Documentations/OpenMesh-Doc-Latest/a00809_source.html

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//=============================================================================

//

//  CLASS InterpolatingSqrt3LGT

//

//=============================================================================


#ifndef OPENMESH_SUBDIVIDER_UNIFORM_INTERP_SQRT3T_LABSIK_GREINER_HH

#define OPENMESH_SUBDIVIDER_UNIFORM_INTERP_SQRT3T_LABSIK_GREINER_HH


//== INCLUDES =================================================================


#include <OpenMesh/Core/Mesh/Handles.hh>

#include <OpenMesh/Core/System/config.hh>

#include <OpenMesh/Tools/Subdivider/Uniform/SubdividerT.hh>


#if defined(_DEBUG) || defined(DEBUG)

// Makes life lot easier, when playing/messing around with low-level topology

// changing methods of OpenMesh

#  include <OpenMesh/Tools/Utils/MeshCheckerT.hh>

#  define ASSERT_CONSISTENCY( T, m ) \

     assert(OpenMesh::Utils::MeshCheckerT<T>(m).check())

#else

#  define ASSERT_CONSISTENCY( T, m )

#endif

// -------------------- STL

#include <vector>

#if defined(OM_CC_MIPS)

#  include <math.h>

#else

#  include <cmath>

#endif


//#define MIRROR_TRIANGLES

//#define MIN_NORM


//== NAMESPACE ================================================================


namespace OpenMesh   { // BEGIN_NS_OPENMESH

namespace Subdivider { // BEGIN_NS_DECIMATER

namespace Uniform    { // BEGIN_NS_UNIFORM


//== CLASS DEFINITION =========================================================


template <typename MeshType, typename RealType = double>

class InterpolatingSqrt3LGT : public SubdividerT< MeshType, RealType >

{

public:


  typedef RealType                                real_t;

  typedef MeshType                                mesh_t;

  typedef SubdividerT< mesh_t, real_t >           parent_t;


  typedef std::vector< std::vector<real_t> >      weights_t;


public:


  InterpolatingSqrt3LGT(void) : parent_t()

  { init_weights(); }


  explicit InterpolatingSqrt3LGT(MeshType &_m) : parent_t(_m)

  { init_weights(); }


  virtual ~InterpolatingSqrt3LGT() {}


public:


  const char *name() const override { return "Uniform Interpolating Sqrt3"; }


  void init_weights(size_t _max_valence=50)

  {

    weights_.resize(_max_valence);


    weights_[3].resize(4);

    weights_[3][0] = real_t(+4.0/27);

    weights_[3][1] = real_t(-5.0/27);

    weights_[3][2] = real_t(+4.0/27);

    weights_[3][3] = real_t(+8.0/9);


    weights_[4].resize(5);

    weights_[4][0] = real_t(+2.0/9);

    weights_[4][1] = real_t(-1.0/9);

    weights_[4][2] = real_t(-1.0/9);

    weights_[4][3] = real_t(+2.0/9);

    weights_[4][4] = real_t(+7.0/9);


    for(unsigned int K=5; K<_max_valence; ++K)

    {

        weights_[K].resize(K+1);

        double aH = 2.0*cos(M_PI/static_cast<double>(K))/3.0;

        weights_[K][K] = static_cast<real_t>(1.0 - aH*aH);

        for(unsigned int i=0; i<K; ++i)

        {


            weights_[K][i] = static_cast<real_t>((aH*aH + 2.0*aH*cos(2.0*static_cast<double>(i)*M_PI/static_cast<double>(K) + M_PI/static_cast<double>(K)) +

                                      2.0*aH*aH*cos(4.0*static_cast<double>(i)*M_PI/static_cast<double>(K) + 2.0*M_PI/static_cast<double>(K)))/static_cast<double>(K));

        }

    }


    //just to be sure:

    weights_[6].resize(0);


  }


protected:


  bool prepare( MeshType& _m ) override

  {

    _m.request_edge_status();

    _m.add_property( fp_pos_ );

    _m.add_property( ep_nv_ );

    _m.add_property( mp_gen_ );

    _m.property( mp_gen_ ) = 0;


    return _m.has_edge_status()

      &&   ep_nv_.is_valid() && mp_gen_.is_valid();

  }


  bool cleanup( MeshType& _m ) override

  {

    _m.release_edge_status();

    _m.remove_property( fp_pos_ );

    _m.remove_property( ep_nv_ );

    _m.remove_property( mp_gen_ );

    return true;

  }


  bool subdivide( MeshType& _m, size_t _n , const bool _update_points = true) override

  {


    typename MeshType::VertexIter       vit;

    typename MeshType::VertexVertexIter vvit;

    typename MeshType::EdgeIter         eit;

    typename MeshType::FaceIter         fit;

    typename MeshType::FaceVertexIter   fvit;

    typename MeshType::FaceHalfedgeIter fheit;

    typename MeshType::VertexHandle     vh;

    typename MeshType::HalfedgeHandle   heh;

    typename MeshType::Point            pos(0,0,0), zero(0,0,0);

    size_t                              &gen = _m.property( mp_gen_ );


    for (size_t l=0; l<_n; ++l)

    {

      // tag existing edges

      for (eit=_m.edges_begin(); eit != _m.edges_end();++eit)

      {

        _m.status( *eit ).set_tagged( true );

        if ( (gen%2) && _m.is_boundary(*eit) )

          compute_new_boundary_points( _m, *eit ); // *) creates new vertices

      }


      // insert new vertices, and store pos in vp_pos_

      typename MeshType::FaceIter fend = _m.faces_end();

      for (fit = _m.faces_begin();fit != fend; ++fit)

      {

        if (_m.is_boundary(*fit))

        {

            if(gen%2)

                _m.property(fp_pos_, *fit).invalidate();

            else

            {

                //find the interior boundary halfedge

                for( heh = _m.halfedge_handle(*fit); !_m.is_boundary( _m.opposite_halfedge_handle(heh) ); heh = _m.next_halfedge_handle(heh) )

                  ;

                assert(_m.is_boundary( _m.opposite_halfedge_handle(heh) ));

                pos = zero;

                //check for two boundaries case:

                if( _m.is_boundary(_m.next_halfedge_handle(heh)) || _m.is_boundary(_m.prev_halfedge_handle(heh)) )

                {

                    if(_m.is_boundary(_m.prev_halfedge_handle(heh)))

                        heh = _m.prev_halfedge_handle(heh); //ensure that the boundary halfedges are heh and heh->next

                    //check for three boundaries case:

                    if(_m.is_boundary(_m.next_halfedge_handle(_m.next_halfedge_handle(heh))))

                    {

                        //three boundaries, use COG of triangle

                        pos += real_t(1.0/3) * _m.point(_m.to_vertex_handle(heh));

                        pos += real_t(1.0/3) * _m.point(_m.to_vertex_handle(_m.next_halfedge_handle(heh)));

                        pos += real_t(1.0/3) * _m.point(_m.to_vertex_handle(_m.prev_halfedge_handle(heh)));

                    }

                    else

                    {

#ifdef MIRROR_TRIANGLES

                        //two boundaries, mirror two triangles

                        pos += real_t(2.0/9) * _m.point(_m.to_vertex_handle(heh));

                        pos += real_t(4.0/9) * _m.point(_m.to_vertex_handle(_m.next_halfedge_handle(heh)));

                        pos += real_t(4.0/9) * _m.point(_m.to_vertex_handle(_m.prev_halfedge_handle(heh)));

                        pos += real_t(-1.0/9) * _m.point(_m.to_vertex_handle(_m.next_halfedge_handle(_m.opposite_halfedge_handle(_m.prev_halfedge_handle(heh)))));

#else

                        pos += real_t(7.0/24) * _m.point(_m.to_vertex_handle(heh));

                        pos += real_t(3.0/8) * _m.point(_m.to_vertex_handle(_m.next_halfedge_handle(heh)));

                        pos += real_t(3.0/8) * _m.point(_m.to_vertex_handle(_m.prev_halfedge_handle(heh)));

                        pos += real_t(-1.0/24) * _m.point(_m.to_vertex_handle(_m.next_halfedge_handle(_m.opposite_halfedge_handle(_m.prev_halfedge_handle(heh)))));

#endif

                    }

                }

                else

                {

                    vh = _m.to_vertex_handle(_m.next_halfedge_handle(heh));

                    //check last vertex regularity

                    if((_m.valence(vh) == 6) || _m.is_boundary(vh))

                    {

#ifdef MIRROR_TRIANGLES

                        //use regular rule and mirror one triangle

                        pos += real_t(5.0/9) * _m.point(vh);

                        pos += real_t(3.0/9) * _m.point(_m.to_vertex_handle(heh));

                        pos += real_t(3.0/9) * _m.point(_m.to_vertex_handle(_m.opposite_halfedge_handle(heh)));

                        pos += real_t(-1.0/9) * _m.point(_m.to_vertex_handle(_m.next_halfedge_handle(_m.opposite_halfedge_handle(_m.next_halfedge_handle(heh)))));

                        pos += real_t(-1.0/9) * _m.point(_m.to_vertex_handle(_m.next_halfedge_handle(_m.opposite_halfedge_handle(_m.prev_halfedge_handle(heh)))));

#else

#ifdef MIN_NORM

                        pos += real_t(1.0/9) * _m.point(vh);

                        pos += real_t(1.0/3) * _m.point(_m.to_vertex_handle(heh));

                        pos += real_t(1.0/3) * _m.point(_m.to_vertex_handle(_m.opposite_halfedge_handle(heh)));

                        pos += real_t(1.0/9) * _m.point(_m.to_vertex_handle(_m.next_halfedge_handle(_m.opposite_halfedge_handle(_m.next_halfedge_handle(heh)))));

                        pos += real_t(1.0/9) * _m.point(_m.to_vertex_handle(_m.next_halfedge_handle(_m.opposite_halfedge_handle(_m.prev_halfedge_handle(heh)))));

#else

                        pos += real_t(1.0/2) * _m.point(vh);

                        pos += real_t(1.0/3) * _m.point(_m.to_vertex_handle(heh));

                        pos += real_t(1.0/3) * _m.point(_m.to_vertex_handle(_m.opposite_halfedge_handle(heh)));

                        pos += real_t(-1.0/12) * _m.point(_m.to_vertex_handle(_m.next_halfedge_handle(_m.opposite_halfedge_handle(_m.next_halfedge_handle(heh)))));

                        pos += real_t(-1.0/12) * _m.point(_m.to_vertex_handle(_m.next_halfedge_handle(_m.opposite_halfedge_handle(_m.prev_halfedge_handle(heh)))));

#endif

#endif

                    }

                    else

                    {

                        //irregular setting, use usual irregular rule

                        unsigned int K = _m.valence(vh);

                        pos += weights_[K][K]*_m.point(vh);

                        heh = _m.opposite_halfedge_handle( _m.next_halfedge_handle(heh) );

                        for(unsigned int i = 0; i<K; ++i, heh = _m.opposite_halfedge_handle(_m.prev_halfedge_handle(heh)) )

                        {

                            pos += weights_[K][i]*_m.point(_m.to_vertex_handle(heh));

                        }

                    }

                }

                vh   = _m.add_vertex( pos );

                _m.property(fp_pos_, *fit) = vh;

            }

        }

        else

        {

            pos = zero;

            int nOrdinary = 0;


            //check number of extraordinary vertices

            for(fvit = _m.fv_iter( *fit ); fvit.is_valid(); ++fvit)

                if( (_m.valence(*fvit)) == 6 || _m.is_boundary(*fvit) )

                    ++nOrdinary;


            if(nOrdinary==3)

            {

                for(fheit = _m.fh_iter( *fit ); fheit.is_valid(); ++fheit)

                {

                    //one ring vertex has weight 32/81

                    heh = *fheit;

                    assert(_m.to_vertex_handle(heh).is_valid());

                    pos += real_t(32.0/81) * _m.point(_m.to_vertex_handle(heh));

                    //tip vertex has weight -1/81

                    heh = _m.opposite_halfedge_handle(heh);

                    assert(heh.is_valid());

                    assert(_m.next_halfedge_handle(heh).is_valid());

                    assert(_m.to_vertex_handle(_m.next_halfedge_handle(heh)).is_valid());

                    pos -= real_t(1.0/81) * _m.point(_m.to_vertex_handle(_m.next_halfedge_handle(heh)));

                    //outer vertices have weight -2/81

                    heh = _m.opposite_halfedge_handle(_m.prev_halfedge_handle(heh));

                    assert(heh.is_valid());

                    assert(_m.next_halfedge_handle(heh).is_valid());

                    assert(_m.to_vertex_handle(_m.next_halfedge_handle(heh)).is_valid());

                    pos -= real_t(2.0/81) * _m.point(_m.to_vertex_handle(_m.next_halfedge_handle(heh)));

                    heh = _m.opposite_halfedge_handle(_m.prev_halfedge_handle(heh));

                    assert(heh.is_valid());

                    assert(_m.next_halfedge_handle(heh).is_valid());

                    assert(_m.to_vertex_handle(_m.next_halfedge_handle(heh)).is_valid());

                    pos -= real_t(2.0/81) * _m.point(_m.to_vertex_handle(_m.next_halfedge_handle(heh)));

                }

            }

            else

            {

                //only use irregular vertices:

                for(fheit = _m.fh_iter( *fit ); fheit.is_valid(); ++fheit)

                {

                    vh = _m.to_vertex_handle(*fheit);

                    if( (_m.valence(vh) != 6) && (!_m.is_boundary(vh)) )

                    {

                        unsigned int K = _m.valence(vh);

                        pos += weights_[K][K]*_m.point(vh);

                        heh = _m.opposite_halfedge_handle( *fheit );

                        for(unsigned int i = 0; i<K; ++i, heh = _m.opposite_halfedge_handle(_m.prev_halfedge_handle(heh)) )

                        {

                            pos += weights_[K][i]*_m.point(_m.to_vertex_handle(heh));

                        }

                    }

                }

                pos *= real_t(1.0/(3-nOrdinary));

            }


            vh   = _m.add_vertex( pos );

            _m.property(fp_pos_, *fit) = vh;

        }

      }


      //split faces

      for (fit = _m.faces_begin();fit != fend; ++fit)

      {

        if ( _m.is_boundary(*fit) && (gen%2))

        {

                boundary_split( _m, *fit );

        }

        else

        {

            assert(_m.property(fp_pos_, *fit).is_valid());

            _m.split( *fit, _m.property(fp_pos_, *fit) );

        }

      }


      // flip old edges

      for (eit=_m.edges_begin(); eit != _m.edges_end(); ++eit)

        if ( _m.status( *eit ).tagged() && !_m.is_boundary( *eit ) )

          _m.flip(*eit);


      // Now we have an consistent mesh!

      ASSERT_CONSISTENCY( MeshType, _m );


      // increase generation by one

      ++gen;

    }

    return true;

  }


private:


  // Pre-compute location of new boundary points for odd generations

  // and store them in the edge property ep_nv_;

  void compute_new_boundary_points( MeshType& _m,

                                    const typename MeshType::EdgeHandle& _eh)

  {

    assert( _m.is_boundary(_eh) );


    typename MeshType::HalfedgeHandle heh;

    typename MeshType::VertexHandle   vh1, vh2, vh3, vh4, vhl, vhr;

    typename MeshType::Point          P1, P2, P3, P4;


    /*

    //       *---------*---------*

    //      / \       / \       / \

    //     /   \     /   \     /   \

    //    /     \   /     \   /     \

    //   /       \ /       \ /       \

    //  *---------*--#---#--*---------*

    //

    //  ^         ^  ^   ^  ^         ^

    //  P1        P2 pl  pr P3        P4

    */

    // get halfedge pointing from P3 to P2 (outer boundary halfedge)


    heh = _m.halfedge_handle(_eh,

                             _m.is_boundary(_m.halfedge_handle(_eh,1)));


    assert( _m.is_boundary( _m.next_halfedge_handle( heh ) ) );

    assert( _m.is_boundary( _m.prev_halfedge_handle( heh ) ) );


    vh1 = _m.to_vertex_handle( _m.next_halfedge_handle( heh ) );

    vh2 = _m.to_vertex_handle( heh );

    vh3 = _m.from_vertex_handle( heh );

    vh4 = _m.from_vertex_handle( _m.prev_halfedge_handle( heh ));


    P1  = _m.point(vh1);

    P2  = _m.point(vh2);

    P3  = _m.point(vh3);

    P4  = _m.point(vh4);


    vhl = _m.add_vertex(real_t(-5.0/81)*P1 + real_t(20.0/27)*P2 + real_t(10.0/27)*P3 + real_t(-4.0/81)*P4);

    vhr = _m.add_vertex(real_t(-5.0/81)*P4 + real_t(20.0/27)*P3 + real_t(10.0/27)*P2 + real_t(-4.0/81)*P1);


    _m.property(ep_nv_, _eh).first  = vhl;

    _m.property(ep_nv_, _eh).second = vhr;

  }


  void boundary_split( MeshType& _m, const typename MeshType::FaceHandle& _fh )

  {

    assert( _m.is_boundary(_fh) );


    typename MeshType::VertexHandle     vhl, vhr;

    typename MeshType::FaceEdgeIter     fe_it;

    typename MeshType::HalfedgeHandle   heh;


    // find boundary edge

    for( fe_it=_m.fe_iter( _fh ); fe_it.is_valid() && !_m.is_boundary( *fe_it ); ++fe_it ) {};


    // use precomputed, already inserted but not linked vertices

    vhl = _m.property(ep_nv_, *fe_it).first;

    vhr = _m.property(ep_nv_, *fe_it).second;


    /*

    //       *---------*---------*

    //      / \       / \       / \

    //     /   \     /   \     /   \

    //    /     \   /     \   /     \

    //   /       \ /       \ /       \

    //  *---------*--#---#--*---------*

    //

    //  ^         ^  ^   ^  ^         ^

    //  P1        P2 pl  pr P3        P4

    */

    // get halfedge pointing from P2 to P3 (inner boundary halfedge)


    heh = _m.halfedge_handle(*fe_it, _m.is_boundary(_m.halfedge_handle(*fe_it,0)));


    typename MeshType::HalfedgeHandle pl_P3;


    // split P2->P3 (heh) in P2->pl (heh) and pl->P3

    boundary_split( _m, heh, vhl );         // split edge

    pl_P3 = _m.next_halfedge_handle( heh ); // store next halfedge handle

    boundary_split( _m, heh );              // split face


    // split pl->P3 in pl->pr and pr->P3

    boundary_split( _m, pl_P3, vhr );

    boundary_split( _m, pl_P3 );


    assert( _m.is_boundary( vhl ) && _m.halfedge_handle(vhl).is_valid() );

    assert( _m.is_boundary( vhr ) && _m.halfedge_handle(vhr).is_valid() );

  }


  void boundary_split(MeshType& _m,

                      const typename MeshType::HalfedgeHandle& _heh,

                      const typename MeshType::VertexHandle& _vh)

  {

    assert( _m.is_boundary( _m.edge_handle(_heh) ) );


    typename MeshType::HalfedgeHandle

      heh(_heh),

      opp_heh( _m.opposite_halfedge_handle(_heh) ),

      new_heh, opp_new_heh;

    typename MeshType::VertexHandle   to_vh(_m.to_vertex_handle(heh));

    typename MeshType::HalfedgeHandle t_heh;


    /*

     *            P5

     *             *

     *            /|\

     *           /   \

     *          /     \

     *         /       \

     *        /         \

     *       /_ heh  new \

     *      *-----\*-----\*\-----*

     *             ^      ^ t_heh

     *            _vh     to_vh

     *

     *     P1     P2     P3     P4

     */

    // Re-Setting Handles


    // find halfedge point from P4 to P3

    for(t_heh = heh;

        _m.next_halfedge_handle(t_heh) != opp_heh;

        t_heh = _m.opposite_halfedge_handle(_m.next_halfedge_handle(t_heh)))

    {}


    assert( _m.is_boundary( t_heh ) );


    new_heh     = _m.new_edge( _vh, to_vh );

    opp_new_heh = _m.opposite_halfedge_handle(new_heh);


    // update halfedge connectivity

    _m.set_next_halfedge_handle(t_heh,   opp_new_heh);                  // P4-P3 -> P3-P2

    _m.set_next_halfedge_handle(new_heh, _m.next_halfedge_handle(heh)); // P2-P3 -> P3-P5

    _m.set_next_halfedge_handle(heh,         new_heh);                  // P1-P2 -> P2-P3

    _m.set_next_halfedge_handle(opp_new_heh, opp_heh);                  // P3-P2 -> P2-P1


    // both opposite halfedges point to same face

    _m.set_face_handle(opp_new_heh, _m.face_handle(opp_heh));


    // let heh finally point to new inserted vertex

    _m.set_vertex_handle(heh, _vh);


    // let heh and new_heh point to same face

    _m.set_face_handle(new_heh, _m.face_handle(heh));


    // let opp_new_heh be the new outgoing halfedge for to_vh

    // (replaces for opp_heh)

    _m.set_halfedge_handle( to_vh, opp_new_heh );


    // let opp_heh be the outgoing halfedge for _vh

    _m.set_halfedge_handle( _vh, opp_heh );

  }


  void boundary_split( MeshType& _m,

                       const typename MeshType::HalfedgeHandle& _heh)

  {

    assert( _m.is_boundary( _m.opposite_halfedge_handle( _heh ) ) );


    typename MeshType::HalfedgeHandle

      heh(_heh),

      n_heh(_m.next_halfedge_handle(heh));


    typename MeshType::VertexHandle

      to_vh(_m.to_vertex_handle(heh));


    typename MeshType::HalfedgeHandle

      heh2(_m.new_edge(to_vh,

                       _m.to_vertex_handle(_m.next_halfedge_handle(n_heh)))),

      heh3(_m.opposite_halfedge_handle(heh2));


    typename MeshType::FaceHandle

      new_fh(_m.new_face()),

      fh(_m.face_handle(heh));


    // Relink (half)edges

    _m.set_face_handle(heh,  new_fh);

    _m.set_face_handle(heh2, new_fh);

    _m.set_next_halfedge_handle(heh2, _m.next_halfedge_handle(_m.next_halfedge_handle(n_heh)));

    _m.set_next_halfedge_handle(heh,  heh2);

    _m.set_face_handle( _m.next_halfedge_handle(heh2), new_fh);


    _m.set_next_halfedge_handle(heh3,                           n_heh);

    _m.set_next_halfedge_handle(_m.next_halfedge_handle(n_heh), heh3);

    _m.set_face_handle(heh3,  fh);


    _m.set_halfedge_handle(    fh, n_heh);

    _m.set_halfedge_handle(new_fh, heh);


  }


private:


  weights_t     weights_;

  OpenMesh::FPropHandleT< typename MeshType::VertexHandle >             fp_pos_;

  OpenMesh::EPropHandleT< std::pair< typename MeshType::VertexHandle,

                                     typename MeshType::VertexHandle> > ep_nv_;

  OpenMesh::MPropHandleT< size_t >                                      mp_gen_;

};


//=============================================================================

} // END_NS_UNIFORM

} // END_NS_SUBDIVIDER

} // END_NS_OPENMESH

//=============================================================================

#endif // OPENMESH_SUBDIVIDER_UNIFORM_SQRT3T_HH

//=============================================================================

SubdividerT.hh

OpenMesh
Contains all the mesh ingredients like the polygonal mesh, the triangle mesh, different mesh kernels ...
Definition: MeshItems.hh:59

OpenMesh::BaseHandle::is_valid
bool is_valid() const
The handle is valid iff the index is not negative.
Definition: Handles.hh:72

OpenMesh::EPropHandleT
Handle representing an edge property.
Definition: Property.hh:447

OpenMesh::FPropHandleT< typename MeshType::VertexHandle >

OpenMesh::MPropHandleT< size_t >

OpenMesh::Subdivider::Uniform::InterpolatingSqrt3LGT
Uniform Interpolating Sqrt3 subdivision algorithm
Definition: Sqrt3InterpolatingSubdividerLabsikGreinerT.hh:107

OpenMesh::Subdivider::Uniform::InterpolatingSqrt3LGT::cleanup
bool cleanup(MeshType &_m) override
Cleanup mesh after usage, e.g. remove added properties.
Definition: Sqrt3InterpolatingSubdividerLabsikGreinerT.hh:186

OpenMesh::Subdivider::Uniform::InterpolatingSqrt3LGT::name
const char * name() const override
Return name of subdivision algorithm.
Definition: Sqrt3InterpolatingSubdividerLabsikGreinerT.hh:131

OpenMesh::Subdivider::Uniform::InterpolatingSqrt3LGT::subdivide
bool subdivide(MeshType &_m, size_t _n, const bool _update_points=true) override
Subdivide mesh _m _n times.
Definition: Sqrt3InterpolatingSubdividerLabsikGreinerT.hh:196

OpenMesh::Subdivider::Uniform::InterpolatingSqrt3LGT::prepare
bool prepare(MeshType &_m) override
Prepare mesh, e.g. add properties.
Definition: Sqrt3InterpolatingSubdividerLabsikGreinerT.hh:173

OpenMesh::Subdivider::Uniform::InterpolatingSqrt3LGT::init_weights
void init_weights(size_t _max_valence=50)
Pre-compute weights.
Definition: Sqrt3InterpolatingSubdividerLabsikGreinerT.hh:134

OpenMesh::Subdivider::Uniform::SubdividerT
Abstract base class for uniform subdivision algorithms.
Definition: SubdividerT.hh:89