cannam@62: // Copyright (c) 2013-2014 Sandstorm Development Group, Inc. and contributors cannam@62: // Licensed under the MIT License: cannam@62: // cannam@62: // Permission is hereby granted, free of charge, to any person obtaining a copy cannam@62: // of this software and associated documentation files (the "Software"), to deal cannam@62: // in the Software without restriction, including without limitation the rights cannam@62: // to use, copy, modify, merge, publish, distribute, sublicense, and/or sell cannam@62: // copies of the Software, and to permit persons to whom the Software is cannam@62: // furnished to do so, subject to the following conditions: cannam@62: // cannam@62: // The above copyright notice and this permission notice shall be included in cannam@62: // all copies or substantial portions of the Software. cannam@62: // cannam@62: // THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR cannam@62: // IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, cannam@62: // FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE cannam@62: // AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER cannam@62: // LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, cannam@62: // OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN cannam@62: // THE SOFTWARE. cannam@62: cannam@62: #ifndef KJ_MUTEX_H_ cannam@62: #define KJ_MUTEX_H_ cannam@62: cannam@62: #if defined(__GNUC__) && !KJ_HEADER_WARNINGS cannam@62: #pragma GCC system_header cannam@62: #endif cannam@62: cannam@62: #include "memory.h" cannam@62: #include cannam@62: cannam@62: #if __linux__ && !defined(KJ_USE_FUTEX) cannam@62: #define KJ_USE_FUTEX 1 cannam@62: #endif cannam@62: cannam@62: #if !KJ_USE_FUTEX && !_WIN32 cannam@62: // On Linux we use futex. On other platforms we wrap pthreads. cannam@62: // TODO(someday): Write efficient low-level locking primitives for other platforms. cannam@62: #include cannam@62: #endif cannam@62: cannam@62: namespace kj { cannam@62: cannam@62: // ======================================================================================= cannam@62: // Private details -- public interfaces follow below. cannam@62: cannam@62: namespace _ { // private cannam@62: cannam@62: class Mutex { cannam@62: // Internal implementation details. See `MutexGuarded`. cannam@62: cannam@62: public: cannam@62: Mutex(); cannam@62: ~Mutex(); cannam@62: KJ_DISALLOW_COPY(Mutex); cannam@62: cannam@62: enum Exclusivity { cannam@62: EXCLUSIVE, cannam@62: SHARED cannam@62: }; cannam@62: cannam@62: void lock(Exclusivity exclusivity); cannam@62: void unlock(Exclusivity exclusivity); cannam@62: cannam@62: void assertLockedByCaller(Exclusivity exclusivity); cannam@62: // In debug mode, assert that the mutex is locked by the calling thread, or if that is cannam@62: // non-trivial, assert that the mutex is locked (which should be good enough to catch problems cannam@62: // in unit tests). In non-debug builds, do nothing. cannam@62: cannam@62: private: cannam@62: #if KJ_USE_FUTEX cannam@62: uint futex; cannam@62: // bit 31 (msb) = set if exclusive lock held cannam@62: // bit 30 (msb) = set if threads are waiting for exclusive lock cannam@62: // bits 0-29 = count of readers; If an exclusive lock is held, this is the count of threads cannam@62: // waiting for a read lock, otherwise it is the count of threads that currently hold a read cannam@62: // lock. cannam@62: cannam@62: static constexpr uint EXCLUSIVE_HELD = 1u << 31; cannam@62: static constexpr uint EXCLUSIVE_REQUESTED = 1u << 30; cannam@62: static constexpr uint SHARED_COUNT_MASK = EXCLUSIVE_REQUESTED - 1; cannam@62: cannam@62: #elif _WIN32 cannam@62: uintptr_t srwLock; // Actually an SRWLOCK, but don't want to #include in header. cannam@62: cannam@62: #else cannam@62: mutable pthread_rwlock_t mutex; cannam@62: #endif cannam@62: }; cannam@62: cannam@62: class Once { cannam@62: // Internal implementation details. See `Lazy`. cannam@62: cannam@62: public: cannam@62: #if KJ_USE_FUTEX cannam@62: inline Once(bool startInitialized = false) cannam@62: : futex(startInitialized ? INITIALIZED : UNINITIALIZED) {} cannam@62: #else cannam@62: Once(bool startInitialized = false); cannam@62: ~Once(); cannam@62: #endif cannam@62: KJ_DISALLOW_COPY(Once); cannam@62: cannam@62: class Initializer { cannam@62: public: cannam@62: virtual void run() = 0; cannam@62: }; cannam@62: cannam@62: void runOnce(Initializer& init); cannam@62: cannam@62: #if _WIN32 // TODO(perf): Can we make this inline on win32 somehow? cannam@62: bool isInitialized() noexcept; cannam@62: cannam@62: #else cannam@62: inline bool isInitialized() noexcept { cannam@62: // Fast path check to see if runOnce() would simply return immediately. cannam@62: #if KJ_USE_FUTEX cannam@62: return __atomic_load_n(&futex, __ATOMIC_ACQUIRE) == INITIALIZED; cannam@62: #else cannam@62: return __atomic_load_n(&state, __ATOMIC_ACQUIRE) == INITIALIZED; cannam@62: #endif cannam@62: } cannam@62: #endif cannam@62: cannam@62: void reset(); cannam@62: // Returns the state from initialized to uninitialized. It is an error to call this when cannam@62: // not already initialized, or when runOnce() or isInitialized() might be called concurrently in cannam@62: // another thread. cannam@62: cannam@62: private: cannam@62: #if KJ_USE_FUTEX cannam@62: uint futex; cannam@62: cannam@62: enum State { cannam@62: UNINITIALIZED, cannam@62: INITIALIZING, cannam@62: INITIALIZING_WITH_WAITERS, cannam@62: INITIALIZED cannam@62: }; cannam@62: cannam@62: #elif _WIN32 cannam@62: uintptr_t initOnce; // Actually an INIT_ONCE, but don't want to #include in header. cannam@62: cannam@62: #else cannam@62: enum State { cannam@62: UNINITIALIZED, cannam@62: INITIALIZED cannam@62: }; cannam@62: State state; cannam@62: pthread_mutex_t mutex; cannam@62: #endif cannam@62: }; cannam@62: cannam@62: } // namespace _ (private) cannam@62: cannam@62: // ======================================================================================= cannam@62: // Public interface cannam@62: cannam@62: template cannam@62: class Locked { cannam@62: // Return type for `MutexGuarded::lock()`. `Locked` provides access to the bounded object cannam@62: // and unlocks the mutex when it goes out of scope. cannam@62: cannam@62: public: cannam@62: KJ_DISALLOW_COPY(Locked); cannam@62: inline Locked(): mutex(nullptr), ptr(nullptr) {} cannam@62: inline Locked(Locked&& other): mutex(other.mutex), ptr(other.ptr) { cannam@62: other.mutex = nullptr; cannam@62: other.ptr = nullptr; cannam@62: } cannam@62: inline ~Locked() { cannam@62: if (mutex != nullptr) mutex->unlock(isConst() ? _::Mutex::SHARED : _::Mutex::EXCLUSIVE); cannam@62: } cannam@62: cannam@62: inline Locked& operator=(Locked&& other) { cannam@62: if (mutex != nullptr) mutex->unlock(isConst() ? _::Mutex::SHARED : _::Mutex::EXCLUSIVE); cannam@62: mutex = other.mutex; cannam@62: ptr = other.ptr; cannam@62: other.mutex = nullptr; cannam@62: other.ptr = nullptr; cannam@62: return *this; cannam@62: } cannam@62: cannam@62: inline void release() { cannam@62: if (mutex != nullptr) mutex->unlock(isConst() ? _::Mutex::SHARED : _::Mutex::EXCLUSIVE); cannam@62: mutex = nullptr; cannam@62: ptr = nullptr; cannam@62: } cannam@62: cannam@62: inline T* operator->() { return ptr; } cannam@62: inline const T* operator->() const { return ptr; } cannam@62: inline T& operator*() { return *ptr; } cannam@62: inline const T& operator*() const { return *ptr; } cannam@62: inline T* get() { return ptr; } cannam@62: inline const T* get() const { return ptr; } cannam@62: inline operator T*() { return ptr; } cannam@62: inline operator const T*() const { return ptr; } cannam@62: cannam@62: private: cannam@62: _::Mutex* mutex; cannam@62: T* ptr; cannam@62: cannam@62: inline Locked(_::Mutex& mutex, T& value): mutex(&mutex), ptr(&value) {} cannam@62: cannam@62: template cannam@62: friend class MutexGuarded; cannam@62: }; cannam@62: cannam@62: template cannam@62: class MutexGuarded { cannam@62: // An object of type T, bounded by a mutex. In order to access the object, you must lock it. cannam@62: // cannam@62: // Write locks are not "recursive" -- trying to lock again in a thread that already holds a lock cannam@62: // will deadlock. Recursive write locks are usually a sign of bad design. cannam@62: // cannam@62: // Unfortunately, **READ LOCKS ARE NOT RECURSIVE** either. Common sense says they should be. cannam@62: // But on many operating systems (BSD, OSX), recursively read-locking a pthread_rwlock is cannam@62: // actually unsafe. The problem is that writers are "prioritized" over readers, so a read lock cannam@62: // request will block if any write lock requests are outstanding. So, if thread A takes a read cannam@62: // lock, thread B requests a write lock (and starts waiting), and then thread A tries to take cannam@62: // another read lock recursively, the result is deadlock. cannam@62: cannam@62: public: cannam@62: template cannam@62: explicit MutexGuarded(Params&&... params); cannam@62: // Initialize the mutex-bounded object by passing the given parameters to its constructor. cannam@62: cannam@62: Locked lockExclusive() const; cannam@62: // Exclusively locks the object and returns it. The returned `Locked` can be passed by cannam@62: // move, similar to `Own`. cannam@62: // cannam@62: // This method is declared `const` in accordance with KJ style rules which say that constness cannam@62: // should be used to indicate thread-safety. It is safe to share a const pointer between threads, cannam@62: // but it is not safe to share a mutable pointer. Since the whole point of MutexGuarded is to cannam@62: // be shared between threads, its methods should be const, even though locking it produces a cannam@62: // non-const pointer to the contained object. cannam@62: cannam@62: Locked lockShared() const; cannam@62: // Lock the value for shared access. Multiple shared locks can be taken concurrently, but cannot cannam@62: // be held at the same time as a non-shared lock. cannam@62: cannam@62: inline const T& getWithoutLock() const { return value; } cannam@62: inline T& getWithoutLock() { return value; } cannam@62: // Escape hatch for cases where some external factor guarantees that it's safe to get the cannam@62: // value. You should treat these like const_cast -- be highly suspicious of any use. cannam@62: cannam@62: inline const T& getAlreadyLockedShared() const; cannam@62: inline T& getAlreadyLockedShared(); cannam@62: inline T& getAlreadyLockedExclusive() const; cannam@62: // Like `getWithoutLock()`, but asserts that the lock is already held by the calling thread. cannam@62: cannam@62: private: cannam@62: mutable _::Mutex mutex; cannam@62: mutable T value; cannam@62: }; cannam@62: cannam@62: template cannam@62: class MutexGuarded { cannam@62: // MutexGuarded cannot guard a const type. This would be pointless anyway, and would complicate cannam@62: // the implementation of Locked, which uses constness to decide what kind of lock it holds. cannam@62: static_assert(sizeof(T) < 0, "MutexGuarded's type cannot be const."); cannam@62: }; cannam@62: cannam@62: template cannam@62: class Lazy { cannam@62: // A lazily-initialized value. cannam@62: cannam@62: public: cannam@62: template cannam@62: T& get(Func&& init); cannam@62: template cannam@62: const T& get(Func&& init) const; cannam@62: // The first thread to call get() will invoke the given init function to construct the value. cannam@62: // Other threads will block until construction completes, then return the same value. cannam@62: // cannam@62: // `init` is a functor(typically a lambda) which takes `SpaceFor&` as its parameter and returns cannam@62: // `Own`. If `init` throws an exception, the exception is propagated out of that thread's cannam@62: // call to `get()`, and subsequent calls behave as if `get()` hadn't been called at all yet -- cannam@62: // in other words, subsequent calls retry initialization until it succeeds. cannam@62: cannam@62: private: cannam@62: mutable _::Once once; cannam@62: mutable SpaceFor space; cannam@62: mutable Own value; cannam@62: cannam@62: template cannam@62: class InitImpl; cannam@62: }; cannam@62: cannam@62: // ======================================================================================= cannam@62: // Inline implementation details cannam@62: cannam@62: template cannam@62: template cannam@62: inline MutexGuarded::MutexGuarded(Params&&... params) cannam@62: : value(kj::fwd(params)...) {} cannam@62: cannam@62: template cannam@62: inline Locked MutexGuarded::lockExclusive() const { cannam@62: mutex.lock(_::Mutex::EXCLUSIVE); cannam@62: return Locked(mutex, value); cannam@62: } cannam@62: cannam@62: template cannam@62: inline Locked MutexGuarded::lockShared() const { cannam@62: mutex.lock(_::Mutex::SHARED); cannam@62: return Locked(mutex, value); cannam@62: } cannam@62: cannam@62: template cannam@62: inline const T& MutexGuarded::getAlreadyLockedShared() const { cannam@62: #ifdef KJ_DEBUG cannam@62: mutex.assertLockedByCaller(_::Mutex::SHARED); cannam@62: #endif cannam@62: return value; cannam@62: } cannam@62: template cannam@62: inline T& MutexGuarded::getAlreadyLockedShared() { cannam@62: #ifdef KJ_DEBUG cannam@62: mutex.assertLockedByCaller(_::Mutex::SHARED); cannam@62: #endif cannam@62: return value; cannam@62: } cannam@62: template cannam@62: inline T& MutexGuarded::getAlreadyLockedExclusive() const { cannam@62: #ifdef KJ_DEBUG cannam@62: mutex.assertLockedByCaller(_::Mutex::EXCLUSIVE); cannam@62: #endif cannam@62: return const_cast(value); cannam@62: } cannam@62: cannam@62: template cannam@62: template cannam@62: class Lazy::InitImpl: public _::Once::Initializer { cannam@62: public: cannam@62: inline InitImpl(const Lazy& lazy, Func&& func): lazy(lazy), func(kj::fwd(func)) {} cannam@62: cannam@62: void run() override { cannam@62: lazy.value = func(lazy.space); cannam@62: } cannam@62: cannam@62: private: cannam@62: const Lazy& lazy; cannam@62: Func func; cannam@62: }; cannam@62: cannam@62: template cannam@62: template cannam@62: inline T& Lazy::get(Func&& init) { cannam@62: if (!once.isInitialized()) { cannam@62: InitImpl initImpl(*this, kj::fwd(init)); cannam@62: once.runOnce(initImpl); cannam@62: } cannam@62: return *value; cannam@62: } cannam@62: cannam@62: template cannam@62: template cannam@62: inline const T& Lazy::get(Func&& init) const { cannam@62: if (!once.isInitialized()) { cannam@62: InitImpl initImpl(*this, kj::fwd(init)); cannam@62: once.runOnce(initImpl); cannam@62: } cannam@62: return *value; cannam@62: } cannam@62: cannam@62: } // namespace kj cannam@62: cannam@62: #endif // KJ_MUTEX_H_