import torch import yaml import sys import copy import os sys.path.append("/home/ubuntu/Desktop/Domain_Adaptation_Project/repos/SVDSAM/") from data_utils import * from model import * from utils import * label_names = ['Liver', 'Tumor'] # visualize_li = [[1,0,0],[0,1,0],[1,0,0], [0,0,1], [0,0,1]] label_dict = {} # visualize_dict = {} for i,ln in enumerate(label_names): label_dict[ln] = i # visualize_dict[ln] = visualize_li[i] def parse_args(): parser = argparse.ArgumentParser() parser.add_argument('--data_config', default='config_tmp.yml', help='data config file path') parser.add_argument('--model_config', default='model_baseline.yml', help='model config file path') parser.add_argument('--pretrained_path', default=None, help='pretrained model path') parser.add_argument('--save_path', default='checkpoints/temp.pth', help='pretrained model path') parser.add_argument('--gt_path', default='', help='ground truth path') parser.add_argument('--device', default='cuda:0', help='device to train on') parser.add_argument('--labels_of_interest', default='Left Prograsp Forceps,Maryland Bipolar Forceps,Right Prograsp Forceps,Left Large Needle Driver,Right Large Needle Driver', help='labels of interest') parser.add_argument('--codes', default='1,2,1,3,3', help='numeric label to save per instrument') args = parser.parse_args() return args def main(): args = parse_args() with open(args.data_config, 'r') as f: data_config = yaml.load(f, Loader=yaml.FullLoader) with open(args.model_config, 'r') as f: model_config = yaml.load(f, Loader=yaml.FullLoader) #make folder to save visualizations os.makedirs(os.path.join(args.save_path,"preds"),exist_ok=True) os.makedirs(os.path.join(args.save_path,"rescaled_preds"),exist_ok=True) os.makedirs(os.path.join(args.save_path,"rescaled_gt"),exist_ok=True) #load model model = Prompt_Adapted_SAM(config=model_config, label_text_dict=label_dict, device=args.device, training_strategy='svdtuning') # model = Prompt_Adapted_SAM(config=model_config, label_text_dict=label_dict, device=args.device, training_strategy='lora') #legacy model support sdict = torch.load(args.pretrained_path, map_location=args.device) # for key in list(sdict.keys()): # if 'sam_encoder.neck' in key: # if '0' in key: # new_key = key.replace('0','conv1') # if '1' in key: # new_key = key.replace('1','ln1') # if '2' in key: # new_key = key.replace('2','conv2') # if '3' in key: # new_key = key.replace('3','ln2') # sdict[new_key] = sdict[key] # _ = sdict.pop(key) # if 'mask_decoder' in key: # if 'trainable' in key: # _ = sdict.pop(key) model.load_state_dict(sdict,strict=True) model = model.to(args.device) model = model.eval() #load data transform data_transform = LiTS2_Transform(config=data_config) #dice tumor_dices = [] tumor_ious=[] liver_dices = [] liver_ious=[] #load data root_path = "/media/ubuntu/New Volume/jay/LiTS2/archive" imgs_path = os.path.join(root_path, 'dataset_6/dataset_6') test_csv = pd.read_csv(os.path.join(root_path, 'lits_test.csv')) for i in range(len(test_csv)): if i%10!=0: continue img_path = (os.path.join(root_path,'dataset_6',test_csv['filepath'].iloc[i][18:])) image_name = test_csv['filepath'].iloc[i][28:] liver_mask_path = os.path.join(root_path,'dataset_6',test_csv['liver_maskpath'].iloc[i][18:]) tumor_mask_path = os.path.join(root_path,'dataset_6',test_csv['tumor_maskpath'].iloc[i][18:]) # print(img_path) img = torch.as_tensor(np.array(Image.open(img_path).convert("RGB"))) img = img.permute(2,0,1) C,H,W = img.shape #make a dummy mask of shape 1XHXW try: liver_label = torch.Tensor(np.array(Image.open(liver_mask_path)))[:,:,0] tumor_label = torch.Tensor(np.array(Image.open(tumor_mask_path)))[:,:,0] except: liver_label = torch.zeros(H, W) tumor_label = torch.zeros(H, W) # label = np.array(Image.open(gt_path).convert("RGB")) # temp = np.zeros((H,W)).astype('uint8') # selected_color_list = label_dict[args.labels_of_interest] # for c in selected_color_list: # temp = temp | (np.all(np.where(label==c,1,0),axis=2)) # # plt.imshow(gold) # # plt.show() # mask = torch.Tensor(temp).unsqueeze(0) liver_label = liver_label.unsqueeze(0) liver_label = (liver_label>0)+0 tumor_label = tumor_label.unsqueeze(0) tumor_label = (tumor_label>0)+0 #convert all grayscale pixels due to resizing back to 0, 1 img1, liver_label = data_transform(img, liver_label, is_train=False, apply_norm=True) liver_label = (liver_label>=0.5)+0 # liver_label = liver_label[0] #convert all grayscale pixels due to resizing back to 0, 1 _, tumor_label = data_transform(img, tumor_label, is_train=False, apply_norm=True) tumor_label = (tumor_label>=0.5)+0 # tumor_label = tumor_label[0] #get image embeddings img = img1.unsqueeze(0).to(args.device) #1XCXHXW img_embeds = model.get_image_embeddings(img) # generate masks for all labels of interest img_embeds_repeated = img_embeds.repeat(1,1,1,1) x_text = ['Liver'] x_text2 = ['Tumor'] masks_liver = model.get_masks_for_multiple_labels(img_embeds_repeated, x_text).cpu() masks_tumor = model.get_masks_for_multiple_labels(img_embeds_repeated, x_text2).cpu() plt.imshow((masks_liver[0]>=0.5), cmap='gray') plt.savefig(os.path.join(args.save_path,'rescaled_preds', image_name[:-4] +'_liver.png')) plt.close() # plt.show() plt.imshow((masks_tumor[0]>=0.5), cmap='gray') plt.savefig(os.path.join(args.save_path,'rescaled_preds', image_name[:-4] +'_tumor.png')) plt.close() # plt.show() plt.imshow((liver_label[0]), cmap='gray') plt.savefig(os.path.join(args.save_path,'rescaled_gt', image_name[:-4] +'_liver.png')) plt.close() # plt.show() plt.imshow((tumor_label[0]), cmap='gray') plt.savefig(os.path.join(args.save_path,'rescaled_gt', image_name[:-4] +'_tumor.png')) plt.close() # plt.show() # print("dice: ",dice_coef(label, (masks>0.5)+0)) # print(liver_label.shape) # print((((masks[0]>=0.5)+0).unsqueeze(0)).shape) liver_dices.append(dice_coef(liver_label, ((masks_liver[0]>=0.5)+0).unsqueeze(0))) tumor_dices.append(dice_coef(tumor_label, ((masks_tumor[0]>=0.5)+0).unsqueeze(0))) liver_ious.append(iou_coef(liver_label, ((masks_liver[0]>=0.5)+0).unsqueeze(0))) tumor_ious.append(iou_coef(tumor_label, ((masks_tumor[0]>=0.5)+0).unsqueeze(0))) # 1/0 # break print("Liver DICE: ",torch.mean(torch.Tensor(liver_dices))) print("Liver IoU", torch.mean(torch.Tensor(liver_ious))) print("Tumor DICE", torch.mean(torch.Tensor(tumor_dices))) print("Tumor IoU", torch.mean(torch.Tensor(tumor_ious))) if __name__ == '__main__': main()