// Copyright (c) HashiCorp, Inc. // SPDX-License-Identifier: MPL-2.0 package raft import ( "context" "encoding/json" "errors" "fmt" "math" "os" "strconv" "sync" "time" "github.com/armon/go-metrics" "github.com/hashicorp/go-secure-stdlib/parseutil" "github.com/hashicorp/go-secure-stdlib/strutil" "github.com/hashicorp/raft" autopilot "github.com/hashicorp/raft-autopilot" "github.com/mitchellh/mapstructure" "go.uber.org/atomic" ) type CleanupDeadServersValue int const ( CleanupDeadServersUnset CleanupDeadServersValue = 0 CleanupDeadServersTrue CleanupDeadServersValue = 1 CleanupDeadServersFalse CleanupDeadServersValue = 2 AutopilotUpgradeVersionTag string = "upgrade_version" AutopilotRedundancyZoneTag string = "redundancy_zone" ) func (c CleanupDeadServersValue) Value() bool { switch c { case CleanupDeadServersTrue: return true default: return false } } // AutopilotConfig is used for querying/setting the Autopilot configuration. type AutopilotConfig struct { // CleanupDeadServers controls whether to remove dead servers from the Raft // peer list periodically or when a new server joins. CleanupDeadServers bool `mapstructure:"cleanup_dead_servers"` // CleanupDeadServersValue is used to shadow the CleanupDeadServers field in // storage. Having it as an int helps in knowing if the value was set explicitly // using the API or not. CleanupDeadServersValue CleanupDeadServersValue `mapstructure:"cleanup_dead_servers_value"` // LastContactThreshold is the limit on the amount of time a server can go // without leader contact before being considered unhealthy. LastContactThreshold time.Duration `mapstructure:"-"` // DeadServerLastContactThreshold is the limit on the amount of time a server // can go without leader contact before being considered failed. This takes // effect only when CleanupDeadServers is set. DeadServerLastContactThreshold time.Duration `mapstructure:"-"` // MaxTrailingLogs is the amount of entries in the Raft Log that a server can // be behind before being considered unhealthy. MaxTrailingLogs uint64 `mapstructure:"max_trailing_logs"` // MinQuorum sets the minimum number of servers allowed in a cluster before // autopilot can prune dead servers. MinQuorum uint `mapstructure:"min_quorum"` // ServerStabilizationTime is the minimum amount of time a server must be in a // stable, healthy state before it can be added to the cluster. Only applicable // with Raft protocol version 3 or higher. ServerStabilizationTime time.Duration `mapstructure:"-"` // (Enterprise-only) DisableUpgradeMigration will disable Autopilot's upgrade migration // strategy of waiting until enough newer-versioned servers have been added to the // cluster before promoting them to voters. DisableUpgradeMigration bool `mapstructure:"disable_upgrade_migration"` // (Enterprise-only) RedundancyZoneTag is the node tag to use for separating // servers into zones for redundancy. If left blank, this feature will be disabled. RedundancyZoneTag string `mapstructure:"redundancy_zone_tag"` // (Enterprise-only) UpgradeVersionTag is the node tag to use for version info when // performing upgrade migrations. If left blank, the Consul version will be used. UpgradeVersionTag string `mapstructure:"upgrade_version_tag"` } // Merge combines the supplied config with the receiver. Supplied ones take // priority. func (to *AutopilotConfig) Merge(from *AutopilotConfig) { if from == nil { return } if from.CleanupDeadServersValue != CleanupDeadServersUnset { to.CleanupDeadServers = from.CleanupDeadServersValue.Value() } if from.MinQuorum != 0 { to.MinQuorum = from.MinQuorum } if from.LastContactThreshold != 0 { to.LastContactThreshold = from.LastContactThreshold } if from.DeadServerLastContactThreshold != 0 { to.DeadServerLastContactThreshold = from.DeadServerLastContactThreshold } if from.MaxTrailingLogs != 0 { to.MaxTrailingLogs = from.MaxTrailingLogs } if from.ServerStabilizationTime != 0 { to.ServerStabilizationTime = from.ServerStabilizationTime } // UpgradeVersionTag and RedundancyZoneTag are purposely not included here since those values aren't user // controllable and should never change. to.DisableUpgradeMigration = from.DisableUpgradeMigration } // Clone returns a duplicate instance of AutopilotConfig with the exact same values. func (ac *AutopilotConfig) Clone() *AutopilotConfig { if ac == nil { return nil } return &AutopilotConfig{ CleanupDeadServers: ac.CleanupDeadServers, LastContactThreshold: ac.LastContactThreshold, DeadServerLastContactThreshold: ac.DeadServerLastContactThreshold, MaxTrailingLogs: ac.MaxTrailingLogs, MinQuorum: ac.MinQuorum, ServerStabilizationTime: ac.ServerStabilizationTime, UpgradeVersionTag: ac.UpgradeVersionTag, RedundancyZoneTag: ac.RedundancyZoneTag, DisableUpgradeMigration: ac.DisableUpgradeMigration, } } // MarshalJSON makes the autopilot config fields JSON compatible func (ac *AutopilotConfig) MarshalJSON() ([]byte, error) { return json.Marshal(map[string]interface{}{ "cleanup_dead_servers": ac.CleanupDeadServers, "cleanup_dead_servers_value": ac.CleanupDeadServersValue, "last_contact_threshold": ac.LastContactThreshold.String(), "dead_server_last_contact_threshold": ac.DeadServerLastContactThreshold.String(), "max_trailing_logs": ac.MaxTrailingLogs, "min_quorum": ac.MinQuorum, "server_stabilization_time": ac.ServerStabilizationTime.String(), "upgrade_version_tag": ac.UpgradeVersionTag, "redundancy_zone_tag": ac.RedundancyZoneTag, "disable_upgrade_migration": ac.DisableUpgradeMigration, }) } // UnmarshalJSON parses the autopilot config JSON blob func (ac *AutopilotConfig) UnmarshalJSON(b []byte) error { var data interface{} err := json.Unmarshal(b, &data) if err != nil { return err } conf := data.(map[string]interface{}) if err = mapstructure.WeakDecode(conf, ac); err != nil { return err } if ac.LastContactThreshold, err = parseutil.ParseDurationSecond(conf["last_contact_threshold"]); err != nil { return err } if ac.DeadServerLastContactThreshold, err = parseutil.ParseDurationSecond(conf["dead_server_last_contact_threshold"]); err != nil { return err } if ac.ServerStabilizationTime, err = parseutil.ParseDurationSecond(conf["server_stabilization_time"]); err != nil { return err } return nil } // FollowerState represents the information about peer that the leader tracks. type FollowerState struct { AppliedIndex uint64 LastHeartbeat time.Time LastTerm uint64 IsDead *atomic.Bool DesiredSuffrage string Version string UpgradeVersion string RedundancyZone string } // EchoRequestUpdate is here to avoid 1) the list of arguments to Update() getting huge 2) an import cycle on the vault package type EchoRequestUpdate struct { NodeID string AppliedIndex uint64 Term uint64 DesiredSuffrage string UpgradeVersion string SDKVersion string RedundancyZone string } // FollowerStates holds information about all the followers in the raft cluster // tracked by the leader. type FollowerStates struct { l sync.RWMutex followers map[string]*FollowerState } // NewFollowerStates creates a new FollowerStates object func NewFollowerStates() *FollowerStates { return &FollowerStates{ followers: make(map[string]*FollowerState), } } // Update the peer information in the follower states. Note that this function runs on the active node. func (s *FollowerStates) Update(req *EchoRequestUpdate) { s.l.Lock() defer s.l.Unlock() state, ok := s.followers[req.NodeID] if !ok { state = &FollowerState{ IsDead: atomic.NewBool(false), } s.followers[req.NodeID] = state } state.IsDead.Store(false) state.AppliedIndex = req.AppliedIndex state.LastTerm = req.Term state.DesiredSuffrage = req.DesiredSuffrage state.LastHeartbeat = time.Now() state.Version = req.SDKVersion state.UpgradeVersion = req.UpgradeVersion state.RedundancyZone = req.RedundancyZone } // Clear wipes all the information regarding peers in the follower states. func (s *FollowerStates) Clear() { s.l.Lock() for i := range s.followers { delete(s.followers, i) } s.l.Unlock() } // Delete the entry of a peer represented by the nodeID from follower states. func (s *FollowerStates) Delete(nodeID string) { s.l.Lock() delete(s.followers, nodeID) s.l.Unlock() } // MinIndex returns the minimum raft index applied in the raft cluster. func (s *FollowerStates) MinIndex() uint64 { var min uint64 = math.MaxUint64 minFunc := func(a, b uint64) uint64 { if a > b { return b } return a } s.l.RLock() for _, state := range s.followers { min = minFunc(min, state.AppliedIndex) } s.l.RUnlock() if min == math.MaxUint64 { return 0 } return min } // Ensure that the Delegate implements the ApplicationIntegration interface var _ autopilot.ApplicationIntegration = (*Delegate)(nil) // Delegate is an implementation of autopilot.ApplicationIntegration interface. // This is used by the autopilot library to retrieve information and to have // application specific tasks performed. type Delegate struct { *RaftBackend // dl is a lock dedicated for guarding delegate's fields dl sync.RWMutex inflightRemovals map[raft.ServerID]bool emptyVersionLogs map[raft.ServerID]struct{} } func NewDelegate(b *RaftBackend) *Delegate { return &Delegate{ RaftBackend: b, inflightRemovals: make(map[raft.ServerID]bool), emptyVersionLogs: make(map[raft.ServerID]struct{}), } } // AutopilotConfig is called by the autopilot library to know the desired // autopilot configuration. func (d *Delegate) AutopilotConfig() *autopilot.Config { d.l.RLock() config := &autopilot.Config{ CleanupDeadServers: d.autopilotConfig.CleanupDeadServers, LastContactThreshold: d.autopilotConfig.LastContactThreshold, MaxTrailingLogs: d.autopilotConfig.MaxTrailingLogs, MinQuorum: d.autopilotConfig.MinQuorum, ServerStabilizationTime: d.autopilotConfig.ServerStabilizationTime, Ext: d.autopilotConfigExt(), } d.l.RUnlock() return config } // NotifyState is called by the autopilot library whenever there is a state // change. We update a few metrics when this happens. func (d *Delegate) NotifyState(state *autopilot.State) { if d.raft.State() == raft.Leader { metrics.SetGauge([]string{"autopilot", "failure_tolerance"}, float32(state.FailureTolerance)) if state.Healthy { metrics.SetGauge([]string{"autopilot", "healthy"}, 1) } else { metrics.SetGauge([]string{"autopilot", "healthy"}, 0) } for id, state := range state.Servers { labels := []metrics.Label{ { Name: "node_id", Value: string(id), }, } if state.Health.Healthy { metrics.SetGaugeWithLabels([]string{"autopilot", "node", "healthy"}, 1, labels) } else { metrics.SetGaugeWithLabels([]string{"autopilot", "node", "healthy"}, 0, labels) } } } } // FetchServerStats is called by the autopilot library to retrieve information // about all the nodes in the raft cluster. func (d *Delegate) FetchServerStats(ctx context.Context, servers map[raft.ServerID]*autopilot.Server) map[raft.ServerID]*autopilot.ServerStats { ret := make(map[raft.ServerID]*autopilot.ServerStats) d.l.RLock() followerStates := d.followerStates d.l.RUnlock() followerStates.l.RLock() defer followerStates.l.RUnlock() now := time.Now() for id, followerState := range followerStates.followers { ret[raft.ServerID(id)] = &autopilot.ServerStats{ LastContact: now.Sub(followerState.LastHeartbeat), LastTerm: followerState.LastTerm, LastIndex: followerState.AppliedIndex, } } leaderState, _ := d.fsm.LatestState() ret[raft.ServerID(d.localID)] = &autopilot.ServerStats{ LastTerm: leaderState.Term, LastIndex: leaderState.Index, } return ret } // KnownServers is called by the autopilot library to know the status of each // node in the raft cluster. If the application thinks that certain nodes left, // it is here that we let the autopilot library know of the same. func (d *Delegate) KnownServers() map[raft.ServerID]*autopilot.Server { d.l.RLock() defer d.l.RUnlock() future := d.raft.GetConfiguration() if err := future.Error(); err != nil { d.logger.Error("failed to get raft configuration when computing known servers", "error", err) return nil } apServerStates := d.autopilot.GetState().Servers servers := future.Configuration().Servers serverIDs := make([]string, 0, len(servers)) for _, server := range servers { serverIDs = append(serverIDs, string(server.ID)) } d.followerStates.l.RLock() defer d.followerStates.l.RUnlock() ret := make(map[raft.ServerID]*autopilot.Server) for id, state := range d.followerStates.followers { // If the server is not in raft configuration, even if we received a follower // heartbeat, it shouldn't be a known server for autopilot. if !strutil.StrListContains(serverIDs, id) { continue } // If version isn't found in the state, fake it using the version from the leader so that autopilot // doesn't demote the node to a non-voter, just because of a missed heartbeat. currentServerID := raft.ServerID(id) followerVersion := state.Version leaderVersion := d.effectiveSDKVersion d.dl.Lock() if followerVersion == "" { if _, ok := d.emptyVersionLogs[currentServerID]; !ok { d.logger.Trace("received empty Vault version in heartbeat state. faking it with the leader version for now", "id", id, "leader version", leaderVersion) d.emptyVersionLogs[currentServerID] = struct{}{} } followerVersion = leaderVersion } else { delete(d.emptyVersionLogs, currentServerID) } d.dl.Unlock() server := &autopilot.Server{ ID: currentServerID, Name: id, RaftVersion: raft.ProtocolVersionMax, Meta: d.meta(state), Version: followerVersion, Ext: d.autopilotServerExt(state), } // As KnownServers is a delegate called by autopilot let's check if we already // had this data in the correct format and use it. If we don't (which sounds a // bit sad, unless this ISN'T a voter) then as a fail-safe, let's try what we've // done elsewhere in code to check the desired suffrage and manually set NodeType // based on whether that's a voter or not. If we don't do either of these // things, NodeType isn't set which means technically it's not a voter. // It shouldn't be a voter and end up in this state. if apServerState, found := apServerStates[raft.ServerID(id)]; found && apServerState.Server.NodeType != "" { server.NodeType = apServerState.Server.NodeType } else if state.DesiredSuffrage == "voter" { server.NodeType = autopilot.NodeVoter } switch state.IsDead.Load() { case true: d.logger.Debug("informing autopilot that the node left", "id", id) server.NodeStatus = autopilot.NodeLeft default: server.NodeStatus = autopilot.NodeAlive } ret[raft.ServerID(id)] = server } // Add the leader ret[raft.ServerID(d.localID)] = &autopilot.Server{ ID: raft.ServerID(d.localID), Name: d.localID, RaftVersion: raft.ProtocolVersionMax, NodeStatus: autopilot.NodeAlive, NodeType: autopilot.NodeVoter, // The leader must be a voter Meta: d.meta(&FollowerState{ UpgradeVersion: d.EffectiveVersion(), RedundancyZone: d.RedundancyZone(), }), Version: d.effectiveSDKVersion, Ext: d.autopilotServerExt(nil), IsLeader: true, } return ret } // RemoveFailedServer is called by the autopilot library when it desires a node // to be removed from the raft configuration. This function removes the node // from the raft cluster and stops tracking its information in follower states. // This function needs to return quickly. Hence removal is performed in a // goroutine. func (d *Delegate) RemoveFailedServer(server *autopilot.Server) { go func() { added := false defer func() { if added { d.dl.Lock() delete(d.inflightRemovals, server.ID) d.dl.Unlock() } }() d.dl.Lock() _, ok := d.inflightRemovals[server.ID] if ok { d.logger.Info("removal of dead server is already initiated", "id", server.ID) d.dl.Unlock() return } added = true d.inflightRemovals[server.ID] = true d.dl.Unlock() d.logger.Info("removing dead server from raft configuration", "id", server.ID) if future := d.raft.RemoveServer(server.ID, 0, 0); future.Error() != nil { d.logger.Error("failed to remove server", "server_id", server.ID, "server_address", server.Address, "server_name", server.Name, "error", future.Error()) return } d.followerStates.Delete(string(server.ID)) }() } // SetFollowerStates sets the followerStates field in the backend to track peers // in the raft cluster. func (b *RaftBackend) SetFollowerStates(states *FollowerStates) { b.l.Lock() b.followerStates = states b.l.Unlock() } // SetAutopilotConfig updates the autopilot configuration in the backend. func (b *RaftBackend) SetAutopilotConfig(config *AutopilotConfig) { b.l.Lock() b.autopilotConfig = config b.logger.Info("updated autopilot configuration", "config", b.autopilotConfig) b.l.Unlock() } // AutopilotConfig returns the autopilot configuration in the backend. func (b *RaftBackend) AutopilotConfig() *AutopilotConfig { b.l.RLock() defer b.l.RUnlock() return b.autopilotConfig.Clone() } func (b *RaftBackend) defaultAutopilotConfig() *AutopilotConfig { return &AutopilotConfig{ CleanupDeadServers: false, LastContactThreshold: 10 * time.Second, DeadServerLastContactThreshold: 24 * time.Hour, MaxTrailingLogs: 1000, ServerStabilizationTime: 10 * time.Second, DisableUpgradeMigration: false, UpgradeVersionTag: AutopilotUpgradeVersionTag, RedundancyZoneTag: AutopilotRedundancyZoneTag, } } func (b *RaftBackend) AutopilotDisabled() bool { b.l.RLock() disabled := b.disableAutopilot b.l.RUnlock() return disabled } func (b *RaftBackend) startFollowerHeartbeatTracker() { b.l.RLock() tickerCh := b.followerHeartbeatTicker.C b.l.RUnlock() followerGauge := func(peerID string, suffix string, value float32) { labels := []metrics.Label{ { Name: "peer_id", Value: peerID, }, } metrics.SetGaugeWithLabels([]string{"raft_storage", "follower", suffix}, value, labels) } for range tickerCh { b.l.RLock() if b.raft == nil { // We could be racing with teardown, which will stop the ticker // but that doesn't guarantee that we won't reach this line with a nil // b.raft. b.l.RUnlock() return } b.followerStates.l.RLock() myAppliedIndex := b.raft.AppliedIndex() for peerID, state := range b.followerStates.followers { timeSinceLastHeartbeat := time.Now().Sub(state.LastHeartbeat) / time.Millisecond followerGauge(peerID, "last_heartbeat_ms", float32(timeSinceLastHeartbeat)) followerGauge(peerID, "applied_index_delta", float32(myAppliedIndex-state.AppliedIndex)) if b.autopilotConfig.CleanupDeadServers && b.autopilotConfig.DeadServerLastContactThreshold != 0 { if state.LastHeartbeat.IsZero() || state.IsDead.Load() { continue } now := time.Now() if now.After(state.LastHeartbeat.Add(b.autopilotConfig.DeadServerLastContactThreshold)) { state.IsDead.Store(true) } } } b.followerStates.l.RUnlock() b.l.RUnlock() } } // StopAutopilot stops a running autopilot instance. This should only be called // on the active node. func (b *RaftBackend) StopAutopilot() { b.l.Lock() defer b.l.Unlock() if b.autopilot == nil { return } b.autopilot.Stop() b.autopilot = nil b.followerHeartbeatTicker.Stop() } // AutopilotState represents the health information retrieved from autopilot. type AutopilotState struct { Healthy bool `json:"healthy" mapstructure:"healthy"` FailureTolerance int `json:"failure_tolerance" mapstructure:"failure_tolerance"` Servers map[string]*AutopilotServer `json:"servers" mapstructure:"servers"` Leader string `json:"leader" mapstructure:"leader"` Voters []string `json:"voters" mapstructure:"voters"` NonVoters []string `json:"non_voters,omitempty" mapstructure:"non_voters,omitempty"` RedundancyZones map[string]AutopilotZone `json:"redundancy_zones,omitempty" mapstructure:"redundancy_zones,omitempty"` Upgrade *AutopilotUpgrade `json:"upgrade_info,omitempty" mapstructure:"upgrade_info,omitempty"` OptimisticFailureTolerance int `json:"optimistic_failure_tolerance,omitempty" mapstructure:"optimistic_failure_tolerance,omitempty"` } // AutopilotServer represents the health information of individual server node // retrieved from autopilot. type AutopilotServer struct { ID string `json:"id" mapstructure:"id"` Name string `json:"name" mapstructure:"name"` Address string `json:"address" mapstructure:"address"` NodeStatus string `json:"node_status" mapstructure:"node_status"` LastContact *ReadableDuration `json:"last_contact" mapstructure:"last_contact"` LastTerm uint64 `json:"last_term" mapstructure:"last_term"` LastIndex uint64 `json:"last_index" mapstructure:"last_index"` Healthy bool `json:"healthy" mapstructure:"healthy"` StableSince time.Time `json:"stable_since" mapstructure:"stable_since"` Status string `json:"status" mapstructure:"status"` Version string `json:"version" mapstructure:"version"` RedundancyZone string `json:"redundancy_zone,omitempty" mapstructure:"redundancy_zone,omitempty"` UpgradeVersion string `json:"upgrade_version,omitempty" mapstructure:"upgrade_version,omitempty"` ReadReplica bool `json:"read_replica,omitempty" mapstructure:"read_replica,omitempty"` NodeType string `json:"node_type,omitempty" mapstructure:"node_type,omitempty"` } type AutopilotZone struct { Servers []string `json:"servers,omitempty" mapstructure:"servers,omitempty"` Voters []string `json:"voters,omitempty" mapstructure:"voters,omitempty"` FailureTolerance int `json:"failure_tolerance,omitempty" mapstructure:"failure_tolerance,omitempty"` } type AutopilotUpgrade struct { Status string `json:"status" mapstructure:"status"` TargetVersion string `json:"target_version,omitempty" mapstructure:"target_version,omitempty"` TargetVersionVoters []string `json:"target_version_voters,omitempty" mapstructure:"target_version_voters,omitempty"` TargetVersionNonVoters []string `json:"target_version_non_voters,omitempty" mapstructure:"target_version_non_voters,omitempty"` TargetVersionReadReplicas []string `json:"target_version_read_replicas,omitempty" mapstructure:"target_version_read_replicas,omitempty"` OtherVersionVoters []string `json:"other_version_voters,omitempty" mapstructure:"other_version_voters,omitempty"` OtherVersionNonVoters []string `json:"other_version_non_voters,omitempty" mapstructure:"other_version_non_voters,omitempty"` OtherVersionReadReplicas []string `json:"other_version_read_replicas,omitempty" mapstructure:"other_version_read_replicas,omitempty"` RedundancyZones map[string]AutopilotZoneUpgradeVersions `json:"redundancy_zones,omitempty" mapstructure:"redundancy_zones,omitempty"` } type AutopilotZoneUpgradeVersions struct { TargetVersionVoters []string `json:"target_version_voters,omitempty" mapstructure:"target_version_voters,omitempty"` TargetVersionNonVoters []string `json:"target_version_non_voters,omitempty" mapstructure:"target_version_non_voters,omitempty"` OtherVersionVoters []string `json:"other_version_voters,omitempty" mapstructure:"other_version_voters,omitempty"` OtherVersionNonVoters []string `json:"other_version_non_voters,omitempty" mapstructure:"other_version_non_voters,omitempty"` } // ReadableDuration is a duration type that is serialized to JSON in human readable format. type ReadableDuration time.Duration func NewReadableDuration(dur time.Duration) *ReadableDuration { d := ReadableDuration(dur) return &d } func (d *ReadableDuration) String() string { return d.Duration().String() } func (d *ReadableDuration) Duration() time.Duration { if d == nil { return time.Duration(0) } return time.Duration(*d) } func (d *ReadableDuration) MarshalJSON() ([]byte, error) { return []byte(fmt.Sprintf(`"%s"`, d.Duration().String())), nil } func (d *ReadableDuration) UnmarshalJSON(raw []byte) (err error) { if d == nil { return fmt.Errorf("cannot unmarshal to nil pointer") } var dur time.Duration str := string(raw) if len(str) >= 2 && str[0] == '"' && str[len(str)-1] == '"' { // quoted string dur, err = time.ParseDuration(str[1 : len(str)-1]) if err != nil { return err } } else { // no quotes, not a string v, err := strconv.ParseFloat(str, 64) if err != nil { return err } dur = time.Duration(v) } *d = ReadableDuration(dur) return nil } func stringIDs(ids []raft.ServerID) []string { out := make([]string, len(ids)) for i, id := range ids { out[i] = string(id) } return out } func autopilotToAPIState(state *autopilot.State) (*AutopilotState, error) { out := &AutopilotState{ Healthy: state.Healthy, FailureTolerance: state.FailureTolerance, Leader: string(state.Leader), Voters: stringIDs(state.Voters), Servers: make(map[string]*AutopilotServer), } for id, srv := range state.Servers { aps, err := autopilotToAPIServer(srv) if err != nil { return nil, err } out.Servers[string(id)] = aps } err := autopilotToAPIStateEnterprise(state, out) if err != nil { return nil, err } return out, nil } func autopilotToAPIServer(srv *autopilot.ServerState) (*AutopilotServer, error) { apiSrv := &AutopilotServer{ ID: string(srv.Server.ID), Name: srv.Server.Name, Address: string(srv.Server.Address), NodeStatus: string(srv.Server.NodeStatus), LastContact: NewReadableDuration(srv.Stats.LastContact), LastTerm: srv.Stats.LastTerm, LastIndex: srv.Stats.LastIndex, Healthy: srv.Health.Healthy, StableSince: srv.Health.StableSince, Status: string(srv.State), Version: srv.Server.Version, NodeType: string(srv.Server.NodeType), } err := autopilotToAPIServerEnterprise(&srv.Server, apiSrv) if err != nil { return nil, err } return apiSrv, nil } // GetAutopilotServerState retrieves raft cluster state from autopilot to // return over the API. func (b *RaftBackend) GetAutopilotServerState(ctx context.Context) (*AutopilotState, error) { b.l.RLock() defer b.l.RUnlock() if b.raft == nil { return nil, errors.New("raft storage is not initialized") } if b.autopilot == nil { return nil, nil } apState := b.autopilot.GetState() if apState == nil { return nil, nil } return autopilotToAPIState(apState) } func (b *RaftBackend) DisableAutopilot() { b.l.Lock() b.disableAutopilot = true b.l.Unlock() } // SetupAutopilot gathers information required to configure autopilot and starts // it. If autopilot is disabled, this function does nothing. func (b *RaftBackend) SetupAutopilot(ctx context.Context, storageConfig *AutopilotConfig, followerStates *FollowerStates, disable bool) { b.l.Lock() if disable || os.Getenv("VAULT_RAFT_AUTOPILOT_DISABLE") != "" { b.disableAutopilot = true } if b.disableAutopilot { b.logger.Info("disabling autopilot") b.l.Unlock() return } // Start with a default config b.autopilotConfig = b.defaultAutopilotConfig() // Merge the setting provided over the API b.autopilotConfig.Merge(storageConfig) // Create the autopilot instance options := []autopilot.Option{ autopilot.WithLogger(b.logger), autopilot.WithPromoter(b.autopilotPromoter()), } if b.autopilotReconcileInterval != 0 { options = append(options, autopilot.WithReconcileInterval(b.autopilotReconcileInterval)) } if b.autopilotUpdateInterval != 0 { options = append(options, autopilot.WithUpdateInterval(b.autopilotUpdateInterval)) } b.autopilot = autopilot.New(b.raft, NewDelegate(b), options...) b.followerStates = followerStates b.followerHeartbeatTicker = time.NewTicker(1 * time.Second) b.l.Unlock() b.logger.Info("starting autopilot", "config", b.autopilotConfig, "reconcile_interval", b.autopilotReconcileInterval) b.autopilot.Start(ctx) go b.startFollowerHeartbeatTracker() }