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Initial Holefiller files from OpenFlipper

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This commit is contained in:
Jan Möbius
2024-02-20 15:06:17 +01:00
parent 6cfaa5afa2
commit 90d868e36a
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src/OpenMesh/Tools/HoleFiller/HoleFillerT.hh Normal file
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/*===========================================================================*\
* *
* OpenFlipper *
* Copyright (c) 2001-2015, RWTH-Aachen University *
* Department of Computer Graphics and Multimedia *
* All rights reserved. *
* www.openflipper.org *
* *
*---------------------------------------------------------------------------*
* This file is part of OpenFlipper. *
*---------------------------------------------------------------------------*
* *
* Redistribution and use in source and binary forms, with or without *
* modification, are permitted provided that the following conditions *
* are met: *
* *
* 1. Redistributions of source code must retain the above copyright notice, *
* this list of conditions and the following disclaimer. *
* *
* 2. Redistributions in binary form must reproduce the above copyright *
* notice, this list of conditions and the following disclaimer in the *
* documentation and/or other materials provided with the distribution. *
* *
* 3. Neither the name of the copyright holder nor the names of its *
* contributors may be used to endorse or promote products derived from *
* this software without specific prior written permission. *
* *
* THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS *
* "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED *
* TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A *
* PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT HOLDER *
* OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, *
* EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, *
* PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR *
* PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF *
* LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING *
* NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS *
* SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. *
* *
\*===========================================================================*/
#pragma once
#include <vector>
#include <float.h>
#include <cmath>
#include <OpenMesh/Core/Utils/vector_cast.hh>
#include "OpenMeshUtils.hh"
#include <OpenMesh/Tools/Smoother/JacobiLaplaceSmootherT.hh>
#include <OpenMesh/Core/Mesh/PolyConnectivity.hh>
//=============================================================================
template< class TheMesh >
class HoleFiller
{
public:
typedef TheMesh Mesh;
import_om_abbreviations( typename Mesh );
// A weight is a tuple of area and maximum dihedral angle
//
class Weight {
public:
Weight() : angle_( 180 ), area_( FLT_MAX ) {}
Weight( Scalar _angle, Scalar _area ) : angle_( _angle ), area_( _area ) {}
~Weight() {}
Scalar angle() const { return angle_; }
Scalar area() const { return area_; }
Weight operator+( const Weight & _other ) const {
return Weight( std::max( angle(), _other.angle() ),
area() + _other.area() );
}
bool operator<( const Weight & _rhs ) const {
return ( angle() < _rhs.angle() ||
( angle() == _rhs.angle() && area() < _rhs.area() ) );
}
private:
Scalar angle_;
Scalar area_;
};
// Ctors
explicit HoleFiller( Mesh & _mesh );
~HoleFiller();
// Identify and fill all holes of the mesh.
void fill_all_holes( int _stages = 3 );
// Fill a hole which is identified by one of its boundary edges.
void fill_hole( EH _eh, int _stages = 3 );
// Fair a filling
//void fairing( std::vector< FH >& _faceHandles );
void fairing( std::vector< OpenMesh::SmartFaceHandle >& _faceHandles );
// Remove degenerated faces from the filling
void removeDegeneratedFaces( std::vector< FH >& _faceHandles );
private:
// Refine a face
bool refine( FH _fh );
// Relax an edge
bool relax_edge( OpenMesh::SmartEdgeHandle _eh );
// Test whether a point _x lies in the circumsphere of _a,_b,_c.
bool in_circumsphere( const Point & _x,
const Point & _a,
const Point & _b,
const Point & _c ) const;
// Create the triangulation for polygon (_i,...,_j).
bool fill( int _i, int _j );
// Compute the weight of the triangle (_i,_j,_k).
Weight weight( int _i, int _j, int _k );
// Does edge (_u,_v) already exist?
bool exists_edge( OpenMesh::SmartVertexHandle _u, VH _w );
// Compute the area of the triangle (_a,_b,_c).
Scalar area( VH _a, VH _b, VH _c );
// Compute the dihedral angle (in degrees) between triangle
// (_u,_v,_a) and triangle (_v,_u,_b).
Scalar dihedral_angle( VH _u, VH _v, VH _a, VH _b );
// The mesh, with each vertex we associate a scale factor that is
// needed for remeshing
Mesh & mesh_;
OpenMesh::VPropHandleT< Scalar > scale_;
/*
HOLE
boundary_vertex_
|
V
==*=======*=======*== BOUNDARY
/ \ / \ / \
/ \ / \ / \
\ / \ /
* * <- opposite_vertex_
*/
typedef std::vector< VH > VHVec;
typedef typename std::vector< VH >::iterator VHVecIter;
typedef typename std::vector< VH >::const_iterator CVHVecIter;
typedef std::vector< FH > FHVec;
typedef typename std::vector< FH >::iterator FHVecIter;
typedef typename std::vector< FH >::const_iterator CFHVecIter;
// This vector contains all vertices of the hole (in order)
std::vector< OpenMesh::SmartVertexHandle > boundary_vertex_;
// This vector contains all vertices that are opposite to an edge of the hole
VHVec opposite_vertex_;
// This vector contains all edges of the hole (in order)
std::vector< OpenMesh::SmartEdgeHandle > hole_edge_;
// This vector stores handles to all triangles of the current hole
std::vector< OpenMesh::SmartFaceHandle > hole_triangle_;
// These are the two central arrays that are needed for the dynamic
// programming approach to hole filling.
// w_[i][j] : stores the minimal weight that can be achieved
// for a triangulation of the polygon
// boundary_vertex_[i],...,boundary_vertex_[j]
// l_[i][j] : stores the third index of the triangle
// <boundary_vertex_[i],boundary_vertex_[l_[i][j]],
// boundary_vertex_[j]>
// that is needed for reconstructing the minimal triangulation
std::vector< std::vector< Weight > > w_;
std::vector< std::vector< int > > l_;
};
//=============================================================================
#ifndef HOLEFILLER_CC
#include "HoleFillerT_impl.hh"
#endif
//=============================================================================

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/*===========================================================================*\
* *
* OpenFlipper *
* Copyright (c) 2001-2015, RWTH-Aachen University *
* Department of Computer Graphics and Multimedia *
* All rights reserved. *
* www.openflipper.org *
* *
*---------------------------------------------------------------------------*
* This file is part of OpenFlipper. *
*---------------------------------------------------------------------------*
* *
* Redistribution and use in source and binary forms, with or without *
* modification, are permitted provided that the following conditions *
* are met: *
* *
* 1. Redistributions of source code must retain the above copyright notice, *
* this list of conditions and the following disclaimer. *
* *
* 2. Redistributions in binary form must reproduce the above copyright *
* notice, this list of conditions and the following disclaimer in the *
* documentation and/or other materials provided with the distribution. *
* *
* 3. Neither the name of the copyright holder nor the names of its *
* contributors may be used to endorse or promote products derived from *
* this software without specific prior written permission. *
* *
* THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS *
* "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED *
* TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A *
* PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT HOLDER *
* OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, *
* EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, *
* PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR *
* PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF *
* LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING *
* NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS *
* SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. *
* *
\*===========================================================================*/
//=============================================================================
#include "HoleFillerT.hh"
//=============================================================================
template< class MeshT >
HoleFiller< MeshT >::HoleFiller( Mesh & _mesh )
: mesh_( _mesh )
{
mesh_.request_vertex_status();
mesh_.request_edge_status();
if (! mesh_.get_property_handle(scale_,"scale") )
mesh_.add_property( scale_ , "scale" );
}
//=============================================================================
template< class MeshT >
HoleFiller< MeshT >::~HoleFiller()
{
mesh_.release_vertex_status();
mesh_.release_edge_status();
if ( mesh_.get_property_handle(scale_,"scale") )
mesh_.remove_property( scale_ );
}
//=============================================================================
//
// Identify and fill all holes of the mesh.
//
//=============================================================================
template< class MeshT >
void
HoleFiller< MeshT >::fill_all_holes( int _stages )
{
// Collect all boundary edges
std::vector< EH > bdry_edge;
for (auto ei : mesh_.edges())
if ( ei.is_boundary() )
bdry_edge.push_back( ei );
// Fill holes
int cnt = 0;
for (auto i : bdry_edge)
if ( mesh_.is_boundary( i ) )
{
++cnt;
std::cerr << "Filling hole " << cnt << "\n";
fill_hole( i, _stages );
}
// Smooth fillings
if ( _stages <= 2 )
return;
std::cerr << "Stage 3 : Smoothing the hole fillings ... ";
OpenMesh::Smoother::JacobiLaplaceSmootherT< Mesh > smoother( mesh_ );
smoother.initialize( OpenMesh::Smoother::SmootherT< Mesh >::
Tangential_and_Normal,
OpenMesh::Smoother::SmootherT< Mesh >::C1 );
smoother.smooth( 500 );
std::cerr << "ok\n";
}
//=============================================================================
//
// Fill a hole which is identified by one of its boundary edges.
//
//=============================================================================
template< class MeshT >
void
HoleFiller< MeshT >::fill_hole( EH _eh, int _stages )
{
std::cerr << " Stage 1 : Computing a minimal triangulation ... ";
//remember last vertex for selection of new ones
typename MeshT::VertexHandle old_last_handle = *(--mesh_.vertices_end());
// No boundary edge, no hole
if ( ! mesh_.is_boundary( _eh ) )
return;
// Get boundary halfedge
OpenMesh::SmartHalfedgeHandle hh = make_smart(_eh, mesh_).h0();
if ( ! hh.is_boundary() )
hh = hh.opp();
// Collect boundary vertices
boundary_vertex_.clear();
opposite_vertex_.clear();
OpenMesh::SmartHalfedgeHandle ch = hh;
do {
boundary_vertex_.push_back( ch.from() );
opposite_vertex_.push_back( ch.opp().next().to() );
//check number of outgoing boundary HEH's at Vertex
int c = 0;
OpenMesh::SmartVertexHandle vh = ch.to();
for (auto voh_it : vh.outgoing_halfedges())
if ( voh_it.is_boundary() )
c++;
if ( c >= 2){
OpenMesh::SmartHalfedgeHandle op = ch.opp();
typename MeshT::VertexOHalfedgeIter voh_it(mesh_,op);
ch = *(++voh_it);
}else
ch = ch.next();
} while ( ch != hh );
int nv = boundary_vertex_.size();
// Compute an initial triangulation
w_.clear();
w_.resize( nv, std::vector<Weight>( nv, Weight() ) );
l_.clear();
l_.resize( nv, std::vector<int>( nv, 0 ) );
for ( int i = 0; i < nv - 1; ++i )
w_[i][i+1] = Weight( 0, 0 );
for ( int j = 2; j < nv; ++j )
{
#pragma omp parallel for shared(j, nv)
for(int i = 0; i < nv-j; ++i)
{
Weight valmin;
int argmin = -1;
for ( int m = i + 1; m < i + j; ++m )
{
Weight newval = w_[i][m] + w_[m][i+j] + weight( i, m, i+j );
if ( newval < valmin )
{
valmin = newval;
argmin = m;
}
}
w_[i][i+j] = valmin;
l_[i][i+j] = argmin;
}
}
// Actually fill the hole. We collect all triangles and edges of
// this filling for further processing.
hole_edge_.clear();
hole_triangle_.clear();
if ( fill( 0, nv - 1 ) ){
std::cerr << "ok\n";
if ( _stages <= 1 )
return;
std::cerr << " Stage 2 : Fairing the filling ... ";
std::vector< OpenMesh::SmartFaceHandle > handles = hole_triangle_;
fairing(handles);
//select all new vertices
typename MeshT::VertexIter old_end = ++typename MeshT::VertexIter(mesh_,old_last_handle);
typename MeshT::VertexIter v_end = mesh_.vertices_end();
for(; old_end != v_end; ++old_end)
if ( !mesh_.status(*old_end).deleted() )
mesh_.status(*old_end).set_selected( true );
std::cerr << "ok\n";
}else
std::cerr << "Could not create triangulation" << std::endl;
}
/// path fairing
template< class MeshT >
void
HoleFiller< MeshT >::fairing( std::vector< OpenMesh::SmartFaceHandle >& _faceHandles ){
//generate vector of all edges
hole_edge_.clear();
hole_triangle_ = _faceHandles;
OpenMesh::EPropHandleT< bool > edgeProp;
OpenMesh::VPropHandleT< bool > vertexProp;
OpenMesh::FPropHandleT< bool > faceProp;
OpenMesh::FPropHandleT< bool > orderProp;
if (! mesh_.get_property_handle(edgeProp,"edgeProp") )
mesh_.add_property( edgeProp, "edgeProp" );
if (! mesh_.get_property_handle(vertexProp,"vertexProp") )
mesh_.add_property( vertexProp, "vertexProp" );
if (! mesh_.get_property_handle(faceProp,"faceProp") )
mesh_.add_property( faceProp, "faceProp" );
if (! mesh_.get_property_handle(orderProp,"orderProp") )
mesh_.add_property( orderProp, "orderProp" );
//init properties by setting all of them to false
for (auto fIt : mesh_.faces()) {
mesh_.property( orderProp, fIt ) = false;
mesh_.property( faceProp, fIt ) = false;
}
for (auto eIt : mesh_.edges())
mesh_.property( edgeProp, eIt ) = false;
for (auto vIt : mesh_.vertices()) {
mesh_.property( vertexProp, vIt ) = false;
}
//set face property
for (uint i = 0; i < hole_triangle_.size(); i++){
mesh_.property( faceProp, hole_triangle_[i] ) = true;
}
//set properties
for (unsigned int i = 0; i < hole_triangle_.size(); i++){
for (auto fei : hole_triangle_[i].edges()) {
mesh_.status( fei ).set_locked(true);
//set edge property for all edges inside the hole (eg not on the hole boundary)
if (mesh_.property( faceProp, fei.h0().face() ) &&
mesh_.property( faceProp, fei.h1().face() ) ){
mesh_.property( edgeProp, fei ) = true;
hole_edge_.push_back( fei );
mesh_.status( fei ).set_locked(false);
}
}
/// @TODO, strange iterator at property!
for (auto fvi : hole_triangle_[i].vertices()){
//set vertex property for all vertices of the hole
for ( auto vfi : fvi.faces() )
mesh_.property( vertexProp, fvi ) = true;
}
}
//calculate scaling weights for vertices
for (auto vIt : mesh_.vertices())
if (mesh_.property(vertexProp, vIt)){
Scalar cnt = 0;
Scalar scale = 0;
for ( auto voh_it : vIt.outgoing_halfedges())
{
if (voh_it.face().is_valid() &&
voh_it.opp().face().is_valid() &&
mesh_.property(faceProp, voh_it.face() ) &&
mesh_.property(faceProp, voh_it.opp().face() ))
continue;
cnt += 1.0f;
Point p0 = mesh_.point( vIt );
Point p1 = mesh_.point( voh_it.to() );
scale += ( p1 - p0 ).norm();
}
scale /= cnt;
mesh_.property( scale_, vIt ) = scale;
}
mesh_.remove_property(edgeProp);
mesh_.remove_property(vertexProp);
mesh_.remove_property(faceProp);
mesh_.remove_property(orderProp);
// Do the patch fairing
bool did_refine = true;
for ( int k = 0; k < 40 && did_refine; ++k )
{
uint end = hole_triangle_.size();
did_refine = false;
for ( unsigned int j = 0; j < end; ++j )
did_refine |= refine( hole_triangle_[j] );
for ( int i = 0; i < 10; ++i )
for ( unsigned int j = 0; j < hole_edge_.size(); ++j )
relax_edge( hole_edge_[j] );
}
// unlock everything
for ( auto ei : mesh_.edges())
mesh_.status( ei ).set_locked( false );
}
//=============================================================================
//
// Refine a face: Apply a 1-to-3 split if the edge lengths of the
// face do not match the interpolated edge lengths of the hole
// boundary.
//
//=============================================================================
template< class MeshT >
bool
HoleFiller< MeshT >::refine( FH _fh )
{
// Collect the three edges of the face into e0, e1, e2
FEI fei = mesh_.fe_iter( _fh );
OpenMesh::SmartEdgeHandle e0 = *fei; ++fei;
OpenMesh::SmartEdgeHandle e1 = *fei; ++fei;
OpenMesh::SmartEdgeHandle e2 = *fei; ++fei;
// Collect the vertices, vertex positions and scale factors of the face.
FVI fvi = mesh_.fv_iter( _fh );
VH v0 = *fvi; ++fvi;
VH v1 = *fvi; ++fvi;
VH v2 = *fvi; ++fvi;
Point p0 = mesh_.point( v0 );
Point p1 = mesh_.point( v1 );
Point p2 = mesh_.point( v2 );
Scalar scale0 = mesh_.property( scale_, v0 );
Scalar scale1 = mesh_.property( scale_, v1 );
Scalar scale2 = mesh_.property( scale_, v2 );
// Interpolate the scale factor.
Scalar scale = ( scale0 + scale1 + scale2 ) / 3.0f;
Point center = typename MeshT::Scalar(1.0/3.0) * ( p0 + p1 + p2 );
Scalar d0 = 1.0f * ( p0 - center ).norm();
Scalar d1 = 1.0f * ( p1 - center ).norm();
Scalar d2 = 1.0f * ( p2 - center ).norm();
//dont split triangles which tend to degenerate
if ( (d0 + d1 + d2) / 3.0f < scale) return false;
// If the edge lengths differ too much from the scale, perform a
// triangle split.
if ( ( d0 > scale && d0 > scale0 ) ||
( d1 > scale && d1 > scale1 ) ||
( d2 > scale && d2 > scale2 ) )
{
// Split the face ...
OpenMesh::SmartVertexHandle ch = mesh_.add_vertex( center );
mesh_.split( _fh, ch );
// ... put the new triangles into the global triangle list ...
for ( auto vfi : ch.faces() )
if ( vfi != _fh )
hole_triangle_.push_back( vfi );
// ... put the new edges into the global edge list ...
for ( auto vei : ch.edges() )
hole_edge_.push_back( vei );
// ... and set the appropriate scale factor for the new vertex.
mesh_.property( scale_, ch ) = scale;
relax_edge( e0 );
relax_edge( e1 );
relax_edge( e2 );
return true;
}
return false;
}
//=============================================================================
//
// Relax an edge: Flip it if one of its opposing vertices lies in
// the circumsphere of the other three vertices.
//
//=============================================================================
template< class MeshT >
bool
HoleFiller< MeshT >::relax_edge( OpenMesh::SmartEdgeHandle _eh )
{
if ( mesh_.status( _eh ).locked() )
return false;
// Abbreviations for the two halfedges of _eh
OpenMesh::SmartHalfedgeHandle h0 = _eh.h0();
OpenMesh::SmartHalfedgeHandle h1 = _eh.h1();
// Get the two end-vertices u and v of the edge
Point u( mesh_.point( h0.to() ) );
Point v( mesh_.point( h1.to() ) );
// Get the two opposing vertices a and b
Point a( mesh_.point( h0.next().to() ) );
Point b( mesh_.point( h1.next().to() ) );
// If the circumsphere criterion is fullfilled AND if the flip is
// topologically admissible, we do it.
if ( in_circumsphere( a, u, v, b ) || in_circumsphere( b, u, v, a ) ){
if ( mesh_.is_flip_ok( _eh ) )
{
mesh_.flip( _eh );
return true;
}else
mesh_.status(_eh).set_selected( true );
}
return false;
}
//=============================================================================
//
// Test whether a point _x lies in the circumsphere of _a,_b,_c.
//
//=============================================================================
template< class MeshT >
bool
HoleFiller< MeshT >::in_circumsphere( const Point & _x,
const Point & _a,
const Point & _b,
const Point & _c ) const
{
Point ab = _b - _a;
Point ac = _c - _a;
Scalar a00 = -2.0f * ( ab | _a );
Scalar a01 = -2.0f * ( ab | _b );
Scalar a02 = -2.0f * ( ab | _c );
Scalar b0 = _a.sqrnorm() - _b.sqrnorm();
Scalar a10 = -2.0f * ( ac | _a );
Scalar a11 = -2.0f * ( ac | _b );
Scalar a12 = -2.0f * ( ac | _c );
Scalar b1 = _a.sqrnorm() - _c.sqrnorm();
typename MeshT::Scalar alpha = -(-a11*a02+a01*a12-a12*b0+b1*a02+a11*b0-a01*b1)
/ (-a11*a00+a11*a02-a10*a02+a00*a12+a01*a10-a01*a12);
typename MeshT::Scalar beta = (a10*b0-a10*a02-a12*b0+a00*a12+b1*a02-a00*b1)
/ (-a11*a00+a11*a02-a10*a02+a00*a12+a01*a10-a01*a12);
typename MeshT::Scalar gamma = (-a11*a00-a10*b0+a00*b1+a11*b0+a01*a10-a01*b1)
/ (-a11*a00+a11*a02-a10*a02+a00*a12+a01*a10-a01*a12);
Point center = alpha * _a + beta * _b + gamma * _c;
return ( _x - center ).sqrnorm() < ( _a - center ).sqrnorm();
}
//=============================================================================
//
// Create the triangulation
//
// Recursively creates the triangulation for polygon (_i,...,_j).
//
//=============================================================================
template< class MeshT >
bool
HoleFiller< MeshT >::fill( int _i, int _j )
{
// If the two vertices _i and _j are adjacent, there is nothing to do.
if ( _i + 1 == _j )
return true;
// Create and store the middle triangle, store its edges.
OpenMesh::SmartFaceHandle fh = mesh_.add_face( boundary_vertex_[_i],
boundary_vertex_[ l_[_i][_j] ],
boundary_vertex_[_j] );
hole_triangle_.push_back( fh );
if (!fh.is_valid())
return false;
hole_edge_.push_back( mesh_.edge_handle
( mesh_.find_halfedge( boundary_vertex_[_i],
boundary_vertex_[ l_[_i][_j] ] ) ) );
hole_edge_.push_back( mesh_.edge_handle
( mesh_.find_halfedge( boundary_vertex_[ l_[_i][_j] ],
boundary_vertex_[_j] ) ) );
// Recursively create the left and right side of the
// triangulation.
if (!fill( _i, l_[_i][_j] ) || !fill( l_[_i][_j], _j ))
return false;
else
return true;
}
//=============================================================================
//
// Compute the weight of the triangle (_i,_j,_k).
//
//=============================================================================
template< class MeshT >
typename HoleFiller< MeshT >::Weight
HoleFiller< MeshT >::weight( int _i, int _j, int _k )
{
// Return an infinite weight if the insertion of this triangle
// would create complex edges.
if ( exists_edge( boundary_vertex_[_i], boundary_vertex_[_j] ) ||
exists_edge( boundary_vertex_[_j], boundary_vertex_[_k] ) ||
exists_edge( boundary_vertex_[_k], boundary_vertex_[_i] ) )
return Weight();
// Return an infinite weight, if one of the neighboring patches
// could not be created.
if ( l_[_i][_j] == -1 ) return Weight();
if ( l_[_j][_k] == -1 ) return Weight();
// Compute the maxmimum dihedral angles to the adjacent triangles
// (if they exist)
Scalar angle = 0.0f;
if ( _i + 1 == _j )
angle = std::max( angle, dihedral_angle( boundary_vertex_[_i],
boundary_vertex_[_j],
boundary_vertex_[_k],
opposite_vertex_[_i] ) );
else
angle = std::max( angle, dihedral_angle( boundary_vertex_[_i],
boundary_vertex_[_j],
boundary_vertex_[_k],
boundary_vertex_[l_[_i][_j]] ) );
if ( _j + 1 == _k )
angle = std::max( angle, dihedral_angle( boundary_vertex_[_j],
boundary_vertex_[_k],
boundary_vertex_[_i],
opposite_vertex_[_j] ) );
else
angle = std::max( angle, dihedral_angle( boundary_vertex_[_j],
boundary_vertex_[_k],
boundary_vertex_[_i],
boundary_vertex_[l_[_j][_k]] ) );
if ( _i == 0 && _k == (int) boundary_vertex_.size() - 1 )
angle = std::max( angle, dihedral_angle( boundary_vertex_[_k],
boundary_vertex_[_i],
boundary_vertex_[_j],
opposite_vertex_[_k] ) );
return Weight( angle, area( boundary_vertex_[_i],
boundary_vertex_[_j],
boundary_vertex_[_k] ) );
}
//=============================================================================
//
// Does an edge from vertex _u to _v exist?
//
//=============================================================================
template< class MeshT >
bool
HoleFiller< MeshT >::exists_edge( OpenMesh::SmartVertexHandle _u, VH _w )
{
for ( auto vohi : _u.outgoing_halfedges() )
if ( ! vohi.edge().is_boundary() )
if ( vohi.to() == _w )
return true;
return false;
}
//=============================================================================
//
// Compute the area of the triangle (_a,_b,_c).
//
//=============================================================================
template< class MeshT >
typename MeshT::Scalar
HoleFiller< MeshT >::area( VH _a, VH _b, VH _c )
{
Point a( mesh_.point( _a ) );
Point b( mesh_.point( _b ) );
Point c( mesh_.point( _c ) );
Point n( ( b - a ) % ( c - b ) );
return 0.5 * n.norm();
}
//=============================================================================
//
// Compute a dihedral angle
//
// Computes the dihedral angle (in degrees) between triangle
// (_u,_v,_a) and triangle (_v,_u,_b), no matter whether these
// triangles actually exist in the current mesh or not).
//
//=============================================================================
template< class MeshT >
typename MeshT::Scalar
HoleFiller< MeshT >::dihedral_angle( VH _u, VH _v, VH _a, VH _b )
{
Point u( mesh_.point( _u ) );
Point v( mesh_.point( _v ) );
Point a( mesh_.point( _a ) );
Point b( mesh_.point( _b ) );
Point n0( ( v - u ) % ( a - v ) );
Point n1( ( u - v ) % ( b - u ) );
n0.normalize();
n1.normalize();
return acos( n0 | n1 ) * 180.0 / M_PI;
}
/// remove degenerated faces
template< class MeshT >
void
HoleFiller< MeshT >::removeDegeneratedFaces( std::vector< FH >& _faceHandles ){
for (int i = _faceHandles.size()-1; i >= 0 ; i--){
if ( mesh_.status( _faceHandles[i] ).deleted() ){
// face might be deleted because of a previous edge collapse
// erase the face from the vector
_faceHandles.erase( _faceHandles.begin() + i );
continue;
}
//get the vertices (works only on triMeshes)
FVI fvi = mesh_.fv_iter( _faceHandles[i] );
Point v0 = mesh_.point( *fvi);
++fvi;
Point v1 = mesh_.point( *fvi );
++fvi;
Point v2 = mesh_.point( *fvi );
//check if its degenerated
Point v0v1 = v1 - v0;
Point v0v2 = v2 - v0;
Point n = v0v1 % v0v2; // not normalized !
double d = n.sqrnorm();
if (d < FLT_MIN && d > -FLT_MIN) {
// degenerated face found
FHI hIt = mesh_.fh_iter( _faceHandles[i] );
//try to collapse one of the edges
while (hIt.is_valid()){
if ( mesh_.is_collapse_ok( *hIt ) ){
// collapse the edge to remove the triangle
mesh_.collapse( *hIt );
// and erase the corresponding face from the vector
_faceHandles.erase( _faceHandles.begin() + i );
break;
} else {
++hIt;
}
}
}
}
}
//=============================================================================