route/vendor/google.golang.org/grpc/test/end2end_test.go

5064 lines
152 KiB
Go

/*
*
* Copyright 2014 gRPC authors.
*
* Licensed under the Apache License, Version 2.0 (the "License");
* you may not use this file except in compliance with the License.
* You may obtain a copy of the License at
*
* http://www.apache.org/licenses/LICENSE-2.0
*
* Unless required by applicable law or agreed to in writing, software
* distributed under the License is distributed on an "AS IS" BASIS,
* WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
* See the License for the specific language governing permissions and
* limitations under the License.
*
*/
//go:generate protoc --go_out=plugins=grpc:. codec_perf/perf.proto
//go:generate protoc --go_out=plugins=grpc:. grpc_testing/test.proto
package test
import (
"bytes"
"crypto/tls"
"errors"
"flag"
"fmt"
"io"
"math"
"net"
"os"
"reflect"
"runtime"
"sort"
"strings"
"sync"
"syscall"
"testing"
"time"
"github.com/golang/protobuf/proto"
anypb "github.com/golang/protobuf/ptypes/any"
"golang.org/x/net/context"
"golang.org/x/net/http2"
spb "google.golang.org/genproto/googleapis/rpc/status"
"google.golang.org/grpc"
"google.golang.org/grpc/codes"
"google.golang.org/grpc/connectivity"
"google.golang.org/grpc/credentials"
_ "google.golang.org/grpc/grpclog/glogger"
"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/stats"
"google.golang.org/grpc/status"
"google.golang.org/grpc/tap"
testpb "google.golang.org/grpc/test/grpc_testing"
"google.golang.org/grpc/testdata"
)
var (
// For headers:
testMetadata = metadata.MD{
"key1": []string{"value1"},
"key2": []string{"value2"},
"key3-bin": []string{"binvalue1", string([]byte{1, 2, 3})},
}
testMetadata2 = metadata.MD{
"key1": []string{"value12"},
"key2": []string{"value22"},
}
// For trailers:
testTrailerMetadata = metadata.MD{
"tkey1": []string{"trailerValue1"},
"tkey2": []string{"trailerValue2"},
"tkey3-bin": []string{"trailerbinvalue1", string([]byte{3, 2, 1})},
}
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"
failAppUA = "fail-this-RPC"
detailedError = status.ErrorProto(&spb.Status{
Code: int32(codes.DataLoss),
Message: "error for testing: " + failAppUA,
Details: []*anypb.Any{{
TypeUrl: "url",
Value: []byte{6, 0, 0, 6, 1, 3},
}},
})
)
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.FromIncomingContext(ctx); ok {
// For testing purpose, returns an error if user-agent is failAppUA.
// To test that client gets the correct error.
if ua, ok := md["user-agent"]; !ok || strings.HasPrefix(ua[0], failAppUA) {
return nil, detailedError
}
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.FromIncomingContext(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 <nil>", md, err)
}
if err := grpc.SendHeader(ctx, testMetadata2); err != nil {
return nil, grpc.Errorf(grpc.Code(err), "grpc.SendHeader(_, %v) = %v, want <nil>", 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 <nil>", md, err)
}
if err := grpc.SetHeader(ctx, testMetadata2); err != nil {
return nil, grpc.Errorf(grpc.Code(err), "grpc.SetHeader(_, %v) = %v, want <nil>", testMetadata2, err)
}
} else {
if err := grpc.SendHeader(ctx, md); err != nil {
return nil, grpc.Errorf(grpc.Code(err), "grpc.SendHeader(_, %v) = %v, want <nil>", md, err)
}
}
if err := grpc.SetTrailer(ctx, testTrailerMetadata); err != nil {
return nil, grpc.Errorf(grpc.Code(err), "grpc.SetTrailer(_, %v) = %v, want <nil>", 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 <nil>", 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.FromIncomingContext(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 user-agent is failAppUA.
// To test that client gets the correct error.
if ua, ok := md["user-agent"]; !ok || strings.HasPrefix(ua[0], failAppUA) {
return grpc.Errorf(codes.DataLoss, "error for testing: "+failAppUA)
}
}
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.FromIncomingContext(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 <nil>", stream, md, err)
}
if err := stream.SendHeader(testMetadata2); err != nil {
return grpc.Errorf(grpc.Code(err), "%v.SendHeader(_, %v) = %v, want <nil>", 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 <nil>", stream, md, err)
}
if err := stream.SetHeader(testMetadata2); err != nil {
return grpc.Errorf(grpc.Code(err), "%v.SetHeader(_, %v) = %v, want <nil>", 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 {
// to facilitate testSvrWriteStatusEarlyWrite
if grpc.Code(err) == codes.ResourceExhausted {
return grpc.Errorf(codes.Internal, "fake error for test testSvrWriteStatusEarlyWrite. true error: %s", err.Error())
}
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 {
// to facilitate testSvrWriteStatusEarlyWrite
if grpc.Code(err) == codes.ResourceExhausted {
return grpc.Errorf(codes.Internal, "fake error for test testSvrWriteStatusEarlyWrite. true error: %s", err.Error())
}
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
}
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}
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
maxClientReceiveMsgSize *int
maxClientSendMsgSize *int
maxServerReceiveMsgSize *int
maxServerSendMsgSize *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
customCodec grpc.Codec
serverInitialWindowSize int32
serverInitialConnWindowSize int32
clientInitialWindowSize int32
clientInitialConnWindowSize int32
perRPCCreds credentials.PerRPCCredentials
// 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 != nil {
sopts = append(sopts, grpc.MaxMsgSize(*te.maxMsgSize))
}
if te.maxServerReceiveMsgSize != nil {
sopts = append(sopts, grpc.MaxRecvMsgSize(*te.maxServerReceiveMsgSize))
}
if te.maxServerSendMsgSize != nil {
sopts = append(sopts, grpc.MaxSendMsgSize(*te.maxServerSendMsgSize))
}
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))
}
if te.serverInitialWindowSize > 0 {
sopts = append(sopts, grpc.InitialWindowSize(te.serverInitialWindowSize))
}
if te.serverInitialConnWindowSize > 0 {
sopts = append(sopts, grpc.InitialConnWindowSize(te.serverInitialConnWindowSize))
}
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(testdata.Path("server1.pem"), testdata.Path("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{}))
}
if te.customCodec != nil {
sopts = append(sopts, grpc.CustomCodec(te.customCodec))
}
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 != nil {
opts = append(opts, grpc.WithMaxMsgSize(*te.maxMsgSize))
}
if te.maxClientReceiveMsgSize != nil {
opts = append(opts, grpc.WithDefaultCallOptions(grpc.MaxCallRecvMsgSize(*te.maxClientReceiveMsgSize)))
}
if te.maxClientSendMsgSize != nil {
opts = append(opts, grpc.WithDefaultCallOptions(grpc.MaxCallSendMsgSize(*te.maxClientSendMsgSize)))
}
switch te.e.security {
case "tls":
creds, err := credentials.NewClientTLSFromFile(testdata.Path("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)))
}
if te.clientInitialWindowSize > 0 {
opts = append(opts, grpc.WithInitialWindowSize(te.clientInitialWindowSize))
}
if te.clientInitialConnWindowSize > 0 {
opts = append(opts, grpc.WithInitialConnWindowSize(te.clientInitialConnWindowSize))
}
if te.perRPCCreds != nil {
opts = append(opts, grpc.WithPerRPCCredentials(te.perRPCCreds))
}
if te.customCodec != nil {
opts = append(opts, grpc.WithCodec(te.customCodec))
}
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 _, <nil>", err)
}
te.srv.Stop()
ctx, cancel := context.WithTimeout(context.Background(), time.Millisecond)
_, err := tc.EmptyCall(ctx, &testpb.Empty{}, grpc.FailFast(false))
cancel()
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 _, <nil>", 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, cancel := context.WithTimeout(context.Background(), 10*time.Millisecond)
if _, err := tc.EmptyCall(ctx, &testpb.Empty{}); err != nil && grpc.Code(err) != codes.DeadlineExceeded {
cancel()
break
}
cancel()
}
// 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 <nil>", 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 _, <nil>", 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, cancel := context.WithTimeout(context.Background(), 10*time.Millisecond)
if _, err := tc.EmptyCall(ctx, &testpb.Empty{}, grpc.FailFast(false)); err != nil {
cancel()
break
}
cancel()
}
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 <nil>", stream, req, err)
}
if _, err := stream.Recv(); err != nil {
t.Fatalf("%v.Recv() = _, %v, want _, <nil>", 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 <nil>", 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 _, <nil>", 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, cancel := context.WithTimeout(context.Background(), 10*time.Millisecond)
if _, err := tc.EmptyCall(ctx, &testpb.Empty{}, grpc.FailFast(false)); err != nil {
cancel()
break
}
cancel()
}
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 <nil>", stream, req, err)
}
if _, err := stream.Recv(); err != nil {
t.Fatalf("%v.Recv() = _, %v, want _, <nil>", stream, err)
}
if err := stream.CloseSend(); err != nil {
t.Fatalf("%v.CloseSend() = %v, want <nil>", 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 _, <nil>", 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 <nil>", 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 _, <nil>", 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, cancel := context.WithTimeout(context.Background(), 10*time.Millisecond)
if _, err := tc.EmptyCall(ctx, &testpb.Empty{}, grpc.FailFast(false)); err != nil {
cancel()
break
}
cancel()
}
// 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 _, <nil>", stream, err)
}
}
<-ch
awaitNewConnLogOutput()
}
func TestClientConnCloseAfterGoAwayWithActiveStream(t *testing.T) {
defer leakCheck(t)()
for _, e := range listTestEnv() {
if e.name == "handler-tls" {
continue
}
testClientConnCloseAfterGoAwayWithActiveStream(t, e)
}
}
func testClientConnCloseAfterGoAwayWithActiveStream(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)
if _, err := tc.FullDuplexCall(context.Background()); err != nil {
t.Fatalf("%v.FullDuplexCall(_) = _, %v, want _, <nil>", tc, err)
}
done := make(chan struct{})
go func() {
te.srv.GracefulStop()
close(done)
}()
time.Sleep(time.Second)
cc.Close()
timeout := time.NewTimer(time.Second)
select {
case <-done:
case <-timeout.C:
t.Fatalf("Test timed-out.")
}
}
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 _, <nil>", 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 testServiceConfigSetup(t *testing.T, e env) (*test, chan grpc.ServiceConfig) {
te := newTest(t, e)
// We write before read.
ch := make(chan grpc.ServiceConfig, 1)
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.",
)
return te, ch
}
func newBool(b bool) (a *bool) {
return &b
}
func newInt(b int) (a *int) {
return &b
}
func newDuration(b time.Duration) (a *time.Duration) {
a = new(time.Duration)
*a = b
return
}
func TestServiceConfigGetMethodConfig(t *testing.T) {
defer leakCheck(t)()
for _, e := range listTestEnv() {
testGetMethodConfig(t, e)
}
}
func testGetMethodConfig(t *testing.T, e env) {
te, ch := testServiceConfigSetup(t, e)
defer te.tearDown()
mc1 := grpc.MethodConfig{
WaitForReady: newBool(true),
Timeout: newDuration(time.Millisecond),
}
mc2 := grpc.MethodConfig{WaitForReady: newBool(false)}
m := make(map[string]grpc.MethodConfig)
m["/grpc.testing.TestService/EmptyCall"] = mc1
m["/grpc.testing.TestService/"] = mc2
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)
}
m = make(map[string]grpc.MethodConfig)
m["/grpc.testing.TestService/UnaryCall"] = mc1
m["/grpc.testing.TestService/"] = mc2
sc = grpc.ServiceConfig{
Methods: m,
}
ch <- sc
// Wait for the new service config to propagate.
for {
if _, err := tc.EmptyCall(context.Background(), &testpb.Empty{}); grpc.Code(err) == codes.DeadlineExceeded {
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)
}
}
func TestServiceConfigWaitForReady(t *testing.T) {
defer leakCheck(t)()
for _, e := range listTestEnv() {
testServiceConfigWaitForReady(t, e)
}
}
func testServiceConfigWaitForReady(t *testing.T, e env) {
te, ch := testServiceConfigSetup(t, e)
defer te.tearDown()
// Case1: Client API set failfast to be false, and service config set wait_for_ready to be false, Client API should win, and the rpc will wait until deadline exceeds.
mc := grpc.MethodConfig{
WaitForReady: newBool(false),
Timeout: newDuration(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.FailFast(false)); grpc.Code(err) != codes.DeadlineExceeded {
t.Fatalf("TestService/EmptyCall(_, _) = _, %v, want _, %s", err, codes.DeadlineExceeded)
}
if _, err := tc.FullDuplexCall(context.Background(), grpc.FailFast(false)); grpc.Code(err) != codes.DeadlineExceeded {
t.Fatalf("TestService/FullDuplexCall(_) = _, %v, want %s", err, codes.DeadlineExceeded)
}
// Generate a service config update.
// Case2: Client API does not set failfast, and service config set wait_for_ready to be true, and the rpc will wait until deadline exceeds.
mc.WaitForReady = newBool(true)
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
// Wait for the new service config to take effect.
mc = cc.GetMethodConfig("/grpc.testing.TestService/EmptyCall")
for {
if !*mc.WaitForReady {
time.Sleep(100 * time.Millisecond)
mc = cc.GetMethodConfig("/grpc.testing.TestService/EmptyCall")
continue
}
break
}
// 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)
}
}
func TestServiceConfigTimeout(t *testing.T) {
defer leakCheck(t)()
for _, e := range listTestEnv() {
testServiceConfigTimeout(t, e)
}
}
func testServiceConfigTimeout(t *testing.T, e env) {
te, ch := testServiceConfigSetup(t, e)
defer te.tearDown()
// Case1: Client API sets timeout to be 1ns and ServiceConfig sets timeout to be 1hr. Timeout should be 1ns (min of 1ns and 1hr) and the rpc will wait until deadline exceeds.
mc := grpc.MethodConfig{
Timeout: newDuration(time.Hour),
}
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 1ns deadline.
ctx, cancel := context.WithTimeout(context.Background(), time.Nanosecond)
if _, err := tc.EmptyCall(ctx, &testpb.Empty{}, grpc.FailFast(false)); grpc.Code(err) != codes.DeadlineExceeded {
t.Fatalf("TestService/EmptyCall(_, _) = _, %v, want _, %s", err, codes.DeadlineExceeded)
}
cancel()
ctx, cancel = context.WithTimeout(context.Background(), time.Nanosecond)
if _, err := tc.FullDuplexCall(ctx, grpc.FailFast(false)); grpc.Code(err) != codes.DeadlineExceeded {
t.Fatalf("TestService/FullDuplexCall(_) = _, %v, want %s", err, codes.DeadlineExceeded)
}
cancel()
// Generate a service config update.
// Case2: Client API sets timeout to be 1hr and ServiceConfig sets timeout to be 1ns. Timeout should be 1ns (min of 1ns and 1hr) and the rpc will wait until deadline exceeds.
mc.Timeout = newDuration(time.Nanosecond)
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
// Wait for the new service config to take effect.
mc = cc.GetMethodConfig("/grpc.testing.TestService/FullDuplexCall")
for {
if *mc.Timeout != time.Nanosecond {
time.Sleep(100 * time.Millisecond)
mc = cc.GetMethodConfig("/grpc.testing.TestService/FullDuplexCall")
continue
}
break
}
ctx, cancel = context.WithTimeout(context.Background(), time.Hour)
if _, err := tc.EmptyCall(ctx, &testpb.Empty{}, grpc.FailFast(false)); grpc.Code(err) != codes.DeadlineExceeded {
t.Fatalf("TestService/EmptyCall(_, _) = _, %v, want _, %s", err, codes.DeadlineExceeded)
}
cancel()
ctx, cancel = context.WithTimeout(context.Background(), time.Hour)
if _, err := tc.FullDuplexCall(ctx, grpc.FailFast(false)); grpc.Code(err) != codes.DeadlineExceeded {
t.Fatalf("TestService/FullDuplexCall(_) = _, %v, want %s", err, codes.DeadlineExceeded)
}
cancel()
}
func TestServiceConfigMaxMsgSize(t *testing.T) {
defer leakCheck(t)()
for _, e := range listTestEnv() {
testServiceConfigMaxMsgSize(t, e)
}
}
func testServiceConfigMaxMsgSize(t *testing.T, e env) {
// Setting up values and objects shared across all test cases.
const smallSize = 1
const largeSize = 1024
const extraLargeSize = 2048
smallPayload, err := newPayload(testpb.PayloadType_COMPRESSABLE, smallSize)
if err != nil {
t.Fatal(err)
}
largePayload, err := newPayload(testpb.PayloadType_COMPRESSABLE, largeSize)
if err != nil {
t.Fatal(err)
}
extraLargePayload, err := newPayload(testpb.PayloadType_COMPRESSABLE, extraLargeSize)
if err != nil {
t.Fatal(err)
}
mc := grpc.MethodConfig{
MaxReqSize: newInt(extraLargeSize),
MaxRespSize: newInt(extraLargeSize),
}
m := make(map[string]grpc.MethodConfig)
m["/grpc.testing.TestService/UnaryCall"] = mc
m["/grpc.testing.TestService/FullDuplexCall"] = mc
sc := grpc.ServiceConfig{
Methods: m,
}
// Case1: sc set maxReqSize to 2048 (send), maxRespSize to 2048 (recv).
te1, ch1 := testServiceConfigSetup(t, e)
te1.startServer(&testServer{security: e.security})
defer te1.tearDown()
ch1 <- sc
tc := testpb.NewTestServiceClient(te1.clientConn())
req := &testpb.SimpleRequest{
ResponseType: testpb.PayloadType_COMPRESSABLE.Enum(),
ResponseSize: proto.Int32(int32(extraLargeSize)),
Payload: smallPayload,
}
// Test for unary RPC recv.
if _, err := tc.UnaryCall(context.Background(), req); err == nil || grpc.Code(err) != codes.ResourceExhausted {
t.Fatalf("TestService/UnaryCall(_, _) = _, %v, want _, error code: %s", err, codes.ResourceExhausted)
}
// Test for unary RPC send.
req.Payload = extraLargePayload
req.ResponseSize = proto.Int32(int32(smallSize))
if _, err := tc.UnaryCall(context.Background(), req); err == nil || grpc.Code(err) != codes.ResourceExhausted {
t.Fatalf("TestService/UnaryCall(_, _) = _, %v, want _, error code: %s", err, codes.ResourceExhausted)
}
// Test for streaming RPC recv.
respParam := []*testpb.ResponseParameters{
{
Size: proto.Int32(int32(extraLargeSize)),
},
}
sreq := &testpb.StreamingOutputCallRequest{
ResponseType: testpb.PayloadType_COMPRESSABLE.Enum(),
ResponseParameters: respParam,
Payload: smallPayload,
}
stream, err := tc.FullDuplexCall(te1.ctx)
if err != nil {
t.Fatalf("%v.FullDuplexCall(_) = _, %v, want <nil>", tc, err)
}
if err := stream.Send(sreq); err != nil {
t.Fatalf("%v.Send(%v) = %v, want <nil>", stream, sreq, err)
}
if _, err := stream.Recv(); err == nil || grpc.Code(err) != codes.ResourceExhausted {
t.Fatalf("%v.Recv() = _, %v, want _, error code: %s", stream, err, codes.ResourceExhausted)
}
// Test for streaming RPC send.
respParam[0].Size = proto.Int32(int32(smallSize))
sreq.Payload = extraLargePayload
stream, err = tc.FullDuplexCall(te1.ctx)
if err != nil {
t.Fatalf("%v.FullDuplexCall(_) = _, %v, want <nil>", tc, err)
}
if err := stream.Send(sreq); err == nil || grpc.Code(err) != codes.ResourceExhausted {
t.Fatalf("%v.Send(%v) = %v, want _, error code: %s", stream, sreq, err, codes.ResourceExhausted)
}
// Case2: Client API set maxReqSize to 1024 (send), maxRespSize to 1024 (recv). Sc sets maxReqSize to 2048 (send), maxRespSize to 2048 (recv).
te2, ch2 := testServiceConfigSetup(t, e)
te2.maxClientReceiveMsgSize = newInt(1024)
te2.maxClientSendMsgSize = newInt(1024)
te2.startServer(&testServer{security: e.security})
defer te2.tearDown()
ch2 <- sc
tc = testpb.NewTestServiceClient(te2.clientConn())
// Test for unary RPC recv.
req.Payload = smallPayload
req.ResponseSize = proto.Int32(int32(largeSize))
if _, err := tc.UnaryCall(context.Background(), req); err == nil || grpc.Code(err) != codes.ResourceExhausted {
t.Fatalf("TestService/UnaryCall(_, _) = _, %v, want _, error code: %s", err, codes.ResourceExhausted)
}
// Test for unary RPC send.
req.Payload = largePayload
req.ResponseSize = proto.Int32(int32(smallSize))
if _, err := tc.UnaryCall(context.Background(), req); err == nil || grpc.Code(err) != codes.ResourceExhausted {
t.Fatalf("TestService/UnaryCall(_, _) = _, %v, want _, error code: %s", err, codes.ResourceExhausted)
}
// Test for streaming RPC recv.
stream, err = tc.FullDuplexCall(te2.ctx)
respParam[0].Size = proto.Int32(int32(largeSize))
sreq.Payload = smallPayload
if err != nil {
t.Fatalf("%v.FullDuplexCall(_) = _, %v, want <nil>", tc, err)
}
if err := stream.Send(sreq); err != nil {
t.Fatalf("%v.Send(%v) = %v, want <nil>", stream, sreq, err)
}
if _, err := stream.Recv(); err == nil || grpc.Code(err) != codes.ResourceExhausted {
t.Fatalf("%v.Recv() = _, %v, want _, error code: %s", stream, err, codes.ResourceExhausted)
}
// Test for streaming RPC send.
respParam[0].Size = proto.Int32(int32(smallSize))
sreq.Payload = largePayload
stream, err = tc.FullDuplexCall(te2.ctx)
if err != nil {
t.Fatalf("%v.FullDuplexCall(_) = _, %v, want <nil>", tc, err)
}
if err := stream.Send(sreq); err == nil || grpc.Code(err) != codes.ResourceExhausted {
t.Fatalf("%v.Send(%v) = %v, want _, error code: %s", stream, sreq, err, codes.ResourceExhausted)
}
// Case3: Client API set maxReqSize to 4096 (send), maxRespSize to 4096 (recv). Sc sets maxReqSize to 2048 (send), maxRespSize to 2048 (recv).
te3, ch3 := testServiceConfigSetup(t, e)
te3.maxClientReceiveMsgSize = newInt(4096)
te3.maxClientSendMsgSize = newInt(4096)
te3.startServer(&testServer{security: e.security})
defer te3.tearDown()
ch3 <- sc
tc = testpb.NewTestServiceClient(te3.clientConn())
// Test for unary RPC recv.
req.Payload = smallPayload
req.ResponseSize = proto.Int32(int32(largeSize))
if _, err := tc.UnaryCall(context.Background(), req); err != nil {
t.Fatalf("TestService/UnaryCall(_, _) = _, %v, want <nil>", err)
}
req.ResponseSize = proto.Int32(int32(extraLargeSize))
if _, err := tc.UnaryCall(context.Background(), req); err == nil || grpc.Code(err) != codes.ResourceExhausted {
t.Fatalf("TestService/UnaryCall(_, _) = _, %v, want _, error code: %s", err, codes.ResourceExhausted)
}
// Test for unary RPC send.
req.Payload = largePayload
req.ResponseSize = proto.Int32(int32(smallSize))
if _, err := tc.UnaryCall(context.Background(), req); err != nil {
t.Fatalf("TestService/UnaryCall(_, _) = _, %v, want <nil>", err)
}
req.Payload = extraLargePayload
if _, err := tc.UnaryCall(context.Background(), req); err == nil || grpc.Code(err) != codes.ResourceExhausted {
t.Fatalf("TestService/UnaryCall(_, _) = _, %v, want _, error code: %s", err, codes.ResourceExhausted)
}
// Test for streaming RPC recv.
stream, err = tc.FullDuplexCall(te3.ctx)
if err != nil {
t.Fatalf("%v.FullDuplexCall(_) = _, %v, want <nil>", tc, err)
}
respParam[0].Size = proto.Int32(int32(largeSize))
sreq.Payload = smallPayload
if err := stream.Send(sreq); err != nil {
t.Fatalf("%v.Send(%v) = %v, want <nil>", stream, sreq, err)
}
if _, err := stream.Recv(); err != nil {
t.Fatalf("%v.Recv() = _, %v, want <nil>", stream, err)
}
respParam[0].Size = proto.Int32(int32(extraLargeSize))
if err := stream.Send(sreq); err != nil {
t.Fatalf("%v.Send(%v) = %v, want <nil>", stream, sreq, err)
}
if _, err := stream.Recv(); err == nil || grpc.Code(err) != codes.ResourceExhausted {
t.Fatalf("%v.Recv() = _, %v, want _, error code: %s", stream, err, codes.ResourceExhausted)
}
// Test for streaming RPC send.
respParam[0].Size = proto.Int32(int32(smallSize))
sreq.Payload = largePayload
stream, err = tc.FullDuplexCall(te3.ctx)
if err != nil {
t.Fatalf("%v.FullDuplexCall(_) = _, %v, want <nil>", tc, err)
}
if err := stream.Send(sreq); err != nil {
t.Fatalf("%v.Send(%v) = %v, want <nil>", stream, sreq, err)
}
sreq.Payload = extraLargePayload
if err := stream.Send(sreq); err == nil || grpc.Code(err) != codes.ResourceExhausted {
t.Fatalf("%v.Send(%v) = %v, want _, error code: %s", stream, sreq, err, codes.ResourceExhausted)
}
}
func TestMaxMsgSizeClientDefault(t *testing.T) {
defer leakCheck(t)()
for _, e := range listTestEnv() {
testMaxMsgSizeClientDefault(t, e)
}
}
func testMaxMsgSizeClientDefault(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",
"Failed to dial : context canceled; please retry.",
)
te.startServer(&testServer{security: e.security})
defer te.tearDown()
tc := testpb.NewTestServiceClient(te.clientConn())
const smallSize = 1
const largeSize = 4 * 1024 * 1024
smallPayload, err := newPayload(testpb.PayloadType_COMPRESSABLE, smallSize)
if err != nil {
t.Fatal(err)
}
req := &testpb.SimpleRequest{
ResponseType: testpb.PayloadType_COMPRESSABLE.Enum(),
ResponseSize: proto.Int32(int32(largeSize)),
Payload: smallPayload,
}
// Test for unary RPC recv.
if _, err := tc.UnaryCall(context.Background(), req); err == nil || grpc.Code(err) != codes.ResourceExhausted {
t.Fatalf("TestService/UnaryCall(_, _) = _, %v, want _, error code: %s", err, codes.ResourceExhausted)
}
respParam := []*testpb.ResponseParameters{
{
Size: proto.Int32(int32(largeSize)),
},
}
sreq := &testpb.StreamingOutputCallRequest{
ResponseType: testpb.PayloadType_COMPRESSABLE.Enum(),
ResponseParameters: respParam,
Payload: smallPayload,
}
// Test for streaming RPC recv.
stream, err := tc.FullDuplexCall(te.ctx)
if err != nil {
t.Fatalf("%v.FullDuplexCall(_) = _, %v, want <nil>", tc, err)
}
if err := stream.Send(sreq); err != nil {
t.Fatalf("%v.Send(%v) = %v, want <nil>", stream, sreq, err)
}
if _, err := stream.Recv(); err == nil || grpc.Code(err) != codes.ResourceExhausted {
t.Fatalf("%v.Recv() = _, %v, want _, error code: %s", stream, err, codes.ResourceExhausted)
}
}
func TestMaxMsgSizeClientAPI(t *testing.T) {
defer leakCheck(t)()
for _, e := range listTestEnv() {
testMaxMsgSizeClientAPI(t, e)
}
}
func testMaxMsgSizeClientAPI(t *testing.T, e env) {
te := newTest(t, e)
te.userAgent = testAppUA
// To avoid error on server side.
te.maxServerSendMsgSize = newInt(5 * 1024 * 1024)
te.maxClientReceiveMsgSize = newInt(1024)
te.maxClientSendMsgSize = newInt(1024)
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.",
)
te.startServer(&testServer{security: e.security})
defer te.tearDown()
tc := testpb.NewTestServiceClient(te.clientConn())
const smallSize = 1
const largeSize = 1024
smallPayload, err := newPayload(testpb.PayloadType_COMPRESSABLE, smallSize)
if err != nil {
t.Fatal(err)
}
largePayload, err := newPayload(testpb.PayloadType_COMPRESSABLE, largeSize)
if err != nil {
t.Fatal(err)
}
req := &testpb.SimpleRequest{
ResponseType: testpb.PayloadType_COMPRESSABLE.Enum(),
ResponseSize: proto.Int32(int32(largeSize)),
Payload: smallPayload,
}
// Test for unary RPC recv.
if _, err := tc.UnaryCall(context.Background(), req); err == nil || grpc.Code(err) != codes.ResourceExhausted {
t.Fatalf("TestService/UnaryCall(_, _) = _, %v, want _, error code: %s", err, codes.ResourceExhausted)
}
// Test for unary RPC send.
req.Payload = largePayload
req.ResponseSize = proto.Int32(int32(smallSize))
if _, err := tc.UnaryCall(context.Background(), req); err == nil || grpc.Code(err) != codes.ResourceExhausted {
t.Fatalf("TestService/UnaryCall(_, _) = _, %v, want _, error code: %s", err, codes.ResourceExhausted)
}
respParam := []*testpb.ResponseParameters{
{
Size: proto.Int32(int32(largeSize)),
},
}
sreq := &testpb.StreamingOutputCallRequest{
ResponseType: testpb.PayloadType_COMPRESSABLE.Enum(),
ResponseParameters: respParam,
Payload: smallPayload,
}
// Test for streaming RPC recv.
stream, err := tc.FullDuplexCall(te.ctx)
if err != nil {
t.Fatalf("%v.FullDuplexCall(_) = _, %v, want <nil>", tc, err)
}
if err := stream.Send(sreq); err != nil {
t.Fatalf("%v.Send(%v) = %v, want <nil>", stream, sreq, err)
}
if _, err := stream.Recv(); err == nil || grpc.Code(err) != codes.ResourceExhausted {
t.Fatalf("%v.Recv() = _, %v, want _, error code: %s", stream, err, codes.ResourceExhausted)
}
// Test for streaming RPC send.
respParam[0].Size = proto.Int32(int32(smallSize))
sreq.Payload = largePayload
stream, err = tc.FullDuplexCall(te.ctx)
if err != nil {
t.Fatalf("%v.FullDuplexCall(_) = _, %v, want <nil>", tc, err)
}
if err := stream.Send(sreq); err == nil || grpc.Code(err) != codes.ResourceExhausted {
t.Fatalf("%v.Send(%v) = %v, want _, error code: %s", stream, sreq, err, codes.ResourceExhausted)
}
}
func TestMaxMsgSizeServerAPI(t *testing.T) {
defer leakCheck(t)()
for _, e := range listTestEnv() {
testMaxMsgSizeServerAPI(t, e)
}
}
func testMaxMsgSizeServerAPI(t *testing.T, e env) {
te := newTest(t, e)
te.userAgent = testAppUA
te.maxServerReceiveMsgSize = newInt(1024)
te.maxServerSendMsgSize = newInt(1024)
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.",
)
te.startServer(&testServer{security: e.security})
defer te.tearDown()
tc := testpb.NewTestServiceClient(te.clientConn())
const smallSize = 1
const largeSize = 1024
smallPayload, err := newPayload(testpb.PayloadType_COMPRESSABLE, smallSize)
if err != nil {
t.Fatal(err)
}
largePayload, err := newPayload(testpb.PayloadType_COMPRESSABLE, largeSize)
if err != nil {
t.Fatal(err)
}
req := &testpb.SimpleRequest{
ResponseType: testpb.PayloadType_COMPRESSABLE.Enum(),
ResponseSize: proto.Int32(int32(largeSize)),
Payload: smallPayload,
}
// Test for unary RPC send.
if _, err := tc.UnaryCall(context.Background(), req); err == nil || grpc.Code(err) != codes.ResourceExhausted {
t.Fatalf("TestService/UnaryCall(_, _) = _, %v, want _, error code: %s", err, codes.ResourceExhausted)
}
// Test for unary RPC recv.
req.Payload = largePayload
req.ResponseSize = proto.Int32(int32(smallSize))
if _, err := tc.UnaryCall(context.Background(), req); err == nil || grpc.Code(err) != codes.ResourceExhausted {
t.Fatalf("TestService/UnaryCall(_, _) = _, %v, want _, error code: %s", err, codes.ResourceExhausted)
}
respParam := []*testpb.ResponseParameters{
{
Size: proto.Int32(int32(largeSize)),
},
}
sreq := &testpb.StreamingOutputCallRequest{
ResponseType: testpb.PayloadType_COMPRESSABLE.Enum(),
ResponseParameters: respParam,
Payload: smallPayload,
}
// Test for streaming RPC send.
stream, err := tc.FullDuplexCall(te.ctx)
if err != nil {
t.Fatalf("%v.FullDuplexCall(_) = _, %v, want <nil>", tc, err)
}
if err := stream.Send(sreq); err != nil {
t.Fatalf("%v.Send(%v) = %v, want <nil>", stream, sreq, err)
}
if _, err := stream.Recv(); err == nil || grpc.Code(err) != codes.ResourceExhausted {
t.Fatalf("%v.Recv() = _, %v, want _, error code: %s", stream, err, codes.ResourceExhausted)
}
// Test for streaming RPC recv.
respParam[0].Size = proto.Int32(int32(smallSize))
sreq.Payload = largePayload
stream, err = tc.FullDuplexCall(te.ctx)
if err != nil {
t.Fatalf("%v.FullDuplexCall(_) = _, %v, want <nil>", tc, err)
}
if err := stream.Send(sreq); err != nil {
t.Fatalf("%v.Send(%v) = %v, want <nil>", stream, sreq, err)
}
if _, err := stream.Recv(); err == nil || grpc.Code(err) != codes.ResourceExhausted {
t.Fatalf("%v.Recv() = _, %v, want _, error code: %s", stream, err, codes.ResourceExhausted)
}
}
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 _, <nil>", 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, cancel := context.WithTimeout(context.Background(), d)
defer cancel()
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 _, <nil>", 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"); !reflect.DeepEqual(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(), ""); !reflect.DeepEqual(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(), ""); !reflect.DeepEqual(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 _, <nil>", 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"); !reflect.DeepEqual(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 _, <nil>", 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 _, <nil>", 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 <nil>", 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, <nil>", reply, err, &testpb.Empty{})
}
if v, ok := header["ua"]; !ok || !strings.HasPrefix(v[0], testAppUA) {
t.Fatalf("header[\"ua\"] = %q, %t, want string with prefix %q, true", v, ok, testAppUA)
}
te.srv.Stop()
}
func TestFailedEmptyUnary(t *testing.T) {
defer leakCheck(t)()
for _, e := range listTestEnv() {
if e.name == "handler-tls" {
// This test covers status details, but
// Grpc-Status-Details-Bin is not support in handler_server.
continue
}
testFailedEmptyUnary(t, e)
}
}
func testFailedEmptyUnary(t *testing.T, e env) {
te := newTest(t, e)
te.userAgent = failAppUA
te.startServer(&testServer{security: e.security})
defer te.tearDown()
tc := testpb.NewTestServiceClient(te.clientConn())
ctx := metadata.NewOutgoingContext(context.Background(), testMetadata)
wantErr := detailedError
if _, err := tc.EmptyCall(ctx, &testpb.Empty{}); !reflect.DeepEqual(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 _, <nil>", 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)
}
}
// Test backward-compatability API for setting msg size limit.
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 = newInt(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.ResourceExhausted {
t.Fatalf("TestService/UnaryCall(_, _) = _, %v, want _, error code: %s", err, codes.ResourceExhausted)
}
// 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.ResourceExhausted {
t.Fatalf("TestService/UnaryCall(_, _) = _, %v, want _, error code: %s", err, codes.ResourceExhausted)
}
// Test on server side for streaming RPC.
stream, err := tc.FullDuplexCall(te.ctx)
if err != nil {
t.Fatalf("%v.FullDuplexCall(_) = _, %v, want <nil>", 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 <nil>", stream, sreq, err)
}
if _, err := stream.Recv(); err == nil || grpc.Code(err) != codes.ResourceExhausted {
t.Fatalf("%v.Recv() = _, %v, want _, error code: %s", stream, err, codes.ResourceExhausted)
}
// Test on client side for streaming RPC.
stream, err = tc.FullDuplexCall(te.ctx)
if err != nil {
t.Fatalf("%v.FullDuplexCall(_) = _, %v, want <nil>", 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 <nil>", stream, sreq, err)
}
if _, err := stream.Recv(); err == nil || grpc.Code(err) != codes.ResourceExhausted {
t.Fatalf("%v.Recv() = _, %v, want _, error code: %s", stream, err, codes.ResourceExhausted)
}
}
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 _, <nil>", 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)
}
}
// TestPeerNegative tests that if call fails setting peer
// doesn't cause a segmentation fault.
// issue#1141 https://github.com/grpc/grpc-go/issues/1141
func TestPeerNegative(t *testing.T) {
defer leakCheck(t)()
for _, e := range listTestEnv() {
testPeerNegative(t, e)
}
}
func testPeerNegative(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)
peer := new(peer.Peer)
ctx, cancel := context.WithCancel(context.Background())
cancel()
tc.EmptyCall(ctx, &testpb.Empty{}, grpc.Peer(peer))
}
func TestPeerFailedRPC(t *testing.T) {
defer leakCheck(t)()
for _, e := range listTestEnv() {
testPeerFailedRPC(t, e)
}
}
func testPeerFailedRPC(t *testing.T, e env) {
te := newTest(t, e)
te.maxServerReceiveMsgSize = newInt(1 * 1024)
te.startServer(&testServer{security: e.security})
defer te.tearDown()
tc := testpb.NewTestServiceClient(te.clientConn())
// first make a successful request to the server
if _, err := tc.EmptyCall(context.Background(), &testpb.Empty{}); err != nil {
t.Fatalf("TestService/EmptyCall(_, _) = _, %v, want _, <nil>", err)
}
// make a second request that will be rejected by the server
const largeSize = 5 * 1024
largePayload, err := newPayload(testpb.PayloadType_COMPRESSABLE, largeSize)
if err != nil {
t.Fatal(err)
}
req := &testpb.SimpleRequest{
ResponseType: testpb.PayloadType_COMPRESSABLE.Enum(),
Payload: largePayload,
}
peer := new(peer.Peer)
if _, err := tc.UnaryCall(context.Background(), req, grpc.Peer(peer)); err == nil || grpc.Code(err) != codes.ResourceExhausted {
t.Fatalf("TestService/UnaryCall(_, _) = _, %v, want _, error code: %s", err, codes.ResourceExhausted)
} else {
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.NewOutgoingContext(context.Background(), testMetadata)
if _, err := tc.UnaryCall(ctx, req, grpc.Header(&header), grpc.Trailer(&trailer)); err != nil {
t.Fatalf("TestService.UnaryCall(%v, _, _, _) = _, %v; want _, <nil>", 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
delete(header, "user-agent")
}
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.NewOutgoingContext(context.Background(), testMetadata)
if _, err := tc.UnaryCall(ctx, req, grpc.Trailer(&trailer), grpc.FailFast(false)); err != nil {
t.Fatalf("TestService.UnaryCall(%v, _, _, _) = _, %v; want _, <nil>", 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.NewOutgoingContext(context.Background(), testMetadata)
stream, err := tc.FullDuplexCall(ctx, grpc.FailFast(false))
if err != nil {
t.Fatalf("%v.FullDuplexCall(_) = _, %v, want <nil>", 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.NewOutgoingContext(context.Background(), testMetadata)
if _, err := tc.UnaryCall(ctx, req, grpc.Header(&header), grpc.FailFast(false)); err != nil {
t.Fatalf("TestService.UnaryCall(%v, _, _, _) = _, %v; want _, <nil>", ctx, err)
}
delete(header, "user-agent")
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.NewOutgoingContext(context.Background(), testMetadata)
if _, err := tc.UnaryCall(ctx, req, grpc.Header(&header), grpc.FailFast(false)); err != nil {
t.Fatalf("TestService.UnaryCall(%v, _, _, _) = _, %v; want _, <nil>", ctx, err)
}
delete(header, "user-agent")
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.NewOutgoingContext(context.Background(), testMetadata)
if _, err := tc.UnaryCall(ctx, req, grpc.Header(&header), grpc.FailFast(false)); err == nil {
t.Fatalf("TestService.UnaryCall(%v, _, _, _) = _, %v; want _, <non-nil>", ctx, err)
}
delete(header, "user-agent")
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.NewOutgoingContext(context.Background(), testMetadata)
stream, err := tc.FullDuplexCall(ctx)
if err != nil {
t.Fatalf("%v.FullDuplexCall(_) = _, %v, want <nil>", 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 _, <nil>", stream, err)
}
delete(header, "user-agent")
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.NewOutgoingContext(context.Background(), testMetadata)
stream, err := tc.FullDuplexCall(ctx)
if err != nil {
t.Fatalf("%v.FullDuplexCall(_) = _, %v, want <nil>", 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 <nil>", stream, req, err)
}
if _, err := stream.Recv(); err != nil {
t.Fatalf("%v.Recv() = %v, want <nil>", 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 _, <nil>", stream, err)
}
delete(header, "user-agent")
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.NewOutgoingContext(context.Background(), testMetadata)
stream, err := tc.FullDuplexCall(ctx)
if err != nil {
t.Fatalf("%v.FullDuplexCall(_) = _, %v, want <nil>", 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 <nil>", stream, req, err)
}
if _, err := stream.Recv(); err == nil {
t.Fatalf("%v.Recv() = %v, want <non-nil>", stream, err)
}
header, err := stream.Header()
if err != nil {
t.Fatalf("%v.Header() = _, %v, want _, <nil>", stream, err)
}
delete(header, "user-agent")
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() {
if e.name == "handler-tls" {
// Failed with "server stops accepting new RPCs".
// Server stops accepting new RPCs when the client sends an illegal http2 header.
continue
}
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.NewOutgoingContext(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 _, <nil>", 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() {
if e.name == "handler-tls" {
// In race mode, with go1.6, the test never returns with handler_server.
continue
}
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, cancel := 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 <nil>, error code: %s", err, codes.DeadlineExceeded)
}
cancel()
}
}
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 _, <nil>", 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 _, <nil>", 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 <nil>", 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 <nil>", 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 <nil>", stream, req, err)
}
reply, err := stream.Recv()
if err != nil {
t.Fatalf("%v.Recv() = %v, want <nil>", 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.NewOutgoingContext(te.ctx, testMetadata)
stream, err := tc.FullDuplexCall(ctx)
if err != nil {
t.Fatalf("%v.FullDuplexCall(_) = _, %v, want <nil>", tc, err)
}
go func() {
headerMD, err := stream.Header()
if e.security == "tls" {
delete(headerMD, "transport_security_type")
}
delete(headerMD, "trailer") // ignore if present
delete(headerMD, "user-agent")
if err != nil || !reflect.DeepEqual(testMetadata, headerMD) {
t.Errorf("#1 %v.Header() = %v, %v, want %v, <nil>", stream, headerMD, err, testMetadata)
}
// test the cached value.
headerMD, err = stream.Header()
delete(headerMD, "trailer") // ignore if present
delete(headerMD, "user-agent")
if err != nil || !reflect.DeepEqual(testMetadata, headerMD) {
t.Errorf("#2 %v.Header() = %v, %v, want %v, <nil>", stream, headerMD, err, testMetadata)
}
err = func() error {
for index := 0; index < len(reqSizes); index++ {
respParam := []*testpb.ResponseParameters{
{
Size: proto.Int32(int32(respSizes[index])),
},
}
payload, err := newPayload(testpb.PayloadType_COMPRESSABLE, int32(reqSizes[index]))
if err != nil {
return err
}
req := &testpb.StreamingOutputCallRequest{
ResponseType: testpb.PayloadType_COMPRESSABLE.Enum(),
ResponseParameters: respParam,
Payload: payload,
}
if err := stream.Send(req); err != nil {
return fmt.Errorf("%v.Send(%v) = %v, want <nil>", stream, req, err)
}
}
return nil
}()
// Tell the server we're done sending args.
stream.CloseSend()
if err != nil {
t.Error(err)
}
}()
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 <nil>", 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 <EOF>", 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.userAgent = failAppUA
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.NewOutgoingContext(te.ctx, testMetadata)
stream, err := tc.StreamingOutputCall(ctx, req)
if err != nil {
t.Fatalf("%v.StreamingOutputCall(_) = _, %v, want <nil>", tc, err)
}
wantErr := grpc.Errorf(codes.DataLoss, "error for testing: "+failAppUA)
if _, err := stream.Recv(); !reflect.DeepEqual(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 <nil>", 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 generatePayloadSizes() [][]int {
reqSizes := [][]int{
{27182, 8, 1828, 45904},
}
num8KPayloads := 1024
eightKPayloads := []int{}
for i := 0; i < num8KPayloads; i++ {
eightKPayloads = append(eightKPayloads, (1 << 13))
}
reqSizes = append(reqSizes, eightKPayloads)
num2MPayloads := 8
twoMPayloads := []int{}
for i := 0; i < num2MPayloads; i++ {
twoMPayloads = append(twoMPayloads, (1 << 21))
}
reqSizes = append(reqSizes, twoMPayloads)
return reqSizes
}
func TestClientStreaming(t *testing.T) {
defer leakCheck(t)()
for _, s := range generatePayloadSizes() {
for _, e := range listTestEnv() {
testClientStreaming(t, e, s)
}
}
}
func testClientStreaming(t *testing.T, e env, sizes []int) {
te := newTest(t, e)
te.startServer(&testServer{security: e.security})
defer te.tearDown()
tc := testpb.NewTestServiceClient(te.clientConn())
ctx, cancel := context.WithTimeout(te.ctx, time.Second*30)
defer cancel()
stream, err := tc.StreamingInputCall(ctx)
if err != nil {
t.Fatalf("%v.StreamingInputCall(_) = _, %v, want <nil>", tc, err)
}
var sum int
for _, s := range sizes {
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 <nil>", 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 <nil>", 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 <nil>", 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 _, <nil>", 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() {
if e.name == "handler-tls" {
// The default max stream limit in handler_server is not 100?
continue
}
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 _, <nil>", 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 _, <nil>", 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.Error(err)
return
}
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, cancel := context.WithTimeout(context.Background(), 10*time.Millisecond)
defer cancel()
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 <nil>", 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 <nil>", 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.NewOutgoingContext(context.Background(), metadata.Pairs("something", "something"))
if _, err := tc.UnaryCall(ctx, req); err != nil {
t.Fatalf("TestService/UnaryCall(_, _) = _, %v, want _, <nil>", 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 <nil>", 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 <nil>", stream, sreq, err)
}
if _, err := stream.Recv(); err != nil {
t.Fatalf("%v.Recv() = %v, want <nil>", 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 _, <nil>", 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 <nil>", tc, err)
}
if err := s2.Send(req); err != nil {
t.Fatalf("%v.Send(_) = %v, want <nil>", s2, err)
}
if _, err := s2.Recv(); err != nil {
t.Fatalf("%v.Recv() = _, %v, want _, <nil>", 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 <nil>", 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", "localhost: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, <nil>", 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 * 5
)
requestCount := 10000
if raceMode {
requestCount = 1000
}
lis, err := net.Listen("tcp", "localhost: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, "testing.(*M).") ||
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, "(*loggingT).flushDaemon") ||
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
}
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)
}
// stubServer is a server that is easy to customize within individual test
// cases.
type stubServer struct {
// Guarantees we satisfy this interface; panics if unimplemented methods are called.
testpb.TestServiceServer
// Customizable implementations of server handlers.
emptyCall func(ctx context.Context, in *testpb.Empty) (*testpb.Empty, error)
fullDuplexCall func(stream testpb.TestService_FullDuplexCallServer) error
// A client connected to this service the test may use. Created in Start().
client testpb.TestServiceClient
cleanups []func() // Lambdas executed in Stop(); populated by Start().
}
func (ss *stubServer) EmptyCall(ctx context.Context, in *testpb.Empty) (*testpb.Empty, error) {
return ss.emptyCall(ctx, in)
}
func (ss *stubServer) FullDuplexCall(stream testpb.TestService_FullDuplexCallServer) error {
return ss.fullDuplexCall(stream)
}
// Start starts the server and creates a client connected to it.
func (ss *stubServer) Start(sopts []grpc.ServerOption) error {
lis, err := net.Listen("tcp", "localhost:0")
if err != nil {
return fmt.Errorf(`net.Listen("tcp", "localhost:0") = %v`, err)
}
ss.cleanups = append(ss.cleanups, func() { lis.Close() })
s := grpc.NewServer(sopts...)
testpb.RegisterTestServiceServer(s, ss)
go s.Serve(lis)
ss.cleanups = append(ss.cleanups, s.Stop)
cc, err := grpc.Dial(lis.Addr().String(), grpc.WithInsecure(), grpc.WithBlock())
if err != nil {
return fmt.Errorf("grpc.Dial(%q) = %v", lis.Addr().String(), err)
}
ss.cleanups = append(ss.cleanups, func() { cc.Close() })
ss.client = testpb.NewTestServiceClient(cc)
return nil
}
func (ss *stubServer) Stop() {
for i := len(ss.cleanups) - 1; i >= 0; i-- {
ss.cleanups[i]()
}
}
func TestUnaryProxyDoesNotForwardMetadata(t *testing.T) {
const mdkey = "somedata"
// endpoint ensures mdkey is NOT in metadata and returns an error if it is.
endpoint := &stubServer{
emptyCall: func(ctx context.Context, in *testpb.Empty) (*testpb.Empty, error) {
if md, ok := metadata.FromIncomingContext(ctx); !ok || md[mdkey] != nil {
return nil, status.Errorf(codes.Internal, "endpoint: md=%v; want !contains(%q)", md, mdkey)
}
return &testpb.Empty{}, nil
},
}
if err := endpoint.Start(nil); err != nil {
t.Fatalf("Error starting endpoint server: %v", err)
}
defer endpoint.Stop()
// proxy ensures mdkey IS in metadata, then forwards the RPC to endpoint
// without explicitly copying the metadata.
proxy := &stubServer{
emptyCall: func(ctx context.Context, in *testpb.Empty) (*testpb.Empty, error) {
if md, ok := metadata.FromIncomingContext(ctx); !ok || md[mdkey] == nil {
return nil, status.Errorf(codes.Internal, "proxy: md=%v; want contains(%q)", md, mdkey)
}
return endpoint.client.EmptyCall(ctx, in)
},
}
if err := proxy.Start(nil); err != nil {
t.Fatalf("Error starting proxy server: %v", err)
}
defer proxy.Stop()
ctx, cancel := context.WithTimeout(context.Background(), 2*time.Second)
defer cancel()
md := metadata.Pairs(mdkey, "val")
ctx = metadata.NewOutgoingContext(ctx, md)
// Sanity check that endpoint properly errors when it sees mdkey.
_, err := endpoint.client.EmptyCall(ctx, &testpb.Empty{})
if s, ok := status.FromError(err); !ok || s.Code() != codes.Internal {
t.Fatalf("endpoint.client.EmptyCall(_, _) = _, %v; want _, <status with Code()=Internal>", err)
}
if _, err := proxy.client.EmptyCall(ctx, &testpb.Empty{}); err != nil {
t.Fatal(err.Error())
}
}
func TestStreamingProxyDoesNotForwardMetadata(t *testing.T) {
const mdkey = "somedata"
// doFDC performs a FullDuplexCall with client and returns the error from the
// first stream.Recv call, or nil if that error is io.EOF. Calls t.Fatal if
// the stream cannot be established.
doFDC := func(ctx context.Context, client testpb.TestServiceClient) error {
stream, err := client.FullDuplexCall(ctx)
if err != nil {
t.Fatalf("Unwanted error: %v", err)
}
if _, err := stream.Recv(); err != io.EOF {
return err
}
return nil
}
// endpoint ensures mdkey is NOT in metadata and returns an error if it is.
endpoint := &stubServer{
fullDuplexCall: func(stream testpb.TestService_FullDuplexCallServer) error {
ctx := stream.Context()
if md, ok := metadata.FromIncomingContext(ctx); !ok || md[mdkey] != nil {
return status.Errorf(codes.Internal, "endpoint: md=%v; want !contains(%q)", md, mdkey)
}
return nil
},
}
if err := endpoint.Start(nil); err != nil {
t.Fatalf("Error starting endpoint server: %v", err)
}
defer endpoint.Stop()
// proxy ensures mdkey IS in metadata, then forwards the RPC to endpoint
// without explicitly copying the metadata.
proxy := &stubServer{
fullDuplexCall: func(stream testpb.TestService_FullDuplexCallServer) error {
ctx := stream.Context()
if md, ok := metadata.FromIncomingContext(ctx); !ok || md[mdkey] == nil {
return status.Errorf(codes.Internal, "endpoint: md=%v; want !contains(%q)", md, mdkey)
}
return doFDC(ctx, endpoint.client)
},
}
if err := proxy.Start(nil); err != nil {
t.Fatalf("Error starting proxy server: %v", err)
}
defer proxy.Stop()
ctx, cancel := context.WithTimeout(context.Background(), 2*time.Second)
defer cancel()
md := metadata.Pairs(mdkey, "val")
ctx = metadata.NewOutgoingContext(ctx, md)
// Sanity check that endpoint properly errors when it sees mdkey in ctx.
err := doFDC(ctx, endpoint.client)
if s, ok := status.FromError(err); !ok || s.Code() != codes.Internal {
t.Fatalf("stream.Recv() = _, %v; want _, <status with Code()=Internal>", err)
}
if err := doFDC(ctx, proxy.client); err != nil {
t.Fatalf("doFDC(_, proxy.client) = %v; want nil", err)
}
}
func TestStatsTagsAndTrace(t *testing.T) {
// Data added to context by client (typically in a stats handler).
tags := []byte{1, 5, 2, 4, 3}
trace := []byte{5, 2, 1, 3, 4}
// endpoint ensures Tags() and Trace() in context match those that were added
// by the client and returns an error if not.
endpoint := &stubServer{
emptyCall: func(ctx context.Context, in *testpb.Empty) (*testpb.Empty, error) {
md, _ := metadata.FromIncomingContext(ctx)
if tg := stats.Tags(ctx); !reflect.DeepEqual(tg, tags) {
return nil, status.Errorf(codes.Internal, "stats.Tags(%v)=%v; want %v", ctx, tg, tags)
}
if !reflect.DeepEqual(md["grpc-tags-bin"], []string{string(tags)}) {
return nil, status.Errorf(codes.Internal, "md['grpc-tags-bin']=%v; want %v", md["grpc-tags-bin"], tags)
}
if tr := stats.Trace(ctx); !reflect.DeepEqual(tr, trace) {
return nil, status.Errorf(codes.Internal, "stats.Trace(%v)=%v; want %v", ctx, tr, trace)
}
if !reflect.DeepEqual(md["grpc-trace-bin"], []string{string(trace)}) {
return nil, status.Errorf(codes.Internal, "md['grpc-trace-bin']=%v; want %v", md["grpc-trace-bin"], trace)
}
return &testpb.Empty{}, nil
},
}
if err := endpoint.Start(nil); err != nil {
t.Fatalf("Error starting endpoint server: %v", err)
}
defer endpoint.Stop()
ctx, cancel := context.WithTimeout(context.Background(), 2*time.Second)
defer cancel()
testCases := []struct {
ctx context.Context
want codes.Code
}{
{ctx: ctx, want: codes.Internal},
{ctx: stats.SetTags(ctx, tags), want: codes.Internal},
{ctx: stats.SetTrace(ctx, trace), want: codes.Internal},
{ctx: stats.SetTags(stats.SetTrace(ctx, tags), tags), want: codes.Internal},
{ctx: stats.SetTags(stats.SetTrace(ctx, trace), tags), want: codes.OK},
}
for _, tc := range testCases {
_, err := endpoint.client.EmptyCall(tc.ctx, &testpb.Empty{})
if tc.want == codes.OK && err != nil {
t.Fatalf("endpoint.client.EmptyCall(%v, _) = _, %v; want _, nil", tc.ctx, err)
}
if s, ok := status.FromError(err); !ok || s.Code() != tc.want {
t.Fatalf("endpoint.client.EmptyCall(%v, _) = _, %v; want _, <status with Code()=%v>", tc.ctx, err, tc.want)
}
}
}
func TestTapTimeout(t *testing.T) {
sopts := []grpc.ServerOption{
grpc.InTapHandle(func(ctx context.Context, _ *tap.Info) (context.Context, error) {
c, cancel := context.WithCancel(ctx)
// Call cancel instead of setting a deadline so we can detect which error
// occurred -- this cancellation (desired) or the client's deadline
// expired (indicating this cancellation did not affect the RPC).
time.AfterFunc(10*time.Millisecond, cancel)
return c, nil
}),
}
ss := &stubServer{
emptyCall: func(ctx context.Context, in *testpb.Empty) (*testpb.Empty, error) {
<-ctx.Done()
return &testpb.Empty{}, nil
},
}
if err := ss.Start(sopts); err != nil {
t.Fatalf("Error starting endpoint server: %v", err)
}
defer ss.Stop()
// This was known to be flaky; test several times.
for i := 0; i < 10; i++ {
// Set our own deadline in case the server hangs.
ctx, cancel := context.WithTimeout(context.Background(), 2*time.Second)
res, err := ss.client.EmptyCall(ctx, &testpb.Empty{})
cancel()
if s, ok := status.FromError(err); !ok || s.Code() != codes.Canceled {
t.Fatalf("ss.client.EmptyCall(context.Background(), _) = %v, %v; want nil, <status with Code()=Canceled>", res, err)
}
}
}
type windowSizeConfig struct {
serverStream int32
serverConn int32
clientStream int32
clientConn int32
}
func max(a, b int32) int32 {
if a > b {
return a
}
return b
}
func TestConfigurableWindowSizeWithLargeWindow(t *testing.T) {
defer leakCheck(t)()
wc := windowSizeConfig{
serverStream: 8 * 1024 * 1024,
serverConn: 12 * 1024 * 1024,
clientStream: 6 * 1024 * 1024,
clientConn: 8 * 1024 * 1024,
}
for _, e := range listTestEnv() {
testConfigurableWindowSize(t, e, wc)
}
}
func TestConfigurableWindowSizeWithSmallWindow(t *testing.T) {
defer leakCheck(t)()
wc := windowSizeConfig{
serverStream: 1,
serverConn: 1,
clientStream: 1,
clientConn: 1,
}
for _, e := range listTestEnv() {
testConfigurableWindowSize(t, e, wc)
}
}
func testConfigurableWindowSize(t *testing.T, e env, wc windowSizeConfig) {
te := newTest(t, e)
te.serverInitialWindowSize = wc.serverStream
te.serverInitialConnWindowSize = wc.serverConn
te.clientInitialWindowSize = wc.clientStream
te.clientInitialConnWindowSize = wc.clientConn
te.startServer(&testServer{security: e.security})
defer te.tearDown()
cc := te.clientConn()
tc := testpb.NewTestServiceClient(cc)
stream, err := tc.FullDuplexCall(context.Background())
if err != nil {
t.Fatalf("%v.FullDuplexCall(_) = _, %v, want <nil>", tc, err)
}
numOfIter := 11
// Set message size to exhaust largest of window sizes.
messageSize := max(max(wc.serverStream, wc.serverConn), max(wc.clientStream, wc.clientConn)) / int32(numOfIter-1)
messageSize = max(messageSize, 64*1024)
payload, err := newPayload(testpb.PayloadType_COMPRESSABLE, messageSize)
if err != nil {
t.Fatal(err)
}
respParams := []*testpb.ResponseParameters{
{
Size: proto.Int32(messageSize),
},
}
req := &testpb.StreamingOutputCallRequest{
ResponseType: testpb.PayloadType_COMPRESSABLE.Enum(),
ResponseParameters: respParams,
Payload: payload,
}
for i := 0; i < numOfIter; i++ {
if err := stream.Send(req); err != nil {
t.Fatalf("%v.Send(%v) = %v, want <nil>", stream, req, err)
}
if _, err := stream.Recv(); err != nil {
t.Fatalf("%v.Recv() = _, %v, want _, <nil>", stream, err)
}
}
if err := stream.CloseSend(); err != nil {
t.Fatalf("%v.CloseSend() = %v, want <nil>", stream, err)
}
}
var (
// test authdata
authdata = map[string]string{
"test-key": "test-value",
"test-key2-bin": string([]byte{1, 2, 3}),
}
)
type testPerRPCCredentials struct{}
func (cr testPerRPCCredentials) GetRequestMetadata(ctx context.Context, uri ...string) (map[string]string, error) {
return authdata, nil
}
func (cr testPerRPCCredentials) RequireTransportSecurity() bool {
return false
}
func authHandle(ctx context.Context, info *tap.Info) (context.Context, error) {
md, ok := metadata.FromIncomingContext(ctx)
if !ok {
return ctx, fmt.Errorf("didn't find metadata in context")
}
for k, vwant := range authdata {
vgot, ok := md[k]
if !ok {
return ctx, fmt.Errorf("didn't find authdata key %v in context", k)
}
if vgot[0] != vwant {
return ctx, fmt.Errorf("for key %v, got value %v, want %v", k, vgot, vwant)
}
}
return ctx, nil
}
func TestPerRPCCredentialsViaDialOptions(t *testing.T) {
defer leakCheck(t)()
for _, e := range listTestEnv() {
testPerRPCCredentialsViaDialOptions(t, e)
}
}
func testPerRPCCredentialsViaDialOptions(t *testing.T, e env) {
te := newTest(t, e)
te.tapHandle = authHandle
te.perRPCCreds = testPerRPCCredentials{}
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("Test failed. Reason: %v", err)
}
}
func TestPerRPCCredentialsViaCallOptions(t *testing.T) {
defer leakCheck(t)()
for _, e := range listTestEnv() {
testPerRPCCredentialsViaCallOptions(t, e)
}
}
func testPerRPCCredentialsViaCallOptions(t *testing.T, e env) {
te := newTest(t, e)
te.tapHandle = authHandle
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.PerRPCCredentials(testPerRPCCredentials{})); err != nil {
t.Fatalf("Test failed. Reason: %v", err)
}
}
func TestPerRPCCredentialsViaDialOptionsAndCallOptions(t *testing.T) {
defer leakCheck(t)()
for _, e := range listTestEnv() {
testPerRPCCredentialsViaDialOptionsAndCallOptions(t, e)
}
}
func testPerRPCCredentialsViaDialOptionsAndCallOptions(t *testing.T, e env) {
te := newTest(t, e)
te.perRPCCreds = testPerRPCCredentials{}
// When credentials are provided via both dial options and call options,
// we apply both sets.
te.tapHandle = func(ctx context.Context, _ *tap.Info) (context.Context, error) {
md, ok := metadata.FromIncomingContext(ctx)
if !ok {
return ctx, fmt.Errorf("couldn't find metadata in context")
}
for k, vwant := range authdata {
vgot, ok := md[k]
if !ok {
return ctx, fmt.Errorf("couldn't find metadata for key %v", k)
}
if len(vgot) != 2 {
return ctx, fmt.Errorf("len of value for key %v was %v, want 2", k, len(vgot))
}
if vgot[0] != vwant || vgot[1] != vwant {
return ctx, fmt.Errorf("value for %v was %v, want [%v, %v]", k, vgot, vwant, vwant)
}
}
return ctx, nil
}
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.PerRPCCredentials(testPerRPCCredentials{})); err != nil {
t.Fatalf("Test failed. Reason: %v", err)
}
}
func TestWaitForReadyConnection(t *testing.T) {
defer leakCheck(t)()
for _, e := range listTestEnv() {
testWaitForReadyConnection(t, e)
}
}
func testWaitForReadyConnection(t *testing.T, e env) {
te := newTest(t, e)
te.userAgent = testAppUA
te.startServer(&testServer{security: e.security})
defer te.tearDown()
cc := te.clientConn() // Non-blocking dial.
tc := testpb.NewTestServiceClient(cc)
ctx, cancel := context.WithTimeout(context.Background(), time.Second)
defer cancel()
state := cc.GetState()
// Wait for connection to be Ready.
for ; state != connectivity.Ready && cc.WaitForStateChange(ctx, state); state = cc.GetState() {
}
if state != connectivity.Ready {
t.Fatalf("Want connection state to be Ready, got %v", state)
}
ctx, cancel = context.WithTimeout(context.Background(), time.Second)
defer cancel()
// Make a fail-fast RPC.
if _, err := tc.EmptyCall(ctx, &testpb.Empty{}); err != nil {
t.Fatalf("TestService/EmptyCall(_,_) = _, %v, want _, nil", err)
}
}
type errCodec struct {
noError bool
}
func (c *errCodec) Marshal(v interface{}) ([]byte, error) {
if c.noError {
return []byte{}, nil
}
return nil, fmt.Errorf("3987^12 + 4365^12 = 4472^12")
}
func (c *errCodec) Unmarshal(data []byte, v interface{}) error {
return nil
}
func (c *errCodec) String() string {
return "Fermat's near-miss."
}
func TestEncodeDoesntPanic(t *testing.T) {
defer leakCheck(t)()
for _, e := range listTestEnv() {
testEncodeDoesntPanic(t, e)
}
}
func testEncodeDoesntPanic(t *testing.T, e env) {
te := newTest(t, e)
erc := &errCodec{}
te.customCodec = erc
te.startServer(&testServer{security: e.security})
defer te.tearDown()
te.customCodec = nil
tc := testpb.NewTestServiceClient(te.clientConn())
// Failure case, should not panic.
tc.EmptyCall(context.Background(), &testpb.Empty{})
erc.noError = true
// Passing case.
if _, err := tc.EmptyCall(context.Background(), &testpb.Empty{}); err != nil {
t.Fatalf("EmptyCall(_, _) = _, %v, want _, <nil>", err)
}
}
func TestSvrWriteStatusEarlyWrite(t *testing.T) {
defer leakCheck(t)()
for _, e := range listTestEnv() {
testSvrWriteStatusEarlyWrite(t, e)
}
}
func testSvrWriteStatusEarlyWrite(t *testing.T, e env) {
te := newTest(t, e)
const smallSize = 1024
const largeSize = 2048
const extraLargeSize = 4096
te.maxServerReceiveMsgSize = newInt(largeSize)
te.maxServerSendMsgSize = newInt(largeSize)
smallPayload, err := newPayload(testpb.PayloadType_COMPRESSABLE, smallSize)
if err != nil {
t.Fatal(err)
}
extraLargePayload, err := newPayload(testpb.PayloadType_COMPRESSABLE, extraLargeSize)
if err != nil {
t.Fatal(err)
}
te.startServer(&testServer{security: e.security})
defer te.tearDown()
tc := testpb.NewTestServiceClient(te.clientConn())
respParam := []*testpb.ResponseParameters{
{
Size: proto.Int32(int32(smallSize)),
},
}
sreq := &testpb.StreamingOutputCallRequest{
ResponseType: testpb.PayloadType_COMPRESSABLE.Enum(),
ResponseParameters: respParam,
Payload: extraLargePayload,
}
// Test recv case: server receives a message larger than maxServerReceiveMsgSize.
stream, err := tc.FullDuplexCall(te.ctx)
if err != nil {
t.Fatalf("%v.FullDuplexCall(_) = _, %v, want <nil>", tc, err)
}
if err = stream.Send(sreq); err != nil {
t.Fatalf("%v.Send() = _, %v, want <nil>", stream, err)
}
if _, err = stream.Recv(); err == nil || grpc.Code(err) != codes.ResourceExhausted {
t.Fatalf("%v.Recv() = _, %v, want _, error code: %s", stream, err, codes.ResourceExhausted)
}
// Test send case: server sends a message larger than maxServerSendMsgSize.
sreq.Payload = smallPayload
respParam[0].Size = proto.Int32(int32(extraLargeSize))
stream, err = tc.FullDuplexCall(te.ctx)
if err != nil {
t.Fatalf("%v.FullDuplexCall(_) = _, %v, want <nil>", tc, err)
}
if err = stream.Send(sreq); err != nil {
t.Fatalf("%v.Send(%v) = %v, want <nil>", stream, sreq, err)
}
if _, err = stream.Recv(); err == nil || grpc.Code(err) != codes.ResourceExhausted {
t.Fatalf("%v.Recv() = _, %v, want _, error code: %s", stream, err, codes.ResourceExhausted)
}
}