DwiPhantomGenerationFilter< TOutputScalarType > ::DwiPhantomGenerationFilter() : m_BValue(1000) , m_SignalScale(1000) , m_BaselineImages(0) , m_MaxBaseline(0) , m_MeanBaseline(0) , m_NoiseVariance(0.004) , m_GreyMatterAdc(0.01) , m_SimulateBaseline(true) , m_DefaultBaseline(1000) { this->SetNumberOfRequiredOutputs (1); m_Spacing.Fill(2.5); m_Origin.Fill(0.0); m_DirectionMatrix.SetIdentity(); m_ImageRegion.SetSize(0, 10); m_ImageRegion.SetSize(1, 10); m_ImageRegion.SetSize(2, 10); typename OutputImageType::Pointer outImage = OutputImageType::New(); outImage->SetSpacing( m_Spacing ); // Set the image spacing outImage->SetOrigin( m_Origin ); // Set the image origin outImage->SetDirection( m_DirectionMatrix ); // Set the image direction outImage->SetLargestPossibleRegion( m_ImageRegion ); outImage->SetBufferedRegion( m_ImageRegion ); outImage->SetRequestedRegion( m_ImageRegion ); outImage->SetVectorLength(QBALL_ODFSIZE); outImage->Allocate(); outImage->FillBuffer(0); this->SetNthOutput (0, outImage); }
void DicomDiffusionImageReader<TPixelType, TDimension> ::GenerateOutputInformation(void) { typename OutputImageType::Pointer output = this->GetOutput(); typedef itk::ImageSeriesReader<InputImageType> ReaderType; // Read the first (or last) volume and use its size. if (m_Headers.size() > 0) { typename ReaderType::Pointer reader = ReaderType::New(); try { // Read the image reader->SetFileNames (m_Headers[0]->m_DicomFilenames); reader->UpdateOutputInformation(); output->SetSpacing( reader->GetOutput()->GetSpacing() ); // Set the image spacing output->SetOrigin( reader->GetOutput()->GetOrigin() ); // Set the image origin output->SetDirection( reader->GetOutput()->GetDirection() ); // Set the image direction output->SetLargestPossibleRegion( reader->GetOutput()->GetLargestPossibleRegion() ); output->SetVectorLength( m_Headers.size() ); } catch (itk::ExceptionObject &e) { throw e; } } else { itkExceptionMacro(<< "At least one filename is required." ); } }
void FieldmapGeneratorFilter< OutputImageType >::BeforeThreadedGenerateData() { typename OutputImageType::Pointer outImage = OutputImageType::New(); outImage->SetSpacing( m_Spacing ); outImage->SetOrigin( m_Origin ); outImage->SetDirection( m_DirectionMatrix ); outImage->SetLargestPossibleRegion( m_ImageRegion ); outImage->SetBufferedRegion( m_ImageRegion ); outImage->SetRequestedRegion( m_ImageRegion ); outImage->Allocate(); outImage->FillBuffer(0); this->SetNthOutput(0, outImage); }
void TractsToFiberEndingsImageFilter< TInputImage, TOutputPixelType > ::GenerateData() { MITK_INFO << "Generating 2D fiber endings image"; if(&typeid(TOutputPixelType) != &typeid(unsigned char)) { MITK_INFO << "Only 'unsigned char' and 'itk::RGBAPixel<unsigned char> supported as OutputPixelType"; return; } mitk::Geometry3D::Pointer geometry = m_FiberBundle->GetGeometry(); typename OutputImageType::Pointer outImage = static_cast< OutputImageType * >(this->ProcessObject::GetOutput(0)); outImage->SetSpacing( geometry->GetSpacing()/m_UpsamplingFactor ); // Set the image spacing mitk::Point3D origin = geometry->GetOrigin(); mitk::Point3D indexOrigin; geometry->WorldToIndex(origin, indexOrigin); indexOrigin[0] = indexOrigin[0] - .5 * (1.0-1.0/m_UpsamplingFactor); indexOrigin[1] = indexOrigin[1] - .5 * (1.0-1.0/m_UpsamplingFactor); indexOrigin[2] = indexOrigin[2] - .5 * (1.0-1.0/m_UpsamplingFactor); mitk::Point3D newOrigin; geometry->IndexToWorld(indexOrigin, newOrigin); outImage->SetOrigin( newOrigin ); // Set the image origin itk::Matrix<double, 3, 3> matrix; for (int i=0; i<3; i++) for (int j=0; j<3; j++) matrix[j][i] = geometry->GetMatrixColumn(i)[j]/geometry->GetSpacing().GetElement(i); outImage->SetDirection( matrix ); // Set the image direction float* bounds = m_FiberBundle->GetBounds(); ImageRegion<3> upsampledRegion; upsampledRegion.SetSize(0, bounds[0]); upsampledRegion.SetSize(1, bounds[1]); upsampledRegion.SetSize(2, bounds[2]); typename InputImageType::RegionType::SizeType upsampledSize = upsampledRegion.GetSize(); for (unsigned int n = 0; n < 3; n++) { upsampledSize[n] = upsampledSize[n] * m_UpsamplingFactor; } upsampledRegion.SetSize( upsampledSize ); outImage->SetRegions( upsampledRegion ); outImage->Allocate(); int w = upsampledSize[0]; int h = upsampledSize[1]; int d = upsampledSize[2]; unsigned char* accuout; accuout = reinterpret_cast<unsigned char*>(outImage->GetBufferPointer()); for (int i=0; i<w*h*d; i++) accuout[i] = 0; typedef mitk::FiberBundle::ContainerTractType ContainerTractType; typedef mitk::FiberBundle::ContainerType ContainerType; typedef mitk::FiberBundle::ContainerPointType ContainerPointType; ContainerType::Pointer tractContainer = m_FiberBundle->GetTractContainer(); for (int i=0; i<tractContainer->Size(); i++) { ContainerTractType::Pointer tract = tractContainer->GetElement(i); int tractsize = tract->Size(); if (tractsize>1) { ContainerPointType start = tract->GetElement(0); ContainerPointType end = tract->GetElement(tractsize-1); start[0] = (start[0]+0.5) * m_UpsamplingFactor; start[1] = (start[1]+0.5) * m_UpsamplingFactor; start[2] = (start[2]+0.5) * m_UpsamplingFactor; // int coordinates inside image? int px = (int) (start[0]); if (px < 0 || px >= w) continue; int py = (int) (start[1]); if (py < 0 || py >= h) continue; int pz = (int) (start[2]); if (pz < 0 || pz >= d) continue; accuout[( px + w*(py + h*pz ))] += 1; end[0] = (end[0]+0.5) * m_UpsamplingFactor; end[1] = (end[1]+0.5) * m_UpsamplingFactor; end[2] = (end[2]+0.5) * m_UpsamplingFactor; // int coordinates inside image? px = (int) (end[0]); if (px < 0 || px >= w) continue; py = (int) (end[1]); if (py < 0 || py >= h) continue; pz = (int) (end[2]); if (pz < 0 || pz >= d) continue; accuout[( px + w*(py + h*pz ))] += 1; } } MITK_INFO << "2D fiber endings image generated"; }
void TractDensityImageFilter< OutputImageType >::GenerateData() { // generate upsampled image mitk::Geometry3D::Pointer geometry = m_FiberBundle->GetGeometry(); typename OutputImageType::Pointer outImage = this->GetOutput(); // calculate new image parameters mitk::Vector3D newSpacing; mitk::Point3D newOrigin; itk::Matrix<double, 3, 3> newDirection; ImageRegion<3> upsampledRegion; if (m_UseImageGeometry && !m_InputImage.IsNull()) { MITK_INFO << "TractDensityImageFilter: using image geometry"; newSpacing = m_InputImage->GetSpacing()/m_UpsamplingFactor; upsampledRegion = m_InputImage->GetLargestPossibleRegion(); newOrigin = m_InputImage->GetOrigin(); typename OutputImageType::RegionType::SizeType size = upsampledRegion.GetSize(); size[0] *= m_UpsamplingFactor; size[1] *= m_UpsamplingFactor; size[2] *= m_UpsamplingFactor; upsampledRegion.SetSize(size); newDirection = m_InputImage->GetDirection(); } else { MITK_INFO << "TractDensityImageFilter: using fiber bundle geometry"; newSpacing = geometry->GetSpacing()/m_UpsamplingFactor; newOrigin = geometry->GetOrigin(); mitk::Geometry3D::BoundsArrayType bounds = geometry->GetBounds(); newOrigin[0] += bounds.GetElement(0); newOrigin[1] += bounds.GetElement(2); newOrigin[2] += bounds.GetElement(4); for (int i=0; i<3; i++) for (int j=0; j<3; j++) newDirection[j][i] = geometry->GetMatrixColumn(i)[j]; upsampledRegion.SetSize(0, geometry->GetExtent(0)*m_UpsamplingFactor); upsampledRegion.SetSize(1, geometry->GetExtent(1)*m_UpsamplingFactor); upsampledRegion.SetSize(2, geometry->GetExtent(2)*m_UpsamplingFactor); } typename OutputImageType::RegionType::SizeType upsampledSize = upsampledRegion.GetSize(); // apply new image parameters outImage->SetSpacing( newSpacing ); outImage->SetOrigin( newOrigin ); outImage->SetDirection( newDirection ); outImage->SetRegions( upsampledRegion ); outImage->Allocate(); outImage->FillBuffer(0.0); int w = upsampledSize[0]; int h = upsampledSize[1]; int d = upsampledSize[2]; // set/initialize output OutPixelType* outImageBufferPointer = (OutPixelType*)outImage->GetBufferPointer(); // resample fiber bundle float minSpacing = 1; if(newSpacing[0]<newSpacing[1] && newSpacing[0]<newSpacing[2]) minSpacing = newSpacing[0]; else if (newSpacing[1] < newSpacing[2]) minSpacing = newSpacing[1]; else minSpacing = newSpacing[2]; MITK_INFO << "TractDensityImageFilter: resampling fibers to ensure sufficient voxel coverage"; m_FiberBundle = m_FiberBundle->GetDeepCopy(); m_FiberBundle->ResampleFibers(minSpacing); MITK_INFO << "TractDensityImageFilter: starting image generation"; vtkSmartPointer<vtkPolyData> fiberPolyData = m_FiberBundle->GetFiberPolyData(); vtkSmartPointer<vtkCellArray> vLines = fiberPolyData->GetLines(); vLines->InitTraversal(); int numFibers = m_FiberBundle->GetNumFibers(); boost::progress_display disp(numFibers); for( int i=0; i<numFibers; i++ ) { ++disp; vtkIdType numPoints(0); vtkIdType* points(NULL); vLines->GetNextCell ( numPoints, points ); // fill output image for( int j=0; j<numPoints; j++) { itk::Point<float, 3> vertex = GetItkPoint(fiberPolyData->GetPoint(points[j])); itk::Index<3> index; itk::ContinuousIndex<float, 3> contIndex; outImage->TransformPhysicalPointToIndex(vertex, index); outImage->TransformPhysicalPointToContinuousIndex(vertex, contIndex); float frac_x = contIndex[0] - index[0]; float frac_y = contIndex[1] - index[1]; float frac_z = contIndex[2] - index[2]; if (frac_x<0) { index[0] -= 1; frac_x += 1; } if (frac_y<0) { index[1] -= 1; frac_y += 1; } if (frac_z<0) { index[2] -= 1; frac_z += 1; } frac_x = 1-frac_x; frac_y = 1-frac_y; frac_z = 1-frac_z; // int coordinates inside image? if (index[0] < 0 || index[0] >= w-1) continue; if (index[1] < 0 || index[1] >= h-1) continue; if (index[2] < 0 || index[2] >= d-1) continue; if (m_BinaryOutput) { outImageBufferPointer[( index[0] + w*(index[1] + h*index[2] ))] = 1; outImageBufferPointer[( index[0] + w*(index[1]+1+ h*index[2] ))] = 1; outImageBufferPointer[( index[0] + w*(index[1] + h*index[2]+h))] = 1; outImageBufferPointer[( index[0] + w*(index[1]+1+ h*index[2]+h))] = 1; outImageBufferPointer[( index[0]+1 + w*(index[1] + h*index[2] ))] = 1; outImageBufferPointer[( index[0]+1 + w*(index[1] + h*index[2]+h))] = 1; outImageBufferPointer[( index[0]+1 + w*(index[1]+1+ h*index[2] ))] = 1; outImageBufferPointer[( index[0]+1 + w*(index[1]+1+ h*index[2]+h))] = 1; } else { outImageBufferPointer[( index[0] + w*(index[1] + h*index[2] ))] += ( frac_x)*( frac_y)*( frac_z); outImageBufferPointer[( index[0] + w*(index[1]+1+ h*index[2] ))] += ( frac_x)*(1-frac_y)*( frac_z); outImageBufferPointer[( index[0] + w*(index[1] + h*index[2]+h))] += ( frac_x)*( frac_y)*(1-frac_z); outImageBufferPointer[( index[0] + w*(index[1]+1+ h*index[2]+h))] += ( frac_x)*(1-frac_y)*(1-frac_z); outImageBufferPointer[( index[0]+1 + w*(index[1] + h*index[2] ))] += (1-frac_x)*( frac_y)*( frac_z); outImageBufferPointer[( index[0]+1 + w*(index[1] + h*index[2]+h))] += (1-frac_x)*( frac_y)*(1-frac_z); outImageBufferPointer[( index[0]+1 + w*(index[1]+1+ h*index[2] ))] += (1-frac_x)*(1-frac_y)*( frac_z); outImageBufferPointer[( index[0]+1 + w*(index[1]+1+ h*index[2]+h))] += (1-frac_x)*(1-frac_y)*(1-frac_z); } } } if (!m_OutputAbsoluteValues && !m_BinaryOutput) { MITK_INFO << "TractDensityImageFilter: max-normalizing output image"; OutPixelType max = 0; for (int i=0; i<w*h*d; i++) if (max < outImageBufferPointer[i]) max = outImageBufferPointer[i]; if (max>0) for (int i=0; i<w*h*d; i++) outImageBufferPointer[i] /= max; } if (m_InvertImage) { MITK_INFO << "TractDensityImageFilter: inverting image"; for (int i=0; i<w*h*d; i++) outImageBufferPointer[i] = 1-outImageBufferPointer[i]; } MITK_INFO << "TractDensityImageFilter: finished processing"; }
void TractsToProbabilityImageFilter< TInputImage, TOutputPixelType > ::GenerateData() { bool isRgba = false; if(&typeid(TOutputPixelType) == &typeid(itk::RGBAPixel<unsigned char>)) { isRgba = true; } else if(&typeid(TOutputPixelType) != &typeid(unsigned char)) { MITK_INFO << "Only 'unsigned char' and 'itk::RGBAPixel<unsigned char> supported as OutputPixelType"; return; } mitk::Geometry3D::Pointer geometry = m_FiberBundle->GetGeometry(); typename OutputImageType::Pointer outImage = static_cast< OutputImageType * >(this->ProcessObject::GetOutput(0)); outImage->SetSpacing( geometry->GetSpacing()/m_UpsamplingFactor ); // Set the image spacing mitk::Point3D origin = geometry->GetOrigin(); mitk::Point3D indexOrigin; geometry->WorldToIndex(origin, indexOrigin); indexOrigin[0] = indexOrigin[0] - .5 * (1.0-1.0/m_UpsamplingFactor); indexOrigin[1] = indexOrigin[1] - .5 * (1.0-1.0/m_UpsamplingFactor); indexOrigin[2] = indexOrigin[2] - .5 * (1.0-1.0/m_UpsamplingFactor); mitk::Point3D newOrigin; geometry->IndexToWorld(indexOrigin, newOrigin); outImage->SetOrigin( newOrigin ); // Set the image origin itk::Matrix<double, 3, 3> matrix; for (int i=0; i<3; i++) for (int j=0; j<3; j++) matrix[j][i] = geometry->GetMatrixColumn(i)[j]/geometry->GetSpacing().GetElement(i); outImage->SetDirection( matrix ); // Set the image direction float* bounds = m_FiberBundle->GetBounds(); ImageRegion<3> upsampledRegion; upsampledRegion.SetSize(0, bounds[0]); upsampledRegion.SetSize(1, bounds[1]); upsampledRegion.SetSize(2, bounds[2]); typename InputImageType::RegionType::SizeType upsampledSize = upsampledRegion.GetSize(); for (unsigned int n = 0; n < 3; n++) { upsampledSize[n] = upsampledSize[n] * m_UpsamplingFactor; } upsampledRegion.SetSize( upsampledSize ); outImage->SetRegions( upsampledRegion ); outImage->Allocate(); // itk::RGBAPixel<unsigned char> pix; // pix.Set(0,0,0,0); // outImage->FillBuffer(pix); int w = upsampledSize[0]; int h = upsampledSize[1]; int d = upsampledSize[2]; unsigned char* accuout; float* accu; accuout = reinterpret_cast<unsigned char*>(outImage->GetBufferPointer()); if(isRgba) { // accuout = static_cast<unsigned char*>( outImage->GetBufferPointer()[0].GetDataPointer()); accu = new float[w*h*d*4]; for (int i=0; i<w*h*d*4; i++) accu[i] = 0; } else { accu = new float[w*h*d]; for (int i=0; i<w*h*d; i++) accu[i] = 0; } // for each tract int numTracts = m_FiberBundle->GetNumTracts(); for( int i=0; i<numTracts; i++ ) { //////////////////// // upsampling std::vector< itk::Point<float, 3> > vertices; // for each vertex int numVertices = m_FiberBundle->GetNumPoints(i); for( int j=0; j<numVertices-1; j++) { itk::Point<float, 3> point = m_FiberBundle->GetPoint(i,j); itk::Point<float, 3> nextPoint = m_FiberBundle->GetPoint(i,j+1); point[0] += 0.5 - 0.5/m_UpsamplingFactor; point[1] += 0.5 - 0.5/m_UpsamplingFactor; point[2] += 0.5 - 0.5/m_UpsamplingFactor; nextPoint[0] += 0.5 - 0.5/m_UpsamplingFactor; nextPoint[1] += 0.5 - 0.5/m_UpsamplingFactor; nextPoint[2] += 0.5 - 0.5/m_UpsamplingFactor; for(int k=1; k<=m_UpsamplingFactor; k++) { itk::Point<float, 3> newPoint; newPoint[0] = point[0] + ((double)k/(double)m_UpsamplingFactor)*(nextPoint[0]-point[0]); newPoint[1] = point[1] + ((double)k/(double)m_UpsamplingFactor)*(nextPoint[1]-point[1]); newPoint[2] = point[2] + ((double)k/(double)m_UpsamplingFactor)*(nextPoint[2]-point[2]); vertices.push_back(newPoint); } } //////////////////// // calc directions (which are used as weights) std::list< itk::Point<float, 3> > rgbweights; std::list<float> intensities; // for each vertex numVertices = vertices.size(); for( int j=0; j<numVertices-1; j++) { itk::Point<float, 3> vertex = vertices.at(j); itk::Point<float, 3> vertexPost = vertices.at(j+1); itk::Point<float, 3> dir; dir[0] = fabs((vertexPost[0] - vertex[0]) * outImage->GetSpacing()[0]); dir[1] = fabs((vertexPost[1] - vertex[1]) * outImage->GetSpacing()[1]); dir[2] = fabs((vertexPost[2] - vertex[2]) * outImage->GetSpacing()[2]); if(isRgba) { rgbweights.push_back(dir); } float intensity = sqrt(dir[0]*dir[0]+dir[1]*dir[1]+dir[2]*dir[2]); intensities.push_back(intensity); // last point gets same as previous one if(j==numVertices-2) { if(isRgba) { rgbweights.push_back(dir); } intensities.push_back(intensity); } } //////////////////// // fill output image // for each vertex for( int j=0; j<numVertices; j++) { itk::Point<float, 3> vertex = vertices.at(j); itk::Point<float, 3> rgbweight; if(isRgba) { rgbweight = rgbweights.front(); rgbweights.pop_front(); } float intweight = intensities.front(); intensities.pop_front(); // scaling coordinates (index coords scale with upsampling) vertex[0] = vertex[0] * m_UpsamplingFactor; vertex[1] = vertex[1] * m_UpsamplingFactor; vertex[2] = vertex[2] * m_UpsamplingFactor; // int coordinates inside image? int px = (int) (vertex[0]); if (px < 0 || px >= w-1) continue; int py = (int) (vertex[1]); if (py < 0 || py >= h-1) continue; int pz = (int) (vertex[2]); if (pz < 0 || pz >= d-1) continue; // float fraction of coordinates float frac_x = vertex[0] - px; float frac_y = vertex[1] - py; float frac_z = vertex[2] - pz; float scale = 100 * pow((float)m_UpsamplingFactor,3); if(isRgba) { // add to r-channel in output image accu[0+4*( px + w*(py + h*pz ))] += (1-frac_x)*(1-frac_y)*(1-frac_z) * rgbweight[0] * scale; accu[0+4*( px + w*(py+1+ h*pz ))] += (1-frac_x)*( frac_y)*(1-frac_z) * rgbweight[0] * scale; accu[0+4*( px + w*(py + h*pz+h))] += (1-frac_x)*(1-frac_y)*( frac_z) * rgbweight[0] * scale; accu[0+4*( px + w*(py+1+ h*pz+h))] += (1-frac_x)*( frac_y)*( frac_z) * rgbweight[0] * scale; accu[0+4*( px+1 + w*(py + h*pz ))] += ( frac_x)*(1-frac_y)*(1-frac_z) * rgbweight[0] * scale; accu[0+4*( px+1 + w*(py + h*pz+h))] += ( frac_x)*(1-frac_y)*( frac_z) * rgbweight[0] * scale; accu[0+4*( px+1 + w*(py+1+ h*pz ))] += ( frac_x)*( frac_y)*(1-frac_z) * rgbweight[0] * scale; accu[0+4*( px+1 + w*(py+1+ h*pz+h))] += ( frac_x)*( frac_y)*( frac_z) * rgbweight[0] * scale; // add to g-channel in output image accu[1+4*( px + w*(py + h*pz ))] += (1-frac_x)*(1-frac_y)*(1-frac_z) * rgbweight[1] * scale; accu[1+4*( px + w*(py+1+ h*pz ))] += (1-frac_x)*( frac_y)*(1-frac_z) * rgbweight[1] * scale; accu[1+4*( px + w*(py + h*pz+h))] += (1-frac_x)*(1-frac_y)*( frac_z) * rgbweight[1] * scale; accu[1+4*( px + w*(py+1+ h*pz+h))] += (1-frac_x)*( frac_y)*( frac_z) * rgbweight[1] * scale; accu[1+4*( px+1 + w*(py + h*pz ))] += ( frac_x)*(1-frac_y)*(1-frac_z) * rgbweight[1] * scale; accu[1+4*( px+1 + w*(py + h*pz+h))] += ( frac_x)*(1-frac_y)*( frac_z) * rgbweight[1] * scale; accu[1+4*( px+1 + w*(py+1+ h*pz ))] += ( frac_x)*( frac_y)*(1-frac_z) * rgbweight[1] * scale; accu[1+4*( px+1 + w*(py+1+ h*pz+h))] += ( frac_x)*( frac_y)*( frac_z) * rgbweight[1] * scale; // add to b-channel in output image accu[2+4*( px + w*(py + h*pz ))] += (1-frac_x)*(1-frac_y)*(1-frac_z) * rgbweight[2] * scale; accu[2+4*( px + w*(py+1+ h*pz ))] += (1-frac_x)*( frac_y)*(1-frac_z) * rgbweight[2] * scale; accu[2+4*( px + w*(py + h*pz+h))] += (1-frac_x)*(1-frac_y)*( frac_z) * rgbweight[2] * scale; accu[2+4*( px + w*(py+1+ h*pz+h))] += (1-frac_x)*( frac_y)*( frac_z) * rgbweight[2] * scale; accu[2+4*( px+1 + w*(py + h*pz ))] += ( frac_x)*(1-frac_y)*(1-frac_z) * rgbweight[2] * scale; accu[2+4*( px+1 + w*(py + h*pz+h))] += ( frac_x)*(1-frac_y)*( frac_z) * rgbweight[2] * scale; accu[2+4*( px+1 + w*(py+1+ h*pz ))] += ( frac_x)*( frac_y)*(1-frac_z) * rgbweight[2] * scale; accu[2+4*( px+1 + w*(py+1+ h*pz+h))] += ( frac_x)*( frac_y)*( frac_z) * rgbweight[2] * scale; // add to a-channel in output image accu[3+4*( px + w*(py + h*pz ))] += (1-frac_x)*(1-frac_y)*(1-frac_z) * intweight * scale; accu[3+4*( px + w*(py+1+ h*pz ))] += (1-frac_x)*( frac_y)*(1-frac_z) * intweight * scale; accu[3+4*( px + w*(py + h*pz+h))] += (1-frac_x)*(1-frac_y)*( frac_z) * intweight * scale; accu[3+4*( px + w*(py+1+ h*pz+h))] += (1-frac_x)*( frac_y)*( frac_z) * intweight * scale; accu[3+4*( px+1 + w*(py + h*pz ))] += ( frac_x)*(1-frac_y)*(1-frac_z) * intweight * scale; accu[3+4*( px+1 + w*(py + h*pz+h))] += ( frac_x)*(1-frac_y)*( frac_z) * intweight * scale; accu[3+4*( px+1 + w*(py+1+ h*pz ))] += ( frac_x)*( frac_y)*(1-frac_z) * intweight * scale; accu[3+4*( px+1 + w*(py+1+ h*pz+h))] += ( frac_x)*( frac_y)*( frac_z) * intweight * scale; } else if (m_BinaryEnvelope) { accu[( px + w*(py + h*pz ))] = 1; accu[( px + w*(py+1+ h*pz ))] = 1; accu[( px + w*(py + h*pz+h))] = 1; accu[( px + w*(py+1+ h*pz+h))] = 1; accu[( px+1 + w*(py + h*pz ))] = 1; accu[( px+1 + w*(py + h*pz+h))] = 1; accu[( px+1 + w*(py+1+ h*pz ))] = 1; accu[( px+1 + w*(py+1+ h*pz+h))] = 1; } else { accu[( px + w*(py + h*pz ))] += (1-frac_x)*(1-frac_y)*(1-frac_z) * intweight * scale; accu[( px + w*(py+1+ h*pz ))] += (1-frac_x)*( frac_y)*(1-frac_z) * intweight * scale; accu[( px + w*(py + h*pz+h))] += (1-frac_x)*(1-frac_y)*( frac_z) * intweight * scale; accu[( px + w*(py+1+ h*pz+h))] += (1-frac_x)*( frac_y)*( frac_z) * intweight * scale; accu[( px+1 + w*(py + h*pz ))] += ( frac_x)*(1-frac_y)*(1-frac_z) * intweight * scale; accu[( px+1 + w*(py + h*pz+h))] += ( frac_x)*(1-frac_y)*( frac_z) * intweight * scale; accu[( px+1 + w*(py+1+ h*pz ))] += ( frac_x)*( frac_y)*(1-frac_z) * intweight * scale; accu[( px+1 + w*(py+1+ h*pz+h))] += ( frac_x)*( frac_y)*( frac_z) * intweight * scale; } } } float maxRgb = 0.000000001; float maxInt = 0.000000001; int numPix; if(isRgba) { numPix = w*h*d*4; // calc maxima for(int i=0; i<numPix; i++) { if((i-3)%4 != 0) { if(accu[i] > maxRgb) { maxRgb = accu[i]; } } else { if(accu[i] > maxInt) { maxInt = accu[i]; } } } // write output, normalized uchar 0..255 for(int i=0; i<numPix; i++) { if((i-3)%4 != 0) { accuout[i] = (unsigned char) (255.0 * accu[i] / maxRgb); } else { accuout[i] = (unsigned char) (255.0 * accu[i] / maxInt); } } } else if (m_BinaryEnvelope) { numPix = w*h*d; // write output, normalized uchar 0..255 for(int i=0; i<numPix; i++) { if(m_InvertImage) { accuout[i] = (unsigned char) ((int)(accu[i]+1)%2); } else { accuout[i] = (unsigned char) accu[i]; } } } else { numPix = w*h*d; // calc maxima for(int i=0; i<numPix; i++) { if(accu[i] > maxInt) { maxInt = accu[i]; } } // write output, normalized uchar 0..255 for(int i=0; i<numPix; i++) { accuout[i] = (unsigned char) (255.0 * accu[i] / maxInt); } } delete[] accu; }
void ExtractChannelFromRgbaImageFilter< ReferenceImageType, OutputImageType >::GenerateData() { typename InputImageType::Pointer rgbaImage = static_cast< InputImageType * >( this->ProcessObject::GetInput(0) ); typename OutputImageType::Pointer outputImage = static_cast< OutputImageType * >(this->ProcessObject::GetOutput(0)); typename InputImageType::RegionType region = rgbaImage->GetLargestPossibleRegion(); outputImage->SetSpacing( m_ReferenceImage->GetSpacing() ); // Set the image spacing outputImage->SetOrigin( m_ReferenceImage->GetOrigin() ); // Set the image origin outputImage->SetDirection( m_ReferenceImage->GetDirection() ); // Set the image direction outputImage->SetRegions( m_ReferenceImage->GetLargestPossibleRegion()); outputImage->Allocate(); outputImage->FillBuffer(0); float* outImageBufferPointer = outputImage->GetBufferPointer(); itk::Image< short, 3 >::Pointer counterImage = itk::Image< short, 3 >::New(); counterImage->SetSpacing( m_ReferenceImage->GetSpacing() ); // Set the image spacing counterImage->SetOrigin( m_ReferenceImage->GetOrigin() ); // Set the image origin counterImage->SetDirection( m_ReferenceImage->GetDirection() ); // Set the image direction counterImage->SetRegions( m_ReferenceImage->GetLargestPossibleRegion()); counterImage->Allocate(); counterImage->FillBuffer(0); short* counterImageBufferPointer = counterImage->GetBufferPointer(); int w = m_ReferenceImage->GetLargestPossibleRegion().GetSize().GetElement(0); int h = m_ReferenceImage->GetLargestPossibleRegion().GetSize().GetElement(1); int d = m_ReferenceImage->GetLargestPossibleRegion().GetSize().GetElement(2); typedef ImageRegionConstIterator< InputImageType > InImageIteratorType; InImageIteratorType rgbaIt(rgbaImage, region); rgbaIt.GoToBegin(); while(!rgbaIt.IsAtEnd()){ InPixelType x = rgbaIt.Get(); ++rgbaIt; itk::Point<float, 3> vertex; itk::Index<3> index = rgbaIt.GetIndex(); rgbaImage->TransformIndexToPhysicalPoint(index, vertex); outputImage->TransformPhysicalPointToIndex(vertex, index); itk::ContinuousIndex<float, 3> contIndex; outputImage->TransformPhysicalPointToContinuousIndex(vertex, contIndex); float frac_x = contIndex[0] - index[0]; float frac_y = contIndex[1] - index[1]; float frac_z = contIndex[2] - index[2]; int px = index[0]; if (frac_x<0) { px -= 1; frac_x += 1; } int py = index[1]; if (frac_y<0) { py -= 1; frac_y += 1; } int pz = index[2]; if (frac_z<0) { pz -= 1; frac_z += 1; } frac_x = 1-frac_x; frac_y = 1-frac_y; frac_z = 1-frac_z; // int coordinates inside image? if (px < 0 || px >= w-1) continue; if (py < 0 || py >= h-1) continue; if (pz < 0 || pz >= d-1) continue; OutPixelType out; switch (m_Channel) { case RED: out = (float)x.GetRed()/255; break; case GREEN: out = (float)x.GetGreen()/255; break; case BLUE: out = (float)x.GetBlue()/255; break; case ALPHA: out = (float)x.GetAlpha()/255; } outImageBufferPointer[( px + w*(py + h*pz ))] += out*( frac_x)*( frac_y)*( frac_z); outImageBufferPointer[( px + w*(py+1+ h*pz ))] += out*( frac_x)*(1-frac_y)*( frac_z); outImageBufferPointer[( px + w*(py + h*pz+h))] += out*( frac_x)*( frac_y)*(1-frac_z); outImageBufferPointer[( px + w*(py+1+ h*pz+h))] += out*( frac_x)*(1-frac_y)*(1-frac_z); outImageBufferPointer[( px+1 + w*(py + h*pz ))] += out*(1-frac_x)*( frac_y)*( frac_z); outImageBufferPointer[( px+1 + w*(py + h*pz+h))] += out*(1-frac_x)*( frac_y)*(1-frac_z); outImageBufferPointer[( px+1 + w*(py+1+ h*pz ))] += out*(1-frac_x)*(1-frac_y)*( frac_z); outImageBufferPointer[( px+1 + w*(py+1+ h*pz+h))] += out*(1-frac_x)*(1-frac_y)*(1-frac_z); counterImageBufferPointer[( px + w*(py + h*pz ))] += 1; counterImageBufferPointer[( px + w*(py+1+ h*pz ))] += 1; counterImageBufferPointer[( px + w*(py + h*pz+h))] += 1; counterImageBufferPointer[( px + w*(py+1+ h*pz+h))] += 1; counterImageBufferPointer[( px+1 + w*(py + h*pz ))] += 1; counterImageBufferPointer[( px+1 + w*(py + h*pz+h))] += 1; counterImageBufferPointer[( px+1 + w*(py+1+ h*pz ))] += 1; counterImageBufferPointer[( px+1 + w*(py+1+ h*pz+h))] += 1; } typedef ImageRegionIterator< OutputImageType > OutImageIteratorType; OutImageIteratorType outIt(outputImage, outputImage->GetLargestPossibleRegion()); outIt.GoToBegin(); typedef ImageRegionConstIterator< itk::Image< short, 3 > > CountImageIteratorType; CountImageIteratorType counterIt(counterImage, counterImage->GetLargestPossibleRegion()); counterIt.GoToBegin(); while(!outIt.IsAtEnd() && !counterIt.IsAtEnd()){ if (counterIt.Value()>0) outIt.Set(outIt.Value()/counterIt.Value()); ++outIt; ++counterIt; } }
void DwiPhantomGenerationFilter< TOutputScalarType > ::GenerateData() { if (m_NoiseVariance < 0) m_NoiseVariance = 0.001; if (!m_SimulateBaseline) { MITK_INFO << "Baseline image values are set to default. Noise variance value is treated as SNR!"; if (m_NoiseVariance <= 0) m_NoiseVariance = 0.0001; if (m_NoiseVariance>99) m_NoiseVariance = 0; else { m_NoiseVariance = m_DefaultBaseline/(m_NoiseVariance*m_SignalScale); m_NoiseVariance *= m_NoiseVariance; } } m_RandGen = Statistics::MersenneTwisterRandomVariateGenerator::New(); m_RandGen->SetSeed(); typename OutputImageType::Pointer outImage = OutputImageType::New(); outImage->SetSpacing( m_Spacing ); outImage->SetOrigin( m_Origin ); outImage->SetDirection( m_DirectionMatrix ); outImage->SetLargestPossibleRegion( m_ImageRegion ); outImage->SetBufferedRegion( m_ImageRegion ); outImage->SetRequestedRegion( m_ImageRegion ); outImage->SetVectorLength(m_GradientList.size()); outImage->Allocate(); typename OutputImageType::PixelType pix; pix.SetSize(m_GradientList.size()); pix.Fill(0.0); outImage->FillBuffer(pix); this->SetNthOutput (0, outImage); double minSpacing = m_Spacing[0]; if (m_Spacing[1]<minSpacing) minSpacing = m_Spacing[1]; if (m_Spacing[2]<minSpacing) minSpacing = m_Spacing[2]; m_DirectionImageContainer = ItkDirectionImageContainer::New(); for (int i=0; i<m_SignalRegions.size(); i++) { itk::Vector< float, 3 > nullVec; nullVec.Fill(0.0); ItkDirectionImage::Pointer img = ItkDirectionImage::New(); img->SetSpacing( m_Spacing ); img->SetOrigin( m_Origin ); img->SetDirection( m_DirectionMatrix ); img->SetRegions( m_ImageRegion ); img->Allocate(); img->FillBuffer(nullVec); m_DirectionImageContainer->InsertElement(m_DirectionImageContainer->Size(), img); } m_NumDirectionsImage = ItkUcharImgType::New(); m_NumDirectionsImage->SetSpacing( m_Spacing ); m_NumDirectionsImage->SetOrigin( m_Origin ); m_NumDirectionsImage->SetDirection( m_DirectionMatrix ); m_NumDirectionsImage->SetRegions( m_ImageRegion ); m_NumDirectionsImage->Allocate(); m_NumDirectionsImage->FillBuffer(0); m_SNRImage = ItkFloatImgType::New(); m_SNRImage->SetSpacing( m_Spacing ); m_SNRImage->SetOrigin( m_Origin ); m_SNRImage->SetDirection( m_DirectionMatrix ); m_SNRImage->SetRegions( m_ImageRegion ); m_SNRImage->Allocate(); m_SNRImage->FillBuffer(0); vtkSmartPointer<vtkCellArray> m_VtkCellArray = vtkSmartPointer<vtkCellArray>::New(); vtkSmartPointer<vtkPoints> m_VtkPoints = vtkSmartPointer<vtkPoints>::New(); m_BaselineImages = 0; for( unsigned int i=0; i<m_GradientList.size(); i++) if (m_GradientList[i].GetNorm()<=0.0001) m_BaselineImages++; typedef ImageRegionIterator<OutputImageType> IteratorOutputType; IteratorOutputType it (outImage, m_ImageRegion); // isotropic tensor itk::DiffusionTensor3D<float> isoTensor; isoTensor.Fill(0); float e1 = m_GreyMatterAdc; float e2 = m_GreyMatterAdc; float e3 = m_GreyMatterAdc; isoTensor.SetElement(0,e1); isoTensor.SetElement(3,e2); isoTensor.SetElement(5,e3); m_MaxBaseline = GetTensorL2Norm(isoTensor); GenerateTensors(); // simulate measurement m_MeanBaseline = 0; double noiseStdev = sqrt(m_NoiseVariance); while(!it.IsAtEnd()) { pix = it.Get(); typename OutputImageType::IndexType index = it.GetIndex(); int numDirs = 0; for (int i=0; i<m_SignalRegions.size(); i++) { ItkUcharImgType::Pointer region = m_SignalRegions.at(i); if (region->GetPixel(index)!=0) { numDirs++; pix += SimulateMeasurement(m_TensorList[i], m_TensorWeight[i]); // set direction image pixel ItkDirectionImage::Pointer img = m_DirectionImageContainer->GetElement(i); itk::Vector< float, 3 > pixel = img->GetPixel(index); vnl_vector_fixed<double, 3> dir = m_TensorDirection.at(i); dir.normalize(); dir *= m_TensorWeight.at(i); pixel.SetElement(0, dir[0]); pixel.SetElement(1, dir[1]); pixel.SetElement(2, dir[2]); img->SetPixel(index, pixel); vtkSmartPointer<vtkPolyLine> container = vtkSmartPointer<vtkPolyLine>::New(); itk::ContinuousIndex<double, 3> center; center[0] = index[0]; center[1] = index[1]; center[2] = index[2]; itk::Point<double> worldCenter; outImage->TransformContinuousIndexToPhysicalPoint( center, worldCenter ); itk::Point<double> worldStart; worldStart[0] = worldCenter[0]-dir[0]/2 * minSpacing; worldStart[1] = worldCenter[1]-dir[1]/2 * minSpacing; worldStart[2] = worldCenter[2]-dir[2]/2 * minSpacing; vtkIdType id = m_VtkPoints->InsertNextPoint(worldStart.GetDataPointer()); container->GetPointIds()->InsertNextId(id); itk::Point<double> worldEnd; worldEnd[0] = worldCenter[0]+dir[0]/2 * minSpacing; worldEnd[1] = worldCenter[1]+dir[1]/2 * minSpacing; worldEnd[2] = worldCenter[2]+dir[2]/2 * minSpacing; id = m_VtkPoints->InsertNextPoint(worldEnd.GetDataPointer()); container->GetPointIds()->InsertNextId(id); m_VtkCellArray->InsertNextCell(container); } } if (numDirs>1) { for (int i=0; i<m_GradientList.size(); i++) pix[i] /= numDirs; } else if (numDirs==0) { if (m_SimulateBaseline) pix = SimulateMeasurement(isoTensor, 1.0); else pix.Fill(0.0); } m_MeanBaseline += pix[0]; it.Set(pix); m_NumDirectionsImage->SetPixel(index, numDirs); if (m_NoiseVariance>0) m_SNRImage->SetPixel(index, pix[0]/(noiseStdev*m_SignalScale)); ++it; } m_MeanBaseline /= m_ImageRegion.GetNumberOfPixels(); if (m_NoiseVariance>0) MITK_INFO << "Mean SNR: " << m_MeanBaseline/(noiseStdev*m_SignalScale); else MITK_INFO << "No noise added"; // add rician noise it.GoToBegin(); while(!it.IsAtEnd()) { pix = it.Get(); AddNoise(pix); it.Set(pix); ++it; } // generate fiber bundle vtkSmartPointer<vtkPolyData> directionsPolyData = vtkSmartPointer<vtkPolyData>::New(); directionsPolyData->SetPoints(m_VtkPoints); directionsPolyData->SetLines(m_VtkCellArray); m_OutputFiberBundle = mitk::FiberBundleX::New(directionsPolyData); }
template <class inputType, unsigned int Dimension> medAbstractJob::medJobExitStatus medItkBiasCorrectionProcess::N4BiasCorrectionCore() { medJobExitStatus eRes = medAbstractJob::MED_JOB_EXIT_SUCCESS; typedef itk::Image<inputType, Dimension > ImageType; typedef itk::Image <float, Dimension> OutputImageType; typedef itk::Image<unsigned char, Dimension> MaskImageType; typedef itk::N4BiasFieldCorrectionImageFilter<OutputImageType, MaskImageType, OutputImageType> BiasFilter; typedef itk::ConstantPadImageFilter<OutputImageType, OutputImageType> PadderType; typedef itk::ConstantPadImageFilter<MaskImageType, MaskImageType> MaskPadderType; typedef itk::ShrinkImageFilter<OutputImageType, OutputImageType> ShrinkerType; typedef itk::ShrinkImageFilter<MaskImageType, MaskImageType> MaskShrinkerType; typedef itk::BSplineControlPointImageFilter<typename BiasFilter::BiasFieldControlPointLatticeType, typename BiasFilter::ScalarImageType> BSplinerType; typedef itk::ExpImageFilter<OutputImageType, OutputImageType> ExpFilterType; typedef itk::DivideImageFilter<OutputImageType, OutputImageType, OutputImageType> DividerType; typedef itk::ExtractImageFilter<OutputImageType, OutputImageType> CropperType; unsigned int uiThreadNb = static_cast<unsigned int>(m_poUIThreadNb->value()); unsigned int uiShrinkFactors = static_cast<unsigned int>(m_poUIShrinkFactors->value()); unsigned int uiSplineOrder = static_cast<unsigned int>(m_poUISplineOrder->value()); float fWienerFilterNoise = static_cast<float>(m_poFWienerFilterNoise->value()); float fbfFWHM = static_cast<float>(m_poFbfFWHM->value()); float fConvergenceThreshold = static_cast<float>(m_poFConvergenceThreshold->value()); float fSplineDistance = static_cast<float>(m_poFSplineDistance->value()); float fProgression = 0; QStringList oListValue = m_poSMaxIterations->value().split("x"); std::vector<unsigned int> oMaxNumbersIterationsVector(oListValue.size()); std::vector<float> oInitialMeshResolutionVect(Dimension); for (int i=0; i<oMaxNumbersIterationsVector.size(); ++i) { oMaxNumbersIterationsVector[i] = (unsigned int)oListValue[i].toInt(); } oInitialMeshResolutionVect[0] = static_cast<float>(m_poFInitialMeshResolutionVect1->value()); oInitialMeshResolutionVect[1] = static_cast<float>(m_poFInitialMeshResolutionVect2->value()); oInitialMeshResolutionVect[2] = static_cast<float>(m_poFInitialMeshResolutionVect3->value()); typename ImageType::Pointer image = dynamic_cast<ImageType *>((itk::Object*)(this->input()->data())); typedef itk::CastImageFilter <ImageType, OutputImageType> CastFilterType; typename CastFilterType::Pointer castFilter = CastFilterType::New(); castFilter->SetInput(image); /********************************************************************************/ /***************************** PREPARING STARTING *******************************/ /********************************************************************************/ /*** 0 ******************* Create filter and accessories ******************/ ABORT_CHECKING(m_bAborting); typename BiasFilter::Pointer filter = BiasFilter::New(); typename BiasFilter::ArrayType oNumberOfControlPointsArray; m_filter = filter; /*** 1 ******************* Read input image *******************************/ ABORT_CHECKING(m_bAborting); fProgression = 1; updateProgression(fProgression); /*** 2 ******************* Creating Otsu mask *****************************/ ABORT_CHECKING(m_bAborting); itk::TimeProbe timer; timer.Start(); typename MaskImageType::Pointer maskImage = ITK_NULLPTR; typedef itk::OtsuThresholdImageFilter<OutputImageType, MaskImageType> ThresholderType; typename ThresholderType::Pointer otsu = ThresholderType::New(); m_filter = otsu; otsu->SetInput(castFilter->GetOutput()); otsu->SetNumberOfHistogramBins(200); otsu->SetInsideValue(0); otsu->SetOutsideValue(1); otsu->SetNumberOfThreads(uiThreadNb); otsu->Update(); updateProgression(fProgression); maskImage = otsu->GetOutput(); /*** 3A *************** Set Maximum number of Iterations for the filter ***/ ABORT_CHECKING(m_bAborting); typename BiasFilter::VariableSizeArrayType itkTabMaximumIterations; itkTabMaximumIterations.SetSize(oMaxNumbersIterationsVector.size()); for (int i = 0; i < oMaxNumbersIterationsVector.size(); ++i) { itkTabMaximumIterations[i] = oMaxNumbersIterationsVector[i]; } filter->SetMaximumNumberOfIterations(itkTabMaximumIterations); /*** 3B *************** Set Fitting Levels for the filter *****************/ typename BiasFilter::ArrayType oFittingLevelsTab; oFittingLevelsTab.Fill(oMaxNumbersIterationsVector.size()); filter->SetNumberOfFittingLevels(oFittingLevelsTab); updateProgression(fProgression); /*** 4 ******************* Save image's index, size, origine **************/ ABORT_CHECKING(m_bAborting); typename ImageType::IndexType oImageIndex = image->GetLargestPossibleRegion().GetIndex(); typename ImageType::SizeType oImageSize = image->GetLargestPossibleRegion().GetSize(); typename ImageType::PointType newOrigin = image->GetOrigin(); typename OutputImageType::Pointer outImage = castFilter->GetOutput(); if (fSplineDistance > 0) { /*** 5 ******************* Compute number of control points **************/ ABORT_CHECKING(m_bAborting); itk::SizeValueType lowerBound[3]; itk::SizeValueType upperBound[3]; for (unsigned int i = 0; i < 3; i++) { float domain = static_cast<float>(image->GetLargestPossibleRegion().GetSize()[i] - 1) * image->GetSpacing()[i]; unsigned int numberOfSpans = static_cast<unsigned int>(std::ceil(domain / fSplineDistance)); unsigned long extraPadding = static_cast<unsigned long>((numberOfSpans * fSplineDistance - domain) / image->GetSpacing()[i] + 0.5); lowerBound[i] = static_cast<unsigned long>(0.5 * extraPadding); upperBound[i] = extraPadding - lowerBound[i]; newOrigin[i] -= (static_cast<float>(lowerBound[i]) * image->GetSpacing()[i]); oNumberOfControlPointsArray[i] = numberOfSpans + filter->GetSplineOrder(); } updateProgression(fProgression); /*** 6 ******************* Padder ****************************************/ ABORT_CHECKING(m_bAborting); typename PadderType::Pointer imagePadder = PadderType::New(); m_filter = imagePadder; imagePadder->SetInput(castFilter->GetOutput()); imagePadder->SetPadLowerBound(lowerBound); imagePadder->SetPadUpperBound(upperBound); imagePadder->SetConstant(0); imagePadder->SetNumberOfThreads(uiThreadNb); imagePadder->Update(); updateProgression(fProgression); outImage = imagePadder->GetOutput(); /*** 7 ******************** Handle the mask image *************************/ ABORT_CHECKING(m_bAborting); typename MaskPadderType::Pointer maskPadder = MaskPadderType::New(); m_filter = maskPadder; maskPadder->SetInput(maskImage); maskPadder->SetPadLowerBound(lowerBound); maskPadder->SetPadUpperBound(upperBound); maskPadder->SetConstant(0); maskPadder->SetNumberOfThreads(uiThreadNb); maskPadder->Update(); updateProgression(fProgression); maskImage = maskPadder->GetOutput(); /*** 8 ******************** SetNumber Of Control Points *******************/ ABORT_CHECKING(m_bAborting); filter->SetNumberOfControlPoints(oNumberOfControlPointsArray); } else if (oInitialMeshResolutionVect.size() == 3) { /*** 9 ******************** SetNumber Of Control Points alternative *******/ ABORT_CHECKING(m_bAborting); for (unsigned i = 0; i < 3; i++) { oNumberOfControlPointsArray[i] = static_cast<unsigned int>(oInitialMeshResolutionVect[i]) + filter->GetSplineOrder(); } filter->SetNumberOfControlPoints(oNumberOfControlPointsArray); updateProgression(fProgression, 3); } else { fProgression = 0; updateProgression(fProgression); std::cout << "No BSpline distance and Mesh Resolution is ignored because not 3 dimensions" << std::endl; } /*** 10 ******************* Shrinker image ********************************/ ABORT_CHECKING(m_bAborting); typename ShrinkerType::Pointer imageShrinker = ShrinkerType::New(); m_filter = imageShrinker; imageShrinker->SetInput(outImage); /*** 11 ******************* Shrinker mask *********************************/ ABORT_CHECKING(m_bAborting); typename MaskShrinkerType::Pointer maskShrinker = MaskShrinkerType::New(); m_filter = maskShrinker; maskShrinker->SetInput(maskImage); /*** 12 ******************* Shrink mask and image *************************/ ABORT_CHECKING(m_bAborting); imageShrinker->SetShrinkFactors(uiShrinkFactors); maskShrinker->SetShrinkFactors(uiShrinkFactors); imageShrinker->SetNumberOfThreads(uiThreadNb); maskShrinker->SetNumberOfThreads(uiThreadNb); imageShrinker->Update(); updateProgression(fProgression); maskShrinker->Update(); updateProgression(fProgression); /*** 13 ******************* Filter setings ********************************/ ABORT_CHECKING(m_bAborting); filter->SetSplineOrder(uiSplineOrder); filter->SetWienerFilterNoise(fWienerFilterNoise); filter->SetBiasFieldFullWidthAtHalfMaximum(fbfFWHM); filter->SetConvergenceThreshold(fConvergenceThreshold); filter->SetInput(imageShrinker->GetOutput()); filter->SetMaskImage(maskShrinker->GetOutput()); /*** 14 ******************* Apply filter **********************************/ ABORT_CHECKING(m_bAborting); try { filter->SetNumberOfThreads(uiThreadNb); filter->Update(); updateProgression(fProgression, 5); } catch (itk::ExceptionObject & err) { std::cerr << "ExceptionObject caught !" << std::endl; std::cerr << err << std::endl; eRes = medAbstractJob::MED_JOB_EXIT_FAILURE; return eRes; } /** * Reconstruct the bias field at full image resolution. Divide * the original input image by the bias field to get the final * corrected image. */ ABORT_CHECKING(m_bAborting); typename BSplinerType::Pointer bspliner = BSplinerType::New(); m_filter = bspliner; bspliner->SetInput(filter->GetLogBiasFieldControlPointLattice()); bspliner->SetSplineOrder(filter->GetSplineOrder()); bspliner->SetSize(image->GetLargestPossibleRegion().GetSize()); bspliner->SetOrigin(newOrigin); bspliner->SetDirection(image->GetDirection()); bspliner->SetSpacing(image->GetSpacing()); bspliner->SetNumberOfThreads(uiThreadNb); bspliner->Update(); updateProgression(fProgression); /*********************** Logarithm phase ***************************/ ABORT_CHECKING(m_bAborting); typename OutputImageType::Pointer logField = OutputImageType::New(); logField->SetOrigin(image->GetOrigin()); logField->SetSpacing(image->GetSpacing()); logField->SetRegions(image->GetLargestPossibleRegion()); logField->SetDirection(image->GetDirection()); logField->Allocate(); itk::ImageRegionIterator<typename BiasFilter::ScalarImageType> IB(bspliner->GetOutput(), bspliner->GetOutput()->GetLargestPossibleRegion()); itk::ImageRegionIterator<OutputImageType> IF(logField, logField->GetLargestPossibleRegion()); for (IB.GoToBegin(), IF.GoToBegin(); !IB.IsAtEnd(); ++IB, ++IF) { IF.Set(IB.Get()[0]); } /*********************** Exponential phase *************************/ ABORT_CHECKING(m_bAborting); typename ExpFilterType::Pointer expFilter = ExpFilterType::New(); m_filter = expFilter; expFilter->SetInput(logField); expFilter->SetNumberOfThreads(uiThreadNb); expFilter->Update(); updateProgression(fProgression); /************************ Dividing phase ***************************/ ABORT_CHECKING(m_bAborting); typename DividerType::Pointer divider = DividerType::New(); m_filter = divider; divider->SetInput1(castFilter->GetOutput()); divider->SetInput2(expFilter->GetOutput()); divider->SetNumberOfThreads(uiThreadNb); divider->Update(); updateProgression(fProgression); /******************** Prepare cropping phase ***********************/ ABORT_CHECKING(m_bAborting); typename ImageType::RegionType inputRegion; inputRegion.SetIndex(oImageIndex); inputRegion.SetSize(oImageSize); /************************ Cropping phase ***************************/ ABORT_CHECKING(m_bAborting); typename CropperType::Pointer cropper = CropperType::New(); m_filter = cropper; cropper->SetInput(divider->GetOutput()); cropper->SetExtractionRegion(inputRegion); cropper->SetDirectionCollapseToSubmatrix(); cropper->SetNumberOfThreads(uiThreadNb); cropper->Update(); updateProgression(fProgression); /********************** Write output image *************************/ ABORT_CHECKING(m_bAborting); medAbstractImageData *out = qobject_cast<medAbstractImageData *>(medAbstractDataFactory::instance()->create("itkDataImageFloat3")); out->setData(cropper->GetOutput()); this->setOutput(out); m_filter = 0; return eRes; }
void TractsToFiberEndingsImageFilter< OutputImageType >::GenerateData() { // generate upsampled image mitk::Geometry3D::Pointer geometry = m_FiberBundle->GetGeometry(); typename OutputImageType::Pointer outImage = this->GetOutput(); // calculate new image parameters mitk::Vector3D newSpacing; mitk::Point3D newOrigin; itk::Matrix<double, 3, 3> newDirection; ImageRegion<3> upsampledRegion; if (m_UseImageGeometry && !m_InputImage.IsNull()) { newSpacing = m_InputImage->GetSpacing()/m_UpsamplingFactor; upsampledRegion = m_InputImage->GetLargestPossibleRegion(); newOrigin = m_InputImage->GetOrigin(); typename OutputImageType::RegionType::SizeType size = upsampledRegion.GetSize(); size[0] *= m_UpsamplingFactor; size[1] *= m_UpsamplingFactor; size[2] *= m_UpsamplingFactor; upsampledRegion.SetSize(size); newDirection = m_InputImage->GetDirection(); } else { newSpacing = geometry->GetSpacing()/m_UpsamplingFactor; newOrigin = geometry->GetOrigin(); mitk::Geometry3D::BoundsArrayType bounds = geometry->GetBounds(); newOrigin[0] += bounds.GetElement(0); newOrigin[1] += bounds.GetElement(2); newOrigin[2] += bounds.GetElement(4); for (int i=0; i<3; i++) for (int j=0; j<3; j++) newDirection[j][i] = geometry->GetMatrixColumn(i)[j]; upsampledRegion.SetSize(0, geometry->GetExtent(0)*m_UpsamplingFactor); upsampledRegion.SetSize(1, geometry->GetExtent(1)*m_UpsamplingFactor); upsampledRegion.SetSize(2, geometry->GetExtent(2)*m_UpsamplingFactor); } typename OutputImageType::RegionType::SizeType upsampledSize = upsampledRegion.GetSize(); // apply new image parameters outImage->SetSpacing( newSpacing ); outImage->SetOrigin( newOrigin ); outImage->SetDirection( newDirection ); outImage->SetRegions( upsampledRegion ); outImage->Allocate(); int w = upsampledSize[0]; int h = upsampledSize[1]; int d = upsampledSize[2]; // set/initialize output OutPixelType* outImageBufferPointer = (OutPixelType*)outImage->GetBufferPointer(); for (int i=0; i<w*h*d; i++) outImageBufferPointer[i] = 0; // resample fiber bundle float minSpacing = 1; if(newSpacing[0]<newSpacing[1] && newSpacing[0]<newSpacing[2]) minSpacing = newSpacing[0]; else if (newSpacing[1] < newSpacing[2]) minSpacing = newSpacing[1]; else minSpacing = newSpacing[2]; vtkSmartPointer<vtkPolyData> fiberPolyData = m_FiberBundle->GetFiberPolyData(); vtkSmartPointer<vtkCellArray> vLines = fiberPolyData->GetLines(); vLines->InitTraversal(); int numFibers = m_FiberBundle->GetNumFibers(); boost::progress_display disp(numFibers); for( int i=0; i<numFibers; i++ ) { ++disp; vtkIdType numPoints(0); vtkIdType* points(NULL); vLines->GetNextCell ( numPoints, points ); // fill output image if (numPoints>0) { itk::Point<float, 3> vertex = GetItkPoint(fiberPolyData->GetPoint(points[0])); itk::Index<3> index; outImage->TransformPhysicalPointToIndex(vertex, index); if (m_BinaryOutput) outImage->SetPixel(index, 1); else outImage->SetPixel(index, outImage->GetPixel(index)+1); } if (numPoints>2) { itk::Point<float, 3> vertex = GetItkPoint(fiberPolyData->GetPoint(points[numPoints-1])); itk::Index<3> index; outImage->TransformPhysicalPointToIndex(vertex, index); if (m_BinaryOutput) outImage->SetPixel(index, 1); else outImage->SetPixel(index, outImage->GetPixel(index)+1); } } if (m_InvertImage) for (int i=0; i<w*h*d; i++) outImageBufferPointer[i] = 1-outImageBufferPointer[i]; }