openmesh/Tools/Subdivider/Uniform/Composite/CompositeT.hh

//=============================================================================
//                                                                            
//                               OpenMesh                                     
//        Copyright (C) 2003 by Computer Graphics Group, RWTH Aachen          
//                           www.openmesh.org                                 
//                                                                            
//-----------------------------------------------------------------------------
//                                                                            
//                                License                                     
//                                                                            
//   This library is free software; you can redistribute it and/or modify it 
//   under the terms of the GNU Lesser General Public License as published   
//   by the Free Software Foundation, version 2.1.                           
//                                                                             
//   This library is distributed in the hope that it will be useful, but       
//   WITHOUT ANY WARRANTY; without even the implied warranty of                
//   MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the GNU         
//   Lesser General Public License for more details.                           
//                                                                            
//   You should have received a copy of the GNU Lesser General Public          
//   License along with this library; if not, write to the Free Software       
//   Foundation, Inc., 675 Mass Ave, Cambridge, MA 02139, USA.                 
//                                                                            
//-----------------------------------------------------------------------------
//                                                                            
//   $Revision: 1802 $
//   $Date: 2008-05-19 11:55:07 +0200 (Mo, 19. Mai 2008) $
//                                                                            
//=============================================================================

/** \file Uniform/Composite/CompositeT.hh
    
 */

//=============================================================================
//
//  CLASS CompositeT
//
//=============================================================================

#ifndef OPENMESH_SUBDIVIDER_UNIFORM_COMPOSITE_HH
#define OPENMESH_SUBDIVIDER_UNIFORM_COMPOSITE_HH


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

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

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

namespace OpenMesh   { // BEGIN_NS_OPENMESH
namespace Subdivider { // BEGIN_NS_DECIMATER
namespace Uniform    { // BEGIN_NS_UNIFORM


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

/** This class provides the composite subdivision rules for the uniform case.
 *
 *  To create a subdivider derive from this class and overload the functions
 *  name() and apply_rules(). In the latter one call the wanted rules.
 *
 *  For details on the composite scheme refer to
 *  - <a
 *  href="http://cm.bell-labs.com/who/poswald/sqrt3.pdf">P. Oswald,
 *  P. Schroeder "Composite primal/dual sqrt(3)-subdivision schemes",
 *  CAGD 20, 3, 2003, 135--164</a>

 *  \note Not all rules are implemented!
 *  \see class Adaptive::CompositeT
 */
template <typename MeshType, typename RealType=float > 
class CompositeT : public SubdividerT< MeshType, RealType >
{
public:

  typedef RealType                                real_t;
  typedef MeshType                                mesh_t;
  typedef SubdividerT< mesh_t, real_t >           parent_t;

public:

  CompositeT(void) : parent_t(), p_mesh_(NULL) {}
  CompositeT(MeshType& _mesh) : parent_t(_mesh), p_mesh_(NULL) {};
  virtual ~CompositeT() { }

public: // inherited interface

  virtual const char *name( void ) const = 0;

protected: // inherited interface

  bool prepare( MeshType& _m );

  bool subdivide( MeshType& _m, size_t _n )
  {
    assert( p_mesh_ == &_m );

    while(_n--)
    {
      apply_rules();
      commit(_m);
    }
   
    return true;
  }

#ifdef NDEBUG
  bool cleanup( MeshType& ) 
#else
  bool cleanup( MeshType& _m ) 
#endif
  { 
    assert( p_mesh_ == &_m );
    p_mesh_=NULL; 
    return true; 
  }

protected:

  /// Assemble here the rule sequence, by calling the constructor
  /// of the wanted rules.
  virtual void apply_rules(void) = 0;

protected:

  /// Move vertices to new positions after the rules have been applied
  /// to the mesh (called by subdivide()).
  void commit( MeshType &_m)
  {
    typename MeshType::VertexIter v_it;

    for (v_it=_m.vertices_begin(); v_it != _m.vertices_end(); ++v_it)
      _m.set_point(v_it.handle(), _m.data(v_it).position());
  }

  
public:

  /// Abstract base class for coefficient functions
  struct Coeff
  {
    virtual ~Coeff() { }
    virtual double operator() (size_t _valence) = 0;
  };


protected:

  typedef typename MeshType::Scalar         scalar_t;
  typedef typename MeshType::VertexHandle   VertexHandle;
  typedef typename MeshType::FaceHandle     FaceHandle;
  typedef typename MeshType::EdgeHandle     EdgeHandle;
  typedef typename MeshType::HalfedgeHandle HalfedgeHandle;

  /// \name Uniform composite subdivision rules
  //@{

  
  void Tvv3(); ///< Split Face, using Vertex information (1-3 split)
  void Tvv4(); ///< Split Face, using Vertex information (1-4 split)
  void Tfv();  ///< Split Face, using Face Information

  void FF();                 ///< Face to face averaging.
  void FFc(Coeff& _coeff);   ///< Weighted face to face averaging.
  void FFc(scalar_t _c);     ///< Weighted face to face averaging.

  void FV();                 ///< Face to vertex averaging.
  void FVc(Coeff& _coeff);   ///< Weighted face to vertex Averaging with flaps 
  void FVc(scalar_t _c);     ///< Weighted face to vertex Averaging with flaps 

  void FE();                 ///< Face to edge averaging.

  void VF();                 ///< Vertex to Face Averaging.
  void VFa(Coeff& _coeff);   ///< Vertex to Face Averaging, weighted.
  void VFa(scalar_t _alpha); ///< Vertex to Face Averaging, weighted.

  void VV();                  ///< Vertex to vertex averaging.
  void VVc(Coeff& _coeff);    ///< Vertex to vertex averaging, weighted.
  void VVc(scalar_t _c);      ///< Vertex to vertex averaging, weighted.

  void VE();                  ///< VE Step (Vertex to Edge Averaging)

  
  void VdE();             ///< Vertex to edge averaging, using diamond of edges.
  void VdEc(scalar_t _c); ///< Weighted vertex to edge averaging, using diamond of edges
  
  /// Weigthed vertex to edge averaging, using diamond of edges for
  /// irregular vertices.
  void VdEg(Coeff& _coeff);
  /// Weigthed vertex to edge averaging, using diamond of edges for
  /// irregular vertices.
  void VdEg(scalar_t _gamma);

  void EF();               ///< Edge to face averaging.
  
  void EV();               ///< Edge to vertex averaging.
  void EVc(Coeff& _coeff); ///< Weighted edge to vertex averaging.
  void EVc(scalar_t _c);   ///< Weighted edge to vertex averaging.

  void EdE();              ///< Edge to edge averaging w/ flap rule.
  void EdEc(scalar_t _c);  ///< Weighted edge to edge averaging w/ flap rule.


  //@}

  void corner_cutting(HalfedgeHandle _heh);

  VertexHandle split_edge(HalfedgeHandle _heh);

private:

  MeshType* p_mesh_;

};


//=============================================================================
} // END_NS_UNIFORM
} // END_NS_SUBDIVIDER
} // END_NS_OPENMESH
//=============================================================================
#if defined(OM_INCLUDE_TEMPLATES) && !defined(OPENMESH_SUBDIVIDER_UNIFORM_COMPOSITE_CC)
#define OPENMESH_SUBDIVIDER_TEMPLATES
#include "CompositeT.cc"
#endif
//=============================================================================
#endif // COMPOSITET_HH defined
//=============================================================================
First checkin for OpenMesh 2.0 git-svn-id: http://www.openmesh.org/svnrepo/OpenMesh/trunk@2 fdac6126-5c0c-442c-9429-916003d36597 2009-02-06 13:37:46 +00:00			`//=============================================================================`
			`//`
			`// OpenMesh`
			`// Copyright (C) 2003 by Computer Graphics Group, RWTH Aachen`
			`// www.openmesh.org`
			`//`
			`//-----------------------------------------------------------------------------`
			`//`
			`// License`
			`//`
			`// This library is free software; you can redistribute it and/or modify it`
			`// under the terms of the GNU Lesser General Public License as published`
			`// by the Free Software Foundation, version 2.1.`
			`//`
			`// This library is distributed in the hope that it will be useful, but`
			`// WITHOUT ANY WARRANTY; without even the implied warranty of`
			`// MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU`
			`// Lesser General Public License for more details.`
			`//`
			`// You should have received a copy of the GNU Lesser General Public`
			`// License along with this library; if not, write to the Free Software`
			`// Foundation, Inc., 675 Mass Ave, Cambridge, MA 02139, USA.`
			`//`
			`//-----------------------------------------------------------------------------`
			`//`
			`// $Revision: 1802 $`
			`// $Date: 2008-05-19 11:55:07 +0200 (Mo, 19. Mai 2008) $`
			`//`
			`//=============================================================================`

			`/** \file Uniform/Composite/CompositeT.hh`

			`*/`

			`//=============================================================================`
			`//`
			`// CLASS CompositeT`
			`//`
			`//=============================================================================`

			`#ifndef OPENMESH_SUBDIVIDER_UNIFORM_COMPOSITE_HH`
			`#define OPENMESH_SUBDIVIDER_UNIFORM_COMPOSITE_HH`


			`//== INCLUDES =================================================================`

			`#include <string>`
			`#include <vector>`
			`// --------------------`
			`#include <OpenMesh/Tools/Subdivider/Uniform/SubdividerT.hh>`

			`//== NAMESPACE ================================================================`

			`namespace OpenMesh { // BEGIN_NS_OPENMESH`
			`namespace Subdivider { // BEGIN_NS_DECIMATER`
			`namespace Uniform { // BEGIN_NS_UNIFORM`


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

			`/** This class provides the composite subdivision rules for the uniform case.`
			`*`
			`* To create a subdivider derive from this class and overload the functions`
			`* name() and apply_rules(). In the latter one call the wanted rules.`
			`*`
			`* For details on the composite scheme refer to`
			`* - <a`
			`* href="http://cm.bell-labs.com/who/poswald/sqrt3.pdf">P. Oswald,`
			`* P. Schroeder "Composite primal/dual sqrt(3)-subdivision schemes",`
			`* CAGD 20, 3, 2003, 135--164</a>`

			`* \note Not all rules are implemented!`
			`* \see class Adaptive::CompositeT`
			`*/`
			`template <typename MeshType, typename RealType=float >`
			`class CompositeT : public SubdividerT< MeshType, RealType >`
			`{`
			`public:`

			`typedef RealType real_t;`
			`typedef MeshType mesh_t;`
			`typedef SubdividerT< mesh_t, real_t > parent_t;`

			`public:`

			`CompositeT(void) : parent_t(), p_mesh_(NULL) {}`
			`CompositeT(MeshType& _mesh) : parent_t(_mesh), p_mesh_(NULL) {};`
			`virtual ~CompositeT() { }`

			`public: // inherited interface`

			`virtual const char *name( void ) const = 0;`

			`protected: // inherited interface`

			`bool prepare( MeshType& _m );`

			`bool subdivide( MeshType& _m, size_t _n )`
			`{`
			`assert( p_mesh_ == &_m );`

			`while(_n--)`
			`{`
			`apply_rules();`
			`commit(_m);`
			`}`

			`return true;`
			`}`

			`#ifdef NDEBUG`
			`bool cleanup( MeshType& )`
			`#else`
			`bool cleanup( MeshType& _m )`
			`#endif`
			`{`
			`assert( p_mesh_ == &_m );`
			`p_mesh_=NULL;`
			`return true;`
			`}`

			`protected:`

			`/// Assemble here the rule sequence, by calling the constructor`
			`/// of the wanted rules.`
			`virtual void apply_rules(void) = 0;`

			`protected:`

			`/// Move vertices to new positions after the rules have been applied`
			`/// to the mesh (called by subdivide()).`
			`void commit( MeshType &_m)`
			`{`
			`typename MeshType::VertexIter v_it;`

			`for (v_it=_m.vertices_begin(); v_it != _m.vertices_end(); ++v_it)`
			`_m.set_point(v_it.handle(), _m.data(v_it).position());`
			`}`


			`public:`

			`/// Abstract base class for coefficient functions`
			`struct Coeff`
			`{`
			`virtual ~Coeff() { }`
			`virtual double operator() (size_t _valence) = 0;`
			`};`


			`protected:`

			`typedef typename MeshType::Scalar scalar_t;`
			`typedef typename MeshType::VertexHandle VertexHandle;`
			`typedef typename MeshType::FaceHandle FaceHandle;`
			`typedef typename MeshType::EdgeHandle EdgeHandle;`
			`typedef typename MeshType::HalfedgeHandle HalfedgeHandle;`

			`/// \name Uniform composite subdivision rules`
			`//@{`


			`void Tvv3(); ///< Split Face, using Vertex information (1-3 split)`
			`void Tvv4(); ///< Split Face, using Vertex information (1-4 split)`
			`void Tfv(); ///< Split Face, using Face Information`

			`void FF(); ///< Face to face averaging.`
			`void FFc(Coeff& _coeff); ///< Weighted face to face averaging.`
			`void FFc(scalar_t _c); ///< Weighted face to face averaging.`

			`void FV(); ///< Face to vertex averaging.`
			`void FVc(Coeff& _coeff); ///< Weighted face to vertex Averaging with flaps`
			`void FVc(scalar_t _c); ///< Weighted face to vertex Averaging with flaps`

			`void FE(); ///< Face to edge averaging.`

			`void VF(); ///< Vertex to Face Averaging.`
			`void VFa(Coeff& _coeff); ///< Vertex to Face Averaging, weighted.`
			`void VFa(scalar_t _alpha); ///< Vertex to Face Averaging, weighted.`

			`void VV(); ///< Vertex to vertex averaging.`
			`void VVc(Coeff& _coeff); ///< Vertex to vertex averaging, weighted.`
			`void VVc(scalar_t _c); ///< Vertex to vertex averaging, weighted.`

			`void VE(); ///< VE Step (Vertex to Edge Averaging)`


			`void VdE(); ///< Vertex to edge averaging, using diamond of edges.`
			`void VdEc(scalar_t _c); ///< Weighted vertex to edge averaging, using diamond of edges`

			`/// Weigthed vertex to edge averaging, using diamond of edges for`
			`/// irregular vertices.`
			`void VdEg(Coeff& _coeff);`
			`/// Weigthed vertex to edge averaging, using diamond of edges for`
			`/// irregular vertices.`
			`void VdEg(scalar_t _gamma);`

			`void EF(); ///< Edge to face averaging.`

			`void EV(); ///< Edge to vertex averaging.`
			`void EVc(Coeff& _coeff); ///< Weighted edge to vertex averaging.`
			`void EVc(scalar_t _c); ///< Weighted edge to vertex averaging.`

			`void EdE(); ///< Edge to edge averaging w/ flap rule.`
			`void EdEc(scalar_t _c); ///< Weighted edge to edge averaging w/ flap rule.`


			`//@}`

			`void corner_cutting(HalfedgeHandle _heh);`

			`VertexHandle split_edge(HalfedgeHandle _heh);`

			`private:`

			`MeshType* p_mesh_;`

			`};`


			`//=============================================================================`
			`} // END_NS_UNIFORM`
			`} // END_NS_SUBDIVIDER`
			`} // END_NS_OPENMESH`
			`//=============================================================================`
			`#if defined(OM_INCLUDE_TEMPLATES) && !defined(OPENMESH_SUBDIVIDER_UNIFORM_COMPOSITE_CC)`
			`#define OPENMESH_SUBDIVIDER_TEMPLATES`
			`#include "CompositeT.cc"`
			`#endif`
			`//=============================================================================`
			`#endif // COMPOSITET_HH defined`
			`//=============================================================================`