ad66df7aa0
* stl_function.h (bind1st, bind2nd): Rename __opr to __oper, as __opr is used internally by egcs. * stl_numeric.h (__power, power): Likewise. * stl_algo.h (transform): Rename __opr to __oper, as __opr is used internally by egcs. Reported by Harri Porten <porten@tu-harburg.de> From-SVN: r34949
701 lines
22 KiB
C++
701 lines
22 KiB
C++
/*
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*
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* Copyright (c) 1994
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* Hewlett-Packard Company
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*
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* Permission to use, copy, modify, distribute and sell this software
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* and its documentation for any purpose is hereby granted without fee,
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* provided that the above copyright notice appear in all copies and
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* that both that copyright notice and this permission notice appear
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* in supporting documentation. Hewlett-Packard Company makes no
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* representations about the suitability of this software for any
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* purpose. It is provided "as is" without express or implied warranty.
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*
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*
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* Copyright (c) 1996-1998
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* Silicon Graphics Computer Systems, Inc.
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*
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* Permission to use, copy, modify, distribute and sell this software
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* and its documentation for any purpose is hereby granted without fee,
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* provided that the above copyright notice appear in all copies and
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* that both that copyright notice and this permission notice appear
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* in supporting documentation. Silicon Graphics makes no
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* representations about the suitability of this software for any
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* purpose. It is provided "as is" without express or implied warranty.
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*/
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/* NOTE: This is an internal header file, included by other STL headers.
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* You should not attempt to use it directly.
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*/
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#ifndef __SGI_STL_INTERNAL_FUNCTION_H
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#define __SGI_STL_INTERNAL_FUNCTION_H
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__STL_BEGIN_NAMESPACE
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template <class _Arg, class _Result>
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struct unary_function {
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typedef _Arg argument_type;
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typedef _Result result_type;
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};
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template <class _Arg1, class _Arg2, class _Result>
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struct binary_function {
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typedef _Arg1 first_argument_type;
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typedef _Arg2 second_argument_type;
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typedef _Result result_type;
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};
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template <class _Tp>
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struct plus : public binary_function<_Tp,_Tp,_Tp> {
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_Tp operator()(const _Tp& __x, const _Tp& __y) const { return __x + __y; }
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};
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template <class _Tp>
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struct minus : public binary_function<_Tp,_Tp,_Tp> {
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_Tp operator()(const _Tp& __x, const _Tp& __y) const { return __x - __y; }
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};
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template <class _Tp>
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struct multiplies : public binary_function<_Tp,_Tp,_Tp> {
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_Tp operator()(const _Tp& __x, const _Tp& __y) const { return __x * __y; }
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};
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template <class _Tp>
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struct divides : public binary_function<_Tp,_Tp,_Tp> {
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_Tp operator()(const _Tp& __x, const _Tp& __y) const { return __x / __y; }
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};
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// identity_element (not part of the C++ standard).
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template <class _Tp> inline _Tp identity_element(plus<_Tp>) {
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return _Tp(0);
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}
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template <class _Tp> inline _Tp identity_element(multiplies<_Tp>) {
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return _Tp(1);
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}
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template <class _Tp>
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struct modulus : public binary_function<_Tp,_Tp,_Tp>
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{
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_Tp operator()(const _Tp& __x, const _Tp& __y) const { return __x % __y; }
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};
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template <class _Tp>
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struct negate : public unary_function<_Tp,_Tp>
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{
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_Tp operator()(const _Tp& __x) const { return -__x; }
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};
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template <class _Tp>
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struct equal_to : public binary_function<_Tp,_Tp,bool>
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{
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bool operator()(const _Tp& __x, const _Tp& __y) const { return __x == __y; }
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};
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template <class _Tp>
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struct not_equal_to : public binary_function<_Tp,_Tp,bool>
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{
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bool operator()(const _Tp& __x, const _Tp& __y) const { return __x != __y; }
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};
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template <class _Tp>
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struct greater : public binary_function<_Tp,_Tp,bool>
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{
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bool operator()(const _Tp& __x, const _Tp& __y) const { return __x > __y; }
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};
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template <class _Tp>
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struct less : public binary_function<_Tp,_Tp,bool>
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{
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bool operator()(const _Tp& __x, const _Tp& __y) const { return __x < __y; }
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};
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template <class _Tp>
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struct greater_equal : public binary_function<_Tp,_Tp,bool>
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{
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bool operator()(const _Tp& __x, const _Tp& __y) const { return __x >= __y; }
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};
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template <class _Tp>
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struct less_equal : public binary_function<_Tp,_Tp,bool>
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{
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bool operator()(const _Tp& __x, const _Tp& __y) const { return __x <= __y; }
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};
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template <class _Tp>
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struct logical_and : public binary_function<_Tp,_Tp,bool>
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{
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bool operator()(const _Tp& __x, const _Tp& __y) const { return __x && __y; }
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};
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template <class _Tp>
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struct logical_or : public binary_function<_Tp,_Tp,bool>
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{
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bool operator()(const _Tp& __x, const _Tp& __y) const { return __x || __y; }
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};
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template <class _Tp>
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struct logical_not : public unary_function<_Tp,bool>
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{
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bool operator()(const _Tp& __x) const { return !__x; }
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};
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template <class _Predicate>
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class unary_negate
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: public unary_function<typename _Predicate::argument_type, bool> {
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protected:
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_Predicate _M_pred;
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public:
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explicit unary_negate(const _Predicate& __x) : _M_pred(__x) {}
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bool operator()(const typename _Predicate::argument_type& __x) const {
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return !_M_pred(__x);
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}
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};
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template <class _Predicate>
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inline unary_negate<_Predicate>
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not1(const _Predicate& __pred)
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{
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return unary_negate<_Predicate>(__pred);
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}
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template <class _Predicate>
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class binary_negate
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: public binary_function<typename _Predicate::first_argument_type,
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typename _Predicate::second_argument_type,
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bool> {
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protected:
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_Predicate _M_pred;
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public:
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explicit binary_negate(const _Predicate& __x) : _M_pred(__x) {}
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bool operator()(const typename _Predicate::first_argument_type& __x,
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const typename _Predicate::second_argument_type& __y) const
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{
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return !_M_pred(__x, __y);
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}
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};
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template <class _Predicate>
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inline binary_negate<_Predicate>
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not2(const _Predicate& __pred)
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{
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return binary_negate<_Predicate>(__pred);
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}
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template <class _Operation>
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class binder1st
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: public unary_function<typename _Operation::second_argument_type,
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typename _Operation::result_type> {
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protected:
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_Operation op;
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typename _Operation::first_argument_type value;
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public:
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binder1st(const _Operation& __x,
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const typename _Operation::first_argument_type& __y)
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: op(__x), value(__y) {}
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typename _Operation::result_type
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operator()(const typename _Operation::second_argument_type& __x) const {
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return op(value, __x);
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}
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};
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template <class _Operation, class _Tp>
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inline binder1st<_Operation>
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bind1st(const _Operation& __oper, const _Tp& __x)
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{
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typedef typename _Operation::first_argument_type _Arg1_type;
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return binder1st<_Operation>(__oper, _Arg1_type(__x));
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}
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template <class _Operation>
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class binder2nd
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: public unary_function<typename _Operation::first_argument_type,
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typename _Operation::result_type> {
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protected:
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_Operation op;
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typename _Operation::second_argument_type value;
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public:
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binder2nd(const _Operation& __x,
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const typename _Operation::second_argument_type& __y)
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: op(__x), value(__y) {}
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typename _Operation::result_type
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operator()(const typename _Operation::first_argument_type& __x) const {
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return op(__x, value);
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}
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};
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template <class _Operation, class _Tp>
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inline binder2nd<_Operation>
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bind2nd(const _Operation& __oper, const _Tp& __x)
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{
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typedef typename _Operation::second_argument_type _Arg2_type;
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return binder2nd<_Operation>(__oper, _Arg2_type(__x));
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}
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// unary_compose and binary_compose (extensions, not part of the standard).
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template <class _Operation1, class _Operation2>
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class unary_compose
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: public unary_function<typename _Operation2::argument_type,
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typename _Operation1::result_type>
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{
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protected:
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_Operation1 __op1;
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_Operation2 __op2;
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public:
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unary_compose(const _Operation1& __x, const _Operation2& __y)
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: __op1(__x), __op2(__y) {}
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typename _Operation1::result_type
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operator()(const typename _Operation2::argument_type& __x) const {
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return __op1(__op2(__x));
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}
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};
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template <class _Operation1, class _Operation2>
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inline unary_compose<_Operation1,_Operation2>
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compose1(const _Operation1& __op1, const _Operation2& __op2)
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{
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return unary_compose<_Operation1,_Operation2>(__op1, __op2);
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}
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template <class _Operation1, class _Operation2, class _Operation3>
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class binary_compose
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: public unary_function<typename _Operation2::argument_type,
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typename _Operation1::result_type> {
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protected:
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_Operation1 _M_op1;
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_Operation2 _M_op2;
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_Operation3 _M_op3;
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public:
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binary_compose(const _Operation1& __x, const _Operation2& __y,
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const _Operation3& __z)
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: _M_op1(__x), _M_op2(__y), _M_op3(__z) { }
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typename _Operation1::result_type
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operator()(const typename _Operation2::argument_type& __x) const {
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return _M_op1(_M_op2(__x), _M_op3(__x));
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}
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};
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template <class _Operation1, class _Operation2, class _Operation3>
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inline binary_compose<_Operation1, _Operation2, _Operation3>
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compose2(const _Operation1& __op1, const _Operation2& __op2,
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const _Operation3& __op3)
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{
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return binary_compose<_Operation1,_Operation2,_Operation3>
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(__op1, __op2, __op3);
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}
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template <class _Arg, class _Result>
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class pointer_to_unary_function : public unary_function<_Arg, _Result> {
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protected:
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_Result (*_M_ptr)(_Arg);
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public:
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pointer_to_unary_function() {}
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explicit pointer_to_unary_function(_Result (*__x)(_Arg)) : _M_ptr(__x) {}
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_Result operator()(_Arg __x) const { return _M_ptr(__x); }
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};
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template <class _Arg, class _Result>
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inline pointer_to_unary_function<_Arg, _Result> ptr_fun(_Result (*__x)(_Arg))
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{
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return pointer_to_unary_function<_Arg, _Result>(__x);
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}
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template <class _Arg1, class _Arg2, class _Result>
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class pointer_to_binary_function :
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public binary_function<_Arg1,_Arg2,_Result> {
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protected:
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_Result (*_M_ptr)(_Arg1, _Arg2);
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public:
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pointer_to_binary_function() {}
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explicit pointer_to_binary_function(_Result (*__x)(_Arg1, _Arg2))
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: _M_ptr(__x) {}
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_Result operator()(_Arg1 __x, _Arg2 __y) const {
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return _M_ptr(__x, __y);
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}
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};
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template <class _Arg1, class _Arg2, class _Result>
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inline pointer_to_binary_function<_Arg1,_Arg2,_Result>
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ptr_fun(_Result (*__x)(_Arg1, _Arg2)) {
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return pointer_to_binary_function<_Arg1,_Arg2,_Result>(__x);
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}
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// identity is an extensions: it is not part of the standard.
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template <class _Tp>
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struct _Identity : public unary_function<_Tp,_Tp> {
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const _Tp& operator()(const _Tp& __x) const { return __x; }
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};
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template <class _Tp> struct identity : public _Identity<_Tp> {};
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// select1st and select2nd are extensions: they are not part of the standard.
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template <class _Pair>
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struct _Select1st : public unary_function<_Pair, typename _Pair::first_type> {
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const typename _Pair::first_type& operator()(const _Pair& __x) const {
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return __x.first;
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}
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};
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template <class _Pair>
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struct _Select2nd : public unary_function<_Pair, typename _Pair::second_type>
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{
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const typename _Pair::second_type& operator()(const _Pair& __x) const {
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return __x.second;
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}
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};
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template <class _Pair> struct select1st : public _Select1st<_Pair> {};
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template <class _Pair> struct select2nd : public _Select2nd<_Pair> {};
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// project1st and project2nd are extensions: they are not part of the standard
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template <class _Arg1, class _Arg2>
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struct _Project1st : public binary_function<_Arg1, _Arg2, _Arg1> {
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_Arg1 operator()(const _Arg1& __x, const _Arg2&) const { return __x; }
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};
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template <class _Arg1, class _Arg2>
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struct _Project2nd : public binary_function<_Arg1, _Arg2, _Arg2> {
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_Arg2 operator()(const _Arg1&, const _Arg2& __y) const { return __y; }
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};
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template <class _Arg1, class _Arg2>
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struct project1st : public _Project1st<_Arg1, _Arg2> {};
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template <class _Arg1, class _Arg2>
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struct project2nd : public _Project2nd<_Arg1, _Arg2> {};
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// constant_void_fun, constant_unary_fun, and constant_binary_fun are
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// extensions: they are not part of the standard. (The same, of course,
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// is true of the helper functions constant0, constant1, and constant2.)
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template <class _Result>
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struct constant_void_fun
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{
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typedef _Result result_type;
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result_type __val;
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constant_void_fun(const result_type& __v) : __val(__v) {}
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const result_type& operator()() const { return __val; }
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};
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#ifndef __STL_LIMITED_DEFAULT_TEMPLATES
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template <class _Result, class _Argument = _Result>
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#else
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template <class _Result, class _Argument>
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#endif
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struct constant_unary_fun : public unary_function<_Argument, _Result> {
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_Result _M_val;
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constant_unary_fun(const _Result& __v) : _M_val(__v) {}
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const _Result& operator()(const _Argument&) const { return _M_val; }
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};
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#ifndef __STL_LIMITED_DEFAULT_TEMPLATES
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template <class _Result, class _Arg1 = _Result, class _Arg2 = _Arg1>
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#else
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template <class _Result, class _Arg1, class _Arg2>
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#endif
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struct constant_binary_fun : public binary_function<_Arg1, _Arg2, _Result> {
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_Result _M_val;
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constant_binary_fun(const _Result& __v) : _M_val(__v) {}
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const _Result& operator()(const _Arg1&, const _Arg2&) const {
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return _M_val;
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}
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};
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template <class _Result>
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inline constant_void_fun<_Result> constant0(const _Result& __val)
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{
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return constant_void_fun<_Result>(__val);
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}
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template <class _Result>
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inline constant_unary_fun<_Result,_Result> constant1(const _Result& __val)
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{
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return constant_unary_fun<_Result,_Result>(__val);
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}
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template <class _Result>
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inline constant_binary_fun<_Result,_Result,_Result>
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constant2(const _Result& __val)
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{
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return constant_binary_fun<_Result,_Result,_Result>(__val);
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}
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// subtractive_rng is an extension: it is not part of the standard.
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// Note: this code assumes that int is 32 bits.
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class subtractive_rng : public unary_function<unsigned int, unsigned int> {
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private:
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unsigned int _M_table[55];
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size_t _M_index1;
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size_t _M_index2;
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public:
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unsigned int operator()(unsigned int __limit) {
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_M_index1 = (_M_index1 + 1) % 55;
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_M_index2 = (_M_index2 + 1) % 55;
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_M_table[_M_index1] = _M_table[_M_index1] - _M_table[_M_index2];
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return _M_table[_M_index1] % __limit;
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}
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void _M_initialize(unsigned int __seed)
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{
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unsigned int __k = 1;
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_M_table[54] = __seed;
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size_t __i;
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for (__i = 0; __i < 54; __i++) {
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size_t __ii = (21 * (__i + 1) % 55) - 1;
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_M_table[__ii] = __k;
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__k = __seed - __k;
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__seed = _M_table[__ii];
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}
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for (int __loop = 0; __loop < 4; __loop++) {
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for (__i = 0; __i < 55; __i++)
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_M_table[__i] = _M_table[__i] - _M_table[(1 + __i + 30) % 55];
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}
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_M_index1 = 0;
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_M_index2 = 31;
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}
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subtractive_rng(unsigned int __seed) { _M_initialize(__seed); }
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subtractive_rng() { _M_initialize(161803398u); }
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};
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// Adaptor function objects: pointers to member functions.
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// There are a total of 16 = 2^4 function objects in this family.
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// (1) Member functions taking no arguments vs member functions taking
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// one argument.
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// (2) Call through pointer vs call through reference.
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// (3) Member function with void return type vs member function with
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// non-void return type.
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// (4) Const vs non-const member function.
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// Note that choice (3) is nothing more than a workaround: according
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// to the draft, compilers should handle void and non-void the same way.
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// This feature is not yet widely implemented, though. You can only use
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// member functions returning void if your compiler supports partial
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// specialization.
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// All of this complexity is in the function objects themselves. You can
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// ignore it by using the helper function mem_fun and mem_fun_ref,
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// which create whichever type of adaptor is appropriate.
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// (mem_fun1 and mem_fun1_ref are no longer part of the C++ standard,
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// but they are provided for backward compatibility.)
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template <class _Ret, class _Tp>
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class mem_fun_t : public unary_function<_Tp*,_Ret> {
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public:
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explicit mem_fun_t(_Ret (_Tp::*__pf)()) : _M_f(__pf) {}
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_Ret operator()(_Tp* __p) const { return (__p->*_M_f)(); }
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private:
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_Ret (_Tp::*_M_f)();
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};
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template <class _Ret, class _Tp>
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class const_mem_fun_t : public unary_function<const _Tp*,_Ret> {
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public:
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explicit const_mem_fun_t(_Ret (_Tp::*__pf)() const) : _M_f(__pf) {}
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_Ret operator()(const _Tp* __p) const { return (__p->*_M_f)(); }
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private:
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_Ret (_Tp::*_M_f)() const;
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};
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template <class _Ret, class _Tp>
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class mem_fun_ref_t : public unary_function<_Tp,_Ret> {
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public:
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explicit mem_fun_ref_t(_Ret (_Tp::*__pf)()) : _M_f(__pf) {}
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_Ret operator()(_Tp& __r) const { return (__r.*_M_f)(); }
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private:
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_Ret (_Tp::*_M_f)();
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};
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template <class _Ret, class _Tp>
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class const_mem_fun_ref_t : public unary_function<_Tp,_Ret> {
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public:
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explicit const_mem_fun_ref_t(_Ret (_Tp::*__pf)() const) : _M_f(__pf) {}
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_Ret operator()(const _Tp& __r) const { return (__r.*_M_f)(); }
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private:
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_Ret (_Tp::*_M_f)() const;
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};
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template <class _Ret, class _Tp, class _Arg>
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class mem_fun1_t : public binary_function<_Tp*,_Arg,_Ret> {
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public:
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explicit mem_fun1_t(_Ret (_Tp::*__pf)(_Arg)) : _M_f(__pf) {}
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_Ret operator()(_Tp* __p, _Arg __x) const { return (__p->*_M_f)(__x); }
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private:
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_Ret (_Tp::*_M_f)(_Arg);
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};
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template <class _Ret, class _Tp, class _Arg>
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class const_mem_fun1_t : public binary_function<const _Tp*,_Arg,_Ret> {
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public:
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explicit const_mem_fun1_t(_Ret (_Tp::*__pf)(_Arg) const) : _M_f(__pf) {}
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_Ret operator()(const _Tp* __p, _Arg __x) const
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{ return (__p->*_M_f)(__x); }
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private:
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_Ret (_Tp::*_M_f)(_Arg) const;
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};
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template <class _Ret, class _Tp, class _Arg>
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class mem_fun1_ref_t : public binary_function<_Tp,_Arg,_Ret> {
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public:
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explicit mem_fun1_ref_t(_Ret (_Tp::*__pf)(_Arg)) : _M_f(__pf) {}
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_Ret operator()(_Tp& __r, _Arg __x) const { return (__r.*_M_f)(__x); }
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private:
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_Ret (_Tp::*_M_f)(_Arg);
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};
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template <class _Ret, class _Tp, class _Arg>
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class const_mem_fun1_ref_t : public binary_function<_Tp,_Arg,_Ret> {
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public:
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explicit const_mem_fun1_ref_t(_Ret (_Tp::*__pf)(_Arg) const) : _M_f(__pf) {}
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_Ret operator()(const _Tp& __r, _Arg __x) const { return (__r.*_M_f)(__x); }
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private:
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_Ret (_Tp::*_M_f)(_Arg) const;
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};
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#ifdef __STL_CLASS_PARTIAL_SPECIALIZATION
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template <class _Tp>
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class mem_fun_t<void, _Tp> : public unary_function<_Tp*,void> {
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public:
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explicit mem_fun_t(void (_Tp::*__pf)()) : _M_f(__pf) {}
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void operator()(_Tp* __p) const { (__p->*_M_f)(); }
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private:
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void (_Tp::*_M_f)();
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};
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template <class _Tp>
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class const_mem_fun_t<void, _Tp> : public unary_function<const _Tp*,void> {
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public:
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explicit const_mem_fun_t(void (_Tp::*__pf)() const) : _M_f(__pf) {}
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void operator()(const _Tp* __p) const { (__p->*_M_f)(); }
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private:
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void (_Tp::*_M_f)() const;
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};
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template <class _Tp>
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class mem_fun_ref_t<void, _Tp> : public unary_function<_Tp,void> {
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public:
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explicit mem_fun_ref_t(void (_Tp::*__pf)()) : _M_f(__pf) {}
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void operator()(_Tp& __r) const { (__r.*_M_f)(); }
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private:
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void (_Tp::*_M_f)();
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};
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template <class _Tp>
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class const_mem_fun_ref_t<void, _Tp> : public unary_function<_Tp,void> {
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public:
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explicit const_mem_fun_ref_t(void (_Tp::*__pf)() const) : _M_f(__pf) {}
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void operator()(const _Tp& __r) const { (__r.*_M_f)(); }
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private:
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void (_Tp::*_M_f)() const;
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};
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template <class _Tp, class _Arg>
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class mem_fun1_t<void, _Tp, _Arg> : public binary_function<_Tp*,_Arg,void> {
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public:
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explicit mem_fun1_t(void (_Tp::*__pf)(_Arg)) : _M_f(__pf) {}
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void operator()(_Tp* __p, _Arg __x) const { (__p->*_M_f)(__x); }
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private:
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void (_Tp::*_M_f)(_Arg);
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|
};
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template <class _Tp, class _Arg>
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class const_mem_fun1_t<void, _Tp, _Arg>
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|
: public binary_function<const _Tp*,_Arg,void> {
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public:
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explicit const_mem_fun1_t(void (_Tp::*__pf)(_Arg) const) : _M_f(__pf) {}
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void operator()(const _Tp* __p, _Arg __x) const { (__p->*_M_f)(__x); }
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private:
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|
void (_Tp::*_M_f)(_Arg) const;
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};
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template <class _Tp, class _Arg>
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class mem_fun1_ref_t<void, _Tp, _Arg>
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: public binary_function<_Tp,_Arg,void> {
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public:
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explicit mem_fun1_ref_t(void (_Tp::*__pf)(_Arg)) : _M_f(__pf) {}
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void operator()(_Tp& __r, _Arg __x) const { (__r.*_M_f)(__x); }
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private:
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|
void (_Tp::*_M_f)(_Arg);
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};
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template <class _Tp, class _Arg>
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|
class const_mem_fun1_ref_t<void, _Tp, _Arg>
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|
: public binary_function<_Tp,_Arg,void> {
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public:
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explicit const_mem_fun1_ref_t(void (_Tp::*__pf)(_Arg) const) : _M_f(__pf) {}
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|
void operator()(const _Tp& __r, _Arg __x) const { (__r.*_M_f)(__x); }
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private:
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|
void (_Tp::*_M_f)(_Arg) const;
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|
};
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|
#endif /* __STL_CLASS_PARTIAL_SPECIALIZATION */
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|
|
// Mem_fun adaptor helper functions. There are only two:
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|
// mem_fun and mem_fun_ref. (mem_fun1 and mem_fun1_ref
|
|
// are provided for backward compatibility, but they are no longer
|
|
// part of the C++ standard.)
|
|
|
|
template <class _Ret, class _Tp>
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|
inline mem_fun_t<_Ret,_Tp> mem_fun(_Ret (_Tp::*__f)())
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|
{ return mem_fun_t<_Ret,_Tp>(__f); }
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template <class _Ret, class _Tp>
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|
inline const_mem_fun_t<_Ret,_Tp> mem_fun(_Ret (_Tp::*__f)() const)
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|
{ return const_mem_fun_t<_Ret,_Tp>(__f); }
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|
|
|
template <class _Ret, class _Tp>
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|
inline mem_fun_ref_t<_Ret,_Tp> mem_fun_ref(_Ret (_Tp::*__f)())
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|
{ return mem_fun_ref_t<_Ret,_Tp>(__f); }
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|
|
|
template <class _Ret, class _Tp>
|
|
inline const_mem_fun_ref_t<_Ret,_Tp> mem_fun_ref(_Ret (_Tp::*__f)() const)
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|
{ return const_mem_fun_ref_t<_Ret,_Tp>(__f); }
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|
|
|
template <class _Ret, class _Tp, class _Arg>
|
|
inline mem_fun1_t<_Ret,_Tp,_Arg> mem_fun(_Ret (_Tp::*__f)(_Arg))
|
|
{ return mem_fun1_t<_Ret,_Tp,_Arg>(__f); }
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|
|
|
template <class _Ret, class _Tp, class _Arg>
|
|
inline const_mem_fun1_t<_Ret,_Tp,_Arg> mem_fun(_Ret (_Tp::*__f)(_Arg) const)
|
|
{ return const_mem_fun1_t<_Ret,_Tp,_Arg>(__f); }
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|
|
|
template <class _Ret, class _Tp, class _Arg>
|
|
inline mem_fun1_ref_t<_Ret,_Tp,_Arg> mem_fun_ref(_Ret (_Tp::*__f)(_Arg))
|
|
{ return mem_fun1_ref_t<_Ret,_Tp,_Arg>(__f); }
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|
|
|
template <class _Ret, class _Tp, class _Arg>
|
|
inline const_mem_fun1_ref_t<_Ret,_Tp,_Arg>
|
|
mem_fun_ref(_Ret (_Tp::*__f)(_Arg) const)
|
|
{ return const_mem_fun1_ref_t<_Ret,_Tp,_Arg>(__f); }
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|
|
|
template <class _Ret, class _Tp, class _Arg>
|
|
inline mem_fun1_t<_Ret,_Tp,_Arg> mem_fun1(_Ret (_Tp::*__f)(_Arg))
|
|
{ return mem_fun1_t<_Ret,_Tp,_Arg>(__f); }
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|
|
|
template <class _Ret, class _Tp, class _Arg>
|
|
inline const_mem_fun1_t<_Ret,_Tp,_Arg> mem_fun1(_Ret (_Tp::*__f)(_Arg) const)
|
|
{ return const_mem_fun1_t<_Ret,_Tp,_Arg>(__f); }
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|
|
|
template <class _Ret, class _Tp, class _Arg>
|
|
inline mem_fun1_ref_t<_Ret,_Tp,_Arg> mem_fun1_ref(_Ret (_Tp::*__f)(_Arg))
|
|
{ return mem_fun1_ref_t<_Ret,_Tp,_Arg>(__f); }
|
|
|
|
template <class _Ret, class _Tp, class _Arg>
|
|
inline const_mem_fun1_ref_t<_Ret,_Tp,_Arg>
|
|
mem_fun1_ref(_Ret (_Tp::*__f)(_Arg) const)
|
|
{ return const_mem_fun1_ref_t<_Ret,_Tp,_Arg>(__f); }
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|
|
|
__STL_END_NAMESPACE
|
|
|
|
#endif /* __SGI_STL_INTERNAL_FUNCTION_H */
|
|
|
|
// Local Variables:
|
|
// mode:C++
|
|
// End:
|