third_party/grpc/src/cpp/server/server_context.cc - bazel - Git at Google

 /*
  *
  * Copyright 2015 gRPC authors.
  *
  * Licensed under the Apache License, Version 2.0 (the "License");
  * you may not use this file except in compliance with the License.
  * You may obtain a copy of the License at
  *
  *     http://www.apache.org/licenses/LICENSE-2.0
  *
  * Unless required by applicable law or agreed to in writing, software
  * distributed under the License is distributed on an "AS IS" BASIS,
  * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
  * See the License for the specific language governing permissions and
  * limitations under the License.
  *
  */

 #include <grpcpp/server_context.h>
 #include <grpcpp/support/server_callback.h>

 #include <algorithm>
 #include <mutex>
 #include <utility>

 #include <grpc/compression.h>
 #include <grpc/grpc.h>
 #include <grpc/load_reporting.h>
 #include <grpc/support/alloc.h>
 #include <grpc/support/log.h>
 #include <grpcpp/completion_queue.h>
 #include <grpcpp/impl/call.h>
 #include <grpcpp/support/time.h>

 #include "src/core/lib/surface/call.h"

 namespace grpc {

 // CompletionOp

 class ServerContext::CompletionOp final : public internal::CallOpSetInterface {
  public:
   // initial refs: one in the server context, one in the cq
   // must ref the call before calling constructor and after deleting this
   CompletionOp(internal::Call* call, internal::ServerReactor* reactor)
       : call_(*call),
         reactor_(reactor),
         has_tag_(false),
         tag_(nullptr),
         core_cq_tag_(this),
         refs_(2),
         finalized_(false),
         cancelled_(0),
         done_intercepting_(false) {}

   // CompletionOp isn't copyable or movable
   CompletionOp(const CompletionOp&) = delete;
   CompletionOp& operator=(const CompletionOp&) = delete;
   CompletionOp(CompletionOp&&) = delete;
   CompletionOp& operator=(CompletionOp&&) = delete;

   ~CompletionOp() {
     if (call_.server_rpc_info()) {
       call_.server_rpc_info()->Unref();
     }
   }

   void FillOps(internal::Call* call) override;

   // This should always be arena allocated in the call, so override delete.
   // But this class is not trivially destructible, so must actually call delete
   // before allowing the arena to be freed
   static void operator delete(void* ptr, std::size_t size) {
     assert(size == sizeof(CompletionOp));
   }

   // 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); }

   bool FinalizeResult(void** tag, bool* status) override;

   bool CheckCancelled(CompletionQueue* cq) {
     cq->TryPluck(this);
     return CheckCancelledNoPluck();
   }
   bool CheckCancelledAsync() { return CheckCancelledNoPluck(); }

   void set_tag(void* tag) {
     has_tag_ = true;
     tag_ = tag;
   }

   void set_core_cq_tag(void* core_cq_tag) { core_cq_tag_ = core_cq_tag; }

   void* core_cq_tag() override { return core_cq_tag_; }

   void Unref();

   // 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 {
     /* Servers don't allow hijacking */
     GPR_CODEGEN_ASSERT(false);
   }

   /* Should be called after interceptors are done running */
   void ContinueFillOpsAfterInterception() override {}

   /* Should be called after interceptors are done running on the finalize result
    * path */
   void ContinueFinalizeResultAfterInterception() override {
     done_intercepting_ = true;
     if (!has_tag_) {
       /* We don't have a tag to return. */
       std::unique_lock<std::mutex> lock(mu_);
       if (--refs_ == 0) {
         lock.unlock();
         grpc_call* call = call_.call();
         delete this;
         grpc_call_unref(call);
       }
       return;
     }
     /* Start a dummy op so that we can return the tag */
     GPR_CODEGEN_ASSERT(
         GRPC_CALL_OK ==
         grpc_call_start_batch(call_.call(), nullptr, 0, core_cq_tag_, nullptr));
   }

  private:
   bool CheckCancelledNoPluck() {
     std::lock_guard<std::mutex> g(mu_);
     return finalized_ ? (cancelled_ != 0) : false;
   }

   internal::Call call_;
   internal::ServerReactor* reactor_;
   bool has_tag_;
   void* tag_;
   void* core_cq_tag_;
   std::mutex mu_;
   int refs_;
   bool finalized_;
   int cancelled_;  // This is an int (not bool) because it is passed to core
   bool done_intercepting_;
   internal::InterceptorBatchMethodsImpl interceptor_methods_;
 };

 void ServerContext::CompletionOp::Unref() {
   std::unique_lock<std::mutex> lock(mu_);
   if (--refs_ == 0) {
     lock.unlock();
     grpc_call* call = call_.call();
     delete this;
     grpc_call_unref(call);
   }
 }

 void ServerContext::CompletionOp::FillOps(internal::Call* call) {
   grpc_op ops;
   ops.op = GRPC_OP_RECV_CLOSE_ON_SERVER;
   ops.data.recv_close_on_server.cancelled = &cancelled_;
   ops.flags = 0;
   ops.reserved = nullptr;
   interceptor_methods_.SetCall(&call_);
   interceptor_methods_.SetReverse();
   interceptor_methods_.SetCallOpSetInterface(this);
   GPR_ASSERT(GRPC_CALL_OK == grpc_call_start_batch(call->call(), &ops, 1,
                                                    core_cq_tag_, nullptr));
   /* No interceptors to run here */
 }

 bool ServerContext::CompletionOp::FinalizeResult(void** tag, bool* status) {
   bool ret = false;
   std::unique_lock<std::mutex> lock(mu_);
   if (done_intercepting_) {
     /* We are done intercepting. */
     if (has_tag_) {
       *tag = tag_;
       ret = true;
     }
     if (--refs_ == 0) {
       lock.unlock();
       grpc_call* call = call_.call();
       delete this;
       grpc_call_unref(call);
     }
     return ret;
   }
   finalized_ = true;

   // If for some reason the incoming status is false, mark that as a
   // cancellation.
   // TODO(vjpai): does this ever happen?
   if (!*status) {
     cancelled_ = 1;
   }

   if (cancelled_ && (reactor_ != nullptr)) {
     reactor_->OnCancel();
   }
   /* Release the lock since we are going to be running through interceptors now
    */
   lock.unlock();
   /* Add interception point and run through interceptors */
   interceptor_methods_.AddInterceptionHookPoint(
       experimental::InterceptionHookPoints::POST_RECV_CLOSE);
   if (interceptor_methods_.RunInterceptors()) {
     /* No interceptors were run */
     if (has_tag_) {
       *tag = tag_;
       ret = true;
     }
     lock.lock();
     if (--refs_ == 0) {
       lock.unlock();
       grpc_call* call = call_.call();
       delete this;
       grpc_call_unref(call);
     }
     return ret;
   }
   /* There are interceptors to be run. Return false for now */
   return false;
 }

 // ServerContext body

 ServerContext::ServerContext() { Setup(gpr_inf_future(GPR_CLOCK_REALTIME)); }

 ServerContext::ServerContext(gpr_timespec deadline, grpc_metadata_array* arr) {
   Setup(deadline);
   std::swap(*client_metadata_.arr(), *arr);
 }

 void ServerContext::Setup(gpr_timespec deadline) {
   completion_op_ = nullptr;
   has_notify_when_done_tag_ = false;
   async_notify_when_done_tag_ = nullptr;
   deadline_ = deadline;
   call_ = nullptr;
   cq_ = nullptr;
   sent_initial_metadata_ = false;
   compression_level_set_ = false;
   has_pending_ops_ = false;
   rpc_info_ = nullptr;
 }

 void ServerContext::BindDeadlineAndMetadata(gpr_timespec deadline,
                                             grpc_metadata_array* arr) {
   deadline_ = deadline;
   std::swap(*client_metadata_.arr(), *arr);
 }

 ServerContext::~ServerContext() { Clear(); }

 void ServerContext::Clear() {
   auth_context_.reset();
   initial_metadata_.clear();
   trailing_metadata_.clear();
   client_metadata_.Reset();
   if (completion_op_) {
     completion_op_->Unref();
     completion_op_ = nullptr;
     completion_tag_.Clear();
   }
   if (rpc_info_) {
     rpc_info_->Unref();
     rpc_info_ = nullptr;
   }
   if (call_) {
     auto* call = call_;
     call_ = nullptr;
     grpc_call_unref(call);
   }
 }

 void ServerContext::BeginCompletionOp(internal::Call* call,
                                       std::function<void(bool)> callback,
                                       internal::ServerReactor* reactor) {
   GPR_ASSERT(!completion_op_);
   if (rpc_info_) {
     rpc_info_->Ref();
   }
   grpc_call_ref(call->call());
   completion_op_ =
       new (grpc_call_arena_alloc(call->call(), sizeof(CompletionOp)))
           CompletionOp(call, reactor);
   if (callback != nullptr) {
     completion_tag_.Set(call->call(), std::move(callback), completion_op_);
     completion_op_->set_core_cq_tag(&completion_tag_);
     completion_op_->set_tag(completion_op_);
   } else if (has_notify_when_done_tag_) {
     completion_op_->set_tag(async_notify_when_done_tag_);
   }
   call->PerformOps(completion_op_);
 }

 internal::CompletionQueueTag* ServerContext::GetCompletionOpTag() {
   return static_cast<internal::CompletionQueueTag*>(completion_op_);
 }

 void ServerContext::AddInitialMetadata(const grpc::string& key,
                                        const grpc::string& value) {
   initial_metadata_.insert(std::make_pair(key, value));
 }

 void ServerContext::AddTrailingMetadata(const grpc::string& key,
                                         const grpc::string& value) {
   trailing_metadata_.insert(std::make_pair(key, value));
 }

 void ServerContext::TryCancel() const {
   internal::CancelInterceptorBatchMethods cancel_methods;
   if (rpc_info_) {
     for (size_t i = 0; i < rpc_info_->interceptors_.size(); i++) {
       rpc_info_->RunInterceptor(&cancel_methods, i);
     }
   }
   grpc_call_error err = grpc_call_cancel_with_status(
       call_, GRPC_STATUS_CANCELLED, "Cancelled on the server side", nullptr);
   if (err != GRPC_CALL_OK) {
     gpr_log(GPR_ERROR, "TryCancel failed with: %d", err);
   }
 }

 bool ServerContext::IsCancelled() const {
   if (completion_tag_) {
     // When using callback API, this result is always valid.
     return completion_op_->CheckCancelledAsync();
   } else if (has_notify_when_done_tag_) {
     // When using async API, the result is only valid
     // if the tag has already been delivered at the completion queue
     return completion_op_ && completion_op_->CheckCancelledAsync();
   } else {
     // when using sync API, the result is always valid
     return completion_op_ && completion_op_->CheckCancelled(cq_);
   }
 }

 void ServerContext::set_compression_algorithm(
     grpc_compression_algorithm algorithm) {
   compression_algorithm_ = algorithm;
   const char* algorithm_name = nullptr;
   if (!grpc_compression_algorithm_name(algorithm, &algorithm_name)) {
     gpr_log(GPR_ERROR, "Name for compression algorithm '%d' unknown.",
             algorithm);
     abort();
   }
   GPR_ASSERT(algorithm_name != nullptr);
   AddInitialMetadata(GRPC_COMPRESSION_REQUEST_ALGORITHM_MD_KEY, algorithm_name);
 }

 grpc::string ServerContext::peer() const {
   grpc::string peer;
   if (call_) {
     char* c_peer = grpc_call_get_peer(call_);
     peer = c_peer;
     gpr_free(c_peer);
   }
   return peer;
 }

 const struct census_context* ServerContext::census_context() const {
   return grpc_census_call_get_context(call_);
 }

 void ServerContext::SetLoadReportingCosts(
     const std::vector<grpc::string>& cost_data) {
   if (call_ == nullptr) return;
   for (const auto& cost_datum : cost_data) {
     AddTrailingMetadata(GRPC_LB_COST_MD_KEY, cost_datum);
   }
 }

 }  // namespace grpc
	/*
	*
	* Copyright 2015 gRPC authors.
	*
	* Licensed under the Apache License, Version 2.0 (the "License");
	* you may not use this file except in compliance with the License.
	* You may obtain a copy of the License at
	*
	* http://www.apache.org/licenses/LICENSE-2.0
	*
	* Unless required by applicable law or agreed to in writing, software
	* distributed under the License is distributed on an "AS IS" BASIS,
	* WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
	* See the License for the specific language governing permissions and
	* limitations under the License.
	*
	*/

	#include <grpcpp/server_context.h>
	#include <grpcpp/support/server_callback.h>

	#include <algorithm>
	#include <mutex>
	#include <utility>

	#include <grpc/compression.h>
	#include <grpc/grpc.h>
	#include <grpc/load_reporting.h>
	#include <grpc/support/alloc.h>
	#include <grpc/support/log.h>
	#include <grpcpp/completion_queue.h>
	#include <grpcpp/impl/call.h>
	#include <grpcpp/support/time.h>

	#include "src/core/lib/surface/call.h"

	namespace grpc {

	// CompletionOp

	class ServerContext::CompletionOp final : public internal::CallOpSetInterface {
	public:
	// initial refs: one in the server context, one in the cq
	// must ref the call before calling constructor and after deleting this
	CompletionOp(internal::Call* call, internal::ServerReactor* reactor)
	: call_(*call),
	reactor_(reactor),
	has_tag_(false),
	tag_(nullptr),
	core_cq_tag_(this),
	refs_(2),
	finalized_(false),
	cancelled_(0),
	done_intercepting_(false) {}

	// CompletionOp isn't copyable or movable
	CompletionOp(const CompletionOp&) = delete;
	CompletionOp& operator=(const CompletionOp&) = delete;
	CompletionOp(CompletionOp&&) = delete;
	CompletionOp& operator=(CompletionOp&&) = delete;

	~CompletionOp() {
	if (call_.server_rpc_info()) {
	call_.server_rpc_info()->Unref();
	}
	}

	void FillOps(internal::Call* call) override;

	// This should always be arena allocated in the call, so override delete.
	// But this class is not trivially destructible, so must actually call delete
	// before allowing the arena to be freed
	static void operator delete(void* ptr, std::size_t size) {
	assert(size == sizeof(CompletionOp));
	}

	// 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); }

	bool FinalizeResult(void** tag, bool* status) override;

	bool CheckCancelled(CompletionQueue* cq) {
	cq->TryPluck(this);
	return CheckCancelledNoPluck();
	}
	bool CheckCancelledAsync() { return CheckCancelledNoPluck(); }

	void set_tag(void* tag) {
	has_tag_ = true;
	tag_ = tag;
	}

	void set_core_cq_tag(void* core_cq_tag) { core_cq_tag_ = core_cq_tag; }

	void* core_cq_tag() override { return core_cq_tag_; }

	void Unref();

	// 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 {
	/* Servers don't allow hijacking */
	GPR_CODEGEN_ASSERT(false);
	}

	/* Should be called after interceptors are done running */
	void ContinueFillOpsAfterInterception() override {}

	/* Should be called after interceptors are done running on the finalize result
	* path */
	void ContinueFinalizeResultAfterInterception() override {
	done_intercepting_ = true;
	if (!has_tag_) {
	/* We don't have a tag to return. */
	std::unique_lock<std::mutex> lock(mu_);
	if (--refs_ == 0) {
	lock.unlock();
	grpc_call* call = call_.call();
	delete this;
	grpc_call_unref(call);
	}
	return;
	}
	/* Start a dummy op so that we can return the tag */
	GPR_CODEGEN_ASSERT(
	GRPC_CALL_OK ==
	grpc_call_start_batch(call_.call(), nullptr, 0, core_cq_tag_, nullptr));
	}

	private:
	bool CheckCancelledNoPluck() {
	std::lock_guard<std::mutex> g(mu_);
	return finalized_ ? (cancelled_ != 0) : false;
	}

	internal::Call call_;
	internal::ServerReactor* reactor_;
	bool has_tag_;
	void* tag_;
	void* core_cq_tag_;
	std::mutex mu_;
	int refs_;
	bool finalized_;
	int cancelled_; // This is an int (not bool) because it is passed to core
	bool done_intercepting_;
	internal::InterceptorBatchMethodsImpl interceptor_methods_;
	};

	void ServerContext::CompletionOp::Unref() {
	std::unique_lock<std::mutex> lock(mu_);
	if (--refs_ == 0) {
	lock.unlock();
	grpc_call* call = call_.call();
	delete this;
	grpc_call_unref(call);
	}
	}

	void ServerContext::CompletionOp::FillOps(internal::Call* call) {
	grpc_op ops;
	ops.op = GRPC_OP_RECV_CLOSE_ON_SERVER;
	ops.data.recv_close_on_server.cancelled = &cancelled_;
	ops.flags = 0;
	ops.reserved = nullptr;
	interceptor_methods_.SetCall(&call_);
	interceptor_methods_.SetReverse();
	interceptor_methods_.SetCallOpSetInterface(this);
	GPR_ASSERT(GRPC_CALL_OK == grpc_call_start_batch(call->call(), &ops, 1,
	core_cq_tag_, nullptr));
	/* No interceptors to run here */
	}

	bool ServerContext::CompletionOp::FinalizeResult(void** tag, bool* status) {
	bool ret = false;
	std::unique_lock<std::mutex> lock(mu_);
	if (done_intercepting_) {
	/* We are done intercepting. */
	if (has_tag_) {
	*tag = tag_;
	ret = true;
	}
	if (--refs_ == 0) {
	lock.unlock();
	grpc_call* call = call_.call();
	delete this;
	grpc_call_unref(call);
	}
	return ret;
	}
	finalized_ = true;

	// If for some reason the incoming status is false, mark that as a
	// cancellation.
	// TODO(vjpai): does this ever happen?
	if (!*status) {
	cancelled_ = 1;
	}

	if (cancelled_ && (reactor_ != nullptr)) {
	reactor_->OnCancel();
	}
	/* Release the lock since we are going to be running through interceptors now
	*/
	lock.unlock();
	/* Add interception point and run through interceptors */
	interceptor_methods_.AddInterceptionHookPoint(
	experimental::InterceptionHookPoints::POST_RECV_CLOSE);
	if (interceptor_methods_.RunInterceptors()) {
	/* No interceptors were run */
	if (has_tag_) {
	*tag = tag_;
	ret = true;
	}
	lock.lock();
	if (--refs_ == 0) {
	lock.unlock();
	grpc_call* call = call_.call();
	delete this;
	grpc_call_unref(call);
	}
	return ret;
	}
	/* There are interceptors to be run. Return false for now */
	return false;
	}

	// ServerContext body

	ServerContext::ServerContext() { Setup(gpr_inf_future(GPR_CLOCK_REALTIME)); }

	ServerContext::ServerContext(gpr_timespec deadline, grpc_metadata_array* arr) {
	Setup(deadline);
	std::swap(client_metadata_.arr(), arr);
	}

	void ServerContext::Setup(gpr_timespec deadline) {
	completion_op_ = nullptr;
	has_notify_when_done_tag_ = false;
	async_notify_when_done_tag_ = nullptr;
	deadline_ = deadline;
	call_ = nullptr;
	cq_ = nullptr;
	sent_initial_metadata_ = false;
	compression_level_set_ = false;
	has_pending_ops_ = false;
	rpc_info_ = nullptr;
	}

	void ServerContext::BindDeadlineAndMetadata(gpr_timespec deadline,
	grpc_metadata_array* arr) {
	deadline_ = deadline;
	std::swap(client_metadata_.arr(), arr);
	}

	ServerContext::~ServerContext() { Clear(); }

	void ServerContext::Clear() {
	auth_context_.reset();
	initial_metadata_.clear();
	trailing_metadata_.clear();
	client_metadata_.Reset();
	if (completion_op_) {
	completion_op_->Unref();
	completion_op_ = nullptr;
	completion_tag_.Clear();
	}
	if (rpc_info_) {
	rpc_info_->Unref();
	rpc_info_ = nullptr;
	}
	if (call_) {
	auto* call = call_;
	call_ = nullptr;
	grpc_call_unref(call);
	}
	}

	void ServerContext::BeginCompletionOp(internal::Call* call,
	std::function<void(bool)> callback,
	internal::ServerReactor* reactor) {
	GPR_ASSERT(!completion_op_);
	if (rpc_info_) {
	rpc_info_->Ref();
	}
	grpc_call_ref(call->call());
	completion_op_ =
	new (grpc_call_arena_alloc(call->call(), sizeof(CompletionOp)))
	CompletionOp(call, reactor);
	if (callback != nullptr) {
	completion_tag_.Set(call->call(), std::move(callback), completion_op_);
	completion_op_->set_core_cq_tag(&completion_tag_);
	completion_op_->set_tag(completion_op_);
	} else if (has_notify_when_done_tag_) {
	completion_op_->set_tag(async_notify_when_done_tag_);
	}
	call->PerformOps(completion_op_);
	}

	internal::CompletionQueueTag* ServerContext::GetCompletionOpTag() {
	return static_cast<internal::CompletionQueueTag*>(completion_op_);
	}

	void ServerContext::AddInitialMetadata(const grpc::string& key,
	const grpc::string& value) {
	initial_metadata_.insert(std::make_pair(key, value));
	}

	void ServerContext::AddTrailingMetadata(const grpc::string& key,
	const grpc::string& value) {
	trailing_metadata_.insert(std::make_pair(key, value));
	}

	void ServerContext::TryCancel() const {
	internal::CancelInterceptorBatchMethods cancel_methods;
	if (rpc_info_) {
	for (size_t i = 0; i < rpc_info_->interceptors_.size(); i++) {
	rpc_info_->RunInterceptor(&cancel_methods, i);
	}
	}
	grpc_call_error err = grpc_call_cancel_with_status(
	call_, GRPC_STATUS_CANCELLED, "Cancelled on the server side", nullptr);
	if (err != GRPC_CALL_OK) {
	gpr_log(GPR_ERROR, "TryCancel failed with: %d", err);
	}
	}

	bool ServerContext::IsCancelled() const {
	if (completion_tag_) {
	// When using callback API, this result is always valid.
	return completion_op_->CheckCancelledAsync();
	} else if (has_notify_when_done_tag_) {
	// When using async API, the result is only valid
	// if the tag has already been delivered at the completion queue
	return completion_op_ && completion_op_->CheckCancelledAsync();
	} else {
	// when using sync API, the result is always valid
	return completion_op_ && completion_op_->CheckCancelled(cq_);
	}
	}

	void ServerContext::set_compression_algorithm(
	grpc_compression_algorithm algorithm) {
	compression_algorithm_ = algorithm;
	const char* algorithm_name = nullptr;
	if (!grpc_compression_algorithm_name(algorithm, &algorithm_name)) {
	gpr_log(GPR_ERROR, "Name for compression algorithm '%d' unknown.",
	algorithm);
	abort();
	}
	GPR_ASSERT(algorithm_name != nullptr);
	AddInitialMetadata(GRPC_COMPRESSION_REQUEST_ALGORITHM_MD_KEY, algorithm_name);
	}

	grpc::string ServerContext::peer() const {
	grpc::string peer;
	if (call_) {
	char* c_peer = grpc_call_get_peer(call_);
	peer = c_peer;
	gpr_free(c_peer);
	}
	return peer;
	}

	const struct census_context* ServerContext::census_context() const {
	return grpc_census_call_get_context(call_);
	}

	void ServerContext::SetLoadReportingCosts(
	const std::vector<grpc::string>& cost_data) {
	if (call_ == nullptr) return;
	for (const auto& cost_datum : cost_data) {
	AddTrailingMetadata(GRPC_LB_COST_MD_KEY, cost_datum);
	}
	}

	} // namespace grpc