// // // Copyright 2015-2016 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/lib/surface/completion_queue.h" #include #include #include #include #include #include #include #include #include #include "absl/status/status.h" #include "absl/strings/str_format.h" #include "absl/strings/str_join.h" #include #include #include #include #include #include #include "src/core/lib/debug/stats.h" #include "src/core/lib/debug/stats_data.h" #include "src/core/lib/gpr/spinlock.h" #include "src/core/lib/gprpp/atomic_utils.h" #include "src/core/lib/gprpp/debug_location.h" #include "src/core/lib/gprpp/ref_counted.h" #include "src/core/lib/gprpp/status_helper.h" #include "src/core/lib/gprpp/time.h" #include "src/core/lib/iomgr/closure.h" #include "src/core/lib/iomgr/exec_ctx.h" #include "src/core/lib/iomgr/executor.h" #include "src/core/lib/iomgr/iomgr.h" #include "src/core/lib/iomgr/pollset.h" #include "src/core/lib/surface/api_trace.h" #include "src/core/lib/surface/event_string.h" grpc_core::TraceFlag grpc_trace_operation_failures(false, "op_failure"); grpc_core::DebugOnlyTraceFlag grpc_trace_pending_tags(false, "pending_tags"); grpc_core::DebugOnlyTraceFlag grpc_trace_cq_refcount(false, "cq_refcount"); namespace { // Specifies a cq thread local cache. // The first event that occurs on a thread // with a cq cache will go into that cache, and // will only be returned on the thread that initialized the cache. // NOTE: Only one event will ever be cached. thread_local grpc_cq_completion* g_cached_event; thread_local grpc_completion_queue* g_cached_cq; struct plucker { grpc_pollset_worker** worker; void* tag; }; struct cq_poller_vtable { bool can_get_pollset; bool can_listen; size_t (*size)(void); void (*init)(grpc_pollset* pollset, gpr_mu** mu); grpc_error_handle (*kick)(grpc_pollset* pollset, grpc_pollset_worker* specific_worker); grpc_error_handle (*work)(grpc_pollset* pollset, grpc_pollset_worker** worker, grpc_core::Timestamp deadline); void (*shutdown)(grpc_pollset* pollset, grpc_closure* closure); void (*destroy)(grpc_pollset* pollset); }; typedef struct non_polling_worker { gpr_cv cv; bool kicked; struct non_polling_worker* next; struct non_polling_worker* prev; } non_polling_worker; struct non_polling_poller { gpr_mu mu; bool kicked_without_poller; non_polling_worker* root; grpc_closure* shutdown; }; size_t non_polling_poller_size(void) { return sizeof(non_polling_poller); } void non_polling_poller_init(grpc_pollset* pollset, gpr_mu** mu) { non_polling_poller* npp = reinterpret_cast(pollset); gpr_mu_init(&npp->mu); *mu = &npp->mu; } void non_polling_poller_destroy(grpc_pollset* pollset) { non_polling_poller* npp = reinterpret_cast(pollset); gpr_mu_destroy(&npp->mu); } grpc_error_handle non_polling_poller_work(grpc_pollset* pollset, grpc_pollset_worker** worker, grpc_core::Timestamp deadline) { non_polling_poller* npp = reinterpret_cast(pollset); if (npp->shutdown) return absl::OkStatus(); if (npp->kicked_without_poller) { npp->kicked_without_poller = false; return absl::OkStatus(); } non_polling_worker w; gpr_cv_init(&w.cv); if (worker != nullptr) *worker = reinterpret_cast(&w); if (npp->root == nullptr) { npp->root = w.next = w.prev = &w; } else { w.next = npp->root; w.prev = w.next->prev; w.next->prev = w.prev->next = &w; } w.kicked = false; gpr_timespec deadline_ts = deadline.as_timespec(GPR_CLOCK_MONOTONIC); while (!npp->shutdown && !w.kicked && !gpr_cv_wait(&w.cv, &npp->mu, deadline_ts)) { } grpc_core::ExecCtx::Get()->InvalidateNow(); if (&w == npp->root) { npp->root = w.next; if (&w == npp->root) { if (npp->shutdown) { grpc_core::ExecCtx::Run(DEBUG_LOCATION, npp->shutdown, absl::OkStatus()); } npp->root = nullptr; } } w.next->prev = w.prev; w.prev->next = w.next; gpr_cv_destroy(&w.cv); if (worker != nullptr) *worker = nullptr; return absl::OkStatus(); } grpc_error_handle non_polling_poller_kick( grpc_pollset* pollset, grpc_pollset_worker* specific_worker) { non_polling_poller* p = reinterpret_cast(pollset); if (specific_worker == nullptr) { specific_worker = reinterpret_cast(p->root); } if (specific_worker != nullptr) { non_polling_worker* w = reinterpret_cast(specific_worker); if (!w->kicked) { w->kicked = true; gpr_cv_signal(&w->cv); } } else { p->kicked_without_poller = true; } return absl::OkStatus(); } void non_polling_poller_shutdown(grpc_pollset* pollset, grpc_closure* closure) { non_polling_poller* p = reinterpret_cast(pollset); GPR_ASSERT(closure != nullptr); p->shutdown = closure; if (p->root == nullptr) { grpc_core::ExecCtx::Run(DEBUG_LOCATION, closure, absl::OkStatus()); } else { non_polling_worker* w = p->root; do { gpr_cv_signal(&w->cv); w = w->next; } while (w != p->root); } } const cq_poller_vtable g_poller_vtable_by_poller_type[] = { // GRPC_CQ_DEFAULT_POLLING {true, true, grpc_pollset_size, grpc_pollset_init, grpc_pollset_kick, grpc_pollset_work, grpc_pollset_shutdown, grpc_pollset_destroy}, // GRPC_CQ_NON_LISTENING {true, false, grpc_pollset_size, grpc_pollset_init, grpc_pollset_kick, grpc_pollset_work, grpc_pollset_shutdown, grpc_pollset_destroy}, // GRPC_CQ_NON_POLLING {false, false, non_polling_poller_size, non_polling_poller_init, non_polling_poller_kick, non_polling_poller_work, non_polling_poller_shutdown, non_polling_poller_destroy}, }; } // namespace struct cq_vtable { grpc_cq_completion_type cq_completion_type; size_t data_size; void (*init)(void* data, grpc_completion_queue_functor* shutdown_callback); void (*shutdown)(grpc_completion_queue* cq); void (*destroy)(void* data); bool (*begin_op)(grpc_completion_queue* cq, void* tag); void (*end_op)(grpc_completion_queue* cq, void* tag, grpc_error_handle error, void (*done)(void* done_arg, grpc_cq_completion* storage), void* done_arg, grpc_cq_completion* storage, bool internal); grpc_event (*next)(grpc_completion_queue* cq, gpr_timespec deadline, void* reserved); grpc_event (*pluck)(grpc_completion_queue* cq, void* tag, gpr_timespec deadline, void* reserved); }; namespace { // Queue that holds the cq_completion_events. Internally uses // MultiProducerSingleConsumerQueue (a lockfree multiproducer single consumer // queue). It uses a queue_lock to support multiple consumers. // Only used in completion queues whose completion_type is GRPC_CQ_NEXT class CqEventQueue { public: CqEventQueue() = default; ~CqEventQueue() = default; // Note: The counter is not incremented/decremented atomically with push/pop. // The count is only eventually consistent intptr_t num_items() const { return num_queue_items_.load(std::memory_order_relaxed); } bool Push(grpc_cq_completion* c); grpc_cq_completion* Pop(); private: // Spinlock to serialize consumers i.e pop() operations gpr_spinlock queue_lock_ = GPR_SPINLOCK_INITIALIZER; grpc_core::MultiProducerSingleConsumerQueue queue_; // A lazy counter of number of items in the queue. This is NOT atomically // incremented/decremented along with push/pop operations and hence is only // eventually consistent std::atomic num_queue_items_{0}; }; struct cq_next_data { ~cq_next_data() { GPR_ASSERT(queue.num_items() == 0); #ifndef NDEBUG if (pending_events.load(std::memory_order_acquire) != 0) { gpr_log(GPR_ERROR, "Destroying CQ without draining it fully."); } #endif } /// Completed events for completion-queues of type GRPC_CQ_NEXT CqEventQueue queue; /// Counter of how many things have ever been queued on this completion queue /// useful for avoiding locks to check the queue std::atomic things_queued_ever{0}; /// Number of outstanding events (+1 if not shut down) /// Initial count is dropped by grpc_completion_queue_shutdown std::atomic pending_events{1}; /// 0 initially. 1 once we initiated shutdown bool shutdown_called = false; }; struct cq_pluck_data { cq_pluck_data() { completed_tail = &completed_head; completed_head.next = reinterpret_cast(completed_tail); } ~cq_pluck_data() { GPR_ASSERT(completed_head.next == reinterpret_cast(&completed_head)); #ifndef NDEBUG if (pending_events.load(std::memory_order_acquire) != 0) { gpr_log(GPR_ERROR, "Destroying CQ without draining it fully."); } #endif } /// Completed events for completion-queues of type GRPC_CQ_PLUCK grpc_cq_completion completed_head; grpc_cq_completion* completed_tail; /// Number of pending events (+1 if we're not shutdown). /// Initial count is dropped by grpc_completion_queue_shutdown. std::atomic pending_events{1}; /// Counter of how many things have ever been queued on this completion queue /// useful for avoiding locks to check the queue std::atomic things_queued_ever{0}; /// 0 initially. 1 once we completed shutting // TODO(sreek): This is not needed since (shutdown == 1) if and only if // (pending_events == 0). So consider removing this in future and use // pending_events std::atomic shutdown{false}; /// 0 initially. 1 once we initiated shutdown bool shutdown_called = false; int num_pluckers = 0; plucker pluckers[GRPC_MAX_COMPLETION_QUEUE_PLUCKERS]; }; struct cq_callback_data { explicit cq_callback_data(grpc_completion_queue_functor* shutdown_callback) : shutdown_callback(shutdown_callback) {} ~cq_callback_data() { #ifndef NDEBUG if (pending_events.load(std::memory_order_acquire) != 0) { gpr_log(GPR_ERROR, "Destroying CQ without draining it fully."); } #endif } /// No actual completed events queue, unlike other types /// Number of pending events (+1 if we're not shutdown). /// Initial count is dropped by grpc_completion_queue_shutdown. std::atomic pending_events{1}; /// 0 initially. 1 once we initiated shutdown bool shutdown_called = false; /// A callback that gets invoked when the CQ completes shutdown grpc_completion_queue_functor* shutdown_callback; }; } // namespace // Completion queue structure struct grpc_completion_queue { /// Once owning_refs drops to zero, we will destroy the cq grpc_core::RefCount owning_refs; gpr_mu* mu; const cq_vtable* vtable; const cq_poller_vtable* poller_vtable; #ifndef NDEBUG void** outstanding_tags; size_t outstanding_tag_count; size_t outstanding_tag_capacity; #endif grpc_closure pollset_shutdown_done; int num_polls; }; // Forward declarations static void cq_finish_shutdown_next(grpc_completion_queue* cq); static void cq_finish_shutdown_pluck(grpc_completion_queue* cq); static void cq_finish_shutdown_callback(grpc_completion_queue* cq); static void cq_shutdown_next(grpc_completion_queue* cq); static void cq_shutdown_pluck(grpc_completion_queue* cq); static void cq_shutdown_callback(grpc_completion_queue* cq); static bool cq_begin_op_for_next(grpc_completion_queue* cq, void* tag); static bool cq_begin_op_for_pluck(grpc_completion_queue* cq, void* tag); static bool cq_begin_op_for_callback(grpc_completion_queue* cq, void* tag); // A cq_end_op function is called when an operation on a given CQ with // a given tag has completed. The storage argument is a reference to the // space reserved for this completion as it is placed into the corresponding // queue. The done argument is a callback that will be invoked when it is // safe to free up that storage. The storage MUST NOT be freed until the // done callback is invoked. static void cq_end_op_for_next( grpc_completion_queue* cq, void* tag, grpc_error_handle error, void (*done)(void* done_arg, grpc_cq_completion* storage), void* done_arg, grpc_cq_completion* storage, bool internal); static void cq_end_op_for_pluck( grpc_completion_queue* cq, void* tag, grpc_error_handle error, void (*done)(void* done_arg, grpc_cq_completion* storage), void* done_arg, grpc_cq_completion* storage, bool internal); static void cq_end_op_for_callback( grpc_completion_queue* cq, void* tag, grpc_error_handle error, void (*done)(void* done_arg, grpc_cq_completion* storage), void* done_arg, grpc_cq_completion* storage, bool internal); static grpc_event cq_next(grpc_completion_queue* cq, gpr_timespec deadline, void* reserved); static grpc_event cq_pluck(grpc_completion_queue* cq, void* tag, gpr_timespec deadline, void* reserved); // Note that cq_init_next and cq_init_pluck do not use the shutdown_callback static void cq_init_next(void* data, grpc_completion_queue_functor* shutdown_callback); static void cq_init_pluck(void* data, grpc_completion_queue_functor* shutdown_callback); static void cq_init_callback(void* data, grpc_completion_queue_functor* shutdown_callback); static void cq_destroy_next(void* data); static void cq_destroy_pluck(void* data); static void cq_destroy_callback(void* data); // Completion queue vtables based on the completion-type static const cq_vtable g_cq_vtable[] = { // GRPC_CQ_NEXT {GRPC_CQ_NEXT, sizeof(cq_next_data), cq_init_next, cq_shutdown_next, cq_destroy_next, cq_begin_op_for_next, cq_end_op_for_next, cq_next, nullptr}, // GRPC_CQ_PLUCK {GRPC_CQ_PLUCK, sizeof(cq_pluck_data), cq_init_pluck, cq_shutdown_pluck, cq_destroy_pluck, cq_begin_op_for_pluck, cq_end_op_for_pluck, nullptr, cq_pluck}, // GRPC_CQ_CALLBACK {GRPC_CQ_CALLBACK, sizeof(cq_callback_data), cq_init_callback, cq_shutdown_callback, cq_destroy_callback, cq_begin_op_for_callback, cq_end_op_for_callback, nullptr, nullptr}, }; #define DATA_FROM_CQ(cq) ((void*)((cq) + 1)) #define POLLSET_FROM_CQ(cq) \ ((grpc_pollset*)((cq)->vtable->data_size + (char*)DATA_FROM_CQ(cq))) grpc_core::TraceFlag grpc_cq_pluck_trace(false, "queue_pluck"); #define GRPC_SURFACE_TRACE_RETURNED_EVENT(cq, event) \ do { \ if (GRPC_TRACE_FLAG_ENABLED(grpc_api_trace) && \ (GRPC_TRACE_FLAG_ENABLED(grpc_cq_pluck_trace) || \ (event)->type != GRPC_QUEUE_TIMEOUT)) { \ gpr_log(GPR_INFO, "RETURN_EVENT[%p]: %s", cq, \ grpc_event_string(event).c_str()); \ } \ } while (0) static void on_pollset_shutdown_done(void* arg, grpc_error_handle error); void grpc_completion_queue_thread_local_cache_init(grpc_completion_queue* cq) { if (g_cached_cq == nullptr) { g_cached_event = nullptr; g_cached_cq = cq; } } int grpc_completion_queue_thread_local_cache_flush(grpc_completion_queue* cq, void** tag, int* ok) { grpc_cq_completion* storage = g_cached_event; int ret = 0; if (storage != nullptr && g_cached_cq == cq) { *tag = storage->tag; grpc_core::ExecCtx exec_ctx; *ok = (storage->next & uintptr_t{1}) == 1; storage->done(storage->done_arg, storage); ret = 1; cq_next_data* cqd = static_cast DATA_FROM_CQ(cq); if (cqd->pending_events.fetch_sub(1, std::memory_order_acq_rel) == 1) { GRPC_CQ_INTERNAL_REF(cq, "shutting_down"); gpr_mu_lock(cq->mu); cq_finish_shutdown_next(cq); gpr_mu_unlock(cq->mu); GRPC_CQ_INTERNAL_UNREF(cq, "shutting_down"); } } g_cached_event = nullptr; g_cached_cq = nullptr; return ret; } bool CqEventQueue::Push(grpc_cq_completion* c) { queue_.Push( reinterpret_cast(c)); return num_queue_items_.fetch_add(1, std::memory_order_relaxed) == 0; } grpc_cq_completion* CqEventQueue::Pop() { grpc_cq_completion* c = nullptr; if (gpr_spinlock_trylock(&queue_lock_)) { bool is_empty = false; c = reinterpret_cast(queue_.PopAndCheckEnd(&is_empty)); gpr_spinlock_unlock(&queue_lock_); } if (c) { num_queue_items_.fetch_sub(1, std::memory_order_relaxed); } return c; } grpc_completion_queue* grpc_completion_queue_create_internal( grpc_cq_completion_type completion_type, grpc_cq_polling_type polling_type, grpc_completion_queue_functor* shutdown_callback) { grpc_completion_queue* cq; GRPC_API_TRACE( "grpc_completion_queue_create_internal(completion_type=%d, " "polling_type=%d)", 2, (completion_type, polling_type)); switch (completion_type) { case GRPC_CQ_NEXT: grpc_core::global_stats().IncrementCqNextCreates(); break; case GRPC_CQ_PLUCK: grpc_core::global_stats().IncrementCqPluckCreates(); break; case GRPC_CQ_CALLBACK: grpc_core::global_stats().IncrementCqCallbackCreates(); break; } const cq_vtable* vtable = &g_cq_vtable[completion_type]; const cq_poller_vtable* poller_vtable = &g_poller_vtable_by_poller_type[polling_type]; grpc_core::ExecCtx exec_ctx; cq = static_cast( gpr_zalloc(sizeof(grpc_completion_queue) + vtable->data_size + poller_vtable->size())); cq->vtable = vtable; cq->poller_vtable = poller_vtable; // One for destroy(), one for pollset_shutdown new (&cq->owning_refs) grpc_core::RefCount(2); poller_vtable->init(POLLSET_FROM_CQ(cq), &cq->mu); vtable->init(DATA_FROM_CQ(cq), shutdown_callback); GRPC_CLOSURE_INIT(&cq->pollset_shutdown_done, on_pollset_shutdown_done, cq, grpc_schedule_on_exec_ctx); return cq; } static void cq_init_next(void* data, grpc_completion_queue_functor* /*shutdown_callback*/) { new (data) cq_next_data(); } static void cq_destroy_next(void* data) { cq_next_data* cqd = static_cast(data); cqd->~cq_next_data(); } static void cq_init_pluck( void* data, grpc_completion_queue_functor* /*shutdown_callback*/) { new (data) cq_pluck_data(); } static void cq_destroy_pluck(void* data) { cq_pluck_data* cqd = static_cast(data); cqd->~cq_pluck_data(); } static void cq_init_callback(void* data, grpc_completion_queue_functor* shutdown_callback) { new (data) cq_callback_data(shutdown_callback); } static void cq_destroy_callback(void* data) { cq_callback_data* cqd = static_cast(data); cqd->~cq_callback_data(); } grpc_cq_completion_type grpc_get_cq_completion_type(grpc_completion_queue* cq) { return cq->vtable->cq_completion_type; } int grpc_get_cq_poll_num(grpc_completion_queue* cq) { int cur_num_polls; gpr_mu_lock(cq->mu); cur_num_polls = cq->num_polls; gpr_mu_unlock(cq->mu); return cur_num_polls; } #ifndef NDEBUG void grpc_cq_internal_ref(grpc_completion_queue* cq, const char* reason, const char* file, int line) { grpc_core::DebugLocation debug_location(file, line); #else void grpc_cq_internal_ref(grpc_completion_queue* cq) { grpc_core::DebugLocation debug_location; const char* reason = nullptr; #endif cq->owning_refs.Ref(debug_location, reason); } static void on_pollset_shutdown_done(void* arg, grpc_error_handle /*error*/) { grpc_completion_queue* cq = static_cast(arg); GRPC_CQ_INTERNAL_UNREF(cq, "pollset_destroy"); } #ifndef NDEBUG void grpc_cq_internal_unref(grpc_completion_queue* cq, const char* reason, const char* file, int line) { grpc_core::DebugLocation debug_location(file, line); #else void grpc_cq_internal_unref(grpc_completion_queue* cq) { grpc_core::DebugLocation debug_location; const char* reason = nullptr; #endif if (GPR_UNLIKELY(cq->owning_refs.Unref(debug_location, reason))) { cq->vtable->destroy(DATA_FROM_CQ(cq)); cq->poller_vtable->destroy(POLLSET_FROM_CQ(cq)); #ifndef NDEBUG gpr_free(cq->outstanding_tags); #endif gpr_free(cq); } } #ifndef NDEBUG static void cq_check_tag(grpc_completion_queue* cq, void* tag, bool lock_cq) { int found = 0; if (lock_cq) { gpr_mu_lock(cq->mu); } for (int i = 0; i < static_cast(cq->outstanding_tag_count); i++) { if (cq->outstanding_tags[i] == tag) { cq->outstanding_tag_count--; std::swap(cq->outstanding_tags[i], cq->outstanding_tags[cq->outstanding_tag_count]); found = 1; break; } } if (lock_cq) { gpr_mu_unlock(cq->mu); } GPR_ASSERT(found); } #else static void cq_check_tag(grpc_completion_queue* /*cq*/, void* /*tag*/, bool /*lock_cq*/) {} #endif static bool cq_begin_op_for_next(grpc_completion_queue* cq, void* /*tag*/) { cq_next_data* cqd = static_cast DATA_FROM_CQ(cq); return grpc_core::IncrementIfNonzero(&cqd->pending_events); } static bool cq_begin_op_for_pluck(grpc_completion_queue* cq, void* /*tag*/) { cq_pluck_data* cqd = static_cast DATA_FROM_CQ(cq); return grpc_core::IncrementIfNonzero(&cqd->pending_events); } static bool cq_begin_op_for_callback(grpc_completion_queue* cq, void* /*tag*/) { cq_callback_data* cqd = static_cast DATA_FROM_CQ(cq); return grpc_core::IncrementIfNonzero(&cqd->pending_events); } bool grpc_cq_begin_op(grpc_completion_queue* cq, void* tag) { #ifndef NDEBUG gpr_mu_lock(cq->mu); if (cq->outstanding_tag_count == cq->outstanding_tag_capacity) { cq->outstanding_tag_capacity = std::max(size_t(4), 2 * cq->outstanding_tag_capacity); cq->outstanding_tags = static_cast(gpr_realloc( cq->outstanding_tags, sizeof(*cq->outstanding_tags) * cq->outstanding_tag_capacity)); } cq->outstanding_tags[cq->outstanding_tag_count++] = tag; gpr_mu_unlock(cq->mu); #endif return cq->vtable->begin_op(cq, tag); } // Queue a GRPC_OP_COMPLETED operation to a completion queue (with a // completion // type of GRPC_CQ_NEXT) static void cq_end_op_for_next( grpc_completion_queue* cq, void* tag, grpc_error_handle error, void (*done)(void* done_arg, grpc_cq_completion* storage), void* done_arg, grpc_cq_completion* storage, bool /*internal*/) { if (GRPC_TRACE_FLAG_ENABLED(grpc_api_trace) || (GRPC_TRACE_FLAG_ENABLED(grpc_trace_operation_failures) && !error.ok())) { std::string errmsg = grpc_core::StatusToString(error); GRPC_API_TRACE( "cq_end_op_for_next(cq=%p, tag=%p, error=%s, " "done=%p, done_arg=%p, storage=%p)", 6, (cq, tag, errmsg.c_str(), done, done_arg, storage)); if (GRPC_TRACE_FLAG_ENABLED(grpc_trace_operation_failures) && !error.ok()) { gpr_log(GPR_INFO, "Operation failed: tag=%p, error=%s", tag, errmsg.c_str()); } } cq_next_data* cqd = static_cast DATA_FROM_CQ(cq); int is_success = (error.ok()); storage->tag = tag; storage->done = done; storage->done_arg = done_arg; storage->next = static_cast(is_success); cq_check_tag(cq, tag, true); // Used in debug builds only if (g_cached_cq == cq && g_cached_event == nullptr) { g_cached_event = storage; } else { // Add the completion to the queue bool is_first = cqd->queue.Push(storage); cqd->things_queued_ever.fetch_add(1, std::memory_order_relaxed); // Since we do not hold the cq lock here, it is important to do an 'acquire' // load here (instead of a 'no_barrier' load) to match with the release // store // (done via pending_events.fetch_sub(1, ACQ_REL)) in cq_shutdown_next // if (cqd->pending_events.load(std::memory_order_acquire) != 1) { // Only kick if this is the first item queued if (is_first) { gpr_mu_lock(cq->mu); grpc_error_handle kick_error = cq->poller_vtable->kick(POLLSET_FROM_CQ(cq), nullptr); gpr_mu_unlock(cq->mu); if (!kick_error.ok()) { gpr_log(GPR_ERROR, "Kick failed: %s", grpc_core::StatusToString(kick_error).c_str()); } } if (cqd->pending_events.fetch_sub(1, std::memory_order_acq_rel) == 1) { GRPC_CQ_INTERNAL_REF(cq, "shutting_down"); gpr_mu_lock(cq->mu); cq_finish_shutdown_next(cq); gpr_mu_unlock(cq->mu); GRPC_CQ_INTERNAL_UNREF(cq, "shutting_down"); } } else { GRPC_CQ_INTERNAL_REF(cq, "shutting_down"); cqd->pending_events.store(0, std::memory_order_release); gpr_mu_lock(cq->mu); cq_finish_shutdown_next(cq); gpr_mu_unlock(cq->mu); GRPC_CQ_INTERNAL_UNREF(cq, "shutting_down"); } } } // Queue a GRPC_OP_COMPLETED operation to a completion queue (with a // completion // type of GRPC_CQ_PLUCK) static void cq_end_op_for_pluck( grpc_completion_queue* cq, void* tag, grpc_error_handle error, void (*done)(void* done_arg, grpc_cq_completion* storage), void* done_arg, grpc_cq_completion* storage, bool /*internal*/) { cq_pluck_data* cqd = static_cast DATA_FROM_CQ(cq); int is_success = (error.ok()); if (GRPC_TRACE_FLAG_ENABLED(grpc_api_trace) || (GRPC_TRACE_FLAG_ENABLED(grpc_trace_operation_failures) && !error.ok())) { std::string errmsg = grpc_core::StatusToString(error); GRPC_API_TRACE( "cq_end_op_for_pluck(cq=%p, tag=%p, error=%s, " "done=%p, done_arg=%p, storage=%p)", 6, (cq, tag, errmsg.c_str(), done, done_arg, storage)); if (GRPC_TRACE_FLAG_ENABLED(grpc_trace_operation_failures) && !error.ok()) { gpr_log(GPR_ERROR, "Operation failed: tag=%p, error=%s", tag, errmsg.c_str()); } } storage->tag = tag; storage->done = done; storage->done_arg = done_arg; storage->next = reinterpret_cast(&cqd->completed_head) | static_cast(is_success); gpr_mu_lock(cq->mu); cq_check_tag(cq, tag, false); // Used in debug builds only // Add to the list of completions cqd->things_queued_ever.fetch_add(1, std::memory_order_relaxed); cqd->completed_tail->next = reinterpret_cast(storage) | (1u & cqd->completed_tail->next); cqd->completed_tail = storage; if (cqd->pending_events.fetch_sub(1, std::memory_order_acq_rel) == 1) { cq_finish_shutdown_pluck(cq); gpr_mu_unlock(cq->mu); } else { grpc_pollset_worker* pluck_worker = nullptr; for (int i = 0; i < cqd->num_pluckers; i++) { if (cqd->pluckers[i].tag == tag) { pluck_worker = *cqd->pluckers[i].worker; break; } } grpc_error_handle kick_error = cq->poller_vtable->kick(POLLSET_FROM_CQ(cq), pluck_worker); gpr_mu_unlock(cq->mu); if (!kick_error.ok()) { gpr_log(GPR_ERROR, "Kick failed: %s", grpc_core::StatusToString(kick_error).c_str()); } } } static void functor_callback(void* arg, grpc_error_handle error) { auto* functor = static_cast(arg); functor->functor_run(functor, error.ok()); } // Complete an event on a completion queue of type GRPC_CQ_CALLBACK static void cq_end_op_for_callback( grpc_completion_queue* cq, void* tag, grpc_error_handle error, void (*done)(void* done_arg, grpc_cq_completion* storage), void* done_arg, grpc_cq_completion* storage, bool internal) { cq_callback_data* cqd = static_cast DATA_FROM_CQ(cq); if (GRPC_TRACE_FLAG_ENABLED(grpc_api_trace) || (GRPC_TRACE_FLAG_ENABLED(grpc_trace_operation_failures) && !error.ok())) { std::string errmsg = grpc_core::StatusToString(error); GRPC_API_TRACE( "cq_end_op_for_callback(cq=%p, tag=%p, error=%s, " "done=%p, done_arg=%p, storage=%p)", 6, (cq, tag, errmsg.c_str(), done, done_arg, storage)); if (GRPC_TRACE_FLAG_ENABLED(grpc_trace_operation_failures) && !error.ok()) { gpr_log(GPR_ERROR, "Operation failed: tag=%p, error=%s", tag, errmsg.c_str()); } } // The callback-based CQ isn't really a queue at all and thus has no need // for reserved storage. Invoke the done callback right away to release it. done(done_arg, storage); cq_check_tag(cq, tag, true); // Used in debug builds only if (cqd->pending_events.fetch_sub(1, std::memory_order_acq_rel) == 1) { cq_finish_shutdown_callback(cq); } // If possible, schedule the callback onto an existing thread-local // ApplicationCallbackExecCtx, which is a work queue. This is possible for: // 1. The callback is internally-generated and there is an ACEC available // 2. The callback is marked inlineable and there is an ACEC available // 3. We are already running in a background poller thread (which always has // an ACEC available at the base of the stack). auto* functor = static_cast(tag); if (((internal || functor->inlineable) && grpc_core::ApplicationCallbackExecCtx::Available()) || grpc_iomgr_is_any_background_poller_thread()) { grpc_core::ApplicationCallbackExecCtx::Enqueue(functor, (error.ok())); return; } // Schedule the callback on a closure if not internal or triggered // from a background poller thread. grpc_core::Executor::Run( GRPC_CLOSURE_CREATE(functor_callback, functor, nullptr), error); } void grpc_cq_end_op(grpc_completion_queue* cq, void* tag, grpc_error_handle error, void (*done)(void* done_arg, grpc_cq_completion* storage), void* done_arg, grpc_cq_completion* storage, bool internal) { cq->vtable->end_op(cq, tag, error, done, done_arg, storage, internal); } struct cq_is_finished_arg { gpr_atm last_seen_things_queued_ever; grpc_completion_queue* cq; grpc_core::Timestamp deadline; grpc_cq_completion* stolen_completion; void* tag; // for pluck bool first_loop; }; class ExecCtxNext : public grpc_core::ExecCtx { public: explicit ExecCtxNext(void* arg) : ExecCtx(0), check_ready_to_finish_arg_(arg) {} bool CheckReadyToFinish() override { cq_is_finished_arg* a = static_cast(check_ready_to_finish_arg_); grpc_completion_queue* cq = a->cq; cq_next_data* cqd = static_cast DATA_FROM_CQ(cq); GPR_ASSERT(a->stolen_completion == nullptr); intptr_t current_last_seen_things_queued_ever = cqd->things_queued_ever.load(std::memory_order_relaxed); if (current_last_seen_things_queued_ever != a->last_seen_things_queued_ever) { a->last_seen_things_queued_ever = cqd->things_queued_ever.load(std::memory_order_relaxed); // Pop a cq_completion from the queue. Returns NULL if the queue is empty // might return NULL in some cases even if the queue is not empty; but // that // is ok and doesn't affect correctness. Might effect the tail latencies a // bit) a->stolen_completion = cqd->queue.Pop(); if (a->stolen_completion != nullptr) { return true; } } return !a->first_loop && a->deadline < grpc_core::Timestamp::Now(); } private: void* check_ready_to_finish_arg_; }; #ifndef NDEBUG static void dump_pending_tags(grpc_completion_queue* cq) { if (!GRPC_TRACE_FLAG_ENABLED(grpc_trace_pending_tags)) return; std::vector parts; parts.push_back("PENDING TAGS:"); gpr_mu_lock(cq->mu); for (size_t i = 0; i < cq->outstanding_tag_count; i++) { parts.push_back(absl::StrFormat(" %p", cq->outstanding_tags[i])); } gpr_mu_unlock(cq->mu); gpr_log(GPR_DEBUG, "%s", absl::StrJoin(parts, "").c_str()); } #else static void dump_pending_tags(grpc_completion_queue* /*cq*/) {} #endif static grpc_event cq_next(grpc_completion_queue* cq, gpr_timespec deadline, void* reserved) { grpc_event ret; cq_next_data* cqd = static_cast DATA_FROM_CQ(cq); GRPC_API_TRACE( "grpc_completion_queue_next(" "cq=%p, " "deadline=gpr_timespec { tv_sec: %" PRId64 ", tv_nsec: %d, clock_type: %d }, " "reserved=%p)", 5, (cq, deadline.tv_sec, deadline.tv_nsec, (int)deadline.clock_type, reserved)); GPR_ASSERT(!reserved); dump_pending_tags(cq); GRPC_CQ_INTERNAL_REF(cq, "next"); grpc_core::Timestamp deadline_millis = grpc_core::Timestamp::FromTimespecRoundUp(deadline); cq_is_finished_arg is_finished_arg = { cqd->things_queued_ever.load(std::memory_order_relaxed), cq, deadline_millis, nullptr, nullptr, true}; ExecCtxNext exec_ctx(&is_finished_arg); for (;;) { grpc_core::Timestamp iteration_deadline = deadline_millis; if (is_finished_arg.stolen_completion != nullptr) { grpc_cq_completion* c = is_finished_arg.stolen_completion; is_finished_arg.stolen_completion = nullptr; ret.type = GRPC_OP_COMPLETE; ret.success = c->next & 1u; ret.tag = c->tag; c->done(c->done_arg, c); break; } grpc_cq_completion* c = cqd->queue.Pop(); if (c != nullptr) { ret.type = GRPC_OP_COMPLETE; ret.success = c->next & 1u; ret.tag = c->tag; c->done(c->done_arg, c); break; } else { // If c == NULL it means either the queue is empty OR in an transient // inconsistent state. If it is the latter, we shold do a 0-timeout poll // so that the thread comes back quickly from poll to make a second // attempt at popping. Not doing this can potentially deadlock this // thread forever (if the deadline is infinity) if (cqd->queue.num_items() > 0) { iteration_deadline = grpc_core::Timestamp::ProcessEpoch(); } } if (cqd->pending_events.load(std::memory_order_acquire) == 0) { // Before returning, check if the queue has any items left over (since // MultiProducerSingleConsumerQueue::Pop() can sometimes return NULL // even if the queue is not empty. If so, keep retrying but do not // return GRPC_QUEUE_SHUTDOWN if (cqd->queue.num_items() > 0) { // Go to the beginning of the loop. No point doing a poll because // (cq->shutdown == true) is only possible when there is no pending // work (i.e cq->pending_events == 0) and any outstanding completion // events should have already been queued on this cq continue; } ret.type = GRPC_QUEUE_SHUTDOWN; ret.success = 0; break; } if (!is_finished_arg.first_loop && grpc_core::Timestamp::Now() >= deadline_millis) { ret.type = GRPC_QUEUE_TIMEOUT; ret.success = 0; dump_pending_tags(cq); break; } // The main polling work happens in grpc_pollset_work gpr_mu_lock(cq->mu); cq->num_polls++; grpc_error_handle err = cq->poller_vtable->work( POLLSET_FROM_CQ(cq), nullptr, iteration_deadline); gpr_mu_unlock(cq->mu); if (!err.ok()) { gpr_log(GPR_ERROR, "Completion queue next failed: %s", grpc_core::StatusToString(err).c_str()); if (err == absl::CancelledError()) { ret.type = GRPC_QUEUE_SHUTDOWN; } else { ret.type = GRPC_QUEUE_TIMEOUT; } ret.success = 0; dump_pending_tags(cq); break; } is_finished_arg.first_loop = false; } if (cqd->queue.num_items() > 0 && cqd->pending_events.load(std::memory_order_acquire) > 0) { gpr_mu_lock(cq->mu); (void)cq->poller_vtable->kick(POLLSET_FROM_CQ(cq), nullptr); gpr_mu_unlock(cq->mu); } GRPC_SURFACE_TRACE_RETURNED_EVENT(cq, &ret); GRPC_CQ_INTERNAL_UNREF(cq, "next"); GPR_ASSERT(is_finished_arg.stolen_completion == nullptr); return ret; } // Finishes the completion queue shutdown. This means that there are no more // completion events / tags expected from the completion queue // - Must be called under completion queue lock // - Must be called only once in completion queue's lifetime // - grpc_completion_queue_shutdown() MUST have been called before calling // this function static void cq_finish_shutdown_next(grpc_completion_queue* cq) { cq_next_data* cqd = static_cast DATA_FROM_CQ(cq); GPR_ASSERT(cqd->shutdown_called); GPR_ASSERT(cqd->pending_events.load(std::memory_order_relaxed) == 0); cq->poller_vtable->shutdown(POLLSET_FROM_CQ(cq), &cq->pollset_shutdown_done); } static void cq_shutdown_next(grpc_completion_queue* cq) { cq_next_data* cqd = static_cast DATA_FROM_CQ(cq); // Need an extra ref for cq here because: // We call cq_finish_shutdown_next() below, that would call pollset shutdown. // Pollset shutdown decrements the cq ref count which can potentially destroy // the cq (if that happens to be the last ref). // Creating an extra ref here prevents the cq from getting destroyed while // this function is still active GRPC_CQ_INTERNAL_REF(cq, "shutting_down"); gpr_mu_lock(cq->mu); if (cqd->shutdown_called) { gpr_mu_unlock(cq->mu); GRPC_CQ_INTERNAL_UNREF(cq, "shutting_down"); return; } cqd->shutdown_called = true; // Doing acq/release fetch_sub here to match with // cq_begin_op_for_next and cq_end_op_for_next functions which read/write // on this counter without necessarily holding a lock on cq if (cqd->pending_events.fetch_sub(1, std::memory_order_acq_rel) == 1) { cq_finish_shutdown_next(cq); } gpr_mu_unlock(cq->mu); GRPC_CQ_INTERNAL_UNREF(cq, "shutting_down"); } grpc_event grpc_completion_queue_next(grpc_completion_queue* cq, gpr_timespec deadline, void* reserved) { return cq->vtable->next(cq, deadline, reserved); } static int add_plucker(grpc_completion_queue* cq, void* tag, grpc_pollset_worker** worker) { cq_pluck_data* cqd = static_cast DATA_FROM_CQ(cq); if (cqd->num_pluckers == GRPC_MAX_COMPLETION_QUEUE_PLUCKERS) { return 0; } cqd->pluckers[cqd->num_pluckers].tag = tag; cqd->pluckers[cqd->num_pluckers].worker = worker; cqd->num_pluckers++; return 1; } static void del_plucker(grpc_completion_queue* cq, void* tag, grpc_pollset_worker** worker) { cq_pluck_data* cqd = static_cast DATA_FROM_CQ(cq); for (int i = 0; i < cqd->num_pluckers; i++) { if (cqd->pluckers[i].tag == tag && cqd->pluckers[i].worker == worker) { cqd->num_pluckers--; std::swap(cqd->pluckers[i], cqd->pluckers[cqd->num_pluckers]); return; } } GPR_UNREACHABLE_CODE(return); } class ExecCtxPluck : public grpc_core::ExecCtx { public: explicit ExecCtxPluck(void* arg) : ExecCtx(0), check_ready_to_finish_arg_(arg) {} bool CheckReadyToFinish() override { cq_is_finished_arg* a = static_cast(check_ready_to_finish_arg_); grpc_completion_queue* cq = a->cq; cq_pluck_data* cqd = static_cast DATA_FROM_CQ(cq); GPR_ASSERT(a->stolen_completion == nullptr); gpr_atm current_last_seen_things_queued_ever = cqd->things_queued_ever.load(std::memory_order_relaxed); if (current_last_seen_things_queued_ever != a->last_seen_things_queued_ever) { gpr_mu_lock(cq->mu); a->last_seen_things_queued_ever = cqd->things_queued_ever.load(std::memory_order_relaxed); grpc_cq_completion* c; grpc_cq_completion* prev = &cqd->completed_head; while ((c = reinterpret_cast( prev->next & ~uintptr_t{1})) != &cqd->completed_head) { if (c->tag == a->tag) { prev->next = (prev->next & uintptr_t{1}) | (c->next & ~uintptr_t{1}); if (c == cqd->completed_tail) { cqd->completed_tail = prev; } gpr_mu_unlock(cq->mu); a->stolen_completion = c; return true; } prev = c; } gpr_mu_unlock(cq->mu); } return !a->first_loop && a->deadline < grpc_core::Timestamp::Now(); } private: void* check_ready_to_finish_arg_; }; static grpc_event cq_pluck(grpc_completion_queue* cq, void* tag, gpr_timespec deadline, void* reserved) { grpc_event ret; grpc_cq_completion* c; grpc_cq_completion* prev; grpc_pollset_worker* worker = nullptr; cq_pluck_data* cqd = static_cast DATA_FROM_CQ(cq); if (GRPC_TRACE_FLAG_ENABLED(grpc_cq_pluck_trace)) { GRPC_API_TRACE( "grpc_completion_queue_pluck(" "cq=%p, tag=%p, " "deadline=gpr_timespec { tv_sec: %" PRId64 ", tv_nsec: %d, clock_type: %d }, " "reserved=%p)", 6, (cq, tag, deadline.tv_sec, deadline.tv_nsec, (int)deadline.clock_type, reserved)); } GPR_ASSERT(!reserved); dump_pending_tags(cq); GRPC_CQ_INTERNAL_REF(cq, "pluck"); gpr_mu_lock(cq->mu); grpc_core::Timestamp deadline_millis = grpc_core::Timestamp::FromTimespecRoundUp(deadline); cq_is_finished_arg is_finished_arg = { cqd->things_queued_ever.load(std::memory_order_relaxed), cq, deadline_millis, nullptr, tag, true}; ExecCtxPluck exec_ctx(&is_finished_arg); for (;;) { if (is_finished_arg.stolen_completion != nullptr) { gpr_mu_unlock(cq->mu); c = is_finished_arg.stolen_completion; is_finished_arg.stolen_completion = nullptr; ret.type = GRPC_OP_COMPLETE; ret.success = c->next & 1u; ret.tag = c->tag; c->done(c->done_arg, c); break; } prev = &cqd->completed_head; while ((c = reinterpret_cast( prev->next & ~uintptr_t{1})) != &cqd->completed_head) { if (c->tag == tag) { prev->next = (prev->next & uintptr_t{1}) | (c->next & ~uintptr_t{1}); if (c == cqd->completed_tail) { cqd->completed_tail = prev; } gpr_mu_unlock(cq->mu); ret.type = GRPC_OP_COMPLETE; ret.success = c->next & 1u; ret.tag = c->tag; c->done(c->done_arg, c); goto done; } prev = c; } if (cqd->shutdown.load(std::memory_order_relaxed)) { gpr_mu_unlock(cq->mu); ret.type = GRPC_QUEUE_SHUTDOWN; ret.success = 0; break; } if (!add_plucker(cq, tag, &worker)) { gpr_log(GPR_DEBUG, "Too many outstanding grpc_completion_queue_pluck calls: maximum " "is %d", GRPC_MAX_COMPLETION_QUEUE_PLUCKERS); gpr_mu_unlock(cq->mu); // TODO(ctiller): should we use a different result here ret.type = GRPC_QUEUE_TIMEOUT; ret.success = 0; dump_pending_tags(cq); break; } if (!is_finished_arg.first_loop && grpc_core::Timestamp::Now() >= deadline_millis) { del_plucker(cq, tag, &worker); gpr_mu_unlock(cq->mu); ret.type = GRPC_QUEUE_TIMEOUT; ret.success = 0; dump_pending_tags(cq); break; } cq->num_polls++; grpc_error_handle err = cq->poller_vtable->work(POLLSET_FROM_CQ(cq), &worker, deadline_millis); if (!err.ok()) { del_plucker(cq, tag, &worker); gpr_mu_unlock(cq->mu); gpr_log(GPR_ERROR, "Completion queue pluck failed: %s", grpc_core::StatusToString(err).c_str()); ret.type = GRPC_QUEUE_TIMEOUT; ret.success = 0; dump_pending_tags(cq); break; } is_finished_arg.first_loop = false; del_plucker(cq, tag, &worker); } done: GRPC_SURFACE_TRACE_RETURNED_EVENT(cq, &ret); GRPC_CQ_INTERNAL_UNREF(cq, "pluck"); GPR_ASSERT(is_finished_arg.stolen_completion == nullptr); return ret; } grpc_event grpc_completion_queue_pluck(grpc_completion_queue* cq, void* tag, gpr_timespec deadline, void* reserved) { return cq->vtable->pluck(cq, tag, deadline, reserved); } static void cq_finish_shutdown_pluck(grpc_completion_queue* cq) { cq_pluck_data* cqd = static_cast DATA_FROM_CQ(cq); GPR_ASSERT(cqd->shutdown_called); GPR_ASSERT(!cqd->shutdown.load(std::memory_order_relaxed)); cqd->shutdown.store(true, std::memory_order_relaxed); cq->poller_vtable->shutdown(POLLSET_FROM_CQ(cq), &cq->pollset_shutdown_done); } // NOTE: This function is almost exactly identical to cq_shutdown_next() but // merging them is a bit tricky and probably not worth it static void cq_shutdown_pluck(grpc_completion_queue* cq) { cq_pluck_data* cqd = static_cast DATA_FROM_CQ(cq); // Need an extra ref for cq here because: // We call cq_finish_shutdown_pluck() below, that would call pollset shutdown. // Pollset shutdown decrements the cq ref count which can potentially destroy // the cq (if that happens to be the last ref). // Creating an extra ref here prevents the cq from getting destroyed while // this function is still active GRPC_CQ_INTERNAL_REF(cq, "shutting_down (pluck cq)"); gpr_mu_lock(cq->mu); if (cqd->shutdown_called) { gpr_mu_unlock(cq->mu); GRPC_CQ_INTERNAL_UNREF(cq, "shutting_down (pluck cq)"); return; } cqd->shutdown_called = true; if (cqd->pending_events.fetch_sub(1, std::memory_order_acq_rel) == 1) { cq_finish_shutdown_pluck(cq); } gpr_mu_unlock(cq->mu); GRPC_CQ_INTERNAL_UNREF(cq, "shutting_down (pluck cq)"); } static void cq_finish_shutdown_callback(grpc_completion_queue* cq) { cq_callback_data* cqd = static_cast DATA_FROM_CQ(cq); auto* callback = cqd->shutdown_callback; GPR_ASSERT(cqd->shutdown_called); cq->poller_vtable->shutdown(POLLSET_FROM_CQ(cq), &cq->pollset_shutdown_done); if (grpc_iomgr_is_any_background_poller_thread()) { grpc_core::ApplicationCallbackExecCtx::Enqueue(callback, true); return; } // Schedule the callback on a closure if not internal or triggered // from a background poller thread. grpc_core::Executor::Run( GRPC_CLOSURE_CREATE(functor_callback, callback, nullptr), absl::OkStatus()); } static void cq_shutdown_callback(grpc_completion_queue* cq) { cq_callback_data* cqd = static_cast DATA_FROM_CQ(cq); // Need an extra ref for cq here because: // We call cq_finish_shutdown_callback() below, which calls pollset shutdown. // Pollset shutdown decrements the cq ref count which can potentially destroy // the cq (if that happens to be the last ref). // Creating an extra ref here prevents the cq from getting destroyed while // this function is still active GRPC_CQ_INTERNAL_REF(cq, "shutting_down (callback cq)"); gpr_mu_lock(cq->mu); if (cqd->shutdown_called) { gpr_mu_unlock(cq->mu); GRPC_CQ_INTERNAL_UNREF(cq, "shutting_down (callback cq)"); return; } cqd->shutdown_called = true; if (cqd->pending_events.fetch_sub(1, std::memory_order_acq_rel) == 1) { gpr_mu_unlock(cq->mu); cq_finish_shutdown_callback(cq); } else { gpr_mu_unlock(cq->mu); } GRPC_CQ_INTERNAL_UNREF(cq, "shutting_down (callback cq)"); } // Shutdown simply drops a ref that we reserved at creation time; if we drop // to zero here, then enter shutdown mode and wake up any waiters void grpc_completion_queue_shutdown(grpc_completion_queue* cq) { grpc_core::ApplicationCallbackExecCtx callback_exec_ctx; grpc_core::ExecCtx exec_ctx; GRPC_API_TRACE("grpc_completion_queue_shutdown(cq=%p)", 1, (cq)); cq->vtable->shutdown(cq); } void grpc_completion_queue_destroy(grpc_completion_queue* cq) { GRPC_API_TRACE("grpc_completion_queue_destroy(cq=%p)", 1, (cq)); grpc_completion_queue_shutdown(cq); grpc_core::ExecCtx exec_ctx; GRPC_CQ_INTERNAL_UNREF(cq, "destroy"); } grpc_pollset* grpc_cq_pollset(grpc_completion_queue* cq) { return cq->poller_vtable->can_get_pollset ? POLLSET_FROM_CQ(cq) : nullptr; } bool grpc_cq_can_listen(grpc_completion_queue* cq) { return cq->poller_vtable->can_listen; }