X-Git-Url: https://git.creatis.insa-lyon.fr/pubgit/?a=blobdiff_plain;f=tools%2FclitkAffineTransformGenericFilter.txx;h=dc4d362dd0e50a0c83a4a2d73f4844de5c14cddb;hb=9259ccb7138d0a678a677c8fccd283563154036e;hp=0fa4869f2af12d9f680373060faa16ccba109f85;hpb=ce0a8e0e49a805729cf3dbb4c9e1c82ee78429ce;p=clitk.git

diff --git a/tools/clitkAffineTransformGenericFilter.txx b/tools/clitkAffineTransformGenericFilter.txx
index 0fa4869..dc4d362 100644
--- a/tools/clitkAffineTransformGenericFilter.txx
+++ b/tools/clitkAffineTransformGenericFilter.txx
@@ -14,451 +14,579 @@
 
   - BSD        See included LICENSE.txt file
   - CeCILL-B   http://www.cecill.info/licences/Licence_CeCILL-B_V1-en.html
-===========================================================================**/
+  ===========================================================================**/
 #ifndef clitkAffineTransformGenericFilter_txx
 #define clitkAffineTransformGenericFilter_txx
 
-/* =================================================
- * @file   clitkAffineTransformGenericFilter.txx
- * @author
- * @date
- *
- * @brief
- *
- ===================================================*/
-
+#include <sstream>
+#include <istream>
+#include <iterator>
+#include <itkCenteredEuler3DTransform.h>
 
 namespace clitk
 {
 
-//-----------------------------------------------------------
-// Constructor
-//-----------------------------------------------------------
-template<class args_info_type>
-AffineTransformGenericFilter<args_info_type>::AffineTransformGenericFilter()
-{
-  m_Verbose=false;
-  m_InputFileName="";
-}
-
-
-//-----------------------------------------------------------
-// Update
-//-----------------------------------------------------------
-template<class args_info_type>
-void AffineTransformGenericFilter<args_info_type>::Update()
-{
-  // Read the Dimension and PixelType
-  int Dimension, Components;
-  std::string PixelType;
-  ReadImageDimensionAndPixelType(m_InputFileName, Dimension, PixelType, Components);
-
-
-  // Call UpdateWithDim
-  if(Dimension==2) UpdateWithDim<2>(PixelType, Components);
-  else if(Dimension==3) UpdateWithDim<3>(PixelType, Components);
-  else if (Dimension==4)UpdateWithDim<4>(PixelType, Components);
-  else {
-    std::cout<<"Error, Only for 2, 3 or 4  Dimensions!!!"<<std::endl ;
-    return;
+  //-----------------------------------------------------------
+  // Constructor
+  //-----------------------------------------------------------
+  template<class args_info_type>
+  AffineTransformGenericFilter<args_info_type>::AffineTransformGenericFilter()
+  {
+    m_Verbose=false;
+    m_InputFileName="";
   }
-}
-
-//-------------------------------------------------------------------
-// Update with the number of dimensions
-//-------------------------------------------------------------------
-template<class args_info_type>
-template<unsigned int Dimension>
-void
-AffineTransformGenericFilter<args_info_type>::UpdateWithDim(std::string PixelType, int Components)
-{
-  if (m_Verbose) std::cout << "Image was detected to be "<<Dimension<<"D and "<<Components<<" component(s) of "<<  PixelType<<"..."<<std::endl;
-
-  if (Components==1) {
-    if(PixelType == "short") {
-      if (m_Verbose) std::cout << "Launching filter in "<< Dimension <<"D and signed short..." << std::endl;
-      UpdateWithDimAndPixelType<Dimension, signed short>();
-    }
-    //    else if(PixelType == "unsigned_short"){
-    //       if (m_Verbose) std::cout  << "Launching filter in "<< Dimension <<"D and unsigned_short..." << std::endl;
-    //       UpdateWithDimAndPixelType<Dimension, unsigned short>();
-    //     }
-
-    else if (PixelType == "unsigned_char") {
-      if (m_Verbose) std::cout  << "Launching filter in "<< Dimension <<"D and unsigned_char..." << std::endl;
-      UpdateWithDimAndPixelType<Dimension, unsigned char>();
-    }
-
-    //     else if (PixelType == "char"){
-    //       if (m_Verbose) std::cout  << "Launching filter in "<< Dimension <<"D and signed_char..." << std::endl;
-    //       UpdateWithDimAndPixelType<Dimension, signed char>();
-    //     }
+  //-------------------------------------------------------------------
+ 
+
+  //-----------------------------------------------------------
+  // Update
+  //-----------------------------------------------------------
+  template<class args_info_type>
+  void AffineTransformGenericFilter<args_info_type>::Update()
+  {
+    // Read the Dimension and PixelType
+    int Dimension, Components;
+    std::string PixelType;
+    ReadImageDimensionAndPixelType(m_InputFileName, Dimension, PixelType, Components);
+
+    // Call UpdateWithDim
+    if(Dimension==2) UpdateWithDim<2>(PixelType, Components);
+    else 
+    if(Dimension==3) UpdateWithDim<3>(PixelType, Components);
+    else if (Dimension==4)UpdateWithDim<4>(PixelType, Components);
     else {
-      if (m_Verbose) std::cout  << "Launching filter in "<< Dimension <<"D and float..." << std::endl;
-      UpdateWithDimAndPixelType<Dimension, float>();
+      std::cout<<"Error, Only for 2, 3 or 4  Dimensions!!!"<<std::endl ;
+      return;
     }
   }
+  //-------------------------------------------------------------------
+ 
+
+  //-------------------------------------------------------------------
+  // Update with the number of dimensions
+  //-------------------------------------------------------------------
+  template<class args_info_type>
+  template<unsigned int Dimension>
+  void
+  AffineTransformGenericFilter<args_info_type>::UpdateWithDim(std::string PixelType, int Components)
+  {
+    if (m_Verbose) std::cout << "Image was detected to be "<<Dimension<<"D and "<<Components<<" component(s) of "<<  PixelType<<"..."<<std::endl;
 
-  else if (Components==3) {
-    if (m_Verbose) std::cout  << "Launching transform in "<< Dimension <<"D and 3D float (DVF)" << std::endl;
-    UpdateWithDimAndVectorType<Dimension, itk::Vector<float, Dimension> >();
-  }
-
-  else std::cerr<<"Number of components is "<<Components<<", not supported!"<<std::endl;
-
-}
+    if (Components==1) {
+      if(PixelType == "short") {
+        if (m_Verbose) std::cout << "Launching filter in "<< Dimension <<"D and signed short..." << std::endl;
+        UpdateWithDimAndPixelType<Dimension, signed short>();
+      }
+      //    else if(PixelType == "unsigned_short"){
+      //       if (m_Verbose) std::cout  << "Launching filter in "<< Dimension <<"D and unsigned_short..." << std::endl;
+      //       UpdateWithDimAndPixelType<Dimension, unsigned short>();
+      //     }
+
+      else if (PixelType == "unsigned_char") {
+        if (m_Verbose) std::cout  << "Launching filter in "<< Dimension <<"D and unsigned_char..." << std::endl;
+        UpdateWithDimAndPixelType<Dimension, unsigned char>();
+      }
 
+      //     else if (PixelType == "char"){
+      //       if (m_Verbose) std::cout  << "Launching filter in "<< Dimension <<"D and signed_char..." << std::endl;
+      //       UpdateWithDimAndPixelType<Dimension, signed char>();
+      //     }
+      else {
+        if (m_Verbose) std::cout  << "Launching filter in "<< Dimension <<"D and float..." << std::endl;
+        UpdateWithDimAndPixelType<Dimension, float>();
+      }
+    }
 
-//-------------------------------------------------------------------
-// Update with the number of dimensions and the pixeltype
-//-------------------------------------------------------------------
-template<class args_info_type>
-template <unsigned int Dimension, class  PixelType>
-void
-AffineTransformGenericFilter<args_info_type>::UpdateWithDimAndPixelType()
-{
+    else if (Components==3) {
+      if (m_Verbose) std::cout  << "Launching transform in "<< Dimension <<"D and 3D float (DVF)" << std::endl;
+      UpdateWithDimAndVectorType<Dimension, itk::Vector<float, Dimension> >();
+    }
 
-  // ImageTypes
-  typedef itk::Image<PixelType, Dimension> InputImageType;
-  typedef itk::Image<PixelType, Dimension> OutputImageType;
+    else std::cerr<<"Number of components is "<<Components<<", not supported!"<<std::endl;
 
-  // Read the input
-  typedef itk::ImageFileReader<InputImageType> InputReaderType;
-  typename InputReaderType::Pointer reader = InputReaderType::New();
-  reader->SetFileName( m_InputFileName);
-  reader->Update();
-  typename InputImageType::Pointer input= reader->GetOutput();
+  }
+  //-------------------------------------------------------------------
+ 
+
+  //-------------------------------------------------------------------
+  // Update with the number of dimensions and the pixeltype
+  //-------------------------------------------------------------------
+  template<class args_info_type>
+  template <unsigned int Dimension, class  PixelType>
+  void
+  AffineTransformGenericFilter<args_info_type>::UpdateWithDimAndPixelType()
+  {
 
-  //Filter
-  typedef  itk::ResampleImageFilter< InputImageType,OutputImageType >  ResampleFilterType;
-  typename ResampleFilterType::Pointer resampler = ResampleFilterType::New();
+    // ImageTypes
+    typedef itk::Image<PixelType, Dimension> InputImageType;
+    typedef itk::Image<PixelType, Dimension> OutputImageType;
+
+    // Read the input
+    typedef itk::ImageFileReader<InputImageType> InputReaderType;
+    typename InputReaderType::Pointer reader = InputReaderType::New();
+    reader->SetFileName( m_InputFileName);
+    reader->Update();
+    typename InputImageType::Pointer input= reader->GetOutput();
+
+    //Filter
+    typedef  itk::ResampleImageFilter< InputImageType,OutputImageType >  ResampleFilterType;
+    typename ResampleFilterType::Pointer resampler = ResampleFilterType::New();
+
+    // Matrix
+    typename itk::Matrix<double, Dimension+1, Dimension+1> matrix;
+    if (m_ArgsInfo.rotate_given || m_ArgsInfo.translate_given)
+      {
+        if (m_ArgsInfo.matrix_given)
+          {
+            std::cerr << "You must use either rotate/translate or matrix options" << std::cout;
+            return;
+          }
+        itk::Array<double> transformParameters(2 * Dimension);
+        transformParameters.Fill(0.0);
+        if (m_ArgsInfo.rotate_given)
+          {
+            if (Dimension == 2)
+              transformParameters[0] = m_ArgsInfo.rotate_arg[0];
+            else
+              for (unsigned int i = 0; i < 3; i++)
+                transformParameters[i] = m_ArgsInfo.rotate_arg[i];
+          }
+        if (m_ArgsInfo.translate_given)
+          {
+            int pos = 3;
+            if (Dimension == 2)
+              pos = 1;
+            for (unsigned int i = 0; i < Dimension && i < 3; i++)
+              transformParameters[pos++] = m_ArgsInfo.translate_arg[i];
+          }
+        if (Dimension == 4)
+          {
+            matrix.SetIdentity();
+            itk::Matrix<double, 4, 4> tmp = GetForwardAffineMatrix3D(transformParameters);
+            for (unsigned int i = 0; i < 3; ++i)
+              for (unsigned int j = 0; j < 3; ++j)
+                matrix[i][j] = tmp[i][j];
+            for (unsigned int i = 0; i < 3; ++i)
+              matrix[i][4] = tmp[i][3];
+          }
+        else
+          matrix = GetForwardAffineMatrix<Dimension>(transformParameters);
+      }
+    else
+      {
+        if (m_ArgsInfo.matrix_given)
+          {
+            matrix= clitk::ReadMatrix<Dimension>(m_ArgsInfo.matrix_arg);
+            if (m_Verbose) std::cout << "Reading the matrix..." << std::endl;
+          }
+        else {
+          if (m_ArgsInfo.elastix_given) {
+            matrix = createMatrixFromElastixFile<Dimension,PixelType>(m_ArgsInfo.elastix_arg);
+          }
+          else 
+            matrix.SetIdentity();
+        }
+      }
+    if (m_Verbose)
+      std::cout << "Using the following matrix:" << std::endl
+                << matrix << std::endl;
+    typename itk::Matrix<double, Dimension, Dimension> rotationMatrix = clitk::GetRotationalPartMatrix(matrix);
+    typename itk::Vector<double, Dimension> translationPart = clitk::GetTranslationPartMatrix(matrix);
+
+    // Transform
+    typedef itk::AffineTransform<double, Dimension> AffineTransformType;
+    typename AffineTransformType::Pointer affineTransform=AffineTransformType::New();
+    affineTransform->SetMatrix(rotationMatrix);
+    affineTransform->SetTranslation(translationPart);
+
+    // Interp
+    typedef clitk::GenericInterpolator<args_info_type, InputImageType, double> GenericInterpolatorType;
+    typename GenericInterpolatorType::Pointer genericInterpolator=GenericInterpolatorType::New();
+    genericInterpolator->SetArgsInfo(m_ArgsInfo);
+
+    // Properties
+    if (m_ArgsInfo.like_given) {
+      typename InputReaderType::Pointer likeReader=InputReaderType::New();
+      likeReader->SetFileName(m_ArgsInfo.like_arg);
+      likeReader->Update();
+      resampler->SetOutputParametersFromImage(likeReader->GetOutput());
+    } else if(m_ArgsInfo.transform_grid_flag) {
+      typename itk::Matrix<double, Dimension+1, Dimension+1> invMatrix( matrix.GetInverse() );
+      typename itk::Matrix<double, Dimension, Dimension> invRotMatrix( clitk::GetRotationalPartMatrix(invMatrix) );
+      typename itk::Vector<double,Dimension> invTrans =  clitk::GetTranslationPartMatrix(invMatrix);
+      
+      // Display warning
+      if (m_ArgsInfo.spacing_given)
+        std::cout << "Warning --spacing ignored (because --transform_grid_flag)" << std::endl;
+      if (m_ArgsInfo.origin_given)
+        std::cout << "Warning --origin ignored (because --transform_grid_flag)" << std::endl;
+
+      // Spacing is influenced by affine transform matrix and input direction
+      typename InputImageType::SpacingType outputSpacing;
+      outputSpacing = invRotMatrix *
+        input->GetDirection() *
+        input->GetSpacing();
+
+      // Origin is influenced by translation but not by input direction
+      typename InputImageType::PointType outputOrigin;
+      outputOrigin = invRotMatrix *
+        input->GetOrigin() +
+        invTrans;
+
+      // Size is influenced by affine transform matrix and input direction
+      // Size is converted to double, transformed and converted back to size type.
+      vnl_vector<double> vnlOutputSize(Dimension);
+      for(unsigned int i=0; i< Dimension; i++) {
+        vnlOutputSize[i] = input->GetLargestPossibleRegion().GetSize()[i];
+      }
+      vnlOutputSize = invRotMatrix *
+        input->GetDirection().GetVnlMatrix() *
+        vnlOutputSize;
+      typename OutputImageType::SizeType outputSize;
+      for(unsigned int i=0; i< Dimension; i++) {
+        // If the size is negative, we have a flip and we must modify
+        // the origin and the spacing accordingly.
+        if(vnlOutputSize[i]<0.) {
+          vnlOutputSize[i] *= -1.;
+          outputOrigin[i] = outputOrigin[i] + outputSpacing[i] * (vnlOutputSize[i]-1);
+          outputSpacing[i] *= -1.;
+        }
+        outputSize[i] = lrint(vnlOutputSize[i]);
+      }
+      resampler->SetSize( outputSize );
+      resampler->SetOutputSpacing( outputSpacing );
+      resampler->SetOutputOrigin( outputOrigin );
+    } else {
+      //Size
+      typename OutputImageType::SizeType outputSize;
+      if (m_ArgsInfo.size_given) {
+        for(unsigned int i=0; i< Dimension; i++)
+          outputSize[i]=m_ArgsInfo.size_arg[i];
+      } else outputSize=input->GetLargestPossibleRegion().GetSize();
+
+      //Spacing
+      typename OutputImageType::SpacingType outputSpacing;
+      if (m_ArgsInfo.spacing_given) {
+        for(unsigned int i=0; i< Dimension; i++)
+          outputSpacing[i]=m_ArgsInfo.spacing_arg[i];
+      } else outputSpacing=input->GetSpacing();
+
+      //Origin
+      typename OutputImageType::PointType outputOrigin;
+      if (m_ArgsInfo.origin_given) {
+        for(unsigned int i=0; i< Dimension; i++)
+          outputOrigin[i]=m_ArgsInfo.origin_arg[i];
+      } else outputOrigin=input->GetOrigin();
+
+      // Set
+      resampler->SetSize( outputSize );
+      resampler->SetOutputSpacing( outputSpacing );
+      resampler->SetOutputOrigin(  outputOrigin );
 
-  // Matrix
-  typename itk::Matrix<double, Dimension+1, Dimension+1> matrix;
-  if (m_ArgsInfo.rotate_given || m_ArgsInfo.translate_given)
-  {
-    if (m_ArgsInfo.matrix_given)
-    {
-      std::cerr << "You must use either rotate/translate or matrix options" << std::cout;
-      return;
     }
-    itk::Array<double> transformParameters(2 * Dimension);
-    transformParameters.Fill(0.0);
-    if (m_ArgsInfo.rotate_given)
-    {
-      if (Dimension == 2)
-        transformParameters[0] = m_ArgsInfo.rotate_arg[0];
-      else
-        for (unsigned int i = 0; i < 3; i++)
-          transformParameters[i] = m_ArgsInfo.rotate_arg[i];
+
+    if (m_ArgsInfo.spacinglike_given) {
+      typename InputReaderType::Pointer likeReader=InputReaderType::New();
+      likeReader->SetFileName(m_ArgsInfo.spacinglike_arg);
+      likeReader->Update(); 
+      resampler->SetOutputSpacing( likeReader->GetOutput()->GetSpacing() );
     }
-    if (m_ArgsInfo.translate_given)
-    {
-      int pos = 3;
-      if (Dimension == 2)
-        pos = 1;
-      for (unsigned int i = 0; i < Dimension && i < 3; i++)
-        transformParameters[pos++] = m_ArgsInfo.translate_arg[i];
+
+    if (m_ArgsInfo.verbose_flag) {
+      std::cout << "Setting the output size to " << resampler->GetSize() << "..." << std::endl;
+      std::cout << "Setting the output spacing to " << resampler->GetOutputSpacing() << "..." << std::endl;
+      std::cout << "Setting the output origin to " << resampler->GetOutputOrigin() << "..." << std::endl;
     }
-    if (Dimension == 4)
-    {
-      matrix.SetIdentity();
-      itk::Matrix<double, 4, 4> tmp = GetForwardAffineMatrix3D(transformParameters);
-      for (unsigned int i = 0; i < 3; ++i)
-        for (unsigned int j = 0; j < 3; ++j)
-          matrix[i][j] = tmp[i][j];
-      for (unsigned int i = 0; i < 3; ++i)
-        matrix[i][4] = tmp[i][3];
+
+    resampler->SetInput( input );
+    resampler->SetTransform( affineTransform );
+    resampler->SetInterpolator( genericInterpolator->GetInterpolatorPointer());
+    resampler->SetDefaultPixelValue( static_cast<PixelType>(m_ArgsInfo.pad_arg) );
+
+    try {
+      resampler->Update();
+    } catch(itk::ExceptionObject) {
+      std::cerr<<"Error resampling the image"<<std::endl;
     }
-    else
-      matrix = GetForwardAffineMatrix<Dimension>(transformParameters);
+
+    typename OutputImageType::Pointer output = resampler->GetOutput();
+
+    // Output
+    typedef itk::ImageFileWriter<OutputImageType> WriterType;
+    typename WriterType::Pointer writer = WriterType::New();
+    writer->SetFileName(m_ArgsInfo.output_arg);
+    writer->SetInput(output);
+    writer->Update();
+
   }
-  else
+  //-------------------------------------------------------------------
+    
+
+  //-------------------------------------------------------------------
+  // Update with the number of dimensions and the pixeltype (components)
+  //-------------------------------------------------------------------
+  template<class args_info_type>
+  template<unsigned int Dimension, class PixelType>
+  void AffineTransformGenericFilter<args_info_type>::UpdateWithDimAndVectorType()
   {
-    if (m_ArgsInfo.matrix_given)
-    {
-      matrix= clitk::ReadMatrix<Dimension>(m_ArgsInfo.matrix_arg);
-      if (m_Verbose) std::cout << "Reading the matrix..." << std::endl;
-    }
+    // ImageTypes
+    typedef itk::Image<PixelType, Dimension> InputImageType;
+    typedef itk::Image<PixelType, Dimension> OutputImageType;
+
+    // Read the input
+    typedef itk::ImageFileReader<InputImageType> InputReaderType;
+    typename InputReaderType::Pointer reader = InputReaderType::New();
+    reader->SetFileName( m_InputFileName);
+    reader->Update();
+    typename InputImageType::Pointer input= reader->GetOutput();
+
+    //Filter
+    typedef  itk::VectorResampleImageFilter< InputImageType,OutputImageType, double >  ResampleFilterType;
+    typename ResampleFilterType::Pointer resampler = ResampleFilterType::New();
+
+    // Matrix
+    typename itk::Matrix<double, Dimension+1, Dimension+1> matrix;
+    if (m_ArgsInfo.rotate_given || m_ArgsInfo.translate_given)
+      {
+        if (m_ArgsInfo.matrix_given)
+          {
+            std::cerr << "You must use either rotate/translate or matrix options" << std::cout;
+            return;
+          }
+        itk::Array<double> transformParameters(2 * Dimension);
+        transformParameters.Fill(0.0);
+        if (m_ArgsInfo.rotate_given)
+          {
+            if (Dimension == 2)
+              transformParameters[0] = m_ArgsInfo.rotate_arg[0];
+            else
+              for (unsigned int i = 0; i < 3; i++)
+                transformParameters[i] = m_ArgsInfo.rotate_arg[i];
+          }
+        if (m_ArgsInfo.translate_given)
+          {
+            int pos = 3;
+            if (Dimension == 2)
+              pos = 1;
+            for (unsigned int i = 0; i < Dimension && i < 3; i++)
+              transformParameters[pos++] = m_ArgsInfo.translate_arg[i];
+          }
+        if (Dimension == 4)
+          {
+            matrix.SetIdentity();
+            itk::Matrix<double, 4, 4> tmp = GetForwardAffineMatrix3D(transformParameters);
+            for (unsigned int i = 0; i < 3; ++i)
+              for (unsigned int j = 0; j < 3; ++j)
+                matrix[i][j] = tmp[i][j];
+            for (unsigned int i = 0; i < 3; ++i)
+              matrix[i][4] = tmp[i][3];
+          }
+        else
+          matrix = GetForwardAffineMatrix<Dimension>(transformParameters);
+      }
     else
-      matrix.SetIdentity();
-  }
-  if (m_Verbose)
-    std::cout << "Using the following matrix:" << std::endl
-              << matrix << std::endl;
-  typename itk::Matrix<double, Dimension, Dimension> rotationMatrix = clitk::GetRotationalPartMatrix(matrix);
-  typename itk::Vector<double, Dimension> translationPart = clitk::GetTranslationPartMatrix(matrix);
-
-  // Transform
-  typedef itk::AffineTransform<double, Dimension> AffineTransformType;
-  typename AffineTransformType::Pointer affineTransform=AffineTransformType::New();
-  affineTransform->SetMatrix(rotationMatrix);
-  affineTransform->SetTranslation(translationPart);
-
-  // Interp
-  typedef clitk::GenericInterpolator<args_info_type, InputImageType, double> GenericInterpolatorType;
-  typename GenericInterpolatorType::Pointer genericInterpolator=GenericInterpolatorType::New();
-  genericInterpolator->SetArgsInfo(m_ArgsInfo);
-
-  // Properties
-  if (m_ArgsInfo.like_given) {
-    typename InputReaderType::Pointer likeReader=InputReaderType::New();
-    likeReader->SetFileName(m_ArgsInfo.like_arg);
-    likeReader->Update();
-    resampler->SetOutputParametersFromImage(likeReader->GetOutput());
-  } else if(m_ArgsInfo.transform_grid_flag) {
-    typename itk::Matrix<double, Dimension+1, Dimension+1> invMatrix( matrix.GetInverse() );
-    typename itk::Matrix<double, Dimension, Dimension> invRotMatrix( clitk::GetRotationalPartMatrix(invMatrix) );
-    typename itk::Vector<double,Dimension> invTrans =  clitk::GetTranslationPartMatrix(invMatrix);
-
-    // Display warning
-    if (m_ArgsInfo.spacing_given)
-      std::cout << "Warning --spacing ignored (because --transform_grid_flag)" << std::endl;
-    if (m_ArgsInfo.origin_given)
-      std::cout << "Warning --origin ignored (because --transform_grid_flag)" << std::endl;
-
-    // Spacing is influenced by affine transform matrix and input direction
-    typename InputImageType::SpacingType outputSpacing;
-    outputSpacing = invRotMatrix *
-                    input->GetDirection() *
-                    input->GetSpacing();
-
-    // Origin is influenced by translation but not by input direction
-    typename InputImageType::PointType outputOrigin;
-    outputOrigin = invRotMatrix *
-                   input->GetOrigin() +
-                   invTrans;
-
-    // Size is influenced by affine transform matrix and input direction
-    // Size is converted to double, transformed and converted back to size type.
-    vnl_vector<double> vnlOutputSize(Dimension);
-    for(unsigned int i=0; i< Dimension; i++) {
-      vnlOutputSize[i] = input->GetLargestPossibleRegion().GetSize()[i];
-    }
-    vnlOutputSize = invRotMatrix *
-                    input->GetDirection().GetVnlMatrix() *
-                    vnlOutputSize;
-    typename OutputImageType::SizeType outputSize;
-    for(unsigned int i=0; i< Dimension; i++) {
-      // If the size is negative, we have a flip and we must modify
-      // the origin and the spacing accordingly.
-      if(vnlOutputSize[i]<0.) {
-        vnlOutputSize[i] *= -1.;
-        outputOrigin[i] = outputOrigin[i] + outputSpacing[i] * (vnlOutputSize[i]-1);
-        outputSpacing[i] *= -1.;
+      {
+        if (m_ArgsInfo.matrix_given)
+          {
+            matrix= clitk::ReadMatrix<Dimension>(m_ArgsInfo.matrix_arg);
+            if (m_Verbose) std::cout << "Reading the matrix..." << std::endl;
+          }
+        else
+          matrix.SetIdentity();
       }
-      outputSize[i] = lrint(vnlOutputSize[i]);
+    if (m_Verbose)
+      std::cout << "Using the following matrix:" << std::endl
+                << matrix << std::endl;
+    typename itk::Matrix<double, Dimension, Dimension> rotationMatrix = clitk::GetRotationalPartMatrix(matrix);
+    typename itk::Vector<double, Dimension> translationPart = clitk::GetTranslationPartMatrix(matrix);
+
+    // Transform
+    typedef itk::AffineTransform<double, Dimension> AffineTransformType;
+    typename AffineTransformType::Pointer affineTransform=AffineTransformType::New();
+    affineTransform->SetMatrix(rotationMatrix);
+    affineTransform->SetTranslation(translationPart);
+
+    // Interp
+    typedef clitk::GenericVectorInterpolator<args_info_type, InputImageType, double> GenericInterpolatorType;
+    typename GenericInterpolatorType::Pointer genericInterpolator=GenericInterpolatorType::New();
+    genericInterpolator->SetArgsInfo(m_ArgsInfo);
+
+    // Properties
+    if (m_ArgsInfo.like_given) {
+      typename InputReaderType::Pointer likeReader=InputReaderType::New();
+      likeReader->SetFileName(m_ArgsInfo.like_arg);
+      likeReader->Update();
+      resampler->SetSize( likeReader->GetOutput()->GetLargestPossibleRegion().GetSize() );
+      resampler->SetOutputSpacing( likeReader->GetOutput()->GetSpacing() );
+      resampler->SetOutputOrigin(  likeReader->GetOutput()->GetOrigin() );
+    } else {
+      //Size
+      typename OutputImageType::SizeType outputSize;
+      if (m_ArgsInfo.size_given) {
+        for(unsigned int i=0; i< Dimension; i++)
+          outputSize[i]=m_ArgsInfo.size_arg[i];
+      } else outputSize=input->GetLargestPossibleRegion().GetSize();
+      std::cout<<"Setting the size to "<<outputSize<<"..."<<std::endl;
+
+      //Spacing
+      typename OutputImageType::SpacingType outputSpacing;
+      if (m_ArgsInfo.spacing_given) {
+        for(unsigned int i=0; i< Dimension; i++)
+          outputSpacing[i]=m_ArgsInfo.spacing_arg[i];
+      } else outputSpacing=input->GetSpacing();
+      std::cout<<"Setting the spacing to "<<outputSpacing<<"..."<<std::endl;
+
+      //Origin
+      typename OutputImageType::PointType outputOrigin;
+      if (m_ArgsInfo.origin_given) {
+        for(unsigned int i=0; i< Dimension; i++)
+          outputOrigin[i]=m_ArgsInfo.origin_arg[i];
+      } else outputOrigin=input->GetOrigin();
+      std::cout<<"Setting the origin to "<<outputOrigin<<"..."<<std::endl;
+
+      // Set
+      resampler->SetSize( outputSize );
+      resampler->SetOutputSpacing( outputSpacing );
+      resampler->SetOutputOrigin(  outputOrigin );
+
     }
-    resampler->SetSize( outputSize );
-    resampler->SetOutputSpacing( outputSpacing );
-    resampler->SetOutputOrigin( outputOrigin );
-  } else {
-    //Size
-    typename OutputImageType::SizeType outputSize;
-    if (m_ArgsInfo.size_given) {
-      for(unsigned int i=0; i< Dimension; i++)
-        outputSize[i]=m_ArgsInfo.size_arg[i];
-    } else outputSize=input->GetLargestPossibleRegion().GetSize();
-
-    //Spacing
-    typename OutputImageType::SpacingType outputSpacing;
-    if (m_ArgsInfo.spacing_given) {
-      for(unsigned int i=0; i< Dimension; i++)
-        outputSpacing[i]=m_ArgsInfo.spacing_arg[i];
-    } else outputSpacing=input->GetSpacing();
-
-    //Origin
-    typename OutputImageType::PointType outputOrigin;
-    if (m_ArgsInfo.origin_given) {
-      for(unsigned int i=0; i< Dimension; i++)
-        outputOrigin[i]=m_ArgsInfo.origin_arg[i];
-    } else outputOrigin=input->GetOrigin();
-
-    // Set
-    resampler->SetSize( outputSize );
-    resampler->SetOutputSpacing( outputSpacing );
-    resampler->SetOutputOrigin(  outputOrigin );
 
-  }
+    resampler->SetInput( input );
+    resampler->SetTransform( affineTransform );
+    resampler->SetInterpolator( genericInterpolator->GetInterpolatorPointer());
+    resampler->SetDefaultPixelValue( static_cast<PixelType>(m_ArgsInfo.pad_arg) );
 
-  if (m_ArgsInfo.verbose_flag) {
-    std::cout << "Setting the output size to " << resampler->GetSize() << "..." << std::endl;
-    std::cout << "Setting the output spacing to " << resampler->GetOutputSpacing() << "..." << std::endl;
-    std::cout << "Setting the output origin to " << resampler->GetOutputOrigin() << "..." << std::endl;
-  }
+    try {
+      resampler->Update();
+    } catch(itk::ExceptionObject) {
+      std::cerr<<"Error resampling the image"<<std::endl;
+    }
 
-  resampler->SetInput( input );
-  resampler->SetTransform( affineTransform );
-  resampler->SetInterpolator( genericInterpolator->GetInterpolatorPointer());
-  resampler->SetDefaultPixelValue( static_cast<PixelType>(m_ArgsInfo.pad_arg) );
+    typename OutputImageType::Pointer output = resampler->GetOutput();
 
-  try {
-    resampler->Update();
-  } catch(itk::ExceptionObject) {
-    std::cerr<<"Error resampling the image"<<std::endl;
-  }
+    // Output
+    typedef itk::ImageFileWriter<OutputImageType> WriterType;
+    typename WriterType::Pointer writer = WriterType::New();
+    writer->SetFileName(m_ArgsInfo.output_arg);
+    writer->SetInput(output);
+    writer->Update();
 
-  typename OutputImageType::Pointer output = resampler->GetOutput();
-
-  // Output
-  typedef itk::ImageFileWriter<OutputImageType> WriterType;
-  typename WriterType::Pointer writer = WriterType::New();
-  writer->SetFileName(m_ArgsInfo.output_arg);
-  writer->SetInput(output);
-  writer->Update();
+  }
+  //-------------------------------------------------------------------
+  
+  
+  //-------------------------------------------------------------------
+  template<class args_info_type>
+  template<unsigned int Dimension, class PixelType>
+  typename itk::Matrix<double, Dimension+1, Dimension+1>
+   AffineTransformGenericFilter<args_info_type>::createMatrixFromElastixFile(std::string filename)
+  {
+    if (Dimension != 3) {
+      FATAL("Only 3D yet" << std::endl);
+    }
+    typename itk::Matrix<double, Dimension+1, Dimension+1> matrix;
 
-}
+    // Open file
+    std::ifstream is;
+    clitk::openFileForReading(is, filename);
 
-//-------------------------------------------------------------------
-// Update with the number of dimensions and the pixeltype (components)
-//-------------------------------------------------------------------
-template<class args_info_type>
-template<unsigned int Dimension, class PixelType>
-void AffineTransformGenericFilter<args_info_type>::UpdateWithDimAndVectorType()
-{
-  // ImageTypes
-  typedef itk::Image<PixelType, Dimension> InputImageType;
-  typedef itk::Image<PixelType, Dimension> OutputImageType;
-
-  // Read the input
-  typedef itk::ImageFileReader<InputImageType> InputReaderType;
-  typename InputReaderType::Pointer reader = InputReaderType::New();
-  reader->SetFileName( m_InputFileName);
-  reader->Update();
-  typename InputImageType::Pointer input= reader->GetOutput();
-
-  //Filter
-  typedef  itk::VectorResampleImageFilter< InputImageType,OutputImageType, double >  ResampleFilterType;
-  typename ResampleFilterType::Pointer resampler = ResampleFilterType::New();
-
-  // Matrix
-  typename itk::Matrix<double, Dimension+1, Dimension+1> matrix;
-  if (m_ArgsInfo.rotate_given || m_ArgsInfo.translate_given)
-  {
-    if (m_ArgsInfo.matrix_given)
-    {
-      std::cerr << "You must use either rotate/translate or matrix options" << std::cout;
-      return;
+    // Check Transform
+    std::string s; 
+    bool b = GetElastixValueFromTag(is, "Transform ", s);
+    if (!b) {
+      FATAL("Error must read 'Transform' in " << filename << std::endl);
     }
-    itk::Array<double> transformParameters(2 * Dimension);
-    transformParameters.Fill(0.0);
-    if (m_ArgsInfo.rotate_given)
-    {
-      if (Dimension == 2)
-        transformParameters[0] = m_ArgsInfo.rotate_arg[0];
-      else
-        for (unsigned int i = 0; i < 3; i++)
-          transformParameters[i] = m_ArgsInfo.rotate_arg[i];
+    if (s != "EulerTransform") {
+      FATAL("Sorry only 'EulerTransform'" << std::endl);
     }
-    if (m_ArgsInfo.translate_given)
-    {
-      int pos = 3;
-      if (Dimension == 2)
-        pos = 1;
-      for (unsigned int i = 0; i < Dimension && i < 3; i++)
-        transformParameters[pos++] = m_ArgsInfo.translate_arg[i];
+
+    // FIXME check
+    //    (InitialTransformParametersFileName "NoInitialTransform")
+
+    // Get CenterOfRotationPoint
+    GetElastixValueFromTag(is, "CenterOfRotationPoint ", s); // space is needed
+    if (!b) {
+      FATAL("Error must read 'CenterOfRotationPoint' in " << filename << std::endl);
     }
-    if (Dimension == 4)
-    {
-      matrix.SetIdentity();
-      itk::Matrix<double, 4, 4> tmp = GetForwardAffineMatrix3D(transformParameters);
-      for (unsigned int i = 0; i < 3; ++i)
-        for (unsigned int j = 0; j < 3; ++j)
-          matrix[i][j] = tmp[i][j];
-      for (unsigned int i = 0; i < 3; ++i)
-        matrix[i][4] = tmp[i][3];
+    std::vector<std::string> cor; 
+    GetValuesFromValue(s, cor);
+
+    // Get Transformparameters
+    GetElastixValueFromTag(is, "TransformParameters ", s); // space is needed
+    if (!b) {
+      FATAL("Error must read 'TransformParameters' in " << filename << std::endl);
     }
-    else
-      matrix = GetForwardAffineMatrix<Dimension>(transformParameters);
-  }
-  else
-  {
-    if (m_ArgsInfo.matrix_given)
-    {
-      matrix= clitk::ReadMatrix<Dimension>(m_ArgsInfo.matrix_arg);
-      if (m_Verbose) std::cout << "Reading the matrix..." << std::endl;
+    std::vector<std::string> results; 
+    GetValuesFromValue(s, results);
+    
+    // construct a stream from the string
+    itk::CenteredEuler3DTransform<double>::Pointer mat = itk::CenteredEuler3DTransform<double>::New();
+    itk::CenteredEuler3DTransform<double>::ParametersType p;
+    p.SetSize(9);
+    for(uint i=0; i<3; i++)
+      p[i] = atof(results[i].c_str()); // Rotation
+    for(uint i=0; i<3; i++)
+      p[i+3] = atof(cor[i].c_str()); // Centre of rotation
+    for(uint i=0; i<3; i++)
+      p[i+6] = atof(results[i+3].c_str()); // Translation
+    mat->SetParameters(p);
+    
+    if (m_Verbose) {
+      std::cout << "Rotation      (deg) : " << rad2deg(p[0]) << " " << rad2deg(p[1]) << " " << rad2deg(p[2]) << std::endl;
+      std::cout << "Translation   (phy) : " << p[3] << " " << p[4] << " " << p[5] << std::endl;
+      std::cout << "Center of rot (phy) : " << p[6] << " " << p[7] << " " << p[8] << std::endl;
     }
-    else
-      matrix.SetIdentity();
-  }
-  if (m_Verbose)
-    std::cout << "Using the following matrix:" << std::endl
-              << matrix << std::endl;
-  typename itk::Matrix<double, Dimension, Dimension> rotationMatrix = clitk::GetRotationalPartMatrix(matrix);
-  typename itk::Vector<double, Dimension> translationPart = clitk::GetTranslationPartMatrix(matrix);
-
-  // Transform
-  typedef itk::AffineTransform<double, Dimension> AffineTransformType;
-  typename AffineTransformType::Pointer affineTransform=AffineTransformType::New();
-  affineTransform->SetMatrix(rotationMatrix);
-  affineTransform->SetTranslation(translationPart);
-
-  // Interp
-  typedef clitk::GenericVectorInterpolator<args_info_type, InputImageType, double> GenericInterpolatorType;
-  typename GenericInterpolatorType::Pointer genericInterpolator=GenericInterpolatorType::New();
-  genericInterpolator->SetArgsInfo(m_ArgsInfo);
-
-  // Properties
-  if (m_ArgsInfo.like_given) {
-    typename InputReaderType::Pointer likeReader=InputReaderType::New();
-    likeReader->SetFileName(m_ArgsInfo.like_arg);
-    likeReader->Update();
-    resampler->SetSize( likeReader->GetOutput()->GetLargestPossibleRegion().GetSize() );
-    resampler->SetOutputSpacing( likeReader->GetOutput()->GetSpacing() );
-    resampler->SetOutputOrigin(  likeReader->GetOutput()->GetOrigin() );
-  } else {
-    //Size
-    typename OutputImageType::SizeType outputSize;
-    if (m_ArgsInfo.size_given) {
-      for(unsigned int i=0; i< Dimension; i++)
-        outputSize[i]=m_ArgsInfo.size_arg[i];
-    } else outputSize=input->GetLargestPossibleRegion().GetSize();
-    std::cout<<"Setting the size to "<<outputSize<<"..."<<std::endl;
-
-    //Spacing
-    typename OutputImageType::SpacingType outputSpacing;
-    if (m_ArgsInfo.spacing_given) {
-      for(unsigned int i=0; i< Dimension; i++)
-        outputSpacing[i]=m_ArgsInfo.spacing_arg[i];
-    } else outputSpacing=input->GetSpacing();
-    std::cout<<"Setting the spacing to "<<outputSpacing<<"..."<<std::endl;
-
-    //Origin
-    typename OutputImageType::PointType outputOrigin;
-    if (m_ArgsInfo.origin_given) {
-      for(unsigned int i=0; i< Dimension; i++)
-        outputOrigin[i]=m_ArgsInfo.origin_arg[i];
-    } else outputOrigin=input->GetOrigin();
-    std::cout<<"Setting the origin to "<<outputOrigin<<"..."<<std::endl;
-
-    // Set
-    resampler->SetSize( outputSize );
-    resampler->SetOutputSpacing( outputSpacing );
-    resampler->SetOutputOrigin(  outputOrigin );
 
+    for(uint i=0; i<3; i++)
+      for(uint j=0; j<3; j++)
+        matrix[i][j] = mat->GetMatrix()[i][j];
+    // Offset is -Rc + t + c
+    matrix[0][3] = mat->GetOffset()[0];
+    matrix[1][3] = mat->GetOffset()[1];
+    matrix[2][3] = mat->GetOffset()[2];
+    matrix[3][3] = 1;
+    
+    return matrix;
   }
 
-  resampler->SetInput( input );
-  resampler->SetTransform( affineTransform );
-  resampler->SetInterpolator( genericInterpolator->GetInterpolatorPointer());
-  resampler->SetDefaultPixelValue( static_cast<PixelType>(m_ArgsInfo.pad_arg) );
-
-  try {
-    resampler->Update();
-  } catch(itk::ExceptionObject) {
-    std::cerr<<"Error resampling the image"<<std::endl;
+  //-------------------------------------------------------------------
+  template<class args_info_type>
+  bool
+  AffineTransformGenericFilter<args_info_type>::GetElastixValueFromTag(std::ifstream & is, 
+                                                                       std::string tag, 
+                                                                       std::string & value)
+  {
+    std::string line;
+    is.seekg (0, is.beg);
+    while(std::getline(is, line))   {
+      unsigned pos = line.find(tag);
+      if (pos<line.size()) {
+        value=line.substr(pos+tag.size(),line.size()-2);// remove last ')'
+        value.erase (std::remove (value.begin(), value.end(), '"'), value.end());
+        value.erase (std::remove (value.begin(), value.end(), ')'), value.end());
+        return true;
+      }
+   }
+    return false;
   }
+  //-------------------------------------------------------------------
 
-  typename OutputImageType::Pointer output = resampler->GetOutput();
-
-  // Output
-  typedef itk::ImageFileWriter<OutputImageType> WriterType;
-  typename WriterType::Pointer writer = WriterType::New();
-  writer->SetFileName(m_ArgsInfo.output_arg);
-  writer->SetInput(output);
-  writer->Update();
 
-}
+  //-------------------------------------------------------------------
+  template<class args_info_type>
+  void
+  AffineTransformGenericFilter<args_info_type>::GetValuesFromValue(const std::string & s, 
+                                                                   std::vector<std::string> & values)
+  {
+    std::stringstream strstr(s);
+    std::istream_iterator<std::string> it(strstr);
+    std::istream_iterator<std::string> end;
+    std::vector<std::string> results(it, end);
+    values.clear();
+    values.resize(results.size());
+    for(uint i=0; i<results.size(); i++) values[i] = results[i];
+  }
+  //-------------------------------------------------------------------
 
 
 } //end clitk