/* * Copyright (C) 1998, 2000-2007, 2010, 2011, 2012, 2013 SINTEF ICT, * Applied Mathematics, Norway. * * Contact information: E-mail: tor.dokken@sintef.no * SINTEF ICT, Department of Applied Mathematics, * P.O. Box 124 Blindern, * 0314 Oslo, Norway. * * This file is part of TTL. * * TTL is free software: you can redistribute it and/or modify * it under the terms of the GNU Affero General Public License as * published by the Free Software Foundation, either version 3 of the * License, or (at your option) any later version. * * TTL is distributed in the hope that it will be useful, * but WITHOUT ANY WARRANTY; without even the implied warranty of * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the * GNU Affero General Public License for more details. * * You should have received a copy of the GNU Affero General Public * License along with TTL. If not, see * . * * In accordance with Section 7(b) of the GNU Affero General Public * License, a covered work must retain the producer line in every data * file that is created or manipulated using TTL. * * Other Usage * You can be released from the requirements of the license by purchasing * a commercial license. Buying such a license is mandatory as soon as you * develop commercial activities involving the TTL library without * disclosing the source code of your own applications. * * This file may be used in accordance with the terms contained in a * written agreement between you and SINTEF ICT. */ #ifndef _HALF_EDGE_TRAITS_ #define _HALF_EDGE_TRAITS_ #include #include namespace hed { /** * \struct TTLtraits * \brief \b Traits class (static struct) for the half-edge data structure. * * The member functions are those required by different function templates * in the TTL. Documentation is given here to explain what actions * should be carried out on the actual data structure as required by the functions * in the \ref ttl namespace. * * The source code of \c %HeTraits.h shows how the traits class is implemented for the * half-edge data structure. * * \see \ref api */ struct TTLtraits { /** * The floating point type used in calculations involving scalar products and cross products. */ typedef double REAL_TYPE; /** @name Geometric Predicates */ //@{ /** * Scalar product between two 2D vectors represented as darts.\n * * ttl_util::scalarProduct2d can be used. */ static REAL_TYPE ScalarProduct2D( const DART& aV1, const DART& aV2 ) { DART v10 = aV1; v10.Alpha0(); DART v20 = aV2; v20.Alpha0(); return ttl_util::ScalarProduct2D( v10.X() - aV1.X(), v10.Y() - aV1.Y(), v20.X() - aV2.X(), v20.Y() - aV2.Y() ); } /** * Scalar product between two 2D vectors. * The first vector is represented by a dart \e v, and the second * vector has direction from the source node of \e v to the point \e p.\n * * ttl_util::ScalarProduct2D can be used. */ static REAL_TYPE ScalarProduct2D( const DART& aV, const NODE_PTR& aP ) { DART d0 = aV; d0.Alpha0(); return ttl_util::ScalarProduct2D( d0.X() - aV.X(), d0.Y() - aV.Y(), aP->GetX() - aV.X(), aP->GetY() - aV.Y() ); } /** * Cross product between two vectors in the plane represented as darts. * The z-component of the cross product is returned.\n * * ttl_util::CrossProduct2D can be used. */ static REAL_TYPE CrossProduct2D( const DART& aV1, const DART& aV2 ) { DART v10 = aV1; v10.Alpha0(); DART v20 = aV2; v20.Alpha0(); return ttl_util::CrossProduct2D( v10.X() - aV1.X(), v10.Y() - aV1.Y(), v20.X() - aV2.X(), v20.Y() - aV2.Y() ); } /** * Cross product between two vectors in the plane. * The first vector is represented by a dart \e v, and the second * vector has direction from the source node of \e v to the point \e p. * The z-component of the cross product is returned.\n * * ttl_util::CrossProduct2d can be used. */ static REAL_TYPE CrossProduct2D( const DART& aV, const NODE_PTR& aP ) { DART d0 = aV; d0.Alpha0(); return ttl_util::CrossProduct2D( d0.X() - aV.X(), d0.Y() - aV.Y(), aP->GetX() - aV.X(), aP->GetY() - aV.Y() ); } /** * Let \e n1 and \e n2 be the nodes associated with two darts, and let \e p * be a point in the plane. Return a positive value if \e n1, \e n2, * and \e p occur in counterclockwise order; a negative value if they occur * in clockwise order; and zero if they are collinear. */ static REAL_TYPE Orient2D( const DART& aN1, const DART& aN2, const NODE_PTR& aP ) { REAL_TYPE pa[2]; REAL_TYPE pb[2]; REAL_TYPE pc[2]; pa[0] = aN1.X(); pa[1] = aN1.Y(); pb[0] = aN2.X(); pb[1] = aN2.Y(); pc[0] = aP->GetX(); pc[1] = aP->GetY(); return ttl_util::Orient2DFast( pa, pb, pc ); } /** * This is the same predicate as represented with the function above, * but with a slighty different interface: * The last parameter is given as a dart where the source node of the dart * represents a point in the plane. * This function is required for constrained triangulation. */ static REAL_TYPE Orient2D( const DART& aN1, const DART& aN2, const DART& aP ) { REAL_TYPE pa[2]; REAL_TYPE pb[2]; REAL_TYPE pc[2]; pa[0] = aN1.X(); pa[1] = aN1.Y(); pb[0] = aN2.X(); pb[1] = aN2.Y(); pc[0] = aP.X(); pc[1] = aP.Y(); return ttl_util::Orient2DFast( pa, pb, pc ); } //@} // End of Geometric Predicates Group }; }; // End of hed namespace #endif