Property.hh

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//#ifndef OPENMESH_PROPERTY_HH
//#define OPENMESH_PROPERTY_HH
#pragma once
 
//== INCLUDES =================================================================
 
 
#include <OpenMesh/Core/System/config.h>
#include <OpenMesh/Core/Mesh/Handles.hh>
#include <OpenMesh/Core/Utils/BaseProperty.hh>
#include <vector>
#include <string>
#include <algorithm>
 
#include <OpenMesh/Core/IO/SR_store.hh>
#include <iostream>
 
 
//== NAMESPACES ===============================================================
 
namespace OpenMesh {
 
//== CLASS DEFINITION =========================================================
 
// TODO: it might be possible to define Property using kind of a runtime info
// structure holding the size of T. Then reserve, swap, resize, etc can be written
// in pure malloc() style w/o virtual overhead. Template member function proved per
// element access to the properties, asserting dynamic_casts in debug
 
template <class T>
class PropertyT : public BaseProperty
{
public:
 
  typedef T                                       Value;
  typedef std::vector<T>                          vector_type;
  typedef T                                       value_type;
  typedef typename vector_type::reference         reference;
  typedef typename vector_type::const_reference   const_reference;
 
public:
 
  explicit PropertyT(
            const std::string& _name = "<unknown>",
            const std::string& _internal_type_name = "<unknown>")
  : BaseProperty(_name, _internal_type_name)
  {}
 
  PropertyT(const PropertyT & _rhs)
      : BaseProperty( _rhs ), data_( _rhs.data_ ) {}
 
public: // inherited from BaseProperty
 
  virtual void reserve(size_t _n) override { data_.reserve(_n);    }
  virtual void resize(size_t _n) override  { data_.resize(_n);     }
  virtual void clear() override  { data_.clear(); vector_type().swap(data_);    }
  virtual void push_back() override        { data_.emplace_back(); }
  virtual void swap(size_t _i0, size_t _i1) override
  { std::swap(data_[_i0], data_[_i1]); }
  virtual void copy(size_t _i0, size_t _i1) override
  { data_[_i1] = data_[_i0]; }
 
public:
 
  virtual void set_persistent( bool _yn ) override
  { check_and_set_persistent<T>( _yn ); }
 
  virtual size_t       n_elements()   const override { return data_.size(); }
  virtual size_t       element_size() const override { return IO::size_of<T>(); }
 
#ifndef DOXY_IGNORE_THIS
  struct plus {
    size_t operator () ( size_t _b, const T& _v )
    { return _b + IO::size_of<T>(_v); }
  };
#endif
 
  virtual size_t size_of(void) const override
  {
    if (element_size() != IO::UnknownSize)
      return this->BaseProperty::size_of(n_elements());
    return std::accumulate(data_.begin(), data_.end(), size_t(0), plus());
  }
 
  virtual size_t size_of(size_t _n_elem) const override
  { return this->BaseProperty::size_of(_n_elem); }
 
  virtual size_t store( std::ostream& _ostr, bool _swap ) const override
  {
    if (IO::is_streamable<vector_type>() && element_size() != IO::UnknownSize)
      return IO::store(_ostr, data_, _swap, false);   //does not need to store its length
 
    size_t bytes = 0;
    for (size_t i=0; i<n_elements(); ++i)
      bytes += IO::store( _ostr, data_[i], _swap);
    return bytes;
  }
 
  virtual size_t restore( std::istream& _istr, bool _swap ) override
  {
    if ( IO::is_streamable<vector_type>() && element_size() != IO::UnknownSize)
      return IO::restore(_istr, data_, _swap, false);  //does not need to restore its length
 
    size_t bytes = 0;
    for (size_t i=0; i<n_elements(); ++i)
      bytes += IO::restore( _istr, data_[i], _swap);
    return bytes;
  }
 
public: // data access interface
 
  const T* data() const {
 
    if( data_.empty() )
      return 0;
 
    return &data_[0];
  }
 
  vector_type& data_vector() {
    return data_;
  }
 
  const vector_type& data_vector() const {
    return data_;
  }
 
  reference operator[](int _idx)
  {
    assert( size_t(_idx) < data_.size() );
    return data_[_idx];
  }
 
  const_reference operator[](int _idx) const
  {
    assert( size_t(_idx) < data_.size());
    return data_[_idx];
  }
 
  PropertyT<T>* clone() const override
  {
    PropertyT<T>* p = new PropertyT<T>( *this );
    return p;
  }
 
  std::string get_storage_name() const override
  {
    return OpenMesh::IO::binary<T>::type_identifier();
  }
 
private:
 
  vector_type data_;
};
 
//-----------------------------------------------------------------------------
 
 
template <>
class PropertyT<bool> : public BaseProperty
{
public:
 
  typedef std::vector<bool>                       vector_type;
  typedef bool                                    value_type;
  typedef vector_type::reference                  reference;
  typedef vector_type::const_reference            const_reference;
 
public:
 
  explicit PropertyT(const std::string& _name = "<unknown>", const std::string& _internal_type_name="" )
    : BaseProperty(_name, _internal_type_name)
  { }
 
public: // inherited from BaseProperty
 
  virtual void reserve(size_t _n) override { data_.reserve(_n);    }
  virtual void resize(size_t _n) override  { data_.resize(_n);     }
  virtual void clear() override  { data_.clear(); vector_type().swap(data_);    }
  virtual void push_back() override        { data_.emplace_back(); }
  virtual void swap(size_t _i0, size_t _i1) override
  { bool t(data_[_i0]); data_[_i0]=data_[_i1]; data_[_i1]=t; }
  virtual void copy(size_t _i0, size_t _i1) override
  { data_[_i1] = data_[_i0]; }
 
public:
 
  virtual void set_persistent( bool _yn ) override
  {
    check_and_set_persistent<bool>( _yn );
  }
 
  virtual size_t       n_elements()   const override { return data_.size();  }
  virtual size_t       element_size() const override { return UnknownSize;    }
  virtual size_t       size_of() const override      { return size_of( n_elements() ); }
  virtual size_t       size_of(size_t _n_elem) const override
  {
    return _n_elem / 8 + ((_n_elem % 8)!=0);
  }
 
  size_t store( std::ostream& _ostr, bool /* _swap */ ) const override
  {
    size_t bytes = 0;
 
    size_t N = data_.size() / 8;
    size_t R = data_.size() % 8;
 
    size_t        idx;  // element index
    size_t        bidx;
    unsigned char bits; // bitset
 
    for (bidx=idx=0; idx < N; ++idx, bidx+=8)
    {
      bits = static_cast<unsigned char>(data_[bidx])
        | (static_cast<unsigned char>(data_[bidx+1]) << 1)
        | (static_cast<unsigned char>(data_[bidx+2]) << 2)
        | (static_cast<unsigned char>(data_[bidx+3]) << 3)
        | (static_cast<unsigned char>(data_[bidx+4]) << 4)
        | (static_cast<unsigned char>(data_[bidx+5]) << 5)
        | (static_cast<unsigned char>(data_[bidx+6]) << 6)
        | (static_cast<unsigned char>(data_[bidx+7]) << 7);
      _ostr << bits;
    }
    bytes = N;
 
    if (R)
    {
      bits = 0;
      for (idx=0; idx < R; ++idx)
        bits |= static_cast<unsigned char>(data_[bidx+idx]) << idx;
      _ostr << bits;
      ++bytes;
    }
 
    assert( bytes == size_of() );
 
    return bytes;
  }
 
  size_t restore( std::istream& _istr, bool /* _swap */ ) override
  {
    size_t bytes = 0;
 
    size_t N = data_.size() / 8;
    size_t R = data_.size() % 8;
 
    size_t        idx;  // element index
    size_t        bidx; //
    unsigned char bits; // bitset
 
    for (bidx=idx=0; idx < N; ++idx, bidx+=8)
    {
      _istr >> bits;
      data_[bidx+0] = (bits & 0x01) != 0;
      data_[bidx+1] = (bits & 0x02) != 0;
      data_[bidx+2] = (bits & 0x04) != 0;
      data_[bidx+3] = (bits & 0x08) != 0;
      data_[bidx+4] = (bits & 0x10) != 0;
      data_[bidx+5] = (bits & 0x20) != 0;
      data_[bidx+6] = (bits & 0x40) != 0;
      data_[bidx+7] = (bits & 0x80) != 0;
    }
    bytes = N;
 
    if (R)
    {
      _istr >> bits;
      for (idx=0; idx < R; ++idx)
        data_[bidx+idx] = (bits & (1<<idx)) != 0;
      ++bytes;
    }
 
    return bytes;
  }
 
 
public:
 
  vector_type& data_vector() {
    return data_;
  }
 
  const vector_type& data_vector() const {
    return data_;
  }
 
  reference operator[](int _idx)
  {
    assert( size_t(_idx) < data_.size() );
    return data_[_idx];
  }
 
  const_reference operator[](int _idx) const
  {
    assert( size_t(_idx) < data_.size());
    return data_[_idx];
  }
 
  PropertyT<bool>* clone() const override
  {
    PropertyT<bool>* p = new PropertyT<bool>( *this );
    return p;
  }
 
    std::string get_storage_name() const override
    {
      return OpenMesh::IO::binary<bool>::type_identifier();
    }
 
 
private:
 
  vector_type data_;
};
 
 
//-----------------------------------------------------------------------------
 
 
template <class T>
struct BasePropHandleT : public BaseHandle
{
  typedef T                                       Value;
  typedef std::vector<T>                          vector_type;
  typedef T                                       value_type;
  typedef typename vector_type::reference         reference;
  typedef typename vector_type::const_reference   const_reference;
 
  explicit BasePropHandleT(int _idx=-1) : BaseHandle(_idx) {}
};
 
 
template <class T>
struct VPropHandleT : public BasePropHandleT<T>
{
  typedef T                       Value;
  typedef T                       value_type;
  typedef VertexHandle            Handle;
 
  explicit VPropHandleT(int _idx=-1) : BasePropHandleT<T>(_idx) {}
  explicit VPropHandleT(const BasePropHandleT<T>& _b) : BasePropHandleT<T>(_b) {}
};
 
 
template <class T>
struct HPropHandleT : public BasePropHandleT<T>
{
  typedef T                       Value;
  typedef T                       value_type;
  typedef HalfedgeHandle          Handle;
 
  explicit HPropHandleT(int _idx=-1) : BasePropHandleT<T>(_idx) {}
  explicit HPropHandleT(const BasePropHandleT<T>& _b) : BasePropHandleT<T>(_b) {}
};
 
 
template <class T>
struct EPropHandleT : public BasePropHandleT<T>
{
  typedef T                       Value;
  typedef T                       value_type;
  typedef EdgeHandle              Handle;
 
  explicit EPropHandleT(int _idx=-1) : BasePropHandleT<T>(_idx) {}
  explicit EPropHandleT(const BasePropHandleT<T>& _b) : BasePropHandleT<T>(_b) {}
};
 
 
template <class T>
struct FPropHandleT : public BasePropHandleT<T>
{
  typedef T                       Value;
  typedef T                       value_type;
  typedef FaceHandle              Handle;
 
  explicit FPropHandleT(int _idx=-1) : BasePropHandleT<T>(_idx) {}
  explicit FPropHandleT(const BasePropHandleT<T>& _b) : BasePropHandleT<T>(_b) {}
};
 
 
template <class T>
struct MPropHandleT : public BasePropHandleT<T>
{
  typedef T                       Value;
  typedef T                       value_type;
  typedef MeshHandle              Handle;
 
  explicit MPropHandleT(int _idx=-1) : BasePropHandleT<T>(_idx) {}
  explicit MPropHandleT(const BasePropHandleT<T>& _b) : BasePropHandleT<T>(_b) {}
};
 
template <typename HandleT>
struct PropHandle;
 
template <>
struct PropHandle<VertexHandle> {
  template <typename T>
  using type = VPropHandleT<T>;
};
 
template <>
struct PropHandle<HalfedgeHandle> {
  template <typename T>
  using type = HPropHandleT<T>;
};
 
template <>
struct PropHandle<EdgeHandle> {
  template <typename T>
  using type = EPropHandleT<T>;
};
 
template <>
struct PropHandle<FaceHandle> {
  template <typename T>
  using type = FPropHandleT<T>;
};
 
template <>
struct PropHandle<MeshHandle> {
  template <typename T>
  using type = MPropHandleT<T>;
};
 
} // namespace OpenMesh
//=============================================================================
//#endif // OPENMESH_PROPERTY_HH defined
//=============================================================================