Exemple #1
0
func createCluster(t *testing.T, ts *testServer, id, name string, policy api.AcceptancePolicy, rootCA *ca.RootCA) *api.Cluster {
	cluster := createClusterObj(id, name, policy, rootCA)
	assert.NoError(t, ts.Store.Update(func(tx store.Tx) error {
		return store.CreateCluster(tx, cluster)
	}))
	return cluster
}
Exemple #2
0
// NewInitNode creates a new raft node initiating the cluster
// for other members to join
func NewInitNode(t *testing.T, tc *cautils.TestCA, raftConfig *api.RaftConfig, opts ...raft.NewNodeOptions) (*TestNode, *fakeclock.FakeClock) {
	ctx := context.Background()
	clockSource := fakeclock.NewFakeClock(time.Now())
	n := NewNode(t, clockSource, tc, opts...)

	err := n.Node.JoinAndStart()
	require.NoError(t, err, "can't join cluster")

	leadershipCh, cancel := n.SubscribeLeadership()
	defer cancel()

	go n.Run(ctx)

	// Wait for the node to become the leader.
	<-leadershipCh

	if raftConfig != nil {
		assert.NoError(t, n.MemoryStore().Update(func(tx store.Tx) error {
			return store.CreateCluster(tx, &api.Cluster{
				ID: identity.NewID(),
				Spec: api.ClusterSpec{
					Annotations: api.Annotations{
						Name: store.DefaultClusterName,
					},
					Raft: *raftConfig,
				},
			})
		}))
	}

	return n, clockSource
}
Exemple #3
0
func createCluster(t *testing.T, s *store.MemoryStore, id, name string) *api.Cluster {
	spec := createClusterSpec(name)

	cluster := &api.Cluster{
		ID:   id,
		Spec: *spec,
	}
	assert.NoError(t, s.Update(func(tx store.Tx) error {
		return store.CreateCluster(tx, cluster)
	}))
	return cluster
}
Exemple #4
0
func createClusterObject(t *testing.T, s *store.MemoryStore, acceptancePolicy api.AcceptancePolicy) {
	assert.NoError(t, s.Update(func(tx store.Tx) error {
		store.CreateCluster(tx, &api.Cluster{
			ID: identity.NewID(),
			Spec: api.ClusterSpec{
				Annotations: api.Annotations{
					Name: store.DefaultClusterName,
				},
				AcceptancePolicy: acceptancePolicy,
			},
		})
		return nil
	}))
}
Exemple #5
0
func createClusterObject(t *testing.T, s *store.MemoryStore, clusterID string, acceptancePolicy api.AcceptancePolicy, externalCAs ...*api.ExternalCA) {
	assert.NoError(t, s.Update(func(tx store.Tx) error {
		store.CreateCluster(tx, &api.Cluster{
			ID: clusterID,
			Spec: api.ClusterSpec{
				Annotations: api.Annotations{
					Name: store.DefaultClusterName,
				},
				AcceptancePolicy: acceptancePolicy,
				CAConfig: api.CAConfig{
					ExternalCAs: externalCAs,
				},
			},
		})
		return nil
	}))
}
func createCluster(t *testing.T, ts *testServer, id, name string, policy api.AcceptancePolicy) *api.Cluster {
	spec := createClusterSpec(name)
	spec.AcceptancePolicy = policy

	cluster := &api.Cluster{
		ID:   id,
		Spec: *spec,
		RootCA: api.RootCA{
			CACert:     []byte("-----BEGIN CERTIFICATE-----AwEHoUQDQgAEZ4vGYkSt/kjoHbUjDx9eyO1xBVJEH2F+AwM9lACIZ414cD1qYy8u-----BEGIN CERTIFICATE-----"),
			CAKey:      []byte("-----BEGIN EC PRIVATE KEY-----AwEHoUQDQgAEZ4vGYkSt/kjoHbUjDx9eyO1xBVJEH2F+AwM9lACIZ414cD1qYy8u-----END EC PRIVATE KEY-----"),
			CACertHash: "hash",
		},
	}
	assert.NoError(t, ts.Store.Update(func(tx store.Tx) error {
		return store.CreateCluster(tx, cluster)
	}))
	return cluster
}
Exemple #7
0
func createClusterObject(t *testing.T, s *store.MemoryStore, clusterID, workerToken, managerToken string, externalCAs ...*api.ExternalCA) {
	assert.NoError(t, s.Update(func(tx store.Tx) error {
		store.CreateCluster(tx, &api.Cluster{
			ID: clusterID,
			Spec: api.ClusterSpec{
				Annotations: api.Annotations{
					Name: store.DefaultClusterName,
				},
				CAConfig: api.CAConfig{
					ExternalCAs: externalCAs,
				},
			},
			RootCA: api.RootCA{
				JoinTokens: api.JoinTokens{
					Worker:  workerToken,
					Manager: managerToken,
				},
			},
		})
		return nil
	}))
}
Exemple #8
0
// 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
	}
}
Exemple #9
0
// becomeLeader starts the subsystems that are run on the leader.
func (m *Manager) becomeLeader(ctx context.Context) {
	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, defaultClusterObject(clusterID, initialCAConfig, raftCfg, rootCA))
		// Add Node entry for ourself, if one
		// doesn't exist already.
		store.CreateNode(tx, managerNode(nodeID))
		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(s, 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)

}
func TestUpdater(t *testing.T) {
	ctx := context.Background()
	s := store.NewMemoryStore(nil)
	assert.NotNil(t, s)

	// Move tasks to their desired state.
	watch, cancel := state.Watch(s.WatchQueue(), state.EventUpdateTask{})
	defer cancel()
	go func() {
		for {
			select {
			case e := <-watch:
				task := e.(state.EventUpdateTask).Task
				if task.Status.State == task.DesiredState {
					continue
				}
				err := s.Update(func(tx store.Tx) error {
					task = store.GetTask(tx, task.ID)
					task.Status.State = task.DesiredState
					return store.UpdateTask(tx, task)
				})
				assert.NoError(t, err)
			}
		}
	}()

	instances := 3
	cluster := &api.Cluster{
		// test cluster configuration propagation to task creation.
		Spec: api.ClusterSpec{
			Annotations: api.Annotations{
				Name: "default",
			},
		},
	}

	service := &api.Service{
		ID: "id1",
		Spec: api.ServiceSpec{
			Annotations: api.Annotations{
				Name: "name1",
			},
			Mode: &api.ServiceSpec_Replicated{
				Replicated: &api.ReplicatedService{
					Replicas: uint64(instances),
				},
			},
			Task: api.TaskSpec{
				Runtime: &api.TaskSpec_Container{
					Container: &api.ContainerSpec{
						Image: "v:1",
						// This won't apply in this test because we set the old tasks to DEAD.
						StopGracePeriod: ptypes.DurationProto(time.Hour),
					},
				},
			},
		},
	}

	err := s.Update(func(tx store.Tx) error {
		assert.NoError(t, store.CreateCluster(tx, cluster))
		assert.NoError(t, store.CreateService(tx, service))
		for i := 0; i < instances; i++ {
			assert.NoError(t, store.CreateTask(tx, newTask(cluster, service, uint64(i))))
		}
		return nil
	})
	assert.NoError(t, err)

	originalTasks := getRunnableServiceTasks(t, s, service)
	for _, task := range originalTasks {
		assert.Equal(t, "v:1", task.Spec.GetContainer().Image)
		assert.Nil(t, task.LogDriver) // should be left alone
	}

	service.Spec.Task.GetContainer().Image = "v:2"
	service.Spec.Task.LogDriver = &api.Driver{Name: "tasklogdriver"}
	updater := NewUpdater(s, NewRestartSupervisor(s))
	updater.Run(ctx, cluster, service, getRunnableServiceTasks(t, s, service))
	updatedTasks := getRunnableServiceTasks(t, s, service)
	for _, task := range updatedTasks {
		assert.Equal(t, "v:2", task.Spec.GetContainer().Image)
		assert.Equal(t, service.Spec.Task.LogDriver, task.LogDriver) // pick up from task
	}

	service.Spec.Task.GetContainer().Image = "v:3"
	cluster.Spec.DefaultLogDriver = &api.Driver{Name: "clusterlogdriver"} // make cluster default logdriver.
	service.Spec.Update = &api.UpdateConfig{
		Parallelism: 1,
	}
	updater = NewUpdater(s, NewRestartSupervisor(s))
	updater.Run(ctx, cluster, service, getRunnableServiceTasks(t, s, service))
	updatedTasks = getRunnableServiceTasks(t, s, service)
	for _, task := range updatedTasks {
		assert.Equal(t, "v:3", task.Spec.GetContainer().Image)
		assert.Equal(t, service.Spec.Task.LogDriver, task.LogDriver) // still pick up from task
	}

	service.Spec.Task.GetContainer().Image = "v:4"
	service.Spec.Task.LogDriver = nil // use cluster default now.
	service.Spec.Update = &api.UpdateConfig{
		Parallelism: 1,
		Delay:       *ptypes.DurationProto(10 * time.Millisecond),
	}
	updater = NewUpdater(s, NewRestartSupervisor(s))
	updater.Run(ctx, cluster, service, getRunnableServiceTasks(t, s, service))
	updatedTasks = getRunnableServiceTasks(t, s, service)
	for _, task := range updatedTasks {
		assert.Equal(t, "v:4", task.Spec.GetContainer().Image)
		assert.Equal(t, cluster.Spec.DefaultLogDriver, task.LogDriver) // pick up from cluster
	}
}
Exemple #11
0
func TestTaskHistory(t *testing.T) {
	ctx := context.Background()
	s := store.NewMemoryStore(nil)
	assert.NotNil(t, s)

	assert.NoError(t, s.Update(func(tx store.Tx) error {
		store.CreateCluster(tx, &api.Cluster{
			ID: identity.NewID(),
			Spec: api.ClusterSpec{
				Annotations: api.Annotations{
					Name: store.DefaultClusterName,
				},
				Orchestration: api.OrchestrationConfig{
					TaskHistoryRetentionLimit: 2,
				},
			},
		})
		return nil
	}))

	taskReaper := NewTaskReaper(s)
	defer taskReaper.Stop()
	orchestrator := NewReplicatedOrchestrator(s)
	defer orchestrator.Stop()

	watch, cancel := state.Watch(s.WatchQueue() /*state.EventCreateTask{}, state.EventUpdateTask{}*/)
	defer cancel()

	// Create a service with two instances specified before the orchestrator is
	// started. This should result in two tasks when the orchestrator
	// starts up.
	err := s.Update(func(tx store.Tx) error {
		j1 := &api.Service{
			ID: "id1",
			Spec: api.ServiceSpec{
				Annotations: api.Annotations{
					Name: "name1",
				},
				Mode: &api.ServiceSpec_Replicated{
					Replicated: &api.ReplicatedService{
						Replicas: 2,
					},
				},
				Task: api.TaskSpec{
					Restart: &api.RestartPolicy{
						Condition: api.RestartOnAny,
						Delay:     ptypes.DurationProto(0),
					},
				},
			},
		}
		assert.NoError(t, store.CreateService(tx, j1))
		return nil
	})
	assert.NoError(t, err)

	// Start the orchestrator.
	go func() {
		assert.NoError(t, orchestrator.Run(ctx))
	}()
	go taskReaper.Run()

	observedTask1 := watchTaskCreate(t, watch)
	assert.Equal(t, observedTask1.Status.State, api.TaskStateNew)
	assert.Equal(t, observedTask1.ServiceAnnotations.Name, "name1")

	observedTask2 := watchTaskCreate(t, watch)
	assert.Equal(t, observedTask2.Status.State, api.TaskStateNew)
	assert.Equal(t, observedTask2.ServiceAnnotations.Name, "name1")

	// Fail both tasks. They should both get restarted.
	updatedTask1 := observedTask1.Copy()
	updatedTask1.Status.State = api.TaskStateFailed
	updatedTask1.ServiceAnnotations = api.Annotations{Name: "original"}
	updatedTask2 := observedTask2.Copy()
	updatedTask2.Status.State = api.TaskStateFailed
	updatedTask2.ServiceAnnotations = api.Annotations{Name: "original"}
	err = s.Update(func(tx store.Tx) error {
		assert.NoError(t, store.UpdateTask(tx, updatedTask1))
		assert.NoError(t, store.UpdateTask(tx, updatedTask2))
		return nil
	})

	expectCommit(t, watch)
	expectTaskUpdate(t, watch)
	expectTaskUpdate(t, watch)
	expectCommit(t, watch)

	expectTaskUpdate(t, watch)
	observedTask3 := watchTaskCreate(t, watch)
	assert.Equal(t, observedTask3.Status.State, api.TaskStateNew)
	assert.Equal(t, observedTask3.ServiceAnnotations.Name, "name1")

	expectTaskUpdate(t, watch)
	observedTask4 := watchTaskCreate(t, watch)
	assert.Equal(t, observedTask4.Status.State, api.TaskStateNew)
	assert.Equal(t, observedTask4.ServiceAnnotations.Name, "name1")

	// Fail these replacement tasks. Since TaskHistory is set to 2, this
	// should cause the oldest tasks for each instance to get deleted.
	updatedTask3 := observedTask3.Copy()
	updatedTask3.Status.State = api.TaskStateFailed
	updatedTask4 := observedTask4.Copy()
	updatedTask4.Status.State = api.TaskStateFailed
	err = s.Update(func(tx store.Tx) error {
		assert.NoError(t, store.UpdateTask(tx, updatedTask3))
		assert.NoError(t, store.UpdateTask(tx, updatedTask4))
		return nil
	})

	deletedTask1 := watchTaskDelete(t, watch)
	deletedTask2 := watchTaskDelete(t, watch)

	assert.Equal(t, api.TaskStateFailed, deletedTask1.Status.State)
	assert.Equal(t, "original", deletedTask1.ServiceAnnotations.Name)
	assert.Equal(t, api.TaskStateFailed, deletedTask2.Status.State)
	assert.Equal(t, "original", deletedTask2.ServiceAnnotations.Name)

	var foundTasks []*api.Task
	s.View(func(tx store.ReadTx) {
		foundTasks, err = store.FindTasks(tx, store.All)
	})
	assert.NoError(t, err)
	assert.Len(t, foundTasks, 4)
}
Exemple #12
0
func TestRemoveNodes(t *testing.T) {
	ts := newTestServer(t)
	defer ts.Stop()

	ts.Store.Update(func(tx store.Tx) error {
		store.CreateCluster(tx, &api.Cluster{
			ID: identity.NewID(),
			Spec: api.ClusterSpec{
				Annotations: api.Annotations{
					Name: store.DefaultClusterName,
				},
			},
		})
		return nil
	})

	r, err := ts.Client.ListNodes(context.Background(), &api.ListNodesRequest{})
	assert.NoError(t, err)
	assert.Empty(t, r.Nodes)

	createNode(t, ts, "id1", api.NodeRoleManager, api.NodeMembershipAccepted, api.NodeStatus_READY)
	r, err = ts.Client.ListNodes(context.Background(), &api.ListNodesRequest{})
	assert.NoError(t, err)
	assert.Len(t, r.Nodes, 1)

	createNode(t, ts, "id2", api.NodeRoleWorker, api.NodeMembershipAccepted, api.NodeStatus_READY)
	createNode(t, ts, "id3", api.NodeRoleWorker, api.NodeMembershipPending, api.NodeStatus_UNKNOWN)
	r, err = ts.Client.ListNodes(context.Background(), &api.ListNodesRequest{})
	assert.NoError(t, err)
	assert.Len(t, r.Nodes, 3)

	// Attempt to remove a ready node without force
	_, err = ts.Client.RemoveNode(context.Background(),
		&api.RemoveNodeRequest{
			NodeID: "id2",
			Force:  false,
		},
	)
	assert.Error(t, err)

	r, err = ts.Client.ListNodes(context.Background(),
		&api.ListNodesRequest{
			Filters: &api.ListNodesRequest_Filters{
				Roles: []api.NodeRole{api.NodeRoleManager, api.NodeRoleWorker},
			},
		},
	)
	assert.NoError(t, err)
	assert.Len(t, r.Nodes, 3)

	// Attempt to remove a ready node with force
	_, err = ts.Client.RemoveNode(context.Background(),
		&api.RemoveNodeRequest{
			NodeID: "id2",
			Force:  true,
		},
	)
	assert.NoError(t, err)

	r, err = ts.Client.ListNodes(context.Background(),
		&api.ListNodesRequest{
			Filters: &api.ListNodesRequest_Filters{
				Roles: []api.NodeRole{api.NodeRoleManager, api.NodeRoleWorker},
			},
		},
	)
	assert.NoError(t, err)
	assert.Len(t, r.Nodes, 2)

	clusterResp, err := ts.Client.ListClusters(context.Background(), &api.ListClustersRequest{})
	assert.NoError(t, err)
	require.Len(t, clusterResp.Clusters, 1)
	require.Len(t, clusterResp.Clusters[0].BlacklistedCertificates, 1)
	_, ok := clusterResp.Clusters[0].BlacklistedCertificates["id2"]
	assert.True(t, ok)

	// Attempt to remove a non-ready node without force
	_, err = ts.Client.RemoveNode(context.Background(),
		&api.RemoveNodeRequest{
			NodeID: "id3",
			Force:  false,
		},
	)
	assert.NoError(t, err)

	r, err = ts.Client.ListNodes(context.Background(),
		&api.ListNodesRequest{
			Filters: &api.ListNodesRequest_Filters{
				Roles: []api.NodeRole{api.NodeRoleManager, api.NodeRoleWorker},
			},
		},
	)
	assert.NoError(t, err)
	assert.Len(t, r.Nodes, 1)
}
Exemple #13
0
func TestUpdaterFailureAction(t *testing.T) {
	ctx := context.Background()
	s := store.NewMemoryStore(nil)
	assert.NotNil(t, s)
	defer s.Close()

	// Fail new tasks the updater tries to run
	watch, cancel := state.Watch(s.WatchQueue(), state.EventUpdateTask{})
	defer cancel()
	go func() {
		for {
			select {
			case e := <-watch:
				task := e.(state.EventUpdateTask).Task
				if task.DesiredState == api.TaskStateRunning && task.Status.State != api.TaskStateFailed {
					err := s.Update(func(tx store.Tx) error {
						task = store.GetTask(tx, task.ID)
						task.Status.State = api.TaskStateFailed
						return store.UpdateTask(tx, task)
					})
					assert.NoError(t, err)
				} else if task.DesiredState > api.TaskStateRunning {
					err := s.Update(func(tx store.Tx) error {
						task = store.GetTask(tx, task.ID)
						task.Status.State = task.DesiredState
						return store.UpdateTask(tx, task)
					})
					assert.NoError(t, err)
				}
			}
		}
	}()

	instances := 3
	cluster := &api.Cluster{
		Spec: api.ClusterSpec{
			Annotations: api.Annotations{
				Name: "default",
			},
		},
	}

	service := &api.Service{
		ID: "id1",
		Spec: api.ServiceSpec{
			Annotations: api.Annotations{
				Name: "name1",
			},
			Mode: &api.ServiceSpec_Replicated{
				Replicated: &api.ReplicatedService{
					Replicas: uint64(instances),
				},
			},
			Task: api.TaskSpec{
				Runtime: &api.TaskSpec_Container{
					Container: &api.ContainerSpec{
						Image: "v:1",
						// This won't apply in this test because we set the old tasks to DEAD.
						StopGracePeriod: ptypes.DurationProto(time.Hour),
					},
				},
			},
			Update: &api.UpdateConfig{
				FailureAction: api.UpdateConfig_PAUSE,
				Parallelism:   1,
				Delay:         *ptypes.DurationProto(500 * time.Millisecond),
			},
		},
	}

	err := s.Update(func(tx store.Tx) error {
		assert.NoError(t, store.CreateCluster(tx, cluster))
		assert.NoError(t, store.CreateService(tx, service))
		for i := 0; i < instances; i++ {
			assert.NoError(t, store.CreateTask(tx, newTask(cluster, service, uint64(i))))
		}
		return nil
	})
	assert.NoError(t, err)

	originalTasks := getRunnableSlotSlice(t, s, service)
	for _, slot := range originalTasks {
		for _, task := range slot {
			assert.Equal(t, "v:1", task.Spec.GetContainer().Image)
		}
	}

	service.Spec.Task.GetContainer().Image = "v:2"
	updater := NewUpdater(s, NewRestartSupervisor(s), cluster, service)
	updater.Run(ctx, getRunnableSlotSlice(t, s, service))
	updatedTasks := getRunnableSlotSlice(t, s, service)
	v1Counter := 0
	v2Counter := 0
	for _, slot := range updatedTasks {
		for _, task := range slot {
			if task.Spec.GetContainer().Image == "v:1" {
				v1Counter++
			} else if task.Spec.GetContainer().Image == "v:2" {
				v2Counter++
			}
		}
	}
	assert.Equal(t, instances-1, v1Counter)
	assert.Equal(t, 1, v2Counter)

	s.View(func(tx store.ReadTx) {
		service = store.GetService(tx, service.ID)
	})
	assert.Equal(t, api.UpdateStatus_PAUSED, service.UpdateStatus.State)

	// Updating again should do nothing while the update is PAUSED
	updater = NewUpdater(s, NewRestartSupervisor(s), cluster, service)
	updater.Run(ctx, getRunnableSlotSlice(t, s, service))
	updatedTasks = getRunnableSlotSlice(t, s, service)
	v1Counter = 0
	v2Counter = 0
	for _, slot := range updatedTasks {
		for _, task := range slot {
			if task.Spec.GetContainer().Image == "v:1" {
				v1Counter++
			} else if task.Spec.GetContainer().Image == "v:2" {
				v2Counter++
			}
		}
	}
	assert.Equal(t, instances-1, v1Counter)
	assert.Equal(t, 1, v2Counter)

	// Switch to a service with FailureAction: CONTINUE
	err = s.Update(func(tx store.Tx) error {
		service = store.GetService(tx, service.ID)
		service.Spec.Update.FailureAction = api.UpdateConfig_CONTINUE
		service.UpdateStatus = nil
		assert.NoError(t, store.UpdateService(tx, service))
		return nil
	})
	assert.NoError(t, err)

	service.Spec.Task.GetContainer().Image = "v:3"
	updater = NewUpdater(s, NewRestartSupervisor(s), cluster, service)
	updater.Run(ctx, getRunnableSlotSlice(t, s, service))
	updatedTasks = getRunnableSlotSlice(t, s, service)
	v2Counter = 0
	v3Counter := 0
	for _, slot := range updatedTasks {
		for _, task := range slot {
			if task.Spec.GetContainer().Image == "v:2" {
				v2Counter++
			} else if task.Spec.GetContainer().Image == "v:3" {
				v3Counter++
			}
		}
	}

	assert.Equal(t, 0, v2Counter)
	assert.Equal(t, instances, v3Counter)

}
Exemple #14
0
func TestUpdateClusterRotateUnlockKey(t *testing.T) {
	ts := newTestServer(t)
	defer ts.Stop()
	// create a cluster with extra encryption keys, to make sure they exist
	cluster := createClusterObj("id", "name", api.AcceptancePolicy{}, ts.Server.rootCA)
	expected := make(map[string]*api.EncryptionKey)
	for i := 1; i <= 2; i++ {
		value := fmt.Sprintf("fake%d", i)
		expected[value] = &api.EncryptionKey{Subsystem: value, Key: []byte(value)}
		cluster.UnlockKeys = append(cluster.UnlockKeys, expected[value])
	}
	require.NoError(t, ts.Store.Update(func(tx store.Tx) error {
		return store.CreateCluster(tx, cluster)
	}))

	// we have to get the key from the memory store, since the cluster returned by the API is redacted
	getManagerKey := func() (managerKey *api.EncryptionKey) {
		ts.Store.View(func(tx store.ReadTx) {
			viewCluster := store.GetCluster(tx, cluster.ID)
			// no matter whether there's a manager key or not, the other keys should not have been affected
			foundKeys := make(map[string]*api.EncryptionKey)
			for _, eKey := range viewCluster.UnlockKeys {
				foundKeys[eKey.Subsystem] = eKey
			}
			for v, key := range expected {
				foundKey, ok := foundKeys[v]
				require.True(t, ok)
				require.Equal(t, key, foundKey)
			}
			managerKey = foundKeys[ca.ManagerRole]
		})
		return
	}

	validateListResult := func(expectedLocked bool) api.Version {
		r, err := ts.Client.ListClusters(context.Background(), &api.ListClustersRequest{
			Filters: &api.ListClustersRequest_Filters{
				NamePrefixes: []string{"name"},
			},
		})

		require.NoError(t, err)
		require.Len(t, r.Clusters, 1)
		require.Equal(t, expectedLocked, r.Clusters[0].Spec.EncryptionConfig.AutoLockManagers)
		require.Nil(t, r.Clusters[0].UnlockKeys) // redacted

		return r.Clusters[0].Meta.Version
	}

	// we start off with manager autolocking turned off
	version := validateListResult(false)
	require.Nil(t, getManagerKey())

	// Rotate unlock key without turning auto-lock on - key should still be nil
	_, err := ts.Client.UpdateCluster(context.Background(), &api.UpdateClusterRequest{
		ClusterID:      cluster.ID,
		Spec:           &cluster.Spec,
		ClusterVersion: &version,
		Rotation: api.KeyRotation{
			ManagerUnlockKey: true,
		},
	})
	require.NoError(t, err)
	version = validateListResult(false)
	require.Nil(t, getManagerKey())

	// Enable auto-lock only, no rotation boolean
	spec := cluster.Spec.Copy()
	spec.EncryptionConfig.AutoLockManagers = true
	_, err = ts.Client.UpdateCluster(context.Background(), &api.UpdateClusterRequest{
		ClusterID:      cluster.ID,
		Spec:           spec,
		ClusterVersion: &version,
	})
	require.NoError(t, err)
	version = validateListResult(true)
	managerKey := getManagerKey()
	require.NotNil(t, managerKey)

	// Rotate the manager key
	_, err = ts.Client.UpdateCluster(context.Background(), &api.UpdateClusterRequest{
		ClusterID:      cluster.ID,
		Spec:           spec,
		ClusterVersion: &version,
		Rotation: api.KeyRotation{
			ManagerUnlockKey: true,
		},
	})
	require.NoError(t, err)
	version = validateListResult(true)
	newManagerKey := getManagerKey()
	require.NotNil(t, managerKey)
	require.NotEqual(t, managerKey, newManagerKey)
	managerKey = newManagerKey

	// Just update the cluster without modifying unlock keys
	_, err = ts.Client.UpdateCluster(context.Background(), &api.UpdateClusterRequest{
		ClusterID:      cluster.ID,
		Spec:           spec,
		ClusterVersion: &version,
	})
	require.NoError(t, err)
	version = validateListResult(true)
	newManagerKey = getManagerKey()
	require.Equal(t, managerKey, newManagerKey)

	// Disable auto lock
	_, err = ts.Client.UpdateCluster(context.Background(), &api.UpdateClusterRequest{
		ClusterID:      cluster.ID,
		Spec:           &cluster.Spec, // set back to original spec
		ClusterVersion: &version,
		Rotation: api.KeyRotation{
			ManagerUnlockKey: true, // this will be ignored because we disable the auto-lock
		},
	})
	require.NoError(t, err)
	validateListResult(false)
	require.Nil(t, getManagerKey())
}
Exemple #15
0
func TestUpdater(t *testing.T) {
	ctx := context.Background()
	s := store.NewMemoryStore(nil)
	assert.NotNil(t, s)
	defer s.Close()

	// Move tasks to their desired state.
	watch, cancel := state.Watch(s.WatchQueue(), state.EventUpdateTask{})
	defer cancel()
	go func() {
		for {
			select {
			case e := <-watch:
				task := e.(state.EventUpdateTask).Task
				if task.Status.State == task.DesiredState {
					continue
				}
				err := s.Update(func(tx store.Tx) error {
					task = store.GetTask(tx, task.ID)
					task.Status.State = task.DesiredState
					return store.UpdateTask(tx, task)
				})
				assert.NoError(t, err)
			}
		}
	}()

	instances := 3
	cluster := &api.Cluster{
		// test cluster configuration propagation to task creation.
		Spec: api.ClusterSpec{
			Annotations: api.Annotations{
				Name: "default",
			},
		},
	}

	service := &api.Service{
		ID: "id1",
		Spec: api.ServiceSpec{
			Annotations: api.Annotations{
				Name: "name1",
			},
			Mode: &api.ServiceSpec_Replicated{
				Replicated: &api.ReplicatedService{
					Replicas: uint64(instances),
				},
			},
			Task: api.TaskSpec{
				Runtime: &api.TaskSpec_Container{
					Container: &api.ContainerSpec{
						Image: "v:1",
					},
				},
			},
			Update: &api.UpdateConfig{
				// avoid having Run block for a long time to watch for failures
				Monitor: gogotypes.DurationProto(50 * time.Millisecond),
			},
		},
	}

	err := s.Update(func(tx store.Tx) error {
		assert.NoError(t, store.CreateCluster(tx, cluster))
		assert.NoError(t, store.CreateService(tx, service))
		for i := 0; i < instances; i++ {
			assert.NoError(t, store.CreateTask(tx, orchestrator.NewTask(cluster, service, uint64(i), "")))
		}
		return nil
	})
	assert.NoError(t, err)

	originalTasks := getRunnableSlotSlice(t, s, service)
	for _, slot := range originalTasks {
		for _, task := range slot {
			assert.Equal(t, "v:1", task.Spec.GetContainer().Image)
			assert.Nil(t, task.LogDriver) // should be left alone
		}
	}

	service.Spec.Task.GetContainer().Image = "v:2"
	service.Spec.Task.LogDriver = &api.Driver{Name: "tasklogdriver"}
	updater := NewUpdater(s, restart.NewSupervisor(s), cluster, service)
	updater.Run(ctx, getRunnableSlotSlice(t, s, service))
	updatedTasks := getRunnableSlotSlice(t, s, service)
	for _, slot := range updatedTasks {
		for _, task := range slot {
			assert.Equal(t, "v:2", task.Spec.GetContainer().Image)
			assert.Equal(t, service.Spec.Task.LogDriver, task.LogDriver) // pick up from task
		}
	}

	service.Spec.Task.GetContainer().Image = "v:3"
	cluster.Spec.TaskDefaults.LogDriver = &api.Driver{Name: "clusterlogdriver"} // make cluster default logdriver.
	service.Spec.Update = &api.UpdateConfig{
		Parallelism: 1,
		Monitor:     gogotypes.DurationProto(50 * time.Millisecond),
	}
	updater = NewUpdater(s, restart.NewSupervisor(s), cluster, service)
	updater.Run(ctx, getRunnableSlotSlice(t, s, service))
	updatedTasks = getRunnableSlotSlice(t, s, service)
	for _, slot := range updatedTasks {
		for _, task := range slot {
			assert.Equal(t, "v:3", task.Spec.GetContainer().Image)
			assert.Equal(t, service.Spec.Task.LogDriver, task.LogDriver) // still pick up from task
		}
	}

	service.Spec.Task.GetContainer().Image = "v:4"
	service.Spec.Task.LogDriver = nil // use cluster default now.
	service.Spec.Update = &api.UpdateConfig{
		Parallelism: 1,
		Delay:       10 * time.Millisecond,
		Monitor:     gogotypes.DurationProto(50 * time.Millisecond),
	}
	updater = NewUpdater(s, restart.NewSupervisor(s), cluster, service)
	updater.Run(ctx, getRunnableSlotSlice(t, s, service))
	updatedTasks = getRunnableSlotSlice(t, s, service)
	for _, slot := range updatedTasks {
		for _, task := range slot {
			assert.Equal(t, "v:4", task.Spec.GetContainer().Image)
			assert.Equal(t, cluster.Spec.TaskDefaults.LogDriver, task.LogDriver) // pick up from cluster
		}
	}
}