15 registerCacheCleanup = time.Minute * 20 DisabledClientAuth = "disabled" RelaxedClientAuth = "relaxed" EnforcedClientAuth = "enforced" ) // Headscale represents the base app of the service. type Headscale struct { cfg *types.Config db *db.HSDatabase dbString string dbType string dbDebug bool privateKey2019 *key.MachinePrivate noisePrivateKey *key.MachinePrivate DERPMap *tailcfg.DERPMap DERPServer *DERPServer ACLPolicy *policy.ACLPolicy lastStateChange *xsync.MapOf[string, time.Time] oidcProvider *oidc.Provider oauth2Config *oauth2.Config registrationCache *cache.Cache shutdownChan chan struct{} pollNetMapStreamWG sync.WaitGroup stateUpdateChan chan struct{} cancelStateUpdateChan chan struct{} } func NewHeadscale(cfg *types.Config) (*Headscale, error) { privateKey, err := readOrCreatePrivateKey(cfg.PrivateKeyPath) if err != nil { return nil, fmt.Errorf("failed to read or create private key: %w", err) } // TS2021 requires to have a different key from the legacy protocol. noisePrivateKey, err := readOrCreatePrivateKey(cfg.NoisePrivateKeyPath) if err != nil { return nil, fmt.Errorf("failed to read or create Noise protocol private key: %w", err) } if privateKey.Equal(*noisePrivateKey) { return nil, fmt.Errorf("private key and noise private key are the same: %w", err) } var dbString string switch cfg.DBtype { case db.Postgres: dbString = fmt.Sprintf( "host=%s dbname=%s user=%s", cfg.DBhost, cfg.DBname, cfg.DBuser, ) if sslEnabled, err := strconv.ParseBool(cfg.DBssl); err == nil { if !sslEnabled { dbString += " sslmode=disable" } } else { dbString += fmt.Sprintf(" sslmode=%s", cfg.DBssl) } if cfg.DBport != 0 { dbString += fmt.Sprintf(" port=%d", cfg.DBport) } if cfg.DBpass != "" { dbString += fmt.Sprintf(" password=%s", cfg.DBpass) } case db.Sqlite: dbString = cfg.DBpath default: return nil, errUnsupportedDatabase } registrationCache := cache.New( registerCacheExpiration, registerCacheCleanup, ) app := Headscale{ cfg: cfg, dbType: cfg.DBtype, dbString: dbString, privateKey2019: privateKey, noisePrivateKey: noisePrivateKey, registrationCache: registrationCache, pollNetMapStreamWG: sync.WaitGroup{}, lastStateChange: xsync.NewMapOf[time.Time](), stateUpdateChan: make(chan struct{}), cancelStateUpdateChan: make(chan struct{}), } go app.watchStateChannel() database, err := db.NewHeadscaleDatabase( cfg.DBtype, dbString, cfg.OIDC.StripEmaildomain, app.dbDebug, app.stateUpdateChan, cfg.IPPrefixes, cfg.BaseDomain) if err != nil { return nil, err } app.db = database if cfg.OIDC.Issuer != "" { err = app.initOIDC() if err != nil { if cfg.OIDC.OnlyStartIfOIDCIsAvailable { return nil, err } else { log.Warn().Err(err).Msg("failed to set up OIDC provider, falling back to CLI based authentication") } } } if app.cfg.DNSConfig != nil && app.cfg.DNSConfig.Proxied { // if MagicDNS magicDNSDomains := generateMagicDNSRootDomains(app.cfg.IPPrefixes) // we might have routes already from Split DNS if app.cfg.DNSConfig.Routes == nil { app.cfg.DNSConfig.Routes = make(map[string][]*dnstype.Resolver) } for _, d := range magicDNSDomains { app.cfg.DNSConfig.Routes[d.WithoutTrailingDot()] = nil } } if cfg.DERP.ServerEnabled { embeddedDERPServer, err := app.NewDERPServer() if err != nil { return nil, err } app.DERPServer = embeddedDERPServer } return &app, nil } // Redirect to our TLS url. func (h *Headscale) redirect(w http.ResponseWriter, req *http.Request) { target := h.cfg.ServerURL + req.URL.RequestURI() http.Redirect(w, req, target, http.StatusFound) } // expireEphemeralNodes deletes ephemeral machine records that have not been // seen for longer than h.cfg.EphemeralNodeInactivityTimeout. func (h *Headscale) expireEphemeralNodes(milliSeconds int64) { ticker := time.NewTicker(time.Duration(milliSeconds) * time.Millisecond) for range ticker.C { h.db.ExpireEphemeralMachines(h.cfg.EphemeralNodeInactivityTimeout) } } // expireExpiredMachines expires machines that have an explicit expiry set // after that expiry time has passed. func (h *Headscale) expireExpiredMachines(milliSeconds int64) { ticker := time.NewTicker(time.Duration(milliSeconds) * time.Millisecond) for range ticker.C { h.db.ExpireExpiredMachines(h.getLastStateChange()) } } func (h *Headscale) failoverSubnetRoutes(milliSeconds int64) { ticker := time.NewTicker(time.Duration(milliSeconds) * time.Millisecond) for range ticker.C { err := h.db.HandlePrimarySubnetFailover() if err != nil { log.Error().Err(err).Msg("failed to handle primary subnet failover") } } } func (h *Headscale) grpcAuthenticationInterceptor(ctx context.Context, req interface{}, info *grpc.UnaryServerInfo, handler grpc.UnaryHandler, ) (interface{}, error) { // Check if the request is coming from the on-server client. // This is not secure, but it is to maintain maintainability // with the "legacy" database-based client // It is also neede for grpc-gateway to be able to connect to // the server client, _ := peer.FromContext(ctx) log.Trace(). Caller(). Str("client_address", client.Addr.String()). Msg("Client is trying to authenticate") meta, ok := metadata.FromIncomingContext(ctx) if !ok { log.Error(). Caller(). Str("client_address", client.Addr.String()). Msg("Retrieving metadata is failed") return ctx, status.Errorf( codes.InvalidArgument, "Retrieving metadata is failed", ) } authHeader, ok := meta["authorization"] if !ok { log.Error(). Caller(). Str("client_address", client.Addr.String()). Msg("Authorization token is not supplied") return ctx, status.Errorf( codes.Unauthenticated, "Authorization token is not supplied", ) } token := authHeader[0] if !strings.HasPrefix(token, AuthPrefix) { log.Error(). Caller(). Str("client_address", client.Addr.String()). Msg(`missing "Bearer " prefix in "Authorization" header`) return ctx, status.Error( codes.Unauthenticated, `missing "Bearer " prefix in "Authorization" header`, ) } valid, err := h.db.ValidateAPIKey(strings.TrimPrefix(token, AuthPrefix)) if err != nil { log.Error(). Caller(). Err(err). Str("client_address", client.Addr.String()). Msg("failed to validate token") return ctx, status.Error(codes.Internal, "failed to validate token") } if !valid { log.Info(). Str("client_address", client.Addr.String()). Msg("invalid token") return ctx, status.Error(codes.Unauthenticated, "invalid token") } return handler(ctx, req) } func (h *Headscale) httpAuthenticationMiddleware(next http.Handler) http.Handler { return http.HandlerFunc(func( writer http.ResponseWriter, req *http.Request, ) { log.Trace(). Caller(). Str("client_address", req.RemoteAddr). Msg("HTTP authentication invoked") authHeader := req.Header.Get("authorization") if !strings.HasPrefix(authHeader, AuthPrefix) { log.Error(). Caller(). Str("client_address", req.RemoteAddr). Msg(`missing "Bearer " prefix in "Authorization" header`) writer.WriteHeader(http.StatusUnauthorized) _, err := writer.Write([]byte("Unauthorized")) if err != nil { log.Error(). Caller(). Err(err). Msg("Failed to write response") } return } valid, err := h.db.ValidateAPIKey(strings.TrimPrefix(authHeader, AuthPrefix)) if err != nil { log.Error(). Caller(). Err(err). Str("client_address", req.RemoteAddr). Msg("failed to validate token") writer.WriteHeader(http.StatusInternalServerError) _, err := writer.Write([]byte("Unauthorized")) if err != nil { log.Error(). Caller(). Err(err). Msg("Failed to write response") } return } if !valid { log.Info(). Str("client_address", req.RemoteAddr). Msg("invalid token") writer.WriteHeader(http.StatusUnauthorized) _, err := writer.Write([]byte("Unauthorized")) if err != nil { log.Error(). Caller(). Err(err). Msg("Failed to write response") } return } next.ServeHTTP(writer, req) }) } // ensureUnixSocketIsAbsent will check if the given path for headscales unix socket is clear // and will remove it if it is not. func (h *Headscale) ensureUnixSocketIsAbsent() error { // File does not exist, all fine if _, err := os.Stat(h.cfg.UnixSocket); errors.Is(err, os.ErrNotExist) { return nil } return os.Remove(h.cfg.UnixSocket) } func (h *Headscale) createRouter(grpcMux *runtime.ServeMux) *mux.Router { router := mux.NewRouter() router.HandleFunc(ts2021UpgradePath, h.NoiseUpgradeHandler).Methods(http.MethodPost) router.HandleFunc("/health", h.HealthHandler).Methods(http.MethodGet) router.HandleFunc("/key", h.KeyHandler).Methods(http.MethodGet) router.HandleFunc("/register/{nkey}", h.RegisterWebAPI).Methods(http.MethodGet) h.addLegacyHandlers(router) router.HandleFunc("/oidc/register/{nkey}", h.RegisterOIDC).Methods(http.MethodGet) router.HandleFunc("/oidc/callback", h.OIDCCallback).Methods(http.MethodGet) router.HandleFunc("/apple", h.AppleConfigMessage).Methods(http.MethodGet) router.HandleFunc("/apple/{platform}", h.ApplePlatformConfig). Methods(http.MethodGet) router.HandleFunc("/windows", h.WindowsConfigMessage).Methods(http.MethodGet) router.HandleFunc("/windows/tailscale.reg", h.WindowsRegConfig). Methods(http.MethodGet) // TODO(kristoffer): move swagger into a package router.HandleFunc("/swagger", headscale.SwaggerUI).Methods(http.MethodGet) router.HandleFunc("/swagger/v1/openapiv2.json", headscale.SwaggerAPIv1). Methods(http.MethodGet) if h.cfg.DERP.ServerEnabled { router.HandleFunc("/derp", h.DERPHandler) router.HandleFunc("/derp/probe", h.DERPProbeHandler) router.HandleFunc("/bootstrap-dns", h.DERPBootstrapDNSHandler) } apiRouter := router.PathPrefix("/api").Subrouter() apiRouter.Use(h.httpAuthenticationMiddleware) apiRouter.PathPrefix("/v1/").HandlerFunc(grpcMux.ServeHTTP) router.PathPrefix("/").HandlerFunc(notFoundHandler) return router } // Serve launches a GIN server with the Headscale API. func (h *Headscale) Serve() error { var err error // Fetch an initial DERP Map before we start serving h.DERPMap = GetDERPMap(h.cfg.DERP) if h.cfg.DERP.ServerEnabled { // When embedded DERP is enabled we always need a STUN server if h.cfg.DERP.STUNAddr == "" { return errSTUNAddressNotSet } h.DERPMap.Regions[h.DERPServer.region.RegionID] = &h.DERPServer.region go h.ServeSTUN() } if h.cfg.DERP.AutoUpdate { derpMapCancelChannel := make(chan struct{}) defer func() { derpMapCancelChannel <- struct{}{} }() go h.scheduledDERPMapUpdateWorker(derpMapCancelChannel) } // TODO(kradalby): These should have cancel channels and be cleaned // up on shutdown. go h.expireEphemeralNodes(updateInterval) go h.expireExpiredMachines(updateInterval) go h.failoverSubnetRoutes(updateInterval) if zl.GlobalLevel() == zl.TraceLevel { zerolog.RespLog = true } else { zerolog.RespLog = false } // Prepare group for running listeners errorGroup := new(errgroup.Group) ctx := context.Background() ctx, cancel := context.WithCancel(ctx) defer cancel() // // // Set up LOCAL listeners // err = h.ensureUnixSocketIsAbsent() if err != nil { return fmt.Errorf("unable to remove old socket file: %w", err) } socketListener, err := net.Listen("unix", h.cfg.UnixSocket) if err != nil { return fmt.Errorf("failed to set up gRPC socket: %w", err) } // Change socket permissions if err := os.Chmod(h.cfg.UnixSocket, h.cfg.UnixSocketPermission); err != nil { return fmt.Errorf("failed change permission of gRPC socket: %w", err) } grpcGatewayMux := runtime.NewServeMux() // Make the grpc-gateway connect to grpc over socket grpcGatewayConn, err := grpc.Dial( h.cfg.UnixSocket, []grpc.DialOption{ grpc.WithTransportCredentials(insecure.NewCredentials()), grpc.WithContextDialer(util.GrpcSocketDialer), }..., ) if err != nil { return err } // Connect to the gRPC server over localhost to skip // the authentication. err = v1.RegisterHeadscaleServiceHandler(ctx, grpcGatewayMux, grpcGatewayConn) if err != nil { return err } // Start the local gRPC server without TLS and without authentication grpcSocket := grpc.NewServer(zerolog.UnaryInterceptor()) v1.RegisterHeadscaleServiceServer(grpcSocket, newHeadscaleV1APIServer(h)) reflection.Register(grpcSocket) errorGroup.Go(func() error { return grpcSocket.Serve(socketListener) }) // // // Set up REMOTE listeners // tlsConfig, err := h.getTLSSettings() if err != nil { log.Error().Err(err).Msg("Failed to set up TLS configuration") return err } // // // gRPC setup // // We are sadly not able to run gRPC and HTTPS (2.0) on the same // port because the connection mux does not support matching them // since they are so similar. There is multiple issues open and we // can revisit this if changes: // https://github.com/soheilhy/cmux/issues/68 // https://github.com/soheilhy/cmux/issues/91 var grpcServer *grpc.Server var grpcListener net.Listener if tlsConfig != nil || h.cfg.GRPCAllowInsecure { log.Info().Msgf("Enabling remote gRPC at %s", h.cfg.GRPCAddr) grpcOptions := []grpc.ServerOption{ grpc.UnaryInterceptor( grpcMiddleware.ChainUnaryServer( h.grpcAuthenticationInterceptor, zerolog.NewUnaryServerInterceptor(), ), ), } if tlsConfig != nil { grpcOptions = append(grpcOptions, grpc.Creds(credentials.NewTLS(tlsConfig)), ) } else { log.Warn().Msg("gRPC is running without security") } grpcServer = grpc.NewServer(grpcOptions...) v1.RegisterHeadscaleServiceServer(grpcServer, newHeadscaleV1APIServer(h)) reflection.Register(grpcServer) grpcListener, err = net.Listen("tcp", h.cfg.GRPCAddr) if err != nil { return fmt.Errorf("failed to bind to TCP address: %w", err) } errorGroup.Go(func() error { return grpcServer.Serve(grpcListener) }) log.Info(). Msgf("listening and serving gRPC on: %s", h.cfg.GRPCAddr) } // // // HTTP setup // // This is the regular router that we expose // over our main Addr. It also serves the legacy Tailcale API router := h.createRouter(grpcGatewayMux) httpServer := &http.Server{ Addr: h.cfg.Addr, Handler: router, ReadTimeout: HTTPReadTimeout, // Go does not handle timeouts in HTTP very well, and there is // no good way to handle streaming timeouts, therefore we need to // keep this at unlimited and be careful to clean up connections // https://blog.cloudflare.com/the-complete-guide-to-golang-net-http-timeouts/#aboutstreaming WriteTimeout: 0, } var httpListener net.Listener if tlsConfig != nil { httpServer.TLSConfig = tlsConfig httpListener, err = tls.Listen("tcp", h.cfg.Addr, tlsConfig) } else { httpListener, err = net.Listen("tcp", h.cfg.Addr) } if err != nil { return fmt.Errorf("failed to bind to TCP address: %w", err) } errorGroup.Go(func() error { return httpServer.Serve(httpListener) }) log.Info(). Msgf("listening and serving HTTP on: %s", h.cfg.Addr) promMux := http.NewServeMux() promMux.Handle("/metrics", promhttp.Handler()) promHTTPServer := &http.Server{ Addr: h.cfg.MetricsAddr, Handler: promMux, ReadTimeout: HTTPReadTimeout, WriteTimeout: 0, } var promHTTPListener net.Listener promHTTPListener, err = net.Listen("tcp", h.cfg.MetricsAddr) if err != nil { return fmt.Errorf("failed to bind to TCP address: %w", err) } errorGroup.Go(func() error { return promHTTPServer.Serve(promHTTPListener) }) log.Info(). Msgf("listening and serving metrics on: %s", h.cfg.MetricsAddr) // Handle common process-killing signals so we can gracefully shut down: h.shutdownChan = make(chan struct{}) sigc := make(chan os.Signal, 1) signal.Notify(sigc, syscall.SIGHUP, syscall.SIGINT, syscall.SIGTERM, syscall.SIGQUIT, syscall.SIGHUP) sigFunc := func(c chan os.Signal) { // Wait for a SIGINT or SIGKILL: for { sig := <-c switch sig { case syscall.SIGHUP: log.Info(). Str("signal", sig.String()). Msg("Received SIGHUP, reloading ACL and Config") // TODO(kradalby): Reload config on SIGHUP if h.cfg.ACL.PolicyPath != "" { aclPath := util.AbsolutePathFromConfigPath(h.cfg.ACL.PolicyPath) pol, err := policy.LoadACLPolicyFromPath(aclPath) if err != nil { log.Error().Err(err).Msg("Failed to reload ACL policy") } h.ACLPolicy = pol log.Info(). Str("path", aclPath). Msg("ACL policy successfully reloaded, notifying nodes of change") h.setLastStateChangeToNow() } default: log.Info(). Str("signal", sig.String()). Msg("Received signal to stop, shutting down gracefully") close(h.shutdownChan) h.pollNetMapStreamWG.Wait() // Gracefully shut down servers ctx, cancel := context.WithTimeout( context.Background(), HTTPShutdownTimeout, ) if err := promHTTPServer.Shutdown(ctx); err != nil { log.Error().Err(err).Msg("Failed to shutdown prometheus http") } if err := httpServer.Shutdown(ctx); err != nil { log.Error().Err(err).Msg("Failed to shutdown http") } grpcSocket.GracefulStop() if grpcServer != nil { grpcServer.GracefulStop() grpcListener.Close() } // Close network listeners promHTTPListener.Close() httpListener.Close() grpcGatewayConn.Close() // Stop listening (and unlink the socket if unix type): socketListener.Close() <-h.cancelStateUpdateChan close(h.stateUpdateChan) close(h.cancelStateUpdateChan) // Close db connections err = h.db.Close() if err != nil { log.Error().Err(err).Msg("Failed to close db") } log.Info(). Msg("Headscale stopped") // And we're done: cancel() } } } errorGroup.Go(func() error { sigFunc(sigc) return nil }) return errorGroup.Wait() } func (h *Headscale) getTLSSettings() (*tls.Config, error) { var err error if h.cfg.TLS.LetsEncrypt.Hostname != "" { if !strings.HasPrefix(h.cfg.ServerURL, "https://") { log.Warn(). Msg("Listening with TLS but ServerURL does not start with https://") } certManager := autocert.Manager{ Prompt: autocert.AcceptTOS, HostPolicy: autocert.HostWhitelist(h.cfg.TLS.LetsEncrypt.Hostname), Cache: autocert.DirCache(h.cfg.TLS.LetsEncrypt.CacheDir), Client: &acme.Client{ DirectoryURL: h.cfg.ACMEURL, }, Email: h.cfg.ACMEEmail, } switch h.cfg.TLS.LetsEncrypt.ChallengeType { case types.TlsALPN01ChallengeType: // Configuration via autocert with TLS-ALPN-01 (https://tools.ietf.org/html/rfc8737) // The RFC requires that the validation is done on port 443; in other words, headscale // must be reachable on port 443. return certManager.TLSConfig(), nil case types.Http01ChallengeType: // Configuration via autocert with HTTP-01. This requires listening on // port 80 for the certificate validation in addition to the headscale // service, which can be configured to run on any other port. server := &http.Server{ Addr: h.cfg.TLS.LetsEncrypt.Listen, Handler: certManager.HTTPHandler(http.HandlerFunc(h.redirect)), ReadTimeout: HTTPReadTimeout, } go func() { err := server.ListenAndServe() log.Fatal(). Caller(). Err(err). Msg("failed to set up a HTTP server") }() return certManager.TLSConfig(), nil default: return nil, errUnsupportedLetsEncryptChallengeType } } else if h.cfg.TLS.CertPath == "" { if !strings.HasPrefix(h.cfg.ServerURL, "http://") { log.Warn().Msg("Listening without TLS but ServerURL does not start with http://") } return nil, err } else { if !strings.HasPrefix(h.cfg.ServerURL, "https://") { log.Warn().Msg("Listening with TLS but ServerURL does not start with https://") } tlsConfig := &tls.Config{ NextProtos: []string{"http/1.1"}, Certificates: make([]tls.Certificate, 1), MinVersion: tls.VersionTLS12, } tlsConfig.Certificates[0], err = tls.LoadX509KeyPair(h.cfg.TLS.CertPath, h.cfg.TLS.KeyPath) return tlsConfig, err } } // TODO(kradalby): baby steps, make this more robust. func (h *Headscale) watchStateChannel() { for { select { case <-h.stateUpdateChan: h.setLastStateChangeToNow() case <-h.cancelStateUpdateChan: return } } } func (h *Headscale) setLastStateChangeToNow() { var err error now := time.Now().UTC() users, err := h.db.ListUsers() if err != nil { log.Error(). Caller(). Err(err). Msg("failed to fetch all users, failing to update last changed state.") } for _, user := range users { lastStateUpdate.WithLabelValues(user.Name, "headscale").Set(float64(now.Unix())) if h.lastStateChange == nil { h.lastStateChange = xsync.NewMapOf[time.Time]() } h.lastStateChange.Store(user.Name, now) } } func (h *Headscale) getLastStateChange(users ...types.User) time.Time { times := []time.Time{} // getLastStateChange takes a list of users as a "filter", if no users // are past, then use the entier list of users and look for the last update if len(users) > 0 { for _, user := range users { if lastChange, ok := h.lastStateChange.Load(user.Name); ok { times = append(times, lastChange) } } } else { h.lastStateChange.Range(func(key string, value time.Time) bool { times = append(times, value) return true }) } sort.Slice(times, func(i, j int) bool { return times[i].After(times[j]) }) log.Trace().Msgf("Latest times %#v", times) if len(times) == 0 { return time.Now().UTC() } else { return times[0] } } func notFoundHandler( writer http.ResponseWriter, req *http.Request, ) { body, _ := io.ReadAll(req.Body) log.Trace(). Interface("header", req.Header). Interface("proto", req.Proto). Interface("url", req.URL). Bytes("body", body). Msg("Request did not match") writer.WriteHeader(http.StatusNotFound) } func readOrCreatePrivateKey(path string) (*key.MachinePrivate, error) { privateKey, err := os.ReadFile(path) if errors.Is(err, os.ErrNotExist) { log.Info().Str("path", path).Msg("No private key file at path, creating...") machineKey := key.NewMachine() machineKeyStr, err := machineKey.MarshalText() if err != nil { return nil, fmt.Errorf( "failed to convert private key to string for saving: %w", err, ) } err = os.WriteFile(path, machineKeyStr, privateKeyFileMode) if err != nil { return nil, fmt.Errorf( "failed to save private key to disk: %w", err, ) } return &machineKey, nil } else if err != nil { return nil, fmt.Errorf("failed to read private key file: %w", err) } trimmedPrivateKey := strings.TrimSpace(string(privateKey)) privateKeyEnsurePrefix := util.PrivateKeyEnsurePrefix(trimmedPrivateKey) var machineKey key.MachinePrivate if err = machineKey.UnmarshalText([]byte(privateKeyEnsurePrefix)); err != nil { log.Info(). Str("path", path). Msg("This might be due to a legacy (headscale pre-0.12) private key. " + "If the key is in WireGuard format, delete the key and restart headscale. " + "A new key will automatically be generated. All Tailscale clients will have to be restarted") return nil, fmt.Errorf("failed to parse private key: %w", err) } return &machineKey, nil }