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Diffstat (limited to 'src/3rdparty/2geom/include/2geom/symbolic/mvpoly-tools.h')
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diff --git a/src/3rdparty/2geom/include/2geom/symbolic/mvpoly-tools.h b/src/3rdparty/2geom/include/2geom/symbolic/mvpoly-tools.h new file mode 100644 index 0000000..34dece7 --- /dev/null +++ b/src/3rdparty/2geom/include/2geom/symbolic/mvpoly-tools.h @@ -0,0 +1,690 @@ +/* + * Routines that extend univariate polynomial functions + * to multi-variate polynomial exploiting recursion at compile time + * + * Authors: + * Marco Cecchetti <mrcekets at gmail.com> + * + * Copyright 2008 authors + * + * This library is free software; you can redistribute it and/or + * modify it either under the terms of the GNU Lesser General Public + * License version 2.1 as published by the Free Software Foundation + * (the "LGPL") or, at your option, under the terms of the Mozilla + * Public License Version 1.1 (the "MPL"). If you do not alter this + * notice, a recipient may use your version of this file under either + * the MPL or the LGPL. + * + * You should have received a copy of the LGPL along with this library + * in the file COPYING-LGPL-2.1; if not, write to the Free Software + * Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA + * You should have received a copy of the MPL along with this library + * in the file COPYING-MPL-1.1 + * + * The contents of this file are subject to the Mozilla Public License + * Version 1.1 (the "License"); you may not use this file except in + * compliance with the License. You may obtain a copy of the License at + * http://www.mozilla.org/MPL/ + * + * This software is distributed on an "AS IS" basis, WITHOUT WARRANTY + * OF ANY KIND, either express or implied. See the LGPL or the MPL for + * the specific language governing rights and limitations. + */ + +#ifndef _GEOM_SL_MVPOLY_TOOLS_H_ +#define _GEOM_SL_MVPOLY_TOOLS_H_ + + +#include <2geom/exception.h> + +#include <2geom/symbolic/multi-index.h> +#include <2geom/symbolic/unity-builder.h> +#include <2geom/symbolic/polynomial.h> + +#include <array> +#include <functional> +#include <iostream> +#include <type_traits> + + +namespace Geom { namespace SL { + +/* + * rank<PolyT>::value == total amount of indeterminates + * x_(0),x_(1),...,x_(rank-1) that belong to type PolyT + */ + +template <typename T> +struct rank +{ + static const size_t value = 0; +}; + +template <typename CoeffT> +struct rank< Polynomial<CoeffT> > +{ + static const size_t value = rank<CoeffT>::value + 1; +}; + + +/* + * mvpoly<N, CoeffT> creates a multi-variate polynomial type + * by nesting N-1 Polynomial class template and setting + * the coefficient type of the most nested Polynomial to CoeffT + * example: mvpoly<3, double>::type is the same than + * Polynomial< Polynomial< Polynomial<double> > > + */ + +template <size_t N, typename CoeffT> +struct mvpoly +{ + typedef Polynomial<typename mvpoly<N-1, CoeffT>::type> type; + typedef CoeffT coeff_type; + static const size_t rank = N; + + /* + * computes the lexicographic degree of the mv polynomial p + */ + static + multi_index_type lex_degree (type const& p) + { + multi_index_type D(N); + lex_degree_impl<0>(p, D); + return D; + } + + /* + * Returns in the out-parameter D an N-sequence where each entry value + * represents the max degree of the polynomial related to the passed + * index I, if one index value in I is greater than the related max degree + * the routine returns false otherwise it returns true. + * This routine can be used to test if a given multi-index I is related + * to an actual initialized coefficient. + */ + static + bool max_degree (type const& p, + multi_index_type& D, + multi_index_type const& I) + { + if (I.size() != N) + THROW_RANGEERROR ("multi-index with wrong length"); + D.resize(N); + return max_degree_impl<0>(p, D, I); + } + + /* + * Returns in the out-parameter D an N-sequence where each entry value + * represents the real degree of the polynomial related to the passed + * index I, if one index value in I is greater than the related real degree + * the routine returns false otherwise it returns true. + * This routine can be used to test if a given multi-index I is related + * to an actual initialized and non-zero coefficient. + */ + + static + bool real_degree (type const& p, + multi_index_type& D, + multi_index_type const& I) + { + if (I.size() != N) + THROW_RANGEERROR ("multi-index with wrong length"); + D.resize(N); + return real_degree_impl<0>(p, D, I); + } + + /* + * Multiplies p by X^I + */ + static + void shift(type & p, multi_index_type const& I) + { + if (I.size() != N) + THROW_RANGEERROR ("multi-index with wrong length"); + shift_impl<0>(p, I); + } + + /* + * mv poly evaluation: + * T can be any type that is able to be += with the coefficient type + * and that can be *= with the same type T moreover a specialization + * of zero struct for the type T is needed + */ + template <typename T> + static + T evaluate(type const& p, std::array<T, N> const& X) + { + return evaluate_impl<T, 0>(p, X); + } + + /* + * trim leading zero coefficients + */ + static + void normalize(type & p) + { + p.normalize(); + for (size_t k = 0; k < p.size(); ++k) + mvpoly<N-1, CoeffT>::normalize(p[k]); + } + + /* + * Applies the unary operator "op" to each coefficient of p with rank M. + * For instance when M = 0 op is applied to each coefficient + * of the multi-variate polynomial p. + * When M < N the function call recursively the for_each routine + * for p.real_degree() times, when M == N the operator "op" is invoked on p; + */ + template <size_t M> + static + void for_each + (type & p, + std::function<void (typename mvpoly<M, CoeffT>::type &)> const& op, + typename std::enable_if_t<(M < N)>* = 0) + { + for (size_t k = 0; k <= p.real_degree(); ++k) + { + mvpoly<N-1, CoeffT>::template for_each<M>(p[k], op); + } + } + + template <size_t M> + static + void for_each + (type & p, + std::function<void (typename mvpoly<M, CoeffT>::type &)> const& op, + typename std::enable_if_t<(M == N)>* = 0) + { + op(p); + } + + // this is only an helper function to be passed to the for_each routine + static + void multiply_to (type& p, type const& q) + { + p *= q; + } + + private: + template <size_t i> + static + void lex_degree_impl (type const& p, multi_index_type& D) + { + D[i] = p.real_degree(); + mvpoly<N-1, CoeffT>::template lex_degree_impl<i+1>(p[D[i]], D); + } + + template <size_t i> + static + bool max_degree_impl (type const& p, + multi_index_type& D, + multi_index_type const& I) + { + D[i] = p.max_degree(); + if (I[i] > D[i]) return false; + return + mvpoly<N-1, CoeffT>::template max_degree_impl<i+1>(p[I[i]], D, I); + } + + template <size_t i> + static + bool real_degree_impl (type const& p, + multi_index_type& D, + multi_index_type const& I) + { + D[i] = p.real_degree(); + if (I[i] > D[i]) return false; + return + mvpoly<N-1, CoeffT>::template real_degree_impl<i+1>(p[I[i]], D, I); + } + + template <size_t i> + static + void shift_impl(type & p, multi_index_type const& I) + { + p <<= I[i]; + for (size_t k = 0; k < p.size(); ++k) + { + mvpoly<N-1, CoeffT>::template shift_impl<i+1>(p[k], I); + } + } + + template <typename T, size_t i> + static + T evaluate_impl(type const& p, std::array<T, N+i> const& X) + { +// T r = zero<T>()(); +// for (size_t k = p.max_degree(); k > 0; --k) +// { +// r += mvpoly<N-1, CoeffT>::template evaluate_impl<T, i+1>(p[k], X); +// r *= X[i]; +// } +// r += mvpoly<N-1, CoeffT>::template evaluate_impl<T, i+1>(p[0], X); + + int n = p.max_degree(); + T r = mvpoly<N-1, CoeffT>::template evaluate_impl<T, i+1>(p[n], X); + for (int k = n - 1; k >= 0; --k) + { + r *= X[i]; + r += mvpoly<N-1, CoeffT>::template evaluate_impl<T, i+1>(p[k], X); + } + return r; + } + + template <size_t M, typename C> + friend struct mvpoly; +}; + +/* + * rank 0 mv poly, that is a scalar value (usually a numeric value), + * the routines implemented here are used only to stop recursion + * (but for_each) + */ +template< typename CoeffT > +struct mvpoly<0, CoeffT> +{ + typedef CoeffT type; + typedef CoeffT coeff_type; + static const size_t rank = 0; + + template <size_t M> + static + void for_each + (type & p, + std::function<void (typename mvpoly<M, CoeffT>::type &)> const& op, + typename std::enable_if_t<(M == 0)>* = 0) + { + op(p); + } + + // multiply_to and divide_to are only helper functions + // to be passed to the for_each routine + static + void multiply_to (type& p, type const& q) + { + p *= q; + } + + static + void divide_to (type& p, type const& c) + { + p /= c; + } + + private: + template <size_t i> + static + void lex_degree_impl (type const &/*p*/, multi_index_type&/*D*/) + { + return; + } + + template <size_t i> + static + bool max_degree_impl (type const &/*p*/, + multi_index_type &/*D*/, + multi_index_type const &/*I*/) + { + return true; + } + + template <size_t i> + static + bool real_degree_impl (type const &/*p*/, + multi_index_type &/*D*/, + multi_index_type const &/*I*/) + { + return true; + } + + template <size_t i> + static + void shift_impl(type &/*p*/, multi_index_type const &/*I*/) + {} + + template <typename T, size_t i> + static + T evaluate_impl(type const &p, std::array<T, i> const &/*X*/) + { + return p; + } + + static + void normalize(type &/*p*/) + {} + + + template <size_t M, typename C> + friend struct mvpoly; +}; + + +/* + * monomial::make generate a mv-poly made up by a single term: + * monomial::make<N>(I,c) == c*X^I, where X=(x_(0), .., x_(N-1)) + */ + +template <size_t N, typename CoeffT> +struct monomial +{ + typedef typename mvpoly<N, CoeffT>::type poly_type; + + static inline + poly_type make(multi_index_type const& I, CoeffT c) + { + if (I.size() != N) // an exponent for each indeterminate + THROW_RANGEERROR ("multi-index with wrong length"); + + return make_impl<0>(I, c); + } + + private: + // at i-th level of recursion I need to pick up the i-th exponent in "I" + // so I pass i as a template parameter, this trick is needed to avoid + // to create a new multi-index at each recursion level: + // (J = I[std::slice[1, I.size()-1, 1)]) that will be more expensive + template <size_t i> + static + poly_type make_impl(multi_index_type const& I, CoeffT c) + { + poly_type p(monomial<N-1,CoeffT>::template make_impl<i+1>(I, c), I[i]); + return p; + } + + // make_impl private require that monomial classes to be each other friend + template <size_t M, typename C> + friend struct monomial; +}; + + +// case N = 0 for stopping recursion +template <typename CoeffT> +struct monomial<0, CoeffT> +{ + private: + template <size_t i> + static + CoeffT make_impl(multi_index_type const &/*I*/, CoeffT c) + { + return c; + } + + template<size_t N, typename C> + friend struct monomial; +}; + + +/* + * coefficient<N, PolyT> + * + * N should be in the range [0, rank<PolyT>-1] + * + * "type" == the type of the coefficient of the polynomial with + * rank = rank<PolyT> - N - 1, that is it is the type of the object returned + * by applying the operator[] of a Polynomial object N+1 times; + * + * "zero" represents the zero element (in the group theory meaning) + * for the coefficient type "type"; having it as a static class member + * allows to return always a (const) reference by the "get_safe" method + * + * get(p, I) returns the coefficient of the monomial X^I + * this method doesn't check if such a coefficient really exists, + * so it's up to the user checking that the passed multi-index I is + * not out of range + * + * get_safe(p, I) returns the coefficient of the monomial X^I + * in case such a coefficient doesn't really exist "zero" is returned + * + * set_safe(p, I, c) set the coefficient of the monomial X^I to "c" + * in case such a coefficient doesn't really exist this method creates it + * and creates all monomials X^J with J < I that don't exist yet, setting + * their coefficients to "zero"; + * (with J < I we mean "<" wrt the lexicographic order) + * + */ + +template <size_t N, typename T> +struct coefficient +{ +}; + + +template <size_t N, typename CoeffT> +struct coefficient< N, Polynomial<CoeffT> > +{ + typedef typename coefficient<N-1, CoeffT>::type type; + typedef Polynomial<CoeffT> poly_type; + + static const type zero; + + static + type const& get(poly_type const& p, multi_index_type const& I) + { + if (I.size() != N+1) + THROW_RANGEERROR ("multi-index with wrong length"); + + return get_impl<0>(p, I); + } + + static + type & get(poly_type & p, multi_index_type const& I) + { + if (I.size() != N+1) + THROW_RANGEERROR ("multi-index with wrong length"); + + return get_impl<0>(p, I); + } + + static + type const& get_safe(poly_type const& p, multi_index_type const& I) + { + if (I.size() != N+1) + THROW_RANGEERROR ("multi-index with wrong length"); + + return get_safe_impl<0>(p, I); + } + + static + void set_safe(poly_type & p, multi_index_type const& I, type const& c) + { + if (I.size() != N+1) + THROW_RANGEERROR ("multi-index with wrong length"); + + return set_safe_impl<0>(p, I, c); + } + + private: + template <size_t i> + static + type const& get_impl(poly_type const& p, multi_index_type const& I) + { + return coefficient<N-1, CoeffT>::template get_impl<i+1>(p[I[i]], I); + } + + template <size_t i> + static + type & get_impl(poly_type & p, multi_index_type const& I) + { + return coefficient<N-1, CoeffT>::template get_impl<i+1>(p[I[i]], I); + } + + template <size_t i> + static + type const& get_safe_impl(poly_type const& p, multi_index_type const& I) + { + if (I[i] > p.max_degree()) + { + return zero; + } + else + { + return + coefficient<N-1, CoeffT>::template get_safe_impl<i+1>(p[I[i]], I); + } + } + + template <size_t i> + static + void set_safe_impl(poly_type & p, multi_index_type const& I, type const& c) + { + if (I[i] > p.max_degree()) + { + multi_index_type J = shift(I, i+1); + CoeffT m = monomial<N, type>::make(J, c); + p.coefficient(I[i], m); + } + else + { + coefficient<N-1, CoeffT>::template set_safe_impl<i+1>(p[I[i]], I, c); + } + } + + template<size_t M, typename T> + friend struct coefficient; + +}; + +// initialization of static member zero +template <size_t N, typename CoeffT> +const typename coefficient< N, Polynomial<CoeffT> >::type +coefficient< N, Polynomial<CoeffT> >::zero + = Geom::SL::zero<typename coefficient< N, Polynomial<CoeffT> >::type >()(); + + +// case N = 0 for stopping recursion +template <typename CoeffT> +struct coefficient< 0, Polynomial<CoeffT> > +{ + typedef CoeffT type; + typedef Polynomial<CoeffT> poly_type; + + static const type zero; + + static + type const& get(poly_type const& p, multi_index_type const& I) + { + if (I.size() != 1) + THROW_RANGEERROR ("multi-index with wrong length"); + + return p[I[0]]; + } + + static + type & get(poly_type & p, multi_index_type const& I) + { + if (I.size() != 1) + THROW_RANGEERROR ("multi-index with wrong length"); + + return p[I[0]]; + } + + static + type const& get_safe(poly_type const& p, multi_index_type const& I) + { + if (I.size() != 1) + THROW_RANGEERROR ("multi-index with wrong length"); + + return p.coefficient(I[0]); + } + + static + void set_safe(poly_type & p, multi_index_type const& I, type const& c) + { + if (I.size() != 1) + THROW_RANGEERROR ("multi-index with wrong length"); + + p.coefficient(I[0], c); + } + + private: + template <size_t i> + static + type const& get_impl(poly_type const& p, multi_index_type const& I) + { + return p[I[i]]; + } + + template <size_t i> + static + type & get_impl(poly_type & p, multi_index_type const& I) + { + return p[I[i]]; + } + + template <size_t i> + static + type const& get_safe_impl(poly_type const& p, multi_index_type const& I) + { + return p.coefficient(I[i]); + } + + template <size_t i> + static + void set_safe_impl(poly_type & p, multi_index_type const& I, type const& c) + { + p.coefficient(I[i], c); + } + + template<size_t M, typename T> + friend struct coefficient; +}; + +// initialization of static member zero +template <typename CoeffT> +const typename coefficient< 0, Polynomial<CoeffT> >::type +coefficient< 0, Polynomial<CoeffT> >::zero + = Geom::SL::zero<typename coefficient< 0, Polynomial<CoeffT> >::type >()(); + + +/* + * ordering types: + * lex : lexicographic ordering + * ilex : inverse lexicographic ordering + * max_lex : max degree + lexicographic ordering for disambiguation + * + */ + +namespace ordering +{ + struct lex; // WARNING: at present only lex ordering is supported + struct ilex; + struct max_lex; +} + + +/* + * degree of a mv poly wrt a given ordering + */ + +template <size_t N, typename CoeffT, typename OrderT = ordering::lex> +struct mvdegree +{}; + +template <size_t N, typename CoeffT> +struct mvdegree<N, CoeffT, ordering::lex> +{ + typedef typename mvpoly<N, CoeffT>::type poly_type; + typedef ordering::lex ordering; + + static + multi_index_type value(poly_type const& p) + { + return Geom::SL::mvpoly<N, CoeffT>::lex_degree(p); + } +}; + +} /*end namespace Geom*/ } /*end namespace SL*/ + + +#endif // _GEOM_SL_MVPOLY_TOOLS_H_ + + +/* + Local Variables: + mode:c++ + c-file-style:"stroustrup" + c-file-offsets:((innamespace . 0)(inline-open . 0)(case-label . +)) + indent-tabs-mode:nil + fill-column:99 + End: +*/ +// vim: filetype=cpp:expandtab:shiftwidth=4:tabstop=8:softtabstop=4:fileencoding=utf-8:textwidth=99 : |