void QmitkBasicImageProcessing::StartButtonClicked()
{
  if(!m_SelectedImageNode->GetNode()) return;

  this->BusyCursorOn();

  mitk::Image::Pointer newImage;

  try
  {
    newImage = dynamic_cast<mitk::Image*>(m_SelectedImageNode->GetNode()->GetData());
  }
  catch ( std::exception &e )
  {
  QString exceptionString = "An error occured during image loading:\n";
  exceptionString.append( e.what() );
    QMessageBox::warning( NULL, "Basic Image Processing", exceptionString , QMessageBox::Ok, QMessageBox::NoButton );
    this->BusyCursorOff();
    return;
  }

  // check if input image is valid, casting does not throw exception when casting from 'NULL-Object'
  if ( (! newImage) || (newImage->IsInitialized() == false) )
  {
    this->BusyCursorOff();

    QMessageBox::warning( NULL, "Basic Image Processing", "Input image is broken or not initialized. Returning.", QMessageBox::Ok, QMessageBox::NoButton );
    return;
  }

  // check if operation is done on 4D a image time step
  if(newImage->GetDimension() > 3)
  {
    mitk::ImageTimeSelector::Pointer timeSelector = mitk::ImageTimeSelector::New();
    timeSelector->SetInput(newImage);
    timeSelector->SetTimeNr( ((QmitkSliderNavigatorWidget*)m_Controls->sliceNavigatorTime)->GetPos() );
    timeSelector->Update();
    newImage = timeSelector->GetOutput();
  }



  // check if image or vector image
  ImageType::Pointer itkImage = ImageType::New();
  VectorImageType::Pointer itkVecImage = VectorImageType::New();

  int isVectorImage = newImage->GetPixelType().GetNumberOfComponents();

  if(isVectorImage > 1)
  {
    CastToItkImage( newImage, itkVecImage );
  }
  else
  {
    CastToItkImage( newImage, itkImage );
  }

  std::stringstream nameAddition("");

  int param1 = m_Controls->sbParam1->value();
  int param2 = m_Controls->sbParam2->value();
  double dparam1 = m_Controls->dsbParam1->value();
  double dparam2 = m_Controls->dsbParam2->value();
  double dparam3 = m_Controls->dsbParam3->value();

  try{

  switch (m_SelectedAction)
  {

  case GAUSSIAN:
    {
      GaussianFilterType::Pointer gaussianFilter = GaussianFilterType::New();
      gaussianFilter->SetInput( itkImage );
      gaussianFilter->SetVariance( param1 );
      gaussianFilter->UpdateLargestPossibleRegion();
      newImage = mitk::ImportItkImage(gaussianFilter->GetOutput())->Clone();
      nameAddition << "_Gaussian_var_" << param1;
      std::cout << "Gaussian filtering successful." << std::endl;
      break;
    }

  case MEDIAN:
    {
      MedianFilterType::Pointer medianFilter = MedianFilterType::New();
      MedianFilterType::InputSizeType size;
      size.Fill(param1);
      medianFilter->SetRadius( size );
      medianFilter->SetInput(itkImage);
      medianFilter->UpdateLargestPossibleRegion();
      newImage = mitk::ImportItkImage(medianFilter->GetOutput())->Clone();
      nameAddition << "_Median_radius_" << param1;
      std::cout << "Median Filtering successful." << std::endl;
      break;
    }

  case TOTALVARIATION:
    {
      if(isVectorImage > 1)
      {
        VectorTotalVariationFilterType::Pointer TVFilter
          = VectorTotalVariationFilterType::New();
        TVFilter->SetInput( itkVecImage.GetPointer() );
        TVFilter->SetNumberIterations(param1);
        TVFilter->SetLambda(double(param2)/1000.);
        TVFilter->UpdateLargestPossibleRegion();

        newImage = mitk::ImportItkImage(TVFilter->GetOutput())->Clone();
      }
      else
      {
        ImagePTypeToFloatPTypeCasterType::Pointer floatCaster = ImagePTypeToFloatPTypeCasterType::New();
        floatCaster->SetInput( itkImage );
        floatCaster->Update();
        FloatImageType::Pointer fImage = floatCaster->GetOutput();

        TotalVariationFilterType::Pointer TVFilter
          = TotalVariationFilterType::New();
        TVFilter->SetInput( fImage.GetPointer() );
        TVFilter->SetNumberIterations(param1);
        TVFilter->SetLambda(double(param2)/1000.);
        TVFilter->UpdateLargestPossibleRegion();

        newImage = mitk::ImportItkImage(TVFilter->GetOutput())->Clone();
      }

      nameAddition << "_TV_Iter_" << param1 << "_L_" << param2;
      std::cout << "Total Variation Filtering successful." << std::endl;
      break;
    }

  case DILATION:
    {
      BallType binaryBall;
      binaryBall.SetRadius( param1 );
      binaryBall.CreateStructuringElement();

      DilationFilterType::Pointer dilationFilter = DilationFilterType::New();
      dilationFilter->SetInput( itkImage );
      dilationFilter->SetKernel( binaryBall );
      dilationFilter->UpdateLargestPossibleRegion();
      newImage = mitk::ImportItkImage(dilationFilter->GetOutput())->Clone();
      nameAddition << "_Dilated_by_" << param1;
      std::cout << "Dilation successful." << std::endl;
      break;
    }

  case EROSION:
    {
      BallType binaryBall;
      binaryBall.SetRadius( param1 );
      binaryBall.CreateStructuringElement();

      ErosionFilterType::Pointer erosionFilter = ErosionFilterType::New();
      erosionFilter->SetInput( itkImage );
      erosionFilter->SetKernel( binaryBall );
      erosionFilter->UpdateLargestPossibleRegion();
      newImage = mitk::ImportItkImage(erosionFilter->GetOutput())->Clone();
      nameAddition << "_Eroded_by_" << param1;
      std::cout << "Erosion successful." << std::endl;
      break;
    }

  case OPENING:
    {
      BallType binaryBall;
      binaryBall.SetRadius( param1 );
      binaryBall.CreateStructuringElement();

      OpeningFilterType::Pointer openFilter = OpeningFilterType::New();
      openFilter->SetInput( itkImage );
      openFilter->SetKernel( binaryBall );
      openFilter->UpdateLargestPossibleRegion();
      newImage = mitk::ImportItkImage(openFilter->GetOutput())->Clone();
      nameAddition << "_Opened_by_" << param1;
      std::cout << "Opening successful." << std::endl;
      break;
    }

  case CLOSING:
    {
      BallType binaryBall;
      binaryBall.SetRadius( param1 );
      binaryBall.CreateStructuringElement();

      ClosingFilterType::Pointer closeFilter = ClosingFilterType::New();
      closeFilter->SetInput( itkImage );
      closeFilter->SetKernel( binaryBall );
      closeFilter->UpdateLargestPossibleRegion();
      newImage = mitk::ImportItkImage(closeFilter->GetOutput())->Clone();
      nameAddition << "_Closed_by_" << param1;
      std::cout << "Closing successful." << std::endl;
      break;
    }

  case GRADIENT:
    {
      GradientFilterType::Pointer gradientFilter = GradientFilterType::New();
      gradientFilter->SetInput( itkImage );
      gradientFilter->SetSigma( param1 );
      gradientFilter->UpdateLargestPossibleRegion();
      newImage = mitk::ImportItkImage(gradientFilter->GetOutput())->Clone();
      nameAddition << "_Gradient_sigma_" << param1;
      std::cout << "Gradient calculation successful." << std::endl;
      break;
    }

  case LAPLACIAN:
    {
      // the laplace filter requires a float type image as input, we need to cast the itkImage
      // to correct type
      ImagePTypeToFloatPTypeCasterType::Pointer caster = ImagePTypeToFloatPTypeCasterType::New();
      caster->SetInput( itkImage );
      caster->Update();
      FloatImageType::Pointer fImage = caster->GetOutput();

      LaplacianFilterType::Pointer laplacianFilter = LaplacianFilterType::New();
      laplacianFilter->SetInput( fImage );
      laplacianFilter->UpdateLargestPossibleRegion();
      newImage = mitk::ImportItkImage(laplacianFilter->GetOutput())->Clone();
      nameAddition << "_Second_Derivative";
      std::cout << "Laplacian filtering successful." << std::endl;
      break;
    }

  case SOBEL:
    {
      // the sobel filter requires a float type image as input, we need to cast the itkImage
      // to correct type
      ImagePTypeToFloatPTypeCasterType::Pointer caster = ImagePTypeToFloatPTypeCasterType::New();
      caster->SetInput( itkImage );
      caster->Update();
      FloatImageType::Pointer fImage = caster->GetOutput();

      SobelFilterType::Pointer sobelFilter = SobelFilterType::New();
      sobelFilter->SetInput( fImage );
      sobelFilter->UpdateLargestPossibleRegion();
      newImage = mitk::ImportItkImage(sobelFilter->GetOutput())->Clone();
      nameAddition << "_Sobel";
      std::cout << "Edge Detection successful." << std::endl;
      break;
    }

  case THRESHOLD:
    {
      ThresholdFilterType::Pointer thFilter = ThresholdFilterType::New();
      thFilter->SetLowerThreshold(param1 < param2 ? param1 : param2);
      thFilter->SetUpperThreshold(param2 > param1 ? param2 : param1);
      thFilter->SetInsideValue(1);
      thFilter->SetOutsideValue(0);
      thFilter->SetInput(itkImage);
      thFilter->UpdateLargestPossibleRegion();
      newImage = mitk::ImportItkImage(thFilter->GetOutput())->Clone();
      nameAddition << "_Threshold";
      std::cout << "Thresholding successful." << std::endl;
      break;
    }

  case INVERSION:
    {
      InversionFilterType::Pointer invFilter = InversionFilterType::New();
      mitk::ScalarType min = newImage->GetScalarValueMin();
      mitk::ScalarType max = newImage->GetScalarValueMax();
      invFilter->SetMaximum( max + min );
      invFilter->SetInput(itkImage);
      invFilter->UpdateLargestPossibleRegion();
      newImage = mitk::ImportItkImage(invFilter->GetOutput())->Clone();
      nameAddition << "_Inverted";
      std::cout << "Image inversion successful." << std::endl;
      break;
    }

  case DOWNSAMPLING:
    {
      ResampleImageFilterType::Pointer downsampler = ResampleImageFilterType::New();
      downsampler->SetInput( itkImage );

      NearestInterpolatorType::Pointer interpolator = NearestInterpolatorType::New();
      downsampler->SetInterpolator( interpolator );

      downsampler->SetDefaultPixelValue( 0 );

      ResampleImageFilterType::SpacingType spacing = itkImage->GetSpacing();
      spacing *= (double) param1;
      downsampler->SetOutputSpacing( spacing );

      downsampler->SetOutputOrigin( itkImage->GetOrigin() );
      downsampler->SetOutputDirection( itkImage->GetDirection() );

      ResampleImageFilterType::SizeType size = itkImage->GetLargestPossibleRegion().GetSize();
      for ( int i = 0; i < 3; ++i )
      {
        size[i] /= param1;
      }
      downsampler->SetSize( size );
      downsampler->UpdateLargestPossibleRegion();

      newImage = mitk::ImportItkImage(downsampler->GetOutput())->Clone();
      nameAddition << "_Downsampled_by_" << param1;
      std::cout << "Downsampling successful." << std::endl;
      break;
    }

  case FLIPPING:
    {
      FlipImageFilterType::Pointer flipper = FlipImageFilterType::New();
      flipper->SetInput( itkImage );
      itk::FixedArray<bool, 3> flipAxes;
      for(int i=0; i<3; ++i)
      {
        if(i == param1)
        {
          flipAxes[i] = true;
        }
        else
        {
          flipAxes[i] = false;
        }
      }
      flipper->SetFlipAxes(flipAxes);
      flipper->UpdateLargestPossibleRegion();
      newImage = mitk::ImportItkImage(flipper->GetOutput())->Clone();
      std::cout << "Image flipping successful." << std::endl;
      break;
    }

  case RESAMPLING:
    {
      std::string selectedInterpolator;
      ResampleImageFilterType::Pointer resampler = ResampleImageFilterType::New();
      switch (m_SelectedInterpolation)
      {
      case LINEAR:
        {
          LinearInterpolatorType::Pointer interpolator = LinearInterpolatorType::New();
          resampler->SetInterpolator(interpolator);
          selectedInterpolator = "Linear";
          break;
        }
      case NEAREST:
        {
          NearestInterpolatorType::Pointer interpolator = NearestInterpolatorType::New();
          resampler->SetInterpolator(interpolator);
          selectedInterpolator = "Nearest";
          break;
        }
      default:
        {
          LinearInterpolatorType::Pointer interpolator = LinearInterpolatorType::New();
          resampler->SetInterpolator(interpolator);
          selectedInterpolator = "Linear";
          break;
        }
      }
      resampler->SetInput( itkImage );
      resampler->SetOutputOrigin( itkImage->GetOrigin() );

      ImageType::SizeType input_size = itkImage->GetLargestPossibleRegion().GetSize();
      ImageType::SpacingType input_spacing = itkImage->GetSpacing();

      ImageType::SizeType output_size;
      ImageType::SpacingType output_spacing;

      output_size[0] = input_size[0] * (input_spacing[0] / dparam1);
      output_size[1] = input_size[1] * (input_spacing[1] / dparam2);
      output_size[2] = input_size[2] * (input_spacing[2] / dparam3);
      output_spacing [0] = dparam1;
      output_spacing [1] = dparam2;
      output_spacing [2] = dparam3;

      resampler->SetSize( output_size );
      resampler->SetOutputSpacing( output_spacing );
      resampler->SetOutputDirection( itkImage->GetDirection() );

      resampler->UpdateLargestPossibleRegion();

      ImageType::Pointer resampledImage = resampler->GetOutput();

      newImage = mitk::ImportItkImage( resampledImage );
      nameAddition << "_Resampled_" << selectedInterpolator;
      std::cout << "Resampling successful." << std::endl;
      break;
    }


  case RESCALE:
    {
      FloatImageType::Pointer floatImage = FloatImageType::New();
      CastToItkImage( newImage, floatImage );
      itk::RescaleIntensityImageFilter<FloatImageType,FloatImageType>::Pointer filter = itk::RescaleIntensityImageFilter<FloatImageType,FloatImageType>::New();
      filter->SetInput(0, floatImage);
      filter->SetOutputMinimum(dparam1);
      filter->SetOutputMaximum(dparam2);
      filter->Update();
      floatImage = filter->GetOutput();

      newImage = mitk::Image::New();
      newImage->InitializeByItk(floatImage.GetPointer());
      newImage->SetVolume(floatImage->GetBufferPointer());
      nameAddition << "_Rescaled";
      std::cout << "Rescaling successful." << std::endl;

      break;
    }

  default:
    this->BusyCursorOff();
    return;
  }
  }
  catch (...)
  {
    this->BusyCursorOff();
    QMessageBox::warning(NULL, "Warning", "Problem when applying filter operation. Check your input...");
    return;
  }

  newImage->DisconnectPipeline();

  // adjust level/window to new image
  mitk::LevelWindow levelwindow;
  levelwindow.SetAuto( newImage );
  mitk::LevelWindowProperty::Pointer levWinProp = mitk::LevelWindowProperty::New();
  levWinProp->SetLevelWindow( levelwindow );

  // compose new image name
  std::string name = m_SelectedImageNode->GetNode()->GetName();
  if (name.find(".pic.gz") == name.size() -7 )
  {
    name = name.substr(0,name.size() -7);
  }
  name.append( nameAddition.str() );

  // create final result MITK data storage node
  mitk::DataNode::Pointer result = mitk::DataNode::New();
  result->SetProperty( "levelwindow", levWinProp );
  result->SetProperty( "name", mitk::StringProperty::New( name.c_str() ) );
  result->SetData( newImage );

  // for vector images, a different mapper is needed
  if(isVectorImage > 1)
  {
    mitk::VectorImageMapper2D::Pointer mapper =
      mitk::VectorImageMapper2D::New();
    result->SetMapper(1,mapper);
  }

  // reset GUI to ease further processing
//  this->ResetOneImageOpPanel();

  // add new image to data storage and set as active to ease further processing
  GetDefaultDataStorage()->Add( result, m_SelectedImageNode->GetNode() );
  if ( m_Controls->cbHideOrig->isChecked() == true )
    m_SelectedImageNode->GetNode()->SetProperty( "visible", mitk::BoolProperty::New(false) );
  // TODO!! m_Controls->m_ImageSelector1->SetSelectedNode(result);

  // show the results
  mitk::RenderingManager::GetInstance()->RequestUpdateAll();
  this->BusyCursorOff();
}
Beispiel #2
0
InputImageType::Pointer Curvelet::RunOnInputImage(InputImageType::Pointer InputImage)
{
	//InputImage = NewInputImage;
	slices = InputImage->GetLargestPossibleRegion().GetSize()[2];
	InputImageType::Pointer outputim = InputImageType::New();
	outputim->SetRegions(InputImage->GetLargestPossibleRegion());
	outputim->Allocate();
	FloatImageType::Pointer cosim = FloatImageType::New();
	cosim->SetRegions(InputImage->GetLargestPossibleRegion());
	cosim->Allocate();
	FloatImageType::Pointer sinim = FloatImageType::New();
	sinim->SetRegions(InputImage->GetLargestPossibleRegion());
	sinim->Allocate();

	if(outputim->GetBufferPointer() == NULL || cosim->GetBufferPointer() == NULL || sinim->GetBufferPointer() == NULL)
	{
		printf("Couldnt' allocate memory - 3.. going to crash now\n");
	}
	int max_dim = tile_size;


	int xsize = InputImage->GetLargestPossibleRegion().GetSize()[0];
	int ysize = InputImage->GetLargestPossibleRegion().GetSize()[1];

	int kx = 0;int ky = 0;


	kx = xsize /(max_dim-this->border);
	ky = ysize /(max_dim-this->border);

	int remx = xsize % (max_dim-this->border);
	int remy = ysize % (max_dim-this->border);

	if ( remx > 0 )
		kx ++;
	if ( remy > 0 )
		ky ++;

	for(int xco = 0; xco < kx; xco++)
	{
		for(int yco = 0; yco < ky; yco++)
		{

			InputImageType::SizeType imsize = InputImage->GetLargestPossibleRegion().GetSize();
			InputImageType::IndexType index;
			InputImageType::SizeType size;
			InputImageType::RegionType region;

			index.Fill(0);
			size[0] =  MIN((xco)*(max_dim-this->border)+max_dim-1,imsize[0]-1) -  xco * (max_dim-this->border) +1;
			size[1] =  MIN((yco)*(max_dim-this->border)+max_dim-1,imsize[1]-1) -  yco * (max_dim-this->border) +1;
			size[2] = imsize[2];

			InputImageType::Pointer imtile = InputImageType::New();
			region.SetIndex(index);
			region.SetSize(size);
			imtile->SetRegions(region);
			imtile->Allocate();
			if(imtile->GetBufferPointer()==NULL)
				printf("Couldn't allocate memory - 4 .. going to crash now\n");
			InputImageType::RegionType region1;
			index[0] = xco *(max_dim-this->border);
			index[1] = yco *(max_dim-this->border);
			index[2] = 0;
			region1.SetIndex(index);
			region1.SetSize(size);

			typedef itk::ImageRegionIterator<InputImageType> IteratorType;
			IteratorType iter1(InputImage,region1);
			IteratorType iter2(imtile,region);


			//printf("xco = %d yco = %d :\n",xco,yco);
			region1.Print(std::cout);
			region.Print(std::cout);

			iter1.GoToBegin();
			iter2.GoToBegin();
			for(;!iter1.IsAtEnd();++iter1,++iter2)
			{
				iter2.Set(iter1.Get());
			}


			InputImageType::Pointer outputtile = InputImageType::New();
			outputtile->SetRegions(imtile->GetLargestPossibleRegion());
			outputtile->Allocate();
			FloatImageType::Pointer cosimtile = FloatImageType::New();
			cosimtile->SetRegions(imtile->GetLargestPossibleRegion());
			cosimtile->Allocate();
			FloatImageType::Pointer sinimtile = FloatImageType::New();
			sinimtile->SetRegions(imtile->GetLargestPossibleRegion());
			sinimtile->Allocate();
			if(outputtile->GetBufferPointer() == NULL || cosimtile->GetBufferPointer()==NULL || sinimtile->GetBufferPointer() == NULL )
			{
				printf("Couldn't allocate memory - 5 .. going to crash now ..\n");
			}

			{
#pragma omp parallel for shared(cosimtile,imtile,sinimtile,outputtile)  num_threads(numt)
				for(int counter = 0; counter < slices; counter++)
				{
					//printf("Counter = %d\n",counter);
					Input2DImageType::Pointer im2d = getSlice(imtile,counter);
					Input2DImageType::Pointer om2d;
					Float2DImageType::Pointer cosim2d,sinim2d;
					//call single slice 2-d curvelets function
					getCurveletsForOneSlice(im2d,om2d,cosim2d,sinim2d);
					copyslice<InputPixelType>(om2d,outputtile,counter);
					copyslice<float>(cosim2d,cosimtile,counter);
					copyslice<float>(sinim2d,sinimtile,counter);
				}
			}
			
			//printf("copying the tile\n");
			if(xco != 0)
			{
				size[0] = size[0] - border/2;
				index[0] = border/2;
			}
			if(xco != kx-1)
			{
				size[0] = size[0] - border/2;
			}

			if(yco != 0)
			{
				size[1] = size[1] - border/2;
				index[1] = border/2;
			}
			if(yco != ky-1)
			{
				size[1] = size[1] - border/2;
			}
			size[2] = slices;
			index[2] = 0;


			region.SetIndex(index);
			region.SetSize(size);
			
			if(xco!=0)
			{
				index[0] = xco *(max_dim-border)+border/2;
			}
			if(yco!=0)
			{
				index[1] = yco *(max_dim-border)+border/2;
			}
			
			
			index[2] = 0;
			region1.SetSize(size);
			region1.SetIndex(index);

			iter1 = IteratorType(outputim,region1);
			iter2 = IteratorType(outputtile,region);
			typedef itk::ImageRegionIterator<FloatImageType> FIteratorType;
			FIteratorType iter3(cosim,region1);
			FIteratorType iter4(cosimtile,region);
			FIteratorType iter5(sinim,region1);
			FIteratorType iter6(sinimtile, region);

			iter1.GoToBegin();iter2.GoToBegin();
			iter3.GoToBegin();iter4.GoToBegin();
			iter5.GoToBegin();iter6.GoToBegin();

			for(;!iter1.IsAtEnd();++iter1,++iter2,++iter3,++iter4,++iter5,++iter6)
			{
				iter1.Set(iter2.Get());
				iter3.Set(iter4.Get());
				iter5.Set(iter6.Get());
			}
			//printf("Done with copying the tile to full image\n");
		}
	}
	return outputim;
}