package agent import ( "fmt" "log" "reflect" "strings" "sync" "sync/atomic" "time" "github.com/hashicorp/consul/consul" "github.com/hashicorp/consul/consul/structs" "github.com/hashicorp/consul/lib" "github.com/hashicorp/consul/types" ) const ( syncStaggerIntv = 3 * time.Second syncRetryIntv = 15 * time.Second ) // syncStatus is used to represent the difference between // the local and remote state, and if action needs to be taken type syncStatus struct { inSync bool // Is this in sync with the server } // localState is used to represent the node's services, // and checks. We used it to perform anti-entropy with the // catalog representation type localState struct { // paused is used to check if we are paused. Must be the first // element due to a go bug. paused int32 sync.RWMutex logger *log.Logger // Config is the agent config config *Config // iface is the consul interface to use for keeping in sync iface consul.Interface // nodeInfoInSync tracks whether the server has our correct top-level // node information in sync (currently only used for tagged addresses) nodeInfoInSync bool // Services tracks the local services services map[string]*structs.NodeService serviceStatus map[string]syncStatus serviceTokens map[string]string // Checks tracks the local checks checks map[types.CheckID]*structs.HealthCheck checkStatus map[types.CheckID]syncStatus checkTokens map[types.CheckID]string checkCriticalTime map[types.CheckID]time.Time // Used to track checks that are being deferred deferCheck map[types.CheckID]*time.Timer // metadata tracks the local metadata fields metadata map[string]string // consulCh is used to inform of a change to the known // consul nodes. This may be used to retry a sync run consulCh chan struct{} // triggerCh is used to inform of a change to local state // that requires anti-entropy with the server triggerCh chan struct{} } // Init is used to initialize the local state func (l *localState) Init(config *Config, logger *log.Logger) { l.config = config l.logger = logger l.services = make(map[string]*structs.NodeService) l.serviceStatus = make(map[string]syncStatus) l.serviceTokens = make(map[string]string) l.checks = make(map[types.CheckID]*structs.HealthCheck) l.checkStatus = make(map[types.CheckID]syncStatus) l.checkTokens = make(map[types.CheckID]string) l.checkCriticalTime = make(map[types.CheckID]time.Time) l.deferCheck = make(map[types.CheckID]*time.Timer) l.metadata = make(map[string]string) l.consulCh = make(chan struct{}, 1) l.triggerCh = make(chan struct{}, 1) } // SetIface is used to set the Consul interface. Must be set prior to // starting anti-entropy func (l *localState) SetIface(iface consul.Interface) { l.iface = iface } // changeMade is used to trigger an anti-entropy run func (l *localState) changeMade() { select { case l.triggerCh <- struct{}{}: default: } } // ConsulServerUp is used to inform that a new consul server is now // up. This can be used to speed up the sync process if we are blocking // waiting to discover a consul server func (l *localState) ConsulServerUp() { select { case l.consulCh <- struct{}{}: default: } } // Pause is used to pause state synchronization, this can be // used to make batch changes func (l *localState) Pause() { atomic.AddInt32(&l.paused, 1) } // Resume is used to resume state synchronization func (l *localState) Resume() { paused := atomic.AddInt32(&l.paused, -1) if paused < 0 { panic("unbalanced localState.Resume() detected") } l.changeMade() } // isPaused is used to check if we are paused func (l *localState) isPaused() bool { return atomic.LoadInt32(&l.paused) > 0 } // ServiceToken returns the configured ACL token for the given // service ID. If none is present, the agent's token is returned. func (l *localState) ServiceToken(id string) string { l.RLock() defer l.RUnlock() return l.serviceToken(id) } // serviceToken returns an ACL token associated with a service. func (l *localState) serviceToken(id string) string { token := l.serviceTokens[id] if token == "" { token = l.config.ACLToken } return token } // AddService is used to add a service entry to the local state. // This entry is persistent and the agent will make a best effort to // ensure it is registered func (l *localState) AddService(service *structs.NodeService, token string) { // Assign the ID if none given if service.ID == "" && service.Service != "" { service.ID = service.Service } l.Lock() defer l.Unlock() l.services[service.ID] = service l.serviceStatus[service.ID] = syncStatus{} l.serviceTokens[service.ID] = token l.changeMade() } // RemoveService is used to remove a service entry from the local state. // The agent will make a best effort to ensure it is deregistered func (l *localState) RemoveService(serviceID string) error { l.Lock() defer l.Unlock() if _, ok := l.services[serviceID]; ok { delete(l.services, serviceID) delete(l.serviceTokens, serviceID) l.serviceStatus[serviceID] = syncStatus{inSync: false} l.changeMade() } else { return fmt.Errorf("Service does not exist") } return nil } // Services returns the locally registered services that the // agent is aware of and are being kept in sync with the server func (l *localState) Services() map[string]*structs.NodeService { services := make(map[string]*structs.NodeService) l.RLock() defer l.RUnlock() for name, serv := range l.services { services[name] = serv } return services } // CheckToken is used to return the configured health check token for a // Check, or if none is configured, the default agent ACL token. func (l *localState) CheckToken(checkID types.CheckID) string { l.RLock() defer l.RUnlock() return l.checkToken(checkID) } // checkToken returns an ACL token associated with a check. func (l *localState) checkToken(checkID types.CheckID) string { token := l.checkTokens[checkID] if token == "" { token = l.config.ACLToken } return token } // AddCheck is used to add a health check to the local state. // This entry is persistent and the agent will make a best effort to // ensure it is registered func (l *localState) AddCheck(check *structs.HealthCheck, token string) { // Set the node name check.Node = l.config.NodeName l.Lock() defer l.Unlock() l.checks[check.CheckID] = check l.checkStatus[check.CheckID] = syncStatus{} l.checkTokens[check.CheckID] = token delete(l.checkCriticalTime, check.CheckID) l.changeMade() } // RemoveCheck is used to remove a health check from the local state. // The agent will make a best effort to ensure it is deregistered func (l *localState) RemoveCheck(checkID types.CheckID) { l.Lock() defer l.Unlock() delete(l.checks, checkID) delete(l.checkTokens, checkID) delete(l.checkCriticalTime, checkID) l.checkStatus[checkID] = syncStatus{inSync: false} l.changeMade() } // UpdateCheck is used to update the status of a check func (l *localState) UpdateCheck(checkID types.CheckID, status, output string) { l.Lock() defer l.Unlock() check, ok := l.checks[checkID] if !ok { return } // Update the critical time tracking (this doesn't cause a server updates // so we can always keep this up to date). if status == structs.HealthCritical { _, wasCritical := l.checkCriticalTime[checkID] if !wasCritical { l.checkCriticalTime[checkID] = time.Now() } } else { delete(l.checkCriticalTime, checkID) } // Do nothing if update is idempotent if check.Status == status && check.Output == output { return } // Defer a sync if the output has changed. This is an optimization around // frequent updates of output. Instead, we update the output internally, // and periodically do a write-back to the servers. If there is a status // change we do the write immediately. if l.config.CheckUpdateInterval > 0 && check.Status == status { check.Output = output if _, ok := l.deferCheck[checkID]; !ok { intv := time.Duration(uint64(l.config.CheckUpdateInterval)/2) + lib.RandomStagger(l.config.CheckUpdateInterval) deferSync := time.AfterFunc(intv, func() { l.Lock() if _, ok := l.checkStatus[checkID]; ok { l.checkStatus[checkID] = syncStatus{inSync: false} l.changeMade() } delete(l.deferCheck, checkID) l.Unlock() }) l.deferCheck[checkID] = deferSync } return } // Update status and mark out of sync check.Status = status check.Output = output l.checkStatus[checkID] = syncStatus{inSync: false} l.changeMade() } // Checks returns the locally registered checks that the // agent is aware of and are being kept in sync with the server func (l *localState) Checks() map[types.CheckID]*structs.HealthCheck { checks := make(map[types.CheckID]*structs.HealthCheck) l.RLock() defer l.RUnlock() for checkID, check := range l.checks { checks[checkID] = check } return checks } // CriticalCheck is used to return the duration a check has been critical along // with its associated health check. type CriticalCheck struct { CriticalFor time.Duration Check *structs.HealthCheck } // CriticalChecks returns locally registered health checks that the agent is // aware of and are being kept in sync with the server, and that are in a // critical state. This also returns information about how long each check has // been critical. func (l *localState) CriticalChecks() map[types.CheckID]CriticalCheck { checks := make(map[types.CheckID]CriticalCheck) l.RLock() defer l.RUnlock() now := time.Now() for checkID, criticalTime := range l.checkCriticalTime { checks[checkID] = CriticalCheck{ CriticalFor: now.Sub(criticalTime), Check: l.checks[checkID], } } return checks } // Metadata returns the local node metadata fields that the // agent is aware of and are being kept in sync with the server func (l *localState) Metadata() map[string]string { metadata := make(map[string]string) l.RLock() defer l.RUnlock() for key, value := range l.metadata { metadata[key] = value } return metadata } // antiEntropy is a long running method used to perform anti-entropy // between local and remote state. func (l *localState) antiEntropy(shutdownCh chan struct{}) { SYNC: // Sync our state with the servers for { err := l.setSyncState() if err == nil { break } l.logger.Printf("[ERR] agent: failed to sync remote state: %v", err) select { case <-l.consulCh: // Stagger the retry on leader election, avoid a thundering heard select { case <-time.After(lib.RandomStagger(aeScale(syncStaggerIntv, len(l.iface.LANMembers())))): case <-shutdownCh: return } case <-time.After(syncRetryIntv + lib.RandomStagger(aeScale(syncRetryIntv, len(l.iface.LANMembers())))): case <-shutdownCh: return } } // Force-trigger AE to pickup any changes l.changeMade() // Schedule the next full sync, with a random stagger aeIntv := aeScale(l.config.AEInterval, len(l.iface.LANMembers())) aeIntv = aeIntv + lib.RandomStagger(aeIntv) aeTimer := time.After(aeIntv) // Wait for sync events for { select { case <-aeTimer: goto SYNC case <-l.triggerCh: // Skip the sync if we are paused if l.isPaused() { continue } if err := l.syncChanges(); err != nil { l.logger.Printf("[ERR] agent: failed to sync changes: %v", err) } case <-shutdownCh: return } } } // setSyncState does a read of the server state, and updates // the local syncStatus as appropriate func (l *localState) setSyncState() error { req := structs.NodeSpecificRequest{ Datacenter: l.config.Datacenter, Node: l.config.NodeName, QueryOptions: structs.QueryOptions{Token: l.config.GetTokenForAgent()}, } var out1 structs.IndexedNodeServices var out2 structs.IndexedHealthChecks if e := l.iface.RPC("Catalog.NodeServices", &req, &out1); e != nil { return e } if err := l.iface.RPC("Health.NodeChecks", &req, &out2); err != nil { return err } checks := out2.HealthChecks l.Lock() defer l.Unlock() // Check the node info if out1.NodeServices == nil || out1.NodeServices.Node == nil || !reflect.DeepEqual(out1.NodeServices.Node.TaggedAddresses, l.config.TaggedAddresses) || !reflect.DeepEqual(out1.NodeServices.Node.Meta, l.metadata) { l.nodeInfoInSync = false } // Check all our services services := make(map[string]*structs.NodeService) if out1.NodeServices != nil { services = out1.NodeServices.Services } for id, _ := range l.services { // If the local service doesn't exist remotely, then sync it if _, ok := services[id]; !ok { l.serviceStatus[id] = syncStatus{inSync: false} } } for id, service := range services { // If we don't have the service locally, deregister it existing, ok := l.services[id] if !ok { l.serviceStatus[id] = syncStatus{inSync: false} continue } // If our definition is different, we need to update it. Make a // copy so that we don't retain a pointer to any actual state // store info for in-memory RPCs. if existing.EnableTagOverride { existing.Tags = make([]string, len(service.Tags)) copy(existing.Tags, service.Tags) } equal := existing.IsSame(service) l.serviceStatus[id] = syncStatus{inSync: equal} } // Index the remote health checks to improve efficiency checkIndex := make(map[types.CheckID]*structs.HealthCheck, len(checks)) for _, check := range checks { checkIndex[check.CheckID] = check } // Sync any check which doesn't exist on the remote side for id, _ := range l.checks { if _, ok := checkIndex[id]; !ok { l.checkStatus[id] = syncStatus{inSync: false} } } for _, check := range checks { // If we don't have the check locally, deregister it id := check.CheckID existing, ok := l.checks[id] if !ok { // The Serf check is created automatically, and does not // need to be registered if id == consul.SerfCheckID { continue } l.checkStatus[id] = syncStatus{inSync: false} continue } // If our definition is different, we need to update it var equal bool if l.config.CheckUpdateInterval == 0 { equal = existing.IsSame(check) } else { // Copy the existing check before potentially modifying // it before the compare operation. eCopy := existing.Clone() // Copy the server's check before modifying, otherwise // in-memory RPCs will have side effects. cCopy := check.Clone() // If there's a defer timer active then we've got a // potentially spammy check so we don't sync the output // during this sweep since the timer will mark the check // out of sync for us. Otherwise, it is safe to sync the // output now. This is especially important for checks // that don't change state after they are created, in // which case we'd never see their output synced back ever. if _, ok := l.deferCheck[id]; ok { eCopy.Output = "" cCopy.Output = "" } equal = eCopy.IsSame(cCopy) } // Update the status l.checkStatus[id] = syncStatus{inSync: equal} } return nil } // syncChanges is used to scan the status our local services and checks // and update any that are out of sync with the server func (l *localState) syncChanges() error { l.Lock() defer l.Unlock() // We will do node-level info syncing at the end, since it will get // updated by a service or check sync anyway, given how the register // API works. // Sync the services for id, status := range l.serviceStatus { if _, ok := l.services[id]; !ok { if err := l.deleteService(id); err != nil { return err } } else if !status.inSync { if err := l.syncService(id); err != nil { return err } } else { l.logger.Printf("[DEBUG] agent: Service '%s' in sync", id) } } // Sync the checks for id, status := range l.checkStatus { if _, ok := l.checks[id]; !ok { if err := l.deleteCheck(id); err != nil { return err } } else if !status.inSync { // Cancel a deferred sync if timer := l.deferCheck[id]; timer != nil { timer.Stop() delete(l.deferCheck, id) } if err := l.syncCheck(id); err != nil { return err } } else { l.logger.Printf("[DEBUG] agent: Check '%s' in sync", id) } } // Now sync the node level info if we need to, and didn't do any of // the other sync operations. if !l.nodeInfoInSync { if err := l.syncNodeInfo(); err != nil { return err } } else { l.logger.Printf("[DEBUG] agent: Node info in sync") } return nil } // deleteService is used to delete a service from the server func (l *localState) deleteService(id string) error { if id == "" { return fmt.Errorf("ServiceID missing") } req := structs.DeregisterRequest{ Datacenter: l.config.Datacenter, Node: l.config.NodeName, ServiceID: id, WriteRequest: structs.WriteRequest{Token: l.serviceToken(id)}, } var out struct{} err := l.iface.RPC("Catalog.Deregister", &req, &out) if err == nil { delete(l.serviceStatus, id) l.logger.Printf("[INFO] agent: Deregistered service '%s'", id) } return err } // deleteCheck is used to delete a check from the server func (l *localState) deleteCheck(id types.CheckID) error { if id == "" { return fmt.Errorf("CheckID missing") } req := structs.DeregisterRequest{ Datacenter: l.config.Datacenter, Node: l.config.NodeName, CheckID: id, WriteRequest: structs.WriteRequest{Token: l.checkToken(id)}, } var out struct{} err := l.iface.RPC("Catalog.Deregister", &req, &out) if err == nil { delete(l.checkStatus, id) l.logger.Printf("[INFO] agent: Deregistered check '%s'", id) } return err } // syncService is used to sync a service to the server func (l *localState) syncService(id string) error { req := structs.RegisterRequest{ Datacenter: l.config.Datacenter, Node: l.config.NodeName, Address: l.config.AdvertiseAddr, TaggedAddresses: l.config.TaggedAddresses, NodeMeta: l.metadata, Service: l.services[id], WriteRequest: structs.WriteRequest{Token: l.serviceToken(id)}, } // If the service has associated checks that are out of sync, // piggyback them on the service sync so they are part of the // same transaction and are registered atomically. var checks structs.HealthChecks for _, check := range l.checks { if check.ServiceID == id { if stat, ok := l.checkStatus[check.CheckID]; !ok || !stat.inSync { checks = append(checks, check) } } } // Backwards-compatibility for Consul < 0.5 if len(checks) == 1 { req.Check = checks[0] } else { req.Checks = checks } var out struct{} err := l.iface.RPC("Catalog.Register", &req, &out) if err == nil { l.serviceStatus[id] = syncStatus{inSync: true} // Given how the register API works, this info is also updated // every time we sync a service. l.nodeInfoInSync = true l.logger.Printf("[INFO] agent: Synced service '%s'", id) for _, check := range checks { l.checkStatus[check.CheckID] = syncStatus{inSync: true} } } else if strings.Contains(err.Error(), permissionDenied) { l.serviceStatus[id] = syncStatus{inSync: true} l.logger.Printf("[WARN] agent: Service '%s' registration blocked by ACLs", id) for _, check := range checks { l.checkStatus[check.CheckID] = syncStatus{inSync: true} } return nil } return err } // syncCheck is used to sync a check to the server func (l *localState) syncCheck(id types.CheckID) error { // Pull in the associated service if any check := l.checks[id] var service *structs.NodeService if check.ServiceID != "" { if serv, ok := l.services[check.ServiceID]; ok { service = serv } } req := structs.RegisterRequest{ Datacenter: l.config.Datacenter, Node: l.config.NodeName, Address: l.config.AdvertiseAddr, TaggedAddresses: l.config.TaggedAddresses, NodeMeta: l.metadata, Service: service, Check: l.checks[id], WriteRequest: structs.WriteRequest{Token: l.checkToken(id)}, } var out struct{} err := l.iface.RPC("Catalog.Register", &req, &out) if err == nil { l.checkStatus[id] = syncStatus{inSync: true} // Given how the register API works, this info is also updated // every time we sync a service. l.nodeInfoInSync = true l.logger.Printf("[INFO] agent: Synced check '%s'", id) } else if strings.Contains(err.Error(), permissionDenied) { l.checkStatus[id] = syncStatus{inSync: true} l.logger.Printf("[WARN] agent: Check '%s' registration blocked by ACLs", id) return nil } return err } func (l *localState) syncNodeInfo() error { req := structs.RegisterRequest{ Datacenter: l.config.Datacenter, Node: l.config.NodeName, Address: l.config.AdvertiseAddr, TaggedAddresses: l.config.TaggedAddresses, NodeMeta: l.metadata, WriteRequest: structs.WriteRequest{Token: l.config.GetTokenForAgent()}, } var out struct{} err := l.iface.RPC("Catalog.Register", &req, &out) if err == nil { l.nodeInfoInSync = true l.logger.Printf("[INFO] agent: Synced node info") } else if strings.Contains(err.Error(), permissionDenied) { l.nodeInfoInSync = true l.logger.Printf("[WARN] agent: Node info update blocked by ACLs") return nil } return err }