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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.
*
*/
#if defined(__GNUC__)
#pragma GCC system_header
#endif
#ifndef GRPCPP_IMPL_CODEGEN_CALL_OP_SET_H
#define GRPCPP_IMPL_CODEGEN_CALL_OP_SET_H
// IWYU pragma: private
#include <cstring>
#include <map>
#include <memory>
#include <grpc/impl/codegen/compression_types.h>
#include <grpc/impl/codegen/grpc_types.h>
#include <grpcpp/impl/codegen/byte_buffer.h>
#include <grpcpp/impl/codegen/call.h>
#include <grpcpp/impl/codegen/call_hook.h>
#include <grpcpp/impl/codegen/call_op_set_interface.h>
#include <grpcpp/impl/codegen/client_context.h>
#include <grpcpp/impl/codegen/completion_queue.h>
#include <grpcpp/impl/codegen/completion_queue_tag.h>
#include <grpcpp/impl/codegen/config.h>
#include <grpcpp/impl/codegen/core_codegen_interface.h>
#include <grpcpp/impl/codegen/intercepted_channel.h>
#include <grpcpp/impl/codegen/interceptor_common.h>
#include <grpcpp/impl/codegen/serialization_traits.h>
#include <grpcpp/impl/codegen/slice.h>
#include <grpcpp/impl/codegen/string_ref.h>
namespace grpc {
extern CoreCodegenInterface* g_core_codegen_interface;
namespace internal {
class Call;
class CallHook;
// TODO(yangg) if the map is changed before we send, the pointers will be a
// mess. Make sure it does not happen.
inline grpc_metadata* FillMetadataArray(
const std::multimap<TString, TString>& metadata,
size_t* metadata_count, const TString& optional_error_details) {
*metadata_count = metadata.size() + (optional_error_details.empty() ? 0 : 1);
if (*metadata_count == 0) {
return nullptr;
}
grpc_metadata* metadata_array =
static_cast<grpc_metadata*>(g_core_codegen_interface->gpr_malloc(
(*metadata_count) * sizeof(grpc_metadata)));
size_t i = 0;
for (auto iter = metadata.cbegin(); iter != metadata.cend(); ++iter, ++i) {
metadata_array[i].key = SliceReferencingString(iter->first);
metadata_array[i].value = SliceReferencingString(iter->second);
}
if (!optional_error_details.empty()) {
metadata_array[i].key =
g_core_codegen_interface->grpc_slice_from_static_buffer(
kBinaryErrorDetailsKey, sizeof(kBinaryErrorDetailsKey) - 1);
metadata_array[i].value = SliceReferencingString(optional_error_details);
}
return metadata_array;
}
} // namespace internal
/// Per-message write options.
class WriteOptions {
public:
WriteOptions() : flags_(0), last_message_(false) {}
/// Clear all flags.
inline void Clear() { flags_ = 0; }
/// Returns raw flags bitset.
inline uint32_t flags() const { return flags_; }
/// Sets flag for the disabling of compression for the next message write.
///
/// \sa GRPC_WRITE_NO_COMPRESS
inline WriteOptions& set_no_compression() {
SetBit(GRPC_WRITE_NO_COMPRESS);
return *this;
}
/// Clears flag for the disabling of compression for the next message write.
///
/// \sa GRPC_WRITE_NO_COMPRESS
inline WriteOptions& clear_no_compression() {
ClearBit(GRPC_WRITE_NO_COMPRESS);
return *this;
}
/// Get value for the flag indicating whether compression for the next
/// message write is forcefully disabled.
///
/// \sa GRPC_WRITE_NO_COMPRESS
inline bool get_no_compression() const {
return GetBit(GRPC_WRITE_NO_COMPRESS);
}
/// Sets flag indicating that the write may be buffered and need not go out on
/// the wire immediately.
///
/// \sa GRPC_WRITE_BUFFER_HINT
inline WriteOptions& set_buffer_hint() {
SetBit(GRPC_WRITE_BUFFER_HINT);
return *this;
}
/// Clears flag indicating that the write may be buffered and need not go out
/// on the wire immediately.
///
/// \sa GRPC_WRITE_BUFFER_HINT
inline WriteOptions& clear_buffer_hint() {
ClearBit(GRPC_WRITE_BUFFER_HINT);
return *this;
}
/// Get value for the flag indicating that the write may be buffered and need
/// not go out on the wire immediately.
///
/// \sa GRPC_WRITE_BUFFER_HINT
inline bool get_buffer_hint() const { return GetBit(GRPC_WRITE_BUFFER_HINT); }
/// corked bit: aliases set_buffer_hint currently, with the intent that
/// set_buffer_hint will be removed in the future
inline WriteOptions& set_corked() {
SetBit(GRPC_WRITE_BUFFER_HINT);
return *this;
}
inline WriteOptions& clear_corked() {
ClearBit(GRPC_WRITE_BUFFER_HINT);
return *this;
}
inline bool is_corked() const { return GetBit(GRPC_WRITE_BUFFER_HINT); }
/// last-message bit: indicates this is the last message in a stream
/// client-side: makes Write the equivalent of performing Write, WritesDone
/// in a single step
/// server-side: hold the Write until the service handler returns (sync api)
/// or until Finish is called (async api)
inline WriteOptions& set_last_message() {
last_message_ = true;
return *this;
}
/// Clears flag indicating that this is the last message in a stream,
/// disabling coalescing.
inline WriteOptions& clear_last_message() {
last_message_ = false;
return *this;
}
/// Get value for the flag indicating that this is the last message, and
/// should be coalesced with trailing metadata.
///
/// \sa GRPC_WRITE_LAST_MESSAGE
bool is_last_message() const { return last_message_; }
/// Guarantee that all bytes have been written to the socket before completing
/// this write (usually writes are completed when they pass flow control).
inline WriteOptions& set_write_through() {
SetBit(GRPC_WRITE_THROUGH);
return *this;
}
inline WriteOptions& clear_write_through() {
ClearBit(GRPC_WRITE_THROUGH);
return *this;
}
inline bool is_write_through() const { return GetBit(GRPC_WRITE_THROUGH); }
private:
void SetBit(const uint32_t mask) { flags_ |= mask; }
void ClearBit(const uint32_t mask) { flags_ &= ~mask; }
bool GetBit(const uint32_t mask) const { return (flags_ & mask) != 0; }
uint32_t flags_;
bool last_message_;
};
namespace internal {
/// Default argument for CallOpSet. The Unused parameter is unused by
/// the class, but can be used for generating multiple names for the
/// same thing.
template <int Unused>
class CallNoOp {
protected:
void AddOp(grpc_op* /*ops*/, size_t* /*nops*/) {}
void FinishOp(bool* /*status*/) {}
void SetInterceptionHookPoint(
InterceptorBatchMethodsImpl* /*interceptor_methods*/) {}
void SetFinishInterceptionHookPoint(
InterceptorBatchMethodsImpl* /*interceptor_methods*/) {}
void SetHijackingState(InterceptorBatchMethodsImpl* /*interceptor_methods*/) {
}
};
class CallOpSendInitialMetadata {
public:
CallOpSendInitialMetadata() : send_(false) {
maybe_compression_level_.is_set = false;
}
void SendInitialMetadata(std::multimap<TString, TString>* metadata,
uint32_t flags) {
maybe_compression_level_.is_set = false;
send_ = true;
flags_ = flags;
metadata_map_ = metadata;
}
void set_compression_level(grpc_compression_level level) {
maybe_compression_level_.is_set = true;
maybe_compression_level_.level = level;
}
protected:
void AddOp(grpc_op* ops, size_t* nops) {
if (!send_ || hijacked_) return;
grpc_op* op = &ops[(*nops)++];
op->op = GRPC_OP_SEND_INITIAL_METADATA;
op->flags = flags_;
op->reserved = nullptr;
initial_metadata_ =
FillMetadataArray(*metadata_map_, &initial_metadata_count_, "");
op->data.send_initial_metadata.count = initial_metadata_count_;
op->data.send_initial_metadata.metadata = initial_metadata_;
op->data.send_initial_metadata.maybe_compression_level.is_set =
maybe_compression_level_.is_set;
if (maybe_compression_level_.is_set) {
op->data.send_initial_metadata.maybe_compression_level.level =
maybe_compression_level_.level;
}
}
void FinishOp(bool* /*status*/) {
if (!send_ || hijacked_) return;
g_core_codegen_interface->gpr_free(initial_metadata_);
send_ = false;
}
void SetInterceptionHookPoint(
InterceptorBatchMethodsImpl* interceptor_methods) {
if (!send_) return;
interceptor_methods->AddInterceptionHookPoint(
experimental::InterceptionHookPoints::PRE_SEND_INITIAL_METADATA);
interceptor_methods->SetSendInitialMetadata(metadata_map_);
}
void SetFinishInterceptionHookPoint(
InterceptorBatchMethodsImpl* /*interceptor_methods*/) {}
void SetHijackingState(InterceptorBatchMethodsImpl* /*interceptor_methods*/) {
hijacked_ = true;
}
bool hijacked_ = false;
bool send_;
uint32_t flags_;
size_t initial_metadata_count_;
std::multimap<TString, TString>* metadata_map_;
grpc_metadata* initial_metadata_;
struct {
bool is_set;
grpc_compression_level level;
} maybe_compression_level_;
};
class CallOpSendMessage {
public:
CallOpSendMessage() : send_buf_() {}
/// Send \a message using \a options for the write. The \a options are cleared
/// after use.
template <class M>
Status SendMessage(const M& message,
WriteOptions options) GRPC_MUST_USE_RESULT;
template <class M>
Status SendMessage(const M& message) GRPC_MUST_USE_RESULT;
/// Send \a message using \a options for the write. The \a options are cleared
/// after use. This form of SendMessage allows gRPC to reference \a message
/// beyond the lifetime of SendMessage.
template <class M>
Status SendMessagePtr(const M* message,
WriteOptions options) GRPC_MUST_USE_RESULT;
/// This form of SendMessage allows gRPC to reference \a message beyond the
/// lifetime of SendMessage.
template <class M>
Status SendMessagePtr(const M* message) GRPC_MUST_USE_RESULT;
protected:
void AddOp(grpc_op* ops, size_t* nops) {
if (msg_ == nullptr && !send_buf_.Valid()) return;
if (hijacked_) {
serializer_ = nullptr;
return;
}
if (msg_ != nullptr) {
GPR_CODEGEN_ASSERT(serializer_(msg_).ok());
}
serializer_ = nullptr;
grpc_op* op = &ops[(*nops)++];
op->op = GRPC_OP_SEND_MESSAGE;
op->flags = write_options_.flags();
op->reserved = nullptr;
op->data.send_message.send_message = send_buf_.c_buffer();
// Flags are per-message: clear them after use.
write_options_.Clear();
}
void FinishOp(bool* status) {
if (msg_ == nullptr && !send_buf_.Valid()) return;
send_buf_.Clear();
if (hijacked_ && failed_send_) {
// Hijacking interceptor failed this Op
*status = false;
} else if (!*status) {
// This Op was passed down to core and the Op failed
failed_send_ = true;
}
}
void SetInterceptionHookPoint(
InterceptorBatchMethodsImpl* interceptor_methods) {
if (msg_ == nullptr && !send_buf_.Valid()) return;
interceptor_methods->AddInterceptionHookPoint(
experimental::InterceptionHookPoints::PRE_SEND_MESSAGE);
interceptor_methods->SetSendMessage(&send_buf_, &msg_, &failed_send_,
serializer_);
}
void SetFinishInterceptionHookPoint(
InterceptorBatchMethodsImpl* interceptor_methods) {
if (msg_ != nullptr || send_buf_.Valid()) {
interceptor_methods->AddInterceptionHookPoint(
experimental::InterceptionHookPoints::POST_SEND_MESSAGE);
}
send_buf_.Clear();
msg_ = nullptr;
// The contents of the SendMessage value that was previously set
// has had its references stolen by core's operations
interceptor_methods->SetSendMessage(nullptr, nullptr, &failed_send_,
nullptr);
}
void SetHijackingState(InterceptorBatchMethodsImpl* /*interceptor_methods*/) {
hijacked_ = true;
}
private:
const void* msg_ = nullptr; // The original non-serialized message
bool hijacked_ = false;
bool failed_send_ = false;
ByteBuffer send_buf_;
WriteOptions write_options_;
std::function<Status(const void*)> serializer_;
};
template <class M>
Status CallOpSendMessage::SendMessage(const M& message, WriteOptions options) {
write_options_ = options;
// Serialize immediately since we do not have access to the message pointer
bool own_buf;
// TODO(vjpai): Remove the void below when possible
// The void in the template parameter below should not be needed
// (since it should be implicit) but is needed due to an observed
// difference in behavior between clang and gcc for certain internal users
Status result = SerializationTraits<M, void>::Serialize(
message, send_buf_.bbuf_ptr(), &own_buf);
if (!own_buf) {
send_buf_.Duplicate();
}
return result;
}
template <class M>
Status CallOpSendMessage::SendMessage(const M& message) {
return SendMessage(message, WriteOptions());
}
template <class M>
Status CallOpSendMessage::SendMessagePtr(const M* message,
WriteOptions options) {
msg_ = message;
write_options_ = options;
// Store the serializer for later since we have access to the message
serializer_ = [this](const void* message) {
bool own_buf;
// TODO(vjpai): Remove the void below when possible
// The void in the template parameter below should not be needed
// (since it should be implicit) but is needed due to an observed
// difference in behavior between clang and gcc for certain internal users
Status result = SerializationTraits<M, void>::Serialize(
*static_cast<const M*>(message), send_buf_.bbuf_ptr(), &own_buf);
if (!own_buf) {
send_buf_.Duplicate();
}
return result;
};
return Status();
}
template <class M>
Status CallOpSendMessage::SendMessagePtr(const M* message) {
return SendMessagePtr(message, WriteOptions());
}
template <class R>
class CallOpRecvMessage {
public:
void RecvMessage(R* message) { message_ = message; }
// Do not change status if no message is received.
void AllowNoMessage() { allow_not_getting_message_ = true; }
bool got_message = false;
protected:
void AddOp(grpc_op* ops, size_t* nops) {
if (message_ == nullptr || hijacked_) return;
grpc_op* op = &ops[(*nops)++];
op->op = GRPC_OP_RECV_MESSAGE;
op->flags = 0;
op->reserved = nullptr;
op->data.recv_message.recv_message = recv_buf_.c_buffer_ptr();
}
void FinishOp(bool* status) {
if (message_ == nullptr) return;
if (recv_buf_.Valid()) {
if (*status) {
got_message = *status =
SerializationTraits<R>::Deserialize(recv_buf_.bbuf_ptr(), message_)
.ok();
recv_buf_.Release();
} else {
got_message = false;
recv_buf_.Clear();
}
} else if (hijacked_) {
if (hijacked_recv_message_failed_) {
FinishOpRecvMessageFailureHandler(status);
} else {
// The op was hijacked and it was successful. There is no further action
// to be performed since the message is already in its non-serialized
// form.
}
} else {
FinishOpRecvMessageFailureHandler(status);
}
}
void SetInterceptionHookPoint(
InterceptorBatchMethodsImpl* interceptor_methods) {
if (message_ == nullptr) return;
interceptor_methods->SetRecvMessage(message_,
&hijacked_recv_message_failed_);
}
void SetFinishInterceptionHookPoint(
InterceptorBatchMethodsImpl* interceptor_methods) {
if (message_ == nullptr) return;
interceptor_methods->AddInterceptionHookPoint(
experimental::InterceptionHookPoints::POST_RECV_MESSAGE);
if (!got_message) interceptor_methods->SetRecvMessage(nullptr, nullptr);
}
void SetHijackingState(InterceptorBatchMethodsImpl* interceptor_methods) {
hijacked_ = true;
if (message_ == nullptr) return;
interceptor_methods->AddInterceptionHookPoint(
experimental::InterceptionHookPoints::PRE_RECV_MESSAGE);
got_message = true;
}
private:
// Sets got_message and \a status for a failed recv message op
void FinishOpRecvMessageFailureHandler(bool* status) {
got_message = false;
if (!allow_not_getting_message_) {
*status = false;
}
}
R* message_ = nullptr;
ByteBuffer recv_buf_;
bool allow_not_getting_message_ = false;
bool hijacked_ = false;
bool hijacked_recv_message_failed_ = false;
};
class DeserializeFunc {
public:
virtual Status Deserialize(ByteBuffer* buf) = 0;
virtual ~DeserializeFunc() {}
};
template <class R>
class DeserializeFuncType final : public DeserializeFunc {
public:
explicit DeserializeFuncType(R* message) : message_(message) {}
Status Deserialize(ByteBuffer* buf) override {
return SerializationTraits<R>::Deserialize(buf->bbuf_ptr(), message_);
}
~DeserializeFuncType() override {}
private:
R* message_; // Not a managed pointer because management is external to this
};
class CallOpGenericRecvMessage {
public:
template <class R>
void RecvMessage(R* message) {
// Use an explicit base class pointer to avoid resolution error in the
// following unique_ptr::reset for some old implementations.
DeserializeFunc* func = new DeserializeFuncType<R>(message);
deserialize_.reset(func);
message_ = message;
}
// Do not change status if no message is received.
void AllowNoMessage() { allow_not_getting_message_ = true; }
bool got_message = false;
protected:
void AddOp(grpc_op* ops, size_t* nops) {
if (!deserialize_ || hijacked_) return;
grpc_op* op = &ops[(*nops)++];
op->op = GRPC_OP_RECV_MESSAGE;
op->flags = 0;
op->reserved = nullptr;
op->data.recv_message.recv_message = recv_buf_.c_buffer_ptr();
}
void FinishOp(bool* status) {
if (!deserialize_) return;
if (recv_buf_.Valid()) {
if (*status) {
got_message = true;
*status = deserialize_->Deserialize(&recv_buf_).ok();
recv_buf_.Release();
} else {
got_message = false;
recv_buf_.Clear();
}
} else if (hijacked_) {
if (hijacked_recv_message_failed_) {
FinishOpRecvMessageFailureHandler(status);
} else {
// The op was hijacked and it was successful. There is no further action
// to be performed since the message is already in its non-serialized
// form.
}
} else {
got_message = false;
if (!allow_not_getting_message_) {
*status = false;
}
}
}
void SetInterceptionHookPoint(
InterceptorBatchMethodsImpl* interceptor_methods) {
if (!deserialize_) return;
interceptor_methods->SetRecvMessage(message_,
&hijacked_recv_message_failed_);
}
void SetFinishInterceptionHookPoint(
InterceptorBatchMethodsImpl* interceptor_methods) {
if (!deserialize_) return;
interceptor_methods->AddInterceptionHookPoint(
experimental::InterceptionHookPoints::POST_RECV_MESSAGE);
if (!got_message) interceptor_methods->SetRecvMessage(nullptr, nullptr);
deserialize_.reset();
}
void SetHijackingState(InterceptorBatchMethodsImpl* interceptor_methods) {
hijacked_ = true;
if (!deserialize_) return;
interceptor_methods->AddInterceptionHookPoint(
experimental::InterceptionHookPoints::PRE_RECV_MESSAGE);
got_message = true;
}
private:
// Sets got_message and \a status for a failed recv message op
void FinishOpRecvMessageFailureHandler(bool* status) {
got_message = false;
if (!allow_not_getting_message_) {
*status = false;
}
}
void* message_ = nullptr;
std::unique_ptr<DeserializeFunc> deserialize_;
ByteBuffer recv_buf_;
bool allow_not_getting_message_ = false;
bool hijacked_ = false;
bool hijacked_recv_message_failed_ = false;
};
class CallOpClientSendClose {
public:
CallOpClientSendClose() : send_(false) {}
void ClientSendClose() { send_ = true; }
protected:
void AddOp(grpc_op* ops, size_t* nops) {
if (!send_ || hijacked_) return;
grpc_op* op = &ops[(*nops)++];
op->op = GRPC_OP_SEND_CLOSE_FROM_CLIENT;
op->flags = 0;
op->reserved = nullptr;
}
void FinishOp(bool* /*status*/) { send_ = false; }
void SetInterceptionHookPoint(
InterceptorBatchMethodsImpl* interceptor_methods) {
if (!send_) return;
interceptor_methods->AddInterceptionHookPoint(
experimental::InterceptionHookPoints::PRE_SEND_CLOSE);
}
void SetFinishInterceptionHookPoint(
InterceptorBatchMethodsImpl* /*interceptor_methods*/) {}
void SetHijackingState(InterceptorBatchMethodsImpl* /*interceptor_methods*/) {
hijacked_ = true;
}
private:
bool hijacked_ = false;
bool send_;
};
class CallOpServerSendStatus {
public:
CallOpServerSendStatus() : send_status_available_(false) {}
void ServerSendStatus(
std::multimap<TString, TString>* trailing_metadata,
const Status& status) {
send_error_details_ = status.error_details();
metadata_map_ = trailing_metadata;
send_status_available_ = true;
send_status_code_ = static_cast<grpc_status_code>(status.error_code());
send_error_message_ = status.error_message();
}
protected:
void AddOp(grpc_op* ops, size_t* nops) {
if (!send_status_available_ || hijacked_) return;
trailing_metadata_ = FillMetadataArray(
*metadata_map_, &trailing_metadata_count_, send_error_details_);
grpc_op* op = &ops[(*nops)++];
op->op = GRPC_OP_SEND_STATUS_FROM_SERVER;
op->data.send_status_from_server.trailing_metadata_count =
trailing_metadata_count_;
op->data.send_status_from_server.trailing_metadata = trailing_metadata_;
op->data.send_status_from_server.status = send_status_code_;
error_message_slice_ = SliceReferencingString(send_error_message_);
op->data.send_status_from_server.status_details =
send_error_message_.empty() ? nullptr : &error_message_slice_;
op->flags = 0;
op->reserved = nullptr;
}
void FinishOp(bool* /*status*/) {
if (!send_status_available_ || hijacked_) return;
g_core_codegen_interface->gpr_free(trailing_metadata_);
send_status_available_ = false;
}
void SetInterceptionHookPoint(
InterceptorBatchMethodsImpl* interceptor_methods) {
if (!send_status_available_) return;
interceptor_methods->AddInterceptionHookPoint(
experimental::InterceptionHookPoints::PRE_SEND_STATUS);
interceptor_methods->SetSendTrailingMetadata(metadata_map_);
interceptor_methods->SetSendStatus(&send_status_code_, &send_error_details_,
&send_error_message_);
}
void SetFinishInterceptionHookPoint(
InterceptorBatchMethodsImpl* /*interceptor_methods*/) {}
void SetHijackingState(InterceptorBatchMethodsImpl* /*interceptor_methods*/) {
hijacked_ = true;
}
private:
bool hijacked_ = false;
bool send_status_available_;
grpc_status_code send_status_code_;
TString send_error_details_;
TString send_error_message_;
size_t trailing_metadata_count_;
std::multimap<TString, TString>* metadata_map_;
grpc_metadata* trailing_metadata_;
grpc_slice error_message_slice_;
};
class CallOpRecvInitialMetadata {
public:
CallOpRecvInitialMetadata() : metadata_map_(nullptr) {}
void RecvInitialMetadata(grpc::ClientContext* context) {
context->initial_metadata_received_ = true;
metadata_map_ = &context->recv_initial_metadata_;
}
protected:
void AddOp(grpc_op* ops, size_t* nops) {
if (metadata_map_ == nullptr || hijacked_) return;
grpc_op* op = &ops[(*nops)++];
op->op = GRPC_OP_RECV_INITIAL_METADATA;
op->data.recv_initial_metadata.recv_initial_metadata = metadata_map_->arr();
op->flags = 0;
op->reserved = nullptr;
}
void FinishOp(bool* /*status*/) {
if (metadata_map_ == nullptr || hijacked_) return;
}
void SetInterceptionHookPoint(
InterceptorBatchMethodsImpl* interceptor_methods) {
interceptor_methods->SetRecvInitialMetadata(metadata_map_);
}
void SetFinishInterceptionHookPoint(
InterceptorBatchMethodsImpl* interceptor_methods) {
if (metadata_map_ == nullptr) return;
interceptor_methods->AddInterceptionHookPoint(
experimental::InterceptionHookPoints::POST_RECV_INITIAL_METADATA);
metadata_map_ = nullptr;
}
void SetHijackingState(InterceptorBatchMethodsImpl* interceptor_methods) {
hijacked_ = true;
if (metadata_map_ == nullptr) return;
interceptor_methods->AddInterceptionHookPoint(
experimental::InterceptionHookPoints::PRE_RECV_INITIAL_METADATA);
}
private:
bool hijacked_ = false;
MetadataMap* metadata_map_;
};
class CallOpClientRecvStatus {
public:
CallOpClientRecvStatus()
: recv_status_(nullptr), debug_error_string_(nullptr) {}
void ClientRecvStatus(grpc::ClientContext* context, Status* status) {
client_context_ = context;
metadata_map_ = &client_context_->trailing_metadata_;
recv_status_ = status;
error_message_ = g_core_codegen_interface->grpc_empty_slice();
}
protected:
void AddOp(grpc_op* ops, size_t* nops) {
if (recv_status_ == nullptr || hijacked_) return;
grpc_op* op = &ops[(*nops)++];
op->op = GRPC_OP_RECV_STATUS_ON_CLIENT;
op->data.recv_status_on_client.trailing_metadata = metadata_map_->arr();
op->data.recv_status_on_client.status = &status_code_;
op->data.recv_status_on_client.status_details = &error_message_;
op->data.recv_status_on_client.error_string = &debug_error_string_;
op->flags = 0;
op->reserved = nullptr;
}
void FinishOp(bool* /*status*/) {
if (recv_status_ == nullptr || hijacked_) return;
if (static_cast<StatusCode>(status_code_) == StatusCode::OK) {
*recv_status_ = Status();
GPR_CODEGEN_DEBUG_ASSERT(debug_error_string_ == nullptr);
} else {
*recv_status_ =
Status(static_cast<StatusCode>(status_code_),
GRPC_SLICE_IS_EMPTY(error_message_)
? TString()
: TString(reinterpret_cast<const char*>GRPC_SLICE_START_PTR(error_message_),
reinterpret_cast<const char*>GRPC_SLICE_END_PTR(error_message_)),
metadata_map_->GetBinaryErrorDetails());
if (debug_error_string_ != nullptr) {
client_context_->set_debug_error_string(debug_error_string_);
g_core_codegen_interface->gpr_free(
const_cast<char*>(debug_error_string_));
}
}
// TODO(soheil): Find callers that set debug string even for status OK,
// and fix them.
g_core_codegen_interface->grpc_slice_unref(error_message_);
}
void SetInterceptionHookPoint(
InterceptorBatchMethodsImpl* interceptor_methods) {
interceptor_methods->SetRecvStatus(recv_status_);
interceptor_methods->SetRecvTrailingMetadata(metadata_map_);
}
void SetFinishInterceptionHookPoint(
InterceptorBatchMethodsImpl* interceptor_methods) {
if (recv_status_ == nullptr) return;
interceptor_methods->AddInterceptionHookPoint(
experimental::InterceptionHookPoints::POST_RECV_STATUS);
recv_status_ = nullptr;
}
void SetHijackingState(InterceptorBatchMethodsImpl* interceptor_methods) {
hijacked_ = true;
if (recv_status_ == nullptr) return;
interceptor_methods->AddInterceptionHookPoint(
experimental::InterceptionHookPoints::PRE_RECV_STATUS);
}
private:
bool hijacked_ = false;
grpc::ClientContext* client_context_;
MetadataMap* metadata_map_;
Status* recv_status_;
const char* debug_error_string_;
grpc_status_code status_code_;
grpc_slice error_message_;
};
template <class Op1 = CallNoOp<1>, class Op2 = CallNoOp<2>,
class Op3 = CallNoOp<3>, class Op4 = CallNoOp<4>,
class Op5 = CallNoOp<5>, class Op6 = CallNoOp<6>>
class CallOpSet;
/// Primary implementation of CallOpSetInterface.
/// Since we cannot use variadic templates, we declare slots up to
/// the maximum count of ops we'll need in a set. We leverage the
/// empty base class optimization to slim this class (especially
/// when there are many unused slots used). To avoid duplicate base classes,
/// the template parameter for CallNoOp is varied by argument position.
template <class Op1, class Op2, class Op3, class Op4, class Op5, class Op6>
class CallOpSet : public CallOpSetInterface,
public Op1,
public Op2,
public Op3,
public Op4,
public Op5,
public Op6 {
public:
CallOpSet() : core_cq_tag_(this), return_tag_(this) {}
// The copy constructor and assignment operator reset the value of
// core_cq_tag_, return_tag_, done_intercepting_ and interceptor_methods_
// since those are only meaningful on a specific object, not across objects.
CallOpSet(const CallOpSet& other)
: core_cq_tag_(this),
return_tag_(this),
call_(other.call_),
done_intercepting_(false),
interceptor_methods_(InterceptorBatchMethodsImpl()) {}
CallOpSet& operator=(const CallOpSet& other) {
if (&other == this) {
return *this;
}
core_cq_tag_ = this;
return_tag_ = this;
call_ = other.call_;
done_intercepting_ = false;
interceptor_methods_ = InterceptorBatchMethodsImpl();
return *this;
}
void FillOps(Call* call) override {
done_intercepting_ = false;
g_core_codegen_interface->grpc_call_ref(call->call());
call_ =
*call; // It's fine to create a copy of call since it's just pointers
if (RunInterceptors()) {
ContinueFillOpsAfterInterception();
} else {
// After the interceptors are run, ContinueFillOpsAfterInterception will
// be run
}
}
bool FinalizeResult(void** tag, bool* status) override {
if (done_intercepting_) {
// Complete the avalanching since we are done with this batch of ops
call_.cq()->CompleteAvalanching();
// We have already finished intercepting and filling in the results. This
// round trip from the core needed to be made because interceptors were
// run
*tag = return_tag_;
*status = saved_status_;
g_core_codegen_interface->grpc_call_unref(call_.call());
return true;
}
this->Op1::FinishOp(status);
this->Op2::FinishOp(status);
this->Op3::FinishOp(status);
this->Op4::FinishOp(status);
this->Op5::FinishOp(status);
this->Op6::FinishOp(status);
saved_status_ = *status;
if (RunInterceptorsPostRecv()) {
*tag = return_tag_;
g_core_codegen_interface->grpc_call_unref(call_.call());
return true;
}
// Interceptors are going to be run, so we can't return the tag just yet.
// After the interceptors are run, ContinueFinalizeResultAfterInterception
return false;
}
void set_output_tag(void* return_tag) { return_tag_ = return_tag; }
void* core_cq_tag() override { return core_cq_tag_; }
/// set_core_cq_tag is used to provide a different core CQ tag than "this".
/// This is used for callback-based tags, where the core tag is the core
/// callback function. It does not change the use or behavior of any other
/// function (such as FinalizeResult)
void set_core_cq_tag(void* core_cq_tag) { core_cq_tag_ = core_cq_tag; }
// This will be called while interceptors are run if the RPC is a hijacked
// RPC. This should set hijacking state for each of the ops.
void SetHijackingState() override {
this->Op1::SetHijackingState(&interceptor_methods_);
this->Op2::SetHijackingState(&interceptor_methods_);
this->Op3::SetHijackingState(&interceptor_methods_);
this->Op4::SetHijackingState(&interceptor_methods_);
this->Op5::SetHijackingState(&interceptor_methods_);
this->Op6::SetHijackingState(&interceptor_methods_);
}
// Should be called after interceptors are done running
void ContinueFillOpsAfterInterception() override {
static const size_t MAX_OPS = 6;
grpc_op ops[MAX_OPS];
size_t nops = 0;
this->Op1::AddOp(ops, &nops);
this->Op2::AddOp(ops, &nops);
this->Op3::AddOp(ops, &nops);
this->Op4::AddOp(ops, &nops);
this->Op5::AddOp(ops, &nops);
this->Op6::AddOp(ops, &nops);
grpc_call_error err = g_core_codegen_interface->grpc_call_start_batch(
call_.call(), ops, nops, core_cq_tag(), nullptr);
if (err != GRPC_CALL_OK) {
// A failure here indicates an API misuse; for example, doing a Write
// while another Write is already pending on the same RPC or invoking
// WritesDone multiple times
// gpr_log(GPR_ERROR, "API misuse of type %s observed",
// g_core_codegen_interface->grpc_call_error_to_string(err));
GPR_CODEGEN_ASSERT(false);
}
}
// Should be called after interceptors are done running on the finalize result
// path
void ContinueFinalizeResultAfterInterception() override {
done_intercepting_ = true;
// The following call_start_batch is internally-generated so no need for an
// explanatory log on failure.
GPR_CODEGEN_ASSERT(g_core_codegen_interface->grpc_call_start_batch(
call_.call(), nullptr, 0, core_cq_tag(), nullptr) ==
GRPC_CALL_OK);
}
private:
// Returns true if no interceptors need to be run
bool RunInterceptors() {
interceptor_methods_.ClearState();
interceptor_methods_.SetCallOpSetInterface(this);
interceptor_methods_.SetCall(&call_);
this->Op1::SetInterceptionHookPoint(&interceptor_methods_);
this->Op2::SetInterceptionHookPoint(&interceptor_methods_);
this->Op3::SetInterceptionHookPoint(&interceptor_methods_);
this->Op4::SetInterceptionHookPoint(&interceptor_methods_);
this->Op5::SetInterceptionHookPoint(&interceptor_methods_);
this->Op6::SetInterceptionHookPoint(&interceptor_methods_);
if (interceptor_methods_.InterceptorsListEmpty()) {
return true;
}
// This call will go through interceptors and would need to
// schedule new batches, so delay completion queue shutdown
call_.cq()->RegisterAvalanching();
return interceptor_methods_.RunInterceptors();
}
// Returns true if no interceptors need to be run
bool RunInterceptorsPostRecv() {
// Call and OpSet had already been set on the set state.
// SetReverse also clears previously set hook points
interceptor_methods_.SetReverse();
this->Op1::SetFinishInterceptionHookPoint(&interceptor_methods_);
this->Op2::SetFinishInterceptionHookPoint(&interceptor_methods_);
this->Op3::SetFinishInterceptionHookPoint(&interceptor_methods_);
this->Op4::SetFinishInterceptionHookPoint(&interceptor_methods_);
this->Op5::SetFinishInterceptionHookPoint(&interceptor_methods_);
this->Op6::SetFinishInterceptionHookPoint(&interceptor_methods_);
return interceptor_methods_.RunInterceptors();
}
void* core_cq_tag_;
void* return_tag_;
Call call_;
bool done_intercepting_ = false;
InterceptorBatchMethodsImpl interceptor_methods_;
bool saved_status_;
};
} // namespace internal
} // namespace grpc
#endif // GRPCPP_IMPL_CODEGEN_CALL_OP_SET_H
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