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/*
*
* Copyright 2018 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 <grpcpp/channel.h>
#include <grpcpp/client_context.h>
#include <grpcpp/create_channel.h>
#include <grpcpp/generic/generic_stub.h>
#include <grpcpp/impl/codegen/proto_utils.h>
#include <grpcpp/server.h>
#include <grpcpp/server_builder.h>
#include <grpcpp/server_context.h>
#include <grpcpp/support/client_callback.h>
#include <gtest/gtest.h>
#include <algorithm>
#include <condition_variable>
#include <functional>
#include <mutex>
#include <sstream>
#include <thread>
#include "src/core/lib/gpr/env.h"
#include "src/core/lib/iomgr/iomgr.h"
#include "src/proto/grpc/testing/echo.grpc.pb.h"
#include "test/core/util/port.h"
#include "test/core/util/test_config.h"
#include "test/cpp/end2end/interceptors_util.h"
#include "test/cpp/end2end/test_service_impl.h"
#include "test/cpp/util/byte_buffer_proto_helper.h"
#include "test/cpp/util/string_ref_helper.h"
#include "test/cpp/util/test_credentials_provider.h"
// MAYBE_SKIP_TEST is a macro to determine if this particular test configuration
// should be skipped based on a decision made at SetUp time. In particular, any
// callback tests can only be run if the iomgr can run in the background or if
// the transport is in-process.
#define MAYBE_SKIP_TEST \
do { \
if (do_not_test_) { \
return; \
} \
} while (0)
namespace grpc {
namespace testing {
namespace {
enum class Protocol { INPROC, TCP };
class TestScenario {
public:
TestScenario(bool serve_callback, Protocol protocol, bool intercept,
const std::string& creds_type)
: callback_server(serve_callback),
protocol(protocol),
use_interceptors(intercept),
credentials_type(creds_type) {}
void Log() const;
bool callback_server;
Protocol protocol;
bool use_interceptors;
const std::string credentials_type;
};
static std::ostream& operator<<(std::ostream& out,
const TestScenario& scenario) {
return out << "TestScenario{callback_server="
<< (scenario.callback_server ? "true" : "false") << ",protocol="
<< (scenario.protocol == Protocol::INPROC ? "INPROC" : "TCP")
<< ",intercept=" << (scenario.use_interceptors ? "true" : "false")
<< ",creds=" << scenario.credentials_type << "}";
}
void TestScenario::Log() const {
std::ostringstream out;
out << *this;
gpr_log(GPR_DEBUG, "%s", out.str().c_str());
}
class ClientCallbackEnd2endTest
: public ::testing::TestWithParam<TestScenario> {
protected:
ClientCallbackEnd2endTest() { GetParam().Log(); }
void SetUp() override {
ServerBuilder builder;
auto server_creds = GetCredentialsProvider()->GetServerCredentials(
GetParam().credentials_type);
// TODO(vjpai): Support testing of AuthMetadataProcessor
if (GetParam().protocol == Protocol::TCP) {
picked_port_ = grpc_pick_unused_port_or_die();
server_address_ << "localhost:" << picked_port_;
builder.AddListeningPort(server_address_.str(), server_creds);
}
if (!GetParam().callback_server) {
builder.RegisterService(&service_);
} else {
builder.RegisterService(&callback_service_);
}
if (GetParam().use_interceptors) {
std::vector<
std::unique_ptr<experimental::ServerInterceptorFactoryInterface>>
creators;
// Add 20 dummy server interceptors
creators.reserve(20);
for (auto i = 0; i < 20; i++) {
creators.push_back(std::unique_ptr<DummyInterceptorFactory>(
new DummyInterceptorFactory()));
}
builder.experimental().SetInterceptorCreators(std::move(creators));
}
server_ = builder.BuildAndStart();
is_server_started_ = true;
if (GetParam().protocol == Protocol::TCP &&
!grpc_iomgr_run_in_background()) {
do_not_test_ = true;
}
}
void ResetStub() {
ChannelArguments args;
auto channel_creds = GetCredentialsProvider()->GetChannelCredentials(
GetParam().credentials_type, &args);
switch (GetParam().protocol) {
case Protocol::TCP:
if (!GetParam().use_interceptors) {
channel_ = ::grpc::CreateCustomChannel(server_address_.str(),
channel_creds, args);
} else {
channel_ = CreateCustomChannelWithInterceptors(
server_address_.str(), channel_creds, args,
CreateDummyClientInterceptors());
}
break;
case Protocol::INPROC:
if (!GetParam().use_interceptors) {
channel_ = server_->InProcessChannel(args);
} else {
channel_ = server_->experimental().InProcessChannelWithInterceptors(
args, CreateDummyClientInterceptors());
}
break;
default:
assert(false);
}
stub_ = grpc::testing::EchoTestService::NewStub(channel_);
generic_stub_.reset(new GenericStub(channel_));
DummyInterceptor::Reset();
}
void TearDown() override {
if (is_server_started_) {
// Although we would normally do an explicit shutdown, the server
// should also work correctly with just a destructor call. The regular
// end2end test uses explicit shutdown, so let this one just do reset.
server_.reset();
}
if (picked_port_ > 0) {
grpc_recycle_unused_port(picked_port_);
}
}
void SendRpcs(int num_rpcs, bool with_binary_metadata) {
std::string test_string("");
for (int i = 0; i < num_rpcs; i++) {
EchoRequest request;
EchoResponse response;
ClientContext cli_ctx;
test_string += "Hello world. ";
request.set_message(test_string);
std::string val;
if (with_binary_metadata) {
request.mutable_param()->set_echo_metadata(true);
char bytes[8] = {'\0', '\1', '\2', '\3',
'\4', '\5', '\6', static_cast<char>(i)};
val = std::string(bytes, 8);
cli_ctx.AddMetadata("custom-bin", val);
}
cli_ctx.set_compression_algorithm(GRPC_COMPRESS_GZIP);
std::mutex mu;
std::condition_variable cv;
bool done = false;
stub_->experimental_async()->Echo(
&cli_ctx, &request, &response,
[&cli_ctx, &request, &response, &done, &mu, &cv, val,
with_binary_metadata](Status s) {
GPR_ASSERT(s.ok());
EXPECT_EQ(request.message(), response.message());
if (with_binary_metadata) {
EXPECT_EQ(
1u, cli_ctx.GetServerTrailingMetadata().count("custom-bin"));
EXPECT_EQ(val, ToString(cli_ctx.GetServerTrailingMetadata()
.find("custom-bin")
->second));
}
std::lock_guard<std::mutex> l(mu);
done = true;
cv.notify_one();
});
std::unique_lock<std::mutex> l(mu);
while (!done) {
cv.wait(l);
}
}
}
void SendRpcsRawReq(int num_rpcs) {
std::string test_string("Hello raw world.");
EchoRequest request;
request.set_message(test_string);
std::unique_ptr<ByteBuffer> send_buf = SerializeToByteBuffer(&request);
for (int i = 0; i < num_rpcs; i++) {
EchoResponse response;
ClientContext cli_ctx;
std::mutex mu;
std::condition_variable cv;
bool done = false;
stub_->experimental_async()->Echo(
&cli_ctx, send_buf.get(), &response,
[&request, &response, &done, &mu, &cv](Status s) {
GPR_ASSERT(s.ok());
EXPECT_EQ(request.message(), response.message());
std::lock_guard<std::mutex> l(mu);
done = true;
cv.notify_one();
});
std::unique_lock<std::mutex> l(mu);
while (!done) {
cv.wait(l);
}
}
}
void SendRpcsGeneric(int num_rpcs, bool maybe_except) {
const std::string kMethodName("/grpc.testing.EchoTestService/Echo");
std::string test_string("");
for (int i = 0; i < num_rpcs; i++) {
EchoRequest request;
std::unique_ptr<ByteBuffer> send_buf;
ByteBuffer recv_buf;
ClientContext cli_ctx;
test_string += "Hello world. ";
request.set_message(test_string);
send_buf = SerializeToByteBuffer(&request);
std::mutex mu;
std::condition_variable cv;
bool done = false;
generic_stub_->experimental().UnaryCall(
&cli_ctx, kMethodName, send_buf.get(), &recv_buf,
[&request, &recv_buf, &done, &mu, &cv, maybe_except](Status s) {
GPR_ASSERT(s.ok());
EchoResponse response;
EXPECT_TRUE(ParseFromByteBuffer(&recv_buf, &response));
EXPECT_EQ(request.message(), response.message());
std::lock_guard<std::mutex> l(mu);
done = true;
cv.notify_one();
#if GRPC_ALLOW_EXCEPTIONS
if (maybe_except) {
throw - 1;
}
#else
GPR_ASSERT(!maybe_except);
#endif
});
std::unique_lock<std::mutex> l(mu);
while (!done) {
cv.wait(l);
}
}
}
void SendGenericEchoAsBidi(int num_rpcs, int reuses, bool do_writes_done) {
const std::string kMethodName("/grpc.testing.EchoTestService/Echo");
std::string test_string("");
for (int i = 0; i < num_rpcs; i++) {
test_string += "Hello world. ";
class Client : public grpc::experimental::ClientBidiReactor<ByteBuffer,
ByteBuffer> {
public:
Client(ClientCallbackEnd2endTest* test, const std::string& method_name,
const std::string& test_str, int reuses, bool do_writes_done)
: reuses_remaining_(reuses), do_writes_done_(do_writes_done) {
activate_ = [this, test, method_name, test_str] {
if (reuses_remaining_ > 0) {
cli_ctx_.reset(new ClientContext);
reuses_remaining_--;
test->generic_stub_->experimental().PrepareBidiStreamingCall(
cli_ctx_.get(), method_name, this);
request_.set_message(test_str);
send_buf_ = SerializeToByteBuffer(&request_);
StartWrite(send_buf_.get());
StartRead(&recv_buf_);
StartCall();
} else {
std::unique_lock<std::mutex> l(mu_);
done_ = true;
cv_.notify_one();
}
};
activate_();
}
void OnWriteDone(bool /*ok*/) override {
if (do_writes_done_) {
StartWritesDone();
}
}
void OnReadDone(bool /*ok*/) override {
EchoResponse response;
EXPECT_TRUE(ParseFromByteBuffer(&recv_buf_, &response));
EXPECT_EQ(request_.message(), response.message());
};
void OnDone(const Status& s) override {
EXPECT_TRUE(s.ok());
activate_();
}
void Await() {
std::unique_lock<std::mutex> l(mu_);
while (!done_) {
cv_.wait(l);
}
}
EchoRequest request_;
std::unique_ptr<ByteBuffer> send_buf_;
ByteBuffer recv_buf_;
std::unique_ptr<ClientContext> cli_ctx_;
int reuses_remaining_;
std::function<void()> activate_;
std::mutex mu_;
std::condition_variable cv_;
bool done_ = false;
const bool do_writes_done_;
};
Client rpc(this, kMethodName, test_string, reuses, do_writes_done);
rpc.Await();
}
}
bool do_not_test_{false};
bool is_server_started_{false};
int picked_port_{0};
std::shared_ptr<Channel> channel_;
std::unique_ptr<grpc::testing::EchoTestService::Stub> stub_;
std::unique_ptr<grpc::GenericStub> generic_stub_;
TestServiceImpl service_;
CallbackTestServiceImpl callback_service_;
std::unique_ptr<Server> server_;
std::ostringstream server_address_;
};
TEST_P(ClientCallbackEnd2endTest, SimpleRpc) {
MAYBE_SKIP_TEST;
ResetStub();
SendRpcs(1, false);
}
TEST_P(ClientCallbackEnd2endTest, SimpleRpcExpectedError) {
MAYBE_SKIP_TEST;
ResetStub();
EchoRequest request;
EchoResponse response;
ClientContext cli_ctx;
ErrorStatus error_status;
request.set_message("Hello failure");
error_status.set_code(1); // CANCELLED
error_status.set_error_message("cancel error message");
*request.mutable_param()->mutable_expected_error() = error_status;
std::mutex mu;
std::condition_variable cv;
bool done = false;
stub_->experimental_async()->Echo(
&cli_ctx, &request, &response,
[&response, &done, &mu, &cv, &error_status](Status s) {
EXPECT_EQ("", response.message());
EXPECT_EQ(error_status.code(), s.error_code());
EXPECT_EQ(error_status.error_message(), s.error_message());
std::lock_guard<std::mutex> l(mu);
done = true;
cv.notify_one();
});
std::unique_lock<std::mutex> l(mu);
while (!done) {
cv.wait(l);
}
}
TEST_P(ClientCallbackEnd2endTest, SimpleRpcUnderLockNested) {
MAYBE_SKIP_TEST;
ResetStub();
// The request/response state associated with an RPC and the synchronization
// variables needed to notify its completion.
struct RpcState {
std::mutex mu;
std::condition_variable cv;
bool done = false;
EchoRequest request;
EchoResponse response;
ClientContext cli_ctx;
RpcState() = default;
~RpcState() {
// Grab the lock to prevent destruction while another is still holding
// lock
std::lock_guard<std::mutex> lock(mu);
}
};
std::vector<RpcState> rpc_state(3);
for (size_t i = 0; i < rpc_state.size(); i++) {
std::string message = "Hello locked world";
message += std::to_string(i);
rpc_state[i].request.set_message(message);
}
// Grab a lock and then start an RPC whose callback grabs the same lock and
// then calls this function to start the next RPC under lock (up to a limit of
// the size of the rpc_state vector).
std::function<void(int)> nested_call = [this, &nested_call,
&rpc_state](int index) {
std::lock_guard<std::mutex> l(rpc_state[index].mu);
stub_->experimental_async()->Echo(
&rpc_state[index].cli_ctx, &rpc_state[index].request,
&rpc_state[index].response,
[index, &nested_call, &rpc_state](Status s) {
std::lock_guard<std::mutex> l1(rpc_state[index].mu);
EXPECT_TRUE(s.ok());
rpc_state[index].done = true;
rpc_state[index].cv.notify_all();
// Call the next level of nesting if possible
if (index + 1 < rpc_state.size()) {
nested_call(index + 1);
}
});
};
nested_call(0);
// Wait for completion notifications from all RPCs. Order doesn't matter.
for (RpcState& state : rpc_state) {
std::unique_lock<std::mutex> l(state.mu);
while (!state.done) {
state.cv.wait(l);
}
EXPECT_EQ(state.request.message(), state.response.message());
}
}
TEST_P(ClientCallbackEnd2endTest, SimpleRpcUnderLock) {
MAYBE_SKIP_TEST;
ResetStub();
std::mutex mu;
std::condition_variable cv;
bool done = false;
EchoRequest request;
request.set_message("Hello locked world.");
EchoResponse response;
ClientContext cli_ctx;
{
std::lock_guard<std::mutex> l(mu);
stub_->experimental_async()->Echo(
&cli_ctx, &request, &response,
[&mu, &cv, &done, &request, &response](Status s) {
std::lock_guard<std::mutex> l(mu);
EXPECT_TRUE(s.ok());
EXPECT_EQ(request.message(), response.message());
done = true;
cv.notify_one();
});
}
std::unique_lock<std::mutex> l(mu);
while (!done) {
cv.wait(l);
}
}
TEST_P(ClientCallbackEnd2endTest, SequentialRpcs) {
MAYBE_SKIP_TEST;
ResetStub();
SendRpcs(10, false);
}
TEST_P(ClientCallbackEnd2endTest, SequentialRpcsRawReq) {
MAYBE_SKIP_TEST;
ResetStub();
SendRpcsRawReq(10);
}
TEST_P(ClientCallbackEnd2endTest, SendClientInitialMetadata) {
MAYBE_SKIP_TEST;
ResetStub();
SimpleRequest request;
SimpleResponse response;
ClientContext cli_ctx;
cli_ctx.AddMetadata(kCheckClientInitialMetadataKey,
kCheckClientInitialMetadataVal);
std::mutex mu;
std::condition_variable cv;
bool done = false;
stub_->experimental_async()->CheckClientInitialMetadata(
&cli_ctx, &request, &response, [&done, &mu, &cv](Status s) {
GPR_ASSERT(s.ok());
std::lock_guard<std::mutex> l(mu);
done = true;
cv.notify_one();
});
std::unique_lock<std::mutex> l(mu);
while (!done) {
cv.wait(l);
}
}
TEST_P(ClientCallbackEnd2endTest, SimpleRpcWithBinaryMetadata) {
MAYBE_SKIP_TEST;
ResetStub();
SendRpcs(1, true);
}
TEST_P(ClientCallbackEnd2endTest, SequentialRpcsWithVariedBinaryMetadataValue) {
MAYBE_SKIP_TEST;
ResetStub();
SendRpcs(10, true);
}
TEST_P(ClientCallbackEnd2endTest, SequentialGenericRpcs) {
MAYBE_SKIP_TEST;
ResetStub();
SendRpcsGeneric(10, false);
}
TEST_P(ClientCallbackEnd2endTest, SequentialGenericRpcsAsBidi) {
MAYBE_SKIP_TEST;
ResetStub();
SendGenericEchoAsBidi(10, 1, /*do_writes_done=*/true);
}
TEST_P(ClientCallbackEnd2endTest, SequentialGenericRpcsAsBidiWithReactorReuse) {
MAYBE_SKIP_TEST;
ResetStub();
SendGenericEchoAsBidi(10, 10, /*do_writes_done=*/true);
}
TEST_P(ClientCallbackEnd2endTest, GenericRpcNoWritesDone) {
MAYBE_SKIP_TEST;
ResetStub();
SendGenericEchoAsBidi(1, 1, /*do_writes_done=*/false);
}
#if GRPC_ALLOW_EXCEPTIONS
TEST_P(ClientCallbackEnd2endTest, ExceptingRpc) {
MAYBE_SKIP_TEST;
ResetStub();
SendRpcsGeneric(10, true);
}
#endif
TEST_P(ClientCallbackEnd2endTest, MultipleRpcsWithVariedBinaryMetadataValue) {
MAYBE_SKIP_TEST;
ResetStub();
std::vector<std::thread> threads;
threads.reserve(10);
for (int i = 0; i < 10; ++i) {
threads.emplace_back([this] { SendRpcs(10, true); });
}
for (int i = 0; i < 10; ++i) {
threads[i].join();
}
}
TEST_P(ClientCallbackEnd2endTest, MultipleRpcs) {
MAYBE_SKIP_TEST;
ResetStub();
std::vector<std::thread> threads;
threads.reserve(10);
for (int i = 0; i < 10; ++i) {
threads.emplace_back([this] { SendRpcs(10, false); });
}
for (int i = 0; i < 10; ++i) {
threads[i].join();
}
}
TEST_P(ClientCallbackEnd2endTest, CancelRpcBeforeStart) {
MAYBE_SKIP_TEST;
ResetStub();
EchoRequest request;
EchoResponse response;
ClientContext context;
request.set_message("hello");
context.TryCancel();
std::mutex mu;
std::condition_variable cv;
bool done = false;
stub_->experimental_async()->Echo(
&context, &request, &response, [&response, &done, &mu, &cv](Status s) {
EXPECT_EQ("", response.message());
EXPECT_EQ(grpc::StatusCode::CANCELLED, s.error_code());
std::lock_guard<std::mutex> l(mu);
done = true;
cv.notify_one();
});
std::unique_lock<std::mutex> l(mu);
while (!done) {
cv.wait(l);
}
if (GetParam().use_interceptors) {
EXPECT_EQ(20, DummyInterceptor::GetNumTimesCancel());
}
}
TEST_P(ClientCallbackEnd2endTest, RequestEchoServerCancel) {
MAYBE_SKIP_TEST;
ResetStub();
EchoRequest request;
EchoResponse response;
ClientContext context;
request.set_message("hello");
context.AddMetadata(kServerTryCancelRequest,
std::to_string(CANCEL_BEFORE_PROCESSING));
std::mutex mu;
std::condition_variable cv;
bool done = false;
stub_->experimental_async()->Echo(
&context, &request, &response, [&done, &mu, &cv](Status s) {
EXPECT_FALSE(s.ok());
EXPECT_EQ(grpc::StatusCode::CANCELLED, s.error_code());
std::lock_guard<std::mutex> l(mu);
done = true;
cv.notify_one();
});
std::unique_lock<std::mutex> l(mu);
while (!done) {
cv.wait(l);
}
}
struct ClientCancelInfo {
bool cancel{false};
int ops_before_cancel;
ClientCancelInfo() : cancel{false} {}
explicit ClientCancelInfo(int ops) : cancel{true}, ops_before_cancel{ops} {}
};
class WriteClient : public grpc::experimental::ClientWriteReactor<EchoRequest> {
public:
WriteClient(grpc::testing::EchoTestService::Stub* stub,
ServerTryCancelRequestPhase server_try_cancel,
int num_msgs_to_send, ClientCancelInfo client_cancel = {})
: server_try_cancel_(server_try_cancel),
num_msgs_to_send_(num_msgs_to_send),
client_cancel_{client_cancel} {
std::string msg{"Hello server."};
for (int i = 0; i < num_msgs_to_send; i++) {
desired_ += msg;
}
if (server_try_cancel != DO_NOT_CANCEL) {
// Send server_try_cancel value in the client metadata
context_.AddMetadata(kServerTryCancelRequest,
std::to_string(server_try_cancel));
}
context_.set_initial_metadata_corked(true);
stub->experimental_async()->RequestStream(&context_, &response_, this);
StartCall();
request_.set_message(msg);
MaybeWrite();
}
void OnWriteDone(bool ok) override {
if (ok) {
num_msgs_sent_++;
MaybeWrite();
}
}
void OnDone(const Status& s) override {
gpr_log(GPR_INFO, "Sent %d messages", num_msgs_sent_);
int num_to_send =
(client_cancel_.cancel)
? std::min(num_msgs_to_send_, client_cancel_.ops_before_cancel)
: num_msgs_to_send_;
switch (server_try_cancel_) {
case CANCEL_BEFORE_PROCESSING:
case CANCEL_DURING_PROCESSING:
// If the RPC is canceled by server before / during messages from the
// client, it means that the client most likely did not get a chance to
// send all the messages it wanted to send. i.e num_msgs_sent <=
// num_msgs_to_send
EXPECT_LE(num_msgs_sent_, num_to_send);
break;
case DO_NOT_CANCEL:
case CANCEL_AFTER_PROCESSING:
// If the RPC was not canceled or canceled after all messages were read
// by the server, the client did get a chance to send all its messages
EXPECT_EQ(num_msgs_sent_, num_to_send);
break;
default:
assert(false);
break;
}
if ((server_try_cancel_ == DO_NOT_CANCEL) && !client_cancel_.cancel) {
EXPECT_TRUE(s.ok());
EXPECT_EQ(response_.message(), desired_);
} else {
EXPECT_FALSE(s.ok());
EXPECT_EQ(grpc::StatusCode::CANCELLED, s.error_code());
}
std::unique_lock<std::mutex> l(mu_);
done_ = true;
cv_.notify_one();
}
void Await() {
std::unique_lock<std::mutex> l(mu_);
while (!done_) {
cv_.wait(l);
}
}
private:
void MaybeWrite() {
if (client_cancel_.cancel &&
num_msgs_sent_ == client_cancel_.ops_before_cancel) {
context_.TryCancel();
} else if (num_msgs_to_send_ > num_msgs_sent_ + 1) {
StartWrite(&request_);
} else if (num_msgs_to_send_ == num_msgs_sent_ + 1) {
StartWriteLast(&request_, WriteOptions());
}
}
EchoRequest request_;
EchoResponse response_;
ClientContext context_;
const ServerTryCancelRequestPhase server_try_cancel_;
int num_msgs_sent_{0};
const int num_msgs_to_send_;
std::string desired_;
const ClientCancelInfo client_cancel_;
std::mutex mu_;
std::condition_variable cv_;
bool done_ = false;
};
TEST_P(ClientCallbackEnd2endTest, RequestStream) {
MAYBE_SKIP_TEST;
ResetStub();
WriteClient test{stub_.get(), DO_NOT_CANCEL, 3};
test.Await();
// Make sure that the server interceptors were not notified to cancel
if (GetParam().use_interceptors) {
EXPECT_EQ(0, DummyInterceptor::GetNumTimesCancel());
}
}
TEST_P(ClientCallbackEnd2endTest, ClientCancelsRequestStream) {
MAYBE_SKIP_TEST;
ResetStub();
WriteClient test{stub_.get(), DO_NOT_CANCEL, 3, ClientCancelInfo{2}};
test.Await();
// Make sure that the server interceptors got the cancel
if (GetParam().use_interceptors) {
EXPECT_EQ(20, DummyInterceptor::GetNumTimesCancel());
}
}
// Server to cancel before doing reading the request
TEST_P(ClientCallbackEnd2endTest, RequestStreamServerCancelBeforeReads) {
MAYBE_SKIP_TEST;
ResetStub();
WriteClient test{stub_.get(), CANCEL_BEFORE_PROCESSING, 1};
test.Await();
// Make sure that the server interceptors were notified
if (GetParam().use_interceptors) {
EXPECT_EQ(20, DummyInterceptor::GetNumTimesCancel());
}
}
// Server to cancel while reading a request from the stream in parallel
TEST_P(ClientCallbackEnd2endTest, RequestStreamServerCancelDuringRead) {
MAYBE_SKIP_TEST;
ResetStub();
WriteClient test{stub_.get(), CANCEL_DURING_PROCESSING, 10};
test.Await();
// Make sure that the server interceptors were notified
if (GetParam().use_interceptors) {
EXPECT_EQ(20, DummyInterceptor::GetNumTimesCancel());
}
}
// Server to cancel after reading all the requests but before returning to the
// client
TEST_P(ClientCallbackEnd2endTest, RequestStreamServerCancelAfterReads) {
MAYBE_SKIP_TEST;
ResetStub();
WriteClient test{stub_.get(), CANCEL_AFTER_PROCESSING, 4};
test.Await();
// Make sure that the server interceptors were notified
if (GetParam().use_interceptors) {
EXPECT_EQ(20, DummyInterceptor::GetNumTimesCancel());
}
}
TEST_P(ClientCallbackEnd2endTest, UnaryReactor) {
MAYBE_SKIP_TEST;
ResetStub();
class UnaryClient : public grpc::experimental::ClientUnaryReactor {
public:
UnaryClient(grpc::testing::EchoTestService::Stub* stub) {
cli_ctx_.AddMetadata("key1", "val1");
cli_ctx_.AddMetadata("key2", "val2");
request_.mutable_param()->set_echo_metadata_initially(true);
request_.set_message("Hello metadata");
stub->experimental_async()->Echo(&cli_ctx_, &request_, &response_, this);
StartCall();
}
void OnReadInitialMetadataDone(bool ok) override {
EXPECT_TRUE(ok);
EXPECT_EQ(1u, cli_ctx_.GetServerInitialMetadata().count("key1"));
EXPECT_EQ(
"val1",
ToString(cli_ctx_.GetServerInitialMetadata().find("key1")->second));
EXPECT_EQ(1u, cli_ctx_.GetServerInitialMetadata().count("key2"));
EXPECT_EQ(
"val2",
ToString(cli_ctx_.GetServerInitialMetadata().find("key2")->second));
initial_metadata_done_ = true;
}
void OnDone(const Status& s) override {
EXPECT_TRUE(initial_metadata_done_);
EXPECT_EQ(0u, cli_ctx_.GetServerTrailingMetadata().size());
EXPECT_TRUE(s.ok());
EXPECT_EQ(request_.message(), response_.message());
std::unique_lock<std::mutex> l(mu_);
done_ = true;
cv_.notify_one();
}
void Await() {
std::unique_lock<std::mutex> l(mu_);
while (!done_) {
cv_.wait(l);
}
}
private:
EchoRequest request_;
EchoResponse response_;
ClientContext cli_ctx_;
std::mutex mu_;
std::condition_variable cv_;
bool done_{false};
bool initial_metadata_done_{false};
};
UnaryClient test{stub_.get()};
test.Await();
// Make sure that the server interceptors were not notified of a cancel
if (GetParam().use_interceptors) {
EXPECT_EQ(0, DummyInterceptor::GetNumTimesCancel());
}
}
TEST_P(ClientCallbackEnd2endTest, GenericUnaryReactor) {
MAYBE_SKIP_TEST;
ResetStub();
const std::string kMethodName("/grpc.testing.EchoTestService/Echo");
class UnaryClient : public grpc::experimental::ClientUnaryReactor {
public:
UnaryClient(grpc::GenericStub* stub, const std::string& method_name) {
cli_ctx_.AddMetadata("key1", "val1");
cli_ctx_.AddMetadata("key2", "val2");
request_.mutable_param()->set_echo_metadata_initially(true);
request_.set_message("Hello metadata");
send_buf_ = SerializeToByteBuffer(&request_);
stub->experimental().PrepareUnaryCall(&cli_ctx_, method_name,
send_buf_.get(), &recv_buf_, this);
StartCall();
}
void OnReadInitialMetadataDone(bool ok) override {
EXPECT_TRUE(ok);
EXPECT_EQ(1u, cli_ctx_.GetServerInitialMetadata().count("key1"));
EXPECT_EQ(
"val1",
ToString(cli_ctx_.GetServerInitialMetadata().find("key1")->second));
EXPECT_EQ(1u, cli_ctx_.GetServerInitialMetadata().count("key2"));
EXPECT_EQ(
"val2",
ToString(cli_ctx_.GetServerInitialMetadata().find("key2")->second));
initial_metadata_done_ = true;
}
void OnDone(const Status& s) override {
EXPECT_TRUE(initial_metadata_done_);
EXPECT_EQ(0u, cli_ctx_.GetServerTrailingMetadata().size());
EXPECT_TRUE(s.ok());
EchoResponse response;
EXPECT_TRUE(ParseFromByteBuffer(&recv_buf_, &response));
EXPECT_EQ(request_.message(), response.message());
std::unique_lock<std::mutex> l(mu_);
done_ = true;
cv_.notify_one();
}
void Await() {
std::unique_lock<std::mutex> l(mu_);
while (!done_) {
cv_.wait(l);
}
}
private:
EchoRequest request_;
std::unique_ptr<ByteBuffer> send_buf_;
ByteBuffer recv_buf_;
ClientContext cli_ctx_;
std::mutex mu_;
std::condition_variable cv_;
bool done_{false};
bool initial_metadata_done_{false};
};
UnaryClient test{generic_stub_.get(), kMethodName};
test.Await();
// Make sure that the server interceptors were not notified of a cancel
if (GetParam().use_interceptors) {
EXPECT_EQ(0, DummyInterceptor::GetNumTimesCancel());
}
}
class ReadClient : public grpc::experimental::ClientReadReactor<EchoResponse> {
public:
ReadClient(grpc::testing::EchoTestService::Stub* stub,
ServerTryCancelRequestPhase server_try_cancel,
ClientCancelInfo client_cancel = {})
: server_try_cancel_(server_try_cancel), client_cancel_{client_cancel} {
if (server_try_cancel_ != DO_NOT_CANCEL) {
// Send server_try_cancel value in the client metadata
context_.AddMetadata(kServerTryCancelRequest,
std::to_string(server_try_cancel));
}
request_.set_message("Hello client ");
stub->experimental_async()->ResponseStream(&context_, &request_, this);
if (client_cancel_.cancel &&
reads_complete_ == client_cancel_.ops_before_cancel) {
context_.TryCancel();
}
// Even if we cancel, read until failure because there might be responses
// pending
StartRead(&response_);
StartCall();
}
void OnReadDone(bool ok) override {
if (!ok) {
if (server_try_cancel_ == DO_NOT_CANCEL && !client_cancel_.cancel) {
EXPECT_EQ(reads_complete_, kServerDefaultResponseStreamsToSend);
}
} else {
EXPECT_LE(reads_complete_, kServerDefaultResponseStreamsToSend);
EXPECT_EQ(response_.message(),
request_.message() + std::to_string(reads_complete_));
reads_complete_++;
if (client_cancel_.cancel &&
reads_complete_ == client_cancel_.ops_before_cancel) {
context_.TryCancel();
}
// Even if we cancel, read until failure because there might be responses
// pending
StartRead(&response_);
}
}
void OnDone(const Status& s) override {
gpr_log(GPR_INFO, "Read %d messages", reads_complete_);
switch (server_try_cancel_) {
case DO_NOT_CANCEL:
if (!client_cancel_.cancel || client_cancel_.ops_before_cancel >
kServerDefaultResponseStreamsToSend) {
EXPECT_TRUE(s.ok());
EXPECT_EQ(reads_complete_, kServerDefaultResponseStreamsToSend);
} else {
EXPECT_GE(reads_complete_, client_cancel_.ops_before_cancel);
EXPECT_LE(reads_complete_, kServerDefaultResponseStreamsToSend);
// Status might be ok or cancelled depending on whether server
// sent status before client cancel went through
if (!s.ok()) {
EXPECT_EQ(grpc::StatusCode::CANCELLED, s.error_code());
}
}
break;
case CANCEL_BEFORE_PROCESSING:
EXPECT_FALSE(s.ok());
EXPECT_EQ(grpc::StatusCode::CANCELLED, s.error_code());
EXPECT_EQ(reads_complete_, 0);
break;
case CANCEL_DURING_PROCESSING:
case CANCEL_AFTER_PROCESSING:
// If server canceled while writing messages, client must have read
// less than or equal to the expected number of messages. Even if the
// server canceled after writing all messages, the RPC may be canceled
// before the Client got a chance to read all the messages.
EXPECT_FALSE(s.ok());
EXPECT_EQ(grpc::StatusCode::CANCELLED, s.error_code());
EXPECT_LE(reads_complete_, kServerDefaultResponseStreamsToSend);
break;
default:
assert(false);
}
std::unique_lock<std::mutex> l(mu_);
done_ = true;
cv_.notify_one();
}
void Await() {
std::unique_lock<std::mutex> l(mu_);
while (!done_) {
cv_.wait(l);
}
}
private:
EchoRequest request_;
EchoResponse response_;
ClientContext context_;
const ServerTryCancelRequestPhase server_try_cancel_;
int reads_complete_{0};
const ClientCancelInfo client_cancel_;
std::mutex mu_;
std::condition_variable cv_;
bool done_ = false;
};
TEST_P(ClientCallbackEnd2endTest, ResponseStream) {
MAYBE_SKIP_TEST;
ResetStub();
ReadClient test{stub_.get(), DO_NOT_CANCEL};
test.Await();
// Make sure that the server interceptors were not notified of a cancel
if (GetParam().use_interceptors) {
EXPECT_EQ(0, DummyInterceptor::GetNumTimesCancel());
}
}
TEST_P(ClientCallbackEnd2endTest, ClientCancelsResponseStream) {
MAYBE_SKIP_TEST;
ResetStub();
ReadClient test{stub_.get(), DO_NOT_CANCEL, ClientCancelInfo{2}};
test.Await();
// Because cancel in this case races with server finish, we can't be sure that
// server interceptors even see cancellation
}
// Server to cancel before sending any response messages
TEST_P(ClientCallbackEnd2endTest, ResponseStreamServerCancelBefore) {
MAYBE_SKIP_TEST;
ResetStub();
ReadClient test{stub_.get(), CANCEL_BEFORE_PROCESSING};
test.Await();
// Make sure that the server interceptors were notified
if (GetParam().use_interceptors) {
EXPECT_EQ(20, DummyInterceptor::GetNumTimesCancel());
}
}
// Server to cancel while writing a response to the stream in parallel
TEST_P(ClientCallbackEnd2endTest, ResponseStreamServerCancelDuring) {
MAYBE_SKIP_TEST;
ResetStub();
ReadClient test{stub_.get(), CANCEL_DURING_PROCESSING};
test.Await();
// Make sure that the server interceptors were notified
if (GetParam().use_interceptors) {
EXPECT_EQ(20, DummyInterceptor::GetNumTimesCancel());
}
}
// Server to cancel after writing all the respones to the stream but before
// returning to the client
TEST_P(ClientCallbackEnd2endTest, ResponseStreamServerCancelAfter) {
MAYBE_SKIP_TEST;
ResetStub();
ReadClient test{stub_.get(), CANCEL_AFTER_PROCESSING};
test.Await();
// Make sure that the server interceptors were notified
if (GetParam().use_interceptors) {
EXPECT_EQ(20, DummyInterceptor::GetNumTimesCancel());
}
}
class BidiClient
: public grpc::experimental::ClientBidiReactor<EchoRequest, EchoResponse> {
public:
BidiClient(grpc::testing::EchoTestService::Stub* stub,
ServerTryCancelRequestPhase server_try_cancel,
int num_msgs_to_send, bool cork_metadata, bool first_write_async,
ClientCancelInfo client_cancel = {})
: server_try_cancel_(server_try_cancel),
msgs_to_send_{num_msgs_to_send},
client_cancel_{client_cancel} {
if (server_try_cancel_ != DO_NOT_CANCEL) {
// Send server_try_cancel value in the client metadata
context_.AddMetadata(kServerTryCancelRequest,
std::to_string(server_try_cancel));
}
request_.set_message("Hello fren ");
context_.set_initial_metadata_corked(cork_metadata);
stub->experimental_async()->BidiStream(&context_, this);
MaybeAsyncWrite(first_write_async);
StartRead(&response_);
StartCall();
}
void OnReadDone(bool ok) override {
if (!ok) {
if (server_try_cancel_ == DO_NOT_CANCEL) {
if (!client_cancel_.cancel) {
EXPECT_EQ(reads_complete_, msgs_to_send_);
} else {
EXPECT_LE(reads_complete_, writes_complete_);
}
}
} else {
EXPECT_LE(reads_complete_, msgs_to_send_);
EXPECT_EQ(response_.message(), request_.message());
reads_complete_++;
StartRead(&response_);
}
}
void OnWriteDone(bool ok) override {
if (async_write_thread_.joinable()) {
async_write_thread_.join();
RemoveHold();
}
if (server_try_cancel_ == DO_NOT_CANCEL) {
EXPECT_TRUE(ok);
} else if (!ok) {
return;
}
writes_complete_++;
MaybeWrite();
}
void OnDone(const Status& s) override {
gpr_log(GPR_INFO, "Sent %d messages", writes_complete_);
gpr_log(GPR_INFO, "Read %d messages", reads_complete_);
switch (server_try_cancel_) {
case DO_NOT_CANCEL:
if (!client_cancel_.cancel ||
client_cancel_.ops_before_cancel > msgs_to_send_) {
EXPECT_TRUE(s.ok());
EXPECT_EQ(writes_complete_, msgs_to_send_);
EXPECT_EQ(reads_complete_, writes_complete_);
} else {
EXPECT_FALSE(s.ok());
EXPECT_EQ(grpc::StatusCode::CANCELLED, s.error_code());
EXPECT_EQ(writes_complete_, client_cancel_.ops_before_cancel);
EXPECT_LE(reads_complete_, writes_complete_);
}
break;
case CANCEL_BEFORE_PROCESSING:
EXPECT_FALSE(s.ok());
EXPECT_EQ(grpc::StatusCode::CANCELLED, s.error_code());
// The RPC is canceled before the server did any work or returned any
// reads, but it's possible that some writes took place first from the
// client
EXPECT_LE(writes_complete_, msgs_to_send_);
EXPECT_EQ(reads_complete_, 0);
break;
case CANCEL_DURING_PROCESSING:
EXPECT_FALSE(s.ok());
EXPECT_EQ(grpc::StatusCode::CANCELLED, s.error_code());
EXPECT_LE(writes_complete_, msgs_to_send_);
EXPECT_LE(reads_complete_, writes_complete_);
break;
case CANCEL_AFTER_PROCESSING:
EXPECT_FALSE(s.ok());
EXPECT_EQ(grpc::StatusCode::CANCELLED, s.error_code());
EXPECT_EQ(writes_complete_, msgs_to_send_);
// The Server canceled after reading the last message and after writing
// the message to the client. However, the RPC cancellation might have
// taken effect before the client actually read the response.
EXPECT_LE(reads_complete_, writes_complete_);
break;
default:
assert(false);
}
std::unique_lock<std::mutex> l(mu_);
done_ = true;
cv_.notify_one();
}
void Await() {
std::unique_lock<std::mutex> l(mu_);
while (!done_) {
cv_.wait(l);
}
}
private:
void MaybeAsyncWrite(bool first_write_async) {
if (first_write_async) {
// Make sure that we have a write to issue.
// TODO(vjpai): Make this work with 0 writes case as well.
assert(msgs_to_send_ >= 1);
AddHold();
async_write_thread_ = std::thread([this] {
std::unique_lock<std::mutex> lock(async_write_thread_mu_);
async_write_thread_cv_.wait(
lock, [this] { return async_write_thread_start_; });
MaybeWrite();
});
std::lock_guard<std::mutex> lock(async_write_thread_mu_);
async_write_thread_start_ = true;
async_write_thread_cv_.notify_one();
return;
}
MaybeWrite();
}
void MaybeWrite() {
if (client_cancel_.cancel &&
writes_complete_ == client_cancel_.ops_before_cancel) {
context_.TryCancel();
} else if (writes_complete_ == msgs_to_send_) {
StartWritesDone();
} else {
StartWrite(&request_);
}
}
EchoRequest request_;
EchoResponse response_;
ClientContext context_;
const ServerTryCancelRequestPhase server_try_cancel_;
int reads_complete_{0};
int writes_complete_{0};
const int msgs_to_send_;
const ClientCancelInfo client_cancel_;
std::mutex mu_;
std::condition_variable cv_;
bool done_ = false;
std::thread async_write_thread_;
bool async_write_thread_start_ = false;
std::mutex async_write_thread_mu_;
std::condition_variable async_write_thread_cv_;
};
TEST_P(ClientCallbackEnd2endTest, BidiStream) {
MAYBE_SKIP_TEST;
ResetStub();
BidiClient test(stub_.get(), DO_NOT_CANCEL,
kServerDefaultResponseStreamsToSend,
/*cork_metadata=*/false, /*first_write_async=*/false);
test.Await();
// Make sure that the server interceptors were not notified of a cancel
if (GetParam().use_interceptors) {
EXPECT_EQ(0, DummyInterceptor::GetNumTimesCancel());
}
}
TEST_P(ClientCallbackEnd2endTest, BidiStreamFirstWriteAsync) {
MAYBE_SKIP_TEST;
ResetStub();
BidiClient test(stub_.get(), DO_NOT_CANCEL,
kServerDefaultResponseStreamsToSend,
/*cork_metadata=*/false, /*first_write_async=*/true);
test.Await();
// Make sure that the server interceptors were not notified of a cancel
if (GetParam().use_interceptors) {
EXPECT_EQ(0, DummyInterceptor::GetNumTimesCancel());
}
}
TEST_P(ClientCallbackEnd2endTest, BidiStreamCorked) {
MAYBE_SKIP_TEST;
ResetStub();
BidiClient test(stub_.get(), DO_NOT_CANCEL,
kServerDefaultResponseStreamsToSend,
/*cork_metadata=*/true, /*first_write_async=*/false);
test.Await();
// Make sure that the server interceptors were not notified of a cancel
if (GetParam().use_interceptors) {
EXPECT_EQ(0, DummyInterceptor::GetNumTimesCancel());
}
}
TEST_P(ClientCallbackEnd2endTest, BidiStreamCorkedFirstWriteAsync) {
MAYBE_SKIP_TEST;
ResetStub();
BidiClient test(stub_.get(), DO_NOT_CANCEL,
kServerDefaultResponseStreamsToSend,
/*cork_metadata=*/true, /*first_write_async=*/true);
test.Await();
// Make sure that the server interceptors were not notified of a cancel
if (GetParam().use_interceptors) {
EXPECT_EQ(0, DummyInterceptor::GetNumTimesCancel());
}
}
TEST_P(ClientCallbackEnd2endTest, ClientCancelsBidiStream) {
MAYBE_SKIP_TEST;
ResetStub();
BidiClient test(stub_.get(), DO_NOT_CANCEL,
kServerDefaultResponseStreamsToSend,
/*cork_metadata=*/false, /*first_write_async=*/false,
ClientCancelInfo(2));
test.Await();
// Make sure that the server interceptors were notified of a cancel
if (GetParam().use_interceptors) {
EXPECT_EQ(20, DummyInterceptor::GetNumTimesCancel());
}
}
// Server to cancel before reading/writing any requests/responses on the stream
TEST_P(ClientCallbackEnd2endTest, BidiStreamServerCancelBefore) {
MAYBE_SKIP_TEST;
ResetStub();
BidiClient test(stub_.get(), CANCEL_BEFORE_PROCESSING, /*num_msgs_to_send=*/2,
/*cork_metadata=*/false, /*first_write_async=*/false);
test.Await();
// Make sure that the server interceptors were notified
if (GetParam().use_interceptors) {
EXPECT_EQ(20, DummyInterceptor::GetNumTimesCancel());
}
}
// Server to cancel while reading/writing requests/responses on the stream in
// parallel
TEST_P(ClientCallbackEnd2endTest, BidiStreamServerCancelDuring) {
MAYBE_SKIP_TEST;
ResetStub();
BidiClient test(stub_.get(), CANCEL_DURING_PROCESSING,
/*num_msgs_to_send=*/10, /*cork_metadata=*/false,
/*first_write_async=*/false);
test.Await();
// Make sure that the server interceptors were notified
if (GetParam().use_interceptors) {
EXPECT_EQ(20, DummyInterceptor::GetNumTimesCancel());
}
}
// Server to cancel after reading/writing all requests/responses on the stream
// but before returning to the client
TEST_P(ClientCallbackEnd2endTest, BidiStreamServerCancelAfter) {
MAYBE_SKIP_TEST;
ResetStub();
BidiClient test(stub_.get(), CANCEL_AFTER_PROCESSING, /*num_msgs_to_send=*/5,
/*cork_metadata=*/false, /*first_write_async=*/false);
test.Await();
// Make sure that the server interceptors were notified
if (GetParam().use_interceptors) {
EXPECT_EQ(20, DummyInterceptor::GetNumTimesCancel());
}
}
TEST_P(ClientCallbackEnd2endTest, SimultaneousReadAndWritesDone) {
MAYBE_SKIP_TEST;
ResetStub();
class Client : public grpc::experimental::ClientBidiReactor<EchoRequest,
EchoResponse> {
public:
Client(grpc::testing::EchoTestService::Stub* stub) {
request_.set_message("Hello bidi ");
stub->experimental_async()->BidiStream(&context_, this);
StartWrite(&request_);
StartCall();
}
void OnReadDone(bool ok) override {
EXPECT_TRUE(ok);
EXPECT_EQ(response_.message(), request_.message());
}
void OnWriteDone(bool ok) override {
EXPECT_TRUE(ok);
// Now send out the simultaneous Read and WritesDone
StartWritesDone();
StartRead(&response_);
}
void OnDone(const Status& s) override {
EXPECT_TRUE(s.ok());
EXPECT_EQ(response_.message(), request_.message());
std::unique_lock<std::mutex> l(mu_);
done_ = true;
cv_.notify_one();
}
void Await() {
std::unique_lock<std::mutex> l(mu_);
while (!done_) {
cv_.wait(l);
}
}
private:
EchoRequest request_;
EchoResponse response_;
ClientContext context_;
std::mutex mu_;
std::condition_variable cv_;
bool done_ = false;
} test{stub_.get()};
test.Await();
}
TEST_P(ClientCallbackEnd2endTest, UnimplementedRpc) {
MAYBE_SKIP_TEST;
ChannelArguments args;
const auto& channel_creds = GetCredentialsProvider()->GetChannelCredentials(
GetParam().credentials_type, &args);
std::shared_ptr<Channel> channel =
(GetParam().protocol == Protocol::TCP)
? ::grpc::CreateCustomChannel(server_address_.str(), channel_creds,
args)
: server_->InProcessChannel(args);
std::unique_ptr<grpc::testing::UnimplementedEchoService::Stub> stub;
stub = grpc::testing::UnimplementedEchoService::NewStub(channel);
EchoRequest request;
EchoResponse response;
ClientContext cli_ctx;
request.set_message("Hello world.");
std::mutex mu;
std::condition_variable cv;
bool done = false;
stub->experimental_async()->Unimplemented(
&cli_ctx, &request, &response, [&done, &mu, &cv](Status s) {
EXPECT_EQ(StatusCode::UNIMPLEMENTED, s.error_code());
EXPECT_EQ("", s.error_message());
std::lock_guard<std::mutex> l(mu);
done = true;
cv.notify_one();
});
std::unique_lock<std::mutex> l(mu);
while (!done) {
cv.wait(l);
}
}
TEST_P(ClientCallbackEnd2endTest,
ResponseStreamExtraReactionFlowReadsUntilDone) {
MAYBE_SKIP_TEST;
ResetStub();
class ReadAllIncomingDataClient
: public grpc::experimental::ClientReadReactor<EchoResponse> {
public:
ReadAllIncomingDataClient(grpc::testing::EchoTestService::Stub* stub) {
request_.set_message("Hello client ");
stub->experimental_async()->ResponseStream(&context_, &request_, this);
}
bool WaitForReadDone() {
std::unique_lock<std::mutex> l(mu_);
while (!read_done_) {
read_cv_.wait(l);
}
read_done_ = false;
return read_ok_;
}
void Await() {
std::unique_lock<std::mutex> l(mu_);
while (!done_) {
done_cv_.wait(l);
}
}
// RemoveHold under the same lock used for OnDone to make sure that we don't
// call OnDone directly or indirectly from the RemoveHold function.
void RemoveHoldUnderLock() {
std::unique_lock<std::mutex> l(mu_);
RemoveHold();
}
const Status& status() {
std::unique_lock<std::mutex> l(mu_);
return status_;
}
private:
void OnReadDone(bool ok) override {
std::unique_lock<std::mutex> l(mu_);
read_ok_ = ok;
read_done_ = true;
read_cv_.notify_one();
}
void OnDone(const Status& s) override {
std::unique_lock<std::mutex> l(mu_);
done_ = true;
status_ = s;
done_cv_.notify_one();
}
EchoRequest request_;
EchoResponse response_;
ClientContext context_;
bool read_ok_ = false;
bool read_done_ = false;
std::mutex mu_;
std::condition_variable read_cv_;
std::condition_variable done_cv_;
bool done_ = false;
Status status_;
} client{stub_.get()};
int reads_complete = 0;
client.AddHold();
client.StartCall();
EchoResponse response;
bool read_ok = true;
while (read_ok) {
client.StartRead(&response);
read_ok = client.WaitForReadDone();
if (read_ok) {
++reads_complete;
}
}
client.RemoveHoldUnderLock();
client.Await();
EXPECT_EQ(kServerDefaultResponseStreamsToSend, reads_complete);
EXPECT_EQ(client.status().error_code(), grpc::StatusCode::OK);
}
std::vector<TestScenario> CreateTestScenarios(bool test_insecure) {
#if TARGET_OS_IPHONE
// Workaround Apple CFStream bug
gpr_setenv("grpc_cfstream", "0");
#endif
std::vector<TestScenario> scenarios;
std::vector<std::string> credentials_types{
GetCredentialsProvider()->GetSecureCredentialsTypeList()};
auto insec_ok = [] {
// Only allow insecure credentials type when it is registered with the
// provider. User may create providers that do not have insecure.
return GetCredentialsProvider()->GetChannelCredentials(
kInsecureCredentialsType, nullptr) != nullptr;
};
if (test_insecure && insec_ok()) {
credentials_types.push_back(kInsecureCredentialsType);
}
GPR_ASSERT(!credentials_types.empty());
bool barr[]{false, true};
Protocol parr[]{Protocol::INPROC, Protocol::TCP};
for (Protocol p : parr) {
for (const auto& cred : credentials_types) {
// TODO(vjpai): Test inproc with secure credentials when feasible
if (p == Protocol::INPROC &&
(cred != kInsecureCredentialsType || !insec_ok())) {
continue;
}
for (bool callback_server : barr) {
for (bool use_interceptors : barr) {
scenarios.emplace_back(callback_server, p, use_interceptors, cred);
}
}
}
}
return scenarios;
}
INSTANTIATE_TEST_SUITE_P(ClientCallbackEnd2endTest, ClientCallbackEnd2endTest,
::testing::ValuesIn(CreateTestScenarios(true)));
} // namespace
} // namespace testing
} // namespace grpc
int main(int argc, char** argv) {
::testing::InitGoogleTest(&argc, argv);
grpc::testing::TestEnvironment env(argc, argv);
grpc_init();
int ret = RUN_ALL_TESTS();
grpc_shutdown();
return ret;
}