boost/numeric/ublas/detail/matrix_assign.hpp
// // Copyright (c) 2000-2002 // Joerg Walter, Mathias Koch // // 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_MATRIX_ASSIGN_ #define _BOOST_UBLAS_MATRIX_ASSIGN_ #include <boost/numeric/ublas/traits.hpp> // Required for make_conformant storage #include <vector> // Iterators based on ideas of Jeremy Siek namespace boost { namespace numeric { namespace ublas { namespace detail { // Weak equality check - useful to compare equality two arbitary matrix expression results. // Since the actual expressions are unknown, we check for and arbitary error bound // on the relative error. // For a linear expression the infinity norm makes sense as we do not know how the elements will be // combined in the expression. False positive results are inevitable for arbirary expressions! template<class E1, class E2, class S> BOOST_UBLAS_INLINE bool equals (const matrix_expression<E1> &e1, const matrix_expression<E2> &e2, S epsilon, S min_norm) { return norm_inf (e1 - e2) <= epsilon * std::max<S> (std::max<S> (norm_inf (e1), norm_inf (e2)), min_norm); } template<class E1, class E2> BOOST_UBLAS_INLINE bool expression_type_check (const matrix_expression<E1> &e1, const matrix_expression<E2> &e2) { typedef typename type_traits<typename promote_traits<typename E1::value_type, typename E2::value_type>::promote_type>::real_type real_type; return equals (e1, e2, BOOST_UBLAS_TYPE_CHECK_EPSILON, BOOST_UBLAS_TYPE_CHECK_MIN); } template<class M, class E, class R> // BOOST_UBLAS_INLINE This function seems to be big. So we do not let the compiler inline it. void make_conformant (M &m, const matrix_expression<E> &e, row_major_tag, R) { BOOST_UBLAS_CHECK (m.size1 () == e ().size1 (), bad_size ()); BOOST_UBLAS_CHECK (m.size2 () == e ().size2 (), bad_size ()); typedef R conformant_restrict_type; typedef typename M::size_type size_type; typedef typename M::difference_type difference_type; typedef typename M::value_type value_type; // FIXME unbounded_array with push_back maybe better std::vector<std::pair<size_type, size_type> > index; typename M::iterator1 it1 (m.begin1 ()); typename M::iterator1 it1_end (m.end1 ()); typename E::const_iterator1 it1e (e ().begin1 ()); typename E::const_iterator1 it1e_end (e ().end1 ()); while (it1 != it1_end && it1e != it1e_end) { difference_type compare = it1.index1 () - it1e.index1 (); if (compare == 0) { #ifndef BOOST_UBLAS_NO_NESTED_CLASS_RELATION typename M::iterator2 it2 (it1.begin ()); typename M::iterator2 it2_end (it1.end ()); typename E::const_iterator2 it2e (it1e.begin ()); typename E::const_iterator2 it2e_end (it1e.end ()); #else typename M::iterator2 it2 (begin (it1, iterator1_tag ())); typename M::iterator2 it2_end (end (it1, iterator1_tag ())); typename E::const_iterator2 it2e (begin (it1e, iterator1_tag ())); typename E::const_iterator2 it2e_end (end (it1e, iterator1_tag ())); #endif if (it2 != it2_end && it2e != it2e_end) { size_type it2_index = it2.index2 (), it2e_index = it2e.index2 (); for (;;) { difference_type compare2 = it2_index - it2e_index; if (compare2 == 0) { ++ it2, ++ it2e; if (it2 != it2_end && it2e != it2e_end) { it2_index = it2.index2 (); it2e_index = it2e.index2 (); } else break; } else if (compare2 < 0) { increment (it2, it2_end, - compare2); if (it2 != it2_end) it2_index = it2.index2 (); else break; } else if (compare2 > 0) { if (conformant_restrict_type::other (it2e.index1 (), it2e.index2 ())) if (static_cast<value_type>(*it2e) != value_type/*zero*/()) index.push_back (std::pair<size_type, size_type> (it2e.index1 (), it2e.index2 ())); ++ it2e; if (it2e != it2e_end) it2e_index = it2e.index2 (); else break; } } } while (it2e != it2e_end) { if (conformant_restrict_type::other (it2e.index1 (), it2e.index2 ())) if (static_cast<value_type>(*it2e) != value_type/*zero*/()) index.push_back (std::pair<size_type, size_type> (it2e.index1 (), it2e.index2 ())); ++ it2e; } ++ it1, ++ it1e; } else if (compare < 0) { increment (it1, it1_end, - compare); } else if (compare > 0) { #ifndef BOOST_UBLAS_NO_NESTED_CLASS_RELATION typename E::const_iterator2 it2e (it1e.begin ()); typename E::const_iterator2 it2e_end (it1e.end ()); #else typename E::const_iterator2 it2e (begin (it1e, iterator1_tag ())); typename E::const_iterator2 it2e_end (end (it1e, iterator1_tag ())); #endif while (it2e != it2e_end) { if (conformant_restrict_type::other (it2e.index1 (), it2e.index2 ())) if (static_cast<value_type>(*it2e) != value_type/*zero*/()) index.push_back (std::pair<size_type, size_type> (it2e.index1 (), it2e.index2 ())); ++ it2e; } ++ it1e; } } while (it1e != it1e_end) { #ifndef BOOST_UBLAS_NO_NESTED_CLASS_RELATION typename E::const_iterator2 it2e (it1e.begin ()); typename E::const_iterator2 it2e_end (it1e.end ()); #else typename E::const_iterator2 it2e (begin (it1e, iterator1_tag ())); typename E::const_iterator2 it2e_end (end (it1e, iterator1_tag ())); #endif while (it2e != it2e_end) { if (conformant_restrict_type::other (it2e.index1 (), it2e.index2 ())) if (static_cast<value_type>(*it2e) != value_type/*zero*/()) index.push_back (std::pair<size_type, size_type> (it2e.index1 (), it2e.index2 ())); ++ it2e; } ++ it1e; } // ISSUE proxies require insert_element for (size_type k = 0; k < index.size (); ++ k) m (index [k].first, index [k].second) = value_type/*zero*/(); } template<class M, class E, class R> // BOOST_UBLAS_INLINE This function seems to be big. So we do not let the compiler inline it. void make_conformant (M &m, const matrix_expression<E> &e, column_major_tag, R) { BOOST_UBLAS_CHECK (m.size1 () == e ().size1 (), bad_size ()); BOOST_UBLAS_CHECK (m.size2 () == e ().size2 (), bad_size ()); typedef R conformant_restrict_type; typedef typename M::size_type size_type; typedef typename M::difference_type difference_type; typedef typename M::value_type value_type; std::vector<std::pair<size_type, size_type> > index; typename M::iterator2 it2 (m.begin2 ()); typename M::iterator2 it2_end (m.end2 ()); typename E::const_iterator2 it2e (e ().begin2 ()); typename E::const_iterator2 it2e_end (e ().end2 ()); while (it2 != it2_end && it2e != it2e_end) { difference_type compare = it2.index2 () - it2e.index2 (); if (compare == 0) { #ifndef BOOST_UBLAS_NO_NESTED_CLASS_RELATION typename M::iterator1 it1 (it2.begin ()); typename M::iterator1 it1_end (it2.end ()); typename E::const_iterator1 it1e (it2e.begin ()); typename E::const_iterator1 it1e_end (it2e.end ()); #else typename M::iterator1 it1 (begin (it2, iterator2_tag ())); typename M::iterator1 it1_end (end (it2, iterator2_tag ())); typename E::const_iterator1 it1e (begin (it2e, iterator2_tag ())); typename E::const_iterator1 it1e_end (end (it2e, iterator2_tag ())); #endif if (it1 != it1_end && it1e != it1e_end) { size_type it1_index = it1.index1 (), it1e_index = it1e.index1 (); for (;;) { difference_type compare2 = it1_index - it1e_index; if (compare2 == 0) { ++ it1, ++ it1e; if (it1 != it1_end && it1e != it1e_end) { it1_index = it1.index1 (); it1e_index = it1e.index1 (); } else break; } else if (compare2 < 0) { increment (it1, it1_end, - compare2); if (it1 != it1_end) it1_index = it1.index1 (); else break; } else if (compare2 > 0) { if (conformant_restrict_type::other (it1e.index1 (), it1e.index2 ())) if (static_cast<value_type>(*it1e) != value_type/*zero*/()) index.push_back (std::pair<size_type, size_type> (it1e.index1 (), it1e.index2 ())); ++ it1e; if (it1e != it1e_end) it1e_index = it1e.index1 (); else break; } } } while (it1e != it1e_end) { if (conformant_restrict_type::other (it1e.index1 (), it1e.index2 ())) if (static_cast<value_type>(*it1e) != value_type/*zero*/()) index.push_back (std::pair<size_type, size_type> (it1e.index1 (), it1e.index2 ())); ++ it1e; } ++ it2, ++ it2e; } else if (compare < 0) { increment (it2, it2_end, - compare); } else if (compare > 0) { #ifndef BOOST_UBLAS_NO_NESTED_CLASS_RELATION typename E::const_iterator1 it1e (it2e.begin ()); typename E::const_iterator1 it1e_end (it2e.end ()); #else typename E::const_iterator1 it1e (begin (it2e, iterator2_tag ())); typename E::const_iterator1 it1e_end (end (it2e, iterator2_tag ())); #endif while (it1e != it1e_end) { if (conformant_restrict_type::other (it1e.index1 (), it1e.index2 ())) if (static_cast<value_type>(*it1e) != value_type/*zero*/()) index.push_back (std::pair<size_type, size_type> (it1e.index1 (), it1e.index2 ())); ++ it1e; } ++ it2e; } } while (it2e != it2e_end) { #ifndef BOOST_UBLAS_NO_NESTED_CLASS_RELATION typename E::const_iterator1 it1e (it2e.begin ()); typename E::const_iterator1 it1e_end (it2e.end ()); #else typename E::const_iterator1 it1e (begin (it2e, iterator2_tag ())); typename E::const_iterator1 it1e_end (end (it2e, iterator2_tag ())); #endif while (it1e != it1e_end) { if (conformant_restrict_type::other (it1e.index1 (), it1e.index2 ())) if (static_cast<value_type>(*it1e) != value_type/*zero*/()) index.push_back (std::pair<size_type, size_type> (it1e.index1 (), it1e.index2 ())); ++ it1e; } ++ it2e; } // ISSUE proxies require insert_element for (size_type k = 0; k < index.size (); ++ k) m (index [k].first, index [k].second) = value_type/*zero*/(); } }//namespace detail // Explicitly iterating row major template<template <class T1, class T2> class F, class M, class T> // BOOST_UBLAS_INLINE This function seems to be big. So we do not let the compiler inline it. void iterating_matrix_assign_scalar (M &m, const T &t, row_major_tag) { typedef F<typename M::iterator2::reference, T> functor_type; typedef typename M::difference_type difference_type; difference_type size1 (m.size1 ()); difference_type size2 (m.size2 ()); typename M::iterator1 it1 (m.begin1 ()); BOOST_UBLAS_CHECK (size2 == 0 || m.end1 () - it1 == size1, bad_size ()); while (-- size1 >= 0) { #ifndef BOOST_UBLAS_NO_NESTED_CLASS_RELATION typename M::iterator2 it2 (it1.begin ()); #else typename M::iterator2 it2 (begin (it1, iterator1_tag ())); #endif BOOST_UBLAS_CHECK (it1.end () - it2 == size2, bad_size ()); difference_type temp_size2 (size2); #ifndef BOOST_UBLAS_USE_DUFF_DEVICE while (-- temp_size2 >= 0) functor_type::apply (*it2, t), ++ it2; #else DD (temp_size2, 4, r, (functor_type::apply (*it2, t), ++ it2)); #endif ++ it1; } } // Explicitly iterating column major template<template <class T1, class T2> class F, class M, class T> // BOOST_UBLAS_INLINE This function seems to be big. So we do not let the compiler inline it. void iterating_matrix_assign_scalar (M &m, const T &t, column_major_tag) { typedef F<typename M::iterator1::reference, T> functor_type; typedef typename M::difference_type difference_type; difference_type size2 (m.size2 ()); difference_type size1 (m.size1 ()); typename M::iterator2 it2 (m.begin2 ()); BOOST_UBLAS_CHECK (size1 == 0 || m.end2 () - it2 == size2, bad_size ()); while (-- size2 >= 0) { #ifndef BOOST_UBLAS_NO_NESTED_CLASS_RELATION typename M::iterator1 it1 (it2.begin ()); #else typename M::iterator1 it1 (begin (it2, iterator2_tag ())); #endif BOOST_UBLAS_CHECK (it2.end () - it1 == size1, bad_size ()); difference_type temp_size1 (size1); #ifndef BOOST_UBLAS_USE_DUFF_DEVICE while (-- temp_size1 >= 0) functor_type::apply (*it1, t), ++ it1; #else DD (temp_size1, 4, r, (functor_type::apply (*it1, t), ++ it1)); #endif ++ it2; } } // Explicitly indexing row major template<template <class T1, class T2> class F, class M, class T> // BOOST_UBLAS_INLINE This function seems to be big. So we do not let the compiler inline it. void indexing_matrix_assign_scalar (M &m, const T &t, row_major_tag) { typedef F<typename M::reference, T> functor_type; typedef typename M::size_type size_type; size_type size1 (m.size1 ()); size_type size2 (m.size2 ()); for (size_type i = 0; i < size1; ++ i) { #ifndef BOOST_UBLAS_USE_DUFF_DEVICE for (size_type j = 0; j < size2; ++ j) functor_type::apply (m (i, j), t); #else size_type j (0); DD (size2, 4, r, (functor_type::apply (m (i, j), t), ++ j)); #endif } } // Explicitly indexing column major template<template <class T1, class T2> class F, class M, class T> // BOOST_UBLAS_INLINE This function seems to be big. So we do not let the compiler inline it. void indexing_matrix_assign_scalar (M &m, const T &t, column_major_tag) { typedef F<typename M::reference, T> functor_type; typedef typename M::size_type size_type; size_type size2 (m.size2 ()); size_type size1 (m.size1 ()); for (size_type j = 0; j < size2; ++ j) { #ifndef BOOST_UBLAS_USE_DUFF_DEVICE for (size_type i = 0; i < size1; ++ i) functor_type::apply (m (i, j), t); #else size_type i (0); DD (size1, 4, r, (functor_type::apply (m (i, j), t), ++ i)); #endif } } // Dense (proxy) case template<template <class T1, class T2> class F, class M, class T, class C> // BOOST_UBLAS_INLINE This function seems to be big. So we do not let the compiler inline it. void matrix_assign_scalar (M &m, const T &t, dense_proxy_tag, C) { typedef C orientation_category; #ifdef BOOST_UBLAS_USE_INDEXING indexing_matrix_assign_scalar<F> (m, t, orientation_category ()); #elif BOOST_UBLAS_USE_ITERATING iterating_matrix_assign_scalar<F> (m, t, orientation_category ()); #else typedef typename M::size_type size_type; size_type size1 (m.size1 ()); size_type size2 (m.size2 ()); if (size1 >= BOOST_UBLAS_ITERATOR_THRESHOLD && size2 >= BOOST_UBLAS_ITERATOR_THRESHOLD) iterating_matrix_assign_scalar<F> (m, t, orientation_category ()); else indexing_matrix_assign_scalar<F> (m, t, orientation_category ()); #endif } // Packed (proxy) row major case template<template <class T1, class T2> class F, class M, class T> // BOOST_UBLAS_INLINE This function seems to be big. So we do not let the compiler inline it. void matrix_assign_scalar (M &m, const T &t, packed_proxy_tag, row_major_tag) { typedef F<typename M::iterator2::reference, T> functor_type; typedef typename M::difference_type difference_type; typename M::iterator1 it1 (m.begin1 ()); difference_type size1 (m.end1 () - it1); while (-- size1 >= 0) { #ifndef BOOST_UBLAS_NO_NESTED_CLASS_RELATION typename M::iterator2 it2 (it1.begin ()); difference_type size2 (it1.end () - it2); #else typename M::iterator2 it2 (begin (it1, iterator1_tag ())); difference_type size2 (end (it1, iterator1_tag ()) - it2); #endif while (-- size2 >= 0) functor_type::apply (*it2, t), ++ it2; ++ it1; } } // Packed (proxy) column major case template<template <class T1, class T2> class F, class M, class T> // BOOST_UBLAS_INLINE This function seems to be big. So we do not let the compiler inline it. void matrix_assign_scalar (M &m, const T &t, packed_proxy_tag, column_major_tag) { typedef F<typename M::iterator1::reference, T> functor_type; typedef typename M::difference_type difference_type; typename M::iterator2 it2 (m.begin2 ()); difference_type size2 (m.end2 () - it2); while (-- size2 >= 0) { #ifndef BOOST_UBLAS_NO_NESTED_CLASS_RELATION typename M::iterator1 it1 (it2.begin ()); difference_type size1 (it2.end () - it1); #else typename M::iterator1 it1 (begin (it2, iterator2_tag ())); difference_type size1 (end (it2, iterator2_tag ()) - it1); #endif while (-- size1 >= 0) functor_type::apply (*it1, t), ++ it1; ++ it2; } } // Sparse (proxy) row major case template<template <class T1, class T2> class F, class M, class T> // BOOST_UBLAS_INLINE This function seems to be big. So we do not let the compiler inline it. void matrix_assign_scalar (M &m, const T &t, sparse_proxy_tag, row_major_tag) { typedef F<typename M::iterator2::reference, T> functor_type; typename M::iterator1 it1 (m.begin1 ()); typename M::iterator1 it1_end (m.end1 ()); while (it1 != it1_end) { #ifndef BOOST_UBLAS_NO_NESTED_CLASS_RELATION typename M::iterator2 it2 (it1.begin ()); typename M::iterator2 it2_end (it1.end ()); #else typename M::iterator2 it2 (begin (it1, iterator1_tag ())); typename M::iterator2 it2_end (end (it1, iterator1_tag ())); #endif while (it2 != it2_end) functor_type::apply (*it2, t), ++ it2; ++ it1; } } // Sparse (proxy) column major case template<template <class T1, class T2> class F, class M, class T> // BOOST_UBLAS_INLINE This function seems to be big. So we do not let the compiler inline it. void matrix_assign_scalar (M &m, const T &t, sparse_proxy_tag, column_major_tag) { typedef F<typename M::iterator1::reference, T> functor_type; typename M::iterator2 it2 (m.begin2 ()); typename M::iterator2 it2_end (m.end2 ()); while (it2 != it2_end) { #ifndef BOOST_UBLAS_NO_NESTED_CLASS_RELATION typename M::iterator1 it1 (it2.begin ()); typename M::iterator1 it1_end (it2.end ()); #else typename M::iterator1 it1 (begin (it2, iterator2_tag ())); typename M::iterator1 it1_end (end (it2, iterator2_tag ())); #endif while (it1 != it1_end) functor_type::apply (*it1, t), ++ it1; ++ it2; } } // Dispatcher template<template <class T1, class T2> class F, class M, class T> BOOST_UBLAS_INLINE void matrix_assign_scalar (M &m, const T &t) { typedef typename M::storage_category storage_category; typedef typename M::orientation_category orientation_category; matrix_assign_scalar<F> (m, t, storage_category (), orientation_category ()); } template<class SC, bool COMPUTED, class RI1, class RI2> struct matrix_assign_traits { typedef SC storage_category; }; template<bool COMPUTED> struct matrix_assign_traits<dense_tag, COMPUTED, packed_random_access_iterator_tag, packed_random_access_iterator_tag> { typedef packed_tag storage_category; }; template<> struct matrix_assign_traits<dense_tag, false, sparse_bidirectional_iterator_tag, sparse_bidirectional_iterator_tag> { typedef sparse_tag storage_category; }; template<> struct matrix_assign_traits<dense_tag, true, sparse_bidirectional_iterator_tag, sparse_bidirectional_iterator_tag> { typedef sparse_proxy_tag storage_category; }; template<bool COMPUTED> struct matrix_assign_traits<dense_proxy_tag, COMPUTED, packed_random_access_iterator_tag, packed_random_access_iterator_tag> { typedef packed_proxy_tag storage_category; }; template<bool COMPUTED> struct matrix_assign_traits<dense_proxy_tag, COMPUTED, sparse_bidirectional_iterator_tag, sparse_bidirectional_iterator_tag> { typedef sparse_proxy_tag storage_category; }; template<> struct matrix_assign_traits<packed_tag, false, sparse_bidirectional_iterator_tag, sparse_bidirectional_iterator_tag> { typedef sparse_tag storage_category; }; template<> struct matrix_assign_traits<packed_tag, true, sparse_bidirectional_iterator_tag, sparse_bidirectional_iterator_tag> { typedef sparse_proxy_tag storage_category; }; template<bool COMPUTED> struct matrix_assign_traits<packed_proxy_tag, COMPUTED, sparse_bidirectional_iterator_tag, sparse_bidirectional_iterator_tag> { typedef sparse_proxy_tag storage_category; }; template<> struct matrix_assign_traits<sparse_tag, true, dense_random_access_iterator_tag, dense_random_access_iterator_tag> { typedef sparse_proxy_tag storage_category; }; template<> struct matrix_assign_traits<sparse_tag, true, packed_random_access_iterator_tag, packed_random_access_iterator_tag> { typedef sparse_proxy_tag storage_category; }; template<> struct matrix_assign_traits<sparse_tag, true, sparse_bidirectional_iterator_tag, sparse_bidirectional_iterator_tag> { typedef sparse_proxy_tag storage_category; }; // Explicitly iterating row major template<template <class T1, class T2> class F, class M, class E> // BOOST_UBLAS_INLINE This function seems to be big. So we do not let the compiler inline it. void iterating_matrix_assign (M &m, const matrix_expression<E> &e, row_major_tag) { typedef F<typename M::iterator2::reference, typename E::value_type> functor_type; typedef typename M::difference_type difference_type; difference_type size1 (BOOST_UBLAS_SAME (m.size1 (), e ().size1 ())); difference_type size2 (BOOST_UBLAS_SAME (m.size2 (), e ().size2 ())); typename M::iterator1 it1 (m.begin1 ()); BOOST_UBLAS_CHECK (size2 == 0 || m.end1 () - it1 == size1, bad_size ()); typename E::const_iterator1 it1e (e ().begin1 ()); BOOST_UBLAS_CHECK (size2 == 0 || e ().end1 () - it1e == size1, bad_size ()); while (-- size1 >= 0) { #ifndef BOOST_UBLAS_NO_NESTED_CLASS_RELATION typename M::iterator2 it2 (it1.begin ()); typename E::const_iterator2 it2e (it1e.begin ()); #else typename M::iterator2 it2 (begin (it1, iterator1_tag ())); typename E::const_iterator2 it2e (begin (it1e, iterator1_tag ())); #endif BOOST_UBLAS_CHECK (it1.end () - it2 == size2, bad_size ()); BOOST_UBLAS_CHECK (it1e.end () - it2e == size2, bad_size ()); difference_type temp_size2 (size2); #ifndef BOOST_UBLAS_USE_DUFF_DEVICE while (-- temp_size2 >= 0) functor_type::apply (*it2, *it2e), ++ it2, ++ it2e; #else DD (temp_size2, 2, r, (functor_type::apply (*it2, *it2e), ++ it2, ++ it2e)); #endif ++ it1, ++ it1e; } } // Explicitly iterating column major template<template <class T1, class T2> class F, class M, class E> // BOOST_UBLAS_INLINE This function seems to be big. So we do not let the compiler inline it. void iterating_matrix_assign (M &m, const matrix_expression<E> &e, column_major_tag) { typedef F<typename M::iterator1::reference, typename E::value_type> functor_type; typedef typename M::difference_type difference_type; difference_type size2 (BOOST_UBLAS_SAME (m.size2 (), e ().size2 ())); difference_type size1 (BOOST_UBLAS_SAME (m.size1 (), e ().size1 ())); typename M::iterator2 it2 (m.begin2 ()); BOOST_UBLAS_CHECK (size1 == 0 || m.end2 () - it2 == size2, bad_size ()); typename E::const_iterator2 it2e (e ().begin2 ()); BOOST_UBLAS_CHECK (size1 == 0 || e ().end2 () - it2e == size2, bad_size ()); while (-- size2 >= 0) { #ifndef BOOST_UBLAS_NO_NESTED_CLASS_RELATION typename M::iterator1 it1 (it2.begin ()); typename E::const_iterator1 it1e (it2e.begin ()); #else typename M::iterator1 it1 (begin (it2, iterator2_tag ())); typename E::const_iterator1 it1e (begin (it2e, iterator2_tag ())); #endif BOOST_UBLAS_CHECK (it2.end () - it1 == size1, bad_size ()); BOOST_UBLAS_CHECK (it2e.end () - it1e == size1, bad_size ()); difference_type temp_size1 (size1); #ifndef BOOST_UBLAS_USE_DUFF_DEVICE while (-- temp_size1 >= 0) functor_type::apply (*it1, *it1e), ++ it1, ++ it1e; #else DD (temp_size1, 2, r, (functor_type::apply (*it1, *it1e), ++ it1, ++ it1e)); #endif ++ it2, ++ it2e; } } // Explicitly indexing row major template<template <class T1, class T2> class F, class M, class E> // BOOST_UBLAS_INLINE This function seems to be big. So we do not let the compiler inline it. void indexing_matrix_assign (M &m, const matrix_expression<E> &e, row_major_tag) { typedef F<typename M::reference, typename E::value_type> functor_type; typedef typename M::size_type size_type; size_type size1 (BOOST_UBLAS_SAME (m.size1 (), e ().size1 ())); size_type size2 (BOOST_UBLAS_SAME (m.size2 (), e ().size2 ())); for (size_type i = 0; i < size1; ++ i) { #ifndef BOOST_UBLAS_USE_DUFF_DEVICE for (size_type j = 0; j < size2; ++ j) functor_type::apply (m (i, j), e () (i, j)); #else size_type j (0); DD (size2, 2, r, (functor_type::apply (m (i, j), e () (i, j)), ++ j)); #endif } } // Explicitly indexing column major template<template <class T1, class T2> class F, class M, class E> // BOOST_UBLAS_INLINE This function seems to be big. So we do not let the compiler inline it. void indexing_matrix_assign (M &m, const matrix_expression<E> &e, column_major_tag) { typedef F<typename M::reference, typename E::value_type> functor_type; typedef typename M::size_type size_type; size_type size2 (BOOST_UBLAS_SAME (m.size2 (), e ().size2 ())); size_type size1 (BOOST_UBLAS_SAME (m.size1 (), e ().size1 ())); for (size_type j = 0; j < size2; ++ j) { #ifndef BOOST_UBLAS_USE_DUFF_DEVICE for (size_type i = 0; i < size1; ++ i) functor_type::apply (m (i, j), e () (i, j)); #else size_type i (0); DD (size1, 2, r, (functor_type::apply (m (i, j), e () (i, j)), ++ i)); #endif } } // Dense (proxy) case template<template <class T1, class T2> class F, class R, class M, class E, class C> // BOOST_UBLAS_INLINE This function seems to be big. So we do not let the compiler inline it. void matrix_assign (M &m, const matrix_expression<E> &e, dense_proxy_tag, C) { // R unnecessary, make_conformant not required typedef C orientation_category; #ifdef BOOST_UBLAS_USE_INDEXING indexing_matrix_assign<F> (m, e, orientation_category ()); #elif BOOST_UBLAS_USE_ITERATING iterating_matrix_assign<F> (m, e, orientation_category ()); #else typedef typename M::difference_type difference_type; size_type size1 (BOOST_UBLAS_SAME (m.size1 (), e ().size1 ())); size_type size2 (BOOST_UBLAS_SAME (m.size2 (), e ().size2 ())); if (size1 >= BOOST_UBLAS_ITERATOR_THRESHOLD && size2 >= BOOST_UBLAS_ITERATOR_THRESHOLD) iterating_matrix_assign<F> (m, e, orientation_category ()); else indexing_matrix_assign<F> (m, e, orientation_category ()); #endif } // Packed (proxy) row major case template<template <class T1, class T2> class F, class R, class M, class E> // BOOST_UBLAS_INLINE This function seems to be big. So we do not let the compiler inline it. void matrix_assign (M &m, const matrix_expression<E> &e, packed_proxy_tag, row_major_tag) { typedef typename matrix_traits<E>::value_type expr_value_type; typedef F<typename M::iterator2::reference, expr_value_type> functor_type; // R unnecessary, make_conformant not required typedef typename M::difference_type difference_type; BOOST_UBLAS_CHECK (m.size1 () == e ().size1 (), bad_size ()); BOOST_UBLAS_CHECK (m.size2 () == e ().size2 (), bad_size ()); #if BOOST_UBLAS_TYPE_CHECK typedef typename M::value_type value_type; matrix<value_type, row_major> cm (m.size1 (), m.size2 ()); indexing_matrix_assign<scalar_assign> (cm, m, row_major_tag ()); indexing_matrix_assign<F> (cm, e, row_major_tag ()); #endif typename M::iterator1 it1 (m.begin1 ()); typename M::iterator1 it1_end (m.end1 ()); typename E::const_iterator1 it1e (e ().begin1 ()); typename E::const_iterator1 it1e_end (e ().end1 ()); difference_type it1_size (it1_end - it1); difference_type it1e_size (it1e_end - it1e); difference_type diff1 (0); if (it1_size > 0 && it1e_size > 0) diff1 = it1.index1 () - it1e.index1 (); if (diff1 != 0) { difference_type size1 = (std::min) (diff1, it1e_size); if (size1 > 0) { it1e += size1; it1e_size -= size1; diff1 -= size1; } size1 = (std::min) (- diff1, it1_size); if (size1 > 0) { it1_size -= size1; //Disabled warning C4127 because the conditional expression is constant #ifdef _MSC_VER #pragma warning(push) #pragma warning(disable: 4127) #endif if (!functor_type::computed) { #ifdef _MSC_VER #pragma warning(pop) #endif while (-- size1 >= 0) { // zeroing #ifndef BOOST_UBLAS_NO_NESTED_CLASS_RELATION typename M::iterator2 it2 (it1.begin ()); typename M::iterator2 it2_end (it1.end ()); #else typename M::iterator2 it2 (begin (it1, iterator1_tag ())); typename M::iterator2 it2_end (end (it1, iterator1_tag ())); #endif difference_type size2 (it2_end - it2); while (-- size2 >= 0) functor_type::apply (*it2, expr_value_type/*zero*/()), ++ it2; ++ it1; } } else { it1 += size1; } diff1 += size1; } } difference_type size1 ((std::min) (it1_size, it1e_size)); it1_size -= size1; it1e_size -= size1; while (-- size1 >= 0) { #ifndef BOOST_UBLAS_NO_NESTED_CLASS_RELATION typename M::iterator2 it2 (it1.begin ()); typename M::iterator2 it2_end (it1.end ()); typename E::const_iterator2 it2e (it1e.begin ()); typename E::const_iterator2 it2e_end (it1e.end ()); #else typename M::iterator2 it2 (begin (it1, iterator1_tag ())); typename M::iterator2 it2_end (end (it1, iterator1_tag ())); typename E::const_iterator2 it2e (begin (it1e, iterator1_tag ())); typename E::const_iterator2 it2e_end (end (it1e, iterator1_tag ())); #endif difference_type it2_size (it2_end - it2); difference_type it2e_size (it2e_end - it2e); difference_type diff2 (0); if (it2_size > 0 && it2e_size > 0) { diff2 = it2.index2 () - it2e.index2 (); difference_type size2 = (std::min) (diff2, it2e_size); if (size2 > 0) { it2e += size2; it2e_size -= size2; diff2 -= size2; } size2 = (std::min) (- diff2, it2_size); if (size2 > 0) { it2_size -= size2; //Disabled warning C4127 because the conditional expression is constant #ifdef _MSC_VER #pragma warning(push) #pragma warning(disable: 4127) #endif if (!functor_type::computed) { #ifdef _MSC_VER #pragma warning(pop) #endif while (-- size2 >= 0) // zeroing functor_type::apply (*it2, expr_value_type/*zero*/()), ++ it2; } else { it2 += size2; } diff2 += size2; } } difference_type size2 ((std::min) (it2_size, it2e_size)); it2_size -= size2; it2e_size -= size2; while (-- size2 >= 0) functor_type::apply (*it2, *it2e), ++ it2, ++ it2e; size2 = it2_size; //Disabled warning C4127 because the conditional expression is constant #ifdef _MSC_VER #pragma warning(push) #pragma warning(disable: 4127) #endif if (!functor_type::computed) { #ifdef _MSC_VER #pragma warning(pop) #endif while (-- size2 >= 0) // zeroing functor_type::apply (*it2, expr_value_type/*zero*/()), ++ it2; } else { it2 += size2; } ++ it1, ++ it1e; } size1 = it1_size; //Disabled warning C4127 because the conditional expression is constant #ifdef _MSC_VER #pragma warning(push) #pragma warning(disable: 4127) #endif if (!functor_type::computed) { #ifdef _MSC_VER #pragma warning(pop) #endif while (-- size1 >= 0) { // zeroing #ifndef BOOST_UBLAS_NO_NESTED_CLASS_RELATION typename M::iterator2 it2 (it1.begin ()); typename M::iterator2 it2_end (it1.end ()); #else typename M::iterator2 it2 (begin (it1, iterator1_tag ())); typename M::iterator2 it2_end (end (it1, iterator1_tag ())); #endif difference_type size2 (it2_end - it2); while (-- size2 >= 0) functor_type::apply (*it2, expr_value_type/*zero*/()), ++ it2; ++ it1; } } else { it1 += size1; } #if BOOST_UBLAS_TYPE_CHECK if (! disable_type_check<bool>::value) BOOST_UBLAS_CHECK (detail::expression_type_check (m, cm), external_logic ()); #endif } // Packed (proxy) column major case template<template <class T1, class T2> class F, class R, class M, class E> // BOOST_UBLAS_INLINE This function seems to be big. So we do not let the compiler inline it. void matrix_assign (M &m, const matrix_expression<E> &e, packed_proxy_tag, column_major_tag) { typedef typename matrix_traits<E>::value_type expr_value_type; typedef F<typename M::iterator1::reference, expr_value_type> functor_type; // R unnecessary, make_conformant not required typedef typename M::difference_type difference_type; BOOST_UBLAS_CHECK (m.size2 () == e ().size2 (), bad_size ()); BOOST_UBLAS_CHECK (m.size1 () == e ().size1 (), bad_size ()); #if BOOST_UBLAS_TYPE_CHECK typedef typename M::value_type value_type; matrix<value_type, column_major> cm (m.size1 (), m.size2 ()); indexing_matrix_assign<scalar_assign> (cm, m, column_major_tag ()); indexing_matrix_assign<F> (cm, e, column_major_tag ()); #endif typename M::iterator2 it2 (m.begin2 ()); typename M::iterator2 it2_end (m.end2 ()); typename E::const_iterator2 it2e (e ().begin2 ()); typename E::const_iterator2 it2e_end (e ().end2 ()); difference_type it2_size (it2_end - it2); difference_type it2e_size (it2e_end - it2e); difference_type diff2 (0); if (it2_size > 0 && it2e_size > 0) diff2 = it2.index2 () - it2e.index2 (); if (diff2 != 0) { difference_type size2 = (std::min) (diff2, it2e_size); if (size2 > 0) { it2e += size2; it2e_size -= size2; diff2 -= size2; } size2 = (std::min) (- diff2, it2_size); if (size2 > 0) { it2_size -= size2; //Disabled warning C4127 because the conditional expression is constant #ifdef _MSC_VER #pragma warning(push) #pragma warning(disable: 4127) #endif if (!functor_type::computed) { #ifdef _MSC_VER #pragma warning(pop) #endif while (-- size2 >= 0) { // zeroing #ifndef BOOST_UBLAS_NO_NESTED_CLASS_RELATION typename M::iterator1 it1 (it2.begin ()); typename M::iterator1 it1_end (it2.end ()); #else typename M::iterator1 it1 (begin (it2, iterator2_tag ())); typename M::iterator1 it1_end (end (it2, iterator2_tag ())); #endif difference_type size1 (it1_end - it1); while (-- size1 >= 0) functor_type::apply (*it1, expr_value_type/*zero*/()), ++ it1; ++ it2; } } else { it2 += size2; } diff2 += size2; } } difference_type size2 ((std::min) (it2_size, it2e_size)); it2_size -= size2; it2e_size -= size2; while (-- size2 >= 0) { #ifndef BOOST_UBLAS_NO_NESTED_CLASS_RELATION typename M::iterator1 it1 (it2.begin ()); typename M::iterator1 it1_end (it2.end ()); typename E::const_iterator1 it1e (it2e.begin ()); typename E::const_iterator1 it1e_end (it2e.end ()); #else typename M::iterator1 it1 (begin (it2, iterator2_tag ())); typename M::iterator1 it1_end (end (it2, iterator2_tag ())); typename E::const_iterator1 it1e (begin (it2e, iterator2_tag ())); typename E::const_iterator1 it1e_end (end (it2e, iterator2_tag ())); #endif difference_type it1_size (it1_end - it1); difference_type it1e_size (it1e_end - it1e); difference_type diff1 (0); if (it1_size > 0 && it1e_size > 0) { diff1 = it1.index1 () - it1e.index1 (); difference_type size1 = (std::min) (diff1, it1e_size); if (size1 > 0) { it1e += size1; it1e_size -= size1; diff1 -= size1; } size1 = (std::min) (- diff1, it1_size); if (size1 > 0) { it1_size -= size1; //Disabled warning C4127 because the conditional expression is constant #ifdef _MSC_VER #pragma warning(push) #pragma warning(disable: 4127) #endif if (!functor_type::computed) { #ifdef _MSC_VER #pragma warning(pop) #endif while (-- size1 >= 0) // zeroing functor_type::apply (*it1, expr_value_type/*zero*/()), ++ it1; } else { it1 += size1; } diff1 += size1; } } difference_type size1 ((std::min) (it1_size, it1e_size)); it1_size -= size1; it1e_size -= size1; while (-- size1 >= 0) functor_type::apply (*it1, *it1e), ++ it1, ++ it1e; size1 = it1_size; //Disabled warning C4127 because the conditional expression is constant #ifdef _MSC_VER #pragma warning(push) #pragma warning(disable: 4127) #endif if (!functor_type::computed) { #ifdef _MSC_VER #pragma warning(pop) #endif while (-- size1 >= 0) // zeroing functor_type::apply (*it1, expr_value_type/*zero*/()), ++ it1; } else { it1 += size1; } ++ it2, ++ it2e; } size2 = it2_size; //Disabled warning C4127 because the conditional expression is constant #ifdef _MSC_VER #pragma warning(push) #pragma warning(disable: 4127) #endif if (!functor_type::computed) { #ifdef _MSC_VER #pragma warning(pop) #endif while (-- size2 >= 0) { // zeroing #ifndef BOOST_UBLAS_NO_NESTED_CLASS_RELATION typename M::iterator1 it1 (it2.begin ()); typename M::iterator1 it1_end (it2.end ()); #else typename M::iterator1 it1 (begin (it2, iterator2_tag ())); typename M::iterator1 it1_end (end (it2, iterator2_tag ())); #endif difference_type size1 (it1_end - it1); while (-- size1 >= 0) functor_type::apply (*it1, expr_value_type/*zero*/()), ++ it1; ++ it2; } } else { it2 += size2; } #if BOOST_UBLAS_TYPE_CHECK if (! disable_type_check<bool>::value) BOOST_UBLAS_CHECK (detail::expression_type_check (m, cm), external_logic ()); #endif } // Sparse row major case template<template <class T1, class T2> class F, class R, class M, class E> // BOOST_UBLAS_INLINE This function seems to be big. So we do not let the compiler inline it. void matrix_assign (M &m, const matrix_expression<E> &e, sparse_tag, row_major_tag) { typedef F<typename M::iterator2::reference, typename E::value_type> functor_type; // R unnecessary, make_conformant not required //Disabled warning C4127 because the conditional expression is constant #ifdef _MSC_VER #pragma warning(push) #pragma warning(disable: 4127) #endif BOOST_STATIC_ASSERT ((!functor_type::computed)); #ifdef _MSC_VER #pragma warning(pop) #endif BOOST_UBLAS_CHECK (m.size1 () == e ().size1 (), bad_size ()); BOOST_UBLAS_CHECK (m.size2 () == e ().size2 (), bad_size ()); typedef typename M::value_type value_type; // Sparse type has no numeric constraints to check m.clear (); typename E::const_iterator1 it1e (e ().begin1 ()); typename E::const_iterator1 it1e_end (e ().end1 ()); while (it1e != it1e_end) { #ifndef BOOST_UBLAS_NO_NESTED_CLASS_RELATION typename E::const_iterator2 it2e (it1e.begin ()); typename E::const_iterator2 it2e_end (it1e.end ()); #else typename E::const_iterator2 it2e (begin (it1e, iterator1_tag ())); typename E::const_iterator2 it2e_end (end (it1e, iterator1_tag ())); #endif while (it2e != it2e_end) { value_type t (*it2e); if (t != value_type/*zero*/()) m.insert_element (it2e.index1 (), it2e.index2 (), t); ++ it2e; } ++ it1e; } } // Sparse column major case template<template <class T1, class T2> class F, class R, class M, class E> // BOOST_UBLAS_INLINE This function seems to be big. So we do not let the compiler inline it. void matrix_assign (M &m, const matrix_expression<E> &e, sparse_tag, column_major_tag) { typedef F<typename M::iterator1::reference, typename E::value_type> functor_type; // R unnecessary, make_conformant not required //Disabled warning C4127 because the conditional expression is constant #ifdef _MSC_VER #pragma warning(push) #pragma warning(disable: 4127) #endif BOOST_STATIC_ASSERT ((!functor_type::computed)); #ifdef _MSC_VER #pragma warning(pop) #endif BOOST_UBLAS_CHECK (m.size1 () == e ().size1 (), bad_size ()); BOOST_UBLAS_CHECK (m.size2 () == e ().size2 (), bad_size ()); typedef typename M::value_type value_type; // Sparse type has no numeric constraints to check m.clear (); typename E::const_iterator2 it2e (e ().begin2 ()); typename E::const_iterator2 it2e_end (e ().end2 ()); while (it2e != it2e_end) { #ifndef BOOST_UBLAS_NO_NESTED_CLASS_RELATION typename E::const_iterator1 it1e (it2e.begin ()); typename E::const_iterator1 it1e_end (it2e.end ()); #else typename E::const_iterator1 it1e (begin (it2e, iterator2_tag ())); typename E::const_iterator1 it1e_end (end (it2e, iterator2_tag ())); #endif while (it1e != it1e_end) { value_type t (*it1e); if (t != value_type/*zero*/()) m.insert_element (it1e.index1 (), it1e.index2 (), t); ++ it1e; } ++ it2e; } } // Sparse proxy or functional row major case template<template <class T1, class T2> class F, class R, class M, class E> // BOOST_UBLAS_INLINE This function seems to be big. So we do not let the compiler inline it. void matrix_assign (M &m, const matrix_expression<E> &e, sparse_proxy_tag, row_major_tag) { typedef typename matrix_traits<E>::value_type expr_value_type; typedef F<typename M::iterator2::reference, expr_value_type> functor_type; typedef R conformant_restrict_type; typedef typename M::size_type size_type; typedef typename M::difference_type difference_type; BOOST_UBLAS_CHECK (m.size1 () == e ().size1 (), bad_size ()); BOOST_UBLAS_CHECK (m.size2 () == e ().size2 (), bad_size ()); #if BOOST_UBLAS_TYPE_CHECK typedef typename M::value_type value_type; matrix<value_type, row_major> cm (m.size1 (), m.size2 ()); indexing_matrix_assign<scalar_assign> (cm, m, row_major_tag ()); indexing_matrix_assign<F> (cm, e, row_major_tag ()); #endif detail::make_conformant (m, e, row_major_tag (), conformant_restrict_type ()); typename M::iterator1 it1 (m.begin1 ()); typename M::iterator1 it1_end (m.end1 ()); typename E::const_iterator1 it1e (e ().begin1 ()); typename E::const_iterator1 it1e_end (e ().end1 ()); while (it1 != it1_end && it1e != it1e_end) { difference_type compare = it1.index1 () - it1e.index1 (); if (compare == 0) { #ifndef BOOST_UBLAS_NO_NESTED_CLASS_RELATION typename M::iterator2 it2 (it1.begin ()); typename M::iterator2 it2_end (it1.end ()); typename E::const_iterator2 it2e (it1e.begin ()); typename E::const_iterator2 it2e_end (it1e.end ()); #else typename M::iterator2 it2 (begin (it1, iterator1_tag ())); typename M::iterator2 it2_end (end (it1, iterator1_tag ())); typename E::const_iterator2 it2e (begin (it1e, iterator1_tag ())); typename E::const_iterator2 it2e_end (end (it1e, iterator1_tag ())); #endif if (it2 != it2_end && it2e != it2e_end) { size_type it2_index = it2.index2 (), it2e_index = it2e.index2 (); for (;;) { difference_type compare2 = it2_index - it2e_index; if (compare2 == 0) { functor_type::apply (*it2, *it2e); ++ it2, ++ it2e; if (it2 != it2_end && it2e != it2e_end) { it2_index = it2.index2 (); it2e_index = it2e.index2 (); } else break; } else if (compare2 < 0) { //Disabled warning C4127 because the conditional expression is constant #ifdef _MSC_VER #pragma warning(push) #pragma warning(disable: 4127) #endif if (!functor_type::computed) { #ifdef _MSC_VER #pragma warning(pop) #endif functor_type::apply (*it2, expr_value_type/*zero*/()); ++ it2; } else increment (it2, it2_end, - compare2); if (it2 != it2_end) it2_index = it2.index2 (); else break; } else if (compare2 > 0) { increment (it2e, it2e_end, compare2); if (it2e != it2e_end) it2e_index = it2e.index2 (); else break; } } } //Disabled warning C4127 because the conditional expression is constant #ifdef _MSC_VER #pragma warning(push) #pragma warning(disable: 4127) #endif if (!functor_type::computed) { #ifdef _MSC_VER #pragma warning(pop) #endif while (it2 != it2_end) { // zeroing functor_type::apply (*it2, expr_value_type/*zero*/()); ++ it2; } } else { it2 = it2_end; } ++ it1, ++ it1e; } else if (compare < 0) { //Disabled warning C4127 because the conditional expression is constant #ifdef _MSC_VER #pragma warning(push) #pragma warning(disable: 4127) #endif if (!functor_type::computed) { #ifdef _MSC_VER #pragma warning(pop) #endif #ifndef BOOST_UBLAS_NO_NESTED_CLASS_RELATION typename M::iterator2 it2 (it1.begin ()); typename M::iterator2 it2_end (it1.end ()); #else typename M::iterator2 it2 (begin (it1, iterator1_tag ())); typename M::iterator2 it2_end (end (it1, iterator1_tag ())); #endif while (it2 != it2_end) { // zeroing functor_type::apply (*it2, expr_value_type/*zero*/()); ++ it2; } ++ it1; } else { increment (it1, it1_end, - compare); } } else if (compare > 0) { increment (it1e, it1e_end, compare); } } //Disabled warning C4127 because the conditional expression is constant #ifdef _MSC_VER #pragma warning(push) #pragma warning(disable: 4127) #endif if (!functor_type::computed) { #ifdef _MSC_VER #pragma warning(pop) #endif while (it1 != it1_end) { #ifndef BOOST_UBLAS_NO_NESTED_CLASS_RELATION typename M::iterator2 it2 (it1.begin ()); typename M::iterator2 it2_end (it1.end ()); #else typename M::iterator2 it2 (begin (it1, iterator1_tag ())); typename M::iterator2 it2_end (end (it1, iterator1_tag ())); #endif while (it2 != it2_end) { // zeroing functor_type::apply (*it2, expr_value_type/*zero*/()); ++ it2; } ++ it1; } } else { it1 = it1_end; } #if BOOST_UBLAS_TYPE_CHECK if (! disable_type_check<bool>::value) BOOST_UBLAS_CHECK (detail::expression_type_check (m, cm), external_logic ()); #endif } // Sparse proxy or functional column major case template<template <class T1, class T2> class F, class R, class M, class E> // BOOST_UBLAS_INLINE This function seems to be big. So we do not let the compiler inline it. void matrix_assign (M &m, const matrix_expression<E> &e, sparse_proxy_tag, column_major_tag) { typedef typename matrix_traits<E>::value_type expr_value_type; typedef F<typename M::iterator1::reference, expr_value_type> functor_type; typedef R conformant_restrict_type; typedef typename M::size_type size_type; typedef typename M::difference_type difference_type; BOOST_UBLAS_CHECK (m.size1 () == e ().size1 (), bad_size ()); BOOST_UBLAS_CHECK (m.size2 () == e ().size2 (), bad_size ()); #if BOOST_UBLAS_TYPE_CHECK typedef typename M::value_type value_type; matrix<value_type, column_major> cm (m.size1 (), m.size2 ()); indexing_matrix_assign<scalar_assign> (cm, m, column_major_tag ()); indexing_matrix_assign<F> (cm, e, column_major_tag ()); #endif detail::make_conformant (m, e, column_major_tag (), conformant_restrict_type ()); typename M::iterator2 it2 (m.begin2 ()); typename M::iterator2 it2_end (m.end2 ()); typename E::const_iterator2 it2e (e ().begin2 ()); typename E::const_iterator2 it2e_end (e ().end2 ()); while (it2 != it2_end && it2e != it2e_end) { difference_type compare = it2.index2 () - it2e.index2 (); if (compare == 0) { #ifndef BOOST_UBLAS_NO_NESTED_CLASS_RELATION typename M::iterator1 it1 (it2.begin ()); typename M::iterator1 it1_end (it2.end ()); typename E::const_iterator1 it1e (it2e.begin ()); typename E::const_iterator1 it1e_end (it2e.end ()); #else typename M::iterator1 it1 (begin (it2, iterator2_tag ())); typename M::iterator1 it1_end (end (it2, iterator2_tag ())); typename E::const_iterator1 it1e (begin (it2e, iterator2_tag ())); typename E::const_iterator1 it1e_end (end (it2e, iterator2_tag ())); #endif if (it1 != it1_end && it1e != it1e_end) { size_type it1_index = it1.index1 (), it1e_index = it1e.index1 (); for (;;) { difference_type compare2 = it1_index - it1e_index; if (compare2 == 0) { functor_type::apply (*it1, *it1e); ++ it1, ++ it1e; if (it1 != it1_end && it1e != it1e_end) { it1_index = it1.index1 (); it1e_index = it1e.index1 (); } else break; } else if (compare2 < 0) { //Disabled warning C4127 because the conditional expression is constant #ifdef _MSC_VER #pragma warning(push) #pragma warning(disable: 4127) #endif if (!functor_type::computed) { #ifdef _MSC_VER #pragma warning(pop) #endif functor_type::apply (*it1, expr_value_type/*zero*/()); // zeroing ++ it1; } else increment (it1, it1_end, - compare2); if (it1 != it1_end) it1_index = it1.index1 (); else break; } else if (compare2 > 0) { increment (it1e, it1e_end, compare2); if (it1e != it1e_end) it1e_index = it1e.index1 (); else break; } } } //Disabled warning C4127 because the conditional expression is constant #ifdef _MSC_VER #pragma warning(push) #pragma warning(disable: 4127) #endif if (!functor_type::computed) { #ifdef _MSC_VER #pragma warning(pop) #endif while (it1 != it1_end) { // zeroing functor_type::apply (*it1, expr_value_type/*zero*/()); ++ it1; } } else { it1 = it1_end; } ++ it2, ++ it2e; } else if (compare < 0) { //Disabled warning C4127 because the conditional expression is constant #ifdef _MSC_VER #pragma warning(push) #pragma warning(disable: 4127) #endif if (!functor_type::computed) { #ifdef _MSC_VER #pragma warning(pop) #endif #ifndef BOOST_UBLAS_NO_NESTED_CLASS_RELATION typename M::iterator1 it1 (it2.begin ()); typename M::iterator1 it1_end (it2.end ()); #else typename M::iterator1 it1 (begin (it2, iterator2_tag ())); typename M::iterator1 it1_end (end (it2, iterator2_tag ())); #endif while (it1 != it1_end) { // zeroing functor_type::apply (*it1, expr_value_type/*zero*/()); ++ it1; } ++ it2; } else { increment (it2, it2_end, - compare); } } else if (compare > 0) { increment (it2e, it2e_end, compare); } } //Disabled warning C4127 because the conditional expression is constant #ifdef _MSC_VER #pragma warning(push) #pragma warning(disable: 4127) #endif if (!functor_type::computed) { #ifdef _MSC_VER #pragma warning(pop) #endif while (it2 != it2_end) { #ifndef BOOST_UBLAS_NO_NESTED_CLASS_RELATION typename M::iterator1 it1 (it2.begin ()); typename M::iterator1 it1_end (it2.end ()); #else typename M::iterator1 it1 (begin (it2, iterator2_tag ())); typename M::iterator1 it1_end (end (it2, iterator2_tag ())); #endif while (it1 != it1_end) { // zeroing functor_type::apply (*it1, expr_value_type/*zero*/()); ++ it1; } ++ it2; } } else { it2 = it2_end; } #if BOOST_UBLAS_TYPE_CHECK if (! disable_type_check<bool>::value) BOOST_UBLAS_CHECK (detail::expression_type_check (m, cm), external_logic ()); #endif } // Dispatcher template<template <class T1, class T2> class F, class M, class E> BOOST_UBLAS_INLINE void matrix_assign (M &m, const matrix_expression<E> &e) { typedef typename matrix_assign_traits<typename M::storage_category, F<typename M::reference, typename E::value_type>::computed, typename E::const_iterator1::iterator_category, typename E::const_iterator2::iterator_category>::storage_category storage_category; // give preference to matrix M's orientation if known typedef typename boost::mpl::if_<boost::is_same<typename M::orientation_category, unknown_orientation_tag>, typename E::orientation_category , typename M::orientation_category >::type orientation_category; typedef basic_full<typename M::size_type> unrestricted; matrix_assign<F, unrestricted> (m, e, storage_category (), orientation_category ()); } template<template <class T1, class T2> class F, class R, class M, class E> BOOST_UBLAS_INLINE void matrix_assign (M &m, const matrix_expression<E> &e) { typedef R conformant_restrict_type; typedef typename matrix_assign_traits<typename M::storage_category, F<typename M::reference, typename E::value_type>::computed, typename E::const_iterator1::iterator_category, typename E::const_iterator2::iterator_category>::storage_category storage_category; // give preference to matrix M's orientation if known typedef typename boost::mpl::if_<boost::is_same<typename M::orientation_category, unknown_orientation_tag>, typename E::orientation_category , typename M::orientation_category >::type orientation_category; matrix_assign<F, conformant_restrict_type> (m, e, storage_category (), orientation_category ()); } template<class SC, class RI1, class RI2> struct matrix_swap_traits { typedef SC storage_category; }; template<> struct matrix_swap_traits<dense_proxy_tag, sparse_bidirectional_iterator_tag, sparse_bidirectional_iterator_tag> { typedef sparse_proxy_tag storage_category; }; template<> struct matrix_swap_traits<packed_proxy_tag, sparse_bidirectional_iterator_tag, sparse_bidirectional_iterator_tag> { typedef sparse_proxy_tag storage_category; }; // Dense (proxy) row major case template<template <class T1, class T2> class F, class R, class M, class E> // BOOST_UBLAS_INLINE This function seems to be big. So we do not let the compiler inline it. void matrix_swap (M &m, matrix_expression<E> &e, dense_proxy_tag, row_major_tag) { typedef F<typename M::iterator2::reference, typename E::reference> functor_type; // R unnecessary, make_conformant not required //typedef typename M::size_type size_type; // gcc is complaining that this is not used, although this is not right typedef typename M::difference_type difference_type; typename M::iterator1 it1 (m.begin1 ()); typename E::iterator1 it1e (e ().begin1 ()); difference_type size1 (BOOST_UBLAS_SAME (m.size1 (), typename M::size_type (e ().end1 () - it1e))); while (-- size1 >= 0) { #ifndef BOOST_UBLAS_NO_NESTED_CLASS_RELATION typename M::iterator2 it2 (it1.begin ()); typename E::iterator2 it2e (it1e.begin ()); difference_type size2 (BOOST_UBLAS_SAME (m.size2 (), typename M::size_type (it1e.end () - it2e))); #else typename M::iterator2 it2 (begin (it1, iterator1_tag ())); typename E::iterator2 it2e (begin (it1e, iterator1_tag ())); difference_type size2 (BOOST_UBLAS_SAME (m.size2 (), typename M::size_type (end (it1e, iterator1_tag ()) - it2e))); #endif while (-- size2 >= 0) functor_type::apply (*it2, *it2e), ++ it2, ++ it2e; ++ it1, ++ it1e; } } // Dense (proxy) column major case template<template <class T1, class T2> class F, class R, class M, class E> // BOOST_UBLAS_INLINE This function seems to be big. So we do not let the compiler inline it. void matrix_swap (M &m, matrix_expression<E> &e, dense_proxy_tag, column_major_tag) { typedef F<typename M::iterator1::reference, typename E::reference> functor_type; // R unnecessary, make_conformant not required // typedef typename M::size_type size_type; // gcc is complaining that this is not used, although this is not right typedef typename M::difference_type difference_type; typename M::iterator2 it2 (m.begin2 ()); typename E::iterator2 it2e (e ().begin2 ()); difference_type size2 (BOOST_UBLAS_SAME (m.size2 (), typename M::size_type (e ().end2 () - it2e))); while (-- size2 >= 0) { #ifndef BOOST_UBLAS_NO_NESTED_CLASS_RELATION typename M::iterator1 it1 (it2.begin ()); typename E::iterator1 it1e (it2e.begin ()); difference_type size1 (BOOST_UBLAS_SAME (m.size1 (), typename M::size_type (it2e.end () - it1e))); #else typename M::iterator1 it1 (begin (it2, iterator2_tag ())); typename E::iterator1 it1e (begin (it2e, iterator2_tag ())); difference_type size1 (BOOST_UBLAS_SAME (m.size1 (), typename M::size_type (end (it2e, iterator2_tag ()) - it1e))); #endif while (-- size1 >= 0) functor_type::apply (*it1, *it1e), ++ it1, ++ it1e; ++ it2, ++ it2e; } } // Packed (proxy) row major case template<template <class T1, class T2> class F, class R, class M, class E> // BOOST_UBLAS_INLINE This function seems to be big. So we do not let the compiler inline it. void matrix_swap (M &m, matrix_expression<E> &e, packed_proxy_tag, row_major_tag) { typedef F<typename M::iterator2::reference, typename E::reference> functor_type; // R unnecessary, make_conformant not required typedef typename M::difference_type difference_type; typename M::iterator1 it1 (m.begin1 ()); typename E::iterator1 it1e (e ().begin1 ()); difference_type size1 (BOOST_UBLAS_SAME (m.end1 () - it1, e ().end1 () - it1e)); while (-- size1 >= 0) { #ifndef BOOST_UBLAS_NO_NESTED_CLASS_RELATION typename M::iterator2 it2 (it1.begin ()); typename E::iterator2 it2e (it1e.begin ()); difference_type size2 (BOOST_UBLAS_SAME (it1.end () - it2, it1e.end () - it2e)); #else typename M::iterator2 it2 (begin (it1, iterator1_tag ())); typename E::iterator2 it2e (begin (it1e, iterator1_tag ())); difference_type size2 (BOOST_UBLAS_SAME (end (it1, iterator1_tag ()) - it2, end (it1e, iterator1_tag ()) - it2e)); #endif while (-- size2 >= 0) functor_type::apply (*it2, *it2e), ++ it2, ++ it2e; ++ it1, ++ it1e; } } // Packed (proxy) column major case template<template <class T1, class T2> class F, class R, class M, class E> // BOOST_UBLAS_INLINE This function seems to be big. So we do not let the compiler inline it. void matrix_swap (M &m, matrix_expression<E> &e, packed_proxy_tag, column_major_tag) { typedef F<typename M::iterator1::reference, typename E::reference> functor_type; // R unnecessary, make_conformant not required typedef typename M::difference_type difference_type; typename M::iterator2 it2 (m.begin2 ()); typename E::iterator2 it2e (e ().begin2 ()); difference_type size2 (BOOST_UBLAS_SAME (m.end2 () - it2, e ().end2 () - it2e)); while (-- size2 >= 0) { #ifndef BOOST_UBLAS_NO_NESTED_CLASS_RELATION typename M::iterator1 it1 (it2.begin ()); typename E::iterator1 it1e (it2e.begin ()); difference_type size1 (BOOST_UBLAS_SAME (it2.end () - it1, it2e.end () - it1e)); #else typename M::iterator1 it1 (begin (it2, iterator2_tag ())); typename E::iterator1 it1e (begin (it2e, iterator2_tag ())); difference_type size1 (BOOST_UBLAS_SAME (end (it2, iterator2_tag ()) - it1, end (it2e, iterator2_tag ()) - it1e)); #endif while (-- size1 >= 0) functor_type::apply (*it1, *it1e), ++ it1, ++ it1e; ++ it2, ++ it2e; } } // Sparse (proxy) row major case template<template <class T1, class T2> class F, class R, class M, class E> // BOOST_UBLAS_INLINE This function seems to be big. So we do not let the compiler inline it. void matrix_swap (M &m, matrix_expression<E> &e, sparse_proxy_tag, row_major_tag) { typedef F<typename M::iterator2::reference, typename E::reference> functor_type; typedef R conformant_restrict_type; typedef typename M::size_type size_type; typedef typename M::difference_type difference_type; BOOST_UBLAS_CHECK (m.size1 () == e ().size1 (), bad_size ()); BOOST_UBLAS_CHECK (m.size2 () == e ().size2 (), bad_size ()); detail::make_conformant (m, e, row_major_tag (), conformant_restrict_type ()); // FIXME should be a seperate restriction for E detail::make_conformant (e (), m, row_major_tag (), conformant_restrict_type ()); typename M::iterator1 it1 (m.begin1 ()); typename M::iterator1 it1_end (m.end1 ()); typename E::iterator1 it1e (e ().begin1 ()); typename E::iterator1 it1e_end (e ().end1 ()); while (it1 != it1_end && it1e != it1e_end) { difference_type compare = it1.index1 () - it1e.index1 (); if (compare == 0) { #ifndef BOOST_UBLAS_NO_NESTED_CLASS_RELATION typename M::iterator2 it2 (it1.begin ()); typename M::iterator2 it2_end (it1.end ()); typename E::iterator2 it2e (it1e.begin ()); typename E::iterator2 it2e_end (it1e.end ()); #else typename M::iterator2 it2 (begin (it1, iterator1_tag ())); typename M::iterator2 it2_end (end (it1, iterator1_tag ())); typename E::iterator2 it2e (begin (it1e, iterator1_tag ())); typename E::iterator2 it2e_end (end (it1e, iterator1_tag ())); #endif if (it2 != it2_end && it2e != it2e_end) { size_type it2_index = it2.index2 (), it2e_index = it2e.index2 (); for (;;) { difference_type compare2 = it2_index - it2e_index; if (compare2 == 0) { functor_type::apply (*it2, *it2e); ++ it2, ++ it2e; if (it2 != it2_end && it2e != it2e_end) { it2_index = it2.index2 (); it2e_index = it2e.index2 (); } else break; } else if (compare2 < 0) { increment (it2, it2_end, - compare2); if (it2 != it2_end) it2_index = it2.index2 (); else break; } else if (compare2 > 0) { increment (it2e, it2e_end, compare2); if (it2e != it2e_end) it2e_index = it2e.index2 (); else break; } } } #if BOOST_UBLAS_TYPE_CHECK increment (it2e, it2e_end); increment (it2, it2_end); #endif ++ it1, ++ it1e; } else if (compare < 0) { #if BOOST_UBLAS_TYPE_CHECK while (it1.index1 () < it1e.index1 ()) { #ifndef BOOST_UBLAS_NO_NESTED_CLASS_RELATION typename M::iterator2 it2 (it1.begin ()); typename M::iterator2 it2_end (it1.end ()); #else typename M::iterator2 it2 (begin (it1, iterator1_tag ())); typename M::iterator2 it2_end (end (it1, iterator1_tag ())); #endif increment (it2, it2_end); ++ it1; } #else increment (it1, it1_end, - compare); #endif } else if (compare > 0) { #if BOOST_UBLAS_TYPE_CHECK while (it1e.index1 () < it1.index1 ()) { #ifndef BOOST_UBLAS_NO_NESTED_CLASS_RELATION typename E::iterator2 it2e (it1e.begin ()); typename E::iterator2 it2e_end (it1e.end ()); #else typename E::iterator2 it2e (begin (it1e, iterator1_tag ())); typename E::iterator2 it2e_end (end (it1e, iterator1_tag ())); #endif increment (it2e, it2e_end); ++ it1e; } #else increment (it1e, it1e_end, compare); #endif } } #if BOOST_UBLAS_TYPE_CHECK while (it1e != it1e_end) { #ifndef BOOST_UBLAS_NO_NESTED_CLASS_RELATION typename E::iterator2 it2e (it1e.begin ()); typename E::iterator2 it2e_end (it1e.end ()); #else typename E::iterator2 it2e (begin (it1e, iterator1_tag ())); typename E::iterator2 it2e_end (end (it1e, iterator1_tag ())); #endif increment (it2e, it2e_end); ++ it1e; } while (it1 != it1_end) { #ifndef BOOST_UBLAS_NO_NESTED_CLASS_RELATION typename M::iterator2 it2 (it1.begin ()); typename M::iterator2 it2_end (it1.end ()); #else typename M::iterator2 it2 (begin (it1, iterator1_tag ())); typename M::iterator2 it2_end (end (it1, iterator1_tag ())); #endif increment (it2, it2_end); ++ it1; } #endif } // Sparse (proxy) column major case template<template <class T1, class T2> class F, class R, class M, class E> // BOOST_UBLAS_INLINE This function seems to be big. So we do not let the compiler inline it. void matrix_swap (M &m, matrix_expression<E> &e, sparse_proxy_tag, column_major_tag) { typedef F<typename M::iterator1::reference, typename E::reference> functor_type; typedef R conformant_restrict_type; typedef typename M::size_type size_type; typedef typename M::difference_type difference_type; BOOST_UBLAS_CHECK (m.size1 () == e ().size1 (), bad_size ()); BOOST_UBLAS_CHECK (m.size2 () == e ().size2 (), bad_size ()); detail::make_conformant (m, e, column_major_tag (), conformant_restrict_type ()); // FIXME should be a seperate restriction for E detail::make_conformant (e (), m, column_major_tag (), conformant_restrict_type ()); typename M::iterator2 it2 (m.begin2 ()); typename M::iterator2 it2_end (m.end2 ()); typename E::iterator2 it2e (e ().begin2 ()); typename E::iterator2 it2e_end (e ().end2 ()); while (it2 != it2_end && it2e != it2e_end) { difference_type compare = it2.index2 () - it2e.index2 (); if (compare == 0) { #ifndef BOOST_UBLAS_NO_NESTED_CLASS_RELATION typename M::iterator1 it1 (it2.begin ()); typename M::iterator1 it1_end (it2.end ()); typename E::iterator1 it1e (it2e.begin ()); typename E::iterator1 it1e_end (it2e.end ()); #else typename M::iterator1 it1 (begin (it2, iterator2_tag ())); typename M::iterator1 it1_end (end (it2, iterator2_tag ())); typename E::iterator1 it1e (begin (it2e, iterator2_tag ())); typename E::iterator1 it1e_end (end (it2e, iterator2_tag ())); #endif if (it1 != it1_end && it1e != it1e_end) { size_type it1_index = it1.index1 (), it1e_index = it1e.index1 (); for (;;) { difference_type compare2 = it1_index - it1e_index; if (compare2 == 0) { functor_type::apply (*it1, *it1e); ++ it1, ++ it1e; if (it1 != it1_end && it1e != it1e_end) { it1_index = it1.index1 (); it1e_index = it1e.index1 (); } else break; } else if (compare2 < 0) { increment (it1, it1_end, - compare2); if (it1 != it1_end) it1_index = it1.index1 (); else break; } else if (compare2 > 0) { increment (it1e, it1e_end, compare2); if (it1e != it1e_end) it1e_index = it1e.index1 (); else break; } } } #if BOOST_UBLAS_TYPE_CHECK increment (it1e, it1e_end); increment (it1, it1_end); #endif ++ it2, ++ it2e; } else if (compare < 0) { #if BOOST_UBLAS_TYPE_CHECK while (it2.index2 () < it2e.index2 ()) { #ifndef BOOST_UBLAS_NO_NESTED_CLASS_RELATION typename M::iterator1 it1 (it2.begin ()); typename M::iterator1 it1_end (it2.end ()); #else typename M::iterator1 it1 (begin (it2, iterator2_tag ())); typename M::iterator1 it1_end (end (it2, iterator2_tag ())); #endif increment (it1, it1_end); ++ it2; } #else increment (it2, it2_end, - compare); #endif } else if (compare > 0) { #if BOOST_UBLAS_TYPE_CHECK while (it2e.index2 () < it2.index2 ()) { #ifndef BOOST_UBLAS_NO_NESTED_CLASS_RELATION typename E::iterator1 it1e (it2e.begin ()); typename E::iterator1 it1e_end (it2e.end ()); #else typename E::iterator1 it1e (begin (it2e, iterator2_tag ())); typename E::iterator1 it1e_end (end (it2e, iterator2_tag ())); #endif increment (it1e, it1e_end); ++ it2e; } #else increment (it2e, it2e_end, compare); #endif } } #if BOOST_UBLAS_TYPE_CHECK while (it2e != it2e_end) { #ifndef BOOST_UBLAS_NO_NESTED_CLASS_RELATION typename E::iterator1 it1e (it2e.begin ()); typename E::iterator1 it1e_end (it2e.end ()); #else typename E::iterator1 it1e (begin (it2e, iterator2_tag ())); typename E::iterator1 it1e_end (end (it2e, iterator2_tag ())); #endif increment (it1e, it1e_end); ++ it2e; } while (it2 != it2_end) { #ifndef BOOST_UBLAS_NO_NESTED_CLASS_RELATION typename M::iterator1 it1 (it2.begin ()); typename M::iterator1 it1_end (it2.end ()); #else typename M::iterator1 it1 (begin (it2, iterator2_tag ())); typename M::iterator1 it1_end (end (it2, iterator2_tag ())); #endif increment (it1, it1_end); ++ it2; } #endif } // Dispatcher template<template <class T1, class T2> class F, class M, class E> BOOST_UBLAS_INLINE void matrix_swap (M &m, matrix_expression<E> &e) { typedef typename matrix_swap_traits<typename M::storage_category, typename E::const_iterator1::iterator_category, typename E::const_iterator2::iterator_category>::storage_category storage_category; // give preference to matrix M's orientation if known typedef typename boost::mpl::if_<boost::is_same<typename M::orientation_category, unknown_orientation_tag>, typename E::orientation_category , typename M::orientation_category >::type orientation_category; typedef basic_full<typename M::size_type> unrestricted; matrix_swap<F, unrestricted> (m, e, storage_category (), orientation_category ()); } template<template <class T1, class T2> class F, class R, class M, class E> BOOST_UBLAS_INLINE void matrix_swap (M &m, matrix_expression<E> &e) { typedef R conformant_restrict_type; typedef typename matrix_swap_traits<typename M::storage_category, typename E::const_iterator1::iterator_category, typename E::const_iterator2::iterator_category>::storage_category storage_category; // give preference to matrix M's orientation if known typedef typename boost::mpl::if_<boost::is_same<typename M::orientation_category, unknown_orientation_tag>, typename E::orientation_category , typename M::orientation_category >::type orientation_category; matrix_swap<F, conformant_restrict_type> (m, e, storage_category (), orientation_category ()); } }}} #endif