diff --git a/Modules/Bundles/org.mitk.gui.qt.diffusionimaging/src/internal/QmitkControlVisualizationPropertiesView.cpp b/Modules/Bundles/org.mitk.gui.qt.diffusionimaging/src/internal/QmitkControlVisualizationPropertiesView.cpp index 273f0074cd..3745399944 100644 --- a/Modules/Bundles/org.mitk.gui.qt.diffusionimaging/src/internal/QmitkControlVisualizationPropertiesView.cpp +++ b/Modules/Bundles/org.mitk.gui.qt.diffusionimaging/src/internal/QmitkControlVisualizationPropertiesView.cpp @@ -1,1544 +1,1547 @@ /*========================================================================= Program: Medical Imaging & Interaction Toolkit Module: $RCSfile$ Language: C++ Date: $Date: 2009-05-28 17:19:30 +0200 (Do, 28 Mai 2009) $ Version: $Revision: 17495 $ Copyright (c) German Cancer Research Center, Division of Medical and Biological Informatics. All rights reserved. See MITKCopyright.txt or http://www.mitk.org/copyright.html for details. This software is distributed WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the above copyright notices for more information. =========================================================================*/ #include "QmitkControlVisualizationPropertiesView.h" #include "mitkNodePredicateDataType.h" #include "mitkDataNodeObject.h" #include "mitkOdfNormalizationMethodProperty.h" #include "mitkOdfScaleByProperty.h" #include "mitkResliceMethodProperty.h" #include "mitkRenderingManager.h" #include "mitkDiffusionImage.h" #include "mitkPlanarFigure.h" #include "mitkFiberBundle.h" #include "QmitkDataStorageComboBox.h" #include "QmitkStdMultiWidget.h" #include "mitkFiberBundleInteractor.h" #include "mitkPlanarFigureInteractor.h" #include "mitkGlobalInteraction.h" #include "mitkGeometry2D.h" #include "berryIWorkbenchWindow.h" #include "berryIWorkbenchPage.h" #include "berryISelectionService.h" #include "berryConstants.h" #include "berryPlatformUI.h" #include "itkRGBAPixel.h" #include "itkTractsToProbabilityImageFilter.h" #include "qwidgetaction.h" #include "qcolordialog.h" #include #include const std::string QmitkControlVisualizationPropertiesView::VIEW_ID = "org.mitk.views.controlvisualizationpropertiesview"; using namespace berry; struct CvpSelListener : ISelectionListener { berryObjectMacro(CvpSelListener); CvpSelListener(QmitkControlVisualizationPropertiesView* view) { m_View = view; } void ApplySettings(mitk::DataNode::Pointer node) { bool tex_int; node->GetBoolProperty("texture interpolation", tex_int); if(tex_int) { m_View->m_Controls->m_TextureIntON->setIcon(*m_View->m_IconTexON); m_View->m_Controls->m_TextureIntON->setChecked(true); m_View->m_TexIsOn = true; } else { m_View->m_Controls->m_TextureIntON->setIcon(*m_View->m_IconTexOFF); m_View->m_Controls->m_TextureIntON->setChecked(false); m_View->m_TexIsOn = false; } int val; node->GetIntProperty("ShowMaxNumber", val); m_View->m_Controls->m_ShowMaxNumber->setValue(val); m_View->m_Controls->m_NormalizationDropdown->setCurrentIndex(dynamic_cast(node->GetProperty("Normalization"))->GetValueAsId()); float fval; node->GetFloatProperty("Scaling",fval); m_View->m_Controls->m_ScalingFactor->setValue(fval); m_View->m_Controls->m_AdditionalScaling->setCurrentIndex(dynamic_cast(node->GetProperty("ScaleBy"))->GetValueAsId()); node->GetFloatProperty("IndexParam1",fval); m_View->m_Controls->m_IndexParam1->setValue(fval); node->GetFloatProperty("IndexParam2",fval); m_View->m_Controls->m_IndexParam2->setValue(fval); } void DoSelectionChanged(ISelection::ConstPointer selection) { // save current selection in member variable m_View->m_CurrentSelection = selection.Cast(); m_View->m_Controls->m_VisibleOdfsON_T->setVisible(false); m_View->m_Controls->m_VisibleOdfsON_S->setVisible(false); m_View->m_Controls->m_VisibleOdfsON_C->setVisible(false); m_View->m_Controls->m_TextureIntON->setVisible(false); m_View->m_Controls->m_ImageControlsFrame->setVisible(false); m_View->m_Controls->m_PlanarFigureControlsFrame->setVisible(false); m_View->m_Controls->m_BundleControlsFrame->setVisible(false); m_View->m_SelectedNode = 0; if(m_View->m_CurrentSelection.IsNull()) return; if(m_View->m_CurrentSelection->Size() == 1) { mitk::DataNodeObject::Pointer nodeObj = m_View->m_CurrentSelection->Begin()->Cast(); if(nodeObj.IsNotNull()) { mitk::DataNode::Pointer node = nodeObj->GetDataNode(); if(dynamic_cast(node->GetData()) != 0) { m_View->m_Controls->m_PlanarFigureControlsFrame->setVisible(true); m_View->m_SelectedNode = node; float val; node->GetFloatProperty("planarfigure.line.width", val); m_View->m_Controls->m_PFWidth->setValue((int)(val*10.0)); QString label = "Width %1"; label = label.arg(val); m_View->m_Controls->label_pfwidth->setText(label); float color[3]; node->GetColor( color, NULL, "planarfigure.default.line.color"); QString styleSheet = "background-color:rgb("; styleSheet.append(QString::number(color[0]*255.0)); styleSheet.append(","); styleSheet.append(QString::number(color[1]*255.0)); styleSheet.append(","); styleSheet.append(QString::number(color[2]*255.0)); styleSheet.append(")"); m_View->m_Controls->m_PFColor->setAutoFillBackground(true); m_View->m_Controls->m_PFColor->setStyleSheet(styleSheet); node->GetColor( color, NULL, "color"); styleSheet = "background-color:rgb("; styleSheet.append(QString::number(color[0]*255.0)); styleSheet.append(","); styleSheet.append(QString::number(color[1]*255.0)); styleSheet.append(","); styleSheet.append(QString::number(color[2]*255.0)); styleSheet.append(")"); m_View->m_Controls->m_PFColor3D->setAutoFillBackground(true); m_View->m_Controls->m_PFColor3D->setStyleSheet(styleSheet); m_View->PlanarFigureFocus(); } if(dynamic_cast(node->GetData()) != 0) { m_View->m_Controls->m_BundleControlsFrame->setVisible(true); m_View->m_SelectedNode = node; if(m_View->m_CurrentPickingNode != 0 && node.GetPointer() != m_View->m_CurrentPickingNode) { m_View->m_Controls->m_Crosshair->setEnabled(false); } else { m_View->m_Controls->m_Crosshair->setEnabled(true); } float val; node->GetFloatProperty("TubeRadius", val); m_View->m_Controls->m_TubeRadius->setValue((int)(val * 100.0)); QString label = "Radius %1"; label = label.arg(val); m_View->m_Controls->label_tuberadius->setText(label); int width; node->GetIntProperty("LineWidth", width); m_View->m_Controls->m_LineWidth->setValue(width); label = "Width %1"; label = label.arg(width); m_View->m_Controls->label_linewidth->setText(label); // mitk::ColorProperty* nodecolor= mitk::ColorProperty::New(); // node->GetProperty(nodecolor,"color"); // m_View->m_Controls->m_Color->setAutoFillBackground(true); // QString styleSheet = "background-color:rgb("; // styleSheet.append(QString::number(nodecolor->GetColor().GetRed()*255.0)); // styleSheet.append(","); // styleSheet.append(QString::number(nodecolor->GetColor().GetGreen()*255.0)); // styleSheet.append(","); // styleSheet.append(QString::number(nodecolor->GetColor().GetBlue()*255.0)); // styleSheet.append(")"); // m_View->m_Controls->m_Color->setStyleSheet(styleSheet); } } } if(m_View->m_CurrentSelection->Size() > 0 && m_View->m_SelectedNode == 0) { m_View->m_Controls->m_ImageControlsFrame->setVisible(true); bool foundDiffusionImage = false; bool foundQBIVolume = false; bool foundTensorVolume = false; bool foundImage = false; bool foundMultipleOdfImages = false; bool foundRGBAImage = false; // do something with the selected items if(m_View->m_CurrentSelection) { // iterate selection for (IStructuredSelection::iterator i = m_View->m_CurrentSelection->Begin(); i != m_View->m_CurrentSelection->End(); ++i) { // extract datatree node if (mitk::DataNodeObject::Pointer nodeObj = i->Cast()) { mitk::DataNode::Pointer node = nodeObj->GetDataNode(); // only look at interesting types if(QString("DiffusionImage").compare(node->GetData()->GetNameOfClass())==0) { foundDiffusionImage = true; bool tex_int; node->GetBoolProperty("texture interpolation", tex_int); if(tex_int) { m_View->m_Controls->m_TextureIntON->setIcon(*m_View->m_IconTexON); m_View->m_Controls->m_TextureIntON->setChecked(true); m_View->m_TexIsOn = true; } else { m_View->m_Controls->m_TextureIntON->setIcon(*m_View->m_IconTexOFF); m_View->m_Controls->m_TextureIntON->setChecked(false); m_View->m_TexIsOn = false; } int val; node->GetIntProperty("DisplayChannel", val); m_View->m_Controls->m_DisplayIndex->setValue(val); QString label = "Channel %1"; label = label.arg(val); m_View->m_Controls->label_channel->setText(label); int maxVal = (dynamic_cast* >(node->GetData()))->GetVectorImage()->GetVectorLength(); m_View->m_Controls->m_DisplayIndex->setMaximum(maxVal-1); } else if(QString("QBallImage").compare(node->GetData()->GetNameOfClass())==0) { foundMultipleOdfImages = foundQBIVolume || foundTensorVolume; foundQBIVolume = true; ApplySettings(node); } else if(QString("TensorImage").compare(node->GetData()->GetNameOfClass())==0) { foundMultipleOdfImages = foundQBIVolume || foundTensorVolume; foundTensorVolume = true; ApplySettings(node); } else if(QString("Image").compare(node->GetData()->GetNameOfClass())==0) { foundImage = true; mitk::Image::Pointer img = dynamic_cast(node->GetData()); if(img.IsNotNull() && img->GetPixelType().GetItkTypeId() == &typeid(itk::RGBAPixel) ) { foundRGBAImage = true; } bool tex_int; node->GetBoolProperty("texture interpolation", tex_int); if(tex_int) { m_View->m_Controls->m_TextureIntON->setIcon(*m_View->m_IconTexON); m_View->m_Controls->m_TextureIntON->setChecked(true); m_View->m_TexIsOn = true; } else { m_View->m_Controls->m_TextureIntON->setIcon(*m_View->m_IconTexOFF); m_View->m_Controls->m_TextureIntON->setChecked(false); m_View->m_TexIsOn = false; } } } } } m_View->m_Controls->m_DisplayIndex->setVisible(foundDiffusionImage); m_View->m_Controls->label_channel->setVisible(foundDiffusionImage); m_View->m_FoundSingleOdfImage = (foundQBIVolume || foundTensorVolume) && !foundMultipleOdfImages; m_View->m_Controls->m_NumberGlyphsFrame->setVisible(m_View->m_FoundSingleOdfImage); m_View->m_Controls->m_NormalizationDropdown->setVisible(m_View->m_FoundSingleOdfImage); m_View->m_Controls->label->setVisible(m_View->m_FoundSingleOdfImage); m_View->m_Controls->m_ScalingFactor->setVisible(m_View->m_FoundSingleOdfImage); m_View->m_Controls->m_AdditionalScaling->setVisible(m_View->m_FoundSingleOdfImage); m_View->m_Controls->m_NormalizationScalingFrame->setVisible(m_View->m_FoundSingleOdfImage); m_View->m_Controls->OpacMinFrame->setVisible(foundRGBAImage || m_View->m_FoundSingleOdfImage); // changed for SPIE paper, Principle curvature scaling //m_View->m_Controls->params_frame->setVisible(m_View->m_FoundSingleOdfImage); m_View->m_Controls->params_frame->setVisible(false); m_View->m_Controls->m_VisibleOdfsON_T->setVisible(m_View->m_FoundSingleOdfImage); m_View->m_Controls->m_VisibleOdfsON_S->setVisible(m_View->m_FoundSingleOdfImage); m_View->m_Controls->m_VisibleOdfsON_C->setVisible(m_View->m_FoundSingleOdfImage); bool foundAnyImage = foundDiffusionImage || foundQBIVolume || foundTensorVolume || foundImage; m_View->m_Controls->m_Reinit->setVisible(foundAnyImage); m_View->m_Controls->m_TextureIntON->setVisible(foundAnyImage); m_View->m_Controls->m_TSMenu->setVisible(foundAnyImage); if(m_View->m_IsInitialized) { //m_View->GetSite()->GetWorkbenchWindow()->GetActivePage() // ->HideView(IViewPart::Pointer(m_View)); //berry::PlatformUI::GetWorkbench()->GetActiveWorkbenchWindow()->GetActivePage() // ->ShowView(QmitkControlVisualizationPropertiesView::VIEW_ID, // "", berry::IWorkbenchPage::VIEW_VISIBLE); } } } void SelectionChanged(IWorkbenchPart::Pointer part, ISelection::ConstPointer selection) { // check, if selection comes from datamanager if (part) { QString partname(part->GetPartName().c_str()); if(partname.compare("Datamanager")==0) { // apply selection DoSelectionChanged(selection); } } } QmitkControlVisualizationPropertiesView* m_View; }; QmitkControlVisualizationPropertiesView::QmitkControlVisualizationPropertiesView() : QmitkFunctionality(), m_Controls(NULL), m_MultiWidget(NULL), m_NodeUsedForOdfVisualization(NULL), m_IconTexOFF(new QIcon(":/QmitkDiffusionImaging/texIntOFFIcon.png")), m_IconTexON(new QIcon(":/QmitkDiffusionImaging/texIntONIcon.png")), m_IconGlyOFF_T(new QIcon(":/QmitkDiffusionImaging/glyphsoff_T.png")), m_IconGlyON_T(new QIcon(":/QmitkDiffusionImaging/glyphson_T.png")), m_IconGlyOFF_C(new QIcon(":/QmitkDiffusionImaging/glyphsoff_C.png")), m_IconGlyON_C(new QIcon(":/QmitkDiffusionImaging/glyphson_C.png")), m_IconGlyOFF_S(new QIcon(":/QmitkDiffusionImaging/glyphsoff_S.png")), m_IconGlyON_S(new QIcon(":/QmitkDiffusionImaging/glyphson_S.png")), m_CurrentSelection(0), - m_CurrentPickingNode(0) + m_CurrentPickingNode(0), + m_GlyIsOn_S(false), + m_GlyIsOn_C(false), + m_GlyIsOn_T(false) { currentThickSlicesMode = 1; m_MyMenu = NULL; } QmitkControlVisualizationPropertiesView::QmitkControlVisualizationPropertiesView(const QmitkControlVisualizationPropertiesView& other) { Q_UNUSED(other) throw std::runtime_error("Copy constructor not implemented"); } QmitkControlVisualizationPropertiesView::~QmitkControlVisualizationPropertiesView() { this->GetSite()->GetWorkbenchWindow()->GetSelectionService()->RemovePostSelectionListener(/*"org.mitk.views.datamanager",*/ m_SelListener); } void QmitkControlVisualizationPropertiesView::OnThickSlicesModeSelected( QAction* action ) { currentThickSlicesMode = action->data().toInt(); switch(currentThickSlicesMode) { default: case 1: this->m_Controls->m_TSMenu->setText("MIP"); break; case 2: this->m_Controls->m_TSMenu->setText("SUM"); break; case 3: this->m_Controls->m_TSMenu->setText("WEIGH"); break; } mitk::DataNode* n; n = GetDataStorage()->GetNamedNode("widget1Plane"); if(n) n->SetProperty( "reslice.thickslices", mitk::ResliceMethodProperty::New( currentThickSlicesMode ) ); n = GetDataStorage()->GetNamedNode("widget2Plane"); if(n) n->SetProperty( "reslice.thickslices", mitk::ResliceMethodProperty::New( currentThickSlicesMode ) ); n = GetDataStorage()->GetNamedNode("widget3Plane"); if(n) n->SetProperty( "reslice.thickslices", mitk::ResliceMethodProperty::New( currentThickSlicesMode ) ); mitk::BaseRenderer::Pointer renderer = this->GetActiveStdMultiWidget()->GetRenderWindow1()->GetRenderer(); if(renderer.IsNotNull()) { renderer->SendUpdateSlice(); } renderer = this->GetActiveStdMultiWidget()->GetRenderWindow2()->GetRenderer(); if(renderer.IsNotNull()) { renderer->SendUpdateSlice(); } renderer = this->GetActiveStdMultiWidget()->GetRenderWindow3()->GetRenderer(); if(renderer.IsNotNull()) { renderer->SendUpdateSlice(); } renderer->GetRenderingManager()->RequestUpdateAll(); } void QmitkControlVisualizationPropertiesView::OnTSNumChanged(int num) { if(num==0) { mitk::DataNode* n; n = GetDataStorage()->GetNamedNode("widget1Plane"); if(n) n->SetProperty( "reslice.thickslices", mitk::ResliceMethodProperty::New( 0 ) ); n = GetDataStorage()->GetNamedNode("widget2Plane"); if(n) n->SetProperty( "reslice.thickslices", mitk::ResliceMethodProperty::New( 0 ) ); n = GetDataStorage()->GetNamedNode("widget3Plane"); if(n) n->SetProperty( "reslice.thickslices", mitk::ResliceMethodProperty::New( 0 ) ); } else { mitk::DataNode* n; n = GetDataStorage()->GetNamedNode("widget1Plane"); if(n) n->SetProperty( "reslice.thickslices", mitk::ResliceMethodProperty::New( currentThickSlicesMode ) ); n = GetDataStorage()->GetNamedNode("widget2Plane"); if(n) n->SetProperty( "reslice.thickslices", mitk::ResliceMethodProperty::New( currentThickSlicesMode ) ); n = GetDataStorage()->GetNamedNode("widget3Plane"); if(n) n->SetProperty( "reslice.thickslices", mitk::ResliceMethodProperty::New( currentThickSlicesMode ) ); n = GetDataStorage()->GetNamedNode("widget1Plane"); if(n) n->SetProperty( "reslice.thickslices.num", mitk::IntProperty::New( num ) ); n = GetDataStorage()->GetNamedNode("widget2Plane"); if(n) n->SetProperty( "reslice.thickslices.num", mitk::IntProperty::New( num ) ); n = GetDataStorage()->GetNamedNode("widget3Plane"); if(n) n->SetProperty( "reslice.thickslices.num", mitk::IntProperty::New( num ) ); } m_TSLabel->setText(QString::number(num*2+1)); mitk::BaseRenderer::Pointer renderer = this->GetActiveStdMultiWidget()->GetRenderWindow1()->GetRenderer(); if(renderer.IsNotNull()) { renderer->SendUpdateSlice(); } renderer = this->GetActiveStdMultiWidget()->GetRenderWindow2()->GetRenderer(); if(renderer.IsNotNull()) { renderer->SendUpdateSlice(); } renderer = this->GetActiveStdMultiWidget()->GetRenderWindow3()->GetRenderer(); if(renderer.IsNotNull()) { renderer->SendUpdateSlice(); } renderer->GetRenderingManager()->RequestUpdateAll(mitk::RenderingManager::REQUEST_UPDATE_2DWINDOWS); } void QmitkControlVisualizationPropertiesView::CreateQtPartControl(QWidget *parent) { if (!m_Controls) { // create GUI widgets m_Controls = new Ui::QmitkControlVisualizationPropertiesViewControls; m_Controls->setupUi(parent); this->CreateConnections(); m_MyMenu = new QMenu(parent); connect( m_MyMenu, SIGNAL( aboutToShow() ), this, SLOT(OnMenuAboutToShow()) ); // button for changing rotation mode m_Controls->m_TSMenu->setMenu( m_MyMenu ); //m_CrosshairModeButton->setIcon( QIcon( iconCrosshairMode_xpm ) ); m_Controls->params_frame->setVisible(false); QIcon icon5(":/QmitkDiffusionImaging/Refresh_48.png"); m_Controls->m_Reinit->setIcon(icon5); m_Controls->m_Focus->setIcon(icon5); QIcon iconColor(":/QmitkDiffusionImaging/color24.gif"); m_Controls->m_PFColor->setIcon(iconColor); m_Controls->m_PFColor3D->setIcon(iconColor); m_Controls->m_Color->setIcon(iconColor); m_Controls->m_PFColor->setToolButtonStyle(Qt::ToolButtonTextBesideIcon); m_Controls->m_PFColor3D->setToolButtonStyle(Qt::ToolButtonTextBesideIcon); QIcon iconCrosshair(":/QmitkDiffusionImaging/crosshair.png"); m_Controls->m_Crosshair->setIcon(iconCrosshair); QIcon iconPaint(":/QmitkDiffusionImaging/paint2.png"); m_Controls->m_2DHeatmap->setIcon(iconPaint); m_Controls->m_TextureIntON->setCheckable(true); #ifndef DIFFUSION_IMAGING_EXTENDED int size = m_Controls->m_AdditionalScaling->count(); for(int t=0; tm_AdditionalScaling->itemText(t).toStdString() == "Scale by ASR") { m_Controls->m_AdditionalScaling->removeItem(t); } } #endif m_Controls->m_OpacitySlider->setRange(0.0,1.0); m_Controls->m_OpacitySlider->setLowerValue(0.0); m_Controls->m_OpacitySlider->setUpperValue(0.0); m_Controls->m_ScalingFrame->setVisible(false); m_Controls->m_NormalizationFrame->setVisible(false); } m_IsInitialized = false; m_SelListener = berry::ISelectionListener::Pointer(new CvpSelListener(this)); this->GetSite()->GetWorkbenchWindow()->GetSelectionService()->AddPostSelectionListener(/*"org.mitk.views.datamanager",*/ m_SelListener); berry::ISelection::ConstPointer sel( this->GetSite()->GetWorkbenchWindow()->GetSelectionService()->GetSelection("org.mitk.views.datamanager")); m_CurrentSelection = sel.Cast(); m_SelListener.Cast()->DoSelectionChanged(sel); m_IsInitialized = true; } void QmitkControlVisualizationPropertiesView::OnMenuAboutToShow () { // THICK SLICE SUPPORT QMenu *myMenu = m_MyMenu; myMenu->clear(); QActionGroup* thickSlicesActionGroup = new QActionGroup(myMenu); thickSlicesActionGroup->setExclusive(true); mitk::BaseRenderer::Pointer renderer = this->GetActiveStdMultiWidget()->GetRenderWindow1()->GetRenderer(); int currentTSMode = 0; { mitk::ResliceMethodProperty::Pointer m = dynamic_cast(renderer->GetCurrentWorldGeometry2DNode()->GetProperty( "reslice.thickslices" )); if( m.IsNotNull() ) currentTSMode = m->GetValueAsId(); } const int maxTS = 30; int currentNum = 0; { mitk::IntProperty::Pointer m = dynamic_cast(renderer->GetCurrentWorldGeometry2DNode()->GetProperty( "reslice.thickslices.num" )); if( m.IsNotNull() ) { currentNum = m->GetValue(); if(currentNum < 0) currentNum = 0; if(currentNum > maxTS) currentNum = maxTS; } } if(currentTSMode==0) currentNum=0; QSlider *m_TSSlider = new QSlider(myMenu); m_TSSlider->setMinimum(0); m_TSSlider->setMaximum(maxTS-1); m_TSSlider->setValue(currentNum); m_TSSlider->setOrientation(Qt::Horizontal); connect( m_TSSlider, SIGNAL( valueChanged(int) ), this, SLOT( OnTSNumChanged(int) ) ); QHBoxLayout* _TSLayout = new QHBoxLayout; _TSLayout->setContentsMargins(4,4,4,4); _TSLayout->addWidget(m_TSSlider); _TSLayout->addWidget(m_TSLabel=new QLabel(QString::number(currentNum*2+1),myMenu)); QWidget* _TSWidget = new QWidget; _TSWidget->setLayout(_TSLayout); QActionGroup* thickSliceModeActionGroup = new QActionGroup(myMenu); thickSliceModeActionGroup->setExclusive(true); QWidgetAction *m_TSSliderAction = new QWidgetAction(myMenu); m_TSSliderAction->setDefaultWidget(_TSWidget); myMenu->addAction(m_TSSliderAction); QAction* mipThickSlicesAction = new QAction(myMenu); mipThickSlicesAction->setActionGroup(thickSliceModeActionGroup); mipThickSlicesAction->setText("MIP (max. intensity proj.)"); mipThickSlicesAction->setCheckable(true); mipThickSlicesAction->setChecked(currentThickSlicesMode==1); mipThickSlicesAction->setData(1); myMenu->addAction( mipThickSlicesAction ); QAction* sumThickSlicesAction = new QAction(myMenu); sumThickSlicesAction->setActionGroup(thickSliceModeActionGroup); sumThickSlicesAction->setText("SUM (sum intensity proj.)"); sumThickSlicesAction->setCheckable(true); sumThickSlicesAction->setChecked(currentThickSlicesMode==2); sumThickSlicesAction->setData(2); myMenu->addAction( sumThickSlicesAction ); QAction* weightedThickSlicesAction = new QAction(myMenu); weightedThickSlicesAction->setActionGroup(thickSliceModeActionGroup); weightedThickSlicesAction->setText("WEIGHTED (gaussian proj.)"); weightedThickSlicesAction->setCheckable(true); weightedThickSlicesAction->setChecked(currentThickSlicesMode==3); weightedThickSlicesAction->setData(3); myMenu->addAction( weightedThickSlicesAction ); connect( thickSliceModeActionGroup, SIGNAL(triggered(QAction*)), this, SLOT(OnThickSlicesModeSelected(QAction*)) ); } void QmitkControlVisualizationPropertiesView::StdMultiWidgetAvailable (QmitkStdMultiWidget &stdMultiWidget) { m_MultiWidget = &stdMultiWidget; } void QmitkControlVisualizationPropertiesView::StdMultiWidgetNotAvailable() { m_MultiWidget = NULL; } void QmitkControlVisualizationPropertiesView::CreateConnections() { if ( m_Controls ) { connect( (QObject*)(m_Controls->m_DisplayIndex), SIGNAL(valueChanged(int)), this, SLOT(DisplayIndexChanged(int)) ); connect( (QObject*)(m_Controls->m_TextureIntON), SIGNAL(clicked()), this, SLOT(TextIntON()) ); connect( (QObject*)(m_Controls->m_Reinit), SIGNAL(clicked()), this, SLOT(Reinit()) ); connect( (QObject*)(m_Controls->m_VisibleOdfsON_T), SIGNAL(clicked()), this, SLOT(VisibleOdfsON_T()) ); connect( (QObject*)(m_Controls->m_VisibleOdfsON_S), SIGNAL(clicked()), this, SLOT(VisibleOdfsON_S()) ); connect( (QObject*)(m_Controls->m_VisibleOdfsON_C), SIGNAL(clicked()), this, SLOT(VisibleOdfsON_C()) ); connect( (QObject*)(m_Controls->m_ShowMaxNumber), SIGNAL(editingFinished()), this, SLOT(ShowMaxNumberChanged()) ); connect( (QObject*)(m_Controls->m_NormalizationDropdown), SIGNAL(currentIndexChanged(int)), this, SLOT(NormalizationDropdownChanged(int)) ); connect( (QObject*)(m_Controls->m_ScalingFactor), SIGNAL(valueChanged(double)), this, SLOT(ScalingFactorChanged(double)) ); connect( (QObject*)(m_Controls->m_AdditionalScaling), SIGNAL(currentIndexChanged(int)), this, SLOT(AdditionalScaling(int)) ); connect( (QObject*)(m_Controls->m_IndexParam1), SIGNAL(valueChanged(double)), this, SLOT(IndexParam1Changed(double)) ); connect( (QObject*)(m_Controls->m_IndexParam2), SIGNAL(valueChanged(double)), this, SLOT(IndexParam2Changed(double)) ); connect( (QObject*)(m_Controls->m_ScalingCheckbox), SIGNAL(clicked()), this, SLOT(ScalingCheckbox()) ); connect( (QObject*)(m_Controls->m_OpacitySlider), SIGNAL(spanChanged(double,double)), this, SLOT(OpacityChanged(double,double)) ); connect((QObject*) m_Controls->m_Wire, SIGNAL(clicked()), (QObject*) this, SLOT(BundleRepresentationWire())); connect((QObject*) m_Controls->m_Tube, SIGNAL(clicked()), (QObject*) this, SLOT(BundleRepresentationTube())); connect((QObject*) m_Controls->m_Color, SIGNAL(clicked()), (QObject*) this, SLOT(BundleRepresentationColor())); connect((QObject*) m_Controls->m_Focus, SIGNAL(clicked()), (QObject*) this, SLOT(PlanarFigureFocus())); connect((QObject*) m_Controls->m_Crosshair, SIGNAL(clicked()), (QObject*) this, SLOT(SetInteractor())); connect((QObject*) m_Controls->m_PFWidth, SIGNAL(valueChanged(int)), (QObject*) this, SLOT(PFWidth(int))); connect((QObject*) m_Controls->m_PFColor, SIGNAL(clicked()), (QObject*) this, SLOT(PFColor())); connect((QObject*) m_Controls->m_PFColor3D, SIGNAL(clicked()), (QObject*) this, SLOT(PFColor3D())); connect((QObject*) m_Controls->m_2DHeatmap, SIGNAL(clicked()), (QObject*) this, SLOT(Heatmap())); connect((QObject*) m_Controls->m_LineWidth, SIGNAL(valueChanged(int)), (QObject*) this, SLOT(LineWidthChanged(int))); connect((QObject*) m_Controls->m_TubeRadius, SIGNAL(valueChanged(int)), (QObject*) this, SLOT(TubeRadiusChanged(int))); connect((QObject*) m_Controls->m_Welcome, SIGNAL(clicked()), (QObject*) this, SLOT(Welcome())); } } void QmitkControlVisualizationPropertiesView::Activated() { berry::ISelection::ConstPointer sel( this->GetSite()->GetWorkbenchWindow()->GetSelectionService()->GetSelection("org.mitk.views.datamanager")); m_CurrentSelection = sel.Cast(); m_SelListener.Cast()->DoSelectionChanged(sel); QmitkFunctionality::Activated(); } void QmitkControlVisualizationPropertiesView::Deactivated() { QmitkFunctionality::Deactivated(); } int QmitkControlVisualizationPropertiesView::GetSizeFlags(bool width) { if(!width) { return berry::Constants::MIN | berry::Constants::MAX | berry::Constants::FILL; } else { return 0; } } int QmitkControlVisualizationPropertiesView::ComputePreferredSize(bool width, int /*availableParallel*/, int /*availablePerpendicular*/, int preferredResult) { if(width==false) { return m_FoundSingleOdfImage ? 120 : 80; } else { return preferredResult; } } /* OnSelectionChanged is registered to SelectionService, therefore no need to implement SelectionService Listener explicitly */ void QmitkControlVisualizationPropertiesView::OnSelectionChanged( std::vector nodes ) { if ( !this->IsVisible() ) { // do nothing if nobody wants to see me :-( return; } for( std::vector::iterator it = nodes.begin(); it != nodes.end(); ++it ) { mitk::DataNode::Pointer node = *it; if( node.IsNotNull() && (dynamic_cast(node->GetData()) || dynamic_cast(node->GetData())) ) { if(m_NodeUsedForOdfVisualization.IsNotNull()) { m_NodeUsedForOdfVisualization->SetBoolProperty("VisibleOdfs_S", false); m_NodeUsedForOdfVisualization->SetBoolProperty("VisibleOdfs_C", false); m_NodeUsedForOdfVisualization->SetBoolProperty("VisibleOdfs_T", false); } m_NodeUsedForOdfVisualization = node; m_NodeUsedForOdfVisualization->SetBoolProperty("VisibleOdfs_S", m_GlyIsOn_S); m_NodeUsedForOdfVisualization->SetBoolProperty("VisibleOdfs_C", m_GlyIsOn_C); m_NodeUsedForOdfVisualization->SetBoolProperty("VisibleOdfs_T", m_GlyIsOn_T); if(m_MultiWidget) m_MultiWidget->RequestUpdate(); break; } } } mitk::DataStorage::SetOfObjects::Pointer QmitkControlVisualizationPropertiesView::ActiveSet(std::string classname) { if (m_CurrentSelection) { mitk::DataStorage::SetOfObjects::Pointer set = mitk::DataStorage::SetOfObjects::New(); int at = 0; for (IStructuredSelection::iterator i = m_CurrentSelection->Begin(); i != m_CurrentSelection->End(); ++i) { if (mitk::DataNodeObject::Pointer nodeObj = i->Cast()) { mitk::DataNode::Pointer node = nodeObj->GetDataNode(); if(QString(classname.c_str()).compare(node->GetData()->GetNameOfClass())==0) { set->InsertElement(at++, node); } } } return set; } return 0; } void QmitkControlVisualizationPropertiesView::SetBoolProp( mitk::DataStorage::SetOfObjects::Pointer set, std::string name, bool value) { if(set.IsNotNull()) { mitk::DataStorage::SetOfObjects::const_iterator itemiter( set->begin() ); mitk::DataStorage::SetOfObjects::const_iterator itemiterend( set->end() ); while ( itemiter != itemiterend ) { (*itemiter)->SetBoolProperty(name.c_str(), value); ++itemiter; } } } void QmitkControlVisualizationPropertiesView::SetIntProp( mitk::DataStorage::SetOfObjects::Pointer set, std::string name, int value) { if(set.IsNotNull()) { mitk::DataStorage::SetOfObjects::const_iterator itemiter( set->begin() ); mitk::DataStorage::SetOfObjects::const_iterator itemiterend( set->end() ); while ( itemiter != itemiterend ) { (*itemiter)->SetIntProperty(name.c_str(), value); ++itemiter; } } } void QmitkControlVisualizationPropertiesView::SetFloatProp( mitk::DataStorage::SetOfObjects::Pointer set, std::string name, float value) { if(set.IsNotNull()) { mitk::DataStorage::SetOfObjects::const_iterator itemiter( set->begin() ); mitk::DataStorage::SetOfObjects::const_iterator itemiterend( set->end() ); while ( itemiter != itemiterend ) { (*itemiter)->SetFloatProperty(name.c_str(), value); ++itemiter; } } } void QmitkControlVisualizationPropertiesView::SetLevelWindowProp( mitk::DataStorage::SetOfObjects::Pointer set, std::string name, mitk::LevelWindow value) { if(set.IsNotNull()) { mitk::LevelWindowProperty::Pointer prop = mitk::LevelWindowProperty::New(value); mitk::DataStorage::SetOfObjects::const_iterator itemiter( set->begin() ); mitk::DataStorage::SetOfObjects::const_iterator itemiterend( set->end() ); while ( itemiter != itemiterend ) { (*itemiter)->SetProperty(name.c_str(), prop); ++itemiter; } } } void QmitkControlVisualizationPropertiesView::SetEnumProp( mitk::DataStorage::SetOfObjects::Pointer set, std::string name, mitk::EnumerationProperty::Pointer value) { if(set.IsNotNull()) { mitk::DataStorage::SetOfObjects::const_iterator itemiter( set->begin() ); mitk::DataStorage::SetOfObjects::const_iterator itemiterend( set->end() ); while ( itemiter != itemiterend ) { (*itemiter)->SetProperty(name.c_str(), value); ++itemiter; } } } void QmitkControlVisualizationPropertiesView::DisplayIndexChanged(int dispIndex) { QString label = "Channel %1"; label = label.arg(dispIndex); m_Controls->label_channel->setText(label); mitk::DataStorage::SetOfObjects::Pointer set = ActiveSet("DiffusionImage"); if(set.IsNotNull()) { mitk::DataStorage::SetOfObjects::const_iterator itemiter( set->begin() ); mitk::DataStorage::SetOfObjects::const_iterator itemiterend( set->end() ); while ( itemiter != itemiterend ) { (*itemiter)->SetIntProperty("DisplayChannel", dispIndex); ++itemiter; } //m_MultiWidget->RequestUpdate(); mitk::RenderingManager::GetInstance()->RequestUpdateAll(); } } void QmitkControlVisualizationPropertiesView::Reinit() { if (m_CurrentSelection) { mitk::DataNodeObject::Pointer nodeObj = m_CurrentSelection->Begin()->Cast(); mitk::DataNode::Pointer node = nodeObj->GetDataNode(); mitk::BaseData::Pointer basedata = node->GetData(); if (basedata.IsNotNull()) { mitk::RenderingManager::GetInstance()->InitializeViews( basedata->GetTimeSlicedGeometry(), mitk::RenderingManager::REQUEST_UPDATE_ALL, true ); mitk::RenderingManager::GetInstance()->RequestUpdateAll(); } } } void QmitkControlVisualizationPropertiesView::TextIntON() { if(m_TexIsOn) { m_Controls->m_TextureIntON->setIcon(*m_IconTexOFF); } else { m_Controls->m_TextureIntON->setIcon(*m_IconTexON); } mitk::DataStorage::SetOfObjects::Pointer set = ActiveSet("DiffusionImage"); SetBoolProp(set,"texture interpolation", !m_TexIsOn); set = ActiveSet("TensorImage"); SetBoolProp(set,"texture interpolation", !m_TexIsOn); set = ActiveSet("QBallImage"); SetBoolProp(set,"texture interpolation", !m_TexIsOn); set = ActiveSet("Image"); SetBoolProp(set,"texture interpolation", !m_TexIsOn); m_TexIsOn = !m_TexIsOn; if(m_MultiWidget) m_MultiWidget->RequestUpdate(); } void QmitkControlVisualizationPropertiesView::VisibleOdfsON_S() { m_GlyIsOn_S = m_Controls->m_VisibleOdfsON_S->isChecked(); if (m_NodeUsedForOdfVisualization.IsNull()) { MITK_WARN << "ODF visualization activated but m_NodeUsedForOdfVisualization is NULL"; return; } m_NodeUsedForOdfVisualization->SetBoolProperty("VisibleOdfs_S", m_GlyIsOn_S); VisibleOdfsON(0); } void QmitkControlVisualizationPropertiesView::VisibleOdfsON_T() { m_GlyIsOn_T = m_Controls->m_VisibleOdfsON_T->isChecked(); if (m_NodeUsedForOdfVisualization.IsNull()) { MITK_WARN << "ODF visualization activated but m_NodeUsedForOdfVisualization is NULL"; return; } m_NodeUsedForOdfVisualization->SetBoolProperty("VisibleOdfs_T", m_GlyIsOn_T); VisibleOdfsON(1); } void QmitkControlVisualizationPropertiesView::VisibleOdfsON_C() { m_GlyIsOn_C = m_Controls->m_VisibleOdfsON_C->isChecked(); if (m_NodeUsedForOdfVisualization.IsNull()) { MITK_WARN << "ODF visualization activated but m_NodeUsedForOdfVisualization is NULL"; return; } m_NodeUsedForOdfVisualization->SetBoolProperty("VisibleOdfs_C", m_GlyIsOn_C); VisibleOdfsON(2); } void QmitkControlVisualizationPropertiesView::VisibleOdfsON(int view) { if(m_MultiWidget) m_MultiWidget->RequestUpdate(); } void QmitkControlVisualizationPropertiesView::ShowMaxNumberChanged() { int maxNr = m_Controls->m_ShowMaxNumber->value(); if ( maxNr < 1 ) { m_Controls->m_ShowMaxNumber->setValue( 1 ); maxNr = 1; } mitk::DataStorage::SetOfObjects::Pointer set = ActiveSet("QBallImage"); SetIntProp(set,"ShowMaxNumber", maxNr); set = ActiveSet("TensorImage"); SetIntProp(set,"ShowMaxNumber", maxNr); if(m_MultiWidget) m_MultiWidget->RequestUpdate(); } void QmitkControlVisualizationPropertiesView::NormalizationDropdownChanged(int normDropdown) { typedef mitk::OdfNormalizationMethodProperty PropType; PropType::Pointer normMeth = PropType::New(); switch(normDropdown) { case 0: normMeth->SetNormalizationToMinMax(); break; case 1: normMeth->SetNormalizationToMax(); break; case 2: normMeth->SetNormalizationToNone(); break; case 3: normMeth->SetNormalizationToGlobalMax(); break; default: normMeth->SetNormalizationToMinMax(); } mitk::DataStorage::SetOfObjects::Pointer set = ActiveSet("QBallImage"); SetEnumProp(set,"Normalization", normMeth.GetPointer()); set = ActiveSet("TensorImage"); SetEnumProp(set,"Normalization", normMeth.GetPointer()); if(m_MultiWidget) m_MultiWidget->RequestUpdate(); } void QmitkControlVisualizationPropertiesView::ScalingFactorChanged(double scalingFactor) { mitk::DataStorage::SetOfObjects::Pointer set = ActiveSet("QBallImage"); SetFloatProp(set,"Scaling", scalingFactor); set = ActiveSet("TensorImage"); SetFloatProp(set,"Scaling", scalingFactor); if(m_MultiWidget) m_MultiWidget->RequestUpdate(); } void QmitkControlVisualizationPropertiesView::AdditionalScaling(int additionalScaling) { typedef mitk::OdfScaleByProperty PropType; PropType::Pointer scaleBy = PropType::New(); switch(additionalScaling) { case 0: scaleBy->SetScaleByNothing(); break; case 1: scaleBy->SetScaleByGFA(); //m_Controls->params_frame->setVisible(true); break; #ifdef DIFFUSION_IMAGING_EXTENDED case 2: scaleBy->SetScaleByPrincipalCurvature(); // commented in for SPIE paper, Principle curvature scaling //m_Controls->params_frame->setVisible(true); break; #endif default: scaleBy->SetScaleByNothing(); } mitk::DataStorage::SetOfObjects::Pointer set = ActiveSet("QBallImage"); SetEnumProp(set,"ScaleBy", scaleBy.GetPointer()); set = ActiveSet("TensorImage"); SetEnumProp(set,"ScaleBy", scaleBy.GetPointer()); if(m_MultiWidget) m_MultiWidget->RequestUpdate(); } void QmitkControlVisualizationPropertiesView::IndexParam1Changed(double param1) { mitk::DataStorage::SetOfObjects::Pointer set = ActiveSet("QBallImage"); SetFloatProp(set,"IndexParam1", param1); set = ActiveSet("TensorImage"); SetFloatProp(set,"IndexParam1", param1); if(m_MultiWidget) m_MultiWidget->RequestUpdate(); } void QmitkControlVisualizationPropertiesView::IndexParam2Changed(double param2) { mitk::DataStorage::SetOfObjects::Pointer set = ActiveSet("QBallImage"); SetFloatProp(set,"IndexParam2", param2); set = ActiveSet("TensorImage"); SetFloatProp(set,"IndexParam2", param2); if(m_MultiWidget) m_MultiWidget->RequestUpdate(); } void QmitkControlVisualizationPropertiesView::OpacityChanged(double l, double u) { mitk::LevelWindow olw; olw.SetRangeMinMax(l*255, u*255); mitk::DataStorage::SetOfObjects::Pointer set = ActiveSet("QBallImage"); SetLevelWindowProp(set,"opaclevelwindow", olw); set = ActiveSet("TensorImage"); SetLevelWindowProp(set,"opaclevelwindow", olw); set = ActiveSet("Image"); SetLevelWindowProp(set,"opaclevelwindow", olw); m_Controls->m_OpacityMinFaLabel->setText(QString::number(l,'f',2) + " : " + QString::number(u,'f',2)); if(m_MultiWidget) m_MultiWidget->RequestUpdate(); } void QmitkControlVisualizationPropertiesView::ScalingCheckbox() { m_Controls->m_ScalingFrame->setVisible( m_Controls->m_ScalingCheckbox->isChecked()); if(!m_Controls->m_ScalingCheckbox->isChecked()) { m_Controls->m_AdditionalScaling->setCurrentIndex(0); m_Controls->m_ScalingFactor->setValue(1.0); } } void QmitkControlVisualizationPropertiesView::BundleRepresentationWire() { if(m_SelectedNode) { int width = m_Controls->m_LineWidth->value(); m_SelectedNode->SetProperty("LineWidth",mitk::IntProperty::New(width)); m_SelectedNode->SetProperty("ColorCoding",mitk::IntProperty::New(15)); mitk::RenderingManager::GetInstance()->ForceImmediateUpdateAll(); m_SelectedNode->SetProperty("ColorCoding",mitk::IntProperty::New(18)); mitk::RenderingManager::GetInstance()->ForceImmediateUpdateAll(); m_SelectedNode->SetProperty("ColorCoding",mitk::IntProperty::New(1)); mitk::RenderingManager::GetInstance()->ForceImmediateUpdateAll(); m_SelectedNode->SetProperty("ColorCoding",mitk::IntProperty::New(2)); mitk::RenderingManager::GetInstance()->ForceImmediateUpdateAll(); m_SelectedNode->SetProperty("ColorCoding",mitk::IntProperty::New(3)); mitk::RenderingManager::GetInstance()->ForceImmediateUpdateAll(); m_SelectedNode->SetProperty("ColorCoding",mitk::IntProperty::New(4)); mitk::RenderingManager::GetInstance()->ForceImmediateUpdateAll(); m_SelectedNode->SetProperty("ColorCoding",mitk::IntProperty::New(0)); mitk::RenderingManager::GetInstance()->ForceImmediateUpdateAll(); } } void QmitkControlVisualizationPropertiesView::BundleRepresentationTube() { if(m_SelectedNode) { float radius = m_Controls->m_TubeRadius->value() / 100.0; m_SelectedNode->SetProperty("TubeRadius",mitk::FloatProperty::New(radius)); m_SelectedNode->SetProperty("ColorCoding",mitk::IntProperty::New(17)); mitk::RenderingManager::GetInstance()->ForceImmediateUpdateAll(); m_SelectedNode->SetProperty("ColorCoding",mitk::IntProperty::New(13)); mitk::RenderingManager::GetInstance()->ForceImmediateUpdateAll(); m_SelectedNode->SetProperty("ColorCoding",mitk::IntProperty::New(16)); mitk::RenderingManager::GetInstance()->ForceImmediateUpdateAll(); m_SelectedNode->SetProperty("ColorCoding",mitk::IntProperty::New(0)); mitk::RenderingManager::GetInstance()->ForceImmediateUpdateAll(); } } void QmitkControlVisualizationPropertiesView::BundleRepresentationColor() { if(m_SelectedNode) { QColor color = QColorDialog::getColor(); m_Controls->m_Color->setAutoFillBackground(true); QString styleSheet = "background-color:rgb("; styleSheet.append(QString::number(color.red())); styleSheet.append(","); styleSheet.append(QString::number(color.green())); styleSheet.append(","); styleSheet.append(QString::number(color.blue())); styleSheet.append(")"); m_Controls->m_Color->setStyleSheet(styleSheet); m_SelectedNode->SetProperty("color",mitk::ColorProperty::New(color.red()/255.0, color.green()/255.0, color.blue()/255.0)); m_SelectedNode->SetProperty("ColorCoding",mitk::IntProperty::New(14)); mitk::RenderingManager::GetInstance()->ForceImmediateUpdateAll(); m_SelectedNode->SetProperty("ColorCoding",mitk::IntProperty::New(3)); mitk::RenderingManager::GetInstance()->ForceImmediateUpdateAll(); m_SelectedNode->SetProperty("ColorCoding",mitk::IntProperty::New(0)); mitk::RenderingManager::GetInstance()->ForceImmediateUpdateAll(); } } void QmitkControlVisualizationPropertiesView::PlanarFigureFocus() { if(m_SelectedNode) { mitk::PlanarFigure* _PlanarFigure = 0; _PlanarFigure = dynamic_cast (m_SelectedNode->GetData()); if (_PlanarFigure) { QmitkRenderWindow* selectedRenderWindow = 0; bool PlanarFigureInitializedWindow = false; QmitkRenderWindow* RenderWindow1 = this->GetActiveStdMultiWidget()->GetRenderWindow1(); if (m_SelectedNode->GetBoolProperty("PlanarFigureInitializedWindow", PlanarFigureInitializedWindow, RenderWindow1->GetRenderer())) { selectedRenderWindow = RenderWindow1; } QmitkRenderWindow* RenderWindow2 = this->GetActiveStdMultiWidget()->GetRenderWindow2(); if (!selectedRenderWindow && m_SelectedNode->GetBoolProperty( "PlanarFigureInitializedWindow", PlanarFigureInitializedWindow, RenderWindow2->GetRenderer())) { selectedRenderWindow = RenderWindow2; } QmitkRenderWindow* RenderWindow3 = this->GetActiveStdMultiWidget()->GetRenderWindow3(); if (!selectedRenderWindow && m_SelectedNode->GetBoolProperty( "PlanarFigureInitializedWindow", PlanarFigureInitializedWindow, RenderWindow3->GetRenderer())) { selectedRenderWindow = RenderWindow3; } QmitkRenderWindow* RenderWindow4 = this->GetActiveStdMultiWidget()->GetRenderWindow4(); if (!selectedRenderWindow && m_SelectedNode->GetBoolProperty( "PlanarFigureInitializedWindow", PlanarFigureInitializedWindow, RenderWindow4->GetRenderer())) { selectedRenderWindow = RenderWindow4; } const mitk::PlaneGeometry * _PlaneGeometry = dynamic_cast (_PlanarFigure->GetGeometry2D()); mitk::VnlVector normal = _PlaneGeometry->GetNormalVnl(); mitk::Geometry2D::ConstPointer worldGeometry1 = RenderWindow1->GetRenderer()->GetCurrentWorldGeometry2D(); mitk::PlaneGeometry::ConstPointer _Plane1 = dynamic_cast( worldGeometry1.GetPointer() ); mitk::VnlVector normal1 = _Plane1->GetNormalVnl(); mitk::Geometry2D::ConstPointer worldGeometry2 = RenderWindow2->GetRenderer()->GetCurrentWorldGeometry2D(); mitk::PlaneGeometry::ConstPointer _Plane2 = dynamic_cast( worldGeometry2.GetPointer() ); mitk::VnlVector normal2 = _Plane2->GetNormalVnl(); mitk::Geometry2D::ConstPointer worldGeometry3 = RenderWindow3->GetRenderer()->GetCurrentWorldGeometry2D(); mitk::PlaneGeometry::ConstPointer _Plane3 = dynamic_cast( worldGeometry3.GetPointer() ); mitk::VnlVector normal3 = _Plane3->GetNormalVnl(); normal[0] = fabs(normal[0]); normal[1] = fabs(normal[1]); normal[2] = fabs(normal[2]); normal1[0] = fabs(normal1[0]); normal1[1] = fabs(normal1[1]); normal1[2] = fabs(normal1[2]); normal2[0] = fabs(normal2[0]); normal2[1] = fabs(normal2[1]); normal2[2] = fabs(normal2[2]); normal3[0] = fabs(normal3[0]); normal3[1] = fabs(normal3[1]); normal3[2] = fabs(normal3[2]); double ang1 = angle(normal, normal1); double ang2 = angle(normal, normal2); double ang3 = angle(normal, normal3); if(ang1 < ang2 && ang1 < ang3) { selectedRenderWindow = RenderWindow1; } else { if(ang2 < ang3) { selectedRenderWindow = RenderWindow2; } else { selectedRenderWindow = RenderWindow3; } } // make node visible if (selectedRenderWindow) { mitk::Point3D centerP = _PlaneGeometry->GetOrigin(); selectedRenderWindow->GetSliceNavigationController()->ReorientSlices( centerP, _PlaneGeometry->GetNormal()); selectedRenderWindow->GetSliceNavigationController()->SelectSliceByPoint( centerP); } } // set interactor for new node (if not already set) mitk::PlanarFigureInteractor::Pointer figureInteractor = dynamic_cast(m_SelectedNode->GetInteractor()); if(figureInteractor.IsNull()) figureInteractor = mitk::PlanarFigureInteractor::New("PlanarFigureInteractor", m_SelectedNode); mitk::GlobalInteraction::GetInstance()->AddInteractor(figureInteractor); m_SelectedNode->SetProperty("planarfigure.iseditable",mitk::BoolProperty::New(true)); } } void QmitkControlVisualizationPropertiesView::SetInteractor() { typedef std::vector Container; Container _NodeSet = this->GetDataManagerSelection(); mitk::DataNode* node = 0; mitk::FiberBundle* bundle = 0; mitk::FiberBundleInteractor::Pointer bundleInteractor = 0; // finally add all nodes to the model for(Container::const_iterator it=_NodeSet.begin(); it!=_NodeSet.end() ; it++) { node = const_cast(*it); bundle = dynamic_cast(node->GetData()); if(bundle) { bundleInteractor = dynamic_cast(node->GetInteractor()); if(bundleInteractor.IsNotNull()) mitk::GlobalInteraction::GetInstance()->RemoveInteractor(bundleInteractor); if(!m_Controls->m_Crosshair->isChecked()) { m_Controls->m_Crosshair->setChecked(false); this->GetActiveStdMultiWidget()->GetRenderWindow4()->setCursor(Qt::ArrowCursor); m_CurrentPickingNode = 0; } else { m_Controls->m_Crosshair->setChecked(true); bundleInteractor = mitk::FiberBundleInteractor::New("FiberBundleInteractor", node); mitk::GlobalInteraction::GetInstance()->AddInteractor(bundleInteractor); this->GetActiveStdMultiWidget()->GetRenderWindow4()->setCursor(Qt::CrossCursor); m_CurrentPickingNode = node; } } } } void QmitkControlVisualizationPropertiesView::PFWidth(int w) { double width = w/10.0; m_SelectedNode->SetProperty("planarfigure.line.width", mitk::FloatProperty::New(width) ); m_SelectedNode->SetProperty("planarfigure.shadow.widthmodifier", mitk::FloatProperty::New(width) ); m_SelectedNode->SetProperty("planarfigure.outline.width", mitk::FloatProperty::New(width) ); m_SelectedNode->SetProperty("planarfigure.helperline.width", mitk::FloatProperty::New(width) ); mitk::RenderingManager::GetInstance()->RequestUpdateAll(); QString label = "Width %1"; label = label.arg(width); m_Controls->label_pfwidth->setText(label); } void QmitkControlVisualizationPropertiesView::PFColor() { QColor color = QColorDialog::getColor(); m_Controls->m_PFColor->setAutoFillBackground(true); QString styleSheet = "background-color:rgb("; styleSheet.append(QString::number(color.red())); styleSheet.append(","); styleSheet.append(QString::number(color.green())); styleSheet.append(","); styleSheet.append(QString::number(color.blue())); styleSheet.append(")"); m_Controls->m_PFColor->setStyleSheet(styleSheet); m_SelectedNode->SetProperty( "planarfigure.default.line.color", mitk::ColorProperty::New(color.red()/255.0, color.green()/255.0, color.blue()/255.0)); m_SelectedNode->SetProperty( "planarfigure.default.outline.color", mitk::ColorProperty::New(color.red()/255.0, color.green()/255.0, color.blue()/255.0)); m_SelectedNode->SetProperty( "planarfigure.default.helperline.color", mitk::ColorProperty::New(color.red()/255.0, color.green()/255.0, color.blue()/255.0)); m_SelectedNode->SetProperty( "planarfigure.default.markerline.color", mitk::ColorProperty::New(color.red()/255.0, color.green()/255.0, color.blue()/255.0)); m_SelectedNode->SetProperty( "planarfigure.default.marker.color", mitk::ColorProperty::New(color.red()/255.0, color.green()/255.0, color.blue()/255.0)); m_SelectedNode->SetProperty( "planarfigure.hover.line.color", mitk::ColorProperty::New(color.red()/255.0, color.green()/255.0, color.blue()/255.0) ); m_SelectedNode->SetProperty( "planarfigure.hover.outline.color", mitk::ColorProperty::New(color.red()/255.0, color.green()/255.0, color.blue()/255.0) ); m_SelectedNode->SetProperty( "planarfigure.hover.helperline.color", mitk::ColorProperty::New(color.red()/255.0, color.green()/255.0, color.blue()/255.0) ); // m_SelectedNode->SetProperty( "planarfigure.hover.markerline.color", mitk::ColorProperty::New(0.0,1.0,0.0) ); // m_SelectedNode->SetProperty( "planarfigure.hover.marker.color", mitk::ColorProperty::New(0.0,1.0,0.0) ); // m_SelectedNode->SetProperty( "planarfigure.selected.line.color", mitk::ColorProperty::New(1.0,0.0,0.0) ); // m_SelectedNode->SetProperty( "planarfigure.selected.outline.color", mitk::ColorProperty::New(1.0,0.0,0.0) ); // m_SelectedNode->SetProperty( "planarfigure.selected.helperline.color", mitk::ColorProperty::New(1.0,0.0,0.0) ); // m_SelectedNode->SetProperty( "planarfigure.selected.markerline.color", mitk::ColorProperty::New(1.0,0.0,0.0) ); // m_SelectedNode->SetProperty( "planarfigure.selected.marker.color", mitk::ColorProperty::New(1.0,0.0,0.0) ); mitk::RenderingManager::GetInstance()->RequestUpdateAll(); } void QmitkControlVisualizationPropertiesView::PFColor3D() { QColor color = QColorDialog::getColor(); m_Controls->m_PFColor3D->setAutoFillBackground(true); QString styleSheet = "background-color:rgb("; styleSheet.append(QString::number(color.red())); styleSheet.append(","); styleSheet.append(QString::number(color.green())); styleSheet.append(","); styleSheet.append(QString::number(color.blue())); styleSheet.append(")"); m_Controls->m_PFColor3D->setStyleSheet(styleSheet); m_SelectedNode->SetProperty( "color", mitk::ColorProperty::New(color.red()/255.0, color.green()/255.0, color.blue()/255.0)); mitk::RenderingManager::GetInstance()->RequestUpdateAll(); } void QmitkControlVisualizationPropertiesView::Heatmap() { if(m_SelectedNode) { mitk::FiberBundle* bundle = dynamic_cast(m_SelectedNode->GetData()); if(!bundle) return; /////////////////////////////// // Generate unsigned char Image typedef unsigned char OutPixType2; // run generator typedef itk::Image< float, 3 > WMPImageType; typedef itk::TractsToProbabilityImageFilter ImageGeneratorType2; ImageGeneratorType2::Pointer generator = ImageGeneratorType2::New(); //generator->SetInput(NULL); generator->SetFiberBundle(bundle); generator->SetInvertImage(false); generator->SetUpsamplingFactor(2); generator->SetBinaryEnvelope(false); generator->Update(); // get result typedef itk::Image OutType2; OutType2::Pointer outImg = generator->GetOutput(); mitk::Image::Pointer img2 = mitk::Image::New(); img2->InitializeByItk(outImg.GetPointer()); img2->SetVolume(outImg->GetBufferPointer()); // to datastorage mitk::DataNode::Pointer node = mitk::DataNode::New(); node->SetData(img2); QString name(m_SelectedNode->GetName().c_str()); name += "_heatmap"; node->SetName(name.toStdString()); node->SetVisibility(true); GetDataStorage()->Add(node); } } void QmitkControlVisualizationPropertiesView::LineWidthChanged(int w) { m_SelectedNode->SetIntProperty("LineWidth", w); QString label = "Width %1"; label = label.arg(w); m_Controls->label_linewidth->setText(label); } void QmitkControlVisualizationPropertiesView::TubeRadiusChanged(int r) { m_SelectedNode->SetFloatProperty("TubeRadius", (float) r / 100.0); QString label = "Radius %1"; label = label.arg(r / 100.0); m_Controls->label_tuberadius->setText(label); } void QmitkControlVisualizationPropertiesView::Welcome() { berry::PlatformUI::GetWorkbench()->GetIntroManager()->ShowIntro( GetSite()->GetWorkbenchWindow(), false); } diff --git a/Modules/DiffusionImaging/Rendering/mitkOdfVtkMapper2D.h b/Modules/DiffusionImaging/Rendering/mitkOdfVtkMapper2D.h index 69eea3f4de..f85c4d013f 100644 --- a/Modules/DiffusionImaging/Rendering/mitkOdfVtkMapper2D.h +++ b/Modules/DiffusionImaging/Rendering/mitkOdfVtkMapper2D.h @@ -1,154 +1,154 @@ /*========================================================================= Program: Medical Imaging & Interaction Toolkit Language: C++ Date: $Date: 2008-02-08 13:23:19 +0100 (Fr, 08 Feb 2008) $ Version: $Revision: 13561 $ Copyright (c) German Cancer Research Center, Division of Medical and Biological Informatics. All rights reserved. See MITKCopyright.txt or http://www.mitk.org/copyright.html for details. This software is distributed WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the above copyright notices for more information. =========================================================================*/ #ifndef ODFVTKMAPPER2D_H_HEADER_INCLUDED #define ODFVTKMAPPER2D_H_HEADER_INCLUDED #include "mitkVtkMapper2D.h" #include "vtkPropAssembly.h" #include "vtkAppendPolyData.h" #include "vtkActor.h" #include "vtkPolyDataMapper.h" #include "vtkPlane.h" #include "vtkCutter.h" #include "vtkClipPolyData.h" #include "vtkTransform.h" #include "vtkDataArrayTemplate.h" #include "vtkSmartPointer.h" #include "vtkOdfSource.h" #include "vtkThickPlane.h" //#include "mitkTrackingCameraController.h" namespace mitk { //##Documentation //## @brief Base class of all vtk-based 2D-Mappers //## //## Those must implement the abstract //## method vtkProp* GetProp(). //## @ingroup Mapper template class OdfVtkMapper2D : public VtkMapper2D { struct OdfDisplayGeometry { vtkFloatingPointType vp[ 3 ], vnormal[ 3 ]; Vector3D normal; double d, d1, d2; mitk::Point3D M3D, L3D, O3D; vtkFloatingPointType vp_original[ 3 ], vnormal_original[ 3 ]; mitk::Vector2D size, origin; - bool Equals(OdfDisplayGeometry* other) + bool Equals(OdfDisplayGeometry other) { - return other->vp_original[0] == vp[0] && - other->vp_original[1] == vp[1] && - other->vp_original[2] == vp[2] && - other->vnormal_original[0] == vnormal[0] && - other->vnormal_original[1] == vnormal[1] && - other->vnormal_original[2] == vnormal[2] && - other->size[0] == size[0] && - other->size[1] == size[1] && - other->origin[0] == origin[0] && - other->origin[1] == origin[1]; + return other.vp_original[0] == vp[0] && + other.vp_original[1] == vp[1] && + other.vp_original[2] == vp[2] && + other.vnormal_original[0] == vnormal[0] && + other.vnormal_original[1] == vnormal[1] && + other.vnormal_original[2] == vnormal[2] && + other.size[0] == size[0] && + other.size[1] == size[1] && + other.origin[0] == origin[0] && + other.origin[1] == origin[1]; } }; public: mitkClassMacro(OdfVtkMapper2D,VtkMapper2D); itkNewMacro(Self); virtual vtkProp* GetVtkProp(mitk::BaseRenderer* renderer); bool IsVisibleOdfs(mitk::BaseRenderer* renderer); virtual void MitkRenderOverlay(mitk::BaseRenderer* renderer); virtual void MitkRenderOpaqueGeometry(mitk::BaseRenderer* renderer); virtual void MitkRenderTranslucentGeometry(mitk::BaseRenderer* renderer); virtual void MitkRenderVolumetricGeometry(mitk::BaseRenderer* /*renderer*/){}; - OdfDisplayGeometry* MeasureDisplayedGeometry(mitk::BaseRenderer* renderer); + OdfDisplayGeometry MeasureDisplayedGeometry(mitk::BaseRenderer* renderer); void AdaptCameraPosition(mitk::BaseRenderer* renderer, OdfDisplayGeometry* dispGeo ); void AdaptOdfScalingToImageSpacing( int index ); void SetRendererLightSources( mitk::BaseRenderer *renderer ); void ApplyPropertySettings(); virtual void Slice(mitk::BaseRenderer* renderer, - OdfDisplayGeometry* dispGeo); + OdfDisplayGeometry dispGeo); virtual int GetIndex(mitk::BaseRenderer* renderer); static void SetDefaultProperties(DataNode* node, BaseRenderer* renderer = NULL, bool overwrite = false); virtual void GenerateData(); virtual void GenerateDataForRenderer(mitk::BaseRenderer* renderer); virtual bool IsLODEnabled( BaseRenderer * /*renderer*/ ) const { return true; } protected: OdfVtkMapper2D(); virtual ~OdfVtkMapper2D(); static void GlyphMethod(void *arg); bool IsPlaneRotated(mitk::BaseRenderer* renderer); private: std::vector m_PropAssemblies; std::vector m_OdfsPlanes; std::vector m_OdfsActors; std::vector m_OdfsMappers; vtkPolyData* m_TemplateOdf; static vtkSmartPointer m_OdfTransform; static vtkSmartPointer m_OdfVals; static vtkSmartPointer m_OdfSource; static float m_Scaling; static int m_Normalization; static int m_ScaleBy; static float m_IndexParam1; static float m_IndexParam2; int m_ShowMaxNumber; //std::vector m_TrackingCameraControllers; std::vector m_Planes; std::vector m_Cutters; std::vector m_ThickPlanes1; std::vector m_Clippers1; std::vector m_ThickPlanes2; std::vector m_Clippers2; vtkImageData* m_VtkImage ; mitk::Image* GetInput(); - OdfDisplayGeometry* m_LastDisplayGeometry; + OdfDisplayGeometry m_LastDisplayGeometry; }; } // namespace mitk #include "mitkOdfVtkMapper2D.txx" #endif /* ODFVTKMAPPER2D_H_HEADER_INCLUDED */ diff --git a/Modules/DiffusionImaging/Rendering/mitkOdfVtkMapper2D.txx b/Modules/DiffusionImaging/Rendering/mitkOdfVtkMapper2D.txx index 3d5425c6bf..5bdb3ceeed 100644 --- a/Modules/DiffusionImaging/Rendering/mitkOdfVtkMapper2D.txx +++ b/Modules/DiffusionImaging/Rendering/mitkOdfVtkMapper2D.txx @@ -1,1168 +1,1172 @@ /*========================================================================= Program: Medical Imaging & Interaction Toolkit Language: C++ Date: $Date: 2008-08-25 18:10:57 +0200 (Mo, 25 Aug 2008) $ Version: $Revision: 15062 $ Copyright (c) German Cancer Research Center, Division of Medical and Biological Informatics. All rights reserved. See MITKCopyright.txt or http://www.mitk.org/copyright.html for details. This software is distributed WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the above copyright notices for more information. =========================================================================*/ #ifndef __mitkOdfVtkMapper2D_txx__ #define __mitkOdfVtkMapper2D_txx__ #include "mitkOdfVtkMapper2D.h" #include "mitkDataNode.h" #include "mitkBaseRenderer.h" #include "mitkMatrixConvert.h" #include "mitkGeometry3D.h" #include "mitkOdfNormalizationMethodProperty.h" #include "mitkOdfScaleByProperty.h" #include "mitkProperties.h" #include "mitkTensorImage.h" #include "vtkSphereSource.h" #include "vtkPropCollection.h" #include "vtkMaskedGlyph3D.h" #include "vtkGlyph2D.h" #include "vtkGlyph3D.h" #include "vtkMaskedProgrammableGlyphFilter.h" #include "vtkImageData.h" #include "vtkLinearTransform.h" #include "vtkCamera.h" #include "vtkPointData.h" #include "vtkTransformPolyDataFilter.h" #include "vtkTransform.h" #include "vtkOdfSource.h" #include "vtkDoubleArray.h" #include "vtkLookupTable.h" #include "vtkProperty.h" #include "vtkPolyDataNormals.h" #include "vtkLight.h" #include "vtkLightCollection.h" #include "vtkMath.h" #include "vtkFloatArray.h" #include "vtkDelaunay2D.h" #include "vtkMapper.h" #include "vtkRenderer.h" #include "vtkCamera.h" #include "itkOrientationDistributionFunction.h" #include "itkFixedArray.h" #include #include "vtkOpenGLRenderer.h" template vtkSmartPointer mitk::OdfVtkMapper2D::m_OdfTransform = vtkSmartPointer::New(); template vtkSmartPointer mitk::OdfVtkMapper2D::m_OdfVals = vtkSmartPointer::New(); template vtkSmartPointer mitk::OdfVtkMapper2D::m_OdfSource = vtkSmartPointer::New(); template float mitk::OdfVtkMapper2D::m_Scaling; template int mitk::OdfVtkMapper2D::m_Normalization; template int mitk::OdfVtkMapper2D::m_ScaleBy; template float mitk::OdfVtkMapper2D::m_IndexParam1; template float mitk::OdfVtkMapper2D::m_IndexParam2; #define ODF_MAPPER_PI 3.1415926535897932384626433832795 //#include "vtkSphereSource.h" //#include "vtkPolyDataMapper.h" //#include "vtkActor.h" //#include "vtkRenderWindow.h" //#include "vtkRenderer.h" //#include "vtkRenderWindowInteractor.h" //#include "vtkProperty.h" // //void bla(vtkPolyData* poly) //{ // // // map to graphics library // vtkPolyDataMapper *map = vtkPolyDataMapper::New(); // map->SetInput(poly); // // // actor coordinates geometry, properties, transformation // vtkActor *aSphere = vtkActor::New(); // aSphere->SetMapper(map); // aSphere->GetProperty()->SetColor(0,0,1); // sphere color blue // // // a renderer and render window // vtkRenderer *ren1 = vtkRenderer::New(); // vtkRenderWindow *renWin = vtkRenderWindow::New(); // renWin->AddRenderer(ren1); // // // an interactor // vtkRenderWindowInteractor *iren = vtkRenderWindowInteractor::New(); // iren->SetRenderWindow(renWin); // // // add the actor to the scene // ren1->AddActor(aSphere); // ren1->SetBackground(1,1,1); // Background color white // // // render an image (lights and cameras are created automatically) // renWin->Render(); // // // begin mouse interaction // iren->Start(); //} template mitk::OdfVtkMapper2D ::OdfVtkMapper2D() { - m_LastDisplayGeometry = 0; - m_PropAssemblies.push_back(vtkPropAssembly::New()); m_PropAssemblies.push_back(vtkPropAssembly::New()); m_PropAssemblies.push_back(vtkPropAssembly::New()); m_OdfsPlanes.push_back(vtkAppendPolyData::New()); m_OdfsPlanes.push_back(vtkAppendPolyData::New()); m_OdfsPlanes.push_back(vtkAppendPolyData::New()); m_OdfsPlanes[0]->AddInput(vtkPolyData::New()); m_OdfsPlanes[1]->AddInput(vtkPolyData::New()); m_OdfsPlanes[2]->AddInput(vtkPolyData::New()); m_OdfsActors.push_back(vtkActor::New()); m_OdfsActors.push_back(vtkActor::New()); m_OdfsActors.push_back(vtkActor::New()); m_OdfsActors[0]->GetProperty()->SetInterpolationToGouraud(); m_OdfsActors[1]->GetProperty()->SetInterpolationToGouraud(); m_OdfsActors[2]->GetProperty()->SetInterpolationToGouraud(); m_OdfsMappers.push_back(vtkPolyDataMapper::New()); m_OdfsMappers.push_back(vtkPolyDataMapper::New()); m_OdfsMappers.push_back(vtkPolyDataMapper::New()); vtkLookupTable *lut = vtkLookupTable::New(); //lut->SetMinimumTableValue(0,0,1,1); //lut->SetMaximumTableValue(1,0,0,1); //lut->SetWindow(0.1); //lut->SetLevel(0.05); <== not recognized or reset by mapper ?? //lut->Build(); m_OdfsMappers[0]->SetLookupTable(lut); m_OdfsMappers[1]->SetLookupTable(lut); m_OdfsMappers[2]->SetLookupTable(lut); m_OdfsActors[0]->SetMapper(m_OdfsMappers[0]); m_OdfsActors[1]->SetMapper(m_OdfsMappers[1]); m_OdfsActors[2]->SetMapper(m_OdfsMappers[2]); m_Planes.push_back(vtkPlane::New()); m_Planes.push_back(vtkPlane::New()); m_Planes.push_back(vtkPlane::New()); m_Cutters.push_back(vtkCutter::New()); m_Cutters.push_back(vtkCutter::New()); m_Cutters.push_back(vtkCutter::New()); m_Cutters[0]->SetCutFunction( m_Planes[0] ); m_Cutters[0]->GenerateValues( 1, 0, 1 ); m_Cutters[1]->SetCutFunction( m_Planes[1] ); m_Cutters[1]->GenerateValues( 1, 0, 1 ); m_Cutters[2]->SetCutFunction( m_Planes[2] ); m_Cutters[2]->GenerateValues( 1, 0, 1 ); // Windowing the cutted planes in direction 1 m_ThickPlanes1.push_back(vtkThickPlane::New()); m_ThickPlanes1.push_back(vtkThickPlane::New()); m_ThickPlanes1.push_back(vtkThickPlane::New()); m_Clippers1.push_back(vtkClipPolyData::New()); m_Clippers1.push_back(vtkClipPolyData::New()); m_Clippers1.push_back(vtkClipPolyData::New()); m_Clippers1[0]->SetClipFunction( m_ThickPlanes1[0] ); m_Clippers1[1]->SetClipFunction( m_ThickPlanes1[1] ); m_Clippers1[2]->SetClipFunction( m_ThickPlanes1[2] ); // Windowing the cutted planes in direction 2 m_ThickPlanes2.push_back(vtkThickPlane::New()); m_ThickPlanes2.push_back(vtkThickPlane::New()); m_ThickPlanes2.push_back(vtkThickPlane::New()); m_Clippers2.push_back(vtkClipPolyData::New()); m_Clippers2.push_back(vtkClipPolyData::New()); m_Clippers2.push_back(vtkClipPolyData::New()); m_Clippers2[0]->SetClipFunction( m_ThickPlanes2[0] ); m_Clippers2[1]->SetClipFunction( m_ThickPlanes2[1] ); m_Clippers2[2]->SetClipFunction( m_ThickPlanes2[2] ); m_TemplateOdf = itk::OrientationDistributionFunction::GetBaseMesh(); //vtkPoints* points = m_TemplateOdf->GetPoints(); m_OdfVals->Allocate(N); m_OdfSource->SetTemplateOdf(m_TemplateOdf); m_OdfSource->SetOdfVals(m_OdfVals); m_ShowMaxNumber = 500; //vtkMapper::GlobalImmediateModeRenderingOn(); } template mitk::OdfVtkMapper2D ::~OdfVtkMapper2D() { m_PropAssemblies[0]->Delete(); m_PropAssemblies[1]->Delete(); m_PropAssemblies[2]->Delete(); m_OdfsPlanes[0]->Delete(); m_OdfsPlanes[1]->Delete(); m_OdfsPlanes[2]->Delete(); m_OdfsActors[0]->Delete(); m_OdfsActors[1]->Delete(); m_OdfsActors[2]->Delete(); m_OdfsMappers[0]->Delete(); m_OdfsMappers[1]->Delete(); m_OdfsMappers[2]->Delete(); m_Planes[0]->Delete(); m_Planes[1]->Delete(); m_Planes[2]->Delete(); m_Cutters[0]->Delete(); m_Cutters[1]->Delete(); m_Cutters[2]->Delete(); m_ThickPlanes1[0]->Delete(); m_ThickPlanes1[1]->Delete(); m_ThickPlanes1[2]->Delete(); m_ThickPlanes2[0]->Delete(); m_ThickPlanes2[1]->Delete(); m_ThickPlanes2[2]->Delete(); m_Clippers1[0]->Delete(); m_Clippers1[1]->Delete(); m_Clippers1[2]->Delete(); m_Clippers2[0]->Delete(); m_Clippers2[1]->Delete(); m_Clippers2[2]->Delete(); } template mitk::Image* mitk::OdfVtkMapper2D ::GetInput() { return static_cast ( m_DataNode->GetData() ); } template vtkProp* mitk::OdfVtkMapper2D ::GetVtkProp(mitk::BaseRenderer* renderer) { return m_PropAssemblies[GetIndex(renderer)]; } template int mitk::OdfVtkMapper2D ::GetIndex(mitk::BaseRenderer* renderer) { if(!strcmp(renderer->GetName(),"stdmulti.widget1")) return 0; if(!strcmp(renderer->GetName(),"stdmulti.widget2")) return 1; if(!strcmp(renderer->GetName(),"stdmulti.widget3")) return 2; return 0; } template void mitk::OdfVtkMapper2D ::GlyphMethod(void *arg) { vtkMaskedProgrammableGlyphFilter *pfilter=(vtkMaskedProgrammableGlyphFilter*)arg; double point[3]; double debugpoint[3]; pfilter->GetPoint(point); pfilter->GetPoint(debugpoint); itk::Point p(point); Vector3D spacing = pfilter->GetGeometry()->GetSpacing(); p[0] /= spacing[0]; p[1] /= spacing[1]; p[2] /= spacing[2]; mitk::Point3D p2; pfilter->GetGeometry()->IndexToWorld( p, p2 ); point[0] = p2[0]; point[1] = p2[1]; point[2] = p2[2]; vtkPointData* data = pfilter->GetPointData(); vtkDataArray* odfvals = data->GetArray("vector"); vtkIdType id = pfilter->GetPointId(); m_OdfTransform->Identity(); m_OdfTransform->Translate(point[0],point[1],point[2]); typedef itk::OrientationDistributionFunction OdfType; OdfType odf; if(odfvals->GetNumberOfComponents()==6) { float tensorelems[6] = { (float)odfvals->GetComponent(id,0), (float)odfvals->GetComponent(id,1), (float)odfvals->GetComponent(id,2), (float)odfvals->GetComponent(id,3), (float)odfvals->GetComponent(id,4), (float)odfvals->GetComponent(id,5), }; itk::DiffusionTensor3D tensor(tensorelems); odf.InitFromTensor(tensor); } else { for(int i=0; iGetComponent(id,i); } switch(m_Normalization) { case ODFN_MINMAX: odf = odf.MinMaxNormalize(); break; case ODFN_MAX: odf = odf.MaxNormalize(); break; case ODFN_NONE: // nothing break; case ODFN_GLOBAL_MAX: // global max not implemented yet break; default: odf = odf.MinMaxNormalize(); } switch(m_ScaleBy) { case ODFSB_NONE: m_OdfSource->SetAdditionalScale(1.0); break; case ODFSB_GFA: m_OdfSource->SetAdditionalScale(odf.GetGeneralizedGFA(m_IndexParam1, m_IndexParam2)); break; case ODFSB_PC: m_OdfSource->SetAdditionalScale(odf.GetPrincipleCurvature(m_IndexParam1, m_IndexParam2, 0)); break; } for(int i=0; iSetComponent(0,i,0.5*odf[i]*m_Scaling); //double max = -100000; //double min = 100000; //for( unsigned int i=0; i max ? odf[i] : max; // min = odf[i] < min ? odf[i] : min; //} m_OdfSource->Modified(); } template void mitk::OdfVtkMapper2D ::AdaptCameraPosition(mitk::BaseRenderer* renderer, OdfDisplayGeometry* dispGeo ) { double viewAngle = renderer->GetVtkRenderer()->GetActiveCamera()->GetViewAngle(); viewAngle = viewAngle * (ODF_MAPPER_PI/180.0); viewAngle /= 2; - double dist = dispGeo->d/tan(viewAngle); + double dist = dispGeo.d/tan(viewAngle); mitk::Point3D mfoc; - mfoc[0]=dispGeo->M3D[0]; - mfoc[1]=dispGeo->M3D[1]; - mfoc[2]=dispGeo->M3D[2]; + mfoc[0]=dispGeo.M3D[0]; + mfoc[1]=dispGeo.M3D[1]; + mfoc[2]=dispGeo.M3D[2]; mitk::Point3D mpos; - mpos[0]=mfoc[0]+dist*dispGeo->normal[0]; - mpos[1]=mfoc[1]+dist*dispGeo->normal[1]; - mpos[2]=mfoc[2]+dist*dispGeo->normal[2]; + mpos[0]=mfoc[0]+dist*dispGeo.normal[0]; + mpos[1]=mfoc[1]+dist*dispGeo.normal[1]; + mpos[2]=mfoc[2]+dist*dispGeo.normal[2]; mitk::Point3D mup; - mup[0]=dispGeo->O3D[0]-dispGeo->M3D[0]; - mup[1]=dispGeo->O3D[1]-dispGeo->M3D[1]; - mup[2]=dispGeo->O3D[2]-dispGeo->M3D[2]; + mup[0]=dispGeo.O3D[0]-dispGeo.M3D[0]; + mup[1]=dispGeo.O3D[1]-dispGeo.M3D[1]; + mup[2]=dispGeo.O3D[2]-dispGeo.M3D[2]; renderer->GetVtkRenderer()->GetActiveCamera()->SetParallelProjection(true); renderer->GetVtkRenderer()->GetActiveCamera()->SetParallelScale(dist/3.74); vtkCamera* camera = renderer->GetVtkRenderer()->GetActiveCamera(); if (camera) { camera->SetPosition(mpos[0],mpos[1],mpos[2]); camera->SetFocalPoint(mfoc[0], mfoc[1],mfoc[2]); camera->SetViewUp(mup[0],mup[1],mup[2]); } renderer->GetVtkRenderer()->ResetCameraClippingRange(); } template -typename mitk::OdfVtkMapper2D::OdfDisplayGeometry* mitk::OdfVtkMapper2D +typename mitk::OdfVtkMapper2D::OdfDisplayGeometry mitk::OdfVtkMapper2D ::MeasureDisplayedGeometry(mitk::BaseRenderer* renderer) { //vtkLinearTransform * vtktransform = this->GetDataNode()->GetVtkTransform(this->GetTimestep()); - Geometry2D::ConstPointer worldGeometry = + Geometry2D::ConstPointer worldGeometry = renderer->GetCurrentWorldGeometry2D(); PlaneGeometry::ConstPointer worldPlaneGeometry = dynamic_cast( worldGeometry.GetPointer() ); // set up the cutter orientation according to the current geometry of // the renderers plane vtkFloatingPointType vp[ 3 ], vnormal[ 3 ]; Point3D point = worldPlaneGeometry->GetOrigin(); Vector3D normal = worldPlaneGeometry->GetNormal(); normal.Normalize(); vnl2vtk( point.Get_vnl_vector(), vp ); vnl2vtk( normal.Get_vnl_vector(), vnormal ); mitk::DisplayGeometry::Pointer dispGeometry = renderer->GetDisplayGeometry(); mitk::Vector2D size = dispGeometry->GetSizeInMM(); mitk::Vector2D origin = dispGeometry->GetOriginInMM(); // // |------O------| // | d2 | // L d1 M | // | | // |-------------| // mitk::Vector2D M; mitk::Vector2D L; mitk::Vector2D O; M[0] = origin[0] + size[0]/2; M[1] = origin[1] + size[1]/2; L[0] = origin[0]; L[1] = origin[1] + size[1]/2; O[0] = origin[0] + size[0]/2; O[1] = origin[1] + size[1]; mitk::Point2D point1; - point1[0] = M[0]; point1[1] = M[1]; point1[2] = M[2]; + point1[0] = M[0]; point1[1] = M[1]; mitk::Point3D M3D; dispGeometry->Map(point1, M3D); - point1[0] = L[0]; point1[1] = L[1]; point1[2] = L[2]; + point1[0] = L[0]; point1[1] = L[1]; mitk::Point3D L3D; dispGeometry->Map(point1, L3D); - point1[0] = O[0]; point1[1] = O[1]; point1[2] = O[2]; + point1[0] = O[0]; point1[1] = O[1]; mitk::Point3D O3D; dispGeometry->Map(point1, O3D); double d1 = sqrt((M3D[0]-L3D[0])*(M3D[0]-L3D[0]) + (M3D[1]-L3D[1])*(M3D[1]-L3D[1]) + (M3D[2]-L3D[2])*(M3D[2]-L3D[2])); double d2 = sqrt((M3D[0]-O3D[0])*(M3D[0]-O3D[0]) + (M3D[1]-O3D[1])*(M3D[1]-O3D[1]) + (M3D[2]-O3D[2])*(M3D[2]-O3D[2])); double d = d1>d2 ? d1 : d2; d = d2; - OdfDisplayGeometry* retval = new OdfDisplayGeometry(); - retval->vp[0] = vp[0]; - retval->vp[1] = vp[1]; - retval->vp[2] = vp[2]; - retval->vnormal[0] = vnormal[0]; - retval->vnormal[1] = vnormal[1]; - retval->vnormal[2] = vnormal[2]; - retval->normal[0] = normal[0]; - retval->normal[1] = normal[1]; - retval->normal[2] = normal[2]; - retval->d = d; - retval->d1 = d1; - retval->d2 = d2; - retval->M3D[0] = M3D[0]; - retval->M3D[1] = M3D[1]; - retval->M3D[2] = M3D[2]; - retval->L3D[0] = L3D[0]; - retval->L3D[1] = L3D[1]; - retval->L3D[2] = L3D[2]; - retval->O3D[0] = O3D[0]; - retval->O3D[1] = O3D[1]; - retval->O3D[2] = O3D[2]; - - retval->vp_original[0] = vp[0]; - retval->vp_original[1] = vp[1]; - retval->vp_original[2] = vp[2]; - retval->vnormal_original[0] = vnormal[0]; - retval->vnormal_original[1] = vnormal[1]; - retval->vnormal_original[2] = vnormal[2]; - retval->size[0] = size[0]; - retval->size[1] = size[1]; - retval->origin[0] = origin[0]; - retval->origin[1] = origin[1]; + OdfDisplayGeometry retval; + retval.vp[0] = vp[0]; + retval.vp[1] = vp[1]; + retval.vp[2] = vp[2]; + retval.vnormal[0] = vnormal[0]; + retval.vnormal[1] = vnormal[1]; + retval.vnormal[2] = vnormal[2]; + retval.normal[0] = normal[0]; + retval.normal[1] = normal[1]; + retval.normal[2] = normal[2]; + retval.d = d; + retval.d1 = d1; + retval.d2 = d2; + retval.M3D[0] = M3D[0]; + retval.M3D[1] = M3D[1]; + retval.M3D[2] = M3D[2]; + retval.L3D[0] = L3D[0]; + retval.L3D[1] = L3D[1]; + retval.L3D[2] = L3D[2]; + retval.O3D[0] = O3D[0]; + retval.O3D[1] = O3D[1]; + retval.O3D[2] = O3D[2]; + + retval.vp_original[0] = vp[0]; + retval.vp_original[1] = vp[1]; + retval.vp_original[2] = vp[2]; + retval.vnormal_original[0] = vnormal[0]; + retval.vnormal_original[1] = vnormal[1]; + retval.vnormal_original[2] = vnormal[2]; + retval.size[0] = size[0]; + retval.size[1] = size[1]; + retval.origin[0] = origin[0]; + retval.origin[1] = origin[1]; return retval; } template void mitk::OdfVtkMapper2D -::Slice(mitk::BaseRenderer* renderer, OdfDisplayGeometry* dispGeo) +::Slice(mitk::BaseRenderer* renderer, OdfDisplayGeometry dispGeo) { vtkLinearTransform * vtktransform = this->GetDataNode()->GetVtkTransform(this->GetTimestep()); int index = GetIndex(renderer); vtkTransform* inversetransform = vtkTransform::New(); inversetransform->Identity(); inversetransform->Concatenate(vtktransform->GetLinearInverse()); double myscale[3]; ((vtkTransform*)vtktransform)->GetScale(myscale); inversetransform->PostMultiply(); inversetransform->Scale(1*myscale[0],1*myscale[1],1*myscale[2]); - inversetransform->TransformPoint( dispGeo->vp, dispGeo->vp ); - inversetransform->TransformNormalAtPoint( dispGeo->vp, dispGeo->vnormal, dispGeo->vnormal ); + inversetransform->TransformPoint( dispGeo.vp, dispGeo.vp ); + inversetransform->TransformNormalAtPoint( dispGeo.vp, dispGeo.vnormal, dispGeo.vnormal ); // vtk works in axis align coords // thus the normal also must be axis align, since // we do not allow arbitrary cutting through volume // // vnormal should already be axis align, but in order // to get rid of precision effects, we set the two smaller // components to zero here int dims[3]; m_VtkImage->GetDimensions(dims); double spac[3]; m_VtkImage->GetSpacing(spac); - if(fabs(dispGeo->vnormal[0]) > fabs(dispGeo->vnormal[1]) - && fabs(dispGeo->vnormal[0]) > fabs(dispGeo->vnormal[2]) ) + if(fabs(dispGeo.vnormal[0]) > fabs(dispGeo.vnormal[1]) + && fabs(dispGeo.vnormal[0]) > fabs(dispGeo.vnormal[2]) ) { - if(fabs(dispGeo->vp[0]/spac[0]) < 0.4) - dispGeo->vp[0] = 0.4*spac[0]; - if(fabs(dispGeo->vp[0]/spac[0]) > (dims[0]-1)-0.4) - dispGeo->vp[0] = ((dims[0]-1)-0.4)*spac[0]; - dispGeo->vnormal[1] = 0; - dispGeo->vnormal[2] = 0; + if(fabs(dispGeo.vp[0]/spac[0]) < 0.4) + dispGeo.vp[0] = 0.4*spac[0]; + if(fabs(dispGeo.vp[0]/spac[0]) > (dims[0]-1)-0.4) + dispGeo.vp[0] = ((dims[0]-1)-0.4)*spac[0]; + dispGeo.vnormal[1] = 0; + dispGeo.vnormal[2] = 0; } - if(fabs(dispGeo->vnormal[1]) > fabs(dispGeo->vnormal[0]) && fabs(dispGeo->vnormal[1]) > fabs(dispGeo->vnormal[2]) ) + if(fabs(dispGeo.vnormal[1]) > fabs(dispGeo.vnormal[0]) && fabs(dispGeo.vnormal[1]) > fabs(dispGeo.vnormal[2]) ) { - if(fabs(dispGeo->vp[1]/spac[1]) < 0.4) - dispGeo->vp[1] = 0.4*spac[1]; - if(fabs(dispGeo->vp[1]/spac[1]) > (dims[1]-1)-0.4) - dispGeo->vp[1] = ((dims[1]-1)-0.4)*spac[1]; - dispGeo->vnormal[0] = 0; - dispGeo->vnormal[2] = 0; + if(fabs(dispGeo.vp[1]/spac[1]) < 0.4) + dispGeo.vp[1] = 0.4*spac[1]; + if(fabs(dispGeo.vp[1]/spac[1]) > (dims[1]-1)-0.4) + dispGeo.vp[1] = ((dims[1]-1)-0.4)*spac[1]; + dispGeo.vnormal[0] = 0; + dispGeo.vnormal[2] = 0; } - if(fabs(dispGeo->vnormal[2]) > fabs(dispGeo->vnormal[1]) && fabs(dispGeo->vnormal[2]) > fabs(dispGeo->vnormal[0]) ) + if(fabs(dispGeo.vnormal[2]) > fabs(dispGeo.vnormal[1]) && fabs(dispGeo.vnormal[2]) > fabs(dispGeo.vnormal[0]) ) { - if(fabs(dispGeo->vp[2]/spac[2]) < 0.4) - dispGeo->vp[2] = 0.4*spac[2]; - if(fabs(dispGeo->vp[2]/spac[2]) > (dims[2]-1)-0.4) - dispGeo->vp[2] = ((dims[2]-1)-0.4)*spac[2]; - dispGeo->vnormal[0] = 0; - dispGeo->vnormal[1] = 0; + if(fabs(dispGeo.vp[2]/spac[2]) < 0.4) + dispGeo.vp[2] = 0.4*spac[2]; + if(fabs(dispGeo.vp[2]/spac[2]) > (dims[2]-1)-0.4) + dispGeo.vp[2] = ((dims[2]-1)-0.4)*spac[2]; + dispGeo.vnormal[0] = 0; + dispGeo.vnormal[1] = 0; } m_Planes[index]->SetTransform( (vtkAbstractTransform*)NULL ); - m_Planes[index]->SetOrigin( dispGeo->vp ); - m_Planes[index]->SetNormal( dispGeo->vnormal ); + m_Planes[index]->SetOrigin( dispGeo.vp ); + m_Planes[index]->SetNormal( dispGeo.vnormal ); vtkPoints* points = NULL; vtkPoints* tmppoints = NULL; vtkPolyData* polydata = NULL; vtkFloatArray* pointdata = NULL; vtkDelaunay2D *delaunay = NULL; vtkPolyData* cuttedPlane = NULL; // the cutter only works if we do not have a 2D-image // or if we have a 2D-image and want to see the whole image. // // for side views of 2D-images, we need some special treatment - if(!( (dims[0] == 1 && dispGeo->vnormal[0] != 0) || - (dims[1] == 1 && dispGeo->vnormal[1] != 0) || - (dims[2] == 1 && dispGeo->vnormal[2] != 0) )) + if(!( (dims[0] == 1 && dispGeo.vnormal[0] != 0) || + (dims[1] == 1 && dispGeo.vnormal[1] != 0) || + (dims[2] == 1 && dispGeo.vnormal[2] != 0) )) { m_Cutters[index]->SetCutFunction( m_Planes[index] ); m_Cutters[index]->SetInput( m_VtkImage ); m_Cutters[index]->Update(); cuttedPlane = m_Cutters[index]->GetOutput(); } else { // cutting of a 2D-Volume does not work, // so we have to build up our own polydata object cuttedPlane = vtkPolyData::New(); points = vtkPoints::New(); points->SetNumberOfPoints(m_VtkImage->GetNumberOfPoints()); for(int i=0; iGetNumberOfPoints(); i++) { points->SetPoint(i, m_VtkImage->GetPoint(i)); } cuttedPlane->SetPoints(points); pointdata = vtkFloatArray::New(); int comps = m_VtkImage->GetPointData()->GetScalars()->GetNumberOfComponents(); pointdata->SetNumberOfComponents(comps); int tuples = m_VtkImage->GetPointData()->GetScalars()->GetNumberOfTuples(); pointdata->SetNumberOfTuples(tuples); for(int i=0; iSetTuple(i,m_VtkImage->GetPointData()->GetScalars()->GetTuple(i)); pointdata->SetName( "vector" ); cuttedPlane->GetPointData()->AddArray(pointdata); int nZero1, nZero2; if(dims[0]==1) { nZero1 = 1; nZero2 = 2; } else if(dims[1]==1) { nZero1 = 0; nZero2 = 2; } else { nZero1 = 0; nZero2 = 1; } tmppoints = vtkPoints::New(); for(int j=0; jGetNumberOfPoints(); j++){ double pt[3]; m_VtkImage->GetPoint(j,pt); tmppoints->InsertNextPoint(pt[nZero1],pt[nZero2],0); } polydata = vtkPolyData::New(); polydata->SetPoints( tmppoints ); delaunay = vtkDelaunay2D::New(); delaunay->SetInput( polydata ); delaunay->Update(); vtkCellArray* polys = delaunay->GetOutput()->GetPolys(); cuttedPlane->SetPolys(polys); } if(cuttedPlane->GetNumberOfPoints()) { // WINDOWING HERE inversetransform = vtkTransform::New(); inversetransform->Identity(); inversetransform->Concatenate(vtktransform->GetLinearInverse()); double myscale[3]; ((vtkTransform*)vtktransform)->GetScale(myscale); inversetransform->PostMultiply(); inversetransform->Scale(1*myscale[0],1*myscale[1],1*myscale[2]); - dispGeo->vnormal[0] = dispGeo->M3D[0]-dispGeo->O3D[0]; - dispGeo->vnormal[1] = dispGeo->M3D[1]-dispGeo->O3D[1]; - dispGeo->vnormal[2] = dispGeo->M3D[2]-dispGeo->O3D[2]; - vtkMath::Normalize(dispGeo->vnormal); - dispGeo->vp[0] = dispGeo->M3D[0]; - dispGeo->vp[1] = dispGeo->M3D[1]; - dispGeo->vp[2] = dispGeo->M3D[2]; + dispGeo.vnormal[0] = dispGeo.M3D[0]-dispGeo.O3D[0]; + dispGeo.vnormal[1] = dispGeo.M3D[1]-dispGeo.O3D[1]; + dispGeo.vnormal[2] = dispGeo.M3D[2]-dispGeo.O3D[2]; + vtkMath::Normalize(dispGeo.vnormal); + dispGeo.vp[0] = dispGeo.M3D[0]; + dispGeo.vp[1] = dispGeo.M3D[1]; + dispGeo.vp[2] = dispGeo.M3D[2]; - inversetransform->TransformPoint( dispGeo->vp, dispGeo->vp ); - inversetransform->TransformNormalAtPoint( dispGeo->vp, dispGeo->vnormal, dispGeo->vnormal ); + inversetransform->TransformPoint( dispGeo.vp, dispGeo.vp ); + inversetransform->TransformNormalAtPoint( dispGeo.vp, dispGeo.vnormal, dispGeo.vnormal ); m_ThickPlanes1[index]->count = 0; m_ThickPlanes1[index]->SetTransform((vtkAbstractTransform*)NULL ); - m_ThickPlanes1[index]->SetPose( dispGeo->vnormal, dispGeo->vp ); - m_ThickPlanes1[index]->SetThickness(dispGeo->d2); + m_ThickPlanes1[index]->SetPose( dispGeo.vnormal, dispGeo.vp ); + m_ThickPlanes1[index]->SetThickness(dispGeo.d2); m_Clippers1[index]->SetClipFunction( m_ThickPlanes1[index] ); m_Clippers1[index]->SetInput( cuttedPlane ); m_Clippers1[index]->SetInsideOut(1); m_Clippers1[index]->Update(); - dispGeo->vnormal[0] = dispGeo->M3D[0]-dispGeo->L3D[0]; - dispGeo->vnormal[1] = dispGeo->M3D[1]-dispGeo->L3D[1]; - dispGeo->vnormal[2] = dispGeo->M3D[2]-dispGeo->L3D[2]; - vtkMath::Normalize(dispGeo->vnormal); - dispGeo->vp[0] = dispGeo->M3D[0]; - dispGeo->vp[1] = dispGeo->M3D[1]; - dispGeo->vp[2] = dispGeo->M3D[2]; + dispGeo.vnormal[0] = dispGeo.M3D[0]-dispGeo.L3D[0]; + dispGeo.vnormal[1] = dispGeo.M3D[1]-dispGeo.L3D[1]; + dispGeo.vnormal[2] = dispGeo.M3D[2]-dispGeo.L3D[2]; + vtkMath::Normalize(dispGeo.vnormal); + dispGeo.vp[0] = dispGeo.M3D[0]; + dispGeo.vp[1] = dispGeo.M3D[1]; + dispGeo.vp[2] = dispGeo.M3D[2]; - inversetransform->TransformPoint( dispGeo->vp, dispGeo->vp ); - inversetransform->TransformNormalAtPoint( dispGeo->vp, dispGeo->vnormal, dispGeo->vnormal ); + inversetransform->TransformPoint( dispGeo.vp, dispGeo.vp ); + inversetransform->TransformNormalAtPoint( dispGeo.vp, dispGeo.vnormal, dispGeo.vnormal ); m_ThickPlanes2[index]->count = 0; m_ThickPlanes2[index]->SetTransform((vtkAbstractTransform*)NULL ); - m_ThickPlanes2[index]->SetPose( dispGeo->vnormal, dispGeo->vp ); - m_ThickPlanes2[index]->SetThickness(dispGeo->d1); + m_ThickPlanes2[index]->SetPose( dispGeo.vnormal, dispGeo.vp ); + m_ThickPlanes2[index]->SetThickness(dispGeo.d1); m_Clippers2[index]->SetClipFunction( m_ThickPlanes2[index] ); m_Clippers2[index]->SetInput( m_Clippers1[index]->GetOutput() ); m_Clippers2[index]->SetInsideOut(1); m_Clippers2[index]->Update(); cuttedPlane = m_Clippers2[index]->GetOutput (); if(cuttedPlane->GetNumberOfPoints()) { m_OdfsPlanes[index]->RemoveAllInputs(); vtkPolyDataNormals* normals = vtkPolyDataNormals::New(); normals->SetInputConnection( m_OdfSource->GetOutputPort() ); normals->SplittingOff(); normals->ConsistencyOff(); normals->AutoOrientNormalsOff(); normals->ComputePointNormalsOn(); normals->ComputeCellNormalsOff(); normals->FlipNormalsOff(); normals->NonManifoldTraversalOff(); vtkTransformPolyDataFilter* trans = vtkTransformPolyDataFilter::New(); trans->SetInputConnection( normals->GetOutputPort() ); trans->SetTransform(m_OdfTransform); vtkMaskedProgrammableGlyphFilter* glyphGenerator = vtkMaskedProgrammableGlyphFilter::New(); glyphGenerator->SetMaximumNumberOfPoints(m_ShowMaxNumber); glyphGenerator->SetRandomMode(1); glyphGenerator->SetUseMaskPoints(1); glyphGenerator->SetSource( trans->GetOutput() ); glyphGenerator->SetInput(cuttedPlane); glyphGenerator->SetColorModeToColorBySource(); glyphGenerator->SetInputArrayToProcess(0,0,0, vtkDataObject::FIELD_ASSOCIATION_POINTS , "vector"); glyphGenerator->SetGeometry(this->GetDataNode()->GetData()->GetGeometry()); glyphGenerator->SetGlyphMethod(&(GlyphMethod),(void *)glyphGenerator); try { glyphGenerator->Update(); } catch( itk::ExceptionObject& err ) { std::cout << err << std::endl; } m_OdfsPlanes[index]->AddInput(glyphGenerator->GetOutput()); trans->Delete(); glyphGenerator->Delete(); normals->Delete(); m_OdfsPlanes[index]->Update(); } } m_PropAssemblies[index]->VisibilityOn(); if(m_PropAssemblies[index]->GetParts()->IsItemPresent(m_OdfsActors[index])) m_PropAssemblies[index]->RemovePart(m_OdfsActors[index]); m_OdfsMappers[index]->SetInput(m_OdfsPlanes[index]->GetOutput()); m_PropAssemblies[index]->AddPart(m_OdfsActors[index]); if(inversetransform) inversetransform->Delete(); if(points) points->Delete(); if(pointdata) pointdata->Delete(); if(tmppoints) tmppoints->Delete(); if(polydata) polydata->Delete(); if(delaunay) delaunay->Delete(); } template bool mitk::OdfVtkMapper2D ::IsVisibleOdfs(mitk::BaseRenderer* renderer) { if(this->IsPlaneRotated(renderer)) return false; bool retval = false; switch(GetIndex(renderer)) { case 0: retval = this->IsVisible(renderer, "VisibleOdfs_T"); break; case 1: retval = this->IsVisible(renderer, "VisibleOdfs_S"); break; case 2: retval = this->IsVisible(renderer, "VisibleOdfs_C"); break; } return retval; } template void mitk::OdfVtkMapper2D ::MitkRenderOverlay(mitk::BaseRenderer* renderer) { - //std::cout << "MitkRenderOverlay(" << renderer->GetName() << ")" << std::endl; + //std::cout << "OdfVtkMapper2D::MitkRenderOverlay(" << renderer->GetName() << ")" << std::endl; if ( this->IsVisibleOdfs(renderer)==false ) return; if ( this->GetVtkProp(renderer)->GetVisibility() ) { this->GetVtkProp(renderer)->RenderOverlay(renderer->GetVtkRenderer()); } } template void mitk::OdfVtkMapper2D ::MitkRenderOpaqueGeometry(mitk::BaseRenderer* renderer) { - // std::cout << "MitkRenderOpaqueGeometry(" << renderer->GetName() << ")" << std::endl; + std::cout << "OdfVtkMapper2D::MitkRenderOpaqueGeometry(" << renderer->GetName() << ")" << std::endl; if ( this->IsVisibleOdfs( renderer )==false ) return; if ( this->GetVtkProp(renderer)->GetVisibility() ) { // adapt cam pos - OdfDisplayGeometry* dispGeo = MeasureDisplayedGeometry( renderer); + MITK_INFO << "hallo 1"; + OdfDisplayGeometry dispGeo = MeasureDisplayedGeometry( renderer); + MITK_INFO << "hallo 2"; //AdaptCameraPosition(renderer, dispGeo); if(/*this->GetDataNode()->IsOn("DoRefresh",NULL)*/false) { glMatrixMode( GL_PROJECTION ); glPushMatrix(); glLoadIdentity(); glMatrixMode( GL_MODELVIEW ); glPushMatrix(); glLoadIdentity(); renderer->GetVtkRenderer()->SetErase(false); renderer->GetVtkRenderer()->GetActiveCamera()->Render(renderer->GetVtkRenderer()); renderer->GetVtkRenderer()->SetErase(true); //GLfloat matrix[16]; //glGetFloatv(GL_MODELVIEW_MATRIX, matrix); float LightPos[4] = {0,0,0,0}; int index = GetIndex(renderer); if(index==0) { LightPos[2] = -1000; } if(index==1) { LightPos[0] = 1000; } if(index==2) { LightPos[1] = -1000; } glLightfv(GL_LIGHT0,GL_POSITION,LightPos); glLightfv(GL_LIGHT1,GL_POSITION,LightPos); glLightfv(GL_LIGHT2,GL_POSITION,LightPos); glLightfv(GL_LIGHT3,GL_POSITION,LightPos); glLightfv(GL_LIGHT4,GL_POSITION,LightPos); glLightfv(GL_LIGHT5,GL_POSITION,LightPos); glLightfv(GL_LIGHT6,GL_POSITION,LightPos); glLightfv(GL_LIGHT7,GL_POSITION,LightPos); } + MITK_INFO << "HERE 3"; this->GetVtkProp(renderer)->RenderOpaqueGeometry( renderer->GetVtkRenderer() ); + MITK_INFO << "HERE 4"; if(/*this->GetDataNode()->IsOn("DoRefresh",NULL)*/false) { glMatrixMode( GL_PROJECTION ); glPopMatrix(); glMatrixMode( GL_MODELVIEW ); glPopMatrix(); } + MITK_INFO << "HERE 5"; + } } template void mitk::OdfVtkMapper2D ::MitkRenderTranslucentGeometry(mitk::BaseRenderer* renderer) { - //std::cout << "MitkRenderTranslucentGeometry(" << renderer->GetName() << ")" << std::endl; + //std::cout << "OdfVtkMapper2D::MitkRenderTranslucentGeometry(" << renderer->GetName() << ")" << std::endl; if ( this->IsVisibleOdfs(renderer)==false ) return; if ( this->GetVtkProp(renderer)->GetVisibility() ) this->GetVtkProp(renderer)->RenderTranslucentPolygonalGeometry(renderer->GetVtkRenderer()); } template void mitk::OdfVtkMapper2D ::GenerateData() { mitk::Image::Pointer input = const_cast( this->GetInput() ); if ( input.IsNull() ) return ; std::string classname("TensorImage"); if(classname.compare(input->GetNameOfClass())==0) { m_VtkImage = dynamic_cast( this->GetInput() )->GetNonRgbVtkImageData(); } std::string qclassname("QBallImage"); if(qclassname.compare(input->GetNameOfClass())==0) { m_VtkImage = dynamic_cast( this->GetInput() )->GetNonRgbVtkImageData(); } if( m_VtkImage ) { // make sure, that we have point data with more than 1 component (as vectors) vtkPointData* pointData = m_VtkImage->GetPointData(); if ( pointData == NULL ) { itkWarningMacro( << "m_VtkImage->GetPointData() returns NULL!" ); return ; } if ( pointData->GetNumberOfArrays() == 0 ) { itkWarningMacro( << "m_VtkImage->GetPointData()->GetNumberOfArrays() is 0!" ); return ; } else if ( pointData->GetArray(0)->GetNumberOfComponents() != N && pointData->GetArray(0)->GetNumberOfComponents() != 6 /*for tensor visualization*/) { itkWarningMacro( << "number of components != number of directions in ODF!" ); return; } else if ( pointData->GetArrayName( 0 ) == NULL ) { m_VtkImage->GetPointData()->GetArray(0)->SetName("vector"); } } else { itkWarningMacro( << "m_VtkImage is NULL!" ); return ; } } template void mitk::OdfVtkMapper2D ::AdaptOdfScalingToImageSpacing( int index ) { // Spacing adapted scaling double spacing[3]; m_VtkImage->GetSpacing(spacing); double min; if(index==0) { min = spacing[0]; min = min > spacing[1] ? spacing[1] : min; } if(index==1) { min = spacing[1]; min = min > spacing[2] ? spacing[2] : min; } if(index==2) { min = spacing[0]; min = min > spacing[2] ? spacing[2] : min; } m_OdfSource->SetScale(min); } template void mitk::OdfVtkMapper2D ::SetRendererLightSources( mitk::BaseRenderer *renderer ) { // Light Sources vtkCollectionSimpleIterator sit; vtkLight* light; for(renderer->GetVtkRenderer()->GetLights()->InitTraversal(sit); (light = renderer->GetVtkRenderer()->GetLights()->GetNextLight(sit)); ) { renderer->GetVtkRenderer()->RemoveLight(light); } light = vtkLight::New(); light->SetFocalPoint(0,0,0); light->SetLightTypeToSceneLight(); light->SwitchOn(); light->SetIntensity(1.0); light->PositionalOff(); itk::Point p; int index = GetIndex(renderer); if(index==0) { p[0] = 0; p[1] = 0; p[2] = 10000; } if(index==1) { p[0] = 0; p[1] = 10000; p[2] = 0; } if(index==2) { p[0] = 10000; p[1] = 0; p[2] = 0; } mitk::Point3D p2; this->GetInput()->GetGeometry()->IndexToWorld(p,p2); light->SetPosition(p2[0],p2[1],p2[2]); renderer->GetVtkRenderer()->AddLight(light); } template void mitk::OdfVtkMapper2D ::ApplyPropertySettings() { this->GetDataNode()->GetFloatProperty( "Scaling", m_Scaling ); this->GetDataNode()->GetIntProperty( "ShowMaxNumber", m_ShowMaxNumber ); OdfNormalizationMethodProperty* nmp = dynamic_cast ( this->GetDataNode()->GetProperty( "Normalization" )); if(nmp) { m_Normalization = nmp->GetNormalization(); } OdfScaleByProperty* sbp = dynamic_cast ( this->GetDataNode()->GetProperty( "ScaleBy" )); if(sbp) { m_ScaleBy = sbp->GetScaleBy(); } this->GetDataNode()->GetFloatProperty( "IndexParam1", m_IndexParam1); this->GetDataNode()->GetFloatProperty( "IndexParam2", m_IndexParam2); } template bool mitk::OdfVtkMapper2D ::IsPlaneRotated(mitk::BaseRenderer* renderer) { Geometry2D::ConstPointer worldGeometry = renderer->GetCurrentWorldGeometry2D(); PlaneGeometry::ConstPointer worldPlaneGeometry = dynamic_cast( worldGeometry.GetPointer() ); vtkFloatingPointType vnormal[ 3 ]; Vector3D normal = worldPlaneGeometry->GetNormal(); normal.Normalize(); vnl2vtk( normal.Get_vnl_vector(), vnormal ); vtkLinearTransform * vtktransform = this->GetDataNode()->GetVtkTransform(this->GetTimestep()); vtkTransform* inversetransform = vtkTransform::New(); inversetransform->Identity(); inversetransform->Concatenate(vtktransform->GetLinearInverse()); double* n = inversetransform->TransformNormal(vnormal); int nonZeros = 0; for (int j=0; j<3; j++) { if (fabs(n[j])>1e-7){ nonZeros++; } } if(nonZeros>1) return true; return false; } template void mitk::OdfVtkMapper2D ::GenerateDataForRenderer( mitk::BaseRenderer *renderer ) { if(!m_VtkImage) { itkWarningMacro( << "m_VtkImage is NULL!" ); return ; } int index = GetIndex(renderer); if(IsVisibleOdfs(renderer)==false) { m_OdfsActors[0]->VisibilityOff(); m_OdfsActors[1]->VisibilityOff(); m_OdfsActors[2]->VisibilityOff(); return; } else { m_OdfsActors[0]->VisibilityOn(); m_OdfsActors[1]->VisibilityOn(); m_OdfsActors[2]->VisibilityOn(); - OdfDisplayGeometry* dispGeo = + OdfDisplayGeometry dispGeo = MeasureDisplayedGeometry( renderer); - if(!m_LastDisplayGeometry || !dispGeo->Equals(m_LastDisplayGeometry)) + if(!dispGeo.Equals(m_LastDisplayGeometry)) { AdaptOdfScalingToImageSpacing(index); SetRendererLightSources(renderer); ApplyPropertySettings(); //AdaptCameraPosition(renderer, dispGeo); Slice(renderer, dispGeo); m_LastDisplayGeometry = dispGeo; } } // Get the TimeSlicedGeometry of the input object mitk::Image::Pointer input = const_cast(this->GetInput()); const TimeSlicedGeometry *inputTimeGeometry = input->GetTimeSlicedGeometry(); if (( inputTimeGeometry == NULL ) || ( inputTimeGeometry->GetTimeSteps() == 0 )) { m_PropAssemblies[0]->VisibilityOff(); m_PropAssemblies[1]->VisibilityOff(); m_PropAssemblies[2]->VisibilityOff(); return; } if( inputTimeGeometry->IsValidTime( this->GetTimestep() ) == false ) { m_PropAssemblies[0]->VisibilityOff(); m_PropAssemblies[1]->VisibilityOff(); m_PropAssemblies[2]->VisibilityOff(); return; } } template void mitk::OdfVtkMapper2D ::SetDefaultProperties(mitk::DataNode* node, mitk::BaseRenderer* /*renderer*/, bool /*overwrite*/) { node->SetProperty( "ShowMaxNumber", mitk::IntProperty::New( 150 ) ); node->SetProperty( "Scaling", mitk::FloatProperty::New( 1.0 ) ); node->SetProperty( "Normalization", mitk::OdfNormalizationMethodProperty::New()); node->SetProperty( "ScaleBy", mitk::OdfScaleByProperty::New()); node->SetProperty( "IndexParam1", mitk::FloatProperty::New(2)); node->SetProperty( "IndexParam2", mitk::FloatProperty::New(1)); node->SetProperty( "visible", mitk::BoolProperty::New( true ) ); node->SetProperty( "VisibleOdfs_T", mitk::BoolProperty::New( false ) ); node->SetProperty( "VisibleOdfs_C", mitk::BoolProperty::New( false ) ); node->SetProperty( "VisibleOdfs_S", mitk::BoolProperty::New( false ) ); node->SetProperty ("layer", mitk::IntProperty::New(100)); node->SetProperty( "DoRefresh", mitk::BoolProperty::New( true ) ); //node->SetProperty( "opacity", mitk::FloatProperty::New(1.0f) ); } #endif // __mitkOdfVtkMapper2D_txx__