// TR1 functional -*- C++ -*- // Copyright (C) 2005, 2006 Free Software Foundation, Inc. // Written by Douglas Gregor // // 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 2, 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. // You should have received a copy of the GNU General Public License along // with this library; see the file COPYING. If not, write to the Free // Software Foundation, 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301, // USA. // As a special exception, you may use this file as part of a free software // library without restriction. Specifically, if other files instantiate // templates or use macros or inline functions from this file, or you compile // this file and link it with other files to produce an executable, this // file does not by itself cause the resulting executable to be covered by // the GNU General Public License. This exception does not however // invalidate any other reasons why the executable file might be covered by // the GNU General Public License. /** @file tr1/functional_iterate.h * This is an internal header file, included by other library headers. * You should not attempt to use it directly. */ namespace std { _GLIBCXX_BEGIN_NAMESPACE(tr1) template struct _Weak_result_type_impl<_Res(_GLIBCXX_TEMPLATE_ARGS)> { typedef _Res result_type; }; template struct _Weak_result_type_impl<_Res (&)(_GLIBCXX_TEMPLATE_ARGS)> { typedef _Res result_type; }; template struct _Weak_result_type_impl<_Res (*)(_GLIBCXX_TEMPLATE_ARGS)> { typedef _Res result_type; }; #if _GLIBCXX_NUM_ARGS > 0 template struct _Weak_result_type_impl< _Res (_Class::*)(_GLIBCXX_TEMPLATE_ARGS_SHIFTED)> { typedef _Res result_type; }; template struct _Weak_result_type_impl< _Res (_Class::*)(_GLIBCXX_TEMPLATE_ARGS_SHIFTED) const> { typedef _Res result_type; }; template struct _Weak_result_type_impl< _Res (_Class::*)(_GLIBCXX_TEMPLATE_ARGS_SHIFTED) volatile> { typedef _Res result_type; }; template struct _Weak_result_type_impl< _Res (_Class::*)(_GLIBCXX_TEMPLATE_ARGS_SHIFTED) const volatile> { typedef _Res result_type; }; #endif template class result_of<_Functor(_GLIBCXX_TEMPLATE_ARGS)> : public _Result_of_impl< _Has_result_type<_Weak_result_type<_Functor> >::value, _Functor(_GLIBCXX_TEMPLATE_ARGS)> { }; template struct _Result_of_impl { typedef typename _Weak_result_type<_Functor>::result_type type; }; template struct _Result_of_impl { #if _GLIBCXX_NUM_ARGS > 0 typedef typename _Functor ::template result<_Functor(_GLIBCXX_TEMPLATE_ARGS)>::type type; #else typedef void type; #endif }; /** * @if maint * Invoke a function object, which may be either a member pointer or a * function object. The first parameter will tell which. * @endif */ template inline typename __gnu_cxx::__enable_if<(!is_member_pointer<_Functor>::value && !is_function<_Functor>::value && !is_function::type>::value), typename result_of<_Functor(_GLIBCXX_TEMPLATE_ARGS)>::type>::__type __invoke(_Functor& __f _GLIBCXX_COMMA _GLIBCXX_REF_PARAMS) { return __f(_GLIBCXX_ARGS); } #if _GLIBCXX_NUM_ARGS > 0 template inline typename __gnu_cxx::__enable_if<(is_member_pointer<_Functor>::value && !is_function<_Functor>::value && !is_function::type>::value), typename result_of<_Functor(_GLIBCXX_TEMPLATE_ARGS)>::type >::__type __invoke(_Functor& __f _GLIBCXX_COMMA _GLIBCXX_REF_PARAMS) { return mem_fn(__f)(_GLIBCXX_ARGS); } #endif // To pick up function references (that will become function pointers) template inline typename __gnu_cxx::__enable_if<(is_pointer<_Functor>::value && is_function::type>::value), typename result_of<_Functor(_GLIBCXX_TEMPLATE_ARGS)>::type >::__type __invoke(_Functor __f _GLIBCXX_COMMA _GLIBCXX_REF_PARAMS) { return __f(_GLIBCXX_ARGS); } /** * @if maint * Implementation of reference_wrapper::operator() * @endif */ #if _GLIBCXX_NUM_ARGS > 0 template template<_GLIBCXX_TEMPLATE_PARAMS> typename result_of< typename reference_wrapper<_Tp>::_M_func_type(_GLIBCXX_TEMPLATE_ARGS)>::type reference_wrapper<_Tp>::operator()(_GLIBCXX_REF_PARAMS) const { return __invoke(get(), _GLIBCXX_ARGS); } #endif #if _GLIBCXX_NUM_ARGS > 0 template class _Mem_fn<_Res (_Class::*)(_GLIBCXX_TEMPLATE_ARGS_SHIFTED)> #if _GLIBCXX_NUM_ARGS == 1 : public unary_function<_Class*, _Res> #elif _GLIBCXX_NUM_ARGS == 2 : public binary_function<_Class*, _T1, _Res> #endif { typedef _Res (_Class::*_Functor)(_GLIBCXX_TEMPLATE_ARGS_SHIFTED); template _Res _M_call(_Tp& __object, const volatile _Class * _GLIBCXX_COMMA_SHIFTED _GLIBCXX_PARAMS_SHIFTED) const { return (__object.*__pmf)(_GLIBCXX_ARGS_SHIFTED); } template _Res _M_call(_Tp& __ptr, const volatile void * _GLIBCXX_COMMA_SHIFTED _GLIBCXX_PARAMS_SHIFTED) const { return ((*__ptr).*__pmf)(_GLIBCXX_ARGS_SHIFTED); } public: typedef _Res result_type; explicit _Mem_fn(_Functor __pf) : __pmf(__pf) { } // Handle objects _Res operator()(_Class& __object _GLIBCXX_COMMA_SHIFTED _GLIBCXX_PARAMS_SHIFTED) const { return (__object.*__pmf)(_GLIBCXX_ARGS_SHIFTED); } // Handle pointers _Res operator()(_Class* __object _GLIBCXX_COMMA_SHIFTED _GLIBCXX_PARAMS_SHIFTED) const { return (__object->*__pmf)(_GLIBCXX_ARGS_SHIFTED); } // Handle smart pointers, references and pointers to derived template _Res operator()(_Tp& __object _GLIBCXX_COMMA_SHIFTED _GLIBCXX_PARAMS_SHIFTED) const { return _M_call(__object, &__object _GLIBCXX_COMMA_SHIFTED _GLIBCXX_ARGS_SHIFTED); } private: _Functor __pmf; }; template class _Mem_fn<_Res (_Class::*)(_GLIBCXX_TEMPLATE_ARGS_SHIFTED) const> #if _GLIBCXX_NUM_ARGS == 1 : public unary_function #elif _GLIBCXX_NUM_ARGS == 2 : public binary_function #endif { typedef _Res (_Class::*_Functor)(_GLIBCXX_TEMPLATE_ARGS_SHIFTED) const; template _Res _M_call(_Tp& __object, const volatile _Class * _GLIBCXX_COMMA_SHIFTED _GLIBCXX_PARAMS_SHIFTED) const { return (__object.*__pmf)(_GLIBCXX_ARGS_SHIFTED); } template _Res _M_call(_Tp& __ptr, const volatile void * _GLIBCXX_COMMA_SHIFTED _GLIBCXX_PARAMS_SHIFTED) const { return ((*__ptr).*__pmf)(_GLIBCXX_ARGS_SHIFTED); } public: typedef _Res result_type; explicit _Mem_fn(_Functor __pf) : __pmf(__pf) { } // Handle objects _Res operator()(const _Class& __object _GLIBCXX_COMMA_SHIFTED _GLIBCXX_PARAMS_SHIFTED) const { return (__object.*__pmf)(_GLIBCXX_ARGS_SHIFTED); } // Handle pointers _Res operator()(const _Class* __object _GLIBCXX_COMMA_SHIFTED _GLIBCXX_PARAMS_SHIFTED) const { return (__object->*__pmf)(_GLIBCXX_ARGS_SHIFTED); } // Handle smart pointers, references and pointers to derived template _Res operator()(_Tp& __object _GLIBCXX_COMMA_SHIFTED _GLIBCXX_PARAMS_SHIFTED) const { return _M_call(__object, &__object _GLIBCXX_COMMA_SHIFTED _GLIBCXX_ARGS_SHIFTED); } private: _Functor __pmf; }; template class _Mem_fn<_Res (_Class::*)(_GLIBCXX_TEMPLATE_ARGS_SHIFTED) volatile> #if _GLIBCXX_NUM_ARGS == 1 : public unary_function #elif _GLIBCXX_NUM_ARGS == 2 : public binary_function #endif { typedef _Res (_Class::*_Functor)(_GLIBCXX_TEMPLATE_ARGS_SHIFTED) volatile; template _Res _M_call(_Tp& __object, const volatile _Class * _GLIBCXX_COMMA_SHIFTED _GLIBCXX_PARAMS_SHIFTED) const { return (__object.*__pmf)(_GLIBCXX_ARGS_SHIFTED); } template _Res _M_call(_Tp& __ptr, const volatile void * _GLIBCXX_COMMA_SHIFTED _GLIBCXX_PARAMS_SHIFTED) const { return ((*__ptr).*__pmf)(_GLIBCXX_ARGS_SHIFTED); } public: typedef _Res result_type; explicit _Mem_fn(_Functor __pf) : __pmf(__pf) { } // Handle objects _Res operator()(volatile _Class& __object _GLIBCXX_COMMA_SHIFTED _GLIBCXX_PARAMS_SHIFTED) const { return (__object.*__pmf)(_GLIBCXX_ARGS_SHIFTED); } // Handle pointers _Res operator()(volatile _Class* __object _GLIBCXX_COMMA_SHIFTED _GLIBCXX_PARAMS_SHIFTED) const { return (__object->*__pmf)(_GLIBCXX_ARGS_SHIFTED); } // Handle smart pointers, references and pointers to derived template _Res operator()(_Tp& __object _GLIBCXX_COMMA_SHIFTED _GLIBCXX_PARAMS_SHIFTED) const { return _M_call(__object, &__object _GLIBCXX_COMMA_SHIFTED _GLIBCXX_ARGS_SHIFTED); } private: _Functor __pmf; }; template class _Mem_fn<_Res(_Class::*)(_GLIBCXX_TEMPLATE_ARGS_SHIFTED) const volatile> #if _GLIBCXX_NUM_ARGS == 1 : public unary_function #elif _GLIBCXX_NUM_ARGS == 2 : public binary_function #endif { typedef _Res (_Class::*_Functor)(_GLIBCXX_TEMPLATE_ARGS_SHIFTED) const volatile; template _Res _M_call(_Tp& __object, const volatile _Class * _GLIBCXX_COMMA_SHIFTED _GLIBCXX_PARAMS_SHIFTED) const { return (__object.*__pmf)(_GLIBCXX_ARGS_SHIFTED); } template _Res _M_call(_Tp& __ptr, const volatile void * _GLIBCXX_COMMA_SHIFTED _GLIBCXX_PARAMS_SHIFTED) const { return ((*__ptr).*__pmf)(_GLIBCXX_ARGS_SHIFTED); } public: typedef _Res result_type; explicit _Mem_fn(_Functor __pf) : __pmf(__pf) { } // Handle objects _Res operator()(const volatile _Class& __object _GLIBCXX_COMMA_SHIFTED _GLIBCXX_PARAMS_SHIFTED) const { return (__object.*__pmf)(_GLIBCXX_ARGS_SHIFTED); } // Handle pointers _Res operator()(const volatile _Class* __object _GLIBCXX_COMMA_SHIFTED _GLIBCXX_PARAMS_SHIFTED) const { return (__object->*__pmf)(_GLIBCXX_ARGS_SHIFTED); } // Handle smart pointers, references and pointers to derived template _Res operator()(_Tp& __object _GLIBCXX_COMMA_SHIFTED _GLIBCXX_PARAMS_SHIFTED) const { return _M_call(__object, &__object _GLIBCXX_COMMA_SHIFTED _GLIBCXX_ARGS_SHIFTED); } private: _Functor __pmf; }; #endif #if _GLIBCXX_NUM_ARGS > 0 namespace placeholders { namespace { _Placeholder<_GLIBCXX_NUM_ARGS> _GLIBCXX_JOIN(_,_GLIBCXX_NUM_ARGS); } // anonymous namespace } #endif template class _Bind<_Functor(_GLIBCXX_TEMPLATE_ARGS)> : public _Weak_result_type<_Functor> { typedef _Bind __self_type; _Functor _M_f; _GLIBCXX_BIND_MEMBERS public: #if _GLIBCXX_NUM_ARGS == 0 explicit #endif _Bind(_Functor __f _GLIBCXX_COMMA _GLIBCXX_PARAMS) : _M_f(__f) _GLIBCXX_COMMA _GLIBCXX_BIND_MEMBERS_INIT { } #define _GLIBCXX_BIND_REPEAT_HEADER #include #undef _GLIBCXX_BIND_REPEAT_HEADER }; template class _Bind_result<_Result, _Functor(_GLIBCXX_TEMPLATE_ARGS)> { _Functor _M_f; _GLIBCXX_BIND_MEMBERS public: typedef _Result result_type; #if _GLIBCXX_NUM_ARGS == 0 explicit #endif _Bind_result(_Functor __f _GLIBCXX_COMMA _GLIBCXX_PARAMS) : _M_f(__f) _GLIBCXX_COMMA _GLIBCXX_BIND_MEMBERS_INIT { } #define _GLIBCXX_BIND_REPEAT_HEADER #define _GLIBCXX_BIND_HAS_RESULT_TYPE #include #undef _GLIBCXX_BIND_HAS_RESULT_TYPE #undef _GLIBCXX_BIND_REPEAT_HEADER }; // Handle arbitrary function objects template inline _Bind::type (_GLIBCXX_TEMPLATE_ARGS)> bind(_Functor __f _GLIBCXX_COMMA _GLIBCXX_PARAMS) { typedef _Maybe_wrap_member_pointer<_Functor> __maybe_type; typedef typename __maybe_type::type __functor_type; typedef _Bind<__functor_type(_GLIBCXX_TEMPLATE_ARGS)> __result_type; return __result_type(__maybe_type::__do_wrap(__f) _GLIBCXX_COMMA _GLIBCXX_ARGS); } template inline _Bind_result<_Result, typename _Maybe_wrap_member_pointer<_Functor>::type (_GLIBCXX_TEMPLATE_ARGS)> bind(_Functor __f _GLIBCXX_COMMA _GLIBCXX_PARAMS) { typedef _Maybe_wrap_member_pointer<_Functor> __maybe_type; typedef typename __maybe_type::type __functor_type; typedef _Bind_result<_Result, __functor_type(_GLIBCXX_TEMPLATE_ARGS)> __result_type; return __result_type(__maybe_type::__do_wrap(__f) _GLIBCXX_COMMA _GLIBCXX_ARGS); } template class _Function_handler<_Res(_GLIBCXX_TEMPLATE_ARGS), _Functor> : public _Function_base::_Base_manager<_Functor> { typedef _Function_base::_Base_manager<_Functor> _Base; public: static _Res _M_invoke(const _Any_data& __functor _GLIBCXX_COMMA _GLIBCXX_PARAMS) { return (*_Base::_M_get_pointer(__functor))(_GLIBCXX_ARGS); } }; template class _Function_handler : public _Function_base::_Base_manager<_Functor> { typedef _Function_base::_Base_manager<_Functor> _Base; public: static void _M_invoke(const _Any_data& __functor _GLIBCXX_COMMA _GLIBCXX_PARAMS) { (*_Base::_M_get_pointer(__functor))(_GLIBCXX_ARGS); } }; template class _Function_handler<_Res(_GLIBCXX_TEMPLATE_ARGS), reference_wrapper<_Functor> > : public _Function_base::_Ref_manager<_Functor> { typedef _Function_base::_Ref_manager<_Functor> _Base; public: static _Res _M_invoke(const _Any_data& __functor _GLIBCXX_COMMA _GLIBCXX_PARAMS) { return __callable_functor(**_Base::_M_get_pointer(__functor)) (_GLIBCXX_ARGS); } }; template class _Function_handler > : public _Function_base::_Ref_manager<_Functor> { typedef _Function_base::_Ref_manager<_Functor> _Base; public: static void _M_invoke(const _Any_data& __functor _GLIBCXX_COMMA _GLIBCXX_PARAMS) { __callable_functor(**_Base::_M_get_pointer(__functor))(_GLIBCXX_ARGS); } }; template class _Function_handler<_Res(_GLIBCXX_TEMPLATE_ARGS), _Member _Class::*> : public _Function_handler { typedef _Function_handler _Base; public: static _Res _M_invoke(const _Any_data& __functor _GLIBCXX_COMMA _GLIBCXX_PARAMS) { return std::tr1::mem_fn(_Base::_M_get_pointer(__functor)->__value) (_GLIBCXX_ARGS); } }; template class _Function_handler : public _Function_base::_Base_manager< _Simple_type_wrapper< _Member _Class::* > > { typedef _Member _Class::* _Functor; typedef _Simple_type_wrapper< _Functor > _Wrapper; typedef _Function_base::_Base_manager<_Wrapper> _Base; public: static bool _M_manager(_Any_data& __dest, const _Any_data& __source, _Manager_operation __op) { switch (__op) { case __get_type_info: __dest._M_access() = &typeid(_Functor); break; case __get_functor_ptr: __dest._M_access<_Functor*>() = &_Base::_M_get_pointer(__source)->__value; break; default: _Base::_M_manager(__dest, __source, __op); } return false; } static void _M_invoke(const _Any_data& __functor _GLIBCXX_COMMA _GLIBCXX_PARAMS) { std::tr1::mem_fn(_Base::_M_get_pointer(__functor)->__value) (_GLIBCXX_ARGS); } }; template class function<_Res(_GLIBCXX_TEMPLATE_ARGS)> #if _GLIBCXX_NUM_ARGS == 1 : public unary_function<_T1, _Res>, private _Function_base #elif _GLIBCXX_NUM_ARGS == 2 : public binary_function<_T1, _T2, _Res>, private _Function_base #else : private _Function_base #endif { /** * @if maint * This class is used to implement the safe_bool idiom. * @endif */ struct _Hidden_type { _Hidden_type* _M_bool; }; /** * @if maint * This typedef is used to implement the safe_bool idiom. * @endif */ typedef _Hidden_type* _Hidden_type::* _Safe_bool; typedef _Res _Signature_type(_GLIBCXX_TEMPLATE_ARGS); struct _Useless {}; public: typedef _Res result_type; // [3.7.2.1] construct/copy/destroy /** * @brief Default construct creates an empty function call wrapper. * @post @c !(bool)*this */ function() : _Function_base() { } /** * @brief Default construct creates an empty function call wrapper. * @post @c !(bool)*this */ function(_M_clear_type*) : _Function_base() { } /** * @brief %Function copy constructor. * @param x A %function object with identical call signature. * @pre @c (bool)*this == (bool)x * * The newly-created %function contains a copy of the target of @a * x (if it has one). */ function(const function& __x); /** * @brief Builds a %function that targets a copy of the incoming * function object. * @param f A %function object that is callable with parameters of * type @c T1, @c T2, ..., @c TN and returns a value convertible * to @c Res. * * The newly-created %function object will target a copy of @a * f. If @a f is @c reference_wrapper, then this function * object will contain a reference to the function object @c * f.get(). If @a f is a NULL function pointer or NULL * pointer-to-member, the newly-created object will be empty. * * If @a f is a non-NULL function pointer or an object of type @c * reference_wrapper, this function will not throw. */ template function(_Functor __f, typename __gnu_cxx::__enable_if::value, _Useless>::__type = _Useless()); /** * @brief %Function assignment operator. * @param x A %function with identical call signature. * @post @c (bool)*this == (bool)x * @returns @c *this * * The target of @a x is copied to @c *this. If @a x has no * target, then @c *this will be empty. * * If @a x targets a function pointer or a reference to a function * object, then this operation will not throw an exception. */ function& operator=(const function& __x) { function(__x).swap(*this); return *this; } /** * @brief %Function assignment to zero. * @post @c !(bool)*this * @returns @c *this * * The target of @a *this is deallocated, leaving it empty. */ function& operator=(_M_clear_type*) { if (_M_manager) { _M_manager(_M_functor, _M_functor, __destroy_functor); _M_manager = 0; _M_invoker = 0; } return *this; } /** * @brief %Function assignment to a new target. * @param f A %function object that is callable with parameters of * type @c T1, @c T2, ..., @c TN and returns a value convertible * to @c Res. * @return @c *this * * This %function object wrapper will target a copy of @a * f. If @a f is @c reference_wrapper, then this function * object will contain a reference to the function object @c * f.get(). If @a f is a NULL function pointer or NULL * pointer-to-member, @c this object will be empty. * * If @a f is a non-NULL function pointer or an object of type @c * reference_wrapper, this function will not throw. */ template typename __gnu_cxx::__enable_if::value, function&>::__type operator=(_Functor __f) { function(__f).swap(*this); return *this; } // [3.7.2.2] function modifiers /** * @brief Swap the targets of two %function objects. * @param f A %function with identical call signature. * * Swap the targets of @c this function object and @a f. This * function will not throw an exception. */ void swap(function& __x) { _Any_data __old_functor = _M_functor; _M_functor = __x._M_functor; __x._M_functor = __old_functor; _Manager_type __old_manager = _M_manager; _M_manager = __x._M_manager; __x._M_manager = __old_manager; _Invoker_type __old_invoker = _M_invoker; _M_invoker = __x._M_invoker; __x._M_invoker = __old_invoker; } // [3.7.2.3] function capacity /** * @brief Determine if the %function wrapper has a target. * * @return @c true when this %function object contains a target, * or @c false when it is empty. * * This function will not throw an exception. */ operator _Safe_bool() const { if (_M_empty()) { return 0; } else { return &_Hidden_type::_M_bool; } } // [3.7.2.4] function invocation /** * @brief Invokes the function targeted by @c *this. * @returns the result of the target. * @throws bad_function_call when @c !(bool)*this * * The function call operator invokes the target function object * stored by @c this. */ _Res operator()(_GLIBCXX_PARAMS) const; // [3.7.2.5] function target access /** * @brief Determine the type of the target of this function object * wrapper. * * @returns the type identifier of the target function object, or * @c typeid(void) if @c !(bool)*this. * * This function will not throw an exception. */ const type_info& target_type() const; /** * @brief Access the stored target function object. * * @return Returns a pointer to the stored target function object, * if @c typeid(Functor).equals(target_type()); otherwise, a NULL * pointer. * * This function will not throw an exception. */ template _Functor* target(); /** * @overload */ template const _Functor* target() const; private: // [3.7.2.6] undefined operators template void operator==(const function<_Function>&) const; template void operator!=(const function<_Function>&) const; typedef _Res (*_Invoker_type)(const _Any_data& _GLIBCXX_COMMA _GLIBCXX_PARAMS); _Invoker_type _M_invoker; }; template function<_Res(_GLIBCXX_TEMPLATE_ARGS)>::function(const function& __x) : _Function_base() { if (__x) { _M_invoker = __x._M_invoker; _M_manager = __x._M_manager; __x._M_manager(_M_functor, __x._M_functor, __clone_functor); } } template template function<_Res(_GLIBCXX_TEMPLATE_ARGS)> ::function(_Functor __f, typename __gnu_cxx::__enable_if::value, _Useless>::__type) : _Function_base() { typedef _Function_handler<_Signature_type, _Functor> _My_handler; if (_My_handler::_M_not_empty_function(__f)) { _M_invoker = &_My_handler::_M_invoke; _M_manager = &_My_handler::_M_manager; _My_handler::_M_init_functor(_M_functor, __f); } } template _Res function<_Res(_GLIBCXX_TEMPLATE_ARGS)>::operator()(_GLIBCXX_PARAMS) const { if (_M_empty()) { #if __EXCEPTIONS throw bad_function_call(); #else std::abort(); #endif } return _M_invoker(_M_functor _GLIBCXX_COMMA _GLIBCXX_ARGS); } template const type_info& function<_Res(_GLIBCXX_TEMPLATE_ARGS)>::target_type() const { if (_M_manager) { _Any_data __typeinfo_result; _M_manager(__typeinfo_result, _M_functor, __get_type_info); return *__typeinfo_result._M_access(); } else { return typeid(void); } } template template _Functor* function<_Res(_GLIBCXX_TEMPLATE_ARGS)>::target() { if (typeid(_Functor) == target_type() && _M_manager) { _Any_data __ptr; if (_M_manager(__ptr, _M_functor, __get_functor_ptr) && !is_const<_Functor>::value) return 0; else return __ptr._M_access<_Functor*>(); } else { return 0; } } template template const _Functor* function<_Res(_GLIBCXX_TEMPLATE_ARGS)>::target() const { if (typeid(_Functor) == target_type() && _M_manager) { _Any_data __ptr; _M_manager(__ptr, _M_functor, __get_functor_ptr); return __ptr._M_access(); } else { return 0; } } _GLIBCXX_END_NAMESPACE }