boost/numeric/ublas/expression_types.hpp
// Copyright (c) 2000-2013 // Joerg Walter, Mathias Koch. David Bellot // // Distributed under the Boost Software License, Version 1.0. (See // accompanying file LICENSE_1_0.txt or copy at // http://www.boost.org/LICENSE_1_0.txt) // // The authors gratefully acknowledge the support of // GeNeSys mbH & Co. KG in producing this work. // #ifndef _BOOST_UBLAS_EXPRESSION_TYPE_ #define _BOOST_UBLAS_EXPRESSION_TYPE_ #include <boost/numeric/ublas/exception.hpp> #include <boost/numeric/ublas/traits.hpp> #include <boost/numeric/ublas/functional.hpp> // Expression templates based on ideas of Todd Veldhuizen and Geoffrey Furnish // Iterators based on ideas of Jeremy Siek namespace boost { namespace numeric { namespace ublas { /** \brief Base class for uBLAS statically derived expressions using the the Barton Nackman trick * * This is a NonAssignable class * Directly implement nonassignable - simplifes debugging call trace! * * \tparam E an expression type */ template<class E> class ublas_expression { public: typedef E expression_type; /* E can be an incomplete type - to define the following we would need more template arguments typedef typename E::type_category type_category; typedef typename E::value_type value_type; */ protected: ublas_expression () {} ~ublas_expression () {} private: const ublas_expression& operator= (const ublas_expression &); }; /** \brief Base class for Scalar Expression models * * It does not model the Scalar Expression concept but all derived types should. * The class defines a common base type and some common interface for all statically * derived Scalar Expression classes. * * We implement the casts to the statically derived type. * * \tparam E an expression type */ template<class E> class scalar_expression: public ublas_expression<E> { public: typedef E expression_type; typedef scalar_tag type_category; BOOST_UBLAS_INLINE const expression_type &operator () () const { return *static_cast<const expression_type *> (this); } BOOST_UBLAS_INLINE expression_type &operator () () { return *static_cast<expression_type *> (this); } }; template<class T> class scalar_reference: public scalar_expression<scalar_reference<T> > { typedef scalar_reference<T> self_type; public: typedef T value_type; typedef const value_type &const_reference; typedef typename boost::mpl::if_<boost::is_const<T>, const_reference, value_type &>::type reference; typedef const self_type const_closure_type; typedef const_closure_type closure_type; // Construction and destruction BOOST_UBLAS_INLINE explicit scalar_reference (reference t): t_ (t) {} // Conversion BOOST_UBLAS_INLINE operator value_type () const { return t_; } // Assignment BOOST_UBLAS_INLINE scalar_reference &operator = (const scalar_reference &s) { t_ = s.t_; return *this; } template<class AE> BOOST_UBLAS_INLINE scalar_reference &operator = (const scalar_expression<AE> &ae) { t_ = ae; return *this; } // Closure comparison BOOST_UBLAS_INLINE bool same_closure (const scalar_reference &sr) const { return &t_ == &sr.t_; } private: reference t_; }; template<class T> class scalar_value: public scalar_expression<scalar_value<T> > { typedef scalar_value<T> self_type; public: typedef T value_type; typedef const value_type &const_reference; typedef typename boost::mpl::if_<boost::is_const<T>, const_reference, value_type &>::type reference; typedef const scalar_reference<const self_type> const_closure_type; typedef scalar_reference<self_type> closure_type; // Construction and destruction BOOST_UBLAS_INLINE scalar_value (): t_ () {} BOOST_UBLAS_INLINE scalar_value (const value_type &t): t_ (t) {} BOOST_UBLAS_INLINE operator value_type () const { return t_; } // Assignment BOOST_UBLAS_INLINE scalar_value &operator = (const scalar_value &s) { t_ = s.t_; return *this; } template<class AE> BOOST_UBLAS_INLINE scalar_value &operator = (const scalar_expression<AE> &ae) { t_ = ae; return *this; } // Closure comparison BOOST_UBLAS_INLINE bool same_closure (const scalar_value &sv) const { return this == &sv; // self closing on instances value } private: value_type t_; }; /** \brief Base class for Vector Expression models * * it does not model the Vector Expression concept but all derived types should. * The class defines a common base type and some common interface for all * statically derived Vector Expression classes. * We implement the casts to the statically derived type. */ template<class E> class vector_expression: public ublas_expression<E> { public: static const unsigned complexity = 0; typedef E expression_type; typedef vector_tag type_category; /* E can be an incomplete type - to define the following we would need more template arguments typedef typename E::size_type size_type; */ BOOST_UBLAS_INLINE const expression_type &operator () () const { return *static_cast<const expression_type *> (this); } BOOST_UBLAS_INLINE expression_type &operator () () { return *static_cast<expression_type *> (this); } #ifdef BOOST_UBLAS_ENABLE_PROXY_SHORTCUTS private: // projection types typedef vector_range<E> vector_range_type; typedef vector_range<const E> const_vector_range_type; typedef vector_slice<E> vector_slice_type; typedef vector_slice<const E> const_vector_slice_type; // vector_indirect_type will depend on the A template parameter typedef basic_range<> default_range; // required to avoid range/slice name confusion typedef basic_slice<> default_slice; public: BOOST_UBLAS_INLINE const_vector_range_type operator () (const default_range &r) const { return const_vector_range_type (operator () (), r); } BOOST_UBLAS_INLINE vector_range_type operator () (const default_range &r) { return vector_range_type (operator () (), r); } BOOST_UBLAS_INLINE const_vector_slice_type operator () (const default_slice &s) const { return const_vector_slice_type (operator () (), s); } BOOST_UBLAS_INLINE vector_slice_type operator () (const default_slice &s) { return vector_slice_type (operator () (), s); } template<class A> BOOST_UBLAS_INLINE const vector_indirect<const E, indirect_array<A> > operator () (const indirect_array<A> &ia) const { return vector_indirect<const E, indirect_array<A> > (operator () (), ia); } template<class A> BOOST_UBLAS_INLINE vector_indirect<E, indirect_array<A> > operator () (const indirect_array<A> &ia) { return vector_indirect<E, indirect_array<A> > (operator () (), ia); } BOOST_UBLAS_INLINE const_vector_range_type project (const default_range &r) const { return const_vector_range_type (operator () (), r); } BOOST_UBLAS_INLINE vector_range_type project (const default_range &r) { return vector_range_type (operator () (), r); } BOOST_UBLAS_INLINE const_vector_slice_type project (const default_slice &s) const { return const_vector_slice_type (operator () (), s); } BOOST_UBLAS_INLINE vector_slice_type project (const default_slice &s) { return vector_slice_type (operator () (), s); } template<class A> BOOST_UBLAS_INLINE const vector_indirect<const E, indirect_array<A> > project (const indirect_array<A> &ia) const { return vector_indirect<const E, indirect_array<A> > (operator () (), ia); } template<class A> BOOST_UBLAS_INLINE vector_indirect<E, indirect_array<A> > project (const indirect_array<A> &ia) { return vector_indirect<E, indirect_array<A> > (operator () (), ia); } #endif }; /** \brief Base class for Vector container models * * it does not model the Vector concept but all derived types should. * The class defines a common base type and some common interface for all * statically derived Vector classes * We implement the casts to the statically derived type. */ template<class C> class vector_container: public vector_expression<C> { public: static const unsigned complexity = 0; typedef C container_type; typedef vector_tag type_category; BOOST_UBLAS_INLINE const container_type &operator () () const { return *static_cast<const container_type *> (this); } BOOST_UBLAS_INLINE container_type &operator () () { return *static_cast<container_type *> (this); } #ifdef BOOST_UBLAS_ENABLE_PROXY_SHORTCUTS using vector_expression<C>::operator (); #endif }; /** \brief Base class for Matrix Expression models * * it does not model the Matrix Expression concept but all derived types should. * The class defines a common base type and some common interface for all * statically derived Matrix Expression classes * We implement the casts to the statically derived type. */ template<class E> class matrix_expression: public ublas_expression<E> { private: typedef matrix_expression<E> self_type; public: static const unsigned complexity = 0; typedef E expression_type; typedef matrix_tag type_category; /* E can be an incomplete type - to define the following we would need more template arguments typedef typename E::size_type size_type; */ BOOST_UBLAS_INLINE const expression_type &operator () () const { return *static_cast<const expression_type *> (this); } BOOST_UBLAS_INLINE expression_type &operator () () { return *static_cast<expression_type *> (this); } #ifdef BOOST_UBLAS_ENABLE_PROXY_SHORTCUTS private: // projection types typedef vector_range<E> vector_range_type; typedef const vector_range<const E> const_vector_range_type; typedef vector_slice<E> vector_slice_type; typedef const vector_slice<const E> const_vector_slice_type; typedef matrix_row<E> matrix_row_type; typedef const matrix_row<const E> const_matrix_row_type; typedef matrix_column<E> matrix_column_type; typedef const matrix_column<const E> const_matrix_column_type; typedef matrix_range<E> matrix_range_type; typedef const matrix_range<const E> const_matrix_range_type; typedef matrix_slice<E> matrix_slice_type; typedef const matrix_slice<const E> const_matrix_slice_type; // matrix_indirect_type will depend on the A template parameter typedef basic_range<> default_range; // required to avoid range/slice name confusion typedef basic_slice<> default_slice; public: BOOST_UBLAS_INLINE const_matrix_row_type operator [] (std::size_t i) const { return const_matrix_row_type (operator () (), i); } BOOST_UBLAS_INLINE matrix_row_type operator [] (std::size_t i) { return matrix_row_type (operator () (), i); } BOOST_UBLAS_INLINE const_matrix_row_type row (std::size_t i) const { return const_matrix_row_type (operator () (), i); } BOOST_UBLAS_INLINE matrix_row_type row (std::size_t i) { return matrix_row_type (operator () (), i); } BOOST_UBLAS_INLINE const_matrix_column_type column (std::size_t j) const { return const_matrix_column_type (operator () (), j); } BOOST_UBLAS_INLINE matrix_column_type column (std::size_t j) { return matrix_column_type (operator () (), j); } BOOST_UBLAS_INLINE const_matrix_range_type operator () (const default_range &r1, const default_range &r2) const { return const_matrix_range_type (operator () (), r1, r2); } BOOST_UBLAS_INLINE matrix_range_type operator () (const default_range &r1, const default_range &r2) { return matrix_range_type (operator () (), r1, r2); } BOOST_UBLAS_INLINE const_matrix_slice_type operator () (const default_slice &s1, const default_slice &s2) const { return const_matrix_slice_type (operator () (), s1, s2); } BOOST_UBLAS_INLINE matrix_slice_type operator () (const default_slice &s1, const default_slice &s2) { return matrix_slice_type (operator () (), s1, s2); } template<class A> BOOST_UBLAS_INLINE const matrix_indirect<const E, indirect_array<A> > operator () (const indirect_array<A> &ia1, const indirect_array<A> &ia2) const { return matrix_indirect<const E, indirect_array<A> > (operator () (), ia1, ia2); } template<class A> BOOST_UBLAS_INLINE matrix_indirect<E, indirect_array<A> > operator () (const indirect_array<A> &ia1, const indirect_array<A> &ia2) { return matrix_indirect<E, indirect_array<A> > (operator () (), ia1, ia2); } BOOST_UBLAS_INLINE const_matrix_range_type project (const default_range &r1, const default_range &r2) const { return const_matrix_range_type (operator () (), r1, r2); } BOOST_UBLAS_INLINE matrix_range_type project (const default_range &r1, const default_range &r2) { return matrix_range_type (operator () (), r1, r2); } BOOST_UBLAS_INLINE const_matrix_slice_type project (const default_slice &s1, const default_slice &s2) const { return const_matrix_slice_type (operator () (), s1, s2); } BOOST_UBLAS_INLINE matrix_slice_type project (const default_slice &s1, const default_slice &s2) { return matrix_slice_type (operator () (), s1, s2); } template<class A> BOOST_UBLAS_INLINE const matrix_indirect<const E, indirect_array<A> > project (const indirect_array<A> &ia1, const indirect_array<A> &ia2) const { return matrix_indirect<const E, indirect_array<A> > (operator () (), ia1, ia2); } template<class A> BOOST_UBLAS_INLINE matrix_indirect<E, indirect_array<A> > project (const indirect_array<A> &ia1, const indirect_array<A> &ia2) { return matrix_indirect<E, indirect_array<A> > (operator () (), ia1, ia2); } #endif }; #ifdef BOOST_UBLAS_NO_NESTED_CLASS_RELATION struct iterator1_tag {}; struct iterator2_tag {}; template<class I> BOOST_UBLAS_INLINE typename I::dual_iterator_type begin (const I &it, iterator1_tag) { return it ().find2 (1, it.index1 (), 0); } template<class I> BOOST_UBLAS_INLINE typename I::dual_iterator_type end (const I &it, iterator1_tag) { return it ().find2 (1, it.index1 (), it ().size2 ()); } template<class I> BOOST_UBLAS_INLINE typename I::dual_reverse_iterator_type rbegin (const I &it, iterator1_tag) { return typename I::dual_reverse_iterator_type (end (it, iterator1_tag ())); } template<class I> BOOST_UBLAS_INLINE typename I::dual_reverse_iterator_type rend (const I &it, iterator1_tag) { return typename I::dual_reverse_iterator_type (begin (it, iterator1_tag ())); } template<class I> BOOST_UBLAS_INLINE typename I::dual_iterator_type begin (const I &it, iterator2_tag) { return it ().find1 (1, 0, it.index2 ()); } template<class I> BOOST_UBLAS_INLINE typename I::dual_iterator_type end (const I &it, iterator2_tag) { return it ().find1 (1, it ().size1 (), it.index2 ()); } template<class I> BOOST_UBLAS_INLINE typename I::dual_reverse_iterator_type rbegin (const I &it, iterator2_tag) { return typename I::dual_reverse_iterator_type (end (it, iterator2_tag ())); } template<class I> BOOST_UBLAS_INLINE typename I::dual_reverse_iterator_type rend (const I &it, iterator2_tag) { return typename I::dual_reverse_iterator_type (begin (it, iterator2_tag ())); } #endif /** \brief Base class for Matrix container models * * it does not model the Matrix concept but all derived types should. * The class defines a common base type and some common interface for all * statically derived Matrix classes * We implement the casts to the statically derived type. */ template<class C> class matrix_container: public matrix_expression<C> { public: static const unsigned complexity = 0; typedef C container_type; typedef matrix_tag type_category; BOOST_UBLAS_INLINE const container_type &operator () () const { return *static_cast<const container_type *> (this); } BOOST_UBLAS_INLINE container_type &operator () () { return *static_cast<container_type *> (this); } #ifdef BOOST_UBLAS_ENABLE_PROXY_SHORTCUTS using matrix_expression<C>::operator (); #endif }; }}} #endif