diff --git a/Modules/Core/include/mitkImageVtkMapper2D.h b/Modules/Core/include/mitkImageVtkMapper2D.h index 1dc4cb2e23..1c13499b07 100644 --- a/Modules/Core/include/mitkImageVtkMapper2D.h +++ b/Modules/Core/include/mitkImageVtkMapper2D.h @@ -1,309 +1,310 @@ /*=================================================================== The Medical Imaging Interaction Toolkit (MITK) Copyright (c) German Cancer Research Center, Division of Medical and Biological Informatics. All rights reserved. This software is distributed WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See LICENSE.txt or http://www.mitk.org for details. ===================================================================*/ #ifndef MITKIMAGEVTKMAPPER2D_H_HEADER_INCLUDED_C10E906E #define MITKIMAGEVTKMAPPER2D_H_HEADER_INCLUDED_C10E906E // MITK #include // MITK Rendering #include "mitkBaseRenderer.h" #include "mitkExtractSliceFilter.h" #include "mitkVtkMapper.h" // VTK #include #include class vtkActor; class vtkPolyDataMapper; class vtkPlaneSource; class vtkImageData; class vtkLookupTable; class vtkImageExtractComponents; class vtkImageReslice; class vtkImageChangeInformation; class vtkPoints; class vtkMitkThickSlicesFilter; class vtkPolyData; class vtkMitkApplyLevelWindowToRGBFilter; class vtkMitkLevelWindowFilter; namespace mitk { /** \brief Mapper to resample and display 2D slices of a 3D image. * * The following image gives a brief overview of the mapping and the involved parts. * * \image html imageVtkMapper2Darchitecture.png * * First, the image is resliced by means of vtkImageReslice. The volume image * serves as input to the mapper in addition to spatial placement of the slice and a few other * properties such as thick slices. This code was already present in the old version * (mitkImageMapperGL2D). * * Next, the obtained slice (m_ReslicedImage) is put into a vtkMitkLevelWindowFilter * and the scalar levelwindow, opacity levelwindow and optional clipping to * local image bounds are applied * * Next, the output of the vtkMitkLevelWindowFilter is used to create a texture * (m_Texture) and a plane onto which the texture is rendered (m_Plane). For * mapping purposes, a vtkPolyDataMapper (m_Mapper) is utilized. Orthographic * projection is applied to create the effect of a 2D image. The mapper and the * texture are assigned to the actor (m_Actor) which is passed to the VTK rendering * pipeline via the method GetVtkProp(). * * In order to transform the textured plane to the correct position in space, the * same transformation as used for reslicing is applied to both the camera and the * vtkActor. All important steps are explained in more detail below. The resulting * 2D image (by reslicing the underlying 3D input image appropriately) can either * be directly rendered in a 2D view or just be calculated to be used later by another * rendering entity, e.g. in texture mapping in a 3D view. * * Properties that can be set for images and influence the imageMapper2D are: * * - \b "opacity": (FloatProperty) Opacity of the image * - \b "color": (ColorProperty) Color of the image * - \b "LookupTable": (mitkLookupTableProperty) If this property is set, * the default lookuptable will be ignored and the "LookupTable" value * will be used instead. * - \b "Image Rendering.Mode": This property decides which mode is used to render images. (E.g. if a lookup table or a transferfunction is applied). Detailed documentation about the modes can be found here: \link mitk::RenderingerModeProperty \endlink * - \b "Image Rendering.Transfer Function": (mitkTransferFunctionProperty) If this * property is set, a color transferfunction will be used to color the image. * - \b "binary": (BoolProperty) is the image a binary image or not * - \b "outline binary": (BoolProperty) show outline of the image or not * - \b "texture interpolation": (BoolProperty) texture interpolation of the image * - \b "reslice interpolation": (VtkResliceInterpolationProperty) reslice interpolation of the image * - \b "in plane resample extent by geometry": (BoolProperty) Do it or not * - \b "bounding box": (BoolProperty) Is the Bounding Box of the image shown or not * - \b "layer": (IntProperty) Layer of the image * - \b "volume annotation color": (ColorProperty) color of the volume annotation, TODO has to be reimplemented * - \b "volume annotation unit": (StringProperty) annotation unit as string (does not implicit convert the unit!) unit is ml or cm3, TODO has to be reimplemented * The default properties are: * - \b "opacity", mitk::FloatProperty::New(0.3f), renderer, overwrite ) * - \b "color", ColorProperty::New(1.0,0.0,0.0), renderer, overwrite ) * - \b "binary", mitk::BoolProperty::New( true ), renderer, overwrite ) * - \b "outline binary", mitk::BoolProperty::New( false ), renderer, overwrite ) * - \b "texture interpolation", mitk::BoolProperty::New( mitk::DataNodeFactory::m_TextureInterpolationActive ) ) * - \b "reslice interpolation", mitk::VtkResliceInterpolationProperty::New() ) * - \b "in plane resample extent by geometry", mitk::BoolProperty::New( false ) ) * - \b "bounding box", mitk::BoolProperty::New( false ) ) * - \b "layer", mitk::IntProperty::New(10), renderer, overwrite) * - \b "Image Rendering.Transfer Function": Default color transfer function for CTs * - \b "LookupTable": Rainbow color. * If the modality-property is set for an image, the mapper uses modality-specific default properties, * e.g. color maps, if they are defined. * \ingroup Mapper */ class MITKCORE_EXPORT ImageVtkMapper2D : public VtkMapper { public: /** Standard class typedefs. */ mitkClassMacro(ImageVtkMapper2D, VtkMapper); /** Method for creation through the object factory. */ itkFactorylessNewMacro(Self) itkCloneMacro(Self) /** \brief Get the Image to map */ const mitk::Image *GetInput(void); /** \brief Checks whether this mapper needs to update itself and generate * data. */ virtual void Update(mitk::BaseRenderer *renderer) override; //### methods of MITK-VTK rendering pipeline virtual vtkProp *GetVtkProp(mitk::BaseRenderer *renderer) override; //### end of methods of MITK-VTK rendering pipeline /** \brief Internal class holding the mapper, actor, etc. for each of the 3 2D render windows */ /** * To render transveral, coronal, and sagittal, the mapper is called three times. * For performance reasons, the corresponding data for each view is saved in the * internal helper class LocalStorage. This allows rendering n views with just * 1 mitkMapper using n vtkMapper. * */ class MITKCORE_EXPORT LocalStorage : public mitk::Mapper::BaseLocalStorage { public: /** \brief Actor of a 2D render window. */ vtkSmartPointer m_Actor; vtkSmartPointer m_Actors; /** \brief Mapper of a 2D render window. */ vtkSmartPointer m_Mapper; vtkSmartPointer m_VectorComponentExtractor; /** \brief Current slice of a 2D render window.*/ vtkSmartPointer m_ReslicedImage; /** \brief Empty vtkPolyData that is set when rendering geometry does not * intersect the image geometry. * \warning This member variable is set to NULL, * if no image geometry is inside the plane geometry * of the respective render window. Any user of this * slice has to check whether it is set to NULL! */ vtkSmartPointer m_EmptyPolyData; /** \brief Plane on which the slice is rendered as texture. */ vtkSmartPointer m_Plane; /** \brief The texture which is used to render the current slice. */ vtkSmartPointer m_Texture; /** \brief The lookuptables for colors and level window */ vtkSmartPointer m_DefaultLookupTable; vtkSmartPointer m_BinaryLookupTable; vtkSmartPointer m_ColorLookupTable; /** \brief The actual reslicer (one per renderer) */ mitk::ExtractSliceFilter::Pointer m_Reslicer; /** \brief Filter for thick slices */ vtkSmartPointer m_TSFilter; /** \brief PolyData object containg all lines/points needed for outlining the contour. This container is used to save a computed contour for the next rendering execution. For instance, if you zoom or pann, there is no need to recompute the contour. */ vtkSmartPointer m_OutlinePolyData; /** \brief Timestamp of last update of stored data. */ itk::TimeStamp m_LastUpdateTime; /** \brief mmPerPixel relation between pixel and mm. (World spacing).*/ mitk::ScalarType *m_mmPerPixel; /** \brief This filter is used to apply the level window to Grayvalue and RBG(A) images. */ vtkSmartPointer m_LevelWindowFilter; /** \brief Default constructor of the local storage. */ LocalStorage(); /** \brief Default deconstructor of the local storage. */ ~LocalStorage(); }; /** \brief The LocalStorageHandler holds all (three) LocalStorages for the three 2D render windows. */ mitk::LocalStorageHandler m_LSH; /** \brief Get the LocalStorage corresponding to the current renderer. */ LocalStorage *GetLocalStorage(mitk::BaseRenderer *renderer); /** \brief Set the default properties for general image rendering. */ static void SetDefaultProperties(mitk::DataNode *node, mitk::BaseRenderer *renderer = NULL, bool overwrite = false); /** \brief This method switches between different rendering modes (e.g. use a lookup table or a transfer function). * Detailed documentation about the modes can be found here: \link mitk::RenderingerModeProperty \endlink */ void ApplyRenderingMode(mitk::BaseRenderer *renderer); protected: /** \brief Transforms the actor to the actual position in 3D. * \param renderer The current renderer corresponding to the render window. */ void TransformActor(mitk::BaseRenderer *renderer); /** \brief Generates a plane according to the size of the resliced image in milimeters. * * \image html texturedPlane.png * * In VTK a vtkPlaneSource is defined through three points. The origin and two * points defining the axes of the plane (see VTK documentation). The origin is * set to (xMin; yMin; Z), where xMin and yMin are the minimal bounds of the * resliced image in space. Z is relevant for blending and the layer property. * The center of the plane (C) is also the center of the view plane (cf. the image above). * * \note For the standard MITK view with three 2D render windows showing three * different slices, three such planes are generated. All these planes are generated * in the XY-plane (even if they depict a YZ-slice of the volume). * */ void GeneratePlane(mitk::BaseRenderer *renderer, double planeBounds[6]); /** \brief Generates a vtkPolyData object containing the outline of a given binary slice. \param renderer: Pointer to the renderer containing the needed information \note This code is based on code from the iil library. */ + template vtkSmartPointer CreateOutlinePolyData(mitk::BaseRenderer *renderer); /** Default constructor */ ImageVtkMapper2D(); /** Default deconstructor */ virtual ~ImageVtkMapper2D(); /** \brief Does the actual resampling, without rendering the image yet. * All the data is generated inside this method. The vtkProp (or Actor) * is filled with content (i.e. the resliced image). * * After generation, a 4x4 transformation matrix(t) of the current slice is obtained * from the vtkResliceImage object via GetReslicesAxis(). This matrix is * applied to each textured plane (actor->SetUserTransform(t)) to transform everything * to the actual 3D position (cf. the following image). * * \image html cameraPositioning3D.png * */ virtual void GenerateDataForRenderer(mitk::BaseRenderer *renderer) override; /** \brief This method uses the vtkCamera clipping range and the layer property * to calcualte the depth of the object (e.g. image or contour). The depth is used * to keep the correct order for the final VTK rendering.*/ float CalculateLayerDepth(mitk::BaseRenderer *renderer); /** \brief This method applies (or modifies) the lookuptable for all types of images. * \warning To use the lookup table, the property 'Lookup Table' must be set and a 'Image Rendering.Mode' * which uses the lookup table must be set. */ void ApplyLookuptable(mitk::BaseRenderer *renderer); /** \brief This method applies a color transfer function. * Internally, a vtkColorTransferFunction is used. This is usefull for coloring continous * images (e.g. float) * \warning To use the color transfer function, the property 'Image Rendering.Transfer Function' must be set and a * 'Image Rendering.Mode' which uses the color transfer function must be set. */ void ApplyColorTransferFunction(mitk::BaseRenderer *renderer); /** * @brief ApplyLevelWindow Apply the level window for the given renderer. * \warning To use the level window, the property 'LevelWindow' must be set and a 'Image Rendering.Mode' which uses * the level window must be set. * @param renderer Level window for which renderer? */ void ApplyLevelWindow(mitk::BaseRenderer *renderer); /** \brief Set the color of the image/polydata */ void ApplyColor(mitk::BaseRenderer *renderer); /** \brief Set the opacity of the actor. */ void ApplyOpacity(mitk::BaseRenderer *renderer); /** * \brief Calculates whether the given rendering geometry intersects the * given SlicedGeometry3D. * * This method checks if the given PlaneGeometry intersects the given * SlicedGeometry3D. It calculates the distance of the PlaneGeometry to all * 8 cornerpoints of the SlicedGeometry3D. If all distances have the same * sign (all positive or all negative) there is no intersection. * If the distances have different sign, there is an intersection. **/ bool RenderingGeometryIntersectsImage(const PlaneGeometry *renderingGeometry, SlicedGeometry3D *imageGeometry); }; } // namespace mitk #endif /* MITKIMAGEVTKMAPPER2D_H_HEADER_INCLUDED_C10E906E */ diff --git a/Modules/Core/src/Rendering/mitkImageVtkMapper2D.cpp b/Modules/Core/src/Rendering/mitkImageVtkMapper2D.cpp index dbe4278106..9949610191 100644 --- a/Modules/Core/src/Rendering/mitkImageVtkMapper2D.cpp +++ b/Modules/Core/src/Rendering/mitkImageVtkMapper2D.cpp @@ -1,1121 +1,1130 @@ /*=================================================================== The Medical Imaging Interaction Toolkit (MITK) Copyright (c) German Cancer Research Center, Division of Medical and Biological Informatics. All rights reserved. This software is distributed WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See LICENSE.txt or http://www.mitk.org for details. ===================================================================*/ // MITK #include #include #include #include #include #include #include #include #include #include #include //#include #include "mitkImageStatisticsHolder.h" #include "mitkPlaneClipping.h" #include // MITK Rendering #include "mitkImageVtkMapper2D.h" #include "vtkMitkLevelWindowFilter.h" #include "vtkMitkThickSlicesFilter.h" #include "vtkNeverTranslucentTexture.h" // VTK #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include // ITK #include #include mitk::ImageVtkMapper2D::ImageVtkMapper2D() { } mitk::ImageVtkMapper2D::~ImageVtkMapper2D() { // The 3D RW Mapper (PlaneGeometryDataVtkMapper3D) is listening to this event, // in order to delete the images from the 3D RW. this->InvokeEvent(itk::DeleteEvent()); } // set the two points defining the textured plane according to the dimension and spacing void mitk::ImageVtkMapper2D::GeneratePlane(mitk::BaseRenderer *renderer, double planeBounds[6]) { LocalStorage *localStorage = m_LSH.GetLocalStorage(renderer); float depth = this->CalculateLayerDepth(renderer); // Set the origin to (xMin; yMin; depth) of the plane. This is necessary for obtaining the correct // plane size in crosshair rotation and swivel mode. localStorage->m_Plane->SetOrigin(planeBounds[0], planeBounds[2], depth); // These two points define the axes of the plane in combination with the origin. // Point 1 is the x-axis and point 2 the y-axis. // Each plane is transformed according to the view (axial, coronal and saggital) afterwards. localStorage->m_Plane->SetPoint1(planeBounds[1], planeBounds[2], depth); // P1: (xMax, yMin, depth) localStorage->m_Plane->SetPoint2(planeBounds[0], planeBounds[3], depth); // P2: (xMin, yMax, depth) } float mitk::ImageVtkMapper2D::CalculateLayerDepth(mitk::BaseRenderer *renderer) { // get the clipping range to check how deep into z direction we can render images double maxRange = renderer->GetVtkRenderer()->GetActiveCamera()->GetClippingRange()[1]; // Due to a VTK bug, we cannot use the whole clipping range. /100 is empirically determined float depth = -maxRange * 0.01; // divide by 100 int layer = 0; GetDataNode()->GetIntProperty("layer", layer, renderer); // add the layer property for each image to render images with a higher layer on top of the others depth += layer * 10; //*10: keep some room for each image (e.g. for QBalls in between) if (depth > 0.0f) { depth = 0.0f; MITK_WARN << "Layer value exceeds clipping range. Set to minimum instead."; } return depth; } const mitk::Image *mitk::ImageVtkMapper2D::GetInput(void) { return static_cast(GetDataNode()->GetData()); } vtkProp *mitk::ImageVtkMapper2D::GetVtkProp(mitk::BaseRenderer *renderer) { // return the actor corresponding to the renderer return m_LSH.GetLocalStorage(renderer)->m_Actors; } void mitk::ImageVtkMapper2D::GenerateDataForRenderer(mitk::BaseRenderer *renderer) { LocalStorage *localStorage = m_LSH.GetLocalStorage(renderer); SetVtkMapperImmediateModeRendering(localStorage->m_Mapper); - mitk::Image *input = const_cast(this->GetInput()); + mitk::Image *image = const_cast(this->GetInput()); mitk::DataNode *datanode = this->GetDataNode(); - - if (input == NULL || input->IsInitialized() == false) + if (nullptr == image || !image->IsInitialized()) { return; } // check if there is a valid worldGeometry const PlaneGeometry *worldGeometry = renderer->GetCurrentWorldPlaneGeometry(); - if ((worldGeometry == NULL) || (!worldGeometry->IsValid()) || (!worldGeometry->HasReferenceGeometry())) + if (nullptr == worldGeometry || !worldGeometry->IsValid() || !worldGeometry->HasReferenceGeometry()) { return; } - input->Update(); + image->Update(); // early out if there is no intersection of the current rendering geometry // and the geometry of the image that is to be rendered. - if (!RenderingGeometryIntersectsImage(worldGeometry, input->GetSlicedGeometry())) + if (!RenderingGeometryIntersectsImage(worldGeometry, image->GetSlicedGeometry())) { // set image to NULL, to clear the texture in 3D, because // the latest image is used there if the plane is out of the geometry // see bug-13275 localStorage->m_ReslicedImage = NULL; localStorage->m_Mapper->SetInputData(localStorage->m_EmptyPolyData); return; } // set main input for ExtractSliceFilter - localStorage->m_Reslicer->SetInput(input); + localStorage->m_Reslicer->SetInput(image); localStorage->m_Reslicer->SetWorldGeometry(worldGeometry); localStorage->m_Reslicer->SetTimeStep(this->GetTimestep()); // set the transformation of the image to adapt reslice axis localStorage->m_Reslicer->SetResliceTransformByGeometry( - input->GetTimeGeometry()->GetGeometryForTimeStep(this->GetTimestep())); + image->GetTimeGeometry()->GetGeometryForTimeStep(this->GetTimestep())); // is the geometry of the slice based on the input image or the worldgeometry? bool inPlaneResampleExtentByGeometry = false; datanode->GetBoolProperty("in plane resample extent by geometry", inPlaneResampleExtentByGeometry, renderer); localStorage->m_Reslicer->SetInPlaneResampleExtentByGeometry(inPlaneResampleExtentByGeometry); // Initialize the interpolation mode for resampling; switch to nearest // neighbor if the input image is too small. - if ((input->GetDimension() >= 3) && (input->GetDimension(2) > 1)) + if ((image->GetDimension() >= 3) && (image->GetDimension(2) > 1)) { VtkResliceInterpolationProperty *resliceInterpolationProperty; datanode->GetProperty(resliceInterpolationProperty, "reslice interpolation", renderer); int interpolationMode = VTK_RESLICE_NEAREST; if (resliceInterpolationProperty != NULL) { interpolationMode = resliceInterpolationProperty->GetInterpolation(); } switch (interpolationMode) { case VTK_RESLICE_NEAREST: localStorage->m_Reslicer->SetInterpolationMode(ExtractSliceFilter::RESLICE_NEAREST); break; case VTK_RESLICE_LINEAR: localStorage->m_Reslicer->SetInterpolationMode(ExtractSliceFilter::RESLICE_LINEAR); break; case VTK_RESLICE_CUBIC: localStorage->m_Reslicer->SetInterpolationMode(ExtractSliceFilter::RESLICE_CUBIC); break; } } else { localStorage->m_Reslicer->SetInterpolationMode(ExtractSliceFilter::RESLICE_NEAREST); } // set the vtk output property to true, makes sure that no unneeded mitk image convertion // is done. localStorage->m_Reslicer->SetVtkOutputRequest(true); // Thickslicing int thickSlicesMode = 0; int thickSlicesNum = 1; // Thick slices parameters - if (input->GetPixelType().GetNumberOfComponents() == 1) // for now only single component are allowed + if (image->GetPixelType().GetNumberOfComponents() == 1) // for now only single component are allowed { DataNode *dn = renderer->GetCurrentWorldPlaneGeometryNode(); if (dn) { ResliceMethodProperty *resliceMethodEnumProperty = 0; if (dn->GetProperty(resliceMethodEnumProperty, "reslice.thickslices", renderer) && resliceMethodEnumProperty) thickSlicesMode = resliceMethodEnumProperty->GetValueAsId(); IntProperty *intProperty = 0; if (dn->GetProperty(intProperty, "reslice.thickslices.num", renderer) && intProperty) { thickSlicesNum = intProperty->GetValue(); if (thickSlicesNum < 1) thickSlicesNum = 1; } } else { MITK_WARN << "no associated widget plane data tree node found"; } } const PlaneGeometry *planeGeometry = dynamic_cast(worldGeometry); if (thickSlicesMode > 0) { double dataZSpacing = 1.0; Vector3D normInIndex, normal; const mitk::AbstractTransformGeometry *abstractGeometry = dynamic_cast(worldGeometry); if (abstractGeometry != NULL) normal = abstractGeometry->GetPlane()->GetNormal(); else { if (planeGeometry != NULL) { normal = planeGeometry->GetNormal(); } else return; // no fitting geometry set } normal.Normalize(); - input->GetTimeGeometry()->GetGeometryForTimeStep(this->GetTimestep())->WorldToIndex(normal, normInIndex); + image->GetTimeGeometry()->GetGeometryForTimeStep(this->GetTimestep())->WorldToIndex(normal, normInIndex); dataZSpacing = 1.0 / normInIndex.GetNorm(); localStorage->m_Reslicer->SetOutputDimensionality(3); localStorage->m_Reslicer->SetOutputSpacingZDirection(dataZSpacing); localStorage->m_Reslicer->SetOutputExtentZDirection(-thickSlicesNum, 0 + thickSlicesNum); // Do the reslicing. Modified() is called to make sure that the reslicer is // executed even though the input geometry information did not change; this // is necessary when the input /em data, but not the /em geometry changes. localStorage->m_TSFilter->SetThickSliceMode(thickSlicesMode - 1); localStorage->m_TSFilter->SetInputData(localStorage->m_Reslicer->GetVtkOutput()); // vtkFilter=>mitkFilter=>vtkFilter update mechanism will fail without calling manually localStorage->m_Reslicer->Modified(); localStorage->m_Reslicer->Update(); localStorage->m_TSFilter->Modified(); localStorage->m_TSFilter->Update(); localStorage->m_ReslicedImage = localStorage->m_TSFilter->GetOutput(); } else { // this is needed when thick mode was enable bevore. These variable have to be reset to default values localStorage->m_Reslicer->SetOutputDimensionality(2); localStorage->m_Reslicer->SetOutputSpacingZDirection(1.0); localStorage->m_Reslicer->SetOutputExtentZDirection(0, 0); localStorage->m_Reslicer->Modified(); // start the pipeline with updating the largest possible, needed if the geometry of the input has changed localStorage->m_Reslicer->UpdateLargestPossibleRegion(); localStorage->m_ReslicedImage = localStorage->m_Reslicer->GetVtkOutput(); } // Bounds information for reslicing (only reuqired if reference geometry // is present) // this used for generating a vtkPLaneSource with the right size double sliceBounds[6]; for (auto &sliceBound : sliceBounds) { sliceBound = 0.0; } localStorage->m_Reslicer->GetClippedPlaneBounds(sliceBounds); // get the spacing of the slice localStorage->m_mmPerPixel = localStorage->m_Reslicer->GetOutputSpacing(); // calculate minimum bounding rect of IMAGE in texture { double textureClippingBounds[6]; for (auto &textureClippingBound : textureClippingBounds) { textureClippingBound = 0.0; } // Calculate the actual bounds of the transformed plane clipped by the // dataset bounding box; this is required for drawing the texture at the // correct position during 3D mapping. - mitk::PlaneClipping::CalculateClippedPlaneBounds(input->GetGeometry(), planeGeometry, textureClippingBounds); + mitk::PlaneClipping::CalculateClippedPlaneBounds(image->GetGeometry(), planeGeometry, textureClippingBounds); textureClippingBounds[0] = static_cast(textureClippingBounds[0] / localStorage->m_mmPerPixel[0] + 0.5); textureClippingBounds[1] = static_cast(textureClippingBounds[1] / localStorage->m_mmPerPixel[0] + 0.5); textureClippingBounds[2] = static_cast(textureClippingBounds[2] / localStorage->m_mmPerPixel[1] + 0.5); textureClippingBounds[3] = static_cast(textureClippingBounds[3] / localStorage->m_mmPerPixel[1] + 0.5); // clipping bounds for cutting the image localStorage->m_LevelWindowFilter->SetClippingBounds(textureClippingBounds); } // get the number of scalar components to distinguish between different image types int numberOfComponents = localStorage->m_ReslicedImage->GetNumberOfScalarComponents(); // get the binary property bool binary = false; bool binaryOutline = false; datanode->GetBoolProperty("binary", binary, renderer); if (binary) // binary image { datanode->GetBoolProperty("outline binary", binaryOutline, renderer); if (binaryOutline) // contour rendering { - if (input->GetPixelType().GetBpe() <= 8) + // get pixel type of vtk image + itk::ImageIOBase::IOComponentType componentType = static_cast(image->GetPixelType().GetComponentType()); + switch (componentType) { + case itk::ImageIOBase::UCHAR: // generate contours/outlines - localStorage->m_OutlinePolyData = CreateOutlinePolyData(renderer); - - float binaryOutlineWidth(1.0); + localStorage->m_OutlinePolyData = CreateOutlinePolyData(renderer); + break; + case itk::ImageIOBase::USHORT: + // generate contours/outlines + localStorage->m_OutlinePolyData = CreateOutlinePolyData(renderer); + break; + default: + binaryOutline = false; + this->ApplyLookuptable(renderer); + MITK_WARN << "Type of all binary images should be unsigned char or unsigned short. Outline does not work on other pixel types!"; + } + if (binaryOutline) // binary outline is still true --> add outline + { + float binaryOutlineWidth = 1.0; if (datanode->GetFloatProperty("outline width", binaryOutlineWidth, renderer)) { if (localStorage->m_Actors->GetNumberOfPaths() > 1) { - float binaryOutlineShadowWidth(1.5); + float binaryOutlineShadowWidth = 1.5; datanode->GetFloatProperty("outline shadow width", binaryOutlineShadowWidth, renderer); dynamic_cast(localStorage->m_Actors->GetParts()->GetItemAsObject(0)) ->GetProperty() ->SetLineWidth(binaryOutlineWidth * binaryOutlineShadowWidth); } - localStorage->m_Actor->GetProperty()->SetLineWidth(binaryOutlineWidth); } } - else - { - binaryOutline = false; - this->ApplyLookuptable(renderer); - MITK_WARN << "Type of all binary images should be (un)signed char. Outline does not work on other pixel types!"; - } } else // standard binary image { if (numberOfComponents != 1) { MITK_ERROR << "Rendering Error: Binary Images with more then 1 component are not supported!"; } } } this->ApplyOpacity(renderer); this->ApplyRenderingMode(renderer); // do not use a VTK lookup table (we do that ourselves in m_LevelWindowFilter) localStorage->m_Texture->MapColorScalarsThroughLookupTableOff(); int displayedComponent = 0; if (datanode->GetIntProperty("Image.Displayed Component", displayedComponent, renderer) && numberOfComponents > 1) { localStorage->m_VectorComponentExtractor->SetComponents(displayedComponent); localStorage->m_VectorComponentExtractor->SetInputData(localStorage->m_ReslicedImage); localStorage->m_LevelWindowFilter->SetInputConnection(localStorage->m_VectorComponentExtractor->GetOutputPort(0)); } else { // connect the input with the levelwindow filter localStorage->m_LevelWindowFilter->SetInputData(localStorage->m_ReslicedImage); } // check for texture interpolation property bool textureInterpolation = false; GetDataNode()->GetBoolProperty("texture interpolation", textureInterpolation, renderer); // set the interpolation modus according to the property localStorage->m_Texture->SetInterpolate(textureInterpolation); // connect the texture with the output of the levelwindow filter localStorage->m_Texture->SetInputConnection(localStorage->m_LevelWindowFilter->GetOutputPort()); this->TransformActor(renderer); vtkActor *contourShadowActor = dynamic_cast(localStorage->m_Actors->GetParts()->GetItemAsObject(0)); if (binary && binaryOutline) // connect the mapper with the polyData which contains the lines { // We need the contour for the binary outline property as actor localStorage->m_Mapper->SetInputData(localStorage->m_OutlinePolyData); - localStorage->m_Actor->SetTexture(NULL); // no texture for contours + localStorage->m_Actor->SetTexture(nullptr); // no texture for contours - bool binaryOutlineShadow(false); + bool binaryOutlineShadow = false; datanode->GetBoolProperty("outline binary shadow", binaryOutlineShadow, renderer); - if (binaryOutlineShadow) + { contourShadowActor->SetVisibility(true); + } else + { contourShadowActor->SetVisibility(false); + } } else { // Connect the mapper with the input texture. This is the standard case. // setup the textured plane this->GeneratePlane(renderer, sliceBounds); // set the plane as input for the mapper localStorage->m_Mapper->SetInputConnection(localStorage->m_Plane->GetOutputPort()); // set the texture for the actor localStorage->m_Actor->SetTexture(localStorage->m_Texture); contourShadowActor->SetVisibility(false); } // We have been modified => save this for next Update() localStorage->m_LastUpdateTime.Modified(); } void mitk::ImageVtkMapper2D::ApplyLevelWindow(mitk::BaseRenderer *renderer) { LocalStorage *localStorage = this->GetLocalStorage(renderer); LevelWindow levelWindow; this->GetDataNode()->GetLevelWindow(levelWindow, renderer, "levelwindow"); localStorage->m_LevelWindowFilter->GetLookupTable()->SetRange(levelWindow.GetLowerWindowBound(), levelWindow.GetUpperWindowBound()); mitk::LevelWindow opacLevelWindow; if (this->GetDataNode()->GetLevelWindow(opacLevelWindow, renderer, "opaclevelwindow")) { // pass the opaque level window to the filter localStorage->m_LevelWindowFilter->SetMinOpacity(opacLevelWindow.GetLowerWindowBound()); localStorage->m_LevelWindowFilter->SetMaxOpacity(opacLevelWindow.GetUpperWindowBound()); } else { // no opaque level window localStorage->m_LevelWindowFilter->SetMinOpacity(0.0); localStorage->m_LevelWindowFilter->SetMaxOpacity(255.0); } } void mitk::ImageVtkMapper2D::ApplyColor(mitk::BaseRenderer *renderer) { LocalStorage *localStorage = this->GetLocalStorage(renderer); float rgb[3] = {1.0f, 1.0f, 1.0f}; // check for color prop and use it for rendering if it exists // binary image hovering & binary image selection bool hover = false; bool selected = false; bool binary = false; GetDataNode()->GetBoolProperty("binaryimage.ishovering", hover, renderer); GetDataNode()->GetBoolProperty("selected", selected, renderer); GetDataNode()->GetBoolProperty("binary", binary, renderer); if (binary && hover && !selected) { mitk::ColorProperty::Pointer colorprop = dynamic_cast(GetDataNode()->GetProperty("binaryimage.hoveringcolor", renderer)); if (colorprop.IsNotNull()) { memcpy(rgb, colorprop->GetColor().GetDataPointer(), 3 * sizeof(float)); } else { GetDataNode()->GetColor(rgb, renderer, "color"); } } if (binary && selected) { mitk::ColorProperty::Pointer colorprop = dynamic_cast(GetDataNode()->GetProperty("binaryimage.selectedcolor", renderer)); if (colorprop.IsNotNull()) { memcpy(rgb, colorprop->GetColor().GetDataPointer(), 3 * sizeof(float)); } else { GetDataNode()->GetColor(rgb, renderer, "color"); } } if (!binary || (!hover && !selected)) { GetDataNode()->GetColor(rgb, renderer, "color"); } double rgbConv[3] = {(double)rgb[0], (double)rgb[1], (double)rgb[2]}; // conversion to double for VTK dynamic_cast(localStorage->m_Actors->GetParts()->GetItemAsObject(0))->GetProperty()->SetColor(rgbConv); localStorage->m_Actor->GetProperty()->SetColor(rgbConv); if (localStorage->m_Actors->GetParts()->GetNumberOfItems() > 1) { float rgb[3] = {1.0f, 1.0f, 1.0f}; mitk::ColorProperty::Pointer colorprop = dynamic_cast(GetDataNode()->GetProperty("outline binary shadow color", renderer)); if (colorprop.IsNotNull()) { memcpy(rgb, colorprop->GetColor().GetDataPointer(), 3 * sizeof(float)); } double rgbConv[3] = {(double)rgb[0], (double)rgb[1], (double)rgb[2]}; // conversion to double for VTK dynamic_cast(localStorage->m_Actors->GetParts()->GetItemAsObject(0))->GetProperty()->SetColor(rgbConv); } } void mitk::ImageVtkMapper2D::ApplyOpacity(mitk::BaseRenderer *renderer) { LocalStorage *localStorage = this->GetLocalStorage(renderer); float opacity = 1.0f; // check for opacity prop and use it for rendering if it exists GetDataNode()->GetOpacity(opacity, renderer, "opacity"); // set the opacity according to the properties localStorage->m_Actor->GetProperty()->SetOpacity(opacity); if (localStorage->m_Actors->GetParts()->GetNumberOfItems() > 1) { dynamic_cast(localStorage->m_Actors->GetParts()->GetItemAsObject(0)) ->GetProperty() ->SetOpacity(opacity); } } void mitk::ImageVtkMapper2D::ApplyRenderingMode(mitk::BaseRenderer *renderer) { LocalStorage *localStorage = m_LSH.GetLocalStorage(renderer); bool binary = false; this->GetDataNode()->GetBoolProperty("binary", binary, renderer); if (binary) // is it a binary image? { // for binary images, we always use our default LuT and map every value to (0,1) // the opacity of 0 will always be 0.0. We never a apply a LuT/TfF nor a level window. localStorage->m_LevelWindowFilter->SetLookupTable(localStorage->m_BinaryLookupTable); } else { // all other image types can make use of the rendering mode int renderingMode = mitk::RenderingModeProperty::LOOKUPTABLE_LEVELWINDOW_COLOR; mitk::RenderingModeProperty::Pointer mode = dynamic_cast(this->GetDataNode()->GetProperty("Image Rendering.Mode", renderer)); if (mode.IsNotNull()) { renderingMode = mode->GetRenderingMode(); } switch (renderingMode) { case mitk::RenderingModeProperty::LOOKUPTABLE_LEVELWINDOW_COLOR: MITK_DEBUG << "'Image Rendering.Mode' = LevelWindow_LookupTable_Color"; this->ApplyLookuptable(renderer); this->ApplyLevelWindow(renderer); break; case mitk::RenderingModeProperty::COLORTRANSFERFUNCTION_LEVELWINDOW_COLOR: MITK_DEBUG << "'Image Rendering.Mode' = LevelWindow_ColorTransferFunction_Color"; this->ApplyColorTransferFunction(renderer); this->ApplyLevelWindow(renderer); break; case mitk::RenderingModeProperty::LOOKUPTABLE_COLOR: MITK_DEBUG << "'Image Rendering.Mode' = LookupTable_Color"; this->ApplyLookuptable(renderer); break; case mitk::RenderingModeProperty::COLORTRANSFERFUNCTION_COLOR: MITK_DEBUG << "'Image Rendering.Mode' = ColorTransferFunction_Color"; this->ApplyColorTransferFunction(renderer); break; default: MITK_ERROR << "No valid 'Image Rendering.Mode' set. Using LOOKUPTABLE_LEVELWINDOW_COLOR instead."; this->ApplyLookuptable(renderer); this->ApplyLevelWindow(renderer); break; } } // we apply color for all images (including binaries). this->ApplyColor(renderer); } void mitk::ImageVtkMapper2D::ApplyLookuptable(mitk::BaseRenderer *renderer) { LocalStorage *localStorage = m_LSH.GetLocalStorage(renderer); vtkLookupTable *usedLookupTable = localStorage->m_ColorLookupTable; // If lookup table or transferfunction use is requested... mitk::LookupTableProperty::Pointer lookupTableProp = dynamic_cast(this->GetDataNode()->GetProperty("LookupTable")); if (lookupTableProp.IsNotNull()) // is a lookuptable set? { usedLookupTable = lookupTableProp->GetLookupTable()->GetVtkLookupTable(); } else { //"Image Rendering.Mode was set to use a lookup table but there is no property 'LookupTable'. // A default (rainbow) lookup table will be used. // Here have to do nothing. Warning for the user has been removed, due to unwanted console output // in every interation of the rendering. } localStorage->m_LevelWindowFilter->SetLookupTable(usedLookupTable); } void mitk::ImageVtkMapper2D::ApplyColorTransferFunction(mitk::BaseRenderer *renderer) { mitk::TransferFunctionProperty::Pointer transferFunctionProp = dynamic_cast( this->GetDataNode()->GetProperty("Image Rendering.Transfer Function", renderer)); if (transferFunctionProp.IsNull()) { MITK_ERROR << "'Image Rendering.Mode'' was set to use a color transfer function but there is no property 'Image " "Rendering.Transfer Function'. Nothing will be done."; return; } LocalStorage *localStorage = m_LSH.GetLocalStorage(renderer); // pass the transfer function to our level window filter localStorage->m_LevelWindowFilter->SetLookupTable(transferFunctionProp->GetValue()->GetColorTransferFunction()); localStorage->m_LevelWindowFilter->SetOpacityPiecewiseFunction( transferFunctionProp->GetValue()->GetScalarOpacityFunction()); } void mitk::ImageVtkMapper2D::Update(mitk::BaseRenderer *renderer) { bool visible = true; GetDataNode()->GetVisibility(visible, renderer, "visible"); if (!visible) { return; } mitk::Image *data = const_cast(this->GetInput()); if (data == NULL) { return; } // Calculate time step of the input data for the specified renderer (integer value) this->CalculateTimeStep(renderer); // Check if time step is valid const TimeGeometry *dataTimeGeometry = data->GetTimeGeometry(); if ((dataTimeGeometry == NULL) || (dataTimeGeometry->CountTimeSteps() == 0) || (!dataTimeGeometry->IsValidTimeStep(this->GetTimestep()))) { return; } const DataNode *node = this->GetDataNode(); data->UpdateOutputInformation(); LocalStorage *localStorage = m_LSH.GetLocalStorage(renderer); // check if something important has changed and we need to rerender if ((localStorage->m_LastUpdateTime < node->GetMTime()) // was the node modified? || (localStorage->m_LastUpdateTime < data->GetPipelineMTime()) // Was the data modified? || (localStorage->m_LastUpdateTime < renderer->GetCurrentWorldPlaneGeometryUpdateTime()) // was the geometry modified? || (localStorage->m_LastUpdateTime < renderer->GetCurrentWorldPlaneGeometry()->GetMTime()) || (localStorage->m_LastUpdateTime < node->GetPropertyList()->GetMTime()) // was a property modified? || (localStorage->m_LastUpdateTime < node->GetPropertyList(renderer)->GetMTime())) { this->GenerateDataForRenderer(renderer); } // since we have checked that nothing important has changed, we can set // m_LastUpdateTime to the current time localStorage->m_LastUpdateTime.Modified(); } void mitk::ImageVtkMapper2D::SetDefaultProperties(mitk::DataNode *node, mitk::BaseRenderer *renderer, bool overwrite) { mitk::Image::Pointer image = dynamic_cast(node->GetData()); // Properties common for both images and segmentations node->AddProperty("depthOffset", mitk::FloatProperty::New(0.0), renderer, overwrite); node->AddProperty("outline binary", mitk::BoolProperty::New(false), renderer, overwrite); node->AddProperty("outline width", mitk::FloatProperty::New(1.0), renderer, overwrite); node->AddProperty("outline binary shadow", mitk::BoolProperty::New(false), renderer, overwrite); node->AddProperty("outline binary shadow color", ColorProperty::New(0.0, 0.0, 0.0), renderer, overwrite); node->AddProperty("outline shadow width", mitk::FloatProperty::New(1.5), renderer, overwrite); if (image->IsRotated()) node->AddProperty("reslice interpolation", mitk::VtkResliceInterpolationProperty::New(VTK_RESLICE_CUBIC)); else node->AddProperty("reslice interpolation", mitk::VtkResliceInterpolationProperty::New()); node->AddProperty("texture interpolation", mitk::BoolProperty::New(false)); node->AddProperty("in plane resample extent by geometry", mitk::BoolProperty::New(false)); node->AddProperty("bounding box", mitk::BoolProperty::New(false)); mitk::RenderingModeProperty::Pointer renderingModeProperty = mitk::RenderingModeProperty::New(); node->AddProperty("Image Rendering.Mode", renderingModeProperty); // Set default grayscale look-up table mitk::LookupTable::Pointer mitkLut = mitk::LookupTable::New(); mitkLut->SetType(mitk::LookupTable::GRAYSCALE); mitk::LookupTableProperty::Pointer mitkLutProp = mitk::LookupTableProperty::New(); mitkLutProp->SetLookupTable(mitkLut); node->SetProperty("LookupTable", mitkLutProp); std::string photometricInterpretation; // DICOM tag telling us how pixel values should be displayed if (node->GetStringProperty("dicom.pixel.PhotometricInterpretation", photometricInterpretation)) { // modality provided by DICOM or other reader if (photometricInterpretation.find("MONOCHROME1") != std::string::npos) // meaning: display MINIMUM pixels as WHITE { // Set inverse grayscale look-up table mitkLut->SetType(mitk::LookupTable::INVERSE_GRAYSCALE); mitkLutProp->SetLookupTable(mitkLut); node->SetProperty("LookupTable", mitkLutProp); renderingModeProperty->SetValue(mitk::RenderingModeProperty::LOOKUPTABLE_LEVELWINDOW_COLOR); // USE lookuptable } // Otherwise do nothing - the default grayscale look-up table has already been set } bool isBinaryImage(false); if (!node->GetBoolProperty("binary", isBinaryImage) && image->GetPixelType().GetNumberOfComponents() == 1) { // ok, property is not set, use heuristic to determine if this // is a binary image mitk::Image::Pointer centralSliceImage; ScalarType minValue = 0.0; ScalarType maxValue = 0.0; ScalarType min2ndValue = 0.0; ScalarType max2ndValue = 0.0; mitk::ImageSliceSelector::Pointer sliceSelector = mitk::ImageSliceSelector::New(); sliceSelector->SetInput(image); sliceSelector->SetSliceNr(image->GetDimension(2) / 2); sliceSelector->SetTimeNr(image->GetDimension(3) / 2); sliceSelector->SetChannelNr(image->GetDimension(4) / 2); sliceSelector->Update(); centralSliceImage = sliceSelector->GetOutput(); if (centralSliceImage.IsNotNull() && centralSliceImage->IsInitialized()) { minValue = centralSliceImage->GetStatistics()->GetScalarValueMin(); maxValue = centralSliceImage->GetStatistics()->GetScalarValueMax(); min2ndValue = centralSliceImage->GetStatistics()->GetScalarValue2ndMin(); max2ndValue = centralSliceImage->GetStatistics()->GetScalarValue2ndMax(); } if ((maxValue == min2ndValue && minValue == max2ndValue) || minValue == maxValue) { // centralSlice is strange, lets look at all data minValue = image->GetStatistics()->GetScalarValueMin(); maxValue = image->GetStatistics()->GetScalarValueMaxNoRecompute(); min2ndValue = image->GetStatistics()->GetScalarValue2ndMinNoRecompute(); max2ndValue = image->GetStatistics()->GetScalarValue2ndMaxNoRecompute(); } isBinaryImage = (maxValue == min2ndValue && minValue == max2ndValue); } std::string className = image->GetNameOfClass(); if (className != "TensorImage" && className != "QBallImage") { PixelType pixelType = image->GetPixelType(); size_t numComponents = pixelType.GetNumberOfComponents(); if ((pixelType.GetPixelType() == itk::ImageIOBase::VECTOR && numComponents > 1) || numComponents == 2 || numComponents > 4) { node->AddProperty("Image.Displayed Component", mitk::IntProperty::New(0), renderer, overwrite); } } // some more properties specific for a binary... if (isBinaryImage) { node->AddProperty("opacity", mitk::FloatProperty::New(0.3f), renderer, overwrite); node->AddProperty("color", ColorProperty::New(1.0, 0.0, 0.0), renderer, overwrite); node->AddProperty("binaryimage.selectedcolor", ColorProperty::New(1.0, 0.0, 0.0), renderer, overwrite); node->AddProperty("binaryimage.selectedannotationcolor", ColorProperty::New(1.0, 0.0, 0.0), renderer, overwrite); node->AddProperty("binaryimage.hoveringcolor", ColorProperty::New(1.0, 0.0, 0.0), renderer, overwrite); node->AddProperty("binaryimage.hoveringannotationcolor", ColorProperty::New(1.0, 0.0, 0.0), renderer, overwrite); node->AddProperty("binary", mitk::BoolProperty::New(true), renderer, overwrite); node->AddProperty("layer", mitk::IntProperty::New(10), renderer, overwrite); } else //...or image type object { node->AddProperty("opacity", mitk::FloatProperty::New(1.0f), renderer, overwrite); node->AddProperty("color", ColorProperty::New(1.0, 1.0, 1.0), renderer, overwrite); node->AddProperty("binary", mitk::BoolProperty::New(false), renderer, overwrite); node->AddProperty("layer", mitk::IntProperty::New(0), renderer, overwrite); } if (image.IsNotNull() && image->IsInitialized()) { if ((overwrite) || (node->GetProperty("levelwindow", renderer) == NULL)) { /* initialize level/window from DICOM tags */ std::string sLevel = ""; std::string sWindow = ""; if (GetBackwardsCompatibleDICOMProperty( 0x0028, 0x1050, "dicom.voilut.WindowCenter", image->GetPropertyList(), sLevel) && GetBackwardsCompatibleDICOMProperty( 0x0028, 0x1051, "dicom.voilut.WindowWidth", image->GetPropertyList(), sWindow)) { float level = atof(sLevel.c_str()); float window = atof(sWindow.c_str()); mitk::LevelWindow contrast; std::string sSmallestPixelValueInSeries; std::string sLargestPixelValueInSeries; if (GetBackwardsCompatibleDICOMProperty(0x0028, 0x0108, "dicom.series.SmallestPixelValueInSeries", image->GetPropertyList(), sSmallestPixelValueInSeries) && GetBackwardsCompatibleDICOMProperty(0x0028, 0x0109, "dicom.series.LargestPixelValueInSeries", image->GetPropertyList(), sLargestPixelValueInSeries)) { float smallestPixelValueInSeries = atof(sSmallestPixelValueInSeries.c_str()); float largestPixelValueInSeries = atof(sLargestPixelValueInSeries.c_str()); contrast.SetRangeMinMax(smallestPixelValueInSeries - 1, largestPixelValueInSeries + 1); // why not a little buffer? // might remedy some l/w widget challenges } else { contrast.SetAuto(static_cast(node->GetData()), false, true); // we need this as a fallback } contrast.SetLevelWindow(level, window, true); node->SetProperty("levelwindow", LevelWindowProperty::New(contrast), renderer); } } if (((overwrite) || (node->GetProperty("opaclevelwindow", renderer) == NULL)) && (image->GetPixelType().GetPixelType() == itk::ImageIOBase::RGBA) && (image->GetPixelType().GetComponentType() == itk::ImageIOBase::UCHAR)) { mitk::LevelWindow opaclevwin; opaclevwin.SetRangeMinMax(0, 255); opaclevwin.SetWindowBounds(0, 255); mitk::LevelWindowProperty::Pointer prop = mitk::LevelWindowProperty::New(opaclevwin); node->SetProperty("opaclevelwindow", prop, renderer); } } Superclass::SetDefaultProperties(node, renderer, overwrite); } mitk::ImageVtkMapper2D::LocalStorage *mitk::ImageVtkMapper2D::GetLocalStorage(mitk::BaseRenderer *renderer) { return m_LSH.GetLocalStorage(renderer); } +template vtkSmartPointer mitk::ImageVtkMapper2D::CreateOutlinePolyData(mitk::BaseRenderer *renderer) { LocalStorage *localStorage = this->GetLocalStorage(renderer); // get the min and max index values of each direction int *extent = localStorage->m_ReslicedImage->GetExtent(); int xMin = extent[0]; int xMax = extent[1]; int yMin = extent[2]; int yMax = extent[3]; int *dims = localStorage->m_ReslicedImage->GetDimensions(); // dimensions of the image int line = dims[0]; // how many pixels per line? int x = xMin; // pixel index x int y = yMin; // pixel index y - char *currentPixel; // get the depth for each contour float depth = CalculateLayerDepth(renderer); vtkSmartPointer points = vtkSmartPointer::New(); // the points to draw vtkSmartPointer lines = vtkSmartPointer::New(); // the lines to connect the points // We take the pointer to the first pixel of the image - currentPixel = static_cast(localStorage->m_ReslicedImage->GetScalarPointer()); + TPixel* currentPixel = static_cast(localStorage->m_ReslicedImage->GetScalarPointer()); while (y <= yMax) { // if the current pixel value is set to something if ((currentPixel) && (*currentPixel != 0)) { // check in which direction a line is necessary // a line is added if the neighbor of the current pixel has the value 0 // and if the pixel is located at the edge of the image // if vvvvv not the first line vvvvv if (y > yMin && *(currentPixel - line) == 0) { // x direction - bottom edge of the pixel // add the 2 points vtkIdType p1 = points->InsertNextPoint(x * localStorage->m_mmPerPixel[0], y * localStorage->m_mmPerPixel[1], depth); vtkIdType p2 = points->InsertNextPoint((x + 1) * localStorage->m_mmPerPixel[0], y * localStorage->m_mmPerPixel[1], depth); // add the line between both points lines->InsertNextCell(2); lines->InsertCellPoint(p1); lines->InsertCellPoint(p2); } // if vvvvv not the last line vvvvv if (y < yMax && *(currentPixel + line) == 0) { // x direction - top edge of the pixel vtkIdType p1 = points->InsertNextPoint(x * localStorage->m_mmPerPixel[0], (y + 1) * localStorage->m_mmPerPixel[1], depth); vtkIdType p2 = points->InsertNextPoint( (x + 1) * localStorage->m_mmPerPixel[0], (y + 1) * localStorage->m_mmPerPixel[1], depth); lines->InsertNextCell(2); lines->InsertCellPoint(p1); lines->InsertCellPoint(p2); } // if vvvvv not the first pixel vvvvv if ((x > xMin || y > yMin) && *(currentPixel - 1) == 0) { // y direction - left edge of the pixel vtkIdType p1 = points->InsertNextPoint(x * localStorage->m_mmPerPixel[0], y * localStorage->m_mmPerPixel[1], depth); vtkIdType p2 = points->InsertNextPoint(x * localStorage->m_mmPerPixel[0], (y + 1) * localStorage->m_mmPerPixel[1], depth); lines->InsertNextCell(2); lines->InsertCellPoint(p1); lines->InsertCellPoint(p2); } // if vvvvv not the last pixel vvvvv if ((y < yMax || (x < xMax)) && *(currentPixel + 1) == 0) { // y direction - right edge of the pixel vtkIdType p1 = points->InsertNextPoint((x + 1) * localStorage->m_mmPerPixel[0], y * localStorage->m_mmPerPixel[1], depth); vtkIdType p2 = points->InsertNextPoint( (x + 1) * localStorage->m_mmPerPixel[0], (y + 1) * localStorage->m_mmPerPixel[1], depth); lines->InsertNextCell(2); lines->InsertCellPoint(p1); lines->InsertCellPoint(p2); } /* now consider pixels at the edge of the image */ // if vvvvv left edge of image vvvvv if (x == xMin) { // draw left edge of the pixel vtkIdType p1 = points->InsertNextPoint(x * localStorage->m_mmPerPixel[0], y * localStorage->m_mmPerPixel[1], depth); vtkIdType p2 = points->InsertNextPoint(x * localStorage->m_mmPerPixel[0], (y + 1) * localStorage->m_mmPerPixel[1], depth); lines->InsertNextCell(2); lines->InsertCellPoint(p1); lines->InsertCellPoint(p2); } // if vvvvv right edge of image vvvvv if (x == xMax) { // draw right edge of the pixel vtkIdType p1 = points->InsertNextPoint((x + 1) * localStorage->m_mmPerPixel[0], y * localStorage->m_mmPerPixel[1], depth); vtkIdType p2 = points->InsertNextPoint( (x + 1) * localStorage->m_mmPerPixel[0], (y + 1) * localStorage->m_mmPerPixel[1], depth); lines->InsertNextCell(2); lines->InsertCellPoint(p1); lines->InsertCellPoint(p2); } // if vvvvv bottom edge of image vvvvv if (y == yMin) { // draw bottom edge of the pixel vtkIdType p1 = points->InsertNextPoint(x * localStorage->m_mmPerPixel[0], y * localStorage->m_mmPerPixel[1], depth); vtkIdType p2 = points->InsertNextPoint((x + 1) * localStorage->m_mmPerPixel[0], y * localStorage->m_mmPerPixel[1], depth); lines->InsertNextCell(2); lines->InsertCellPoint(p1); lines->InsertCellPoint(p2); } // if vvvvv top edge of image vvvvv if (y == yMax) { // draw top edge of the pixel vtkIdType p1 = points->InsertNextPoint(x * localStorage->m_mmPerPixel[0], (y + 1) * localStorage->m_mmPerPixel[1], depth); vtkIdType p2 = points->InsertNextPoint( (x + 1) * localStorage->m_mmPerPixel[0], (y + 1) * localStorage->m_mmPerPixel[1], depth); lines->InsertNextCell(2); lines->InsertCellPoint(p1); lines->InsertCellPoint(p2); } } // end if currentpixel is set x++; if (x > xMax) { // reached end of line x = xMin; y++; } // Increase the pointer-position to the next pixel. // This is safe, as the while-loop and the x-reset logic above makes // sure we do not exceed the bounds of the image currentPixel++; } // end of while // Create a polydata to store everything in vtkSmartPointer polyData = vtkSmartPointer::New(); // Add the points to the dataset polyData->SetPoints(points); // Add the lines to the dataset polyData->SetLines(lines); return polyData; } void mitk::ImageVtkMapper2D::TransformActor(mitk::BaseRenderer *renderer) { LocalStorage *localStorage = m_LSH.GetLocalStorage(renderer); // get the transformation matrix of the reslicer in order to render the slice as axial, coronal or saggital vtkSmartPointer trans = vtkSmartPointer::New(); vtkSmartPointer matrix = localStorage->m_Reslicer->GetResliceAxes(); trans->SetMatrix(matrix); // transform the plane/contour (the actual actor) to the corresponding view (axial, coronal or saggital) localStorage->m_Actor->SetUserTransform(trans); // transform the origin to center based coordinates, because MITK is center based. localStorage->m_Actor->SetPosition(-0.5 * localStorage->m_mmPerPixel[0], -0.5 * localStorage->m_mmPerPixel[1], 0.0); if (localStorage->m_Actors->GetNumberOfPaths() > 1) { vtkActor *secondaryActor = dynamic_cast(localStorage->m_Actors->GetParts()->GetItemAsObject(0)); secondaryActor->SetUserTransform(trans); secondaryActor->SetPosition(-0.5 * localStorage->m_mmPerPixel[0], -0.5 * localStorage->m_mmPerPixel[1], 0.0); } } bool mitk::ImageVtkMapper2D::RenderingGeometryIntersectsImage(const PlaneGeometry *renderingGeometry, SlicedGeometry3D *imageGeometry) { // if either one of the two geometries is NULL we return true // for safety reasons if (renderingGeometry == NULL || imageGeometry == NULL) return true; // get the distance for the first cornerpoint ScalarType initialDistance = renderingGeometry->SignedDistance(imageGeometry->GetCornerPoint(0)); for (int i = 1; i < 8; i++) { mitk::Point3D cornerPoint = imageGeometry->GetCornerPoint(i); // get the distance to the other cornerpoints ScalarType distance = renderingGeometry->SignedDistance(cornerPoint); // if it has not the same signing as the distance of the first point if (initialDistance * distance < 0) { // we have an intersection and return true return true; } } // all distances have the same sign, no intersection and we return false return false; } mitk::ImageVtkMapper2D::LocalStorage::~LocalStorage() { } mitk::ImageVtkMapper2D::LocalStorage::LocalStorage() : m_VectorComponentExtractor(vtkSmartPointer::New()) { m_LevelWindowFilter = vtkSmartPointer::New(); // Do as much actions as possible in here to avoid double executions. m_Plane = vtkSmartPointer::New(); m_Texture = vtkSmartPointer::New().GetPointer(); m_DefaultLookupTable = vtkSmartPointer::New(); m_BinaryLookupTable = vtkSmartPointer::New(); m_ColorLookupTable = vtkSmartPointer::New(); m_Mapper = vtkSmartPointer::New(); m_Actor = vtkSmartPointer::New(); m_Actors = vtkSmartPointer::New(); m_Reslicer = mitk::ExtractSliceFilter::New(); m_TSFilter = vtkSmartPointer::New(); m_OutlinePolyData = vtkSmartPointer::New(); m_ReslicedImage = vtkSmartPointer::New(); m_EmptyPolyData = vtkSmartPointer::New(); // the following actions are always the same and thus can be performed // in the constructor for each image (i.e. the image-corresponding local storage) m_TSFilter->ReleaseDataFlagOn(); mitk::LookupTable::Pointer mitkLUT = mitk::LookupTable::New(); // built a default lookuptable mitkLUT->SetType(mitk::LookupTable::GRAYSCALE); m_DefaultLookupTable = mitkLUT->GetVtkLookupTable(); mitkLUT->SetType(mitk::LookupTable::LEGACY_BINARY); m_BinaryLookupTable = mitkLUT->GetVtkLookupTable(); mitkLUT->SetType(mitk::LookupTable::LEGACY_RAINBOW_COLOR); m_ColorLookupTable = mitkLUT->GetVtkLookupTable(); // do not repeat the texture (the image) m_Texture->RepeatOff(); // set the mapper for the actor m_Actor->SetMapper(m_Mapper); vtkSmartPointer outlineShadowActor = vtkSmartPointer::New(); outlineShadowActor->SetMapper(m_Mapper); m_Actors->AddPart(outlineShadowActor); m_Actors->AddPart(m_Actor); } diff --git a/Modules/Multilabel/mitkLabelSetImage.cpp b/Modules/Multilabel/mitkLabelSetImage.cpp index 74167e0f44..12d46b3242 100644 --- a/Modules/Multilabel/mitkLabelSetImage.cpp +++ b/Modules/Multilabel/mitkLabelSetImage.cpp @@ -1,965 +1,965 @@ /*=================================================================== The Medical Imaging Interaction Toolkit (MITK) Copyright (c) German Cancer Research Center, Division of Medical and Biological Informatics. All rights reserved. This software is distributed WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See LICENSE.txt or http://www.mitk.org for details. ===================================================================*/ #include "mitkLabelSetImage.h" #include "mitkImageAccessByItk.h" #include "mitkImageCast.h" #include "mitkImageReadAccessor.h" #include "mitkInteractionConst.h" #include "mitkLookupTableProperty.h" #include "mitkPadImageFilter.h" #include "mitkRenderingManager.h" #include #include #include #include #include #include //#include #include template void SetToZero(itk::Image *source) { source->FillBuffer(0); } mitk::LabelSetImage::LabelSetImage() : mitk::Image(), m_ActiveLayer(0), m_activeLayerInvalid(false), m_ExteriorLabel(nullptr) { // Iniitlaize Background Label mitk::Color color; color.Set(0, 0, 0); m_ExteriorLabel = mitk::Label::New(); m_ExteriorLabel->SetColor(color); m_ExteriorLabel->SetName("Exterior"); m_ExteriorLabel->SetOpacity(0.0); m_ExteriorLabel->SetLocked(false); m_ExteriorLabel->SetValue(0); } mitk::LabelSetImage::LabelSetImage(const mitk::LabelSetImage &other) : Image(other), m_ActiveLayer(other.GetActiveLayer()), m_activeLayerInvalid(false), m_ExteriorLabel(other.GetExteriorLabel()->Clone()) { for (unsigned int i = 0; i < other.GetNumberOfLayers(); i++) { // Clone LabelSet data mitk::LabelSet::Pointer lsClone = other.GetLabelSet(i)->Clone(); // add modified event listener to LabelSet (listen to LabelSet changes) itk::SimpleMemberCommand::Pointer command = itk::SimpleMemberCommand::New(); command->SetCallbackFunction(this, &mitk::LabelSetImage::OnLabelSetModified); lsClone->AddObserver(itk::ModifiedEvent(), command); m_LabelSetContainer.push_back(lsClone); // clone layer Image data mitk::Image::Pointer liClone = other.GetLayerImage(i)->Clone(); m_LayerContainer.push_back(liClone); } } void mitk::LabelSetImage::OnLabelSetModified() { Superclass::Modified(); } void mitk::LabelSetImage::SetExteriorLabel(mitk::Label *label) { m_ExteriorLabel = label; } mitk::Label *mitk::LabelSetImage::GetExteriorLabel() { return m_ExteriorLabel; } const mitk::Label *mitk::LabelSetImage::GetExteriorLabel() const { return m_ExteriorLabel; } void mitk::LabelSetImage::Initialize(const mitk::Image *other) { mitk::PixelType pixelType(mitk::MakeScalarPixelType()); if (other->GetDimension() == 2) { const unsigned int dimensions[] = {other->GetDimension(0), other->GetDimension(1), 1}; Superclass::Initialize(pixelType, 3, dimensions); } else { Superclass::Initialize(pixelType, other->GetDimension(), other->GetDimensions()); } auto originalGeometry = other->GetTimeGeometry()->Clone(); this->SetTimeGeometry(originalGeometry); // initialize image memory to zero if (4 == this->GetDimension()) { AccessFixedDimensionByItk(this, SetToZero, 4); } else { AccessByItk(this, SetToZero); } // Add a inital LabelSet ans corresponding image data to the stack AddLayer(); } mitk::LabelSetImage::~LabelSetImage() { m_LabelSetContainer.clear(); } mitk::Image *mitk::LabelSetImage::GetLayerImage(unsigned int layer) { return m_LayerContainer[layer]; } const mitk::Image *mitk::LabelSetImage::GetLayerImage(unsigned int layer) const { return m_LayerContainer[layer]; } unsigned int mitk::LabelSetImage::GetActiveLayer() const { return m_ActiveLayer; } unsigned int mitk::LabelSetImage::GetNumberOfLayers() const { return m_LabelSetContainer.size(); } void mitk::LabelSetImage::RemoveLayer() { int layerToDelete = GetActiveLayer(); // remove all observers from active label set GetLabelSet(layerToDelete)->RemoveAllObservers(); // set the active layer to one below, if exists. if (layerToDelete != 0) { SetActiveLayer(layerToDelete - 1); } else { // we are deleting layer zero, it should not be copied back into the vector m_activeLayerInvalid = true; } // remove labelset and image data m_LabelSetContainer.erase(m_LabelSetContainer.begin() + layerToDelete); m_LayerContainer.erase(m_LayerContainer.begin() + layerToDelete); if (layerToDelete == 0) { this->SetActiveLayer(layerToDelete); } this->Modified(); } unsigned int mitk::LabelSetImage::AddLayer(mitk::LabelSet::Pointer lset) { mitk::Image::Pointer newImage = mitk::Image::New(); newImage->Initialize(this->GetPixelType(), this->GetDimension(), this->GetDimensions(), this->GetImageDescriptor()->GetNumberOfChannels()); newImage->SetTimeGeometry(this->GetTimeGeometry()->Clone()); if (newImage->GetDimension() < 4) { AccessByItk(newImage, SetToZero); } else { AccessFixedDimensionByItk(newImage, SetToZero, 4); } unsigned int newLabelSetId = this->AddLayer(newImage, lset); return newLabelSetId; } unsigned int mitk::LabelSetImage::AddLayer(mitk::Image::Pointer layerImage, mitk::LabelSet::Pointer lset) { unsigned int newLabelSetId = m_LayerContainer.size(); // Add labelset to layer mitk::LabelSet::Pointer ls; if (lset.IsNotNull()) { ls = lset; } else { ls = mitk::LabelSet::New(); ls->AddLabel(GetExteriorLabel()); ls->SetActiveLabel(0 /*Exterior Label*/); } ls->SetLayer(newLabelSetId); // Add exterior Label to label set // mitk::Label::Pointer exteriorLabel = CreateExteriorLabel(); // push a new working image for the new layer m_LayerContainer.push_back(layerImage); // push a new labelset for the new layer m_LabelSetContainer.push_back(ls); // add modified event listener to LabelSet (listen to LabelSet changes) itk::SimpleMemberCommand::Pointer command = itk::SimpleMemberCommand::New(); command->SetCallbackFunction(this, &mitk::LabelSetImage::OnLabelSetModified); ls->AddObserver(itk::ModifiedEvent(), command); SetActiveLayer(newLabelSetId); // MITK_INFO << GetActiveLayer(); this->Modified(); return newLabelSetId; } void mitk::LabelSetImage::AddLabelSetToLayer(const unsigned int layerIdx, const mitk::LabelSet::Pointer labelSet) { if (m_LayerContainer.size() <= layerIdx) { mitkThrow() << "Trying to add labelSet to non-existing layer."; } if (layerIdx < m_LabelSetContainer.size()) { m_LabelSetContainer[layerIdx] = labelSet; } else { while (layerIdx >= m_LabelSetContainer.size()) { mitk::LabelSet::Pointer defaultLabelSet = mitk::LabelSet::New(); defaultLabelSet->AddLabel(GetExteriorLabel()); defaultLabelSet->SetActiveLabel(0 /*Exterior Label*/); defaultLabelSet->SetLayer(m_LabelSetContainer.size()); m_LabelSetContainer.push_back(defaultLabelSet); } m_LabelSetContainer.push_back(labelSet); } } void mitk::LabelSetImage::SetActiveLayer(unsigned int layer) { try { if (4 == this->GetDimension()) { if ((layer != GetActiveLayer() || m_activeLayerInvalid) && (layer < this->GetNumberOfLayers())) { BeforeChangeLayerEvent.Send(); if (m_activeLayerInvalid) { // We should not write the invalid layer back to the vector m_activeLayerInvalid = false; } else { AccessFixedDimensionByItk_n(this, ImageToLayerContainerProcessing, 4, (GetActiveLayer())); } m_ActiveLayer = layer; // only at this place m_ActiveLayer should be manipulated!!! Use Getter and Setter AccessFixedDimensionByItk_n(this, LayerContainerToImageProcessing, 4, (GetActiveLayer())); AfterChangeLayerEvent.Send(); } } else { if ((layer != GetActiveLayer() || m_activeLayerInvalid) && (layer < this->GetNumberOfLayers())) { BeforeChangeLayerEvent.Send(); if (m_activeLayerInvalid) { // We should not write the invalid layer back to the vector m_activeLayerInvalid = false; } else { AccessByItk_1(this, ImageToLayerContainerProcessing, GetActiveLayer()); } m_ActiveLayer = layer; // only at this place m_ActiveLayer should be manipulated!!! Use Getter and Setter AccessByItk_1(this, LayerContainerToImageProcessing, GetActiveLayer()); AfterChangeLayerEvent.Send(); } } } catch (itk::ExceptionObject &e) { mitkThrow() << e.GetDescription(); } this->Modified(); } void mitk::LabelSetImage::Concatenate(mitk::LabelSetImage *other) { const unsigned int *otherDims = other->GetDimensions(); const unsigned int *thisDims = this->GetDimensions(); if ((otherDims[0] != thisDims[0]) || (otherDims[1] != thisDims[1]) || (otherDims[2] != thisDims[2])) mitkThrow() << "Dimensions do not match."; try { int numberOfLayers = other->GetNumberOfLayers(); for (int layer = 0; layer < numberOfLayers; ++layer) { this->SetActiveLayer(layer); AccessByItk_1(this, ConcatenateProcessing, other); mitk::LabelSet *ls = other->GetLabelSet(layer); auto it = ls->IteratorConstBegin(); auto end = ls->IteratorConstEnd(); it++; // skip exterior while (it != end) { GetLabelSet()->AddLabel((it->second)); // AddLabelEvent.Send(); it++; } } } catch (itk::ExceptionObject &e) { mitkThrow() << e.GetDescription(); } this->Modified(); } void mitk::LabelSetImage::ClearBuffer() { try { AccessByItk(this, ClearBufferProcessing); this->Modified(); } catch (itk::ExceptionObject &e) { mitkThrow() << e.GetDescription(); } } bool mitk::LabelSetImage::ExistLabel(PixelType pixelValue) const { bool exist = false; for (unsigned int lidx = 0; lidx < GetNumberOfLayers(); lidx++) exist |= m_LabelSetContainer[lidx]->ExistLabel(pixelValue); return exist; } bool mitk::LabelSetImage::ExistLabel(PixelType pixelValue, unsigned int layer) const { bool exist = m_LabelSetContainer[layer]->ExistLabel(pixelValue); return exist; } bool mitk::LabelSetImage::ExistLabelSet(unsigned int layer) const { return layer < m_LabelSetContainer.size(); } void mitk::LabelSetImage::MergeLabel(PixelType pixelValue, unsigned int /*layer*/) { int targetPixelValue = this->GetActiveLabel(GetActiveLayer())->GetValue(); try { AccessByItk_2(this, MergeLabelProcessing, targetPixelValue, pixelValue); } catch (itk::ExceptionObject &e) { mitkThrow() << e.GetDescription(); } Modified(); } void mitk::LabelSetImage::MergeLabels(std::vector &VectorOfLablePixelValues, PixelType pixelValue, unsigned int layer) { GetLabelSet(layer)->SetActiveLabel(pixelValue); try { for (unsigned int idx = 0; idx < VectorOfLablePixelValues.size(); idx++) { AccessByItk_2(this, MergeLabelProcessing, pixelValue, VectorOfLablePixelValues[idx]); } } catch (itk::ExceptionObject &e) { mitkThrow() << e.GetDescription(); } Modified(); } void mitk::LabelSetImage::RemoveLabels(std::vector &VectorOfLabelPixelValues, unsigned int layer) { for (unsigned int idx = 0; idx < VectorOfLabelPixelValues.size(); idx++) { GetLabelSet(layer)->RemoveLabel(VectorOfLabelPixelValues[idx]); EraseLabel(VectorOfLabelPixelValues[idx], layer); } } void mitk::LabelSetImage::EraseLabels(std::vector &VectorOfLabelPixelValues, unsigned int layer) { for (unsigned int i = 0; i < VectorOfLabelPixelValues.size(); i++) { this->EraseLabel(VectorOfLabelPixelValues[i], layer); } } void mitk::LabelSetImage::EraseLabel(PixelType pixelValue, unsigned int layer) { try { AccessByItk_2(this, EraseLabelProcessing, pixelValue, layer); } catch (itk::ExceptionObject &e) { mitkThrow() << e.GetDescription(); } Modified(); } mitk::Label *mitk::LabelSetImage::GetActiveLabel(unsigned int layer) { - if (m_LabelSetContainer.size() > layer) - return m_LabelSetContainer[layer]->GetActiveLabel(); - else + if (m_LabelSetContainer.size() <= layer) return nullptr; + else + return m_LabelSetContainer[layer]->GetActiveLabel();; } mitk::Label *mitk::LabelSetImage::GetLabel(PixelType pixelValue, unsigned int layer) const { if (m_LabelSetContainer.size() <= layer) return nullptr; else return m_LabelSetContainer[layer]->GetLabel(pixelValue); } mitk::LabelSet *mitk::LabelSetImage::GetLabelSet(unsigned int layer) { if (m_LabelSetContainer.size() <= layer) return nullptr; else return m_LabelSetContainer[layer].GetPointer(); } const mitk::LabelSet *mitk::LabelSetImage::GetLabelSet(unsigned int layer) const { if (m_LabelSetContainer.size() <= layer) return nullptr; else return m_LabelSetContainer[layer].GetPointer(); } mitk::LabelSet *mitk::LabelSetImage::GetActiveLabelSet() { if (m_LabelSetContainer.size() == 0) return nullptr; else return m_LabelSetContainer[GetActiveLayer()].GetPointer(); } void mitk::LabelSetImage::UpdateCenterOfMass(PixelType pixelValue, unsigned int layer) { AccessByItk_2(this, CalculateCenterOfMassProcessing, pixelValue, layer); } unsigned int mitk::LabelSetImage::GetNumberOfLabels(unsigned int layer) const { return m_LabelSetContainer[layer]->GetNumberOfLabels(); } unsigned int mitk::LabelSetImage::GetTotalNumberOfLabels() const { unsigned int totalLabels(0); auto layerIter = m_LabelSetContainer.begin(); for (; layerIter != m_LabelSetContainer.end(); ++layerIter) totalLabels += (*layerIter)->GetNumberOfLabels(); return totalLabels; } void mitk::LabelSetImage::MaskStamp(mitk::Image *mask, bool forceOverwrite) { try { mitk::PadImageFilter::Pointer padImageFilter = mitk::PadImageFilter::New(); padImageFilter->SetInput(0, mask); padImageFilter->SetInput(1, this); padImageFilter->SetPadConstant(0); padImageFilter->SetBinaryFilter(false); padImageFilter->SetLowerThreshold(0); padImageFilter->SetUpperThreshold(1); padImageFilter->Update(); mitk::Image::Pointer paddedMask = padImageFilter->GetOutput(); if (paddedMask.IsNull()) return; AccessByItk_2(this, MaskStampProcessing, paddedMask, forceOverwrite); } catch (...) { mitkThrow() << "Could not stamp the provided mask on the selected label."; } } mitk::Image::Pointer mitk::LabelSetImage::CreateLabelMask(PixelType index) { mitk::Image::Pointer mask = mitk::Image::New(); try { mask->Initialize(this); unsigned int byteSize = sizeof(LabelSetImage::PixelType); for (unsigned int dim = 0; dim < mask->GetDimension(); ++dim) { byteSize *= mask->GetDimension(dim); } mitk::ImageWriteAccessor *accessor = new mitk::ImageWriteAccessor(static_cast(mask)); memset(accessor->GetData(), 0, byteSize); delete accessor; auto geometry = this->GetTimeGeometry()->Clone(); mask->SetTimeGeometry(geometry); AccessByItk_2(this, CreateLabelMaskProcessing, mask, index); } catch (...) { mitkThrow() << "Could not create a mask out of the selected label."; } return mask; } void mitk::LabelSetImage::InitializeByLabeledImage(mitk::Image::Pointer image) { if (image.IsNull() || image->IsEmpty() || !image->IsInitialized()) mitkThrow() << "Invalid labeled image."; try { this->Initialize(image); unsigned int byteSize = sizeof(LabelSetImage::PixelType); for (unsigned int dim = 0; dim < image->GetDimension(); ++dim) { byteSize *= image->GetDimension(dim); } mitk::ImageWriteAccessor *accessor = new mitk::ImageWriteAccessor(static_cast(this)); memset(accessor->GetData(), 0, byteSize); delete accessor; auto geometry = image->GetTimeGeometry()->Clone(); this->SetTimeGeometry(geometry); if (image->GetDimension() == 3) { AccessTwoImagesFixedDimensionByItk(this, image, InitializeByLabeledImageProcessing, 3); } else if (image->GetDimension() == 4) { AccessTwoImagesFixedDimensionByItk(this, image, InitializeByLabeledImageProcessing, 4); } else { mitkThrow() << image->GetDimension() << "-dimensional label set images not yet supported"; } } catch (...) { mitkThrow() << "Could not intialize by provided labeled image."; } this->Modified(); } template void mitk::LabelSetImage::InitializeByLabeledImageProcessing(LabelSetImageType *labelSetImage, ImageType *image) { typedef itk::ImageRegionConstIteratorWithIndex SourceIteratorType; typedef itk::ImageRegionIterator TargetIteratorType; TargetIteratorType targetIter(labelSetImage, labelSetImage->GetRequestedRegion()); targetIter.GoToBegin(); SourceIteratorType sourceIter(image, image->GetRequestedRegion()); sourceIter.GoToBegin(); while (!sourceIter.IsAtEnd()) { PixelType sourceValue = static_cast(sourceIter.Get()); targetIter.Set(sourceValue); if (!this->ExistLabel(sourceValue)) { std::stringstream name; name << "object-" << sourceValue; double rgba[4]; m_LabelSetContainer[this->GetActiveLayer()]->GetLookupTable()->GetTableValue(sourceValue, rgba); mitk::Color color; color.SetRed(rgba[0]); color.SetGreen(rgba[1]); color.SetBlue(rgba[2]); auto label = mitk::Label::New(); label->SetName(name.str().c_str()); label->SetColor(color); label->SetOpacity(rgba[3]); label->SetValue(sourceValue); this->GetLabelSet()->AddLabel(label); if (GetActiveLabelSet()->GetNumberOfLabels() >= mitk::Label::MAX_LABEL_VALUE || sourceValue >= mitk::Label::MAX_LABEL_VALUE) this->AddLayer(); } ++sourceIter; ++targetIter; } } template void mitk::LabelSetImage::MaskStampProcessing(ImageType *itkImage, mitk::Image *mask, bool forceOverwrite) { typename ImageType::Pointer itkMask; mitk::CastToItkImage(mask, itkMask); typedef itk::ImageRegionConstIterator SourceIteratorType; typedef itk::ImageRegionIterator TargetIteratorType; SourceIteratorType sourceIter(itkMask, itkMask->GetLargestPossibleRegion()); sourceIter.GoToBegin(); TargetIteratorType targetIter(itkImage, itkImage->GetLargestPossibleRegion()); targetIter.GoToBegin(); int activeLabel = this->GetActiveLabel(GetActiveLayer())->GetValue(); while (!sourceIter.IsAtEnd()) { PixelType sourceValue = sourceIter.Get(); PixelType targetValue = targetIter.Get(); if ((sourceValue != 0) && (forceOverwrite || !this->GetLabel(targetValue)->GetLocked())) // skip exterior and locked labels { targetIter.Set(activeLabel); } ++sourceIter; ++targetIter; } this->Modified(); } template void mitk::LabelSetImage::CreateLabelMaskProcessing(ImageType *itkImage, mitk::Image *mask, PixelType index) { typename ImageType::Pointer itkMask; mitk::CastToItkImage(mask, itkMask); typedef itk::ImageRegionConstIterator SourceIteratorType; typedef itk::ImageRegionIterator TargetIteratorType; SourceIteratorType sourceIter(itkImage, itkImage->GetLargestPossibleRegion()); sourceIter.GoToBegin(); TargetIteratorType targetIter(itkMask, itkMask->GetLargestPossibleRegion()); targetIter.GoToBegin(); while (!sourceIter.IsAtEnd()) { PixelType sourceValue = sourceIter.Get(); if (sourceValue == index) { targetIter.Set(1); } ++sourceIter; ++targetIter; } } template void mitk::LabelSetImage::CalculateCenterOfMassProcessing(ImageType *itkImage, PixelType pixelValue, unsigned int layer) { // for now, we just retrieve the voxel in the middle typedef itk::ImageRegionConstIterator IteratorType; IteratorType iter(itkImage, itkImage->GetLargestPossibleRegion()); iter.GoToBegin(); std::vector indexVector; while (!iter.IsAtEnd()) { // TODO fix comparison warning more effective if (iter.Get() == pixelValue) { indexVector.push_back(iter.GetIndex()); } ++iter; } mitk::Point3D pos; pos.Fill(0.0); if (!indexVector.empty()) { typename itk::ImageRegionConstIteratorWithIndex::IndexType centerIndex; centerIndex = indexVector.at(indexVector.size() / 2); if (centerIndex.GetIndexDimension() == 3) { pos[0] = centerIndex[0]; pos[1] = centerIndex[1]; pos[2] = centerIndex[2]; } else return; } GetLabelSet(layer)->GetLabel(pixelValue)->SetCenterOfMassIndex(pos); this->GetSlicedGeometry()->IndexToWorld(pos, pos); // TODO: TimeGeometry? GetLabelSet(layer)->GetLabel(pixelValue)->SetCenterOfMassCoordinates(pos); } template void mitk::LabelSetImage::ClearBufferProcessing(ImageType *itkImage) { itkImage->FillBuffer(0); } // todo: concatenate all layers and not just the active one template void mitk::LabelSetImage::ConcatenateProcessing(ImageType *itkTarget, mitk::LabelSetImage *other) { typename ImageType::Pointer itkSource = ImageType::New(); mitk::CastToItkImage(other, itkSource); typedef itk::ImageRegionConstIterator ConstIteratorType; typedef itk::ImageRegionIterator IteratorType; ConstIteratorType sourceIter(itkSource, itkSource->GetLargestPossibleRegion()); IteratorType targetIter(itkTarget, itkTarget->GetLargestPossibleRegion()); int numberOfTargetLabels = this->GetNumberOfLabels(GetActiveLayer()) - 1; // skip exterior sourceIter.GoToBegin(); targetIter.GoToBegin(); while (!sourceIter.IsAtEnd()) { PixelType sourceValue = sourceIter.Get(); PixelType targetValue = targetIter.Get(); if ((sourceValue != 0) && !this->GetLabel(targetValue)->GetLocked()) // skip exterior and locked labels { targetIter.Set(sourceValue + numberOfTargetLabels); } ++sourceIter; ++targetIter; } } template void mitk::LabelSetImage::LayerContainerToImageProcessing(itk::Image *target, unsigned int layer) { typedef itk::Image ImageType; typename ImageType::Pointer itkSource; // mitk::CastToItkImage(m_LayerContainer[layer], itkSource); itkSource = ImageToItkImage(m_LayerContainer[layer]); typedef itk::ImageRegionConstIterator SourceIteratorType; typedef itk::ImageRegionIterator TargetIteratorType; SourceIteratorType sourceIter(itkSource, itkSource->GetLargestPossibleRegion()); sourceIter.GoToBegin(); TargetIteratorType targetIter(target, target->GetLargestPossibleRegion()); targetIter.GoToBegin(); while (!sourceIter.IsAtEnd()) { targetIter.Set(sourceIter.Get()); ++sourceIter; ++targetIter; } } template void mitk::LabelSetImage::ImageToLayerContainerProcessing(itk::Image *source, unsigned int layer) const { typedef itk::Image ImageType; typename ImageType::Pointer itkTarget; // mitk::CastToItkImage(m_LayerContainer[layer], itkTarget); itkTarget = ImageToItkImage(m_LayerContainer[layer]); typedef itk::ImageRegionConstIterator SourceIteratorType; typedef itk::ImageRegionIterator TargetIteratorType; SourceIteratorType sourceIter(source, source->GetLargestPossibleRegion()); sourceIter.GoToBegin(); TargetIteratorType targetIter(itkTarget, itkTarget->GetLargestPossibleRegion()); targetIter.GoToBegin(); while (!sourceIter.IsAtEnd()) { targetIter.Set(sourceIter.Get()); ++sourceIter; ++targetIter; } } template void mitk::LabelSetImage::EraseLabelProcessing(ImageType *itkImage, PixelType pixelValue, unsigned int /*layer*/) { typedef itk::ImageRegionIterator IteratorType; IteratorType iter(itkImage, itkImage->GetLargestPossibleRegion()); iter.GoToBegin(); while (!iter.IsAtEnd()) { PixelType value = iter.Get(); if (value == pixelValue) { iter.Set(0); } ++iter; } } template void mitk::LabelSetImage::MergeLabelProcessing(ImageType *itkImage, PixelType pixelValue, PixelType index) { typedef itk::ImageRegionIterator IteratorType; IteratorType iter(itkImage, itkImage->GetLargestPossibleRegion()); iter.GoToBegin(); while (!iter.IsAtEnd()) { if (iter.Get() == index) { iter.Set(pixelValue); } ++iter; } } bool mitk::Equal(const mitk::LabelSetImage &leftHandSide, const mitk::LabelSetImage &rightHandSide, ScalarType eps, bool verbose) { bool returnValue = true; /* LabelSetImage members */ MITK_INFO(verbose) << "--- LabelSetImage Equal ---"; // number layers returnValue = leftHandSide.GetNumberOfLayers() == rightHandSide.GetNumberOfLayers(); if (!returnValue) { MITK_INFO(verbose) << "Number of layers not equal."; return false; } // total number labels returnValue = leftHandSide.GetTotalNumberOfLabels() == rightHandSide.GetTotalNumberOfLabels(); if (!returnValue) { MITK_INFO(verbose) << "Total number of labels not equal."; return false; } // active layer returnValue = leftHandSide.GetActiveLayer() == rightHandSide.GetActiveLayer(); if (!returnValue) { MITK_INFO(verbose) << "Active layer not equal."; return false; } if (4 == leftHandSide.GetDimension()) { MITK_INFO(verbose) << "Can not compare image data for 4D images - skipping check."; } else { // working image data returnValue = mitk::Equal((const mitk::Image &)leftHandSide, (const mitk::Image &)rightHandSide, eps, verbose); if (!returnValue) { MITK_INFO(verbose) << "Working image data not equal."; return false; } } for (unsigned int layerIndex = 0; layerIndex < leftHandSide.GetNumberOfLayers(); layerIndex++) { if (4 == leftHandSide.GetDimension()) { MITK_INFO(verbose) << "Can not compare image data for 4D images - skipping check."; } else { // layer image data returnValue = mitk::Equal(*leftHandSide.GetLayerImage(layerIndex), *rightHandSide.GetLayerImage(layerIndex), eps, verbose); if (!returnValue) { MITK_INFO(verbose) << "Layer image data not equal."; return false; } } // layer labelset data returnValue = mitk::Equal(*leftHandSide.GetLabelSet(layerIndex), *rightHandSide.GetLabelSet(layerIndex), eps, verbose); if (!returnValue) { MITK_INFO(verbose) << "Layer labelset data not equal."; return false; } } return returnValue; } diff --git a/Modules/Multilabel/mitkLabelSetImageVtkMapper2D.cpp b/Modules/Multilabel/mitkLabelSetImageVtkMapper2D.cpp index 81814c3fd3..e63b04e038 100644 --- a/Modules/Multilabel/mitkLabelSetImageVtkMapper2D.cpp +++ b/Modules/Multilabel/mitkLabelSetImageVtkMapper2D.cpp @@ -1,650 +1,650 @@ /*=================================================================== The Medical Imaging Interaction Toolkit (MITK) Copyright (c) German Cancer Research Center, Division of Medical and Biological Informatics. All rights reserved. This software is distributed WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See LICENSE.txt or http://www.mitk.org for details. ===================================================================*/ #include "mitkLabelSetImageVtkMapper2D.h" // MITK #include #include #include #include #include #include #include #include #include #include #include #include #include #include // MITK Rendering #include "vtkMitkLevelWindowFilter.h" #include "vtkMitkThickSlicesFilter.h" #include "vtkNeverTranslucentTexture.h" // VTK #include #include #include #include #include #include #include #include #include #include #include #include //#include // ITK #include #include mitk::LabelSetImageVtkMapper2D::LabelSetImageVtkMapper2D() { } mitk::LabelSetImageVtkMapper2D::~LabelSetImageVtkMapper2D() { } vtkProp *mitk::LabelSetImageVtkMapper2D::GetVtkProp(mitk::BaseRenderer *renderer) { // return the actor corresponding to the renderer return m_LSH.GetLocalStorage(renderer)->m_Actors; } mitk::LabelSetImageVtkMapper2D::LocalStorage *mitk::LabelSetImageVtkMapper2D::GetLocalStorage( mitk::BaseRenderer *renderer) { return m_LSH.GetLocalStorage(renderer); } void mitk::LabelSetImageVtkMapper2D::GenerateDataForRenderer(mitk::BaseRenderer *renderer) { LocalStorage *localStorage = m_LSH.GetLocalStorage(renderer); mitk::DataNode *node = this->GetDataNode(); mitk::LabelSetImage *image = dynamic_cast(node->GetData()); assert(image && image->IsInitialized()); // check if there is a valid worldGeometry const PlaneGeometry *worldGeometry = renderer->GetCurrentWorldPlaneGeometry(); if ((worldGeometry == NULL) || (!worldGeometry->IsValid()) || (!worldGeometry->HasReferenceGeometry())) return; image->Update(); int numberOfLayers = image->GetNumberOfLayers(); int activeLayer = image->GetActiveLayer(); float opacity = 1.0f; node->GetOpacity(opacity, renderer, "opacity"); if (numberOfLayers != localStorage->m_NumberOfLayers) { localStorage->m_NumberOfLayers = numberOfLayers; localStorage->m_ReslicedImageVector.clear(); localStorage->m_ReslicerVector.clear(); localStorage->m_LayerTextureVector.clear(); localStorage->m_LevelWindowFilterVector.clear(); localStorage->m_LayerMapperVector.clear(); localStorage->m_LayerActorVector.clear(); localStorage->m_Actors = vtkSmartPointer::New(); for (int lidx = 0; lidx < numberOfLayers; ++lidx) { localStorage->m_ReslicedImageVector.push_back(vtkSmartPointer::New()); localStorage->m_ReslicerVector.push_back(mitk::ExtractSliceFilter::New()); localStorage->m_LayerTextureVector.push_back(vtkSmartPointer::New()); localStorage->m_LevelWindowFilterVector.push_back(vtkSmartPointer::New()); localStorage->m_LayerMapperVector.push_back(vtkSmartPointer::New()); localStorage->m_LayerActorVector.push_back(vtkSmartPointer::New()); // do not repeat the texture (the image) localStorage->m_LayerTextureVector[lidx]->RepeatOff(); // set corresponding mappers for the actors localStorage->m_LayerActorVector[lidx]->SetMapper(localStorage->m_LayerMapperVector[lidx]); localStorage->m_Actors->AddPart(localStorage->m_LayerActorVector[lidx]); } localStorage->m_Actors->AddPart(localStorage->m_OutlineShadowActor); localStorage->m_Actors->AddPart(localStorage->m_OutlineActor); } // early out if there is no intersection of the current rendering geometry // and the geometry of the image that is to be rendered. if (!RenderingGeometryIntersectsImage(worldGeometry, image->GetSlicedGeometry())) { // set image to NULL, to clear the texture in 3D, because // the latest image is used there if the plane is out of the geometry // see bug-13275 for (int lidx = 0; lidx < numberOfLayers; ++lidx) { localStorage->m_ReslicedImageVector[lidx] = NULL; localStorage->m_LayerMapperVector[lidx]->SetInputData(localStorage->m_EmptyPolyData); localStorage->m_OutlineActor->SetVisibility(false); localStorage->m_OutlineShadowActor->SetVisibility(false); } return; } for (int lidx = 0; lidx < numberOfLayers; ++lidx) { mitk::Image *layerImage = NULL; // set main input for ExtractSliceFilter if (lidx == activeLayer) layerImage = image; else layerImage = image->GetLayerImage(lidx); localStorage->m_ReslicerVector[lidx]->SetInput(layerImage); localStorage->m_ReslicerVector[lidx]->SetWorldGeometry(worldGeometry); localStorage->m_ReslicerVector[lidx]->SetTimeStep(this->GetTimestep()); // set the transformation of the image to adapt reslice axis localStorage->m_ReslicerVector[lidx]->SetResliceTransformByGeometry( layerImage->GetTimeGeometry()->GetGeometryForTimeStep(this->GetTimestep())); // is the geometry of the slice based on the image image or the worldgeometry? bool inPlaneResampleExtentByGeometry = false; node->GetBoolProperty("in plane resample extent by geometry", inPlaneResampleExtentByGeometry, renderer); localStorage->m_ReslicerVector[lidx]->SetInPlaneResampleExtentByGeometry(inPlaneResampleExtentByGeometry); localStorage->m_ReslicerVector[lidx]->SetInterpolationMode(ExtractSliceFilter::RESLICE_NEAREST); localStorage->m_ReslicerVector[lidx]->SetVtkOutputRequest(true); - // this is needed when thick mode was enable bevore. These variable have to be reset to default values + // this is needed when thick mode was enabled before. These variables have to be reset to default values localStorage->m_ReslicerVector[lidx]->SetOutputDimensionality(2); localStorage->m_ReslicerVector[lidx]->SetOutputSpacingZDirection(1.0); localStorage->m_ReslicerVector[lidx]->SetOutputExtentZDirection(0, 0); - // Bounds information for reslicing (only reuqired if reference geometry is present) + // Bounds information for reslicing (only required if reference geometry is present) // this used for generating a vtkPLaneSource with the right size double sliceBounds[6]; sliceBounds[0] = 0.0; sliceBounds[1] = 0.0; sliceBounds[2] = 0.0; sliceBounds[3] = 0.0; sliceBounds[4] = 0.0; sliceBounds[5] = 0.0; localStorage->m_ReslicerVector[lidx]->GetClippedPlaneBounds(sliceBounds); // setup the textured plane this->GeneratePlane(renderer, sliceBounds); // get the spacing of the slice localStorage->m_mmPerPixel = localStorage->m_ReslicerVector[lidx]->GetOutputSpacing(); localStorage->m_ReslicerVector[lidx]->Modified(); // start the pipeline with updating the largest possible, needed if the geometry of the image has changed localStorage->m_ReslicerVector[lidx]->UpdateLargestPossibleRegion(); localStorage->m_ReslicedImageVector[lidx] = localStorage->m_ReslicerVector[lidx]->GetVtkOutput(); - localStorage->m_OutlineActor->GetProperty()->SetOpacity(opacity); - localStorage->m_OutlineShadowActor->GetProperty()->SetOpacity(opacity); - const PlaneGeometry *planeGeometry = dynamic_cast(worldGeometry); double textureClippingBounds[6]; for (auto &textureClippingBound : textureClippingBounds) { textureClippingBound = 0.0; } // Calculate the actual bounds of the transformed plane clipped by the // dataset bounding box; this is required for drawing the texture at the // correct position during 3D mapping. mitk::PlaneClipping::CalculateClippedPlaneBounds(layerImage->GetGeometry(), planeGeometry, textureClippingBounds); textureClippingBounds[0] = static_cast(textureClippingBounds[0] / localStorage->m_mmPerPixel[0] + 0.5); textureClippingBounds[1] = static_cast(textureClippingBounds[1] / localStorage->m_mmPerPixel[0] + 0.5); textureClippingBounds[2] = static_cast(textureClippingBounds[2] / localStorage->m_mmPerPixel[1] + 0.5); textureClippingBounds[3] = static_cast(textureClippingBounds[3] / localStorage->m_mmPerPixel[1] + 0.5); // clipping bounds for cutting the imageLayer localStorage->m_LevelWindowFilterVector[lidx]->SetClippingBounds(textureClippingBounds); - float contourWidth(2.0); - node->GetFloatProperty("labelset.contour.width", contourWidth, renderer); - - localStorage->m_OutlineActor->GetProperty()->SetLineWidth(contourWidth); - localStorage->m_OutlineShadowActor->GetProperty()->SetLineWidth(contourWidth * 1.5); - localStorage->m_LevelWindowFilterVector[lidx]->SetLookupTable( image->GetLabelSet(lidx)->GetLookupTable()->GetVtkLookupTable()); // do not use a VTK lookup table (we do that ourselves in m_LevelWindowFilter) localStorage->m_LayerTextureVector[lidx]->MapColorScalarsThroughLookupTableOff(); // connect the imageLayer with the levelwindow filter localStorage->m_LevelWindowFilterVector[lidx]->SetInputData(localStorage->m_ReslicedImageVector[lidx]); // connect the texture with the output of the levelwindow filter // check for texture interpolation property bool textureInterpolation = false; node->GetBoolProperty("texture interpolation", textureInterpolation, renderer); // set the interpolation modus according to the property localStorage->m_LayerTextureVector[lidx]->SetInterpolate(textureInterpolation); localStorage->m_LayerTextureVector[lidx]->SetInputConnection( localStorage->m_LevelWindowFilterVector[lidx]->GetOutputPort()); this->TransformActor(renderer); // set the plane as input for the mapper localStorage->m_LayerMapperVector[lidx]->SetInputConnection(localStorage->m_Plane->GetOutputPort()); - // set the texture for the actor + // set the texture for the actor localStorage->m_LayerActorVector[lidx]->SetTexture(localStorage->m_LayerTextureVector[lidx]); - localStorage->m_LayerActorVector[lidx]->GetProperty()->SetOpacity(opacity); } - if (image->GetActiveLabel(image->GetActiveLayer())) - { - int pixelValue = image->GetActiveLabel(image->GetActiveLayer())->GetValue(); - // MITK_INFO << "pixValue VTK " << pixelValue; - // generate contours/outlines - localStorage->m_OutlinePolyData = - this->CreateOutlinePolyData(renderer, localStorage->m_ReslicedImageVector[image->GetActiveLayer()], pixelValue); - localStorage->m_OutlineActor->SetVisibility(true); - localStorage->m_OutlineShadowActor->SetVisibility(true); - const mitk::Color &color = image->GetActiveLabel(image->GetActiveLayer())->GetColor(); - localStorage->m_OutlineActor->GetProperty()->SetColor(color.GetRed(), color.GetGreen(), color.GetBlue()); - localStorage->m_OutlineShadowActor->GetProperty()->SetColor(0, 0, 0); - localStorage->m_OutlineMapper->SetInputData(localStorage->m_OutlinePolyData); - } - else + mitk::Label* activeLabel = image->GetActiveLabel(activeLayer); + if (nullptr != activeLabel) { - localStorage->m_OutlineActor->SetVisibility(false); - localStorage->m_OutlineShadowActor->SetVisibility(false); + bool contourActive = false; + node->GetBoolProperty("labelset.contour.active", contourActive, renderer); + if (contourActive && activeLabel->GetVisible()) //contour rendering + { + //generate contours/outlines + localStorage->m_OutlinePolyData = + this->CreateOutlinePolyData(renderer, localStorage->m_ReslicedImageVector[activeLayer], activeLabel->GetValue()); + localStorage->m_OutlineActor->SetVisibility(true); + localStorage->m_OutlineShadowActor->SetVisibility(true); + const mitk::Color& color = activeLabel->GetColor(); + localStorage->m_OutlineActor->GetProperty()->SetColor(color.GetRed(), color.GetGreen(), color.GetBlue()); + localStorage->m_OutlineShadowActor->GetProperty()->SetColor(0, 0, 0); + + float contourWidth(2.0); + node->GetFloatProperty("labelset.contour.width", contourWidth, renderer); + localStorage->m_OutlineActor->GetProperty()->SetLineWidth(contourWidth); + localStorage->m_OutlineShadowActor->GetProperty()->SetLineWidth(contourWidth * 1.5); + + localStorage->m_OutlineActor->GetProperty()->SetOpacity(opacity); + localStorage->m_OutlineShadowActor->GetProperty()->SetOpacity(opacity); + + localStorage->m_OutlineMapper->SetInputData(localStorage->m_OutlinePolyData); + return; + } } + localStorage->m_OutlineActor->SetVisibility(false); + localStorage->m_OutlineShadowActor->SetVisibility(false); } bool mitk::LabelSetImageVtkMapper2D::RenderingGeometryIntersectsImage(const PlaneGeometry *renderingGeometry, SlicedGeometry3D *imageGeometry) { // if either one of the two geometries is NULL we return true // for safety reasons if (renderingGeometry == NULL || imageGeometry == NULL) return true; // get the distance for the first cornerpoint ScalarType initialDistance = renderingGeometry->SignedDistance(imageGeometry->GetCornerPoint(0)); for (int i = 1; i < 8; i++) { mitk::Point3D cornerPoint = imageGeometry->GetCornerPoint(i); // get the distance to the other cornerpoints ScalarType distance = renderingGeometry->SignedDistance(cornerPoint); // if it has not the same signing as the distance of the first point if (initialDistance * distance < 0) { // we have an intersection and return true return true; } } // all distances have the same sign, no intersection and we return false return false; } vtkSmartPointer mitk::LabelSetImageVtkMapper2D::CreateOutlinePolyData(mitk::BaseRenderer *renderer, vtkImageData *image, int pixelValue) { LocalStorage *localStorage = this->GetLocalStorage(renderer); // get the min and max index values of each direction int *extent = image->GetExtent(); int xMin = extent[0]; int xMax = extent[1]; int yMin = extent[2]; int yMax = extent[3]; int *dims = image->GetDimensions(); // dimensions of the image int line = dims[0]; // how many pixels per line? int x = xMin; // pixel index x int y = yMin; // pixel index y // get the depth for each contour float depth = this->CalculateLayerDepth(renderer); vtkSmartPointer points = vtkSmartPointer::New(); // the points to draw vtkSmartPointer lines = vtkSmartPointer::New(); // the lines to connect the points // We take the pointer to the first pixel of the image mitk::Label::PixelType *currentPixel = static_cast(image->GetScalarPointer()); while (y <= yMax) { // if the current pixel value is set to something if ((currentPixel) && (*currentPixel == pixelValue)) { // check in which direction a line is necessary // a line is added if the neighbor of the current pixel has the value 0 // and if the pixel is located at the edge of the image // if vvvvv not the first line vvvvv if (y > yMin && *(currentPixel - line) != pixelValue) { // x direction - bottom edge of the pixel // add the 2 points vtkIdType p1 = points->InsertNextPoint(x * localStorage->m_mmPerPixel[0], y * localStorage->m_mmPerPixel[1], depth); vtkIdType p2 = points->InsertNextPoint((x + 1) * localStorage->m_mmPerPixel[0], y * localStorage->m_mmPerPixel[1], depth); // add the line between both points lines->InsertNextCell(2); lines->InsertCellPoint(p1); lines->InsertCellPoint(p2); } // if vvvvv not the last line vvvvv if (y < yMax && *(currentPixel + line) != pixelValue) { // x direction - top edge of the pixel vtkIdType p1 = points->InsertNextPoint(x * localStorage->m_mmPerPixel[0], (y + 1) * localStorage->m_mmPerPixel[1], depth); vtkIdType p2 = points->InsertNextPoint( (x + 1) * localStorage->m_mmPerPixel[0], (y + 1) * localStorage->m_mmPerPixel[1], depth); lines->InsertNextCell(2); lines->InsertCellPoint(p1); lines->InsertCellPoint(p2); } // if vvvvv not the first pixel vvvvv if ((x > xMin || y > yMin) && *(currentPixel - 1) != pixelValue) { // y direction - left edge of the pixel vtkIdType p1 = points->InsertNextPoint(x * localStorage->m_mmPerPixel[0], y * localStorage->m_mmPerPixel[1], depth); vtkIdType p2 = points->InsertNextPoint(x * localStorage->m_mmPerPixel[0], (y + 1) * localStorage->m_mmPerPixel[1], depth); lines->InsertNextCell(2); lines->InsertCellPoint(p1); lines->InsertCellPoint(p2); } // if vvvvv not the last pixel vvvvv if ((y < yMax || (x < xMax)) && *(currentPixel + 1) != pixelValue) { // y direction - right edge of the pixel vtkIdType p1 = points->InsertNextPoint((x + 1) * localStorage->m_mmPerPixel[0], y * localStorage->m_mmPerPixel[1], depth); vtkIdType p2 = points->InsertNextPoint( (x + 1) * localStorage->m_mmPerPixel[0], (y + 1) * localStorage->m_mmPerPixel[1], depth); lines->InsertNextCell(2); lines->InsertCellPoint(p1); lines->InsertCellPoint(p2); } /* now consider pixels at the edge of the image */ // if vvvvv left edge of image vvvvv if (x == xMin) { // draw left edge of the pixel vtkIdType p1 = points->InsertNextPoint(x * localStorage->m_mmPerPixel[0], y * localStorage->m_mmPerPixel[1], depth); vtkIdType p2 = points->InsertNextPoint(x * localStorage->m_mmPerPixel[0], (y + 1) * localStorage->m_mmPerPixel[1], depth); lines->InsertNextCell(2); lines->InsertCellPoint(p1); lines->InsertCellPoint(p2); } // if vvvvv right edge of image vvvvv if (x == xMax) { // draw right edge of the pixel vtkIdType p1 = points->InsertNextPoint((x + 1) * localStorage->m_mmPerPixel[0], y * localStorage->m_mmPerPixel[1], depth); vtkIdType p2 = points->InsertNextPoint( (x + 1) * localStorage->m_mmPerPixel[0], (y + 1) * localStorage->m_mmPerPixel[1], depth); lines->InsertNextCell(2); lines->InsertCellPoint(p1); lines->InsertCellPoint(p2); } // if vvvvv bottom edge of image vvvvv if (y == yMin) { // draw bottom edge of the pixel vtkIdType p1 = points->InsertNextPoint(x * localStorage->m_mmPerPixel[0], y * localStorage->m_mmPerPixel[1], depth); vtkIdType p2 = points->InsertNextPoint((x + 1) * localStorage->m_mmPerPixel[0], y * localStorage->m_mmPerPixel[1], depth); lines->InsertNextCell(2); lines->InsertCellPoint(p1); lines->InsertCellPoint(p2); } // if vvvvv top edge of image vvvvv if (y == yMax) { // draw top edge of the pixel vtkIdType p1 = points->InsertNextPoint(x * localStorage->m_mmPerPixel[0], (y + 1) * localStorage->m_mmPerPixel[1], depth); vtkIdType p2 = points->InsertNextPoint( (x + 1) * localStorage->m_mmPerPixel[0], (y + 1) * localStorage->m_mmPerPixel[1], depth); lines->InsertNextCell(2); lines->InsertCellPoint(p1); lines->InsertCellPoint(p2); } } // end if currentpixel is set x++; if (x > xMax) { // reached end of line x = xMin; y++; } // Increase the pointer-position to the next pixel. // This is safe, as the while-loop and the x-reset logic above makes // sure we do not exceed the bounds of the image currentPixel++; } // end of while // Create a polydata to store everything in vtkSmartPointer polyData = vtkSmartPointer::New(); // Add the points to the dataset polyData->SetPoints(points); // Add the lines to the dataset polyData->SetLines(lines); return polyData; } void mitk::LabelSetImageVtkMapper2D::ApplyColor(mitk::BaseRenderer *renderer, const mitk::Color &color) { LocalStorage *localStorage = this->GetLocalStorage(renderer); localStorage->m_OutlineActor->GetProperty()->SetColor(color.GetRed(), color.GetGreen(), color.GetBlue()); localStorage->m_OutlineShadowActor->GetProperty()->SetColor(0, 0, 0); } void mitk::LabelSetImageVtkMapper2D::ApplyOpacity(mitk::BaseRenderer *renderer, int layer) { LocalStorage *localStorage = this->GetLocalStorage(renderer); float opacity = 1.0f; this->GetDataNode()->GetOpacity(opacity, renderer, "opacity"); localStorage->m_LayerActorVector[layer]->GetProperty()->SetOpacity(opacity); localStorage->m_OutlineActor->GetProperty()->SetOpacity(opacity); localStorage->m_OutlineShadowActor->GetProperty()->SetOpacity(opacity); } void mitk::LabelSetImageVtkMapper2D::ApplyLookuptable(mitk::BaseRenderer *renderer, int layer) { LocalStorage *localStorage = m_LSH.GetLocalStorage(renderer); mitk::LabelSetImage *input = dynamic_cast(this->GetDataNode()->GetData()); localStorage->m_LevelWindowFilterVector[layer]->SetLookupTable( input->GetLabelSet(layer)->GetLookupTable()->GetVtkLookupTable()); } void mitk::LabelSetImageVtkMapper2D::Update(mitk::BaseRenderer *renderer) { bool visible = true; const DataNode *node = this->GetDataNode(); node->GetVisibility(visible, renderer, "visible"); if (!visible) return; mitk::LabelSetImage *image = dynamic_cast(node->GetData()); if (image == NULL || image->IsInitialized() == false) return; // Calculate time step of the image data for the specified renderer (integer value) this->CalculateTimeStep(renderer); // Check if time step is valid const TimeGeometry *dataTimeGeometry = image->GetTimeGeometry(); if ((dataTimeGeometry == NULL) || (dataTimeGeometry->CountTimeSteps() == 0) || (!dataTimeGeometry->IsValidTimeStep(this->GetTimestep()))) { return; } image->UpdateOutputInformation(); LocalStorage *localStorage = m_LSH.GetLocalStorage(renderer); // check if something important has changed and we need to re-render //(localStorage->m_LastDataUpdateTime < node->GetMTime()) // this one is too generic if ((localStorage->m_LastDataUpdateTime < image->GetMTime()) // was the data modified? || (localStorage->m_LastDataUpdateTime < image->GetPipelineMTime()) || (localStorage->m_LastDataUpdateTime < renderer->GetCurrentWorldPlaneGeometryUpdateTime()) // was the geometry modified? || (localStorage->m_LastDataUpdateTime < renderer->GetCurrentWorldPlaneGeometry()->GetMTime())) { this->GenerateDataForRenderer(renderer); localStorage->m_LastDataUpdateTime.Modified(); } } // set the two points defining the textured plane according to the dimension and spacing void mitk::LabelSetImageVtkMapper2D::GeneratePlane(mitk::BaseRenderer *renderer, double planeBounds[6]) { LocalStorage *localStorage = m_LSH.GetLocalStorage(renderer); float depth = this->CalculateLayerDepth(renderer); // Set the origin to (xMin; yMin; depth) of the plane. This is necessary for obtaining the correct // plane size in crosshair rotation and swivel mode. localStorage->m_Plane->SetOrigin(planeBounds[0], planeBounds[2], depth); // These two points define the axes of the plane in combination with the origin. // Point 1 is the x-axis and point 2 the y-axis. // Each plane is transformed according to the view (axial, coronal and saggital) afterwards. localStorage->m_Plane->SetPoint1(planeBounds[1], planeBounds[2], depth); // P1: (xMax, yMin, depth) localStorage->m_Plane->SetPoint2(planeBounds[0], planeBounds[3], depth); // P2: (xMin, yMax, depth) } float mitk::LabelSetImageVtkMapper2D::CalculateLayerDepth(mitk::BaseRenderer *renderer) { // get the clipping range to check how deep into z direction we can render images double maxRange = renderer->GetVtkRenderer()->GetActiveCamera()->GetClippingRange()[1]; // Due to a VTK bug, we cannot use the whole clipping range. /100 is empirically determined float depth = -maxRange * 0.01; // divide by 100 int layer = 0; GetDataNode()->GetIntProperty("layer", layer, renderer); // add the layer property for each image to render images with a higher layer on top of the others depth += layer * 10; //*10: keep some room for each image (e.g. for QBalls in between) if (depth > 0.0f) { depth = 0.0f; MITK_WARN << "Layer value exceeds clipping range. Set to minimum instead."; } return depth; } void mitk::LabelSetImageVtkMapper2D::TransformActor(mitk::BaseRenderer *renderer) { LocalStorage *localStorage = m_LSH.GetLocalStorage(renderer); // get the transformation matrix of the reslicer in order to render the slice as axial, coronal or saggital vtkSmartPointer trans = vtkSmartPointer::New(); vtkSmartPointer matrix = localStorage->m_ReslicerVector[0]->GetResliceAxes(); // same for all layers trans->SetMatrix(matrix); for (int lidx = 0; lidx < localStorage->m_NumberOfLayers; ++lidx) { // transform the plane/contour (the actual actor) to the corresponding view (axial, coronal or saggital) localStorage->m_LayerActorVector[lidx]->SetUserTransform(trans); // transform the origin to center based coordinates, because MITK is center based. localStorage->m_LayerActorVector[lidx]->SetPosition( -0.5 * localStorage->m_mmPerPixel[0], -0.5 * localStorage->m_mmPerPixel[1], 0.0); } // same for outline actor localStorage->m_OutlineActor->SetUserTransform(trans); localStorage->m_OutlineActor->SetPosition( -0.5 * localStorage->m_mmPerPixel[0], -0.5 * localStorage->m_mmPerPixel[1], 0.0); // same for outline shadow actor localStorage->m_OutlineShadowActor->SetUserTransform(trans); localStorage->m_OutlineShadowActor->SetPosition( -0.5 * localStorage->m_mmPerPixel[0], -0.5 * localStorage->m_mmPerPixel[1], 0.0); } void mitk::LabelSetImageVtkMapper2D::SetDefaultProperties(mitk::DataNode *node, mitk::BaseRenderer *renderer, bool overwrite) { // add/replace the following properties node->SetProperty("opacity", FloatProperty::New(1.0f), renderer); node->SetProperty("binary", BoolProperty::New(false), renderer); mitk::RenderingModeProperty::Pointer renderingModeProperty = mitk::RenderingModeProperty::New(RenderingModeProperty::LOOKUPTABLE_LEVELWINDOW_COLOR); node->SetProperty("Image Rendering.Mode", renderingModeProperty, renderer); mitk::LevelWindow levelwindow(32767.5, 65535); mitk::LevelWindowProperty::Pointer levWinProp = mitk::LevelWindowProperty::New(levelwindow); levWinProp->SetLevelWindow(levelwindow); node->SetProperty("levelwindow", levWinProp, renderer); - node->SetProperty("labelset.contour.all", BoolProperty::New(false), renderer); node->SetProperty("labelset.contour.active", BoolProperty::New(true), renderer); node->SetProperty("labelset.contour.width", FloatProperty::New(2.0), renderer); Superclass::SetDefaultProperties(node, renderer, overwrite); } mitk::LabelSetImageVtkMapper2D::LocalStorage::~LocalStorage() { } mitk::LabelSetImageVtkMapper2D::LocalStorage::LocalStorage() { // Do as much actions as possible in here to avoid double executions. m_Plane = vtkSmartPointer::New(); m_Actors = vtkSmartPointer::New(); m_OutlinePolyData = vtkSmartPointer::New(); m_EmptyPolyData = vtkSmartPointer::New(); m_OutlineActor = vtkSmartPointer::New(); m_OutlineMapper = vtkSmartPointer::New(); m_OutlineShadowActor = vtkSmartPointer::New(); m_NumberOfLayers = 0; m_OutlineActor->SetMapper(m_OutlineMapper); m_OutlineShadowActor->SetMapper(m_OutlineMapper); m_OutlineActor->SetVisibility(false); m_OutlineShadowActor->SetVisibility(false); } diff --git a/Modules/Multilabel/mitkLabelSetImageVtkMapper2D.h b/Modules/Multilabel/mitkLabelSetImageVtkMapper2D.h index d16a4cee0d..640218150b 100644 --- a/Modules/Multilabel/mitkLabelSetImageVtkMapper2D.h +++ b/Modules/Multilabel/mitkLabelSetImageVtkMapper2D.h @@ -1,246 +1,245 @@ /*=================================================================== The Medical Imaging Interaction Toolkit (MITK) Copyright (c) German Cancer Research Center, Division of Medical and Biological Informatics. All rights reserved. This software is distributed WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See LICENSE.txt or http://www.mitk.org for details. ===================================================================*/ #ifndef __mitkLabelSetImageVtkMapper2D_H_ #define __mitkLabelSetImageVtkMapper2D_H_ // MITK #include "MitkMultilabelExports.h" #include "mitkCommon.h" // MITK Rendering #include "mitkBaseRenderer.h" #include "mitkExtractSliceFilter.h" #include "mitkLabelSetImage.h" #include "mitkVtkMapper.h" // VTK #include class vtkActor; class vtkPolyDataMapper; class vtkPlaneSource; class vtkImageData; class vtkLookupTable; class vtkImageReslice; class vtkPoints; class vtkMitkThickSlicesFilter; class vtkPolyData; class vtkMitkLevelWindowFilter; class vtkNeverTranslucentTexture; namespace mitk { + /** \brief Mapper to resample and display 2D slices of a 3D labelset image. * * Properties that can be set for labelset images and influence this mapper are: * - * - \b "labelset.contour.all": (BoolProperty) whether to show all labels as contours or not * - \b "labelset.contour.active": (BoolProperty) whether to show only the active label as a contour or not * - \b "labelset.contour.width": (FloatProperty) line width of the contour * The default properties are: - * - \b "labelset.contour.all", mitk::BoolProperty::New( false ), renderer, overwrite ) - * - \b "labelset.contour.active", mitk::BoolProperty::New( false ), renderer, overwrite ) + * - \b "labelset.contour.active", mitk::BoolProperty::New( true ), renderer, overwrite ) * - \b "labelset.contour.width", mitk::FloatProperty::New( 2.0 ), renderer, overwrite ) * \ingroup Mapper */ class MITKMULTILABEL_EXPORT LabelSetImageVtkMapper2D : public VtkMapper { public: /** Standard class typedefs. */ mitkClassMacro(LabelSetImageVtkMapper2D, VtkMapper); /** Method for creation through the object factory. */ itkNewMacro(Self); /** \brief Get the Image to map */ const mitk::Image *GetInput(void); /** \brief Checks whether this mapper needs to update itself and generate * data. */ virtual void Update(mitk::BaseRenderer *renderer) override; //### methods of MITK-VTK rendering pipeline virtual vtkProp *GetVtkProp(mitk::BaseRenderer *renderer) override; //### end of methods of MITK-VTK rendering pipeline /** \brief Internal class holding the mapper, actor, etc. for each of the 3 2D render windows */ /** - * To render transveral, coronal, and sagittal, the mapper is called three times. + * To render transversal, coronal, and sagittal, the mapper is called three times. * For performance reasons, the corresponding data for each view is saved in the * internal helper class LocalStorage. This allows rendering n views with just * 1 mitkMapper using n vtkMapper. * */ class MITKMULTILABEL_EXPORT LocalStorage : public mitk::Mapper::BaseLocalStorage { public: vtkSmartPointer m_Actors; std::vector> m_LayerActorVector; std::vector> m_LayerMapperVector; std::vector> m_ReslicedImageVector; std::vector> m_LayerTextureVector; vtkSmartPointer m_EmptyPolyData; vtkSmartPointer m_Plane; std::vector m_ReslicerVector; vtkSmartPointer m_OutlinePolyData; /** \brief An actor for the outline */ vtkSmartPointer m_OutlineActor; /** \brief An actor for the outline shadow*/ vtkSmartPointer m_OutlineShadowActor; /** \brief A mapper for the outline */ vtkSmartPointer m_OutlineMapper; /** \brief Timestamp of last update of stored data. */ itk::TimeStamp m_LastDataUpdateTime; /** \brief Timestamp of last update of a property. */ itk::TimeStamp m_LastPropertyUpdateTime; /** \brief mmPerPixel relation between pixel and mm. (World spacing).*/ mitk::ScalarType *m_mmPerPixel; int m_NumberOfLayers; /** \brief This filter is used to apply the level window to Grayvalue and RBG(A) images. */ // vtkSmartPointer m_LevelWindowFilter; std::vector> m_LevelWindowFilterVector; /** \brief Default constructor of the local storage. */ LocalStorage(); /** \brief Default deconstructor of the local storage. */ ~LocalStorage(); }; /** \brief The LocalStorageHandler holds all (three) LocalStorages for the three 2D render windows. */ mitk::LocalStorageHandler m_LSH; /** \brief Get the LocalStorage corresponding to the current renderer. */ LocalStorage *GetLocalStorage(mitk::BaseRenderer *renderer); /** \brief Set the default properties for general image rendering. */ static void SetDefaultProperties(mitk::DataNode *node, mitk::BaseRenderer *renderer = NULL, bool overwrite = false); /** \brief This method switches between different rendering modes (e.g. use a lookup table or a transfer function). * Detailed documentation about the modes can be found here: \link mitk::RenderingerModeProperty \endlink */ void ApplyRenderingMode(mitk::BaseRenderer *renderer); protected: /** \brief Transforms the actor to the actual position in 3D. * \param renderer The current renderer corresponding to the render window. */ void TransformActor(mitk::BaseRenderer *renderer); /** \brief Generates a plane according to the size of the resliced image in milimeters. * * \image html texturedPlane.png * * In VTK a vtkPlaneSource is defined through three points. The origin and two * points defining the axes of the plane (see VTK documentation). The origin is * set to (xMin; yMin; Z), where xMin and yMin are the minimal bounds of the * resliced image in space. Z is relevant for blending and the layer property. * The center of the plane (C) is also the center of the view plane (cf. the image above). * * \note For the standard MITK view with three 2D render windows showing three * different slices, three such planes are generated. All these planes are generated * in the XY-plane (even if they depict a YZ-slice of the volume). * */ void GeneratePlane(mitk::BaseRenderer *renderer, double planeBounds[6]); /** \brief Generates a vtkPolyData object containing the outline of a given binary slice. \param renderer: Pointer to the renderer containing the needed information \note This code is based on code from the iil library. */ vtkSmartPointer CreateOutlinePolyData(mitk::BaseRenderer *renderer, vtkImageData *image, int pixelValue = 1); /** Default constructor */ LabelSetImageVtkMapper2D(); /** Default deconstructor */ virtual ~LabelSetImageVtkMapper2D(); /** \brief Does the actual resampling, without rendering the image yet. * All the data is generated inside this method. The vtkProp (or Actor) * is filled with content (i.e. the resliced image). * * After generation, a 4x4 transformation matrix(t) of the current slice is obtained * from the vtkResliceImage object via GetReslicesAxis(). This matrix is * applied to each textured plane (actor->SetUserTransform(t)) to transform everything * to the actual 3D position (cf. the following image). * * \image html cameraPositioning3D.png * */ virtual void GenerateDataForRenderer(mitk::BaseRenderer *renderer) override; /** \brief This method uses the vtkCamera clipping range and the layer property * to calcualte the depth of the object (e.g. image or contour). The depth is used * to keep the correct order for the final VTK rendering.*/ float CalculateLayerDepth(mitk::BaseRenderer *renderer); /** \brief This method applies (or modifies) the lookuptable for all types of images. * \warning To use the lookup table, the property 'Lookup Table' must be set and a 'Image Rendering.Mode' * which uses the lookup table must be set. */ void ApplyLookuptable(mitk::BaseRenderer *renderer, int layer); /** \brief This method applies a color transfer function. * Internally, a vtkColorTransferFunction is used. This is usefull for coloring continous * images (e.g. float) * \warning To use the color transfer function, the property 'Image Rendering.Transfer Function' must be set and a * 'Image Rendering.Mode' which uses the color transfer function must be set. */ void ApplyColorTransferFunction(mitk::BaseRenderer *renderer); /** * @brief ApplyLevelWindow Apply the level window for the given renderer. * \warning To use the level window, the property 'LevelWindow' must be set and a 'Image Rendering.Mode' which uses * the level window must be set. * @param renderer Level window for which renderer? */ void ApplyLevelWindow(mitk::BaseRenderer *renderer); /** \brief Set the color of the image/polydata */ void ApplyColor(mitk::BaseRenderer *renderer, const mitk::Color &color); /** \brief Set the opacity of the actor. */ void ApplyOpacity(mitk::BaseRenderer *renderer, int layer); /** * \brief Calculates whether the given rendering geometry intersects the * given SlicedGeometry3D. * * This method checks if the given Geometry2D intersects the given * SlicedGeometry3D. It calculates the distance of the Geometry2D to all * 8 cornerpoints of the SlicedGeometry3D. If all distances have the same * sign (all positive or all negative) there is no intersection. * If the distances have different sign, there is an intersection. **/ bool RenderingGeometryIntersectsImage(const PlaneGeometry *renderingGeometry, SlicedGeometry3D *imageGeometry); }; } // namespace mitk #endif // __mitkLabelSetImageVtkMapper2D_H_ diff --git a/Modules/SegmentationUI/Qmitk/QmitkLabelSetWidget.cpp b/Modules/SegmentationUI/Qmitk/QmitkLabelSetWidget.cpp index 8bdb8605e4..8a982bb184 100644 --- a/Modules/SegmentationUI/Qmitk/QmitkLabelSetWidget.cpp +++ b/Modules/SegmentationUI/Qmitk/QmitkLabelSetWidget.cpp @@ -1,1294 +1,1322 @@ /*=================================================================== The Medical Imaging Interaction Toolkit (MITK) Copyright (c) German Cancer Research Center, Division of Medical and Biological Informatics. All rights reserved. This software is distributed WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See LICENSE.txt or http://www.mitk.org for details. ===================================================================*/ #include "QmitkLabelSetWidget.h" // mitk #include #include #include #include #include #include #include #include #include #include #include // Qmitk #include #include #include // Qt #include #include #include #include #include #include #include #include #include // itk #include // todo: // berry //#include QmitkLabelSetWidget::QmitkLabelSetWidget(QWidget *parent) : QWidget(parent), m_ToolManager(NULL), m_DataStorage(NULL), m_Completer(NULL) { m_Controls.setupUi(this); m_ColorSequenceRainbow.GoToBegin(); m_ToolManager = mitk::ToolManagerProvider::GetInstance()->GetToolManager(); assert(m_ToolManager); m_Controls.m_LabelSearchBox->setAlwaysShowClearIcon(true); m_Controls.m_LabelSearchBox->setShowSearchIcon(true); QStringList completionList; completionList << ""; m_Completer = new QCompleter(completionList, this); m_Completer->setCaseSensitivity(Qt::CaseInsensitive); m_Controls.m_LabelSearchBox->setCompleter(m_Completer); connect(m_Controls.m_LabelSearchBox, SIGNAL(returnPressed()), this, SLOT(OnSearchLabel())); // connect( m_Controls.m_LabelSetTableWidget, SIGNAL(labelListModified(const QStringList&)), this, SLOT( // OnLabelListModified(const QStringList&)) ); // connect( m_Controls.m_LabelSetTableWidget, SIGNAL(mergeLabel(int)), this, SLOT( OnMergeLabel(int)) ); QStringListModel *completeModel = static_cast(m_Completer->model()); completeModel->setStringList(GetLabelStringList()); m_Controls.m_LabelSearchBox->setEnabled(false); m_Controls.m_lblCaption->setText(""); InitializeTableWidget(); } QmitkLabelSetWidget::~QmitkLabelSetWidget() { } void QmitkLabelSetWidget::OnTableViewContextMenuRequested(const QPoint &pos) { QTableWidgetItem *itemAt = m_Controls.m_LabelSetTableWidget->itemAt(pos); // OnItemClicked(itemAt); if (!itemAt) return; int pixelValue = itemAt->data(Qt::UserRole).toInt(); QMenu *menu = new QMenu(m_Controls.m_LabelSetTableWidget); if (m_Controls.m_LabelSetTableWidget->selectedItems().size() > 1) { QAction *mergeAction = new QAction(QIcon(":/Qmitk/MergeLabels.png"), "Merge selection on current label", this); mergeAction->setEnabled(true); QObject::connect(mergeAction, SIGNAL(triggered(bool)), this, SLOT(OnMergeLabels(bool))); menu->addAction(mergeAction); QAction *removeLabelsAction = new QAction(QIcon(":/Qmitk/RemoveLabel.png"), "Remove selected labels", this); removeLabelsAction->setEnabled(true); QObject::connect(removeLabelsAction, SIGNAL(triggered(bool)), this, SLOT(OnRemoveLabels(bool))); menu->addAction(removeLabelsAction); QAction *eraseLabelsAction = new QAction(QIcon(":/Qmitk/EraseLabel.png"), "Erase selected labels", this); eraseLabelsAction->setEnabled(true); QObject::connect(eraseLabelsAction, SIGNAL(triggered(bool)), this, SLOT(OnEraseLabels(bool))); menu->addAction(eraseLabelsAction); QAction *combineAndCreateSurfaceAction = new QAction(QIcon(":/Qmitk/CreateSurface.png"), "Combine and create a surface", this); combineAndCreateSurfaceAction->setEnabled(true); QObject::connect( combineAndCreateSurfaceAction, SIGNAL(triggered(bool)), this, SLOT(OnCombineAndCreateSurface(bool))); // menu->addAction(combineAndCreateSurfaceAction); Not implemented QAction *createMasksAction = new QAction(QIcon(":/Qmitk/CreateMask.png"), "Create a mask for each selected label", this); createMasksAction->setEnabled(true); QObject::connect(createMasksAction, SIGNAL(triggered(bool)), this, SLOT(OnCreateMasks(bool))); // menu->addAction(createMasksAction); Not implemented QAction *combineAndCreateMaskAction = new QAction(QIcon(":/Qmitk/CreateMask.png"), "Combine and create a mask", this); combineAndCreateMaskAction->setEnabled(true); QObject::connect(combineAndCreateMaskAction, SIGNAL(triggered(bool)), this, SLOT(OnCombineAndCreateMask(bool))); // menu->addAction(combineAndCreateMaskAction); Not implemented } else { QAction *renameAction = new QAction(QIcon(":/Qmitk/RenameLabel.png"), "Rename...", this); renameAction->setEnabled(true); QObject::connect(renameAction, SIGNAL(triggered(bool)), this, SLOT(OnRenameLabel(bool))); menu->addAction(renameAction); QAction *removeAction = new QAction(QIcon(":/Qmitk/RemoveLabel.png"), "Remove...", this); removeAction->setEnabled(true); QObject::connect(removeAction, SIGNAL(triggered(bool)), this, SLOT(OnRemoveLabel(bool))); menu->addAction(removeAction); QAction *eraseAction = new QAction(QIcon(":/Qmitk/EraseLabel.png"), "Erase...", this); eraseAction->setEnabled(true); QObject::connect(eraseAction, SIGNAL(triggered(bool)), this, SLOT(OnEraseLabel(bool))); menu->addAction(eraseAction); QAction *mergeAction = new QAction(QIcon(":/Qmitk/MergeLabels.png"), "Merge...", this); mergeAction->setEnabled(true); QObject::connect(mergeAction, SIGNAL(triggered(bool)), this, SLOT(OnMergeLabel(bool))); menu->addAction(mergeAction); QAction *randomColorAction = new QAction(QIcon(":/Qmitk/RandomColor.png"), "Random color", this); randomColorAction->setEnabled(true); QObject::connect(randomColorAction, SIGNAL(triggered(bool)), this, SLOT(OnRandomColor(bool))); menu->addAction(randomColorAction); QAction *viewOnlyAction = new QAction(QIcon(":/Qmitk/visible.png"), "View only", this); viewOnlyAction->setEnabled(true); QObject::connect(viewOnlyAction, SIGNAL(triggered(bool)), this, SLOT(OnSetOnlyActiveLabelVisible(bool))); menu->addAction(viewOnlyAction); QAction *viewAllAction = new QAction(QIcon(":/Qmitk/visible.png"), "View all", this); viewAllAction->setEnabled(true); QObject::connect(viewAllAction, SIGNAL(triggered(bool)), this, SLOT(OnSetAllLabelsVisible(bool))); menu->addAction(viewAllAction); QAction *hideAllAction = new QAction(QIcon(":/Qmitk/invisible.png"), "Hide all", this); hideAllAction->setEnabled(true); QObject::connect(hideAllAction, SIGNAL(triggered(bool)), this, SLOT(OnSetAllLabelsInvisible(bool))); menu->addAction(hideAllAction); QAction *lockAllAction = new QAction(QIcon(":/Qmitk/lock.png"), "Lock all", this); lockAllAction->setEnabled(true); QObject::connect(lockAllAction, SIGNAL(triggered(bool)), this, SLOT(OnLockAllLabels(bool))); menu->addAction(lockAllAction); QAction *unlockAllAction = new QAction(QIcon(":/Qmitk/unlock.png"), "Unlock all", this); unlockAllAction->setEnabled(true); QObject::connect(unlockAllAction, SIGNAL(triggered(bool)), this, SLOT(OnUnlockAllLabels(bool))); menu->addAction(unlockAllAction); QAction *createSurfaceAction = new QAction(QIcon(":/Qmitk/CreateSurface.png"), "Create surface", this); createSurfaceAction->setEnabled(true); createSurfaceAction->setMenu(new QMenu()); QAction *tmp1 = createSurfaceAction->menu()->addAction(QString("Detailed")); QAction *tmp2 = createSurfaceAction->menu()->addAction(QString("Smoothed")); QObject::connect(tmp1, SIGNAL(triggered(bool)), this, SLOT(OnCreateDetailedSurface(bool))); QObject::connect(tmp2, SIGNAL(triggered(bool)), this, SLOT(OnCreateSmoothedSurface(bool))); menu->addAction(createSurfaceAction); QAction *createMaskAction = new QAction(QIcon(":/Qmitk/CreateMask.png"), "Create mask", this); createMaskAction->setEnabled(true); QObject::connect(createMaskAction, SIGNAL(triggered(bool)), this, SLOT(OnCreateMask(bool))); menu->addAction(createMaskAction); QAction *createCroppedMaskAction = new QAction(QIcon(":/Qmitk/CreateMask.png"), "Create cropped mask", this); createCroppedMaskAction->setEnabled(true); QObject::connect(createCroppedMaskAction, SIGNAL(triggered(bool)), this, SLOT(OnCreateCroppedMask(bool))); // QAction* importAction = new QAction(QIcon(":/Qmitk/RenameLabel.png"), "Import...", this ); // importAction->setEnabled(true); // QObject::connect( importAction, SIGNAL( triggered(bool) ), this, SLOT( OnImportSegmentationSession(bool) ) ); // menu->addAction(importAction); menu->addAction(createCroppedMaskAction); QSlider *opacitySlider = new QSlider; opacitySlider->setMinimum(0); opacitySlider->setMaximum(100); opacitySlider->setOrientation(Qt::Horizontal); QObject::connect(opacitySlider, SIGNAL(valueChanged(int)), this, SLOT(OnOpacityChanged(int))); QLabel *_OpacityLabel = new QLabel("Opacity: "); QVBoxLayout *_OpacityWidgetLayout = new QVBoxLayout; _OpacityWidgetLayout->setContentsMargins(4, 4, 4, 4); _OpacityWidgetLayout->addWidget(_OpacityLabel); _OpacityWidgetLayout->addWidget(opacitySlider); QWidget *_OpacityWidget = new QWidget; _OpacityWidget->setLayout(_OpacityWidgetLayout); QWidgetAction *OpacityAction = new QWidgetAction(this); OpacityAction->setDefaultWidget(_OpacityWidget); // QObject::connect( m_OpacityAction, SIGNAL( changed() ), this, SLOT( OpacityActionChanged() ) ); opacitySlider->setValue(static_cast(GetWorkingImage()->GetLabel(pixelValue, GetWorkingImage()->GetActiveLayer())->GetOpacity() * 100)); menu->addAction(OpacityAction); } menu->popup(QCursor::pos()); } void QmitkLabelSetWidget::OnUnlockAllLabels(bool /*value*/) { - GetWorkingImage()->GetLabelSet()->SetAllLabelsLocked(false); + GetWorkingImage()->GetActiveLabelSet()->SetAllLabelsLocked(false); mitk::RenderingManager::GetInstance()->RequestUpdateAll(); } void QmitkLabelSetWidget::OnLockAllLabels(bool /*value*/) { - GetWorkingImage()->GetLabelSet()->SetAllLabelsLocked(true); + GetWorkingImage()->GetActiveLabelSet()->SetAllLabelsLocked(true); mitk::RenderingManager::GetInstance()->RequestUpdateAll(); } void QmitkLabelSetWidget::OnSetAllLabelsVisible(bool /*value*/) { - GetWorkingImage()->GetLabelSet()->SetAllLabelsVisible(true); + GetWorkingImage()->GetActiveLabelSet()->SetAllLabelsVisible(true); mitk::RenderingManager::GetInstance()->RequestUpdateAll(); UpdateAllTableWidgetItems(); } void QmitkLabelSetWidget::OnSetAllLabelsInvisible(bool /*value*/) { - GetWorkingImage()->GetLabelSet()->SetAllLabelsVisible(false); + GetWorkingImage()->GetActiveLabelSet()->SetAllLabelsVisible(false); mitk::RenderingManager::GetInstance()->RequestUpdateAll(); UpdateAllTableWidgetItems(); } void QmitkLabelSetWidget::OnSetOnlyActiveLabelVisible(bool /*value*/) { - mitk::LabelSetImage *workingImage = GetWorkingImage(); + mitk::LabelSetImage* workingImage = GetWorkingImage(); int pixelValue = GetPixelValueOfSelectedItem(); workingImage->GetActiveLabelSet()->SetAllLabelsVisible(false); - workingImage->GetLabel(pixelValue, GetWorkingImage()->GetActiveLayer())->SetVisible(true); + workingImage->GetLabel(pixelValue, workingImage->GetActiveLayer())->SetVisible(true); - GetWorkingImage()->GetActiveLabelSet()->UpdateLookupTable(pixelValue); + workingImage->GetActiveLabelSet()->UpdateLookupTable(pixelValue); this->WaitCursorOn(); - const mitk::Point3D &pos = workingImage->GetLabel(pixelValue, GetWorkingImage()->GetActiveLayer())->GetCenterOfMassCoordinates(); + + const mitk::Point3D &pos = workingImage->GetLabel(pixelValue, workingImage->GetActiveLayer())->GetCenterOfMassCoordinates(); this->WaitCursorOff(); if (pos.GetVnlVector().max_value() > 0.0) + { emit goToLabel(pos); + } UpdateAllTableWidgetItems(); } void QmitkLabelSetWidget::OnMergeLabel(bool /*value*/) { QmitkSearchLabelDialog dialog(this); dialog.setWindowTitle("Select a second label.."); dialog.SetLabelSuggestionList(GetLabelStringList()); int dialogReturnValue = dialog.exec(); if (dialogReturnValue == QDialog::Rejected) return; int pixelValue = -1; for (int i = 0; i < m_Controls.m_LabelSetTableWidget->rowCount(); i++) { if (dialog.GetLabelSetWidgetTableCompleteWord() == QString(m_Controls.m_LabelSetTableWidget->item(i, 0)->text())) pixelValue = m_Controls.m_LabelSetTableWidget->item(i, 0)->data(Qt::UserRole).toInt(); } if (pixelValue == -1) { MITK_INFO << "unknown label"; ; return; } GetWorkingImage()->MergeLabel(pixelValue, GetWorkingImage()->GetActiveLayer()); UpdateAllTableWidgetItems(); mitk::RenderingManager::GetInstance()->RequestUpdateAll(); } void QmitkLabelSetWidget::OnEraseLabel(bool /*value*/) { int pixelValue = GetPixelValueOfSelectedItem(); QString question = "Do you really want to erase the contents of label \""; question.append(QString::fromStdString(GetWorkingImage()->GetLabel(pixelValue, GetWorkingImage()->GetActiveLayer())->GetName())); question.append("\"?"); QMessageBox::StandardButton answerButton = QMessageBox::question(this, "Erase label", question, QMessageBox::Yes | QMessageBox::Cancel, QMessageBox::Yes); if (answerButton == QMessageBox::Yes) { this->WaitCursorOn(); GetWorkingImage()->EraseLabel(pixelValue); this->WaitCursorOff(); mitk::RenderingManager::GetInstance()->RequestUpdateAll(); } } void QmitkLabelSetWidget::OnRemoveLabel(bool /*value*/) { int pixelValue = GetPixelValueOfSelectedItem(); QString question = "Do you really want to remove label \""; question.append(QString::fromStdString(GetWorkingImage()->GetLabel(pixelValue, GetWorkingImage()->GetActiveLayer())->GetName())); question.append("\"?"); QMessageBox::StandardButton answerButton = QMessageBox::question(this, "Remove label", question, QMessageBox::Yes | QMessageBox::Cancel, QMessageBox::Yes); if (answerButton == QMessageBox::Yes) { this->WaitCursorOn(); GetWorkingImage()->GetActiveLabelSet()->RemoveLabel(pixelValue); GetWorkingImage()->EraseLabel(pixelValue); this->WaitCursorOff(); } this->ResetAllTableWidgetItems(); mitk::RenderingManager::GetInstance()->RequestUpdateAll(); } void QmitkLabelSetWidget::OnRenameLabel(bool /*value*/) { QmitkNewSegmentationDialog dialog(this); dialog.setWindowTitle("Rename Label"); dialog.SetSuggestionList(m_OrganColors); // MLI TODO // dialog.SetColor(GetWorkingImage()->GetActiveLabel()->GetColor()); // dialog.SetSegmentationName(GetWorkingImage()->GetActiveLabel()->GetName()); if (dialog.exec() == QDialog::Rejected) return; int pixelValue = GetWorkingImage()->GetActiveLabel(GetWorkingImage()->GetActiveLayer())->GetValue(); GetWorkingImage()->GetLabel(pixelValue, GetWorkingImage()->GetActiveLayer())->SetColor(dialog.GetColor()); GetWorkingImage()->GetLabel(pixelValue, GetWorkingImage()->GetActiveLayer())->SetName(dialog.GetSegmentationName().toStdString()); GetWorkingImage()->GetActiveLabelSet()->UpdateLookupTable(pixelValue); this->ResetAllTableWidgetItems(); mitk::RenderingManager::GetInstance()->RequestUpdateAll(); } void QmitkLabelSetWidget::OnCombineAndCreateMask(bool /*value*/) { m_Controls.m_LabelSetTableWidget->selectedRanges(); // ...to do... // } void QmitkLabelSetWidget::OnCreateMasks(bool /*value*/) { m_Controls.m_LabelSetTableWidget->selectedRanges(); // ..to do.. // } void QmitkLabelSetWidget::OnCombineAndCreateSurface(bool /*value*/) { m_Controls.m_LabelSetTableWidget->selectedRanges(); // ..to do.. // } void QmitkLabelSetWidget::OnEraseLabels(bool /*value*/) { QString question = "Do you really want to erase the selected labels?"; QMessageBox::StandardButton answerButton = QMessageBox::question( this, "Erase selected labels", question, QMessageBox::Yes | QMessageBox::Cancel, QMessageBox::Yes); if (answerButton == QMessageBox::Yes) { QList ranges = m_Controls.m_LabelSetTableWidget->selectedRanges(); if (ranges.isEmpty()) return; std::vector VectorOfLablePixelValues; foreach (QTableWidgetSelectionRange a, ranges) for (int i = a.topRow(); i <= a.bottomRow(); i++) VectorOfLablePixelValues.push_back(m_Controls.m_LabelSetTableWidget->item(i, 0)->data(Qt::UserRole).toInt()); this->WaitCursorOn(); GetWorkingImage()->EraseLabels(VectorOfLablePixelValues, GetWorkingImage()->GetActiveLayer()); this->WaitCursorOff(); mitk::RenderingManager::GetInstance()->RequestUpdateAll(); } } void QmitkLabelSetWidget::OnRemoveLabels(bool /*value*/) { QString question = "Do you really want to remove selected labels?"; QMessageBox::StandardButton answerButton = QMessageBox::question( this, "Remove selected labels", question, QMessageBox::Yes | QMessageBox::Cancel, QMessageBox::Yes); if (answerButton == QMessageBox::Yes) { QList ranges = m_Controls.m_LabelSetTableWidget->selectedRanges(); if (ranges.isEmpty()) + { return; + } std::vector VectorOfLablePixelValues; - foreach (QTableWidgetSelectionRange a, ranges) - for (int i = a.topRow(); i <= a.bottomRow(); i++) + foreach(QTableWidgetSelectionRange a, ranges) + { + for (int i = a.topRow(); i <= a.bottomRow(); ++i) + { VectorOfLablePixelValues.push_back(m_Controls.m_LabelSetTableWidget->item(i, 0)->data(Qt::UserRole).toInt()); + } + } this->WaitCursorOn(); GetWorkingImage()->RemoveLabels(VectorOfLablePixelValues, GetWorkingImage()->GetActiveLayer()); this->WaitCursorOff(); } ResetAllTableWidgetItems(); mitk::RenderingManager::GetInstance()->RequestUpdateAll(); } void QmitkLabelSetWidget::OnMergeLabels(bool /*value*/) { int pixelValue = GetPixelValueOfSelectedItem(); QString question = "Do you really want to merge selected labels into \""; question.append(QString::fromStdString(GetWorkingImage()->GetLabel(pixelValue, GetWorkingImage()->GetActiveLayer())->GetName())); question.append("\"?"); QMessageBox::StandardButton answerButton = QMessageBox::question( this, "Merge selected label", question, QMessageBox::Yes | QMessageBox::Cancel, QMessageBox::Yes); if (answerButton == QMessageBox::Yes) { QList ranges = m_Controls.m_LabelSetTableWidget->selectedRanges(); if (ranges.isEmpty()) + { return; + } std::vector VectorOfLablePixelValues; - foreach (QTableWidgetSelectionRange a, ranges) - for (int i = a.topRow(); i <= a.bottomRow(); i++) + foreach(QTableWidgetSelectionRange a, ranges) + { + for (int i = a.topRow(); i <= a.bottomRow(); ++i) + { VectorOfLablePixelValues.push_back(m_Controls.m_LabelSetTableWidget->item(i, 0)->data(Qt::UserRole).toInt()); + } + } this->WaitCursorOn(); int pixelValue = m_Controls.m_LabelSetTableWidget->item(m_Controls.m_LabelSetTableWidget->currentRow(), 0) ->data(Qt::UserRole) .toInt(); GetWorkingImage()->MergeLabels(VectorOfLablePixelValues, pixelValue, GetWorkingImage()->GetActiveLayer()); this->WaitCursorOff(); mitk::RenderingManager::GetInstance()->RequestUpdateAll(); } } void QmitkLabelSetWidget::OnLockedButtonClicked() { int row; - for (int i = 0; i < m_Controls.m_LabelSetTableWidget->rowCount(); i++) + for(int i = 0; i < m_Controls.m_LabelSetTableWidget->rowCount(); ++i) { if (sender() == m_Controls.m_LabelSetTableWidget->cellWidget(i, LOCKED_COL)) { row = i; } } if (row >= 0 && row < m_Controls.m_LabelSetTableWidget->rowCount()) { int pixelValue = m_Controls.m_LabelSetTableWidget->item(row, 0)->data(Qt::UserRole).toInt(); GetWorkingImage()->GetLabel(pixelValue, GetWorkingImage()->GetActiveLayer())->SetLocked(!GetWorkingImage()->GetLabel(pixelValue, GetWorkingImage()->GetActiveLayer())->GetLocked()); } } void QmitkLabelSetWidget::OnVisibleButtonClicked() { int row; - for (int i = 0; i < m_Controls.m_LabelSetTableWidget->rowCount(); i++) + for(int i = 0; i < m_Controls.m_LabelSetTableWidget->rowCount(); ++i) { if (sender() == m_Controls.m_LabelSetTableWidget->cellWidget(i, VISIBLE_COL)) { row = i; break; } } if (row >= 0 && row < m_Controls.m_LabelSetTableWidget->rowCount()) { QTableWidgetItem *item = m_Controls.m_LabelSetTableWidget->item(row, 0); OnItemClicked(item); int pixelValue = item->data(Qt::UserRole).toInt(); GetWorkingImage()->GetLabel(pixelValue, GetWorkingImage()->GetActiveLayer())->SetVisible(!GetWorkingImage()->GetLabel(pixelValue, GetWorkingImage()->GetActiveLayer())->GetVisible()); GetWorkingImage()->GetActiveLabelSet()->UpdateLookupTable(pixelValue); mitk::RenderingManager::GetInstance()->RequestUpdateAll(); } } void QmitkLabelSetWidget::OnColorButtonClicked() { int row; - for (int i = 0; i < m_Controls.m_LabelSetTableWidget->rowCount(); i++) + for(int i = 0; i < m_Controls.m_LabelSetTableWidget->rowCount(); ++i) { if (sender() == m_Controls.m_LabelSetTableWidget->cellWidget(i, COLOR_COL)) { row = i; } } if (row >= 0 && row < m_Controls.m_LabelSetTableWidget->rowCount()) { int pixelValue = m_Controls.m_LabelSetTableWidget->item(row, 0)->data(Qt::UserRole).toInt(); const mitk::Color &color = GetWorkingImage()->GetLabel(pixelValue, GetWorkingImage()->GetActiveLayer())->GetColor(); QColor initial(color.GetRed() * 255, color.GetGreen() * 255, color.GetBlue() * 255); QColor qcolor = QColorDialog::getColor(initial, 0, QString("Change color")); if (!qcolor.isValid()) + { return; + } - QPushButton *button = (QPushButton *)m_Controls.m_LabelSetTableWidget->cellWidget(row, COLOR_COL); + QPushButton *button = static_cast(m_Controls.m_LabelSetTableWidget->cellWidget(row, COLOR_COL)); if (!button) + { return; + } button->setAutoFillBackground(true); QString styleSheet = "background-color:rgb("; styleSheet.append(QString::number(qcolor.red())); styleSheet.append(","); styleSheet.append(QString::number(qcolor.green())); styleSheet.append(","); styleSheet.append(QString::number(qcolor.blue())); styleSheet.append(")"); button->setStyleSheet(styleSheet); mitk::Color newColor; newColor.SetRed(qcolor.red() / 255.0); newColor.SetGreen(qcolor.green() / 255.0); newColor.SetBlue(qcolor.blue() / 255.0); GetWorkingImage()->GetLabel(pixelValue, GetWorkingImage()->GetActiveLayer())->SetColor(newColor); GetWorkingImage()->GetActiveLabelSet()->UpdateLookupTable(pixelValue); } } void QmitkLabelSetWidget::OnRandomColor(bool /*value*/) { int pixelValue = GetPixelValueOfSelectedItem(); GetWorkingImage()->GetLabel(pixelValue, GetWorkingImage()->GetActiveLayer())->SetColor(m_ColorSequenceRainbow.GetNextColor()); GetWorkingImage()->GetActiveLabelSet()->UpdateLookupTable(pixelValue); UpdateAllTableWidgetItems(); } void QmitkLabelSetWidget::SetOrganColors(const QStringList &organColors) { m_OrganColors = organColors; } void QmitkLabelSetWidget::OnActiveLabelChanged(int pixelValue) { mitk::LabelSetImage *workingImage = GetWorkingImage(); assert(workingImage); workingImage->GetActiveLabelSet()->SetActiveLabel(pixelValue); // MITK_INFO << "Active Label set to << " << pixelValue; mitk::SurfaceBasedInterpolationController *interpolator = mitk::SurfaceBasedInterpolationController::GetInstance(); if (interpolator) + { interpolator->SetActiveLabel(pixelValue); - - workingImage->Modified(); - mitk::RenderingManager::GetInstance()->RequestUpdateAll(); + workingImage->Modified(); + mitk::RenderingManager::GetInstance()->RequestUpdateAll(); + } } void QmitkLabelSetWidget::OnItemClicked(QTableWidgetItem *item) { if (!item) return; int pixelValue = item->data(Qt::UserRole).toInt(); QList ranges = m_Controls.m_LabelSetTableWidget->selectedRanges(); if (!ranges.empty() && ranges.back().rowCount() == 1) { SelectLabelByPixelValue(pixelValue); OnActiveLabelChanged(pixelValue); mitk::RenderingManager::GetInstance()->RequestUpdateAll(); } } void QmitkLabelSetWidget::OnItemDoubleClicked(QTableWidgetItem *item) { if (!item) return; + int pixelValue = item->data(Qt::UserRole).toInt(); // OnItemClicked(item); <<-- Double click first call OnItemClicked WaitCursorOn(); - mitk::LabelSetImage *workingImage = GetWorkingImage(); - workingImage->UpdateCenterOfMass(pixelValue); - const mitk::Point3D &pos = workingImage->GetLabel(pixelValue, GetWorkingImage()->GetActiveLayer())->GetCenterOfMassCoordinates(); + mitk::LabelSetImage* workingImage = GetWorkingImage(); + workingImage->UpdateCenterOfMass(pixelValue, workingImage->GetActiveLayer()); + const mitk::Point3D &pos = workingImage->GetLabel(pixelValue, workingImage->GetActiveLayer())->GetCenterOfMassCoordinates(); WaitCursorOff(); if (pos.GetVnlVector().max_value() > 0.0) + { emit goToLabel(pos); + } + + workingImage->Modified(); } void QmitkLabelSetWidget::SelectLabelByPixelValue(mitk::Label::PixelType pixelValue) { // MITK_INFO << "QmitkLabelSetWidget::SelectLabelByPixelValue " << pixelValue; if (!GetWorkingImage()->ExistLabel(pixelValue)) return; for (int row = 0; row < m_Controls.m_LabelSetTableWidget->rowCount(); row++) { if (m_Controls.m_LabelSetTableWidget->item(row, 0)->data(Qt::UserRole).toInt() == pixelValue) { m_Controls.m_LabelSetTableWidget->clearSelection(); m_Controls.m_LabelSetTableWidget->setSelectionMode(QAbstractItemView::SingleSelection); m_Controls.m_LabelSetTableWidget->selectRow(row); m_Controls.m_LabelSetTableWidget->scrollToItem(m_Controls.m_LabelSetTableWidget->item(row, 0)); m_Controls.m_LabelSetTableWidget->setSelectionMode(QAbstractItemView::ExtendedSelection); // SelectTableWidgetItem(m_Controls.m_LabelSetTableWidget->item(i,0)); // emit resetView(); // GetWorkingImage()->Modified(); return; } } } void QmitkLabelSetWidget::InsertTableWidgetItem(mitk::Label *label) { const mitk::Color &color = label->GetColor(); - QTableWidget *tableWidget = m_Controls.m_LabelSetTableWidget; - QString styleSheet = "background-color:rgb("; styleSheet.append(QString::number(color[0] * 255)); styleSheet.append(","); styleSheet.append(QString::number(color[1] * 255)); styleSheet.append(","); styleSheet.append(QString::number(color[2] * 255)); styleSheet.append(")"); + QTableWidget* tableWidget = m_Controls.m_LabelSetTableWidget; int colWidth = (tableWidget->columnWidth(NAME_COL) < 180) ? 180 : tableWidget->columnWidth(NAME_COL) - 2; QString text = fontMetrics().elidedText(label->GetName().c_str(), Qt::ElideMiddle, colWidth); QTableWidgetItem *nameItem = new QTableWidgetItem(text); nameItem->setTextAlignment(Qt::AlignCenter | Qt::AlignLeft); // ---!--- // IMPORTANT: ADD PIXELVALUE TO TABLEWIDGETITEM.DATA nameItem->setData(Qt::UserRole, QVariant(label->GetValue())); // ---!--- QPushButton *pbColor = new QPushButton(tableWidget); pbColor->setFixedSize(24, 24); pbColor->setCheckable(false); pbColor->setAutoFillBackground(true); pbColor->setToolTip("Change label color"); pbColor->setStyleSheet(styleSheet); connect(pbColor, SIGNAL(clicked()), this, SLOT(OnColorButtonClicked())); QPushButton *pbLocked = new QPushButton(tableWidget); pbLocked->setFixedSize(24, 24); QIcon *iconLocked = new QIcon(); + iconLocked->addFile(QString::fromUtf8(":/Qmitk/lock.png"), QSize(), QIcon::Normal, QIcon::Off); iconLocked->addFile(QString::fromUtf8(":/Qmitk/unlock.png"), QSize(), QIcon::Normal, QIcon::On); pbLocked->setIcon(*iconLocked); pbLocked->setIconSize(QSize(24, 24)); pbLocked->setCheckable(true); pbLocked->setToolTip("Lock/unlock label"); pbLocked->setChecked(!label->GetLocked()); connect(pbLocked, SIGNAL(clicked()), this, SLOT(OnLockedButtonClicked())); QPushButton *pbVisible = new QPushButton(tableWidget); pbVisible->setFixedSize(24, 24); pbVisible->setAutoRepeat(false); QIcon *iconVisible = new QIcon(); iconVisible->addFile(QString::fromUtf8(":/Qmitk/visible.png"), QSize(), QIcon::Normal, QIcon::Off); iconVisible->addFile(QString::fromUtf8(":/Qmitk/invisible.png"), QSize(), QIcon::Normal, QIcon::On); pbVisible->setIcon(*iconVisible); pbVisible->setIconSize(QSize(24, 24)); pbVisible->setCheckable(true); pbVisible->setToolTip("Show/hide label"); pbVisible->setChecked(!label->GetVisible()); connect(pbVisible, SIGNAL(clicked()), this, SLOT(OnVisibleButtonClicked())); int row = tableWidget->rowCount(); tableWidget->insertRow(row); tableWidget->setRowHeight(row, 24); tableWidget->setItem(row, 0, nameItem); tableWidget->setCellWidget(row, 1, pbLocked); tableWidget->setCellWidget(row, 2, pbColor); tableWidget->setCellWidget(row, 3, pbVisible); tableWidget->selectRow(row); // m_LabelSetImage->SetActiveLabel(label->GetPixelValue()); // m_ToolManager->WorkingDataModified.Send(); // emit activeLabelChanged(label->GetPixelValue()); if (row == 0) + { tableWidget->hideRow(row); // hide exterior label - - mitk::LabelSetImage *workingImage; - if ((workingImage = GetWorkingImage()) == NULL) - return; + } } void QmitkLabelSetWidget::UpdateAllTableWidgetItems() { - QTableWidget *tableWidget = m_Controls.m_LabelSetTableWidget; - mitk::LabelSetImage *workingImage = GetWorkingImage(); if (!workingImage) return; // add all labels + QTableWidget* tableWidget = m_Controls.m_LabelSetTableWidget; m_LabelStringList.clear(); - for (int i = 0; i < tableWidget->rowCount(); i++) + for(int i = 0 ; i < tableWidget->rowCount(); ++i) { UpdateTableWidgetItem(tableWidget->item(i, 0)); m_LabelStringList.append(tableWidget->item(i, 0)->text()); } OnLabelListModified(m_LabelStringList); mitk::RenderingManager::GetInstance()->RequestUpdateAll(); } void QmitkLabelSetWidget::UpdateTableWidgetItem(QTableWidgetItem *item) { mitk::LabelSetImage *workingImage = GetWorkingImage(); mitk::Label *label = workingImage->GetLabel(item->data(Qt::UserRole).toInt(), workingImage->GetActiveLayer()); const mitk::Color &color = label->GetColor(); QTableWidget *tableWidget = m_Controls.m_LabelSetTableWidget; QString styleSheet = "background-color:rgb("; styleSheet.append(QString::number(color[0] * 255)); styleSheet.append(","); styleSheet.append(QString::number(color[1] * 255)); styleSheet.append(","); styleSheet.append(QString::number(color[2] * 255)); styleSheet.append(")"); // Update text Label tableWdget->item(row,0) int colWidth = (tableWidget->columnWidth(NAME_COL) < 180) ? 180 : tableWidget->columnWidth(NAME_COL) - 2; QString text = fontMetrics().elidedText(label->GetName().c_str(), Qt::ElideMiddle, colWidth); item->setText(text); QPushButton *pbLocked = dynamic_cast(tableWidget->cellWidget(item->row(), 1)); pbLocked->setChecked(!label->GetLocked()); QPushButton *pbColor = dynamic_cast(tableWidget->cellWidget(item->row(), 2)); pbColor->setStyleSheet(styleSheet); QPushButton *pbVisible = dynamic_cast(tableWidget->cellWidget(item->row(), 3)); pbVisible->setChecked(!label->GetVisible()); if (item->row() == 0) tableWidget->hideRow(item->row()); // hide exterior label } void QmitkLabelSetWidget::ResetAllTableWidgetItems() { QTableWidget *tableWidget = m_Controls.m_LabelSetTableWidget; // remove all rows while (tableWidget->rowCount()) + { tableWidget->removeRow(0); + } mitk::LabelSetImage *workingImage = GetWorkingImage(); if (!workingImage) return; // add all labels m_LabelStringList.clear(); mitk::LabelSet::LabelContainerConstIteratorType it = workingImage->GetActiveLabelSet()->IteratorConstBegin(); mitk::LabelSet::LabelContainerConstIteratorType end = workingImage->GetActiveLabelSet()->IteratorConstEnd(); int pixelValue = -1; while (it != end) { InsertTableWidgetItem(it->second); if (GetWorkingImage()->GetActiveLabel() == it->second) // get active pixelValue = it->first; m_LabelStringList.append(QString(it->second->GetName().c_str())); it++; } SelectLabelByPixelValue(pixelValue); OnLabelListModified(m_LabelStringList); std::stringstream captionText; captionText << "Number of labels: " << workingImage->GetNumberOfLabels() - 1; m_Controls.m_lblCaption->setText(captionText.str().c_str()); mitk::RenderingManager::GetInstance()->RequestUpdateAll(); } int QmitkLabelSetWidget::GetPixelValueOfSelectedItem() { if (m_Controls.m_LabelSetTableWidget->currentItem()) + { return m_Controls.m_LabelSetTableWidget->currentItem()->data(Qt::UserRole).toInt(); + } return -1; } QStringList &QmitkLabelSetWidget::GetLabelStringList() { return m_LabelStringList; } void QmitkLabelSetWidget::InitializeTableWidget() { QTableWidget *tableWidged = m_Controls.m_LabelSetTableWidget; tableWidged->setSizePolicy(QSizePolicy::Expanding, QSizePolicy::Maximum); tableWidged->setTabKeyNavigation(false); tableWidged->setAlternatingRowColors(false); tableWidged->setFocusPolicy(Qt::NoFocus); tableWidged->setColumnCount(4); tableWidged->resizeColumnToContents(NAME_COL); tableWidged->setColumnWidth(LOCKED_COL, 25); tableWidged->setColumnWidth(COLOR_COL, 25); tableWidged->setColumnWidth(VISIBLE_COL, 25); #if QT_VERSION >= QT_VERSION_CHECK(5, 0, 0) tableWidged->horizontalHeader()->setSectionResizeMode(0, QHeaderView::Stretch); #else tableWidged->horizontalHeader()->setResizeMode(0, QHeaderView::Stretch); #endif tableWidged->setContextMenuPolicy(Qt::CustomContextMenu); tableWidged->horizontalHeader()->hide(); tableWidged->setSortingEnabled(false); tableWidged->verticalHeader()->hide(); tableWidged->setEditTriggers(QAbstractItemView::NoEditTriggers); tableWidged->setSelectionMode(QAbstractItemView::ExtendedSelection); tableWidged->setSelectionBehavior(QAbstractItemView::SelectRows); connect(tableWidged, SIGNAL(itemClicked(QTableWidgetItem *)), this, SLOT(OnItemClicked(QTableWidgetItem *))); connect( tableWidged, SIGNAL(itemDoubleClicked(QTableWidgetItem *)), this, SLOT(OnItemDoubleClicked(QTableWidgetItem *))); connect(tableWidged, SIGNAL(customContextMenuRequested(const QPoint &)), this, SLOT(OnTableViewContextMenuRequested(const QPoint &))); // connect( m_Controls.m_LabelSetTableWidget, SIGNAL(activeLabelChanged(int)), this, SLOT(OnActiveLabelChanged(int)) // ); // connect( m_Controls.m_LabelSetTableWidget, SIGNAL(importSegmentation()), this, SLOT( OnImportSegmentation()) ); // connect( m_Controls.m_LabelSetTableWidget, SIGNAL(importLabeledImage()), this, SLOT( OnImportLabeledImage()) ); // connect( m_Controls.m_LabelSetTableWidget, SIGNAL(renameLabel(int, const mitk::Color&, const std::string&)), this, // SLOT(OnRenameLabel(int, const mitk::Color&, const std::string&)) ); // connect( m_Controls.m_LabelSetTableWidget, SIGNAL(createSurface(int, bool)), this, SLOT(OnCreateSurface(int, bool)) // ); // connect( m_Controls.m_LabelSetTableWidget, SIGNAL(toggleOutline(bool)), this, SLOT(OnToggleOutline(bool)) ); // connect( m_Controls.m_LabelSetTableWidget, SIGNAL(goToLabel(const mitk::Point3D&)), this, SIGNAL(goToLabel(const // mitk::Point3D&)) ); // connect( m_Controls.m_LabelSetTableWidget, SIGNAL(combineAndCreateSurface( const QList& // )), // this, SLOT(OnCombineAndCreateSurface( const QList&)) ); // connect( m_Controls.m_LabelSetTableWidget, SIGNAL(createMask(int)), this, SLOT(OnCreateMask(int)) ); // connect( m_Controls.m_LabelSetTableWidget, SIGNAL(createCroppedMask(int)), this, SLOT(OnCreateCroppedMask(int)) ); // connect( m_Controls.m_LabelSetTableWidget, SIGNAL(combineAndCreateMask( const QList& // )), // this, SLOT(OnCombineAndCreateMask( const QList&)) ); } void QmitkLabelSetWidget::OnOpacityChanged(int value) { int pixelValue = m_Controls.m_LabelSetTableWidget->currentItem()->data(Qt::UserRole).toInt(); float opacity = static_cast(value) / 100.0f; GetWorkingImage()->GetLabel(pixelValue, GetWorkingImage()->GetActiveLayer())->SetOpacity(opacity); GetWorkingImage()->GetActiveLabelSet()->UpdateLookupTable(pixelValue); } void QmitkLabelSetWidget::setEnabled(bool enabled) { QWidget::setEnabled(enabled); UpdateControls(); } void QmitkLabelSetWidget::SetDataStorage(mitk::DataStorage *storage) { m_DataStorage = storage; } void QmitkLabelSetWidget::OnSearchLabel() { std::string text = m_Controls.m_LabelSearchBox->text().toStdString(); int pixelValue = -1; int row = -1; - for (int i = 0; i < m_Controls.m_LabelSetTableWidget->rowCount(); i++) + for(int i = 0; i < m_Controls.m_LabelSetTableWidget->rowCount(); ++i) { - if (m_Controls.m_LabelSetTableWidget->item(i, 0)->text().toStdString().compare(text) == 0) + if( m_Controls.m_LabelSetTableWidget->item(i, 0)->text().toStdString().compare(text) == 0) { pixelValue = m_Controls.m_LabelSetTableWidget->item(i, 0)->data(Qt::UserRole).toInt(); row = i; break; } } if (pixelValue == -1) + { return; + } + GetWorkingImage()->GetActiveLabelSet()->SetActiveLabel(pixelValue); QTableWidgetItem *nameItem = m_Controls.m_LabelSetTableWidget->item(row, NAME_COL); if (!nameItem) + { return; + } m_Controls.m_LabelSetTableWidget->clearSelection(); m_Controls.m_LabelSetTableWidget->setSelectionMode(QAbstractItemView::SingleSelection); m_Controls.m_LabelSetTableWidget->selectRow(row); m_Controls.m_LabelSetTableWidget->scrollToItem(nameItem); m_Controls.m_LabelSetTableWidget->setSelectionMode(QAbstractItemView::ExtendedSelection); + GetWorkingImage()->GetActiveLabelSet()->SetActiveLabel(pixelValue); + this->WaitCursorOn(); mitk::Point3D pos = GetWorkingImage()->GetLabel(pixelValue, GetWorkingImage()->GetActiveLayer())->GetCenterOfMassCoordinates(); m_ToolManager->WorkingDataChanged(); if (pos.GetVnlVector().max_value() > 0.0) + { emit goToLabel(pos); + } else { - GetWorkingImage()->UpdateCenterOfMass(pixelValue); + GetWorkingImage()->UpdateCenterOfMass(pixelValue, GetWorkingImage()->GetActiveLayer()); mitk::Point3D pos = GetWorkingImage()->GetLabel(pixelValue, GetWorkingImage()->GetActiveLayer())->GetCenterOfMassCoordinates(); emit goToLabel(pos); } this->WaitCursorOff(); } void QmitkLabelSetWidget::OnLabelListModified(const QStringList &list) { QStringListModel *completeModel = static_cast(m_Completer->model()); completeModel->setStringList(list); } mitk::LabelSetImage *QmitkLabelSetWidget::GetWorkingImage() { mitk::DataNode *workingNode = GetWorkingNode(); mitk::LabelSetImage *workingImage = dynamic_cast(workingNode->GetData()); assert(workingImage); return workingImage; } mitk::DataNode *QmitkLabelSetWidget::GetWorkingNode() { mitk::DataNode *workingNode = m_ToolManager->GetWorkingData(0); assert(workingNode); return workingNode; } void QmitkLabelSetWidget::UpdateControls() { mitk::DataNode *workingNode = m_ToolManager->GetWorkingData(0); - bool hasWorkingData = (workingNode != NULL); + bool hasWorkingData = (workingNode != nullptr); m_Controls.m_LabelSetTableWidget->setEnabled(hasWorkingData); m_Controls.m_LabelSearchBox->setEnabled(hasWorkingData); if (!hasWorkingData) return; QStringListModel *completeModel = static_cast(m_Completer->model()); completeModel->setStringList(GetLabelStringList()); } void QmitkLabelSetWidget::OnCreateCroppedMask(bool) { m_ToolManager->ActivateTool(-1); - mitk::DataNode *workingNode = GetWorkingNode(); mitk::LabelSetImage *workingImage = GetWorkingImage(); - mitk::Image::Pointer maskImage; - int pixelValue = GetPixelValueOfSelectedItem(); try { this->WaitCursorOn(); mitk::AutoCropImageFilter::Pointer cropFilter = mitk::AutoCropImageFilter::New(); cropFilter->SetInput(workingImage->CreateLabelMask(pixelValue)); cropFilter->SetBackgroundValue(0); cropFilter->SetMarginFactor(1.15); cropFilter->Update(); maskImage = cropFilter->GetOutput(); this->WaitCursorOff(); } catch (mitk::Exception &e) { this->WaitCursorOff(); MITK_ERROR << "Exception caught: " << e.GetDescription(); QMessageBox::information(this, "Create Mask", "Could not create a mask out of the selected label.\n"); return; } if (maskImage.IsNull()) { QMessageBox::information(this, "Create Mask", "Could not create a mask out of the selected label.\n"); return; } mitk::DataNode::Pointer maskNode = mitk::DataNode::New(); std::string name = workingImage->GetLabel(pixelValue, workingImage->GetActiveLayer())->GetName(); name += "-mask"; maskNode->SetName(name); maskNode->SetData(maskImage); maskNode->SetBoolProperty("binary", true); maskNode->SetBoolProperty("outline binary", true); maskNode->SetBoolProperty("outline binary shadow", true); maskNode->SetFloatProperty("outline width", 2.0); - maskNode->SetColor(workingImage->GetLabel(pixelValue, GetWorkingImage()->GetActiveLayer())->GetColor()); + maskNode->SetColor(workingImage->GetLabel(pixelValue, workingImage->GetActiveLayer())->GetColor()); maskNode->SetOpacity(1.0); - m_DataStorage->Add(maskNode, workingNode); + m_DataStorage->Add(maskNode, GetWorkingNode()); } void QmitkLabelSetWidget::OnCreateMask(bool /*triggered*/) { m_ToolManager->ActivateTool(-1); - mitk::DataNode *workingNode = GetWorkingNode(); mitk::LabelSetImage *workingImage = GetWorkingImage(); - mitk::Image::Pointer maskImage; - int pixelValue = GetPixelValueOfSelectedItem(); - try { this->WaitCursorOn(); maskImage = workingImage->CreateLabelMask(pixelValue); this->WaitCursorOff(); } catch (mitk::Exception &e) { this->WaitCursorOff(); MITK_ERROR << "Exception caught: " << e.GetDescription(); QMessageBox::information(this, "Create Mask", "Could not create a mask out of the selected label.\n"); return; } if (maskImage.IsNull()) { QMessageBox::information(this, "Create Mask", "Could not create a mask out of the selected label.\n"); return; } mitk::DataNode::Pointer maskNode = mitk::DataNode::New(); std::string name = workingImage->GetLabel(pixelValue, workingImage->GetActiveLayer())->GetName(); name += "-mask"; maskNode->SetName(name); maskNode->SetData(maskImage); maskNode->SetBoolProperty("binary", true); maskNode->SetBoolProperty("outline binary", true); maskNode->SetBoolProperty("outline binary shadow", true); maskNode->SetFloatProperty("outline width", 2.0); - maskNode->SetColor(workingImage->GetLabel(pixelValue, GetWorkingImage()->GetActiveLayer())->GetColor()); + maskNode->SetColor(workingImage->GetLabel(pixelValue, workingImage->GetActiveLayer())->GetColor()); maskNode->SetOpacity(1.0); - m_DataStorage->Add(maskNode, workingNode); + m_DataStorage->Add(maskNode, GetWorkingNode()); } void QmitkLabelSetWidget::OnToggleOutline(bool value) { mitk::DataNode *workingNode = m_ToolManager->GetWorkingData(0); assert(workingNode); - workingNode->SetBoolProperty("labelset.contour.all", value); + workingNode->SetBoolProperty("labelset.contour.active", value); workingNode->GetData()->Modified(); // fixme: workaround to force data-type rendering (and not only property-type) mitk::RenderingManager::GetInstance()->RequestUpdateAll(); } void QmitkLabelSetWidget::OnCreateSmoothedSurface(bool /*triggered*/) { m_ToolManager->ActivateTool(-1); mitk::DataNode::Pointer workingNode = GetWorkingNode(); mitk::LabelSetImage *workingImage = GetWorkingImage(); int pixelValue = GetPixelValueOfSelectedItem(); mitk::LabelSetImageToSurfaceThreadedFilter::Pointer surfaceFilter = mitk::LabelSetImageToSurfaceThreadedFilter::New(); itk::SimpleMemberCommand::Pointer successCommand = itk::SimpleMemberCommand::New(); successCommand->SetCallbackFunction(this, &QmitkLabelSetWidget::OnThreadedCalculationDone); surfaceFilter->AddObserver(mitk::ResultAvailable(), successCommand); itk::SimpleMemberCommand::Pointer errorCommand = itk::SimpleMemberCommand::New(); errorCommand->SetCallbackFunction(this, &QmitkLabelSetWidget::OnThreadedCalculationDone); surfaceFilter->AddObserver(mitk::ProcessingError(), errorCommand); mitk::DataNode::Pointer groupNode = workingNode; surfaceFilter->SetPointerParameter("Group node", groupNode); surfaceFilter->SetPointerParameter("Input", workingImage); surfaceFilter->SetParameter("RequestedLabel", pixelValue); surfaceFilter->SetParameter("Smooth", true); surfaceFilter->SetDataStorage(*m_DataStorage); mitk::StatusBar::GetInstance()->DisplayText("Surface creation is running in background..."); try { surfaceFilter->StartAlgorithm(); } catch (mitk::Exception &e) { MITK_ERROR << "Exception caught: " << e.GetDescription(); QMessageBox::information(this, "Create Surface", "Could not create a surface mesh out of the selected label. See error log for details.\n"); } } void QmitkLabelSetWidget::OnCreateDetailedSurface(bool /*triggered*/) { m_ToolManager->ActivateTool(-1); mitk::DataNode::Pointer workingNode = GetWorkingNode(); mitk::LabelSetImage *workingImage = GetWorkingImage(); int pixelValue = GetPixelValueOfSelectedItem(); mitk::LabelSetImageToSurfaceThreadedFilter::Pointer surfaceFilter = mitk::LabelSetImageToSurfaceThreadedFilter::New(); itk::SimpleMemberCommand::Pointer successCommand = itk::SimpleMemberCommand::New(); successCommand->SetCallbackFunction(this, &QmitkLabelSetWidget::OnThreadedCalculationDone); surfaceFilter->AddObserver(mitk::ResultAvailable(), successCommand); itk::SimpleMemberCommand::Pointer errorCommand = itk::SimpleMemberCommand::New(); errorCommand->SetCallbackFunction(this, &QmitkLabelSetWidget::OnThreadedCalculationDone); surfaceFilter->AddObserver(mitk::ProcessingError(), errorCommand); mitk::DataNode::Pointer groupNode = workingNode; surfaceFilter->SetPointerParameter("Group node", groupNode); surfaceFilter->SetPointerParameter("Input", workingImage); surfaceFilter->SetParameter("RequestedLabel", pixelValue); surfaceFilter->SetParameter("Smooth", false); surfaceFilter->SetDataStorage(*m_DataStorage); mitk::StatusBar::GetInstance()->DisplayText("Surface creation is running in background..."); try { surfaceFilter->StartAlgorithm(); } catch (mitk::Exception &e) { MITK_ERROR << "Exception caught: " << e.GetDescription(); QMessageBox::information(this, "Create Surface", "Could not create a surface mesh out of the selected label. See error log for details.\n"); } } void QmitkLabelSetWidget::OnImportLabeledImage() { /* m_ToolManager->ActivateTool(-1); mitk::DataNode* referenceNode = m_ToolManager->GetReferenceData(0); assert(referenceNode); // Ask the user for a list of files to open QStringList fileNames = QFileDialog::getOpenFileNames( this, "Open Image", m_LastFileOpenPath, mitk::CoreObjectFactory::GetInstance()->GetFileExtensions()); if (fileNames.empty()) return; try { this->WaitCursorOn(); mitk::Image::Pointer image = mitk::IOUtil::LoadImage( fileNames.front().toStdString() ); if (image.IsNull()) { this->WaitCursorOff(); QMessageBox::information(this, "Import Labeled Image", "Could not load the selected segmentation.\n"); return; } mitk::LabelSetImage::Pointer newImage = mitk::LabelSetImage::New(); newImage->InitializeByLabeledImage(image); this->WaitCursorOff(); mitk::DataNode::Pointer newNode = mitk::DataNode::New(); std::string newName = referenceNode->GetName(); newName += "-labels"; newNode->SetName(newName); newNode->SetData(newImage); m_DataStorage->Add(newNode, referenceNode); } catch (mitk::Exception & e) { this->WaitCursorOff(); MITK_ERROR << "Exception caught: " << e.GetDescription(); QMessageBox::information(this, "Import Labeled Image", "Could not load the selected segmentation. See error log for details.\n"); return; } this->UpdateControls(); mitk::RenderingManager::GetInstance()->RequestUpdateAll(); */ } void QmitkLabelSetWidget::OnImportSegmentation() { /* m_ToolManager->ActivateTool(-1); mitk::DataNode* workingNode = m_ToolManager->GetWorkingData(0); assert(workingNode); mitk::LabelSetImage* workingImage = dynamic_cast( workingNode->GetData() ); assert(workingImage); std::string fileExtensions("Segmentation files (*.lset);;"); QString qfileName = QFileDialog::getOpenFileName(this, "Import Segmentation", m_LastFileOpenPath, fileExtensions.c_str() ); if (qfileName.isEmpty() ) return; mitk::NrrdLabelSetImageReader::Pointer reader = mitk::NrrdLabelSetImageReader::New(); reader->SetFileName(qfileName.toLatin1()); try { this->WaitCursorOn(); reader->Update(); mitk::LabelSetImage::Pointer newImage = reader->GetOutput(); workingImage->Concatenate(newImage); this->WaitCursorOff(); } catch ( mitk::Exception& e ) { this->WaitCursorOff(); MITK_ERROR << "Exception caught: " << e.GetDescription(); QMessageBox::information(this, "Import Segmentation", "Could not import the selected segmentation session.\n See error log for details.\n"); } */ mitk::RenderingManager::GetInstance()->RequestUpdateAll(); } void QmitkLabelSetWidget::WaitCursorOn() { QApplication::setOverrideCursor(QCursor(Qt::WaitCursor)); } void QmitkLabelSetWidget::WaitCursorOff() { this->RestoreOverrideCursor(); } void QmitkLabelSetWidget::RestoreOverrideCursor() { QApplication::restoreOverrideCursor(); } void QmitkLabelSetWidget::OnThreadedCalculationDone() { mitk::StatusBar::GetInstance()->Clear(); } diff --git a/Plugins/org.mitk.gui.qt.multilabelsegmentation/plugin.xml b/Plugins/org.mitk.gui.qt.multilabelsegmentation/plugin.xml index 95a89089cf..c0d36be55e 100644 --- a/Plugins/org.mitk.gui.qt.multilabelsegmentation/plugin.xml +++ b/Plugins/org.mitk.gui.qt.multilabelsegmentation/plugin.xml @@ -1,42 +1,42 @@ - + diff --git a/Plugins/org.mitk.gui.qt.multilabelsegmentation/src/QmitkMultiLabelSegmentationPreferencePage.cpp b/Plugins/org.mitk.gui.qt.multilabelsegmentation/src/QmitkMultiLabelSegmentationPreferencePage.cpp index 2d4e21e132..84034f3c57 100644 --- a/Plugins/org.mitk.gui.qt.multilabelsegmentation/src/QmitkMultiLabelSegmentationPreferencePage.cpp +++ b/Plugins/org.mitk.gui.qt.multilabelsegmentation/src/QmitkMultiLabelSegmentationPreferencePage.cpp @@ -1,170 +1,170 @@ /*=================================================================== The Medical Imaging Interaction Toolkit (MITK) Copyright (c) German Cancer Research Center, Division of Medical and Biological Informatics. All rights reserved. This software is distributed WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See LICENSE.txt or http://www.mitk.org for details. ===================================================================*/ #include "QmitkMultiLabelSegmentationPreferencePage.h" #include #include #include #include #include #include #include #include #include #include QmitkMultiLabelSegmentationPreferencePage::QmitkMultiLabelSegmentationPreferencePage() : m_MainControl(0) , m_Initializing(false) { } QmitkMultiLabelSegmentationPreferencePage::~QmitkMultiLabelSegmentationPreferencePage() { } void QmitkMultiLabelSegmentationPreferencePage::Init(berry::IWorkbench::Pointer ) { } void QmitkMultiLabelSegmentationPreferencePage::CreateQtControl(QWidget* parent) { m_Initializing = true; berry::IPreferencesService* prefService = berry::Platform::GetPreferencesService(); - m_SegmentationPreferencesNode = prefService->GetSystemPreferences()->Node("/org.mitk.views.segmentation"); + m_SegmentationPreferencesNode = prefService->GetSystemPreferences()->Node("/org.mitk.views.multilabelsegmentation"); m_MainControl = new QWidget(parent); QVBoxLayout* displayOptionsLayout = new QVBoxLayout; m_RadioOutline = new QRadioButton( "Draw as outline", m_MainControl); displayOptionsLayout->addWidget( m_RadioOutline ); m_RadioOverlay = new QRadioButton( "Draw as transparent overlay", m_MainControl); displayOptionsLayout->addWidget( m_RadioOverlay ); QFormLayout *formLayout = new QFormLayout; formLayout->setHorizontalSpacing(8); formLayout->setVerticalSpacing(24); formLayout->addRow( "2D display", displayOptionsLayout ); m_VolumeRenderingCheckBox = new QCheckBox( "Show as volume rendering", m_MainControl ); formLayout->addRow( "3D display", m_VolumeRenderingCheckBox ); connect( m_VolumeRenderingCheckBox, SIGNAL(stateChanged(int)), this, SLOT(OnVolumeRenderingCheckboxChecked(int)) ); QFormLayout* surfaceLayout = new QFormLayout; surfaceLayout->setSpacing(8); m_SmoothingSpinBox = new QDoubleSpinBox(m_MainControl); m_SmoothingSpinBox->setMinimum(0.0); m_SmoothingSpinBox->setSingleStep(0.5); m_SmoothingSpinBox->setValue(0.1); m_SmoothingSpinBox->setToolTip("The Smoothing value is used as Sigma for a gaussian blur."); surfaceLayout->addRow("Smoothing value (mm)", m_SmoothingSpinBox); m_DecimationSpinBox = new QDoubleSpinBox(m_MainControl); m_DecimationSpinBox->setMinimum(0.0); m_DecimationSpinBox->setMaximum(0.99); m_DecimationSpinBox->setSingleStep(0.1); m_DecimationSpinBox->setValue(0.5); m_DecimationSpinBox->setToolTip("Valid range is [0, 1). High values increase decimation, especially when very close to 1. A value of 0 disables decimation."); surfaceLayout->addRow("Decimation rate", m_DecimationSpinBox); m_SelectionModeCheckBox = new QCheckBox("Enable auto-selection mode", m_MainControl); m_SelectionModeCheckBox->setToolTip("If checked the segmentation plugin ensures that only one segmentation and the according greyvalue image are visible at one time."); formLayout->addRow("Data node selection mode",m_SelectionModeCheckBox); formLayout->addRow("Smoothed surface creation", surfaceLayout); m_MainControl->setLayout(formLayout); this->Update(); m_Initializing = false; } QWidget* QmitkMultiLabelSegmentationPreferencePage::GetQtControl() const { return m_MainControl; } bool QmitkMultiLabelSegmentationPreferencePage::PerformOk() { m_SegmentationPreferencesNode->PutBool("draw outline", m_RadioOutline->isChecked()); m_SegmentationPreferencesNode->PutBool("volume rendering", m_VolumeRenderingCheckBox->isChecked()); m_SegmentationPreferencesNode->PutDouble("smoothing value", m_SmoothingSpinBox->value()); m_SegmentationPreferencesNode->PutDouble("decimation rate", m_DecimationSpinBox->value()); m_SegmentationPreferencesNode->PutBool("auto selection", m_SelectionModeCheckBox->isChecked()); return true; } void QmitkMultiLabelSegmentationPreferencePage::PerformCancel() { } void QmitkMultiLabelSegmentationPreferencePage::Update() { //m_EnableSingleEditing->setChecked(m_SegmentationPreferencesNode->GetBool("Single click property editing", true)); if (m_SegmentationPreferencesNode->GetBool("draw outline", true) ) { m_RadioOutline->setChecked( true ); } else { m_RadioOverlay->setChecked( true ); } m_VolumeRenderingCheckBox->setChecked( m_SegmentationPreferencesNode->GetBool("volume rendering", false) ); if (m_SegmentationPreferencesNode->GetBool("smoothing hint", true)) { m_SmoothingSpinBox->setDisabled(true); } else { m_SmoothingSpinBox->setEnabled(true); } m_SelectionModeCheckBox->setChecked( m_SegmentationPreferencesNode->GetBool("auto selection", true) ); m_SmoothingSpinBox->setValue(m_SegmentationPreferencesNode->GetDouble("smoothing value", 0.1)); m_DecimationSpinBox->setValue(m_SegmentationPreferencesNode->GetDouble("decimation rate", 0.5)); } void QmitkMultiLabelSegmentationPreferencePage::OnVolumeRenderingCheckboxChecked(int state) { if (m_Initializing) return; if ( state != Qt::Unchecked ) { QMessageBox::information(NULL, "Memory warning", "Turning on volume rendering of segmentations will make the application more memory intensive (and potentially prone to crashes).\n\n" "If you encounter out-of-memory problems, try turning off volume rendering again."); } } void QmitkMultiLabelSegmentationPreferencePage::OnSmoothingCheckboxChecked(int state) { if (state != Qt::Unchecked) m_SmoothingSpinBox->setDisabled(true); else m_SmoothingSpinBox->setEnabled(true); } diff --git a/Plugins/org.mitk.gui.qt.multilabelsegmentation/src/internal/QmitkCreatePolygonModelAction.cpp b/Plugins/org.mitk.gui.qt.multilabelsegmentation/src/internal/QmitkCreatePolygonModelAction.cpp index 93f72d0b6c..3dd81c60f2 100644 --- a/Plugins/org.mitk.gui.qt.multilabelsegmentation/src/internal/QmitkCreatePolygonModelAction.cpp +++ b/Plugins/org.mitk.gui.qt.multilabelsegmentation/src/internal/QmitkCreatePolygonModelAction.cpp @@ -1,173 +1,173 @@ /*=================================================================== The Medical Imaging Interaction Toolkit (MITK) Copyright (c) German Cancer Research Center, Division of Medical and Biological Informatics. All rights reserved. This software is distributed WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See LICENSE.txt or http://www.mitk.org for details. ===================================================================*/ #include "QmitkCreatePolygonModelAction.h" // MITK #include #include #include #include #include #include #include // Blueberry #include #include #include #include #include using namespace berry; using namespace mitk; using namespace std; QmitkCreatePolygonModelAction::QmitkCreatePolygonModelAction() { } QmitkCreatePolygonModelAction::~QmitkCreatePolygonModelAction() { } void QmitkCreatePolygonModelAction::Run(const QList &selectedNodes) { DataNode::Pointer selectedNode = selectedNodes[0]; Image::Pointer image = dynamic_cast(selectedNode->GetData()); if (image.IsNull()) return; try { if (!m_IsSmoothed) { ShowSegmentationAsSurface::Pointer surfaceFilter = ShowSegmentationAsSurface::New(); itk::SimpleMemberCommand::Pointer successCommand = itk::SimpleMemberCommand::New(); successCommand->SetCallbackFunction(this, &QmitkCreatePolygonModelAction::OnSurfaceCalculationDone); surfaceFilter->AddObserver(ResultAvailable(), successCommand); itk::SimpleMemberCommand::Pointer errorCommand = itk::SimpleMemberCommand::New(); errorCommand->SetCallbackFunction(this, &QmitkCreatePolygonModelAction::OnSurfaceCalculationDone); surfaceFilter->AddObserver(ProcessingError(), errorCommand); surfaceFilter->SetDataStorage(*m_DataStorage); surfaceFilter->SetPointerParameter("Input", image); surfaceFilter->SetPointerParameter("Group node", selectedNode); surfaceFilter->SetParameter("Show result", true); surfaceFilter->SetParameter("Sync visibility", false); surfaceFilter->SetParameter("Smooth", false); surfaceFilter->SetParameter("Apply median", false); surfaceFilter->SetParameter("Median kernel size", 3u); surfaceFilter->SetParameter("Gaussian SD", 1.5f); surfaceFilter->SetParameter("Decimate mesh", m_IsDecimated); surfaceFilter->SetParameter("Decimation rate", 0.8f); StatusBar::GetInstance()->DisplayText("Surface creation started in background..."); surfaceFilter->StartAlgorithm(); } else { ShowSegmentationAsSmoothedSurface::Pointer surfaceFilter = ShowSegmentationAsSmoothedSurface::New(); itk::SimpleMemberCommand::Pointer successCommand = itk::SimpleMemberCommand::New(); successCommand->SetCallbackFunction(this, &QmitkCreatePolygonModelAction::OnSurfaceCalculationDone); surfaceFilter->AddObserver(mitk::ResultAvailable(), successCommand); itk::SimpleMemberCommand::Pointer errorCommand = itk::SimpleMemberCommand::New(); errorCommand->SetCallbackFunction(this, &QmitkCreatePolygonModelAction::OnSurfaceCalculationDone); surfaceFilter->AddObserver(mitk::ProcessingError(), errorCommand); surfaceFilter->SetDataStorage(*m_DataStorage); surfaceFilter->SetPointerParameter("Input", image); surfaceFilter->SetPointerParameter("Group node", selectedNode); berry::IWorkbenchPart::Pointer activePart = berry::PlatformUI::GetWorkbench()->GetActiveWorkbenchWindow()->GetActivePage()->GetActivePart(); mitk::IRenderWindowPart* renderPart = dynamic_cast(activePart.GetPointer()); mitk::SliceNavigationController* timeNavController = 0; if (renderPart != 0) { timeNavController = renderPart->GetRenderingManager()->GetTimeNavigationController(); } int timeNr = timeNavController != 0 ? timeNavController->GetTime()->GetPos() : 0; surfaceFilter->SetParameter("TimeNr", timeNr); IPreferencesService* prefService = berry::Platform::GetPreferencesService(); - IPreferences::Pointer segPref = prefService->GetSystemPreferences()->Node("/org.mitk.views.segmentation"); + IPreferences::Pointer segPref = prefService->GetSystemPreferences()->Node("/org.mitk.views.multilabelsegmentation"); bool smoothingHint = segPref->GetBool("smoothing hint", true); ScalarType smoothing = segPref->GetDouble("smoothing value", 1.0); ScalarType decimation = segPref->GetDouble("decimation rate", 0.5); ScalarType closing = segPref->GetDouble("closing ratio", 0.0); if (smoothingHint) { smoothing = 0.0; Vector3D spacing = image->GetGeometry()->GetSpacing(); for (Vector3D::Iterator iter = spacing.Begin(); iter != spacing.End(); ++iter) smoothing = max(smoothing, *iter); } surfaceFilter->SetParameter("Smoothing", smoothing); surfaceFilter->SetParameter("Decimation", decimation); surfaceFilter->SetParameter("Closing", closing); ProgressBar::GetInstance()->AddStepsToDo(8); StatusBar::GetInstance()->DisplayText("Smoothed surface creation started in background..."); try { surfaceFilter->StartAlgorithm(); } catch (...) { MITK_ERROR<<"Error creating smoothed polygon model: Not enough memory!"; } } } catch(...) { MITK_ERROR << "Surface creation failed!"; } } void QmitkCreatePolygonModelAction::OnSurfaceCalculationDone() { StatusBar::GetInstance()->Clear(); } void QmitkCreatePolygonModelAction::SetDataStorage(DataStorage *dataStorage) { m_DataStorage = dataStorage; } void QmitkCreatePolygonModelAction::SetSmoothed(bool smoothed) { m_IsSmoothed = smoothed; } void QmitkCreatePolygonModelAction::SetDecimated(bool decimated) { m_IsDecimated = decimated; } void QmitkCreatePolygonModelAction::SetFunctionality(QtViewPart *) { } diff --git a/Plugins/org.mitk.gui.qt.multilabelsegmentation/src/internal/QmitkMultiLabelSegmentationView.cpp b/Plugins/org.mitk.gui.qt.multilabelsegmentation/src/internal/QmitkMultiLabelSegmentationView.cpp index 2c3261d472..820a80a8fb 100644 --- a/Plugins/org.mitk.gui.qt.multilabelsegmentation/src/internal/QmitkMultiLabelSegmentationView.cpp +++ b/Plugins/org.mitk.gui.qt.multilabelsegmentation/src/internal/QmitkMultiLabelSegmentationView.cpp @@ -1,944 +1,991 @@ /*=================================================================== The Medical Imaging Interaction Toolkit (MITK) Copyright (c) German Cancer Research Center, Division of Medical and Biological Informatics. All rights reserved. This software is distributed WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See LICENSE.txt or http://www.mitk.org for details. ===================================================================*/ #include "QmitkMultiLabelSegmentationView.h" // blueberry #include #include // mitk #include "mitkLabelSetImage.h" #include "mitkStatusBar.h" #include "mitkApplicationCursor.h" #include "mitkToolManagerProvider.h" //#include "mitkSegmentationObjectFactory.h" #include "mitkSegTool2D.h" #include "mitkPlanePositionManager.h" #include "mitkPluginActivator.h" #include "mitkInteractionEventObserver.h" // Qmitk #include "QmitkSegmentationOrganNamesHandling.cpp" #include "QmitkRenderWindow.h" #include "QmitkNewSegmentationDialog.h" // us #include #include #include #include #include // Qt #include #include #include #include #include "tinyxml.h" #include const std::string QmitkMultiLabelSegmentationView::VIEW_ID = "org.mitk.views.multilabelsegmentation"; QmitkMultiLabelSegmentationView::QmitkMultiLabelSegmentationView() : m_Parent(NULL), m_IRenderWindowPart(NULL), m_ReferenceNode(NULL), m_ToolManager(NULL), m_WorkingNode(NULL), m_MouseCursorSet(false) { m_SegmentationPredicate = mitk::NodePredicateAnd::New(); m_SegmentationPredicate->AddPredicate(mitk::TNodePredicateDataType::New()); m_SegmentationPredicate->AddPredicate(mitk::NodePredicateNot::New(mitk::NodePredicateProperty::New("helper object"))); mitk::TNodePredicateDataType::Pointer isImage = mitk::TNodePredicateDataType::New(); mitk::NodePredicateProperty::Pointer isBinary = mitk::NodePredicateProperty::New("binary", mitk::BoolProperty::New(true)); mitk::NodePredicateAnd::Pointer isMask = mitk::NodePredicateAnd::New(isBinary, isImage); mitk::NodePredicateDataType::Pointer isDwi = mitk::NodePredicateDataType::New("DiffusionImage"); mitk::NodePredicateDataType::Pointer isDti = mitk::NodePredicateDataType::New("TensorImage"); mitk::NodePredicateDataType::Pointer isQbi = mitk::NodePredicateDataType::New("QBallImage"); mitk::NodePredicateOr::Pointer validImages = mitk::NodePredicateOr::New(); validImages->AddPredicate(isImage); validImages->AddPredicate(isDwi); validImages->AddPredicate(isDti); validImages->AddPredicate(isQbi); m_ReferencePredicate = mitk::NodePredicateAnd::New(); m_ReferencePredicate->AddPredicate(validImages); m_ReferencePredicate->AddPredicate(mitk::NodePredicateNot::New(m_SegmentationPredicate)); m_ReferencePredicate->AddPredicate(mitk::NodePredicateNot::New(isMask)); m_ReferencePredicate->AddPredicate(mitk::NodePredicateNot::New(mitk::NodePredicateProperty::New("helper object"))); } QmitkMultiLabelSegmentationView::~QmitkMultiLabelSegmentationView() { //m_ToolManager->ActivateTool(-1); /* todo: check this m_Controls.m_SliceBasedInterpolatorWidget->EnableInterpolation(false); ctkPluginContext* context = mitk::PluginActivator::getContext(); ctkServiceReference ppmRef = context->getServiceReference(); mitk::PlanePositionManagerService* service = context->getService(ppmRef); service->RemoveAllPlanePositions(); context->ungetService(ppmRef); */ //m_ToolManager->SetReferenceData(NULL); //m_ToolManager->SetWorkingData(NULL); //m_ServiceRegistration.Unregister(); //Loose LabelSetConnections OnLooseLabelSetConnection(); } void QmitkMultiLabelSegmentationView::CreateQtPartControl(QWidget* parent) { // setup the basic GUI of this view -// m_Parent = parent; + m_Parent = parent; m_Controls.setupUi(parent); - // *------------------------ // * DATA SELECTION WIDGETS // *------------------------ m_Controls.m_cbReferenceNodeSelector->SetAutoSelectNewItems(true); m_Controls.m_cbReferenceNodeSelector->SetPredicate(m_ReferencePredicate); m_Controls.m_cbReferenceNodeSelector->SetDataStorage(this->GetDataStorage()); m_Controls.m_cbWorkingNodeSelector->SetAutoSelectNewItems(true); m_Controls.m_cbWorkingNodeSelector->SetPredicate(m_SegmentationPredicate); m_Controls.m_cbWorkingNodeSelector->SetDataStorage(this->GetDataStorage()); connect( m_Controls.m_cbReferenceNodeSelector, SIGNAL( OnSelectionChanged( const mitk::DataNode* ) ), this, SLOT( OnReferenceSelectionChanged( const mitk::DataNode* ) ) ); connect( m_Controls.m_cbWorkingNodeSelector, SIGNAL( OnSelectionChanged( const mitk::DataNode* ) ), this, SLOT( OnSegmentationSelectionChanged( const mitk::DataNode* ) ) ); // *------------------------ // * ToolManager // *------------------------ m_ToolManager = mitk::ToolManagerProvider::GetInstance()->GetToolManager(); assert(m_ToolManager); m_ToolManager->SetDataStorage( *(this->GetDataStorage()) ); m_ToolManager->InitializeTools(); //use the same ToolManager instance for our 3D Tools m_Controls.m_ManualToolSelectionBox3D->SetToolManager(*m_ToolManager); // *------------------------ // * LabelSetWidget // *------------------------ m_Controls.m_LabelSetWidget->SetDataStorage(this->GetDataStorage()); m_Controls.m_LabelSetWidget->SetOrganColors(mitk::OrganNamesHandling::GetDefaultOrganColorString()); m_Controls.m_LabelSetWidget->hide(); // *------------------------ // * Interpolation // *------------------------ m_Controls.m_SurfaceBasedInterpolatorWidget->SetDataStorage( *(this->GetDataStorage()) ); m_Controls.m_SliceBasedInterpolatorWidget->SetDataStorage( *(this->GetDataStorage()) ); connect( m_Controls.m_cbInterpolation, SIGNAL( activated (int) ), this, SLOT( OnInterpolationSelectionChanged(int) ) ); m_Controls.m_cbInterpolation->setCurrentIndex(0); m_Controls.m_swInterpolation->hide(); // *------------------------ // * ToolSelection 2D // *------------------------ m_Controls.m_ManualToolSelectionBox2D->SetGenerateAccelerators(true); m_Controls.m_ManualToolSelectionBox2D->SetToolGUIArea( m_Controls.m_ManualToolGUIContainer2D ); m_Controls.m_ManualToolSelectionBox2D->SetDisplayedToolGroups("Add Subtract Fill Erase Paint Wipe 'Region Growing' FastMarching2D Correction 'Live Wire'");// todo: "Correction 'Live Wire'" m_Controls.m_ManualToolSelectionBox2D->SetEnabledMode( QmitkToolSelectionBox::EnabledWithReferenceAndWorkingDataVisible ); connect( m_Controls.m_ManualToolSelectionBox2D, SIGNAL(ToolSelected(int)), this, SLOT(OnManualTool2DSelected(int)) ); // *------------------------ // * ToolSelection 3D // *------------------------ m_Controls.m_ManualToolSelectionBox3D->SetGenerateAccelerators(true); m_Controls.m_ManualToolSelectionBox3D->SetToolGUIArea( m_Controls.m_ManualToolGUIContainer3D ); m_Controls.m_ManualToolSelectionBox3D->SetDisplayedToolGroups("Threshold 'Two Thresholds' 'Auto Threshold' 'Multiple Otsu'"); // todo add : FastMarching3D RegionGrowing Watershed m_Controls.m_ManualToolSelectionBox3D->SetLayoutColumns(2); m_Controls.m_ManualToolSelectionBox3D->SetEnabledMode( QmitkToolSelectionBox::EnabledWithReferenceAndWorkingDataVisible ); // *------------------------* // * Connect PushButtons (pb) // *------------------------* connect( m_Controls.m_pbNewLabel, SIGNAL(clicked()), this, SLOT( OnNewLabel()) ); connect( m_Controls.m_pbNewSegmentationSession, SIGNAL(clicked()), this, SLOT( OnNewSegmentationSession()) ); connect( m_Controls.m_pbShowLabelTable, SIGNAL(toggled(bool)), this, SLOT( OnShowLabelTable(bool)) ); // *------------------------* // * Connect LabelSetWidget // *------------------------* connect(m_Controls.m_LabelSetWidget, SIGNAL(goToLabel(const mitk::Point3D&)), this, SLOT(OnGoToLabel(const mitk::Point3D&)) ); connect(m_Controls.m_LabelSetWidget, SIGNAL(resetView()), this, SLOT(OnResetView()) ); // *------------------------* // * DATA SLECTION WIDGET // *------------------------* m_IRenderWindowPart = this->GetRenderWindowPart(); if (m_IRenderWindowPart) { QList controllers; controllers.push_back(m_IRenderWindowPart->GetQmitkRenderWindow("axial")->GetSliceNavigationController()); controllers.push_back(m_IRenderWindowPart->GetQmitkRenderWindow("sagittal")->GetSliceNavigationController()); controllers.push_back(m_IRenderWindowPart->GetQmitkRenderWindow("coronal")->GetSliceNavigationController()); m_Controls.m_SliceBasedInterpolatorWidget->SetSliceNavigationControllers(controllers); // m_Controls.m_LabelSetWidget->SetRenderWindowPart(this->m_IRenderWindowPart); } // this->InitializeListeners(); connect( m_Controls.m_btAddLayer, SIGNAL(clicked()), this, SLOT( OnAddLayer()) ); connect( m_Controls.m_btDeleteLayer, SIGNAL(clicked()), this, SLOT( OnDeleteLayer()) ); connect( m_Controls.m_btPreviousLayer, SIGNAL(clicked()), this, SLOT( OnPreviousLayer()) ); connect( m_Controls.m_btNextLayer, SIGNAL(clicked()), this, SLOT( OnNextLayer()) ); connect( m_Controls.m_btLockExterior, SIGNAL(toggled(bool)), this, SLOT( OnLockExteriorToggled(bool)) ); connect( m_Controls.m_cbActiveLayer, SIGNAL(currentIndexChanged(int)), this, SLOT( OnChangeLayer(int)) ); m_Controls.m_btAddLayer->setEnabled(false); m_Controls.m_btDeleteLayer->setEnabled(false); m_Controls.m_btNextLayer->setEnabled(false); m_Controls.m_btPreviousLayer->setEnabled(false); m_Controls.m_cbActiveLayer->setEnabled(false); m_Controls.m_pbNewLabel->setEnabled(false); m_Controls.m_btLockExterior->setEnabled(false); m_Controls.m_pbShowLabelTable->setEnabled(false); // Make sure the GUI notices if appropriate data is already present on creation this->OnReferenceSelectionChanged(m_Controls.m_cbReferenceNodeSelector->GetSelectedNode()); this->OnSegmentationSelectionChanged(m_Controls.m_cbWorkingNodeSelector->GetSelectedNode()); } void QmitkMultiLabelSegmentationView::Activated() { m_ToolManager->SetReferenceData(m_Controls.m_cbReferenceNodeSelector->GetSelectedNode()); m_ToolManager->SetWorkingData(m_Controls.m_cbWorkingNodeSelector->GetSelectedNode()); } void QmitkMultiLabelSegmentationView::Deactivated() { // Not yet implemented } void QmitkMultiLabelSegmentationView::Visible() { // Not yet implemented } void QmitkMultiLabelSegmentationView::Hidden() { // Not yet implemented } + void QmitkMultiLabelSegmentationView::InitializeListeners() { if (m_Interactor.IsNull()) { us::Module* module = us::GetModuleContext()->GetModule(); std::vector resources = module->FindResources("/", "*", true); for (std::vector::iterator iter = resources.begin(); iter != resources.end(); ++iter) { MITK_INFO << iter->GetResourcePath(); } m_Interactor = mitk::SegmentationInteractor::New(); if (!m_Interactor->LoadStateMachine("SegmentationInteraction.xml", module)) { MITK_WARN << "Error loading state machine"; } if (!m_Interactor->SetEventConfig ("ConfigSegmentation.xml", module)) { MITK_WARN << "Error loading state machine configuration"; } // Register as listener via micro services us::ServiceProperties props; props["name"] = std::string("SegmentationInteraction"); m_ServiceRegistration = us::GetModuleContext()->RegisterService(m_Interactor.GetPointer(), props); } } void QmitkMultiLabelSegmentationView::SetFocus () { } bool QmitkMultiLabelSegmentationView::CheckForSameGeometry(const mitk::Image *image1, const mitk::Image *image2) const { bool isSameGeometry(true); if (image1 && image2) { mitk::BaseGeometry::Pointer geo1 = image1->GetGeometry(); mitk::BaseGeometry::Pointer geo2 = image2->GetGeometry(); isSameGeometry = isSameGeometry && mitk::Equal(geo1->GetOrigin(), geo2->GetOrigin()); isSameGeometry = isSameGeometry && mitk::Equal(geo1->GetExtent(0), geo2->GetExtent(0)); isSameGeometry = isSameGeometry && mitk::Equal(geo1->GetExtent(1), geo2->GetExtent(1)); isSameGeometry = isSameGeometry && mitk::Equal(geo1->GetExtent(2), geo2->GetExtent(2)); isSameGeometry = isSameGeometry && mitk::Equal(geo1->GetSpacing(), geo2->GetSpacing()); isSameGeometry = isSameGeometry && mitk::MatrixEqualElementWise(geo1->GetIndexToWorldTransform()->GetMatrix(), geo2->GetIndexToWorldTransform()->GetMatrix()); return isSameGeometry; } else { return false; } } void QmitkMultiLabelSegmentationView::RenderWindowPartActivated(mitk::IRenderWindowPart* renderWindowPart) { if (m_IRenderWindowPart != renderWindowPart) { m_IRenderWindowPart = renderWindowPart; m_Parent->setEnabled(true); QList controllers; - controllers.push_back(renderWindowPart->GetQmitkRenderWindow("axial")->GetSliceNavigationController()); - controllers.push_back(renderWindowPart->GetQmitkRenderWindow("sagittal")->GetSliceNavigationController()); - controllers.push_back(renderWindowPart->GetQmitkRenderWindow("coronal")->GetSliceNavigationController()); + controllers.push_back(m_IRenderWindowPart->GetQmitkRenderWindow("axial")->GetSliceNavigationController()); + controllers.push_back(m_IRenderWindowPart->GetQmitkRenderWindow("sagittal")->GetSliceNavigationController()); + controllers.push_back(m_IRenderWindowPart->GetQmitkRenderWindow("coronal")->GetSliceNavigationController()); m_Controls.m_SliceBasedInterpolatorWidget->SetSliceNavigationControllers(controllers); } } void QmitkMultiLabelSegmentationView::RenderWindowPartDeactivated(mitk::IRenderWindowPart* /*renderWindowPart*/) { m_ToolManager->ActivateTool(-1); m_IRenderWindowPart = 0; m_Parent->setEnabled(false); } int QmitkMultiLabelSegmentationView::GetSizeFlags(bool width) { if(!width) { return berry::Constants::MIN | berry::Constants::MAX | berry::Constants::FILL; } else { return 0; } } int QmitkMultiLabelSegmentationView::ComputePreferredSize(bool width, int /*availableParallel*/, int /*availablePerpendicular*/, int preferredResult) { if(width==false) { return 100; } else { return preferredResult; } } void QmitkMultiLabelSegmentationView::UpdateControls() { mitk::DataNode* referenceNode = m_ToolManager->GetReferenceData(0); bool hasReferenceNode = referenceNode != NULL; mitk::DataNode* workingNode = m_ToolManager->GetWorkingData(0); bool hasValidWorkingNode = workingNode != NULL; m_Controls.m_pbNewLabel->setEnabled(false); m_Controls.m_gbInterpolation->setEnabled(false); m_Controls.m_SliceBasedInterpolatorWidget->setEnabled(false); m_Controls.m_SurfaceBasedInterpolatorWidget->setEnabled(false); m_Controls.m_LabelSetWidget->setEnabled(false); m_Controls.m_btAddLayer->setEnabled(false); m_Controls.m_btDeleteLayer->setEnabled(false); m_Controls.m_cbActiveLayer->setEnabled(false); m_Controls.m_btPreviousLayer->setEnabled(false); m_Controls.m_btNextLayer->setEnabled(false); m_Controls.m_btLockExterior->setChecked(false); m_Controls.m_btLockExterior->setEnabled(false); m_Controls.m_pbShowLabelTable->setChecked(false); m_Controls.m_pbShowLabelTable->setEnabled(false); m_Controls.m_ManualToolSelectionBox3D->SetEnabledMode(QmitkToolSelectionBox::EnabledWithReferenceAndWorkingDataVisible); m_Controls.m_ManualToolSelectionBox2D->SetEnabledMode(QmitkToolSelectionBox::EnabledWithReferenceAndWorkingDataVisible); if(hasValidWorkingNode) { // TODO adapt tool manager so that this check is done there, e.g. convenience function mitk::LabelSetImage* workingImage = dynamic_cast(workingNode->GetData()); hasValidWorkingNode = workingImage != nullptr; if (hasValidWorkingNode) { m_Controls.m_pbNewLabel->setEnabled(true); m_Controls.m_btLockExterior->setEnabled(true); m_Controls.m_pbShowLabelTable->setEnabled(true); m_Controls.m_gbInterpolation->setEnabled(true); m_Controls.m_SliceBasedInterpolatorWidget->setEnabled(true); m_Controls.m_SurfaceBasedInterpolatorWidget->setEnabled(true); m_Controls.m_LabelSetWidget->setEnabled(true); m_Controls.m_btAddLayer->setEnabled(true); int activeLayer = workingImage->GetActiveLayer(); int numberOfLayers = workingImage->GetNumberOfLayers(); m_Controls.m_cbActiveLayer->blockSignals(true); m_Controls.m_cbActiveLayer->clear(); for (unsigned int lidx=0; lidxGetNumberOfLayers(); ++lidx) m_Controls.m_cbActiveLayer->addItem(QString::number(lidx)); m_Controls.m_cbActiveLayer->setCurrentIndex(activeLayer); m_Controls.m_cbActiveLayer->blockSignals(false); - m_Controls.m_btDeleteLayer->setEnabled(numberOfLayers>1); - m_Controls.m_cbActiveLayer->setEnabled(numberOfLayers>1); - m_Controls.m_btPreviousLayer->setEnabled(activeLayer>0); - m_Controls.m_btNextLayer->setEnabled(activeLayer!=numberOfLayers-1); - m_Controls.m_btLockExterior->setChecked(workingImage->GetLabel(0)->GetLocked()); + m_Controls.m_cbActiveLayer->setEnabled(numberOfLayers > 1); + m_Controls.m_btDeleteLayer->setEnabled(numberOfLayers > 1); + m_Controls.m_btPreviousLayer->setEnabled(activeLayer > 0); + m_Controls.m_btNextLayer->setEnabled(activeLayer != numberOfLayers - 1); + m_Controls.m_btLockExterior->setChecked(workingImage->GetLabel(0, activeLayer)->GetLocked()); m_Controls.m_pbShowLabelTable->setChecked(workingImage->GetNumberOfLabels() > 1 /*1st is exterior*/); //MLI TODO //m_Controls.m_ManualToolSelectionBox2D->SetEnabledMode(QmitkToolSelectionBox::EnabledWithWorkingDataVisible); } } if(hasValidWorkingNode && hasReferenceNode) { int layer = -1; referenceNode->GetIntProperty("layer", layer); - workingNode->SetIntProperty("layer", layer+1); + workingNode->SetIntProperty("layer", layer + 1); } this->RequestRenderWindowUpdate(mitk::RenderingManager::REQUEST_UPDATE_ALL); } void QmitkMultiLabelSegmentationView::OnNewSegmentationSession() { mitk::DataNode* referenceNode = m_Controls.m_cbReferenceNodeSelector->GetSelectedNode(); if (!referenceNode) { QMessageBox::information( m_Parent, "New Segmentation Session", "Please load and select a patient image before starting some action."); return; } m_ToolManager->ActivateTool(-1); mitk::Image* referenceImage = dynamic_cast( referenceNode->GetData() ); assert(referenceImage); QString newName = QString::fromStdString(referenceNode->GetName()); newName.append("-labels"); bool ok = false; newName = QInputDialog::getText(m_Parent, "New Segmentation Session", "New name:", QLineEdit::Normal, newName, &ok); if(!ok) return; this->WaitCursorOn(); mitk::LabelSetImage::Pointer workingImage = mitk::LabelSetImage::New(); try { workingImage->Initialize(referenceImage); } catch ( mitk::Exception& e ) { this->WaitCursorOff(); MITK_ERROR << "Exception caught: " << e.GetDescription(); QMessageBox::information(m_Parent, "New Segmentation Session", "Could not create a new segmentation session.\n"); return; } this->WaitCursorOff(); mitk::DataNode::Pointer workingNode = mitk::DataNode::New(); workingNode->SetData(workingImage); workingNode->SetName(newName.toStdString()); workingImage->GetExteriorLabel()->SetProperty("name.parent",mitk::StringProperty::New(referenceNode->GetName().c_str())); workingImage->GetExteriorLabel()->SetProperty("name.image",mitk::StringProperty::New(newName.toStdString().c_str())); if (!this->GetDataStorage()->Exists(workingNode)) this->GetDataStorage()->Add(workingNode, referenceNode); m_Controls.m_LabelSetWidget->ResetAllTableWidgetItems(); OnNewLabel(); } void QmitkMultiLabelSegmentationView::OnNewLabel() { m_ToolManager->ActivateTool(-1); mitk::DataNode* workingNode = m_ToolManager->GetWorkingData(0); if (!workingNode) { QMessageBox::information(m_Parent, "New Segmentation Session", "Please load and select a patient image before starting some action."); return; } mitk::LabelSetImage* workingImage = dynamic_cast(workingNode->GetData()); if (!workingImage) { QMessageBox::information(m_Parent, "New Segmentation Session", "Please load and select a patient image before starting some action."); return; } QmitkNewSegmentationDialog* dialog = new QmitkNewSegmentationDialog( m_Parent ); dialog->SetSuggestionList( mitk::OrganNamesHandling::GetDefaultOrganColorString() ); dialog->setWindowTitle("New Label"); int dialogReturnValue = dialog->exec(); if ( dialogReturnValue == QDialog::Rejected ) return; QString segName = dialog->GetSegmentationName(); if(segName.isEmpty()) segName = "Unnamed"; workingImage->GetActiveLabelSet()->AddLabel(segName.toStdString(), dialog->GetColor()); UpdateControls(); m_Controls.m_LabelSetWidget->ResetAllTableWidgetItems(); } void QmitkMultiLabelSegmentationView::OnShowLabelTable(bool value) { if (value) m_Controls.m_LabelSetWidget->show(); else m_Controls.m_LabelSetWidget->hide(); } void QmitkMultiLabelSegmentationView::OnNextLayer() { m_ToolManager->ActivateTool(-1); mitk::DataNode* workingNode = m_ToolManager->GetWorkingData(0); assert(workingNode); mitk::LabelSetImage* workingImage = dynamic_cast(workingNode->GetData()); assert(workingImage); OnChangeLayer(workingImage->GetActiveLayer() + 1 ); } void QmitkMultiLabelSegmentationView::OnPreviousLayer() { m_ToolManager->ActivateTool(-1); mitk::DataNode* workingNode = m_ToolManager->GetWorkingData(0); assert(workingNode); mitk::LabelSetImage* workingImage = dynamic_cast(workingNode->GetData()); assert(workingImage); OnChangeLayer(workingImage->GetActiveLayer() - 1 ); } void QmitkMultiLabelSegmentationView::OnChangeLayer(int layer) { m_ToolManager->ActivateTool(-1); mitk::DataNode* workingNode = m_ToolManager->GetWorkingData(0); assert(workingNode); mitk::LabelSetImage* workingImage = dynamic_cast(workingNode->GetData()); assert(workingImage); this->WaitCursorOn(); - workingImage->SetActiveLayer( layer ); + workingImage->SetActiveLayer(layer); this->WaitCursorOff(); UpdateControls(); m_Controls.m_LabelSetWidget->ResetAllTableWidgetItems(); } void QmitkMultiLabelSegmentationView::OnDeleteLayer() { m_ToolManager->ActivateTool(-1); mitk::DataNode* workingNode = m_ToolManager->GetWorkingData(0); assert(workingNode); mitk::LabelSetImage* workingImage = dynamic_cast(workingNode->GetData()); assert(workingImage); if (workingImage->GetNumberOfLayers() < 2) return; QString question = "Do you really want to delete the current layer?"; QMessageBox::StandardButton answerButton = QMessageBox::question( m_Controls.m_LabelSetWidget, "Delete layer", question, QMessageBox::Yes | QMessageBox::Cancel, QMessageBox::Yes); if (answerButton != QMessageBox::Yes) return; try { this->WaitCursorOn(); workingImage->RemoveLayer(); this->WaitCursorOff(); } catch ( mitk::Exception& e ) { this->WaitCursorOff(); MITK_ERROR << "Exception caught: " << e.GetDescription(); QMessageBox::information(m_Controls.m_LabelSetWidget, "Delete Layer", "Could not delete the currently active layer. See error log for details.\n"); return; } UpdateControls(); m_Controls.m_LabelSetWidget->ResetAllTableWidgetItems(); } void QmitkMultiLabelSegmentationView::OnAddLayer() { m_ToolManager->ActivateTool(-1); mitk::DataNode* workingNode = m_ToolManager->GetWorkingData(0); assert(workingNode); mitk::LabelSetImage* workingImage = dynamic_cast(workingNode->GetData()); assert(workingImage); QString question = "Do you really want to add a layer to the current segmentation session?"; QMessageBox::StandardButton answerButton = QMessageBox::question( m_Controls.m_LabelSetWidget, "Add layer", question, QMessageBox::Yes | QMessageBox::Cancel, QMessageBox::Yes); if (answerButton != QMessageBox::Yes) return; int newLabelSetId = -1; try { WaitCursorOn(); newLabelSetId = workingImage->AddLayer(); WaitCursorOff(); } catch ( mitk::Exception& e ) { WaitCursorOff(); MITK_ERROR << "Exception caught: " << e.GetDescription(); QMessageBox::information(m_Controls.m_LabelSetWidget, "Add Layer", "Could not add a new layer. See error log for details.\n"); return; } // Update controls and label set list for direct response m_Controls.m_LabelSetWidget->ResetAllTableWidgetItems(); OnNewLabel(); UpdateControls(); } void QmitkMultiLabelSegmentationView::OnDeactivateActiveTool() { m_ToolManager->ActivateTool(-1); } void QmitkMultiLabelSegmentationView::OnLockExteriorToggled(bool checked) { mitk::DataNode* workingNode = m_ToolManager->GetWorkingData(0); assert(workingNode); mitk::LabelSetImage* workingImage = dynamic_cast(workingNode->GetData()); assert(workingImage); workingImage->GetLabel(0)->SetLocked(checked); } void QmitkMultiLabelSegmentationView::NodeAdded(const mitk::DataNode*) { /* bool isHelperObject(false); node->GetBoolProperty("helper object", isHelperObject); if (isHelperObject) return; if (m_ReferenceNode.IsNotNull() && dynamic_cast(node->GetData())) { mitk::LabelSetImage* workingImage = dynamic_cast(node->GetData()); if (workingImage->GetNumberOfLabels() > 2) m_Controls.m_LabelSetWidget->show(); else m_Controls.m_LabelSetWidget->hide(); } */ } void QmitkMultiLabelSegmentationView::NodeRemoved(const mitk::DataNode* node) { bool isHelperObject(false); node->GetBoolProperty("helper object", isHelperObject); if (isHelperObject) return; if (m_ReferenceNode.IsNotNull() && dynamic_cast(node->GetData())) { // remove all possible contour markers of the segmentation mitk::DataStorage::SetOfObjects::ConstPointer allContourMarkers = this->GetDataStorage()->GetDerivations(node, mitk::NodePredicateProperty::New("isContourMarker", mitk::BoolProperty::New(true))); ctkPluginContext* context = mitk::PluginActivator::getContext(); ctkServiceReference ppmRef = context->getServiceReference(); mitk::PlanePositionManagerService* service = context->getService(ppmRef); for (mitk::DataStorage::SetOfObjects::ConstIterator it = allContourMarkers->Begin(); it != allContourMarkers->End(); ++it) { std::string nodeName = node->GetName(); unsigned int t = nodeName.find_last_of(" "); unsigned int id = atof(nodeName.substr(t+1).c_str())-1; service->RemovePlanePosition(id); this->GetDataStorage()->Remove(it->Value()); } context->ungetService(ppmRef); service = NULL; } } void QmitkMultiLabelSegmentationView::OnInterpolationSelectionChanged(int index) { if (index == 1) { m_Controls.m_SurfaceBasedInterpolatorWidget->m_Controls.m_btStart->setChecked(false);//OnToggleWidgetActivation(false); m_Controls.m_swInterpolation->setCurrentIndex(0); m_Controls.m_swInterpolation->show(); } else if (index == 2) { m_Controls.m_SliceBasedInterpolatorWidget->m_Controls.m_btStart->setChecked(false); m_Controls.m_swInterpolation->setCurrentIndex(1); m_Controls.m_swInterpolation->show(); } else { m_Controls.m_SurfaceBasedInterpolatorWidget->m_Controls.m_btStart->setChecked(false); m_Controls.m_SliceBasedInterpolatorWidget->m_Controls.m_btStart->setChecked(false); m_Controls.m_swInterpolation->setCurrentIndex(2); m_Controls.m_swInterpolation->hide(); } } void QmitkMultiLabelSegmentationView::OnReferenceSelectionChanged( const mitk::DataNode* node ) { m_ToolManager->ActivateTool(-1); m_ReferenceNode = const_cast(node); m_ToolManager->SetReferenceData(m_ReferenceNode); //check match of segmentation and reference image geometries if (node && m_WorkingNode.IsNotNull()) { mitk::Image* workingImage = dynamic_cast(m_WorkingNode->GetData()); assert(workingImage); mitk::Image* refImage = dynamic_cast(node->GetData()); assert(refImage); if (!this->CheckForSameGeometry(refImage, workingImage)) return; } this->UpdateControls(); //m_Controls.m_LabelSetWidget->ResetAllTableWidgetItems(); } void QmitkMultiLabelSegmentationView::OnEstablishLabelSetConnection() { MITK_INFO << "Connection Established"; if (m_WorkingNode.IsNull()) { return; } mitk::LabelSetImage* workingImage = dynamic_cast(m_WorkingNode->GetData()); assert(workingImage); workingImage->GetActiveLabelSet()->AddLabelEvent += mitk::MessageDelegate( m_Controls.m_LabelSetWidget, &QmitkLabelSetWidget::ResetAllTableWidgetItems); workingImage->GetActiveLabelSet()->RemoveLabelEvent += mitk::MessageDelegate( m_Controls.m_LabelSetWidget, &QmitkLabelSetWidget::ResetAllTableWidgetItems); workingImage->GetActiveLabelSet()->ModifyLabelEvent += mitk::MessageDelegate( m_Controls.m_LabelSetWidget, &QmitkLabelSetWidget::UpdateAllTableWidgetItems); workingImage->GetActiveLabelSet()->AllLabelsModifiedEvent += mitk::MessageDelegate( m_Controls.m_LabelSetWidget, &QmitkLabelSetWidget::UpdateAllTableWidgetItems); workingImage->GetActiveLabelSet()->ActiveLabelEvent += mitk::MessageDelegate1(m_Controls.m_LabelSetWidget, &QmitkLabelSetWidget::SelectLabelByPixelValue); workingImage->BeforeChangeLayerEvent += mitk::MessageDelegate( this, &QmitkMultiLabelSegmentationView::OnLooseLabelSetConnection); } void QmitkMultiLabelSegmentationView::OnLooseLabelSetConnection() { MITK_INFO << "Connection Lost"; if (m_WorkingNode.IsNull()) { return; } mitk::LabelSetImage* workingImage = dynamic_cast(m_WorkingNode->GetData()); assert(workingImage); // Reset LabelSetWidget Events workingImage->GetActiveLabelSet()->AddLabelEvent -= mitk::MessageDelegate( m_Controls.m_LabelSetWidget, &QmitkLabelSetWidget::ResetAllTableWidgetItems); workingImage->GetActiveLabelSet()->RemoveLabelEvent -= mitk::MessageDelegate( m_Controls.m_LabelSetWidget, &QmitkLabelSetWidget::ResetAllTableWidgetItems); workingImage->GetActiveLabelSet()->ModifyLabelEvent -= mitk::MessageDelegate( m_Controls.m_LabelSetWidget, &QmitkLabelSetWidget::UpdateAllTableWidgetItems); workingImage->GetActiveLabelSet()->AllLabelsModifiedEvent -= mitk::MessageDelegate( m_Controls.m_LabelSetWidget, &QmitkLabelSetWidget::UpdateAllTableWidgetItems); workingImage->GetActiveLabelSet()->ActiveLabelEvent -= mitk::MessageDelegate1(m_Controls.m_LabelSetWidget, &QmitkLabelSetWidget::SelectLabelByPixelValue); workingImage->BeforeChangeLayerEvent -= mitk::MessageDelegate( this, &QmitkMultiLabelSegmentationView::OnLooseLabelSetConnection); } void QmitkMultiLabelSegmentationView::OnSegmentationSelectionChanged(const mitk::DataNode *node) { m_ToolManager->ActivateTool(-1); if(m_WorkingNode.IsNotNull()) { mitk::LabelSetImage* workingImage = dynamic_cast(m_WorkingNode->GetData()); assert(workingImage); //Loose LabelSetConnections OnLooseLabelSetConnection(); } m_WorkingNode = const_cast(node); if(m_WorkingNode.IsNotNull()) { mitk::LabelSetImage* workingImage = dynamic_cast(m_WorkingNode->GetData()); assert(workingImage); //Establish LabelSetConnection OnEstablishLabelSetConnection(); } m_ToolManager->SetWorkingData(m_WorkingNode); //check match of segmentation and reference image geometries if (node && m_ReferenceNode.IsNotNull()) { mitk::Image* refImage = dynamic_cast(m_ReferenceNode->GetData()); assert(refImage); mitk::Image* workingImage = dynamic_cast(node->GetData()); assert(workingImage); if (!this->CheckForSameGeometry(refImage, workingImage)) return; } if (m_WorkingNode.IsNotNull()) { mitk::DataStorage::SetOfObjects::ConstPointer segNodes = this->GetDataStorage()->GetSubset(m_SegmentationPredicate); for(mitk::DataStorage::SetOfObjects::const_iterator iter = segNodes->begin(); iter != segNodes->end(); ++iter) { mitk::DataNode* _segNode = *iter; _segNode->SetVisibility(false); } m_WorkingNode->SetVisibility(true); } this->UpdateControls(); if (m_WorkingNode.IsNotNull()) { m_Controls.m_LabelSetWidget->ResetAllTableWidgetItems(); } } void QmitkMultiLabelSegmentationView::OnManualTool2DSelected(int id) { this->ResetMouseCursor(); mitk::StatusBar::GetInstance()->DisplayText(""); if (id >= 0) { std::string text = "Active Tool: \""; text += m_ToolManager->GetToolById(id)->GetName(); text += "\""; mitk::StatusBar::GetInstance()->DisplayText(text.c_str()); us::ModuleResource resource = m_ToolManager->GetToolById(id)->GetCursorIconResource(); if (resource.IsValid()) this->SetMouseCursor(resource, 0, 0); } } +void QmitkMultiLabelSegmentationView::OnPreferencesChanged(const berry::IBerryPreferences* prefs) +{ + if (m_Parent && m_WorkingNode.IsNotNull()) + { + mitk::BoolProperty::Pointer drawOutline = mitk::BoolProperty::New(prefs->GetBool("draw outline", true)); + mitk::BoolProperty::Pointer volumeRendering = mitk::BoolProperty::New(prefs->GetBool("volume rendering", false)); + mitk::LabelSetImage* labelSetImage; + mitk::DataNode* segmentation; + + // iterate all segmentations (binary (single label) and LabelSetImages) + mitk::NodePredicateProperty::Pointer isBinaryPredicate = mitk::NodePredicateProperty::New("binary", mitk::BoolProperty::New(true)); + mitk::NodePredicateOr::Pointer allSegmentationsPredicate = mitk::NodePredicateOr::New(isBinaryPredicate, m_SegmentationPredicate); + mitk::DataStorage::SetOfObjects::ConstPointer allSegmentations = GetDataStorage()->GetSubset(allSegmentationsPredicate); + + for (mitk::DataStorage::SetOfObjects::const_iterator it = allSegmentations->begin(); it != allSegmentations->end(); ++it) + { + segmentation = *it; + labelSetImage = dynamic_cast(segmentation->GetData()); + if (nullptr != labelSetImage) + { + // segmentation node is a multi label segmentation + segmentation->SetProperty("labelset.contour.active", drawOutline); + segmentation->SetProperty("opacity", mitk::FloatProperty::New(drawOutline->GetValue() ? 1.0f : 0.3f)); + segmentation->SetProperty("volumerendering", volumeRendering); + // force render window update to show outline + segmentation->GetData()->Modified(); + } + else + { + // node is actually a 'single label' segmentation, + // but its outline property can be set in the 'multi label' segmentation preference page as well + bool isBinary = false; + segmentation->GetBoolProperty("binary", isBinary); + if (isBinary) + { + segmentation->SetProperty("outline binary", drawOutline); + segmentation->SetProperty("outline width", mitk::FloatProperty::New(2.0)); + segmentation->SetProperty("opacity", mitk::FloatProperty::New(drawOutline->GetValue() ? 1.0f : 0.3f)); + segmentation->SetProperty("volumerendering", volumeRendering); + // force render window update to show outline + segmentation->GetData()->Modified(); + } + } + } + } +} + void QmitkMultiLabelSegmentationView::ResetMouseCursor() { if ( m_MouseCursorSet ) { mitk::ApplicationCursor::GetInstance()->PopCursor(); m_MouseCursorSet = false; } } void QmitkMultiLabelSegmentationView::SetMouseCursor( const us::ModuleResource resource, int hotspotX, int hotspotY ) { // Remove previously set mouse cursor if ( m_MouseCursorSet ) { mitk::ApplicationCursor::GetInstance()->PopCursor(); } us::ModuleResourceStream cursor(resource, std::ios::binary); mitk::ApplicationCursor::GetInstance()->PushCursor( cursor, hotspotX, hotspotY ); m_MouseCursorSet = true; } void QmitkMultiLabelSegmentationView::OnGoToLabel(const mitk::Point3D& pos) { if (m_IRenderWindowPart) m_IRenderWindowPart->SetSelectedPosition(pos); } void QmitkMultiLabelSegmentationView::OnResetView() { if (m_IRenderWindowPart) m_IRenderWindowPart->ForceImmediateUpdate(); } QString QmitkMultiLabelSegmentationView::GetLastFileOpenPath() { return this->GetPreferences()->Get("LastFileOpenPath", ""); } void QmitkMultiLabelSegmentationView::SetLastFileOpenPath(const QString& path) { this->GetPreferences()->Put("LastFileOpenPath", path); this->GetPreferences()->Flush(); } diff --git a/Plugins/org.mitk.gui.qt.multilabelsegmentation/src/internal/QmitkMultiLabelSegmentationView.h b/Plugins/org.mitk.gui.qt.multilabelsegmentation/src/internal/QmitkMultiLabelSegmentationView.h index c128117418..a5d124d8af 100644 --- a/Plugins/org.mitk.gui.qt.multilabelsegmentation/src/internal/QmitkMultiLabelSegmentationView.h +++ b/Plugins/org.mitk.gui.qt.multilabelsegmentation/src/internal/QmitkMultiLabelSegmentationView.h @@ -1,168 +1,173 @@ /*=================================================================== The Medical Imaging Interaction Toolkit (MITK) Copyright (c) German Cancer Research Center, Division of Medical and Biological Informatics. All rights reserved. This software is distributed WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See LICENSE.txt or http://www.mitk.org for details. ===================================================================*/ #ifndef QmitkMultiLabelSegmentationView_h #define QmitkMultiLabelSegmentationView_h #include #include #include "mitkSegmentationInteractor.h" #include "ui_QmitkMultiLabelSegmentationControls.h" +// berry +#include class QmitkRenderWindow; /** * \ingroup ToolManagerEtAl * \ingroup org_mitk_gui_qt_multilabelsegmentation_internal */ class QmitkMultiLabelSegmentationView : public QmitkAbstractView, public mitk::ILifecycleAwarePart { Q_OBJECT public: static const std::string VIEW_ID; QmitkMultiLabelSegmentationView(); virtual ~QmitkMultiLabelSegmentationView(); typedef std::map NodeTagMapType; // GUI setup void CreateQtPartControl(QWidget* parent); // ILifecycleAwarePart interface public: void Activated(); void Deactivated(); void Visible(); void Hidden(); virtual int GetSizeFlags(bool width); virtual int ComputePreferredSize(bool width, int /*availableParallel*/, int /*availablePerpendicular*/, int preferredResult); protected slots: /// \brief reaction to the selection of a new patient (reference) image in the DataStorage combobox void OnReferenceSelectionChanged(const mitk::DataNode* node); /// \brief reaction to the selection of a new Segmentation (working) image in the DataStorage combobox void OnSegmentationSelectionChanged(const mitk::DataNode *node); /// \brief reaction to ... void OnInterpolationSelectionChanged(int); /// \brief reaction to the selection of any 2D segmentation tool void OnManualTool2DSelected(int id); /// \brief reaction to button "New Label" void OnNewLabel(); /// \brief reaction to button "Show Label Table" void OnShowLabelTable(bool value); /// \brief reaction to button "New Segmentation Session" void OnNewSegmentationSession(); /// \brief reaction to signal "goToLabel" from labelset widget void OnGoToLabel(const mitk::Point3D& pos); void OnResetView(); // reaction to the button "Add Layer" void OnAddLayer(); // reaction to the button "Delete Layer" void OnDeleteLayer(); // reaction to the button "Previous Layer" void OnPreviousLayer(); // reaction to the button "Next Layer" void OnNextLayer(); // reaction to the combobox change "Change Layer" void OnChangeLayer(int); // reaction to the button "Deactive Active Tool" void OnDeactivateActiveTool(); // reaction to the button "Lock exterior" void OnLockExteriorToggled(bool); protected: + // invoked when the preferences were changed + void OnPreferencesChanged(const berry::IBerryPreferences* prefs) override; + void OnEstablishLabelSetConnection(); void OnLooseLabelSetConnection(); void SetFocus(); void UpdateControls(); void RenderWindowPartActivated(mitk::IRenderWindowPart *renderWindowPart); void RenderWindowPartDeactivated(mitk::IRenderWindowPart *renderWindowPart); void ResetMouseCursor(); void SetMouseCursor(const us::ModuleResource, int hotspotX, int hotspotY ); void InitializeListeners(); /// \brief Checks if two images have the same size and geometry bool CheckForSameGeometry(const mitk::Image *image1, const mitk::Image *image2) const; /// \brief Reimplemented from QmitkAbstractView virtual void NodeAdded(const mitk::DataNode* node); /// \brief Reimplemented from QmitkAbstractView virtual void NodeRemoved(const mitk::DataNode* node); QString GetLastFileOpenPath(); void SetLastFileOpenPath(const QString& path); /// \brief the Qt parent of our GUI (NOT of this object) QWidget* m_Parent; /// \brief Qt GUI file Ui::QmitkMultiLabelSegmentationControls m_Controls; mitk::IRenderWindowPart* m_IRenderWindowPart; mitk::ToolManager* m_ToolManager; mitk::DataNode::Pointer m_ReferenceNode; mitk::DataNode::Pointer m_WorkingNode; mitk::NodePredicateAnd::Pointer m_ReferencePredicate; mitk::NodePredicateAnd::Pointer m_SegmentationPredicate; bool m_MouseCursorSet; mitk::SegmentationInteractor::Pointer m_Interactor; /** * Reference to the service registration of the observer, * it is needed to unregister the observer on unload. */ us::ServiceRegistration m_ServiceRegistration; }; #endif // QmitkMultiLabelSegmentationView_h diff --git a/Plugins/org.mitk.gui.qt.segmentation/src/internal/QmitkSegmentationView.cpp b/Plugins/org.mitk.gui.qt.segmentation/src/internal/QmitkSegmentationView.cpp index b32304c3b0..f9b18c6cb4 100644 --- a/Plugins/org.mitk.gui.qt.segmentation/src/internal/QmitkSegmentationView.cpp +++ b/Plugins/org.mitk.gui.qt.segmentation/src/internal/QmitkSegmentationView.cpp @@ -1,1269 +1,1295 @@ /*=================================================================== The Medical Imaging Interaction Toolkit (MITK) Copyright (c) German Cancer Research Center, Division of Medical and Biological Informatics. All rights reserved. This software is distributed WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See LICENSE.txt or http://www.mitk.org for details. ===================================================================*/ #include #include "mitkProperties.h" #include "mitkSegTool2D.h" #include "mitkStatusBar.h" #include "QmitkStdMultiWidget.h" #include "QmitkNewSegmentationDialog.h" #include #include #include #include "QmitkSegmentationView.h" #include #include "mitkVtkResliceInterpolationProperty.h" #include "mitkApplicationCursor.h" #include "mitkSegmentationObjectFactory.h" #include "mitkPluginActivator.h" #include "mitkCameraController.h" #include "mitkLabelSetImage.h" #include "usModuleResource.h" #include "usModuleResourceStream.h" //micro service to get the ToolManager instance #include "mitkToolManagerProvider.h" const std::string QmitkSegmentationView::VIEW_ID = "org.mitk.views.segmentation"; // public methods QmitkSegmentationView::QmitkSegmentationView() :m_MouseCursorSet(false) ,m_Parent(NULL) ,m_Controls(NULL) ,m_MultiWidget(NULL) ,m_DataSelectionChanged(false) { mitk::NodePredicateDataType::Pointer isDwi = mitk::NodePredicateDataType::New("DiffusionImage"); mitk::NodePredicateDataType::Pointer isDti = mitk::NodePredicateDataType::New("TensorImage"); mitk::NodePredicateDataType::Pointer isQbi = mitk::NodePredicateDataType::New("QBallImage"); mitk::NodePredicateOr::Pointer isDiffusionImage = mitk::NodePredicateOr::New(isDwi, isDti); isDiffusionImage = mitk::NodePredicateOr::New(isDiffusionImage, isQbi); m_IsOfTypeImagePredicate = mitk::NodePredicateOr::New(isDiffusionImage, mitk::TNodePredicateDataType::New()); m_IsBinaryPredicate = mitk::NodePredicateProperty::New("binary", mitk::BoolProperty::New(true)); m_IsNotBinaryPredicate = mitk::NodePredicateNot::New( m_IsBinaryPredicate ); m_IsNotABinaryImagePredicate = mitk::NodePredicateAnd::New( m_IsOfTypeImagePredicate, m_IsNotBinaryPredicate ); m_IsABinaryImagePredicate = mitk::NodePredicateAnd::New( m_IsOfTypeImagePredicate, m_IsBinaryPredicate); m_IsASegmentationImagePredicate = mitk::NodePredicateOr::New(m_IsABinaryImagePredicate, mitk::TNodePredicateDataType::New()); m_IsAPatientImagePredicate = mitk::NodePredicateAnd::New(m_IsNotABinaryImagePredicate, mitk::NodePredicateNot::New(mitk::TNodePredicateDataType::New())); } QmitkSegmentationView::~QmitkSegmentationView() { delete m_Controls; } void QmitkSegmentationView::NewNodesGenerated() { MITK_WARN<<"Use of deprecated function: NewNodesGenerated!! This function is empty and will be removed in the next time!"; } void QmitkSegmentationView::NewNodeObjectsGenerated(mitk::ToolManager::DataVectorType* nodes) { if (!nodes) return; mitk::ToolManager* toolManager = mitk::ToolManagerProvider::GetInstance()->GetToolManager(); if (!toolManager) return; for (mitk::ToolManager::DataVectorType::iterator iter = nodes->begin(); iter != nodes->end(); ++iter) { this->FireNodeSelected( *iter ); // only last iteration meaningful, multiple generated objects are not taken into account here } } void QmitkSegmentationView::Visible() { if (m_DataSelectionChanged) { this->OnSelectionChanged(this->GetDataManagerSelection()); } } void QmitkSegmentationView::Activated() { // should be moved to ::BecomesVisible() or similar if( m_Controls ) { m_Controls->m_ManualToolSelectionBox2D->setEnabled( true ); m_Controls->m_ManualToolSelectionBox3D->setEnabled( true ); // m_Controls->m_OrganToolSelectionBox->setEnabled( true ); // m_Controls->m_LesionToolSelectionBox->setEnabled( true ); // m_Controls->m_SlicesInterpolator->Enable3DInterpolation( m_Controls->widgetStack->currentWidget() == m_Controls->pageManual ); mitk::DataStorage::SetOfObjects::ConstPointer segmentations = this->GetDefaultDataStorage()->GetSubset( m_IsABinaryImagePredicate ); mitk::DataStorage::SetOfObjects::ConstPointer image = this->GetDefaultDataStorage()->GetSubset(m_IsAPatientImagePredicate); if (!image->empty()) { OnSelectionChanged(*image->begin()); } for ( mitk::DataStorage::SetOfObjects::const_iterator iter = segmentations->begin(); iter != segmentations->end(); ++iter) { mitk::DataNode* node = *iter; itk::SimpleMemberCommand::Pointer command = itk::SimpleMemberCommand::New(); command->SetCallbackFunction(this, &QmitkSegmentationView::OnWorkingNodeVisibilityChanged); m_WorkingDataObserverTags.insert( std::pair( node, node->GetProperty("visible")->AddObserver( itk::ModifiedEvent(), command ) ) ); itk::SimpleMemberCommand::Pointer command2 = itk::SimpleMemberCommand::New(); command2->SetCallbackFunction(this, &QmitkSegmentationView::OnBinaryPropertyChanged); m_BinaryPropertyObserverTags.insert( std::pair( node, node->GetProperty("binary")->AddObserver( itk::ModifiedEvent(), command2 ) ) ); } } itk::SimpleMemberCommand::Pointer command3 = itk::SimpleMemberCommand::New(); command3->SetCallbackFunction( this, &QmitkSegmentationView::RenderingManagerReinitialized ); m_RenderingManagerObserverTag = mitk::RenderingManager::GetInstance()->AddObserver( mitk::RenderingManagerViewsInitializedEvent(), command3 ); this->SetToolManagerSelection(m_Controls->patImageSelector->GetSelectedNode(), m_Controls->segImageSelector->GetSelectedNode()); } void QmitkSegmentationView::Deactivated() { if( m_Controls ) { this->SetToolSelectionBoxesEnabled( false ); //deactivate all tools mitk::ToolManagerProvider::GetInstance()->GetToolManager()->ActivateTool(-1); //Removing all observers for ( NodeTagMapType::iterator dataIter = m_WorkingDataObserverTags.begin(); dataIter != m_WorkingDataObserverTags.end(); ++dataIter ) { (*dataIter).first->GetProperty("visible")->RemoveObserver( (*dataIter).second ); } m_WorkingDataObserverTags.clear(); for ( NodeTagMapType::iterator dataIter = m_BinaryPropertyObserverTags.begin(); dataIter != m_BinaryPropertyObserverTags.end(); ++dataIter ) { (*dataIter).first->GetProperty("binary")->RemoveObserver( (*dataIter).second ); } m_BinaryPropertyObserverTags.clear(); mitk::RenderingManager::GetInstance()->RemoveObserver(m_RenderingManagerObserverTag); ctkPluginContext* context = mitk::PluginActivator::getContext(); ctkServiceReference ppmRef = context->getServiceReference(); mitk::PlanePositionManagerService* service = context->getService(ppmRef); service->RemoveAllPlanePositions(); context->ungetService(ppmRef); this->SetToolManagerSelection(0,0); } } void QmitkSegmentationView::StdMultiWidgetAvailable( QmitkStdMultiWidget& stdMultiWidget ) { SetMultiWidget(&stdMultiWidget); } void QmitkSegmentationView::StdMultiWidgetNotAvailable() { SetMultiWidget(NULL); } void QmitkSegmentationView::StdMultiWidgetClosed( QmitkStdMultiWidget& /*stdMultiWidget*/ ) { SetMultiWidget(NULL); } void QmitkSegmentationView::SetMultiWidget(QmitkStdMultiWidget* multiWidget) { // save the current multiwidget as the working widget m_MultiWidget = multiWidget; if (m_Parent) { m_Parent->setEnabled(m_MultiWidget); } // tell the interpolation about toolmanager and multiwidget (and data storage) if (m_Controls && m_MultiWidget) { mitk::ToolManager* toolManager = mitk::ToolManagerProvider::GetInstance()->GetToolManager(); m_Controls->m_SlicesInterpolator->SetDataStorage( this->GetDefaultDataStorage()); QList controllers; controllers.push_back(m_MultiWidget->GetRenderWindow1()->GetSliceNavigationController()); controllers.push_back(m_MultiWidget->GetRenderWindow2()->GetSliceNavigationController()); controllers.push_back(m_MultiWidget->GetRenderWindow3()->GetSliceNavigationController()); m_Controls->m_SlicesInterpolator->Initialize( toolManager, controllers ); } } void QmitkSegmentationView::OnPreferencesChanged(const berry::IBerryPreferences* prefs) { if (m_Controls != NULL) { bool slimView = prefs->GetBool("slim view", false); m_Controls->m_ManualToolSelectionBox2D->SetShowNames(!slimView); m_Controls->m_ManualToolSelectionBox3D->SetShowNames(!slimView); } m_AutoSelectionEnabled = prefs->GetBool("auto selection", false); this->ForceDisplayPreferencesUponAllImages(); } void QmitkSegmentationView::CreateNewSegmentation() { mitk::DataNode::Pointer node = mitk::ToolManagerProvider::GetInstance()->GetToolManager()->GetReferenceData(0); if (node.IsNotNull()) { mitk::Image::Pointer image = dynamic_cast( node->GetData() ); if (image.IsNotNull()) { if (image->GetDimension()>1) { // ask about the name and organ type of the new segmentation QmitkNewSegmentationDialog* dialog = new QmitkNewSegmentationDialog( m_Parent ); // needs a QWidget as parent, "this" is not QWidget QString storedList = this->GetPreferences()->Get("Organ-Color-List",""); QStringList organColors; if (storedList.isEmpty()) { organColors = mitk::OrganNamesHandling::GetDefaultOrganColorString(); } else { /* a couple of examples of how organ names are stored: a simple item is built up like 'name#AABBCC' where #AABBCC is the hexadecimal notation of a color as known from HTML items are stored separated by ';' this makes it necessary to escape occurrences of ';' in name. otherwise the string "hugo;ypsilon#AABBCC;eugen#AABBCC" could not be parsed as two organs but we would get "hugo" and "ypsilon#AABBCC" and "eugen#AABBCC" so the organ name "hugo;ypsilon" is stored as "hugo\;ypsilon" and must be unescaped after loading the following lines could be one split with Perl's negative lookbehind */ // recover string list from BlueBerry view's preferences QString storedString = this->GetPreferences()->Get("Organ-Color-List",""); MITK_DEBUG << "storedString: " << storedString.toStdString(); // match a string consisting of any number of repetitions of either "anything but ;" or "\;". This matches everything until the next unescaped ';' QRegExp onePart("(?:[^;]|\\\\;)*"); MITK_DEBUG << "matching " << onePart.pattern().toStdString(); int count = 0; int pos = 0; while( (pos = onePart.indexIn( storedString, pos )) != -1 ) { ++count; int length = onePart.matchedLength(); if (length == 0) break; QString matchedString = storedString.mid(pos, length); MITK_DEBUG << " Captured length " << length << ": " << matchedString.toStdString(); pos += length + 1; // skip separating ';' // unescape possible occurrences of '\;' in the string matchedString.replace("\\;", ";"); // add matched string part to output list organColors << matchedString; } MITK_DEBUG << "Captured " << count << " organ name/colors"; } dialog->SetSuggestionList( organColors ); int dialogReturnValue = dialog->exec(); if ( dialogReturnValue == QDialog::Rejected ) return; // user clicked cancel or pressed Esc or something similar // ask the user about an organ type and name, add this information to the image's (!) propertylist // create a new image of the same dimensions and smallest possible pixel type mitk::ToolManager* toolManager = mitk::ToolManagerProvider::GetInstance()->GetToolManager(); mitk::Tool* firstTool = toolManager->GetToolById(0); if (firstTool) { try { std::string newNodeName = dialog->GetSegmentationName().toStdString(); if(newNodeName.empty()) newNodeName = "no_name"; mitk::DataNode::Pointer emptySegmentation = firstTool->CreateEmptySegmentationNode( image, newNodeName, dialog->GetColor() ); // initialize showVolume to false to prevent recalculating the volume while working on the segmentation emptySegmentation->SetProperty( "showVolume", mitk::BoolProperty::New( false ) ); if (!emptySegmentation) return; // could be aborted by user mitk::OrganNamesHandling::UpdateOrganList(organColors, dialog->GetSegmentationName(), dialog->GetColor()); /* escape ';' here (replace by '\;'), see longer comment above */ QString stringForStorage = organColors.replaceInStrings(";","\\;").join(";"); MITK_DEBUG << "Will store: " << stringForStorage; this->GetPreferences()->Put("Organ-Color-List", stringForStorage); this->GetPreferences()->Flush(); if(mitk::ToolManagerProvider::GetInstance()->GetToolManager()->GetWorkingData(0)) { mitk::ToolManagerProvider::GetInstance()->GetToolManager()->GetWorkingData(0)->SetSelected(false); } emptySegmentation->SetSelected(true); this->GetDefaultDataStorage()->Add( emptySegmentation, node ); // add as a child, because the segmentation "derives" from the original this->ApplyDisplayOptions( emptySegmentation ); this->FireNodeSelected( emptySegmentation ); this->OnSelectionChanged( emptySegmentation ); m_Controls->segImageSelector->SetSelectedNode(emptySegmentation); mitk::RenderingManager::GetInstance()->InitializeViews(emptySegmentation->GetData()->GetTimeGeometry(), mitk::RenderingManager::REQUEST_UPDATE_ALL, true ); } catch (std::bad_alloc) { QMessageBox::warning(NULL,tr("Create new segmentation"),tr("Could not allocate memory for new segmentation")); } } } else { QMessageBox::information(NULL,tr("Segmentation"),tr("Segmentation is currently not supported for 2D images")); } } } else { MITK_ERROR << "'Create new segmentation' button should never be clickable unless a patient image is selected..."; } } void QmitkSegmentationView::OnWorkingNodeVisibilityChanged() { mitk::DataNode* selectedNode = m_Controls->segImageSelector->GetSelectedNode(); if ( !selectedNode ) { this->SetToolSelectionBoxesEnabled(false); return; } bool selectedNodeIsVisible = selectedNode->IsVisible(mitk::BaseRenderer::GetInstance( mitk::BaseRenderer::GetRenderWindowByName("stdmulti.widget1"))); if (!selectedNodeIsVisible) { this->SetToolSelectionBoxesEnabled(false); this->UpdateWarningLabel(tr("The selected segmentation is currently not visible!")); } else { this->SetToolSelectionBoxesEnabled(true); this->UpdateWarningLabel(""); } } void QmitkSegmentationView::OnBinaryPropertyChanged() { mitk::DataStorage::SetOfObjects::ConstPointer patImages = m_Controls->patImageSelector->GetNodes(); bool isBinary(false); for (mitk::DataStorage::SetOfObjects::ConstIterator it = patImages->Begin(); it != patImages->End(); ++it) { const mitk::DataNode* node = it->Value(); node->GetBoolProperty("binary", isBinary); mitk::LabelSetImage::Pointer labelSetImage = dynamic_cast(node->GetData()); isBinary = isBinary || labelSetImage.IsNotNull(); if(isBinary) { m_Controls->patImageSelector->RemoveNode(node); m_Controls->segImageSelector->AddNode(node); this->SetToolManagerSelection(NULL,NULL); return; } } mitk::DataStorage::SetOfObjects::ConstPointer segImages = m_Controls->segImageSelector->GetNodes(); isBinary = true; for (mitk::DataStorage::SetOfObjects::ConstIterator it = segImages->Begin(); it != segImages->End(); ++it) { const mitk::DataNode* node = it->Value(); node->GetBoolProperty("binary", isBinary); mitk::LabelSetImage::Pointer labelSetImage = dynamic_cast(node->GetData()); isBinary = isBinary || labelSetImage.IsNotNull(); if(!isBinary) { m_Controls->segImageSelector->RemoveNode(node); m_Controls->patImageSelector->AddNode(node); if (mitk::ToolManagerProvider::GetInstance()->GetToolManager()->GetWorkingData(0) == node) mitk::ToolManagerProvider::GetInstance()->GetToolManager()->SetWorkingData(NULL); return; } } } void QmitkSegmentationView::NodeAdded(const mitk::DataNode *node) { bool isBinary (false); bool isHelperObject (false); bool isImage (false); node->GetBoolProperty("binary", isBinary); mitk::LabelSetImage::Pointer labelSetImage = dynamic_cast(node->GetData()); isBinary = isBinary || labelSetImage.IsNotNull(); node->GetBoolProperty("helper object", isHelperObject); if( dynamic_cast(node->GetData()) ) { isImage = true; } if (m_AutoSelectionEnabled) { if (!isBinary && isImage) { FireNodeSelected(const_cast(node)); } } if (isImage && !isHelperObject) { itk::SimpleMemberCommand::Pointer command = itk::SimpleMemberCommand::New(); command->SetCallbackFunction(this, &QmitkSegmentationView::OnWorkingNodeVisibilityChanged); m_WorkingDataObserverTags.insert( std::pair( const_cast(node), node->GetProperty("visible")->AddObserver( itk::ModifiedEvent(), command ) ) ); itk::SimpleMemberCommand::Pointer command2 = itk::SimpleMemberCommand::New(); command2->SetCallbackFunction(this, &QmitkSegmentationView::OnBinaryPropertyChanged); m_BinaryPropertyObserverTags.insert( std::pair( const_cast(node), node->GetProperty("binary")->AddObserver( itk::ModifiedEvent(), command2 ) ) ); this->ApplyDisplayOptions( const_cast(node) ); m_Controls->segImageSelector->setCurrentIndex( m_Controls->segImageSelector->Find(node) ); } } void QmitkSegmentationView::NodeRemoved(const mitk::DataNode* node) { bool isSeg(false); bool isHelperObject(false); node->GetBoolProperty("helper object", isHelperObject); node->GetBoolProperty("binary", isSeg); mitk::LabelSetImage::Pointer labelSetImage = dynamic_cast(node->GetData()); isSeg = isSeg || labelSetImage.IsNotNull(); mitk::Image* image = dynamic_cast(node->GetData()); if(isSeg && !isHelperObject && image) { //First of all remove all possible contour markers of the segmentation mitk::DataStorage::SetOfObjects::ConstPointer allContourMarkers = this->GetDataStorage()->GetDerivations(node, mitk::NodePredicateProperty::New("isContourMarker" , mitk::BoolProperty::New(true))); ctkPluginContext* context = mitk::PluginActivator::getContext(); ctkServiceReference ppmRef = context->getServiceReference(); mitk::PlanePositionManagerService* service = context->getService(ppmRef); for (mitk::DataStorage::SetOfObjects::ConstIterator it = allContourMarkers->Begin(); it != allContourMarkers->End(); ++it) { std::string nodeName = node->GetName(); unsigned int t = nodeName.find_last_of(" "); unsigned int id = atof(nodeName.substr(t+1).c_str())-1; service->RemovePlanePosition(id); this->GetDataStorage()->Remove(it->Value()); } context->ungetService(ppmRef); service = NULL; if ((mitk::ToolManagerProvider::GetInstance()->GetToolManager()->GetWorkingData(0) == node) && m_Controls->patImageSelector->GetSelectedNode().IsNotNull()) { this->SetToolManagerSelection(mitk::ToolManagerProvider::GetInstance()->GetToolManager()->GetReferenceData(0), NULL); this->UpdateWarningLabel(tr("Select or create a segmentation")); } mitk::SurfaceInterpolationController::GetInstance()->RemoveInterpolationSession(image); } mitk::DataNode* tempNode = const_cast(node); //Since the binary property could be changed during runtime by the user if (image && !isHelperObject) { node->GetProperty("visible")->RemoveObserver( m_WorkingDataObserverTags[tempNode] ); m_WorkingDataObserverTags.erase(tempNode); node->GetProperty("binary")->RemoveObserver( m_BinaryPropertyObserverTags[tempNode] ); m_BinaryPropertyObserverTags.erase(tempNode); } if((mitk::ToolManagerProvider::GetInstance()->GetToolManager()->GetReferenceData(0) == node)) { //as we don't know which node was actually removed e.g. our reference node, disable 'New Segmentation' button. //consider the case that there is no more image in the datastorage this->SetToolManagerSelection(NULL, NULL); this->SetToolSelectionBoxesEnabled( false ); } } //void QmitkSegmentationView::CreateSegmentationFromSurface() //{ // mitk::DataNode::Pointer surfaceNode = // m_Controls->MaskSurfaces->GetSelectedNode(); // mitk::Surface::Pointer surface(0); // if(surfaceNode.IsNotNull()) // surface = dynamic_cast ( surfaceNode->GetData() ); // if(surface.IsNull()) // { // this->HandleException( "No surface selected.", m_Parent, true); // return; // } // mitk::DataNode::Pointer imageNode // = mitk::ToolManagerProvider::GetInstance()->GetToolManager()->GetReferenceData(0); // mitk::Image::Pointer image(0); // if (imageNode.IsNotNull()) // image = dynamic_cast( imageNode->GetData() ); // if(image.IsNull()) // { // this->HandleException( "No image selected.", m_Parent, true); // return; // } // mitk::SurfaceToImageFilter::Pointer s2iFilter // = mitk::SurfaceToImageFilter::New(); // s2iFilter->MakeOutputBinaryOn(); // s2iFilter->SetInput(surface); // s2iFilter->SetImage(image); // s2iFilter->Update(); // mitk::DataNode::Pointer resultNode = mitk::DataNode::New(); // std::string nameOfResultImage = imageNode->GetName(); // nameOfResultImage.append(surfaceNode->GetName()); // resultNode->SetProperty("name", mitk::StringProperty::New(nameOfResultImage) ); // resultNode->SetProperty("binary", mitk::BoolProperty::New(true) ); // resultNode->SetData( s2iFilter->GetOutput() ); // this->GetDataStorage()->Add(resultNode, imageNode); //} //void QmitkSegmentationView::ToolboxStackPageChanged(int id) //{ // // interpolation only with manual tools visible // m_Controls->m_SlicesInterpolator->EnableInterpolation( id == 0 ); // if( id == 0 ) // { // mitk::DataNode::Pointer workingData = mitk::ToolManagerProvider::GetInstance()->GetToolManager()->GetWorkingData(0); // if( workingData.IsNotNull() ) // { // m_Controls->segImageSelector->setCurrentIndex( m_Controls->segImageSelector->Find(workingData) ); // } // } // // this is just a workaround, should be removed when all tools support 3D+t // if (id==2) // lesions // { // mitk::DataNode::Pointer node = mitk::ToolManagerProvider::GetInstance()->GetToolManager()->GetReferenceData(0); // if (node.IsNotNull()) // { // mitk::Image::Pointer image = dynamic_cast( node->GetData() ); // if (image.IsNotNull()) // { // if (image->GetDimension()>3) // { // m_Controls->widgetStack->setCurrentIndex(0); // QMessageBox::information(NULL,"Segmentation","Lesion segmentation is currently not supported for 4D images"); // } // } // } // } //} // protected void QmitkSegmentationView::OnPatientComboBoxSelectionChanged( const mitk::DataNode* node ) { //mitk::DataNode* selectedNode = const_cast(node); if( node != NULL ) { this->UpdateWarningLabel(""); mitk::DataNode* segNode = m_Controls->segImageSelector->GetSelectedNode(); if (segNode) { mitk::DataStorage::SetOfObjects::ConstPointer possibleParents = this->GetDefaultDataStorage()->GetSources(segNode, m_IsAPatientImagePredicate); bool isSourceNode(false); for (mitk::DataStorage::SetOfObjects::ConstIterator it = possibleParents->Begin(); it != possibleParents->End(); it++) { if (it.Value() == node) isSourceNode = true; } if ( !isSourceNode && (!this->CheckForSameGeometry(segNode, node) || possibleParents->Size() > 0 )) { this->SetToolManagerSelection(node, NULL); this->SetToolSelectionBoxesEnabled( false ); this->UpdateWarningLabel(tr("The selected patient image does not match with the selected segmentation!")); } else if ((!isSourceNode && this->CheckForSameGeometry(segNode, node)) || isSourceNode ) { this->SetToolManagerSelection(node, segNode); //Doing this we can assure that the segmenation is always visible if the segmentation and the patient image are //loaded separately int layer(10); node->GetIntProperty("layer", layer); layer++; segNode->SetProperty("layer", mitk::IntProperty::New(layer)); //this->UpdateWarningLabel(""); RenderingManagerReinitialized(); } } else { this->SetToolManagerSelection(node, NULL); this->SetToolSelectionBoxesEnabled( false ); this->UpdateWarningLabel(tr("Select or create a segmentation")); } } else { this->UpdateWarningLabel(tr("Please load an image!")); this->SetToolSelectionBoxesEnabled( false ); } } void QmitkSegmentationView::OnSegmentationComboBoxSelectionChanged(const mitk::DataNode *node) { if (node == NULL) { this->UpdateWarningLabel(tr("Select or create a segmentation")); this->SetToolSelectionBoxesEnabled( false ); return; } mitk::DataNode* refNode = m_Controls->patImageSelector->GetSelectedNode(); RenderingManagerReinitialized(); if ( m_Controls->lblSegmentationWarnings->isVisible()) // "RenderingManagerReinitialized()" caused a warning. we do not need to go any further return; if (m_AutoSelectionEnabled) { this->OnSelectionChanged(const_cast(node)); } else { mitk::DataStorage::SetOfObjects::ConstPointer possibleParents = this->GetDefaultDataStorage()->GetSources(node, m_IsAPatientImagePredicate); if ( possibleParents->Size() == 1 ) { mitk::DataNode* parentNode = possibleParents->ElementAt(0); if (parentNode != refNode) { this->UpdateWarningLabel(tr("The selected segmentation does not match with the selected patient image!")); this->SetToolSelectionBoxesEnabled( false ); this->SetToolManagerSelection(NULL, node); } else { this->UpdateWarningLabel(""); this->SetToolManagerSelection(refNode, node); } } else if (refNode && this->CheckForSameGeometry(node, refNode)) { this->UpdateWarningLabel(""); this->SetToolManagerSelection(refNode, node); } else if (!refNode || !this->CheckForSameGeometry(node, refNode)) { this->UpdateWarningLabel(tr("Please select or load the according patient image!")); } } if (!node->IsVisible(mitk::BaseRenderer::GetInstance( mitk::BaseRenderer::GetRenderWindowByName("stdmulti.widget1")))) { this->UpdateWarningLabel(tr("The selected segmentation is currently not visible!")); this->SetToolSelectionBoxesEnabled( false ); } } void QmitkSegmentationView::OnShowMarkerNodes (bool state) { mitk::SegTool2D::Pointer manualSegmentationTool; unsigned int numberOfExistingTools = mitk::ToolManagerProvider::GetInstance()->GetToolManager()->GetTools().size(); for(unsigned int i = 0; i < numberOfExistingTools; i++) { manualSegmentationTool = dynamic_cast(mitk::ToolManagerProvider::GetInstance()->GetToolManager()->GetToolById(i)); if (manualSegmentationTool) { if(state == true) { manualSegmentationTool->SetShowMarkerNodes( true ); } else { manualSegmentationTool->SetShowMarkerNodes( false ); } } } } void QmitkSegmentationView::OnSelectionChanged(mitk::DataNode* node) { std::vector nodes; nodes.push_back( node ); this->OnSelectionChanged( nodes ); } void QmitkSegmentationView::OnSelectionChanged(std::vector nodes) { if (nodes.size() != 0) { std::string markerName = "Position"; unsigned int numberOfNodes = nodes.size(); std::string nodeName = nodes.at( 0 )->GetName(); if ( ( numberOfNodes == 1 ) && ( nodeName.find( markerName ) == 0) ) { this->OnContourMarkerSelected( nodes.at( 0 ) ); return; } } if (m_AutoSelectionEnabled && this->IsActivated()) { if (nodes.size() == 0 && m_Controls->patImageSelector->GetSelectedNode().IsNull()) { SetToolManagerSelection(NULL,NULL); } else if (nodes.size() == 1) { mitk::DataNode::Pointer selectedNode = nodes.at(0); if(selectedNode.IsNull()) { return; } mitk::Image::Pointer selectedImage = dynamic_cast(selectedNode->GetData()); if (selectedImage.IsNull()) { SetToolManagerSelection(NULL,NULL); return; } else { bool isASegmentation(false); selectedNode->GetBoolProperty("binary", isASegmentation); mitk::LabelSetImage::Pointer labelSetImage = dynamic_cast(selectedNode->GetData()); isASegmentation = isASegmentation || labelSetImage.IsNotNull(); if (isASegmentation) { //If a segmentation is selected find a possible reference image: mitk::DataStorage::SetOfObjects::ConstPointer sources = this->GetDataStorage()->GetSources(selectedNode, m_IsAPatientImagePredicate); mitk::DataNode::Pointer refNode; if (sources->Size() != 0) { refNode = sources->ElementAt(0); refNode->SetVisibility(true); selectedNode->SetVisibility(true); SetToolManagerSelection(refNode,selectedNode); mitk::DataStorage::SetOfObjects::ConstPointer otherSegmentations = this->GetDataStorage()->GetSubset(m_IsASegmentationImagePredicate); for(mitk::DataStorage::SetOfObjects::const_iterator iter = otherSegmentations->begin(); iter != otherSegmentations->end(); ++iter) { mitk::DataNode* node = *iter; if (dynamic_cast(node->GetData()) != selectedImage.GetPointer()) node->SetVisibility(false); } mitk::DataStorage::SetOfObjects::ConstPointer otherPatientImages = this->GetDataStorage()->GetSubset(m_IsAPatientImagePredicate); for(mitk::DataStorage::SetOfObjects::const_iterator iter = otherPatientImages->begin(); iter != otherPatientImages->end(); ++iter) { mitk::DataNode* node = *iter; if (dynamic_cast(node->GetData()) != dynamic_cast(refNode->GetData())) node->SetVisibility(false); } } else { mitk::DataStorage::SetOfObjects::ConstPointer possiblePatientImages = this->GetDataStorage()->GetSubset(m_IsAPatientImagePredicate); for (mitk::DataStorage::SetOfObjects::ConstIterator it = possiblePatientImages->Begin(); it != possiblePatientImages->End(); it++) { refNode = it->Value(); if (this->CheckForSameGeometry(selectedNode, it->Value())) { refNode->SetVisibility(true); selectedNode->SetVisibility(true); mitk::DataStorage::SetOfObjects::ConstPointer otherSegmentations = this->GetDataStorage()->GetSubset(m_IsASegmentationImagePredicate); for(mitk::DataStorage::SetOfObjects::const_iterator iter = otherSegmentations->begin(); iter != otherSegmentations->end(); ++iter) { mitk::DataNode* node = *iter; if (dynamic_cast(node->GetData()) != selectedImage.GetPointer()) node->SetVisibility(false); } mitk::DataStorage::SetOfObjects::ConstPointer otherPatientImages = this->GetDataStorage()->GetSubset(m_IsAPatientImagePredicate); for(mitk::DataStorage::SetOfObjects::const_iterator iter = otherPatientImages->begin(); iter != otherPatientImages->end(); ++iter) { mitk::DataNode* node = *iter; if (dynamic_cast(node->GetData()) != dynamic_cast(refNode->GetData())) node->SetVisibility(false); } this->SetToolManagerSelection(refNode, selectedNode); //Doing this we can assure that the segmenation is always visible if the segmentation and the patient image are at the //same level in the datamanager int layer(10); refNode->GetIntProperty("layer", layer); layer++; selectedNode->SetProperty("layer", mitk::IntProperty::New(layer)); return; } } this->SetToolManagerSelection(NULL, selectedNode); } mitk::RenderingManager::GetInstance()->InitializeViews(selectedNode->GetData()->GetTimeGeometry(), mitk::RenderingManager::REQUEST_UPDATE_ALL, true ); } else { if (mitk::ToolManagerProvider::GetInstance()->GetToolManager()->GetReferenceData(0) != selectedNode) { SetToolManagerSelection(selectedNode, NULL); //May be a bug in the selection services. A node which is deselected will be passed as selected node to the OnSelectionChanged function if (!selectedNode->IsVisible(mitk::BaseRenderer::GetInstance( mitk::BaseRenderer::GetRenderWindowByName("stdmulti.widget1")))) selectedNode->SetVisibility(true); this->UpdateWarningLabel(tr("The selected patient image does not\nmatchwith the selected segmentation!")); this->SetToolSelectionBoxesEnabled( false ); } } } } if ( m_Controls->lblSegmentationWarnings->isVisible()) // "RenderingManagerReinitialized()" caused a warning. we do not need to go any further return; RenderingManagerReinitialized(); } } void QmitkSegmentationView::OnContourMarkerSelected(const mitk::DataNode *node) { QmitkRenderWindow* selectedRenderWindow = 0; QmitkRenderWindow* RenderWindow1 = this->GetActiveStdMultiWidget()->GetRenderWindow1(); QmitkRenderWindow* RenderWindow2 = this->GetActiveStdMultiWidget()->GetRenderWindow2(); QmitkRenderWindow* RenderWindow3 = this->GetActiveStdMultiWidget()->GetRenderWindow3(); QmitkRenderWindow* RenderWindow4 = this->GetActiveStdMultiWidget()->GetRenderWindow4(); bool PlanarFigureInitializedWindow = false; // find initialized renderwindow if (node->GetBoolProperty("PlanarFigureInitializedWindow", PlanarFigureInitializedWindow, RenderWindow1->GetRenderer())) { selectedRenderWindow = RenderWindow1; } if (!selectedRenderWindow && node->GetBoolProperty( "PlanarFigureInitializedWindow", PlanarFigureInitializedWindow, RenderWindow2->GetRenderer())) { selectedRenderWindow = RenderWindow2; } if (!selectedRenderWindow && node->GetBoolProperty( "PlanarFigureInitializedWindow", PlanarFigureInitializedWindow, RenderWindow3->GetRenderer())) { selectedRenderWindow = RenderWindow3; } if (!selectedRenderWindow && node->GetBoolProperty( "PlanarFigureInitializedWindow", PlanarFigureInitializedWindow, RenderWindow4->GetRenderer())) { selectedRenderWindow = RenderWindow4; } // make node visible if (selectedRenderWindow) { std::string nodeName = node->GetName(); unsigned int t = nodeName.find_last_of(" "); unsigned int id = atof(nodeName.substr(t+1).c_str())-1; { ctkPluginContext* context = mitk::PluginActivator::getContext(); ctkServiceReference ppmRef = context->getServiceReference(); mitk::PlanePositionManagerService* service = context->getService(ppmRef); selectedRenderWindow->GetSliceNavigationController()->ExecuteOperation(service->GetPlanePosition(id)); context->ungetService(ppmRef); } selectedRenderWindow->GetRenderer()->GetCameraController()->Fit(); mitk::RenderingManager::GetInstance()->RequestUpdateAll(); } } void QmitkSegmentationView::OnTabWidgetChanged(int id) { //always disable tools on tab changed mitk::ToolManagerProvider::GetInstance()->GetToolManager()->ActivateTool(-1); //2D Tab ID = 0 //3D Tab ID = 1 if (id == 0) { //Hide 3D selection box, show 2D selection box m_Controls->m_ManualToolSelectionBox3D->hide(); m_Controls->m_ManualToolSelectionBox2D->show(); //Deactivate possible active tool //TODO Remove possible visible interpolations -> Maybe changes in SlicesInterpolator } else { //Hide 3D selection box, show 2D selection box m_Controls->m_ManualToolSelectionBox2D->hide(); m_Controls->m_ManualToolSelectionBox3D->show(); //Deactivate possible active tool } } void QmitkSegmentationView::SetToolManagerSelection(const mitk::DataNode* referenceData, const mitk::DataNode* workingData) { // called as a result of new BlueBerry selections // tells the ToolManager for manual segmentation about new selections // updates GUI information about what the user should select mitk::ToolManager* toolManager = mitk::ToolManagerProvider::GetInstance()->GetToolManager(); toolManager->SetReferenceData(const_cast(referenceData)); toolManager->SetWorkingData( const_cast(workingData)); // check original image m_Controls->btnNewSegmentation->setEnabled(referenceData != NULL); if (referenceData) { this->UpdateWarningLabel(""); disconnect( m_Controls->patImageSelector, SIGNAL( OnSelectionChanged( const mitk::DataNode* ) ), this, SLOT( OnPatientComboBoxSelectionChanged( const mitk::DataNode* ) ) ); m_Controls->patImageSelector->setCurrentIndex( m_Controls->patImageSelector->Find(referenceData) ); connect( m_Controls->patImageSelector, SIGNAL( OnSelectionChanged( const mitk::DataNode* ) ), this, SLOT( OnPatientComboBoxSelectionChanged( const mitk::DataNode* ) ) ); } // check segmentation if (referenceData) { if (workingData) { this->FireNodeSelected(const_cast(workingData)); // if( m_Controls->widgetStack->currentIndex() == 0 ) // { disconnect( m_Controls->segImageSelector, SIGNAL( OnSelectionChanged( const mitk::DataNode* ) ), this, SLOT( OnSegmentationComboBoxSelectionChanged( const mitk::DataNode* ) ) ); m_Controls->segImageSelector->setCurrentIndex(m_Controls->segImageSelector->Find(workingData)); connect( m_Controls->segImageSelector, SIGNAL( OnSelectionChanged( const mitk::DataNode* ) ), this, SLOT( OnSegmentationComboBoxSelectionChanged(const mitk::DataNode*)) ); // } } } } void QmitkSegmentationView::ForceDisplayPreferencesUponAllImages() { - if (!m_Parent || !m_Parent->isVisible()) return; + if (!m_Parent) + { + return; + } // check all images and segmentations in DataStorage: // (items in brackets are implicitly done by previous steps) // 1. // if a reference image is selected, // show the reference image // and hide all other images (orignal and segmentation), // (and hide all segmentations of the other original images) // and show all the reference's segmentations // if no reference image is selected, do do nothing // // 2. // if a segmentation is selected, // show it // (and hide all all its siblings (childs of the same parent, incl, NULL parent)) // if no segmentation is selected, do nothing if (!m_Controls) - return; // might happen on initialization (preferences loaded) + { + return; // might happen on initialization (preferences loaded) + } mitk::ToolManager* toolManager = mitk::ToolManagerProvider::GetInstance()->GetToolManager(); mitk::DataNode::Pointer referenceData = toolManager->GetReferenceData(0); mitk::DataNode::Pointer workingData = toolManager->GetWorkingData(0); // 1. if (referenceData.IsNotNull()) { // iterate all images mitk::DataStorage::SetOfObjects::ConstPointer allImages = this->GetDefaultDataStorage()->GetSubset(m_IsASegmentationImagePredicate); for ( mitk::DataStorage::SetOfObjects::const_iterator iter = allImages->begin(); iter != allImages->end(); ++iter) { mitk::DataNode* node = *iter; // apply display preferences ApplyDisplayOptions(node); // set visibility node->SetVisibility(node == referenceData); } } // 2. if (workingData.IsNotNull()) workingData->SetVisibility(true); mitk::RenderingManager::GetInstance()->RequestUpdateAll(); } void QmitkSegmentationView::ApplyDisplayOptions(mitk::DataNode* node) { - if (!node) return; - - bool isBinary(false); - node->GetPropertyValue("binary", isBinary); + if (!node) + { + return; + } - if (isBinary) - { - node->SetProperty( "outline binary", mitk::BoolProperty::New( this->GetPreferences()->GetBool("draw outline", true)) ); - node->SetProperty( "outline width", mitk::FloatProperty::New( 2.0 ) ); - node->SetProperty( "opacity", mitk::FloatProperty::New( this->GetPreferences()->GetBool("draw outline", true) ? 1.0 : 0.3 ) ); - node->SetProperty( "volumerendering", mitk::BoolProperty::New( this->GetPreferences()->GetBool("volume rendering", false) ) ); - } + mitk::BoolProperty::Pointer drawOutline = mitk::BoolProperty::New(GetPreferences()->GetBool("draw outline", true)); + mitk::BoolProperty::Pointer volumeRendering = mitk::BoolProperty::New(GetPreferences()->GetBool("volume rendering", false)); + mitk::LabelSetImage* labelSetImage = dynamic_cast(node->GetData()); + if (nullptr != labelSetImage) + { + // node is actually a multi label segmentation, + // but its outline property can be set in the 'single label' segmentation preference page as well + node->SetProperty("labelset.contour.active", drawOutline); + node->SetProperty("opacity", mitk::FloatProperty::New(drawOutline->GetValue() ? 1.0f : 0.3f)); + node->SetProperty("volumerendering", volumeRendering); + // force render window update to show outline + node->GetData()->Modified(); + } + else + { + // node is a 'single label' segmentation + bool isBinary = false; + node->GetBoolProperty("binary", isBinary); + if (isBinary) + { + node->SetProperty("outline binary", drawOutline); + node->SetProperty("outline width", mitk::FloatProperty::New(2.0)); + node->SetProperty("opacity", mitk::FloatProperty::New(drawOutline->GetValue() ? 1.0f : 0.3f)); + node->SetProperty("volumerendering", volumeRendering); + // force render window update to show outline + node->GetData()->Modified(); + } + } } void QmitkSegmentationView::RenderingManagerReinitialized() { if ( ! m_MultiWidget ) { return; } /* * Here we check whether the geometry of the selected segmentation image if aligned with the worldgeometry * At the moment it is not supported to use a geometry different from the selected image for reslicing. * For further information see Bug 16063 */ mitk::DataNode* workingNode = m_Controls->segImageSelector->GetSelectedNode(); const mitk::BaseGeometry* worldGeo = m_MultiWidget->GetRenderWindow4()->GetSliceNavigationController()->GetCurrentGeometry3D(); if (workingNode && worldGeo) { const mitk::BaseGeometry* workingNodeGeo = workingNode->GetData()->GetGeometry(); const mitk::BaseGeometry* worldGeo = m_MultiWidget->GetRenderWindow4()->GetSliceNavigationController()->GetCurrentGeometry3D(); if (mitk::Equal(*workingNodeGeo->GetBoundingBox(), *worldGeo->GetBoundingBox(), mitk::eps, true)) { this->SetToolManagerSelection(m_Controls->patImageSelector->GetSelectedNode(), workingNode); this->SetToolSelectionBoxesEnabled(true); this->UpdateWarningLabel(""); } else { this->SetToolManagerSelection(m_Controls->patImageSelector->GetSelectedNode(), NULL); this->SetToolSelectionBoxesEnabled(false); this->UpdateWarningLabel(tr("Please perform a reinit on the segmentation image!")); } } } bool QmitkSegmentationView::CheckForSameGeometry(const mitk::DataNode *node1, const mitk::DataNode *node2) const { bool isSameGeometry(true); mitk::Image* image1 = dynamic_cast(node1->GetData()); mitk::Image* image2 = dynamic_cast(node2->GetData()); if (image1 && image2) { mitk::BaseGeometry* geo1 = image1->GetGeometry(); mitk::BaseGeometry* geo2 = image2->GetGeometry(); isSameGeometry = isSameGeometry && mitk::Equal(geo1->GetOrigin(), geo2->GetOrigin()); isSameGeometry = isSameGeometry && mitk::Equal(geo1->GetExtent(0), geo2->GetExtent(0)); isSameGeometry = isSameGeometry && mitk::Equal(geo1->GetExtent(1), geo2->GetExtent(1)); isSameGeometry = isSameGeometry && mitk::Equal(geo1->GetExtent(2), geo2->GetExtent(2)); isSameGeometry = isSameGeometry && mitk::Equal(geo1->GetSpacing(), geo2->GetSpacing()); isSameGeometry = isSameGeometry && mitk::MatrixEqualElementWise(geo1->GetIndexToWorldTransform()->GetMatrix(), geo2->GetIndexToWorldTransform()->GetMatrix()); return isSameGeometry; } else { return false; } } void QmitkSegmentationView::UpdateWarningLabel(QString text) { if (text.size() == 0) m_Controls->lblSegmentationWarnings->hide(); else m_Controls->lblSegmentationWarnings->show(); m_Controls->lblSegmentationWarnings->setText(text); } void QmitkSegmentationView::CreateQtPartControl(QWidget* parent) { // setup the basic GUI of this view m_Parent = parent; m_Controls = new Ui::QmitkSegmentationControls; m_Controls->setupUi(parent); m_Controls->patImageSelector->SetDataStorage(this->GetDefaultDataStorage()); m_Controls->patImageSelector->SetPredicate(mitk::NodePredicateAnd::New(m_IsAPatientImagePredicate, mitk::NodePredicateNot::New(mitk::NodePredicateProperty::New("helper object"))).GetPointer()); this->UpdateWarningLabel(tr("Please load an image")); if( m_Controls->patImageSelector->GetSelectedNode().IsNotNull() ) this->UpdateWarningLabel(tr("Select or create a new segmentation")); m_Controls->segImageSelector->SetDataStorage(this->GetDefaultDataStorage()); m_Controls->segImageSelector->SetPredicate(mitk::NodePredicateAnd::New(m_IsASegmentationImagePredicate, mitk::NodePredicateNot::New(mitk::NodePredicateProperty::New("helper object"))).GetPointer()); if( m_Controls->segImageSelector->GetSelectedNode().IsNotNull() ) this->UpdateWarningLabel(""); mitk::ToolManager* toolManager = mitk::ToolManagerProvider::GetInstance()->GetToolManager(); assert ( toolManager ); toolManager->SetDataStorage( *(this->GetDefaultDataStorage()) ); toolManager->InitializeTools(); // all part of open source MITK m_Controls->m_ManualToolSelectionBox2D->SetGenerateAccelerators(true); m_Controls->m_ManualToolSelectionBox2D->SetToolGUIArea( m_Controls->m_ManualToolGUIContainer2D ); m_Controls->m_ManualToolSelectionBox2D->SetDisplayedToolGroups(tr("Add Subtract Correction Paint Wipe 'Region Growing' Fill Erase 'Live Wire' '2D Fast Marching'").toStdString()); m_Controls->m_ManualToolSelectionBox2D->SetLayoutColumns(3); m_Controls->m_ManualToolSelectionBox2D->SetEnabledMode( QmitkToolSelectionBox::EnabledWithReferenceAndWorkingDataVisible ); connect( m_Controls->m_ManualToolSelectionBox2D, SIGNAL(ToolSelected(int)), this, SLOT(OnManualTool2DSelected(int)) ); //setup 3D Tools m_Controls->m_ManualToolSelectionBox3D->SetGenerateAccelerators(true); m_Controls->m_ManualToolSelectionBox3D->SetToolGUIArea( m_Controls->m_ManualToolGUIContainer3D ); //specify tools to be added to 3D Tool area m_Controls->m_ManualToolSelectionBox3D->SetDisplayedToolGroups(tr("Threshold 'UL Threshold' Otsu 'Fast Marching 3D' 'Region Growing 3D' Watershed Picking").toStdString()); m_Controls->m_ManualToolSelectionBox3D->SetLayoutColumns(3); m_Controls->m_ManualToolSelectionBox3D->SetEnabledMode( QmitkToolSelectionBox::EnabledWithReferenceAndWorkingDataVisible ); //Hide 3D selection box, show 2D selection box m_Controls->m_ManualToolSelectionBox3D->hide(); m_Controls->m_ManualToolSelectionBox2D->show(); toolManager->NewNodesGenerated += mitk::MessageDelegate( this, &QmitkSegmentationView::NewNodesGenerated ); // update the list of segmentations toolManager->NewNodeObjectsGenerated += mitk::MessageDelegate1( this, &QmitkSegmentationView::NewNodeObjectsGenerated ); // update the list of segmentations // create signal/slot connections connect( m_Controls->patImageSelector, SIGNAL( OnSelectionChanged( const mitk::DataNode* ) ), this, SLOT( OnPatientComboBoxSelectionChanged( const mitk::DataNode* ) ) ); connect( m_Controls->segImageSelector, SIGNAL( OnSelectionChanged( const mitk::DataNode* ) ), this, SLOT( OnSegmentationComboBoxSelectionChanged( const mitk::DataNode* ) ) ); connect( m_Controls->btnNewSegmentation, SIGNAL(clicked()), this, SLOT(CreateNewSegmentation()) ); // connect( m_Controls->CreateSegmentationFromSurface, SIGNAL(clicked()), this, SLOT(CreateSegmentationFromSurface()) ); // connect( m_Controls->widgetStack, SIGNAL(currentChanged(int)), this, SLOT(ToolboxStackPageChanged(int)) ); connect( m_Controls->tabWidgetSegmentationTools, SIGNAL(currentChanged(int)), this, SLOT(OnTabWidgetChanged(int))); // connect(m_Controls->MaskSurfaces, SIGNAL( OnSelectionChanged( const mitk::DataNode* ) ), // this, SLOT( OnSurfaceSelectionChanged( ) ) ); connect(m_Controls->m_SlicesInterpolator, SIGNAL(SignalShowMarkerNodes(bool)), this, SLOT(OnShowMarkerNodes(bool))); // m_Controls->MaskSurfaces->SetDataStorage(this->GetDefaultDataStorage()); // m_Controls->MaskSurfaces->SetPredicate(mitk::NodePredicateDataType::New("Surface")); } void QmitkSegmentationView::OnManualTool2DSelected(int id) { if (id >= 0) { std::string text = "Active Tool: \""; mitk::ToolManager* toolManager = mitk::ToolManagerProvider::GetInstance()->GetToolManager(); text += toolManager->GetToolById(id)->GetName(); text += "\""; mitk::StatusBar::GetInstance()->DisplayText(text.c_str()); us::ModuleResource resource = toolManager->GetToolById(id)->GetCursorIconResource(); this->SetMouseCursor(resource, 0, 0); } else { this->ResetMouseCursor(); mitk::StatusBar::GetInstance()->DisplayText(""); } } void QmitkSegmentationView::ResetMouseCursor() { if ( m_MouseCursorSet ) { mitk::ApplicationCursor::GetInstance()->PopCursor(); m_MouseCursorSet = false; } } void QmitkSegmentationView::SetMouseCursor( const us::ModuleResource& resource, int hotspotX, int hotspotY ) { if (!resource) return; // Remove previously set mouse cursor if ( m_MouseCursorSet ) { mitk::ApplicationCursor::GetInstance()->PopCursor(); } us::ModuleResourceStream cursor(resource, std::ios::binary); mitk::ApplicationCursor::GetInstance()->PushCursor( cursor, hotspotX, hotspotY ); m_MouseCursorSet = true; } void QmitkSegmentationView::SetToolSelectionBoxesEnabled(bool status) { if (status) { m_Controls->m_ManualToolSelectionBox2D->RecreateButtons(); m_Controls->m_ManualToolSelectionBox3D->RecreateButtons(); } m_Controls->m_ManualToolSelectionBox2D->setEnabled(status); m_Controls->m_ManualToolSelectionBox3D->setEnabled(status); m_Controls->m_SlicesInterpolator->setEnabled(status); }