// // 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 #include "src/core/client_channel/subchannel.h" #include #include #include #include #include #include #include "absl/status/statusor.h" #include "absl/strings/cord.h" #include "absl/strings/str_cat.h" #include "absl/strings/string_view.h" #include "absl/types/optional.h" #include #include #include #include #include "src/core/client_channel/subchannel_pool_interface.h" #include "src/core/lib/address_utils/sockaddr_utils.h" #include "src/core/lib/backoff/backoff.h" #include "src/core/lib/channel/channel_args.h" #include "src/core/lib/channel/channel_stack.h" #include "src/core/lib/channel/channel_stack_builder_impl.h" #include "src/core/lib/channel/channel_trace.h" #include "src/core/lib/channel/channelz.h" #include "src/core/lib/config/core_configuration.h" #include "src/core/lib/debug/stats.h" #include "src/core/lib/debug/stats_data.h" #include "src/core/lib/debug/trace.h" #include "src/core/lib/gpr/alloc.h" #include "src/core/lib/gpr/useful.h" #include "src/core/lib/gprpp/debug_location.h" #include "src/core/lib/gprpp/ref_counted_ptr.h" #include "src/core/lib/gprpp/status_helper.h" #include "src/core/lib/gprpp/sync.h" #include "src/core/lib/handshaker/proxy_mapper_registry.h" #include "src/core/lib/iomgr/exec_ctx.h" #include "src/core/lib/iomgr/pollset_set.h" #include "src/core/lib/promise/cancel_callback.h" #include "src/core/lib/promise/seq.h" #include "src/core/lib/slice/slice_internal.h" #include "src/core/lib/surface/channel_init.h" #include "src/core/lib/surface/channel_stack_type.h" #include "src/core/lib/surface/init_internally.h" #include "src/core/lib/transport/connectivity_state.h" #include "src/core/lib/transport/error_utils.h" #include "src/core/lib/transport/transport.h" // Backoff parameters. #define GRPC_SUBCHANNEL_INITIAL_CONNECT_BACKOFF_SECONDS 1 #define GRPC_SUBCHANNEL_RECONNECT_BACKOFF_MULTIPLIER 1.6 #define GRPC_SUBCHANNEL_RECONNECT_MIN_TIMEOUT_SECONDS 20 #define GRPC_SUBCHANNEL_RECONNECT_MAX_BACKOFF_SECONDS 120 #define GRPC_SUBCHANNEL_RECONNECT_JITTER 0.2 // Conversion between subchannel call and call stack. #define SUBCHANNEL_CALL_TO_CALL_STACK(call) \ (grpc_call_stack*)((char*)(call) + \ GPR_ROUND_UP_TO_ALIGNMENT_SIZE(sizeof(SubchannelCall))) #define CALL_STACK_TO_SUBCHANNEL_CALL(callstack) \ (SubchannelCall*)(((char*)(call_stack)) - \ GPR_ROUND_UP_TO_ALIGNMENT_SIZE(sizeof(SubchannelCall))) namespace grpc_core { using ::grpc_event_engine::experimental::EventEngine; TraceFlag grpc_trace_subchannel(false, "subchannel"); DebugOnlyTraceFlag grpc_trace_subchannel_refcount(false, "subchannel_refcount"); // // ConnectedSubchannel // ConnectedSubchannel::ConnectedSubchannel( grpc_channel_stack* channel_stack, const ChannelArgs& args, RefCountedPtr channelz_subchannel) : RefCounted( GRPC_TRACE_FLAG_ENABLED(grpc_trace_subchannel_refcount) ? "ConnectedSubchannel" : nullptr), channel_stack_(channel_stack), args_(args), channelz_subchannel_(std::move(channelz_subchannel)) {} ConnectedSubchannel::~ConnectedSubchannel() { GRPC_CHANNEL_STACK_UNREF(channel_stack_, "connected_subchannel_dtor"); } void ConnectedSubchannel::StartWatch( grpc_pollset_set* interested_parties, OrphanablePtr watcher) { grpc_transport_op* op = grpc_make_transport_op(nullptr); op->start_connectivity_watch = std::move(watcher); op->start_connectivity_watch_state = GRPC_CHANNEL_READY; op->bind_pollset_set = interested_parties; grpc_channel_element* elem = grpc_channel_stack_element(channel_stack_, 0); elem->filter->start_transport_op(elem, op); } void ConnectedSubchannel::Ping(grpc_closure* on_initiate, grpc_closure* on_ack) { grpc_transport_op* op = grpc_make_transport_op(nullptr); grpc_channel_element* elem; op->send_ping.on_initiate = on_initiate; op->send_ping.on_ack = on_ack; elem = grpc_channel_stack_element(channel_stack_, 0); elem->filter->start_transport_op(elem, op); } size_t ConnectedSubchannel::GetInitialCallSizeEstimate() const { return GPR_ROUND_UP_TO_ALIGNMENT_SIZE(sizeof(SubchannelCall)) + channel_stack_->call_stack_size; } ArenaPromise ConnectedSubchannel::MakeCallPromise( CallArgs call_args) { // If not using channelz, we just need to call the channel stack. if (channelz_subchannel() == nullptr) { return channel_stack_->MakeClientCallPromise(std::move(call_args)); } // Otherwise, we need to wrap the channel stack promise with code that // handles the channelz updates. return OnCancel( Seq(channel_stack_->MakeClientCallPromise(std::move(call_args)), [self = Ref()](ServerMetadataHandle metadata) { channelz::SubchannelNode* channelz_subchannel = self->channelz_subchannel(); GPR_ASSERT(channelz_subchannel != nullptr); if (metadata->get(GrpcStatusMetadata()) .value_or(GRPC_STATUS_UNKNOWN) != GRPC_STATUS_OK) { channelz_subchannel->RecordCallFailed(); } else { channelz_subchannel->RecordCallSucceeded(); } return metadata; }), [self = Ref()]() { channelz::SubchannelNode* channelz_subchannel = self->channelz_subchannel(); GPR_ASSERT(channelz_subchannel != nullptr); channelz_subchannel->RecordCallFailed(); }); } // // SubchannelCall // RefCountedPtr SubchannelCall::Create(Args args, grpc_error_handle* error) { const size_t allocation_size = args.connected_subchannel->GetInitialCallSizeEstimate(); Arena* arena = args.arena; return RefCountedPtr(new ( arena->Alloc(allocation_size)) SubchannelCall(std::move(args), error)); } SubchannelCall::SubchannelCall(Args args, grpc_error_handle* error) : connected_subchannel_(std::move(args.connected_subchannel)), deadline_(args.deadline) { grpc_call_stack* callstk = SUBCHANNEL_CALL_TO_CALL_STACK(this); const grpc_call_element_args call_args = { callstk, // call_stack nullptr, // server_transport_data args.context, // context args.path.c_slice(), // path args.start_time, // start_time args.deadline, // deadline args.arena, // arena args.call_combiner // call_combiner }; *error = grpc_call_stack_init(connected_subchannel_->channel_stack(), 1, SubchannelCall::Destroy, this, &call_args); if (GPR_UNLIKELY(!error->ok())) { gpr_log(GPR_ERROR, "error: %s", StatusToString(*error).c_str()); return; } grpc_call_stack_set_pollset_or_pollset_set(callstk, args.pollent); auto* channelz_node = connected_subchannel_->channelz_subchannel(); if (channelz_node != nullptr) { channelz_node->RecordCallStarted(); } } void SubchannelCall::StartTransportStreamOpBatch( grpc_transport_stream_op_batch* batch) { MaybeInterceptRecvTrailingMetadata(batch); grpc_call_stack* call_stack = SUBCHANNEL_CALL_TO_CALL_STACK(this); grpc_call_element* top_elem = grpc_call_stack_element(call_stack, 0); GRPC_CALL_LOG_OP(GPR_INFO, top_elem, batch); top_elem->filter->start_transport_stream_op_batch(top_elem, batch); } grpc_call_stack* SubchannelCall::GetCallStack() { return SUBCHANNEL_CALL_TO_CALL_STACK(this); } void SubchannelCall::SetAfterCallStackDestroy(grpc_closure* closure) { GPR_ASSERT(after_call_stack_destroy_ == nullptr); GPR_ASSERT(closure != nullptr); after_call_stack_destroy_ = closure; } RefCountedPtr SubchannelCall::Ref() { IncrementRefCount(); return RefCountedPtr(this); } RefCountedPtr SubchannelCall::Ref(const DebugLocation& location, const char* reason) { IncrementRefCount(location, reason); return RefCountedPtr(this); } void SubchannelCall::Unref() { GRPC_CALL_STACK_UNREF(SUBCHANNEL_CALL_TO_CALL_STACK(this), ""); } void SubchannelCall::Unref(const DebugLocation& /*location*/, const char* reason) { GRPC_CALL_STACK_UNREF(SUBCHANNEL_CALL_TO_CALL_STACK(this), reason); } void SubchannelCall::Destroy(void* arg, grpc_error_handle /*error*/) { SubchannelCall* self = static_cast(arg); // Keep some members before destroying the subchannel call. grpc_closure* after_call_stack_destroy = self->after_call_stack_destroy_; RefCountedPtr connected_subchannel = std::move(self->connected_subchannel_); // Destroy the subchannel call. self->~SubchannelCall(); // Destroy the call stack. This should be after destroying the subchannel // call, because call->after_call_stack_destroy(), if not null, will free the // call arena. grpc_call_stack_destroy(SUBCHANNEL_CALL_TO_CALL_STACK(self), nullptr, after_call_stack_destroy); // Automatically reset connected_subchannel. This should be after destroying // the call stack, because destroying call stack needs access to the channel // stack. } void SubchannelCall::MaybeInterceptRecvTrailingMetadata( grpc_transport_stream_op_batch* batch) { // only intercept payloads with recv trailing. if (!batch->recv_trailing_metadata) { return; } // only add interceptor is channelz is enabled. if (connected_subchannel_->channelz_subchannel() == nullptr) { return; } GRPC_CLOSURE_INIT(&recv_trailing_metadata_ready_, RecvTrailingMetadataReady, this, grpc_schedule_on_exec_ctx); // save some state needed for the interception callback. GPR_ASSERT(recv_trailing_metadata_ == nullptr); recv_trailing_metadata_ = batch->payload->recv_trailing_metadata.recv_trailing_metadata; original_recv_trailing_metadata_ = batch->payload->recv_trailing_metadata.recv_trailing_metadata_ready; batch->payload->recv_trailing_metadata.recv_trailing_metadata_ready = &recv_trailing_metadata_ready_; } namespace { // Sets *status based on the rest of the parameters. void GetCallStatus(grpc_status_code* status, Timestamp deadline, grpc_metadata_batch* md_batch, grpc_error_handle error) { if (!error.ok()) { grpc_error_get_status(error, deadline, status, nullptr, nullptr, nullptr); } else { *status = md_batch->get(GrpcStatusMetadata()).value_or(GRPC_STATUS_UNKNOWN); } } } // namespace void SubchannelCall::RecvTrailingMetadataReady(void* arg, grpc_error_handle error) { SubchannelCall* call = static_cast(arg); GPR_ASSERT(call->recv_trailing_metadata_ != nullptr); grpc_status_code status = GRPC_STATUS_OK; GetCallStatus(&status, call->deadline_, call->recv_trailing_metadata_, error); channelz::SubchannelNode* channelz_subchannel = call->connected_subchannel_->channelz_subchannel(); GPR_ASSERT(channelz_subchannel != nullptr); if (status == GRPC_STATUS_OK) { channelz_subchannel->RecordCallSucceeded(); } else { channelz_subchannel->RecordCallFailed(); } Closure::Run(DEBUG_LOCATION, call->original_recv_trailing_metadata_, error); } void SubchannelCall::IncrementRefCount() { GRPC_CALL_STACK_REF(SUBCHANNEL_CALL_TO_CALL_STACK(this), ""); } void SubchannelCall::IncrementRefCount(const DebugLocation& /*location*/, const char* reason) { GRPC_CALL_STACK_REF(SUBCHANNEL_CALL_TO_CALL_STACK(this), reason); } // // Subchannel::ConnectedSubchannelStateWatcher // class Subchannel::ConnectedSubchannelStateWatcher final : public AsyncConnectivityStateWatcherInterface { public: // Must be instantiated while holding c->mu. explicit ConnectedSubchannelStateWatcher(WeakRefCountedPtr c) : subchannel_(std::move(c)) {} ~ConnectedSubchannelStateWatcher() override { subchannel_.reset(DEBUG_LOCATION, "state_watcher"); } private: void OnConnectivityStateChange(grpc_connectivity_state new_state, const absl::Status& status) override { Subchannel* c = subchannel_.get(); { MutexLock lock(&c->mu_); // If we're either shutting down or have already seen this connection // failure (i.e., c->connected_subchannel_ is null), do nothing. // // The transport reports TRANSIENT_FAILURE upon GOAWAY but SHUTDOWN // upon connection close. So if the server gracefully shuts down, // we will see TRANSIENT_FAILURE followed by SHUTDOWN, but if not, we // will see only SHUTDOWN. Either way, we react to the first one we // see, ignoring anything that happens after that. if (c->connected_subchannel_ == nullptr) return; if (new_state == GRPC_CHANNEL_TRANSIENT_FAILURE || new_state == GRPC_CHANNEL_SHUTDOWN) { if (GRPC_TRACE_FLAG_ENABLED(grpc_trace_subchannel)) { gpr_log(GPR_INFO, "subchannel %p %s: Connected subchannel %p reports %s: %s", c, c->key_.ToString().c_str(), c->connected_subchannel_.get(), ConnectivityStateName(new_state), status.ToString().c_str()); } c->connected_subchannel_.reset(); if (c->channelz_node() != nullptr) { c->channelz_node()->SetChildSocket(nullptr); } // Even though we're reporting IDLE instead of TRANSIENT_FAILURE here, // pass along the status from the transport, since it may have // keepalive info attached to it that the channel needs. // TODO(roth): Consider whether there's a cleaner way to do this. c->SetConnectivityStateLocked(GRPC_CHANNEL_IDLE, status); c->backoff_.Reset(); } } // Drain any connectivity state notifications after releasing the mutex. c->work_serializer_.DrainQueue(); } WeakRefCountedPtr subchannel_; }; // // Subchannel::ConnectivityStateWatcherList // void Subchannel::ConnectivityStateWatcherList::AddWatcherLocked( RefCountedPtr watcher) { watchers_.insert(std::make_pair(watcher.get(), std::move(watcher))); } void Subchannel::ConnectivityStateWatcherList::RemoveWatcherLocked( ConnectivityStateWatcherInterface* watcher) { watchers_.erase(watcher); } void Subchannel::ConnectivityStateWatcherList::NotifyLocked( grpc_connectivity_state state, const absl::Status& status) { for (const auto& p : watchers_) { subchannel_->work_serializer_.Schedule( [watcher = p.second->Ref(), state, status]() mutable { auto* watcher_ptr = watcher.get(); watcher_ptr->OnConnectivityStateChange(std::move(watcher), state, status); }, DEBUG_LOCATION); } } // // Subchannel // namespace { BackOff::Options ParseArgsForBackoffValues(const ChannelArgs& args, Duration* min_connect_timeout) { const absl::optional fixed_reconnect_backoff = args.GetDurationFromIntMillis("grpc.testing.fixed_reconnect_backoff_ms"); if (fixed_reconnect_backoff.has_value()) { const Duration backoff = std::max(Duration::Milliseconds(100), *fixed_reconnect_backoff); *min_connect_timeout = backoff; return BackOff::Options() .set_initial_backoff(backoff) .set_multiplier(1.0) .set_jitter(0.0) .set_max_backoff(backoff); } const Duration initial_backoff = std::max( Duration::Milliseconds(100), args.GetDurationFromIntMillis(GRPC_ARG_INITIAL_RECONNECT_BACKOFF_MS) .value_or(Duration::Seconds( GRPC_SUBCHANNEL_INITIAL_CONNECT_BACKOFF_SECONDS))); *min_connect_timeout = std::max(Duration::Milliseconds(100), args.GetDurationFromIntMillis(GRPC_ARG_MIN_RECONNECT_BACKOFF_MS) .value_or(Duration::Seconds( GRPC_SUBCHANNEL_RECONNECT_MIN_TIMEOUT_SECONDS))); const Duration max_backoff = std::max(Duration::Milliseconds(100), args.GetDurationFromIntMillis(GRPC_ARG_MAX_RECONNECT_BACKOFF_MS) .value_or(Duration::Seconds( GRPC_SUBCHANNEL_RECONNECT_MAX_BACKOFF_SECONDS))); return BackOff::Options() .set_initial_backoff(initial_backoff) .set_multiplier(GRPC_SUBCHANNEL_RECONNECT_BACKOFF_MULTIPLIER) .set_jitter(GRPC_SUBCHANNEL_RECONNECT_JITTER) .set_max_backoff(max_backoff); } } // namespace Subchannel::Subchannel(SubchannelKey key, OrphanablePtr connector, const ChannelArgs& args) : DualRefCounted( GRPC_TRACE_FLAG_ENABLED(grpc_trace_subchannel_refcount) ? "Subchannel" : nullptr), key_(std::move(key)), args_(args), pollset_set_(grpc_pollset_set_create()), connector_(std::move(connector)), watcher_list_(this), work_serializer_(args_.GetObjectRef()), backoff_(ParseArgsForBackoffValues(args_, &min_connect_timeout_)), event_engine_(args_.GetObjectRef()) { // A grpc_init is added here to ensure that grpc_shutdown does not happen // until the subchannel is destroyed. Subchannels can persist longer than // channels because they maybe reused/shared among multiple channels. As a // result the subchannel destruction happens asynchronously to channel // destruction. If the last channel destruction triggers a grpc_shutdown // before the last subchannel destruction, then there maybe race conditions // triggering segmentation faults. To prevent this issue, we call a grpc_init // here and a grpc_shutdown in the subchannel destructor. InitInternally(); global_stats().IncrementClientSubchannelsCreated(); GRPC_CLOSURE_INIT(&on_connecting_finished_, OnConnectingFinished, this, grpc_schedule_on_exec_ctx); // Check proxy mapper to determine address to connect to and channel // args to use. address_for_connect_ = CoreConfiguration::Get() .proxy_mapper_registry() .MapAddress(key_.address(), &args_) .value_or(key_.address()); // Initialize channelz. const bool channelz_enabled = args_.GetBool(GRPC_ARG_ENABLE_CHANNELZ) .value_or(GRPC_ENABLE_CHANNELZ_DEFAULT); if (channelz_enabled) { const size_t channel_tracer_max_memory = Clamp( args_.GetInt(GRPC_ARG_MAX_CHANNEL_TRACE_EVENT_MEMORY_PER_NODE) .value_or(GRPC_MAX_CHANNEL_TRACE_EVENT_MEMORY_PER_NODE_DEFAULT), 0, INT_MAX); channelz_node_ = MakeRefCounted( grpc_sockaddr_to_uri(&key_.address()) .value_or(""), channel_tracer_max_memory); channelz_node_->AddTraceEvent( channelz::ChannelTrace::Severity::Info, grpc_slice_from_static_string("subchannel created")); } } Subchannel::~Subchannel() { if (channelz_node_ != nullptr) { channelz_node_->AddTraceEvent( channelz::ChannelTrace::Severity::Info, grpc_slice_from_static_string("Subchannel destroyed")); channelz_node_->UpdateConnectivityState(GRPC_CHANNEL_SHUTDOWN); } connector_.reset(); grpc_pollset_set_destroy(pollset_set_); // grpc_shutdown is called here because grpc_init is called in the ctor. ShutdownInternally(); } RefCountedPtr Subchannel::Create( OrphanablePtr connector, const grpc_resolved_address& address, const ChannelArgs& args) { SubchannelKey key(address, args); auto* subchannel_pool = args.GetObject(); GPR_ASSERT(subchannel_pool != nullptr); RefCountedPtr c = subchannel_pool->FindSubchannel(key); if (c != nullptr) { return c; } c = MakeRefCounted(std::move(key), std::move(connector), args); // Try to register the subchannel before setting the subchannel pool. // Otherwise, in case of a registration race, unreffing c in // RegisterSubchannel() will cause c to be tried to be unregistered, while // its key maps to a different subchannel. RefCountedPtr registered = subchannel_pool->RegisterSubchannel(c->key_, c); if (registered == c) c->subchannel_pool_ = subchannel_pool->Ref(); return registered; } void Subchannel::ThrottleKeepaliveTime(int new_keepalive_time) { MutexLock lock(&mu_); // Only update the value if the new keepalive time is larger. if (new_keepalive_time > keepalive_time_) { keepalive_time_ = new_keepalive_time; if (GRPC_TRACE_FLAG_ENABLED(grpc_trace_subchannel)) { gpr_log(GPR_INFO, "subchannel %p %s: throttling keepalive time to %d", this, key_.ToString().c_str(), new_keepalive_time); } args_ = args_.Set(GRPC_ARG_KEEPALIVE_TIME_MS, new_keepalive_time); } } channelz::SubchannelNode* Subchannel::channelz_node() { return channelz_node_.get(); } void Subchannel::WatchConnectivityState( RefCountedPtr watcher) { { MutexLock lock(&mu_); grpc_pollset_set* interested_parties = watcher->interested_parties(); if (interested_parties != nullptr) { grpc_pollset_set_add_pollset_set(pollset_set_, interested_parties); } work_serializer_.Schedule( [watcher = watcher->Ref(), state = state_, status = status_]() mutable { auto* watcher_ptr = watcher.get(); watcher_ptr->OnConnectivityStateChange(std::move(watcher), state, status); }, DEBUG_LOCATION); watcher_list_.AddWatcherLocked(std::move(watcher)); } // Drain any connectivity state notifications after releasing the mutex. work_serializer_.DrainQueue(); } void Subchannel::CancelConnectivityStateWatch( ConnectivityStateWatcherInterface* watcher) { { MutexLock lock(&mu_); grpc_pollset_set* interested_parties = watcher->interested_parties(); if (interested_parties != nullptr) { grpc_pollset_set_del_pollset_set(pollset_set_, interested_parties); } watcher_list_.RemoveWatcherLocked(watcher); } // Drain any connectivity state notifications after releasing the mutex. // (Shouldn't actually be necessary in this case, but better safe than sorry.) work_serializer_.DrainQueue(); } void Subchannel::RequestConnection() { { MutexLock lock(&mu_); if (state_ == GRPC_CHANNEL_IDLE) { StartConnectingLocked(); } } // Drain any connectivity state notifications after releasing the mutex. work_serializer_.DrainQueue(); } void Subchannel::ResetBackoff() { // Hold a ref to ensure cancellation and subsequent deletion of the closure // does not eliminate the last ref and destroy the Subchannel before the // method returns. auto self = WeakRef(DEBUG_LOCATION, "ResetBackoff"); { MutexLock lock(&mu_); backoff_.Reset(); if (state_ == GRPC_CHANNEL_TRANSIENT_FAILURE && event_engine_->Cancel(retry_timer_handle_)) { OnRetryTimerLocked(); } else if (state_ == GRPC_CHANNEL_CONNECTING) { next_attempt_time_ = Timestamp::Now(); } } // Drain any connectivity state notifications after releasing the mutex. work_serializer_.DrainQueue(); } void Subchannel::Orphaned() { // The subchannel_pool is only used once here in this subchannel, so the // access can be outside of the lock. if (subchannel_pool_ != nullptr) { subchannel_pool_->UnregisterSubchannel(key_, this); subchannel_pool_.reset(); } { MutexLock lock(&mu_); GPR_ASSERT(!shutdown_); shutdown_ = true; connector_.reset(); connected_subchannel_.reset(); } // Drain any connectivity state notifications after releasing the mutex. work_serializer_.DrainQueue(); } void Subchannel::GetOrAddDataProducer( UniqueTypeName type, std::function get_or_add) { MutexLock lock(&mu_); auto it = data_producer_map_.emplace(type, nullptr).first; get_or_add(&it->second); } void Subchannel::RemoveDataProducer(DataProducerInterface* data_producer) { MutexLock lock(&mu_); auto it = data_producer_map_.find(data_producer->type()); if (it != data_producer_map_.end() && it->second == data_producer) { data_producer_map_.erase(it); } } // Note: Must be called with a state that is different from the current state. void Subchannel::SetConnectivityStateLocked(grpc_connectivity_state state, const absl::Status& status) { state_ = state; if (status.ok()) { status_ = status; } else { // Augment status message to include IP address. status_ = absl::Status(status.code(), absl::StrCat(grpc_sockaddr_to_uri(&key_.address()) .value_or(""), ": ", status.message())); status.ForEachPayload( [this](absl::string_view key, const absl::Cord& value) // Want to use ABSL_EXCLUSIVE_LOCKS_REQUIRED(&mu_) here, // but that won't work, because we can't pass the lock // annotation through absl::Status::ForEachPayload(). ABSL_NO_THREAD_SAFETY_ANALYSIS { status_.SetPayload(key, value); }); } if (channelz_node_ != nullptr) { channelz_node_->UpdateConnectivityState(state); channelz_node_->AddTraceEvent( channelz::ChannelTrace::Severity::Info, grpc_slice_from_cpp_string(absl::StrCat( "Subchannel connectivity state changed to ", ConnectivityStateName(state), status.ok() ? "" : absl::StrCat(": ", status_.ToString())))); } // Notify watchers. watcher_list_.NotifyLocked(state, status_); } void Subchannel::OnRetryTimer() { { MutexLock lock(&mu_); OnRetryTimerLocked(); } // Drain any connectivity state notifications after releasing the mutex. work_serializer_.DrainQueue(); } void Subchannel::OnRetryTimerLocked() { if (shutdown_) return; gpr_log(GPR_INFO, "subchannel %p %s: backoff delay elapsed, reporting IDLE", this, key_.ToString().c_str()); SetConnectivityStateLocked(GRPC_CHANNEL_IDLE, absl::OkStatus()); } void Subchannel::StartConnectingLocked() { // Set next attempt time. const Timestamp min_deadline = min_connect_timeout_ + Timestamp::Now(); next_attempt_time_ = backoff_.NextAttemptTime(); // Report CONNECTING. SetConnectivityStateLocked(GRPC_CHANNEL_CONNECTING, absl::OkStatus()); // Start connection attempt. SubchannelConnector::Args args; args.address = &address_for_connect_; args.interested_parties = pollset_set_; args.deadline = std::max(next_attempt_time_, min_deadline); args.channel_args = args_; WeakRef(DEBUG_LOCATION, "Connect").release(); // Ref held by callback. connector_->Connect(args, &connecting_result_, &on_connecting_finished_); } void Subchannel::OnConnectingFinished(void* arg, grpc_error_handle error) { WeakRefCountedPtr c(static_cast(arg)); { MutexLock lock(&c->mu_); c->OnConnectingFinishedLocked(error); } // Drain any connectivity state notifications after releasing the mutex. c->work_serializer_.DrainQueue(); c.reset(DEBUG_LOCATION, "Connect"); } void Subchannel::OnConnectingFinishedLocked(grpc_error_handle error) { if (shutdown_) { connecting_result_.Reset(); return; } // If we didn't get a transport or we fail to publish it, report // TRANSIENT_FAILURE and start the retry timer. // Note that if the connection attempt took longer than the backoff // time, then the timer will fire immediately, and we will quickly // transition back to IDLE. if (connecting_result_.transport == nullptr || !PublishTransportLocked()) { const Duration time_until_next_attempt = next_attempt_time_ - Timestamp::Now(); gpr_log(GPR_INFO, "subchannel %p %s: connect failed (%s), backing off for %" PRId64 " ms", this, key_.ToString().c_str(), StatusToString(error).c_str(), time_until_next_attempt.millis()); SetConnectivityStateLocked(GRPC_CHANNEL_TRANSIENT_FAILURE, grpc_error_to_absl_status(error)); retry_timer_handle_ = event_engine_->RunAfter( time_until_next_attempt, [self = WeakRef(DEBUG_LOCATION, "RetryTimer")]() mutable { { ApplicationCallbackExecCtx callback_exec_ctx; ExecCtx exec_ctx; self->OnRetryTimer(); // Subchannel deletion might require an active ExecCtx. So if // self.reset() is not called here, the WeakRefCountedPtr destructor // may run after the ExecCtx declared in the callback is destroyed. // Since subchannel may get destroyed when the WeakRefCountedPtr // destructor runs, it may not have an active ExecCtx - thus leading // to crashes. self.reset(); } }); } } bool Subchannel::PublishTransportLocked() { // Construct channel stack. // Builder takes ownership of transport. ChannelStackBuilderImpl builder( "subchannel", GRPC_CLIENT_SUBCHANNEL, connecting_result_.channel_args.SetObject( std::exchange(connecting_result_.transport, nullptr))); if (!CoreConfiguration::Get().channel_init().CreateStack(&builder)) { return false; } absl::StatusOr> stk = builder.Build(); if (!stk.ok()) { auto error = absl_status_to_grpc_error(stk.status()); connecting_result_.Reset(); gpr_log(GPR_ERROR, "subchannel %p %s: error initializing subchannel stack: %s", this, key_.ToString().c_str(), StatusToString(error).c_str()); return false; } RefCountedPtr socket = std::move(connecting_result_.socket_node); connecting_result_.Reset(); if (shutdown_) return false; // Publish. connected_subchannel_.reset( new ConnectedSubchannel(stk->release(), args_, channelz_node_)); if (GRPC_TRACE_FLAG_ENABLED(grpc_trace_subchannel)) { gpr_log(GPR_INFO, "subchannel %p %s: new connected subchannel at %p", this, key_.ToString().c_str(), connected_subchannel_.get()); } if (channelz_node_ != nullptr) { channelz_node_->SetChildSocket(std::move(socket)); } // Start watching connected subchannel. connected_subchannel_->StartWatch( pollset_set_, MakeOrphanable( WeakRef(DEBUG_LOCATION, "state_watcher"))); // Report initial state. SetConnectivityStateLocked(GRPC_CHANNEL_READY, absl::Status()); return true; } } // namespace grpc_core