#ifndef __ReadWriteData_h_
#define __ReadWriteData_h_
#include "antsAllocImage.h"
#include <iostream>
#include <fstream>
#include <stdio.h>
#include "itkVector.h"
#include "itkImage.h"
#include "itkImageFileWriter.h"
#include "itkImageFileReader.h"
#include "itkImageRegionIteratorWithIndex.h"
#include "itkLabeledPointSetFileReader.h"
#include "itkLabeledPointSetFileWriter.h"
#include "itkImageIntensityAndGradientToPointSetFilter.h"
#include "itkWarpImageFilter.h"
// #include "itkInverseWarpImageFilter.h"
#include "itkAffineTransform.h"
#include "itkImageRegionIterator.h"
#include "itkResampleImageFilter.h"
#include "itkVariableLengthVector.h"
#include "itkVectorIndexSelectionCastImageFilter.h"
#include "itkImageRegionIteratorWithIndex.h"
#include "itkNearestNeighborInterpolateImageFunction.h"
#include "itkVectorIndexSelectionCastImageFilter.h"
#include "itkLogTensorImageFilter.h"
#include "itkExpTensorImageFilter.h"
#include "itkCastImageFilter.h"
#include <sys/stat.h>
extern bool ANTSFileExists(const std::string & strFilename);
// Nifti stores DTI values in lower tri format but itk uses upper tri
// currently, nifti io does nothing to deal with this. if this changes
// the function below should be modified/eliminated.
#if 1 // currrently unimplemented
template <class TImageType>
void NiftiDTICheck(itk::SmartPointer<TImageType> &, const char *, bool )
{
}
#else
template <class TImageType>
void NiftiDTICheck(itk::SmartPointer<TImageType> & target, const char *file, bool makeLower)
{
typedef typename TImageType::PixelType PixType;
return;
// typedef itk::ImageFileWriter<TImageType> Writer;
// typename Writer::Pointer writer = Writer::New();
// writer->SetInput( target );
// writer->SetFileName( "testdt.nii" );
// writer->Update();
// Check for nifti file
std::string filename = file;
std::string::size_type pos1 = filename.find( ".nii" );
std::string::size_type pos2 = filename.find( ".nia" );
if( (pos1 == std::string::npos) && (pos2 == std::string::npos) )
{
return;
}
if( PixType::Length != 6 )
{
return;
}
std::cout << "Performing lower/upper triangular format check for Nifti DTI" << std::endl;
// swap elements 2 and 3 for lower<->upper conversion
itk::ImageRegionIteratorWithIndex<TImageType>
iter(target, target->GetLargestPossibleRegion() );
unsigned int looksLikeLower = 0;
unsigned int looksLikeUpper = 0;
unsigned int nBadVoxels = 0;
unsigned int count = 0;
unsigned int el2Neg = 0;
unsigned int el3Neg = 0;
while( !iter.IsAtEnd() )
{
bool isValid = true;
for( unsigned int i = 0; i < 6; i++ )
{
if( iter.Get()[i] != iter.Get()[i] )
{
++nBadVoxels;
isValid = false;
}
}
double el2 = iter.Get()[2];
double el3 = iter.Get()[3];
if( el2 < 0 )
{
++el2Neg;
}
if( el3 < 0 )
{
++el3Neg;
}
if( isValid )
{
if( el2 > el3 )
{
++looksLikeLower;
}
else
{
++looksLikeUpper;
}
}
++count;
++iter;
}
// std::cout << "Invalid: " << nBadVoxels << "/" << count << std::endl;
// std::cout << "Lower: " << looksLikeLower << ", Upper: " << looksLikeUpper << std::endl;
// std::cout << "el2Neg: " << el2Neg << ", el3Neg: " << el3Neg << std::endl;
if( ( (looksLikeUpper > looksLikeLower) && makeLower) || ( (looksLikeLower > looksLikeUpper) && !makeLower) )
{
std::cout << "Performing lower/upper triangular format swap for Nifti DTI" << std::endl;
iter.GoToBegin();
while( !iter.IsAtEnd() )
{
PixType pix = iter.Get();
typename PixType::ValueType temp;
temp = pix[2];
pix[2] = pix[3];
pix[3] = temp;
iter.Set(pix);
++iter;
}
}
}
#endif
template <class TImageType>
void ReadTensorImage(itk::SmartPointer<TImageType> & target, const char *file, bool takelog = true)
{
if( !ANTSFileExists(std::string(file) ) )
{
std::cerr << " file " << std::string(file) << " does not exist . " << std::endl;
return;
}
typedef TImageType ImageType;
typedef itk::ImageFileReader<ImageType> FileSourceType;
typedef itk::LogTensorImageFilter<ImageType, ImageType> LogFilterType;
typename FileSourceType::Pointer reffilter = nullptr;
if( file[0] == '0' && file[1] == 'x' )
{
void* ptr;
sscanf(file, "%p", (void **)&ptr);
target = *( static_cast<typename TImageType::Pointer *>( ptr ) );
}
else
{
// Read the image files begin
reffilter = FileSourceType::New();
reffilter->SetFileName( file );
try
{
reffilter->Update();
}
catch( itk::ExceptionObject & e )
{
std::cerr << "Exception caught during reference file reading " << std::endl;
std::cerr << e << " file " << file << std::endl;
target = nullptr;
return;
}
target = reffilter->GetOutput();
}
//NiftiDTICheck<ImageType>(target, file, false);
if( takelog )
{
typename LogFilterType::Pointer logFilter = LogFilterType::New();
logFilter->SetInput( reffilter->GetOutput() );
try
{
logFilter->Update();
}
catch( itk::ExceptionObject & e )
{
std::cerr << "Exception caught during log tensor filter " << std::endl;
std::cerr << e << " file " << file << std::endl;
target = nullptr;
return;
}
target = logFilter->GetOutput();
std::cout << "Returning Log(D) for log-euclidean math ops" << std::endl;
}
}
template <class TImageType>
// void ReadImage(typename TImageType::Pointer target, const char *file)
bool ReadImage(itk::SmartPointer<TImageType> & target, const char *file)
{
enum { ImageDimension = TImageType::ImageDimension };
if( std::string(file).length() < 3 )
{
target = nullptr;
return false;
}
std::string comparetype1 = std::string( "0x" );
std::string comparetype2 = std::string( file );
comparetype2 = comparetype2.substr( 0, 2 );
// Read the image files begin
if( comparetype1 == comparetype2 )
{
typedef TImageType RImageType;
void* ptr;
sscanf(file, "%p", (void **)&ptr);
typename RImageType::Pointer Rimage = *( static_cast<typename RImageType::Pointer *>( ptr ) );
/** more needs to be done here to cast the pointer to an image type --- this is a work-around */
typedef itk::CastImageFilter<RImageType, TImageType> CastFilterType;
typename CastFilterType::Pointer caster = CastFilterType::New();
caster->SetInput( Rimage );
caster->UpdateLargestPossibleRegion();
target = caster->GetOutput();
}
else
{
if( !ANTSFileExists(std::string(file) ) )
{
std::cerr << " file " << std::string(file) << " does not exist . " << std::endl; target = nullptr;
return false;
}
typedef TImageType ImageType;
typedef itk::ImageFileReader<ImageType> FileSourceType;
typename FileSourceType::Pointer reffilter = FileSourceType::New();
reffilter->SetFileName( file );
try
{
reffilter->Update();
}
catch( itk::ExceptionObject & e )
{
std::cerr << "Exception caught during reference file reading " << std::endl;
std::cerr << e << " file " << file << std::endl;
target = nullptr;
std::exception();
return false;
}
// typename ImageType::DirectionType dir;
// dir.SetIdentity();
// reffilter->GetOutput()->SetDirection(dir);
// std::cout << " setting pointer " << std::endl;
target = reffilter->GetOutput();
}
return true;
}
template <class ImageType>
typename ImageType::Pointer ReadImage(char* fn )
{
// Read the image files begin
typedef itk::ImageFileReader<ImageType> FileSourceType;
typename FileSourceType::Pointer reffilter = FileSourceType::New();
reffilter->SetFileName( fn );
try
{
reffilter->Update();
}
catch( itk::ExceptionObject & e )
{
std::cerr << "Exception caught during image reference file reading " << std::endl;
std::cerr << e << std::endl;
return nullptr;
}
//typename ImageType::DirectionType dir;
//dir.SetIdentity();
// reffilter->GetOutput()->SetDirection(dir);
typename ImageType::Pointer target = reffilter->GetOutput();
// if (reffilter->GetImageIO->GetNumberOfComponents() == 6)
// NiftiDTICheck<ImageType>(target,fn);
return target;
}
template <class ImageType>
typename ImageType::Pointer ReadTensorImage(char* fn, bool takelog = true )
{
// Read the image files begin
typedef itk::ImageFileReader<ImageType> FileSourceType;
typedef itk::LogTensorImageFilter<ImageType, ImageType> LogFilterType;
typename FileSourceType::Pointer reffilter = FileSourceType::New();
reffilter->SetFileName( fn );
try
{
reffilter->Update();
}
catch( itk::ExceptionObject & e )
{
std::cerr << "Exception caught during tensor image reference file reading " << std::endl;
std::cerr << e << std::endl;
return nullptr;
}
typename ImageType::Pointer target = reffilter->GetOutput();
NiftiDTICheck<ImageType>(target, fn, false);
if( takelog )
{
typename LogFilterType::Pointer logFilter = LogFilterType::New();
logFilter->SetInput( target->GetOutput() );
logFilter->Update();
target = logFilter->GetOutput();
}
return target;
}
template <class TPointSet>
// void ReadImage(typename TPointSet::Pointer target, const char *file)
bool ReadLabeledPointSet( itk::SmartPointer<TPointSet> & target, const char *file,
bool boundaryPointsOnly = false, float samplingPercentage = 1.0 )
{
if( std::string( file ).length() < 3 )
{
target = nullptr;
return false;
}
if( !ANTSFileExists( std::string( file ) ) )
{
std::cerr << " file " << std::string( file ) << " does not exist . " << std::endl;
return false;
}
// Read the image files begin
typedef itk::LabeledPointSetFileReader<TPointSet> FileSourceType;
typename FileSourceType::Pointer reffilter = FileSourceType::New();
reffilter->SetFileName( file );
reffilter->SetExtractBoundaryPoints( boundaryPointsOnly );
reffilter->SetRandomPercentage( samplingPercentage );
try
{
reffilter->Update();
}
catch( itk::ExceptionObject & e )
{
std::cerr << "Exception caught during point set reference file reading " << std::endl;
std::cerr << e << std::endl;
return false;
}
target = reffilter->GetOutput();
return true;
}
template <class TImage, class TMask, class TPointSet>
bool ReadImageIntensityPointSet( itk::SmartPointer<TPointSet> & target, const char *imageFile,
const char *maskFile, std::vector<unsigned int> neighborhoodRadius, double sigma )
{
if( std::string( imageFile ).length() < 3 )
{
std::cerr << " bad image file name " << std::string( imageFile ) << std::endl;
target = nullptr;
return false;
}
if( !ANTSFileExists( std::string( imageFile ) ) )
{
std::cerr << " image file " << std::string( imageFile ) << " does not exist . " << std::endl;
target = nullptr;
return false;
}
if( std::string( maskFile ).length() < 3 )
{
std::cerr << " bad mask file name " << std::string( maskFile ) << std::endl;
target = nullptr;
return false;
}
if( !ANTSFileExists( std::string( maskFile ) ) )
{
std::cerr << " mask file " << std::string( maskFile ) << " does not exist . " << std::endl;
target = nullptr;
return false;
}
if( neighborhoodRadius.size() != TImage::ImageDimension )
{
std::cerr << " size of the neighborhood radius is not equal to the image dimension." << std::endl;
target = nullptr;
return false;
}
typename TImage::Pointer intensityImage = ReadImage<TImage>( (char *)imageFile );
typename TMask::Pointer maskImage = ReadImage<TMask>( (char *)maskFile );
typedef itk::ImageIntensityAndGradientToPointSetFilter<TImage, TMask, TPointSet> FilterType;
typename FilterType::NeighborhoodRadiusType radius;
for( unsigned int d = 0; d < TImage::ImageDimension; d++ )
{
radius[d] = neighborhoodRadius[d];
}
typename FilterType::Pointer filter = FilterType::New();
filter->SetInput1( intensityImage );
filter->SetInput2( maskImage );
filter->SetSigma( sigma );
filter->SetNeighborhoodRadius( radius );
filter->Update();
target = filter->GetOutput();
return true;
}
template <class TPointSet>
typename TPointSet::Pointer ReadLabeledPointSet( char* fn )
{
if( !ANTSFileExists( std::string( fn ) ) )
{
std::cerr << " file " << std::string( fn ) << " does not exist . " << std::endl;
return;
}
// Read the image files begin
typedef itk::LabeledPointSetFileReader<TPointSet> FileSourceType;
typename FileSourceType::Pointer reffilter = FileSourceType::New();
reffilter->SetFileName( fn );
try
{
reffilter->Update();
}
catch( itk::ExceptionObject & e )
{
std::cerr << "Exception caught during point set reference file reading " << std::endl;
std::cerr << e << std::endl;
return nullptr;
}
typename TPointSet::Pointer target = reffilter->GetOutput();
return target;
}
template <class TPointSet>
bool WritePointSet( itk::SmartPointer<TPointSet> pointSet, const char *file )
{
if( std::string(file).length() < 3 )
{
return false;
}
typename itk::LabeledPointSetFileWriter<TPointSet>::Pointer writer =
itk::LabeledPointSetFileWriter<TPointSet>::New();
writer->SetFileName( file );
if( !pointSet )
{
std::cerr << " Point set is nullptr." << std::endl;
std::exception();
}
writer->SetInput( pointSet );
writer->Update();
return true;
}
template <class TImageType>
bool WriteImage(const itk::SmartPointer<TImageType> image, const char *file)
{
if( std::string(file).length() < 3 )
{
return false;
}
// typename TImageType::DirectionType dir;
// dir.SetIdentity();
// image->SetDirection(dir);
// std::cout << " now Write direction " << image->GetOrigin() << std::endl;
// if (writer->GetImageIO->GetNumberOfComponents() == 6)
// NiftiDTICheck<TImageType>(image,file);
if( file[0] == '0' && file[1] == 'x' )
{
void* ptr;
sscanf(file, "%p", (void **)&ptr);
*( static_cast<typename TImageType::Pointer *>( ptr ) ) = image;
}
else
{
typename itk::ImageFileWriter<TImageType>::Pointer writer =
itk::ImageFileWriter<TImageType>::New();
writer->SetFileName(file);
if( !image )
{
std::cerr << "Image is nullptr." << std::endl;
std::exception();
}
writer->SetInput(image);
writer->SetUseCompression( true );
writer->Update();
}
return true;
}
template <class TImageType>
void WriteTensorImage(itk::SmartPointer<TImageType> image, const char *file, bool takeexp = true)
{
typedef itk::ExpTensorImageFilter<TImageType, TImageType> ExpFilterType;
typename itk::ImageFileWriter<TImageType>::Pointer writer =
itk::ImageFileWriter<TImageType>::New();
writer->SetFileName(file);
typename TImageType::Pointer writeImage = image;
if( takeexp )
{
typename ExpFilterType::Pointer expFilter = ExpFilterType::New();
expFilter->SetInput( image );
expFilter->Update();
writeImage = expFilter->GetOutput();
std::cout << "Taking Exp(D) before writing" << std::endl;
}
// convert from upper tri to lower tri
NiftiDTICheck<TImageType>(writeImage, file, true); // BA May 30 2009 -- remove b/c ITK fixed NIFTI reader
if( file[0] == '0' && file[1] == 'x' )
{
void* ptr;
sscanf(file, "%p", (void **)&ptr);
*( static_cast<typename TImageType::Pointer *>( ptr ) ) = writeImage;
}
else
{
writer->SetInput(writeImage);
writer->SetUseCompression( true );
writer->Update();
}
}
template <class TImage, class TField>
typename TField::Pointer
ReadWarpFromFile( std::string warpfn, std::string ext)
{
typedef TField FieldType;
typedef typename FieldType::PixelType VectorType;
enum { ImageDimension = FieldType::ImageDimension };
typedef itk::Image<float, ImageDimension> RealImageType;
typedef RealImageType ImageType;
// typedef itk::Vector<float,itkGetStaticConstMacro(ImageDimension)> VectorType;
// typedef itk::Image<VectorType,itkGetStaticConstMacro(ImageDimension)> FieldType;
// std::cout << " warp file name " << warpfn + ext << std::endl;
// First - read the vector fields
// NOTE : THE FIELD SHOULD WARP INPUT1 TO INPUT2, THUS SHOULD POINT
// FROM INPUT2 TO INPUT1
std::string fn = warpfn + "x" + ext;
typename RealImageType::Pointer xvec = ReadImage<ImageType>( (char *)fn.c_str() );
// std::cout << " done reading " << fn << std::endl;
fn = warpfn + "y" + ext;
typename RealImageType::Pointer yvec = ReadImage<ImageType>( (char *)fn.c_str() );
// std::cout << " done reading " << fn << std::endl;
fn = warpfn + "z" + ext;
typename RealImageType::Pointer zvec = nullptr;
// std::cout << " done reading " << fn << std::endl;
if( ImageDimension == 3 )
{
zvec = ReadImage<ImageType>( (char *)fn.c_str() );
}
typename FieldType::Pointer field = AllocImage<FieldType>(xvec);
itk::ImageRegionIteratorWithIndex<RealImageType>
it( xvec, xvec->GetLargestPossibleRegion() );
// std::cout << " spacing xv " << xvec->GetSpacing()[0]
// << " field " << field->GetSpacing()[0] << std::endl;
unsigned int ct = 0;
for( it.GoToBegin(); !it.IsAtEnd(); ++it )
{
ct++;
typename ImageType::IndexType index = it.GetIndex();
VectorType disp;
disp[0] = xvec->GetPixel(index);
disp[1] = yvec->GetPixel(index);
if( ImageDimension == 3 )
{
disp[2] = zvec->GetPixel(index);
}
field->SetPixel(index, disp);
// if (ct == 10000) std::cout << " 10000th pix " << disp << std::endl;
}
return field;
}
template <class TImage>
typename TImage::Pointer
MakeNewImage(typename TImage::Pointer image1, typename TImage::PixelType initval )
{
typedef itk::ImageRegionIteratorWithIndex<TImage> Iterator;
typename TImage::Pointer varimage = AllocImage<TImage>(image1);
Iterator vfIter2( varimage, varimage->GetLargestPossibleRegion() );
for( vfIter2.GoToBegin(); !vfIter2.IsAtEnd(); ++vfIter2 )
{
if( initval >= 0 )
{
vfIter2.Set(initval);
}
else
{
vfIter2.Set(image1->GetPixel(vfIter2.GetIndex() ) );
}
}
return varimage;
}
template <class TField>
void
WriteDisplacementField(TField* field, std::string filename)
{
typedef TField FieldType;
enum { ImageDimension = FieldType::ImageDimension };
typedef itk::Image<float, ImageDimension> RealImageType;
// Initialize the caster to the displacement field
typedef itk::VectorIndexSelectionCastImageFilter<FieldType, RealImageType> IndexSelectCasterType;
for( unsigned int dim = 0; dim < ImageDimension; dim++ )
{
typename IndexSelectCasterType::Pointer fieldCaster = IndexSelectCasterType::New();
fieldCaster->SetInput( field );
fieldCaster->SetIndex( dim );
fieldCaster->Update();
// Set up the output filename
std::string outfile = filename + static_cast<char>('x' + dim) + std::string("vec.nii.gz");
std::cout << "Writing displacements to " << outfile << " spacing "
<< field->GetSpacing()[0] << std::endl;
typename RealImageType::Pointer fieldcomponent = fieldCaster->GetOutput();
fieldcomponent->SetSpacing(field->GetSpacing() );
fieldcomponent->SetOrigin(field->GetOrigin() );
fieldcomponent->SetDirection(field->GetDirection() );
WriteImage<RealImageType>(fieldcomponent, outfile.c_str() );
}
std::cout << "...done" << std::endl;
return;
}
template <class TField>
void
WriteDisplacementField2(TField* field, std::string filename, std::string app)
{
typedef TField FieldType;
enum { ImageDimension = FieldType::ImageDimension };
typedef itk::Image<float, ImageDimension> RealImageType;
// Initialize the caster to the displacement field
typedef itk::VectorIndexSelectionCastImageFilter<FieldType, RealImageType> IndexSelectCasterType;
for( unsigned int dim = 0; dim < ImageDimension; dim++ )
{
typename IndexSelectCasterType::Pointer fieldCaster = IndexSelectCasterType::New();
fieldCaster->SetInput( field );
fieldCaster->SetIndex( dim );
fieldCaster->Update();
// Set up the output filename
std::string outfile = filename + static_cast<char>('x' + dim) + std::string(app);
std::cout << "Writing displacements to " << outfile << " spacing "
<< field->GetSpacing()[0] << std::endl;
typename RealImageType::Pointer fieldcomponent = fieldCaster->GetOutput();
fieldcomponent->SetSpacing(field->GetSpacing() );
fieldcomponent->SetOrigin(field->GetOrigin() );
WriteImage<RealImageType>(fieldcomponent, outfile.c_str() );
}
std::cout << "...done" << std::endl;
return;
}
template<class TTimeSeriesImageType, class MultiChannelImageType>
typename MultiChannelImageType::Pointer
ConvertTimeSeriesImageToMultiChannelImage( TTimeSeriesImageType *timeSeriesImage )
{
enum { ImageDimension = MultiChannelImageType::ImageDimension };
typename MultiChannelImageType::SpacingType spacing;
typename MultiChannelImageType::PointType origin;
typename MultiChannelImageType::RegionType::SizeType size;
typename MultiChannelImageType::DirectionType direction;
typename TTimeSeriesImageType::SpacingType timeSeriesSpacing =
timeSeriesImage->GetSpacing();
typename TTimeSeriesImageType::PointType timeSeriesOrigin =
timeSeriesImage->GetOrigin();
typename TTimeSeriesImageType::RegionType::SizeType timeSeriesSize =
timeSeriesImage->GetRequestedRegion().GetSize();
typename TTimeSeriesImageType::DirectionType timeSeriesDirection =
timeSeriesImage->GetDirection();
for( itk::SizeValueType d = 0; d < ImageDimension; d++ )
{
spacing[d] = timeSeriesSpacing[d];
origin[d] = timeSeriesOrigin[d];
size[d] = timeSeriesSize[d];
for( itk::SizeValueType e = 0; e < ImageDimension; e++ )
{
direction( d, e ) = timeSeriesDirection( d, e );
}
}
typename MultiChannelImageType::Pointer multiChannelImage =
MultiChannelImageType::New();
multiChannelImage->SetRegions( size );
multiChannelImage->SetSpacing( spacing );
multiChannelImage->SetOrigin( origin );
multiChannelImage->SetDirection( direction );
multiChannelImage->SetVectorLength( timeSeriesSize[ImageDimension] );
multiChannelImage->AllocateInitialized();
itk::ImageRegionIteratorWithIndex<MultiChannelImageType> It(
multiChannelImage, multiChannelImage->GetRequestedRegion() );
for( It.GoToBegin(); !It.IsAtEnd(); ++It )
{
typename MultiChannelImageType::IndexType index = It.GetIndex();
typename MultiChannelImageType::PixelType multiChannelVoxel;
multiChannelVoxel.SetSize( timeSeriesSize[ImageDimension] );
for( itk::SizeValueType n = 0; n < timeSeriesSize[ImageDimension]; n++ )
{
typename TTimeSeriesImageType::IndexType timeSeriesIndex;
for( itk::SizeValueType d = 0; d < ImageDimension; d++ )
{
timeSeriesIndex[d] = index[d];
}
timeSeriesIndex[ImageDimension] = n;
multiChannelVoxel[n] = timeSeriesImage->GetPixel( timeSeriesIndex );
}
It.Set( multiChannelVoxel );
}
return multiChannelImage;
}
template<class MultiChannelImageType, class TimeSeriesImageType>
typename TimeSeriesImageType::Pointer
ConvertMultiChannelImageToTimeSeriesImage( MultiChannelImageType *multiChannelImage )
{
enum { ImageDimension = MultiChannelImageType::ImageDimension };
typename MultiChannelImageType::SpacingType spacing = multiChannelImage->GetSpacing();
typename MultiChannelImageType::PointType origin = multiChannelImage->GetOrigin();
typename MultiChannelImageType::RegionType::SizeType size =
multiChannelImage->GetRequestedRegion().GetSize();
typename MultiChannelImageType::DirectionType direction =
multiChannelImage->GetDirection();
typename TimeSeriesImageType::SpacingType timeSeriesSpacing;
typename TimeSeriesImageType::PointType timeSeriesOrigin;
typename TimeSeriesImageType::RegionType::SizeType timeSeriesSize;
typename TimeSeriesImageType::DirectionType timeSeriesDirection;
timeSeriesDirection.SetIdentity();
typename MultiChannelImageType::IndexType index;
index.Fill( 0 );
typename MultiChannelImageType::PixelType multiChannelVoxel =
multiChannelImage->GetPixel( index );
for( itk::SizeValueType d = 0; d < ImageDimension; d++ )
{
timeSeriesSpacing[d] = spacing[d];
timeSeriesOrigin[d] = origin[d];
timeSeriesSize[d] = size[d];
for( itk::SizeValueType e = 0; e < ImageDimension; e++ )
{
timeSeriesDirection( d, e ) = direction( d, e );
}
}
timeSeriesSpacing[ImageDimension] = 1;
timeSeriesOrigin[ImageDimension] = 0;
timeSeriesSize[ImageDimension] = multiChannelVoxel.GetSize();
typename TimeSeriesImageType::Pointer timeSeriesImage =
AllocImage<TimeSeriesImageType>(
timeSeriesSize, timeSeriesSpacing, timeSeriesOrigin, timeSeriesDirection );
itk::ImageRegionIteratorWithIndex<MultiChannelImageType> It(
multiChannelImage, multiChannelImage->GetRequestedRegion() );
for( It.GoToBegin(); !It.IsAtEnd(); ++It )
{
index = It.GetIndex();
multiChannelVoxel = It.Get();
for( itk::SizeValueType n = 0; n < timeSeriesSize[ImageDimension]; n++ )
{
typename TimeSeriesImageType::IndexType timeSeriesIndex;
for( itk::SizeValueType d = 0; d < ImageDimension; d++ )
{
timeSeriesIndex[d] = index[d];
}
timeSeriesIndex[ImageDimension] = n;
timeSeriesImage->SetPixel( timeSeriesIndex, multiChannelVoxel[n] );
}
}
return timeSeriesImage;
}
class nullBuf
: public std::streambuf
{
public:
virtual std::streamsize xsputn( const char * itkNotUsed( s ), std::streamsize n )
{
return n;
}
virtual int overflow( int itkNotUsed( c ) )
{
return 1;
}
};
class nullStream
: public std::ostream
{
public:
nullStream() : std::ostream( &buf ) {}
private:
nullBuf buf;
};
#endif
