// Copyright (c) 1999 // Utrecht University (The Netherlands), // ETH Zurich (Switzerland), // INRIA Sophia-Antipolis (France), // Max-Planck-Institute Saarbruecken (Germany), // and Tel-Aviv University (Israel). All rights reserved. // // This file is part of CGAL (www.cgal.org); you can redistribute it and/or // modify it under the terms of the GNU Lesser General Public License as // published by the Free Software Foundation; either version 3 of the License, // or (at your option) any later version. // // Licensees holding a valid commercial license may use this file in // accordance with the commercial license agreement provided with the software. // // This file is provided AS IS with NO WARRANTY OF ANY KIND, INCLUDING THE // WARRANTY OF DESIGN, MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE. // // $URL$ // $Id$ // SPDX-License-Identifier: LGPL-3.0+ // // // Author(s) : Andreas Fabri #ifndef CGAL_LINE_2_H #define CGAL_LINE_2_H #include #include #include #include #include namespace CGAL { template class Line_2 : public R_::Kernel_base::Line_2 { typedef typename R_::RT RT; typedef typename R_::FT FT; typedef typename R_::Point_2 Point_2; typedef typename R_::Segment_2 Segment_2; typedef typename R_::Ray_2 Ray_2; typedef typename R_::Vector_2 Vector_2; typedef typename R_::Direction_2 Direction_2; typedef typename R_::Aff_transformation_2 Aff_transformation_2; typedef typename R_::Kernel_base::Line_2 RLine_2; typedef Line_2 Self; CGAL_static_assertion((boost::is_same::value)); public: typedef Dimension_tag<2> Ambient_dimension; typedef Dimension_tag<1> Feature_dimension; typedef RLine_2 Rep; const Rep& rep() const { return *this; } Rep& rep() { return *this; } typedef R_ R; Line_2() {} Line_2(const RLine_2& l) // conversion impl -> interface class : RLine_2(l) {} Line_2(const Point_2 &p, const Point_2 &q) : RLine_2(typename R::Construct_line_2()(Return_base_tag(), p,q)) {} Line_2(const RT &a, const RT &b, const RT &c) : RLine_2(typename R::Construct_line_2()(Return_base_tag(), a,b,c)) {} explicit Line_2(const Segment_2& s) : RLine_2(typename R::Construct_line_2()(Return_base_tag(), s)) {} explicit Line_2(const Ray_2& r) : RLine_2(typename R::Construct_line_2()(Return_base_tag(), r)) {} Line_2(const Point_2 &p, const Direction_2 &d) : RLine_2(typename R::Construct_line_2()(Return_base_tag(), p,d)) {} Line_2(const Point_2 &p, const Vector_2 &v) : RLine_2(typename R::Construct_line_2()(Return_base_tag(), p,v)) {} // FIXME : Use Qrt<> here. RT a() const { return R().compute_a_2_object()(*this); } RT b() const { return R().compute_b_2_object()(*this); } RT c() const { return R().compute_c_2_object()(*this); } Line_2 transform(const Aff_transformation_2 &t) const { return Line_2(t.transform(point(0)), t.transform(direction())); } Line_2 opposite() const { return R().construct_opposite_line_2_object()(*this); } Direction_2 direction() const { return R().construct_direction_2_object()(*this); } Vector_2 to_vector() const { return R().construct_vector_2_object()(*this); } Line_2 perpendicular(const Point_2 &p) const { return R().construct_perpendicular_line_2_object()(*this,p); } Point_2 projection(const Point_2& p) const { return R().construct_projected_point_2_object()(*this,p); } typename R::Boolean is_horizontal() const { return R().is_horizontal_2_object()(*this); } typename R::Boolean is_vertical() const { return R().is_vertical_2_object()(*this); } typename R::Boolean is_degenerate() const { return R().is_degenerate_2_object()(*this); } typename R::Oriented_side oriented_side(const Point_2 &p) const { return R().oriented_side_2_object()(*this,p); } typename R::Boolean has_on_boundary(const Point_2 &p) const { return oriented_side(p) == ON_ORIENTED_BOUNDARY; } typename R::Boolean has_on_positive_side(const Point_2 &p) const { return oriented_side(p) == ON_POSITIVE_SIDE; } typename R::Boolean has_on_negative_side(const Point_2 &p) const { return oriented_side(p) == ON_NEGATIVE_SIDE; } typename R::Boolean has_on(const Point_2 &p) const { return has_on_boundary(p); } FT x_at_y(const FT &y) const { return R().compute_x_at_y_2_object()(*this, y); } FT y_at_x(const FT &y) const { return R().compute_y_at_x_2_object()(*this, y); } Point_2 point() const { return R().construct_point_2_object()(*this); } Point_2 point(int i) const { return R().construct_point_2_object()(*this,i); } typename R::Boolean operator==(const Line_2 &l) const { return R().equal_2_object()(*this, l); } typename R::Boolean operator!=(const Line_2 &l) const { return !(*this == l); } }; template std::ostream& insert(std::ostream& os, const Line_2& l) { switch(get_mode(os)) { case IO::ASCII : return os << l.a() << ' ' << l.b() << ' ' << l.c(); case IO::BINARY : write(os, l.a()); write(os, l.b()); write(os, l.c()); return os; default: return os << "Line_2(" << l.a() << ", " << l.b() << ", " << l.c() <<')'; } } template < class R > std::ostream & operator<<(std::ostream &os, const Line_2 &l) { return insert(os, l); } template std::istream& extract(std::istream& is, Line_2& l) { typename R::RT a(0), b(0), c(0); switch(get_mode(is)) { case IO::ASCII : is >> iformat(a) >> iformat(b) >> iformat(c); break; case IO::BINARY : read(is, a); read(is, b); read(is, c); break; default: is.setstate(std::ios::failbit); std::cerr << "" << std::endl; std::cerr << "Stream must be in ascii or binary mode" << std::endl; break; } if (is) l = Line_2(a, b, c); return is; } template < class R > std::istream & operator>>(std::istream &is, Line_2 &l) { return extract(is, l); } } //namespace CGAL #endif // CGAL_LINE_2_H