/* * Copyright 2015-present Facebook, Inc. * * 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. */ #pragma once #include #include #include #include #include #include #include #include #include namespace folly { /** * DelayedDestructionBase is a helper class to ensure objects are not deleted * while they still have functions executing in a higher stack frame. * * This is useful for objects that invoke callback functions, to ensure that a * callback does not destroy the calling object. * * Classes needing this functionality should: * - derive from DelayedDestructionBase directly * - implement onDelayedDestroy which'll be called before the object is * going to be destructed * - create a DestructorGuard object on the stack in each public method that * may invoke a callback * * DelayedDestructionBase does not perform any locking. It is intended to be * used only from a single thread. */ class DelayedDestructionBase : private boost::noncopyable { public: virtual ~DelayedDestructionBase() = default; /** * Classes should create a DestructorGuard object on the stack in any * function that may invoke callback functions. * * The DestructorGuard prevents the guarded class from being destroyed while * it exists. Without this, the callback function could delete the guarded * object, causing problems when the callback function returns and the * guarded object's method resumes execution. */ class DestructorGuard { public: explicit DestructorGuard(DelayedDestructionBase* dd) : dd_(dd) { if (dd_ != nullptr) { ++dd_->guardCount_; assert(dd_->guardCount_ > 0); // check for wrapping } } DestructorGuard(const DestructorGuard& dg) : DestructorGuard(dg.dd_) {} DestructorGuard(DestructorGuard&& dg) noexcept : dd_(std::exchange(dg.dd_, nullptr)) {} DestructorGuard& operator=(DestructorGuard dg) noexcept { std::swap(dd_, dg.dd_); return *this; } DestructorGuard& operator=(DelayedDestructionBase* dd) { *this = DestructorGuard(dd); return *this; } ~DestructorGuard() { if (dd_ != nullptr) { assert(dd_->guardCount_ > 0); --dd_->guardCount_; if (dd_->guardCount_ == 0) { dd_->onDelayedDestroy(true); } } } DelayedDestructionBase* get() const { return dd_; } explicit operator bool() const { return dd_ != nullptr; } private: DelayedDestructionBase* dd_; }; /** * This smart pointer is a convenient way to manage a concrete * DelayedDestructorBase child. It can replace the equivalent raw pointer and * provide automatic memory management. */ template class IntrusivePtr : private DestructorGuard { template friend class IntrusivePtr; public: template static IntrusivePtr make(Args&&... args) { return {new AliasType(std::forward(args)...)}; } IntrusivePtr() = default; IntrusivePtr(const IntrusivePtr&) = default; IntrusivePtr(IntrusivePtr&&) noexcept = default; template < typename CopyAliasType, typename = typename std::enable_if< std::is_convertible::value>::type> IntrusivePtr(const IntrusivePtr& copy) : DestructorGuard(copy) {} template < typename CopyAliasType, typename = typename std::enable_if< std::is_convertible::value>::type> IntrusivePtr(IntrusivePtr&& copy) : DestructorGuard(std::move(copy)) {} explicit IntrusivePtr(AliasType* dd) : DestructorGuard(dd) {} // Copying from a unique_ptr is safe because if the upcast to // DelayedDestructionBase works, then the instance is already using // intrusive ref-counting. template < typename CopyAliasType, typename Deleter, typename = typename std::enable_if< std::is_convertible::value>::type> explicit IntrusivePtr(const std::unique_ptr& copy) : DestructorGuard(copy.get()) {} IntrusivePtr& operator=(const IntrusivePtr&) = default; IntrusivePtr& operator=(IntrusivePtr&&) noexcept = default; template < typename CopyAliasType, typename = typename std::enable_if< std::is_convertible::value>::type> IntrusivePtr& operator=(IntrusivePtr copy) noexcept { DestructorGuard::operator=(copy); return *this; } IntrusivePtr& operator=(AliasType* dd) { DestructorGuard::operator=(dd); return *this; } void reset(AliasType* dd = nullptr) { *this = dd; } AliasType* get() const { return static_cast(DestructorGuard::get()); } AliasType& operator*() const { return *get(); } AliasType* operator->() const { return get(); } explicit operator bool() const { return DestructorGuard::operator bool(); } }; protected: DelayedDestructionBase() : guardCount_(0) {} /** * Get the number of DestructorGuards currently protecting this object. * * This is primarily intended for debugging purposes, such as asserting * that an object has at least 1 guard. */ uint32_t getDestructorGuardCount() const { return guardCount_; } /** * Implement onDelayedDestroy in subclasses. * onDelayedDestroy() is invoked when the object is potentially being * destroyed. * * @param delayed This parameter is true if destruction was delayed because * of a DestructorGuard object, or false if onDelayedDestroy() * is being called directly from the destructor. */ virtual void onDelayedDestroy(bool delayed) = 0; private: /** * guardCount_ is incremented by DestructorGuard, to indicate that one of * the DelayedDestructionBase object's methods is currently running. * * If the destructor is called while guardCount_ is non-zero, destruction * will be delayed until guardCount_ drops to 0. This allows * DelayedDestructionBase objects to invoke callbacks without having to worry * about being deleted before the callback returns. */ uint32_t guardCount_; }; inline bool operator==( const DelayedDestructionBase::DestructorGuard& left, const DelayedDestructionBase::DestructorGuard& right) { return left.get() == right.get(); } inline bool operator!=( const DelayedDestructionBase::DestructorGuard& left, const DelayedDestructionBase::DestructorGuard& right) { return left.get() != right.get(); } inline bool operator==( const DelayedDestructionBase::DestructorGuard& left, std::nullptr_t) { return left.get() == nullptr; } inline bool operator==( std::nullptr_t, const DelayedDestructionBase::DestructorGuard& right) { return nullptr == right.get(); } inline bool operator!=( const DelayedDestructionBase::DestructorGuard& left, std::nullptr_t) { return left.get() != nullptr; } inline bool operator!=( std::nullptr_t, const DelayedDestructionBase::DestructorGuard& right) { return nullptr != right.get(); } template inline bool operator==( const DelayedDestructionBase::IntrusivePtr& left, const DelayedDestructionBase::IntrusivePtr& right) { return left.get() == right.get(); } template inline bool operator!=( const DelayedDestructionBase::IntrusivePtr& left, const DelayedDestructionBase::IntrusivePtr& right) { return left.get() != right.get(); } template inline bool operator==( const DelayedDestructionBase::IntrusivePtr& left, std::nullptr_t) { return left.get() == nullptr; } template inline bool operator==( std::nullptr_t, const DelayedDestructionBase::IntrusivePtr& right) { return nullptr == right.get(); } template inline bool operator!=( const DelayedDestructionBase::IntrusivePtr& left, std::nullptr_t) { return left.get() != nullptr; } template inline bool operator!=( std::nullptr_t, const DelayedDestructionBase::IntrusivePtr& right) { return nullptr != right.get(); } } // namespace folly