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// C++11 type_traits -*- C++ -*-// Copyright (C) 2007-2012 Free Software Foundation, Inc.//// This file is part of the GNU ISO C++ Library. This library is free// software; you can redistribute it and/or modify it under the// terms of the GNU General Public License as published by the// Free Software Foundation; either version 3, or (at your option)// any later version.// This library is distributed in the hope that it will be useful,// but WITHOUT ANY WARRANTY; without even the implied warranty of// MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the// GNU General Public License for more details.// Under Section 7 of GPL version 3, you are granted additional// permissions described in the GCC Runtime Library Exception, version// 3.1, as published by the Free Software Foundation.// You should have received a copy of the GNU General Public License and// a copy of the GCC Runtime Library Exception along with this program;// see the files COPYING3 and COPYING.RUNTIME respectively. If not, see// <http://www.gnu.org/licenses/>./** @file include/type_traits* This is a Standard C++ Library header.*/#ifndef _GLIBCXX_TYPE_TRAITS#define _GLIBCXX_TYPE_TRAITS 1#pragma GCC system_header#if __cplusplus < 201103L# include <bits/c++0x_warning.h>#else#include <bits/c++config.h>namespace std _GLIBCXX_VISIBILITY(default){_GLIBCXX_BEGIN_NAMESPACE_VERSION/*** @defgroup metaprogramming Metaprogramming and type traits* @ingroup utilities** Template utilities for compile-time introspection and modification,* including type classification traits, type property inspection traits* and type transformation traits.** @{*//// integral_constanttemplate<typename _Tp, _Tp __v>struct integral_constant{static constexpr _Tp value = __v;typedef _Tp value_type;typedef integral_constant<_Tp, __v> type;constexpr operator value_type() { return value; }};/// The type used as a compile-time boolean with true value.typedef integral_constant<bool, true> true_type;/// The type used as a compile-time boolean with false value.typedef integral_constant<bool, false> false_type;template<typename _Tp, _Tp __v>constexpr _Tp integral_constant<_Tp, __v>::value;// Meta programming helper types.template<bool, typename, typename>struct conditional;template<typename...>struct __or_;template<>struct __or_<>: public false_type{ };template<typename _B1>struct __or_<_B1>: public _B1{ };template<typename _B1, typename _B2>struct __or_<_B1, _B2>: public conditional<_B1::value, _B1, _B2>::type{ };template<typename _B1, typename _B2, typename _B3, typename... _Bn>struct __or_<_B1, _B2, _B3, _Bn...>: public conditional<_B1::value, _B1, __or_<_B2, _B3, _Bn...>>::type{ };template<typename...>struct __and_;template<>struct __and_<>: public true_type{ };template<typename _B1>struct __and_<_B1>: public _B1{ };template<typename _B1, typename _B2>struct __and_<_B1, _B2>: public conditional<_B1::value, _B2, _B1>::type{ };template<typename _B1, typename _B2, typename _B3, typename... _Bn>struct __and_<_B1, _B2, _B3, _Bn...>: public conditional<_B1::value, __and_<_B2, _B3, _Bn...>, _B1>::type{ };template<typename _Pp>struct __not_: public integral_constant<bool, !_Pp::value>{ };struct __sfinae_types{typedef char __one;typedef struct { char __arr[2]; } __two;};// For several sfinae-friendly trait implementations we transport both the// result information (as the member type) and the failure information (no// member type). This is very similar to std::enable_if, but we cannot use// them, because we need to derive from them as an implementation detail.template<typename _Tp>struct __success_type{ typedef _Tp type; };struct __failure_type{ };// primary type categories.template<typename>struct remove_cv;template<typename>struct __is_void_helper: public false_type { };template<>struct __is_void_helper<void>: public true_type { };/// is_voidtemplate<typename _Tp>struct is_void: public integral_constant<bool, (__is_void_helper<typenameremove_cv<_Tp>::type>::value)>{ };template<typename>struct __is_integral_helper: public false_type { };template<>struct __is_integral_helper<bool>: public true_type { };template<>struct __is_integral_helper<char>: public true_type { };template<>struct __is_integral_helper<signed char>: public true_type { };template<>struct __is_integral_helper<unsigned char>: public true_type { };#ifdef _GLIBCXX_USE_WCHAR_Ttemplate<>struct __is_integral_helper<wchar_t>: public true_type { };#endiftemplate<>struct __is_integral_helper<char16_t>: public true_type { };template<>struct __is_integral_helper<char32_t>: public true_type { };template<>struct __is_integral_helper<short>: public true_type { };template<>struct __is_integral_helper<unsigned short>: public true_type { };template<>struct __is_integral_helper<int>: public true_type { };template<>struct __is_integral_helper<unsigned int>: public true_type { };template<>struct __is_integral_helper<long>: public true_type { };template<>struct __is_integral_helper<unsigned long>: public true_type { };template<>struct __is_integral_helper<long long>: public true_type { };template<>struct __is_integral_helper<unsigned long long>: public true_type { };#if !defined(__STRICT_ANSI__) && defined(_GLIBCXX_USE_INT128)template<>struct __is_integral_helper<__int128>: public true_type { };template<>struct __is_integral_helper<unsigned __int128>: public true_type { };#endif/// is_integraltemplate<typename _Tp>struct is_integral: public integral_constant<bool, (__is_integral_helper<typenameremove_cv<_Tp>::type>::value)>{ };template<typename>struct __is_floating_point_helper: public false_type { };template<>struct __is_floating_point_helper<float>: public true_type { };template<>struct __is_floating_point_helper<double>: public true_type { };template<>struct __is_floating_point_helper<long double>: public true_type { };#if !defined(__STRICT_ANSI__) && defined(_GLIBCXX_USE_FLOAT128)template<>struct __is_floating_point_helper<__float128>: public true_type { };#endif/// is_floating_pointtemplate<typename _Tp>struct is_floating_point: public integral_constant<bool, (__is_floating_point_helper<typenameremove_cv<_Tp>::type>::value)>{ };/// is_arraytemplate<typename>struct is_array: public false_type { };template<typename _Tp, std::size_t _Size>struct is_array<_Tp[_Size]>: public true_type { };template<typename _Tp>struct is_array<_Tp[]>: public true_type { };template<typename>struct __is_pointer_helper: public false_type { };template<typename _Tp>struct __is_pointer_helper<_Tp*>: public true_type { };/// is_pointertemplate<typename _Tp>struct is_pointer: public integral_constant<bool, (__is_pointer_helper<typenameremove_cv<_Tp>::type>::value)>{ };/// is_lvalue_referencetemplate<typename>struct is_lvalue_reference: public false_type { };template<typename _Tp>struct is_lvalue_reference<_Tp&>: public true_type { };/// is_rvalue_referencetemplate<typename>struct is_rvalue_reference: public false_type { };template<typename _Tp>struct is_rvalue_reference<_Tp&&>: public true_type { };template<typename>struct is_function;template<typename>struct __is_member_object_pointer_helper: public false_type { };template<typename _Tp, typename _Cp>struct __is_member_object_pointer_helper<_Tp _Cp::*>: public integral_constant<bool, !is_function<_Tp>::value> { };/// is_member_object_pointertemplate<typename _Tp>struct is_member_object_pointer: public integral_constant<bool, (__is_member_object_pointer_helper<typename remove_cv<_Tp>::type>::value)>{ };template<typename>struct __is_member_function_pointer_helper: public false_type { };template<typename _Tp, typename _Cp>struct __is_member_function_pointer_helper<_Tp _Cp::*>: public integral_constant<bool, is_function<_Tp>::value> { };/// is_member_function_pointertemplate<typename _Tp>struct is_member_function_pointer: public integral_constant<bool, (__is_member_function_pointer_helper<typename remove_cv<_Tp>::type>::value)>{ };/// is_enumtemplate<typename _Tp>struct is_enum: public integral_constant<bool, __is_enum(_Tp)>{ };/// is_uniontemplate<typename _Tp>struct is_union: public integral_constant<bool, __is_union(_Tp)>{ };/// is_classtemplate<typename _Tp>struct is_class: public integral_constant<bool, __is_class(_Tp)>{ };/// is_functiontemplate<typename>struct is_function: public false_type { };template<typename _Res, typename... _ArgTypes>struct is_function<_Res(_ArgTypes...)>: public true_type { };template<typename _Res, typename... _ArgTypes>struct is_function<_Res(_ArgTypes......)>: public true_type { };template<typename _Res, typename... _ArgTypes>struct is_function<_Res(_ArgTypes...) const>: public true_type { };template<typename _Res, typename... _ArgTypes>struct is_function<_Res(_ArgTypes......) const>: public true_type { };template<typename _Res, typename... _ArgTypes>struct is_function<_Res(_ArgTypes...) volatile>: public true_type { };template<typename _Res, typename... _ArgTypes>struct is_function<_Res(_ArgTypes......) volatile>: public true_type { };template<typename _Res, typename... _ArgTypes>struct is_function<_Res(_ArgTypes...) const volatile>: public true_type { };template<typename _Res, typename... _ArgTypes>struct is_function<_Res(_ArgTypes......) const volatile>: public true_type { };template<typename>struct __is_nullptr_t_helper: public false_type { };template<>struct __is_nullptr_t_helper<std::nullptr_t>: public true_type { };// __is_nullptr_t (extension).template<typename _Tp>struct __is_nullptr_t: public integral_constant<bool, (__is_nullptr_t_helper<typenameremove_cv<_Tp>::type>::value)>{ };// composite type categories./// is_referencetemplate<typename _Tp>struct is_reference: public __or_<is_lvalue_reference<_Tp>,is_rvalue_reference<_Tp>>::type{ };/// is_arithmetictemplate<typename _Tp>struct is_arithmetic: public __or_<is_integral<_Tp>, is_floating_point<_Tp>>::type{ };/// is_fundamentaltemplate<typename _Tp>struct is_fundamental: public __or_<is_arithmetic<_Tp>, is_void<_Tp>>::type{ };/// is_objecttemplate<typename _Tp>struct is_object: public __not_<__or_<is_function<_Tp>, is_reference<_Tp>,is_void<_Tp>>>::type{ };template<typename>struct is_member_pointer;/// is_scalartemplate<typename _Tp>struct is_scalar: public __or_<is_arithmetic<_Tp>, is_enum<_Tp>, is_pointer<_Tp>,is_member_pointer<_Tp>, __is_nullptr_t<_Tp>>::type{ };/// is_compoundtemplate<typename _Tp>struct is_compound: public integral_constant<bool, !is_fundamental<_Tp>::value> { };template<typename _Tp>struct __is_member_pointer_helper: public false_type { };template<typename _Tp, typename _Cp>struct __is_member_pointer_helper<_Tp _Cp::*>: public true_type { };/// is_member_pointertemplate<typename _Tp>struct is_member_pointer: public integral_constant<bool, (__is_member_pointer_helper<typename remove_cv<_Tp>::type>::value)>{ };// type properties./// is_consttemplate<typename>struct is_const: public false_type { };template<typename _Tp>struct is_const<_Tp const>: public true_type { };/// is_volatiletemplate<typename>struct is_volatile: public false_type { };template<typename _Tp>struct is_volatile<_Tp volatile>: public true_type { };/// is_trivialtemplate<typename _Tp>struct is_trivial: public integral_constant<bool, __is_trivial(_Tp)>{ };// is_trivially_copyable (still unimplemented)/// is_standard_layouttemplate<typename _Tp>struct is_standard_layout: public integral_constant<bool, __is_standard_layout(_Tp)>{ };/// is_pod// Could use is_standard_layout && is_trivial instead of the builtin.template<typename _Tp>struct is_pod: public integral_constant<bool, __is_pod(_Tp)>{ };/// is_literal_typetemplate<typename _Tp>struct is_literal_type: public integral_constant<bool, __is_literal_type(_Tp)>{ };/// is_emptytemplate<typename _Tp>struct is_empty: public integral_constant<bool, __is_empty(_Tp)>{ };/// is_polymorphictemplate<typename _Tp>struct is_polymorphic: public integral_constant<bool, __is_polymorphic(_Tp)>{ };/// is_abstracttemplate<typename _Tp>struct is_abstract: public integral_constant<bool, __is_abstract(_Tp)>{ };template<typename _Tp,bool = is_integral<_Tp>::value,bool = is_floating_point<_Tp>::value>struct __is_signed_helper: public false_type { };template<typename _Tp>struct __is_signed_helper<_Tp, false, true>: public true_type { };template<typename _Tp>struct __is_signed_helper<_Tp, true, false>: public integral_constant<bool, static_cast<bool>(_Tp(-1) < _Tp(0))>{ };/// is_signedtemplate<typename _Tp>struct is_signed: public integral_constant<bool, __is_signed_helper<_Tp>::value>{ };/// is_unsignedtemplate<typename _Tp>struct is_unsigned: public __and_<is_arithmetic<_Tp>, __not_<is_signed<_Tp>>>::type{ };// destructible and constructible type propertiestemplate<typename>struct add_rvalue_reference;/*** @brief Utility to simplify expressions used in unevaluated operands* @ingroup utilities*/template<typename _Tp>typename add_rvalue_reference<_Tp>::type declval() noexcept;template<typename, unsigned = 0>struct extent;template<typename>struct remove_all_extents;template<typename _Tp>struct __is_array_known_bounds: public integral_constant<bool, (extent<_Tp>::value > 0)>{ };template<typename _Tp>struct __is_array_unknown_bounds: public __and_<is_array<_Tp>, __not_<extent<_Tp>>>::type{ };// In N3290 is_destructible does not say anything about function// types and abstract types, see LWG 2049. This implementation// describes function types as non-destructible and all complete// object types as destructible, iff the explicit destructor// call expression is wellformed.struct __do_is_destructible_impl{template<typename _Tp, typename = decltype(declval<_Tp&>().~_Tp())>static true_type __test(int);template<typename>static false_type __test(...);};template<typename _Tp>struct __is_destructible_impl: public __do_is_destructible_impl{typedef decltype(__test<_Tp>(0)) type;};template<typename _Tp,bool = __or_<is_void<_Tp>,__is_array_unknown_bounds<_Tp>,is_function<_Tp>>::value,bool = __or_<is_reference<_Tp>, is_scalar<_Tp>>::value>struct __is_destructible_safe;template<typename _Tp>struct __is_destructible_safe<_Tp, false, false>: public __is_destructible_impl<typenameremove_all_extents<_Tp>::type>::type{ };template<typename _Tp>struct __is_destructible_safe<_Tp, true, false>: public false_type { };template<typename _Tp>struct __is_destructible_safe<_Tp, false, true>: public true_type { };/// is_destructibletemplate<typename _Tp>struct is_destructible: public integral_constant<bool, (__is_destructible_safe<_Tp>::value)>{ };// is_nothrow_destructible requires that is_destructible is// satisfied as well. We realize that by mimicing the// implementation of is_destructible but refer to noexcept(expr)// instead of decltype(expr).struct __do_is_nt_destructible_impl{template<typename _Tp>static integral_constant<bool, noexcept(declval<_Tp&>().~_Tp())>__test(int);template<typename>static false_type __test(...);};template<typename _Tp>struct __is_nt_destructible_impl: public __do_is_nt_destructible_impl{typedef decltype(__test<_Tp>(0)) type;};template<typename _Tp,bool = __or_<is_void<_Tp>,__is_array_unknown_bounds<_Tp>,is_function<_Tp>>::value,bool = __or_<is_reference<_Tp>, is_scalar<_Tp>>::value>struct __is_nt_destructible_safe;template<typename _Tp>struct __is_nt_destructible_safe<_Tp, false, false>: public __is_nt_destructible_impl<typenameremove_all_extents<_Tp>::type>::type{ };template<typename _Tp>struct __is_nt_destructible_safe<_Tp, true, false>: public false_type { };template<typename _Tp>struct __is_nt_destructible_safe<_Tp, false, true>: public true_type { };/// is_nothrow_destructibletemplate<typename _Tp>struct is_nothrow_destructible: public integral_constant<bool, (__is_nt_destructible_safe<_Tp>::value)>{ };struct __do_is_default_constructible_impl{template<typename _Tp, typename = decltype(_Tp())>static true_type __test(int);template<typename>static false_type __test(...);};template<typename _Tp>struct __is_default_constructible_impl: public __do_is_default_constructible_impl{typedef decltype(__test<_Tp>(0)) type;};template<typename _Tp>struct __is_default_constructible_atom: public __and_<__not_<is_void<_Tp>>,__is_default_constructible_impl<_Tp>>::type{ };template<typename _Tp, bool = is_array<_Tp>::value>struct __is_default_constructible_safe;// The following technique is a workaround for a current core language// restriction, which does not allow for array types to occur in// functional casts of the form T(). Complete arrays can be default-// constructed, if the element type is default-constructible, but// arrays with unknown bounds are not.template<typename _Tp>struct __is_default_constructible_safe<_Tp, true>: public __and_<__is_array_known_bounds<_Tp>,__is_default_constructible_atom<typenameremove_all_extents<_Tp>::type>>::type{ };template<typename _Tp>struct __is_default_constructible_safe<_Tp, false>: public __is_default_constructible_atom<_Tp>::type{ };/// is_default_constructibletemplate<typename _Tp>struct is_default_constructible: public integral_constant<bool, (__is_default_constructible_safe<_Tp>::value)>{ };// Implementation of is_constructible.// The hardest part of this trait is the binary direct-initialization// case, because we hit into a functional cast of the form T(arg).// This implementation uses different strategies depending on the// target type to reduce the test overhead as much as possible://// a) For a reference target type, we use a static_cast expression// modulo its extra cases.//// b) For a non-reference target type we use a ::new expression.struct __do_is_static_castable_impl{template<typename _From, typename _To, typename= decltype(static_cast<_To>(declval<_From>()))>static true_type __test(int);template<typename, typename>static false_type __test(...);};template<typename _From, typename _To>struct __is_static_castable_impl: public __do_is_static_castable_impl{typedef decltype(__test<_From, _To>(0)) type;};template<typename _From, typename _To>struct __is_static_castable_safe: public __is_static_castable_impl<_From, _To>::type{ };// __is_static_castabletemplate<typename _From, typename _To>struct __is_static_castable: public integral_constant<bool, (__is_static_castable_safe<_From, _To>::value)>{ };// Implementation for non-reference types. To meet the proper// variable definition semantics, we also need to test for// is_destructible in this case.// This form should be simplified by a single expression:// ::delete ::new _Tp(declval<_Arg>()), see c++/51222.struct __do_is_direct_constructible_impl{template<typename _Tp, typename _Arg, typename= decltype(::new _Tp(declval<_Arg>()))>static true_type __test(int);template<typename, typename>static false_type __test(...);};template<typename _Tp, typename _Arg>struct __is_direct_constructible_impl: public __do_is_direct_constructible_impl{typedef decltype(__test<_Tp, _Arg>(0)) type;};template<typename _Tp, typename _Arg>struct __is_direct_constructible_new_safe: public __and_<is_destructible<_Tp>,__is_direct_constructible_impl<_Tp, _Arg>>::type{ };template<typename, typename>struct is_same;template<typename, typename>struct is_base_of;template<typename>struct remove_reference;template<typename _From, typename _To, bool= __not_<__or_<is_void<_From>,is_function<_From>>>::value>struct __is_base_to_derived_ref;// Detect whether we have a downcast situation during// reference binding.template<typename _From, typename _To>struct __is_base_to_derived_ref<_From, _To, true>{typedef typename remove_cv<typename remove_reference<_From>::type>::type __src_t;typedef typename remove_cv<typename remove_reference<_To>::type>::type __dst_t;typedef __and_<__not_<is_same<__src_t, __dst_t>>,is_base_of<__src_t, __dst_t>> type;static constexpr bool value = type::value;};template<typename _From, typename _To>struct __is_base_to_derived_ref<_From, _To, false>: public false_type{ };template<typename _From, typename _To, bool= __and_<is_lvalue_reference<_From>,is_rvalue_reference<_To>>::value>struct __is_lvalue_to_rvalue_ref;// Detect whether we have an lvalue of non-function type// bound to a reference-compatible rvalue-reference.template<typename _From, typename _To>struct __is_lvalue_to_rvalue_ref<_From, _To, true>{typedef typename remove_cv<typename remove_reference<_From>::type>::type __src_t;typedef typename remove_cv<typename remove_reference<_To>::type>::type __dst_t;typedef __and_<__not_<is_function<__src_t>>,__or_<is_same<__src_t, __dst_t>,is_base_of<__dst_t, __src_t>>> type;static constexpr bool value = type::value;};template<typename _From, typename _To>struct __is_lvalue_to_rvalue_ref<_From, _To, false>: public false_type{ };// Here we handle direct-initialization to a reference type as// equivalent to a static_cast modulo overshooting conversions.// These are restricted to the following conversions:// a) A base class value to a derived class reference// b) An lvalue to an rvalue-reference of reference-compatible// types that are not functionstemplate<typename _Tp, typename _Arg>struct __is_direct_constructible_ref_cast: public __and_<__is_static_castable<_Arg, _Tp>,__not_<__or_<__is_base_to_derived_ref<_Arg, _Tp>,__is_lvalue_to_rvalue_ref<_Arg, _Tp>>>>::type{ };template<typename _Tp, typename _Arg>struct __is_direct_constructible_new: public conditional<is_reference<_Tp>::value,__is_direct_constructible_ref_cast<_Tp, _Arg>,__is_direct_constructible_new_safe<_Tp, _Arg>>::type{ };template<typename _Tp, typename _Arg>struct __is_direct_constructible: public integral_constant<bool, (__is_direct_constructible_new<_Tp, _Arg>::value)>{ };// Since default-construction and binary direct-initialization have// been handled separately, the implementation of the remaining// n-ary construction cases is rather straightforward. We can use// here a functional cast, because array types are excluded anyway// and this form is never interpreted as a C cast.struct __do_is_nary_constructible_impl{template<typename _Tp, typename... _Args, typename= decltype(_Tp(declval<_Args>()...))>static true_type __test(int);template<typename, typename...>static false_type __test(...);};template<typename _Tp, typename... _Args>struct __is_nary_constructible_impl: public __do_is_nary_constructible_impl{typedef decltype(__test<_Tp, _Args...>(0)) type;};template<typename _Tp, typename... _Args>struct __is_nary_constructible: public __is_nary_constructible_impl<_Tp, _Args...>::type{static_assert(sizeof...(_Args) > 1,"Only useful for > 1 arguments");};template<typename _Tp, typename... _Args>struct __is_constructible_impl: public __is_nary_constructible<_Tp, _Args...>{ };template<typename _Tp, typename _Arg>struct __is_constructible_impl<_Tp, _Arg>: public __is_direct_constructible<_Tp, _Arg>{ };template<typename _Tp>struct __is_constructible_impl<_Tp>: public is_default_constructible<_Tp>{ };/// is_constructibletemplate<typename _Tp, typename... _Args>struct is_constructible: public integral_constant<bool, (__is_constructible_impl<_Tp,_Args...>::value)>{ };template<typename _Tp, bool = is_void<_Tp>::value>struct __is_copy_constructible_impl;template<typename _Tp>struct __is_copy_constructible_impl<_Tp, true>: public false_type { };template<typename _Tp>struct __is_copy_constructible_impl<_Tp, false>: public is_constructible<_Tp, const _Tp&>{ };/// is_copy_constructibletemplate<typename _Tp>struct is_copy_constructible: public __is_copy_constructible_impl<_Tp>{ };template<typename _Tp, bool = is_void<_Tp>::value>struct __is_move_constructible_impl;template<typename _Tp>struct __is_move_constructible_impl<_Tp, true>: public false_type { };template<typename _Tp>struct __is_move_constructible_impl<_Tp, false>: public is_constructible<_Tp, _Tp&&>{ };/// is_move_constructibletemplate<typename _Tp>struct is_move_constructible: public __is_move_constructible_impl<_Tp>{ };template<typename _Tp>struct __is_nt_default_constructible_atom: public integral_constant<bool, noexcept(_Tp())>{ };template<typename _Tp, bool = is_array<_Tp>::value>struct __is_nt_default_constructible_impl;template<typename _Tp>struct __is_nt_default_constructible_impl<_Tp, true>: public __and_<__is_array_known_bounds<_Tp>,__is_nt_default_constructible_atom<typenameremove_all_extents<_Tp>::type>>::type{ };template<typename _Tp>struct __is_nt_default_constructible_impl<_Tp, false>: public __is_nt_default_constructible_atom<_Tp>{ };/// is_nothrow_default_constructibletemplate<typename _Tp>struct is_nothrow_default_constructible: public __and_<is_default_constructible<_Tp>,__is_nt_default_constructible_impl<_Tp>>::type{ };template<typename _Tp, typename... _Args>struct __is_nt_constructible_impl: public integral_constant<bool, noexcept(_Tp(declval<_Args>()...))>{ };template<typename _Tp, typename _Arg>struct __is_nt_constructible_impl<_Tp, _Arg>: public integral_constant<bool,noexcept(static_cast<_Tp>(declval<_Arg>()))>{ };template<typename _Tp>struct __is_nt_constructible_impl<_Tp>: public is_nothrow_default_constructible<_Tp>{ };/// is_nothrow_constructibletemplate<typename _Tp, typename... _Args>struct is_nothrow_constructible: public __and_<is_constructible<_Tp, _Args...>,__is_nt_constructible_impl<_Tp, _Args...>>::type{ };template<typename _Tp, bool = is_void<_Tp>::value>struct __is_nothrow_copy_constructible_impl;template<typename _Tp>struct __is_nothrow_copy_constructible_impl<_Tp, true>: public false_type { };template<typename _Tp>struct __is_nothrow_copy_constructible_impl<_Tp, false>: public is_nothrow_constructible<_Tp, const _Tp&>{ };/// is_nothrow_copy_constructibletemplate<typename _Tp>struct is_nothrow_copy_constructible: public __is_nothrow_copy_constructible_impl<_Tp>{ };template<typename _Tp, bool = is_void<_Tp>::value>struct __is_nothrow_move_constructible_impl;template<typename _Tp>struct __is_nothrow_move_constructible_impl<_Tp, true>: public false_type { };template<typename _Tp>struct __is_nothrow_move_constructible_impl<_Tp, false>: public is_nothrow_constructible<_Tp, _Tp&&>{ };/// is_nothrow_move_constructibletemplate<typename _Tp>struct is_nothrow_move_constructible: public __is_nothrow_move_constructible_impl<_Tp>{ };template<typename _Tp, typename _Up>class __is_assignable_helper: public __sfinae_types{template<typename _Tp1, typename _Up1>static decltype(declval<_Tp1>() = declval<_Up1>(), __one())__test(int);template<typename, typename>static __two __test(...);public:static constexpr bool value = sizeof(__test<_Tp, _Up>(0)) == 1;};/// is_assignabletemplate<typename _Tp, typename _Up>struct is_assignable: public integral_constant<bool,__is_assignable_helper<_Tp, _Up>::value>{ };template<typename _Tp, bool = is_void<_Tp>::value>struct __is_copy_assignable_impl;template<typename _Tp>struct __is_copy_assignable_impl<_Tp, true>: public false_type { };template<typename _Tp>struct __is_copy_assignable_impl<_Tp, false>: public is_assignable<_Tp&, const _Tp&>{ };/// is_copy_assignabletemplate<typename _Tp>struct is_copy_assignable: public __is_copy_assignable_impl<_Tp>{ };template<typename _Tp, bool = is_void<_Tp>::value>struct __is_move_assignable_impl;template<typename _Tp>struct __is_move_assignable_impl<_Tp, true>: public false_type { };template<typename _Tp>struct __is_move_assignable_impl<_Tp, false>: public is_assignable<_Tp&, _Tp&&>{ };/// is_move_assignabletemplate<typename _Tp>struct is_move_assignable: public __is_move_assignable_impl<_Tp>{ };template<typename _Tp, typename _Up>struct __is_nt_assignable_impl: public integral_constant<bool, noexcept(declval<_Tp>() = declval<_Up>())>{ };/// is_nothrow_assignabletemplate<typename _Tp, typename _Up>struct is_nothrow_assignable: public __and_<is_assignable<_Tp, _Up>,__is_nt_assignable_impl<_Tp, _Up>>::type{ };template<typename _Tp, bool = is_void<_Tp>::value>struct __is_nt_copy_assignable_impl;template<typename _Tp>struct __is_nt_copy_assignable_impl<_Tp, true>: public false_type { };template<typename _Tp>struct __is_nt_copy_assignable_impl<_Tp, false>: public is_nothrow_assignable<_Tp&, const _Tp&>{ };/// is_nothrow_copy_assignabletemplate<typename _Tp>struct is_nothrow_copy_assignable: public __is_nt_copy_assignable_impl<_Tp>{ };template<typename _Tp, bool = is_void<_Tp>::value>struct __is_nt_move_assignable_impl;template<typename _Tp>struct __is_nt_move_assignable_impl<_Tp, true>: public false_type { };template<typename _Tp>struct __is_nt_move_assignable_impl<_Tp, false>: public is_nothrow_assignable<_Tp&, _Tp&&>{ };/// is_nothrow_move_assignabletemplate<typename _Tp>struct is_nothrow_move_assignable: public __is_nt_move_assignable_impl<_Tp>{ };/// is_trivially_constructible (still unimplemented)/// is_trivially_default_constructible (still unimplemented)/// is_trivially_copy_constructible (still unimplemented)/// is_trivially_move_constructible (still unimplemented)/// is_trivially_assignable (still unimplemented)/// is_trivially_copy_assignable (still unimplemented)/// is_trivially_move_assignable (still unimplemented)/// is_trivially_destructibletemplate<typename _Tp>struct is_trivially_destructible: public __and_<is_destructible<_Tp>, integral_constant<bool,__has_trivial_destructor(_Tp)>>::type{ };/// has_trivial_default_constructor (temporary legacy)template<typename _Tp>struct has_trivial_default_constructor: public integral_constant<bool, __has_trivial_constructor(_Tp)>{ };/// has_trivial_copy_constructor (temporary legacy)template<typename _Tp>struct has_trivial_copy_constructor: public integral_constant<bool, __has_trivial_copy(_Tp)>{ };/// has_trivial_copy_assign (temporary legacy)template<typename _Tp>struct has_trivial_copy_assign: public integral_constant<bool, __has_trivial_assign(_Tp)>{ };/// has_virtual_destructortemplate<typename _Tp>struct has_virtual_destructor: public integral_constant<bool, __has_virtual_destructor(_Tp)>{ };// type property queries./// alignment_oftemplate<typename _Tp>struct alignment_of: public integral_constant<std::size_t, __alignof__(_Tp)> { };/// ranktemplate<typename>struct rank: public integral_constant<std::size_t, 0> { };template<typename _Tp, std::size_t _Size>struct rank<_Tp[_Size]>: public integral_constant<std::size_t, 1 + rank<_Tp>::value> { };template<typename _Tp>struct rank<_Tp[]>: public integral_constant<std::size_t, 1 + rank<_Tp>::value> { };/// extenttemplate<typename, unsigned _Uint>struct extent: public integral_constant<std::size_t, 0> { };template<typename _Tp, unsigned _Uint, std::size_t _Size>struct extent<_Tp[_Size], _Uint>: public integral_constant<std::size_t,_Uint == 0 ? _Size : extent<_Tp,_Uint - 1>::value>{ };template<typename _Tp, unsigned _Uint>struct extent<_Tp[], _Uint>: public integral_constant<std::size_t,_Uint == 0 ? 0 : extent<_Tp,_Uint - 1>::value>{ };// type relations./// is_sametemplate<typename, typename>struct is_same: public false_type { };template<typename _Tp>struct is_same<_Tp, _Tp>: public true_type { };/// is_base_oftemplate<typename _Base, typename _Derived>struct is_base_of: public integral_constant<bool, __is_base_of(_Base, _Derived)>{ };template<typename _From, typename _To,bool = __or_<is_void<_From>, is_function<_To>,is_array<_To>>::value>struct __is_convertible_helper{ static constexpr bool value = is_void<_To>::value; };template<typename _From, typename _To>class __is_convertible_helper<_From, _To, false>: public __sfinae_types{template<typename _To1>static void __test_aux(_To1);template<typename _From1, typename _To1>static decltype(__test_aux<_To1>(std::declval<_From1>()), __one())__test(int);template<typename, typename>static __two __test(...);public:static constexpr bool value = sizeof(__test<_From, _To>(0)) == 1;};/// is_convertibletemplate<typename _From, typename _To>struct is_convertible: public integral_constant<bool,__is_convertible_helper<_From, _To>::value>{ };// const-volatile modifications./// remove_consttemplate<typename _Tp>struct remove_const{ typedef _Tp type; };template<typename _Tp>struct remove_const<_Tp const>{ typedef _Tp type; };/// remove_volatiletemplate<typename _Tp>struct remove_volatile{ typedef _Tp type; };template<typename _Tp>struct remove_volatile<_Tp volatile>{ typedef _Tp type; };/// remove_cvtemplate<typename _Tp>struct remove_cv{typedef typenameremove_const<typename remove_volatile<_Tp>::type>::type type;};/// add_consttemplate<typename _Tp>struct add_const{ typedef _Tp const type; };/// add_volatiletemplate<typename _Tp>struct add_volatile{ typedef _Tp volatile type; };/// add_cvtemplate<typename _Tp>struct add_cv{typedef typenameadd_const<typename add_volatile<_Tp>::type>::type type;};// Reference transformations./// remove_referencetemplate<typename _Tp>struct remove_reference{ typedef _Tp type; };template<typename _Tp>struct remove_reference<_Tp&>{ typedef _Tp type; };template<typename _Tp>struct remove_reference<_Tp&&>{ typedef _Tp type; };template<typename _Tp,bool = __and_<__not_<is_reference<_Tp>>,__not_<is_void<_Tp>>>::value,bool = is_rvalue_reference<_Tp>::value>struct __add_lvalue_reference_helper{ typedef _Tp type; };template<typename _Tp>struct __add_lvalue_reference_helper<_Tp, true, false>{ typedef _Tp& type; };template<typename _Tp>struct __add_lvalue_reference_helper<_Tp, false, true>{ typedef typename remove_reference<_Tp>::type& type; };/// add_lvalue_referencetemplate<typename _Tp>struct add_lvalue_reference: public __add_lvalue_reference_helper<_Tp>{ };template<typename _Tp,bool = __and_<__not_<is_reference<_Tp>>,__not_<is_void<_Tp>>>::value>struct __add_rvalue_reference_helper{ typedef _Tp type; };template<typename _Tp>struct __add_rvalue_reference_helper<_Tp, true>{ typedef _Tp&& type; };/// add_rvalue_referencetemplate<typename _Tp>struct add_rvalue_reference: public __add_rvalue_reference_helper<_Tp>{ };// sign modifications.// Utility for constructing identically cv-qualified types.template<typename _Unqualified, bool _IsConst, bool _IsVol>struct __cv_selector;template<typename _Unqualified>struct __cv_selector<_Unqualified, false, false>{ typedef _Unqualified __type; };template<typename _Unqualified>struct __cv_selector<_Unqualified, false, true>{ typedef volatile _Unqualified __type; };template<typename _Unqualified>struct __cv_selector<_Unqualified, true, false>{ typedef const _Unqualified __type; };template<typename _Unqualified>struct __cv_selector<_Unqualified, true, true>{ typedef const volatile _Unqualified __type; };template<typename _Qualified, typename _Unqualified,bool _IsConst = is_const<_Qualified>::value,bool _IsVol = is_volatile<_Qualified>::value>class __match_cv_qualifiers{typedef __cv_selector<_Unqualified, _IsConst, _IsVol> __match;public:typedef typename __match::__type __type;};// Utility for finding the unsigned versions of signed integral types.template<typename _Tp>struct __make_unsigned{ typedef _Tp __type; };template<>struct __make_unsigned<char>{ typedef unsigned char __type; };template<>struct __make_unsigned<signed char>{ typedef unsigned char __type; };template<>struct __make_unsigned<short>{ typedef unsigned short __type; };template<>struct __make_unsigned<int>{ typedef unsigned int __type; };template<>struct __make_unsigned<long>{ typedef unsigned long __type; };template<>struct __make_unsigned<long long>{ typedef unsigned long long __type; };#if !defined(__STRICT_ANSI__) && defined(_GLIBCXX_USE_INT128)template<>struct __make_unsigned<__int128>{ typedef unsigned __int128 __type; };#endif// Select between integral and enum: not possible to be both.template<typename _Tp,bool _IsInt = is_integral<_Tp>::value,bool _IsEnum = is_enum<_Tp>::value>class __make_unsigned_selector;template<typename _Tp>class __make_unsigned_selector<_Tp, true, false>{typedef __make_unsigned<typename remove_cv<_Tp>::type> __unsignedt;typedef typename __unsignedt::__type __unsigned_type;typedef __match_cv_qualifiers<_Tp, __unsigned_type> __cv_unsigned;public:typedef typename __cv_unsigned::__type __type;};template<typename _Tp>class __make_unsigned_selector<_Tp, false, true>{// With -fshort-enums, an enum may be as small as a char.typedef unsigned char __smallest;static const bool __b0 = sizeof(_Tp) <= sizeof(__smallest);static const bool __b1 = sizeof(_Tp) <= sizeof(unsigned short);static const bool __b2 = sizeof(_Tp) <= sizeof(unsigned int);typedef conditional<__b2, unsigned int, unsigned long> __cond2;typedef typename __cond2::type __cond2_type;typedef conditional<__b1, unsigned short, __cond2_type> __cond1;typedef typename __cond1::type __cond1_type;public:typedef typename conditional<__b0, __smallest, __cond1_type>::type __type;};// Given an integral/enum type, return the corresponding unsigned// integer type.// Primary template./// make_unsignedtemplate<typename _Tp>struct make_unsigned{ typedef typename __make_unsigned_selector<_Tp>::__type type; };// Integral, but don't define.template<>struct make_unsigned<bool>;// Utility for finding the signed versions of unsigned integral types.template<typename _Tp>struct __make_signed{ typedef _Tp __type; };template<>struct __make_signed<char>{ typedef signed char __type; };template<>struct __make_signed<unsigned char>{ typedef signed char __type; };template<>struct __make_signed<unsigned short>{ typedef signed short __type; };template<>struct __make_signed<unsigned int>{ typedef signed int __type; };template<>struct __make_signed<unsigned long>{ typedef signed long __type; };template<>struct __make_signed<unsigned long long>{ typedef signed long long __type; };#if !defined(__STRICT_ANSI__) && defined(_GLIBCXX_USE_INT128)template<>struct __make_signed<unsigned __int128>{ typedef __int128 __type; };#endif// Select between integral and enum: not possible to be both.template<typename _Tp,bool _IsInt = is_integral<_Tp>::value,bool _IsEnum = is_enum<_Tp>::value>class __make_signed_selector;template<typename _Tp>class __make_signed_selector<_Tp, true, false>{typedef __make_signed<typename remove_cv<_Tp>::type> __signedt;typedef typename __signedt::__type __signed_type;typedef __match_cv_qualifiers<_Tp, __signed_type> __cv_signed;public:typedef typename __cv_signed::__type __type;};template<typename _Tp>class __make_signed_selector<_Tp, false, true>{// With -fshort-enums, an enum may be as small as a char.typedef signed char __smallest;static const bool __b0 = sizeof(_Tp) <= sizeof(__smallest);static const bool __b1 = sizeof(_Tp) <= sizeof(signed short);static const bool __b2 = sizeof(_Tp) <= sizeof(signed int);typedef conditional<__b2, signed int, signed long> __cond2;typedef typename __cond2::type __cond2_type;typedef conditional<__b1, signed short, __cond2_type> __cond1;typedef typename __cond1::type __cond1_type;public:typedef typename conditional<__b0, __smallest, __cond1_type>::type __type;};// Given an integral/enum type, return the corresponding signed// integer type.// Primary template./// make_signedtemplate<typename _Tp>struct make_signed{ typedef typename __make_signed_selector<_Tp>::__type type; };// Integral, but don't define.template<>struct make_signed<bool>;// array modifications./// remove_extenttemplate<typename _Tp>struct remove_extent{ typedef _Tp type; };template<typename _Tp, std::size_t _Size>struct remove_extent<_Tp[_Size]>{ typedef _Tp type; };template<typename _Tp>struct remove_extent<_Tp[]>{ typedef _Tp type; };/// remove_all_extentstemplate<typename _Tp>struct remove_all_extents{ typedef _Tp type; };template<typename _Tp, std::size_t _Size>struct remove_all_extents<_Tp[_Size]>{ typedef typename remove_all_extents<_Tp>::type type; };template<typename _Tp>struct remove_all_extents<_Tp[]>{ typedef typename remove_all_extents<_Tp>::type type; };// pointer modifications.template<typename _Tp, typename>struct __remove_pointer_helper{ typedef _Tp type; };template<typename _Tp, typename _Up>struct __remove_pointer_helper<_Tp, _Up*>{ typedef _Up type; };/// remove_pointertemplate<typename _Tp>struct remove_pointer: public __remove_pointer_helper<_Tp, typename remove_cv<_Tp>::type>{ };/// add_pointertemplate<typename _Tp>struct add_pointer{ typedef typename remove_reference<_Tp>::type* type; };template<std::size_t _Len>struct __aligned_storage_msa{union __type{unsigned char __data[_Len];struct __attribute__((__aligned__)) { } __align;};};/*** @brief Alignment type.** The value of _Align is a default-alignment which shall be the* most stringent alignment requirement for any C++ object type* whose size is no greater than _Len (3.9). The member typedef* type shall be a POD type suitable for use as uninitialized* storage for any object whose size is at most _Len and whose* alignment is a divisor of _Align.*/template<std::size_t _Len, std::size_t _Align =__alignof__(typename __aligned_storage_msa<_Len>::__type)>struct aligned_storage{union type{unsigned char __data[_Len];struct __attribute__((__aligned__((_Align)))) { } __align;};};// Decay trait for arrays and functions, used for perfect forwarding// in make_pair, make_tuple, etc.template<typename _Up,bool _IsArray = is_array<_Up>::value,bool _IsFunction = is_function<_Up>::value>struct __decay_selector;// NB: DR 705.template<typename _Up>struct __decay_selector<_Up, false, false>{ typedef typename remove_cv<_Up>::type __type; };template<typename _Up>struct __decay_selector<_Up, true, false>{ typedef typename remove_extent<_Up>::type* __type; };template<typename _Up>struct __decay_selector<_Up, false, true>{ typedef typename add_pointer<_Up>::type __type; };/// decaytemplate<typename _Tp>class decay{typedef typename remove_reference<_Tp>::type __remove_type;public:typedef typename __decay_selector<__remove_type>::__type type;};template<typename _Tp>class reference_wrapper;// Helper which adds a reference to a type when given a reference_wrappertemplate<typename _Tp>struct __strip_reference_wrapper{typedef _Tp __type;};template<typename _Tp>struct __strip_reference_wrapper<reference_wrapper<_Tp> >{typedef _Tp& __type;};template<typename _Tp>struct __strip_reference_wrapper<const reference_wrapper<_Tp> >{typedef _Tp& __type;};template<typename _Tp>struct __decay_and_strip{typedef typename __strip_reference_wrapper<typename decay<_Tp>::type>::__type __type;};// Primary template./// Define a member typedef @c type only if a boolean constant is true.template<bool, typename _Tp = void>struct enable_if{ };// Partial specialization for true.template<typename _Tp>struct enable_if<true, _Tp>{ typedef _Tp type; };// Primary template./// Define a member typedef @c type to one of two argument types.template<bool _Cond, typename _Iftrue, typename _Iffalse>struct conditional{ typedef _Iftrue type; };// Partial specialization for false.template<typename _Iftrue, typename _Iffalse>struct conditional<false, _Iftrue, _Iffalse>{ typedef _Iffalse type; };/// common_typetemplate<typename... _Tp>struct common_type;// sfinae-friendly common_type implementation:struct __do_common_type_impl{template<typename _Tp, typename _Up>static __success_type<typename decay<decltype(true ? std::declval<_Tp>(): std::declval<_Up>())>::type> _S_test(int);template<typename, typename>static __failure_type _S_test(...);};template<typename _Tp, typename _Up>struct __common_type_impl: private __do_common_type_impl{typedef decltype(_S_test<_Tp, _Up>(0)) type;};struct __do_member_type_wrapper{template<typename _Tp>static __success_type<typename _Tp::type> _S_test(int);template<typename>static __failure_type _S_test(...);};template<typename _Tp>struct __member_type_wrapper: private __do_member_type_wrapper{typedef decltype(_S_test<_Tp>(0)) type;};template<typename _CTp, typename... _Args>struct __expanded_common_type_wrapper{typedef common_type<typename _CTp::type, _Args...> type;};template<typename... _Args>struct __expanded_common_type_wrapper<__failure_type, _Args...>{ typedef __failure_type type; };template<typename _Tp>struct common_type<_Tp>{ typedef typename decay<_Tp>::type type; };template<typename _Tp, typename _Up>struct common_type<_Tp, _Up>: public __common_type_impl<_Tp, _Up>::type{ };template<typename _Tp, typename _Up, typename... _Vp>struct common_type<_Tp, _Up, _Vp...>: public __expanded_common_type_wrapper<typename __member_type_wrapper<common_type<_Tp, _Up>>::type, _Vp...>::type{ };/// The underlying type of an enum.template<typename _Tp>struct underlying_type{typedef __underlying_type(_Tp) type;};template<typename _Tp>struct __declval_protector{static const bool __stop = false;static typename add_rvalue_reference<_Tp>::type __delegate();};template<typename _Tp>inline typename add_rvalue_reference<_Tp>::typedeclval() noexcept{static_assert(__declval_protector<_Tp>::__stop,"declval() must not be used!");return __declval_protector<_Tp>::__delegate();}/// result_oftemplate<typename _Signature>class result_of;// sfinae-friendly result_of implementation:// [func.require] paragraph 1 bullet 1:struct __result_of_memfun_ref_impl{template<typename _Fp, typename _Tp1, typename... _Args>static __success_type<decltype((std::declval<_Tp1>().*std::declval<_Fp>())(std::declval<_Args>()...))> _S_test(int);template<typename...>static __failure_type _S_test(...);};template<typename _MemPtr, typename _Arg, typename... _Args>struct __result_of_memfun_ref: private __result_of_memfun_ref_impl{typedef decltype(_S_test<_MemPtr, _Arg, _Args...>(0)) type;};// [func.require] paragraph 1 bullet 2:struct __result_of_memfun_deref_impl{template<typename _Fp, typename _Tp1, typename... _Args>static __success_type<decltype(((*std::declval<_Tp1>()).*std::declval<_Fp>())(std::declval<_Args>()...))> _S_test(int);template<typename...>static __failure_type _S_test(...);};template<typename _MemPtr, typename _Arg, typename... _Args>struct __result_of_memfun_deref: private __result_of_memfun_deref_impl{typedef decltype(_S_test<_MemPtr, _Arg, _Args...>(0)) type;};// [func.require] paragraph 1 bullet 3:struct __result_of_memobj_ref_impl{template<typename _Fp, typename _Tp1>static __success_type<decltype(std::declval<_Tp1>().*std::declval<_Fp>())> _S_test(int);template<typename, typename>static __failure_type _S_test(...);};template<typename _MemPtr, typename _Arg>struct __result_of_memobj_ref: private __result_of_memobj_ref_impl{typedef decltype(_S_test<_MemPtr, _Arg>(0)) type;};// [func.require] paragraph 1 bullet 4:struct __result_of_memobj_deref_impl{template<typename _Fp, typename _Tp1>static __success_type<decltype((*std::declval<_Tp1>()).*std::declval<_Fp>())> _S_test(int);template<typename, typename>static __failure_type _S_test(...);};template<typename _MemPtr, typename _Arg>struct __result_of_memobj_deref: private __result_of_memobj_deref_impl{typedef decltype(_S_test<_MemPtr, _Arg>(0)) type;};template<typename _MemPtr, typename _Arg>struct __result_of_memobj;template<typename _Res, typename _Class, typename _Arg>struct __result_of_memobj<_Res _Class::*, _Arg>{typedef typename remove_cv<typename remove_reference<_Arg>::type>::type _Argval;typedef _Res _Class::* _MemPtr;typedef typename conditional<__or_<is_same<_Argval, _Class>,is_base_of<_Class, _Argval>>::value,__result_of_memobj_ref<_MemPtr, _Arg>,__result_of_memobj_deref<_MemPtr, _Arg>>::type::type type;};template<typename _MemPtr, typename _Arg, typename... _Args>struct __result_of_memfun;template<typename _Res, typename _Class, typename _Arg, typename... _Args>struct __result_of_memfun<_Res _Class::*, _Arg, _Args...>{typedef typename remove_cv<typename remove_reference<_Arg>::type>::type _Argval;typedef _Res _Class::* _MemPtr;typedef typename conditional<__or_<is_same<_Argval, _Class>,is_base_of<_Class, _Argval>>::value,__result_of_memfun_ref<_MemPtr, _Arg, _Args...>,__result_of_memfun_deref<_MemPtr, _Arg, _Args...>>::type::type type;};template<bool, bool, typename _Functor, typename... _ArgTypes>struct __result_of_impl{typedef __failure_type type;};template<typename _MemPtr, typename _Arg>struct __result_of_impl<true, false, _MemPtr, _Arg>: public __result_of_memobj<typename decay<_MemPtr>::type, _Arg>{ };template<typename _MemPtr, typename _Arg, typename... _Args>struct __result_of_impl<false, true, _MemPtr, _Arg, _Args...>: public __result_of_memfun<typename decay<_MemPtr>::type, _Arg, _Args...>{ };// [func.require] paragraph 1 bullet 5:struct __result_of_other_impl{template<typename _Fn, typename... _Args>static __success_type<decltype(std::declval<_Fn>()(std::declval<_Args>()...))> _S_test(int);template<typename...>static __failure_type _S_test(...);};template<typename _Functor, typename... _ArgTypes>struct __result_of_impl<false, false, _Functor, _ArgTypes...>: private __result_of_other_impl{typedef decltype(_S_test<_Functor, _ArgTypes...>(0)) type;};template<typename _Functor, typename... _ArgTypes>struct result_of<_Functor(_ArgTypes...)>: public __result_of_impl<is_member_object_pointer<typename remove_reference<_Functor>::type>::value,is_member_function_pointer<typename remove_reference<_Functor>::type>::value,_Functor, _ArgTypes...>::type{ };/*** Use SFINAE to determine if the type _Tp has a publicly-accessible* member type _NTYPE.*/#define _GLIBCXX_HAS_NESTED_TYPE(_NTYPE) \template<typename _Tp> \class __has_##_NTYPE##_helper \: __sfinae_types \{ \template<typename _Up> \struct _Wrap_type \{ }; \\template<typename _Up> \static __one __test(_Wrap_type<typename _Up::_NTYPE>*); \\template<typename _Up> \static __two __test(...); \\public: \static constexpr bool value = sizeof(__test<_Tp>(0)) == 1; \}; \\template<typename _Tp> \struct __has_##_NTYPE \: integral_constant<bool, __has_##_NTYPE##_helper \<typename remove_cv<_Tp>::type>::value> \{ };/// @} group metaprogramming_GLIBCXX_END_NAMESPACE_VERSION} // namespace#endif // C++11#endif // _GLIBCXX_TYPE_TRAITS