// // // 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. // // #ifndef GRPC_SRC_CORE_LIB_IOMGR_EXEC_CTX_H #define GRPC_SRC_CORE_LIB_IOMGR_EXEC_CTX_H #include #include #if __APPLE__ // Provides TARGET_OS_IPHONE #include #endif #include "absl/log/check.h" #include #include #include #include #include #include "src/core/lib/gprpp/crash.h" #include "src/core/lib/gprpp/debug_location.h" #include "src/core/lib/gprpp/fork.h" #include "src/core/lib/gprpp/time.h" #include "src/core/lib/iomgr/closure.h" #include "src/core/util/time_precise.h" #if !defined(_WIN32) || !defined(_DLL) #define EXEC_CTX exec_ctx_ #define CALLBACK_EXEC_CTX callback_exec_ctx_ #else #define EXEC_CTX exec_ctx() #define CALLBACK_EXEC_CTX callback_exec_ctx() #endif /// A combiner represents a list of work to be executed later. /// Forward declared here to avoid a circular dependency with combiner.h. typedef struct grpc_combiner grpc_combiner; // This exec_ctx is ready to return: either pre-populated, or cached as soon as // the finish_check returns true #define GRPC_EXEC_CTX_FLAG_IS_FINISHED 1 // The exec_ctx's thread is (potentially) owned by a call or channel: care // should be given to not delete said call/channel from this exec_ctx #define GRPC_EXEC_CTX_FLAG_THREAD_RESOURCE_LOOP 2 // This exec ctx was initialized by an internal thread, and should not // be counted by fork handlers #define GRPC_EXEC_CTX_FLAG_IS_INTERNAL_THREAD 4 // This application callback exec ctx was initialized by an internal thread, and // should not be counted by fork handlers #define GRPC_APP_CALLBACK_EXEC_CTX_FLAG_IS_INTERNAL_THREAD 1 namespace grpc_core { class Combiner; /// Execution context. /// A bag of data that collects information along a callstack. /// It is created on the stack at core entry points (public API or iomgr), and /// stored internally as a thread-local variable. /// /// Generally, to create an exec_ctx instance, add the following line at the top /// of the public API entry point or at the start of a thread's work function : /// /// ExecCtx exec_ctx; /// /// Access the created ExecCtx instance using : /// ExecCtx::Get() /// /// Specific responsibilities (this may grow in the future): /// - track a list of core work that needs to be delayed until the base of the /// call stack (this provides a convenient mechanism to run callbacks /// without worrying about locking issues) /// - provide a decision maker (via IsReadyToFinish) that provides a /// signal as to whether a borrowed thread should continue to do work or /// should actively try to finish up and get this thread back to its owner /// /// CONVENTIONS: /// - Instance of this must ALWAYS be constructed on the stack, never /// heap allocated. /// - Do not pass exec_ctx as a parameter to a function. Always access it using /// ExecCtx::Get(). /// - NOTE: In the future, the convention is likely to change to allow only one /// ExecCtx on a thread's stack at the same time. The TODO below /// discusses this plan in more detail. /// /// TODO(yashykt): Only allow one "active" ExecCtx on a thread at the same time. /// Stage 1: If a new one is created on the stack, it should just /// pass-through to the underlying ExecCtx deeper in the thread's /// stack. /// Stage 2: Assert if a 2nd one is ever created on the stack /// since that implies a core re-entry outside of application /// callbacks. /// class GRPC_DLL ExecCtx { public: /// Default Constructor ExecCtx() : flags_(GRPC_EXEC_CTX_FLAG_IS_FINISHED) { Fork::IncExecCtxCount(); Set(this); } /// Parameterised Constructor explicit ExecCtx(uintptr_t fl) : flags_(fl) { if (!(GRPC_EXEC_CTX_FLAG_IS_INTERNAL_THREAD & flags_)) { Fork::IncExecCtxCount(); } Set(this); } /// Destructor virtual ~ExecCtx() { flags_ |= GRPC_EXEC_CTX_FLAG_IS_FINISHED; Flush(); Set(last_exec_ctx_); if (!(GRPC_EXEC_CTX_FLAG_IS_INTERNAL_THREAD & flags_)) { Fork::DecExecCtxCount(); } } /// Disallow copy and assignment operators ExecCtx(const ExecCtx&) = delete; ExecCtx& operator=(const ExecCtx&) = delete; struct CombinerData { // currently active combiner: updated only via combiner.c Combiner* active_combiner; // last active combiner in the active combiner list Combiner* last_combiner; }; /// Only to be used by grpc-combiner code CombinerData* combiner_data() { return &combiner_data_; } /// Return pointer to grpc_closure_list grpc_closure_list* closure_list() { return &closure_list_; } /// Return flags uintptr_t flags() { return flags_; } /// Checks if there is work to be done bool HasWork() { return combiner_data_.active_combiner != nullptr || !grpc_closure_list_empty(closure_list_); } /// Flush any work that has been enqueued onto this grpc_exec_ctx. /// Caller must guarantee that no interfering locks are held. /// Returns true if work was performed, false otherwise. /// bool Flush(); /// Returns true if we'd like to leave this execution context as soon as /// possible: useful for deciding whether to do something more or not /// depending on outside context. /// bool IsReadyToFinish() { if ((flags_ & GRPC_EXEC_CTX_FLAG_IS_FINISHED) == 0) { if (CheckReadyToFinish()) { flags_ |= GRPC_EXEC_CTX_FLAG_IS_FINISHED; return true; } return false; } else { return true; } } void SetReadyToFinishFlag() { flags_ |= GRPC_EXEC_CTX_FLAG_IS_FINISHED; } Timestamp Now() { return Timestamp::Now(); } void InvalidateNow() { #if !TARGET_OS_IPHONE time_cache_.InvalidateCache(); #endif } void SetNowIomgrShutdown() { #if !TARGET_OS_IPHONE // We get to do a test only set now on this path just because iomgr // is getting removed and no point adding more interfaces for it. time_cache_.TestOnlySetNow(Timestamp::InfFuture()); #endif } void TestOnlySetNow(Timestamp now) { #if !TARGET_OS_IPHONE time_cache_.TestOnlySetNow(now); #endif } /// Gets pointer to current exec_ctx. static ExecCtx* Get() { return EXEC_CTX; } static void Run(const DebugLocation& location, grpc_closure* closure, grpc_error_handle error); static void RunList(const DebugLocation& location, grpc_closure_list* list); protected: /// Check if ready to finish. virtual bool CheckReadyToFinish() { return false; } /// Disallow delete on ExecCtx. static void operator delete(void* /* p */) { abort(); } private: /// Set EXEC_CTX to ctx. static void Set(ExecCtx* ctx) { EXEC_CTX = ctx; } grpc_closure_list closure_list_ = GRPC_CLOSURE_LIST_INIT; CombinerData combiner_data_ = {nullptr, nullptr}; uintptr_t flags_; #if !TARGET_OS_IPHONE ScopedTimeCache time_cache_; #endif #if !defined(_WIN32) || !defined(_DLL) static thread_local ExecCtx* exec_ctx_; #else // cannot be thread_local data member (e.g. exec_ctx_) on windows static ExecCtx*& exec_ctx(); #endif ExecCtx* last_exec_ctx_ = Get(); }; /// Application-callback execution context. /// A bag of data that collects information along a callstack. /// It is created on the stack at core entry points, and stored internally /// as a thread-local variable. /// /// There are three key differences between this structure and ExecCtx: /// 1. ApplicationCallbackExecCtx builds a list of application-level /// callbacks, but ExecCtx builds a list of internal callbacks to invoke. /// 2. ApplicationCallbackExecCtx invokes its callbacks only at destruction; /// there is no explicit Flush method. /// 3. If more than one ApplicationCallbackExecCtx is created on the thread's /// stack, only the one closest to the base of the stack is actually /// active and this is the only one that enqueues application callbacks. /// (Unlike ExecCtx, it is not feasible to prevent multiple of these on the /// stack since the executing application callback may itself enter core. /// However, the new one created will just pass callbacks through to the /// base one and those will not be executed until the return to the /// destructor of the base one, preventing unlimited stack growth.) /// /// This structure exists because application callbacks may themselves cause a /// core re-entry (e.g., through a public API call) and if that call in turn /// causes another application-callback, there could be arbitrarily growing /// stacks of core re-entries. Instead, any application callbacks instead should /// not be invoked until other core work is done and other application callbacks /// have completed. To accomplish this, any application callback should be /// enqueued using ApplicationCallbackExecCtx::Enqueue . /// /// CONVENTIONS: /// - Instances of this must ALWAYS be constructed on the stack, never /// heap allocated. /// - Instances of this are generally constructed before ExecCtx when needed. /// The only exception is for ExecCtx's that are explicitly flushed and /// that survive beyond the scope of the function that can cause application /// callbacks to be invoked (e.g., in the timer thread). /// /// Generally, core entry points that may trigger application-level callbacks /// will have the following declarations: /// /// ApplicationCallbackExecCtx callback_exec_ctx; /// ExecCtx exec_ctx; /// /// This ordering is important to make sure that the ApplicationCallbackExecCtx /// is destroyed after the ExecCtx (to prevent the re-entry problem described /// above, as well as making sure that ExecCtx core callbacks are invoked first) /// /// class GRPC_DLL ApplicationCallbackExecCtx { public: /// Default Constructor ApplicationCallbackExecCtx() { Set(this, flags_); } /// Parameterised Constructor explicit ApplicationCallbackExecCtx(uintptr_t fl) : flags_(fl) { Set(this, flags_); } ~ApplicationCallbackExecCtx() { if (Get() == this) { while (head_ != nullptr) { auto* f = head_; head_ = f->internal_next; if (f->internal_next == nullptr) { tail_ = nullptr; } (*f->functor_run)(f, f->internal_success); } CALLBACK_EXEC_CTX = nullptr; if (!(GRPC_APP_CALLBACK_EXEC_CTX_FLAG_IS_INTERNAL_THREAD & flags_)) { Fork::DecExecCtxCount(); } } else { DCHECK_EQ(head_, nullptr); DCHECK_EQ(tail_, nullptr); } } uintptr_t Flags() { return flags_; } static ApplicationCallbackExecCtx* Get() { return CALLBACK_EXEC_CTX; } static void Set(ApplicationCallbackExecCtx* exec_ctx, uintptr_t flags) { if (Get() == nullptr) { if (!(GRPC_APP_CALLBACK_EXEC_CTX_FLAG_IS_INTERNAL_THREAD & flags)) { Fork::IncExecCtxCount(); } CALLBACK_EXEC_CTX = exec_ctx; } } static void Enqueue(grpc_completion_queue_functor* functor, int is_success) { functor->internal_success = is_success; functor->internal_next = nullptr; ApplicationCallbackExecCtx* ctx = Get(); if (ctx->head_ == nullptr) { ctx->head_ = functor; } if (ctx->tail_ != nullptr) { ctx->tail_->internal_next = functor; } ctx->tail_ = functor; } static bool Available() { return Get() != nullptr; } private: uintptr_t flags_{0u}; grpc_completion_queue_functor* head_{nullptr}; grpc_completion_queue_functor* tail_{nullptr}; #if !defined(_WIN32) || !defined(_DLL) static thread_local ApplicationCallbackExecCtx* callback_exec_ctx_; #else // cannot be thread_local data member (e.g. callback_exec_ctx_) on windows static ApplicationCallbackExecCtx*& callback_exec_ctx(); #endif }; template void EnsureRunInExecCtx(F f) { if (ExecCtx::Get() == nullptr) { ApplicationCallbackExecCtx app_ctx; ExecCtx exec_ctx; f(); } else { f(); } } #undef EXEC_CTX #undef CALLBACK_EXEC_CTX } // namespace grpc_core #endif // GRPC_SRC_CORE_LIB_IOMGR_EXEC_CTX_H