package agent import ( "fmt" "net/http" "strconv" "time" "github.com/hashicorp/consul/api" "github.com/hashicorp/consul/consul/structs" multierror "github.com/hashicorp/go-multierror" "github.com/hashicorp/raft" "strings" ) // OperatorRaftConfiguration is used to inspect the current Raft configuration. // This supports the stale query mode in case the cluster doesn't have a leader. func (s *HTTPServer) OperatorRaftConfiguration(resp http.ResponseWriter, req *http.Request) (interface{}, error) { if req.Method != "GET" { resp.WriteHeader(http.StatusMethodNotAllowed) return nil, nil } var args structs.DCSpecificRequest if done := s.parse(resp, req, &args.Datacenter, &args.QueryOptions); done { return nil, nil } var reply structs.RaftConfigurationResponse if err := s.agent.RPC("Operator.RaftGetConfiguration", &args, &reply); err != nil { return nil, err } return reply, nil } // OperatorRaftPeer supports actions on Raft peers. Currently we only support // removing peers by address. func (s *HTTPServer) OperatorRaftPeer(resp http.ResponseWriter, req *http.Request) (interface{}, error) { if req.Method != "DELETE" { resp.WriteHeader(http.StatusMethodNotAllowed) return nil, nil } var args structs.RaftPeerByAddressRequest s.parseDC(req, &args.Datacenter) s.parseToken(req, &args.Token) params := req.URL.Query() if _, ok := params["address"]; ok { args.Address = raft.ServerAddress(params.Get("address")) } else { resp.WriteHeader(http.StatusBadRequest) resp.Write([]byte("Must specify ?address with IP:port of peer to remove")) return nil, nil } var reply struct{} if err := s.agent.RPC("Operator.RaftRemovePeerByAddress", &args, &reply); err != nil { return nil, err } return nil, nil } type keyringArgs struct { Key string Token string RelayFactor uint8 } // OperatorKeyringEndpoint handles keyring operations (install, list, use, remove) func (s *HTTPServer) OperatorKeyringEndpoint(resp http.ResponseWriter, req *http.Request) (interface{}, error) { var args keyringArgs if req.Method == "POST" || req.Method == "PUT" || req.Method == "DELETE" { if err := decodeBody(req, &args, nil); err != nil { resp.WriteHeader(400) resp.Write([]byte(fmt.Sprintf("Request decode failed: %v", err))) return nil, nil } } s.parseToken(req, &args.Token) // Parse relay factor if relayFactor := req.URL.Query().Get("relay-factor"); relayFactor != "" { n, err := strconv.Atoi(relayFactor) if err != nil { resp.WriteHeader(400) resp.Write([]byte(fmt.Sprintf("Error parsing relay factor: %v", err))) return nil, nil } args.RelayFactor, err = ParseRelayFactor(n) if err != nil { resp.WriteHeader(400) resp.Write([]byte(fmt.Sprintf("Invalid relay factor: %v", err))) return nil, nil } } // Switch on the method switch req.Method { case "GET": return s.KeyringList(resp, req, &args) case "POST": return s.KeyringInstall(resp, req, &args) case "PUT": return s.KeyringUse(resp, req, &args) case "DELETE": return s.KeyringRemove(resp, req, &args) default: resp.WriteHeader(http.StatusMethodNotAllowed) return nil, nil } } // KeyringInstall is used to install a new gossip encryption key into the cluster func (s *HTTPServer) KeyringInstall(resp http.ResponseWriter, req *http.Request, args *keyringArgs) (interface{}, error) { responses, err := s.agent.InstallKey(args.Key, args.Token, args.RelayFactor) if err != nil { return nil, err } return nil, keyringErrorsOrNil(responses.Responses) } // KeyringList is used to list the keys installed in the cluster func (s *HTTPServer) KeyringList(resp http.ResponseWriter, req *http.Request, args *keyringArgs) (interface{}, error) { responses, err := s.agent.ListKeys(args.Token, args.RelayFactor) if err != nil { return nil, err } return responses.Responses, keyringErrorsOrNil(responses.Responses) } // KeyringRemove is used to list the keys installed in the cluster func (s *HTTPServer) KeyringRemove(resp http.ResponseWriter, req *http.Request, args *keyringArgs) (interface{}, error) { responses, err := s.agent.RemoveKey(args.Key, args.Token, args.RelayFactor) if err != nil { return nil, err } return nil, keyringErrorsOrNil(responses.Responses) } // KeyringUse is used to change the primary gossip encryption key func (s *HTTPServer) KeyringUse(resp http.ResponseWriter, req *http.Request, args *keyringArgs) (interface{}, error) { responses, err := s.agent.UseKey(args.Key, args.Token, args.RelayFactor) if err != nil { return nil, err } return nil, keyringErrorsOrNil(responses.Responses) } func keyringErrorsOrNil(responses []*structs.KeyringResponse) error { var errs error for _, response := range responses { if response.Error != "" { pool := response.Datacenter + " (LAN)" if response.WAN { pool = "WAN" } errs = multierror.Append(errs, fmt.Errorf("%s error: %s", pool, response.Error)) for key, message := range response.Messages { errs = multierror.Append(errs, fmt.Errorf("%s: %s", key, message)) } } } return errs } // OperatorAutopilotConfiguration is used to inspect the current Autopilot configuration. // This supports the stale query mode in case the cluster doesn't have a leader. func (s *HTTPServer) OperatorAutopilotConfiguration(resp http.ResponseWriter, req *http.Request) (interface{}, error) { // Switch on the method switch req.Method { case "GET": var args structs.DCSpecificRequest if done := s.parse(resp, req, &args.Datacenter, &args.QueryOptions); done { return nil, nil } var reply structs.AutopilotConfig if err := s.agent.RPC("Operator.AutopilotGetConfiguration", &args, &reply); err != nil { return nil, err } out := api.AutopilotConfiguration{ CleanupDeadServers: reply.CleanupDeadServers, LastContactThreshold: api.NewReadableDuration(reply.LastContactThreshold), MaxTrailingLogs: reply.MaxTrailingLogs, ServerStabilizationTime: api.NewReadableDuration(reply.ServerStabilizationTime), CreateIndex: reply.CreateIndex, ModifyIndex: reply.ModifyIndex, } return out, nil case "PUT": var args structs.AutopilotSetConfigRequest s.parseDC(req, &args.Datacenter) s.parseToken(req, &args.Token) var conf api.AutopilotConfiguration if err := decodeBody(req, &conf, FixupConfigDurations); err != nil { resp.WriteHeader(400) resp.Write([]byte(fmt.Sprintf("Error parsing autopilot config: %v", err))) return nil, nil } args.Config = structs.AutopilotConfig{ CleanupDeadServers: conf.CleanupDeadServers, LastContactThreshold: conf.LastContactThreshold.Duration(), MaxTrailingLogs: conf.MaxTrailingLogs, ServerStabilizationTime: conf.ServerStabilizationTime.Duration(), } // Check for cas value params := req.URL.Query() if _, ok := params["cas"]; ok { casVal, err := strconv.ParseUint(params.Get("cas"), 10, 64) if err != nil { resp.WriteHeader(400) resp.Write([]byte(fmt.Sprintf("Error parsing cas value: %v", err))) return nil, nil } args.Config.ModifyIndex = casVal args.CAS = true } var reply bool if err := s.agent.RPC("Operator.AutopilotSetConfiguration", &args, &reply); err != nil { return nil, err } // Only use the out value if this was a CAS if !args.CAS { return true, nil } else { return reply, nil } default: resp.WriteHeader(http.StatusMethodNotAllowed) return nil, nil } } // FixupConfigDurations is used to handle parsing the duration fields in // the Autopilot config struct func FixupConfigDurations(raw interface{}) error { rawMap, ok := raw.(map[string]interface{}) if !ok { return nil } for key, val := range rawMap { if strings.ToLower(key) == "lastcontactthreshold" || strings.ToLower(key) == "serverstabilizationtime" { // Convert a string value into an integer if vStr, ok := val.(string); ok { dur, err := time.ParseDuration(vStr) if err != nil { return err } rawMap[key] = dur } } } return nil } // OperatorServerHealth is used to get the health of the servers in the local DC func (s *HTTPServer) OperatorServerHealth(resp http.ResponseWriter, req *http.Request) (interface{}, error) { if req.Method != "GET" { resp.WriteHeader(http.StatusMethodNotAllowed) return nil, nil } var args structs.DCSpecificRequest if done := s.parse(resp, req, &args.Datacenter, &args.QueryOptions); done { return nil, nil } var reply structs.OperatorHealthReply if err := s.agent.RPC("Operator.ServerHealth", &args, &reply); err != nil { return nil, err } // Reply with status 429 if something is unhealthy if !reply.Healthy { resp.WriteHeader(http.StatusTooManyRequests) } out := &api.OperatorHealthReply{ Healthy: reply.Healthy, FailureTolerance: reply.FailureTolerance, } for _, server := range reply.Servers { out.Servers = append(out.Servers, api.ServerHealth{ ID: server.ID, Name: server.Name, SerfStatus: server.SerfStatus.String(), LastContact: api.NewReadableDuration(server.LastContact), LastTerm: server.LastTerm, LastIndex: server.LastIndex, Healthy: server.Healthy, Voter: server.Voter, StableSince: server.StableSince.Round(time.Second).UTC(), }) } return out, nil }