// Run starts all manager sub-systems and the gRPC server at the configured // address. // The call never returns unless an error occurs or `Stop()` is called. // // TODO(aluzzardi): /!\ This function is *way* too complex. /!\ // It needs to be split into smaller manageable functions. func (m *Manager) Run(parent context.Context) error { ctx, ctxCancel := context.WithCancel(parent) defer ctxCancel() // Harakiri. go func() { select { case <-ctx.Done(): case <-m.stopped: ctxCancel() } }() leadershipCh, cancel := m.RaftNode.SubscribeLeadership() defer cancel() go func() { for leadershipEvent := range leadershipCh { // read out and discard all of the messages when we've stopped // don't acquire the mutex yet. if stopped is closed, we don't need // this stops this loop from starving Run()'s attempt to Lock select { case <-m.stopped: continue default: // do nothing, we're not stopped } // we're not stopping so NOW acquire the mutex m.mu.Lock() newState := leadershipEvent.(raft.LeadershipState) if newState == raft.IsLeader { s := m.RaftNode.MemoryStore() rootCA := m.config.SecurityConfig.RootCA() nodeID := m.config.SecurityConfig.ClientTLSCreds.NodeID() raftCfg := raft.DefaultRaftConfig() raftCfg.ElectionTick = uint32(m.RaftNode.Config.ElectionTick) raftCfg.HeartbeatTick = uint32(m.RaftNode.Config.HeartbeatTick) clusterID := m.config.SecurityConfig.ClientTLSCreds.Organization() initialCAConfig := ca.DefaultCAConfig() initialCAConfig.ExternalCAs = m.config.ExternalCAs s.Update(func(tx store.Tx) error { // Add a default cluster object to the // store. Don't check the error because // we expect this to fail unless this // is a brand new cluster. store.CreateCluster(tx, &api.Cluster{ ID: clusterID, Spec: api.ClusterSpec{ Annotations: api.Annotations{ Name: store.DefaultClusterName, }, Orchestration: api.OrchestrationConfig{ TaskHistoryRetentionLimit: defaultTaskHistoryRetentionLimit, }, Dispatcher: api.DispatcherConfig{ HeartbeatPeriod: ptypes.DurationProto(dispatcher.DefaultHeartBeatPeriod), }, Raft: raftCfg, CAConfig: initialCAConfig, }, RootCA: api.RootCA{ CAKey: rootCA.Key, CACert: rootCA.Cert, CACertHash: rootCA.Digest.String(), JoinTokens: api.JoinTokens{ Worker: ca.GenerateJoinToken(rootCA), Manager: ca.GenerateJoinToken(rootCA), }, }, }) // Add Node entry for ourself, if one // doesn't exist already. store.CreateNode(tx, &api.Node{ ID: nodeID, Certificate: api.Certificate{ CN: nodeID, Role: api.NodeRoleManager, Status: api.IssuanceStatus{ State: api.IssuanceStateIssued, }, }, Spec: api.NodeSpec{ Role: api.NodeRoleManager, Membership: api.NodeMembershipAccepted, }, }) return nil }) // Attempt to rotate the key-encrypting-key of the root CA key-material err := m.rotateRootCAKEK(ctx, clusterID) if err != nil { log.G(ctx).WithError(err).Error("root key-encrypting-key rotation failed") } m.replicatedOrchestrator = orchestrator.NewReplicatedOrchestrator(s) m.globalOrchestrator = orchestrator.NewGlobalOrchestrator(s) m.taskReaper = orchestrator.NewTaskReaper(s) m.scheduler = scheduler.New(s) m.keyManager = keymanager.New(m.RaftNode.MemoryStore(), keymanager.DefaultConfig()) // TODO(stevvooe): Allocate a context that can be used to // shutdown underlying manager processes when leadership is // lost. m.allocator, err = allocator.New(s) if err != nil { log.G(ctx).WithError(err).Error("failed to create allocator") // TODO(stevvooe): It doesn't seem correct here to fail // creating the allocator but then use it anyway. } if m.keyManager != nil { go func(keyManager *keymanager.KeyManager) { if err := keyManager.Run(ctx); err != nil { log.G(ctx).WithError(err).Error("keymanager failed with an error") } }(m.keyManager) } go func(d *dispatcher.Dispatcher) { if err := d.Run(ctx); err != nil { log.G(ctx).WithError(err).Error("Dispatcher exited with an error") } }(m.Dispatcher) go func(server *ca.Server) { if err := server.Run(ctx); err != nil { log.G(ctx).WithError(err).Error("CA signer exited with an error") } }(m.caserver) // Start all sub-components in separate goroutines. // TODO(aluzzardi): This should have some kind of error handling so that // any component that goes down would bring the entire manager down. if m.allocator != nil { go func(allocator *allocator.Allocator) { if err := allocator.Run(ctx); err != nil { log.G(ctx).WithError(err).Error("allocator exited with an error") } }(m.allocator) } go func(scheduler *scheduler.Scheduler) { if err := scheduler.Run(ctx); err != nil { log.G(ctx).WithError(err).Error("scheduler exited with an error") } }(m.scheduler) go func(taskReaper *orchestrator.TaskReaper) { taskReaper.Run() }(m.taskReaper) go func(orchestrator *orchestrator.ReplicatedOrchestrator) { if err := orchestrator.Run(ctx); err != nil { log.G(ctx).WithError(err).Error("replicated orchestrator exited with an error") } }(m.replicatedOrchestrator) go func(globalOrchestrator *orchestrator.GlobalOrchestrator) { if err := globalOrchestrator.Run(ctx); err != nil { log.G(ctx).WithError(err).Error("global orchestrator exited with an error") } }(m.globalOrchestrator) } else if newState == raft.IsFollower { m.Dispatcher.Stop() m.caserver.Stop() if m.allocator != nil { m.allocator.Stop() m.allocator = nil } m.replicatedOrchestrator.Stop() m.replicatedOrchestrator = nil m.globalOrchestrator.Stop() m.globalOrchestrator = nil m.taskReaper.Stop() m.taskReaper = nil m.scheduler.Stop() m.scheduler = nil if m.keyManager != nil { m.keyManager.Stop() m.keyManager = nil } } m.mu.Unlock() } }() proxyOpts := []grpc.DialOption{ grpc.WithTimeout(5 * time.Second), grpc.WithTransportCredentials(m.config.SecurityConfig.ClientTLSCreds), } cs := raftpicker.NewConnSelector(m.RaftNode, proxyOpts...) m.connSelector = cs // We need special connSelector for controlapi because it provides automatic // leader tracking. // Other APIs are using connSelector which errors out on leader change, but // allows to react quickly to reelections. controlAPIProxyOpts := []grpc.DialOption{ grpc.WithBackoffMaxDelay(time.Second), grpc.WithTransportCredentials(m.config.SecurityConfig.ClientTLSCreds), } controlAPIConnSelector := hackpicker.NewConnSelector(m.RaftNode, controlAPIProxyOpts...) authorize := func(ctx context.Context, roles []string) error { // Authorize the remote roles, ensure they can only be forwarded by managers _, err := ca.AuthorizeForwardedRoleAndOrg(ctx, roles, []string{ca.ManagerRole}, m.config.SecurityConfig.ClientTLSCreds.Organization()) return err } baseControlAPI := controlapi.NewServer(m.RaftNode.MemoryStore(), m.RaftNode, m.config.SecurityConfig.RootCA()) healthServer := health.NewHealthServer() authenticatedControlAPI := api.NewAuthenticatedWrapperControlServer(baseControlAPI, authorize) authenticatedDispatcherAPI := api.NewAuthenticatedWrapperDispatcherServer(m.Dispatcher, authorize) authenticatedCAAPI := api.NewAuthenticatedWrapperCAServer(m.caserver, authorize) authenticatedNodeCAAPI := api.NewAuthenticatedWrapperNodeCAServer(m.caserver, authorize) authenticatedRaftAPI := api.NewAuthenticatedWrapperRaftServer(m.RaftNode, authorize) authenticatedHealthAPI := api.NewAuthenticatedWrapperHealthServer(healthServer, authorize) authenticatedRaftMembershipAPI := api.NewAuthenticatedWrapperRaftMembershipServer(m.RaftNode, authorize) proxyDispatcherAPI := api.NewRaftProxyDispatcherServer(authenticatedDispatcherAPI, cs, m.RaftNode, ca.WithMetadataForwardTLSInfo) proxyCAAPI := api.NewRaftProxyCAServer(authenticatedCAAPI, cs, m.RaftNode, ca.WithMetadataForwardTLSInfo) proxyNodeCAAPI := api.NewRaftProxyNodeCAServer(authenticatedNodeCAAPI, cs, m.RaftNode, ca.WithMetadataForwardTLSInfo) proxyRaftMembershipAPI := api.NewRaftProxyRaftMembershipServer(authenticatedRaftMembershipAPI, cs, m.RaftNode, ca.WithMetadataForwardTLSInfo) // localProxyControlAPI is a special kind of proxy. It is only wired up // to receive requests from a trusted local socket, and these requests // don't use TLS, therefore the requests it handles locally should // bypass authorization. When it proxies, it sends them as requests from // this manager rather than forwarded requests (it has no TLS // information to put in the metadata map). forwardAsOwnRequest := func(ctx context.Context) (context.Context, error) { return ctx, nil } localProxyControlAPI := api.NewRaftProxyControlServer(baseControlAPI, controlAPIConnSelector, m.RaftNode, forwardAsOwnRequest) // Everything registered on m.server should be an authenticated // wrapper, or a proxy wrapping an authenticated wrapper! api.RegisterCAServer(m.server, proxyCAAPI) api.RegisterNodeCAServer(m.server, proxyNodeCAAPI) api.RegisterRaftServer(m.server, authenticatedRaftAPI) api.RegisterHealthServer(m.server, authenticatedHealthAPI) api.RegisterRaftMembershipServer(m.server, proxyRaftMembershipAPI) api.RegisterControlServer(m.localserver, localProxyControlAPI) api.RegisterControlServer(m.server, authenticatedControlAPI) api.RegisterDispatcherServer(m.server, proxyDispatcherAPI) errServe := make(chan error, 2) for proto, l := range m.listeners { go func(proto string, lis net.Listener) { ctx := log.WithLogger(ctx, log.G(ctx).WithFields( logrus.Fields{ "proto": lis.Addr().Network(), "addr": lis.Addr().String()})) if proto == "unix" { log.G(ctx).Info("Listening for local connections") // we need to disallow double closes because UnixListener.Close // can delete unix-socket file of newer listener. grpc calls // Close twice indeed: in Serve and in Stop. errServe <- m.localserver.Serve(&closeOnceListener{Listener: lis}) } else { log.G(ctx).Info("Listening for connections") errServe <- m.server.Serve(lis) } }(proto, l) } // Set the raft server as serving for the health server healthServer.SetServingStatus("Raft", api.HealthCheckResponse_SERVING) if err := m.RaftNode.JoinAndStart(); err != nil { for _, lis := range m.listeners { lis.Close() } return fmt.Errorf("can't initialize raft node: %v", err) } close(m.started) go func() { err := m.RaftNode.Run(ctx) if err != nil { log.G(ctx).Error(err) m.Stop(ctx) } }() if err := raft.WaitForLeader(ctx, m.RaftNode); err != nil { m.server.Stop() return err } c, err := raft.WaitForCluster(ctx, m.RaftNode) if err != nil { m.server.Stop() return err } raftConfig := c.Spec.Raft if int(raftConfig.ElectionTick) != m.RaftNode.Config.ElectionTick { log.G(ctx).Warningf("election tick value (%ds) is different from the one defined in the cluster config (%vs), the cluster may be unstable", m.RaftNode.Config.ElectionTick, raftConfig.ElectionTick) } if int(raftConfig.HeartbeatTick) != m.RaftNode.Config.HeartbeatTick { log.G(ctx).Warningf("heartbeat tick value (%ds) is different from the one defined in the cluster config (%vs), the cluster may be unstable", m.RaftNode.Config.HeartbeatTick, raftConfig.HeartbeatTick) } // wait for an error in serving. err = <-errServe select { // check to see if stopped was posted to. if so, we're in the process of // stopping, or done and that's why we got the error. if stopping is // deliberate, stopped will ALWAYS be closed before the error is trigger, // so this path will ALWAYS be taken if the stop was deliberate case <-m.stopped: // shutdown was requested, do not return an error // but first, we wait to acquire a mutex to guarantee that stopping is // finished. as long as we acquire the mutex BEFORE we return, we know // that stopping is stopped. m.mu.Lock() m.mu.Unlock() return nil // otherwise, we'll get something from errServe, which indicates that an // error in serving has actually occurred and this isn't a planned shutdown default: return err } }
// Run starts all manager sub-systems and the gRPC server at the configured // address. // The call never returns unless an error occurs or `Stop()` is called. func (m *Manager) Run(parent context.Context) error { ctx, ctxCancel := context.WithCancel(parent) defer ctxCancel() // Harakiri. go func() { select { case <-ctx.Done(): case <-m.stopped: ctxCancel() } }() leadershipCh, cancel := m.RaftNode.SubscribeLeadership() defer cancel() go m.handleLeadershipEvents(ctx, leadershipCh) proxyOpts := []grpc.DialOption{ grpc.WithTimeout(5 * time.Second), grpc.WithTransportCredentials(m.config.SecurityConfig.ClientTLSCreds), } cs := raftpicker.NewConnSelector(m.RaftNode, proxyOpts...) m.connSelector = cs // We need special connSelector for controlapi because it provides automatic // leader tracking. // Other APIs are using connSelector which errors out on leader change, but // allows to react quickly to reelections. controlAPIProxyOpts := []grpc.DialOption{ grpc.WithBackoffMaxDelay(time.Second), grpc.WithTransportCredentials(m.config.SecurityConfig.ClientTLSCreds), } controlAPIConnSelector := hackpicker.NewConnSelector(m.RaftNode, controlAPIProxyOpts...) authorize := func(ctx context.Context, roles []string) error { // Authorize the remote roles, ensure they can only be forwarded by managers _, err := ca.AuthorizeForwardedRoleAndOrg(ctx, roles, []string{ca.ManagerRole}, m.config.SecurityConfig.ClientTLSCreds.Organization()) return err } baseControlAPI := controlapi.NewServer(m.RaftNode.MemoryStore(), m.RaftNode, m.config.SecurityConfig.RootCA()) baseResourceAPI := resourceapi.New(m.RaftNode.MemoryStore()) healthServer := health.NewHealthServer() localHealthServer := health.NewHealthServer() authenticatedControlAPI := api.NewAuthenticatedWrapperControlServer(baseControlAPI, authorize) authenticatedResourceAPI := api.NewAuthenticatedWrapperResourceAllocatorServer(baseResourceAPI, authorize) authenticatedDispatcherAPI := api.NewAuthenticatedWrapperDispatcherServer(m.Dispatcher, authorize) authenticatedCAAPI := api.NewAuthenticatedWrapperCAServer(m.caserver, authorize) authenticatedNodeCAAPI := api.NewAuthenticatedWrapperNodeCAServer(m.caserver, authorize) authenticatedRaftAPI := api.NewAuthenticatedWrapperRaftServer(m.RaftNode, authorize) authenticatedHealthAPI := api.NewAuthenticatedWrapperHealthServer(healthServer, authorize) authenticatedRaftMembershipAPI := api.NewAuthenticatedWrapperRaftMembershipServer(m.RaftNode, authorize) proxyDispatcherAPI := api.NewRaftProxyDispatcherServer(authenticatedDispatcherAPI, cs, m.RaftNode, ca.WithMetadataForwardTLSInfo) proxyCAAPI := api.NewRaftProxyCAServer(authenticatedCAAPI, cs, m.RaftNode, ca.WithMetadataForwardTLSInfo) proxyNodeCAAPI := api.NewRaftProxyNodeCAServer(authenticatedNodeCAAPI, cs, m.RaftNode, ca.WithMetadataForwardTLSInfo) proxyRaftMembershipAPI := api.NewRaftProxyRaftMembershipServer(authenticatedRaftMembershipAPI, cs, m.RaftNode, ca.WithMetadataForwardTLSInfo) proxyResourceAPI := api.NewRaftProxyResourceAllocatorServer(authenticatedResourceAPI, cs, m.RaftNode, ca.WithMetadataForwardTLSInfo) // localProxyControlAPI is a special kind of proxy. It is only wired up // to receive requests from a trusted local socket, and these requests // don't use TLS, therefore the requests it handles locally should // bypass authorization. When it proxies, it sends them as requests from // this manager rather than forwarded requests (it has no TLS // information to put in the metadata map). forwardAsOwnRequest := func(ctx context.Context) (context.Context, error) { return ctx, nil } localProxyControlAPI := api.NewRaftProxyControlServer(baseControlAPI, controlAPIConnSelector, m.RaftNode, forwardAsOwnRequest) // Everything registered on m.server should be an authenticated // wrapper, or a proxy wrapping an authenticated wrapper! api.RegisterCAServer(m.server, proxyCAAPI) api.RegisterNodeCAServer(m.server, proxyNodeCAAPI) api.RegisterRaftServer(m.server, authenticatedRaftAPI) api.RegisterHealthServer(m.server, authenticatedHealthAPI) api.RegisterRaftMembershipServer(m.server, proxyRaftMembershipAPI) api.RegisterControlServer(m.server, authenticatedControlAPI) api.RegisterResourceAllocatorServer(m.server, proxyResourceAPI) api.RegisterDispatcherServer(m.server, proxyDispatcherAPI) api.RegisterControlServer(m.localserver, localProxyControlAPI) api.RegisterHealthServer(m.localserver, localHealthServer) errServe := make(chan error, 2) for proto, l := range m.listeners { go m.serveListener(ctx, errServe, proto, l) } // Set the raft server as serving for the health server healthServer.SetServingStatus("Raft", api.HealthCheckResponse_SERVING) localHealthServer.SetServingStatus("ControlAPI", api.HealthCheckResponse_SERVING) defer func() { m.server.Stop() m.localserver.Stop() }() if err := m.RaftNode.JoinAndStart(); err != nil { return fmt.Errorf("can't initialize raft node: %v", err) } close(m.started) go func() { err := m.RaftNode.Run(ctx) if err != nil { log.G(ctx).Error(err) m.Stop(ctx) } }() if err := raft.WaitForLeader(ctx, m.RaftNode); err != nil { return err } c, err := raft.WaitForCluster(ctx, m.RaftNode) if err != nil { return err } raftConfig := c.Spec.Raft if int(raftConfig.ElectionTick) != m.RaftNode.Config.ElectionTick { log.G(ctx).Warningf("election tick value (%ds) is different from the one defined in the cluster config (%vs), the cluster may be unstable", m.RaftNode.Config.ElectionTick, raftConfig.ElectionTick) } if int(raftConfig.HeartbeatTick) != m.RaftNode.Config.HeartbeatTick { log.G(ctx).Warningf("heartbeat tick value (%ds) is different from the one defined in the cluster config (%vs), the cluster may be unstable", m.RaftNode.Config.HeartbeatTick, raftConfig.HeartbeatTick) } // wait for an error in serving. err = <-errServe select { // check to see if stopped was posted to. if so, we're in the process of // stopping, or done and that's why we got the error. if stopping is // deliberate, stopped will ALWAYS be closed before the error is trigger, // so this path will ALWAYS be taken if the stop was deliberate case <-m.stopped: // shutdown was requested, do not return an error // but first, we wait to acquire a mutex to guarantee that stopping is // finished. as long as we acquire the mutex BEFORE we return, we know // that stopping is stopped. m.mu.Lock() m.mu.Unlock() return nil // otherwise, we'll get something from errServe, which indicates that an // error in serving has actually occurred and this isn't a planned shutdown default: return err } }