diff --git a/Modules/SegmentationUI/Qmitk/QmitkAdaptiveRegionGrowingToolGUI.cpp b/Modules/SegmentationUI/Qmitk/QmitkAdaptiveRegionGrowingToolGUI.cpp index 20ef1b65eb..d8867ee81c 100644 --- a/Modules/SegmentationUI/Qmitk/QmitkAdaptiveRegionGrowingToolGUI.cpp +++ b/Modules/SegmentationUI/Qmitk/QmitkAdaptiveRegionGrowingToolGUI.cpp @@ -1,970 +1,952 @@ /*=================================================================== 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 "QmitkAdaptiveRegionGrowingToolGUI.h" -#include "QmitkStdMultiWidget.h" - #include #include "mitkITKImageImport.h" #include "mitkImageAccessByItk.h" #include "mitkImageTimeSelector.h" #include "mitkNodePredicateDataType.h" #include "mitkProperties.h" #include "mitkTransferFunctionProperty.h" #include "mitkImageStatisticsHolder.h" #include "itkMaskImageFilter.h" #include "itkNumericTraits.h" #include #include #include #include #include "QmitkConfirmSegmentationDialog.h" #include "itkOrImageFilter.h" #include "mitkImageCast.h" #include "mitkImagePixelReadAccessor.h" #include "mitkPixelTypeMultiplex.h" #include "mitkImageCast.h" MITK_TOOL_GUI_MACRO(, QmitkAdaptiveRegionGrowingToolGUI, "") QmitkAdaptiveRegionGrowingToolGUI::QmitkAdaptiveRegionGrowingToolGUI(QWidget *parent) : QmitkToolGUI(), - m_MultiWidget(nullptr), m_DataStorage(nullptr), m_UseVolumeRendering(false), m_UpdateSuggestedThreshold(true), m_SuggestedThValue(0.0) { this->setParent(parent); m_Controls.setupUi(this); m_Controls.m_ThresholdSlider->setDecimals(1); m_Controls.m_ThresholdSlider->setSpinBoxAlignment(Qt::AlignVCenter); m_Controls.m_PreviewSlider->setEnabled(false); m_Controls.m_PreviewSlider->setSingleStep(0.5); // Not yet available // m_Controls.m_PreviewSlider->InvertedAppearance(true); //3D preview doesn't work: T24430. Postponed until reimplementation of segmentation m_Controls.m_cbVolumeRendering->setVisible(false); this->CreateConnections(); this->SetDataNodeNames("labeledRGSegmentation", "RGResult", "RGFeedbackSurface", "maskedSegmentation"); connect(this, SIGNAL(NewToolAssociated(mitk::Tool *)), this, SLOT(OnNewToolAssociated(mitk::Tool *))); } QmitkAdaptiveRegionGrowingToolGUI::~QmitkAdaptiveRegionGrowingToolGUI() { // Removing the observer of the PointSet node if (m_RegionGrow3DTool->GetPointSetNode().IsNotNull()) { m_RegionGrow3DTool->GetPointSetNode()->GetData()->RemoveObserver(m_PointSetAddObserverTag); m_RegionGrow3DTool->GetPointSetNode()->GetData()->RemoveObserver(m_PointSetMoveObserverTag); } this->RemoveHelperNodes(); } void QmitkAdaptiveRegionGrowingToolGUI::OnNewToolAssociated(mitk::Tool *tool) { m_RegionGrow3DTool = dynamic_cast(tool); if (m_RegionGrow3DTool.IsNotNull()) { SetInputImageNode(this->m_RegionGrow3DTool->GetReferenceData()); this->m_DataStorage = this->m_RegionGrow3DTool->GetDataStorage(); this->EnableControls(true); // Watch for point added or modified itk::SimpleMemberCommand::Pointer pointAddedCommand = itk::SimpleMemberCommand::New(); pointAddedCommand->SetCallbackFunction(this, &QmitkAdaptiveRegionGrowingToolGUI::OnPointAdded); m_PointSetAddObserverTag = m_RegionGrow3DTool->GetPointSetNode()->GetData()->AddObserver(mitk::PointSetAddEvent(), pointAddedCommand); m_PointSetMoveObserverTag = m_RegionGrow3DTool->GetPointSetNode()->GetData()->AddObserver(mitk::PointSetMoveEvent(), pointAddedCommand); } else { this->EnableControls(false); } } void QmitkAdaptiveRegionGrowingToolGUI::RemoveHelperNodes() { mitk::DataNode::Pointer imageNode = m_DataStorage->GetNamedNode(m_NAMEFORLABLEDSEGMENTATIONIMAGE); if (imageNode.IsNotNull()) { m_DataStorage->Remove(imageNode); } mitk::DataNode::Pointer maskedSegmentationNode = m_DataStorage->GetNamedNode(m_NAMEFORMASKEDSEGMENTATION); if (maskedSegmentationNode.IsNotNull()) { m_DataStorage->Remove(maskedSegmentationNode); } } void QmitkAdaptiveRegionGrowingToolGUI::CreateConnections() { // Connecting GUI components connect((QObject *)(m_Controls.m_pbRunSegmentation), SIGNAL(clicked()), this, SLOT(RunSegmentation())); connect(m_Controls.m_PreviewSlider, SIGNAL(valueChanged(double)), this, SLOT(ChangeLevelWindow(double))); connect((QObject *)(m_Controls.m_pbConfirmSegementation), SIGNAL(clicked()), this, SLOT(ConfirmSegmentation())); connect( m_Controls.m_ThresholdSlider, SIGNAL(maximumValueChanged(double)), this, SLOT(SetUpperThresholdValue(double))); connect( m_Controls.m_ThresholdSlider, SIGNAL(minimumValueChanged(double)), this, SLOT(SetLowerThresholdValue(double))); } void QmitkAdaptiveRegionGrowingToolGUI::SetDataNodeNames(std::string labledSegmentation, std::string binaryImage, std::string surface, std::string maskedSegmentation) { m_NAMEFORLABLEDSEGMENTATIONIMAGE = labledSegmentation; m_NAMEFORBINARYIMAGE = binaryImage; m_NAMEFORSURFACE = surface; m_NAMEFORMASKEDSEGMENTATION = maskedSegmentation; } void QmitkAdaptiveRegionGrowingToolGUI::SetDataStorage(mitk::DataStorage *dataStorage) { m_DataStorage = dataStorage; } -void QmitkAdaptiveRegionGrowingToolGUI::SetMultiWidget(QmitkStdMultiWidget *multiWidget) -{ - m_MultiWidget = multiWidget; -} - void QmitkAdaptiveRegionGrowingToolGUI::SetInputImageNode(mitk::DataNode *node) { m_InputImageNode = node; mitk::Image *inputImage = dynamic_cast(m_InputImageNode->GetData()); if (inputImage) { mitk::ScalarType max = inputImage->GetStatistics()->GetScalarValueMax(); mitk::ScalarType min = inputImage->GetStatistics()->GetScalarValueMin(); m_Controls.m_ThresholdSlider->setMaximum(max); m_Controls.m_ThresholdSlider->setMinimum(min); // Just for initialization m_Controls.m_ThresholdSlider->setMaximumValue(max); m_Controls.m_ThresholdSlider->setMinimumValue(min); } } template static void AccessPixel(mitk::PixelType /*ptype*/, const mitk::Image::Pointer im, mitk::Point3D p, int &val) { mitk::ImagePixelReadAccessor access(im); val = access.GetPixelByWorldCoordinates(p); } void QmitkAdaptiveRegionGrowingToolGUI::OnPointAdded() { if (m_RegionGrow3DTool.IsNull()) return; mitk::DataNode *node = m_RegionGrow3DTool->GetPointSetNode(); if (node != nullptr) { mitk::PointSet::Pointer pointSet = dynamic_cast(node->GetData()); if (pointSet.IsNull()) { QMessageBox::critical(nullptr, "QmitkAdaptiveRegionGrowingToolGUI", "PointSetNode does not contain a pointset"); return; } m_Controls.m_lblSetSeedpoint->setText(""); mitk::Image *image = dynamic_cast(m_InputImageNode->GetData()); mitk::Point3D seedPoint = pointSet ->GetPointSet( mitk::BaseRenderer::GetInstance(mitk::BaseRenderer::GetRenderWindowByName("stdmulti.widget1"))->GetTimeStep()) ->GetPoints() ->ElementAt(0); if (image->GetGeometry()->IsInside(seedPoint)) mitkPixelTypeMultiplex3( AccessPixel, image->GetChannelDescriptor().GetPixelType(), image, seedPoint, m_SeedpointValue) else return; /* In this case the seedpoint is placed e.g. in the lung or bronchialtree * The lowerFactor sets the windowsize depending on the regiongrowing direction */ m_CurrentRGDirectionIsUpwards = true; if (m_SeedpointValue < -500) { m_CurrentRGDirectionIsUpwards = false; } // Initializing the region by the area around the seedpoint m_SeedPointValueMean = 0; itk::Index<3> currentIndex, runningIndex; mitk::ScalarType pixelValues[125]; unsigned int pos(0); image->GetGeometry(0)->WorldToIndex(seedPoint, currentIndex); runningIndex = currentIndex; for (int i = runningIndex[0] - 2; i <= runningIndex[0] + 2; i++) { for (int j = runningIndex[1] - 2; j <= runningIndex[1] + 2; j++) { for (int k = runningIndex[2] - 2; k <= runningIndex[2] + 2; k++) { currentIndex[0] = i; currentIndex[1] = j; currentIndex[2] = k; if (image->GetGeometry()->IsIndexInside(currentIndex)) { int component = 0; m_InputImageNode->GetIntProperty("Image.Displayed Component", component); mitkPixelTypeMultiplex4(mitk::FastSinglePixelAccess, image->GetChannelDescriptor().GetPixelType(), image, nullptr, currentIndex, pixelValues[pos]); pos++; } else { pixelValues[pos] = std::numeric_limits::min(); pos++; } } } } // Now calculation mean of the pixelValues // Now calculation mean of the pixelValues unsigned int numberOfValues(0); for (auto &pixelValue : pixelValues) { if (pixelValue > std::numeric_limits::min()) { m_SeedPointValueMean += pixelValue; numberOfValues++; } } m_SeedPointValueMean = m_SeedPointValueMean / numberOfValues; mitk::ScalarType var = 0; if (numberOfValues > 1) { for (auto &pixelValue : pixelValues) { if (pixelValue > std::numeric_limits::min()) { var += (pixelValue - m_SeedPointValueMean) * (pixelValue - m_SeedPointValueMean); } } var /= numberOfValues - 1; } mitk::ScalarType stdDev = sqrt(var); /* * Here the upper- and lower threshold is calculated: * The windowSize is 20% of the maximum range of the intensity values existing in the current image * If the RG direction is upwards the lower TH is meanSeedValue-0.15*windowSize and upper TH is * meanSeedValue+0.85*windowsSize * if the RG direction is downwards the lower TH is meanSeedValue-0.85*windowSize and upper TH is * meanSeedValue+0.15*windowsSize */ mitk::ScalarType min = image->GetStatistics()->GetScalarValueMin(); mitk::ScalarType max = image->GetStatistics()->GetScalarValueMax(); mitk::ScalarType windowSize = max - min; windowSize = 0.15 * windowSize; if (m_CurrentRGDirectionIsUpwards) { m_LOWERTHRESHOLD = m_SeedPointValueMean - stdDev; m_UPPERTHRESHOLD = m_SeedpointValue + windowSize; if (m_UPPERTHRESHOLD > max) m_UPPERTHRESHOLD = max; m_Controls.m_ThresholdSlider->setMaximumValue(m_UPPERTHRESHOLD); m_Controls.m_ThresholdSlider->setMinimumValue(m_LOWERTHRESHOLD); } else { m_UPPERTHRESHOLD = m_SeedPointValueMean; if (m_SeedpointValue > m_SeedPointValueMean) m_UPPERTHRESHOLD = m_SeedpointValue; m_LOWERTHRESHOLD = m_SeedpointValue - windowSize; if (m_LOWERTHRESHOLD < min) m_LOWERTHRESHOLD = min; m_Controls.m_ThresholdSlider->setMinimumValue(m_LOWERTHRESHOLD); m_Controls.m_ThresholdSlider->setMaximumValue(m_UPPERTHRESHOLD); } } } void QmitkAdaptiveRegionGrowingToolGUI::RunSegmentation() { if (m_InputImageNode.IsNull()) { QMessageBox::information(nullptr, "Adaptive Region Growing functionality", "Please specify the image in Datamanager!"); return; } mitk::DataNode::Pointer node = m_RegionGrow3DTool->GetPointSetNode(); if (node.IsNull()) { QMessageBox::information(nullptr, "Adaptive Region Growing functionality", "Please insert a seed point inside the " "image.\n\nFirst press the \"Define Seed " "Point\" button,\nthen click left mouse " "button inside the image."); return; } // safety if no pointSet or pointSet empty mitk::PointSet::Pointer seedPointSet = dynamic_cast(node->GetData()); if (seedPointSet.IsNull()) { m_Controls.m_pbRunSegmentation->setEnabled(true); QMessageBox::information( nullptr, "Adaptive Region Growing functionality", "The seed point is empty! Please choose a new seed point."); return; } int timeStep = mitk::BaseRenderer::GetInstance(mitk::BaseRenderer::GetRenderWindowByName("stdmulti.widget1"))->GetTimeStep(); if (!(seedPointSet->GetSize(timeStep))) { m_Controls.m_pbRunSegmentation->setEnabled(true); QMessageBox::information( nullptr, "Adaptive Region Growing functionality", "The seed point is empty! Please choose a new seed point."); return; } QApplication::setOverrideCursor(QCursor(Qt::WaitCursor)); mitk::PointSet::PointType seedPoint = seedPointSet->GetPointSet(timeStep)->GetPoints()->Begin().Value(); mitk::Image::Pointer orgImage = dynamic_cast(m_InputImageNode->GetData()); if (orgImage.IsNotNull()) { if (orgImage->GetDimension() == 4) { mitk::ImageTimeSelector::Pointer timeSelector = mitk::ImageTimeSelector::New(); timeSelector->SetInput(orgImage); timeSelector->SetTimeNr(timeStep); timeSelector->UpdateLargestPossibleRegion(); mitk::Image *timedImage = timeSelector->GetOutput(); AccessByItk_2(timedImage, StartRegionGrowing, timedImage->GetGeometry(), seedPoint); } else if (orgImage->GetDimension() == 3) { // QApplication::setOverrideCursor(QCursor(Qt::WaitCursor)); //set the cursor to waiting AccessByItk_2(orgImage, StartRegionGrowing, orgImage->GetGeometry(), seedPoint); // QApplication::restoreOverrideCursor();//reset cursor } else { QApplication::restoreOverrideCursor(); // reset cursor QMessageBox::information( nullptr, "Adaptive Region Growing functionality", "Only images of dimension 3 or 4 can be processed!"); return; } } EnableControls(true); // Segmentation ran successfully, so enable all controls. node->SetVisibility(true); QApplication::restoreOverrideCursor(); // reset cursor } template void QmitkAdaptiveRegionGrowingToolGUI::StartRegionGrowing(itk::Image *itkImage, mitk::BaseGeometry *imageGeometry, mitk::PointSet::PointType seedPoint) { typedef itk::Image InputImageType; typedef typename InputImageType::IndexType IndexType; typedef itk::ConnectedAdaptiveThresholdImageFilter RegionGrowingFilterType; typename RegionGrowingFilterType::Pointer regionGrower = RegionGrowingFilterType::New(); typedef itk::BinaryThresholdImageFilter ThresholdFilterType; typedef itk::MaskImageFilter MaskImageFilterType; if (!imageGeometry->IsInside(seedPoint)) { QApplication::restoreOverrideCursor(); // reset cursor to be able to click ok with the regular mouse cursor QMessageBox::information(nullptr, "Segmentation functionality", "The seed point is outside of the image! Please choose a position inside the image!"); return; } IndexType seedIndex; imageGeometry->WorldToIndex(seedPoint, seedIndex); // convert world coordinates to image indices if (m_SeedpointValue > m_UPPERTHRESHOLD || m_SeedpointValue < m_LOWERTHRESHOLD) { QApplication::restoreOverrideCursor(); // reset cursor to be able to click ok with the regular mouse cursor QMessageBox::information( nullptr, "Segmentation functionality", "The seed point is outside the defined thresholds! Please set a new seed point or adjust the thresholds."); MITK_INFO << "Mean: " << m_SeedPointValueMean; return; } // Setting the direction of the regiongrowing. For dark structures e.g. the lung the regiongrowing // is performed starting at the upper value going to the lower one regionGrower->SetGrowingDirectionIsUpwards(m_CurrentRGDirectionIsUpwards); regionGrower->SetInput(itkImage); regionGrower->AddSeed(seedIndex); // In some cases we have to subtract 1 for the lower threshold and add 1 to the upper. // Otherwise no region growing is done. Maybe a bug in the ConnectiveAdaptiveThresholdFilter regionGrower->SetLower(m_LOWERTHRESHOLD - 1); regionGrower->SetUpper(m_UPPERTHRESHOLD + 1); try { regionGrower->Update(); } catch (itk::ExceptionObject &exc) { QMessageBox errorInfo; errorInfo.setWindowTitle("Adaptive RG Segmentation Functionality"); errorInfo.setIcon(QMessageBox::Critical); errorInfo.setText("An error occurred during region growing!"); errorInfo.setDetailedText(exc.what()); errorInfo.exec(); return; // can't work } catch (...) { QMessageBox::critical(nullptr, "Adaptive RG Segmentation Functionality", "An error occurred during region growing!"); return; } mitk::Image::Pointer resultImage = mitk::ImportItkImage(regionGrower->GetOutput())->Clone(); // initialize slider m_Controls.m_PreviewSlider->setMinimum(m_LOWERTHRESHOLD); mitk::ScalarType max = m_SeedpointValue + resultImage->GetStatistics()->GetScalarValueMax(); if (max < m_UPPERTHRESHOLD) m_Controls.m_PreviewSlider->setMaximum(max); else m_Controls.m_PreviewSlider->setMaximum(m_UPPERTHRESHOLD); this->m_DetectedLeakagePoint = regionGrower->GetLeakagePoint(); if (m_CurrentRGDirectionIsUpwards) { m_Controls.m_PreviewSlider->setValue(m_SeedPointValueMean - 1); } else { m_Controls.m_PreviewSlider->setValue(m_SeedPointValueMean + 1); } this->m_SliderInitialized = true; // create new node and then delete the old one if there is one mitk::DataNode::Pointer newNode = mitk::DataNode::New(); newNode->SetData(resultImage); // set some properties newNode->SetProperty("name", mitk::StringProperty::New(m_NAMEFORLABLEDSEGMENTATIONIMAGE)); newNode->SetProperty("helper object", mitk::BoolProperty::New(true)); newNode->SetProperty("color", mitk::ColorProperty::New(0.0, 1.0, 0.0)); newNode->SetProperty("layer", mitk::IntProperty::New(1)); newNode->SetProperty("opacity", mitk::FloatProperty::New(0.7)); // delete the old image, if there was one: mitk::DataNode::Pointer binaryNode = m_DataStorage->GetNamedNode(m_NAMEFORLABLEDSEGMENTATIONIMAGE); m_DataStorage->Remove(binaryNode); // now add result to data tree m_DataStorage->Add(newNode, m_InputImageNode); typename InputImageType::Pointer inputImageItk; mitk::CastToItkImage(resultImage, inputImageItk); // volume rendering preview masking typename ThresholdFilterType::Pointer thresholdFilter = ThresholdFilterType::New(); thresholdFilter->SetInput(inputImageItk); thresholdFilter->SetInsideValue(1); thresholdFilter->SetOutsideValue(0); double sliderVal = this->m_Controls.m_PreviewSlider->value(); if (m_CurrentRGDirectionIsUpwards) { thresholdFilter->SetLowerThreshold(sliderVal); thresholdFilter->SetUpperThreshold(itk::NumericTraits::max()); } else { thresholdFilter->SetLowerThreshold(itk::NumericTraits::min()); thresholdFilter->SetUpperThreshold(sliderVal); } thresholdFilter->SetInPlace(false); typename MaskImageFilterType::Pointer maskFilter = MaskImageFilterType::New(); maskFilter->SetInput(inputImageItk); maskFilter->SetInPlace(false); maskFilter->SetMaskImage(thresholdFilter->GetOutput()); maskFilter->SetOutsideValue(0); maskFilter->UpdateLargestPossibleRegion(); mitk::Image::Pointer mitkMask; mitk::CastToMitkImage(maskFilter->GetOutput(), mitkMask); mitk::DataNode::Pointer maskedNode = mitk::DataNode::New(); maskedNode->SetData(mitkMask); // set some properties maskedNode->SetProperty("name", mitk::StringProperty::New(m_NAMEFORMASKEDSEGMENTATION)); maskedNode->SetProperty("helper object", mitk::BoolProperty::New(true)); maskedNode->SetProperty("color", mitk::ColorProperty::New(0.0, 1.0, 0.0)); maskedNode->SetProperty("layer", mitk::IntProperty::New(1)); maskedNode->SetProperty("opacity", mitk::FloatProperty::New(0.0)); // delete the old image, if there was one: mitk::DataNode::Pointer deprecatedMask = m_DataStorage->GetNamedNode(m_NAMEFORMASKEDSEGMENTATION); m_DataStorage->Remove(deprecatedMask); // now add result to data tree m_DataStorage->Add(maskedNode, m_InputImageNode); this->InitializeLevelWindow(); if (m_UseVolumeRendering) this->EnableVolumeRendering(true); m_UpdateSuggestedThreshold = true; // reset first stored threshold value // Setting progress to finished mitk::ProgressBar::GetInstance()->Progress(357); mitk::RenderingManager::GetInstance()->RequestUpdateAll(); } void QmitkAdaptiveRegionGrowingToolGUI::InitializeLevelWindow() { // get the preview from the datatree mitk::DataNode::Pointer newNode = m_DataStorage->GetNamedNode(m_NAMEFORLABLEDSEGMENTATIONIMAGE); mitk::LevelWindow tempLevelWindow; newNode->GetLevelWindow(tempLevelWindow, nullptr, "levelwindow"); mitk::ScalarType *level = new mitk::ScalarType(0.0); mitk::ScalarType *window = new mitk::ScalarType(1.0); int upper; if (m_CurrentRGDirectionIsUpwards) { upper = m_UPPERTHRESHOLD - m_SeedpointValue; } else { upper = m_SeedpointValue - m_LOWERTHRESHOLD; } tempLevelWindow.SetRangeMinMax(mitk::ScalarType(0), mitk::ScalarType(upper)); // get the suggested threshold from the detected leakage-point and adjust the slider if (m_CurrentRGDirectionIsUpwards) { this->m_Controls.m_PreviewSlider->setValue(m_SeedpointValue); *level = m_UPPERTHRESHOLD - (m_SeedpointValue) + 0.5; } else { this->m_Controls.m_PreviewSlider->setValue(m_SeedpointValue); *level = (m_SeedpointValue)-m_LOWERTHRESHOLD + 0.5; } tempLevelWindow.SetLevelWindow(*level, *window); newNode->SetLevelWindow(tempLevelWindow, nullptr, "levelwindow"); // update the widgets mitk::RenderingManager::GetInstance()->RequestUpdateAll(); m_SliderInitialized = true; // inquiry need to fix bug#1828 static int lastSliderPosition = 0; if ((this->m_SeedpointValue + this->m_DetectedLeakagePoint - 1) == lastSliderPosition) { this->ChangeLevelWindow(lastSliderPosition); } lastSliderPosition = this->m_SeedpointValue + this->m_DetectedLeakagePoint - 1; - if (m_MultiWidget) - { - this->m_MultiWidget->levelWindowWidget->GetManager()->SetAutoTopMostImage(false); - this->m_MultiWidget->levelWindowWidget->GetManager()->SetLevelWindowProperty( - static_cast(newNode->GetProperty("levelwindow"))); - } - if (m_UseVolumeRendering) this->UpdateVolumeRenderingThreshold((int)(*level + 0.5)); // lower threshold for labeled image } void QmitkAdaptiveRegionGrowingToolGUI::ChangeLevelWindow(double newValue) { if (m_SliderInitialized) { // do nothing, if no preview exists mitk::DataNode::Pointer newNode = m_DataStorage->GetNamedNode(m_NAMEFORLABLEDSEGMENTATIONIMAGE); if (newNode.IsNull()) return; mitk::LevelWindow tempLevelWindow; newNode->GetLevelWindow(tempLevelWindow, nullptr, "levelwindow"); // get the levelWindow associated with the preview mitk::ScalarType level; // = this->m_UPPERTHRESHOLD - newValue + 0.5; mitk::ScalarType *window = new mitk::ScalarType(1); // adjust the levelwindow according to the position of the slider (newvalue) if (m_CurrentRGDirectionIsUpwards) { level = m_UPPERTHRESHOLD - newValue + 0.5; tempLevelWindow.SetLevelWindow(level, *window); } else { level = newValue - m_LOWERTHRESHOLD + 0.5; tempLevelWindow.SetLevelWindow(level, *window); } newNode->SetLevelWindow(tempLevelWindow, nullptr, "levelwindow"); if (m_UseVolumeRendering) this->UpdateVolumeRenderingThreshold((int)(level - 0.5)); // lower threshold for labeled image newNode->SetVisibility(true); mitk::RenderingManager::GetInstance()->RequestUpdateAll(); } } void QmitkAdaptiveRegionGrowingToolGUI::DecreaseSlider() { // moves the slider one step to the left, when the "-"-button is pressed if (this->m_Controls.m_PreviewSlider->value() != this->m_Controls.m_PreviewSlider->minimum()) { int newValue = this->m_Controls.m_PreviewSlider->value() - 1; this->ChangeLevelWindow(newValue); this->m_Controls.m_PreviewSlider->setValue(newValue); } } void QmitkAdaptiveRegionGrowingToolGUI::IncreaseSlider() { // moves the slider one step to the right, when the "+"-button is pressed if (this->m_Controls.m_PreviewSlider->value() != this->m_Controls.m_PreviewSlider->maximum()) { int newValue = this->m_Controls.m_PreviewSlider->value() + 1; this->ChangeLevelWindow(newValue); this->m_Controls.m_PreviewSlider->setValue(newValue); } } void QmitkAdaptiveRegionGrowingToolGUI::ConfirmSegmentation() { // get image node if (m_InputImageNode.IsNull()) { QMessageBox::critical(nullptr, "Adaptive region growing functionality", "Please specify the image in Datamanager!"); return; } // get image data mitk::Image::Pointer orgImage = dynamic_cast(m_InputImageNode->GetData()); if (orgImage.IsNull()) { QMessageBox::critical(nullptr, "Adaptive region growing functionality", "No Image found!"); return; } // get labeled segmentation mitk::Image::Pointer labeledSeg = (mitk::Image *)m_DataStorage->GetNamedObject(m_NAMEFORLABLEDSEGMENTATIONIMAGE); if (labeledSeg.IsNull()) { QMessageBox::critical(nullptr, "Adaptive region growing functionality", "No Segmentation Preview found!"); return; } mitk::DataNode::Pointer newNode = m_DataStorage->GetNamedNode(m_NAMEFORLABLEDSEGMENTATIONIMAGE); if (newNode.IsNull()) return; QmitkConfirmSegmentationDialog dialog; QString segName = QString::fromStdString(m_RegionGrow3DTool->GetCurrentSegmentationName()); dialog.SetSegmentationName(segName); int result = dialog.exec(); switch (result) { case QmitkConfirmSegmentationDialog::CREATE_NEW_SEGMENTATION: m_RegionGrow3DTool->SetOverwriteExistingSegmentation(false); break; case QmitkConfirmSegmentationDialog::OVERWRITE_SEGMENTATION: m_RegionGrow3DTool->SetOverwriteExistingSegmentation(true); break; case QmitkConfirmSegmentationDialog::CANCEL_SEGMENTATION: return; } mitk::Image::Pointer img = dynamic_cast(newNode->GetData()); AccessByItk(img, ITKThresholding); // disable volume rendering preview after the segmentation node was created this->EnableVolumeRendering(false); newNode->SetVisibility(false); m_Controls.m_cbVolumeRendering->setChecked(false); // TODO disable slider etc... if (m_RegionGrow3DTool.IsNotNull()) { m_RegionGrow3DTool->ConfirmSegmentation(); } } template void QmitkAdaptiveRegionGrowingToolGUI::ITKThresholding(itk::Image *itkImage) { mitk::Image::Pointer originalSegmentation = dynamic_cast(this->m_RegionGrow3DTool->GetTargetSegmentationNode()->GetData()); int timeStep = mitk::BaseRenderer::GetInstance(mitk::BaseRenderer::GetRenderWindowByName("stdmulti.widget1"))->GetTimeStep(); if (originalSegmentation) { typedef itk::Image InputImageType; typedef itk::Image SegmentationType; // select single 3D volume if we have more than one time step typename SegmentationType::Pointer originalSegmentationInITK = SegmentationType::New(); if (originalSegmentation->GetTimeGeometry()->CountTimeSteps() > 1) { mitk::ImageTimeSelector::Pointer timeSelector = mitk::ImageTimeSelector::New(); timeSelector->SetInput(originalSegmentation); timeSelector->SetTimeNr(timeStep); timeSelector->UpdateLargestPossibleRegion(); CastToItkImage(timeSelector->GetOutput(), originalSegmentationInITK); } else // use original { CastToItkImage(originalSegmentation, originalSegmentationInITK); } // Fill current preiview image in segmentation image originalSegmentationInITK->FillBuffer(0); itk::ImageRegionIterator itOutput(originalSegmentationInITK, originalSegmentationInITK->GetLargestPossibleRegion()); itk::ImageRegionIterator itInput(itkImage, itkImage->GetLargestPossibleRegion()); itOutput.GoToBegin(); itInput.GoToBegin(); // calculate threhold from slider value int currentTreshold = 0; if (m_CurrentRGDirectionIsUpwards) { currentTreshold = m_UPPERTHRESHOLD - m_Controls.m_PreviewSlider->value() + 1; } else { currentTreshold = m_Controls.m_PreviewSlider->value() - m_LOWERTHRESHOLD; } // iterate over image and set pixel in segmentation according to thresholded labeled image while (!itOutput.IsAtEnd() && !itInput.IsAtEnd()) { // Use threshold slider to determine if pixel is set to 1 if (itInput.Value() != 0 && itInput.Value() >= static_cast::PixelType>(currentTreshold)) { itOutput.Set(1); } ++itOutput; ++itInput; } // combine current working segmentation image with our region growing result originalSegmentation->SetVolume((void *)(originalSegmentationInITK->GetPixelContainer()->GetBufferPointer()), timeStep); originalSegmentation->Modified(); mitk::RenderingManager::GetInstance()->RequestUpdateAll(); } } void QmitkAdaptiveRegionGrowingToolGUI::EnableControls(bool enable) { if (m_RegionGrow3DTool.IsNull()) return; // Check if seed point is already set, if not leave RunSegmentation disabled // if even m_DataStorage is nullptr leave node nullptr mitk::DataNode::Pointer node = m_RegionGrow3DTool->GetPointSetNode(); if (node.IsNull()) { this->m_Controls.m_pbRunSegmentation->setEnabled(false); } else { this->m_Controls.m_pbRunSegmentation->setEnabled(enable); } // Check if a segmentation exists, if not leave segmentation dependent disabled. // if even m_DataStorage is nullptr leave node nullptr node = m_DataStorage ? m_DataStorage->GetNamedNode(m_NAMEFORLABLEDSEGMENTATIONIMAGE) : nullptr; if (node.IsNull()) { this->m_Controls.m_PreviewSlider->setEnabled(false); this->m_Controls.m_pbConfirmSegementation->setEnabled(false); } else { this->m_Controls.m_PreviewSlider->setEnabled(enable); this->m_Controls.m_pbConfirmSegementation->setEnabled(enable); } this->m_Controls.m_cbVolumeRendering->setEnabled(enable); } void QmitkAdaptiveRegionGrowingToolGUI::EnableVolumeRendering(bool enable) { mitk::DataNode::Pointer node = m_DataStorage->GetNamedNode(m_NAMEFORMASKEDSEGMENTATION); if (node.IsNull()) return; - if (m_MultiWidget) - m_MultiWidget->SetWidgetPlanesVisibility(!enable); - if (enable) { node->SetBoolProperty("volumerendering", enable); node->SetBoolProperty("volumerendering.uselod", true); } else { node->SetBoolProperty("volumerendering", enable); } double val = this->m_Controls.m_PreviewSlider->value(); this->ChangeLevelWindow(val); mitk::RenderingManager::GetInstance()->RequestUpdateAll(); } void QmitkAdaptiveRegionGrowingToolGUI::UpdateVolumeRenderingThreshold(int) { typedef short PixelType; typedef itk::Image InputImageType; typedef itk::BinaryThresholdImageFilter ThresholdFilterType; typedef itk::MaskImageFilter MaskImageFilterType; mitk::DataNode::Pointer grownImageNode = m_DataStorage->GetNamedNode(m_NAMEFORLABLEDSEGMENTATIONIMAGE); mitk::Image::Pointer grownImage = dynamic_cast(grownImageNode->GetData()); if (!grownImage) { MITK_ERROR << "Missing data node for labeled segmentation image."; return; } InputImageType::Pointer itkGrownImage; mitk::CastToItkImage(grownImage, itkGrownImage); ThresholdFilterType::Pointer thresholdFilter = ThresholdFilterType::New(); thresholdFilter->SetInput(itkGrownImage); thresholdFilter->SetInPlace(false); double sliderVal = this->m_Controls.m_PreviewSlider->value(); PixelType threshold = itk::NumericTraits::min(); if (m_CurrentRGDirectionIsUpwards) { threshold = static_cast(m_UPPERTHRESHOLD - sliderVal + 0.5); thresholdFilter->SetLowerThreshold(threshold); thresholdFilter->SetUpperThreshold(itk::NumericTraits::max()); } else { threshold = sliderVal - m_LOWERTHRESHOLD + 0.5; thresholdFilter->SetLowerThreshold(itk::NumericTraits::min()); thresholdFilter->SetUpperThreshold(threshold); } thresholdFilter->UpdateLargestPossibleRegion(); MaskImageFilterType::Pointer maskFilter = MaskImageFilterType::New(); maskFilter->SetInput(itkGrownImage); maskFilter->SetInPlace(false); maskFilter->SetMaskImage(thresholdFilter->GetOutput()); maskFilter->SetOutsideValue(0); maskFilter->UpdateLargestPossibleRegion(); mitk::Image::Pointer mitkMaskedImage; mitk::CastToMitkImage(maskFilter->GetOutput(), mitkMaskedImage); mitk::DataNode::Pointer maskNode = m_DataStorage->GetNamedNode(m_NAMEFORMASKEDSEGMENTATION); maskNode->SetData(mitkMaskedImage); } void QmitkAdaptiveRegionGrowingToolGUI::UseVolumeRendering(bool on) { m_UseVolumeRendering = on; this->EnableVolumeRendering(on); } void QmitkAdaptiveRegionGrowingToolGUI::SetLowerThresholdValue(double lowerThreshold) { m_LOWERTHRESHOLD = lowerThreshold; } void QmitkAdaptiveRegionGrowingToolGUI::SetUpperThresholdValue(double upperThreshold) { m_UPPERTHRESHOLD = upperThreshold; } void QmitkAdaptiveRegionGrowingToolGUI::Deactivated() { // make the segmentation preview node invisible mitk::DataNode::Pointer node = m_DataStorage->GetNamedNode(m_NAMEFORLABLEDSEGMENTATIONIMAGE); if (node.IsNotNull()) { node->SetVisibility(false); } // disable volume rendering preview after the segmentation node was created this->EnableVolumeRendering(false); m_Controls.m_cbVolumeRendering->setChecked(false); } void QmitkAdaptiveRegionGrowingToolGUI::Activated() { } diff --git a/Modules/SegmentationUI/Qmitk/QmitkAdaptiveRegionGrowingToolGUI.h b/Modules/SegmentationUI/Qmitk/QmitkAdaptiveRegionGrowingToolGUI.h index 4177033e7e..6fdbfc16f2 100644 --- a/Modules/SegmentationUI/Qmitk/QmitkAdaptiveRegionGrowingToolGUI.h +++ b/Modules/SegmentationUI/Qmitk/QmitkAdaptiveRegionGrowingToolGUI.h @@ -1,232 +1,222 @@ /*=================================================================== 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 QMITK_QmitkAdaptiveRegionGrowingToolGUI_H #define QMITK_QmitkAdaptiveRegionGrowingToolGUI_H #include "itkImage.h" #include "mitkDataStorage.h" #include "mitkGeometry3D.h" #include "mitkPointSet.h" #include "qwidget.h" #include "ui_QmitkAdaptiveRegionGrowingToolGUIControls.h" #include #include "QmitkToolGUI.h" #include "mitkAdaptiveRegionGrowingTool.h" -class QmitkStdMultiWidget; class DataNode; class QmitkAdaptiveRegionGrowingToolGUIControls; /*! * * \brief QmitkAdaptiveRegionGrowingToolGUI * * Adaptive Region Growing View class of the segmentation. * */ class MITKSEGMENTATIONUI_EXPORT QmitkAdaptiveRegionGrowingToolGUI : public QmitkToolGUI { Q_OBJECT public: /** * @brief mitkClassMacro */ mitkClassMacro(QmitkAdaptiveRegionGrowingToolGUI, QmitkToolGUI); itkFactorylessNewMacro(Self) itkCloneMacro(Self) QmitkAdaptiveRegionGrowingToolGUI(QWidget *parent = nullptr); /** \brief Method to create the connections for the component. This Method is obligatory even if no connections is * needed*/ virtual void CreateConnections(); ///** \brief Method to set the default data storage.*/ virtual void SetDataStorage(mitk::DataStorage *dataStorage); - /** - * @brief Method to set the used multiwidget. - * @param multiWidget - */ - void SetMultiWidget(QmitkStdMultiWidget *multiWidget); - /** * @brief Method to set the name of a data node. * @param labledSegmentation Name of the labeled segmentation * @param binaryImage Name of the binary image * @param surface Name of the surface */ void SetDataNodeNames(std::string labledSegmentation, std::string binaryImage, /*std::string vesselTree,*/ std::string surface, std::string maskedSegmentation); /** * @brief Method to enable/disable controls for region growing * * This method checks if a seed point is set and a segmentation exists. * @param enable/disable controls */ void EnableControls(bool enable); /** * @brief Method to set the input image node * @param data node */ void SetInputImageNode(mitk::DataNode *node); void Deactivated(); void Activated(); /** * @brief The created GUI from the .ui-File. This Attribute is obligatory */ Ui::QmitkAdaptiveRegionGrowingToolGUIControls m_Controls; protected slots: /** * @brief Method to start the segmentation * * This method is called, when the "Start Segmentation" button is clicked. */ void RunSegmentation(); /** * @brief Method to change the level window * * This method is called, when the level window slider is changed via the slider in the control widget * @param new value */ void ChangeLevelWindow(double newValue); /** * @brief Method to increase the preview slider * * This method is called, when the + button is clicked and increases the value by 1 */ void IncreaseSlider(); /** * @brief Method to decrease the preview slider * * This method is called, when the - button is clicked and decreases the value by 1 */ void DecreaseSlider(); /** * @brief Method to confirm the preview segmentation * * This method is called, when the "Confirm Segmentation" button is clicked. */ void ConfirmSegmentation(); /** * @brief Method to switch the volume rendering on/off * @param on/off */ void UseVolumeRendering(bool on); /** * @brief Method to set the lower threshold * * This method is called, when the minimum threshold slider has changed * @param lower threshold */ void SetLowerThresholdValue(double lowerThreshold); /** * @brief Method to set upper threshold * * This Method is called, when the maximum threshold slider has changed * @param upper threshold */ void SetUpperThresholdValue(double upperThreshold); /** * @brief Method to determine which tool to activate * * This method listens to the tool manager and activates this tool if requested otherwise disables this view */ void OnNewToolAssociated(mitk::Tool *); protected: mitk::AdaptiveRegionGrowingTool::Pointer m_RegionGrow3DTool; /** \brief Destructor. */ ~QmitkAdaptiveRegionGrowingToolGUI() override; - // Pointer to the main widget to be able to reach the renderer - QmitkStdMultiWidget *m_MultiWidget; - mitk::DataStorage *m_DataStorage; mitk::DataNode::Pointer m_InputImageNode; /** * @brief Method to calculate parameter settings, when a seed point is set */ void OnPointAdded(); private: std::string m_NAMEFORORGIMAGE; std::string m_NAMEFORLABLEDSEGMENTATIONIMAGE; std::string m_NAMEFORBINARYIMAGE; std::string m_NAMEFORSURFACE; std::string m_NAMEFORMASKEDSEGMENTATION; mitk::ScalarType m_LOWERTHRESHOLD; // Hounsfield value mitk::ScalarType m_UPPERTHRESHOLD; // Hounsfield value mitk::ScalarType m_SeedPointValueMean; void RemoveHelperNodes(); int m_DetectedLeakagePoint; bool m_CurrentRGDirectionIsUpwards; // defines fixed threshold (true = LOWERTHRESHOLD fixed, false = UPPERTHRESHOLD // fixed) int m_SeedpointValue; bool m_SliderInitialized; bool m_UseVolumeRendering; bool m_UpdateSuggestedThreshold; float m_SuggestedThValue; long m_PointSetAddObserverTag; long m_PointSetMoveObserverTag; template void StartRegionGrowing(itk::Image *itkImage, mitk::BaseGeometry *imageGeometry, mitk::PointSet::PointType seedPoint); template void ITKThresholding(itk::Image *inputImage); void InitializeLevelWindow(); void EnableVolumeRendering(bool enable); void UpdateVolumeRenderingThreshold(int thValue); }; #endif