third_party/perfetto/src/tracing/ipc/service/consumer_ipc_service.cc - cobalt - Git at Google

 /*
  * Copyright (C) 2017 The Android Open Source Project
  *
  * 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 "src/tracing/ipc/service/consumer_ipc_service.h"

 #include <cinttypes>

 #include "perfetto/base/logging.h"
 #include "perfetto/base/task_runner.h"
 #include "perfetto/ext/base/scoped_file.h"
 #include "perfetto/ext/ipc/basic_types.h"
 #include "perfetto/ext/ipc/host.h"
 #include "perfetto/ext/tracing/core/shared_memory_abi.h"
 #include "perfetto/ext/tracing/core/slice.h"
 #include "perfetto/ext/tracing/core/trace_packet.h"
 #include "perfetto/ext/tracing/core/trace_stats.h"
 #include "perfetto/ext/tracing/core/tracing_service.h"
 #include "perfetto/tracing/core/trace_config.h"
 #include "perfetto/tracing/core/tracing_service_capabilities.h"
 #include "perfetto/tracing/core/tracing_service_state.h"

 namespace perfetto {

 ConsumerIPCService::ConsumerIPCService(TracingService* core_service)
     : core_service_(core_service), weak_ptr_factory_(this) {}

 ConsumerIPCService::~ConsumerIPCService() = default;

 ConsumerIPCService::RemoteConsumer*
 ConsumerIPCService::GetConsumerForCurrentRequest() {
   const ipc::ClientID ipc_client_id = ipc::Service::client_info().client_id();
   const uid_t uid = ipc::Service::client_info().uid();
   PERFETTO_CHECK(ipc_client_id);
   auto it = consumers_.find(ipc_client_id);
   if (it == consumers_.end()) {
     auto* remote_consumer = new RemoteConsumer();
     consumers_[ipc_client_id].reset(remote_consumer);
     remote_consumer->service_endpoint =
         core_service_->ConnectConsumer(remote_consumer, uid);
     return remote_consumer;
   }
   return it->second.get();
 }

 // Called by the IPC layer.
 void ConsumerIPCService::OnClientDisconnected() {
   ipc::ClientID client_id = ipc::Service::client_info().client_id();
   consumers_.erase(client_id);
 }

 // Called by the IPC layer.
 void ConsumerIPCService::EnableTracing(
     const protos::gen::EnableTracingRequest& req,
     DeferredEnableTracingResponse resp) {
   RemoteConsumer* remote_consumer = GetConsumerForCurrentRequest();
   if (req.attach_notification_only()) {
     remote_consumer->enable_tracing_response = std::move(resp);
     return;
   }
   const TraceConfig& trace_config = req.trace_config();
   base::ScopedFile fd;
   if (trace_config.write_into_file() && trace_config.output_path().empty())
     fd = ipc::Service::TakeReceivedFD();
   remote_consumer->service_endpoint->EnableTracing(trace_config, std::move(fd));
   remote_consumer->enable_tracing_response = std::move(resp);
 }

 // Called by the IPC layer.
 void ConsumerIPCService::StartTracing(const protos::gen::StartTracingRequest&,
                                       DeferredStartTracingResponse resp) {
   RemoteConsumer* remote_consumer = GetConsumerForCurrentRequest();
   remote_consumer->service_endpoint->StartTracing();
   resp.Resolve(ipc::AsyncResult<protos::gen::StartTracingResponse>::Create());
 }

 // Called by the IPC layer.
 void ConsumerIPCService::ChangeTraceConfig(
     const protos::gen::ChangeTraceConfigRequest& req,
     DeferredChangeTraceConfigResponse resp) {
   RemoteConsumer* remote_consumer = GetConsumerForCurrentRequest();
   remote_consumer->service_endpoint->ChangeTraceConfig(req.trace_config());
   resp.Resolve(
       ipc::AsyncResult<protos::gen::ChangeTraceConfigResponse>::Create());
 }

 // Called by the IPC layer.
 void ConsumerIPCService::DisableTracing(
     const protos::gen::DisableTracingRequest&,
     DeferredDisableTracingResponse resp) {
   GetConsumerForCurrentRequest()->service_endpoint->DisableTracing();
   resp.Resolve(ipc::AsyncResult<protos::gen::DisableTracingResponse>::Create());
 }

 // Called by the IPC layer.
 void ConsumerIPCService::ReadBuffers(const protos::gen::ReadBuffersRequest&,
                                      DeferredReadBuffersResponse resp) {
   RemoteConsumer* remote_consumer = GetConsumerForCurrentRequest();
   remote_consumer->read_buffers_response = std::move(resp);
   remote_consumer->service_endpoint->ReadBuffers();
 }

 // Called by the IPC layer.
 void ConsumerIPCService::FreeBuffers(const protos::gen::FreeBuffersRequest&,
                                      DeferredFreeBuffersResponse resp) {
   GetConsumerForCurrentRequest()->service_endpoint->FreeBuffers();
   resp.Resolve(ipc::AsyncResult<protos::gen::FreeBuffersResponse>::Create());
 }

 // Called by the IPC layer.
 void ConsumerIPCService::Flush(const protos::gen::FlushRequest& req,
                                DeferredFlushResponse resp) {
   auto it = pending_flush_responses_.insert(pending_flush_responses_.end(),
                                             std::move(resp));
   auto weak_this = weak_ptr_factory_.GetWeakPtr();
   auto callback = [weak_this, it](bool success) {
     if (weak_this)
       weak_this->OnFlushCallback(success, std::move(it));
   };
   GetConsumerForCurrentRequest()->service_endpoint->Flush(req.timeout_ms(),
                                                           std::move(callback));
 }

 // Called by the IPC layer.
 void ConsumerIPCService::Detach(const protos::gen::DetachRequest& req,
                                 DeferredDetachResponse resp) {
   // OnDetach() will resolve the |detach_response|.
   RemoteConsumer* remote_consumer = GetConsumerForCurrentRequest();
   remote_consumer->detach_response = std::move(resp);
   remote_consumer->service_endpoint->Detach(req.key());
 }

 // Called by the IPC layer.
 void ConsumerIPCService::Attach(const protos::gen::AttachRequest& req,
                                 DeferredAttachResponse resp) {
   // OnAttach() will resolve the |attach_response|.
   RemoteConsumer* remote_consumer = GetConsumerForCurrentRequest();
   remote_consumer->attach_response = std::move(resp);
   remote_consumer->service_endpoint->Attach(req.key());
 }

 // Called by the IPC layer.
 void ConsumerIPCService::GetTraceStats(const protos::gen::GetTraceStatsRequest&,
                                        DeferredGetTraceStatsResponse resp) {
   // OnTraceStats() will resolve the |get_trace_stats_response|.
   RemoteConsumer* remote_consumer = GetConsumerForCurrentRequest();
   remote_consumer->get_trace_stats_response = std::move(resp);
   remote_consumer->service_endpoint->GetTraceStats();
 }

 // Called by the IPC layer.
 void ConsumerIPCService::ObserveEvents(
     const protos::gen::ObserveEventsRequest& req,
     DeferredObserveEventsResponse resp) {
   RemoteConsumer* remote_consumer = GetConsumerForCurrentRequest();

   // If there's a prior stream, close it so that client can clean it up.
   remote_consumer->CloseObserveEventsResponseStream();

   remote_consumer->observe_events_response = std::move(resp);

   uint32_t events_mask = 0;
   for (const auto& type : req.events_to_observe()) {
     events_mask |= static_cast<uint32_t>(type);
   }
   remote_consumer->service_endpoint->ObserveEvents(events_mask);

   // If no events are to be observed, close the stream immediately so that the
   // client can clean up.
   if (events_mask == 0)
     remote_consumer->CloseObserveEventsResponseStream();
 }

 // Called by the IPC layer.
 void ConsumerIPCService::QueryServiceState(
     const protos::gen::QueryServiceStateRequest&,
     DeferredQueryServiceStateResponse resp) {
   RemoteConsumer* remote_consumer = GetConsumerForCurrentRequest();
   auto it = pending_query_service_responses_.insert(
       pending_query_service_responses_.end(), std::move(resp));
   auto weak_this = weak_ptr_factory_.GetWeakPtr();
   auto callback = [weak_this, it](bool success,
                                   const TracingServiceState& svc_state) {
     if (weak_this)
       weak_this->OnQueryServiceCallback(success, svc_state, std::move(it));
   };
   remote_consumer->service_endpoint->QueryServiceState(callback);
 }

 // Called by the service in response to service_endpoint->QueryServiceState().
 void ConsumerIPCService::OnQueryServiceCallback(
     bool success,
     const TracingServiceState& svc_state,
     PendingQuerySvcResponses::iterator pending_response_it) {
   DeferredQueryServiceStateResponse response(std::move(*pending_response_it));
   pending_query_service_responses_.erase(pending_response_it);
   if (!success) {
     response.Reject();
     return;
   }

   // The TracingServiceState object might be too big to fit into a single IPC
   // message because it contains the DataSourceDescriptor of each data source.
   // Here we split it in chunks to fit in the IPC limit, observing the
   // following rule: each chunk must be invididually a valid TracingServiceState
   // message; all the chunks concatenated together must form the original
   // message. This is to deal with the legacy API that was just sending one
   // whole message (failing in presence of too many data sources, b/153142114).
   // The message is split as follows: we take the whole TracingServiceState,
   // take out the data sources section (which is a top-level repeated field)
   // and re-add them one-by-one. If, in the process of appending, the IPC msg
   // size is reached, a new chunk is created. This assumes that the rest of
   // TracingServiceState fits in one IPC message and each DataSourceDescriptor
   // fits in the worst case in a dedicated message (which is true, because
   // otherwise the RegisterDataSource() which passes the descriptor in the first
   // place would fail).

   std::vector<uint8_t> chunked_reply;

   // Transmits the current chunk and starts a new one.
   bool sent_eof = false;
   auto send_chunked_reply = [&chunked_reply, &response,
                              &sent_eof](bool has_more) {
     PERFETTO_CHECK(!sent_eof);
     sent_eof = !has_more;
     auto resp =
         ipc::AsyncResult<protos::gen::QueryServiceStateResponse>::Create();
     resp.set_has_more(has_more);
     PERFETTO_CHECK(resp->mutable_service_state()->ParseFromArray(
         chunked_reply.data(), chunked_reply.size()));
     chunked_reply.clear();
     response.Resolve(std::move(resp));
   };

   // Create a copy of the whole response and cut away the data_sources section.
   protos::gen::TracingServiceState svc_state_copy = svc_state;
   auto data_sources = std::move(*svc_state_copy.mutable_data_sources());
   chunked_reply = svc_state_copy.SerializeAsArray();

   // Now re-add them fitting within the IPC message limits (- some margin for
   // the outer IPC frame).
   constexpr size_t kMaxMsgSize = ipc::kIPCBufferSize - 128;
   for (const auto& data_source : data_sources) {
     protos::gen::TracingServiceState tmp;
     tmp.mutable_data_sources()->emplace_back(std::move(data_source));
     std::vector<uint8_t> chunk = tmp.SerializeAsArray();
     if (chunked_reply.size() + chunk.size() < kMaxMsgSize) {
       chunked_reply.insert(chunked_reply.end(), chunk.begin(), chunk.end());
     } else {
       send_chunked_reply(/*has_more=*/true);
       chunked_reply = std::move(chunk);
     }
   }

   PERFETTO_DCHECK(!chunked_reply.empty());
   send_chunked_reply(/*has_more=*/false);
   PERFETTO_CHECK(sent_eof);
 }

 // Called by the service in response to a service_endpoint->Flush() request.
 void ConsumerIPCService::OnFlushCallback(
     bool success,
     PendingFlushResponses::iterator pending_response_it) {
   DeferredFlushResponse response(std::move(*pending_response_it));
   pending_flush_responses_.erase(pending_response_it);
   if (success) {
     response.Resolve(ipc::AsyncResult<protos::gen::FlushResponse>::Create());
   } else {
     response.Reject();
   }
 }

 void ConsumerIPCService::QueryCapabilities(
     const protos::gen::QueryCapabilitiesRequest&,
     DeferredQueryCapabilitiesResponse resp) {
   RemoteConsumer* remote_consumer = GetConsumerForCurrentRequest();
   auto it = pending_query_capabilities_responses_.insert(
       pending_query_capabilities_responses_.end(), std::move(resp));
   auto weak_this = weak_ptr_factory_.GetWeakPtr();
   auto callback = [weak_this, it](const TracingServiceCapabilities& caps) {
     if (weak_this)
       weak_this->OnQueryCapabilitiesCallback(caps, std::move(it));
   };
   remote_consumer->service_endpoint->QueryCapabilities(callback);
 }

 // Called by the service in response to service_endpoint->QueryCapabilities().
 void ConsumerIPCService::OnQueryCapabilitiesCallback(
     const TracingServiceCapabilities& caps,
     PendingQueryCapabilitiesResponses::iterator pending_response_it) {
   DeferredQueryCapabilitiesResponse response(std::move(*pending_response_it));
   pending_query_capabilities_responses_.erase(pending_response_it);
   auto resp =
       ipc::AsyncResult<protos::gen::QueryCapabilitiesResponse>::Create();
   *resp->mutable_capabilities() = caps;
   response.Resolve(std::move(resp));
 }

 void ConsumerIPCService::SaveTraceForBugreport(
     const protos::gen::SaveTraceForBugreportRequest&,
     DeferredSaveTraceForBugreportResponse resp) {
   RemoteConsumer* remote_consumer = GetConsumerForCurrentRequest();
   auto it = pending_bugreport_responses_.insert(
       pending_bugreport_responses_.end(), std::move(resp));
   auto weak_this = weak_ptr_factory_.GetWeakPtr();
   auto callback = [weak_this, it](bool success, const std::string& msg) {
     if (weak_this)
       weak_this->OnSaveTraceForBugreportCallback(success, msg, std::move(it));
   };
   remote_consumer->service_endpoint->SaveTraceForBugreport(callback);
 }

 void ConsumerIPCService::CloneSession(
     const protos::gen::CloneSessionRequest& req,
     DeferredCloneSessionResponse resp) {
   RemoteConsumer* remote_consumer = GetConsumerForCurrentRequest();
   remote_consumer->clone_session_response = std::move(resp);
   remote_consumer->service_endpoint->CloneSession(req.session_id());
 }

 // Called by the service in response to
 // service_endpoint->SaveTraceForBugreport().
 void ConsumerIPCService::OnSaveTraceForBugreportCallback(
     bool success,
     const std::string& msg,
     PendingSaveTraceForBugreportResponses::iterator pending_response_it) {
   DeferredSaveTraceForBugreportResponse response(
       std::move(*pending_response_it));
   pending_bugreport_responses_.erase(pending_response_it);
   auto resp =
       ipc::AsyncResult<protos::gen::SaveTraceForBugreportResponse>::Create();
   resp->set_success(success);
   resp->set_msg(msg);
   response.Resolve(std::move(resp));
 }

 ////////////////////////////////////////////////////////////////////////////////
 // RemoteConsumer methods
 ////////////////////////////////////////////////////////////////////////////////

 ConsumerIPCService::RemoteConsumer::RemoteConsumer() = default;
 ConsumerIPCService::RemoteConsumer::~RemoteConsumer() = default;

 // Invoked by the |core_service_| business logic after the ConnectConsumer()
 // call. There is nothing to do here, we really expected the ConnectConsumer()
 // to just work in the local case.
 void ConsumerIPCService::RemoteConsumer::OnConnect() {}

 // Invoked by the |core_service_| business logic after we destroy the
 // |service_endpoint| (in the RemoteConsumer dtor).
 void ConsumerIPCService::RemoteConsumer::OnDisconnect() {}

 void ConsumerIPCService::RemoteConsumer::OnTracingDisabled(
     const std::string& error) {
   if (enable_tracing_response.IsBound()) {
     auto result =
         ipc::AsyncResult<protos::gen::EnableTracingResponse>::Create();
     result->set_disabled(true);
     if (!error.empty())
       result->set_error(error);
     enable_tracing_response.Resolve(std::move(result));
   }
 }

 void ConsumerIPCService::RemoteConsumer::OnTraceData(
     std::vector<TracePacket> trace_packets,
     bool has_more) {
   if (!read_buffers_response.IsBound())
     return;

   auto result = ipc::AsyncResult<protos::gen::ReadBuffersResponse>::Create();

   // A TracePacket might be too big to fit into a single IPC message (max
   // kIPCBufferSize). However a TracePacket is made of slices and each slice
   // is way smaller than kIPCBufferSize (a slice size is effectively bounded by
   // the max chunk size of the SharedMemoryABI). When sending a TracePacket,
   // if its slices don't fit within one IPC, chunk them over several contiguous
   // IPCs using the |last_slice_for_packet| for glueing on the other side.
   static_assert(ipc::kIPCBufferSize >= SharedMemoryABI::kMaxPageSize * 2,
                 "kIPCBufferSize too small given the max possible slice size");

   auto send_ipc_reply = [this, &result](bool more) {
     result.set_has_more(more);
     read_buffers_response.Resolve(std::move(result));
     result = ipc::AsyncResult<protos::gen::ReadBuffersResponse>::Create();
   };

   size_t approx_reply_size = 0;
   for (const TracePacket& trace_packet : trace_packets) {
     size_t num_slices_left_for_packet = trace_packet.slices().size();
     for (const Slice& slice : trace_packet.slices()) {
       // Check if this slice would cause the IPC to overflow its max size and,
       // if that is the case, split the IPCs. The "16" and "64" below are
       // over-estimations of, respectively:
       // 16: the preamble that prefixes each slice (there are 2 x size fields
       //     in the proto + the |last_slice_for_packet| bool).
       // 64: the overhead of the IPC InvokeMethodReply + wire_protocol's frame.
       // If these estimations are wrong, BufferedFrameDeserializer::Serialize()
       // will hit a DCHECK anyways.
       const size_t approx_slice_size = slice.size + 16;
       if (approx_reply_size + approx_slice_size > ipc::kIPCBufferSize - 64) {
         // If we hit this CHECK we got a single slice that is > kIPCBufferSize.
         PERFETTO_CHECK(result->slices_size() > 0);
         send_ipc_reply(/*has_more=*/true);
         approx_reply_size = 0;
       }
       approx_reply_size += approx_slice_size;

       auto* res_slice = result->add_slices();
       res_slice->set_last_slice_for_packet(--num_slices_left_for_packet == 0);
       res_slice->set_data(slice.start, slice.size);
     }
   }
   send_ipc_reply(has_more);
 }

 void ConsumerIPCService::RemoteConsumer::OnDetach(bool success) {
   if (!success) {
     std::move(detach_response).Reject();
     return;
   }
   auto resp = ipc::AsyncResult<protos::gen::DetachResponse>::Create();
   std::move(detach_response).Resolve(std::move(resp));
 }

 void ConsumerIPCService::RemoteConsumer::OnAttach(
     bool success,
     const TraceConfig& trace_config) {
   if (!success) {
     std::move(attach_response).Reject();
     return;
   }
   auto response = ipc::AsyncResult<protos::gen::AttachResponse>::Create();
   *response->mutable_trace_config() = trace_config;
   std::move(attach_response).Resolve(std::move(response));
 }

 void ConsumerIPCService::RemoteConsumer::OnTraceStats(bool success,
                                                       const TraceStats& stats) {
   if (!success) {
     std::move(get_trace_stats_response).Reject();
     return;
   }
   auto response =
       ipc::AsyncResult<protos::gen::GetTraceStatsResponse>::Create();
   *response->mutable_trace_stats() = stats;
   std::move(get_trace_stats_response).Resolve(std::move(response));
 }

 void ConsumerIPCService::RemoteConsumer::OnObservableEvents(
     const ObservableEvents& events) {
   if (!observe_events_response.IsBound())
     return;

   auto result = ipc::AsyncResult<protos::gen::ObserveEventsResponse>::Create();
   result.set_has_more(true);
   *result->mutable_events() = events;
   observe_events_response.Resolve(std::move(result));
 }

 void ConsumerIPCService::RemoteConsumer::CloseObserveEventsResponseStream() {
   if (!observe_events_response.IsBound())
     return;

   auto result = ipc::AsyncResult<protos::gen::ObserveEventsResponse>::Create();
   result.set_has_more(false);
   observe_events_response.Resolve(std::move(result));
 }

 void ConsumerIPCService::RemoteConsumer::OnSessionCloned(
     bool success,
     const std::string& error) {
   if (!clone_session_response.IsBound())
     return;

   auto resp = ipc::AsyncResult<protos::gen::CloneSessionResponse>::Create();
   resp->set_success(success);
   resp->set_error(error);
   std::move(clone_session_response).Resolve(std::move(resp));
 }

 }  // namespace perfetto
	/*
	* Copyright (C) 2017 The Android Open Source Project
	*
	* 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 "src/tracing/ipc/service/consumer_ipc_service.h"

	#include <cinttypes>

	#include "perfetto/base/logging.h"
	#include "perfetto/base/task_runner.h"
	#include "perfetto/ext/base/scoped_file.h"
	#include "perfetto/ext/ipc/basic_types.h"
	#include "perfetto/ext/ipc/host.h"
	#include "perfetto/ext/tracing/core/shared_memory_abi.h"
	#include "perfetto/ext/tracing/core/slice.h"
	#include "perfetto/ext/tracing/core/trace_packet.h"
	#include "perfetto/ext/tracing/core/trace_stats.h"
	#include "perfetto/ext/tracing/core/tracing_service.h"
	#include "perfetto/tracing/core/trace_config.h"
	#include "perfetto/tracing/core/tracing_service_capabilities.h"
	#include "perfetto/tracing/core/tracing_service_state.h"

	namespace perfetto {

	ConsumerIPCService::ConsumerIPCService(TracingService* core_service)
	: core_service_(core_service), weak_ptr_factory_(this) {}

	ConsumerIPCService::~ConsumerIPCService() = default;

	ConsumerIPCService::RemoteConsumer*
	ConsumerIPCService::GetConsumerForCurrentRequest() {
	const ipc::ClientID ipc_client_id = ipc::Service::client_info().client_id();
	const uid_t uid = ipc::Service::client_info().uid();
	PERFETTO_CHECK(ipc_client_id);
	auto it = consumers_.find(ipc_client_id);
	if (it == consumers_.end()) {
	auto* remote_consumer = new RemoteConsumer();
	consumers_[ipc_client_id].reset(remote_consumer);
	remote_consumer->service_endpoint =
	core_service_->ConnectConsumer(remote_consumer, uid);
	return remote_consumer;
	}
	return it->second.get();
	}

	// Called by the IPC layer.
	void ConsumerIPCService::OnClientDisconnected() {
	ipc::ClientID client_id = ipc::Service::client_info().client_id();
	consumers_.erase(client_id);
	}

	// Called by the IPC layer.
	void ConsumerIPCService::EnableTracing(
	const protos::gen::EnableTracingRequest& req,
	DeferredEnableTracingResponse resp) {
	RemoteConsumer* remote_consumer = GetConsumerForCurrentRequest();
	if (req.attach_notification_only()) {
	remote_consumer->enable_tracing_response = std::move(resp);
	return;
	}
	const TraceConfig& trace_config = req.trace_config();
	base::ScopedFile fd;
	if (trace_config.write_into_file() && trace_config.output_path().empty())
	fd = ipc::Service::TakeReceivedFD();
	remote_consumer->service_endpoint->EnableTracing(trace_config, std::move(fd));
	remote_consumer->enable_tracing_response = std::move(resp);
	}

	// Called by the IPC layer.
	void ConsumerIPCService::StartTracing(const protos::gen::StartTracingRequest&,
	DeferredStartTracingResponse resp) {
	RemoteConsumer* remote_consumer = GetConsumerForCurrentRequest();
	remote_consumer->service_endpoint->StartTracing();
	resp.Resolve(ipc::AsyncResult<protos::gen::StartTracingResponse>::Create());
	}

	// Called by the IPC layer.
	void ConsumerIPCService::ChangeTraceConfig(
	const protos::gen::ChangeTraceConfigRequest& req,
	DeferredChangeTraceConfigResponse resp) {
	RemoteConsumer* remote_consumer = GetConsumerForCurrentRequest();
	remote_consumer->service_endpoint->ChangeTraceConfig(req.trace_config());
	resp.Resolve(
	ipc::AsyncResult<protos::gen::ChangeTraceConfigResponse>::Create());
	}

	// Called by the IPC layer.
	void ConsumerIPCService::DisableTracing(
	const protos::gen::DisableTracingRequest&,
	DeferredDisableTracingResponse resp) {
	GetConsumerForCurrentRequest()->service_endpoint->DisableTracing();
	resp.Resolve(ipc::AsyncResult<protos::gen::DisableTracingResponse>::Create());
	}

	// Called by the IPC layer.
	void ConsumerIPCService::ReadBuffers(const protos::gen::ReadBuffersRequest&,
	DeferredReadBuffersResponse resp) {
	RemoteConsumer* remote_consumer = GetConsumerForCurrentRequest();
	remote_consumer->read_buffers_response = std::move(resp);
	remote_consumer->service_endpoint->ReadBuffers();
	}

	// Called by the IPC layer.
	void ConsumerIPCService::FreeBuffers(const protos::gen::FreeBuffersRequest&,
	DeferredFreeBuffersResponse resp) {
	GetConsumerForCurrentRequest()->service_endpoint->FreeBuffers();
	resp.Resolve(ipc::AsyncResult<protos::gen::FreeBuffersResponse>::Create());
	}

	// Called by the IPC layer.
	void ConsumerIPCService::Flush(const protos::gen::FlushRequest& req,
	DeferredFlushResponse resp) {
	auto it = pending_flush_responses_.insert(pending_flush_responses_.end(),
	std::move(resp));
	auto weak_this = weak_ptr_factory_.GetWeakPtr();
	auto callback = [weak_this, it](bool success) {
	if (weak_this)
	weak_this->OnFlushCallback(success, std::move(it));
	};
	GetConsumerForCurrentRequest()->service_endpoint->Flush(req.timeout_ms(),
	std::move(callback));
	}

	// Called by the IPC layer.
	void ConsumerIPCService::Detach(const protos::gen::DetachRequest& req,
	DeferredDetachResponse resp) {
	// OnDetach() will resolve the \|detach_response\|.
	RemoteConsumer* remote_consumer = GetConsumerForCurrentRequest();
	remote_consumer->detach_response = std::move(resp);
	remote_consumer->service_endpoint->Detach(req.key());
	}

	// Called by the IPC layer.
	void ConsumerIPCService::Attach(const protos::gen::AttachRequest& req,
	DeferredAttachResponse resp) {
	// OnAttach() will resolve the \|attach_response\|.
	RemoteConsumer* remote_consumer = GetConsumerForCurrentRequest();
	remote_consumer->attach_response = std::move(resp);
	remote_consumer->service_endpoint->Attach(req.key());
	}

	// Called by the IPC layer.
	void ConsumerIPCService::GetTraceStats(const protos::gen::GetTraceStatsRequest&,
	DeferredGetTraceStatsResponse resp) {
	// OnTraceStats() will resolve the \|get_trace_stats_response\|.
	RemoteConsumer* remote_consumer = GetConsumerForCurrentRequest();
	remote_consumer->get_trace_stats_response = std::move(resp);
	remote_consumer->service_endpoint->GetTraceStats();
	}

	// Called by the IPC layer.
	void ConsumerIPCService::ObserveEvents(
	const protos::gen::ObserveEventsRequest& req,
	DeferredObserveEventsResponse resp) {
	RemoteConsumer* remote_consumer = GetConsumerForCurrentRequest();

	// If there's a prior stream, close it so that client can clean it up.
	remote_consumer->CloseObserveEventsResponseStream();

	remote_consumer->observe_events_response = std::move(resp);

	uint32_t events_mask = 0;
	for (const auto& type : req.events_to_observe()) {
	events_mask \|= static_cast<uint32_t>(type);
	}
	remote_consumer->service_endpoint->ObserveEvents(events_mask);

	// If no events are to be observed, close the stream immediately so that the
	// client can clean up.
	if (events_mask == 0)
	remote_consumer->CloseObserveEventsResponseStream();
	}

	// Called by the IPC layer.
	void ConsumerIPCService::QueryServiceState(
	const protos::gen::QueryServiceStateRequest&,
	DeferredQueryServiceStateResponse resp) {
	RemoteConsumer* remote_consumer = GetConsumerForCurrentRequest();
	auto it = pending_query_service_responses_.insert(
	pending_query_service_responses_.end(), std::move(resp));
	auto weak_this = weak_ptr_factory_.GetWeakPtr();
	auto callback = [weak_this, it](bool success,
	const TracingServiceState& svc_state) {
	if (weak_this)
	weak_this->OnQueryServiceCallback(success, svc_state, std::move(it));
	};
	remote_consumer->service_endpoint->QueryServiceState(callback);
	}

	// Called by the service in response to service_endpoint->QueryServiceState().
	void ConsumerIPCService::OnQueryServiceCallback(
	bool success,
	const TracingServiceState& svc_state,
	PendingQuerySvcResponses::iterator pending_response_it) {
	DeferredQueryServiceStateResponse response(std::move(*pending_response_it));
	pending_query_service_responses_.erase(pending_response_it);
	if (!success) {
	response.Reject();
	return;
	}

	// The TracingServiceState object might be too big to fit into a single IPC
	// message because it contains the DataSourceDescriptor of each data source.
	// Here we split it in chunks to fit in the IPC limit, observing the
	// following rule: each chunk must be invididually a valid TracingServiceState
	// message; all the chunks concatenated together must form the original
	// message. This is to deal with the legacy API that was just sending one
	// whole message (failing in presence of too many data sources, b/153142114).
	// The message is split as follows: we take the whole TracingServiceState,
	// take out the data sources section (which is a top-level repeated field)
	// and re-add them one-by-one. If, in the process of appending, the IPC msg
	// size is reached, a new chunk is created. This assumes that the rest of
	// TracingServiceState fits in one IPC message and each DataSourceDescriptor
	// fits in the worst case in a dedicated message (which is true, because
	// otherwise the RegisterDataSource() which passes the descriptor in the first
	// place would fail).

	std::vector<uint8_t> chunked_reply;

	// Transmits the current chunk and starts a new one.
	bool sent_eof = false;
	auto send_chunked_reply = [&chunked_reply, &response,
	&sent_eof](bool has_more) {
	PERFETTO_CHECK(!sent_eof);
	sent_eof = !has_more;
	auto resp =
	ipc::AsyncResult<protos::gen::QueryServiceStateResponse>::Create();
	resp.set_has_more(has_more);
	PERFETTO_CHECK(resp->mutable_service_state()->ParseFromArray(
	chunked_reply.data(), chunked_reply.size()));
	chunked_reply.clear();
	response.Resolve(std::move(resp));
	};

	// Create a copy of the whole response and cut away the data_sources section.
	protos::gen::TracingServiceState svc_state_copy = svc_state;
	auto data_sources = std::move(*svc_state_copy.mutable_data_sources());
	chunked_reply = svc_state_copy.SerializeAsArray();

	// Now re-add them fitting within the IPC message limits (- some margin for
	// the outer IPC frame).
	constexpr size_t kMaxMsgSize = ipc::kIPCBufferSize - 128;
	for (const auto& data_source : data_sources) {
	protos::gen::TracingServiceState tmp;
	tmp.mutable_data_sources()->emplace_back(std::move(data_source));
	std::vector<uint8_t> chunk = tmp.SerializeAsArray();
	if (chunked_reply.size() + chunk.size() < kMaxMsgSize) {
	chunked_reply.insert(chunked_reply.end(), chunk.begin(), chunk.end());
	} else {
	send_chunked_reply(/has_more=/true);
	chunked_reply = std::move(chunk);
	}
	}

	PERFETTO_DCHECK(!chunked_reply.empty());
	send_chunked_reply(/has_more=/false);
	PERFETTO_CHECK(sent_eof);
	}

	// Called by the service in response to a service_endpoint->Flush() request.
	void ConsumerIPCService::OnFlushCallback(
	bool success,
	PendingFlushResponses::iterator pending_response_it) {
	DeferredFlushResponse response(std::move(*pending_response_it));
	pending_flush_responses_.erase(pending_response_it);
	if (success) {
	response.Resolve(ipc::AsyncResult<protos::gen::FlushResponse>::Create());
	} else {
	response.Reject();
	}
	}

	void ConsumerIPCService::QueryCapabilities(
	const protos::gen::QueryCapabilitiesRequest&,
	DeferredQueryCapabilitiesResponse resp) {
	RemoteConsumer* remote_consumer = GetConsumerForCurrentRequest();
	auto it = pending_query_capabilities_responses_.insert(
	pending_query_capabilities_responses_.end(), std::move(resp));
	auto weak_this = weak_ptr_factory_.GetWeakPtr();
	auto callback = [weak_this, it](const TracingServiceCapabilities& caps) {
	if (weak_this)
	weak_this->OnQueryCapabilitiesCallback(caps, std::move(it));
	};
	remote_consumer->service_endpoint->QueryCapabilities(callback);
	}

	// Called by the service in response to service_endpoint->QueryCapabilities().
	void ConsumerIPCService::OnQueryCapabilitiesCallback(
	const TracingServiceCapabilities& caps,
	PendingQueryCapabilitiesResponses::iterator pending_response_it) {
	DeferredQueryCapabilitiesResponse response(std::move(*pending_response_it));
	pending_query_capabilities_responses_.erase(pending_response_it);
	auto resp =
	ipc::AsyncResult<protos::gen::QueryCapabilitiesResponse>::Create();
	*resp->mutable_capabilities() = caps;
	response.Resolve(std::move(resp));
	}

	void ConsumerIPCService::SaveTraceForBugreport(
	const protos::gen::SaveTraceForBugreportRequest&,
	DeferredSaveTraceForBugreportResponse resp) {
	RemoteConsumer* remote_consumer = GetConsumerForCurrentRequest();
	auto it = pending_bugreport_responses_.insert(
	pending_bugreport_responses_.end(), std::move(resp));
	auto weak_this = weak_ptr_factory_.GetWeakPtr();
	auto callback = [weak_this, it](bool success, const std::string& msg) {
	if (weak_this)
	weak_this->OnSaveTraceForBugreportCallback(success, msg, std::move(it));
	};
	remote_consumer->service_endpoint->SaveTraceForBugreport(callback);
	}

	void ConsumerIPCService::CloneSession(
	const protos::gen::CloneSessionRequest& req,
	DeferredCloneSessionResponse resp) {
	RemoteConsumer* remote_consumer = GetConsumerForCurrentRequest();
	remote_consumer->clone_session_response = std::move(resp);
	remote_consumer->service_endpoint->CloneSession(req.session_id());
	}

	// Called by the service in response to
	// service_endpoint->SaveTraceForBugreport().
	void ConsumerIPCService::OnSaveTraceForBugreportCallback(
	bool success,
	const std::string& msg,
	PendingSaveTraceForBugreportResponses::iterator pending_response_it) {
	DeferredSaveTraceForBugreportResponse response(
	std::move(*pending_response_it));
	pending_bugreport_responses_.erase(pending_response_it);
	auto resp =
	ipc::AsyncResult<protos::gen::SaveTraceForBugreportResponse>::Create();
	resp->set_success(success);
	resp->set_msg(msg);
	response.Resolve(std::move(resp));
	}

	////////////////////////////////////////////////////////////////////////////////
	// RemoteConsumer methods
	////////////////////////////////////////////////////////////////////////////////

	ConsumerIPCService::RemoteConsumer::RemoteConsumer() = default;
	ConsumerIPCService::RemoteConsumer::~RemoteConsumer() = default;

	// Invoked by the \|core_service_\| business logic after the ConnectConsumer()
	// call. There is nothing to do here, we really expected the ConnectConsumer()
	// to just work in the local case.
	void ConsumerIPCService::RemoteConsumer::OnConnect() {}

	// Invoked by the \|core_service_\| business logic after we destroy the
	// \|service_endpoint\| (in the RemoteConsumer dtor).
	void ConsumerIPCService::RemoteConsumer::OnDisconnect() {}

	void ConsumerIPCService::RemoteConsumer::OnTracingDisabled(
	const std::string& error) {
	if (enable_tracing_response.IsBound()) {
	auto result =
	ipc::AsyncResult<protos::gen::EnableTracingResponse>::Create();
	result->set_disabled(true);
	if (!error.empty())
	result->set_error(error);
	enable_tracing_response.Resolve(std::move(result));
	}
	}

	void ConsumerIPCService::RemoteConsumer::OnTraceData(
	std::vector<TracePacket> trace_packets,
	bool has_more) {
	if (!read_buffers_response.IsBound())
	return;

	auto result = ipc::AsyncResult<protos::gen::ReadBuffersResponse>::Create();

	// A TracePacket might be too big to fit into a single IPC message (max
	// kIPCBufferSize). However a TracePacket is made of slices and each slice
	// is way smaller than kIPCBufferSize (a slice size is effectively bounded by
	// the max chunk size of the SharedMemoryABI). When sending a TracePacket,
	// if its slices don't fit within one IPC, chunk them over several contiguous
	// IPCs using the \|last_slice_for_packet\| for glueing on the other side.
	static_assert(ipc::kIPCBufferSize >= SharedMemoryABI::kMaxPageSize * 2,
	"kIPCBufferSize too small given the max possible slice size");

	auto send_ipc_reply = [this, &result](bool more) {
	result.set_has_more(more);
	read_buffers_response.Resolve(std::move(result));
	result = ipc::AsyncResult<protos::gen::ReadBuffersResponse>::Create();
	};

	size_t approx_reply_size = 0;
	for (const TracePacket& trace_packet : trace_packets) {
	size_t num_slices_left_for_packet = trace_packet.slices().size();
	for (const Slice& slice : trace_packet.slices()) {
	// Check if this slice would cause the IPC to overflow its max size and,
	// if that is the case, split the IPCs. The "16" and "64" below are
	// over-estimations of, respectively:
	// 16: the preamble that prefixes each slice (there are 2 x size fields
	// in the proto + the \|last_slice_for_packet\| bool).
	// 64: the overhead of the IPC InvokeMethodReply + wire_protocol's frame.
	// If these estimations are wrong, BufferedFrameDeserializer::Serialize()
	// will hit a DCHECK anyways.
	const size_t approx_slice_size = slice.size + 16;
	if (approx_reply_size + approx_slice_size > ipc::kIPCBufferSize - 64) {
	// If we hit this CHECK we got a single slice that is > kIPCBufferSize.
	PERFETTO_CHECK(result->slices_size() > 0);
	send_ipc_reply(/has_more=/true);
	approx_reply_size = 0;
	}
	approx_reply_size += approx_slice_size;

	auto* res_slice = result->add_slices();
	res_slice->set_last_slice_for_packet(--num_slices_left_for_packet == 0);
	res_slice->set_data(slice.start, slice.size);
	}
	}
	send_ipc_reply(has_more);
	}

	void ConsumerIPCService::RemoteConsumer::OnDetach(bool success) {
	if (!success) {
	std::move(detach_response).Reject();
	return;
	}
	auto resp = ipc::AsyncResult<protos::gen::DetachResponse>::Create();
	std::move(detach_response).Resolve(std::move(resp));
	}

	void ConsumerIPCService::RemoteConsumer::OnAttach(
	bool success,
	const TraceConfig& trace_config) {
	if (!success) {
	std::move(attach_response).Reject();
	return;
	}
	auto response = ipc::AsyncResult<protos::gen::AttachResponse>::Create();
	*response->mutable_trace_config() = trace_config;
	std::move(attach_response).Resolve(std::move(response));
	}

	void ConsumerIPCService::RemoteConsumer::OnTraceStats(bool success,
	const TraceStats& stats) {
	if (!success) {
	std::move(get_trace_stats_response).Reject();
	return;
	}
	auto response =
	ipc::AsyncResult<protos::gen::GetTraceStatsResponse>::Create();
	*response->mutable_trace_stats() = stats;
	std::move(get_trace_stats_response).Resolve(std::move(response));
	}

	void ConsumerIPCService::RemoteConsumer::OnObservableEvents(
	const ObservableEvents& events) {
	if (!observe_events_response.IsBound())
	return;

	auto result = ipc::AsyncResult<protos::gen::ObserveEventsResponse>::Create();
	result.set_has_more(true);
	*result->mutable_events() = events;
	observe_events_response.Resolve(std::move(result));
	}

	void ConsumerIPCService::RemoteConsumer::CloseObserveEventsResponseStream() {
	if (!observe_events_response.IsBound())
	return;

	auto result = ipc::AsyncResult<protos::gen::ObserveEventsResponse>::Create();
	result.set_has_more(false);
	observe_events_response.Resolve(std::move(result));
	}

	void ConsumerIPCService::RemoteConsumer::OnSessionCloned(
	bool success,
	const std::string& error) {
	if (!clone_session_response.IsBound())
	return;

	auto resp = ipc::AsyncResult<protos::gen::CloneSessionResponse>::Create();
	resp->set_success(success);
	resp->set_error(error);
	std::move(clone_session_response).Resolve(std::move(resp));
	}

	} // namespace perfetto