示例#1
0
int StartPeakExtraction(int argc, char* argv[])
{
    mitkCommandLineParser parser;
    parser.setArgumentPrefix("--", "-");
    parser.addArgument("image", "i", mitkCommandLineParser::InputFile, "Input image", "sh coefficient image", us::Any(), false);
    parser.addArgument("outroot", "o", mitkCommandLineParser::OutputDirectory, "Output directory", "output root", us::Any(), false);
    parser.addArgument("mask", "m", mitkCommandLineParser::InputFile, "Mask", "mask image");
    parser.addArgument("normalization", "n", mitkCommandLineParser::Int, "Normalization", "0=no norm, 1=max norm, 2=single vec norm", 1, true);
    parser.addArgument("numpeaks", "p", mitkCommandLineParser::Int, "Max. number of peaks", "maximum number of extracted peaks", 2, true);
    parser.addArgument("peakthres", "r", mitkCommandLineParser::Float, "Peak threshold", "peak threshold relative to largest peak", 0.4, true);
    parser.addArgument("abspeakthres", "a", mitkCommandLineParser::Float, "Absolute peak threshold", "absolute peak threshold weighted with local GFA value", 0.06, true);
    parser.addArgument("shConvention", "s", mitkCommandLineParser::String, "Use specified SH-basis", "use specified SH-basis (MITK, FSL, MRtrix)", string("MITK"), true);
    parser.addArgument("noFlip", "f", mitkCommandLineParser::Bool, "No flip", "do not flip input image to match MITK coordinate convention");
    parser.addArgument("clusterThres", "c", mitkCommandLineParser::Float, "Clustering threshold", "directions closer together than the specified angular threshold will be clustered (in rad)", 0.9);
    parser.addArgument("flipX", "fx", mitkCommandLineParser::Bool, "Flip X", "Flip peaks in x direction");
    parser.addArgument("flipY", "fy", mitkCommandLineParser::Bool, "Flip Y", "Flip peaks in y direction");
    parser.addArgument("flipZ", "fz", mitkCommandLineParser::Bool, "Flip Z", "Flip peaks in z direction");


    parser.setCategory("Preprocessing Tools");
    parser.setTitle("Peak Extraction");
    parser.setDescription("");
    parser.setContributor("MIC");

    map<string, us::Any> parsedArgs = parser.parseArguments(argc, argv);
    if (parsedArgs.size()==0)
        return EXIT_FAILURE;

    // mandatory arguments
    string imageName = us::any_cast<string>(parsedArgs["image"]);
    string outRoot = us::any_cast<string>(parsedArgs["outroot"]);

    // optional arguments
    string maskImageName("");
    if (parsedArgs.count("mask"))
        maskImageName = us::any_cast<string>(parsedArgs["mask"]);

    int normalization = 1;
    if (parsedArgs.count("normalization"))
        normalization = us::any_cast<int>(parsedArgs["normalization"]);

    int numPeaks = 2;
    if (parsedArgs.count("numpeaks"))
        numPeaks = us::any_cast<int>(parsedArgs["numpeaks"]);

    float peakThres = 0.4;
    if (parsedArgs.count("peakthres"))
        peakThres = us::any_cast<float>(parsedArgs["peakthres"]);

    float absPeakThres = 0.06;
    if (parsedArgs.count("abspeakthres"))
        absPeakThres = us::any_cast<float>(parsedArgs["abspeakthres"]);

    float clusterThres = 0.9;
    if (parsedArgs.count("clusterThres"))
        clusterThres = us::any_cast<float>(parsedArgs["clusterThres"]);

    bool noFlip = false;
    if (parsedArgs.count("noFlip"))
        noFlip = us::any_cast<bool>(parsedArgs["noFlip"]);

    bool flipX = false;
    if (parsedArgs.count("flipX"))
        flipX = us::any_cast<bool>(parsedArgs["flipX"]);

    bool flipY = false;
    if (parsedArgs.count("flipY"))
        flipY = us::any_cast<bool>(parsedArgs["flipY"]);

    bool flipZ = false;
    if (parsedArgs.count("flipZ"))
        flipZ = us::any_cast<bool>(parsedArgs["flipZ"]);

    std::cout << "image: " << imageName;
    std::cout << "outroot: " << outRoot;
    if (!maskImageName.empty())
        std::cout << "mask: " << maskImageName;
    else
        std::cout << "no mask image selected";
    std::cout << "numpeaks: " << numPeaks;
    std::cout << "peakthres: " << peakThres;
    std::cout << "abspeakthres: " << absPeakThres;
    std::cout << "shOrder: " << shOrder;

    try
    {
        mitk::Image::Pointer image = dynamic_cast<mitk::Image*>(mitk::IOUtil::Load(imageName)[0].GetPointer());
        mitk::Image::Pointer mask = dynamic_cast<mitk::Image*>(mitk::IOUtil::Load(maskImageName)[0].GetPointer());

        typedef itk::Image<unsigned char, 3>  ItkUcharImgType;
        typedef itk::FiniteDiffOdfMaximaExtractionFilter< float, shOrder, 20242 > MaximaExtractionFilterType;
        typename MaximaExtractionFilterType::Pointer filter = MaximaExtractionFilterType::New();

        int toolkitConvention = 0;

        if (parsedArgs.count("shConvention"))
        {
            string convention = us::any_cast<string>(parsedArgs["shConvention"]).c_str();
            if ( boost::algorithm::equals(convention, "FSL") )
            {
                toolkitConvention = 1;
                std::cout << "Using FSL SH-basis";
            }
            else if ( boost::algorithm::equals(convention, "MRtrix") )
            {
                toolkitConvention = 2;
                std::cout << "Using MRtrix SH-basis";
            }
            else
                std::cout << "Using MITK SH-basis";
        }
        else
            std::cout << "Using MITK SH-basis";

        ItkUcharImgType::Pointer itkMaskImage = nullptr;
        if (mask.IsNotNull())
        {
            try{
                itkMaskImage = ItkUcharImgType::New();
                mitk::CastToItkImage(mask, itkMaskImage);
                filter->SetMaskImage(itkMaskImage);
            }
            catch(...)
            {

            }
        }

        if (toolkitConvention>0)
        {
            std::cout << "Converting coefficient image to MITK format";
            typedef itk::ShCoefficientImageImporter< float, shOrder > ConverterType;
            typedef mitk::ImageToItk< itk::Image< float, 4 > > CasterType;
            CasterType::Pointer caster = CasterType::New();
            caster->SetInput(image);
            caster->Update();
            itk::Image< float, 4 >::Pointer itkImage = caster->GetOutput();

            typename ConverterType::Pointer converter = ConverterType::New();

            if (noFlip)
            {
                converter->SetInputImage(itkImage);
            }
            else
            {
                std::cout << "Flipping image";
                itk::FixedArray<bool, 4> flipAxes;
                flipAxes[0] = true;
                flipAxes[1] = true;
                flipAxes[2] = false;
                flipAxes[3] = false;
                itk::FlipImageFilter< itk::Image< float, 4 > >::Pointer flipper = itk::FlipImageFilter< itk::Image< float, 4 > >::New();
                flipper->SetInput(itkImage);
                flipper->SetFlipAxes(flipAxes);
                flipper->Update();
                itk::Image< float, 4 >::Pointer flipped = flipper->GetOutput();
                itk::Matrix< double,4,4 > m = itkImage->GetDirection(); m[0][0] *= -1; m[1][1] *= -1;
                flipped->SetDirection(m);

                itk::Point< float, 4 > o = itkImage->GetOrigin();
                o[0] -= (flipped->GetLargestPossibleRegion().GetSize(0)-1);
                o[1] -= (flipped->GetLargestPossibleRegion().GetSize(1)-1);
                flipped->SetOrigin(o);
                converter->SetInputImage(flipped);
            }

            std::cout << "Starting conversion";
            switch (toolkitConvention)
            {
            case 1:
                converter->SetToolkit(ConverterType::FSL);
                filter->SetToolkit(MaximaExtractionFilterType::FSL);
                break;
            case 2:
                converter->SetToolkit(ConverterType::MRTRIX);
                filter->SetToolkit(MaximaExtractionFilterType::MRTRIX);
                break;
            default:
                converter->SetToolkit(ConverterType::FSL);
                filter->SetToolkit(MaximaExtractionFilterType::FSL);
                break;
            }
            converter->GenerateData();
            filter->SetInput(converter->GetCoefficientImage());
        }
        else
        {
            try{
                typedef mitk::ImageToItk< typename MaximaExtractionFilterType::CoefficientImageType > CasterType;
                typename CasterType::Pointer caster = CasterType::New();
                caster->SetInput(image);
                caster->Update();
                filter->SetInput(caster->GetOutput());
            }
            catch(...)
            {
                std::cout << "wrong image type";
                return EXIT_FAILURE;
            }
        }

        filter->SetMaxNumPeaks(numPeaks);
        filter->SetPeakThreshold(peakThres);
        filter->SetAbsolutePeakThreshold(absPeakThres);
        filter->SetAngularThreshold(1);
        filter->SetClusteringThreshold(clusterThres);
        filter->SetFlipX(flipX);
        filter->SetFlipY(flipY);
        filter->SetFlipZ(flipZ);

        switch (normalization)
        {
        case 0:
            filter->SetNormalizationMethod(MaximaExtractionFilterType::NO_NORM);
            break;
        case 1:
            filter->SetNormalizationMethod(MaximaExtractionFilterType::MAX_VEC_NORM);
            break;
        case 2:
            filter->SetNormalizationMethod(MaximaExtractionFilterType::SINGLE_VEC_NORM);
            break;
        }

        std::cout << "Starting extraction";
        filter->Update();

        // write direction image
        {
            typename MaximaExtractionFilterType::PeakImageType::Pointer itkImg = filter->GetPeakImage();
            string outfilename = outRoot;
            outfilename.append("_PEAKS.nrrd");

            typedef itk::ImageFileWriter< typename MaximaExtractionFilterType::PeakImageType > WriterType;
            typename WriterType::Pointer writer = WriterType::New();
            writer->SetFileName(outfilename);
            writer->SetInput(itkImg);
            writer->Update();
        }

        // write num directions image
        {
            ItkUcharImgType::Pointer numDirImage = filter->GetNumDirectionsImage();

            if (itkMaskImage.IsNotNull())
            {
                numDirImage->SetDirection(itkMaskImage->GetDirection());
                numDirImage->SetOrigin(itkMaskImage->GetOrigin());
            }

            string outfilename = outRoot.c_str();
            outfilename.append("_NUM_PEAKS.nrrd");
            typedef itk::ImageFileWriter< ItkUcharImgType > WriterType;
            WriterType::Pointer writer = WriterType::New();
            writer->SetFileName(outfilename);
            writer->SetInput(numDirImage);
            writer->Update();
        }
    }
    catch (itk::ExceptionObject e)
    {
        std::cout << e;
        return EXIT_FAILURE;
    }
    catch (std::exception e)
    {
        std::cout << e.what();
        return EXIT_FAILURE;
    }
    catch (...)
    {
        std::cout << "ERROR!?!";
        return EXIT_FAILURE;
    }
    return EXIT_SUCCESS;
}
示例#2
0
void QmitkOdfMaximaExtractionView::StartMaximaExtraction()
{
    typedef itk::FiniteDiffOdfMaximaExtractionFilter< float, shOrder, 20242 > MaximaExtractionFilterType;
    typename MaximaExtractionFilterType::Pointer filter = MaximaExtractionFilterType::New();

    mitk::Geometry3D::Pointer geometry;
    try{
        Image::Pointer img = dynamic_cast<Image*>(m_ImageNodes.at(0)->GetData());
        typedef ImageToItk< typename MaximaExtractionFilterType::CoefficientImageType > CasterType;
        typename CasterType::Pointer caster = CasterType::New();
        caster->SetInput(img);
        caster->Update();
        filter->SetInput(caster->GetOutput());
        geometry = img->GetGeometry();
    }
    catch(itk::ExceptionObject &e)
    {
        MITK_INFO << "wrong image type: " << e.what();
        throw;
    }

    filter->SetAngularThreshold(cos((float)m_Controls->m_AngularThreshold->value()*M_PI/180));
    filter->SetClusteringThreshold(cos((float)m_Controls->m_ClusteringAngleBox->value()*M_PI/180));
    filter->SetMaxNumPeaks(m_Controls->m_MaxNumPeaksBox->value());
    filter->SetPeakThreshold(m_Controls->m_PeakThresholdBox->value());
    filter->SetAbsolutePeakThreshold(m_Controls->m_AbsoluteThresholdBox->value());

    if (!m_BinaryImageNodes.empty())
    {
        ItkUcharImgType::Pointer itkMaskImage = ItkUcharImgType::New();
        Image::Pointer mitkMaskImg = dynamic_cast<Image*>(m_BinaryImageNodes.at(0)->GetData());
        CastToItkImage<ItkUcharImgType>(mitkMaskImg, itkMaskImage);
        filter->SetMaskImage(itkMaskImage);
    }

    switch (m_Controls->m_NormalizationBox->currentIndex())
    {
    case 0:
        filter->SetNormalizationMethod(MaximaExtractionFilterType::NO_NORM);
        break;
    case 1:
        filter->SetNormalizationMethod(MaximaExtractionFilterType::MAX_VEC_NORM);
        break;
    case 2:
        filter->SetNormalizationMethod(MaximaExtractionFilterType::SINGLE_VEC_NORM);
        break;
    }

    filter->Update();

    if (m_Controls->m_OutputDirectionImagesBox->isChecked())
    {
        typedef typename MaximaExtractionFilterType::ItkDirectionImageContainer ItkDirectionImageContainer;
        typename ItkDirectionImageContainer::Pointer container = filter->GetDirectionImageContainer();
        for (int i=0; i<container->Size(); i++)
        {
            typename MaximaExtractionFilterType::ItkDirectionImage::Pointer itkImg = container->GetElement(i);
            mitk::Image::Pointer img = mitk::Image::New();
            img->InitializeByItk( itkImg.GetPointer() );
            img->SetVolume( itkImg->GetBufferPointer() );
            DataNode::Pointer node = DataNode::New();
            node->SetData(img);
            QString name(m_ImageNodes.at(0)->GetName().c_str());
            name += "_Direction";
            name += QString::number(i+1);
            node->SetName(name.toStdString().c_str());
            GetDataStorage()->Add(node);
        }
    }

    if (m_Controls->m_OutputNumDirectionsBox->isChecked())
    {
        ItkUcharImgType::Pointer numDirImage = filter->GetNumDirectionsImage();
        mitk::Image::Pointer image2 = mitk::Image::New();
        image2->InitializeByItk( numDirImage.GetPointer() );
        image2->SetVolume( numDirImage->GetBufferPointer() );
        DataNode::Pointer node2 = DataNode::New();
        node2->SetData(image2);
        QString name(m_ImageNodes.at(0)->GetName().c_str());
        name += "_NumDirections";
        node2->SetName(name.toStdString().c_str());
        GetDataStorage()->Add(node2);
    }

    if (m_Controls->m_OutputVectorFieldBox->isChecked())
    {
        mitk::Vector3D outImageSpacing = geometry->GetSpacing();
        float minSpacing = 1;
        if(outImageSpacing[0]<outImageSpacing[1] && outImageSpacing[0]<outImageSpacing[2])
            minSpacing = outImageSpacing[0];
        else if (outImageSpacing[1] < outImageSpacing[2])
            minSpacing = outImageSpacing[1];
        else
            minSpacing = outImageSpacing[2];

        mitk::FiberBundleX::Pointer directions = filter->GetOutputFiberBundle();
        directions->SetGeometry(geometry);
        DataNode::Pointer node = DataNode::New();
        node->SetData(directions);
        QString name(m_ImageNodes.at(0)->GetName().c_str());
        name += "_VectorField";
        node->SetName(name.toStdString().c_str());
        node->SetProperty("Fiber2DSliceThickness", mitk::FloatProperty::New(minSpacing));
        node->SetProperty("Fiber2DfadeEFX", mitk::BoolProperty::New(false));
        GetDataStorage()->Add(node);
    }
}