// // // Copyright 2015 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. // // #include #include #include #include "absl/memory/memory.h" #include #include #include #include #include #include #include #include #include #include #include #include #include "src/proto/grpc/testing/echo.grpc.pb.h" #include "test/core/test_util/port.h" #include "test/core/test_util/test_config.h" #include "test/cpp/util/byte_buffer_proto_helper.h" namespace grpc { namespace testing { namespace { void* tag(int i) { return reinterpret_cast(i); } void verify_ok(CompletionQueue* cq, int i, bool expect_ok) { bool ok; void* got_tag; EXPECT_TRUE(cq->Next(&got_tag, &ok)); EXPECT_EQ(expect_ok, ok); EXPECT_EQ(tag(i), got_tag); } class GenericEnd2endTest : public ::testing::Test { protected: GenericEnd2endTest() : server_host_("localhost") {} void SetUp() override { shut_down_ = false; int port = grpc_pick_unused_port_or_die(); server_address_ << server_host_ << ":" << port; // Setup server ServerBuilder builder; builder.AddListeningPort(server_address_.str(), InsecureServerCredentials()); builder.RegisterAsyncGenericService(&generic_service_); // Include a second call to RegisterAsyncGenericService to make sure that // we get an error in the log, since it is not allowed to have 2 async // generic services builder.RegisterAsyncGenericService(&generic_service_); srv_cq_ = builder.AddCompletionQueue(); server_ = builder.BuildAndStart(); } void ShutDownServerAndCQs() { if (!shut_down_) { server_->Shutdown(); void* ignored_tag; bool ignored_ok; cli_cq_.Shutdown(); srv_cq_->Shutdown(); while (cli_cq_.Next(&ignored_tag, &ignored_ok)) { } while (srv_cq_->Next(&ignored_tag, &ignored_ok)) { } shut_down_ = true; } } void TearDown() override { ShutDownServerAndCQs(); } void ResetStub() { std::shared_ptr channel = grpc::CreateChannel( server_address_.str(), InsecureChannelCredentials()); stub_ = grpc::testing::EchoTestService::NewStub(channel); generic_stub_ = std::make_unique(channel); } void server_ok(int i) { verify_ok(srv_cq_.get(), i, true); } void client_ok(int i) { verify_ok(&cli_cq_, i, true); } void server_fail(int i) { verify_ok(srv_cq_.get(), i, false); } void client_fail(int i) { verify_ok(&cli_cq_, i, false); } void SendRpc(int num_rpcs) { SendRpc(num_rpcs, false, gpr_inf_future(GPR_CLOCK_MONOTONIC)); } void SendRpc(int num_rpcs, bool check_deadline, gpr_timespec deadline) { const std::string kMethodName("/grpc.cpp.test.util.EchoTestService/Echo"); for (int i = 0; i < num_rpcs; i++) { EchoRequest send_request; EchoRequest recv_request; EchoResponse send_response; EchoResponse recv_response; Status recv_status; ClientContext cli_ctx; GenericServerContext srv_ctx; GenericServerAsyncReaderWriter stream(&srv_ctx); // The string needs to be long enough to test heap-based slice. send_request.set_message("Hello world. Hello world. Hello world."); if (check_deadline) { cli_ctx.set_deadline(deadline); } // Rather than using the original kMethodName, make a short-lived // copy to also confirm that we don't refer to this object beyond // the initial call preparation const std::string* method_name = new std::string(kMethodName); std::unique_ptr call = generic_stub_->PrepareCall(&cli_ctx, *method_name, &cli_cq_); delete method_name; // Make sure that this is not needed after invocation std::thread request_call([this]() { server_ok(4); }); call->StartCall(tag(1)); client_ok(1); std::unique_ptr send_buffer = SerializeToByteBuffer(&send_request); call->Write(*send_buffer, tag(2)); // Send ByteBuffer can be destroyed after calling Write. send_buffer.reset(); client_ok(2); call->WritesDone(tag(3)); client_ok(3); generic_service_.RequestCall(&srv_ctx, &stream, srv_cq_.get(), srv_cq_.get(), tag(4)); request_call.join(); EXPECT_EQ(server_host_, srv_ctx.host().substr(0, server_host_.length())); EXPECT_EQ(kMethodName, srv_ctx.method()); if (check_deadline) { EXPECT_TRUE(gpr_time_similar(deadline, srv_ctx.raw_deadline(), gpr_time_from_millis(1000, GPR_TIMESPAN))); } ByteBuffer recv_buffer; stream.Read(&recv_buffer, tag(5)); server_ok(5); EXPECT_TRUE(ParseFromByteBuffer(&recv_buffer, &recv_request)); EXPECT_EQ(send_request.message(), recv_request.message()); send_response.set_message(recv_request.message()); send_buffer = SerializeToByteBuffer(&send_response); stream.Write(*send_buffer, tag(6)); send_buffer.reset(); server_ok(6); stream.Finish(Status::OK, tag(7)); server_ok(7); recv_buffer.Clear(); call->Read(&recv_buffer, tag(8)); client_ok(8); EXPECT_TRUE(ParseFromByteBuffer(&recv_buffer, &recv_response)); call->Finish(&recv_status, tag(9)); client_ok(9); EXPECT_EQ(send_response.message(), recv_response.message()); EXPECT_TRUE(recv_status.ok()); } } // Return errors to up to one call that comes in on the supplied completion // queue, until the CQ is being shut down (and therefore we can no longer // enqueue further events). void DriveCompletionQueue() { enum class Event : uintptr_t { kCallReceived, kResponseSent, }; // Request the call, but only if the main thread hasn't beaten us to // shutting down the CQ. grpc::GenericServerContext server_context; grpc::GenericServerAsyncReaderWriter reader_writer(&server_context); { std::lock_guard lock(shutting_down_mu_); if (!shutting_down_) { generic_service_.RequestCall( &server_context, &reader_writer, srv_cq_.get(), srv_cq_.get(), reinterpret_cast(Event::kCallReceived)); } } // Process events. { Event event; bool ok; while (srv_cq_->Next(reinterpret_cast(&event), &ok)) { std::lock_guard lock(shutting_down_mu_); if (shutting_down_) { // The main thread has started shutting down. Simply continue to drain // events. continue; } switch (event) { case Event::kCallReceived: reader_writer.Finish( grpc::Status(grpc::StatusCode::UNIMPLEMENTED, "go away"), reinterpret_cast(Event::kResponseSent)); break; case Event::kResponseSent: // We are done. break; } } } } CompletionQueue cli_cq_; std::unique_ptr srv_cq_; std::unique_ptr stub_; std::unique_ptr generic_stub_; std::unique_ptr server_; AsyncGenericService generic_service_; const std::string server_host_; std::ostringstream server_address_; bool shutting_down_; bool shut_down_; std::mutex shutting_down_mu_; }; TEST_F(GenericEnd2endTest, SimpleRpc) { ResetStub(); SendRpc(1); } TEST_F(GenericEnd2endTest, SequentialRpcs) { ResetStub(); SendRpc(10); } TEST_F(GenericEnd2endTest, SequentialUnaryRpcs) { ResetStub(); const int num_rpcs = 10; const std::string kMethodName("/grpc.cpp.test.util.EchoTestService/Echo"); for (int i = 0; i < num_rpcs; i++) { EchoRequest send_request; EchoRequest recv_request; EchoResponse send_response; EchoResponse recv_response; Status recv_status; ClientContext cli_ctx; GenericServerContext srv_ctx; GenericServerAsyncReaderWriter stream(&srv_ctx); // The string needs to be long enough to test heap-based slice. send_request.set_message("Hello world. Hello world. Hello world."); std::unique_ptr cli_send_buffer = SerializeToByteBuffer(&send_request); std::thread request_call([this]() { server_ok(4); }); std::unique_ptr call = generic_stub_->PrepareUnaryCall(&cli_ctx, kMethodName, *cli_send_buffer, &cli_cq_); call->StartCall(); ByteBuffer cli_recv_buffer; call->Finish(&cli_recv_buffer, &recv_status, tag(1)); std::thread client_check([this] { client_ok(1); }); generic_service_.RequestCall(&srv_ctx, &stream, srv_cq_.get(), srv_cq_.get(), tag(4)); request_call.join(); EXPECT_EQ(server_host_, srv_ctx.host().substr(0, server_host_.length())); EXPECT_EQ(kMethodName, srv_ctx.method()); ByteBuffer srv_recv_buffer; stream.Read(&srv_recv_buffer, tag(5)); server_ok(5); EXPECT_TRUE(ParseFromByteBuffer(&srv_recv_buffer, &recv_request)); EXPECT_EQ(send_request.message(), recv_request.message()); send_response.set_message(recv_request.message()); std::unique_ptr srv_send_buffer = SerializeToByteBuffer(&send_response); stream.Write(*srv_send_buffer, tag(6)); server_ok(6); stream.Finish(Status::OK, tag(7)); server_ok(7); client_check.join(); EXPECT_TRUE(ParseFromByteBuffer(&cli_recv_buffer, &recv_response)); EXPECT_EQ(send_response.message(), recv_response.message()); EXPECT_TRUE(recv_status.ok()); } } // One ping, one pong. TEST_F(GenericEnd2endTest, SimpleBidiStreaming) { ResetStub(); const std::string kMethodName( "/grpc.cpp.test.util.EchoTestService/BidiStream"); EchoRequest send_request; EchoRequest recv_request; EchoResponse send_response; EchoResponse recv_response; Status recv_status; ClientContext cli_ctx; GenericServerContext srv_ctx; GenericServerAsyncReaderWriter srv_stream(&srv_ctx); cli_ctx.set_compression_algorithm(GRPC_COMPRESS_GZIP); send_request.set_message("Hello"); std::thread request_call([this]() { server_ok(2); }); std::unique_ptr cli_stream = generic_stub_->PrepareCall(&cli_ctx, kMethodName, &cli_cq_); cli_stream->StartCall(tag(1)); client_ok(1); generic_service_.RequestCall(&srv_ctx, &srv_stream, srv_cq_.get(), srv_cq_.get(), tag(2)); request_call.join(); EXPECT_EQ(server_host_, srv_ctx.host().substr(0, server_host_.length())); EXPECT_EQ(kMethodName, srv_ctx.method()); std::unique_ptr send_buffer = SerializeToByteBuffer(&send_request); cli_stream->Write(*send_buffer, tag(3)); send_buffer.reset(); client_ok(3); ByteBuffer recv_buffer; srv_stream.Read(&recv_buffer, tag(4)); server_ok(4); EXPECT_TRUE(ParseFromByteBuffer(&recv_buffer, &recv_request)); EXPECT_EQ(send_request.message(), recv_request.message()); send_response.set_message(recv_request.message()); send_buffer = SerializeToByteBuffer(&send_response); srv_stream.Write(*send_buffer, tag(5)); send_buffer.reset(); server_ok(5); cli_stream->Read(&recv_buffer, tag(6)); client_ok(6); EXPECT_TRUE(ParseFromByteBuffer(&recv_buffer, &recv_response)); EXPECT_EQ(send_response.message(), recv_response.message()); cli_stream->WritesDone(tag(7)); client_ok(7); srv_stream.Read(&recv_buffer, tag(8)); server_fail(8); srv_stream.Finish(Status::OK, tag(9)); server_ok(9); cli_stream->Finish(&recv_status, tag(10)); client_ok(10); EXPECT_EQ(send_response.message(), recv_response.message()); EXPECT_TRUE(recv_status.ok()); } TEST_F(GenericEnd2endTest, Deadline) { ResetStub(); SendRpc(1, true, gpr_time_add(gpr_now(GPR_CLOCK_MONOTONIC), gpr_time_from_seconds(10, GPR_TIMESPAN))); } TEST_F(GenericEnd2endTest, ShortDeadline) { ResetStub(); ClientContext cli_ctx; EchoRequest request; EchoResponse response; shutting_down_ = false; std::thread driver([this] { DriveCompletionQueue(); }); request.set_message(""); cli_ctx.set_deadline(gpr_time_add(gpr_now(GPR_CLOCK_MONOTONIC), gpr_time_from_micros(500, GPR_TIMESPAN))); Status s = stub_->Echo(&cli_ctx, request, &response); EXPECT_FALSE(s.ok()); { std::lock_guard lock(shutting_down_mu_); shutting_down_ = true; } ShutDownServerAndCQs(); driver.join(); } } // namespace } // namespace testing } // namespace grpc int main(int argc, char** argv) { grpc::testing::TestEnvironment env(&argc, argv); ::testing::InitGoogleTest(&argc, argv); return RUN_ALL_TESTS(); }