The C based gRPC (C++, Python, Ruby, Objective-C, PHP, C#) https://grpc.io/
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/*
*
* 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,
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* LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE,
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* THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
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* OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
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*/
#include <cassert>
#include <forward_list>
#include <functional>
#include <list>
#include <memory>
#include <mutex>
#include <string>
#include <thread>
#include <vector>
#include <sstream>
#include <grpc/grpc.h>
#include <grpc/support/histogram.h>
#include <grpc/support/log.h>
#include <gflags/gflags.h>
#include <grpc++/client_context.h>
#include "test/cpp/qps/qpstest.grpc.pb.h"
#include "test/cpp/qps/timer.h"
#include "test/cpp/qps/client.h"
#include "test/cpp/util/create_test_channel.h"
namespace grpc {
namespace testing {
typedef std::list<grpc_time> deadline_list;
class ClientRpcContext {
public:
explicit ClientRpcContext(int ch) : channel_id_(ch) {}
virtual ~ClientRpcContext() {}
// next state, return false if done. Collect stats when appropriate
virtual bool RunNextState(bool, Histogram* hist) = 0;
virtual ClientRpcContext* StartNewClone() = 0;
static void* tag(ClientRpcContext* c) { return reinterpret_cast<void*>(c); }
static ClientRpcContext* detag(void* t) {
return reinterpret_cast<ClientRpcContext*>(t);
}
deadline_list::iterator deadline_posn() const { return deadline_posn_; }
void set_deadline_posn(const deadline_list::iterator& it) {
deadline_posn_ = it;
}
virtual void Start(CompletionQueue* cq) = 0;
int channel_id() const { return channel_id_; }
protected:
int channel_id_;
private:
deadline_list::iterator deadline_posn_;
};
template <class RequestType, class ResponseType>
class ClientRpcContextUnaryImpl : public ClientRpcContext {
public:
ClientRpcContextUnaryImpl(
int channel_id, TestService::Stub* stub, const RequestType& req,
std::function<
std::unique_ptr<grpc::ClientAsyncResponseReader<ResponseType>>(
TestService::Stub*, grpc::ClientContext*, const RequestType&,
CompletionQueue*)> start_req,
std::function<void(grpc::Status, ResponseType*)> on_done)
: ClientRpcContext(channel_id),
context_(),
stub_(stub),
req_(req),
response_(),
next_state_(&ClientRpcContextUnaryImpl::RespDone),
callback_(on_done),
start_req_(start_req) {}
void Start(CompletionQueue* cq) GRPC_OVERRIDE {
start_ = Timer::Now();
response_reader_ = start_req_(stub_, &context_, req_, cq);
response_reader_->Finish(&response_, &status_, ClientRpcContext::tag(this));
}
~ClientRpcContextUnaryImpl() GRPC_OVERRIDE {}
bool RunNextState(bool ok, Histogram* hist) GRPC_OVERRIDE {
bool ret = (this->*next_state_)(ok);
if (!ret) {
hist->Add((Timer::Now() - start_) * 1e9);
}
return ret;
}
ClientRpcContext* StartNewClone() GRPC_OVERRIDE {
return new ClientRpcContextUnaryImpl(channel_id_, stub_, req_, start_req_,
callback_);
}
private:
bool RespDone(bool) {
next_state_ = &ClientRpcContextUnaryImpl::DoCallBack;
return false;
}
bool DoCallBack(bool) {
callback_(status_, &response_);
return true; // we're done, this'll be ignored
}
grpc::ClientContext context_;
TestService::Stub* stub_;
RequestType req_;
ResponseType response_;
bool (ClientRpcContextUnaryImpl::*next_state_)(bool);
std::function<void(grpc::Status, ResponseType*)> callback_;
std::function<std::unique_ptr<grpc::ClientAsyncResponseReader<ResponseType>>(
TestService::Stub*, grpc::ClientContext*, const RequestType&,
CompletionQueue*)> start_req_;
grpc::Status status_;
double start_;
std::unique_ptr<grpc::ClientAsyncResponseReader<ResponseType>>
response_reader_;
};
typedef std::forward_list<ClientRpcContext*> context_list;
class AsyncClient : public Client {
public:
explicit AsyncClient(
const ClientConfig& config,
std::function<ClientRpcContext*(int, TestService::Stub*,
const SimpleRequest&)> setup_ctx)
: Client(config),
channel_lock_(new std::mutex[config.client_channels()]),
contexts_(config.client_channels()),
max_outstanding_per_channel_(config.outstanding_rpcs_per_channel()),
channel_count_(config.client_channels()),
pref_channel_inc_(config.async_client_threads()) {
SetupLoadTest(config, config.async_client_threads());
for (int i = 0; i < config.async_client_threads(); i++) {
cli_cqs_.emplace_back(new CompletionQueue);
if (!closed_loop_) {
rpc_deadlines_.emplace_back();
next_channel_.push_back(i % channel_count_);
issue_allowed_.emplace_back(true);
grpc_time next_issue;
NextIssueTime(i, &next_issue);
next_issue_.push_back(next_issue);
}
}
int t = 0;
for (int i = 0; i < config.outstanding_rpcs_per_channel(); i++) {
for (int ch = 0; ch < channel_count_; ch++) {
auto* cq = cli_cqs_[t].get();
t = (t + 1) % cli_cqs_.size();
auto ctx = setup_ctx(ch, channels_[ch].get_stub(), request_);
if (closed_loop_) {
ctx->Start(cq);
} else {
contexts_[ch].push_front(ctx);
}
}
}
}
virtual ~AsyncClient() {
for (auto cq = cli_cqs_.begin(); cq != cli_cqs_.end(); cq++) {
(*cq)->Shutdown();
void* got_tag;
bool ok;
while ((*cq)->Next(&got_tag, &ok)) {
delete ClientRpcContext::detag(got_tag);
}
}
// Now clear out all the pre-allocated idle contexts
for (int ch = 0; ch < channel_count_; ch++) {
while (!contexts_[ch].empty()) {
// Get an idle context from the front of the list
auto* ctx = *(contexts_[ch].begin());
contexts_[ch].pop_front();
delete ctx;
}
}
delete[] channel_lock_;
}
bool ThreadFunc(Histogram* histogram,
size_t thread_idx) GRPC_OVERRIDE GRPC_FINAL {
void* got_tag;
bool ok;
grpc_time deadline, short_deadline;
if (closed_loop_) {
deadline = grpc_time_source::now() + std::chrono::seconds(1);
short_deadline = deadline;
} else {
if (rpc_deadlines_[thread_idx].empty()) {
deadline = grpc_time_source::now() + std::chrono::seconds(1);
} else {
deadline = *(rpc_deadlines_[thread_idx].begin());
}
short_deadline =
issue_allowed_[thread_idx] ? next_issue_[thread_idx] : deadline;
}
bool got_event;
switch (cli_cqs_[thread_idx]->AsyncNext(&got_tag, &ok, short_deadline)) {
case CompletionQueue::SHUTDOWN:
return false;
case CompletionQueue::TIMEOUT:
got_event = false;
break;
case CompletionQueue::GOT_EVENT:
got_event = true;
break;
default:
GPR_ASSERT(false);
break;
}
if (got_event) {
ClientRpcContext* ctx = ClientRpcContext::detag(got_tag);
if (ctx->RunNextState(ok, histogram) == false) {
// call the callback and then clone the ctx
ctx->RunNextState(ok, histogram);
ClientRpcContext* clone_ctx = ctx->StartNewClone();
if (closed_loop_) {
clone_ctx->Start(cli_cqs_[thread_idx].get());
} else {
// Remove the entry from the rpc deadlines list
rpc_deadlines_[thread_idx].erase(ctx->deadline_posn());
// Put the clone_ctx in the list of idle contexts for this channel
// Under lock
int ch = clone_ctx->channel_id();
std::lock_guard<std::mutex> g(channel_lock_[ch]);
contexts_[ch].push_front(clone_ctx);
}
// delete the old version
delete ctx;
}
if (!closed_loop_)
issue_allowed_[thread_idx] =
true; // may be ok now even if it hadn't been
}
if (!closed_loop_ && issue_allowed_[thread_idx] &&
grpc_time_source::now() >= next_issue_[thread_idx]) {
// Attempt to issue
bool issued = false;
for (int num_attempts = 0, channel_attempt = next_channel_[thread_idx];
num_attempts < channel_count_ && !issued; num_attempts++) {
bool can_issue = false;
ClientRpcContext* ctx = nullptr;
{
std::lock_guard<std::mutex> g(channel_lock_[channel_attempt]);
if (!contexts_[channel_attempt].empty()) {
// Get an idle context from the front of the list
ctx = *(contexts_[channel_attempt].begin());
contexts_[channel_attempt].pop_front();
can_issue = true;
}
}
if (can_issue) {
// do the work to issue
rpc_deadlines_[thread_idx].emplace_back(grpc_time_source::now() +
std::chrono::seconds(1));
auto it = rpc_deadlines_[thread_idx].end();
--it;
ctx->set_deadline_posn(it);
ctx->Start(cli_cqs_[thread_idx].get());
issued = true;
// If we did issue, then next time, try our thread's next
// preferred channel
next_channel_[thread_idx] += pref_channel_inc_;
if (next_channel_[thread_idx] >= channel_count_)
next_channel_[thread_idx] = (thread_idx % channel_count_);
} else {
// Do a modular increment of channel attempt if we couldn't issue
channel_attempt = (channel_attempt + 1) % channel_count_;
}
}
if (issued) {
// We issued one; see when we can issue the next
grpc_time next_issue;
NextIssueTime(thread_idx, &next_issue);
next_issue_[thread_idx] = next_issue;
} else {
issue_allowed_[thread_idx] = false;
}
}
return true;
}
private:
class boolean { // exists only to avoid data-race on vector<bool>
public:
boolean() : val_(false) {}
boolean(bool b) : val_(b) {}
operator bool() const { return val_; }
boolean& operator=(bool b) {
val_ = b;
return *this;
}
private:
bool val_;
};
std::vector<std::unique_ptr<CompletionQueue>> cli_cqs_;
std::vector<deadline_list> rpc_deadlines_; // per thread deadlines
std::vector<int> next_channel_; // per thread round-robin channel ctr
std::vector<boolean> issue_allowed_; // may this thread attempt to issue
std::vector<grpc_time> next_issue_; // when should it issue?
std::mutex*
channel_lock_; // a vector, but avoid std::vector for old compilers
std::vector<context_list> contexts_; // per-channel list of idle contexts
int max_outstanding_per_channel_;
int channel_count_;
int pref_channel_inc_;
};
class AsyncUnaryClient GRPC_FINAL : public AsyncClient {
public:
explicit AsyncUnaryClient(const ClientConfig& config)
: AsyncClient(config, SetupCtx) {
StartThreads(config.async_client_threads());
}
~AsyncUnaryClient() GRPC_OVERRIDE { EndThreads(); }
private:
static void CheckDone(grpc::Status s, SimpleResponse* response) {}
static std::unique_ptr<grpc::ClientAsyncResponseReader<SimpleResponse>>
StartReq(TestService::Stub* stub, grpc::ClientContext* ctx,
const SimpleRequest& request, CompletionQueue* cq) {
return stub->AsyncUnaryCall(ctx, request, cq);
};
static ClientRpcContext* SetupCtx(int channel_id, TestService::Stub* stub,
const SimpleRequest& req) {
return new ClientRpcContextUnaryImpl<SimpleRequest, SimpleResponse>(
channel_id, stub, req, AsyncUnaryClient::StartReq,
AsyncUnaryClient::CheckDone);
}
};
template <class RequestType, class ResponseType>
class ClientRpcContextStreamingImpl : public ClientRpcContext {
public:
ClientRpcContextStreamingImpl(
int channel_id, TestService::Stub* stub, const RequestType& req,
std::function<std::unique_ptr<grpc::ClientAsyncReaderWriter<
RequestType, ResponseType>>(TestService::Stub*, grpc::ClientContext*,
CompletionQueue*, void*)> start_req,
std::function<void(grpc::Status, ResponseType*)> on_done)
: ClientRpcContext(channel_id),
context_(),
stub_(stub),
req_(req),
response_(),
next_state_(&ClientRpcContextStreamingImpl::ReqSent),
callback_(on_done),
start_req_(start_req),
start_(Timer::Now()) {}
~ClientRpcContextStreamingImpl() GRPC_OVERRIDE {}
bool RunNextState(bool ok, Histogram* hist) GRPC_OVERRIDE {
return (this->*next_state_)(ok, hist);
}
ClientRpcContext* StartNewClone() GRPC_OVERRIDE {
return new ClientRpcContextStreamingImpl(channel_id_, stub_, req_,
start_req_, callback_);
}
void Start(CompletionQueue* cq) GRPC_OVERRIDE {
stream_ = start_req_(stub_, &context_, cq, ClientRpcContext::tag(this));
}
private:
bool ReqSent(bool ok, Histogram*) { return StartWrite(ok); }
bool StartWrite(bool ok) {
if (!ok) {
return (false);
}
start_ = Timer::Now();
next_state_ = &ClientRpcContextStreamingImpl::WriteDone;
stream_->Write(req_, ClientRpcContext::tag(this));
return true;
}
bool WriteDone(bool ok, Histogram*) {
if (!ok) {
return (false);
}
next_state_ = &ClientRpcContextStreamingImpl::ReadDone;
stream_->Read(&response_, ClientRpcContext::tag(this));
return true;
}
bool ReadDone(bool ok, Histogram* hist) {
hist->Add((Timer::Now() - start_) * 1e9);
return StartWrite(ok);
}
grpc::ClientContext context_;
TestService::Stub* stub_;
RequestType req_;
ResponseType response_;
bool (ClientRpcContextStreamingImpl::*next_state_)(bool, Histogram*);
std::function<void(grpc::Status, ResponseType*)> callback_;
std::function<
std::unique_ptr<grpc::ClientAsyncReaderWriter<RequestType, ResponseType>>(
TestService::Stub*, grpc::ClientContext*, CompletionQueue*, void*)>
start_req_;
grpc::Status status_;
double start_;
std::unique_ptr<grpc::ClientAsyncReaderWriter<RequestType, ResponseType>>
stream_;
};
class AsyncStreamingClient GRPC_FINAL : public AsyncClient {
public:
explicit AsyncStreamingClient(const ClientConfig& config)
: AsyncClient(config, SetupCtx) {
// async streaming currently only supported closed loop
GPR_ASSERT(config.load_type() == CLOSED_LOOP);
StartThreads(config.async_client_threads());
}
~AsyncStreamingClient() GRPC_OVERRIDE { EndThreads(); }
private:
static void CheckDone(grpc::Status s, SimpleResponse* response) {}
static std::unique_ptr<
grpc::ClientAsyncReaderWriter<SimpleRequest, SimpleResponse>>
StartReq(TestService::Stub* stub, grpc::ClientContext* ctx,
CompletionQueue* cq, void* tag) {
auto stream = stub->AsyncStreamingCall(ctx, cq, tag);
return stream;
};
static ClientRpcContext* SetupCtx(int channel_id, TestService::Stub* stub,
const SimpleRequest& req) {
return new ClientRpcContextStreamingImpl<SimpleRequest, SimpleResponse>(
channel_id, stub, req, AsyncStreamingClient::StartReq,
AsyncStreamingClient::CheckDone);
}
};
std::unique_ptr<Client> CreateAsyncUnaryClient(const ClientConfig& args) {
return std::unique_ptr<Client>(new AsyncUnaryClient(args));
}
std::unique_ptr<Client> CreateAsyncStreamingClient(const ClientConfig& args) {
return std::unique_ptr<Client>(new AsyncStreamingClient(args));
}
} // namespace testing
} // namespace grpc