/* * * 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. * */ #ifndef GRPCPP_IMPL_CODEGEN_CLIENT_CALLBACK_H #define GRPCPP_IMPL_CODEGEN_CLIENT_CALLBACK_H #include #include #include #include #include #include #include #include namespace grpc { class Channel; class ClientContext; class CompletionQueue; namespace internal { class RpcMethod; /// Perform a callback-based unary call /// TODO(vjpai): Combine as much as possible with the blocking unary call code template void CallbackUnaryCall(ChannelInterface* channel, const RpcMethod& method, ClientContext* context, const InputMessage* request, OutputMessage* result, std::function on_completion) { CallbackUnaryCallImpl x( channel, method, context, request, result, on_completion); } template class CallbackUnaryCallImpl { public: CallbackUnaryCallImpl(ChannelInterface* channel, const RpcMethod& method, ClientContext* context, const InputMessage* request, OutputMessage* result, std::function on_completion) { CompletionQueue* cq = channel->CallbackCQ(); GPR_CODEGEN_ASSERT(cq != nullptr); Call call(channel->CreateCall(method, context, cq)); using FullCallOpSet = CallOpSet, CallOpClientSendClose, CallOpClientRecvStatus>; auto* ops = new (g_core_codegen_interface->grpc_call_arena_alloc( call.call(), sizeof(FullCallOpSet))) FullCallOpSet; auto* tag = new (g_core_codegen_interface->grpc_call_arena_alloc( call.call(), sizeof(CallbackWithStatusTag))) CallbackWithStatusTag(call.call(), on_completion, ops); // TODO(vjpai): Unify code with sync API as much as possible Status s = ops->SendMessagePtr(request); if (!s.ok()) { tag->force_run(s); return; } ops->SendInitialMetadata(&context->send_initial_metadata_, context->initial_metadata_flags()); ops->RecvInitialMetadata(context); ops->RecvMessage(result); ops->AllowNoMessage(); ops->ClientSendClose(); ops->ClientRecvStatus(context, tag->status_ptr()); ops->set_core_cq_tag(tag); call.PerformOps(ops); } }; } // namespace internal namespace experimental { // Forward declarations template class ClientBidiReactor; template class ClientReadReactor; template class ClientWriteReactor; class ClientUnaryReactor; // NOTE: The streaming objects are not actually implemented in the public API. // These interfaces are provided for mocking only. Typical applications // will interact exclusively with the reactors that they define. template class ClientCallbackReaderWriter { public: virtual ~ClientCallbackReaderWriter() {} virtual void StartCall() = 0; virtual void Write(const Request* req, WriteOptions options) = 0; virtual void WritesDone() = 0; virtual void Read(Response* resp) = 0; virtual void AddHold(int holds) = 0; virtual void RemoveHold() = 0; protected: void BindReactor(ClientBidiReactor* reactor) { reactor->BindStream(this); } }; template class ClientCallbackReader { public: virtual ~ClientCallbackReader() {} virtual void StartCall() = 0; virtual void Read(Response* resp) = 0; virtual void AddHold(int holds) = 0; virtual void RemoveHold() = 0; protected: void BindReactor(ClientReadReactor* reactor) { reactor->BindReader(this); } }; template class ClientCallbackWriter { public: virtual ~ClientCallbackWriter() {} virtual void StartCall() = 0; void Write(const Request* req) { Write(req, WriteOptions()); } virtual void Write(const Request* req, WriteOptions options) = 0; void WriteLast(const Request* req, WriteOptions options) { Write(req, options.set_last_message()); } virtual void WritesDone() = 0; virtual void AddHold(int holds) = 0; virtual void RemoveHold() = 0; protected: void BindReactor(ClientWriteReactor* reactor) { reactor->BindWriter(this); } }; class ClientCallbackUnary { public: virtual ~ClientCallbackUnary() {} virtual void StartCall() = 0; protected: void BindReactor(ClientUnaryReactor* reactor); }; // The following classes are the reactor interfaces that are to be implemented // by the user. They are passed in to the library as an argument to a call on a // stub (either a codegen-ed call or a generic call). The streaming RPC is // activated by calling StartCall, possibly after initiating StartRead, // StartWrite, or AddHold operations on the streaming object. Note that none of // the classes are pure; all reactions have a default empty reaction so that the // user class only needs to override those classes that it cares about. /// \a ClientBidiReactor is the interface for a bidirectional streaming RPC. template class ClientBidiReactor { public: virtual ~ClientBidiReactor() {} /// Activate the RPC and initiate any reads or writes that have been Start'ed /// before this call. All streaming RPCs issued by the client MUST have /// StartCall invoked on them (even if they are canceled) as this call is the /// activation of their lifecycle. void StartCall() { stream_->StartCall(); } /// Initiate a read operation (or post it for later initiation if StartCall /// has not yet been invoked). /// /// \param[out] resp Where to eventually store the read message. Valid when /// the library calls OnReadDone void StartRead(Response* resp) { stream_->Read(resp); } /// Initiate a write operation (or post it for later initiation if StartCall /// has not yet been invoked). /// /// \param[in] req The message to be written. The library takes temporary /// ownership until OnWriteDone, at which point the application /// regains ownership of msg. void StartWrite(const Request* req) { StartWrite(req, WriteOptions()); } /// Initiate/post a write operation with specified options. /// /// \param[in] req The message to be written. The library takes temporary /// ownership until OnWriteDone, at which point the application /// regains ownership of msg. /// \param[in] options The WriteOptions to use for writing this message void StartWrite(const Request* req, WriteOptions options) { stream_->Write(req, std::move(options)); } /// Initiate/post a write operation with specified options and an indication /// that this is the last write (like StartWrite and StartWritesDone, merged). /// Note that calling this means that no more calls to StartWrite, /// StartWriteLast, or StartWritesDone are allowed. /// /// \param[in] req The message to be written. The library takes temporary /// ownership until OnWriteDone, at which point the application /// regains ownership of msg. /// \param[in] options The WriteOptions to use for writing this message void StartWriteLast(const Request* req, WriteOptions options) { StartWrite(req, std::move(options.set_last_message())); } /// Indicate that the RPC will have no more write operations. This can only be /// issued once for a given RPC. This is not required or allowed if /// StartWriteLast is used since that already has the same implication. /// Note that calling this means that no more calls to StartWrite, /// StartWriteLast, or StartWritesDone are allowed. void StartWritesDone() { stream_->WritesDone(); } /// Holds are needed if (and only if) this stream has operations that take /// place on it after StartCall but from outside one of the reactions /// (OnReadDone, etc). This is _not_ a common use of the streaming API. /// /// Holds must be added before calling StartCall. If a stream still has a hold /// in place, its resources will not be destroyed even if the status has /// already come in from the wire and there are currently no active callbacks /// outstanding. Similarly, the stream will not call OnDone if there are still /// holds on it. /// /// For example, if a StartRead or StartWrite operation is going to be /// initiated from elsewhere in the application, the application should call /// AddHold or AddMultipleHolds before StartCall. If there is going to be, /// for example, a read-flow and a write-flow taking place outside the /// reactions, then call AddMultipleHolds(2) before StartCall. When the /// application knows that it won't issue any more read operations (such as /// when a read comes back as not ok), it should issue a RemoveHold(). It /// should also call RemoveHold() again after it does StartWriteLast or /// StartWritesDone that indicates that there will be no more write ops. /// The number of RemoveHold calls must match the total number of AddHold /// calls plus the number of holds added by AddMultipleHolds. void AddHold() { AddMultipleHolds(1); } void AddMultipleHolds(int holds) { stream_->AddHold(holds); } void RemoveHold() { stream_->RemoveHold(); } /// Notifies the application that all operations associated with this RPC /// have completed and provides the RPC status outcome. /// /// \param[in] s The status outcome of this RPC virtual void OnDone(const Status& s) {} /// Notifies the application that a read of initial metadata from the /// server is done. If the application chooses not to implement this method, /// it can assume that the initial metadata has been read before the first /// call of OnReadDone or OnDone. /// /// \param[in] ok Was the initial metadata read successfully? If false, no /// further read-side operation will succeed. virtual void OnReadInitialMetadataDone(bool ok) {} /// Notifies the application that a StartRead operation completed. /// /// \param[in] ok Was it successful? If false, no further read-side operation /// will succeed. virtual void OnReadDone(bool ok) {} /// Notifies the application that a StartWrite operation completed. /// /// \param[in] ok Was it successful? If false, no further write-side operation /// will succeed. virtual void OnWriteDone(bool ok) {} /// Notifies the application that a StartWritesDone operation completed. Note /// that this is only used on explicit StartWritesDone operations and not for /// those that are implicitly invoked as part of a StartWriteLast. /// /// \param[in] ok Was it successful? If false, the application will later see /// the failure reflected as a bad status in OnDone. virtual void OnWritesDoneDone(bool ok) {} private: friend class ClientCallbackReaderWriter; void BindStream(ClientCallbackReaderWriter* stream) { stream_ = stream; } ClientCallbackReaderWriter* stream_; }; /// \a ClientReadReactor is the interface for a server-streaming RPC. /// All public methods behave as in ClientBidiReactor. template class ClientReadReactor { public: virtual ~ClientReadReactor() {} void StartCall() { reader_->StartCall(); } void StartRead(Response* resp) { reader_->Read(resp); } void AddHold() { AddMultipleHolds(1); } void AddMultipleHolds(int holds) { reader_->AddHold(holds); } void RemoveHold() { reader_->RemoveHold(); } virtual void OnDone(const Status& s) {} virtual void OnReadInitialMetadataDone(bool ok) {} virtual void OnReadDone(bool ok) {} private: friend class ClientCallbackReader; void BindReader(ClientCallbackReader* reader) { reader_ = reader; } ClientCallbackReader* reader_; }; /// \a ClientWriteReactor is the interface for a client-streaming RPC. /// All public methods behave as in ClientBidiReactor. template class ClientWriteReactor { public: virtual ~ClientWriteReactor() {} void StartCall() { writer_->StartCall(); } void StartWrite(const Request* req) { StartWrite(req, WriteOptions()); } void StartWrite(const Request* req, WriteOptions options) { writer_->Write(req, std::move(options)); } void StartWriteLast(const Request* req, WriteOptions options) { StartWrite(req, std::move(options.set_last_message())); } void StartWritesDone() { writer_->WritesDone(); } void AddHold() { AddMultipleHolds(1); } void AddMultipleHolds(int holds) { writer_->AddHold(holds); } void RemoveHold() { writer_->RemoveHold(); } virtual void OnDone(const Status& s) {} virtual void OnReadInitialMetadataDone(bool ok) {} virtual void OnWriteDone(bool ok) {} virtual void OnWritesDoneDone(bool ok) {} private: friend class ClientCallbackWriter; void BindWriter(ClientCallbackWriter* writer) { writer_ = writer; } ClientCallbackWriter* writer_; }; /// \a ClientUnaryReactor is a reactor-style interface for a unary RPC. /// This is _not_ a common way of invoking a unary RPC. In practice, this /// option should be used only if the unary RPC wants to receive initial /// metadata without waiting for the response to complete. Most deployments of /// RPC systems do not use this option, but it is needed for generality. /// All public methods behave as in ClientBidiReactor. /// StartCall is included for consistency with the other reactor flavors: even /// though there are no StartRead or StartWrite operations to queue before the /// call (that is part of the unary call itself) and there is no reactor object /// being created as a result of this call, we keep a consistent 2-phase /// initiation API among all the reactor flavors. class ClientUnaryReactor { public: virtual ~ClientUnaryReactor() {} void StartCall() { call_->StartCall(); } virtual void OnDone(const Status& s) {} virtual void OnReadInitialMetadataDone(bool ok) {} private: friend class ClientCallbackUnary; void BindCall(ClientCallbackUnary* call) { call_ = call; } ClientCallbackUnary* call_; }; // Define function out-of-line from class to avoid forward declaration issue inline void ClientCallbackUnary::BindReactor(ClientUnaryReactor* reactor) { reactor->BindCall(this); } } // namespace experimental namespace internal { // Forward declare factory classes for friendship template class ClientCallbackReaderWriterFactory; template class ClientCallbackReaderFactory; template class ClientCallbackWriterFactory; template class ClientCallbackReaderWriterImpl : public ::grpc::experimental::ClientCallbackReaderWriter { public: // always allocated against a call arena, no memory free required static void operator delete(void* ptr, std::size_t size) { assert(size == sizeof(ClientCallbackReaderWriterImpl)); } // This operator should never be called as the memory should be freed as part // of the arena destruction. It only exists to provide a matching operator // delete to the operator new so that some compilers will not complain (see // https://github.com/grpc/grpc/issues/11301) Note at the time of adding this // there are no tests catching the compiler warning. static void operator delete(void*, void*) { assert(0); } void MaybeFinish() { if (--callbacks_outstanding_ == 0) { Status s = std::move(finish_status_); auto* reactor = reactor_; auto* call = call_.call(); this->~ClientCallbackReaderWriterImpl(); g_core_codegen_interface->grpc_call_unref(call); reactor->OnDone(s); } } void StartCall() override { // This call initiates two batches, plus any backlog, each with a callback // 1. Send initial metadata (unless corked) + recv initial metadata // 2. Any read backlog // 3. Any write backlog // 4. Recv trailing metadata, on_completion callback started_ = true; start_tag_.Set(call_.call(), [this](bool ok) { reactor_->OnReadInitialMetadataDone(ok); MaybeFinish(); }, &start_ops_); if (!start_corked_) { start_ops_.SendInitialMetadata(&context_->send_initial_metadata_, context_->initial_metadata_flags()); } start_ops_.RecvInitialMetadata(context_); start_ops_.set_core_cq_tag(&start_tag_); call_.PerformOps(&start_ops_); // Also set up the read and write tags so that they don't have to be set up // each time write_tag_.Set(call_.call(), [this](bool ok) { reactor_->OnWriteDone(ok); MaybeFinish(); }, &write_ops_); write_ops_.set_core_cq_tag(&write_tag_); read_tag_.Set(call_.call(), [this](bool ok) { reactor_->OnReadDone(ok); MaybeFinish(); }, &read_ops_); read_ops_.set_core_cq_tag(&read_tag_); if (read_ops_at_start_) { call_.PerformOps(&read_ops_); } if (write_ops_at_start_) { call_.PerformOps(&write_ops_); } if (writes_done_ops_at_start_) { call_.PerformOps(&writes_done_ops_); } finish_tag_.Set(call_.call(), [this](bool ok) { MaybeFinish(); }, &finish_ops_); finish_ops_.ClientRecvStatus(context_, &finish_status_); finish_ops_.set_core_cq_tag(&finish_tag_); call_.PerformOps(&finish_ops_); } void Read(Response* msg) override { read_ops_.RecvMessage(msg); callbacks_outstanding_++; if (started_) { call_.PerformOps(&read_ops_); } else { read_ops_at_start_ = true; } } void Write(const Request* msg, WriteOptions options) override { if (start_corked_) { write_ops_.SendInitialMetadata(&context_->send_initial_metadata_, context_->initial_metadata_flags()); start_corked_ = false; } if (options.is_last_message()) { options.set_buffer_hint(); write_ops_.ClientSendClose(); } // TODO(vjpai): don't assert GPR_CODEGEN_ASSERT(write_ops_.SendMessagePtr(msg, options).ok()); callbacks_outstanding_++; if (started_) { call_.PerformOps(&write_ops_); } else { write_ops_at_start_ = true; } } void WritesDone() override { if (start_corked_) { writes_done_ops_.SendInitialMetadata(&context_->send_initial_metadata_, context_->initial_metadata_flags()); start_corked_ = false; } writes_done_ops_.ClientSendClose(); writes_done_tag_.Set(call_.call(), [this](bool ok) { reactor_->OnWritesDoneDone(ok); MaybeFinish(); }, &writes_done_ops_); writes_done_ops_.set_core_cq_tag(&writes_done_tag_); callbacks_outstanding_++; if (started_) { call_.PerformOps(&writes_done_ops_); } else { writes_done_ops_at_start_ = true; } } virtual void AddHold(int holds) override { callbacks_outstanding_ += holds; } virtual void RemoveHold() override { MaybeFinish(); } private: friend class ClientCallbackReaderWriterFactory; ClientCallbackReaderWriterImpl( Call call, ClientContext* context, ::grpc::experimental::ClientBidiReactor* reactor) : context_(context), call_(call), reactor_(reactor), start_corked_(context_->initial_metadata_corked_) { this->BindReactor(reactor); } ClientContext* const context_; Call call_; ::grpc::experimental::ClientBidiReactor* const reactor_; CallOpSet start_ops_; CallbackWithSuccessTag start_tag_; bool start_corked_; CallOpSet finish_ops_; CallbackWithSuccessTag finish_tag_; Status finish_status_; CallOpSet write_ops_; CallbackWithSuccessTag write_tag_; bool write_ops_at_start_{false}; CallOpSet writes_done_ops_; CallbackWithSuccessTag writes_done_tag_; bool writes_done_ops_at_start_{false}; CallOpSet> read_ops_; CallbackWithSuccessTag read_tag_; bool read_ops_at_start_{false}; // Minimum of 2 callbacks to pre-register for start and finish std::atomic_int callbacks_outstanding_{2}; bool started_{false}; }; template class ClientCallbackReaderWriterFactory { public: static void Create( ChannelInterface* channel, const ::grpc::internal::RpcMethod& method, ClientContext* context, ::grpc::experimental::ClientBidiReactor* reactor) { Call call = channel->CreateCall(method, context, channel->CallbackCQ()); g_core_codegen_interface->grpc_call_ref(call.call()); new (g_core_codegen_interface->grpc_call_arena_alloc( call.call(), sizeof(ClientCallbackReaderWriterImpl))) ClientCallbackReaderWriterImpl(call, context, reactor); } }; template class ClientCallbackReaderImpl : public ::grpc::experimental::ClientCallbackReader { public: // always allocated against a call arena, no memory free required static void operator delete(void* ptr, std::size_t size) { assert(size == sizeof(ClientCallbackReaderImpl)); } // This operator should never be called as the memory should be freed as part // of the arena destruction. It only exists to provide a matching operator // delete to the operator new so that some compilers will not complain (see // https://github.com/grpc/grpc/issues/11301) Note at the time of adding this // there are no tests catching the compiler warning. static void operator delete(void*, void*) { assert(0); } void MaybeFinish() { if (--callbacks_outstanding_ == 0) { Status s = std::move(finish_status_); auto* reactor = reactor_; auto* call = call_.call(); this->~ClientCallbackReaderImpl(); g_core_codegen_interface->grpc_call_unref(call); reactor->OnDone(s); } } void StartCall() override { // This call initiates two batches, plus any backlog, each with a callback // 1. Send initial metadata (unless corked) + recv initial metadata // 2. Any backlog // 3. Recv trailing metadata, on_completion callback started_ = true; start_tag_.Set(call_.call(), [this](bool ok) { reactor_->OnReadInitialMetadataDone(ok); MaybeFinish(); }, &start_ops_); start_ops_.SendInitialMetadata(&context_->send_initial_metadata_, context_->initial_metadata_flags()); start_ops_.RecvInitialMetadata(context_); start_ops_.set_core_cq_tag(&start_tag_); call_.PerformOps(&start_ops_); // Also set up the read tag so it doesn't have to be set up each time read_tag_.Set(call_.call(), [this](bool ok) { reactor_->OnReadDone(ok); MaybeFinish(); }, &read_ops_); read_ops_.set_core_cq_tag(&read_tag_); if (read_ops_at_start_) { call_.PerformOps(&read_ops_); } finish_tag_.Set(call_.call(), [this](bool ok) { MaybeFinish(); }, &finish_ops_); finish_ops_.ClientRecvStatus(context_, &finish_status_); finish_ops_.set_core_cq_tag(&finish_tag_); call_.PerformOps(&finish_ops_); } void Read(Response* msg) override { read_ops_.RecvMessage(msg); callbacks_outstanding_++; if (started_) { call_.PerformOps(&read_ops_); } else { read_ops_at_start_ = true; } } virtual void AddHold(int holds) override { callbacks_outstanding_ += holds; } virtual void RemoveHold() override { MaybeFinish(); } private: friend class ClientCallbackReaderFactory; template ClientCallbackReaderImpl( Call call, ClientContext* context, Request* request, ::grpc::experimental::ClientReadReactor* reactor) : context_(context), call_(call), reactor_(reactor) { this->BindReactor(reactor); // TODO(vjpai): don't assert GPR_CODEGEN_ASSERT(start_ops_.SendMessagePtr(request).ok()); start_ops_.ClientSendClose(); } ClientContext* const context_; Call call_; ::grpc::experimental::ClientReadReactor* const reactor_; CallOpSet start_ops_; CallbackWithSuccessTag start_tag_; CallOpSet finish_ops_; CallbackWithSuccessTag finish_tag_; Status finish_status_; CallOpSet> read_ops_; CallbackWithSuccessTag read_tag_; bool read_ops_at_start_{false}; // Minimum of 2 callbacks to pre-register for start and finish std::atomic_int callbacks_outstanding_{2}; bool started_{false}; }; template class ClientCallbackReaderFactory { public: template static void Create( ChannelInterface* channel, const ::grpc::internal::RpcMethod& method, ClientContext* context, const Request* request, ::grpc::experimental::ClientReadReactor* reactor) { Call call = channel->CreateCall(method, context, channel->CallbackCQ()); g_core_codegen_interface->grpc_call_ref(call.call()); new (g_core_codegen_interface->grpc_call_arena_alloc( call.call(), sizeof(ClientCallbackReaderImpl))) ClientCallbackReaderImpl(call, context, request, reactor); } }; template class ClientCallbackWriterImpl : public ::grpc::experimental::ClientCallbackWriter { public: // always allocated against a call arena, no memory free required static void operator delete(void* ptr, std::size_t size) { assert(size == sizeof(ClientCallbackWriterImpl)); } // This operator should never be called as the memory should be freed as part // of the arena destruction. It only exists to provide a matching operator // delete to the operator new so that some compilers will not complain (see // https://github.com/grpc/grpc/issues/11301) Note at the time of adding this // there are no tests catching the compiler warning. static void operator delete(void*, void*) { assert(0); } void MaybeFinish() { if (--callbacks_outstanding_ == 0) { Status s = std::move(finish_status_); auto* reactor = reactor_; auto* call = call_.call(); this->~ClientCallbackWriterImpl(); g_core_codegen_interface->grpc_call_unref(call); reactor->OnDone(s); } } void StartCall() override { // This call initiates two batches, plus any backlog, each with a callback // 1. Send initial metadata (unless corked) + recv initial metadata // 2. Any backlog // 3. Recv trailing metadata, on_completion callback started_ = true; start_tag_.Set(call_.call(), [this](bool ok) { reactor_->OnReadInitialMetadataDone(ok); MaybeFinish(); }, &start_ops_); if (!start_corked_) { start_ops_.SendInitialMetadata(&context_->send_initial_metadata_, context_->initial_metadata_flags()); } start_ops_.RecvInitialMetadata(context_); start_ops_.set_core_cq_tag(&start_tag_); call_.PerformOps(&start_ops_); // Also set up the read and write tags so that they don't have to be set up // each time write_tag_.Set(call_.call(), [this](bool ok) { reactor_->OnWriteDone(ok); MaybeFinish(); }, &write_ops_); write_ops_.set_core_cq_tag(&write_tag_); if (write_ops_at_start_) { call_.PerformOps(&write_ops_); } if (writes_done_ops_at_start_) { call_.PerformOps(&writes_done_ops_); } finish_tag_.Set(call_.call(), [this](bool ok) { MaybeFinish(); }, &finish_ops_); finish_ops_.ClientRecvStatus(context_, &finish_status_); finish_ops_.set_core_cq_tag(&finish_tag_); call_.PerformOps(&finish_ops_); } void Write(const Request* msg, WriteOptions options) override { if (start_corked_) { write_ops_.SendInitialMetadata(&context_->send_initial_metadata_, context_->initial_metadata_flags()); start_corked_ = false; } if (options.is_last_message()) { options.set_buffer_hint(); write_ops_.ClientSendClose(); } // TODO(vjpai): don't assert GPR_CODEGEN_ASSERT(write_ops_.SendMessagePtr(msg, options).ok()); callbacks_outstanding_++; if (started_) { call_.PerformOps(&write_ops_); } else { write_ops_at_start_ = true; } } void WritesDone() override { if (start_corked_) { writes_done_ops_.SendInitialMetadata(&context_->send_initial_metadata_, context_->initial_metadata_flags()); start_corked_ = false; } writes_done_ops_.ClientSendClose(); writes_done_tag_.Set(call_.call(), [this](bool ok) { reactor_->OnWritesDoneDone(ok); MaybeFinish(); }, &writes_done_ops_); writes_done_ops_.set_core_cq_tag(&writes_done_tag_); callbacks_outstanding_++; if (started_) { call_.PerformOps(&writes_done_ops_); } else { writes_done_ops_at_start_ = true; } } virtual void AddHold(int holds) override { callbacks_outstanding_ += holds; } virtual void RemoveHold() override { MaybeFinish(); } private: friend class ClientCallbackWriterFactory; template ClientCallbackWriterImpl( Call call, ClientContext* context, Response* response, ::grpc::experimental::ClientWriteReactor* reactor) : context_(context), call_(call), reactor_(reactor), start_corked_(context_->initial_metadata_corked_) { this->BindReactor(reactor); finish_ops_.RecvMessage(response); finish_ops_.AllowNoMessage(); } ClientContext* const context_; Call call_; ::grpc::experimental::ClientWriteReactor* const reactor_; CallOpSet start_ops_; CallbackWithSuccessTag start_tag_; bool start_corked_; CallOpSet finish_ops_; CallbackWithSuccessTag finish_tag_; Status finish_status_; CallOpSet write_ops_; CallbackWithSuccessTag write_tag_; bool write_ops_at_start_{false}; CallOpSet writes_done_ops_; CallbackWithSuccessTag writes_done_tag_; bool writes_done_ops_at_start_{false}; // Minimum of 2 callbacks to pre-register for start and finish std::atomic_int callbacks_outstanding_{2}; bool started_{false}; }; template class ClientCallbackWriterFactory { public: template static void Create( ChannelInterface* channel, const ::grpc::internal::RpcMethod& method, ClientContext* context, Response* response, ::grpc::experimental::ClientWriteReactor* reactor) { Call call = channel->CreateCall(method, context, channel->CallbackCQ()); g_core_codegen_interface->grpc_call_ref(call.call()); new (g_core_codegen_interface->grpc_call_arena_alloc( call.call(), sizeof(ClientCallbackWriterImpl))) ClientCallbackWriterImpl(call, context, response, reactor); } }; class ClientCallbackUnaryImpl final : public ::grpc::experimental::ClientCallbackUnary { public: // always allocated against a call arena, no memory free required static void operator delete(void* ptr, std::size_t size) { assert(size == sizeof(ClientCallbackUnaryImpl)); } // This operator should never be called as the memory should be freed as part // of the arena destruction. It only exists to provide a matching operator // delete to the operator new so that some compilers will not complain (see // https://github.com/grpc/grpc/issues/11301) Note at the time of adding this // there are no tests catching the compiler warning. static void operator delete(void*, void*) { assert(0); } void StartCall() override { // This call initiates two batches, each with a callback // 1. Send initial metadata + write + writes done + recv initial metadata // 2. Read message, recv trailing metadata started_ = true; start_tag_.Set(call_.call(), [this](bool ok) { reactor_->OnReadInitialMetadataDone(ok); MaybeFinish(); }, &start_ops_); start_ops_.SendInitialMetadata(&context_->send_initial_metadata_, context_->initial_metadata_flags()); start_ops_.RecvInitialMetadata(context_); start_ops_.set_core_cq_tag(&start_tag_); call_.PerformOps(&start_ops_); finish_tag_.Set(call_.call(), [this](bool ok) { MaybeFinish(); }, &finish_ops_); finish_ops_.ClientRecvStatus(context_, &finish_status_); finish_ops_.set_core_cq_tag(&finish_tag_); call_.PerformOps(&finish_ops_); } void MaybeFinish() { if (--callbacks_outstanding_ == 0) { Status s = std::move(finish_status_); auto* reactor = reactor_; auto* call = call_.call(); this->~ClientCallbackUnaryImpl(); g_core_codegen_interface->grpc_call_unref(call); reactor->OnDone(s); } } private: friend class ClientCallbackUnaryFactory; template ClientCallbackUnaryImpl(Call call, ClientContext* context, Request* request, Response* response, ::grpc::experimental::ClientUnaryReactor* reactor) : context_(context), call_(call), reactor_(reactor) { this->BindReactor(reactor); // TODO(vjpai): don't assert GPR_CODEGEN_ASSERT(start_ops_.SendMessagePtr(request).ok()); start_ops_.ClientSendClose(); finish_ops_.RecvMessage(response); finish_ops_.AllowNoMessage(); } ClientContext* const context_; Call call_; ::grpc::experimental::ClientUnaryReactor* const reactor_; CallOpSet start_ops_; CallbackWithSuccessTag start_tag_; CallOpSet finish_ops_; CallbackWithSuccessTag finish_tag_; Status finish_status_; // This call will have 2 callbacks: start and finish std::atomic_int callbacks_outstanding_{2}; bool started_{false}; }; class ClientCallbackUnaryFactory { public: template static void Create(ChannelInterface* channel, const ::grpc::internal::RpcMethod& method, ClientContext* context, const Request* request, Response* response, ::grpc::experimental::ClientUnaryReactor* reactor) { Call call = channel->CreateCall(method, context, channel->CallbackCQ()); g_core_codegen_interface->grpc_call_ref(call.call()); new (g_core_codegen_interface->grpc_call_arena_alloc( call.call(), sizeof(ClientCallbackUnaryImpl))) ClientCallbackUnaryImpl(call, context, request, response, reactor); } }; } // namespace internal } // namespace grpc #endif // GRPCPP_IMPL_CODEGEN_CLIENT_CALLBACK_H