diff --git a/Modules/DiffusionImaging/DiffusionCore/IODataStructures/Properties/mitkDiffusionPropertyHelper.cpp b/Modules/DiffusionImaging/DiffusionCore/IODataStructures/Properties/mitkDiffusionPropertyHelper.cpp index 09443b53e8..5580e9e49e 100644 --- a/Modules/DiffusionImaging/DiffusionCore/IODataStructures/Properties/mitkDiffusionPropertyHelper.cpp +++ b/Modules/DiffusionImaging/DiffusionCore/IODataStructures/Properties/mitkDiffusionPropertyHelper.cpp @@ -1,404 +1,409 @@ /*=================================================================== 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 "mitkDiffusionPropertyHelper.h" #include #include #include #include const std::string mitk::DiffusionPropertyHelper::GRADIENTCONTAINERPROPERTYNAME = "meta.GradientDirections"; const std::string mitk::DiffusionPropertyHelper::ORIGINALGRADIENTCONTAINERPROPERTYNAME = "meta.OriginalGradientDirections"; const std::string mitk::DiffusionPropertyHelper::MEASUREMENTFRAMEPROPERTYNAME = "meta.MeasurementFrame"; const std::string mitk::DiffusionPropertyHelper::REFERENCEBVALUEPROPERTYNAME = "meta.ReferenceBValue"; const std::string mitk::DiffusionPropertyHelper::BVALUEMAPPROPERTYNAME = "BValueMap"; mitk::DiffusionPropertyHelper::DiffusionPropertyHelper() { } mitk::DiffusionPropertyHelper::DiffusionPropertyHelper( mitk::Image* inputImage) : m_Image( inputImage ) { // Update props } mitk::DiffusionPropertyHelper::~DiffusionPropertyHelper() { } mitk::DiffusionPropertyHelper::GradientDirectionsContainerType::Pointer mitk::DiffusionPropertyHelper::CalcAveragedDirectionSet(double precision, GradientDirectionsContainerType::Pointer directions) { // save old and construct new direction container GradientDirectionsContainerType::Pointer newDirections = GradientDirectionsContainerType::New(); // fill new direction container for(GradientDirectionsContainerType::ConstIterator gdcitOld = directions->Begin(); gdcitOld != directions->End(); ++gdcitOld) { // already exists? bool found = false; for(GradientDirectionsContainerType::ConstIterator gdcitNew = newDirections->Begin(); gdcitNew != newDirections->End(); ++gdcitNew) { if(AreAlike(gdcitNew.Value(), gdcitOld.Value(), precision)) { found = true; break; } } // if not found, add it to new container if(!found) { newDirections->push_back(gdcitOld.Value()); } } return newDirections; } void mitk::DiffusionPropertyHelper::AverageRedundantGradients(double precision) { mitk::GradientDirectionsProperty* DirectionsProperty = static_cast( m_Image->GetProperty(mitk::DiffusionPropertyHelper::GRADIENTCONTAINERPROPERTYNAME.c_str()).GetPointer() ); GradientDirectionsContainerType::Pointer oldDirs = DirectionsProperty->GetGradientDirectionsContainer(); GradientDirectionsContainerType::Pointer newDirs = CalcAveragedDirectionSet(precision, oldDirs); // if sizes equal, we do not need to do anything in this function if(oldDirs->size() == newDirs->size()) return; // new image ImageType::Pointer oldImage = ImageType::New(); mitk::CastToItkImage( m_Image, oldImage); ImageType::Pointer newITKImage = ImageType::New(); newITKImage->SetSpacing( oldImage->GetSpacing() ); // Set the image spacing newITKImage->SetOrigin( oldImage->GetOrigin() ); // Set the image origin newITKImage->SetDirection( oldImage->GetDirection() ); // Set the image direction newITKImage->SetLargestPossibleRegion( oldImage->GetLargestPossibleRegion() ); newITKImage->SetVectorLength( newDirs->size() ); newITKImage->SetBufferedRegion( oldImage->GetLargestPossibleRegion() ); newITKImage->Allocate(); // average image data that corresponds to identical directions itk::ImageRegionIterator< ImageType > newIt(newITKImage, newITKImage->GetLargestPossibleRegion()); newIt.GoToBegin(); itk::ImageRegionIterator< ImageType > oldIt(oldImage, oldImage->GetLargestPossibleRegion()); oldIt.GoToBegin(); // initial new value of voxel ImageType::PixelType newVec; newVec.SetSize(newDirs->size()); newVec.AllocateElements(newDirs->size()); // find which gradients should be averaged GradientDirectionsContainerType::Pointer oldDirections = oldDirs; std::vector > dirIndices; for(GradientDirectionsContainerType::ConstIterator gdcitNew = newDirs->Begin(); gdcitNew != newDirs->End(); ++gdcitNew) { dirIndices.push_back(std::vector(0)); for(GradientDirectionsContainerType::ConstIterator gdcitOld = oldDirs->Begin(); gdcitOld != oldDirections->End(); ++gdcitOld) { if(AreAlike(gdcitNew.Value(), gdcitOld.Value(), precision)) { //MITK_INFO << gdcitNew.Value() << " " << gdcitOld.Value(); dirIndices[gdcitNew.Index()].push_back(gdcitOld.Index()); } } } //int ind1 = -1; while(!newIt.IsAtEnd()) { // progress //typename ImageType::IndexType ind = newIt.GetIndex(); //ind1 = ind.m_Index[2]; // init new vector with zeros newVec.Fill(0.0); // the old voxel value with duplicates ImageType::PixelType oldVec = oldIt.Get(); for(unsigned int i=0; iSetProperty( mitk::DiffusionPropertyHelper::GRADIENTCONTAINERPROPERTYNAME.c_str(), mitk::GradientDirectionsProperty::New( newDirs ) ); m_Image->SetProperty( mitk::DiffusionPropertyHelper::ORIGINALGRADIENTCONTAINERPROPERTYNAME.c_str(), mitk::GradientDirectionsProperty::New( newDirs ) ); ApplyMeasurementFrame(); UpdateBValueMap(); std::cout << std::endl; } void mitk::DiffusionPropertyHelper::ApplyMeasurementFrame() { if( m_Image->GetProperty(mitk::DiffusionPropertyHelper::ORIGINALGRADIENTCONTAINERPROPERTYNAME.c_str()).IsNull() ) { return; } GradientDirectionsContainerType::Pointer originalDirections = static_cast( m_Image->GetProperty(mitk::DiffusionPropertyHelper::ORIGINALGRADIENTCONTAINERPROPERTYNAME.c_str()).GetPointer())->GetGradientDirectionsContainer(); MeasurementFrameType measurementFrame = GetMeasurementFrame(m_Image); GradientDirectionsContainerType::Pointer directions = GradientDirectionsContainerType::New(); if( originalDirections.IsNull() || ( originalDirections->size() == 0 ) ) { // original direction container was not set return; } GradientDirectionsContainerType::Pointer direction = GradientDirectionsContainerType::New(); int c = 0; for(GradientDirectionsContainerType::ConstIterator gdcit = originalDirections->Begin(); gdcit != originalDirections->End(); ++gdcit) { vnl_vector vec = gdcit.Value(); vec = vec.pre_multiply(measurementFrame); directions->InsertElement(c, vec); c++; } m_Image->SetProperty( mitk::DiffusionPropertyHelper::GRADIENTCONTAINERPROPERTYNAME.c_str(), mitk::GradientDirectionsProperty::New( directions ) ); } void mitk::DiffusionPropertyHelper::UpdateBValueMap() { BValueMapType b_ValueMap; if(m_Image->GetProperty(mitk::DiffusionPropertyHelper::BVALUEMAPPROPERTYNAME.c_str()).IsNull()) { } else { b_ValueMap = static_cast(m_Image->GetProperty(mitk::DiffusionPropertyHelper::BVALUEMAPPROPERTYNAME.c_str()).GetPointer() )->GetBValueMap(); } if(!b_ValueMap.empty()) { b_ValueMap.clear(); } if( m_Image->GetProperty(mitk::DiffusionPropertyHelper::GRADIENTCONTAINERPROPERTYNAME.c_str()).IsNotNull() ) { GradientDirectionsContainerType::Pointer directions = static_cast( m_Image->GetProperty(mitk::DiffusionPropertyHelper::GRADIENTCONTAINERPROPERTYNAME.c_str()).GetPointer() )->GetGradientDirectionsContainer(); GradientDirectionsContainerType::ConstIterator gdcit; for( gdcit = directions->Begin(); gdcit != directions->End(); ++gdcit) { b_ValueMap[GetB_Value(gdcit.Index())].push_back(gdcit.Index()); } } m_Image->SetProperty( mitk::DiffusionPropertyHelper::BVALUEMAPPROPERTYNAME.c_str(), mitk::BValueMapProperty::New( b_ValueMap ) ); } bool mitk::DiffusionPropertyHelper::AreAlike(GradientDirectionType g1, GradientDirectionType g2, double precision) { GradientDirectionType diff = g1 - g2; GradientDirectionType diff2 = g1 + g2; return diff.two_norm() < precision || diff2.two_norm() < precision; } float mitk::DiffusionPropertyHelper::GetB_Value(unsigned int i) { GradientDirectionsContainerType::Pointer directions = static_cast( m_Image->GetProperty(mitk::DiffusionPropertyHelper::GRADIENTCONTAINERPROPERTYNAME.c_str()).GetPointer() )->GetGradientDirectionsContainer(); float b_value = static_cast(m_Image->GetProperty(mitk::DiffusionPropertyHelper::REFERENCEBVALUEPROPERTYNAME.c_str()).GetPointer() )->GetValue(); if(i > directions->Size()-1) return -1; if(directions->ElementAt(i).one_norm() <= 0.0) { return 0; } else { double twonorm = directions->ElementAt(i).two_norm(); double bval = b_value*twonorm*twonorm; if (bval<0) bval = ceil(bval - 0.5); else bval = floor(bval + 0.5); return bval; } } void mitk::DiffusionPropertyHelper::InitializeImage() { this->ApplyMeasurementFrame(); this->UpdateBValueMap(); // initialize missing properties mitk::MeasurementFrameProperty::Pointer mf = dynamic_cast( m_Image->GetProperty(MEASUREMENTFRAMEPROPERTYNAME.c_str()).GetPointer()); if( mf.IsNull() ) { //no measurement frame present, identity is assumed MeasurementFrameType identity; identity.set_identity(); m_Image->SetProperty( mitk::DiffusionPropertyHelper::MEASUREMENTFRAMEPROPERTYNAME.c_str(), mitk::MeasurementFrameProperty::New( identity )); } } +bool mitk::DiffusionPropertyHelper::IsDiffusionWeightedImage(const mitk::DataNode* node) +{ + return IsDiffusionWeightedImage(dynamic_cast(node->GetData())); +} + bool mitk::DiffusionPropertyHelper::IsDiffusionWeightedImage(const mitk::Image * image) { bool isDiffusionWeightedImage( true ); if( image == NULL ) { isDiffusionWeightedImage = false; } if( isDiffusionWeightedImage ) { mitk::FloatProperty::Pointer referenceBValue = dynamic_cast(image->GetProperty(REFERENCEBVALUEPROPERTYNAME.c_str()).GetPointer()); if( referenceBValue.IsNull() ) { isDiffusionWeightedImage = false; } } unsigned int gradientDirections( 0 ); if( isDiffusionWeightedImage ) { mitk::GradientDirectionsProperty::Pointer gradientDirectionsProperty = dynamic_cast(image->GetProperty(GRADIENTCONTAINERPROPERTYNAME.c_str()).GetPointer()); if( gradientDirectionsProperty.IsNull() ) { isDiffusionWeightedImage = false; } else { gradientDirections = gradientDirectionsProperty->GetGradientDirectionsContainer()->size(); } } if( isDiffusionWeightedImage ) { unsigned int components = image->GetPixelType().GetNumberOfComponents(); if( components != gradientDirections ) { isDiffusionWeightedImage = false; } } return isDiffusionWeightedImage; } const mitk::DiffusionPropertyHelper::BValueMapType & mitk::DiffusionPropertyHelper::GetBValueMap(const mitk::Image *image) { return dynamic_cast(image->GetProperty(BVALUEMAPPROPERTYNAME.c_str()).GetPointer())->GetBValueMap(); } float mitk::DiffusionPropertyHelper::GetReferenceBValue(const mitk::Image *image) { return dynamic_cast(image->GetProperty(REFERENCEBVALUEPROPERTYNAME.c_str()).GetPointer())->GetValue(); } const mitk::DiffusionPropertyHelper::MeasurementFrameType & mitk::DiffusionPropertyHelper::GetMeasurementFrame(const mitk::Image *image) { mitk::MeasurementFrameProperty::Pointer mf = dynamic_cast( image->GetProperty(MEASUREMENTFRAMEPROPERTYNAME.c_str()).GetPointer()); if( mf.IsNull() ) { //no measurement frame present, identity is assumed MeasurementFrameType identity; identity.set_identity(); mf = mitk::MeasurementFrameProperty::New( identity ); } return mf->GetMeasurementFrame(); } mitk::DiffusionPropertyHelper::GradientDirectionsContainerType::Pointer mitk::DiffusionPropertyHelper::GetOriginalGradientContainer(const mitk::Image *image) { return dynamic_cast(image->GetProperty(ORIGINALGRADIENTCONTAINERPROPERTYNAME.c_str()).GetPointer())->GetGradientDirectionsContainer(); } mitk::DiffusionPropertyHelper::GradientDirectionsContainerType::Pointer mitk::DiffusionPropertyHelper::GetGradientContainer(const mitk::Image *image) { return dynamic_cast(image->GetProperty(GRADIENTCONTAINERPROPERTYNAME.c_str()).GetPointer())->GetGradientDirectionsContainer(); } bool mitk::DiffusionPropertyHelper::IsDiffusionWeightedImage() const { return IsDiffusionWeightedImage(m_Image); } const mitk::DiffusionPropertyHelper::BValueMapType &mitk::DiffusionPropertyHelper::GetBValueMap() const { return GetBValueMap(m_Image); } float mitk::DiffusionPropertyHelper::GetReferenceBValue() const { return GetReferenceBValue(m_Image); } const mitk::DiffusionPropertyHelper::MeasurementFrameType & mitk::DiffusionPropertyHelper::GetMeasurementFrame() const { return GetMeasurementFrame(m_Image); } mitk::DiffusionPropertyHelper::GradientDirectionsContainerType::Pointer mitk::DiffusionPropertyHelper::GetOriginalGradientContainer() const { return GetOriginalGradientContainer(m_Image); } mitk::DiffusionPropertyHelper::GradientDirectionsContainerType::Pointer mitk::DiffusionPropertyHelper::GetGradientContainer() const { return GetGradientContainer(m_Image); } diff --git a/Modules/DiffusionImaging/DiffusionCore/IODataStructures/Properties/mitkDiffusionPropertyHelper.h b/Modules/DiffusionImaging/DiffusionCore/IODataStructures/Properties/mitkDiffusionPropertyHelper.h index 97081800cb..76b34da010 100644 --- a/Modules/DiffusionImaging/DiffusionCore/IODataStructures/Properties/mitkDiffusionPropertyHelper.h +++ b/Modules/DiffusionImaging/DiffusionCore/IODataStructures/Properties/mitkDiffusionPropertyHelper.h @@ -1,133 +1,135 @@ /*=================================================================== 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 MITKDIFFUSIONPROPERTYHELPER_H #define MITKDIFFUSIONPROPERTYHELPER_H #include #include #include #include #include +#include namespace mitk { /** \brief Helper class for mitk::Images containing diffusion weighted data * * This class takes a pointer to a mitk::Image containing diffusion weighted information and provides * functions to manipulate the diffusion meta-data. Will log an error if required information is * missing. */ class MitkDiffusionCore_EXPORT DiffusionPropertyHelper { public: typedef short DiffusionPixelType; typedef mitk::BValueMapProperty::BValueMap BValueMapType; typedef GradientDirectionsProperty::GradientDirectionType GradientDirectionType; typedef GradientDirectionsProperty::GradientDirectionsContainerType GradientDirectionsContainerType; typedef mitk::MeasurementFrameProperty::MeasurementFrameType MeasurementFrameType; typedef itk::VectorImage< DiffusionPixelType, 3> ImageType; static const std::string GRADIENTCONTAINERPROPERTYNAME; static const std::string ORIGINALGRADIENTCONTAINERPROPERTYNAME; static const std::string MEASUREMENTFRAMEPROPERTYNAME; static const std::string REFERENCEBVALUEPROPERTYNAME; static const std::string BVALUEMAPPROPERTYNAME; /// Public constructor, takes a mitk::Image pointer as argument DiffusionPropertyHelper( mitk::Image* inputImage ); ~DiffusionPropertyHelper(); /** \brief Decide whether a provided image is a valid diffusion weighted image * * An image will be considered a valid diffusion weighted image if the following are true * - It has a reference b value * - It has a gradient directions property * - The number of gradients directions matches the number of components of the image * * This does not guarantee that the data is sensible or accurate, it just verfies that it * meets the formal requirements to possibly be a valid diffusion weighted image. */ static bool IsDiffusionWeightedImage(const mitk::Image *); + static bool IsDiffusionWeightedImage(const mitk::DataNode* node); /// Convenience method to get the BValueMap static const BValueMapType & GetBValueMap(const mitk::Image *); /// Convenience method to get the BValue static float GetReferenceBValue(const mitk::Image *); /** \brief Convenience method to get the measurement frame * * This method will return the measurement frame of the image. * * \note If the image has no associated measurement frame the identity will be returned. */ static const MeasurementFrameType & GetMeasurementFrame(const mitk::Image *); /// Convenience method to get the original gradient directions static GradientDirectionsContainerType::Pointer GetOriginalGradientContainer(const mitk::Image *); /// Convenience method to get the gradient directions static GradientDirectionsContainerType::Pointer GetGradientContainer(const mitk::Image *); const BValueMapType & GetBValueMap() const; float GetReferenceBValue() const; const MeasurementFrameType & GetMeasurementFrame() const; GradientDirectionsContainerType::Pointer GetOriginalGradientContainer() const; GradientDirectionsContainerType::Pointer GetGradientContainer() const; bool IsDiffusionWeightedImage() const; void AverageRedundantGradients(double precision); /** \brief Make certain the owned image is up to date with all necessary properties * * This function will generate the B Value map and copy all properties to the owned image. */ void InitializeImage(); GradientDirectionsContainerType::Pointer CalcAveragedDirectionSet(double precision, GradientDirectionsContainerType::Pointer directions); protected: DiffusionPropertyHelper(); /** * \brief Apply the previouse set MeasurementFrame to all gradients in the GradientsDirectionContainer (m_Directions) * * \warning first set the MeasurementFrame */ void ApplyMeasurementFrame(); /** * \brief Update the BValueMap (m_B_ValueMap) using the current gradient directions (m_Directions) * * \warning Have to be called after each manipulation on the GradientDirectionContainer * !especially after manipulation of the m_Directions (GetDirections()) container via pointer access! */ void UpdateBValueMap(); /// Determines whether gradients can be considered to be equal bool AreAlike(GradientDirectionType g1, GradientDirectionType g2, double precision); /// Get the b value belonging to an index float GetB_Value(unsigned int i); mitk::Image* m_Image; }; } #endif diff --git a/Modules/DiffusionImaging/DiffusionIO/mitkFiberBundleXMapper2D.cpp b/Modules/DiffusionImaging/DiffusionIO/mitkFiberBundleXMapper2D.cpp index 77f4934755..cdbeaa1088 100644 --- a/Modules/DiffusionImaging/DiffusionIO/mitkFiberBundleXMapper2D.cpp +++ b/Modules/DiffusionImaging/DiffusionIO/mitkFiberBundleXMapper2D.cpp @@ -1,214 +1,192 @@ /*=================================================================== 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. ===================================================================*/ -/* - * mitkFiberBundleMapper2D.cpp - * mitk-all - * - * Created by HAL9000 on 1/17/11. - * Copyright 2011 __MyCompanyName__. All rights reserved. - * - */ #include "mitkFiberBundleXMapper2D.h" #include - - #include #include #include #include #include -//#include - -//#include #include #include #include #include #include #include #include #include - -//#include +#include #include #include - #include #include - #include mitk::FiberBundleXMapper2D::FiberBundleXMapper2D() { m_lut = vtkLookupTable::New(); m_lut->Build(); } mitk::FiberBundleXMapper2D::~FiberBundleXMapper2D() { } mitk::FiberBundleX* mitk::FiberBundleXMapper2D::GetInput() { return dynamic_cast< mitk::FiberBundleX * > ( GetDataNode()->GetData() ); } void mitk::FiberBundleXMapper2D::Update(mitk::BaseRenderer * renderer) { bool visible = true; GetDataNode()->GetVisibility(visible, renderer, "visible"); if ( !visible ) return; // Calculate time step of the input data for the specified renderer (integer value) // this method is implemented in mitkMapper this->CalculateTimeStep( renderer ); //check if updates occured in the node or on the display FBXLocalStorage *localStorage = m_LocalStorageHandler.GetLocalStorage(renderer); //set renderer independent shader properties const DataNode::Pointer node = this->GetDataNode(); float thickness = 2.0; if(!this->GetDataNode()->GetPropertyValue("Fiber2DSliceThickness",thickness)) MITK_INFO << "FIBER2D SLICE THICKNESS PROPERTY ERROR"; bool fiberfading = false; if(!this->GetDataNode()->GetPropertyValue("Fiber2DfadeEFX",fiberfading)) MITK_INFO << "FIBER2D SLICE FADE EFX PROPERTY ERROR"; float fiberOpacity; this->GetDataNode()->GetOpacity(fiberOpacity, NULL); node->SetFloatProperty("shader.mitkShaderFiberClipping.fiberThickness",thickness); node->SetIntProperty("shader.mitkShaderFiberClipping.fiberFadingON",fiberfading); node->SetFloatProperty("shader.mitkShaderFiberClipping.fiberOpacity",fiberOpacity); mitk::FiberBundleX* fiberBundle = this->GetInput(); if (fiberBundle==NULL) return; if ( localStorage->m_LastUpdateTimeGetDisplayGeometry()->GetMTime() || localStorage->m_LastUpdateTimeGetUpdateTime2D() ) { this->UpdateShaderParameter(renderer); this->GenerateDataForRenderer( renderer ); } } void mitk::FiberBundleXMapper2D::UpdateShaderParameter(mitk::BaseRenderer * renderer) { //get information about current position of views mitk::SliceNavigationController::Pointer sliceContr = renderer->GetSliceNavigationController(); mitk::PlaneGeometry::ConstPointer planeGeo = sliceContr->GetCurrentPlaneGeometry(); //generate according cutting planes based on the view position float planeNormal[3]; planeNormal[0] = planeGeo->GetNormal()[0]; planeNormal[1] = planeGeo->GetNormal()[1]; planeNormal[2] = planeGeo->GetNormal()[2]; float tmp1 = planeGeo->GetOrigin()[0] * planeNormal[0]; float tmp2 = planeGeo->GetOrigin()[1] * planeNormal[1]; float tmp3 = planeGeo->GetOrigin()[2] * planeNormal[2]; float thickness = tmp1 + tmp2 + tmp3; //attention, correct normalvector DataNode::Pointer node = this->GetDataNode(); node->SetFloatProperty("shader.mitkShaderFiberClipping.slicingPlane.w",thickness,renderer); node->SetFloatProperty("shader.mitkShaderFiberClipping.slicingPlane.x",planeNormal[0],renderer); node->SetFloatProperty("shader.mitkShaderFiberClipping.slicingPlane.y",planeNormal[1],renderer); node->SetFloatProperty("shader.mitkShaderFiberClipping.slicingPlane.z",planeNormal[2],renderer); } // vtkActors and Mappers are feeded here void mitk::FiberBundleXMapper2D::GenerateDataForRenderer(mitk::BaseRenderer *renderer) { mitk::FiberBundleX* fiberBundle = this->GetInput(); //the handler of local storage gets feeded in this method with requested data for related renderwindow FBXLocalStorage *localStorage = m_LocalStorageHandler.GetLocalStorage(renderer); mitk::DataNode* node = this->GetDataNode(); if ( node == NULL ) return; vtkSmartPointer fiberPolyData = fiberBundle->GetFiberPolyData(); if (fiberPolyData == NULL) return; fiberPolyData->GetPointData()->AddArray(fiberBundle->GetFiberColors()); localStorage->m_FiberMapper->ScalarVisibilityOn(); localStorage->m_FiberMapper->SetScalarModeToUsePointFieldData(); localStorage->m_FiberMapper->SetLookupTable(m_lut); //apply the properties after the slice was set localStorage->m_PointActor->GetProperty()->SetOpacity(0.999); localStorage->m_FiberMapper->SelectColorArray("FIBER_COLORS"); -// if(fiberBundle->GetCurrentColorCoding() == fiberBundle->COLORCODING_CUSTOM){ -// float temprgb[3]; -// this->GetDataNode()->GetColor( temprgb, NULL ); -// double trgb[3] = { (double) temprgb[0], (double) temprgb[1], (double) temprgb[2] }; -// localStorage->m_PointActor->GetProperty()->SetColor(trgb); -// } - int lineWidth = 1; node->GetIntProperty("LineWidth",lineWidth); localStorage->m_FiberMapper->SetInputData(fiberPolyData); localStorage->m_PointActor->SetMapper(localStorage->m_FiberMapper); localStorage->m_PointActor->GetProperty()->ShadingOn(); localStorage->m_PointActor->GetProperty()->SetLineWidth(lineWidth); // Applying shading properties this->ApplyShaderProperties(renderer); // We have been modified => save this for next Update() localStorage->m_LastUpdateTime.Modified(); } vtkProp* mitk::FiberBundleXMapper2D::GetVtkProp(mitk::BaseRenderer *renderer) { this->Update(renderer); return m_LocalStorageHandler.GetLocalStorage(renderer)->m_PointActor; } void mitk::FiberBundleXMapper2D::SetDefaultProperties(mitk::DataNode* node, mitk::BaseRenderer* renderer, bool overwrite) { Superclass::SetDefaultProperties(node, renderer, overwrite); node->SetProperty("shader",mitk::ShaderProperty::New("mitkShaderFiberClipping")); // Shaders IShaderRepository* shaderRepo = CoreServices::GetShaderRepository(); if (shaderRepo) { shaderRepo->AddDefaultProperties(node, renderer, overwrite); } //add other parameters to propertylist node->AddProperty( "Fiber2DSliceThickness", mitk::FloatProperty::New(1.0f), renderer, overwrite ); node->AddProperty( "Fiber2DfadeEFX", mitk::BoolProperty::New(true), renderer, overwrite ); node->AddProperty( "color", mitk::ColorProperty::New(1.0,1.0,1.0), renderer, overwrite); + node->AddProperty( "TubeRadius",mitk::FloatProperty::New( 0.0 ), renderer, overwrite); } mitk::FiberBundleXMapper2D::FBXLocalStorage::FBXLocalStorage() { m_PointActor = vtkSmartPointer::New(); m_FiberMapper = vtkSmartPointer::New(); } diff --git a/Modules/DiffusionImaging/DiffusionIO/mitkFiberBundleXMapper3D.cpp b/Modules/DiffusionImaging/DiffusionIO/mitkFiberBundleXMapper3D.cpp index 3d4d2c1a2e..3b720644c6 100644 --- a/Modules/DiffusionImaging/DiffusionIO/mitkFiberBundleXMapper3D.cpp +++ b/Modules/DiffusionImaging/DiffusionIO/mitkFiberBundleXMapper3D.cpp @@ -1,157 +1,181 @@ /*=================================================================== 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 "mitkFiberBundleXMapper3D.h" #include -//#include -//#include #include #include #include #include #include #include - -//not essential for mapper -// #include +#include mitk::FiberBundleXMapper3D::FiberBundleXMapper3D() + : m_TubeRadius(0.0) + , m_TubeSides(15) { m_lut = vtkLookupTable::New(); m_lut->Build(); } mitk::FiberBundleXMapper3D::~FiberBundleXMapper3D() { } const mitk::FiberBundleX* mitk::FiberBundleXMapper3D::GetInput() { return static_cast ( GetDataNode()->GetData() ); } /* This method is called once the mapper gets new input, for UI rotation or changes in colorcoding this method is NOT called */ void mitk::FiberBundleXMapper3D::InternalGenerateData(mitk::BaseRenderer *renderer) { mitk::FiberBundleX* fiberBundle = dynamic_cast (GetDataNode()->GetData()); if (fiberBundle == NULL) return; vtkSmartPointer fiberPolyData = fiberBundle->GetFiberPolyData(); if (fiberPolyData == NULL) return; fiberPolyData->GetPointData()->AddArray(fiberBundle->GetFiberColors()); float tmpopa; this->GetDataNode()->GetOpacity(tmpopa, NULL); FBXLocalStorage3D *localStorage = m_LocalStorageHandler.GetLocalStorage(renderer); + if (m_TubeRadius>0.0) + { + vtkSmartPointer tubeFilter = vtkSmartPointer::New(); + tubeFilter->SetInputData(fiberPolyData); + tubeFilter->SetNumberOfSides(m_TubeSides); + tubeFilter->SetRadius(m_TubeRadius); + tubeFilter->Update(); + fiberPolyData = tubeFilter->GetOutput(); + } + if (tmpopa<1) { vtkSmartPointer depthSort = vtkSmartPointer::New(); depthSort->SetInputData( fiberPolyData ); depthSort->SetCamera( renderer->GetVtkRenderer()->GetActiveCamera() ); depthSort->SetDirectionToFrontToBack(); depthSort->Update(); localStorage->m_FiberMapper->SetInputConnection(depthSort->GetOutputPort()); } else { localStorage->m_FiberMapper->SetInputData(fiberPolyData); } localStorage->m_FiberMapper->SelectColorArray("FIBER_COLORS"); localStorage->m_FiberMapper->ScalarVisibilityOn(); localStorage->m_FiberMapper->SetScalarModeToUsePointFieldData(); localStorage->m_FiberActor->SetMapper(localStorage->m_FiberMapper); localStorage->m_FiberMapper->SetLookupTable(m_lut); // set Opacity localStorage->m_FiberActor->GetProperty()->SetOpacity((double) tmpopa); int lineWidth = 1; this->GetDataNode()->GetIntProperty("LineWidth",lineWidth); localStorage->m_FiberActor->GetProperty()->SetLineWidth(lineWidth); localStorage->m_FiberAssembly->AddPart(localStorage->m_FiberActor); localStorage->m_LastUpdateTime.Modified(); } void mitk::FiberBundleXMapper3D::GenerateDataForRenderer( mitk::BaseRenderer *renderer ) { bool visible = true; GetDataNode()->GetVisibility(visible, renderer, "visible"); if ( !visible ) return; const DataNode* node = this->GetDataNode(); FBXLocalStorage3D* localStorage = m_LocalStorageHandler.GetLocalStorage(renderer); mitk::FiberBundleX* fiberBundle = dynamic_cast(node->GetData()); + + float tubeRadius = 0; + node->GetFloatProperty("TubeRadius", tubeRadius); + if (m_TubeRadius!=tubeRadius) + { + m_TubeRadius = tubeRadius; + fiberBundle->RequestUpdate3D(); + } + int tubeSides = 0; + node->GetIntProperty("TubeSides", tubeSides); + if (m_TubeSides!=tubeSides) + { + m_TubeSides = tubeSides; + fiberBundle->RequestUpdate3D(); + } + if (localStorage->m_LastUpdateTime>=fiberBundle->GetUpdateTime3D()) return; // Calculate time step of the input data for the specified renderer (integer value) // this method is implemented in mitkMapper this->CalculateTimeStep( renderer ); this->InternalGenerateData(renderer); } void mitk::FiberBundleXMapper3D::SetDefaultProperties(mitk::DataNode* node, mitk::BaseRenderer* renderer, bool overwrite) { Superclass::SetDefaultProperties(node, renderer, overwrite); node->AddProperty( "LineWidth", mitk::IntProperty::New( true ), renderer, overwrite ); node->AddProperty( "opacity", mitk::FloatProperty::New( 1.0 ), renderer, overwrite); node->AddProperty( "color", mitk::ColorProperty::New(1.0,1.0,1.0), renderer, overwrite); node->AddProperty( "pickable", mitk::BoolProperty::New( true ), renderer, overwrite); + + node->AddProperty( "TubeRadius",mitk::FloatProperty::New( 0.0 ), renderer, overwrite); + node->AddProperty( "TubeSides",mitk::IntProperty::New( 15 ), renderer, overwrite); } vtkProp* mitk::FiberBundleXMapper3D::GetVtkProp(mitk::BaseRenderer *renderer) { - //MITK_INFO << "FiberBundleXxXXMapper3D()GetVTKProp"; - //this->GenerateData(); return m_LocalStorageHandler.GetLocalStorage(renderer)->m_FiberAssembly; - } void mitk::FiberBundleXMapper3D::UpdateVtkObjects() { } void mitk::FiberBundleXMapper3D::SetVtkMapperImmediateModeRendering(vtkMapper *) { } mitk::FiberBundleXMapper3D::FBXLocalStorage3D::FBXLocalStorage3D() { m_FiberActor = vtkSmartPointer::New(); m_FiberMapper = vtkSmartPointer::New(); m_FiberAssembly = vtkSmartPointer::New(); } diff --git a/Modules/DiffusionImaging/DiffusionIO/mitkFiberBundleXMapper3D.h b/Modules/DiffusionImaging/DiffusionIO/mitkFiberBundleXMapper3D.h index 4f8424637d..75c8a8f01b 100644 --- a/Modules/DiffusionImaging/DiffusionIO/mitkFiberBundleXMapper3D.h +++ b/Modules/DiffusionImaging/DiffusionIO/mitkFiberBundleXMapper3D.h @@ -1,103 +1,104 @@ /*=================================================================== 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 FiberBundleXMapper3D_H_HEADER_INCLUDED #define FiberBundleXMapper3D_H_HEADER_INCLUDED //#include //?? necessary #include #include #include #include #include #include class vtkPropAssembly; namespace mitk { //##Documentation //## @brief Mapper for FiberBundleX //## @ingroup Mapper class FiberBundleXMapper3D : public VtkMapper { public: mitkClassMacro(FiberBundleXMapper3D, VtkMapper) itkFactorylessNewMacro(Self) itkCloneMacro(Self) //========== essential implementation for 3D mapper ======== const FiberBundleX* GetInput(); virtual vtkProp *GetVtkProp(mitk::BaseRenderer *renderer); //looks like depricated.. should be replaced bz GetViewProp() static void SetDefaultProperties(DataNode* node, BaseRenderer* renderer = NULL, bool overwrite = false ); static void SetVtkMapperImmediateModeRendering(vtkMapper *mapper); virtual void GenerateDataForRenderer(mitk::BaseRenderer* renderer); //========================================================= class FBXLocalStorage3D : public mitk::Mapper::BaseLocalStorage { public: /** \brief Point Actor of a 3D render window. */ vtkSmartPointer m_FiberActor; /** \brief Point Mapper of a 3D render window. */ vtkSmartPointer m_FiberMapper; vtkSmartPointer m_FiberAssembly; /** \brief Timestamp of last update of stored data. */ itk::TimeStamp m_LastUpdateTime; /** \brief Constructor of the local storage. Do as much actions as possible in here to avoid double executions. */ FBXLocalStorage3D(); //if u copy&paste from this 2Dmapper, be aware that the implementation of this constructor is in the cpp file ~FBXLocalStorage3D() { } }; /** \brief This member holds all three LocalStorages for the 3D render window(s). */ mitk::LocalStorageHandler m_LocalStorageHandler; protected: FiberBundleXMapper3D(); virtual ~FiberBundleXMapper3D(); void InternalGenerateData(mitk::BaseRenderer *renderer); void UpdateVtkObjects(); //?? private: vtkSmartPointer m_lut; - + float m_TubeRadius; + int m_TubeSides; }; } // end namespace mitk #endif /* FiberBundleXMapper3D_H_HEADER_INCLUDED */ diff --git a/Plugins/org.mitk.gui.qt.diffusionimaging/src/internal/QmitkControlVisualizationPropertiesView.cpp b/Plugins/org.mitk.gui.qt.diffusionimaging/src/internal/QmitkControlVisualizationPropertiesView.cpp index 5519f43796..03db72eb23 100644 --- a/Plugins/org.mitk.gui.qt.diffusionimaging/src/internal/QmitkControlVisualizationPropertiesView.cpp +++ b/Plugins/org.mitk.gui.qt.diffusionimaging/src/internal/QmitkControlVisualizationPropertiesView.cpp @@ -1,1022 +1,1033 @@ /*=================================================================== 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 "QmitkControlVisualizationPropertiesView.h" #include "mitkNodePredicateDataType.h" #include "mitkDataNodeObject.h" #include "mitkOdfNormalizationMethodProperty.h" #include "mitkOdfScaleByProperty.h" #include "mitkResliceMethodProperty.h" #include "mitkRenderingManager.h" #include "mitkTbssImage.h" #include "mitkPlanarFigure.h" #include "mitkFiberBundleX.h" #include "QmitkDataStorageComboBox.h" #include "QmitkStdMultiWidget.h" #include "mitkFiberBundleInteractor.h" #include "mitkPlanarFigureInteractor.h" #include #include #include #include #include #include "mitkGlobalInteraction.h" #include "usModuleRegistry.h" #include "mitkPlaneGeometry.h" #include "berryIWorkbenchWindow.h" #include "berryIWorkbenchPage.h" #include "berryISelectionService.h" #include "berryConstants.h" #include "berryPlatformUI.h" #include "itkRGBAPixel.h" #include #include "qwidgetaction.h" #include "qcolordialog.h" #include #include #define ROUND(a) ((a)>0 ? (int)((a)+0.5) : -(int)(0.5-(a))) const std::string QmitkControlVisualizationPropertiesView::VIEW_ID = "org.mitk.views.controlvisualizationpropertiesview"; using namespace berry; QmitkControlVisualizationPropertiesView::QmitkControlVisualizationPropertiesView() : QmitkFunctionality(), m_Controls(NULL), m_MultiWidget(NULL), m_NodeUsedForOdfVisualization(NULL), m_IconTexOFF(new QIcon(":/QmitkDiffusionImaging/texIntOFFIcon.png")), m_IconTexON(new QIcon(":/QmitkDiffusionImaging/texIntONIcon.png")), m_IconGlyOFF_T(new QIcon(":/QmitkDiffusionImaging/glyphsoff_T.png")), m_IconGlyON_T(new QIcon(":/QmitkDiffusionImaging/glyphson_T.png")), m_IconGlyOFF_C(new QIcon(":/QmitkDiffusionImaging/glyphsoff_C.png")), m_IconGlyON_C(new QIcon(":/QmitkDiffusionImaging/glyphson_C.png")), m_IconGlyOFF_S(new QIcon(":/QmitkDiffusionImaging/glyphsoff_S.png")), m_IconGlyON_S(new QIcon(":/QmitkDiffusionImaging/glyphson_S.png")), m_CurrentSelection(0), m_CurrentPickingNode(0), m_GlyIsOn_S(false), m_GlyIsOn_C(false), m_GlyIsOn_T(false), m_FiberBundleObserverTag(0), m_FiberBundleObserveOpacityTag(0), m_Color(NULL) { currentThickSlicesMode = 1; m_MyMenu = NULL; int numThread = itk::MultiThreader::GetGlobalMaximumNumberOfThreads(); if (numThread > 12) numThread = 12; itk::MultiThreader::SetGlobalDefaultNumberOfThreads(numThread); } QmitkControlVisualizationPropertiesView::QmitkControlVisualizationPropertiesView(const QmitkControlVisualizationPropertiesView& other) { Q_UNUSED(other) throw std::runtime_error("Copy constructor not implemented"); } QmitkControlVisualizationPropertiesView::~QmitkControlVisualizationPropertiesView() { if(m_SlicesRotationObserverTag1 ) { mitk::SlicesCoordinator::Pointer coordinator = m_MultiWidget->GetSlicesRotator(); if( coordinator.IsNotNull() ) coordinator->RemoveObserver(m_SlicesRotationObserverTag1); } if( m_SlicesRotationObserverTag2) { mitk::SlicesCoordinator::Pointer coordinator = m_MultiWidget->GetSlicesRotator(); if( coordinator.IsNotNull() ) coordinator->RemoveObserver(m_SlicesRotationObserverTag1); } this->GetSite()->GetWorkbenchWindow()->GetSelectionService()->RemovePostSelectionListener(/*"org.mitk.views.datamanager",*/ m_SelListener); } void QmitkControlVisualizationPropertiesView::OnThickSlicesModeSelected( QAction* action ) { currentThickSlicesMode = action->data().toInt(); switch(currentThickSlicesMode) { default: case 1: this->m_Controls->m_TSMenu->setText("MIP"); break; case 2: this->m_Controls->m_TSMenu->setText("SUM"); break; case 3: this->m_Controls->m_TSMenu->setText("WEIGH"); break; } mitk::DataNode* n; n = this->m_MultiWidget->GetWidgetPlane1(); if(n) n->SetProperty( "reslice.thickslices", mitk::ResliceMethodProperty::New( currentThickSlicesMode ) ); n = this->m_MultiWidget->GetWidgetPlane2(); if(n) n->SetProperty( "reslice.thickslices", mitk::ResliceMethodProperty::New( currentThickSlicesMode ) ); n = this->m_MultiWidget->GetWidgetPlane3(); if(n) n->SetProperty( "reslice.thickslices", mitk::ResliceMethodProperty::New( currentThickSlicesMode ) ); mitk::BaseRenderer::Pointer renderer = this->GetActiveStdMultiWidget()->GetRenderWindow1()->GetRenderer(); if(renderer.IsNotNull()) { renderer->SendUpdateSlice(); } renderer = this->GetActiveStdMultiWidget()->GetRenderWindow2()->GetRenderer(); if(renderer.IsNotNull()) { renderer->SendUpdateSlice(); } renderer = this->GetActiveStdMultiWidget()->GetRenderWindow3()->GetRenderer(); if(renderer.IsNotNull()) { renderer->SendUpdateSlice(); } renderer->GetRenderingManager()->RequestUpdateAll(); } void QmitkControlVisualizationPropertiesView::OnTSNumChanged(int num) { if(num==0) { mitk::DataNode* n; n = this->m_MultiWidget->GetWidgetPlane1(); if(n) n->SetProperty( "reslice.thickslices", mitk::ResliceMethodProperty::New( 0 ) ); if(n) n->SetProperty( "reslice.thickslices.num", mitk::IntProperty::New( num ) ); if(n) n->SetProperty( "reslice.thickslices.showarea", mitk::BoolProperty::New( false ) ); n = this->m_MultiWidget->GetWidgetPlane2(); if(n) n->SetProperty( "reslice.thickslices", mitk::ResliceMethodProperty::New( 0 ) ); if(n) n->SetProperty( "reslice.thickslices.num", mitk::IntProperty::New( num ) ); if(n) n->SetProperty( "reslice.thickslices.showarea", mitk::BoolProperty::New( false ) ); n = this->m_MultiWidget->GetWidgetPlane3(); if(n) n->SetProperty( "reslice.thickslices", mitk::ResliceMethodProperty::New( 0 ) ); if(n) n->SetProperty( "reslice.thickslices.num", mitk::IntProperty::New( num ) ); if(n) n->SetProperty( "reslice.thickslices.showarea", mitk::BoolProperty::New( false ) ); } else { mitk::DataNode* n; n = this->m_MultiWidget->GetWidgetPlane1(); if(n) n->SetProperty( "reslice.thickslices", mitk::ResliceMethodProperty::New( currentThickSlicesMode ) ); if(n) n->SetProperty( "reslice.thickslices.num", mitk::IntProperty::New( num ) ); if(n) n->SetProperty( "reslice.thickslices.showarea", mitk::BoolProperty::New( (num>0) ) ); n = this->m_MultiWidget->GetWidgetPlane2(); if(n) n->SetProperty( "reslice.thickslices", mitk::ResliceMethodProperty::New( currentThickSlicesMode ) ); if(n) n->SetProperty( "reslice.thickslices.num", mitk::IntProperty::New( num ) ); if(n) n->SetProperty( "reslice.thickslices.showarea", mitk::BoolProperty::New( (num>0) ) ); n = this->m_MultiWidget->GetWidgetPlane3(); if(n) n->SetProperty( "reslice.thickslices", mitk::ResliceMethodProperty::New( currentThickSlicesMode ) ); if(n) n->SetProperty( "reslice.thickslices.num", mitk::IntProperty::New( num ) ); if(n) n->SetProperty( "reslice.thickslices.showarea", mitk::BoolProperty::New( (num>0) ) ); } m_TSLabel->setText(QString::number(num*2+1)); mitk::BaseRenderer::Pointer renderer = this->GetActiveStdMultiWidget()->GetRenderWindow1()->GetRenderer(); if(renderer.IsNotNull()) renderer->SendUpdateSlice(); renderer = this->GetActiveStdMultiWidget()->GetRenderWindow2()->GetRenderer(); if(renderer.IsNotNull()) renderer->SendUpdateSlice(); renderer = this->GetActiveStdMultiWidget()->GetRenderWindow3()->GetRenderer(); if(renderer.IsNotNull()) renderer->SendUpdateSlice(); renderer->GetRenderingManager()->RequestUpdateAll(mitk::RenderingManager::REQUEST_UPDATE_2DWINDOWS); } void QmitkControlVisualizationPropertiesView::CreateQtPartControl(QWidget *parent) { if (!m_Controls) { // create GUI widgets m_Controls = new Ui::QmitkControlVisualizationPropertiesViewControls; m_Controls->setupUi(parent); this->CreateConnections(); // hide warning (ODFs in rotated planes) m_Controls->m_lblRotatedPlanesWarning->hide(); m_MyMenu = new QMenu(parent); m_Controls->m_TSMenu->setMenu( m_MyMenu ); QIcon iconFiberFade(":/QmitkDiffusionImaging/MapperEfx2D.png"); m_Controls->m_FiberFading2D->setIcon(iconFiberFade); #ifndef DIFFUSION_IMAGING_EXTENDED int size = m_Controls->m_AdditionalScaling->count(); for(int t=0; tm_AdditionalScaling->itemText(t).toStdString() == "Scale by ASR") { m_Controls->m_AdditionalScaling->removeItem(t); } } #endif m_Controls->m_ScalingFrame->setVisible(false); m_Controls->m_NormalizationFrame->setVisible(false); } } void QmitkControlVisualizationPropertiesView::StdMultiWidgetAvailable (QmitkStdMultiWidget &stdMultiWidget) { m_MultiWidget = &stdMultiWidget; if (m_MultiWidget) { mitk::SlicesCoordinator* coordinator = m_MultiWidget->GetSlicesRotator(); if (coordinator) { itk::ReceptorMemberCommand::Pointer command2 = itk::ReceptorMemberCommand::New(); command2->SetCallbackFunction( this, &QmitkControlVisualizationPropertiesView::SliceRotation ); m_SlicesRotationObserverTag1 = coordinator->AddObserver( mitk::SliceRotationEvent(), command2 ); } coordinator = m_MultiWidget->GetSlicesSwiveller(); if (coordinator) { itk::ReceptorMemberCommand::Pointer command2 = itk::ReceptorMemberCommand::New(); command2->SetCallbackFunction( this, &QmitkControlVisualizationPropertiesView::SliceRotation ); m_SlicesRotationObserverTag2 = coordinator->AddObserver( mitk::SliceRotationEvent(), command2 ); } } } void QmitkControlVisualizationPropertiesView::SliceRotation(const itk::EventObject&) { // test if plane rotated if( m_GlyIsOn_T || m_GlyIsOn_C || m_GlyIsOn_S ) { if( this->IsPlaneRotated() ) { // show label m_Controls->m_lblRotatedPlanesWarning->show(); } else { //hide label m_Controls->m_lblRotatedPlanesWarning->hide(); } } } void QmitkControlVisualizationPropertiesView::StdMultiWidgetNotAvailable() { m_MultiWidget = NULL; } void QmitkControlVisualizationPropertiesView::NodeRemoved(const mitk::DataNode* node) { } #include void QmitkControlVisualizationPropertiesView::CreateConnections() { if ( m_Controls ) { connect( (QObject*)(m_Controls->m_VisibleOdfsON_T), SIGNAL(clicked()), this, SLOT(VisibleOdfsON_T()) ); connect( (QObject*)(m_Controls->m_VisibleOdfsON_S), SIGNAL(clicked()), this, SLOT(VisibleOdfsON_S()) ); connect( (QObject*)(m_Controls->m_VisibleOdfsON_C), SIGNAL(clicked()), this, SLOT(VisibleOdfsON_C()) ); connect( (QObject*)(m_Controls->m_ShowMaxNumber), SIGNAL(editingFinished()), this, SLOT(ShowMaxNumberChanged()) ); connect( (QObject*)(m_Controls->m_NormalizationDropdown), SIGNAL(currentIndexChanged(int)), this, SLOT(NormalizationDropdownChanged(int)) ); connect( (QObject*)(m_Controls->m_ScalingFactor), SIGNAL(valueChanged(double)), this, SLOT(ScalingFactorChanged(double)) ); connect( (QObject*)(m_Controls->m_AdditionalScaling), SIGNAL(currentIndexChanged(int)), this, SLOT(AdditionalScaling(int)) ); connect( (QObject*)(m_Controls->m_ScalingCheckbox), SIGNAL(clicked()), this, SLOT(ScalingCheckbox()) ); connect((QObject*) m_Controls->m_ResetColoring, SIGNAL(clicked()), (QObject*) this, SLOT(BundleRepresentationResetColoring())); connect((QObject*) m_Controls->m_FiberFading2D, SIGNAL(clicked()), (QObject*) this, SLOT( Fiber2DfadingEFX() ) ); connect((QObject*) m_Controls->m_FiberThicknessSlider, SIGNAL(sliderReleased()), (QObject*) this, SLOT( FiberSlicingThickness2D() ) ); connect((QObject*) m_Controls->m_FiberThicknessSlider, SIGNAL(valueChanged(int)), (QObject*) this, SLOT( FiberSlicingUpdateLabel(int) )); connect((QObject*) m_Controls->m_Crosshair, SIGNAL(clicked()), (QObject*) this, SLOT(SetInteractor())); connect((QObject*) m_Controls->m_LineWidth, SIGNAL(editingFinished()), (QObject*) this, SLOT(LineWidthChanged())); + connect((QObject*) m_Controls->m_TubeWidth, SIGNAL(editingFinished()), (QObject*) this, SLOT(TubeRadiusChanged())); } } void QmitkControlVisualizationPropertiesView::Activated() { } void QmitkControlVisualizationPropertiesView::Deactivated() { } // set diffusion image channel to b0 volume void QmitkControlVisualizationPropertiesView::NodeAdded(const mitk::DataNode *node) { mitk::DataNode* notConst = const_cast(node); bool isDiffusionImage( mitk::DiffusionPropertyHelper::IsDiffusionWeightedImage( dynamic_cast(node->GetData())) ); if (isDiffusionImage) { mitk::Image::Pointer dimg = dynamic_cast(notConst->GetData()); // if there is no b0 image in the dataset, the GetB0Indices() returns a vector of size 0 // and hence we cannot set the Property directly to .front() int displayChannelPropertyValue = 0; mitk::BValueMapProperty* bmapproperty = static_cast(dimg->GetProperty(mitk::DiffusionPropertyHelper::BVALUEMAPPROPERTYNAME.c_str()).GetPointer() ); mitk::DiffusionPropertyHelper::BValueMapType map = bmapproperty->GetBValueMap(); if( map[0].size() > 0) displayChannelPropertyValue = map[0].front(); notConst->SetIntProperty("DisplayChannel", displayChannelPropertyValue ); } } /* OnSelectionChanged is registered to SelectionService, therefore no need to implement SelectionService Listener explicitly */ void QmitkControlVisualizationPropertiesView::OnSelectionChanged( std::vector nodes ) { m_Controls->m_BundleControlsFrame->setVisible(false); m_Controls->m_ImageControlsFrame->setVisible(false); if (nodes.size()>1) // only do stuff if one node is selected return; m_Controls->m_NumberGlyphsFrame->setVisible(false); m_Controls->m_GlyphFrame->setVisible(false); m_Controls->m_TSMenu->setVisible(false); m_SelectedNode = NULL; int numOdfImages = 0; for( std::vector::iterator it = nodes.begin(); it != nodes.end(); ++it ) { mitk::DataNode::Pointer node = *it; if(node.IsNull()) continue; mitk::BaseData* nodeData = node->GetData(); if(nodeData == NULL) continue; m_SelectedNode = node; if (dynamic_cast(nodeData)) { // handle fiber bundle property observers if (m_Color.IsNotNull()) m_Color->RemoveObserver(m_FiberBundleObserverTag); itk::ReceptorMemberCommand::Pointer command = itk::ReceptorMemberCommand::New(); command->SetCallbackFunction( this, &QmitkControlVisualizationPropertiesView::SetFiberBundleCustomColor ); m_Color = dynamic_cast(node->GetProperty("color", NULL)); if (m_Color.IsNotNull()) m_FiberBundleObserverTag = m_Color->AddObserver( itk::ModifiedEvent(), command ); if (m_Opacity.IsNotNull()) m_Opacity->RemoveObserver(m_FiberBundleObserveOpacityTag); itk::ReceptorMemberCommand::Pointer command2 = itk::ReceptorMemberCommand::New(); command2->SetCallbackFunction( this, &QmitkControlVisualizationPropertiesView::SetFiberBundleOpacity ); m_Opacity = dynamic_cast(node->GetProperty("opacity", NULL)); if (m_Opacity.IsNotNull()) m_FiberBundleObserveOpacityTag = m_Opacity->AddObserver( itk::ModifiedEvent(), command2 ); m_Controls->m_BundleControlsFrame->setVisible(true); // ??? if(m_CurrentPickingNode != 0 && node.GetPointer() != m_CurrentPickingNode) m_Controls->m_Crosshair->setEnabled(false); else m_Controls->m_Crosshair->setEnabled(true); int width; node->GetIntProperty("LineWidth", width); m_Controls->m_LineWidth->setValue(width); float range; node->GetFloatProperty("Fiber2DSliceThickness",range); mitk::FiberBundleX::Pointer fib = dynamic_cast(node->GetData()); mitk::BaseGeometry::Pointer geo = fib->GetGeometry(); mitk::ScalarType max = geo->GetExtentInMM(0); max = std::max(max, geo->GetExtentInMM(1)); max = std::max(max, geo->GetExtentInMM(2)); m_Controls->m_FiberThicknessSlider->setMaximum(max * 10); m_Controls->m_FiberThicknessSlider->setValue(range * 10); m_Controls->m_FiberThicknessSlider->setFocus(); } else if(dynamic_cast(nodeData) || dynamic_cast(nodeData)) { m_Controls->m_ImageControlsFrame->setVisible(true); m_Controls->m_NumberGlyphsFrame->setVisible(true); m_Controls->m_GlyphFrame->setVisible(true); if(m_NodeUsedForOdfVisualization.IsNotNull()) { m_NodeUsedForOdfVisualization->SetBoolProperty("VisibleOdfs_S", false); m_NodeUsedForOdfVisualization->SetBoolProperty("VisibleOdfs_C", false); m_NodeUsedForOdfVisualization->SetBoolProperty("VisibleOdfs_T", false); } m_NodeUsedForOdfVisualization = node; m_NodeUsedForOdfVisualization->SetBoolProperty("VisibleOdfs_S", m_GlyIsOn_S); m_NodeUsedForOdfVisualization->SetBoolProperty("VisibleOdfs_C", m_GlyIsOn_C); m_NodeUsedForOdfVisualization->SetBoolProperty("VisibleOdfs_T", m_GlyIsOn_T); int val; node->GetIntProperty("ShowMaxNumber", val); m_Controls->m_ShowMaxNumber->setValue(val); m_Controls->m_NormalizationDropdown->setCurrentIndex(dynamic_cast(node->GetProperty("Normalization"))->GetValueAsId()); float fval; node->GetFloatProperty("Scaling",fval); m_Controls->m_ScalingFactor->setValue(fval); m_Controls->m_AdditionalScaling->setCurrentIndex(dynamic_cast(node->GetProperty("ScaleBy"))->GetValueAsId()); numOdfImages++; } else if(dynamic_cast(nodeData)) { PlanarFigureFocus(); } else if( dynamic_cast(nodeData) ) { m_Controls->m_ImageControlsFrame->setVisible(true); m_Controls->m_TSMenu->setVisible(true); } } if( nodes.empty() ) return; mitk::DataNode::Pointer node = nodes.at(0); if( node.IsNull() ) return; QMenu *myMenu = m_MyMenu; myMenu->clear(); QActionGroup* thickSlicesActionGroup = new QActionGroup(myMenu); thickSlicesActionGroup->setExclusive(true); int currentTSMode = 0; { mitk::ResliceMethodProperty::Pointer m = dynamic_cast(node->GetProperty( "reslice.thickslices" )); if( m.IsNotNull() ) currentTSMode = m->GetValueAsId(); } int maxTS = 30; for( std::vector::iterator it = nodes.begin(); it != nodes.end(); ++it ) { mitk::Image* image = dynamic_cast((*it)->GetData()); if (image) { int size = std::max(image->GetDimension(0), std::max(image->GetDimension(1), image->GetDimension(2))); if (size>maxTS) maxTS=size; } } maxTS /= 2; int currentNum = 0; { mitk::IntProperty::Pointer m = dynamic_cast(node->GetProperty( "reslice.thickslices.num" )); if( m.IsNotNull() ) { currentNum = m->GetValue(); if(currentNum < 0) currentNum = 0; if(currentNum > maxTS) currentNum = maxTS; } } if(currentTSMode==0) currentNum=0; QSlider *m_TSSlider = new QSlider(myMenu); m_TSSlider->setMinimum(0); m_TSSlider->setMaximum(maxTS-1); m_TSSlider->setValue(currentNum); m_TSSlider->setOrientation(Qt::Horizontal); connect( m_TSSlider, SIGNAL( valueChanged(int) ), this, SLOT( OnTSNumChanged(int) ) ); QHBoxLayout* _TSLayout = new QHBoxLayout; _TSLayout->setContentsMargins(4,4,4,4); _TSLayout->addWidget(m_TSSlider); _TSLayout->addWidget(m_TSLabel=new QLabel(QString::number(currentNum*2+1),myMenu)); QWidget* _TSWidget = new QWidget; _TSWidget->setLayout(_TSLayout); QActionGroup* thickSliceModeActionGroup = new QActionGroup(myMenu); thickSliceModeActionGroup->setExclusive(true); QWidgetAction *m_TSSliderAction = new QWidgetAction(myMenu); m_TSSliderAction->setDefaultWidget(_TSWidget); myMenu->addAction(m_TSSliderAction); QAction* mipThickSlicesAction = new QAction(myMenu); mipThickSlicesAction->setActionGroup(thickSliceModeActionGroup); mipThickSlicesAction->setText("MIP (max. intensity proj.)"); mipThickSlicesAction->setCheckable(true); mipThickSlicesAction->setChecked(currentThickSlicesMode==1); mipThickSlicesAction->setData(1); myMenu->addAction( mipThickSlicesAction ); QAction* sumThickSlicesAction = new QAction(myMenu); sumThickSlicesAction->setActionGroup(thickSliceModeActionGroup); sumThickSlicesAction->setText("SUM (sum intensity proj.)"); sumThickSlicesAction->setCheckable(true); sumThickSlicesAction->setChecked(currentThickSlicesMode==2); sumThickSlicesAction->setData(2); myMenu->addAction( sumThickSlicesAction ); QAction* weightedThickSlicesAction = new QAction(myMenu); weightedThickSlicesAction->setActionGroup(thickSliceModeActionGroup); weightedThickSlicesAction->setText("WEIGHTED (gaussian proj.)"); weightedThickSlicesAction->setCheckable(true); weightedThickSlicesAction->setChecked(currentThickSlicesMode==3); weightedThickSlicesAction->setData(3); myMenu->addAction( weightedThickSlicesAction ); connect( thickSliceModeActionGroup, SIGNAL(triggered(QAction*)), this, SLOT(OnThickSlicesModeSelected(QAction*)) ); } void QmitkControlVisualizationPropertiesView::VisibleOdfsON_S() { m_GlyIsOn_S = m_Controls->m_VisibleOdfsON_S->isChecked(); if (m_NodeUsedForOdfVisualization.IsNull()) { MITK_WARN << "ODF visualization activated but m_NodeUsedForOdfVisualization is NULL"; return; } m_NodeUsedForOdfVisualization->SetBoolProperty("VisibleOdfs_S", m_GlyIsOn_S); mitk::RenderingManager::GetInstance()->RequestUpdateAll(); } void QmitkControlVisualizationPropertiesView::VisibleOdfsON_T() { m_GlyIsOn_T = m_Controls->m_VisibleOdfsON_T->isChecked(); if (m_NodeUsedForOdfVisualization.IsNull()) { MITK_WARN << "ODF visualization activated but m_NodeUsedForOdfVisualization is NULL"; return; } m_NodeUsedForOdfVisualization->SetBoolProperty("VisibleOdfs_T", m_GlyIsOn_T); mitk::RenderingManager::GetInstance()->RequestUpdateAll(); } void QmitkControlVisualizationPropertiesView::VisibleOdfsON_C() { m_GlyIsOn_C = m_Controls->m_VisibleOdfsON_C->isChecked(); if (m_NodeUsedForOdfVisualization.IsNull()) { MITK_WARN << "ODF visualization activated but m_NodeUsedForOdfVisualization is NULL"; return; } m_NodeUsedForOdfVisualization->SetBoolProperty("VisibleOdfs_C", m_GlyIsOn_C); mitk::RenderingManager::GetInstance()->RequestUpdateAll(); } bool QmitkControlVisualizationPropertiesView::IsPlaneRotated() { mitk::Image* currentImage = dynamic_cast( m_NodeUsedForOdfVisualization->GetData() ); if( currentImage == NULL ) { MITK_ERROR << " Casting problems. Returning false"; return false; } mitk::Vector3D imageNormal0 = currentImage->GetSlicedGeometry()->GetAxisVector(0); mitk::Vector3D imageNormal1 = currentImage->GetSlicedGeometry()->GetAxisVector(1); mitk::Vector3D imageNormal2 = currentImage->GetSlicedGeometry()->GetAxisVector(2); imageNormal0.Normalize(); imageNormal1.Normalize(); imageNormal2.Normalize(); double eps = 0.000001; // for all 2D renderwindows of m_MultiWidget check alignment { mitk::PlaneGeometry::ConstPointer displayPlane = dynamic_cast( m_MultiWidget->GetRenderWindow1()->GetRenderer()->GetCurrentWorldGeometry2D() ); if (displayPlane.IsNull()) return false; mitk::Vector3D normal = displayPlane->GetNormal(); normal.Normalize(); int test = 0; if( fabs(fabs(dot_product(normal.GetVnlVector(),imageNormal0.GetVnlVector()))-1) > eps ) test++; if( fabs(fabs(dot_product(normal.GetVnlVector(),imageNormal1.GetVnlVector()))-1) > eps ) test++; if( fabs(fabs(dot_product(normal.GetVnlVector(),imageNormal2.GetVnlVector()))-1) > eps ) test++; if (test==3) return true; } { mitk::PlaneGeometry::ConstPointer displayPlane = dynamic_cast( m_MultiWidget->GetRenderWindow2()->GetRenderer()->GetCurrentWorldGeometry2D() ); if (displayPlane.IsNull()) return false; mitk::Vector3D normal = displayPlane->GetNormal(); normal.Normalize(); int test = 0; if( fabs(fabs(dot_product(normal.GetVnlVector(),imageNormal0.GetVnlVector()))-1) > eps ) test++; if( fabs(fabs(dot_product(normal.GetVnlVector(),imageNormal1.GetVnlVector()))-1) > eps ) test++; if( fabs(fabs(dot_product(normal.GetVnlVector(),imageNormal2.GetVnlVector()))-1) > eps ) test++; if (test==3) return true; } { mitk::PlaneGeometry::ConstPointer displayPlane = dynamic_cast( m_MultiWidget->GetRenderWindow3()->GetRenderer()->GetCurrentWorldGeometry2D() ); if (displayPlane.IsNull()) return false; mitk::Vector3D normal = displayPlane->GetNormal(); normal.Normalize(); int test = 0; if( fabs(fabs(dot_product(normal.GetVnlVector(),imageNormal0.GetVnlVector()))-1) > eps ) test++; if( fabs(fabs(dot_product(normal.GetVnlVector(),imageNormal1.GetVnlVector()))-1) > eps ) test++; if( fabs(fabs(dot_product(normal.GetVnlVector(),imageNormal2.GetVnlVector()))-1) > eps ) test++; if (test==3) return true; } return false; } void QmitkControlVisualizationPropertiesView::ShowMaxNumberChanged() { int maxNr = m_Controls->m_ShowMaxNumber->value(); if ( maxNr < 1 ) { m_Controls->m_ShowMaxNumber->setValue( 1 ); maxNr = 1; } if (dynamic_cast(m_SelectedNode->GetData()) || dynamic_cast(m_SelectedNode->GetData())) m_SelectedNode->SetIntProperty("ShowMaxNumber", maxNr); mitk::RenderingManager::GetInstance()->RequestUpdateAll(); } void QmitkControlVisualizationPropertiesView::NormalizationDropdownChanged(int normDropdown) { typedef mitk::OdfNormalizationMethodProperty PropType; PropType::Pointer normMeth = PropType::New(); switch(normDropdown) { case 0: normMeth->SetNormalizationToMinMax(); break; case 1: normMeth->SetNormalizationToMax(); break; case 2: normMeth->SetNormalizationToNone(); break; case 3: normMeth->SetNormalizationToGlobalMax(); break; default: normMeth->SetNormalizationToMinMax(); } if (dynamic_cast(m_SelectedNode->GetData()) || dynamic_cast(m_SelectedNode->GetData())) m_SelectedNode->SetProperty("Normalization", normMeth.GetPointer()); mitk::RenderingManager::GetInstance()->RequestUpdateAll(); } void QmitkControlVisualizationPropertiesView::ScalingFactorChanged(double scalingFactor) { if (dynamic_cast(m_SelectedNode->GetData()) || dynamic_cast(m_SelectedNode->GetData())) m_SelectedNode->SetFloatProperty("Scaling", scalingFactor); if(m_MultiWidget) m_MultiWidget->RequestUpdate(); } void QmitkControlVisualizationPropertiesView::AdditionalScaling(int additionalScaling) { typedef mitk::OdfScaleByProperty PropType; PropType::Pointer scaleBy = PropType::New(); switch(additionalScaling) { case 0: scaleBy->SetScaleByNothing(); break; case 1: scaleBy->SetScaleByGFA(); //m_Controls->params_frame->setVisible(true); break; #ifdef DIFFUSION_IMAGING_EXTENDED case 2: scaleBy->SetScaleByPrincipalCurvature(); // commented in for SPIE paper, Principle curvature scaling //m_Controls->params_frame->setVisible(true); break; #endif default: scaleBy->SetScaleByNothing(); } if (dynamic_cast(m_SelectedNode->GetData()) || dynamic_cast(m_SelectedNode->GetData())) m_SelectedNode->SetProperty("Normalization", scaleBy.GetPointer()); mitk::RenderingManager::GetInstance()->RequestUpdateAll(); } void QmitkControlVisualizationPropertiesView::ScalingCheckbox() { m_Controls->m_ScalingFrame->setVisible( m_Controls->m_ScalingCheckbox->isChecked()); if(!m_Controls->m_ScalingCheckbox->isChecked()) { m_Controls->m_AdditionalScaling->setCurrentIndex(0); m_Controls->m_ScalingFactor->setValue(1.0); } } void QmitkControlVisualizationPropertiesView::Fiber2DfadingEFX() { if (m_SelectedNode && dynamic_cast(m_SelectedNode->GetData()) ) { bool currentMode; m_SelectedNode->GetBoolProperty("Fiber2DfadeEFX", currentMode); m_SelectedNode->SetProperty("Fiber2DfadeEFX", mitk::BoolProperty::New(!currentMode)); dynamic_cast(m_SelectedNode->GetData())->RequestUpdate2D(); mitk::RenderingManager::GetInstance()->RequestUpdateAll(); } } void QmitkControlVisualizationPropertiesView::FiberSlicingThickness2D() { if (m_SelectedNode && dynamic_cast(m_SelectedNode->GetData())) { float fibThickness = m_Controls->m_FiberThicknessSlider->value() * 0.1; float currentThickness = 0; m_SelectedNode->GetFloatProperty("Fiber2DSliceThickness", currentThickness); if (fabs(fibThickness-currentThickness)<0.001) return; m_SelectedNode->SetProperty("Fiber2DSliceThickness", mitk::FloatProperty::New(fibThickness)); dynamic_cast(m_SelectedNode->GetData())->RequestUpdate2D(); mitk::RenderingManager::GetInstance()->RequestUpdateAll(); } } void QmitkControlVisualizationPropertiesView::FiberSlicingUpdateLabel(int value) { QString label = "Range %1 mm"; label = label.arg(value * 0.1); m_Controls->label_range->setText(label); FiberSlicingThickness2D(); } void QmitkControlVisualizationPropertiesView::SetFiberBundleOpacity(const itk::EventObject& /*e*/) { if(m_SelectedNode) { mitk::FiberBundleX::Pointer fib = dynamic_cast(m_SelectedNode->GetData()); fib->RequestUpdate(); mitk::RenderingManager::GetInstance()->RequestUpdateAll(); } } void QmitkControlVisualizationPropertiesView::SetFiberBundleCustomColor(const itk::EventObject& /*e*/) { if(m_SelectedNode && dynamic_cast(m_SelectedNode->GetData())) { float color[3]; m_SelectedNode->GetColor(color); mitk::FiberBundleX::Pointer fib = dynamic_cast(m_SelectedNode->GetData()); fib->SetFiberColors(color[0]*255, color[1]*255, color[2]*255); mitk::RenderingManager::GetInstance()->RequestUpdateAll(); } } void QmitkControlVisualizationPropertiesView::BundleRepresentationResetColoring() { if(m_SelectedNode && dynamic_cast(m_SelectedNode->GetData())) { mitk::FiberBundleX::Pointer fib = dynamic_cast(m_SelectedNode->GetData()); fib->DoColorCodingOrientationBased(); mitk::RenderingManager::GetInstance()->RequestUpdateAll(); } } void QmitkControlVisualizationPropertiesView::PlanarFigureFocus() { if(m_SelectedNode) { mitk::PlanarFigure* _PlanarFigure = 0; _PlanarFigure = dynamic_cast (m_SelectedNode->GetData()); if (_PlanarFigure && _PlanarFigure->GetPlaneGeometry()) { QmitkRenderWindow* selectedRenderWindow = 0; bool PlanarFigureInitializedWindow = false; QmitkRenderWindow* RenderWindow1 = this->GetActiveStdMultiWidget()->GetRenderWindow1(); if (m_SelectedNode->GetBoolProperty("PlanarFigureInitializedWindow", PlanarFigureInitializedWindow, RenderWindow1->GetRenderer())) { selectedRenderWindow = RenderWindow1; } QmitkRenderWindow* RenderWindow2 = this->GetActiveStdMultiWidget()->GetRenderWindow2(); if (!selectedRenderWindow && m_SelectedNode->GetBoolProperty( "PlanarFigureInitializedWindow", PlanarFigureInitializedWindow, RenderWindow2->GetRenderer())) { selectedRenderWindow = RenderWindow2; } QmitkRenderWindow* RenderWindow3 = this->GetActiveStdMultiWidget()->GetRenderWindow3(); if (!selectedRenderWindow && m_SelectedNode->GetBoolProperty( "PlanarFigureInitializedWindow", PlanarFigureInitializedWindow, RenderWindow3->GetRenderer())) { selectedRenderWindow = RenderWindow3; } QmitkRenderWindow* RenderWindow4 = this->GetActiveStdMultiWidget()->GetRenderWindow4(); if (!selectedRenderWindow && m_SelectedNode->GetBoolProperty( "PlanarFigureInitializedWindow", PlanarFigureInitializedWindow, RenderWindow4->GetRenderer())) { selectedRenderWindow = RenderWindow4; } const mitk::PlaneGeometry* _PlaneGeometry = _PlanarFigure->GetPlaneGeometry(); mitk::VnlVector normal = _PlaneGeometry->GetNormalVnl(); mitk::Geometry2D::ConstPointer worldGeometry1 = RenderWindow1->GetRenderer()->GetCurrentWorldGeometry2D(); mitk::PlaneGeometry::ConstPointer _Plane1 = dynamic_cast( worldGeometry1.GetPointer() ); mitk::VnlVector normal1 = _Plane1->GetNormalVnl(); mitk::Geometry2D::ConstPointer worldGeometry2 = RenderWindow2->GetRenderer()->GetCurrentWorldGeometry2D(); mitk::PlaneGeometry::ConstPointer _Plane2 = dynamic_cast( worldGeometry2.GetPointer() ); mitk::VnlVector normal2 = _Plane2->GetNormalVnl(); mitk::Geometry2D::ConstPointer worldGeometry3 = RenderWindow3->GetRenderer()->GetCurrentWorldGeometry2D(); mitk::PlaneGeometry::ConstPointer _Plane3 = dynamic_cast( worldGeometry3.GetPointer() ); mitk::VnlVector normal3 = _Plane3->GetNormalVnl(); normal[0] = fabs(normal[0]); normal[1] = fabs(normal[1]); normal[2] = fabs(normal[2]); normal1[0] = fabs(normal1[0]); normal1[1] = fabs(normal1[1]); normal1[2] = fabs(normal1[2]); normal2[0] = fabs(normal2[0]); normal2[1] = fabs(normal2[1]); normal2[2] = fabs(normal2[2]); normal3[0] = fabs(normal3[0]); normal3[1] = fabs(normal3[1]); normal3[2] = fabs(normal3[2]); double ang1 = angle(normal, normal1); double ang2 = angle(normal, normal2); double ang3 = angle(normal, normal3); if(ang1 < ang2 && ang1 < ang3) { selectedRenderWindow = RenderWindow1; } else { if(ang2 < ang3) { selectedRenderWindow = RenderWindow2; } else { selectedRenderWindow = RenderWindow3; } } // make node visible if (selectedRenderWindow) { const mitk::Point3D& centerP = _PlaneGeometry->GetOrigin(); selectedRenderWindow->GetSliceNavigationController()->ReorientSlices( centerP, _PlaneGeometry->GetNormal()); } } // set interactor for new node (if not already set) mitk::PlanarFigureInteractor::Pointer figureInteractor = dynamic_cast(m_SelectedNode->GetDataInteractor().GetPointer()); if(figureInteractor.IsNull()) { figureInteractor = mitk::PlanarFigureInteractor::New(); us::Module* planarFigureModule = us::ModuleRegistry::GetModule( "MitkPlanarFigure" ); figureInteractor->LoadStateMachine("PlanarFigureInteraction.xml", planarFigureModule ); figureInteractor->SetEventConfig( "PlanarFigureConfig.xml", planarFigureModule ); figureInteractor->SetDataNode( m_SelectedNode ); } m_SelectedNode->SetProperty("planarfigure.iseditable",mitk::BoolProperty::New(true)); } } void QmitkControlVisualizationPropertiesView::SetInteractor() { typedef std::vector Container; Container _NodeSet = this->GetDataManagerSelection(); mitk::DataNode* node = 0; mitk::FiberBundleX* bundle = 0; mitk::FiberBundleInteractor::Pointer bundleInteractor = 0; // finally add all nodes to the model for(Container::const_iterator it=_NodeSet.begin(); it!=_NodeSet.end() ; it++) { node = const_cast(*it); bundle = dynamic_cast(node->GetData()); if(bundle) { bundleInteractor = dynamic_cast(node->GetInteractor()); if(bundleInteractor.IsNotNull()) mitk::GlobalInteraction::GetInstance()->RemoveInteractor(bundleInteractor); if(!m_Controls->m_Crosshair->isChecked()) { m_Controls->m_Crosshair->setChecked(false); this->GetActiveStdMultiWidget()->GetRenderWindow4()->setCursor(Qt::ArrowCursor); m_CurrentPickingNode = 0; } else { m_Controls->m_Crosshair->setChecked(true); bundleInteractor = mitk::FiberBundleInteractor::New("FiberBundleInteractor", node); mitk::GlobalInteraction::GetInstance()->AddInteractor(bundleInteractor); this->GetActiveStdMultiWidget()->GetRenderWindow4()->setCursor(Qt::CrossCursor); m_CurrentPickingNode = node; } } } } +void QmitkControlVisualizationPropertiesView::TubeRadiusChanged() +{ + if(m_SelectedNode && dynamic_cast(m_SelectedNode->GetData())) + { + float newRadius = m_Controls->m_TubeWidth->value(); + m_SelectedNode->SetFloatProperty("TubeRadius", newRadius); + mitk::RenderingManager::GetInstance()->RequestUpdateAll(); + } +} + void QmitkControlVisualizationPropertiesView::LineWidthChanged() { if(m_SelectedNode && dynamic_cast(m_SelectedNode->GetData())) { int newWidth = m_Controls->m_LineWidth->value(); int currentWidth = 0; m_SelectedNode->GetIntProperty("LineWidth", currentWidth); if (currentWidth==newWidth) return; m_SelectedNode->SetIntProperty("LineWidth", newWidth); dynamic_cast(m_SelectedNode->GetData())->RequestUpdate2D(); dynamic_cast(m_SelectedNode->GetData())->RequestUpdate3D(); mitk::RenderingManager::GetInstance()->RequestUpdateAll(); } } void QmitkControlVisualizationPropertiesView::Welcome() { berry::PlatformUI::GetWorkbench()->GetIntroManager()->ShowIntro( GetSite()->GetWorkbenchWindow(), false); } diff --git a/Plugins/org.mitk.gui.qt.diffusionimaging/src/internal/QmitkControlVisualizationPropertiesView.h b/Plugins/org.mitk.gui.qt.diffusionimaging/src/internal/QmitkControlVisualizationPropertiesView.h index 9c42cd9d08..1b890d9d1c 100644 --- a/Plugins/org.mitk.gui.qt.diffusionimaging/src/internal/QmitkControlVisualizationPropertiesView.h +++ b/Plugins/org.mitk.gui.qt.diffusionimaging/src/internal/QmitkControlVisualizationPropertiesView.h @@ -1,153 +1,154 @@ /*=================================================================== 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 _QMITKControlVisualizationPropertiesView_H_INCLUDED #define _QMITKControlVisualizationPropertiesView_H_INCLUDED #include #include #include "berryISelectionListener.h" #include "berryIStructuredSelection.h" #include "berryISizeProvider.h" #include "ui_QmitkControlVisualizationPropertiesViewControls.h" #include "mitkEnumerationProperty.h" /*! * \ingroup org_mitk_gui_qt_diffusionquantification_internal * * \brief QmitkControlVisualizationPropertiesView * * Document your class here. * * \sa QmitkFunctionality */ class QmitkControlVisualizationPropertiesView : public QmitkFunctionality//, public berry::ISizeProvider { friend struct CvpSelListener; // this is needed for all Qt objects that should have a MOC object (everything that derives from QObject) Q_OBJECT public: static const std::string VIEW_ID; QmitkControlVisualizationPropertiesView(); QmitkControlVisualizationPropertiesView(const QmitkControlVisualizationPropertiesView& other); virtual ~QmitkControlVisualizationPropertiesView(); virtual void CreateQtPartControl(QWidget *parent); /// \brief Creation of the connections of main and control widget virtual void CreateConnections(); /// \brief Called when the functionality is activated virtual void Activated(); virtual void Deactivated(); virtual void StdMultiWidgetAvailable (QmitkStdMultiWidget &stdMultiWidget); virtual void StdMultiWidgetNotAvailable(); protected slots: void VisibleOdfsON_S(); void VisibleOdfsON_T(); void VisibleOdfsON_C(); void ShowMaxNumberChanged(); void NormalizationDropdownChanged(int); void ScalingFactorChanged(double); void AdditionalScaling(int); void ScalingCheckbox(); void OnThickSlicesModeSelected( QAction* action ); void OnTSNumChanged(int num); void BundleRepresentationResetColoring(); void PlanarFigureFocus(); void Fiber2DfadingEFX(); void FiberSlicingThickness2D(); void FiberSlicingUpdateLabel(int); void LineWidthChanged(); + void TubeRadiusChanged(); void SetInteractor(); void Welcome(); protected: virtual void NodeRemoved(const mitk::DataNode* node); /// \brief called by QmitkFunctionality when DataManager's selection has changed virtual void OnSelectionChanged( std::vector nodes ); virtual void NodeAdded(const mitk::DataNode *node); void SetFiberBundleCustomColor(const itk::EventObject& /*e*/); void SetFiberBundleOpacity(const itk::EventObject& /*e*/); bool IsPlaneRotated(); void SliceRotation(const itk::EventObject&); Ui::QmitkControlVisualizationPropertiesViewControls* m_Controls; QmitkStdMultiWidget* m_MultiWidget; berry::ISelectionListener::Pointer m_SelListener; berry::IStructuredSelection::ConstPointer m_CurrentSelection; mitk::DataNode::Pointer m_NodeUsedForOdfVisualization; QIcon* m_IconTexOFF; QIcon* m_IconTexON; QIcon* m_IconGlyOFF_T; QIcon* m_IconGlyON_T; QIcon* m_IconGlyOFF_C; QIcon* m_IconGlyON_C; QIcon* m_IconGlyOFF_S; QIcon* m_IconGlyON_S; bool m_TexIsOn; bool m_GlyIsOn_T; bool m_GlyIsOn_C; bool m_GlyIsOn_S; int currentThickSlicesMode; QLabel* m_TSLabel; QMenu* m_MyMenu; // for planarfigure and bundle handling: mitk::DataNode::Pointer m_SelectedNode; mitk::DataNode* m_CurrentPickingNode; unsigned long m_SlicesRotationObserverTag1; unsigned long m_SlicesRotationObserverTag2; unsigned long m_FiberBundleObserverTag; unsigned long m_FiberBundleObserveOpacityTag; mitk::ColorProperty::Pointer m_Color; mitk::FloatProperty::Pointer m_Opacity; }; #endif // _QMITKControlVisualizationPropertiesView_H_INCLUDED diff --git a/Plugins/org.mitk.gui.qt.diffusionimaging/src/internal/QmitkControlVisualizationPropertiesViewControls.ui b/Plugins/org.mitk.gui.qt.diffusionimaging/src/internal/QmitkControlVisualizationPropertiesViewControls.ui index b9366d9c7d..30c0704d5d 100644 --- a/Plugins/org.mitk.gui.qt.diffusionimaging/src/internal/QmitkControlVisualizationPropertiesViewControls.ui +++ b/Plugins/org.mitk.gui.qt.diffusionimaging/src/internal/QmitkControlVisualizationPropertiesViewControls.ui @@ -1,702 +1,722 @@ QmitkControlVisualizationPropertiesViewControls 0 0 567 619 0 100 0 0 QmitkTemplate 0 0 0 0 QFrame::NoFrame QFrame::Raised 0 0 0 0 0 0 QFrame::NoFrame QFrame::Raised 0 0 0 0 Multislice Projection MIP QToolButton::MenuButtonPopup Qt::NoArrow QFrame::NoFrame QFrame::Plain 0 0 0 0 Toggle visibility of ODF glyphs (axial) :/QmitkDiffusionImaging/glyphsoff_T.png :/QmitkDiffusionImaging/glyphson_T.png:/QmitkDiffusionImaging/glyphsoff_T.png true false Toggle visibility of ODF glyphs (sagittal) :/QmitkDiffusionImaging/glyphsoff_S.png :/QmitkDiffusionImaging/glyphson_S.png:/QmitkDiffusionImaging/glyphsoff_S.png true false Toggle visibility of ODF glyphs (coronal) :/QmitkDiffusionImaging/glyphsoff_C.png :/QmitkDiffusionImaging/glyphson_C.png:/QmitkDiffusionImaging/glyphsoff_C.png true false #Glyphs 9999 Qt::Horizontal 20 20 QFrame::NoFrame QFrame::Raised 0 0 0 0 0 QFrame::NoFrame QFrame::Raised 0 0 0 0 6 0 QFrame::NoFrame QFrame::Plain 0 0 0 0 false None By GFA By ASR * Additional scaling factor 3 999999999.000000000000000 0.100000000000000 1.000000000000000 Scaling QFrame::NoFrame QFrame::Plain 0 0 0 0 0 ODF normalization false Min-Max Max None QFrame::NoFrame QFrame::Raised 0 0 0 0 QFrame::NoFrame QFrame::Raised 0 0 0 0 Reset to Default Coloring :/QmitkDiffusionImaging/reset.png:/QmitkDiffusionImaging/reset.png Position Crosshair by 3D-Click :/QmitkDiffusionImaging/crosshair.png:/QmitkDiffusionImaging/crosshair.png true false 2D Fiberfading on/off Qt::Horizontal 40 20 QFrame::NoFrame QFrame::Raised 0 0 0 0 2D Clipping 100 10 10 10 Qt::Horizontal 90 0 10000 16777215 Range QFrame::NoFrame QFrame::Raised - + 0 0 0 0 - + + + Tube Width + + + + + Line Width - + 1 10 + + + + Fiber tube radius in mm. If > 0, fibers are rendered as tubes in 3D. + + + 4 + + + 0.100000000000000 + + + 50 false false <!DOCTYPE HTML PUBLIC "-//W3C//DTD HTML 4.0//EN" "http://www.w3.org/TR/REC-html40/strict.dtd"> <html><head><meta name="qrichtext" content="1" /><style type="text/css"> p, li { white-space: pre-wrap; } </style></head><body style=" font-family:'Ubuntu'; font-size:11pt; font-weight:400; font-style:normal;"> <p align="center" style=" margin-top:0px; margin-bottom:0px; margin-left:0px; margin-right:0px; -qt-block-indent:0; text-indent:0px;"><span style=" color:#ff0000;">One or more slices are rotated. ODF Visualisation is not possible in rotated planes. Use 'Reinit' on the image node to reset. </span></p></body></html> Qt::AutoText true Qt::Vertical 20 40 QmitkDataStorageComboBox.h