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267 lines
14 KiB
C++
267 lines
14 KiB
C++
//
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// Copyright (c) 2000-2002
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// Joerg Walter, Mathias Koch
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//
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// Distributed under the Boost Software License, Version 1.0. (See
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// accompanying file LICENSE_1_0.txt or copy at
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// http://www.boost.org/LICENSE_1_0.txt)
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//
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// The authors gratefully acknowledge the support of
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// GeNeSys mbH & Co. KG in producing this work.
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//
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#ifndef _BOOST_UBLAS_OPERATION_BLOCKED_
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#define _BOOST_UBLAS_OPERATION_BLOCKED_
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#include <boost/numeric/ublas/traits.hpp>
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#include <boost/numeric/ublas/detail/vector_assign.hpp> // indexing_vector_assign
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#include <boost/numeric/ublas/detail/matrix_assign.hpp> // indexing_matrix_assign
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namespace boost { namespace numeric { namespace ublas {
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template<class V, typename V::size_type BS, class E1, class E2>
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BOOST_UBLAS_INLINE
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V
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block_prod (const matrix_expression<E1> &e1,
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const vector_expression<E2> &e2) {
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typedef V vector_type;
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typedef const E1 expression1_type;
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typedef const E2 expression2_type;
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typedef typename V::size_type size_type;
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typedef typename V::value_type value_type;
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const size_type block_size = BS;
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V v (e1 ().size1 ());
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#if BOOST_UBLAS_TYPE_CHECK
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vector<value_type> cv (v.size ());
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typedef typename type_traits<value_type>::real_type real_type;
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real_type verrorbound (norm_1 (v) + norm_1 (e1) * norm_1 (e2));
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indexing_vector_assign<scalar_assign> (cv, prod (e1, e2));
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#endif
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size_type i_size = e1 ().size1 ();
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size_type j_size = BOOST_UBLAS_SAME (e1 ().size2 (), e2 ().size ());
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for (size_type i_begin = 0; i_begin < i_size; i_begin += block_size) {
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size_type i_end = i_begin + (std::min) (i_size - i_begin, block_size);
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// FIX: never ignore Martin Weiser's advice ;-(
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#ifdef BOOST_UBLAS_NO_CACHE
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vector_range<vector_type> v_range (v, range (i_begin, i_end));
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#else
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// vector<value_type, bounded_array<value_type, block_size> > v_range (i_end - i_begin);
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vector<value_type> v_range (i_end - i_begin);
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#endif
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v_range.assign (zero_vector<value_type> (i_end - i_begin));
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for (size_type j_begin = 0; j_begin < j_size; j_begin += block_size) {
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size_type j_end = j_begin + (std::min) (j_size - j_begin, block_size);
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#ifdef BOOST_UBLAS_NO_CACHE
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const matrix_range<expression1_type> e1_range (e1 (), range (i_begin, i_end), range (j_begin, j_end));
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const vector_range<expression2_type> e2_range (e2 (), range (j_begin, j_end));
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v_range.plus_assign (prod (e1_range, e2_range));
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#else
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// const matrix<value_type, row_major, bounded_array<value_type, block_size * block_size> > e1_range (project (e1 (), range (i_begin, i_end), range (j_begin, j_end)));
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// const vector<value_type, bounded_array<value_type, block_size> > e2_range (project (e2 (), range (j_begin, j_end)));
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const matrix<value_type, row_major> e1_range (project (e1 (), range (i_begin, i_end), range (j_begin, j_end)));
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const vector<value_type> e2_range (project (e2 (), range (j_begin, j_end)));
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v_range.plus_assign (prod (e1_range, e2_range));
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#endif
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}
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#ifndef BOOST_UBLAS_NO_CACHE
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project (v, range (i_begin, i_end)).assign (v_range);
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#endif
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}
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#if BOOST_UBLAS_TYPE_CHECK
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BOOST_UBLAS_CHECK (norm_1 (v - cv) <= 2 * std::numeric_limits<real_type>::epsilon () * verrorbound, internal_logic ());
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#endif
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return v;
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}
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template<class V, typename V::size_type BS, class E1, class E2>
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BOOST_UBLAS_INLINE
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V
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block_prod (const vector_expression<E1> &e1,
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const matrix_expression<E2> &e2) {
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typedef V vector_type;
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typedef const E1 expression1_type;
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typedef const E2 expression2_type;
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typedef typename V::size_type size_type;
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typedef typename V::value_type value_type;
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const size_type block_size = BS;
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V v (e2 ().size2 ());
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#if BOOST_UBLAS_TYPE_CHECK
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vector<value_type> cv (v.size ());
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typedef typename type_traits<value_type>::real_type real_type;
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real_type verrorbound (norm_1 (v) + norm_1 (e1) * norm_1 (e2));
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indexing_vector_assign<scalar_assign> (cv, prod (e1, e2));
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#endif
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size_type i_size = BOOST_UBLAS_SAME (e1 ().size (), e2 ().size1 ());
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size_type j_size = e2 ().size2 ();
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for (size_type j_begin = 0; j_begin < j_size; j_begin += block_size) {
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size_type j_end = j_begin + (std::min) (j_size - j_begin, block_size);
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// FIX: never ignore Martin Weiser's advice ;-(
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#ifdef BOOST_UBLAS_NO_CACHE
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vector_range<vector_type> v_range (v, range (j_begin, j_end));
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#else
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// vector<value_type, bounded_array<value_type, block_size> > v_range (j_end - j_begin);
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vector<value_type> v_range (j_end - j_begin);
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#endif
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v_range.assign (zero_vector<value_type> (j_end - j_begin));
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for (size_type i_begin = 0; i_begin < i_size; i_begin += block_size) {
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size_type i_end = i_begin + (std::min) (i_size - i_begin, block_size);
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#ifdef BOOST_UBLAS_NO_CACHE
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const vector_range<expression1_type> e1_range (e1 (), range (i_begin, i_end));
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const matrix_range<expression2_type> e2_range (e2 (), range (i_begin, i_end), range (j_begin, j_end));
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#else
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// const vector<value_type, bounded_array<value_type, block_size> > e1_range (project (e1 (), range (i_begin, i_end)));
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// const matrix<value_type, column_major, bounded_array<value_type, block_size * block_size> > e2_range (project (e2 (), range (i_begin, i_end), range (j_begin, j_end)));
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const vector<value_type> e1_range (project (e1 (), range (i_begin, i_end)));
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const matrix<value_type, column_major> e2_range (project (e2 (), range (i_begin, i_end), range (j_begin, j_end)));
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#endif
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v_range.plus_assign (prod (e1_range, e2_range));
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}
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#ifndef BOOST_UBLAS_NO_CACHE
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project (v, range (j_begin, j_end)).assign (v_range);
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#endif
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}
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#if BOOST_UBLAS_TYPE_CHECK
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BOOST_UBLAS_CHECK (norm_1 (v - cv) <= 2 * std::numeric_limits<real_type>::epsilon () * verrorbound, internal_logic ());
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#endif
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return v;
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}
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template<class M, typename M::size_type BS, class E1, class E2>
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BOOST_UBLAS_INLINE
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M
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block_prod (const matrix_expression<E1> &e1,
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const matrix_expression<E2> &e2,
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row_major_tag) {
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typedef M matrix_type;
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typedef const E1 expression1_type;
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typedef const E2 expression2_type;
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typedef typename M::size_type size_type;
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typedef typename M::value_type value_type;
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const size_type block_size = BS;
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M m (e1 ().size1 (), e2 ().size2 ());
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#if BOOST_UBLAS_TYPE_CHECK
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matrix<value_type, row_major> cm (m.size1 (), m.size2 ());
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typedef typename type_traits<value_type>::real_type real_type;
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real_type merrorbound (norm_1 (m) + norm_1 (e1) * norm_1 (e2));
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indexing_matrix_assign<scalar_assign> (cm, prod (e1, e2), row_major_tag ());
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disable_type_check<bool>::value = true;
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#endif
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size_type i_size = e1 ().size1 ();
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size_type j_size = e2 ().size2 ();
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size_type k_size = BOOST_UBLAS_SAME (e1 ().size2 (), e2 ().size1 ());
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for (size_type i_begin = 0; i_begin < i_size; i_begin += block_size) {
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size_type i_end = i_begin + (std::min) (i_size - i_begin, block_size);
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for (size_type j_begin = 0; j_begin < j_size; j_begin += block_size) {
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size_type j_end = j_begin + (std::min) (j_size - j_begin, block_size);
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// FIX: never ignore Martin Weiser's advice ;-(
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#ifdef BOOST_UBLAS_NO_CACHE
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matrix_range<matrix_type> m_range (m, range (i_begin, i_end), range (j_begin, j_end));
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#else
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// matrix<value_type, row_major, bounded_array<value_type, block_size * block_size> > m_range (i_end - i_begin, j_end - j_begin);
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matrix<value_type, row_major> m_range (i_end - i_begin, j_end - j_begin);
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#endif
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m_range.assign (zero_matrix<value_type> (i_end - i_begin, j_end - j_begin));
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for (size_type k_begin = 0; k_begin < k_size; k_begin += block_size) {
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size_type k_end = k_begin + (std::min) (k_size - k_begin, block_size);
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#ifdef BOOST_UBLAS_NO_CACHE
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const matrix_range<expression1_type> e1_range (e1 (), range (i_begin, i_end), range (k_begin, k_end));
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const matrix_range<expression2_type> e2_range (e2 (), range (k_begin, k_end), range (j_begin, j_end));
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#else
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// const matrix<value_type, row_major, bounded_array<value_type, block_size * block_size> > e1_range (project (e1 (), range (i_begin, i_end), range (k_begin, k_end)));
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// const matrix<value_type, column_major, bounded_array<value_type, block_size * block_size> > e2_range (project (e2 (), range (k_begin, k_end), range (j_begin, j_end)));
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const matrix<value_type, row_major> e1_range (project (e1 (), range (i_begin, i_end), range (k_begin, k_end)));
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const matrix<value_type, column_major> e2_range (project (e2 (), range (k_begin, k_end), range (j_begin, j_end)));
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#endif
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m_range.plus_assign (prod (e1_range, e2_range));
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}
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#ifndef BOOST_UBLAS_NO_CACHE
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project (m, range (i_begin, i_end), range (j_begin, j_end)).assign (m_range);
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#endif
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}
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}
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#if BOOST_UBLAS_TYPE_CHECK
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disable_type_check<bool>::value = false;
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BOOST_UBLAS_CHECK (norm_1 (m - cm) <= 2 * std::numeric_limits<real_type>::epsilon () * merrorbound, internal_logic ());
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#endif
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return m;
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}
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template<class M, typename M::size_type BS, class E1, class E2>
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BOOST_UBLAS_INLINE
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M
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block_prod (const matrix_expression<E1> &e1,
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const matrix_expression<E2> &e2,
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column_major_tag) {
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typedef M matrix_type;
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typedef const E1 expression1_type;
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typedef const E2 expression2_type;
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typedef typename M::size_type size_type;
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typedef typename M::value_type value_type;
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const size_type block_size = BS;
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M m (e1 ().size1 (), e2 ().size2 ());
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#if BOOST_UBLAS_TYPE_CHECK
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matrix<value_type, column_major> cm (m.size1 (), m.size2 ());
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typedef typename type_traits<value_type>::real_type real_type;
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real_type merrorbound (norm_1 (m) + norm_1 (e1) * norm_1 (e2));
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indexing_matrix_assign<scalar_assign> (cm, prod (e1, e2), column_major_tag ());
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disable_type_check<bool>::value = true;
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#endif
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size_type i_size = e1 ().size1 ();
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size_type j_size = e2 ().size2 ();
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size_type k_size = BOOST_UBLAS_SAME (e1 ().size2 (), e2 ().size1 ());
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for (size_type j_begin = 0; j_begin < j_size; j_begin += block_size) {
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size_type j_end = j_begin + (std::min) (j_size - j_begin, block_size);
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for (size_type i_begin = 0; i_begin < i_size; i_begin += block_size) {
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size_type i_end = i_begin + (std::min) (i_size - i_begin, block_size);
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// FIX: never ignore Martin Weiser's advice ;-(
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#ifdef BOOST_UBLAS_NO_CACHE
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matrix_range<matrix_type> m_range (m, range (i_begin, i_end), range (j_begin, j_end));
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#else
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// matrix<value_type, column_major, bounded_array<value_type, block_size * block_size> > m_range (i_end - i_begin, j_end - j_begin);
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matrix<value_type, column_major> m_range (i_end - i_begin, j_end - j_begin);
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#endif
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m_range.assign (zero_matrix<value_type> (i_end - i_begin, j_end - j_begin));
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for (size_type k_begin = 0; k_begin < k_size; k_begin += block_size) {
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size_type k_end = k_begin + (std::min) (k_size - k_begin, block_size);
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#ifdef BOOST_UBLAS_NO_CACHE
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const matrix_range<expression1_type> e1_range (e1 (), range (i_begin, i_end), range (k_begin, k_end));
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const matrix_range<expression2_type> e2_range (e2 (), range (k_begin, k_end), range (j_begin, j_end));
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#else
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// const matrix<value_type, row_major, bounded_array<value_type, block_size * block_size> > e1_range (project (e1 (), range (i_begin, i_end), range (k_begin, k_end)));
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// const matrix<value_type, column_major, bounded_array<value_type, block_size * block_size> > e2_range (project (e2 (), range (k_begin, k_end), range (j_begin, j_end)));
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const matrix<value_type, row_major> e1_range (project (e1 (), range (i_begin, i_end), range (k_begin, k_end)));
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const matrix<value_type, column_major> e2_range (project (e2 (), range (k_begin, k_end), range (j_begin, j_end)));
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#endif
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m_range.plus_assign (prod (e1_range, e2_range));
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}
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#ifndef BOOST_UBLAS_NO_CACHE
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project (m, range (i_begin, i_end), range (j_begin, j_end)).assign (m_range);
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#endif
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}
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}
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#if BOOST_UBLAS_TYPE_CHECK
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disable_type_check<bool>::value = false;
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BOOST_UBLAS_CHECK (norm_1 (m - cm) <= 2 * std::numeric_limits<real_type>::epsilon () * merrorbound, internal_logic ());
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#endif
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return m;
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}
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// Dispatcher
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template<class M, typename M::size_type BS, class E1, class E2>
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BOOST_UBLAS_INLINE
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M
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block_prod (const matrix_expression<E1> &e1,
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const matrix_expression<E2> &e2) {
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typedef typename M::orientation_category orientation_category;
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return block_prod<M, BS> (e1, e2, orientation_category ());
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}
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}}}
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#endif
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