// -*- C++ -*- /*************************************************************************** * * valaray - Declarations for the Standard Library valarray * * $Id$ * *************************************************************************** * * Licensed to the Apache Software Foundation (ASF) under one or more * contributor license agreements. See the NOTICE file distributed * with this work for additional information regarding copyright * ownership. The ASF licenses this file to you under the Apache * License, Version 2.0 (the "License"); you may not use this file * except in compliance with the License. You may obtain a copy of * the License at * * http://www.apache.org/licenses/LICENSE-2.0 * * Unless required by applicable law or agreed to in writing, software * distributed under the License is distributed on an "AS IS" BASIS, * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or * implied. See the License for the specific language governing * permissions and limitations under the License. * * Copyright 1994-2007 Rogue Wave Software, Inc. * **************************************************************************/ #ifndef _RWSTD_VALARRAY_INCLUDED #define _RWSTD_VALARRAY_INCLUDED #include #include #include #include #include #include _RWSTD_CMATH #ifdef _RWSTD_MSVC # pragma warning (push) // disable conversion from 'double' to 'float', possible loss of data // until a conforming header with float and long double overloads // for the C functions is provided # pragma warning (disable: 4244) #endif // _RWSTD_MSVC _RWSTD_NAMESPACE (std) { // forward declarations class _RWSTD_EXPORT slice; template class slice_array; class _RWSTD_EXPORT gslice; template class gslice_array; template class mask_array; template class indirect_array; // 26.3.2 _EXPORT template class valarray { public: typedef _TypeT value_type; // 26.3.2.1, p1 valarray () { } // 26.3.2.1, p2 explicit valarray (_RWSTD_SIZE_T __size) : _C_array (value_type (), __size) { } // 26.3.2.1, p3 valarray (const value_type& __val, _RWSTD_SIZE_T __size) : _C_array (__val, __size) { } // 26.3.2.1, p4 valarray (const value_type* __p, _RWSTD_SIZE_T __size) : _C_array (__p, __size) { } // 26.3.2.1, p5 valarray (const valarray& __rhs) : _C_array (__rhs._C_array) { } // 26.3.2.1, p6 valarray (const slice_array&); valarray (const gslice_array&); valarray (const mask_array&); valarray (const indirect_array&); // 26.3.2.2, p1 - assignment valarray& operator= (const valarray &__rhs) { if (this != &__rhs) _C_array = __rhs._C_array; return *this; } // 26.3.2.2, p2 - assignment valarray& operator= (const value_type &__val) { return _STD::fill (_C_array.begin (), _C_array.end (), __val), *this; } // 26.3.2.2, p3 - assignment valarray& operator= (const slice_array&); valarray& operator= (const gslice_array&); valarray& operator= (const mask_array&); valarray& operator= (const indirect_array&); // 26.3.2.3 - element access const value_type& operator[] (_RWSTD_SIZE_T __i) const { _RWSTD_ASSERT (__i < size ()); return _C_array[__i]; } value_type& operator[] (_RWSTD_SIZE_T __i) { _RWSTD_ASSERT (__i < size ()); return _C_array[__i]; } // 26.3.2.4 - subset operations valarray operator[] (slice) const; slice_array operator[] (slice); valarray operator[] (const gslice&) const; gslice_array operator[] (const gslice&); valarray operator[] (const valarray&) const; mask_array operator[] (const valarray&); valarray operator[] (const valarray<_RWSTD_SIZE_T>&) const; indirect_array operator[] (const valarray<_RWSTD_SIZE_T>&); // 26.3.2.5 - unary operators valarray operator+ () const; valarray operator- () const; valarray operator~ () const; valarray operator! () const; // 26.3.2.6, p1 - computed assignment valarray& operator*= (const valarray&); valarray& operator/= (const valarray&); valarray& operator+= (const valarray&); valarray& operator-= (const valarray&); valarray& operator%= (const valarray&); valarray& operator^= (const valarray&); valarray& operator&= (const valarray&); valarray& operator|= (const valarray&); valarray& operator<<= (const valarray&); valarray& operator>>= (const valarray&); // 26.3.2.6, p5 - computed assignment valarray& operator*= (const value_type&); valarray& operator/= (const value_type&); valarray& operator%= (const value_type&); valarray& operator+= (const value_type&); valarray& operator-= (const value_type&); valarray& operator^= (const value_type&); valarray& operator&= (const value_type&); valarray& operator|= (const value_type&); valarray& operator<<= (const value_type&); valarray& operator>>= (const value_type&); // 26.3.2.7, p1 _RWSTD_SIZE_T size () const { return _C_array.size (); } // 26.3.2.7, p2 value_type sum () const { return accumulate (_C_array.begin (), _C_array.end (), value_type ()); } // 26.3.2.7, p3 value_type (min)() const { _RWSTD_ASSERT (0 != size ()); return *min_element (_C_array.begin (), _C_array.end ()); } // 26.3.2.7, p4 value_type (max)() const { _RWSTD_ASSERT (0 != size ()); return *max_element (_C_array.begin (), _C_array.end ()); } // 26.3.2.7, p5 - ordinary shift valarray shift (int) const; // 26.3.2.7, p7 - circular shift valarray cshift (int) const; // 26.3.2.7, p8 valarray apply (value_type __func (value_type)) const; valarray apply (value_type __func (const value_type&)) const; // 26.3.2.7, p9 void resize (_RWSTD_SIZE_T __size, value_type __val = value_type ()) { _C_array.resize (__size, __val); } // implementation valarray (_RW::__rw_array &__rhs) { _C_array.swap (__rhs); } _RW::__rw_array _C_array; }; } // namespace std _RWSTD_NAMESPACE (__rw) { template inline _STD::valarray<_TypeT> __rw_unary_function (const _STD::valarray<_TypeT> &__val, _UnaryFunction __fun) { // allocate but do not initialize __rw_array<_TypeT> __tmp (__val.size ()); typedef _STD::raw_storage_iterator<_TypeT*, _TypeT> _Iter; // apply `fun' to each element of `a' and initialize `tmp' _STD::transform (__val._C_array.begin (), __val._C_array.end (), _Iter (__tmp.begin ()), __fun); return _STD::valarray<_TypeT>(__tmp); } // implements symmetric non-member valarray binary operators template inline _STD::valarray __rw_binary_function (const _STD::valarray<_TypeT> &__lhs, const _STD::valarray<_TypeT> &__rhs, _BinaryFunction __fun) { typedef typename _BinaryFunction::result_type result_type; typedef _STD::raw_storage_iterator _Iter; // allocate but do not initialize __rw_array __tmp = __rw_array((_STD::min)(__lhs.size (), __rhs.size ())); // apply `fun' to each pair of elements of `lhs' and `rhs' _STD::transform (__lhs._C_array.begin (), __lhs._C_array.begin () + __tmp.size (), __rhs._C_array.begin (), _Iter (__tmp.begin ()), __fun); return _STD::valarray(__tmp); } // implements asymmetric non-member valarray binary operators template inline _STD::valarray __rw_binary_function (const _STD::valarray<_TypeT> &__val, _BinaryFunction __fun) { typedef typename _BinaryFunction::result_type result_type; typedef _STD::raw_storage_iterator _Iter; // allocate but do not initialize __rw_array __tmp = __rw_array(__val.size ()); // apply `fun' to each element of `a' and initialize `tmp' _STD::transform (__val._C_array.begin (), __val._C_array.end (), _Iter (__tmp.begin ()), __fun); return _STD::valarray(__tmp); } template inline void __rw_unary_function (const _STD::slice_array<_TypeT>&, const _STD::valarray<_TypeT>&, _UnaryFunction); template inline void __rw_binary_function (const _STD::slice_array<_TypeT>&, const _STD::valarray<_TypeT>&, _BinaryFunction); template inline void __rw_unary_function (const _STD::mask_array<_TypeT>&, const _STD::valarray<_TypeT>&, _UnaryFunction); template inline void __rw_binary_function (const _STD::mask_array<_TypeT>&, const _STD::valarray<_TypeT>&, _BinaryFunction); template inline void __rw_unary_function (const _STD::indirect_array<_TypeT>&, const _STD::valarray<_TypeT>&, _UnaryFunction); template inline void __rw_binary_function (const _STD::indirect_array<_TypeT>&, const _STD::valarray<_TypeT>&, _BinaryFunction); } // namespace __rw _RWSTD_NAMESPACE (std) { template inline valarray<_TypeT> valarray<_TypeT>::operator+ () const { return _RW::__rw_unary_function (*this, _RW::unary_plus<_TypeT>()); } template inline valarray<_TypeT> valarray<_TypeT>::operator- () const { return _RW::__rw_unary_function (*this, negate<_TypeT>()); } template inline valarray<_TypeT> valarray<_TypeT>::operator~ () const { return _RW::__rw_unary_function (*this, _RW::bitwise_complement<_TypeT>()); } template inline valarray valarray<_TypeT>::operator! () const { _RW::__rw_array __tmp = _RW::__rw_array(size ()); transform (_C_array.begin (), _C_array.end (), __tmp.begin (), logical_not<_TypeT>()); return valarray(__tmp); } template inline valarray<_TypeT>& valarray<_TypeT>::operator*= (const valarray<_TypeT>& __rhs) { transform (_C_array.begin (), _C_array.begin () + (_STD::min)(size (), __rhs.size ()), __rhs._C_array.begin (), _C_array.begin (), multiplies<_TypeT>()); return *this; } template inline valarray<_TypeT>& valarray<_TypeT>::operator/= (const valarray<_TypeT>& __rhs) { transform (_C_array.begin (), _C_array.begin () + (_STD::min)(size (), __rhs.size ()), __rhs._C_array.begin (), _C_array.begin (), divides<_TypeT>()); return *this; } template inline valarray<_TypeT>& valarray<_TypeT>::operator+= (const valarray<_TypeT>& __rhs) { transform (_C_array.begin (), _C_array.begin () + (_STD::min)(size (), __rhs.size ()), __rhs._C_array.begin (), _C_array.begin (), plus<_TypeT>()); return *this; } template inline valarray<_TypeT>& valarray<_TypeT>::operator-= (const valarray<_TypeT>& __rhs) { transform (_C_array.begin (), _C_array.begin () + (_STD::min)(size (), __rhs.size ()), __rhs._C_array.begin (), _C_array.begin (), minus<_TypeT>()); return *this; } template inline valarray<_TypeT>& valarray<_TypeT>::operator%= (const valarray<_TypeT>& __rhs) { transform (_C_array.begin (), _C_array.begin () + (_STD::min)(size (), __rhs.size ()), __rhs._C_array.begin (), _C_array.begin (), modulus<_TypeT>()); return *this; } template inline valarray<_TypeT>& valarray<_TypeT>::operator^= (const valarray<_TypeT>& __rhs) { transform (_C_array.begin (), _C_array.begin () + (_STD::min)(size (), __rhs.size ()), __rhs._C_array.begin (), _C_array.begin (), _RW::exclusive_or<_TypeT>()); return *this; } template inline valarray<_TypeT>& valarray<_TypeT>::operator&= (const valarray<_TypeT>& __rhs) { transform (_C_array.begin (), _C_array.begin () + (_STD::min)(size (), __rhs.size ()), __rhs._C_array.begin (), _C_array.begin (), _RW::bitwise_and<_TypeT>()); return *this; } template inline valarray<_TypeT>& valarray<_TypeT>::operator|= (const valarray<_TypeT>& __rhs) { transform (_C_array.begin (), _C_array.begin () + (_STD::min)(size (), __rhs.size ()), __rhs._C_array.begin (), _C_array.begin (), _RW::bitwise_or<_TypeT>()); return *this; } template inline valarray<_TypeT>& valarray<_TypeT>::operator<<= (const valarray<_TypeT>& __rhs) { transform (_C_array.begin (), _C_array.begin () + (_STD::min)(size (), __rhs.size ()), __rhs._C_array.begin (), _C_array.begin (), _RW::shift_left<_TypeT>()); return *this; } template inline valarray<_TypeT>& valarray<_TypeT>::operator>>= (const valarray<_TypeT>& __rhs) { transform (_C_array.begin (), _C_array.begin () + (_STD::min)(size (), __rhs.size ()), __rhs._C_array.begin (), _C_array.begin (), _RW::shift_right<_TypeT>()); return *this; } template inline valarray<_TypeT>& valarray<_TypeT>::operator*= (const _TypeT& __rhs) { transform (_C_array.begin (), _C_array.end (), _C_array.begin (), bind2nd (multiplies<_TypeT>(), __rhs)); return *this; } template inline valarray<_TypeT>& valarray<_TypeT>::operator/= (const _TypeT& __rhs) { transform (_C_array.begin (), _C_array.end (), _C_array.begin (), bind2nd (divides<_TypeT>(), __rhs)); return *this; } template inline valarray<_TypeT>& valarray<_TypeT>::operator+= (const _TypeT& __rhs) { transform (_C_array.begin (), _C_array.end (), _C_array.begin (), bind2nd (plus<_TypeT>(), __rhs)); return *this; } template inline valarray<_TypeT>& valarray<_TypeT>::operator-= (const _TypeT& __rhs) { transform (_C_array.begin (), _C_array.end (), _C_array.begin (), bind2nd (minus<_TypeT>(), __rhs)); return *this; } template inline valarray<_TypeT>& valarray<_TypeT>::operator%= (const _TypeT& __rhs) { transform (_C_array.begin (), _C_array.end (), _C_array.begin (), bind2nd (modulus<_TypeT>(), __rhs)); return *this; } template inline valarray<_TypeT>& valarray<_TypeT>::operator^= (const _TypeT& __rhs) { transform (_C_array.begin (), _C_array.end (), _C_array.begin (), bind2nd (_RW::exclusive_or<_TypeT>(), __rhs)); return *this; } template inline valarray<_TypeT>& valarray<_TypeT>::operator&= (const _TypeT& __rhs) { transform (_C_array.begin (), _C_array.end (), _C_array.begin (), bind2nd (_RW::bitwise_and<_TypeT>(), __rhs)); return *this; } template inline valarray<_TypeT>& valarray<_TypeT>::operator|= (const _TypeT& __rhs) { transform (_C_array.begin (), _C_array.end (), _C_array.begin (), bind2nd (_RW::bitwise_or<_TypeT>(), __rhs)); return *this; } template inline valarray<_TypeT>& valarray<_TypeT>::operator<<= (const _TypeT& __rhs) { transform (_C_array.begin (), _C_array.end (), _C_array.begin (), bind2nd (_RW::shift_left<_TypeT>(), __rhs)); return *this; } template inline valarray<_TypeT>& valarray<_TypeT>::operator>>= (const _TypeT& __rhs) { transform (_C_array.begin (), _C_array.end (), _C_array.begin (), bind2nd (_RW::shift_right<_TypeT>(), __rhs)); return *this; } template inline valarray<_TypeT> valarray<_TypeT>::apply (_TypeT __fun (_TypeT)) const { return _RW::__rw_unary_function (*this, __fun); } template inline valarray<_TypeT> valarray<_TypeT>::apply (_TypeT __fun (const _TypeT&)) const { return _RW::__rw_unary_function (*this, __fun); } // 26.3.3 - valarray non-members // 26.3.3.1 - valarray binary operators template inline valarray<_TypeT> operator* (const valarray<_TypeT> &__lhs, const valarray<_TypeT> &__rhs) { return valarray<_TypeT>(__lhs) *= __rhs; } template inline valarray<_TypeT> operator/ (const valarray<_TypeT> &__lhs, const valarray<_TypeT> &__rhs) { return valarray<_TypeT>(__lhs) /= __rhs; } template inline valarray<_TypeT> operator% (const valarray<_TypeT> &__lhs, const valarray<_TypeT> &__rhs) { return valarray<_TypeT>(__lhs) %= __rhs; } template inline valarray<_TypeT> operator+ (const valarray<_TypeT> &__lhs, const valarray<_TypeT> &__rhs) { return valarray<_TypeT>(__lhs) += __rhs; } template inline valarray<_TypeT> operator- (const valarray<_TypeT> &__lhs, const valarray<_TypeT> &__rhs) { return valarray<_TypeT>(__lhs) -= __rhs; } template inline valarray<_TypeT> operator^ (const valarray<_TypeT> &__lhs, const valarray<_TypeT> &__rhs) { return valarray<_TypeT>(__lhs) ^= __rhs; } template inline valarray<_TypeT> operator& (const valarray<_TypeT> &__lhs, const valarray<_TypeT> &__rhs) { return valarray<_TypeT>(__lhs) &= __rhs; } template inline valarray<_TypeT> operator| (const valarray<_TypeT> &__lhs, const valarray<_TypeT> &__rhs) { return valarray<_TypeT>(__lhs) |= __rhs; } template inline valarray<_TypeT> operator<< (const valarray<_TypeT> &__lhs, const valarray<_TypeT> &__rhs) { return valarray<_TypeT>(__lhs) <<= __rhs; } template inline valarray<_TypeT> operator>>(const valarray<_TypeT> &__lhs, const valarray<_TypeT> &__rhs) { return valarray<_TypeT>(__lhs) >>= __rhs; } template inline valarray operator&& (const valarray<_TypeT> &__lhs, const valarray<_TypeT> &__rhs) { return _RW::__rw_binary_function (__lhs, __rhs, logical_and<_TypeT>()); } template inline valarray operator|| (const valarray<_TypeT> &__lhs, const valarray<_TypeT> &__rhs) { return _RW::__rw_binary_function (__lhs, __rhs, logical_or<_TypeT>()); } template inline valarray<_TypeT> operator* (const valarray<_TypeT> &__lhs, const _TypeT &__rhs) { return valarray<_TypeT>(__lhs) *= __rhs; } template inline valarray<_TypeT> operator/ (const valarray<_TypeT> &__lhs, const _TypeT &__rhs) { return valarray<_TypeT>(__lhs) /= __rhs; } template inline valarray<_TypeT> operator% (const valarray<_TypeT> &__lhs, const _TypeT &__rhs) { return valarray<_TypeT>(__lhs) %= __rhs; } template inline valarray<_TypeT> operator+ (const valarray<_TypeT> &__lhs, const _TypeT &__rhs) { return valarray<_TypeT>(__lhs) += __rhs; } template inline valarray<_TypeT> operator- (const valarray<_TypeT> &__lhs, const _TypeT &__rhs) { return valarray<_TypeT>(__lhs) -= __rhs; } template inline valarray<_TypeT> operator^ (const valarray<_TypeT> &__lhs, const _TypeT &__rhs) { return valarray<_TypeT>(__lhs) ^= __rhs; } template inline valarray<_TypeT> operator& (const valarray<_TypeT> &__lhs, const _TypeT &__rhs) { return valarray<_TypeT>(__lhs) &= __rhs; } template inline valarray<_TypeT> operator| (const valarray<_TypeT> &__lhs, const _TypeT &__rhs) { return valarray<_TypeT>(__lhs) |= __rhs; } template inline valarray<_TypeT> operator<< (const valarray<_TypeT> &__lhs, const _TypeT &__rhs) { return valarray<_TypeT>(__lhs) <<= __rhs; } template inline valarray<_TypeT> operator>>(const valarray<_TypeT> &__lhs, const _TypeT &__rhs) { return valarray<_TypeT>(__lhs) >>= __rhs; } // 26.3.3.2 - valarray logical operators template inline valarray operator&& (const valarray<_TypeT> &__lhs, const _TypeT &__rhs) { return _RW::__rw_binary_function (__lhs, bind2nd (equal_to<_TypeT>(), __rhs)); } template inline valarray operator|| (const valarray<_TypeT> &__lhs, const _TypeT &__rhs) { return _RW::__rw_binary_function (__lhs, bind2nd (logical_or<_TypeT>(), __rhs)); } template inline valarray<_TypeT> operator* (const _TypeT& __lhs, const valarray<_TypeT> &__rhs) { return _RW::__rw_binary_function (__rhs, bind1st (multiplies<_TypeT>(), __lhs)); } template inline valarray<_TypeT> operator/ (const _TypeT &__lhs, const valarray<_TypeT> &__rhs) { return _RW::__rw_binary_function (__rhs, bind1st (divides<_TypeT>(), __lhs)); } template inline valarray<_TypeT> operator% (const _TypeT &__lhs, const valarray<_TypeT> &__rhs) { return _RW::__rw_binary_function (__rhs, bind1st (modulus<_TypeT>(), __lhs)); } template inline valarray<_TypeT> operator+ (const _TypeT &__lhs, const valarray<_TypeT> &__rhs) { return _RW::__rw_binary_function (__rhs, bind1st (plus<_TypeT>(), __lhs)); } template inline valarray<_TypeT> operator- (const _TypeT &__lhs, const valarray<_TypeT> &__rhs) { return _RW::__rw_binary_function (__rhs, bind1st (minus<_TypeT>(), __lhs)); } template inline valarray<_TypeT> operator^ (const _TypeT &__lhs, const valarray<_TypeT> &__rhs) { return _RW::__rw_binary_function (__rhs, bind1st (_RW::exclusive_or<_TypeT>(), __lhs)); } template inline valarray<_TypeT> operator& (const _TypeT &__lhs, const valarray<_TypeT> &__rhs) { return _RW::__rw_binary_function (__rhs, bind1st (_RW::bitwise_and<_TypeT>(), __lhs)); } template inline valarray<_TypeT> operator| (const _TypeT &__lhs, const valarray<_TypeT> &__rhs) { return _RW::__rw_binary_function (__rhs, bind1st (_RW::bitwise_or<_TypeT>(), __lhs)); } template inline valarray<_TypeT> operator<< (const _TypeT &__lhs, const valarray<_TypeT> &__rhs) { return _RW::__rw_binary_function (__rhs, bind1st (_RW::shift_left<_TypeT>(), __lhs)); } template inline valarray<_TypeT> operator>>(const _TypeT &__lhs, const valarray<_TypeT> &__rhs) { return _RW::__rw_binary_function (__rhs, bind1st (_RW::shift_right<_TypeT>(), __lhs)); } template inline valarray operator&& (const _TypeT &__lhs, const valarray<_TypeT> &__rhs) { return _RW::__rw_binary_function (__rhs, bind1st (logical_and<_TypeT>(), __lhs)); } template inline valarray operator|| (const _TypeT &__lhs, const valarray<_TypeT> &__rhs) { return _RW::__rw_binary_function (__rhs, bind1st (logical_or<_TypeT>(), __lhs)); } template inline valarray operator== (const valarray<_TypeT> &__lhs, const valarray<_TypeT> &__rhs) { return _RW::__rw_binary_function (__lhs, __rhs, equal_to<_TypeT>()); } template inline valarray operator!= (const valarray<_TypeT> &__lhs, const valarray<_TypeT> &__rhs) { return _RW::__rw_binary_function (__lhs, __rhs, not_equal_to<_TypeT>()); } template inline valarray operator< (const valarray<_TypeT> &__lhs, const valarray<_TypeT> &__rhs) { return _RW::__rw_binary_function (__lhs, __rhs, less<_TypeT>()); } template inline valarray operator>(const valarray<_TypeT> &__lhs, const valarray<_TypeT> &__rhs) { return _RW::__rw_binary_function (__lhs, __rhs, greater<_TypeT>()); } template inline valarray operator<= (const valarray<_TypeT> &__lhs, const valarray<_TypeT> &__rhs) { return _RW::__rw_binary_function (__lhs, __rhs, less_equal<_TypeT>()); } template valarray operator>= (const valarray<_TypeT> &__lhs, const valarray<_TypeT> &__rhs) { return _RW::__rw_binary_function (__lhs, __rhs, greater_equal<_TypeT>()); } template inline valarray operator== (const valarray<_TypeT> &__lhs, const _TypeT &__rhs) { return _RW::__rw_binary_function (__lhs, bind2nd (equal_to<_TypeT>(), __rhs)); } template inline valarray operator!= (const valarray<_TypeT> &__lhs, const _TypeT &__rhs) { return _RW::__rw_binary_function (__lhs, bind2nd (not_equal_to<_TypeT>(), __rhs)); } template inline valarray operator< (const valarray<_TypeT> &__lhs, const _TypeT &__rhs) { return _RW::__rw_binary_function (__lhs, bind2nd (less<_TypeT>(), __rhs)); } template inline valarray operator>(const valarray<_TypeT> &__lhs, const _TypeT &__rhs) { return _RW::__rw_binary_function (__lhs, bind2nd (greater<_TypeT>(), __rhs)); } template inline valarray operator<= (const valarray<_TypeT> &__lhs, const _TypeT &__rhs) { return _RW::__rw_binary_function (__lhs, bind2nd (less_equal<_TypeT>(), __rhs)); } template inline valarray operator>= (const valarray<_TypeT> &__lhs, const _TypeT &__rhs) { return _RW::__rw_binary_function (__lhs, bind2nd (greater_equal<_TypeT>(), __rhs)); } template inline valarray operator== (const _TypeT &__lhs, const valarray<_TypeT> &__rhs) { return _RW::__rw_binary_function (__rhs, bind1st (equal_to<_TypeT>(), __lhs)); } template inline valarray operator!= (const _TypeT &__lhs, const valarray<_TypeT> &__rhs) { return _RW::__rw_binary_function (__rhs, bind1st (not_equal_to<_TypeT>(), __lhs)); } template inline valarray operator< (const _TypeT &__lhs, const valarray<_TypeT> &__rhs) { return _RW::__rw_binary_function (__rhs, bind1st (less<_TypeT>(), __lhs)); } template inline valarray operator>(const _TypeT &__lhs, const valarray<_TypeT> &__rhs) { return _RW::__rw_binary_function (__rhs, bind1st (greater<_TypeT>(), __lhs)); } template inline valarray operator<= (const _TypeT &__lhs, const valarray<_TypeT> &__rhs) { return _RW::__rw_binary_function (__rhs, bind1st (less_equal<_TypeT>(), __lhs)); } template valarray operator>= (const _TypeT &__lhs, const valarray<_TypeT> &__rhs) { return _RW::__rw_binary_function (__rhs, bind1st (greater_equal<_TypeT>(), __lhs)); } // 26.3.3.3 - valarray transcendentals // can't use function objects in definitions below due to different linkage // of the math functions' overloads (e.g., extern "C" double cos (double) // and extern "C++" float cos (float), etc...) template inline valarray<_TypeT> abs (const valarray<_TypeT> &__val) { _RW::__rw_array<_TypeT> __tmp (_TypeT (0), __val.size ()); for (_RWSTD_SIZE_T __i = 0; __i != __val.size (); ++__i) __tmp [__i] = __val [__i] < _TypeT () ? -__val [__i] : __val [__i]; return valarray<_TypeT>(__tmp); } template inline valarray<_TypeT> acos (const valarray<_TypeT> &__val) { _RW::__rw_array<_TypeT> __tmp (_TypeT (0), __val.size ()); for (_RWSTD_SIZE_T __i = 0; __i != __val.size (); ++__i) __tmp [__i] = _RWSTD_C::acos (__val [__i]); return valarray<_TypeT>(__tmp); } template inline valarray<_TypeT> asin (const valarray<_TypeT> &__val) { _RW::__rw_array<_TypeT> __tmp (_TypeT (0), __val.size ()); for (_RWSTD_SIZE_T __i = 0; __i != __val.size (); ++__i) __tmp [__i] = _RWSTD_C::asin (__val [__i]); return valarray<_TypeT>(__tmp); } template valarray<_TypeT> atan (const valarray<_TypeT> &__val) { _RW::__rw_array<_TypeT> __tmp (_TypeT (0), __val.size ()); for (_RWSTD_SIZE_T __i = 0; __i != __val.size (); ++__i) __tmp [__i] = _RWSTD_C::atan (__val [__i]); return valarray<_TypeT>(__tmp); } template inline valarray<_TypeT> cos (const valarray<_TypeT> &__val) { _RW::__rw_array<_TypeT> __tmp (_TypeT (0), __val.size ()); for (_RWSTD_SIZE_T __i = 0; __i != __val.size (); ++__i) __tmp [__i] = _RWSTD_C::cos (__val [__i]); return valarray<_TypeT>(__tmp); } template inline valarray<_TypeT> cosh (const valarray<_TypeT> &__val) { _RW::__rw_array<_TypeT> __tmp (_TypeT (0), __val.size ()); for (_RWSTD_SIZE_T __i = 0; __i != __val.size (); ++__i) __tmp [__i] = _RWSTD_C::cosh (__val [__i]); return valarray<_TypeT>(__tmp); } template inline valarray<_TypeT> exp (const valarray<_TypeT> &__val) { _RW::__rw_array<_TypeT> __tmp (_TypeT (0), __val.size ()); for (_RWSTD_SIZE_T __i = 0; __i != __val.size (); ++__i) __tmp [__i] = _RWSTD_C::exp (__val [__i]); return valarray<_TypeT>(__tmp); } template inline valarray<_TypeT> log (const valarray<_TypeT> &__val) { _RW::__rw_array<_TypeT> __tmp (_TypeT (0), __val.size ()); for (_RWSTD_SIZE_T __i = 0; __i != __val.size (); ++__i) __tmp [__i] = _RWSTD_C::log (__val [__i]); return valarray<_TypeT>(__tmp); } template inline valarray<_TypeT> log10 (const valarray<_TypeT> &__val) { _RW::__rw_array<_TypeT> __tmp (_TypeT (0), __val.size ()); for (_RWSTD_SIZE_T __i = 0; __i != __val.size (); ++__i) __tmp [__i] = _RWSTD_C::log10 (__val [__i]); return valarray<_TypeT>(__tmp); } template inline valarray<_TypeT> sinh (const valarray<_TypeT> &__val) { _RW::__rw_array<_TypeT> __tmp (_TypeT (0), __val.size ()); for (_RWSTD_SIZE_T __i = 0; __i != __val.size (); ++__i) __tmp [__i] = _RWSTD_C::sinh (__val [__i]); return valarray<_TypeT>(__tmp); } template inline valarray<_TypeT> sin (const valarray<_TypeT> &__val) { _RW::__rw_array<_TypeT> __tmp (_TypeT (0), __val.size ()); for (_RWSTD_SIZE_T __i = 0; __i != __val.size (); ++__i) __tmp [__i] = _RWSTD_C::sin (__val [__i]); return valarray<_TypeT>(__tmp); } template inline valarray<_TypeT> sqrt (const valarray<_TypeT> &__val) { _RW::__rw_array<_TypeT> __tmp (_TypeT (0), __val.size ()); for (_RWSTD_SIZE_T __i = 0; __i != __val.size (); ++__i) __tmp [__i] = _RWSTD_C::sqrt (__val [__i]); return valarray<_TypeT>(__tmp); } template inline valarray<_TypeT> tan (const valarray<_TypeT> &__val) { _RW::__rw_array<_TypeT> __tmp (_TypeT (0), __val.size ()); for (_RWSTD_SIZE_T __i = 0; __i != __val.size (); ++__i) __tmp [__i] = _RWSTD_C::tan (__val [__i]); return valarray<_TypeT>(__tmp); } template inline valarray<_TypeT> tanh (const valarray<_TypeT> &__val) { _RW::__rw_array<_TypeT> __tmp (_TypeT (0), __val.size ()); for (_RWSTD_SIZE_T __i = 0; __i != __val.size (); ++__i) __tmp [__i] = _RWSTD_C::tanh (__val [__i]); return valarray<_TypeT>(__tmp); } template inline valarray<_TypeT> atan2 (const valarray<_TypeT> &__x, const valarray<_TypeT> &__y) { _RWSTD_ASSERT (__x.size () == __y.size ()); _RW::__rw_array<_TypeT> __tmp (_TypeT (0), __x.size ()); for (_RWSTD_SIZE_T __i = 0; __i != __tmp.size (); ++__i) __tmp [__i] = _RWSTD_C::atan2 (__x [__i], __y [__i]); return valarray<_TypeT>(__tmp); } template inline valarray<_TypeT> atan2 (const valarray<_TypeT> &__x, const _TypeT &__y) { _RW::__rw_array<_TypeT> __tmp (_TypeT (0), __x.size ()); for (_RWSTD_SIZE_T __i = 0; __i != __tmp.size (); ++__i) __tmp [__i] = _RWSTD_C::atan2 (__x [__i], __y); return valarray<_TypeT>(__tmp); } template inline valarray<_TypeT> atan2 (const _TypeT &__x, const valarray<_TypeT> &__y) { _RW::__rw_array<_TypeT> __tmp (_TypeT (0), __y.size ()); for (_RWSTD_SIZE_T __i = 0; __i != __tmp.size (); ++__i) __tmp [__i] = _RWSTD_C::atan2 (__x, __y [__i]); return valarray<_TypeT>(__tmp); } template inline valarray<_TypeT> pow (const valarray<_TypeT> &__x, const valarray<_TypeT> &__y) { _RWSTD_ASSERT (__x.size () == __y.size ()); _RW::__rw_array<_TypeT> __tmp (_TypeT (0), __x.size ()); for (_RWSTD_SIZE_T __i = 0; __i != __tmp.size (); ++__i) __tmp [__i] = _RWSTD_C::pow (__x [__i], __y [__i]); return valarray<_TypeT>(__tmp); } template inline valarray<_TypeT> pow (const valarray<_TypeT> &__x, const _TypeT &__y) { _RW::__rw_array<_TypeT> __tmp (_TypeT (0), __x.size ()); for (_RWSTD_SIZE_T __i = 0; __i != __tmp.size (); ++__i) __tmp [__i] = _RWSTD_C::pow (__x [__i], __y); return valarray<_TypeT>(__tmp); } template inline valarray<_TypeT> pow (const _TypeT &__x, const valarray<_TypeT> &__y) { _RW::__rw_array<_TypeT> __tmp (_TypeT (0), __y.size ()); for (_RWSTD_SIZE_T __i = 0; __i != __tmp.size (); ++__i) __tmp [__i] = _RWSTD_C::pow (__x, __y [__i]); return valarray<_TypeT>(__tmp); } // 26.3.4 class _RWSTD_EXPORT slice { public: slice (): _C_start (0), _C_length (0), _C_stride (0) { } slice (_RWSTD_SIZE_T __start, _RWSTD_SIZE_T __length, _RWSTD_SIZE_T __stride) : _C_start (__start) , _C_length (__length) , _C_stride (__stride) { } // 26.3.4.2 - slice access functions _RWSTD_SIZE_T start () const { return _C_start; } _RWSTD_SIZE_T size () const { return _C_length; } _RWSTD_SIZE_T stride () const { return _C_stride; } private: _RWSTD_SIZE_T _C_start; // starting offset _RWSTD_SIZE_T _C_length; // length of this slice _RWSTD_SIZE_T _C_stride; // offset between elements }; // 26.3.5 - helper class not to be directly used template class slice_array { friend class valarray<_TypeT>; public: typedef _TypeT value_type; slice_array (const slice_array &__rhs) : _C_array(__rhs.get_ref_mem_array()), _C_slice(__rhs._C_get_slice()) { } // implementation slice_array (_RW::__rw_array* __a, const slice &__s) : _C_array (__a), _C_slice (__s) { } _RW::__rw_array* get_ref_mem_array () const { return _C_array; } slice _C_get_slice () const { return _C_slice; } // 26.3.5.4 - fill function void operator= (const value_type&) const; // 26.3.5.2 - assignment void operator= (const valarray &__rhs) const { _RW::__rw_unary_function (*this, __rhs, _RW::identity()); } // 26.3.5.3 - slice_array computed assignment void operator*= (const valarray &__rhs) const { _RW::__rw_binary_function (*this, __rhs, multiplies()); } void operator/= (const valarray &__rhs) const { _RW::__rw_binary_function (*this, __rhs, divides()); } void operator+= (const valarray &__rhs) const { _RW::__rw_binary_function (*this, __rhs, plus()); } void operator-= (const valarray &__rhs) const { _RW::__rw_binary_function (*this, __rhs, minus()); } void operator%= (const valarray &__rhs) const { _RW::__rw_binary_function (*this, __rhs, modulus()); } void operator^= (const valarray &__rhs) const { _RW::__rw_binary_function (*this, __rhs, _RW::exclusive_or()); } void operator&= (const valarray &__rhs) const { _RW::__rw_binary_function (*this, __rhs, _RW::bitwise_and()); } void operator|= (const valarray &__rhs) const { _RW::__rw_binary_function (*this, __rhs, _RW::bitwise_or()); } void operator<<= (const valarray &__rhs) const { _RW::__rw_binary_function (*this, __rhs, _RW::shift_left()); } void operator>>= (const valarray &__rhs) const { _RW::__rw_binary_function (*this, __rhs, _RW::shift_right()); } private: slice_array (); slice_array& operator= (const slice_array&); _RW::__rw_array *_C_array; // the referenced valarray slice _C_slice; // slice of referenced valarray }; template inline void slice_array<_TypeT>::operator= (const value_type &__rhs) const { // assign the value `__rhs' to the given slice of valarray for (_RWSTD_SIZE_T __i = _C_slice.start(), __j = 0; __i < _C_array->size () && __j != _C_slice.size (); __i += _C_slice.stride (), ++__j) (*_C_array)[__i] = __rhs; } // 26.3.6 - generalized slice of a valarray class _RWSTD_EXPORT gslice { public: // 26.3.6.1 gslice () : _C_start (0), _C_reset (true) { } gslice (_RWSTD_SIZE_T __start, const valarray<_RWSTD_SIZE_T>& __length, const valarray<_RWSTD_SIZE_T>& __stride) : _C_start (__start), _C_length (__length), _C_stride (__stride), _C_reset (true), _C_r_length ((_RWSTD_SIZE_T)0, __length.size ()) { _RWSTD_ASSERT (_C_length.size () == _C_stride.size ()); } gslice (const gslice &__rhs) : _C_start (__rhs._C_start), _C_length (__rhs._C_length), _C_stride (__rhs._C_stride), _C_reset (true), _C_r_length ((_RWSTD_SIZE_T)0, __rhs._C_length.size ()) { _RWSTD_ASSERT (_C_length.size () == _C_stride.size ()); } // 26.3.6.2 _RWSTD_SIZE_T start () const { return _C_start; } valarray<_RWSTD_SIZE_T> size () const { return _C_length; } valarray<_RWSTD_SIZE_T> stride () const { return _C_stride; } // convenience functions _RWSTD_SIZE_T next_ind (); bool is_reseted () const { return _C_reset; } _RWSTD_SIZE_T ind_numb () const; private: _RWSTD_SIZE_T _C_start; // starting offset valarray<_RWSTD_SIZE_T> _C_length; // set of lengths (sizes equal) valarray<_RWSTD_SIZE_T> _C_stride; // set of strides (sizes equal) bool _C_reset; valarray<_RWSTD_SIZE_T> _C_r_length; }; template class gslice_array { friend class valarray<_TypeT>; public: typedef _TypeT value_type; gslice_array (const gslice_array& __rhs) : _C_array (__rhs.get_ref_mem_array ()), _C_slice (__rhs._C_get_slice ()) { } gslice_array (_RW::__rw_array* __a, const gslice & __s) : _C_array (__a), _C_slice (__s) { } _RW::__rw_array* get_ref_mem_array () const { return _C_array; } gslice _C_get_slice () const { return _C_slice; } void operator= (const valarray &__rhs) const; void operator= (const value_type &__rhs) const; void operator*= (const valarray &__rhs) const; void operator/= (const valarray &__rhs) const; void operator+= (const valarray &__rhs) const; void operator-= (const valarray &__rhs) const; void operator%= (const valarray &__rhs) const; void operator^= (const valarray &__rhs) const; void operator&= (const valarray &__rhs) const; void operator|= (const valarray &__rhs) const; void operator<<= (const valarray &__rhs) const; void operator>>= (const valarray &__rhs) const; private: gslice_array (); gslice_array& operator= (const gslice_array&); _RW::__rw_array* _C_array; gslice _C_slice; }; template class mask_array { friend class valarray<_TypeT>; public: typedef _TypeT value_type; mask_array (const mask_array &__rhs) : _C_array (__rhs.get_ref_mem_array ()), _C_valarray (__rhs._C_get_array ()) { } mask_array (_RW::__rw_array *__a, const valarray& __val) : _C_array (__a), _C_valarray (__val) { } _RW::__rw_array* get_ref_mem_array () const { return _C_array; } valarray _C_get_array () const { return _C_valarray; } const valarray* _C_get_array_ptr () const { return &_C_valarray; } void operator= (const value_type&) const; void operator= (const valarray &__rhs) const { _RW::__rw_unary_function (*this, __rhs, _RW::identity()); } void operator*= (const valarray &__rhs) const { _RW::__rw_binary_function (*this, __rhs, multiplies()); } void operator/= (const valarray &__rhs) const { _RW::__rw_binary_function (*this, __rhs, divides()); } void operator+= (const valarray &__rhs) const { _RW::__rw_binary_function (*this, __rhs, plus()); } void operator-= (const valarray &__rhs) const { _RW::__rw_binary_function (*this, __rhs, minus()); } void operator%= (const valarray &__rhs) const { _RW::__rw_binary_function (*this, __rhs, modulus()); } void operator^= (const valarray &__rhs) const { _RW::__rw_binary_function (*this, __rhs, _RW::exclusive_or()); } void operator&= (const valarray &__rhs) const { _RW::__rw_binary_function (*this, __rhs, _RW::bitwise_and()); } void operator|= (const valarray &__rhs) const { _RW::__rw_binary_function (*this, __rhs, _RW::bitwise_or()); } void operator<<= (const valarray &__rhs) const { _RW::__rw_binary_function (*this, __rhs, _RW::shift_left()); } void operator>>= (const valarray &__rhs) const { _RW::__rw_binary_function (*this, __rhs, _RW::shift_right()); } private: mask_array (); mask_array& operator= (const mask_array&); _RW::__rw_array* _C_array; valarray _C_valarray; }; template void mask_array<_TypeT>::operator= (const value_type &__rhs) const { _RWSTD_ASSERT (0 != get_ref_mem_array ()); _RW::__rw_array<_TypeT> &__a = *get_ref_mem_array (); for (_RWSTD_SIZE_T __i = 0; __i != _C_valarray.size (); ++__i) { if (_C_valarray [__i]) __a [__i] = __rhs; } } /**************************************************************** * INDIRECT_ARRAY * ****************************************************************/ template class indirect_array { friend class valarray<_TypeT>; public: typedef _TypeT value_type; indirect_array (const indirect_array& __sl) :_C_array (__sl.get_ref_mem_array ()), _C_valarray (__sl._C_get_array ()) { } indirect_array (_RW::__rw_array *__a, const valarray<_RWSTD_SIZE_T> &__v) :_C_array (__a), _C_valarray (__v) { } _RW::__rw_array* get_ref_mem_array () const { return _C_array; } valarray<_RWSTD_SIZE_T> _C_get_array () const { return _C_valarray; } const valarray<_RWSTD_SIZE_T>* _C_get_array_ptr () const { return &_C_valarray; } void operator= (const value_type&) const; void operator= (const valarray &__rhs) const { _RW::__rw_unary_function (*this, __rhs, _RW::identity()); } void operator*= (const valarray &__rhs) const { _RW::__rw_binary_function (*this, __rhs, multiplies()); } void operator/= (const valarray &__rhs) const { _RW::__rw_binary_function (*this, __rhs, divides()); } void operator+= (const valarray &__rhs) const { _RW::__rw_binary_function (*this, __rhs, plus()); } void operator-= (const valarray &__rhs) const { _RW::__rw_binary_function (*this, __rhs, minus()); } void operator%= (const valarray &__rhs) const { _RW::__rw_binary_function (*this, __rhs, modulus()); } void operator^= (const valarray &__rhs) const { _RW::__rw_binary_function (*this, __rhs, _RW::exclusive_or()); } void operator&= (const valarray &__rhs) const { _RW::__rw_binary_function (*this, __rhs, _RW::bitwise_and()); } void operator|= (const valarray &__rhs) const { _RW::__rw_binary_function (*this, __rhs, _RW::bitwise_or()); } void operator<<= (const valarray &__rhs) const { _RW::__rw_binary_function (*this, __rhs, _RW::shift_left()); } void operator>>= (const valarray &__rhs) const { _RW::__rw_binary_function (*this, __rhs, _RW::shift_right()); } private: indirect_array (); indirect_array& operator= (const indirect_array&); _RW::__rw_array* _C_array; valarray<_RWSTD_SIZE_T> _C_valarray; }; template inline void indirect_array<_TypeT>::operator= (const _TypeT &__rhs) const { for (_RWSTD_SIZE_T __i = 0; __i != _C_valarray.size (); ++__i) (*_C_array)[_C_valarray [__i]] = __rhs; } } // namespace std _RWSTD_NAMESPACE (__rw) { template inline void __rw_unary_function (const _STD::slice_array<_TypeT> &__lhs, const _STD::valarray<_TypeT> &__rhs, _UnaryFunction __fun) { _RWSTD_ASSERT (0 != __lhs.get_ref_mem_array ()); _STD::slice __slice = __lhs._C_get_slice (); _RW::__rw_array<_TypeT> &__ar = *__lhs.get_ref_mem_array (); for (_RWSTD_SIZE_T __i = __slice.start (), __j = 0; __j != __slice.size (); ++__j) { if (__j < __rhs.size () && __i < __ar.size ()) __ar [__i] = __fun (__rhs [__j]); __i += __slice.stride (); } } template inline void __rw_binary_function (const _STD::slice_array<_TypeT> &__lhs, const _STD::valarray<_TypeT> &__rhs, _BinaryFunction __fun) { _RWSTD_ASSERT (0 != __lhs.get_ref_mem_array ()); _STD::slice __slice = __lhs._C_get_slice (); _RW::__rw_array<_TypeT> &__ar = *__lhs.get_ref_mem_array (); for (_RWSTD_SIZE_T __i = __slice.start (), __j = 0; __j != __slice.size (); ++__j) { if (__j < __rhs.size () && __i < __ar.size ()) __ar [__i] = __fun (__ar [__i], __rhs [__j]); __i += __slice.stride (); } } template inline void __rw_unary_function (const _STD::mask_array<_TypeT> &__lhs, const _STD::valarray<_TypeT> &__rhs, _UnaryFunction __fun) { _RWSTD_ASSERT (0 != __lhs.get_ref_mem_array ()); _RW::__rw_array<_TypeT> &__ar = *__lhs.get_ref_mem_array (); const _STD::valarray &__vlray = *__lhs._C_get_array_ptr (); for (_RWSTD_SIZE_T __i = 0, __j = 0; __i != __vlray.size (); ++__i) if (__vlray [__i]) __ar [__i] = __fun (__rhs [__j++]); } template inline void __rw_binary_function (const _STD::mask_array<_TypeT> &__lhs, const _STD::valarray<_TypeT> &__rhs, _BinaryFunction __fun) { _RWSTD_ASSERT (0 != __lhs.get_ref_mem_array ()); _RW::__rw_array<_TypeT> &__ar = *__lhs.get_ref_mem_array (); const _STD::valarray &__vlray = *__lhs._C_get_array_ptr (); for (_RWSTD_SIZE_T __i = 0, __j = 0; __i != __vlray.size (); ++__i) if (__vlray [__i]) __ar [__i] = __fun (__ar [__i], __rhs [__j++]); } template inline void __rw_unary_function (const _STD::indirect_array<_TypeT> &__lhs, const _STD::valarray<_TypeT> &__rhs, _UnaryFunction __fun) { _RWSTD_ASSERT (0 != __lhs.get_ref_mem_array ()); _RW::__rw_array<_TypeT> &__ar = *__lhs.get_ref_mem_array (); const _STD::valarray<_RWSTD_SIZE_T> &__vlray = *__lhs._C_get_array_ptr (); for (_RWSTD_SIZE_T __i = 0; __i != __vlray.size (); ++__i) __ar [__vlray [__i]] = __fun (__rhs [__i]); } template inline void __rw_binary_function (const _STD::indirect_array<_TypeT> &__lhs, const _STD::valarray<_TypeT> &__rhs, _BinaryFunction __fun) { _RWSTD_ASSERT (0 != __lhs.get_ref_mem_array ()); _RW::__rw_array<_TypeT> &__ar = *__lhs.get_ref_mem_array (); const _STD::valarray<_RWSTD_SIZE_T> &__vlray = *__lhs._C_get_array_ptr (); for (_RWSTD_SIZE_T __i = 0; __i != __vlray.size (); ++__i) __ar [__vlray [__i]] = __fun (__ar [__vlray [__i]], __rhs [__i]); } } // namespace __rw _RWSTD_NAMESPACE (std) { /***************************************************************** * * * GSLICE_ARRAY MEMBER FUNCTIONS * * * ******************************************************************/ // gslice_array inline member functions template inline void gslice_array<_TypeT>::operator= (const valarray<_TypeT>& __rhs) const { gslice *gsl = _RWSTD_CONST_CAST (gslice*, &_C_slice); _RWSTD_SIZE_T __i = gsl->next_ind(); _RWSTD_SIZE_T __cpt = 0; while ( (!gsl->is_reseted () || (!__cpt && gsl->ind_numb ())) && __cpt < __rhs.size ()) { (*_C_array)[__i] = __rhs[__cpt]; __i= gsl->next_ind(); __cpt++; } } template inline void gslice_array<_TypeT>::operator= (const _TypeT& value) const { gslice *gsl = _RWSTD_CONST_CAST (gslice*, &_C_slice); _RWSTD_SIZE_T __i = gsl->next_ind(); _RWSTD_SIZE_T __cpt = 0; while (!gsl->is_reseted () || (!__cpt && gsl->ind_numb ())) { (*_C_array)[__i] = value; __i= gsl->next_ind(); __cpt++; } } // computed assignment template inline void gslice_array<_TypeT>::operator*= (const valarray<_TypeT>& __rhs) const { gslice *gsl = _RWSTD_CONST_CAST (gslice*, &_C_slice); _RWSTD_SIZE_T __i = gsl->next_ind(); _RWSTD_SIZE_T __cpt = 0; while ( (!gsl->is_reseted () || (!__cpt && gsl->ind_numb ())) && __cpt < __rhs.size ()) { (*_C_array)[__i] *= __rhs[__cpt]; __i= gsl->next_ind(); __cpt++; } } template inline void gslice_array<_TypeT>::operator/= (const valarray<_TypeT>& __rhs) const { gslice *gsl = _RWSTD_CONST_CAST (gslice*, &_C_slice); _RWSTD_SIZE_T __i = gsl->next_ind(); _RWSTD_SIZE_T __cpt = 0; while ( (!gsl->is_reseted () || (!__cpt && gsl->ind_numb ())) && __cpt < __rhs.size ()) { (*_C_array)[__i] /= __rhs[__cpt]; __i= gsl->next_ind(); __cpt++; } } template inline void gslice_array<_TypeT>::operator+= (const valarray<_TypeT>& __rhs) const { gslice *gsl = _RWSTD_CONST_CAST (gslice*, &_C_slice); _RWSTD_SIZE_T __i = gsl->next_ind(); _RWSTD_SIZE_T __cpt = 0; while ( (!gsl->is_reseted () || (!__cpt && gsl->ind_numb ())) && __cpt < __rhs.size ()) { (*_C_array)[__i] += __rhs[__cpt]; __i= gsl->next_ind(); __cpt++; } } template inline void gslice_array<_TypeT>::operator-= (const valarray<_TypeT>& __rhs) const { gslice *gsl = _RWSTD_CONST_CAST (gslice*, &_C_slice); _RWSTD_SIZE_T __i = gsl->next_ind(); _RWSTD_SIZE_T __cpt = 0; while ( (!gsl->is_reseted() || (!__cpt && gsl->ind_numb ())) && __cpt < __rhs.size ()) { (*_C_array)[__i] -= __rhs[__cpt]; __i= gsl->next_ind(); __cpt++; } } template inline void gslice_array<_TypeT>::operator%= (const valarray<_TypeT>& __rhs) const { gslice *gsl = _RWSTD_CONST_CAST (gslice*, &_C_slice); _RWSTD_SIZE_T __i = gsl->next_ind(); _RWSTD_SIZE_T __cpt = 0; while ( (!gsl->is_reseted () || (!__cpt && gsl->ind_numb ())) && __cpt < __rhs.size ()) { (*_C_array)[__i] %= __rhs[__cpt]; __i= gsl->next_ind(); __cpt++; } } template inline void gslice_array<_TypeT>::operator^= (const valarray<_TypeT>& __rhs) const { gslice *gsl = _RWSTD_CONST_CAST (gslice*, &_C_slice); _RWSTD_SIZE_T __i = gsl->next_ind(); _RWSTD_SIZE_T __cpt = 0; while ( (!gsl->is_reseted () || (!__cpt && gsl->ind_numb ())) && __cpt < __rhs.size ()) { (*_C_array)[__i] ^= __rhs[__cpt]; __i= gsl->next_ind(); __cpt++; } } template inline void gslice_array<_TypeT>::operator&= (const valarray<_TypeT>& __rhs) const { gslice *gsl = _RWSTD_CONST_CAST (gslice*, &_C_slice); _RWSTD_SIZE_T __i = gsl->next_ind(); _RWSTD_SIZE_T __cpt = 0; while ( (!gsl->is_reseted() || (!__cpt && gsl->ind_numb ())) && __cpt < __rhs.size ()) { (*_C_array)[__i] &= __rhs[__cpt]; __i= gsl->next_ind(); __cpt++; } } template inline void gslice_array<_TypeT>::operator|= (const valarray<_TypeT>& __rhs) const { gslice *gsl = _RWSTD_CONST_CAST (gslice*, &_C_slice); _RWSTD_SIZE_T __i = gsl->next_ind(); _RWSTD_SIZE_T __cpt = 0; while ( (!gsl->is_reseted() || (!__cpt && gsl->ind_numb ())) && __cpt < __rhs.size ()) { (*_C_array)[__i] |= __rhs[__cpt]; __i= gsl->next_ind(); __cpt++; } } template inline void gslice_array<_TypeT>::operator<<= (const valarray<_TypeT>& __rhs) const { gslice *gsl = _RWSTD_CONST_CAST (gslice*, &_C_slice); _RWSTD_SIZE_T __i = gsl->next_ind(); _RWSTD_SIZE_T __cpt = 0; while ( (!gsl->is_reseted () || (!__cpt && gsl->ind_numb ())) && __cpt < __rhs.size ()) { (*_C_array)[__i] <<= __rhs[__cpt]; __i= gsl->next_ind(); __cpt++; } } template inline void gslice_array<_TypeT>::operator>>= (const valarray<_TypeT>& __rhs) const { gslice *gsl = _RWSTD_CONST_CAST (gslice*, &_C_slice); _RWSTD_SIZE_T __i = gsl->next_ind(); _RWSTD_SIZE_T __cpt = 0; while ( (!gsl->is_reseted () || (!__cpt && gsl->ind_numb ())) && __cpt < __rhs.size ()) { (*_C_array)[__i] >>= __rhs[__cpt]; __i= gsl->next_ind(); __cpt++; } } inline _RWSTD_SIZE_T gslice::ind_numb() const { if (_C_length.size () == 0) return 0; _RWSTD_SIZE_T __inx = _C_length [0] != 0; for(_RWSTD_SIZE_T __i = 0; __i < _C_length.size (); ++__i) { if (_C_length [__i]) __inx *= _C_length [__i]; } return __inx; } template inline valarray<_TypeT> valarray<_TypeT>::operator[] (slice __sl) const { if (0 == __sl.size ()) return valarray<_TypeT>(); _RWSTD_ASSERT (__sl.start () < size ()); _RWSTD_ASSERT (0 != __sl.stride ()); const _RWSTD_SIZE_T __max_span = size () - __sl.start () - 1; const _RWSTD_SIZE_T __size = __max_span < (__sl.size () - 1) * __sl.stride () ? __max_span / __sl.stride () + 1 : __sl.size (); _RWSTD_ASSERT (__size <= size ()); _RW::__rw_array <_TypeT> __tmp = _RW::__rw_array <_TypeT>(_TypeT (), __size); for (_RWSTD_SIZE_T __i = __sl.start (), __j = 0; __j != __size; __i += __sl.stride (), ++__j) __tmp [__j] = _C_array [__i]; return valarray<_TypeT>(__tmp); } template inline valarray<_TypeT>::valarray (const slice_array<_TypeT>& sl_ar) { _RW::__rw_array <_TypeT> __tmp = _RW::__rw_array <_TypeT>(_TypeT (), sl_ar._C_get_slice ().size()); _RWSTD_SIZE_T __i = sl_ar._C_get_slice().start(); _RWSTD_SIZE_T __cpt = 0; while( __cpt < sl_ar._C_get_slice().size() ) { __tmp[__cpt] = (*(sl_ar.get_ref_mem_array()))[__i]; __i+= sl_ar._C_get_slice().stride(); __cpt++; } _C_array.swap (__tmp); } template inline valarray<_TypeT>& valarray<_TypeT>::operator= (const slice_array<_TypeT>& sl_ar) { _RW::__rw_array <_TypeT> __tmp = _RW::__rw_array <_TypeT>(_TypeT (), sl_ar._C_get_slice ().size()); _RWSTD_SIZE_T __i = sl_ar._C_get_slice().start(); _RWSTD_SIZE_T __cpt = 0; while( __cpt < sl_ar._C_get_slice().size() ) { __tmp[__cpt] = (*(sl_ar.get_ref_mem_array()))[__i]; __i+= sl_ar._C_get_slice().stride(); __cpt++; } if ( &_C_array == sl_ar.get_ref_mem_array() ) _C_array.resize(0); _C_array.swap (__tmp); return *this; } template inline valarray<_TypeT> valarray<_TypeT>::operator[](const gslice& __sl) const { const _RWSTD_SIZE_T __maxinx = __sl.ind_numb (); _RW::__rw_array<_TypeT> __tmp = _RW::__rw_array<_TypeT>(_TypeT (), __maxinx); gslice* const __gsl = _RWSTD_CONST_CAST (gslice*, &__sl); for (_RWSTD_SIZE_T __i = 0; __i != __maxinx; ++__i) { const _RWSTD_SIZE_T __inx = __gsl->next_ind (); __tmp [__i] = _C_array [__inx]; } return valarray<_TypeT>(__tmp); } template inline valarray<_TypeT>::valarray(const gslice_array<_TypeT>& sl_ar) { gslice __sl(sl_ar._C_get_slice()); const _RWSTD_SIZE_T __maxinx = __sl.ind_numb (); _RW::__rw_array <_TypeT> __tmp = _RW::__rw_array <_TypeT>(_TypeT (), __maxinx); _RWSTD_SIZE_T __i = __sl.next_ind(); _RWSTD_SIZE_T __cpt = 0; while (!__sl.is_reseted () || (!__cpt && __maxinx)) { __tmp[__cpt] = (*(sl_ar.get_ref_mem_array()))[__i]; __i= __sl.next_ind(); __cpt++; } _C_array.swap (__tmp); } template inline valarray<_TypeT>& valarray<_TypeT>::operator= (const gslice_array<_TypeT>& sl_ar) { gslice __sl(sl_ar._C_get_slice()); const _RWSTD_SIZE_T __maxinx = __sl.ind_numb (); _RW::__rw_array <_TypeT> __tmp = _RW::__rw_array <_TypeT>(_TypeT (), __maxinx); _RWSTD_SIZE_T __i = __sl.next_ind(); _RWSTD_SIZE_T __cpt = 0; while( !__sl.is_reseted() || !__cpt && __maxinx ) { __tmp[__cpt] = (*(sl_ar.get_ref_mem_array()))[__i]; __i= __sl.next_ind(); __cpt++; } if ( &_C_array == sl_ar.get_ref_mem_array() ) _C_array.resize(0); _C_array.swap (__tmp); return *this; } template inline valarray<_TypeT> valarray<_TypeT>::operator[](const valarray& __rhs) const { _RWSTD_SIZE_T __i, __n = 0; for(__i=0; __i < __rhs.size(); __i++ ) if ( __rhs[__i]) __n++; _RW::__rw_array <_TypeT> __tmp = _RW::__rw_array <_TypeT>(_TypeT (), __n); _RWSTD_SIZE_T __cpt = 0; for( __i=0; __i < __rhs.size(); __i++ ) if ( __rhs[__i]) __tmp[__cpt++] = _C_array[__i]; return valarray<_TypeT>(__tmp); } template inline valarray<_TypeT>::valarray(const mask_array<_TypeT>& __rhs) { mask_array<_TypeT> *__msk = _RWSTD_CONST_CAST (mask_array<_TypeT>*, &__rhs); const valarray*__sec = __msk->_C_get_array_ptr(); _RWSTD_SIZE_T __i, __n = 0; for(__i = 0; __i < __sec->size(); __i++) if ( (*__sec)[__i]) __n++; _RW::__rw_array <_TypeT> __tmp = _RW::__rw_array <_TypeT>(_TypeT (), __n); _RWSTD_SIZE_T __cpt = 0; for( __i=0; __i < __sec->size(); __i++ ) if ( (*__sec)[__i]) __tmp[__cpt++] = (*(__rhs.get_ref_mem_array()))[__i]; _C_array.swap (__tmp); } template inline valarray<_TypeT>& valarray<_TypeT>::operator= (const mask_array<_TypeT>& __rhs) { mask_array<_TypeT> *__msk = _RWSTD_CONST_CAST (mask_array<_TypeT>*, &__rhs); const valarray*__sec = __msk->_C_get_array_ptr(); _RWSTD_SIZE_T __i, __n = 0; for (__i = 0; __i < __sec->size(); __i++) if ((*__sec)[__i]) __n++; _RW::__rw_array <_TypeT> __tmp = _RW::__rw_array <_TypeT>(_TypeT (), __n); _RWSTD_SIZE_T __cpt = 0; for( __i=0; __i < __sec->size(); __i++ ) if ( (*__sec)[__i]) __tmp[__cpt++] = (*(__rhs.get_ref_mem_array()))[__i]; if ( &_C_array == __rhs.get_ref_mem_array() ) _C_array.resize(0); _C_array.swap (__tmp); return *this; } template inline valarray<_TypeT> valarray<_TypeT>::operator[](const valarray<_RWSTD_SIZE_T>& __rhs) const { _RW::__rw_array <_TypeT> __tmp = _RW::__rw_array <_TypeT>(__rhs.size ()); #if defined (__GNUG__) && __GNUC__ <= 2 && __GNUC_MINOR__ < 97 for (_RWSTD_SIZE_T __i = 0; __i != __rhs.size (); ++__i) { // prevent a g++ 2.95.2 ICE _TypeT *__place = __tmp.begin () + __i; new (__place) _TypeT ((*this)[__rhs [__i]]); } #else // if __GNUG__ >= 2.97 for (_RWSTD_SIZE_T __i = 0; __i != __rhs.size (); ++__i) new (&__tmp [__i]) _TypeT ((*this)[__rhs [__i]]); #endif // __GNUG__ >= 2.97 return valarray (__tmp); } template inline valarray<_TypeT>::valarray (const indirect_array<_TypeT>& __rhs) { indirect_array<_TypeT> *__ia = _RWSTD_CONST_CAST (indirect_array<_TypeT>*, &__rhs); const valarray<_RWSTD_SIZE_T> *__sec = __ia->_C_get_array_ptr(); _RW::__rw_array <_TypeT> __tmp = _RW::__rw_array <_TypeT>(_TypeT (), __sec->size()); _RWSTD_SIZE_T __cpt = 0; for(_RWSTD_SIZE_T __i=0; __i < __sec->size(); __i++ ) __tmp[__cpt++] = (*(__rhs.get_ref_mem_array()))[(*__sec)[__i]]; _C_array.swap (__tmp); } template inline valarray<_TypeT>& valarray<_TypeT>::operator= (const indirect_array<_TypeT>& __rhs) { indirect_array<_TypeT> *__ia = _RWSTD_CONST_CAST (indirect_array<_TypeT>*, &__rhs); const valarray<_RWSTD_SIZE_T> *__sec = __ia->_C_get_array_ptr(); _RW::__rw_array <_TypeT> __tmp = _RW::__rw_array <_TypeT>(_TypeT (), __sec->size()); _RWSTD_SIZE_T __cpt = 0; for(_RWSTD_SIZE_T __i=0; __i < __sec->size(); __i++ ) __tmp[__cpt++] = (*(__rhs.get_ref_mem_array()))[(*__sec)[__i]]; if (&_C_array == __rhs.get_ref_mem_array() ) _C_array.resize(0); _C_array.swap (__tmp); return *this; } template inline slice_array<_TypeT> valarray<_TypeT>::operator[] (slice __x) { return slice_array(&_C_array, __x); } template inline gslice_array<_TypeT> valarray<_TypeT>::operator[] (const gslice &__x) { return gslice_array(&_C_array, __x); } template inline mask_array<_TypeT> valarray<_TypeT>::operator[] (const valarray &__x) { return mask_array(&_C_array, __x); } template inline indirect_array<_TypeT> valarray<_TypeT>::operator[] (const valarray<_RWSTD_SIZE_T> &__x) { return indirect_array(&_C_array, __x); } } // namespace std #ifdef _RWSTD_NO_IMPLICIT_INCLUSION # include #endif #ifdef _RWSTD_MSVC # pragma warning (pop) #endif // _RWSTD_MSVC #endif // _RWSTD_VALARRAY_INCLUDED