diff --git a/Modules/ContourModel/Algorithms/mitkContourModelUtils.cpp b/Modules/ContourModel/Algorithms/mitkContourModelUtils.cpp index f96f7a385e..c3ea18a797 100755 --- a/Modules/ContourModel/Algorithms/mitkContourModelUtils.cpp +++ b/Modules/ContourModel/Algorithms/mitkContourModelUtils.cpp @@ -1,238 +1,238 @@ /*============================================================================ The Medical Imaging Interaction Toolkit (MITK) Copyright (c) German Cancer Research Center (DKFZ) All rights reserved. Use of this source code is governed by a 3-clause BSD license that can be found in the LICENSE file. ============================================================================*/ #include #include #include #include #include #include #include #include mitk::ContourModelUtils::ContourModelUtils() { } mitk::ContourModelUtils::~ContourModelUtils() { } mitk::ContourModel::Pointer mitk::ContourModelUtils::ProjectContourTo2DSlice( const Image *slice, const ContourModel *contourIn3D, bool, bool) { if (nullptr == slice || nullptr == contourIn3D) return nullptr; auto projectedContour = ContourModel::New(); projectedContour->Initialize(*contourIn3D); auto sliceGeometry = slice->GetGeometry(); - auto numberOfTimesteps = static_cast(contourIn3D->GetTimeSteps()); + const auto numberOfTimesteps = static_cast(contourIn3D->GetTimeSteps()); - for (decltype(numberOfTimesteps) t = 0; t < numberOfTimesteps; ++t) + for (std::remove_const_t t = 0; t < numberOfTimesteps; ++t) { auto iter = contourIn3D->Begin(t); auto end = contourIn3D->End(t); while (iter != end) { const auto ¤tPointIn3D = (*iter)->Coordinates; Point3D projectedPointIn2D; projectedPointIn2D.Fill(0.0); sliceGeometry->WorldToIndex(currentPointIn3D, projectedPointIn2D); projectedContour->AddVertex(projectedPointIn2D, t); ++iter; } } return projectedContour; } mitk::ContourModel::Pointer mitk::ContourModelUtils::BackProjectContourFrom2DSlice( const BaseGeometry *sliceGeometry, const ContourModel *contourIn2D, bool) { if (nullptr == sliceGeometry || nullptr == contourIn2D) return nullptr; auto worldContour = ContourModel::New(); worldContour->Initialize(*contourIn2D); - auto numberOfTimesteps = static_cast(contourIn2D->GetTimeSteps()); + const auto numberOfTimesteps = static_cast(contourIn2D->GetTimeSteps()); - for (decltype(numberOfTimesteps) t = 0; t < numberOfTimesteps; ++t) + for (std::remove_const_t t = 0; t < numberOfTimesteps; ++t) { auto iter = contourIn2D->Begin(t); auto end = contourIn2D->End(t); while (iter != end) { const auto ¤tPointIn2D = (*iter)->Coordinates; Point3D worldPointIn3D; worldPointIn3D.Fill(0.0); sliceGeometry->IndexToWorld(currentPointIn2D, worldPointIn3D); worldContour->AddVertex(worldPointIn3D, t); ++iter; } } return worldContour; } void mitk::ContourModelUtils::FillContourInSlice( const ContourModel *projectedContour, Image *sliceImage, const Image* workingImage, int paintingPixelValue) { FillContourInSlice(projectedContour, 0, sliceImage, workingImage, paintingPixelValue); } void mitk::ContourModelUtils::FillContourInSlice( const ContourModel *projectedContour, TimeStepType contourTimeStep, Image *sliceImage, const Image* workingImage, int paintingPixelValue) { if (nullptr == projectedContour) { mitkThrow() << "Cannot fill contour in slice. Passed contour is invalid"; } if (nullptr == sliceImage) { mitkThrow() << "Cannot fill contour in slice. Passed slice is invalid"; } auto contourModelFilter = mitk::ContourModelToSurfaceFilter::New(); contourModelFilter->SetInput(projectedContour); contourModelFilter->Update(); auto surface = mitk::Surface::New(); surface = contourModelFilter->GetOutput(); if (nullptr == surface->GetVtkPolyData(contourTimeStep)) { MITK_WARN << "Could not create surface from contour model."; return; } auto surface2D = vtkSmartPointer::New(); surface2D->SetPoints(surface->GetVtkPolyData(contourTimeStep)->GetPoints()); surface2D->SetLines(surface->GetVtkPolyData(contourTimeStep)->GetLines()); auto image = vtkSmartPointer::New(); image->DeepCopy(sliceImage->GetVtkImageData()); const double FOREGROUND_VALUE = 255.0; const double BACKGROUND_VALUE = 0.0; - vtkIdType count = image->GetNumberOfPoints(); - for (decltype(count) i = 0; i < count; ++i) + const vtkIdType count = image->GetNumberOfPoints(); + for (std::remove_const_t i = 0; i < count; ++i) image->GetPointData()->GetScalars()->SetTuple1(i, FOREGROUND_VALUE); auto polyDataToImageStencil = vtkSmartPointer::New(); // Set a minimal tolerance, so that clipped pixels will be added to contour as well. polyDataToImageStencil->SetTolerance(mitk::eps); polyDataToImageStencil->SetInputData(surface2D); polyDataToImageStencil->Update(); auto imageStencil = vtkSmartPointer::New(); imageStencil->SetInputData(image); imageStencil->SetStencilConnection(polyDataToImageStencil->GetOutputPort()); imageStencil->ReverseStencilOff(); imageStencil->SetBackgroundValue(BACKGROUND_VALUE); imageStencil->Update(); vtkSmartPointer filledImage = imageStencil->GetOutput(); vtkSmartPointer resultImage = sliceImage->GetVtkImageData(); FillSliceInSlice(filledImage, resultImage, workingImage, paintingPixelValue); sliceImage->SetVolume(resultImage->GetScalarPointer()); } void mitk::ContourModelUtils::FillSliceInSlice( - vtkSmartPointer filledImage, vtkSmartPointer resultImage, const Image* image, int paintingPixelValue) + vtkSmartPointer filledImage, vtkSmartPointer resultImage, const Image* image, int paintingPixelValue, double fillForegroundThreshold) { auto labelImage = dynamic_cast(image); - auto numberOfPoints = filledImage->GetNumberOfPoints(); + const auto numberOfPoints = filledImage->GetNumberOfPoints(); if (nullptr == labelImage) { - for (decltype(numberOfPoints) i = 0; i < numberOfPoints; ++i) + for (std::remove_const_t i = 0; i < numberOfPoints; ++i) { - if (1 < filledImage->GetPointData()->GetScalars()->GetTuple1(i)) + if (fillForegroundThreshold <= filledImage->GetPointData()->GetScalars()->GetTuple1(i)) resultImage->GetPointData()->GetScalars()->SetTuple1(i, paintingPixelValue); } } else { - auto backgroundValue = labelImage->GetExteriorLabel()->GetValue(); + const auto backgroundValue = labelImage->GetExteriorLabel()->GetValue(); if (paintingPixelValue != backgroundValue) { - for (decltype(numberOfPoints) i = 0; i < numberOfPoints; ++i) + for (std::remove_const_t i = 0; i < numberOfPoints; ++i) { - if (1 < filledImage->GetPointData()->GetScalars()->GetTuple1(i)) + const auto filledValue = filledImage->GetPointData()->GetScalars()->GetTuple1(i); + if (fillForegroundThreshold <= filledValue) { - auto existingValue = resultImage->GetPointData()->GetScalars()->GetTuple1(i); + const auto existingValue = resultImage->GetPointData()->GetScalars()->GetTuple1(i); if (!labelImage->GetLabel(existingValue, labelImage->GetActiveLayer())->GetLocked()) resultImage->GetPointData()->GetScalars()->SetTuple1(i, paintingPixelValue); } } } else { - auto activePixelValue = labelImage->GetActiveLabel(labelImage->GetActiveLayer())->GetValue(); - - for (decltype(numberOfPoints) i = 0; i < numberOfPoints; ++i) + const auto activePixelValue = labelImage->GetActiveLabel(labelImage->GetActiveLayer())->GetValue(); + for (std::remove_const_t i = 0; i < numberOfPoints; ++i) { - if (1 < filledImage->GetPointData()->GetScalars()->GetTuple1(i)) + if (fillForegroundThreshold <= filledImage->GetPointData()->GetScalars()->GetTuple1(i)) { if (resultImage->GetPointData()->GetScalars()->GetTuple1(i) == activePixelValue) resultImage->GetPointData()->GetScalars()->SetTuple1(i, paintingPixelValue); } } } } } mitk::ContourModel::Pointer mitk::ContourModelUtils::MoveZerothContourTimeStep(const ContourModel *contour, TimeStepType t) { if (nullptr == contour) return nullptr; auto resultContour = ContourModel::New(); resultContour->Expand(t + 1); std::for_each(contour->Begin(), contour->End(), [&resultContour, t](ContourElement::VertexType *vertex) { resultContour->AddVertex(*vertex, t); }); return resultContour; } int mitk::ContourModelUtils::GetActivePixelValue(const Image* workingImage) { auto labelSetImage = dynamic_cast(workingImage); int activePixelValue = 1; if (nullptr != labelSetImage) { activePixelValue = labelSetImage->GetActiveLabel(labelSetImage->GetActiveLayer())->GetValue(); } return activePixelValue; } diff --git a/Modules/ContourModel/Algorithms/mitkContourModelUtils.h b/Modules/ContourModel/Algorithms/mitkContourModelUtils.h index cfc364b9df..b43386aefb 100644 --- a/Modules/ContourModel/Algorithms/mitkContourModelUtils.h +++ b/Modules/ContourModel/Algorithms/mitkContourModelUtils.h @@ -1,113 +1,117 @@ /*============================================================================ The Medical Imaging Interaction Toolkit (MITK) Copyright (c) German Cancer Research Center (DKFZ) All rights reserved. Use of this source code is governed by a 3-clause BSD license that can be found in the LICENSE file. ============================================================================*/ #ifndef mitkContourModelUtils_h #define mitkContourModelUtils_h #include #include #include #include namespace mitk { /** * \brief Helpful methods for working with contours and images * * */ class MITKCONTOURMODEL_EXPORT ContourModelUtils : public itk::Object { public: mitkClassMacroItkParent(ContourModelUtils, itk::Object); /** \brief Projects a contour onto an image point by point. Converts from world to index coordinates. \param slice \param contourIn3D \param correctionForIpSegmentation adds 0.5 to x and y index coordinates (difference between ipSegmentation and MITK contours) \param constrainToInside */ static ContourModel::Pointer ProjectContourTo2DSlice(const Image *slice, const ContourModel *contourIn3D, bool correctionForIpSegmentation, bool constrainToInside); /** \brief Projects a slice index coordinates of a contour back into world coordinates. \param sliceGeometry \param contourIn2D \param correctionForIpSegmentation subtracts 0.5 to x and y index coordinates (difference between ipSegmentation and MITK contours) */ static ContourModel::Pointer BackProjectContourFrom2DSlice(const BaseGeometry *sliceGeometry, const ContourModel *contourIn2D, bool correctionForIpSegmentation = false); /** \brief Fill a contour in a 2D slice with a specified pixel value. This version always uses the contour of time step 0 and fills the image. \pre sliceImage points to a valid instance \pre projectedContour points to a valid instance */ static void FillContourInSlice(const ContourModel *projectedContour, Image *sliceImage, const Image* workingImage, int paintingPixelValue = 1); /** \brief Fill a contour in a 2D slice with a specified pixel value. This overloaded version uses the contour at the passed contourTimeStep to fill the passed image slice. \pre sliceImage points to a valid instance \pre projectedContour points to a valid instance */ static void FillContourInSlice(const ContourModel *projectedContour, TimeStepType contourTimeStep, Image *sliceImage, const Image* workingImage, int paintingPixelValue = 1); /** \brief Fills a image (filledImage) into another image (resultImage) by incorporating the rules of LabelSet-Images + \param paintingPixelValue the pixelvalue/label that should be used in the result image when filling. + \param fillForegroundThreshold The threshold value that decides if a pixel in the filled image counts + as foreground (>=fillForegroundThreshold) or not. */ static void FillSliceInSlice(vtkSmartPointer filledImage, vtkSmartPointer resultImage, const Image* image, - int paintingPixelValue); + int paintingPixelValue, + double fillForegroundThreshold = 1.0); /** \brief Move the contour in time step 0 to to a new contour model at the given time step. */ static ContourModel::Pointer MoveZerothContourTimeStep(const ContourModel *contour, TimeStepType timeStep); /** \brief Retrieves the active pixel value of a (labelset) image. If the image is basic image, the pixel value 1 (one) will be returned. If the image is actually a labelset image, the pixel value of the active label of the active layer will be returned. \param workingImage The (labelset) image to retrieve the active pixel value of. */ static int GetActivePixelValue(const Image* workingImage); protected: ContourModelUtils(); ~ContourModelUtils() override; }; } #endif diff --git a/Modules/Segmentation/Interactions/mitkSegTool2D.cpp b/Modules/Segmentation/Interactions/mitkSegTool2D.cpp index 57ddfb9e90..67a2b2e8d3 100644 --- a/Modules/Segmentation/Interactions/mitkSegTool2D.cpp +++ b/Modules/Segmentation/Interactions/mitkSegTool2D.cpp @@ -1,834 +1,757 @@ /*============================================================================ The Medical Imaging Interaction Toolkit (MITK) Copyright (c) German Cancer Research Center (DKFZ) All rights reserved. Use of this source code is governed by a 3-clause BSD license that can be found in the LICENSE file. ============================================================================*/ #include "mitkSegTool2D.h" #include "mitkToolManager.h" #include "mitkBaseRenderer.h" #include "mitkDataStorage.h" #include "mitkPlaneGeometry.h" // Include of the new ImageExtractor #include "mitkMorphologicalOperations.h" #include "mitkPlanarCircle.h" #include "usGetModuleContext.h" // Includes for 3DSurfaceInterpolation #include "mitkImageTimeSelector.h" #include "mitkImageToContourFilter.h" #include "mitkSurfaceInterpolationController.h" // includes for resling and overwriting #include #include #include #include #include "mitkOperationEvent.h" #include "mitkUndoController.h" #include #include "mitkAbstractTransformGeometry.h" #include "mitkLabelSetImage.h" #include "mitkContourModelUtils.h" #include "itkImageRegionIterator.h" #define ROUND(a) ((a) > 0 ? (int)((a) + 0.5) : -(int)(0.5 - (a))) bool mitk::SegTool2D::m_SurfaceInterpolationEnabled = true; mitk::SegTool2D::SliceInformation::SliceInformation(const mitk::Image* aSlice, const mitk::PlaneGeometry* aPlane, mitk::TimeStepType aTimestep) : slice(aSlice), plane(aPlane), timestep(aTimestep) { } mitk::SegTool2D::SegTool2D(const char *type, const us::Module *interactorModule) : Tool(type, interactorModule), m_Contourmarkername("Position") { Tool::m_EventConfig = "DisplayConfigMITKNoCrosshair.xml"; } mitk::SegTool2D::~SegTool2D() { } bool mitk::SegTool2D::FilterEvents(InteractionEvent *interactionEvent, DataNode *) { const auto *positionEvent = dynamic_cast(interactionEvent); bool isValidEvent = (positionEvent && // Only events of type mitk::InteractionPositionEvent interactionEvent->GetSender()->GetMapperID() == BaseRenderer::Standard2D // Only events from the 2D renderwindows ); return isValidEvent; } bool mitk::SegTool2D::DetermineAffectedImageSlice(const Image *image, const PlaneGeometry *plane, int &affectedDimension, int &affectedSlice) { assert(image); assert(plane); // compare normal of plane to the three axis vectors of the image Vector3D normal = plane->GetNormal(); Vector3D imageNormal0 = image->GetSlicedGeometry()->GetAxisVector(0); Vector3D imageNormal1 = image->GetSlicedGeometry()->GetAxisVector(1); Vector3D imageNormal2 = image->GetSlicedGeometry()->GetAxisVector(2); normal.Normalize(); imageNormal0.Normalize(); imageNormal1.Normalize(); imageNormal2.Normalize(); imageNormal0.SetVnlVector(vnl_cross_3d(normal.GetVnlVector(), imageNormal0.GetVnlVector())); imageNormal1.SetVnlVector(vnl_cross_3d(normal.GetVnlVector(), imageNormal1.GetVnlVector())); imageNormal2.SetVnlVector(vnl_cross_3d(normal.GetVnlVector(), imageNormal2.GetVnlVector())); double eps(0.00001); // axial if (imageNormal2.GetNorm() <= eps) { affectedDimension = 2; } // sagittal else if (imageNormal1.GetNorm() <= eps) { affectedDimension = 1; } // frontal else if (imageNormal0.GetNorm() <= eps) { affectedDimension = 0; } else { affectedDimension = -1; // no idea return false; } // determine slice number in image BaseGeometry *imageGeometry = image->GetGeometry(0); Point3D testPoint = imageGeometry->GetCenter(); Point3D projectedPoint; plane->Project(testPoint, projectedPoint); Point3D indexPoint; imageGeometry->WorldToIndex(projectedPoint, indexPoint); affectedSlice = ROUND(indexPoint[affectedDimension]); MITK_DEBUG << "indexPoint " << indexPoint << " affectedDimension " << affectedDimension << " affectedSlice " << affectedSlice; // check if this index is still within the image if (affectedSlice < 0 || affectedSlice >= static_cast(image->GetDimension(affectedDimension))) return false; return true; } void mitk::SegTool2D::UpdateSurfaceInterpolation(const Image *slice, const Image *workingImage, const PlaneGeometry *plane, bool detectIntersection) { std::vector slices = { SliceInformation(slice, plane, 0)}; Self::UpdateSurfaceInterpolation(slices, workingImage, detectIntersection); } void mitk::SegTool2D::RemoveContourFromInterpolator(const SliceInformation& sliceInfo) { mitk::SurfaceInterpolationController::ContourPositionInformation contourInfo; contourInfo.contourNormal = sliceInfo.plane->GetNormal(); contourInfo.contourPoint = sliceInfo.plane->GetOrigin(); mitk::SurfaceInterpolationController::GetInstance()->RemoveContour(contourInfo); } void mitk::SegTool2D::UpdateSurfaceInterpolation(const std::vector& sliceInfos, const Image* workingImage, bool detectIntersection) { if (!m_SurfaceInterpolationEnabled) return; //Remark: the ImageTimeSelector is just needed to extract a timestep/channel of //the image in order to get the image dimension (time dimension and channel dimension //stripped away). Therfore it is OK to always use time step 0 and channel 0 mitk::ImageTimeSelector::Pointer timeSelector = mitk::ImageTimeSelector::New(); timeSelector->SetInput(workingImage); timeSelector->SetTimeNr(0); timeSelector->SetChannelNr(0); timeSelector->Update(); const auto dimRefImg = timeSelector->GetOutput()->GetDimension(); if (dimRefImg != 3) return; std::vector contourList; contourList.reserve(sliceInfos.size()); ImageToContourFilter::Pointer contourExtractor = ImageToContourFilter::New(); std::vector relevantSlices = sliceInfos; if (detectIntersection) { relevantSlices.clear(); for (const auto& sliceInfo : sliceInfos) { // Test whether there is something to extract or whether the slice just contains intersections of others mitk::Image::Pointer slice2 = sliceInfo.slice->Clone(); mitk::MorphologicalOperations::Erode(slice2, 2, mitk::MorphologicalOperations::Ball); contourExtractor->SetInput(slice2); contourExtractor->Update(); mitk::Surface::Pointer contour = contourExtractor->GetOutput(); if (contour->GetVtkPolyData()->GetNumberOfPoints() == 0) { Self::RemoveContourFromInterpolator(sliceInfo); } else { relevantSlices.push_back(sliceInfo); } } } if (relevantSlices.empty()) return; for (const auto& sliceInfo : relevantSlices) { contourExtractor->SetInput(sliceInfo.slice); contourExtractor->Update(); mitk::Surface::Pointer contour = contourExtractor->GetOutput(); if (contour->GetVtkPolyData()->GetNumberOfPoints() == 0) { Self::RemoveContourFromInterpolator(sliceInfo); } else { contour->DisconnectPipeline(); contourList.push_back(contour); } } mitk::SurfaceInterpolationController::GetInstance()->AddNewContours(contourList); } mitk::Image::Pointer mitk::SegTool2D::GetAffectedImageSliceAs2DImage(const InteractionPositionEvent *positionEvent, const Image *image, unsigned int component /*= 0*/) { if (!positionEvent) { return nullptr; } assert(positionEvent->GetSender()); // sure, right? const auto timeStep = positionEvent->GetSender()->GetTimeStep(image); // get the timestep of the visible part (time-wise) of the image return GetAffectedImageSliceAs2DImage(positionEvent->GetSender()->GetCurrentWorldPlaneGeometry(), image, timeStep, component); } mitk::Image::Pointer mitk::SegTool2D::GetAffectedImageSliceAs2DImageByTimePoint(const PlaneGeometry* planeGeometry, const Image* image, TimePointType timePoint, unsigned int component /*= 0*/) { if (!image || !planeGeometry) { return nullptr; } if (!image->GetTimeGeometry()->IsValidTimePoint(timePoint)) return nullptr; return SegTool2D::GetAffectedImageSliceAs2DImage(planeGeometry, image, image->GetTimeGeometry()->TimePointToTimeStep(timePoint), component); } mitk::Image::Pointer mitk::SegTool2D::GetAffectedImageSliceAs2DImage(const PlaneGeometry *planeGeometry, const Image *image, TimeStepType timeStep, unsigned int component /*= 0*/) { if (!image || !planeGeometry) { return nullptr; } // Make sure that for reslicing and overwriting the same alogrithm is used. We can specify the mode of the vtk reslicer vtkSmartPointer reslice = vtkSmartPointer::New(); // set to false to extract a slice reslice->SetOverwriteMode(false); reslice->Modified(); // use ExtractSliceFilter with our specific vtkImageReslice for overwriting and extracting mitk::ExtractSliceFilter::Pointer extractor = mitk::ExtractSliceFilter::New(reslice); extractor->SetInput(image); extractor->SetTimeStep(timeStep); extractor->SetWorldGeometry(planeGeometry); extractor->SetVtkOutputRequest(false); extractor->SetResliceTransformByGeometry(image->GetTimeGeometry()->GetGeometryForTimeStep(timeStep)); // additionally extract the given component // default is 0; the extractor checks for multi-component images extractor->SetComponent(component); extractor->Modified(); extractor->Update(); Image::Pointer slice = extractor->GetOutput(); return slice; } mitk::Image::Pointer mitk::SegTool2D::GetAffectedWorkingSlice(const InteractionPositionEvent *positionEvent) const { const auto workingNode = this->GetWorkingDataNode(); if (!workingNode) { return nullptr; } const auto *workingImage = dynamic_cast(workingNode->GetData()); if (!workingImage) { return nullptr; } return GetAffectedImageSliceAs2DImage(positionEvent, workingImage); } mitk::Image::Pointer mitk::SegTool2D::GetAffectedReferenceSlice(const InteractionPositionEvent *positionEvent) const { DataNode* referenceNode = this->GetReferenceDataNode(); if (!referenceNode) { return nullptr; } auto *referenceImage = dynamic_cast(referenceNode->GetData()); if (!referenceImage) { return nullptr; } int displayedComponent = 0; if (referenceNode->GetIntProperty("Image.Displayed Component", displayedComponent)) { // found the displayed component return GetAffectedImageSliceAs2DImage(positionEvent, referenceImage, displayedComponent); } else { return GetAffectedImageSliceAs2DImage(positionEvent, referenceImage); } } mitk::Image::Pointer mitk::SegTool2D::GetAffectedReferenceSlice(const PlaneGeometry* planeGeometry, TimeStepType timeStep) const { DataNode* referenceNode = this->GetReferenceDataNode(); if (!referenceNode) { return nullptr; } auto* referenceImage = dynamic_cast(referenceNode->GetData()); if (!referenceImage) { return nullptr; } int displayedComponent = 0; if (referenceNode->GetIntProperty("Image.Displayed Component", displayedComponent)) { // found the displayed component return GetAffectedImageSliceAs2DImage(planeGeometry, referenceImage, timeStep, displayedComponent); } else { return GetAffectedImageSliceAs2DImage(planeGeometry, referenceImage, timeStep); } } void mitk::SegTool2D::Activated() { Superclass::Activated(); m_ToolManager->SelectedTimePointChanged += mitk::MessageDelegate(this, &mitk::SegTool2D::OnTimePointChangedInternal); m_LastTimePointTriggered = mitk::RenderingManager::GetInstance()->GetTimeNavigationController()->GetSelectedTimePoint(); } void mitk::SegTool2D::Deactivated() { m_ToolManager->SelectedTimePointChanged -= mitk::MessageDelegate(this, &mitk::SegTool2D::OnTimePointChangedInternal); Superclass::Deactivated(); } void mitk::SegTool2D::OnTimePointChangedInternal() { if (m_IsTimePointChangeAware && nullptr != this->GetWorkingDataNode()) { const auto timePoint = mitk::RenderingManager::GetInstance()->GetTimeNavigationController()->GetSelectedTimePoint(); if (timePoint != m_LastTimePointTriggered) { m_LastTimePointTriggered = timePoint; this->OnTimePointChanged(); } } } void mitk::SegTool2D::OnTimePointChanged() { //default implementation does nothing } mitk::DataNode* mitk::SegTool2D::GetWorkingDataNode() const { if (nullptr != m_ToolManager) { return m_ToolManager->GetWorkingData(0); } return nullptr; } mitk::Image* mitk::SegTool2D::GetWorkingData() const { auto node = this->GetWorkingDataNode(); if (nullptr != node) { return dynamic_cast(node->GetData()); } return nullptr; } mitk::DataNode* mitk::SegTool2D::GetReferenceDataNode() const { if (nullptr != m_ToolManager) { return m_ToolManager->GetReferenceData(0); } return nullptr; } mitk::Image* mitk::SegTool2D::GetReferenceData() const { auto node = this->GetReferenceDataNode(); if (nullptr != node) { return dynamic_cast(node->GetData()); } return nullptr; } void mitk::SegTool2D::WriteBackSegmentationResult(const InteractionPositionEvent *positionEvent, const Image * segmentationResult) { if (!positionEvent) return; const PlaneGeometry *planeGeometry((positionEvent->GetSender()->GetCurrentWorldPlaneGeometry())); const auto *abstractTransformGeometry( dynamic_cast(positionEvent->GetSender()->GetCurrentWorldPlaneGeometry())); if (planeGeometry && segmentationResult && !abstractTransformGeometry) { const auto workingNode = this->GetWorkingDataNode(); auto *image = dynamic_cast(workingNode->GetData()); const auto timeStep = positionEvent->GetSender()->GetTimeStep(image); this->WriteBackSegmentationResult(planeGeometry, segmentationResult, timeStep); } } void mitk::SegTool2D::WriteBackSegmentationResult(const DataNode* workingNode, const PlaneGeometry* planeGeometry, const Image* segmentationResult, TimeStepType timeStep) { if (!planeGeometry || !segmentationResult) return; SliceInformation sliceInfo(segmentationResult, const_cast(planeGeometry), timeStep); Self::WriteBackSegmentationResults(workingNode, { sliceInfo }, true); } void mitk::SegTool2D::WriteBackSegmentationResult(const PlaneGeometry *planeGeometry, const Image * segmentationResult, TimeStepType timeStep) { if (!planeGeometry || !segmentationResult) return; SliceInformation sliceInfo(segmentationResult, const_cast(planeGeometry), timeStep); WriteBackSegmentationResults({ sliceInfo }, true); } void mitk::SegTool2D::WriteBackSegmentationResults(const std::vector &sliceList, bool writeSliceToVolume) { if (sliceList.empty()) { return; } if (nullptr == m_LastEventSender) { MITK_WARN << "Cannot write tool results. Tool seems to be in an invalid state, as no interaction event was recieved but is expected."; return; } const auto workingNode = this->GetWorkingDataNode(); mitk::SegTool2D::WriteBackSegmentationResults(workingNode, sliceList, writeSliceToVolume); // the first geometry is needed otherwise restoring the position is not working const auto* plane3 = dynamic_cast(dynamic_cast( m_LastEventSender->GetSliceNavigationController()->GetCurrentGeometry3D()) ->GetPlaneGeometry(0)); unsigned int slicePosition = m_LastEventSender->GetSliceNavigationController()->GetSlice()->GetPos(); /* A cleaner solution would be to add a contour marker for each slice info. It currently does not work as the contour markers expect that the plane is always the plane of slice 0. Had not the time to do it properly no. Should be solved by T28146*/ this->AddContourmarker(plane3, slicePosition); } void mitk::SegTool2D::WriteBackSegmentationResults(const DataNode* workingNode, const std::vector& sliceList, bool writeSliceToVolume) { if (sliceList.empty()) { return; } if (nullptr == workingNode) { mitkThrow() << "Cannot write slice to working node. Working node is invalid."; } auto* image = dynamic_cast(workingNode->GetData()); if (nullptr == image) { mitkThrow() << "Cannot write slice to working node. Working node does not contain an image."; } for (const auto& sliceInfo : sliceList) { if (writeSliceToVolume && nullptr != sliceInfo.plane && sliceInfo.slice.IsNotNull()) { mitk::SegTool2D::WriteSliceToVolume(image, sliceInfo, true); } } mitk::SegTool2D::UpdateSurfaceInterpolation(sliceList, image, false); // also mark its node as modified (T27308). Can be removed if T27307 // is properly solved if (workingNode != nullptr) workingNode->Modified(); mitk::RenderingManager::GetInstance()->RequestUpdateAll(); } void mitk::SegTool2D::WriteSliceToVolume(Image* workingImage, const PlaneGeometry* planeGeometry, const Image* slice, TimeStepType timeStep, bool allowUndo) { SliceInformation sliceInfo(slice, planeGeometry, timeStep); WriteSliceToVolume(workingImage, sliceInfo , allowUndo); } void mitk::SegTool2D::WriteSliceToVolume(Image* workingImage, const SliceInformation &sliceInfo, bool allowUndo) { if (nullptr == workingImage) { mitkThrow() << "Cannot write slice to working node. Working node does not contain an image."; } DiffSliceOperation* undoOperation = nullptr; if (allowUndo) { /*============= BEGIN undo/redo feature block ========================*/ // Create undo operation by caching the not yet modified slices mitk::Image::Pointer originalSlice = GetAffectedImageSliceAs2DImage(sliceInfo.plane, workingImage, sliceInfo.timestep); undoOperation = new DiffSliceOperation(workingImage, originalSlice, dynamic_cast(originalSlice->GetGeometry()), sliceInfo.timestep, sliceInfo.plane); /*============= END undo/redo feature block ========================*/ } // Make sure that for reslicing and overwriting the same alogrithm is used. We can specify the mode of the vtk // reslicer vtkSmartPointer reslice = vtkSmartPointer::New(); // Set the slice as 'input' // casting const away is needed and OK as long the OverwriteMode of // mitkVTKImageOverwrite is true. // Reason: because then the input slice is not touched but // used to overwrite the input of the ExtractSliceFilter. auto noneConstSlice = const_cast(sliceInfo.slice.GetPointer()); reslice->SetInputSlice(noneConstSlice->GetVtkImageData()); // set overwrite mode to true to write back to the image volume reslice->SetOverwriteMode(true); reslice->Modified(); mitk::ExtractSliceFilter::Pointer extractor = mitk::ExtractSliceFilter::New(reslice); extractor->SetInput(workingImage); extractor->SetTimeStep(sliceInfo.timestep); extractor->SetWorldGeometry(sliceInfo.plane); extractor->SetVtkOutputRequest(false); extractor->SetResliceTransformByGeometry(workingImage->GetGeometry(sliceInfo.timestep)); extractor->Modified(); extractor->Update(); // the image was modified within the pipeline, but not marked so workingImage->Modified(); workingImage->GetVtkImageData()->Modified(); if (allowUndo) { /*============= BEGIN undo/redo feature block ========================*/ // specify the redo operation with the edited slice auto* doOperation = new DiffSliceOperation(workingImage, extractor->GetOutput(), dynamic_cast(sliceInfo.slice->GetGeometry()), sliceInfo.timestep, sliceInfo.plane); // create an operation event for the undo stack OperationEvent* undoStackItem = new OperationEvent(DiffSliceOperationApplier::GetInstance(), doOperation, undoOperation, "Segmentation"); // add it to the undo controller UndoStackItem::IncCurrObjectEventId(); UndoStackItem::IncCurrGroupEventId(); UndoController::GetCurrentUndoModel()->SetOperationEvent(undoStackItem); /*============= END undo/redo feature block ========================*/ } } void mitk::SegTool2D::SetShowMarkerNodes(bool status) { m_ShowMarkerNodes = status; } void mitk::SegTool2D::SetEnable3DInterpolation(bool enabled) { m_SurfaceInterpolationEnabled = enabled; } int mitk::SegTool2D::AddContourmarker(const PlaneGeometry* planeGeometry, unsigned int sliceIndex) { if (planeGeometry == nullptr) return -1; us::ServiceReference serviceRef = us::GetModuleContext()->GetServiceReference(); PlanePositionManagerService *service = us::GetModuleContext()->GetService(serviceRef); unsigned int size = service->GetNumberOfPlanePositions(); unsigned int id = service->AddNewPlanePosition(planeGeometry, sliceIndex); mitk::PlanarCircle::Pointer contourMarker = mitk::PlanarCircle::New(); mitk::Point2D p1; planeGeometry->Map(planeGeometry->GetCenter(), p1); mitk::Point2D p2 = p1; p2[0] -= planeGeometry->GetSpacing()[0]; p2[1] -= planeGeometry->GetSpacing()[1]; contourMarker->PlaceFigure(p1); contourMarker->SetCurrentControlPoint(p1); contourMarker->SetPlaneGeometry(planeGeometry->Clone()); std::stringstream markerStream; auto workingNode = this->GetWorkingDataNode(); markerStream << m_Contourmarkername; markerStream << " "; markerStream << id + 1; DataNode::Pointer rotatedContourNode = DataNode::New(); rotatedContourNode->SetData(contourMarker); rotatedContourNode->SetProperty("name", StringProperty::New(markerStream.str())); rotatedContourNode->SetProperty("isContourMarker", BoolProperty::New(true)); rotatedContourNode->SetBoolProperty("PlanarFigureInitializedWindow", true, m_LastEventSender); rotatedContourNode->SetProperty("includeInBoundingBox", BoolProperty::New(false)); rotatedContourNode->SetProperty("helper object", mitk::BoolProperty::New(!m_ShowMarkerNodes)); rotatedContourNode->SetProperty("planarfigure.drawcontrolpoints", BoolProperty::New(false)); rotatedContourNode->SetProperty("planarfigure.drawname", BoolProperty::New(false)); rotatedContourNode->SetProperty("planarfigure.drawoutline", BoolProperty::New(false)); rotatedContourNode->SetProperty("planarfigure.drawshadow", BoolProperty::New(false)); if (planeGeometry) { if (id == size) { m_ToolManager->GetDataStorage()->Add(rotatedContourNode, workingNode); } else { mitk::NodePredicateProperty::Pointer isMarker = mitk::NodePredicateProperty::New("isContourMarker", mitk::BoolProperty::New(true)); mitk::DataStorage::SetOfObjects::ConstPointer markers = m_ToolManager->GetDataStorage()->GetDerivations(workingNode, isMarker); for (auto iter = markers->begin(); iter != markers->end(); ++iter) { std::string nodeName = (*iter)->GetName(); unsigned int t = nodeName.find_last_of(" "); unsigned int markerId = atof(nodeName.substr(t + 1).c_str()) - 1; if (id == markerId) { return id; } } m_ToolManager->GetDataStorage()->Add(rotatedContourNode, workingNode); } } return id; } void mitk::SegTool2D::InteractiveSegmentationBugMessage(const std::string &message) const { MITK_ERROR << "********************************************************************************" << std::endl << " " << message << std::endl << "********************************************************************************" << std::endl << " " << std::endl << " If your image is rotated or the 2D views don't really contain the patient image, try to press the " "button next to the image selection. " << std::endl << " " << std::endl << " Please file a BUG REPORT: " << std::endl << " https://phabricator.mitk.org/" << std::endl << " Contain the following information:" << std::endl << " - What image were you working on?" << std::endl << " - Which region of the image?" << std::endl << " - Which tool did you use?" << std::endl << " - What did you do?" << std::endl << " - What happened (not)? What did you expect?" << std::endl; } -template -void InternalWritePreviewOnWorkingImage(itk::Image *targetSlice, - const mitk::Image *sourceSlice, - mitk::Image *originalImage, - int overwritevalue) -{ - typedef itk::Image SliceType; - - typename SliceType::Pointer sourceSliceITK; - CastToItkImage(sourceSlice, sourceSliceITK); - - // now the original slice and the ipSegmentation-painted slice are in the same format, and we can just copy all pixels - // that are non-zero - typedef itk::ImageRegionIterator OutputIteratorType; - typedef itk::ImageRegionConstIterator InputIteratorType; - - InputIteratorType inputIterator(sourceSliceITK, sourceSliceITK->GetLargestPossibleRegion()); - OutputIteratorType outputIterator(targetSlice, targetSlice->GetLargestPossibleRegion()); - - outputIterator.GoToBegin(); - inputIterator.GoToBegin(); - - auto *workingImage = dynamic_cast(originalImage); - assert(workingImage); - - int activePixelValue = workingImage->GetActiveLabel()->GetValue(); - - if (activePixelValue == 0) // if exterior is the active label - { - while (!outputIterator.IsAtEnd()) - { - if (inputIterator.Get() != 0) - { - outputIterator.Set(overwritevalue); - } - ++outputIterator; - ++inputIterator; - } - } - else if (overwritevalue != 0) // if we are not erasing - { - while (!outputIterator.IsAtEnd()) - { - auto targetValue = static_cast(outputIterator.Get()); - if (inputIterator.Get() != 0) - { - if (!workingImage->GetLabel(targetValue)->GetLocked()) - { - outputIterator.Set(overwritevalue); - } - } - if (targetValue == overwritevalue) - { - outputIterator.Set(inputIterator.Get()); - } - - ++outputIterator; - ++inputIterator; - } - } - else // if we are erasing - { - while (!outputIterator.IsAtEnd()) - { - const int targetValue = outputIterator.Get(); - if (inputIterator.Get() != 0) - { - if (targetValue == activePixelValue) - outputIterator.Set(overwritevalue); - } - - ++outputIterator; - ++inputIterator; - } - } -} - void mitk::SegTool2D::WritePreviewOnWorkingImage( Image *targetSlice, const Image *sourceSlice, const Image *workingImage, int paintingPixelValue) { if (nullptr == targetSlice) { mitkThrow() << "Cannot write preview on working image. Target slice does not point to a valid instance."; } if (nullptr == sourceSlice) { mitkThrow() << "Cannot write preview on working image. Source slice does not point to a valid instance."; } if (nullptr == workingImage) { mitkThrow() << "Cannot write preview on working image. Working image does not point to a valid instance."; } auto constVtkSource = sourceSlice->GetVtkImageData(); /*Need to const cast because Vtk interface does not support const correctly. (or I am not experienced enough to use it correctly)*/ auto nonConstVtkSource = const_cast(constVtkSource); - ContourModelUtils::FillSliceInSlice(nonConstVtkSource, targetSlice->GetVtkImageData(), workingImage, paintingPixelValue); + ContourModelUtils::FillSliceInSlice(nonConstVtkSource, targetSlice->GetVtkImageData(), workingImage, paintingPixelValue, 1.0); } diff --git a/Modules/Segmentation/Interactions/mitkSetRegionTool.h b/Modules/Segmentation/Interactions/mitkSetRegionTool.h index 42376155c0..b1fc705dab 100644 --- a/Modules/Segmentation/Interactions/mitkSetRegionTool.h +++ b/Modules/Segmentation/Interactions/mitkSetRegionTool.h @@ -1,65 +1,64 @@ /*============================================================================ The Medical Imaging Interaction Toolkit (MITK) Copyright (c) German Cancer Research Center (DKFZ) All rights reserved. Use of this source code is governed by a 3-clause BSD license that can be found in the LICENSE file. ============================================================================*/ #ifndef mitkSetRegionTool_h_Included #define mitkSetRegionTool_h_Included #include "mitkCommon.h" #include "mitkFeedbackContourTool.h" #include namespace mitk { class Image; class StateMachineAction; class InteractionEvent; /** \brief Fills or erases a 2D region \sa FeedbackContourTool \sa ExtractImageFilter \sa OverwriteSliceImageFilter \ingroup Interaction \ingroup ToolManagerEtAl Finds the outer contour of a shape in 2D (possibly including holes) and sets all the inside pixels to a specified value. This might fill holes or erase segmentations. \warning Only to be instantiated by mitk::ToolManager. $Author$ */ class MITKSEGMENTATION_EXPORT SetRegionTool : public FeedbackContourTool { public: mitkClassMacro(SetRegionTool, FeedbackContourTool); protected: SetRegionTool(int paintingPixelValue = 1); // purposely hidden ~SetRegionTool() override; void ConnectActionsAndFunctions() override; void Activated() override; void Deactivated() override; virtual void OnMousePressed(StateMachineAction *, InteractionEvent *); virtual void OnMouseReleased(StateMachineAction *, InteractionEvent *); virtual void OnMouseMoved(StateMachineAction *, InteractionEvent *); - int m_PaintingPixelValue; }; } // namespace #endif