// functional standard header #ifndef _FUNCTIONAL_ #define _FUNCTIONAL_ #include #ifdef _MSC_VER #pragma pack(push,8) #endif /* _MSC_VER */ _STD_BEGIN // TEMPLATE STRUCT unary_function template struct unary_function { typedef _A argument_type; typedef _R result_type; }; // TEMPLATE STRUCT binary_function template struct binary_function { typedef _A1 first_argument_type; typedef _A2 second_argument_type; typedef _R result_type; }; // TEMPLATE STRUCT plus template struct plus : binary_function<_Ty, _Ty, _Ty> { _Ty operator()(const _Ty& _X, const _Ty& _Y) const {return (_X + _Y); } }; // TEMPLATE STRUCT minus template struct minus : binary_function<_Ty, _Ty, _Ty> { _Ty operator()(const _Ty& _X, const _Ty& _Y) const {return (_X - _Y); } }; // TEMPLATE STRUCT multiplies template struct multiplies : binary_function<_Ty, _Ty, _Ty> { _Ty operator()(const _Ty& _X, const _Ty& _Y) const {return (_X * _Y); } }; // TEMPLATE STRUCT divides template struct divides : binary_function<_Ty, _Ty, _Ty> { _Ty operator()(const _Ty& _X, const _Ty& _Y) const {return (_X / _Y); } }; // TEMPLATE STRUCT modulus template struct modulus : binary_function<_Ty, _Ty, _Ty> { _Ty operator()(const _Ty& _X, const _Ty& _Y) const {return (_X % _Y); } }; // TEMPLATE STRUCT negate template struct negate : unary_function<_Ty, _Ty> { _Ty operator()(const _Ty& _X) const {return (-_X); } }; // TEMPLATE STRUCT equal_to template struct equal_to : binary_function<_Ty, _Ty, bool> { bool operator()(const _Ty& _X, const _Ty& _Y) const {return (_X == _Y); } }; // TEMPLATE STRUCT not_equal_to template struct not_equal_to : binary_function<_Ty, _Ty, bool> { bool operator()(const _Ty& _X, const _Ty& _Y) const {return (_X != _Y); } }; // TEMPLATE STRUCT greater template struct greater : binary_function<_Ty, _Ty, bool> { bool operator()(const _Ty& _X, const _Ty& _Y) const {return (_X > _Y); } }; // TEMPLATE STRUCT less template struct less : binary_function<_Ty, _Ty, bool> { bool operator()(const _Ty& _X, const _Ty& _Y) const {return (_X < _Y); } }; // TEMPLATE STRUCT greater_equal template struct greater_equal : binary_function<_Ty, _Ty, bool> { bool operator()(const _Ty& _X, const _Ty& _Y) const {return (_X >= _Y); } }; // TEMPLATE STRUCT less_equal template struct less_equal : binary_function<_Ty, _Ty, bool> { bool operator()(const _Ty& _X, const _Ty& _Y) const {return (_X <= _Y); } }; // TEMPLATE STRUCT logical_and template struct logical_and : binary_function<_Ty, _Ty, bool> { bool operator()(const _Ty& _X, const _Ty& _Y) const {return (_X && _Y); } }; // TEMPLATE STRUCT logical_or template struct logical_or : binary_function<_Ty, _Ty, bool> { bool operator()(const _Ty& _X, const _Ty& _Y) const {return (_X || _Y); } }; // TEMPLATE STRUCT logical_not template struct logical_not : unary_function<_Ty, bool> { bool operator()(const _Ty& _X) const {return (!_X); } }; // TEMPLATE CLASS unary_negate template class unary_negate : public unary_function<_Ufn::argument_type, bool> { public: explicit unary_negate(const _Ufn& _X) : _Fn(_X) {} bool operator()(const _Ufn::argument_type& _X) const {return (!_Fn(_X)); } protected: _Ufn _Fn; }; // TEMPLATE FUNCTION not1 template inline unary_negate<_Ufn> not1(const _Ufn& _X) {return (unary_negate<_Ufn>(_X)); } // TEMPLATE CLASS binary_negate template class binary_negate : public binary_function<_Bfn::first_argument_type, _Bfn::second_argument_type, bool> { public: explicit binary_negate(const _Bfn& _X) : _Fn(_X) {} bool operator()(const _Bfn::first_argument_type& _X, const _Bfn::second_argument_type& _Y) const {return (!_Fn(_X, _Y)); } protected: _Bfn _Fn; }; // TEMPLATE FUNCTION not2 template inline binary_negate<_Bfn> not2(const _Bfn& _X) {return (binary_negate<_Bfn>(_X)); } // TEMPLATE CLASS binder1st template class binder1st : public unary_function<_Bfn::second_argument_type, _Bfn::result_type> { public: binder1st(const _Bfn& _X, const _Bfn::first_argument_type& _Y) : op(_X), value(_Y) {} result_type operator()(const argument_type& _X) const {return (op(value, _X)); } protected: _Bfn op; _Bfn::first_argument_type value; }; // TEMPLATE FUNCTION bind1st template inline binder1st<_Bfn> bind1st(const _Bfn& _X, const _Ty& _Y) {return (binder1st<_Bfn>(_X, _Bfn::first_argument_type(_Y))); } // TEMPLATE CLASS binder2nd template class binder2nd : public unary_function<_Bfn::first_argument_type, _Bfn::result_type> { public: binder2nd(const _Bfn& _X, const _Bfn::second_argument_type& _Y) : op(_X), value(_Y) {} result_type operator()(const argument_type& _X) const {return (op(_X, value)); } protected: _Bfn op; _Bfn::second_argument_type value; }; // TEMPLATE FUNCTION bind2nd template inline binder2nd<_Bfn> bind2nd(const _Bfn& _X, const _Ty& _Y) {return (binder2nd<_Bfn>(_X, _Bfn::second_argument_type(_Y))); } // TEMPLATE CLASS pointer_to_unary_function template class pointer_to_unary_function : public unary_function<_A, _R> { public: explicit pointer_to_unary_function(_R (__cdecl *_X)(_A)) : _Fn(_X) {} _R operator()(_A _X) const {return (_Fn(_X)); } protected: _R (__cdecl *_Fn)(_A); }; // TEMPLATE CLASS pointer_to_binary_function template class pointer_to_binary_function : public binary_function<_A1, _A2, _R> { public: explicit pointer_to_binary_function( _R (__cdecl *_X)(_A1, _A2)) : _Fn(_X) {} _R operator()(_A1 _X, _A2 _Y) const {return (_Fn(_X, _Y)); } protected: _R (__cdecl *_Fn)(_A1, _A2); }; // TEMPLATE FUNCTION ptr_fun template inline pointer_to_unary_function<_A, _R> ptr_fun(_R (__cdecl *_X)(_A)) {return (pointer_to_unary_function<_A, _R>(_X)); } template inline pointer_to_binary_function<_A1, _A2, _R> ptr_fun(_R (__cdecl *_X)(_A1, _A2)) {return (pointer_to_binary_function<_A1, _A2, _R>(_X)); } // TEMPLATE CLASS mem_fun_t template class mem_fun_t : public unary_function<_Ty *, _R> { public: explicit mem_fun_t(_R (_Ty::*_Pm)()) : _Ptr(_Pm) {} _R operator()(_Ty *_P) const {return ((_P->*_Ptr)()); } private: _R (_Ty::*_Ptr)(); }; // TEMPLATE FUNCTION mem_fun template inline mem_fun_t<_R, _Ty> mem_fun(_R (_Ty::*_Pm)()) {return (mem_fun_t<_R, _Ty>(_Pm)); } // TEMPLATE CLASS mem_fun1_t template class mem_fun1_t : public binary_function<_Ty *, _A, _R> { public: explicit mem_fun1_t(_R (_Ty::*_Pm)(_A)) : _Ptr(_Pm) {} _R operator()(_Ty *_P, _A _Arg) const {return ((_P->*_Ptr)(_Arg)); } private: _R (_Ty::*_Ptr)(_A); }; // TEMPLATE FUNCTION mem_fun1 template inline mem_fun1_t<_R, _Ty, _A> mem_fun1(_R (_Ty::*_Pm)(_A)) {return (mem_fun1_t<_R, _Ty, _A>(_Pm)); } // TEMPLATE CLASS mem_fun_ref_t template class mem_fun_ref_t : public unary_function<_Ty, _R> { public: explicit mem_fun_ref_t(_R (_Ty::*_Pm)()) : _Ptr(_Pm) {} _R operator()(_Ty& _X) const {return ((_X.*_Ptr)()); } private: _R (_Ty::*_Ptr)(); }; // TEMPLATE FUNCTION mem_fun_ref template inline mem_fun_ref_t<_R, _Ty> mem_fun_ref(_R (_Ty::*_Pm)()) {return (mem_fun_ref_t<_R, _Ty>(_Pm)); } // TEMPLATE CLASS mem_fun1_ref_t template class mem_fun1_ref_t : public binary_function<_Ty *, _A, _R> { public: explicit mem_fun1_ref_t(_R (_Ty::*_Pm)(_A)) : _Ptr(_Pm) {} _R operator()(_Ty& _X, _A _Arg) const {return ((_X.*_Ptr)(_Arg)); } private: _R (_Ty::*_Ptr)(_A); }; // TEMPLATE FUNCTION mem_fun1_ref template inline mem_fun1_ref_t<_R, _Ty, _A> mem_fun1_ref(_R (_Ty::*_Pm)(_A)) {return (mem_fun1_ref_t<_R, _Ty, _A>(_Pm)); } _STD_END #ifdef _MSC_VER #pragma pack(pop) #endif /* _MSC_VER */ #endif /* _FUNCTIONAL_ */ /* * Copyright (c) 1995 by P.J. Plauger. ALL RIGHTS RESERVED. * Consult your license regarding permissions and restrictions. */ /* * This file is derived from software bearing the following * restrictions: * * Copyright (c) 1994 * Hewlett-Packard Company * * Permission to use, copy, modify, distribute and sell this * software and its documentation for any purpose is hereby * granted without fee, provided that the above copyright notice * appear in all copies and that both that copyright notice and * this permission notice appear in supporting documentation. * Hewlett-Packard Company makes no representations about the * suitability of this software for any purpose. It is provided * "as is" without express or implied warranty. */