------------------------------------------------=*/
//--------------------------------------------------------------------
-template<unsigned int Dim>
-void VFResampleGenericFilter::Update_WithDim() {
-#define TRY_TYPE(TYPE) \
- if (IsSameType<TYPE>(mPixelTypeName)) { Update_WithDimAndPixelType<Dim, TYPE>(); return; }
- TRY_TYPE(float);
-#undef TRY_TYPE
- std::string list = CreateListOfTypes<float, double>();
- std::cerr << "Error, I don't know the type '" << mPixelTypeName << "' for the input image '"
- << mInputFilenames[0] << "'." << std::endl << "Known types are " << list << std::endl;
- exit(0);
-}
-//--------------------------------------------------------------------
-
-//--------------------------------------------------------------------
-template<unsigned int Dim, class PixelType>
-void VFResampleGenericFilter::Update_WithDimAndPixelType() {
-
- if (mNbOfComponents == 1) {
- std::cerr << "Error, only one components ? Use clitkImageResample instead." << std::endl;
- exit(0);
- }
- if (mNbOfComponents == 2) Update_WithDimAndPixelTypeAndComponent<Dim,PixelType,2>();
- if (mNbOfComponents == 3) Update_WithDimAndPixelTypeAndComponent<Dim,PixelType,3>();
- if (mNbOfComponents == 4) Update_WithDimAndPixelTypeAndComponent<Dim,PixelType,4>();
-}
-//--------------------------------------------------------------------
-
-//--------------------------------------------------------------------
-template<unsigned int Dim, class PixelType, unsigned int DimCompo>
-void VFResampleGenericFilter::Update_WithDimAndPixelTypeAndComponent() {
- // Reading input
- typedef itk::Vector<PixelType, DimCompo> DisplacementType;
- typedef itk::Image< DisplacementType, Dim > ImageType;
-
- typename ImageType::Pointer input = clitk::readImage<ImageType>(mInputFilenames, mIOVerbose);
-
- // Main filter
- typename ImageType::Pointer outputImage = ComputeImage<ImageType>(input);
-
- // Write results
- SetNextOutput<ImageType>(outputImage);
-}
-//--------------------------------------------------------------------
-
-//--------------------------------------------------------------------
-template<class ImageType>
-typename ImageType::Pointer
-VFResampleGenericFilter::ComputeImage(typename ImageType::Pointer inputImage) {
-
- // Check options
- static unsigned int dim = ImageType::ImageDimension;
- if (mOutputSize.size() != dim) {
- std::cerr << "Please set size with " << dim << " dimensions." << std::endl;
- return NULL;
- }
- if (mOutputSpacing.size() != dim) {
- std::cerr << "Please set spacing with " << dim << " dimensions." << std::endl;
- return NULL;
- }
- mOutputOrigin.resize(dim);
-
- if (mApplyGaussianFilterBefore && mSigma.size() != dim) {
- std::cerr << "Please set sigma with " << dim << " dimensions." << std::endl;
- return NULL;
- }
-
- // Some typedefs
- typedef typename ImageType::SizeType SizeType;
- typedef typename ImageType::SpacingType SpacingType;
- typedef typename ImageType::PointType PointType;
-
- // Create Image Filter
- typedef itk::VectorResampleImageFilter<ImageType,ImageType> FilterType;
- typename FilterType::Pointer filter = FilterType::New();
-
- // Instance of the transform object to be passed to the resample
- // filter. By default, identity transform is applied
- typedef itk::AffineTransform<double, ImageType::ImageDimension> TransformType;
- typename TransformType::Pointer transform = TransformType::New();
- filter->SetTransform(transform);
-
- // Set filter's parameters
- SizeType outputSize;
- SpacingType outputSpacing;
- PointType outputOrigin;
- for(unsigned int i=0; i<ImageType::ImageDimension; i++) {
- outputSize[i] = mOutputSize[i];
- outputSpacing[i] = mOutputSpacing[i];
- outputOrigin[i] = inputImage->GetOrigin()[i];
- }
-
- filter->SetSize(outputSize);
- filter->SetOutputSpacing(outputSpacing);
- filter->SetOutputOrigin(outputOrigin);
- filter->SetDefaultPixelValue(static_cast<typename ImageType::PixelType>(mDefaultPixelValue));
-
- // Select interpolator
- if (mInterpolatorName == "nn") {
- typedef itk::VectorNearestNeighborInterpolateImageFunction<ImageType, double> InterpolatorType;
- typename InterpolatorType::Pointer interpolator = InterpolatorType::New();
- filter->SetInterpolator(interpolator);
- }
- else {
- if (mInterpolatorName == "linear") {
- typedef itk::VectorLinearInterpolateImageFunction<ImageType, double> InterpolatorType;
- typename InterpolatorType::Pointer interpolator = InterpolatorType::New();
- filter->SetInterpolator(interpolator);
- }
- else {
- std::cerr << "Sorry, I do not know the interpolator (for vector field) '" << mInterpolatorName
- << "'. Known interpolators are : nn, linear" << std::endl;
- exit(0);
- }
- }
-
- // Build initial Gaussian bluring (if needed)
- typedef itk::RecursiveGaussianImageFilter<ImageType, ImageType> GaussianFilterType;
- std::vector<typename GaussianFilterType::Pointer> gaussianFilters;
- if (mApplyGaussianFilterBefore) {
- for(unsigned int i=0; i<ImageType::ImageDimension; i++) {
- // Create filter
- gaussianFilters.push_back(GaussianFilterType::New());
- // Set options
- gaussianFilters[i]->SetDirection(i);
- gaussianFilters[i]->SetOrder(GaussianFilterType::ZeroOrder);
- gaussianFilters[i]->SetNormalizeAcrossScale(false);
- gaussianFilters[i]->SetSigma(mSigma[i]); // in millimeter !
- // Set input
- if (i==0) gaussianFilters[i]->SetInput(inputImage);
- else gaussianFilters[i]->SetInput(gaussianFilters[i-1]->GetOutput());
- }
- filter->SetInput(gaussianFilters[ImageType::ImageDimension-1]->GetOutput());
- }
- else {
- filter->SetInput(inputImage);
- }
-
- // Go !
- try {
- filter->Update();
- }
- catch( itk::ExceptionObject & err ) {
- std::cerr << "Error while filtering " << mInputFilenames[0].c_str()
- << " " << err << std::endl;
- exit(0);
- }
-
- // Return result
- return filter->GetOutput();
-
-}
-//--------------------------------------------------------------------
-
-
#endif /* end #define CLITKVFRESAMPLEGENERICFILTER_TXX */