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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 <memory>
#include <vector>
#include "absl/memory/memory.h"
#include <grpcpp/channel.h>
#include <grpcpp/client_context.h>
#include <grpcpp/create_channel.h>
#include <grpcpp/create_channel_posix.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/server_posix.h>
#include <grpcpp/support/client_interceptor.h>
#include "src/core/lib/iomgr/port.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"
#ifdef GRPC_POSIX_SOCKET
#include <fcntl.h>
#include "src/core/lib/iomgr/socket_utils_posix.h"
#endif /* GRPC_POSIX_SOCKET */
#include <gtest/gtest.h>
namespace grpc {
namespace testing {
namespace {
enum class RPCType {
kSyncUnary,
kSyncClientStreaming,
kSyncServerStreaming,
kSyncBidiStreaming,
kAsyncCQUnary,
kAsyncCQClientStreaming,
kAsyncCQServerStreaming,
kAsyncCQBidiStreaming,
};
enum class ChannelType {
kHttpChannel,
kFdChannel,
};
/* Hijacks Echo RPC and fills in the expected values */
class HijackingInterceptor : public experimental::Interceptor {
public:
explicit HijackingInterceptor(experimental::ClientRpcInfo* info) {
info_ = info;
// Make sure it is the right method
EXPECT_EQ(strcmp("/grpc.testing.EchoTestService/Echo", info->method()), 0);
EXPECT_EQ(info->type(), experimental::ClientRpcInfo::Type::UNARY);
}
void Intercept(experimental::InterceptorBatchMethods* methods) override {
bool hijack = false;
if (methods->QueryInterceptionHookPoint(
experimental::InterceptionHookPoints::PRE_SEND_INITIAL_METADATA)) {
auto* map = methods->GetSendInitialMetadata();
// Check that we can see the test metadata
ASSERT_EQ(map->size(), static_cast<unsigned>(1));
auto iterator = map->begin();
EXPECT_EQ("testkey", iterator->first);
EXPECT_EQ("testvalue", iterator->second);
hijack = true;
}
if (methods->QueryInterceptionHookPoint(
experimental::InterceptionHookPoints::PRE_SEND_MESSAGE)) {
EchoRequest req;
auto* buffer = methods->GetSerializedSendMessage();
auto copied_buffer = *buffer;
EXPECT_TRUE(
SerializationTraits<EchoRequest>::Deserialize(&copied_buffer, &req)
.ok());
EXPECT_EQ(req.message(), "Hello");
}
if (methods->QueryInterceptionHookPoint(
experimental::InterceptionHookPoints::PRE_SEND_CLOSE)) {
// Got nothing to do here for now
}
if (methods->QueryInterceptionHookPoint(
experimental::InterceptionHookPoints::POST_RECV_INITIAL_METADATA)) {
auto* map = methods->GetRecvInitialMetadata();
// Got nothing better to do here for now
EXPECT_EQ(map->size(), static_cast<unsigned>(0));
}
if (methods->QueryInterceptionHookPoint(
experimental::InterceptionHookPoints::POST_RECV_MESSAGE)) {
EchoResponse* resp =
static_cast<EchoResponse*>(methods->GetRecvMessage());
// Check that we got the hijacked message, and re-insert the expected
// message
EXPECT_EQ(resp->message(), "Hello1");
resp->set_message("Hello");
}
if (methods->QueryInterceptionHookPoint(
experimental::InterceptionHookPoints::POST_RECV_STATUS)) {
auto* map = methods->GetRecvTrailingMetadata();
bool found = false;
// Check that we received the metadata as an echo
for (const auto& pair : *map) {
found = pair.first.starts_with("testkey") &&
pair.second.starts_with("testvalue");
if (found) break;
}
EXPECT_EQ(found, true);
auto* status = methods->GetRecvStatus();
EXPECT_EQ(status->ok(), true);
}
if (methods->QueryInterceptionHookPoint(
experimental::InterceptionHookPoints::PRE_RECV_INITIAL_METADATA)) {
auto* map = methods->GetRecvInitialMetadata();
// Got nothing better to do here at the moment
EXPECT_EQ(map->size(), static_cast<unsigned>(0));
}
if (methods->QueryInterceptionHookPoint(
experimental::InterceptionHookPoints::PRE_RECV_MESSAGE)) {
// Insert a different message than expected
EchoResponse* resp =
static_cast<EchoResponse*>(methods->GetRecvMessage());
resp->set_message("Hello1");
}
if (methods->QueryInterceptionHookPoint(
experimental::InterceptionHookPoints::PRE_RECV_STATUS)) {
auto* map = methods->GetRecvTrailingMetadata();
// insert the metadata that we want
EXPECT_EQ(map->size(), static_cast<unsigned>(0));
map->insert(std::make_pair("testkey", "testvalue"));
auto* status = methods->GetRecvStatus();
*status = Status(StatusCode::OK, "");
}
if (hijack) {
methods->Hijack();
} else {
methods->Proceed();
}
}
private:
experimental::ClientRpcInfo* info_;
};
class HijackingInterceptorFactory
: public experimental::ClientInterceptorFactoryInterface {
public:
experimental::Interceptor* CreateClientInterceptor(
experimental::ClientRpcInfo* info) override {
return new HijackingInterceptor(info);
}
};
class HijackingInterceptorMakesAnotherCall : public experimental::Interceptor {
public:
explicit HijackingInterceptorMakesAnotherCall(
experimental::ClientRpcInfo* info) {
info_ = info;
// Make sure it is the right method
EXPECT_EQ(strcmp("/grpc.testing.EchoTestService/Echo", info->method()), 0);
}
void Intercept(experimental::InterceptorBatchMethods* methods) override {
if (methods->QueryInterceptionHookPoint(
experimental::InterceptionHookPoints::PRE_SEND_INITIAL_METADATA)) {
auto* map = methods->GetSendInitialMetadata();
// Check that we can see the test metadata
ASSERT_EQ(map->size(), static_cast<unsigned>(1));
auto iterator = map->begin();
EXPECT_EQ("testkey", iterator->first);
EXPECT_EQ("testvalue", iterator->second);
// Make a copy of the map
metadata_map_ = *map;
}
if (methods->QueryInterceptionHookPoint(
experimental::InterceptionHookPoints::PRE_SEND_MESSAGE)) {
EchoRequest req;
auto* buffer = methods->GetSerializedSendMessage();
auto copied_buffer = *buffer;
EXPECT_TRUE(
SerializationTraits<EchoRequest>::Deserialize(&copied_buffer, &req)
.ok());
EXPECT_EQ(req.message(), "Hello");
req_ = req;
stub_ = grpc::testing::EchoTestService::NewStub(
methods->GetInterceptedChannel());
ctx_.AddMetadata(metadata_map_.begin()->first,
metadata_map_.begin()->second);
stub_->experimental_async()->Echo(&ctx_, &req_, &resp_,
[this, methods](Status s) {
EXPECT_EQ(s.ok(), true);
EXPECT_EQ(resp_.message(), "Hello");
methods->Hijack();
});
// This is a Unary RPC and we have got nothing interesting to do in the
// PRE_SEND_CLOSE interception hook point for this interceptor, so let's
// return here. (We do not want to call methods->Proceed(). When the new
// RPC returns, we will call methods->Hijack() instead.)
return;
}
if (methods->QueryInterceptionHookPoint(
experimental::InterceptionHookPoints::PRE_SEND_CLOSE)) {
// Got nothing to do here for now
}
if (methods->QueryInterceptionHookPoint(
experimental::InterceptionHookPoints::POST_RECV_INITIAL_METADATA)) {
auto* map = methods->GetRecvInitialMetadata();
// Got nothing better to do here for now
EXPECT_EQ(map->size(), static_cast<unsigned>(0));
}
if (methods->QueryInterceptionHookPoint(
experimental::InterceptionHookPoints::POST_RECV_MESSAGE)) {
EchoResponse* resp =
static_cast<EchoResponse*>(methods->GetRecvMessage());
// Check that we got the hijacked message, and re-insert the expected
// message
EXPECT_EQ(resp->message(), "Hello");
}
if (methods->QueryInterceptionHookPoint(
experimental::InterceptionHookPoints::POST_RECV_STATUS)) {
auto* map = methods->GetRecvTrailingMetadata();
bool found = false;
// Check that we received the metadata as an echo
for (const auto& pair : *map) {
found = pair.first.starts_with("testkey") &&
pair.second.starts_with("testvalue");
if (found) break;
}
EXPECT_EQ(found, true);
auto* status = methods->GetRecvStatus();
EXPECT_EQ(status->ok(), true);
}
if (methods->QueryInterceptionHookPoint(
experimental::InterceptionHookPoints::PRE_RECV_INITIAL_METADATA)) {
auto* map = methods->GetRecvInitialMetadata();
// Got nothing better to do here at the moment
EXPECT_EQ(map->size(), static_cast<unsigned>(0));
}
if (methods->QueryInterceptionHookPoint(
experimental::InterceptionHookPoints::PRE_RECV_MESSAGE)) {
// Insert a different message than expected
EchoResponse* resp =
static_cast<EchoResponse*>(methods->GetRecvMessage());
resp->set_message(resp_.message());
}
if (methods->QueryInterceptionHookPoint(
experimental::InterceptionHookPoints::PRE_RECV_STATUS)) {
auto* map = methods->GetRecvTrailingMetadata();
// insert the metadata that we want
EXPECT_EQ(map->size(), static_cast<unsigned>(0));
map->insert(std::make_pair("testkey", "testvalue"));
auto* status = methods->GetRecvStatus();
*status = Status(StatusCode::OK, "");
}
methods->Proceed();
}
private:
experimental::ClientRpcInfo* info_;
std::multimap<std::string, std::string> metadata_map_;
ClientContext ctx_;
EchoRequest req_;
EchoResponse resp_;
std::unique_ptr<grpc::testing::EchoTestService::Stub> stub_;
};
class HijackingInterceptorMakesAnotherCallFactory
: public experimental::ClientInterceptorFactoryInterface {
public:
experimental::Interceptor* CreateClientInterceptor(
experimental::ClientRpcInfo* info) override {
return new HijackingInterceptorMakesAnotherCall(info);
}
};
class BidiStreamingRpcHijackingInterceptor : public experimental::Interceptor {
public:
explicit BidiStreamingRpcHijackingInterceptor(
experimental::ClientRpcInfo* info) {
info_ = info;
}
void Intercept(experimental::InterceptorBatchMethods* methods) override {
bool hijack = false;
if (methods->QueryInterceptionHookPoint(
experimental::InterceptionHookPoints::PRE_SEND_INITIAL_METADATA)) {
CheckMetadata(*methods->GetSendInitialMetadata(), "testkey", "testvalue");
hijack = true;
}
if (methods->QueryInterceptionHookPoint(
experimental::InterceptionHookPoints::PRE_SEND_MESSAGE)) {
EchoRequest req;
auto* buffer = methods->GetSerializedSendMessage();
auto copied_buffer = *buffer;
EXPECT_TRUE(
SerializationTraits<EchoRequest>::Deserialize(&copied_buffer, &req)
.ok());
EXPECT_EQ(req.message().find("Hello"), 0u);
msg = req.message();
}
if (methods->QueryInterceptionHookPoint(
experimental::InterceptionHookPoints::PRE_SEND_CLOSE)) {
// Got nothing to do here for now
}
if (methods->QueryInterceptionHookPoint(
experimental::InterceptionHookPoints::POST_RECV_STATUS)) {
CheckMetadata(*methods->GetRecvTrailingMetadata(), "testkey",
"testvalue");
auto* status = methods->GetRecvStatus();
EXPECT_EQ(status->ok(), true);
}
if (methods->QueryInterceptionHookPoint(
experimental::InterceptionHookPoints::PRE_RECV_MESSAGE)) {
EchoResponse* resp =
static_cast<EchoResponse*>(methods->GetRecvMessage());
resp->set_message(msg);
}
if (methods->QueryInterceptionHookPoint(
experimental::InterceptionHookPoints::POST_RECV_MESSAGE)) {
EXPECT_EQ(static_cast<EchoResponse*>(methods->GetRecvMessage())
->message()
.find("Hello"),
0u);
}
if (methods->QueryInterceptionHookPoint(
experimental::InterceptionHookPoints::PRE_RECV_STATUS)) {
auto* map = methods->GetRecvTrailingMetadata();
// insert the metadata that we want
EXPECT_EQ(map->size(), static_cast<unsigned>(0));
map->insert(std::make_pair("testkey", "testvalue"));
auto* status = methods->GetRecvStatus();
*status = Status(StatusCode::OK, "");
}
if (hijack) {
methods->Hijack();
} else {
methods->Proceed();
}
}
private:
experimental::ClientRpcInfo* info_;
std::string msg;
};
class ClientStreamingRpcHijackingInterceptor
: public experimental::Interceptor {
public:
explicit ClientStreamingRpcHijackingInterceptor(
experimental::ClientRpcInfo* info) {
info_ = info;
}
void Intercept(experimental::InterceptorBatchMethods* methods) override {
bool hijack = false;
if (methods->QueryInterceptionHookPoint(
experimental::InterceptionHookPoints::PRE_SEND_INITIAL_METADATA)) {
hijack = true;
}
if (methods->QueryInterceptionHookPoint(
experimental::InterceptionHookPoints::PRE_SEND_MESSAGE)) {
if (++count_ > 10) {
methods->FailHijackedSendMessage();
}
}
if (methods->QueryInterceptionHookPoint(
experimental::InterceptionHookPoints::POST_SEND_MESSAGE)) {
EXPECT_FALSE(got_failed_send_);
got_failed_send_ = !methods->GetSendMessageStatus();
}
if (methods->QueryInterceptionHookPoint(
experimental::InterceptionHookPoints::PRE_RECV_STATUS)) {
auto* status = methods->GetRecvStatus();
*status = Status(StatusCode::UNAVAILABLE, "Done sending 10 messages");
}
if (hijack) {
methods->Hijack();
} else {
methods->Proceed();
}
}
static bool GotFailedSend() { return got_failed_send_; }
private:
experimental::ClientRpcInfo* info_;
int count_ = 0;
static bool got_failed_send_;
};
bool ClientStreamingRpcHijackingInterceptor::got_failed_send_ = false;
class ClientStreamingRpcHijackingInterceptorFactory
: public experimental::ClientInterceptorFactoryInterface {
public:
experimental::Interceptor* CreateClientInterceptor(
experimental::ClientRpcInfo* info) override {
return new ClientStreamingRpcHijackingInterceptor(info);
}
};
class ServerStreamingRpcHijackingInterceptor
: public experimental::Interceptor {
public:
explicit ServerStreamingRpcHijackingInterceptor(
experimental::ClientRpcInfo* info) {
info_ = info;
got_failed_message_ = false;
}
void Intercept(experimental::InterceptorBatchMethods* methods) override {
bool hijack = false;
if (methods->QueryInterceptionHookPoint(
experimental::InterceptionHookPoints::PRE_SEND_INITIAL_METADATA)) {
auto* map = methods->GetSendInitialMetadata();
// Check that we can see the test metadata
ASSERT_EQ(map->size(), static_cast<unsigned>(1));
auto iterator = map->begin();
EXPECT_EQ("testkey", iterator->first);
EXPECT_EQ("testvalue", iterator->second);
hijack = true;
}
if (methods->QueryInterceptionHookPoint(
experimental::InterceptionHookPoints::PRE_SEND_MESSAGE)) {
EchoRequest req;
auto* buffer = methods->GetSerializedSendMessage();
auto copied_buffer = *buffer;
EXPECT_TRUE(
SerializationTraits<EchoRequest>::Deserialize(&copied_buffer, &req)
.ok());
EXPECT_EQ(req.message(), "Hello");
}
if (methods->QueryInterceptionHookPoint(
experimental::InterceptionHookPoints::PRE_SEND_CLOSE)) {
// Got nothing to do here for now
}
if (methods->QueryInterceptionHookPoint(
experimental::InterceptionHookPoints::POST_RECV_STATUS)) {
auto* map = methods->GetRecvTrailingMetadata();
bool found = false;
// Check that we received the metadata as an echo
for (const auto& pair : *map) {
found = pair.first.starts_with("testkey") &&
pair.second.starts_with("testvalue");
if (found) break;
}
EXPECT_EQ(found, true);
auto* status = methods->GetRecvStatus();
EXPECT_EQ(status->ok(), true);
}
if (methods->QueryInterceptionHookPoint(
experimental::InterceptionHookPoints::PRE_RECV_MESSAGE)) {
if (++count_ > 10) {
methods->FailHijackedRecvMessage();
}
EchoResponse* resp =
static_cast<EchoResponse*>(methods->GetRecvMessage());
resp->set_message("Hello");
}
if (methods->QueryInterceptionHookPoint(
experimental::InterceptionHookPoints::POST_RECV_MESSAGE)) {
// Only the last message will be a failure
EXPECT_FALSE(got_failed_message_);
got_failed_message_ = methods->GetRecvMessage() == nullptr;
}
if (methods->QueryInterceptionHookPoint(
experimental::InterceptionHookPoints::PRE_RECV_STATUS)) {
auto* map = methods->GetRecvTrailingMetadata();
// insert the metadata that we want
EXPECT_EQ(map->size(), static_cast<unsigned>(0));
map->insert(std::make_pair("testkey", "testvalue"));
auto* status = methods->GetRecvStatus();
*status = Status(StatusCode::OK, "");
}
if (hijack) {
methods->Hijack();
} else {
methods->Proceed();
}
}
static bool GotFailedMessage() { return got_failed_message_; }
private:
experimental::ClientRpcInfo* info_;
static bool got_failed_message_;
int count_ = 0;
};
bool ServerStreamingRpcHijackingInterceptor::got_failed_message_ = false;
class ServerStreamingRpcHijackingInterceptorFactory
: public experimental::ClientInterceptorFactoryInterface {
public:
experimental::Interceptor* CreateClientInterceptor(
experimental::ClientRpcInfo* info) override {
return new ServerStreamingRpcHijackingInterceptor(info);
}
};
class BidiStreamingRpcHijackingInterceptorFactory
: public experimental::ClientInterceptorFactoryInterface {
public:
experimental::Interceptor* CreateClientInterceptor(
experimental::ClientRpcInfo* info) override {
return new BidiStreamingRpcHijackingInterceptor(info);
}
};
// The logging interceptor is for testing purposes only. It is used to verify
// that all the appropriate hook points are invoked for an RPC. The counts are
// reset each time a new object of LoggingInterceptor is created, so only a
// single RPC should be made on the channel before calling the Verify methods.
class LoggingInterceptor : public experimental::Interceptor {
public:
explicit LoggingInterceptor(experimental::ClientRpcInfo* /*info*/) {
pre_send_initial_metadata_ = false;
pre_send_message_count_ = 0;
pre_send_close_ = false;
post_recv_initial_metadata_ = false;
post_recv_message_count_ = 0;
post_recv_status_ = false;
}
void Intercept(experimental::InterceptorBatchMethods* methods) override {
if (methods->QueryInterceptionHookPoint(
experimental::InterceptionHookPoints::PRE_SEND_INITIAL_METADATA)) {
auto* map = methods->GetSendInitialMetadata();
// Check that we can see the test metadata
ASSERT_EQ(map->size(), static_cast<unsigned>(1));
auto iterator = map->begin();
EXPECT_EQ("testkey", iterator->first);
EXPECT_EQ("testvalue", iterator->second);
ASSERT_FALSE(pre_send_initial_metadata_);
pre_send_initial_metadata_ = true;
}
if (methods->QueryInterceptionHookPoint(
experimental::InterceptionHookPoints::PRE_SEND_MESSAGE)) {
EchoRequest req;
auto* send_msg = methods->GetSendMessage();
if (send_msg == nullptr) {
// We did not get the non-serialized form of the message. Get the
// serialized form.
auto* buffer = methods->GetSerializedSendMessage();
auto copied_buffer = *buffer;
EchoRequest req;
EXPECT_TRUE(
SerializationTraits<EchoRequest>::Deserialize(&copied_buffer, &req)
.ok());
EXPECT_EQ(req.message(), "Hello");
} else {
EXPECT_EQ(
static_cast<const EchoRequest*>(send_msg)->message().find("Hello"),
0u);
}
auto* buffer = methods->GetSerializedSendMessage();
auto copied_buffer = *buffer;
EXPECT_TRUE(
SerializationTraits<EchoRequest>::Deserialize(&copied_buffer, &req)
.ok());
EXPECT_TRUE(req.message().find("Hello") == 0u);
pre_send_message_count_++;
}
if (methods->QueryInterceptionHookPoint(
experimental::InterceptionHookPoints::PRE_SEND_CLOSE)) {
// Got nothing to do here for now
pre_send_close_ = true;
}
if (methods->QueryInterceptionHookPoint(
experimental::InterceptionHookPoints::POST_RECV_INITIAL_METADATA)) {
auto* map = methods->GetRecvInitialMetadata();
// Got nothing better to do here for now
EXPECT_EQ(map->size(), static_cast<unsigned>(0));
post_recv_initial_metadata_ = true;
}
if (methods->QueryInterceptionHookPoint(
experimental::InterceptionHookPoints::POST_RECV_MESSAGE)) {
EchoResponse* resp =
static_cast<EchoResponse*>(methods->GetRecvMessage());
if (resp != nullptr) {
EXPECT_TRUE(resp->message().find("Hello") == 0u);
post_recv_message_count_++;
}
}
if (methods->QueryInterceptionHookPoint(
experimental::InterceptionHookPoints::POST_RECV_STATUS)) {
auto* map = methods->GetRecvTrailingMetadata();
bool found = false;
// Check that we received the metadata as an echo
for (const auto& pair : *map) {
found = pair.first.starts_with("testkey") &&
pair.second.starts_with("testvalue");
if (found) break;
}
EXPECT_EQ(found, true);
auto* status = methods->GetRecvStatus();
EXPECT_EQ(status->ok(), true);
post_recv_status_ = true;
}
methods->Proceed();
}
static void VerifyCall(RPCType type) {
switch (type) {
case RPCType::kSyncUnary:
case RPCType::kAsyncCQUnary:
VerifyUnaryCall();
break;
case RPCType::kSyncClientStreaming:
case RPCType::kAsyncCQClientStreaming:
VerifyClientStreamingCall();
break;
case RPCType::kSyncServerStreaming:
case RPCType::kAsyncCQServerStreaming:
VerifyServerStreamingCall();
break;
case RPCType::kSyncBidiStreaming:
case RPCType::kAsyncCQBidiStreaming:
VerifyBidiStreamingCall();
break;
}
}
static void VerifyCallCommon() {
EXPECT_TRUE(pre_send_initial_metadata_);
EXPECT_TRUE(pre_send_close_);
EXPECT_TRUE(post_recv_initial_metadata_);
EXPECT_TRUE(post_recv_status_);
}
static void VerifyUnaryCall() {
VerifyCallCommon();
EXPECT_EQ(pre_send_message_count_, 1);
EXPECT_EQ(post_recv_message_count_, 1);
}
static void VerifyClientStreamingCall() {
VerifyCallCommon();
EXPECT_EQ(pre_send_message_count_, kNumStreamingMessages);
EXPECT_EQ(post_recv_message_count_, 1);
}
static void VerifyServerStreamingCall() {
VerifyCallCommon();
EXPECT_EQ(pre_send_message_count_, 1);
EXPECT_EQ(post_recv_message_count_, kNumStreamingMessages);
}
static void VerifyBidiStreamingCall() {
VerifyCallCommon();
EXPECT_EQ(pre_send_message_count_, kNumStreamingMessages);
EXPECT_EQ(post_recv_message_count_, kNumStreamingMessages);
}
private:
static bool pre_send_initial_metadata_;
static int pre_send_message_count_;
static bool pre_send_close_;
static bool post_recv_initial_metadata_;
static int post_recv_message_count_;
static bool post_recv_status_;
};
bool LoggingInterceptor::pre_send_initial_metadata_;
int LoggingInterceptor::pre_send_message_count_;
bool LoggingInterceptor::pre_send_close_;
bool LoggingInterceptor::post_recv_initial_metadata_;
int LoggingInterceptor::post_recv_message_count_;
bool LoggingInterceptor::post_recv_status_;
class LoggingInterceptorFactory
: public experimental::ClientInterceptorFactoryInterface {
public:
experimental::Interceptor* CreateClientInterceptor(
experimental::ClientRpcInfo* info) override {
return new LoggingInterceptor(info);
}
};
class TestScenario {
public:
explicit TestScenario(const ChannelType& channel_type,
const RPCType& rpc_type)
: channel_type_(channel_type), rpc_type_(rpc_type) {}
ChannelType channel_type() const { return channel_type_; }
RPCType rpc_type() const { return rpc_type_; }
private:
const ChannelType channel_type_;
const RPCType rpc_type_;
};
std::vector<TestScenario> CreateTestScenarios() {
std::vector<TestScenario> scenarios;
std::vector<RPCType> rpc_types;
rpc_types.emplace_back(RPCType::kSyncUnary);
rpc_types.emplace_back(RPCType::kSyncClientStreaming);
rpc_types.emplace_back(RPCType::kSyncServerStreaming);
rpc_types.emplace_back(RPCType::kSyncBidiStreaming);
rpc_types.emplace_back(RPCType::kAsyncCQUnary);
rpc_types.emplace_back(RPCType::kAsyncCQServerStreaming);
for (const auto& rpc_type : rpc_types) {
scenarios.emplace_back(ChannelType::kHttpChannel, rpc_type);
// TODO(yashykt): Maybe add support for non-posix sockets too
#ifdef GRPC_POSIX_SOCKET
scenarios.emplace_back(ChannelType::kFdChannel, rpc_type);
#endif /* GRPC_POSIX_SOCKET */
}
return scenarios;
}
class ParameterizedClientInterceptorsEnd2endTest
: public ::testing::TestWithParam<TestScenario> {
protected:
ParameterizedClientInterceptorsEnd2endTest() {
ServerBuilder builder;
builder.RegisterService(&service_);
if (GetParam().channel_type() == ChannelType::kHttpChannel) {
int port = grpc_pick_unused_port_or_die();
server_address_ = "localhost:" + std::to_string(port);
builder.AddListeningPort(server_address_, InsecureServerCredentials());
server_ = builder.BuildAndStart();
}
#ifdef GRPC_POSIX_SOCKET
else if (GetParam().channel_type() == ChannelType::kFdChannel) {
int flags;
GPR_ASSERT(socketpair(AF_UNIX, SOCK_STREAM, 0, sv_) == 0);
flags = fcntl(sv_[0], F_GETFL, 0);
GPR_ASSERT(fcntl(sv_[0], F_SETFL, flags | O_NONBLOCK) == 0);
flags = fcntl(sv_[1], F_GETFL, 0);
GPR_ASSERT(fcntl(sv_[1], F_SETFL, flags | O_NONBLOCK) == 0);
GPR_ASSERT(grpc_set_socket_no_sigpipe_if_possible(sv_[0]) ==
GRPC_ERROR_NONE);
GPR_ASSERT(grpc_set_socket_no_sigpipe_if_possible(sv_[1]) ==
GRPC_ERROR_NONE);
server_ = builder.BuildAndStart();
AddInsecureChannelFromFd(server_.get(), sv_[1]);
}
#endif /* GRPC_POSIX_SOCKET */
}
~ParameterizedClientInterceptorsEnd2endTest() override {
server_->Shutdown();
}
std::shared_ptr<grpc::Channel> CreateClientChannel(
std::vector<std::unique_ptr<
grpc::experimental::ClientInterceptorFactoryInterface>>
creators) {
if (GetParam().channel_type() == ChannelType::kHttpChannel) {
return experimental::CreateCustomChannelWithInterceptors(
server_address_, InsecureChannelCredentials(), ChannelArguments(),
std::move(creators));
}
#ifdef GRPC_POSIX_SOCKET
else if (GetParam().channel_type() == ChannelType::kFdChannel) {
return experimental::CreateCustomInsecureChannelWithInterceptorsFromFd(
"", sv_[0], ChannelArguments(), std::move(creators));
}
#endif /* GRPC_POSIX_SOCKET */
return nullptr;
}
void SendRPC(const std::shared_ptr<Channel>& channel) {
switch (GetParam().rpc_type()) {
case RPCType::kSyncUnary:
MakeCall(channel);
break;
case RPCType::kSyncClientStreaming:
MakeClientStreamingCall(channel);
break;
case RPCType::kSyncServerStreaming:
MakeServerStreamingCall(channel);
break;
case RPCType::kSyncBidiStreaming:
MakeBidiStreamingCall(channel);
break;
case RPCType::kAsyncCQUnary:
MakeAsyncCQCall(channel);
break;
case RPCType::kAsyncCQClientStreaming:
// TODO(yashykt) : Fill this out
break;
case RPCType::kAsyncCQServerStreaming:
MakeAsyncCQServerStreamingCall(channel);
break;
case RPCType::kAsyncCQBidiStreaming:
// TODO(yashykt) : Fill this out
break;
}
}
std::string server_address_;
int sv_[2];
EchoTestServiceStreamingImpl service_;
std::unique_ptr<Server> server_;
};
TEST_P(ParameterizedClientInterceptorsEnd2endTest,
ClientInterceptorLoggingTest) {
ChannelArguments args;
DummyInterceptor::Reset();
std::vector<std::unique_ptr<experimental::ClientInterceptorFactoryInterface>>
creators;
creators.push_back(absl::make_unique<LoggingInterceptorFactory>());
// Add 20 dummy interceptors
for (auto i = 0; i < 20; i++) {
creators.push_back(absl::make_unique<DummyInterceptorFactory>());
}
auto channel = CreateClientChannel(std::move(creators));
SendRPC(channel);
LoggingInterceptor::VerifyCall(GetParam().rpc_type());
// Make sure all 20 dummy interceptors were run
EXPECT_EQ(DummyInterceptor::GetNumTimesRun(), 20);
}
INSTANTIATE_TEST_SUITE_P(ParameterizedClientInterceptorsEnd2end,
ParameterizedClientInterceptorsEnd2endTest,
::testing::ValuesIn(CreateTestScenarios()));
class ClientInterceptorsEnd2endTest
: public ::testing::TestWithParam<TestScenario> {
protected:
ClientInterceptorsEnd2endTest() {
int port = grpc_pick_unused_port_or_die();
ServerBuilder builder;
server_address_ = "localhost:" + std::to_string(port);
builder.AddListeningPort(server_address_, InsecureServerCredentials());
builder.RegisterService(&service_);
server_ = builder.BuildAndStart();
}
~ClientInterceptorsEnd2endTest() override { server_->Shutdown(); }
std::string server_address_;
TestServiceImpl service_;
std::unique_ptr<Server> server_;
};
TEST_F(ClientInterceptorsEnd2endTest,
LameChannelClientInterceptorHijackingTest) {
ChannelArguments args;
std::vector<std::unique_ptr<experimental::ClientInterceptorFactoryInterface>>
creators;
creators.push_back(absl::make_unique<HijackingInterceptorFactory>());
auto channel = experimental::CreateCustomChannelWithInterceptors(
server_address_, nullptr, args, std::move(creators));
MakeCall(channel);
}
TEST_F(ClientInterceptorsEnd2endTest, ClientInterceptorHijackingTest) {
ChannelArguments args;
DummyInterceptor::Reset();
std::vector<std::unique_ptr<experimental::ClientInterceptorFactoryInterface>>
creators;
// Add 20 dummy interceptors before hijacking interceptor
creators.reserve(20);
for (auto i = 0; i < 20; i++) {
creators.push_back(absl::make_unique<DummyInterceptorFactory>());
}
creators.push_back(absl::make_unique<HijackingInterceptorFactory>());
// Add 20 dummy interceptors after hijacking interceptor
for (auto i = 0; i < 20; i++) {
creators.push_back(absl::make_unique<DummyInterceptorFactory>());
}
auto channel = experimental::CreateCustomChannelWithInterceptors(
server_address_, InsecureChannelCredentials(), args, std::move(creators));
MakeCall(channel);
// Make sure only 20 dummy interceptors were run
EXPECT_EQ(DummyInterceptor::GetNumTimesRun(), 20);
}
TEST_F(ClientInterceptorsEnd2endTest, ClientInterceptorLogThenHijackTest) {
ChannelArguments args;
std::vector<std::unique_ptr<experimental::ClientInterceptorFactoryInterface>>
creators;
creators.push_back(absl::make_unique<LoggingInterceptorFactory>());
creators.push_back(absl::make_unique<HijackingInterceptorFactory>());
auto channel = experimental::CreateCustomChannelWithInterceptors(
server_address_, InsecureChannelCredentials(), args, std::move(creators));
MakeCall(channel);
LoggingInterceptor::VerifyUnaryCall();
}
TEST_F(ClientInterceptorsEnd2endTest,
ClientInterceptorHijackingMakesAnotherCallTest) {
ChannelArguments args;
DummyInterceptor::Reset();
std::vector<std::unique_ptr<experimental::ClientInterceptorFactoryInterface>>
creators;
// Add 5 dummy interceptors before hijacking interceptor
creators.reserve(5);
for (auto i = 0; i < 5; i++) {
creators.push_back(absl::make_unique<DummyInterceptorFactory>());
}
creators.push_back(
std::unique_ptr<experimental::ClientInterceptorFactoryInterface>(
new HijackingInterceptorMakesAnotherCallFactory()));
// Add 7 dummy interceptors after hijacking interceptor
for (auto i = 0; i < 7; i++) {
creators.push_back(absl::make_unique<DummyInterceptorFactory>());
}
auto channel = server_->experimental().InProcessChannelWithInterceptors(
args, std::move(creators));
MakeCall(channel);
// Make sure all interceptors were run once, since the hijacking interceptor
// makes an RPC on the intercepted channel
EXPECT_EQ(DummyInterceptor::GetNumTimesRun(), 12);
}
class ClientInterceptorsCallbackEnd2endTest : public ::testing::Test {
protected:
ClientInterceptorsCallbackEnd2endTest() {
int port = grpc_pick_unused_port_or_die();
ServerBuilder builder;
server_address_ = "localhost:" + std::to_string(port);
builder.AddListeningPort(server_address_, InsecureServerCredentials());
builder.RegisterService(&service_);
server_ = builder.BuildAndStart();
}
~ClientInterceptorsCallbackEnd2endTest() override { server_->Shutdown(); }
std::string server_address_;
TestServiceImpl service_;
std::unique_ptr<Server> server_;
};
TEST_F(ClientInterceptorsCallbackEnd2endTest,
ClientInterceptorLoggingTestWithCallback) {
ChannelArguments args;
DummyInterceptor::Reset();
std::vector<std::unique_ptr<experimental::ClientInterceptorFactoryInterface>>
creators;
creators.push_back(absl::make_unique<LoggingInterceptorFactory>());
// Add 20 dummy interceptors
for (auto i = 0; i < 20; i++) {
creators.push_back(absl::make_unique<DummyInterceptorFactory>());
}
auto channel = server_->experimental().InProcessChannelWithInterceptors(
args, std::move(creators));
MakeCallbackCall(channel);
LoggingInterceptor::VerifyUnaryCall();
// Make sure all 20 dummy interceptors were run
EXPECT_EQ(DummyInterceptor::GetNumTimesRun(), 20);
}
TEST_F(ClientInterceptorsCallbackEnd2endTest,
ClientInterceptorFactoryAllowsNullptrReturn) {
ChannelArguments args;
DummyInterceptor::Reset();
std::vector<std::unique_ptr<experimental::ClientInterceptorFactoryInterface>>
creators;
creators.push_back(absl::make_unique<LoggingInterceptorFactory>());
// Add 20 dummy interceptors and 20 null interceptors
for (auto i = 0; i < 20; i++) {
creators.push_back(absl::make_unique<DummyInterceptorFactory>());
creators.push_back(absl::make_unique<NullInterceptorFactory>());
}
auto channel = server_->experimental().InProcessChannelWithInterceptors(
args, std::move(creators));
MakeCallbackCall(channel);
LoggingInterceptor::VerifyUnaryCall();
// Make sure all 20 dummy interceptors were run
EXPECT_EQ(DummyInterceptor::GetNumTimesRun(), 20);
}
class ClientInterceptorsStreamingEnd2endTest : public ::testing::Test {
protected:
ClientInterceptorsStreamingEnd2endTest() {
int port = grpc_pick_unused_port_or_die();
ServerBuilder builder;
server_address_ = "localhost:" + std::to_string(port);
builder.AddListeningPort(server_address_, InsecureServerCredentials());
builder.RegisterService(&service_);
server_ = builder.BuildAndStart();
}
~ClientInterceptorsStreamingEnd2endTest() override { server_->Shutdown(); }
std::string server_address_;
EchoTestServiceStreamingImpl service_;
std::unique_ptr<Server> server_;
};
TEST_F(ClientInterceptorsStreamingEnd2endTest, ClientStreamingTest) {
ChannelArguments args;
DummyInterceptor::Reset();
std::vector<std::unique_ptr<experimental::ClientInterceptorFactoryInterface>>
creators;
creators.push_back(absl::make_unique<LoggingInterceptorFactory>());
// Add 20 dummy interceptors
for (auto i = 0; i < 20; i++) {
creators.push_back(absl::make_unique<DummyInterceptorFactory>());
}
auto channel = experimental::CreateCustomChannelWithInterceptors(
server_address_, InsecureChannelCredentials(), args, std::move(creators));
MakeClientStreamingCall(channel);
LoggingInterceptor::VerifyClientStreamingCall();
// Make sure all 20 dummy interceptors were run
EXPECT_EQ(DummyInterceptor::GetNumTimesRun(), 20);
}
TEST_F(ClientInterceptorsStreamingEnd2endTest, ServerStreamingTest) {
ChannelArguments args;
DummyInterceptor::Reset();
std::vector<std::unique_ptr<experimental::ClientInterceptorFactoryInterface>>
creators;
creators.push_back(absl::make_unique<LoggingInterceptorFactory>());
// Add 20 dummy interceptors
for (auto i = 0; i < 20; i++) {
creators.push_back(absl::make_unique<DummyInterceptorFactory>());
}
auto channel = experimental::CreateCustomChannelWithInterceptors(
server_address_, InsecureChannelCredentials(), args, std::move(creators));
MakeServerStreamingCall(channel);
LoggingInterceptor::VerifyServerStreamingCall();
// Make sure all 20 dummy interceptors were run
EXPECT_EQ(DummyInterceptor::GetNumTimesRun(), 20);
}
TEST_F(ClientInterceptorsStreamingEnd2endTest, ClientStreamingHijackingTest) {
ChannelArguments args;
std::vector<std::unique_ptr<experimental::ClientInterceptorFactoryInterface>>
creators;
creators.push_back(
absl::make_unique<ClientStreamingRpcHijackingInterceptorFactory>());
auto channel = experimental::CreateCustomChannelWithInterceptors(
server_address_, InsecureChannelCredentials(), args, std::move(creators));
auto stub = grpc::testing::EchoTestService::NewStub(channel);
ClientContext ctx;
EchoRequest req;
EchoResponse resp;
req.mutable_param()->set_echo_metadata(true);
req.set_message("Hello");
string expected_resp = "";
auto writer = stub->RequestStream(&ctx, &resp);
for (int i = 0; i < 10; i++) {
EXPECT_TRUE(writer->Write(req));
expected_resp += "Hello";
}
// The interceptor will reject the 11th message
writer->Write(req);
Status s = writer->Finish();
EXPECT_EQ(s.ok(), false);
EXPECT_TRUE(ClientStreamingRpcHijackingInterceptor::GotFailedSend());
}
TEST_F(ClientInterceptorsStreamingEnd2endTest, ServerStreamingHijackingTest) {
ChannelArguments args;
DummyInterceptor::Reset();
std::vector<std::unique_ptr<experimental::ClientInterceptorFactoryInterface>>
creators;
creators.push_back(
absl::make_unique<ServerStreamingRpcHijackingInterceptorFactory>());
auto channel = experimental::CreateCustomChannelWithInterceptors(
server_address_, InsecureChannelCredentials(), args, std::move(creators));
MakeServerStreamingCall(channel);
EXPECT_TRUE(ServerStreamingRpcHijackingInterceptor::GotFailedMessage());
}
TEST_F(ClientInterceptorsStreamingEnd2endTest,
AsyncCQServerStreamingHijackingTest) {
ChannelArguments args;
DummyInterceptor::Reset();
std::vector<std::unique_ptr<experimental::ClientInterceptorFactoryInterface>>
creators;
creators.push_back(
absl::make_unique<ServerStreamingRpcHijackingInterceptorFactory>());
auto channel = experimental::CreateCustomChannelWithInterceptors(
server_address_, InsecureChannelCredentials(), args, std::move(creators));
MakeAsyncCQServerStreamingCall(channel);
EXPECT_TRUE(ServerStreamingRpcHijackingInterceptor::GotFailedMessage());
}
TEST_F(ClientInterceptorsStreamingEnd2endTest, BidiStreamingHijackingTest) {
ChannelArguments args;
DummyInterceptor::Reset();
std::vector<std::unique_ptr<experimental::ClientInterceptorFactoryInterface>>
creators;
creators.push_back(
absl::make_unique<BidiStreamingRpcHijackingInterceptorFactory>());
auto channel = experimental::CreateCustomChannelWithInterceptors(
server_address_, InsecureChannelCredentials(), args, std::move(creators));
MakeBidiStreamingCall(channel);
}
TEST_F(ClientInterceptorsStreamingEnd2endTest, BidiStreamingTest) {
ChannelArguments args;
DummyInterceptor::Reset();
std::vector<std::unique_ptr<experimental::ClientInterceptorFactoryInterface>>
creators;
creators.push_back(absl::make_unique<LoggingInterceptorFactory>());
// Add 20 dummy interceptors
for (auto i = 0; i < 20; i++) {
creators.push_back(absl::make_unique<DummyInterceptorFactory>());
}
auto channel = experimental::CreateCustomChannelWithInterceptors(
server_address_, InsecureChannelCredentials(), args, std::move(creators));
MakeBidiStreamingCall(channel);
LoggingInterceptor::VerifyBidiStreamingCall();
// Make sure all 20 dummy interceptors were run
EXPECT_EQ(DummyInterceptor::GetNumTimesRun(), 20);
}
class ClientGlobalInterceptorEnd2endTest : public ::testing::Test {
protected:
ClientGlobalInterceptorEnd2endTest() {
int port = grpc_pick_unused_port_or_die();
ServerBuilder builder;
server_address_ = "localhost:" + std::to_string(port);
builder.AddListeningPort(server_address_, InsecureServerCredentials());
builder.RegisterService(&service_);
server_ = builder.BuildAndStart();
}
~ClientGlobalInterceptorEnd2endTest() override { server_->Shutdown(); }
std::string server_address_;
TestServiceImpl service_;
std::unique_ptr<Server> server_;
};
TEST_F(ClientGlobalInterceptorEnd2endTest, DummyGlobalInterceptor) {
// We should ideally be registering a global interceptor only once per
// process, but for the purposes of testing, it should be fine to modify the
// registered global interceptor when there are no ongoing gRPC operations
DummyInterceptorFactory global_factory;
experimental::RegisterGlobalClientInterceptorFactory(&global_factory);
ChannelArguments args;
DummyInterceptor::Reset();
std::vector<std::unique_ptr<experimental::ClientInterceptorFactoryInterface>>
creators;
// Add 20 dummy interceptors
creators.reserve(20);
for (auto i = 0; i < 20; i++) {
creators.push_back(absl::make_unique<DummyInterceptorFactory>());
}
auto channel = experimental::CreateCustomChannelWithInterceptors(
server_address_, InsecureChannelCredentials(), args, std::move(creators));
MakeCall(channel);
// Make sure all 20 dummy interceptors were run with the global interceptor
EXPECT_EQ(DummyInterceptor::GetNumTimesRun(), 21);
experimental::TestOnlyResetGlobalClientInterceptorFactory();
}
TEST_F(ClientGlobalInterceptorEnd2endTest, LoggingGlobalInterceptor) {
// We should ideally be registering a global interceptor only once per
// process, but for the purposes of testing, it should be fine to modify the
// registered global interceptor when there are no ongoing gRPC operations
LoggingInterceptorFactory global_factory;
experimental::RegisterGlobalClientInterceptorFactory(&global_factory);
ChannelArguments args;
DummyInterceptor::Reset();
std::vector<std::unique_ptr<experimental::ClientInterceptorFactoryInterface>>
creators;
// Add 20 dummy interceptors
creators.reserve(20);
for (auto i = 0; i < 20; i++) {
creators.push_back(absl::make_unique<DummyInterceptorFactory>());
}
auto channel = experimental::CreateCustomChannelWithInterceptors(
server_address_, InsecureChannelCredentials(), args, std::move(creators));
MakeCall(channel);
LoggingInterceptor::VerifyUnaryCall();
// Make sure all 20 dummy interceptors were run
EXPECT_EQ(DummyInterceptor::GetNumTimesRun(), 20);
experimental::TestOnlyResetGlobalClientInterceptorFactory();
}
TEST_F(ClientGlobalInterceptorEnd2endTest, HijackingGlobalInterceptor) {
// We should ideally be registering a global interceptor only once per
// process, but for the purposes of testing, it should be fine to modify the
// registered global interceptor when there are no ongoing gRPC operations
HijackingInterceptorFactory global_factory;
experimental::RegisterGlobalClientInterceptorFactory(&global_factory);
ChannelArguments args;
DummyInterceptor::Reset();
std::vector<std::unique_ptr<experimental::ClientInterceptorFactoryInterface>>
creators;
// Add 20 dummy interceptors
creators.reserve(20);
for (auto i = 0; i < 20; i++) {
creators.push_back(absl::make_unique<DummyInterceptorFactory>());
}
auto channel = experimental::CreateCustomChannelWithInterceptors(
server_address_, InsecureChannelCredentials(), args, std::move(creators));
MakeCall(channel);
// Make sure all 20 dummy interceptors were run
EXPECT_EQ(DummyInterceptor::GetNumTimesRun(), 20);
experimental::TestOnlyResetGlobalClientInterceptorFactory();
}
} // namespace
} // namespace testing
} // namespace grpc
int main(int argc, char** argv) {
grpc::testing::TestEnvironment env(argc, argv);
::testing::InitGoogleTest(&argc, argv);
return RUN_ALL_TESTS();
}