vcglib/vcg/complex/algorithms/intersection.h

459 lines
16 KiB
C++

/****************************************************************************
* VCGLib o o *
* Visual and Computer Graphics Library o o *
* _ O _ *
* Copyright(C) 2004-2016 \/)\/ *
* Visual Computing Lab /\/| *
* ISTI - Italian National Research Council | *
* \ *
* All rights reserved. *
* *
* This program is free software; you can redistribute it and/or modify *
* it under the terms of the GNU General Public License as published by *
* the Free Software Foundation; either version 2 of the License, or *
* (at your option) any later version. *
* *
* This program 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 General Public License (http://www.gnu.org/licenses/gpl.txt) *
* for more details. *
* *
****************************************************************************/
#include<vcg/space/plane3.h>
#include<vcg/space/segment3.h>
#include<vcg/space/intersection3.h>
#include<vcg/complex/complex.h>
#include<vcg/complex/algorithms/closest.h>
#include<vcg/complex/algorithms/update/quality.h>
#ifndef __VCGLIB_INTERSECTION_TRI_MESH
#define __VCGLIB_INTERSECTION_TRI_MESH
namespace vcg{
// NAMING CONVENTION
// INTERSECTION<SIMPLEOBJECT,COMPLEXSTUFF>
// and it returns the portion of Complexstuff intersected by the simpleobject.
/** \addtogroup complex */
/*@{*/
/**
Function computing the intersection between a grid and a plane. It returns all the cells intersected
*/
template < typename GridType,typename ScalarType>
bool IntersectionPlaneGrid( GridType & grid, Plane3<ScalarType> plane, std::vector<typename GridType::Cell *> &cells)
{
cells.clear();
Point3d p,_d;
Plane3d pl;
_d.Import(plane.Direction());
pl.SetDirection(_d);
pl.SetOffset(plane.Offset());
for( int ax = 0; ax <3; ++ax)
{ int axis = ax;
int axis0 = (axis+1)%3;
int axis1 = (axis+2)%3;
int i,j;
Point3i pi;
Segment3<double> seg;
seg.P0().Import(grid.bbox.min);
seg.P1().Import(grid.bbox.min);
seg.P1()[axis] = grid.bbox.max[axis];
for(i = 0 ; i <= grid.siz[axis0]; ++i){
for(j = 0 ; j <= grid.siz[axis1]; ++j)
{
seg.P0()[axis0] = grid.bbox.min[axis0]+ (i+0.01) * grid.voxel[axis0] ;
seg.P1()[axis0] = grid.bbox.min[axis0]+ (i+0.01) * grid.voxel[axis0];
seg.P0()[axis1] = grid.bbox.min[axis1]+ (j+0.01) * grid.voxel[axis1];
seg.P1()[axis1] = grid.bbox.min[axis1]+ (j+0.01) * grid.voxel[axis1];
if ( IntersectionPlaneSegmentEpsilon(pl,seg,p))
{
pi[axis] = std::min(std::max(0,(int)floor((p[axis ]-grid.bbox.min[axis])/grid.voxel[axis])),grid.siz[axis]);
pi[axis0] = i;
pi[axis1] = j;
grid.Grid(pi,axis,cells);
}
}
}
}
sort(cells.begin(),cells.end());
cells.erase(unique(cells.begin(),cells.end()),cells.end());
return false;
}
/*@}*/
/** \addtogroup complex */
/*@{*/
/** \brief Compute the intersection between a trimesh and a plane building an edge mesh.
*
Basic Function Computing the intersection between a trimesh and a plane. It returns an EdgeMesh without needing anything else.
Note: This version always returns a segment for each triangle of the mesh which intersects with the plane. In other
words there are 2*n vertices where n is the number of segments fo the mesh. You can run vcg::edge:Unify to unify
the vertices closer that a given value epsilon. Note that, due to subtraction error during triangle plane intersection,
it is not safe to put epsilon to 0.
*/
template < typename TriMeshType, typename EdgeMeshType, class ScalarType >
bool IntersectionPlaneMeshOld(TriMeshType & m,
Plane3<ScalarType> pl,
EdgeMeshType & em)
{
typename EdgeMeshType::VertexIterator vi;
typename TriMeshType::FaceIterator fi;
em.Clear();
Segment3<ScalarType> seg;
for(fi=m.face.begin();fi!=m.face.end();++fi)
if(!(*fi).IsD())
{
if(vcg::IntersectionPlaneTriangle(pl,*fi,seg))// intersezione piano triangolo
{
vcg::tri::Allocator<EdgeMeshType>::AddEdges(em,1);
vi = vcg::tri::Allocator<EdgeMeshType>::AddVertices(em,2);
(*vi).P() = seg.P0();
em.edge.back().V(0) = &(*vi);
vi++;
(*vi).P() = seg.P1();
em.edge.back().V(1) = &(*vi);
}
}//end for
return true;
}
/** \addtogroup complex */
/*@{*/
/** \brief More stable version of the IntersectionPlaneMesh function
*
* This version of the make a first pass storing the distance to the plane
* into a vertex attribute and then use this value to compute in a safe way the
* intersection.
*/
template < typename TriMeshType, typename EdgeMeshType, class ScalarType >
bool IntersectionPlaneMesh(TriMeshType & m,
Plane3<ScalarType> pl,
EdgeMeshType & em)
{
std::vector<Point3<ScalarType> > ptVec;
std::vector<Point3<ScalarType> > nmVec;
typename TriMeshType::template PerVertexAttributeHandle < ScalarType > qH =
tri::Allocator<TriMeshType> :: template AddPerVertexAttribute < ScalarType >(m,"TemporaryPlaneDistance");
for(auto vi=m.vert.begin();vi!=m.vert.end();++vi) if(!(*vi).IsD())
qH[vi] = SignedDistancePlanePoint(pl,(*vi).cP());
for(size_t i=0;i<m.face.size();i++)
if(!m.face[i].IsD())
{
ptVec.clear();
nmVec.clear();
for(int j=0;j<3;++j)
{
if((qH[m.face[i].V0(j)] * qH[m.face[i].V1(j)])<0)
{
const Point3<ScalarType> &p0 = m.face[i].V0(j)->cP();
const Point3<ScalarType> &p1 = m.face[i].V1(j)->cP();
const Point3<ScalarType> &n0 = m.face[i].V0(j)->cN();
const Point3<ScalarType> &n1 = m.face[i].V1(j)->cN();
float q0 = qH[m.face[i].V0(j)];
float q1 = qH[m.face[i].V1(j)];
// printf("Intersection ( %3.2f %3.2f %3.2f )-( %3.2f %3.2f %3.2f )\n",p0[0],p0[1],p0[2],p1[0],p1[1],p1[2]);
Point3<ScalarType> pp;
Segment3<ScalarType> seg(p0,p1);
IntersectionPlaneSegment(pl,seg,pp);
ptVec.push_back(pp);
Point3<ScalarType> nn =(n0*fabs(q1) + n1*fabs(q0))/fabs(q0-q1);
nmVec.push_back(nn);
}
if (qH[m.face[i].V(j)] == 0)
{
ptVec.push_back(m.face[i].V(j)->cP());
nmVec.push_back(m.face[i].V(j)->cN());
}
}
if(ptVec.size()>=2)
{
typename EdgeMeshType::VertexIterator vi;
vcg::tri::Allocator<EdgeMeshType>::AddEdges(em,1);
vi = vcg::tri::Allocator<EdgeMeshType>::AddVertices(em,2);
(*vi).P() = ptVec[0];
(*vi).N() = nmVec[0];
em.edge.back().V(0) = &(*vi);
vi++;
(*vi).P() = ptVec[1];
(*vi).N() = nmVec[1];
em.edge.back().V(1) = &(*vi);
}
}
tri::Allocator<TriMeshType> :: template DeletePerVertexAttribute < ScalarType >(m,qH);
return true;
}
/** \addtogroup complex */
/*@{*/
/**
Compute the intersection between a trimesh and a plane.
given a plane return the set of faces that are contained
into intersected cells.
*/
template < typename TriMeshType, class ScalarType, class IndexingType >
bool Intersection(Plane3<ScalarType> pl,
IndexingType *grid,
typename std::vector<typename TriMeshType::FaceType*> &v)
{
typedef IndexingType GridType;
typename TriMeshType::FaceIterator fi;
v.clear();
typename std::vector< typename GridType::Cell* > cells;
Intersect(*grid,pl,cells);
typename std::vector<typename GridType::Cell*>::iterator ic;
typename GridType::Cell fs,ls;
for(ic = cells.begin(); ic != cells.end();++ic)
{
grid->Grid(*ic,fs,ls);
typename GridType::Link * lk = fs;
while(lk != ls){
typename TriMeshType::FaceType & face = *(lk->Elem());
v.push_back(&face);
lk++;
}//end while
}//end for
return true;
}
/**
Computes the intersection between a Ray and a Mesh. Returns a 3D Pointset.
*/
template < typename TriMeshType, class ScalarType>
bool IntersectionRayMesh(
/* Input Mesh */ TriMeshType * m,
/* Ray */ const Line3<ScalarType> & ray,
/* Intersect Point */ Point3<ScalarType> & hitPoint)
{
//typedef typename TriMeshType::FaceContainer FaceContainer;
typename TriMeshType::FaceIterator fi;
bool hit=false;
if(m==0) return false;
//TriMeshType::FaceIterator fi;
//std::vector<TriMeshType::FaceType*>::iterator fi;
ScalarType bar1,bar2,dist;
Point3<ScalarType> p1;
Point3<ScalarType> p2;
Point3<ScalarType> p3;
for(fi = m->face.begin(); fi != m->face.end(); ++fi)
{
p1=vcg::Point3<ScalarType>( (*fi).P(0).X() ,(*fi).P(0).Y(),(*fi).P(0).Z() );
p2=vcg::Point3<ScalarType>( (*fi).P(1).X() ,(*fi).P(1).Y(),(*fi).P(1).Z() );
p3=vcg::Point3<ScalarType>( (*fi).P(2).X() ,(*fi).P(2).Y(),(*fi).P(2).Z() );
if(IntersectionLineTriangle<ScalarType>(ray,p1,p2,p3,dist,bar1,bar2))
{
hitPoint= p1*(1-bar1-bar2) + p2*bar1 + p3*bar2;
hit=true;
}
}
return hit;
}
/**
Computes the intersection between a Ray and a Mesh. Returns a 3D Pointset, baricentric's coordinates
and a pointer of intersected face.
*/
template < typename TriMeshType, class ScalarType>
bool IntersectionRayMesh(
/* Input Mesh */ TriMeshType * m,
/* Ray */ const Line3<ScalarType> & ray,
/* Intersect Point */ Point3<ScalarType> & hitPoint,
/* Baricentric coord 1*/ ScalarType &bar1,
/* Baricentric coord 2*/ ScalarType &bar2,
/* Baricentric coord 3*/ ScalarType &bar3,
/* FacePointer */ typename TriMeshType::FacePointer & fp
)
{
//typedef typename TriMeshType::FaceContainer FaceContainer;
typename TriMeshType::FaceIterator fi;
bool hit=false;
if(m==0) return false;
//TriMeshType::FaceIterator fi;
//std::vector<TriMeshType::FaceType*>::iterator fi;
ScalarType dist;
Point3<ScalarType> p1;
Point3<ScalarType> p2;
Point3<ScalarType> p3;
for(fi = m->face.begin(); fi != m->face.end(); ++fi)
{
p1=vcg::Point3<ScalarType>( (*fi).P(0).X() ,(*fi).P(0).Y(),(*fi).P(0).Z() );
p2=vcg::Point3<ScalarType>( (*fi).P(1).X() ,(*fi).P(1).Y(),(*fi).P(1).Z() );
p3=vcg::Point3<ScalarType>( (*fi).P(2).X() ,(*fi).P(2).Y(),(*fi).P(2).Z() );
if(IntersectionLineTriangle<ScalarType>(ray,p1,p2,p3,dist,bar1,bar2))
{
bar3 = (1-bar1-bar2);
hitPoint= p1*bar3 + p2*bar1 + p3*bar2;
fp = &(*fi);
hit=true;
}
}
return hit;
}
/**
Compute the intersection between a mesh and a ball.
given a mesh return a new mesh made by a copy of all the faces entirely includeded in the ball plus
new faces created by refining the ones intersected by the ball border.
It works by recursively splitting the triangles that cross the border, as long as their area is greater than
a given value tol. If no value is provided, 1/10^5*2*pi*radius is used
NOTE: the returned mesh is a triangle soup
*/
template < typename TriMeshType, class ScalarType>
void IntersectionBallMesh( TriMeshType & m, const vcg::Sphere3<ScalarType> &ball, TriMeshType & res,
float tol = 0){
typename TriMeshType::VertexIterator v0,v1,v2;
typename TriMeshType::FaceIterator fi;
std::vector<typename TriMeshType:: FaceType*> closests;
vcg::Point3<ScalarType> witness;
std::pair<ScalarType, ScalarType> info;
if(tol == 0) tol = M_PI * ball.Radius() * ball.Radius() / 100000;
tri::UpdateSelection<TriMeshType>::FaceClear(m);
for(fi = m.face.begin(); fi != m.face.end(); ++fi)
if(!(*fi).IsD() && IntersectionSphereTriangle<ScalarType>(ball ,(*fi), witness , &info))
(*fi).SetS();
res.Clear();
tri::Append<TriMeshType,TriMeshType>::Selected(res,m);
int i =0;
while(i<res.fn){
bool allIn = ( ball.IsIn(res.face[i].P(0)) && ball.IsIn(res.face[i].P(1))&&ball.IsIn(res.face[i].P(2)));
if( IntersectionSphereTriangle<ScalarType>(ball ,res.face[i], witness , &info) && !allIn){
if(vcg::DoubleArea(res.face[i]) > tol)
{
// split the face res.face[i] in four, add the four new faces to the mesh and delete the face res.face[i]
v0 = vcg::tri::Allocator<TriMeshType>::AddVertices(res,3);
fi = vcg::tri::Allocator<TriMeshType>::AddFaces(res,4);
v1 = v0; ++v1;
v2 = v1; ++v2;
(*v0).P() = (res.face[i].P(0) + res.face[i].P(1))*0.5;
(*v1).P() = (res.face[i].P(1) + res.face[i].P(2))*0.5;
(*v2).P() = (res.face[i].P(2) + res.face[i].P(0))*0.5;
(*fi).V(0) = res.face[i].V(0);
(*fi).V(1) = &(*v0);
(*fi).V(2) = &(*v2);
++fi;
(*fi).V(0) = res.face[i].V(1);
(*fi).V(1) = &(*v1);
(*fi).V(2) = &(*v0);
++fi;
(*fi).V(0) = &(*v0);
(*fi).V(1) = &(*v1);
(*fi).V(2) = &(*v2);
++fi;
(*fi).V(0) = &(*v2);
(*fi).V(1) = &(*v1);
(*fi).V(2) = res.face[i].V(2) ;
vcg::tri::Allocator<TriMeshType>::DeleteFace(res,res.face[i]);
}
}// there was no intersection with the boundary
if(info.first > 0.0) // closest point - radius. If >0 is outside
vcg::tri::Allocator<TriMeshType>::DeleteFace(res,res.face[i]);
++i;
}
}
template < typename TriMeshType, class ScalarType, class IndexingType>
void IntersectionBallMesh( IndexingType * grid, TriMeshType & m, const vcg::Sphere3<ScalarType> &ball, TriMeshType & res,
float tol = 0){
typename TriMeshType::VertexIterator v0,v1,v2;
typename std::vector<typename TriMeshType::FacePointer >::iterator cfi;
typename TriMeshType::FaceIterator fi;
std::vector<typename TriMeshType:: FaceType*> closestsF,closests;
vcg::Point3<ScalarType> witness;
std::vector<vcg::Point3<ScalarType> > witnesses;
std::vector<ScalarType> distances;
std::pair<ScalarType, ScalarType> info;
if(tol == 0) tol = M_PI * ball.Radius() * ball.Radius() / 100000;
vcg::tri::GetInSphereFaceBase(m,*grid, ball.Center(), ball.Radius(),closestsF,distances,witnesses);
for(cfi =closestsF.begin(); cfi != closestsF.end(); ++cfi)
if(!(**cfi).IsD() && IntersectionSphereTriangle<ScalarType>(ball ,(**cfi), witness , &info))
closests.push_back(&(**cfi));
res.Clear();
SubSet(res,closests);
int i =0;
while(i<res.fn){
bool allIn = ( ball.IsIn(res.face[i].P(0)) && ball.IsIn(res.face[i].P(1))&&ball.IsIn(res.face[i].P(2)));
if( IntersectionSphereTriangle<ScalarType>(ball ,res.face[i], witness , &info) && !allIn){
if(vcg::DoubleArea(res.face[i]) > tol)
{
// split the face res.face[i] in four, add the four new faces to the mesh and delete the face res.face[i]
v0 = vcg::tri::Allocator<TriMeshType>::AddVertices(res,3);
fi = vcg::tri::Allocator<TriMeshType>::AddFaces(res,4);
v1 = v0; ++v1;
v2 = v1; ++v2;
(*v0).P() = (res.face[i].P(0) + res.face[i].P(1))*0.5;
(*v1).P() = (res.face[i].P(1) + res.face[i].P(2))*0.5;
(*v2).P() = (res.face[i].P(2) + res.face[i].P(0))*0.5;
(*fi).V(0) = res.face[i].V(0);
(*fi).V(1) = &(*v0);
(*fi).V(2) = &(*v2);
++fi;
(*fi).V(0) = res.face[i].V(1);
(*fi).V(1) = &(*v1);
(*fi).V(2) = &(*v0);
++fi;
(*fi).V(0) = &(*v0);
(*fi).V(1) = &(*v1);
(*fi).V(2) = &(*v2);
++fi;
(*fi).V(0) = &(*v2);
(*fi).V(1) = &(*v1);
(*fi).V(2) = res.face[i].V(2) ;
vcg::tri::Allocator<TriMeshType>::DeleteFace(res,res.face[i]);
}
}// there was no intersection with the boundary
if(info.first > 0.0) // closest point - radius. If >0 is outside
vcg::tri::Allocator<TriMeshType>::DeleteFace(res,res.face[i]);
++i;
}
}
/*@}*/
} // end namespace vcg
#endif