diff --git a/Plugins/org.mitk.gui.qt.diffusionimaging.preprocessing/src/internal/QmitkPreprocessingView.cpp b/Plugins/org.mitk.gui.qt.diffusionimaging.preprocessing/src/internal/QmitkPreprocessingView.cpp index 9f3b391..ae57c25 100644 --- a/Plugins/org.mitk.gui.qt.diffusionimaging.preprocessing/src/internal/QmitkPreprocessingView.cpp +++ b/Plugins/org.mitk.gui.qt.diffusionimaging.preprocessing/src/internal/QmitkPreprocessingView.cpp @@ -1,2024 +1,2024 @@ /*=================================================================== The Medical Imaging Interaction Toolkit (MITK) Copyright (c) German Cancer Research Center. 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. ===================================================================*/ //#define MBILOG_ENABLE_DEBUG #include "QmitkPreprocessingView.h" #include "mitkDiffusionImagingConfigure.h" // qt includes #include // itk includes #include "itkTimeProbe.h" #include "itkB0ImageExtractionImageFilter.h" #include "itkB0ImageExtractionToSeparateImageFilter.h" #include "itkBrainMaskExtractionImageFilter.h" #include "itkCastImageFilter.h" #include "itkVectorContainer.h" #include #include #include #include #include #include // Multishell includes #include // Multishell Functors #include #include #include #include // mitk includes #include "QmitkDataStorageComboBox.h" #include "mitkProgressBar.h" #include "mitkStatusBar.h" #include "mitkNodePredicateDataType.h" #include "mitkProperties.h" #include "mitkVtkResliceInterpolationProperty.h" #include "mitkLookupTable.h" #include "mitkLookupTableProperty.h" #include "mitkTransferFunction.h" #include "mitkTransferFunctionProperty.h" #include "mitkDataNodeObject.h" #include "mitkOdfNormalizationMethodProperty.h" #include "mitkOdfScaleByProperty.h" #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include const std::string QmitkPreprocessingView::VIEW_ID = "org.mitk.views.diffusionpreprocessing"; #define DI_INFO MITK_INFO("DiffusionImaging") typedef float TTensorPixelType; QmitkPreprocessingView::QmitkPreprocessingView() : QmitkAbstractView(), m_Controls(nullptr) { } QmitkPreprocessingView::~QmitkPreprocessingView() { } void QmitkPreprocessingView::CreateQtPartControl(QWidget *parent) { if (!m_Controls) { // create GUI widgets m_Controls = new Ui::QmitkPreprocessingViewControls; m_Controls->setupUi(parent); this->CreateConnections(); m_Controls->m_MeasurementFrameTable->horizontalHeader()->setSectionResizeMode(QHeaderView::Stretch); m_Controls->m_MeasurementFrameTable->verticalHeader()->setSectionResizeMode(QHeaderView::Stretch); m_Controls->m_DirectionMatrixTable->horizontalHeader()->setSectionResizeMode(QHeaderView::Stretch); m_Controls->m_DirectionMatrixTable->verticalHeader()->setSectionResizeMode(QHeaderView::Stretch); } } void QmitkPreprocessingView::SetFocus() { m_Controls->m_MirrorGradientToHalfSphereButton->setFocus(); } void QmitkPreprocessingView::CreateConnections() { if ( m_Controls ) { m_Controls->m_NormalizationMaskBox->SetDataStorage(this->GetDataStorage()); m_Controls->m_SelctedImageComboBox->SetDataStorage(this->GetDataStorage()); m_Controls->m_MergeDwiBox->SetDataStorage(this->GetDataStorage()); m_Controls->m_AlignImageBox->SetDataStorage(this->GetDataStorage()); mitk::TNodePredicateDataType::Pointer isMitkImage = mitk::TNodePredicateDataType::New(); mitk::NodePredicateDataType::Pointer isDti = mitk::NodePredicateDataType::New("TensorImage"); mitk::NodePredicateDataType::Pointer isOdf = mitk::NodePredicateDataType::New("OdfImage"); mitk::NodePredicateOr::Pointer isDiffusionImage = mitk::NodePredicateOr::New(isOdf, isDti); mitk::NodePredicateAnd::Pointer noDiffusionImage = mitk::NodePredicateAnd::New(isMitkImage, mitk::NodePredicateNot::New(isDiffusionImage)); mitk::NodePredicateProperty::Pointer isBinaryPredicate = mitk::NodePredicateProperty::New("binary", mitk::BoolProperty::New(true)); mitk::NodePredicateAnd::Pointer binaryNoDiffusionImage = mitk::NodePredicateAnd::New(noDiffusionImage, isBinaryPredicate); m_Controls->m_NormalizationMaskBox->SetPredicate(binaryNoDiffusionImage); m_Controls->m_SelctedImageComboBox->SetPredicate(isMitkImage); m_Controls->m_MergeDwiBox->SetPredicate(isMitkImage); m_Controls->m_AlignImageBox->SetPredicate(isMitkImage); m_Controls->m_ExtractBrainMask->setVisible(false); m_Controls->m_BrainMaskIterationsBox->setVisible(false); m_Controls->m_ResampleIntFrame->setVisible(false); connect( (QObject*)(m_Controls->m_ButtonAverageGradients), SIGNAL(clicked()), this, SLOT(AverageGradients()) ); connect( (QObject*)(m_Controls->m_ButtonExtractB0), SIGNAL(clicked()), this, SLOT(ExtractB0()) ); connect( (QObject*)(m_Controls->m_ReduceGradientsButton), SIGNAL(clicked()), this, SLOT(DoReduceGradientDirections()) ); connect( (QObject*)(m_Controls->m_ShowGradientsButton), SIGNAL(clicked()), this, SLOT(DoShowGradientDirections()) ); connect( (QObject*)(m_Controls->m_MirrorGradientToHalfSphereButton), SIGNAL(clicked()), this, SLOT(DoHalfSphereGradientDirections()) ); connect( (QObject*)(m_Controls->m_SwapGradientsButton), SIGNAL(clicked()), this, SLOT(DoSwapGradientDimensions()) ); connect( (QObject*)(m_Controls->m_MergeDwisButton), SIGNAL(clicked()), this, SLOT(MergeDwis()) ); connect( (QObject*)(m_Controls->m_ProjectSignalButton), SIGNAL(clicked()), this, SLOT(DoProjectSignal()) ); connect( (QObject*)(m_Controls->m_B_ValueMap_Rounder_SpinBox), SIGNAL(valueChanged(int)), this, SLOT(UpdateDwiBValueMapRounder(int))); connect( (QObject*)(m_Controls->m_CreateLengthCorrectedDwi), SIGNAL(clicked()), this, SLOT(DoLengthCorrection()) ); connect( (QObject*)(m_Controls->m_NormalizeImageValuesButton), SIGNAL(clicked()), this, SLOT(DoDwiNormalization()) ); connect( (QObject*)(m_Controls->m_ResampleImageButton), SIGNAL(clicked()), this, SLOT(DoResampleImage()) ); connect( (QObject*)(m_Controls->m_ResampleTypeBox), SIGNAL(currentIndexChanged(int)), this, SLOT(DoUpdateInterpolationGui(int)) ); connect( (QObject*)(m_Controls->m_CropImageButton), SIGNAL(clicked()), this, SLOT(DoCropImage()) ); connect( (QObject*)(m_Controls->m_RemoveGradientButton), SIGNAL(clicked()), this, SLOT(DoRemoveGradient()) ); connect( (QObject*)(m_Controls->m_ExtractGradientButton), SIGNAL(clicked()), this, SLOT(DoExtractGradient()) ); connect( (QObject*)(m_Controls->m_FlipAxis), SIGNAL(clicked()), this, SLOT(DoFlipAxis()) ); connect( (QObject*)(m_Controls->m_FlipGradientsButton), SIGNAL(clicked()), this, SLOT(DoFlipGradientDirections()) ); connect( (QObject*)(m_Controls->m_ClearRotationButton), SIGNAL(clicked()), this, SLOT(DoClearRotationOfGradients()) ); connect( (QObject*)(m_Controls->m_ModifyHeader), SIGNAL(clicked()), this, SLOT(DoApplyHeader()) ); connect( (QObject*)(m_Controls->m_AlignImageButton), SIGNAL(clicked()), this, SLOT(DoAlignImages()) ); connect( (QObject*)(m_Controls->m_SelctedImageComboBox), SIGNAL(OnSelectionChanged(const mitk::DataNode*)), this, SLOT(OnImageSelectionChanged()) ); m_Controls->m_NormalizationMaskBox->SetZeroEntryText("--"); QFont f("monospace"); f.setStyleHint(QFont::Monospace); m_Controls->m_OriginalGradientsText->setFont(f); m_Controls->m_WorkingGradientsText->setFont(f); } } void QmitkPreprocessingView::DoAlignImages() { mitk::DataNode::Pointer node = m_Controls->m_SelctedImageComboBox->GetSelectedNode(); if (node.IsNull()) { return; } mitk::Image::Pointer image = dynamic_cast(node->GetData()); if ( image == nullptr ) { return; } mitk::DataNode::Pointer target_node = m_Controls->m_AlignImageBox->GetSelectedNode(); if (target_node.IsNull()) { return; } mitk::Image::Pointer target_image = dynamic_cast(target_node->GetData()); if ( target_image == nullptr ) { return; } image->SetOrigin(target_image->GetGeometry()->GetOrigin()); mitk::RenderingManager::GetInstance()->InitializeViews( image->GetTimeGeometry(), mitk::RenderingManager::REQUEST_UPDATE_ALL, true ); mitk::RenderingManager::GetInstance()->RequestUpdateAll(); } void QmitkPreprocessingView::DoFlipAxis() { mitk::DataNode::Pointer node = m_Controls->m_SelctedImageComboBox->GetSelectedNode(); if (node.IsNull()) { return; } mitk::Image::Pointer image = dynamic_cast(node->GetData()); if ( image == nullptr ) { return; } bool isDiffusionImage( PropHelper::IsDiffusionWeightedImage(node) ); if (isDiffusionImage) { ItkDwiType::Pointer itkVectorImagePointer = ItkDwiType::New(); mitk::CastToItkImage(image, itkVectorImagePointer); itk::FixedArray flipAxes; flipAxes[0] = m_Controls->m_FlipX->isChecked(); flipAxes[1] = m_Controls->m_FlipY->isChecked(); flipAxes[2] = m_Controls->m_FlipZ->isChecked(); itk::FlipImageFilter< ItkDwiType >::Pointer flipper = itk::FlipImageFilter< ItkDwiType >::New(); flipper->SetInput(itkVectorImagePointer); flipper->SetFlipAxes(flipAxes); flipper->Update(); auto oldGradients = PropHelper::GetGradientContainer(image); auto newGradients = GradProp::GradientDirectionsContainerType::New(); for (unsigned int i=0; iSize(); i++) { GradProp::GradientDirectionType g = oldGradients->GetElement(i); GradProp::GradientDirectionType newG = g; if (flipAxes[0]) { newG[0] *= -1; } if (flipAxes[1]) { newG[1] *= -1; } if (flipAxes[2]) { newG[2] *= -1; } newGradients->InsertElement(i, newG); } mitk::Image::Pointer newImage = mitk::GrabItkImageMemory( flipper->GetOutput() ); PropHelper::CopyProperties(image, newImage, true); PropHelper::SetGradientContainer(newImage, newGradients); PropHelper::InitializeImage(newImage); newImage->GetGeometry()->SetOrigin(image->GetGeometry()->GetOrigin()); mitk::DataNode::Pointer imageNode = mitk::DataNode::New(); imageNode->SetData( newImage ); QString name = node->GetName().c_str(); imageNode->SetName((name+"_flipped").toStdString().c_str()); GetDataStorage()->Add(imageNode, node); mitk::RenderingManager::GetInstance()->InitializeViews( imageNode->GetData()->GetTimeGeometry(), mitk::RenderingManager::REQUEST_UPDATE_ALL, true ); mitk::RenderingManager::GetInstance()->RequestUpdateAll(); } else if( image->GetPixelType().GetNumberOfComponents() == 1 ) { AccessFixedDimensionByItk(image, TemplatedFlipAxis,3); } else { QMessageBox::warning(nullptr,"Warning", QString("Operation not supported in multi-component images") ); } } template < typename TPixel, unsigned int VImageDimension > void QmitkPreprocessingView::TemplatedFlipAxis(itk::Image* itkImage) { mitk::DataNode::Pointer node = m_Controls->m_SelctedImageComboBox->GetSelectedNode(); if (node.IsNull()) { return; } mitk::Image::Pointer image = dynamic_cast(node->GetData()); if ( image == nullptr ) { return; } itk::FixedArray flipAxes; flipAxes[0] = m_Controls->m_FlipX->isChecked(); flipAxes[1] = m_Controls->m_FlipY->isChecked(); flipAxes[2] = m_Controls->m_FlipZ->isChecked(); typename itk::FlipImageFilter< itk::Image >::Pointer flipper = itk::FlipImageFilter< itk::Image >::New(); flipper->SetInput(itkImage); flipper->SetFlipAxes(flipAxes); flipper->Update(); mitk::Image::Pointer newImage = mitk::GrabItkImageMemory( flipper->GetOutput() ); newImage->GetGeometry()->SetOrigin(image->GetGeometry()->GetOrigin()); mitk::DataNode::Pointer imageNode = mitk::DataNode::New(); imageNode->SetData( newImage ); QString name = node->GetName().c_str(); imageNode->SetName((name+"_flipped").toStdString().c_str()); GetDataStorage()->Add(imageNode, node); mitk::RenderingManager::GetInstance()->InitializeViews( imageNode->GetData()->GetTimeGeometry(), mitk::RenderingManager::REQUEST_UPDATE_ALL, true ); mitk::RenderingManager::GetInstance()->RequestUpdateAll(); } void QmitkPreprocessingView::DoRemoveGradient() { mitk::DataNode::Pointer node = m_Controls->m_SelctedImageComboBox->GetSelectedNode(); if (node.IsNull()) { return; } mitk::Image::Pointer image = dynamic_cast(node->GetData()); if ( image == nullptr ) { return; } bool isDiffusionImage( PropHelper::IsDiffusionWeightedImage(image) ); if ( !isDiffusionImage ) { return; } std::vector< unsigned int > channelsToRemove; channelsToRemove.push_back(m_Controls->m_RemoveGradientBox->value()); ItkDwiType::Pointer itkVectorImagePointer = ItkDwiType::New(); mitk::CastToItkImage(image, itkVectorImagePointer); itk::RemoveDwiChannelFilter< short >::Pointer filter = itk::RemoveDwiChannelFilter< short >::New(); filter->SetInput(itkVectorImagePointer); filter->SetChannelIndices(channelsToRemove); filter->SetDirections(PropHelper::GetGradientContainer(image)); filter->Update(); mitk::Image::Pointer newImage = mitk::GrabItkImageMemory( filter->GetOutput() ); PropHelper::CopyProperties(image, newImage, true); PropHelper::SetGradientContainer(newImage, filter->GetNewDirections()); PropHelper::InitializeImage( newImage ); mitk::DataNode::Pointer imageNode = mitk::DataNode::New(); imageNode->SetData( newImage ); QString name = node->GetName().c_str(); imageNode->SetName((name+"_removedgradients").toStdString().c_str()); GetDataStorage()->Add(imageNode, node); mitk::RenderingManager::GetInstance()->InitializeViews( imageNode->GetData()->GetTimeGeometry(), mitk::RenderingManager::REQUEST_UPDATE_ALL, true ); mitk::RenderingManager::GetInstance()->RequestUpdateAll(); } void QmitkPreprocessingView::DoExtractGradient() { mitk::DataNode::Pointer node = m_Controls->m_SelctedImageComboBox->GetSelectedNode(); if (node.IsNull()) { return; } mitk::Image::Pointer image = dynamic_cast(node->GetData()); if ( image == nullptr ) { return; } bool isDiffusionImage( PropHelper::IsDiffusionWeightedImage(image) ); if ( !isDiffusionImage ) { return; } ItkDwiType::Pointer itkVectorImagePointer = ItkDwiType::New(); mitk::CastToItkImage(image, itkVectorImagePointer); unsigned int channel = m_Controls->m_ExtractGradientBox->value(); itk::ExtractDwiChannelFilter< short >::Pointer filter = itk::ExtractDwiChannelFilter< short >::New(); filter->SetInput( itkVectorImagePointer); filter->SetChannelIndex(channel); filter->Update(); mitk::Image::Pointer newImage = mitk::Image::New(); newImage->InitializeByItk( filter->GetOutput() ); newImage->SetImportChannel( filter->GetOutput()->GetBufferPointer() ); mitk::DataNode::Pointer imageNode = mitk::DataNode::New(); imageNode->SetData( newImage ); QString name = node->GetName().c_str(); imageNode->SetName( (name+"_direction-"+QString::number(channel)).toStdString().c_str() ); GetDataStorage()->Add(imageNode, node); mitk::RenderingManager::GetInstance()->InitializeViews( imageNode->GetData()->GetTimeGeometry(), mitk::RenderingManager::REQUEST_UPDATE_ALL, true); } void QmitkPreprocessingView::DoCropImage() { mitk::DataNode::Pointer node = m_Controls->m_SelctedImageComboBox->GetSelectedNode(); if (node.IsNull()) { return; } mitk::Image::Pointer image = dynamic_cast(node->GetData()); if ( image == nullptr ) { return; } bool isDiffusionImage( PropHelper::IsDiffusionWeightedImage(image) ); if ( isDiffusionImage ) { ItkDwiType::Pointer itkVectorImagePointer = ItkDwiType::New(); mitk::CastToItkImage(image, itkVectorImagePointer); ItkDwiType::SizeType lower; ItkDwiType::SizeType upper; lower[0] = m_Controls->m_XstartBox->value(); lower[1] = m_Controls->m_YstartBox->value(); lower[2] = m_Controls->m_ZstartBox->value(); upper[0] = m_Controls->m_XendBox->value(); upper[1] = m_Controls->m_YendBox->value(); upper[2] = m_Controls->m_ZendBox->value(); itk::CropImageFilter< ItkDwiType, ItkDwiType >::Pointer cropper = itk::CropImageFilter< ItkDwiType, ItkDwiType >::New(); cropper->SetLowerBoundaryCropSize(lower); cropper->SetUpperBoundaryCropSize(upper); cropper->SetInput( itkVectorImagePointer ); cropper->Update(); ItkDwiType::Pointer itkOutImage = cropper->GetOutput(); ItkDwiType::DirectionType dir = itkOutImage->GetDirection(); itk::Point origin = itkOutImage->GetOrigin(); itk::Point t; t[0] = lower[0]*itkOutImage->GetSpacing()[0]; t[1] = lower[1]*itkOutImage->GetSpacing()[1]; t[2] = lower[2]*itkOutImage->GetSpacing()[2]; t= dir*t; origin[0] += t[0]; origin[1] += t[1]; origin[2] += t[2]; itkOutImage->SetOrigin(origin); mitk::Image::Pointer newimage = mitk::GrabItkImageMemory( itkOutImage ); PropHelper::CopyProperties(image, newimage, false); PropHelper::InitializeImage( newimage ); mitk::DataNode::Pointer imageNode = mitk::DataNode::New(); imageNode->SetData( newimage ); QString name = node->GetName().c_str(); imageNode->SetName((name+"_cropped").toStdString().c_str()); GetDataStorage()->Add(imageNode, node); mitk::RenderingManager::GetInstance()->InitializeViews( imageNode->GetData()->GetTimeGeometry(), mitk::RenderingManager::REQUEST_UPDATE_ALL, true ); mitk::RenderingManager::GetInstance()->RequestUpdateAll(); mitk::RenderingManager::GetInstance()->InitializeViews( imageNode->GetData()->GetTimeGeometry(), mitk::RenderingManager::REQUEST_UPDATE_ALL, true ); mitk::RenderingManager::GetInstance()->RequestUpdateAll(); } else if( image->GetPixelType().GetNumberOfComponents() ) { AccessFixedDimensionByItk(image, TemplatedCropImage,3); } else { QMessageBox::warning(nullptr,"Warning", QString("Operation not supported in multi-component images") ); } } template < typename TPixel, unsigned int VImageDimension > void QmitkPreprocessingView::TemplatedCropImage( itk::Image* itkImage) { mitk::DataNode::Pointer node = m_Controls->m_SelctedImageComboBox->GetSelectedNode(); if (node.IsNull()) { return; } ItkDwiType::SizeType lower; ItkDwiType::SizeType upper; lower[0] = m_Controls->m_XstartBox->value(); lower[1] = m_Controls->m_YstartBox->value(); lower[2] = m_Controls->m_ZstartBox->value(); upper[0] = m_Controls->m_XendBox->value(); upper[1] = m_Controls->m_YendBox->value(); upper[2] = m_Controls->m_ZendBox->value(); typedef itk::Image ImageType; typename itk::CropImageFilter< ImageType, ImageType >::Pointer cropper = itk::CropImageFilter< ImageType, ImageType >::New(); cropper->SetLowerBoundaryCropSize(lower); cropper->SetUpperBoundaryCropSize(upper); cropper->SetInput(itkImage); cropper->Update(); typename ImageType::Pointer itkOutImage = cropper->GetOutput(); typename ImageType::DirectionType dir = itkOutImage->GetDirection(); itk::Point origin = itkOutImage->GetOrigin(); itk::Point t; t[0] = lower[0]*itkOutImage->GetSpacing()[0]; t[1] = lower[1]*itkOutImage->GetSpacing()[1]; t[2] = lower[2]*itkOutImage->GetSpacing()[2]; t= dir*t; origin[0] += t[0]; origin[1] += t[1]; origin[2] += t[2]; itkOutImage->SetOrigin(origin); mitk::Image::Pointer image = mitk::Image::New(); image->InitializeByItk( itkOutImage.GetPointer() ); image->SetVolume( itkOutImage->GetBufferPointer() ); mitk::DataNode::Pointer imageNode = mitk::DataNode::New(); imageNode->SetData( image ); QString name = node->GetName().c_str(); imageNode->SetName((name+"_cropped").toStdString().c_str()); GetDataStorage()->Add(imageNode, node); mitk::RenderingManager::GetInstance()->InitializeViews( imageNode->GetData()->GetTimeGeometry(), mitk::RenderingManager::REQUEST_UPDATE_ALL, true ); mitk::RenderingManager::GetInstance()->RequestUpdateAll(); } void QmitkPreprocessingView::DoUpdateInterpolationGui(int i) { mitk::DataNode::Pointer node = m_Controls->m_SelctedImageComboBox->GetSelectedNode(); if (node.IsNull()) { return; } mitk::Image::Pointer image = dynamic_cast(node->GetData()); if ( image == nullptr ) { return; } switch (i) { case 0: { m_Controls->m_ResampleIntFrame->setVisible(false); m_Controls->m_ResampleDoubleFrame->setVisible(true); break; } case 1: { m_Controls->m_ResampleIntFrame->setVisible(false); m_Controls->m_ResampleDoubleFrame->setVisible(true); mitk::BaseGeometry* geom = image->GetGeometry(); m_Controls->m_ResampleDoubleX->setValue(geom->GetSpacing()[0]); m_Controls->m_ResampleDoubleY->setValue(geom->GetSpacing()[1]); m_Controls->m_ResampleDoubleZ->setValue(geom->GetSpacing()[2]); break; } case 2: { m_Controls->m_ResampleIntFrame->setVisible(true); m_Controls->m_ResampleDoubleFrame->setVisible(false); mitk::BaseGeometry* geom = image->GetGeometry(); m_Controls->m_ResampleIntX->setValue(geom->GetExtent(0)); m_Controls->m_ResampleIntY->setValue(geom->GetExtent(1)); m_Controls->m_ResampleIntZ->setValue(geom->GetExtent(2)); break; } default: { m_Controls->m_ResampleIntFrame->setVisible(false); m_Controls->m_ResampleDoubleFrame->setVisible(true); } } } void QmitkPreprocessingView::DoExtractBrainMask() { } void QmitkPreprocessingView::DoResampleImage() { mitk::DataNode::Pointer node = m_Controls->m_SelctedImageComboBox->GetSelectedNode(); if (node.IsNull()) { return; } mitk::Image::Pointer image = dynamic_cast(node->GetData()); if ( image == nullptr ) { return; } bool isDiffusionImage( PropHelper::IsDiffusionWeightedImage(image) ); if ( isDiffusionImage ) { ItkDwiType::Pointer itkVectorImagePointer = ItkDwiType::New(); mitk::CastToItkImage(image, itkVectorImagePointer); typedef itk::ResampleDwiImageFilter< short > ResampleFilter; ResampleFilter::Pointer resampler = ResampleFilter::New(); resampler->SetInput( itkVectorImagePointer ); switch (m_Controls->m_ResampleTypeBox->currentIndex()) { case 0: { itk::Vector< double, 3 > samplingFactor; samplingFactor[0] = m_Controls->m_ResampleDoubleX->value(); samplingFactor[1] = m_Controls->m_ResampleDoubleY->value(); samplingFactor[2] = m_Controls->m_ResampleDoubleZ->value(); resampler->SetSamplingFactor(samplingFactor); break; } case 1: { itk::Vector< double, 3 > newSpacing; newSpacing[0] = m_Controls->m_ResampleDoubleX->value(); newSpacing[1] = m_Controls->m_ResampleDoubleY->value(); newSpacing[2] = m_Controls->m_ResampleDoubleZ->value(); resampler->SetNewSpacing(newSpacing); break; } case 2: { itk::ImageRegion<3> newRegion; newRegion.SetSize(0, m_Controls->m_ResampleIntX->value()); newRegion.SetSize(1, m_Controls->m_ResampleIntY->value()); newRegion.SetSize(2, m_Controls->m_ResampleIntZ->value()); resampler->SetNewImageSize(newRegion); break; } default: { MITK_WARN << "Unknown resampling parameters!"; return; } } QString outAdd; switch (m_Controls->m_InterpolatorBox->currentIndex()) { case 0: { resampler->SetInterpolation(ResampleFilter::Interpolate_NearestNeighbour); outAdd = "NearestNeighbour"; break; } case 1: { resampler->SetInterpolation(ResampleFilter::Interpolate_Linear); outAdd = "Linear"; break; } case 2: { resampler->SetInterpolation(ResampleFilter::Interpolate_BSpline); outAdd = "BSpline"; break; } case 3: { resampler->SetInterpolation(ResampleFilter::Interpolate_WindowedSinc); outAdd = "WindowedSinc"; break; } default: { resampler->SetInterpolation(ResampleFilter::Interpolate_NearestNeighbour); outAdd = "NearestNeighbour"; } } resampler->Update(); mitk::Image::Pointer newImage = mitk::GrabItkImageMemory( resampler->GetOutput() ); PropHelper::CopyProperties(image, newImage, false); PropHelper::InitializeImage( newImage ); mitk::DataNode::Pointer imageNode = mitk::DataNode::New(); imageNode->SetData( newImage ); QString name = node->GetName().c_str(); imageNode->SetName((name+"_resampled_"+outAdd).toStdString().c_str()); - imageNode->SetVisibility(false); + imageNode->SetVisibility(true); GetDataStorage()->Add(imageNode, node); } else if( image->GetPixelType().GetNumberOfComponents() ) { AccessFixedDimensionByItk(image, TemplatedResampleImage,3); } else { QMessageBox::warning(nullptr,"Warning", QString("Operation not supported in multi-component images") ); } } template < typename TPixel, unsigned int VImageDimension > void QmitkPreprocessingView::TemplatedResampleImage( itk::Image* itkImage) { mitk::DataNode::Pointer node = m_Controls->m_SelctedImageComboBox->GetSelectedNode(); if (node.IsNull()) { return; } itk::Vector< double, 3 > newSpacing; itk::ImageRegion<3> newRegion; switch (m_Controls->m_ResampleTypeBox->currentIndex()) { case 0: { itk::Vector< double, 3 > sampling; sampling[0] = m_Controls->m_ResampleDoubleX->value(); sampling[1] = m_Controls->m_ResampleDoubleY->value(); sampling[2] = m_Controls->m_ResampleDoubleZ->value(); newSpacing = itkImage->GetSpacing(); newSpacing[0] /= sampling[0]; newSpacing[1] /= sampling[1]; newSpacing[2] /= sampling[2]; newRegion = itkImage->GetLargestPossibleRegion(); newRegion.SetSize(0, newRegion.GetSize(0)*sampling[0]); newRegion.SetSize(1, newRegion.GetSize(1)*sampling[1]); newRegion.SetSize(2, newRegion.GetSize(2)*sampling[2]); break; } case 1: { newSpacing[0] = m_Controls->m_ResampleDoubleX->value(); newSpacing[1] = m_Controls->m_ResampleDoubleY->value(); newSpacing[2] = m_Controls->m_ResampleDoubleZ->value(); itk::Vector< double, 3 > oldSpacing = itkImage->GetSpacing(); itk::Vector< double, 3 > sampling; sampling[0] = oldSpacing[0]/newSpacing[0]; sampling[1] = oldSpacing[1]/newSpacing[1]; sampling[2] = oldSpacing[2]/newSpacing[2]; newRegion = itkImage->GetLargestPossibleRegion(); newRegion.SetSize(0, newRegion.GetSize(0)*sampling[0]); newRegion.SetSize(1, newRegion.GetSize(1)*sampling[1]); newRegion.SetSize(2, newRegion.GetSize(2)*sampling[2]); break; } case 2: { newRegion.SetSize(0, m_Controls->m_ResampleIntX->value()); newRegion.SetSize(1, m_Controls->m_ResampleIntY->value()); newRegion.SetSize(2, m_Controls->m_ResampleIntZ->value()); itk::ImageRegion<3> oldRegion = itkImage->GetLargestPossibleRegion(); itk::Vector< double, 3 > sampling; sampling[0] = (double)newRegion.GetSize(0)/oldRegion.GetSize(0); sampling[1] = (double)newRegion.GetSize(1)/oldRegion.GetSize(1); sampling[2] = (double)newRegion.GetSize(2)/oldRegion.GetSize(2); newSpacing = itkImage->GetSpacing(); newSpacing[0] /= sampling[0]; newSpacing[1] /= sampling[1]; newSpacing[2] /= sampling[2]; break; } default: { MITK_WARN << "Unknown resampling parameters!"; return; } } itk::Point origin = itkImage->GetOrigin(); origin[0] -= itkImage->GetSpacing()[0]/2; origin[1] -= itkImage->GetSpacing()[1]/2; origin[2] -= itkImage->GetSpacing()[2]/2; origin[0] += newSpacing[0]/2; origin[1] += newSpacing[1]/2; origin[2] += newSpacing[2]/2; typedef itk::Image ImageType; typename ImageType::Pointer outImage = ImageType::New(); outImage->SetSpacing( newSpacing ); outImage->SetOrigin( origin ); outImage->SetDirection( itkImage->GetDirection() ); outImage->SetLargestPossibleRegion( newRegion ); outImage->SetBufferedRegion( newRegion ); outImage->SetRequestedRegion( newRegion ); outImage->Allocate(); typedef itk::ResampleImageFilter ResampleFilter; typename ResampleFilter::Pointer resampler = ResampleFilter::New(); resampler->SetInput(itkImage); resampler->SetOutputParametersFromImage(outImage); QString outAdd; switch (m_Controls->m_InterpolatorBox->currentIndex()) { case 0: { typename itk::NearestNeighborInterpolateImageFunction::Pointer interp = itk::NearestNeighborInterpolateImageFunction::New(); resampler->SetInterpolator(interp); outAdd = "NearestNeighbour"; break; } case 1: { typename itk::LinearInterpolateImageFunction::Pointer interp = itk::LinearInterpolateImageFunction::New(); resampler->SetInterpolator(interp); outAdd = "Linear"; break; } case 2: { typename itk::BSplineInterpolateImageFunction::Pointer interp = itk::BSplineInterpolateImageFunction::New(); resampler->SetInterpolator(interp); outAdd = "BSpline"; break; } case 3: { typename itk::WindowedSincInterpolateImageFunction::Pointer interp = itk::WindowedSincInterpolateImageFunction::New(); resampler->SetInterpolator(interp); outAdd = "WindowedSinc"; break; } default: { typename itk::NearestNeighborInterpolateImageFunction::Pointer interp = itk::NearestNeighborInterpolateImageFunction::New(); resampler->SetInterpolator(interp); outAdd = "NearestNeighbour"; } } resampler->Update(); mitk::Image::Pointer image = mitk::Image::New(); image->InitializeByItk( resampler->GetOutput() ); image->SetVolume( resampler->GetOutput()->GetBufferPointer() ); mitk::DataNode::Pointer imageNode = mitk::DataNode::New(); imageNode->SetData( image ); QString name = node->GetName().c_str(); imageNode->SetName((name+"_resampled_"+outAdd).toStdString().c_str()); GetDataStorage()->Add(imageNode, node); } void QmitkPreprocessingView::DoApplyHeader() { mitk::DataNode::Pointer node = m_Controls->m_SelctedImageComboBox->GetSelectedNode(); if (node.IsNull()) { return; } mitk::Image::Pointer image = dynamic_cast(node->GetData()); if ( image == nullptr ) { return; } bool isDiffusionImage( PropHelper::IsDiffusionWeightedImage(image) ); bool isDti = false; bool isOdf = false; bool isPeak = false; if (!isDiffusionImage) { if ( dynamic_cast(node->GetData()) ) isDti = true; else if ( dynamic_cast(node->GetData()) ) isOdf = true; else if ( dynamic_cast(node->GetData()) ) isPeak = true; } mitk::Image::Pointer newImage = image->Clone(); mitk::Vector3D spacing; spacing[0] = m_Controls->m_HeaderSpacingX->value(); spacing[1] = m_Controls->m_HeaderSpacingY->value(); spacing[2] = m_Controls->m_HeaderSpacingZ->value(); newImage->GetGeometry()->SetSpacing( spacing ); mitk::Point3D origin; origin[0] = m_Controls->m_HeaderOriginX->value(); origin[1] = m_Controls->m_HeaderOriginY->value(); origin[2] = m_Controls->m_HeaderOriginZ->value(); newImage->GetGeometry()->SetOrigin(origin); vtkSmartPointer< vtkMatrix4x4 > matrix = vtkSmartPointer< vtkMatrix4x4 >::New(); matrix->SetElement(0,3,newImage->GetGeometry()->GetOrigin()[0]); matrix->SetElement(1,3,newImage->GetGeometry()->GetOrigin()[1]); matrix->SetElement(2,3,newImage->GetGeometry()->GetOrigin()[2]); for (int r=0; r<3; r++) { for (int c=0; c<3; c++) { QTableWidgetItem* item = m_Controls->m_DirectionMatrixTable->item(r,c); if (!item) continue; matrix->SetElement(r,c,item->text().toDouble()); } } newImage->GetGeometry()->SetIndexToWorldTransformByVtkMatrixWithoutChangingSpacing(matrix); if ( isDiffusionImage ) { vnl_matrix_fixed< double, 3, 3 > mf; for (int r=0; r<3; r++) { for (int c=0; c<3; c++) { QTableWidgetItem* item = m_Controls->m_MeasurementFrameTable->item(r,c); if (!item) continue; mf[r][c] = item->text().toDouble(); } } PropHelper::SetMeasurementFrame(newImage, mf); PropHelper::InitializeImage( newImage ); } mitk::DataNode::Pointer imageNode = mitk::DataNode::New(); if (isOdf) { mitk::OdfImage::ItkOdfImageType::Pointer itk_img = mitk::OdfImage::ItkOdfImageType::New(); mitk::CastToItkImage(newImage, itk_img); mitk::Image::Pointer odfImage = dynamic_cast(mitk::OdfImage::New().GetPointer()); mitk::CastToMitkImage(itk_img, odfImage); odfImage->SetVolume(itk_img->GetBufferPointer()); imageNode->SetData( odfImage ); } else if (isDti) { mitk::TensorImage::ItkTensorImageType::Pointer itk_img = mitk::ImageToItkImage(newImage); mitk::Image::Pointer tensorImage = dynamic_cast(mitk::TensorImage::New().GetPointer()); mitk::CastToMitkImage(itk_img, tensorImage); tensorImage->SetVolume(itk_img->GetBufferPointer()); imageNode->SetData( tensorImage ); } else if (isPeak) { mitk::PeakImage::ItkPeakImageType::Pointer itk_img = mitk::ImageToItkImage(newImage); mitk::Image::Pointer peakImage = dynamic_cast(mitk::PeakImage::New().GetPointer()); mitk::CastToMitkImage(itk_img, peakImage); peakImage->SetVolume(itk_img->GetBufferPointer()); imageNode->SetData( peakImage ); } else imageNode->SetData( newImage ); QString name = node->GetName().c_str(); imageNode->SetName((name+"_newheader").toStdString().c_str()); GetDataStorage()->Add(imageNode, node); mitk::RenderingManager::GetInstance()->InitializeViews( imageNode->GetData()->GetTimeGeometry(), mitk::RenderingManager::REQUEST_UPDATE_ALL, true ); mitk::RenderingManager::GetInstance()->RequestUpdateAll(); } void QmitkPreprocessingView::DoProjectSignal() { switch(m_Controls->m_ProjectionMethodBox->currentIndex()) { case 0: DoADCAverage(); break; case 1: DoAKCFit(); break; case 2: DoBiExpFit(); break; default: DoADCAverage(); } } void QmitkPreprocessingView::DoDwiNormalization() { mitk::DataNode::Pointer node = m_Controls->m_SelctedImageComboBox->GetSelectedNode(); if (node.IsNull()) { return; } mitk::Image::Pointer image = dynamic_cast(node->GetData()); if ( image == nullptr ) { return; } bool isDiffusionImage( PropHelper::IsDiffusionWeightedImage(image) ); if ( ! isDiffusionImage ) { return; } auto gradientContainer = PropHelper::GetGradientContainer(image); int b0Index = -1; for (unsigned int i=0; isize(); i++) { GradientDirectionType g = gradientContainer->GetElement(i); if (g.magnitude()<0.001) { b0Index = i; break; } } if (b0Index==-1) { return; } typedef itk::DwiNormilzationFilter FilterType; ItkDwiType::Pointer itkVectorImagePointer = ItkDwiType::New(); mitk::CastToItkImage(image, itkVectorImagePointer); FilterType::Pointer filter = FilterType::New(); filter->SetInput( itkVectorImagePointer ); filter->SetGradientDirections(PropHelper::GetGradientContainer(image)); filter->SetNewMean(m_Controls->m_NewMean->value()); filter->SetNewStdev(m_Controls->m_NewStdev->value()); UcharImageType::Pointer itkImage = nullptr; if (m_Controls->m_NormalizationMaskBox->GetSelectedNode().IsNotNull()) { itkImage = UcharImageType::New(); if ( dynamic_cast(m_Controls->m_NormalizationMaskBox->GetSelectedNode()->GetData()) != nullptr ) { mitk::CastToItkImage( dynamic_cast(m_Controls->m_NormalizationMaskBox->GetSelectedNode()->GetData()), itkImage ); } filter->SetMaskImage(itkImage); } filter->Update(); mitk::Image::Pointer newImage = mitk::GrabItkImageMemory( filter->GetOutput() ); PropHelper::CopyProperties(image, newImage, false); PropHelper::InitializeImage( newImage ); mitk::DataNode::Pointer imageNode = mitk::DataNode::New(); imageNode->SetData( newImage ); QString name = node->GetName().c_str(); imageNode->SetName((name+"_normalized").toStdString().c_str()); GetDataStorage()->Add(imageNode, node); } void QmitkPreprocessingView::DoLengthCorrection() { mitk::DataNode::Pointer node = m_Controls->m_SelctedImageComboBox->GetSelectedNode(); if (node.IsNull()) return; mitk::Image::Pointer image = dynamic_cast(node->GetData()); if (image == nullptr ) return; if (!PropHelper::IsDiffusionWeightedImage(image)) return; typedef itk::DwiGradientLengthCorrectionFilter FilterType; ItkDwiType::Pointer itkVectorImagePointer = PropHelper::GetItkVectorImage(image); FilterType::Pointer filter = FilterType::New(); filter->SetRoundingValue( m_Controls->m_B_ValueMap_Rounder_SpinBox->value()); filter->SetReferenceBValue(PropHelper::GetReferenceBValue(image)); filter->SetReferenceGradientDirectionContainer(PropHelper::GetGradientContainer(image)); filter->Update(); mitk::Image::Pointer newImage = mitk::Image::New(); newImage->InitializeByItk( itkVectorImagePointer.GetPointer() ); newImage->SetImportVolume( itkVectorImagePointer->GetBufferPointer(), 0, 0, mitk::Image::CopyMemory); itkVectorImagePointer->GetPixelContainer()->ContainerManageMemoryOff(); PropHelper::CopyProperties(image, newImage, true); PropHelper::SetGradientContainer(newImage, filter->GetOutputGradientDirectionContainer()); PropHelper::SetReferenceBValue(newImage, filter->GetNewBValue()); PropHelper::InitializeImage( newImage ); mitk::DataNode::Pointer imageNode = mitk::DataNode::New(); imageNode->SetData( newImage ); QString name = node->GetName().c_str(); imageNode->SetName((name+"_rounded").toStdString().c_str()); GetDataStorage()->Add(imageNode, node); } void QmitkPreprocessingView::UpdateDwiBValueMapRounder(int i) { mitk::DataNode::Pointer node = m_Controls->m_SelctedImageComboBox->GetSelectedNode(); if (node.IsNull()) { return; } bool isDiffusionImage( PropHelper::IsDiffusionWeightedImage(node) ); if ( ! isDiffusionImage ) { return; } UpdateBValueTableWidget(i); UpdateGradientDetails(); } void QmitkPreprocessingView:: CallMultishellToSingleShellFilter( itk::DWIVoxelFunctor * functor, mitk::Image::Pointer image, QString imageName, mitk::DataNode* parent ) { typedef itk::RadialMultishellToSingleshellImageFilter FilterType; // filter input parameter const mitk::BValueMapProperty::BValueMap& originalShellMap = PropHelper::GetBValueMap(image); ItkDwiType::Pointer itkVectorImagePointer = PropHelper::GetItkVectorImage(image); ItkDwiType* vectorImage = itkVectorImagePointer.GetPointer(); const GradProp::GradientDirectionsContainerType::ConstPointer gradientContainer = PropHelper::GetGradientContainer(image); const unsigned int& bValue = PropHelper::GetReferenceBValue(image); mitk::DataNode::Pointer imageNode = 0; // filter call FilterType::Pointer filter = FilterType::New(); filter->SetInput(vectorImage); filter->SetOriginalGradientDirections(gradientContainer); filter->SetOriginalBValueMap(originalShellMap); filter->SetOriginalBValue(bValue); filter->SetFunctor(functor); filter->Update(); // create new DWI image mitk::Image::Pointer outImage = mitk::GrabItkImageMemory( filter->GetOutput() ); PropHelper::CopyProperties(image, outImage, true); PropHelper::SetGradientContainer(outImage, filter->GetTargetGradientDirections()); PropHelper::SetReferenceBValue(outImage, m_Controls->m_targetBValueSpinBox->value()); PropHelper::InitializeImage( outImage ); imageNode = mitk::DataNode::New(); imageNode->SetData( outImage ); imageNode->SetName(imageName.toStdString().c_str()); GetDataStorage()->Add(imageNode, parent); } void QmitkPreprocessingView::DoBiExpFit() { mitk::DataNode::Pointer node = m_Controls->m_SelctedImageComboBox->GetSelectedNode(); if (node.IsNull()) { return; } mitk::Image::Pointer image = dynamic_cast(node->GetData()); if ( image == nullptr ) { return; } bool isDiffusionImage( PropHelper::IsDiffusionWeightedImage(image) ); if ( ! isDiffusionImage ) { return; } itk::BiExpFitFunctor::Pointer functor = itk::BiExpFitFunctor::New(); QString name(node->GetName().c_str()); const mitk::BValueMapProperty::BValueMap& originalShellMap = PropHelper::GetBValueMap(image); mitk::BValueMapProperty::BValueMap::const_iterator it = originalShellMap.begin(); ++it;/* skip b=0*/ unsigned int s = 0; /*shell index */ vnl_vector bValueList(originalShellMap.size()-1); while( it != originalShellMap.end() ) { bValueList.put(s++,(it++)->first); } const double targetBValue = m_Controls->m_targetBValueSpinBox->value(); functor->setListOfBValues(bValueList); functor->setTargetBValue(targetBValue); CallMultishellToSingleShellFilter(functor,image,name + "_BiExp", node); } void QmitkPreprocessingView::DoAKCFit() { mitk::DataNode::Pointer node = m_Controls->m_SelctedImageComboBox->GetSelectedNode(); if (node.IsNull()) { return; } mitk::Image::Pointer image = dynamic_cast(node->GetData()); if ( image == nullptr ) { return; } bool isDiffusionImage( PropHelper::IsDiffusionWeightedImage(image) ); if ( ! isDiffusionImage ) { return; } itk::KurtosisFitFunctor::Pointer functor = itk::KurtosisFitFunctor::New(); QString name(node->GetName().c_str()); const mitk::BValueMapProperty::BValueMap& originalShellMap = PropHelper::GetBValueMap(image); mitk::BValueMapProperty::BValueMap::const_iterator it = originalShellMap.begin(); ++it;/* skip b=0*/ unsigned int s = 0; /*shell index */ vnl_vector bValueList(originalShellMap.size()-1); while(it != originalShellMap.end()) bValueList.put(s++,(it++)->first); const double targetBValue = m_Controls->m_targetBValueSpinBox->value(); functor->setListOfBValues(bValueList); functor->setTargetBValue(targetBValue); CallMultishellToSingleShellFilter(functor,image,name + "_AKC", node); } void QmitkPreprocessingView::DoADCFit() { // later } void QmitkPreprocessingView::DoADCAverage() { mitk::DataNode::Pointer node = m_Controls->m_SelctedImageComboBox->GetSelectedNode(); if (node.IsNull()) { return; } mitk::Image::Pointer image = dynamic_cast(node->GetData()); if ( image == nullptr ) { return; } bool isDiffusionImage( PropHelper::IsDiffusionWeightedImage(image) ); if ( ! isDiffusionImage ) return; itk::ADCAverageFunctor::Pointer functor = itk::ADCAverageFunctor::New(); QString name(node->GetName().c_str()); const mitk::BValueMapProperty::BValueMap &originalShellMap = PropHelper::GetBValueMap(image); mitk::BValueMapProperty::BValueMap::const_iterator it = originalShellMap.begin(); ++it;/* skip b=0*/ unsigned int s = 0; /*shell index */ vnl_vector bValueList(originalShellMap.size()-1); while(it != originalShellMap.end()) bValueList.put(s++,(it++)->first); const double targetBValue = m_Controls->m_targetBValueSpinBox->value(); functor->setListOfBValues(bValueList); functor->setTargetBValue(targetBValue); CallMultishellToSingleShellFilter(functor,image,name + "_ADC", node); } void QmitkPreprocessingView::CleanBValueTableWidget() { m_Controls->m_B_ValueMap_TableWidget->clear(); m_Controls->m_B_ValueMap_TableWidget->setRowCount(1); QStringList headerList; headerList << "b-Value" << "Number of gradients"; m_Controls->m_B_ValueMap_TableWidget->setHorizontalHeaderLabels(headerList); m_Controls->m_B_ValueMap_TableWidget->setItem(0,0,new QTableWidgetItem("-")); m_Controls->m_B_ValueMap_TableWidget->setItem(0,1,new QTableWidgetItem("-")); } void QmitkPreprocessingView::UpdateGradientDetails() { mitk::DataNode::Pointer node = m_Controls->m_SelctedImageComboBox->GetSelectedNode(); mitk::Image::Pointer image = dynamic_cast(node->GetData()); if ( image == nullptr ) { return; } bool isDiffusionImage(false); isDiffusionImage = PropHelper::IsDiffusionWeightedImage(image); if ( ! isDiffusionImage ) { m_Controls->m_WorkingGradientsText->clear(); m_Controls->m_OriginalGradientsText->clear(); return; } auto gradientContainer = PropHelper::GetGradientContainer(image); QString text = ""; for (unsigned int j=0; jSize(); j++) { auto g = gradientContainer->at(j); g = g.normalize(); if (g[0]>=0) text += " "; text += QString::number(g[0]); if (jSize()-1) text += " "; else text += "\n"; } for (unsigned int j=0; jSize(); j++) { auto g = gradientContainer->at(j); g = g.normalize(); if (g[1]>=0) text += " "; text += QString::number(g[1]); if (jSize()-1) text += " "; else text += "\n"; } for (unsigned int j=0; jSize(); j++) { auto g = gradientContainer->at(j); g = g.normalize(); if (g[2]>=0) text += " "; text += QString::number(g[2]); if (jSize()-1) text += " "; else text += "\n"; } m_Controls->m_WorkingGradientsText->setPlainText(text); gradientContainer = PropHelper::GetOriginalGradientContainer(image); text = ""; for (unsigned int j=0; jSize(); j++) { auto g = gradientContainer->at(j); g = g.normalize(); if (g[0]>=0) text += " "; text += QString::number(g[0]); if (jSize()-1) text += " "; else text += "\n"; } for (unsigned int j=0; jSize(); j++) { auto g = gradientContainer->at(j); g = g.normalize(); if (g[1]>=0) text += " "; text += QString::number(g[1]); if (jSize()-1) text += " "; else text += "\n"; } for (unsigned int j=0; jSize(); j++) { auto g = gradientContainer->at(j); g = g.normalize(); if (g[2]>=0) text += " "; text += QString::number(g[2]); if (jSize()-1) text += " "; else text += "\n"; } m_Controls->m_OriginalGradientsText->setPlainText(text); } void QmitkPreprocessingView::UpdateBValueTableWidget(int) { mitk::DataNode::Pointer node = m_Controls->m_SelctedImageComboBox->GetSelectedNode(); if (node.IsNull()) { CleanBValueTableWidget(); return; } mitk::Image::Pointer image = dynamic_cast(node->GetData()); if ( image == nullptr ) { return; } bool isDiffusionImage(false); isDiffusionImage = PropHelper::IsDiffusionWeightedImage(image); if ( ! isDiffusionImage ) { CleanBValueTableWidget(); } else { typedef mitk::BValueMapProperty::BValueMap BValueMap; typedef mitk::BValueMapProperty::BValueMap::iterator BValueMapIterator; BValueMapIterator it; BValueMap roundedBValueMap = PropHelper::GetBValueMap(image); m_Controls->m_B_ValueMap_TableWidget->clear(); m_Controls->m_B_ValueMap_TableWidget->setRowCount(roundedBValueMap.size() ); QStringList headerList; headerList << "b-Value" << "Number of gradients"; m_Controls->m_B_ValueMap_TableWidget->setHorizontalHeaderLabels(headerList); int i = 0 ; for(it = roundedBValueMap.begin() ;it != roundedBValueMap.end(); it++) { m_Controls->m_B_ValueMap_TableWidget->setItem(i,0,new QTableWidgetItem(QString::number(it->first))); QTableWidgetItem* item = m_Controls->m_B_ValueMap_TableWidget->item(i,0); item->setFlags(item->flags() & ~Qt::ItemIsEditable); m_Controls->m_B_ValueMap_TableWidget->setItem(i,1,new QTableWidgetItem(QString::number(it->second.size()))); i++; } } } void QmitkPreprocessingView::OnSelectionChanged(berry::IWorkbenchPart::Pointer , const QList& nodes) { (void) nodes; this->OnImageSelectionChanged(); } void QmitkPreprocessingView::OnImageSelectionChanged() { for (int r=0; r<3; r++) for (int c=0; c<3; c++) { { QTableWidgetItem* item = m_Controls->m_MeasurementFrameTable->item( r, c ); delete item; item = new QTableWidgetItem(); m_Controls->m_MeasurementFrameTable->setItem( r, c, item ); } { QTableWidgetItem* item = m_Controls->m_DirectionMatrixTable->item( r, c ); delete item; item = new QTableWidgetItem(); m_Controls->m_DirectionMatrixTable->setItem( r, c, item ); } } bool foundImageVolume = true; mitk::DataNode::Pointer node = m_Controls->m_SelctedImageComboBox->GetSelectedNode(); if (node.IsNull()) { return; } bool foundDwiVolume( PropHelper::IsDiffusionWeightedImage( node ) ); mitk::Image::Pointer image = dynamic_cast(node->GetData()); if ( image == nullptr ) { return; } bool multiComponentVolume = (image->GetPixelType().GetNumberOfComponents() > 1); bool threeDplusTVolume = (image->GetTimeSteps() > 1); m_Controls->m_ButtonAverageGradients->setEnabled(foundDwiVolume); m_Controls->m_ButtonExtractB0->setEnabled(foundDwiVolume); m_Controls->m_CheckExtractAll->setEnabled(foundDwiVolume); m_Controls->m_MeasurementFrameTable->setEnabled(foundDwiVolume); m_Controls->m_ReduceGradientsButton->setEnabled(foundDwiVolume); m_Controls->m_ShowGradientsButton->setEnabled(foundDwiVolume); m_Controls->m_MirrorGradientToHalfSphereButton->setEnabled(foundDwiVolume); m_Controls->m_SwapGradientsButton->setEnabled(foundDwiVolume); m_Controls->m_MergeDwisButton->setEnabled(foundDwiVolume); m_Controls->m_B_ValueMap_Rounder_SpinBox->setEnabled(foundDwiVolume); m_Controls->m_ProjectSignalButton->setEnabled(foundDwiVolume); m_Controls->m_CreateLengthCorrectedDwi->setEnabled(foundDwiVolume); m_Controls->m_targetBValueSpinBox->setEnabled(foundDwiVolume); m_Controls->m_NormalizeImageValuesButton->setEnabled(foundDwiVolume); m_Controls->m_RemoveGradientButton->setEnabled(foundDwiVolume); m_Controls->m_ExtractGradientButton->setEnabled(foundDwiVolume); m_Controls->m_FlipGradientsButton->setEnabled(foundDwiVolume); m_Controls->m_ClearRotationButton->setEnabled(foundDwiVolume); m_Controls->m_DirectionMatrixTable->setEnabled(foundImageVolume); m_Controls->m_ModifyHeader->setEnabled(foundImageVolume); m_Controls->m_AlignImageBox->setEnabled(foundImageVolume); // we do not support multi-component and 3D+t images for certain operations bool foundSingleImageVolume = foundDwiVolume || (foundImageVolume && !(multiComponentVolume || threeDplusTVolume)); m_Controls->m_FlipAxis->setEnabled(foundSingleImageVolume); m_Controls->m_CropImageButton->setEnabled(foundSingleImageVolume); m_Controls->m_ExtractBrainMask->setEnabled(foundSingleImageVolume); m_Controls->m_ResampleImageButton->setEnabled(foundSingleImageVolume); // reset sampling frame to 1 and update all ealted components m_Controls->m_B_ValueMap_Rounder_SpinBox->setValue(1); UpdateBValueTableWidget(m_Controls->m_B_ValueMap_Rounder_SpinBox->value()); DoUpdateInterpolationGui(m_Controls->m_ResampleTypeBox->currentIndex()); UpdateGradientDetails(); m_Controls->m_HeaderSpacingX->setValue(image->GetGeometry()->GetSpacing()[0]); m_Controls->m_HeaderSpacingY->setValue(image->GetGeometry()->GetSpacing()[1]); m_Controls->m_HeaderSpacingZ->setValue(image->GetGeometry()->GetSpacing()[2]); m_Controls->m_HeaderOriginX->setValue(image->GetGeometry()->GetOrigin()[0]); m_Controls->m_HeaderOriginY->setValue(image->GetGeometry()->GetOrigin()[1]); m_Controls->m_HeaderOriginZ->setValue(image->GetGeometry()->GetOrigin()[2]); m_Controls->m_XstartBox->setMaximum(image->GetGeometry()->GetExtent(0)-1); m_Controls->m_YstartBox->setMaximum(image->GetGeometry()->GetExtent(1)-1); m_Controls->m_ZstartBox->setMaximum(image->GetGeometry()->GetExtent(2)-1); m_Controls->m_XendBox->setMaximum(image->GetGeometry()->GetExtent(0)-1); m_Controls->m_YendBox->setMaximum(image->GetGeometry()->GetExtent(1)-1); m_Controls->m_ZendBox->setMaximum(image->GetGeometry()->GetExtent(2)-1); for (int r=0; r<3; r++) for (int c=0; c<3; c++) { // Direction matrix QTableWidgetItem* item = m_Controls->m_DirectionMatrixTable->item( r, c ); delete item; item = new QTableWidgetItem(); item->setTextAlignment(Qt::AlignCenter | Qt::AlignVCenter); double val = image->GetGeometry()->GetVtkMatrix()->GetElement(r,c)/image->GetGeometry()->GetSpacing()[c]; item->setText(QString::number(val)); m_Controls->m_DirectionMatrixTable->setItem( r, c, item ); } if (foundDwiVolume) { m_Controls->m_InputData->setTitle("Input Data"); vnl_matrix_fixed< double, 3, 3 > mf = PropHelper::GetMeasurementFrame(image); for (int r=0; r<3; r++) for (int c=0; c<3; c++) { // Measurement frame QTableWidgetItem* item = m_Controls->m_MeasurementFrameTable->item( r, c ); delete item; item = new QTableWidgetItem(); item->setTextAlignment(Qt::AlignCenter | Qt::AlignVCenter); item->setText(QString::number(mf.get(r,c))); m_Controls->m_MeasurementFrameTable->setItem( r, c, item ); } //calculate target bValue for MultishellToSingleShellfilter const mitk::BValueMapProperty::BValueMap & bValMap = PropHelper::GetBValueMap(image); mitk::BValueMapProperty::BValueMap::const_iterator it = bValMap.begin(); unsigned int targetBVal = 0; while(it != bValMap.end()) { targetBVal += (it++)->first; } targetBVal /= (float)bValMap.size()-1; m_Controls->m_targetBValueSpinBox->setValue(targetBVal); m_Controls->m_RemoveGradientBox->setMaximum(PropHelper::GetGradientContainer(image)->Size()-1); m_Controls->m_ExtractGradientBox->setMaximum(PropHelper::GetGradientContainer(image)->Size()-1); } } void QmitkPreprocessingView::Activated() { } void QmitkPreprocessingView::Deactivated() { OnImageSelectionChanged(); } void QmitkPreprocessingView::Visible() { OnImageSelectionChanged(); } void QmitkPreprocessingView::Hidden() { } void QmitkPreprocessingView::DoClearRotationOfGradients() { mitk::DataNode::Pointer node = m_Controls->m_SelctedImageComboBox->GetSelectedNode(); if (node.IsNull()) return; mitk::Image::Pointer image = dynamic_cast(node->GetData()); if (image == nullptr) return; if(!PropHelper::IsDiffusionWeightedImage(image)) return; mitk::Image::Pointer newDwi = image->Clone(); PropHelper::SetApplyMatrixToGradients(newDwi, false); mitk::DataNode::Pointer imageNode = mitk::DataNode::New(); imageNode->SetData( newDwi ); QString name = node->GetName().c_str(); imageNode->SetName( (name+"_OriginalGradients").toStdString().c_str() ); GetDataStorage()->Add( imageNode, node ); } void QmitkPreprocessingView::DoFlipGradientDirections() { mitk::DataNode::Pointer node = m_Controls->m_SelctedImageComboBox->GetSelectedNode(); if (node.IsNull()) { return; } mitk::Image::Pointer image = dynamic_cast(node->GetData()); if ( image == nullptr ) { return; } mitk::Image::Pointer newDwi = image->Clone(); auto gradientContainer = PropHelper::GetGradientContainer(newDwi); auto newGradientContainer = PropHelper::GradientDirectionsContainerType::New(); for (unsigned int j=0; jSize(); j++) { PropHelper::GradientDirectionType g; g[0] = gradientContainer->at(j)[0]; g[1] = gradientContainer->at(j)[1]; g[2] = gradientContainer->at(j)[2]; if (m_Controls->m_FlipGradBoxX->isChecked()) { g[0] *= -1; } if (m_Controls->m_FlipGradBoxY->isChecked()) { g[1] *= -1; } if (m_Controls->m_FlipGradBoxZ->isChecked()) { g[2] *= -1; } newGradientContainer->push_back(g); } PropHelper::CopyProperties(image, newDwi, true); PropHelper::SetGradientContainer(newDwi, newGradientContainer); PropHelper::InitializeImage( newDwi ); mitk::DataNode::Pointer imageNode = mitk::DataNode::New(); imageNode->SetData( newDwi ); QString name = node->GetName().c_str(); imageNode->SetName( (name+"_GradientFlip").toStdString().c_str() ); GetDataStorage()->Add( imageNode, node ); } void QmitkPreprocessingView::DoSwapGradientDimensions() { mitk::DataNode::Pointer node = m_Controls->m_SelctedImageComboBox->GetSelectedNode(); if (node.IsNull()) { return; } mitk::Image::Pointer image = dynamic_cast(node->GetData()); if ( image == nullptr ) { return; } mitk::Image::Pointer newDwi = image->Clone(); auto gradientContainer = PropHelper::GetGradientContainer(newDwi); auto newGradientContainer = PropHelper::GradientDirectionsContainerType::New(); std::vector dims_split; std::string swap_string = m_Controls->m_SwapGradientsEdit->text().toStdString(); boost::split(dims_split, swap_string, boost::is_any_of(" "), boost::token_compress_on); std::vector dims_split_clean; for (auto s : dims_split) { if (s=="x") dims_split_clean.push_back(0); else if (s=="y") dims_split_clean.push_back(1); else if (s=="z") dims_split_clean.push_back(2); } if (dims_split_clean.size()!=3) { QMessageBox::warning(nullptr,"Warning", QString("String should contain x, y and z in arbitrary order separated by a space.") ); return; } for (unsigned int j=0; jSize(); j++) { PropHelper::GradientDirectionType g; g[0] = gradientContainer->at(j)[dims_split_clean.at(0)]; g[1] = gradientContainer->at(j)[dims_split_clean.at(1)]; g[2] = gradientContainer->at(j)[dims_split_clean.at(2)]; newGradientContainer->push_back(g); } PropHelper::CopyProperties(image, newDwi, true); PropHelper::SetGradientContainer(newDwi, newGradientContainer); PropHelper::InitializeImage( newDwi ); mitk::DataNode::Pointer imageNode = mitk::DataNode::New(); imageNode->SetData( newDwi ); QString name = node->GetName().c_str(); imageNode->SetName( (name+"_GradientDimSwapped").toStdString().c_str() ); GetDataStorage()->Add( imageNode, node ); } void QmitkPreprocessingView::DoHalfSphereGradientDirections() { mitk::DataNode::Pointer node = m_Controls->m_SelctedImageComboBox->GetSelectedNode(); if (node.IsNull()) { return; } mitk::Image::Pointer image = dynamic_cast(node->GetData()); if ( image == nullptr ) { return; } mitk::Image::Pointer newDwi = image->Clone(); auto gradientContainer = PropHelper::GetGradientContainer(newDwi); auto newGradientContainer = PropHelper::GradientDirectionsContainerType::New(); for (unsigned int j=0; jSize(); j++) { PropHelper::GradientDirectionType g; g[0] = gradientContainer->at(j)[0]; g[1] = gradientContainer->at(j)[1]; g[2] = gradientContainer->at(j)[2]; if (g[0]<0) { g = -g; } newGradientContainer->push_back(g); } PropHelper::CopyProperties(image, newDwi, true); PropHelper::SetGradientContainer(newDwi, newGradientContainer); PropHelper::InitializeImage( newDwi ); mitk::DataNode::Pointer imageNode = mitk::DataNode::New(); imageNode->SetData( newDwi ); QString name = node->GetName().c_str(); imageNode->SetName( (name+"_halfsphere").toStdString().c_str() ); GetDataStorage()->Add( imageNode, node ); } void QmitkPreprocessingView::DoShowGradientDirections() { mitk::DataNode::Pointer node = m_Controls->m_SelctedImageComboBox->GetSelectedNode(); if (node.IsNull()) { return; } mitk::Image::Pointer image = dynamic_cast(node->GetData()); if ( image == nullptr ) { return; } bool isDiffusionImage( PropHelper::IsDiffusionWeightedImage(image) ); if ( !isDiffusionImage ) { return; } int maxIndex = 0; unsigned int maxSize = image->GetDimension(0); if (maxSizeGetDimension(1)) { maxSize = image->GetDimension(1); maxIndex = 1; } if (maxSizeGetDimension(2)) { maxSize = image->GetDimension(2); maxIndex = 2; } mitk::Point3D origin = image->GetGeometry()->GetOrigin(); mitk::PointSet::Pointer originSet = mitk::PointSet::New(); typedef mitk::BValueMapProperty::BValueMap BValueMap; typedef mitk::BValueMapProperty::BValueMap::iterator BValueMapIterator; BValueMap bValMap = PropHelper::GetBValueMap(image); auto gradientContainer = PropHelper::GetGradientContainer(image); mitk::BaseGeometry::Pointer geometry = image->GetGeometry(); int shellCount = 1; for(BValueMapIterator it = bValMap.begin(); it!=bValMap.end(); ++it) { mitk::PointSet::Pointer pointset = mitk::PointSet::New(); for (unsigned int j=0; jsecond.size(); j++) { mitk::Point3D ip; vnl_vector_fixed< double, 3 > v = gradientContainer->at(it->second[j]); if (v.magnitude()>mitk::eps) { ip[0] = v[0]*maxSize*geometry->GetSpacing()[maxIndex]/2 + origin[0]-0.5*geometry->GetSpacing()[0] + geometry->GetSpacing()[0]*image->GetDimension(0)/2; ip[1] = v[1]*maxSize*geometry->GetSpacing()[maxIndex]/2 + origin[1]-0.5*geometry->GetSpacing()[1] + geometry->GetSpacing()[1]*image->GetDimension(1)/2; ip[2] = v[2]*maxSize*geometry->GetSpacing()[maxIndex]/2 + origin[2]-0.5*geometry->GetSpacing()[2] + geometry->GetSpacing()[2]*image->GetDimension(2)/2; pointset->InsertPoint(j, ip); } else if (originSet->IsEmpty()) { ip[0] = v[0]*maxSize*geometry->GetSpacing()[maxIndex]/2 + origin[0]-0.5*geometry->GetSpacing()[0] + geometry->GetSpacing()[0]*image->GetDimension(0)/2; ip[1] = v[1]*maxSize*geometry->GetSpacing()[maxIndex]/2 + origin[1]-0.5*geometry->GetSpacing()[1] + geometry->GetSpacing()[1]*image->GetDimension(1)/2; ip[2] = v[2]*maxSize*geometry->GetSpacing()[maxIndex]/2 + origin[2]-0.5*geometry->GetSpacing()[2] + geometry->GetSpacing()[2]*image->GetDimension(2)/2; originSet->InsertPoint(j, ip); } } if ( it->first < mitk::eps ) { continue; } // add shell to datastorage mitk::DataNode::Pointer newNode = mitk::DataNode::New(); newNode->SetData(pointset); QString name = node->GetName().c_str(); name += "_Shell_"; name += QString::number( it->first ); newNode->SetName( name.toStdString().c_str() ); newNode->SetProperty( "pointsize", mitk::FloatProperty::New((float)maxSize / 50) ); int b0 = shellCount % 2; int b1 = 0; int b2 = 0; if (shellCount>4) { b2 = 1; } if (shellCount%4 >= 2) { b1 = 1; } newNode->SetProperty("color", mitk::ColorProperty::New( b2, b1, b0 )); GetDataStorage()->Add( newNode, node ); shellCount++; } // add origin to datastorage mitk::DataNode::Pointer newNode = mitk::DataNode::New(); newNode->SetData(originSet); QString name = node->GetName().c_str(); name += "_Origin"; newNode->SetName(name.toStdString().c_str()); newNode->SetProperty("pointsize", mitk::FloatProperty::New((float)maxSize/50)); newNode->SetProperty("color", mitk::ColorProperty::New(1,1,1)); GetDataStorage()->Add(newNode, node); } void QmitkPreprocessingView::DoReduceGradientDirections() { mitk::DataNode::Pointer node = m_Controls->m_SelctedImageComboBox->GetSelectedNode(); if (node.IsNull()) { return; } mitk::Image::Pointer image = dynamic_cast(node->GetData()); if ( image == nullptr ) { return; } bool isDiffusionImage( PropHelper::IsDiffusionWeightedImage(image) ); if ( !isDiffusionImage ) { return; } typedef itk::ElectrostaticRepulsionDiffusionGradientReductionFilter FilterType; typedef mitk::BValueMapProperty::BValueMap BValueMap; // GetShellSelection from GUI BValueMap shellSlectionMap; BValueMap originalShellMap = PropHelper::GetBValueMap(image); std::vector newNumGradientDirections; int shellCounter = 0; QString name = node->GetName().c_str(); for (int i=0; im_B_ValueMap_TableWidget->rowCount(); i++) { double BValue = m_Controls->m_B_ValueMap_TableWidget->item(i,0)->text().toDouble(); shellSlectionMap[BValue] = originalShellMap[BValue]; unsigned int num = m_Controls->m_B_ValueMap_TableWidget->item(i,1)->text().toUInt(); newNumGradientDirections.push_back(num); name += "_"; name += QString::number(num); shellCounter++; } if (newNumGradientDirections.empty()) { return; } auto gradientContainer = PropHelper::GetGradientContainer(image); ItkDwiType::Pointer itkVectorImagePointer = ItkDwiType::New(); mitk::CastToItkImage(image, itkVectorImagePointer); FilterType::Pointer filter = FilterType::New(); filter->SetInput( itkVectorImagePointer ); filter->SetOriginalGradientDirections(gradientContainer); filter->SetNumGradientDirections(newNumGradientDirections); filter->SetOriginalBValueMap(originalShellMap); filter->SetShellSelectionBValueMap(shellSlectionMap); filter->SetUseFirstN(m_Controls->m_KeepFirstNBox->isChecked()); filter->Update(); mitk::Image::Pointer newImage = mitk::GrabItkImageMemory( filter->GetOutput() ); PropHelper::CopyProperties(image, newImage, true); PropHelper::SetGradientContainer(newImage, filter->GetGradientDirections()); PropHelper::InitializeImage(newImage); mitk::DataNode::Pointer imageNode = mitk::DataNode::New(); imageNode->SetData( newImage ); imageNode->SetName(name.toStdString().c_str()); GetDataStorage()->Add(imageNode, node); // update the b-value widget to remove the modified number of gradients used for extraction this->CleanBValueTableWidget(); this->UpdateBValueTableWidget(0); this->UpdateGradientDetails(); } void QmitkPreprocessingView::MergeDwis() { typedef GradProp::GradientDirectionsContainerType GradientContainerType; mitk::DataNode::Pointer node = m_Controls->m_SelctedImageComboBox->GetSelectedNode(); if (node.IsNull()) { return; } mitk::Image::Pointer image = dynamic_cast(node->GetData()); if ( image == nullptr ) { return; } bool isDiffusionImage( PropHelper::IsDiffusionWeightedImage(image) ); if ( !isDiffusionImage ) { return; } mitk::DataNode::Pointer node2 = m_Controls->m_MergeDwiBox->GetSelectedNode(); if (node2.IsNull()) { return; } mitk::Image::Pointer image2 = dynamic_cast(node2->GetData()); if ( image2 == nullptr ) { return; } typedef itk::VectorImage DwiImageType; typedef std::vector< DwiImageType::Pointer > DwiImageContainerType; typedef std::vector< GradientContainerType::ConstPointer > GradientListContainerType; DwiImageContainerType imageContainer; GradientListContainerType gradientListContainer; std::vector< double > bValueContainer; QString name = ""; { ItkDwiType::Pointer itkVectorImagePointer = ItkDwiType::New(); mitk::CastToItkImage(image, itkVectorImagePointer); imageContainer.push_back( itkVectorImagePointer ); gradientListContainer.push_back(PropHelper::GetGradientContainer(image)); bValueContainer.push_back(PropHelper::GetReferenceBValue(image)); name += node->GetName().c_str(); } { ItkDwiType::Pointer itkVectorImagePointer = ItkDwiType::New(); mitk::CastToItkImage(image2, itkVectorImagePointer); imageContainer.push_back( itkVectorImagePointer ); gradientListContainer.push_back(PropHelper::GetGradientContainer(image2)); bValueContainer.push_back(PropHelper::GetReferenceBValue(image2)); name += "+"; name += node2->GetName().c_str(); } typedef itk::MergeDiffusionImagesFilter FilterType; FilterType::Pointer filter = FilterType::New(); filter->SetImageVolumes(imageContainer); filter->SetGradientLists(gradientListContainer); filter->SetBValues(bValueContainer); filter->Update(); vnl_matrix_fixed< double, 3, 3 > mf; mf.set_identity(); mitk::Image::Pointer newImage = mitk::GrabItkImageMemory( filter->GetOutput() ); PropHelper::SetGradientContainer(newImage, filter->GetOutputGradients()); PropHelper::SetMeasurementFrame(newImage, mf); PropHelper::SetReferenceBValue(newImage, filter->GetB_Value()); PropHelper::InitializeImage( newImage ); mitk::DataNode::Pointer imageNode = mitk::DataNode::New(); imageNode->SetData( newImage ); imageNode->SetName(name.toStdString().c_str()); GetDataStorage()->Add(imageNode); } void QmitkPreprocessingView::ExtractB0() { mitk::DataNode::Pointer node = m_Controls->m_SelctedImageComboBox->GetSelectedNode(); if (node.IsNull()) { return; } mitk::Image::Pointer image = dynamic_cast(node->GetData()); if ( image == nullptr ) { return; } bool isDiffusionImage( PropHelper::IsDiffusionWeightedImage(image) ); if ( !isDiffusionImage ) { return; } // call the extraction withou averaging if the check-box is checked if( this->m_Controls->m_CheckExtractAll->isChecked() ) { DoExtractBOWithoutAveraging(); return; } ItkDwiType::Pointer itkVectorImagePointer = ItkDwiType::New(); mitk::CastToItkImage(image, itkVectorImagePointer); // Extract image using found index typedef itk::B0ImageExtractionImageFilter FilterType; FilterType::Pointer filter = FilterType::New(); filter->SetInput( itkVectorImagePointer ); filter->SetDirections(PropHelper::GetGradientContainer(image)); filter->Update(); mitk::Image::Pointer mitkImage = mitk::Image::New(); mitkImage->InitializeByItk( filter->GetOutput() ); mitkImage->SetVolume( filter->GetOutput()->GetBufferPointer() ); mitk::DataNode::Pointer newNode=mitk::DataNode::New(); newNode->SetData( mitkImage ); newNode->SetProperty( "name", mitk::StringProperty::New(node->GetName() + "_B0")); GetDataStorage()->Add(newNode, node); } void QmitkPreprocessingView::DoExtractBOWithoutAveraging() { mitk::DataNode::Pointer node = m_Controls->m_SelctedImageComboBox->GetSelectedNode(); if (node.IsNull()) { return; } mitk::Image::Pointer image = dynamic_cast(node->GetData()); if ( image == nullptr ) { return; } bool isDiffusionImage( PropHelper::IsDiffusionWeightedImage(image) ); if ( !isDiffusionImage ) { return; } // typedefs typedef itk::B0ImageExtractionToSeparateImageFilter< short, short> FilterType; ItkDwiType::Pointer itkVectorImagePointer = ItkDwiType::New(); mitk::CastToItkImage(image, itkVectorImagePointer); // Extract image using found index FilterType::Pointer filter = FilterType::New(); filter->SetInput( itkVectorImagePointer ); filter->SetDirections(PropHelper::GetGradientContainer(image)); filter->Update(); mitk::Image::Pointer mitkImage = mitk::Image::New(); mitkImage->InitializeByItk( filter->GetOutput() ); mitkImage->SetImportChannel( filter->GetOutput()->GetBufferPointer() ); mitk::DataNode::Pointer newNode=mitk::DataNode::New(); newNode->SetData( mitkImage ); newNode->SetProperty( "name", mitk::StringProperty::New(node->GetName() + "_B0_ALL")); GetDataStorage()->Add(newNode, node); /*A reinitialization is needed to access the time channels via the ImageNavigationController The Global-Geometry can not recognize the time channel without a re-init. (for a new selection in datamanger a automatically updated of the Global-Geometry should be done - if it contains the time channel)*/ mitk::RenderingManager::GetInstance()->InitializeViews( newNode->GetData()->GetTimeGeometry(), mitk::RenderingManager::REQUEST_UPDATE_ALL, true); } void QmitkPreprocessingView::AverageGradients() { mitk::DataNode::Pointer node = m_Controls->m_SelctedImageComboBox->GetSelectedNode(); if (node.IsNull()) { return; } mitk::Image::Pointer image = dynamic_cast(node->GetData()); if ( image == nullptr ) { return; } bool isDiffusionImage( PropHelper::IsDiffusionWeightedImage(image) ); if ( !isDiffusionImage ) return; mitk::Image::Pointer newDwi = image->Clone(); PropHelper::AverageRedundantGradients(newDwi, m_Controls->m_Blur->value()); PropHelper::InitializeImage(newDwi); mitk::DataNode::Pointer imageNode = mitk::DataNode::New(); imageNode->SetData( newDwi ); QString name = node->GetName().c_str(); imageNode->SetName((name+"_averaged").toStdString().c_str()); GetDataStorage()->Add(imageNode, node); } diff --git a/Plugins/org.mitk.gui.qt.diffusionimaging.tractography/src/internal/QmitkStreamlineTrackingView.cpp b/Plugins/org.mitk.gui.qt.diffusionimaging.tractography/src/internal/QmitkStreamlineTrackingView.cpp index 1a89cb7..4233463 100644 --- a/Plugins/org.mitk.gui.qt.diffusionimaging.tractography/src/internal/QmitkStreamlineTrackingView.cpp +++ b/Plugins/org.mitk.gui.qt.diffusionimaging.tractography/src/internal/QmitkStreamlineTrackingView.cpp @@ -1,1170 +1,1170 @@ /*=================================================================== The Medical Imaging Interaction Toolkit (MITK) Copyright (c) German Cancer Research Center. All rights reserved. This software is distributed WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See LICENSE.txt or http://www.mitk.org for details. ===================================================================*/ // Blueberry #include #include #include // Qmitk #include "QmitkStreamlineTrackingView.h" #include "QmitkStdMultiWidget.h" // Qt #include #include // MITK #include #include #include #include #include #include #include #include #include #include #include #include #include #include // VTK #include #include #include #include #include #include #include #include #include #include const std::string QmitkStreamlineTrackingView::VIEW_ID = "org.mitk.views.streamlinetracking"; const std::string id_DataManager = "org.mitk.views.datamanager"; using namespace berry; QmitkStreamlineTrackingWorker::QmitkStreamlineTrackingWorker(QmitkStreamlineTrackingView* view) : m_View(view) { } void QmitkStreamlineTrackingWorker::run() { m_View->m_Tracker->Update(); m_View->m_TrackingThread.quit(); } QmitkStreamlineTrackingView::QmitkStreamlineTrackingView() : m_TrackingWorker(this) , m_Controls(nullptr) , m_FirstTensorProbRun(true) , m_FirstInteractiveRun(true) , m_TrackingHandler(nullptr) , m_ThreadIsRunning(false) , m_DeleteTrackingHandler(false) , m_Visible(false) , m_LastPrior(nullptr) , m_TrackingPriorHandler(nullptr) { m_TrackingWorker.moveToThread(&m_TrackingThread); connect(&m_TrackingThread, SIGNAL(started()), this, SLOT(BeforeThread())); connect(&m_TrackingThread, SIGNAL(started()), &m_TrackingWorker, SLOT(run())); connect(&m_TrackingThread, SIGNAL(finished()), this, SLOT(AfterThread())); m_TrackingTimer = new QTimer(this); } // Destructor QmitkStreamlineTrackingView::~QmitkStreamlineTrackingView() { if (m_Tracker.IsNull()) return; m_Tracker->SetStopTracking(true); m_TrackingThread.wait(); } void QmitkStreamlineTrackingView::CreateQtPartControl( QWidget *parent ) { if ( !m_Controls ) { // create GUI widgets from the Qt Designer's .ui file m_Controls = new Ui::QmitkStreamlineTrackingViewControls; m_Controls->setupUi( parent ); m_Controls->m_FaImageSelectionWidget->SetDataStorage(this->GetDataStorage()); m_Controls->m_SeedImageSelectionWidget->SetDataStorage(this->GetDataStorage()); m_Controls->m_MaskImageSelectionWidget->SetDataStorage(this->GetDataStorage()); m_Controls->m_TargetImageSelectionWidget->SetDataStorage(this->GetDataStorage()); m_Controls->m_PriorImageSelectionWidget->SetDataStorage(this->GetDataStorage()); m_Controls->m_StopImageSelectionWidget->SetDataStorage(this->GetDataStorage()); m_Controls->m_ForestSelectionWidget->SetDataStorage(this->GetDataStorage()); m_Controls->m_ExclusionImageSelectionWidget->SetDataStorage(this->GetDataStorage()); mitk::TNodePredicateDataType::Pointer isPeakImagePredicate = mitk::TNodePredicateDataType::New(); mitk::TNodePredicateDataType::Pointer isImagePredicate = mitk::TNodePredicateDataType::New(); mitk::TNodePredicateDataType::Pointer isTractographyForest = mitk::TNodePredicateDataType::New(); mitk::NodePredicateProperty::Pointer isBinaryPredicate = mitk::NodePredicateProperty::New("binary", mitk::BoolProperty::New(true)); mitk::NodePredicateNot::Pointer isNotBinaryPredicate = mitk::NodePredicateNot::New( isBinaryPredicate ); mitk::NodePredicateAnd::Pointer isNotABinaryImagePredicate = mitk::NodePredicateAnd::New( isImagePredicate, isNotBinaryPredicate ); mitk::NodePredicateDimension::Pointer dimensionPredicate = mitk::NodePredicateDimension::New(3); m_Controls->m_ForestSelectionWidget->SetNodePredicate(isTractographyForest); m_Controls->m_FaImageSelectionWidget->SetNodePredicate( mitk::NodePredicateAnd::New(isNotABinaryImagePredicate, dimensionPredicate) ); m_Controls->m_FaImageSelectionWidget->SetEmptyInfo("--"); m_Controls->m_FaImageSelectionWidget->SetSelectionIsOptional(true); m_Controls->m_SeedImageSelectionWidget->SetNodePredicate( mitk::NodePredicateAnd::New(isImagePredicate, dimensionPredicate) ); m_Controls->m_SeedImageSelectionWidget->SetEmptyInfo("--"); m_Controls->m_SeedImageSelectionWidget->SetSelectionIsOptional(true); m_Controls->m_MaskImageSelectionWidget->SetNodePredicate( mitk::NodePredicateAnd::New(isImagePredicate, dimensionPredicate) ); m_Controls->m_MaskImageSelectionWidget->SetEmptyInfo("--"); m_Controls->m_MaskImageSelectionWidget->SetSelectionIsOptional(true); m_Controls->m_StopImageSelectionWidget->SetNodePredicate( mitk::NodePredicateAnd::New(isImagePredicate, dimensionPredicate) ); m_Controls->m_StopImageSelectionWidget->SetEmptyInfo("--"); m_Controls->m_StopImageSelectionWidget->SetSelectionIsOptional(true); m_Controls->m_TargetImageSelectionWidget->SetNodePredicate( mitk::NodePredicateAnd::New(isImagePredicate, dimensionPredicate) ); m_Controls->m_TargetImageSelectionWidget->SetEmptyInfo("--"); m_Controls->m_TargetImageSelectionWidget->SetSelectionIsOptional(true); m_Controls->m_PriorImageSelectionWidget->SetNodePredicate( isPeakImagePredicate ); m_Controls->m_PriorImageSelectionWidget->SetEmptyInfo("--"); m_Controls->m_PriorImageSelectionWidget->SetSelectionIsOptional(true); m_Controls->m_ExclusionImageSelectionWidget->SetNodePredicate( mitk::NodePredicateAnd::New(isImagePredicate, dimensionPredicate) ); m_Controls->m_ExclusionImageSelectionWidget->SetEmptyInfo("--"); m_Controls->m_ExclusionImageSelectionWidget->SetSelectionIsOptional(true); connect( m_TrackingTimer, SIGNAL(timeout()), this, SLOT(TimerUpdate()) ); connect( m_Controls->m_SaveParametersButton, SIGNAL(clicked()), this, SLOT(SaveParameters()) ); connect( m_Controls->m_LoadParametersButton, SIGNAL(clicked()), this, SLOT(LoadParameters()) ); connect( m_Controls->commandLinkButton_2, SIGNAL(clicked()), this, SLOT(StopTractography()) ); connect( m_Controls->commandLinkButton, SIGNAL(clicked()), this, SLOT(DoFiberTracking()) ); connect( m_Controls->m_InteractiveBox, SIGNAL(stateChanged(int)), this, SLOT(ToggleInteractive()) ); connect( m_Controls->m_ModeBox, SIGNAL(currentIndexChanged(int)), this, SLOT(UpdateGui()) ); - connect( m_Controls->m_FaImageSelectionWidget, SIGNAL(CurrentSelectionChanged(QList)), this, SLOT(DeleteTrackingHandler()) ); + connect( m_Controls->m_FaImageSelectionWidget, &QmitkAbstractNodeSelectionWidget::CurrentSelectionChanged, this, &QmitkStreamlineTrackingView::DeleteTrackingHandler ); connect( m_Controls->m_ModeBox, SIGNAL(currentIndexChanged(int)), this, SLOT(DeleteTrackingHandler()) ); connect( m_Controls->m_OutputProbMap, SIGNAL(stateChanged(int)), this, SLOT(OutputStyleSwitched()) ); - connect( m_Controls->m_SeedImageSelectionWidget, SIGNAL(CurrentSelectionChanged(QList)), this, SLOT(OnParameterChanged()) ); + connect( m_Controls->m_SeedImageSelectionWidget, &QmitkAbstractNodeSelectionWidget::CurrentSelectionChanged, this, &QmitkStreamlineTrackingView::OnParameterChanged ); connect( m_Controls->m_ModeBox, SIGNAL(currentIndexChanged(int)), this, SLOT(OnParameterChanged()) ); - connect( m_Controls->m_StopImageSelectionWidget, SIGNAL(CurrentSelectionChanged(QList)), this, SLOT(OnParameterChanged()) ); - connect( m_Controls->m_TargetImageSelectionWidget, SIGNAL(CurrentSelectionChanged(QList)), this, SLOT(OnParameterChanged()) ); - connect( m_Controls->m_PriorImageSelectionWidget, SIGNAL(CurrentSelectionChanged(QList)), this, SLOT(OnParameterChanged()) ); - connect( m_Controls->m_ExclusionImageSelectionWidget, SIGNAL(CurrentSelectionChanged(QList)), this, SLOT(OnParameterChanged()) ); - connect( m_Controls->m_MaskImageSelectionWidget, SIGNAL(CurrentSelectionChanged(QList)), this, SLOT(OnParameterChanged()) ); - connect( m_Controls->m_FaImageSelectionWidget, SIGNAL(CurrentSelectionChanged(QList)), this, SLOT(OnParameterChanged()) ); - connect( m_Controls->m_ForestSelectionWidget, SIGNAL(CurrentSelectionChanged(QList)), this, SLOT(ForestSwitched()) ); - connect( m_Controls->m_ForestSelectionWidget, SIGNAL(CurrentSelectionChanged(QList)), this, SLOT(OnParameterChanged()) ); + connect( m_Controls->m_StopImageSelectionWidget, &QmitkAbstractNodeSelectionWidget::CurrentSelectionChanged, this, &QmitkStreamlineTrackingView::OnParameterChanged ); + connect( m_Controls->m_TargetImageSelectionWidget, &QmitkAbstractNodeSelectionWidget::CurrentSelectionChanged, this, &QmitkStreamlineTrackingView::OnParameterChanged ); + connect( m_Controls->m_PriorImageSelectionWidget, &QmitkAbstractNodeSelectionWidget::CurrentSelectionChanged, this, &QmitkStreamlineTrackingView::OnParameterChanged ); + connect( m_Controls->m_ExclusionImageSelectionWidget, &QmitkAbstractNodeSelectionWidget::CurrentSelectionChanged, this, &QmitkStreamlineTrackingView::OnParameterChanged ); + connect( m_Controls->m_MaskImageSelectionWidget, &QmitkAbstractNodeSelectionWidget::CurrentSelectionChanged, this, &QmitkStreamlineTrackingView::OnParameterChanged ); + connect( m_Controls->m_FaImageSelectionWidget, &QmitkAbstractNodeSelectionWidget::CurrentSelectionChanged, this, &QmitkStreamlineTrackingView::OnParameterChanged ); + connect( m_Controls->m_ForestSelectionWidget, &QmitkAbstractNodeSelectionWidget::CurrentSelectionChanged, this, &QmitkStreamlineTrackingView::ForestSwitched ); + connect( m_Controls->m_ForestSelectionWidget, &QmitkAbstractNodeSelectionWidget::CurrentSelectionChanged, this, &QmitkStreamlineTrackingView::OnParameterChanged ); connect( m_Controls->m_SeedsPerVoxelBox, SIGNAL(editingFinished()), this, SLOT(OnParameterChanged()) ); connect( m_Controls->m_NumFibersBox, SIGNAL(editingFinished()), this, SLOT(OnParameterChanged()) ); connect( m_Controls->m_ScalarThresholdBox, SIGNAL(editingFinished()), this, SLOT(OnParameterChanged()) ); connect( m_Controls->m_OdfCutoffBox, SIGNAL(editingFinished()), this, SLOT(OnParameterChanged()) ); connect( m_Controls->m_StepSizeBox, SIGNAL(editingFinished()), this, SLOT(OnParameterChanged()) ); connect( m_Controls->m_SamplingDistanceBox, SIGNAL(editingFinished()), this, SLOT(OnParameterChanged()) ); connect( m_Controls->m_AngularThresholdBox, SIGNAL(editingFinished()), this, SLOT(OnParameterChanged()) ); connect( m_Controls->m_MinTractLengthBox, SIGNAL(editingFinished()), this, SLOT(OnParameterChanged()) ); connect( m_Controls->m_MaxTractLengthBox, SIGNAL(editingFinished()), this, SLOT(OnParameterChanged()) ); connect( m_Controls->m_fBox, SIGNAL(editingFinished()), this, SLOT(OnParameterChanged()) ); connect( m_Controls->m_gBox, SIGNAL(editingFinished()), this, SLOT(OnParameterChanged()) ); connect( m_Controls->m_NumSamplesBox, SIGNAL(editingFinished()), this, SLOT(OnParameterChanged()) ); connect( m_Controls->m_SeedRadiusBox, SIGNAL(editingFinished()), this, SLOT(InteractiveSeedChanged()) ); connect( m_Controls->m_NumSeedsBox, SIGNAL(editingFinished()), this, SLOT(InteractiveSeedChanged()) ); connect( m_Controls->m_OutputProbMap, SIGNAL(stateChanged(int)), this, SLOT(OnParameterChanged()) ); connect( m_Controls->m_SharpenOdfsBox, SIGNAL(stateChanged(int)), this, SLOT(OnParameterChanged()) ); connect( m_Controls->m_InterpolationBox, SIGNAL(stateChanged(int)), this, SLOT(OnParameterChanged()) ); connect( m_Controls->m_MaskInterpolationBox, SIGNAL(stateChanged(int)), this, SLOT(OnParameterChanged()) ); connect( m_Controls->m_FlipXBox, SIGNAL(stateChanged(int)), this, SLOT(OnParameterChanged()) ); connect( m_Controls->m_FlipYBox, SIGNAL(stateChanged(int)), this, SLOT(OnParameterChanged()) ); connect( m_Controls->m_FlipZBox, SIGNAL(stateChanged(int)), this, SLOT(OnParameterChanged()) ); connect( m_Controls->m_PriorFlipXBox, SIGNAL(stateChanged(int)), this, SLOT(OnParameterChanged()) ); connect( m_Controls->m_PriorFlipYBox, SIGNAL(stateChanged(int)), this, SLOT(OnParameterChanged()) ); connect( m_Controls->m_PriorFlipZBox, SIGNAL(stateChanged(int)), this, SLOT(OnParameterChanged()) ); connect( m_Controls->m_FrontalSamplesBox, SIGNAL(stateChanged(int)), this, SLOT(OnParameterChanged()) ); connect( m_Controls->m_StopVotesBox, SIGNAL(stateChanged(int)), this, SLOT(OnParameterChanged()) ); connect( m_Controls->m_LoopCheckBox, SIGNAL(editingFinished()), this, SLOT(OnParameterChanged()) ); connect( m_Controls->m_TrialsPerSeedBox, SIGNAL(editingFinished()), this, SLOT(OnParameterChanged()) ); connect( m_Controls->m_EpConstraintsBox, SIGNAL(currentIndexChanged(int)), this, SLOT(OnParameterChanged()) ); connect( m_Controls->m_PeakJitterBox, SIGNAL(editingFinished()), this, SLOT(OnParameterChanged()) ); m_Controls->m_SeedsPerVoxelBox->editingFinished(); m_Controls->m_NumFibersBox->editingFinished(); m_Controls->m_ScalarThresholdBox->editingFinished(); m_Controls->m_OdfCutoffBox->editingFinished(); m_Controls->m_StepSizeBox->editingFinished(); m_Controls->m_SamplingDistanceBox->editingFinished(); m_Controls->m_AngularThresholdBox->editingFinished(); m_Controls->m_MinTractLengthBox->editingFinished(); m_Controls->m_MaxTractLengthBox->editingFinished(); m_Controls->m_fBox->editingFinished(); m_Controls->m_gBox->editingFinished(); m_Controls->m_NumSamplesBox->editingFinished(); m_Controls->m_SeedRadiusBox->editingFinished(); m_Controls->m_NumSeedsBox->editingFinished(); m_Controls->m_LoopCheckBox->editingFinished(); m_Controls->m_TrialsPerSeedBox->editingFinished(); m_Controls->m_PeakJitterBox->editingFinished(); StartStopTrackingGui(false); } m_ParameterFile = QDir::currentPath()+"/param.stp"; UpdateGui(); } void QmitkStreamlineTrackingView::ParametersToGui(mitk::StreamlineTractographyParameters& params) { m_Controls->m_SeedRadiusBox->setValue(params.m_InteractiveRadiusMm); m_Controls->m_NumSeedsBox->setValue(params.m_NumInteractiveSeeds); m_Controls->m_InteractiveBox->setChecked(params.m_EnableInteractive); m_Controls->m_FiberErrorBox->setValue(params.m_Compression); m_Controls->m_ResampleFibersBox->setChecked(params.m_CompressFibers); m_Controls->m_SeedRadiusBox->setValue(params.m_InteractiveRadiusMm); m_Controls->m_NumFibersBox->setValue(params.m_MaxNumFibers); m_Controls->m_ScalarThresholdBox->setValue(params.m_Cutoff); m_Controls->m_fBox->setValue(params.m_F); m_Controls->m_gBox->setValue(params.m_G); m_Controls->m_OdfCutoffBox->setValue(params.m_OdfCutoff); m_Controls->m_SharpenOdfsBox->setChecked(params.m_SharpenOdfs); m_Controls->m_PriorWeightBox->setValue(params.m_Weight); m_Controls->m_PriorAsMaskBox->setChecked(params.m_RestrictToPrior); m_Controls->m_NewDirectionsFromPriorBox->setChecked(params.m_NewDirectionsFromPrior); m_Controls->m_PriorFlipXBox->setChecked(params.m_PriorFlipX); m_Controls->m_PriorFlipYBox->setChecked(params.m_PriorFlipY); m_Controls->m_PriorFlipZBox->setChecked(params.m_PriorFlipZ); m_Controls->m_FlipXBox->setChecked(params.m_FlipX); m_Controls->m_FlipYBox->setChecked(params.m_FlipY); m_Controls->m_FlipZBox->setChecked(params.m_FlipZ); m_Controls->m_InterpolationBox->setChecked(params.m_InterpolateTractographyData); m_Controls->m_MaskInterpolationBox->setChecked(params.m_InterpolateRoiImages); m_Controls->m_SeedsPerVoxelBox->setValue(params.m_SeedsPerVoxel); m_Controls->m_StepSizeBox->setValue(params.GetStepSizeVox()); m_Controls->m_SamplingDistanceBox->setValue(params.GetSamplingDistanceVox()); m_Controls->m_StopVotesBox->setChecked(params.m_StopVotes); m_Controls->m_FrontalSamplesBox->setChecked(params.m_OnlyForwardSamples); m_Controls->m_TrialsPerSeedBox->setValue(params.m_TrialsPerSeed); m_Controls->m_NumSamplesBox->setValue(params.m_NumSamples); m_Controls->m_LoopCheckBox->setValue(params.GetLoopCheckDeg()); m_Controls->m_AngularThresholdBox->setValue(params.GetAngularThresholdDeg()); m_Controls->m_MinTractLengthBox->setValue(params.m_MinTractLengthMm); m_Controls->m_MaxTractLengthBox->setValue(params.m_MaxTractLengthMm); m_Controls->m_OutputProbMap->setChecked(params.m_OutputProbMap); m_Controls->m_FixSeedBox->setChecked(params.m_FixRandomSeed); m_Controls->m_PeakJitterBox->setValue(params.m_PeakJitter); switch (params.m_Mode) { case mitk::TrackingDataHandler::MODE::DETERMINISTIC: m_Controls->m_ModeBox->setCurrentIndex(0); break; case mitk::TrackingDataHandler::MODE::PROBABILISTIC: m_Controls->m_ModeBox->setCurrentIndex(1); break; } switch (params.m_EpConstraints) { case itk::StreamlineTrackingFilter::EndpointConstraints::NONE: m_Controls->m_EpConstraintsBox->setCurrentIndex(0); break; case itk::StreamlineTrackingFilter::EndpointConstraints::EPS_IN_TARGET: m_Controls->m_EpConstraintsBox->setCurrentIndex(1); break; case itk::StreamlineTrackingFilter::EndpointConstraints::EPS_IN_TARGET_LABELDIFF: m_Controls->m_EpConstraintsBox->setCurrentIndex(2); break; case itk::StreamlineTrackingFilter::EndpointConstraints::EPS_IN_SEED_AND_TARGET: m_Controls->m_EpConstraintsBox->setCurrentIndex(3); break; case itk::StreamlineTrackingFilter::EndpointConstraints::MIN_ONE_EP_IN_TARGET: m_Controls->m_EpConstraintsBox->setCurrentIndex(4); break; case itk::StreamlineTrackingFilter::EndpointConstraints::ONE_EP_IN_TARGET: m_Controls->m_EpConstraintsBox->setCurrentIndex(5); break; case itk::StreamlineTrackingFilter::EndpointConstraints::NO_EP_IN_TARGET: m_Controls->m_EpConstraintsBox->setCurrentIndex(6); break; } } std::shared_ptr QmitkStreamlineTrackingView::GetParametersFromGui() { // NOT IN GUI // unsigned int m_NumPreviousDirections = 1; // bool m_AvoidStop = true; // bool m_RandomSampling = false; // float m_DeflectionMod = 1.0; // bool m_ApplyDirectionMatrix = false; std::shared_ptr params = std::make_shared(); params->m_InteractiveRadiusMm = m_Controls->m_SeedRadiusBox->value(); params->m_NumInteractiveSeeds = m_Controls->m_NumSeedsBox->value(); params->m_EnableInteractive = m_Controls->m_InteractiveBox->isChecked(); params->m_Compression = m_Controls->m_FiberErrorBox->value(); params->m_CompressFibers = m_Controls->m_ResampleFibersBox->isChecked(); params->m_InteractiveRadiusMm = m_Controls->m_SeedRadiusBox->value(); params->m_MaxNumFibers = m_Controls->m_NumFibersBox->value(); params->m_Cutoff = static_cast(m_Controls->m_ScalarThresholdBox->value()); params->m_F = static_cast(m_Controls->m_fBox->value()); params->m_G = static_cast(m_Controls->m_gBox->value()); params->m_OdfCutoff = static_cast(m_Controls->m_OdfCutoffBox->value()); params->m_SharpenOdfs = m_Controls->m_SharpenOdfsBox->isChecked(); params->m_Weight = static_cast(m_Controls->m_PriorWeightBox->value()); params->m_RestrictToPrior = m_Controls->m_PriorAsMaskBox->isChecked(); params->m_NewDirectionsFromPrior = m_Controls->m_NewDirectionsFromPriorBox->isChecked(); params->m_PriorFlipX = m_Controls->m_PriorFlipXBox->isChecked(); params->m_PriorFlipY = m_Controls->m_PriorFlipYBox->isChecked(); params->m_PriorFlipZ = m_Controls->m_PriorFlipZBox->isChecked(); params->m_FlipX = m_Controls->m_FlipXBox->isChecked(); params->m_FlipY = m_Controls->m_FlipYBox->isChecked(); params->m_FlipZ = m_Controls->m_FlipZBox->isChecked(); params->m_InterpolateTractographyData = m_Controls->m_InterpolationBox->isChecked(); params->m_InterpolateRoiImages = m_Controls->m_MaskInterpolationBox->isChecked(); params->m_SeedsPerVoxel = m_Controls->m_SeedsPerVoxelBox->value(); params->SetStepSizeVox(m_Controls->m_StepSizeBox->value()); params->SetSamplingDistanceVox(m_Controls->m_SamplingDistanceBox->value()); params->m_StopVotes = m_Controls->m_StopVotesBox->isChecked(); params->m_OnlyForwardSamples = m_Controls->m_FrontalSamplesBox->isChecked(); params->m_TrialsPerSeed = m_Controls->m_TrialsPerSeedBox->value(); params->m_NumSamples = m_Controls->m_NumSamplesBox->value(); params->SetLoopCheckDeg(m_Controls->m_LoopCheckBox->value()); params->SetAngularThresholdDeg(m_Controls->m_AngularThresholdBox->value()); params->m_MinTractLengthMm = m_Controls->m_MinTractLengthBox->value(); params->m_MaxTractLengthMm = m_Controls->m_MaxTractLengthBox->value(); params->m_OutputProbMap = m_Controls->m_OutputProbMap->isChecked(); params->m_FixRandomSeed = m_Controls->m_FixSeedBox->isChecked(); params->m_PeakJitter = static_cast(m_Controls->m_PeakJitterBox->value()); switch (m_Controls->m_ModeBox->currentIndex()) { case 0: params->m_Mode = mitk::TrackingDataHandler::MODE::DETERMINISTIC; break; case 1: params->m_Mode = mitk::TrackingDataHandler::MODE::PROBABILISTIC; break; default: params->m_Mode = mitk::TrackingDataHandler::MODE::DETERMINISTIC; } switch (m_Controls->m_EpConstraintsBox->currentIndex()) { case 0: params->m_EpConstraints = itk::StreamlineTrackingFilter::EndpointConstraints::NONE; break; case 1: params->m_EpConstraints = itk::StreamlineTrackingFilter::EndpointConstraints::EPS_IN_TARGET; break; case 2: params->m_EpConstraints = itk::StreamlineTrackingFilter::EndpointConstraints::EPS_IN_TARGET_LABELDIFF; break; case 3: params->m_EpConstraints = itk::StreamlineTrackingFilter::EndpointConstraints::EPS_IN_SEED_AND_TARGET; break; case 4: params->m_EpConstraints = itk::StreamlineTrackingFilter::EndpointConstraints::MIN_ONE_EP_IN_TARGET; break; case 5: params->m_EpConstraints = itk::StreamlineTrackingFilter::EndpointConstraints::ONE_EP_IN_TARGET; break; case 6: params->m_EpConstraints = itk::StreamlineTrackingFilter::EndpointConstraints::NO_EP_IN_TARGET; break; } return params; } void QmitkStreamlineTrackingView::SaveParameters() { QString filename = QFileDialog::getSaveFileName( 0, tr("Save Tractography Parameters"), m_ParameterFile, tr("Streamline Tractography Parameters (*.stp)") ); if(filename.isEmpty() || filename.isNull()) return; m_ParameterFile = filename; auto params = GetParametersFromGui(); params->SaveParameters(m_ParameterFile.toStdString()); } void QmitkStreamlineTrackingView::LoadParameters() { QString filename = QFileDialog::getOpenFileName( 0, tr("Load Tractography Parameters"), m_ParameterFile, tr("Streamline Tractography Parameters (*.stp)") ); if(filename.isEmpty() || filename.isNull()) return; m_ParameterFile = filename; mitk::StreamlineTractographyParameters params; params.LoadParameters(m_ParameterFile.toStdString()); ParametersToGui(params); } void QmitkStreamlineTrackingView::StopTractography() { if (m_Tracker.IsNull()) return; m_Tracker->SetStopTracking(true); } void QmitkStreamlineTrackingView::TimerUpdate() { if (m_Tracker.IsNull()) return; QString status_text(m_Tracker->GetStatusText().c_str()); m_Controls->m_StatusTextBox->setText(status_text); } void QmitkStreamlineTrackingView::BeforeThread() { m_TrackingTimer->start(1000); } void QmitkStreamlineTrackingView::AfterThread() { auto params = m_Tracker->GetParameters(); m_TrackingTimer->stop(); if (!params->m_OutputProbMap) { vtkSmartPointer fiberBundle = m_Tracker->GetFiberPolyData(); if (!m_Controls->m_InteractiveBox->isChecked() && fiberBundle->GetNumberOfLines() == 0) { QMessageBox warnBox; warnBox.setWindowTitle("Warning"); warnBox.setText("No fiberbundle was generated!"); warnBox.setDetailedText("No fibers were generated using the chosen parameters. Typical reasons are:\n\n- Cutoff too high. Some images feature very low FA/GFA/peak size. Try to lower this parameter.\n- Angular threshold too strict. Try to increase this parameter.\n- A small step sizes also means many steps to go wrong. Especially in the case of probabilistic tractography. Try to adjust the angular threshold."); warnBox.setIcon(QMessageBox::Warning); warnBox.exec(); if (m_InteractivePointSetNode.IsNotNull()) m_InteractivePointSetNode->SetProperty("color", mitk::ColorProperty::New(1,1,1)); StartStopTrackingGui(false); if (m_DeleteTrackingHandler) DeleteTrackingHandler(); UpdateGui(); return; } mitk::FiberBundle::Pointer fib = mitk::FiberBundle::New(fiberBundle); fib->SetTrackVisHeader(dynamic_cast(m_ParentNode->GetData())->GetGeometry()); if (m_Controls->m_ResampleFibersBox->isChecked() && fiberBundle->GetNumberOfLines()>0) fib->Compress(m_Controls->m_FiberErrorBox->value()); fib->ColorFibersByOrientation(); m_Tracker->SetDicomProperties(fib); mitk::DiffusionPropertyHelper::CopyDICOMProperties(m_ParentNode->GetData(), fib); if (m_Controls->m_InteractiveBox->isChecked()) { if (m_InteractiveNode.IsNull()) { m_InteractiveNode = mitk::DataNode::New(); QString name("Interactive"); m_InteractiveNode->SetName(name.toStdString()); GetDataStorage()->Add(m_InteractiveNode); } m_InteractiveNode->SetData(fib); m_InteractiveNode->SetFloatProperty("Fiber2DSliceThickness", params->GetMinVoxelSizeMm()/2); MITK_INFO << params->GetMinVoxelSizeMm()/2; if (auto renderWindowPart = this->GetRenderWindowPart()) renderWindowPart->RequestUpdate(); } else { mitk::DataNode::Pointer node = mitk::DataNode::New(); node->SetData(fib); QString name("FiberBundle_"); name += m_ParentNode->GetName().c_str(); name += "_Streamline"; node->SetName(name.toStdString()); node->SetFloatProperty("Fiber2DSliceThickness", params->GetMinVoxelSizeMm()/2); GetDataStorage()->Add(node, m_ParentNode); } } else { TrackerType::ItkDoubleImgType::Pointer outImg = m_Tracker->GetOutputProbabilityMap(); mitk::Image::Pointer img = mitk::Image::New(); img->InitializeByItk(outImg.GetPointer()); img->SetVolume(outImg->GetBufferPointer()); mitk::DiffusionPropertyHelper::CopyDICOMProperties(m_ParentNode->GetData(), img); if (m_Controls->m_InteractiveBox->isChecked()) { if (m_InteractiveNode.IsNull()) { m_InteractiveNode = mitk::DataNode::New(); QString name("Interactive"); m_InteractiveNode->SetName(name.toStdString()); GetDataStorage()->Add(m_InteractiveNode); } m_InteractiveNode->SetData(img); mitk::LookupTable::Pointer lut = mitk::LookupTable::New(); lut->SetType(mitk::LookupTable::JET_TRANSPARENT); mitk::LookupTableProperty::Pointer lut_prop = mitk::LookupTableProperty::New(); lut_prop->SetLookupTable(lut); m_InteractiveNode->SetProperty("LookupTable", lut_prop); m_InteractiveNode->SetProperty("opacity", mitk::FloatProperty::New(0.5)); m_InteractiveNode->SetFloatProperty("Fiber2DSliceThickness", params->GetMinVoxelSizeMm()/2); if (auto renderWindowPart = this->GetRenderWindowPart()) renderWindowPart->RequestUpdate(); } else { mitk::DataNode::Pointer node = mitk::DataNode::New(); node->SetData(img); QString name("ProbabilityMap_"); name += m_ParentNode->GetName().c_str(); node->SetName(name.toStdString()); mitk::LookupTable::Pointer lut = mitk::LookupTable::New(); lut->SetType(mitk::LookupTable::JET_TRANSPARENT); mitk::LookupTableProperty::Pointer lut_prop = mitk::LookupTableProperty::New(); lut_prop->SetLookupTable(lut); node->SetProperty("LookupTable", lut_prop); node->SetProperty("opacity", mitk::FloatProperty::New(0.5)); GetDataStorage()->Add(node, m_ParentNode); } } if (m_InteractivePointSetNode.IsNotNull()) m_InteractivePointSetNode->SetProperty("color", mitk::ColorProperty::New(1,1,1)); StartStopTrackingGui(false); if (m_DeleteTrackingHandler) DeleteTrackingHandler(); UpdateGui(); } void QmitkStreamlineTrackingView::InteractiveSeedChanged(bool posChanged) { if(!CheckAndStoreLastParams(sender()) && !posChanged) return; if (m_ThreadIsRunning || !m_Visible) return; if (!posChanged && (!m_Controls->m_InteractiveBox->isChecked() || !m_Controls->m_ParamUpdateBox->isChecked()) ) return; std::srand(std::time(0)); m_SeedPoints.clear(); itk::Point world_pos = this->GetRenderWindowPart()->GetSelectedPosition(); m_SeedPoints.push_back(world_pos); float radius = m_Controls->m_SeedRadiusBox->value(); int num = m_Controls->m_NumSeedsBox->value(); mitk::PointSet::Pointer pointset = mitk::PointSet::New(); pointset->InsertPoint(0, world_pos); m_InteractivePointSetNode->SetProperty("pointsize", mitk::FloatProperty::New(radius*2)); m_InteractivePointSetNode->SetProperty("point 2D size", mitk::FloatProperty::New(radius*2)); m_InteractivePointSetNode->SetData(pointset); for (int i=1; i p; p[0] = rand()%1000-500; p[1] = rand()%1000-500; p[2] = rand()%1000-500; p.Normalize(); p *= radius; m_SeedPoints.push_back(world_pos+p); } m_InteractivePointSetNode->SetProperty("color", mitk::ColorProperty::New(1,0,0)); DoFiberTracking(); } bool QmitkStreamlineTrackingView::CheckAndStoreLastParams(QObject* obj) { if (obj!=nullptr) { std::string new_val = ""; if(qobject_cast(obj)!=nullptr) new_val = boost::lexical_cast(qobject_cast(obj)->value()); else if (qobject_cast(obj)!=nullptr) new_val = boost::lexical_cast(qobject_cast(obj)->value()); else return true; if (m_LastTractoParams.find(obj->objectName())==m_LastTractoParams.end()) { m_LastTractoParams[obj->objectName()] = new_val; return false; } else if (m_LastTractoParams.at(obj->objectName()) != new_val) { m_LastTractoParams[obj->objectName()] = new_val; return true; } else if (m_LastTractoParams.at(obj->objectName()) == new_val) return false; } return true; } void QmitkStreamlineTrackingView::OnParameterChanged() { UpdateGui(); if(!CheckAndStoreLastParams(sender())) return; if (m_Controls->m_InteractiveBox->isChecked() && m_Controls->m_ParamUpdateBox->isChecked()) DoFiberTracking(); } void QmitkStreamlineTrackingView::ToggleInteractive() { UpdateGui(); m_Controls->m_SeedsPerVoxelBox->setEnabled(!m_Controls->m_InteractiveBox->isChecked()); m_Controls->m_SeedsPerVoxelLabel->setEnabled(!m_Controls->m_InteractiveBox->isChecked()); m_Controls->m_SeedImageSelectionWidget->setEnabled(!m_Controls->m_InteractiveBox->isChecked()); m_Controls->label_6->setEnabled(!m_Controls->m_InteractiveBox->isChecked()); if ( m_Controls->m_InteractiveBox->isChecked() ) { if (m_FirstInteractiveRun) { QMessageBox::information(nullptr, "Information", "Place and move a spherical seed region anywhere in the image by left-clicking and dragging. If the seed region is colored red, tracking is in progress. If the seed region is colored white, tracking is finished.\nPlacing the seed region for the first time in a newly selected dataset might cause a short delay, since the tracker needs to be initialized."); m_FirstInteractiveRun = false; } QApplication::setOverrideCursor(Qt::PointingHandCursor); QApplication::processEvents(); m_InteractivePointSetNode = mitk::DataNode::New(); m_InteractivePointSetNode->SetProperty("color", mitk::ColorProperty::New(1,1,1)); m_InteractivePointSetNode->SetName("InteractiveSeedRegion"); mitk::PointSetShapeProperty::Pointer shape_prop = mitk::PointSetShapeProperty::New(); shape_prop->SetValue(mitk::PointSetShapeProperty::PointSetShape::CIRCLE); m_InteractivePointSetNode->SetProperty("Pointset.2D.shape", shape_prop); GetDataStorage()->Add(m_InteractivePointSetNode); m_SliceChangeListener.RenderWindowPartActivated(this->GetRenderWindowPart()); connect(&m_SliceChangeListener, SIGNAL(SliceChanged()), this, SLOT(OnSliceChanged())); } else { QApplication::restoreOverrideCursor(); QApplication::processEvents(); m_InteractiveNode = nullptr; m_InteractivePointSetNode = nullptr; m_SliceChangeListener.RenderWindowPartActivated(this->GetRenderWindowPart()); disconnect(&m_SliceChangeListener, SIGNAL(SliceChanged()), this, SLOT(OnSliceChanged())); } } void QmitkStreamlineTrackingView::Activated() { } void QmitkStreamlineTrackingView::Deactivated() { } void QmitkStreamlineTrackingView::Visible() { m_Visible = true; } void QmitkStreamlineTrackingView::Hidden() { m_Visible = false; m_Controls->m_InteractiveBox->setChecked(false); ToggleInteractive(); } void QmitkStreamlineTrackingView::OnSliceChanged() { InteractiveSeedChanged(true); } void QmitkStreamlineTrackingView::SetFocus() { } void QmitkStreamlineTrackingView::DeleteTrackingHandler() { if (!m_ThreadIsRunning && m_TrackingHandler != nullptr) { if (m_TrackingPriorHandler != nullptr) { delete m_TrackingPriorHandler; m_TrackingPriorHandler = nullptr; } delete m_TrackingHandler; m_TrackingHandler = nullptr; m_DeleteTrackingHandler = false; m_LastPrior = nullptr; } else if (m_ThreadIsRunning) { m_DeleteTrackingHandler = true; } } void QmitkStreamlineTrackingView::ForestSwitched() { DeleteTrackingHandler(); } void QmitkStreamlineTrackingView::OutputStyleSwitched() { if (m_InteractiveNode.IsNotNull()) GetDataStorage()->Remove(m_InteractiveNode); m_InteractiveNode = nullptr; } void QmitkStreamlineTrackingView::OnSelectionChanged( berry::IWorkbenchPart::Pointer , const QList& nodes ) { std::vector< mitk::DataNode::Pointer > last_nodes = m_InputImageNodes; m_InputImageNodes.clear(); m_AdditionalInputImages.clear(); bool retrack = false; for( auto node : nodes ) { if( node.IsNotNull() && dynamic_cast(node->GetData()) ) { if( dynamic_cast(node->GetData()) || dynamic_cast(node->GetData()) || dynamic_cast(node->GetData()) || dynamic_cast(node->GetData()) || mitk::DiffusionPropertyHelper::IsDiffusionWeightedImage( dynamic_cast(node->GetData()))) { m_InputImageNodes.push_back(node); retrack = true; } else { mitk::Image* img = dynamic_cast(node->GetData()); if (img!=nullptr && img->GetDimension()==3) m_AdditionalInputImages.push_back(dynamic_cast(node->GetData())); } } } // sometimes the OnSelectionChanged event is sent twice and actually no selection has changed for the first event. We need to catch that. if (last_nodes.size() == m_InputImageNodes.size()) { bool same_nodes = true; for (unsigned int i=0; im_TensorImageLabel->setText("select in data-manager"); m_Controls->m_fBox->setEnabled(false); m_Controls->m_fLabel->setEnabled(false); m_Controls->m_gBox->setEnabled(false); m_Controls->m_gLabel->setEnabled(false); m_Controls->m_FaImageSelectionWidget->setEnabled(true); m_Controls->mFaImageLabel->setEnabled(true); m_Controls->m_OdfCutoffBox->setEnabled(false); m_Controls->m_OdfCutoffLabel->setEnabled(false); m_Controls->m_SharpenOdfsBox->setEnabled(false); m_Controls->m_ForestSelectionWidget->setVisible(false); m_Controls->m_ForestLabel->setVisible(false); m_Controls->commandLinkButton->setEnabled(false); m_Controls->m_TrialsPerSeedBox->setEnabled(false); m_Controls->m_TrialsPerSeedLabel->setEnabled(false); m_Controls->m_TargetImageSelectionWidget->setEnabled(false); m_Controls->m_TargetImageLabel->setEnabled(false); m_Controls->m_PeakJitterBox->setEnabled(false); if (m_Controls->m_InteractiveBox->isChecked()) { m_Controls->m_InteractiveSeedingFrame->setVisible(true); m_Controls->m_StaticSeedingFrame->setVisible(false); m_Controls->commandLinkButton_2->setVisible(false); m_Controls->commandLinkButton->setVisible(false); } else { m_Controls->m_InteractiveSeedingFrame->setVisible(false); m_Controls->m_StaticSeedingFrame->setVisible(true); m_Controls->commandLinkButton_2->setVisible(m_ThreadIsRunning); m_Controls->commandLinkButton->setVisible(!m_ThreadIsRunning); } if (m_Controls->m_EpConstraintsBox->currentIndex()>0) { m_Controls->m_TargetImageSelectionWidget->setEnabled(true); m_Controls->m_TargetImageLabel->setEnabled(true); } // stuff that is only important for probabilistic tractography if (m_Controls->m_ModeBox->currentIndex()==1) { m_Controls->m_TrialsPerSeedBox->setEnabled(true); m_Controls->m_TrialsPerSeedLabel->setEnabled(true); m_Controls->m_PeakJitterBox->setEnabled(true); } if(!m_InputImageNodes.empty()) { if (m_InputImageNodes.size()>1) m_Controls->m_TensorImageLabel->setText( ( std::to_string(m_InputImageNodes.size()) + " images selected").c_str() ); else m_Controls->m_TensorImageLabel->setText(m_InputImageNodes.at(0)->GetName().c_str()); m_Controls->commandLinkButton->setEnabled(!m_Controls->m_InteractiveBox->isChecked() && !m_ThreadIsRunning); m_Controls->m_ScalarThresholdBox->setEnabled(true); m_Controls->m_FaThresholdLabel->setEnabled(true); if ( dynamic_cast(m_InputImageNodes.at(0)->GetData()) ) { m_Controls->m_fBox->setEnabled(true); m_Controls->m_fLabel->setEnabled(true); m_Controls->m_gBox->setEnabled(true); m_Controls->m_gLabel->setEnabled(true); } else if ( dynamic_cast(m_InputImageNodes.at(0)->GetData()) || dynamic_cast(m_InputImageNodes.at(0)->GetData())) { m_Controls->m_OdfCutoffBox->setEnabled(true); m_Controls->m_OdfCutoffLabel->setEnabled(true); m_Controls->m_SharpenOdfsBox->setEnabled(true); } else if ( mitk::DiffusionPropertyHelper::IsDiffusionWeightedImage( dynamic_cast(m_InputImageNodes.at(0)->GetData())) ) { m_Controls->m_ForestSelectionWidget->setVisible(true); m_Controls->m_ForestLabel->setVisible(true); m_Controls->m_ScalarThresholdBox->setEnabled(false); m_Controls->m_FaThresholdLabel->setEnabled(false); } } } void QmitkStreamlineTrackingView::StartStopTrackingGui(bool start) { m_ThreadIsRunning = start; if (!m_Controls->m_InteractiveBox->isChecked()) { m_Controls->commandLinkButton_2->setVisible(start); m_Controls->commandLinkButton->setVisible(!start); m_Controls->m_InteractiveBox->setEnabled(!start); m_Controls->m_StatusTextBox->setVisible(start); } } void QmitkStreamlineTrackingView::DoFiberTracking() { auto params = GetParametersFromGui(); if (m_InputImageNodes.empty()) { QMessageBox::information(nullptr, "Information", "Please select an input image in the datamaneger (tensor, ODF, peak or dMRI image)!"); return; } if (m_ThreadIsRunning || !m_Visible) return; if (m_Controls->m_InteractiveBox->isChecked() && m_SeedPoints.empty()) return; StartStopTrackingGui(true); m_Tracker = TrackerType::New(); if (params->m_EpConstraints == itk::StreamlineTrackingFilter::EndpointConstraints::NONE) m_Tracker->SetTargetRegions(nullptr); if( dynamic_cast(m_InputImageNodes.at(0)->GetData()) ) { if (m_Controls->m_ModeBox->currentIndex()==1) { if (m_InputImageNodes.size()>1) { QMessageBox::information(nullptr, "Information", "Probabilistic tensor tractography is only implemented for single-tensor mode!"); StartStopTrackingGui(false); return; } if (m_TrackingHandler==nullptr) { m_TrackingHandler = new mitk::TrackingHandlerOdf(); typedef itk::TensorImageToOdfImageFilter< float, float > FilterType; FilterType::Pointer filter = FilterType::New(); filter->SetInput( mitk::convert::GetItkTensorFromTensorImage(dynamic_cast(m_InputImageNodes.at(0)->GetData())) ); filter->Update(); dynamic_cast(m_TrackingHandler)->SetOdfImage(filter->GetOutput()); if (m_Controls->m_FaImageSelectionWidget->GetSelectedNode().IsNotNull()) { ItkFloatImageType::Pointer itkImg = ItkFloatImageType::New(); mitk::CastToItkImage(dynamic_cast(m_Controls->m_FaImageSelectionWidget->GetSelectedNode()->GetData()), itkImg); dynamic_cast(m_TrackingHandler)->SetGfaImage(itkImg); } } dynamic_cast(m_TrackingHandler)->SetIsOdfFromTensor(true); } else { if (m_TrackingHandler==nullptr) { m_TrackingHandler = new mitk::TrackingHandlerTensor(); for (unsigned int i=0; i(m_TrackingHandler)->AddTensorImage(mitk::convert::GetItkTensorFromTensorImage(dynamic_cast(m_InputImageNodes.at(i)->GetData())).GetPointer()); if (m_Controls->m_FaImageSelectionWidget->GetSelectedNode().IsNotNull()) { ItkFloatImageType::Pointer itkImg = ItkFloatImageType::New(); mitk::CastToItkImage(dynamic_cast(m_Controls->m_FaImageSelectionWidget->GetSelectedNode()->GetData()), itkImg); dynamic_cast(m_TrackingHandler)->SetFaImage(itkImg); } } } } else if ( dynamic_cast(m_InputImageNodes.at(0)->GetData()) || dynamic_cast(m_InputImageNodes.at(0)->GetData())) { if (m_TrackingHandler==nullptr) { m_TrackingHandler = new mitk::TrackingHandlerOdf(); if (dynamic_cast(m_InputImageNodes.at(0)->GetData())) dynamic_cast(m_TrackingHandler)->SetOdfImage(mitk::convert::GetItkOdfFromShImage(dynamic_cast(m_InputImageNodes.at(0)->GetData()))); else dynamic_cast(m_TrackingHandler)->SetOdfImage(mitk::convert::GetItkOdfFromOdfImage(dynamic_cast(m_InputImageNodes.at(0)->GetData()))); if (m_Controls->m_FaImageSelectionWidget->GetSelectedNode().IsNotNull()) { ItkFloatImageType::Pointer itkImg = ItkFloatImageType::New(); mitk::CastToItkImage(dynamic_cast(m_Controls->m_FaImageSelectionWidget->GetSelectedNode()->GetData()), itkImg); dynamic_cast(m_TrackingHandler)->SetGfaImage(itkImg); } } } else if ( mitk::DiffusionPropertyHelper::IsDiffusionWeightedImage( dynamic_cast(m_InputImageNodes.at(0)->GetData())) ) { if ( m_Controls->m_ForestSelectionWidget->GetSelectedNode().IsNull() ) { QMessageBox::information(nullptr, "Information", "Not random forest for machine learning based tractography (raw dMRI tractography) selected. Did you accidentally select the raw diffusion-weighted image in the datamanager?"); StartStopTrackingGui(false); return; } if (m_TrackingHandler==nullptr) { mitk::TractographyForest::Pointer forest = dynamic_cast(m_Controls->m_ForestSelectionWidget->GetSelectedNode()->GetData()); mitk::Image::Pointer dwi = dynamic_cast(m_InputImageNodes.at(0)->GetData()); std::vector< std::vector< ItkFloatImageType::Pointer > > additionalFeatureImages; additionalFeatureImages.push_back(std::vector< ItkFloatImageType::Pointer >()); for (auto img : m_AdditionalInputImages) { ItkFloatImageType::Pointer itkimg = ItkFloatImageType::New(); mitk::CastToItkImage(img, itkimg); additionalFeatureImages.at(0).push_back(itkimg); } bool forest_valid = false; if (forest->GetNumFeatures()>=100) { params->m_NumPreviousDirections = static_cast((forest->GetNumFeatures() - (100 + additionalFeatureImages.at(0).size()))/3); m_TrackingHandler = new mitk::TrackingHandlerRandomForest<6, 100>(); dynamic_cast*>(m_TrackingHandler)->AddDwi(dwi); dynamic_cast*>(m_TrackingHandler)->SetAdditionalFeatureImages(additionalFeatureImages); dynamic_cast*>(m_TrackingHandler)->SetForest(forest); forest_valid = dynamic_cast*>(m_TrackingHandler)->IsForestValid(); } else { params->m_NumPreviousDirections = static_cast((forest->GetNumFeatures() - (28 + additionalFeatureImages.at(0).size()))/3); m_TrackingHandler = new mitk::TrackingHandlerRandomForest<6, 28>(); dynamic_cast*>(m_TrackingHandler)->AddDwi(dwi); dynamic_cast*>(m_TrackingHandler)->SetAdditionalFeatureImages(additionalFeatureImages); dynamic_cast*>(m_TrackingHandler)->SetForest(forest); forest_valid = dynamic_cast*>(m_TrackingHandler)->IsForestValid(); } if (!forest_valid) { QMessageBox::information(nullptr, "Information", "Random forest is invalid. The forest signatue does not match the parameters of TrackingHandlerRandomForest."); StartStopTrackingGui(false); return; } } } else { if (m_TrackingHandler==nullptr) { m_TrackingHandler = new mitk::TrackingHandlerPeaks(); dynamic_cast(m_TrackingHandler)->SetPeakImage(mitk::convert::GetItkPeakFromPeakImage(dynamic_cast(m_InputImageNodes.at(0)->GetData()))); } } if (m_Controls->m_InteractiveBox->isChecked()) { m_Tracker->SetSeedPoints(m_SeedPoints); } else if (m_Controls->m_SeedImageSelectionWidget->GetSelectedNode().IsNotNull()) { ItkFloatImageType::Pointer mask = ItkFloatImageType::New(); mitk::CastToItkImage(dynamic_cast(m_Controls->m_SeedImageSelectionWidget->GetSelectedNode()->GetData()), mask); m_Tracker->SetSeedImage(mask); } if (m_Controls->m_MaskImageSelectionWidget->GetSelectedNode().IsNotNull()) { ItkFloatImageType::Pointer mask = ItkFloatImageType::New(); mitk::CastToItkImage(dynamic_cast(m_Controls->m_MaskImageSelectionWidget->GetSelectedNode()->GetData()), mask); m_Tracker->SetMaskImage(mask); } if (m_Controls->m_StopImageSelectionWidget->GetSelectedNode().IsNotNull()) { ItkFloatImageType::Pointer mask = ItkFloatImageType::New(); mitk::CastToItkImage(dynamic_cast(m_Controls->m_StopImageSelectionWidget->GetSelectedNode()->GetData()), mask); m_Tracker->SetStoppingRegions(mask); } if (m_Controls->m_TargetImageSelectionWidget->GetSelectedNode().IsNotNull()) { ItkFloatImageType::Pointer mask = ItkFloatImageType::New(); mitk::CastToItkImage(dynamic_cast(m_Controls->m_TargetImageSelectionWidget->GetSelectedNode()->GetData()), mask); m_Tracker->SetTargetRegions(mask); } if (m_Controls->m_PriorImageSelectionWidget->GetSelectedNode().IsNotNull()) { auto prior_params = GetParametersFromGui(); if (m_LastPrior!=m_Controls->m_PriorImageSelectionWidget->GetSelectedNode() || m_TrackingPriorHandler==nullptr) { typedef mitk::ImageToItk< mitk::TrackingHandlerPeaks::PeakImgType > CasterType; CasterType::Pointer caster = CasterType::New(); caster->SetInput(dynamic_cast(m_Controls->m_PriorImageSelectionWidget->GetSelectedNode()->GetData())); caster->SetCopyMemFlag(true); caster->Update(); mitk::TrackingHandlerPeaks::PeakImgType::Pointer itkImg = caster->GetOutput(); m_TrackingPriorHandler = new mitk::TrackingHandlerPeaks(); dynamic_cast(m_TrackingPriorHandler)->SetPeakImage(itkImg); m_LastPrior = m_Controls->m_PriorImageSelectionWidget->GetSelectedNode(); } prior_params->m_FlipX = m_Controls->m_PriorFlipXBox->isChecked(); prior_params->m_FlipY = m_Controls->m_PriorFlipYBox->isChecked(); prior_params->m_FlipZ = m_Controls->m_PriorFlipZBox->isChecked(); m_TrackingPriorHandler->SetParameters(prior_params); m_Tracker->SetTrackingPriorHandler(m_TrackingPriorHandler); } else if (m_Controls->m_PriorImageSelectionWidget->GetSelectedNode().IsNull()) m_Tracker->SetTrackingPriorHandler(nullptr); if (m_Controls->m_ExclusionImageSelectionWidget->GetSelectedNode().IsNotNull()) { ItkFloatImageType::Pointer mask = ItkFloatImageType::New(); mitk::CastToItkImage(dynamic_cast(m_Controls->m_ExclusionImageSelectionWidget->GetSelectedNode()->GetData()), mask); m_Tracker->SetExclusionRegions(mask); } if (params->m_EpConstraints!=itk::StreamlineTrackingFilter::EndpointConstraints::NONE && m_Controls->m_TargetImageSelectionWidget->GetSelectedNode().IsNull()) { QMessageBox::information(nullptr, "Error", "Endpoint constraints are used but no target image is set!"); StartStopTrackingGui(false); return; } else if (params->m_EpConstraints==itk::StreamlineTrackingFilter::EndpointConstraints::EPS_IN_SEED_AND_TARGET && (m_Controls->m_SeedImageSelectionWidget->GetSelectedNode().IsNull()|| m_Controls->m_TargetImageSelectionWidget->GetSelectedNode().IsNull()) ) { QMessageBox::information(nullptr, "Error", "Endpoint constraint EPS_IN_SEED_AND_TARGET is used but no target or no seed image is set!"); StartStopTrackingGui(false); return; } auto spacing = dynamic_cast(m_InputImageNodes.at(0)->GetData())->GetGeometry()->GetSpacing(); params->SetMinVoxelSizeMm(spacing[0]); if (spacing[1] < params->GetMinVoxelSizeMm()) params->SetMinVoxelSizeMm(spacing[1]); if (spacing[2] < params->GetMinVoxelSizeMm()) params->SetMinVoxelSizeMm(spacing[2]); m_Tracker->SetParameters(params); m_Tracker->SetTrackingHandler(m_TrackingHandler); m_Tracker->SetVerbose(!m_Controls->m_InteractiveBox->isChecked()); m_ParentNode = m_InputImageNodes.at(0); m_TrackingThread.start(QThread::LowestPriority); }