/*=========================================================================
Program: vv http://www.creatis.insa-lyon.fr/rio/vv
- Authors belong to:
+ Authors belong to:
- University of LYON http://www.universite-lyon.fr/
- - Léon Bérard cancer center http://oncora1.lyon.fnclcc.fr
+ - Léon Bérard cancer center http://www.centreleonberard.fr
- CREATIS CNRS laboratory http://www.creatis.insa-lyon.fr
This software is distributed WITHOUT ANY WARRANTY; without even
- BSD See included LICENSE.txt file
- CeCILL-B http://www.cecill.info/licences/Licence_CeCILL-B_V1-en.html
- ======================================================================-====*/
+ ===========================================================================**/
// clitk
-#include "clitkCommon.h"
+#include "clitkDD.h"
// itk include
#include "itkImage.h"
#include "itkResampleImageFilter.h"
#include "itkAffineTransform.h"
#include "itkNearestNeighborInterpolateImageFunction.h"
+#include "itkWindowedSincInterpolateImageFunction.h"
#include "itkLinearInterpolateImageFunction.h"
#include "itkBSplineInterpolateImageFunction.h"
#include "itkBSplineInterpolateImageFunctionWithLUT.h"
#include "itkCommand.h"
-namespace clitk {
-
- //--------------------------------------------------------------------
- template <class TInputImage, class TOutputImage>
- ResampleImageWithOptionsFilter<TInputImage, TOutputImage>::
- ResampleImageWithOptionsFilter():itk::ImageToImageFilter<TInputImage, TOutputImage>() {
- static const unsigned int dim = InputImageType::ImageDimension;
- this->SetNumberOfRequiredInputs(1);
- m_IsoSpacing = -1;
- m_InterpolationType = NearestNeighbor;
- m_GaussianFilteringEnabled = true;
- m_BSplineOrder = 3;
- m_BLUTSamplingFactor = 20;
- m_LastDimensionIsTime = false;
- m_Transform = TransformType::New();
- if (dim == 4) m_LastDimensionIsTime = true; // by default 4D is 3D+t
- for(unsigned int i=0; i<dim; i++) {
- m_OutputSize[i] = 0;
- m_OutputSpacing[i] = -1;
- m_GaussianSigma[i] = -1;
- }
- m_VerboseOptions = false;
+//--------------------------------------------------------------------
+template <class InputImageType, class OutputImageType>
+clitk::ResampleImageWithOptionsFilter<InputImageType, OutputImageType>::
+ResampleImageWithOptionsFilter():itk::ImageToImageFilter<InputImageType, OutputImageType>()
+{
+ static const unsigned int dim = InputImageType::ImageDimension;
+ this->SetNumberOfRequiredInputs(1);
+ m_OutputIsoSpacing = -1;
+ m_InterpolationType = NearestNeighbor;
+ m_GaussianFilteringEnabled = true;
+ m_BSplineOrder = 3;
+ m_BLUTSamplingFactor = 20;
+ m_LastDimensionIsTime = false;
+ m_Transform = TransformType::New();
+ if (dim == 4) m_LastDimensionIsTime = true; // by default 4D is 3D+t
+ for(unsigned int i=0; i<dim; i++) {
+ m_OutputSize[i] = 0;
+ m_OutputSpacing[i] = -1;
+ m_GaussianSigma[i] = -1;
}
- //--------------------------------------------------------------------
+ m_OutputOrigin.Fill(0);
+ m_OutputDirection.SetIdentity();
+ m_VerboseOptions = false;
+ SetDefaultPixelValue(0);
+}
+//--------------------------------------------------------------------
- //--------------------------------------------------------------------
- template <class TInputImage, class TOutputImage>
- void
- ResampleImageWithOptionsFilter<TInputImage, TOutputImage>::
- SetInput(const InputImageType * image) {
- // Process object is not const-correct so the const casting is required.
- this->SetNthInput(0, const_cast<InputImageType *>(image));
- }
- //--------------------------------------------------------------------
-
-
- //--------------------------------------------------------------------
- template <class TInputImage, class TOutputImage>
- void
- ResampleImageWithOptionsFilter<TInputImage, TOutputImage>::
- GenerateInputRequestedRegion() {
- // call the superclass's implementation of this method
- Superclass::GenerateInputRequestedRegion();
-
- // get pointers to the input and output
- InputImagePointer inputPtr =
- const_cast< TInputImage *>( this->GetInput() );
-
- // Request the entire input image
- InputImageRegionType inputRegion;
- inputRegion = inputPtr->GetLargestPossibleRegion();
- inputPtr->SetRequestedRegion(inputRegion);
- }
- //--------------------------------------------------------------------
-
-
- //--------------------------------------------------------------------
- template <class TInputImage, class TOutputImage>
- void
- ResampleImageWithOptionsFilter<TInputImage, TOutputImage>::
- GenerateOutputInformation() {
- static const unsigned int dim = InputImageType::ImageDimension;
-
- // Warning
- if (!std::numeric_limits<InputImagePixelType>::is_signed) {
- if ((m_InterpolationType == BSpline) ||
- (m_InterpolationType == B_LUT)) {
- std::cerr << "Warning : input pixel type is not signed, use bspline interpolation at your own risk ..." << std::endl;
- }
+//--------------------------------------------------------------------
+template <class InputImageType, class OutputImageType>
+void
+clitk::ResampleImageWithOptionsFilter<InputImageType, OutputImageType>::
+SetInput(const InputImageType * image)
+{
+ // Process object is not const-correct so the const casting is required.
+ this->SetNthInput(0, const_cast<InputImageType *>(image));
+}
+//--------------------------------------------------------------------
+
+
+//--------------------------------------------------------------------
+template <class InputImageType, class OutputImageType>
+void
+clitk::ResampleImageWithOptionsFilter<InputImageType, OutputImageType>::
+GenerateInputRequestedRegion()
+{
+ // call the superclass's implementation of this method
+ Superclass::GenerateInputRequestedRegion();
+
+ // get pointers to the input and output
+ InputImagePointer inputPtr =
+ const_cast< InputImageType *>( this->GetInput() );
+
+ // Request the entire input image
+ InputImageRegionType inputRegion;
+ inputRegion = inputPtr->GetLargestPossibleRegion();
+ inputPtr->SetRequestedRegion(inputRegion);
+}
+//--------------------------------------------------------------------
+
+
+//--------------------------------------------------------------------
+template <class InputImageType, class OutputImageType>
+void
+clitk::ResampleImageWithOptionsFilter<InputImageType, OutputImageType>::
+GenerateOutputInformation()
+{
+ static const unsigned int dim = InputImageType::ImageDimension;
+
+ // Warning
+ if (!std::numeric_limits<InputImagePixelType>::is_signed) {
+ if ((m_InterpolationType == BSpline) ||
+ (m_InterpolationType == B_LUT)) {
+ std::cerr << "Warning : input pixel type is not signed, use bspline interpolation at your own risk ..." << std::endl;
}
+ }
- // Get input pointer
- InputImagePointer input = dynamic_cast<InputImageType*>(itk::ProcessObject::GetInput(0));
-
- // Perform default implementation
- Superclass::GenerateOutputInformation();
+ // Get input pointer
+ InputImagePointer input = dynamic_cast<InputImageType*>(itk::ProcessObject::GetInput(0));
- // Compute sizes
- InputImageSpacingType inputSpacing = input->GetSpacing();
- InputImageSizeType inputSize = input->GetLargestPossibleRegion().GetSize();
+ // Perform default implementation
+ Superclass::GenerateOutputInformation();
- if (m_IsoSpacing != -1) { // apply isoSpacing
+ // Compute sizes
+ InputImageSpacingType inputSpacing = input->GetSpacing();
+ InputImageSizeType inputSize = input->GetLargestPossibleRegion().GetSize();
+
+ if (m_OutputIsoSpacing != -1) { // apply isoSpacing
+ for(unsigned int i=0; i<dim; i++) {
+ m_OutputSpacing[i] = m_OutputIsoSpacing;
+ // floor() is used to intentionally reduce the number of slices
+ // because, from a clinical point of view, it's better to
+ // remove data than to add data that privously didn't exist.
+ if(inputSpacing[i]*m_OutputSpacing[i]<0)
+ itkExceptionMacro( << "Input and output spacings don't have the same signs, can't cope with that" );
+ m_OutputSize[i] = (int)floor(inputSize[i]*inputSpacing[i]/m_OutputSpacing[i]);
+ }
+ }
+ else if(m_OutputSpacing[0]==-1 || m_OutputSize[0]==0){
+ if (m_OutputSpacing[0] != -1) { // apply spacing, compute size
for(unsigned int i=0; i<dim; i++) {
- m_OutputSpacing[i] = m_IsoSpacing;
- m_OutputSize[i] = (int)lrint(inputSize[i]*inputSpacing[i]/m_OutputSpacing[i]);
+ if(inputSpacing[i]*m_OutputSpacing[i]<0) {
+ itkExceptionMacro( << "Input and output spacings don't have the same signs, can't cope with that" );
+ }
+ // see comment above for the use of floor()
+ m_OutputSize[i] = (int)floor(inputSize[i]*inputSpacing[i]/m_OutputSpacing[i]);
}
}
else {
- if (m_OutputSpacing[0] != -1) { // apply spacing, compute size
+ if (m_OutputSize[0] != 0) { // apply size, compute spacing
for(unsigned int i=0; i<dim; i++) {
- m_OutputSize[i] = (int)lrint(inputSize[i]*inputSpacing[i]/m_OutputSpacing[i]);
+ m_OutputSpacing[i] = (double)inputSize[i]*inputSpacing[i]/(double)m_OutputSize[i];
}
}
- else {
- if (m_OutputSize[0] != 0) { // apply size, compute spacing
- for(unsigned int i=0; i<dim; i++) {
- m_OutputSpacing[i] = (double)inputSize[i]*inputSpacing[i]/(double)m_OutputSize[i];
- }
- }
- else { // copy input size/spacing ... (no resampling)
- m_OutputSize = inputSize;
- m_OutputSpacing = inputSpacing;
- }
+ else { // copy input size/spacing ... (no resampling)
+ m_OutputSize = inputSize;
+ m_OutputSpacing = inputSpacing;
}
}
+ }
- // Special case for temporal image 2D+t or 3D+t
- if (m_LastDimensionIsTime) {
- int l = dim-1;
- m_OutputSize[l] = inputSize[l];
- m_OutputSpacing[l] = inputSpacing[l];
- }
-
- // Set Size/Spacing
- OutputImagePointer outputImage = this->GetOutput(0);
- OutputImageRegionType region;
- region.SetSize(m_OutputSize);
- region.SetIndex(input->GetLargestPossibleRegion().GetIndex());
- outputImage->SetLargestPossibleRegion(region);
-
- // Init Gaussian sigma
- if (m_GaussianSigma[0] != -1) { // Gaussian filter set by user
- m_GaussianFilteringEnabled = true;
- }
- else {
- if (m_GaussianFilteringEnabled) { // Automated sigma when downsample
- for(unsigned int i=0; i<dim; i++) {
- if (m_OutputSpacing[i] > inputSpacing[i]) { // downsample
- m_GaussianSigma[i] = 0.5*m_OutputSpacing[i];// / inputSpacing[i]);
- }
- else m_GaussianSigma[i] = 0; // will be ignore after
+ // Special case for temporal image 2D+t or 3D+t
+ if (m_LastDimensionIsTime) {
+ int l = dim-1;
+ m_OutputSize[l] = inputSize[l];
+ m_OutputSpacing[l] = inputSpacing[l];
+ }
+
+ // Set Size/Spacing
+ OutputImagePointer outputImage = this->GetOutput(0);
+ // OutputImageRegionType region;
+ m_OutputRegion.SetSize(m_OutputSize);
+ m_OutputRegion.SetIndex(input->GetLargestPossibleRegion().GetIndex());
+ outputImage->CopyInformation(input);
+ outputImage->SetLargestPossibleRegion(m_OutputRegion);
+ outputImage->SetSpacing(m_OutputSpacing);
+
+ // Init Gaussian sigma
+ if (m_GaussianSigma[0] != -1) { // Gaussian filter set by user
+ m_GaussianFilteringEnabled = true;
+ }
+ else {
+ if (m_GaussianFilteringEnabled) { // Automated sigma when downsample
+ for(unsigned int i=0; i<dim; i++) {
+ if (m_OutputSpacing[i] > inputSpacing[i]) { // downsample
+ m_GaussianSigma[i] = 0.5*m_OutputSpacing[i];// / inputSpacing[i]);
}
+ else m_GaussianSigma[i] = 0; // will be ignore after
}
}
- if (m_GaussianFilteringEnabled && m_LastDimensionIsTime) {
- m_GaussianSigma[dim-1] = 0;
- }
}
- //--------------------------------------------------------------------
-
-
- //--------------------------------------------------------------------
- template <class TInputImage, class TOutputImage>
- void
- ResampleImageWithOptionsFilter<TInputImage, TOutputImage>::
- GenerateData() {
-
- // Get input pointer
- InputImagePointer input = dynamic_cast<InputImageType*>(itk::ProcessObject::GetInput(0));
- static const unsigned int dim = InputImageType::ImageDimension;
-
- // Create main Resample Image Filter
- typedef itk::ResampleImageFilter<InputImageType,OutputImageType> FilterType;
- typename FilterType::Pointer filter = FilterType::New();
- filter->GraftOutput(this->GetOutput());
-
- // Print options if needed
- if (m_VerboseOptions) {
- std::cout << "Output Spacing = " << m_OutputSpacing << std::endl
- << "Output Size = " << m_OutputSize << std::endl
- << "Gaussian = " << m_GaussianFilteringEnabled << std::endl;
- if (m_GaussianFilteringEnabled)
- std::cout << "Sigma = " << m_GaussianSigma << std::endl;
- std::cout << "Interpol = ";
- switch (m_InterpolationType) {
- case NearestNeighbor: std::cout << "NearestNeighbor" << std::endl; break;
- case Linear: std::cout << "Linear" << std::endl; break;
- case BSpline: std::cout << "BSpline " << m_BSplineOrder << std::endl; break;
- case B_LUT: std::cout << "B-LUT " << m_BSplineOrder << " " << m_BLUTSamplingFactor << std::endl; break;
- }
- std::cout << "Threads = " << this->GetNumberOfThreads() << std::endl;
- std::cout << "LastDimIsTime = " << m_LastDimensionIsTime << std::endl;
- }
+ if (m_GaussianFilteringEnabled && m_LastDimensionIsTime) {
+ m_GaussianSigma[dim-1] = 0;
+ }
+}
+//--------------------------------------------------------------------
+
+
+//--------------------------------------------------------------------
+template <class InputImageType, class OutputImageType>
+void
+clitk::ResampleImageWithOptionsFilter<InputImageType, OutputImageType>::
+GenerateData()
+{
+
+ // Get input pointer
+ InputImagePointer input = dynamic_cast<InputImageType*>(itk::ProcessObject::GetInput(0));
+ static const unsigned int dim = InputImageType::ImageDimension;
- // Instance of the transform object to be passed to the resample
- // filter. By default, identity transform is applied
- filter->SetTransform(m_Transform);
- filter->SetSize(m_OutputSize);
- filter->SetOutputSpacing(m_OutputSpacing);
- filter->SetOutputOrigin(input->GetOrigin());
- filter->SetDefaultPixelValue(m_DefaultPixelValue);
- filter->SetNumberOfThreads(this->GetNumberOfThreads());
+ // Create main Resample Image Filter
+ typedef itk::ResampleImageFilter<InputImageType,OutputImageType> FilterType;
+ typename FilterType::Pointer filter = FilterType::New();
+ filter->GraftOutput(this->GetOutput());
+ this->GetOutput()->SetBufferedRegion(this->GetOutput()->GetLargestPossibleRegion());
- // Select interpolator
+ // Print options if needed
+ if (m_VerboseOptions) {
+ std::cout << "Output Spacing = " << m_OutputSpacing << std::endl
+ << "Output Size = " << m_OutputSize << std::endl
+ << "Gaussian = " << m_GaussianFilteringEnabled << std::endl;
+ if (m_GaussianFilteringEnabled)
+ std::cout << "Sigma = " << m_GaussianSigma << std::endl;
+ std::cout << "Interpol = ";
switch (m_InterpolationType) {
- case NearestNeighbor:
- {
- typedef itk::NearestNeighborInterpolateImageFunction<InputImageType, double> InterpolatorType;
- typename InterpolatorType::Pointer interpolator = InterpolatorType::New();
- filter->SetInterpolator(interpolator);
- break;
- }
- case Linear:
- {
- typedef itk::LinearInterpolateImageFunction<InputImageType, double> InterpolatorType;
- typename InterpolatorType::Pointer interpolator = InterpolatorType::New();
- filter->SetInterpolator(interpolator);
- break;
- }
- case BSpline:
- {
- typedef itk::BSplineInterpolateImageFunction<InputImageType, double> InterpolatorType;
- typename InterpolatorType::Pointer interpolator = InterpolatorType::New();
- interpolator->SetSplineOrder(m_BSplineOrder);
- filter->SetInterpolator(interpolator);
- break;
- }
- case B_LUT:
- {
- typedef itk::BSplineInterpolateImageFunctionWithLUT<InputImageType, double> InterpolatorType;
- typename InterpolatorType::Pointer interpolator = InterpolatorType::New();
- interpolator->SetSplineOrder(m_BSplineOrder);
- interpolator->SetLUTSamplingFactor(m_BLUTSamplingFactor);
- filter->SetInterpolator(interpolator);
- break;
- }
+ case NearestNeighbor: std::cout << "NearestNeighbor" << std::endl; break;
+ case Linear: std::cout << "Linear" << std::endl; break;
+ case BSpline: std::cout << "BSpline " << m_BSplineOrder << std::endl; break;
+ case B_LUT: std::cout << "B-LUT " << m_BSplineOrder << " " << m_BLUTSamplingFactor << std::endl; break;
+ case WSINC: std::cout << "Windowed Sinc" << std::endl; break;
}
-
- // Initial Gaussian blurring if needed
- typedef itk::RecursiveGaussianImageFilter<InputImageType, InputImageType> GaussianFilterType;
- std::vector<typename GaussianFilterType::Pointer> gaussianFilters;
- if (m_GaussianFilteringEnabled) {
- for(unsigned int i=0; i<dim; i++) {
- if (m_GaussianSigma[i] != 0) {
- gaussianFilters.push_back(GaussianFilterType::New());
- gaussianFilters[i]->SetDirection(i);
- gaussianFilters[i]->SetOrder(GaussianFilterType::ZeroOrder);
- gaussianFilters[i]->SetNormalizeAcrossScale(false);
- gaussianFilters[i]->SetSigma(m_GaussianSigma[i]); // in millimeter !
- if (gaussianFilters.size() == 1) { // first
- gaussianFilters[0]->SetInput(input);
- }
- else {
- gaussianFilters[i]->SetInput(gaussianFilters[i-1]->GetOutput());
- }
+#if ITK_VERSION_MAJOR <= 4
+ std::cout << "Threads = " << this->GetNumberOfThreads() << std::endl;
+#else
+ std::cout << "Threads = " << this->GetNumberOfWorkUnits() << std::endl;
+#endif
+ std::cout << "LastDimIsTime = " << m_LastDimensionIsTime << std::endl;
+ }
+
+ // Compute origin based on image corner
+ for(unsigned int i=0; i<OutputImageType::ImageDimension; i++) {
+ m_OutputOrigin[i] -= 0.5 * input->GetSpacing()[i];
+ m_OutputOrigin[i] += 0.5 * m_OutputSpacing[i];
+ }
+
+ // Instance of the transform object to be passed to the resample
+ // filter. By default, identity transform is applied
+ filter->SetTransform(m_Transform);
+ filter->SetSize(m_OutputSize);
+ filter->SetOutputSpacing(m_OutputSpacing);
+ filter->SetOutputOrigin(m_OutputOrigin);
+ filter->SetDefaultPixelValue(m_DefaultPixelValue);
+#if ITK_VERSION_MAJOR <= 4
+ filter->SetNumberOfThreads(this->GetNumberOfThreads());
+#else
+ filter->SetNumberOfWorkUnits(this->GetNumberOfWorkUnits());
+#endif
+ filter->SetOutputDirection(m_OutputDirection); // <-- NEEDED if we want to keep orientation (in case of PermutAxes for example)
+
+ // Select interpolator
+ switch (m_InterpolationType) {
+ case NearestNeighbor: {
+ typedef itk::NearestNeighborInterpolateImageFunction<InputImageType, double> InterpolatorType;
+ typename InterpolatorType::Pointer interpolator = InterpolatorType::New();
+ filter->SetInterpolator(interpolator);
+ break;
+ }
+ case Linear: {
+ typedef itk::LinearInterpolateImageFunction<InputImageType, double> InterpolatorType;
+ typename InterpolatorType::Pointer interpolator = InterpolatorType::New();
+ filter->SetInterpolator(interpolator);
+ break;
+ }
+ case BSpline: {
+ typedef itk::BSplineInterpolateImageFunction<InputImageType, double> InterpolatorType;
+ typename InterpolatorType::Pointer interpolator = InterpolatorType::New();
+ interpolator->SetSplineOrder(m_BSplineOrder);
+ filter->SetInterpolator(interpolator);
+ break;
+ }
+ case B_LUT: {
+ typedef itk::BSplineInterpolateImageFunctionWithLUT<InputImageType, double> InterpolatorType;
+ typename InterpolatorType::Pointer interpolator = InterpolatorType::New();
+ interpolator->SetSplineOrder(m_BSplineOrder);
+ interpolator->SetLUTSamplingFactor(m_BLUTSamplingFactor);
+ filter->SetInterpolator(interpolator);
+ break;
+ }
+ case WSINC: {
+ typedef itk::WindowedSincInterpolateImageFunction<InputImageType, 4> InterpolatorType;
+ typename InterpolatorType::Pointer interpolator = InterpolatorType::New();
+ filter->SetInterpolator(interpolator);
+ break;
+ }
+ }
+
+ // Initial Gaussian blurring if needed
+ // TODO : replace by itk::DiscreteGaussianImageFilter for small sigma
+ typedef itk::RecursiveGaussianImageFilter<InputImageType, InputImageType> GaussianFilterType;
+ std::vector<typename GaussianFilterType::Pointer> gaussianFilters;
+ if (m_GaussianFilteringEnabled) {
+ for(unsigned int i=0; i<dim; i++) {
+ if (m_GaussianSigma[i] != 0) {
+ gaussianFilters.push_back(GaussianFilterType::New());
+ gaussianFilters[i]->SetDirection(i);
+ gaussianFilters[i]->SetOrder(GaussianFilterType::ZeroOrder);
+ gaussianFilters[i]->SetNormalizeAcrossScale(false);
+ gaussianFilters[i]->SetSigma(m_GaussianSigma[i]); // in millimeter !
+ if (gaussianFilters.size() == 1) { // first
+ gaussianFilters[0]->SetInput(input);
+ } else {
+ gaussianFilters[i]->SetInput(gaussianFilters[i-1]->GetOutput());
}
}
- if (gaussianFilters.size() > 0) {
- filter->SetInput(gaussianFilters[gaussianFilters.size()-1]->GetOutput());
- }
- else filter->SetInput(input);
}
- else filter->SetInput(input);
+ if (gaussianFilters.size() > 0) {
+ filter->SetInput(gaussianFilters[gaussianFilters.size()-1]->GetOutput());
+ } else filter->SetInput(input);
+ } else filter->SetInput(input);
+
+ // Go !
+ filter->Update();
+
+ // Set output
+ this->GraftOutput(filter->GetOutput());
+}
+//--------------------------------------------------------------------
+
- // Go !
- filter->Update();
-
- // Set output
- this->GraftOutput(filter->GetOutput());
+//--------------------------------------------------------------------
+template<class InputImageType>
+typename InputImageType::Pointer
+clitk::ResampleImageSpacing(typename InputImageType::Pointer input,
+ typename InputImageType::SpacingType spacing,
+ int interpolationType)
+{
+ typedef clitk::ResampleImageWithOptionsFilter<InputImageType> ResampleFilterType;
+ typename ResampleFilterType::Pointer resampler = ResampleFilterType::New();
+ resampler->SetInput(input);
+ resampler->SetOutputSpacing(spacing);
+ typename ResampleFilterType::InterpolationTypeEnumeration inter=ResampleFilterType::NearestNeighbor;
+ switch(interpolationType) {
+ case 0: inter = ResampleFilterType::NearestNeighbor; break;
+ case 1: inter = ResampleFilterType::Linear; break;
+ case 2: inter = ResampleFilterType::BSpline; break;
+ case 3: inter = ResampleFilterType::B_LUT; break;
+ case 4: inter = ResampleFilterType::WSINC; break;
}
- //--------------------------------------------------------------------
-
-}//end clitk
-
+ resampler->SetInterpolationType(inter);
+ resampler->SetGaussianFilteringEnabled(true);
+ resampler->Update();
+ return resampler->GetOutput();
+}
+//--------------------------------------------------------------------