include/__functional_base - chromium/llvm-project/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>
 #include <new>

 #if !defined(_LIBCPP_HAS_NO_PRAGMA_SYSTEM_HEADER)
 #pragma GCC system_header
 #endif

 _LIBCPP_BEGIN_NAMESPACE_STD

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

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

 template <class _Tp> struct _LIBCPP_TYPE_VIS_ONLY hash;

 template <class _Tp>
 struct __has_result_type
 {
 private:
  struct __two {char __lx; char __lxx;};
  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;
 };

 #if _LIBCPP_STD_VER > 11
 template <class _Tp = void>
 #else
 template <class _Tp>
 #endif
 struct _LIBCPP_TYPE_VIS_ONLY less : binary_function<_Tp, _Tp, bool>
 {
  _LIBCPP_CONSTEXPR_AFTER_CXX11 _LIBCPP_INLINE_VISIBILITY
  bool operator()(const _Tp& __x, const _Tp& __y) const
  {return __x < __y;}
 };

 #if _LIBCPP_STD_VER > 11
 template <>
 struct _LIBCPP_TYPE_VIS_ONLY less<void>
 {
  template <class _T1, class _T2>
  _LIBCPP_CONSTEXPR_AFTER_CXX11 _LIBCPP_INLINE_VISIBILITY
  auto operator()(_T1&& __t, _T2&& __u) const
  _NOEXCEPT_(noexcept(_VSTD::forward<_T1>(__t) < _VSTD::forward<_T2>(__u)))
  -> decltype (_VSTD::forward<_T1>(__t) < _VSTD::forward<_T2>(__u))
  { return _VSTD::forward<_T1>(__t) < _VSTD::forward<_T2>(__u); }
  typedef void is_transparent;
 };
 #endif

 // addressof

 template <class _Tp>
 inline _LIBCPP_INLINE_VISIBILITY
 _Tp*
 addressof(_Tp& __x) _NOEXCEPT
 {
  return (_Tp*)&reinterpret_cast<const volatile char&>(__x);
 }

 #if defined(_LIBCPP_HAS_OBJC_ARC) && !defined(_LIBCPP_PREDEFINED_OBJC_ARC_ADDRESSOF)
 // Objective-C++ Automatic Reference Counting uses qualified pointers
 // that require special addressof() signatures. When
 // _LIBCPP_PREDEFINED_OBJC_ARC_ADDRESSOF is defined, the compiler
 // itself is providing these definitions. Otherwise, we provide them.
 template <class _Tp>
 inline _LIBCPP_INLINE_VISIBILITY
 __strong _Tp*
 addressof(__strong _Tp& __x) _NOEXCEPT
 {
  return &__x;
 }

 #ifdef _LIBCPP_HAS_OBJC_ARC_WEAK
 template <class _Tp>
 inline _LIBCPP_INLINE_VISIBILITY
 __weak _Tp*
 addressof(__weak _Tp& __x) _NOEXCEPT
 {
  return &__x;
 }
 #endif

 template <class _Tp>
 inline _LIBCPP_INLINE_VISIBILITY
 __autoreleasing _Tp*
 addressof(__autoreleasing _Tp& __x) _NOEXCEPT
 {
  return &__x;
 }

 template <class _Tp>
 inline _LIBCPP_INLINE_VISIBILITY
 __unsafe_unretained _Tp*
 addressof(__unsafe_unretained _Tp& __x) _NOEXCEPT
 {
  return &__x;
 }
 #endif

 #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 __lx; char __lxx;};
  static __two __test(...);
  template <class _Ap, class _Rp>
  static unary_function<_Ap, _Rp>
  __test(const volatile unary_function<_Ap, _Rp>*);
 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 __lx; char __lxx;};
  static __two __test(...);
  template <class _A1, class _A2, class _Rp>
  static binary_function<_A1, _A2, _Rp>
  __test(const volatile binary_function<_A1, _A2, _Rp>*);
 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 _Rp>
 struct __weak_result_type<_Rp ()>
 {
  typedef _Rp result_type;
 };

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

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

 // 1 argument case

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

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

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

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

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

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

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

 // 2 argument case

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

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

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

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

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

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

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

 // 3 or more arguments

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

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

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

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

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

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

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

 // __invoke

 // bullets 1 and 2

 template <class _Fp, class _A0, class ..._Args,
  class>
 inline _LIBCPP_INLINE_VISIBILITY
 auto
 __invoke(_Fp&& __f, _A0&& __a0, _Args&& ...__args)
  -> decltype((_VSTD::forward<_A0>(__a0).*__f)(_VSTD::forward<_Args>(__args)...))
 {
  return (_VSTD::forward<_A0>(__a0).*__f)(_VSTD::forward<_Args>(__args)...);
 }

 template <class _Fp, class _A0, class ..._Args,
  class>
 inline _LIBCPP_INLINE_VISIBILITY
 auto
 __invoke(_Fp&& __f, _A0&& __a0, _Args&& ...__args)
  -> decltype(((*_VSTD::forward<_A0>(__a0)).*__f)(_VSTD::forward<_Args>(__args)...))
 {
  return ((*_VSTD::forward<_A0>(__a0)).*__f)(_VSTD::forward<_Args>(__args)...);
 }

 // bullets 3 and 4

 template <class _Fp, class _A0,
  class>
 inline _LIBCPP_INLINE_VISIBILITY
 auto
 __invoke(_Fp&& __f, _A0&& __a0)
  -> decltype(_VSTD::forward<_A0>(__a0).*__f)
 {
  return _VSTD::forward<_A0>(__a0).*__f;
 }

 template <class _Fp, class _A0,
  class>
 inline _LIBCPP_INLINE_VISIBILITY
 auto
 __invoke(_Fp&& __f, _A0&& __a0)
  -> decltype((*_VSTD::forward<_A0>(__a0)).*__f)
 {
  return (*_VSTD::forward<_A0>(__a0)).*__f;
 }

 // bullet 5

 template <class _Fp, class ..._Args>
 inline _LIBCPP_INLINE_VISIBILITY
 auto
 __invoke(_Fp&& __f, _Args&& ...__args)
  -> decltype(_VSTD::forward<_Fp>(__f)(_VSTD::forward<_Args>(__args)...))
 {
  return _VSTD::forward<_Fp>(__f)(_VSTD::forward<_Args>(__args)...);
 }

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

 template <class _Ret>
 struct __invoke_void_return_wrapper
 {
  template <class ..._Args>
  static _Ret __call(_Args&&... __args)
  {
  return __invoke(_VSTD::forward<_Args>(__args)...);
  }
 };

 template <>
 struct __invoke_void_return_wrapper<void>
 {
  template <class ..._Args>
  static void __call(_Args&&... __args)
  {
  __invoke(_VSTD::forward<_Args>(__args)...);
  }
 };

 template <class _Tp>
 class _LIBCPP_TYPE_VIS_ONLY 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) _NOEXCEPT
  : __f_(_VSTD::addressof(__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 _NOEXCEPT {return *__f_;}
  _LIBCPP_INLINE_VISIBILITY type& get() const _NOEXCEPT {return *__f_;}

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

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

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

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

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

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

 #ifndef _LIBCPP_HAS_NO_RVALUE_REFERENCES
 #ifndef _LIBCPP_HAS_NO_DELETED_FUNCTIONS

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

 #else // _LIBCPP_HAS_NO_DELETED_FUNCTIONS

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

 #endif // _LIBCPP_HAS_NO_DELETED_FUNCTIONS

 #endif // _LIBCPP_HAS_NO_RVALUE_REFERENCES

 #endif // _LIBCPP_HAS_NO_VARIADICS

 #if _LIBCPP_STD_VER > 11
 template <class _Tp1, class _Tp2 = void>
 struct __is_transparent
 {
 private:
  struct __two {char __lx; char __lxx;};
  template <class _Up> static __two __test(...);
  template <class _Up> static char __test(typename _Up::is_transparent* = 0);
 public:
  static const bool value = sizeof(__test<_Tp1>(0)) == 1;
 };
 #endif

 // allocator_arg_t

 struct _LIBCPP_TYPE_VIS_ONLY allocator_arg_t { };

 #if defined(_LIBCPP_HAS_NO_CONSTEXPR) || defined(_LIBCPP_BUILDING_MEMORY)
 extern const allocator_arg_t allocator_arg;
 #else
 constexpr allocator_arg_t allocator_arg = allocator_arg_t();
 #endif

 // uses_allocator

 template <class _Tp>
 struct __has_allocator_type
 {
 private:
  struct __two {char __lx; char __lxx;};
  template <class _Up> static __two __test(...);
  template <class _Up> static char __test(typename _Up::allocator_type* = 0);
 public:
  static const bool value = sizeof(__test<_Tp>(0)) == 1;
 };

 template <class _Tp, class _Alloc, bool = __has_allocator_type<_Tp>::value>
 struct __uses_allocator
  : public integral_constant<bool,
  is_convertible<_Alloc, typename _Tp::allocator_type>::value>
 {
 };

 template <class _Tp, class _Alloc>
 struct __uses_allocator<_Tp, _Alloc, false>
  : public false_type
 {
 };

 template <class _Tp, class _Alloc>
 struct _LIBCPP_TYPE_VIS_ONLY uses_allocator
  : public __uses_allocator<_Tp, _Alloc>
 {
 };

 #ifndef _LIBCPP_HAS_NO_VARIADICS

 // allocator construction

 template <class _Tp, class _Alloc, class ..._Args>
 struct __uses_alloc_ctor_imp
 {
  static const bool __ua = uses_allocator<_Tp, _Alloc>::value;
  static const bool __ic =
  is_constructible<_Tp, allocator_arg_t, _Alloc, _Args...>::value;
  static const int value = __ua ? 2 - __ic : 0;
 };

 template <class _Tp, class _Alloc, class ..._Args>
 struct __uses_alloc_ctor
  : integral_constant<int, __uses_alloc_ctor_imp<_Tp, _Alloc, _Args...>::value>
  {};

 template <class _Tp, class _Allocator, class... _Args>
 inline _LIBCPP_INLINE_VISIBILITY
 void __user_alloc_construct_impl (integral_constant<int, 0>, _Tp *__storage, const _Allocator &, _Args &&... __args )
 {
  new (__storage) _Tp (_VSTD::forward<_Args>(__args)...);
 }

 template <class _Tp, class _Allocator, class... _Args>
 inline _LIBCPP_INLINE_VISIBILITY
 void __user_alloc_construct_impl (integral_constant<int, 1>, _Tp *__storage, const _Allocator &__a, _Args &&... __args )
 {
  new (__storage) _Tp (allocator_arg, __a, _VSTD::forward<_Args>(__args)...);
 }

 template <class _Tp, class _Allocator, class... _Args>
 inline _LIBCPP_INLINE_VISIBILITY
 void __user_alloc_construct_impl (integral_constant<int, 2>, _Tp *__storage, const _Allocator &__a, _Args &&... __args )
 {
  new (__storage) _Tp (_VSTD::forward<_Args>(__args)..., __a);
 }

 template <class _Tp, class _Allocator, class... _Args>
 inline _LIBCPP_INLINE_VISIBILITY
 void __user_alloc_construct (_Tp *__storage, const _Allocator &__a, _Args &&... __args)
 {
  __user_alloc_construct_impl(
  __uses_alloc_ctor<_Tp, _Allocator>(),
  __storage, __a, _VSTD::forward<_Args>(__args)...
  );
 }
 #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>
	#include <new>

	#if !defined(_LIBCPP_HAS_NO_PRAGMA_SYSTEM_HEADER)
	#pragma GCC system_header
	#endif

	_LIBCPP_BEGIN_NAMESPACE_STD

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

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

	template <class _Tp> struct _LIBCPP_TYPE_VIS_ONLY hash;

	template <class _Tp>
	struct __has_result_type
	{
	private:
	struct __two {char __lx; char __lxx;};
	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;
	};

	#if _LIBCPP_STD_VER > 11
	template <class _Tp = void>
	#else
	template <class _Tp>
	#endif
	struct _LIBCPP_TYPE_VIS_ONLY less : binary_function<_Tp, _Tp, bool>
	{
	_LIBCPP_CONSTEXPR_AFTER_CXX11 _LIBCPP_INLINE_VISIBILITY
	bool operator()(const _Tp& __x, const _Tp& __y) const
	{return __x < __y;}
	};

	#if _LIBCPP_STD_VER > 11
	template <>
	struct _LIBCPP_TYPE_VIS_ONLY less<void>
	{
	template <class _T1, class _T2>
	_LIBCPP_CONSTEXPR_AFTER_CXX11 _LIBCPP_INLINE_VISIBILITY
	auto operator()(_T1&& __t, _T2&& __u) const
	_NOEXCEPT_(noexcept(_VSTD::forward<_T1>(__t) < _VSTD::forward<_T2>(__u)))
	-> decltype (_VSTD::forward<_T1>(__t) < _VSTD::forward<_T2>(__u))
	{ return _VSTD::forward<_T1>(__t) < _VSTD::forward<_T2>(__u); }
	typedef void is_transparent;
	};
	#endif

	// addressof

	template <class _Tp>
	inline _LIBCPP_INLINE_VISIBILITY
	_Tp*
	addressof(_Tp& __x) _NOEXCEPT
	{
	return (_Tp*)&reinterpret_cast<const volatile char&>(__x);
	}

	#if defined(_LIBCPP_HAS_OBJC_ARC) && !defined(_LIBCPP_PREDEFINED_OBJC_ARC_ADDRESSOF)
	// Objective-C++ Automatic Reference Counting uses qualified pointers
	// that require special addressof() signatures. When
	// _LIBCPP_PREDEFINED_OBJC_ARC_ADDRESSOF is defined, the compiler
	// itself is providing these definitions. Otherwise, we provide them.
	template <class _Tp>
	inline _LIBCPP_INLINE_VISIBILITY
	__strong _Tp*
	addressof(__strong _Tp& __x) _NOEXCEPT
	{
	return &__x;
	}

	#ifdef _LIBCPP_HAS_OBJC_ARC_WEAK
	template <class _Tp>
	inline _LIBCPP_INLINE_VISIBILITY
	__weak _Tp*
	addressof(__weak _Tp& __x) _NOEXCEPT
	{
	return &__x;
	}
	#endif

	template <class _Tp>
	inline _LIBCPP_INLINE_VISIBILITY
	__autoreleasing _Tp*
	addressof(__autoreleasing _Tp& __x) _NOEXCEPT
	{
	return &__x;
	}

	template <class _Tp>
	inline _LIBCPP_INLINE_VISIBILITY
	__unsafe_unretained _Tp*
	addressof(__unsafe_unretained _Tp& __x) _NOEXCEPT
	{
	return &__x;
	}
	#endif

	#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 __lx; char __lxx;};
	static __two __test(...);
	template <class _Ap, class _Rp>
	static unary_function<_Ap, _Rp>
	__test(const volatile unary_function<_Ap, _Rp>*);
	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 __lx; char __lxx;};
	static __two __test(...);
	template <class _A1, class _A2, class _Rp>
	static binary_function<_A1, _A2, _Rp>
	__test(const volatile binary_function<_A1, _A2, _Rp>*);
	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 _Rp>
	struct __weak_result_type<_Rp ()>
	{
	typedef _Rp result_type;
	};

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

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

	// 1 argument case

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

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

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

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

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

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

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

	// 2 argument case

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

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

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

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

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

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

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

	// 3 or more arguments

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

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

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

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

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

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

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

	// __invoke

	// bullets 1 and 2

	template <class _Fp, class _A0, class ..._Args,
	class>
	inline _LIBCPP_INLINE_VISIBILITY
	auto
	__invoke(_Fp&& __f, _A0&& __a0, _Args&& ...__args)
	-> decltype((_VSTD::forward<_A0>(__a0).*__f)(_VSTD::forward<_Args>(__args)...))
	{
	return (_VSTD::forward<_A0>(__a0).*__f)(_VSTD::forward<_Args>(__args)...);
	}

	template <class _Fp, class _A0, class ..._Args,
	class>
	inline _LIBCPP_INLINE_VISIBILITY
	auto
	__invoke(_Fp&& __f, _A0&& __a0, _Args&& ...__args)
	-> decltype(((_VSTD::forward<_A0>(__a0)).__f)(_VSTD::forward<_Args>(__args)...))
	{
	return ((_VSTD::forward<_A0>(__a0)).__f)(_VSTD::forward<_Args>(__args)...);
	}

	// bullets 3 and 4

	template <class _Fp, class _A0,
	class>
	inline _LIBCPP_INLINE_VISIBILITY
	auto
	__invoke(_Fp&& __f, _A0&& __a0)
	-> decltype(_VSTD::forward<_A0>(__a0).*__f)
	{
	return _VSTD::forward<_A0>(__a0).*__f;
	}

	template <class _Fp, class _A0,
	class>
	inline _LIBCPP_INLINE_VISIBILITY
	auto
	__invoke(_Fp&& __f, _A0&& __a0)
	-> decltype((_VSTD::forward<_A0>(__a0)).__f)
	{
	return (_VSTD::forward<_A0>(__a0)).__f;
	}

	// bullet 5

	template <class _Fp, class ..._Args>
	inline _LIBCPP_INLINE_VISIBILITY
	auto
	__invoke(_Fp&& __f, _Args&& ...__args)
	-> decltype(_VSTD::forward<_Fp>(__f)(_VSTD::forward<_Args>(__args)...))
	{
	return _VSTD::forward<_Fp>(__f)(_VSTD::forward<_Args>(__args)...);
	}

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

	template <class _Ret>
	struct __invoke_void_return_wrapper
	{
	template <class ..._Args>
	static _Ret __call(_Args&&... __args)
	{
	return __invoke(_VSTD::forward<_Args>(__args)...);
	}
	};

	template <>
	struct __invoke_void_return_wrapper<void>
	{
	template <class ..._Args>
	static void __call(_Args&&... __args)
	{
	__invoke(_VSTD::forward<_Args>(__args)...);
	}
	};

	template <class _Tp>
	class _LIBCPP_TYPE_VIS_ONLY 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) _NOEXCEPT
	: __f_(_VSTD::addressof(__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 _NOEXCEPT {return *__f_;}
	_LIBCPP_INLINE_VISIBILITY type& get() const _NOEXCEPT {return *__f_;}

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

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

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

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

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

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

	#ifndef _LIBCPP_HAS_NO_RVALUE_REFERENCES
	#ifndef _LIBCPP_HAS_NO_DELETED_FUNCTIONS

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

	#else // _LIBCPP_HAS_NO_DELETED_FUNCTIONS

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

	#endif // _LIBCPP_HAS_NO_DELETED_FUNCTIONS

	#endif // _LIBCPP_HAS_NO_RVALUE_REFERENCES

	#endif // _LIBCPP_HAS_NO_VARIADICS

	#if _LIBCPP_STD_VER > 11
	template <class _Tp1, class _Tp2 = void>
	struct __is_transparent
	{
	private:
	struct __two {char __lx; char __lxx;};
	template <class _Up> static __two __test(...);
	template <class _Up> static char __test(typename _Up::is_transparent* = 0);
	public:
	static const bool value = sizeof(__test<_Tp1>(0)) == 1;
	};
	#endif

	// allocator_arg_t

	struct _LIBCPP_TYPE_VIS_ONLY allocator_arg_t { };

	#if defined(_LIBCPP_HAS_NO_CONSTEXPR) \|\| defined(_LIBCPP_BUILDING_MEMORY)
	extern const allocator_arg_t allocator_arg;
	#else
	constexpr allocator_arg_t allocator_arg = allocator_arg_t();
	#endif

	// uses_allocator

	template <class _Tp>
	struct __has_allocator_type
	{
	private:
	struct __two {char __lx; char __lxx;};
	template <class _Up> static __two __test(...);
	template <class _Up> static char __test(typename _Up::allocator_type* = 0);
	public:
	static const bool value = sizeof(__test<_Tp>(0)) == 1;
	};

	template <class _Tp, class _Alloc, bool = __has_allocator_type<_Tp>::value>
	struct __uses_allocator
	: public integral_constant<bool,
	is_convertible<_Alloc, typename _Tp::allocator_type>::value>
	{
	};

	template <class _Tp, class _Alloc>
	struct __uses_allocator<_Tp, _Alloc, false>
	: public false_type
	{
	};

	template <class _Tp, class _Alloc>
	struct _LIBCPP_TYPE_VIS_ONLY uses_allocator
	: public __uses_allocator<_Tp, _Alloc>
	{
	};

	#ifndef _LIBCPP_HAS_NO_VARIADICS

	// allocator construction

	template <class _Tp, class _Alloc, class ..._Args>
	struct __uses_alloc_ctor_imp
	{
	static const bool __ua = uses_allocator<_Tp, _Alloc>::value;
	static const bool __ic =
	is_constructible<_Tp, allocator_arg_t, _Alloc, _Args...>::value;
	static const int value = __ua ? 2 - __ic : 0;
	};

	template <class _Tp, class _Alloc, class ..._Args>
	struct __uses_alloc_ctor
	: integral_constant<int, __uses_alloc_ctor_imp<_Tp, _Alloc, _Args...>::value>
	{};

	template <class _Tp, class _Allocator, class... _Args>
	inline _LIBCPP_INLINE_VISIBILITY
	void __user_alloc_construct_impl (integral_constant<int, 0>, _Tp *__storage, const _Allocator &, _Args &&... __args )
	{
	new (__storage) _Tp (_VSTD::forward<_Args>(__args)...);
	}

	template <class _Tp, class _Allocator, class... _Args>
	inline _LIBCPP_INLINE_VISIBILITY
	void __user_alloc_construct_impl (integral_constant<int, 1>, _Tp *__storage, const _Allocator &__a, _Args &&... __args )
	{
	new (__storage) _Tp (allocator_arg, __a, _VSTD::forward<_Args>(__args)...);
	}

	template <class _Tp, class _Allocator, class... _Args>
	inline _LIBCPP_INLINE_VISIBILITY
	void __user_alloc_construct_impl (integral_constant<int, 2>, _Tp *__storage, const _Allocator &__a, _Args &&... __args )
	{
	new (__storage) _Tp (_VSTD::forward<_Args>(__args)..., __a);
	}

	template <class _Tp, class _Allocator, class... _Args>
	inline _LIBCPP_INLINE_VISIBILITY
	void __user_alloc_construct (_Tp *__storage, const _Allocator &__a, _Args &&... __args)
	{
	__user_alloc_construct_impl(
	__uses_alloc_ctor<_Tp, _Allocator>(),
	__storage, __a, _VSTD::forward<_Args>(__args)...
	);
	}
	#endif // _LIBCPP_HAS_NO_VARIADICS

	_LIBCPP_END_NAMESPACE_STD

	#endif // _LIBCPP_FUNCTIONAL_BASE