File Coverage

/usr/include/c++/5/functional

Criterion	Covered	Total	%
statement	46	56	82.1
branch	10	28	35.7
condition			n/a
subroutine			n/a
pod			n/a
total	56	84	66.6

line	stmt	bran	code
1			// -- C++ --
2
3			// Copyright (C) 2001-2015 Free Software Foundation, Inc.
4			//
5			// This file is part of the GNU ISO C++ Library. This library is free
6			// software; you can redistribute it and/or modify it under the
7			// terms of the GNU General Public License as published by the
8			// Free Software Foundation; either version 3, or (at your option)
9			// any later version.
10
11			// This library is distributed in the hope that it will be useful,
12			// but WITHOUT ANY WARRANTY; without even the implied warranty of
13			// MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
14			// GNU General Public License for more details.
15
16			// Under Section 7 of GPL version 3, you are granted additional
17			// permissions described in the GCC Runtime Library Exception, version
18			// 3.1, as published by the Free Software Foundation.
19
20			// You should have received a copy of the GNU General Public License and
21			// a copy of the GCC Runtime Library Exception along with this program;
22			// see the files COPYING3 and COPYING.RUNTIME respectively. If not, see
23			// .
24
25			/*
26			* Copyright (c) 1997
27			* Silicon Graphics Computer Systems, Inc.
28			*
29			* Permission to use, copy, modify, distribute and sell this software
30			* and its documentation for any purpose is hereby granted without fee,
31			* provided that the above copyright notice appear in all copies and
32			* that both that copyright notice and this permission notice appear
33			* in supporting documentation. Silicon Graphics makes no
34			* representations about the suitability of this software for any
35			* purpose. It is provided "as is" without express or implied warranty.
36			*
37			*/
38
39			/** @file include/functional
40			* This is a Standard C++ Library header.
41			*/
42
43			#ifndef _GLIBCXX_FUNCTIONAL
44			#define _GLIBCXX_FUNCTIONAL 1
45
46			#pragma GCC system_header
47
48			#include
49			#include
50
51			#if __cplusplus >= 201103L
52
53			#include
54			#include
55			#include
56			#include
57			#include
58			#include
59
60			namespace std _GLIBCXX_VISIBILITY(default)
61			{
62			_GLIBCXX_BEGIN_NAMESPACE_VERSION
63
64			template
65			class _Mem_fn;
66			template
67			_Mem_fn<_Tp _Class::*>
68			mem_fn(_Tp _Class::*) noexcept;
69
70			/// If we have found a result_type, extract it.
71			template>
72			struct _Maybe_get_result_type
73			{ };
74
75			template
76			struct _Maybe_get_result_type<_Functor,
77			__void_t>
78			{ typedef typename _Functor::result_type result_type; };
79
80			/**
81			* Base class for any function object that has a weak result type, as
82			* defined in 20.8.2 [func.require] of C++11.
83			*/
84			template
85			struct _Weak_result_type_impl
86			: _Maybe_get_result_type<_Functor>
87			{ };
88
89			/// Retrieve the result type for a function type.
90			template
91			struct _Weak_result_type_impl<_Res(_ArgTypes...)>
92			{ typedef _Res result_type; };
93
94			template
95			struct _Weak_result_type_impl<_Res(_ArgTypes......)>
96			{ typedef _Res result_type; };
97
98			template
99			struct _Weak_result_type_impl<_Res(_ArgTypes...) const>
100			{ typedef _Res result_type; };
101
102			template
103			struct _Weak_result_type_impl<_Res(_ArgTypes......) const>
104			{ typedef _Res result_type; };
105
106			template
107			struct _Weak_result_type_impl<_Res(_ArgTypes...) volatile>
108			{ typedef _Res result_type; };
109
110			template
111			struct _Weak_result_type_impl<_Res(_ArgTypes......) volatile>
112			{ typedef _Res result_type; };
113
114			template
115			struct _Weak_result_type_impl<_Res(_ArgTypes...) const volatile>
116			{ typedef _Res result_type; };
117
118			template
119			struct _Weak_result_type_impl<_Res(_ArgTypes......) const volatile>
120			{ typedef _Res result_type; };
121
122			/// Retrieve the result type for a function reference.
123			template
124			struct _Weak_result_type_impl<_Res(&)(_ArgTypes...)>
125			{ typedef _Res result_type; };
126
127			template
128			struct _Weak_result_type_impl<_Res(&)(_ArgTypes......)>
129			{ typedef _Res result_type; };
130
131			/// Retrieve the result type for a function pointer.
132			template
133			struct _Weak_result_type_impl<_Res(*)(_ArgTypes...)>
134			{ typedef _Res result_type; };
135
136			template
137			struct _Weak_result_type_impl<_Res(*)(_ArgTypes......)>
138			{ typedef _Res result_type; };
139
140			/// Retrieve result type for a member function pointer.
141			template
142			struct _Weak_result_type_impl<_Res (_Class::*)(_ArgTypes...)>
143			{ typedef _Res result_type; };
144
145			template
146			struct _Weak_result_type_impl<_Res (_Class::*)(_ArgTypes......)>
147			{ typedef _Res result_type; };
148
149			/// Retrieve result type for a const member function pointer.
150			template
151			struct _Weak_result_type_impl<_Res (_Class::*)(_ArgTypes...) const>
152			{ typedef _Res result_type; };
153
154			template
155			struct _Weak_result_type_impl<_Res (_Class::*)(_ArgTypes......) const>
156			{ typedef _Res result_type; };
157
158			/// Retrieve result type for a volatile member function pointer.
159			template
160			struct _Weak_result_type_impl<_Res (_Class::*)(_ArgTypes...) volatile>
161			{ typedef _Res result_type; };
162
163			template
164			struct _Weak_result_type_impl<_Res (_Class::*)(_ArgTypes......) volatile>
165			{ typedef _Res result_type; };
166
167			/// Retrieve result type for a const volatile member function pointer.
168			template
169			struct _Weak_result_type_impl<_Res (_Class::*)(_ArgTypes...)
170			const volatile>
171			{ typedef _Res result_type; };
172
173			template
174			struct _Weak_result_type_impl<_Res (_Class::*)(_ArgTypes......)
175			const volatile>
176			{ typedef _Res result_type; };
177
178			/**
179			* Strip top-level cv-qualifiers from the function object and let
180			* _Weak_result_type_impl perform the real work.
181			*/
182			template
183			struct _Weak_result_type
184			: _Weak_result_type_impl::type>
185			{ };
186
187			/**
188			* Invoke a function object, which may be either a member pointer or a
189			* function object. The first parameter will tell which.
190			*/
191			template
192			inline
193			typename enable_if<
194			(!is_member_pointer<_Functor>::value
195			&& !is_function<_Functor>::value
196			&& !is_function::type>::value),
197			typename result_of<_Functor&(_Args&&...)>::type
198			>::type
199			__invoke(_Functor& __f, _Args&&... __args)
200			{
201			return __f(std::forward<_Args>(__args)...);
202			}
203
204			template
205			inline
206			typename enable_if<
207			(is_member_pointer<_Functor>::value
208			&& !is_function<_Functor>::value
209			&& !is_function::type>::value),
210			typename result_of<_Functor(_Args&&...)>::type
211			>::type
212			__invoke(_Functor& __f, _Args&&... __args)
213			{
214			return std::mem_fn(__f)(std::forward<_Args>(__args)...);
215			}
216
217			// To pick up function references (that will become function pointers)
218			template
219			inline
220			typename enable_if<
221			(is_pointer<_Functor>::value
222			&& is_function::type>::value),
223			typename result_of<_Functor(_Args&&...)>::type
224			>::type
225			__invoke(_Functor __f, _Args&&... __args)
226			{
227			return __f(std::forward<_Args>(__args)...);
228			}
229
230			/**
231			* Knowing which of unary_function and binary_function _Tp derives
232			* from, derives from the same and ensures that reference_wrapper
233			* will have a weak result type. See cases below.
234			*/
235			template
236			struct _Reference_wrapper_base_impl;
237
238			// None of the nested argument types.
239			template
240			struct _Reference_wrapper_base_impl
241			: _Weak_result_type<_Tp>
242			{ };
243
244			// Nested argument_type only.
245			template
246			struct _Reference_wrapper_base_impl
247			: _Weak_result_type<_Tp>
248			{
249			typedef typename _Tp::argument_type argument_type;
250			};
251
252			// Nested first_argument_type and second_argument_type only.
253			template
254			struct _Reference_wrapper_base_impl
255			: _Weak_result_type<_Tp>
256			{
257			typedef typename _Tp::first_argument_type first_argument_type;
258			typedef typename _Tp::second_argument_type second_argument_type;
259			};
260
261			// All the nested argument types.
262			template
263			struct _Reference_wrapper_base_impl
264			: _Weak_result_type<_Tp>
265			{
266			typedef typename _Tp::argument_type argument_type;
267			typedef typename _Tp::first_argument_type first_argument_type;
268			typedef typename _Tp::second_argument_type second_argument_type;
269			};
270
271			_GLIBCXX_HAS_NESTED_TYPE(argument_type)
272			_GLIBCXX_HAS_NESTED_TYPE(first_argument_type)
273			_GLIBCXX_HAS_NESTED_TYPE(second_argument_type)
274
275			/**
276			* Derives from unary_function or binary_function when it
277			* can. Specializations handle all of the easy cases. The primary
278			* template determines what to do with a class type, which may
279			* derive from both unary_function and binary_function.
280			*/
281			template
282			struct _Reference_wrapper_base
283			: _Reference_wrapper_base_impl<
284			__has_argument_type<_Tp>::value,
285			__has_first_argument_type<_Tp>::value
286			&& __has_second_argument_type<_Tp>::value,
287			_Tp>
288			{ };
289
290			// - a function type (unary)
291			template
292			struct _Reference_wrapper_base<_Res(_T1)>
293			: unary_function<_T1, _Res>
294			{ };
295
296			template
297			struct _Reference_wrapper_base<_Res(_T1) const>
298			: unary_function<_T1, _Res>
299			{ };
300
301			template
302			struct _Reference_wrapper_base<_Res(_T1) volatile>
303			: unary_function<_T1, _Res>
304			{ };
305
306			template
307			struct _Reference_wrapper_base<_Res(_T1) const volatile>
308			: unary_function<_T1, _Res>
309			{ };
310
311			// - a function type (binary)
312			template
313			struct _Reference_wrapper_base<_Res(_T1, _T2)>
314			: binary_function<_T1, _T2, _Res>
315			{ };
316
317			template
318			struct _Reference_wrapper_base<_Res(_T1, _T2) const>
319			: binary_function<_T1, _T2, _Res>
320			{ };
321
322			template
323			struct _Reference_wrapper_base<_Res(_T1, _T2) volatile>
324			: binary_function<_T1, _T2, _Res>
325			{ };
326
327			template
328			struct _Reference_wrapper_base<_Res(_T1, _T2) const volatile>
329			: binary_function<_T1, _T2, _Res>
330			{ };
331
332			// - a function pointer type (unary)
333			template
334			struct _Reference_wrapper_base<_Res(*)(_T1)>
335			: unary_function<_T1, _Res>
336			{ };
337
338			// - a function pointer type (binary)
339			template
340			struct _Reference_wrapper_base<_Res(*)(_T1, _T2)>
341			: binary_function<_T1, _T2, _Res>
342			{ };
343
344			// - a pointer to member function type (unary, no qualifiers)
345			template
346			struct _Reference_wrapper_base<_Res (_T1::*)()>
347			: unary_function<_T1*, _Res>
348			{ };
349
350			// - a pointer to member function type (binary, no qualifiers)
351			template
352			struct _Reference_wrapper_base<_Res (_T1::*)(_T2)>
353			: binary_function<_T1*, _T2, _Res>
354			{ };
355
356			// - a pointer to member function type (unary, const)
357			template
358			struct _Reference_wrapper_base<_Res (_T1::*)() const>
359			: unary_function
360			{ };
361
362			// - a pointer to member function type (binary, const)
363			template
364			struct _Reference_wrapper_base<_Res (_T1::*)(_T2) const>
365			: binary_function
366			{ };
367
368			// - a pointer to member function type (unary, volatile)
369			template
370			struct _Reference_wrapper_base<_Res (_T1::*)() volatile>
371			: unary_function
372			{ };
373
374			// - a pointer to member function type (binary, volatile)
375			template
376			struct _Reference_wrapper_base<_Res (_T1::*)(_T2) volatile>
377			: binary_function
378			{ };
379
380			// - a pointer to member function type (unary, const volatile)
381			template
382			struct _Reference_wrapper_base<_Res (_T1::*)() const volatile>
383			: unary_function
384			{ };
385
386			// - a pointer to member function type (binary, const volatile)
387			template
388			struct _Reference_wrapper_base<_Res (_T1::*)(_T2) const volatile>
389			: binary_function
390			{ };
391
392			/**
393			* @brief Primary class template for reference_wrapper.
394			* @ingroup functors
395			* @{
396			*/
397			template
398			class reference_wrapper
399			: public _Reference_wrapper_base::type>
400			{
401			_Tp* _M_data;
402
403			public:
404			typedef _Tp type;
405
406			reference_wrapper(_Tp& __indata) noexcept
407			: _M_data(std::__addressof(__indata))
408			{ }
409
410			reference_wrapper(_Tp&&) = delete;
411
412			reference_wrapper(const reference_wrapper&) = default;
413
414			reference_wrapper&
415			operator=(const reference_wrapper&) = default;
416
417			operator _Tp&() const noexcept
418			{ return this->get(); }
419
420			_Tp&
421			get() const noexcept
422			{ return *_M_data; }
423
424			template
425			typename result_of<_Tp&(_Args&&...)>::type
426			operator()(_Args&&... __args) const
427			{
428			return __invoke(get(), std::forward<_Args>(__args)...);
429			}
430			};
431
432
433			/// Denotes a reference should be taken to a variable.
434			template
435			inline reference_wrapper<_Tp>
436			ref(_Tp& __t) noexcept
437			{ return reference_wrapper<_Tp>(__t); }
438
439			/// Denotes a const reference should be taken to a variable.
440			template
441			inline reference_wrapper
442			cref(const _Tp& __t) noexcept
443			{ return reference_wrapper(__t); }
444
445			template
446			void ref(const _Tp&&) = delete;
447
448			template
449			void cref(const _Tp&&) = delete;
450
451			/// Partial specialization.
452			template
453			inline reference_wrapper<_Tp>
454			ref(reference_wrapper<_Tp> __t) noexcept
455			{ return ref(__t.get()); }
456
457			/// Partial specialization.
458			template
459			inline reference_wrapper
460			cref(reference_wrapper<_Tp> __t) noexcept
461			{ return cref(__t.get()); }
462
463			// @} group functors
464
465			template
466			struct _Pack : integral_constant
467			{ };
468
469			template
470			struct _AllConvertible : false_type
471			{ };
472
473			template
474			struct _AllConvertible<_Pack<_From...>, _Pack<_To...>, true>
475			: __and_...>
476			{ };
477
478			template
479			using _NotSame = __not_::type,
480			typename std::decay<_Tp2>::type>>;
481
482			/**
483			* Derives from @c unary_function or @c binary_function, or perhaps
484			* nothing, depending on the number of arguments provided. The
485			* primary template is the basis case, which derives nothing.
486			*/
487			template
488			struct _Maybe_unary_or_binary_function { };
489
490			/// Derives from @c unary_function, as appropriate.
491			template
492	168		struct _Maybe_unary_or_binary_function<_Res, _T1>
493			: std::unary_function<_T1, _Res> { };
494
495			/// Derives from @c binary_function, as appropriate.
496			template
497			struct _Maybe_unary_or_binary_function<_Res, _T1, _T2>
498			: std::binary_function<_T1, _T2, _Res> { };
499
500			template
501			struct _Mem_fn_traits;
502
503			template
504			struct _Mem_fn_traits_base
505			{
506			using __result_type = _Res;
507			using __class_type = _Class;
508			using __arg_types = _Pack<_ArgTypes...>;
509			using __maybe_type
510			= _Maybe_unary_or_binary_function<_Res, _Class*, _ArgTypes...>;
511			using __arity = integral_constant;
512			};
513
514			#define _GLIBCXX_MEM_FN_TRAITS2(_CV, _REF, _LVAL, _RVAL) \
515			template \
516			struct _Mem_fn_traits<_Res (_Class::*)(_ArgTypes...) _CV _REF> \
517			: _Mem_fn_traits_base<_Res, _CV _Class, _ArgTypes...> \
518			{ \
519			using __pmf_type = _Res (_Class::*)(_ArgTypes...) _CV _REF; \
520			using __lvalue = _LVAL; \
521			using __rvalue = _RVAL; \
522			using __vararg = false_type; \
523			}; \
524			template \
525			struct _Mem_fn_traits<_Res (_Class::*)(_ArgTypes... ...) _CV _REF> \
526			: _Mem_fn_traits_base<_Res, _CV _Class, _ArgTypes...> \
527			{ \
528			using __pmf_type = _Res (_Class::*)(_ArgTypes... ...) _CV _REF; \
529			using __lvalue = _LVAL; \
530			using __rvalue = _RVAL; \
531			using __vararg = true_type; \
532			};
533
534			#define _GLIBCXX_MEM_FN_TRAITS(_REF, _LVAL, _RVAL) \
535			_GLIBCXX_MEM_FN_TRAITS2( , _REF, _LVAL, _RVAL) \
536			_GLIBCXX_MEM_FN_TRAITS2(const , _REF, _LVAL, _RVAL) \
537			_GLIBCXX_MEM_FN_TRAITS2(volatile , _REF, _LVAL, _RVAL) \
538			_GLIBCXX_MEM_FN_TRAITS2(const volatile, _REF, _LVAL, _RVAL)
539
540			_GLIBCXX_MEM_FN_TRAITS( , true_type, true_type)
541			_GLIBCXX_MEM_FN_TRAITS(&, true_type, false_type)
542			_GLIBCXX_MEM_FN_TRAITS(&&, false_type, true_type)
543
544			#undef _GLIBCXX_MEM_FN_TRAITS
545			#undef _GLIBCXX_MEM_FN_TRAITS2
546
547			template
548			bool __is_mem_fn = is_member_function_pointer<_MemFunPtr>::value>
549			class _Mem_fn_base
550			: public _Mem_fn_traits<_MemFunPtr>::__maybe_type
551			{
552			using _Traits = _Mem_fn_traits<_MemFunPtr>;
553
554			using _Class = typename _Traits::__class_type;
555			using _ArgTypes = typename _Traits::__arg_types;
556			using _Pmf = typename _Traits::__pmf_type;
557
558			using _Arity = typename _Traits::__arity;
559			using _Varargs = typename _Traits::__vararg;
560
561			template
562			friend struct _Bind_check_arity;
563
564			// for varargs functions we just check the number of arguments,
565			// otherwise we also check they are convertible.
566			template
567			using _CheckArgs = typename conditional<_Varargs::value,
568			__bool_constant<(_Args::value >= _ArgTypes::value)>,
569			_AllConvertible<_Args, _ArgTypes>
570			>::type;
571
572			public:
573			using result_type = typename _Traits::__result_type;
574
575			explicit _Mem_fn_base(_Pmf __pmf) : _M_pmf(__pmf) { }
576
577			// Handle objects
578			template
579			= _Require
580			_CheckArgs<_Pack<_Args...>>>>
581			result_type
582			operator()(_Class& __object, _Args&&... __args) const
583			{ return (__object.*_M_pmf)(std::forward<_Args>(__args)...); }
584
585			template
586			= _Require
587			_CheckArgs<_Pack<_Args...>>>>
588			result_type
589			operator()(_Class&& __object, _Args&&... __args) const
590			{
591			return (std::move(__object).*_M_pmf)(std::forward<_Args>(__args)...);
592			}
593
594			// Handle pointers
595			template
596			= _Require
597			_CheckArgs<_Pack<_Args...>>>>
598			result_type
599			operator()(_Class* __object, _Args&&... __args) const
600			{ return (__object->*_M_pmf)(std::forward<_Args>(__args)...); }
601
602			// Handle smart pointers, references and pointers to derived
603			template
604			= _Require<_NotSame<_Class, _Tp>, _NotSame<_Class*, _Tp>,
605			_CheckArgs<_Pack<_Args...>>>>
606			result_type
607			operator()(_Tp&& __object, _Args&&... __args) const
608			{
609			return _M_call(std::forward<_Tp>(__object), &__object,
610			std::forward<_Args>(__args)...);
611			}
612
613			// Handle reference wrappers
614			template
615			= _Require, typename _Traits::__lvalue,
616			_CheckArgs<_Pack<_Args...>>>>
617			result_type
618			operator()(reference_wrapper<_Tp> __ref, _Args&&... __args) const
619			{ return operator()(__ref.get(), std::forward<_Args>(__args)...); }
620
621			private:
622			template
623			result_type
624			_M_call(_Tp&& __object, const volatile _Class *,
625			_Args&&... __args) const
626			{
627			return (std::forward<_Tp>(__object).*_M_pmf)
628			(std::forward<_Args>(__args)...);
629			}
630
631			template
632			result_type
633			_M_call(_Tp&& __ptr, const volatile void *, _Args&&... __args) const
634			{ return ((__ptr)._M_pmf)(std::forward<_Args>(__args)...); }
635
636			_Pmf _M_pmf;
637			};
638
639			// Partial specialization for member object pointers.
640			template
641			class _Mem_fn_base<_Res _Class::*, false>
642			{
643			using __pm_type = _Res _Class::*;
644
645			// This bit of genius is due to Peter Dimov, improved slightly by
646			// Douglas Gregor.
647			// Made less elegant to support perfect forwarding and noexcept.
648			template
649			auto
650			_M_call(_Tp&& __object, const _Class *) const noexcept
651			-> decltype(std::forward<_Tp>(__object).*std::declval<__pm_type&>())
652			{ return std::forward<_Tp>(__object).*_M_pm; }
653
654			template
655			auto
656			_M_call(_Tp&& __object, _Up * const *) const noexcept
657			-> decltype((std::forward<_Tp>(__object)).std::declval<__pm_type&>())
658			{ return (std::forward<_Tp>(__object))._M_pm; }
659
660			template
661			auto
662			_M_call(_Tp&& __ptr, const volatile void*) const
663			noexcept(noexcept((__ptr).std::declval<__pm_type&>()))
664			-> decltype((__ptr).std::declval<__pm_type&>())
665			{ return (__ptr)._M_pm; }
666
667			using _Arity = integral_constant;
668			using _Varargs = false_type;
669
670			template
671			friend struct _Bind_check_arity;
672
673			public:
674			explicit
675			_Mem_fn_base(_Res _Class::*__pm) noexcept : _M_pm(__pm) { }
676
677			// Handle objects
678			_Res&
679			operator()(_Class& __object) const noexcept
680			{ return __object.*_M_pm; }
681
682			const _Res&
683			operator()(const _Class& __object) const noexcept
684			{ return __object.*_M_pm; }
685
686			_Res&&
687			operator()(_Class&& __object) const noexcept
688			{ return std::forward<_Class>(__object).*_M_pm; }
689
690			const _Res&&
691			operator()(const _Class&& __object) const noexcept
692			{ return std::forward(__object).*_M_pm; }
693
694			// Handle pointers
695			_Res&
696			operator()(_Class* __object) const noexcept
697			{ return __object->*_M_pm; }
698
699			const _Res&
700			operator()(const _Class* __object) const noexcept
701			{ return __object->*_M_pm; }
702
703			// Handle smart pointers and derived
704			template>>
705			auto
706			operator()(_Tp&& __unknown) const
707			noexcept(noexcept(std::declval<_Mem_fn_base*>()->_M_call
708			(std::forward<_Tp>(__unknown), &__unknown)))
709			-> decltype(this->_M_call(std::forward<_Tp>(__unknown), &__unknown))
710			{ return _M_call(std::forward<_Tp>(__unknown), &__unknown); }
711
712			template>>
713			auto
714			operator()(reference_wrapper<_Tp> __ref) const
715			noexcept(noexcept(std::declval<_Mem_fn_base&>()(__ref.get())))
716			-> decltype((*this)(__ref.get()))
717			{ return (*this)(__ref.get()); }
718
719			private:
720			_Res _Class::*_M_pm;
721			};
722
723			template
724			struct _Mem_fn<_Res _Class::*>
725			: _Mem_fn_base<_Res _Class::*>
726			{
727			using _Mem_fn_base<_Res _Class::*>::_Mem_fn_base;
728			};
729
730			// _GLIBCXX_RESOLVE_LIB_DEFECTS
731			// 2048. Unnecessary mem_fn overloads
732			/**
733			* @brief Returns a function object that forwards to the member
734			* pointer @a pm.
735			* @ingroup functors
736			*/
737			template
738			inline _Mem_fn<_Tp _Class::*>
739			mem_fn(_Tp _Class::* __pm) noexcept
740			{
741			return _Mem_fn<_Tp _Class::*>(__pm);
742			}
743
744			/**
745			* @brief Determines if the given type _Tp is a function object
746			* should be treated as a subexpression when evaluating calls to
747			* function objects returned by bind(). [TR1 3.6.1]
748			* @ingroup binders
749			*/
750			template
751			struct is_bind_expression
752			: public false_type { };
753
754			/**
755			* @brief Determines if the given type _Tp is a placeholder in a
756			* bind() expression and, if so, which placeholder it is. [TR1 3.6.2]
757			* @ingroup binders
758			*/
759			template
760			struct is_placeholder
761			: public integral_constant
762			{ };
763
764			/** @brief The type of placeholder objects defined by libstdc++.
765			* @ingroup binders
766			*/
767			template struct _Placeholder { };
768
769			_GLIBCXX_END_NAMESPACE_VERSION
770
771			/** @namespace std::placeholders
772			* @brief ISO C++11 entities sub-namespace for functional.
773			* @ingroup binders
774			*/
775			namespace placeholders
776			{
777			_GLIBCXX_BEGIN_NAMESPACE_VERSION
778			/* Define a large number of placeholders. There is no way to
779			* simplify this with variadic templates, because we're introducing
780			* unique names for each.
781			*/
782			extern const _Placeholder<1> _1;
783			extern const _Placeholder<2> _2;
784			extern const _Placeholder<3> _3;
785			extern const _Placeholder<4> _4;
786			extern const _Placeholder<5> _5;
787			extern const _Placeholder<6> _6;
788			extern const _Placeholder<7> _7;
789			extern const _Placeholder<8> _8;
790			extern const _Placeholder<9> _9;
791			extern const _Placeholder<10> _10;
792			extern const _Placeholder<11> _11;
793			extern const _Placeholder<12> _12;
794			extern const _Placeholder<13> _13;
795			extern const _Placeholder<14> _14;
796			extern const _Placeholder<15> _15;
797			extern const _Placeholder<16> _16;
798			extern const _Placeholder<17> _17;
799			extern const _Placeholder<18> _18;
800			extern const _Placeholder<19> _19;
801			extern const _Placeholder<20> _20;
802			extern const _Placeholder<21> _21;
803			extern const _Placeholder<22> _22;
804			extern const _Placeholder<23> _23;
805			extern const _Placeholder<24> _24;
806			extern const _Placeholder<25> _25;
807			extern const _Placeholder<26> _26;
808			extern const _Placeholder<27> _27;
809			extern const _Placeholder<28> _28;
810			extern const _Placeholder<29> _29;
811			_GLIBCXX_END_NAMESPACE_VERSION
812			}
813
814			_GLIBCXX_BEGIN_NAMESPACE_VERSION
815
816			/**
817			* Partial specialization of is_placeholder that provides the placeholder
818			* number for the placeholder objects defined by libstdc++.
819			* @ingroup binders
820			*/
821			template
822			struct is_placeholder<_Placeholder<_Num> >
823			: public integral_constant
824			{ };
825
826			template
827			struct is_placeholder >
828			: public integral_constant
829			{ };
830
831			/**
832			* Used by _Safe_tuple_element to indicate that there is no tuple
833			* element at this position.
834			*/
835			struct _No_tuple_element;
836
837			/**
838			* Implementation helper for _Safe_tuple_element. This primary
839			* template handles the case where it is safe to use @c
840			* tuple_element.
841			*/
842			template
843			struct _Safe_tuple_element_impl
844			: tuple_element<__i, _Tuple> { };
845
846			/**
847			* Implementation helper for _Safe_tuple_element. This partial
848			* specialization handles the case where it is not safe to use @c
849			* tuple_element. We just return @c _No_tuple_element.
850			*/
851			template
852			struct _Safe_tuple_element_impl<__i, _Tuple, false>
853			{
854			typedef _No_tuple_element type;
855			};
856
857			/**
858			* Like tuple_element, but returns @c _No_tuple_element when
859			* tuple_element would return an error.
860			*/
861			template
862			struct _Safe_tuple_element
863			: _Safe_tuple_element_impl<__i, _Tuple,
864			(__i < tuple_size<_Tuple>::value)>
865			{ };
866
867			/**
868			* Maps an argument to bind() into an actual argument to the bound
869			* function object [TR1 3.6.3/5]. Only the first parameter should
870			* be specified: the rest are used to determine among the various
871			* implementations. Note that, although this class is a function
872			* object, it isn't entirely normal because it takes only two
873			* parameters regardless of the number of parameters passed to the
874			* bind expression. The first parameter is the bound argument and
875			* the second parameter is a tuple containing references to the
876			* rest of the arguments.
877			*/
878			template
879			bool _IsBindExp = is_bind_expression<_Arg>::value,
880			bool _IsPlaceholder = (is_placeholder<_Arg>::value > 0)>
881			class _Mu;
882
883			/**
884			* If the argument is reference_wrapper<_Tp>, returns the
885			* underlying reference. [TR1 3.6.3/5 bullet 1]
886			*/
887			template
888			class _Mu, false, false>
889			{
890			public:
891			typedef _Tp& result_type;
892
893			/* Note: This won't actually work for const volatile
894			* reference_wrappers, because reference_wrapper::get() is const
895			* but not volatile-qualified. This might be a defect in the TR.
896			*/
897			template
898			result_type
899			operator()(_CVRef& __arg, _Tuple&) const volatile
900			{ return __arg.get(); }
901			};
902
903			/**
904			* If the argument is a bind expression, we invoke the underlying
905			* function object with the same cv-qualifiers as we are given and
906			* pass along all of our arguments (unwrapped). [TR1 3.6.3/5 bullet 2]
907			*/
908			template
909			class _Mu<_Arg, true, false>
910			{
911			public:
912			template
913			auto
914			operator()(_CVArg& __arg,
915			tuple<_Args...>& __tuple) const volatile
916			-> decltype(__arg(declval<_Args>()...))
917			{
918			// Construct an index tuple and forward to __call
919			typedef typename _Build_index_tuple::__type
920			_Indexes;
921			return this->__call(__arg, __tuple, _Indexes());
922			}
923
924			private:
925			// Invokes the underlying function object __arg by unpacking all
926			// of the arguments in the tuple.
927			template
928			auto
929			__call(_CVArg& __arg, tuple<_Args...>& __tuple,
930			const _Index_tuple<_Indexes...>&) const volatile
931			-> decltype(__arg(declval<_Args>()...))
932			{
933			return __arg(std::forward<_Args>(std::get<_Indexes>(__tuple))...);
934			}
935			};
936
937			/**
938			* If the argument is a placeholder for the Nth argument, returns
939			* a reference to the Nth argument to the bind function object.
940			* [TR1 3.6.3/5 bullet 3]
941			*/
942			template
943			class _Mu<_Arg, false, true>
944			{
945			public:
946			template class result;
947
948			template
949			class result<_CVMu(_CVArg, _Tuple)>
950			{
951			// Add a reference, if it hasn't already been done for us.
952			// This allows us to be a little bit sloppy in constructing
953			// the tuple that we pass to result_of<...>.
954			typedef typename _Safe_tuple_element<(is_placeholder<_Arg>::value
955			- 1), _Tuple>::type
956			__base_type;
957
958			public:
959			typedef typename add_rvalue_reference<__base_type>::type type;
960			};
961
962			template
963			typename result<_Mu(_Arg, _Tuple)>::type
964			operator()(const volatile _Arg&, _Tuple& __tuple) const volatile
965			{
966			return std::forward::type>(
967			::std::get<(is_placeholder<_Arg>::value - 1)>(__tuple));
968			}
969			};
970
971			/**
972			* If the argument is just a value, returns a reference to that
973			* value. The cv-qualifiers on the reference are the same as the
974			* cv-qualifiers on the _Mu object. [TR1 3.6.3/5 bullet 4]
975			*/
976			template
977			class _Mu<_Arg, false, false>
978			{
979			public:
980			template struct result;
981
982			template
983			struct result<_CVMu(_CVArg, _Tuple)>
984			{
985			typedef typename add_lvalue_reference<_CVArg>::type type;
986			};
987
988			// Pick up the cv-qualifiers of the argument
989			template
990			_CVArg&&
991			operator()(_CVArg&& __arg, _Tuple&) const volatile
992			{ return std::forward<_CVArg>(__arg); }
993			};
994
995			/**
996			* Maps member pointers into instances of _Mem_fn but leaves all
997			* other function objects untouched. Used by std::bind(). The
998			* primary template handles the non-member-pointer case.
999			*/
1000			template
1001			struct _Maybe_wrap_member_pointer
1002			{
1003			typedef _Tp type;
1004
1005			static const _Tp&
1006			__do_wrap(const _Tp& __x)
1007			{ return __x; }
1008
1009			static _Tp&&
1010			__do_wrap(_Tp&& __x)
1011			{ return static_cast<_Tp&&>(__x); }
1012			};
1013
1014			/**
1015			* Maps member pointers into instances of _Mem_fn but leaves all
1016			* other function objects untouched. Used by std::bind(). This
1017			* partial specialization handles the member pointer case.
1018			*/
1019			template
1020			struct _Maybe_wrap_member_pointer<_Tp _Class::*>
1021			{
1022			typedef _Mem_fn<_Tp _Class::*> type;
1023
1024			static type
1025			__do_wrap(_Tp _Class::* __pm)
1026			{ return type(__pm); }
1027			};
1028
1029			// Specialization needed to prevent "forming reference to void" errors when
1030			// bind() is called, because argument deduction instantiates
1031			// _Maybe_wrap_member_pointer outside the immediate context where
1032			// SFINAE applies.
1033			template<>
1034			struct _Maybe_wrap_member_pointer
1035			{
1036			typedef void type;
1037			};
1038
1039			// std::get for volatile-qualified tuples
1040			template
1041			inline auto
1042			__volget(volatile tuple<_Tp...>& __tuple)
1043			-> __tuple_element_t<_Ind, tuple<_Tp...>> volatile&
1044			{ return std::get<_Ind>(const_cast&>(__tuple)); }
1045
1046			// std::get for const-volatile-qualified tuples
1047			template
1048			inline auto
1049			__volget(const volatile tuple<_Tp...>& __tuple)
1050			-> __tuple_element_t<_Ind, tuple<_Tp...>> const volatile&
1051			{ return std::get<_Ind>(const_cast&>(__tuple)); }
1052
1053			/// Type of the function object returned from bind().
1054			template
1055			struct _Bind;
1056
1057			template
1058			class _Bind<_Functor(_Bound_args...)>
1059			: public _Weak_result_type<_Functor>
1060			{
1061			typedef _Bind __self_type;
1062			typedef typename _Build_index_tuple::__type
1063			_Bound_indexes;
1064
1065			_Functor _M_f;
1066			tuple<_Bound_args...> _M_bound_args;
1067
1068			// Call unqualified
1069			template
1070			_Result
1071			__call(tuple<_Args...>&& __args, _Index_tuple<_Indexes...>)
1072			{
1073			return _M_f(_Mu<_Bound_args>()
1074			(std::get<_Indexes>(_M_bound_args), __args)...);
1075			}
1076
1077			// Call as const
1078			template
1079			_Result
1080			__call_c(tuple<_Args...>&& __args, _Index_tuple<_Indexes...>) const
1081			{
1082			return _M_f(_Mu<_Bound_args>()
1083			(std::get<_Indexes>(_M_bound_args), __args)...);
1084			}
1085
1086			// Call as volatile
1087			template
1088			_Result
1089			__call_v(tuple<_Args...>&& __args,
1090			_Index_tuple<_Indexes...>) volatile
1091			{
1092			return _M_f(_Mu<_Bound_args>()
1093			(__volget<_Indexes>(_M_bound_args), __args)...);
1094			}
1095
1096			// Call as const volatile
1097			template
1098			_Result
1099			__call_c_v(tuple<_Args...>&& __args,
1100			_Index_tuple<_Indexes...>) const volatile
1101			{
1102			return _M_f(_Mu<_Bound_args>()
1103			(__volget<_Indexes>(_M_bound_args), __args)...);
1104			}
1105
1106			public:
1107			template
1108			explicit _Bind(const _Functor& __f, _Args&&... __args)
1109			: _M_f(__f), _M_bound_args(std::forward<_Args>(__args)...)
1110			{ }
1111
1112			template
1113			explicit _Bind(_Functor&& __f, _Args&&... __args)
1114			: _M_f(std::move(__f)), _M_bound_args(std::forward<_Args>(__args)...)
1115			{ }
1116
1117			_Bind(const _Bind&) = default;
1118
1119			_Bind(_Bind&& __b)
1120			: _M_f(std::move(__b._M_f)), _M_bound_args(std::move(__b._M_bound_args))
1121			{ }
1122
1123			// Call unqualified
1124			template
1125			= decltype( std::declval<_Functor&>()(
1126			_Mu<_Bound_args>()( std::declval<_Bound_args&>(),
1127			std::declval&>() )... ) )>
1128			_Result
1129			operator()(_Args&&... __args)
1130			{
1131			return this->__call<_Result>(
1132			std::forward_as_tuple(std::forward<_Args>(__args)...),
1133			_Bound_indexes());
1134			}
1135
1136			// Call as const
1137			template
1138			= decltype( std::declval= 0),
1139			typename add_const<_Functor>::type&>::type>()(
1140			_Mu<_Bound_args>()( std::declval(),
1141			std::declval&>() )... ) )>
1142			_Result
1143			operator()(_Args&&... __args) const
1144			{
1145			return this->__call_c<_Result>(
1146			std::forward_as_tuple(std::forward<_Args>(__args)...),
1147			_Bound_indexes());
1148			}
1149
1150			// Call as volatile
1151			template
1152			= decltype( std::declval= 0),
1153			typename add_volatile<_Functor>::type&>::type>()(
1154			_Mu<_Bound_args>()( std::declval(),
1155			std::declval&>() )... ) )>
1156			_Result
1157			operator()(_Args&&... __args) volatile
1158			{
1159			return this->__call_v<_Result>(
1160			std::forward_as_tuple(std::forward<_Args>(__args)...),
1161			_Bound_indexes());
1162			}
1163
1164			// Call as const volatile
1165			template
1166			= decltype( std::declval= 0),
1167			typename add_cv<_Functor>::type&>::type>()(
1168			_Mu<_Bound_args>()( std::declval(),
1169			std::declval&>() )... ) )>
1170			_Result
1171			operator()(_Args&&... __args) const volatile
1172			{
1173			return this->__call_c_v<_Result>(
1174			std::forward_as_tuple(std::forward<_Args>(__args)...),
1175			_Bound_indexes());
1176			}
1177			};
1178
1179			/// Type of the function object returned from bind().
1180			template
1181			struct _Bind_result;
1182
1183			template
1184			class _Bind_result<_Result, _Functor(_Bound_args...)>
1185			{
1186			typedef _Bind_result __self_type;
1187			typedef typename _Build_index_tuple::__type
1188			_Bound_indexes;
1189
1190			_Functor _M_f;
1191			tuple<_Bound_args...> _M_bound_args;
1192
1193			// sfinae types
1194			template
1195			struct __enable_if_void : enable_if::value, int> { };
1196			template
1197			struct __disable_if_void : enable_if::value, int> { };
1198
1199			// Call unqualified
1200			template
1201			_Result
1202			__call(tuple<_Args...>&& __args, _Index_tuple<_Indexes...>,
1203			typename __disable_if_void<_Res>::type = 0)
1204			{
1205			return _M_f(_Mu<_Bound_args>()
1206			(std::get<_Indexes>(_M_bound_args), __args)...);
1207			}
1208
1209			// Call unqualified, return void
1210			template
1211			void
1212			__call(tuple<_Args...>&& __args, _Index_tuple<_Indexes...>,
1213			typename __enable_if_void<_Res>::type = 0)
1214			{
1215			_M_f(_Mu<_Bound_args>()
1216			(std::get<_Indexes>(_M_bound_args), __args)...);
1217			}
1218
1219			// Call as const
1220			template
1221			_Result
1222			__call(tuple<_Args...>&& __args, _Index_tuple<_Indexes...>,
1223			typename __disable_if_void<_Res>::type = 0) const
1224			{
1225			return _M_f(_Mu<_Bound_args>()
1226			(std::get<_Indexes>(_M_bound_args), __args)...);
1227			}
1228
1229			// Call as const, return void
1230			template
1231			void
1232			__call(tuple<_Args...>&& __args, _Index_tuple<_Indexes...>,
1233			typename __enable_if_void<_Res>::type = 0) const
1234			{
1235			_M_f(_Mu<_Bound_args>()
1236			(std::get<_Indexes>(_M_bound_args), __args)...);
1237			}
1238
1239			// Call as volatile
1240			template
1241			_Result
1242			__call(tuple<_Args...>&& __args, _Index_tuple<_Indexes...>,
1243			typename __disable_if_void<_Res>::type = 0) volatile
1244			{
1245			return _M_f(_Mu<_Bound_args>()
1246			(__volget<_Indexes>(_M_bound_args), __args)...);
1247			}
1248
1249			// Call as volatile, return void
1250			template
1251			void
1252			__call(tuple<_Args...>&& __args, _Index_tuple<_Indexes...>,
1253			typename __enable_if_void<_Res>::type = 0) volatile
1254			{
1255			_M_f(_Mu<_Bound_args>()
1256			(__volget<_Indexes>(_M_bound_args), __args)...);
1257			}
1258
1259			// Call as const volatile
1260			template
1261			_Result
1262			__call(tuple<_Args...>&& __args, _Index_tuple<_Indexes...>,
1263			typename __disable_if_void<_Res>::type = 0) const volatile
1264			{
1265			return _M_f(_Mu<_Bound_args>()
1266			(__volget<_Indexes>(_M_bound_args), __args)...);
1267			}
1268
1269			// Call as const volatile, return void
1270			template
1271			void
1272			__call(tuple<_Args...>&& __args,
1273			_Index_tuple<_Indexes...>,
1274			typename __enable_if_void<_Res>::type = 0) const volatile
1275			{
1276			_M_f(_Mu<_Bound_args>()
1277			(__volget<_Indexes>(_M_bound_args), __args)...);
1278			}
1279
1280			public:
1281			typedef _Result result_type;
1282
1283			template
1284			explicit _Bind_result(const _Functor& __f, _Args&&... __args)
1285			: _M_f(__f), _M_bound_args(std::forward<_Args>(__args)...)
1286			{ }
1287
1288			template
1289			explicit _Bind_result(_Functor&& __f, _Args&&... __args)
1290			: _M_f(std::move(__f)), _M_bound_args(std::forward<_Args>(__args)...)
1291			{ }
1292
1293			_Bind_result(const _Bind_result&) = default;
1294
1295			_Bind_result(_Bind_result&& __b)
1296			: _M_f(std::move(__b._M_f)), _M_bound_args(std::move(__b._M_bound_args))
1297			{ }
1298
1299			// Call unqualified
1300			template
1301			result_type
1302			operator()(_Args&&... __args)
1303			{
1304			return this->__call<_Result>(
1305			std::forward_as_tuple(std::forward<_Args>(__args)...),
1306			_Bound_indexes());
1307			}
1308
1309			// Call as const
1310			template
1311			result_type
1312			operator()(_Args&&... __args) const
1313			{
1314			return this->__call<_Result>(
1315			std::forward_as_tuple(std::forward<_Args>(__args)...),
1316			_Bound_indexes());
1317			}
1318
1319			// Call as volatile
1320			template
1321			result_type
1322			operator()(_Args&&... __args) volatile
1323			{
1324			return this->__call<_Result>(
1325			std::forward_as_tuple(std::forward<_Args>(__args)...),
1326			_Bound_indexes());
1327			}
1328
1329			// Call as const volatile
1330			template
1331			result_type
1332			operator()(_Args&&... __args) const volatile
1333			{
1334			return this->__call<_Result>(
1335			std::forward_as_tuple(std::forward<_Args>(__args)...),
1336			_Bound_indexes());
1337			}
1338			};
1339
1340			/**
1341			* @brief Class template _Bind is always a bind expression.
1342			* @ingroup binders
1343			*/
1344			template
1345			struct is_bind_expression<_Bind<_Signature> >
1346			: public true_type { };
1347
1348			/**
1349			* @brief Class template _Bind is always a bind expression.
1350			* @ingroup binders
1351			*/
1352			template
1353			struct is_bind_expression >
1354			: public true_type { };
1355
1356			/**
1357			* @brief Class template _Bind is always a bind expression.
1358			* @ingroup binders
1359			*/
1360			template
1361			struct is_bind_expression >
1362			: public true_type { };
1363
1364			/**
1365			* @brief Class template _Bind is always a bind expression.
1366			* @ingroup binders
1367			*/
1368			template
1369			struct is_bind_expression>
1370			: public true_type { };
1371
1372			/**
1373			* @brief Class template _Bind_result is always a bind expression.
1374			* @ingroup binders
1375			*/
1376			template
1377			struct is_bind_expression<_Bind_result<_Result, _Signature>>
1378			: public true_type { };
1379
1380			/**
1381			* @brief Class template _Bind_result is always a bind expression.
1382			* @ingroup binders
1383			*/
1384			template
1385			struct is_bind_expression>
1386			: public true_type { };
1387
1388			/**
1389			* @brief Class template _Bind_result is always a bind expression.
1390			* @ingroup binders
1391			*/
1392			template
1393			struct is_bind_expression>
1394			: public true_type { };
1395
1396			/**
1397			* @brief Class template _Bind_result is always a bind expression.
1398			* @ingroup binders
1399			*/
1400			template
1401			struct is_bind_expression>
1402			: public true_type { };
1403
1404			template
1405			struct _Bind_check_arity { };
1406
1407			template
1408			struct _Bind_check_arity<_Ret (*)(_Args...), _BoundArgs...>
1409			{
1410			static_assert(sizeof...(_BoundArgs) == sizeof...(_Args),
1411			"Wrong number of arguments for function");
1412			};
1413
1414			template
1415			struct _Bind_check_arity<_Ret (*)(_Args......), _BoundArgs...>
1416			{
1417			static_assert(sizeof...(_BoundArgs) >= sizeof...(_Args),
1418			"Wrong number of arguments for function");
1419			};
1420
1421			template
1422			struct _Bind_check_arity<_Tp _Class::*, _BoundArgs...>
1423			{
1424			using _Arity = typename _Mem_fn<_Tp _Class::*>::_Arity;
1425			using _Varargs = typename _Mem_fn<_Tp _Class::*>::_Varargs;
1426			static_assert(_Varargs::value
1427			? sizeof...(_BoundArgs) >= _Arity::value + 1
1428			: sizeof...(_BoundArgs) == _Arity::value + 1,
1429			"Wrong number of arguments for pointer-to-member");
1430			};
1431
1432			// Trait type used to remove std::bind() from overload set via SFINAE
1433			// when first argument has integer type, so that std::bind() will
1434			// not be a better match than ::bind() from the BSD Sockets API.
1435			template::type>
1436			using __is_socketlike = __or_, is_enum<_Tp2>>;
1437
1438			template
1439			struct _Bind_helper
1440			: _Bind_check_arity::type, _BoundArgs...>
1441			{
1442			typedef _Maybe_wrap_member_pointer::type>
1443			__maybe_type;
1444			typedef typename __maybe_type::type __func_type;
1445			typedef _Bind<__func_type(typename decay<_BoundArgs>::type...)> type;
1446			};
1447
1448			// Partial specialization for is_socketlike == true, does not define
1449			// nested type so std::bind() will not participate in overload resolution
1450			// when the first argument might be a socket file descriptor.
1451			template
1452			struct _Bind_helper
1453			{ };
1454
1455			/**
1456			* @brief Function template for std::bind.
1457			* @ingroup binders
1458			*/
1459			template
1460			inline typename
1461			_Bind_helper<__is_socketlike<_Func>::value, _Func, _BoundArgs...>::type
1462			bind(_Func&& __f, _BoundArgs&&... __args)
1463			{
1464			typedef _Bind_helper __helper_type;
1465			typedef typename __helper_type::__maybe_type __maybe_type;
1466			typedef typename __helper_type::type __result_type;
1467			return __result_type(__maybe_type::__do_wrap(std::forward<_Func>(__f)),
1468			std::forward<_BoundArgs>(__args)...);
1469			}
1470
1471			template
1472			struct _Bindres_helper
1473			: _Bind_check_arity::type, _BoundArgs...>
1474			{
1475			typedef _Maybe_wrap_member_pointer::type>
1476			__maybe_type;
1477			typedef typename __maybe_type::type __functor_type;
1478			typedef _Bind_result<_Result,
1479			__functor_type(typename decay<_BoundArgs>::type...)>
1480			type;
1481			};
1482
1483			/**
1484			* @brief Function template for std::bind.
1485			* @ingroup binders
1486			*/
1487			template
1488			inline
1489			typename _Bindres_helper<_Result, _Func, _BoundArgs...>::type
1490			bind(_Func&& __f, _BoundArgs&&... __args)
1491			{
1492			typedef _Bindres_helper<_Result, _Func, _BoundArgs...> __helper_type;
1493			typedef typename __helper_type::__maybe_type __maybe_type;
1494			typedef typename __helper_type::type __result_type;
1495			return __result_type(__maybe_type::__do_wrap(std::forward<_Func>(__f)),
1496			std::forward<_BoundArgs>(__args)...);
1497			}
1498
1499			template
1500			struct _Bind_simple;
1501
1502			template
1503			struct _Bind_simple<_Callable(_Args...)>
1504			{
1505			typedef typename result_of<_Callable(_Args...)>::type result_type;
1506
1507			template
1508			explicit
1509			_Bind_simple(_Tp&& __f, _Up&&... __args)
1510			: _M_bound(std::forward<_Tp>(__f), std::forward<_Up>(__args)...)
1511			{ }
1512
1513			_Bind_simple(const _Bind_simple&) = default;
1514			_Bind_simple(_Bind_simple&&) = default;
1515
1516			result_type
1517			operator()()
1518			{
1519			typedef typename _Build_index_tuple::__type _Indices;
1520			return _M_invoke(_Indices());
1521			}
1522
1523			private:
1524			template
1525			typename result_of<_Callable(_Args...)>::type
1526			_M_invoke(_Index_tuple<_Indices...>)
1527			{
1528			// std::bind always forwards bound arguments as lvalues,
1529			// but this type can call functions which only accept rvalues.
1530			return std::forward<_Callable>(std::get<0>(_M_bound))(
1531			std::forward<_Args>(std::get<_Indices+1>(_M_bound))...);
1532			}
1533
1534			std::tuple<_Callable, _Args...> _M_bound;
1535			};
1536
1537			template
1538			struct _Bind_simple_helper
1539			: _Bind_check_arity::type, _BoundArgs...>
1540			{
1541			typedef _Maybe_wrap_member_pointer::type>
1542			__maybe_type;
1543			typedef typename __maybe_type::type __func_type;
1544			typedef _Bind_simple<__func_type(typename decay<_BoundArgs>::type...)>
1545			__type;
1546			};
1547
1548			// Simplified version of std::bind for internal use, without support for
1549			// unbound arguments, placeholders or nested bind expressions.
1550			template
1551			typename _Bind_simple_helper<_Callable, _Args...>::__type
1552			__bind_simple(_Callable&& __callable, _Args&&... __args)
1553			{
1554			typedef _Bind_simple_helper<_Callable, _Args...> __helper_type;
1555			typedef typename __helper_type::__maybe_type __maybe_type;
1556			typedef typename __helper_type::__type __result_type;
1557			return __result_type(
1558			__maybe_type::__do_wrap( std::forward<_Callable>(__callable)),
1559			std::forward<_Args>(__args)...);
1560			}
1561
1562			/**
1563			* @brief Exception class thrown when class template function's
1564			* operator() is called with an empty target.
1565			* @ingroup exceptions
1566			*/
1567			class bad_function_call : public std::exception
1568			{
1569			public:
1570			virtual ~bad_function_call() noexcept;
1571
1572			const char* what() const noexcept;
1573			};
1574
1575			/**
1576			* Trait identifying "location-invariant" types, meaning that the
1577			* address of the object (or any of its members) will not escape.
1578			* Trivially copyable types are location-invariant and users can
1579			* specialize this trait for other types.
1580			*/
1581			template
1582			struct __is_location_invariant
1583			: is_trivially_copyable<_Tp>::type
1584			{ };
1585
1586			class _Undefined_class;
1587
1588			union _Nocopy_types
1589			{
1590			void* _M_object;
1591			const void* _M_const_object;
1592			void (*_M_function_pointer)();
1593			void (_Undefined_class::*_M_member_pointer)();
1594			};
1595
1596			union _Any_data
1597			{
1598	336		void* _M_access() { return &_M_pod_data[0]; }
1599	164		const void* _M_access() const { return &_M_pod_data[0]; }
1600
1601			template
1602			_Tp&
1603	84		_M_access()
1604	84		{ return static_cast<_Tp>(_M_access()); }
1605
1606			template
1607			const _Tp&
1608	82		_M_access() const
1609	82		{ return *static_cast(_M_access()); }
1610
1611			_Nocopy_types _M_unused;
1612			char _M_pod_data[sizeof(_Nocopy_types)];
1613			};
1614
1615			enum _Manager_operation
1616			{
1617			__get_type_info,
1618			__get_functor_ptr,
1619			__clone_functor,
1620			__destroy_functor
1621			};
1622
1623			// Simple type wrapper that helps avoid annoying const problems
1624			// when casting between void pointers and pointers-to-pointers.
1625			template
1626			struct _Simple_type_wrapper
1627			{
1628			_Simple_type_wrapper(_Tp __value) : __value(__value) { }
1629
1630			_Tp __value;
1631			};
1632
1633			template
1634			struct __is_location_invariant<_Simple_type_wrapper<_Tp> >
1635			: __is_location_invariant<_Tp>
1636			{ };
1637
1638			// Converts a reference to a function object into a callable
1639			// function object.
1640			template
1641			inline _Functor&
1642			__callable_functor(_Functor& __f)
1643			{ return __f; }
1644
1645			template
1646			inline _Mem_fn<_Member _Class::*>
1647			__callable_functor(_Member _Class::* &__p)
1648			{ return std::mem_fn(__p); }
1649
1650			template
1651			inline _Mem_fn<_Member _Class::*>
1652			__callable_functor(_Member _Class::* const &__p)
1653			{ return std::mem_fn(__p); }
1654
1655			template
1656			inline _Mem_fn<_Member _Class::*>
1657			__callable_functor(_Member _Class::* volatile &__p)
1658			{ return std::mem_fn(__p); }
1659
1660			template
1661			inline _Mem_fn<_Member _Class::*>
1662			__callable_functor(_Member _Class::* const volatile &__p)
1663			{ return std::mem_fn(__p); }
1664
1665			template
1666			class function;
1667
1668			/// Base class of all polymorphic function object wrappers.
1669			class _Function_base
1670			{
1671			public:
1672			static const std::size_t _M_max_size = sizeof(_Nocopy_types);
1673			static const std::size_t _M_max_align = __alignof__(_Nocopy_types);
1674
1675			template
1676			class _Base_manager
1677			{
1678			protected:
1679			static const bool __stored_locally =
1680			(__is_location_invariant<_Functor>::value
1681			&& sizeof(_Functor) <= _M_max_size
1682			&& __alignof__(_Functor) <= _M_max_align
1683			&& (_M_max_align % __alignof__(_Functor) == 0));
1684
1685			typedef integral_constant _Local_storage;
1686
1687			// Retrieve a pointer to the function object
1688			static _Functor*
1689	82		_M_get_pointer(const _Any_data& __source)
1690			{
1691			const _Functor* __ptr =
1692	82		__stored_locally? std::__addressof(__source._M_access<_Functor>())
1693	82		/* have stored a pointer / : __source._M_access<_Functor>();
1694	82		return const_cast<_Functor*>(__ptr);
1695			}
1696
1697			// Clone a location-invariant function object that fits within
1698			// an _Any_data structure.
1699			static void
1700	0		_M_clone(_Any_data& __dest, const _Any_data& __source, true_type)
1701			{
1702	0	0	new (__dest._M_access()) _Functor(__source._M_access<_Functor>());
		0
1703	0		}
1704
1705			// Clone a function object that is not location-invariant or
1706			// that cannot fit into an _Any_data structure.
1707			static void
1708			_M_clone(_Any_data& __dest, const _Any_data& __source, false_type)
1709			{
1710			__dest._M_access<_Functor*>() =
1711			new _Functor(__source._M_access<_Functor>());
1712			}
1713
1714			// Destroying a location-invariant object may still require
1715			// destruction.
1716			static void
1717	84		_M_destroy(_Any_data& __victim, true_type)
1718			{
1719	84		__victim._M_access<_Functor>().~_Functor();
1720	84		}
1721
1722			// Destroying an object located on the heap.
1723			static void
1724			_M_destroy(_Any_data& __victim, false_type)
1725			{
1726			delete __victim._M_access<_Functor*>();
1727			}
1728
1729			public:
1730			static bool
1731	84		_M_manager(_Any_data& __dest, const _Any_data& __source,
1732			_Manager_operation __op)
1733			{
1734	84		switch (__op)
1735			{
1736			#if __cpp_rtti
1737			case __get_type_info:
1738	0		__dest._M_access() = &typeid(_Functor);
1739	0		break;
1740			#endif
1741			case __get_functor_ptr:
1742	0		__dest._M_access<_Functor*>() = _M_get_pointer(__source);
1743	0		break;
1744
1745			case __clone_functor:
1746	0	0	_M_clone(__dest, __source, _Local_storage());
		0
1747	0		break;
1748
1749			case __destroy_functor:
1750	84	50	_M_destroy(__dest, _Local_storage());
		50
1751	84		break;
1752			}
1753	84		return false;
1754			}
1755
1756			static void
1757	84		_M_init_functor(_Any_data& __functor, _Functor&& __f)
1758	84		{ _M_init_functor(__functor, std::move(__f), _Local_storage()); }
1759
1760			template
1761			static bool
1762			_M_not_empty_function(const function<_Signature>& __f)
1763			{ return static_cast(__f); }
1764
1765			template
1766			static bool
1767			_M_not_empty_function(_Tp* const& __fp)
1768			{ return __fp; }
1769
1770			template
1771			static bool
1772			_M_not_empty_function(_Tp _Class::* const& __mp)
1773			{ return __mp; }
1774
1775			template
1776			static bool
1777	84		_M_not_empty_function(const _Tp&)
1778	84		{ return true; }
1779
1780			private:
1781			static void
1782	84		_M_init_functor(_Any_data& __functor, _Functor&& __f, true_type)
1783	84	50	{ new (__functor._M_access()) _Functor(std::move(__f)); }
		50
1784
1785			static void
1786			_M_init_functor(_Any_data& __functor, _Functor&& __f, false_type)
1787			{ __functor._M_access<_Functor*>() = new _Functor(std::move(__f)); }
1788			};
1789
1790			template
1791			class _Ref_manager : public _Base_manager<_Functor*>
1792			{
1793			typedef _Function_base::_Base_manager<_Functor*> _Base;
1794
1795			public:
1796			static bool
1797			_M_manager(_Any_data& __dest, const _Any_data& __source,
1798			_Manager_operation __op)
1799			{
1800			switch (__op)
1801			{
1802			#if __cpp_rtti
1803			case __get_type_info:
1804			__dest._M_access() = &typeid(_Functor);
1805			break;
1806			#endif
1807			case __get_functor_ptr:
1808			__dest._M_access<_Functor>() = _Base::_M_get_pointer(__source);
1809			return is_const<_Functor>::value;
1810			break;
1811
1812			default:
1813			_Base::_M_manager(__dest, __source, __op);
1814			}
1815			return false;
1816			}
1817
1818			static void
1819			_M_init_functor(_Any_data& __functor, reference_wrapper<_Functor> __f)
1820			{
1821			_Base::_M_init_functor(__functor, std::__addressof(__f.get()));
1822			}
1823			};
1824
1825	84		_Function_base() : _M_manager(nullptr) { }
1826
1827	84		~_Function_base()
1828	84		{
1829	84	50	if (_M_manager)
1830	84		_M_manager(_M_functor, _M_functor, __destroy_functor);
1831	84		}
1832
1833
1834	164		bool _M_empty() const { return !_M_manager; }
1835
1836			typedef bool (*_Manager_type)(_Any_data&, const _Any_data&,
1837			_Manager_operation);
1838
1839			_Any_data _M_functor;
1840			_Manager_type _M_manager;
1841			};
1842
1843			template
1844			class _Function_handler;
1845
1846			template
1847			class _Function_handler<_Res(_ArgTypes...), _Functor>
1848			: public _Function_base::_Base_manager<_Functor>
1849			{
1850			typedef _Function_base::_Base_manager<_Functor> _Base;
1851
1852			public:
1853			static _Res
1854	82		_M_invoke(const _Any_data& __functor, _ArgTypes&&... __args)
1855			{
1856	82		return (*_Base::_M_get_pointer(__functor))(
1857	164		std::forward<_ArgTypes>(__args)...);
1858			}
1859			};
1860
1861			template
1862			class _Function_handler
1863			: public _Function_base::_Base_manager<_Functor>
1864			{
1865			typedef _Function_base::_Base_manager<_Functor> _Base;
1866
1867			public:
1868			static void
1869			_M_invoke(const _Any_data& __functor, _ArgTypes&&... __args)
1870			{
1871			(*_Base::_M_get_pointer(__functor))(
1872			std::forward<_ArgTypes>(__args)...);
1873			}
1874			};
1875
1876			template
1877			class _Function_handler<_Res(_ArgTypes...), reference_wrapper<_Functor> >
1878			: public _Function_base::_Ref_manager<_Functor>
1879			{
1880			typedef _Function_base::_Ref_manager<_Functor> _Base;
1881
1882			public:
1883			static _Res
1884			_M_invoke(const _Any_data& __functor, _ArgTypes&&... __args)
1885			{
1886			return std::__callable_functor(**_Base::_M_get_pointer(__functor))(
1887			std::forward<_ArgTypes>(__args)...);
1888			}
1889			};
1890
1891			template
1892			class _Function_handler >
1893			: public _Function_base::_Ref_manager<_Functor>
1894			{
1895			typedef _Function_base::_Ref_manager<_Functor> _Base;
1896
1897			public:
1898			static void
1899			_M_invoke(const _Any_data& __functor, _ArgTypes&&... __args)
1900			{
1901			std::__callable_functor(**_Base::_M_get_pointer(__functor))(
1902			std::forward<_ArgTypes>(__args)...);
1903			}
1904			};
1905
1906			template
1907			typename... _ArgTypes>
1908			class _Function_handler<_Res(_ArgTypes...), _Member _Class::*>
1909			: public _Function_handler
1910			{
1911			typedef _Function_handler
1912			_Base;
1913
1914			public:
1915			static _Res
1916			_M_invoke(const _Any_data& __functor, _ArgTypes&&... __args)
1917			{
1918			return std::mem_fn(_Base::_M_get_pointer(__functor)->__value)(
1919			std::forward<_ArgTypes>(__args)...);
1920			}
1921			};
1922
1923			template
1924			class _Function_handler
1925			: public _Function_base::_Base_manager<
1926			_Simple_type_wrapper< _Member _Class::* > >
1927			{
1928			typedef _Member _Class::* _Functor;
1929			typedef _Simple_type_wrapper<_Functor> _Wrapper;
1930			typedef _Function_base::_Base_manager<_Wrapper> _Base;
1931
1932			public:
1933			static bool
1934			_M_manager(_Any_data& __dest, const _Any_data& __source,
1935			_Manager_operation __op)
1936			{
1937			switch (__op)
1938			{
1939			#if __cpp_rtti
1940			case __get_type_info:
1941			__dest._M_access() = &typeid(_Functor);
1942			break;
1943			#endif
1944			case __get_functor_ptr:
1945			__dest._M_access<_Functor*>() =
1946			&_Base::_M_get_pointer(__source)->__value;
1947			break;
1948
1949			default:
1950			_Base::_M_manager(__dest, __source, __op);
1951			}
1952			return false;
1953			}
1954
1955			static void
1956			_M_invoke(const _Any_data& __functor, _ArgTypes&&... __args)
1957			{
1958			std::mem_fn(_Base::_M_get_pointer(__functor)->__value)(
1959			std::forward<_ArgTypes>(__args)...);
1960			}
1961			};
1962
1963			template
1964			using __check_func_return_type
1965			= __or_, is_convertible<_From, _To>>;
1966
1967			/**
1968			* @brief Primary class template for std::function.
1969			* @ingroup functors
1970			*
1971			* Polymorphic function wrapper.
1972			*/
1973			template
1974	168		class function<_Res(_ArgTypes...)>
1975			: public _Maybe_unary_or_binary_function<_Res, _ArgTypes...>,
1976			private _Function_base
1977			{
1978			typedef _Res _Signature_type(_ArgTypes...);
1979
1980			template
1981			typename _Res2 = typename result_of<_Func(_ArgTypes...)>::type>
1982			struct _Callable : __check_func_return_type<_Res2, _Res> { };
1983
1984			// Used so the return type convertibility checks aren't done when
1985			// performing overload resolution for copy construction/assignment.
1986			template
1987			struct _Callable : false_type { };
1988
1989			template
1990			using _Requires = typename enable_if<_Cond::value, _Tp>::type;
1991
1992			public:
1993			typedef _Res result_type;
1994
1995			// [3.7.2.1] construct/copy/destroy
1996
1997			/**
1998			* @brief Default construct creates an empty function call wrapper.
1999			* @post @c !(bool)*this
2000			*/
2001			function() noexcept
2002			: _Function_base() { }
2003
2004			/**
2005			* @brief Creates an empty function call wrapper.
2006			* @post @c !(bool)*this
2007			*/
2008			function(nullptr_t) noexcept
2009			: _Function_base() { }
2010
2011			/**
2012			* @brief %Function copy constructor.
2013			* @param __x A %function object with identical call signature.
2014			* @post @c bool(*this) == bool(__x)
2015			*
2016			* The newly-created %function contains a copy of the target of @a
2017			* __x (if it has one).
2018			*/
2019			function(const function& __x);
2020
2021			/**
2022			* @brief %Function move constructor.
2023			* @param __x A %function object rvalue with identical call signature.
2024			*
2025			* The newly-created %function contains the target of @a __x
2026			* (if it has one).
2027			*/
2028			function(function&& __x) : _Function_base()
2029			{
2030			__x.swap(*this);
2031			}
2032
2033			// TODO: needs allocator_arg_t
2034
2035			/**
2036			* @brief Builds a %function that targets a copy of the incoming
2037			* function object.
2038			* @param __f A %function object that is callable with parameters of
2039			* type @c T1, @c T2, ..., @c TN and returns a value convertible
2040			* to @c Res.
2041			*
2042			* The newly-created %function object will target a copy of
2043			* @a __f. If @a __f is @c reference_wrapper, then this function
2044			* object will contain a reference to the function object @c
2045			* __f.get(). If @a __f is a NULL function pointer or NULL
2046			* pointer-to-member, the newly-created object will be empty.
2047			*
2048			* If @a __f is a non-NULL function pointer or an object of type @c
2049			* reference_wrapper, this function will not throw.
2050			*/
2051			template
2052			typename = _Requires<__not_>, void>,
2053			typename = _Requires<_Callable<_Functor>, void>>
2054			function(_Functor);
2055
2056			/**
2057			* @brief %Function assignment operator.
2058			* @param __x A %function with identical call signature.
2059			* @post @c (bool)*this == (bool)x
2060			* @returns @c *this
2061			*
2062			* The target of @a __x is copied to @c *this. If @a __x has no
2063			* target, then @c *this will be empty.
2064			*
2065			* If @a __x targets a function pointer or a reference to a function
2066			* object, then this operation will not throw an %exception.
2067			*/
2068			function&
2069			operator=(const function& __x)
2070			{
2071			function(__x).swap(*this);
2072			return *this;
2073			}
2074
2075			/**
2076			* @brief %Function move-assignment operator.
2077			* @param __x A %function rvalue with identical call signature.
2078			* @returns @c *this
2079			*
2080			* The target of @a __x is moved to @c *this. If @a __x has no
2081			* target, then @c *this will be empty.
2082			*
2083			* If @a __x targets a function pointer or a reference to a function
2084			* object, then this operation will not throw an %exception.
2085			*/
2086			function&
2087			operator=(function&& __x)
2088			{
2089			function(std::move(__x)).swap(*this);
2090			return *this;
2091			}
2092
2093			/**
2094			* @brief %Function assignment to zero.
2095			* @post @c !(bool)*this
2096			* @returns @c *this
2097			*
2098			* The target of @c *this is deallocated, leaving it empty.
2099			*/
2100			function&
2101			operator=(nullptr_t) noexcept
2102			{
2103			if (_M_manager)
2104			{
2105			_M_manager(_M_functor, _M_functor, __destroy_functor);
2106			_M_manager = nullptr;
2107			_M_invoker = nullptr;
2108			}
2109			return *this;
2110			}
2111
2112			/**
2113			* @brief %Function assignment to a new target.
2114			* @param __f A %function object that is callable with parameters of
2115			* type @c T1, @c T2, ..., @c TN and returns a value convertible
2116			* to @c Res.
2117			* @return @c *this
2118			*
2119			* This %function object wrapper will target a copy of @a
2120			* __f. If @a __f is @c reference_wrapper, then this function
2121			* object will contain a reference to the function object @c
2122			* __f.get(). If @a __f is a NULL function pointer or NULL
2123			* pointer-to-member, @c this object will be empty.
2124			*
2125			* If @a __f is a non-NULL function pointer or an object of type @c
2126			* reference_wrapper, this function will not throw.
2127			*/
2128			template
2129			_Requires<_Callable::type>, function&>
2130			operator=(_Functor&& __f)
2131			{
2132			function(std::forward<_Functor>(__f)).swap(*this);
2133			return *this;
2134			}
2135
2136			/// @overload
2137			template
2138			function&
2139			operator=(reference_wrapper<_Functor> __f) noexcept
2140			{
2141			function(__f).swap(*this);
2142			return *this;
2143			}
2144
2145			// [3.7.2.2] function modifiers
2146
2147			/**
2148			* @brief Swap the targets of two %function objects.
2149			* @param __x A %function with identical call signature.
2150			*
2151			* Swap the targets of @c this function object and @a __f. This
2152			* function will not throw an %exception.
2153			*/
2154			void swap(function& __x)
2155			{
2156			std::swap(_M_functor, __x._M_functor);
2157			std::swap(_M_manager, __x._M_manager);
2158			std::swap(_M_invoker, __x._M_invoker);
2159			}
2160
2161			// TODO: needs allocator_arg_t
2162			/*
2163			template
2164			void
2165			assign(_Functor&& __f, const _Alloc& __a)
2166			{
2167			function(allocator_arg, __a,
2168			std::forward<_Functor>(__f)).swap(*this);
2169			}
2170			*/
2171
2172			// [3.7.2.3] function capacity
2173
2174			/**
2175			* @brief Determine if the %function wrapper has a target.
2176			*
2177			* @return @c true when this %function object contains a target,
2178			* or @c false when it is empty.
2179			*
2180			* This function will not throw an %exception.
2181			*/
2182			explicit operator bool() const noexcept
2183			{ return !_M_empty(); }
2184
2185			// [3.7.2.4] function invocation
2186
2187			/**
2188			* @brief Invokes the function targeted by @c *this.
2189			* @returns the result of the target.
2190			* @throws bad_function_call when @c !(bool)*this
2191			*
2192			* The function call operator invokes the target function object
2193			* stored by @c this.
2194			*/
2195			_Res operator()(_ArgTypes... __args) const;
2196
2197			#if __cpp_rtti
2198			// [3.7.2.5] function target access
2199			/**
2200			* @brief Determine the type of the target of this function object
2201			* wrapper.
2202			*
2203			* @returns the type identifier of the target function object, or
2204			* @c typeid(void) if @c !(bool)*this.
2205			*
2206			* This function will not throw an %exception.
2207			*/
2208			const type_info& target_type() const noexcept;
2209
2210			/**
2211			* @brief Access the stored target function object.
2212			*
2213			* @return Returns a pointer to the stored target function object,
2214			* if @c typeid(Functor).equals(target_type()); otherwise, a NULL
2215			* pointer.
2216			*
2217			* This function will not throw an %exception.
2218			*/
2219			template _Functor* target() noexcept;
2220
2221			/// @overload
2222			template const _Functor* target() const noexcept;
2223			#endif
2224
2225			private:
2226			using _Invoker_type = _Res (*)(const _Any_data&, _ArgTypes&&...);
2227			_Invoker_type _M_invoker;
2228			};
2229
2230			// Out-of-line member definitions.
2231			template
2232			function<_Res(_ArgTypes...)>::
2233			function(const function& __x)
2234			: _Function_base()
2235			{
2236			if (static_cast(__x))
2237			{
2238			__x._M_manager(_M_functor, __x._M_functor, __clone_functor);
2239			_M_invoker = __x._M_invoker;
2240			_M_manager = __x._M_manager;
2241			}
2242			}
2243
2244			template
2245			template
2246	84		function<_Res(_ArgTypes...)>::
2247			function(_Functor __f)
2248	84		: _Function_base()
2249			{
2250			typedef _Function_handler<_Signature_type, _Functor> _My_handler;
2251
2252	84	50	if (_My_handler::_M_not_empty_function(__f))
		50
2253			{
2254	84	50	_My_handler::_M_init_functor(_M_functor, std::move(__f));
		50
2255	84		_M_invoker = &_My_handler::_M_invoke;
2256	84		_M_manager = &_My_handler::_M_manager;
2257			}
2258	84		}
2259
2260			template
2261			_Res
2262	82		function<_Res(_ArgTypes...)>::
2263			operator()(_ArgTypes... __args) const
2264			{
2265	82	50	if (_M_empty())
2266	0		__throw_bad_function_call();
2267	82		return _M_invoker(_M_functor, std::forward<_ArgTypes>(__args)...);
2268			}
2269
2270			#if __cpp_rtti
2271			template
2272			const type_info&
2273			function<_Res(_ArgTypes...)>::
2274			target_type() const noexcept
2275			{
2276			if (_M_manager)
2277			{
2278			_Any_data __typeinfo_result;
2279			_M_manager(__typeinfo_result, _M_functor, __get_type_info);
2280			return *__typeinfo_result._M_access();
2281			}
2282			else
2283			return typeid(void);
2284			}
2285
2286			template
2287			template
2288			_Functor*
2289			function<_Res(_ArgTypes...)>::
2290			target() noexcept
2291			{
2292			if (typeid(_Functor) == target_type() && _M_manager)
2293			{
2294			_Any_data __ptr;
2295			if (_M_manager(__ptr, _M_functor, __get_functor_ptr)
2296			&& !is_const<_Functor>::value)
2297			return 0;
2298			else
2299			return __ptr._M_access<_Functor*>();
2300			}
2301			else
2302			return 0;
2303			}
2304
2305			template
2306			template
2307			const _Functor*
2308			function<_Res(_ArgTypes...)>::
2309			target() const noexcept
2310			{
2311			if (typeid(_Functor) == target_type() && _M_manager)
2312			{
2313			_Any_data __ptr;
2314			_M_manager(__ptr, _M_functor, __get_functor_ptr);
2315			return __ptr._M_access();
2316			}
2317			else
2318			return 0;
2319			}
2320			#endif
2321
2322			// [20.7.15.2.6] null pointer comparisons
2323
2324			/**
2325			* @brief Compares a polymorphic function object wrapper against 0
2326			* (the NULL pointer).
2327			* @returns @c true if the wrapper has no target, @c false otherwise
2328			*
2329			* This function will not throw an %exception.
2330			*/
2331			template
2332			inline bool
2333			operator==(const function<_Res(_Args...)>& __f, nullptr_t) noexcept
2334			{ return !static_cast(__f); }
2335
2336			/// @overload
2337			template
2338			inline bool
2339			operator==(nullptr_t, const function<_Res(_Args...)>& __f) noexcept
2340			{ return !static_cast(__f); }
2341
2342			/**
2343			* @brief Compares a polymorphic function object wrapper against 0
2344			* (the NULL pointer).
2345			* @returns @c false if the wrapper has no target, @c true otherwise
2346			*
2347			* This function will not throw an %exception.
2348			*/
2349			template
2350			inline bool
2351			operator!=(const function<_Res(_Args...)>& __f, nullptr_t) noexcept
2352			{ return static_cast(__f); }
2353
2354			/// @overload
2355			template
2356			inline bool
2357			operator!=(nullptr_t, const function<_Res(_Args...)>& __f) noexcept
2358			{ return static_cast(__f); }
2359
2360			// [20.7.15.2.7] specialized algorithms
2361
2362			/**
2363			* @brief Swap the targets of two polymorphic function object wrappers.
2364			*
2365			* This function will not throw an %exception.
2366			*/
2367			template
2368			inline void
2369			swap(function<_Res(_Args...)>& __x, function<_Res(_Args...)>& __y)
2370			{ __x.swap(__y); }
2371
2372			_GLIBCXX_END_NAMESPACE_VERSION
2373			} // namespace std
2374
2375			#endif // C++11
2376
2377			#endif // _GLIBCXX_FUNCTIONAL