""" It performs data-based evaluation """ import numpy as np import cv2 from sklearn.metrics import confusion_matrix import os import pandas as pd import warnings warnings.filterwarnings("ignore") # Chronic wound dataset directory dir_label = r'.\azh_wound_care_center_dataset_patches\test\labels' # label directory dir_pred = r'.\predictions\OldDFU' # prediction directory HARD_LINE = True names = os.listdir(dir_label) stp, stn, sfp, sfn = 0, 0, 0, 0 ep = 1e-6 save_dir_pred = r'.\predictions' # Create dataframe to store records df = pd.DataFrame(index=[], columns = [ 'Name', 'Accuracy', 'Specificity', 'iou', 'Precision', 'Recall', 'Dice'], dtype='object') # Create dataframe to store data-based record df_data = pd.DataFrame(index=[], columns = [ 'Name', 'type', 'Accuracy', 'Specificity', 'iou', 'Precision', 'Recall', 'Dice', 'stp', 'stn', 'sfp', 'sfn'], dtype='object') for i, name in enumerate(names): # image = cv2.imread(os.path.join(dir_im, name))[:,:,::-1] gt_mask = cv2.imread(os.path.join(dir_label, name), 0) # Note: Image shape: torch.Size([1, 3, 512, 512]) and mask shape: torch.Size([1, 1, 512, 512]) pr_mask = cv2.imread(os.path.join(dir_pred, name), 0) # Move to CPU and convert to numpy gt_mask = np.squeeze(gt_mask) pred = np.squeeze(pr_mask) # Calculate accuracy, specificity, iou, precision, recall, and dice flat_mask = np.squeeze(gt_mask).flatten() flat_pred = np.squeeze(pred).flatten() # Calculate tp, fp, tn, fn unq_mask_val = np.unique(flat_mask) # unique values in the mask. For binary image, it should be 0 and 1 'Case I: If there is no GT pixels in the image' if len(unq_mask_val)==1 and unq_mask_val==0: # Only one unique mask value and it is zero 'Case I.a: If both GT and prediction are black' if np.array_equal(flat_mask, flat_pred): # Calculate metrics for image-based evaluation. This time consider background as y_true. acc, sp, p, r, dice, iou = 100, 100, 100, 100, 100, 100 print("Img # {:1s}, Image {:1s}: acc: {:3f}, sp: {:3f}, iou: {:3f}, p: {:3f}, r: {:3f}, dice: {:3f}".format(str(i+1), name, acc, sp, iou, p, r, dice)) # Calculate the confusion matrix for data-based evaluation # Only tn will be counted. All others will be zero. Because the GT and the prediction # both have 0 pixels only. So, everything is truly negative. tn, fp, fn, tp = len(flat_mask), 0, 0, 0 else: 'Case I.b: If GT is black, but prediction not' if HARD_LINE: # If HARD_LINE is True, then all metrics will be set to 0s. # Calculate metrics for image-based evaluation acc, sp, p, r, dice, iou = 0, 0, 0, 0, 0, 0 # Calculate confusion matrix for data-based evaluation tp, fn = 0, 0 fp = np.count_nonzero(flat_pred) # no. of non-zero pixels tn = len(flat_pred) - fp # no. of zero intensity pixels else: # If HARD_LINE is False, then metrics will be calculated considering # background pixels as y_true. # Calculate metrics for image-based evaluation. # This time consider background as y_true. # Invert (logical NOT) GT and prediction, meaning background will be considered as foreground now. invt_flat_mask = np.logical_not(flat_mask) * 1 invt_flat_pred = np.logical_not(flat_pred) * 1 itn, ifp, ifn, itp = confusion_matrix(invt_flat_mask, invt_flat_pred).ravel() # Calculate metrics for image-based evaluation acc = ((itp + itn)/(itp + itn + ifn + ifp))*100 sp = (itn/(itn + ifp + ep))*100 p = (itp/(itp + ifp + ep))*100 r = (itp/(itp + ifn + ep))*100 dice = 0#(2 * itp / (2 * itp + ifp + ifn))*100 iou = (itp/(itp + ifp + ifn + ep)) * 100 print("Img # {:1s}, Image {:1s}: acc: {:3f}, sp: {:3f}, iou: {:3f}, p: {:3f}, r: {:3f}, dice: {:3f}".format(str(i+1), name, acc, sp, iou, p, r, dice)) # Calculate the confusion matrix for data-based evaluation # Do not do inversion (logical NOT). There will be some fp and tn. tp and fn will be 0. tn, fp, fn, tp = confusion_matrix(flat_mask, flat_pred).ravel() else: 'Case II: If there is some GT pixels in the image' tn, fp, fn, tp = confusion_matrix(flat_mask, flat_pred).ravel() # Calculate metrics acc = ((tp + tn)/(tp + tn + fn + fp))*100 sp = (tn/(tn + fp + ep))*100 p = (tp/(tp + fp + ep))*100 r = (tp/(tp + fn + ep))*100 dice = (2 * tp / (2 * tp + fp + fn))*100 iou = (tp/(tp + fp + fn + ep)) * 100 print("Img # {:1s}, Image {:1s}: acc: {:3f}, sp: {:3f}, iou: {:3f}, p: {:3f}, r: {:3f}, dice: {:3f}".format(str(i+1), name, acc, sp, iou, p, r, dice)) # Keep adding tp, tn, fp, and fn stp += tp stn += tn sfp += fp sfn += fn # Add to dataframe tmp = pd.Series([name, acc, sp, iou, p, r, dice], index=['Name', 'Accuracy', 'Specificity', 'iou', 'Precision', 'Recall', 'Dice']) df = df.append(tmp, ignore_index = True) df.to_csv(os.path.join(save_dir_pred, 'result_best_model.csv'), index=False) print("Mean Accuracy: ", df["Accuracy"].mean()) print("Mean Specificity: ", df["Specificity"].mean()) print('Mean IoU: ', df['iou'].mean()) print("Mean precision: ", df["Precision"].mean()) print("Mean recall: ", df["Recall"].mean()) print("Mean dice: ", df["Dice"].mean()) siou = (stp/(stp + sfp + sfn + ep))*100 sprecision = (stp/(stp + sfp + ep))*100 srecall = (stp/(stp + sfn + ep))*100 sdice = (2 * stp / (2 * stp + sfp + sfn))*100 print('siou:', siou) print('sprecision:', sprecision) print('srecall:', srecall) print('sdice:', sdice) # Save data-based result in a text file with open(os.path.join(save_dir_pred, 'result_data_based_best_model.txt'), 'w') as f: print(f'siou = {siou}', file=f) print(f'sprecision = {sprecision}', file=f) print(f'srecall = {srecall}', file=f) print(f'sdice = {sdice}', file=f)