/* * * Copyright 2014, Google Inc. * All rights reserved. * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions are * met: * * * Redistributions of source code must retain the above copyright * notice, this list of conditions and the following disclaimer. * * Redistributions in binary form must reproduce the above * copyright notice, this list of conditions and the following disclaimer * in the documentation and/or other materials provided with the * distribution. * * Neither the name of Google Inc. nor the names of its * contributors may be used to endorse or promote products derived from * this software without specific prior written permission. * * THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS * "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT * LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR * A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT * OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, * SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT * LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, * DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY * THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT * (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE * OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. * */ package grpc_test import ( "bytes" "crypto/tls" "errors" "flag" "fmt" "io" "log" "math" "net" "os" "reflect" "runtime" "sort" "strings" "sync" "syscall" "testing" "time" "github.com/golang/protobuf/proto" "golang.org/x/net/context" "golang.org/x/net/http2" "google.golang.org/grpc" "google.golang.org/grpc/codes" "google.golang.org/grpc/credentials" "google.golang.org/grpc/grpclog" "google.golang.org/grpc/health" healthpb "google.golang.org/grpc/health/grpc_health_v1" "google.golang.org/grpc/internal" "google.golang.org/grpc/metadata" "google.golang.org/grpc/peer" "google.golang.org/grpc/tap" testpb "google.golang.org/grpc/test/grpc_testing" ) var ( // For headers: testMetadata = metadata.MD{ "key1": []string{"value1"}, "key2": []string{"value2"}, } testMetadata2 = metadata.MD{ "key1": []string{"value12"}, "key2": []string{"value22"}, } // For trailers: testTrailerMetadata = metadata.MD{ "tkey1": []string{"trailerValue1"}, "tkey2": []string{"trailerValue2"}, } testTrailerMetadata2 = metadata.MD{ "tkey1": []string{"trailerValue12"}, "tkey2": []string{"trailerValue22"}, } // capital "Key" is illegal in HTTP/2. malformedHTTP2Metadata = metadata.MD{ "Key": []string{"foo"}, } testAppUA = "myApp1/1.0 myApp2/0.9" ) var raceMode bool // set by race_test.go in race mode type testServer struct { security string // indicate the authentication protocol used by this server. earlyFail bool // whether to error out the execution of a service handler prematurely. setAndSendHeader bool // whether to call setHeader and sendHeader. setHeaderOnly bool // whether to only call setHeader, not sendHeader. multipleSetTrailer bool // whether to call setTrailer multiple times. } func (s *testServer) EmptyCall(ctx context.Context, in *testpb.Empty) (*testpb.Empty, error) { if md, ok := metadata.FromContext(ctx); ok { // For testing purpose, returns an error if there is attached metadata other than // the user agent set by the client application. if _, ok := md["user-agent"]; !ok { return nil, grpc.Errorf(codes.DataLoss, "missing expected user-agent") } var str []string for _, entry := range md["user-agent"] { str = append(str, "ua", entry) } grpc.SendHeader(ctx, metadata.Pairs(str...)) } return new(testpb.Empty), nil } func newPayload(t testpb.PayloadType, size int32) (*testpb.Payload, error) { if size < 0 { return nil, fmt.Errorf("Requested a response with invalid length %d", size) } body := make([]byte, size) switch t { case testpb.PayloadType_COMPRESSABLE: case testpb.PayloadType_UNCOMPRESSABLE: return nil, fmt.Errorf("PayloadType UNCOMPRESSABLE is not supported") default: return nil, fmt.Errorf("Unsupported payload type: %d", t) } return &testpb.Payload{ Type: t.Enum(), Body: body, }, nil } func (s *testServer) UnaryCall(ctx context.Context, in *testpb.SimpleRequest) (*testpb.SimpleResponse, error) { md, ok := metadata.FromContext(ctx) if ok { if _, exists := md[":authority"]; !exists { return nil, grpc.Errorf(codes.DataLoss, "expected an :authority metadata: %v", md) } if s.setAndSendHeader { if err := grpc.SetHeader(ctx, md); err != nil { return nil, grpc.Errorf(grpc.Code(err), "grpc.SetHeader(_, %v) = %v, want ", md, err) } if err := grpc.SendHeader(ctx, testMetadata2); err != nil { return nil, grpc.Errorf(grpc.Code(err), "grpc.SendHeader(_, %v) = %v, want ", testMetadata2, err) } } else if s.setHeaderOnly { if err := grpc.SetHeader(ctx, md); err != nil { return nil, grpc.Errorf(grpc.Code(err), "grpc.SetHeader(_, %v) = %v, want ", md, err) } if err := grpc.SetHeader(ctx, testMetadata2); err != nil { return nil, grpc.Errorf(grpc.Code(err), "grpc.SetHeader(_, %v) = %v, want ", testMetadata2, err) } } else { if err := grpc.SendHeader(ctx, md); err != nil { return nil, grpc.Errorf(grpc.Code(err), "grpc.SendHeader(_, %v) = %v, want ", md, err) } } if err := grpc.SetTrailer(ctx, testTrailerMetadata); err != nil { return nil, grpc.Errorf(grpc.Code(err), "grpc.SetTrailer(_, %v) = %v, want ", testTrailerMetadata, err) } if s.multipleSetTrailer { if err := grpc.SetTrailer(ctx, testTrailerMetadata2); err != nil { return nil, grpc.Errorf(grpc.Code(err), "grpc.SetTrailer(_, %v) = %v, want ", testTrailerMetadata2, err) } } } pr, ok := peer.FromContext(ctx) if !ok { return nil, grpc.Errorf(codes.DataLoss, "failed to get peer from ctx") } if pr.Addr == net.Addr(nil) { return nil, grpc.Errorf(codes.DataLoss, "failed to get peer address") } if s.security != "" { // Check Auth info var authType, serverName string switch info := pr.AuthInfo.(type) { case credentials.TLSInfo: authType = info.AuthType() serverName = info.State.ServerName default: return nil, grpc.Errorf(codes.Unauthenticated, "Unknown AuthInfo type") } if authType != s.security { return nil, grpc.Errorf(codes.Unauthenticated, "Wrong auth type: got %q, want %q", authType, s.security) } if serverName != "x.test.youtube.com" { return nil, grpc.Errorf(codes.Unauthenticated, "Unknown server name %q", serverName) } } // Simulate some service delay. time.Sleep(time.Second) payload, err := newPayload(in.GetResponseType(), in.GetResponseSize()) if err != nil { return nil, err } return &testpb.SimpleResponse{ Payload: payload, }, nil } func (s *testServer) StreamingOutputCall(args *testpb.StreamingOutputCallRequest, stream testpb.TestService_StreamingOutputCallServer) error { if md, ok := metadata.FromContext(stream.Context()); ok { if _, exists := md[":authority"]; !exists { return grpc.Errorf(codes.DataLoss, "expected an :authority metadata: %v", md) } // For testing purpose, returns an error if there is attached metadata except for authority. if len(md) > 1 { return grpc.Errorf(codes.DataLoss, "got extra metadata") } } cs := args.GetResponseParameters() for _, c := range cs { if us := c.GetIntervalUs(); us > 0 { time.Sleep(time.Duration(us) * time.Microsecond) } payload, err := newPayload(args.GetResponseType(), c.GetSize()) if err != nil { return err } if err := stream.Send(&testpb.StreamingOutputCallResponse{ Payload: payload, }); err != nil { return err } } return nil } func (s *testServer) StreamingInputCall(stream testpb.TestService_StreamingInputCallServer) error { var sum int for { in, err := stream.Recv() if err == io.EOF { return stream.SendAndClose(&testpb.StreamingInputCallResponse{ AggregatedPayloadSize: proto.Int32(int32(sum)), }) } if err != nil { return err } p := in.GetPayload().GetBody() sum += len(p) if s.earlyFail { return grpc.Errorf(codes.NotFound, "not found") } } } func (s *testServer) FullDuplexCall(stream testpb.TestService_FullDuplexCallServer) error { md, ok := metadata.FromContext(stream.Context()) if ok { if s.setAndSendHeader { if err := stream.SetHeader(md); err != nil { return grpc.Errorf(grpc.Code(err), "%v.SetHeader(_, %v) = %v, want ", stream, md, err) } if err := stream.SendHeader(testMetadata2); err != nil { return grpc.Errorf(grpc.Code(err), "%v.SendHeader(_, %v) = %v, want ", stream, testMetadata2, err) } } else if s.setHeaderOnly { if err := stream.SetHeader(md); err != nil { return grpc.Errorf(grpc.Code(err), "%v.SetHeader(_, %v) = %v, want ", stream, md, err) } if err := stream.SetHeader(testMetadata2); err != nil { return grpc.Errorf(grpc.Code(err), "%v.SetHeader(_, %v) = %v, want ", stream, testMetadata2, err) } } else { if err := stream.SendHeader(md); err != nil { return grpc.Errorf(grpc.Code(err), "%v.SendHeader(%v) = %v, want %v", stream, md, err, nil) } } stream.SetTrailer(testTrailerMetadata) if s.multipleSetTrailer { stream.SetTrailer(testTrailerMetadata2) } } for { in, err := stream.Recv() if err == io.EOF { // read done. return nil } if err != nil { return err } cs := in.GetResponseParameters() for _, c := range cs { if us := c.GetIntervalUs(); us > 0 { time.Sleep(time.Duration(us) * time.Microsecond) } payload, err := newPayload(in.GetResponseType(), c.GetSize()) if err != nil { return err } if err := stream.Send(&testpb.StreamingOutputCallResponse{ Payload: payload, }); err != nil { return err } } } } func (s *testServer) HalfDuplexCall(stream testpb.TestService_HalfDuplexCallServer) error { var msgBuf []*testpb.StreamingOutputCallRequest for { in, err := stream.Recv() if err == io.EOF { // read done. break } if err != nil { return err } msgBuf = append(msgBuf, in) } for _, m := range msgBuf { cs := m.GetResponseParameters() for _, c := range cs { if us := c.GetIntervalUs(); us > 0 { time.Sleep(time.Duration(us) * time.Microsecond) } payload, err := newPayload(m.GetResponseType(), c.GetSize()) if err != nil { return err } if err := stream.Send(&testpb.StreamingOutputCallResponse{ Payload: payload, }); err != nil { return err } } } return nil } const tlsDir = "testdata/" type env struct { name string network string // The type of network such as tcp, unix, etc. security string // The security protocol such as TLS, SSH, etc. httpHandler bool // whether to use the http.Handler ServerTransport; requires TLS balancer bool // whether to use balancer } func (e env) runnable() bool { if runtime.GOOS == "windows" && e.network == "unix" { return false } return true } func (e env) dialer(addr string, timeout time.Duration) (net.Conn, error) { return net.DialTimeout(e.network, addr, timeout) } var ( tcpClearEnv = env{name: "tcp-clear", network: "tcp", balancer: true} tcpTLSEnv = env{name: "tcp-tls", network: "tcp", security: "tls", balancer: true} unixClearEnv = env{name: "unix-clear", network: "unix", balancer: true} unixTLSEnv = env{name: "unix-tls", network: "unix", security: "tls", balancer: true} handlerEnv = env{name: "handler-tls", network: "tcp", security: "tls", httpHandler: true, balancer: true} noBalancerEnv = env{name: "no-balancer", network: "tcp", security: "tls", balancer: false} // TODO add handlerEnv back when ServeHTTP is stable. allEnv = []env{tcpClearEnv, tcpTLSEnv, unixClearEnv, unixTLSEnv /*handlerEnv,*/, noBalancerEnv} ) var onlyEnv = flag.String("only_env", "", "If non-empty, one of 'tcp-clear', 'tcp-tls', 'unix-clear', 'unix-tls', or 'handler-tls' to only run the tests for that environment. Empty means all.") func listTestEnv() (envs []env) { if *onlyEnv != "" { for _, e := range allEnv { if e.name == *onlyEnv { if !e.runnable() { panic(fmt.Sprintf("--only_env environment %q does not run on %s", *onlyEnv, runtime.GOOS)) } return []env{e} } } panic(fmt.Sprintf("invalid --only_env value %q", *onlyEnv)) } for _, e := range allEnv { if e.runnable() { envs = append(envs, e) } } return envs } // test is an end-to-end test. It should be created with the newTest // func, modified as needed, and then started with its startServer method. // It should be cleaned up with the tearDown method. type test struct { t *testing.T e env ctx context.Context // valid for life of test, before tearDown cancel context.CancelFunc // Configurable knobs, after newTest returns: testServer testpb.TestServiceServer // nil means none healthServer *health.Server // nil means disabled maxStream uint32 tapHandle tap.ServerInHandle maxMsgSize int userAgent string clientCompression bool serverCompression bool unaryClientInt grpc.UnaryClientInterceptor streamClientInt grpc.StreamClientInterceptor unaryServerInt grpc.UnaryServerInterceptor streamServerInt grpc.StreamServerInterceptor unknownHandler grpc.StreamHandler sc <-chan grpc.ServiceConfig // srv and srvAddr are set once startServer is called. srv *grpc.Server srvAddr string cc *grpc.ClientConn // nil until requested via clientConn restoreLogs func() // nil unless declareLogNoise is used } func (te *test) tearDown() { if te.cancel != nil { te.cancel() te.cancel = nil } if te.cc != nil { te.cc.Close() te.cc = nil } if te.restoreLogs != nil { te.restoreLogs() te.restoreLogs = nil } if te.srv != nil { te.srv.Stop() } } // newTest returns a new test using the provided testing.T and // environment. It is returned with default values. Tests should // modify it before calling its startServer and clientConn methods. func newTest(t *testing.T, e env) *test { te := &test{ t: t, e: e, maxStream: math.MaxUint32, } te.ctx, te.cancel = context.WithCancel(context.Background()) return te } // startServer starts a gRPC server listening. Callers should defer a // call to te.tearDown to clean up. func (te *test) startServer(ts testpb.TestServiceServer) { te.testServer = ts te.t.Logf("Running test in %s environment...", te.e.name) sopts := []grpc.ServerOption{grpc.MaxConcurrentStreams(te.maxStream)} if te.maxMsgSize > 0 { sopts = append(sopts, grpc.MaxMsgSize(te.maxMsgSize)) } if te.tapHandle != nil { sopts = append(sopts, grpc.InTapHandle(te.tapHandle)) } if te.serverCompression { sopts = append(sopts, grpc.RPCCompressor(grpc.NewGZIPCompressor()), grpc.RPCDecompressor(grpc.NewGZIPDecompressor()), ) } if te.unaryServerInt != nil { sopts = append(sopts, grpc.UnaryInterceptor(te.unaryServerInt)) } if te.streamServerInt != nil { sopts = append(sopts, grpc.StreamInterceptor(te.streamServerInt)) } if te.unknownHandler != nil { sopts = append(sopts, grpc.UnknownServiceHandler(te.unknownHandler)) } la := "localhost:0" switch te.e.network { case "unix": la = "/tmp/testsock" + fmt.Sprintf("%d", time.Now().UnixNano()) syscall.Unlink(la) } lis, err := net.Listen(te.e.network, la) if err != nil { te.t.Fatalf("Failed to listen: %v", err) } switch te.e.security { case "tls": creds, err := credentials.NewServerTLSFromFile(tlsDir+"server1.pem", tlsDir+"server1.key") if err != nil { te.t.Fatalf("Failed to generate credentials %v", err) } sopts = append(sopts, grpc.Creds(creds)) case "clientAlwaysFailCred": sopts = append(sopts, grpc.Creds(clientAlwaysFailCred{})) case "clientTimeoutCreds": sopts = append(sopts, grpc.Creds(&clientTimeoutCreds{})) } s := grpc.NewServer(sopts...) te.srv = s if te.e.httpHandler { internal.TestingUseHandlerImpl(s) } if te.healthServer != nil { healthpb.RegisterHealthServer(s, te.healthServer) } if te.testServer != nil { testpb.RegisterTestServiceServer(s, te.testServer) } addr := la switch te.e.network { case "unix": default: _, port, err := net.SplitHostPort(lis.Addr().String()) if err != nil { te.t.Fatalf("Failed to parse listener address: %v", err) } addr = "localhost:" + port } go s.Serve(lis) te.srvAddr = addr } func (te *test) clientConn() *grpc.ClientConn { if te.cc != nil { return te.cc } opts := []grpc.DialOption{ grpc.WithDialer(te.e.dialer), grpc.WithUserAgent(te.userAgent), } if te.sc != nil { opts = append(opts, grpc.WithServiceConfig(te.sc)) } if te.clientCompression { opts = append(opts, grpc.WithCompressor(grpc.NewGZIPCompressor()), grpc.WithDecompressor(grpc.NewGZIPDecompressor()), ) } if te.unaryClientInt != nil { opts = append(opts, grpc.WithUnaryInterceptor(te.unaryClientInt)) } if te.streamClientInt != nil { opts = append(opts, grpc.WithStreamInterceptor(te.streamClientInt)) } if te.maxMsgSize > 0 { opts = append(opts, grpc.WithMaxMsgSize(te.maxMsgSize)) } switch te.e.security { case "tls": creds, err := credentials.NewClientTLSFromFile(tlsDir+"ca.pem", "x.test.youtube.com") if err != nil { te.t.Fatalf("Failed to load credentials: %v", err) } opts = append(opts, grpc.WithTransportCredentials(creds)) case "clientAlwaysFailCred": opts = append(opts, grpc.WithTransportCredentials(clientAlwaysFailCred{})) case "clientTimeoutCreds": opts = append(opts, grpc.WithTransportCredentials(&clientTimeoutCreds{})) default: opts = append(opts, grpc.WithInsecure()) } if te.e.balancer { opts = append(opts, grpc.WithBalancer(grpc.RoundRobin(nil))) } var err error te.cc, err = grpc.Dial(te.srvAddr, opts...) if err != nil { te.t.Fatalf("Dial(%q) = %v", te.srvAddr, err) } return te.cc } func (te *test) declareLogNoise(phrases ...string) { te.restoreLogs = declareLogNoise(te.t, phrases...) } func (te *test) withServerTester(fn func(st *serverTester)) { c, err := te.e.dialer(te.srvAddr, 10*time.Second) if err != nil { te.t.Fatal(err) } defer c.Close() if te.e.security == "tls" { c = tls.Client(c, &tls.Config{ InsecureSkipVerify: true, NextProtos: []string{http2.NextProtoTLS}, }) } st := newServerTesterFromConn(te.t, c) st.greet() fn(st) } func TestTimeoutOnDeadServer(t *testing.T) { defer leakCheck(t)() for _, e := range listTestEnv() { testTimeoutOnDeadServer(t, e) } } func testTimeoutOnDeadServer(t *testing.T, e env) { te := newTest(t, e) te.userAgent = testAppUA te.declareLogNoise( "transport: http2Client.notifyError got notified that the client transport was broken EOF", "grpc: addrConn.transportMonitor exits due to: grpc: the connection is closing", "grpc: addrConn.resetTransport failed to create client transport: connection error", ) te.startServer(&testServer{security: e.security}) defer te.tearDown() cc := te.clientConn() tc := testpb.NewTestServiceClient(cc) if _, err := tc.EmptyCall(context.Background(), &testpb.Empty{}, grpc.FailFast(false)); err != nil { t.Fatalf("TestService/EmptyCall(_, _) = _, %v, want _, ", err) } te.srv.Stop() ctx, _ := context.WithTimeout(context.Background(), time.Millisecond) _, err := tc.EmptyCall(ctx, &testpb.Empty{}, grpc.FailFast(false)) if e.balancer && grpc.Code(err) != codes.DeadlineExceeded { // If e.balancer == nil, the ac will stop reconnecting because the dialer returns non-temp error, // the error will be an internal error. t.Fatalf("TestService/EmptyCall(%v, _) = _, %v, want _, error code: %s", ctx, err, codes.DeadlineExceeded) } awaitNewConnLogOutput() } func TestServerGracefulStopIdempotent(t *testing.T) { defer leakCheck(t)() for _, e := range listTestEnv() { if e.name == "handler-tls" { continue } testServerGracefulStopIdempotent(t, e) } } func testServerGracefulStopIdempotent(t *testing.T, e env) { te := newTest(t, e) te.userAgent = testAppUA te.startServer(&testServer{security: e.security}) defer te.tearDown() for i := 0; i < 3; i++ { te.srv.GracefulStop() } } func TestServerGoAway(t *testing.T) { defer leakCheck(t)() for _, e := range listTestEnv() { if e.name == "handler-tls" { continue } testServerGoAway(t, e) } } func testServerGoAway(t *testing.T, e env) { te := newTest(t, e) te.userAgent = testAppUA te.startServer(&testServer{security: e.security}) defer te.tearDown() cc := te.clientConn() tc := testpb.NewTestServiceClient(cc) // Finish an RPC to make sure the connection is good. if _, err := tc.EmptyCall(context.Background(), &testpb.Empty{}, grpc.FailFast(false)); err != nil { t.Fatalf("TestService/EmptyCall(_, _) = _, %v, want _, ", err) } ch := make(chan struct{}) go func() { te.srv.GracefulStop() close(ch) }() // Loop until the server side GoAway signal is propagated to the client. for { ctx, _ := context.WithTimeout(context.Background(), 10*time.Millisecond) if _, err := tc.EmptyCall(ctx, &testpb.Empty{}, grpc.FailFast(false)); err == nil { continue } break } // A new RPC should fail. if _, err := tc.EmptyCall(context.Background(), &testpb.Empty{}); grpc.Code(err) != codes.Unavailable && grpc.Code(err) != codes.Internal { t.Fatalf("TestService/EmptyCall(_, _) = _, %v, want _, %s or %s", err, codes.Unavailable, codes.Internal) } <-ch awaitNewConnLogOutput() } func TestServerGoAwayPendingRPC(t *testing.T) { defer leakCheck(t)() for _, e := range listTestEnv() { if e.name == "handler-tls" { continue } testServerGoAwayPendingRPC(t, e) } } func testServerGoAwayPendingRPC(t *testing.T, e env) { te := newTest(t, e) te.userAgent = testAppUA te.declareLogNoise( "transport: http2Client.notifyError got notified that the client transport was broken EOF", "grpc: addrConn.transportMonitor exits due to: grpc: the connection is closing", "grpc: addrConn.resetTransport failed to create client transport: connection error", ) te.startServer(&testServer{security: e.security}) defer te.tearDown() cc := te.clientConn() tc := testpb.NewTestServiceClient(cc) ctx, cancel := context.WithCancel(context.Background()) stream, err := tc.FullDuplexCall(ctx, grpc.FailFast(false)) if err != nil { t.Fatalf("%v.FullDuplexCall(_) = _, %v, want ", tc, err) } // Finish an RPC to make sure the connection is good. if _, err := tc.EmptyCall(context.Background(), &testpb.Empty{}, grpc.FailFast(false)); err != nil { t.Fatalf("%v.EmptyCall(_, _, _) = _, %v, want _, ", tc, err) } ch := make(chan struct{}) go func() { te.srv.GracefulStop() close(ch) }() // Loop until the server side GoAway signal is propagated to the client. for { ctx, _ := context.WithTimeout(context.Background(), 10*time.Millisecond) if _, err := tc.EmptyCall(ctx, &testpb.Empty{}, grpc.FailFast(false)); err == nil { continue } break } respParam := []*testpb.ResponseParameters{ { Size: proto.Int32(1), }, } payload, err := newPayload(testpb.PayloadType_COMPRESSABLE, int32(100)) if err != nil { t.Fatal(err) } req := &testpb.StreamingOutputCallRequest{ ResponseType: testpb.PayloadType_COMPRESSABLE.Enum(), ResponseParameters: respParam, Payload: payload, } // The existing RPC should be still good to proceed. if err := stream.Send(req); err != nil { t.Fatalf("%v.Send(%v) = %v, want ", stream, req, err) } if _, err := stream.Recv(); err != nil { t.Fatalf("%v.Recv() = _, %v, want _, ", stream, err) } cancel() <-ch awaitNewConnLogOutput() } func TestServerMultipleGoAwayPendingRPC(t *testing.T) { defer leakCheck(t)() for _, e := range listTestEnv() { if e.name == "handler-tls" { continue } testServerMultipleGoAwayPendingRPC(t, e) } } func testServerMultipleGoAwayPendingRPC(t *testing.T, e env) { te := newTest(t, e) te.userAgent = testAppUA te.declareLogNoise( "transport: http2Client.notifyError got notified that the client transport was broken EOF", "grpc: addrConn.transportMonitor exits due to: grpc: the connection is closing", "grpc: addrConn.resetTransport failed to create client transport: connection error", ) te.startServer(&testServer{security: e.security}) defer te.tearDown() cc := te.clientConn() tc := testpb.NewTestServiceClient(cc) ctx, cancel := context.WithCancel(context.Background()) stream, err := tc.FullDuplexCall(ctx, grpc.FailFast(false)) if err != nil { t.Fatalf("%v.FullDuplexCall(_) = _, %v, want ", tc, err) } // Finish an RPC to make sure the connection is good. if _, err := tc.EmptyCall(context.Background(), &testpb.Empty{}, grpc.FailFast(false)); err != nil { t.Fatalf("%v.EmptyCall(_, _, _) = _, %v, want _, ", tc, err) } ch1 := make(chan struct{}) go func() { te.srv.GracefulStop() close(ch1) }() ch2 := make(chan struct{}) go func() { te.srv.GracefulStop() close(ch2) }() // Loop until the server side GoAway signal is propagated to the client. for { ctx, _ := context.WithTimeout(context.Background(), 10*time.Millisecond) if _, err := tc.EmptyCall(ctx, &testpb.Empty{}, grpc.FailFast(false)); err == nil { continue } break } select { case <-ch1: t.Fatal("GracefulStop() terminated early") case <-ch2: t.Fatal("GracefulStop() terminated early") default: } respParam := []*testpb.ResponseParameters{ { Size: proto.Int32(1), }, } payload, err := newPayload(testpb.PayloadType_COMPRESSABLE, int32(100)) if err != nil { t.Fatal(err) } req := &testpb.StreamingOutputCallRequest{ ResponseType: testpb.PayloadType_COMPRESSABLE.Enum(), ResponseParameters: respParam, Payload: payload, } // The existing RPC should be still good to proceed. if err := stream.Send(req); err != nil { t.Fatalf("%v.Send(%v) = %v, want ", stream, req, err) } if _, err := stream.Recv(); err != nil { t.Fatalf("%v.Recv() = _, %v, want _, ", stream, err) } if err := stream.CloseSend(); err != nil { t.Fatalf("%v.CloseSend() = %v, want ", stream, err) } <-ch1 <-ch2 cancel() awaitNewConnLogOutput() } func TestConcurrentClientConnCloseAndServerGoAway(t *testing.T) { defer leakCheck(t)() for _, e := range listTestEnv() { if e.name == "handler-tls" { continue } testConcurrentClientConnCloseAndServerGoAway(t, e) } } func testConcurrentClientConnCloseAndServerGoAway(t *testing.T, e env) { te := newTest(t, e) te.userAgent = testAppUA te.declareLogNoise( "transport: http2Client.notifyError got notified that the client transport was broken EOF", "grpc: addrConn.transportMonitor exits due to: grpc: the connection is closing", "grpc: addrConn.resetTransport failed to create client transport: connection error", ) te.startServer(&testServer{security: e.security}) defer te.tearDown() cc := te.clientConn() tc := testpb.NewTestServiceClient(cc) if _, err := tc.EmptyCall(context.Background(), &testpb.Empty{}, grpc.FailFast(false)); err != nil { t.Fatalf("%v.EmptyCall(_, _, _) = _, %v, want _, ", tc, err) } ch := make(chan struct{}) // Close ClientConn and Server concurrently. go func() { te.srv.GracefulStop() close(ch) }() go func() { cc.Close() }() <-ch } func TestConcurrentServerStopAndGoAway(t *testing.T) { defer leakCheck(t)() for _, e := range listTestEnv() { if e.name == "handler-tls" { continue } testConcurrentServerStopAndGoAway(t, e) } } func testConcurrentServerStopAndGoAway(t *testing.T, e env) { te := newTest(t, e) te.userAgent = testAppUA te.declareLogNoise( "transport: http2Client.notifyError got notified that the client transport was broken EOF", "grpc: addrConn.transportMonitor exits due to: grpc: the connection is closing", "grpc: addrConn.resetTransport failed to create client transport: connection error", ) te.startServer(&testServer{security: e.security}) defer te.tearDown() cc := te.clientConn() tc := testpb.NewTestServiceClient(cc) stream, err := tc.FullDuplexCall(context.Background(), grpc.FailFast(false)) if err != nil { t.Fatalf("%v.FullDuplexCall(_) = _, %v, want ", tc, err) } // Finish an RPC to make sure the connection is good. if _, err := tc.EmptyCall(context.Background(), &testpb.Empty{}, grpc.FailFast(false)); err != nil { t.Fatalf("%v.EmptyCall(_, _, _) = _, %v, want _, ", tc, err) } ch := make(chan struct{}) go func() { te.srv.GracefulStop() close(ch) }() // Loop until the server side GoAway signal is propagated to the client. for { ctx, _ := context.WithTimeout(context.Background(), 10*time.Millisecond) if _, err := tc.EmptyCall(ctx, &testpb.Empty{}, grpc.FailFast(false)); err == nil { continue } break } // Stop the server and close all the connections. te.srv.Stop() respParam := []*testpb.ResponseParameters{ { Size: proto.Int32(1), }, } payload, err := newPayload(testpb.PayloadType_COMPRESSABLE, int32(100)) if err != nil { t.Fatal(err) } req := &testpb.StreamingOutputCallRequest{ ResponseType: testpb.PayloadType_COMPRESSABLE.Enum(), ResponseParameters: respParam, Payload: payload, } if err := stream.Send(req); err == nil { if _, err := stream.Recv(); err == nil { t.Fatalf("%v.Recv() = _, %v, want _, ", stream, err) } } <-ch awaitNewConnLogOutput() } func TestFailFast(t *testing.T) { defer leakCheck(t)() for _, e := range listTestEnv() { testFailFast(t, e) } } func testFailFast(t *testing.T, e env) { te := newTest(t, e) te.userAgent = testAppUA te.declareLogNoise( "transport: http2Client.notifyError got notified that the client transport was broken EOF", "grpc: addrConn.transportMonitor exits due to: grpc: the connection is closing", "grpc: addrConn.resetTransport failed to create client transport: connection error", ) te.startServer(&testServer{security: e.security}) defer te.tearDown() cc := te.clientConn() tc := testpb.NewTestServiceClient(cc) if _, err := tc.EmptyCall(context.Background(), &testpb.Empty{}); err != nil { t.Fatalf("TestService/EmptyCall(_, _) = _, %v, want _, ", err) } // Stop the server and tear down all the exisiting connections. te.srv.Stop() // Loop until the server teardown is propagated to the client. for { _, err := tc.EmptyCall(context.Background(), &testpb.Empty{}) if grpc.Code(err) == codes.Unavailable { break } fmt.Printf("%v.EmptyCall(_, _) = _, %v", tc, err) time.Sleep(10 * time.Millisecond) } // The client keeps reconnecting and ongoing fail-fast RPCs should fail with code.Unavailable. if _, err := tc.EmptyCall(context.Background(), &testpb.Empty{}); grpc.Code(err) != codes.Unavailable { t.Fatalf("TestService/EmptyCall(_, _, _) = _, %v, want _, error code: %s", err, codes.Unavailable) } if _, err := tc.StreamingInputCall(context.Background()); grpc.Code(err) != codes.Unavailable { t.Fatalf("TestService/StreamingInputCall(_) = _, %v, want _, error code: %s", err, codes.Unavailable) } awaitNewConnLogOutput() } func TestServiceConfig(t *testing.T) { defer leakCheck(t)() for _, e := range listTestEnv() { testServiceConfig(t, e) } } func testServiceConfig(t *testing.T, e env) { te := newTest(t, e) ch := make(chan grpc.ServiceConfig) te.sc = ch te.userAgent = testAppUA te.declareLogNoise( "transport: http2Client.notifyError got notified that the client transport was broken EOF", "grpc: addrConn.transportMonitor exits due to: grpc: the connection is closing", "grpc: addrConn.resetTransport failed to create client transport: connection error", "Failed to dial : context canceled; please retry.", ) defer te.tearDown() var wg sync.WaitGroup wg.Add(1) go func() { defer wg.Done() mc := grpc.MethodConfig{ WaitForReady: true, Timeout: time.Millisecond, } m := make(map[string]grpc.MethodConfig) m["/grpc.testing.TestService/EmptyCall"] = mc m["/grpc.testing.TestService/FullDuplexCall"] = mc sc := grpc.ServiceConfig{ Methods: m, } ch <- sc }() cc := te.clientConn() tc := testpb.NewTestServiceClient(cc) // The following RPCs are expected to become non-fail-fast ones with 1ms deadline. if _, err := tc.EmptyCall(context.Background(), &testpb.Empty{}); grpc.Code(err) != codes.DeadlineExceeded { t.Fatalf("TestService/EmptyCall(_, _) = _, %v, want _, %s", err, codes.DeadlineExceeded) } if _, err := tc.FullDuplexCall(context.Background()); grpc.Code(err) != codes.DeadlineExceeded { t.Fatalf("TestService/FullDuplexCall(_) = _, %v, want %s", err, codes.DeadlineExceeded) } wg.Wait() // Generate a service config update. mc := grpc.MethodConfig{ WaitForReady: false, } m := make(map[string]grpc.MethodConfig) m["/grpc.testing.TestService/EmptyCall"] = mc m["/grpc.testing.TestService/FullDuplexCall"] = mc sc := grpc.ServiceConfig{ Methods: m, } ch <- sc // Loop until the new update becomes effective. for { if _, err := tc.EmptyCall(context.Background(), &testpb.Empty{}); grpc.Code(err) != codes.Unavailable { continue } break } // The following RPCs are expected to become fail-fast. if _, err := tc.EmptyCall(context.Background(), &testpb.Empty{}); grpc.Code(err) != codes.Unavailable { t.Fatalf("TestService/EmptyCall(_, _) = _, %v, want _, %s", err, codes.Unavailable) } if _, err := tc.FullDuplexCall(context.Background()); grpc.Code(err) != codes.Unavailable { t.Fatalf("TestService/FullDuplexCall(_) = _, %v, want %s", err, codes.Unavailable) } } func TestTap(t *testing.T) { defer leakCheck(t)() for _, e := range listTestEnv() { if e.name == "handler-tls" { continue } testTap(t, e) } } type myTap struct { cnt int } func (t *myTap) handle(ctx context.Context, info *tap.Info) (context.Context, error) { if info != nil { if info.FullMethodName == "/grpc.testing.TestService/EmptyCall" { t.cnt++ } else if info.FullMethodName == "/grpc.testing.TestService/UnaryCall" { return nil, fmt.Errorf("tap error") } } return ctx, nil } func testTap(t *testing.T, e env) { te := newTest(t, e) te.userAgent = testAppUA ttap := &myTap{} te.tapHandle = ttap.handle te.declareLogNoise( "transport: http2Client.notifyError got notified that the client transport was broken EOF", "grpc: addrConn.transportMonitor exits due to: grpc: the connection is closing", "grpc: addrConn.resetTransport failed to create client transport: connection error", ) te.startServer(&testServer{security: e.security}) defer te.tearDown() cc := te.clientConn() tc := testpb.NewTestServiceClient(cc) if _, err := tc.EmptyCall(context.Background(), &testpb.Empty{}); err != nil { t.Fatalf("TestService/EmptyCall(_, _) = _, %v, want _, ", err) } if ttap.cnt != 1 { t.Fatalf("Get the count in ttap %d, want 1", ttap.cnt) } payload, err := newPayload(testpb.PayloadType_COMPRESSABLE, 31) if err != nil { t.Fatal(err) } req := &testpb.SimpleRequest{ ResponseType: testpb.PayloadType_COMPRESSABLE.Enum(), ResponseSize: proto.Int32(45), Payload: payload, } if _, err := tc.UnaryCall(context.Background(), req); grpc.Code(err) != codes.Unavailable { t.Fatalf("TestService/UnaryCall(_, _) = _, %v, want _, %s", err, codes.Unavailable) } } func healthCheck(d time.Duration, cc *grpc.ClientConn, serviceName string) (*healthpb.HealthCheckResponse, error) { ctx, _ := context.WithTimeout(context.Background(), d) hc := healthpb.NewHealthClient(cc) req := &healthpb.HealthCheckRequest{ Service: serviceName, } return hc.Check(ctx, req) } func TestHealthCheckOnSuccess(t *testing.T) { defer leakCheck(t)() for _, e := range listTestEnv() { testHealthCheckOnSuccess(t, e) } } func testHealthCheckOnSuccess(t *testing.T, e env) { te := newTest(t, e) hs := health.NewServer() hs.SetServingStatus("grpc.health.v1.Health", 1) te.healthServer = hs te.startServer(&testServer{security: e.security}) defer te.tearDown() cc := te.clientConn() if _, err := healthCheck(1*time.Second, cc, "grpc.health.v1.Health"); err != nil { t.Fatalf("Health/Check(_, _) = _, %v, want _, ", err) } } func TestHealthCheckOnFailure(t *testing.T) { defer leakCheck(t)() for _, e := range listTestEnv() { testHealthCheckOnFailure(t, e) } } func testHealthCheckOnFailure(t *testing.T, e env) { defer leakCheck(t)() te := newTest(t, e) te.declareLogNoise( "Failed to dial ", "grpc: the client connection is closing; please retry", ) hs := health.NewServer() hs.SetServingStatus("grpc.health.v1.HealthCheck", 1) te.healthServer = hs te.startServer(&testServer{security: e.security}) defer te.tearDown() cc := te.clientConn() wantErr := grpc.Errorf(codes.DeadlineExceeded, "context deadline exceeded") if _, err := healthCheck(0*time.Second, cc, "grpc.health.v1.Health"); !equalErrors(err, wantErr) { t.Fatalf("Health/Check(_, _) = _, %v, want _, error code %s", err, codes.DeadlineExceeded) } awaitNewConnLogOutput() } func TestHealthCheckOff(t *testing.T) { defer leakCheck(t)() for _, e := range listTestEnv() { // TODO(bradfitz): Temporarily skip this env due to #619. if e.name == "handler-tls" { continue } testHealthCheckOff(t, e) } } func testHealthCheckOff(t *testing.T, e env) { te := newTest(t, e) te.startServer(&testServer{security: e.security}) defer te.tearDown() want := grpc.Errorf(codes.Unimplemented, "unknown service grpc.health.v1.Health") if _, err := healthCheck(1*time.Second, te.clientConn(), ""); !equalErrors(err, want) { t.Fatalf("Health/Check(_, _) = _, %v, want _, %v", err, want) } } func TestUnknownHandler(t *testing.T) { defer leakCheck(t)() // An example unknownHandler that returns a different code and a different method, making sure that we do not // expose what methods are implemented to a client that is not authenticated. unknownHandler := func(srv interface{}, stream grpc.ServerStream) error { return grpc.Errorf(codes.Unauthenticated, "user unauthenticated") } for _, e := range listTestEnv() { // TODO(bradfitz): Temporarily skip this env due to #619. if e.name == "handler-tls" { continue } testUnknownHandler(t, e, unknownHandler) } } func testUnknownHandler(t *testing.T, e env, unknownHandler grpc.StreamHandler) { te := newTest(t, e) te.unknownHandler = unknownHandler te.startServer(&testServer{security: e.security}) defer te.tearDown() want := grpc.Errorf(codes.Unauthenticated, "user unauthenticated") if _, err := healthCheck(1*time.Second, te.clientConn(), ""); !equalErrors(err, want) { t.Fatalf("Health/Check(_, _) = _, %v, want _, %v", err, want) } } func TestHealthCheckServingStatus(t *testing.T) { defer leakCheck(t)() for _, e := range listTestEnv() { testHealthCheckServingStatus(t, e) } } func testHealthCheckServingStatus(t *testing.T, e env) { te := newTest(t, e) hs := health.NewServer() te.healthServer = hs te.startServer(&testServer{security: e.security}) defer te.tearDown() cc := te.clientConn() out, err := healthCheck(1*time.Second, cc, "") if err != nil { t.Fatalf("Health/Check(_, _) = _, %v, want _, ", err) } if out.Status != healthpb.HealthCheckResponse_SERVING { t.Fatalf("Got the serving status %v, want SERVING", out.Status) } wantErr := grpc.Errorf(codes.NotFound, "unknown service") if _, err := healthCheck(1*time.Second, cc, "grpc.health.v1.Health"); !equalErrors(err, wantErr) { t.Fatalf("Health/Check(_, _) = _, %v, want _, error code %s", err, codes.NotFound) } hs.SetServingStatus("grpc.health.v1.Health", healthpb.HealthCheckResponse_SERVING) out, err = healthCheck(1*time.Second, cc, "grpc.health.v1.Health") if err != nil { t.Fatalf("Health/Check(_, _) = _, %v, want _, ", err) } if out.Status != healthpb.HealthCheckResponse_SERVING { t.Fatalf("Got the serving status %v, want SERVING", out.Status) } hs.SetServingStatus("grpc.health.v1.Health", healthpb.HealthCheckResponse_NOT_SERVING) out, err = healthCheck(1*time.Second, cc, "grpc.health.v1.Health") if err != nil { t.Fatalf("Health/Check(_, _) = _, %v, want _, ", err) } if out.Status != healthpb.HealthCheckResponse_NOT_SERVING { t.Fatalf("Got the serving status %v, want NOT_SERVING", out.Status) } } func TestErrorChanNoIO(t *testing.T) { defer leakCheck(t)() for _, e := range listTestEnv() { testErrorChanNoIO(t, e) } } func testErrorChanNoIO(t *testing.T, e env) { te := newTest(t, e) te.startServer(&testServer{security: e.security}) defer te.tearDown() tc := testpb.NewTestServiceClient(te.clientConn()) if _, err := tc.FullDuplexCall(context.Background()); err != nil { t.Fatalf("%v.FullDuplexCall(_) = _, %v, want ", tc, err) } } func TestEmptyUnaryWithUserAgent(t *testing.T) { defer leakCheck(t)() for _, e := range listTestEnv() { testEmptyUnaryWithUserAgent(t, e) } } func testEmptyUnaryWithUserAgent(t *testing.T, e env) { te := newTest(t, e) te.userAgent = testAppUA te.startServer(&testServer{security: e.security}) defer te.tearDown() cc := te.clientConn() tc := testpb.NewTestServiceClient(cc) var header metadata.MD reply, err := tc.EmptyCall(context.Background(), &testpb.Empty{}, grpc.Header(&header)) if err != nil || !proto.Equal(&testpb.Empty{}, reply) { t.Fatalf("TestService/EmptyCall(_, _) = %v, %v, want %v, ", reply, err, &testpb.Empty{}) } if v, ok := header["ua"]; !ok || v[0] != testAppUA { t.Fatalf("header[\"ua\"] = %q, %t, want %q, true", v, ok, testAppUA) } te.srv.Stop() } func TestFailedEmptyUnary(t *testing.T) { defer leakCheck(t)() for _, e := range listTestEnv() { testFailedEmptyUnary(t, e) } } func testFailedEmptyUnary(t *testing.T, e env) { te := newTest(t, e) te.startServer(&testServer{security: e.security}) defer te.tearDown() tc := testpb.NewTestServiceClient(te.clientConn()) ctx := metadata.NewContext(context.Background(), testMetadata) wantErr := grpc.Errorf(codes.DataLoss, "missing expected user-agent") if _, err := tc.EmptyCall(ctx, &testpb.Empty{}); !equalErrors(err, wantErr) { t.Fatalf("TestService/EmptyCall(_, _) = _, %v, want _, %v", err, wantErr) } } func TestLargeUnary(t *testing.T) { defer leakCheck(t)() for _, e := range listTestEnv() { testLargeUnary(t, e) } } func testLargeUnary(t *testing.T, e env) { te := newTest(t, e) te.startServer(&testServer{security: e.security}) defer te.tearDown() tc := testpb.NewTestServiceClient(te.clientConn()) const argSize = 271828 const respSize = 314159 payload, err := newPayload(testpb.PayloadType_COMPRESSABLE, argSize) if err != nil { t.Fatal(err) } req := &testpb.SimpleRequest{ ResponseType: testpb.PayloadType_COMPRESSABLE.Enum(), ResponseSize: proto.Int32(respSize), Payload: payload, } reply, err := tc.UnaryCall(context.Background(), req) if err != nil { t.Fatalf("TestService/UnaryCall(_, _) = _, %v, want _, ", err) } pt := reply.GetPayload().GetType() ps := len(reply.GetPayload().GetBody()) if pt != testpb.PayloadType_COMPRESSABLE || ps != respSize { t.Fatalf("Got the reply with type %d len %d; want %d, %d", pt, ps, testpb.PayloadType_COMPRESSABLE, respSize) } } func TestExceedMsgLimit(t *testing.T) { defer leakCheck(t)() for _, e := range listTestEnv() { testExceedMsgLimit(t, e) } } func testExceedMsgLimit(t *testing.T, e env) { te := newTest(t, e) te.maxMsgSize = 1024 te.startServer(&testServer{security: e.security}) defer te.tearDown() tc := testpb.NewTestServiceClient(te.clientConn()) argSize := int32(te.maxMsgSize + 1) const smallSize = 1 payload, err := newPayload(testpb.PayloadType_COMPRESSABLE, argSize) if err != nil { t.Fatal(err) } smallPayload, err := newPayload(testpb.PayloadType_COMPRESSABLE, smallSize) if err != nil { t.Fatal(err) } // test on server side for unary RPC req := &testpb.SimpleRequest{ ResponseType: testpb.PayloadType_COMPRESSABLE.Enum(), ResponseSize: proto.Int32(smallSize), Payload: payload, } if _, err := tc.UnaryCall(context.Background(), req); err == nil || grpc.Code(err) != codes.Internal { t.Fatalf("TestService/UnaryCall(_, _) = _, %v, want _, error code: %s", err, codes.Internal) } // test on client side for unary RPC req.ResponseSize = proto.Int32(int32(te.maxMsgSize) + 1) req.Payload = smallPayload if _, err := tc.UnaryCall(context.Background(), req); err == nil || grpc.Code(err) != codes.Internal { t.Fatalf("TestService/UnaryCall(_, _) = _, %v, want _, error code: %s", err, codes.Internal) } // test on server side for streaming RPC stream, err := tc.FullDuplexCall(te.ctx) if err != nil { t.Fatalf("%v.FullDuplexCall(_) = _, %v, want ", tc, err) } respParam := []*testpb.ResponseParameters{ { Size: proto.Int32(1), }, } spayload, err := newPayload(testpb.PayloadType_COMPRESSABLE, int32(te.maxMsgSize+1)) if err != nil { t.Fatal(err) } sreq := &testpb.StreamingOutputCallRequest{ ResponseType: testpb.PayloadType_COMPRESSABLE.Enum(), ResponseParameters: respParam, Payload: spayload, } if err := stream.Send(sreq); err != nil { t.Fatalf("%v.Send(%v) = %v, want ", stream, sreq, err) } if _, err := stream.Recv(); err == nil || grpc.Code(err) != codes.Internal { t.Fatalf("%v.Recv() = _, %v, want _, error code: %s", stream, err, codes.Internal) } // test on client side for streaming RPC stream, err = tc.FullDuplexCall(te.ctx) if err != nil { t.Fatalf("%v.FullDuplexCall(_) = _, %v, want ", tc, err) } respParam[0].Size = proto.Int32(int32(te.maxMsgSize) + 1) sreq.Payload = smallPayload if err := stream.Send(sreq); err != nil { t.Fatalf("%v.Send(%v) = %v, want ", stream, sreq, err) } if _, err := stream.Recv(); err == nil || grpc.Code(err) != codes.Internal { t.Fatalf("%v.Recv() = _, %v, want _, error code: %s", stream, err, codes.Internal) } } func TestPeerClientSide(t *testing.T) { defer leakCheck(t)() for _, e := range listTestEnv() { testPeerClientSide(t, e) } } func testPeerClientSide(t *testing.T, e env) { te := newTest(t, e) te.userAgent = testAppUA te.startServer(&testServer{security: e.security}) defer te.tearDown() tc := testpb.NewTestServiceClient(te.clientConn()) peer := new(peer.Peer) if _, err := tc.EmptyCall(context.Background(), &testpb.Empty{}, grpc.Peer(peer), grpc.FailFast(false)); err != nil { t.Fatalf("TestService/EmptyCall(_, _) = _, %v, want _, ", err) } pa := peer.Addr.String() if e.network == "unix" { if pa != te.srvAddr { t.Fatalf("peer.Addr = %v, want %v", pa, te.srvAddr) } return } _, pp, err := net.SplitHostPort(pa) if err != nil { t.Fatalf("Failed to parse address from peer.") } _, sp, err := net.SplitHostPort(te.srvAddr) if err != nil { t.Fatalf("Failed to parse address of test server.") } if pp != sp { t.Fatalf("peer.Addr = localhost:%v, want localhost:%v", pp, sp) } } func TestMetadataUnaryRPC(t *testing.T) { defer leakCheck(t)() for _, e := range listTestEnv() { testMetadataUnaryRPC(t, e) } } func testMetadataUnaryRPC(t *testing.T, e env) { te := newTest(t, e) te.startServer(&testServer{security: e.security}) defer te.tearDown() tc := testpb.NewTestServiceClient(te.clientConn()) const argSize = 2718 const respSize = 314 payload, err := newPayload(testpb.PayloadType_COMPRESSABLE, argSize) if err != nil { t.Fatal(err) } req := &testpb.SimpleRequest{ ResponseType: testpb.PayloadType_COMPRESSABLE.Enum(), ResponseSize: proto.Int32(respSize), Payload: payload, } var header, trailer metadata.MD ctx := metadata.NewContext(context.Background(), testMetadata) if _, err := tc.UnaryCall(ctx, req, grpc.Header(&header), grpc.Trailer(&trailer)); err != nil { t.Fatalf("TestService.UnaryCall(%v, _, _, _) = _, %v; want _, ", ctx, err) } // Ignore optional response headers that Servers may set: if header != nil { delete(header, "trailer") // RFC 2616 says server SHOULD (but optional) declare trailers delete(header, "date") // the Date header is also optional } if !reflect.DeepEqual(header, testMetadata) { t.Fatalf("Received header metadata %v, want %v", header, testMetadata) } if !reflect.DeepEqual(trailer, testTrailerMetadata) { t.Fatalf("Received trailer metadata %v, want %v", trailer, testTrailerMetadata) } } func TestMultipleSetTrailerUnaryRPC(t *testing.T) { defer leakCheck(t)() for _, e := range listTestEnv() { testMultipleSetTrailerUnaryRPC(t, e) } } func testMultipleSetTrailerUnaryRPC(t *testing.T, e env) { te := newTest(t, e) te.startServer(&testServer{security: e.security, multipleSetTrailer: true}) defer te.tearDown() tc := testpb.NewTestServiceClient(te.clientConn()) const ( argSize = 1 respSize = 1 ) payload, err := newPayload(testpb.PayloadType_COMPRESSABLE, argSize) if err != nil { t.Fatal(err) } req := &testpb.SimpleRequest{ ResponseType: testpb.PayloadType_COMPRESSABLE.Enum(), ResponseSize: proto.Int32(respSize), Payload: payload, } var trailer metadata.MD ctx := metadata.NewContext(context.Background(), testMetadata) if _, err := tc.UnaryCall(ctx, req, grpc.Trailer(&trailer), grpc.FailFast(false)); err != nil { t.Fatalf("TestService.UnaryCall(%v, _, _, _) = _, %v; want _, ", ctx, err) } expectedTrailer := metadata.Join(testTrailerMetadata, testTrailerMetadata2) if !reflect.DeepEqual(trailer, expectedTrailer) { t.Fatalf("Received trailer metadata %v, want %v", trailer, expectedTrailer) } } func TestMultipleSetTrailerStreamingRPC(t *testing.T) { defer leakCheck(t)() for _, e := range listTestEnv() { testMultipleSetTrailerStreamingRPC(t, e) } } func testMultipleSetTrailerStreamingRPC(t *testing.T, e env) { te := newTest(t, e) te.startServer(&testServer{security: e.security, multipleSetTrailer: true}) defer te.tearDown() tc := testpb.NewTestServiceClient(te.clientConn()) ctx := metadata.NewContext(context.Background(), testMetadata) stream, err := tc.FullDuplexCall(ctx, grpc.FailFast(false)) if err != nil { t.Fatalf("%v.FullDuplexCall(_) = _, %v, want ", tc, err) } if err := stream.CloseSend(); err != nil { t.Fatalf("%v.CloseSend() got %v, want %v", stream, err, nil) } if _, err := stream.Recv(); err != io.EOF { t.Fatalf("%v failed to complele the FullDuplexCall: %v", stream, err) } trailer := stream.Trailer() expectedTrailer := metadata.Join(testTrailerMetadata, testTrailerMetadata2) if !reflect.DeepEqual(trailer, expectedTrailer) { t.Fatalf("Received trailer metadata %v, want %v", trailer, expectedTrailer) } } func TestSetAndSendHeaderUnaryRPC(t *testing.T) { defer leakCheck(t)() for _, e := range listTestEnv() { if e.name == "handler-tls" { continue } testSetAndSendHeaderUnaryRPC(t, e) } } // To test header metadata is sent on SendHeader(). func testSetAndSendHeaderUnaryRPC(t *testing.T, e env) { te := newTest(t, e) te.startServer(&testServer{security: e.security, setAndSendHeader: true}) defer te.tearDown() tc := testpb.NewTestServiceClient(te.clientConn()) const ( argSize = 1 respSize = 1 ) payload, err := newPayload(testpb.PayloadType_COMPRESSABLE, argSize) if err != nil { t.Fatal(err) } req := &testpb.SimpleRequest{ ResponseType: testpb.PayloadType_COMPRESSABLE.Enum(), ResponseSize: proto.Int32(respSize), Payload: payload, } var header metadata.MD ctx := metadata.NewContext(context.Background(), testMetadata) if _, err := tc.UnaryCall(ctx, req, grpc.Header(&header), grpc.FailFast(false)); err != nil { t.Fatalf("TestService.UnaryCall(%v, _, _, _) = _, %v; want _, ", ctx, err) } expectedHeader := metadata.Join(testMetadata, testMetadata2) if !reflect.DeepEqual(header, expectedHeader) { t.Fatalf("Received header metadata %v, want %v", header, expectedHeader) } } func TestMultipleSetHeaderUnaryRPC(t *testing.T) { defer leakCheck(t)() for _, e := range listTestEnv() { if e.name == "handler-tls" { continue } testMultipleSetHeaderUnaryRPC(t, e) } } // To test header metadata is sent when sending response. func testMultipleSetHeaderUnaryRPC(t *testing.T, e env) { te := newTest(t, e) te.startServer(&testServer{security: e.security, setHeaderOnly: true}) defer te.tearDown() tc := testpb.NewTestServiceClient(te.clientConn()) const ( argSize = 1 respSize = 1 ) payload, err := newPayload(testpb.PayloadType_COMPRESSABLE, argSize) if err != nil { t.Fatal(err) } req := &testpb.SimpleRequest{ ResponseType: testpb.PayloadType_COMPRESSABLE.Enum(), ResponseSize: proto.Int32(respSize), Payload: payload, } var header metadata.MD ctx := metadata.NewContext(context.Background(), testMetadata) if _, err := tc.UnaryCall(ctx, req, grpc.Header(&header), grpc.FailFast(false)); err != nil { t.Fatalf("TestService.UnaryCall(%v, _, _, _) = _, %v; want _, ", ctx, err) } expectedHeader := metadata.Join(testMetadata, testMetadata2) if !reflect.DeepEqual(header, expectedHeader) { t.Fatalf("Received header metadata %v, want %v", header, expectedHeader) } } func TestMultipleSetHeaderUnaryRPCError(t *testing.T) { defer leakCheck(t)() for _, e := range listTestEnv() { if e.name == "handler-tls" { continue } testMultipleSetHeaderUnaryRPCError(t, e) } } // To test header metadata is sent when sending status. func testMultipleSetHeaderUnaryRPCError(t *testing.T, e env) { te := newTest(t, e) te.startServer(&testServer{security: e.security, setHeaderOnly: true}) defer te.tearDown() tc := testpb.NewTestServiceClient(te.clientConn()) const ( argSize = 1 respSize = -1 // Invalid respSize to make RPC fail. ) payload, err := newPayload(testpb.PayloadType_COMPRESSABLE, argSize) if err != nil { t.Fatal(err) } req := &testpb.SimpleRequest{ ResponseType: testpb.PayloadType_COMPRESSABLE.Enum(), ResponseSize: proto.Int32(respSize), Payload: payload, } var header metadata.MD ctx := metadata.NewContext(context.Background(), testMetadata) if _, err := tc.UnaryCall(ctx, req, grpc.Header(&header), grpc.FailFast(false)); err == nil { t.Fatalf("TestService.UnaryCall(%v, _, _, _) = _, %v; want _, ", ctx, err) } expectedHeader := metadata.Join(testMetadata, testMetadata2) if !reflect.DeepEqual(header, expectedHeader) { t.Fatalf("Received header metadata %v, want %v", header, expectedHeader) } } func TestSetAndSendHeaderStreamingRPC(t *testing.T) { defer leakCheck(t)() for _, e := range listTestEnv() { if e.name == "handler-tls" { continue } testSetAndSendHeaderStreamingRPC(t, e) } } // To test header metadata is sent on SendHeader(). func testSetAndSendHeaderStreamingRPC(t *testing.T, e env) { te := newTest(t, e) te.startServer(&testServer{security: e.security, setAndSendHeader: true}) defer te.tearDown() tc := testpb.NewTestServiceClient(te.clientConn()) const ( argSize = 1 respSize = 1 ) ctx := metadata.NewContext(context.Background(), testMetadata) stream, err := tc.FullDuplexCall(ctx) if err != nil { t.Fatalf("%v.FullDuplexCall(_) = _, %v, want ", tc, err) } if err := stream.CloseSend(); err != nil { t.Fatalf("%v.CloseSend() got %v, want %v", stream, err, nil) } if _, err := stream.Recv(); err != io.EOF { t.Fatalf("%v failed to complele the FullDuplexCall: %v", stream, err) } header, err := stream.Header() if err != nil { t.Fatalf("%v.Header() = _, %v, want _, ", stream, err) } expectedHeader := metadata.Join(testMetadata, testMetadata2) if !reflect.DeepEqual(header, expectedHeader) { t.Fatalf("Received header metadata %v, want %v", header, expectedHeader) } } func TestMultipleSetHeaderStreamingRPC(t *testing.T) { defer leakCheck(t)() for _, e := range listTestEnv() { if e.name == "handler-tls" { continue } testMultipleSetHeaderStreamingRPC(t, e) } } // To test header metadata is sent when sending response. func testMultipleSetHeaderStreamingRPC(t *testing.T, e env) { te := newTest(t, e) te.startServer(&testServer{security: e.security, setHeaderOnly: true}) defer te.tearDown() tc := testpb.NewTestServiceClient(te.clientConn()) const ( argSize = 1 respSize = 1 ) ctx := metadata.NewContext(context.Background(), testMetadata) stream, err := tc.FullDuplexCall(ctx) if err != nil { t.Fatalf("%v.FullDuplexCall(_) = _, %v, want ", tc, err) } payload, err := newPayload(testpb.PayloadType_COMPRESSABLE, argSize) if err != nil { t.Fatal(err) } req := &testpb.StreamingOutputCallRequest{ ResponseType: testpb.PayloadType_COMPRESSABLE.Enum(), ResponseParameters: []*testpb.ResponseParameters{ {Size: proto.Int32(respSize)}, }, Payload: payload, } if err := stream.Send(req); err != nil { t.Fatalf("%v.Send(%v) = %v, want ", stream, req, err) } if _, err := stream.Recv(); err != nil { t.Fatalf("%v.Recv() = %v, want ", stream, err) } if err := stream.CloseSend(); err != nil { t.Fatalf("%v.CloseSend() got %v, want %v", stream, err, nil) } if _, err := stream.Recv(); err != io.EOF { t.Fatalf("%v failed to complele the FullDuplexCall: %v", stream, err) } header, err := stream.Header() if err != nil { t.Fatalf("%v.Header() = _, %v, want _, ", stream, err) } expectedHeader := metadata.Join(testMetadata, testMetadata2) if !reflect.DeepEqual(header, expectedHeader) { t.Fatalf("Received header metadata %v, want %v", header, expectedHeader) } } func TestMultipleSetHeaderStreamingRPCError(t *testing.T) { defer leakCheck(t)() for _, e := range listTestEnv() { if e.name == "handler-tls" { continue } testMultipleSetHeaderStreamingRPCError(t, e) } } // To test header metadata is sent when sending status. func testMultipleSetHeaderStreamingRPCError(t *testing.T, e env) { te := newTest(t, e) te.startServer(&testServer{security: e.security, setHeaderOnly: true}) defer te.tearDown() tc := testpb.NewTestServiceClient(te.clientConn()) const ( argSize = 1 respSize = -1 ) ctx := metadata.NewContext(context.Background(), testMetadata) stream, err := tc.FullDuplexCall(ctx) if err != nil { t.Fatalf("%v.FullDuplexCall(_) = _, %v, want ", tc, err) } payload, err := newPayload(testpb.PayloadType_COMPRESSABLE, argSize) if err != nil { t.Fatal(err) } req := &testpb.StreamingOutputCallRequest{ ResponseType: testpb.PayloadType_COMPRESSABLE.Enum(), ResponseParameters: []*testpb.ResponseParameters{ {Size: proto.Int32(respSize)}, }, Payload: payload, } if err := stream.Send(req); err != nil { t.Fatalf("%v.Send(%v) = %v, want ", stream, req, err) } if _, err := stream.Recv(); err == nil { t.Fatalf("%v.Recv() = %v, want ", stream, err) } header, err := stream.Header() if err != nil { t.Fatalf("%v.Header() = _, %v, want _, ", stream, err) } expectedHeader := metadata.Join(testMetadata, testMetadata2) if !reflect.DeepEqual(header, expectedHeader) { t.Fatalf("Received header metadata %v, want %v", header, expectedHeader) } if err := stream.CloseSend(); err != nil { t.Fatalf("%v.CloseSend() got %v, want %v", stream, err, nil) } } // TestMalformedHTTP2Metedata verfies the returned error when the client // sends an illegal metadata. func TestMalformedHTTP2Metadata(t *testing.T) { defer leakCheck(t)() for _, e := range listTestEnv() { testMalformedHTTP2Metadata(t, e) } } func testMalformedHTTP2Metadata(t *testing.T, e env) { te := newTest(t, e) te.startServer(&testServer{security: e.security}) defer te.tearDown() tc := testpb.NewTestServiceClient(te.clientConn()) payload, err := newPayload(testpb.PayloadType_COMPRESSABLE, 2718) if err != nil { t.Fatal(err) } req := &testpb.SimpleRequest{ ResponseType: testpb.PayloadType_COMPRESSABLE.Enum(), ResponseSize: proto.Int32(314), Payload: payload, } ctx := metadata.NewContext(context.Background(), malformedHTTP2Metadata) if _, err := tc.UnaryCall(ctx, req); grpc.Code(err) != codes.Internal { t.Fatalf("TestService.UnaryCall(%v, _) = _, %v; want _, %s", ctx, err, codes.Internal) } } func performOneRPC(t *testing.T, tc testpb.TestServiceClient, wg *sync.WaitGroup) { defer wg.Done() const argSize = 2718 const respSize = 314 payload, err := newPayload(testpb.PayloadType_COMPRESSABLE, argSize) if err != nil { t.Error(err) return } req := &testpb.SimpleRequest{ ResponseType: testpb.PayloadType_COMPRESSABLE.Enum(), ResponseSize: proto.Int32(respSize), Payload: payload, } reply, err := tc.UnaryCall(context.Background(), req, grpc.FailFast(false)) if err != nil { t.Errorf("TestService/UnaryCall(_, _) = _, %v, want _, ", err) return } pt := reply.GetPayload().GetType() ps := len(reply.GetPayload().GetBody()) if pt != testpb.PayloadType_COMPRESSABLE || ps != respSize { t.Errorf("Got reply with type %d len %d; want %d, %d", pt, ps, testpb.PayloadType_COMPRESSABLE, respSize) return } } func TestRetry(t *testing.T) { defer leakCheck(t)() for _, e := range listTestEnv() { testRetry(t, e) } } // This test mimics a user who sends 1000 RPCs concurrently on a faulty transport. // TODO(zhaoq): Refactor to make this clearer and add more cases to test racy // and error-prone paths. func testRetry(t *testing.T, e env) { te := newTest(t, e) te.declareLogNoise("transport: http2Client.notifyError got notified that the client transport was broken") te.startServer(&testServer{security: e.security}) defer te.tearDown() cc := te.clientConn() tc := testpb.NewTestServiceClient(cc) var wg sync.WaitGroup numRPC := 1000 rpcSpacing := 2 * time.Millisecond if raceMode { // The race detector has a limit on how many goroutines it can track. // This test is near the upper limit, and goes over the limit // depending on the environment (the http.Handler environment uses // more goroutines) t.Logf("Shortening test in race mode.") numRPC /= 2 rpcSpacing *= 2 } wg.Add(1) go func() { // Halfway through starting RPCs, kill all connections: time.Sleep(time.Duration(numRPC/2) * rpcSpacing) // The server shuts down the network connection to make a // transport error which will be detected by the client side // code. internal.TestingCloseConns(te.srv) wg.Done() }() // All these RPCs should succeed eventually. for i := 0; i < numRPC; i++ { time.Sleep(rpcSpacing) wg.Add(1) go performOneRPC(t, tc, &wg) } wg.Wait() } func TestRPCTimeout(t *testing.T) { defer leakCheck(t)() for _, e := range listTestEnv() { testRPCTimeout(t, e) } } // TODO(zhaoq): Have a better test coverage of timeout and cancellation mechanism. func testRPCTimeout(t *testing.T, e env) { te := newTest(t, e) te.startServer(&testServer{security: e.security}) defer te.tearDown() cc := te.clientConn() tc := testpb.NewTestServiceClient(cc) const argSize = 2718 const respSize = 314 payload, err := newPayload(testpb.PayloadType_COMPRESSABLE, argSize) if err != nil { t.Fatal(err) } req := &testpb.SimpleRequest{ ResponseType: testpb.PayloadType_COMPRESSABLE.Enum(), ResponseSize: proto.Int32(respSize), Payload: payload, } for i := -1; i <= 10; i++ { ctx, _ := context.WithTimeout(context.Background(), time.Duration(i)*time.Millisecond) if _, err := tc.UnaryCall(ctx, req); grpc.Code(err) != codes.DeadlineExceeded { t.Fatalf("TestService/UnaryCallv(_, _) = _, %v; want , error code: %s", err, codes.DeadlineExceeded) } } } func TestCancel(t *testing.T) { defer leakCheck(t)() for _, e := range listTestEnv() { testCancel(t, e) } } func testCancel(t *testing.T, e env) { te := newTest(t, e) te.declareLogNoise("grpc: the client connection is closing; please retry") te.startServer(&testServer{security: e.security}) defer te.tearDown() cc := te.clientConn() tc := testpb.NewTestServiceClient(cc) const argSize = 2718 const respSize = 314 payload, err := newPayload(testpb.PayloadType_COMPRESSABLE, argSize) if err != nil { t.Fatal(err) } req := &testpb.SimpleRequest{ ResponseType: testpb.PayloadType_COMPRESSABLE.Enum(), ResponseSize: proto.Int32(respSize), Payload: payload, } ctx, cancel := context.WithCancel(context.Background()) time.AfterFunc(1*time.Millisecond, cancel) if r, err := tc.UnaryCall(ctx, req); grpc.Code(err) != codes.Canceled { t.Fatalf("TestService/UnaryCall(_, _) = %v, %v; want _, error code: %s", r, err, codes.Canceled) } awaitNewConnLogOutput() } func TestCancelNoIO(t *testing.T) { defer leakCheck(t)() for _, e := range listTestEnv() { testCancelNoIO(t, e) } } func testCancelNoIO(t *testing.T, e env) { te := newTest(t, e) te.declareLogNoise("http2Client.notifyError got notified that the client transport was broken") te.maxStream = 1 // Only allows 1 live stream per server transport. te.startServer(&testServer{security: e.security}) defer te.tearDown() cc := te.clientConn() tc := testpb.NewTestServiceClient(cc) // Start one blocked RPC for which we'll never send streaming // input. This will consume the 1 maximum concurrent streams, // causing future RPCs to hang. ctx, cancelFirst := context.WithCancel(context.Background()) _, err := tc.StreamingInputCall(ctx) if err != nil { t.Fatalf("%v.StreamingInputCall(_) = _, %v, want _, ", tc, err) } // Loop until the ClientConn receives the initial settings // frame from the server, notifying it about the maximum // concurrent streams. We know when it's received it because // an RPC will fail with codes.DeadlineExceeded instead of // succeeding. // TODO(bradfitz): add internal test hook for this (Issue 534) for { ctx, cancelSecond := context.WithTimeout(context.Background(), 250*time.Millisecond) _, err := tc.StreamingInputCall(ctx) cancelSecond() if err == nil { time.Sleep(50 * time.Millisecond) continue } if grpc.Code(err) == codes.DeadlineExceeded { break } t.Fatalf("%v.StreamingInputCall(_) = _, %v, want _, %s", tc, err, codes.DeadlineExceeded) } // If there are any RPCs in flight before the client receives // the max streams setting, let them be expired. // TODO(bradfitz): add internal test hook for this (Issue 534) time.Sleep(500 * time.Millisecond) ch := make(chan struct{}) go func() { defer close(ch) // This should be blocked until the 1st is canceled. ctx, cancelThird := context.WithTimeout(context.Background(), 2*time.Second) if _, err := tc.StreamingInputCall(ctx); err != nil { t.Errorf("%v.StreamingInputCall(_) = _, %v, want _, ", tc, err) } cancelThird() }() cancelFirst() <-ch } // The following tests the gRPC streaming RPC implementations. // TODO(zhaoq): Have better coverage on error cases. var ( reqSizes = []int{27182, 8, 1828, 45904} respSizes = []int{31415, 9, 2653, 58979} ) func TestNoService(t *testing.T) { defer leakCheck(t)() for _, e := range listTestEnv() { testNoService(t, e) } } func testNoService(t *testing.T, e env) { te := newTest(t, e) te.startServer(nil) defer te.tearDown() cc := te.clientConn() tc := testpb.NewTestServiceClient(cc) stream, err := tc.FullDuplexCall(te.ctx, grpc.FailFast(false)) if err != nil { t.Fatalf("%v.FullDuplexCall(_) = _, %v, want ", tc, err) } if _, err := stream.Recv(); grpc.Code(err) != codes.Unimplemented { t.Fatalf("stream.Recv() = _, %v, want _, error code %s", err, codes.Unimplemented) } } func TestPingPong(t *testing.T) { defer leakCheck(t)() for _, e := range listTestEnv() { testPingPong(t, e) } } func testPingPong(t *testing.T, e env) { te := newTest(t, e) te.startServer(&testServer{security: e.security}) defer te.tearDown() tc := testpb.NewTestServiceClient(te.clientConn()) stream, err := tc.FullDuplexCall(te.ctx) if err != nil { t.Fatalf("%v.FullDuplexCall(_) = _, %v, want ", tc, err) } var index int for index < len(reqSizes) { respParam := []*testpb.ResponseParameters{ { Size: proto.Int32(int32(respSizes[index])), }, } payload, err := newPayload(testpb.PayloadType_COMPRESSABLE, int32(reqSizes[index])) if err != nil { t.Fatal(err) } req := &testpb.StreamingOutputCallRequest{ ResponseType: testpb.PayloadType_COMPRESSABLE.Enum(), ResponseParameters: respParam, Payload: payload, } if err := stream.Send(req); err != nil { t.Fatalf("%v.Send(%v) = %v, want ", stream, req, err) } reply, err := stream.Recv() if err != nil { t.Fatalf("%v.Recv() = %v, want ", stream, err) } pt := reply.GetPayload().GetType() if pt != testpb.PayloadType_COMPRESSABLE { t.Fatalf("Got the reply of type %d, want %d", pt, testpb.PayloadType_COMPRESSABLE) } size := len(reply.GetPayload().GetBody()) if size != int(respSizes[index]) { t.Fatalf("Got reply body of length %d, want %d", size, respSizes[index]) } index++ } if err := stream.CloseSend(); err != nil { t.Fatalf("%v.CloseSend() got %v, want %v", stream, err, nil) } if _, err := stream.Recv(); err != io.EOF { t.Fatalf("%v failed to complele the ping pong test: %v", stream, err) } } func TestMetadataStreamingRPC(t *testing.T) { defer leakCheck(t)() for _, e := range listTestEnv() { testMetadataStreamingRPC(t, e) } } func testMetadataStreamingRPC(t *testing.T, e env) { te := newTest(t, e) te.startServer(&testServer{security: e.security}) defer te.tearDown() tc := testpb.NewTestServiceClient(te.clientConn()) ctx := metadata.NewContext(te.ctx, testMetadata) stream, err := tc.FullDuplexCall(ctx) if err != nil { t.Fatalf("%v.FullDuplexCall(_) = _, %v, want ", tc, err) } go func() { headerMD, err := stream.Header() if e.security == "tls" { delete(headerMD, "transport_security_type") } delete(headerMD, "trailer") // ignore if present if err != nil || !reflect.DeepEqual(testMetadata, headerMD) { t.Errorf("#1 %v.Header() = %v, %v, want %v, ", stream, headerMD, err, testMetadata) } // test the cached value. headerMD, err = stream.Header() delete(headerMD, "trailer") // ignore if present if err != nil || !reflect.DeepEqual(testMetadata, headerMD) { t.Errorf("#2 %v.Header() = %v, %v, want %v, ", stream, headerMD, err, testMetadata) } var index int for index < len(reqSizes) { respParam := []*testpb.ResponseParameters{ { Size: proto.Int32(int32(respSizes[index])), }, } payload, err := newPayload(testpb.PayloadType_COMPRESSABLE, int32(reqSizes[index])) if err != nil { t.Fatal(err) } req := &testpb.StreamingOutputCallRequest{ ResponseType: testpb.PayloadType_COMPRESSABLE.Enum(), ResponseParameters: respParam, Payload: payload, } if err := stream.Send(req); err != nil { t.Errorf("%v.Send(%v) = %v, want ", stream, req, err) return } index++ } // Tell the server we're done sending args. stream.CloseSend() }() for { if _, err := stream.Recv(); err != nil { break } } trailerMD := stream.Trailer() if !reflect.DeepEqual(testTrailerMetadata, trailerMD) { t.Fatalf("%v.Trailer() = %v, want %v", stream, trailerMD, testTrailerMetadata) } } func TestServerStreaming(t *testing.T) { defer leakCheck(t)() for _, e := range listTestEnv() { testServerStreaming(t, e) } } func testServerStreaming(t *testing.T, e env) { te := newTest(t, e) te.startServer(&testServer{security: e.security}) defer te.tearDown() tc := testpb.NewTestServiceClient(te.clientConn()) respParam := make([]*testpb.ResponseParameters, len(respSizes)) for i, s := range respSizes { respParam[i] = &testpb.ResponseParameters{ Size: proto.Int32(int32(s)), } } req := &testpb.StreamingOutputCallRequest{ ResponseType: testpb.PayloadType_COMPRESSABLE.Enum(), ResponseParameters: respParam, } stream, err := tc.StreamingOutputCall(context.Background(), req) if err != nil { t.Fatalf("%v.StreamingOutputCall(_) = _, %v, want ", tc, err) } var rpcStatus error var respCnt int var index int for { reply, err := stream.Recv() if err != nil { rpcStatus = err break } pt := reply.GetPayload().GetType() if pt != testpb.PayloadType_COMPRESSABLE { t.Fatalf("Got the reply of type %d, want %d", pt, testpb.PayloadType_COMPRESSABLE) } size := len(reply.GetPayload().GetBody()) if size != int(respSizes[index]) { t.Fatalf("Got reply body of length %d, want %d", size, respSizes[index]) } index++ respCnt++ } if rpcStatus != io.EOF { t.Fatalf("Failed to finish the server streaming rpc: %v, want ", rpcStatus) } if respCnt != len(respSizes) { t.Fatalf("Got %d reply, want %d", len(respSizes), respCnt) } } func TestFailedServerStreaming(t *testing.T) { defer leakCheck(t)() for _, e := range listTestEnv() { testFailedServerStreaming(t, e) } } func testFailedServerStreaming(t *testing.T, e env) { te := newTest(t, e) te.startServer(&testServer{security: e.security}) defer te.tearDown() tc := testpb.NewTestServiceClient(te.clientConn()) respParam := make([]*testpb.ResponseParameters, len(respSizes)) for i, s := range respSizes { respParam[i] = &testpb.ResponseParameters{ Size: proto.Int32(int32(s)), } } req := &testpb.StreamingOutputCallRequest{ ResponseType: testpb.PayloadType_COMPRESSABLE.Enum(), ResponseParameters: respParam, } ctx := metadata.NewContext(te.ctx, testMetadata) stream, err := tc.StreamingOutputCall(ctx, req) if err != nil { t.Fatalf("%v.StreamingOutputCall(_) = _, %v, want ", tc, err) } wantErr := grpc.Errorf(codes.DataLoss, "got extra metadata") if _, err := stream.Recv(); !equalErrors(err, wantErr) { t.Fatalf("%v.Recv() = _, %v, want _, %v", stream, err, wantErr) } } // concurrentSendServer is a TestServiceServer whose // StreamingOutputCall makes ten serial Send calls, sending payloads // "0".."9", inclusive. TestServerStreamingConcurrent verifies they // were received in the correct order, and that there were no races. // // All other TestServiceServer methods crash if called. type concurrentSendServer struct { testpb.TestServiceServer } func (s concurrentSendServer) StreamingOutputCall(args *testpb.StreamingOutputCallRequest, stream testpb.TestService_StreamingOutputCallServer) error { for i := 0; i < 10; i++ { stream.Send(&testpb.StreamingOutputCallResponse{ Payload: &testpb.Payload{ Body: []byte{'0' + uint8(i)}, }, }) } return nil } // Tests doing a bunch of concurrent streaming output calls. func TestServerStreamingConcurrent(t *testing.T) { defer leakCheck(t)() for _, e := range listTestEnv() { testServerStreamingConcurrent(t, e) } } func testServerStreamingConcurrent(t *testing.T, e env) { te := newTest(t, e) te.startServer(concurrentSendServer{}) defer te.tearDown() cc := te.clientConn() tc := testpb.NewTestServiceClient(cc) doStreamingCall := func() { req := &testpb.StreamingOutputCallRequest{} stream, err := tc.StreamingOutputCall(context.Background(), req) if err != nil { t.Errorf("%v.StreamingOutputCall(_) = _, %v, want ", tc, err) return } var ngot int var buf bytes.Buffer for { reply, err := stream.Recv() if err == io.EOF { break } if err != nil { t.Fatal(err) } ngot++ if buf.Len() > 0 { buf.WriteByte(',') } buf.Write(reply.GetPayload().GetBody()) } if want := 10; ngot != want { t.Errorf("Got %d replies, want %d", ngot, want) } if got, want := buf.String(), "0,1,2,3,4,5,6,7,8,9"; got != want { t.Errorf("Got replies %q; want %q", got, want) } } var wg sync.WaitGroup for i := 0; i < 20; i++ { wg.Add(1) go func() { defer wg.Done() doStreamingCall() }() } wg.Wait() } func TestClientStreaming(t *testing.T) { defer leakCheck(t)() for _, e := range listTestEnv() { testClientStreaming(t, e) } } func testClientStreaming(t *testing.T, e env) { te := newTest(t, e) te.startServer(&testServer{security: e.security}) defer te.tearDown() tc := testpb.NewTestServiceClient(te.clientConn()) stream, err := tc.StreamingInputCall(te.ctx) if err != nil { t.Fatalf("%v.StreamingInputCall(_) = _, %v, want ", tc, err) } var sum int for _, s := range reqSizes { payload, err := newPayload(testpb.PayloadType_COMPRESSABLE, int32(s)) if err != nil { t.Fatal(err) } req := &testpb.StreamingInputCallRequest{ Payload: payload, } if err := stream.Send(req); err != nil { t.Fatalf("%v.Send(%v) = %v, want ", stream, req, err) } sum += s } reply, err := stream.CloseAndRecv() if err != nil { t.Fatalf("%v.CloseAndRecv() got error %v, want %v", stream, err, nil) } if reply.GetAggregatedPayloadSize() != int32(sum) { t.Fatalf("%v.CloseAndRecv().GetAggregatePayloadSize() = %v; want %v", stream, reply.GetAggregatedPayloadSize(), sum) } } func TestClientStreamingError(t *testing.T) { defer leakCheck(t)() for _, e := range listTestEnv() { if e.name == "handler-tls" { continue } testClientStreamingError(t, e) } } func testClientStreamingError(t *testing.T, e env) { te := newTest(t, e) te.startServer(&testServer{security: e.security, earlyFail: true}) defer te.tearDown() tc := testpb.NewTestServiceClient(te.clientConn()) stream, err := tc.StreamingInputCall(te.ctx) if err != nil { t.Fatalf("%v.StreamingInputCall(_) = _, %v, want ", tc, err) } payload, err := newPayload(testpb.PayloadType_COMPRESSABLE, 1) if err != nil { t.Fatal(err) } req := &testpb.StreamingInputCallRequest{ Payload: payload, } // The 1st request should go through. if err := stream.Send(req); err != nil { t.Fatalf("%v.Send(%v) = %v, want ", stream, req, err) } for { if err := stream.Send(req); err != io.EOF { continue } if _, err := stream.CloseAndRecv(); grpc.Code(err) != codes.NotFound { t.Fatalf("%v.CloseAndRecv() = %v, want error %s", stream, err, codes.NotFound) } break } } func TestExceedMaxStreamsLimit(t *testing.T) { defer leakCheck(t)() for _, e := range listTestEnv() { testExceedMaxStreamsLimit(t, e) } } func testExceedMaxStreamsLimit(t *testing.T, e env) { te := newTest(t, e) te.declareLogNoise( "http2Client.notifyError got notified that the client transport was broken", "Conn.resetTransport failed to create client transport", "grpc: the connection is closing", ) te.maxStream = 1 // Only allows 1 live stream per server transport. te.startServer(&testServer{security: e.security}) defer te.tearDown() cc := te.clientConn() tc := testpb.NewTestServiceClient(cc) _, err := tc.StreamingInputCall(te.ctx) if err != nil { t.Fatalf("%v.StreamingInputCall(_) = _, %v, want _, ", tc, err) } // Loop until receiving the new max stream setting from the server. for { ctx, cancel := context.WithTimeout(context.Background(), time.Second) defer cancel() _, err := tc.StreamingInputCall(ctx) if err == nil { time.Sleep(time.Second) continue } if grpc.Code(err) == codes.DeadlineExceeded { break } t.Fatalf("%v.StreamingInputCall(_) = _, %v, want _, %s", tc, err, codes.DeadlineExceeded) } } const defaultMaxStreamsClient = 100 func TestExceedDefaultMaxStreamsLimit(t *testing.T) { defer leakCheck(t)() for _, e := range listTestEnv() { testExceedDefaultMaxStreamsLimit(t, e) } } func testExceedDefaultMaxStreamsLimit(t *testing.T, e env) { te := newTest(t, e) te.declareLogNoise( "http2Client.notifyError got notified that the client transport was broken", "Conn.resetTransport failed to create client transport", "grpc: the connection is closing", ) // When masStream is set to 0 the server doesn't send a settings frame for // MaxConcurrentStreams, essentially allowing infinite (math.MaxInt32) streams. // In such a case, there should be a default cap on the client-side. te.maxStream = 0 te.startServer(&testServer{security: e.security}) defer te.tearDown() cc := te.clientConn() tc := testpb.NewTestServiceClient(cc) // Create as many streams as a client can. for i := 0; i < defaultMaxStreamsClient; i++ { if _, err := tc.StreamingInputCall(te.ctx); err != nil { t.Fatalf("%v.StreamingInputCall(_) = _, %v, want _, ", tc, err) } } // Trying to create one more should timeout. ctx, cancel := context.WithTimeout(context.Background(), time.Second) defer cancel() _, err := tc.StreamingInputCall(ctx) if err == nil || grpc.Code(err) != codes.DeadlineExceeded { t.Fatalf("%v.StreamingInputCall(_) = _, %v, want _, %s", tc, err, codes.DeadlineExceeded) } } func TestStreamsQuotaRecovery(t *testing.T) { defer leakCheck(t)() for _, e := range listTestEnv() { testStreamsQuotaRecovery(t, e) } } func testStreamsQuotaRecovery(t *testing.T, e env) { te := newTest(t, e) te.declareLogNoise( "http2Client.notifyError got notified that the client transport was broken", "Conn.resetTransport failed to create client transport", "grpc: the connection is closing", ) te.maxStream = 1 // Allows 1 live stream. te.startServer(&testServer{security: e.security}) defer te.tearDown() cc := te.clientConn() tc := testpb.NewTestServiceClient(cc) if _, err := tc.StreamingInputCall(context.Background()); err != nil { t.Fatalf("%v.StreamingInputCall(_) = _, %v, want _, ", tc, err) } // Loop until the new max stream setting is effective. for { ctx, cancel := context.WithTimeout(context.Background(), time.Second) defer cancel() _, err := tc.StreamingInputCall(ctx) if err == nil { time.Sleep(time.Second) continue } if grpc.Code(err) == codes.DeadlineExceeded { break } t.Fatalf("%v.StreamingInputCall(_) = _, %v, want _, %s", tc, err, codes.DeadlineExceeded) } var wg sync.WaitGroup for i := 0; i < 10; i++ { wg.Add(1) go func() { defer wg.Done() payload, err := newPayload(testpb.PayloadType_COMPRESSABLE, 314) if err != nil { t.Fatal(err) } req := &testpb.SimpleRequest{ ResponseType: testpb.PayloadType_COMPRESSABLE.Enum(), ResponseSize: proto.Int32(1592), Payload: payload, } // No rpc should go through due to the max streams limit. ctx, _ := context.WithTimeout(context.Background(), 10*time.Millisecond) if _, err := tc.UnaryCall(ctx, req, grpc.FailFast(false)); grpc.Code(err) != codes.DeadlineExceeded { t.Errorf("TestService/UnaryCall(_, _) = _, %v, want _, %s", err, codes.DeadlineExceeded) } }() } wg.Wait() } func TestCompressServerHasNoSupport(t *testing.T) { defer leakCheck(t)() for _, e := range listTestEnv() { testCompressServerHasNoSupport(t, e) } } func testCompressServerHasNoSupport(t *testing.T, e env) { te := newTest(t, e) te.serverCompression = false te.clientCompression = true te.startServer(&testServer{security: e.security}) defer te.tearDown() tc := testpb.NewTestServiceClient(te.clientConn()) const argSize = 271828 const respSize = 314159 payload, err := newPayload(testpb.PayloadType_COMPRESSABLE, argSize) if err != nil { t.Fatal(err) } req := &testpb.SimpleRequest{ ResponseType: testpb.PayloadType_COMPRESSABLE.Enum(), ResponseSize: proto.Int32(respSize), Payload: payload, } if _, err := tc.UnaryCall(context.Background(), req); err == nil || grpc.Code(err) != codes.Unimplemented { t.Fatalf("TestService/UnaryCall(_, _) = _, %v, want _, error code %s", err, codes.Unimplemented) } // Streaming RPC stream, err := tc.FullDuplexCall(context.Background()) if err != nil { t.Fatalf("%v.FullDuplexCall(_) = _, %v, want ", tc, err) } respParam := []*testpb.ResponseParameters{ { Size: proto.Int32(31415), }, } payload, err = newPayload(testpb.PayloadType_COMPRESSABLE, int32(31415)) if err != nil { t.Fatal(err) } sreq := &testpb.StreamingOutputCallRequest{ ResponseType: testpb.PayloadType_COMPRESSABLE.Enum(), ResponseParameters: respParam, Payload: payload, } if err := stream.Send(sreq); err != nil { t.Fatalf("%v.Send(%v) = %v, want ", stream, sreq, err) } if _, err := stream.Recv(); err == nil || grpc.Code(err) != codes.Unimplemented { t.Fatalf("%v.Recv() = %v, want error code %s", stream, err, codes.Unimplemented) } } func TestCompressOK(t *testing.T) { defer leakCheck(t)() for _, e := range listTestEnv() { testCompressOK(t, e) } } func testCompressOK(t *testing.T, e env) { te := newTest(t, e) te.serverCompression = true te.clientCompression = true te.startServer(&testServer{security: e.security}) defer te.tearDown() tc := testpb.NewTestServiceClient(te.clientConn()) // Unary call const argSize = 271828 const respSize = 314159 payload, err := newPayload(testpb.PayloadType_COMPRESSABLE, argSize) if err != nil { t.Fatal(err) } req := &testpb.SimpleRequest{ ResponseType: testpb.PayloadType_COMPRESSABLE.Enum(), ResponseSize: proto.Int32(respSize), Payload: payload, } ctx := metadata.NewContext(context.Background(), metadata.Pairs("something", "something")) if _, err := tc.UnaryCall(ctx, req); err != nil { t.Fatalf("TestService/UnaryCall(_, _) = _, %v, want _, ", err) } // Streaming RPC ctx, cancel := context.WithCancel(context.Background()) defer cancel() stream, err := tc.FullDuplexCall(ctx) if err != nil { t.Fatalf("%v.FullDuplexCall(_) = _, %v, want ", tc, err) } respParam := []*testpb.ResponseParameters{ { Size: proto.Int32(31415), }, } payload, err = newPayload(testpb.PayloadType_COMPRESSABLE, int32(31415)) if err != nil { t.Fatal(err) } sreq := &testpb.StreamingOutputCallRequest{ ResponseType: testpb.PayloadType_COMPRESSABLE.Enum(), ResponseParameters: respParam, Payload: payload, } if err := stream.Send(sreq); err != nil { t.Fatalf("%v.Send(%v) = %v, want ", stream, sreq, err) } if _, err := stream.Recv(); err != nil { t.Fatalf("%v.Recv() = %v, want ", stream, err) } } func TestUnaryClientInterceptor(t *testing.T) { defer leakCheck(t)() for _, e := range listTestEnv() { testUnaryClientInterceptor(t, e) } } func failOkayRPC(ctx context.Context, method string, req, reply interface{}, cc *grpc.ClientConn, invoker grpc.UnaryInvoker, opts ...grpc.CallOption) error { err := invoker(ctx, method, req, reply, cc, opts...) if err == nil { return grpc.Errorf(codes.NotFound, "") } return err } func testUnaryClientInterceptor(t *testing.T, e env) { te := newTest(t, e) te.userAgent = testAppUA te.unaryClientInt = failOkayRPC te.startServer(&testServer{security: e.security}) defer te.tearDown() tc := testpb.NewTestServiceClient(te.clientConn()) if _, err := tc.EmptyCall(context.Background(), &testpb.Empty{}); grpc.Code(err) != codes.NotFound { t.Fatalf("%v.EmptyCall(_, _) = _, %v, want _, error code %s", tc, err, codes.NotFound) } } func TestStreamClientInterceptor(t *testing.T) { defer leakCheck(t)() for _, e := range listTestEnv() { testStreamClientInterceptor(t, e) } } func failOkayStream(ctx context.Context, desc *grpc.StreamDesc, cc *grpc.ClientConn, method string, streamer grpc.Streamer, opts ...grpc.CallOption) (grpc.ClientStream, error) { s, err := streamer(ctx, desc, cc, method, opts...) if err == nil { return nil, grpc.Errorf(codes.NotFound, "") } return s, nil } func testStreamClientInterceptor(t *testing.T, e env) { te := newTest(t, e) te.streamClientInt = failOkayStream te.startServer(&testServer{security: e.security}) defer te.tearDown() tc := testpb.NewTestServiceClient(te.clientConn()) respParam := []*testpb.ResponseParameters{ { Size: proto.Int32(int32(1)), }, } payload, err := newPayload(testpb.PayloadType_COMPRESSABLE, int32(1)) if err != nil { t.Fatal(err) } req := &testpb.StreamingOutputCallRequest{ ResponseType: testpb.PayloadType_COMPRESSABLE.Enum(), ResponseParameters: respParam, Payload: payload, } if _, err := tc.StreamingOutputCall(context.Background(), req); grpc.Code(err) != codes.NotFound { t.Fatalf("%v.StreamingOutputCall(_) = _, %v, want _, error code %s", tc, err, codes.NotFound) } } func TestUnaryServerInterceptor(t *testing.T) { defer leakCheck(t)() for _, e := range listTestEnv() { testUnaryServerInterceptor(t, e) } } func errInjector(ctx context.Context, req interface{}, info *grpc.UnaryServerInfo, handler grpc.UnaryHandler) (interface{}, error) { return nil, grpc.Errorf(codes.PermissionDenied, "") } func testUnaryServerInterceptor(t *testing.T, e env) { te := newTest(t, e) te.unaryServerInt = errInjector te.startServer(&testServer{security: e.security}) defer te.tearDown() tc := testpb.NewTestServiceClient(te.clientConn()) if _, err := tc.EmptyCall(context.Background(), &testpb.Empty{}); grpc.Code(err) != codes.PermissionDenied { t.Fatalf("%v.EmptyCall(_, _) = _, %v, want _, error code %s", tc, err, codes.PermissionDenied) } } func TestStreamServerInterceptor(t *testing.T) { defer leakCheck(t)() for _, e := range listTestEnv() { // TODO(bradfitz): Temporarily skip this env due to #619. if e.name == "handler-tls" { continue } testStreamServerInterceptor(t, e) } } func fullDuplexOnly(srv interface{}, ss grpc.ServerStream, info *grpc.StreamServerInfo, handler grpc.StreamHandler) error { if info.FullMethod == "/grpc.testing.TestService/FullDuplexCall" { return handler(srv, ss) } // Reject the other methods. return grpc.Errorf(codes.PermissionDenied, "") } func testStreamServerInterceptor(t *testing.T, e env) { te := newTest(t, e) te.streamServerInt = fullDuplexOnly te.startServer(&testServer{security: e.security}) defer te.tearDown() tc := testpb.NewTestServiceClient(te.clientConn()) respParam := []*testpb.ResponseParameters{ { Size: proto.Int32(int32(1)), }, } payload, err := newPayload(testpb.PayloadType_COMPRESSABLE, int32(1)) if err != nil { t.Fatal(err) } req := &testpb.StreamingOutputCallRequest{ ResponseType: testpb.PayloadType_COMPRESSABLE.Enum(), ResponseParameters: respParam, Payload: payload, } s1, err := tc.StreamingOutputCall(context.Background(), req) if err != nil { t.Fatalf("%v.StreamingOutputCall(_) = _, %v, want _, ", tc, err) } if _, err := s1.Recv(); grpc.Code(err) != codes.PermissionDenied { t.Fatalf("%v.StreamingInputCall(_) = _, %v, want _, error code %s", tc, err, codes.PermissionDenied) } s2, err := tc.FullDuplexCall(context.Background()) if err != nil { t.Fatalf("%v.FullDuplexCall(_) = _, %v, want ", tc, err) } if err := s2.Send(req); err != nil { t.Fatalf("%v.Send(_) = %v, want ", s2, err) } if _, err := s2.Recv(); err != nil { t.Fatalf("%v.Recv() = _, %v, want _, ", s2, err) } } // funcServer implements methods of TestServiceServer using funcs, // similar to an http.HandlerFunc. // Any unimplemented method will crash. Tests implement the method(s) // they need. type funcServer struct { testpb.TestServiceServer unaryCall func(ctx context.Context, in *testpb.SimpleRequest) (*testpb.SimpleResponse, error) streamingInputCall func(stream testpb.TestService_StreamingInputCallServer) error } func (s *funcServer) UnaryCall(ctx context.Context, in *testpb.SimpleRequest) (*testpb.SimpleResponse, error) { return s.unaryCall(ctx, in) } func (s *funcServer) StreamingInputCall(stream testpb.TestService_StreamingInputCallServer) error { return s.streamingInputCall(stream) } func TestClientRequestBodyErrorUnexpectedEOF(t *testing.T) { defer leakCheck(t)() for _, e := range listTestEnv() { testClientRequestBodyErrorUnexpectedEOF(t, e) } } func testClientRequestBodyErrorUnexpectedEOF(t *testing.T, e env) { te := newTest(t, e) ts := &funcServer{unaryCall: func(ctx context.Context, in *testpb.SimpleRequest) (*testpb.SimpleResponse, error) { errUnexpectedCall := errors.New("unexpected call func server method") t.Error(errUnexpectedCall) return nil, errUnexpectedCall }} te.startServer(ts) defer te.tearDown() te.withServerTester(func(st *serverTester) { st.writeHeadersGRPC(1, "/grpc.testing.TestService/UnaryCall") // Say we have 5 bytes coming, but set END_STREAM flag: st.writeData(1, true, []byte{0, 0, 0, 0, 5}) st.wantAnyFrame() // wait for server to crash (it used to crash) }) } func TestClientRequestBodyErrorCloseAfterLength(t *testing.T) { defer leakCheck(t)() for _, e := range listTestEnv() { testClientRequestBodyErrorCloseAfterLength(t, e) } } func testClientRequestBodyErrorCloseAfterLength(t *testing.T, e env) { te := newTest(t, e) te.declareLogNoise("Server.processUnaryRPC failed to write status") ts := &funcServer{unaryCall: func(ctx context.Context, in *testpb.SimpleRequest) (*testpb.SimpleResponse, error) { errUnexpectedCall := errors.New("unexpected call func server method") t.Error(errUnexpectedCall) return nil, errUnexpectedCall }} te.startServer(ts) defer te.tearDown() te.withServerTester(func(st *serverTester) { st.writeHeadersGRPC(1, "/grpc.testing.TestService/UnaryCall") // say we're sending 5 bytes, but then close the connection instead. st.writeData(1, false, []byte{0, 0, 0, 0, 5}) st.cc.Close() }) } func TestClientRequestBodyErrorCancel(t *testing.T) { defer leakCheck(t)() for _, e := range listTestEnv() { testClientRequestBodyErrorCancel(t, e) } } func testClientRequestBodyErrorCancel(t *testing.T, e env) { te := newTest(t, e) gotCall := make(chan bool, 1) ts := &funcServer{unaryCall: func(ctx context.Context, in *testpb.SimpleRequest) (*testpb.SimpleResponse, error) { gotCall <- true return new(testpb.SimpleResponse), nil }} te.startServer(ts) defer te.tearDown() te.withServerTester(func(st *serverTester) { st.writeHeadersGRPC(1, "/grpc.testing.TestService/UnaryCall") // Say we have 5 bytes coming, but cancel it instead. st.writeRSTStream(1, http2.ErrCodeCancel) st.writeData(1, false, []byte{0, 0, 0, 0, 5}) // Verify we didn't a call yet. select { case <-gotCall: t.Fatal("unexpected call") default: } // And now send an uncanceled (but still invalid), just to get a response. st.writeHeadersGRPC(3, "/grpc.testing.TestService/UnaryCall") st.writeData(3, true, []byte{0, 0, 0, 0, 0}) <-gotCall st.wantAnyFrame() }) } func TestClientRequestBodyErrorCancelStreamingInput(t *testing.T) { defer leakCheck(t)() for _, e := range listTestEnv() { testClientRequestBodyErrorCancelStreamingInput(t, e) } } func testClientRequestBodyErrorCancelStreamingInput(t *testing.T, e env) { te := newTest(t, e) recvErr := make(chan error, 1) ts := &funcServer{streamingInputCall: func(stream testpb.TestService_StreamingInputCallServer) error { _, err := stream.Recv() recvErr <- err return nil }} te.startServer(ts) defer te.tearDown() te.withServerTester(func(st *serverTester) { st.writeHeadersGRPC(1, "/grpc.testing.TestService/StreamingInputCall") // Say we have 5 bytes coming, but cancel it instead. st.writeData(1, false, []byte{0, 0, 0, 0, 5}) st.writeRSTStream(1, http2.ErrCodeCancel) var got error select { case got = <-recvErr: case <-time.After(3 * time.Second): t.Fatal("timeout waiting for error") } if grpc.Code(got) != codes.Canceled { t.Errorf("error = %#v; want error code %s", got, codes.Canceled) } }) } const clientAlwaysFailCredErrorMsg = "clientAlwaysFailCred always fails" var errClientAlwaysFailCred = errors.New(clientAlwaysFailCredErrorMsg) type clientAlwaysFailCred struct{} func (c clientAlwaysFailCred) ClientHandshake(ctx context.Context, addr string, rawConn net.Conn) (net.Conn, credentials.AuthInfo, error) { return nil, nil, errClientAlwaysFailCred } func (c clientAlwaysFailCred) ServerHandshake(rawConn net.Conn) (net.Conn, credentials.AuthInfo, error) { return rawConn, nil, nil } func (c clientAlwaysFailCred) Info() credentials.ProtocolInfo { return credentials.ProtocolInfo{} } func (c clientAlwaysFailCred) Clone() credentials.TransportCredentials { return nil } func (c clientAlwaysFailCred) OverrideServerName(s string) error { return nil } func TestDialWithBlockErrorOnBadCertificates(t *testing.T) { te := newTest(t, env{name: "bad-cred", network: "tcp", security: "clientAlwaysFailCred", balancer: true}) te.startServer(&testServer{security: te.e.security}) defer te.tearDown() var ( err error opts []grpc.DialOption ) opts = append(opts, grpc.WithTransportCredentials(clientAlwaysFailCred{}), grpc.WithBlock()) te.cc, err = grpc.Dial(te.srvAddr, opts...) if err != errClientAlwaysFailCred { te.t.Fatalf("Dial(%q) = %v, want %v", te.srvAddr, err, errClientAlwaysFailCred) } } func TestFailFastRPCErrorOnBadCertificates(t *testing.T) { te := newTest(t, env{name: "bad-cred", network: "tcp", security: "clientAlwaysFailCred", balancer: true}) te.startServer(&testServer{security: te.e.security}) defer te.tearDown() cc := te.clientConn() tc := testpb.NewTestServiceClient(cc) if _, err := tc.EmptyCall(context.Background(), &testpb.Empty{}); !strings.Contains(err.Error(), clientAlwaysFailCredErrorMsg) { te.t.Fatalf("TestService/EmptyCall(_, _) = _, %v, want err.Error() contains %q", err, clientAlwaysFailCredErrorMsg) } } func TestFailFastRPCWithNoBalancerErrorOnBadCertificates(t *testing.T) { te := newTest(t, env{name: "bad-cred", network: "tcp", security: "clientAlwaysFailCred", balancer: false}) te.startServer(&testServer{security: te.e.security}) defer te.tearDown() cc := te.clientConn() tc := testpb.NewTestServiceClient(cc) if _, err := tc.EmptyCall(context.Background(), &testpb.Empty{}); !strings.Contains(err.Error(), clientAlwaysFailCredErrorMsg) { te.t.Fatalf("TestService/EmptyCall(_, _) = _, %v, want err.Error() contains %q", err, clientAlwaysFailCredErrorMsg) } } func TestNonFailFastRPCWithNoBalancerErrorOnBadCertificates(t *testing.T) { te := newTest(t, env{name: "bad-cred", network: "tcp", security: "clientAlwaysFailCred", balancer: false}) te.startServer(&testServer{security: te.e.security}) defer te.tearDown() cc := te.clientConn() tc := testpb.NewTestServiceClient(cc) if _, err := tc.EmptyCall(context.Background(), &testpb.Empty{}, grpc.FailFast(false)); !strings.Contains(err.Error(), clientAlwaysFailCredErrorMsg) { te.t.Fatalf("TestService/EmptyCall(_, _) = _, %v, want err.Error() contains %q", err, clientAlwaysFailCredErrorMsg) } } type clientTimeoutCreds struct { timeoutReturned bool } func (c *clientTimeoutCreds) ClientHandshake(ctx context.Context, addr string, rawConn net.Conn) (net.Conn, credentials.AuthInfo, error) { if !c.timeoutReturned { c.timeoutReturned = true return nil, nil, context.DeadlineExceeded } return rawConn, nil, nil } func (c *clientTimeoutCreds) ServerHandshake(rawConn net.Conn) (net.Conn, credentials.AuthInfo, error) { return rawConn, nil, nil } func (c *clientTimeoutCreds) Info() credentials.ProtocolInfo { return credentials.ProtocolInfo{} } func (c *clientTimeoutCreds) Clone() credentials.TransportCredentials { return nil } func (c *clientTimeoutCreds) OverrideServerName(s string) error { return nil } func TestNonFailFastRPCSucceedOnTimeoutCreds(t *testing.T) { te := newTest(t, env{name: "timeout-cred", network: "tcp", security: "clientTimeoutCreds", balancer: false}) te.userAgent = testAppUA te.startServer(&testServer{security: te.e.security}) defer te.tearDown() cc := te.clientConn() tc := testpb.NewTestServiceClient(cc) // This unary call should succeed, because ClientHandshake will succeed for the second time. if _, err := tc.EmptyCall(context.Background(), &testpb.Empty{}, grpc.FailFast(false)); err != nil { te.t.Fatalf("TestService/EmptyCall(_, _) = _, %v, want ", err) } } type serverDispatchCred struct { ready chan struct{} rawConn net.Conn } func newServerDispatchCred() *serverDispatchCred { return &serverDispatchCred{ ready: make(chan struct{}), } } func (c *serverDispatchCred) ClientHandshake(ctx context.Context, addr string, rawConn net.Conn) (net.Conn, credentials.AuthInfo, error) { return rawConn, nil, nil } func (c *serverDispatchCred) ServerHandshake(rawConn net.Conn) (net.Conn, credentials.AuthInfo, error) { c.rawConn = rawConn close(c.ready) return nil, nil, credentials.ErrConnDispatched } func (c *serverDispatchCred) Info() credentials.ProtocolInfo { return credentials.ProtocolInfo{} } func (c *serverDispatchCred) Clone() credentials.TransportCredentials { return nil } func (c *serverDispatchCred) OverrideServerName(s string) error { return nil } func (c *serverDispatchCred) getRawConn() net.Conn { <-c.ready return c.rawConn } func TestServerCredsDispatch(t *testing.T) { lis, err := net.Listen("tcp", ":0") if err != nil { t.Fatalf("Failed to listen: %v", err) } cred := newServerDispatchCred() s := grpc.NewServer(grpc.Creds(cred)) go s.Serve(lis) defer s.Stop() cc, err := grpc.Dial(lis.Addr().String(), grpc.WithTransportCredentials(cred)) if err != nil { t.Fatalf("grpc.Dial(%q) = %v", lis.Addr().String(), err) } defer cc.Close() // Check rawConn is not closed. if n, err := cred.getRawConn().Write([]byte{0}); n <= 0 || err != nil { t.Errorf("Read() = %v, %v; want n>0, ", n, err) } } func TestFlowControlLogicalRace(t *testing.T) { // Test for a regression of https://github.com/grpc/grpc-go/issues/632, // and other flow control bugs. defer leakCheck(t)() const ( itemCount = 100 itemSize = 1 << 10 recvCount = 2 maxFailures = 3 requestTimeout = time.Second ) requestCount := 10000 if raceMode { requestCount = 1000 } lis, err := net.Listen("tcp", ":0") if err != nil { t.Fatalf("Failed to listen: %v", err) } defer lis.Close() s := grpc.NewServer() testpb.RegisterTestServiceServer(s, &flowControlLogicalRaceServer{ itemCount: itemCount, itemSize: itemSize, }) defer s.Stop() go s.Serve(lis) ctx := context.Background() cc, err := grpc.Dial(lis.Addr().String(), grpc.WithInsecure(), grpc.WithBlock()) if err != nil { t.Fatalf("grpc.Dial(%q) = %v", lis.Addr().String(), err) } defer cc.Close() cl := testpb.NewTestServiceClient(cc) failures := 0 for i := 0; i < requestCount; i++ { ctx, cancel := context.WithTimeout(ctx, requestTimeout) output, err := cl.StreamingOutputCall(ctx, &testpb.StreamingOutputCallRequest{}) if err != nil { t.Fatalf("StreamingOutputCall; err = %q", err) } j := 0 loop: for ; j < recvCount; j++ { _, err := output.Recv() if err != nil { if err == io.EOF { break loop } switch grpc.Code(err) { case codes.DeadlineExceeded: break loop default: t.Fatalf("Recv; err = %q", err) } } } cancel() <-ctx.Done() if j < recvCount { t.Errorf("got %d responses to request %d", j, i) failures++ if failures >= maxFailures { // Continue past the first failure to see if the connection is // entirely broken, or if only a single RPC was affected break } } } } type flowControlLogicalRaceServer struct { testpb.TestServiceServer itemSize int itemCount int } func (s *flowControlLogicalRaceServer) StreamingOutputCall(req *testpb.StreamingOutputCallRequest, srv testpb.TestService_StreamingOutputCallServer) error { for i := 0; i < s.itemCount; i++ { err := srv.Send(&testpb.StreamingOutputCallResponse{ Payload: &testpb.Payload{ // Sending a large stream of data which the client reject // helps to trigger some types of flow control bugs. // // Reallocating memory here is inefficient, but the stress it // puts on the GC leads to more frequent flow control // failures. The GC likely causes more variety in the // goroutine scheduling orders. Body: bytes.Repeat([]byte("a"), s.itemSize), }, }) if err != nil { return err } } return nil } // interestingGoroutines returns all goroutines we care about for the purpose // of leak checking. It excludes testing or runtime ones. func interestingGoroutines() (gs []string) { buf := make([]byte, 2<<20) buf = buf[:runtime.Stack(buf, true)] for _, g := range strings.Split(string(buf), "\n\n") { sl := strings.SplitN(g, "\n", 2) if len(sl) != 2 { continue } stack := strings.TrimSpace(sl[1]) if strings.HasPrefix(stack, "testing.RunTests") { continue } if stack == "" || strings.Contains(stack, "testing.Main(") || strings.Contains(stack, "testing.tRunner(") || strings.Contains(stack, "runtime.goexit") || strings.Contains(stack, "created by runtime.gc") || strings.Contains(stack, "created by runtime/trace.Start") || strings.Contains(stack, "created by google3/base/go/log.init") || strings.Contains(stack, "interestingGoroutines") || strings.Contains(stack, "runtime.MHeap_Scavenger") || strings.Contains(stack, "signal.signal_recv") || strings.Contains(stack, "sigterm.handler") || strings.Contains(stack, "runtime_mcall") || strings.Contains(stack, "goroutine in C code") { continue } gs = append(gs, g) } sort.Strings(gs) return } // leakCheck snapshots the currently-running goroutines and returns a // function to be run at the end of tests to see whether any // goroutines leaked. func leakCheck(t testing.TB) func() { orig := map[string]bool{} for _, g := range interestingGoroutines() { orig[g] = true } return func() { // Loop, waiting for goroutines to shut down. // Wait up to 10 seconds, but finish as quickly as possible. deadline := time.Now().Add(10 * time.Second) for { var leaked []string for _, g := range interestingGoroutines() { if !orig[g] { leaked = append(leaked, g) } } if len(leaked) == 0 { return } if time.Now().Before(deadline) { time.Sleep(50 * time.Millisecond) continue } for _, g := range leaked { t.Errorf("Leaked goroutine: %v", g) } return } } } type lockingWriter struct { mu sync.Mutex w io.Writer } func (lw *lockingWriter) Write(p []byte) (n int, err error) { lw.mu.Lock() defer lw.mu.Unlock() return lw.w.Write(p) } func (lw *lockingWriter) setWriter(w io.Writer) { lw.mu.Lock() defer lw.mu.Unlock() lw.w = w } var testLogOutput = &lockingWriter{w: os.Stderr} // awaitNewConnLogOutput waits for any of grpc.NewConn's goroutines to // terminate, if they're still running. It spams logs with this // message. We wait for it so our log filter is still // active. Otherwise the "defer restore()" at the top of various test // functions restores our log filter and then the goroutine spams. func awaitNewConnLogOutput() { awaitLogOutput(50*time.Millisecond, "grpc: the client connection is closing; please retry") } func awaitLogOutput(maxWait time.Duration, phrase string) { pb := []byte(phrase) timer := time.NewTimer(maxWait) defer timer.Stop() wakeup := make(chan bool, 1) for { if logOutputHasContents(pb, wakeup) { return } select { case <-timer.C: // Too slow. Oh well. return case <-wakeup: } } } func logOutputHasContents(v []byte, wakeup chan<- bool) bool { testLogOutput.mu.Lock() defer testLogOutput.mu.Unlock() fw, ok := testLogOutput.w.(*filterWriter) if !ok { return false } fw.mu.Lock() defer fw.mu.Unlock() if bytes.Contains(fw.buf.Bytes(), v) { return true } fw.wakeup = wakeup return false } func init() { grpclog.SetLogger(log.New(testLogOutput, "", log.LstdFlags)) } var verboseLogs = flag.Bool("verbose_logs", false, "show all grpclog output, without filtering") func noop() {} // declareLogNoise declares that t is expected to emit the following noisy phrases, // even on success. Those phrases will be filtered from grpclog output // and only be shown if *verbose_logs or t ends up failing. // The returned restore function should be called with defer to be run // before the test ends. func declareLogNoise(t *testing.T, phrases ...string) (restore func()) { if *verboseLogs { return noop } fw := &filterWriter{dst: os.Stderr, filter: phrases} testLogOutput.setWriter(fw) return func() { if t.Failed() { fw.mu.Lock() defer fw.mu.Unlock() if fw.buf.Len() > 0 { t.Logf("Complete log output:\n%s", fw.buf.Bytes()) } } testLogOutput.setWriter(os.Stderr) } } type filterWriter struct { dst io.Writer filter []string mu sync.Mutex buf bytes.Buffer wakeup chan<- bool // if non-nil, gets true on write } func (fw *filterWriter) Write(p []byte) (n int, err error) { fw.mu.Lock() fw.buf.Write(p) if fw.wakeup != nil { select { case fw.wakeup <- true: default: } } fw.mu.Unlock() ps := string(p) for _, f := range fw.filter { if strings.Contains(ps, f) { return len(p), nil } } return fw.dst.Write(p) } func equalErrors(l, r error) bool { return grpc.Code(l) == grpc.Code(r) && grpc.ErrorDesc(l) == grpc.ErrorDesc(r) }