diff --git a/Plugins/org.mitk.gui.qt.diffusionimaging.partialvolume/src/internal/QmitkPartialVolumeAnalysisView.cpp b/Plugins/org.mitk.gui.qt.diffusionimaging.partialvolume/src/internal/QmitkPartialVolumeAnalysisView.cpp index c32bba8afe..41876e35d8 100644 --- a/Plugins/org.mitk.gui.qt.diffusionimaging.partialvolume/src/internal/QmitkPartialVolumeAnalysisView.cpp +++ b/Plugins/org.mitk.gui.qt.diffusionimaging.partialvolume/src/internal/QmitkPartialVolumeAnalysisView.cpp @@ -1,2161 +1,2145 @@ /*=================================================================== 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 "QmitkPartialVolumeAnalysisView.h" #include #include #include #include #include #include #include #include #include #include #include #include #include #include "QmitkSliderNavigatorWidget.h" #include #include "mitkNodePredicateDataType.h" #include "mitkNodePredicateOr.h" #include "mitkImageTimeSelector.h" #include "mitkProperties.h" #include "mitkProgressBar.h" #include "mitkImageCast.h" #include "mitkImageToItk.h" #include "mitkITKImageImport.h" #include "mitkDataNodeObject.h" #include "mitkNodePredicateData.h" #include "mitkPlanarFigureInteractor.h" #include "mitkTensorImage.h" #include "mitkPlanarCircle.h" #include "mitkPlanarRectangle.h" #include "mitkPlanarPolygon.h" #include "mitkPartialVolumeAnalysisClusteringCalculator.h" #include "usModuleRegistry.h" #include #include "itkTensorDerivedMeasurementsFilter.h" #include "itkDiffusionTensor3D.h" #include "itkCartesianToPolarVectorImageFilter.h" #include "itkPolarToCartesianVectorImageFilter.h" #include "itkBinaryThresholdImageFilter.h" #include "itkMaskImageFilter.h" #include "itkCastImageFilter.h" #include "itkImageMomentsCalculator.h" #include #include #include #include #include #define _USE_MATH_DEFINES #include #define PVA_PI M_PI const std::string QmitkPartialVolumeAnalysisView::VIEW_ID = "org.mitk.views.partialvolumeanalysisview"; class QmitkRequestStatisticsUpdateEvent : public QEvent { public: enum Type { StatisticsUpdateRequest = QEvent::MaxUser - 1025 }; QmitkRequestStatisticsUpdateEvent() : QEvent( (QEvent::Type) StatisticsUpdateRequest ) {}; }; typedef itk::Image ImageType; typedef itk::Image FloatImageType; typedef itk::Image, 3> VectorImageType; inline bool my_isnan(float x) { volatile float d = x; if(d!=d) return true; if(d==d) return false; return d != d; } QmitkPartialVolumeAnalysisView::QmitkPartialVolumeAnalysisView(QObject * /*parent*/, const char * /*name*/) : QmitkAbstractView(), - m_Controls( nullptr ), - m_TimeStepperAdapter( nullptr ), - m_MeasurementInfoRenderer(0), - m_MeasurementInfoAnnotation(0), - m_SelectedImageNodes( ), - m_SelectedImage( nullptr ), - m_SelectedMaskNode( nullptr ), - m_SelectedImageMask( nullptr ), - m_SelectedPlanarFigureNodes(0), - m_SelectedPlanarFigure( nullptr ), + m_Controls(nullptr), + m_TimeStepperAdapter(nullptr), + m_MeasurementInfoRenderer(nullptr), + m_MeasurementInfoAnnotation(nullptr), m_IsTensorImage(false), - m_FAImage(0), - m_RDImage(0), - m_ADImage(0), - m_MDImage(0), - m_CAImage(0), - // m_DirectionImage(0), - m_DirectionComp1Image(0), - m_DirectionComp2Image(0), - m_AngularErrorImage(0), m_SelectedRenderWindow(nullptr), m_LastRenderWindow(nullptr), - m_ImageObserverTag( -1 ), - m_ImageMaskObserverTag( -1 ), - m_PlanarFigureObserverTag( -1 ), - m_CurrentStatisticsValid( false ), - m_StatisticsUpdatePending( false ), + m_ImageObserverTag(-1), + m_ImageMaskObserverTag(-1), + m_PlanarFigureObserverTag(-1), + m_CurrentStatisticsValid(false), + m_StatisticsUpdatePending(false), m_GaussianSigmaChangedSliding(false), m_NumberBinsSliding(false), m_UpsamplingChangedSliding(false), - m_ClusteringResult(nullptr), m_EllipseCounter(0), m_RectangleCounter(0), m_PolygonCounter(0), m_CurrentFigureNodeInitialized(false), m_QuantifyClass(2), m_IconTexOFF(new QIcon(":/QmitkPartialVolumeAnalysisView/texIntOFFIcon.png")), m_IconTexON(new QIcon(":/QmitkPartialVolumeAnalysisView/texIntONIcon.png")), m_TexIsOn(true), m_Visible(false) { } QmitkPartialVolumeAnalysisView::~QmitkPartialVolumeAnalysisView() { if ( m_SelectedImage.IsNotNull() ) m_SelectedImage->RemoveObserver( m_ImageObserverTag ); if ( m_SelectedImageMask.IsNotNull() ) m_SelectedImageMask->RemoveObserver( m_ImageMaskObserverTag ); if ( m_SelectedPlanarFigure.IsNotNull() ) { m_SelectedPlanarFigure->RemoveObserver( m_PlanarFigureObserverTag ); m_SelectedPlanarFigure->RemoveObserver( m_InitializedObserverTag ); } this->GetDataStorage()->AddNodeEvent -= mitk::MessageDelegate1( this, &QmitkPartialVolumeAnalysisView::NodeAddedInDataStorage ); m_SelectedPlanarFigureNodes->NodeChanged.RemoveListener( mitk::MessageDelegate1( this, &QmitkPartialVolumeAnalysisView::NodeChanged ) ); m_SelectedPlanarFigureNodes->NodeRemoved.RemoveListener( mitk::MessageDelegate1( this, &QmitkPartialVolumeAnalysisView::NodeRemoved ) ); m_SelectedPlanarFigureNodes->PropertyChanged.RemoveListener( mitk::MessageDelegate2( this, &QmitkPartialVolumeAnalysisView::PropertyChanged ) ); m_SelectedImageNodes->NodeChanged.RemoveListener( mitk::MessageDelegate1( this, &QmitkPartialVolumeAnalysisView::NodeChanged ) ); m_SelectedImageNodes->NodeRemoved.RemoveListener( mitk::MessageDelegate1( this, &QmitkPartialVolumeAnalysisView::NodeRemoved ) ); m_SelectedImageNodes->PropertyChanged.RemoveListener( mitk::MessageDelegate2( this, &QmitkPartialVolumeAnalysisView::PropertyChanged ) ); } void QmitkPartialVolumeAnalysisView::CreateQtPartControl(QWidget *parent) { if (m_Controls == nullptr) { m_Controls = new Ui::QmitkPartialVolumeAnalysisViewControls; m_Controls->setupUi(parent); this->CreateConnections(); } SetHistogramVisibility(); m_Controls->m_TextureIntON->setIcon(*m_IconTexON); m_Controls->m_SimilarAnglesFrame->setVisible(false); m_Controls->m_SimilarAnglesLabel->setVisible(false); vtkTextProperty *textProp = vtkTextProperty::New(); textProp->SetColor(1.0, 1.0, 1.0); m_MeasurementInfoAnnotation = vtkCornerAnnotation::New(); m_MeasurementInfoAnnotation->SetMaximumFontSize(12); m_MeasurementInfoAnnotation->SetTextProperty(textProp); m_MeasurementInfoRenderer = vtkRenderer::New(); m_MeasurementInfoRenderer->AddActor(m_MeasurementInfoAnnotation); m_SelectedPlanarFigureNodes = mitk::DataStorageSelection::New(this->GetDataStorage(), false); m_SelectedPlanarFigureNodes->NodeChanged.AddListener( mitk::MessageDelegate1( this, &QmitkPartialVolumeAnalysisView::NodeChanged ) ); m_SelectedPlanarFigureNodes->NodeRemoved.AddListener( mitk::MessageDelegate1( this, &QmitkPartialVolumeAnalysisView::NodeRemoved ) ); m_SelectedPlanarFigureNodes->PropertyChanged.AddListener( mitk::MessageDelegate2( this, &QmitkPartialVolumeAnalysisView::PropertyChanged ) ); m_SelectedImageNodes = mitk::DataStorageSelection::New(this->GetDataStorage(), false); m_SelectedImageNodes->PropertyChanged.AddListener( mitk::MessageDelegate2( this, &QmitkPartialVolumeAnalysisView::PropertyChanged ) ); m_SelectedImageNodes->NodeChanged.AddListener( mitk::MessageDelegate1( this, &QmitkPartialVolumeAnalysisView::NodeChanged ) ); m_SelectedImageNodes->NodeRemoved.AddListener( mitk::MessageDelegate1( this, &QmitkPartialVolumeAnalysisView::NodeRemoved ) ); this->GetDataStorage()->AddNodeEvent.AddListener( mitk::MessageDelegate1( this, &QmitkPartialVolumeAnalysisView::NodeAddedInDataStorage ) ); Select(nullptr,true,true); SetAdvancedVisibility(); } void QmitkPartialVolumeAnalysisView::SetFocus() { m_Controls->m_CircleButton->setFocus(); } void QmitkPartialVolumeAnalysisView::SetHistogramVisibility() { m_Controls->m_HistogramWidget->setVisible(m_Controls->m_DisplayHistogramCheckbox->isChecked()); } void QmitkPartialVolumeAnalysisView::SetAdvancedVisibility() { m_Controls->frame_7->setVisible(m_Controls->m_AdvancedCheckbox->isChecked()); } void QmitkPartialVolumeAnalysisView::CreateConnections() { if ( m_Controls ) { connect( m_Controls->m_DisplayHistogramCheckbox, SIGNAL( clicked() ) , this, SLOT( SetHistogramVisibility() ) ); connect( m_Controls->m_AdvancedCheckbox, SIGNAL( clicked() ) , this, SLOT( SetAdvancedVisibility() ) ); connect( m_Controls->m_NumberBinsSlider, SIGNAL( sliderReleased () ), this, SLOT( NumberBinsReleasedSlider( ) ) ); connect( m_Controls->m_UpsamplingSlider, SIGNAL( sliderReleased( ) ), this, SLOT( UpsamplingReleasedSlider( ) ) ); connect( m_Controls->m_GaussianSigmaSlider, SIGNAL( sliderReleased( ) ), this, SLOT( GaussianSigmaReleasedSlider( ) ) ); connect( m_Controls->m_SimilarAnglesSlider, SIGNAL( sliderReleased( ) ), this, SLOT( SimilarAnglesReleasedSlider( ) ) ); connect( m_Controls->m_NumberBinsSlider, SIGNAL( valueChanged (int) ), this, SLOT( NumberBinsChangedSlider( int ) ) ); connect( m_Controls->m_UpsamplingSlider, SIGNAL( valueChanged( int ) ), this, SLOT( UpsamplingChangedSlider( int ) ) ); connect( m_Controls->m_GaussianSigmaSlider, SIGNAL( valueChanged( int ) ), this, SLOT( GaussianSigmaChangedSlider( int ) ) ); connect( m_Controls->m_SimilarAnglesSlider, SIGNAL( valueChanged( int ) ), this, SLOT( SimilarAnglesChangedSlider(int) ) ); connect( m_Controls->m_OpacitySlider, SIGNAL( valueChanged( int ) ), this, SLOT( OpacityChangedSlider(int) ) ); connect( (QObject*)(m_Controls->m_ButtonCopyHistogramToClipboard), SIGNAL(clicked()),(QObject*) this, SLOT(ToClipBoard())); connect( m_Controls->m_CircleButton, SIGNAL( clicked() ) , this, SLOT( ActionDrawEllipseTriggered() ) ); connect( m_Controls->m_RectangleButton, SIGNAL( clicked() ) , this, SLOT( ActionDrawRectangleTriggered() ) ); connect( m_Controls->m_PolygonButton, SIGNAL( clicked() ) , this, SLOT( ActionDrawPolygonTriggered() ) ); connect( m_Controls->m_GreenRadio, SIGNAL( clicked(bool) ) , this, SLOT( GreenRadio(bool) ) ); connect( m_Controls->m_PartialVolumeRadio, SIGNAL( clicked(bool) ) , this, SLOT( PartialVolumeRadio(bool) ) ); connect( m_Controls->m_BlueRadio, SIGNAL( clicked(bool) ) , this, SLOT( BlueRadio(bool) ) ); connect( m_Controls->m_AllRadio, SIGNAL( clicked(bool) ) , this, SLOT( AllRadio(bool) ) ); connect( m_Controls->m_EstimateCircle, SIGNAL( clicked() ) , this, SLOT( EstimateCircle() ) ); connect( (QObject*)(m_Controls->m_TextureIntON), SIGNAL(clicked()), this, SLOT(TextIntON()) ); connect( m_Controls->m_ExportClusteringResultsButton, SIGNAL(clicked()), this, SLOT(ExportClusteringResults())); } } void QmitkPartialVolumeAnalysisView::ExportClusteringResults() { if (m_ClusteringResult.IsNull() || m_SelectedImage.IsNull()) return; mitk::BaseGeometry* geometry = m_SelectedImage->GetGeometry(); itk::Image< short, 3>::Pointer referenceImage = itk::Image< short, 3>::New(); itk::Vector newSpacing = geometry->GetSpacing(); 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 newDirection; itk::ImageRegion<3> imageRegion; for (int i=0; i<3; i++) for (int j=0; j<3; j++) newDirection[j][i] = geometry->GetMatrixColumn(i)[j]/newSpacing[j]; imageRegion.SetSize(0, geometry->GetExtent(0)); imageRegion.SetSize(1, geometry->GetExtent(1)); imageRegion.SetSize(2, geometry->GetExtent(2)); // apply new image parameters referenceImage->SetSpacing( newSpacing ); referenceImage->SetOrigin( newOrigin ); referenceImage->SetDirection( newDirection ); referenceImage->SetRegions( imageRegion ); referenceImage->Allocate(); typedef itk::Image< float, 3 > OutType; mitk::Image::Pointer mitkInImage = dynamic_cast(m_ClusteringResult->GetData()); typedef itk::Image< itk::RGBAPixel, 3 > ItkRgbaImageType; typedef mitk::ImageToItk< ItkRgbaImageType > CasterType; CasterType::Pointer caster = CasterType::New(); caster->SetInput(mitkInImage); caster->Update(); ItkRgbaImageType::Pointer itkInImage = caster->GetOutput(); typedef itk::ExtractChannelFromRgbaImageFilter< itk::Image< short, 3>, OutType > ExtractionFilterType; ExtractionFilterType::Pointer filter = ExtractionFilterType::New(); filter->SetInput(itkInImage); filter->SetChannel(ExtractionFilterType::ALPHA); filter->SetReferenceImage(referenceImage); filter->Update(); OutType::Pointer outImg = filter->GetOutput(); mitk::Image::Pointer img = mitk::Image::New(); img->InitializeByItk(outImg.GetPointer()); img->SetVolume(outImg->GetBufferPointer()); // init data node mitk::DataNode::Pointer node = mitk::DataNode::New(); node->SetData(img); node->SetName("Clustering Result"); GetDataStorage()->Add(node); } void QmitkPartialVolumeAnalysisView::EstimateCircle() { typedef itk::Image SegImageType; SegImageType::Pointer mask_itk = SegImageType::New(); typedef mitk::ImageToItk CastType; CastType::Pointer caster = CastType::New(); caster->SetInput(m_SelectedImageMask); caster->Update(); typedef itk::ImageMomentsCalculator< SegImageType > MomentsType; MomentsType::Pointer momentsCalc = MomentsType::New(); momentsCalc->SetImage(caster->GetOutput()); momentsCalc->Compute(); MomentsType::VectorType cog = momentsCalc->GetCenterOfGravity(); MomentsType::MatrixType axes = momentsCalc->GetPrincipalAxes(); MomentsType::VectorType moments = momentsCalc->GetPrincipalMoments(); // moments-coord conversion // third coordinate min oder max? // max-min = extent MomentsType::AffineTransformPointer trafo = momentsCalc->GetPhysicalAxesToPrincipalAxesTransform(); itk::ImageRegionIterator itimage(caster->GetOutput(), caster->GetOutput()->GetLargestPossibleRegion()); - itimage = itimage.Begin(); + itimage.GoToBegin(); double max = -9999999999.0; double min = 9999999999.0; while( !itimage.IsAtEnd() ) { if(itimage.Get()) { ImageType::IndexType index = itimage.GetIndex(); itk::Point point; caster->GetOutput()->TransformIndexToPhysicalPoint(index,point); itk::Point newPoint; newPoint = trafo->TransformPoint(point); if(newPoint[2]max) max = newPoint[2]; } ++itimage; } double extent = max - min; MITK_DEBUG << "EXTENT = " << extent; mitk::Point3D origin; mitk::Vector3D right, bottom, normal; double factor = 1000.0; mitk::FillVector3D(origin, cog[0]-factor*axes[1][0]-factor*axes[2][0], cog[1]-factor*axes[1][1]-factor*axes[2][1], cog[2]-factor*axes[1][2]-factor*axes[2][2]); // mitk::FillVector3D(normal, axis[0][0],axis[0][1],axis[0][2]); mitk::FillVector3D(bottom, 2*factor*axes[1][0], 2*factor*axes[1][1], 2*factor*axes[1][2]); mitk::FillVector3D(right, 2*factor*axes[2][0], 2*factor*axes[2][1], 2*factor*axes[2][2]); mitk::PlaneGeometry::Pointer planegeometry = mitk::PlaneGeometry::New(); - planegeometry->InitializeStandardPlane(right.Get_vnl_vector(), bottom.Get_vnl_vector()); + planegeometry->InitializeStandardPlane(right.GetVnlVector(), bottom.GetVnlVector()); planegeometry->SetOrigin(origin); double len1 = sqrt(axes[1][0]*axes[1][0] + axes[1][1]*axes[1][1] + axes[1][2]*axes[1][2]); double len2 = sqrt(axes[2][0]*axes[2][0] + axes[2][1]*axes[2][1] + axes[2][2]*axes[2][2]); mitk::Point2D point1; point1[0] = factor*len1; point1[1] = factor*len2; mitk::Point2D point2; point2[0] = factor*len1+extent*.5; point2[1] = factor*len2; mitk::PlanarCircle::Pointer circle = mitk::PlanarCircle::New(); circle->SetPlaneGeometry(planegeometry); circle->PlaceFigure( point1 ); circle->SetControlPoint(0,point1); circle->SetControlPoint(1,point2); //circle->SetCurrentControlPoint( point2 ); mitk::PlanarFigure::PolyLineType polyline = circle->GetPolyLine( 0 ); MITK_DEBUG << "SIZE of planar figure polyline: " << polyline.size(); AddFigureToDataStorage(circle, "Circle"); } bool QmitkPartialVolumeAnalysisView::AssertDrawingIsPossible(bool checked) { if (m_SelectedImageNodes->GetNode().IsNull()) { checked = false; this->HandleException("Please select an image!", dynamic_cast(this->parent()), true); return false; } //this->GetRenderWindowPart(OPEN)->EnableSlicingPlanes(false); return checked; } void QmitkPartialVolumeAnalysisView::ActionDrawEllipseTriggered() { bool checked = m_Controls->m_CircleButton->isChecked(); if(!this->AssertDrawingIsPossible(checked)) return; mitk::PlanarCircle::Pointer figure = mitk::PlanarCircle::New(); // using PV_ prefix for planar figures from this view // to distinguish them from that ones created throught the measurement view this->AddFigureToDataStorage(figure, QString("PV_Circle%1").arg(++m_EllipseCounter)); MITK_DEBUG << "PlanarCircle created ..."; } void QmitkPartialVolumeAnalysisView::ActionDrawRectangleTriggered() { bool checked = m_Controls->m_RectangleButton->isChecked(); if(!this->AssertDrawingIsPossible(checked)) return; mitk::PlanarRectangle::Pointer figure = mitk::PlanarRectangle::New(); // using PV_ prefix for planar figures from this view // to distinguish them from that ones created throught the measurement view this->AddFigureToDataStorage(figure, QString("PV_Rectangle%1").arg(++m_RectangleCounter)); MITK_DEBUG << "PlanarRectangle created ..."; } void QmitkPartialVolumeAnalysisView::ActionDrawPolygonTriggered() { bool checked = m_Controls->m_PolygonButton->isChecked(); if(!this->AssertDrawingIsPossible(checked)) return; mitk::PlanarPolygon::Pointer figure = mitk::PlanarPolygon::New(); figure->ClosedOn(); // using PV_ prefix for planar figures from this view // to distinguish them from that ones created throught the measurement view this->AddFigureToDataStorage(figure, QString("PV_Polygon%1").arg(++m_PolygonCounter)); MITK_DEBUG << "PlanarPolygon created ..."; } void QmitkPartialVolumeAnalysisView::AddFigureToDataStorage(mitk::PlanarFigure* figure, const QString& name, const char *propertyKey, mitk::BaseProperty *property ) { mitk::DataNode::Pointer newNode = mitk::DataNode::New(); newNode->SetName(name.toStdString()); newNode->SetData(figure); // Add custom property, if available if ( (propertyKey != nullptr) && (property != nullptr) ) { newNode->AddProperty( propertyKey, property ); } // figure drawn on the topmost layer / image this->GetDataStorage()->Add(newNode, m_SelectedImageNodes->GetNode() ); QList selectedNodes = this->GetDataManagerSelection(); - for(unsigned int i = 0; i < selectedNodes.size(); i++) + for(int i = 0; i < selectedNodes.size(); ++i) { selectedNodes[i]->SetSelected(false); } std::vector selectedPFNodes = m_SelectedPlanarFigureNodes->GetNodes(); - for(unsigned int i = 0; i < selectedPFNodes.size(); i++) + for(std::size_t i = 0; i < selectedPFNodes.size(); ++i) { selectedPFNodes[i]->SetSelected(false); } newNode->SetSelected(true); Select(newNode); } void QmitkPartialVolumeAnalysisView::PlanarFigureInitialized() { if(m_SelectedPlanarFigureNodes->GetNode().IsNull()) return; m_CurrentFigureNodeInitialized = true; this->Select(m_SelectedPlanarFigureNodes->GetNode()); m_Controls->m_CircleButton->setChecked(false); m_Controls->m_RectangleButton->setChecked(false); m_Controls->m_PolygonButton->setChecked(false); //this->GetRenderWindowPart(OPEN)->EnableSlicingPlanes(true); this->RequestStatisticsUpdate(); } void QmitkPartialVolumeAnalysisView::PlanarFigureFocus(mitk::DataNode* node) { mitk::PlanarFigure* _PlanarFigure = 0; _PlanarFigure = dynamic_cast (node->GetData()); if (_PlanarFigure) { FindRenderWindow(node); const mitk::PlaneGeometry* _PlaneGeometry = _PlanarFigure->GetPlaneGeometry(); // make node visible if (m_SelectedRenderWindow) { mitk::Point3D centerP = _PlaneGeometry->GetOrigin(); m_SelectedRenderWindow->GetSliceNavigationController()->ReorientSlices( centerP, _PlaneGeometry->GetNormal()); m_SelectedRenderWindow->GetSliceNavigationController()->SelectSliceByPoint( centerP); } } } void QmitkPartialVolumeAnalysisView::FindRenderWindow(mitk::DataNode* node) { if (node && dynamic_cast (node->GetData())) { m_SelectedRenderWindow = 0; bool PlanarFigureInitializedWindow = false; foreach(QmitkRenderWindow * window, this->GetRenderWindowPart()->GetQmitkRenderWindows().values()) { if (!m_SelectedRenderWindow && node->GetBoolProperty("PlanarFigureInitializedWindow", PlanarFigureInitializedWindow, window->GetRenderer())) { m_SelectedRenderWindow = window; } } } } -void QmitkPartialVolumeAnalysisView::OnSelectionChanged(berry::IWorkbenchPart::Pointer part, const QList &nodes) +void QmitkPartialVolumeAnalysisView::OnSelectionChanged(berry::IWorkbenchPart::Pointer, const QList &nodes) { m_Controls->m_InputData->setTitle("Please Select Input Data"); if (!m_Visible) return; if ( nodes.empty() ) { if (m_ClusteringResult.IsNotNull()) { this->GetDataStorage()->Remove(m_ClusteringResult); mitk::RenderingManager::GetInstance()->RequestUpdateAll(); } Select(nullptr, true, true); } for (int i=0; iRemoveOrphanImages(); bool somethingChanged = false; if(node.IsNull()) { somethingChanged = true; if(clearMaskOnFirstArgnullptr) { if ( (m_SelectedImageMask.IsNotNull()) && (m_ImageMaskObserverTag >= 0) ) { m_SelectedImageMask->RemoveObserver( m_ImageMaskObserverTag ); m_ImageMaskObserverTag = -1; } if ( (m_SelectedPlanarFigure.IsNotNull()) && (m_PlanarFigureObserverTag >= 0) ) { m_SelectedPlanarFigure->RemoveObserver( m_PlanarFigureObserverTag ); m_PlanarFigureObserverTag = -1; } if ( (m_SelectedPlanarFigure.IsNotNull()) && (m_InitializedObserverTag >= 0) ) { m_SelectedPlanarFigure->RemoveObserver( m_InitializedObserverTag ); m_InitializedObserverTag = -1; } m_SelectedPlanarFigure = nullptr; m_SelectedPlanarFigureNodes->RemoveAllNodes(); m_CurrentFigureNodeInitialized = false; m_SelectedRenderWindow = 0; m_SelectedMaskNode = nullptr; m_SelectedImageMask = nullptr; } if(clearImageOnFirstArgnullptr) { if ( (m_SelectedImage.IsNotNull()) && (m_ImageObserverTag >= 0) ) { m_SelectedImage->RemoveObserver( m_ImageObserverTag ); m_ImageObserverTag = -1; } m_SelectedImageNodes->RemoveAllNodes(); m_SelectedImage = nullptr; m_IsTensorImage = false; m_FAImage = nullptr; m_RDImage = nullptr; m_ADImage = nullptr; m_MDImage = nullptr; m_CAImage = nullptr; m_DirectionComp1Image = nullptr; m_DirectionComp2Image = nullptr; m_AngularErrorImage = nullptr; m_Controls->m_SimilarAnglesFrame->setVisible(false); m_Controls->m_SimilarAnglesLabel->setVisible(false); } } else { typedef itk::SimpleMemberCommand< QmitkPartialVolumeAnalysisView > ITKCommandType; ITKCommandType::Pointer changeListener; changeListener = ITKCommandType::New(); changeListener->SetCallbackFunction( this, &QmitkPartialVolumeAnalysisView::RequestStatisticsUpdate ); // Get selected element mitk::TensorImage *selectedTensorImage = dynamic_cast< mitk::TensorImage * >( node->GetData() ); mitk::Image *selectedImage = dynamic_cast< mitk::Image * >( node->GetData() ); mitk::PlanarFigure *selectedPlanar = dynamic_cast< mitk::PlanarFigure * >( node->GetData() ); bool isMask = false; bool isImage = false; bool isPlanar = false; bool isTensorImage = false; if (selectedTensorImage != nullptr) { isTensorImage = true; } else if(selectedImage != nullptr) { node->GetPropertyValue("binary", isMask); isImage = !isMask; } else if ( (selectedPlanar != nullptr) ) { isPlanar = true; } // image if(isImage && selectedImage->GetDimension()==3) { if(selectedImage != m_SelectedImage.GetPointer()) { somethingChanged = true; if ( (m_SelectedImage.IsNotNull()) && (m_ImageObserverTag >= 0) ) { m_SelectedImage->RemoveObserver( m_ImageObserverTag ); m_ImageObserverTag = -1; } *m_SelectedImageNodes = node; m_SelectedImage = selectedImage; m_IsTensorImage = false; m_FAImage = nullptr; m_RDImage = nullptr; m_ADImage = nullptr; m_MDImage = nullptr; m_CAImage = nullptr; m_DirectionComp1Image = nullptr; m_DirectionComp2Image = nullptr; m_AngularErrorImage = nullptr; // Add change listeners to selected objects m_ImageObserverTag = m_SelectedImage->AddObserver( itk::ModifiedEvent(), changeListener ); m_Controls->m_SimilarAnglesFrame->setVisible(false); m_Controls->m_SimilarAnglesLabel->setVisible(false); m_Controls->m_SelectedImageLabel->setText( m_SelectedImageNodes->GetNode()->GetName().c_str() ); } } //planar if(isPlanar) { if(selectedPlanar != m_SelectedPlanarFigure.GetPointer()) { MITK_DEBUG << "Planar selection changed"; somethingChanged = true; // Possibly previous change listeners if ( (m_SelectedPlanarFigure.IsNotNull()) && (m_PlanarFigureObserverTag >= 0) ) { m_SelectedPlanarFigure->RemoveObserver( m_PlanarFigureObserverTag ); m_PlanarFigureObserverTag = -1; } if ( (m_SelectedPlanarFigure.IsNotNull()) && (m_InitializedObserverTag >= 0) ) { m_SelectedPlanarFigure->RemoveObserver( m_InitializedObserverTag ); m_InitializedObserverTag = -1; } m_SelectedPlanarFigure = selectedPlanar; *m_SelectedPlanarFigureNodes = node; m_CurrentFigureNodeInitialized = selectedPlanar->IsPlaced(); m_SelectedMaskNode = nullptr; m_SelectedImageMask = nullptr; m_PlanarFigureObserverTag = m_SelectedPlanarFigure->AddObserver( mitk::EndInteractionPlanarFigureEvent(), changeListener ); if(!m_CurrentFigureNodeInitialized) { typedef itk::SimpleMemberCommand< QmitkPartialVolumeAnalysisView > ITKCommandType; ITKCommandType::Pointer initializationCommand; initializationCommand = ITKCommandType::New(); // set the callback function of the member command initializationCommand->SetCallbackFunction( this, &QmitkPartialVolumeAnalysisView::PlanarFigureInitialized ); // add an observer m_InitializedObserverTag = selectedPlanar->AddObserver( mitk::EndPlacementPlanarFigureEvent(), initializationCommand ); } m_Controls->m_SelectedMaskLabel->setText( m_SelectedPlanarFigureNodes->GetNode()->GetName().c_str() ); PlanarFigureFocus(node); } } //mask this->m_Controls->m_EstimateCircle->setEnabled(isMask && selectedImage->GetDimension()==3); if(isMask && selectedImage->GetDimension()==3) { if(selectedImage != m_SelectedImage.GetPointer()) { somethingChanged = true; if ( (m_SelectedImageMask.IsNotNull()) && (m_ImageMaskObserverTag >= 0) ) { m_SelectedImageMask->RemoveObserver( m_ImageMaskObserverTag ); m_ImageMaskObserverTag = -1; } m_SelectedMaskNode = node; m_SelectedImageMask = selectedImage; m_SelectedPlanarFigure = nullptr; m_SelectedPlanarFigureNodes->RemoveAllNodes(); m_ImageMaskObserverTag = m_SelectedImageMask->AddObserver( itk::ModifiedEvent(), changeListener ); m_Controls->m_SelectedMaskLabel->setText( m_SelectedMaskNode->GetName().c_str() ); } } //tensor image if(isTensorImage && selectedTensorImage->GetDimension()==3) { if(selectedImage != m_SelectedImage.GetPointer()) { somethingChanged = true; if ( (m_SelectedImage.IsNotNull()) && (m_ImageObserverTag >= 0) ) { m_SelectedImage->RemoveObserver( m_ImageObserverTag ); m_ImageObserverTag = -1; } *m_SelectedImageNodes = node; m_SelectedImage = selectedImage; m_IsTensorImage = true; ExtractTensorImages(selectedImage); // Add change listeners to selected objects m_ImageObserverTag = m_SelectedImage->AddObserver( itk::ModifiedEvent(), changeListener ); m_Controls->m_SimilarAnglesFrame->setVisible(true); m_Controls->m_SimilarAnglesLabel->setVisible(true); m_Controls->m_SelectedImageLabel->setText( m_SelectedImageNodes->GetNode()->GetName().c_str() ); } } } if(somethingChanged) { this->SetMeasurementInfoToRenderWindow(""); if(m_SelectedPlanarFigure.IsNull() && m_SelectedImageMask.IsNull() ) { m_Controls->m_SelectedMaskLabel->setText("mandatory"); m_Controls->m_ResampleOptionsFrame->setEnabled(false); m_Controls->m_HistogramWidget->setEnabled(false); m_Controls->m_ClassSelector->setEnabled(false); m_Controls->m_DisplayHistogramCheckbox->setEnabled(false); m_Controls->m_AdvancedCheckbox->setEnabled(false); m_Controls->frame_7->setEnabled(false); } else { m_Controls->m_ResampleOptionsFrame->setEnabled(true); m_Controls->m_HistogramWidget->setEnabled(true); m_Controls->m_ClassSelector->setEnabled(true); m_Controls->m_DisplayHistogramCheckbox->setEnabled(true); m_Controls->m_AdvancedCheckbox->setEnabled(true); m_Controls->frame_7->setEnabled(true); } // Clear statistics / histogram GUI if nothing is selected if ( m_SelectedImage.IsNull() ) { m_Controls->m_PlanarFigureButtonsFrame->setEnabled(false); m_Controls->m_OpacityFrame->setEnabled(false); m_Controls->m_SelectedImageLabel->setText("mandatory"); } else { m_Controls->m_PlanarFigureButtonsFrame->setEnabled(true); m_Controls->m_OpacityFrame->setEnabled(true); } if( !m_Visible || m_SelectedImage.IsNull() || (m_SelectedPlanarFigure.IsNull() && m_SelectedImageMask.IsNull()) ) { m_Controls->m_InputData->setTitle("Please Select Input Data"); m_Controls->m_HistogramWidget->ClearItemModel(); m_CurrentStatisticsValid = false; } else { m_Controls->m_InputData->setTitle("Input Data"); this->RequestStatisticsUpdate(); } } } void QmitkPartialVolumeAnalysisView::ShowClusteringResults() { typedef itk::Image MaskImageType; mitk::Image::Pointer mask = 0; MaskImageType::Pointer itkmask = 0; if(m_IsTensorImage && m_Controls->m_SimilarAnglesSlider->value() != 0) { typedef itk::Image AngularErrorImageType; typedef mitk::ImageToItk CastType; CastType::Pointer caster = CastType::New(); caster->SetInput(m_AngularErrorImage); caster->Update(); typedef itk::BinaryThresholdImageFilter< AngularErrorImageType, MaskImageType > ThreshType; ThreshType::Pointer thresh = ThreshType::New(); thresh->SetUpperThreshold((90-m_Controls->m_SimilarAnglesSlider->value())*(PVA_PI/180.0)); thresh->SetInsideValue(1.0); thresh->SetInput(caster->GetOutput()); thresh->Update(); itkmask = thresh->GetOutput(); mask = mitk::Image::New(); mask->InitializeByItk(itkmask.GetPointer()); mask->SetVolume(itkmask->GetBufferPointer()); // GetDataStorage()->Remove(m_newnode); // m_newnode = mitk::DataNode::New(); // m_newnode->SetData(mask); // m_newnode->SetName("masking node"); // m_newnode->SetIntProperty( "layer", 1002 ); // GetDataStorage()->Add(m_newnode, m_SelectedImageNodes->GetNode()); } mitk::Image::Pointer clusteredImage; ClusteringType::Pointer clusterer = ClusteringType::New(); if(m_QuantifyClass==3) { if(m_IsTensorImage) { double *green_fa, *green_rd, *green_ad, *green_md; //double *greengray_fa, *greengray_rd, *greengray_ad, *greengray_md; double *gray_fa, *gray_rd, *gray_ad, *gray_md; //double *redgray_fa, *redgray_rd, *redgray_ad, *redgray_md; double *red_fa, *red_rd, *red_ad, *red_md; mitk::Image* tmpImg = m_CurrentStatisticsCalculator->GetInternalAdditionalResampledImage(0); mitk::Image::ConstPointer imgToCluster = tmpImg; red_fa = clusterer->PerformQuantification(imgToCluster, m_CurrentRGBClusteringResults->rgbChannels->r, mask); green_fa = clusterer->PerformQuantification(imgToCluster, m_CurrentRGBClusteringResults->rgbChannels->g, mask); gray_fa = clusterer->PerformQuantification(imgToCluster, m_CurrentRGBClusteringResults->rgbChannels->b, mask); tmpImg = m_CurrentStatisticsCalculator->GetInternalAdditionalResampledImage(3); mitk::Image::ConstPointer imgToCluster3 = tmpImg; red_rd = clusterer->PerformQuantification(imgToCluster3, m_CurrentRGBClusteringResults->rgbChannels->r, mask); green_rd = clusterer->PerformQuantification(imgToCluster3, m_CurrentRGBClusteringResults->rgbChannels->g, mask); gray_rd = clusterer->PerformQuantification(imgToCluster3, m_CurrentRGBClusteringResults->rgbChannels->b, mask); tmpImg = m_CurrentStatisticsCalculator->GetInternalAdditionalResampledImage(4); mitk::Image::ConstPointer imgToCluster4 = tmpImg; red_ad = clusterer->PerformQuantification(imgToCluster4, m_CurrentRGBClusteringResults->rgbChannels->r, mask); green_ad = clusterer->PerformQuantification(imgToCluster4, m_CurrentRGBClusteringResults->rgbChannels->g, mask); gray_ad = clusterer->PerformQuantification(imgToCluster4, m_CurrentRGBClusteringResults->rgbChannels->b, mask); tmpImg = m_CurrentStatisticsCalculator->GetInternalAdditionalResampledImage(5); mitk::Image::ConstPointer imgToCluster5 = tmpImg; red_md = clusterer->PerformQuantification(imgToCluster5, m_CurrentRGBClusteringResults->rgbChannels->r, mask); green_md = clusterer->PerformQuantification(imgToCluster5, m_CurrentRGBClusteringResults->rgbChannels->g, mask); gray_md = clusterer->PerformQuantification(imgToCluster5, m_CurrentRGBClusteringResults->rgbChannels->b, mask); // clipboard QString clipboardText("FA\t%1\t%2\t\t%3\t%4\t\t%5\t%6\t"); clipboardText = clipboardText .arg(red_fa[0]).arg(red_fa[1]) .arg(gray_fa[0]).arg(gray_fa[1]) .arg(green_fa[0]).arg(green_fa[1]); QString clipboardText3("RD\t%1\t%2\t\t%3\t%4\t\t%5\t%6\t"); clipboardText3 = clipboardText3 .arg(red_rd[0]).arg(red_rd[1]) .arg(gray_rd[0]).arg(gray_rd[1]) .arg(green_rd[0]).arg(green_rd[1]); QString clipboardText4("AD\t%1\t%2\t\t%3\t%4\t\t%5\t%6\t"); clipboardText4 = clipboardText4 .arg(red_ad[0]).arg(red_ad[1]) .arg(gray_ad[0]).arg(gray_ad[1]) .arg(green_ad[0]).arg(green_ad[1]); QString clipboardText5("MD\t%1\t%2\t\t%3\t%4\t\t%5\t%6"); clipboardText5 = clipboardText5 .arg(red_md[0]).arg(red_md[1]) .arg(gray_md[0]).arg(gray_md[1]) .arg(green_md[0]).arg(green_md[1]); QApplication::clipboard()->setText(clipboardText+clipboardText3+clipboardText4+clipboardText5, QClipboard::Clipboard); // now paint infos also on renderwindow QString plainInfoText("%1 %2 %3 \n"); plainInfoText = plainInfoText .arg("Red ", 20) .arg("Gray ", 20) .arg("Green", 20); QString plainInfoText0("FA:%1 ± %2%3 ± %4%5 ± %6\n"); plainInfoText0 = plainInfoText0 .arg(red_fa[0], 10, 'g', 2, QLatin1Char( ' ' )).arg(red_fa[1], -10, 'g', 2, QLatin1Char( ' ' )) .arg(gray_fa[0], 10, 'g', 2, QLatin1Char( ' ' )).arg(gray_fa[1], -10, 'g', 2, QLatin1Char( ' ' )) .arg(green_fa[0], 10, 'g', 2, QLatin1Char( ' ' )).arg(green_fa[1], -10, 'g', 2, QLatin1Char( ' ' )); QString plainInfoText3("RDx10³:%1 ± %2%3 ± %4%5 ± %6\n"); plainInfoText3 = plainInfoText3 .arg(1000.0 * red_rd[0], 10, 'g', 2, QLatin1Char( ' ' )).arg(1000.0 * red_rd[1], -10, 'g', 2, QLatin1Char( ' ' )) .arg(1000.0 * gray_rd[0], 10, 'g', 2, QLatin1Char( ' ' )).arg(1000.0 * gray_rd[1], -10, 'g', 2, QLatin1Char( ' ' )) .arg(1000.0 * green_rd[0], 10, 'g', 2, QLatin1Char( ' ' )).arg(1000.0 * green_rd[1], -10, 'g', 2, QLatin1Char( ' ' )); QString plainInfoText4("ADx10³:%1 ± %2%3 ± %4%5 ± %6\n"); plainInfoText4 = plainInfoText4 .arg(1000.0 * red_ad[0], 10, 'g', 2, QLatin1Char( ' ' )).arg(1000.0 * red_ad[1], -10, 'g', 2, QLatin1Char( ' ' )) .arg(1000.0 * gray_ad[0], 10, 'g', 2, QLatin1Char( ' ' )).arg(1000.0 * gray_ad[1], -10, 'g', 2, QLatin1Char( ' ' )) .arg(1000.0 * green_ad[0], 10, 'g', 2, QLatin1Char( ' ' )).arg(1000.0 * green_ad[1], -10, 'g', 2, QLatin1Char( ' ' )); QString plainInfoText5("MDx10³:%1 ± %2%3 ± %4%5 ± %6"); plainInfoText5 = plainInfoText5 .arg(1000.0 * red_md[0], 10, 'g', 2, QLatin1Char( ' ' )).arg(1000.0 * red_md[1], -10, 'g', 2, QLatin1Char( ' ' )) .arg(1000.0 * gray_md[0], 10, 'g', 2, QLatin1Char( ' ' )).arg(1000.0 * gray_md[1], -10, 'g', 2, QLatin1Char( ' ' )) .arg(1000.0 * green_md[0], 10, 'g', 2, QLatin1Char( ' ' )).arg(1000.0 * green_md[1], -10, 'g', 2, QLatin1Char( ' ' )); this->SetMeasurementInfoToRenderWindow(plainInfoText+plainInfoText0+plainInfoText3+plainInfoText4+plainInfoText5); } else { double* green; double* gray; double* red; mitk::Image* tmpImg = m_CurrentStatisticsCalculator->GetInternalImage(); mitk::Image::ConstPointer imgToCluster = tmpImg; red = clusterer->PerformQuantification(imgToCluster, m_CurrentRGBClusteringResults->rgbChannels->r); green = clusterer->PerformQuantification(imgToCluster, m_CurrentRGBClusteringResults->rgbChannels->g); gray = clusterer->PerformQuantification(imgToCluster, m_CurrentRGBClusteringResults->rgbChannels->b); // clipboard QString clipboardText("%1\t%2\t\t%3\t%4\t\t%5\t%6"); clipboardText = clipboardText.arg(red[0]).arg(red[1]) .arg(gray[0]).arg(gray[1]) .arg(green[0]).arg(green[1]); QApplication::clipboard()->setText(clipboardText, QClipboard::Clipboard); // now paint infos also on renderwindow QString plainInfoText("Red: %1 ± %2\nGray: %3 ± %4\nGreen: %5 ± %6"); plainInfoText = plainInfoText.arg(red[0]).arg(red[1]) .arg(gray[0]).arg(gray[1]) .arg(green[0]).arg(green[1]); this->SetMeasurementInfoToRenderWindow(plainInfoText); } clusteredImage = m_CurrentRGBClusteringResults->rgb; } else { if(m_IsTensorImage) { double *red_fa, *red_rd, *red_ad, *red_md; mitk::Image* tmpImg = m_CurrentStatisticsCalculator->GetInternalAdditionalResampledImage(0); mitk::Image::ConstPointer imgToCluster = tmpImg; red_fa = clusterer->PerformQuantification(imgToCluster, m_CurrentPerformClusteringResults->clusteredImage, mask); tmpImg = m_CurrentStatisticsCalculator->GetInternalAdditionalResampledImage(3); mitk::Image::ConstPointer imgToCluster3 = tmpImg; red_rd = clusterer->PerformQuantification(imgToCluster3, m_CurrentPerformClusteringResults->clusteredImage, mask); tmpImg = m_CurrentStatisticsCalculator->GetInternalAdditionalResampledImage(4); mitk::Image::ConstPointer imgToCluster4 = tmpImg; red_ad = clusterer->PerformQuantification(imgToCluster4, m_CurrentPerformClusteringResults->clusteredImage, mask); tmpImg = m_CurrentStatisticsCalculator->GetInternalAdditionalResampledImage(5); mitk::Image::ConstPointer imgToCluster5 = tmpImg; red_md = clusterer->PerformQuantification(imgToCluster5, m_CurrentPerformClusteringResults->clusteredImage, mask); // clipboard QString clipboardText("FA\t%1\t%2\t"); clipboardText = clipboardText .arg(red_fa[0]).arg(red_fa[1]); QString clipboardText3("RD\t%1\t%2\t"); clipboardText3 = clipboardText3 .arg(red_rd[0]).arg(red_rd[1]); QString clipboardText4("AD\t%1\t%2\t"); clipboardText4 = clipboardText4 .arg(red_ad[0]).arg(red_ad[1]); QString clipboardText5("MD\t%1\t%2\t"); clipboardText5 = clipboardText5 .arg(red_md[0]).arg(red_md[1]); QApplication::clipboard()->setText(clipboardText+clipboardText3+clipboardText4+clipboardText5, QClipboard::Clipboard); // now paint infos also on renderwindow QString plainInfoText("%1 \n"); plainInfoText = plainInfoText .arg("Red ", 20); QString plainInfoText0("FA:%1 ± %2\n"); plainInfoText0 = plainInfoText0 .arg(red_fa[0], 10, 'g', 2, QLatin1Char( ' ' )).arg(red_fa[1], -10, 'g', 2, QLatin1Char( ' ' )); QString plainInfoText3("RDx10³:%1 ± %2\n"); plainInfoText3 = plainInfoText3 .arg(1000.0 * red_rd[0], 10, 'g', 2, QLatin1Char( ' ' )).arg(1000.0 * red_rd[1], -10, 'g', 2, QLatin1Char( ' ' )); QString plainInfoText4("ADx10³:%1 ± %2\n"); plainInfoText4 = plainInfoText4 .arg(1000.0 * red_ad[0], 10, 'g', 2, QLatin1Char( ' ' )).arg(1000.0 * red_ad[1], -10, 'g', 2, QLatin1Char( ' ' )); QString plainInfoText5("MDx10³:%1 ± %2"); plainInfoText5 = plainInfoText5 .arg(1000.0 * red_md[0], 10, 'g', 2, QLatin1Char( ' ' )).arg(1000.0 * red_md[1], -10, 'g', 2, QLatin1Char( ' ' )); this->SetMeasurementInfoToRenderWindow(plainInfoText+plainInfoText0+plainInfoText3+plainInfoText4+plainInfoText5); } else { double* quant; mitk::Image* tmpImg = m_CurrentStatisticsCalculator->GetInternalImage(); mitk::Image::ConstPointer imgToCluster = tmpImg; quant = clusterer->PerformQuantification(imgToCluster, m_CurrentPerformClusteringResults->clusteredImage); // clipboard QString clipboardText("%1\t%2"); clipboardText = clipboardText.arg(quant[0]).arg(quant[1]); QApplication::clipboard()->setText(clipboardText, QClipboard::Clipboard); // now paint infos also on renderwindow QString plainInfoText("Measurement: %1 ± %2"); plainInfoText = plainInfoText.arg(quant[0]).arg(quant[1]); this->SetMeasurementInfoToRenderWindow(plainInfoText); } clusteredImage = m_CurrentPerformClusteringResults->displayImage; } if(mask.IsNotNull()) { typedef itk::Image,3> RGBImageType; typedef mitk::ImageToItk ClusterCasterType; ClusterCasterType::Pointer clCaster = ClusterCasterType::New(); clCaster->SetInput(clusteredImage); clCaster->Update(); clCaster->GetOutput(); typedef itk::MaskImageFilter< RGBImageType, MaskImageType, RGBImageType > MaskType; MaskType::Pointer masker = MaskType::New(); masker->SetInput1(clCaster->GetOutput()); masker->SetInput2(itkmask); masker->Update(); clusteredImage = mitk::Image::New(); clusteredImage->InitializeByItk(masker->GetOutput()); clusteredImage->SetVolume(masker->GetOutput()->GetBufferPointer()); } if(m_ClusteringResult.IsNotNull()) { this->GetDataStorage()->Remove(m_ClusteringResult); } m_ClusteringResult = mitk::DataNode::New(); m_ClusteringResult->SetBoolProperty("helper object", true); m_ClusteringResult->SetIntProperty( "layer", 1000 ); m_ClusteringResult->SetBoolProperty("texture interpolation", m_TexIsOn); m_ClusteringResult->SetData(clusteredImage); m_ClusteringResult->SetName("Clusterprobs"); this->GetDataStorage()->Add(m_ClusteringResult, m_SelectedImageNodes->GetNode()); if(m_SelectedPlanarFigure.IsNotNull() && m_SelectedPlanarFigureNodes->GetNode().IsNotNull()) { m_SelectedPlanarFigureNodes->GetNode()->SetIntProperty( "layer", 1001 ); } this->RequestRenderWindowUpdate(); } void QmitkPartialVolumeAnalysisView::UpdateStatistics() { if(!m_CurrentFigureNodeInitialized && m_SelectedPlanarFigure.IsNotNull()) { MITK_DEBUG << "Selected planar figure not initialized. No stats calculation performed."; return; } // Remove any cached images that are no longer referenced elsewhere this->RemoveOrphanImages(); if ( m_SelectedImage.IsNotNull() ) { // Check if a the selected image is a multi-channel image. If yes, statistics // cannot be calculated currently. if ( !m_IsTensorImage && m_SelectedImage->GetPixelType().GetNumberOfComponents() > 1 ) { QMessageBox::information( nullptr, "Warning", "Non-tensor multi-component images not supported."); m_Controls->m_HistogramWidget->ClearItemModel(); m_CurrentStatisticsValid = false; return; } m_CurrentStatisticsCalculator = nullptr; if(!m_IsTensorImage) { // Retrieve HistogramStatisticsCalculator from has map (or create a new one // for this image if non-existant) PartialVolumeAnalysisMapType::iterator it = m_PartialVolumeAnalysisMap.find( m_SelectedImage ); if ( it != m_PartialVolumeAnalysisMap.end() ) { m_CurrentStatisticsCalculator = it->second; } } if(m_CurrentStatisticsCalculator.IsNull()) { m_CurrentStatisticsCalculator = mitk::PartialVolumeAnalysisHistogramCalculator::New(); m_CurrentStatisticsCalculator->SetPlanarFigureThickness(m_Controls->m_PlanarFiguresThickness->value()); if(m_IsTensorImage) { m_CurrentStatisticsCalculator->SetImage( m_CAImage ); m_CurrentStatisticsCalculator->AddAdditionalResamplingImage( m_FAImage ); m_CurrentStatisticsCalculator->AddAdditionalResamplingImage( m_DirectionComp1Image ); m_CurrentStatisticsCalculator->AddAdditionalResamplingImage( m_DirectionComp2Image ); m_CurrentStatisticsCalculator->AddAdditionalResamplingImage( m_RDImage ); m_CurrentStatisticsCalculator->AddAdditionalResamplingImage( m_ADImage ); m_CurrentStatisticsCalculator->AddAdditionalResamplingImage( m_MDImage ); } else { m_CurrentStatisticsCalculator->SetImage( m_SelectedImage ); } m_PartialVolumeAnalysisMap[m_SelectedImage] = m_CurrentStatisticsCalculator; MITK_DEBUG << "Creating StatisticsCalculator"; } std::string maskName; std::string maskType; unsigned int maskDimension; if ( m_SelectedImageMask.IsNotNull() ) { mitk::PixelType pixelType = m_SelectedImageMask->GetPixelType(); MITK_DEBUG << pixelType.GetPixelTypeAsString(); if(pixelType.GetComponentTypeAsString() == "char") { MITK_DEBUG << "Pixel type is char instead of uchar"; return; } if(pixelType.GetBitsPerComponent() == 16) { //convert from ushort to uchar typedef itk::Image UCharImageType; UCharImageType::Pointer charImage; if(pixelType.GetComponentTypeAsString() == "short" ) { typedef itk::Image ShortImageType; ShortImageType::Pointer shortImage; mitk::CastToItkImage( m_SelectedImageMask, shortImage ); typedef itk::ImageDuplicator< ShortImageType > DuplicatorType; DuplicatorType::Pointer duplicator = DuplicatorType::New(); duplicator->SetInputImage( shortImage ); duplicator->Update(); typedef itk::CastImageFilter ImageCasterType; ImageCasterType::Pointer caster = ImageCasterType::New(); caster->SetInput( duplicator->GetOutput() ); caster->Update(); charImage = caster->GetOutput(); } else { typedef itk::Image UShortImageType; UShortImageType::Pointer shortImage; mitk::CastToItkImage( m_SelectedImageMask, shortImage ); typedef itk::ImageDuplicator< UShortImageType > DuplicatorType; DuplicatorType::Pointer duplicator = DuplicatorType::New(); duplicator->SetInputImage( shortImage ); duplicator->Update(); typedef itk::CastImageFilter ImageCasterType; ImageCasterType::Pointer caster = ImageCasterType::New(); caster->SetInput( duplicator->GetOutput() ); caster->Update(); charImage = caster->GetOutput(); } m_SelectedImageMask = nullptr; m_SelectedImageMask = mitk::Image::New(); m_SelectedImageMask->InitializeByItk( charImage.GetPointer() ); m_SelectedImageMask->SetVolume( charImage->GetBufferPointer() ); mitk::CastToMitkImage(charImage, m_SelectedImageMask); } m_CurrentStatisticsCalculator->SetImageMask( m_SelectedImageMask ); m_CurrentStatisticsCalculator->SetMaskingModeToImage(); maskName = m_SelectedMaskNode->GetName(); maskType = m_SelectedImageMask->GetNameOfClass(); maskDimension = 3; std::stringstream maskLabel; maskLabel << maskName; if ( maskDimension > 0 ) { maskLabel << " [" << maskDimension << "D " << maskType << "]"; } m_Controls->m_SelectedMaskLabel->setText( maskLabel.str().c_str() ); } else if ( m_SelectedPlanarFigure.IsNotNull() && m_SelectedPlanarFigureNodes->GetNode().IsNotNull()) { m_CurrentStatisticsCalculator->SetPlanarFigure( m_SelectedPlanarFigure ); m_CurrentStatisticsCalculator->SetMaskingModeToPlanarFigure(); maskName = m_SelectedPlanarFigureNodes->GetNode()->GetName(); maskType = m_SelectedPlanarFigure->GetNameOfClass(); maskDimension = 2; } else { m_CurrentStatisticsCalculator->SetMaskingModeToNone(); maskName = "-"; maskType = ""; maskDimension = 0; } bool statisticsChanged = false; bool statisticsCalculationSuccessful = false; // Initialize progress bar mitk::ProgressBar::GetInstance()->AddStepsToDo( 100 ); // Install listener for progress events and initialize progress bar typedef itk::SimpleMemberCommand< QmitkPartialVolumeAnalysisView > ITKCommandType; ITKCommandType::Pointer progressListener; progressListener = ITKCommandType::New(); progressListener->SetCallbackFunction( this, &QmitkPartialVolumeAnalysisView::UpdateProgressBar ); unsigned long progressObserverTag = m_CurrentStatisticsCalculator ->AddObserver( itk::ProgressEvent(), progressListener ); ClusteringType::ParamsType *cparams = 0; ClusteringType::ClusterResultType *cresult = 0; ClusteringType::HistType *chist = 0; try { m_CurrentStatisticsCalculator->SetNumberOfBins(m_Controls->m_NumberBins->text().toInt()); m_CurrentStatisticsCalculator->SetUpsamplingFactor(m_Controls->m_Upsampling->text().toDouble()); m_CurrentStatisticsCalculator->SetGaussianSigma(m_Controls->m_GaussianSigma->text().toDouble()); // Compute statistics statisticsChanged = m_CurrentStatisticsCalculator->ComputeStatistics( ); mitk::Image* tmpImg = m_CurrentStatisticsCalculator->GetInternalImage(); mitk::Image::ConstPointer imgToCluster = tmpImg; if(imgToCluster.IsNotNull()) { // perform clustering const HistogramType *histogram = m_CurrentStatisticsCalculator->GetHistogram( ); if(histogram != nullptr) { ClusteringType::Pointer clusterer = ClusteringType::New(); clusterer->SetStepsNumIntegration(200); clusterer->SetMaxIt(1000); mitk::Image::Pointer pFiberImg; if(m_QuantifyClass==3) { if(m_Controls->m_Quantiles->isChecked()) { m_CurrentRGBClusteringResults = clusterer->PerformRGBQuantiles(imgToCluster, histogram, m_Controls->m_q1->value(),m_Controls->m_q2->value()); } else { m_CurrentRGBClusteringResults = clusterer->PerformRGBClustering(imgToCluster, histogram); } pFiberImg = m_CurrentRGBClusteringResults->rgbChannels->r; cparams = m_CurrentRGBClusteringResults->params; cresult = m_CurrentRGBClusteringResults->result; chist = m_CurrentRGBClusteringResults->hist; } else { if(m_Controls->m_Quantiles->isChecked()) { m_CurrentPerformClusteringResults = clusterer->PerformQuantiles(imgToCluster, histogram, m_Controls->m_q1->value(),m_Controls->m_q2->value()); } else { m_CurrentPerformClusteringResults = clusterer->PerformClustering(imgToCluster, histogram, m_QuantifyClass); } pFiberImg = m_CurrentPerformClusteringResults->clusteredImage; cparams = m_CurrentPerformClusteringResults->params; cresult = m_CurrentPerformClusteringResults->result; chist = m_CurrentPerformClusteringResults->hist; } if(m_IsTensorImage) { m_AngularErrorImage = clusterer->CaculateAngularErrorImage( m_CurrentStatisticsCalculator->GetInternalAdditionalResampledImage(1), m_CurrentStatisticsCalculator->GetInternalAdditionalResampledImage(2), pFiberImg); // GetDataStorage()->Remove(m_newnode2); // m_newnode2 = mitk::DataNode::New(); // m_newnode2->SetData(m_AngularErrorImage); // m_newnode2->SetName(("AngularError")); // m_newnode2->SetIntProperty( "layer", 1003 ); // GetDataStorage()->Add(m_newnode2, m_SelectedImageNodes->GetNode()); // newnode = mitk::DataNode::New(); // newnode->SetData(m_CurrentStatisticsCalculator->GetInternalAdditionalResampledImage(1)); // newnode->SetName(("Comp1")); // GetDataStorage()->Add(newnode, m_SelectedImageNodes->GetNode()); // newnode = mitk::DataNode::New(); // newnode->SetData(m_CurrentStatisticsCalculator->GetInternalAdditionalResampledImage(2)); // newnode->SetName(("Comp2")); // GetDataStorage()->Add(newnode, m_SelectedImageNodes->GetNode()); } ShowClusteringResults(); } } statisticsCalculationSuccessful = true; } catch ( const std::runtime_error &e ) { QMessageBox::information( nullptr, "Warning", e.what()); } catch ( const std::exception &e ) { MITK_ERROR << "Caught exception: " << e.what(); QMessageBox::information( nullptr, "Warning", e.what()); } m_CurrentStatisticsCalculator->RemoveObserver( progressObserverTag ); // Make sure that progress bar closes mitk::ProgressBar::GetInstance()->Progress( 100 ); if ( statisticsCalculationSuccessful ) { if ( statisticsChanged ) { // Do not show any error messages m_CurrentStatisticsValid = true; } // m_Controls->m_HistogramWidget->SetHistogramModeToDirectHistogram(); m_Controls->m_HistogramWidget->SetParameters( cparams, cresult, chist ); // m_Controls->m_HistogramWidget->UpdateItemModelFromHistogram(); } else { m_Controls->m_SelectedMaskLabel->setText("mandatory"); // Clear statistics and histogram m_Controls->m_HistogramWidget->ClearItemModel(); m_CurrentStatisticsValid = false; // If a (non-closed) PlanarFigure is selected, display a line profile widget if ( m_SelectedPlanarFigure.IsNotNull() ) { // TODO: enable line profile widget //m_Controls->m_StatisticsWidgetStack->setCurrentIndex( 1 ); //m_Controls->m_LineProfileWidget->SetImage( m_SelectedImage ); //m_Controls->m_LineProfileWidget->SetPlanarFigure( m_SelectedPlanarFigure ); //m_Controls->m_LineProfileWidget->UpdateItemModelFromPath(); } } } } void QmitkPartialVolumeAnalysisView::SetMeasurementInfoToRenderWindow(const QString& text) { FindRenderWindow(m_SelectedPlanarFigureNodes->GetNode()); if(m_LastRenderWindow != m_SelectedRenderWindow) { if(m_LastRenderWindow) { QObject::disconnect( m_LastRenderWindow, SIGNAL( destroyed(QObject*) ) , this, SLOT( OnRenderWindowDelete(QObject*) ) ); } m_LastRenderWindow = m_SelectedRenderWindow; if(m_LastRenderWindow) { QObject::connect( m_LastRenderWindow, SIGNAL( destroyed(QObject*) ) , this, SLOT( OnRenderWindowDelete(QObject*) ) ); } } if(m_LastRenderWindow && m_SelectedPlanarFigureNodes->GetNode().IsNotNull()) { if (!text.isEmpty()) { m_MeasurementInfoAnnotation->SetText(1, text.toLatin1().data()); mitk::VtkLayerController::GetInstance(m_LastRenderWindow->GetRenderWindow())->InsertForegroundRenderer( m_MeasurementInfoRenderer, true); } else { if (mitk::VtkLayerController::GetInstance( m_LastRenderWindow->GetRenderWindow()) ->IsRendererInserted( m_MeasurementInfoRenderer)) mitk::VtkLayerController::GetInstance(m_LastRenderWindow->GetRenderWindow())->RemoveRenderer( m_MeasurementInfoRenderer); } } else { mitk::IRenderWindowPart* renderWindowPart = this->GetRenderWindowPart(); if ( renderWindowPart == nullptr ) { return; } if (!text.isEmpty()) { m_MeasurementInfoAnnotation->SetText(1, text.toLatin1().data()); mitk::VtkLayerController::GetInstance(renderWindowPart->GetQmitkRenderWindow("axial")->GetRenderWindow())->InsertForegroundRenderer( m_MeasurementInfoRenderer, true); } else { if (mitk::VtkLayerController::GetInstance( renderWindowPart->GetQmitkRenderWindow("axial")->GetRenderWindow()) ->IsRendererInserted( m_MeasurementInfoRenderer)) mitk::VtkLayerController::GetInstance(renderWindowPart->GetQmitkRenderWindow("axial")->GetRenderWindow())->RemoveRenderer( m_MeasurementInfoRenderer); } } } void QmitkPartialVolumeAnalysisView::UpdateProgressBar() { mitk::ProgressBar::GetInstance()->Progress(); } void QmitkPartialVolumeAnalysisView::RequestStatisticsUpdate() { if ( !m_StatisticsUpdatePending ) { QApplication::postEvent( this, new QmitkRequestStatisticsUpdateEvent ); m_StatisticsUpdatePending = true; } } void QmitkPartialVolumeAnalysisView::RemoveOrphanImages() { PartialVolumeAnalysisMapType::iterator it = m_PartialVolumeAnalysisMap.begin(); while ( it != m_PartialVolumeAnalysisMap.end() ) { mitk::Image *image = it->first; mitk::PartialVolumeAnalysisHistogramCalculator *calculator = it->second; ++it; mitk::NodePredicateData::Pointer hasImage = mitk::NodePredicateData::New( image ); if ( this->GetDataStorage()->GetNode( hasImage ) == nullptr ) { if ( m_SelectedImage == image ) { m_SelectedImage = nullptr; m_SelectedImageNodes->RemoveAllNodes(); } if ( m_CurrentStatisticsCalculator == calculator ) { m_CurrentStatisticsCalculator = nullptr; } m_PartialVolumeAnalysisMap.erase( image ); it = m_PartialVolumeAnalysisMap.begin(); } } } void QmitkPartialVolumeAnalysisView::ExtractTensorImages( mitk::Image::Pointer tensorimage) { typedef itk::Image< itk::DiffusionTensor3D, 3> TensorImageType; typedef mitk::ImageToItk CastType; CastType::Pointer caster = CastType::New(); caster->SetInput(tensorimage); caster->Update(); TensorImageType::Pointer image = caster->GetOutput(); typedef itk::TensorDerivedMeasurementsFilter MeasurementsType; MeasurementsType::Pointer measurementsCalculator = MeasurementsType::New(); measurementsCalculator->SetInput(image ); measurementsCalculator->SetMeasure(MeasurementsType::FA); measurementsCalculator->Update(); MeasurementsType::OutputImageType::Pointer fa = measurementsCalculator->GetOutput(); m_FAImage = mitk::Image::New(); m_FAImage->InitializeByItk(fa.GetPointer()); m_FAImage->SetVolume(fa->GetBufferPointer()); // mitk::DataNode::Pointer node = mitk::DataNode::New(); // node->SetData(m_FAImage); // GetDataStorage()->Add(node); measurementsCalculator = MeasurementsType::New(); measurementsCalculator->SetInput(image ); measurementsCalculator->SetMeasure(MeasurementsType::CA); measurementsCalculator->Update(); MeasurementsType::OutputImageType::Pointer ca = measurementsCalculator->GetOutput(); m_CAImage = mitk::Image::New(); m_CAImage->InitializeByItk(ca.GetPointer()); m_CAImage->SetVolume(ca->GetBufferPointer()); // node = mitk::DataNode::New(); // node->SetData(m_CAImage); // GetDataStorage()->Add(node); measurementsCalculator = MeasurementsType::New(); measurementsCalculator->SetInput(image ); measurementsCalculator->SetMeasure(MeasurementsType::RD); measurementsCalculator->Update(); MeasurementsType::OutputImageType::Pointer rd = measurementsCalculator->GetOutput(); m_RDImage = mitk::Image::New(); m_RDImage->InitializeByItk(rd.GetPointer()); m_RDImage->SetVolume(rd->GetBufferPointer()); // node = mitk::DataNode::New(); // node->SetData(m_CAImage); // GetDataStorage()->Add(node); measurementsCalculator = MeasurementsType::New(); measurementsCalculator->SetInput(image ); measurementsCalculator->SetMeasure(MeasurementsType::AD); measurementsCalculator->Update(); MeasurementsType::OutputImageType::Pointer ad = measurementsCalculator->GetOutput(); m_ADImage = mitk::Image::New(); m_ADImage->InitializeByItk(ad.GetPointer()); m_ADImage->SetVolume(ad->GetBufferPointer()); // node = mitk::DataNode::New(); // node->SetData(m_CAImage); // GetDataStorage()->Add(node); measurementsCalculator = MeasurementsType::New(); measurementsCalculator->SetInput(image ); measurementsCalculator->SetMeasure(MeasurementsType::RA); measurementsCalculator->Update(); MeasurementsType::OutputImageType::Pointer md = measurementsCalculator->GetOutput(); m_MDImage = mitk::Image::New(); m_MDImage->InitializeByItk(md.GetPointer()); m_MDImage->SetVolume(md->GetBufferPointer()); // node = mitk::DataNode::New(); // node->SetData(m_CAImage); // GetDataStorage()->Add(node); typedef DirectionsFilterType::PeakImageType DirImageType; DirectionsFilterType::Pointer dirFilter = DirectionsFilterType::New(); dirFilter->SetInput(image ); dirFilter->SetUsePolarCoordinates(true); dirFilter->Update(); ItkUcharImgType::Pointer numDirImage = dirFilter->GetOutput(); DirImageType::Pointer dirImage = dirFilter->GetPeakImage(); itk::ImageRegionIterator itd(dirImage, dirImage->GetLargestPossibleRegion()); - itd = itd.Begin(); + itd.GoToBegin(); while( !itd.IsAtEnd() ) { DirImageType::PixelType direction = itd.Get(); direction = fabs(direction); itd.Set(direction); ++itd; } typedef itk::Image CompImageType; CompImageType::Pointer comp1 = CompImageType::New(); comp1->SetSpacing( numDirImage->GetSpacing() ); // Set the image spacing comp1->SetOrigin( numDirImage->GetOrigin() ); // Set the image origin comp1->SetDirection( numDirImage->GetDirection() ); // Set the image direction comp1->SetRegions( numDirImage->GetLargestPossibleRegion() ); comp1->Allocate(); CompImageType::Pointer comp2 = CompImageType::New(); comp2->SetSpacing( numDirImage->GetSpacing() ); // Set the image spacing comp2->SetOrigin( numDirImage->GetOrigin() ); // Set the image origin comp2->SetDirection( numDirImage->GetDirection() ); // Set the image direction comp2->SetRegions( numDirImage->GetLargestPossibleRegion() ); comp2->Allocate(); itk::ImageRegionIterator it1(comp1, comp1->GetLargestPossibleRegion()); itk::ImageRegionIterator it2(comp2, comp2->GetLargestPossibleRegion()); - it1 = it1.Begin(); - it2 = it2.Begin(); + it1.GoToBegin(); + it2.GoToBegin(); while( !it2.IsAtEnd() ) { DirImageType::IndexType peakIndex; peakIndex[0] = it1.GetIndex()[0]; peakIndex[1] = it1.GetIndex()[1]; peakIndex[2] = it1.GetIndex()[2]; peakIndex[3] = 1; it1.Set(dirImage->GetPixel(peakIndex)); peakIndex[3] = 2; it2.Set(dirImage->GetPixel(peakIndex)); ++it1; ++it2; } m_DirectionComp1Image = mitk::Image::New(); m_DirectionComp1Image->InitializeByItk(comp1.GetPointer()); m_DirectionComp1Image->SetVolume(comp1->GetBufferPointer()); m_DirectionComp2Image = mitk::Image::New(); m_DirectionComp2Image->InitializeByItk(comp2.GetPointer()); m_DirectionComp2Image->SetVolume(comp2->GetBufferPointer()); } void QmitkPartialVolumeAnalysisView::OnRenderWindowDelete(QObject * obj) { if(obj == m_LastRenderWindow) m_LastRenderWindow = 0; if(obj == m_SelectedRenderWindow) m_SelectedRenderWindow = 0; } bool QmitkPartialVolumeAnalysisView::event( QEvent *event ) { if ( event->type() == (QEvent::Type) QmitkRequestStatisticsUpdateEvent::StatisticsUpdateRequest ) { // Update statistics m_StatisticsUpdatePending = false; this->UpdateStatistics(); return true; } return false; } void QmitkPartialVolumeAnalysisView::Activated() { mitk::DataStorage::SetOfObjects::ConstPointer _NodeSet = this->GetDataStorage()->GetAll(); mitk::DataNode* node = 0; mitk::PlanarFigure* figure = 0; mitk::PlanarFigureInteractor::Pointer figureInteractor = 0; // finally add all nodes to the model for(mitk::DataStorage::SetOfObjects::ConstIterator it=_NodeSet->Begin(); it!=_NodeSet->End() ; it++) { node = const_cast(it->Value().GetPointer()); figure = dynamic_cast(node->GetData()); if(figure) { figureInteractor = dynamic_cast(node->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( node ); } } } } void QmitkPartialVolumeAnalysisView::Deactivated() { } -void QmitkPartialVolumeAnalysisView::ActivatedZombieView(berry::IWorkbenchPartReference::Pointer reference) +void QmitkPartialVolumeAnalysisView::ActivatedZombieView(berry::IWorkbenchPartReference::Pointer) { this->SetMeasurementInfoToRenderWindow(""); mitk::DataStorage::SetOfObjects::ConstPointer _NodeSet = this->GetDataStorage()->GetAll(); mitk::DataNode* node = 0; mitk::PlanarFigure* figure = 0; mitk::PlanarFigureInteractor::Pointer figureInteractor = 0; // finally add all nodes to the model for(mitk::DataStorage::SetOfObjects::ConstIterator it=_NodeSet->Begin(); it!=_NodeSet->End() ; it++) { node = const_cast(it->Value().GetPointer()); figure = dynamic_cast(node->GetData()); if(figure) { figureInteractor = dynamic_cast(node->GetDataInteractor().GetPointer()); if(figureInteractor) figureInteractor->SetDataNode( nullptr ); } } } void QmitkPartialVolumeAnalysisView::Hidden() { if (m_ClusteringResult.IsNotNull()) { this->GetDataStorage()->Remove(m_ClusteringResult); mitk::RenderingManager::GetInstance()->RequestUpdateAll(); } Select(nullptr, true, true); m_Visible = false; } void QmitkPartialVolumeAnalysisView::Visible() { m_Visible = true; berry::IWorkbenchPart::Pointer bla; if (!this->GetCurrentSelection().empty()) { this->OnSelectionChanged(bla, this->GetCurrentSelection()); } else { this->OnSelectionChanged(bla, this->GetDataManagerSelection()); } } void QmitkPartialVolumeAnalysisView::GreenRadio(bool checked) { if(checked) { m_Controls->m_PartialVolumeRadio->setChecked(false); m_Controls->m_BlueRadio->setChecked(false); m_Controls->m_AllRadio->setChecked(false); m_Controls->m_ExportClusteringResultsButton->setEnabled(true); } m_QuantifyClass = 0; RequestStatisticsUpdate(); } void QmitkPartialVolumeAnalysisView::PartialVolumeRadio(bool checked) { if(checked) { m_Controls->m_GreenRadio->setChecked(false); m_Controls->m_BlueRadio->setChecked(false); m_Controls->m_AllRadio->setChecked(false); m_Controls->m_ExportClusteringResultsButton->setEnabled(true); } m_QuantifyClass = 1; RequestStatisticsUpdate(); } void QmitkPartialVolumeAnalysisView::BlueRadio(bool checked) { if(checked) { m_Controls->m_PartialVolumeRadio->setChecked(false); m_Controls->m_GreenRadio->setChecked(false); m_Controls->m_AllRadio->setChecked(false); m_Controls->m_ExportClusteringResultsButton->setEnabled(true); } m_QuantifyClass = 2; RequestStatisticsUpdate(); } void QmitkPartialVolumeAnalysisView::AllRadio(bool checked) { if(checked) { m_Controls->m_BlueRadio->setChecked(false); m_Controls->m_PartialVolumeRadio->setChecked(false); m_Controls->m_GreenRadio->setChecked(false); m_Controls->m_ExportClusteringResultsButton->setEnabled(false); } m_QuantifyClass = 3; RequestStatisticsUpdate(); } -void QmitkPartialVolumeAnalysisView::NumberBinsChangedSlider(int v ) +void QmitkPartialVolumeAnalysisView::NumberBinsChangedSlider(int) { m_Controls->m_NumberBins->setText(QString("%1").arg(m_Controls->m_NumberBinsSlider->value()*5.0)); } -void QmitkPartialVolumeAnalysisView::UpsamplingChangedSlider( int v) +void QmitkPartialVolumeAnalysisView::UpsamplingChangedSlider(int) { m_Controls->m_Upsampling->setText(QString("%1").arg(m_Controls->m_UpsamplingSlider->value()/10.0)); } -void QmitkPartialVolumeAnalysisView::GaussianSigmaChangedSlider(int v ) +void QmitkPartialVolumeAnalysisView::GaussianSigmaChangedSlider(int) { m_Controls->m_GaussianSigma->setText(QString("%1").arg(m_Controls->m_GaussianSigmaSlider->value()/100.0)); } -void QmitkPartialVolumeAnalysisView::SimilarAnglesChangedSlider(int v ) +void QmitkPartialVolumeAnalysisView::SimilarAnglesChangedSlider(int) { m_Controls->m_SimilarAngles->setText(QString("%1°").arg(90-m_Controls->m_SimilarAnglesSlider->value())); ShowClusteringResults(); } void QmitkPartialVolumeAnalysisView::OpacityChangedSlider(int v ) { if(m_SelectedImageNodes->GetNode().IsNotNull()) { float opacImag = 1.0f-(v-5)/5.0f; opacImag = opacImag < 0 ? 0 : opacImag; m_SelectedImageNodes->GetNode()->SetFloatProperty("opacity", opacImag); mitk::RenderingManager::GetInstance()->RequestUpdateAll(); } if(m_ClusteringResult.IsNotNull()) { float opacClust = v/5.0f; opacClust = opacClust > 1 ? 1 : opacClust; m_ClusteringResult->SetFloatProperty("opacity", opacClust); mitk::RenderingManager::GetInstance()->RequestUpdateAll(); } } void QmitkPartialVolumeAnalysisView::NumberBinsReleasedSlider( ) { RequestStatisticsUpdate(); } void QmitkPartialVolumeAnalysisView::UpsamplingReleasedSlider( ) { RequestStatisticsUpdate(); } void QmitkPartialVolumeAnalysisView::GaussianSigmaReleasedSlider( ) { RequestStatisticsUpdate(); } void QmitkPartialVolumeAnalysisView::SimilarAnglesReleasedSlider( ) { } void QmitkPartialVolumeAnalysisView::ToClipBoard() { std::vector* > vals = m_Controls->m_HistogramWidget->m_Vals; QString clipboardText; for (std::vector* >::iterator it = vals.begin(); it != vals.end(); ++it) { for (std::vector::iterator it2 = (**it).begin(); it2 != (**it).end(); ++it2) { clipboardText.append(QString("%1 \t").arg(*it2)); } clipboardText.append(QString("\n")); } QApplication::clipboard()->setText(clipboardText, QClipboard::Clipboard); } void QmitkPartialVolumeAnalysisView::PropertyChanged(const mitk::DataNode* /*node*/, const mitk::BaseProperty* /*prop*/) { } void QmitkPartialVolumeAnalysisView::NodeChanged(const mitk::DataNode* /*node*/) { } void QmitkPartialVolumeAnalysisView::NodeRemoved(const mitk::DataNode* node) { if (dynamic_cast(node->GetData())) this->GetDataStorage()->Remove(m_ClusteringResult); if( node == m_SelectedPlanarFigureNodes->GetNode().GetPointer() || node == m_SelectedMaskNode.GetPointer() ) { this->Select(nullptr,true,false); SetMeasurementInfoToRenderWindow(""); } if( node == m_SelectedImageNodes->GetNode().GetPointer() ) { this->Select(nullptr,false,true); SetMeasurementInfoToRenderWindow(""); } } void QmitkPartialVolumeAnalysisView::NodeAddedInDataStorage(const mitk::DataNode* node) { if(!m_Visible) return; mitk::DataNode* nonConstNode = const_cast(node); mitk::PlanarFigure* figure = dynamic_cast(nonConstNode->GetData()); if(figure) { // set interactor for new node (if not already set) mitk::PlanarFigureInteractor::Pointer figureInteractor = dynamic_cast(node->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( nonConstNode ); } // remove uninitialized old planars if( m_SelectedPlanarFigureNodes->GetNode().IsNotNull() && m_CurrentFigureNodeInitialized == false ) { this->GetDataStorage()->Remove(m_SelectedPlanarFigureNodes->GetNode()); } } } void QmitkPartialVolumeAnalysisView::TextIntON() { if(m_ClusteringResult.IsNotNull()) { if(m_TexIsOn) { m_Controls->m_TextureIntON->setIcon(*m_IconTexOFF); } else { m_Controls->m_TextureIntON->setIcon(*m_IconTexON); } m_ClusteringResult->SetBoolProperty("texture interpolation", !m_TexIsOn); m_TexIsOn = !m_TexIsOn; this->RequestRenderWindowUpdate(); } } diff --git a/Plugins/org.mitk.gui.qt.diffusionimaging.partialvolume/src/internal/QmitkPartialVolumeAnalysisView.h b/Plugins/org.mitk.gui.qt.diffusionimaging.partialvolume/src/internal/QmitkPartialVolumeAnalysisView.h index 97236bb35a..83c9dd870f 100644 --- a/Plugins/org.mitk.gui.qt.diffusionimaging.partialvolume/src/internal/QmitkPartialVolumeAnalysisView.h +++ b/Plugins/org.mitk.gui.qt.diffusionimaging.partialvolume/src/internal/QmitkPartialVolumeAnalysisView.h @@ -1,273 +1,270 @@ /*=================================================================== 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. ===================================================================*/ #if !defined(QmitkPartialVolumeAnalysisView_H__INCLUDED) #define QmitkPartialVolumeAnalysisView_H__INCLUDED #include "ui_QmitkPartialVolumeAnalysisViewControls.h" #include #include #include // berry #include #include // itk #include #include #include // qmitk #include "QmitkStepperAdapter.h" #include "QmitkRenderWindow.h" // mitk #include "mitkPartialVolumeAnalysisHistogramCalculator.h" #include "mitkPlanarLine.h" #include #include "mitkDataStorageSelection.h" #include // vtk #include #include #include //#include "itkProcessObject.h" /*! \brief QmitkPartialVolumeAnalysis */ class QmitkPartialVolumeAnalysisView : public QmitkAbstractView, public mitk::IZombieViewPart//, public itk::ProcessObject { Q_OBJECT public: /*! \ Convenient typedefs */ typedef mitk::DataStorage::SetOfObjects ConstVector; typedef ConstVector::ConstPointer ConstVectorPointer; typedef ConstVector::ConstIterator ConstVectorIterator; typedef mitk::PartialVolumeAnalysisHistogramCalculator HistogramCalculatorType; typedef HistogramCalculatorType::HistogramType HistogramType; typedef mitk::PartialVolumeAnalysisClusteringCalculator ClusteringType; typedef itk::DiffusionTensorPrincipalDirectionImageFilter DirectionsFilterType; typedef itk::Image ItkUcharImgType; /*! \brief default constructor */ QmitkPartialVolumeAnalysisView(QObject *parent=0, const char *name=0); /*! \brief default destructor */ virtual ~QmitkPartialVolumeAnalysisView(); /*! \brief method for creating the widget containing the application controls, like sliders, buttons etc. */ virtual void CreateQtPartControl(QWidget *parent) override; /*! \brief method for creating the connections of main and control widget */ virtual void CreateConnections(); virtual bool event( QEvent *event ) override; virtual void OnSelectionChanged(berry::IWorkbenchPart::Pointer part, const QList& nodes) override; virtual void Activated() override; virtual void Deactivated() override; virtual void ActivatedZombieView(berry::IWorkbenchPartReference::Pointer reference) override; virtual void Hidden() override; virtual void Visible() override; virtual void SetFocus() override; bool AssertDrawingIsPossible(bool checked); virtual void NodeChanged(const mitk::DataNode* node) override; virtual void PropertyChanged(const mitk::DataNode* node, const mitk::BaseProperty* prop); virtual void NodeRemoved(const mitk::DataNode* node) override; virtual void NodeAddedInDataStorage(const mitk::DataNode* node); virtual void AddFigureToDataStorage(mitk::PlanarFigure* figure, const QString& name, const char *propertyKey = nullptr, mitk::BaseProperty *property = nullptr ); void PlanarFigureInitialized(); void PlanarFigureFocus(mitk::DataNode* node); void ShowClusteringResults(); static const std::string VIEW_ID; protected slots: void EstimateCircle(); void SetHistogramVisibility(); void SetAdvancedVisibility(); void NumberBinsChangedSlider(int v ); void UpsamplingChangedSlider( int v ); void GaussianSigmaChangedSlider( int v ); void SimilarAnglesChangedSlider(int v ); void OpacityChangedSlider(int v ); void NumberBinsReleasedSlider( ); void UpsamplingReleasedSlider( ); void GaussianSigmaReleasedSlider( ); void SimilarAnglesReleasedSlider( ); void ActionDrawEllipseTriggered(); void ActionDrawRectangleTriggered(); void ActionDrawPolygonTriggered(); void ToClipBoard(); void GreenRadio(bool checked); void PartialVolumeRadio(bool checked); void BlueRadio(bool checked); void AllRadio(bool checked); void OnRenderWindowDelete(QObject * obj); void TextIntON(); void ExportClusteringResults(); protected: /** \brief Issues a request to update statistics by sending an event to the * Qt event processing queue. * * Statistics update should only be executed after program execution returns * to the Qt main loop. This mechanism also prevents multiple execution of * updates where only one is required.*/ void RequestStatisticsUpdate(); /** \brief Recalculate statistics for currently selected image and mask and * update the GUI. */ void UpdateStatistics(); /** \brief Listener for progress events to update progress bar. */ void UpdateProgressBar(); /** \brief Removes any cached images which are no longer referenced elsewhere. */ void RemoveOrphanImages(); void Select( mitk::DataNode::Pointer node, bool clearMaskOnFirstArgnullptr=false, bool clearImageOnFirstArgnullptr=false ); void SetMeasurementInfoToRenderWindow(const QString& text); void FindRenderWindow(mitk::DataNode* node); void ExtractTensorImages( mitk::Image::Pointer tensorimage); typedef std::map< mitk::Image *, mitk::PartialVolumeAnalysisHistogramCalculator::Pointer > PartialVolumeAnalysisMapType; /*! * controls containing sliders for scrolling through the slices */ Ui::QmitkPartialVolumeAnalysisViewControls *m_Controls; QmitkStepperAdapter* m_TimeStepperAdapter; unsigned int m_CurrentTime; QString m_Clipboard; // result text rendering vtkRenderer * m_MeasurementInfoRenderer; vtkCornerAnnotation *m_MeasurementInfoAnnotation; // Image and mask data mitk::DataStorageSelection::Pointer m_SelectedImageNodes; mitk::Image::Pointer m_SelectedImage; mitk::DataNode::Pointer m_SelectedMaskNode; mitk::Image::Pointer m_SelectedImageMask; mitk::DataStorageSelection::Pointer m_SelectedPlanarFigureNodes; mitk::PlanarFigure::Pointer m_SelectedPlanarFigure; bool m_IsTensorImage; mitk::Image::Pointer m_FAImage; mitk::Image::Pointer m_CAImage; mitk::Image::Pointer m_RDImage; mitk::Image::Pointer m_ADImage; mitk::Image::Pointer m_MDImage; -// mitk::Image::Pointer m_DirectionImage; mitk::Image::Pointer m_DirectionComp1Image; mitk::Image::Pointer m_DirectionComp2Image; mitk::Image::Pointer m_AngularErrorImage; QmitkRenderWindow* m_SelectedRenderWindow; QmitkRenderWindow* m_LastRenderWindow; long m_ImageObserverTag; long m_ImageMaskObserverTag; long m_PlanarFigureObserverTag; // Hash map for associating one image statistics calculator with each iamge // (so that previously calculated histograms / statistics can be recovered // if a recalculation is not required) PartialVolumeAnalysisMapType m_PartialVolumeAnalysisMap; HistogramCalculatorType::Pointer m_CurrentStatisticsCalculator; bool m_CurrentStatisticsValid; bool m_StatisticsUpdatePending; bool m_GaussianSigmaChangedSliding; bool m_NumberBinsSliding; bool m_UpsamplingChangedSliding; - bool m_Visible; - mitk::DataNode::Pointer m_ClusteringResult; int m_EllipseCounter; int m_RectangleCounter; int m_PolygonCounter; - unsigned int m_InitializedObserverTag; + long m_InitializedObserverTag; bool m_CurrentFigureNodeInitialized; int m_QuantifyClass; ClusteringType::HelperStructPerformRGBClusteringRetval* m_CurrentRGBClusteringResults; ClusteringType::HelperStructPerformClusteringRetval *m_CurrentPerformClusteringResults; -// mitk::DataNode::Pointer m_newnode; -// mitk::DataNode::Pointer m_newnode2; QIcon* m_IconTexOFF; QIcon* m_IconTexON; bool m_TexIsOn; + + bool m_Visible; }; -#endif // !defined(QmitkPartialVolumeAnalysis_H__INCLUDED) +#endif