452 lines
15 KiB
C
452 lines
15 KiB
C
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// Copyright (c) 1997-2000 Max-Planck-Institute Saarbruecken (Germany).
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// All rights reserved.
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//
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// This file is part of CGAL (www.cgal.org).
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// You can redistribute it and/or modify it under the terms of the GNU
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// General Public License as published by the Free Software Foundation,
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// either version 3 of the License, or (at your option) any later version.
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//
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// Licensees holding a valid commercial license may use this file in
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// accordance with the commercial license agreement provided with the software.
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//
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// This file is provided AS IS with NO WARRANTY OF ANY KIND, INCLUDING THE
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// WARRANTY OF DESIGN, MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE.
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//
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// $URL$
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// $Id$
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// SPDX-License-Identifier: GPL-3.0+
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//
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//
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// Author(s) : Michael Seel <seel@mpi-sb.mpg.de>
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#ifndef CGAL_EXTENDED_CARTESIAN_H
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#define CGAL_EXTENDED_CARTESIAN_H
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#include <CGAL/license/Nef_2.h>
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#include <CGAL/disable_warnings.h>
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#include <CGAL/Simple_cartesian.h>
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#include <CGAL/Point_2.h>
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#include <CGAL/Line_2_Line_2_intersection.h>
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#include <CGAL/Nef_polynomial.h>
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#undef CGAL_NEF_DEBUG
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#define CGAL_NEF_DEBUG 5
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#include <CGAL/Nef_2/debug.h>
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#include <CGAL/Nef_2/Line_to_epoint.h>
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#include <CGAL/Is_extended_kernel.h>
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namespace CGAL {
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template <class T> class Extended_cartesian;
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template<class T>
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struct Is_extended_kernel<Extended_cartesian<T> > {
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typedef Tag_true value_type;
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};
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/*{\Xanpage {Extended_cartesian}{}{An extended geometric kernel model}{K}}*/
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template <class pFT>
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class Extended_cartesian : public
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CGAL::Simple_cartesian< CGAL::Nef_polynomial<pFT> > {
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public:
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typedef CGAL::Simple_cartesian< CGAL::Nef_polynomial<pFT> > Base;
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typedef Extended_cartesian<pFT> Self;
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typedef Cartesian_tag Kernel_tag;
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/*{\Xdefinition |\Mname| is a kernel model realizing the concept
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extended geometry. }*/
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/*{\Xtypes 6.5}*/
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/*{\Xtext \headerline{Affine kernel and types}}*/
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typedef CGAL::Simple_cartesian<pFT> Standard_kernel;
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/*{\Xtypemember the standard affine kernel.}*/
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typedef typename Standard_kernel::RT Standard_RT;
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/*{\Xtypemember the standard ring type.}*/
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typedef typename Standard_kernel::FT Standard_FT;
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/*{\Xtypemember the field type.}*/
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typedef typename Standard_kernel::Point_2 Standard_point_2;
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/*{\Xtypemember standard points.}*/
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typedef typename Standard_kernel::Segment_2 Standard_segment_2;
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/*{\Xtypemember standard segments.}*/
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typedef typename Standard_kernel::Line_2 Standard_line_2;
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/*{\Xtypemember standard oriented lines.}*/
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typedef typename Standard_kernel::Direction_2 Standard_direction_2;
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/*{\Xtypemember standard directions.}*/
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typedef typename Standard_kernel::Ray_2 Standard_ray_2;
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/*{\Xtypemember standard rays.}*/
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typedef typename Standard_kernel::Aff_transformation_2
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Standard_aff_transformation_2;
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/*{\Xtypemember standard affine transformations.}*/
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/*{\Xtext \headerline{Extended kernel types}}*/
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typedef typename Base::RT RT;
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/*{\Xtypemember the ring type of our extended kernel.}*/
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typedef typename Base::FT FT;
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/*{\Xtypemember the ring type of our extended kernel.}*/
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typedef typename Base::Point_2 Point_2;
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/*{\Xtypemember extended points.}*/
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typedef typename Base::Segment_2 Segment_2;
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/*{\Xtypemember extended segments.}*/
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typedef typename Base::Line_2 Line_2;
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/*{\Xtypemember extended lines.}*/
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typedef typename Base::Direction_2 Direction_2;
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/*{\Xtypemember extended directions.}*/
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enum Point_type { SWCORNER=1, LEFTFRAME, NWCORNER,
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BOTTOMFRAME, STANDARD, TOPFRAME,
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SECORNER, RIGHTFRAME, NECORNER };
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/*{\Xenum a type descriptor for extended points.}*/
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Point_2 epoint(const Standard_FT& m1, const Standard_FT& n1,
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const Standard_FT& m2, const Standard_FT& n2) const
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{ return Point_2(FT(n1,m1),FT(n2,m2)); }
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public:
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/*{\Xoperations 2}*/
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/*{\Xtext \headerline{Interfacing the affine kernel types}}*/
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Point_2 construct_point(const Standard_point_2& p) const
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/*{\Xop creates an extended point |Point_2| and initializes it to the
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standard point |p|.}*/
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{ return Point_2(p.x(), p.y()); }
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Point_2 construct_point(const Standard_line_2& l, Point_type& t) const
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/*{\Xop creates an extended point initialized to the equivalence
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class of all the rays underlying the oriented line |l|.
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|t| returns the type of the new extended point.}*/
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{
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t = (Point_type)Line_to_epoint<Standard_kernel>::determine_type(l);
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Point_2 res;
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switch (t) {
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case SWCORNER: res = epoint(-1, 0, -1, 0); break;
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case NWCORNER: res = epoint(-1, 0, 1, 0); break;
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case SECORNER: res = epoint( 1, 0, -1, 0); break;
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case NECORNER: res = epoint( 1, 0, 1, 0); break;
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case LEFTFRAME:
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res = epoint(-1, 0, l.a()/l.b(), -l.c()/l.b()); break;
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case RIGHTFRAME:
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res = epoint( 1, 0, -l.a()/l.b(), -l.c()/l.b()); break;
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case BOTTOMFRAME:
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res = epoint( l.b()/l.a(), -l.c()/l.a(), -1, 0); break;
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case TOPFRAME:
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res = epoint(-l.b()/l.a(), -l.c()/l.a(), 1, 0); break;
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default: CGAL_error_msg("EPoint type not correct!");
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}
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return res;
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}
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Point_2 construct_point(const Standard_point_2& p1,
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const Standard_point_2& p2,
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Point_type& t) const
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/*{\Xop creates an extended point and initializes it to the equivalence
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class of all the rays underlying the oriented line |l(p1,p2)|.
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|t| returns the type of the new extended point.}*/
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{ return construct_point(Standard_line_2(p1,p2),t); }
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Point_2 construct_point(const Standard_line_2& l) const
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/*{\Xop creates an extended point and initializes it to the equivalence
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class of all the rays underlying the oriented line |l|. }*/
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{ Point_type dummy; return construct_point(l,dummy); }
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Point_2 construct_point(const Standard_point_2& p1,
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const Standard_point_2& p2) const
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/*{\Xop creates an extended point and initializes it to the equivalence
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class of all the rays underlying the oriented line |l(p1,p2)|.}*/
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{ return construct_point(Standard_line_2(p1,p2)); }
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Point_2 construct_point(const Standard_point_2& p,
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const Standard_direction_2& d) const
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/*{\Xop creates an extended point and initializes it to the equivalence
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class of all the rays underlying the ray starting in |p| in direction |d|.}*/
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{ return construct_point(Standard_line_2(p,d)); }
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Point_2 construct_opposite_point(const Standard_line_2& l) const
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/*{\Xop creates an extended point and initializes it to the equivalence
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class of all the rays underlying the oriented line opposite to |l|. }*/
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{ Point_type dummy; return construct_point(l.opposite(),dummy); }
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Point_type type(const Point_2& p) const
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/*{\Xop determines the type of |p| and returns it.}*/
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{
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CGAL_assertion(p.x().degree()>=0 && p.y().degree()>=0 );
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if ( p.x().degree() == 0 && p.y().degree() == 0)
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return STANDARD;
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// now we are on the square frame
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FT rx = p.x();
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FT ry = p.y();
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int sx = CGAL_NTS sign(rx);
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int sy = CGAL_NTS sign(ry);
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if (sx < 0) rx = -rx;
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if (sy < 0) ry = -ry;
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if (rx>ry) {
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if (sx > 0) return RIGHTFRAME;
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else return LEFTFRAME;
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}
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if (rx<ry) {
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if (sy > 0) return TOPFRAME;
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else return BOTTOMFRAME;
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}
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// now (rx == ry)
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if (sx==sy) {
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if (sx < 0) return SWCORNER;
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else return NECORNER;
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} else { CGAL_assertion(sx==-sy);
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if (sx < 0) return NWCORNER;
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else return SECORNER;
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}
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}
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bool is_standard(const Point_2& p) const
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/*{\Xop returns |true| iff |p| is a standard point.}*/
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{ return (type(p)==STANDARD); }
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Standard_point_2 standard_point(const Point_2& p) const
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/*{\Xop returns the standard point represented by |p|.
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\precond |\Mvar.is_standard(p)|.}*/
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{ CGAL_assertion( type(p)==STANDARD );
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return Standard_point_2(p.x()[0],p.y()[0]);
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}
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Standard_line_2 standard_line(const Point_2& p) const
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/*{\Xop returns the oriented line representing the
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bundle of rays defining |p|.
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\precond |!\Mvar.is_standard(p)|.}*/
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{ CGAL_assertion( type(p)!=STANDARD );
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FT x = p.x(), y = p.y();
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Standard_FT dx = x.degree()>0 ? x[1] : Standard_FT(0);
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Standard_FT dy = y.degree()>0 ? y[1] : Standard_FT(0);
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Standard_point_2 p0(x[0],y[0]);
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Standard_point_2 p1(x[0]+dx,y[0]+dy);
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return Standard_line_2(p0,p1);
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}
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Standard_ray_2 standard_ray(const Point_2& p) const
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/*{\Xop a ray defining |p|. \precond |!\Mvar.is_standard(p)|.}*/
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{
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CGAL_assertion( type(p)!=STANDARD );
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FT x = p.x(), y = p.y();
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Standard_FT dx = x.degree()>0 ? x[1] : Standard_FT(0);
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Standard_FT dy = y.degree()>0 ? y[1] : Standard_FT(0);
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Standard_point_2 p0(x[0],y[0]);
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Standard_point_2 p1(x[0]+dx,y[0]+dy);
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return Standard_ray_2(p0,p1);
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}
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Point_2 NE() const { return construct_point(Standard_line_2(-1, 1,0)); }
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/*{\Xop returns the point on the north east frame corner.}*/
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Point_2 SE() const { return construct_point(Standard_line_2( 1, 1,0)); }
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/*{\Xop returns the point on the south east frame corner.}*/
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Point_2 NW() const { return construct_point(Standard_line_2(-1,-1,0)); }
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/*{\Xop returns the point on the north west frame corner.}*/
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Point_2 SW() const { return construct_point(Standard_line_2( 1,-1,0)); }
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/*{\Xop returns the point on the south west frame corner.}*/
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Line_2 upper() const { return construct_line(NW(),NE()); }
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/*{\Xop returns the line underlying the upper frame segment.}*/
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Line_2 lower() const { return construct_line(SW(),SE()); }
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/*{\Xop returns the line underlying the lower frame segment.}*/
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Line_2 left() const { return construct_line(SW(),NW()); }
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/*{\Xop returns the line underlying the left frame segment.}*/
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Line_2 right() const { return construct_line(SE(),NE()); }
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/*{\Xop returns the line underlying the right frame segment.}*/
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/*{\Xtext \headerline{Geometric kernel calls}}*/
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Point_2 source(const Segment_2& s) const
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/*{\Xop returns the source point of |s|.}*/
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{ typename Base::Construct_vertex_2 _source =
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this->construct_vertex_2_object();
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return _source(s,0); }
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Point_2 target(const Segment_2& s) const
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/*{\Xop returns the target point of |s|.}*/
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{ typename Base::Construct_vertex_2 _target =
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this->construct_vertex_2_object();
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return _target(s,1); }
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Segment_2 construct_segment(const Point_2& p, const Point_2& q) const
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/*{\Xop constructs a segment |pq|.}*/
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{ typename Base::Construct_segment_2 _segment =
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this->construct_segment_2_object();
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return _segment(p,q); }
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Line_2 construct_line(const Standard_line_2& l) const
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/*{\Xop returns an extended line.}*/
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{ return Line_2(l.a(),l.b(),l.c()); }
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Line_2 construct_line(const Point_2& p1, const Point_2& p2) const
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/*{\Xop returns a line through the two extended points |p1| and |p2|.}*/
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{ Line_2 l(p1,p2);
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CGAL_NEF_TRACEN("eline("<<p1<<p2<<")="<<l);
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RT a=l.a(), b=l.b(), c=l.c();
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l = Line_2(a,b,c);
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return l;
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}
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int orientation(const Segment_2& s, const Point_2& p) const
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/*{\Xop returns the orientation of |p| with respect to the line
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through |s|.}*/
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{ typename Base::Orientation_2 _orientation =
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this->orientation_2_object();
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return static_cast<int> ( _orientation(source(s),target(s),p) );
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}
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int orientation(const Point_2& p1, const Point_2& p2, const Point_2& p3)
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const
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/*{\Xop returns the orientation of |p2| with respect to the line
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through |p1p2|.}*/
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{ typename Base::Orientation_2 _orientation =
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this->orientation_2_object();
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return static_cast<int> ( _orientation(p1,p2,p3) );
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}
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bool left_turn(const Point_2& p1, const Point_2& p2, const Point_2& p3)
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const
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/*{\Xop return true iff the |p3| is left of the line through |p1p2|.}*/
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{ return orientation(p1,p2,p3) > 0; }
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bool is_degenerate(const Segment_2& s) const
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/*{\Xop return true iff |s| is degenerate.}*/
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{ typename Base::Is_degenerate_2 _is_degenerate =
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this->is_degenerate_2_object();
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return _is_degenerate(s); }
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int compare_xy(const Point_2& p1, const Point_2& p2) const
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/*{\Xop returns the lexicographic order of |p1| and |p2|.}*/
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{ typename Base::Compare_xy_2 _compare_xy =
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this->compare_xy_2_object();
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return static_cast<int>( _compare_xy(p1,p2) );
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}
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int compare_x(const Point_2& p1, const Point_2& p2) const
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/*{\Xop returns the order on the $x$-coordinates of |p1| and |p2|.}*/
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{ typename Base::Compare_x_2 _compare_x =
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this->compare_x_2_object();
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return static_cast<int>( _compare_x(p1,p2) );
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}
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int compare_y(const Point_2& p1, const Point_2& p2) const
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/*{\Xop returns the order on the $y$-coordinates of |p1| and |p2|.}*/
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{ typename Base::Compare_y_2 _compare_y =
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this->compare_y_2_object();
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return static_cast<int>( _compare_y(p1,p2) );
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}
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Point_2 intersection(
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const Segment_2& s1, const Segment_2& s2) const
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/*{\Xop returns the point of intersection of the lines supported by |s1|
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and |s2|.}*/
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{ typename Base::Intersect_2 _intersect =
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this->intersect_2_object();
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typename Base::Construct_line_2 _line =
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this->construct_line_2_object();
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Point_2 p;
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Line_2 l1 = _line(s1);
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Line_2 l2 = _line(s2);
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CGAL::Object result =
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_intersect(l1, l2);
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if ( !CGAL::assign(p, result) )
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CGAL_error_msg("intersection: no intersection.");
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return p;
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}
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Direction_2 construct_direction(
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const Point_2& p1, const Point_2& p2) const
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/*{\Xop returns the direction of the vector |p2| - |p1|.}*/
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{ typename Base::Construct_direction_2 _direction =
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|
this->construct_direction_2_object();
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||
|
return _direction(construct_line(p1,p2)); }
|
||
|
|
||
|
bool strictly_ordered_ccw(const Direction_2& d1,
|
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|
const Direction_2& d2, const Direction_2& d3) const
|
||
|
/*{\Xop returns |true| iff |d2| is in the interior of the
|
||
|
counterclockwise angular sector between |d1| and |d3|.}*/
|
||
|
{
|
||
|
if ( d1 < d2 ) return ( d2 < d3 )||( d3 <= d1 );
|
||
|
if ( d1 > d2 ) return ( d2 < d3 )&&( d3 <= d1 );
|
||
|
return false;
|
||
|
}
|
||
|
|
||
|
bool contains(const Segment_2& s, const Point_2& p) const
|
||
|
/*{\Xop returns true iff |s| contains |p|.}*/
|
||
|
{ typename Base::Has_on_2 _contains = this->has_on_2_object();
|
||
|
return _contains(s,p);
|
||
|
}
|
||
|
|
||
|
bool strictly_ordered_along_line(
|
||
|
const Point_2& p1, const Point_2& p2, const Point_2& p3) const
|
||
|
/*{\Xop returns |true| iff |p2| is in the relative interior of the
|
||
|
segment |p1p3|.}*/
|
||
|
{ typename Base::Are_strictly_ordered_along_line_2 _ordered =
|
||
|
this->are_strictly_ordered_along_line_2_object();
|
||
|
return _ordered(p1,p2,p3);
|
||
|
}
|
||
|
|
||
|
bool first_pair_closer_than_second(
|
||
|
const Point_2& p1, const Point_2& p2,
|
||
|
const Point_2& p3, const Point_2& p4) const
|
||
|
{ return ( squared_distance(p1,p2) < squared_distance(p3,p4) ); }
|
||
|
|
||
|
template <class Forward_iterator>
|
||
|
void determine_frame_radius(Forward_iterator start, Forward_iterator end,
|
||
|
Standard_RT& R0) const
|
||
|
{ Standard_RT R;
|
||
|
while ( start != end ) {
|
||
|
Point_2 p = *start++;
|
||
|
if ( is_standard(p) ) {
|
||
|
R = (CGAL::max)(CGAL_NTS abs(p.x()[0]), CGAL_NTS abs(p.y()[0]));
|
||
|
} else {
|
||
|
RT rx = CGAL_NTS abs(p.x()), ry = CGAL_NTS abs(p.y());
|
||
|
if ( rx[1] > ry[1] ) R = CGAL_NTS abs(ry[0]-rx[0])/(rx[1]-ry[1]);
|
||
|
else if ( rx[1] < ry[1] ) R = CGAL_NTS abs(rx[0]-ry[0])/(ry[1]-rx[1]);
|
||
|
else /* rx[1] == ry[1] */ R = CGAL_NTS abs(rx[0]-ry[0])/2;
|
||
|
}
|
||
|
R0 = (CGAL::max)(R+1,R0);
|
||
|
}
|
||
|
}
|
||
|
|
||
|
|
||
|
|
||
|
const char* output_identifier() const { return "Extended_cartesian"; }
|
||
|
|
||
|
};
|
||
|
|
||
|
|
||
|
|
||
|
#undef Polynomial
|
||
|
} //namespace CGAL
|
||
|
|
||
|
#include <CGAL/enable_warnings.h>
|
||
|
|
||
|
#endif // CGAL_EXTENDED_CARTESIAN_H
|