[thirdparty/gcc.git] / libstdc++-v3 / include / bits / valarray_before.h

// The template and inlines for the -*- C++ -*- internal _Meta class.

// Copyright (C) 1997, 1998, 1999, 2000, 2001, 2002, 2003 Free Software Foundation, Inc.
//
// This file is part of the GNU ISO C++ Library.  This library is free
// software; you can redistribute it and/or modify it under the
// terms of the GNU General Public License as published by the
// Free Software Foundation; either version 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, 59 Temple Place - Suite 330, Boston, MA 02111-1307,
// 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.

// Written by Gabriel Dos Reis <Gabriel.Dos-Reis@cmla.ens-cachan.fr>

/** @file valarray_meta.h
 *  This is an internal header file, included by other library headers.
 *  You should not attempt to use it directly.
 */

#ifndef _VALARRAY_BEFORE_H
#define _VALARRAY_BEFORE_H 1

#pragma GCC system_header

#include <bits/slice_array.h>

namespace std
{
  //
  // Implementing a loosened valarray return value is tricky.
  // First we need to meet 26.3.1/3: we should not add more than
  // two levels of template nesting. Therefore we resort to template
  // template to "flatten" loosened return value types.
  // At some point we use partial specialization to remove one level
  // template nesting due to _Expr<>
  //
  
  // This class is NOT defined. It doesn't need to.
  template<typename _Tp1, typename _Tp2> class _Constant;

  // Implementations of unary functions applied to valarray<>s.
  // I use hard-coded object functions here instead of a generic
  // approach like pointers to function:
  //    1) correctness: some functions take references, others values.
  //       we can't deduce the correct type afterwards.
  //    2) efficiency -- object functions can be easily inlined
  //    3) be Koenig-lookup-friendly

  struct __abs
  {
    template<typename _Tp>
      _Tp operator()(const _Tp& __t) const { return abs(__t); }
  };

  struct __cos
  {
    template<typename _Tp>
      _Tp operator()(const _Tp& __t) const { return cos(__t); }
  };

  struct __acos
  {
    template<typename _Tp>
      _Tp operator()(const _Tp& __t) const { return acos(__t); }
  };

  struct __cosh
  {
    template<typename _Tp>
      _Tp operator()(const _Tp& __t) const { return cosh(__t); }
  };

  struct __sin
  {
    template<typename _Tp>
      _Tp operator()(const _Tp& __t) const { return sin(__t); }
  };

  struct __asin
  {
    template<typename _Tp>
      _Tp operator()(const _Tp& __t) const { return asin(__t); }
  };

  struct __sinh
  {
    template<typename _Tp>
      _Tp operator()(const _Tp& __t) const { return sinh(__t); }
  };

  struct __tan
  {
    template<typename _Tp>
      _Tp operator()(const _Tp& __t) const { return tan(__t); }
  };

  struct __atan
  {
    template<typename _Tp>
      _Tp operator()(const _Tp& __t) const { return atan(__t); }
  };

  struct __tanh
  {
    template<typename _Tp>
      _Tp operator()(const _Tp& __t) const { return tanh(__t); }
  };

  struct __exp
  {
    template<typename _Tp>
      _Tp operator()(const _Tp& __t) const { return exp(__t); }
  };

  struct __log
  {
    template<typename _Tp>
      _Tp operator()(const _Tp& __t) const { return log(__t); }
  };

  struct __log10
  {
    template<typename _Tp>
      _Tp operator()(const _Tp& __t) const { return log10(__t); }
  };

  struct __sqrt
  {
    template<typename _Tp>
      _Tp operator()(const _Tp& __t) const { return sqrt(__t); }
  };

  // In the past, we used to tailor operator applications semantics
  // to the specialization of standard function objects (i.e. plus<>, etc.)
  // That is incorrect.  Therefore we provide our own surrogates.

  struct __unary_plus
  {
    template<typename _Tp>
      _Tp operator()(const _Tp& __t) const { return +__t; }
  };

  struct __negate
  {
    template<typename _Tp>
      _Tp operator()(const _Tp& __t) const { return -__t; }
  };

  struct __bitwise_not
  {
    template<typename _Tp>
      _Tp operator()(const _Tp& __t) const { return ~__t; }
  };

  struct __plus
  {
    template<typename _Tp>
      _Tp operator()(const _Tp& __x, const _Tp& __y) const
      { return __x + __y; }
  };

  struct __minus
  {
    template<typename _Tp>
      _Tp operator()(const _Tp& __x, const _Tp& __y) const
      { return __x - __y; }
  };

  struct __multiplies
  {
    template<typename _Tp>
      _Tp operator()(const _Tp& __x, const _Tp& __y) const
      { return __x * __y; }
  };

  struct __divides
  {
    template<typename _Tp>
      _Tp operator()(const _Tp& __x, const _Tp& __y) const
      { return __x / __y; }
  };

  struct __modulus
  {
    template<typename _Tp>
      _Tp operator()(const _Tp& __x, const _Tp& __y) const
      { return __x % __y; }
  };

  struct __bitwise_xor
  {
    template<typename _Tp>
      _Tp operator()(const _Tp& __x, const _Tp& __y) const
      { return __x ^ __y; }
  };

  struct __bitwise_and
  {
    template<typename _Tp>
      _Tp operator()(const _Tp& __x, const _Tp& __y) const
      { return __x & __y; }
  };

  struct __bitwise_or
  {
    template<typename _Tp>
      _Tp operator()(const _Tp& __x, const _Tp& __y) const
      { return __x | __y; }
  };

  struct __shift_left
  {
    template<typename _Tp>
      _Tp operator()(const _Tp& __x, const _Tp& __y) const
      { return __x << __y; }
  };

  struct __shift_right
  {
    template<typename _Tp>
      _Tp operator()(const _Tp& __x, const _Tp& __y) const
      { return __x >> __y; }
  };

  struct __logical_and
  {
    template<typename _Tp>
      bool operator()(const _Tp& __x, const _Tp& __y) const
      { return __x && __y; }
  };

  struct __logical_or
  {
    template<typename _Tp>
      bool operator()(const _Tp& __x, const _Tp& __y) const
      { return __x || __y; }
  };

  struct __logical_not
  {
    template<typename _Tp>
      bool operator()(const _Tp& __x) const { return !__x; }
  };

  struct __equal_to
  {
    template<typename _Tp>
      bool operator()(const _Tp& __x, const _Tp& __y) const
      { return __x == __y; }
  };

  struct __not_equal_to
  {
    template<typename _Tp>
      bool operator()(const _Tp& __x, const _Tp& __y) const
      { return __x != __y; }
  };

  struct __less
  {
    template<typename _Tp>
      bool operator()(const _Tp& __x, const _Tp& __y) const
      { return __x < __y; }
  };

  struct __greater
  {
    template<typename _Tp>
      bool operator()(const _Tp& __x, const _Tp& __y) const
      { return __x > __y; }
  };

  struct __less_equal
  {
    template<typename _Tp>
      bool operator()(const _Tp& __x, const _Tp& __y) const
      { return __x <= __y; }
  };

  struct __greater_equal
  {
    template<typename _Tp>
      bool operator()(const _Tp& __x, const _Tp& __y) const
      { return __x >= __y; }
  };

  // The few binary functions we miss.
  struct __atan2
  {
    template<typename _Tp>
      _Tp operator()(const _Tp& __x, const _Tp& __y) const
      { return atan2(__x, __y); }
  };

  struct __pow
  {
    template<typename _Tp>
      _Tp operator()(const _Tp& __x, const _Tp& __y) const
      { return pow(__x, __y); }
  };


  // We need these bits in order to recover the return type of
  // some functions/operators now that we're no longer using
  // function templates.
  template<typename, typename _Tp>
    struct __fun
    {
      typedef _Tp result_type;
    };

  // several specializations for relational operators.
  template<typename _Tp>
    struct __fun<__logical_not, _Tp>
    {
      typedef bool result_type;
    };

  template<typename _Tp>
    struct __fun<__logical_and, _Tp>
    {
      typedef bool result_type;
    };

  template<typename _Tp>
    struct __fun<__logical_or, _Tp>
    {
      typedef bool result_type;
    };

  template<typename _Tp>
    struct __fun<__less, _Tp>
    {
      typedef bool result_type;
    };

  template<typename _Tp>
    struct __fun<__greater, _Tp>
    {
      typedef bool result_type;
    };

  template<typename _Tp>
    struct __fun<__less_equal, _Tp>
    {
      typedef bool result_type;
    };

  template<typename _Tp>
    struct __fun<__greater_equal, _Tp>
    {
      typedef bool result_type;
    };

  template<typename _Tp>
    struct __fun<__equal_to, _Tp>
    {
      typedef bool result_type;
    };

  template<typename _Tp>
    struct __fun<__not_equal_to, _Tp>
    {
      typedef bool result_type;
    };

    //
    // Apply function taking a value/const reference closure
    //

  template<typename _Dom, typename _Arg>
    class _FunBase 
    {
    public:
      typedef typename _Dom::value_type value_type;
      
      _FunBase(const _Dom& __e, value_type __f(_Arg))
	: _M_expr(__e), _M_func(__f) {}

      value_type operator[](size_t __i) const
      { return _M_func (_M_expr[__i]); }

      size_t size() const { return _M_expr.size ();}

    private:
        const _Dom& _M_expr;
        value_type (*_M_func)(_Arg);
    };

  template<class _Dom>
    struct _ValFunClos<_Expr,_Dom> : _FunBase<_Dom, typename _Dom::value_type> 
    {
      typedef _FunBase<_Dom, typename _Dom::value_type> _Base;
      typedef typename _Base::value_type value_type;
      typedef value_type _Tp;
    
      _ValFunClos(const _Dom& __e, _Tp __f(_Tp)) : _Base(__e, __f) {}
    };

  template<typename _Tp>
    struct _ValFunClos<_ValArray,_Tp> : _FunBase<valarray<_Tp>, _Tp>
    {
      typedef _FunBase<valarray<_Tp>, _Tp> _Base;
      typedef _Tp value_type;
      
      _ValFunClos(const valarray<_Tp>& __v, _Tp __f(_Tp)) : _Base(__v, __f) {}
    };

  template<class _Dom>
    struct _RefFunClos<_Expr,_Dom> :
        _FunBase<_Dom, const typename _Dom::value_type&> 
    {
      typedef _FunBase<_Dom, const typename _Dom::value_type&> _Base;
      typedef typename _Base::value_type value_type;
      typedef value_type _Tp;
      
      _RefFunClos(const _Dom& __e, _Tp __f(const _Tp&))
	: _Base(__e, __f) {}
    };

  template<typename _Tp>
    struct _RefFunClos<_ValArray,_Tp> : _FunBase<valarray<_Tp>, const _Tp&> 
    {
      typedef _FunBase<valarray<_Tp>, const _Tp&> _Base;
      typedef _Tp value_type;
      
      _RefFunClos(const valarray<_Tp>& __v, _Tp __f(const _Tp&))
	: _Base(__v, __f) {}
    };
    
  //
  // Unary expression closure.
  //

  template<class _Oper, class _Arg>
    class _UnBase
    {
    public:
      typedef typename _Arg::value_type _Vt;
      typedef typename __fun<_Oper, _Vt>::result_type value_type;

      _UnBase(const _Arg& __e) : _M_expr(__e) {}

      value_type operator[](size_t __i) const
      { return _Oper()(_M_expr[__i]); }

      size_t size() const { return _M_expr.size(); }

    private:
      const _Arg& _M_expr;
    };

  template<class _Oper, class _Dom>
    struct _UnClos<_Oper, _Expr, _Dom> :  _UnBase<_Oper, _Dom>
    {
      typedef _Dom _Arg;
      typedef _UnBase<_Oper, _Dom> _Base;
      typedef typename _Base::value_type value_type;
      
      _UnClos(const _Arg& __e) : _Base(__e) {}
    };

  template<class _Oper, typename _Tp>
    struct _UnClos<_Oper, _ValArray, _Tp> : _UnBase<_Oper, valarray<_Tp> > 
    {
      typedef valarray<_Tp> _Arg;
      typedef _UnBase<_Oper, valarray<_Tp> > _Base;
      typedef typename _Base::value_type value_type;
      
      _UnClos(const _Arg& __e) : _Base(__e) {}
    };


  //
  // Binary expression closure.
  //

  template<class _Oper, class _FirstArg, class _SecondArg>
    class _BinBase 
    {
    public:
        typedef typename _FirstArg::value_type _Vt;
        typedef typename __fun<_Oper, _Vt>::result_type value_type;

      _BinBase(const _FirstArg& __e1, const _SecondArg& __e2)
	: _M_expr1(__e1), _M_expr2(__e2) {}
      
      value_type operator[](size_t __i) const
      { return _Oper()(_M_expr1[__i], _M_expr2[__i]); }

      size_t size() const { return _M_expr1.size(); }
        
    private:
      const _FirstArg& _M_expr1;
      const _SecondArg& _M_expr2;
    };


  template<class _Oper, class _Clos>
    class _BinBase2
    {
    public:
      typedef typename _Clos::value_type _Vt;
      typedef typename __fun<_Oper, _Vt>::result_type value_type;

      _BinBase2(const _Clos& __e, const _Vt& __t)
	: _M_expr1(__e), _M_expr2(__t) {}

      value_type operator[](size_t __i) const
      { return _Oper()(_M_expr1[__i], _M_expr2); }

      size_t size() const { return _M_expr1.size(); }

    private:
      const _Clos& _M_expr1;
      const _Vt& _M_expr2;
    };

  template<class _Oper, class _Clos>
    class _BinBase1
    {
    public:
      typedef typename _Clos::value_type _Vt;
      typedef typename __fun<_Oper, _Vt>::result_type value_type;

      _BinBase1(const _Vt& __t, const _Clos& __e)
	: _M_expr1(__t), _M_expr2(__e) {}

      value_type operator[](size_t __i) const
      { return _Oper()(_M_expr1, _M_expr2[__i]); }
      
      size_t size() const { return _M_expr2.size(); }

    private:
      const _Vt& _M_expr1;
      const _Clos& _M_expr2;
    };
    
  template<class _Oper, class _Dom1, class _Dom2>
    struct _BinClos<_Oper, _Expr, _Expr, _Dom1, _Dom2>
        : _BinBase<_Oper,_Dom1,_Dom2> 
    {
      typedef _BinBase<_Oper,_Dom1,_Dom2> _Base;
      typedef typename _Base::value_type value_type;
        
      _BinClos(const _Dom1& __e1, const _Dom2& __e2) : _Base(__e1, __e2) {}
    };

  template<class _Oper, typename _Tp>
    struct _BinClos<_Oper,_ValArray,_ValArray,_Tp,_Tp>
      : _BinBase<_Oper,valarray<_Tp>,valarray<_Tp> > 
    {
      typedef _BinBase<_Oper,valarray<_Tp>,valarray<_Tp> > _Base;
      typedef _Tp value_type;

      _BinClos(const valarray<_Tp>& __v, const valarray<_Tp>& __w)
	: _Base(__v, __w) {}
    };

  template<class _Oper, class _Dom>
    struct _BinClos<_Oper,_Expr,_ValArray,_Dom,typename _Dom::value_type>
      : _BinBase<_Oper,_Dom,valarray<typename _Dom::value_type> > 
    {
      typedef typename _Dom::value_type _Tp;
      typedef _BinBase<_Oper,_Dom,valarray<_Tp> > _Base;
      typedef typename _Base::value_type value_type;
      
      _BinClos(const _Dom& __e1, const valarray<_Tp>& __e2)
	: _Base(__e1, __e2) {}
    };

  template<class _Oper, class _Dom>
    struct  _BinClos<_Oper,_ValArray,_Expr,typename _Dom::value_type,_Dom>
      : _BinBase<_Oper,valarray<typename _Dom::value_type>,_Dom> 
    {
      typedef typename _Dom::value_type _Tp;
      typedef _BinBase<_Oper,valarray<_Tp>,_Dom> _Base;
      typedef typename _Base::value_type value_type;
      
      _BinClos(const valarray<_Tp>& __e1, const _Dom& __e2)
	: _Base(__e1, __e2) {}
    };

  template<class _Oper, class _Dom>
    struct _BinClos<_Oper,_Expr,_Constant,_Dom,typename _Dom::value_type>
      : _BinBase2<_Oper,_Dom> 
    {
      typedef typename _Dom::value_type _Tp;
      typedef _BinBase2<_Oper,_Dom> _Base;
      typedef typename _Base::value_type value_type;
      
      _BinClos(const _Dom& __e1, const _Tp& __e2) : _Base(__e1, __e2) {}
    };

  template<class _Oper, class _Dom>
    struct _BinClos<_Oper,_Constant,_Expr,typename _Dom::value_type,_Dom>
      : _BinBase1<_Oper,_Dom> 
    {
      typedef typename _Dom::value_type _Tp;
      typedef _BinBase1<_Oper,_Dom> _Base;
      typedef typename _Base::value_type value_type;
      
      _BinClos(const _Tp& __e1, const _Dom& __e2) : _Base(__e1, __e2) {}
    };
    
  template<class _Oper, typename _Tp>
    struct _BinClos<_Oper,_ValArray,_Constant,_Tp,_Tp>
      : _BinBase2<_Oper,valarray<_Tp> > 
    {
      typedef _BinBase2<_Oper,valarray<_Tp> > _Base;
      typedef typename _Base::value_type value_type;
      
      _BinClos(const valarray<_Tp>& __v, const _Tp& __t) : _Base(__v, __t) {}
    };

  template<class _Oper, typename _Tp>
    struct _BinClos<_Oper,_Constant,_ValArray,_Tp,_Tp>
      : _BinBase1<_Oper,valarray<_Tp> > 
    {
      typedef _BinBase1<_Oper,valarray<_Tp> > _Base;
      typedef typename _Base::value_type value_type;
      
      _BinClos(const _Tp& __t, const valarray<_Tp>& __v) : _Base(__t, __v) {}
    };
        

    //
    // slice_array closure.
    //
    template<typename _Dom>  class _SBase {
    public:
        typedef typename _Dom::value_type value_type;

        _SBase (const _Dom& __e, const slice& __s)
                : _M_expr (__e), _M_slice (__s) {}
        value_type operator[] (size_t __i) const
        { return _M_expr[_M_slice.start () + __i * _M_slice.stride ()]; }
        size_t size() const { return _M_slice.size (); }

    private:
        const _Dom& _M_expr;
        const slice& _M_slice;
    };

    template<typename _Tp> class _SBase<_Array<_Tp> > {
    public:
        typedef _Tp value_type;

        _SBase (_Array<_Tp> __a, const slice& __s)
                : _M_array (__a._M_data+__s.start()), _M_size (__s.size()),
                  _M_stride (__s.stride()) {}
        value_type operator[] (size_t __i) const
        { return _M_array._M_data[__i * _M_stride]; }
        size_t size() const { return _M_size; }

    private:
        const _Array<_Tp> _M_array;
        const size_t _M_size;
        const size_t _M_stride;
    };

    template<class _Dom> struct  _SClos<_Expr,_Dom> : _SBase<_Dom> {
        typedef _SBase<_Dom> _Base;
        typedef typename _Base::value_type value_type;
        
        _SClos (const _Dom& __e, const slice& __s) : _Base (__e, __s) {}
    };

    template<typename _Tp>
    struct _SClos<_ValArray,_Tp> : _SBase<_Array<_Tp> > {
        typedef  _SBase<_Array<_Tp> > _Base;
        typedef _Tp value_type;

        _SClos (_Array<_Tp> __a, const slice& __s) : _Base (__a, __s) {}
    };

} // std::


#endif /* _CPP_VALARRAY_BEFORE_H */

// Local Variables:
// mode:c++
// End:
Commit	Line	Data
c13bea50 NS	1	// The template and inlines for the -- C++ -- internal _Meta class.
	2
	3	// Copyright (C) 1997, 1998, 1999, 2000, 2001, 2002, 2003 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 2, 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	// You should have received a copy of the GNU General Public License along
	17	// with this library; see the file COPYING. If not, write to the Free
	18	// Software Foundation, 59 Temple Place - Suite 330, Boston, MA 02111-1307,
	19	// USA.
	20
	21	// As a special exception, you may use this file as part of a free software
	22	// library without restriction. Specifically, if other files instantiate
	23	// templates or use macros or inline functions from this file, or you compile
	24	// this file and link it with other files to produce an executable, this
	25	// file does not by itself cause the resulting executable to be covered by
	26	// the GNU General Public License. This exception does not however
	27	// invalidate any other reasons why the executable file might be covered by
	28	// the GNU General Public License.
	29
	30	// Written by Gabriel Dos Reis <Gabriel.Dos-Reis@cmla.ens-cachan.fr>
	31
	32	/** @file valarray_meta.h
	33	* This is an internal header file, included by other library headers.
	34	* You should not attempt to use it directly.
	35	*/
	36
3d7c150e BK	37	#ifndef _VALARRAY_BEFORE_H
3d7c150e BK	38	#define _VALARRAY_BEFORE_H 1
c13bea50 NS	39
	40	#pragma GCC system_header
	41
	42	#include <bits/slice_array.h>
	43
	44	namespace std
	45	{
	46	//
	47	// Implementing a loosened valarray return value is tricky.
	48	// First we need to meet 26.3.1/3: we should not add more than
	49	// two levels of template nesting. Therefore we resort to template
	50	// template to "flatten" loosened return value types.
	51	// At some point we use partial specialization to remove one level
	52	// template nesting due to _Expr<>
	53	//
	54
	55	// This class is NOT defined. It doesn't need to.
	56	template<typename _Tp1, typename _Tp2> class _Constant;
	57
	58	// Implementations of unary functions applied to valarray<>s.
	59	// I use hard-coded object functions here instead of a generic
	60	// approach like pointers to function:
	61	// 1) correctness: some functions take references, others values.
	62	// we can't deduce the correct type afterwards.
	63	// 2) efficiency -- object functions can be easily inlined
	64	// 3) be Koenig-lookup-friendly
	65
	66	struct __abs
	67	{
	68	template<typename _Tp>
	69	_Tp operator()(const _Tp& __t) const { return abs(__t); }
	70	};
	71
	72	struct __cos
	73	{
	74	template<typename _Tp>
	75	_Tp operator()(const _Tp& __t) const { return cos(__t); }
	76	};
	77
	78	struct __acos
	79	{
	80	template<typename _Tp>
	81	_Tp operator()(const _Tp& __t) const { return acos(__t); }
	82	};
	83
	84	struct __cosh
	85	{
	86	template<typename _Tp>
	87	_Tp operator()(const _Tp& __t) const { return cosh(__t); }
	88	};
	89
	90	struct __sin
	91	{
	92	template<typename _Tp>
	93	_Tp operator()(const _Tp& __t) const { return sin(__t); }
	94	};
	95
	96	struct __asin
	97	{
	98	template<typename _Tp>
	99	_Tp operator()(const _Tp& __t) const { return asin(__t); }
	100	};
	101
	102	struct __sinh
103	{
104	template<typename _Tp>
105	_Tp operator()(const _Tp& __t) const { return sinh(__t); }
106	};
107
108	struct __tan
109	{
110	template<typename _Tp>
111	_Tp operator()(const _Tp& __t) const { return tan(__t); }
112	};
113
114	struct __atan
115	{
116	template<typename _Tp>
117	_Tp operator()(const _Tp& __t) const { return atan(__t); }
118	};
119
120	struct __tanh
121	{
122	template<typename _Tp>
123	_Tp operator()(const _Tp& __t) const { return tanh(__t); }
124	};
125
126	struct __exp
127	{
128	template<typename _Tp>
129	_Tp operator()(const _Tp& __t) const { return exp(__t); }
130	};
131
132	struct __log
133	{
134	template<typename _Tp>
135	_Tp operator()(const _Tp& __t) const { return log(__t); }
136	};
137
138	struct __log10
139	{
140	template<typename _Tp>
141	_Tp operator()(const _Tp& __t) const { return log10(__t); }
142	};
143
144	struct __sqrt
145	{
146	template<typename _Tp>
147	_Tp operator()(const _Tp& __t) const { return sqrt(__t); }
148	};
149
150	// In the past, we used to tailor operator applications semantics
151	// to the specialization of standard function objects (i.e. plus<>, etc.)
152	// That is incorrect. Therefore we provide our own surrogates.
153
154	struct __unary_plus
155	{
156	template<typename _Tp>
157	_Tp operator()(const _Tp& __t) const { return +__t; }
158	};
159
160	struct __negate
161	{
162	template<typename _Tp>
163	_Tp operator()(const _Tp& __t) const { return -__t; }
164	};
165
166	struct __bitwise_not
167	{
168	template<typename _Tp>
169	_Tp operator()(const _Tp& __t) const { return ~__t; }
170	};
171
172	struct __plus
173	{
174	template<typename _Tp>
175	_Tp operator()(const _Tp& __x, const _Tp& __y) const
176	{ return __x + __y; }
177	};
178
179	struct __minus
180	{
181	template<typename _Tp>
182	_Tp operator()(const _Tp& __x, const _Tp& __y) const
183	{ return __x - __y; }
184	};
185
186	struct __multiplies
187	{
188	template<typename _Tp>
189	_Tp operator()(const _Tp& __x, const _Tp& __y) const
190	{ return __x * __y; }
191	};
192
193	struct __divides
194	{
195	template<typename _Tp>
196	_Tp operator()(const _Tp& __x, const _Tp& __y) const
197	{ return __x / __y; }
198	};
199
200	struct __modulus
201	{
202	template<typename _Tp>
203	_Tp operator()(const _Tp& __x, const _Tp& __y) const
204	{ return __x % __y; }
205	};
206
207	struct __bitwise_xor
208	{
209	template<typename _Tp>
210	_Tp operator()(const _Tp& __x, const _Tp& __y) const
211	{ return __x ^ __y; }
212	};
213
214	struct __bitwise_and
215	{
216	template<typename _Tp>
217	_Tp operator()(const _Tp& __x, const _Tp& __y) const
218	{ return __x & __y; }
219	};
220
221	struct __bitwise_or
222	{
223	template<typename _Tp>
224	_Tp operator()(const _Tp& __x, const _Tp& __y) const
225	{ return __x \| __y; }
226	};
227
228	struct __shift_left
229	{
230	template<typename _Tp>
231	_Tp operator()(const _Tp& __x, const _Tp& __y) const
232	{ return __x << __y; }
233	};
234
235	struct __shift_right
236	{
237	template<typename _Tp>
238	_Tp operator()(const _Tp& __x, const _Tp& __y) const
239	{ return __x >> __y; }
240	};
241
242	struct __logical_and
243	{
244	template<typename _Tp>
245	bool operator()(const _Tp& __x, const _Tp& __y) const
246	{ return __x && __y; }
247	};
248
249	struct __logical_or
250	{
251	template<typename _Tp>
252	bool operator()(const _Tp& __x, const _Tp& __y) const
253	{ return __x \|\| __y; }
254	};
255
256	struct __logical_not
257	{
258	template<typename _Tp>
259	bool operator()(const _Tp& __x) const { return !__x; }
260	};
261
262	struct __equal_to
263	{
264	template<typename _Tp>
265	bool operator()(const _Tp& __x, const _Tp& __y) const
266	{ return __x == __y; }
267	};
268
269	struct __not_equal_to
270	{
271	template<typename _Tp>
272	bool operator()(const _Tp& __x, const _Tp& __y) const
847e8c74	273	{ return __x != __y; }
c13bea50 NS	274	};
	275
	276	struct __less
	277	{
	278	template<typename _Tp>
	279	bool operator()(const _Tp& __x, const _Tp& __y) const
	280	{ return __x < __y; }
	281	};
	282
	283	struct __greater
	284	{
	285	template<typename _Tp>
	286	bool operator()(const _Tp& __x, const _Tp& __y) const
	287	{ return __x > __y; }
	288	};
	289
	290	struct __less_equal
	291	{
	292	template<typename _Tp>
	293	bool operator()(const _Tp& __x, const _Tp& __y) const
	294	{ return __x <= __y; }
	295	};
	296
	297	struct __greater_equal
	298	{
	299	template<typename _Tp>
	300	bool operator()(const _Tp& __x, const _Tp& __y) const
	301	{ return __x >= __y; }
	302	};
	303
	304	// The few binary functions we miss.
	305	struct __atan2
	306	{
	307	template<typename _Tp>
	308	_Tp operator()(const _Tp& __x, const _Tp& __y) const
	309	{ return atan2(__x, __y); }
	310	};
	311
	312	struct __pow
	313	{
	314	template<typename _Tp>
	315	_Tp operator()(const _Tp& __x, const _Tp& __y) const
	316	{ return pow(__x, __y); }
	317	};
	318
	319
	320	// We need these bits in order to recover the return type of
	321	// some functions/operators now that we're no longer using
	322	// function templates.
	323	template<typename, typename _Tp>
	324	struct __fun
	325	{
	326	typedef _Tp result_type;
	327	};
	328
	329	// several specializations for relational operators.
	330	template<typename _Tp>
	331	struct __fun<__logical_not, _Tp>
	332	{
	333	typedef bool result_type;
	334	};
	335
	336	template<typename _Tp>
	337	struct __fun<__logical_and, _Tp>
338	{
339	typedef bool result_type;
340	};
341
342	template<typename _Tp>
343	struct __fun<__logical_or, _Tp>
344	{
345	typedef bool result_type;
346	};
347
348	template<typename _Tp>
349	struct __fun<__less, _Tp>
350	{
351	typedef bool result_type;
352	};
353
354	template<typename _Tp>
355	struct __fun<__greater, _Tp>
356	{
357	typedef bool result_type;
358	};
359
360	template<typename _Tp>
361	struct __fun<__less_equal, _Tp>
362	{
363	typedef bool result_type;
364	};
365
366	template<typename _Tp>
367	struct __fun<__greater_equal, _Tp>
368	{
369	typedef bool result_type;
370	};
371
372	template<typename _Tp>
373	struct __fun<__equal_to, _Tp>
374	{
375	typedef bool result_type;
376	};
377
378	template<typename _Tp>
379	struct __fun<__not_equal_to, _Tp>
380	{
381	typedef bool result_type;
382	};
383
384	//
385	// Apply function taking a value/const reference closure
386	//
387
388	template<typename _Dom, typename _Arg>
389	class _FunBase
390	{
391	public:
392	typedef typename _Dom::value_type value_type;
393
394	_FunBase(const _Dom& __e, value_type __f(_Arg))
395	: _M_expr(__e), _M_func(__f) {}
396
397	value_type operator[](size_t __i) const
398	{ return _M_func (_M_expr[__i]); }
399
400	size_t size() const { return _M_expr.size ();}
401
402	private:
403	const _Dom& _M_expr;
404	value_type (*_M_func)(_Arg);
405	};
406
407	template<class _Dom>
408	struct _ValFunClos<_Expr,_Dom> : _FunBase<_Dom, typename _Dom::value_type>
409	{
410	typedef _FunBase<_Dom, typename _Dom::value_type> _Base;
411	typedef typename _Base::value_type value_type;
412	typedef value_type _Tp;
413
414	_ValFunClos(const _Dom& __e, _Tp __f(_Tp)) : _Base(__e, __f) {}
415	};
416
417	template<typename _Tp>
418	struct _ValFunClos<_ValArray,_Tp> : _FunBase<valarray<_Tp>, _Tp>
419	{
420	typedef _FunBase<valarray<_Tp>, _Tp> _Base;
421	typedef _Tp value_type;
422
423	_ValFunClos(const valarray<_Tp>& __v, _Tp __f(_Tp)) : _Base(__v, __f) {}
424	};
425
426	template<class _Dom>
427	struct _RefFunClos<_Expr,_Dom> :
428	_FunBase<_Dom, const typename _Dom::value_type&>
429	{
430	typedef _FunBase<_Dom, const typename _Dom::value_type&> _Base;
431	typedef typename _Base::value_type value_type;
432	typedef value_type _Tp;
433
434	_RefFunClos(const _Dom& __e, _Tp __f(const _Tp&))
435	: _Base(__e, __f) {}
436	};
437
438	template<typename _Tp>
439	struct _RefFunClos<_ValArray,_Tp> : _FunBase<valarray<_Tp>, const _Tp&>
440	{
441	typedef _FunBase<valarray<_Tp>, const _Tp&> _Base;
442	typedef _Tp value_type;
443
444	_RefFunClos(const valarray<_Tp>& __v, _Tp __f(const _Tp&))
445	: _Base(__v, __f) {}
446	};
447
448	//
449	// Unary expression closure.
450	//
451
452	template<class _Oper, class _Arg>
453	class _UnBase
454	{
455	public:
456	typedef typename _Arg::value_type _Vt;
457	typedef typename __fun<_Oper, _Vt>::result_type value_type;
458
459	_UnBase(const _Arg& __e) : _M_expr(__e) {}
460
461	value_type operator[](size_t __i) const
847e8c74	462	{ return _Oper()(_M_expr[__i]); }
c13bea50 NS	463
	464	size_t size() const { return _M_expr.size(); }
	465
	466	private:
	467	const _Arg& _M_expr;
	468	};
	469
	470	template<class _Oper, class _Dom>
	471	struct _UnClos<_Oper, _Expr, _Dom> : _UnBase<_Oper, _Dom>
	472	{
	473	typedef _Dom _Arg;
	474	typedef _UnBase<_Oper, _Dom> _Base;
	475	typedef typename _Base::value_type value_type;
	476
	477	_UnClos(const _Arg& __e) : _Base(__e) {}
	478	};
	479
	480	template<class _Oper, typename _Tp>
	481	struct _UnClos<_Oper, _ValArray, _Tp> : _UnBase<_Oper, valarray<_Tp> >
	482	{
	483	typedef valarray<_Tp> _Arg;
	484	typedef _UnBase<_Oper, valarray<_Tp> > _Base;
	485	typedef typename _Base::value_type value_type;
	486
	487	_UnClos(const _Arg& __e) : _Base(__e) {}
	488	};
	489
	490
	491	//
	492	// Binary expression closure.
	493	//
	494
	495	template<class _Oper, class _FirstArg, class _SecondArg>
	496	class _BinBase
	497	{
	498	public:
	499	typedef typename _FirstArg::value_type _Vt;
	500	typedef typename __fun<_Oper, _Vt>::result_type value_type;
	501
	502	_BinBase(const _FirstArg& __e1, const _SecondArg& __e2)
	503	: _M_expr1(__e1), _M_expr2(__e2) {}
	504
	505	value_type operator[](size_t __i) const
	506	{ return _Oper()(_M_expr1[__i], _M_expr2[__i]); }
	507
	508	size_t size() const { return _M_expr1.size(); }
	509
	510	private:
	511	const _FirstArg& _M_expr1;
	512	const _SecondArg& _M_expr2;
	513	};
	514
	515
	516	template<class _Oper, class _Clos>
	517	class _BinBase2
	518	{
	519	public:
	520	typedef typename _Clos::value_type _Vt;
	521	typedef typename __fun<_Oper, _Vt>::result_type value_type;
	522
	523	_BinBase2(const _Clos& __e, const _Vt& __t)
	524	: _M_expr1(__e), _M_expr2(__t) {}
	525
	526	value_type operator[](size_t __i) const
527	{ return _Oper()(_M_expr1[__i], _M_expr2); }
528
529	size_t size() const { return _M_expr1.size(); }
530
531	private:
532	const _Clos& _M_expr1;
533	const _Vt& _M_expr2;
534	};
535
536	template<class _Oper, class _Clos>
537	class _BinBase1
538	{
539	public:
540	typedef typename _Clos::value_type _Vt;
541	typedef typename __fun<_Oper, _Vt>::result_type value_type;
542
543	_BinBase1(const _Vt& __t, const _Clos& __e)
544	: _M_expr1(__t), _M_expr2(__e) {}
545
546	value_type operator[](size_t __i) const
547	{ return _Oper()(_M_expr1, _M_expr2[__i]); }
548
549	size_t size() const { return _M_expr2.size(); }
550
551	private:
552	const _Vt& _M_expr1;
553	const _Clos& _M_expr2;
554	};
555
556	template<class _Oper, class _Dom1, class _Dom2>
557	struct _BinClos<_Oper, _Expr, _Expr, _Dom1, _Dom2>
558	: _BinBase<_Oper,_Dom1,_Dom2>
559	{
560	typedef _BinBase<_Oper,_Dom1,_Dom2> _Base;
561	typedef typename _Base::value_type value_type;
562
563	_BinClos(const _Dom1& __e1, const _Dom2& __e2) : _Base(__e1, __e2) {}
564	};
565
566	template<class _Oper, typename _Tp>
567	struct _BinClos<_Oper,_ValArray,_ValArray,_Tp,_Tp>
568	: _BinBase<_Oper,valarray<_Tp>,valarray<_Tp> >
569	{
570	typedef _BinBase<_Oper,valarray<_Tp>,valarray<_Tp> > _Base;
571	typedef _Tp value_type;
572
573	_BinClos(const valarray<_Tp>& __v, const valarray<_Tp>& __w)
574	: _Base(__v, __w) {}
575	};
576
577	template<class _Oper, class _Dom>
578	struct _BinClos<_Oper,_Expr,_ValArray,_Dom,typename _Dom::value_type>
579	: _BinBase<_Oper,_Dom,valarray<typename _Dom::value_type> >
580	{
581	typedef typename _Dom::value_type _Tp;
582	typedef _BinBase<_Oper,_Dom,valarray<_Tp> > _Base;
583	typedef typename _Base::value_type value_type;
584
585	_BinClos(const _Dom& __e1, const valarray<_Tp>& __e2)
586	: _Base(__e1, __e2) {}
587	};
588
589	template<class _Oper, class _Dom>
590	struct _BinClos<_Oper,_ValArray,_Expr,typename _Dom::value_type,_Dom>
591	: _BinBase<_Oper,valarray<typename _Dom::value_type>,_Dom>
592	{
593	typedef typename _Dom::value_type _Tp;
594	typedef _BinBase<_Oper,valarray<_Tp>,_Dom> _Base;
595	typedef typename _Base::value_type value_type;
596
597	_BinClos(const valarray<_Tp>& __e1, const _Dom& __e2)
598	: _Base(__e1, __e2) {}
599	};
600
601	template<class _Oper, class _Dom>
602	struct _BinClos<_Oper,_Expr,_Constant,_Dom,typename _Dom::value_type>
603	: _BinBase2<_Oper,_Dom>
604	{
605	typedef typename _Dom::value_type _Tp;
606	typedef _BinBase2<_Oper,_Dom> _Base;
607	typedef typename _Base::value_type value_type;
608
609	_BinClos(const _Dom& __e1, const _Tp& __e2) : _Base(__e1, __e2) {}
610	};
611
612	template<class _Oper, class _Dom>
613	struct _BinClos<_Oper,_Constant,_Expr,typename _Dom::value_type,_Dom>
614	: _BinBase1<_Oper,_Dom>
615	{
616	typedef typename _Dom::value_type _Tp;
617	typedef _BinBase1<_Oper,_Dom> _Base;
618	typedef typename _Base::value_type value_type;
619
620	_BinClos(const _Tp& __e1, const _Dom& __e2) : _Base(__e1, __e2) {}
621	};
622
623	template<class _Oper, typename _Tp>
624	struct _BinClos<_Oper,_ValArray,_Constant,_Tp,_Tp>
625	: _BinBase2<_Oper,valarray<_Tp> >
626	{
627	typedef _BinBase2<_Oper,valarray<_Tp> > _Base;
628	typedef typename _Base::value_type value_type;
629
630	_BinClos(const valarray<_Tp>& __v, const _Tp& __t) : _Base(__v, __t) {}
631	};
632
633	template<class _Oper, typename _Tp>
634	struct _BinClos<_Oper,_Constant,_ValArray,_Tp,_Tp>
635	: _BinBase1<_Oper,valarray<_Tp> >
636	{
637	typedef _BinBase1<_Oper,valarray<_Tp> > _Base;
638	typedef typename _Base::value_type value_type;
639
640	_BinClos(const _Tp& __t, const valarray<_Tp>& __v) : _Base(__t, __v) {}
641	};
642
643
644	//
645	// slice_array closure.
646	//
647	template<typename _Dom> class _SBase {
648	public:
649	typedef typename _Dom::value_type value_type;
650
651	_SBase (const _Dom& __e, const slice& __s)
652	: _M_expr (__e), _M_slice (__s) {}
653	value_type operator[] (size_t __i) const
654	{ return _M_expr[_M_slice.start () + __i * _M_slice.stride ()]; }
655	size_t size() const { return _M_slice.size (); }
656
657	private:
658	const _Dom& _M_expr;
659	const slice& _M_slice;
660	};
661
662	template<typename _Tp> class _SBase<_Array<_Tp> > {
663	public:
664	typedef _Tp value_type;
665
666	_SBase (_Array<_Tp> __a, const slice& __s)
667	: _M_array (__a._M_data+__s.start()), _M_size (__s.size()),
668	_M_stride (__s.stride()) {}
669	value_type operator[] (size_t __i) const
670	{ return _M_array._M_data[__i * _M_stride]; }
671	size_t size() const { return _M_size; }
672
673	private:
674	const _Array<_Tp> _M_array;
675	const size_t _M_size;
676	const size_t _M_stride;
677	};
678
679	template<class _Dom> struct _SClos<_Expr,_Dom> : _SBase<_Dom> {
680	typedef _SBase<_Dom> _Base;
681	typedef typename _Base::value_type value_type;
682
683	_SClos (const _Dom& __e, const slice& __s) : _Base (__e, __s) {}
684	};
685
686	template<typename _Tp>
687	struct _SClos<_ValArray,_Tp> : _SBase<_Array<_Tp> > {
688	typedef _SBase<_Array<_Tp> > _Base;
689	typedef _Tp value_type;
690
691	_SClos (_Array<_Tp> __a, const slice& __s) : _Base (__a, __s) {}
692	};
693
694	} // std::
695
696
697	#endif /* _CPP_VALARRAY_BEFORE_H */
698
699	// Local Variables:
700	// mode:c++
701	// End: