// Copyright (c) HashiCorp, Inc. // SPDX-License-Identifier: MPL-2.0 package proxycfg import ( "testing" "time" "github.com/stretchr/testify/require" "github.com/hashicorp/consul/acl" cachetype "github.com/hashicorp/consul/agent/cache-types" "github.com/hashicorp/consul/agent/configentry" "github.com/hashicorp/consul/agent/connect" "github.com/hashicorp/consul/agent/consul/discoverychain" "github.com/hashicorp/consul/agent/proxycfg/internal/watch" "github.com/hashicorp/consul/agent/structs" "github.com/hashicorp/consul/api" "github.com/hashicorp/consul/proto/private/pbpeering" "github.com/hashicorp/consul/sdk/testutil" ) const testSource ProxySource = "test" func mustCopyProxyConfig(t *testing.T, ns *structs.NodeService) structs.ConnectProxyConfig { cfg, err := copyProxyConfig(ns) require.NoError(t, err) return cfg } // assertLastReqArgs verifies that each request type had the correct source // parameters (e.g. Datacenter name) and token. func assertLastReqArgs(t *testing.T, dataSources *TestDataSources, token string, source *structs.QuerySource) { t.Helper() // Roots needs correct DC and token rootReq := dataSources.CARoots.LastReq() require.Equal(t, token, rootReq.Token) require.Equal(t, source.Datacenter, rootReq.Datacenter) // Leaf needs correct DC and token leafReq := dataSources.LeafCertificate.LastReq() require.Equal(t, token, leafReq.Token) require.Equal(t, source.Datacenter, leafReq.Datacenter) // Intentions needs correct DC and token intReq := dataSources.Intentions.LastReq() require.Equal(t, token, intReq.Token) require.Equal(t, source.Datacenter, intReq.Datacenter) } func TestManager_BasicLifecycle(t *testing.T) { if testing.Short() { t.Skip("too slow for testing.Short") } // Create a bunch of common data for the various test cases. roots, leaf := TestCerts(t) dbDefaultChain := func() *structs.CompiledDiscoveryChain { set := configentry.NewDiscoveryChainSet() set.AddEntries(&structs.ServiceResolverConfigEntry{ Kind: structs.ServiceResolver, Name: "db", }) return discoverychain.TestCompileConfigEntries(t, "db", "default", "default", "dc1", connect.TestClusterID+".consul", func(req *discoverychain.CompileRequest) { // This is because structs.TestUpstreams uses an opaque config // to override connect timeouts. req.OverrideConnectTimeout = 1 * time.Second }, set) } dbSplitChain := func() *structs.CompiledDiscoveryChain { set := configentry.NewDiscoveryChainSet() set.AddEntries(&structs.ProxyConfigEntry{ Kind: structs.ProxyDefaults, Name: structs.ProxyConfigGlobal, Config: map[string]interface{}{ "protocol": "http", }, }, &structs.ServiceResolverConfigEntry{ Kind: structs.ServiceResolver, Name: "db", Subsets: map[string]structs.ServiceResolverSubset{ "v1": { Filter: "Service.Meta.version == v1", }, "v2": { Filter: "Service.Meta.version == v2", }, }, }, &structs.ServiceSplitterConfigEntry{ Kind: structs.ServiceSplitter, Name: "db", Splits: []structs.ServiceSplit{ {Weight: 60, ServiceSubset: "v1"}, {Weight: 40, ServiceSubset: "v2"}, }, }) return discoverychain.TestCompileConfigEntries(t, "db", "default", "default", "dc1", "trustdomain.consul", func(req *discoverychain.CompileRequest) { // This is because structs.TestUpstreams uses an opaque config // to override connect timeouts. req.OverrideConnectTimeout = 1 * time.Second }, set) } upstreams := structs.TestUpstreams(t, false) for i := range upstreams { upstreams[i].DestinationNamespace = structs.IntentionDefaultNamespace upstreams[i].DestinationPartition = api.PartitionDefaultName } webProxy := &structs.NodeService{ Kind: structs.ServiceKindConnectProxy, ID: "web-sidecar-proxy", Service: "web-sidecar-proxy", Port: 9999, Meta: map[string]string{}, Proxy: structs.ConnectProxyConfig{ DestinationServiceID: "web", DestinationServiceName: "web", LocalServiceAddress: "127.0.0.1", LocalServicePort: 8080, Config: map[string]interface{}{ "foo": "bar", }, Upstreams: upstreams, }, } rootsReq := &structs.DCSpecificRequest{ Datacenter: "dc1", QueryOptions: structs.QueryOptions{Token: "my-token"}, } leafReq := &cachetype.ConnectCALeafRequest{ Datacenter: "dc1", Token: "my-token", Service: "web", } intentionReq := &structs.ServiceSpecificRequest{ Datacenter: "dc1", QueryOptions: structs.QueryOptions{Token: "my-token"}, EnterpriseMeta: *acl.DefaultEnterpriseMeta(), ServiceName: "web", } meshConfigReq := &structs.ConfigEntryQuery{ Datacenter: "dc1", QueryOptions: structs.QueryOptions{Token: "my-token"}, Kind: structs.MeshConfig, Name: structs.MeshConfigMesh, EnterpriseMeta: *structs.DefaultEnterpriseMetaInDefaultPartition(), } dbChainReq := &structs.DiscoveryChainRequest{ Name: "db", EvaluateInDatacenter: "dc1", EvaluateInNamespace: "default", EvaluateInPartition: "default", // This is because structs.TestUpstreams uses an opaque config // to override connect timeouts. OverrideConnectTimeout: 1 * time.Second, Datacenter: "dc1", QueryOptions: structs.QueryOptions{Token: "my-token"}, } dbHealthReq := &structs.ServiceSpecificRequest{ Datacenter: "dc1", QueryOptions: structs.QueryOptions{Token: "my-token", Filter: ""}, ServiceName: "db", Connect: true, EnterpriseMeta: *structs.DefaultEnterpriseMetaInDefaultPartition(), } db_v1_HealthReq := &structs.ServiceSpecificRequest{ Datacenter: "dc1", QueryOptions: structs.QueryOptions{Token: "my-token", Filter: "Service.Meta.version == v1", }, ServiceName: "db", Connect: true, EnterpriseMeta: *structs.DefaultEnterpriseMetaInDefaultPartition(), } db_v2_HealthReq := &structs.ServiceSpecificRequest{ Datacenter: "dc1", QueryOptions: structs.QueryOptions{Token: "my-token", Filter: "Service.Meta.version == v2", }, ServiceName: "db", Connect: true, EnterpriseMeta: *structs.DefaultEnterpriseMetaInDefaultPartition(), } db := structs.NewServiceName("db", nil) dbUID := NewUpstreamIDFromServiceName(db) // Create test cases using some of the common data above. tests := []*testcase_BasicLifecycle{ { name: "simple-default-resolver", setup: func(t *testing.T, dataSources *TestDataSources) { // Note that we deliberately leave the 'geo-cache' prepared query to time out dataSources.Health.Set(dbHealthReq, &structs.IndexedCheckServiceNodes{ Nodes: TestUpstreamNodes(t, db.Name), }) dataSources.CompiledDiscoveryChain.Set(dbChainReq, &structs.DiscoveryChainResponse{ Chain: dbDefaultChain(), }) }, expectSnap: &ConfigSnapshot{ Kind: structs.ServiceKindConnectProxy, Service: webProxy.Service, ProxyID: ProxyID{ServiceID: webProxy.CompoundServiceID()}, Address: webProxy.Address, Port: webProxy.Port, Proxy: mustCopyProxyConfig(t, webProxy), ServiceMeta: webProxy.Meta, TaggedAddresses: make(map[string]structs.ServiceAddress), Roots: roots, ConnectProxy: configSnapshotConnectProxy{ ConfigSnapshotUpstreams: ConfigSnapshotUpstreams{ Leaf: leaf, MeshConfigSet: true, DiscoveryChain: map[UpstreamID]*structs.CompiledDiscoveryChain{ dbUID: dbDefaultChain(), }, WatchedUpstreamEndpoints: map[UpstreamID]map[string]structs.CheckServiceNodes{ dbUID: { "db.default.default.dc1": TestUpstreamNodes(t, db.Name), }, }, WatchedGateways: nil, // Clone() clears this out WatchedGatewayEndpoints: map[UpstreamID]map[string]structs.CheckServiceNodes{ dbUID: {}, }, WatchedLocalGWEndpoints: watch.NewMap[string, structs.CheckServiceNodes](), UpstreamConfig: map[UpstreamID]*structs.Upstream{ NewUpstreamID(&upstreams[0]): &upstreams[0], NewUpstreamID(&upstreams[1]): &upstreams[1], NewUpstreamID(&upstreams[2]): &upstreams[2], }, PassthroughUpstreams: map[UpstreamID]map[string]map[string]struct{}{}, PassthroughIndices: map[string]indexedTarget{}, UpstreamPeerTrustBundles: watch.NewMap[PeerName, *pbpeering.PeeringTrustBundle](), PeerUpstreamEndpoints: watch.NewMap[UpstreamID, structs.CheckServiceNodes](), PeerUpstreamEndpointsUseHostnames: map[UpstreamID]struct{}{}, }, PreparedQueryEndpoints: map[UpstreamID]structs.CheckServiceNodes{}, DestinationsUpstream: watch.NewMap[UpstreamID, *structs.ServiceConfigEntry](), DestinationGateways: watch.NewMap[UpstreamID, structs.CheckServiceNodes](), WatchedServiceChecks: map[structs.ServiceID][]structs.CheckType{}, Intentions: TestIntentions(), IntentionsSet: true, }, Datacenter: "dc1", Locality: GatewayKey{Datacenter: "dc1", Partition: acl.PartitionOrDefault("")}, }, }, { name: "chain-resolver-with-version-split", setup: func(t *testing.T, dataSources *TestDataSources) { // Note that we deliberately leave the 'geo-cache' prepared query to time out dataSources.Health.Set(db_v1_HealthReq, &structs.IndexedCheckServiceNodes{ Nodes: TestUpstreamNodes(t, db.Name), }) dataSources.Health.Set(db_v2_HealthReq, &structs.IndexedCheckServiceNodes{ Nodes: TestUpstreamNodesAlternate(t), }) dataSources.CompiledDiscoveryChain.Set(dbChainReq, &structs.DiscoveryChainResponse{ Chain: dbSplitChain(), }) }, expectSnap: &ConfigSnapshot{ Kind: structs.ServiceKindConnectProxy, Service: webProxy.Service, ProxyID: ProxyID{ServiceID: webProxy.CompoundServiceID()}, Address: webProxy.Address, Port: webProxy.Port, Proxy: mustCopyProxyConfig(t, webProxy), ServiceMeta: webProxy.Meta, TaggedAddresses: make(map[string]structs.ServiceAddress), Roots: roots, ConnectProxy: configSnapshotConnectProxy{ ConfigSnapshotUpstreams: ConfigSnapshotUpstreams{ Leaf: leaf, MeshConfigSet: true, DiscoveryChain: map[UpstreamID]*structs.CompiledDiscoveryChain{ dbUID: dbSplitChain(), }, WatchedUpstreamEndpoints: map[UpstreamID]map[string]structs.CheckServiceNodes{ dbUID: { "v1.db.default.default.dc1": TestUpstreamNodes(t, db.Name), "v2.db.default.default.dc1": TestUpstreamNodesAlternate(t), }, }, WatchedGateways: nil, // Clone() clears this out WatchedGatewayEndpoints: map[UpstreamID]map[string]structs.CheckServiceNodes{ dbUID: {}, }, WatchedLocalGWEndpoints: watch.NewMap[string, structs.CheckServiceNodes](), UpstreamConfig: map[UpstreamID]*structs.Upstream{ NewUpstreamID(&upstreams[0]): &upstreams[0], NewUpstreamID(&upstreams[1]): &upstreams[1], NewUpstreamID(&upstreams[2]): &upstreams[2], }, PassthroughUpstreams: map[UpstreamID]map[string]map[string]struct{}{}, PassthroughIndices: map[string]indexedTarget{}, UpstreamPeerTrustBundles: watch.NewMap[PeerName, *pbpeering.PeeringTrustBundle](), PeerUpstreamEndpoints: watch.NewMap[UpstreamID, structs.CheckServiceNodes](), PeerUpstreamEndpointsUseHostnames: map[UpstreamID]struct{}{}, }, PreparedQueryEndpoints: map[UpstreamID]structs.CheckServiceNodes{}, DestinationsUpstream: watch.NewMap[UpstreamID, *structs.ServiceConfigEntry](), DestinationGateways: watch.NewMap[UpstreamID, structs.CheckServiceNodes](), WatchedServiceChecks: map[structs.ServiceID][]structs.CheckType{}, Intentions: TestIntentions(), IntentionsSet: true, }, Datacenter: "dc1", Locality: GatewayKey{Datacenter: "dc1", Partition: acl.PartitionOrDefault("")}, }, }, } for _, tt := range tests { t.Run(tt.name, func(t *testing.T) { require.NotNil(t, tt.setup) require.NotNil(t, tt.expectSnap) // Setup initial values dataSources := NewTestDataSources() dataSources.LeafCertificate.Set(leafReq, leaf) dataSources.CARoots.Set(rootsReq, roots) dataSources.Intentions.Set(intentionReq, TestIntentions()) dataSources.ConfigEntry.Set(meshConfigReq, &structs.ConfigEntryResponse{Entry: nil}) tt.setup(t, dataSources) expectSnapCopy := tt.expectSnap.Clone() webProxyCopy := webProxy.DeepCopy() testManager_BasicLifecycle(t, dataSources, rootsReq, leafReq, roots, webProxyCopy, expectSnapCopy, ) }) } } type testcase_BasicLifecycle struct { name string setup func(t *testing.T, dataSources *TestDataSources) webProxy *structs.NodeService expectSnap *ConfigSnapshot } func testManager_BasicLifecycle( t *testing.T, dataSources *TestDataSources, rootsReq *structs.DCSpecificRequest, leafReq *cachetype.ConnectCALeafRequest, roots *structs.IndexedCARoots, webProxy *structs.NodeService, expectSnap *ConfigSnapshot, ) { logger := testutil.Logger(t) source := &structs.QuerySource{Datacenter: "dc1"} // Create manager m, err := NewManager(ManagerConfig{ Source: source, Logger: logger, DataSources: dataSources.ToDataSources(), }) require.NoError(t, err) webProxyID := ProxyID{ ServiceID: webProxy.CompoundServiceID(), } // BEFORE we register, we should be able to get a watch channel wCh, cancel := m.Watch(webProxyID) defer cancel() // And it should block with nothing sent on it yet assertWatchChanBlocks(t, wCh) require.NoError(t, m.Register(webProxyID, webProxy, testSource, "my-token", false)) // We should see the initial config delivered but not until after the // coalesce timeout start := time.Now() assertWatchChanRecvs(t, wCh, expectSnap) require.True(t, time.Since(start) >= coalesceTimeout) assertLastReqArgs(t, dataSources, "my-token", source) // Update NodeConfig webProxy.Port = 7777 require.NoError(t, m.Register(webProxyID, webProxy, testSource, "my-token", false)) expectSnap.Port = 7777 assertWatchChanRecvs(t, wCh, expectSnap) // Register a second watcher wCh2, cancel2 := m.Watch(webProxyID) defer cancel2() // New watcher should immediately receive the current state assertWatchChanRecvs(t, wCh2, expectSnap) // Change token require.NoError(t, m.Register(webProxyID, webProxy, testSource, "other-token", false)) assertWatchChanRecvs(t, wCh, expectSnap) assertWatchChanRecvs(t, wCh2, expectSnap) // This is actually sort of timing dependent - the cache background fetcher // will still be fetching with the old token, but we rely on the fact that our // mock type will have been blocked on those for a while. assertLastReqArgs(t, dataSources, "other-token", source) // Update roots newRoots, newLeaf := TestCerts(t) newRoots.Roots = append(newRoots.Roots, roots.Roots...) dataSources.CARoots.Set(rootsReq, newRoots) // Expect new roots in snapshot expectSnap.Roots = newRoots assertWatchChanRecvs(t, wCh, expectSnap) assertWatchChanRecvs(t, wCh2, expectSnap) // Update leaf dataSources.LeafCertificate.Set(leafReq, newLeaf) // Expect new roots in snapshot expectSnap.ConnectProxy.Leaf = newLeaf assertWatchChanRecvs(t, wCh, expectSnap) assertWatchChanRecvs(t, wCh2, expectSnap) // Remove the proxy m.Deregister(webProxyID, testSource) // Chan should NOT close assertWatchChanBlocks(t, wCh) assertWatchChanBlocks(t, wCh2) // Re-add the proxy with another new port webProxy.Port = 3333 require.NoError(t, m.Register(webProxyID, webProxy, testSource, "other-token", false)) // Same watch chan should be notified again expectSnap.Port = 3333 assertWatchChanRecvs(t, wCh, expectSnap) assertWatchChanRecvs(t, wCh2, expectSnap) // Cancel watch cancel() // Watch chan should be closed assertWatchChanRecvs(t, wCh, nil) // We specifically don't remove the proxy or cancel the second watcher to // ensure both are cleaned up by close. require.NoError(t, m.Close()) // Sanity check the state is clean m.mu.Lock() defer m.mu.Unlock() require.Len(t, m.proxies, 0) require.Len(t, m.watchers, 0) } func assertWatchChanBlocks(t *testing.T, ch <-chan *ConfigSnapshot) { t.Helper() select { case <-ch: t.Fatal("Should be nothing sent on watch chan yet") default: } } func assertWatchChanRecvs(t *testing.T, ch <-chan *ConfigSnapshot, expect *ConfigSnapshot) { t.Helper() select { case got, ok := <-ch: require.Equal(t, expect, got) if expect == nil { require.False(t, ok, "watch chan should be closed") } case <-time.After(100*time.Millisecond + coalesceTimeout): t.Fatal("recv timeout") } } func TestManager_deliverLatest(t *testing.T) { // None of these need to do anything to test this method just be valid logger := testutil.Logger(t) cfg := ManagerConfig{ Source: &structs.QuerySource{ Node: "node1", Datacenter: "dc1", }, Logger: logger, } m, err := NewManager(cfg) require.NoError(t, err) snap1 := &ConfigSnapshot{ ProxyID: ProxyID{ServiceID: structs.NewServiceID("test-proxy", nil)}, Port: 1111, } snap2 := &ConfigSnapshot{ ProxyID: ProxyID{ServiceID: structs.NewServiceID("test-proxy", nil)}, Port: 2222, } // test 1 buffered chan ch1 := make(chan *ConfigSnapshot, 1) // Sending to an unblocked chan should work m.deliverLatest(snap1, ch1) // Check it was delivered require.Equal(t, snap1, <-ch1) // Now send both without reading simulating a slow client m.deliverLatest(snap1, ch1) m.deliverLatest(snap2, ch1) // Check we got the _second_ one require.Equal(t, snap2, <-ch1) // Same again for 5-buffered chan ch5 := make(chan *ConfigSnapshot, 5) // Sending to an unblocked chan should work m.deliverLatest(snap1, ch5) // Check it was delivered require.Equal(t, snap1, <-ch5) // Now send enough to fill the chan simulating a slow client for i := 0; i < 5; i++ { m.deliverLatest(snap1, ch5) } m.deliverLatest(snap2, ch5) // Check we got the _second_ one require.Equal(t, snap2, <-ch5) } func TestManager_SyncState_No_Notify(t *testing.T) { dataSources := NewTestDataSources() logger := testutil.Logger(t) m, err := NewManager(ManagerConfig{ Source: &structs.QuerySource{Datacenter: "dc1"}, Logger: logger, DataSources: dataSources.ToDataSources(), }) require.NoError(t, err) defer m.Close() srv := &structs.NodeService{ Kind: structs.ServiceKindConnectProxy, ID: "web-sidecar-proxy", Service: "web-sidecar-proxy", Port: 9999, Meta: map[string]string{}, Proxy: structs.ConnectProxyConfig{ DestinationServiceID: "web", DestinationServiceName: "web", LocalServiceAddress: "127.0.0.1", LocalServicePort: 8080, Config: map[string]interface{}{ "foo": "bar", }, }, } proxyID := ProxyID{ ServiceID: srv.CompoundServiceID(), } require.NoError(t, m.Register(proxyID, srv, testSource, "", false)) watchCh, cancelWatch := m.Watch(proxyID) t.Cleanup(cancelWatch) // Get the relevant notification Channel, should only have 1 notifyCH := m.proxies[proxyID].ch // update the leaf certs roots, issuedCert := TestCerts(t) notifyCH <- UpdateEvent{ CorrelationID: leafWatchID, Result: issuedCert, Err: nil, } // at this point the snapshot should not be valid and not be sent after := time.After(200 * time.Millisecond) select { case <-watchCh: t.Fatal("snap should not be valid") case <-after: } // update the root certs notifyCH <- UpdateEvent{ CorrelationID: rootsWatchID, Result: roots, Err: nil, } // at this point the snapshot should not be valid and not be sent after = time.After(200 * time.Millisecond) select { case <-watchCh: t.Fatal("snap should not be valid") case <-after: } // update the mesh config entry notifyCH <- UpdateEvent{ CorrelationID: meshConfigEntryID, Result: &structs.ConfigEntryResponse{}, Err: nil, } // at this point the snapshot should not be valid and not be sent after = time.After(200 * time.Millisecond) select { case <-watchCh: t.Fatal("snap should not be valid") case <-after: } // update the intentions notifyCH <- UpdateEvent{ CorrelationID: intentionsWatchID, Result: structs.Intentions{}, Err: nil, } // at this point we have a valid snapshot after = time.After(500 * time.Millisecond) select { case <-watchCh: case <-after: t.Fatal("snap should be valid") } }