package catalogtest import ( "testing" "github.com/hashicorp/consul/internal/catalog" rtest "github.com/hashicorp/consul/internal/resource/resourcetest" pbcatalog "github.com/hashicorp/consul/proto-public/pbcatalog/v1alpha1" "github.com/hashicorp/consul/proto-public/pbresource" "github.com/hashicorp/consul/sdk/testutil" ) // RunCatalogV1Alpha1LifecycleIntegrationTest intends to excercise functionality of // managing catalog resources over their normal lifecycle where they will be modified // several times, change state etc. func RunCatalogV1Alpha1LifecycleIntegrationTest(t *testing.T, client pbresource.ResourceServiceClient) { t.Helper() testutil.RunStep(t, "node-lifecycle", func(t *testing.T) { RunCatalogV1Alpha1NodeLifecycleIntegrationTest(t, client) }) testutil.RunStep(t, "workload-lifecycle", func(t *testing.T) { RunCatalogV1Alpha1WorkloadLifecycleIntegrationTest(t, client) }) testutil.RunStep(t, "endpoints-lifecycle", func(t *testing.T) { RunCatalogV1Alpha1EndpointsLifecycleIntegrationTest(t, client) }) } // RunCatalogV1Alpha1NodeLifecycleIntegrationTest verifies correct functionality of // the node-health controller. This test will exercise the following behaviors: // // * Creating a Node without associated HealthStatuses will mark the node as passing // * Associating a HealthStatus with a Node will cause recomputation of the Health // * Changing HealthStatus to a worse health will cause recomputation of the Health // * Changing HealthStatus to a better health will cause recomputation of the Health // * Deletion of associated HealthStatuses will recompute the Health (back to passing) // * Deletion of the node will cause deletion of associated health statuses func RunCatalogV1Alpha1NodeLifecycleIntegrationTest(t *testing.T, client pbresource.ResourceServiceClient) { c := rtest.NewClient(client) nodeName := "test-lifecycle" nodeHealthName := "test-lifecycle-node-status" // initial node creation node := rtest.Resource(catalog.NodeV1Alpha1Type, nodeName). WithData(t, &pbcatalog.Node{ Addresses: []*pbcatalog.NodeAddress{ {Host: "172.16.2.3"}, {Host: "198.18.2.3", External: true}, }, }). Write(t, c) // wait for the node health controller to mark the node as healthy c.WaitForStatusCondition(t, node.Id, catalog.NodeHealthStatusKey, catalog.NodeHealthConditions[pbcatalog.Health_HEALTH_PASSING]) // Its easy enough to simply repeatedly set the health status and it proves // that going both from better to worse health and worse to better all // happen as expected. We leave the health in a warning state to allow for // the subsequent health status deletion to cause the health to go back // to passing. healthChanges := []pbcatalog.Health{ pbcatalog.Health_HEALTH_PASSING, pbcatalog.Health_HEALTH_WARNING, pbcatalog.Health_HEALTH_CRITICAL, pbcatalog.Health_HEALTH_MAINTENANCE, pbcatalog.Health_HEALTH_CRITICAL, pbcatalog.Health_HEALTH_WARNING, pbcatalog.Health_HEALTH_PASSING, pbcatalog.Health_HEALTH_WARNING, } // This will be set within the loop and used afterwards to delete the health status var nodeHealth *pbresource.Resource // Iterate through the various desired health statuses, updating // a HealthStatus resource owned by the node and waiting for // reconciliation at each point for _, health := range healthChanges { // update the health check nodeHealth = setHealthStatus(t, c, node.Id, nodeHealthName, health) // wait for reconciliation to kick in and put the node into the right // health status. c.WaitForStatusCondition(t, node.Id, catalog.NodeHealthStatusKey, catalog.NodeHealthConditions[health]) } // now delete the health status and ensure things go back to passing c.MustDelete(t, nodeHealth.Id) // wait for the node health controller to mark the node as healthy c.WaitForStatusCondition(t, node.Id, catalog.NodeHealthStatusKey, catalog.NodeHealthConditions[pbcatalog.Health_HEALTH_PASSING]) // Add the health status back once more, the actual status doesn't matter. // It just must be owned by the node so that we can show cascading // deletions of owned health statuses working. healthStatus := setHealthStatus(t, c, node.Id, nodeHealthName, pbcatalog.Health_HEALTH_CRITICAL) // Delete the node and wait for the health status to be deleted. c.MustDelete(t, node.Id) c.WaitForDeletion(t, healthStatus.Id) } // RunCatalogV1Alpha1WorkloadLifecycleIntegrationTest verifies correct functionality of // the workload-health controller. This test will exercise the following behaviors: // // - Associating a workload with a node causes recomputation of the health and takes // into account the nodes health // - Modifying the workloads associated node causes health recomputation and takes into // account the new nodes health // - Removal of the node association causes recomputation of health and for no node health // to be taken into account. // - Creating a workload without associated health statuses or node association will // be marked passing // - Creating a workload without associated health statuses but with a node will // inherit its health from the node. // - Changing HealthStatus to a worse health will cause recompuation of the Health // - Changing HealthStatus to a better health will cause recompuation of the Health // - Overall health is computed as the worst health amongst the nodes health and all // of the workloads associated HealthStatuses // - Deletion of the workload will cause deletion of all associated health statuses. func RunCatalogV1Alpha1WorkloadLifecycleIntegrationTest(t *testing.T, client pbresource.ResourceServiceClient) { c := rtest.NewClient(client) testutil.RunStep(t, "nodeless-workload", func(t *testing.T) { runV1Alpha1NodelessWorkloadLifecycleIntegrationTest(t, c) }) testutil.RunStep(t, "node-associated-workload", func(t *testing.T) { runV1Alpha1NodeAssociatedWorkloadLifecycleIntegrationTest(t, c) }) } // runV1Alpha1NodelessWorkloadLifecycleIntegrationTest verifies correct functionality of // the workload-health controller for workloads without node associations. In particular // the following behaviors are being tested // // - Creating a workload without associated health statuses or node association will // be marked passing // - Changing HealthStatus to a worse health will cause recompuation of the Health // - Changing HealthStatus to a better health will cause recompuation of the Health // - Deletion of associated HealthStatus for a nodeless workload will be set back to passing // - Deletion of the workload will cause deletion of all associated health statuses. func runV1Alpha1NodelessWorkloadLifecycleIntegrationTest(t *testing.T, c *rtest.Client) { workloadName := "test-lifecycle-workload" workloadHealthName := "test-lifecycle-workload-status" // create a workload without a node association or health statuses yet workload := rtest.Resource(catalog.WorkloadV1Alpha1Type, workloadName). WithData(t, &pbcatalog.Workload{ Addresses: []*pbcatalog.WorkloadAddress{ {Host: "198.18.9.8"}, }, Ports: map[string]*pbcatalog.WorkloadPort{ "http": {Port: 8080, Protocol: pbcatalog.Protocol_PROTOCOL_HTTP}, }, Identity: "test-lifecycle", }). Write(t, c) // wait for the workload health controller to mark the workload as healthy c.WaitForStatusCondition(t, workload.Id, catalog.WorkloadHealthStatusKey, catalog.WorkloadHealthConditions[pbcatalog.Health_HEALTH_PASSING]) // We may not need to iterate through all of these states but its easy // enough and quick enough to do so. The general rationale is that we // should move through changing the workloads associated health status // in this progression. We can prove that moving from better to worse // health or worse to better both function correctly. healthChanges := []pbcatalog.Health{ pbcatalog.Health_HEALTH_PASSING, pbcatalog.Health_HEALTH_WARNING, pbcatalog.Health_HEALTH_CRITICAL, pbcatalog.Health_HEALTH_MAINTENANCE, pbcatalog.Health_HEALTH_CRITICAL, pbcatalog.Health_HEALTH_WARNING, pbcatalog.Health_HEALTH_PASSING, pbcatalog.Health_HEALTH_WARNING, } var workloadHealth *pbresource.Resource // Iterate through the various desired health statuses, updating // a HealthStatus resource owned by the workload and waiting for // reconciliation at each point for _, health := range healthChanges { // update the health status workloadHealth = setHealthStatus(t, c, workload.Id, workloadHealthName, health) // wait for reconciliation to kick in and put the workload into // the right health status. c.WaitForStatusCondition(t, workload.Id, catalog.WorkloadHealthStatusKey, catalog.WorkloadHealthConditions[health]) } // Now delete the health status, things should go back to passing status c.MustDelete(t, workloadHealth.Id) // ensure the workloads health went back to passing c.WaitForStatusCondition(t, workload.Id, catalog.WorkloadHealthStatusKey, catalog.WorkloadHealthConditions[pbcatalog.Health_HEALTH_PASSING]) // Reset the workload health. The actual health is irrelevant, we just want it // to exist to provde that Health Statuses get deleted along with the workload // when its deleted. workloadHealth = setHealthStatus(t, c, workload.Id, workloadHealthName, pbcatalog.Health_HEALTH_WARNING) // Delete the workload and wait for the HealthStatus to also be deleted c.MustDelete(t, workload.Id) c.WaitForDeletion(t, workloadHealth.Id) } // runV1Alpha1NodeAssociatedWorkloadLifecycleIntegrationTest verifies correct functionality of // the workload-health controller. This test will exercise the following behaviors: // // - Associating a workload with a node causes recomputation of the health and takes // into account the nodes health // - Modifying the workloads associated node causes health recomputation and takes into // account the new nodes health // - Removal of the node association causes recomputation of health and for no node health // to be taken into account. // - Creating a workload without associated health statuses but with a node will // inherit its health from the node. // - Overall health is computed as the worst health amongst the nodes health and all // of the workloads associated HealthStatuses func runV1Alpha1NodeAssociatedWorkloadLifecycleIntegrationTest(t *testing.T, c *rtest.Client) { workloadName := "test-lifecycle" workloadHealthName := "test-lifecycle" nodeName1 := "test-lifecycle-1" nodeName2 := "test-lifecycle-2" nodeHealthName1 := "test-lifecycle-node-1" nodeHealthName2 := "test-lifecycle-node-2" // Insert a some nodes to link the workloads to at various points throughout the test node1 := rtest.Resource(catalog.NodeV1Alpha1Type, nodeName1). WithData(t, &pbcatalog.Node{ Addresses: []*pbcatalog.NodeAddress{{Host: "172.17.9.10"}}, }). Write(t, c) node2 := rtest.Resource(catalog.NodeV1Alpha1Type, nodeName2). WithData(t, &pbcatalog.Node{ Addresses: []*pbcatalog.NodeAddress{{Host: "172.17.9.11"}}, }). Write(t, c) // Set some non-passing health statuses for those nodes. Using non-passing will make // it easy to see that changing a passing workloads node association appropriately // impacts the overall workload health. setHealthStatus(t, c, node1.Id, nodeHealthName1, pbcatalog.Health_HEALTH_CRITICAL) setHealthStatus(t, c, node2.Id, nodeHealthName2, pbcatalog.Health_HEALTH_WARNING) // Add the workload but don't immediately associate with any node. workload := rtest.Resource(catalog.WorkloadV1Alpha1Type, workloadName). WithData(t, &pbcatalog.Workload{ Addresses: []*pbcatalog.WorkloadAddress{ {Host: "198.18.9.8"}, }, Ports: map[string]*pbcatalog.WorkloadPort{ "http": {Port: 8080, Protocol: pbcatalog.Protocol_PROTOCOL_HTTP}, }, Identity: "test-lifecycle", }). Write(t, c) // wait for the workload health controller to mark the workload as healthy c.WaitForStatusCondition(t, workload.Id, catalog.WorkloadHealthStatusKey, catalog.WorkloadHealthConditions[pbcatalog.Health_HEALTH_PASSING]) // now modify the workload to associate it with node 1 (currently with CRITICAL health) workload = rtest.ResourceID(workload.Id). WithData(t, &pbcatalog.Workload{ Addresses: []*pbcatalog.WorkloadAddress{{Host: "198.18.9.8"}}, Ports: map[string]*pbcatalog.WorkloadPort{"http": {Port: 8080, Protocol: pbcatalog.Protocol_PROTOCOL_HTTP}}, Identity: "test-lifecycle", // this is the only difference from the previous write NodeName: node1.Id.Name, }). Write(t, c) // wait for the workload health controller to mark the workload as critical (due to node 1 having critical health) c.WaitForStatusCondition(t, workload.Id, catalog.WorkloadHealthStatusKey, catalog.WorkloadAndNodeHealthConditions[pbcatalog.Health_HEALTH_PASSING][pbcatalog.Health_HEALTH_CRITICAL]) // Now reassociate the workload with node 2. This should cause recalculation of its health into the warning state workload = rtest.ResourceID(workload.Id). WithData(t, &pbcatalog.Workload{ Addresses: []*pbcatalog.WorkloadAddress{{Host: "198.18.9.8"}}, Ports: map[string]*pbcatalog.WorkloadPort{"http": {Port: 8080, Protocol: pbcatalog.Protocol_PROTOCOL_HTTP}}, Identity: "test-lifecycle", // this is the only difference from the previous write NodeName: node2.Id.Name, }). Write(t, c) // Wait for the workload health controller to mark the workload as warning (due to node 2 having warning health) c.WaitForStatusCondition(t, workload.Id, catalog.WorkloadHealthStatusKey, catalog.WorkloadAndNodeHealthConditions[pbcatalog.Health_HEALTH_PASSING][pbcatalog.Health_HEALTH_WARNING]) // Delete the node, this should cause the health to be recalculated as critical because the node association // is broken. c.MustDelete(t, node2.Id) // Wait for the workload health controller to mark the workload as critical due to the missing node c.WaitForStatusCondition(t, workload.Id, catalog.WorkloadHealthStatusKey, catalog.WorkloadAndNodeHealthConditions[pbcatalog.Health_HEALTH_PASSING][pbcatalog.Health_HEALTH_CRITICAL]) // Now fixup the node association to point at node 1 workload = rtest.ResourceID(workload.Id). WithData(t, &pbcatalog.Workload{ Addresses: []*pbcatalog.WorkloadAddress{{Host: "198.18.9.8"}}, Ports: map[string]*pbcatalog.WorkloadPort{"http": {Port: 8080, Protocol: pbcatalog.Protocol_PROTOCOL_HTTP}}, Identity: "test-lifecycle", // this is the only difference from the previous write NodeName: node1.Id.Name, }). Write(t, c) // Also set node 1 health down to WARNING setHealthStatus(t, c, node1.Id, nodeHealthName1, pbcatalog.Health_HEALTH_WARNING) // Wait for the workload health controller to mark the workload as warning (due to node 1 having warning health now) c.WaitForStatusCondition(t, workload.Id, catalog.WorkloadHealthStatusKey, catalog.WorkloadAndNodeHealthConditions[pbcatalog.Health_HEALTH_PASSING][pbcatalog.Health_HEALTH_WARNING]) // Now add a critical workload health check to ensure that both node and workload health are accounted for. setHealthStatus(t, c, workload.Id, workloadHealthName, pbcatalog.Health_HEALTH_CRITICAL) // Wait for the workload health to be recomputed and put into the critical status. c.WaitForStatusCondition(t, workload.Id, catalog.WorkloadHealthStatusKey, catalog.WorkloadAndNodeHealthConditions[pbcatalog.Health_HEALTH_CRITICAL][pbcatalog.Health_HEALTH_WARNING]) // Reset the workloads health to passing. We expect the overall health to go back to warning setHealthStatus(t, c, workload.Id, workloadHealthName, pbcatalog.Health_HEALTH_PASSING) c.WaitForStatusCondition(t, workload.Id, catalog.WorkloadHealthStatusKey, catalog.WorkloadAndNodeHealthConditions[pbcatalog.Health_HEALTH_PASSING][pbcatalog.Health_HEALTH_WARNING]) // Remove the node association and wait for the health to go back to passing workload = rtest.ResourceID(workload.Id). WithData(t, &pbcatalog.Workload{ Addresses: []*pbcatalog.WorkloadAddress{{Host: "198.18.9.8"}}, Ports: map[string]*pbcatalog.WorkloadPort{"http": {Port: 8080, Protocol: pbcatalog.Protocol_PROTOCOL_HTTP}}, Identity: "test-lifecycle", }). Write(t, c) c.WaitForStatusCondition(t, workload.Id, catalog.WorkloadHealthStatusKey, catalog.WorkloadHealthConditions[pbcatalog.Health_HEALTH_PASSING]) } // RunCatalogV1Alpha1EndpointsLifecycleIntegrationTest verifies the correct functionality of // the endpoints controller. This test will exercise the following behaviors: // // * Services without a selector get marked with status indicating their endpoints are unmanaged // * Services with a selector get marked with status indicating their endpoints are managed // * Deleting a service will delete the associated endpoints (regardless of them being managed or not) // * Moving from managed to unmanaged endpoints will delete the managed endpoints // * Moving from unmanaged to managed endpoints will overwrite any previous endpoints. // * A service with a selector that matches no workloads will still have the endpoints object written. // * Adding ports to a service will recalculate the endpoints // * Removing ports from a service will recalculate the endpoints // * Changing the workload will recalculate the endpoints (ports, addresses, or health) func RunCatalogV1Alpha1EndpointsLifecycleIntegrationTest(t *testing.T, client pbresource.ResourceServiceClient) { c := rtest.NewClient(client) serviceName := "test-lifecycle" // Create the service without a selector. We should not see endpoints generated but we should see the // status updated to note endpoints are not being managed. service := rtest.Resource(catalog.ServiceV1Alpha1Type, serviceName). WithData(t, &pbcatalog.Service{ Ports: []*pbcatalog.ServicePort{{TargetPort: "http", Protocol: pbcatalog.Protocol_PROTOCOL_HTTP}}, }). Write(t, c) // Wait to ensure the status is updated accordingly c.WaitForStatusCondition(t, service.Id, catalog.EndpointsStatusKey, catalog.EndpointsStatusConditionUnmanaged) // Verify that no endpoints were created. endpointsID := rtest.Resource(catalog.ServiceEndpointsV1Alpha1Type, serviceName).ID() c.RequireResourceNotFound(t, endpointsID) // Add some empty endpoints (type validations enforce that they are owned by the service) rtest.ResourceID(endpointsID). WithData(t, &pbcatalog.ServiceEndpoints{}). WithOwner(service.Id). Write(t, c) // Now delete the service and ensure that they are cleaned up. c.MustDelete(t, service.Id) c.WaitForDeletion(t, endpointsID) // Add some workloads to eventually select by the service // api-1 has all ports (http, grpc and mesh). It also has a mixture of Addresses // that select individual ports and one that selects all ports implicitly api1 := rtest.Resource(catalog.WorkloadV1Alpha1Type, "api-1"). WithData(t, &pbcatalog.Workload{ Addresses: []*pbcatalog.WorkloadAddress{ {Host: "127.0.0.1"}, {Host: "::1", Ports: []string{"grpc"}}, {Host: "127.0.0.2", Ports: []string{"http"}}, {Host: "172.17.1.1", Ports: []string{"mesh"}}, }, Ports: map[string]*pbcatalog.WorkloadPort{ "mesh": {Port: 10000, Protocol: pbcatalog.Protocol_PROTOCOL_MESH}, "http": {Port: 8080, Protocol: pbcatalog.Protocol_PROTOCOL_HTTP}, "grpc": {Port: 9090, Protocol: pbcatalog.Protocol_PROTOCOL_GRPC}, }, Identity: "api", }). Write(t, c) // api-2 has only grpc and mesh ports. It also has a mixture of Addresses that // select individual ports and one that selects all ports implicitly api2 := rtest.Resource(catalog.WorkloadV1Alpha1Type, "api-2"). WithData(t, &pbcatalog.Workload{ Addresses: []*pbcatalog.WorkloadAddress{ {Host: "127.0.0.1"}, {Host: "::1", Ports: []string{"grpc"}}, {Host: "172.17.1.2", Ports: []string{"mesh"}}, }, Ports: map[string]*pbcatalog.WorkloadPort{ "mesh": {Port: 10000, Protocol: pbcatalog.Protocol_PROTOCOL_MESH}, "grpc": {Port: 9090, Protocol: pbcatalog.Protocol_PROTOCOL_GRPC}, }, Identity: "api", }). Write(t, c) // api-3 has the mesh and HTTP ports. It also has a mixture of Addresses that // select individual ports and one that selects all ports. api3 := rtest.Resource(catalog.WorkloadV1Alpha1Type, "api-3"). WithData(t, &pbcatalog.Workload{ Addresses: []*pbcatalog.WorkloadAddress{ {Host: "127.0.0.1"}, {Host: "172.17.1.3", Ports: []string{"mesh"}}, }, Ports: map[string]*pbcatalog.WorkloadPort{ "mesh": {Port: 10000, Protocol: pbcatalog.Protocol_PROTOCOL_MESH}, "http": {Port: 8080, Protocol: pbcatalog.Protocol_PROTOCOL_HTTP}, }, Identity: "api", }). Write(t, c) // Now create a service with unmanaged endpoints again service = rtest.Resource(catalog.ServiceV1Alpha1Type, serviceName). WithData(t, &pbcatalog.Service{ Ports: []*pbcatalog.ServicePort{{TargetPort: "http", Protocol: pbcatalog.Protocol_PROTOCOL_HTTP}}, }). Write(t, c) // Inject the endpoints resource. We want to prove that transition from unmanaged to // managed endpoints results in overwriting of the old endpoints rtest.ResourceID(endpointsID). WithData(t, &pbcatalog.ServiceEndpoints{ Endpoints: []*pbcatalog.Endpoint{ { Addresses: []*pbcatalog.WorkloadAddress{ {Host: "198.18.1.1", External: true}, }, Ports: map[string]*pbcatalog.WorkloadPort{ "http": {Port: 443, Protocol: pbcatalog.Protocol_PROTOCOL_HTTP}, }, HealthStatus: pbcatalog.Health_HEALTH_PASSING, }, }, }). WithOwner(service.Id). Write(t, c) // Wait to ensure the status is updated accordingly c.WaitForStatusCondition(t, service.Id, catalog.EndpointsStatusKey, catalog.EndpointsStatusConditionUnmanaged) // Now move the service to having managed endpoints service = rtest.ResourceID(service.Id). WithData(t, &pbcatalog.Service{ Workloads: &pbcatalog.WorkloadSelector{Names: []string{"bar"}}, Ports: []*pbcatalog.ServicePort{{TargetPort: "http", Protocol: pbcatalog.Protocol_PROTOCOL_HTTP}}, }). Write(t, c) // Verify that this status is updated to show this service as having managed endpoints c.WaitForStatusCondition(t, service.Id, catalog.EndpointsStatusKey, catalog.EndpointsStatusConditionManaged) // Verify that the service endpoints are created. In this case they will be empty verifyServiceEndpoints(t, c, endpointsID, &pbcatalog.ServiceEndpoints{}) // Rewrite the service to select the API workloads - just select the singular port for now service = rtest.ResourceID(service.Id). WithData(t, &pbcatalog.Service{ Workloads: &pbcatalog.WorkloadSelector{Prefixes: []string{"api-"}}, Ports: []*pbcatalog.ServicePort{{TargetPort: "http", Protocol: pbcatalog.Protocol_PROTOCOL_HTTP}}, }). Write(t, c) // Wait for the status to be updated. The condition itself will remain unchanged but we are waiting for // the generations to match to know that the endpoints would have been regenerated c.WaitForStatusCondition(t, service.Id, catalog.EndpointsStatusKey, catalog.EndpointsStatusConditionManaged) // ensure that api-1 and api-3 are selected but api-2 is excluded due to not having the desired port verifyServiceEndpoints(t, c, endpointsID, &pbcatalog.ServiceEndpoints{ Endpoints: []*pbcatalog.Endpoint{ { TargetRef: api1.Id, Addresses: []*pbcatalog.WorkloadAddress{ {Host: "127.0.0.1", Ports: []string{"http"}}, {Host: "127.0.0.2", Ports: []string{"http"}}, }, Ports: map[string]*pbcatalog.WorkloadPort{ "http": {Port: 8080, Protocol: pbcatalog.Protocol_PROTOCOL_HTTP}, }, HealthStatus: pbcatalog.Health_HEALTH_PASSING, }, { TargetRef: api3.Id, Addresses: []*pbcatalog.WorkloadAddress{ {Host: "127.0.0.1", Ports: []string{"http"}}, }, Ports: map[string]*pbcatalog.WorkloadPort{ "http": {Port: 8080, Protocol: pbcatalog.Protocol_PROTOCOL_HTTP}, }, HealthStatus: pbcatalog.Health_HEALTH_PASSING, }, }, }) // Rewrite the service to select the API workloads - changing from selecting the HTTP port to the gRPC port service = rtest.ResourceID(service.Id). WithData(t, &pbcatalog.Service{ Workloads: &pbcatalog.WorkloadSelector{Prefixes: []string{"api-"}}, Ports: []*pbcatalog.ServicePort{{TargetPort: "grpc", Protocol: pbcatalog.Protocol_PROTOCOL_GRPC}}, }). Write(t, c) // Wait for the status to be updated. The condition itself will remain unchanged but we are waiting for // the generations to match to know that the endpoints would have been regenerated c.WaitForStatusCondition(t, service.Id, catalog.EndpointsStatusKey, catalog.EndpointsStatusConditionManaged) // Check that the endpoints were generated as expected verifyServiceEndpoints(t, c, endpointsID, &pbcatalog.ServiceEndpoints{ Endpoints: []*pbcatalog.Endpoint{ { TargetRef: api1.Id, Addresses: []*pbcatalog.WorkloadAddress{ {Host: "127.0.0.1", Ports: []string{"grpc"}}, {Host: "::1", Ports: []string{"grpc"}}, }, Ports: map[string]*pbcatalog.WorkloadPort{ "grpc": {Port: 9090, Protocol: pbcatalog.Protocol_PROTOCOL_GRPC}, }, HealthStatus: pbcatalog.Health_HEALTH_PASSING, }, { TargetRef: api2.Id, Addresses: []*pbcatalog.WorkloadAddress{ {Host: "127.0.0.1", Ports: []string{"grpc"}}, {Host: "::1", Ports: []string{"grpc"}}, }, Ports: map[string]*pbcatalog.WorkloadPort{ "grpc": {Port: 9090, Protocol: pbcatalog.Protocol_PROTOCOL_GRPC}, }, HealthStatus: pbcatalog.Health_HEALTH_PASSING, }, }, }) // Update the service to change the ports used. This should result in the workload being removed // from the endpoints rtest.ResourceID(api2.Id). WithData(t, &pbcatalog.Workload{ Addresses: []*pbcatalog.WorkloadAddress{ {Host: "127.0.0.1"}, {Host: "::1", Ports: []string{"http"}}, {Host: "172.17.1.2", Ports: []string{"mesh"}}, }, Ports: map[string]*pbcatalog.WorkloadPort{ "mesh": {Port: 10000, Protocol: pbcatalog.Protocol_PROTOCOL_MESH}, "http": {Port: 8080, Protocol: pbcatalog.Protocol_PROTOCOL_HTTP}, }, Identity: "api", }). Write(t, c) // Verify that api-2 was removed from the service endpoints as it no longer has a grpc port verifyServiceEndpoints(t, c, endpointsID, &pbcatalog.ServiceEndpoints{ Endpoints: []*pbcatalog.Endpoint{ { TargetRef: api1.Id, Addresses: []*pbcatalog.WorkloadAddress{ {Host: "127.0.0.1", Ports: []string{"grpc"}}, {Host: "::1", Ports: []string{"grpc"}}, }, Ports: map[string]*pbcatalog.WorkloadPort{ "grpc": {Port: 9090, Protocol: pbcatalog.Protocol_PROTOCOL_GRPC}, }, HealthStatus: pbcatalog.Health_HEALTH_PASSING, }, }, }) // Remove the ::1 address from workload api1 which should result in recomputing endpoints rtest.ResourceID(api1.Id). WithData(t, &pbcatalog.Workload{ Addresses: []*pbcatalog.WorkloadAddress{ {Host: "127.0.0.1"}, {Host: "172.17.1.1", Ports: []string{"mesh"}}, }, Ports: map[string]*pbcatalog.WorkloadPort{ "mesh": {Port: 10000, Protocol: pbcatalog.Protocol_PROTOCOL_MESH}, "grpc": {Port: 9090, Protocol: pbcatalog.Protocol_PROTOCOL_GRPC}, }, Identity: "api", }). Write(t, c) // Verify that api-1 had its addresses modified appropriately verifyServiceEndpoints(t, c, endpointsID, &pbcatalog.ServiceEndpoints{ Endpoints: []*pbcatalog.Endpoint{ { TargetRef: api1.Id, Addresses: []*pbcatalog.WorkloadAddress{ {Host: "127.0.0.1", Ports: []string{"grpc"}}, }, Ports: map[string]*pbcatalog.WorkloadPort{ "grpc": {Port: 9090, Protocol: pbcatalog.Protocol_PROTOCOL_GRPC}, }, HealthStatus: pbcatalog.Health_HEALTH_PASSING, }, }, }) // Add a failing health status to the api1 workload to force recomputation of endpoints setHealthStatus(t, c, api1.Id, "api-failed", pbcatalog.Health_HEALTH_CRITICAL) // Verify that api-1 within the endpoints has the expected health verifyServiceEndpoints(t, c, endpointsID, &pbcatalog.ServiceEndpoints{ Endpoints: []*pbcatalog.Endpoint{ { TargetRef: api1.Id, Addresses: []*pbcatalog.WorkloadAddress{ {Host: "127.0.0.1", Ports: []string{"grpc"}}, }, Ports: map[string]*pbcatalog.WorkloadPort{ "grpc": {Port: 9090, Protocol: pbcatalog.Protocol_PROTOCOL_GRPC}, }, HealthStatus: pbcatalog.Health_HEALTH_CRITICAL, }, }, }) // Move the service to being unmanaged. We should see the ServiceEndpoints being removed. service = rtest.ResourceID(service.Id). WithData(t, &pbcatalog.Service{ Ports: []*pbcatalog.ServicePort{{TargetPort: "grpc", Protocol: pbcatalog.Protocol_PROTOCOL_GRPC}}, }). Write(t, c) // Wait for the endpoints controller to inform us that the endpoints are not being managed c.WaitForStatusCondition(t, service.Id, catalog.EndpointsStatusKey, catalog.EndpointsStatusConditionUnmanaged) // Ensure that the managed endpoints were deleted c.WaitForDeletion(t, endpointsID) // Put the service back into managed mode. service = rtest.ResourceID(service.Id). WithData(t, &pbcatalog.Service{ Workloads: &pbcatalog.WorkloadSelector{Prefixes: []string{"api-"}}, Ports: []*pbcatalog.ServicePort{{TargetPort: "grpc", Protocol: pbcatalog.Protocol_PROTOCOL_GRPC}}, }). Write(t, c) // Wait for the service endpoints to be regenerated c.WaitForStatusCondition(t, service.Id, catalog.EndpointsStatusKey, catalog.EndpointsStatusConditionManaged) c.RequireResourceExists(t, endpointsID) // Now delete the service and ensure that the endpoints eventually are deleted as well c.MustDelete(t, service.Id) c.WaitForDeletion(t, endpointsID) } func setHealthStatus(t *testing.T, client *rtest.Client, owner *pbresource.ID, name string, health pbcatalog.Health) *pbresource.Resource { return rtest.Resource(catalog.HealthStatusV1Alpha1Type, name). WithData(t, &pbcatalog.HealthStatus{ Type: "synthetic", Status: health, }). WithOwner(owner). Write(t, client) }