void mitk::TimeGeometry::UpdateBoundingBox () { assert(m_BoundingBox.IsNotNull()); typedef BoundingBox::PointsContainer ContainerType; unsigned long lastModifiedTime = 0; unsigned long currentModifiedTime = 0; ContainerType::Pointer points = ContainerType::New(); points->reserve(2*CountTimeSteps()); for (TimeStepType step = 0; step <CountTimeSteps(); ++step) { currentModifiedTime = GetGeometryForTimeStep(step)->GetMTime(); if (currentModifiedTime > lastModifiedTime) lastModifiedTime = currentModifiedTime; for (int i=0; i < 8; ++i) { Point3D cornerPoint = GetGeometryForTimeStep(step)->GetCornerPoint(i); points->push_back(cornerPoint); } } m_BoundingBox->SetPoints(points); m_BoundingBox->ComputeBoundingBox(); if (this->GetMTime() < lastModifiedTime) this->Modified(); }
mitk::TimeGeometry::TimeGeometry() : m_BoundingBox(BoundingBox::New()) { typedef BoundingBox::PointsContainer ContainerType; ContainerType::Pointer points = ContainerType::New(); m_BoundingBox->SetPoints(points.GetPointer()); }
void TractsToDWIImageFilter::GenerateParticleGrid() { MITK_INFO << "Generating particle grid from fiber bundle"; m_ParticleGrid = mitk::ParticleGrid::New(); float* bounds = m_FiberBundle->GetBounds(); int size[] = {(int)bounds[0],(int)bounds[1],(int)bounds[2]}; m_ParticleGrid->SetSize(size); typedef itk::Point<float,3> ContainerPointType; //no need to init, is no smartpointer typedef itk::VectorContainer<unsigned int, ContainerPointType> ContainerTractType; typedef itk::VectorContainer< unsigned int, ContainerTractType::Pointer > ContainerType; //init via smartpointer ContainerType::Pointer tractContainer = m_FiberBundle->GetTractContainer(); for (int i=0; i<tractContainer->Size(); i++) { ContainerTractType::Pointer tract = tractContainer->GetElement(i); for (int j=0; j<tract->Size(); j++) { vnl_vector_fixed<float,3> pos = tract->GetElement(j).GetVnlVector(); vnl_vector_fixed<float,3> next; vnl_vector_fixed<float,3> dir; if (j<tract->Size()-1) next = tract->GetElement(j+1).GetVnlVector(); else next = tract->GetElement(j-1).GetVnlVector(); dir = next-pos; dir.normalize(); mitk::Particle* p = new mitk::Particle(); p->SetPosition(pos); p->SetDirection(dir); m_ParticleGrid->AddParticle(p); } } }
void TractsToFiberEndingsImageFilter< TInputImage, TOutputPixelType > ::GenerateData() { MITK_INFO << "Generating 2D fiber endings image"; if(&typeid(TOutputPixelType) != &typeid(unsigned char)) { MITK_INFO << "Only 'unsigned char' and 'itk::RGBAPixel<unsigned char> supported as OutputPixelType"; return; } mitk::Geometry3D::Pointer geometry = m_FiberBundle->GetGeometry(); typename OutputImageType::Pointer outImage = static_cast< OutputImageType * >(this->ProcessObject::GetOutput(0)); outImage->SetSpacing( geometry->GetSpacing()/m_UpsamplingFactor ); // Set the image spacing mitk::Point3D origin = geometry->GetOrigin(); mitk::Point3D indexOrigin; geometry->WorldToIndex(origin, indexOrigin); indexOrigin[0] = indexOrigin[0] - .5 * (1.0-1.0/m_UpsamplingFactor); indexOrigin[1] = indexOrigin[1] - .5 * (1.0-1.0/m_UpsamplingFactor); indexOrigin[2] = indexOrigin[2] - .5 * (1.0-1.0/m_UpsamplingFactor); mitk::Point3D newOrigin; geometry->IndexToWorld(indexOrigin, newOrigin); outImage->SetOrigin( newOrigin ); // Set the image origin itk::Matrix<double, 3, 3> matrix; for (int i=0; i<3; i++) for (int j=0; j<3; j++) matrix[j][i] = geometry->GetMatrixColumn(i)[j]/geometry->GetSpacing().GetElement(i); outImage->SetDirection( matrix ); // Set the image direction float* bounds = m_FiberBundle->GetBounds(); ImageRegion<3> upsampledRegion; upsampledRegion.SetSize(0, bounds[0]); upsampledRegion.SetSize(1, bounds[1]); upsampledRegion.SetSize(2, bounds[2]); typename InputImageType::RegionType::SizeType upsampledSize = upsampledRegion.GetSize(); for (unsigned int n = 0; n < 3; n++) { upsampledSize[n] = upsampledSize[n] * m_UpsamplingFactor; } upsampledRegion.SetSize( upsampledSize ); outImage->SetRegions( upsampledRegion ); outImage->Allocate(); int w = upsampledSize[0]; int h = upsampledSize[1]; int d = upsampledSize[2]; unsigned char* accuout; accuout = reinterpret_cast<unsigned char*>(outImage->GetBufferPointer()); for (int i=0; i<w*h*d; i++) accuout[i] = 0; typedef mitk::FiberBundle::ContainerTractType ContainerTractType; typedef mitk::FiberBundle::ContainerType ContainerType; typedef mitk::FiberBundle::ContainerPointType ContainerPointType; ContainerType::Pointer tractContainer = m_FiberBundle->GetTractContainer(); for (int i=0; i<tractContainer->Size(); i++) { ContainerTractType::Pointer tract = tractContainer->GetElement(i); int tractsize = tract->Size(); if (tractsize>1) { ContainerPointType start = tract->GetElement(0); ContainerPointType end = tract->GetElement(tractsize-1); start[0] = (start[0]+0.5) * m_UpsamplingFactor; start[1] = (start[1]+0.5) * m_UpsamplingFactor; start[2] = (start[2]+0.5) * m_UpsamplingFactor; // int coordinates inside image? int px = (int) (start[0]); if (px < 0 || px >= w) continue; int py = (int) (start[1]); if (py < 0 || py >= h) continue; int pz = (int) (start[2]); if (pz < 0 || pz >= d) continue; accuout[( px + w*(py + h*pz ))] += 1; end[0] = (end[0]+0.5) * m_UpsamplingFactor; end[1] = (end[1]+0.5) * m_UpsamplingFactor; end[2] = (end[2]+0.5) * m_UpsamplingFactor; // int coordinates inside image? px = (int) (end[0]); if (px < 0 || px >= w) continue; py = (int) (end[1]); if (py < 0 || py >= h) continue; pz = (int) (end[2]); if (pz < 0 || pz >= d) continue; accuout[( px + w*(py + h*pz ))] += 1; } } MITK_INFO << "2D fiber endings image generated"; }
void FiberBundleReader::GenerateOutputInformation() { m_OutputCache = OutputType::New(); std::string ext = itksys::SystemTools::GetFilenameLastExtension(m_FileName); ext = itksys::SystemTools::LowerCase(ext); if ( m_FileName == "") { } else if (ext == ".fib") { try { TiXmlDocument doc( m_FileName ); doc.LoadFile(); TiXmlHandle hDoc(&doc); TiXmlElement* pElem; TiXmlHandle hRoot(0); pElem = hDoc.FirstChildElement().Element(); // save this for later hRoot = TiXmlHandle(pElem); pElem = hRoot.FirstChildElement(FiberBundleReader::XML_GEOMETRY).Element(); // read geometry mitk::Geometry3D::Pointer geometry = mitk::Geometry3D::New(); // read origin mitk::Point3D origin; double temp = 0; pElem->Attribute(FiberBundleReader::XML_ORIGIN_X, &temp); origin[0] = temp; pElem->Attribute(FiberBundleReader::XML_ORIGIN_Y, &temp); origin[1] = temp; pElem->Attribute(FiberBundleReader::XML_ORIGIN_Z, &temp); origin[2] = temp; geometry->SetOrigin(origin); // read spacing float spacing[3]; pElem->Attribute(FiberBundleReader::XML_SPACING_X, &temp); spacing[0] = temp; pElem->Attribute(FiberBundleReader::XML_SPACING_Y, &temp); spacing[1] = temp; pElem->Attribute(FiberBundleReader::XML_SPACING_Z, &temp); spacing[2] = temp; geometry->SetSpacing(spacing); // read transform vtkMatrix4x4* m = vtkMatrix4x4::New(); pElem->Attribute(FiberBundleReader::XML_MATRIX_XX, &temp); m->SetElement(0,0,temp); pElem->Attribute(FiberBundleReader::XML_MATRIX_XY, &temp); m->SetElement(1,0,temp); pElem->Attribute(FiberBundleReader::XML_MATRIX_XZ, &temp); m->SetElement(2,0,temp); pElem->Attribute(FiberBundleReader::XML_MATRIX_YX, &temp); m->SetElement(0,1,temp); pElem->Attribute(FiberBundleReader::XML_MATRIX_YY, &temp); m->SetElement(1,1,temp); pElem->Attribute(FiberBundleReader::XML_MATRIX_YZ, &temp); m->SetElement(2,1,temp); pElem->Attribute(FiberBundleReader::XML_MATRIX_ZX, &temp); m->SetElement(0,2,temp); pElem->Attribute(FiberBundleReader::XML_MATRIX_ZY, &temp); m->SetElement(1,2,temp); pElem->Attribute(FiberBundleReader::XML_MATRIX_ZZ, &temp); m->SetElement(2,2,temp); m->SetElement(0,3,origin[0]); m->SetElement(1,3,origin[1]); m->SetElement(2,3,origin[2]); m->SetElement(3,3,1); geometry->SetIndexToWorldTransformByVtkMatrix(m); // read bounds float bounds[] = {0, 0, 0, 0, 0, 0}; pElem->Attribute(FiberBundleReader::XML_SIZE_X, &temp); bounds[1] = temp; pElem->Attribute(FiberBundleReader::XML_SIZE_Y, &temp); bounds[3] = temp; pElem->Attribute(FiberBundleReader::XML_SIZE_Z, &temp); bounds[5] = temp; geometry->SetFloatBounds(bounds); // read bounds float bounds2[] = {0, 0, 0}; bounds2[0] = bounds[1]; bounds2[1] = bounds[3]; bounds2[2] = bounds[5]; m_OutputCache->SetBounds(bounds2); geometry->SetImageGeometry(true); m_OutputCache->SetGeometry(geometry); // generate tract container ContainerType::Pointer tractContainer = ContainerType::New(); int fiberID = 0; pElem = hRoot.FirstChildElement(FiberBundleReader::XML_FIBER_BUNDLE).FirstChild().Element(); for( pElem; pElem; pElem=pElem->NextSiblingElement()) { TiXmlElement* pElem2 = pElem->FirstChildElement(); ContainerTractType::Pointer tract = ContainerTractType::New(); for( pElem2; pElem2; pElem2=pElem2->NextSiblingElement()) { ContainerPointType point; pElem2->Attribute(FiberBundleReader::XML_POS_X, &temp); point[0] = temp; pElem2->Attribute(FiberBundleReader::XML_POS_Y, &temp); point[1] = temp; pElem2->Attribute(FiberBundleReader::XML_POS_Z, &temp); point[2] = temp; tract->InsertElement(tract->Size(), point); } pElem->Attribute(FiberBundleReader::XML_ID, &fiberID); tractContainer->CreateIndex(fiberID); tractContainer->SetElement(fiberID, tract); } m_OutputCache->addTractContainer(tractContainer); m_OutputCache->initFiberGroup(); MITK_INFO << "Fiber bundle read"; } catch(...) { MITK_INFO << "Could not read file "; } } else if (ext == ".vfib") { // generate tract container ContainerType::Pointer tractContainer = ContainerType::New(); mitk::Geometry3D::Pointer geometry = mitk::Geometry3D::New(); ///We create a Generic Reader to test de .vtk/ vtkDataReader *chooser=vtkDataReader::New(); chooser->SetFileName(m_FileName.c_str() ); if( chooser->IsFilePolyData()) { vtkPolyDataReader *reader = vtkPolyDataReader::New(); reader->SetFileName( m_FileName.c_str() ); reader->Update(); if ( reader->GetOutput() != NULL ) { vtkPolyData* output = reader->GetOutput(); output->ComputeBounds(); double bounds[3]; output->GetBounds(bounds); double center[3]; output->GetCenter(center); Point3D origin; origin.SetElement(0, -center[0]); origin.SetElement(1, -center[1]); origin.SetElement(2, -center[2]); MITK_INFO << origin; mitk::Surface::Pointer surf = mitk::Surface::New(); surf->SetVtkPolyData(output); mitk::Geometry3D* geom = surf->GetGeometry(); //geom->SetOrigin(origin); geom->SetImageGeometry(true); m_OutputCache->SetBounds(bounds); m_OutputCache->SetGeometry(geom); vtkCellArray* cells = output->GetLines(); cells->InitTraversal(); for (int i=0; i<output->GetNumberOfCells(); i++) { ContainerTractType::Pointer tract = ContainerTractType::New(); vtkCell* cell = output->GetCell(i); int p = cell->GetNumberOfPoints(); vtkPoints* points = cell->GetPoints(); for (int j=0; j<p; j++) { double p[3]; points->GetPoint(j, p); ContainerPointType point; point[0] = p[0]; point[1] = p[1]; point[2] = p[2]; tract->InsertElement(tract->Size(), point); } tractContainer->InsertElement(i, tract); } } reader->Delete(); } chooser->Delete(); m_OutputCache->addTractContainer(tractContainer); m_OutputCache->initFiberGroup(); MITK_INFO << "Fiber bundle read"; } }