third_party/llvm-subzero/include/llvm/ADT/IntrusiveRefCntPtr.h - SwiftShader - Git at Google

 //== 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 <atomic>
 #include <cassert>
 #include <cstddef>

 namespace llvm {

 //===----------------------------------------------------------------------===//
 /// 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 Derived>
   class RefCountedBase {
     mutable unsigned ref_cnt = 0;

   public:
     RefCountedBase() = default;
     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<const Derived*>(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 = 0;

     virtual void anchor();

   protected:
     RefCountedBaseVPTR() = default;
     RefCountedBaseVPTR(const RefCountedBaseVPTR &) : ref_cnt(0) {}

     virtual ~RefCountedBaseVPTR() = default;

     void Retain() const { ++ref_cnt; }
     void Release() const {
       assert (ref_cnt > 0 && "Reference count is already zero.");
       if (--ref_cnt == 0) delete this;
     }

     template <typename T>
     friend struct IntrusiveRefCntPtrInfo;
   };


   template <typename T> 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 Derived>
 class ThreadSafeRefCountedBase {
   mutable std::atomic<int> RefCount;

 protected:
   ThreadSafeRefCountedBase() : RefCount(0) {}

 public:
   void Retain() const { RefCount.fetch_add(1, std::memory_order_relaxed); }

   void Release() const {
     int NewRefCount = RefCount.fetch_sub(1, std::memory_order_acq_rel) - 1;
     assert(NewRefCount >= 0 && "Reference count was already zero.");
     if (NewRefCount == 0)
       delete static_cast<const Derived*>(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 <typename T>
   class IntrusiveRefCntPtr {
     T* Obj = nullptr;

   public:
     typedef T element_type;

     explicit IntrusiveRefCntPtr() = default;

     IntrusiveRefCntPtr(T* obj) : Obj(obj) {
       retain();
     }

     IntrusiveRefCntPtr(const IntrusiveRefCntPtr& S) : Obj(S.Obj) {
       retain();
     }

     IntrusiveRefCntPtr(IntrusiveRefCntPtr&& S) : Obj(S.Obj) {
       S.Obj = nullptr;
     }

     template <class X>
     IntrusiveRefCntPtr(IntrusiveRefCntPtr<X>&& S) : Obj(S.get()) {
       S.Obj = nullptr;
     }

     template <class X>
     IntrusiveRefCntPtr(const IntrusiveRefCntPtr<X>& 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 = nullptr;
     }

   private:
     void retain() { if (Obj) IntrusiveRefCntPtrInfo<T>::retain(Obj); }
     void release() { if (Obj) IntrusiveRefCntPtrInfo<T>::release(Obj); }

     template <typename X>
     friend class IntrusiveRefCntPtr;
   };

   template<class T, class U>
   inline bool operator==(const IntrusiveRefCntPtr<T>& A,
                          const IntrusiveRefCntPtr<U>& B)
   {
     return A.get() == B.get();
   }

   template<class T, class U>
   inline bool operator!=(const IntrusiveRefCntPtr<T>& A,
                          const IntrusiveRefCntPtr<U>& B)
   {
     return A.get() != B.get();
   }

   template<class T, class U>
   inline bool operator==(const IntrusiveRefCntPtr<T>& A,
                          U* B)
   {
     return A.get() == B;
   }

   template<class T, class U>
   inline bool operator!=(const IntrusiveRefCntPtr<T>& A,
                          U* B)
   {
     return A.get() != B;
   }

   template<class T, class U>
   inline bool operator==(T* A,
                          const IntrusiveRefCntPtr<U>& B)
   {
     return A == B.get();
   }

   template<class T, class U>
   inline bool operator!=(T* A,
                          const IntrusiveRefCntPtr<U>& B)
   {
     return A != B.get();
   }

   template <class T>
   bool operator==(std::nullptr_t A, const IntrusiveRefCntPtr<T> &B) {
     return !B;
   }

   template <class T>
   bool operator==(const IntrusiveRefCntPtr<T> &A, std::nullptr_t B) {
     return B == A;
   }

   template <class T>
   bool operator!=(std::nullptr_t A, const IntrusiveRefCntPtr<T> &B) {
     return !(A == B);
   }

   template <class T>
   bool operator!=(const IntrusiveRefCntPtr<T> &A, std::nullptr_t B) {
     return !(A == B);
   }

 //===----------------------------------------------------------------------===//
 // LLVM-style downcasting support for IntrusiveRefCntPtr objects
 //===----------------------------------------------------------------------===//

   template <typename From> struct simplify_type;

   template<class T> struct simplify_type<IntrusiveRefCntPtr<T>> {
     typedef T* SimpleType;
     static SimpleType getSimplifiedValue(IntrusiveRefCntPtr<T>& Val) {
       return Val.get();
     }
   };

   template<class T> struct simplify_type<const IntrusiveRefCntPtr<T>> {
     typedef /*const*/ T* SimpleType;
     static SimpleType getSimplifiedValue(const IntrusiveRefCntPtr<T>& Val) {
       return Val.get();
     }
   };

 } // end namespace llvm

 #endif // LLVM_ADT_INTRUSIVEREFCNTPTR_H
	//== 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 <atomic>
	#include <cassert>
	#include <cstddef>

	namespace llvm {

	//===----------------------------------------------------------------------===//
	/// 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 Derived>
	class RefCountedBase {
	mutable unsigned ref_cnt = 0;

	public:
	RefCountedBase() = default;
	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<const Derived*>(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 = 0;

	virtual void anchor();

	protected:
	RefCountedBaseVPTR() = default;
	RefCountedBaseVPTR(const RefCountedBaseVPTR &) : ref_cnt(0) {}

	virtual ~RefCountedBaseVPTR() = default;

	void Retain() const { ++ref_cnt; }
	void Release() const {
	assert (ref_cnt > 0 && "Reference count is already zero.");
	if (--ref_cnt == 0) delete this;
	}

	template <typename T>
	friend struct IntrusiveRefCntPtrInfo;
	};


	template <typename T> 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 Derived>
	class ThreadSafeRefCountedBase {
	mutable std::atomic<int> RefCount;

	protected:
	ThreadSafeRefCountedBase() : RefCount(0) {}

	public:
	void Retain() const { RefCount.fetch_add(1, std::memory_order_relaxed); }

	void Release() const {
	int NewRefCount = RefCount.fetch_sub(1, std::memory_order_acq_rel) - 1;
	assert(NewRefCount >= 0 && "Reference count was already zero.");
	if (NewRefCount == 0)
	delete static_cast<const Derived*>(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 <typename T>
	class IntrusiveRefCntPtr {
	T* Obj = nullptr;

	public:
	typedef T element_type;

	explicit IntrusiveRefCntPtr() = default;

	IntrusiveRefCntPtr(T* obj) : Obj(obj) {
	retain();
	}

	IntrusiveRefCntPtr(const IntrusiveRefCntPtr& S) : Obj(S.Obj) {
	retain();
	}

	IntrusiveRefCntPtr(IntrusiveRefCntPtr&& S) : Obj(S.Obj) {
	S.Obj = nullptr;
	}

	template <class X>
	IntrusiveRefCntPtr(IntrusiveRefCntPtr<X>&& S) : Obj(S.get()) {
	S.Obj = nullptr;
	}

	template <class X>
	IntrusiveRefCntPtr(const IntrusiveRefCntPtr<X>& 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 = nullptr;
	}

	private:
	void retain() { if (Obj) IntrusiveRefCntPtrInfo<T>::retain(Obj); }
	void release() { if (Obj) IntrusiveRefCntPtrInfo<T>::release(Obj); }

	template <typename X>
	friend class IntrusiveRefCntPtr;
	};

	template<class T, class U>
	inline bool operator==(const IntrusiveRefCntPtr<T>& A,
	const IntrusiveRefCntPtr<U>& B)
	{
	return A.get() == B.get();
	}

	template<class T, class U>
	inline bool operator!=(const IntrusiveRefCntPtr<T>& A,
	const IntrusiveRefCntPtr<U>& B)
	{
	return A.get() != B.get();
	}

	template<class T, class U>
	inline bool operator==(const IntrusiveRefCntPtr<T>& A,
	U* B)
	{
	return A.get() == B;
	}

	template<class T, class U>
	inline bool operator!=(const IntrusiveRefCntPtr<T>& A,
	U* B)
	{
	return A.get() != B;
	}

	template<class T, class U>
	inline bool operator==(T* A,
	const IntrusiveRefCntPtr<U>& B)
	{
	return A == B.get();
	}

	template<class T, class U>
	inline bool operator!=(T* A,
	const IntrusiveRefCntPtr<U>& B)
	{
	return A != B.get();
	}

	template <class T>
	bool operator==(std::nullptr_t A, const IntrusiveRefCntPtr<T> &B) {
	return !B;
	}

	template <class T>
	bool operator==(const IntrusiveRefCntPtr<T> &A, std::nullptr_t B) {
	return B == A;
	}

	template <class T>
	bool operator!=(std::nullptr_t A, const IntrusiveRefCntPtr<T> &B) {
	return !(A == B);
	}

	template <class T>
	bool operator!=(const IntrusiveRefCntPtr<T> &A, std::nullptr_t B) {
	return !(A == B);
	}

	//===----------------------------------------------------------------------===//
	// LLVM-style downcasting support for IntrusiveRefCntPtr objects
	//===----------------------------------------------------------------------===//

	template <typename From> struct simplify_type;

	template<class T> struct simplify_type<IntrusiveRefCntPtr<T>> {
	typedef T* SimpleType;
	static SimpleType getSimplifiedValue(IntrusiveRefCntPtr<T>& Val) {
	return Val.get();
	}
	};

	template<class T> struct simplify_type<const IntrusiveRefCntPtr<T>> {
	typedef /const/ T* SimpleType;
	static SimpleType getSimplifiedValue(const IntrusiveRefCntPtr<T>& Val) {
	return Val.get();
	}
	};

	} // end namespace llvm

	#endif // LLVM_ADT_INTRUSIVEREFCNTPTR_H