/* * * 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 #include #include #include #include #include #include #include #include #include #include #include #include #include "src/core/lib/profiling/timers.h" #include "src/proto/grpc/testing/services.grpc.pb.h" #include "test/cpp/qps/client.h" #include "test/cpp/qps/interarrival.h" #include "test/cpp/qps/usage_timer.h" namespace grpc { namespace testing { static std::unique_ptr BenchmarkStubCreator( std::shared_ptr ch) { return BenchmarkService::NewStub(ch); } class SynchronousClient : public ClientImpl { public: SynchronousClient(const ClientConfig& config) : ClientImpl( config, BenchmarkStubCreator) { num_threads_ = config.outstanding_rpcs_per_channel() * config.client_channels(); responses_.resize(num_threads_); SetupLoadTest(config, num_threads_); } virtual ~SynchronousClient(){}; virtual void InitThreadFuncImpl(size_t thread_idx) = 0; virtual bool ThreadFuncImpl(HistogramEntry* entry, size_t thread_idx) = 0; void ThreadFunc(size_t thread_idx, Thread* t) override { InitThreadFuncImpl(thread_idx); for (;;) { // run the loop body HistogramEntry entry; const bool thread_still_ok = ThreadFuncImpl(&entry, thread_idx); t->UpdateHistogram(&entry); if (!thread_still_ok) { gpr_log(GPR_ERROR, "Finishing client thread due to RPC error"); } if (!thread_still_ok || ThreadCompleted()) { return; } } } protected: // WaitToIssue returns false if we realize that we need to break out bool WaitToIssue(int thread_idx) { if (!closed_loop_) { const gpr_timespec next_issue_time = NextIssueTime(thread_idx); // Avoid sleeping for too long continuously because we might // need to terminate before then. This is an issue since // exponential distribution can occasionally produce bad outliers while (true) { const gpr_timespec one_sec_delay = gpr_time_add(gpr_now(GPR_CLOCK_MONOTONIC), gpr_time_from_seconds(1, GPR_TIMESPAN)); if (gpr_time_cmp(next_issue_time, one_sec_delay) <= 0) { gpr_sleep_until(next_issue_time); return true; } else { gpr_sleep_until(one_sec_delay); if (gpr_atm_acq_load(&thread_pool_done_) != static_cast(0)) { return false; } } } } return true; } size_t num_threads_; std::vector responses_; private: void DestroyMultithreading() override final { EndThreads(); } }; class SynchronousUnaryClient final : public SynchronousClient { public: SynchronousUnaryClient(const ClientConfig& config) : SynchronousClient(config) { StartThreads(num_threads_); } ~SynchronousUnaryClient() {} void InitThreadFuncImpl(size_t thread_idx) override {} bool ThreadFuncImpl(HistogramEntry* entry, size_t thread_idx) override { if (!WaitToIssue(thread_idx)) { return true; } auto* stub = channels_[thread_idx % channels_.size()].get_stub(); double start = UsageTimer::Now(); GPR_TIMER_SCOPE("SynchronousUnaryClient::ThreadFunc", 0); grpc::ClientContext context; grpc::Status s = stub->UnaryCall(&context, request_, &responses_[thread_idx]); if (s.ok()) { entry->set_value((UsageTimer::Now() - start) * 1e9); } entry->set_status(s.error_code()); return true; } }; template class SynchronousStreamingClient : public SynchronousClient { public: SynchronousStreamingClient(const ClientConfig& config) : SynchronousClient(config), context_(num_threads_), stream_(num_threads_), messages_per_stream_(config.messages_per_stream()), messages_issued_(num_threads_) { StartThreads(num_threads_); } virtual ~SynchronousStreamingClient() { std::vector cleanup_threads; for (size_t i = 0; i < num_threads_; i++) { cleanup_threads.emplace_back([this, i]() { auto stream = &stream_[i]; if (*stream) { // forcibly cancel the streams, then finish context_[i].TryCancel(); (*stream)->Finish().IgnoreError(); // don't log any error message on !ok since this was canceled } }); } for (auto& th : cleanup_threads) { th.join(); } } protected: std::vector context_; std::vector> stream_; const int messages_per_stream_; std::vector messages_issued_; void FinishStream(HistogramEntry* entry, size_t thread_idx) { Status s = stream_[thread_idx]->Finish(); // don't set the value since the stream is failed and shouldn't be timed entry->set_status(s.error_code()); if (!s.ok()) { gpr_log(GPR_ERROR, "Stream %" PRIuPTR " received an error %s", thread_idx, s.error_message().c_str()); } context_[thread_idx].~ClientContext(); new (&context_[thread_idx]) ClientContext(); } }; class SynchronousStreamingPingPongClient final : public SynchronousStreamingClient< grpc::ClientReaderWriter> { public: SynchronousStreamingPingPongClient(const ClientConfig& config) : SynchronousStreamingClient(config) {} ~SynchronousStreamingPingPongClient() { std::vector cleanup_threads; for (size_t i = 0; i < num_threads_; i++) { cleanup_threads.emplace_back([this, i]() { auto stream = &stream_[i]; if (*stream) { (*stream)->WritesDone(); } }); } for (auto& th : cleanup_threads) { th.join(); } } void InitThreadFuncImpl(size_t thread_idx) override { auto* stub = channels_[thread_idx % channels_.size()].get_stub(); stream_[thread_idx] = stub->StreamingCall(&context_[thread_idx]); messages_issued_[thread_idx] = 0; } bool ThreadFuncImpl(HistogramEntry* entry, size_t thread_idx) override { if (!WaitToIssue(thread_idx)) { return true; } GPR_TIMER_SCOPE("SynchronousStreamingPingPongClient::ThreadFunc", 0); double start = UsageTimer::Now(); if (stream_[thread_idx]->Write(request_) && stream_[thread_idx]->Read(&responses_[thread_idx])) { entry->set_value((UsageTimer::Now() - start) * 1e9); // don't set the status since there isn't one yet if ((messages_per_stream_ != 0) && (++messages_issued_[thread_idx] < messages_per_stream_)) { return true; } else if (messages_per_stream_ == 0) { return true; } else { // Fall through to the below resetting code after finish } } stream_[thread_idx]->WritesDone(); FinishStream(entry, thread_idx); auto* stub = channels_[thread_idx % channels_.size()].get_stub(); stream_[thread_idx] = stub->StreamingCall(&context_[thread_idx]); messages_issued_[thread_idx] = 0; return true; } }; class SynchronousStreamingFromClientClient final : public SynchronousStreamingClient> { public: SynchronousStreamingFromClientClient(const ClientConfig& config) : SynchronousStreamingClient(config), last_issue_(num_threads_) {} ~SynchronousStreamingFromClientClient() { std::vector cleanup_threads; for (size_t i = 0; i < num_threads_; i++) { cleanup_threads.emplace_back([this, i]() { auto stream = &stream_[i]; if (*stream) { (*stream)->WritesDone(); } }); } for (auto& th : cleanup_threads) { th.join(); } } void InitThreadFuncImpl(size_t thread_idx) override { auto* stub = channels_[thread_idx % channels_.size()].get_stub(); stream_[thread_idx] = stub->StreamingFromClient(&context_[thread_idx], &responses_[thread_idx]); last_issue_[thread_idx] = UsageTimer::Now(); } bool ThreadFuncImpl(HistogramEntry* entry, size_t thread_idx) override { // Figure out how to make histogram sensible if this is rate-paced if (!WaitToIssue(thread_idx)) { return true; } GPR_TIMER_SCOPE("SynchronousStreamingFromClientClient::ThreadFunc", 0); if (stream_[thread_idx]->Write(request_)) { double now = UsageTimer::Now(); entry->set_value((now - last_issue_[thread_idx]) * 1e9); last_issue_[thread_idx] = now; return true; } stream_[thread_idx]->WritesDone(); FinishStream(entry, thread_idx); auto* stub = channels_[thread_idx % channels_.size()].get_stub(); stream_[thread_idx] = stub->StreamingFromClient(&context_[thread_idx], &responses_[thread_idx]); return true; } private: std::vector last_issue_; }; class SynchronousStreamingFromServerClient final : public SynchronousStreamingClient> { public: SynchronousStreamingFromServerClient(const ClientConfig& config) : SynchronousStreamingClient(config), last_recv_(num_threads_) {} void InitThreadFuncImpl(size_t thread_idx) override { auto* stub = channels_[thread_idx % channels_.size()].get_stub(); stream_[thread_idx] = stub->StreamingFromServer(&context_[thread_idx], request_); last_recv_[thread_idx] = UsageTimer::Now(); } bool ThreadFuncImpl(HistogramEntry* entry, size_t thread_idx) override { GPR_TIMER_SCOPE("SynchronousStreamingFromServerClient::ThreadFunc", 0); if (stream_[thread_idx]->Read(&responses_[thread_idx])) { double now = UsageTimer::Now(); entry->set_value((now - last_recv_[thread_idx]) * 1e9); last_recv_[thread_idx] = now; return true; } FinishStream(entry, thread_idx); auto* stub = channels_[thread_idx % channels_.size()].get_stub(); stream_[thread_idx] = stub->StreamingFromServer(&context_[thread_idx], request_); return true; } private: std::vector last_recv_; }; class SynchronousStreamingBothWaysClient final : public SynchronousStreamingClient< grpc::ClientReaderWriter> { public: SynchronousStreamingBothWaysClient(const ClientConfig& config) : SynchronousStreamingClient(config) {} ~SynchronousStreamingBothWaysClient() { std::vector cleanup_threads; for (size_t i = 0; i < num_threads_; i++) { cleanup_threads.emplace_back([this, i]() { auto stream = &stream_[i]; if (*stream) { (*stream)->WritesDone(); } }); } for (auto& th : cleanup_threads) { th.join(); } } void InitThreadFuncImpl(size_t thread_idx) override { auto* stub = channels_[thread_idx % channels_.size()].get_stub(); stream_[thread_idx] = stub->StreamingBothWays(&context_[thread_idx]); } bool ThreadFuncImpl(HistogramEntry* entry, size_t thread_idx) override { // TODO (vjpai): Do this return true; } }; std::unique_ptr CreateSynchronousClient(const ClientConfig& config) { switch (config.rpc_type()) { case UNARY: return std::unique_ptr(new SynchronousUnaryClient(config)); case STREAMING: return std::unique_ptr( new SynchronousStreamingPingPongClient(config)); case STREAMING_FROM_CLIENT: return std::unique_ptr( new SynchronousStreamingFromClientClient(config)); case STREAMING_FROM_SERVER: return std::unique_ptr( new SynchronousStreamingFromServerClient(config)); case STREAMING_BOTH_WAYS: return std::unique_ptr( new SynchronousStreamingBothWaysClient(config)); default: assert(false); return nullptr; } } } // namespace testing } // namespace grpc