diff --git a/Modules/Segmentation/Interactions/mitkSegTool2D.cpp b/Modules/Segmentation/Interactions/mitkSegTool2D.cpp index fbfc99fdec..3588f953dc 100644 --- a/Modules/Segmentation/Interactions/mitkSegTool2D.cpp +++ b/Modules/Segmentation/Interactions/mitkSegTool2D.cpp @@ -1,465 +1,468 @@ /*=================================================================== 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 "mitkSegTool2D.h" #include "mitkToolManager.h" #include "mitkDataStorage.h" #include "mitkBaseRenderer.h" #include "mitkPlaneGeometry.h" #include "mitkExtractImageFilter.h" #include "mitkExtractDirectedPlaneImageFilter.h" //Include of the new ImageExtractor #include "mitkExtractDirectedPlaneImageFilterNew.h" #include "mitkPlanarCircle.h" #include "mitkOverwriteSliceImageFilter.h" #include "mitkOverwriteDirectedPlaneImageFilter.h" #include "mitkMorphologicalOperations.h" #include "usGetModuleContext.h" //Includes for 3DSurfaceInterpolation #include "mitkImageToContourFilter.h" #include "mitkSurfaceInterpolationController.h" //includes for resling and overwriting #include #include #include #include #include #include "mitkOperationEvent.h" #include "mitkUndoController.h" #include "mitkAbstractTransformGeometry.h" #define ROUND(a) ((a)>0 ? (int)((a)+0.5) : -(int)(0.5-(a))) bool mitk::SegTool2D::m_SurfaceInterpolationEnabled = true; mitk::SegTool2D::SegTool2D(const char* type) :Tool(type), m_LastEventSender(NULL), m_LastEventSlice(0), m_Contourmarkername ("Position"), m_ShowMarkerNodes (false) { } mitk::SegTool2D::~SegTool2D() { } float mitk::SegTool2D::CanHandleEvent( InteractionEvent const *stateEvent) const { const InteractionPositionEvent* positionEvent = dynamic_cast( stateEvent ); if (!positionEvent) return 0.0; if ( positionEvent->GetSender()->GetMapperID() != BaseRenderer::Standard2D ) return 0.0; // we don't want anything but 2D return 1.0; } bool mitk::SegTool2D::DetermineAffectedImageSlice( const Image* image, const PlaneGeometry* plane, int& affectedDimension, int& affectedSlice ) { assert(image); assert(plane); // compare normal of plane to the three axis vectors of the image Vector3D normal = plane->GetNormal(); Vector3D imageNormal0 = image->GetSlicedGeometry()->GetAxisVector(0); Vector3D imageNormal1 = image->GetSlicedGeometry()->GetAxisVector(1); Vector3D imageNormal2 = image->GetSlicedGeometry()->GetAxisVector(2); normal.Normalize(); imageNormal0.Normalize(); imageNormal1.Normalize(); imageNormal2.Normalize(); imageNormal0.SetVnlVector( vnl_cross_3d(normal.GetVnlVector(),imageNormal0.GetVnlVector()) ); imageNormal1.SetVnlVector( vnl_cross_3d(normal.GetVnlVector(),imageNormal1.GetVnlVector()) ); imageNormal2.SetVnlVector( vnl_cross_3d(normal.GetVnlVector(),imageNormal2.GetVnlVector()) ); double eps( 0.00001 ); // axial if ( imageNormal2.GetNorm() <= eps ) { affectedDimension = 2; } // sagittal else if ( imageNormal1.GetNorm() <= eps ) { affectedDimension = 1; } // frontal else if ( imageNormal0.GetNorm() <= eps ) { affectedDimension = 0; } else { affectedDimension = -1; // no idea return false; } // determine slice number in image BaseGeometry* imageGeometry = image->GetGeometry(0); Point3D testPoint = imageGeometry->GetCenter(); Point3D projectedPoint; plane->Project( testPoint, projectedPoint ); Point3D indexPoint; imageGeometry->WorldToIndex( projectedPoint, indexPoint ); affectedSlice = ROUND( indexPoint[affectedDimension] ); MITK_DEBUG << "indexPoint " << indexPoint << " affectedDimension " << affectedDimension << " affectedSlice " << affectedSlice; // check if this index is still within the image if ( affectedSlice < 0 || affectedSlice >= static_cast(image->GetDimension(affectedDimension)) ) return false; return true; } void mitk::SegTool2D::UpdateSurfaceInterpolation (const Image* slice, const Image* workingImage, const PlaneGeometry *plane, bool detectIntersection) { if (!m_SurfaceInterpolationEnabled) return; ImageToContourFilter::Pointer contourExtractor = ImageToContourFilter::New(); mitk::Surface::Pointer contour; if (detectIntersection) { // Test whether there is something to extract or whether the slice just contains intersections of others mitk::Image::Pointer slice2 = slice->Clone(); mitk::MorphologicalOperations::Erode(slice2, 2, mitk::MorphologicalOperations::Ball); contourExtractor->SetInput(slice2); contourExtractor->Update(); contour = contourExtractor->GetOutput(); if (contour->GetVtkPolyData()->GetNumberOfPoints() == 0) { // Remove contour! - mitk::SurfaceInterpolationController::GetInstance()->RemoveContour(plane); + mitk::SurfaceInterpolationController::ContourPositionInformation contourInfo; + contourInfo.contourNormal = plane->GetNormal(); + contourInfo.contourPoint = plane->GetOrigin(); + mitk::SurfaceInterpolationController::GetInstance()->RemoveContour(contourInfo); return; } } contourExtractor->SetInput(slice); contourExtractor->Update(); contour = contourExtractor->GetOutput(); if (contour->GetVtkPolyData()->GetNumberOfPoints() != 0 && workingImage->GetDimension() == 3) { - mitk::SurfaceInterpolationController::GetInstance()->AddNewContour( contour, plane); + mitk::SurfaceInterpolationController::GetInstance()->AddNewContour( contour ); contour->DisconnectPipeline(); } else { // Remove contour! - mitk::SurfaceInterpolationController::GetInstance()->RemoveContour(plane); + mitk::SurfaceInterpolationController::ContourPositionInformation contourInfo; + contourInfo.contourNormal = plane->GetNormal(); + contourInfo.contourPoint = plane->GetOrigin(); + mitk::SurfaceInterpolationController::GetInstance()->RemoveContour(contourInfo); } } mitk::Image::Pointer mitk::SegTool2D::GetAffectedImageSliceAs2DImage(const InteractionPositionEvent* positionEvent, const Image* image) { if (!positionEvent) return NULL; assert( positionEvent->GetSender() ); // sure, right? unsigned int timeStep = positionEvent->GetSender()->GetTimeStep( image ); // get the timestep of the visible part (time-wise) of the image // first, we determine, which slice is affected const PlaneGeometry* planeGeometry( dynamic_cast (positionEvent->GetSender()->GetCurrentWorldPlaneGeometry() ) ); return this->GetAffectedImageSliceAs2DImage(planeGeometry, image, timeStep); } mitk::Image::Pointer mitk::SegTool2D::GetAffectedImageSliceAs2DImage(const PlaneGeometry* planeGeometry, const Image* image, unsigned int timeStep) { if ( !image || !planeGeometry ) return NULL; //Make sure that for reslicing and overwriting the same alogrithm is used. We can specify the mode of the vtk reslicer vtkSmartPointer reslice = vtkSmartPointer::New(); //set to false to extract a slice reslice->SetOverwriteMode(false); reslice->Modified(); //use ExtractSliceFilter with our specific vtkImageReslice for overwriting and extracting mitk::ExtractSliceFilter::Pointer extractor = mitk::ExtractSliceFilter::New(reslice); extractor->SetInput( image ); extractor->SetTimeStep( timeStep ); extractor->SetWorldGeometry( planeGeometry ); extractor->SetVtkOutputRequest(false); extractor->SetResliceTransformByGeometry( image->GetTimeGeometry()->GetGeometryForTimeStep( timeStep ) ); extractor->Modified(); extractor->Update(); Image::Pointer slice = extractor->GetOutput(); /*============= BEGIN undo feature block ========================*/ //specify the undo operation with the non edited slice m_undoOperation = new DiffSliceOperation(const_cast(image), extractor->GetVtkOutput(), dynamic_cast(slice->GetGeometry()), timeStep, const_cast(planeGeometry)); /*============= END undo feature block ========================*/ return slice; } mitk::Image::Pointer mitk::SegTool2D::GetAffectedWorkingSlice(const InteractionPositionEvent* positionEvent) { DataNode* workingNode( m_ToolManager->GetWorkingData(0) ); if ( !workingNode ) return NULL; Image* workingImage = dynamic_cast(workingNode->GetData()); if ( !workingImage ) return NULL; return GetAffectedImageSliceAs2DImage( positionEvent, workingImage ); } mitk::Image::Pointer mitk::SegTool2D::GetAffectedReferenceSlice(const InteractionPositionEvent* positionEvent) { DataNode* referenceNode( m_ToolManager->GetReferenceData(0) ); if ( !referenceNode ) return NULL; Image* referenceImage = dynamic_cast(referenceNode->GetData()); if ( !referenceImage ) return NULL; return GetAffectedImageSliceAs2DImage( positionEvent, referenceImage ); } void mitk::SegTool2D::WriteBackSegmentationResult (const InteractionPositionEvent* positionEvent, Image* slice) { if(!positionEvent) return; const PlaneGeometry* planeGeometry( dynamic_cast (positionEvent->GetSender()->GetCurrentWorldPlaneGeometry() ) ); const AbstractTransformGeometry* abstractTransformGeometry( dynamic_cast (positionEvent->GetSender()->GetCurrentWorldPlaneGeometry() ) ); if( planeGeometry && slice && !abstractTransformGeometry) { DataNode* workingNode( m_ToolManager->GetWorkingData(0) ); Image* image = dynamic_cast(workingNode->GetData()); unsigned int timeStep = positionEvent->GetSender()->GetTimeStep( image ); this->WriteBackSegmentationResult(planeGeometry, slice, timeStep); } } void mitk::SegTool2D::WriteBackSegmentationResult (const PlaneGeometry* planeGeometry, Image* slice, unsigned int timeStep) { if(!planeGeometry || !slice) return; SliceInformation sliceInfo (slice, const_cast(planeGeometry), timeStep); this->WriteSliceToVolume(sliceInfo); DataNode* workingNode( m_ToolManager->GetWorkingData(0) ); Image* image = dynamic_cast(workingNode->GetData()); this->UpdateSurfaceInterpolation(slice, image, planeGeometry, false); mitk::RenderingManager::GetInstance()->RequestUpdateAll(); } void mitk::SegTool2D::WriteBackSegmentationResult(std::vector sliceList) { - mitk::SurfaceInterpolationController::ContourPositionPairList contourList; + std::vector contourList; contourList.reserve(sliceList.size()); ImageToContourFilter::Pointer contourExtractor = ImageToContourFilter::New(); DataNode* workingNode( m_ToolManager->GetWorkingData(0) ); Image* image = dynamic_cast(workingNode->GetData()); for (unsigned int i = 0; i < sliceList.size(); ++i) { SliceInformation currentSliceInfo = sliceList.at(i); this->WriteSliceToVolume(currentSliceInfo); if (m_SurfaceInterpolationEnabled && image->GetDimension() == 3) { currentSliceInfo.slice->DisconnectPipeline(); contourExtractor->SetInput(currentSliceInfo.slice); contourExtractor->Update(); mitk::Surface::Pointer contour = contourExtractor->GetOutput(); contour->DisconnectPipeline(); - mitk::SurfaceInterpolationController::ContourPositionPair pair; - pair.contour = contour; - pair.plane = currentSliceInfo.plane;; - contourList.push_back(pair); + contourList.push_back(contour); } } mitk::SurfaceInterpolationController::GetInstance()->AddNewContours(contourList); mitk::RenderingManager::GetInstance()->RequestUpdateAll(); } void mitk::SegTool2D::WriteSliceToVolume(mitk::SegTool2D::SliceInformation sliceInfo) { DataNode* workingNode( m_ToolManager->GetWorkingData(0) ); Image* image = dynamic_cast(workingNode->GetData()); //Make sure that for reslicing and overwriting the same alogrithm is used. We can specify the mode of the vtk reslicer vtkSmartPointer reslice = vtkSmartPointer::New(); //Set the slice as 'input' reslice->SetInputSlice(sliceInfo.slice->GetVtkImageData()); //set overwrite mode to true to write back to the image volume reslice->SetOverwriteMode(true); reslice->Modified(); mitk::ExtractSliceFilter::Pointer extractor = mitk::ExtractSliceFilter::New(reslice); extractor->SetInput( image ); extractor->SetTimeStep( sliceInfo.timestep ); extractor->SetWorldGeometry( sliceInfo.plane ); extractor->SetVtkOutputRequest(true); extractor->SetResliceTransformByGeometry( image->GetGeometry( sliceInfo.timestep ) ); extractor->Modified(); extractor->Update(); //the image was modified within the pipeline, but not marked so image->Modified(); image->GetVtkImageData()->Modified(); /*============= BEGIN undo feature block ========================*/ //specify the undo operation with the edited slice m_doOperation = new DiffSliceOperation(image, extractor->GetVtkOutput(),dynamic_cast(sliceInfo.slice->GetGeometry()), sliceInfo.timestep, sliceInfo.plane); //create an operation event for the undo stack OperationEvent* undoStackItem = new OperationEvent( DiffSliceOperationApplier::GetInstance(), m_doOperation, m_undoOperation, "Segmentation" ); //add it to the undo controller UndoController::GetCurrentUndoModel()->SetOperationEvent( undoStackItem ); //clear the pointers as the operation are stored in the undocontroller and also deleted from there m_undoOperation = NULL; m_doOperation = NULL; /*============= END undo feature block ========================*/ } void mitk::SegTool2D::SetShowMarkerNodes(bool status) { m_ShowMarkerNodes = status; } void mitk::SegTool2D::SetEnable3DInterpolation(bool enabled) { m_SurfaceInterpolationEnabled = enabled; } unsigned int mitk::SegTool2D::AddContourmarker() { us::ServiceReference serviceRef = us::GetModuleContext()->GetServiceReference(); PlanePositionManagerService* service = us::GetModuleContext()->GetService(serviceRef); unsigned int slicePosition = m_LastEventSender->GetSliceNavigationController()->GetSlice()->GetPos(); // the first geometry is needed otherwise restoring the position is not working const mitk::PlaneGeometry* plane = dynamic_cast (dynamic_cast< const mitk::SlicedGeometry3D*>( m_LastEventSender->GetSliceNavigationController()->GetCurrentGeometry3D())->GetPlaneGeometry(0)); unsigned int size = service->GetNumberOfPlanePositions(); unsigned int id = service->AddNewPlanePosition(plane, slicePosition); mitk::PlanarCircle::Pointer contourMarker = mitk::PlanarCircle::New(); mitk::Point2D p1; plane->Map(plane->GetCenter(), p1); mitk::Point2D p2 = p1; p2[0] -= plane->GetSpacing()[0]; p2[1] -= plane->GetSpacing()[1]; contourMarker->PlaceFigure( p1 ); contourMarker->SetCurrentControlPoint( p1 ); contourMarker->SetPlaneGeometry( const_cast(plane)); std::stringstream markerStream; mitk::DataNode* workingNode (m_ToolManager->GetWorkingData(0)); markerStream << m_Contourmarkername ; markerStream << " "; markerStream << id+1; DataNode::Pointer rotatedContourNode = DataNode::New(); rotatedContourNode->SetData(contourMarker); rotatedContourNode->SetProperty( "name", StringProperty::New(markerStream.str()) ); rotatedContourNode->SetProperty( "isContourMarker", BoolProperty::New(true)); rotatedContourNode->SetBoolProperty( "PlanarFigureInitializedWindow", true, m_LastEventSender ); rotatedContourNode->SetProperty( "includeInBoundingBox", BoolProperty::New(false)); rotatedContourNode->SetProperty( "helper object", mitk::BoolProperty::New(!m_ShowMarkerNodes)); rotatedContourNode->SetProperty( "planarfigure.drawcontrolpoints", BoolProperty::New(false)); rotatedContourNode->SetProperty( "planarfigure.drawname", BoolProperty::New(false)); rotatedContourNode->SetProperty( "planarfigure.drawoutline", BoolProperty::New(false)); rotatedContourNode->SetProperty( "planarfigure.drawshadow", BoolProperty::New(false)); if (plane) { if ( id == size ) { m_ToolManager->GetDataStorage()->Add(rotatedContourNode, workingNode); } else { mitk::NodePredicateProperty::Pointer isMarker = mitk::NodePredicateProperty::New("isContourMarker", mitk::BoolProperty::New(true)); mitk::DataStorage::SetOfObjects::ConstPointer markers = m_ToolManager->GetDataStorage()->GetDerivations(workingNode,isMarker); for ( mitk::DataStorage::SetOfObjects::const_iterator iter = markers->begin(); iter != markers->end(); ++iter) { std::string nodeName = (*iter)->GetName(); unsigned int t = nodeName.find_last_of(" "); unsigned int markerId = atof(nodeName.substr(t+1).c_str())-1; if(id == markerId) { return id; } } m_ToolManager->GetDataStorage()->Add(rotatedContourNode, workingNode); } } return id; } void mitk::SegTool2D::InteractiveSegmentationBugMessage( const std::string& message ) { MITK_ERROR << "********************************************************************************" << std::endl << " " << message << std::endl << "********************************************************************************" << std::endl << " " << std::endl << " If your image is rotated or the 2D views don't really contain the patient image, try to press the button next to the image selection. " << std::endl << " " << std::endl << " Please file a BUG REPORT: " << std::endl << " http://bugs.mitk.org" << std::endl << " Contain the following information:" << std::endl << " - What image were you working on?" << std::endl << " - Which region of the image?" << std::endl << " - Which tool did you use?" << std::endl << " - What did you do?" << std::endl << " - What happened (not)? What did you expect?" << std::endl; } diff --git a/Modules/SegmentationUI/Qmitk/QmitkSlicesInterpolator.cpp b/Modules/SegmentationUI/Qmitk/QmitkSlicesInterpolator.cpp index 578e0fde36..77c7ee898f 100644 --- a/Modules/SegmentationUI/Qmitk/QmitkSlicesInterpolator.cpp +++ b/Modules/SegmentationUI/Qmitk/QmitkSlicesInterpolator.cpp @@ -1,1088 +1,1123 @@ /*=================================================================== 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 "QmitkSlicesInterpolator.h" #include "QmitkStdMultiWidget.h" #include "QmitkSelectableGLWidget.h" #include "mitkToolManager.h" #include "mitkDataNodeFactory.h" #include "mitkLevelWindowProperty.h" #include "mitkColorProperty.h" #include "mitkProperties.h" #include "mitkRenderingManager.h" #include "mitkOverwriteSliceImageFilter.h" #include "mitkProgressBar.h" #include "mitkGlobalInteraction.h" #include "mitkOperationEvent.h" #include "mitkUndoController.h" #include "mitkInteractionConst.h" #include "mitkApplyDiffImageOperation.h" #include "mitkDiffImageApplier.h" #include "mitkSegTool2D.h" #include "mitkCoreObjectFactory.h" #include "mitkSurfaceToImageFilter.h" #include "mitkSliceNavigationController.h" #include #include #include #include #include #include #include #include #include #include #include //#define ROUND(a) ((a)>0 ? (int)((a)+0.5) : -(int)(0.5-(a))) const std::map QmitkSlicesInterpolator::createActionToSliceDimension() { std::map actionToSliceDimension; foreach(mitk::SliceNavigationController* slicer, m_ControllerToDeleteObserverTag.keys()) { actionToSliceDimension[new QAction(QString::fromStdString(slicer->GetViewDirectionAsString()),0)] = slicer; } return actionToSliceDimension; } QmitkSlicesInterpolator::QmitkSlicesInterpolator(QWidget* parent, const char* /*name*/) :QWidget(parent), // ACTION_TO_SLICEDIMENSION( createActionToSliceDimension() ), m_Interpolator( mitk::SegmentationInterpolationController::New() ), m_SurfaceInterpolator(mitk::SurfaceInterpolationController::GetInstance()), m_ToolManager(NULL), m_Initialized(false), m_LastSNC(0), m_LastSliceIndex(0), m_2DInterpolationEnabled(false), m_3DInterpolationEnabled(false) { m_GroupBoxEnableExclusiveInterpolationMode = new QGroupBox("Interpolation", this); QVBoxLayout* vboxLayout = new QVBoxLayout(m_GroupBoxEnableExclusiveInterpolationMode); m_CmbInterpolation = new QComboBox(m_GroupBoxEnableExclusiveInterpolationMode); m_CmbInterpolation->addItem("Disabled"); m_CmbInterpolation->addItem("2-Dimensional"); m_CmbInterpolation->addItem("3-Dimensional"); vboxLayout->addWidget(m_CmbInterpolation); m_BtnApply2D = new QPushButton("Confirm for single slice", m_GroupBoxEnableExclusiveInterpolationMode); vboxLayout->addWidget(m_BtnApply2D); m_BtnApplyForAllSlices2D = new QPushButton("Confirm for all slices", m_GroupBoxEnableExclusiveInterpolationMode); vboxLayout->addWidget(m_BtnApplyForAllSlices2D); m_BtnApply3D = new QPushButton("Confirm", m_GroupBoxEnableExclusiveInterpolationMode); vboxLayout->addWidget(m_BtnApply3D); + m_BtnReinit3DInterpolation = new QPushButton("Reinit Interpolation", m_GroupBoxEnableExclusiveInterpolationMode); + vboxLayout->addWidget(m_BtnReinit3DInterpolation); + m_ChkShowPositionNodes = new QCheckBox("Show Position Nodes", m_GroupBoxEnableExclusiveInterpolationMode); vboxLayout->addWidget(m_ChkShowPositionNodes); + this->HideAllInterpolationControls(); connect(m_CmbInterpolation, SIGNAL(currentIndexChanged(int)), this, SLOT(OnInterpolationMethodChanged(int))); connect(m_BtnApply2D, SIGNAL(clicked()), this, SLOT(OnAcceptInterpolationClicked())); connect(m_BtnApplyForAllSlices2D, SIGNAL(clicked()), this, SLOT(OnAcceptAllInterpolationsClicked())); connect(m_BtnApply3D, SIGNAL(clicked()), this, SLOT(OnAccept3DInterpolationClicked())); + connect(m_BtnReinit3DInterpolation, SIGNAL(clicked()), this, SLOT(OnReinit3DInterpolation())); connect(m_ChkShowPositionNodes, SIGNAL(toggled(bool)), this, SLOT(OnShowMarkers(bool))); connect(m_ChkShowPositionNodes, SIGNAL(toggled(bool)), this, SIGNAL(SignalShowMarkerNodes(bool))); QHBoxLayout* layout = new QHBoxLayout(this); layout->addWidget(m_GroupBoxEnableExclusiveInterpolationMode); this->setLayout(layout); itk::ReceptorMemberCommand::Pointer command = itk::ReceptorMemberCommand::New(); command->SetCallbackFunction( this, &QmitkSlicesInterpolator::OnInterpolationInfoChanged ); InterpolationInfoChangedObserverTag = m_Interpolator->AddObserver( itk::ModifiedEvent(), command ); itk::ReceptorMemberCommand::Pointer command2 = itk::ReceptorMemberCommand::New(); command2->SetCallbackFunction( this, &QmitkSlicesInterpolator::OnSurfaceInterpolationInfoChanged ); SurfaceInterpolationInfoChangedObserverTag = m_SurfaceInterpolator->AddObserver( itk::ModifiedEvent(), command2 ); // feedback node and its visualization properties m_FeedbackNode = mitk::DataNode::New(); mitk::CoreObjectFactory::GetInstance()->SetDefaultProperties( m_FeedbackNode ); m_FeedbackNode->SetProperty( "binary", mitk::BoolProperty::New(true) ); m_FeedbackNode->SetProperty( "outline binary", mitk::BoolProperty::New(true) ); m_FeedbackNode->SetProperty( "color", mitk::ColorProperty::New(255.0, 255.0, 0.0) ); m_FeedbackNode->SetProperty( "texture interpolation", mitk::BoolProperty::New(false) ); m_FeedbackNode->SetProperty( "layer", mitk::IntProperty::New( 20 ) ); m_FeedbackNode->SetProperty( "levelwindow", mitk::LevelWindowProperty::New( mitk::LevelWindow(0, 1) ) ); m_FeedbackNode->SetProperty( "name", mitk::StringProperty::New("Interpolation feedback") ); m_FeedbackNode->SetProperty( "opacity", mitk::FloatProperty::New(0.8) ); m_FeedbackNode->SetProperty( "helper object", mitk::BoolProperty::New(true) ); m_InterpolatedSurfaceNode = mitk::DataNode::New(); m_InterpolatedSurfaceNode->SetProperty( "color", mitk::ColorProperty::New(255.0,255.0,0.0) ); m_InterpolatedSurfaceNode->SetProperty( "name", mitk::StringProperty::New("Surface Interpolation feedback") ); m_InterpolatedSurfaceNode->SetProperty( "opacity", mitk::FloatProperty::New(0.5) ); m_InterpolatedSurfaceNode->SetProperty( "includeInBoundingBox", mitk::BoolProperty::New(false)); m_InterpolatedSurfaceNode->SetProperty( "helper object", mitk::BoolProperty::New(true) ); m_InterpolatedSurfaceNode->SetVisibility(false); m_3DContourNode = mitk::DataNode::New(); m_3DContourNode->SetProperty( "color", mitk::ColorProperty::New(0.0, 0.0, 0.0) ); - m_3DContourNode->SetProperty("helper object", mitk::BoolProperty::New(true)); + m_3DContourNode->SetProperty("hidden object", mitk::BoolProperty::New(true)); m_3DContourNode->SetProperty( "name", mitk::StringProperty::New("Drawn Contours") ); m_3DContourNode->SetProperty("material.representation", mitk::VtkRepresentationProperty::New(VTK_WIREFRAME)); m_3DContourNode->SetProperty("material.wireframeLineWidth", mitk::FloatProperty::New(2.0f)); m_3DContourNode->SetProperty("3DContourContainer", mitk::BoolProperty::New(true)); m_3DContourNode->SetProperty( "includeInBoundingBox", mitk::BoolProperty::New(false)); m_3DContourNode->SetVisibility(false, mitk::BaseRenderer::GetInstance( mitk::BaseRenderer::GetRenderWindowByName("stdmulti.widget1"))); m_3DContourNode->SetVisibility(false, mitk::BaseRenderer::GetInstance( mitk::BaseRenderer::GetRenderWindowByName("stdmulti.widget2"))); m_3DContourNode->SetVisibility(false, mitk::BaseRenderer::GetInstance( mitk::BaseRenderer::GetRenderWindowByName("stdmulti.widget3"))); m_3DContourNode->SetVisibility(false, mitk::BaseRenderer::GetInstance( mitk::BaseRenderer::GetRenderWindowByName("stdmulti.widget4"))); QWidget::setContentsMargins(0, 0, 0, 0); if ( QWidget::layout() != NULL ) { QWidget::layout()->setContentsMargins(0, 0, 0, 0); } //For running 3D Interpolation in background // create a QFuture and a QFutureWatcher connect(&m_Watcher, SIGNAL(started()), this, SLOT(StartUpdateInterpolationTimer())); connect(&m_Watcher, SIGNAL(finished()), this, SLOT(OnSurfaceInterpolationFinished())); connect(&m_Watcher, SIGNAL(finished()), this, SLOT(StopUpdateInterpolationTimer())); m_Timer = new QTimer(this); connect(m_Timer, SIGNAL(timeout()), this, SLOT(ChangeSurfaceColor())); } void QmitkSlicesInterpolator::SetDataStorage( mitk::DataStorage::Pointer storage ) { m_DataStorage = storage; m_SurfaceInterpolator->SetDataStorage(storage); } mitk::DataStorage* QmitkSlicesInterpolator::GetDataStorage() { if ( m_DataStorage.IsNotNull() ) { return m_DataStorage; } else { return NULL; } } void QmitkSlicesInterpolator::Initialize(mitk::ToolManager* toolManager, const QList &controllers) { Q_ASSERT(!controllers.empty()); if (m_Initialized) { // remove old observers Uninitialize(); } m_ToolManager = toolManager; if (m_ToolManager) { // set enabled only if a segmentation is selected mitk::DataNode* node = m_ToolManager->GetWorkingData(0); QWidget::setEnabled( node != NULL ); // react whenever the set of selected segmentation changes m_ToolManager->WorkingDataChanged += mitk::MessageDelegate( this, &QmitkSlicesInterpolator::OnToolManagerWorkingDataModified ); m_ToolManager->ReferenceDataChanged += mitk::MessageDelegate( this, &QmitkSlicesInterpolator::OnToolManagerReferenceDataModified ); // connect to the slice navigation controller. after each change, call the interpolator foreach(mitk::SliceNavigationController* slicer, controllers) { //Has to be initialized m_LastSNC = slicer; m_TimeStep.insert(slicer, slicer->GetTime()->GetPos()); itk::MemberCommand::Pointer deleteCommand = itk::MemberCommand::New(); deleteCommand->SetCallbackFunction( this, &QmitkSlicesInterpolator::OnSliceNavigationControllerDeleted); m_ControllerToDeleteObserverTag.insert(slicer, slicer->AddObserver(itk::DeleteEvent(), deleteCommand)); itk::MemberCommand::Pointer timeChangedCommand = itk::MemberCommand::New(); timeChangedCommand->SetCallbackFunction( this, &QmitkSlicesInterpolator::OnTimeChanged); m_ControllerToTimeObserverTag.insert(slicer, slicer->AddObserver(mitk::SliceNavigationController::TimeGeometryEvent(NULL,0), timeChangedCommand)); itk::MemberCommand::Pointer sliceChangedCommand = itk::MemberCommand::New(); sliceChangedCommand->SetCallbackFunction( this, &QmitkSlicesInterpolator::OnSliceChanged); m_ControllerToSliceObserverTag.insert(slicer, slicer->AddObserver(mitk::SliceNavigationController::GeometrySliceEvent(NULL,0), sliceChangedCommand)); } ACTION_TO_SLICEDIMENSION = createActionToSliceDimension(); } m_Initialized = true; } void QmitkSlicesInterpolator::Uninitialize() { if (m_ToolManager.IsNotNull()) { m_ToolManager->WorkingDataChanged -= mitk::MessageDelegate(this, &QmitkSlicesInterpolator::OnToolManagerWorkingDataModified); m_ToolManager->ReferenceDataChanged -= mitk::MessageDelegate(this, &QmitkSlicesInterpolator::OnToolManagerReferenceDataModified); } foreach(mitk::SliceNavigationController* slicer, m_ControllerToSliceObserverTag.keys()) { slicer->RemoveObserver(m_ControllerToDeleteObserverTag.take(slicer)); slicer->RemoveObserver(m_ControllerToTimeObserverTag.take(slicer)); slicer->RemoveObserver(m_ControllerToSliceObserverTag.take(slicer)); } ACTION_TO_SLICEDIMENSION.clear(); m_ToolManager = NULL; m_Initialized = false; } QmitkSlicesInterpolator::~QmitkSlicesInterpolator() { if (m_Initialized) { // remove old observers Uninitialize(); } if(m_DataStorage->Exists(m_3DContourNode)) m_DataStorage->Remove(m_3DContourNode); if(m_DataStorage->Exists(m_InterpolatedSurfaceNode)) m_DataStorage->Remove(m_InterpolatedSurfaceNode); // remove observer m_Interpolator->RemoveObserver( InterpolationInfoChangedObserverTag ); m_SurfaceInterpolator->RemoveObserver( SurfaceInterpolationInfoChangedObserverTag ); delete m_Timer; } /** External enableization... */ void QmitkSlicesInterpolator::setEnabled( bool enable ) { QWidget::setEnabled(enable); //Set the gui elements of the different interpolation modi enabled if (enable) { if (m_2DInterpolationEnabled) { this->Show2DInterpolationControls(true); m_Interpolator->Activate2DInterpolation(true); } else if (m_3DInterpolationEnabled) { this->Show3DInterpolationControls(true); this->Show3DInterpolationResult(true); } } //Set all gui elements of the interpolation disabled else { this->HideAllInterpolationControls(); this->Show3DInterpolationResult(false); } } void QmitkSlicesInterpolator::On2DInterpolationEnabled(bool status) { OnInterpolationActivated(status); m_Interpolator->Activate2DInterpolation(status); } void QmitkSlicesInterpolator::On3DInterpolationEnabled(bool status) { On3DInterpolationActivated(status); } void QmitkSlicesInterpolator::OnInterpolationDisabled(bool status) { if (status) { OnInterpolationActivated(!status); On3DInterpolationActivated(!status); this->Show3DInterpolationResult(false); } } void QmitkSlicesInterpolator::HideAllInterpolationControls() { this->Show2DInterpolationControls(false); this->Show3DInterpolationControls(false); } void QmitkSlicesInterpolator::Show2DInterpolationControls(bool show) { m_BtnApply2D->setVisible(show); m_BtnApplyForAllSlices2D->setVisible(show); } void QmitkSlicesInterpolator::Show3DInterpolationControls(bool show) { m_BtnApply3D->setVisible(show); m_ChkShowPositionNodes->setVisible(show); + m_BtnReinit3DInterpolation->setVisible(show); } void QmitkSlicesInterpolator::OnInterpolationMethodChanged(int index) { switch(index) { case 0: // Disabled m_GroupBoxEnableExclusiveInterpolationMode->setTitle("Interpolation"); this->HideAllInterpolationControls(); this->OnInterpolationActivated(false); this->On3DInterpolationActivated(false); this->Show3DInterpolationResult(false); m_Interpolator->Activate2DInterpolation(false); break; case 1: // 2D m_GroupBoxEnableExclusiveInterpolationMode->setTitle("Interpolation (Enabled)"); this->HideAllInterpolationControls(); this->Show2DInterpolationControls(true); this->OnInterpolationActivated(true); this->On3DInterpolationActivated(false); m_Interpolator->Activate2DInterpolation(true); break; case 2: // 3D m_GroupBoxEnableExclusiveInterpolationMode->setTitle("Interpolation (Enabled)"); this->HideAllInterpolationControls(); this->Show3DInterpolationControls(true); this->OnInterpolationActivated(false); this->On3DInterpolationActivated(true); m_Interpolator->Activate2DInterpolation(false); break; default: MITK_ERROR << "Unknown interpolation method!"; m_CmbInterpolation->setCurrentIndex(0); break; } } void QmitkSlicesInterpolator::OnShowMarkers(bool state) { mitk::DataStorage::SetOfObjects::ConstPointer allContourMarkers = m_DataStorage->GetSubset(mitk::NodePredicateProperty::New("isContourMarker" , mitk::BoolProperty::New(true))); for (mitk::DataStorage::SetOfObjects::ConstIterator it = allContourMarkers->Begin(); it != allContourMarkers->End(); ++it) { it->Value()->SetProperty("helper object", mitk::BoolProperty::New(!state)); } } void QmitkSlicesInterpolator::OnToolManagerWorkingDataModified() { if (m_ToolManager->GetWorkingData(0) != 0) { m_Segmentation = dynamic_cast(m_ToolManager->GetWorkingData(0)->GetData()); + m_BtnReinit3DInterpolation->setEnabled(true); } else { //If no workingdata is set, remove the interpolation feedback this->GetDataStorage()->Remove(m_FeedbackNode); m_FeedbackNode->SetData(NULL); this->GetDataStorage()->Remove(m_3DContourNode); m_3DContourNode->SetData(NULL); this->GetDataStorage()->Remove(m_InterpolatedSurfaceNode); m_InterpolatedSurfaceNode->SetData(NULL); + m_BtnReinit3DInterpolation->setEnabled(false); return; } //Updating the current selected segmentation for the 3D interpolation SetCurrentContourListID(); if (m_2DInterpolationEnabled) { OnInterpolationActivated( true ); // re-initialize if needed } this->CheckSupportedImageDimension(); } void QmitkSlicesInterpolator::OnToolManagerReferenceDataModified() { } void QmitkSlicesInterpolator::OnTimeChanged(itk::Object* sender, const itk::EventObject& e) { //Check if we really have a GeometryTimeEvent if (!dynamic_cast(&e)) return; mitk::SliceNavigationController* slicer = dynamic_cast(sender); Q_ASSERT(slicer); - m_TimeStep[slicer]/* = event.GetPos()*/; + m_TimeStep[slicer]; - //TODO Macht das hier wirklich Sinn???? if (m_LastSNC == slicer) { slicer->SendSlice();//will trigger a new interpolation } } void QmitkSlicesInterpolator::OnSliceChanged(itk::Object *sender, const itk::EventObject &e) { //Check whether we really have a GeometrySliceEvent if (!dynamic_cast(&e)) return; mitk::SliceNavigationController* slicer = dynamic_cast(sender); if (TranslateAndInterpolateChangedSlice(e, slicer)) { slicer->GetRenderer()->RequestUpdate(); } } bool QmitkSlicesInterpolator::TranslateAndInterpolateChangedSlice(const itk::EventObject& e, mitk::SliceNavigationController* slicer) { if (!m_2DInterpolationEnabled) return false; try { const mitk::SliceNavigationController::GeometrySliceEvent& event = dynamic_cast(e); mitk::TimeGeometry* tsg = event.GetTimeGeometry(); if (tsg && m_TimeStep.contains(slicer)) { mitk::SlicedGeometry3D* slicedGeometry = dynamic_cast(tsg->GetGeometryForTimeStep(m_TimeStep[slicer]).GetPointer()); if (slicedGeometry) { m_LastSNC = slicer; mitk::PlaneGeometry* plane = dynamic_cast(slicedGeometry->GetPlaneGeometry( event.GetPos() )); if (plane) Interpolate( plane, m_TimeStep[slicer], slicer ); return true; } } } catch(std::bad_cast) { return false; // so what } return false; } void QmitkSlicesInterpolator::Interpolate( mitk::PlaneGeometry* plane, unsigned int timeStep, mitk::SliceNavigationController* slicer ) { if (m_ToolManager) { mitk::DataNode* node = m_ToolManager->GetWorkingData(0); if (node) { m_Segmentation = dynamic_cast(node->GetData()); if (m_Segmentation) { int clickedSliceDimension(-1); int clickedSliceIndex(-1); // calculate real slice position, i.e. slice of the image and not slice of the TimeSlicedGeometry mitk::SegTool2D::DetermineAffectedImageSlice( m_Segmentation, plane, clickedSliceDimension, clickedSliceIndex ); mitk::Image::Pointer interpolation = m_Interpolator->Interpolate( clickedSliceDimension, clickedSliceIndex, plane, timeStep ); m_FeedbackNode->SetData( interpolation ); m_LastSNC = slicer; m_LastSliceIndex = clickedSliceIndex; } } } } void QmitkSlicesInterpolator::OnSurfaceInterpolationFinished() { mitk::Surface::Pointer interpolatedSurface = m_SurfaceInterpolator->GetInterpolationResult(); mitk::DataNode* workingNode = m_ToolManager->GetWorkingData(0); if(interpolatedSurface.IsNotNull() && workingNode && workingNode->IsVisible(mitk::BaseRenderer::GetInstance( mitk::BaseRenderer::GetRenderWindowByName("stdmulti.widget3")))) { m_BtnApply3D->setEnabled(true); m_InterpolatedSurfaceNode->SetData(interpolatedSurface); m_3DContourNode->SetData(m_SurfaceInterpolator->GetContoursAsSurface()); this->Show3DInterpolationResult(true); - if( !m_DataStorage->Exists(m_InterpolatedSurfaceNode) && !m_DataStorage->Exists(m_3DContourNode)) + if( !m_DataStorage->Exists(m_InterpolatedSurfaceNode) ) { - m_DataStorage->Add(m_3DContourNode); m_DataStorage->Add(m_InterpolatedSurfaceNode); } + if (!m_DataStorage->Exists(m_3DContourNode)) + { + m_DataStorage->Add(m_3DContourNode, workingNode); + } + } else if (interpolatedSurface.IsNull()) { m_BtnApply3D->setEnabled(false); if (m_DataStorage->Exists(m_InterpolatedSurfaceNode)) { this->Show3DInterpolationResult(false); } } + m_BtnReinit3DInterpolation->setEnabled(true); + foreach (mitk::SliceNavigationController* slicer, m_ControllerToTimeObserverTag.keys()) { slicer->GetRenderer()->RequestUpdate(); } } void QmitkSlicesInterpolator::OnAcceptInterpolationClicked() { if (m_Segmentation && m_FeedbackNode->GetData()) { //making interpolation separately undoable mitk::UndoStackItem::IncCurrObjectEventId(); mitk::UndoStackItem::IncCurrGroupEventId(); mitk::UndoStackItem::ExecuteIncrement(); //Make sure that for reslicing and overwriting the same alogrithm is used. We can specify the mode of the vtk reslicer vtkSmartPointer reslice = vtkSmartPointer::New(); // Set slice as input mitk::Image::Pointer slice = dynamic_cast(m_FeedbackNode->GetData()); reslice->SetInputSlice(slice->GetSliceData()->GetVtkImageAccessor(slice)->GetVtkImageData()); //set overwrite mode to true to write back to the image volume reslice->SetOverwriteMode(true); reslice->Modified(); mitk::ExtractSliceFilter::Pointer extractor = mitk::ExtractSliceFilter::New(reslice); extractor->SetInput( m_Segmentation ); unsigned int timestep = m_LastSNC->GetTime()->GetPos(); extractor->SetTimeStep( timestep ); extractor->SetWorldGeometry( m_LastSNC->GetCurrentPlaneGeometry() ); extractor->SetVtkOutputRequest(true); extractor->SetResliceTransformByGeometry( m_Segmentation->GetTimeGeometry()->GetGeometryForTimeStep( timestep ) ); extractor->Modified(); extractor->Update(); //the image was modified within the pipeline, but not marked so m_Segmentation->Modified(); m_Segmentation->GetVtkImageData()->Modified(); m_FeedbackNode->SetData(NULL); mitk::RenderingManager::GetInstance()->RequestUpdateAll(); } } void QmitkSlicesInterpolator::AcceptAllInterpolations(mitk::SliceNavigationController* slicer) { /* * What exactly is done here: * 1. We create an empty diff image for the current segmentation * 2. All interpolated slices are written into the diff image * 3. Then the diffimage is applied to the original segmentation */ if (m_Segmentation) { //making interpolation separately undoable mitk::UndoStackItem::IncCurrObjectEventId(); mitk::UndoStackItem::IncCurrGroupEventId(); mitk::UndoStackItem::ExecuteIncrement(); mitk::Image::Pointer image3D = m_Segmentation; unsigned int timeStep( slicer->GetTime()->GetPos() ); if (m_Segmentation->GetDimension() == 4) { mitk::ImageTimeSelector::Pointer timeSelector = mitk::ImageTimeSelector::New(); timeSelector->SetInput( m_Segmentation ); timeSelector->SetTimeNr( timeStep ); timeSelector->Update(); image3D = timeSelector->GetOutput(); } // create a empty diff image for the undo operation mitk::Image::Pointer diffImage = mitk::Image::New(); diffImage->Initialize( image3D ); // Create scope for ImageWriteAccessor so that the accessor is destroyed // after the image is initialized. Otherwise later image access will lead to an error { mitk::ImageWriteAccessor imAccess(diffImage); // Set all pixels to zero mitk::PixelType pixelType( mitk::MakeScalarPixelType() ); memset( imAccess.GetData(), 0, (pixelType.GetBpe() >> 3) * diffImage->GetDimension(0) * diffImage->GetDimension(1) * diffImage->GetDimension(2) ); } // Since we need to shift the plane it must be clone so that the original plane isn't altered mitk::PlaneGeometry::Pointer reslicePlane = slicer->GetCurrentPlaneGeometry()->Clone(); int sliceDimension(-1); int sliceIndex(-1); mitk::SegTool2D::DetermineAffectedImageSlice( m_Segmentation, reslicePlane, sliceDimension, sliceIndex ); unsigned int zslices = m_Segmentation->GetDimension( sliceDimension ); mitk::ProgressBar::GetInstance()->AddStepsToDo(zslices); mitk::Point3D origin = reslicePlane->GetOrigin(); unsigned int totalChangedSlices(0); for (unsigned int sliceIndex = 0; sliceIndex < zslices; ++sliceIndex) { // Transforming the current origin of the reslice plane // so that it matches the one of the next slice m_Segmentation->GetSlicedGeometry()->WorldToIndex(origin, origin); origin[sliceDimension] = sliceIndex; m_Segmentation->GetSlicedGeometry()->IndexToWorld(origin, origin); reslicePlane->SetOrigin(origin); //Set the slice as 'input' mitk::Image::Pointer interpolation = m_Interpolator->Interpolate( sliceDimension, sliceIndex, reslicePlane, timeStep ); if (interpolation.IsNotNull()) // we don't check if interpolation is necessary/sensible - but m_Interpolator does { //Setting up the reslicing pipeline which allows us to write the interpolation results back into //the image volume vtkSmartPointer reslice = vtkSmartPointer::New(); //set overwrite mode to true to write back to the image volume reslice->SetInputSlice(interpolation->GetSliceData()->GetVtkImageAccessor(interpolation)->GetVtkImageData()); reslice->SetOverwriteMode(true); reslice->Modified(); mitk::ExtractSliceFilter::Pointer diffslicewriter = mitk::ExtractSliceFilter::New(reslice); diffslicewriter->SetInput( diffImage ); diffslicewriter->SetTimeStep( timeStep ); diffslicewriter->SetWorldGeometry(reslicePlane); diffslicewriter->SetVtkOutputRequest(true); diffslicewriter->SetResliceTransformByGeometry( diffImage->GetTimeGeometry()->GetGeometryForTimeStep( timeStep ) ); diffslicewriter->Modified(); diffslicewriter->Update(); ++totalChangedSlices; } mitk::ProgressBar::GetInstance()->Progress(); } mitk::RenderingManager::GetInstance()->RequestUpdateAll(); if (totalChangedSlices > 0) { // store undo stack items if ( true ) { // create do/undo operations mitk::ApplyDiffImageOperation* doOp = new mitk::ApplyDiffImageOperation( mitk::OpTEST, m_Segmentation, diffImage, timeStep ); mitk::ApplyDiffImageOperation* undoOp = new mitk::ApplyDiffImageOperation( mitk::OpTEST, m_Segmentation, diffImage, timeStep ); undoOp->SetFactor( -1.0 ); std::stringstream comment; comment << "Confirm all interpolations (" << totalChangedSlices << ")"; mitk::OperationEvent* undoStackItem = new mitk::OperationEvent( mitk::DiffImageApplier::GetInstanceForUndo(), doOp, undoOp, comment.str() ); mitk::UndoController::GetCurrentUndoModel()->SetOperationEvent( undoStackItem ); // acutally apply the changes here to the original image mitk::DiffImageApplier::GetInstanceForUndo()->ExecuteOperation( doOp ); } } m_FeedbackNode->SetData(NULL); mitk::RenderingManager::GetInstance()->RequestUpdateAll(); } } void QmitkSlicesInterpolator::FinishInterpolation(mitk::SliceNavigationController* slicer) { //this redirect is for calling from outside if (slicer == NULL) OnAcceptAllInterpolationsClicked(); else AcceptAllInterpolations( slicer ); } void QmitkSlicesInterpolator::OnAcceptAllInterpolationsClicked() { QMenu orientationPopup(this); std::map::const_iterator it; for(it = ACTION_TO_SLICEDIMENSION.begin(); it != ACTION_TO_SLICEDIMENSION.end(); it++) orientationPopup.addAction(it->first); connect( &orientationPopup, SIGNAL(triggered(QAction*)), this, SLOT(OnAcceptAllPopupActivated(QAction*)) ); orientationPopup.exec( QCursor::pos() ); } void QmitkSlicesInterpolator::OnAccept3DInterpolationClicked() { if (m_InterpolatedSurfaceNode.IsNotNull() && m_InterpolatedSurfaceNode->GetData()) { mitk::SurfaceToImageFilter::Pointer s2iFilter = mitk::SurfaceToImageFilter::New(); s2iFilter->MakeOutputBinaryOn(); s2iFilter->SetInput(dynamic_cast(m_InterpolatedSurfaceNode->GetData())); // check if ToolManager holds valid ReferenceData if (m_ToolManager->GetReferenceData(0) == NULL || m_ToolManager->GetWorkingData(0) == NULL) { return; } s2iFilter->SetImage(dynamic_cast(m_ToolManager->GetReferenceData(0)->GetData())); s2iFilter->Update(); mitk::DataNode* segmentationNode = m_ToolManager->GetWorkingData(0); segmentationNode->SetData(s2iFilter->GetOutput()); m_CmbInterpolation->setCurrentIndex(0); mitk::RenderingManager::GetInstance()->RequestUpdateAll(); this->Show3DInterpolationResult(false); } } +void QmitkSlicesInterpolator::OnReinit3DInterpolation() +{ + mitk::NodePredicateProperty::Pointer pred = mitk::NodePredicateProperty::New("3DContourContainer", mitk::BoolProperty::New(true)); + mitk::DataStorage::SetOfObjects::ConstPointer contourNodes = m_DataStorage->GetDerivations( m_ToolManager->GetWorkingData(0), pred); + if (contourNodes->Size() != 0) + { + m_3DContourNode = contourNodes->at(0); + } + else + { + QMessageBox errorInfo; + errorInfo.setWindowTitle("Reinitialize surface interpolation"); + errorInfo.setIcon(QMessageBox::Information); + errorInfo.setText("No contours available for the selected segmentation!"); + errorInfo.exec(); + } + mitk::Surface::Pointer contours = dynamic_cast(m_3DContourNode->GetData()); + if (contours) + mitk::SurfaceInterpolationController::GetInstance()->ReinitializeInterpolation(contours); + m_BtnReinit3DInterpolation->setEnabled(false); +} + void QmitkSlicesInterpolator::OnAcceptAllPopupActivated(QAction* action) { try { std::map::const_iterator iter = ACTION_TO_SLICEDIMENSION.find( action ); if (iter != ACTION_TO_SLICEDIMENSION.end()) { mitk::SliceNavigationController* slicer = iter->second; AcceptAllInterpolations( slicer ); } } catch(...) { /* Showing message box with possible memory error */ QMessageBox errorInfo; errorInfo.setWindowTitle("Interpolation Process"); errorInfo.setIcon(QMessageBox::Critical); errorInfo.setText("An error occurred during interpolation. Possible cause: Not enough memory!"); errorInfo.exec(); //additional error message on std::cerr std::cerr << "Ill construction in " __FILE__ " l. " << __LINE__ << std::endl; } } void QmitkSlicesInterpolator::OnInterpolationActivated(bool on) { m_2DInterpolationEnabled = on; try { if ( m_DataStorage.IsNotNull() ) { if (on && !m_DataStorage->Exists(m_FeedbackNode)) { m_DataStorage->Add( m_FeedbackNode ); } } } catch(...) { // don't care (double add/remove) } if (m_ToolManager) { mitk::DataNode* workingNode = m_ToolManager->GetWorkingData(0); mitk::DataNode* referenceNode = m_ToolManager->GetReferenceData(0); QWidget::setEnabled( workingNode != NULL ); m_BtnApply2D->setEnabled( on ); m_FeedbackNode->SetVisibility( on ); if (!on) { mitk::RenderingManager::GetInstance()->RequestUpdateAll(); return; } if (workingNode) { mitk::Image* segmentation = dynamic_cast(workingNode->GetData()); if (segmentation) { m_Interpolator->SetSegmentationVolume( segmentation ); if (referenceNode) { mitk::Image* referenceImage = dynamic_cast(referenceNode->GetData()); m_Interpolator->SetReferenceVolume( referenceImage ); // may be NULL } } } } UpdateVisibleSuggestion(); } void QmitkSlicesInterpolator::Run3DInterpolation() { m_SurfaceInterpolator->Interpolate(); } void QmitkSlicesInterpolator::StartUpdateInterpolationTimer() { m_Timer->start(500); } void QmitkSlicesInterpolator::StopUpdateInterpolationTimer() { m_Timer->stop(); m_InterpolatedSurfaceNode->SetProperty("color", mitk::ColorProperty::New(255.0,255.0,0.0)); mitk::RenderingManager::GetInstance()->RequestUpdate(mitk::BaseRenderer::GetInstance( mitk::BaseRenderer::GetRenderWindowByName("stdmulti.widget4"))->GetRenderWindow()); } void QmitkSlicesInterpolator::ChangeSurfaceColor() { float currentColor[3]; m_InterpolatedSurfaceNode->GetColor(currentColor); float yellow[3] = {255.0,255.0,0.0}; if( currentColor[2] == yellow[2]) { m_InterpolatedSurfaceNode->SetProperty("color", mitk::ColorProperty::New(255.0,255.0,255.0)); } else { m_InterpolatedSurfaceNode->SetProperty("color", mitk::ColorProperty::New(yellow)); } m_InterpolatedSurfaceNode->Update(); mitk::RenderingManager::GetInstance()->RequestUpdate(mitk::BaseRenderer::GetInstance( mitk::BaseRenderer::GetRenderWindowByName("stdmulti.widget4"))->GetRenderWindow()); } void QmitkSlicesInterpolator::On3DInterpolationActivated(bool on) { m_3DInterpolationEnabled = on; this->CheckSupportedImageDimension(); try { if ( m_DataStorage.IsNotNull() && m_ToolManager && m_3DInterpolationEnabled) { mitk::DataNode* workingNode = m_ToolManager->GetWorkingData(0); if (workingNode) { bool isInterpolationResult(false); workingNode->GetBoolProperty("3DInterpolationResult",isInterpolationResult); if ((workingNode->IsVisible(mitk::BaseRenderer::GetInstance( mitk::BaseRenderer::GetRenderWindowByName("stdmulti.widget3")))) && !isInterpolationResult && m_3DInterpolationEnabled) { int ret = QMessageBox::Yes; if (m_SurfaceInterpolator->EstimatePortionOfNeededMemory() > 0.5) { QMessageBox msgBox; msgBox.setText("Due to short handed system memory the 3D interpolation may be very slow!"); msgBox.setInformativeText("Are you sure you want to activate the 3D interpolation?"); msgBox.setStandardButtons(QMessageBox::No | QMessageBox::Yes); ret = msgBox.exec(); } if (m_Watcher.isRunning()) m_Watcher.waitForFinished(); if (ret == QMessageBox::Yes) { m_Future = QtConcurrent::run(this, &QmitkSlicesInterpolator::Run3DInterpolation); m_Watcher.setFuture(m_Future); } else { m_CmbInterpolation->setCurrentIndex(0); } } else if (!m_3DInterpolationEnabled) { this->Show3DInterpolationResult(false); m_BtnApply3D->setEnabled(m_3DInterpolationEnabled); } } else { QWidget::setEnabled( false ); m_ChkShowPositionNodes->setEnabled(m_3DInterpolationEnabled); } } if (!m_3DInterpolationEnabled) { this->Show3DInterpolationResult(false); m_BtnApply3D->setEnabled(m_3DInterpolationEnabled); } } catch(...) { MITK_ERROR<<"Error with 3D surface interpolation!"; } mitk::RenderingManager::GetInstance()->RequestUpdateAll(); } void QmitkSlicesInterpolator::EnableInterpolation(bool on) { // only to be called from the outside world // just a redirection to OnInterpolationActivated OnInterpolationActivated(on); } void QmitkSlicesInterpolator::Enable3DInterpolation(bool on) { // only to be called from the outside world // just a redirection to OnInterpolationActivated On3DInterpolationActivated(on); } void QmitkSlicesInterpolator::UpdateVisibleSuggestion() { if (m_2DInterpolationEnabled && m_LastSNC) { // determine which one is the current view, try to do an initial interpolation mitk::BaseRenderer* renderer = m_LastSNC->GetRenderer(); if (renderer && renderer->GetMapperID() == mitk::BaseRenderer::Standard2D) { const mitk::TimeGeometry* timeGeometry = dynamic_cast( renderer->GetWorldGeometry() ); if (timeGeometry) { mitk::SliceNavigationController::GeometrySliceEvent event( const_cast(timeGeometry), renderer->GetSlice() ); TranslateAndInterpolateChangedSlice(event, m_LastSNC); } } } mitk::RenderingManager::GetInstance()->RequestUpdateAll(); } void QmitkSlicesInterpolator::OnInterpolationInfoChanged(const itk::EventObject& /*e*/) { // something (e.g. undo) changed the interpolation info, we should refresh our display UpdateVisibleSuggestion(); } void QmitkSlicesInterpolator::OnSurfaceInterpolationInfoChanged(const itk::EventObject& /*e*/) { if(m_3DInterpolationEnabled) { if (m_Watcher.isRunning()) m_Watcher.waitForFinished(); m_Future = QtConcurrent::run(this, &QmitkSlicesInterpolator::Run3DInterpolation); m_Watcher.setFuture(m_Future); } } void QmitkSlicesInterpolator:: SetCurrentContourListID() { // New ContourList = hide current interpolation Show3DInterpolationResult(false); if ( m_DataStorage.IsNotNull() && m_ToolManager && m_LastSNC ) { mitk::DataNode* workingNode = m_ToolManager->GetWorkingData(0); if (workingNode) { bool isInterpolationResult(false); workingNode->GetBoolProperty("3DInterpolationResult",isInterpolationResult); if (!isInterpolationResult) { QWidget::setEnabled( true ); //TODO Aufruf hier pruefen! mitk::Vector3D spacing = workingNode->GetData()->GetGeometry( m_LastSNC->GetTime()->GetPos() )->GetSpacing(); double minSpacing (100); double maxSpacing (0); for (int i =0; i < 3; i++) { if (spacing[i] < minSpacing) { minSpacing = spacing[i]; } else if (spacing[i] > maxSpacing) { maxSpacing = spacing[i]; } } m_SurfaceInterpolator->SetMaxSpacing(maxSpacing); m_SurfaceInterpolator->SetMinSpacing(minSpacing); m_SurfaceInterpolator->SetDistanceImageVolume(50000); mitk::Image* segmentationImage = dynamic_cast(workingNode->GetData()); if (segmentationImage->GetDimension() == 3) m_SurfaceInterpolator->SetCurrentInterpolationSession(segmentationImage); else MITK_INFO<<"3D Interpolation is only supported for 3D images at the moment!"; if (m_3DInterpolationEnabled) { if (m_Watcher.isRunning()) m_Watcher.waitForFinished(); m_Future = QtConcurrent::run(this, &QmitkSlicesInterpolator::Run3DInterpolation); m_Watcher.setFuture(m_Future); } } } else { QWidget::setEnabled(false); } } } void QmitkSlicesInterpolator::Show3DInterpolationResult(bool status) { if (m_InterpolatedSurfaceNode.IsNotNull()) m_InterpolatedSurfaceNode->SetVisibility(status); if (m_3DContourNode.IsNotNull()) m_3DContourNode->SetVisibility(status, mitk::BaseRenderer::GetInstance( mitk::BaseRenderer::GetRenderWindowByName("stdmulti.widget4"))); mitk::RenderingManager::GetInstance()->RequestUpdateAll(); } void QmitkSlicesInterpolator::CheckSupportedImageDimension() { if (m_3DInterpolationEnabled && m_Segmentation->GetDimension() != 3) { QMessageBox info; info.setWindowTitle("3D Interpolation Process"); info.setIcon(QMessageBox::Information); info.setText("3D Interpolation is only supported for 3D images at the moment!"); info.exec(); m_CmbInterpolation->setCurrentIndex(0); } } void QmitkSlicesInterpolator::OnSliceNavigationControllerDeleted(const itk::Object *sender, const itk::EventObject& /*e*/) { //Don't know how to avoid const_cast here?! mitk::SliceNavigationController* slicer = dynamic_cast(const_cast(sender)); if (slicer) { m_ControllerToTimeObserverTag.remove(slicer); m_ControllerToSliceObserverTag.remove(slicer); m_ControllerToDeleteObserverTag.remove(slicer); } } diff --git a/Modules/SegmentationUI/Qmitk/QmitkSlicesInterpolator.h b/Modules/SegmentationUI/Qmitk/QmitkSlicesInterpolator.h index d04e4dd546..758d15545d 100644 --- a/Modules/SegmentationUI/Qmitk/QmitkSlicesInterpolator.h +++ b/Modules/SegmentationUI/Qmitk/QmitkSlicesInterpolator.h @@ -1,279 +1,282 @@ /*=================================================================== 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 QmitkSlicesInterpolator_h_Included #define QmitkSlicesInterpolator_h_Included #include "mitkSliceNavigationController.h" #include #include "mitkSegmentationInterpolationController.h" #include "mitkDataNode.h" #include "mitkDataStorage.h" #include "mitkWeakPointer.h" #include "mitkSurfaceInterpolationController.h" #include "mitkToolManager.h" #include #include #include #include #include #include #include #include "mitkVtkRepresentationProperty.h" #include "vtkProperty.h" //For running 3D interpolation in background #include #include #include #include namespace mitk { class PlaneGeometry; class SliceNavigationController; } class QPushButton; /** \brief GUI for slices interpolation. \ingroup ToolManagerEtAl \ingroup Widgets \sa QmitkInteractiveSegmentation \sa mitk::SegmentationInterpolation There is a separate page describing the general design of QmitkInteractiveSegmentation: \ref QmitkInteractiveSegmentationTechnicalPage While mitk::SegmentationInterpolation does the bookkeeping of interpolation (keeping track of which slices contain how much segmentation) and the algorithmic work, QmitkSlicesInterpolator is responsible to watch the GUI, to notice, which slice is currently visible. It triggers generation of interpolation suggestions and also triggers acception of suggestions. \todo show/hide feedback on demand Last contributor: $Author: maleike $ */ class MitkSegmentationUI_EXPORT QmitkSlicesInterpolator : public QWidget { Q_OBJECT public: QmitkSlicesInterpolator(QWidget* parent = 0, const char* name = 0); /** To be called once before real use. */ void Initialize(mitk::ToolManager* toolManager, const QList &controllers); void Uninitialize(); virtual ~QmitkSlicesInterpolator(); void SetDataStorage( mitk::DataStorage::Pointer storage ); mitk::DataStorage* GetDataStorage(); /** Just public because it is called by itk::Commands. You should not need to call this. */ void OnToolManagerWorkingDataModified(); /** Just public because it is called by itk::Commands. You should not need to call this. */ void OnToolManagerReferenceDataModified(); void OnTimeChanged(itk::Object* sender, const itk::EventObject&); void OnSliceChanged(itk::Object* sender, const itk::EventObject&); void OnSliceNavigationControllerDeleted(const itk::Object *sender, const itk::EventObject& ); /** Just public because it is called by itk::Commands. You should not need to call this. */ void OnInterpolationInfoChanged(const itk::EventObject&); /** Just public because it is called by itk::Commands. You should not need to call this. */ void OnSurfaceInterpolationInfoChanged(const itk::EventObject&); /** * @brief Set the visibility of the 3d interpolation */ void Show3DInterpolationResult(bool); signals: void SignalRememberContourPositions(bool); void SignalShowMarkerNodes(bool); public slots: virtual void setEnabled( bool ); /** Call this from the outside to enable/disable interpolation */ void EnableInterpolation(bool); void Enable3DInterpolation(bool); /** Call this from the outside to accept all interpolations */ void FinishInterpolation(mitk::SliceNavigationController* slicer = NULL); protected slots: /** Reaction to button clicks. */ void OnAcceptInterpolationClicked(); /* Opens popup to ask about which orientation should be interpolated */ void OnAcceptAllInterpolationsClicked(); /* Reaction to button clicks */ void OnAccept3DInterpolationClicked(); + void OnReinit3DInterpolation(); + /* * Will trigger interpolation for all slices in given orientation (called from popup menu of OnAcceptAllInterpolationsClicked) */ void OnAcceptAllPopupActivated(QAction* action); /** Called on activation/deactivation */ void OnInterpolationActivated(bool); void On3DInterpolationActivated(bool); void OnInterpolationMethodChanged(int index); //Enhancement for 3D interpolation void On2DInterpolationEnabled(bool); void On3DInterpolationEnabled(bool); void OnInterpolationDisabled(bool); void OnShowMarkers(bool); void Run3DInterpolation(); void OnSurfaceInterpolationFinished(); void StartUpdateInterpolationTimer(); void StopUpdateInterpolationTimer(); void ChangeSurfaceColor(); protected: const std::map createActionToSliceDimension(); std::map ACTION_TO_SLICEDIMENSION; void AcceptAllInterpolations(mitk::SliceNavigationController* slicer); /** Retrieves the currently selected PlaneGeometry from a SlicedGeometry3D that is generated by a SliceNavigationController and calls Interpolate to further process this PlaneGeometry into an interpolation. \param e is a actually a mitk::SliceNavigationController::GeometrySliceEvent, sent by a SliceNavigationController \param slice the SliceNavigationController */ bool TranslateAndInterpolateChangedSlice(const itk::EventObject& e, mitk::SliceNavigationController* slicer); /** Given a PlaneGeometry, this method figures out which slice of the first working image (of the associated ToolManager) should be interpolated. The actual work is then done by our SegmentationInterpolation object. */ void Interpolate( mitk::PlaneGeometry* plane, unsigned int timeStep, mitk::SliceNavigationController *slicer ); //void InterpolateSurface(); /** Called internally to update the interpolation suggestion. Finds out about the focused render window and requests an interpolation. */ void UpdateVisibleSuggestion(); void SetCurrentContourListID(); private: void HideAllInterpolationControls(); void Show2DInterpolationControls(bool show); void Show3DInterpolationControls(bool show); void CheckSupportedImageDimension(); mitk::SegmentationInterpolationController::Pointer m_Interpolator; mitk::SurfaceInterpolationController::Pointer m_SurfaceInterpolator; mitk::ToolManager::Pointer m_ToolManager; bool m_Initialized; QHash m_ControllerToTimeObserverTag; QHash m_ControllerToSliceObserverTag; QHash m_ControllerToDeleteObserverTag; unsigned int InterpolationInfoChangedObserverTag; unsigned int SurfaceInterpolationInfoChangedObserverTag; QGroupBox* m_GroupBoxEnableExclusiveInterpolationMode; QComboBox* m_CmbInterpolation; QPushButton* m_BtnApply2D; QPushButton* m_BtnApplyForAllSlices2D; QPushButton* m_BtnApply3D; QCheckBox* m_ChkShowPositionNodes; + QPushButton* m_BtnReinit3DInterpolation; mitk::DataNode::Pointer m_FeedbackNode; mitk::DataNode::Pointer m_InterpolatedSurfaceNode; mitk::DataNode::Pointer m_3DContourNode; mitk::Image* m_Segmentation; mitk::SliceNavigationController* m_LastSNC; unsigned int m_LastSliceIndex; QHash m_TimeStep; bool m_2DInterpolationEnabled; bool m_3DInterpolationEnabled; //unsigned int m_CurrentListID; mitk::DataStorage::Pointer m_DataStorage; QFuture m_Future; QFutureWatcher m_Watcher; QTimer* m_Timer; }; #endif diff --git a/Modules/SurfaceInterpolation/Testing/mitkSurfaceInterpolationControllerTest.cpp b/Modules/SurfaceInterpolation/Testing/mitkSurfaceInterpolationControllerTest.cpp index 2ab70d8ffe..3c8977830f 100644 --- a/Modules/SurfaceInterpolation/Testing/mitkSurfaceInterpolationControllerTest.cpp +++ b/Modules/SurfaceInterpolation/Testing/mitkSurfaceInterpolationControllerTest.cpp @@ -1,397 +1,398 @@ /*=================================================================== 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 #include #include #include #include class mitkSurfaceInterpolationControllerTestSuite : public mitk::TestFixture { CPPUNIT_TEST_SUITE(mitkSurfaceInterpolationControllerTestSuite); MITK_TEST(TestSingleton); MITK_TEST(TestSetCurrentInterpolationSession); MITK_TEST(TestRemoveAllInterpolationSessions); MITK_TEST(TestRemoveInterpolationSession); MITK_TEST(TestOnSegmentationDeleted); /// \todo Workaround for memory leak in TestAddNewContour. Bug 18096. vtkDebugLeaks::SetExitError(0); MITK_TEST(TestAddNewContour); MITK_TEST(TestRemoveContour); CPPUNIT_TEST_SUITE_END(); private: mitk::SurfaceInterpolationController::Pointer m_Controller; public: mitk::Image::Pointer createImage(unsigned int *dimensions) { mitk::Image::Pointer newImage = mitk::Image::New(); mitk::PixelType p_type = mitk::MakeScalarPixelType(); newImage->Initialize(p_type, 3, dimensions); return newImage; } - const mitk::PlaneGeometry* createPlaneForContour(mitk::BaseGeometry* geo, vtkPolyData* contour, mitk::PlaneGeometry::PlaneOrientation orientation) - { - mitk::PlaneGeometry::Pointer plane = mitk::PlaneGeometry::New(); - mitk::Point3D p = contour->GetPoint(0); - geo->WorldToIndex(p,p); - unsigned int sliceIndex; - if (orientation == mitk::PlaneGeometry::Axial) - { - sliceIndex = p[2]; - } - else if (orientation == mitk::PlaneGeometry::Sagittal) - { - sliceIndex = p[0]; - } - else - { - sliceIndex = p[1]; - } - plane->InitializeStandardPlane(geo, orientation, sliceIndex, true, false); - mitk::Point3D origin = plane->GetOrigin(); - mitk::Vector3D normal; - normal = plane->GetNormal(); - normal.Normalize(); - origin += normal * 0.5; - plane->SetOrigin(origin); - return plane; - } - void setUp() { m_Controller = mitk::SurfaceInterpolationController::GetInstance(); vtkSmartPointer polygonSource = vtkSmartPointer::New(); polygonSource->SetRadius(100); polygonSource->SetNumberOfSides(7); polygonSource->Update(); mitk::Surface::Pointer surface = mitk::Surface::New(); surface->SetVtkPolyData(polygonSource->GetOutput()); } void TestSingleton() { mitk::SurfaceInterpolationController::Pointer controller2 = mitk::SurfaceInterpolationController::GetInstance(); CPPUNIT_ASSERT_MESSAGE("SurfaceInterpolationController pointers are not equal!", m_Controller.GetPointer() == controller2.GetPointer()); } void TestSetCurrentInterpolationSession() { // Create image for testing unsigned int dimensions1[] = {10, 10, 10}; mitk::Image::Pointer segmentation_1 = createImage(dimensions1); unsigned int dimensions2[] = {20, 10, 30}; mitk::Image::Pointer segmentation_2 = createImage(dimensions2); // Test 1 m_Controller->SetCurrentInterpolationSession(segmentation_1); MITK_ASSERT_EQUAL(m_Controller->GetCurrentSegmentation(), segmentation_1->Clone(), "Segmentation images are not equal"); CPPUNIT_ASSERT_MESSAGE("Segmentation images are not equal", m_Controller->GetCurrentSegmentation().GetPointer() == segmentation_1.GetPointer()); CPPUNIT_ASSERT_MESSAGE("Number of interpolation session not 1", m_Controller->GetNumberOfInterpolationSessions() == 1); // Test 2 m_Controller->SetCurrentInterpolationSession(segmentation_2); MITK_ASSERT_EQUAL(m_Controller->GetCurrentSegmentation(), segmentation_2->Clone(), "Segmentation images are not equal"); CPPUNIT_ASSERT_MESSAGE("Segmentation images are not equal", m_Controller->GetCurrentSegmentation().GetPointer() == segmentation_2.GetPointer()); CPPUNIT_ASSERT_MESSAGE("Number of interpolation session not 2", m_Controller->GetNumberOfInterpolationSessions() == 2); // Test 3 m_Controller->SetCurrentInterpolationSession(segmentation_1); MITK_ASSERT_EQUAL(m_Controller->GetCurrentSegmentation(), segmentation_1->Clone(), "Segmentation images are not equal"); CPPUNIT_ASSERT_MESSAGE("Segmentation images are not equal", m_Controller->GetCurrentSegmentation().GetPointer() == segmentation_1.GetPointer()); CPPUNIT_ASSERT_MESSAGE("Number of interpolation session not 2", m_Controller->GetNumberOfInterpolationSessions() == 2); // Test 4 m_Controller->SetCurrentInterpolationSession(segmentation_1); MITK_ASSERT_EQUAL(m_Controller->GetCurrentSegmentation(), segmentation_1->Clone(), "Segmentation images are not equal"); CPPUNIT_ASSERT_MESSAGE("Segmentation images are not equal", m_Controller->GetCurrentSegmentation().GetPointer() == segmentation_1.GetPointer()); CPPUNIT_ASSERT_MESSAGE("Number of interpolation session not 2", m_Controller->GetNumberOfInterpolationSessions() == 2); // Test 5 m_Controller->SetCurrentInterpolationSession(0); CPPUNIT_ASSERT_MESSAGE("Segmentation images are not equal", m_Controller->GetCurrentSegmentation().IsNull()); CPPUNIT_ASSERT_MESSAGE("Number of interpolation session not 2", m_Controller->GetNumberOfInterpolationSessions() == 2); } void TestRemoveAllInterpolationSessions() { // Create image for testing unsigned int dimensions1[] = {10, 10, 10}; mitk::Image::Pointer segmentation_1 = createImage(dimensions1); unsigned int dimensions2[] = {20, 10, 30}; mitk::Image::Pointer segmentation_2 = createImage(dimensions2); // Test 1 m_Controller->SetCurrentInterpolationSession(segmentation_1); m_Controller->SetCurrentInterpolationSession(segmentation_2); m_Controller->RemoveAllInterpolationSessions(); CPPUNIT_ASSERT_MESSAGE("Number of interpolation session not 0", m_Controller->GetNumberOfInterpolationSessions() == 0); } void TestRemoveInterpolationSession() { // Create image for testing unsigned int dimensions1[] = {10, 10, 10}; mitk::Image::Pointer segmentation_1 = createImage(dimensions1); unsigned int dimensions2[] = {20, 10, 30}; mitk::Image::Pointer segmentation_2 = createImage(dimensions2); // Test 1 m_Controller->SetCurrentInterpolationSession(segmentation_1); m_Controller->SetCurrentInterpolationSession(segmentation_2); CPPUNIT_ASSERT_MESSAGE("Number of interpolation session not 2", m_Controller->GetNumberOfInterpolationSessions() == 2); // Test current segmentation should not be null if another one was removed m_Controller->RemoveInterpolationSession(segmentation_1); CPPUNIT_ASSERT_MESSAGE("Number of interpolation session not 1", m_Controller->GetNumberOfInterpolationSessions() == 1); CPPUNIT_ASSERT_MESSAGE("Segmentation images are not equal", m_Controller->GetCurrentSegmentation().GetPointer() == segmentation_2.GetPointer()); CPPUNIT_ASSERT_MESSAGE("Current segmentation is null after another one was removed", m_Controller->GetCurrentSegmentation().IsNotNull()); m_Controller->SetCurrentInterpolationSession(segmentation_1); CPPUNIT_ASSERT_MESSAGE("Number of interpolation session not 2", m_Controller->GetNumberOfInterpolationSessions() == 2); // Test current segmentation should not be null if another one was removed m_Controller->RemoveInterpolationSession(segmentation_1); CPPUNIT_ASSERT_MESSAGE("Number of interpolation session not 1", m_Controller->GetNumberOfInterpolationSessions() == 1); CPPUNIT_ASSERT_MESSAGE("Current segmentation is not null after session was removed", m_Controller->GetCurrentSegmentation().IsNull()); } void TestOnSegmentationDeleted() { { // Create image for testing unsigned int dimensions1[] = {10, 10, 10}; mitk::Image::Pointer segmentation_1 = createImage(dimensions1); m_Controller->SetCurrentInterpolationSession(segmentation_1); } CPPUNIT_ASSERT_MESSAGE("Number of interpolation session not 0", m_Controller->GetNumberOfInterpolationSessions() == 0); } void TestAddNewContour() { // Create segmentation image unsigned int dimensions1[] = {10, 10, 10}; mitk::Image::Pointer segmentation_1 = createImage(dimensions1); - mitk::BaseGeometry* geo_1 = segmentation_1->GetGeometry(); m_Controller->SetCurrentInterpolationSession(segmentation_1); // Create some contours + double center_1[3] = {1.25f ,3.43f ,4.44f}; + double normal_1[3] = {0.25f ,1.76f, 0.93f}; vtkSmartPointer p_source = vtkSmartPointer::New(); p_source->SetNumberOfSides(20); - p_source->SetCenter(4.0,4.0,4.0); + p_source->SetCenter(center_1); p_source->SetRadius(4); - p_source->SetNormal(0,1,0); + p_source->SetNormal(normal_1); p_source->Update(); vtkPolyData* poly_1 = p_source->GetOutput(); mitk::Surface::Pointer surf_1 = mitk::Surface::New(); surf_1->SetVtkPolyData(poly_1); + double center_2[3] = {4.0f ,4.0f ,4.0f}; + double normal_2[3] = {1.0f ,0.0f, 0.0f}; vtkSmartPointer p_source_2 = vtkSmartPointer::New(); p_source_2->SetNumberOfSides(80); - p_source_2->SetCenter(4.0,4.0,4.0); + p_source_2->SetCenter(center_2); p_source_2->SetRadius(4); - p_source_2->SetNormal(1, 0, 0); + p_source_2->SetNormal(normal_2); p_source_2->Update(); vtkPolyData* poly_2 = p_source_2->GetOutput(); mitk::Surface::Pointer surf_2 = mitk::Surface::New(); surf_2->SetVtkPolyData(poly_2); + double center_3[3] = {4.0f ,4.0f ,3.0f}; + double normal_3[3] = {0.0f ,0.0f, 1.0f}; vtkSmartPointer p_source_3 = vtkSmartPointer::New(); p_source_3->SetNumberOfSides(10); - p_source_3->SetCenter(4.0,4.0,3.0); + p_source_3->SetCenter(center_3); p_source_3->SetRadius(4); - p_source_3->SetNormal(0,0,1); + p_source_3->SetNormal(normal_3); p_source_3->Update(); vtkPolyData* poly_3 = p_source_3->GetOutput(); mitk::Surface::Pointer surf_3 = mitk::Surface::New(); surf_3->SetVtkPolyData(poly_3); - // Create planes for contours - mitk::PlaneGeometry::ConstPointer plane_1 = createPlaneForContour(geo_1, poly_1, mitk::PlaneGeometry::Frontal); - mitk::PlaneGeometry::ConstPointer plane_2 = createPlaneForContour(geo_1, poly_2, mitk::PlaneGeometry::Sagittal); - mitk::PlaneGeometry::ConstPointer plane_3 = createPlaneForContour(geo_1, poly_3, mitk::PlaneGeometry::Axial); - // Add contours - m_Controller->AddNewContour(surf_1, plane_1); - m_Controller->AddNewContour(surf_2, plane_2); - m_Controller->AddNewContour(surf_3, plane_3); + m_Controller->AddNewContour(surf_1); + m_Controller->AddNewContour(surf_2); + m_Controller->AddNewContour(surf_3); // Check if all contours are there - mitk::PlaneGeometry::ConstPointer plane_1_clone = const_cast(plane_1->Clone().GetPointer()); - mitk::PlaneGeometry::ConstPointer plane_2_clone = const_cast(plane_2->Clone().GetPointer()); - mitk::PlaneGeometry::ConstPointer plane_3_clone = const_cast(plane_3->Clone().GetPointer()); - mitk::Surface* contour_1 = const_cast(m_Controller->GetContour(plane_1_clone)); - mitk::Surface* contour_2 = const_cast(m_Controller->GetContour(plane_2_clone)); - mitk::Surface* contour_3 = const_cast(m_Controller->GetContour(plane_3_clone)); + mitk::SurfaceInterpolationController::ContourPositionInformation contourInfo1; + contourInfo1.contourNormal = normal_1; + contourInfo1.contourPoint = center_1; + + mitk::SurfaceInterpolationController::ContourPositionInformation contourInfo2; + contourInfo2.contourNormal = normal_2; + contourInfo2.contourPoint = center_2; + + mitk::SurfaceInterpolationController::ContourPositionInformation contourInfo3; + contourInfo3.contourNormal = normal_3; + contourInfo3.contourPoint = center_3; + + const mitk::Surface* contour_1 = m_Controller->GetContour(contourInfo1); + const mitk::Surface* contour_2 = m_Controller->GetContour(contourInfo2); + const mitk::Surface* contour_3 = m_Controller->GetContour(contourInfo3); + CPPUNIT_ASSERT_MESSAGE("Wrong number of contours!", m_Controller->GetNumberOfContours() == 3); CPPUNIT_ASSERT_MESSAGE("Contours not equal!", mitk::Equal(*(surf_1->GetVtkPolyData()), *(contour_1->GetVtkPolyData()), 0.000001, true)); CPPUNIT_ASSERT_MESSAGE("Contours not equal!", mitk::Equal(*(surf_2->GetVtkPolyData()), *(contour_2->GetVtkPolyData()), 0.000001, true)); CPPUNIT_ASSERT_MESSAGE("Contours not equal!", mitk::Equal(*(surf_3->GetVtkPolyData()), *(contour_3->GetVtkPolyData()), 0.000001, true)); // Create another segmentation image unsigned int dimensions2[] = {20, 20, 20}; mitk::Image::Pointer segmentation_2 = createImage(dimensions2); - mitk::BaseGeometry* geo_2 = segmentation_2->GetGeometry(); m_Controller->SetCurrentInterpolationSession(segmentation_2); // Create some contours + double center_4[3] = {10.0f ,10.0f ,10.0f}; + double normal_4[3] = {0.0f ,1.0f, 0.0f}; vtkSmartPointer p_source_4 = vtkSmartPointer::New(); p_source_4->SetNumberOfSides(8); - p_source_4->SetCenter(10.0,10.0,10.0); + p_source_4->SetCenter(center_4); p_source_4->SetRadius(5); - p_source_4->SetNormal(0,1,0); + p_source_4->SetNormal(normal_4); p_source_4->Update(); vtkPolyData* poly_4 = p_source_4->GetOutput(); mitk::Surface::Pointer surf_4 = mitk::Surface::New(); surf_4->SetVtkPolyData(poly_4); + double center_5[3] = {3.0f ,10.0f ,10.0f}; + double normal_5[3] = {1.0f ,0.0f, 0.0f}; vtkSmartPointer p_source_5 = vtkSmartPointer::New(); p_source_5->SetNumberOfSides(16); - p_source_5->SetCenter(3.0,10.0,10.0); + p_source_5->SetCenter(center_5); p_source_5->SetRadius(8); - p_source_5->SetNormal(1, 0, 0); + p_source_5->SetNormal(normal_5); p_source_5->Update(); vtkPolyData* poly_5 = p_source_5->GetOutput(); mitk::Surface::Pointer surf_5 = mitk::Surface::New(); surf_5->SetVtkPolyData(poly_5); + double center_6[3] = {10.0f ,10.0f ,3.0f}; + double normal_6[3] = {0.0f ,0.0f, 1.0f}; vtkSmartPointer p_source_6 = vtkSmartPointer::New(); p_source_6->SetNumberOfSides(100); - p_source_6->SetCenter(10.0,10.0,3.0); + p_source_6->SetCenter(center_6); p_source_6->SetRadius(5); - p_source_6->SetNormal(0,0,1); + p_source_6->SetNormal(normal_6); p_source_6->Update(); vtkPolyData* poly_6 = p_source_6->GetOutput(); mitk::Surface::Pointer surf_6 = mitk::Surface::New(); surf_6->SetVtkPolyData(poly_6); - // Create planes for contours - mitk::PlaneGeometry::ConstPointer plane_4 = createPlaneForContour(geo_2, poly_4, mitk::PlaneGeometry::Frontal); - mitk::PlaneGeometry::ConstPointer plane_5 = createPlaneForContour(geo_2, poly_5, mitk::PlaneGeometry::Sagittal); - mitk::PlaneGeometry::ConstPointer plane_6 = createPlaneForContour(geo_2, poly_6, mitk::PlaneGeometry::Axial); + mitk::SurfaceInterpolationController::ContourPositionInformation contourInfo4; + contourInfo4.contourNormal = normal_4; + contourInfo4.contourPoint = center_4; + + mitk::SurfaceInterpolationController::ContourPositionInformation contourInfo5; + contourInfo5.contourNormal = normal_5; + contourInfo5.contourPoint = center_5; + + mitk::SurfaceInterpolationController::ContourPositionInformation contourInfo6; + contourInfo6.contourNormal = normal_6; + contourInfo6.contourPoint = center_6; // Add contours - m_Controller->AddNewContour(surf_4, plane_4); - m_Controller->AddNewContour(surf_5, plane_5); - m_Controller->AddNewContour(surf_6, plane_6); + m_Controller->AddNewContour(surf_4); + m_Controller->AddNewContour(surf_5); + m_Controller->AddNewContour(surf_6); // Check if all contours are there - mitk::PlaneGeometry::ConstPointer plane_4_clone = const_cast(plane_4->Clone().GetPointer()); - mitk::PlaneGeometry::ConstPointer plane_5_clone = const_cast(plane_5->Clone().GetPointer()); - mitk::PlaneGeometry::ConstPointer plane_6_clone = const_cast(plane_6->Clone().GetPointer()); - mitk::Surface* contour_4 = const_cast(m_Controller->GetContour(plane_4_clone)); - mitk::Surface* contour_5 = const_cast(m_Controller->GetContour(plane_5_clone)); - mitk::Surface* contour_6 = const_cast(m_Controller->GetContour(plane_6_clone)); + mitk::Surface* contour_4 = const_cast(m_Controller->GetContour(contourInfo4)); + mitk::Surface* contour_5 = const_cast(m_Controller->GetContour(contourInfo5)); + mitk::Surface* contour_6 = const_cast(m_Controller->GetContour(contourInfo6)); CPPUNIT_ASSERT_MESSAGE("Wrong number of contours!", m_Controller->GetNumberOfContours() == 3); CPPUNIT_ASSERT_MESSAGE("Contours not equal!", mitk::Equal(*(surf_4->GetVtkPolyData()), *(contour_4->GetVtkPolyData()), 0.000001, true)); CPPUNIT_ASSERT_MESSAGE("Contours not equal!", mitk::Equal(*(surf_5->GetVtkPolyData()), *(contour_5->GetVtkPolyData()), 0.000001, true)); CPPUNIT_ASSERT_MESSAGE("Contours not equal!", mitk::Equal(*(surf_6->GetVtkPolyData()), *(contour_6->GetVtkPolyData()), 0.000001, true)); // Modify some contours vtkSmartPointer p_source_7 = vtkSmartPointer::New(); p_source_7->SetNumberOfSides(200); p_source_7->SetCenter(3.0,10.0,10.0); p_source_7->SetRadius(5); p_source_7->SetNormal(1, 0, 0); p_source_7->Update(); vtkPolyData* poly_7 = p_source_7->GetOutput(); mitk::Surface::Pointer surf_7 = mitk::Surface::New(); surf_7->SetVtkPolyData(poly_7); - m_Controller->AddNewContour(surf_7, plane_5); - mitk::Surface* contour_7 = const_cast(m_Controller->GetContour(plane_5_clone)); + m_Controller->AddNewContour(surf_7); + mitk::Surface* contour_7 = const_cast(m_Controller->GetContour(contourInfo5)); CPPUNIT_ASSERT_MESSAGE("Contours not equal!", mitk::Equal(*(surf_7->GetVtkPolyData()), *(contour_7->GetVtkPolyData()), 0.000001, true)); // Change session and test if all contours are available m_Controller->SetCurrentInterpolationSession(segmentation_1); - mitk::Surface* contour_8 = const_cast(m_Controller->GetContour(plane_1_clone)); - mitk::Surface* contour_9 = const_cast(m_Controller->GetContour(plane_2_clone)); - mitk::Surface* contour_10 = const_cast(m_Controller->GetContour(plane_3_clone)); + mitk::Surface* contour_8 = const_cast(m_Controller->GetContour(contourInfo1)); + mitk::Surface* contour_9 = const_cast(m_Controller->GetContour(contourInfo2)); + mitk::Surface* contour_10 = const_cast(m_Controller->GetContour(contourInfo3)); CPPUNIT_ASSERT_MESSAGE("Wrong number of contours!", m_Controller->GetNumberOfContours() == 3); CPPUNIT_ASSERT_MESSAGE("Contours not equal!", mitk::Equal(*(surf_1->GetVtkPolyData()), *(contour_8->GetVtkPolyData()), 0.000001, true)); CPPUNIT_ASSERT_MESSAGE("Contours not equal!", mitk::Equal(*(surf_2->GetVtkPolyData()), *(contour_9->GetVtkPolyData()), 0.000001, true)); CPPUNIT_ASSERT_MESSAGE("Contours not equal!", mitk::Equal(*(surf_3->GetVtkPolyData()), *(contour_10->GetVtkPolyData()), 0.000001, true)); } void TestRemoveContour() { // Create segmentation image unsigned int dimensions1[] = {10, 10, 10}; mitk::Image::Pointer segmentation_1 = createImage(dimensions1); - mitk::BaseGeometry* geo_1 = segmentation_1->GetGeometry(); m_Controller->SetCurrentInterpolationSession(segmentation_1); // Create some contours + double center_1[3] = {4.0f ,4.0f ,4.0f}; + double normal_1[3] = {0.0f ,1.0f, 0.0f}; vtkSmartPointer p_source = vtkSmartPointer::New(); p_source->SetNumberOfSides(20); - p_source->SetCenter(4.0,4.0,4.0); + p_source->SetCenter(center_1); p_source->SetRadius(4); - p_source->SetNormal(0,1,0); + p_source->SetNormal(normal_1); p_source->Update(); vtkPolyData* poly_1 = p_source->GetOutput(); mitk::Surface::Pointer surf_1 = mitk::Surface::New(); surf_1->SetVtkPolyData(poly_1); + double center_2[3] = {4.0f ,4.0f ,4.0f}; + double normal_2[3] = {1.0f ,0.0f, 0.0f}; vtkSmartPointer p_source_2 = vtkSmartPointer::New(); p_source_2->SetNumberOfSides(80); - p_source_2->SetCenter(4.0,4.0,4.0); + p_source_2->SetCenter(center_2); p_source_2->SetRadius(4); - p_source_2->SetNormal(1, 0, 0); + p_source_2->SetNormal(normal_2); p_source_2->Update(); vtkPolyData* poly_2 = p_source_2->GetOutput(); mitk::Surface::Pointer surf_2 = mitk::Surface::New(); surf_2->SetVtkPolyData(poly_2); - // Create planes for contours - mitk::PlaneGeometry::ConstPointer plane_1 = createPlaneForContour(geo_1, poly_1, mitk::PlaneGeometry::Frontal); - mitk::PlaneGeometry::ConstPointer plane_2 = createPlaneForContour(geo_1, poly_2, mitk::PlaneGeometry::Sagittal); - // Add contours - m_Controller->AddNewContour(surf_1, plane_1); - m_Controller->AddNewContour(surf_2, plane_2); - MITK_INFO<<"[NUM CONTOURS]: "<GetNumberOfContours(); + m_Controller->AddNewContour(surf_1); + m_Controller->AddNewContour(surf_2); CPPUNIT_ASSERT_MESSAGE("Wrong number of contours!", m_Controller->GetNumberOfContours() == 2); - // Remove a contour - bool success = m_Controller->RemoveContour(plane_1); - CPPUNIT_ASSERT_MESSAGE("Remove failed - contour not removed correctly!", (m_Controller->GetNumberOfContours() == 1) && success); - - // Test remove non existing contour - mitk::PlaneGeometry::Pointer plane_3 = plane_1->Clone(); - mitk::Point3D origin = plane_3->GetOrigin(); - origin += 0.5; - plane_3->SetOrigin(origin); + mitk::SurfaceInterpolationController::ContourPositionInformation contourInfo3; + contourInfo3.contour = surf_1->Clone(); + contourInfo3.contourNormal = normal_1; + contourInfo3.contourPoint = center_1; + // Shift the new contour so that it is different + contourInfo3.contourPoint += 0.5; + + bool success = m_Controller->RemoveContour(contourInfo3); + CPPUNIT_ASSERT_MESSAGE("Remove failed - contour was unintentionally removed!", (m_Controller->GetNumberOfContours() == 2) && !success); + + mitk::SurfaceInterpolationController::ContourPositionInformation contourInfo2; + contourInfo2.contourNormal = normal_2; + contourInfo2.contourPoint = center_2; + contourInfo2.contour = surf_2; + success = m_Controller->RemoveContour(contourInfo2); + CPPUNIT_ASSERT_MESSAGE("Remove failed - contour was not removed!", (m_Controller->GetNumberOfContours() == 1) && success); + + // Let's see if the other contour No. 1 is still there + contourInfo3.contourPoint -= 0.5; + const mitk::Surface* remainingContour = m_Controller->GetContour(contourInfo3); + CPPUNIT_ASSERT_MESSAGE("Remove failed - contour was accidentally removed!", + (m_Controller->GetNumberOfContours() == 1) && + mitk::Equal(*(surf_1->GetVtkPolyData()), *(remainingContour->GetVtkPolyData()), 0.000001, true) &&success); - success = m_Controller->RemoveContour(plane_3); - CPPUNIT_ASSERT_MESSAGE("Remove failed - contour was unintentionally removed!", (m_Controller->GetNumberOfContours() == 1) && !success); } }; MITK_TEST_SUITE_REGISTRATION(mitkSurfaceInterpolationController) diff --git a/Modules/SurfaceInterpolation/mitkSurfaceInterpolationController.cpp b/Modules/SurfaceInterpolation/mitkSurfaceInterpolationController.cpp index 3b7119e0fa..8453c381c8 100644 --- a/Modules/SurfaceInterpolation/mitkSurfaceInterpolationController.cpp +++ b/Modules/SurfaceInterpolation/mitkSurfaceInterpolationController.cpp @@ -1,383 +1,531 @@ /*=================================================================== 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 "mitkSurfaceInterpolationController.h" #include "mitkMemoryUtilities.h" #include "mitkImageAccessByItk.h" #include "mitkImageCast.h" #include "mitkImageToSurfaceFilter.h" +bool ContoursCoplanar(mitk::SurfaceInterpolationController::ContourPositionInformation leftHandSide, mitk::SurfaceInterpolationController::ContourPositionInformation rightHandSide) +{ + double vec[3]; + vec[0] = leftHandSide.contourPoint[0] - rightHandSide.contourPoint[0]; + vec[1] = leftHandSide.contourPoint[1] - rightHandSide.contourPoint[1]; + vec[2] = leftHandSide.contourPoint[2] - rightHandSide.contourPoint[2]; + double n[3]; + n[0] = rightHandSide.contourNormal[0]; + n[1] = rightHandSide.contourNormal[1]; + n[2] = rightHandSide.contourNormal[2]; + double dot = vtkMath::Dot(n, vec); + + double n2[3]; + n2[0] = leftHandSide.contourNormal[0]; + n2[1] = leftHandSide.contourNormal[1]; + n2[2] = leftHandSide.contourNormal[2]; + + // The normals of both contours have to be parallel but not of the same orientation + double lengthLHS = leftHandSide.contourNormal.GetNorm(); + double lengthRHS = rightHandSide.contourNormal.GetNorm(); + double dot2 = vtkMath::Dot(n, n2); + + if (mitk::Equal(dot, 0.0, 0.001) && mitk::Equal(fabs(lengthLHS*lengthRHS), fabs(dot2), 0.001)) + return true; + else + return false; +} + +mitk::SurfaceInterpolationController::ContourPositionInformation CreateContourPositionInformation(mitk::Surface::Pointer contour) +{ + mitk::SurfaceInterpolationController::ContourPositionInformation contourInfo; + contourInfo.contour = contour; + double n[3]; + double p[3]; + contour->GetVtkPolyData()->GetPoints()->GetPoint(0, p); + vtkPolygon::ComputeNormal(contour->GetVtkPolyData()->GetPoints(), n); + contourInfo.contourNormal = n; + contourInfo.contourPoint = p; + return contourInfo; +} + mitk::SurfaceInterpolationController::SurfaceInterpolationController() :m_SelectedSegmentation(0) { m_ReduceFilter = ReduceContourSetFilter::New(); m_NormalsFilter = ComputeContourSetNormalsFilter::New(); m_InterpolateSurfaceFilter = CreateDistanceImageFromSurfaceFilter::New(); m_ReduceFilter->SetUseProgressBar(false); m_NormalsFilter->SetUseProgressBar(false); m_InterpolateSurfaceFilter->SetUseProgressBar(false); m_Contours = Surface::New(); m_PolyData = vtkSmartPointer::New(); vtkSmartPointer points = vtkSmartPointer::New(); m_PolyData->SetPoints(points); m_InterpolationResult = 0; m_CurrentNumberOfReducedContours = 0; } mitk::SurfaceInterpolationController::~SurfaceInterpolationController() { //Removing all observers std::map::iterator dataIter = m_SegmentationObserverTags.begin(); for (; dataIter != m_SegmentationObserverTags.end(); ++dataIter ) { (*dataIter).first->RemoveObserver( (*dataIter).second ); } m_SegmentationObserverTags.clear(); } mitk::SurfaceInterpolationController* mitk::SurfaceInterpolationController::GetInstance() { static mitk::SurfaceInterpolationController::Pointer m_Instance; if ( m_Instance.IsNull() ) { m_Instance = SurfaceInterpolationController::New(); } return m_Instance; } -void mitk::SurfaceInterpolationController::AddNewContour (mitk::Surface::Pointer newContour, PlaneGeometry::ConstPointer plane) +void mitk::SurfaceInterpolationController::AddNewContour (mitk::Surface::Pointer newContour) { - ContourPositionPair pair; - pair.contour = newContour; - pair.plane = plane; - this->AddToInterpolationPipeline(pair); + ContourPositionInformation contourInfo = CreateContourPositionInformation(newContour); + this->AddToInterpolationPipeline(contourInfo); this->Modified(); } -void mitk::SurfaceInterpolationController::AddNewContours(ContourPositionPairList newContours) +void mitk::SurfaceInterpolationController::AddNewContours(std::vector newContours) { for (unsigned int i = 0; i < newContours.size(); ++i) { - this->AddToInterpolationPipeline(newContours.at(i)); + ContourPositionInformation contourInfo = CreateContourPositionInformation(newContours.at(i)); + this->AddToInterpolationPipeline(contourInfo); } this->Modified(); } -void mitk::SurfaceInterpolationController::AddToInterpolationPipeline(ContourPositionPair pair) +void mitk::SurfaceInterpolationController::AddToInterpolationPipeline(ContourPositionInformation contourInfo) { int pos (-1); - ContourPositionPairList currentContourList = m_ListOfInterpolationSessions[m_SelectedSegmentation]; - const mitk::PlaneGeometry* plane = pair.plane; - mitk::Surface* newContour = pair.contour; + ContourPositionInformationList currentContourList = m_ListOfInterpolationSessions[m_SelectedSegmentation]; + mitk::Surface* newContour = contourInfo.contour; for (unsigned int i = 0; i < currentContourList.size(); i++) { - mitk::PlaneGeometry::ConstPointer planeFromList = currentContourList.at(i).plane; - if ( mitk::Equal(*plane, *planeFromList, mitk::eps, false) ) + ContourPositionInformation contourFromList = currentContourList.at(i); + if (ContoursCoplanar(contourInfo, contourFromList)) { pos = i; break; } } //Don't save a new empty contour if (pos == -1 && newContour->GetVtkPolyData()->GetNumberOfPoints() > 0) { m_ReduceFilter->SetInput(m_ListOfInterpolationSessions[m_SelectedSegmentation].size(), newContour); - m_ListOfInterpolationSessions[m_SelectedSegmentation].push_back(pair); + m_ListOfInterpolationSessions[m_SelectedSegmentation].push_back(contourInfo); } else if (pos != -1 && newContour->GetVtkPolyData()->GetNumberOfPoints() > 0) { - m_ListOfInterpolationSessions[m_SelectedSegmentation].at(pos) = pair; + m_ListOfInterpolationSessions[m_SelectedSegmentation].at(pos) = contourInfo; m_ReduceFilter->SetInput(pos, newContour); } else if (newContour->GetVtkPolyData()->GetNumberOfPoints() == 0) { - this->RemoveContour(plane); + this->RemoveContour(contourInfo); } m_ReduceFilter->Update(); m_CurrentNumberOfReducedContours = m_ReduceFilter->GetNumberOfOutputs(); for (unsigned int i = 0; i < m_CurrentNumberOfReducedContours; i++) { m_NormalsFilter->SetInput(i, m_ReduceFilter->GetOutput(i)); m_InterpolateSurfaceFilter->SetInput(i, m_NormalsFilter->GetOutput(i)); } } -bool mitk::SurfaceInterpolationController::RemoveContour(const mitk::PlaneGeometry *plane) +bool mitk::SurfaceInterpolationController::RemoveContour(ContourPositionInformation contourInfo) { - ContourPositionPairList::iterator it = m_ListOfInterpolationSessions[m_SelectedSegmentation].begin(); + ContourPositionInformationList::iterator it = m_ListOfInterpolationSessions[m_SelectedSegmentation].begin(); while (it != m_ListOfInterpolationSessions[m_SelectedSegmentation].end()) { - ContourPositionPair pair = (*it); - if (mitk::Equal(*plane, *pair.plane, mitk::eps, false)) + ContourPositionInformation currentContour = (*it); + if (ContoursCoplanar(currentContour, contourInfo)) { m_ListOfInterpolationSessions[m_SelectedSegmentation].erase(it); this->ReinitializeInterpolation(); return true; } ++it; } return false; } -const mitk::Surface* mitk::SurfaceInterpolationController::GetContour(mitk::PlaneGeometry::ConstPointer plane) +const mitk::Surface* mitk::SurfaceInterpolationController::GetContour(ContourPositionInformation contourInfo) { - ContourPositionPairList contourList = m_ListOfInterpolationSessions[m_SelectedSegmentation]; + ContourPositionInformationList contourList = m_ListOfInterpolationSessions[m_SelectedSegmentation]; for (unsigned int i = 0; i < contourList.size(); ++i) { - ContourPositionPair pair = contourList.at(i); - if (mitk::Equal(*plane, *pair.plane, mitk::eps, false)) - return pair.contour; + ContourPositionInformation currentContour = contourList.at(i); + if (ContoursCoplanar(contourInfo, currentContour)) + return currentContour.contour; } return 0; } unsigned int mitk::SurfaceInterpolationController::GetNumberOfContours() { return m_ListOfInterpolationSessions[m_SelectedSegmentation].size(); } void mitk::SurfaceInterpolationController::Interpolate() { if (m_CurrentNumberOfReducedContours< 2) { //If no interpolation is possible reset the interpolation result m_InterpolationResult = 0; return; } //Setting up progress bar /* * Removed due to bug 12441. ProgressBar messes around with Qt event queue which is fatal for segmentation */ //mitk::ProgressBar::GetInstance()->AddStepsToDo(8); // create a surface from the distance-image mitk::ImageToSurfaceFilter::Pointer imageToSurfaceFilter = mitk::ImageToSurfaceFilter::New(); imageToSurfaceFilter->SetInput( m_InterpolateSurfaceFilter->GetOutput() ); imageToSurfaceFilter->SetThreshold( 0 ); imageToSurfaceFilter->SetSmooth(true); imageToSurfaceFilter->SetSmoothIteration(20); imageToSurfaceFilter->Update(); m_InterpolationResult = imageToSurfaceFilter->GetOutput(); vtkSmartPointer polyDataAppender = vtkSmartPointer::New(); - for (unsigned int i = 0; i < m_ReduceFilter->GetNumberOfOutputs(); i++) + for (unsigned int i = 0; i < m_ListOfInterpolationSessions[m_SelectedSegmentation].size(); i++) { - polyDataAppender->AddInputData(m_ReduceFilter->GetOutput(i)->GetVtkPolyData()); + polyDataAppender->AddInputData(m_ListOfInterpolationSessions[m_SelectedSegmentation].at(i).contour->GetVtkPolyData()); } polyDataAppender->Update(); m_Contours->SetVtkPolyData(polyDataAppender->GetOutput()); //Last progress step /* * Removed due to bug 12441. ProgressBar messes around with Qt event queue which is fatal for segmentation */ //mitk::ProgressBar::GetInstance()->Progress(8); m_InterpolationResult->DisconnectPipeline(); } mitk::Surface::Pointer mitk::SurfaceInterpolationController::GetInterpolationResult() { return m_InterpolationResult; } mitk::Surface* mitk::SurfaceInterpolationController::GetContoursAsSurface() { return m_Contours; } void mitk::SurfaceInterpolationController::SetDataStorage(DataStorage::Pointer ds) { m_DataStorage = ds; } void mitk::SurfaceInterpolationController::SetMinSpacing(double minSpacing) { m_ReduceFilter->SetMinSpacing(minSpacing); } void mitk::SurfaceInterpolationController::SetMaxSpacing(double maxSpacing) { m_ReduceFilter->SetMaxSpacing(maxSpacing); m_NormalsFilter->SetMaxSpacing(maxSpacing); } void mitk::SurfaceInterpolationController::SetDistanceImageVolume(unsigned int distImgVolume) { m_InterpolateSurfaceFilter->SetDistanceImageVolume(distImgVolume); } mitk::Image::Pointer mitk::SurfaceInterpolationController::GetCurrentSegmentation() { return m_SelectedSegmentation; } mitk::Image* mitk::SurfaceInterpolationController::GetImage() { return m_InterpolateSurfaceFilter->GetOutput(); } double mitk::SurfaceInterpolationController::EstimatePortionOfNeededMemory() { double numberOfPointsAfterReduction = m_ReduceFilter->GetNumberOfPointsAfterReduction()*3; double sizeOfPoints = pow(numberOfPointsAfterReduction,2)*sizeof(double); double totalMem = mitk::MemoryUtilities::GetTotalSizeOfPhysicalRam(); double percentage = sizeOfPoints/totalMem; return percentage; } unsigned int mitk::SurfaceInterpolationController::GetNumberOfInterpolationSessions() { return m_ListOfInterpolationSessions.size(); } template void mitk::SurfaceInterpolationController::GetImageBase(itk::Image* input, itk::ImageBase<3>::Pointer& result) { result->Graft(input); } void mitk::SurfaceInterpolationController::SetCurrentSegmentationInterpolationList(mitk::Image::Pointer segmentation) { this->SetCurrentInterpolationSession(segmentation); } void mitk::SurfaceInterpolationController::SetCurrentInterpolationSession(mitk::Image::Pointer currentSegmentationImage) { if (currentSegmentationImage.GetPointer() == m_SelectedSegmentation) return; if (currentSegmentationImage.IsNull()) { m_SelectedSegmentation = 0; return; } m_SelectedSegmentation = currentSegmentationImage.GetPointer(); ContourListMap::iterator it = m_ListOfInterpolationSessions.find(currentSegmentationImage.GetPointer()); // If the session does not exist yet create a new ContourPositionPairList otherwise reinitialize the interpolation pipeline if (it == m_ListOfInterpolationSessions.end()) { - ContourPositionPairList newList; - m_ListOfInterpolationSessions.insert(std::pair(m_SelectedSegmentation, newList)); + ContourPositionInformationList newList; + m_ListOfInterpolationSessions.insert(std::pair(m_SelectedSegmentation, newList)); m_InterpolationResult = 0; m_CurrentNumberOfReducedContours = 0; itk::MemberCommand::Pointer command = itk::MemberCommand::New(); command->SetCallbackFunction(this, &SurfaceInterpolationController::OnSegmentationDeleted); m_SegmentationObserverTags.insert( std::pair( m_SelectedSegmentation, m_SelectedSegmentation->AddObserver( itk::DeleteEvent(), command ) ) ); } this->ReinitializeInterpolation(); } void mitk::SurfaceInterpolationController::RemoveSegmentationFromContourList(mitk::Image *segmentation) { this->RemoveInterpolationSession(segmentation); } void mitk::SurfaceInterpolationController::RemoveInterpolationSession(mitk::Image::Pointer segmentationImage) { if (segmentationImage) { if (m_SelectedSegmentation == segmentationImage) { m_NormalsFilter->SetSegmentationBinaryImage(NULL); m_SelectedSegmentation = 0; } m_ListOfInterpolationSessions.erase(segmentationImage); // Remove observer std::map::iterator pos = m_SegmentationObserverTags.find(segmentationImage); if (pos != m_SegmentationObserverTags.end()) { segmentationImage->RemoveObserver((*pos).second); m_SegmentationObserverTags.erase(pos); } } } void mitk::SurfaceInterpolationController::RemoveAllInterpolationSessions() { //Removing all observers std::map::iterator dataIter = m_SegmentationObserverTags.begin(); while (dataIter != m_SegmentationObserverTags.end()) { mitk::Image* image = (*dataIter).first; image->RemoveObserver((*dataIter).second); ++dataIter; } m_SegmentationObserverTags.clear(); m_SelectedSegmentation = 0; m_ListOfInterpolationSessions.clear(); } +void mitk::SurfaceInterpolationController::ReinitializeInterpolation(mitk::Surface::Pointer contours) +{ + // 1. detect coplanar contours + // 2. merge coplanar contours into a single surface + // 4. add contour to pipeline + // 5. create position nodes + + // Split the surface into separate polygons + vtkSmartPointer existingPolys; + vtkSmartPointer existingPoints; + existingPolys = contours->GetVtkPolyData()->GetPolys(); + existingPoints = contours->GetVtkPolyData()->GetPoints(); + existingPolys->InitTraversal(); + + vtkSmartPointer ids = vtkSmartPointer::New(); + + typedef std::pair PointNormalPair; + std::vector list; + std::vector > pointsList; + int count (0); + for( existingPolys->InitTraversal(); existingPolys->GetNextCell(ids);) + { + // Get the points + vtkSmartPointer points = vtkSmartPointer::New(); + existingPoints->GetPoints(ids, points); + ++count; + pointsList.push_back(points); + + + PointNormalPair p_n; + double n[3]; + vtkPolygon::ComputeNormal(points, n); + p_n.first = n; + double p[3]; + + existingPoints->GetPoint(ids->GetId(0), p); + p_n.second = p; + + ContourPositionInformation p_info; + p_info.contourNormal = n; + p_info.contourPoint = p; + list.push_back(p_info); + continue; + } + + // Detect and sort coplanar polygons + std::vector::iterator outer = list.begin(); + std::vector< std::vector< vtkSmartPointer > > relatedPoints; + while (outer != list.end()) + { + std::vector::iterator inner = outer; + ++inner; + std::vector< vtkSmartPointer > rel; + std::vector< vtkSmartPointer >::iterator pointsIter = pointsList.begin(); + rel.push_back((*pointsIter)); + pointsIter = pointsList.erase(pointsIter); + + while (inner != list.end()) + { + if(ContoursCoplanar((*outer),(*inner))) + { + inner = list.erase(inner); + rel.push_back((*pointsIter)); + pointsIter = pointsList.erase(pointsIter); + } + else + { + ++inner; + ++pointsIter; + } + } + relatedPoints.push_back(rel); + ++outer; + } + + // Build the separate surfaces again + std::vector finalSurfaces; + for (unsigned int i = 0; i < relatedPoints.size(); ++i) + { + vtkSmartPointer contourSurface = vtkSmartPointer::New(); + vtkSmartPointer points = vtkSmartPointer::New(); + vtkSmartPointer polygons = vtkSmartPointer::New(); + unsigned int pointId (0); + for (unsigned int j = 0; j < relatedPoints.at(i).size(); ++j) + { + unsigned int numPoints = relatedPoints.at(i).at(j)->GetNumberOfPoints(); + vtkSmartPointer polygon = vtkSmartPointer::New(); + polygon->GetPointIds()->SetNumberOfIds(numPoints); + polygon->GetPoints()->SetNumberOfPoints(numPoints); + vtkSmartPointer currentPoints = relatedPoints.at(i).at(j); + for (unsigned k = 0; k < numPoints; ++k) + { + points->InsertPoint(pointId, currentPoints->GetPoint(k)); + polygon->GetPointIds()->SetId(k, pointId); + ++pointId; + } + polygons->InsertNextCell(polygon); + } + contourSurface->SetPoints(points); + contourSurface->SetPolys(polygons); + contourSurface->BuildLinks(); + mitk::Surface::Pointer surface = mitk::Surface::New(); + surface->SetVtkPolyData(contourSurface); + finalSurfaces.push_back(surface); + } + + this->AddNewContours(finalSurfaces); +} + void mitk::SurfaceInterpolationController::OnSegmentationDeleted(const itk::Object *caller, const itk::EventObject &/*event*/) { mitk::Image* tempImage = dynamic_cast(const_cast(caller)); if (tempImage) { if (m_SelectedSegmentation == tempImage) { m_NormalsFilter->SetSegmentationBinaryImage(NULL); m_SelectedSegmentation = 0; } m_SegmentationObserverTags.erase(tempImage); m_ListOfInterpolationSessions.erase(tempImage); } } void mitk::SurfaceInterpolationController::ReinitializeInterpolation() { m_NormalsFilter->SetSegmentationBinaryImage(m_SelectedSegmentation); // If session has changed reset the pipeline m_ReduceFilter->Reset(); m_NormalsFilter->Reset(); m_InterpolateSurfaceFilter->Reset(); itk::ImageBase<3>::Pointer itkImage = itk::ImageBase<3>::New(); AccessFixedDimensionByItk_1( m_SelectedSegmentation, GetImageBase, 3, itkImage ); m_InterpolateSurfaceFilter->SetReferenceImage(itkImage.GetPointer()); for (unsigned int i = 0; i < m_ListOfInterpolationSessions[m_SelectedSegmentation].size(); i++) { m_ReduceFilter->SetInput(i, m_ListOfInterpolationSessions[m_SelectedSegmentation].at(i).contour); } m_ReduceFilter->Update(); m_CurrentNumberOfReducedContours = m_ReduceFilter->GetNumberOfOutputs(); for (unsigned int i = 0; i < m_CurrentNumberOfReducedContours; i++) { m_NormalsFilter->SetInput(i, m_ReduceFilter->GetOutput(i)); m_InterpolateSurfaceFilter->SetInput(i, m_NormalsFilter->GetOutput(i)); } Modified(); } diff --git a/Modules/SurfaceInterpolation/mitkSurfaceInterpolationController.h b/Modules/SurfaceInterpolation/mitkSurfaceInterpolationController.h index 6bdcc5875f..02e1ce4fea 100644 --- a/Modules/SurfaceInterpolation/mitkSurfaceInterpolationController.h +++ b/Modules/SurfaceInterpolation/mitkSurfaceInterpolationController.h @@ -1,222 +1,227 @@ /*=================================================================== 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 mitkSurfaceInterpolationController_h_Included #define mitkSurfaceInterpolationController_h_Included #include "mitkCommon.h" #include #include "mitkRestorePlanePositionOperation.h" #include "mitkSurface.h" #include "mitkInteractionConst.h" #include "mitkColorProperty.h" #include "mitkProperties.h" #include "mitkCreateDistanceImageFromSurfaceFilter.h" #include "mitkReduceContourSetFilter.h" #include "mitkComputeContourSetNormalsFilter.h" #include "mitkDataNode.h" #include "mitkDataStorage.h" #include "mitkWeakPointer.h" #include "vtkPolygon.h" #include "vtkPoints.h" #include "vtkCellArray.h" #include "vtkPolyData.h" #include "vtkSmartPointer.h" #include "vtkAppendPolyData.h" #include "vtkMarchingCubes.h" #include "vtkImageData.h" #include "mitkVtkRepresentationProperty.h" #include "vtkProperty.h" #include "mitkProgressBar.h" namespace mitk { class MitkSurfaceInterpolation_EXPORT SurfaceInterpolationController : public itk::Object { public: mitkClassMacro(SurfaceInterpolationController, itk::Object) itkFactorylessNewMacro(Self) itkCloneMacro(Self) - struct ContourPositionPair { + struct ContourPositionInformation { Surface::Pointer contour; - mitk::PlaneGeometry::ConstPointer plane; + Vector3D contourNormal; + Point3D contourPoint; }; - typedef std::vector ContourPositionPairList; - typedef std::map ContourListMap; + typedef std::vector ContourPositionInformationList; + typedef std::map ContourListMap; static SurfaceInterpolationController* GetInstance(); /** * @brief Adds a new extracted contour to the list * @param newContour the contour to be added * @param plane the image plane in which the contour lies. If plane already exists the related * contour will be updated */ - void AddNewContour (Surface::Pointer newContour, PlaneGeometry::ConstPointer plane); + void AddNewContour (Surface::Pointer newContour); /** * @brief Removes the contour for a given plane for the current selected segmenation - * @param plane the plane for which the contour should be returned + * @param contourInfo the contour which should be returned * @return true if a contour was found and removed, false if no contour was found */ - bool RemoveContour (const mitk::PlaneGeometry* plane); + bool RemoveContour (ContourPositionInformation contourInfo); /** * @brief Adds new extracted contours to the list. If one or more contours at a given position * already exist they will be updated respectively - * @param newContours the list of the contours and the respective positions + * @param newContours the list of the contours */ - void AddNewContours (ContourPositionPairList newContours); + void AddNewContours (std::vector newContours); /** * @brief Returns the contour for a given plane for the current selected segmenation * @param plane the plane for which the contour should be returned * @return the contour as an mitk::Surface. If no contour is available for the plane NULL is returned */ - const mitk::Surface* GetContour (PlaneGeometry::ConstPointer plane); + const mitk::Surface* GetContour (ContourPositionInformation contourInfo); /** * @brief Returns the number of available contours for the current selected segmentation * @return the number of contours */ unsigned int GetNumberOfContours(); /** * Interpolates the 3D surface from the given extracted contours */ void Interpolate (); mitk::Surface::Pointer GetInterpolationResult(); /** * Sets the minimum spacing of the current selected segmentation * This is needed since the contour points we reduced before they are used to interpolate the surface */ void SetMinSpacing(double minSpacing); /** * Sets the minimum spacing of the current selected segmentation * This is needed since the contour points we reduced before they are used to interpolate the surface */ void SetMaxSpacing(double maxSpacing); /** * Sets the volume i.e. the number of pixels that the distance image should have * By evaluation we found out that 50.000 pixel delivers a good result */ void SetDistanceImageVolume(unsigned int distImageVolume); /** * @brief Get the current selected segmentation for which the interpolation is performed * @return the current segmentation image */ mitk::Image::Pointer GetCurrentSegmentation(); Surface* GetContoursAsSurface(); void SetDataStorage(DataStorage::Pointer ds); /** * Sets the current list of contourpoints which is used for the surface interpolation * @param segmentation The current selected segmentation * \deprecatedSince{2014_03} */ DEPRECATED (void SetCurrentSegmentationInterpolationList(mitk::Image::Pointer segmentation)); /** * Sets the current list of contourpoints which is used for the surface interpolation * @param segmentation The current selected segmentation */ void SetCurrentInterpolationSession(mitk::Image::Pointer currentSegmentationImage); /** * Removes the segmentation and all its contours from the list * @param segmentation The segmentation to be removed * \deprecatedSince{2014_03} */ DEPRECATED (void RemoveSegmentationFromContourList(mitk::Image* segmentation)); /** * @brief Remove interpolation session * @param segmentationImage the session to be removed */ void RemoveInterpolationSession(mitk::Image::Pointer segmentationImage); /** * @brief Removes all sessions */ void RemoveAllInterpolationSessions(); + /** + * @brief Reinitializes the interpolation using the provided contour data + * @param contours a mitk::Surface which contains the contours as polys in the vtkPolyData + */ + void ReinitializeInterpolation(mitk::Surface::Pointer contours); + mitk::Image* GetImage(); /** * Estimates the memory which is needed to build up the equationsystem for the interpolation. * \returns The percentage of the real memory which will be used by the interpolation */ double EstimatePortionOfNeededMemory(); unsigned int GetNumberOfInterpolationSessions(); protected: SurfaceInterpolationController(); ~SurfaceInterpolationController(); template void GetImageBase(itk::Image* input, itk::ImageBase<3>::Pointer& result); private: void OnSegmentationDeleted(const itk::Object *caller, const itk::EventObject &event); void ReinitializeInterpolation(); - void AddToInterpolationPipeline(ContourPositionPair pair); - - ContourPositionPairList::iterator m_Iterator; + void AddToInterpolationPipeline(ContourPositionInformation contourInfo); ReduceContourSetFilter::Pointer m_ReduceFilter; ComputeContourSetNormalsFilter::Pointer m_NormalsFilter; CreateDistanceImageFromSurfaceFilter::Pointer m_InterpolateSurfaceFilter; Surface::Pointer m_Contours; vtkSmartPointer m_PolyData; mitk::DataStorage::Pointer m_DataStorage; ContourListMap m_ListOfInterpolationSessions; mitk::Surface::Pointer m_InterpolationResult; unsigned int m_CurrentNumberOfReducedContours; mitk::Image* m_SelectedSegmentation; std::map m_SegmentationObserverTags; }; } #endif