/usr/include/ITK-4.5/itkDiscreteGaussianDerivativeImageFunction.h is in libinsighttoolkit4-dev 4.5.0-3.
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*
* Copyright Insight Software Consortium
*
* Licensed under the Apache License, Version 2.0 (the "License");
* you may not use this file except in compliance with the License.
* You may obtain a copy of the License at
*
* http://www.apache.org/licenses/LICENSE-2.0.txt
*
* Unless required by applicable law or agreed to in writing, software
* distributed under the License is distributed on an "AS IS" BASIS,
* WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
* See the License for the specific language governing permissions and
* limitations under the License.
*
*=========================================================================*/
#ifndef __itkDiscreteGaussianDerivativeImageFunction_h
#define __itkDiscreteGaussianDerivativeImageFunction_h
#include "itkNeighborhoodOperatorImageFunction.h"
#include "itkGaussianDerivativeOperator.h"
namespace itk
{
/**
* \class DiscreteGaussianDerivativeImageFunction
* \brief Compute the discrete gaussian derivatives of an the image
* at a specific location in space, i.e. point, index or continuous
* index. This class computes a single derivative given the order in
* each direction (by default zero).
* This class is templated over the input image type.
*
* The Initialize() method must be called after setting the parameters and before
* evaluating the function.
*
* \author Ivan Macia, VICOMTech, Spain, http://www.vicomtech.es
*
* This implementation was taken from the Insight Journal paper:
* http://hdl.handle.net/1926/1290
*
* \sa NeighborhoodOperator
* \sa ImageFunction
* \ingroup ITKReview
*/
template< typename TInputImage, typename TOutput = double >
class DiscreteGaussianDerivativeImageFunction:
public ImageFunction< TInputImage, TOutput, TOutput >
{
public:
/**Standard "Self" typedef */
typedef DiscreteGaussianDerivativeImageFunction Self;
/** Standard "Superclass" typedef */
typedef ImageFunction< TInputImage, TOutput, TOutput > Superclass;
/** Smart pointer typedef support. */
typedef SmartPointer< Self > Pointer;
typedef SmartPointer< const Self > ConstPointer;
/** Method for creation through the object factory. */
itkNewMacro(Self);
/** Run-time type information (and related methods). */
itkTypeMacro(DiscreteGaussianDerivativeImageFunction, ImageFunction);
/** Image dependent types. */
typedef typename Superclass::InputImageType InputImageType;
typedef typename Superclass::InputPixelType InputPixelType;
typedef typename Superclass::IndexType IndexType;
typedef typename Superclass::IndexValueType IndexValueType;
typedef typename Superclass::ContinuousIndexType ContinuousIndexType;
typedef typename Superclass::PointType PointType;
/** Dimension of the underlying image. */
itkStaticConstMacro(ImageDimension2, unsigned int,
InputImageType::ImageDimension);
/** Output type. */
typedef typename Superclass::OutputType OutputType;
/** Arrays for native types. */
typedef FixedArray< double, itkGetStaticConstMacro(ImageDimension2) > VarianceArrayType;
typedef FixedArray< unsigned int, itkGetStaticConstMacro(ImageDimension2) > OrderArrayType;
typedef itk::GaussianDerivativeOperator< TOutput,
itkGetStaticConstMacro(ImageDimension2) > GaussianDerivativeOperatorType;
/** Array to store gaussian derivative operators one for each dimension. */
typedef FixedArray< GaussianDerivativeOperatorType,
itkGetStaticConstMacro(ImageDimension2) > GaussianDerivativeOperatorArrayType;
/** Precomputed N-dimensional derivative kernel. */
typedef Neighborhood< TOutput, itkGetStaticConstMacro(ImageDimension2) > KernelType;
/** Image function that performs convolution with the neighborhood operator.
*/
typedef NeighborhoodOperatorImageFunction
< InputImageType, TOutput > OperatorImageFunctionType;
typedef typename OperatorImageFunctionType::Pointer OperatorImageFunctionPointer;
/** Interpolation modes. */
enum InterpolationModeType { NearestNeighbourInterpolation, LinearInterpolation };
public:
/** Evaluate the function at specified point. */
virtual OutputType Evaluate(const PointType & point) const;
/** Evaluate the function at specified Index position */
virtual OutputType EvaluateAtIndex(const IndexType & index) const;
/** Evaluate the function at specified ContinousIndex position. */
virtual OutputType EvaluateAtContinuousIndex(
const ContinuousIndexType & index) const;
/** Set/Get the variance for the discrete Gaussian kernel.
* Sets the variance for individual dimensions. The default is 0.0
* in each dimension. If UseImageSpacing is true, the units are the
* physical units of your image. If UseImageSpacing is false then
* the units are pixels.
*/
itkSetMacro(Variance, VarianceArrayType);
itkGetConstMacro(Variance, const VarianceArrayType);
itkSetVectorMacro(Variance, double, VarianceArrayType::Length);
/** Convenience method for setting the variance for all dimensions. */
virtual void SetVariance(double variance)
{
m_Variance.Fill(variance);
this->Modified();
}
/** Convenience method for setting the variance through the standard
* deviation.
*/
void SetSigma(const double sigma)
{
SetVariance(sigma * sigma);
}
/** Set/Get the desired maximum error of the gaussian approximation. Maximum
* error is the difference between the area under the discrete Gaussian curve
* and the area under the continuous Gaussian. Maximum error affects the
* Gaussian operator size. The value is clamped between 0.00001 and
* 0.99999.
*/
itkSetClampMacro(MaximumError, double, 0.00001, 0.99999);
itkGetConstMacro(MaximumError, double);
/** Set/Get the derivative order for an individual dimension. */
itkSetMacro(Order, OrderArrayType);
itkGetConstMacro(Order, const OrderArrayType);
itkSetVectorMacro(Order, unsigned int, OrderArrayType::Length);
/** Convenience method for setting the order for all dimensions. */
virtual void SetOrder(unsigned int order)
{
m_Order.Fill(order);
this->Modified();
}
/** Set/Get the flag for calculating scale-space normalized derivatives.
* Normalized derivatives are obtained multiplying by the scale
* parameter t. */
itkSetMacro(NormalizeAcrossScale, bool);
itkGetConstMacro(NormalizeAcrossScale, bool);
itkBooleanMacro(NormalizeAcrossScale);
/** Set/Get the flag for using image spacing when calculating derivatives. */
itkSetMacro(UseImageSpacing, bool);
itkGetConstMacro(UseImageSpacing, bool);
itkBooleanMacro(UseImageSpacing);
/** Set/Get a limit for growth of the kernel. Small maximum error values with
* large variances will yield very large kernel sizes. This value can be
* used to truncate a kernel in such instances. A warning will be given on
* truncation of the kernel. */
itkSetMacro(MaximumKernelWidth, unsigned int);
itkGetConstMacro(MaximumKernelWidth, unsigned int);
/** Set/Get the interpolation mode. */
itkSetMacro(InterpolationMode, InterpolationModeType);
itkGetConstMacro(InterpolationMode, InterpolationModeType);
/** Set the input image.
* \warning this method caches BufferedRegion information.
* If the BufferedRegion has changed, user must call
* SetInputImage again to update cached values. */
virtual void SetInputImage(const InputImageType *ptr);
/** Initialize the Gaussian kernel. Call this method before
* evaluating the function. This method MUST be called after any
* changes to function parameters. */
virtual void Initialize() { RecomputeGaussianKernel(); }
protected:
DiscreteGaussianDerivativeImageFunction();
DiscreteGaussianDerivativeImageFunction(const Self &){}
~DiscreteGaussianDerivativeImageFunction(){}
void operator=(const Self &){}
void PrintSelf(std::ostream & os, Indent indent) const;
void RecomputeGaussianKernel();
private:
/** Desired variance of the discrete Gaussian function. */
VarianceArrayType m_Variance;
/** Order of the derivatives in each dimension. */
OrderArrayType m_Order;
/** Difference between the areas under the curves of the continuous and
* discrete Gaussian functions. */
double m_MaximumError;
/** Maximum kernel size allowed. This value is used to truncate a kernel
* that has grown too large. A warning is given when the specified maximum
* error causes the kernel to exceed this size. */
unsigned int m_MaximumKernelWidth;
/** Array of derivative operators, one for each dimension. */
GaussianDerivativeOperatorArrayType m_OperatorArray;
/** N-dimensional kernel which is the result of convolving the operators
* for calculating derivatives. */
KernelType m_DerivativeKernel;
/** OperatorImageFunction */
OperatorImageFunctionPointer m_OperatorImageFunction;
/** Flag for scale-space normalization of derivatives. */
bool m_NormalizeAcrossScale;
/** Flag to indicate whether to use image spacing */
bool m_UseImageSpacing;
/** Interpolation mode. */
InterpolationModeType m_InterpolationMode;
};
} // namespace itk
#ifndef ITK_MANUAL_INSTANTIATION
#include "itkDiscreteGaussianDerivativeImageFunction.hxx"
#endif
#endif
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