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/****************************************************************************
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* VCGLib o o *
* Visual and Computer Graphics Library o o *
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* Copyright ( C ) 2004 - 2016 \ / ) \ / *
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* Visual Computing Lab / \ / | *
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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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* This program is distributed in the hope that it will be useful , *
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# ifndef VORONOI_PROCESSING_H
# define VORONOI_PROCESSING_H
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# include <vcg/complex/algorithms/geodesic.h>
# include <vcg/complex/algorithms/update/color.h>
# include <vcg/complex/algorithms/refine.h>
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# include <vcg/complex/algorithms/smooth.h>
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# include <vcg/space/fitting3.h>
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# include <wrap/callback.h>
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namespace vcg
{
namespace tri
{
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struct VoronoiProcessingParameter
{
enum {
None = 0 ,
DistanceFromSeed = 1 ,
DistanceFromBorder = 2 ,
RegionArea = 3
} ;
VoronoiProcessingParameter ( )
{
colorStrategy = DistanceFromSeed ;
areaThresholdPerc = 0 ;
deleteUnreachedRegionFlag = false ;
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constrainSelectedSeed = false ;
preserveFixedSeed = false ;
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collapseShortEdge = false ;
collapseShortEdgePerc = 0.01f ;
triangulateRegion = false ;
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unbiasedSeedFlag = true ;
geodesicRelaxFlag = true ;
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relaxOnlyConstrainedFlag = false ;
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refinementRatio = 5.0f ;
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seedPerturbationProbability = 0 ;
seedPerturbationAmount = 0.001f ;
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}
int colorStrategy ;
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float areaThresholdPerc ;
bool deleteUnreachedRegionFlag ;
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bool unbiasedSeedFlag ;
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bool constrainSelectedSeed ; /// If true the selected vertexes define a constraining domain:
/// During relaxation all selected seeds are constrained to move
/// only on other selected vertices.
/// In this way you can constrain some seed to move only on certain
/// domains, for example moving only along some linear features
/// like border of creases.
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bool relaxOnlyConstrainedFlag ;
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bool preserveFixedSeed ; /// If true the 'fixed' seeds are not moved during relaxation.
/// \see FixVertexVector function to see how to fix a set of seeds.
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float refinementRatio ; /// It defines how much the input mesh has to be refined in order to have a supporting
/// triangulation that is dense enough to well approximate the voronoi diagram.
/// reasonable values are in the range 4..10. It is used by PreprocessForVoronoi and this value
/// says how many triangles you should expect in a voronoi region of a given radius.
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float seedPerturbationProbability ; /// if true at each iteration step each seed has the given probability to be perturbed a little.
float seedPerturbationAmount ; /// As a bbox diag fraction (e.g. in the 0..1 range).
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// Convertion to Voronoi Diagram Parameters
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bool triangulateRegion ; /// If true when building the voronoi diagram mesh each region is a
/// triangulated polygon. Otherwise it each voronoi region is a star
/// triangulation with the original seed in the center.
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bool collapseShortEdge ;
float collapseShortEdgePerc ;
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bool geodesicRelaxFlag ;
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} ;
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template < class MeshType , class DistanceFunctor = EuclideanDistance < MeshType > >
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class VoronoiProcessing
{
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typedef typename MeshType : : CoordType CoordType ;
typedef typename MeshType : : ScalarType ScalarType ;
typedef typename MeshType : : VertexType VertexType ;
typedef typename MeshType : : VertexPointer VertexPointer ;
typedef typename MeshType : : VertexIterator VertexIterator ;
typedef typename MeshType : : FacePointer FacePointer ;
typedef typename MeshType : : FaceIterator FaceIterator ;
typedef typename MeshType : : FaceType FaceType ;
typedef typename MeshType : : FaceContainer FaceContainer ;
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typedef typename tri : : Geodesic < MeshType > : : VertDist VertDist ;
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static math : : MarsenneTwisterRNG & RandomGenerator ( )
{
static math : : MarsenneTwisterRNG rnd ;
return rnd ;
}
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public :
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typedef typename MeshType : : template PerVertexAttributeHandle < VertexPointer > PerVertexPointerHandle ;
typedef typename MeshType : : template PerVertexAttributeHandle < bool > PerVertexBoolHandle ;
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typedef typename MeshType : : template PerVertexAttributeHandle < float > PerVertexFloatHandle ;
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typedef typename MeshType : : template PerFaceAttributeHandle < VertexPointer > PerFacePointerHandle ;
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// Given a vector of point3f it finds the closest vertices on the mesh.
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static void SeedToVertexConversion ( MeshType & m , std : : vector < CoordType > & seedPVec , std : : vector < VertexType * > & seedVVec , bool compactFlag = true )
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{
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typedef typename vcg : : SpatialHashTable < VertexType , ScalarType > HashVertexGrid ;
seedVVec . clear ( ) ;
HashVertexGrid HG ;
HG . Set ( m . vert . begin ( ) , m . vert . end ( ) ) ;
const float dist_upper_bound = m . bbox . Diag ( ) / 10.0 ;
typename std : : vector < CoordType > : : iterator pi ;
for ( pi = seedPVec . begin ( ) ; pi ! = seedPVec . end ( ) ; + + pi )
{
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ScalarType dist ;
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VertexPointer vp ;
vp = tri : : GetClosestVertex < MeshType , HashVertexGrid > ( m , HG , * pi , dist_upper_bound , dist ) ;
if ( vp )
{
seedVVec . push_back ( vp ) ;
}
}
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if ( compactFlag )
{
std : : sort ( seedVVec . begin ( ) , seedVVec . end ( ) ) ;
typename std : : vector < VertexType * > : : iterator vi = std : : unique ( seedVVec . begin ( ) , seedVVec . end ( ) ) ;
seedVVec . resize ( std : : distance ( seedVVec . begin ( ) , vi ) ) ;
}
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}
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static void ComputePerVertexSources ( MeshType & m , std : : vector < VertexType * > & seedVec , DistanceFunctor & df )
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{
tri : : Allocator < MeshType > : : DeletePerVertexAttribute ( m , " sources " ) ; // delete any conflicting handle regardless of the type...
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PerVertexPointerHandle vertexSources = tri : : Allocator < MeshType > : : template AddPerVertexAttribute < VertexPointer > ( m , " sources " ) ;
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tri : : Allocator < MeshType > : : DeletePerFaceAttribute ( m , " sources " ) ; // delete any conflicting handle regardless of the type...
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tri : : Allocator < MeshType > : : template AddPerFaceAttribute < VertexPointer > ( m , " sources " ) ;
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assert ( tri : : Allocator < MeshType > : : IsValidHandle ( m , vertexSources ) ) ;
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tri : : Geodesic < MeshType > : : Compute ( m , seedVec , df , std : : numeric_limits < ScalarType > : : max ( ) , 0 , & vertexSources ) ;
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}
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static void VoronoiColoring ( MeshType & m , bool frontierFlag = true )
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{
PerVertexPointerHandle sources = tri : : Allocator < MeshType > : : template GetPerVertexAttribute < VertexPointer > ( m , " sources " ) ;
assert ( tri : : Allocator < MeshType > : : IsValidHandle ( m , sources ) ) ;
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if ( frontierFlag )
{
//static_cast<VertexPointer>(NULL) has been introduced just to avoid an error in the MSVS2010's compiler confusing pointer with int. You could use nullptr to avoid it, but it's not supported by all compilers.
//The error should have been removed from MSVS2012
std : : pair < float , VertexPointer > zz ( 0.0f , static_cast < VertexPointer > ( NULL ) ) ;
std : : vector < std : : pair < float , VertexPointer > > regionArea ( m . vert . size ( ) , zz ) ;
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std : : vector < VertexPointer > frontierVec ;
GetAreaAndFrontier ( m , sources , regionArea , frontierVec ) ;
tri : : Geodesic < MeshType > : : Compute ( m , frontierVec ) ;
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}
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float minQ = std : : numeric_limits < float > : : max ( ) ;
float maxQ = - std : : numeric_limits < float > : : max ( ) ;
for ( VertexIterator vi = m . vert . begin ( ) ; vi ! = m . vert . end ( ) ; + + vi )
if ( sources [ * vi ] )
{
if ( ( * vi ) . Q ( ) < minQ ) minQ = ( * vi ) . Q ( ) ;
if ( ( * vi ) . Q ( ) > maxQ ) maxQ = ( * vi ) . Q ( ) ;
}
for ( VertexIterator vi = m . vert . begin ( ) ; vi ! = m . vert . end ( ) ; + + vi )
if ( sources [ * vi ] )
( * vi ) . C ( ) . SetColorRamp ( minQ , maxQ , ( * vi ) . Q ( ) ) ;
else
( * vi ) . C ( ) = Color4b : : DarkGray ;
// tri::UpdateColor<MeshType>::PerVertexQualityRamp(m);
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}
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static void VoronoiAreaColoring ( MeshType & m , std : : vector < VertexType * > & seedVec ,
std : : vector < std : : pair < float , VertexPointer > > & regionArea )
{
PerVertexPointerHandle vertexSources = tri : : Allocator < MeshType > : : template GetPerVertexAttribute < VertexPointer > ( m , " sources " ) ;
float meshArea = tri : : Stat < MeshType > : : ComputeMeshArea ( m ) ;
float expectedArea = meshArea / float ( seedVec . size ( ) ) ;
for ( size_t i = 0 ; i < m . vert . size ( ) ; + + i )
m . vert [ i ] . C ( ) = Color4b : : ColorRamp ( expectedArea * 0.75f , expectedArea * 1.25f , regionArea [ tri : : Index ( m , vertexSources [ i ] ) ] . first ) ;
}
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// It associates the faces with a given vertex according to the vertex associations
//
// It READS the PerVertex attribute 'sources'
// It WRITES the PerFace attribute 'sources'
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static void FaceAssociateRegion ( MeshType & m )
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{
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PerFacePointerHandle faceSources = tri : : Allocator < MeshType > : : template GetPerFaceAttribute < VertexPointer > ( m , " sources " ) ;
PerVertexPointerHandle vertexSources = tri : : Allocator < MeshType > : : template GetPerVertexAttribute < VertexPointer > ( m , " sources " ) ;
for ( FaceIterator fi = m . face . begin ( ) ; fi ! = m . face . end ( ) ; + + fi )
{
faceSources [ fi ] = 0 ;
std : : vector < VertexPointer > vp ( 3 ) ;
for ( int i = 0 ; i < 3 ; + + i ) vp [ i ] = vertexSources [ fi - > V ( i ) ] ;
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for ( int i = 0 ; i < 3 ; + + i ) // First try to associate to the most reached vertex
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{
if ( vp [ 0 ] = = vp [ 1 ] & & vp [ 0 ] = = vp [ 2 ] ) faceSources [ fi ] = vp [ 0 ] ;
else
{
if ( vp [ 0 ] = = vp [ 1 ] & & vp [ 0 ] - > Q ( ) < vp [ 2 ] - > Q ( ) ) faceSources [ fi ] = vp [ 0 ] ;
if ( vp [ 0 ] = = vp [ 2 ] & & vp [ 0 ] - > Q ( ) < vp [ 1 ] - > Q ( ) ) faceSources [ fi ] = vp [ 0 ] ;
if ( vp [ 1 ] = = vp [ 2 ] & & vp [ 1 ] - > Q ( ) < vp [ 0 ] - > Q ( ) ) faceSources [ fi ] = vp [ 1 ] ;
}
}
}
tri : : UpdateTopology < MeshType > : : FaceFace ( m ) ;
int unassCnt = 0 ;
do
{
unassCnt = 0 ;
for ( FaceIterator fi = m . face . begin ( ) ; fi ! = m . face . end ( ) ; + + fi )
{
if ( faceSources [ fi ] = = 0 )
{
std : : vector < VertexPointer > vp ( 3 ) ;
for ( int i = 0 ; i < 3 ; + + i )
vp [ i ] = faceSources [ fi - > FFp ( i ) ] ;
if ( vp [ 0 ] ! = 0 & & ( vp [ 0 ] = = vp [ 1 ] | | vp [ 0 ] = = vp [ 2 ] ) )
faceSources [ fi ] = vp [ 0 ] ;
else if ( vp [ 1 ] ! = 0 & & ( vp [ 1 ] = = vp [ 2 ] ) )
faceSources [ fi ] = vp [ 1 ] ;
else
faceSources [ fi ] = std : : max ( vp [ 0 ] , std : : max ( vp [ 1 ] , vp [ 2 ] ) ) ;
if ( faceSources [ fi ] = = 0 ) unassCnt + + ;
}
}
}
while ( unassCnt > 0 ) ;
}
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// Select all the faces with a given source vertex <vp>
// It reads the PerFace attribute 'sources'
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static int FaceSelectAssociateRegion ( MeshType & m , VertexPointer vp )
{
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PerFacePointerHandle sources = tri : : Allocator < MeshType > : : template FindPerFaceAttribute < VertexPointer > ( m , " sources " ) ;
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assert ( tri : : Allocator < MeshType > : : IsValidHandle ( m , sources ) ) ;
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tri : : UpdateSelection < MeshType > : : Clear ( m ) ;
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int selCnt = 0 ;
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for ( FaceIterator fi = m . face . begin ( ) ; fi ! = m . face . end ( ) ; + + fi )
{
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if ( sources [ fi ] = = vp )
{
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fi - > SetS ( ) ;
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+ + selCnt ;
}
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}
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return selCnt ;
}
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// Given a seed <vp>, it selects all the faces that have the minimal distance vertex sourced by the given <vp>.
// <vp> can be null (it search for unreached faces...)
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// returns the number of selected faces;
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//
// It reads the PerVertex attribute 'sources'
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static int FaceSelectRegion ( MeshType & m , VertexPointer vp )
{
PerVertexPointerHandle sources = tri : : Allocator < MeshType > : : template GetPerVertexAttribute < VertexPointer > ( m , " sources " ) ;
assert ( tri : : Allocator < MeshType > : : IsValidHandle ( m , sources ) ) ;
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tri : : UpdateSelection < MeshType > : : Clear ( m ) ;
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int selCnt = 0 ;
for ( FaceIterator fi = m . face . begin ( ) ; fi ! = m . face . end ( ) ; + + fi )
{
int minInd = 0 ; float minVal = std : : numeric_limits < float > : : max ( ) ;
for ( int i = 0 ; i < 3 ; + + i )
{
if ( ( * fi ) . V ( i ) - > Q ( ) < minVal )
{
minInd = i ;
minVal = ( * fi ) . V ( i ) - > Q ( ) ;
}
}
if ( sources [ ( * fi ) . V ( minInd ) ] = = vp )
{
fi - > SetS ( ) ;
selCnt + + ;
}
}
return selCnt ;
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}
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/// Given a mesh with for each vertex the link to the closest seed
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/// (e.g. for all vertexes we know what is the corresponding voronoi region)
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/// we compute:
/// area of all the voronoi regions
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/// the vector of the frontier vertexes (e.g. vert of faces shared by at least two regions)
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///
/// Area is computed only for triangles that fully belong to a given source.
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static void GetAreaAndFrontier ( MeshType & m , PerVertexPointerHandle & sources ,
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std : : vector < std : : pair < float , VertexPointer > > & regionArea , // for each seed we store area
std : : vector < VertexPointer > & frontierVec )
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{
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tri : : UpdateFlags < MeshType > : : VertexClearV ( m ) ;
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frontierVec . clear ( ) ;
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for ( FaceIterator fi = m . face . begin ( ) ; fi ! = m . face . end ( ) ; + + fi )
{
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VertexPointer s0 = sources [ ( * fi ) . V ( 0 ) ] ;
VertexPointer s1 = sources [ ( * fi ) . V ( 1 ) ] ;
VertexPointer s2 = sources [ ( * fi ) . V ( 2 ) ] ;
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assert ( s0 & & s1 & & s2 ) ;
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if ( ( s0 ! = s1 ) | | ( s0 ! = s2 ) )
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{
for ( int i = 0 ; i < 3 ; + + i )
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if ( ! fi - > V ( i ) - > IsV ( ) )
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{
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frontierVec . push_back ( fi - > V ( i ) ) ;
fi - > V ( i ) - > SetV ( ) ;
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}
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}
else // the face belongs to a single region; accumulate area;
{
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if ( s0 ! = 0 )
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{
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int seedIndex = tri : : Index ( m , s0 ) ;
regionArea [ seedIndex ] . first + = DoubleArea ( * fi ) * 0.5f ;
regionArea [ seedIndex ] . second = s0 ;
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}
}
}
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}
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/// Given a mesh with for each vertex the link to the closest seed
/// we compute:
/// the vector of the corner faces (ie the faces shared exactly by three regions)
/// the vector of the frontier faces that are on the boundary.
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static void GetFaceCornerVec ( MeshType & m , PerVertexPointerHandle & sources ,
std : : vector < FacePointer > & cornerVec ,
std : : vector < FacePointer > & borderCornerVec )
{
tri : : UpdateFlags < MeshType > : : VertexClearV ( m ) ;
cornerVec . clear ( ) ;
for ( FaceIterator fi = m . face . begin ( ) ; fi ! = m . face . end ( ) ; + + fi )
{
VertexPointer s0 = sources [ ( * fi ) . V ( 0 ) ] ;
VertexPointer s1 = sources [ ( * fi ) . V ( 1 ) ] ;
VertexPointer s2 = sources [ ( * fi ) . V ( 2 ) ] ;
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assert ( s0 & & s1 & & s2 ) ;
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if ( s1 ! = s2 & & s0 ! = s1 & & s0 ! = s2 ) {
cornerVec . push_back ( & * fi ) ;
}
else
{
if ( isBorderCorner ( & * fi , sources ) )
borderCornerVec . push_back ( & * fi ) ;
}
}
}
static bool isBorderCorner ( FaceType * f , typename MeshType : : template PerVertexAttributeHandle < VertexPointer > & sources )
{
for ( int i = 0 ; i < 3 ; + + i )
{
if ( sources [ ( * f ) . V0 ( i ) ] ! = sources [ ( * f ) . V1 ( i ) ] & & f - > IsB ( i ) )
return true ;
}
return false ;
}
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// Given two supposedly adjacent border corner faces it finds the source common to them;
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static VertexPointer CommonSourceBetweenBorderCorner ( FacePointer f0 , FacePointer f1 , typename MeshType : : template PerVertexAttributeHandle < VertexPointer > & sources )
{
assert ( isBorderCorner ( f0 , sources ) ) ;
assert ( isBorderCorner ( f1 , sources ) ) ;
int b0 = - 1 , b1 = - 1 ;
for ( int i = 0 ; i < 3 ; + + i )
{
if ( face : : IsBorder ( * f0 , i ) ) b0 = i ;
if ( face : : IsBorder ( * f1 , i ) ) b1 = i ;
}
assert ( b0 ! = - 1 & & b1 ! = - 1 ) ;
if ( ( sources [ f0 - > V0 ( b0 ) ] = = sources [ f1 - > V0 ( b1 ) ] ) | | ( sources [ f0 - > V0 ( b0 ) ] = = sources [ f1 - > V1 ( b1 ) ] ) )
return sources [ f0 - > V0 ( b0 ) ] ;
if ( ( sources [ f0 - > V1 ( b0 ) ] = = sources [ f1 - > V0 ( b1 ) ] ) | | ( sources [ f0 - > V1 ( b0 ) ] = = sources [ f1 - > V1 ( b1 ) ] ) )
return sources [ f0 - > V1 ( b0 ) ] ;
assert ( 0 ) ;
return 0 ;
}
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static void ConvertVoronoiDiagramToMesh ( MeshType & m ,
MeshType & outMesh , MeshType & outPoly ,
std : : vector < VertexType * > & seedVec ,
VoronoiProcessingParameter & vpp )
{
tri : : RequirePerVertexAttribute ( m , " sources " ) ;
PerVertexPointerHandle sources = tri : : Allocator < MeshType > : : template GetPerVertexAttribute < VertexPointer > ( m , " sources " ) ;
outMesh . Clear ( ) ;
outPoly . Clear ( ) ;
tri : : UpdateTopology < MeshType > : : FaceFace ( m ) ;
tri : : UpdateFlags < MeshType > : : FaceBorderFromFF ( m ) ;
std : : vector < FacePointer > innerCornerVec , // Faces adjacent to three different regions
borderCornerVec ; // Faces that are on the border and adjacent to at least two regions.
GetFaceCornerVec ( m , sources , innerCornerVec , borderCornerVec ) ;
// For each seed collect all the vertices and build
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for ( size_t i = 0 ; i < seedVec . size ( ) ; + + i )
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tri : : Allocator < MeshType > : : AddVertex ( outMesh , seedVec [ i ] - > P ( ) , Color4b : : DarkGray ) ;
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for ( size_t i = 0 ; i < seedVec . size ( ) ; + + i )
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{
VertexPointer curSeed = seedVec [ i ] ;
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vector < CoordType > pt ;
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for ( size_t j = 0 ; j < innerCornerVec . size ( ) ; + + j )
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for ( int qq = 0 ; qq < 3 ; qq + + )
if ( sources [ innerCornerVec [ j ] - > V ( qq ) ] = = curSeed )
{
pt . push_back ( Barycenter ( * innerCornerVec [ j ] ) ) ;
break ;
}
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for ( size_t j = 0 ; j < borderCornerVec . size ( ) ; + + j )
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for ( int qq = 0 ; qq < 3 ; qq + + )
if ( sources [ borderCornerVec [ j ] - > V ( qq ) ] = = curSeed )
{
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CoordType edgeCenter ;
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for ( int jj = 0 ; jj < 3 ; + + jj ) if ( face : : IsBorder ( * ( borderCornerVec [ j ] ) , jj ) )
edgeCenter = ( borderCornerVec [ j ] - > P0 ( jj ) + borderCornerVec [ j ] - > P1 ( jj ) ) / 2.0f ;
pt . push_back ( edgeCenter ) ;
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break ;
}
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Plane3 < ScalarType > pl ;
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pt . push_back ( curSeed - > P ( ) ) ;
FitPlaneToPointSet ( pt , pl ) ;
pt . pop_back ( ) ;
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CoordType nZ = pl . Direction ( ) ;
CoordType nX = ( pt [ 0 ] - curSeed - > P ( ) ) . Normalize ( ) ;
CoordType nY = ( nX ^ nZ ) . Normalize ( ) ;
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vector < std : : pair < float , int > > angleVec ( pt . size ( ) ) ;
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for ( size_t j = 0 ; j < pt . size ( ) ; + + j )
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{
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CoordType p = ( pt [ j ] - curSeed - > P ( ) ) . Normalize ( ) ;
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float angle = 180.0f + math : : ToDeg ( atan2 ( p * nY , p * nX ) ) ;
angleVec [ j ] = make_pair ( angle , j ) ;
}
std : : sort ( angleVec . begin ( ) , angleVec . end ( ) ) ;
// Now build another piece of mesh.
int curRegionStart = outMesh . vert . size ( ) ;
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for ( size_t j = 0 ; j < pt . size ( ) ; + + j )
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tri : : Allocator < MeshType > : : AddVertex ( outMesh , pt [ angleVec [ j ] . second ] , Color4b : : LightGray ) ;
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for ( size_t j = 0 ; j < pt . size ( ) ; + + j ) {
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float curAngle = angleVec [ ( j + 1 ) % pt . size ( ) ] . first - angleVec [ j ] . first ;
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// printf("seed %4i (%i) - face %i angle %5.1f %5.1f %5.1f\n",i,curRegionStart,j,angleVec[j].first,angleVec[(j+1)%pt.size()].first,curAngle);
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if ( curAngle < 0 ) curAngle + = 360.0 ;
if ( curAngle < 170.0 )
tri : : Allocator < MeshType > : : AddFace ( outMesh ,
& outMesh . vert [ i ] ,
& outMesh . vert [ curRegionStart + j ] ,
& outMesh . vert [ curRegionStart + ( ( j + 1 ) % pt . size ( ) ) ] ) ;
outMesh . face . back ( ) . SetF ( 0 ) ;
outMesh . face . back ( ) . SetF ( 2 ) ;
}
} // end for each seed.
tri : : Clean < MeshType > : : RemoveDuplicateVertex ( outMesh ) ;
tri : : UpdateTopology < MeshType > : : FaceFace ( outMesh ) ;
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bool oriented , orientable ;
tri : : Clean < MeshType > : : OrientCoherentlyMesh ( outMesh , oriented , orientable ) ;
tri : : UpdateTopology < MeshType > : : FaceFace ( outMesh ) ;
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// last loop to remove faux edges bit that are now on the boundary.
for ( FaceIterator fi = outMesh . face . begin ( ) ; fi ! = outMesh . face . end ( ) ; + + fi )
for ( int i = 0 ; i < 3 ; + + i )
if ( face : : IsBorder ( * fi , i ) & & fi - > IsF ( i ) ) fi - > ClearF ( i ) ;
std : : vector < typename tri : : UpdateTopology < MeshType > : : PEdge > EdgeVec ;
// ******************* star to tri conversion *********
// If requested the voronoi regions are converted from a star arragned polygon
// with vertex on the seed to a simple triangulated polygon by mean of a simple edge collapse
if ( vpp . triangulateRegion )
{
tri : : UpdateFlags < MeshType > : : FaceBorderFromFF ( outMesh ) ;
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tri : : UpdateFlags < MeshType > : : VertexBorderFromFaceBorder ( outMesh ) ;
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for ( FaceIterator fi = outMesh . face . begin ( ) ; fi ! = outMesh . face . end ( ) ; + + fi ) if ( ! fi - > IsD ( ) )
{
for ( int i = 0 ; i < 3 ; + + i )
{
bool b0 = fi - > V0 ( i ) - > IsB ( ) ;
bool b1 = fi - > V1 ( i ) - > IsB ( ) ;
if ( ( ( b0 & & b1 ) | | ( fi - > IsF ( i ) & & ! b0 ) ) & &
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tri : : Index ( outMesh , fi - > V0 ( i ) ) < seedVec . size ( ) )
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{
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if ( ! seedVec [ tri : : Index ( outMesh , fi - > V0 ( i ) ) ] - > IsS ( ) )
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if ( face : : FFLinkCondition ( * fi , i ) )
{
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face : : FFEdgeCollapse ( outMesh , * fi , i ) ; // we delete vertex fi->V0(i)
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break ;
}
}
}
}
}
// Now a plain conversion of the non faux edges into a polygonal mesh
tri : : UpdateTopology < MeshType > : : FillUniqueEdgeVector ( outMesh , EdgeVec , false ) ;
tri : : UpdateTopology < MeshType > : : AllocateEdge ( outMesh ) ;
for ( size_t i = 0 ; i < outMesh . vert . size ( ) ; + + i )
tri : : Allocator < MeshType > : : AddVertex ( outPoly , outMesh . vert [ i ] . P ( ) ) ;
for ( size_t i = 0 ; i < EdgeVec . size ( ) ; + + i )
{
size_t e0 = tri : : Index ( outMesh , EdgeVec [ i ] . v [ 0 ] ) ;
size_t e1 = tri : : Index ( outMesh , EdgeVec [ i ] . v [ 1 ] ) ;
assert ( e0 < outPoly . vert . size ( ) ) ;
tri : : Allocator < MeshType > : : AddEdge ( outPoly , & ( outPoly . vert [ e0 ] ) , & ( outPoly . vert [ e1 ] ) ) ;
}
}
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/// \brief Build a mesh of voronoi diagram from the given seeds
///
/// This function assumes that you have just run a geodesic like algorithm over your mesh using
/// a seed set as starting points and that there is an PerVertex Attribute called 'sources'
/// with pointers to the seed source. Usually you can initialize it with something like
///
/// DistanceFunctor &df,
/// tri::Geodesic<MeshType>::Compute(m, seedVec, df, std::numeric_limits<ScalarType>::max(),0,&sources);
///
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static void ConvertVoronoiDiagramToMeshOld ( MeshType & m ,
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MeshType & outMesh , MeshType & outPoly ,
std : : vector < VertexType * > & seedVec ,
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VoronoiProcessingParameter & vpp )
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{
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tri : : RequirePerVertexAttribute ( m , " sources " ) ;
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PerVertexPointerHandle sources = tri : : Allocator < MeshType > : : template GetPerVertexAttribute < VertexPointer > ( m , " sources " ) ;
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outMesh . Clear ( ) ;
outPoly . Clear ( ) ;
tri : : UpdateTopology < MeshType > : : FaceFace ( m ) ;
tri : : UpdateFlags < MeshType > : : FaceBorderFromFF ( m ) ;
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std : : map < VertexPointer , int > seedMap ; // It says if a given vertex of m is a seed (and what position it has in the seed vector)
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for ( size_t i = 0 ; i < m . vert . size ( ) ; + + i )
seedMap [ & ( m . vert [ i ] ) ] = - 1 ;
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for ( size_t i = 0 ; i < seedVec . size ( ) ; + + i )
seedMap [ seedVec [ i ] ] = i ;
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// Consistency Checks
for ( VertexIterator vi = m . vert . begin ( ) ; vi ! = m . vert . end ( ) ; + + vi )
{
assert ( sources [ vi ] ! = 0 ) ; // all vertices mush have a source must be seeds.
int ind = tri : : Index ( m , sources [ vi ] ) ;
assert ( ( ind > = 0 ) & & ( ind < m . vn ) ) ; // the source must be a vertex of the mesh
assert ( seedMap [ sources [ vi ] ] ! = - 1 ) ; // the source must be one of the seedVec
}
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std : : vector < FacePointer > innerCornerVec , // Faces adjacent to three different regions
borderCornerVec ; // Faces that are on the border and adjacent to at least two regions.
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GetFaceCornerVec ( m , sources , innerCornerVec , borderCornerVec ) ;
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std : : map < FacePointer , int > vertexIndCornerMap ; // Given a cornerFace (border or inner) what is the corresponding vertex?
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for ( size_t i = 0 ; i < m . face . size ( ) ; + + i )
vertexIndCornerMap [ & ( m . face [ i ] ) ] = - 1 ;
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// First add all the needed vertices: seeds and corners
for ( size_t i = 0 ; i < seedVec . size ( ) ; + + i )
tri : : Allocator < MeshType > : : AddVertex ( outMesh , seedVec [ i ] - > P ( ) , Color4b : : White ) ;
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for ( size_t i = 0 ; i < innerCornerVec . size ( ) ; + + i ) {
tri : : Allocator < MeshType > : : AddVertex ( outMesh , vcg : : Barycenter ( * ( innerCornerVec [ i ] ) ) , Color4b : : Gray ) ;
vertexIndCornerMap [ innerCornerVec [ i ] ] = outMesh . vn - 1 ;
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}
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for ( size_t i = 0 ; i < borderCornerVec . size ( ) ; + + i ) {
Point3f edgeCenter ;
for ( int j = 0 ; j < 3 ; + + j ) if ( face : : IsBorder ( * ( borderCornerVec [ i ] ) , j ) )
edgeCenter = ( borderCornerVec [ i ] - > P0 ( j ) + borderCornerVec [ i ] - > P1 ( j ) ) / 2.0f ;
tri : : Allocator < MeshType > : : AddVertex ( outMesh , edgeCenter , Color4b : : Gray ) ;
vertexIndCornerMap [ borderCornerVec [ i ] ] = outMesh . vn - 1 ;
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}
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tri : : Append < MeshType , MeshType > : : MeshCopy ( outPoly , outMesh ) ;
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// There is a voronoi edge if there are two corner face that share two sources.
// In such a case we add a pair of triangles with an edge connecting these two corner faces
// and with the two involved sources
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// For each pair of adjacent seed we store the first of the two corner that we encounter.
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std : : map < std : : pair < VertexPointer , VertexPointer > , FacePointer > VoronoiEdge ;
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// 1) Build internal triangles
// Loop build all the triangles connecting seeds with internal corners
// we loop over the all the voronoi corner (triangles with three different sources)
// we build
for ( size_t i = 0 ; i < innerCornerVec . size ( ) ; + + i )
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{
for ( int j = 0 ; j < 3 ; + + j )
{
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VertexPointer v0 = sources [ innerCornerVec [ i ] - > V0 ( j ) ] ;
VertexPointer v1 = sources [ innerCornerVec [ i ] - > V1 ( j ) ] ;
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assert ( seedMap [ v0 ] > = 0 ) ; assert ( seedMap [ v1 ] > = 0 ) ;
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if ( v1 < v0 ) std : : swap ( v0 , v1 ) ; assert ( v1 ! = v0 ) ;
if ( VoronoiEdge [ std : : make_pair ( v0 , v1 ) ] = = 0 )
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VoronoiEdge [ std : : make_pair ( v0 , v1 ) ] = innerCornerVec [ i ] ;
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else
{
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FacePointer otherCorner = VoronoiEdge [ std : : make_pair ( v0 , v1 ) ] ;
VertexPointer corner0 = & ( outMesh . vert [ vertexIndCornerMap [ innerCornerVec [ i ] ] ] ) ;
VertexPointer corner1 = & ( outMesh . vert [ vertexIndCornerMap [ otherCorner ] ] ) ;
tri : : Allocator < MeshType > : : AddFace ( outMesh , & ( outMesh . vert [ seedMap [ v0 ] ] ) , corner0 , corner1 ) ;
tri : : Allocator < MeshType > : : AddFace ( outMesh , & ( outMesh . vert [ seedMap [ v1 ] ] ) , corner1 , corner0 ) ;
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}
}
}
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// 2) build the boundary facets:
// We loop over border corners and build triangles with seed vertex
// we do **only** triangles with a bordercorner and a internal 'corner'
for ( size_t i = 0 ; i < borderCornerVec . size ( ) ; + + i )
{
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VertexPointer s0 = sources [ borderCornerVec [ i ] - > V ( 0 ) ] ; // All bordercorner faces have only two different regions
VertexPointer s1 = sources [ borderCornerVec [ i ] - > V ( 1 ) ] ;
if ( s1 = = s0 ) s1 = sources [ borderCornerVec [ i ] - > V ( 2 ) ] ;
if ( s1 < s0 ) std : : swap ( s0 , s1 ) ; assert ( s1 ! = s0 ) ;
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FacePointer innerCorner = VoronoiEdge [ std : : make_pair ( s0 , s1 ) ] ;
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if ( innerCorner )
{
VertexPointer corner0 = & ( outMesh . vert [ vertexIndCornerMap [ innerCorner ] ] ) ;
VertexPointer corner1 = & ( outMesh . vert [ vertexIndCornerMap [ borderCornerVec [ i ] ] ] ) ;
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tri : : Allocator < MeshType > : : AddFace ( outMesh , & ( outMesh . vert [ seedMap [ s0 ] ] ) , corner0 , corner1 ) ;
tri : : Allocator < MeshType > : : AddFace ( outMesh , & ( outMesh . vert [ seedMap [ s1 ] ] ) , corner0 , corner1 ) ;
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}
}
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// Final pass
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tri : : UpdateFlags < MeshType > : : FaceClearV ( m ) ;
bool AllFaceVisited = false ;
while ( ! AllFaceVisited )
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{
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// search for a unvisited boundary face
face : : Pos < FaceType > pos , startPos ;
AllFaceVisited = true ;
for ( size_t i = 0 ; ( AllFaceVisited ) & & ( i < borderCornerVec . size ( ) ) ; + + i )
if ( ! borderCornerVec [ i ] - > IsV ( ) )
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{
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for ( int j = 0 ; j < 3 ; + + j )
if ( face : : IsBorder ( * ( borderCornerVec [ i ] ) , j ) )
{
pos . Set ( borderCornerVec [ i ] , j , borderCornerVec [ i ] - > V ( j ) ) ;
AllFaceVisited = false ;
}
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}
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if ( AllFaceVisited ) break ;
assert ( pos . IsBorder ( ) ) ;
startPos = pos ;
bool foundBorderSeed = false ;
FacePointer curBorderCorner = pos . F ( ) ;
do
{
pos . F ( ) - > SetV ( ) ;
pos . NextB ( ) ;
if ( sources [ pos . V ( ) ] = = pos . V ( ) )
foundBorderSeed = true ;
assert ( isBorderCorner ( curBorderCorner , sources ) ) ;
if ( isBorderCorner ( pos . F ( ) , sources ) )
if ( pos . F ( ) ! = curBorderCorner )
{
VertexPointer curReg = CommonSourceBetweenBorderCorner ( curBorderCorner , pos . F ( ) , sources ) ;
VertexPointer curSeed = & ( outMesh . vert [ seedMap [ curReg ] ] ) ;
int otherCorner0 = vertexIndCornerMap [ pos . F ( ) ] ;
int otherCorner1 = vertexIndCornerMap [ curBorderCorner ] ;
VertexPointer corner0 = & ( outMesh . vert [ otherCorner0 ] ) ;
VertexPointer corner1 = & ( outMesh . vert [ otherCorner1 ] ) ;
if ( ! foundBorderSeed )
tri : : Allocator < MeshType > : : AddFace ( outMesh , curSeed , corner0 , corner1 ) ;
foundBorderSeed = false ;
curBorderCorner = pos . F ( ) ;
}
}
while ( pos ! = startPos ) ;
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}
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//**************** CLEANING ***************
// 1) reorient
bool oriented , orientable ;
tri : : UpdateTopology < MeshType > : : FaceFace ( outMesh ) ;
tri : : Clean < MeshType > : : OrientCoherentlyMesh ( outMesh , oriented , orientable ) ;
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// assert(orientable);
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// check that the normal of the input mesh are consistent with the result
tri : : UpdateNormal < MeshType > : : PerVertexNormalizedPerFaceNormalized ( outMesh ) ;
tri : : UpdateNormal < MeshType > : : PerVertexNormalizedPerFaceNormalized ( m ) ;
if ( seedVec [ 0 ] - > N ( ) * outMesh . vert [ 0 ] . N ( ) < 0 )
tri : : Clean < MeshType > : : FlipMesh ( outMesh ) ;
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tri : : UpdateTopology < MeshType > : : FaceFace ( outMesh ) ;
tri : : UpdateFlags < MeshType > : : FaceBorderFromFF ( outMesh ) ;
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// 2) Remove Flips
tri : : UpdateNormal < MeshType > : : PerFaceNormalized ( outMesh ) ;
tri : : UpdateFlags < MeshType > : : FaceClearV ( outMesh ) ;
for ( FaceIterator fi = outMesh . face . begin ( ) ; fi ! = outMesh . face . end ( ) ; + + fi )
{
int badDiedralCnt = 0 ;
for ( int i = 0 ; i < 3 ; + + i )
if ( fi - > N ( ) * fi - > FFp ( i ) - > N ( ) < 0 ) badDiedralCnt + + ;
if ( badDiedralCnt = = 2 ) fi - > SetV ( ) ;
}
for ( FaceIterator fi = outMesh . face . begin ( ) ; fi ! = outMesh . face . end ( ) ; + + fi )
if ( fi - > IsV ( ) ) Allocator < MeshType > : : DeleteFace ( outMesh , * fi ) ;
tri : : Allocator < MeshType > : : CompactEveryVector ( outMesh ) ;
tri : : UpdateTopology < MeshType > : : FaceFace ( outMesh ) ;
tri : : UpdateFlags < MeshType > : : FaceBorderFromFF ( outMesh ) ;
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tri : : UpdateFlags < MeshType > : : VertexBorderFromFaceBorder ( outMesh ) ;
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// 3) set up faux bits
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for ( FaceIterator fi = outMesh . face . begin ( ) ; fi ! = outMesh . face . end ( ) ; + + fi )
for ( int i = 0 ; i < 3 ; + + i )
{
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size_t v0 = tri : : Index ( outMesh , fi - > V0 ( i ) ) ;
size_t v1 = tri : : Index ( outMesh , fi - > V1 ( i ) ) ;
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if ( v0 < seedVec . size ( ) & & ! ( seedVec [ v0 ] - > IsB ( ) & & fi - > IsB ( i ) ) ) fi - > SetF ( i ) ;
if ( v1 < seedVec . size ( ) & & ! ( seedVec [ v1 ] - > IsB ( ) & & fi - > IsB ( i ) ) ) fi - > SetF ( i ) ;
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}
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if ( vpp . collapseShortEdge )
{
float distThr = m . bbox . Diag ( ) * vpp . collapseShortEdgePerc ;
for ( FaceIterator fi = outMesh . face . begin ( ) ; fi ! = outMesh . face . end ( ) ; + + fi ) if ( ! fi - > IsD ( ) )
{
for ( int i = 0 ; i < 3 ; + + i )
if ( ( Distance ( fi - > P0 ( i ) , fi - > P1 ( i ) ) < distThr ) & & ! fi - > IsF ( i ) )
{
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// printf("Collapsing face %i:%i e%i \n",tri::Index(outMesh,*fi),tri::Index(outMesh,fi->FFp(i)),i);
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if ( ( ! fi - > V ( i ) - > IsB ( ) ) & & ( face : : FFLinkCondition ( * fi , i ) ) )
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face : : FFEdgeCollapse ( outMesh , * fi , i ) ;
break ;
}
}
}
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//******************** END OF CLEANING ****************
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// ******************* star to tri conversion *********
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// If requested the voronoi regions are converted from a star arragned polygon
// with vertex on the seed to a simple triangulated polygon by mean of a simple edge collapse
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if ( vpp . triangulateRegion )
{
for ( FaceIterator fi = outMesh . face . begin ( ) ; fi ! = outMesh . face . end ( ) ; + + fi ) if ( ! fi - > IsD ( ) )
{
for ( int i = 0 ; i < 3 ; + + i )
{
bool b0 = fi - > V0 ( i ) - > IsB ( ) ;
bool b1 = fi - > V1 ( i ) - > IsB ( ) ;
if ( ( ( b0 & & b1 ) | | ( fi - > IsF ( i ) & & ! b0 & & ! b1 ) ) & &
tri : : Index ( outMesh , fi - > V ( i ) ) < seedVec . size ( ) )
{
if ( ! seedVec [ tri : : Index ( outMesh , fi - > V ( i ) ) ] - > IsS ( ) )
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if ( face : : FFLinkCondition ( * fi , i ) )
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{
face : : FFEdgeCollapse ( outMesh , * fi , i ) ;
break ;
}
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}
}
}
}
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// Now a plain conversion of the non faux edges into a polygonal mesh
std : : vector < typename tri : : UpdateTopology < MeshType > : : PEdge > EdgeVec ;
tri : : UpdateTopology < MeshType > : : FillUniqueEdgeVector ( outMesh , EdgeVec , false ) ;
tri : : UpdateTopology < MeshType > : : AllocateEdge ( outMesh ) ;
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for ( size_t i = 0 ; i < EdgeVec . size ( ) ; + + i )
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{
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size_t e0 = tri : : Index ( outMesh , EdgeVec [ i ] . v [ 0 ] ) ;
size_t e1 = tri : : Index ( outMesh , EdgeVec [ i ] . v [ 1 ] ) ;
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assert ( e0 < outPoly . vert . size ( ) ) ;
tri : : Allocator < MeshType > : : AddEdge ( outPoly , & ( outPoly . vert [ e0 ] ) , & ( outPoly . vert [ e1 ] ) ) ;
}
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}
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class VoronoiEdge
{
public :
VertexPointer r0 , r1 ;
FacePointer f0 , f1 ;
bool operator = = ( const VoronoiEdge & ve ) const { return ve . r0 = = r0 & & ve . r1 = = r1 ; }
bool operator < ( const VoronoiEdge & ve ) const { return ( ve . r0 = = r0 ) ? ve . r1 < r1 : ve . r0 < r0 ; }
float Len ( ) const { return Distance ( vcg : : Barycenter ( * f0 ) , vcg : : Barycenter ( * f1 ) ) ; }
} ;
static void BuildVoronoiEdgeVec ( MeshType & m , std : : vector < VoronoiEdge > & edgeVec )
{
PerVertexPointerHandle sources = tri : : Allocator < MeshType > : : template GetPerVertexAttribute < VertexPointer > ( m , " sources " ) ;
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edgeVec . clear ( ) ;
std : : vector < FacePointer > cornerVec ;
std : : vector < FacePointer > borderCornerVec ;
GetFaceCornerVec ( m , sources , cornerVec , borderCornerVec ) ;
// Now find all the voronoi edges: each edge (a *face pair) is identified by two voronoi regions
typedef std : : map < std : : pair < VertexPointer , VertexPointer > , std : : pair < FacePointer , FacePointer > > EdgeMapType ;
EdgeMapType EdgeMap ;
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printf ( " cornerVec.size() %i \n " , ( int ) cornerVec . size ( ) ) ;
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for ( size_t i = 0 ; i < cornerVec . size ( ) ; + + i )
{
for ( int j = 0 ; j < 3 ; + + j )
{
VertexPointer v0 = sources [ cornerVec [ i ] - > V0 ( j ) ] ;
VertexPointer v1 = sources [ cornerVec [ i ] - > V1 ( j ) ] ;
assert ( v0 ! = v1 ) ;
if ( v0 > v1 ) std : : swap ( v1 , v0 ) ;
std : : pair < VertexPointer , VertexPointer > adjRegion = std : : make_pair ( v0 , v1 ) ;
if ( EdgeMap [ adjRegion ] . first = = 0 )
EdgeMap [ adjRegion ] . first = cornerVec [ i ] ;
else
EdgeMap [ adjRegion ] . second = cornerVec [ i ] ;
}
}
for ( size_t i = 0 ; i < borderCornerVec . size ( ) ; + + i )
{
VertexPointer v0 = sources [ borderCornerVec [ i ] - > V ( 0 ) ] ;
VertexPointer v1 = sources [ borderCornerVec [ i ] - > V ( 1 ) ] ;
if ( v0 = = v1 ) v1 = sources [ borderCornerVec [ i ] - > V ( 2 ) ] ;
assert ( v0 ! = v1 ) ;
if ( v0 > v1 ) std : : swap ( v1 , v0 ) ;
std : : pair < VertexPointer , VertexPointer > adjRegion = std : : make_pair ( v0 , v1 ) ;
if ( EdgeMap [ adjRegion ] . first = = 0 )
EdgeMap [ adjRegion ] . first = borderCornerVec [ i ] ;
else
EdgeMap [ adjRegion ] . second = borderCornerVec [ i ] ;
}
typename EdgeMapType : : iterator mi ;
for ( mi = EdgeMap . begin ( ) ; mi ! = EdgeMap . end ( ) ; + + mi )
{
if ( ( * mi ) . second . first & & ( * mi ) . second . second )
{
assert ( ( * mi ) . first . first & & ( * mi ) . first . second ) ;
edgeVec . push_back ( VoronoiEdge ( ) ) ;
edgeVec . back ( ) . r0 = ( * mi ) . first . first ;
edgeVec . back ( ) . r1 = ( * mi ) . first . second ;
edgeVec . back ( ) . f0 = ( * mi ) . second . first ;
edgeVec . back ( ) . f1 = ( * mi ) . second . second ;
}
}
}
static void BuildBiasedSeedVec ( MeshType & m ,
DistanceFunctor & df ,
std : : vector < VertexPointer > & seedVec ,
std : : vector < VertexPointer > & frontierVec ,
std : : vector < VertDist > & biasedFrontierVec ,
VoronoiProcessingParameter & vpp )
{
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( void ) df ;
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biasedFrontierVec . clear ( ) ;
if ( vpp . unbiasedSeedFlag )
{
for ( size_t i = 0 ; i < frontierVec . size ( ) ; + + i )
biasedFrontierVec . push_back ( VertDist ( frontierVec [ i ] , 0 ) ) ;
assert ( biasedFrontierVec . size ( ) = = frontierVec . size ( ) ) ;
return ;
}
std : : vector < VoronoiEdge > edgeVec ;
BuildVoronoiEdgeVec ( m , edgeVec ) ;
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printf ( " Found %i edges on a diagram of %i seeds \n " , int ( edgeVec . size ( ) ) , int ( seedVec . size ( ) ) ) ;
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std : : map < VertexPointer , std : : vector < VoronoiEdge * > > SeedToEdgeVecMap ;
std : : map < std : : pair < VertexPointer , VertexPointer > , VoronoiEdge * > SeedPairToEdgeMap ;
float totalLen = 0 ;
for ( size_t i = 0 ; i < edgeVec . size ( ) ; + + i )
{
SeedToEdgeVecMap [ edgeVec [ i ] . r0 ] . push_back ( & ( edgeVec [ i ] ) ) ;
SeedToEdgeVecMap [ edgeVec [ i ] . r1 ] . push_back ( & ( edgeVec [ i ] ) ) ;
SeedPairToEdgeMap [ std : : make_pair ( edgeVec [ i ] . r0 , edgeVec [ i ] . r1 ) ] = & ( edgeVec [ i ] ) ;
assert ( edgeVec [ i ] . r0 < edgeVec [ i ] . r1 ) ;
totalLen + = edgeVec [ i ] . Len ( ) ;
}
// compute the perimeter of each region
std : : map < VertexPointer , float > regionPerymeter ;
for ( size_t i = 0 ; i < seedVec . size ( ) ; + + i )
{
for ( size_t j = 0 ; j < SeedToEdgeVecMap [ seedVec [ i ] ] . size ( ) ; + + j )
{
VoronoiEdge * vep = SeedToEdgeVecMap [ seedVec [ i ] ] [ j ] ;
regionPerymeter [ seedVec [ i ] ] + = vep - > Len ( ) ;
}
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printf ( " perimeter of region %i is %f \n " , ( int ) i , regionPerymeter [ seedVec [ i ] ] ) ;
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}
PerVertexPointerHandle sources = tri : : Allocator < MeshType > : : template GetPerVertexAttribute < VertexPointer > ( m , " sources " ) ;
// The real bias for each edge is (perim)/(edge)
// each source can belong to two edges max. so the weight is
std : : map < VertexPointer , float > weight ;
std : : map < VertexPointer , int > cnt ;
float biasSum = totalLen / 5.0f ;
for ( FaceIterator fi = m . face . begin ( ) ; fi ! = m . face . end ( ) ; + + fi )
{
for ( int i = 0 ; i < 3 ; + + i )
{
VertexPointer s0 = sources [ ( * fi ) . V0 ( i ) ] ;
VertexPointer s1 = sources [ ( * fi ) . V1 ( i ) ] ;
if ( s0 ! = s1 )
{
if ( s0 > s1 ) std : : swap ( s0 , s1 ) ;
VoronoiEdge * ve = SeedPairToEdgeMap [ std : : make_pair ( s0 , s1 ) ] ;
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if ( ! ve ) printf ( " v %i %i \n " , ( int ) tri : : Index ( m , s0 ) , ( int ) tri : : Index ( m , s1 ) ) ;
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assert ( ve ) ;
float el = ve - > Len ( ) ;
weight [ ( * fi ) . V0 ( i ) ] + = ( regionPerymeter [ s0 ] + biasSum ) / ( el + biasSum ) ;
weight [ ( * fi ) . V1 ( i ) ] + = ( regionPerymeter [ s1 ] + biasSum ) / ( el + biasSum ) ;
cnt [ ( * fi ) . V0 ( i ) ] + + ;
cnt [ ( * fi ) . V1 ( i ) ] + + ;
}
}
}
for ( VertexIterator vi = m . vert . begin ( ) ; vi ! = m . vert . end ( ) ; + + vi )
{
if ( cnt [ & * vi ] > 0 )
{
// float bias = weight[&*vi]/float(cnt[&*vi]);
float bias = weight [ & * vi ] / float ( cnt [ & * vi ] ) + totalLen ;
biasedFrontierVec . push_back ( VertDist ( & * vi , bias ) ) ;
}
}
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printf ( " Collected %i frontier vertexes \n " , ( int ) biasedFrontierVec . size ( ) ) ;
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}
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static void DeleteUnreachedRegions ( MeshType & m , PerVertexPointerHandle & sources )
{
tri : : UpdateFlags < MeshType > : : VertexClearV ( m ) ;
for ( size_t i = 0 ; i < m . vert . size ( ) ; + + i )
if ( sources [ i ] = = 0 ) m . vert [ i ] . SetV ( ) ;
for ( FaceIterator fi = m . face . begin ( ) ; fi ! = m . face . end ( ) ; + + fi )
if ( fi - > V ( 0 ) - > IsV ( ) | | fi - > V ( 1 ) - > IsV ( ) | | fi - > V ( 2 ) - > IsV ( ) )
{
face : : VFDetach ( * fi ) ;
tri : : Allocator < MeshType > : : DeleteFace ( m , * fi ) ;
}
// qDebug("Deleted faces not reached: %i -> %i",int(m.face.size()),m.fn);
tri : : Clean < MeshType > : : RemoveUnreferencedVertex ( m ) ;
tri : : Allocator < MeshType > : : CompactEveryVector ( m ) ;
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}
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/// Let f_p(q) be the squared distance of q from p
/// f_p(q) = (p_x-q_x)^2 + (p_y-q_y)^2 + (p_z-q_z)^2
/// f_p(q) = p_x^2 -2p_xq_x +q_x^2 + ... + p_z^2 -2p_zq_z +q_z^2
///
struct QuadricSumDistance
{
ScalarType a ;
ScalarType c ;
CoordType b ;
QuadricSumDistance ( ) { a = 0 ; c = 0 ; b [ 0 ] = 0 ; b [ 1 ] = 0 ; b [ 2 ] = 0 ; }
void AddPoint ( CoordType p )
{
a + = 1 ;
assert ( c > = 0 ) ;
c + = p * p ;
b [ 0 ] + = - 2.0f * p [ 0 ] ;
b [ 1 ] + = - 2.0f * p [ 1 ] ;
b [ 2 ] + = - 2.0f * p [ 2 ] ;
}
ScalarType Eval ( CoordType p ) const
{
ScalarType d = a * ( p * p ) + b * p + c ;
assert ( d > = 0 ) ;
return d ;
}
CoordType Min ( ) const
{
return b * - 0.5f ;
}
} ;
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/// \brief Relax the seeds of a Voronoi diagram according to the quadric distance rule.
///
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/// For each region it search the vertex that minimize the sum of the squared distance
/// from all the points of the region.
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///
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/// It uses a vector of QuadricSumDistances;
/// for simplicity it is sized as the vertex vector even if only the ones of the quadric
/// corresponding to seeds are actually used.
///
/// It return true if at least one seed changed position.
///
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static bool QuadricRelax ( MeshType & m , std : : vector < VertexType * > & seedVec ,
std : : vector < VertexPointer > & frontierVec ,
std : : vector < VertexType * > & newSeeds ,
DistanceFunctor & df ,
VoronoiProcessingParameter & vpp )
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{
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( void ) seedVec ;
( void ) frontierVec ;
( void ) df ;
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newSeeds . clear ( ) ;
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PerVertexPointerHandle sources = tri : : Allocator < MeshType > : : template GetPerVertexAttribute < VertexPointer > ( m , " sources " ) ;
PerVertexBoolHandle fixed = tri : : Allocator < MeshType > : : template GetPerVertexAttribute < bool > ( m , " fixed " ) ;
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QuadricSumDistance dz ;
std : : vector < QuadricSumDistance > dVec ( m . vert . size ( ) , dz ) ;
for ( VertexIterator vi = m . vert . begin ( ) ; vi ! = m . vert . end ( ) ; + + vi )
{
assert ( sources [ vi ] ! = 0 ) ;
int seedIndex = tri : : Index ( m , sources [ vi ] ) ;
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// When constraining seeds movement we move selected seeds only onto other selected vertices
if ( vpp . constrainSelectedSeed )
{ // So we sum only the contribs of the selected vertices
if ( ( sources [ vi ] - > IsS ( ) & & vi - > IsS ( ) ) | | ( ! sources [ vi ] - > IsS ( ) ) )
dVec [ seedIndex ] . AddPoint ( vi - > P ( ) ) ;
}
else
dVec [ seedIndex ] . AddPoint ( vi - > P ( ) ) ;
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}
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// Search the local maxima for each region and use them as new seeds
std : : pair < float , VertexPointer > zz ( std : : numeric_limits < ScalarType > : : max ( ) , static_cast < VertexPointer > ( 0 ) ) ;
std : : vector < std : : pair < float , VertexPointer > > seedMaximaVec ( m . vert . size ( ) , zz ) ;
for ( VertexIterator vi = m . vert . begin ( ) ; vi ! = m . vert . end ( ) ; + + vi )
{
assert ( sources [ vi ] ! = 0 ) ;
int seedIndex = tri : : Index ( m , sources [ vi ] ) ;
ScalarType val = dVec [ seedIndex ] . Eval ( vi - > P ( ) ) ;
vi - > Q ( ) = val ;
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// if constrainSelectedSeed we search only among selected vertices
if ( ! vpp . constrainSelectedSeed | | ! sources [ vi ] - > IsS ( ) | | vi - > IsS ( ) )
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{
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if ( seedMaximaVec [ seedIndex ] . first > val )
{
seedMaximaVec [ seedIndex ] . first = val ;
seedMaximaVec [ seedIndex ] . second = & * vi ;
}
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}
}
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if ( vpp . colorStrategy = = VoronoiProcessingParameter : : DistanceFromBorder )
tri : : UpdateColor < MeshType > : : PerVertexQualityRamp ( m ) ;
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// tri::io::ExporterPLY<MeshType>::Save(m,"last.ply",tri::io::Mask::IOM_VERTCOLOR + tri::io::Mask::IOM_VERTQUALITY );
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bool seedChanged = false ;
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// update the seedvector with the new maxima (For the vertex not fixed)
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for ( size_t i = 0 ; i < m . vert . size ( ) ; + + i )
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if ( seedMaximaVec [ i ] . second ) // Most of the seedMaximaVec is unused: only the updated entries have a non zero pointer
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{
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VertexPointer curSrc = sources [ seedMaximaVec [ i ] . second ] ;
if ( vpp . preserveFixedSeed & & fixed [ curSrc ] )
newSeeds . push_back ( curSrc ) ;
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else
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{
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newSeeds . push_back ( seedMaximaVec [ i ] . second ) ;
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if ( curSrc ! = seedMaximaVec [ i ] . second )
seedChanged = true ;
}
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}
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return seedChanged ;
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}
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/// \brief Relax the Seeds of a Voronoi diagram according to the geodesic rule.
///
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/// For each region, given the frontiers, it chooses the point with the highest distance from the frontier
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/// This strategy automatically moves the vertices onto the boundary (if any).
///
/// It return true if at least one seed changed position.
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///
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static bool GeodesicRelax ( MeshType & m , std : : vector < VertexType * > & seedVec , std : : vector < VertexPointer > & frontierVec ,
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std : : vector < VertexType * > & newSeeds ,
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DistanceFunctor & df , VoronoiProcessingParameter & vpp )
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{
newSeeds . clear ( ) ;
typename MeshType : : template PerVertexAttributeHandle < VertexPointer > sources ;
sources = tri : : Allocator < MeshType > : : template GetPerVertexAttribute < VertexPointer > ( m , " sources " ) ;
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typename MeshType : : template PerVertexAttributeHandle < bool > fixed ;
fixed = tri : : Allocator < MeshType > : : template GetPerVertexAttribute < bool > ( m , " fixed " ) ;
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std : : vector < typename tri : : Geodesic < MeshType > : : VertDist > biasedFrontierVec ;
BuildBiasedSeedVec ( m , df , seedVec , frontierVec , biasedFrontierVec , vpp ) ;
tri : : Geodesic < MeshType > : : Visit ( m , biasedFrontierVec , df ) ;
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if ( vpp . colorStrategy = = VoronoiProcessingParameter : : DistanceFromSeed )
tri : : UpdateColor < MeshType > : : PerVertexQualityRamp ( m ) ;
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// tri::io::ExporterPLY<MeshType>::Save(m,"last.ply",tri::io::Mask::IOM_VERTCOLOR + tri::io::Mask::IOM_VERTQUALITY );
if ( vpp . colorStrategy = = VoronoiProcessingParameter : : DistanceFromBorder )
tri : : UpdateColor < MeshType > : : PerVertexQualityRamp ( m ) ;
// Search the local maxima for each region and use them as new seeds
std : : pair < float , VertexPointer > zz ( 0.0f , static_cast < VertexPointer > ( NULL ) ) ;
std : : vector < std : : pair < float , VertexPointer > > seedMaximaVec ( m . vert . size ( ) , zz ) ;
for ( VertexIterator vi = m . vert . begin ( ) ; vi ! = m . vert . end ( ) ; + + vi )
{
assert ( sources [ vi ] ! = 0 ) ;
int seedIndex = tri : : Index ( m , sources [ vi ] ) ;
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if ( ! vpp . constrainSelectedSeed | | ! sources [ vi ] - > IsS ( ) | | vi - > IsS ( ) )
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{
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if ( seedMaximaVec [ seedIndex ] . first < ( * vi ) . Q ( ) )
{
seedMaximaVec [ seedIndex ] . first = ( * vi ) . Q ( ) ;
seedMaximaVec [ seedIndex ] . second = & * vi ;
}
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}
}
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bool seedChanged = false ;
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// update the seedvector with the new maxima (For the vertex not selected)
for ( size_t i = 0 ; i < seedMaximaVec . size ( ) ; + + i )
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if ( seedMaximaVec [ i ] . second ) // only updated entries have a non zero pointer
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{
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VertexPointer curSrc = sources [ seedMaximaVec [ i ] . second ] ;
if ( vpp . preserveFixedSeed & & fixed [ curSrc ] )
newSeeds . push_back ( curSrc ) ;
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else
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{
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newSeeds . push_back ( seedMaximaVec [ i ] . second ) ;
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if ( curSrc ! = seedMaximaVec [ i ] . second ) seedChanged = true ;
}
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}
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return seedChanged ;
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}
static void PruneSeedByRegionArea ( std : : vector < VertexType * > & seedVec ,
std : : vector < std : : pair < float , VertexPointer > > & regionArea ,
VoronoiProcessingParameter & vpp )
{
// Smaller area region are discarded
Distribution < float > H ;
for ( size_t i = 0 ; i < regionArea . size ( ) ; + + i )
if ( regionArea [ i ] . second ) H . Add ( regionArea [ i ] . first ) ;
float areaThreshold = 0 ;
if ( vpp . areaThresholdPerc ! = 0 ) areaThreshold = H . Percentile ( vpp . areaThresholdPerc ) ;
std : : vector < VertexType * > newSeedVec ;
// update the seedvector with the new maxima (For the vertex not selected)
for ( size_t i = 0 ; i < seedVec . size ( ) ; + + i )
{
if ( regionArea [ i ] . first > = areaThreshold )
newSeedVec . push_back ( seedVec [ i ] ) ;
}
swap ( seedVec , newSeedVec ) ;
}
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/// \brief Mark a vector of seeds to be fixed.
///
/// Vertex pointers must belong to the mesh.
/// The framework use a boolean attribute called "fixed" to store this info.
///
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static void FixVertexVector ( MeshType & m , std : : vector < VertexType * > & vertToFixVec )
{
typename MeshType : : template PerVertexAttributeHandle < bool > fixed ;
fixed = tri : : Allocator < MeshType > : : template GetPerVertexAttribute < bool > ( m , " fixed " ) ;
for ( VertexIterator vi = m . vert . begin ( ) ; vi ! = m . vert . end ( ) ; + + vi )
fixed [ vi ] = false ;
for ( size_t i = 0 ; i < vertToFixVec . size ( ) ; + + i )
fixed [ vertToFixVec [ i ] ] = true ;
}
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static int RestrictedVoronoiRelaxing ( MeshType & m , std : : vector < CoordType > & seedPosVec ,
std : : vector < bool > & fixedVec ,
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int relaxStep ,
VoronoiProcessingParameter & vpp ,
vcg : : CallBackPos * cb = 0 )
{
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PerVertexFloatHandle area = tri : : Allocator < MeshType > : : template GetPerVertexAttribute < float > ( m , " area " ) ;
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for ( VertexIterator vi = m . vert . begin ( ) ; vi ! = m . vert . end ( ) ; + + vi )
area [ vi ] = 0 ;
for ( FaceIterator fi = m . face . begin ( ) ; fi ! = m . face . end ( ) ; + + fi )
{
ScalarType a3 = DoubleArea ( * fi ) / 6.0 ;
for ( int i = 0 ; i < 3 ; + + i )
area [ fi - > V ( i ) ] + = a3 ;
}
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assert ( m . vn > ( int ) seedPosVec . size ( ) * 20 ) ;
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int i ;
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ScalarType perturb = m . bbox . Diag ( ) * vpp . seedPerturbationAmount ;
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for ( i = 0 ; i < relaxStep ; + + i )
{
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if ( cb ) cb ( i * 100 / relaxStep , " RestrictedVoronoiRelaxing " ) ;
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// Kdtree for the seeds must be rebuilt at each step;
VectorConstDataWrapper < std : : vector < CoordType > > vdw ( seedPosVec ) ;
KdTree < ScalarType > seedTree ( vdw ) ;
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std : : vector < std : : pair < ScalarType , CoordType > > sumVec ( seedPosVec . size ( ) , std : : make_pair ( 0 , CoordType ( 0 , 0 , 0 ) ) ) ;
for ( VertexIterator vi = m . vert . begin ( ) ; vi ! = m . vert . end ( ) ; + + vi )
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{
unsigned int seedInd ;
ScalarType sqdist ;
seedTree . doQueryClosest ( vi - > P ( ) , seedInd , sqdist ) ;
vi - > Q ( ) = sqrt ( sqdist ) ;
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sumVec [ seedInd ] . first + = area [ vi ] ;
sumVec [ seedInd ] . second + = vi - > cP ( ) * area [ vi ] ;
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}
vector < CoordType > newseedVec ;
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vector < bool > newfixedVec ;
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for ( size_t i = 0 ; i < seedPosVec . size ( ) ; + + i )
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{
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if ( fixedVec [ i ] )
{
newseedVec . push_back ( seedPosVec [ i ] ) ;
newfixedVec . push_back ( true ) ;
}
else
{
if ( sumVec [ i ] . first ! = 0 )
{
newseedVec . push_back ( sumVec [ i ] . second / ScalarType ( sumVec [ i ] . first ) ) ;
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if ( vpp . seedPerturbationProbability > RandomGenerator ( ) . generate01 ( ) )
newseedVec . back ( ) + = math : : GeneratePointInUnitBallUniform < ScalarType , math : : MarsenneTwisterRNG > ( RandomGenerator ( ) ) * perturb ;
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newfixedVec . push_back ( false ) ;
}
}
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}
std : : swap ( seedPosVec , newseedVec ) ;
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std : : swap ( fixedVec , newfixedVec ) ;
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tri : : UpdateColor < MeshType > : : PerVertexQualityRamp ( m ) ;
}
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return relaxStep ;
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}
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/// \brief Perform a Lloyd relaxation cycle over a mesh
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/// It uses two conventions:
/// 1) a few vertexes can remain fixed, you have to set a per vertex bool attribute named 'fixed'
/// 2)
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///
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static int VoronoiRelaxing ( MeshType & m , std : : vector < VertexType * > & seedVec ,
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int relaxIter , DistanceFunctor & df ,
VoronoiProcessingParameter & vpp ,
vcg : : CallBackPos * cb = 0 )
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{
tri : : RequireVFAdjacency ( m ) ;
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tri : : RequireCompactness ( m ) ;
for ( VertexIterator vi = m . vert . begin ( ) ; vi ! = m . vert . end ( ) ; + + vi )
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assert ( vi - > VFp ( ) & & " Require mesh without unreferenced vertexes \n " ) ;
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std : : vector < VertexType * > selectedVec ;
if ( vpp . relaxOnlyConstrainedFlag )
{
for ( size_t i = 0 ; i < seedVec . size ( ) ; + + i )
if ( seedVec [ i ] - > IsS ( ) )
selectedVec . push_back ( seedVec [ i ] ) ;
std : : swap ( seedVec , selectedVec ) ;
}
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tri : : UpdateFlags < MeshType > : : FaceBorderFromVF ( m ) ;
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tri : : UpdateFlags < MeshType > : : VertexBorderFromFaceBorder ( m ) ;
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PerVertexPointerHandle sources = tri : : Allocator < MeshType > : : template GetPerVertexAttribute < VertexPointer > ( m , " sources " ) ;
PerVertexBoolHandle fixed = tri : : Allocator < MeshType > : : template GetPerVertexAttribute < bool > ( m , " fixed " ) ;
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int iter ;
for ( iter = 0 ; iter < relaxIter ; + + iter )
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{
if ( cb ) cb ( iter * 100 / relaxIter , " Voronoi Lloyd Relaxation: First Partitioning " ) ;
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// first run: find for each point what is the closest to one of the seeds.
tri : : Geodesic < MeshType > : : Compute ( m , seedVec , df , std : : numeric_limits < ScalarType > : : max ( ) , 0 , & sources ) ;
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if ( vpp . colorStrategy = = VoronoiProcessingParameter : : DistanceFromSeed )
tri : : UpdateColor < MeshType > : : PerVertexQualityRamp ( m ) ;
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// Delete all the (hopefully) small regions that have not been reached by the seeds;
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if ( vpp . deleteUnreachedRegionFlag ) DeleteUnreachedRegions ( m , sources ) ;
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std : : pair < float , VertexPointer > zz ( 0.0f , static_cast < VertexPointer > ( NULL ) ) ;
std : : vector < std : : pair < float , VertexPointer > > regionArea ( m . vert . size ( ) , zz ) ;
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std : : vector < VertexPointer > frontierVec ;
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GetAreaAndFrontier ( m , sources , regionArea , frontierVec ) ;
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assert ( frontierVec . size ( ) > 0 ) ;
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if ( vpp . colorStrategy = = VoronoiProcessingParameter : : RegionArea ) VoronoiAreaColoring ( m , seedVec , regionArea ) ;
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// qDebug("We have found %i regions range (%f %f), avg area is %f, Variance is %f 10perc is %f",(int)seedVec.size(),H.Min(),H.Max(),H.Avg(),H.StandardDeviation(),areaThreshold);
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if ( cb ) cb ( iter * 100 / relaxIter , " Voronoi Lloyd Relaxation: Searching New Seeds " ) ;
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std : : vector < VertexPointer > newSeedVec ;
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bool changed ;
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if ( vpp . geodesicRelaxFlag )
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changed = GeodesicRelax ( m , seedVec , frontierVec , newSeedVec , df , vpp ) ;
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else
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changed = QuadricRelax ( m , seedVec , frontierVec , newSeedVec , df , vpp ) ;
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//assert(newSeedVec.size() == seedVec.size());
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PruneSeedByRegionArea ( newSeedVec , regionArea , vpp ) ;
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for ( size_t i = 0 ; i < frontierVec . size ( ) ; + + i )
frontierVec [ i ] - > C ( ) = Color4b : : Gray ;
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for ( size_t i = 0 ; i < seedVec . size ( ) ; + + i )
seedVec [ i ] - > C ( ) = Color4b : : Black ;
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for ( size_t i = 0 ; i < newSeedVec . size ( ) ; + + i )
newSeedVec [ i ] - > C ( ) = Color4b : : White ;
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swap ( newSeedVec , seedVec ) ;
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if ( ! changed ) break ;
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}
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// Last run: Needed if we have changed the seed set to leave the sources handle correct.
if ( iter = = relaxIter )
tri : : Geodesic < MeshType > : : Compute ( m , seedVec , df , std : : numeric_limits < ScalarType > : : max ( ) , 0 , & sources ) ;
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if ( vpp . relaxOnlyConstrainedFlag )
{
std : : swap ( seedVec , selectedVec ) ;
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size_t i , j ;
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for ( i = 0 , j = 0 ; i < seedVec . size ( ) ; + + i ) {
if ( seedVec [ i ] - > IsS ( ) )
{
seedVec [ i ] = selectedVec [ j ] ;
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fixed [ seedVec [ i ] ] = true ;
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+ + j ;
}
}
}
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return iter ;
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}
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// Base vertex voronoi coloring algorithm.
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// It assumes VF adjacency.
// No attempt of computing real geodesic distnace is done. Just a BFS visit starting from the seeds
// It leaves in each vertex quality the index of the seed.
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static void TopologicalVertexColoring ( MeshType & m , std : : vector < VertexType * > & seedVec )
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{
std : : queue < VertexPointer > VQ ;
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tri : : UpdateQuality < MeshType > : : VertexConstant ( m , 0 ) ;
for ( size_t i = 0 ; i < seedVec . size ( ) ; + + i )
{
VQ . push ( seedVec [ i ] ) ;
seedVec [ i ] - > Q ( ) = i + 1 ;
}
while ( ! VQ . empty ( ) )
{
VertexPointer vp = VQ . front ( ) ;
VQ . pop ( ) ;
std : : vector < VertexPointer > vertStar ;
vcg : : face : : VVStarVF < FaceType > ( vp , vertStar ) ;
for ( typename std : : vector < VertexPointer > : : iterator vv = vertStar . begin ( ) ; vv ! = vertStar . end ( ) ; + + vv )
{
if ( ( * vv ) - > Q ( ) = = 0 )
{
( * vv ) - > Q ( ) = vp - > Q ( ) ;
VQ . push ( * vv ) ;
}
}
} // end while(!VQ.empty())
}
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template < class genericType >
static std : : pair < genericType , genericType > ordered_pair ( const genericType & a , const genericType & b )
{
if ( a < b ) return std : : make_pair ( a , b ) ;
return std : : make_pair ( b , a ) ;
}
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/// For each edge of the delaunay triangulation it search a 'good' middle point:
/// E.g the point that belongs on the corresponding edge of the voronoi diagram (e.g. on a frontier face)
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/// and that has minimal distance from the two seeds.
///
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/// Note: if the edge connects two "constrained" vertices (e.g. selected) we must search only among the constrained.
///
///
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static void GenerateMidPointMap ( MeshType & m ,
map < std : : pair < VertexPointer , VertexPointer > , VertexPointer > & midMap )
{
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PerVertexPointerHandle sources = tri : : Allocator < MeshType > : : template GetPerVertexAttribute < VertexPointer > ( m , " sources " ) ;
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for ( FaceIterator fi = m . face . begin ( ) ; fi ! = m . face . end ( ) ; + + fi )
{
VertexPointer vp [ 3 ] , sp [ 3 ] ;
vp [ 0 ] = ( * fi ) . V ( 0 ) ; vp [ 1 ] = ( * fi ) . V ( 1 ) ; vp [ 2 ] = ( * fi ) . V ( 2 ) ;
sp [ 0 ] = sources [ vp [ 0 ] ] ; sp [ 1 ] = sources [ vp [ 1 ] ] ; sp [ 2 ] = sources [ vp [ 2 ] ] ;
if ( ( sp [ 0 ] = = sp [ 1 ] ) & & ( sp [ 0 ] = = sp [ 2 ] ) ) continue ; // skip internal faces
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// if((sp[0] != sp[1]) && (sp[0] != sp[2]) && (sp[1] != sp[2])) continue; // skip corner faces
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for ( int i = 0 ; i < 3 ; + + i ) // for each edge of a frontier face
{
int i0 = i ;
int i1 = ( i + 1 ) % 3 ;
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// if((sp[i0]->IsS() && sp[i1]->IsS()) && !( vp[i0]->IsS() || vp[i1]->IsS() ) ) continue;
VertexPointer closestVert = vp [ i0 ] ;
if ( vp [ i1 ] - > Q ( ) < closestVert - > Q ( ) ) closestVert = vp [ i1 ] ;
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if ( sp [ i0 ] - > IsS ( ) & & sp [ i1 ] - > IsS ( ) )
{
if ( ( vp [ i0 ] - > IsS ( ) ) & & ! ( vp [ i1 ] - > IsS ( ) ) ) closestVert = vp [ i0 ] ;
if ( ! ( vp [ i0 ] - > IsS ( ) ) & & ( vp [ i1 ] - > IsS ( ) ) ) closestVert = vp [ i1 ] ;
if ( ( vp [ i0 ] - > IsS ( ) ) & & ( vp [ i1 ] - > IsS ( ) ) ) closestVert = ( vp [ i0 ] - > Q ( ) < vp [ i1 ] - > Q ( ) ) ? vp [ i0 ] : vp [ i1 ] ;
}
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if ( midMap [ ordered_pair ( sp [ i0 ] , sp [ i1 ] ) ] = = 0 ) {
midMap [ ordered_pair ( sp [ i0 ] , sp [ i1 ] ) ] = closestVert ;
}
else {
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if ( sp [ i0 ] - > IsS ( ) & & sp [ i1 ] - > IsS ( ) ) // constrained edge
{
if ( ! ( midMap [ ordered_pair ( sp [ i0 ] , sp [ i1 ] ) ] - > IsS ( ) ) & & closestVert - > IsS ( ) )
midMap [ ordered_pair ( sp [ i0 ] , sp [ i1 ] ) ] = closestVert ;
if ( midMap [ ordered_pair ( sp [ i0 ] , sp [ i1 ] ) ] - > IsS ( ) & & closestVert - > IsS ( ) & &
closestVert - > Q ( ) < midMap [ ordered_pair ( sp [ i0 ] , sp [ i1 ] ) ] - > Q ( ) )
{
midMap [ ordered_pair ( sp [ i0 ] , sp [ i1 ] ) ] = closestVert ;
}
}
else // UNCOSTRAINED EDGE
{
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if ( closestVert - > Q ( ) < midMap [ ordered_pair ( sp [ i0 ] , sp [ i1 ] ) ] - > Q ( ) )
midMap [ ordered_pair ( sp [ i0 ] , sp [ i1 ] ) ] = closestVert ;
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}
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}
}
}
}
/// \brief Check the topological correcteness of the induced Voronoi diagram
///
/// This function assumes that you have just run a geodesic like algorithm over your mesh using
/// a seed set as starting points and that there is an PerVertex Attribute called 'sources'
/// with pointers to the seed source. Usually you can initialize it with something like
///
/// DistanceFunctor &df,
/// tri::Geodesic<MeshType>::Compute(m, seedVec, df, std::numeric_limits<ScalarType>::max(),0,&sources);
static bool CheckVoronoiTopology ( MeshType & m , std : : vector < VertexType * > & seedVec )
{
tri : : RequirePerVertexAttribute ( m , " sources " ) ;
tri : : RequireCompactness ( m ) ;
typename MeshType : : template PerVertexAttributeHandle < VertexPointer > sources ;
sources = tri : : Allocator < MeshType > : : template GetPerVertexAttribute < VertexPointer > ( m , " sources " ) ;
std : : map < VertexPointer , int > seedMap ; // It says if a given vertex of m is a seed (and its index in seedVec)
BuildSeedMap ( m , seedVec , seedMap ) ;
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// Very basic check: each vertex must have a source that is a seed.
for ( int i = 0 ; i < m . vn ; + + i )
{
VertexPointer vp = sources [ i ] ;
int seedInd = seedMap [ vp ] ;
if ( seedInd < 0 )
return false ;
}
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std : : vector < MeshType * > regionVec ( seedVec . size ( ) , 0 ) ;
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for ( size_t i = 0 ; i < seedVec . size ( ) ; i + + ) regionVec [ i ] = new MeshType ;
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for ( int i = 0 ; i < m . fn ; + + i )
{
int vi0 = seedMap [ sources [ m . face [ i ] . V ( 0 ) ] ] ;
int vi1 = seedMap [ sources [ m . face [ i ] . V ( 1 ) ] ] ;
int vi2 = seedMap [ sources [ m . face [ i ] . V ( 2 ) ] ] ;
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assert ( vi0 > = 0 & & vi1 > = 0 & & vi2 > = 0 ) ;
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tri : : Allocator < MeshType > : : AddFace ( * regionVec [ vi0 ] , m . face [ i ] . cP ( 0 ) , m . face [ i ] . cP ( 1 ) , m . face [ i ] . cP ( 2 ) ) ;
if ( vi1 ! = vi0 )
tri : : Allocator < MeshType > : : AddFace ( * regionVec [ vi1 ] , m . face [ i ] . cP ( 0 ) , m . face [ i ] . cP ( 1 ) , m . face [ i ] . cP ( 2 ) ) ;
if ( ( vi2 ! = vi0 ) & & ( vi2 ! = vi1 ) )
tri : : Allocator < MeshType > : : AddFace ( * regionVec [ vi2 ] , m . face [ i ] . cP ( 0 ) , m . face [ i ] . cP ( 1 ) , m . face [ i ] . cP ( 2 ) ) ;
}
bool AllDiskRegion = true ;
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for ( size_t i = 0 ; i < seedVec . size ( ) ; i + + )
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{
MeshType & rm = * ( regionVec [ i ] ) ;
tri : : Clean < MeshType > : : RemoveDuplicateVertex ( rm ) ;
tri : : Allocator < MeshType > : : CompactEveryVector ( rm ) ;
tri : : UpdateTopology < MeshType > : : FaceFace ( rm ) ;
// char buf[100]; sprintf(buf,"disk%04i.ply",i); tri::io::ExporterPLY<MeshType>::Save(rm,buf,tri::io::Mask::IOM_VERTCOLOR + tri::io::Mask::IOM_VERTQUALITY );
int NNmanifoldE = tri : : Clean < MeshType > : : CountNonManifoldEdgeFF ( rm ) ;
if ( NNmanifoldE ! = 0 )
AllDiskRegion = false ;
int G = tri : : Clean < MeshType > : : MeshGenus ( rm ) ;
int numholes = tri : : Clean < MeshType > : : CountHoles ( rm ) ;
if ( numholes ! = 1 )
AllDiskRegion = false ;
if ( G ! = 0 ) AllDiskRegion = false ;
delete regionVec [ i ] ;
}
if ( ! AllDiskRegion ) return false ;
// **** Final step build a rough delaunay tri and check that it is manifold
MeshType delaMesh ;
std : : vector < FacePointer > innerCornerVec , // Faces adjacent to three different regions
borderCornerVec ; // Faces that are on the border and adjacent to at least two regions.
GetFaceCornerVec ( m , sources , innerCornerVec , borderCornerVec ) ;
// First add all the needed vertices: seeds and corners
for ( size_t i = 0 ; i < seedVec . size ( ) ; + + i )
tri : : Allocator < MeshType > : : AddVertex ( delaMesh , seedVec [ i ] - > P ( ) ) ;
// Now just add one face for each inner corner
for ( size_t i = 0 ; i < innerCornerVec . size ( ) ; + + i )
{
VertexPointer v0 = & delaMesh . vert [ seedMap [ sources [ innerCornerVec [ i ] - > V ( 0 ) ] ] ] ;
VertexPointer v1 = & delaMesh . vert [ seedMap [ sources [ innerCornerVec [ i ] - > V ( 1 ) ] ] ] ;
VertexPointer v2 = & delaMesh . vert [ seedMap [ sources [ innerCornerVec [ i ] - > V ( 2 ) ] ] ] ;
tri : : Allocator < MeshType > : : AddFace ( delaMesh , v0 , v1 , v2 ) ;
}
Clean < MeshType > : : RemoveUnreferencedVertex ( delaMesh ) ;
tri : : Allocator < MeshType > : : CompactVertexVector ( delaMesh ) ;
tri : : UpdateTopology < MeshType > : : FaceFace ( delaMesh ) ;
int nonManif = tri : : Clean < MeshType > : : CountNonManifoldEdgeFF ( delaMesh ) ;
if ( nonManif > 0 ) return false ;
return true ;
}
static void BuildSeedMap ( MeshType & m , std : : vector < VertexType * > & seedVec , std : : map < VertexPointer , int > & seedMap )
{
seedMap . clear ( ) ;
for ( size_t i = 0 ; i < m . vert . size ( ) ; + + i )
seedMap [ & ( m . vert [ i ] ) ] = - 1 ;
for ( size_t i = 0 ; i < seedVec . size ( ) ; + + i )
seedMap [ seedVec [ i ] ] = i ;
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for ( size_t i = 0 ; i < seedVec . size ( ) ; + + i )
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assert ( tri : : Index ( m , seedVec [ i ] ) > = 0 & & tri : : Index ( m , seedVec [ i ] ) < size_t ( m . vn ) ) ;
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}
/// \brief Build a mesh of the Delaunay triangulation induced by the given seeds
///
/// This function assumes that you have just run a geodesic like algorithm over your mesh using
/// a seed set as starting points and that there is an PerVertex Attribute called 'sources'
/// with pointers to the seed source. Usually you can initialize it with something like
///
/// DistanceFunctor &df,
/// tri::Geodesic<MeshType>::Compute(m, seedVec, df, std::numeric_limits<ScalarType>::max(),0,&sources);
///
/// The function can also
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static void ConvertDelaunayTriangulationToMesh ( MeshType & m ,
MeshType & outMesh ,
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std : : vector < VertexType * > & seedVec , bool refineFlag = true )
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{
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tri : : RequirePerVertexAttribute ( m , " sources " ) ;
tri : : RequireCompactness ( m ) ;
tri : : RequireVFAdjacency ( m ) ;
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PerVertexPointerHandle sources = tri : : Allocator < MeshType > : : template GetPerVertexAttribute < VertexPointer > ( m , " sources " ) ;
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outMesh . Clear ( ) ;
tri : : UpdateTopology < MeshType > : : FaceFace ( m ) ;
tri : : UpdateFlags < MeshType > : : FaceBorderFromFF ( m ) ;
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std : : map < VertexPointer , int > seedMap ; // It says if a given vertex of m is a seed (and its index in seedVec)
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BuildSeedMap ( m , seedVec , seedMap ) ;
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std : : vector < FacePointer > innerCornerVec , // Faces adjacent to three different regions
borderCornerVec ; // Faces that are on the border and adjacent to at least two regions.
GetFaceCornerVec ( m , sources , innerCornerVec , borderCornerVec ) ;
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// First add all the needed vertices: seeds and corners
for ( size_t i = 0 ; i < seedVec . size ( ) ; + + i )
tri : : Allocator < MeshType > : : AddVertex ( outMesh , seedVec [ i ] - > P ( ) , Color4b : : White ) ;
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map < std : : pair < VertexPointer , VertexPointer > , int > midMapInd ;
// Given a pair of sources gives the index of the mid vertex
map < std : : pair < VertexPointer , VertexPointer > , VertexPointer > midMapPt ;
if ( refineFlag )
{
GenerateMidPointMap ( m , midMapPt ) ;
typename std : : map < std : : pair < VertexPointer , VertexPointer > , VertexPointer > : : iterator mi ;
for ( mi = midMapPt . begin ( ) ; mi ! = midMapPt . end ( ) ; + + mi )
{
midMapInd [ ordered_pair ( mi - > first . first , mi - > first . second ) ] = outMesh . vert . size ( ) ;
tri : : Allocator < MeshType > : : AddVertex ( outMesh , mi - > second - > cP ( ) , Color4b : : LightBlue ) ;
}
}
// Now just add one (or four) face for each inner corner
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for ( size_t i = 0 ; i < innerCornerVec . size ( ) ; + + i )
{
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VertexPointer s0 = sources [ innerCornerVec [ i ] - > V ( 0 ) ] ;
VertexPointer s1 = sources [ innerCornerVec [ i ] - > V ( 1 ) ] ;
VertexPointer s2 = sources [ innerCornerVec [ i ] - > V ( 2 ) ] ;
assert ( ( s0 ! = s1 ) & & ( s0 ! = s2 ) & & ( s1 ! = s2 ) ) ;
VertexPointer v0 = & outMesh . vert [ seedMap [ s0 ] ] ;
VertexPointer v1 = & outMesh . vert [ seedMap [ s1 ] ] ;
VertexPointer v2 = & outMesh . vert [ seedMap [ s2 ] ] ;
if ( refineFlag )
{
VertexPointer mp01 = & outMesh . vert [ midMapInd [ ordered_pair ( s0 , s1 ) ] ] ;
VertexPointer mp02 = & outMesh . vert [ midMapInd [ ordered_pair ( s0 , s2 ) ] ] ;
VertexPointer mp12 = & outMesh . vert [ midMapInd [ ordered_pair ( s1 , s2 ) ] ] ;
assert ( ( mp01 ! = mp02 ) & & ( mp01 ! = mp12 ) & & ( mp02 ! = mp12 ) ) ;
tri : : Allocator < MeshType > : : AddFace ( outMesh , v0 , mp01 , mp02 ) ;
tri : : Allocator < MeshType > : : AddFace ( outMesh , v1 , mp12 , mp01 ) ;
tri : : Allocator < MeshType > : : AddFace ( outMesh , v2 , mp02 , mp12 ) ;
tri : : Allocator < MeshType > : : AddFace ( outMesh , mp01 , mp12 , mp02 ) ;
}
else
tri : : Allocator < MeshType > : : AddFace ( outMesh , v0 , v1 , v2 ) ;
}
Clean < MeshType > : : RemoveUnreferencedVertex ( outMesh ) ;
tri : : Allocator < MeshType > : : CompactVertexVector ( outMesh ) ;
}
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template < class MidPointType >
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static void PreprocessForVoronoi ( MeshType & m , ScalarType radius ,
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MidPointType mid ,
VoronoiProcessingParameter & vpp )
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{
const int maxSubDiv = 10 ;
tri : : RequireFFAdjacency ( m ) ;
tri : : UpdateTopology < MeshType > : : FaceFace ( m ) ;
tri : : Clean < MeshType > : : RemoveUnreferencedVertex ( m ) ;
ScalarType edgeLen = tri : : Stat < MeshType > : : ComputeFaceEdgeLengthAverage ( m ) ;
for ( int i = 0 ; i < maxSubDiv ; + + i )
{
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bool ret = tri : : Refine < MeshType , MidPointType > ( m , mid , min ( edgeLen * 2.0f , radius / vpp . refinementRatio ) ) ;
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if ( ! ret ) break ;
}
tri : : Allocator < MeshType > : : CompactEveryVector ( m ) ;
tri : : UpdateTopology < MeshType > : : VertexFace ( m ) ;
}
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static void PreprocessForVoronoi ( MeshType & m , float radius , VoronoiProcessingParameter & vpp )
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{
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tri : : MidPoint < MeshType > mid ( & m ) ;
PreprocessForVoronoi < tri : : MidPoint < MeshType > > ( m , radius , mid , vpp ) ;
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}
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static void RelaxRefineTriangulationSpring ( MeshType & m , MeshType & delaMesh , int relaxStep = 10 , int refineStep = 3 )
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{
tri : : RequireCompactness ( m ) ;
tri : : RequireCompactness ( delaMesh ) ;
tri : : RequireVFAdjacency ( delaMesh ) ;
tri : : RequireFFAdjacency ( delaMesh ) ;
tri : : RequirePerFaceMark ( delaMesh ) ;
const float convergenceThr = 0.001f ;
const float eulerStep = 0.1f ;
tri : : UpdateNormal < MeshType > : : PerVertexNormalizedPerFaceNormalized ( m ) ;
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typedef GridStaticPtr < FaceType , ScalarType > TriMeshGrid ;
TriMeshGrid ug ;
ug . Set ( m . face . begin ( ) , m . face . end ( ) ) ;
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typedef typename vcg : : SpatialHashTable < VertexType , ScalarType > HashVertexGrid ;
HashVertexGrid HG ;
HG . Set ( m . vert . begin ( ) , m . vert . end ( ) ) ;
PerVertexBoolHandle fixed = tri : : Allocator < MeshType > : : template GetPerVertexAttribute < bool > ( m , " fixed " ) ;
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const ScalarType maxDist = m . bbox . Diag ( ) / 4.f ;
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for ( int kk = 0 ; kk < refineStep + 1 ; kk + + )
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{
tri : : UpdateTopology < MeshType > : : FaceFace ( delaMesh ) ;
if ( kk ! = 0 ) // first step do not refine;
{
int nonManif = tri : : Clean < MeshType > : : CountNonManifoldEdgeFF ( delaMesh ) ;
if ( nonManif ) return ;
tri : : Refine < MeshType , tri : : MidPoint < MeshType > > ( delaMesh , tri : : MidPoint < MeshType > ( & delaMesh ) ) ;
}
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tri : : UpdateTopology < MeshType > : : VertexFace ( delaMesh ) ;
const float dist_upper_bound = m . bbox . Diag ( ) / 10.0 ;
float dist ;
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for ( int k = 0 ; k < relaxStep ; k + + )
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{
std : : vector < Point3f > avgForce ( delaMesh . vn ) ;
std : : vector < float > avgLenVec ( delaMesh . vn , 0 ) ;
for ( int i = 0 ; i < delaMesh . vn ; + + i )
{
vector < VertexPointer > starVec ;
face : : VVStarVF < FaceType > ( & delaMesh . vert [ i ] , starVec ) ;
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for ( size_t j = 0 ; j < starVec . size ( ) ; + + j )
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avgLenVec [ i ] + = Distance ( delaMesh . vert [ i ] . cP ( ) , starVec [ j ] - > cP ( ) ) ;
avgLenVec [ i ] / = float ( starVec . size ( ) ) ;
avgForce [ i ] = Point3f ( 0 , 0 , 0 ) ;
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for ( size_t j = 0 ; j < starVec . size ( ) ; + + j )
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{
Point3f force = delaMesh . vert [ i ] . cP ( ) - starVec [ j ] - > cP ( ) ;
float len = force . Norm ( ) ;
force . Normalize ( ) ;
avgForce [ i ] + = force * ( avgLenVec [ i ] - len ) ;
}
}
bool changed = false ;
for ( int i = 0 ; i < delaMesh . vn ; + + i )
{
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VertexPointer vp = tri : : GetClosestVertex < MeshType , HashVertexGrid > ( m , HG , delaMesh . vert [ i ] . P ( ) , dist_upper_bound , dist ) ;
if ( ! fixed [ vp ] & & ! ( vp - > IsS ( ) ) ) // update only non fixed vertices
{
delaMesh . vert [ i ] . P ( ) + = ( avgForce [ i ] * eulerStep ) ;
CoordType closest ;
float dist ;
tri : : GetClosestFaceBase ( m , ug , delaMesh . vert [ i ] . cP ( ) , maxDist , dist , closest ) ;
assert ( dist ! = maxDist ) ;
if ( Distance ( closest , delaMesh . vert [ i ] . P ( ) ) > avgLenVec [ i ] * convergenceThr ) changed = true ;
delaMesh . vert [ i ] . P ( ) = closest ;
}
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}
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if ( ! changed ) k = relaxStep ;
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} // end for k
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}
}
static void RelaxRefineTriangulationLaplacian ( MeshType & m , MeshType & delaMesh , int refineStep = 3 , int relaxStep = 10 )
{
tri : : RequireCompactness ( m ) ;
tri : : RequireCompactness ( delaMesh ) ;
tri : : RequireFFAdjacency ( delaMesh ) ;
tri : : RequirePerFaceMark ( delaMesh ) ;
tri : : UpdateTopology < MeshType > : : FaceFace ( delaMesh ) ;
typedef GridStaticPtr < FaceType , ScalarType > TriMeshGrid ;
TriMeshGrid ug ;
ug . Set ( m . face . begin ( ) , m . face . end ( ) ) ;
const ScalarType maxDist = m . bbox . Diag ( ) / 4.f ;
int origVertNum = delaMesh . vn ;
for ( int k = 0 ; k < refineStep ; + + k )
{
tri : : UpdateSelection < MeshType > : : VertexClear ( delaMesh ) ;
tri : : Refine < MeshType , tri : : MidPoint < MeshType > > ( delaMesh , tri : : MidPoint < MeshType > ( & delaMesh ) ) ;
for ( int j = 0 ; j < relaxStep ; + + j )
{
// tri::Smooth<MeshType>::VertexCoordLaplacian(delaMesh,1,true);
for ( int i = origVertNum ; i < delaMesh . vn ; + + i )
{
float dist ;
delaMesh . vert [ i ] . SetS ( ) ;
CoordType closest ;
tri : : GetClosestFaceBase ( m , ug , delaMesh . vert [ i ] . cP ( ) , maxDist , dist , closest ) ;
assert ( dist ! = maxDist ) ;
delaMesh . vert [ i ] . P ( ) = ( delaMesh . vert [ i ] . P ( ) + closest ) / 2.0f ;
}
tri : : Smooth < MeshType > : : VertexCoordLaplacianBlend ( delaMesh , 1 , 0.2f , true ) ;
}
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}
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for ( int i = origVertNum ; i < delaMesh . vn ; + + i ) delaMesh . vert [ i ] . C ( ) = Color4b : : LightBlue ;
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}
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} ; // end class VoronoiProcessing
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} // end namespace tri
} // end namespace vcg
# endif