557 lines
17 KiB
C++
557 lines
17 KiB
C++
/****************************************************************************
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* VCGLib o o *
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* Visual and Computer Graphics Library o o *
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* _ O _ *
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* Copyright(C) 2004-2016 \/)\/ *
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* Visual Computing Lab /\/| *
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* ISTI - Italian National Research Council | *
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* \ *
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* All rights reserved. *
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* *
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* This program is free software; you can redistribute it and/or modify *
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* it under the terms of the GNU General Public License as published by *
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* the Free Software Foundation; either version 2 of the License, or *
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* (at your option) any later version. *
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* *
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* This program is distributed in the hope that it will be useful, *
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* but WITHOUT ANY WARRANTY; without even the implied warranty of *
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* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the *
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* GNU General Public License (http://www.gnu.org/licenses/gpl.txt) *
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* for more details. *
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* *
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****************************************************************************/
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/****************************************************************************/
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#ifndef __VCG_DISTANCE3
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#define __VCG_DISTANCE3
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#include <limits>
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#include <vcg/space/intersection3.h>
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namespace vcg {
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/*
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* Computes the minimum distance between a 3D box and a point
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* @param[in] p The input point
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* @param[in] b The input bounding box
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* return The distance
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* This function returns 0 for points Inside the bbox while the next one return the distance from the surface
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*/
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template<class Scalar>
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Scalar PointFilledBoxDistance(const Point3<Scalar> &p, const Box3<Scalar> &bbox)
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{
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Scalar dist2 = 0.;
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Scalar aux;
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for (int k=0 ; k<3 ; ++k)
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{
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if ( (aux = (p[k]-bbox.min[k]))<0. )
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dist2 += aux*aux;
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else if ( (aux = (bbox.max[k]-p[k]))<0. )
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dist2 += aux*aux;
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}
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return sqrt(dist2);
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}
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/*
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* Computes the minimum distance between a 3D box and a point
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* @param[in] p The input point
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* @param[in] b The input bounding box
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* @param[out] dist The distance
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* Note that this function with respect to the previous one compute the distance between a point
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* and the 'surface' of a Box3.
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*
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*/
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template <class ScalarType>
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void PointBoxDistance(const Point3<ScalarType> &p,
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const Box3<ScalarType> &b,
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ScalarType& dist)
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{
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///if fall inside return distance to a face
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if (b.IsIn(p))
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{
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const ScalarType dx = std::min<ScalarType>(b.max.X()-p.X(), p.X()-b.min.X());
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const ScalarType dy = std::min<ScalarType>(b.max.Y()-p.Y(), p.Y()-b.min.Y());
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const ScalarType dz = std::min<ScalarType>(b.max.Z()-p.Z(), p.Z()-b.min.Z());
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dist= std::min<ScalarType>(dx, std::min<ScalarType>(dy, dz));
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return;
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}
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{
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ScalarType sq_dist = ScalarType(0);
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for (int i=0; i<3; ++i)
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{
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ScalarType delta = ScalarType(0);
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if (p[i] < b.min[i]) delta = p[i] - b.min[i];
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else if (p[i] > b.max[i]) delta = p[i] - b.max[i];
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sq_dist += delta * delta;
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}
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dist= math::Sqrt(sq_dist);
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}
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}
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/*
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* Computes the minimum distance between a sphere and a point
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* @param[in] p The input point
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* @param[in] sphere The input sphere
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* @param[out] dist The distance
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*/
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template <class ScalarType>
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void SpherePointDistance(const Sphere3<ScalarType> &sphere,
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const Point3<ScalarType> &p,
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ScalarType& dist)
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{
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dist = Distance(p, sphere.Center()) - sphere.Radius();
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if(dist < 0) dist = 0;
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}
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/*
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* Computes the minimum distance between two spheres
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* @param[in] sphere0 The input sphere
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* @param[in] sphere1 The input sphere
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* @param[out] dist The distance
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*/
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template <class ScalarType>
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void SphereSphereDistance(const Sphere3<ScalarType> &sphere0,
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const Sphere3<ScalarType> &sphere1,
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ScalarType& dist)
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{
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dist = (sphere1.Center()-sphere0.Center()).Norm()
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- sphere0.Radius() - sphere1.Radius();
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if(dist < 0) dist = 0;
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return dist;
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}
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/*
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* Computes the minimum squared distance between a between a point and a plane
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* @param[in] pl The input line
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* @param[in] p The input point
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* @param[out] closest The closest point
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* @param[out] dist The squared distance
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*/
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template <class ScalarType>
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void PlanePointSquaredDistance(const vcg::Plane3<ScalarType> &Pl,
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const Point3<ScalarType> &p,
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Point3<ScalarType> &closest,
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ScalarType &dist)
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{
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closest=Pl.Projection(p);
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dist= (closest - p).SquaredNorm();
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}
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/*
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* Computes the minimum squared distance between a between a point and a plane
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* @param[in] pl The input line
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* @param[in] p The input point
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* @param[out] closest The closest point
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* @param[out] dist The squared distance
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*/
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template <class ScalarType>
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ScalarType PlanePointSquaredDistance(const vcg::Plane3<ScalarType> &Pl,
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const Point3<ScalarType> &p)
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{
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ScalarType dist;
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vcg::Point3<ScalarType> closest;
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PlanePointSquaredDistance(Pl,p,closest,dist);
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return (dist);
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}
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/*
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* Computes the minimum squared distance between a between a point and a line
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* @param[in] l The input line
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* @param[in] p The input point
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* @param[out] closest The closest point
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* @param[out] dist The squared distance
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*/
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template <class ScalarType>
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void LinePointSquaredDistance(const Line3<ScalarType> &l,const Point3<ScalarType> &p,
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Point3<ScalarType> &closest,ScalarType &dist)
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{
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closest=l.P(l.Projection(p));
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dist= (closest - p).SquaredNorm();
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}
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/*
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* Computes the minimum distance between a between a point and a line
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* @param[in] l The input line
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* @param[in] p The input point
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* @param[out] closest The closest point
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* @param[out] dist The distance
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*/
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template <class ScalarType>
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void LinePointDistance(const Line3<ScalarType> &l,const Point3<ScalarType> &p,
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Point3<ScalarType> &closest,ScalarType &dist)
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{
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LinePointSquaredDistance(l,p,closest,dist);
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dist=sqrt(dist);
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}
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/*
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* Computes the minimum distance between two lines
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* @param[in] mLine0 The input line0
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* @param[in] mLine1 The input line1
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* @param[out] parallel true if the two lines are parallel
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* @param[mClosestPoint0] the closest point on line0
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* @param[mClosestPoint1] the closest point on line1
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*/
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template <class ScalarType>
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void LineLineDistance(const vcg::Line3<ScalarType> &mLine0,
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const vcg::Line3<ScalarType> &mLine1,
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bool ¶llel,
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ScalarType &dist,
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vcg::Point3<ScalarType> &mClosestPoint0,
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vcg::Point3<ScalarType> &mClosestPoint1)
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{
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const ScalarType loc_EPSILON=ScalarType(0.000000001);
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typedef typename vcg::Point3<ScalarType> CoordType;
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CoordType diff = mLine0.Origin() - mLine1.Origin();
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ScalarType a01 = -mLine0.Direction()* mLine1.Direction();
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ScalarType b0 = diff *(mLine0.Direction());
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ScalarType c = diff.SquaredNorm();
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ScalarType det = fabs((ScalarType)1 - a01*a01);
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ScalarType b1, s0, s1, sqrDist;
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if (det >=loc_EPSILON)
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{
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// Lines are not parallel.
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b1 = -diff*(mLine1.Direction());
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ScalarType invDet = ((ScalarType)1)/det;
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s0 = (a01*b1 - b0)*invDet;
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s1 = (a01*b0 - b1)*invDet;
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sqrDist = s0*(s0 + a01*s1 + ((ScalarType)2)*b0) +
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s1*(a01*s0 + s1 + ((ScalarType)2)*b1) + c;
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parallel=false;
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}
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else
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{
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// Lines are parallel, select any closest pair of points.
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s0 = -b0;
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s1 = (ScalarType)0;
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sqrDist = b0*s0 + c;
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parallel=true;
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}
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///find the two closest points
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mClosestPoint0 = mLine0.Origin() + mLine0.Direction()*s0;
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mClosestPoint1 = mLine1.Origin() + mLine1.Direction()*s1;
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/*mLine0Parameter = s0;
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mLine1Parameter = s1;*/
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// Account for numerical round-off errors.
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if (sqrDist < (ScalarType)0)
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{
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sqrDist = (ScalarType)0;
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}
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dist=sqrt(sqrDist);
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}
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/*
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* Computes the minimum distance between a segment and a point
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* @param[in] segment The input segment
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* @param[in] p The input point
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* @param[in] clos The closest point
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* @param[in] sqr_dist The squared distance
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*/
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template <class ScalarType>
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void SegmentPointSquaredDistance( const Segment3<ScalarType> &s,
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const Point3<ScalarType> & p,
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Point3< ScalarType > &closest,
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ScalarType &sqr_dist)
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{
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Point3<ScalarType> e = s.P1()-s.P0();
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ScalarType eSquaredNorm = e.SquaredNorm();
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if (eSquaredNorm < std::numeric_limits<ScalarType>::min())
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{
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closest=s.MidPoint();
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sqr_dist=SquaredDistance(closest,p);
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}
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else
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{
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ScalarType t = ((p-s.P0())*e)/eSquaredNorm;
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if(t<0) t = 0;
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else if(t>1) t = 1;
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closest = s.P0()+e*t;
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sqr_dist = SquaredDistance(p,closest);
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assert(!math::IsNAN(sqr_dist));
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}
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}
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/*
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* Computes the minimum distance between a segment and a point
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* @param[in] segment The input segment
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* @param[in] p The input point
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* @param[in] clos The closest point
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* @param[in] dist The distance
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*/
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template <class ScalarType>
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void SegmentPointDistance( Segment3<ScalarType> s,
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const Point3<ScalarType> & p,
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Point3< ScalarType > &clos,
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ScalarType &dist)
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{
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SegmentPointSquaredDistance(s,p,clos,dist);
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dist=sqrt(dist);
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}
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/*
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* Computes the minimum distance between two segments
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* @param[in] s0 The input segment0
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* @param[in] s1 The input segment1
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* @param[out] parallel true if the two segments are parallel
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* @param[out] dist the distance
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* @param[closest0] the closest point on segment0
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* @param[closest1] the closest point on segment1
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*/
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template <class ScalarType>
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void SegmentSegmentDistance(const vcg::Segment3<ScalarType> &s0,
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const vcg::Segment3<ScalarType> &s1,
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ScalarType &dist,
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bool ¶llel,
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vcg::Point3<ScalarType> &closest0,
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vcg::Point3<ScalarType> &closest1)
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{
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typedef typename vcg::Point3<ScalarType> CoordType;
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vcg::Line3<ScalarType> l0,l1;
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///construct two lines
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l0.SetOrigin(s0.P0());
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l0.SetDirection((s0.P1()-s0.P0()).Normalize());
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l1.SetOrigin(s1.P0());
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l1.SetDirection((s1.P1()-s1.P0()).Normalize());
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///then find closest point
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ScalarType line_dist;
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CoordType closest_test0,closest_test1;
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LineLineDistance(l0,l1,parallel,line_dist,closest_test0,closest_test1);
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///special case if the two lines are parallel
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if (parallel)
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{
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///find the minimum distance between extremes to segments
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ScalarType dist_test;
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CoordType clos_test;
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//CoordType to_test[4]={s1.P0(),s1.P1(),s0.P0(),s1.P1()};
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///find combination of distances between all extremes and segments
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SegmentPointSquaredDistance(s0,s1.P0(),clos_test,dist);
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closest0=clos_test;
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closest1=s1.P0();
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///and find the minimum updating coherently the closest points
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SegmentPointSquaredDistance(s0,s1.P1(),clos_test,dist_test);
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if (dist_test<dist)
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{
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dist=dist_test;
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closest0=clos_test;
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closest1=s1.P1();
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}
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SegmentPointSquaredDistance(s1,s0.P0(),clos_test,dist_test);
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if (dist_test<dist)
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{
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dist=dist_test;
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closest0=s0.P0();
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closest1=clos_test;
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}
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SegmentPointSquaredDistance(s1,s0.P1(),clos_test,dist_test);
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if (dist_test<dist)
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{
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dist=dist_test;
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closest0=s0.P1();
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closest1=clos_test;
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}
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dist=sqrt(dist);
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return;
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}
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///then ffind the closest segments points...
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///means that if it is not an extreme then take
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///the closest extreme
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ScalarType sqr_dist0;
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SegmentPointSquaredDistance(s0,closest_test0,closest0,sqr_dist0);
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ScalarType sqr_dist1;
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SegmentPointSquaredDistance(s1,closest_test1,closest1,sqr_dist1);
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///then return the distance
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dist=(closest0-closest1).Norm();
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}
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/* @brief Computes the distance between a triangle and a point.
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*
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* @param t reference to the triangle
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* @param q point location
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* @param dist distance from p to t
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* @param closest perpendicular projection of p onto t
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*/
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template<class ScalarType>
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void TrianglePointDistance(const vcg::Triangle3<ScalarType> &t,
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const typename vcg::Point3<ScalarType> & q,
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ScalarType & dist,
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typename vcg::Point3<ScalarType> & closest )
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{
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typedef typename vcg::Point3<ScalarType> CoordType;
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CoordType clos[3];
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ScalarType distv[3];
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CoordType clos_proj;
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ScalarType distproj;
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///find distance on the plane
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vcg::Plane3<ScalarType> plane;
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plane.Init(t.P(0),t.P(1),t.P(2));
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clos_proj=plane.Projection(q);
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///control if inside/outside
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CoordType n=(t.P(1)-t.P(0))^(t.P(2)-t.P(0));
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CoordType n0=(t.P(0)-clos_proj)^(t.P(1)-clos_proj);
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CoordType n1=(t.P(1)-clos_proj)^(t.P(2)-clos_proj);
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CoordType n2=(t.P(2)-clos_proj)^(t.P(0)-clos_proj);
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distproj=(clos_proj-q).Norm();
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if (((n*n0)>=0)&&((n*n1)>=0)&&((n*n2)>=0))
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{
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closest=clos_proj;
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dist=distproj;
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return;
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}
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//distance from the edges
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vcg::Segment3<ScalarType> e0=vcg::Segment3<ScalarType>(t.P(0),t.P(1));
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vcg::Segment3<ScalarType> e1=vcg::Segment3<ScalarType>(t.P(1),t.P(2));
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vcg::Segment3<ScalarType> e2=vcg::Segment3<ScalarType>(t.P(2),t.P(0));
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SegmentPointDistance(e0,q,clos[0],distv[0]);
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SegmentPointDistance(e1,q,clos[1],distv[1]);
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SegmentPointDistance(e2,q,clos[2],distv[2]);
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/*clos[0]=ClosestPoint<ScalarType>( e0, q);
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clos[1]=ClosestPoint<ScalarType>( e1, q);
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clos[2]=ClosestPoint<ScalarType>( e2, q);
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*/
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//distv[0]=(clos[0]-q).Norm();
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//distv[1]=(clos[1]-q).Norm();
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//distv[2]=(clos[2]-q).Norm();
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int min=0;
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///find minimum distance
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for (int i=1;i<3;i++)
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{
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if (distv[i]<distv[min])
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min=i;
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}
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closest=clos[min];
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dist=distv[min];
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}
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/*
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* return the distance between a triangle and a segment
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* @param[in] t The input triangle
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* @param[in] s The input segment
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* @param[out] dist the distance
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*/
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template<class ScalarType>
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void TriangleSegmentDistance(const vcg::Triangle3<ScalarType> &t,
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const vcg::Segment3<ScalarType> &s,
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ScalarType & dist)
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{
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dist=std::numeric_limits<ScalarType>::max();
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///test the intersection
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ScalarType a,b;
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typedef typename vcg::Point3<ScalarType> CoordType;
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bool intersect=IntersectionSegmentTriangle<vcg::Triangle3<ScalarType> >(s,t,a,b);
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if (intersect)
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{
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dist=0;
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return;
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}
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///project endpoints and see if they fall into the triangle
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vcg::Plane3<ScalarType> pl3;
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pl3.Init(t.P(0),t.P(1),t.P(2));
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CoordType pj0=pl3.Projection(s.P(0));
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CoordType pj1=pl3.Projection(s.P(1));
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///take distances
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ScalarType dpj0=(pj0-s.P(0)).Norm();
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ScalarType dpj1=(pj1-s.P(1)).Norm();
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///test if they fall inside the triangle
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CoordType bary0,bary1;
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bool Inside0=vcg::InterpolationParameters(t,pj0,bary0);
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bool Inside1=vcg::InterpolationParameters(t,pj1,bary1);
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if (Inside0&&Inside1)
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{
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dist=std::min(dpj0,dpj1);
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return;
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}
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///initialize with the sdistance if only once falls into
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if (Inside0)
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dist=dpj0;
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if (Inside1)
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dist=dpj1;
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|
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///then test segment-to segment distance with edges of the triangle
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for (int i=0;i<3;i++)
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{
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vcg::Segment3<ScalarType> edge=vcg::Segment3<ScalarType>(t.P0(i),t.P0((i+1)%3));
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ScalarType test_dist;
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CoordType clos1,clos2;
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bool parallel;
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vcg::SegmentSegmentDistance<ScalarType>(s,edge,test_dist,parallel,clos1,clos2);
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if (test_dist<dist)
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|
dist=test_dist;
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|
}
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|
}
|
|
|
|
/*
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* return the minimum distance between two triangles
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|
* @param[in] t0 The input triangle0
|
|
* @param[in] t1 The input triangle1
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|
* @param[out] dist the distance
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|
*/
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|
template<class ScalarType>
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|
void TriangleTriangleDistance(const vcg::Triangle3<ScalarType> &t0,
|
|
const vcg::Triangle3<ScalarType> &t1,
|
|
ScalarType &dist)
|
|
{
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|
const ScalarType loc_EPSILON=(vcg::DoubleArea(t0)+vcg::DoubleArea(t1))*(ScalarType)0.0000001;
|
|
dist=std::numeric_limits<ScalarType>::max();
|
|
|
|
///test each segment of t1 with t0
|
|
///keeping the minimum distance
|
|
for (int i=0;i<3;i++)
|
|
{
|
|
vcg::Segment3<ScalarType> edge=vcg::Segment3<ScalarType>(t0.P0(i),t0.P0((i+1)%3));
|
|
ScalarType test_dist;
|
|
vcg::TriangleSegmentDistance<ScalarType>(t1,edge,test_dist);
|
|
if (test_dist<loc_EPSILON)
|
|
{
|
|
dist=0;
|
|
return;
|
|
}
|
|
if (test_dist<dist)
|
|
dist=test_dist;
|
|
}
|
|
///then viceversa
|
|
for (int i=0;i<3;i++)
|
|
{
|
|
vcg::Segment3<ScalarType> edge=vcg::Segment3<ScalarType>(t1.P0(i),t1.P0((i+1)%3));
|
|
ScalarType test_dist;
|
|
vcg::TriangleSegmentDistance<ScalarType>(t0,edge,test_dist);
|
|
if (test_dist<loc_EPSILON)
|
|
{
|
|
dist=0;
|
|
return;
|
|
}
|
|
if (test_dist<dist)
|
|
dist=test_dist;
|
|
}
|
|
}
|
|
|
|
}///end namespace vcg
|
|
|
|
#endif
|