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/*
*
* Copyright 2015, Google Inc.
* All rights reserved.
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions are
* met:
*
* * Redistributions of source code must retain the above copyright
* notice, this list of conditions and the following disclaimer.
* * Redistributions in binary form must reproduce the above
* copyright notice, this list of conditions and the following disclaimer
* in the documentation and/or other materials provided with the
* distribution.
* * Neither the name of Google Inc. nor the names of its
* contributors may be used to endorse or promote products derived from
* this software without specific prior written permission.
*
* THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS
* "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT
* LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR
* A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT
* OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL,
* SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT
* LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE,
* DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY
* THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
* (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE
* OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
*
*/
#ifndef GRPCXX_IMPL_CODEGEN_ASYNC_STREAM_H
#define GRPCXX_IMPL_CODEGEN_ASYNC_STREAM_H
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#include <grpc++/impl/codegen/call.h>
#include <grpc++/impl/codegen/channel_interface.h>
#include <grpc++/impl/codegen/core_codegen_interface.h>
#include <grpc++/impl/codegen/server_context.h>
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#include <grpc++/impl/codegen/service_type.h>
#include <grpc++/impl/codegen/status.h>
namespace grpc {
class CompletionQueue;
/// Common interface for all client side asynchronous streaming.
class ClientAsyncStreamingInterface {
public:
virtual ~ClientAsyncStreamingInterface() {}
/// Request notification of the reading of the initial metadata. Completion
/// will be notified by \a tag on the associated completion queue.
/// This call is optional, but if it is used, it cannot be used concurrently
/// with or after the \a Read method.
///
/// \param[in] tag Tag identifying this request.
virtual void ReadInitialMetadata(void* tag) = 0;
/// Indicate that the stream is to be finished and request notification
/// Should not be used concurrently with other operations
///
/// \param[out] status To be updated with the operation status.
/// \param[in] tag Tag identifying this request.
virtual void Finish(Status* status, void* tag) = 0;
};
/// An interface that yields a sequence of messages of type \a R.
template <class R>
class AsyncReaderInterface {
public:
virtual ~AsyncReaderInterface() {}
/// Read a message of type \a R into \a msg. Completion will be notified by \a
/// tag on the associated completion queue.
/// This is thread-safe with respect to \a Write or \a WritesDone methods. It
/// should not be called concurrently with other streaming APIs
/// on the same stream. It is not meaningful to call it concurrently
/// with another \a Read on the same stream since reads on the same stream
/// are delivered in order.
///
/// \param[out] msg Where to eventually store the read message.
/// \param[in] tag The tag identifying the operation.
virtual void Read(R* msg, void* tag) = 0;
};
/// An interface that can be fed a sequence of messages of type \a W.
template <class W>
class AsyncWriterInterface {
public:
virtual ~AsyncWriterInterface() {}
/// Request the writing of \a msg with identifying tag \a tag.
///
/// Only one write may be outstanding at any given time. This means that
/// after calling Write, one must wait to receive \a tag from the completion
/// queue BEFORE calling Write again.
/// This is thread-safe with respect to \a Read
///
/// \param[in] msg The message to be written.
/// \param[in] tag The tag identifying the operation.
virtual void Write(const W& msg, void* tag) = 0;
/// Request the writing of \a msg using WriteOptions \a options with
/// identifying tag \a tag.
///
/// Only one write may be outstanding at any given time. This means that
/// after calling Write, one must wait to receive \a tag from the completion
/// queue BEFORE calling Write again.
/// WriteOptions \a options is used to set the write options of this message.
/// This is thread-safe with respect to \a Read
///
/// \param[in] msg The message to be written.
/// \param[in] options The WriteOptions to be used to write this message.
/// \param[in] tag The tag identifying the operation.
virtual void Write(const W& msg, WriteOptions options, void* tag) = 0;
/// Request the writing of \a msg and coalesce it with the writing
/// of trailing metadata, using WriteOptions \a options with identifying tag
/// \a tag.
///
/// For client, WriteLast is equivalent of performing Write and WritesDone in
/// a single step.
/// For server, WriteLast buffers the \a msg. The writing of \a msg is held
/// until Finish is called, where \a msg and trailing metadata are coalesced
/// and write is initiated. Note that WriteLast can only buffer \a msg up to
/// the flow control window size. If \a msg size is larger than the window
/// size, it will be sent on wire without buffering.
///
/// \param[in] msg The message to be written.
/// \param[in] options The WriteOptions to be used to write this message.
/// \param[in] tag The tag identifying the operation.
void WriteLast(const W& msg, WriteOptions options, void* tag) {
Write(msg, options.set_last_message(), tag);
}
};
template <class R>
class ClientAsyncReaderInterface : public ClientAsyncStreamingInterface,
public AsyncReaderInterface<R> {};
template <class R>
class ClientAsyncReader final : public ClientAsyncReaderInterface<R> {
public:
/// Create a stream and write the first request out.
template <class W>
ClientAsyncReader(ChannelInterface* channel, CompletionQueue* cq,
const RpcMethod& method, ClientContext* context,
const W& request, void* tag)
: context_(context), call_(channel->CreateCall(method, context, cq)) {
init_ops_.set_output_tag(tag);
init_ops_.SendInitialMetadata(context->send_initial_metadata_,
context->initial_metadata_flags());
// TODO(ctiller): don't assert
GPR_CODEGEN_ASSERT(init_ops_.SendMessage(request).ok());
init_ops_.ClientSendClose();
call_.PerformOps(&init_ops_);
}
void ReadInitialMetadata(void* tag) override {
GPR_CODEGEN_ASSERT(!context_->initial_metadata_received_);
meta_ops_.set_output_tag(tag);
meta_ops_.RecvInitialMetadata(context_);
call_.PerformOps(&meta_ops_);
}
void Read(R* msg, void* tag) override {
read_ops_.set_output_tag(tag);
if (!context_->initial_metadata_received_) {
read_ops_.RecvInitialMetadata(context_);
}
read_ops_.RecvMessage(msg);
call_.PerformOps(&read_ops_);
}
void Finish(Status* status, void* tag) override {
finish_ops_.set_output_tag(tag);
if (!context_->initial_metadata_received_) {
finish_ops_.RecvInitialMetadata(context_);
}
finish_ops_.ClientRecvStatus(context_, status);
call_.PerformOps(&finish_ops_);
}
private:
ClientContext* context_;
Call call_;
CallOpSet<CallOpSendInitialMetadata, CallOpSendMessage, CallOpClientSendClose>
init_ops_;
CallOpSet<CallOpRecvInitialMetadata> meta_ops_;
CallOpSet<CallOpRecvInitialMetadata, CallOpRecvMessage<R>> read_ops_;
CallOpSet<CallOpRecvInitialMetadata, CallOpClientRecvStatus> finish_ops_;
};
/// Common interface for client side asynchronous writing.
template <class W>
class ClientAsyncWriterInterface : public ClientAsyncStreamingInterface,
public AsyncWriterInterface<W> {
public:
/// Signal the client is done with the writes.
/// Thread-safe with respect to \a Read
///
/// \param[in] tag The tag identifying the operation.
virtual void WritesDone(void* tag) = 0;
};
template <class W>
class ClientAsyncWriter final : public ClientAsyncWriterInterface<W> {
public:
template <class R>
ClientAsyncWriter(ChannelInterface* channel, CompletionQueue* cq,
const RpcMethod& method, ClientContext* context,
R* response, void* tag)
: context_(context), call_(channel->CreateCall(method, context, cq)) {
finish_ops_.RecvMessage(response);
finish_ops_.AllowNoMessage();
// if corked bit is set in context, we buffer up the initial metadata to
// coalesce with later message to be sent. No op is performed.
if (context_->initial_metadata_corked_) {
write_ops_.SendInitialMetadata(context->send_initial_metadata_,
context->initial_metadata_flags());
} else {
write_ops_.set_output_tag(tag);
write_ops_.SendInitialMetadata(context->send_initial_metadata_,
context->initial_metadata_flags());
call_.PerformOps(&write_ops_);
}
}
void ReadInitialMetadata(void* tag) override {
GPR_CODEGEN_ASSERT(!context_->initial_metadata_received_);
meta_ops_.set_output_tag(tag);
meta_ops_.RecvInitialMetadata(context_);
call_.PerformOps(&meta_ops_);
}
void Write(const W& msg, void* tag) override {
write_ops_.set_output_tag(tag);
// TODO(ctiller): don't assert
GPR_CODEGEN_ASSERT(write_ops_.SendMessage(msg).ok());
call_.PerformOps(&write_ops_);
}
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void Write(const W& msg, WriteOptions options, void* tag) override {
write_ops_.set_output_tag(tag);
if (options.is_last_message()) {
options.set_buffer_hint();
write_ops_.ClientSendClose();
}
// TODO(ctiller): don't assert
GPR_CODEGEN_ASSERT(write_ops_.SendMessage(msg, options).ok());
call_.PerformOps(&write_ops_);
}
void WritesDone(void* tag) override {
write_ops_.set_output_tag(tag);
write_ops_.ClientSendClose();
call_.PerformOps(&write_ops_);
}
void Finish(Status* status, void* tag) override {
finish_ops_.set_output_tag(tag);
if (!context_->initial_metadata_received_) {
finish_ops_.RecvInitialMetadata(context_);
}
finish_ops_.ClientRecvStatus(context_, status);
call_.PerformOps(&finish_ops_);
}
private:
ClientContext* context_;
Call call_;
CallOpSet<CallOpRecvInitialMetadata> meta_ops_;
CallOpSet<CallOpSendInitialMetadata, CallOpSendMessage, CallOpClientSendClose>
write_ops_;
CallOpSet<CallOpRecvInitialMetadata, CallOpGenericRecvMessage,
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CallOpClientRecvStatus>
finish_ops_;
};
/// Client-side interface for asynchronous bi-directional streaming.
template <class W, class R>
class ClientAsyncReaderWriterInterface : public ClientAsyncStreamingInterface,
public AsyncWriterInterface<W>,
public AsyncReaderInterface<R> {
public:
/// Signal the client is done with the writes.
/// Thread-safe with respect to \a Read
///
/// \param[in] tag The tag identifying the operation.
virtual void WritesDone(void* tag) = 0;
};
template <class W, class R>
class ClientAsyncReaderWriter final
: public ClientAsyncReaderWriterInterface<W, R> {
public:
ClientAsyncReaderWriter(ChannelInterface* channel, CompletionQueue* cq,
const RpcMethod& method, ClientContext* context,
void* tag)
: context_(context), call_(channel->CreateCall(method, context, cq)) {
if (context_->initial_metadata_corked_) {
// if corked bit is set in context, we buffer up the initial metadata to
// coalesce with later message to be sent. No op is performed.
write_ops_.SendInitialMetadata(context->send_initial_metadata_,
context->initial_metadata_flags());
} else {
write_ops_.set_output_tag(tag);
write_ops_.SendInitialMetadata(context->send_initial_metadata_,
context->initial_metadata_flags());
call_.PerformOps(&write_ops_);
}
}
void ReadInitialMetadata(void* tag) override {
GPR_CODEGEN_ASSERT(!context_->initial_metadata_received_);
meta_ops_.set_output_tag(tag);
meta_ops_.RecvInitialMetadata(context_);
call_.PerformOps(&meta_ops_);
}
void Read(R* msg, void* tag) override {
read_ops_.set_output_tag(tag);
if (!context_->initial_metadata_received_) {
read_ops_.RecvInitialMetadata(context_);
}
read_ops_.RecvMessage(msg);
call_.PerformOps(&read_ops_);
}
void Write(const W& msg, void* tag) override {
write_ops_.set_output_tag(tag);
// TODO(ctiller): don't assert
GPR_CODEGEN_ASSERT(write_ops_.SendMessage(msg).ok());
call_.PerformOps(&write_ops_);
}
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void Write(const W& msg, WriteOptions options, void* tag) override {
write_ops_.set_output_tag(tag);
if (options.is_last_message()) {
options.set_buffer_hint();
write_ops_.ClientSendClose();
}
// TODO(ctiller): don't assert
GPR_CODEGEN_ASSERT(write_ops_.SendMessage(msg, options).ok());
call_.PerformOps(&write_ops_);
}
void WritesDone(void* tag) override {
write_ops_.set_output_tag(tag);
write_ops_.ClientSendClose();
call_.PerformOps(&write_ops_);
}
void Finish(Status* status, void* tag) override {
finish_ops_.set_output_tag(tag);
if (!context_->initial_metadata_received_) {
finish_ops_.RecvInitialMetadata(context_);
}
finish_ops_.ClientRecvStatus(context_, status);
call_.PerformOps(&finish_ops_);
}
private:
ClientContext* context_;
Call call_;
CallOpSet<CallOpRecvInitialMetadata> meta_ops_;
CallOpSet<CallOpRecvInitialMetadata, CallOpRecvMessage<R>> read_ops_;
CallOpSet<CallOpSendInitialMetadata, CallOpSendMessage, CallOpClientSendClose>
write_ops_;
CallOpSet<CallOpRecvInitialMetadata, CallOpClientRecvStatus> finish_ops_;
};
template <class W, class R>
class ServerAsyncReaderInterface : public ServerAsyncStreamingInterface,
public AsyncReaderInterface<R> {
public:
virtual void Finish(const W& msg, const Status& status, void* tag) = 0;
virtual void FinishWithError(const Status& status, void* tag) = 0;
};
template <class W, class R>
class ServerAsyncReader final : public ServerAsyncReaderInterface<W, R> {
public:
explicit ServerAsyncReader(ServerContext* ctx)
: call_(nullptr, nullptr, nullptr), ctx_(ctx) {}
void SendInitialMetadata(void* tag) override {
GPR_CODEGEN_ASSERT(!ctx_->sent_initial_metadata_);
meta_ops_.set_output_tag(tag);
meta_ops_.SendInitialMetadata(ctx_->initial_metadata_,
ctx_->initial_metadata_flags());
if (ctx_->compression_level_set()) {
meta_ops_.set_compression_level(ctx_->compression_level());
}
ctx_->sent_initial_metadata_ = true;
call_.PerformOps(&meta_ops_);
}
void Read(R* msg, void* tag) override {
read_ops_.set_output_tag(tag);
read_ops_.RecvMessage(msg);
call_.PerformOps(&read_ops_);
}
void Finish(const W& msg, const Status& status, void* tag) override {
finish_ops_.set_output_tag(tag);
if (!ctx_->sent_initial_metadata_) {
finish_ops_.SendInitialMetadata(ctx_->initial_metadata_,
ctx_->initial_metadata_flags());
if (ctx_->compression_level_set()) {
finish_ops_.set_compression_level(ctx_->compression_level());
}
ctx_->sent_initial_metadata_ = true;
}
// The response is dropped if the status is not OK.
if (status.ok()) {
finish_ops_.ServerSendStatus(ctx_->trailing_metadata_,
finish_ops_.SendMessage(msg));
} else {
finish_ops_.ServerSendStatus(ctx_->trailing_metadata_, status);
}
call_.PerformOps(&finish_ops_);
}
void FinishWithError(const Status& status, void* tag) override {
GPR_CODEGEN_ASSERT(!status.ok());
finish_ops_.set_output_tag(tag);
if (!ctx_->sent_initial_metadata_) {
finish_ops_.SendInitialMetadata(ctx_->initial_metadata_,
ctx_->initial_metadata_flags());
if (ctx_->compression_level_set()) {
finish_ops_.set_compression_level(ctx_->compression_level());
}
ctx_->sent_initial_metadata_ = true;
}
finish_ops_.ServerSendStatus(ctx_->trailing_metadata_, status);
call_.PerformOps(&finish_ops_);
}
private:
void BindCall(Call* call) override { call_ = *call; }
Call call_;
ServerContext* ctx_;
CallOpSet<CallOpSendInitialMetadata> meta_ops_;
CallOpSet<CallOpRecvMessage<R>> read_ops_;
CallOpSet<CallOpSendInitialMetadata, CallOpServerSendStatus> finish_ops_;
};
template <class W>
class ServerAsyncWriterInterface : public ServerAsyncStreamingInterface,
public AsyncWriterInterface<W> {
public:
virtual void Finish(const Status& status, void* tag) = 0;
/// Request the writing of \a msg and coalesce it with trailing metadata which
/// contains \a status, using WriteOptions options with identifying tag \a
/// tag.
///
/// WriteAndFinish is equivalent of performing WriteLast and Finish in a
/// single step.
///
/// \param[in] msg The message to be written.
/// \param[in] options The WriteOptions to be used to write this message.
/// \param[in] status The Status that server returns to client.
/// \param[in] tag The tag identifying the operation.
virtual void WriteAndFinish(const W& msg, WriteOptions options,
const Status& status, void* tag) = 0;
};
template <class W>
class ServerAsyncWriter final : public ServerAsyncWriterInterface<W> {
public:
explicit ServerAsyncWriter(ServerContext* ctx)
: call_(nullptr, nullptr, nullptr), ctx_(ctx) {}
void SendInitialMetadata(void* tag) override {
GPR_CODEGEN_ASSERT(!ctx_->sent_initial_metadata_);
meta_ops_.set_output_tag(tag);
meta_ops_.SendInitialMetadata(ctx_->initial_metadata_,
ctx_->initial_metadata_flags());
if (ctx_->compression_level_set()) {
meta_ops_.set_compression_level(ctx_->compression_level());
}
ctx_->sent_initial_metadata_ = true;
call_.PerformOps(&meta_ops_);
}
void EnsureInitialMetadataSent(CallOpSetInterface* ops) {
if (!ctx_->sent_initial_metadata_) {
ops.SendInitialMetadata(ctx_->initial_metadata_,
ctx_->initial_metadata_flags());
if (ctx_->compression_level_set()) {
ops.set_compression_level(ctx_->compression_level());
}
ctx_->sent_initial_metadata_ = true;
}
}
void Write(const W& msg, void* tag) override {
write_ops_.set_output_tag(tag);
EnsureInitialMetadataSent(&write_ops_);
// TODO(ctiller): don't assert
GPR_CODEGEN_ASSERT(write_ops_.SendMessage(msg).ok());
call_.PerformOps(&write_ops_);
}
void Write(const W& msg, WriteOptions options, void* tag) override {
write_ops_.set_output_tag(tag);
if (options.is_last_message()) {
options.set_buffer_hint();
}
EnsureInitialMetadataSent(&write_ops_);
// TODO(ctiller): don't assert
GPR_CODEGEN_ASSERT(write_ops_.SendMessage(msg, options).ok());
call_.PerformOps(&write_ops_);
}
void WriteAndFinish(const W& msg, WriteOptions options, const Status& status,
void* tag) override {
write_ops_.set_output_tag(tag);
EnsureInitialMetadataSent(&write_ops_);
options.set_buffer_hint();
GPR_CODEGEN_ASSERT(write_ops_.SendMessage(msg, options).ok());
write_ops_.ServerSendStatus(ctx_->trailing_metadata_, status);
call_.PerformOps(&write_ops_);
}
void Finish(const Status& status, void* tag) override {
finish_ops_.set_output_tag(tag);
EnsureInitialMetadataSent(&finish_ops_);
finish_ops_.ServerSendStatus(ctx_->trailing_metadata_, status);
call_.PerformOps(&finish_ops_);
}
private:
void BindCall(Call* call) override { call_ = *call; }
Call call_;
ServerContext* ctx_;
CallOpSet<CallOpSendInitialMetadata> meta_ops_;
CallOpSet<CallOpSendInitialMetadata, CallOpSendMessage,
CallOpServerSendStatus>
write_ops_;
CallOpSet<CallOpSendInitialMetadata, CallOpServerSendStatus> finish_ops_;
};
/// Server-side interface for asynchronous bi-directional streaming.
template <class W, class R>
class ServerAsyncReaderWriterInterface : public ServerAsyncStreamingInterface,
public AsyncWriterInterface<W>,
public AsyncReaderInterface<R> {
public:
virtual void Finish(const Status& status, void* tag) = 0;
/// Request the writing of \a msg and coalesce it with trailing metadata which
/// contains \a status, using WriteOptions options with identifying tag \a
/// tag.
///
/// WriteAndFinish is equivalent of performing WriteLast and Finish in a
/// single step.
///
/// \param[in] msg The message to be written.
/// \param[in] options The WriteOptions to be used to write this message.
/// \param[in] status The Status that server returns to client.
/// \param[in] tag The tag identifying the operation.
virtual void WriteAndFinish(const W& msg, WriteOptions options,
const Status& status, void* tag) = 0;
};
template <class W, class R>
class ServerAsyncReaderWriter final
: public ServerAsyncReaderWriterInterface<W, R> {
public:
explicit ServerAsyncReaderWriter(ServerContext* ctx)
: call_(nullptr, nullptr, nullptr), ctx_(ctx) {}
void SendInitialMetadata(void* tag) override {
GPR_CODEGEN_ASSERT(!ctx_->sent_initial_metadata_);
meta_ops_.set_output_tag(tag);
meta_ops_.SendInitialMetadata(ctx_->initial_metadata_,
ctx_->initial_metadata_flags());
if (ctx_->compression_level_set()) {
meta_ops_.set_compression_level(ctx_->compression_level());
}
ctx_->sent_initial_metadata_ = true;
call_.PerformOps(&meta_ops_);
}
void EnsureInitialMetadataSent(CallOpSetInterface* ops) {
if (!ctx_->sent_initial_metadata_) {
ops.SendInitialMetadata(ctx_->initial_metadata_,
ctx_->initial_metadata_flags());
if (ctx_->compression_level_set()) {
ops.set_compression_level(ctx_->compression_level());
}
ctx_->sent_initial_metadata_ = true;
}
}
void Read(R* msg, void* tag) override {
read_ops_.set_output_tag(tag);
read_ops_.RecvMessage(msg);
call_.PerformOps(&read_ops_);
}
void Write(const W& msg, void* tag) override {
write_ops_.set_output_tag(tag);
EnsureInitialMetadataSent(&write_ops_);
// TODO(ctiller): don't assert
GPR_CODEGEN_ASSERT(write_ops_.SendMessage(msg).ok());
call_.PerformOps(&write_ops_);
}
void Write(const W& msg, WriteOptions options, void* tag) override {
write_ops_.set_output_tag(tag);
if (options.is_last_message()) {
options.set_buffer_hint();
}
EnsureInitialMetadataSent(&write_ops_);
GPR_CODEGEN_ASSERT(write_ops_.SendMessage(msg, options).ok());
call_.PerformOps(&write_ops_);
}
void WriteAndFinish(const W& msg, WriteOptions options, const Status& status,
void* tag) override {
write_ops_.set_output_tag(tag);
EnsureInitialMetadataSent(&write_ops_);
options.set_buffer_hint();
GPR_CODEGEN_ASSERT(write_ops_.SendMessage(msg, options).ok());
write_ops_.ServerSendStatus(ctx_->trailing_metadata_, status);
call_.PerformOps(&write_ops_);
}
void Finish(const Status& status, void* tag) override {
finish_ops_.set_output_tag(tag);
EnsureInitialMetadataSent(&finish_ops_);
finish_ops_.ServerSendStatus(ctx_->trailing_metadata_, status);
call_.PerformOps(&finish_ops_);
}
private:
friend class ::grpc::Server;
void BindCall(Call* call) override { call_ = *call; }
Call call_;
ServerContext* ctx_;
CallOpSet<CallOpSendInitialMetadata> meta_ops_;
CallOpSet<CallOpRecvMessage<R>> read_ops_;
CallOpSet<CallOpSendInitialMetadata, CallOpSendMessage,
CallOpServerSendStatus>
write_ops_;
CallOpSet<CallOpSendInitialMetadata, CallOpServerSendStatus> finish_ops_;
};
} // namespace grpc
#endif // GRPCXX_IMPL_CODEGEN_ASYNC_STREAM_H