package consul import ( "crypto/x509" "fmt" "net" "os" "reflect" "strings" "sync" "sync/atomic" "testing" "time" "github.com/armon/go-metrics" "github.com/google/tcpproxy" "github.com/hashicorp/go-hclog" "github.com/hashicorp/go-uuid" "github.com/hashicorp/memberlist" "github.com/hashicorp/raft" "github.com/stretchr/testify/require" "golang.org/x/time/rate" "google.golang.org/grpc" "github.com/hashicorp/consul-net-rpc/net/rpc" "github.com/hashicorp/consul/agent/connect" external "github.com/hashicorp/consul/agent/grpc-external" "github.com/hashicorp/consul/agent/metadata" "github.com/hashicorp/consul/agent/rpc/middleware" "github.com/hashicorp/consul/agent/structs" "github.com/hashicorp/consul/agent/token" "github.com/hashicorp/consul/ipaddr" "github.com/hashicorp/consul/sdk/freeport" "github.com/hashicorp/consul/sdk/testutil" "github.com/hashicorp/consul/sdk/testutil/retry" "github.com/hashicorp/consul/testrpc" "github.com/hashicorp/consul/tlsutil" "github.com/hashicorp/consul/types" ) const ( TestDefaultInitialManagementToken = "d9f05e83-a7ae-47ce-839e-c0d53a68c00a" ) // testTLSCertificates Generates a TLS CA and server key/cert and returns them // in PEM encoded form. func testTLSCertificates(serverName string) (cert string, key string, cacert string, err error) { signer, _, err := tlsutil.GeneratePrivateKey() if err != nil { return "", "", "", err } ca, _, err := tlsutil.GenerateCA(tlsutil.CAOpts{Signer: signer}) if err != nil { return "", "", "", err } cert, privateKey, err := tlsutil.GenerateCert(tlsutil.CertOpts{ Signer: signer, CA: ca, Name: "Test Cert Name", Days: 365, DNSNames: []string{serverName}, ExtKeyUsage: []x509.ExtKeyUsage{x509.ExtKeyUsageServerAuth, x509.ExtKeyUsageClientAuth}, }) if err != nil { return "", "", "", err } return cert, privateKey, ca, nil } func testServerACLConfig(c *Config) { c.PrimaryDatacenter = "dc1" c.ACLsEnabled = true c.ACLInitialManagementToken = TestDefaultInitialManagementToken c.ACLResolverSettings.ACLDefaultPolicy = "deny" } func configureTLS(config *Config) { config.TLSConfig.InternalRPC.CAFile = "../../test/ca/root.cer" config.TLSConfig.InternalRPC.CertFile = "../../test/key/ourdomain.cer" config.TLSConfig.InternalRPC.KeyFile = "../../test/key/ourdomain.key" } var id int64 func uniqueNodeName(name string) string { name = strings.ReplaceAll(name, "/", "_") return fmt.Sprintf("%s-node-%d", name, atomic.AddInt64(&id, 1)) } // This will find the leader of a list of servers and verify that leader establishment has completed func waitForLeaderEstablishment(t *testing.T, servers ...*Server) { t.Helper() retry.Run(t, func(r *retry.R) { hasLeader := false for _, srv := range servers { if srv.IsLeader() { hasLeader = true require.True(r, srv.isReadyForConsistentReads(), "Leader %s hasn't finished establishing leadership yet", srv.config.NodeName) } } require.True(r, hasLeader, "Cluster has not elected a leader yet") }) } func testServerConfig(t *testing.T) (string, *Config) { dir := testutil.TempDir(t, "consul") config := DefaultConfig() ports := freeport.GetN(t, 4) // {server, serf_lan, serf_wan, grpc} config.NodeName = uniqueNodeName(t.Name()) config.Bootstrap = true config.Datacenter = "dc1" config.PrimaryDatacenter = "dc1" config.DataDir = dir // bind the rpc server to a random port. config.RPCAdvertise will be // set to the listen address unless it was set in the configuration. // In that case get the address from srv.Listener.Addr(). config.RPCAddr = &net.TCPAddr{IP: []byte{127, 0, 0, 1}, Port: ports[0]} nodeID, err := uuid.GenerateUUID() if err != nil { t.Fatal(err) } config.NodeID = types.NodeID(nodeID) // set the memberlist bind port to 0 to bind to a random port. // memberlist will update the value of BindPort after bind // to the actual value. config.SerfLANConfig.MemberlistConfig.BindAddr = "127.0.0.1" config.SerfLANConfig.MemberlistConfig.BindPort = ports[1] config.SerfLANConfig.MemberlistConfig.AdvertisePort = ports[1] config.SerfLANConfig.MemberlistConfig.SuspicionMult = 2 config.SerfLANConfig.MemberlistConfig.ProbeTimeout = 50 * time.Millisecond config.SerfLANConfig.MemberlistConfig.ProbeInterval = 100 * time.Millisecond config.SerfLANConfig.MemberlistConfig.GossipInterval = 100 * time.Millisecond config.SerfLANConfig.MemberlistConfig.DeadNodeReclaimTime = 100 * time.Millisecond config.SerfWANConfig.MemberlistConfig.BindAddr = "127.0.0.1" config.SerfWANConfig.MemberlistConfig.BindPort = ports[2] config.SerfWANConfig.MemberlistConfig.AdvertisePort = ports[2] config.SerfWANConfig.MemberlistConfig.SuspicionMult = 2 config.SerfWANConfig.MemberlistConfig.ProbeTimeout = 50 * time.Millisecond config.SerfWANConfig.MemberlistConfig.ProbeInterval = 100 * time.Millisecond config.SerfWANConfig.MemberlistConfig.GossipInterval = 100 * time.Millisecond config.SerfWANConfig.MemberlistConfig.DeadNodeReclaimTime = 100 * time.Millisecond config.RaftConfig.LeaderLeaseTimeout = 100 * time.Millisecond config.RaftConfig.HeartbeatTimeout = 200 * time.Millisecond config.RaftConfig.ElectionTimeout = 200 * time.Millisecond config.ReconcileInterval = 300 * time.Millisecond config.AutopilotConfig.ServerStabilizationTime = 100 * time.Millisecond config.ServerHealthInterval = 50 * time.Millisecond config.AutopilotInterval = 100 * time.Millisecond config.CoordinateUpdatePeriod = 100 * time.Millisecond config.LeaveDrainTime = 1 * time.Millisecond // TODO (slackpad) - We should be able to run all tests w/o this, but it // looks like several depend on it. config.RPCHoldTimeout = 10 * time.Second config.GRPCPort = ports[3] config.ConnectEnabled = true config.CAConfig = &structs.CAConfiguration{ ClusterID: connect.TestClusterID, Provider: structs.ConsulCAProvider, Config: map[string]interface{}{ "PrivateKey": "", "RootCert": "", "LeafCertTTL": "72h", "IntermediateCertTTL": "288h", }, } config.PeeringEnabled = true return dir, config } // Deprecated: use testServerWithConfig instead. It does the same thing and more. func testServer(t *testing.T) (string, *Server) { return testServerWithConfig(t) } // Deprecated: use testServerWithConfig func testServerDC(t *testing.T, dc string) (string, *Server) { return testServerWithConfig(t, func(c *Config) { c.Datacenter = dc c.Bootstrap = true }) } // Deprecated: use testServerWithConfig func testServerDCBootstrap(t *testing.T, dc string, bootstrap bool) (string, *Server) { return testServerWithConfig(t, func(c *Config) { c.Datacenter = dc c.PrimaryDatacenter = dc c.Bootstrap = bootstrap }) } // Deprecated: use testServerWithConfig func testServerDCExpect(t *testing.T, dc string, expect int) (string, *Server) { return testServerWithConfig(t, func(c *Config) { c.Datacenter = dc c.Bootstrap = false c.BootstrapExpect = expect }) } func testServerWithConfig(t *testing.T, configOpts ...func(*Config)) (string, *Server) { var dir string var srv *Server // Retry added to avoid cases where bind addr is already in use retry.RunWith(retry.ThreeTimes(), t, func(r *retry.R) { var config *Config dir, config = testServerConfig(t) for _, fn := range configOpts { fn(config) } // Apply config to copied fields because many tests only set the old //values. config.ACLResolverSettings.ACLsEnabled = config.ACLsEnabled config.ACLResolverSettings.NodeName = config.NodeName config.ACLResolverSettings.Datacenter = config.Datacenter config.ACLResolverSettings.EnterpriseMeta = *config.AgentEnterpriseMeta() var err error srv, err = newServer(t, config) if err != nil { r.Fatalf("err: %v", err) } }) t.Cleanup(func() { srv.Shutdown() }) if srv.config.GRPCPort > 0 { // Normally the gRPC server listener is created at the agent level and // passed down into the Server creation. externalGRPCAddr := fmt.Sprintf("127.0.0.1:%d", srv.config.GRPCPort) ln, err := net.Listen("tcp", externalGRPCAddr) require.NoError(t, err) go func() { _ = srv.externalGRPCServer.Serve(ln) }() t.Cleanup(srv.externalGRPCServer.Stop) } return dir, srv } // cb is a function that can alter the test servers configuration prior to the server starting. func testACLServerWithConfig(t *testing.T, cb func(*Config), initReplicationToken bool) (string, *Server, rpc.ClientCodec) { opts := []func(*Config){testServerACLConfig} if cb != nil { opts = append(opts, cb) } dir, srv := testServerWithConfig(t, opts...) if initReplicationToken { // setup some tokens here so we get less warnings in the logs srv.tokens.UpdateReplicationToken(TestDefaultInitialManagementToken, token.TokenSourceConfig) } codec := rpcClient(t, srv) return dir, srv, codec } func testGRPCIntegrationServer(t *testing.T, cb func(*Config)) (*Server, *grpc.ClientConn, rpc.ClientCodec) { _, srv, codec := testACLServerWithConfig(t, cb, false) grpcAddr := fmt.Sprintf("127.0.0.1:%d", srv.config.GRPCPort) conn, err := grpc.Dial(grpcAddr, grpc.WithInsecure()) require.NoError(t, err) t.Cleanup(func() { _ = conn.Close() }) return srv, conn, codec } func newServer(t *testing.T, c *Config) (*Server, error) { return newServerWithDeps(t, c, newDefaultDeps(t, c)) } func newServerWithDeps(t *testing.T, c *Config, deps Deps) (*Server, error) { // chain server up notification oldNotify := c.NotifyListen up := make(chan struct{}) c.NotifyListen = func() { close(up) if oldNotify != nil { oldNotify() } } srv, err := NewServer(c, deps, external.NewServer(deps.Logger.Named("grpc.external"), deps.TLSConfigurator)) if err != nil { return nil, err } t.Cleanup(func() { srv.Shutdown() }) // wait until after listen <-up // get the real address // // the server already sets the RPCAdvertise address // if it wasn't configured since it needs it for // some initialization // // todo(fs): setting RPCAddr should probably be guarded // todo(fs): but for now it is a shortcut to avoid fixing // todo(fs): tests which depend on that value. They should // todo(fs): just get the listener address instead. c.RPCAddr = srv.Listener.Addr().(*net.TCPAddr) return srv, nil } func TestServer_StartStop(t *testing.T) { t.Parallel() // Start up a server and then stop it. _, s1 := testServer(t) if err := s1.Shutdown(); err != nil { t.Fatalf("err: %v", err) } // Shut down again, which should be idempotent. if err := s1.Shutdown(); err != nil { t.Fatalf("err: %v", err) } } func TestServer_fixupACLDatacenter(t *testing.T) { if testing.Short() { t.Skip("too slow for testing.Short") } t.Parallel() _, s1 := testServerWithConfig(t, func(c *Config) { c.Datacenter = "aye" c.PrimaryDatacenter = "aye" c.ACLsEnabled = true }) defer s1.Shutdown() _, s2 := testServerWithConfig(t, func(c *Config) { c.Datacenter = "bee" c.PrimaryDatacenter = "aye" c.ACLsEnabled = true }) defer s2.Shutdown() // Try to join joinWAN(t, s2, s1) retry.Run(t, func(r *retry.R) { if got, want := len(s1.WANMembers()), 2; got != want { r.Fatalf("got %d s1 WAN members want %d", got, want) } if got, want := len(s2.WANMembers()), 2; got != want { r.Fatalf("got %d s2 WAN members want %d", got, want) } }) testrpc.WaitForLeader(t, s1.RPC, "aye") testrpc.WaitForLeader(t, s2.RPC, "bee") require.Equal(t, "aye", s1.config.Datacenter) require.Equal(t, "aye", s1.config.PrimaryDatacenter) require.Equal(t, "aye", s1.config.PrimaryDatacenter) require.Equal(t, "bee", s2.config.Datacenter) require.Equal(t, "aye", s2.config.PrimaryDatacenter) require.Equal(t, "aye", s2.config.PrimaryDatacenter) } func TestServer_JoinLAN(t *testing.T) { t.Parallel() dir1, s1 := testServer(t) defer os.RemoveAll(dir1) defer s1.Shutdown() dir2, s2 := testServer(t) defer os.RemoveAll(dir2) defer s2.Shutdown() // Try to join joinLAN(t, s2, s1) retry.Run(t, func(r *retry.R) { if got, want := len(s1.LANMembersInAgentPartition()), 2; got != want { r.Fatalf("got %d s1 LAN members want %d", got, want) } if got, want := len(s2.LANMembersInAgentPartition()), 2; got != want { r.Fatalf("got %d s2 LAN members want %d", got, want) } }) } // TestServer_JoinLAN_SerfAllowedCIDRs test that IPs might be blocked with // Serf. // // To run properly, this test requires to be able to bind and have access on // 127.0.1.1 which is the case for most Linux machines and Windows, so Unit // test will run in the CI. // // To run it on Mac OS, please run this command first, otherwise the test will // be skipped: `sudo ifconfig lo0 alias 127.0.1.1 up` func TestServer_JoinLAN_SerfAllowedCIDRs(t *testing.T) { t.Parallel() const targetAddr = "127.0.1.1" skipIfCannotBindToIP(t, targetAddr) dir1, s1 := testServerWithConfig(t, func(c *Config) { c.BootstrapExpect = 1 lan, err := memberlist.ParseCIDRs([]string{"127.0.0.1/32"}) require.NoError(t, err) c.SerfLANConfig.MemberlistConfig.CIDRsAllowed = lan wan, err := memberlist.ParseCIDRs([]string{"127.0.0.0/24", "::1/128"}) require.NoError(t, err) c.SerfWANConfig.MemberlistConfig.CIDRsAllowed = wan }) defer os.RemoveAll(dir1) defer s1.Shutdown() dir2, a2 := testClientWithConfig(t, func(c *Config) { c.SerfLANConfig.MemberlistConfig.BindAddr = targetAddr }) defer os.RemoveAll(dir2) defer a2.Shutdown() dir3, rs3 := testServerWithConfig(t, func(c *Config) { c.BootstrapExpect = 1 c.Datacenter = "dc2" }) defer os.RemoveAll(dir3) defer rs3.Shutdown() leaderAddr := joinAddrLAN(s1) if _, err := a2.JoinLAN([]string{leaderAddr}, nil); err != nil { t.Fatalf("Expected no error, had: %#v", err) } // Try to join joinWAN(t, rs3, s1) retry.Run(t, func(r *retry.R) { if got, want := len(s1.LANMembersInAgentPartition()), 1; got != want { // LAN is blocked, should be 1 only r.Fatalf("got %d s1 LAN members want %d", got, want) } if got, want := len(a2.LANMembersInAgentPartition()), 2; got != want { // LAN is blocked a2 can see s1, but not s1 r.Fatalf("got %d a2 LAN members want %d", got, want) } if got, want := len(s1.WANMembers()), 2; got != want { r.Fatalf("got %d s1 WAN members want %d", got, want) } if got, want := len(rs3.WANMembers()), 2; got != want { r.Fatalf("got %d rs3 WAN members want %d", got, want) } }) } // TestServer_JoinWAN_SerfAllowedCIDRs test that IPs might be // blocked with Serf. // // To run properly, this test requires to be able to bind and have access on // 127.0.1.1 which is the case for most Linux machines and Windows, so Unit // test will run in the CI. // // To run it on Mac OS, please run this command first, otherwise the test will // be skipped: `sudo ifconfig lo0 alias 127.0.1.1 up` func TestServer_JoinWAN_SerfAllowedCIDRs(t *testing.T) { if testing.Short() { t.Skip("too slow for testing.Short") } const targetAddr = "127.0.1.1" skipIfCannotBindToIP(t, targetAddr) wanCIDRs, err := memberlist.ParseCIDRs([]string{"127.0.0.1/32"}) require.NoError(t, err) dir1, s1 := testServerWithConfig(t, func(c *Config) { c.Bootstrap = true c.BootstrapExpect = 1 c.Datacenter = "dc1" c.SerfWANConfig.MemberlistConfig.CIDRsAllowed = wanCIDRs }) defer os.RemoveAll(dir1) defer s1.Shutdown() waitForLeaderEstablishment(t, s1) testrpc.WaitForLeader(t, s1.RPC, "dc1") dir2, s2 := testServerWithConfig(t, func(c *Config) { c.Bootstrap = true c.BootstrapExpect = 1 c.PrimaryDatacenter = "dc1" c.Datacenter = "dc2" c.SerfWANConfig.MemberlistConfig.BindAddr = targetAddr }) defer os.RemoveAll(dir2) defer s2.Shutdown() waitForLeaderEstablishment(t, s2) testrpc.WaitForLeader(t, s2.RPC, "dc2") // Joining should be fine joinWANWithNoMembershipChecks(t, s2, s1) // But membership is blocked if you go and take a peek on the server. t.Run("LAN membership should only show each other", func(t *testing.T) { require.Len(t, s1.LANMembersInAgentPartition(), 1) require.Len(t, s2.LANMembersInAgentPartition(), 1) }) t.Run("WAN membership in the primary should not show the secondary", func(t *testing.T) { require.Len(t, s1.WANMembers(), 1) }) t.Run("WAN membership in the secondary can show the primary", func(t *testing.T) { require.Len(t, s2.WANMembers(), 2) }) } func skipIfCannotBindToIP(t *testing.T, ip string) { l, err := net.Listen("tcp", net.JoinHostPort(ip, "0")) if err != nil { t.Skipf("Cannot bind on %s, to run on Mac OS: `sudo ifconfig lo0 alias %s up`", ip, ip) } l.Close() } func TestServer_LANReap(t *testing.T) { if testing.Short() { t.Skip("too slow for testing.Short") } t.Parallel() configureServer := func(c *Config) { c.SerfFloodInterval = 100 * time.Millisecond c.SerfLANConfig.ReconnectTimeout = 250 * time.Millisecond c.SerfLANConfig.TombstoneTimeout = 250 * time.Millisecond c.SerfLANConfig.ReapInterval = 300 * time.Millisecond } dir1, s1 := testServerWithConfig(t, func(c *Config) { c.Datacenter = "dc1" c.Bootstrap = true configureServer(c) }) defer os.RemoveAll(dir1) defer s1.Shutdown() dir2, s2 := testServerWithConfig(t, func(c *Config) { c.Datacenter = "dc1" c.Bootstrap = false configureServer(c) }) defer os.RemoveAll(dir2) dir3, s3 := testServerWithConfig(t, func(c *Config) { c.Datacenter = "dc1" c.Bootstrap = false configureServer(c) }) defer os.RemoveAll(dir3) defer s3.Shutdown() // Try to join joinLAN(t, s2, s1) joinLAN(t, s3, s1) testrpc.WaitForLeader(t, s1.RPC, "dc1") testrpc.WaitForLeader(t, s2.RPC, "dc1") testrpc.WaitForLeader(t, s3.RPC, "dc1") retry.Run(t, func(r *retry.R) { require.Len(r, s1.LANMembersInAgentPartition(), 3) require.Len(r, s2.LANMembersInAgentPartition(), 3) require.Len(r, s3.LANMembersInAgentPartition(), 3) }) // Check the router has both retry.Run(t, func(r *retry.R) { require.Len(r, s1.serverLookup.Servers(), 3) require.Len(r, s2.serverLookup.Servers(), 3) require.Len(r, s3.serverLookup.Servers(), 3) }) // shutdown the second dc s2.Shutdown() retry.Run(t, func(r *retry.R) { require.Len(r, s1.LANMembersInAgentPartition(), 2) servers := s1.serverLookup.Servers() require.Len(r, servers, 2) // require.Equal(r, s1.config.NodeName, servers[0].Name) }) } func TestServer_JoinWAN(t *testing.T) { t.Parallel() dir1, s1 := testServer(t) defer os.RemoveAll(dir1) defer s1.Shutdown() dir2, s2 := testServerDC(t, "dc2") defer os.RemoveAll(dir2) defer s2.Shutdown() // Try to join joinWAN(t, s2, s1) retry.Run(t, func(r *retry.R) { if got, want := len(s1.WANMembers()), 2; got != want { r.Fatalf("got %d s1 WAN members want %d", got, want) } if got, want := len(s2.WANMembers()), 2; got != want { r.Fatalf("got %d s2 WAN members want %d", got, want) } }) // Check the router has both retry.Run(t, func(r *retry.R) { if got, want := len(s1.router.GetDatacenters()), 2; got != want { r.Fatalf("got %d routes want %d", got, want) } if got, want := len(s2.router.GetDatacenters()), 2; got != want { r.Fatalf("got %d datacenters want %d", got, want) } }) } func TestServer_WANReap(t *testing.T) { if testing.Short() { t.Skip("too slow for testing.Short") } t.Parallel() dir1, s1 := testServerWithConfig(t, func(c *Config) { c.Datacenter = "dc1" c.Bootstrap = true c.SerfFloodInterval = 100 * time.Millisecond c.SerfWANConfig.ReconnectTimeout = 250 * time.Millisecond c.SerfWANConfig.TombstoneTimeout = 250 * time.Millisecond c.SerfWANConfig.ReapInterval = 500 * time.Millisecond }) defer os.RemoveAll(dir1) defer s1.Shutdown() dir2, s2 := testServerDC(t, "dc2") defer os.RemoveAll(dir2) // Try to join joinWAN(t, s2, s1) retry.Run(t, func(r *retry.R) { require.Len(r, s1.WANMembers(), 2) require.Len(r, s2.WANMembers(), 2) }) // Check the router has both retry.Run(t, func(r *retry.R) { require.Len(r, s1.router.GetDatacenters(), 2) require.Len(r, s2.router.GetDatacenters(), 2) }) // shutdown the second dc s2.Shutdown() retry.Run(t, func(r *retry.R) { require.Len(r, s1.WANMembers(), 1) datacenters := s1.router.GetDatacenters() require.Len(r, datacenters, 1) require.Equal(r, "dc1", datacenters[0]) }) } func TestServer_JoinWAN_Flood(t *testing.T) { if testing.Short() { t.Skip("too slow for testing.Short") } t.Parallel() // Set up two servers in a WAN. dir1, s1 := testServerDCBootstrap(t, "dc1", true) defer os.RemoveAll(dir1) defer s1.Shutdown() dir2, s2 := testServerDCBootstrap(t, "dc2", true) defer os.RemoveAll(dir2) defer s2.Shutdown() joinWAN(t, s2, s1) for _, s := range []*Server{s1, s2} { retry.Run(t, func(r *retry.R) { if got, want := len(s.WANMembers()), 2; got != want { r.Fatalf("got %d WAN members want %d", got, want) } }) } dir3, s3 := testServerDCBootstrap(t, "dc1", false) defer os.RemoveAll(dir3) defer s3.Shutdown() // Do just a LAN join for the new server and make sure it // shows up in the WAN. joinLAN(t, s3, s1) for _, s := range []*Server{s1, s2, s3} { retry.Run(t, func(r *retry.R) { if got, want := len(s.WANMembers()), 3; got != want { r.Fatalf("got %d WAN members for %s want %d", got, s.config.NodeName, want) } }) } } // This is a mirror of a similar test in agent/agent_test.go func TestServer_JoinWAN_viaMeshGateway(t *testing.T) { // if this test is failing because of expired certificates // use the procedure in test/CA-GENERATION.md if testing.Short() { t.Skip("too slow for testing.Short") } t.Parallel() port := freeport.GetOne(t) gwAddr := ipaddr.FormatAddressPort("127.0.0.1", port) dir1, s1 := testServerWithConfig(t, func(c *Config) { c.TLSConfig.Domain = "consul" c.NodeName = "bob" c.Datacenter = "dc1" c.PrimaryDatacenter = "dc1" c.Bootstrap = true // tls c.TLSConfig.InternalRPC.CAFile = "../../test/hostname/CertAuth.crt" c.TLSConfig.InternalRPC.CertFile = "../../test/hostname/Bob.crt" c.TLSConfig.InternalRPC.KeyFile = "../../test/hostname/Bob.key" c.TLSConfig.InternalRPC.VerifyIncoming = true c.TLSConfig.InternalRPC.VerifyOutgoing = true c.TLSConfig.InternalRPC.VerifyServerHostname = true // wanfed c.ConnectMeshGatewayWANFederationEnabled = true }) defer os.RemoveAll(dir1) defer s1.Shutdown() dir2, s2 := testServerWithConfig(t, func(c *Config) { c.TLSConfig.Domain = "consul" c.NodeName = "betty" c.Datacenter = "dc2" c.PrimaryDatacenter = "dc1" c.Bootstrap = true // tls c.TLSConfig.InternalRPC.CAFile = "../../test/hostname/CertAuth.crt" c.TLSConfig.InternalRPC.CertFile = "../../test/hostname/Betty.crt" c.TLSConfig.InternalRPC.KeyFile = "../../test/hostname/Betty.key" c.TLSConfig.InternalRPC.VerifyIncoming = true c.TLSConfig.InternalRPC.VerifyOutgoing = true c.TLSConfig.InternalRPC.VerifyServerHostname = true // wanfed c.ConnectMeshGatewayWANFederationEnabled = true }) defer os.RemoveAll(dir2) defer s2.Shutdown() dir3, s3 := testServerWithConfig(t, func(c *Config) { c.TLSConfig.Domain = "consul" c.NodeName = "bonnie" c.Datacenter = "dc3" c.PrimaryDatacenter = "dc1" c.Bootstrap = true // tls c.TLSConfig.InternalRPC.CAFile = "../../test/hostname/CertAuth.crt" c.TLSConfig.InternalRPC.CertFile = "../../test/hostname/Bonnie.crt" c.TLSConfig.InternalRPC.KeyFile = "../../test/hostname/Bonnie.key" c.TLSConfig.InternalRPC.VerifyIncoming = true c.TLSConfig.InternalRPC.VerifyOutgoing = true c.TLSConfig.InternalRPC.VerifyServerHostname = true // wanfed c.ConnectMeshGatewayWANFederationEnabled = true }) defer os.RemoveAll(dir3) defer s3.Shutdown() // We'll use the same gateway for all datacenters since it doesn't care. var p tcpproxy.Proxy p.AddSNIRoute(gwAddr, "bob.server.dc1.consul", tcpproxy.To(s1.config.RPCAddr.String())) p.AddSNIRoute(gwAddr, "betty.server.dc2.consul", tcpproxy.To(s2.config.RPCAddr.String())) p.AddSNIRoute(gwAddr, "bonnie.server.dc3.consul", tcpproxy.To(s3.config.RPCAddr.String())) p.AddStopACMESearch(gwAddr) require.NoError(t, p.Start()) defer func() { p.Close() p.Wait() }() t.Logf("routing %s => %s", "bob.server.dc1.consul", s1.config.RPCAddr.String()) t.Logf("routing %s => %s", "betty.server.dc2.consul", s2.config.RPCAddr.String()) t.Logf("routing %s => %s", "bonnie.server.dc3.consul", s3.config.RPCAddr.String()) // Register this into the catalog in dc1. { arg := structs.RegisterRequest{ Datacenter: "dc1", Node: "bob", Address: "127.0.0.1", Service: &structs.NodeService{ Kind: structs.ServiceKindMeshGateway, ID: "mesh-gateway", Service: "mesh-gateway", Meta: map[string]string{structs.MetaWANFederationKey: "1"}, Port: port, }, } var out struct{} require.NoError(t, s1.RPC("Catalog.Register", &arg, &out)) } // Wait for it to make it into the gateway locator. retry.Run(t, func(r *retry.R) { require.NotEmpty(r, s1.gatewayLocator.PickGateway("dc1")) }) // Seed the secondaries with the address of the primary and wait for that to // be in their locators. s2.RefreshPrimaryGatewayFallbackAddresses([]string{gwAddr}) retry.Run(t, func(r *retry.R) { require.NotEmpty(r, s2.gatewayLocator.PickGateway("dc1")) }) s3.RefreshPrimaryGatewayFallbackAddresses([]string{gwAddr}) retry.Run(t, func(r *retry.R) { require.NotEmpty(r, s3.gatewayLocator.PickGateway("dc1")) }) // Try to join from secondary to primary. We can't use joinWAN() because we // are simulating proper bootstrapping and if ACLs were on we would have to // delay gateway registration in the secondary until after one directional // join. So this way we explicitly join secondary-to-primary as a standalone // operation and follow it up later with a full join. _, err := s2.JoinWAN([]string{joinAddrWAN(s1)}) require.NoError(t, err) retry.Run(t, func(r *retry.R) { if got, want := len(s2.WANMembers()), 2; got != want { r.Fatalf("got %d s2 WAN members want %d", got, want) } }) _, err = s3.JoinWAN([]string{joinAddrWAN(s1)}) require.NoError(t, err) retry.Run(t, func(r *retry.R) { if got, want := len(s3.WANMembers()), 3; got != want { r.Fatalf("got %d s3 WAN members want %d", got, want) } }) // Now we can register this into the catalog in dc2 and dc3. { arg := structs.RegisterRequest{ Datacenter: "dc2", Node: "betty", Address: "127.0.0.1", Service: &structs.NodeService{ Kind: structs.ServiceKindMeshGateway, ID: "mesh-gateway", Service: "mesh-gateway", Meta: map[string]string{structs.MetaWANFederationKey: "1"}, Port: port, }, } var out struct{} require.NoError(t, s2.RPC("Catalog.Register", &arg, &out)) } { arg := structs.RegisterRequest{ Datacenter: "dc3", Node: "bonnie", Address: "127.0.0.1", Service: &structs.NodeService{ Kind: structs.ServiceKindMeshGateway, ID: "mesh-gateway", Service: "mesh-gateway", Meta: map[string]string{structs.MetaWANFederationKey: "1"}, Port: port, }, } var out struct{} require.NoError(t, s3.RPC("Catalog.Register", &arg, &out)) } // Wait for it to make it into the gateway locator in dc2 and then for // AE to carry it back to the primary retry.Run(t, func(r *retry.R) { require.NotEmpty(r, s3.gatewayLocator.PickGateway("dc2")) require.NotEmpty(r, s2.gatewayLocator.PickGateway("dc2")) require.NotEmpty(r, s1.gatewayLocator.PickGateway("dc2")) require.NotEmpty(r, s3.gatewayLocator.PickGateway("dc3")) require.NotEmpty(r, s2.gatewayLocator.PickGateway("dc3")) require.NotEmpty(r, s1.gatewayLocator.PickGateway("dc3")) }) // Try to join again using the standard verification method now that // all of the plumbing is in place. joinWAN(t, s2, s1) retry.Run(t, func(r *retry.R) { if got, want := len(s1.WANMembers()), 3; got != want { r.Fatalf("got %d s1 WAN members want %d", got, want) } if got, want := len(s2.WANMembers()), 3; got != want { r.Fatalf("got %d s2 WAN members want %d", got, want) } }) // Check the router has all of them retry.Run(t, func(r *retry.R) { if got, want := len(s1.router.GetDatacenters()), 3; got != want { r.Fatalf("got %d routes want %d", got, want) } if got, want := len(s2.router.GetDatacenters()), 3; got != want { r.Fatalf("got %d datacenters want %d", got, want) } if got, want := len(s3.router.GetDatacenters()), 3; got != want { r.Fatalf("got %d datacenters want %d", got, want) } }) // Ensure we can do some trivial RPC in all directions. servers := map[string]*Server{"dc1": s1, "dc2": s2, "dc3": s3} names := map[string]string{"dc1": "bob", "dc2": "betty", "dc3": "bonnie"} for _, srcDC := range []string{"dc1", "dc2", "dc3"} { srv := servers[srcDC] for _, dstDC := range []string{"dc1", "dc2", "dc3"} { if srcDC == dstDC { continue } t.Run(srcDC+" to "+dstDC, func(t *testing.T) { arg := structs.DCSpecificRequest{ Datacenter: dstDC, } var out structs.IndexedNodes require.NoError(t, srv.RPC("Catalog.ListNodes", &arg, &out)) require.Len(t, out.Nodes, 1) node := out.Nodes[0] require.Equal(t, dstDC, node.Datacenter) require.Equal(t, names[dstDC], node.Node) }) } } } func TestServer_JoinSeparateLanAndWanAddresses(t *testing.T) { if testing.Short() { t.Skip("too slow for testing.Short") } t.Parallel() dir1, s1 := testServerWithConfig(t, func(c *Config) { c.NodeName = t.Name() + "-s1" c.Datacenter = "dc1" c.Bootstrap = true c.SerfFloodInterval = 100 * time.Millisecond }) defer os.RemoveAll(dir1) defer s1.Shutdown() s2Name := t.Name() + "-s2" dir2, s2 := testServerWithConfig(t, func(c *Config) { c.NodeName = s2Name c.Datacenter = "dc2" c.Bootstrap = false // This wan address will be expected to be seen on s1 c.SerfWANConfig.MemberlistConfig.AdvertiseAddr = "127.0.0.2" // This lan address will be expected to be seen on s3 c.SerfLANConfig.MemberlistConfig.AdvertiseAddr = "127.0.0.3" c.SerfFloodInterval = 100 * time.Millisecond }) defer os.RemoveAll(dir2) defer s2.Shutdown() dir3, s3 := testServerWithConfig(t, func(c *Config) { c.NodeName = t.Name() + "-s3" c.Datacenter = "dc2" c.Bootstrap = true c.SerfFloodInterval = 100 * time.Millisecond }) defer os.RemoveAll(dir3) defer s3.Shutdown() // Join s2 to s1 on wan joinWAN(t, s2, s1) // Join s3 to s2 on lan joinLAN(t, s3, s2) // We rely on flood joining to fill across the LAN, so we expect s3 to // show up on the WAN as well, even though it's not explicitly joined. retry.Run(t, func(r *retry.R) { if got, want := len(s1.WANMembers()), 3; got != want { r.Fatalf("got %d s1 WAN members want %d", got, want) } if got, want := len(s2.WANMembers()), 3; got != want { r.Fatalf("got %d s2 WAN members want %d", got, want) } if got, want := len(s2.LANMembersInAgentPartition()), 2; got != want { r.Fatalf("got %d s2 LAN members want %d", got, want) } if got, want := len(s3.LANMembersInAgentPartition()), 2; got != want { r.Fatalf("got %d s3 LAN members want %d", got, want) } }) // Check the router has both retry.Run(t, func(r *retry.R) { if len(s1.router.GetDatacenters()) != 2 { r.Fatalf("remote consul missing") } if len(s2.router.GetDatacenters()) != 2 { r.Fatalf("remote consul missing") } if len(s2.serverLookup.Servers()) != 2 { r.Fatalf("local consul fellow s3 for s2 missing") } }) // Get and check the wan address of s2 from s1 var s2WanAddr string for _, member := range s1.WANMembers() { if member.Name == s2Name+".dc2" { s2WanAddr = member.Addr.String() } } if s2WanAddr != "127.0.0.2" { t.Fatalf("s1 sees s2 on a wrong address: %s, expecting: %s", s2WanAddr, "127.0.0.2") } // Get and check the lan address of s2 from s3 var s2LanAddr string for _, lanmember := range s3.LANMembersInAgentPartition() { if lanmember.Name == s2Name { s2LanAddr = lanmember.Addr.String() } } if s2LanAddr != "127.0.0.3" { t.Fatalf("s3 sees s2 on a wrong address: %s, expecting: %s", s2LanAddr, "127.0.0.3") } } func TestServer_LeaveLeader(t *testing.T) { if testing.Short() { t.Skip("too slow for testing.Short") } t.Parallel() dir1, s1 := testServer(t) defer os.RemoveAll(dir1) defer s1.Shutdown() dir2, s2 := testServerDCBootstrap(t, "dc1", false) defer os.RemoveAll(dir2) defer s2.Shutdown() dir3, s3 := testServerDCBootstrap(t, "dc1", false) defer os.RemoveAll(dir3) defer s3.Shutdown() testrpc.WaitForLeader(t, s1.RPC, "dc1") joinLAN(t, s2, s1) joinLAN(t, s3, s1) retry.Run(t, func(r *retry.R) { r.Check(wantPeers(s1, 3)) r.Check(wantPeers(s2, 3)) r.Check(wantPeers(s3, 3)) }) // Issue a leave to the leader var leader *Server switch { case s1.IsLeader(): leader = s1 case s2.IsLeader(): leader = s2 case s3.IsLeader(): leader = s3 default: t.Fatal("no leader") } if err := leader.Leave(); err != nil { t.Fatal("leave failed: ", err) } // Should lose a peer retry.Run(t, func(r *retry.R) { r.Check(wantPeers(s1, 2)) r.Check(wantPeers(s2, 2)) r.Check(wantPeers(s3, 2)) }) } func TestServer_Leave(t *testing.T) { if testing.Short() { t.Skip("too slow for testing.Short") } t.Parallel() dir1, s1 := testServer(t) defer os.RemoveAll(dir1) defer s1.Shutdown() // Second server not in bootstrap mode dir2, s2 := testServerDCBootstrap(t, "dc1", false) defer os.RemoveAll(dir2) defer s2.Shutdown() // Try to join joinLAN(t, s2, s1) testrpc.WaitForLeader(t, s1.RPC, "dc1") testrpc.WaitForLeader(t, s2.RPC, "dc1") // Issue a leave to the non-leader var nonleader *Server switch { case s1.IsLeader(): nonleader = s2 case s2.IsLeader(): nonleader = s1 default: t.Fatal("no leader") } if err := nonleader.Leave(); err != nil { t.Fatal("leave failed: ", err) } // Should lose a peer retry.Run(t, func(r *retry.R) { r.Check(wantPeers(s1, 1)) r.Check(wantPeers(s2, 1)) }) } func TestServer_RPC(t *testing.T) { t.Parallel() dir1, s1 := testServer(t) defer os.RemoveAll(dir1) defer s1.Shutdown() var out struct{} if err := s1.RPC("Status.Ping", struct{}{}, &out); err != nil { t.Fatalf("err: %v", err) } } // TestServer_RPC_MetricsIntercept_Off proves that we can turn off net/rpc interceptors all together. func TestServer_RPC_MetricsIntercept_Off(t *testing.T) { if testing.Short() { t.Skip("too slow for testing.Short") } storage := &sync.Map{} // string -> float32 keyMakingFunc := func(key []string, labels []metrics.Label) string { allKey := strings.Join(key, "+") for _, label := range labels { if label.Name == "method" { allKey = allKey + "+" + label.Value } } return allKey } simpleRecorderFunc := func(key []string, val float32, labels []metrics.Label) { storage.Store(keyMakingFunc(key, labels), val) } t.Run("test no net/rpc interceptor metric with nil func", func(t *testing.T) { _, conf := testServerConfig(t) deps := newDefaultDeps(t, conf) // "disable" metrics net/rpc interceptor deps.GetNetRPCInterceptorFunc = nil // "hijack" the rpc recorder for asserts; // note that there will be "internal" net/rpc calls made // that will still show up; those don't go thru the net/rpc interceptor; // see consul.agent.rpc.middleware.RPCTypeInternal for context deps.NewRequestRecorderFunc = func(logger hclog.Logger, isLeader func() bool, localDC string) *middleware.RequestRecorder { // for the purposes of this test, we don't need isLeader or localDC return &middleware.RequestRecorder{ Logger: hclog.NewInterceptLogger(&hclog.LoggerOptions{}), RecorderFunc: simpleRecorderFunc, } } s1, err := NewServer(conf, deps, grpc.NewServer()) if err != nil { t.Fatalf("err: %v", err) } t.Cleanup(func() { s1.Shutdown() }) var out struct{} if err := s1.RPC("Status.Ping", struct{}{}, &out); err != nil { t.Fatalf("err: %v", err) } key := keyMakingFunc(middleware.OneTwelveRPCSummary[0].Name, []metrics.Label{{Name: "method", Value: "Status.Ping"}}) if _, ok := storage.Load(key); ok { t.Fatalf("Did not expect to find key %s in the metrics log, ", key) } }) t.Run("test no net/rpc interceptor metric with func that gives nil", func(t *testing.T) { _, conf := testServerConfig(t) deps := newDefaultDeps(t, conf) // "hijack" the rpc recorder for asserts; // note that there will be "internal" net/rpc calls made // that will still show up; those don't go thru the net/rpc interceptor; // see consul.agent.rpc.middleware.RPCTypeInternal for context deps.NewRequestRecorderFunc = func(logger hclog.Logger, isLeader func() bool, localDC string) *middleware.RequestRecorder { // for the purposes of this test, we don't need isLeader or localDC return &middleware.RequestRecorder{ Logger: hclog.NewInterceptLogger(&hclog.LoggerOptions{}), RecorderFunc: simpleRecorderFunc, } } deps.GetNetRPCInterceptorFunc = func(recorder *middleware.RequestRecorder) rpc.ServerServiceCallInterceptor { return nil } s2, err := NewServer(conf, deps, grpc.NewServer()) if err != nil { t.Fatalf("err: %v", err) } t.Cleanup(func() { s2.Shutdown() }) if err != nil { t.Fatalf("err: %v", err) } var out struct{} if err := s2.RPC("Status.Ping", struct{}{}, &out); err != nil { t.Fatalf("err: %v", err) } key := keyMakingFunc(middleware.OneTwelveRPCSummary[0].Name, []metrics.Label{{Name: "method", Value: "Status.Ping"}}) if _, ok := storage.Load(key); ok { t.Fatalf("Did not expect to find key %s in the metrics log, ", key) } }) } // TestServer_RPC_RequestRecorder proves that we cannot make a server without a valid RequestRecorder provider func // or a non nil RequestRecorder. func TestServer_RPC_RequestRecorder(t *testing.T) { if testing.Short() { t.Skip("too slow for testing.Short") } t.Run("test nil func provider", func(t *testing.T) { _, conf := testServerConfig(t) deps := newDefaultDeps(t, conf) deps.NewRequestRecorderFunc = nil s1, err := NewServer(conf, deps, grpc.NewServer()) require.Error(t, err, "need err when provider func is nil") require.Equal(t, err.Error(), "cannot initialize server without an RPC request recorder provider") t.Cleanup(func() { if s1 != nil { s1.Shutdown() } }) }) t.Run("test nil RequestRecorder", func(t *testing.T) { _, conf := testServerConfig(t) deps := newDefaultDeps(t, conf) deps.NewRequestRecorderFunc = func(logger hclog.Logger, isLeader func() bool, localDC string) *middleware.RequestRecorder { return nil } s2, err := NewServer(conf, deps, grpc.NewServer()) require.Error(t, err, "need err when RequestRecorder is nil") require.Equal(t, err.Error(), "cannot initialize server with a nil RPC request recorder") t.Cleanup(func() { if s2 != nil { s2.Shutdown() } }) }) } // TestServer_RPC_MetricsIntercept mocks a request recorder and asserts that RPC calls are observed. func TestServer_RPC_MetricsIntercept(t *testing.T) { if testing.Short() { t.Skip("too slow for testing.Short") } _, conf := testServerConfig(t) deps := newDefaultDeps(t, conf) // The method used to record metric observations here is similar to that used in // interceptors_test.go. storage := &sync.Map{} // string -> float32 keyMakingFunc := func(key []string, labels []metrics.Label) string { allKey := strings.Join(key, "+") for _, label := range labels { allKey = allKey + "+" + label.Value } return allKey } simpleRecorderFunc := func(key []string, val float32, labels []metrics.Label) { storage.Store(keyMakingFunc(key, labels), val) } deps.NewRequestRecorderFunc = func(logger hclog.Logger, isLeader func() bool, localDC string) *middleware.RequestRecorder { // for the purposes of this test, we don't need isLeader or localDC return &middleware.RequestRecorder{ Logger: hclog.NewInterceptLogger(&hclog.LoggerOptions{}), RecorderFunc: simpleRecorderFunc, } } deps.GetNetRPCInterceptorFunc = func(recorder *middleware.RequestRecorder) rpc.ServerServiceCallInterceptor { return func(reqServiceMethod string, argv, replyv reflect.Value, handler func() error) { reqStart := time.Now() err := handler() recorder.Record(reqServiceMethod, "test", reqStart, argv.Interface(), err != nil) } } s, err := newServerWithDeps(t, conf, deps) if err != nil { t.Fatalf("err: %v", err) } defer s.Shutdown() testrpc.WaitForTestAgent(t, s.RPC, "dc1") // asserts t.Run("test happy path for metrics interceptor", func(t *testing.T) { var out struct{} if err := s.RPC("Status.Ping", struct{}{}, &out); err != nil { t.Fatalf("err: %v", err) } expectedLabels := []metrics.Label{ {Name: "method", Value: "Status.Ping"}, {Name: "errored", Value: "false"}, {Name: "request_type", Value: "read"}, {Name: "rpc_type", Value: "test"}, {Name: "server_role", Value: "unreported"}, } key := keyMakingFunc(middleware.OneTwelveRPCSummary[0].Name, expectedLabels) if _, ok := storage.Load(key); !ok { // the compound key will look like: "rpc+server+call+Status.Ping+false+read+test+unreported" t.Fatalf("Did not find key %s in the metrics log, ", key) } }) } func TestServer_JoinLAN_TLS(t *testing.T) { if testing.Short() { t.Skip("too slow for testing.Short") } t.Parallel() _, conf1 := testServerConfig(t) conf1.TLSConfig.InternalRPC.VerifyIncoming = true conf1.TLSConfig.InternalRPC.VerifyOutgoing = true configureTLS(conf1) s1, err := newServer(t, conf1) if err != nil { t.Fatalf("err: %v", err) } defer s1.Shutdown() testrpc.WaitForTestAgent(t, s1.RPC, "dc1") _, conf2 := testServerConfig(t) conf2.Bootstrap = false conf2.TLSConfig.InternalRPC.VerifyIncoming = true conf2.TLSConfig.InternalRPC.VerifyOutgoing = true configureTLS(conf2) s2, err := newServer(t, conf2) if err != nil { t.Fatalf("err: %v", err) } defer s2.Shutdown() // Try to join joinLAN(t, s2, s1) testrpc.WaitForTestAgent(t, s2.RPC, "dc1") // Verify Raft has established a peer retry.Run(t, func(r *retry.R) { r.Check(wantRaft([]*Server{s1, s2})) }) } func TestServer_Expect(t *testing.T) { if testing.Short() { t.Skip("too slow for testing.Short") } // All test servers should be in expect=3 mode, except for the 3rd one, // but one with expect=0 can cause a bootstrap to occur from the other // servers as currently implemented. dir1, s1 := testServerDCExpect(t, "dc1", 3) defer os.RemoveAll(dir1) defer s1.Shutdown() dir2, s2 := testServerDCExpect(t, "dc1", 3) defer os.RemoveAll(dir2) defer s2.Shutdown() dir3, s3 := testServerDCExpect(t, "dc1", 0) defer os.RemoveAll(dir3) defer s3.Shutdown() dir4, s4 := testServerDCExpect(t, "dc1", 3) defer os.RemoveAll(dir4) defer s4.Shutdown() // Join the first two servers. joinLAN(t, s2, s1) // Should have no peers yet since the bootstrap didn't occur. retry.Run(t, func(r *retry.R) { r.Check(wantPeers(s1, 0)) r.Check(wantPeers(s2, 0)) }) // Join the third node. joinLAN(t, s3, s1) // Now we have three servers so we should bootstrap. retry.Run(t, func(r *retry.R) { r.Check(wantPeers(s1, 3)) r.Check(wantPeers(s2, 3)) r.Check(wantPeers(s3, 3)) }) // Join the fourth node. joinLAN(t, s4, s1) // Wait for the new server to see itself added to the cluster. retry.Run(t, func(r *retry.R) { r.Check(wantRaft([]*Server{s1, s2, s3, s4})) }) } // Should not trigger bootstrap and new election when s3 joins, since cluster exists func TestServer_AvoidReBootstrap(t *testing.T) { if testing.Short() { t.Skip("too slow for testing.Short") } dir1, s1 := testServerDCExpect(t, "dc1", 2) defer os.RemoveAll(dir1) defer s1.Shutdown() dir2, s2 := testServerDCExpect(t, "dc1", 0) defer os.RemoveAll(dir2) defer s2.Shutdown() dir3, s3 := testServerDCExpect(t, "dc1", 2) defer os.RemoveAll(dir3) defer s3.Shutdown() // Join the first two servers joinLAN(t, s2, s1) // Make sure a leader is elected, grab the current term and then add in // the third server. testrpc.WaitForLeader(t, s1.RPC, "dc1") termBefore := s1.raft.Stats()["last_log_term"] joinLAN(t, s3, s1) // Wait for the new server to see itself added to the cluster. retry.Run(t, func(r *retry.R) { r.Check(wantRaft([]*Server{s1, s2, s3})) }) // Make sure there's still a leader and that the term didn't change, // so we know an election didn't occur. testrpc.WaitForLeader(t, s1.RPC, "dc1") termAfter := s1.raft.Stats()["last_log_term"] if termAfter != termBefore { t.Fatalf("looks like an election took place") } } func TestServer_Expect_NonVoters(t *testing.T) { if testing.Short() { t.Skip("too slow for testing.Short") } t.Parallel() dir1, s1 := testServerWithConfig(t, func(c *Config) { c.Bootstrap = false c.BootstrapExpect = 2 c.ReadReplica = true }) defer os.RemoveAll(dir1) defer s1.Shutdown() dir2, s2 := testServerDCExpect(t, "dc1", 2) defer os.RemoveAll(dir2) defer s2.Shutdown() dir3, s3 := testServerDCExpect(t, "dc1", 2) defer os.RemoveAll(dir3) defer s3.Shutdown() // Join the first two servers. joinLAN(t, s2, s1) // Should have no peers yet since the bootstrap didn't occur. retry.Run(t, func(r *retry.R) { r.Check(wantPeers(s1, 0)) r.Check(wantPeers(s2, 0)) }) // Join the third node. joinLAN(t, s3, s1) // Now we have three servers so we should bootstrap. retry.Run(t, func(r *retry.R) { r.Check(wantPeers(s1, 2)) r.Check(wantPeers(s2, 2)) r.Check(wantPeers(s3, 2)) }) // Make sure a leader is elected testrpc.WaitForLeader(t, s1.RPC, "dc1") retry.Run(t, func(r *retry.R) { r.Check(wantRaft([]*Server{s1, s2, s3})) }) } func TestServer_BadExpect(t *testing.T) { t.Parallel() // this one is in expect=3 mode dir1, s1 := testServerDCExpect(t, "dc1", 3) defer os.RemoveAll(dir1) defer s1.Shutdown() // this one is in expect=2 mode dir2, s2 := testServerDCExpect(t, "dc1", 2) defer os.RemoveAll(dir2) defer s2.Shutdown() // and this one is in expect=3 mode dir3, s3 := testServerDCExpect(t, "dc1", 3) defer os.RemoveAll(dir3) defer s3.Shutdown() // Try to join joinLAN(t, s2, s1) // should have no peers yet retry.Run(t, func(r *retry.R) { r.Check(wantPeers(s1, 0)) r.Check(wantPeers(s2, 0)) }) // join the third node joinLAN(t, s3, s1) // should still have no peers (because s2 is in expect=2 mode) retry.Run(t, func(r *retry.R) { r.Check(wantPeers(s1, 0)) r.Check(wantPeers(s2, 0)) r.Check(wantPeers(s3, 0)) }) } type fakeGlobalResp struct{} func (r *fakeGlobalResp) Add(interface{}) { } func (r *fakeGlobalResp) New() interface{} { return struct{}{} } func TestServer_keyringRPCs(t *testing.T) { t.Parallel() dir1, s1 := testServerDC(t, "dc1") defer os.RemoveAll(dir1) defer s1.Shutdown() retry.Run(t, func(r *retry.R) { if len(s1.router.GetDatacenters()) != 1 { r.Fatal(nil) } }) // Check that an error from a remote DC is returned _, err := s1.keyringRPCs("Bad.Method", nil, []string{s1.config.Datacenter}) if err == nil { t.Fatalf("should have errored") } if !strings.Contains(err.Error(), "Bad.Method") { t.Fatalf("unexpected error: %s", err) } } func testVerifyRPC(s1, s2 *Server, t *testing.T) (bool, error) { joinLAN(t, s1, s2) retry.Run(t, func(r *retry.R) { r.Check(wantRaft([]*Server{s1, s2})) }) // Have s2 make an RPC call to s1 var leader *metadata.Server for _, server := range s2.serverLookup.Servers() { if server.Name == s1.config.NodeName { leader = server } } if leader == nil { t.Fatal("no leader") } return s2.connPool.Ping(leader.Datacenter, leader.ShortName, leader.Addr) } func TestServer_TLSToNoTLS(t *testing.T) { if testing.Short() { t.Skip("too slow for testing.Short") } t.Parallel() // Set up a server with no TLS configured dir1, s1 := testServer(t) defer os.RemoveAll(dir1) defer s1.Shutdown() testrpc.WaitForLeader(t, s1.RPC, "dc1") // Add a second server with TLS configured dir2, s2 := testServerWithConfig(t, func(c *Config) { c.Bootstrap = false c.TLSConfig.InternalRPC.CAFile = "../../test/client_certs/rootca.crt" c.TLSConfig.InternalRPC.CertFile = "../../test/client_certs/server.crt" c.TLSConfig.InternalRPC.KeyFile = "../../test/client_certs/server.key" }) defer os.RemoveAll(dir2) defer s2.Shutdown() success, err := testVerifyRPC(s1, s2, t) if err != nil { t.Fatal(err) } if !success { t.Fatalf("bad: %v", success) } } func TestServer_TLSForceOutgoingToNoTLS(t *testing.T) { if testing.Short() { t.Skip("too slow for testing.Short") } t.Parallel() // Set up a server with no TLS configured dir1, s1 := testServer(t) defer os.RemoveAll(dir1) defer s1.Shutdown() testrpc.WaitForLeader(t, s1.RPC, "dc1") // Add a second server with TLS and VerifyOutgoing set dir2, s2 := testServerWithConfig(t, func(c *Config) { c.Bootstrap = false c.TLSConfig.InternalRPC.CAFile = "../../test/client_certs/rootca.crt" c.TLSConfig.InternalRPC.CertFile = "../../test/client_certs/server.crt" c.TLSConfig.InternalRPC.KeyFile = "../../test/client_certs/server.key" c.TLSConfig.InternalRPC.VerifyOutgoing = true }) defer os.RemoveAll(dir2) defer s2.Shutdown() _, err := testVerifyRPC(s1, s2, t) if err == nil || !strings.Contains(err.Error(), "remote error: tls") { t.Fatalf("should fail") } } func TestServer_TLSToFullVerify(t *testing.T) { if testing.Short() { t.Skip("too slow for testing.Short") } t.Parallel() // Set up a server with TLS and VerifyIncoming set dir1, s1 := testServerWithConfig(t, func(c *Config) { c.TLSConfig.InternalRPC.CAFile = "../../test/client_certs/rootca.crt" c.TLSConfig.InternalRPC.CertFile = "../../test/client_certs/server.crt" c.TLSConfig.InternalRPC.KeyFile = "../../test/client_certs/server.key" c.TLSConfig.InternalRPC.VerifyOutgoing = true }) defer os.RemoveAll(dir1) defer s1.Shutdown() testrpc.WaitForLeader(t, s1.RPC, "dc1") // Add a second server with TLS configured dir2, s2 := testServerWithConfig(t, func(c *Config) { c.Bootstrap = false c.TLSConfig.InternalRPC.CAFile = "../../test/client_certs/rootca.crt" c.TLSConfig.InternalRPC.CertFile = "../../test/client_certs/server.crt" c.TLSConfig.InternalRPC.KeyFile = "../../test/client_certs/server.key" }) defer os.RemoveAll(dir2) defer s2.Shutdown() success, err := testVerifyRPC(s1, s2, t) if err != nil { t.Fatal(err) } if !success { t.Fatalf("bad: %v", success) } } func TestServer_RevokeLeadershipIdempotent(t *testing.T) { if testing.Short() { t.Skip("too slow for testing.Short") } t.Parallel() dir1, s1 := testServer(t) defer os.RemoveAll(dir1) defer s1.Shutdown() testrpc.WaitForLeader(t, s1.RPC, "dc1") s1.revokeLeadership() s1.revokeLeadership() } func TestServer_ReloadConfig(t *testing.T) { if testing.Short() { t.Skip("too slow for testing.Short") } t.Parallel() entryInit := &structs.ProxyConfigEntry{ Kind: structs.ProxyDefaults, Name: structs.ProxyConfigGlobal, Config: map[string]interface{}{ // these are made a []uint8 and a int64 to allow the Equals test to pass // otherwise it will fail complaining about data types "foo": "bar", "bar": int64(1), }, } dir1, s := testServerWithConfig(t, func(c *Config) { c.Build = "1.5.0" c.RPCRateLimit = 500 c.RPCMaxBurst = 5000 // Set one raft param to be non-default in the initial config, others are // default. c.RaftConfig.TrailingLogs = 1234 }) defer os.RemoveAll(dir1) defer s.Shutdown() testrpc.WaitForTestAgent(t, s.RPC, "dc1") limiter := s.rpcLimiter.Load().(*rate.Limiter) require.Equal(t, rate.Limit(500), limiter.Limit()) require.Equal(t, 5000, limiter.Burst()) rc := ReloadableConfig{ RPCRateLimit: 1000, RPCMaxBurst: 10000, ConfigEntryBootstrap: []structs.ConfigEntry{entryInit}, // Reset the custom one to default be removing it from config file (it will // be a zero value here). RaftTrailingLogs: 0, // Set a different Raft param to something custom now RaftSnapshotThreshold: 4321, // Leave other raft fields default } require.NoError(t, s.ReloadConfig(rc)) _, entry, err := s.fsm.State().ConfigEntry(nil, structs.ProxyDefaults, structs.ProxyConfigGlobal, structs.DefaultEnterpriseMetaInDefaultPartition()) require.NoError(t, err) require.NotNil(t, entry) global, ok := entry.(*structs.ProxyConfigEntry) require.True(t, ok) require.Equal(t, entryInit.Kind, global.Kind) require.Equal(t, entryInit.Name, global.Name) require.Equal(t, entryInit.Config, global.Config) // Check rate limiter got updated limiter = s.rpcLimiter.Load().(*rate.Limiter) require.Equal(t, rate.Limit(1000), limiter.Limit()) require.Equal(t, 10000, limiter.Burst()) // Check raft config defaults := DefaultConfig() got := s.raft.ReloadableConfig() require.Equal(t, uint64(4321), got.SnapshotThreshold, "should have be reloaded to new value") require.Equal(t, defaults.RaftConfig.SnapshotInterval, got.SnapshotInterval, "should have remained the default interval") require.Equal(t, defaults.RaftConfig.TrailingLogs, got.TrailingLogs, "should have reloaded to default trailing_logs") // Now check that update each of those raft fields separately works correctly // too. } func TestServer_computeRaftReloadableConfig(t *testing.T) { defaults := DefaultConfig().RaftConfig cases := []struct { name string rc ReloadableConfig want raft.ReloadableConfig }{ { // This case is the common path - reload is called with a ReloadableConfig // populated from the RuntimeConfig which has zero values for the fields. // On startup we selectively pick non-zero runtime config fields to // override defaults so we need to do the same. name: "Still defaults", rc: ReloadableConfig{}, want: raft.ReloadableConfig{ SnapshotThreshold: defaults.SnapshotThreshold, SnapshotInterval: defaults.SnapshotInterval, TrailingLogs: defaults.TrailingLogs, ElectionTimeout: defaults.ElectionTimeout, HeartbeatTimeout: defaults.HeartbeatTimeout, }, }, { name: "Threshold set", rc: ReloadableConfig{ RaftSnapshotThreshold: 123456, }, want: raft.ReloadableConfig{ SnapshotThreshold: 123456, SnapshotInterval: defaults.SnapshotInterval, TrailingLogs: defaults.TrailingLogs, ElectionTimeout: defaults.ElectionTimeout, HeartbeatTimeout: defaults.HeartbeatTimeout, }, }, { name: "interval set", rc: ReloadableConfig{ RaftSnapshotInterval: 13 * time.Minute, }, want: raft.ReloadableConfig{ SnapshotThreshold: defaults.SnapshotThreshold, SnapshotInterval: 13 * time.Minute, TrailingLogs: defaults.TrailingLogs, ElectionTimeout: defaults.ElectionTimeout, HeartbeatTimeout: defaults.HeartbeatTimeout, }, }, { name: "trailing logs set", rc: ReloadableConfig{ RaftTrailingLogs: 78910, }, want: raft.ReloadableConfig{ SnapshotThreshold: defaults.SnapshotThreshold, SnapshotInterval: defaults.SnapshotInterval, TrailingLogs: 78910, ElectionTimeout: defaults.ElectionTimeout, HeartbeatTimeout: defaults.HeartbeatTimeout, }, }, { name: "all set", rc: ReloadableConfig{ RaftSnapshotThreshold: 123456, RaftSnapshotInterval: 13 * time.Minute, RaftTrailingLogs: 78910, ElectionTimeout: 300 * time.Millisecond, HeartbeatTimeout: 400 * time.Millisecond, }, want: raft.ReloadableConfig{ SnapshotThreshold: 123456, SnapshotInterval: 13 * time.Minute, TrailingLogs: 78910, ElectionTimeout: 300 * time.Millisecond, HeartbeatTimeout: 400 * time.Millisecond, }, }, } for _, tc := range cases { tc := tc t.Run(tc.name, func(t *testing.T) { got := computeRaftReloadableConfig(tc.rc) require.Equal(t, tc.want, got) }) } } func TestServer_RPC_RateLimit(t *testing.T) { if testing.Short() { t.Skip("too slow for testing.Short") } t.Parallel() _, conf1 := testServerConfig(t) conf1.RPCRateLimit = 2 conf1.RPCMaxBurst = 2 s1, err := newServer(t, conf1) if err != nil { t.Fatalf("err: %v", err) } defer s1.Shutdown() testrpc.WaitForLeader(t, s1.RPC, "dc1") retry.Run(t, func(r *retry.R) { var out struct{} if err := s1.RPC("Status.Ping", struct{}{}, &out); err != structs.ErrRPCRateExceeded { r.Fatalf("err: %v", err) } }) } // TestServer_Peering_LeadershipCheck tests that a peering service can receive the leader address // through the LeaderAddress IRL. func TestServer_Peering_LeadershipCheck(t *testing.T) { if testing.Short() { t.Skip("too slow for testing.Short") } t.Parallel() // given two servers: s1 (leader), s2 (follower) _, conf1 := testServerConfig(t) s1, err := newServer(t, conf1) if err != nil { t.Fatalf("err: %v", err) } defer s1.Shutdown() _, conf2 := testServerConfig(t) conf2.Bootstrap = false s2, err := newServer(t, conf2) if err != nil { t.Fatalf("err: %v", err) } defer s2.Shutdown() // Try to join joinLAN(t, s2, s1) // Verify Raft has established a peer retry.Run(t, func(r *retry.R) { r.Check(wantRaft([]*Server{s1, s2})) }) testrpc.WaitForLeader(t, s1.RPC, "dc1") testrpc.WaitForLeader(t, s2.RPC, "dc1") waitForLeaderEstablishment(t, s1) // the actual tests // when leadership has been established s2 should have the address of s1 // in the peering service peeringLeaderAddr := s2.peeringBackend.GetLeaderAddress() require.Equal(t, s1.config.RPCAddr.String(), peeringLeaderAddr) // test corollary by transitivity to future-proof against any setup bugs require.NotEqual(t, s2.config.RPCAddr.String(), peeringLeaderAddr) }