+vtkImageData* wxContourMainFrame::getImageData(){
+ return _theViewPanel->getImageData();
+}
+
+void wxContourMainFrame::onSegmentationOneSliceITK(wxString distance, wxString sigma, wxString alfa, wxString beta, wxString propagation, wxString iterations, wxString inflation)
+{
+ //JCP 20-10-08 Undo redo implementation
+ saveState();
+ //JCP 20-10-08 Undo redo implementation
+
+ wxBusyCursor wait;
+ int x = _theViewPanel->GetX();
+ int y = _theViewPanel->GetY();
+ int z = _theViewPanel->GetZ();
+ SegmentationOneSliceITK( x,y,z,distance, sigma, alfa, beta, propagation, iterations, inflation);
+ RefreshInterface();
+}
+
+void wxContourMainFrame::SegmentationOneSliceITK(int x, int y, int z, wxString distanc, wxString sigm, wxString alf, wxString bet, wxString prop, wxString iter, wxString inflation)
+{
+ int typeofcontour = 1;
+ //Image Data
+ vtkImageData *imagedata = getImageData();
+
+ //Tipo de pixeles a utilizar internamente en ITK
+ typedef float InternalPixelType;
+ const unsigned int Dimension = 2;
+ typedef itk::Image< InternalPixelType, Dimension > InternalImageType;
+
+ //Tipo de pixeles de salida 1
+ typedef unsigned char OutputPixelType;
+ typedef itk::Image< OutputPixelType, Dimension > OutputImageType;
+
+ //Tipo de pixeles de salida 2
+ typedef unsigned short OutputPixelType2;
+ typedef itk::Image< OutputPixelType2, Dimension > OutputImageType2;
+
+ //DefiniciÛn del thresholder
+ typedef itk::BinaryThresholdImageFilter<
+ InternalImageType,
+ OutputImageType > ThresholdingFilterType;
+
+ //DefiniciÛn del primer filtro de conversiÛn de pixeles
+ typedef itk::CastImageFilter<
+ OutputImageType, OutputImageType2 > CastFilterType;
+
+ //DefiniciÛn del segundo tipo de conversiÛn de pixeles
+ typedef itk::CastImageFilter<
+ OutputImageType2, InternalImageType > CastFilterType2;
+
+ //Tercer tipo de conversiÛn
+ typedef itk::RescaleIntensityImageFilter<
+ InternalImageType,
+ OutputImageType > CastFilterType3;
+
+ //Cuarto tipo de conversiÛn
+ typedef itk::RescaleIntensityImageFilter<
+ OutputImageType,
+ OutputImageType > CastFilterType4;
+
+ ThresholdingFilterType::Pointer thresholder = ThresholdingFilterType::New();
+
+ thresholder->SetLowerThreshold( 0.0 );
+ thresholder->SetUpperThreshold( 128 );
+
+ thresholder->SetOutsideValue( 255 );
+ thresholder->SetInsideValue( 0 );
+
+ //DefinciÛn de conexiÛnes entre VTK e ITK y el writer
+ typedef itk::VTKImageToImageFilter<OutputImageType2> ConnectorType;
+ typedef itk::ImageToVTKImageFilter<OutputImageType> ConnectorType2;
+ typedef itk::ImageFileWriter< OutputImageType > WriterType;
+
+ ConnectorType::Pointer connector= ConnectorType::New();
+ ConnectorType2::Pointer connector2= ConnectorType2::New();
+
+
+ CastFilterType::Pointer filter=CastFilterType::New();
+ CastFilterType2::Pointer filter2=CastFilterType2::New();
+
+ connector->SetInput( imagedata );
+ filter2->SetInput(connector->GetOutput());
+
+ typedef itk::CurvatureAnisotropicDiffusionImageFilter<
+ InternalImageType,
+ InternalImageType > SmoothingFilterType;
+
+ SmoothingFilterType::Pointer smoothing = SmoothingFilterType::New();
+
+ typedef itk::GradientMagnitudeRecursiveGaussianImageFilter<
+ InternalImageType,
+ InternalImageType > GradientFilterType;
+
+ typedef itk::SigmoidImageFilter<
+ InternalImageType,
+ InternalImageType > SigmoidFilterType;
+
+ GradientFilterType::Pointer gradientMagnitude = GradientFilterType::New();
+
+ SigmoidFilterType::Pointer sigmoid = SigmoidFilterType::New();
+
+ sigmoid->SetOutputMinimum( 0.0 );
+ sigmoid->SetOutputMaximum( 255.0 );
+
+
+ typedef itk::FastMarchingImageFilter<
+ InternalImageType,
+ InternalImageType > FastMarchingFilterType;
+
+
+ FastMarchingFilterType::Pointer fastMarching = FastMarchingFilterType::New();
+
+ typedef itk::GeodesicActiveContourLevelSetImageFilter< InternalImageType,
+ InternalImageType > GeodesicActiveContourFilterType;
+ GeodesicActiveContourFilterType::Pointer geodesicActiveContour =
+ GeodesicActiveContourFilterType::New();
+
+ typedef itk::ZeroCrossingImageFilter<
+ InternalImageType,
+ InternalImageType > ZeroCrossingFilterType;
+ ZeroCrossingFilterType::Pointer zeroCrossing =
+ ZeroCrossingFilterType::New();
+
+ const double propagationScaling = atof( crea::wx2std(prop).c_str() );
+
+ geodesicActiveContour->SetPropagationScaling( propagationScaling );
+ geodesicActiveContour->SetCurvatureScaling( 1.0 );
+ geodesicActiveContour->SetAdvectionScaling( 1.0 );
+
+ geodesicActiveContour->SetMaximumRMSError( 0.02 );
+ int it=atoi( crea::wx2std(iter).c_str() );
+ geodesicActiveContour->SetNumberOfIterations( it );
+
+ smoothing->SetInput( filter2->GetOutput() );
+ gradientMagnitude->SetInput( smoothing->GetOutput() );
+ sigmoid->SetInput( gradientMagnitude->GetOutput() );
+ fastMarching->SetInput( sigmoid->GetOutput() );
+ geodesicActiveContour->SetInput( fastMarching->GetOutput() );
+ geodesicActiveContour->SetFeatureImage( sigmoid->GetOutput() );
+
+ zeroCrossing->SetInput( geodesicActiveContour->GetOutput() );
+ //thresholder->SetInput( zeroCrossing->GetOutput() );
+ thresholder->SetInput( geodesicActiveContour->GetOutput() );
+ connector2->SetInput( thresholder->GetOutput() );
+
+
+ smoothing->SetTimeStep( 0.125 );
+ smoothing->SetNumberOfIterations( 5 );
+ smoothing->SetConductanceParameter( 9.0 );
+
+
+ const double sigma = atof( crea::wx2std(sigm).c_str() );
+ gradientMagnitude->SetSigma( sigma );
+
+ const double alpha = atof( crea::wx2std(alf).c_str() );
+ const double beta = atof( crea::wx2std(bet).c_str() );
+
+ sigmoid->SetAlpha( alpha );
+ sigmoid->SetBeta( beta );
+
+ typedef FastMarchingFilterType::NodeContainer NodeContainer;
+ typedef FastMarchingFilterType::NodeType NodeType;
+
+ NodeContainer::Pointer seeds = NodeContainer::New();
+
+ InternalImageType::IndexType seedPosition;
+ seedPosition[0] = x;
+ seedPosition[1] = y;
+
+ const double initialDistance = atof( crea::wx2std(distanc).c_str() );
+
+ NodeType node;
+
+ const double seedValue = - initialDistance;
+
+ node.SetValue( seedValue );
+ node.SetIndex( seedPosition );
+
+ seeds->Initialize();
+ seeds->InsertElement( 0, node );
+
+ fastMarching->SetTrialPoints( seeds );
+
+ fastMarching->SetSpeedConstant( 1.0 );
+
+ fastMarching->SetOutputSize(
+ connector->GetOutput()->GetBufferedRegion().GetSize() );
+
+ fastMarching->SetStoppingValue( 800 );
+ try
+ {
+
+ connector2->Update();
+ vtkImageData *idata = connector2->GetOutput();
+
+ vtkMarchingContourFilter* cntVTK = vtkMarchingContourFilter::New( );
+
+ cntVTK->SetInput( idata );
+
+ cntVTK->SetNumberOfContours( 1 );
+ cntVTK->SetValue( 0, 255 );
+ cntVTK->Update( );
+ cntVTK->UpdateInformation();
+
+ vtkCleanPolyData* cpd = vtkCleanPolyData::New( );
+ cpd->SetInput( cntVTK->GetOutput( ) );
+ cpd->Update( );
+ cpd->UpdateInformation();
+
+ vtkPolyDataConnectivityFilter* conn = vtkPolyDataConnectivityFilter::New( );
+ conn->SetExtractionModeToLargestRegion( );
+ conn->SetInput( cpd->GetOutput( ) );
+ conn->Update( );
+ conn->UpdateInformation();
+
+ vtkStripper* vtkstripper = vtkStripper::New( );
+ vtkstripper->SetInput( conn->GetOutput() );
+ vtkstripper->Update();
+ vtkstripper->UpdateInformation();
+
+
+ vtkPolyData* polyDataResult = cntVTK->GetOutput();
+ //std::cout<<"Points "<<polyDataResult->GetNumberOfPoints()<<std::endl;
+ polyDataResult->Update( );
+ polyDataResult->UpdateInformation();
+
+ //EED
+ /*
+ ofstream myfile;
+ myfile.open ("C:/Creatis/example.txt");
+ myfile << "\n";
+ polyDataResult->Print(myfile);
+ myfile << "-------------------------------------\n";
+ polyDataResult->GetLines()->Print(myfile);
+ myfile.close();*/
+
+ cntVTK -> Delete();
+ cpd -> Delete();
+ conn -> Delete();
+
+
+ //--Calculating control points
+
+ std::vector<double> vecX;
+ std::vector<double> vecY;
+ std::vector<double> vecXo;
+ std::vector<double> vecYo;
+ std::vector<double>::iterator vecXoi;
+ std::vector<double>::iterator vecYoi;
+ std::vector<double> vecZ;
+
+ std::vector<double> vecCtrlPointX;
+ std::vector<double> vecCtrlPointY;
+ std::vector<double> vecCtrlPointZ;
+
+
+ double *p;
+ double xAct=0;
+ double yAct=0;
+ int ii,size=polyDataResult->GetNumberOfPoints();
+ ofstream myfile;
+ myfile.open ("C:/Creatis/example2.txt");
+
+ size=polyDataResult->GetNumberOfPoints();
+ for (ii=0;ii<size;ii++)
+ {
+ if(ii==0)
+ {
+ xAct=x;
+ yAct=y;
+ }
+ p = polyDataResult->GetPoint(ii);
+ double x=p[0];
+ double y=p[1];
+ /*if(fabs(yAct-y)>20)
+ {
+ if((xAct-x)>1 || (xAct-x)<-1)
+ {
+ vecX.push_back( p[0] );
+ vecY.push_back( p[1] );
+ myfile <<p[0]<<","<<p[1]<<"\n";
+ std::cout<<" x Anterior "<<xAct<<" x actual "<<x<<std::endl;
+ std::cout<<" y Anterior "<<yAct<<" y actual "<<y<<std::endl;
+ std::cout<<" x "<<p[0]<<" y "<<p[1]<<std::endl;
+ vecZ.push_back( 900 );
+ xAct=x;
+ yAct=y;
+ }
+ else
+ {
+ vecXo.push_back(p[0]);
+ vecYo.push_back(p[1]);
+ }
+
+ }
+ else*/ if(fabs(xAct-x)>11)
+ {
+ vecXo.push_back(p[0]);
+ vecYo.push_back(p[1]);
+ }
+ else
+ {
+ vecX.push_back( p[0] );
+ myfile <<p[0]<<","<<p[1]<<"\n";
+ //std::cout<<" x Anterior "<<xAct<<" x actual "<<x<<std::endl;
+ //std::cout<<" y Anterior "<<yAct<<" y actual "<<y<<std::endl;
+ //std::cout<<" x "<<p[0]<<" y "<<p[1]<<std::endl;
+ vecY.push_back( p[1] );
+ vecZ.push_back( 900 );
+ xAct=x;
+ yAct=y;
+ }
+
+
+ }
+
+ while(!vecXo.empty())
+ {
+ vecX.push_back(vecXo.back());
+ //std::cout<<" x Siguiente "<<vecXo.back();
+ vecXo.pop_back();
+ vecZ.push_back( 900 );
+ }
+ while(!vecYo.empty())
+ {
+ vecY.push_back(vecYo.back());
+ vecYo.pop_back();
+ }
+ myfile.close();
+
+ /*for(int l=0;l<vecX.size();l++)
+ {
+ if(l==0)
+ {
+ vecXo.push_back(p[0]);
+ vecYo.push_back(p[1]);
+ }
+ else
+ {
+ if(vecXoi[l-1]==)
+ {
+ }
+ }
+
+ }*/
+
+ ExtractControlPoints2D *extractcontrolpoints2d = new ExtractControlPoints2D();
+
+ extractcontrolpoints2d->SetContour( &vecX , &vecY , &vecZ );
+
+ int method=2;
+ if (method==0){
+ extractcontrolpoints2d->GetInitialControlPoints( &vecCtrlPointX , &vecCtrlPointY , &vecCtrlPointZ );
+ }
+ else if (method==1){
+ extractcontrolpoints2d->GetControlPoints( &vecCtrlPointX , &vecCtrlPointY , &vecCtrlPointZ );
+ }
+ else if (method==2){
+ extractcontrolpoints2d->SetSamplingControlPoints( 15 );
+ extractcontrolpoints2d->GetSamplingControlPoints( &vecCtrlPointX , &vecCtrlPointY , &vecCtrlPointZ );
+ }
+ //--Adding contour to the system
+
+ std::vector<int> actualInstantVector;
+ _instantPanel->getInstant( actualInstantVector );
+ actualInstantVector[1]=z;
+
+ int j,sizeCtrPt = vecCtrlPointX.size();
+
+ manualBaseModel *manModelContour = kernelManager->factoryManualContourModel( typeofcontour );
+ manModelContour->SetNumberOfPointsSpline( ((sizeCtrPt/100)+1)*100 );
+ if (sizeCtrPt>=3){
+ for (j=0 ; j<sizeCtrPt ; j++)
+ {
+ manModelContour->AddPoint( vecCtrlPointX[j] , vecCtrlPointY[j] , vecCtrlPointZ[j] );
+ } // for
+ std::string theName;
+ //theName = _modelManager->createOutline( manModelContour, actualInstantVector );
+ theName = kernelManager->createOutline( manModelContour, actualInstantVector );
+ bool addedModel = theName.compare("") != 0;
+ if( addedModel )
+ {
+ double spc[3];//Si no hay imagen pero hay contornos que spacing se pone por default
+ _theViewPanel->getSpacing(spc);
+ //Adding the manualContourControler to interface objects structure
+ //Adding the manualViewContour to interface objects structure
+ //_theViewPanel->getSceneManager()->setControlActiveStateOfALL( false );//This call is being done here because if the ROI is created underneath the previously created ROIS will still be active.
+ _theViewPanel->configureViewControlTo(theName, manModelContour, spc, typeofcontour);
+ //_theViewPanel->getSceneManager()->configureViewControlTo( theName, manModelContour,spc, typeofcontour ) ;
+ } // if addedModel
+ } // if sizeCtrPt
+
+
+
+ WriterType::Pointer writer = WriterType::New();
+ CastFilterType3::Pointer caster = CastFilterType3::New();
+
+ caster->SetInput( gradientMagnitude->GetOutput() );
+ writer->SetInput( caster->GetOutput() );
+ writer->SetFileName("Gradient Magnitude.png");
+ caster->SetOutputMinimum( 0 );
+ caster->SetOutputMaximum( 255 );
+ writer->Update();
+
+ CastFilterType3::Pointer caster2 = CastFilterType3::New();
+ WriterType::Pointer writer2 = WriterType::New();
+
+ caster2->SetInput( sigmoid->GetOutput() );
+ writer2->SetInput( caster2->GetOutput() );
+ writer2->SetFileName("Sigmoid.png");
+ caster2->SetOutputMinimum( 0 );
+ caster2->SetOutputMaximum( 255 );
+ writer2->Update();
+
+ CastFilterType3::Pointer caster3 = CastFilterType3::New();
+ WriterType::Pointer writer3 = WriterType::New();
+
+ caster3->SetInput( fastMarching->GetOutput() );
+ writer3->SetInput( caster3->GetOutput() );
+ writer3->SetFileName("FastMarching.bmp");
+ caster3->SetOutputMinimum( 0 );
+ caster3->SetOutputMaximum( 255 );
+ writer3->Update();
+
+ CastFilterType3::Pointer caster4 = CastFilterType3::New();
+ WriterType::Pointer writer4 = WriterType::New();
+
+ caster4->SetInput( geodesicActiveContour->GetOutput() );
+ writer4->SetInput( caster4->GetOutput() );
+ writer4->SetFileName("GeodesicActiveContour.png");
+ caster4->SetOutputMinimum( 0 );
+ caster4->SetOutputMaximum( 255 );
+ writer4->Update();
+
+ CastFilterType3::Pointer caster5 = CastFilterType3::New();
+ WriterType::Pointer writer5 = WriterType::New();
+
+ caster5->SetInput( zeroCrossing->GetOutput() );
+ writer5->SetInput( caster5->GetOutput() );
+ writer5->SetFileName("ZeroCrossing.bmp");
+ caster5->SetOutputMinimum( 0 );
+ caster5->SetOutputMaximum( 255 );
+ writer5->Update();
+ }
+ catch( itk::ExceptionObject & excep )
+ {
+ std::cerr << "Exception caught !" << std::endl;
+ std::cerr << excep << std::endl;
+ }