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/*
*
* Copyright 2016 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.
*
*/
/* Benchmark gRPC end2end in various configurations */
#include <benchmark/benchmark.h>
#include <fstream>
#include "absl/flags/flag.h"
#include "absl/memory/memory.h"
#include "src/core/ext/transport/chttp2/transport/chttp2_transport.h"
#include "src/core/ext/transport/chttp2/transport/internal.h"
#include "src/core/lib/iomgr/timer_manager.h"
#include "src/core/lib/profiling/timers.h"
#include "src/proto/grpc/testing/echo.grpc.pb.h"
#include "test/core/util/resource_user_util.h"
#include "test/core/util/test_config.h"
#include "test/core/util/trickle_endpoint.h"
#include "test/cpp/microbenchmarks/fullstack_context_mutators.h"
#include "test/cpp/microbenchmarks/fullstack_fixtures.h"
#include "test/cpp/util/test_config.h"
ABSL_FLAG(bool, log, false, "Log state to CSV files");
ABSL_FLAG(int32_t, warmup_megabytes, 1,
"Number of megabytes to pump before collecting flow control stats");
ABSL_FLAG(int32_t, warmup_iterations, 100,
"Number of iterations to run before collecting flow control stats");
ABSL_FLAG(int32_t, warmup_max_time_seconds, 10,
"Maximum number of seconds to run warmup loop");
namespace grpc {
namespace testing {
gpr_atm g_now_us = 0;
static gpr_timespec fake_now(gpr_clock_type clock_type) {
gpr_timespec t;
gpr_atm now = gpr_atm_no_barrier_load(&g_now_us);
t.tv_sec = now / GPR_US_PER_SEC;
t.tv_nsec = (now % GPR_US_PER_SEC) * GPR_NS_PER_US;
t.clock_type = clock_type;
return t;
}
static void inc_time() {
gpr_atm_no_barrier_fetch_add(&g_now_us, 100);
grpc_timer_manager_tick();
}
static void* tag(intptr_t x) { return reinterpret_cast<void*>(x); }
template <class A0>
static void write_csv(std::ostream* out, A0&& a0) {
if (!out) return;
(*out) << a0 << "\n";
}
template <class A0, class... Arg>
static void write_csv(std::ostream* out, A0&& a0, Arg&&... arg) {
if (!out) return;
(*out) << a0 << ",";
write_csv(out, std::forward<Arg>(arg)...);
}
class TrickledCHTTP2 : public EndpointPairFixture {
public:
TrickledCHTTP2(Service* service, bool streaming, size_t req_size,
size_t resp_size, size_t kilobits_per_second,
grpc_passthru_endpoint_stats* stats)
: EndpointPairFixture(service, MakeEndpoints(kilobits_per_second, stats),
FixtureConfiguration()),
stats_(stats) {
if (absl::GetFlag(FLAGS_log)) {
std::ostringstream fn;
fn << "trickle." << (streaming ? "streaming" : "unary") << "." << req_size
<< "." << resp_size << "." << kilobits_per_second << ".csv";
log_ = absl::make_unique<std::ofstream>(fn.str().c_str());
write_csv(log_.get(), "t", "iteration", "client_backlog",
"server_backlog", "client_t_stall", "client_s_stall",
"server_t_stall", "server_s_stall", "client_t_remote",
"server_t_remote", "client_t_announced", "server_t_announced",
"client_s_remote_delta", "server_s_remote_delta",
"client_s_local_delta", "server_s_local_delta",
"client_s_announced_delta", "server_s_announced_delta",
"client_peer_iws", "client_local_iws", "client_sent_iws",
"client_acked_iws", "server_peer_iws", "server_local_iws",
"server_sent_iws", "server_acked_iws", "client_queued_bytes",
"server_queued_bytes");
}
}
~TrickledCHTTP2() override {
if (stats_ != nullptr) {
grpc_passthru_endpoint_stats_destroy(stats_);
}
}
void AddToLabel(std::ostream& out, benchmark::State& state) override {
out << " writes/iter:"
<< (static_cast<double>(stats_->num_writes) /
static_cast<double>(state.iterations()))
<< " cli_transport_stalls/iter:"
<< (static_cast<double>(
client_stats_.streams_stalled_due_to_transport_flow_control) /
static_cast<double>(state.iterations()))
<< " cli_stream_stalls/iter:"
<< (static_cast<double>(
client_stats_.streams_stalled_due_to_stream_flow_control) /
static_cast<double>(state.iterations()))
<< " svr_transport_stalls/iter:"
<< (static_cast<double>(
server_stats_.streams_stalled_due_to_transport_flow_control) /
static_cast<double>(state.iterations()))
<< " svr_stream_stalls/iter:"
<< (static_cast<double>(
server_stats_.streams_stalled_due_to_stream_flow_control) /
static_cast<double>(state.iterations()));
}
void Log(int64_t iteration) GPR_ATTRIBUTE_NO_TSAN {
auto now = gpr_time_sub(gpr_now(GPR_CLOCK_MONOTONIC), start_);
grpc_chttp2_transport* client =
reinterpret_cast<grpc_chttp2_transport*>(client_transport_);
grpc_chttp2_transport* server =
reinterpret_cast<grpc_chttp2_transport*>(server_transport_);
grpc_chttp2_stream* client_stream =
client->stream_map.count == 1
? static_cast<grpc_chttp2_stream*>(client->stream_map.values[0])
: nullptr;
grpc_chttp2_stream* server_stream =
server->stream_map.count == 1
? static_cast<grpc_chttp2_stream*>(server->stream_map.values[0])
: nullptr;
write_csv(
log_.get(),
static_cast<double>(now.tv_sec) +
1e-9 * static_cast<double>(now.tv_nsec),
iteration, grpc_trickle_get_backlog(endpoint_pair_.client),
grpc_trickle_get_backlog(endpoint_pair_.server),
client->lists[GRPC_CHTTP2_LIST_STALLED_BY_TRANSPORT].head != nullptr,
client->lists[GRPC_CHTTP2_LIST_STALLED_BY_STREAM].head != nullptr,
server->lists[GRPC_CHTTP2_LIST_STALLED_BY_TRANSPORT].head != nullptr,
server->lists[GRPC_CHTTP2_LIST_STALLED_BY_STREAM].head != nullptr,
client->flow_control->remote_window_,
server->flow_control->remote_window_,
client->flow_control->announced_window_,
server->flow_control->announced_window_,
client_stream ? client_stream->flow_control->remote_window_delta_ : -1,
server_stream ? server_stream->flow_control->remote_window_delta_ : -1,
client_stream ? client_stream->flow_control->local_window_delta_ : -1,
server_stream ? server_stream->flow_control->local_window_delta_ : -1,
client_stream ? client_stream->flow_control->announced_window_delta_
: -1,
server_stream ? server_stream->flow_control->announced_window_delta_
: -1,
client->settings[GRPC_PEER_SETTINGS]
[GRPC_CHTTP2_SETTINGS_INITIAL_WINDOW_SIZE],
client->settings[GRPC_LOCAL_SETTINGS]
[GRPC_CHTTP2_SETTINGS_INITIAL_WINDOW_SIZE],
client->settings[GRPC_SENT_SETTINGS]
[GRPC_CHTTP2_SETTINGS_INITIAL_WINDOW_SIZE],
client->settings[GRPC_ACKED_SETTINGS]
[GRPC_CHTTP2_SETTINGS_INITIAL_WINDOW_SIZE],
server->settings[GRPC_PEER_SETTINGS]
[GRPC_CHTTP2_SETTINGS_INITIAL_WINDOW_SIZE],
server->settings[GRPC_LOCAL_SETTINGS]
[GRPC_CHTTP2_SETTINGS_INITIAL_WINDOW_SIZE],
server->settings[GRPC_SENT_SETTINGS]
[GRPC_CHTTP2_SETTINGS_INITIAL_WINDOW_SIZE],
server->settings[GRPC_ACKED_SETTINGS]
[GRPC_CHTTP2_SETTINGS_INITIAL_WINDOW_SIZE],
client_stream ? client_stream->flow_controlled_buffer.length : 0,
server_stream ? server_stream->flow_controlled_buffer.length : 0);
}
void Step(bool update_stats) {
grpc_core::ExecCtx exec_ctx;
inc_time();
size_t client_backlog =
grpc_trickle_endpoint_trickle(endpoint_pair_.client);
size_t server_backlog =
grpc_trickle_endpoint_trickle(endpoint_pair_.server);
if (update_stats) {
UpdateStats(reinterpret_cast<grpc_chttp2_transport*>(client_transport_),
&client_stats_, client_backlog);
UpdateStats(reinterpret_cast<grpc_chttp2_transport*>(server_transport_),
&server_stats_, server_backlog);
}
}
private:
grpc_passthru_endpoint_stats* stats_;
struct Stats {
int streams_stalled_due_to_stream_flow_control = 0;
int streams_stalled_due_to_transport_flow_control = 0;
};
Stats client_stats_;
Stats server_stats_;
std::unique_ptr<std::ofstream> log_;
gpr_timespec start_ = gpr_now(GPR_CLOCK_MONOTONIC);
static grpc_endpoint_pair MakeEndpoints(size_t kilobits,
grpc_passthru_endpoint_stats* stats) {
grpc_endpoint_pair p;
grpc_passthru_endpoint_create(&p.client, &p.server, stats);
double bytes_per_second = 125.0 * kilobits;
p.client = grpc_trickle_endpoint_create(p.client, bytes_per_second);
p.server = grpc_trickle_endpoint_create(p.server, bytes_per_second);
return p;
}
void UpdateStats(grpc_chttp2_transport* t, Stats* s,
size_t backlog) GPR_ATTRIBUTE_NO_TSAN {
if (backlog == 0) {
if (t->lists[GRPC_CHTTP2_LIST_STALLED_BY_STREAM].head != nullptr) {
s->streams_stalled_due_to_stream_flow_control++;
}
if (t->lists[GRPC_CHTTP2_LIST_STALLED_BY_TRANSPORT].head != nullptr) {
s->streams_stalled_due_to_transport_flow_control++;
}
}
}
};
static void TrickleCQNext(TrickledCHTTP2* fixture, void** t, bool* ok,
int64_t iteration) {
while (true) {
fixture->Log(iteration);
switch (
fixture->cq()->AsyncNext(t, ok, gpr_inf_past(GPR_CLOCK_MONOTONIC))) {
case CompletionQueue::TIMEOUT:
fixture->Step(iteration != -1);
break;
case CompletionQueue::SHUTDOWN:
GPR_ASSERT(false);
break;
case CompletionQueue::GOT_EVENT:
return;
}
}
}
static void BM_PumpStreamServerToClient_Trickle(benchmark::State& state) {
EchoTestService::AsyncService service;
std::unique_ptr<TrickledCHTTP2> fixture(new TrickledCHTTP2(
&service, true, state.range(0) /* req_size */,
state.range(0) /* resp_size */, state.range(1) /* bw in kbit/s */,
grpc_passthru_endpoint_stats_create()));
{
EchoResponse send_response;
EchoResponse recv_response;
if (state.range(0) > 0) {
send_response.set_message(std::string(state.range(0), 'a'));
}
Status recv_status;
ServerContext svr_ctx;
ServerAsyncReaderWriter<EchoResponse, EchoRequest> response_rw(&svr_ctx);
service.RequestBidiStream(&svr_ctx, &response_rw, fixture->cq(),
fixture->cq(), tag(0));
std::unique_ptr<EchoTestService::Stub> stub(
EchoTestService::NewStub(fixture->channel()));
ClientContext cli_ctx;
auto request_rw = stub->AsyncBidiStream(&cli_ctx, fixture->cq(), tag(1));
int need_tags = (1 << 0) | (1 << 1);
void* t;
bool ok;
while (need_tags) {
TrickleCQNext(fixture.get(), &t, &ok, -1);
GPR_ASSERT(ok);
int i = static_cast<int>(reinterpret_cast<intptr_t>(t));
GPR_ASSERT(need_tags & (1 << i));
need_tags &= ~(1 << i);
}
request_rw->Read(&recv_response, tag(0));
auto inner_loop = [&](bool in_warmup) {
GPR_TIMER_SCOPE("BenchmarkCycle", 0);
response_rw.Write(send_response, tag(1));
while (true) {
TrickleCQNext(fixture.get(), &t, &ok,
in_warmup ? -1 : state.iterations());
if (t == tag(0)) {
request_rw->Read(&recv_response, tag(0));
} else if (t == tag(1)) {
break;
} else {
GPR_ASSERT(false);
}
}
};
gpr_timespec warmup_start = gpr_now(GPR_CLOCK_MONOTONIC);
for (int i = 0; i < GPR_MAX(absl::GetFlag(FLAGS_warmup_iterations),
absl::GetFlag(FLAGS_warmup_megabytes) * 1024 *
1024 / (14 + state.range(0)));
i++) {
inner_loop(true);
if (gpr_time_cmp(gpr_time_sub(gpr_now(GPR_CLOCK_MONOTONIC), warmup_start),
gpr_time_from_seconds(
absl::GetFlag(FLAGS_warmup_max_time_seconds),
GPR_TIMESPAN)) > 0) {
break;
}
}
while (state.KeepRunning()) {
inner_loop(false);
}
response_rw.Finish(Status::OK, tag(1));
grpc::Status status;
request_rw->Finish(&status, tag(2));
need_tags = (1 << 0) | (1 << 1) | (1 << 2);
while (need_tags) {
TrickleCQNext(fixture.get(), &t, &ok, -1);
if (t == tag(0) && ok) {
request_rw->Read(&recv_response, tag(0));
continue;
}
int i = static_cast<int>(reinterpret_cast<intptr_t>(t));
GPR_ASSERT(need_tags & (1 << i));
need_tags &= ~(1 << i);
}
}
fixture->Finish(state);
fixture.reset();
state.SetBytesProcessed(state.range(0) * state.iterations());
}
static void StreamingTrickleArgs(benchmark::internal::Benchmark* b) {
for (int i = 1; i <= 128 * 1024 * 1024; i *= 8) {
for (int j = 64; j <= 128 * 1024 * 1024; j *= 8) {
double expected_time =
static_cast<double>(14 + i) / (125.0 * static_cast<double>(j));
if (expected_time > 2.0) continue;
b->Args({i, j});
}
}
}
BENCHMARK(BM_PumpStreamServerToClient_Trickle)->Apply(StreamingTrickleArgs);
static void BM_PumpUnbalancedUnary_Trickle(benchmark::State& state) {
EchoTestService::AsyncService service;
std::unique_ptr<TrickledCHTTP2> fixture(new TrickledCHTTP2(
&service, false, state.range(0) /* req_size */,
state.range(1) /* resp_size */, state.range(2) /* bw in kbit/s */,
grpc_passthru_endpoint_stats_create()));
EchoRequest send_request;
EchoResponse send_response;
EchoResponse recv_response;
if (state.range(0) > 0) {
send_request.set_message(std::string(state.range(0), 'a'));
}
if (state.range(1) > 0) {
send_response.set_message(std::string(state.range(1), 'a'));
}
Status recv_status;
struct ServerEnv {
ServerContext ctx;
EchoRequest recv_request;
grpc::ServerAsyncResponseWriter<EchoResponse> response_writer;
ServerEnv() : response_writer(&ctx) {}
};
uint8_t server_env_buffer[2 * sizeof(ServerEnv)];
ServerEnv* server_env[2] = {
reinterpret_cast<ServerEnv*>(server_env_buffer),
reinterpret_cast<ServerEnv*>(server_env_buffer + sizeof(ServerEnv))};
new (server_env[0]) ServerEnv;
new (server_env[1]) ServerEnv;
service.RequestEcho(&server_env[0]->ctx, &server_env[0]->recv_request,
&server_env[0]->response_writer, fixture->cq(),
fixture->cq(), tag(0));
service.RequestEcho(&server_env[1]->ctx, &server_env[1]->recv_request,
&server_env[1]->response_writer, fixture->cq(),
fixture->cq(), tag(1));
std::unique_ptr<EchoTestService::Stub> stub(
EchoTestService::NewStub(fixture->channel()));
auto inner_loop = [&](bool in_warmup) {
GPR_TIMER_SCOPE("BenchmarkCycle", 0);
recv_response.Clear();
ClientContext cli_ctx;
std::unique_ptr<ClientAsyncResponseReader<EchoResponse>> response_reader(
stub->AsyncEcho(&cli_ctx, send_request, fixture->cq()));
void* t;
bool ok;
response_reader->Finish(&recv_response, &recv_status, tag(4));
TrickleCQNext(fixture.get(), &t, &ok, in_warmup ? -1 : state.iterations());
GPR_ASSERT(ok);
GPR_ASSERT(t == tag(0) || t == tag(1));
intptr_t slot = reinterpret_cast<intptr_t>(t);
ServerEnv* senv = server_env[slot];
senv->response_writer.Finish(send_response, Status::OK, tag(3));
for (int i = (1 << 3) | (1 << 4); i != 0;) {
TrickleCQNext(fixture.get(), &t, &ok,
in_warmup ? -1 : state.iterations());
GPR_ASSERT(ok);
int tagnum = static_cast<int>(reinterpret_cast<intptr_t>(t));
GPR_ASSERT(i & (1 << tagnum));
i -= 1 << tagnum;
}
GPR_ASSERT(recv_status.ok());
senv->~ServerEnv();
senv = new (senv) ServerEnv();
service.RequestEcho(&senv->ctx, &senv->recv_request, &senv->response_writer,
fixture->cq(), fixture->cq(), tag(slot));
};
gpr_timespec warmup_start = gpr_now(GPR_CLOCK_MONOTONIC);
for (int i = 0; i < GPR_MAX(absl::GetFlag(FLAGS_warmup_iterations),
absl::GetFlag(FLAGS_warmup_megabytes) * 1024 *
1024 / (14 + state.range(0)));
i++) {
inner_loop(true);
if (gpr_time_cmp(
gpr_time_sub(gpr_now(GPR_CLOCK_MONOTONIC), warmup_start),
gpr_time_from_seconds(absl::GetFlag(FLAGS_warmup_max_time_seconds),
GPR_TIMESPAN)) > 0) {
break;
}
}
while (state.KeepRunning()) {
inner_loop(false);
}
fixture->Finish(state);
fixture.reset();
server_env[0]->~ServerEnv();
server_env[1]->~ServerEnv();
state.SetBytesProcessed(state.range(0) * state.iterations() +
state.range(1) * state.iterations());
}
static void UnaryTrickleArgs(benchmark::internal::Benchmark* b) {
for (int bw = 64; bw <= 128 * 1024 * 1024; bw *= 16) {
b->Args({1, 1, bw});
for (int i = 64; i <= 128 * 1024 * 1024; i *= 64) {
double expected_time =
static_cast<double>(14 + i) / (125.0 * static_cast<double>(bw));
if (expected_time > 2.0) continue;
b->Args({i, 1, bw});
b->Args({1, i, bw});
b->Args({i, i, bw});
}
}
}
BENCHMARK(BM_PumpUnbalancedUnary_Trickle)->Apply(UnaryTrickleArgs);
} // namespace testing
} // namespace grpc
extern gpr_timespec (*gpr_now_impl)(gpr_clock_type clock_type);
// Some distros have RunSpecifiedBenchmarks under the benchmark namespace,
// and others do not. This allows us to support both modes.
namespace benchmark {
void RunTheBenchmarksNamespaced() { RunSpecifiedBenchmarks(); }
} // namespace benchmark
int main(int argc, char** argv) {
grpc::testing::TestEnvironment env(argc, argv);
LibraryInitializer libInit;
::benchmark::Initialize(&argc, argv);
::grpc::testing::InitTest(&argc, &argv, false);
grpc_timer_manager_set_threading(false);
gpr_now_impl = ::grpc::testing::fake_now;
benchmark::RunTheBenchmarksNamespaced();
}