Source/cm_auto_ptr.hxx - third_party/cmake - Git at Google

 /* Distributed under the OSI-approved BSD 3-Clause License.  See accompanying
    file Copyright.txt or https://cmake.org/licensing for details.  */
 #ifndef CM_AUTO_PTR_HXX
 #define CM_AUTO_PTR_HXX

 #include "cmConfigure.h"

 #ifdef CMake_HAVE_CXX_AUTO_PTR

 #include <memory>
 #define CM_AUTO_PTR std::auto_ptr

 #else

 #define CM_AUTO_PTR cm::auto_ptr

 // The HP compiler cannot handle the conversions necessary to use
 // auto_ptr_ref to pass an auto_ptr returned from one function
 // directly to another function as in use_auto_ptr(get_auto_ptr()).
 // We instead use const_cast to achieve the syntax on those platforms.
 // We do not use const_cast on other platforms to maintain the C++
 // standard design and guarantee that if an auto_ptr is bound
 // to a reference-to-const then ownership will be maintained.
 #if defined(__HP_aCC)
 #define cm_AUTO_PTR_REF 0
 #define cm_AUTO_PTR_CONST const
 #define cm_AUTO_PTR_CAST(a) cast(a)
 #else
 #define cm_AUTO_PTR_REF 1
 #define cm_AUTO_PTR_CONST
 #define cm_AUTO_PTR_CAST(a) a
 #endif

 // In C++11, clang will warn about using dynamic exception specifications
 // as they are deprecated.  But as this class is trying to faithfully
 // mimic std::auto_ptr, we want to keep the 'throw()' decorations below.
 // So we suppress the warning.
 #if defined(__clang__) && defined(__has_warning)
 #if __has_warning("-Wdeprecated")
 #pragma clang diagnostic push
 #pragma clang diagnostic ignored "-Wdeprecated"
 #endif
 #endif

 namespace cm {

 template <class X>
 class auto_ptr;

 #if cm_AUTO_PTR_REF
 namespace detail {
 // The auto_ptr_ref template is supposed to be a private member of
 // auto_ptr but Borland 5.8 cannot handle it.  Instead put it in
 // a private namespace.
 template <class Y>
 struct auto_ptr_ref
 {
   Y* p_;

   // The extra constructor argument prevents implicit conversion to
   // auto_ptr_ref from auto_ptr through the constructor.  Normally
   // this should be done with the explicit keyword but Borland 5.x
   // generates code in the conversion operator to call itself
   // infinately.
   auto_ptr_ref(Y* p, int)
     : p_(p)
   {
   }
 };
 }
 #endif

 /** C++98 Standard Section 20.4.5 - Template class auto_ptr.  */
 template <class X>
 class auto_ptr
 {
 #if !cm_AUTO_PTR_REF
   template <typename Y>
   static inline auto_ptr<Y>& cast(auto_ptr<Y> const& a)
   {
     return const_cast<auto_ptr<Y>&>(a);
   }
 #endif

   /** The pointer to the object held.  */
   X* x_;

 public:
   /** The type of object held by the auto_ptr.  */
   typedef X element_type;

   /** Construct from an auto_ptr holding a compatible object.  This
       transfers ownership to the newly constructed auto_ptr.  */
   template <class Y>
   auto_ptr(auto_ptr<Y> cm_AUTO_PTR_CONST& a) throw()
     : x_(cm_AUTO_PTR_CAST(a).release())
   {
   }

   /** Assign from an auto_ptr holding a compatible object.  This
       transfers ownership to the left-hand-side of the assignment.  */
   template <class Y>
   auto_ptr& operator=(auto_ptr<Y> cm_AUTO_PTR_CONST& a) throw() // NOLINT
   {
     this->reset(cm_AUTO_PTR_CAST(a).release());
     return *this; // NOLINT
   }

   /**
    * Explicitly construct from a raw pointer.  This is typically
    * called with the result of operator new.  For example:
    *
    *   auto_ptr<X> ptr(new X());
    */
   explicit auto_ptr(X* p = CM_NULLPTR) throw()
     : x_(p)
   {
   }

   /** Construct from another auto_ptr holding an object of the same
       type.  This transfers ownership to the newly constructed
       auto_ptr.  */
   auto_ptr(auto_ptr cm_AUTO_PTR_CONST& a) throw()
     : x_(cm_AUTO_PTR_CAST(a).release())
   {
   }

   /** Assign from another auto_ptr holding an object of the same type.
       This transfers ownership to the newly constructed auto_ptr.  */
   auto_ptr& operator=(auto_ptr cm_AUTO_PTR_CONST& a) throw() // NOLINT
   {
     this->reset(cm_AUTO_PTR_CAST(a).release());
     return *this; // NOLINT
   }

   /** Destruct and delete the object held.  */
   ~auto_ptr() throw()
   {
     // Assume object destructor is nothrow.
     delete this->x_;
   }

   /** Dereference and return a reference to the object held.  */
   X& operator*() const throw() { return *this->x_; }

   /** Return a pointer to the object held.  */
   X* operator->() const throw() { return this->x_; }

   /** Return a pointer to the object held.  */
   X* get() const throw() { return this->x_; }

   /** Return a pointer to the object held and reset to hold no object.
       This transfers ownership to the caller.  */
   X* release() throw()
   {
     X* x = this->x_;
     this->x_ = CM_NULLPTR;
     return x;
   }

   /** Assume ownership of the given object.  The object previously
       held is deleted.  */
   void reset(X* p = 0) throw()
   {
     if (this->x_ != p) {
       // Assume object destructor is nothrow.
       delete this->x_;
       this->x_ = p;
     }
   }

   /** Convert to an auto_ptr holding an object of a compatible type.
       This transfers ownership to the returned auto_ptr.  */
   template <class Y>
   operator auto_ptr<Y>() throw()
   {
     return auto_ptr<Y>(this->release());
   }

 #if cm_AUTO_PTR_REF
   /** Construct from an auto_ptr_ref.  This is used when the
       constructor argument is a call to a function returning an
       auto_ptr.  */
   auto_ptr(detail::auto_ptr_ref<X> r) throw()
     : x_(r.p_)
   {
   }

   /** Assign from an auto_ptr_ref.  This is used when a function
       returning an auto_ptr is passed on the right-hand-side of an
       assignment.  */
   auto_ptr& operator=(detail::auto_ptr_ref<X> r) throw()
   {
     this->reset(r.p_);
     return *this; // NOLINT
   }

   /** Convert to an auto_ptr_ref.  This is used when a function
       returning an auto_ptr is the argument to the constructor of
       another auto_ptr.  */
   template <class Y>
   operator detail::auto_ptr_ref<Y>() throw()
   {
     return detail::auto_ptr_ref<Y>(this->release(), 1);
   }
 #endif
 };

 } // namespace cm

 // Undo warning suppression.
 #if defined(__clang__) && defined(__has_warning)
 #if __has_warning("-Wdeprecated")
 #pragma clang diagnostic pop
 #endif
 #endif

 #endif

 #endif
	/* Distributed under the OSI-approved BSD 3-Clause License. See accompanying
	file Copyright.txt or https://cmake.org/licensing for details. */
	#ifndef CM_AUTO_PTR_HXX
	#define CM_AUTO_PTR_HXX

	#include "cmConfigure.h"

	#ifdef CMake_HAVE_CXX_AUTO_PTR

	#include <memory>
	#define CM_AUTO_PTR std::auto_ptr

	#else

	#define CM_AUTO_PTR cm::auto_ptr

	// The HP compiler cannot handle the conversions necessary to use
	// auto_ptr_ref to pass an auto_ptr returned from one function
	// directly to another function as in use_auto_ptr(get_auto_ptr()).
	// We instead use const_cast to achieve the syntax on those platforms.
	// We do not use const_cast on other platforms to maintain the C++
	// standard design and guarantee that if an auto_ptr is bound
	// to a reference-to-const then ownership will be maintained.
	#if defined(__HP_aCC)
	#define cm_AUTO_PTR_REF 0
	#define cm_AUTO_PTR_CONST const
	#define cm_AUTO_PTR_CAST(a) cast(a)
	#else
	#define cm_AUTO_PTR_REF 1
	#define cm_AUTO_PTR_CONST
	#define cm_AUTO_PTR_CAST(a) a
	#endif

	// In C++11, clang will warn about using dynamic exception specifications
	// as they are deprecated. But as this class is trying to faithfully
	// mimic std::auto_ptr, we want to keep the 'throw()' decorations below.
	// So we suppress the warning.
	#if defined(__clang__) && defined(__has_warning)
	#if __has_warning("-Wdeprecated")
	#pragma clang diagnostic push
	#pragma clang diagnostic ignored "-Wdeprecated"
	#endif
	#endif

	namespace cm {

	template <class X>
	class auto_ptr;

	#if cm_AUTO_PTR_REF
	namespace detail {
	// The auto_ptr_ref template is supposed to be a private member of
	// auto_ptr but Borland 5.8 cannot handle it. Instead put it in
	// a private namespace.
	template <class Y>
	struct auto_ptr_ref
	{
	Y* p_;

	// The extra constructor argument prevents implicit conversion to
	// auto_ptr_ref from auto_ptr through the constructor. Normally
	// this should be done with the explicit keyword but Borland 5.x
	// generates code in the conversion operator to call itself
	// infinately.
	auto_ptr_ref(Y* p, int)
	: p_(p)
	{
	}
	};
	}
	#endif

	/** C++98 Standard Section 20.4.5 - Template class auto_ptr. */
	template <class X>
	class auto_ptr
	{
	#if !cm_AUTO_PTR_REF
	template <typename Y>
	static inline auto_ptr<Y>& cast(auto_ptr<Y> const& a)
	{
	return const_cast<auto_ptr<Y>&>(a);
	}
	#endif

	/** The pointer to the object held. */
	X* x_;

	public:
	/** The type of object held by the auto_ptr. */
	typedef X element_type;

	/** Construct from an auto_ptr holding a compatible object. This
	transfers ownership to the newly constructed auto_ptr. */
	template <class Y>
	auto_ptr(auto_ptr<Y> cm_AUTO_PTR_CONST& a) throw()
	: x_(cm_AUTO_PTR_CAST(a).release())
	{
	}

	/** Assign from an auto_ptr holding a compatible object. This
	transfers ownership to the left-hand-side of the assignment. */
	template <class Y>
	auto_ptr& operator=(auto_ptr<Y> cm_AUTO_PTR_CONST& a) throw() // NOLINT
	{
	this->reset(cm_AUTO_PTR_CAST(a).release());
	return *this; // NOLINT
	}

	/**
	* Explicitly construct from a raw pointer. This is typically
	* called with the result of operator new. For example:
	*
	* auto_ptr<X> ptr(new X());
	*/
	explicit auto_ptr(X* p = CM_NULLPTR) throw()
	: x_(p)
	{
	}

	/** Construct from another auto_ptr holding an object of the same
	type. This transfers ownership to the newly constructed
	auto_ptr. */
	auto_ptr(auto_ptr cm_AUTO_PTR_CONST& a) throw()
	: x_(cm_AUTO_PTR_CAST(a).release())
	{
	}

	/** Assign from another auto_ptr holding an object of the same type.
	This transfers ownership to the newly constructed auto_ptr. */
	auto_ptr& operator=(auto_ptr cm_AUTO_PTR_CONST& a) throw() // NOLINT
	{
	this->reset(cm_AUTO_PTR_CAST(a).release());
	return *this; // NOLINT
	}

	/** Destruct and delete the object held. */
	~auto_ptr() throw()
	{
	// Assume object destructor is nothrow.
	delete this->x_;
	}

	/** Dereference and return a reference to the object held. */
	X& operator() const throw() { return this->x_; }

	/** Return a pointer to the object held. */
	X* operator->() const throw() { return this->x_; }

	/** Return a pointer to the object held. */
	X* get() const throw() { return this->x_; }

	/** Return a pointer to the object held and reset to hold no object.
	This transfers ownership to the caller. */
	X* release() throw()
	{
	X* x = this->x_;
	this->x_ = CM_NULLPTR;
	return x;
	}

	/** Assume ownership of the given object. The object previously
	held is deleted. */
	void reset(X* p = 0) throw()
	{
	if (this->x_ != p) {
	// Assume object destructor is nothrow.
	delete this->x_;
	this->x_ = p;
	}
	}

	/** Convert to an auto_ptr holding an object of a compatible type.
	This transfers ownership to the returned auto_ptr. */
	template <class Y>
	operator auto_ptr<Y>() throw()
	{
	return auto_ptr<Y>(this->release());
	}

	#if cm_AUTO_PTR_REF
	/** Construct from an auto_ptr_ref. This is used when the
	constructor argument is a call to a function returning an
	auto_ptr. */
	auto_ptr(detail::auto_ptr_ref<X> r) throw()
	: x_(r.p_)
	{
	}

	/** Assign from an auto_ptr_ref. This is used when a function
	returning an auto_ptr is passed on the right-hand-side of an
	assignment. */
	auto_ptr& operator=(detail::auto_ptr_ref<X> r) throw()
	{
	this->reset(r.p_);
	return *this; // NOLINT
	}

	/** Convert to an auto_ptr_ref. This is used when a function
	returning an auto_ptr is the argument to the constructor of
	another auto_ptr. */
	template <class Y>
	operator detail::auto_ptr_ref<Y>() throw()
	{
	return detail::auto_ptr_ref<Y>(this->release(), 1);
	}
	#endif
	};

	} // namespace cm

	// Undo warning suppression.
	#if defined(__clang__) && defined(__has_warning)
	#if __has_warning("-Wdeprecated")
	#pragma clang diagnostic pop
	#endif
	#endif

	#endif

	#endif