//== llvm/ADT/IntrusiveRefCntPtr.h - Smart Refcounting Pointer ---*- C++ -*-==// // // The LLVM Compiler Infrastructure // // This file is distributed under the University of Illinois Open Source // License. See LICENSE.TXT for details. // //===----------------------------------------------------------------------===// // // This file defines IntrusiveRefCntPtr, a template class that // implements a "smart" pointer for objects that maintain their own // internal reference count, and RefCountedBase/RefCountedBaseVPTR, two // generic base classes for objects that wish to have their lifetimes // managed using reference counting. // // IntrusiveRefCntPtr is similar to Boost's intrusive_ptr with added // LLVM-style casting. // //===----------------------------------------------------------------------===// #ifndef LLVM_ADT_INTRUSIVEREFCNTPTR_H #define LLVM_ADT_INTRUSIVEREFCNTPTR_H #include "llvm/Support/Casting.h" #include "llvm/Support/Compiler.h" #include #include namespace llvm { template class IntrusiveRefCntPtr; //===----------------------------------------------------------------------===// /// RefCountedBase - A generic base class for objects that wish to /// have their lifetimes managed using reference counts. Classes /// subclass RefCountedBase to obtain such functionality, and are /// typically handled with IntrusiveRefCntPtr "smart pointers" (see below) /// which automatically handle the management of reference counts. /// Objects that subclass RefCountedBase should not be allocated on /// the stack, as invoking "delete" (which is called when the /// reference count hits 0) on such objects is an error. //===----------------------------------------------------------------------===// template class RefCountedBase { mutable unsigned ref_cnt; public: RefCountedBase() : ref_cnt(0) {} RefCountedBase(const RefCountedBase &) : ref_cnt(0) {} void Retain() const { ++ref_cnt; } void Release() const { assert (ref_cnt > 0 && "Reference count is already zero."); if (--ref_cnt == 0) delete static_cast(this); } }; //===----------------------------------------------------------------------===// /// RefCountedBaseVPTR - A class that has the same function as /// RefCountedBase, but with a virtual destructor. Should be used /// instead of RefCountedBase for classes that already have virtual /// methods to enforce dynamic allocation via 'new'. Classes that /// inherit from RefCountedBaseVPTR can't be allocated on stack - /// attempting to do this will produce a compile error. //===----------------------------------------------------------------------===// class RefCountedBaseVPTR { mutable unsigned ref_cnt; virtual void anchor(); protected: RefCountedBaseVPTR() : ref_cnt(0) {} RefCountedBaseVPTR(const RefCountedBaseVPTR &) : ref_cnt(0) {} virtual ~RefCountedBaseVPTR() {} void Retain() const { ++ref_cnt; } void Release() const { assert (ref_cnt > 0 && "Reference count is already zero."); if (--ref_cnt == 0) delete this; } template friend struct IntrusiveRefCntPtrInfo; }; template struct IntrusiveRefCntPtrInfo { static void retain(T *obj) { obj->Retain(); } static void release(T *obj) { obj->Release(); } }; /// \brief A thread-safe version of \c llvm::RefCountedBase. /// /// A generic base class for objects that wish to have their lifetimes managed /// using reference counts. Classes subclass \c ThreadSafeRefCountedBase to /// obtain such functionality, and are typically handled with /// \c IntrusiveRefCntPtr "smart pointers" which automatically handle the /// management of reference counts. template class ThreadSafeRefCountedBase { mutable std::atomic RefCount; protected: ThreadSafeRefCountedBase() : RefCount(0) {} public: void Retain() const { ++RefCount; } void Release() const { int NewRefCount = --RefCount; assert(NewRefCount >= 0 && "Reference count was already zero."); if (NewRefCount == 0) delete static_cast(this); } }; //===----------------------------------------------------------------------===// /// IntrusiveRefCntPtr - A template class that implements a "smart pointer" /// that assumes the wrapped object has a reference count associated /// with it that can be managed via calls to /// IntrusivePtrAddRef/IntrusivePtrRelease. The smart pointers /// manage reference counts via the RAII idiom: upon creation of /// smart pointer the reference count of the wrapped object is /// incremented and upon destruction of the smart pointer the /// reference count is decremented. This class also safely handles /// wrapping NULL pointers. /// /// Reference counting is implemented via calls to /// Obj->Retain()/Obj->Release(). Release() is required to destroy /// the object when the reference count reaches zero. Inheriting from /// RefCountedBase/RefCountedBaseVPTR takes care of this /// automatically. //===----------------------------------------------------------------------===// template class IntrusiveRefCntPtr { T* Obj; public: typedef T element_type; explicit IntrusiveRefCntPtr() : Obj(nullptr) {} IntrusiveRefCntPtr(T* obj) : Obj(obj) { retain(); } IntrusiveRefCntPtr(const IntrusiveRefCntPtr& S) : Obj(S.Obj) { retain(); } IntrusiveRefCntPtr(IntrusiveRefCntPtr&& S) : Obj(S.Obj) { S.Obj = nullptr; } template IntrusiveRefCntPtr(IntrusiveRefCntPtr&& S) : Obj(S.get()) { S.Obj = 0; } template IntrusiveRefCntPtr(const IntrusiveRefCntPtr& S) : Obj(S.get()) { retain(); } IntrusiveRefCntPtr& operator=(IntrusiveRefCntPtr S) { swap(S); return *this; } ~IntrusiveRefCntPtr() { release(); } T& operator*() const { return *Obj; } T* operator->() const { return Obj; } T* get() const { return Obj; } explicit operator bool() const { return Obj; } void swap(IntrusiveRefCntPtr& other) { T* tmp = other.Obj; other.Obj = Obj; Obj = tmp; } void reset() { release(); Obj = nullptr; } void resetWithoutRelease() { Obj = 0; } private: void retain() { if (Obj) IntrusiveRefCntPtrInfo::retain(Obj); } void release() { if (Obj) IntrusiveRefCntPtrInfo::release(Obj); } template friend class IntrusiveRefCntPtr; }; template inline bool operator==(const IntrusiveRefCntPtr& A, const IntrusiveRefCntPtr& B) { return A.get() == B.get(); } template inline bool operator!=(const IntrusiveRefCntPtr& A, const IntrusiveRefCntPtr& B) { return A.get() != B.get(); } template inline bool operator==(const IntrusiveRefCntPtr& A, U* B) { return A.get() == B; } template inline bool operator!=(const IntrusiveRefCntPtr& A, U* B) { return A.get() != B; } template inline bool operator==(T* A, const IntrusiveRefCntPtr& B) { return A == B.get(); } template inline bool operator!=(T* A, const IntrusiveRefCntPtr& B) { return A != B.get(); } template bool operator==(std::nullptr_t A, const IntrusiveRefCntPtr &B) { return !B; } template bool operator==(const IntrusiveRefCntPtr &A, std::nullptr_t B) { return B == A; } template bool operator!=(std::nullptr_t A, const IntrusiveRefCntPtr &B) { return !(A == B); } template bool operator!=(const IntrusiveRefCntPtr &A, std::nullptr_t B) { return !(A == B); } //===----------------------------------------------------------------------===// // LLVM-style downcasting support for IntrusiveRefCntPtr objects //===----------------------------------------------------------------------===// template struct simplify_type > { typedef T* SimpleType; static SimpleType getSimplifiedValue(IntrusiveRefCntPtr& Val) { return Val.get(); } }; template struct simplify_type > { typedef /*const*/ T* SimpleType; static SimpleType getSimplifiedValue(const IntrusiveRefCntPtr& Val) { return Val.get(); } }; } // end namespace llvm #endif // LLVM_ADT_INTRUSIVEREFCNTPTR_H