package agent import ( "bytes" "crypto/tls" "encoding/json" "errors" "fmt" "net" "net/http" "net/http/pprof" "os" "strconv" "strings" "time" "github.com/NYTimes/gziphandler" assetfs "github.com/elazarl/go-bindata-assetfs" "github.com/gorilla/websocket" "github.com/hashicorp/go-connlimit" log "github.com/hashicorp/go-hclog" "github.com/hashicorp/go-msgpack/codec" "github.com/hashicorp/nomad/helper/noxssrw" "github.com/hashicorp/nomad/helper/tlsutil" "github.com/hashicorp/nomad/nomad/structs" "github.com/rs/cors" ) const ( // ErrInvalidMethod is used if the HTTP method is not supported ErrInvalidMethod = "Invalid method" // ErrEntOnly is the error returned if accessing an enterprise only // endpoint ErrEntOnly = "Nomad Enterprise only endpoint" // ContextKeyReqID is a unique ID for a given request ContextKeyReqID = "requestID" // MissingRequestID is a placeholder if we cannot retrieve a request // UUID from context MissingRequestID = "" ) var ( // Set to false by stub_asset if the ui build tag isn't enabled uiEnabled = true // Overridden if the ui build tag isn't enabled stubHTML = "" // allowCORS sets permissive CORS headers for a handler allowCORS = cors.New(cors.Options{ AllowedOrigins: []string{"*"}, AllowedMethods: []string{"HEAD", "GET"}, AllowedHeaders: []string{"*"}, AllowCredentials: true, }) ) type handlerFn func(resp http.ResponseWriter, req *http.Request) (interface{}, error) type handlerByteFn func(resp http.ResponseWriter, req *http.Request) ([]byte, error) // HTTPServer is used to wrap an Agent and expose it over an HTTP interface type HTTPServer struct { agent *Agent mux *http.ServeMux listener net.Listener listenerCh chan struct{} logger log.Logger Addr string wsUpgrader *websocket.Upgrader } // NewHTTPServer starts new HTTP server over the agent func NewHTTPServer(agent *Agent, config *Config) (*HTTPServer, error) { // Start the listener lnAddr, err := net.ResolveTCPAddr("tcp", config.normalizedAddrs.HTTP) if err != nil { return nil, err } ln, err := config.Listener("tcp", lnAddr.IP.String(), lnAddr.Port) if err != nil { return nil, fmt.Errorf("failed to start HTTP listener: %v", err) } // If TLS is enabled, wrap the listener with a TLS listener if config.TLSConfig.EnableHTTP { tlsConf, err := tlsutil.NewTLSConfiguration(config.TLSConfig, config.TLSConfig.VerifyHTTPSClient, true) if err != nil { return nil, err } tlsConfig, err := tlsConf.IncomingTLSConfig() if err != nil { return nil, err } ln = tls.NewListener(tcpKeepAliveListener{ln.(*net.TCPListener)}, tlsConfig) } // Create the mux mux := http.NewServeMux() wsUpgrader := &websocket.Upgrader{ ReadBufferSize: 2048, WriteBufferSize: 2048, } // Create the server srv := &HTTPServer{ agent: agent, mux: mux, listener: ln, listenerCh: make(chan struct{}), logger: agent.httpLogger, Addr: ln.Addr().String(), wsUpgrader: wsUpgrader, } srv.registerHandlers(config.EnableDebug) // Handle requests with gzip compression gzip, err := gziphandler.GzipHandlerWithOpts(gziphandler.MinSize(0)) if err != nil { return nil, err } // Get connection handshake timeout limit handshakeTimeout, err := time.ParseDuration(config.Limits.HTTPSHandshakeTimeout) if err != nil { return nil, fmt.Errorf("error parsing https_handshake_timeout: %v", err) } else if handshakeTimeout < 0 { return nil, fmt.Errorf("https_handshake_timeout must be >= 0") } // Get max connection limit maxConns := 0 if mc := config.Limits.HTTPMaxConnsPerClient; mc != nil { maxConns = *mc } if maxConns < 0 { return nil, fmt.Errorf("http_max_conns_per_client must be >= 0") } // Create HTTP server with timeouts httpServer := http.Server{ Addr: srv.Addr, Handler: gzip(mux), ConnState: makeConnState(config.TLSConfig.EnableHTTP, handshakeTimeout, maxConns), ErrorLog: newHTTPServerLogger(srv.logger), } go func() { defer close(srv.listenerCh) httpServer.Serve(ln) }() return srv, nil } // makeConnState returns a ConnState func for use in an http.Server. If // isTLS=true and handshakeTimeout>0 then the handshakeTimeout will be applied // as a connection deadline to new connections and removed when the connection // is active (meaning it has successfully completed the TLS handshake). // // If limit > 0, a per-address connection limit will be enabled regardless of // TLS. If connLimit == 0 there is no connection limit. func makeConnState(isTLS bool, handshakeTimeout time.Duration, connLimit int) func(conn net.Conn, state http.ConnState) { if !isTLS || handshakeTimeout == 0 { if connLimit > 0 { // Still return the connection limiter return connlimit.NewLimiter(connlimit.Config{ MaxConnsPerClientIP: connLimit, }).HTTPConnStateFunc() } return nil } if connLimit > 0 { // Return conn state callback with connection limiting and a // handshake timeout. connLimiter := connlimit.NewLimiter(connlimit.Config{ MaxConnsPerClientIP: connLimit, }).HTTPConnStateFunc() return func(conn net.Conn, state http.ConnState) { switch state { case http.StateNew: // Set deadline to prevent slow send before TLS handshake or first // byte of request. conn.SetDeadline(time.Now().Add(handshakeTimeout)) case http.StateActive: // Clear read deadline. We should maybe set read timeouts more // generally but that's a bigger task as some HTTP endpoints may // stream large requests and responses (e.g. snapshot) so we can't // set sensible blanket timeouts here. conn.SetDeadline(time.Time{}) } // Call connection limiter connLimiter(conn, state) } } // Return conn state callback with just a handshake timeout // (connection limiting disabled). return func(conn net.Conn, state http.ConnState) { switch state { case http.StateNew: // Set deadline to prevent slow send before TLS handshake or first // byte of request. conn.SetDeadline(time.Now().Add(handshakeTimeout)) case http.StateActive: // Clear read deadline. We should maybe set read timeouts more // generally but that's a bigger task as some HTTP endpoints may // stream large requests and responses (e.g. snapshot) so we can't // set sensible blanket timeouts here. conn.SetDeadline(time.Time{}) } } } // tcpKeepAliveListener sets TCP keep-alive timeouts on accepted // connections. It's used by NewHttpServer so // dead TCP connections eventually go away. type tcpKeepAliveListener struct { *net.TCPListener } func (ln tcpKeepAliveListener) Accept() (c net.Conn, err error) { tc, err := ln.AcceptTCP() if err != nil { return } tc.SetKeepAlive(true) tc.SetKeepAlivePeriod(30 * time.Second) return tc, nil } // Shutdown is used to shutdown the HTTP server func (s *HTTPServer) Shutdown() { if s != nil { s.logger.Debug("shutting down http server") s.listener.Close() <-s.listenerCh // block until http.Serve has returned. } } // registerHandlers is used to attach our handlers to the mux func (s *HTTPServer) registerHandlers(enableDebug bool) { s.mux.HandleFunc("/v1/jobs", s.wrap(s.JobsRequest)) s.mux.HandleFunc("/v1/jobs/parse", s.wrap(s.JobsParseRequest)) s.mux.HandleFunc("/v1/job/", s.wrap(s.JobSpecificRequest)) s.mux.HandleFunc("/v1/nodes", s.wrap(s.NodesRequest)) s.mux.HandleFunc("/v1/node/", s.wrap(s.NodeSpecificRequest)) s.mux.HandleFunc("/v1/allocations", s.wrap(s.AllocsRequest)) s.mux.HandleFunc("/v1/allocation/", s.wrap(s.AllocSpecificRequest)) s.mux.HandleFunc("/v1/evaluations", s.wrap(s.EvalsRequest)) s.mux.HandleFunc("/v1/evaluation/", s.wrap(s.EvalSpecificRequest)) s.mux.HandleFunc("/v1/deployments", s.wrap(s.DeploymentsRequest)) s.mux.HandleFunc("/v1/deployment/", s.wrap(s.DeploymentSpecificRequest)) s.mux.HandleFunc("/v1/volumes", s.wrap(s.CSIVolumesRequest)) s.mux.HandleFunc("/v1/volume/csi/", s.wrap(s.CSIVolumeSpecificRequest)) s.mux.HandleFunc("/v1/plugins", s.wrap(s.CSIPluginsRequest)) s.mux.HandleFunc("/v1/plugin/csi/", s.wrap(s.CSIPluginSpecificRequest)) s.mux.HandleFunc("/v1/acl/policies", s.wrap(s.ACLPoliciesRequest)) s.mux.HandleFunc("/v1/acl/policy/", s.wrap(s.ACLPolicySpecificRequest)) s.mux.HandleFunc("/v1/acl/bootstrap", s.wrap(s.ACLTokenBootstrap)) s.mux.HandleFunc("/v1/acl/tokens", s.wrap(s.ACLTokensRequest)) s.mux.HandleFunc("/v1/acl/token", s.wrap(s.ACLTokenSpecificRequest)) s.mux.HandleFunc("/v1/acl/token/", s.wrap(s.ACLTokenSpecificRequest)) s.mux.Handle("/v1/client/fs/", wrapCORS(s.wrap(s.FsRequest))) s.mux.HandleFunc("/v1/client/gc", s.wrap(s.ClientGCRequest)) s.mux.Handle("/v1/client/stats", wrapCORS(s.wrap(s.ClientStatsRequest))) s.mux.Handle("/v1/client/allocation/", wrapCORS(s.wrap(s.ClientAllocRequest))) s.mux.HandleFunc("/v1/agent/self", s.wrap(s.AgentSelfRequest)) s.mux.HandleFunc("/v1/agent/join", s.wrap(s.AgentJoinRequest)) s.mux.HandleFunc("/v1/agent/members", s.wrap(s.AgentMembersRequest)) s.mux.HandleFunc("/v1/agent/force-leave", s.wrap(s.AgentForceLeaveRequest)) s.mux.HandleFunc("/v1/agent/servers", s.wrap(s.AgentServersRequest)) s.mux.HandleFunc("/v1/agent/keyring/", s.wrap(s.KeyringOperationRequest)) s.mux.HandleFunc("/v1/agent/health", s.wrap(s.HealthRequest)) s.mux.HandleFunc("/v1/agent/host", s.wrap(s.AgentHostRequest)) // Monitor is *not* an untrusted endpoint despite the log contents // potentially containing unsanitized user input. Monitor, like // "/v1/client/fs/logs", explicitly sets a "text/plain" or // "application/json" Content-Type depending on the ?plain= query // parameter. s.mux.HandleFunc("/v1/agent/monitor", s.wrap(s.AgentMonitor)) s.mux.HandleFunc("/v1/agent/pprof/", s.wrapNonJSON(s.AgentPprofRequest)) s.mux.HandleFunc("/v1/metrics", s.wrap(s.MetricsRequest)) s.mux.HandleFunc("/v1/validate/job", s.wrap(s.ValidateJobRequest)) s.mux.HandleFunc("/v1/regions", s.wrap(s.RegionListRequest)) s.mux.HandleFunc("/v1/scaling/policies", s.wrap(s.ScalingPoliciesRequest)) s.mux.HandleFunc("/v1/scaling/policy/", s.wrap(s.ScalingPolicySpecificRequest)) s.mux.HandleFunc("/v1/status/leader", s.wrap(s.StatusLeaderRequest)) s.mux.HandleFunc("/v1/status/peers", s.wrap(s.StatusPeersRequest)) s.mux.HandleFunc("/v1/search", s.wrap(s.SearchRequest)) s.mux.HandleFunc("/v1/operator/raft/", s.wrap(s.OperatorRequest)) s.mux.HandleFunc("/v1/operator/autopilot/configuration", s.wrap(s.OperatorAutopilotConfiguration)) s.mux.HandleFunc("/v1/operator/autopilot/health", s.wrap(s.OperatorServerHealth)) s.mux.HandleFunc("/v1/operator/snapshot", s.wrap(s.SnapshotRequest)) s.mux.HandleFunc("/v1/system/gc", s.wrap(s.GarbageCollectRequest)) s.mux.HandleFunc("/v1/system/reconcile/summaries", s.wrap(s.ReconcileJobSummaries)) s.mux.HandleFunc("/v1/operator/scheduler/configuration", s.wrap(s.OperatorSchedulerConfiguration)) s.mux.HandleFunc("/v1/event/stream", s.wrap(s.EventStream)) s.mux.HandleFunc("/v1/namespaces", s.wrap(s.NamespacesRequest)) s.mux.HandleFunc("/v1/namespace", s.wrap(s.NamespaceCreateRequest)) s.mux.HandleFunc("/v1/namespace/", s.wrap(s.NamespaceSpecificRequest)) if uiEnabled { s.mux.Handle("/ui/", http.StripPrefix("/ui/", s.handleUI(http.FileServer(&UIAssetWrapper{FileSystem: assetFS()})))) } else { // Write the stubHTML s.mux.HandleFunc("/ui/", func(w http.ResponseWriter, r *http.Request) { w.Write([]byte(stubHTML)) }) } s.mux.Handle("/", s.handleRootFallthrough()) if enableDebug { if !s.agent.config.DevMode { s.logger.Warn("enable_debug is set to true. This is insecure and should not be enabled in production") } s.mux.HandleFunc("/debug/pprof/", pprof.Index) s.mux.HandleFunc("/debug/pprof/cmdline", pprof.Cmdline) s.mux.HandleFunc("/debug/pprof/profile", pprof.Profile) s.mux.HandleFunc("/debug/pprof/symbol", pprof.Symbol) s.mux.HandleFunc("/debug/pprof/trace", pprof.Trace) } // Register enterprise endpoints. s.registerEnterpriseHandlers() } // HTTPCodedError is used to provide the HTTP error code type HTTPCodedError interface { error Code() int } type UIAssetWrapper struct { FileSystem *assetfs.AssetFS } func (fs *UIAssetWrapper) Open(name string) (http.File, error) { if file, err := fs.FileSystem.Open(name); err == nil { return file, nil } else { // serve index.html instead of 404ing if err == os.ErrNotExist { return fs.FileSystem.Open("index.html") } return nil, err } } func CodedError(c int, s string) HTTPCodedError { return &codedError{s, c} } type codedError struct { s string code int } func (e *codedError) Error() string { return e.s } func (e *codedError) Code() int { return e.code } func (s *HTTPServer) handleUI(h http.Handler) http.Handler { return http.HandlerFunc(func(w http.ResponseWriter, req *http.Request) { header := w.Header() header.Add("Content-Security-Policy", "default-src 'none'; connect-src *; img-src 'self' data:; script-src 'self'; style-src 'self' 'unsafe-inline'; form-action 'none'; frame-ancestors 'none'") h.ServeHTTP(w, req) return }) } func (s *HTTPServer) handleRootFallthrough() http.Handler { return s.auditHTTPHandler(http.HandlerFunc(func(w http.ResponseWriter, req *http.Request) { if req.URL.Path == "/" { http.Redirect(w, req, "/ui/", 307) } else { w.WriteHeader(http.StatusNotFound) } })) } func errCodeFromHandler(err error) (int, string) { if err == nil { return 0, "" } code := 500 errMsg := err.Error() if http, ok := err.(HTTPCodedError); ok { code = http.Code() } else if ecode, emsg, ok := structs.CodeFromRPCCodedErr(err); ok { code = ecode errMsg = emsg } else { // RPC errors get wrapped, so manually unwrap by only looking at their suffix if strings.HasSuffix(errMsg, structs.ErrPermissionDenied.Error()) { errMsg = structs.ErrPermissionDenied.Error() code = 403 } else if strings.HasSuffix(errMsg, structs.ErrTokenNotFound.Error()) { errMsg = structs.ErrTokenNotFound.Error() code = 403 } } return code, errMsg } // wrap is used to wrap functions to make them more convenient func (s *HTTPServer) wrap(handler func(resp http.ResponseWriter, req *http.Request) (interface{}, error)) func(resp http.ResponseWriter, req *http.Request) { f := func(resp http.ResponseWriter, req *http.Request) { setHeaders(resp, s.agent.config.HTTPAPIResponseHeaders) // Invoke the handler reqURL := req.URL.String() start := time.Now() defer func() { s.logger.Debug("request complete", "method", req.Method, "path", reqURL, "duration", time.Now().Sub(start)) }() obj, err := s.auditHandler(handler)(resp, req) // Check for an error HAS_ERR: if err != nil { code := 500 errMsg := err.Error() if http, ok := err.(HTTPCodedError); ok { code = http.Code() } else if ecode, emsg, ok := structs.CodeFromRPCCodedErr(err); ok { code = ecode errMsg = emsg } else { // RPC errors get wrapped, so manually unwrap by only looking at their suffix if strings.HasSuffix(errMsg, structs.ErrPermissionDenied.Error()) { errMsg = structs.ErrPermissionDenied.Error() code = 403 } else if strings.HasSuffix(errMsg, structs.ErrTokenNotFound.Error()) { errMsg = structs.ErrTokenNotFound.Error() code = 403 } } resp.WriteHeader(code) resp.Write([]byte(errMsg)) if isAPIClientError(code) { s.logger.Debug("request failed", "method", req.Method, "path", reqURL, "error", err, "code", code) } else { s.logger.Error("request failed", "method", req.Method, "path", reqURL, "error", err, "code", code) } return } prettyPrint := false if v, ok := req.URL.Query()["pretty"]; ok { if len(v) > 0 && (len(v[0]) == 0 || v[0] != "0") { prettyPrint = true } } // Write out the JSON object if obj != nil { var buf bytes.Buffer if prettyPrint { enc := codec.NewEncoder(&buf, structs.JsonHandlePretty) err = enc.Encode(obj) if err == nil { buf.Write([]byte("\n")) } } else { enc := codec.NewEncoder(&buf, structs.JsonHandle) err = enc.Encode(obj) } if err != nil { goto HAS_ERR } resp.Header().Set("Content-Type", "application/json") resp.Write(buf.Bytes()) } } return f } // wrapNonJSON is used to wrap functions returning non JSON // serializeable data to make them more convenient. It is primarily // responsible for setting nomad headers and logging. // Handler functions are responsible for setting Content-Type Header func (s *HTTPServer) wrapNonJSON(handler func(resp http.ResponseWriter, req *http.Request) ([]byte, error)) func(resp http.ResponseWriter, req *http.Request) { f := func(resp http.ResponseWriter, req *http.Request) { setHeaders(resp, s.agent.config.HTTPAPIResponseHeaders) // Invoke the handler reqURL := req.URL.String() start := time.Now() defer func() { s.logger.Debug("request complete", "method", req.Method, "path", reqURL, "duration", time.Now().Sub(start)) }() obj, err := s.auditNonJSONHandler(handler)(resp, req) // Check for an error if err != nil { code, errMsg := errCodeFromHandler(err) resp.WriteHeader(code) resp.Write([]byte(errMsg)) if isAPIClientError(code) { s.logger.Debug("request failed", "method", req.Method, "path", reqURL, "error", err, "code", code) } else { s.logger.Error("request failed", "method", req.Method, "path", reqURL, "error", err, "code", code) } return } // write response if obj != nil { resp.Write(obj) } } return f } // isAPIClientError returns true if the passed http code represents a client error func isAPIClientError(code int) bool { return 400 <= code && code <= 499 } // decodeBody is used to decode a JSON request body func decodeBody(req *http.Request, out interface{}) error { if req.Body == http.NoBody { return errors.New("Request body is empty") } dec := json.NewDecoder(req.Body) return dec.Decode(&out) } // setIndex is used to set the index response header func setIndex(resp http.ResponseWriter, index uint64) { resp.Header().Set("X-Nomad-Index", strconv.FormatUint(index, 10)) } // setKnownLeader is used to set the known leader header func setKnownLeader(resp http.ResponseWriter, known bool) { s := "true" if !known { s = "false" } resp.Header().Set("X-Nomad-KnownLeader", s) } // setLastContact is used to set the last contact header func setLastContact(resp http.ResponseWriter, last time.Duration) { lastMsec := uint64(last / time.Millisecond) resp.Header().Set("X-Nomad-LastContact", strconv.FormatUint(lastMsec, 10)) } // setMeta is used to set the query response meta data func setMeta(resp http.ResponseWriter, m *structs.QueryMeta) { setIndex(resp, m.Index) setLastContact(resp, m.LastContact) setKnownLeader(resp, m.KnownLeader) } // setHeaders is used to set canonical response header fields func setHeaders(resp http.ResponseWriter, headers map[string]string) { for field, value := range headers { resp.Header().Set(http.CanonicalHeaderKey(field), value) } } // parseWait is used to parse the ?wait and ?index query params // Returns true on error func parseWait(resp http.ResponseWriter, req *http.Request, b *structs.QueryOptions) bool { query := req.URL.Query() if wait := query.Get("wait"); wait != "" { dur, err := time.ParseDuration(wait) if err != nil { resp.WriteHeader(400) resp.Write([]byte("Invalid wait time")) return true } b.MaxQueryTime = dur } if idx := query.Get("index"); idx != "" { index, err := strconv.ParseUint(idx, 10, 64) if err != nil { resp.WriteHeader(400) resp.Write([]byte("Invalid index")) return true } b.MinQueryIndex = index } return false } // parseConsistency is used to parse the ?stale query params. func parseConsistency(req *http.Request, b *structs.QueryOptions) { query := req.URL.Query() if _, ok := query["stale"]; ok { b.AllowStale = true } } // parsePrefix is used to parse the ?prefix query param func parsePrefix(req *http.Request, b *structs.QueryOptions) { query := req.URL.Query() if prefix := query.Get("prefix"); prefix != "" { b.Prefix = prefix } } // parseRegion is used to parse the ?region query param func (s *HTTPServer) parseRegion(req *http.Request, r *string) { if other := req.URL.Query().Get("region"); other != "" { *r = other } else if *r == "" { *r = s.agent.config.Region } } // parseNamespace is used to parse the ?namespace parameter func parseNamespace(req *http.Request, n *string) { if other := req.URL.Query().Get("namespace"); other != "" { *n = other } else if *n == "" { *n = structs.DefaultNamespace } } // parseBool parses a query parameter to a boolean or returns (nil, nil) if the // parameter is not present. func parseBool(req *http.Request, field string) (*bool, error) { if str := req.URL.Query().Get(field); str != "" { param, err := strconv.ParseBool(str) if err != nil { return nil, fmt.Errorf("Failed to parse value of %q (%v) as a bool: %v", field, str, err) } return ¶m, nil } return nil, nil } // parseToken is used to parse the X-Nomad-Token param func (s *HTTPServer) parseToken(req *http.Request, token *string) { if other := req.Header.Get("X-Nomad-Token"); other != "" { *token = other return } } // parse is a convenience method for endpoints that need to parse multiple flags // It sets r to the region and b to the QueryOptions in req func (s *HTTPServer) parse(resp http.ResponseWriter, req *http.Request, r *string, b *structs.QueryOptions) bool { s.parseRegion(req, r) s.parseToken(req, &b.AuthToken) parseConsistency(req, b) parsePrefix(req, b) parseNamespace(req, &b.Namespace) return parseWait(resp, req, b) } // parseWriteRequest is a convenience method for endpoints that need to parse a // write request. func (s *HTTPServer) parseWriteRequest(req *http.Request, w *structs.WriteRequest) { parseNamespace(req, &w.Namespace) s.parseToken(req, &w.AuthToken) s.parseRegion(req, &w.Region) } // wrapUntrustedContent wraps handlers in a http.ResponseWriter that prevents // setting Content-Types that a browser may render (eg text/html). Any API that // returns service-generated content (eg /v1/client/fs/cat) must be wrapped. func (s *HTTPServer) wrapUntrustedContent(handler handlerFn) handlerFn { return func(resp http.ResponseWriter, req *http.Request) (interface{}, error) { resp, closeWriter := noxssrw.NewResponseWriter(resp) defer func() { if _, err := closeWriter(); err != nil { // Can't write an error response at this point so just // log. s.wrap does not even log when resp.Write fails, // so log at low level. s.logger.Debug("error writing HTTP response", "error", err, "method", req.Method, "path", req.URL.String()) } }() // Call the wrapped handler return handler(resp, req) } } // wrapCORS wraps a HandlerFunc in allowCORS and returns a http.Handler func wrapCORS(f func(http.ResponseWriter, *http.Request)) http.Handler { return allowCORS.Handler(http.HandlerFunc(f)) }