package client import ( "fmt" "io/ioutil" "net" "os" "path/filepath" "runtime" "sort" "testing" "time" memdb "github.com/hashicorp/go-memdb" trstate "github.com/hashicorp/nomad/client/allocrunner/taskrunner/state" "github.com/hashicorp/nomad/client/config" consulApi "github.com/hashicorp/nomad/client/consul" "github.com/hashicorp/nomad/client/fingerprint" "github.com/hashicorp/nomad/client/state" "github.com/hashicorp/nomad/command/agent/consul" "github.com/hashicorp/nomad/helper/pluginutils/catalog" "github.com/hashicorp/nomad/helper/pluginutils/singleton" "github.com/hashicorp/nomad/helper/testlog" "github.com/hashicorp/nomad/helper/uuid" "github.com/hashicorp/nomad/nomad" "github.com/hashicorp/nomad/nomad/mock" "github.com/hashicorp/nomad/nomad/structs" nconfig "github.com/hashicorp/nomad/nomad/structs/config" "github.com/hashicorp/nomad/plugins/device" psstructs "github.com/hashicorp/nomad/plugins/shared/structs" "github.com/hashicorp/nomad/testutil" "github.com/stretchr/testify/assert" cstate "github.com/hashicorp/nomad/client/state" "github.com/stretchr/testify/require" ) func testACLServer(t *testing.T, cb func(*nomad.Config)) (*nomad.Server, string, *structs.ACLToken, func()) { server, token, cleanup := nomad.TestACLServer(t, cb) return server, server.GetConfig().RPCAddr.String(), token, cleanup } func testServer(t *testing.T, cb func(*nomad.Config)) (*nomad.Server, string, func()) { server, cleanup := nomad.TestServer(t, cb) return server, server.GetConfig().RPCAddr.String(), cleanup } func TestClient_StartStop(t *testing.T) { t.Parallel() client, cleanup := TestClient(t, nil) defer cleanup() if err := client.Shutdown(); err != nil { t.Fatalf("err: %v", err) } } // Certain labels for metrics are dependant on client initial setup. This tests // that the client has properly initialized before we assign values to labels func TestClient_BaseLabels(t *testing.T) { t.Parallel() assert := assert.New(t) client, cleanup := TestClient(t, nil) if err := client.Shutdown(); err != nil { t.Fatalf("err: %v", err) } defer cleanup() // directly invoke this function, as otherwise this will fail on a CI build // due to a race condition client.emitStats() baseLabels := client.baseLabels assert.NotEqual(0, len(baseLabels)) nodeID := client.Node().ID for _, e := range baseLabels { if e.Name == "node_id" { assert.Equal(nodeID, e.Value) } } } func TestClient_RPC(t *testing.T) { t.Parallel() _, addr, cleanupS1 := testServer(t, nil) defer cleanupS1() c1, cleanupC1 := TestClient(t, func(c *config.Config) { c.Servers = []string{addr} }) defer cleanupC1() // RPC should succeed testutil.WaitForResult(func() (bool, error) { var out struct{} err := c1.RPC("Status.Ping", struct{}{}, &out) return err == nil, err }, func(err error) { t.Fatalf("err: %v", err) }) } func TestClient_RPC_FireRetryWatchers(t *testing.T) { t.Parallel() _, addr, cleanupS1 := testServer(t, nil) defer cleanupS1() c1, cleanupC1 := TestClient(t, func(c *config.Config) { c.Servers = []string{addr} }) defer cleanupC1() watcher := c1.rpcRetryWatcher() // RPC should succeed testutil.WaitForResult(func() (bool, error) { var out struct{} err := c1.RPC("Status.Ping", struct{}{}, &out) return err == nil, err }, func(err error) { t.Fatalf("err: %v", err) }) select { case <-watcher: default: t.Fatal("watcher should be fired") } } func TestClient_RPC_Passthrough(t *testing.T) { t.Parallel() s1, _, cleanupS1 := testServer(t, nil) defer cleanupS1() c1, cleanupC1 := TestClient(t, func(c *config.Config) { c.RPCHandler = s1 }) defer cleanupC1() // RPC should succeed testutil.WaitForResult(func() (bool, error) { var out struct{} err := c1.RPC("Status.Ping", struct{}{}, &out) return err == nil, err }, func(err error) { t.Fatalf("err: %v", err) }) } func TestClient_Fingerprint(t *testing.T) { t.Parallel() c, cleanup := TestClient(t, nil) defer cleanup() // Ensure we are fingerprinting testutil.WaitForResult(func() (bool, error) { node := c.Node() if _, ok := node.Attributes["kernel.name"]; !ok { return false, fmt.Errorf("Expected value for kernel.name") } if _, ok := node.Attributes["cpu.arch"]; !ok { return false, fmt.Errorf("Expected value for cpu.arch") } return true, nil }, func(err error) { t.Fatalf("err: %v", err) }) } // TestClient_Fingerprint_Periodic asserts that driver node attributes are // periodically fingerprinted. func TestClient_Fingerprint_Periodic(t *testing.T) { t.Parallel() c1, cleanup := TestClient(t, func(c *config.Config) { confs := []*nconfig.PluginConfig{ { Name: "mock_driver", Config: map[string]interface{}{ "shutdown_periodic_after": true, "shutdown_periodic_duration": time.Second, }, }, } c.PluginLoader = catalog.TestPluginLoaderWithOptions(t, "", nil, confs) }) defer cleanup() node := c1.config.Node { // Ensure the mock driver is registered on the client testutil.WaitForResult(func() (bool, error) { c1.configLock.Lock() defer c1.configLock.Unlock() // assert that the driver is set on the node attributes mockDriverInfoAttr := node.Attributes["driver.mock_driver"] if mockDriverInfoAttr == "" { return false, fmt.Errorf("mock driver is empty when it should be set on the node attributes") } mockDriverInfo := node.Drivers["mock_driver"] // assert that the Driver information for the node is also set correctly if mockDriverInfo == nil { return false, fmt.Errorf("mock driver is nil when it should be set on node Drivers") } if !mockDriverInfo.Detected { return false, fmt.Errorf("mock driver should be set as detected") } if !mockDriverInfo.Healthy { return false, fmt.Errorf("mock driver should be set as healthy") } if mockDriverInfo.HealthDescription == "" { return false, fmt.Errorf("mock driver description should not be empty") } return true, nil }, func(err error) { t.Fatalf("err: %v", err) }) } { testutil.WaitForResult(func() (bool, error) { c1.configLock.Lock() defer c1.configLock.Unlock() mockDriverInfo := node.Drivers["mock_driver"] // assert that the Driver information for the node is also set correctly if mockDriverInfo == nil { return false, fmt.Errorf("mock driver is nil when it should be set on node Drivers") } if mockDriverInfo.Detected { return false, fmt.Errorf("mock driver should not be set as detected") } if mockDriverInfo.Healthy { return false, fmt.Errorf("mock driver should not be set as healthy") } if mockDriverInfo.HealthDescription == "" { return false, fmt.Errorf("mock driver description should not be empty") } return true, nil }, func(err error) { t.Fatalf("err: %v", err) }) } } // TestClient_MixedTLS asserts that when a server is running with TLS enabled // it will reject any RPC connections from clients that lack TLS. See #2525 func TestClient_MixedTLS(t *testing.T) { t.Parallel() const ( cafile = "../helper/tlsutil/testdata/ca.pem" foocert = "../helper/tlsutil/testdata/nomad-foo.pem" fookey = "../helper/tlsutil/testdata/nomad-foo-key.pem" ) s1, addr, cleanupS1 := testServer(t, func(c *nomad.Config) { c.TLSConfig = &nconfig.TLSConfig{ EnableHTTP: true, EnableRPC: true, VerifyServerHostname: true, CAFile: cafile, CertFile: foocert, KeyFile: fookey, } }) defer cleanupS1() testutil.WaitForLeader(t, s1.RPC) c1, cleanup := TestClient(t, func(c *config.Config) { c.Servers = []string{addr} }) defer cleanup() req := structs.NodeSpecificRequest{ NodeID: c1.Node().ID, QueryOptions: structs.QueryOptions{Region: "global"}, } var out structs.SingleNodeResponse testutil.AssertUntil(100*time.Millisecond, func() (bool, error) { err := c1.RPC("Node.GetNode", &req, &out) if err == nil { return false, fmt.Errorf("client RPC succeeded when it should have failed:\n%+v", out) } return true, nil }, func(err error) { t.Fatalf(err.Error()) }, ) } // TestClient_BadTLS asserts that when a client and server are running with TLS // enabled -- but their certificates are signed by different CAs -- they're // unable to communicate. func TestClient_BadTLS(t *testing.T) { t.Parallel() const ( cafile = "../helper/tlsutil/testdata/ca.pem" foocert = "../helper/tlsutil/testdata/nomad-foo.pem" fookey = "../helper/tlsutil/testdata/nomad-foo-key.pem" badca = "../helper/tlsutil/testdata/ca-bad.pem" badcert = "../helper/tlsutil/testdata/nomad-bad.pem" badkey = "../helper/tlsutil/testdata/nomad-bad-key.pem" ) s1, addr, cleanupS1 := testServer(t, func(c *nomad.Config) { c.TLSConfig = &nconfig.TLSConfig{ EnableHTTP: true, EnableRPC: true, VerifyServerHostname: true, CAFile: cafile, CertFile: foocert, KeyFile: fookey, } }) defer cleanupS1() testutil.WaitForLeader(t, s1.RPC) c1, cleanupC1 := TestClient(t, func(c *config.Config) { c.Servers = []string{addr} c.TLSConfig = &nconfig.TLSConfig{ EnableHTTP: true, EnableRPC: true, VerifyServerHostname: true, CAFile: badca, CertFile: badcert, KeyFile: badkey, } }) defer cleanupC1() req := structs.NodeSpecificRequest{ NodeID: c1.Node().ID, QueryOptions: structs.QueryOptions{Region: "global"}, } var out structs.SingleNodeResponse testutil.AssertUntil(100*time.Millisecond, func() (bool, error) { err := c1.RPC("Node.GetNode", &req, &out) if err == nil { return false, fmt.Errorf("client RPC succeeded when it should have failed:\n%+v", out) } return true, nil }, func(err error) { t.Fatalf(err.Error()) }, ) } func TestClient_Register(t *testing.T) { t.Parallel() s1, _, cleanupS1 := testServer(t, nil) defer cleanupS1() testutil.WaitForLeader(t, s1.RPC) c1, cleanupC1 := TestClient(t, func(c *config.Config) { c.RPCHandler = s1 }) defer cleanupC1() req := structs.NodeSpecificRequest{ NodeID: c1.Node().ID, QueryOptions: structs.QueryOptions{Region: "global"}, } var out structs.SingleNodeResponse // Register should succeed testutil.WaitForResult(func() (bool, error) { err := s1.RPC("Node.GetNode", &req, &out) if err != nil { return false, err } if out.Node == nil { return false, fmt.Errorf("missing reg") } return out.Node.ID == req.NodeID, nil }, func(err error) { t.Fatalf("err: %v", err) }) } func TestClient_Heartbeat(t *testing.T) { t.Parallel() s1, _, cleanupS1 := testServer(t, func(c *nomad.Config) { c.MinHeartbeatTTL = 50 * time.Millisecond }) defer cleanupS1() testutil.WaitForLeader(t, s1.RPC) c1, cleanupC1 := TestClient(t, func(c *config.Config) { c.RPCHandler = s1 }) defer cleanupC1() req := structs.NodeSpecificRequest{ NodeID: c1.Node().ID, QueryOptions: structs.QueryOptions{Region: "global"}, } var out structs.SingleNodeResponse // Register should succeed testutil.WaitForResult(func() (bool, error) { err := s1.RPC("Node.GetNode", &req, &out) if err != nil { return false, err } if out.Node == nil { return false, fmt.Errorf("missing reg") } return out.Node.Status == structs.NodeStatusReady, nil }, func(err error) { t.Fatalf("err: %v", err) }) } // TestClient_UpdateAllocStatus that once running allocations send updates to // the server. func TestClient_UpdateAllocStatus(t *testing.T) { t.Parallel() s1, _, cleanupS1 := testServer(t, nil) defer cleanupS1() _, cleanup := TestClient(t, func(c *config.Config) { c.RPCHandler = s1 }) defer cleanup() job := mock.Job() // allow running job on any node including self client, that may not be a Linux box job.Constraints = nil job.TaskGroups[0].Count = 1 task := job.TaskGroups[0].Tasks[0] task.Driver = "mock_driver" task.Config = map[string]interface{}{ "run_for": "10s", } task.Services = nil // WaitForRunning polls the server until the ClientStatus is running testutil.WaitForRunning(t, s1.RPC, job) } func TestClient_WatchAllocs(t *testing.T) { t.Parallel() s1, _, cleanupS1 := testServer(t, nil) defer cleanupS1() testutil.WaitForLeader(t, s1.RPC) c1, cleanup := TestClient(t, func(c *config.Config) { c.RPCHandler = s1 }) defer cleanup() // Wait until the node is ready waitTilNodeReady(c1, t) // Create mock allocations job := mock.Job() job.TaskGroups[0].Count = 3 job.TaskGroups[0].Tasks[0].Driver = "mock_driver" job.TaskGroups[0].Tasks[0].Config = map[string]interface{}{ "run_for": "10s", } alloc1 := mock.Alloc() alloc1.JobID = job.ID alloc1.Job = job alloc1.NodeID = c1.Node().ID alloc2 := mock.Alloc() alloc2.NodeID = c1.Node().ID alloc2.JobID = job.ID alloc2.Job = job state := s1.State() if err := state.UpsertJob(100, job); err != nil { t.Fatal(err) } if err := state.UpsertJobSummary(101, mock.JobSummary(alloc1.JobID)); err != nil { t.Fatal(err) } err := state.UpsertAllocs(102, []*structs.Allocation{alloc1, alloc2}) if err != nil { t.Fatalf("err: %v", err) } // Both allocations should get registered testutil.WaitForResult(func() (bool, error) { c1.allocLock.RLock() num := len(c1.allocs) c1.allocLock.RUnlock() return num == 2, nil }, func(err error) { t.Fatalf("err: %v", err) }) // Delete one allocation if err := state.DeleteEval(103, nil, []string{alloc1.ID}); err != nil { t.Fatalf("err: %v", err) } // Update the other allocation. Have to make a copy because the allocs are // shared in memory in the test and the modify index would be updated in the // alloc runner. alloc2_2 := alloc2.Copy() alloc2_2.DesiredStatus = structs.AllocDesiredStatusStop if err := state.UpsertAllocs(104, []*structs.Allocation{alloc2_2}); err != nil { t.Fatalf("err upserting stopped alloc: %v", err) } // One allocation should get GC'd and removed testutil.WaitForResult(func() (bool, error) { c1.allocLock.RLock() num := len(c1.allocs) c1.allocLock.RUnlock() return num == 1, nil }, func(err error) { t.Fatalf("err: %v", err) }) // One allocations should get updated testutil.WaitForResult(func() (bool, error) { c1.allocLock.RLock() ar := c1.allocs[alloc2.ID] c1.allocLock.RUnlock() return ar.Alloc().DesiredStatus == structs.AllocDesiredStatusStop, nil }, func(err error) { t.Fatalf("err: %v", err) }) } func waitTilNodeReady(client *Client, t *testing.T) { testutil.WaitForResult(func() (bool, error) { n := client.Node() if n.Status != structs.NodeStatusReady { return false, fmt.Errorf("node not registered") } return true, nil }, func(err error) { t.Fatalf("err: %v", err) }) } func TestClient_SaveRestoreState(t *testing.T) { t.Parallel() s1, _, cleanupS1 := testServer(t, nil) defer cleanupS1() testutil.WaitForLeader(t, s1.RPC) c1, cleanupC1 := TestClient(t, func(c *config.Config) { c.DevMode = false c.RPCHandler = s1 }) defer cleanupC1() // Wait until the node is ready waitTilNodeReady(c1, t) // Create mock allocations job := mock.Job() alloc1 := mock.Alloc() alloc1.NodeID = c1.Node().ID alloc1.Job = job alloc1.JobID = job.ID alloc1.Job.TaskGroups[0].Tasks[0].Driver = "mock_driver" alloc1.Job.TaskGroups[0].Tasks[0].Config = map[string]interface{}{ "run_for": "10s", } alloc1.ClientStatus = structs.AllocClientStatusRunning state := s1.State() if err := state.UpsertJob(100, job); err != nil { t.Fatal(err) } if err := state.UpsertJobSummary(101, mock.JobSummary(alloc1.JobID)); err != nil { t.Fatal(err) } if err := state.UpsertAllocs(102, []*structs.Allocation{alloc1}); err != nil { t.Fatalf("err: %v", err) } // Allocations should get registered testutil.WaitForResult(func() (bool, error) { c1.allocLock.RLock() ar := c1.allocs[alloc1.ID] c1.allocLock.RUnlock() if ar == nil { return false, fmt.Errorf("nil alloc runner") } if ar.Alloc().ClientStatus != structs.AllocClientStatusRunning { return false, fmt.Errorf("client status: got %v; want %v", ar.Alloc().ClientStatus, structs.AllocClientStatusRunning) } return true, nil }, func(err error) { t.Fatalf("err: %v", err) }) // Shutdown the client, saves state if err := c1.Shutdown(); err != nil { t.Fatalf("err: %v", err) } // Create a new client logger := testlog.HCLogger(t) c1.config.Logger = logger consulCatalog := consul.NewMockCatalog(logger) mockService := consulApi.NewMockConsulServiceClient(t, logger) // ensure we use non-shutdown driver instances c1.config.PluginLoader = catalog.TestPluginLoaderWithOptions(t, "", c1.config.Options, nil) c1.config.PluginSingletonLoader = singleton.NewSingletonLoader(logger, c1.config.PluginLoader) c2, err := NewClient(c1.config, consulCatalog, mockService) if err != nil { t.Fatalf("err: %v", err) } defer c2.Shutdown() // Ensure the allocation is running testutil.WaitForResult(func() (bool, error) { c2.allocLock.RLock() ar := c2.allocs[alloc1.ID] c2.allocLock.RUnlock() status := ar.Alloc().ClientStatus alive := status == structs.AllocClientStatusRunning || status == structs.AllocClientStatusPending if !alive { return false, fmt.Errorf("incorrect client status: %#v", ar.Alloc()) } return true, nil }, func(err error) { t.Fatalf("err: %v", err) }) // Destroy all the allocations for _, ar := range c2.getAllocRunners() { ar.Destroy() } for _, ar := range c2.getAllocRunners() { <-ar.DestroyCh() } } func TestClient_AddAllocError(t *testing.T) { t.Parallel() require := require.New(t) s1, _, cleanupS1 := testServer(t, nil) defer cleanupS1() testutil.WaitForLeader(t, s1.RPC) c1, cleanupC1 := TestClient(t, func(c *config.Config) { c.DevMode = false c.RPCHandler = s1 }) defer cleanupC1() // Wait until the node is ready waitTilNodeReady(c1, t) // Create mock allocation with invalid task group name job := mock.Job() alloc1 := mock.Alloc() alloc1.NodeID = c1.Node().ID alloc1.Job = job alloc1.JobID = job.ID alloc1.Job.TaskGroups[0].Tasks[0].Driver = "mock_driver" alloc1.Job.TaskGroups[0].Tasks[0].Config = map[string]interface{}{ "run_for": "10s", } alloc1.ClientStatus = structs.AllocClientStatusPending // Set these two fields to nil to cause alloc runner creation to fail alloc1.AllocatedResources = nil alloc1.TaskResources = nil state := s1.State() err := state.UpsertJob(100, job) require.Nil(err) err = state.UpsertJobSummary(101, mock.JobSummary(alloc1.JobID)) require.Nil(err) err = state.UpsertAllocs(102, []*structs.Allocation{alloc1}) require.Nil(err) // Push this alloc update to the client allocUpdates := &allocUpdates{ pulled: map[string]*structs.Allocation{ alloc1.ID: alloc1, }, } c1.runAllocs(allocUpdates) // Ensure the allocation has been marked as invalid and failed on the server testutil.WaitForResult(func() (bool, error) { c1.allocLock.RLock() ar := c1.allocs[alloc1.ID] _, isInvalid := c1.invalidAllocs[alloc1.ID] c1.allocLock.RUnlock() if ar != nil { return false, fmt.Errorf("expected nil alloc runner") } if !isInvalid { return false, fmt.Errorf("expected alloc to be marked as invalid") } alloc, err := s1.State().AllocByID(nil, alloc1.ID) require.Nil(err) failed := alloc.ClientStatus == structs.AllocClientStatusFailed if !failed { return false, fmt.Errorf("Expected failed client status, but got %v", alloc.ClientStatus) } return true, nil }, func(err error) { require.NoError(err) }) } func TestClient_Init(t *testing.T) { t.Parallel() dir, err := ioutil.TempDir("", "nomad") if err != nil { t.Fatalf("err: %s", err) } defer os.RemoveAll(dir) allocDir := filepath.Join(dir, "alloc") client := &Client{ config: &config.Config{ AllocDir: allocDir, StateDBFactory: cstate.GetStateDBFactory(true), }, logger: testlog.HCLogger(t), } if err := client.init(); err != nil { t.Fatalf("err: %s", err) } if _, err := os.Stat(allocDir); err != nil { t.Fatalf("err: %s", err) } } func TestClient_BlockedAllocations(t *testing.T) { t.Parallel() s1, _, cleanupS1 := testServer(t, nil) defer cleanupS1() testutil.WaitForLeader(t, s1.RPC) c1, cleanup := TestClient(t, func(c *config.Config) { c.RPCHandler = s1 }) defer cleanup() // Wait for the node to be ready state := s1.State() testutil.WaitForResult(func() (bool, error) { ws := memdb.NewWatchSet() out, err := state.NodeByID(ws, c1.Node().ID) if err != nil { return false, err } if out == nil || out.Status != structs.NodeStatusReady { return false, fmt.Errorf("bad node: %#v", out) } return true, nil }, func(err error) { t.Fatalf("err: %v", err) }) // Add an allocation alloc := mock.Alloc() alloc.NodeID = c1.Node().ID alloc.Job.TaskGroups[0].Tasks[0].Driver = "mock_driver" alloc.Job.TaskGroups[0].Tasks[0].Config = map[string]interface{}{ "kill_after": "1s", "run_for": "100s", "exit_code": 0, "exit_signal": 0, } state.UpsertJobSummary(99, mock.JobSummary(alloc.JobID)) state.UpsertAllocs(100, []*structs.Allocation{alloc}) // Wait until the client downloads and starts the allocation testutil.WaitForResult(func() (bool, error) { ws := memdb.NewWatchSet() out, err := state.AllocByID(ws, alloc.ID) if err != nil { return false, err } if out == nil || out.ClientStatus != structs.AllocClientStatusRunning { return false, fmt.Errorf("bad alloc: %#v", out) } return true, nil }, func(err error) { t.Fatalf("err: %v", err) }) // Add a new chained alloc alloc2 := alloc.Copy() alloc2.ID = uuid.Generate() alloc2.Job = alloc.Job alloc2.JobID = alloc.JobID alloc2.PreviousAllocation = alloc.ID if err := state.UpsertAllocs(200, []*structs.Allocation{alloc2}); err != nil { t.Fatalf("err: %v", err) } // Ensure that the chained allocation is being tracked as blocked testutil.WaitForResult(func() (bool, error) { ar := c1.getAllocRunners()[alloc2.ID] if ar == nil { return false, fmt.Errorf("alloc 2's alloc runner does not exist") } if !ar.IsWaiting() { return false, fmt.Errorf("alloc 2 is not blocked") } return true, nil }, func(err error) { t.Fatalf("err: %v", err) }) // Change the desired state of the parent alloc to stop alloc1 := alloc.Copy() alloc1.DesiredStatus = structs.AllocDesiredStatusStop if err := state.UpsertAllocs(300, []*structs.Allocation{alloc1}); err != nil { t.Fatalf("err: %v", err) } // Ensure that there are no blocked allocations testutil.WaitForResult(func() (bool, error) { for id, ar := range c1.getAllocRunners() { if ar.IsWaiting() { return false, fmt.Errorf("%q still blocked", id) } if ar.IsMigrating() { return false, fmt.Errorf("%q still migrating", id) } } return true, nil }, func(err error) { t.Fatalf("err: %v", err) }) // Destroy all the allocations for _, ar := range c1.getAllocRunners() { ar.Destroy() } for _, ar := range c1.getAllocRunners() { <-ar.DestroyCh() } } func TestClient_ValidateMigrateToken_ValidToken(t *testing.T) { t.Parallel() assert := assert.New(t) c, cleanup := TestClient(t, func(c *config.Config) { c.ACLEnabled = true }) defer cleanup() alloc := mock.Alloc() validToken, err := structs.GenerateMigrateToken(alloc.ID, c.secretNodeID()) assert.Nil(err) assert.Equal(c.ValidateMigrateToken(alloc.ID, validToken), true) } func TestClient_ValidateMigrateToken_InvalidToken(t *testing.T) { t.Parallel() assert := assert.New(t) c, cleanup := TestClient(t, func(c *config.Config) { c.ACLEnabled = true }) defer cleanup() assert.Equal(c.ValidateMigrateToken("", ""), false) alloc := mock.Alloc() assert.Equal(c.ValidateMigrateToken(alloc.ID, alloc.ID), false) assert.Equal(c.ValidateMigrateToken(alloc.ID, ""), false) } func TestClient_ValidateMigrateToken_ACLDisabled(t *testing.T) { t.Parallel() assert := assert.New(t) c, cleanup := TestClient(t, func(c *config.Config) {}) defer cleanup() assert.Equal(c.ValidateMigrateToken("", ""), true) } func TestClient_ReloadTLS_UpgradePlaintextToTLS(t *testing.T) { t.Parallel() assert := assert.New(t) s1, addr, cleanupS1 := testServer(t, func(c *nomad.Config) { c.Region = "global" }) defer cleanupS1() testutil.WaitForLeader(t, s1.RPC) const ( cafile = "../helper/tlsutil/testdata/ca.pem" foocert = "../helper/tlsutil/testdata/nomad-foo.pem" fookey = "../helper/tlsutil/testdata/nomad-foo-key.pem" ) c1, cleanup := TestClient(t, func(c *config.Config) { c.Servers = []string{addr} }) defer cleanup() // Registering a node over plaintext should succeed { req := structs.NodeSpecificRequest{ NodeID: c1.Node().ID, QueryOptions: structs.QueryOptions{Region: "global"}, } testutil.WaitForResult(func() (bool, error) { var out structs.SingleNodeResponse err := c1.RPC("Node.GetNode", &req, &out) if err != nil { return false, fmt.Errorf("client RPC failed when it should have succeeded:\n%+v", err) } return true, nil }, func(err error) { t.Fatalf(err.Error()) }, ) } newConfig := &nconfig.TLSConfig{ EnableHTTP: true, EnableRPC: true, VerifyServerHostname: true, CAFile: cafile, CertFile: foocert, KeyFile: fookey, } err := c1.reloadTLSConnections(newConfig) assert.Nil(err) // Registering a node over plaintext should fail after the node has upgraded // to TLS { req := structs.NodeSpecificRequest{ NodeID: c1.Node().ID, QueryOptions: structs.QueryOptions{Region: "global"}, } testutil.WaitForResult(func() (bool, error) { var out structs.SingleNodeResponse err := c1.RPC("Node.GetNode", &req, &out) if err == nil { return false, fmt.Errorf("client RPC succeeded when it should have failed:\n%+v", err) } return true, nil }, func(err error) { t.Fatalf(err.Error()) }, ) } } func TestClient_ReloadTLS_DowngradeTLSToPlaintext(t *testing.T) { t.Parallel() assert := assert.New(t) s1, addr, cleanupS1 := testServer(t, func(c *nomad.Config) { c.Region = "global" }) defer cleanupS1() testutil.WaitForLeader(t, s1.RPC) const ( cafile = "../helper/tlsutil/testdata/ca.pem" foocert = "../helper/tlsutil/testdata/nomad-foo.pem" fookey = "../helper/tlsutil/testdata/nomad-foo-key.pem" ) c1, cleanup := TestClient(t, func(c *config.Config) { c.Servers = []string{addr} c.TLSConfig = &nconfig.TLSConfig{ EnableHTTP: true, EnableRPC: true, VerifyServerHostname: true, CAFile: cafile, CertFile: foocert, KeyFile: fookey, } }) defer cleanup() // assert that when one node is running in encrypted mode, a RPC request to a // node running in plaintext mode should fail { req := structs.NodeSpecificRequest{ NodeID: c1.Node().ID, QueryOptions: structs.QueryOptions{Region: "global"}, } testutil.WaitForResult(func() (bool, error) { var out structs.SingleNodeResponse err := c1.RPC("Node.GetNode", &req, &out) if err == nil { return false, fmt.Errorf("client RPC succeeded when it should have failed :\n%+v", err) } return true, nil }, func(err error) { t.Fatalf(err.Error()) }, ) } newConfig := &nconfig.TLSConfig{} err := c1.reloadTLSConnections(newConfig) assert.Nil(err) // assert that when both nodes are in plaintext mode, a RPC request should // succeed { req := structs.NodeSpecificRequest{ NodeID: c1.Node().ID, QueryOptions: structs.QueryOptions{Region: "global"}, } testutil.WaitForResult(func() (bool, error) { var out structs.SingleNodeResponse err := c1.RPC("Node.GetNode", &req, &out) if err != nil { return false, fmt.Errorf("client RPC failed when it should have succeeded:\n%+v", err) } return true, nil }, func(err error) { t.Fatalf(err.Error()) }, ) } } // TestClient_ServerList tests client methods that interact with the internal // nomad server list. func TestClient_ServerList(t *testing.T) { t.Parallel() client, cleanup := TestClient(t, func(c *config.Config) {}) defer cleanup() if s := client.GetServers(); len(s) != 0 { t.Fatalf("expected server lit to be empty but found: %+q", s) } if _, err := client.SetServers(nil); err != noServersErr { t.Fatalf("expected setting an empty list to return a 'no servers' error but received %v", err) } if _, err := client.SetServers([]string{"123.456.13123.123.13:80"}); err == nil { t.Fatalf("expected setting a bad server to return an error") } if _, err := client.SetServers([]string{"123.456.13123.123.13:80", "127.0.0.1:1234", "127.0.0.1"}); err == nil { t.Fatalf("expected setting at least one good server to succeed but received: %v", err) } s := client.GetServers() if len(s) != 0 { t.Fatalf("expected 2 servers but received: %+q", s) } } func TestClient_UpdateNodeFromDevicesAccumulates(t *testing.T) { t.Parallel() client, cleanup := TestClient(t, func(c *config.Config) {}) defer cleanup() client.updateNodeFromFingerprint(&fingerprint.FingerprintResponse{ NodeResources: &structs.NodeResources{ Cpu: structs.NodeCpuResources{CpuShares: 123}, }, }) client.updateNodeFromFingerprint(&fingerprint.FingerprintResponse{ NodeResources: &structs.NodeResources{ Memory: structs.NodeMemoryResources{MemoryMB: 1024}, }, }) client.updateNodeFromDevices([]*structs.NodeDeviceResource{ { Vendor: "vendor", Type: "type", }, }) // initial check expectedResources := &structs.NodeResources{ // computed through test client initialization Networks: client.configCopy.Node.NodeResources.Networks, NodeNetworks: client.configCopy.Node.NodeResources.NodeNetworks, Disk: client.configCopy.Node.NodeResources.Disk, // injected Cpu: structs.NodeCpuResources{CpuShares: 123}, Memory: structs.NodeMemoryResources{MemoryMB: 1024}, Devices: []*structs.NodeDeviceResource{ { Vendor: "vendor", Type: "type", }, }, } assert.EqualValues(t, expectedResources, client.configCopy.Node.NodeResources) // overrides of values client.updateNodeFromFingerprint(&fingerprint.FingerprintResponse{ NodeResources: &structs.NodeResources{ Memory: structs.NodeMemoryResources{MemoryMB: 2048}, }, }) client.updateNodeFromDevices([]*structs.NodeDeviceResource{ { Vendor: "vendor", Type: "type", }, { Vendor: "vendor2", Type: "type2", }, }) expectedResources2 := &structs.NodeResources{ // computed through test client initialization Networks: client.configCopy.Node.NodeResources.Networks, NodeNetworks: client.configCopy.Node.NodeResources.NodeNetworks, Disk: client.configCopy.Node.NodeResources.Disk, // injected Cpu: structs.NodeCpuResources{CpuShares: 123}, Memory: structs.NodeMemoryResources{MemoryMB: 2048}, Devices: []*structs.NodeDeviceResource{ { Vendor: "vendor", Type: "type", }, { Vendor: "vendor2", Type: "type2", }, }, } assert.EqualValues(t, expectedResources2, client.configCopy.Node.NodeResources) } // TestClient_UpdateNodeFromFingerprintKeepsConfig asserts manually configured // network interfaces take precedence over fingerprinted ones. func TestClient_UpdateNodeFromFingerprintKeepsConfig(t *testing.T) { t.Parallel() // Client without network configured updates to match fingerprint client, cleanup := TestClient(t, nil) defer cleanup() client.updateNodeFromFingerprint(&fingerprint.FingerprintResponse{ NodeResources: &structs.NodeResources{ Cpu: structs.NodeCpuResources{CpuShares: 123}, Networks: []*structs.NetworkResource{{Mode: "host", Device: "any-interface"}}, }, Resources: &structs.Resources{ CPU: 80, }, }) idx := len(client.config.Node.NodeResources.Networks) - 1 require.Equal(t, int64(123), client.config.Node.NodeResources.Cpu.CpuShares) require.Equal(t, "any-interface", client.config.Node.NodeResources.Networks[idx].Device) require.Equal(t, 80, client.config.Node.Resources.CPU) // lookup an interface. client.Node starts with a hardcoded value, eth0, // and is only updated async through fingerprinter. // Let's just lookup network device; anyone will do for this test interfaces, err := net.Interfaces() require.NoError(t, err) require.NotEmpty(t, interfaces) dev := interfaces[0].Name // Client with network interface configured keeps the config // setting on update name := "TestClient_UpdateNodeFromFingerprintKeepsConfig2" client, cleanup = TestClient(t, func(c *config.Config) { c.NetworkInterface = dev c.Node.Name = name c.Options["fingerprint.blacklist"] = "network" // Node is already a mock.Node, with a device c.Node.NodeResources.Networks[0].Device = dev }) defer cleanup() client.updateNodeFromFingerprint(&fingerprint.FingerprintResponse{ NodeResources: &structs.NodeResources{ Cpu: structs.NodeCpuResources{CpuShares: 123}, Networks: []*structs.NetworkResource{ {Mode: "host", Device: "any-interface", MBits: 20}, }, }, }) require.Equal(t, int64(123), client.config.Node.NodeResources.Cpu.CpuShares) // only the configured device is kept require.Equal(t, 2, len(client.config.Node.NodeResources.Networks)) require.Equal(t, dev, client.config.Node.NodeResources.Networks[0].Device) require.Equal(t, "bridge", client.config.Node.NodeResources.Networks[1].Mode) // Network speed is applied to all NetworkResources client.config.NetworkInterface = "" client.config.NetworkSpeed = 100 client.updateNodeFromFingerprint(&fingerprint.FingerprintResponse{ NodeResources: &structs.NodeResources{ Cpu: structs.NodeCpuResources{CpuShares: 123}, Networks: []*structs.NetworkResource{ {Mode: "host", Device: "any-interface", MBits: 20}, }, }, Resources: &structs.Resources{ CPU: 80, }, }) assert.Equal(t, 3, len(client.config.Node.NodeResources.Networks)) assert.Equal(t, "any-interface", client.config.Node.NodeResources.Networks[2].Device) assert.Equal(t, 100, client.config.Node.NodeResources.Networks[2].MBits) assert.Equal(t, 0, client.config.Node.NodeResources.Networks[1].MBits) } // Support multiple IP addresses (ipv4 vs. 6, e.g.) on the configured network interface func Test_UpdateNodeFromFingerprintMultiIP(t *testing.T) { t.Parallel() var dev string switch runtime.GOOS { case "linux": dev = "lo" case "darwin": dev = "lo0" } // Client without network configured updates to match fingerprint client, cleanup := TestClient(t, func(c *config.Config) { c.NetworkInterface = dev c.Options["fingerprint.blacklist"] = "network,cni,bridge" c.Node.Resources.Networks = c.Node.NodeResources.Networks }) defer cleanup() client.updateNodeFromFingerprint(&fingerprint.FingerprintResponse{ NodeResources: &structs.NodeResources{ Cpu: structs.NodeCpuResources{CpuShares: 123}, Networks: []*structs.NetworkResource{ {Device: dev, IP: "127.0.0.1"}, {Device: dev, IP: "::1"}, }, }, }) nets := structs.Networks{ mock.Node().NodeResources.Networks[0], {Device: dev, IP: "127.0.0.1"}, {Device: dev, IP: "::1"}, } require.Equal(t, nets, client.config.Node.NodeResources.Networks) } func TestClient_computeAllocatedDeviceStats(t *testing.T) { logger := testlog.HCLogger(t) c := &Client{logger: logger} newDeviceStats := func(strValue string) *device.DeviceStats { return &device.DeviceStats{ Summary: &psstructs.StatValue{ StringVal: &strValue, }, } } allocatedDevices := []*structs.AllocatedDeviceResource{ { Vendor: "vendor", Type: "type", Name: "name", DeviceIDs: []string{"d2", "d3", "notfoundid"}, }, { Vendor: "vendor2", Type: "type2", Name: "name2", DeviceIDs: []string{"a2"}, }, { Vendor: "vendor_notfound", Type: "type_notfound", Name: "name_notfound", DeviceIDs: []string{"d3"}, }, } hostDeviceGroupStats := []*device.DeviceGroupStats{ { Vendor: "vendor", Type: "type", Name: "name", InstanceStats: map[string]*device.DeviceStats{ "unallocated": newDeviceStats("unallocated"), "d2": newDeviceStats("d2"), "d3": newDeviceStats("d3"), }, }, { Vendor: "vendor2", Type: "type2", Name: "name2", InstanceStats: map[string]*device.DeviceStats{ "a2": newDeviceStats("a2"), }, }, { Vendor: "vendor_unused", Type: "type_unused", Name: "name_unused", InstanceStats: map[string]*device.DeviceStats{ "unallocated_unused": newDeviceStats("unallocated_unused"), }, }, } // test some edge conditions assert.Empty(t, c.computeAllocatedDeviceGroupStats(nil, nil)) assert.Empty(t, c.computeAllocatedDeviceGroupStats(nil, hostDeviceGroupStats)) assert.Empty(t, c.computeAllocatedDeviceGroupStats(allocatedDevices, nil)) // actual test result := c.computeAllocatedDeviceGroupStats(allocatedDevices, hostDeviceGroupStats) sort.Slice(result, func(i, j int) bool { return result[i].Vendor < result[j].Vendor }) expected := []*device.DeviceGroupStats{ { Vendor: "vendor", Type: "type", Name: "name", InstanceStats: map[string]*device.DeviceStats{ "d2": newDeviceStats("d2"), "d3": newDeviceStats("d3"), }, }, { Vendor: "vendor2", Type: "type2", Name: "name2", InstanceStats: map[string]*device.DeviceStats{ "a2": newDeviceStats("a2"), }, }, } assert.EqualValues(t, expected, result) } func TestClient_getAllocatedResources(t *testing.T) { t.Parallel() require := require.New(t) client, cleanup := TestClient(t, nil) defer cleanup() allocStops := mock.BatchAlloc() allocStops.Job.TaskGroups[0].Count = 1 allocStops.Job.TaskGroups[0].Tasks[0].Driver = "mock_driver" allocStops.Job.TaskGroups[0].Tasks[0].Config = map[string]interface{}{ "run_for": "1ms", "exit_code": "0", } allocStops.Job.TaskGroups[0].RestartPolicy.Attempts = 0 allocStops.AllocatedResources.Shared.DiskMB = 64 allocStops.AllocatedResources.Tasks["web"].Cpu = structs.AllocatedCpuResources{CpuShares: 64} allocStops.AllocatedResources.Tasks["web"].Memory = structs.AllocatedMemoryResources{MemoryMB: 64} require.Nil(client.addAlloc(allocStops, "")) allocFails := mock.BatchAlloc() allocFails.Job.TaskGroups[0].Count = 1 allocFails.Job.TaskGroups[0].Tasks[0].Driver = "mock_driver" allocFails.Job.TaskGroups[0].Tasks[0].Config = map[string]interface{}{ "run_for": "1ms", "exit_code": "1", } allocFails.Job.TaskGroups[0].RestartPolicy.Attempts = 0 allocFails.AllocatedResources.Shared.DiskMB = 128 allocFails.AllocatedResources.Tasks["web"].Cpu = structs.AllocatedCpuResources{CpuShares: 128} allocFails.AllocatedResources.Tasks["web"].Memory = structs.AllocatedMemoryResources{MemoryMB: 128} require.Nil(client.addAlloc(allocFails, "")) allocRuns := mock.Alloc() allocRuns.Job.TaskGroups[0].Count = 1 allocRuns.Job.TaskGroups[0].Tasks[0].Driver = "mock_driver" allocRuns.Job.TaskGroups[0].Tasks[0].Config = map[string]interface{}{ "run_for": "3s", } allocRuns.AllocatedResources.Shared.DiskMB = 256 allocRuns.AllocatedResources.Tasks["web"].Cpu = structs.AllocatedCpuResources{CpuShares: 256} allocRuns.AllocatedResources.Tasks["web"].Memory = structs.AllocatedMemoryResources{MemoryMB: 256} require.Nil(client.addAlloc(allocRuns, "")) allocPends := mock.Alloc() allocPends.Job.TaskGroups[0].Count = 1 allocPends.Job.TaskGroups[0].Tasks[0].Driver = "mock_driver" allocPends.Job.TaskGroups[0].Tasks[0].Config = map[string]interface{}{ "run_for": "5s", "start_block_for": "10s", } allocPends.AllocatedResources.Shared.DiskMB = 512 allocPends.AllocatedResources.Tasks["web"].Cpu = structs.AllocatedCpuResources{CpuShares: 512} allocPends.AllocatedResources.Tasks["web"].Memory = structs.AllocatedMemoryResources{MemoryMB: 512} require.Nil(client.addAlloc(allocPends, "")) // wait for allocStops to stop running and for allocRuns to be pending/running testutil.WaitForResult(func() (bool, error) { as, err := client.GetAllocState(allocPends.ID) if err != nil { return false, err } else if as.ClientStatus != structs.AllocClientStatusPending { return false, fmt.Errorf("allocPends not yet pending: %#v", as) } as, err = client.GetAllocState(allocRuns.ID) if as.ClientStatus != structs.AllocClientStatusRunning { return false, fmt.Errorf("allocRuns not yet running: %#v", as) } else if err != nil { return false, err } as, err = client.GetAllocState(allocStops.ID) if err != nil { return false, err } else if as.ClientStatus != structs.AllocClientStatusComplete { return false, fmt.Errorf("allocStops not yet complete: %#v", as) } as, err = client.GetAllocState(allocFails.ID) if err != nil { return false, err } else if as.ClientStatus != structs.AllocClientStatusFailed { return false, fmt.Errorf("allocFails not yet failed: %#v", as) } return true, nil }, func(err error) { require.NoError(err) }) result := client.getAllocatedResources(client.config.Node) // Ignore comparing networks for now result.Flattened.Networks = nil expected := structs.ComparableResources{ Flattened: structs.AllocatedTaskResources{ Cpu: structs.AllocatedCpuResources{ CpuShares: 768, }, Memory: structs.AllocatedMemoryResources{ MemoryMB: 768, }, Networks: nil, }, Shared: structs.AllocatedSharedResources{ DiskMB: 768, }, } assert.EqualValues(t, expected, *result) } func TestClient_updateNodeFromDriverUpdatesAll(t *testing.T) { t.Parallel() client, cleanup := TestClient(t, nil) defer cleanup() // initial update { info := &structs.DriverInfo{ Detected: true, Healthy: false, HealthDescription: "not healthy at start", Attributes: map[string]string{ "node.mock.testattr1": "val1", }, } client.updateNodeFromDriver("mock", info) n := client.config.Node updatedInfo := *n.Drivers["mock"] // compare without update time updatedInfo.UpdateTime = info.UpdateTime assert.EqualValues(t, updatedInfo, *info) // check node attributes assert.Equal(t, "val1", n.Attributes["node.mock.testattr1"]) } // initial update { info := &structs.DriverInfo{ Detected: true, Healthy: true, HealthDescription: "healthy", Attributes: map[string]string{ "node.mock.testattr1": "val2", }, } client.updateNodeFromDriver("mock", info) n := client.Node() updatedInfo := *n.Drivers["mock"] // compare without update time updatedInfo.UpdateTime = info.UpdateTime assert.EqualValues(t, updatedInfo, *info) // check node attributes are updated assert.Equal(t, "val2", n.Attributes["node.mock.testattr1"]) // update once more with the same info, updateTime shouldn't change client.updateNodeFromDriver("mock", info) un := client.Node() assert.EqualValues(t, n, un) } // update once more to unhealthy because why not { info := &structs.DriverInfo{ Detected: true, Healthy: false, HealthDescription: "lost track", Attributes: map[string]string{ "node.mock.testattr1": "", }, } client.updateNodeFromDriver("mock", info) n := client.Node() updatedInfo := *n.Drivers["mock"] // compare without update time updatedInfo.UpdateTime = info.UpdateTime assert.EqualValues(t, updatedInfo, *info) // check node attributes are updated assert.Equal(t, "", n.Attributes["node.mock.testattr1"]) // update once more with the same info, updateTime shouldn't change client.updateNodeFromDriver("mock", info) un := client.Node() assert.EqualValues(t, n, un) } } // COMPAT(0.12): remove once upgrading from 0.9.5 is no longer supported func TestClient_hasLocalState(t *testing.T) { t.Parallel() c, cleanup := TestClient(t, nil) defer cleanup() c.stateDB = state.NewMemDB(c.logger) t.Run("plain alloc", func(t *testing.T) { alloc := mock.BatchAlloc() c.stateDB.PutAllocation(alloc) require.False(t, c.hasLocalState(alloc)) }) t.Run("alloc with a task with local state", func(t *testing.T) { alloc := mock.BatchAlloc() taskName := alloc.Job.LookupTaskGroup(alloc.TaskGroup).Tasks[0].Name ls := &trstate.LocalState{} c.stateDB.PutAllocation(alloc) c.stateDB.PutTaskRunnerLocalState(alloc.ID, taskName, ls) require.True(t, c.hasLocalState(alloc)) }) t.Run("alloc with a task with task state", func(t *testing.T) { alloc := mock.BatchAlloc() taskName := alloc.Job.LookupTaskGroup(alloc.TaskGroup).Tasks[0].Name ts := &structs.TaskState{ State: structs.TaskStateRunning, } c.stateDB.PutAllocation(alloc) c.stateDB.PutTaskState(alloc.ID, taskName, ts) require.True(t, c.hasLocalState(alloc)) }) } func Test_verifiedTasks(t *testing.T) { t.Parallel() logger := testlog.HCLogger(t) // produce a result and check against expected tasks and/or error output try := func(t *testing.T, a *structs.Allocation, tasks, expTasks []string, expErr string) { result, err := verifiedTasks(logger, a, tasks) if expErr != "" { require.EqualError(t, err, expErr) } else { require.NoError(t, err) require.Equal(t, expTasks, result) } } // create an alloc with TaskGroup=g1, tasks configured given g1Tasks alloc := func(g1Tasks []string) *structs.Allocation { var tasks []*structs.Task for _, taskName := range g1Tasks { tasks = append(tasks, &structs.Task{Name: taskName}) } return &structs.Allocation{ Job: &structs.Job{ TaskGroups: []*structs.TaskGroup{ {Name: "g0", Tasks: []*structs.Task{{Name: "g0t1"}}}, {Name: "g1", Tasks: tasks}, }, }, TaskGroup: "g1", } } t.Run("nil alloc", func(t *testing.T) { tasks := []string{"g1t1"} try(t, nil, tasks, nil, "nil allocation") }) t.Run("missing task names", func(t *testing.T) { var tasks []string tgTasks := []string{"g1t1"} try(t, alloc(tgTasks), tasks, nil, "missing task names") }) t.Run("missing group", func(t *testing.T) { tasks := []string{"g1t1"} a := alloc(tasks) a.TaskGroup = "other" try(t, a, tasks, nil, "group name in allocation is not present in job") }) t.Run("nonexistent task", func(t *testing.T) { tasks := []string{"missing"} try(t, alloc([]string{"task1"}), tasks, nil, `task "missing" not found in allocation`) }) t.Run("matching task", func(t *testing.T) { tasks := []string{"g1t1"} try(t, alloc(tasks), tasks, tasks, "") }) t.Run("matching task subset", func(t *testing.T) { tasks := []string{"g1t1", "g1t3"} tgTasks := []string{"g1t1", "g1t2", "g1t3"} try(t, alloc(tgTasks), tasks, tasks, "") }) }