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fine tuning of the voronoi scaffolding engine

This commit is contained in:
Paolo Cignoni 2016-02-04 18:18:53 +00:00
parent 61fa57f561
commit 831e3f9036
1 changed files with 49 additions and 28 deletions
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73
vcg/complex/algorithms/voronoi_volume_sampling.h
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@ -50,8 +50,8 @@ public:
typedef typename vcg::tri::TrivialWalker<MeshType,MyVolume> MyWalker; typedef typename vcg::tri::TrivialWalker<MeshType,MyVolume> MyWalker;
typedef typename vcg::tri::MarchingCubes<MeshType, MyWalker> MyMarchingCubes; typedef typename vcg::tri::MarchingCubes<MeshType, MyWalker> MyMarchingCubes;
VoronoiVolumeSampling(MeshType &_baseMesh, MeshType &_seedMesh) VoronoiVolumeSampling(MeshType &_baseMesh)
:surfTree(0),seedTree(0),baseMesh(_baseMesh),seedMesh(_seedMesh),cb(0),restrictedRelaxationFlag(false) :surfTree(0),seedTree(0),baseMesh(_baseMesh),cb(0),restrictedRelaxationFlag(false)
{ {
tri::RequirePerFaceMark(baseMesh); tri::RequirePerFaceMark(baseMesh);
tri::UpdateBounding<MeshType>::Box(baseMesh); tri::UpdateBounding<MeshType>::Box(baseMesh);
@ -69,12 +69,13 @@ public:
vcg::face::PointDistanceBaseFunctor<ScalarType> PDistFunct; vcg::face::PointDistanceBaseFunctor<ScalarType> PDistFunct;
MeshType &baseMesh; MeshType &baseMesh;
MeshType &seedMesh; MeshType seedMesh;
MeshType poissonSurfaceMesh; MeshType poissonSurfaceMesh;
ScalarType poissonRadiusSurface; ScalarType poissonRadiusSurface;
MeshType montecarloVolumeMesh; // we use this mesh as volume evaluator MeshType montecarloVolumeMesh; // we use this mesh as volume evaluator
MeshType seedDomainMesh; // where we choose the seeds (by default is the montecarlo volume mesh) MeshType seedDomainMesh; // where we choose the seeds (by default is the montecarlo volume mesh)
vcg::CallBackPos *cb; vcg::CallBackPos *cb;
math::MarsenneTwisterRNG rng;
bool restrictedRelaxationFlag; bool restrictedRelaxationFlag;
@ -91,12 +92,14 @@ public:
ScalarType meshArea = Stat<MeshType>::ComputeMeshArea(baseMesh); ScalarType meshArea = Stat<MeshType>::ComputeMeshArea(baseMesh);
int MontecarloSurfSampleNum = 10 * meshArea / (poissonRadiusSurface*poissonRadiusSurface); int MontecarloSurfSampleNum = 10 * meshArea / (poissonRadiusSurface*poissonRadiusSurface);
tri::MeshSampler<MeshType> sampler(montecarloSurfaceMesh); tri::MeshSampler<MeshType> sampler(montecarloSurfaceMesh);
tri::SurfaceSampling<MeshType,tri::MeshSampler<MeshType> >::SamplingRandomGenerator()=rng;
tri::SurfaceSampling<MeshType,tri::MeshSampler<MeshType> >::Montecarlo(baseMesh, sampler, MontecarloSurfSampleNum); tri::SurfaceSampling<MeshType,tri::MeshSampler<MeshType> >::Montecarlo(baseMesh, sampler, MontecarloSurfSampleNum);
montecarloSurfaceMesh.bbox = baseMesh.bbox; // we want the same bounding box montecarloSurfaceMesh.bbox = baseMesh.bbox; // we want the same bounding box
poissonSurfaceMesh.Clear(); poissonSurfaceMesh.Clear();
tri::MeshSampler<MeshType> mps(poissonSurfaceMesh); tri::MeshSampler<MeshType> mps(poissonSurfaceMesh);
typename tri::SurfaceSampling<MeshType,tri::MeshSampler<MeshType> >::PoissonDiskParam pp; typename tri::SurfaceSampling<MeshType,tri::MeshSampler<MeshType> >::PoissonDiskParam pp;
pp.geodesicDistanceFlag=false; pp.geodesicDistanceFlag=false;
tri::SurfaceSampling<MeshType,tri::MeshSampler<MeshType> >::PoissonDiskPruning(mps, montecarloSurfaceMesh, poissonRadiusSurface,pp); tri::SurfaceSampling<MeshType,tri::MeshSampler<MeshType> >::PoissonDiskPruning(mps, montecarloSurfaceMesh, poissonRadiusSurface,pp);
vcg::tri::UpdateBounding<MeshType>::Box(poissonSurfaceMesh); vcg::tri::UpdateBounding<MeshType>::Box(poissonSurfaceMesh);
@ -144,7 +147,7 @@ ScalarType DistanceFromVoronoiSeed(CoordType p_point)
{ {
ScalarType squaredDist; ScalarType squaredDist;
unsigned int ind; unsigned int ind;
surfTree->doQueryClosest(p_point,ind,squaredDist); seedTree->doQueryClosest(p_point,ind,squaredDist);
return math::Sqrt(squaredDist); return math::Sqrt(squaredDist);
} }
@ -196,6 +199,30 @@ ScalarType DistanceFromVoronoiFace(CoordType p_point)
return closestDist; return closestDist;
} }
ScalarType DistanceFromVoronoiCorner(CoordType p_point)
{
seedTree->doQueryK(p_point,4,pq);
std::vector<std::pair<ScalarType, CoordType> > closeSeedVec;
CoordType p0= this->seedMesh.vert[pq.getIndex(0)].P();
CoordType p1= this->seedMesh.vert[pq.getIndex(1)].P();
CoordType p2= this->seedMesh.vert[pq.getIndex(2)].P();
CoordType p3= this->seedMesh.vert[pq.getIndex(3)].P();
Plane3<ScalarType> pl01; pl01.Init((p0+p1)/2.0f,p0-p1);
Plane3<ScalarType> pl02; pl02.Init((p0+p2)/2.0f,p0-p2);
Plane3<ScalarType> pl03; pl03.Init((p0+p3)/2.0f,p0-p3);
Line3<ScalarType> voroLine;
// Calculating the line R that intersect the planes pl01 and pl02
vcg::IntersectionPlanePlane(pl01,pl02,voroLine);
CoordType intersectionPt;
bool ret = vcg::IntersectionLinePlane(voroLine,pl03,intersectionPt);
return vcg::Distance(p_point,intersectionPt);
}
void BarycentricRelaxVoronoiSamples(int relaxStep) void BarycentricRelaxVoronoiSamples(int relaxStep)
{ {
bool changed=false; bool changed=false;
@ -319,26 +346,20 @@ void QuadricRelaxVoronoiSamples(int relaxStep)
* PruningPoisson: mesh of inside and surface points, it's the voronoi3d diagram * PruningPoisson: mesh of inside and surface points, it's the voronoi3d diagram
* n_voxel: number of voxels for the greater side * n_voxel: number of voxels for the greater side
*/ */
void BuildScaffoldingMesh(MeshType &scaffoldingMesh, int volumeSide, ScalarType isoThr,int elemEnum, bool surfFlag) void BuildScaffoldingMesh(MeshType &scaffoldingMesh, float voxelSide, ScalarType isoThr,int elemEnum, bool surfFlag)
{ {
printf("Scaffolding of the mesh \n");
MyVolume volume; MyVolume volume;
ScalarType max = math::Max(baseMesh.bbox.DimX(),baseMesh.bbox.DimY(),baseMesh.bbox.DimZ()); int sizeX = (baseMesh.bbox.DimX() / voxelSide)+1;
ScalarType voxel = max / volumeSide; int sizeY = (baseMesh.bbox.DimY() / voxelSide)+1;
int sizeX = (baseMesh.bbox.DimX() / voxel)+1; int sizeZ = (baseMesh.bbox.DimZ() / voxelSide)+1;
int sizeY = (baseMesh.bbox.DimY() / voxel)+1;
int sizeZ = (baseMesh.bbox.DimZ() / voxel)+1;
// Kdtree printf("Scaffolding of the mesh %i %i %i\n",sizeX,sizeY,sizeZ);
// seedTree->setMaxNofNeighbors(4);
BoxType bb = BoxType::Construct(baseMesh.bbox); BoxType bb = BoxType::Construct(baseMesh.bbox);
bb.Offset(baseMesh.bbox.Diag()*0.04f); bb.Offset(voxelSide+isoThr*2.0f);
volume.Init(Point3i(sizeX,sizeY,sizeZ),bb); volume.Init(Point3i(sizeX,sizeY,sizeZ),bb);
// qDebug("Init Volume of %i %i %i",sizeX,sizeY,sizeZ);
int cnt=0; int cnt=0;
ScalarType offset= volume.voxel.Norm()*isoThr;
for(ScalarType i=0;i<sizeX;i++) for(ScalarType i=0;i<sizeX;i++)
for(ScalarType j=0;j<sizeY;j++) for(ScalarType j=0;j<sizeY;j++)
for(ScalarType k=0;k<sizeZ;k++) for(ScalarType k=0;k<sizeZ;k++)
@ -351,9 +372,10 @@ void QuadricRelaxVoronoiSamples(int relaxStep)
ScalarType elemDist; ScalarType elemDist;
switch(elemEnum) switch(elemEnum)
{ {
case 0: elemDist = DistanceFromVoronoiSeed(p) - offset; break; case 0: elemDist = DistanceFromVoronoiSeed(p) - isoThr; break;
case 1: elemDist = DistanceFromVoronoiEdge(p) - offset; break; case 1: elemDist = DistanceFromVoronoiEdge(p) - isoThr; break;
case 2: elemDist = DistanceFromVoronoiFace(p) - offset; break; case 2: elemDist = DistanceFromVoronoiFace(p) - isoThr; break;
case 3: elemDist = DistanceFromVoronoiCorner(p) - isoThr; break;
default: assert(0); default: assert(0);
} }
@ -362,9 +384,9 @@ void QuadricRelaxVoronoiSamples(int relaxStep)
val = std::max(-elemDist,surfDist); val = std::max(-elemDist,surfDist);
else else
val = std::max(elemDist,surfDist); val = std::max(elemDist,surfDist);
volume.Val(i,j,k) = val; volume.Val(i,j,k) = val;
cnt++; cnt++;
} }
// MARCHING CUBES // MARCHING CUBES
@ -436,7 +458,6 @@ void QuadricRelaxVoronoiSamples(int relaxStep)
void RefineSkeletonVolume(MeshType &skelMesh) void RefineSkeletonVolume(MeshType &skelMesh)
{ {
math::SubtractiveRingRNG rng;
int trialNum=0; int trialNum=0;
for(int i=0;i<skelMesh.vn;++i) for(int i=0;i<skelMesh.vn;++i)
{ {
@ -454,7 +475,7 @@ void QuadricRelaxVoronoiSamples(int relaxStep)
void BuildMontecarloSampling(int montecarloSampleNum) void BuildMontecarloSampling(int montecarloSampleNum)
{ {
montecarloVolumeMesh.Clear(); montecarloVolumeMesh.Clear();
math::SubtractiveRingRNG rng;
int trialNum=0; int trialNum=0;
while(montecarloVolumeMesh.vn < montecarloSampleNum) while(montecarloVolumeMesh.vn < montecarloSampleNum)
{ {
@ -478,7 +499,7 @@ void QuadricRelaxVoronoiSamples(int relaxStep)
* Build a Poisson-Disk Point cloud that cover all the space of the original mesh m * Build a Poisson-Disk Point cloud that cover all the space of the original mesh m
* *
*/ */
void BuildVolumeSampling(int montecarloSampleNum, int seedNum, ScalarType &poissonRadius) void BuildVolumeSampling(int montecarloSampleNum, int poissonSampleNum, ScalarType &poissonRadius, int randSeed)
{ {
if(montecarloSampleNum >0) if(montecarloSampleNum >0)
this->BuildMontecarloSampling(montecarloSampleNum); this->BuildMontecarloSampling(montecarloSampleNum);
@ -486,10 +507,10 @@ void QuadricRelaxVoronoiSamples(int relaxStep)
tri::Append<MeshType,MeshType>::MeshCopy(seedDomainMesh,montecarloVolumeMesh); tri::Append<MeshType,MeshType>::MeshCopy(seedDomainMesh,montecarloVolumeMesh);
vector<VertexPointer> pruningVec; vector<VertexPointer> pruningVec;
if(poissonRadius ==0 && seedNum!=0) if(poissonRadius ==0 && poissonSampleNum!=0)
tri::PoissonPruningExact(seedDomainMesh,pruningVec,poissonRadius,seedNum); tri::PoissonPruningExact(seedDomainMesh,pruningVec,poissonRadius,poissonSampleNum,0.04,10,randSeed);
else else
tri::PoissonPruning(seedDomainMesh,pruningVec,poissonRadius,seedNum); tri::PoissonPruning(seedDomainMesh,pruningVec,poissonRadius,randSeed);
std::vector<CoordType> seedPts(pruningVec.size()); std::vector<CoordType> seedPts(pruningVec.size());
for(size_t i=0;i<pruningVec.size();++i) for(size_t i=0;i<pruningVec.size();++i)