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Program: Visualization Toolkit
Module: vtkAbstractImageInterpolator.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 vtkAbstractImageInterpolator - interpolate data values from images
// .SECTION Description
// vtkAbstractImageInterpolator provides an abstract interface for
// interpolating image data. You specify the data set you want to
// interpolate values from, then call Interpolate(x,y,z) to interpolate
// the data.
// .SECTION Thanks
// Thanks to David Gobbi at the Seaman Family MR Centre and Dept. of Clinical
// Neurosciences, Foothills Medical Centre, Calgary, for providing this class.
// .SECTION See also
// vtkImageReslice vtkImageInterpolator vtkImageSincInterpolator
#ifndef __vtkAbstractImageInterpolator_h
#define __vtkAbstractImageInterpolator_h
#include "vtkObject.h"
#define VTK_IMAGE_BORDER_CLAMP 0
#define VTK_IMAGE_BORDER_REPEAT 1
#define VTK_IMAGE_BORDER_MIRROR 2
class vtkDataObject;
class vtkImageData;
class vtkDataArray;
struct vtkInterpolationInfo;
struct vtkInterpolationWeights;
class VTK_FILTERING_EXPORT vtkAbstractImageInterpolator : public vtkObject
{
public:
vtkTypeMacro(vtkAbstractImageInterpolator, vtkObject);
virtual void PrintSelf(ostream& os, vtkIndent indent);
// Description:
// Initialize the interpolator with the data that you wish to interpolate.
virtual void Initialize(vtkDataObject *data);
// Description:
// Release any data stored by the interpolator.
virtual void ReleaseData();
// Description:
// Copy the interpolator. It is possible to duplicate an interpolator
// by calling NewInstance() followed by DeepCopy().
void DeepCopy(vtkAbstractImageInterpolator *obj);
// Description:
// Update the interpolator. If the interpolator has been modified by
// a Set method since Initialize() was called, you must call this method
// to update the interpolator before you can use it.
void Update();
// Description:
// Get the result of interpolating the specified component of the input
// data, which should be set to zero if there is only one component.
// If the point is not within the bounds of the data set, then OutValue
// will be returned. This method is primarily meant for use by the
// wrapper languages.
double Interpolate(double x, double y, double z, int component);
// Description:
// Sample the input data. This is an inline method that calls the
// function that performs the appropriate interpolation for the
// data type. If the point is not within the bounds of the data set,
// then the return value is false, and each component will be set to
// the OutValue.
bool Interpolate(const double point[3], double *value);
// Description:
// The value to return when the point is out of bounds.
void SetOutValue(double outValue);
double GetOutValue() { return this->OutValue; }
// Description:
// The tolerance to apply when checking whether a point is out of bounds.
// This is a fractional distance relative to the voxel size, so a tolerance
// of 1 expands the bounds by one voxel.
void SetTolerance(double tol);
double GetTolerance() { return this->Tolerance; }
// Description:
// This method specifies which component of the input will be interpolated,
// or if ComponentCount is also set, it specifies the first component.
// When the interpolation is performed, it will be clamped to the number
// of available components.
void SetComponentOffset(int offset);
int GetComponentOffset() { return this->ComponentOffset; }
// Description:
// This method specifies the number of components to extract. The default
// value is -1, which extracts all available components. When the
// interpolation is performed, this will be clamped to the number of
// available components.
void SetComponentCount(int count);
int GetComponentCount() { return this->ComponentCount; }
// Description:
// Compute the number of output components based on the ComponentOffset,
// ComponentCount, and the number of components in the input data.
int ComputeNumberOfComponents(int inputComponents);
// Description:
// Get the number of components that will be returned when Interpolate()
// is called. This is only valid after initialization. Before then, use
// ComputeNumberOfComponents instead.
int GetNumberOfComponents();
// Description:
// A version of Interpolate that takes structured coords instead of data
// coords. Structured coords are the data coords after subtracting the
// Origin and dividing by the Spacing.
void InterpolateIJK(const double point[3], double *value);
void InterpolateIJK(const float point[3], float *value);
// Description:
// Check an x,y,z point to see if it is within the bounds for the
// structured coords of the image. This is meant to be called prior
// to InterpolateIJK. The bounds that are checked against are the input
// image extent plus the tolerance.
bool CheckBoundsIJK(const double x[3]);
bool CheckBoundsIJK(const float x[3]);
// Description:
// The border mode (default: clamp). This controls how out-of-bounds
// lookups are handled, i.e. how data will be extrapolated beyond the
// bounds of the image. The default is to clamp the lookup point to the
// bounds. The other modes wrap around to the opposite boundary, or
// mirror the image at the boundary.
void SetBorderMode(int mode);
void SetBorderModeToClamp() {
this->SetBorderMode(VTK_IMAGE_BORDER_CLAMP); }
void SetBorderModeToRepeat() {
this->SetBorderMode(VTK_IMAGE_BORDER_REPEAT); }
void SetBorderModeToMirror() {
this->SetBorderMode(VTK_IMAGE_BORDER_MIRROR); }
int GetBorderMode() { return this->BorderMode; }
const char *GetBorderModeAsString();
// Description:
// Get the support size for use in computing update extents. If the data
// will be sampled on a regular grid, then pass a matrix describing the
// structured coordinate transformation between the output and the input.
// Otherwise, pass NULL as the matrix to retrieve the full kernel size.
virtual void ComputeSupportSize(const double matrix[16], int support[3]) = 0;
// Description:
// True if the interpolation is separable, which means that the weights
// can be precomputed in order to accelerate the interpolation. Any
// interpolator which is separable will implement the methods
// PrecomputeWeightsForExtent and InterpolateRow
virtual bool IsSeparable() = 0;
// Description:
// If the data is going to be sampled on a regular grid, then the
// interpolation weights can be precomputed. A matrix must be supplied
// that provides a transformation between the provided extent and the
// structured coordinates of the input. This matrix must perform only
// permutation, scale, and translation, i.e. each of the three columns
// must have only one non-zero value. A checkExtent is provided that can
// be used to check which indices in the extent map to out-of-bounds
// coordinates in the input data.
virtual void PrecomputeWeightsForExtent(
const double matrix[16], const int extent[6], int checkExtent[6],
vtkInterpolationWeights *&weights);
virtual void PrecomputeWeightsForExtent(
const float matrix[16], const int extent[6], int checkExtent[6],
vtkInterpolationWeights *&weights);
// Description:
// Free the weights that were provided by PrecomputeWeightsForExtent.
virtual void FreePrecomputedWeights(vtkInterpolationWeights *&weights);
// Description:
// Get a row of samples, using the weights that were precomputed
// by PrecomputeWeightsForExtent. Note that each sample may have
// multiple components. It is possible to select which components
// will be returned by setting the ComponentOffset and ComponentCount.
void InterpolateRow(
vtkInterpolationWeights *&weights, int xIdx, int yIdx, int zIdx,
double *value, int n);
void InterpolateRow(
vtkInterpolationWeights *&weights, int xIdx, int yIdx, int zIdx,
float *value, int n);
// Description:
// Get the spacing of the data being interpolated.
vtkGetVector3Macro(Spacing, double);
// Description:
// Get the origin of the data being interpolated.
vtkGetVector3Macro(Origin, double);
// Description:
// Get the extent of the data being interpolated.
vtkGetVector6Macro(Extent, int);
// Description:
// Get the whole extent of the data being interpolated, including
// parts of the data that are not currently in memory.
vtkGetVector6Macro(WholeExtent, int);
protected:
vtkAbstractImageInterpolator();
~vtkAbstractImageInterpolator();
// Description:
// Subclass-specific updates.
virtual void InternalUpdate() = 0;
// Description:
// Subclass-specific copy.
virtual void InternalDeepCopy(vtkAbstractImageInterpolator *obj) = 0;
// Description:
// Get the interpolation functions.
virtual void GetInterpolationFunc(
void (**doublefunc)(
vtkInterpolationInfo *, const double [3], double *));
virtual void GetInterpolationFunc(
void (**floatfunc)(
vtkInterpolationInfo *, const float [3], float *));
// Description:
// Get the row interpolation functions.
virtual void GetRowInterpolationFunc(
void (**doublefunc)(
vtkInterpolationWeights *, int, int, int, double *, int));
virtual void GetRowInterpolationFunc(
void (**floatfunc)(
vtkInterpolationWeights *, int, int, int, float *, int));
vtkDataArray *Scalars;
double StructuredBoundsDouble[6];
float StructuredBoundsFloat[6];
int WholeExtent[6];
int Extent[6];
double Spacing[3];
double Origin[3];
double OutValue;
double Tolerance;
int BorderMode;
int ComponentOffset;
int ComponentCount;
// information needed by the interpolator funcs
vtkInterpolationInfo *InterpolationInfo;
void (*InterpolationFuncDouble)(
vtkInterpolationInfo *info, const double point[3], double *outPtr);
void (*InterpolationFuncFloat)(
vtkInterpolationInfo *info, const float point[3], float *outPtr);
void (*RowInterpolationFuncDouble)(
vtkInterpolationWeights *weights, int idX, int idY, int idZ,
double *outPtr, int n);
void (*RowInterpolationFuncFloat)(
vtkInterpolationWeights *weights, int idX, int idY, int idZ,
float *outPtr, int n);
private:
vtkAbstractImageInterpolator(const vtkAbstractImageInterpolator&); // Not implemented.
void operator=(const vtkAbstractImageInterpolator&); // Not implemented.
};
inline void vtkAbstractImageInterpolator::InterpolateIJK(
const double point[3], double *value)
{
this->InterpolationFuncDouble(this->InterpolationInfo, point, value);
}
inline void vtkAbstractImageInterpolator::InterpolateIJK(
const float point[3], float *value)
{
this->InterpolationFuncFloat(this->InterpolationInfo, point, value);
}
inline bool vtkAbstractImageInterpolator::CheckBoundsIJK(const double x[3])
{
double *bounds = this->StructuredBoundsDouble;
return !((x[0] < bounds[0]) | (x[0] > bounds[1]) |
(x[1] < bounds[2]) | (x[1] > bounds[3]) |
(x[2] < bounds[4]) | (x[2] > bounds[5]));
}
inline bool vtkAbstractImageInterpolator::CheckBoundsIJK(const float x[3])
{
float *bounds = this->StructuredBoundsFloat;
return !((x[0] < bounds[0]) | (x[0] > bounds[1]) |
(x[1] < bounds[2]) | (x[1] > bounds[3]) |
(x[2] < bounds[4]) | (x[2] > bounds[5]));
}
inline void vtkAbstractImageInterpolator::InterpolateRow(
vtkInterpolationWeights *&weights, int xIdx, int yIdx, int zIdx,
double *value, int n)
{
this->RowInterpolationFuncDouble(weights, xIdx, yIdx, zIdx, value, n);
}
inline void vtkAbstractImageInterpolator::InterpolateRow(
vtkInterpolationWeights *&weights, int xIdx, int yIdx, int zIdx,
float *value, int n)
{
this->RowInterpolationFuncFloat(weights, xIdx, yIdx, zIdx, value, n);
}
#endif
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