def ngtdm_features(self): ngtdm_dict {} NGTDMFeatures = ngtdm.RadiomicsNGTDM(img,GT) NGTDMFeatures.enableAllFeatures() # On the feature class level, all features are disabled by default. NGTDMFeatures.execute() for (key,val) in six.iteritems(NGTDMFeatures.featureValues): if self.all_: self.feat_dict[self.seq + "_" + self.class_ + '_' + key] = val else: ngtdm_dict[self.seq + "_" + self.class_ + "_" + key] = val df = pd.DataFrame(ngtdm_dict) if self.save_path: df.to_csv(os.path.join(self.save_path, 'ngtdm_features.csv'), index=False) return df
def ngtdm_features(self): ngtdm_dict = {} NGTDMFeatures = ngtdm.RadiomicsNGTDM(self.img, self.GT) NGTDMFeatures.enableAllFeatures( ) # On the feature class level, all features are disabled by default. NGTDMFeatures.execute() for (key, val) in six.iteritems(NGTDMFeatures.featureValues): self.feat_dict[key] = [val] ngtdm_dict[key] = [val] print(ngtdm_dict) df = pd.DataFrame(ngtdm_dict) if self.save_path: df.to_csv(os.path.join(self.save_path, 'ngtdm_features.csv'), index=False) return df
def ngtdm_features(self): ngtdm_dict = {} NGTDMFeatures = ngtdm.RadiomicsNGTDM(self.img, self.GT) NGTDMFeatures.enableAllFeatures( ) # On the feature class level, all features are disabled by default. NGTDMFeatures.execute() for (key, val) in six.iteritems(NGTDMFeatures.featureValues): if self.all_: self.feat_dict[self.seq + "_" + self.class_ + '_' + key] = val else: ngtdm_dict[self.seq + "_" + self.class_ + "_" + key] = val if self.save_path and (not self.all_): self.write(ngtdm_dict, os.path.join(self.save_path, 'ngtdm_features.pickle')) return ngtdm_dict
def extract_features(folder_path, folder_id): # Load in preprocessed mri volumes scans = np.load(r"{}/{}_scans.npy".format(folder_path, folder_id)) # Get t1ce and flair image from which to extract features t1ce_img = sitk.GetImageFromArray(scans[1]) flair_img = sitk.GetImageFromArray(scans[3]) # Convert scans from numpy to torch tensor and obtain segmentations with the model. Must Unsqueeze to be in format (B,C,H,W,D) scans = torch.unsqueeze(torch.from_numpy(scans), 0).to(device) _, mask = model(scans) mask = torch.squeeze(mask, 0) _, mask = mask.max(0) enhancing = (mask == 1).cpu().detach().numpy().astype('long') edema = (mask == 1).cpu().detach().numpy().astype('long') ncr_nenhancing = (mask == 3).cpu().detach().numpy().astype('long') regions = { 'edema': { 'mask': edema, 'modality': flair_img }, 'enhancing': { 'mask': enhancing, 'modality': t1ce_img }, 'ncr_nenhancing': { 'mask': ncr_nenhancing, 'modality': t1ce_img } } # Convert the region arrays into SITK image objects so they can be inputted to the PyRadiomics featureextractor functions. all_features = {} printed = 0 for (region_name, images) in regions.items(): lbl_img = sitk.GetImageFromArray(images['mask']) if len(np.unique(images['mask'])) > 1: # Get First order features firstorderfeatures = firstorder.RadiomicsFirstOrder( images['modality'], lbl_img) firstorderfeatures.enableAllFeatures( ) # On the feature class level, all features are disabled by default firstorderfeatures.execute() for (key, val) in firstorderfeatures.featureValues.items(): all_features[region_name + '_' + key] = val # Get Shape features shapefeatures = shape.RadiomicsShape(images['modality'], lbl_img) shapefeatures.enableAllFeatures() shapefeatures.execute() for (key, val) in shapefeatures.featureValues.items(): all_features[region_name + '_' + key] = val # Get Gray Level Co-occurrence Matrix (GLCM) Features glcmfeatures = glcm.RadiomicsGLCM(images['modality'], lbl_img) glcmfeatures.enableAllFeatures() glcmfeatures.execute() for (key, val) in glcmfeatures.featureValues.items(): all_features[region_name + '_' + key] = val # Get Gray Level Size Zone Matrix (GLSZM) Features glszmfeatures = glszm.RadiomicsGLSZM(images['modality'], lbl_img) glszmfeatures.enableAllFeatures() glszmfeatures.execute() for (key, val) in glszmfeatures.featureValues.items(): all_features[region_name + '_' + key] = val # Get Gray Level Run Length Matrix (GLRLM) Features glrlmfeatures = glrlm.RadiomicsGLRLM(images['modality'], lbl_img) glrlmfeatures.enableAllFeatures() glrlmfeatures.execute() for (key, val) in glrlmfeatures.featureValues.items(): all_features[region_name + '_' + key] = val # Get Neighbouring Gray Tone Difference Matrix (NGTDM) Features ngtdmfeatures = ngtdm.RadiomicsNGTDM(images['modality'], lbl_img) ngtdmfeatures.enableAllFeatures() ngtdmfeatures.execute() for (key, val) in ngtdmfeatures.featureValues.items(): all_features[region_name + '_' + key] = val # Get Gray Level Dependence Matrix (GLDM) Features gldmfeatures = gldm.RadiomicsGLDM(images['modality'], lbl_img) gldmfeatures.enableAllFeatures() gldmfeatures.execute() for (key, val) in gldmfeatures.featureValues.items(): all_features[region_name + '_' + key] = val else: if (not printed): print(folder_id) printed = 1 return all_features
def calculateRadiomicsFromJson(niiFile, jsonFile,wavelet,LoG,Square,SquareRoot,Logarithm,\ Exponential,Gradient,LocalBinaryPattern2D,LocalBinaryPattern3D): sitkImageParent = sitk.ReadImage(niiFile) direction = sitkImageParent.GetDirection() origin = sitkImageParent.GetOrigin() spacing = sitkImageParent.GetSpacing() # processing json nodules = {} parameterList = ["xBegin","yBegin","zBegin","DimInPixelX","DimInPixelY","DimInPixelZ",\ "sliceMask"] with open(jsonFile,mode='r') as f: json_Data = json.load(f) nodule_List = json_Data.get("Nodules",None) if not nodule_List: print("Error!NO DATA IN json") return for subNodule,subVal in nodule_List.items(): if str(subNodule) == 'count' or str(subNodule) == 'version' : continue # print("subNodule=",subNodule) # print("subVal=",subVal) label = subVal.get("Label",None) if not label: print("ERROR:Nodule No Label Info") return nodules[label]={} nodules[label]['label'] = label nodules[label]['sliceMask'] = '' for arg in parameterList: if arg in ["DimInPixelX","DimInPixelY","DimInPixelZ"]: nodules[label][arg] = int(subVal.get(arg,None)) elif arg in ["xBegin","yBegin","zBegin"]: if subVal.get("VerifiedNodule",None).get("mask",None): nodules[label][arg] = float(subVal.get("VerifiedNodule",None).get("mask",None).get(arg,None))#subVal.get("VerifiedNodule",None).get("mask",None).get(arg,None)) else: nodules[label][arg] = float(subVal.get("mask",None).get(arg,None))#subVal.get("VerifiedNodule",None).get("mask",None).get(arg,None)) else: if subVal.get("VerifiedNodule",None).get("mask",None): subSliceMask = subVal.get("VerifiedNodule",None).get("mask",None).get("sliceMask",None)#.get("VerifiedNodule",None).get("mask",None).get("sliceMask",None)#['item'] else: subSliceMask = subVal.get("mask",None).get("sliceMask",None) subSliceMask.pop("count") for key,val in subSliceMask.items():#current for i in val: nodules[label][arg] += i # nodules[label][arg] =subVal.get("VerifiedNodule",None).get("mask",None).get("sliceMask",None)['item'] # print("nodules=",nodules) features = {} kwargs = {'binWidth': 64, 'interpolator': sitk.sitkBSpline, 'resampledPixelSpacing': None} for noduleLabel in nodules: if 'DimInPixelX' not in nodules[noduleLabel]: continue print("noduleLabel=",noduleLabel) bbox_dim = (nodules[noduleLabel]['DimInPixelX'], nodules[noduleLabel]['DimInPixelY'], \ nodules[noduleLabel]['DimInPixelZ']) bbox_ori = (nodules[noduleLabel]['xBegin'], nodules[noduleLabel]['yBegin'], \ nodules[noduleLabel]['zBegin']) sitkMask = sitk.Image(bbox_dim[0], bbox_dim[1], bbox_dim[2], sitk.sitkUInt8) sitkMask.SetSpacing(spacing) sitkMask.SetOrigin(bbox_ori) sitkMask.SetDirection(direction) for z in range(bbox_dim[2]): for y in range(bbox_dim[1]): for x in range(bbox_dim[0]): idx = z * bbox_dim[1] * bbox_dim[0] + y * bbox_dim[0] + x v = int(nodules[noduleLabel]['sliceMask'][idx]) sitkMask.SetPixel(x, y, z, v) ori_matrix = (int(direction[0] * (bbox_ori[0] - origin[0]) / spacing[0]), \ int(direction[4] * (bbox_ori[1] - origin[1]) / spacing[1]), \ int(direction[8] * (bbox_ori[2] - origin[2]) / spacing[2])) sitkMask = resample_sitkImage(sitkMask, (spacing[0]/4, spacing[1]/4, spacing[2]/4)) sitkImage = sitk.RegionOfInterest(sitkImageParent, sitkMask.GetSize(), ori_matrix) sitkImage.SetSpacing(spacing) sitkImage.SetOrigin(bbox_ori) sitkImage.SetDirection(direction) features[noduleLabel] = {} firstOrderFeatures = firstorder.RadiomicsFirstOrder(sitkImage, sitkMask, **kwargs) firstOrderFeatures.enableAllFeatures() firstOrderFeatures.calculateFeatures() firstOrderResult = features[noduleLabel].setdefault('firstorder', {}) for (key, val) in six.iteritems(firstOrderFeatures.featureValues): firstOrderResult[key] = val shapeFeatures = shape.RadiomicsShape(sitkImage, sitkMask, **kwargs) shapeFeatures.enableAllFeatures() shapeFeatures.calculateFeatures() shapeResult = features[noduleLabel].setdefault('shape', {}) for (key, val) in six.iteritems(shapeFeatures.featureValues): shapeResult[key] = val glcmFeatures = glcm.RadiomicsGLCM(sitkImage, sitkMask, **kwargs) glcmFeatures.enableAllFeatures() glcmFeatures.calculateFeatures() glcmResult = features[noduleLabel].setdefault('glcm', {}) for (key, val) in six.iteritems(glcmFeatures.featureValues): glcmResult[key] = val glrlmFeatures = glrlm.RadiomicsGLRLM(sitkImage, sitkMask, **kwargs) glrlmFeatures.enableAllFeatures() glrlmFeatures.calculateFeatures() glrlmResult = features[noduleLabel].setdefault('glrlm', {}) for (key, val) in six.iteritems(glrlmFeatures.featureValues): glrlmResult[key] = val glszmFeatures = glszm.RadiomicsGLSZM(sitkImage, sitkMask, **kwargs) glszmFeatures.enableAllFeatures() glszmFeatures.calculateFeatures() glszmResult = features[noduleLabel].setdefault('glszm', {}) for (key, val) in six.iteritems(glszmFeatures.featureValues): glszmResult[key] = val #added new feature of gldm gldmFeatures = gldm.RadiomicsGLDM(sitkImage, sitkMask, **kwargs) gldmFeatures.enableAllFeatures() gldmFeatures.calculateFeatures() gldmFeatures = features[noduleLabel].setdefault('gldm', {}) for (key, val) in six.iteritems(glszmFeatures.featureValues): gldmFeatures[key] = val #added new feature of ngtdm ngtdmFeatures = ngtdm.RadiomicsNGTDM(sitkImage, sitkMask, **kwargs) ngtdmFeatures.enableAllFeatures() ngtdmFeatures.calculateFeatures() ngtdmFeatures = features[noduleLabel].setdefault('ngtdm', {}) for (key, val) in six.iteritems(glszmFeatures.featureValues): ngtdmFeatures[key] = val print("features=",features) featuresList = ["FirstOrder","Shape","GLCM","GLRLM","GLSZM","NGTDM","GLDM"] if LoG: sigmaValues = numpy.arange(5., 0., -.5)[::1] for logImage, imageTypeName, inputKwargs in imageoperations.getLoGImage(sitkImage, sitkMask,sigma=sigmaValues): for filterName in featuresList: exec("LoG"+filterName+"Features = "+filterName.lower()+".Radiomics"+filterName+"(logImage, sitkMask, **inputKwargs)") for feature in featuresList: exec("LoG"+feature+"Features.enableAllFeatures()") exec("LoG"+feature+"Features.calculateFeatures()") LoGFirstOrderResult = features[noduleLabel].setdefault('LoGFirstOrder', {}) LoGShapeResult = features[noduleLabel].setdefault('LoGShape', {}) LoGGLCMResult = features[noduleLabel].setdefault('LoGGlcm', {}) LoGGLRLMResult = features[noduleLabel].setdefault('LoGGlrlm', {}) LoGGLSZMResult = features[noduleLabel].setdefault('LoGGlszm', {}) LoGGLDMResult = features[noduleLabel].setdefault('LoGGldm', {}) LoGNGTDMResult = features[noduleLabel].setdefault('LoGNGTDM', {}) for filterName in featuresList: subFeatureValue =eval("LoG" + filterName + "Features.featureValues") for (key, val) in six.iteritems(subFeatureValue): exec("LoG"+filterName+"Result[key]=val") if wavelet: for decompositionImage, decompositionName, inputKwargs in imageoperations.getWaveletImage(sitkImage,sitkMask): for filterName in featuresList: exec("wavelet"+filterName+"Features = "+filterName.lower()+".Radiomics"+filterName+"(decompositionImage, sitkMask, **inputKwargs)") exec("wavelet"+filterName+"Features.enableAllFeatures()") exec("wavelet"+filterName+"Features.calculateFeatures()") waveletFirstOrderResult = features[noduleLabel].setdefault('waveletFirstOrder', {}) waveletShapeResult = features[noduleLabel].setdefault('waveletShape', {}) waveletGLCMResult = features[noduleLabel].setdefault('waveletGlcm', {}) waveletGLRLMResult = features[noduleLabel].setdefault('waveletGlrlm', {}) waveletGLSZMResult = features[noduleLabel].setdefault('waveletGlszm', {}) waveletGLDMResult = features[noduleLabel].setdefault('waveletGldm', {}) waveletNGTDMResult = features[noduleLabel].setdefault('waveletNGTDM', {}) for filterName in featuresList: subFeatureValue =eval("wavelet" + filterName + "Features.featureValues") for (key, val) in six.iteritems(subFeatureValue): exec("wavelet"+filterName+"Result[key]=val") if Square: # calculateSubFilterValues(imageType =="Square",features,noduleLabel,sitkImage,sitkMask) for decompositionImage, decompositionName, inputKwargs in imageoperations.getSquareImage(sitkImage,sitkMask): for filterName in featuresList: exec("square"+filterName+"Features = "+filterName.lower()+".Radiomics"+filterName+"(decompositionImage, sitkMask, **inputKwargs)") exec("square"+filterName+"Features.enableAllFeatures()") exec("square"+filterName+"Features.calculateFeatures()") squareFirstOrderResult = features[noduleLabel].setdefault('squareFirstOrder', {}) squareShapeResult = features[noduleLabel].setdefault('squareShape', {}) squareGLCMResult = features[noduleLabel].setdefault('squareGlcm', {}) squareGLRLMResult = features[noduleLabel].setdefault('squareGlrlm', {}) squareGLSZMResult = features[noduleLabel].setdefault('squareGlszm', {}) squareGLDMResult = features[noduleLabel].setdefault('squareGldm', {}) squareNGTDMResult = features[noduleLabel].setdefault('squareNGTDM', {}) for filterName in featuresList: subFeatureValue =eval("square" + filterName + "Features.featureValues") for (key, val) in six.iteritems(subFeatureValue): exec("square"+filterName+"Result[key]=val") if SquareRoot: for decompositionImage, decompositionName, inputKwargs in imageoperations.getSquareRootImage(sitkImage,sitkMask): for filterName in featuresList: exec("squareRoot"+filterName+"Features = "+filterName.lower()+".Radiomics"+filterName+"(decompositionImage, sitkMask, **inputKwargs)") exec("squareRoot"+filterName+"Features.enableAllFeatures()") exec("squareRoot"+filterName+"Features.calculateFeatures()") squareRootFirstOrderResult = features[noduleLabel].setdefault('squareRootFirstOrder', {}) squareRootShapeResult = features[noduleLabel].setdefault('squareRootShape', {}) squareRootGLCMResult = features[noduleLabel].setdefault('squareRootGlcm', {}) squareRootGLRLMResult = features[noduleLabel].setdefault('squareRootGlrlm', {}) squareRootGLSZMResult = features[noduleLabel].setdefault('squareRootGlszm', {}) squareRootGLDMResult = features[noduleLabel].setdefault('squareRootGldm', {}) squareRootNGTDMResult = features[noduleLabel].setdefault('squareRootNGTDM', {}) for filterName in featuresList: subFeatureValue =eval("squareRoot" + filterName + "Features.featureValues") for (key, val) in six.iteritems(subFeatureValue): exec("squareRoot"+filterName+"Result[key]=val") if Logarithm: for decompositionImage, decompositionName, inputKwargs in imageoperations.getLogarithmImage(sitkImage,sitkMask): for filterName in featuresList: exec("logarithm"+filterName+"Features = "+filterName.lower()+".Radiomics"+filterName+"(decompositionImage, sitkMask, **inputKwargs)") exec("logarithm"+filterName+"Features.enableAllFeatures()") exec("logarithm"+filterName+"Features.calculateFeatures()") logarithmFirstOrderResult = features[noduleLabel].setdefault('logarithmFirstOrder', {}) logarithmShapeResult = features[noduleLabel].setdefault('logarithmShape', {}) logarithmGLCMResult = features[noduleLabel].setdefault('logarithmGlcm', {}) logarithmGLRLMResult = features[noduleLabel].setdefault('logarithmGlrlm', {}) logarithmGLSZMResult = features[noduleLabel].setdefault('logarithmGlszm', {}) logarithmGLDMResult = features[noduleLabel].setdefault('logarithmGldm', {}) logarithmNGTDMResult = features[noduleLabel].setdefault('logarithmNGTDM', {}) for filterName in featuresList: subFeatureValue =eval("logarithm" + filterName + "Features.featureValues") for (key, val) in six.iteritems(subFeatureValue): exec("logarithm"+filterName+"Result[key]=val") if Exponential: for decompositionImage, decompositionName, inputKwargs in imageoperations.getExponentialImage(sitkImage,sitkMask): for filterName in featuresList: exec("Exponential"+filterName+"Features = "+filterName.lower()+".Radiomics"+filterName+"(decompositionImage, sitkMask, **inputKwargs)") exec("Exponential"+filterName+"Features.enableAllFeatures()") exec("Exponential"+filterName+"Features.calculateFeatures()") ExponentialFirstOrderResult = features[noduleLabel].setdefault('ExponentialFirstOrder', {}) ExponentialShapeResult = features[noduleLabel].setdefault('ExponentialShape', {}) ExponentialGLCMResult = features[noduleLabel].setdefault('ExponentialGlcm', {}) ExponentialGLRLMResult = features[noduleLabel].setdefault('ExponentialGlrlm', {}) ExponentialGLSZMResult = features[noduleLabel].setdefault('ExponentialGlszm', {}) ExponentialGLDMResult = features[noduleLabel].setdefault('ExponentialGldm', {}) ExponentialNGTDMResult = features[noduleLabel].setdefault('ExponentialNGTDM', {}) for filterName in featuresList: subFeatureValue =eval("Exponential" + filterName + "Features.featureValues") for (key, val) in six.iteritems(subFeatureValue): exec("Exponential"+filterName+"Result[key]=val") if Gradient: for decompositionImage, decompositionName, inputKwargs in imageoperations.getGradientImage(sitkImage,sitkMask): for filterName in featuresList: exec("Gradient"+filterName+"Features = "+filterName.lower()+".Radiomics"+filterName+"(decompositionImage, sitkMask, **inputKwargs)") exec("Gradient"+filterName+"Features.enableAllFeatures()") exec("Gradient"+filterName+"Features.calculateFeatures()") GradientFirstOrderResult = features[noduleLabel].setdefault('GradientFirstOrder', {}) GradientShapeResult = features[noduleLabel].setdefault('GradientShape', {}) GradientGLCMResult = features[noduleLabel].setdefault('GradientGlcm', {}) GradientGLRLMResult = features[noduleLabel].setdefault('GradientGlrlm', {}) GradientGLSZMResult = features[noduleLabel].setdefault('GradientGlszm', {}) GradientGLDMResult = features[noduleLabel].setdefault('GradientGldm', {}) GradientNGTDMResult = features[noduleLabel].setdefault('GradientNGTDM', {}) for filterName in featuresList: subFeatureValue =eval("Gradient" + filterName + "Features.featureValues") for (key, val) in six.iteritems(subFeatureValue): exec("Gradient"+filterName+"Result[key]=val") #LocalBinaryPattern2D,LocalBinaryPattern3D if LocalBinaryPattern2D: for decompositionImage, decompositionName, inputKwargs in imageoperations.getLBP2DImage(sitkImage,sitkMask): for filterName in featuresList: exec("LBP2D"+filterName+"Features = "+filterName.lower()+".Radiomics"+filterName+"(decompositionImage, sitkMask, **inputKwargs)") exec("LBP2D"+filterName+"Features.enableAllFeatures()") exec("LBP2D"+filterName+"Features.calculateFeatures()") LBP2DFirstOrderResult = features[noduleLabel].setdefault('LBP2DFirstOrder', {}) LBP2DShapeResult = features[noduleLabel].setdefault('LBP2DShape', {}) LBP2DGLCMResult = features[noduleLabel].setdefault('LBP2DGlcm', {}) LBP2DGLRLMResult = features[noduleLabel].setdefault('LBP2DGlrlm', {}) LBP2DGLSZMResult = features[noduleLabel].setdefault('LBP2DGlszm', {}) LBP2DGLDMResult = features[noduleLabel].setdefault('LBP2DGldm', {}) LBP2DNGTDMResult = features[noduleLabel].setdefault('LBP2DNGTDM', {}) for filterName in featuresList: subFeatureValue =eval("LBP2D" + filterName + "Features.featureValues") for (key, val) in six.iteritems(subFeatureValue): exec("LBP2D"+filterName+"Result[key]=val") if LocalBinaryPattern3D: for decompositionImage, decompositionName, inputKwargs in imageoperations.getLBP3DImage(sitkImage,sitkMask): for filterName in featuresList: exec("LBP3D"+filterName+"Features = "+filterName.lower()+".Radiomics"+filterName+"(decompositionImage, sitkMask, **inputKwargs)") exec("LBP3D"+filterName+"Features.enableAllFeatures()") exec("LBP3D"+filterName+"Features.calculateFeatures()") LBP3DFirstOrderResult = features[noduleLabel].setdefault('LBP3DFirstOrder', {}) LBP3DShapeResult = features[noduleLabel].setdefault('LBP3DShape', {}) LBP3DGLCMResult = features[noduleLabel].setdefault('LBP3DGlcm', {}) LBP3DGLRLMResult = features[noduleLabel].setdefault('LBP3DGlrlm', {}) LBP3DGLSZMResult = features[noduleLabel].setdefault('LBP3DGlszm', {}) LBP3DGLDMResult = features[noduleLabel].setdefault('LBP3DGldm', {}) LBP3DNGTDMResult = features[noduleLabel].setdefault('LBP3DNGTDM', {}) for filterName in featuresList: subFeatureValue =eval("LBP3D" + filterName + "Features.featureValues") for (key, val) in six.iteritems(subFeatureValue): exec("LBP3D"+filterName+"Result[key]=val") return features
def calculateRadiomicsFromJson(niiFile, jsonFile,wavelet,LoG,Square,SquareRoot,Logarithm,\ Exponential,Gradient,LocalBinaryPattern2D,LocalBinaryPattern3D): # moduleConfig = get_current_config() # processing nii sitkImageParent = sitk.ReadImage(niiFile) direction = sitkImageParent.GetDirection() origin = sitkImageParent.GetOrigin() spacing = sitkImageParent.GetSpacing() # processing json f = open(jsonFile) p = ijson.parse(f) # print("p={}".format(p)) nodules = {} label = '' for prefix, _, value in p: # print() if re.match('Nodules.item\d+.Label', prefix) or prefix == 'Nodules.item.Label': label = value nodules[label] = {} nodules[label]['label'] = value nodules[label]['sliceMask'] = '' if re.match('Nodules.item\d+.mask.xBegin', prefix) or prefix == 'Nodules.item.mask.xBegin': nodules[label]['xBegin'] = float(value) if re.match('Nodules.item\d+.mask.yBegin', prefix) or prefix == 'Nodules.item.mask.yBegin': nodules[label]['yBegin'] = float(value) if re.match('Nodules.item\d+.mask.zBegin', prefix) or prefix == 'Nodules.item.mask.zBegin': nodules[label]['zBegin'] = float(value) if re.match('Nodules.item\d+.DimInPixelX', prefix) or prefix == 'Nodules.item.DimInPixelX': nodules[label]['DimInPixelX'] =int(float(value)) if re.match('Nodules.item\d+.DimInPixelY', prefix) or prefix == 'Nodules.item.DimInPixelY': nodules[label]['DimInPixelY'] = int(float(value)) if re.match('Nodules.item\d+.DimInPixelZ', prefix) or prefix == 'Nodules.item.DimInPixelZ': nodules[label]['DimInPixelZ'] = int(float(value)) if re.match('Nodules.item\d+.mask.sliceMask.item\d+', prefix) or prefix == 'Nodules.item.mask.sliceMask.item': nodules[label]['sliceMask'] += value # working on radiomics calculation features = {} kwargs = {'binWidth': 64, 'interpolator': sitk.sitkBSpline, 'resampledPixelSpacing': None} # print("nodules=",nodules) for noduleLabel in nodules: if 'DimInPixelX' not in nodules[noduleLabel]: continue bbox_dim = (nodules[noduleLabel]['DimInPixelX'], nodules[noduleLabel]['DimInPixelY'], \ nodules[noduleLabel]['DimInPixelZ']) bbox_ori = (nodules[noduleLabel]['xBegin'], nodules[noduleLabel]['yBegin'], \ nodules[noduleLabel]['zBegin']) print("bbox_dim={}".format(bbox_dim)) sitkMask = sitk.Image(bbox_dim[0], bbox_dim[1], bbox_dim[2], sitk.sitkUInt8) sitkMask.SetSpacing(spacing) sitkMask.SetOrigin(bbox_ori) sitkMask.SetDirection(direction) for z in range(bbox_dim[2]):#9 for y in range(bbox_dim[1]): #16 for x in range(bbox_dim[0]): #17 # print("x,y,z={}{}{}".format(x,y,z)) # print("{},{},{}".format(x,y,z)) idx = z * bbox_dim[1] * bbox_dim[0] + y * bbox_dim[0] + x # print("idx={}".format(idx)) v = int(nodules[noduleLabel]['sliceMask'][idx]) sitkMask.SetPixel(x, y, z, v) ori_matrix = (int(direction[0] * (bbox_ori[0] - origin[0]) / spacing[0]), \ int(direction[4] * (bbox_ori[1] - origin[1]) / spacing[1]), \ int(direction[8] * (bbox_ori[2] - origin[2]) / spacing[2])) # sitkMask = resample_sitkImage(sitkMask, (spacing[0]/2, spacing[1]/2, spacing[2]/2)) sitkImage = sitk.RegionOfInterest(sitkImageParent, sitkMask.GetSize(), ori_matrix) sitkImage.SetSpacing(spacing) sitkImage.SetOrigin(bbox_ori) sitkImage.SetDirection(direction) features[noduleLabel] = {} firstOrderFeatures = firstorder.RadiomicsFirstOrder(sitkImage, sitkMask, **kwargs) firstOrderFeatures.enableAllFeatures() firstOrderFeatures.calculateFeatures() firstOrderResult = features[noduleLabel].setdefault('firstorder', {}) for (key, val) in six.iteritems(firstOrderFeatures.featureValues): firstOrderResult[key] = val shapeFeatures = shape.RadiomicsShape(sitkImage, sitkMask, **kwargs) shapeFeatures.enableAllFeatures() shapeFeatures.calculateFeatures() shapeResult = features[noduleLabel].setdefault('shape', {}) for (key, val) in six.iteritems(shapeFeatures.featureValues): shapeResult[key] = val glcmFeatures = glcm.RadiomicsGLCM(sitkImage, sitkMask, **kwargs) glcmFeatures.enableAllFeatures() glcmFeatures.calculateFeatures() glcmResult = features[noduleLabel].setdefault('glcm', {}) for (key, val) in six.iteritems(glcmFeatures.featureValues): glcmResult[key] = val glrlmFeatures = glrlm.RadiomicsGLRLM(sitkImage, sitkMask, **kwargs) glrlmFeatures.enableAllFeatures() glrlmFeatures.calculateFeatures() glrlmResult = features[noduleLabel].setdefault('glrlm', {}) for (key, val) in six.iteritems(glrlmFeatures.featureValues): glrlmResult[key] = val glszmFeatures = glszm.RadiomicsGLSZM(sitkImage, sitkMask, **kwargs) glszmFeatures.enableAllFeatures() glszmFeatures.calculateFeatures() glszmResult = features[noduleLabel].setdefault('glszm', {}) for (key, val) in six.iteritems(glszmFeatures.featureValues): glszmResult[key] = val #added new feature of gldm gldmFeatures = gldm.RadiomicsGLDM(sitkImage, sitkMask, **kwargs) gldmFeatures.enableAllFeatures() gldmFeatures.calculateFeatures() gldmFeatures = features[noduleLabel].setdefault('gldm', {}) for (key, val) in six.iteritems(glszmFeatures.featureValues): gldmFeatures[key] = val #added new feature of ngtdm ngtdmFeatures = ngtdm.RadiomicsNGTDM(sitkImage, sitkMask, **kwargs) ngtdmFeatures.enableAllFeatures() ngtdmFeatures.calculateFeatures() ngtdmFeatures = features[noduleLabel].setdefault('ngtdm', {}) for (key, val) in six.iteritems(glszmFeatures.featureValues): ngtdmFeatures[key] = val featuresList = ["FirstOrder","Shape","GLCM","GLRLM","GLSZM","NGTDM","GLDM"] if LoG: sigmaValues = numpy.arange(5., 0., -.5)[::1] for logImage, imageTypeName, inputKwargs in imageoperations.getLoGImage(sitkImage, sitkMask,sigma=sigmaValues): for filterName in featuresList: exec("LoG"+filterName+"Features = "+filterName.lower()+".Radiomics"+filterName+"(logImage, sitkMask, **inputKwargs)") for feature in featuresList: exec("LoG"+feature+"Features.enableAllFeatures()") exec("LoG"+feature+"Features.calculateFeatures()") LoGFirstOrderResult = features[noduleLabel].setdefault('logFirstOrder', {}) LoGShapeResult = features[noduleLabel].setdefault('logShape', {}) LoGGLCMResult = features[noduleLabel].setdefault('logGlcm', {}) LoGGLRLMResult = features[noduleLabel].setdefault('logGlrlm', {}) LoGGLSZMResult = features[noduleLabel].setdefault('logGlszm', {}) LoGGLDMResult = features[noduleLabel].setdefault('logGldm', {}) LoGNGTDMResult = features[noduleLabel].setdefault('logNGTDM', {}) for filterName in featuresList: subFeatureValue =eval("LoG" + filterName + "Features.featureValues") for (key, val) in six.iteritems(subFeatureValue): exec("LoG"+filterName+"Result[key]=val") if wavelet: for decompositionImage, decompositionName, inputKwargs in imageoperations.getWaveletImage(sitkImage,sitkMask): for filterName in featuresList: exec("wavelet"+filterName+"Features = "+filterName.lower()+".Radiomics"+filterName+"(decompositionImage, sitkMask, **inputKwargs)") exec("wavelet"+filterName+"Features.enableAllFeatures()") exec("wavelet"+filterName+"Features.calculateFeatures()") waveletFirstOrderResult = features[noduleLabel].setdefault('waveletFirstOrder', {}) waveletShapeResult = features[noduleLabel].setdefault('waveletShape', {}) waveletGLCMResult = features[noduleLabel].setdefault('waveletGlcm', {}) waveletGLRLMResult = features[noduleLabel].setdefault('waveletGlrlm', {}) waveletGLSZMResult = features[noduleLabel].setdefault('waveletGlszm', {}) waveletGLDMResult = features[noduleLabel].setdefault('waveletGldm', {}) waveletNGTDMResult = features[noduleLabel].setdefault('waveletNGTDM', {}) for filterName in featuresList: subFeatureValue =eval("wavelet" + filterName + "Features.featureValues") for (key, val) in six.iteritems(subFeatureValue): exec("wavelet"+filterName+"Result[key]=val") if Square: # calculateSubFilterValues(imageType =="Square",features,noduleLabel,sitkImage,sitkMask) for decompositionImage, decompositionName, inputKwargs in imageoperations.getSquareImage(sitkImage,sitkMask): for filterName in featuresList: exec("square"+filterName+"Features = "+filterName.lower()+".Radiomics"+filterName+"(decompositionImage, sitkMask, **inputKwargs)") exec("square"+filterName+"Features.enableAllFeatures()") exec("square"+filterName+"Features.calculateFeatures()") squareFirstOrderResult = features[noduleLabel].setdefault('squareFirstOrder', {}) squareShapeResult = features[noduleLabel].setdefault('squareShape', {}) squareGLCMResult = features[noduleLabel].setdefault('squareGlcm', {}) squareGLRLMResult = features[noduleLabel].setdefault('squareGlrlm', {}) squareGLSZMResult = features[noduleLabel].setdefault('squareGlszm', {}) squareGLDMResult = features[noduleLabel].setdefault('squareGldm', {}) squareNGTDMResult = features[noduleLabel].setdefault('squareNGTDM', {}) for filterName in featuresList: subFeatureValue =eval("square" + filterName + "Features.featureValues") for (key, val) in six.iteritems(subFeatureValue): exec("square"+filterName+"Result[key]=val") if SquareRoot: for decompositionImage, decompositionName, inputKwargs in imageoperations.getSquareRootImage(sitkImage,sitkMask): for filterName in featuresList: exec("squareRoot"+filterName+"Features = "+filterName.lower()+".Radiomics"+filterName+"(decompositionImage, sitkMask, **inputKwargs)") exec("squareRoot"+filterName+"Features.enableAllFeatures()") exec("squareRoot"+filterName+"Features.calculateFeatures()") squareRootFirstOrderResult = features[noduleLabel].setdefault('squareRootFirstOrder', {}) squareRootShapeResult = features[noduleLabel].setdefault('squareRootShape', {}) squareRootGLCMResult = features[noduleLabel].setdefault('squareRootGlcm', {}) squareRootGLRLMResult = features[noduleLabel].setdefault('squareRootGlrlm', {}) squareRootGLSZMResult = features[noduleLabel].setdefault('squareRootGlszm', {}) squareRootGLDMResult = features[noduleLabel].setdefault('squareRootGldm', {}) squareRootNGTDMResult = features[noduleLabel].setdefault('squareRootNGTDM', {}) for filterName in featuresList: subFeatureValue =eval("squareRoot" + filterName + "Features.featureValues") for (key, val) in six.iteritems(subFeatureValue): exec("squareRoot"+filterName+"Result[key]=val") if Logarithm: for decompositionImage, decompositionName, inputKwargs in imageoperations.getLogarithmImage(sitkImage,sitkMask): for filterName in featuresList: exec("logarithm"+filterName+"Features = "+filterName.lower()+".Radiomics"+filterName+"(decompositionImage, sitkMask, **inputKwargs)") exec("logarithm"+filterName+"Features.enableAllFeatures()") exec("logarithm"+filterName+"Features.calculateFeatures()") logarithmFirstOrderResult = features[noduleLabel].setdefault('logarithmFirstOrder', {}) logarithmShapeResult = features[noduleLabel].setdefault('logarithmShape', {}) logarithmGLCMResult = features[noduleLabel].setdefault('logarithmGlcm', {}) logarithmGLRLMResult = features[noduleLabel].setdefault('logarithmGlrlm', {}) logarithmGLSZMResult = features[noduleLabel].setdefault('logarithmGlszm', {}) logarithmGLDMResult = features[noduleLabel].setdefault('logarithmGldm', {}) logarithmNGTDMResult = features[noduleLabel].setdefault('logarithmNGTDM', {}) for filterName in featuresList: subFeatureValue =eval("logarithm" + filterName + "Features.featureValues") for (key, val) in six.iteritems(subFeatureValue): exec("logarithm"+filterName+"Result[key]=val") if Exponential: for decompositionImage, decompositionName, inputKwargs in imageoperations.getExponentialImage(sitkImage,sitkMask): for filterName in featuresList: exec("Exponential"+filterName+"Features = "+filterName.lower()+".Radiomics"+filterName+"(decompositionImage, sitkMask, **inputKwargs)") exec("Exponential"+filterName+"Features.enableAllFeatures()") exec("Exponential"+filterName+"Features.calculateFeatures()") ExponentialFirstOrderResult = features[noduleLabel].setdefault('ExponentialFirstOrder', {}) ExponentialShapeResult = features[noduleLabel].setdefault('ExponentialShape', {}) ExponentialGLCMResult = features[noduleLabel].setdefault('ExponentialGlcm', {}) ExponentialGLRLMResult = features[noduleLabel].setdefault('ExponentialGlrlm', {}) ExponentialGLSZMResult = features[noduleLabel].setdefault('ExponentialGlszm', {}) ExponentialGLDMResult = features[noduleLabel].setdefault('ExponentialGldm', {}) ExponentialNGTDMResult = features[noduleLabel].setdefault('ExponentialNGTDM', {}) for filterName in featuresList: subFeatureValue =eval("Exponential" + filterName + "Features.featureValues") for (key, val) in six.iteritems(subFeatureValue): exec("Exponential"+filterName+"Result[key]=val") if Gradient: for decompositionImage, decompositionName, inputKwargs in imageoperations.getGradientImage(sitkImage,sitkMask): for filterName in featuresList: exec("Gradient"+filterName+"Features = "+filterName.lower()+".Radiomics"+filterName+"(decompositionImage, sitkMask, **inputKwargs)") exec("Gradient"+filterName+"Features.enableAllFeatures()") exec("Gradient"+filterName+"Features.calculateFeatures()") GradientFirstOrderResult = features[noduleLabel].setdefault('GradientFirstOrder', {}) GradientShapeResult = features[noduleLabel].setdefault('GradientShape', {}) GradientGLCMResult = features[noduleLabel].setdefault('GradientGlcm', {}) GradientGLRLMResult = features[noduleLabel].setdefault('GradientGlrlm', {}) GradientGLSZMResult = features[noduleLabel].setdefault('GradientGlszm', {}) GradientGLDMResult = features[noduleLabel].setdefault('GradientGldm', {}) GradientNGTDMResult = features[noduleLabel].setdefault('GradientNGTDM', {}) for filterName in featuresList: subFeatureValue =eval("Gradient" + filterName + "Features.featureValues") for (key, val) in six.iteritems(subFeatureValue): exec("Gradient"+filterName+"Result[key]=val") #LocalBinaryPattern2D,LocalBinaryPattern3D if LocalBinaryPattern2D: for decompositionImage, decompositionName, inputKwargs in imageoperations.getLBP2DImage(sitkImage,sitkMask): for filterName in featuresList: exec("LBP2D"+filterName+"Features = "+filterName.lower()+".Radiomics"+filterName+"(decompositionImage, sitkMask, **inputKwargs)") exec("LBP2D"+filterName+"Features.enableAllFeatures()") exec("LBP2D"+filterName+"Features.calculateFeatures()") LBP2DFirstOrderResult = features[noduleLabel].setdefault('LBP2DFirstOrder', {}) LBP2DShapeResult = features[noduleLabel].setdefault('LBP2DShape', {}) LBP2DGLCMResult = features[noduleLabel].setdefault('LBP2DGlcm', {}) LBP2DGLRLMResult = features[noduleLabel].setdefault('LBP2DGlrlm', {}) LBP2DGLSZMResult = features[noduleLabel].setdefault('LBP2DGlszm', {}) LBP2DGLDMResult = features[noduleLabel].setdefault('LBP2DGldm', {}) LBP2DNGTDMResult = features[noduleLabel].setdefault('LBP2DNGTDM', {}) for filterName in featuresList: subFeatureValue =eval("LBP2D" + filterName + "Features.featureValues") for (key, val) in six.iteritems(subFeatureValue): exec("LBP2D"+filterName+"Result[key]=val") if LocalBinaryPattern3D: for decompositionImage, decompositionName, inputKwargs in imageoperations.getLBP3DImage(sitkImage,sitkMask): for filterName in featuresList: exec("LBP3D"+filterName+"Features = "+filterName.lower()+".Radiomics"+filterName+"(decompositionImage, sitkMask, **inputKwargs)") exec("LBP3D"+filterName+"Features.enableAllFeatures()") exec("LBP3D"+filterName+"Features.calculateFeatures()") LBP3DFirstOrderResult = features[noduleLabel].setdefault('LBP3DFirstOrder', {}) LBP3DShapeResult = features[noduleLabel].setdefault('LBP3DShape', {}) LBP3DGLCMResult = features[noduleLabel].setdefault('LBP3DGlcm', {}) LBP3DGLRLMResult = features[noduleLabel].setdefault('LBP3DGlrlm', {}) LBP3DGLSZMResult = features[noduleLabel].setdefault('LBP3DGlszm', {}) LBP3DGLDMResult = features[noduleLabel].setdefault('LBP3DGldm', {}) LBP3DNGTDMResult = features[noduleLabel].setdefault('LBP3DNGTDM', {}) for filterName in featuresList: subFeatureValue =eval("LBP3D" + filterName + "Features.featureValues") for (key, val) in six.iteritems(subFeatureValue): exec("LBP3D"+filterName+"Result[key]=val") return features
mask_path = '../mask' Tumor = os.listdir(tumor_path) Mask = os.listdir(mask_path) file = Workbook(encoding='ascii') table = file.add_sheet('data') for idx in xrange(len(Tumor)): image = sitk.ReadImage(os.path.join(tumor_path, Tumor[idx])) mask = sitk.ReadImage(os.path.join(mask_path, Mask[idx])) shapeFeatures = shape.RadiomicsShape(image, mask) firstorderFeatures = firstorder.RadiomicsFirstOrder(image, mask) glcmFeatures = glcm.RadiomicsGLCM(image, mask) gldmFeatures = gldm.RadiomicsGLDM(image, mask) glrlmFeatures = glrlm.RadiomicsGLRLM(image, mask) glszmFeatures = glszm.RadiomicsGLSZM(image, mask) ngtdmFeatures = ngtdm.RadiomicsNGTDM(image, mask) shapeFeatures.enableAllFeatures() glcmFeatures.enableAllFeatures() firstorderFeatures.enableAllFeatures() gldmFeatures.enableAllFeatures() glrlmFeatures.enableAllFeatures() glszmFeatures.enableAllFeatures() ngtdmFeatures.enableAllFeatures() shapeFeatures.execute() glszmFeatures.execute() glcmFeatures.execute() firstorderFeatures.execute() gldmFeatures.execute() glrlmFeatures.execute()
def extractor(image_array, mask_array, applyLog = False,applyWavelet = False ): feature_vectors = {} cache_file = os.path.join(DATA_CACHE_PATH_OUT,'cache_%s.nrrd'%random.random()) nrrd.write(cache_file, image_array) image = sitk.ReadImage(cache_file) nrrd.write(cache_file, mask_array) mask = sitk.ReadImage(cache_file) settings = {'binWidth': 25, 'interpolator': None, #sitk.sitkBSpline, 'resampledPixelSpacing': None} # interpolator = settings.get('interpolator') # resampledPixelSpacing = settings.get('resampledPixelSpacing') # if interpolator is not None and resampledPixelSpacing is not None: # image, mask = imageoperations.resampleImage(image, mask, **settings) # bb, correctedMask = imageoperations.checkMask(image, mask) # if correctedMask is not None: # mask = correctedMask # image, mask = imageoperations.cropToTumorMask(image, mask, bb) features = firstorder.RadiomicsFirstOrder(image, mask, **settings) # features.enableFeatureByName('Mean', True) features.enableAllFeatures() # print('Will calculate the following first order features: ') # for f in features.enabledFeatures.keys(): # print(' ', f) # print(getattr(features, 'get%sFeatureValue' % f).__doc__) # print('Calculating first order features...') results = features.execute() # print('done') # print('Calculated first order features: ') for (key, val) in six.iteritems(results): firstOrderFeatureName = '%s_%s' % ('firstOrder', key) if firstOrderFeatureName not in feature_vectors: feature_vectors[firstOrderFeatureName] = val else: print('Error: firstOrder key existing! %s'%firstOrderFeatureName) # break # print(' ', key, ':', val) print('ADDED %s first Order Features'%len(results)) # # Show Shape features # features = shape.RadiomicsShape(image, mask, **settings) features.enableAllFeatures() # print('Will calculate the following Shape features: ') # for f in features.enabledFeatures.keys(): # print(' ', f) # print(getattr(features, 'get%sFeatureValue' % f).__doc__) # print('Calculating Shape features...') results = features.execute() # print('done') # print('Calculated Shape features: ') for (key, val) in six.iteritems(results): ShapeFeatureName = '%s_%s' % ('Shape', key) if ShapeFeatureName not in feature_vectors: feature_vectors[ShapeFeatureName] = val else: print('Error: shape key existing! %s'%ShapeFeatureName) # break # print(' ', key, ':', val) print('ADDED %s shape Features'%len(results)) # # Show GLCM features: Gray Level Co-occurrence Matrix (GLCM) Features # features = glcm.RadiomicsGLCM(image, mask, **settings) features.enableAllFeatures() # print('Will calculate the following GLCM features: ') # for f in features.enabledFeatures.keys(): # print(' ', f) # print(getattr(features, 'get%sFeatureValue' % f).__doc__) # print('Calculating GLCM features...') results = features.execute() # print('done') # print('Calculated GLCM features: ') for (key, val) in six.iteritems(results): GLCMFeatureName = '%s_%s' % ('GLCM', key) if GLCMFeatureName not in feature_vectors: feature_vectors[GLCMFeatureName] = val else: print('Error: GLCM key existing! %s'%GLCMFeatureName) # break # print(' ', key, ':', val) print('ADDED %s GLCM Features'%len(results)) # # Show GLSZM features; Gray Level Size Zone Matrix (GLSZM) Features # features = glszm.RadiomicsGLSZM(image, mask, **settings) features.enableAllFeatures() # print('Will calculate the following GLSZM features: ') # for f in features.enabledFeatures.keys(): # print(' ', f) # print(getattr(features, 'get%sFeatureValue' % f).__doc__) # print('Calculating GLSZM features...') results = features.execute() # print('Calculated GLSZM features: ') for (key, val) in six.iteritems(results): GLSZMFeatureName = '%s_%s' % ('GLSZM', key) if GLSZMFeatureName not in feature_vectors: feature_vectors[GLSZMFeatureName] = val else: print('Error: GLSZM key existing! %s'%GLSZMFeatureName) # break # print(' ', key, ':', val) print('ADDED %s GLSZ Features'%len(results)) # # Show GLRLM features; Gray Level Run Length Matrix (GLRLM) Features # features = glrlm.RadiomicsGLRLM(image, mask, **settings) features.enableAllFeatures() # print('Will calculate the following GLRLM features: ') # for f in features.enabledFeatures.keys(): # print(' ', f) # print(getattr(features, 'get%sFeatureValue' % f).__doc__) # print('Calculating GLRLM features...') results = features.execute() # print('done') # print('Calculated GLRLM features: ') for (key, val) in six.iteritems(results): GLRLMFeatureName = '%s_%s' % ('GLRLM', key) if GLRLMFeatureName not in feature_vectors: feature_vectors[GLRLMFeatureName] = val else: print('Error: GLRLM key existing! %s'%GLRLMFeatureName) # break # print(' ', key, ':', val) print('ADDED %s GLRM Features'%len(results)) # # Show NGTDM features; Neighbouring Gray Tone Difference Matrix (NGTDM) Features # features = ngtdm.RadiomicsNGTDM(image, mask, **settings) features.enableAllFeatures() # print('Will calculate the following NGTDM features: ') # for f in features.enabledFeatures.keys(): # print(' ', f) # print(getattr(features, 'get%sFeatureValue' % f).__doc__) # print('Calculating NGTDM features...') results = features.execute() # print('done') # print('Calculated NGTDM features: ') for (key, val) in six.iteritems(results): NGTDMFeatureName = '%s_%s' % ('NGTDM', key) if NGTDMFeatureName not in feature_vectors: feature_vectors[NGTDMFeatureName] = val else: print('Error: NGTDM key existing! %s'%NGTDMFeatureName) # break # print(' ', key, ':', val) print('ADDED %s NGTDM Features'%len(results)) # # Show GLDM features; Gray Level Dependence Matrix (GLDM) Features # features = gldm.RadiomicsGLDM(image, mask, **settings) features.enableAllFeatures() # print('Will calculate the following GLDM features: ') # for f in features.enabledFeatures.keys(): # print(' ', f) # print(getattr(features, 'get%sFeatureValue' % f).__doc__) # print('Calculating GLDM features...') results = features.execute() # print('done') # print('Calculated GLDM features: ') for (key, val) in six.iteritems(results): GLDMFeatureName = '%s_%s' % ('GLDM', key) if GLDMFeatureName not in feature_vectors: feature_vectors[GLDMFeatureName] = val else: print('Error: GLDM key existing! %s'%GLDMFeatureName) # break # print(' ', key, ':', val) print('ADDED %s GLDM Features'%len(results)) # # Show FirstOrder features, calculated on a LoG filtered image # if applyLog: sigmaValues = np.arange(5., 0., -.5)[::1] cnt = 0 for logImage, imageTypeName, inputKwargs in imageoperations.getLoGImage(image, mask, sigma=sigmaValues): cnt += 1 features = firstorder.RadiomicsFirstOrder(logImage, mask, **inputKwargs) features.enableAllFeatures() results = features.execute() print('ADDEDING %s/%s Features...'%(cnt, len(logImage))) for (key, val) in six.iteritems(results): laplacianFeatureName = '%s_%s' % (imageTypeName, key) if laplacianFeatureName not in feature_vectors: feature_vectors[laplacianFeatureName] = val else: print('Error: LoG key existing! %s'%laplacianFeatureName) # break # print(' ', laplacianFeatureName, ':', val) # # Show FirstOrder features, calculated on a wavelet filtered image # if applyWavelet: cnt = 0 for decompositionImage, decompositionName, inputKwargs in imageoperations.getWaveletImage(image, mask): cnt+=1 features = firstorder.RadiomicsFirstOrder(decompositionImage, mask, **inputKwargs) features.enableAllFeatures() results = features.execute() print('ADDEDING %s/%s WAVELET Features...'%(cnt, str(decompositionName))) print('Calculated firstorder features with wavelet ', decompositionName) for (key, val) in six.iteritems(results): waveletFeatureName = '%s_%s' % (str(decompositionName), key) if waveletFeatureName not in feature_vectors: feature_vectors[waveletFeatureName] = val else: print('Error: wavelet key existing! %s'%waveletFeatureName) # break # print(' ', waveletFeatureName, ':', val) mask = None image = None features = None os.remove(cache_file) print('DONE!') return feature_vectors
def features_extractor(patients_nrrd_path, valid_IDs, applyLog = False, applyWavelet = False): feature_vectors = {} cnt = 0 for case_id in valid_IDs: feature_vectors[case_id] = {} cnt += 1 # try: ct_nrrd_path = os.path.join(patients_nrrd_path,case_id, "image.nrrd") ss_nrrd_path = os.path.join(patients_nrrd_path,case_id, "mask.nrrd") print("Reading ct image") image = sitk.ReadImage(ct_nrrd_path) # image, header = nrrd.read(ct_nrrd_path) print("Reading roi mask") mask = sitk.ReadImage(ss_nrrd_path) # mask, header = nrrd.read(ss_nrrd_path) print("Getting ct image array") image_array = sitk.GetArrayFromImage(image) print("Getting roi mask array") mask_array = sitk.GetArrayFromImage(mask) print(image_array.shape, mask_array.shape) # simple_plot_nrrd(image_array, mask_array, sliceNumber=75, plotSrc='sitk') print (cnt, "_ Calculating features: ",case_id) settings = {'binWidth': 25, 'interpolator': sitk.sitkBSpline, 'resampledPixelSpacing': None} interpolator = settings.get('interpolator') resampledPixelSpacing = settings.get('resampledPixelSpacing') if interpolator is not None and resampledPixelSpacing is not None: image, mask = imageoperations.resampleImage(image, mask, **settings) bb, correctedMask = imageoperations.checkMask(image, mask) if correctedMask is not None: mask = correctedMask image, mask = imageoperations.cropToTumorMask(image, mask, bb) firstOrderFeatures = firstorder.RadiomicsFirstOrder(image, mask, **settings) # firstOrderFeatures.enableFeatureByName('Mean', True) firstOrderFeatures.enableAllFeatures() # print('Will calculate the following first order features: ') # for f in firstOrderFeatures.enabledFeatures.keys(): # print(' ', f) # print(getattr(firstOrderFeatures, 'get%sFeatureValue' % f).__doc__) # print('Calculating first order features...') results = firstOrderFeatures.execute() # print('done') print('Calculated first order features: ') for (key, val) in six.iteritems(results): firstOrderFeatureName = '%s_%s' % ('firstOrder', key) if firstOrderFeatureName not in feature_vectors[case_id]: feature_vectors[case_id][firstOrderFeatureName] = val else: print('Error: firstOrder key existing! %s'%firstOrderFeatureName) # break # print(' ', key, ':', val) # # Show Shape features # shapeFeatures = shape.RadiomicsShape(image, mask, **settings) shapeFeatures.enableAllFeatures() # print('Will calculate the following Shape features: ') # for f in shapeFeatures.enabledFeatures.keys(): # print(' ', f) # print(getattr(shapeFeatures, 'get%sFeatureValue' % f).__doc__) # print('Calculating Shape features...') results = shapeFeatures.execute() # print('done') print('Calculated Shape features: ') for (key, val) in six.iteritems(results): ShapeFeatureName = '%s_%s' % ('Shape', key) if ShapeFeatureName not in feature_vectors[case_id]: feature_vectors[case_id][ShapeFeatureName] = val else: print('Error: shape key existing! %s'%ShapeFeatureName) # break # print(' ', key, ':', val) # # Show GLCM features: Gray Level Co-occurrence Matrix (GLCM) Features # glcmFeatures = glcm.RadiomicsGLCM(image, mask, **settings) glcmFeatures.enableAllFeatures() # print('Will calculate the following GLCM features: ') # for f in glcmFeatures.enabledFeatures.keys(): # print(' ', f) # print(getattr(glcmFeatures, 'get%sFeatureValue' % f).__doc__) # print('Calculating GLCM features...') results = glcmFeatures.execute() # print('done') print('Calculated GLCM features: ') for (key, val) in six.iteritems(results): GLCMFeatureName = '%s_%s' % ('GLCM', key) if GLCMFeatureName not in feature_vectors[case_id]: feature_vectors[case_id][GLCMFeatureName] = val else: print('Error: GLCM key existing! %s'%GLCMFeatureName) # break # print(' ', key, ':', val) # # Show GLSZM features; Gray Level Size Zone Matrix (GLSZM) Features # glszmFeatures = glszm.RadiomicsGLSZM(image, mask, **settings) glszmFeatures.enableAllFeatures() # print('Will calculate the following GLSZM features: ') # for f in glszmFeatures.enabledFeatures.keys(): # print(' ', f) # print(getattr(glszmFeatures, 'get%sFeatureValue' % f).__doc__) # print('Calculating GLSZM features...') results = glszmFeatures.execute() print('done') print('Calculated GLSZM features: ') for (key, val) in six.iteritems(results): GLSZMFeatureName = '%s_%s' % ('GLSZM', key) if GLSZMFeatureName not in feature_vectors[case_id]: feature_vectors[case_id][GLSZMFeatureName] = val else: print('Error: GLSZM key existing! %s'%GLSZMFeatureName) # break # print(' ', key, ':', val) # # Show GLRLM features; Gray Level Run Length Matrix (GLRLM) Features # glrlmFeatures = glrlm.RadiomicsGLRLM(image, mask, **settings) glrlmFeatures.enableAllFeatures() # print('Will calculate the following GLRLM features: ') # for f in glrlmFeatures.enabledFeatures.keys(): # print(' ', f) # print(getattr(glrlmFeatures, 'get%sFeatureValue' % f).__doc__) # print('Calculating GLRLM features...') results = glrlmFeatures.execute() # print('done') print('Calculated GLRLM features: ') for (key, val) in six.iteritems(results): GLRLMFeatureName = '%s_%s' % ('GLRLM', key) if GLRLMFeatureName not in feature_vectors[case_id]: feature_vectors[case_id][GLRLMFeatureName] = val else: print('Error: GLRLM key existing! %s'%GLRLMFeatureName) # break # print(' ', key, ':', val) # # Show NGTDM features; Neighbouring Gray Tone Difference Matrix (NGTDM) Features # ngtdmFeatures = ngtdm.RadiomicsNGTDM(image, mask, **settings) ngtdmFeatures.enableAllFeatures() # print('Will calculate the following NGTDM features: ') # for f in ngtdmFeatures.enabledFeatures.keys(): # print(' ', f) # print(getattr(ngtdmFeatures, 'get%sFeatureValue' % f).__doc__) # print('Calculating NGTDM features...') results = ngtdmFeatures.execute() # print('done') print('Calculated NGTDM features: ') for (key, val) in six.iteritems(results): NGTDMFeatureName = '%s_%s' % ('NGTDM', key) if NGTDMFeatureName not in feature_vectors[case_id]: feature_vectors[case_id][NGTDMFeatureName] = val else: print('Error: NGTDM key existing! %s'%NGTDMFeatureName) # break # print(' ', key, ':', val) # # Show GLDM features; Gray Level Dependence Matrix (GLDM) Features # gldmFeatures = gldm.RadiomicsGLDM(image, mask, **settings) gldmFeatures.enableAllFeatures() # print('Will calculate the following GLDM features: ') # for f in gldmFeatures.enabledFeatures.keys(): # print(' ', f) # print(getattr(gldmFeatures, 'get%sFeatureValue' % f).__doc__) # print('Calculating GLDM features...') results = gldmFeatures.execute() # print('done') print('Calculated GLDM features: ') for (key, val) in six.iteritems(results): GLDMFeatureName = '%s_%s' % ('GLDM', key) if GLDMFeatureName not in feature_vectors[case_id]: feature_vectors[case_id][GLDMFeatureName] = val else: print('Error: GLDM key existing! %s'%GLDMFeatureName) # break # print(' ', key, ':', val) # # Show FirstOrder features, calculated on a LoG filtered image # if applyLog: sigmaValues = np.arange(5., 0., -.5)[::1] for logImage, imageTypeName, inputKwargs in imageoperations.getLoGImage(image, mask, sigma=sigmaValues): logFirstorderFeatures = firstorder.RadiomicsFirstOrder(logImage, mask, **inputKwargs) logFirstorderFeatures.enableAllFeatures() results = logFirstorderFeatures.execute() for (key, val) in np.iteritems(results): laplacianFeatureName = '%s_%s' % (imageTypeName, key) if laplacianFeatureName not in feature_vectors[case_id]: feature_vectors[case_id][laplacianFeatureName] = val else: print('Error: LoG key existing! %s'%laplacianFeatureName) # break # print(' ', laplacianFeatureName, ':', val) # # Show FirstOrder features, calculated on a wavelet filtered image # if applyWavelet: for decompositionImage, decompositionName, inputKwargs in imageoperations.getWaveletImage(image, mask): waveletFirstOrderFeaturs = firstorder.RadiomicsFirstOrder(decompositionImage, mask, **inputKwargs) waveletFirstOrderFeaturs.enableAllFeatures() results = waveletFirstOrderFeaturs.execute() print('Calculated firstorder features with wavelet ', decompositionName) for (key, val) in six.iteritems(results): waveletFeatureName = '%s_%s' % (str(decompositionName), key) if waveletFeatureName not in feature_vectors[case_id]: feature_vectors[case_id][waveletFeatureName] = val else: print('Error: wavelet key existing! %s'%waveletFeatureName) # break # print(' ', waveletFeatureName, ':', val) mask = None image = None return feature_vectors