// Copyright (c) Tailscale Inc & AUTHORS // SPDX-License-Identifier: BSD-3-Clause package ipnlocal import ( "context" "crypto/sha256" "crypto/tls" "encoding/hex" "encoding/json" "errors" "fmt" "io" "net" "net/http" "net/http/httputil" "net/netip" "net/url" "os" "path" "slices" "strconv" "strings" "sync" "sync/atomic" "time" "golang.org/x/net/http2" "tailscale.com/ipn" "tailscale.com/logtail/backoff" "tailscale.com/net/netutil" "tailscale.com/syncs" "tailscale.com/tailcfg" "tailscale.com/types/lazy" "tailscale.com/types/logger" "tailscale.com/util/mak" "tailscale.com/version" ) const ( contentTypeHeader = "Content-Type" grpcBaseContentType = "application/grpc" ) // ErrETagMismatch signals that the given // If-Match header does not match with the // current etag of a resource. var ErrETagMismatch = errors.New("etag mismatch") // serveHTTPContextKey is the context.Value key for a *serveHTTPContext. type serveHTTPContextKey struct{} type serveHTTPContext struct { SrcAddr netip.AddrPort DestPort uint16 } // serveListener is the state of host-level net.Listen for a specific (Tailscale IP, serve port) // combination. If there are two TailscaleIPs (v4 and v6) and three ports being served, // then there will be six of these active and looping in their Run method. // // This is not used in userspace-networking mode. // // Most serve traffic is intercepted by netstack. This exists purely for connections // from the machine itself, as that goes via the kernel, so we need to be in the // kernel's listening/routing tables. type serveListener struct { b *LocalBackend ap netip.AddrPort ctx context.Context // valid while listener is desired cancel context.CancelFunc // for ctx, to close listener logf logger.Logf bo *backoff.Backoff // for retrying failed Listen calls closeListener syncs.AtomicValue[func() error] // Listener's Close method, if any } func (b *LocalBackend) newServeListener(ctx context.Context, ap netip.AddrPort, logf logger.Logf) *serveListener { ctx, cancel := context.WithCancel(ctx) return &serveListener{ b: b, ap: ap, ctx: ctx, cancel: cancel, logf: logf, bo: backoff.NewBackoff("serve-listener", logf, 30*time.Second), } } // Close cancels the context and closes the listener, if any. func (s *serveListener) Close() error { s.cancel() if close, ok := s.closeListener.LoadOk(); ok { s.closeListener.Store(nil) close() } return nil } // Run starts a net.Listen for the serveListener's address and port. // If unable to listen, it retries with exponential backoff. // Listen is retried until the context is canceled. func (s *serveListener) Run() { for { ip := s.ap.Addr() ipStr := ip.String() var lc net.ListenConfig if initListenConfig != nil { // On macOS, this sets the lc.Control hook to // setsockopt the interface index to bind to. This is // required by the network sandbox to allow binding to // a specific interface. Without this hook, the system // chooses a default interface to bind to. if err := initListenConfig(&lc, ip, s.b.prevIfState, s.b.dialer.TUNName()); err != nil { s.logf("serve failed to init listen config %v, backing off: %v", s.ap, err) s.bo.BackOff(s.ctx, err) continue } // On macOS (AppStore or macsys) and if we're binding to a privileged port, if version.IsSandboxedMacOS() && s.ap.Port() < 1024 { // On macOS, we need to bind to ""/all-interfaces due to // the network sandbox. Ideally we would only bind to the // Tailscale interface, but macOS errors out if we try to // to listen on privileged ports binding only to a specific // interface. (#6364) ipStr = "" } } tcp4or6 := "tcp4" if ip.Is6() { tcp4or6 = "tcp6" } ln, err := lc.Listen(s.ctx, tcp4or6, net.JoinHostPort(ipStr, fmt.Sprint(s.ap.Port()))) if err != nil { if s.shouldWarnAboutListenError(err) { s.logf("serve failed to listen on %v, backing off: %v", s.ap, err) } s.bo.BackOff(s.ctx, err) continue } s.closeListener.Store(ln.Close) s.logf("serve listening on %v", s.ap) err = s.handleServeListenersAccept(ln) if s.ctx.Err() != nil { // context canceled, we're done return } if err != nil { s.logf("serve listener accept error, retrying: %v", err) } } } func (s *serveListener) shouldWarnAboutListenError(err error) bool { if !s.b.sys.NetMon.Get().InterfaceState().HasIP(s.ap.Addr()) { // Machine likely doesn't have IPv6 enabled (or the IP is still being // assigned). No need to warn. Notably, WSL2 (Issue 6303). return false } // TODO(bradfitz): check errors.Is(err, syscall.EADDRNOTAVAIL) etc? Let's // see what happens in practice. return true } // handleServeListenersAccept accepts connections for the Listener. It calls the // handler in a new goroutine for each accepted connection. This is used to // handle local "tailscale serve" traffic originating from the machine itself. func (s *serveListener) handleServeListenersAccept(ln net.Listener) error { for { conn, err := ln.Accept() if err != nil { return err } srcAddr := conn.RemoteAddr().(*net.TCPAddr).AddrPort() handler := s.b.tcpHandlerForServe(s.ap.Port(), srcAddr) if handler == nil { s.b.logf("[unexpected] local-serve: no handler for %v to port %v", srcAddr, s.ap.Port()) conn.Close() continue } go handler(conn) } } // updateServeTCPPortNetMapAddrListenersLocked starts a net.Listen for configured // Serve ports on all the node's addresses. // Existing Listeners are closed if port no longer in incoming ports list. // // b.mu must be held. func (b *LocalBackend) updateServeTCPPortNetMapAddrListenersLocked(ports []uint16) { // close existing listeners where port // is no longer in incoming ports list for ap, sl := range b.serveListeners { if !slices.Contains(ports, ap.Port()) { b.logf("closing listener %v", ap) sl.Close() delete(b.serveListeners, ap) } } nm := b.netMap if nm == nil { b.logf("netMap is nil") return } if !nm.SelfNode.Valid() { b.logf("netMap SelfNode is nil") return } addrs := nm.GetAddresses() for i := range addrs.LenIter() { a := addrs.At(i) for _, p := range ports { addrPort := netip.AddrPortFrom(a.Addr(), p) if _, ok := b.serveListeners[addrPort]; ok { continue // already listening } sl := b.newServeListener(context.Background(), addrPort, b.logf) mak.Set(&b.serveListeners, addrPort, sl) go sl.Run() } } } // SetServeConfig establishes or replaces the current serve config. // ETag is an optional parameter to enforce Optimistic Concurrency Control. // If it is an empty string, then the config will be overwritten. func (b *LocalBackend) SetServeConfig(config *ipn.ServeConfig, etag string) error { b.mu.Lock() defer b.mu.Unlock() return b.setServeConfigLocked(config, etag) } func (b *LocalBackend) setServeConfigLocked(config *ipn.ServeConfig, etag string) error { prefs := b.pm.CurrentPrefs() if config.IsFunnelOn() && prefs.ShieldsUp() { return errors.New("Unable to turn on Funnel while shields-up is enabled") } if b.isConfigLocked_Locked() { return errors.New("can't reconfigure tailscaled when using a config file; config file is locked") } nm := b.netMap if nm == nil { return errors.New("netMap is nil") } if !nm.SelfNode.Valid() { return errors.New("netMap SelfNode is nil") } // If etag is present, check that it has // not changed from the last config. prevConfig := b.serveConfig if etag != "" { // Note that we marshal b.serveConfig // and not use b.lastServeConfJSON as that might // be a Go nil value, which produces a different // checksum from a JSON "null" value. prevBytes, err := json.Marshal(prevConfig) if err != nil { return fmt.Errorf("error encoding previous config: %w", err) } sum := sha256.Sum256(prevBytes) previousEtag := hex.EncodeToString(sum[:]) if etag != previousEtag { return ErrETagMismatch } } var bs []byte if config != nil { j, err := json.Marshal(config) if err != nil { return fmt.Errorf("encoding serve config: %w", err) } bs = j } profileID := b.pm.CurrentProfile().ID confKey := ipn.ServeConfigKey(profileID) if err := b.store.WriteState(confKey, bs); err != nil { return fmt.Errorf("writing ServeConfig to StateStore: %w", err) } b.setTCPPortsInterceptedFromNetmapAndPrefsLocked(b.pm.CurrentPrefs()) // clean up and close all previously open foreground sessions // if the current ServeConfig has overwritten them. if prevConfig.Valid() { has := func(string) bool { return false } if b.serveConfig.Valid() { has = b.serveConfig.Foreground().Has } prevConfig.Foreground().Range(func(k string, v ipn.ServeConfigView) (cont bool) { if !has(k) { for _, sess := range b.notifyWatchers { if sess.sessionID == k { close(sess.ch) } } } return true }) } return nil } // ServeConfig provides a view of the current serve mappings. // If serving is not configured, the returned view is not Valid. func (b *LocalBackend) ServeConfig() ipn.ServeConfigView { b.mu.Lock() defer b.mu.Unlock() return b.serveConfig } // DeleteForegroundSession deletes a ServeConfig's foreground session // in the LocalBackend if it exists. It also ensures check, delete, and // set operations happen within the same mutex lock to avoid any races. func (b *LocalBackend) DeleteForegroundSession(sessionID string) error { b.mu.Lock() defer b.mu.Unlock() if !b.serveConfig.Valid() || !b.serveConfig.Foreground().Has(sessionID) { return nil } sc := b.serveConfig.AsStruct() delete(sc.Foreground, sessionID) return b.setServeConfigLocked(sc, "") } // HandleIngressTCPConn handles a TCP connection initiated by the ingressPeer // proxied to the local node over the PeerAPI. // Target represents the destination HostPort of the conn. // srcAddr represents the source AddrPort and not that of the ingressPeer. // getConnOrReset is a callback to get the connection, or reset if the connection // is no longer available. // sendRST is a callback to send a TCP RST to the ingressPeer indicating that // the connection was not accepted. func (b *LocalBackend) HandleIngressTCPConn(ingressPeer tailcfg.NodeView, target ipn.HostPort, srcAddr netip.AddrPort, getConnOrReset func() (net.Conn, bool), sendRST func()) { b.mu.Lock() sc := b.serveConfig b.mu.Unlock() // TODO(maisem,bradfitz): make this not alloc for every conn. logf := logger.WithPrefix(b.logf, "handleIngress: ") if !sc.Valid() { logf("got ingress conn w/o serveConfig; rejecting") sendRST() return } if !sc.HasFunnelForTarget(target) { logf("got ingress conn for unconfigured %q; rejecting", target) sendRST() return } _, port, err := net.SplitHostPort(string(target)) if err != nil { logf("got ingress conn for bad target %q; rejecting", target) sendRST() return } port16, err := strconv.ParseUint(port, 10, 16) if err != nil { logf("got ingress conn for bad target %q; rejecting", target) sendRST() return } dport := uint16(port16) if b.getTCPHandlerForFunnelFlow != nil { handler := b.getTCPHandlerForFunnelFlow(srcAddr, dport) if handler != nil { c, ok := getConnOrReset() if !ok { logf("getConn didn't complete from %v to port %v", srcAddr, dport) return } handler(c) return } } // TODO(bradfitz): pass ingressPeer etc in context to tcpHandlerForServe, // extend serveHTTPContext or similar. handler := b.tcpHandlerForServe(dport, srcAddr) if handler == nil { logf("[unexpected] no matching ingress serve handler for %v to port %v", srcAddr, dport) sendRST() return } c, ok := getConnOrReset() if !ok { logf("getConn didn't complete from %v to port %v", srcAddr, dport) return } handler(c) } // tcpHandlerForServe returns a handler for a TCP connection to be served via // the ipn.ServeConfig. func (b *LocalBackend) tcpHandlerForServe(dport uint16, srcAddr netip.AddrPort) (handler func(net.Conn) error) { b.mu.Lock() sc := b.serveConfig b.mu.Unlock() if !sc.Valid() { return nil } tcph, ok := sc.FindTCP(dport) if !ok { return nil } if tcph.HTTPS() || tcph.HTTP() { hs := &http.Server{ Handler: http.HandlerFunc(b.serveWebHandler), BaseContext: func(_ net.Listener) context.Context { return context.WithValue(context.Background(), serveHTTPContextKey{}, &serveHTTPContext{ SrcAddr: srcAddr, DestPort: dport, }) }, } if tcph.HTTPS() { hs.TLSConfig = &tls.Config{ GetCertificate: b.getTLSServeCertForPort(dport), } return func(c net.Conn) error { return hs.ServeTLS(netutil.NewOneConnListener(c, nil), "", "") } } return func(c net.Conn) error { return hs.Serve(netutil.NewOneConnListener(c, nil)) } } if backDst := tcph.TCPForward(); backDst != "" { return func(conn net.Conn) error { defer conn.Close() ctx, cancel := context.WithTimeout(context.Background(), 10*time.Second) backConn, err := b.dialer.SystemDial(ctx, "tcp", backDst) cancel() if err != nil { b.logf("localbackend: failed to TCP proxy port %v (from %v) to %s: %v", dport, srcAddr, backDst, err) return nil } defer backConn.Close() if sni := tcph.TerminateTLS(); sni != "" { conn = tls.Server(conn, &tls.Config{ GetCertificate: func(hi *tls.ClientHelloInfo) (*tls.Certificate, error) { ctx, cancel := context.WithTimeout(context.Background(), time.Minute) defer cancel() pair, err := b.GetCertPEM(ctx, sni) if err != nil { return nil, err } cert, err := tls.X509KeyPair(pair.CertPEM, pair.KeyPEM) if err != nil { return nil, err } return &cert, nil }, }) } // TODO(bradfitz): do the RegisterIPPortIdentity and // UnregisterIPPortIdentity stuff that netstack does errc := make(chan error, 1) go func() { _, err := io.Copy(backConn, conn) errc <- err }() go func() { _, err := io.Copy(conn, backConn) errc <- err }() return <-errc } } return nil } func getServeHTTPContext(r *http.Request) (c *serveHTTPContext, ok bool) { c, ok = r.Context().Value(serveHTTPContextKey{}).(*serveHTTPContext) return c, ok } func (b *LocalBackend) getServeHandler(r *http.Request) (_ ipn.HTTPHandlerView, at string, ok bool) { var z ipn.HTTPHandlerView // zero value hostname := r.Host if r.TLS == nil { tcd := "." + b.Status().CurrentTailnet.MagicDNSSuffix if host, _, err := net.SplitHostPort(hostname); err == nil { hostname = host } if !strings.HasSuffix(hostname, tcd) { hostname += tcd } } else { hostname = r.TLS.ServerName } sctx, ok := getServeHTTPContext(r) if !ok { b.logf("[unexpected] localbackend: no serveHTTPContext in request") return z, "", false } wsc, ok := b.webServerConfig(hostname, sctx.DestPort) if !ok { return z, "", false } if h, ok := wsc.Handlers().GetOk(r.URL.Path); ok { return h, r.URL.Path, true } pth := path.Clean(r.URL.Path) for { withSlash := pth + "/" if h, ok := wsc.Handlers().GetOk(withSlash); ok { return h, withSlash, true } if h, ok := wsc.Handlers().GetOk(pth); ok { return h, pth, true } if pth == "/" { return z, "", false } pth = path.Dir(pth) } } // proxyHandlerForBackend creates a new HTTP reverse proxy for a particular backend that // we serve requests for. `backend` is a HTTPHandler.Proxy string (url, hostport or just port). func (b *LocalBackend) proxyHandlerForBackend(backend string) (http.Handler, error) { targetURL, insecure := expandProxyArg(backend) u, err := url.Parse(targetURL) if err != nil { return nil, fmt.Errorf("invalid url %s: %w", targetURL, err) } p := &reverseProxy{ logf: b.logf, url: u, insecure: insecure, backend: backend, lb: b, } return p, nil } // reverseProxy is a proxy that forwards a request to a backend host // (preconfigured via ipn.ServeConfig). If the host is configured with // http+insecure prefix, connection between proxy and backend will be over // insecure TLS. If the backend host has a http prefix and the incoming request // has application/grpc content type header, the connection will be over h2c. // Otherwise standard Go http transport will be used. type reverseProxy struct { logf logger.Logf url *url.URL // insecure tracks whether the connection to an https backend should be // insecure (i.e because we cannot verify its CA). insecure bool backend string lb *LocalBackend httpTransport lazy.SyncValue[*http.Transport] // transport for non-h2c backends h2cTransport lazy.SyncValue[*http2.Transport] // transport for h2c backends // closed tracks whether proxy is closed/currently closing. closed atomic.Bool } // close ensures that any open backend connections get closed. func (rp *reverseProxy) close() { rp.closed.Store(true) if h2cT := rp.h2cTransport.Get(func() *http2.Transport { return nil }); h2cT != nil { h2cT.CloseIdleConnections() } if httpTransport := rp.httpTransport.Get(func() *http.Transport { return nil }); httpTransport != nil { httpTransport.CloseIdleConnections() } } func (rp *reverseProxy) ServeHTTP(w http.ResponseWriter, r *http.Request) { if closed := rp.closed.Load(); closed { rp.logf("received a request for a proxy that's being closed or has been closed") http.Error(w, "proxy is closed", http.StatusServiceUnavailable) return } p := &httputil.ReverseProxy{Rewrite: func(r *httputil.ProxyRequest) { r.SetURL(rp.url) r.Out.Host = r.In.Host addProxyForwardedHeaders(r) rp.lb.addTailscaleIdentityHeaders(r) }} // There is no way to autodetect h2c as per RFC 9113 // https://datatracker.ietf.org/doc/html/rfc9113#name-starting-http-2. // However, we assume that http:// proxy prefix in combination with the // protoccol being HTTP/2 is sufficient to detect h2c for our needs. Only use this for // gRPC to fix a known problem of plaintext gRPC backends if rp.shouldProxyViaH2C(r) { rp.logf("received a proxy request for plaintext gRPC") p.Transport = rp.getH2CTransport() } else { p.Transport = rp.getTransport() } p.ServeHTTP(w, r) } // getTransport returns the Transport used for regular (non-GRPC) requests // to the backend. The Transport gets created lazily, at most once. func (rp *reverseProxy) getTransport() *http.Transport { return rp.httpTransport.Get(func() *http.Transport { return &http.Transport{ DialContext: rp.lb.dialer.SystemDial, TLSClientConfig: &tls.Config{ InsecureSkipVerify: rp.insecure, }, // Values for the following parameters have been copied from http.DefaultTransport. ForceAttemptHTTP2: true, MaxIdleConns: 100, IdleConnTimeout: 90 * time.Second, TLSHandshakeTimeout: 10 * time.Second, ExpectContinueTimeout: 1 * time.Second, } }) } // getH2CTransport returns the Transport used for GRPC requests to the backend. // The Transport gets created lazily, at most once. func (rp *reverseProxy) getH2CTransport() *http2.Transport { return rp.h2cTransport.Get(func() *http2.Transport { return &http2.Transport{ AllowHTTP: true, DialTLSContext: func(ctx context.Context, network string, addr string, _ *tls.Config) (net.Conn, error) { return rp.lb.dialer.SystemDial(ctx, "tcp", rp.url.Host) }, } }) } // This is not a generally reliable way how to determine whether a request is // for a h2c server, but sufficient for our particular use case. func (rp *reverseProxy) shouldProxyViaH2C(r *http.Request) bool { contentType := r.Header.Get(contentTypeHeader) return r.ProtoMajor == 2 && strings.HasPrefix(rp.backend, "http://") && isGRPCContentType(contentType) } // isGRPC accepts an HTTP request's content type header value and determines // whether this is gRPC content. grpc-go considers a value that equals // application/grpc or has a prefix of application/grpc+ or application/grpc; a // valid grpc content type header. // https://github.com/grpc/grpc-go/blob/v1.60.0-dev/internal/grpcutil/method.go#L41-L78 func isGRPCContentType(contentType string) bool { s, ok := strings.CutPrefix(contentType, grpcBaseContentType) return ok && (len(s) == 0 || s[0] == '+' || s[0] == ';') } func addProxyForwardedHeaders(r *httputil.ProxyRequest) { r.Out.Header.Set("X-Forwarded-Host", r.In.Host) if r.In.TLS != nil { r.Out.Header.Set("X-Forwarded-Proto", "https") } if c, ok := getServeHTTPContext(r.Out); ok { r.Out.Header.Set("X-Forwarded-For", c.SrcAddr.Addr().String()) } } func (b *LocalBackend) addTailscaleIdentityHeaders(r *httputil.ProxyRequest) { // Clear any incoming values squatting in the headers. r.Out.Header.Del("Tailscale-User-Login") r.Out.Header.Del("Tailscale-User-Name") r.Out.Header.Del("Tailscale-User-Profile-Pic") r.Out.Header.Del("Tailscale-Headers-Info") c, ok := getServeHTTPContext(r.Out) if !ok { return } node, user, ok := b.WhoIs(c.SrcAddr) if !ok { return // traffic from outside of Tailnet (funneled) } if node.IsTagged() { // 2023-06-14: Not setting identity headers for tagged nodes. // Only currently set for nodes with user identities. return } r.Out.Header.Set("Tailscale-User-Login", user.LoginName) r.Out.Header.Set("Tailscale-User-Name", user.DisplayName) r.Out.Header.Set("Tailscale-User-Profile-Pic", user.ProfilePicURL) r.Out.Header.Set("Tailscale-Headers-Info", "https://tailscale.com/s/serve-headers") } // serveWebHandler is an http.HandlerFunc that maps incoming requests to the // correct *http. func (b *LocalBackend) serveWebHandler(w http.ResponseWriter, r *http.Request) { h, mountPoint, ok := b.getServeHandler(r) if !ok { http.NotFound(w, r) return } if s := h.Text(); s != "" { w.Header().Set("Content-Type", "text/plain; charset=utf-8") io.WriteString(w, s) return } if v := h.Path(); v != "" { b.serveFileOrDirectory(w, r, v, mountPoint) return } if v := h.Proxy(); v != "" { p, ok := b.serveProxyHandlers.Load(v) if !ok { http.Error(w, "unknown proxy destination", http.StatusInternalServerError) return } h := p.(http.Handler) // Trim the mount point from the URL path before proxying. (#6571) if r.URL.Path != "/" { h = http.StripPrefix(strings.TrimSuffix(mountPoint, "/"), h) } h.ServeHTTP(w, r) return } http.Error(w, "empty handler", 500) } func (b *LocalBackend) serveFileOrDirectory(w http.ResponseWriter, r *http.Request, fileOrDir, mountPoint string) { fi, err := os.Stat(fileOrDir) if err != nil { if os.IsNotExist(err) { http.NotFound(w, r) return } http.Error(w, err.Error(), 500) return } if fi.Mode().IsRegular() { if mountPoint != r.URL.Path { http.NotFound(w, r) return } f, err := os.Open(fileOrDir) if err != nil { http.Error(w, err.Error(), 500) return } defer f.Close() http.ServeContent(w, r, path.Base(mountPoint), fi.ModTime(), f) return } if !fi.IsDir() { http.Error(w, "not a file or directory", 500) return } if len(r.URL.Path) < len(mountPoint) && r.URL.Path+"/" == mountPoint { http.Redirect(w, r, mountPoint, http.StatusFound) return } var fs http.Handler = http.FileServer(http.Dir(fileOrDir)) if mountPoint != "/" { fs = http.StripPrefix(strings.TrimSuffix(mountPoint, "/"), fs) } fs.ServeHTTP(&fixLocationHeaderResponseWriter{ ResponseWriter: w, mountPoint: mountPoint, }, r) } // fixLocationHeaderResponseWriter is an http.ResponseWriter wrapper that, upon // flushing HTTP headers, prefixes any Location header with the mount point. type fixLocationHeaderResponseWriter struct { http.ResponseWriter mountPoint string fixOnce sync.Once // guards call to fix } func (w *fixLocationHeaderResponseWriter) fix() { h := w.ResponseWriter.Header() if v := h.Get("Location"); v != "" { h.Set("Location", w.mountPoint+v) } } func (w *fixLocationHeaderResponseWriter) WriteHeader(code int) { w.fixOnce.Do(w.fix) w.ResponseWriter.WriteHeader(code) } func (w *fixLocationHeaderResponseWriter) Write(p []byte) (int, error) { w.fixOnce.Do(w.fix) return w.ResponseWriter.Write(p) } // expandProxyArg returns a URL from s, where s can be of form: // // * port number ("8080") // * host:port ("localhost:8080") // * full URL ("http://localhost:8080", in which case it's returned unchanged) // * insecure TLS ("https+insecure://127.0.0.1:4430") func expandProxyArg(s string) (targetURL string, insecureSkipVerify bool) { if s == "" { return "", false } if strings.HasPrefix(s, "http://") || strings.HasPrefix(s, "https://") { return s, false } if rest, ok := strings.CutPrefix(s, "https+insecure://"); ok { return "https://" + rest, true } if allNumeric(s) { return "http://127.0.0.1:" + s, false } return "http://" + s, false } func allNumeric(s string) bool { for i := 0; i < len(s); i++ { if s[i] < '0' || s[i] > '9' { return false } } return s != "" } func (b *LocalBackend) webServerConfig(hostname string, port uint16) (c ipn.WebServerConfigView, ok bool) { key := ipn.HostPort(fmt.Sprintf("%s:%v", hostname, port)) b.mu.Lock() defer b.mu.Unlock() if !b.serveConfig.Valid() { return c, false } return b.serveConfig.FindWeb(key) } func (b *LocalBackend) getTLSServeCertForPort(port uint16) func(hi *tls.ClientHelloInfo) (*tls.Certificate, error) { return func(hi *tls.ClientHelloInfo) (*tls.Certificate, error) { if hi == nil || hi.ServerName == "" { return nil, errors.New("no SNI ServerName") } _, ok := b.webServerConfig(hi.ServerName, port) if !ok { return nil, errors.New("no webserver configured for name/port") } ctx, cancel := context.WithTimeout(context.Background(), time.Minute) defer cancel() pair, err := b.GetCertPEM(ctx, hi.ServerName) if err != nil { return nil, err } cert, err := tls.X509KeyPair(pair.CertPEM, pair.KeyPEM) if err != nil { return nil, err } return &cert, nil } }