diff --git a/Modules/DiffusionImaging/FiberTracking/Algorithms/itkFiberCurvatureFilter.cpp b/Modules/DiffusionImaging/FiberTracking/Algorithms/itkFiberCurvatureFilter.cpp index dacd6964a1..a2ebc7e7f1 100644 --- a/Modules/DiffusionImaging/FiberTracking/Algorithms/itkFiberCurvatureFilter.cpp +++ b/Modules/DiffusionImaging/FiberTracking/Algorithms/itkFiberCurvatureFilter.cpp @@ -1,149 +1,149 @@ /*=================================================================== The Medical Imaging Interaction Toolkit (MITK) Copyright (c) German Cancer Research Center, Division of Medical and Biological Informatics. All rights reserved. This software is distributed WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See LICENSE.txt or http://www.mitk.org for details. ===================================================================*/ #include "itkFiberCurvatureFilter.h" #define _USE_MATH_DEFINES #include #include #include #include namespace itk{ FiberCurvatureFilter::FiberCurvatureFilter() : m_AngularDeviation(30) , m_Distance(5.0) , m_RemoveFibers(false) { } FiberCurvatureFilter::~FiberCurvatureFilter() { } void FiberCurvatureFilter::GenerateData() { vtkSmartPointer inputPoly = m_InputFiberBundle->GetFiberPolyData(); vtkSmartPointer vtkNewPoints = vtkSmartPointer::New(); vtkSmartPointer vtkNewCells = vtkSmartPointer::New(); MITK_INFO << "Applying curvature threshold"; boost::progress_display disp(inputPoly->GetNumberOfCells()); for (int i=0; iGetNumberOfCells(); i++) { ++disp; vtkCell* cell = inputPoly->GetCell(i); int numPoints = cell->GetNumberOfPoints(); vtkPoints* points = cell->GetPoints(); // calculate curvatures vtkSmartPointer container = vtkSmartPointer::New(); for (int j=0; j > vectors; vnl_vector_fixed< float, 3 > meanV; meanV.fill(0.0); while(dist1) { double p1[3]; points->GetPoint(c-1, p1); double p2[3]; points->GetPoint(c, p2); vnl_vector_fixed< float, 3 > v; v[0] = p2[0]-p1[0]; v[1] = p2[1]-p1[1]; v[2] = p2[2]-p1[2]; dist += v.magnitude(); v.normalize(); vectors.push_back(v); if (c==j) meanV += v; c--; } c = j; dist = 0; while(distGetPoint(c, p1); double p2[3]; points->GetPoint(c+1, p2); vnl_vector_fixed< float, 3 > v; v[0] = p2[0]-p1[0]; v[1] = p2[1]-p1[1]; v[2] = p2[2]-p1[2]; dist += v.magnitude(); v.normalize(); vectors.push_back(v); if (c==j) meanV += v; c++; } meanV.normalize(); double dev = 0; - for (int c=0; c1.0) angle = 1.0; if (angle<-1.0) angle = -1.0; dev += acos(angle)*180/M_PI; } if (vectors.size()>0) dev /= vectors.size(); if (devGetPoint(j, p); vtkIdType id = vtkNewPoints->InsertNextPoint(p); container->GetPointIds()->InsertNextId(id); } else { if (m_RemoveFibers) { container = vtkSmartPointer::New(); break; } if (container->GetNumberOfPoints()>0) vtkNewCells->InsertNextCell(container); container = vtkSmartPointer::New(); } } if (container->GetNumberOfPoints()>0) vtkNewCells->InsertNextCell(container); } vtkSmartPointer outputPoly = vtkSmartPointer::New(); outputPoly->SetPoints(vtkNewPoints); outputPoly->SetLines(vtkNewCells); m_OutputFiberBundle = FiberBundle::New(outputPoly); } } diff --git a/Plugins/org.mitk.gui.qt.diffusionimaging/src/internal/QmitkFiberProcessingView.cpp b/Plugins/org.mitk.gui.qt.diffusionimaging/src/internal/QmitkFiberProcessingView.cpp index 138489d02f..4e7e02c8b9 100644 --- a/Plugins/org.mitk.gui.qt.diffusionimaging/src/internal/QmitkFiberProcessingView.cpp +++ b/Plugins/org.mitk.gui.qt.diffusionimaging/src/internal/QmitkFiberProcessingView.cpp @@ -1,1365 +1,1378 @@ /*=================================================================== The Medical Imaging Interaction Toolkit (MITK) Copyright (c) German Cancer Research Center, Division of Medical and Biological Informatics. All rights reserved. This software is distributed WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See LICENSE.txt or http://www.mitk.org for details. ===================================================================*/ // Blueberry #include #include // Qmitk #include "QmitkFiberProcessingView.h" #include // Qt #include // MITK #include #include #include #include #include #include #include #include #include #include #include #include "usModuleRegistry.h" #include #include "mitkNodePredicateDataType.h" #include #include #include #include // ITK #include #include #include #include #include #include #include #define _USE_MATH_DEFINES #include const std::string QmitkFiberProcessingView::VIEW_ID = "org.mitk.views.fiberprocessing"; const std::string id_DataManager = "org.mitk.views.datamanager"; using namespace mitk; QmitkFiberProcessingView::QmitkFiberProcessingView() : QmitkFunctionality() , m_Controls( 0 ) , m_MultiWidget( NULL ) , m_CircleCounter(0) , m_PolygonCounter(0) , m_UpsamplingFactor(1) { } // Destructor QmitkFiberProcessingView::~QmitkFiberProcessingView() { } void QmitkFiberProcessingView::CreateQtPartControl( QWidget *parent ) { // build up qt view, unless already done if ( !m_Controls ) { // create GUI widgets from the Qt Designer's .ui file m_Controls = new Ui::QmitkFiberProcessingViewControls; m_Controls->setupUi( parent ); connect( m_Controls->m_CircleButton, SIGNAL( clicked() ), this, SLOT( OnDrawCircle() ) ); connect( m_Controls->m_PolygonButton, SIGNAL( clicked() ), this, SLOT( OnDrawPolygon() ) ); connect(m_Controls->PFCompoANDButton, SIGNAL(clicked()), this, SLOT(GenerateAndComposite()) ); connect(m_Controls->PFCompoORButton, SIGNAL(clicked()), this, SLOT(GenerateOrComposite()) ); connect(m_Controls->PFCompoNOTButton, SIGNAL(clicked()), this, SLOT(GenerateNotComposite()) ); connect(m_Controls->m_GenerateRoiImage, SIGNAL(clicked()), this, SLOT(GenerateRoiImage()) ); connect(m_Controls->m_JoinBundles, SIGNAL(clicked()), this, SLOT(JoinBundles()) ); connect(m_Controls->m_SubstractBundles, SIGNAL(clicked()), this, SLOT(SubstractBundles()) ); + connect(m_Controls->m_CopyBundle, SIGNAL(clicked()), this, SLOT(CopyBundles()) ); connect(m_Controls->m_ExtractFibersButton, SIGNAL(clicked()), this, SLOT(Extract())); connect(m_Controls->m_RemoveButton, SIGNAL(clicked()), this, SLOT(Remove())); connect(m_Controls->m_ModifyButton, SIGNAL(clicked()), this, SLOT(Modify())); connect(m_Controls->m_ExtractionMethodBox, SIGNAL(currentIndexChanged(int)), this, SLOT(UpdateGui())); connect(m_Controls->m_RemovalMethodBox, SIGNAL(currentIndexChanged(int)), this, SLOT(UpdateGui())); connect(m_Controls->m_ModificationMethodBox, SIGNAL(currentIndexChanged(int)), this, SLOT(UpdateGui())); m_Controls->m_ColorMapBox->SetDataStorage(this->GetDataStorage()); mitk::TNodePredicateDataType::Pointer isMitkImage = mitk::TNodePredicateDataType::New(); mitk::NodePredicateDataType::Pointer isDwi = mitk::NodePredicateDataType::New("DiffusionImage"); mitk::NodePredicateDataType::Pointer isDti = mitk::NodePredicateDataType::New("TensorImage"); mitk::NodePredicateDataType::Pointer isQbi = mitk::NodePredicateDataType::New("QBallImage"); mitk::NodePredicateOr::Pointer isDiffusionImage = mitk::NodePredicateOr::New(isDwi, isDti); isDiffusionImage = mitk::NodePredicateOr::New(isDiffusionImage, isQbi); mitk::NodePredicateNot::Pointer noDiffusionImage = mitk::NodePredicateNot::New(isDiffusionImage); mitk::NodePredicateAnd::Pointer finalPredicate = mitk::NodePredicateAnd::New(isMitkImage, noDiffusionImage); m_Controls->m_ColorMapBox->SetPredicate(finalPredicate); } UpdateGui(); } void QmitkFiberProcessingView::Modify() { switch (m_Controls->m_ModificationMethodBox->currentIndex()) { case 0: { ResampleSelectedBundles(); break; } case 1: { CompressSelectedBundles(); break; } case 2: { DoImageColorCoding(); break; } case 3: { MirrorFibers(); break; } case 4: { WeightFibers(); break; } case 5: { DoCurvatureColorCoding(); break; } } } void QmitkFiberProcessingView::WeightFibers() { float weight = this->m_Controls->m_BundleWeightBox->value(); - for (int i=0; i(m_SelectedFB.at(i)->GetData()); + mitk::FiberBundle::Pointer fib = dynamic_cast(node->GetData()); fib->SetFiberWeights(weight); } } void QmitkFiberProcessingView::Remove() { switch (m_Controls->m_RemovalMethodBox->currentIndex()) { case 0: { RemoveDir(); break; } case 1: { PruneBundle(); break; } case 2: { ApplyCurvatureThreshold(); break; } case 3: { RemoveWithMask(false); break; } case 4: { RemoveWithMask(true); break; } } } void QmitkFiberProcessingView::Extract() { switch (m_Controls->m_ExtractionMethodBox->currentIndex()) { case 0: { ExtractWithPlanarFigure(); break; } case 1: { switch (m_Controls->m_ExtractionBoxMask->currentIndex()) { { case 0: - ExtractWithMask(true, false); - break; + ExtractWithMask(true, false); + break; } { case 1: - ExtractWithMask(true, true); - break; + ExtractWithMask(true, true); + break; } { case 2: - ExtractWithMask(false, false); - break; + ExtractWithMask(false, false); + break; } { case 3: - ExtractWithMask(false, true); - break; + ExtractWithMask(false, true); + break; } } break; } } } void QmitkFiberProcessingView::PruneBundle() { int minLength = this->m_Controls->m_PruneFibersMinBox->value(); int maxLength = this->m_Controls->m_PruneFibersMaxBox->value(); - for (int i=0; i(m_SelectedFB.at(i)->GetData()); + mitk::FiberBundle::Pointer fib = dynamic_cast(node->GetData()); if (!fib->RemoveShortFibers(minLength)) QMessageBox::information(NULL, "No output generated:", "The resulting fiber bundle contains no fibers."); else if (!fib->RemoveLongFibers(maxLength)) QMessageBox::information(NULL, "No output generated:", "The resulting fiber bundle contains no fibers."); } RenderingManager::GetInstance()->RequestUpdateAll(); } void QmitkFiberProcessingView::ApplyCurvatureThreshold() { int angle = this->m_Controls->m_CurvSpinBox->value(); int dist = this->m_Controls->m_CurvDistanceSpinBox->value(); std::vector< DataNode::Pointer > nodes = m_SelectedFB; - for (int i=0; i(nodes.at(i)->GetData()); + mitk::FiberBundle::Pointer fib = dynamic_cast(node->GetData()); itk::FiberCurvatureFilter::Pointer filter = itk::FiberCurvatureFilter::New(); filter->SetInputFiberBundle(fib); filter->SetAngularDeviation(angle); filter->SetDistance(dist); filter->SetRemoveFibers(m_Controls->m_RemoveCurvedFibersBox->isChecked()); filter->Update(); mitk::FiberBundle::Pointer newFib = filter->GetOutputFiberBundle(); if (newFib->GetNumFibers()>0) - { - nodes.at(i)->SetVisibility(false); - DataNode::Pointer newNode = DataNode::New(); - newNode->SetData(newFib); - newNode->SetName(nodes.at(i)->GetName()+"_Curvature"); - GetDefaultDataStorage()->Add(newNode, nodes.at(i)); - } + node->SetData(newFib); else QMessageBox::information(NULL, "No output generated:", "The resulting fiber bundle contains no fibers."); -// if (!fib->ApplyCurvatureThreshold(mm, this->m_Controls->m_RemoveCurvedFibersBox->isChecked())) -// QMessageBox::information(NULL, "No output generated:", "The resulting fiber bundle contains no fibers."); } RenderingManager::GetInstance()->RequestUpdateAll(); } void QmitkFiberProcessingView::RemoveDir() { - for (unsigned int i=0; i(m_SelectedFB.at(i)->GetData()); + mitk::FiberBundle::Pointer fib = dynamic_cast(node->GetData()); vnl_vector_fixed dir; dir[0] = m_Controls->m_ExtractDirX->value(); dir[1] = m_Controls->m_ExtractDirY->value(); dir[2] = m_Controls->m_ExtractDirZ->value(); fib->RemoveDir(dir,cos((float)m_Controls->m_ExtractAngle->value()*M_PI/180)); } RenderingManager::GetInstance()->RequestUpdateAll(); } void QmitkFiberProcessingView::RemoveWithMask(bool removeInside) { if (m_MaskImageNode.IsNull()) return; mitk::Image::Pointer mitkMask = dynamic_cast(m_MaskImageNode->GetData()); - for (unsigned int i=0; i(m_SelectedFB.at(i)->GetData()); - QString name(m_SelectedFB.at(i)->GetName().c_str()); + mitk::FiberBundle::Pointer fib = dynamic_cast(node->GetData()); + QString name(node->GetName().c_str()); itkUCharImageType::Pointer mask = itkUCharImageType::New(); mitk::CastToItkImage(mitkMask, mask); mitk::FiberBundle::Pointer newFib = fib->RemoveFibersOutside(mask, removeInside); if (newFib->GetNumFibers()<=0) { QMessageBox::information(NULL, "No output generated:", "The resulting fiber bundle contains no fibers."); continue; } - DataNode::Pointer newNode = DataNode::New(); - newNode->SetData(newFib); - if (removeInside) - name += "_Inside"; - else - name += "_Outside"; - newNode->SetName(name.toStdString()); - GetDefaultDataStorage()->Add(newNode); - m_SelectedFB.at(i)->SetVisibility(false); + node->SetData(newFib); } + RenderingManager::GetInstance()->RequestUpdateAll(); } void QmitkFiberProcessingView::ExtractWithMask(bool onlyEnds, bool invert) { if (m_MaskImageNode.IsNull()) return; mitk::Image::Pointer mitkMask = dynamic_cast(m_MaskImageNode->GetData()); - for (unsigned int i=0; i(m_SelectedFB.at(i)->GetData()); - QString name(m_SelectedFB.at(i)->GetName().c_str()); + mitk::FiberBundle::Pointer fib = dynamic_cast(node->GetData()); + QString name(node->GetName().c_str()); itkUCharImageType::Pointer mask = itkUCharImageType::New(); mitk::CastToItkImage(mitkMask, mask); mitk::FiberBundle::Pointer newFib = fib->ExtractFiberSubset(mask, !onlyEnds, invert, m_Controls->m_BothEnds->isChecked()); if (newFib->GetNumFibers()<=0) { QMessageBox::information(NULL, "No output generated:", "The resulting fiber bundle contains no fibers."); continue; } DataNode::Pointer newNode = DataNode::New(); newNode->SetData(newFib); if (invert) { name += "_not"; if (onlyEnds) name += "-ending-in-mask"; else name += "-passing-mask"; } else { if (onlyEnds) name += "_ending-in-mask"; else name += "_passing-mask"; } newNode->SetName(name.toStdString()); GetDefaultDataStorage()->Add(newNode); - m_SelectedFB.at(i)->SetVisibility(false); + node->SetVisibility(false); } } void QmitkFiberProcessingView::GenerateRoiImage() { if (m_SelectedPF.empty()) return; mitk::BaseGeometry::Pointer geometry; if (!m_SelectedFB.empty()) { mitk::FiberBundle::Pointer fib = dynamic_cast(m_SelectedFB.front()->GetData()); geometry = fib->GetGeometry(); } else if (m_SelectedImage) geometry = m_SelectedImage->GetGeometry(); else return; itk::Vector spacing = geometry->GetSpacing(); spacing /= m_UpsamplingFactor; mitk::Point3D newOrigin = geometry->GetOrigin(); mitk::Geometry3D::BoundsArrayType bounds = geometry->GetBounds(); newOrigin[0] += bounds.GetElement(0); newOrigin[1] += bounds.GetElement(2); newOrigin[2] += bounds.GetElement(4); itk::Matrix direction; itk::ImageRegion<3> imageRegion; for (int i=0; i<3; i++) for (int j=0; j<3; j++) direction[j][i] = geometry->GetMatrixColumn(i)[j]/spacing[j]; imageRegion.SetSize(0, geometry->GetExtent(0)*m_UpsamplingFactor); imageRegion.SetSize(1, geometry->GetExtent(1)*m_UpsamplingFactor); imageRegion.SetSize(2, geometry->GetExtent(2)*m_UpsamplingFactor); m_PlanarFigureImage = itkUCharImageType::New(); m_PlanarFigureImage->SetSpacing( spacing ); // Set the image spacing m_PlanarFigureImage->SetOrigin( newOrigin ); // Set the image origin m_PlanarFigureImage->SetDirection( direction ); // Set the image direction m_PlanarFigureImage->SetRegions( imageRegion ); m_PlanarFigureImage->Allocate(); m_PlanarFigureImage->FillBuffer( 0 ); Image::Pointer tmpImage = Image::New(); tmpImage->InitializeByItk(m_PlanarFigureImage.GetPointer()); tmpImage->SetVolume(m_PlanarFigureImage->GetBufferPointer()); std::string name = m_SelectedPF.at(0)->GetName(); WritePfToImage(m_SelectedPF.at(0), tmpImage); for (unsigned int i=1; iGetName(); WritePfToImage(m_SelectedPF.at(i), tmpImage); } DataNode::Pointer node = DataNode::New(); tmpImage = Image::New(); tmpImage->InitializeByItk(m_PlanarFigureImage.GetPointer()); tmpImage->SetVolume(m_PlanarFigureImage->GetBufferPointer()); node->SetData(tmpImage); node->SetName(name); this->GetDefaultDataStorage()->Add(node); } void QmitkFiberProcessingView::WritePfToImage(mitk::DataNode::Pointer node, mitk::Image* image) { if (dynamic_cast(node->GetData())) { m_PlanarFigure = dynamic_cast(node->GetData()); AccessFixedDimensionByItk_2( image, InternalReorientImagePlane, 3, m_PlanarFigure->GetGeometry(), -1); AccessFixedDimensionByItk_2( m_InternalImage, InternalCalculateMaskFromPlanarFigure, 3, 2, node->GetName() ); } else if (dynamic_cast(node->GetData())) { DataStorage::SetOfObjects::ConstPointer children = GetDataStorage()->GetDerivations(node); - for (int j=0; jsize(); j++) + for (unsigned int i=0; iSize(); i++) { - WritePfToImage(children->ElementAt(j), image); + WritePfToImage(children->at(i), image); } } } template < typename TPixel, unsigned int VImageDimension > void QmitkFiberProcessingView::InternalReorientImagePlane( const itk::Image< TPixel, VImageDimension > *image, mitk::BaseGeometry* planegeo3D, int additionalIndex ) { typedef itk::Image< TPixel, VImageDimension > ImageType; typedef itk::Image< float, VImageDimension > FloatImageType; typedef itk::ResampleImageFilter ResamplerType; typename ResamplerType::Pointer resampler = ResamplerType::New(); mitk::PlaneGeometry* planegeo = dynamic_cast(planegeo3D); float upsamp = m_UpsamplingFactor; float gausssigma = 0.5; // Spacing typename ResamplerType::SpacingType spacing = planegeo->GetSpacing(); spacing[0] = image->GetSpacing()[0] / upsamp; spacing[1] = image->GetSpacing()[1] / upsamp; spacing[2] = image->GetSpacing()[2]; resampler->SetOutputSpacing( spacing ); // Size typename ResamplerType::SizeType size; size[0] = planegeo->GetExtentInMM(0) / spacing[0]; size[1] = planegeo->GetExtentInMM(1) / spacing[1]; size[2] = 1; resampler->SetSize( size ); // Origin typename mitk::Point3D orig = planegeo->GetOrigin(); typename mitk::Point3D corrorig; planegeo3D->WorldToIndex(orig,corrorig); corrorig[0] += 0.5/upsamp; corrorig[1] += 0.5/upsamp; corrorig[2] += 0; planegeo3D->IndexToWorld(corrorig,corrorig); resampler->SetOutputOrigin(corrorig ); // Direction typename ResamplerType::DirectionType direction; typename mitk::AffineTransform3D::MatrixType matrix = planegeo->GetIndexToWorldTransform()->GetMatrix(); for(int c=0; cSetOutputDirection( direction ); // Gaussian interpolation if(gausssigma != 0) { double sigma[3]; for( unsigned int d = 0; d < 3; d++ ) sigma[d] = gausssigma * image->GetSpacing()[d]; double alpha = 2.0; typedef itk::GaussianInterpolateImageFunction GaussianInterpolatorType; typename GaussianInterpolatorType::Pointer interpolator = GaussianInterpolatorType::New(); interpolator->SetInputImage( image ); interpolator->SetParameters( sigma, alpha ); resampler->SetInterpolator( interpolator ); } else { typedef typename itk::LinearInterpolateImageFunction InterpolatorType; typename InterpolatorType::Pointer interpolator = InterpolatorType::New(); interpolator->SetInputImage( image ); resampler->SetInterpolator( interpolator ); } resampler->SetInput( image ); resampler->SetDefaultPixelValue(0); resampler->Update(); if(additionalIndex < 0) { this->m_InternalImage = mitk::Image::New(); this->m_InternalImage->InitializeByItk( resampler->GetOutput() ); this->m_InternalImage->SetVolume( resampler->GetOutput()->GetBufferPointer() ); } } template < typename TPixel, unsigned int VImageDimension > void QmitkFiberProcessingView::InternalCalculateMaskFromPlanarFigure( itk::Image< TPixel, VImageDimension > *image, unsigned int axis, std::string ) { typedef itk::Image< TPixel, VImageDimension > ImageType; typedef itk::CastImageFilter< ImageType, itkUCharImageType > CastFilterType; // Generate mask image as new image with same header as input image and // initialize with "1". itkUCharImageType::Pointer newMaskImage = itkUCharImageType::New(); newMaskImage->SetSpacing( image->GetSpacing() ); // Set the image spacing newMaskImage->SetOrigin( image->GetOrigin() ); // Set the image origin newMaskImage->SetDirection( image->GetDirection() ); // Set the image direction newMaskImage->SetRegions( image->GetLargestPossibleRegion() ); newMaskImage->Allocate(); newMaskImage->FillBuffer( 1 ); // Generate VTK polygon from (closed) PlanarFigure polyline // (The polyline points are shifted by -0.5 in z-direction to make sure // that the extrusion filter, which afterwards elevates all points by +0.5 // in z-direction, creates a 3D object which is cut by the the plane z=0) const PlaneGeometry *planarFigurePlaneGeometry = m_PlanarFigure->GetPlaneGeometry(); const PlanarFigure::PolyLineType planarFigurePolyline = m_PlanarFigure->GetPolyLine( 0 ); const BaseGeometry *imageGeometry3D = m_InternalImage->GetGeometry( 0 ); vtkPolyData *polyline = vtkPolyData::New(); polyline->Allocate( 1, 1 ); // Determine x- and y-dimensions depending on principal axis int i0, i1; switch ( axis ) { case 0: i0 = 1; i1 = 2; break; case 1: i0 = 0; i1 = 2; break; case 2: default: i0 = 0; i1 = 1; break; } // Create VTK polydata object of polyline contour vtkPoints *points = vtkPoints::New(); PlanarFigure::PolyLineType::const_iterator it; unsigned int numberOfPoints = 0; for ( it = planarFigurePolyline.begin(); it != planarFigurePolyline.end(); ++it ) { Point3D point3D; // Convert 2D point back to the local index coordinates of the selected image Point2D point2D = *it; planarFigurePlaneGeometry->WorldToIndex(point2D, point2D); point2D[0] -= 0.5/m_UpsamplingFactor; point2D[1] -= 0.5/m_UpsamplingFactor; planarFigurePlaneGeometry->IndexToWorld(point2D, point2D); planarFigurePlaneGeometry->Map( point2D, point3D ); // Polygons (partially) outside of the image bounds can not be processed further due to a bug in vtkPolyDataToImageStencil if ( !imageGeometry3D->IsInside( point3D ) ) { float bounds[2] = {0,0}; bounds[0] = this->m_InternalImage->GetLargestPossibleRegion().GetSize().GetElement(i0); bounds[1] = this->m_InternalImage->GetLargestPossibleRegion().GetSize().GetElement(i1); imageGeometry3D->WorldToIndex( point3D, point3D ); if (point3D[i0]<0) point3D[i0] = 0.0; else if (point3D[i0]>bounds[0]) point3D[i0] = bounds[0]-0.001; if (point3D[i1]<0) point3D[i1] = 0.0; else if (point3D[i1]>bounds[1]) point3D[i1] = bounds[1]-0.001; points->InsertNextPoint( point3D[i0], point3D[i1], -0.5 ); numberOfPoints++; } else { imageGeometry3D->WorldToIndex( point3D, point3D ); // Add point to polyline array points->InsertNextPoint( point3D[i0], point3D[i1], -0.5 ); numberOfPoints++; } } polyline->SetPoints( points ); points->Delete(); vtkIdType *ptIds = new vtkIdType[numberOfPoints]; for ( vtkIdType i = 0; i < numberOfPoints; ++i ) ptIds[i] = i; polyline->InsertNextCell( VTK_POLY_LINE, numberOfPoints, ptIds ); // Extrude the generated contour polygon vtkLinearExtrusionFilter *extrudeFilter = vtkLinearExtrusionFilter::New(); extrudeFilter->SetInputData( polyline ); extrudeFilter->SetScaleFactor( 1 ); extrudeFilter->SetExtrusionTypeToNormalExtrusion(); extrudeFilter->SetVector( 0.0, 0.0, 1.0 ); // Make a stencil from the extruded polygon vtkPolyDataToImageStencil *polyDataToImageStencil = vtkPolyDataToImageStencil::New(); polyDataToImageStencil->SetInputConnection( extrudeFilter->GetOutputPort() ); // Export from ITK to VTK (to use a VTK filter) typedef itk::VTKImageImport< itkUCharImageType > ImageImportType; typedef itk::VTKImageExport< itkUCharImageType > ImageExportType; typename ImageExportType::Pointer itkExporter = ImageExportType::New(); itkExporter->SetInput( newMaskImage ); vtkImageImport *vtkImporter = vtkImageImport::New(); this->ConnectPipelines( itkExporter, vtkImporter ); vtkImporter->Update(); // Apply the generated image stencil to the input image vtkImageStencil *imageStencilFilter = vtkImageStencil::New(); imageStencilFilter->SetInputConnection( vtkImporter->GetOutputPort() ); imageStencilFilter->SetStencilConnection(polyDataToImageStencil->GetOutputPort() ); imageStencilFilter->ReverseStencilOff(); imageStencilFilter->SetBackgroundValue( 0 ); imageStencilFilter->Update(); // Export from VTK back to ITK vtkImageExport *vtkExporter = vtkImageExport::New(); vtkExporter->SetInputConnection( imageStencilFilter->GetOutputPort() ); vtkExporter->Update(); typename ImageImportType::Pointer itkImporter = ImageImportType::New(); this->ConnectPipelines( vtkExporter, itkImporter ); itkImporter->Update(); // calculate cropping bounding box m_InternalImageMask3D = itkImporter->GetOutput(); m_InternalImageMask3D->SetDirection(image->GetDirection()); itk::ImageRegionConstIterator itmask(m_InternalImageMask3D, m_InternalImageMask3D->GetLargestPossibleRegion()); itk::ImageRegionIterator itimage(image, image->GetLargestPossibleRegion()); itmask.GoToBegin(); itimage.GoToBegin(); typename ImageType::SizeType lowersize = {{itk::NumericTraits::max(),itk::NumericTraits::max(),itk::NumericTraits::max()}}; typename ImageType::SizeType uppersize = {{0,0,0}}; while( !itmask.IsAtEnd() ) { if(itmask.Get() == 0) itimage.Set(0); else { typename ImageType::IndexType index = itimage.GetIndex(); typename ImageType::SizeType signedindex; signedindex[0] = index[0]; signedindex[1] = index[1]; signedindex[2] = index[2]; lowersize[0] = signedindex[0] < lowersize[0] ? signedindex[0] : lowersize[0]; lowersize[1] = signedindex[1] < lowersize[1] ? signedindex[1] : lowersize[1]; lowersize[2] = signedindex[2] < lowersize[2] ? signedindex[2] : lowersize[2]; uppersize[0] = signedindex[0] > uppersize[0] ? signedindex[0] : uppersize[0]; uppersize[1] = signedindex[1] > uppersize[1] ? signedindex[1] : uppersize[1]; uppersize[2] = signedindex[2] > uppersize[2] ? signedindex[2] : uppersize[2]; } ++itmask; ++itimage; } typename ImageType::IndexType index; index[0] = lowersize[0]; index[1] = lowersize[1]; index[2] = lowersize[2]; typename ImageType::SizeType size; size[0] = uppersize[0] - lowersize[0] + 1; size[1] = uppersize[1] - lowersize[1] + 1; size[2] = uppersize[2] - lowersize[2] + 1; itk::ImageRegion<3> cropRegion = itk::ImageRegion<3>(index, size); // crop internal mask typedef itk::RegionOfInterestImageFilter< itkUCharImageType, itkUCharImageType > ROIMaskFilterType; typename ROIMaskFilterType::Pointer roi2 = ROIMaskFilterType::New(); roi2->SetRegionOfInterest(cropRegion); roi2->SetInput(m_InternalImageMask3D); roi2->Update(); m_InternalImageMask3D = roi2->GetOutput(); Image::Pointer tmpImage = Image::New(); tmpImage->InitializeByItk(m_InternalImageMask3D.GetPointer()); tmpImage->SetVolume(m_InternalImageMask3D->GetBufferPointer()); Image::Pointer tmpImage2 = Image::New(); tmpImage2->InitializeByItk(m_PlanarFigureImage.GetPointer()); const BaseGeometry *pfImageGeometry3D = tmpImage2->GetGeometry( 0 ); const BaseGeometry *intImageGeometry3D = tmpImage->GetGeometry( 0 ); typedef itk::ImageRegionIteratorWithIndex IteratorType; IteratorType imageIterator (m_InternalImageMask3D, m_InternalImageMask3D->GetRequestedRegion()); imageIterator.GoToBegin(); while ( !imageIterator.IsAtEnd() ) { unsigned char val = imageIterator.Value(); if (val>0) { itk::Index<3> index = imageIterator.GetIndex(); Point3D point; point[0] = index[0]; point[1] = index[1]; point[2] = index[2]; intImageGeometry3D->IndexToWorld(point, point); pfImageGeometry3D->WorldToIndex(point, point); point[i0] += 0.5; point[i1] += 0.5; index[0] = point[0]; index[1] = point[1]; index[2] = point[2]; if (pfImageGeometry3D->IsIndexInside(index)) m_PlanarFigureImage->SetPixel(index, 1); } ++imageIterator; } // Clean up VTK objects polyline->Delete(); extrudeFilter->Delete(); polyDataToImageStencil->Delete(); vtkImporter->Delete(); imageStencilFilter->Delete(); //vtkExporter->Delete(); // TODO: crashes when outcommented; memory leak?? delete[] ptIds; } void QmitkFiberProcessingView::StdMultiWidgetAvailable (QmitkStdMultiWidget &stdMultiWidget) { m_MultiWidget = &stdMultiWidget; } void QmitkFiberProcessingView::StdMultiWidgetNotAvailable() { m_MultiWidget = NULL; } void QmitkFiberProcessingView::UpdateGui() { m_Controls->m_FibLabel->setText("mandatory"); m_Controls->m_PfLabel->setText("needed for extraction"); m_Controls->m_InputData->setTitle("Please Select Input Data"); m_Controls->m_RemoveButton->setEnabled(false); m_Controls->m_PlanarFigureButtonsFrame->setEnabled(false); m_Controls->PFCompoANDButton->setEnabled(false); m_Controls->PFCompoORButton->setEnabled(false); m_Controls->PFCompoNOTButton->setEnabled(false); m_Controls->m_GenerateRoiImage->setEnabled(false); m_Controls->m_ExtractFibersButton->setEnabled(false); m_Controls->m_ModifyButton->setEnabled(false); + m_Controls->m_CopyBundle->setEnabled(false); m_Controls->m_JoinBundles->setEnabled(false); m_Controls->m_SubstractBundles->setEnabled(false); // disable alle frames m_Controls->m_BundleWeightFrame->setVisible(false); m_Controls->m_ExtactionFramePF->setVisible(false); m_Controls->m_RemoveDirectionFrame->setVisible(false); m_Controls->m_RemoveLengthFrame->setVisible(false); m_Controls->m_RemoveCurvatureFrame->setVisible(false); m_Controls->m_SmoothFibersFrame->setVisible(false); m_Controls->m_CompressFibersFrame->setVisible(false); m_Controls->m_ColorFibersFrame->setVisible(false); m_Controls->m_MirrorFibersFrame->setVisible(false); m_Controls->m_MaskExtractionFrame->setVisible(false); bool pfSelected = !m_SelectedPF.empty(); bool fibSelected = !m_SelectedFB.empty(); bool multipleFibsSelected = (m_SelectedFB.size()>1); bool maskSelected = m_MaskImageNode.IsNotNull(); bool imageSelected = m_SelectedImage.IsNotNull(); // toggle visibility of elements according to selected method switch ( m_Controls->m_ExtractionMethodBox->currentIndex() ) { case 0: m_Controls->m_ExtactionFramePF->setVisible(true); break; case 1: m_Controls->m_MaskExtractionFrame->setVisible(true); break; } switch ( m_Controls->m_RemovalMethodBox->currentIndex() ) { case 0: m_Controls->m_RemoveDirectionFrame->setVisible(true); if ( fibSelected ) m_Controls->m_RemoveButton->setEnabled(true); break; case 1: m_Controls->m_RemoveLengthFrame->setVisible(true); if ( fibSelected ) m_Controls->m_RemoveButton->setEnabled(true); break; case 2: m_Controls->m_RemoveCurvatureFrame->setVisible(true); if ( fibSelected ) m_Controls->m_RemoveButton->setEnabled(true); break; case 3: break; case 4: break; } switch ( m_Controls->m_ModificationMethodBox->currentIndex() ) { case 0: m_Controls->m_SmoothFibersFrame->setVisible(true); break; case 1: m_Controls->m_CompressFibersFrame->setVisible(true); break; case 2: m_Controls->m_ColorFibersFrame->setVisible(true); break; case 3: m_Controls->m_MirrorFibersFrame->setVisible(true); if (m_SelectedSurfaces.size()>0) m_Controls->m_ModifyButton->setEnabled(true); break; case 4: m_Controls->m_BundleWeightFrame->setVisible(true); } // are fiber bundles selected? if ( fibSelected ) { + m_Controls->m_CopyBundle->setEnabled(true); m_Controls->m_ModifyButton->setEnabled(true); m_Controls->m_PlanarFigureButtonsFrame->setEnabled(true); m_Controls->m_FibLabel->setText(QString(m_SelectedFB.at(0)->GetName().c_str())); // one bundle and one planar figure needed to extract fibers if (pfSelected && m_Controls->m_ExtractionMethodBox->currentIndex()==0) { m_Controls->m_InputData->setTitle("Input Data"); m_Controls->m_PfLabel->setText(QString(m_SelectedPF.at(0)->GetName().c_str())); m_Controls->m_ExtractFibersButton->setEnabled(true); } // more than two bundles needed to join/subtract if (multipleFibsSelected) { m_Controls->m_FibLabel->setText("multiple bundles selected"); m_Controls->m_JoinBundles->setEnabled(true); m_Controls->m_SubstractBundles->setEnabled(true); } if (maskSelected && m_Controls->m_ExtractionMethodBox->currentIndex()==1) { m_Controls->m_InputData->setTitle("Input Data"); m_Controls->m_PfLabel->setText(QString(m_MaskImageNode->GetName().c_str())); m_Controls->m_RemoveButton->setEnabled(true); m_Controls->m_ExtractFibersButton->setEnabled(true); } } // are planar figures selected? if (pfSelected) { if ( fibSelected || m_SelectedImage.IsNotNull()) m_Controls->m_GenerateRoiImage->setEnabled(true); if (m_SelectedPF.size() > 1) { m_Controls->PFCompoANDButton->setEnabled(true); m_Controls->PFCompoORButton->setEnabled(true); } else m_Controls->PFCompoNOTButton->setEnabled(true); } // is image selected if (imageSelected || maskSelected) { m_Controls->m_PlanarFigureButtonsFrame->setEnabled(true); } } void QmitkFiberProcessingView::NodeRemoved(const mitk::DataNode* node) { std::vector nodes; OnSelectionChanged(nodes); } void QmitkFiberProcessingView::NodeAdded(const mitk::DataNode* node) { std::vector nodes; OnSelectionChanged(nodes); } void QmitkFiberProcessingView::OnSelectionChanged( std::vector nodes ) { //reset existing Vectors containing FiberBundles and PlanarFigures from a previous selection m_SelectedFB.clear(); m_SelectedPF.clear(); m_SelectedSurfaces.clear(); m_SelectedImage = NULL; m_MaskImageNode = NULL; for( std::vector::iterator it = nodes.begin(); it != nodes.end(); ++it ) { mitk::DataNode::Pointer node = *it; if ( dynamic_cast(node->GetData()) ) m_SelectedFB.push_back(node); else if (dynamic_cast(node->GetData()) || dynamic_cast(node->GetData()) || dynamic_cast(node->GetData())) m_SelectedPF.push_back(node); else if (dynamic_cast(node->GetData())) { m_SelectedImage = dynamic_cast(node->GetData()); bool isBinary = false; node->GetPropertyValue("binary", isBinary); if (isBinary) m_MaskImageNode = node; } else if (dynamic_cast(node->GetData())) m_SelectedSurfaces.push_back(dynamic_cast(node->GetData())); } if (m_SelectedFB.empty() && m_SelectedSurfaces.empty()) { int maxLayer = 0; itk::VectorContainer::ConstPointer nodes = this->GetDefaultDataStorage()->GetAll(); for (unsigned int i=0; iSize(); i++) if (dynamic_cast(nodes->at(i)->GetData())) { mitk::DataStorage::SetOfObjects::ConstPointer sources = GetDataStorage()->GetSources(nodes->at(i)); if (sources->Size()>0) continue; int layer = 0; nodes->at(i)->GetPropertyValue("layer", layer); if (layer>=maxLayer) { maxLayer = layer; m_SelectedFB.clear(); m_SelectedFB.push_back(nodes->at(i)); } } } if (m_SelectedPF.empty()) { int maxLayer = 0; itk::VectorContainer::ConstPointer nodes = this->GetDefaultDataStorage()->GetAll(); for (unsigned int i=0; iSize(); i++) if (dynamic_cast(nodes->at(i)->GetData()) || dynamic_cast(nodes->at(i)->GetData()) || dynamic_cast(nodes->at(i)->GetData())) { mitk::DataStorage::SetOfObjects::ConstPointer sources = GetDataStorage()->GetSources(nodes->at(i)); if (sources->Size()>0) continue; int layer = 0; nodes->at(i)->GetPropertyValue("layer", layer); if (layer>=maxLayer) { maxLayer = layer; m_SelectedPF.clear(); m_SelectedPF.push_back(nodes->at(i)); } } } UpdateGui(); } void QmitkFiberProcessingView::OnDrawPolygon() { mitk::PlanarPolygon::Pointer figure = mitk::PlanarPolygon::New(); figure->ClosedOn(); this->AddFigureToDataStorage(figure, QString("Polygon%1").arg(++m_PolygonCounter)); } void QmitkFiberProcessingView::OnDrawCircle() { mitk::PlanarCircle::Pointer figure = mitk::PlanarCircle::New(); this->AddFigureToDataStorage(figure, QString("Circle%1").arg(++m_CircleCounter)); } void QmitkFiberProcessingView::Activated() { } void QmitkFiberProcessingView::AddFigureToDataStorage(mitk::PlanarFigure* figure, const QString& name, const char *, mitk::BaseProperty* ) { // initialize figure's geometry with empty geometry mitk::PlaneGeometry::Pointer emptygeometry = mitk::PlaneGeometry::New(); figure->SetPlaneGeometry( emptygeometry ); //set desired data to DataNode where Planarfigure is stored mitk::DataNode::Pointer newNode = mitk::DataNode::New(); newNode->SetName(name.toStdString()); newNode->SetData(figure); newNode->SetBoolProperty("planarfigure.3drendering", true); newNode->SetBoolProperty("planarfigure.3drendering.fill", true); mitk::PlanarFigureInteractor::Pointer figureInteractor = dynamic_cast(newNode->GetDataInteractor().GetPointer()); if(figureInteractor.IsNull()) { figureInteractor = mitk::PlanarFigureInteractor::New(); us::Module* planarFigureModule = us::ModuleRegistry::GetModule( "MitkPlanarFigure" ); figureInteractor->LoadStateMachine("PlanarFigureInteraction.xml", planarFigureModule ); figureInteractor->SetEventConfig( "PlanarFigureConfig.xml", planarFigureModule ); figureInteractor->SetDataNode(newNode); } // figure drawn on the topmost layer / image GetDataStorage()->Add(newNode ); for(unsigned int i = 0; i < m_SelectedPF.size(); i++) m_SelectedPF[i]->SetSelected(false); newNode->SetSelected(true); m_SelectedPF.clear(); m_SelectedPF.push_back(newNode); UpdateGui(); } void QmitkFiberProcessingView::ExtractWithPlanarFigure() { if ( m_SelectedFB.empty() || m_SelectedPF.empty() ){ QMessageBox::information( NULL, "Warning", "No fibe bundle selected!"); return; } std::vector fiberBundles = m_SelectedFB; mitk::DataNode::Pointer planarFigure = m_SelectedPF.at(0); for (unsigned int i=0; i(fiberBundles.at(i)->GetData()); mitk::FiberBundle::Pointer extFB = fib->ExtractFiberSubset(planarFigure, GetDataStorage()); if (extFB->GetNumFibers()<=0) { QMessageBox::information(NULL, "No output generated:", "The resulting fiber bundle contains no fibers."); continue; } mitk::DataNode::Pointer node; node = mitk::DataNode::New(); node->SetData(extFB); QString name(fiberBundles.at(i)->GetName().c_str()); name += "*"; //name += planarFigure->GetName().c_str(); node->SetName(name.toStdString()); fiberBundles.at(i)->SetVisibility(false); GetDataStorage()->Add(node); } } void QmitkFiberProcessingView::GenerateAndComposite() { mitk::PlanarFigureComposite::Pointer PFCAnd = mitk::PlanarFigureComposite::New(); PFCAnd->setOperationType(mitk::PlanarFigureComposite::AND); mitk::DataNode::Pointer newPFCNode; newPFCNode = mitk::DataNode::New(); newPFCNode->SetName("AND"); newPFCNode->SetData(PFCAnd); AddCompositeToDatastorage(newPFCNode, m_SelectedPF); m_SelectedPF.clear(); m_SelectedPF.push_back(newPFCNode); UpdateGui(); } void QmitkFiberProcessingView::GenerateOrComposite() { mitk::PlanarFigureComposite::Pointer PFCOr = mitk::PlanarFigureComposite::New(); PFCOr->setOperationType(mitk::PlanarFigureComposite::OR); mitk::DataNode::Pointer newPFCNode; newPFCNode = mitk::DataNode::New(); newPFCNode->SetName("OR"); newPFCNode->SetData(PFCOr); AddCompositeToDatastorage(newPFCNode, m_SelectedPF); m_SelectedPF.clear(); m_SelectedPF.push_back(newPFCNode); UpdateGui(); } void QmitkFiberProcessingView::GenerateNotComposite() { mitk::PlanarFigureComposite::Pointer PFCNot = mitk::PlanarFigureComposite::New(); PFCNot->setOperationType(mitk::PlanarFigureComposite::NOT); mitk::DataNode::Pointer newPFCNode; newPFCNode = mitk::DataNode::New(); newPFCNode->SetName("NOT"); newPFCNode->SetData(PFCNot); AddCompositeToDatastorage(newPFCNode, m_SelectedPF); m_SelectedPF.clear(); m_SelectedPF.push_back(newPFCNode); UpdateGui(); } void QmitkFiberProcessingView::AddCompositeToDatastorage(mitk::DataNode::Pointer pfc, std::vector children, mitk::DataNode::Pointer parentNode ) { pfc->SetSelected(true); if (parentNode.IsNotNull()) GetDataStorage()->Add(pfc, parentNode); else GetDataStorage()->Add(pfc); - for (int i=0; i(children.at(i)->GetData())) + if (dynamic_cast(child->GetData())) { mitk::DataNode::Pointer newChild; newChild = mitk::DataNode::New(); - newChild->SetData(dynamic_cast(children.at(i)->GetData())); - newChild->SetName( children.at(i)->GetName() ); + newChild->SetData(dynamic_cast(child->GetData())); + newChild->SetName( child->GetName() ); + newChild->SetBoolProperty("planarfigure.3drendering", true); + newChild->SetBoolProperty("planarfigure.3drendering.fill", true); GetDataStorage()->Add(newChild, pfc); - GetDataStorage()->Remove(children.at(i)); + GetDataStorage()->Remove(child); } - else if (dynamic_cast(children.at(i)->GetData())) + else if (dynamic_cast(child->GetData())) { mitk::DataNode::Pointer newChild; newChild = mitk::DataNode::New(); - newChild->SetData(dynamic_cast(children.at(i)->GetData())); - newChild->SetName( children.at(i)->GetName() ); + newChild->SetData(dynamic_cast(child->GetData())); + newChild->SetName( child->GetName() ); std::vector< mitk::DataNode::Pointer > grandChildVector; - mitk::DataStorage::SetOfObjects::ConstPointer grandchildren = GetDataStorage()->GetDerivations(children.at(i)); + mitk::DataStorage::SetOfObjects::ConstPointer grandchildren = GetDataStorage()->GetDerivations(child); for( mitk::DataStorage::SetOfObjects::const_iterator it = grandchildren->begin(); it != grandchildren->end(); ++it ) grandChildVector.push_back(*it); AddCompositeToDatastorage(newChild, grandChildVector, pfc); - GetDataStorage()->Remove(children.at(i)); + GetDataStorage()->Remove(child); } } + UpdateGui(); +} + +void QmitkFiberProcessingView::CopyBundles() +{ + if ( m_SelectedFB.empty() ){ + QMessageBox::information( NULL, "Warning", "Select at least one fiber bundle!"); + MITK_WARN("QmitkFiberProcessingView") << "Select at least one fiber bundle!"; + return; + } + + for (auto node : m_SelectedFB) + { + mitk::FiberBundle::Pointer fib = dynamic_cast(node->GetData()); + mitk::FiberBundle::Pointer newFib = fib->GetDeepCopy(); + + node->SetVisibility(false); + QString name(""); + name += QString(m_SelectedFB.at(0)->GetName().c_str()); + name += "_copy"; + + mitk::DataNode::Pointer fbNode = mitk::DataNode::New(); + fbNode->SetData(newFib); + fbNode->SetName(name.toStdString()); + fbNode->SetVisibility(true); + GetDataStorage()->Add(fbNode); + } + UpdateGui(); } void QmitkFiberProcessingView::JoinBundles() { if ( m_SelectedFB.size()<2 ){ QMessageBox::information( NULL, "Warning", "Select at least two fiber bundles!"); MITK_WARN("QmitkFiberProcessingView") << "Select at least two fiber bundles!"; return; } mitk::FiberBundle::Pointer newBundle = dynamic_cast(m_SelectedFB.at(0)->GetData()); m_SelectedFB.at(0)->SetVisibility(false); QString name(""); name += QString(m_SelectedFB.at(0)->GetName().c_str()); for (unsigned int i=1; iAddBundle(dynamic_cast(m_SelectedFB.at(i)->GetData())); name += "+"+QString(m_SelectedFB.at(i)->GetName().c_str()); m_SelectedFB.at(i)->SetVisibility(false); } mitk::DataNode::Pointer fbNode = mitk::DataNode::New(); fbNode->SetData(newBundle); fbNode->SetName(name.toStdString()); fbNode->SetVisibility(true); GetDataStorage()->Add(fbNode); + UpdateGui(); } void QmitkFiberProcessingView::SubstractBundles() { if ( m_SelectedFB.size()<2 ){ QMessageBox::information( NULL, "Warning", "Select at least two fiber bundles!"); MITK_WARN("QmitkFiberProcessingView") << "Select at least two fiber bundles!"; return; } mitk::FiberBundle::Pointer newBundle = dynamic_cast(m_SelectedFB.at(0)->GetData()); m_SelectedFB.at(0)->SetVisibility(false); QString name(""); name += QString(m_SelectedFB.at(0)->GetName().c_str()); for (unsigned int i=1; iSubtractBundle(dynamic_cast(m_SelectedFB.at(i)->GetData())); if (newBundle.IsNull()) break; name += "-"+QString(m_SelectedFB.at(i)->GetName().c_str()); m_SelectedFB.at(i)->SetVisibility(false); } if (newBundle.IsNull()) { QMessageBox::information(NULL, "No output generated:", "The resulting fiber bundle contains no fibers. Did you select the fiber bundles in the correct order? X-Y is not equal to Y-X!"); return; } mitk::DataNode::Pointer fbNode = mitk::DataNode::New(); fbNode->SetData(newBundle); fbNode->SetName(name.toStdString()); fbNode->SetVisibility(true); GetDataStorage()->Add(fbNode); + UpdateGui(); } void QmitkFiberProcessingView::ResampleSelectedBundles() { double factor = this->m_Controls->m_SmoothFibersBox->value(); - for (unsigned int i=0; i(m_SelectedFB.at(i)->GetData()); + mitk::FiberBundle::Pointer fib = dynamic_cast(node->GetData()); fib->ResampleSpline(factor); } RenderingManager::GetInstance()->RequestUpdateAll(); } void QmitkFiberProcessingView::CompressSelectedBundles() { double factor = this->m_Controls->m_ErrorThresholdBox->value(); - for (unsigned int i=0; i(m_SelectedFB.at(i)->GetData()); + mitk::FiberBundle::Pointer fib = dynamic_cast(node->GetData()); fib->Compress(factor); } RenderingManager::GetInstance()->RequestUpdateAll(); } void QmitkFiberProcessingView::DoImageColorCoding() { if (m_Controls->m_ColorMapBox->GetSelectedNode().IsNull()) { QMessageBox::information(NULL, "Bundle coloring aborted:", "No image providing the scalar values for coloring the selected bundle available."); return; } - for(unsigned int i=0; i(m_SelectedFB.at(i)->GetData()); + mitk::FiberBundle::Pointer fib = dynamic_cast(node->GetData()); fib->ColorFibersByScalarMap(dynamic_cast(m_Controls->m_ColorMapBox->GetSelectedNode()->GetData()), m_Controls->m_FiberOpacityBox->isChecked()); } - - if(m_MultiWidget) - m_MultiWidget->RequestUpdate(); + RenderingManager::GetInstance()->RequestUpdateAll(); } void QmitkFiberProcessingView::DoCurvatureColorCoding() { - for(unsigned int i=0; i(m_SelectedFB.at(i)->GetData()); + mitk::FiberBundle::Pointer fib = dynamic_cast(node->GetData()); fib->ColorFibersByCurvature(); } - - if(m_MultiWidget) - m_MultiWidget->RequestUpdate(); + RenderingManager::GetInstance()->RequestUpdateAll(); } void QmitkFiberProcessingView::MirrorFibers() { unsigned int axis = this->m_Controls->m_MirrorFibersBox->currentIndex(); - for (int i=0; i(m_SelectedFB.at(i)->GetData()); + mitk::FiberBundle::Pointer fib = dynamic_cast(node->GetData()); if (m_SelectedImage.IsNotNull()) fib->SetReferenceGeometry(m_SelectedImage->GetGeometry()); fib->MirrorFibers(axis); } - if (m_SelectedSurfaces.size()>0) + + for (auto surf : m_SelectedSurfaces) { - for (int i=0; i poly = surf->GetVtkPolyData(); - vtkSmartPointer vtkNewPoints = vtkSmartPointer::New(); + vtkSmartPointer poly = surf->GetVtkPolyData(); + vtkSmartPointer vtkNewPoints = vtkSmartPointer::New(); - for (int i=0; iGetNumberOfPoints(); i++) - { - double* point = poly->GetPoint(i); - point[axis] *= -1; - vtkNewPoints->InsertNextPoint(point); - } - poly->SetPoints(vtkNewPoints); - surf->CalculateBoundingBox(); + for (int i=0; iGetNumberOfPoints(); i++) + { + double* point = poly->GetPoint(i); + point[axis] *= -1; + vtkNewPoints->InsertNextPoint(point); } + poly->SetPoints(vtkNewPoints); + surf->CalculateBoundingBox(); } RenderingManager::GetInstance()->RequestUpdateAll(); } diff --git a/Plugins/org.mitk.gui.qt.diffusionimaging/src/internal/QmitkFiberProcessingView.h b/Plugins/org.mitk.gui.qt.diffusionimaging/src/internal/QmitkFiberProcessingView.h index 7509b7c1e1..269229af9f 100644 --- a/Plugins/org.mitk.gui.qt.diffusionimaging/src/internal/QmitkFiberProcessingView.h +++ b/Plugins/org.mitk.gui.qt.diffusionimaging/src/internal/QmitkFiberProcessingView.h @@ -1,190 +1,191 @@ /*=================================================================== The Medical Imaging Interaction Toolkit (MITK) Copyright (c) German Cancer Research Center, Division of Medical and Biological Informatics. All rights reserved. This software is distributed WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See LICENSE.txt or http://www.mitk.org for details. ===================================================================*/ #ifndef QmitkFiberProcessingView_h #define QmitkFiberProcessingView_h #include #include "ui_QmitkFiberProcessingViewControls.h" #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include /*! \brief View to process fiber bundles. Supplies methods to extract fibers from the bundle, join and subtract bundles and much more. \sa QmitkFunctionality \ingroup Functionalities */ class QmitkFiberProcessingView : public QmitkFunctionality { // this is needed for all Qt objects that should have a Qt meta-object // (everything that derives from QObject and wants to have signal/slots) Q_OBJECT public: typedef itk::Image< unsigned char, 3 > itkUCharImageType; static const std::string VIEW_ID; QmitkFiberProcessingView(); virtual ~QmitkFiberProcessingView(); virtual void CreateQtPartControl(QWidget *parent) override; virtual void StdMultiWidgetAvailable (QmitkStdMultiWidget &stdMultiWidget) override; virtual void StdMultiWidgetNotAvailable() override; virtual void Activated() override; protected slots: void OnDrawCircle(); ///< add circle interactors etc. void OnDrawPolygon(); ///< add circle interactors etc. void GenerateAndComposite(); void GenerateOrComposite(); void GenerateNotComposite(); + void CopyBundles(); ///< add copies of selected bundles to data storage void JoinBundles(); ///< merge selected fiber bundles void SubstractBundles(); ///< subtract bundle A from bundle B. Not commutative! Defined by order of selection. void GenerateRoiImage(); ///< generate binary image of selected planar figures. void Remove(); void Extract(); void Modify(); void UpdateGui(); ///< update button activity etc. dpending on current datamanager selection virtual void AddFigureToDataStorage(mitk::PlanarFigure* figure, const QString& name, const char *propertyKey = NULL, mitk::BaseProperty *property = NULL ); protected: void MirrorFibers(); ///< mirror bundle on the specified plane void ResampleSelectedBundles(); ///< smooth fiber bundle using the specified number of sampling points per cm. void DoImageColorCoding(); ///< color fibers by selected scalar image void DoCurvatureColorCoding(); ///< color fibers by curvature void CompressSelectedBundles(); ///< remove points below certain error threshold void WeightFibers(); void RemoveWithMask(bool removeInside); void RemoveDir(); void ApplyCurvatureThreshold(); ///< remove/split fibers with a too high curvature threshold void PruneBundle(); ///< remove too short/too long fibers void ExtractWithMask(bool onlyEnds, bool invert); void ExtractWithPlanarFigure(); /// \brief called by QmitkFunctionality when DataManager's selection has changed virtual void OnSelectionChanged( std::vector nodes ) override; Ui::QmitkFiberProcessingViewControls* m_Controls; QmitkStdMultiWidget* m_MultiWidget; /** Connection from VTK to ITK */ template void ConnectPipelines(VTK_Exporter* exporter, ITK_Importer importer) { importer->SetUpdateInformationCallback(exporter->GetUpdateInformationCallback()); importer->SetPipelineModifiedCallback(exporter->GetPipelineModifiedCallback()); importer->SetWholeExtentCallback(exporter->GetWholeExtentCallback()); importer->SetSpacingCallback(exporter->GetSpacingCallback()); importer->SetOriginCallback(exporter->GetOriginCallback()); importer->SetScalarTypeCallback(exporter->GetScalarTypeCallback()); importer->SetNumberOfComponentsCallback(exporter->GetNumberOfComponentsCallback()); importer->SetPropagateUpdateExtentCallback(exporter->GetPropagateUpdateExtentCallback()); importer->SetUpdateDataCallback(exporter->GetUpdateDataCallback()); importer->SetDataExtentCallback(exporter->GetDataExtentCallback()); importer->SetBufferPointerCallback(exporter->GetBufferPointerCallback()); importer->SetCallbackUserData(exporter->GetCallbackUserData()); } template void ConnectPipelines(ITK_Exporter exporter, VTK_Importer* importer) { importer->SetUpdateInformationCallback(exporter->GetUpdateInformationCallback()); importer->SetPipelineModifiedCallback(exporter->GetPipelineModifiedCallback()); importer->SetWholeExtentCallback(exporter->GetWholeExtentCallback()); importer->SetSpacingCallback(exporter->GetSpacingCallback()); importer->SetOriginCallback(exporter->GetOriginCallback()); importer->SetScalarTypeCallback(exporter->GetScalarTypeCallback()); importer->SetNumberOfComponentsCallback(exporter->GetNumberOfComponentsCallback()); importer->SetPropagateUpdateExtentCallback(exporter->GetPropagateUpdateExtentCallback()); importer->SetUpdateDataCallback(exporter->GetUpdateDataCallback()); importer->SetDataExtentCallback(exporter->GetDataExtentCallback()); importer->SetBufferPointerCallback(exporter->GetBufferPointerCallback()); importer->SetCallbackUserData(exporter->GetCallbackUserData()); } template < typename TPixel, unsigned int VImageDimension > void InternalCalculateMaskFromPlanarFigure( itk::Image< TPixel, VImageDimension > *image, unsigned int axis, std::string nodeName ); template < typename TPixel, unsigned int VImageDimension > void InternalReorientImagePlane( const itk::Image< TPixel, VImageDimension > *image, mitk::BaseGeometry* planegeo3D, int additionalIndex ); int m_CircleCounter; ///< used for data node naming int m_PolygonCounter; ///< used for data node naming std::vector m_SelectedFB; ///< selected fiber bundle nodes std::vector m_SelectedPF; ///< selected planar figure nodes std::vector m_SelectedSurfaces; mitk::Image::Pointer m_SelectedImage; mitk::Image::Pointer m_InternalImage; mitk::PlanarFigure::Pointer m_PlanarFigure; itkUCharImageType::Pointer m_InternalImageMask3D; itkUCharImageType::Pointer m_PlanarFigureImage; float m_UpsamplingFactor; ///< upsampling factor for all image generations mitk::DataNode::Pointer m_MaskImageNode; void AddCompositeToDatastorage(mitk::DataNode::Pointer pfc, std::vector children, mitk::DataNode::Pointer parentNode=NULL); void debugPFComposition(mitk::PlanarFigureComposite::Pointer , int ); void WritePfToImage(mitk::DataNode::Pointer node, mitk::Image* image); mitk::DataNode::Pointer GenerateTractDensityImage(mitk::FiberBundle::Pointer fib, bool binary, bool absolute); mitk::DataNode::Pointer GenerateColorHeatmap(mitk::FiberBundle::Pointer fib); mitk::DataNode::Pointer GenerateFiberEndingsImage(mitk::FiberBundle::Pointer fib); mitk::DataNode::Pointer GenerateFiberEndingsPointSet(mitk::FiberBundle::Pointer fib); void NodeAdded( const mitk::DataNode* node ) override; void NodeRemoved(const mitk::DataNode* node) override; }; #endif // _QMITKFIBERTRACKINGVIEW_H_INCLUDED diff --git a/Plugins/org.mitk.gui.qt.diffusionimaging/src/internal/QmitkFiberProcessingViewControls.ui b/Plugins/org.mitk.gui.qt.diffusionimaging/src/internal/QmitkFiberProcessingViewControls.ui index 4de4c06ede..8ca5d39b84 100644 --- a/Plugins/org.mitk.gui.qt.diffusionimaging/src/internal/QmitkFiberProcessingViewControls.ui +++ b/Plugins/org.mitk.gui.qt.diffusionimaging/src/internal/QmitkFiberProcessingViewControls.ui @@ -1,1366 +1,1399 @@ QmitkFiberProcessingViewControls 0 0 386 540 Form 0 0 0 355 330 Fiber Extraction Extract a fiber subset from the selected fiber bundle using manually placed planar figures as waypoints or binary regions of interest. false 0 0 200 16777215 11 Extract fibers passing through selected ROI or composite ROI. Select ROI and fiber bundle to execute. Extract Qt::Vertical 20 40 QFrame::NoFrame QFrame::Raised 9 9 9 9 0 false 0 0 16777215 16777215 11 Generate a binary image containing all selected ROIs. Select at least one ROI (planar figure) and a reference fiber bundle or image. Generate ROI Image 0 0 200 0 16777215 60 QFrame::NoFrame QFrame::Raised 0 0 0 0 false 60 16777215 Create OR composition with selected ROIs. OR Qt::Horizontal 40 20 false 60 16777215 Create NOT composition from selected ROI. NOT false 60 16777215 Create AND composition with selected ROIs. AND 0 0 200 0 16777215 60 QFrame::NoFrame QFrame::Raised 0 0 0 0 30 30 Draw circular ROI. Select reference fiber bundle to execute. :/QmitkDiffusionImaging/circle.png:/QmitkDiffusionImaging/circle.png 32 32 false true Qt::Horizontal 40 20 30 30 Draw polygonal ROI. Select reference fiber bundle to execute. :/QmitkDiffusionImaging/polygon.png:/QmitkDiffusionImaging/polygon.png 32 32 true true 0 0 Extract using planar figures Extract using binary ROI image QFrame::NoFrame QFrame::Raised 0 0 0 0 0 0 Ending in mask Not ending in mask Passing mask Not passing mask Extract fibers: Both ends true 0 0 270 380 Fiber Removal Remove fibers that satisfy certain criteria from the selected bundle. 0 0 Remove fibers in direction Remove fibers by length Remove fibers by curvature Remove fiber parts outside mask Remove fiber parts inside mask QFrame::NoFrame QFrame::Raised 0 0 0 0 Qt::Horizontal 40 20 Minimum fiber length in mm 0 999999999 20 Max. Length: Min. Length: Maximum fiber length in mm 0 999999999 300 QFrame::NoFrame QFrame::Raised 0 0 0 0 0 X: Y: Z: Angle: Angular deviation threshold in degree 1 90.000000000000000 1.000000000000000 5.000000000000000 QFrame::NoFrame QFrame::Raised 0 0 0 0 If unchecked, the fiber exceeding the threshold will be split in two instead of removed. Remove Fiber false QFrame::NoFrame QFrame::Raised 0 0 0 0 0 Max. Angular Deviation: Qt::Horizontal 40 20 Maximum angular deviation in degree 180.000000000000000 0.100000000000000 30.000000000000000 Distance: Distance in mm 1 999.000000000000000 1.000000000000000 5.000000000000000 false 0 0 200 16777215 11 Remove Qt::Vertical 20 40 0 0 - 280 + 355 349 Bundle Modification Modify the selected bundle with operations such as fiber resampling, FA coloring, etc. QFrame::NoFrame QFrame::Raised 0 0 0 0 0 Error threshold in mm: 999999999.000000000000000 0.100000000000000 0.100000000000000 QFrame::NoFrame QFrame::Raised 0 0 0 0 0 Sagittal Coronal Axial Select direction: QFrame::NoFrame QFrame::Raised 0 0 0 0 0 Scalar map: If checked, the image values are not only used to color the fibers but are also used as opaxity values. Values as opacity true 0 0 Smooth fibers Compress fibers Color fibers by scalar map (e.g. FA) Mirror fibers Weight Bundle Color fibers by curvature QFrame::NoFrame QFrame::Raised 0 0 0 0 0 0.010000000000000 999999999.000000000000000 + + 0.100000000000000 + 1.000000000000000 Point distance in mm: Qt::Vertical 20 40 false 0 0 200 16777215 11 Execute QFrame::NoFrame QFrame::Raised 0 0 0 0 0 Weight: 7 999999999.000000000000000 0.100000000000000 1.000000000000000 0 0 - 360 - 61 + 368 + 152 - Binary Bundle Operations + Bundle Operations - Join or subtract bundles. + Join, subtract or copy bundles. false 0 0 200 16777215 11 Returns all fibers contained in bundle X that are not contained in bundle Y (not commutative!). Select at least two fiber bundles to execute. Substract + + + + Qt::Vertical + + + + 20 + 40 + + + + false 0 0 200 16777215 11 Merge selected fiber bundles. Select at least two fiber bundles to execute. Join - - - Qt::Vertical + + + false - + + + 0 + 0 + + + - 20 - 40 + 200 + 16777215 - + + + 11 + + + + Merge selected fiber bundles. Select at least two fiber bundles to execute. + + + Copy + + Please Select Input Data <html><head/><body><p><span style=" color:#ff0000;">mandatory</span></p></body></html> true <html><head/><body><p><span style=" color:#969696;">needed for extraction</span></p></body></html> true Input DTI Fiber Bundle: Binary seed ROI. If not specified, the whole image area is seeded. ROI: Qt::Vertical 20 40 QmitkDataStorageComboBox QComboBox
QmitkDataStorageComboBox.h