/usr/include/vtk-5.10/vtkEncodedGradientEstimator.h is in libvtk5-dev 5.10.1+dfsg-2.1build1.
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Program: Visualization Toolkit
Module: vtkEncodedGradientEstimator.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 vtkEncodedGradientEstimator - Superclass for gradient estimation
// .SECTION Description
// vtkEncodedGradientEstimator is an abstract superclass for gradient
// estimation. It takes a scalar input of vtkImageData, computes
// a gradient value for every point, and encodes this value into a
// three byte value (2 for direction, 1 for magnitude) using the
// vtkDirectionEncoder. The direction encoder is defaulted to a
// vtkRecursiveSphereDirectionEncoder, but can be overridden with the
// SetDirectionEncoder method. The scale and the bias values for the gradient
// magnitude are used to convert it into a one byte value according to
// v = m*scale + bias where m is the magnitude and v is the resulting
// one byte value.
// .SECTION see also
// vtkFiniteDifferenceGradientEstimator vtkDirectionEncoder
#ifndef __vtkEncodedGradientEstimator_h
#define __vtkEncodedGradientEstimator_h
#include "vtkObject.h"
class vtkImageData;
class vtkDirectionEncoder;
class vtkMultiThreader;
class VTK_VOLUMERENDERING_EXPORT vtkEncodedGradientEstimator : public vtkObject
{
public:
vtkTypeMacro(vtkEncodedGradientEstimator,vtkObject);
void PrintSelf( ostream& os, vtkIndent indent );
// Description:
// Set/Get the scalar input for which the normals will be
// calculated
virtual void SetInput(vtkImageData*);
vtkGetObjectMacro( Input, vtkImageData );
// Description:
// Set/Get the scale and bias for the gradient magnitude
vtkSetMacro( GradientMagnitudeScale, float );
vtkGetMacro( GradientMagnitudeScale, float );
vtkSetMacro( GradientMagnitudeBias, float );
vtkGetMacro( GradientMagnitudeBias, float );
// Description:
// Turn on / off the bounding of the normal computation by
// the this->Bounds bounding box
vtkSetClampMacro( BoundsClip, int, 0, 1 );
vtkGetMacro( BoundsClip, int );
vtkBooleanMacro( BoundsClip, int );
// Description:
// Set / Get the bounds of the computation (used if
// this->ComputationBounds is 1.) The bounds are specified
// xmin, xmax, ymin, ymax, zmin, zmax.
vtkSetVector6Macro( Bounds, int );
vtkGetVectorMacro( Bounds, int, 6 );
// Description:
// Recompute the encoded normals and gradient magnitudes.
void Update( void );
// Description:
// Get the encoded normals.
unsigned short *GetEncodedNormals( void );
// Description:
// Get the encoded normal at an x,y,z location in the volume
int GetEncodedNormalIndex( vtkIdType xyz_index );
int GetEncodedNormalIndex( int x_index, int y_index, int z_index );
// Description:
// Get the gradient magnitudes
unsigned char *GetGradientMagnitudes(void);
// Description:
// Get/Set the number of threads to create when encoding normals
// This defaults to the number of available processors on the machine
vtkSetClampMacro( NumberOfThreads, int, 1, VTK_MAX_THREADS );
vtkGetMacro( NumberOfThreads, int );
// Description:
// Set / Get the direction encoder used to encode normal directions
// to fit within two bytes
void SetDirectionEncoder( vtkDirectionEncoder *direnc );
vtkGetObjectMacro( DirectionEncoder, vtkDirectionEncoder );
// Description:
// If you don't want to compute gradient magnitudes (but you
// do want normals for shading) this can be used. Be careful - if
// if you a non-constant gradient magnitude transfer function and
// you turn this on, it may crash
vtkSetMacro( ComputeGradientMagnitudes, int );
vtkGetMacro( ComputeGradientMagnitudes, int );
vtkBooleanMacro( ComputeGradientMagnitudes, int );
// Description:
// If the data in each slice is only contained within a circle circumscribed
// within the slice, and the slice is square, then don't compute anything
// outside the circle. This circle through the slices forms a cylinder.
vtkSetMacro( CylinderClip, int );
vtkGetMacro( CylinderClip, int );
vtkBooleanMacro( CylinderClip, int );
// Description:
// Get the time required for the last update in seconds or cpu seconds
vtkGetMacro( LastUpdateTimeInSeconds, float );
vtkGetMacro( LastUpdateTimeInCPUSeconds, float );
vtkGetMacro( UseCylinderClip, int );
int *GetCircleLimits() { return this->CircleLimits; };
// Description:
// Set / Get the ZeroNormalThreshold - this defines the minimum magnitude
// of a gradient that is considered sufficient to define a
// direction. Gradients with magnitudes at or less than this value are given
// a "zero normal" index. These are handled specially in the shader,
// and you can set the intensity of light for these zero normals in
// the gradient shader.
void SetZeroNormalThreshold( float v );
vtkGetMacro( ZeroNormalThreshold, float );
// Description:
// Assume that the data value outside the volume is zero when
// computing normals.
vtkSetClampMacro( ZeroPad, int, 0, 1 );
vtkGetMacro( ZeroPad, int );
vtkBooleanMacro( ZeroPad, int );
// These variables should be protected but are being
// made public to be accessible to the templated function.
// We used to have the templated function as a friend, but
// this does not work with all compilers
// The input scalar data on which the normals are computed
vtkImageData *Input;
// The encoded normals (2 bytes) and the size of the encoded normals
unsigned short *EncodedNormals;
int EncodedNormalsSize[3];
// The magnitude of the gradient array and the size of this array
unsigned char *GradientMagnitudes;
// The time at which the normals were last built
vtkTimeStamp BuildTime;
//BTX
vtkGetVectorMacro( InputSize, int, 3 );
vtkGetVectorMacro( InputAspect, float, 3 );
//ETX
protected:
vtkEncodedGradientEstimator();
~vtkEncodedGradientEstimator();
virtual void ReportReferences(vtkGarbageCollector*);
// The number of threads to use when encoding normals
int NumberOfThreads;
vtkMultiThreader *Threader;
vtkDirectionEncoder *DirectionEncoder;
virtual void UpdateNormals( void ) = 0;
float GradientMagnitudeScale;
float GradientMagnitudeBias;
float LastUpdateTimeInSeconds;
float LastUpdateTimeInCPUSeconds;
float ZeroNormalThreshold;
int CylinderClip;
int *CircleLimits;
int CircleLimitsSize;
int UseCylinderClip;
void ComputeCircleLimits( int size );
int BoundsClip;
int Bounds[6];
int InputSize[3];
float InputAspect[3];
int ComputeGradientMagnitudes;
int ZeroPad;
private:
vtkEncodedGradientEstimator(const vtkEncodedGradientEstimator&); // Not implemented.
void operator=(const vtkEncodedGradientEstimator&); // Not implemented.
};
#endif
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