include/__functional_base - third_party/libcxx - Git at Google

 // -*- C++ -*-
 //===----------------------------------------------------------------------===//
 //
 //                     The LLVM Compiler Infrastructure
 //
 // This file is dual licensed under the MIT and the University of Illinois Open
 // Source Licenses. See LICENSE.TXT for details.
 //
 //===----------------------------------------------------------------------===//

 #ifndef _LIBCPP_FUNCTIONAL_BASE
 #define _LIBCPP_FUNCTIONAL_BASE

 #include <__config>
 #include <type_traits>
 #include <typeinfo>
 #include <exception>

 #pragma GCC system_header

 _LIBCPP_BEGIN_NAMESPACE_STD

 template <class _Arg, class _Result>
 struct _LIBCPP_VISIBLE unary_function
 {
     typedef _Arg    argument_type;
     typedef _Result result_type;
 };

 template <class _Arg1, class _Arg2, class _Result>
 struct _LIBCPP_VISIBLE binary_function
 {
     typedef _Arg1   first_argument_type;
     typedef _Arg2   second_argument_type;
     typedef _Result result_type;
 };

 template <class _Tp> struct _LIBCPP_VISIBLE hash;

 template <class _Tp>
 struct __has_result_type
 {
 private:
     struct __two {char _; char __;};
     template <class _Up> static __two __test(...);
     template <class _Up> static char __test(typename _Up::result_type* = 0);
 public:
     static const bool value = sizeof(__test<_Tp>(0)) == 1;
 };

 #ifdef _LIBCPP_HAS_NO_VARIADICS

 #include <__functional_base_03>

 #else  // _LIBCPP_HAS_NO_VARIADICS

 // __weak_result_type

 template <class _Tp>
 struct __derives_from_unary_function
 {
 private:
     struct __two {char _; char __;};
     static __two __test(...);
     template <class _A, class _R>
         static unary_function<_A, _R>
         __test(const volatile unary_function<_A, _R>*);
 public:
     static const bool value = !is_same<decltype(__test((_Tp*)0)), __two>::value;
     typedef decltype(__test((_Tp*)0)) type;
 };

 template <class _Tp>
 struct __derives_from_binary_function
 {
 private:
     struct __two {char _; char __;};
     static __two __test(...);
     template <class _A1, class _A2, class _R>
         static binary_function<_A1, _A2, _R>
         __test(const volatile binary_function<_A1, _A2, _R>*);
 public:
     static const bool value = !is_same<decltype(__test((_Tp*)0)), __two>::value;
     typedef decltype(__test((_Tp*)0)) type;
 };

 template <class _Tp, bool = __derives_from_unary_function<_Tp>::value>
 struct __maybe_derive_from_unary_function  // bool is true
     : public __derives_from_unary_function<_Tp>::type
 {
 };

 template <class _Tp>
 struct __maybe_derive_from_unary_function<_Tp, false>
 {
 };

 template <class _Tp, bool = __derives_from_binary_function<_Tp>::value>
 struct __maybe_derive_from_binary_function  // bool is true
     : public __derives_from_binary_function<_Tp>::type
 {
 };

 template <class _Tp>
 struct __maybe_derive_from_binary_function<_Tp, false>
 {
 };

 template <class _Tp, bool = __has_result_type<_Tp>::value>
 struct __weak_result_type_imp // bool is true
     : public __maybe_derive_from_unary_function<_Tp>,
       public __maybe_derive_from_binary_function<_Tp>
 {
     typedef typename _Tp::result_type result_type;
 };

 template <class _Tp>
 struct __weak_result_type_imp<_Tp, false>
     : public __maybe_derive_from_unary_function<_Tp>,
       public __maybe_derive_from_binary_function<_Tp>
 {
 };

 template <class _Tp>
 struct __weak_result_type
     : public __weak_result_type_imp<_Tp>
 {
 };

 // 0 argument case

 template <class _R>
 struct __weak_result_type<_R ()>
 {
     typedef _R result_type;
 };

 template <class _R>
 struct __weak_result_type<_R (&)()>
 {
     typedef _R result_type;
 };

 template <class _R>
 struct __weak_result_type<_R (*)()>
 {
     typedef _R result_type;
 };

 // 1 argument case

 template <class _R, class _A1>
 struct __weak_result_type<_R (_A1)>
     : public unary_function<_A1, _R>
 {
 };

 template <class _R, class _A1>
 struct __weak_result_type<_R (&)(_A1)>
     : public unary_function<_A1, _R>
 {
 };

 template <class _R, class _A1>
 struct __weak_result_type<_R (*)(_A1)>
     : public unary_function<_A1, _R>
 {
 };

 template <class _R, class _C>
 struct __weak_result_type<_R (_C::*)()>
     : public unary_function<_C*, _R>
 {
 };

 template <class _R, class _C>
 struct __weak_result_type<_R (_C::*)() const>
     : public unary_function<const _C*, _R>
 {
 };

 template <class _R, class _C>
 struct __weak_result_type<_R (_C::*)() volatile>
     : public unary_function<volatile _C*, _R>
 {
 };

 template <class _R, class _C>
 struct __weak_result_type<_R (_C::*)() const volatile>
     : public unary_function<const volatile _C*, _R>
 {
 };

 // 2 argument case

 template <class _R, class _A1, class _A2>
 struct __weak_result_type<_R (_A1, _A2)>
     : public binary_function<_A1, _A2, _R>
 {
 };

 template <class _R, class _A1, class _A2>
 struct __weak_result_type<_R (*)(_A1, _A2)>
     : public binary_function<_A1, _A2, _R>
 {
 };

 template <class _R, class _A1, class _A2>
 struct __weak_result_type<_R (&)(_A1, _A2)>
     : public binary_function<_A1, _A2, _R>
 {
 };

 template <class _R, class _C, class _A1>
 struct __weak_result_type<_R (_C::*)(_A1)>
     : public binary_function<_C*, _A1, _R>
 {
 };

 template <class _R, class _C, class _A1>
 struct __weak_result_type<_R (_C::*)(_A1) const>
     : public binary_function<const _C*, _A1, _R>
 {
 };

 template <class _R, class _C, class _A1>
 struct __weak_result_type<_R (_C::*)(_A1) volatile>
     : public binary_function<volatile _C*, _A1, _R>
 {
 };

 template <class _R, class _C, class _A1>
 struct __weak_result_type<_R (_C::*)(_A1) const volatile>
     : public binary_function<const volatile _C*, _A1, _R>
 {
 };

 // 3 or more arguments

 template <class _R, class _A1, class _A2, class _A3, class ..._A4>
 struct __weak_result_type<_R (_A1, _A2, _A3, _A4...)>
 {
     typedef _R result_type;
 };

 template <class _R, class _A1, class _A2, class _A3, class ..._A4>
 struct __weak_result_type<_R (&)(_A1, _A2, _A3, _A4...)>
 {
     typedef _R result_type;
 };

 template <class _R, class _A1, class _A2, class _A3, class ..._A4>
 struct __weak_result_type<_R (*)(_A1, _A2, _A3, _A4...)>
 {
     typedef _R result_type;
 };

 template <class _R, class _C, class _A1, class _A2, class ..._A3>
 struct __weak_result_type<_R (_C::*)(_A1, _A2, _A3...)>
 {
     typedef _R result_type;
 };

 template <class _R, class _C, class _A1, class _A2, class ..._A3>
 struct __weak_result_type<_R (_C::*)(_A1, _A2, _A3...) const>
 {
     typedef _R result_type;
 };

 template <class _R, class _C, class _A1, class _A2, class ..._A3>
 struct __weak_result_type<_R (_C::*)(_A1, _A2, _A3...) volatile>
 {
     typedef _R result_type;
 };

 template <class _R, class _C, class _A1, class _A2, class ..._A3>
 struct __weak_result_type<_R (_C::*)(_A1, _A2, _A3...) const volatile>
 {
     typedef _R result_type;
 };

 // __invoke

 // first bullet

 template <class _R, class _T, class _T1, class ..._Param, class ..._Arg>
 inline _LIBCPP_INLINE_VISIBILITY
 typename enable_if
 <
     sizeof...(_Param) == sizeof...(_Arg) &&
     is_base_of<_T, typename remove_reference<_T1>::type>::value,
     _R
 >::type
 __invoke(_R (_T::*__f)(_Param...), _T1&& __t1, _Arg&& ...__arg)
 {
     return (_STD::forward<_T>(__t1).*__f)(_STD::forward<_Arg>(__arg)...);
 }

 template <class _R, class _T, class _T1, class ..._Param, class ..._Arg>
 inline _LIBCPP_INLINE_VISIBILITY
 typename enable_if
 <
     sizeof...(_Param) == sizeof...(_Arg) &&
     is_base_of<_T, typename remove_reference<_T1>::type>::value,
     _R
 >::type
 __invoke(_R (_T::*__f)(_Param...) const, _T1&& __t1, _Arg&& ...__arg)
 {
     return (_STD::forward<const _T>(__t1).*__f)(_STD::forward<_Arg>(__arg)...);
 }

 template <class _R, class _T, class _T1, class ..._Param, class ..._Arg>
 inline _LIBCPP_INLINE_VISIBILITY
 typename enable_if
 <
     sizeof...(_Param) == sizeof...(_Arg) &&
     is_base_of<_T, typename remove_reference<_T1>::type>::value,
     _R
 >::type
 __invoke(_R (_T::*__f)(_Param...) volatile, _T1&& __t1, _Arg&& ...__arg)
 {
     return (_STD::forward<volatile _T>(__t1).*__f)(_STD::forward<_Arg>(__arg)...);
 }

 template <class _R, class _T, class _T1, class ..._Param, class ..._Arg>
 inline _LIBCPP_INLINE_VISIBILITY
 typename enable_if
 <
     sizeof...(_Param) == sizeof...(_Arg) &&
     is_base_of<_T, typename remove_reference<_T1>::type>::value,
     _R
 >::type
 __invoke(_R (_T::*__f)(_Param...) const volatile, _T1&& __t1, _Arg&& ...__arg)
 {
     return (_STD::forward<const volatile _T>(__t1).*__f)(_STD::forward<_Arg>(__arg)...);
 }

 // second bullet

 template <class _R, class _T, class _T1, class ..._Param, class ..._Arg>
 inline _LIBCPP_INLINE_VISIBILITY
 typename enable_if
 <
     sizeof...(_Param) == sizeof...(_Arg) &&
     !is_base_of<_T, typename remove_reference<_T1>::type>::value,
     _R
 >::type
 __invoke(_R (_T::*__f)(_Param...), _T1&& __t1, _Arg&& ...__arg)
 {
     return ((*_STD::forward<_T1>(__t1)).*__f)(_STD::forward<_Arg>(__arg)...);
 }

 template <class _R, class _T, class _T1, class ..._Param, class ..._Arg>
 inline _LIBCPP_INLINE_VISIBILITY
 typename enable_if
 <
     sizeof...(_Param) == sizeof...(_Arg) &&
     !is_base_of<_T, typename remove_reference<_T1>::type>::value,
     _R
 >::type
 __invoke(_R (_T::*__f)(_Param...) const, _T1&& __t1, _Arg&& ...__arg)
 {
     return ((*_STD::forward<_T1>(__t1)).*__f)(_STD::forward<_Arg>(__arg)...);
 }

 template <class _R, class _T, class _T1, class ..._Param, class ..._Arg>
 inline _LIBCPP_INLINE_VISIBILITY
 typename enable_if
 <
     sizeof...(_Param) == sizeof...(_Arg) &&
     !is_base_of<_T, typename remove_reference<_T1>::type>::value,
     _R
 >::type
 __invoke(_R (_T::*__f)(_Param...) volatile, _T1&& __t1, _Arg&& ...__arg)
 {
     return ((*_STD::forward<_T1>(__t1)).*__f)(_STD::forward<_Arg>(__arg)...);
 }

 template <class _R, class _T, class _T1, class ..._Param, class ..._Arg>
 inline _LIBCPP_INLINE_VISIBILITY
 typename enable_if
 <
     sizeof...(_Param) == sizeof...(_Arg) &&
     !is_base_of<_T, typename remove_reference<_T1>::type>::value,
     _R
 >::type
 __invoke(_R (_T::*__f)(_Param...) const volatile, _T1&& __t1, _Arg&& ...__arg)
 {
     return ((*_STD::forward<_T1>(__t1)).*__f)(_STD::forward<_Arg>(__arg)...);
 }

 // third bullet

 template <class _R, class _T, class _T1>
 inline _LIBCPP_INLINE_VISIBILITY
 typename enable_if
 <
     is_base_of<_T, typename remove_reference<_T1>::type>::value,
     typename __apply_cv<_T1, _R>::type&&
 >::type
 __invoke(_R _T::* __f, _T1&& __t1)
 {
     return _STD::forward<_T1>(__t1).*__f;
 }

 // forth bullet

 template <class _T1, class _R, bool>
 struct __4th_helper
 {
 };

 template <class _T1, class _R>
 struct __4th_helper<_T1, _R, true>
 {
     typedef typename __apply_cv<decltype(*_STD::declval<_T1>()), _R>::type type;
 };

 template <class _R, class _T, class _T1>
 inline _LIBCPP_INLINE_VISIBILITY
 typename __4th_helper<_T1, _R,
                       !is_base_of<_T,
                                   typename remove_reference<_T1>::type
                                  >::value
                      >::type&&
 __invoke(_R _T::* __f, _T1&& __t1)
 {
     return (*_STD::forward<_T1>(__t1)).*__f;
 }

 // fifth bullet

 template <class _F, class ..._T>
 inline _LIBCPP_INLINE_VISIBILITY
 typename result_of<_F(_T...)>::type
 __invoke(_F&& __f, _T&& ...__t)
 {
     return _STD::forward<_F>(__f)(_STD::forward<_T>(__t)...);
 }

 template <class _Tp, class ..._Args>
 struct __invoke_return
 {
     typedef decltype(__invoke(_STD::declval<_Tp>(), _STD::declval<_Args>()...)) type;
 };

 template <class _Tp>
 class _LIBCPP_VISIBLE reference_wrapper
     : public __weak_result_type<_Tp>
 {
 public:
     // types
     typedef _Tp type;
 private:
     type* __f_;

 public:
     // construct/copy/destroy
     _LIBCPP_INLINE_VISIBILITY reference_wrapper(type& __f) : __f_(&__f) {}
 #ifndef _LIBCPP_HAS_NO_RVALUE_REFERENCES
     private: reference_wrapper(type&&); public: // = delete; // do not bind to temps
 #endif

     // access
     _LIBCPP_INLINE_VISIBILITY operator type&    () const {return *__f_;}
     _LIBCPP_INLINE_VISIBILITY          type& get() const {return *__f_;}

     // invoke
     template <class... _ArgTypes>
        _LIBCPP_INLINE_VISIBILITY
        typename __invoke_return<type&, _ArgTypes...>::type
           operator() (_ArgTypes&&... __args) const
           {
               return __invoke(get(), _STD::forward<_ArgTypes>(__args)...);
           }
 };

 template <class _Tp> struct ____is_reference_wrapper : public false_type {};
 template <class _Tp> struct ____is_reference_wrapper<reference_wrapper<_Tp> > : public true_type {};
 template <class _Tp> struct __is_reference_wrapper
     : public ____is_reference_wrapper<typename remove_cv<_Tp>::type> {};

 template <class _Tp>
 inline _LIBCPP_INLINE_VISIBILITY
 reference_wrapper<_Tp>
 ref(_Tp& __t)
 {
     return reference_wrapper<_Tp>(__t);
 }

 template <class _Tp>
 inline _LIBCPP_INLINE_VISIBILITY
 reference_wrapper<_Tp>
 ref(reference_wrapper<_Tp> __t)
 {
     return ref(__t.get());
 }

 template <class _Tp>
 inline _LIBCPP_INLINE_VISIBILITY
 reference_wrapper<const _Tp>
 cref(const _Tp& __t)
 {
     return reference_wrapper<const _Tp>(__t);
 }

 template <class _Tp>
 inline _LIBCPP_INLINE_VISIBILITY
 reference_wrapper<const _Tp>
 cref(reference_wrapper<_Tp> __t)
 {
     return cref(__t.get());
 }

 #ifndef _LIBCPP_HAS_NO_RVALUE_REFERENCES
 #ifndef _LIBCPP_HAS_NO_DELETED_FUNCTIONS

 template <class _Tp> void ref(const _Tp&& __t) = delete;
 template <class _Tp> void cref(const _Tp&& __t) = delete;

 #else  // _LIBCPP_HAS_NO_DELETED_FUNCTIONS

 template <class _Tp> void ref(const _Tp&& __t);// = delete;
 template <class _Tp> void cref(const _Tp&& __t);// = delete;

 #endif  // _LIBCPP_HAS_NO_DELETED_FUNCTIONS

 #endif  // _LIBCPP_HAS_NO_RVALUE_REFERENCES

 #endif  // _LIBCPP_HAS_NO_VARIADICS

 _LIBCPP_END_NAMESPACE_STD

 #endif  // _LIBCPP_FUNCTIONAL_BASE
	// -- C++ --
	//===----------------------------------------------------------------------===//
	//
	// The LLVM Compiler Infrastructure
	//
	// This file is dual licensed under the MIT and the University of Illinois Open
	// Source Licenses. See LICENSE.TXT for details.
	//
	//===----------------------------------------------------------------------===//

	#ifndef _LIBCPP_FUNCTIONAL_BASE
	#define _LIBCPP_FUNCTIONAL_BASE

	#include <__config>
	#include <type_traits>
	#include <typeinfo>
	#include <exception>

	#pragma GCC system_header

	_LIBCPP_BEGIN_NAMESPACE_STD

	template <class _Arg, class _Result>
	struct _LIBCPP_VISIBLE unary_function
	{
	typedef _Arg argument_type;
	typedef _Result result_type;
	};

	template <class _Arg1, class _Arg2, class _Result>
	struct _LIBCPP_VISIBLE binary_function
	{
	typedef _Arg1 first_argument_type;
	typedef _Arg2 second_argument_type;
	typedef _Result result_type;
	};

	template <class _Tp> struct _LIBCPP_VISIBLE hash;

	template <class _Tp>
	struct __has_result_type
	{
	private:
	struct __two {char _; char __;};
	template <class _Up> static __two __test(...);
	template <class _Up> static char __test(typename _Up::result_type* = 0);
	public:
	static const bool value = sizeof(__test<_Tp>(0)) == 1;
	};

	#ifdef _LIBCPP_HAS_NO_VARIADICS

	#include <__functional_base_03>

	#else // _LIBCPP_HAS_NO_VARIADICS

	// __weak_result_type

	template <class _Tp>
	struct __derives_from_unary_function
	{
	private:
	struct __two {char _; char __;};
	static __two __test(...);
	template <class _A, class _R>
	static unary_function<_A, _R>
	__test(const volatile unary_function<_A, _R>*);
	public:
	static const bool value = !is_same<decltype(__test((_Tp*)0)), __two>::value;
	typedef decltype(__test((_Tp*)0)) type;
	};

	template <class _Tp>
	struct __derives_from_binary_function
	{
	private:
	struct __two {char _; char __;};
	static __two __test(...);
	template <class _A1, class _A2, class _R>
	static binary_function<_A1, _A2, _R>
	__test(const volatile binary_function<_A1, _A2, _R>*);
	public:
	static const bool value = !is_same<decltype(__test((_Tp*)0)), __two>::value;
	typedef decltype(__test((_Tp*)0)) type;
	};

	template <class _Tp, bool = __derives_from_unary_function<_Tp>::value>
	struct __maybe_derive_from_unary_function // bool is true
	: public __derives_from_unary_function<_Tp>::type
	{
	};

	template <class _Tp>
	struct __maybe_derive_from_unary_function<_Tp, false>
	{
	};

	template <class _Tp, bool = __derives_from_binary_function<_Tp>::value>
	struct __maybe_derive_from_binary_function // bool is true
	: public __derives_from_binary_function<_Tp>::type
	{
	};

	template <class _Tp>
	struct __maybe_derive_from_binary_function<_Tp, false>
	{
	};

	template <class _Tp, bool = __has_result_type<_Tp>::value>
	struct __weak_result_type_imp // bool is true
	: public __maybe_derive_from_unary_function<_Tp>,
	public __maybe_derive_from_binary_function<_Tp>
	{
	typedef typename _Tp::result_type result_type;
	};

	template <class _Tp>
	struct __weak_result_type_imp<_Tp, false>
	: public __maybe_derive_from_unary_function<_Tp>,
	public __maybe_derive_from_binary_function<_Tp>
	{
	};

	template <class _Tp>
	struct __weak_result_type
	: public __weak_result_type_imp<_Tp>
	{
	};

	// 0 argument case

	template <class _R>
	struct __weak_result_type<_R ()>
	{
	typedef _R result_type;
	};

	template <class _R>
	struct __weak_result_type<_R (&)()>
	{
	typedef _R result_type;
	};

	template <class _R>
	struct __weak_result_type<_R (*)()>
	{
	typedef _R result_type;
	};

	// 1 argument case

	template <class _R, class _A1>
	struct __weak_result_type<_R (_A1)>
	: public unary_function<_A1, _R>
	{
	};

	template <class _R, class _A1>
	struct __weak_result_type<_R (&)(_A1)>
	: public unary_function<_A1, _R>
	{
	};

	template <class _R, class _A1>
	struct __weak_result_type<_R (*)(_A1)>
	: public unary_function<_A1, _R>
	{
	};

	template <class _R, class _C>
	struct __weak_result_type<_R (_C::*)()>
	: public unary_function<_C*, _R>
	{
	};

	template <class _R, class _C>
	struct __weak_result_type<_R (_C::*)() const>
	: public unary_function<const _C*, _R>
	{
	};

	template <class _R, class _C>
	struct __weak_result_type<_R (_C::*)() volatile>
	: public unary_function<volatile _C*, _R>
	{
	};

	template <class _R, class _C>
	struct __weak_result_type<_R (_C::*)() const volatile>
	: public unary_function<const volatile _C*, _R>
	{
	};

	// 2 argument case

	template <class _R, class _A1, class _A2>
	struct __weak_result_type<_R (_A1, _A2)>
	: public binary_function<_A1, _A2, _R>
	{
	};

	template <class _R, class _A1, class _A2>
	struct __weak_result_type<_R (*)(_A1, _A2)>
	: public binary_function<_A1, _A2, _R>
	{
	};

	template <class _R, class _A1, class _A2>
	struct __weak_result_type<_R (&)(_A1, _A2)>
	: public binary_function<_A1, _A2, _R>
	{
	};

	template <class _R, class _C, class _A1>
	struct __weak_result_type<_R (_C::*)(_A1)>
	: public binary_function<_C*, _A1, _R>
	{
	};

	template <class _R, class _C, class _A1>
	struct __weak_result_type<_R (_C::*)(_A1) const>
	: public binary_function<const _C*, _A1, _R>
	{
	};

	template <class _R, class _C, class _A1>
	struct __weak_result_type<_R (_C::*)(_A1) volatile>
	: public binary_function<volatile _C*, _A1, _R>
	{
	};

	template <class _R, class _C, class _A1>
	struct __weak_result_type<_R (_C::*)(_A1) const volatile>
	: public binary_function<const volatile _C*, _A1, _R>
	{
	};

	// 3 or more arguments

	template <class _R, class _A1, class _A2, class _A3, class ..._A4>
	struct __weak_result_type<_R (_A1, _A2, _A3, _A4...)>
	{
	typedef _R result_type;
	};

	template <class _R, class _A1, class _A2, class _A3, class ..._A4>
	struct __weak_result_type<_R (&)(_A1, _A2, _A3, _A4...)>
	{
	typedef _R result_type;
	};

	template <class _R, class _A1, class _A2, class _A3, class ..._A4>
	struct __weak_result_type<_R (*)(_A1, _A2, _A3, _A4...)>
	{
	typedef _R result_type;
	};

	template <class _R, class _C, class _A1, class _A2, class ..._A3>
	struct __weak_result_type<_R (_C::*)(_A1, _A2, _A3...)>
	{
	typedef _R result_type;
	};

	template <class _R, class _C, class _A1, class _A2, class ..._A3>
	struct __weak_result_type<_R (_C::*)(_A1, _A2, _A3...) const>
	{
	typedef _R result_type;
	};

	template <class _R, class _C, class _A1, class _A2, class ..._A3>
	struct __weak_result_type<_R (_C::*)(_A1, _A2, _A3...) volatile>
	{
	typedef _R result_type;
	};

	template <class _R, class _C, class _A1, class _A2, class ..._A3>
	struct __weak_result_type<_R (_C::*)(_A1, _A2, _A3...) const volatile>
	{
	typedef _R result_type;
	};

	// __invoke

	// first bullet

	template <class _R, class _T, class _T1, class ..._Param, class ..._Arg>
	inline _LIBCPP_INLINE_VISIBILITY
	typename enable_if
	<
	sizeof...(_Param) == sizeof...(_Arg) &&
	is_base_of<_T, typename remove_reference<_T1>::type>::value,
	_R
	>::type
	__invoke(_R (_T::*__f)(_Param...), _T1&& __t1, _Arg&& ...__arg)
	{
	return (_STD::forward<_T>(__t1).*__f)(_STD::forward<_Arg>(__arg)...);
	}

	template <class _R, class _T, class _T1, class ..._Param, class ..._Arg>
	inline _LIBCPP_INLINE_VISIBILITY
	typename enable_if
	<
	sizeof...(_Param) == sizeof...(_Arg) &&
	is_base_of<_T, typename remove_reference<_T1>::type>::value,
	_R
	>::type
	__invoke(_R (_T::*__f)(_Param...) const, _T1&& __t1, _Arg&& ...__arg)
	{
	return (_STD::forward<const _T>(__t1).*__f)(_STD::forward<_Arg>(__arg)...);
	}

	template <class _R, class _T, class _T1, class ..._Param, class ..._Arg>
	inline _LIBCPP_INLINE_VISIBILITY
	typename enable_if
	<
	sizeof...(_Param) == sizeof...(_Arg) &&
	is_base_of<_T, typename remove_reference<_T1>::type>::value,
	_R
	>::type
	__invoke(_R (_T::*__f)(_Param...) volatile, _T1&& __t1, _Arg&& ...__arg)
	{
	return (_STD::forward<volatile _T>(__t1).*__f)(_STD::forward<_Arg>(__arg)...);
	}

	template <class _R, class _T, class _T1, class ..._Param, class ..._Arg>
	inline _LIBCPP_INLINE_VISIBILITY
	typename enable_if
	<
	sizeof...(_Param) == sizeof...(_Arg) &&
	is_base_of<_T, typename remove_reference<_T1>::type>::value,
	_R
	>::type
	__invoke(_R (_T::*__f)(_Param...) const volatile, _T1&& __t1, _Arg&& ...__arg)
	{
	return (_STD::forward<const volatile _T>(__t1).*__f)(_STD::forward<_Arg>(__arg)...);
	}

	// second bullet

	template <class _R, class _T, class _T1, class ..._Param, class ..._Arg>
	inline _LIBCPP_INLINE_VISIBILITY
	typename enable_if
	<
	sizeof...(_Param) == sizeof...(_Arg) &&
	!is_base_of<_T, typename remove_reference<_T1>::type>::value,
	_R
	>::type
	__invoke(_R (_T::*__f)(_Param...), _T1&& __t1, _Arg&& ...__arg)
	{
	return ((_STD::forward<_T1>(__t1)).__f)(_STD::forward<_Arg>(__arg)...);
	}

	template <class _R, class _T, class _T1, class ..._Param, class ..._Arg>
	inline _LIBCPP_INLINE_VISIBILITY
	typename enable_if
	<
	sizeof...(_Param) == sizeof...(_Arg) &&
	!is_base_of<_T, typename remove_reference<_T1>::type>::value,
	_R
	>::type
	__invoke(_R (_T::*__f)(_Param...) const, _T1&& __t1, _Arg&& ...__arg)
	{
	return ((_STD::forward<_T1>(__t1)).__f)(_STD::forward<_Arg>(__arg)...);
	}

	template <class _R, class _T, class _T1, class ..._Param, class ..._Arg>
	inline _LIBCPP_INLINE_VISIBILITY
	typename enable_if
	<
	sizeof...(_Param) == sizeof...(_Arg) &&
	!is_base_of<_T, typename remove_reference<_T1>::type>::value,
	_R
	>::type
	__invoke(_R (_T::*__f)(_Param...) volatile, _T1&& __t1, _Arg&& ...__arg)
	{
	return ((_STD::forward<_T1>(__t1)).__f)(_STD::forward<_Arg>(__arg)...);
	}

	template <class _R, class _T, class _T1, class ..._Param, class ..._Arg>
	inline _LIBCPP_INLINE_VISIBILITY
	typename enable_if
	<
	sizeof...(_Param) == sizeof...(_Arg) &&
	!is_base_of<_T, typename remove_reference<_T1>::type>::value,
	_R
	>::type
	__invoke(_R (_T::*__f)(_Param...) const volatile, _T1&& __t1, _Arg&& ...__arg)
	{
	return ((_STD::forward<_T1>(__t1)).__f)(_STD::forward<_Arg>(__arg)...);
	}

	// third bullet

	template <class _R, class _T, class _T1>
	inline _LIBCPP_INLINE_VISIBILITY
	typename enable_if
	<
	is_base_of<_T, typename remove_reference<_T1>::type>::value,
	typename __apply_cv<_T1, _R>::type&&
	>::type
	__invoke(_R _T::* __f, _T1&& __t1)
	{
	return _STD::forward<_T1>(__t1).*__f;
	}

	// forth bullet

	template <class _T1, class _R, bool>
	struct __4th_helper
	{
	};

	template <class _T1, class _R>
	struct __4th_helper<_T1, _R, true>
	{
	typedef typename __apply_cv<decltype(*_STD::declval<_T1>()), _R>::type type;
	};

	template <class _R, class _T, class _T1>
	inline _LIBCPP_INLINE_VISIBILITY
	typename __4th_helper<_T1, _R,
	!is_base_of<_T,
	typename remove_reference<_T1>::type
	>::value
	>::type&&
	__invoke(_R _T::* __f, _T1&& __t1)
	{
	return (_STD::forward<_T1>(__t1)).__f;
	}

	// fifth bullet

	template <class _F, class ..._T>
	inline _LIBCPP_INLINE_VISIBILITY
	typename result_of<_F(_T...)>::type
	__invoke(_F&& __f, _T&& ...__t)
	{
	return _STD::forward<_F>(__f)(_STD::forward<_T>(__t)...);
	}

	template <class _Tp, class ..._Args>
	struct __invoke_return
	{
	typedef decltype(__invoke(_STD::declval<_Tp>(), _STD::declval<_Args>()...)) type;
	};

	template <class _Tp>
	class _LIBCPP_VISIBLE reference_wrapper
	: public __weak_result_type<_Tp>
	{
	public:
	// types
	typedef _Tp type;
	private:
	type* __f_;

	public:
	// construct/copy/destroy
	_LIBCPP_INLINE_VISIBILITY reference_wrapper(type& __f) : __f_(&__f) {}
	#ifndef _LIBCPP_HAS_NO_RVALUE_REFERENCES
	private: reference_wrapper(type&&); public: // = delete; // do not bind to temps
	#endif

	// access
	_LIBCPP_INLINE_VISIBILITY operator type& () const {return *__f_;}
	_LIBCPP_INLINE_VISIBILITY type& get() const {return *__f_;}

	// invoke
	template <class... _ArgTypes>
	_LIBCPP_INLINE_VISIBILITY
	typename __invoke_return<type&, _ArgTypes...>::type
	operator() (_ArgTypes&&... __args) const
	{
	return __invoke(get(), _STD::forward<_ArgTypes>(__args)...);
	}
	};

	template <class _Tp> struct ____is_reference_wrapper : public false_type {};
	template <class _Tp> struct ____is_reference_wrapper<reference_wrapper<_Tp> > : public true_type {};
	template <class _Tp> struct __is_reference_wrapper
	: public ____is_reference_wrapper<typename remove_cv<_Tp>::type> {};

	template <class _Tp>
	inline _LIBCPP_INLINE_VISIBILITY
	reference_wrapper<_Tp>
	ref(_Tp& __t)
	{
	return reference_wrapper<_Tp>(__t);
	}

	template <class _Tp>
	inline _LIBCPP_INLINE_VISIBILITY
	reference_wrapper<_Tp>
	ref(reference_wrapper<_Tp> __t)
	{
	return ref(__t.get());
	}

	template <class _Tp>
	inline _LIBCPP_INLINE_VISIBILITY
	reference_wrapper<const _Tp>
	cref(const _Tp& __t)
	{
	return reference_wrapper<const _Tp>(__t);
	}

	template <class _Tp>
	inline _LIBCPP_INLINE_VISIBILITY
	reference_wrapper<const _Tp>
	cref(reference_wrapper<_Tp> __t)
	{
	return cref(__t.get());
	}

	#ifndef _LIBCPP_HAS_NO_RVALUE_REFERENCES
	#ifndef _LIBCPP_HAS_NO_DELETED_FUNCTIONS

	template <class _Tp> void ref(const _Tp&& __t) = delete;
	template <class _Tp> void cref(const _Tp&& __t) = delete;

	#else // _LIBCPP_HAS_NO_DELETED_FUNCTIONS

	template <class _Tp> void ref(const _Tp&& __t);// = delete;
	template <class _Tp> void cref(const _Tp&& __t);// = delete;

	#endif // _LIBCPP_HAS_NO_DELETED_FUNCTIONS

	#endif // _LIBCPP_HAS_NO_RVALUE_REFERENCES

	#endif // _LIBCPP_HAS_NO_VARIADICS

	_LIBCPP_END_NAMESPACE_STD

	#endif // _LIBCPP_FUNCTIONAL_BASE