/* * * Copyright 2015, Google Inc. * All rights reserved. * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions are * met: * * * Redistributions of source code must retain the above copyright * notice, this list of conditions and the following disclaimer. * * Redistributions in binary form must reproduce the above * copyright notice, this list of conditions and the following disclaimer * in the documentation and/or other materials provided with the * distribution. * * Neither the name of Google Inc. nor the names of its * contributors may be used to endorse or promote products derived from * this software without specific prior written permission. * * THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS * "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT * LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR * A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT * OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, * SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT * LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, * DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY * THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT * (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE * OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. * */ #include "test/cpp/interop/interop_client.h" #include #include #include #include #include #include #include #include #include #include #include "src/core/lib/transport/byte_stream.h" #include "src/proto/grpc/testing/empty.grpc.pb.h" #include "src/proto/grpc/testing/messages.grpc.pb.h" #include "src/proto/grpc/testing/test.grpc.pb.h" #include "test/cpp/interop/client_helper.h" namespace grpc { namespace testing { static const char* kRandomFile = "test/cpp/interop/rnd.dat"; namespace { // The same value is defined by the Java client. const std::vector request_stream_sizes = {27182, 8, 1828, 45904}; const std::vector response_stream_sizes = {31415, 9, 2653, 58979}; const int kNumResponseMessages = 2000; const int kResponseMessageSize = 1030; const int kReceiveDelayMilliSeconds = 20; const int kLargeRequestSize = 271828; const int kLargeResponseSize = 314159; CompressionType GetInteropCompressionTypeFromCompressionAlgorithm( grpc_compression_algorithm algorithm) { switch (algorithm) { case GRPC_COMPRESS_NONE: return CompressionType::NONE; case GRPC_COMPRESS_GZIP: return CompressionType::GZIP; case GRPC_COMPRESS_DEFLATE: return CompressionType::DEFLATE; default: GPR_ASSERT(false); } } void NoopChecks(const InteropClientContextInspector& inspector, const SimpleRequest* request, const SimpleResponse* response) {} void CompressionChecks(const InteropClientContextInspector& inspector, const SimpleRequest* request, const SimpleResponse* response) { GPR_ASSERT(request->response_compression() == GetInteropCompressionTypeFromCompressionAlgorithm( inspector.GetCallCompressionAlgorithm())); if (request->response_compression() == NONE) { GPR_ASSERT(!(inspector.GetMessageFlags() & GRPC_WRITE_INTERNAL_COMPRESS)); } else if (request->response_type() == PayloadType::COMPRESSABLE) { // requested compression and compressable response => results should always // be compressed. GPR_ASSERT(inspector.GetMessageFlags() & GRPC_WRITE_INTERNAL_COMPRESS); } } } // namespace InteropClient::ServiceStub::ServiceStub(std::shared_ptr channel, bool new_stub_every_call) : channel_(channel), new_stub_every_call_(new_stub_every_call) { // If new_stub_every_call is false, then this is our chance to initialize // stub_. (see Get()) if (!new_stub_every_call) { stub_ = TestService::NewStub(channel); } } TestService::Stub* InteropClient::ServiceStub::Get() { if (new_stub_every_call_) { stub_ = TestService::NewStub(channel_); } return stub_.get(); } void InteropClient::ServiceStub::Reset(std::shared_ptr channel) { channel_ = channel; // Update stub_ as well. Note: If new_stub_every_call_ is true, we can reset // the stub_ since the next call to Get() will create a new stub if (new_stub_every_call_) { stub_.reset(); } else { stub_ = TestService::NewStub(channel); } } void InteropClient::Reset(std::shared_ptr channel) { serviceStub_.Reset(channel); } InteropClient::InteropClient(std::shared_ptr channel, bool new_stub_every_test_case, bool do_not_abort_on_transient_failures) : serviceStub_(channel, new_stub_every_test_case), do_not_abort_on_transient_failures_(do_not_abort_on_transient_failures) {} bool InteropClient::AssertStatusOk(const Status& s) { if (s.ok()) { return true; } // Note: At this point, s.error_code is definitely not StatusCode::OK (we // already checked for s.ok() above). So, the following will call abort() // (unless s.error_code() corresponds to a transient failure and // 'do_not_abort_on_transient_failures' is true) return AssertStatusCode(s, StatusCode::OK); } bool InteropClient::AssertStatusCode(const Status& s, StatusCode expected_code) { if (s.error_code() == expected_code) { return true; } gpr_log(GPR_ERROR, "Error status code: %d (expected: %d), message: %s", s.error_code(), expected_code, s.error_message().c_str()); // In case of transient transient/retryable failures (like a broken // connection) we may or may not abort (see TransientFailureOrAbort()) if (s.error_code() == grpc::StatusCode::UNAVAILABLE) { return TransientFailureOrAbort(); } abort(); } bool InteropClient::DoEmpty() { gpr_log(GPR_DEBUG, "Sending an empty rpc..."); Empty request = Empty::default_instance(); Empty response = Empty::default_instance(); ClientContext context; Status s = serviceStub_.Get()->EmptyCall(&context, request, &response); if (!AssertStatusOk(s)) { return false; } gpr_log(GPR_DEBUG, "Empty rpc done."); return true; } bool InteropClient::PerformLargeUnary(SimpleRequest* request, SimpleResponse* response) { return PerformLargeUnary(request, response, NoopChecks); } bool InteropClient::PerformLargeUnary(SimpleRequest* request, SimpleResponse* response, CheckerFn custom_checks_fn) { ClientContext context; InteropClientContextInspector inspector(context); // If the request doesn't already specify the response type, default to // COMPRESSABLE. request->set_response_size(kLargeResponseSize); grpc::string payload(kLargeRequestSize, '\0'); request->mutable_payload()->set_body(payload.c_str(), kLargeRequestSize); Status s = serviceStub_.Get()->UnaryCall(&context, *request, response); if (!AssertStatusOk(s)) { return false; } custom_checks_fn(inspector, request, response); // Payload related checks. if (request->response_type() != PayloadType::RANDOM) { GPR_ASSERT(response->payload().type() == request->response_type()); } switch (response->payload().type()) { case PayloadType::COMPRESSABLE: GPR_ASSERT(response->payload().body() == grpc::string(kLargeResponseSize, '\0')); break; case PayloadType::UNCOMPRESSABLE: { std::ifstream rnd_file(kRandomFile); GPR_ASSERT(rnd_file.good()); for (int i = 0; i < kLargeResponseSize; i++) { GPR_ASSERT(response->payload().body()[i] == (char)rnd_file.get()); } } break; default: GPR_ASSERT(false); } return true; } bool InteropClient::DoComputeEngineCreds( const grpc::string& default_service_account, const grpc::string& oauth_scope) { gpr_log(GPR_DEBUG, "Sending a large unary rpc with compute engine credentials ..."); SimpleRequest request; SimpleResponse response; request.set_fill_username(true); request.set_fill_oauth_scope(true); request.set_response_type(PayloadType::COMPRESSABLE); if (!PerformLargeUnary(&request, &response)) { return false; } gpr_log(GPR_DEBUG, "Got username %s", response.username().c_str()); gpr_log(GPR_DEBUG, "Got oauth_scope %s", response.oauth_scope().c_str()); GPR_ASSERT(!response.username().empty()); GPR_ASSERT(response.username().c_str() == default_service_account); GPR_ASSERT(!response.oauth_scope().empty()); const char* oauth_scope_str = response.oauth_scope().c_str(); GPR_ASSERT(oauth_scope.find(oauth_scope_str) != grpc::string::npos); gpr_log(GPR_DEBUG, "Large unary with compute engine creds done."); return true; } bool InteropClient::DoOauth2AuthToken(const grpc::string& username, const grpc::string& oauth_scope) { gpr_log(GPR_DEBUG, "Sending a unary rpc with raw oauth2 access token credentials ..."); SimpleRequest request; SimpleResponse response; request.set_fill_username(true); request.set_fill_oauth_scope(true); ClientContext context; Status s = serviceStub_.Get()->UnaryCall(&context, request, &response); if (!AssertStatusOk(s)) { return false; } GPR_ASSERT(!response.username().empty()); GPR_ASSERT(!response.oauth_scope().empty()); GPR_ASSERT(username == response.username()); const char* oauth_scope_str = response.oauth_scope().c_str(); GPR_ASSERT(oauth_scope.find(oauth_scope_str) != grpc::string::npos); gpr_log(GPR_DEBUG, "Unary with oauth2 access token credentials done."); return true; } bool InteropClient::DoPerRpcCreds(const grpc::string& json_key) { gpr_log(GPR_DEBUG, "Sending a unary rpc with per-rpc JWT access token ..."); SimpleRequest request; SimpleResponse response; request.set_fill_username(true); ClientContext context; std::chrono::seconds token_lifetime = std::chrono::hours(1); std::shared_ptr creds = ServiceAccountJWTAccessCredentials(json_key, token_lifetime.count()); context.set_credentials(creds); Status s = serviceStub_.Get()->UnaryCall(&context, request, &response); if (!AssertStatusOk(s)) { return false; } GPR_ASSERT(!response.username().empty()); GPR_ASSERT(json_key.find(response.username()) != grpc::string::npos); gpr_log(GPR_DEBUG, "Unary with per-rpc JWT access token done."); return true; } bool InteropClient::DoJwtTokenCreds(const grpc::string& username) { gpr_log(GPR_DEBUG, "Sending a large unary rpc with JWT token credentials ..."); SimpleRequest request; SimpleResponse response; request.set_fill_username(true); request.set_response_type(PayloadType::COMPRESSABLE); if (!PerformLargeUnary(&request, &response)) { return false; } GPR_ASSERT(!response.username().empty()); GPR_ASSERT(username.find(response.username()) != grpc::string::npos); gpr_log(GPR_DEBUG, "Large unary with JWT token creds done."); return true; } bool InteropClient::DoLargeUnary() { gpr_log(GPR_DEBUG, "Sending a large unary rpc..."); SimpleRequest request; SimpleResponse response; request.set_response_type(PayloadType::COMPRESSABLE); if (!PerformLargeUnary(&request, &response)) { return false; } gpr_log(GPR_DEBUG, "Large unary done."); return true; } bool InteropClient::DoLargeCompressedUnary() { const CompressionType compression_types[] = {NONE, GZIP, DEFLATE}; const PayloadType payload_types[] = {COMPRESSABLE, UNCOMPRESSABLE, RANDOM}; for (size_t i = 0; i < GPR_ARRAY_SIZE(payload_types); i++) { for (size_t j = 0; j < GPR_ARRAY_SIZE(compression_types); j++) { char* log_suffix; gpr_asprintf(&log_suffix, "(compression=%s; payload=%s)", CompressionType_Name(compression_types[j]).c_str(), PayloadType_Name(payload_types[i]).c_str()); gpr_log(GPR_DEBUG, "Sending a large compressed unary rpc %s.", log_suffix); SimpleRequest request; SimpleResponse response; request.set_response_type(payload_types[i]); request.set_response_compression(compression_types[j]); if (!PerformLargeUnary(&request, &response, CompressionChecks)) { gpr_log(GPR_ERROR, "Large compressed unary failed %s", log_suffix); gpr_free(log_suffix); return false; } gpr_log(GPR_DEBUG, "Large compressed unary done %s.", log_suffix); gpr_free(log_suffix); } } return true; } // Either abort() (unless do_not_abort_on_transient_failures_ is true) or return // false bool InteropClient::TransientFailureOrAbort() { if (do_not_abort_on_transient_failures_) { return false; } abort(); } bool InteropClient::DoRequestStreaming() { gpr_log(GPR_DEBUG, "Sending request steaming rpc ..."); ClientContext context; StreamingInputCallRequest request; StreamingInputCallResponse response; std::unique_ptr> stream( serviceStub_.Get()->StreamingInputCall(&context, &response)); int aggregated_payload_size = 0; for (unsigned int i = 0; i < request_stream_sizes.size(); ++i) { Payload* payload = request.mutable_payload(); payload->set_body(grpc::string(request_stream_sizes[i], '\0')); if (!stream->Write(request)) { gpr_log(GPR_ERROR, "DoRequestStreaming(): stream->Write() failed"); return TransientFailureOrAbort(); } aggregated_payload_size += request_stream_sizes[i]; } stream->WritesDone(); Status s = stream->Finish(); if (!AssertStatusOk(s)) { return false; } GPR_ASSERT(response.aggregated_payload_size() == aggregated_payload_size); return true; } bool InteropClient::DoResponseStreaming() { gpr_log(GPR_DEBUG, "Receiving response steaming rpc ..."); ClientContext context; StreamingOutputCallRequest request; for (unsigned int i = 0; i < response_stream_sizes.size(); ++i) { ResponseParameters* response_parameter = request.add_response_parameters(); response_parameter->set_size(response_stream_sizes[i]); } StreamingOutputCallResponse response; std::unique_ptr> stream( serviceStub_.Get()->StreamingOutputCall(&context, request)); unsigned int i = 0; while (stream->Read(&response)) { GPR_ASSERT(response.payload().body() == grpc::string(response_stream_sizes[i], '\0')); ++i; } if (i < response_stream_sizes.size()) { // stream->Read() failed before reading all the expected messages. This is // most likely due to connection failure. gpr_log(GPR_ERROR, "DoResponseStreaming(): Read fewer streams (%d) than " "response_stream_sizes.size() (%d)", i, response_stream_sizes.size()); return TransientFailureOrAbort(); } Status s = stream->Finish(); if (!AssertStatusOk(s)) { return false; } gpr_log(GPR_DEBUG, "Response streaming done."); return true; } bool InteropClient::DoResponseCompressedStreaming() { const CompressionType compression_types[] = {NONE, GZIP, DEFLATE}; const PayloadType payload_types[] = {COMPRESSABLE, UNCOMPRESSABLE, RANDOM}; for (size_t i = 0; i < GPR_ARRAY_SIZE(payload_types); i++) { for (size_t j = 0; j < GPR_ARRAY_SIZE(compression_types); j++) { ClientContext context; InteropClientContextInspector inspector(context); StreamingOutputCallRequest request; char* log_suffix; gpr_asprintf(&log_suffix, "(compression=%s; payload=%s)", CompressionType_Name(compression_types[j]).c_str(), PayloadType_Name(payload_types[i]).c_str()); gpr_log(GPR_DEBUG, "Receiving response steaming rpc %s.", log_suffix); request.set_response_type(payload_types[i]); request.set_response_compression(compression_types[j]); for (size_t k = 0; k < response_stream_sizes.size(); ++k) { ResponseParameters* response_parameter = request.add_response_parameters(); response_parameter->set_size(response_stream_sizes[k]); } StreamingOutputCallResponse response; std::unique_ptr> stream( serviceStub_.Get()->StreamingOutputCall(&context, request)); size_t k = 0; while (stream->Read(&response)) { // Payload related checks. if (request.response_type() != PayloadType::RANDOM) { GPR_ASSERT(response.payload().type() == request.response_type()); } switch (response.payload().type()) { case PayloadType::COMPRESSABLE: GPR_ASSERT(response.payload().body() == grpc::string(response_stream_sizes[k], '\0')); break; case PayloadType::UNCOMPRESSABLE: { std::ifstream rnd_file(kRandomFile); GPR_ASSERT(rnd_file.good()); for (int n = 0; n < response_stream_sizes[k]; n++) { GPR_ASSERT(response.payload().body()[n] == (char)rnd_file.get()); } } break; default: GPR_ASSERT(false); } // Compression related checks. GPR_ASSERT(request.response_compression() == GetInteropCompressionTypeFromCompressionAlgorithm( inspector.GetCallCompressionAlgorithm())); if (request.response_compression() == NONE) { GPR_ASSERT( !(inspector.GetMessageFlags() & GRPC_WRITE_INTERNAL_COMPRESS)); } else if (request.response_type() == PayloadType::COMPRESSABLE) { // requested compression and compressable response => results should // always be compressed. GPR_ASSERT(inspector.GetMessageFlags() & GRPC_WRITE_INTERNAL_COMPRESS); } ++k; } gpr_log(GPR_DEBUG, "Response streaming done %s.", log_suffix); gpr_free(log_suffix); if (k < response_stream_sizes.size()) { // stream->Read() failed before reading all the expected messages. This // is most likely due to a connection failure. gpr_log(GPR_ERROR, "DoResponseCompressedStreaming(): Responses read (k=%d) is " "less than the expected messages (i.e " "response_stream_sizes.size() (%d)). (i=%d, j=%d)", k, response_stream_sizes.size(), i, j); return TransientFailureOrAbort(); } Status s = stream->Finish(); if (!AssertStatusOk(s)) { return false; } } } return true; } bool InteropClient::DoResponseStreamingWithSlowConsumer() { gpr_log(GPR_DEBUG, "Receiving response steaming rpc with slow consumer ..."); ClientContext context; StreamingOutputCallRequest request; for (int i = 0; i < kNumResponseMessages; ++i) { ResponseParameters* response_parameter = request.add_response_parameters(); response_parameter->set_size(kResponseMessageSize); } StreamingOutputCallResponse response; std::unique_ptr> stream( serviceStub_.Get()->StreamingOutputCall(&context, request)); int i = 0; while (stream->Read(&response)) { GPR_ASSERT(response.payload().body() == grpc::string(kResponseMessageSize, '\0')); gpr_log(GPR_DEBUG, "received message %d", i); usleep(kReceiveDelayMilliSeconds * 1000); ++i; } if (i < kNumResponseMessages) { gpr_log(GPR_ERROR, "DoResponseStreamingWithSlowConsumer(): Responses read (i=%d) is " "less than the expected messages (i.e kNumResponseMessages = %d)", i, kNumResponseMessages); return TransientFailureOrAbort(); } Status s = stream->Finish(); if (!AssertStatusOk(s)) { return false; } gpr_log(GPR_DEBUG, "Response streaming done."); return true; } bool InteropClient::DoHalfDuplex() { gpr_log(GPR_DEBUG, "Sending half-duplex streaming rpc ..."); ClientContext context; std::unique_ptr> stream(serviceStub_.Get()->HalfDuplexCall(&context)); StreamingOutputCallRequest request; ResponseParameters* response_parameter = request.add_response_parameters(); for (unsigned int i = 0; i < response_stream_sizes.size(); ++i) { response_parameter->set_size(response_stream_sizes[i]); if (!stream->Write(request)) { gpr_log(GPR_ERROR, "DoHalfDuplex(): stream->Write() failed. i=%d", i); return TransientFailureOrAbort(); } } stream->WritesDone(); unsigned int i = 0; StreamingOutputCallResponse response; while (stream->Read(&response)) { GPR_ASSERT(response.payload().body() == grpc::string(response_stream_sizes[i], '\0')); ++i; } if (i < response_stream_sizes.size()) { // stream->Read() failed before reading all the expected messages. This is // most likely due to a connection failure gpr_log(GPR_ERROR, "DoHalfDuplex(): Responses read (i=%d) are less than the expected " "number of messages response_stream_sizes.size() (%d)", i, response_stream_sizes.size()); return TransientFailureOrAbort(); } Status s = stream->Finish(); if (!AssertStatusOk(s)) { return false; } gpr_log(GPR_DEBUG, "Half-duplex streaming rpc done."); return true; } bool InteropClient::DoPingPong() { gpr_log(GPR_DEBUG, "Sending Ping Pong streaming rpc ..."); ClientContext context; std::unique_ptr> stream(serviceStub_.Get()->FullDuplexCall(&context)); StreamingOutputCallRequest request; request.set_response_type(PayloadType::COMPRESSABLE); ResponseParameters* response_parameter = request.add_response_parameters(); Payload* payload = request.mutable_payload(); StreamingOutputCallResponse response; for (unsigned int i = 0; i < request_stream_sizes.size(); ++i) { response_parameter->set_size(response_stream_sizes[i]); payload->set_body(grpc::string(request_stream_sizes[i], '\0')); if (!stream->Write(request)) { gpr_log(GPR_ERROR, "DoPingPong(): stream->Write() failed. i: %d", i); return TransientFailureOrAbort(); } if (!stream->Read(&response)) { gpr_log(GPR_ERROR, "DoPingPong(): stream->Read() failed. i:%d", i); return TransientFailureOrAbort(); } GPR_ASSERT(response.payload().body() == grpc::string(response_stream_sizes[i], '\0')); } stream->WritesDone(); GPR_ASSERT(!stream->Read(&response)); Status s = stream->Finish(); if (!AssertStatusOk(s)) { return false; } gpr_log(GPR_DEBUG, "Ping pong streaming done."); return true; } bool InteropClient::DoCancelAfterBegin() { gpr_log(GPR_DEBUG, "Sending request steaming rpc ..."); ClientContext context; StreamingInputCallRequest request; StreamingInputCallResponse response; std::unique_ptr> stream( serviceStub_.Get()->StreamingInputCall(&context, &response)); gpr_log(GPR_DEBUG, "Trying to cancel..."); context.TryCancel(); Status s = stream->Finish(); if (!AssertStatusCode(s, StatusCode::CANCELLED)) { return false; } gpr_log(GPR_DEBUG, "Canceling streaming done."); return true; } bool InteropClient::DoCancelAfterFirstResponse() { gpr_log(GPR_DEBUG, "Sending Ping Pong streaming rpc ..."); ClientContext context; std::unique_ptr> stream(serviceStub_.Get()->FullDuplexCall(&context)); StreamingOutputCallRequest request; request.set_response_type(PayloadType::COMPRESSABLE); ResponseParameters* response_parameter = request.add_response_parameters(); response_parameter->set_size(31415); request.mutable_payload()->set_body(grpc::string(27182, '\0')); StreamingOutputCallResponse response; if (!stream->Write(request)) { gpr_log(GPR_ERROR, "DoCancelAfterFirstResponse(): stream->Write() failed"); return TransientFailureOrAbort(); } if (!stream->Read(&response)) { gpr_log(GPR_ERROR, "DoCancelAfterFirstResponse(): stream->Read failed"); return TransientFailureOrAbort(); } GPR_ASSERT(response.payload().body() == grpc::string(31415, '\0')); gpr_log(GPR_DEBUG, "Trying to cancel..."); context.TryCancel(); Status s = stream->Finish(); gpr_log(GPR_DEBUG, "Canceling pingpong streaming done."); return true; } bool InteropClient::DoTimeoutOnSleepingServer() { gpr_log(GPR_DEBUG, "Sending Ping Pong streaming rpc with a short deadline..."); ClientContext context; std::chrono::system_clock::time_point deadline = std::chrono::system_clock::now() + std::chrono::milliseconds(1); context.set_deadline(deadline); std::unique_ptr> stream(serviceStub_.Get()->FullDuplexCall(&context)); StreamingOutputCallRequest request; request.mutable_payload()->set_body(grpc::string(27182, '\0')); stream->Write(request); Status s = stream->Finish(); if (!AssertStatusCode(s, StatusCode::DEADLINE_EXCEEDED)) { return false; } gpr_log(GPR_DEBUG, "Pingpong streaming timeout done."); return true; } bool InteropClient::DoEmptyStream() { gpr_log(GPR_DEBUG, "Starting empty_stream."); ClientContext context; std::unique_ptr> stream(serviceStub_.Get()->FullDuplexCall(&context)); stream->WritesDone(); StreamingOutputCallResponse response; GPR_ASSERT(stream->Read(&response) == false); Status s = stream->Finish(); if (!AssertStatusOk(s)) { return false; } gpr_log(GPR_DEBUG, "empty_stream done."); return true; } bool InteropClient::DoStatusWithMessage() { gpr_log(GPR_DEBUG, "Sending RPC with a request for status code 2 and message"); ClientContext context; SimpleRequest request; SimpleResponse response; EchoStatus* requested_status = request.mutable_response_status(); requested_status->set_code(grpc::StatusCode::UNKNOWN); grpc::string test_msg = "This is a test message"; requested_status->set_message(test_msg); Status s = serviceStub_.Get()->UnaryCall(&context, request, &response); if (!AssertStatusCode(s, grpc::StatusCode::UNKNOWN)) { return false; } GPR_ASSERT(s.error_message() == test_msg); gpr_log(GPR_DEBUG, "Done testing Status and Message"); return true; } bool InteropClient::DoCustomMetadata() { const grpc::string kEchoInitialMetadataKey("x-grpc-test-echo-initial"); const grpc::string kInitialMetadataValue("test_initial_metadata_value"); const grpc::string kEchoTrailingBinMetadataKey( "x-grpc-test-echo-trailing-bin"); const grpc::string kTrailingBinValue("\x0a\x0b\x0a\x0b\x0a\x0b"); ; { gpr_log(GPR_DEBUG, "Sending RPC with custom metadata"); ClientContext context; context.AddMetadata(kEchoInitialMetadataKey, kInitialMetadataValue); context.AddMetadata(kEchoTrailingBinMetadataKey, kTrailingBinValue); SimpleRequest request; SimpleResponse response; request.set_response_size(kLargeResponseSize); grpc::string payload(kLargeRequestSize, '\0'); request.mutable_payload()->set_body(payload.c_str(), kLargeRequestSize); Status s = serviceStub_.Get()->UnaryCall(&context, request, &response); if (!AssertStatusOk(s)) { return false; } const auto& server_initial_metadata = context.GetServerInitialMetadata(); auto iter = server_initial_metadata.find(kEchoInitialMetadataKey); GPR_ASSERT(iter != server_initial_metadata.end()); GPR_ASSERT(iter->second.data() == kInitialMetadataValue); const auto& server_trailing_metadata = context.GetServerTrailingMetadata(); iter = server_trailing_metadata.find(kEchoTrailingBinMetadataKey); GPR_ASSERT(iter != server_trailing_metadata.end()); GPR_ASSERT(grpc::string(iter->second.begin(), iter->second.end()) == kTrailingBinValue); gpr_log(GPR_DEBUG, "Done testing RPC with custom metadata"); } { gpr_log(GPR_DEBUG, "Sending stream with custom metadata"); ClientContext context; context.AddMetadata(kEchoInitialMetadataKey, kInitialMetadataValue); context.AddMetadata(kEchoTrailingBinMetadataKey, kTrailingBinValue); std::unique_ptr> stream(serviceStub_.Get()->FullDuplexCall(&context)); StreamingOutputCallRequest request; request.set_response_type(PayloadType::COMPRESSABLE); ResponseParameters* response_parameter = request.add_response_parameters(); response_parameter->set_size(kLargeResponseSize); grpc::string payload(kLargeRequestSize, '\0'); request.mutable_payload()->set_body(payload.c_str(), kLargeRequestSize); StreamingOutputCallResponse response; if (!stream->Write(request)) { gpr_log(GPR_ERROR, "DoCustomMetadata(): stream->Write() failed"); return TransientFailureOrAbort(); } stream->WritesDone(); if (!stream->Read(&response)) { gpr_log(GPR_ERROR, "DoCustomMetadata(): stream->Read() failed"); return TransientFailureOrAbort(); } GPR_ASSERT(response.payload().body() == grpc::string(kLargeResponseSize, '\0')); GPR_ASSERT(!stream->Read(&response)); Status s = stream->Finish(); if (!AssertStatusOk(s)) { return false; } const auto& server_initial_metadata = context.GetServerInitialMetadata(); auto iter = server_initial_metadata.find(kEchoInitialMetadataKey); GPR_ASSERT(iter != server_initial_metadata.end()); GPR_ASSERT(iter->second.data() == kInitialMetadataValue); const auto& server_trailing_metadata = context.GetServerTrailingMetadata(); iter = server_trailing_metadata.find(kEchoTrailingBinMetadataKey); GPR_ASSERT(iter != server_trailing_metadata.end()); GPR_ASSERT(grpc::string(iter->second.begin(), iter->second.end()) == kTrailingBinValue); gpr_log(GPR_DEBUG, "Done testing stream with custom metadata"); } return true; } } // namespace testing } // namespace grpc