Abseil Common Libraries (C++) (grcp 依赖)
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1129 lines
44 KiB
1129 lines
44 KiB
// Copyright 2017 The Abseil Authors. |
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// |
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// Licensed under the Apache License, Version 2.0 (the "License"); |
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// you may not use this file except in compliance with the License. |
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// You may obtain a copy of the License at |
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// |
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// https://www.apache.org/licenses/LICENSE-2.0 |
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// |
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// Unless required by applicable law or agreed to in writing, software |
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// distributed under the License is distributed on an "AS IS" BASIS, |
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// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. |
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// See the License for the specific language governing permissions and |
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// limitations under the License. |
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// |
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// ----------------------------------------------------------------------------- |
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// mutex.h |
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// ----------------------------------------------------------------------------- |
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// |
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// This header file defines a `Mutex` -- a mutually exclusive lock -- and the |
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// most common type of synchronization primitive for facilitating locks on |
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// shared resources. A mutex is used to prevent multiple threads from accessing |
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// and/or writing to a shared resource concurrently. |
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// |
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// Unlike a `std::mutex`, the Abseil `Mutex` provides the following additional |
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// features: |
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// * Conditional predicates intrinsic to the `Mutex` object |
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// * Shared/reader locks, in addition to standard exclusive/writer locks |
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// * Deadlock detection and debug support. |
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// |
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// The following helper classes are also defined within this file: |
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// |
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// MutexLock - An RAII wrapper to acquire and release a `Mutex` for exclusive/ |
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// write access within the current scope. |
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// |
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// ReaderMutexLock |
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// - An RAII wrapper to acquire and release a `Mutex` for shared/read |
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// access within the current scope. |
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// |
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// WriterMutexLock |
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// - Effectively an alias for `MutexLock` above, designed for use in |
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// distinguishing reader and writer locks within code. |
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// |
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// In addition to simple mutex locks, this file also defines ways to perform |
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// locking under certain conditions. |
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// |
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// Condition - (Preferred) Used to wait for a particular predicate that |
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// depends on state protected by the `Mutex` to become true. |
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// CondVar - A lower-level variant of `Condition` that relies on |
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// application code to explicitly signal the `CondVar` when |
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// a condition has been met. |
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// |
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// See below for more information on using `Condition` or `CondVar`. |
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// |
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// Mutexes and mutex behavior can be quite complicated. The information within |
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// this header file is limited, as a result. Please consult the Mutex guide for |
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// more complete information and examples. |
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#ifndef ABSL_SYNCHRONIZATION_MUTEX_H_ |
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#define ABSL_SYNCHRONIZATION_MUTEX_H_ |
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#include <atomic> |
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#include <cstdint> |
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#include <cstring> |
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#include <iterator> |
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#include <string> |
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#include "absl/base/const_init.h" |
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#include "absl/base/internal/identity.h" |
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#include "absl/base/internal/low_level_alloc.h" |
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#include "absl/base/internal/thread_identity.h" |
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#include "absl/base/internal/tsan_mutex_interface.h" |
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#include "absl/base/port.h" |
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#include "absl/base/thread_annotations.h" |
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#include "absl/synchronization/internal/kernel_timeout.h" |
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#include "absl/synchronization/internal/per_thread_sem.h" |
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#include "absl/time/time.h" |
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namespace absl { |
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ABSL_NAMESPACE_BEGIN |
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class Condition; |
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struct SynchWaitParams; |
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// ----------------------------------------------------------------------------- |
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// Mutex |
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// ----------------------------------------------------------------------------- |
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// |
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// A `Mutex` is a non-reentrant (aka non-recursive) Mutually Exclusive lock |
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// on some resource, typically a variable or data structure with associated |
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// invariants. Proper usage of mutexes prevents concurrent access by different |
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// threads to the same resource. |
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// |
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// A `Mutex` has two basic operations: `Mutex::Lock()` and `Mutex::Unlock()`. |
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// The `Lock()` operation *acquires* a `Mutex` (in a state known as an |
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// *exclusive* -- or write -- lock), while the `Unlock()` operation *releases* a |
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// Mutex. During the span of time between the Lock() and Unlock() operations, |
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// a mutex is said to be *held*. By design all mutexes support exclusive/write |
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// locks, as this is the most common way to use a mutex. |
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// |
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// The `Mutex` state machine for basic lock/unlock operations is quite simple: |
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// |
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// | | Lock() | Unlock() | |
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// |----------------+------------+----------| |
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// | Free | Exclusive | invalid | |
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// | Exclusive | blocks | Free | |
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// |
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// Attempts to `Unlock()` must originate from the thread that performed the |
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// corresponding `Lock()` operation. |
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// |
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// An "invalid" operation is disallowed by the API. The `Mutex` implementation |
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// is allowed to do anything on an invalid call, including but not limited to |
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// crashing with a useful error message, silently succeeding, or corrupting |
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// data structures. In debug mode, the implementation attempts to crash with a |
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// useful error message. |
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// |
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// `Mutex` is not guaranteed to be "fair" in prioritizing waiting threads; it |
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// is, however, approximately fair over long periods, and starvation-free for |
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// threads at the same priority. |
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// |
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// The lock/unlock primitives are now annotated with lock annotations |
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// defined in (base/thread_annotations.h). When writing multi-threaded code, |
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// you should use lock annotations whenever possible to document your lock |
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// synchronization policy. Besides acting as documentation, these annotations |
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// also help compilers or static analysis tools to identify and warn about |
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// issues that could potentially result in race conditions and deadlocks. |
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// |
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// For more information about the lock annotations, please see |
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// [Thread Safety Analysis](http://clang.llvm.org/docs/ThreadSafetyAnalysis.html) |
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// in the Clang documentation. |
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// |
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// See also `MutexLock`, below, for scoped `Mutex` acquisition. |
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class ABSL_LOCKABLE Mutex { |
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public: |
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// Creates a `Mutex` that is not held by anyone. This constructor is |
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// typically used for Mutexes allocated on the heap or the stack. |
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// |
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// To create `Mutex` instances with static storage duration |
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// (e.g. a namespace-scoped or global variable), see |
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// `Mutex::Mutex(absl::kConstInit)` below instead. |
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Mutex(); |
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// Creates a mutex with static storage duration. A global variable |
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// constructed this way avoids the lifetime issues that can occur on program |
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// startup and shutdown. (See absl/base/const_init.h.) |
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// |
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// For Mutexes allocated on the heap and stack, instead use the default |
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// constructor, which can interact more fully with the thread sanitizer. |
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// |
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// Example usage: |
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// namespace foo { |
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// ABSL_CONST_INIT absl::Mutex mu(absl::kConstInit); |
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// } |
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explicit constexpr Mutex(absl::ConstInitType); |
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~Mutex(); |
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// Mutex::Lock() |
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// |
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// Blocks the calling thread, if necessary, until this `Mutex` is free, and |
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// then acquires it exclusively. (This lock is also known as a "write lock.") |
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void Lock() ABSL_EXCLUSIVE_LOCK_FUNCTION(); |
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// Mutex::Unlock() |
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// |
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// Releases this `Mutex` and returns it from the exclusive/write state to the |
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// free state. Calling thread must hold the `Mutex` exclusively. |
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void Unlock() ABSL_UNLOCK_FUNCTION(); |
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// Mutex::TryLock() |
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// |
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// If the mutex can be acquired without blocking, does so exclusively and |
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// returns `true`. Otherwise, returns `false`. Returns `true` with high |
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// probability if the `Mutex` was free. |
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bool TryLock() ABSL_EXCLUSIVE_TRYLOCK_FUNCTION(true); |
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// Mutex::AssertHeld() |
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// |
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// Require that the mutex be held exclusively (write mode) by this thread. |
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// |
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// If the mutex is not currently held by this thread, this function may report |
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// an error (typically by crashing with a diagnostic) or it may do nothing. |
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// This function is intended only as a tool to assist debugging; it doesn't |
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// guarantee correctness. |
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void AssertHeld() const ABSL_ASSERT_EXCLUSIVE_LOCK(); |
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// --------------------------------------------------------------------------- |
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// Reader-Writer Locking |
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// --------------------------------------------------------------------------- |
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// A Mutex can also be used as a starvation-free reader-writer lock. |
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// Neither read-locks nor write-locks are reentrant/recursive to avoid |
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// potential client programming errors. |
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// |
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// The Mutex API provides `Writer*()` aliases for the existing `Lock()`, |
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// `Unlock()` and `TryLock()` methods for use within applications mixing |
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// reader/writer locks. Using `Reader*()` and `Writer*()` operations in this |
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// manner can make locking behavior clearer when mixing read and write modes. |
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// |
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// Introducing reader locks necessarily complicates the `Mutex` state |
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// machine somewhat. The table below illustrates the allowed state transitions |
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// of a mutex in such cases. Note that ReaderLock() may block even if the lock |
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// is held in shared mode; this occurs when another thread is blocked on a |
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// call to WriterLock(). |
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// |
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// --------------------------------------------------------------------------- |
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// Operation: WriterLock() Unlock() ReaderLock() ReaderUnlock() |
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// --------------------------------------------------------------------------- |
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// State |
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// --------------------------------------------------------------------------- |
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// Free Exclusive invalid Shared(1) invalid |
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// Shared(1) blocks invalid Shared(2) or blocks Free |
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// Shared(n) n>1 blocks invalid Shared(n+1) or blocks Shared(n-1) |
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// Exclusive blocks Free blocks invalid |
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// --------------------------------------------------------------------------- |
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// |
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// In comments below, "shared" refers to a state of Shared(n) for any n > 0. |
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// Mutex::ReaderLock() |
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// |
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// Blocks the calling thread, if necessary, until this `Mutex` is either free, |
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// or in shared mode, and then acquires a share of it. Note that |
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// `ReaderLock()` will block if some other thread has an exclusive/writer lock |
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// on the mutex. |
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void ReaderLock() ABSL_SHARED_LOCK_FUNCTION(); |
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// Mutex::ReaderUnlock() |
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// |
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// Releases a read share of this `Mutex`. `ReaderUnlock` may return a mutex to |
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// the free state if this thread holds the last reader lock on the mutex. Note |
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// that you cannot call `ReaderUnlock()` on a mutex held in write mode. |
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void ReaderUnlock() ABSL_UNLOCK_FUNCTION(); |
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// Mutex::ReaderTryLock() |
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// |
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// If the mutex can be acquired without blocking, acquires this mutex for |
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// shared access and returns `true`. Otherwise, returns `false`. Returns |
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// `true` with high probability if the `Mutex` was free or shared. |
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bool ReaderTryLock() ABSL_SHARED_TRYLOCK_FUNCTION(true); |
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// Mutex::AssertReaderHeld() |
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// |
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// Require that the mutex be held at least in shared mode (read mode) by this |
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// thread. |
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// |
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// If the mutex is not currently held by this thread, this function may report |
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// an error (typically by crashing with a diagnostic) or it may do nothing. |
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// This function is intended only as a tool to assist debugging; it doesn't |
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// guarantee correctness. |
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void AssertReaderHeld() const ABSL_ASSERT_SHARED_LOCK(); |
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// Mutex::WriterLock() |
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// Mutex::WriterUnlock() |
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// Mutex::WriterTryLock() |
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// |
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// Aliases for `Mutex::Lock()`, `Mutex::Unlock()`, and `Mutex::TryLock()`. |
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// |
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// These methods may be used (along with the complementary `Reader*()` |
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// methods) to distingish simple exclusive `Mutex` usage (`Lock()`, |
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// etc.) from reader/writer lock usage. |
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void WriterLock() ABSL_EXCLUSIVE_LOCK_FUNCTION() { this->Lock(); } |
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void WriterUnlock() ABSL_UNLOCK_FUNCTION() { this->Unlock(); } |
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bool WriterTryLock() ABSL_EXCLUSIVE_TRYLOCK_FUNCTION(true) { |
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return this->TryLock(); |
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} |
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// --------------------------------------------------------------------------- |
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// Conditional Critical Regions |
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// --------------------------------------------------------------------------- |
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// Conditional usage of a `Mutex` can occur using two distinct paradigms: |
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// |
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// * Use of `Mutex` member functions with `Condition` objects. |
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// * Use of the separate `CondVar` abstraction. |
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// |
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// In general, prefer use of `Condition` and the `Mutex` member functions |
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// listed below over `CondVar`. When there are multiple threads waiting on |
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// distinctly different conditions, however, a battery of `CondVar`s may be |
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// more efficient. This section discusses use of `Condition` objects. |
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// |
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// `Mutex` contains member functions for performing lock operations only under |
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// certain conditions, of class `Condition`. For correctness, the `Condition` |
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// must return a boolean that is a pure function, only of state protected by |
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// the `Mutex`. The condition must be invariant w.r.t. environmental state |
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// such as thread, cpu id, or time, and must be `noexcept`. The condition will |
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// always be invoked with the mutex held in at least read mode, so you should |
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// not block it for long periods or sleep it on a timer. |
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// |
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// Since a condition must not depend directly on the current time, use |
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// `*WithTimeout()` member function variants to make your condition |
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// effectively true after a given duration, or `*WithDeadline()` variants to |
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// make your condition effectively true after a given time. |
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// |
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// The condition function should have no side-effects aside from debug |
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// logging; as a special exception, the function may acquire other mutexes |
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// provided it releases all those that it acquires. (This exception was |
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// required to allow logging.) |
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// Mutex::Await() |
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// |
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// Unlocks this `Mutex` and blocks until simultaneously both `cond` is `true` |
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// and this `Mutex` can be reacquired, then reacquires this `Mutex` in the |
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// same mode in which it was previously held. If the condition is initially |
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// `true`, `Await()` *may* skip the release/re-acquire step. |
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// |
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// `Await()` requires that this thread holds this `Mutex` in some mode. |
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void Await(const Condition &cond); |
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// Mutex::LockWhen() |
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// Mutex::ReaderLockWhen() |
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// Mutex::WriterLockWhen() |
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// |
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// Blocks until simultaneously both `cond` is `true` and this `Mutex` can |
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// be acquired, then atomically acquires this `Mutex`. `LockWhen()` is |
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// logically equivalent to `*Lock(); Await();` though they may have different |
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// performance characteristics. |
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void LockWhen(const Condition &cond) ABSL_EXCLUSIVE_LOCK_FUNCTION(); |
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void ReaderLockWhen(const Condition &cond) ABSL_SHARED_LOCK_FUNCTION(); |
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void WriterLockWhen(const Condition &cond) ABSL_EXCLUSIVE_LOCK_FUNCTION() { |
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this->LockWhen(cond); |
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} |
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// --------------------------------------------------------------------------- |
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// Mutex Variants with Timeouts/Deadlines |
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// --------------------------------------------------------------------------- |
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// Mutex::AwaitWithTimeout() |
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// Mutex::AwaitWithDeadline() |
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// |
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// Unlocks this `Mutex` and blocks until simultaneously: |
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// - either `cond` is true or the {timeout has expired, deadline has passed} |
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// and |
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// - this `Mutex` can be reacquired, |
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// then reacquire this `Mutex` in the same mode in which it was previously |
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// held, returning `true` iff `cond` is `true` on return. |
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// |
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// If the condition is initially `true`, the implementation *may* skip the |
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// release/re-acquire step and return immediately. |
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// |
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// Deadlines in the past are equivalent to an immediate deadline. |
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// Negative timeouts are equivalent to a zero timeout. |
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// |
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// This method requires that this thread holds this `Mutex` in some mode. |
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bool AwaitWithTimeout(const Condition &cond, absl::Duration timeout); |
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bool AwaitWithDeadline(const Condition &cond, absl::Time deadline); |
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// Mutex::LockWhenWithTimeout() |
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// Mutex::ReaderLockWhenWithTimeout() |
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// Mutex::WriterLockWhenWithTimeout() |
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// |
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// Blocks until simultaneously both: |
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// - either `cond` is `true` or the timeout has expired, and |
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// - this `Mutex` can be acquired, |
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// then atomically acquires this `Mutex`, returning `true` iff `cond` is |
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// `true` on return. |
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// |
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// Negative timeouts are equivalent to a zero timeout. |
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bool LockWhenWithTimeout(const Condition &cond, absl::Duration timeout) |
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ABSL_EXCLUSIVE_LOCK_FUNCTION(); |
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bool ReaderLockWhenWithTimeout(const Condition &cond, absl::Duration timeout) |
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ABSL_SHARED_LOCK_FUNCTION(); |
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bool WriterLockWhenWithTimeout(const Condition &cond, absl::Duration timeout) |
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ABSL_EXCLUSIVE_LOCK_FUNCTION() { |
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return this->LockWhenWithTimeout(cond, timeout); |
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} |
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// Mutex::LockWhenWithDeadline() |
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// Mutex::ReaderLockWhenWithDeadline() |
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// Mutex::WriterLockWhenWithDeadline() |
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// |
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// Blocks until simultaneously both: |
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// - either `cond` is `true` or the deadline has been passed, and |
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// - this `Mutex` can be acquired, |
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// then atomically acquires this Mutex, returning `true` iff `cond` is `true` |
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// on return. |
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// |
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// Deadlines in the past are equivalent to an immediate deadline. |
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bool LockWhenWithDeadline(const Condition &cond, absl::Time deadline) |
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ABSL_EXCLUSIVE_LOCK_FUNCTION(); |
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bool ReaderLockWhenWithDeadline(const Condition &cond, absl::Time deadline) |
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ABSL_SHARED_LOCK_FUNCTION(); |
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bool WriterLockWhenWithDeadline(const Condition &cond, absl::Time deadline) |
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ABSL_EXCLUSIVE_LOCK_FUNCTION() { |
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return this->LockWhenWithDeadline(cond, deadline); |
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} |
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// --------------------------------------------------------------------------- |
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// Debug Support: Invariant Checking, Deadlock Detection, Logging. |
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// --------------------------------------------------------------------------- |
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// Mutex::EnableInvariantDebugging() |
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// |
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// If `invariant`!=null and if invariant debugging has been enabled globally, |
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// cause `(*invariant)(arg)` to be called at moments when the invariant for |
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// this `Mutex` should hold (for example: just after acquire, just before |
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// release). |
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// |
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// The routine `invariant` should have no side-effects since it is not |
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// guaranteed how many times it will be called; it should check the invariant |
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// and crash if it does not hold. Enabling global invariant debugging may |
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// substantially reduce `Mutex` performance; it should be set only for |
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// non-production runs. Optimization options may also disable invariant |
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// checks. |
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void EnableInvariantDebugging(void (*invariant)(void *), void *arg); |
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// Mutex::EnableDebugLog() |
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// |
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// Cause all subsequent uses of this `Mutex` to be logged via |
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// `ABSL_RAW_LOG(INFO)`. Log entries are tagged with `name` if no previous |
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// call to `EnableInvariantDebugging()` or `EnableDebugLog()` has been made. |
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// |
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// Note: This method substantially reduces `Mutex` performance. |
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void EnableDebugLog(const char *name); |
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// Deadlock detection |
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// Mutex::ForgetDeadlockInfo() |
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// |
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// Forget any deadlock-detection information previously gathered |
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// about this `Mutex`. Call this method in debug mode when the lock ordering |
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// of a `Mutex` changes. |
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void ForgetDeadlockInfo(); |
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// Mutex::AssertNotHeld() |
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// |
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// Return immediately if this thread does not hold this `Mutex` in any |
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// mode; otherwise, may report an error (typically by crashing with a |
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// diagnostic), or may return immediately. |
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// |
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// Currently this check is performed only if all of: |
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// - in debug mode |
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// - SetMutexDeadlockDetectionMode() has been set to kReport or kAbort |
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// - number of locks concurrently held by this thread is not large. |
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// are true. |
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void AssertNotHeld() const; |
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// Special cases. |
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// A `MuHow` is a constant that indicates how a lock should be acquired. |
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// Internal implementation detail. Clients should ignore. |
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typedef const struct MuHowS *MuHow; |
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// Mutex::InternalAttemptToUseMutexInFatalSignalHandler() |
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// |
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// Causes the `Mutex` implementation to prepare itself for re-entry caused by |
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// future use of `Mutex` within a fatal signal handler. This method is |
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// intended for use only for last-ditch attempts to log crash information. |
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// It does not guarantee that attempts to use Mutexes within the handler will |
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// not deadlock; it merely makes other faults less likely. |
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// |
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// WARNING: This routine must be invoked from a signal handler, and the |
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// signal handler must either loop forever or terminate the process. |
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// Attempts to return from (or `longjmp` out of) the signal handler once this |
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// call has been made may cause arbitrary program behaviour including |
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// crashes and deadlocks. |
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static void InternalAttemptToUseMutexInFatalSignalHandler(); |
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private: |
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std::atomic<intptr_t> mu_; // The Mutex state. |
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// Post()/Wait() versus associated PerThreadSem; in class for required |
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// friendship with PerThreadSem. |
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static void IncrementSynchSem(Mutex *mu, base_internal::PerThreadSynch *w); |
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static bool DecrementSynchSem(Mutex *mu, base_internal::PerThreadSynch *w, |
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synchronization_internal::KernelTimeout t); |
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// slow path acquire |
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void LockSlowLoop(SynchWaitParams *waitp, int flags); |
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// wrappers around LockSlowLoop() |
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bool LockSlowWithDeadline(MuHow how, const Condition *cond, |
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synchronization_internal::KernelTimeout t, |
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int flags); |
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void LockSlow(MuHow how, const Condition *cond, |
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int flags) ABSL_ATTRIBUTE_COLD; |
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// slow path release |
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void UnlockSlow(SynchWaitParams *waitp) ABSL_ATTRIBUTE_COLD; |
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// Common code between Await() and AwaitWithTimeout/Deadline() |
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bool AwaitCommon(const Condition &cond, |
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synchronization_internal::KernelTimeout t); |
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// Attempt to remove thread s from queue. |
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void TryRemove(base_internal::PerThreadSynch *s); |
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// Block a thread on mutex. |
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void Block(base_internal::PerThreadSynch *s); |
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// Wake a thread; return successor. |
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base_internal::PerThreadSynch *Wakeup(base_internal::PerThreadSynch *w); |
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friend class CondVar; // for access to Trans()/Fer(). |
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void Trans(MuHow how); // used for CondVar->Mutex transfer |
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void Fer( |
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base_internal::PerThreadSynch *w); // used for CondVar->Mutex transfer |
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// Catch the error of writing Mutex when intending MutexLock. |
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Mutex(const volatile Mutex * /*ignored*/) {} // NOLINT(runtime/explicit) |
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Mutex(const Mutex&) = delete; |
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Mutex& operator=(const Mutex&) = delete; |
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}; |
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// ----------------------------------------------------------------------------- |
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// Mutex RAII Wrappers |
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// ----------------------------------------------------------------------------- |
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// MutexLock |
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// |
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// `MutexLock` is a helper class, which acquires and releases a `Mutex` via |
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// RAII. |
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// |
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// Example: |
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// |
|
// Class Foo { |
|
// public: |
|
// Foo::Bar* Baz() { |
|
// MutexLock lock(&mu_); |
|
// ... |
|
// return bar; |
|
// } |
|
// |
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// private: |
|
// Mutex mu_; |
|
// }; |
|
class ABSL_SCOPED_LOCKABLE MutexLock { |
|
public: |
|
// Constructors |
|
|
|
// Calls `mu->Lock()` and returns when that call returns. That is, `*mu` is |
|
// guaranteed to be locked when this object is constructed. Requires that |
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// `mu` be dereferenceable. |
|
explicit MutexLock(Mutex *mu) ABSL_EXCLUSIVE_LOCK_FUNCTION(mu) : mu_(mu) { |
|
this->mu_->Lock(); |
|
} |
|
|
|
// Like above, but calls `mu->LockWhen(cond)` instead. That is, in addition to |
|
// the above, the condition given by `cond` is also guaranteed to hold when |
|
// this object is constructed. |
|
explicit MutexLock(Mutex *mu, const Condition &cond) |
|
ABSL_EXCLUSIVE_LOCK_FUNCTION(mu) |
|
: mu_(mu) { |
|
this->mu_->LockWhen(cond); |
|
} |
|
|
|
MutexLock(const MutexLock &) = delete; // NOLINT(runtime/mutex) |
|
MutexLock(MutexLock&&) = delete; // NOLINT(runtime/mutex) |
|
MutexLock& operator=(const MutexLock&) = delete; |
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MutexLock& operator=(MutexLock&&) = delete; |
|
|
|
~MutexLock() ABSL_UNLOCK_FUNCTION() { this->mu_->Unlock(); } |
|
|
|
private: |
|
Mutex *const mu_; |
|
}; |
|
|
|
// ReaderMutexLock |
|
// |
|
// The `ReaderMutexLock` is a helper class, like `MutexLock`, which acquires and |
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// releases a shared lock on a `Mutex` via RAII. |
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class ABSL_SCOPED_LOCKABLE ReaderMutexLock { |
|
public: |
|
explicit ReaderMutexLock(Mutex *mu) ABSL_SHARED_LOCK_FUNCTION(mu) : mu_(mu) { |
|
mu->ReaderLock(); |
|
} |
|
|
|
explicit ReaderMutexLock(Mutex *mu, const Condition &cond) |
|
ABSL_SHARED_LOCK_FUNCTION(mu) |
|
: mu_(mu) { |
|
mu->ReaderLockWhen(cond); |
|
} |
|
|
|
ReaderMutexLock(const ReaderMutexLock&) = delete; |
|
ReaderMutexLock(ReaderMutexLock&&) = delete; |
|
ReaderMutexLock& operator=(const ReaderMutexLock&) = delete; |
|
ReaderMutexLock& operator=(ReaderMutexLock&&) = delete; |
|
|
|
~ReaderMutexLock() ABSL_UNLOCK_FUNCTION() { this->mu_->ReaderUnlock(); } |
|
|
|
private: |
|
Mutex *const mu_; |
|
}; |
|
|
|
// WriterMutexLock |
|
// |
|
// The `WriterMutexLock` is a helper class, like `MutexLock`, which acquires and |
|
// releases a write (exclusive) lock on a `Mutex` via RAII. |
|
class ABSL_SCOPED_LOCKABLE WriterMutexLock { |
|
public: |
|
explicit WriterMutexLock(Mutex *mu) ABSL_EXCLUSIVE_LOCK_FUNCTION(mu) |
|
: mu_(mu) { |
|
mu->WriterLock(); |
|
} |
|
|
|
explicit WriterMutexLock(Mutex *mu, const Condition &cond) |
|
ABSL_EXCLUSIVE_LOCK_FUNCTION(mu) |
|
: mu_(mu) { |
|
mu->WriterLockWhen(cond); |
|
} |
|
|
|
WriterMutexLock(const WriterMutexLock&) = delete; |
|
WriterMutexLock(WriterMutexLock&&) = delete; |
|
WriterMutexLock& operator=(const WriterMutexLock&) = delete; |
|
WriterMutexLock& operator=(WriterMutexLock&&) = delete; |
|
|
|
~WriterMutexLock() ABSL_UNLOCK_FUNCTION() { this->mu_->WriterUnlock(); } |
|
|
|
private: |
|
Mutex *const mu_; |
|
}; |
|
|
|
// ----------------------------------------------------------------------------- |
|
// Condition |
|
// ----------------------------------------------------------------------------- |
|
// |
|
// `Mutex` contains a number of member functions which take a `Condition` as an |
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// argument; clients can wait for conditions to become `true` before attempting |
|
// to acquire the mutex. These sections are known as "condition critical" |
|
// sections. To use a `Condition`, you simply need to construct it, and use |
|
// within an appropriate `Mutex` member function; everything else in the |
|
// `Condition` class is an implementation detail. |
|
// |
|
// A `Condition` is specified as a function pointer which returns a boolean. |
|
// `Condition` functions should be pure functions -- their results should depend |
|
// only on passed arguments, should not consult any external state (such as |
|
// clocks), and should have no side-effects, aside from debug logging. Any |
|
// objects that the function may access should be limited to those which are |
|
// constant while the mutex is blocked on the condition (e.g. a stack variable), |
|
// or objects of state protected explicitly by the mutex. |
|
// |
|
// No matter which construction is used for `Condition`, the underlying |
|
// function pointer / functor / callable must not throw any |
|
// exceptions. Correctness of `Mutex` / `Condition` is not guaranteed in |
|
// the face of a throwing `Condition`. (When Abseil is allowed to depend |
|
// on C++17, these function pointers will be explicitly marked |
|
// `noexcept`; until then this requirement cannot be enforced in the |
|
// type system.) |
|
// |
|
// Note: to use a `Condition`, you need only construct it and pass it to a |
|
// suitable `Mutex' member function, such as `Mutex::Await()`, or to the |
|
// constructor of one of the scope guard classes. |
|
// |
|
// Example using LockWhen/Unlock: |
|
// |
|
// // assume count_ is not internal reference count |
|
// int count_ ABSL_GUARDED_BY(mu_); |
|
// Condition count_is_zero(+[](int *count) { return *count == 0; }, &count_); |
|
// |
|
// mu_.LockWhen(count_is_zero); |
|
// // ... |
|
// mu_.Unlock(); |
|
// |
|
// Example using a scope guard: |
|
// |
|
// { |
|
// MutexLock lock(&mu_, count_is_zero); |
|
// // ... |
|
// } |
|
// |
|
// When multiple threads are waiting on exactly the same condition, make sure |
|
// that they are constructed with the same parameters (same pointer to function |
|
// + arg, or same pointer to object + method), so that the mutex implementation |
|
// can avoid redundantly evaluating the same condition for each thread. |
|
class Condition { |
|
public: |
|
// A Condition that returns the result of "(*func)(arg)" |
|
Condition(bool (*func)(void *), void *arg); |
|
|
|
// Templated version for people who are averse to casts. |
|
// |
|
// To use a lambda, prepend it with unary plus, which converts the lambda |
|
// into a function pointer: |
|
// Condition(+[](T* t) { return ...; }, arg). |
|
// |
|
// Note: lambdas in this case must contain no bound variables. |
|
// |
|
// See class comment for performance advice. |
|
template<typename T> |
|
Condition(bool (*func)(T *), T *arg); |
|
|
|
// Templated version for invoking a method that returns a `bool`. |
|
// |
|
// `Condition(object, &Class::Method)` constructs a `Condition` that evaluates |
|
// `object->Method()`. |
|
// |
|
// Implementation Note: `absl::internal::identity` is used to allow methods to |
|
// come from base classes. A simpler signature like |
|
// `Condition(T*, bool (T::*)())` does not suffice. |
|
template<typename T> |
|
Condition(T *object, bool (absl::internal::identity<T>::type::* method)()); |
|
|
|
// Same as above, for const members |
|
template<typename T> |
|
Condition(const T *object, |
|
bool (absl::internal::identity<T>::type::* method)() const); |
|
|
|
// A Condition that returns the value of `*cond` |
|
explicit Condition(const bool *cond); |
|
|
|
// Templated version for invoking a functor that returns a `bool`. |
|
// This approach accepts pointers to non-mutable lambdas, `std::function`, |
|
// the result of` std::bind` and user-defined functors that define |
|
// `bool F::operator()() const`. |
|
// |
|
// Example: |
|
// |
|
// auto reached = [this, current]() { |
|
// mu_.AssertReaderHeld(); // For annotalysis. |
|
// return processed_ >= current; |
|
// }; |
|
// mu_.Await(Condition(&reached)); |
|
// |
|
// NOTE: never use "mu_.AssertHeld()" instead of "mu_.AssertReaderHeld()" in |
|
// the lambda as it may be called when the mutex is being unlocked from a |
|
// scope holding only a reader lock, which will make the assertion not |
|
// fulfilled and crash the binary. |
|
|
|
// See class comment for performance advice. In particular, if there |
|
// might be more than one waiter for the same condition, make sure |
|
// that all waiters construct the condition with the same pointers. |
|
|
|
// Implementation note: The second template parameter ensures that this |
|
// constructor doesn't participate in overload resolution if T doesn't have |
|
// `bool operator() const`. |
|
template <typename T, typename E = decltype( |
|
static_cast<bool (T::*)() const>(&T::operator()))> |
|
explicit Condition(const T *obj) |
|
: Condition(obj, static_cast<bool (T::*)() const>(&T::operator())) {} |
|
|
|
// A Condition that always returns `true`. |
|
static const Condition kTrue; |
|
|
|
// Evaluates the condition. |
|
bool Eval() const; |
|
|
|
// Returns `true` if the two conditions are guaranteed to return the same |
|
// value if evaluated at the same time, `false` if the evaluation *may* return |
|
// different results. |
|
// |
|
// Two `Condition` values are guaranteed equal if both their `func` and `arg` |
|
// components are the same. A null pointer is equivalent to a `true` |
|
// condition. |
|
static bool GuaranteedEqual(const Condition *a, const Condition *b); |
|
|
|
private: |
|
// Sizing an allocation for a method pointer can be subtle. In the Itanium |
|
// specifications, a method pointer has a predictable, uniform size. On the |
|
// other hand, MSVC ABI, method pointer sizes vary based on the |
|
// inheritance of the class. Specifically, method pointers from classes with |
|
// multiple inheritance are bigger than those of classes with single |
|
// inheritance. Other variations also exist. |
|
|
|
// A good way to allocate enough space for *any* pointer in these ABIs is to |
|
// employ a class declaration with no definition. Because the inheritance |
|
// structure is not available for this declaration, the compiler must |
|
// assume, conservatively, that its method pointers have the largest possible |
|
// size. |
|
class OpaqueClass; |
|
using ConservativeMethodPointer = bool (OpaqueClass::*)(); |
|
static_assert(sizeof(bool(OpaqueClass::*)()) >= sizeof(bool (*)(void *)), |
|
"Unsupported platform."); |
|
|
|
// Allocation for a function pointer or method pointer. |
|
// The {0} initializer ensures that all unused bytes of this buffer are |
|
// always zeroed out. This is necessary, because GuaranteedEqual() compares |
|
// all of the bytes, unaware of which bytes are relevant to a given `eval_`. |
|
char callback_[sizeof(ConservativeMethodPointer)] = {0}; |
|
|
|
// Function with which to evaluate callbacks and/or arguments. |
|
bool (*eval_)(const Condition*); |
|
|
|
// Either an argument for a function call or an object for a method call. |
|
void *arg_; |
|
|
|
// Various functions eval_ can point to: |
|
static bool CallVoidPtrFunction(const Condition*); |
|
template <typename T> static bool CastAndCallFunction(const Condition* c); |
|
template <typename T> static bool CastAndCallMethod(const Condition* c); |
|
|
|
// Helper methods for storing, validating, and reading callback arguments. |
|
template <typename T> |
|
inline void StoreCallback(T callback) { |
|
static_assert( |
|
sizeof(callback) <= sizeof(callback_), |
|
"An overlarge pointer was passed as a callback to Condition."); |
|
std::memcpy(callback_, &callback, sizeof(callback)); |
|
} |
|
|
|
template <typename T> |
|
inline void ReadCallback(T *callback) const { |
|
std::memcpy(callback, callback_, sizeof(*callback)); |
|
} |
|
|
|
Condition(); // null constructor used only to create kTrue |
|
}; |
|
|
|
// ----------------------------------------------------------------------------- |
|
// CondVar |
|
// ----------------------------------------------------------------------------- |
|
// |
|
// A condition variable, reflecting state evaluated separately outside of the |
|
// `Mutex` object, which can be signaled to wake callers. |
|
// This class is not normally needed; use `Mutex` member functions such as |
|
// `Mutex::Await()` and intrinsic `Condition` abstractions. In rare cases |
|
// with many threads and many conditions, `CondVar` may be faster. |
|
// |
|
// The implementation may deliver signals to any condition variable at |
|
// any time, even when no call to `Signal()` or `SignalAll()` is made; as a |
|
// result, upon being awoken, you must check the logical condition you have |
|
// been waiting upon. |
|
// |
|
// Examples: |
|
// |
|
// Usage for a thread waiting for some condition C protected by mutex mu: |
|
// mu.Lock(); |
|
// while (!C) { cv->Wait(&mu); } // releases and reacquires mu |
|
// // C holds; process data |
|
// mu.Unlock(); |
|
// |
|
// Usage to wake T is: |
|
// mu.Lock(); |
|
// // process data, possibly establishing C |
|
// if (C) { cv->Signal(); } |
|
// mu.Unlock(); |
|
// |
|
// If C may be useful to more than one waiter, use `SignalAll()` instead of |
|
// `Signal()`. |
|
// |
|
// With this implementation it is efficient to use `Signal()/SignalAll()` inside |
|
// the locked region; this usage can make reasoning about your program easier. |
|
// |
|
class CondVar { |
|
public: |
|
// A `CondVar` allocated on the heap or on the stack can use the this |
|
// constructor. |
|
CondVar(); |
|
~CondVar(); |
|
|
|
// CondVar::Wait() |
|
// |
|
// Atomically releases a `Mutex` and blocks on this condition variable. |
|
// Waits until awakened by a call to `Signal()` or `SignalAll()` (or a |
|
// spurious wakeup), then reacquires the `Mutex` and returns. |
|
// |
|
// Requires and ensures that the current thread holds the `Mutex`. |
|
void Wait(Mutex *mu); |
|
|
|
// CondVar::WaitWithTimeout() |
|
// |
|
// Atomically releases a `Mutex` and blocks on this condition variable. |
|
// Waits until awakened by a call to `Signal()` or `SignalAll()` (or a |
|
// spurious wakeup), or until the timeout has expired, then reacquires |
|
// the `Mutex` and returns. |
|
// |
|
// Returns true if the timeout has expired without this `CondVar` |
|
// being signalled in any manner. If both the timeout has expired |
|
// and this `CondVar` has been signalled, the implementation is free |
|
// to return `true` or `false`. |
|
// |
|
// Requires and ensures that the current thread holds the `Mutex`. |
|
bool WaitWithTimeout(Mutex *mu, absl::Duration timeout); |
|
|
|
// CondVar::WaitWithDeadline() |
|
// |
|
// Atomically releases a `Mutex` and blocks on this condition variable. |
|
// Waits until awakened by a call to `Signal()` or `SignalAll()` (or a |
|
// spurious wakeup), or until the deadline has passed, then reacquires |
|
// the `Mutex` and returns. |
|
// |
|
// Deadlines in the past are equivalent to an immediate deadline. |
|
// |
|
// Returns true if the deadline has passed without this `CondVar` |
|
// being signalled in any manner. If both the deadline has passed |
|
// and this `CondVar` has been signalled, the implementation is free |
|
// to return `true` or `false`. |
|
// |
|
// Requires and ensures that the current thread holds the `Mutex`. |
|
bool WaitWithDeadline(Mutex *mu, absl::Time deadline); |
|
|
|
// CondVar::Signal() |
|
// |
|
// Signal this `CondVar`; wake at least one waiter if one exists. |
|
void Signal(); |
|
|
|
// CondVar::SignalAll() |
|
// |
|
// Signal this `CondVar`; wake all waiters. |
|
void SignalAll(); |
|
|
|
// CondVar::EnableDebugLog() |
|
// |
|
// Causes all subsequent uses of this `CondVar` to be logged via |
|
// `ABSL_RAW_LOG(INFO)`. Log entries are tagged with `name` if `name != 0`. |
|
// Note: this method substantially reduces `CondVar` performance. |
|
void EnableDebugLog(const char *name); |
|
|
|
private: |
|
bool WaitCommon(Mutex *mutex, synchronization_internal::KernelTimeout t); |
|
void Remove(base_internal::PerThreadSynch *s); |
|
void Wakeup(base_internal::PerThreadSynch *w); |
|
std::atomic<intptr_t> cv_; // Condition variable state. |
|
CondVar(const CondVar&) = delete; |
|
CondVar& operator=(const CondVar&) = delete; |
|
}; |
|
|
|
|
|
// Variants of MutexLock. |
|
// |
|
// If you find yourself using one of these, consider instead using |
|
// Mutex::Unlock() and/or if-statements for clarity. |
|
|
|
// MutexLockMaybe |
|
// |
|
// MutexLockMaybe is like MutexLock, but is a no-op when mu is null. |
|
class ABSL_SCOPED_LOCKABLE MutexLockMaybe { |
|
public: |
|
explicit MutexLockMaybe(Mutex *mu) ABSL_EXCLUSIVE_LOCK_FUNCTION(mu) |
|
: mu_(mu) { |
|
if (this->mu_ != nullptr) { |
|
this->mu_->Lock(); |
|
} |
|
} |
|
|
|
explicit MutexLockMaybe(Mutex *mu, const Condition &cond) |
|
ABSL_EXCLUSIVE_LOCK_FUNCTION(mu) |
|
: mu_(mu) { |
|
if (this->mu_ != nullptr) { |
|
this->mu_->LockWhen(cond); |
|
} |
|
} |
|
|
|
~MutexLockMaybe() ABSL_UNLOCK_FUNCTION() { |
|
if (this->mu_ != nullptr) { this->mu_->Unlock(); } |
|
} |
|
|
|
private: |
|
Mutex *const mu_; |
|
MutexLockMaybe(const MutexLockMaybe&) = delete; |
|
MutexLockMaybe(MutexLockMaybe&&) = delete; |
|
MutexLockMaybe& operator=(const MutexLockMaybe&) = delete; |
|
MutexLockMaybe& operator=(MutexLockMaybe&&) = delete; |
|
}; |
|
|
|
// ReleasableMutexLock |
|
// |
|
// ReleasableMutexLock is like MutexLock, but permits `Release()` of its |
|
// mutex before destruction. `Release()` may be called at most once. |
|
class ABSL_SCOPED_LOCKABLE ReleasableMutexLock { |
|
public: |
|
explicit ReleasableMutexLock(Mutex *mu) ABSL_EXCLUSIVE_LOCK_FUNCTION(mu) |
|
: mu_(mu) { |
|
this->mu_->Lock(); |
|
} |
|
|
|
explicit ReleasableMutexLock(Mutex *mu, const Condition &cond) |
|
ABSL_EXCLUSIVE_LOCK_FUNCTION(mu) |
|
: mu_(mu) { |
|
this->mu_->LockWhen(cond); |
|
} |
|
|
|
~ReleasableMutexLock() ABSL_UNLOCK_FUNCTION() { |
|
if (this->mu_ != nullptr) { this->mu_->Unlock(); } |
|
} |
|
|
|
void Release() ABSL_UNLOCK_FUNCTION(); |
|
|
|
private: |
|
Mutex *mu_; |
|
ReleasableMutexLock(const ReleasableMutexLock&) = delete; |
|
ReleasableMutexLock(ReleasableMutexLock&&) = delete; |
|
ReleasableMutexLock& operator=(const ReleasableMutexLock&) = delete; |
|
ReleasableMutexLock& operator=(ReleasableMutexLock&&) = delete; |
|
}; |
|
|
|
inline Mutex::Mutex() : mu_(0) { |
|
ABSL_TSAN_MUTEX_CREATE(this, __tsan_mutex_not_static); |
|
} |
|
|
|
inline constexpr Mutex::Mutex(absl::ConstInitType) : mu_(0) {} |
|
|
|
inline CondVar::CondVar() : cv_(0) {} |
|
|
|
// static |
|
template <typename T> |
|
bool Condition::CastAndCallMethod(const Condition *c) { |
|
T *object = static_cast<T *>(c->arg_); |
|
bool (T::*method_pointer)(); |
|
c->ReadCallback(&method_pointer); |
|
return (object->*method_pointer)(); |
|
} |
|
|
|
// static |
|
template <typename T> |
|
bool Condition::CastAndCallFunction(const Condition *c) { |
|
bool (*function)(T *); |
|
c->ReadCallback(&function); |
|
T *argument = static_cast<T *>(c->arg_); |
|
return (*function)(argument); |
|
} |
|
|
|
template <typename T> |
|
inline Condition::Condition(bool (*func)(T *), T *arg) |
|
: eval_(&CastAndCallFunction<T>), |
|
arg_(const_cast<void *>(static_cast<const void *>(arg))) { |
|
static_assert(sizeof(&func) <= sizeof(callback_), |
|
"An overlarge function pointer was passed to Condition."); |
|
StoreCallback(func); |
|
} |
|
|
|
template <typename T> |
|
inline Condition::Condition(T *object, |
|
bool (absl::internal::identity<T>::type::*method)()) |
|
: eval_(&CastAndCallMethod<T>), |
|
arg_(object) { |
|
static_assert(sizeof(&method) <= sizeof(callback_), |
|
"An overlarge method pointer was passed to Condition."); |
|
StoreCallback(method); |
|
} |
|
|
|
template <typename T> |
|
inline Condition::Condition(const T *object, |
|
bool (absl::internal::identity<T>::type::*method)() |
|
const) |
|
: eval_(&CastAndCallMethod<T>), |
|
arg_(reinterpret_cast<void *>(const_cast<T *>(object))) { |
|
StoreCallback(method); |
|
} |
|
|
|
// Register hooks for profiling support. |
|
// |
|
// The function pointer registered here will be called whenever a mutex is |
|
// contended. The callback is given the cycles for which waiting happened (as |
|
// measured by //absl/base/internal/cycleclock.h, and which may not |
|
// be real "cycle" counts.) |
|
// |
|
// Calls to this function do not race or block, but there is no ordering |
|
// guaranteed between calls to this function and call to the provided hook. |
|
// In particular, the previously registered hook may still be called for some |
|
// time after this function returns. |
|
void RegisterMutexProfiler(void (*fn)(int64_t wait_cycles)); |
|
|
|
// Register a hook for Mutex tracing. |
|
// |
|
// The function pointer registered here will be called whenever a mutex is |
|
// contended. The callback is given an opaque handle to the contended mutex, |
|
// an event name, and the number of wait cycles (as measured by |
|
// //absl/base/internal/cycleclock.h, and which may not be real |
|
// "cycle" counts.) |
|
// |
|
// The only event name currently sent is "slow release". |
|
// |
|
// This has the same memory ordering concerns as RegisterMutexProfiler() above. |
|
void RegisterMutexTracer(void (*fn)(const char *msg, const void *obj, |
|
int64_t wait_cycles)); |
|
|
|
// TODO(gfalcon): Combine RegisterMutexProfiler() and RegisterMutexTracer() |
|
// into a single interface, since they are only ever called in pairs. |
|
|
|
// Register a hook for CondVar tracing. |
|
// |
|
// The function pointer registered here will be called here on various CondVar |
|
// events. The callback is given an opaque handle to the CondVar object and |
|
// a string identifying the event. This is thread-safe, but only a single |
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// tracer can be registered. |
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// |
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// Events that can be sent are "Wait", "Unwait", "Signal wakeup", and |
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// "SignalAll wakeup". |
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// |
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// This has the same memory ordering concerns as RegisterMutexProfiler() above. |
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void RegisterCondVarTracer(void (*fn)(const char *msg, const void *cv)); |
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|
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// Register a hook for symbolizing stack traces in deadlock detector reports. |
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// |
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// 'pc' is the program counter being symbolized, 'out' is the buffer to write |
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// into, and 'out_size' is the size of the buffer. This function can return |
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// false if symbolizing failed, or true if a NUL-terminated symbol was written |
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// to 'out.' |
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// |
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// This has the same memory ordering concerns as RegisterMutexProfiler() above. |
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// |
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// DEPRECATED: The default symbolizer function is absl::Symbolize() and the |
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// ability to register a different hook for symbolizing stack traces will be |
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// removed on or after 2023-05-01. |
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ABSL_DEPRECATED("absl::RegisterSymbolizer() is deprecated and will be removed " |
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"on or after 2023-05-01") |
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void RegisterSymbolizer(bool (*fn)(const void *pc, char *out, int out_size)); |
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|
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// EnableMutexInvariantDebugging() |
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// |
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// Enable or disable global support for Mutex invariant debugging. If enabled, |
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// then invariant predicates can be registered per-Mutex for debug checking. |
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// See Mutex::EnableInvariantDebugging(). |
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void EnableMutexInvariantDebugging(bool enabled); |
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|
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// When in debug mode, and when the feature has been enabled globally, the |
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// implementation will keep track of lock ordering and complain (or optionally |
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// crash) if a cycle is detected in the acquired-before graph. |
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|
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// Possible modes of operation for the deadlock detector in debug mode. |
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enum class OnDeadlockCycle { |
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kIgnore, // Neither report on nor attempt to track cycles in lock ordering |
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kReport, // Report lock cycles to stderr when detected |
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kAbort, // Report lock cycles to stderr when detected, then abort |
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}; |
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|
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// SetMutexDeadlockDetectionMode() |
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// |
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// Enable or disable global support for detection of potential deadlocks |
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// due to Mutex lock ordering inversions. When set to 'kIgnore', tracking of |
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// lock ordering is disabled. Otherwise, in debug builds, a lock ordering graph |
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// will be maintained internally, and detected cycles will be reported in |
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// the manner chosen here. |
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void SetMutexDeadlockDetectionMode(OnDeadlockCycle mode); |
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ABSL_NAMESPACE_END |
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} // namespace absl |
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// In some build configurations we pass --detect-odr-violations to the |
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// gold linker. This causes it to flag weak symbol overrides as ODR |
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// violations. Because ODR only applies to C++ and not C, |
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// --detect-odr-violations ignores symbols not mangled with C++ names. |
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// By changing our extension points to be extern "C", we dodge this |
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// check. |
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extern "C" { |
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void ABSL_INTERNAL_C_SYMBOL(AbslInternalMutexYield)(); |
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} // extern "C" |
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#endif // ABSL_SYNCHRONIZATION_MUTEX_H_
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