Documentation/OpenFlipper-3.1/a01736_source.html

 #include <iostream>
 #include <string>
 #include <map>
 // -------------------- OpenMesh
 #include <OpenMesh/Core/IO/MeshIO.hh>
 #include <OpenMesh/Core/Mesh/TriMesh_ArrayKernelT.hh>
 #include <OpenMesh/Core/Mesh/PolyMesh_ArrayKernelT.hh>
 // -------------------- little helper
 #include "generate_cube.hh"
 #include "stats.hh"
 #include "fill_props.hh"

 // ----------------------------------------------------------------------------

 // Set to 1 to use an PolyMesh type.
 #define UsePolyMesh 1

 // ----------------------------------------------------------------------------

 using namespace OpenMesh;

 // ----------------------------------------------------------------------------

 typedef TriMesh_ArrayKernelT<>  TriMesh;
 typedef PolyMesh_ArrayKernelT<> PolyMesh;

 #if UsePolyMesh
 typedef PolyMesh Mesh;
 #else
 typedef TriMesh Mesh;
 #endif

 // ----------------------------------------------------------------------------

 #ifndef DOXY_IGNORE_THIS

 struct MyData
 {
   int             ival;
   double          dval;
   bool            bval;
   OpenMesh::Vec4f vec4fval;

   MyData()
     : ival(0), dval(0.0), bval(false)
   { }

   MyData( const MyData& _cpy )
     : ival(_cpy.ival), dval(_cpy.dval), bval(_cpy.bval),
       vec4fval(_cpy.vec4fval)
   { }


   // ---------- assignment

   MyData& operator = (const MyData& _rhs)
   {
     ival = _rhs.ival;
     dval = _rhs.dval;
     bval = _rhs.bval;
     vec4fval = _rhs.vec4fval;
     return *this;
   }

   MyData& operator = (int    _rhs) { ival = _rhs; return *this; }
   MyData& operator = (double _rhs) { dval = _rhs; return *this; }
   MyData& operator = (bool   _rhs) { bval = _rhs; return *this; }
   MyData& operator = (const OpenMesh::Vec4f& _rhs)
   { vec4fval = _rhs; return *this; }


   // ---------- comparison

   bool operator == (const MyData& _rhs) const
   {
     return ival == _rhs.ival
       &&   dval == _rhs.dval
       &&   bval == _rhs.bval
       &&   vec4fval == _rhs.vec4fval;
   }

   bool operator != (const MyData& _rhs) const { return !(*this == _rhs); }

 };

 #endif


 // ----------------------------------------------------------------------------

 typedef std::map< std::string, unsigned int > MyMap;


 // ----------------------------------------------------------------------------

 #ifndef DOXY_IGNORE_THIS

 namespace OpenMesh {
   namespace IO {

     // support persistence for struct MyData

     template <> struct binary<MyData>
     {
       typedef MyData value_type;

       static const bool is_streamable = true;

       // return binary size of the value

       static size_t size_of(void)
       {
         return sizeof(int)+sizeof(double)+sizeof(bool)+sizeof(OpenMesh::Vec4f);
       }

       static size_t size_of(const value_type&)
       {
         return size_of();
       }

       static size_t store(std::ostream& _os, const value_type& _v, bool _swap=false)
       {
         size_t bytes;
         bytes  = IO::store( _os, _v.ival, _swap );
         bytes += IO::store( _os, _v.dval, _swap );
         bytes += IO::store( _os, _v.bval, _swap );
         bytes += IO::store( _os, _v.vec4fval, _swap );
         return _os.good() ? bytes : 0;
       }

       static size_t restore( std::istream& _is, value_type& _v, bool _swap=false)
       {
         size_t bytes;
         bytes  = IO::restore( _is, _v.ival, _swap );
         bytes += IO::restore( _is, _v.dval, _swap );
         bytes += IO::restore( _is, _v.bval, _swap );
         bytes += IO::restore( _is, _v.vec4fval, _swap );
         return _is.good() ? bytes : 0;
       }
     };


     template <> struct binary< MyMap >
     {
       typedef MyMap value_type;

       static const bool is_streamable = true;

       // return generic binary size of self, if known
       static size_t size_of(void) { return UnknownSize; }

       // return binary size of the value
       static size_t size_of(const value_type& _v)
       {
         if (_v.empty())
           return sizeof(unsigned int);

         value_type::const_iterator it = _v.begin();
         unsigned int   N     = _v.size();
         size_t         bytes = IO::size_of(N);

         for(;it!=_v.end(); ++it)
         {
           bytes += IO::size_of( it->first );
           bytes += IO::size_of( it->second );
         }
         return bytes;
       }

       static
       size_t store(std::ostream& _os, const value_type& _v, bool _swap=false)
       {
         size_t   bytes = 0;
         unsigned int N = _v.size();

         value_type::const_iterator it = _v.begin();

         bytes += IO::store( _os, N, _swap );

         for (; it != _v.end() && _os.good(); ++it)
         {
           bytes += IO::store( _os, it->first, _swap );
           bytes += IO::store( _os, it->second, _swap );
         }
         return _os.good() ? bytes : 0;
       }

       static
       size_t restore( std::istream& _is, value_type& _v, bool _swap=false)
       {
         size_t   bytes = 0;
         unsigned int N = 0;

         _v.clear();

         bytes += IO::restore( _is, N, _swap );
         value_type::key_type key;
         value_type::mapped_type  val;

         for (size_t i=0; i<N && _is.good(); ++i)
         {
           bytes += IO::restore( _is, key, _swap );
           bytes += IO::restore( _is, val, _swap );
           _v[key] = val;
         }
         return _is.good() ? bytes : 0;
       }
     };

   }
 }

 #endif


 // ----------------------------------------------------------------------------

 int main(void)
 {
   //
   Mesh mesh;


   // generate a geometry
   generate_cube<Mesh>(mesh);


   // should display 8 vertices, 18/12 edges, 12/6 faces (Tri/Poly)
   mesh_stats(mesh);


   // print out information about properties
   mesh_property_stats(mesh);


   std::cout << "Define some custom properties..\n";

   OpenMesh::VPropHandleT<float>       vprop_float;
   OpenMesh::EPropHandleT<bool>        eprop_bool;
   OpenMesh::FPropHandleT<std::string> fprop_string;
   OpenMesh::HPropHandleT<MyData>      hprop_mydata;
   OpenMesh::MPropHandleT<MyMap>       mprop_map;

   std::cout << ".. and registrate them at the mesh object.\n";

   mesh.add_property(vprop_float,  "vprop_float");
   mesh.add_property(eprop_bool,   "eprop_bool");
   mesh.add_property(fprop_string, "fprop_string");
   mesh.add_property(hprop_mydata, "hprop_mydata");
   mesh.add_property(mprop_map,    "mprop_map");


   mesh_property_stats(mesh);


   std::cout << "Now let's fill the props..\n";

   fill_props(mesh, vprop_float);
   fill_props(mesh, eprop_bool);
   fill_props(mesh, fprop_string);
   fill_props(mesh, hprop_mydata);
   fill_props(mesh, mprop_map);


   std::cout << "Check props..\n";
 #define CHK_PROP( PH ) \
   std::cout << "  " << #PH << " " \
             << (fill_props(mesh, PH, true)?"ok\n":"error\n")

   CHK_PROP(vprop_float);
   CHK_PROP(eprop_bool);
   CHK_PROP(fprop_string);
   CHK_PROP(hprop_mydata);
   CHK_PROP(mprop_map);
 #undef CHK_PROP


   std::cout << "Set persistent flag..\n";
 #define SET_PERS( PH ) \
     mesh.property(PH).set_persistent(true); \
     std::cout << "  " << #PH << " " \
               << (mesh.property(PH).persistent()?"ok\n":"failed!\n")

   mesh.property(vprop_float).set_persistent(true);
   std::cout << "  vprop_float "
             << (mesh.property(vprop_float).persistent()?"ok\n":"failed!\n");

   SET_PERS( eprop_bool );
   SET_PERS( fprop_string );
   SET_PERS( hprop_mydata );
   mesh.mproperty(mprop_map).set_persistent(true);
   std::cout << "  mprop_map "
             << (mesh.mproperty(mprop_map).persistent()?"ok\n":"failed!\n");


   std::cout << "Write mesh..";
   if (IO::write_mesh( mesh, "persistence-check.om" ))
     std::cout << "  ok\n";
   else
   {
     std::cout << "  failed\n";
     return 1;
   }


   std::cout << "Clear mesh\n";
   mesh.clear();
   mesh_stats(mesh, "  ");


   std::cout << "Read back mesh..";
   try
   {
     if (IO::read_mesh( mesh, "persistence-check.om" ))
       std::cout << "  ok\n";
     else
     {
       std::cout << "  failed!\n";
       return 1;
     }
     mesh_stats(mesh, "  ");
   }
   catch( std::exception &x )
   {
     std::cerr << x.what() << std::endl;
     return 1;
   }


   std::cout << "Check props..\n";
 #define CHK_PROP( PH ) \
   std::cout << "  " << #PH << " " \
             << (fill_props(mesh, PH, true)?"ok\n":"error\n")
   CHK_PROP(vprop_float);
   CHK_PROP(eprop_bool);
   CHK_PROP(fprop_string);
   CHK_PROP(hprop_mydata);
   CHK_PROP(mprop_map);
 #undef CHK_PROP

   return 0;
 }

 // end of file
 // ============================================================================
OpenMesh::EPropHandleT
Definition: Property.hh:515

OpenMesh::MPropHandleT
Definition: Property.hh:543

OpenMesh::VPropHandleT< float >

MyData
Definition: unittests_tutorials.cc:15

OpenMesh::IO::size_of
size_t size_of(const T &_v)
Definition: StoreRestore.hh:94

OpenMesh::PolyMesh_ArrayKernelT
Definition: PolyMesh_ArrayKernelT.hh:98

OpenMesh
Definition: MeshItems.hh:64

OpenMesh::VectorT< float, 4 >

PolyMesh
OpenMesh::PolyMesh_ArrayKernelT< PolyTraits > PolyMesh
Simple Name for Mesh.
Definition: PolyMeshTypes.hh:90

OpenMesh::IO::read_mesh
bool read_mesh(Mesh &_mesh, const std::string &_filename)
Read a mesh from file _filename.
Definition: MeshIO.hh:104

OpenMesh::TriMesh_ArrayKernelT
Definition: TriMesh_ArrayKernelT.hh:98

TriMesh
OpenMesh::TriMesh_ArrayKernelT< TriTraits > TriMesh
Simple Name for Mesh.
Definition: TriangleMeshTypes.hh:90

OpenMesh::HPropHandleT
Definition: Property.hh:501

OpenMesh::FPropHandleT
Definition: Property.hh:529

OpenMesh::IO::write_mesh
bool write_mesh(const Mesh &_mesh, const std::string &_filename, Options _opt=Options::Default, std::streamsize _precision=6)
Write a mesh to the file _filename.
Definition: MeshIO.hh:199