/usr/include/vtk-5.10/vtkMolecule.h is in libvtk5-dev 5.10.1+dfsg-2.1build1.
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Program: Visualization Toolkit
Module: vtkMolecule.h
Copyright (c) Ken Martin, Will Schroeder, Bill Lorensen
All rights reserved.
See Copyright.txt or http://www.kitware.com/Copyright.htm for details.
This software is distributed WITHOUT ANY WARRANTY; without even
the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR
PURPOSE. See the above copyright notice for more information.
=========================================================================*/
// .NAME vtkMolecule - class describing a molecule
//
// .SECTION Description
//
// vtkMolecule and the convenience classes vtkAtom and vtkBond
// describe the geometry and connectivity of a molecule. The molecule
// can be constructed using the AppendAtom() and AppendBond() methods in one
// of two ways; either by fully specifying the atom/bond in a single
// call, or by incrementally setting the various attributes using the
// convience vtkAtom and vtkBond classes:
//
// Single call:
// \code
// vtkMolecule *mol = vtkMolecule::New();
// vtkAtom h1 = mol->AppendAtom(1, 0.0, 0.0, -0.5);
// vtkAtom h2 = mol->AppendAtom(1, 0.0, 0.0, 0.5);
// vtkBond b = mol->AppendBond(h1, h2, 1);
// \endcode
//
// Incremental:
// \code
// vtkMolecule *mol = vtkMolecule::New();
//
// vtkAtom h1 = mol->AppendAtom();
// h1.SetAtomicNumber(1);
// h1.SetPosition(0.0, 0.0, -0.5);
//
// vtkAtom h2 = mol->AppendAtom();
// h2.SetAtomicNumber(1);
// vtkVector3d displacement (0.0, 0.0, 1.0);
// h2.SetPosition(h1.GetPositionAsVector3d() + displacement);
//
// vtkBond b = mol->AppendBond(h1, h2, 1);
// \endcode
//
// Both of the above methods will produce the same molecule, two
// hydrogens connected with a 1.0 Angstrom single bond, aligned to the
// z-axis. The second example also demostrates the use of VTK's
// vtkVector class, which is fully supported by the Chemistry kit.
//
// The vtkMolecule object is intended to be used with the
// vtkMoleculeMapper class for visualizing molecular structure using
// common rendering techniques.
//
// \warning While direct use of the underlying vtkUndirectedGraph
// structure is possible due to vtkMolecule's public inheritance, this
// should not be relied upon and may change in the future.
//
// .SECTION See Also
// vtkAtom vtkBond vtkMoleculeMapper vtkPeriodicTable
#ifndef __vtkMolecule_h
#define __vtkMolecule_h
#include "vtkUndirectedGraph.h"
//BTX
#include "vtkAtom.h" // Simple proxy class dependent on vtkMolecule
#include "vtkBond.h" // Simple proxy class dependent on vtkMolecule
//ETX
#include "vtkVector.h" // Small templated vector convenience class
class vtkPlane;
class vtkAbstractElectronicData;
class vtkPoints;
class vtkUnsignedShortArray;
class VTK_FILTERING_EXPORT vtkMolecule : public vtkUndirectedGraph
{
public:
static vtkMolecule *New();
vtkTypeMacro(vtkMolecule,vtkUndirectedGraph);
void PrintSelf(ostream &os, vtkIndent indent);
virtual void Initialize();
//BTX
// Description:
// Add new atom with atomic number 0 (dummy atom) at origin. Return
// a vtkAtom that refers to the new atom.
vtkAtom AppendAtom()
{
return this->AppendAtom(0, vtkVector3f(0, 0, 0));
}
// Description:
// Add new atom with the specified atomic number and position. Return a
// vtkAtom that refers to the new atom.
vtkAtom AppendAtom(unsigned short atomicNumber, const vtkVector3f &pos);
// Description:
// Convenience methods to append a new atom with the specified atomic number
// and position.
vtkAtom AppendAtom(unsigned short atomicNumber, double x, double y, double z)
{
return this->AppendAtom(atomicNumber, vtkVector3f(x, y, z));
}
// Description:
// Return a vtkAtom that refers to the atom with the specified id.
vtkAtom GetAtom(vtkIdType atomId);
// Description:
// Return the number of atoms in the molecule.
vtkIdType GetNumberOfAtoms();
// Description
// Add a bond between the specified atoms, optionally setting the
// bond order (default: 1). Return a vtkBond object referring to the
// new bond.
vtkBond AppendBond(vtkIdType atom1, vtkIdType atom2,
unsigned short order = 1);
vtkBond AppendBond(const vtkAtom &atom1, const vtkAtom &atom2,
unsigned short order = 1)
{
return this->AppendBond(atom1.Id, atom2.Id, order);
}
// Description:
// Return a vtkAtom that refers to the bond with the specified id.
vtkBond GetBond(vtkIdType bondId);
//ETX
// Description:
// Return the number of bonds in the molecule.
vtkIdType GetNumberOfBonds();
// Description:
// Return the atomic number of the atom with the specified id.
unsigned short GetAtomAtomicNumber(vtkIdType atomId);
// Description:
// Set the atomic number of the atom with the specified id.
void SetAtomAtomicNumber(vtkIdType atomId,
unsigned short atomicNum);
// Description:
// Set the position of the atom with the specified id.
void SetAtomPosition(vtkIdType atomId, const vtkVector3f &pos);
void SetAtomPosition(vtkIdType atomId, double x, double y, double z);
// Description:
// Get the position of the atom with the specified id.
vtkVector3f GetAtomPosition(vtkIdType atomId);
void GetAtomPosition(vtkIdType atomId, float pos[3]);
// Description
// Get/Set the bond order of the bond with the specified id
void SetBondOrder(vtkIdType bondId, unsigned short order);
unsigned short GetBondOrder(vtkIdType bondId);
// Description
// Get the bond length of the bond with the specified id
//
// \note If the associated vtkBond object is already available,
// vtkBond::GetBondLength is potentially much faster than this
// function, as a list of all bonds may need to be constructed to
// locate the appropriate bond.
// \sa UpdateBondList()
double GetBondLength(vtkIdType bondId);
// Description:
// Access the raw arrays used in this vtkMolecule instance
vtkPoints * GetAtomicPositionArray();
vtkUnsignedShortArray * GetAtomicNumberArray();
//BTX
// Description:
// Set/Get the AbstractElectronicData-subclassed object for this molecule.
vtkGetObjectMacro(ElectronicData, vtkAbstractElectronicData);
virtual void SetElectronicData(vtkAbstractElectronicData*);
//ETX
// Description:
// Shallow copies the data object into this molecule.
virtual void ShallowCopy(vtkDataObject *obj);
// Description:
// Deep copies the data object into this molecule.
virtual void DeepCopy(vtkDataObject *obj);
// Description:
// Shallow copies the atoms and bonds from @a m into @a this.
virtual void ShallowCopyStructure(vtkMolecule *m);
// Description:
// Deep copies the atoms and bonds from @a m into @a this.
virtual void DeepCopyStructure(vtkMolecule *m);
// Description:
// Shallow copies attributes (i.e. everything besides atoms and bonds) from
// @a m into @a this.
virtual void ShallowCopyAttributes(vtkMolecule *m);
// Description:
// Deep copies attributes (i.e. everything besides atoms and bonds) from
// @a m into @a this.
virtual void DeepCopyAttributes(vtkMolecule *m);
// Description:
// Obtain the plane that passes through the indicated bond with the given
// normal. If the plane is set successfully, the function returns true.
//
// If the normal is not orthogonal to the bond, a new normal will be
// constructed in such a way that the plane will be orthogonal to
// the plane spanned by the bond vector and the input normal vector.
//
// This ensures that the plane passes through the bond, and the
// normal is more of a "hint" indicating the orientation of the plane.
//
// The new normal (n) is defined as the input normal vector (n_i) minus
// the projection of itself (proj[n_i]_v) onto the bond vector (v):
//
// @verbatim
// v ^
// | n = (n_i - proj[n_j]_v)
// proj[n_i]_v ^ |----x
// | | /
// | | / n_i
// | | /
// | |/
// @endverbatim
//
// If n_i is parallel to v, a warning will be printed and no plane will be
// added. Obviously, n_i must not be parallel to v.
static bool GetPlaneFromBond(const vtkBond &bond, const vtkVector3f &normal,
vtkPlane *plane);
static bool GetPlaneFromBond(const vtkAtom &atom1, const vtkAtom &atom2,
const vtkVector3f &normal, vtkPlane *plane);
protected:
vtkMolecule();
~vtkMolecule();
// Description:
// Copy bonds and atoms.
virtual void CopyStructureInternal(vtkMolecule *m, bool deep);
// Description:
// Copy everything but bonds and atoms.
virtual void CopyAttributesInternal(vtkMolecule *m, bool deep);
// Description:
// The graph superclass does not provide fast random access to the
// edge (bond) data. All random access is performed using a lookup
// table that must be rebuilt periodically. These allow for lazy
// building of the lookup table
bool BondListIsDirty;
void SetBondListDirty() {this->BondListIsDirty = true;}
void UpdateBondList();
friend class vtkAtom;
friend class vtkBond;
vtkAbstractElectronicData *ElectronicData;
private:
vtkMolecule(const vtkMolecule&); // Not implemented.
void operator=(const vtkMolecule&); // Not implemented.
};
#endif
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