| | import os |
| | import os.path as osp |
| | join = osp.join |
| | import numpy as np |
| | from glob import glob |
| | import torch |
| | from segment_anything.build_sam3D import sam_model_registry3D |
| | from segment_anything.utils.transforms3D import ResizeLongestSide3D |
| | from segment_anything import sam_model_registry |
| | from tqdm import tqdm |
| | import argparse |
| | import SimpleITK as sitk |
| | import torch.nn.functional as F |
| | from torch.utils.data import DataLoader |
| | import SimpleITK as sitk |
| | import torchio as tio |
| | import numpy as np |
| | from collections import OrderedDict, defaultdict |
| | import json |
| | import pickle |
| | from utils.click_method import get_next_click3D_torch_ritm, get_next_click3D_torch_2 |
| | from utils.data_loader import Dataset_Union_ALL_Val |
| | from itertools import product |
| |
|
| | parser = argparse.ArgumentParser() |
| | parser.add_argument('-tdp', '--test_data_path', type=str, default='./data/validation') |
| | parser.add_argument('-cp', '--checkpoint_path', type=str, default='./ckpt/sam_med3d.pth') |
| | parser.add_argument('--output_dir', type=str, default='./visualization') |
| | parser.add_argument('--task_name', type=str, default='test_amos') |
| | parser.add_argument('--skip_existing_pred', action='store_true', default=False) |
| | parser.add_argument('--save_image_and_gt', action='store_true', default=False) |
| | parser.add_argument('--sliding_window', action='store_true', default=False) |
| |
|
| | parser.add_argument('--image_size', type=int, default=256) |
| | parser.add_argument('--crop_size', type=int, default=128) |
| | parser.add_argument('--device', type=str, default='cuda') |
| | parser.add_argument('-mt', '--model_type', type=str, default='vit_b_ori') |
| | parser.add_argument('-nc', '--num_clicks', type=int, default=5) |
| | parser.add_argument('-pm', '--point_method', type=str, default='default') |
| | parser.add_argument('-dt', '--data_type', type=str, default='Ts') |
| |
|
| | parser.add_argument('--threshold', type=int, default=0) |
| | parser.add_argument('--dim', type=int, default=3) |
| | parser.add_argument('--split_idx', type=int, default=0) |
| | parser.add_argument('--split_num', type=int, default=1) |
| | parser.add_argument('--ft2d', action='store_true', default=False) |
| | parser.add_argument('--seed', type=int, default=2023) |
| |
|
| | args = parser.parse_args() |
| |
|
| | ''' parse and output_dir and task_name ''' |
| | args.output_dir = join(args.output_dir, args.task_name) |
| | args.pred_output_dir = join(args.output_dir, "pred") |
| | os.makedirs(args.output_dir, exist_ok=True) |
| | os.makedirs(args.pred_output_dir, exist_ok=True) |
| | args.save_name = join(args.output_dir, "dice.py") |
| | print("output_dir set to", args.output_dir) |
| |
|
| | SEED = args.seed |
| | print("set seed as", SEED) |
| | torch.manual_seed(SEED) |
| | np.random.seed(SEED) |
| |
|
| | if torch.cuda.is_available(): |
| | torch.cuda.init() |
| |
|
| | click_methods = { |
| | 'default': get_next_click3D_torch_ritm, |
| | 'ritm': get_next_click3D_torch_ritm, |
| | 'random': get_next_click3D_torch_2, |
| | } |
| |
|
| | def compute_iou(pred_mask, gt_semantic_seg): |
| | in_mask = np.logical_and(gt_semantic_seg, pred_mask) |
| | out_mask = np.logical_or(gt_semantic_seg, pred_mask) |
| | iou = np.sum(in_mask) / np.sum(out_mask) |
| | return iou |
| |
|
| | def compute_dice(mask_gt, mask_pred, dtype=np.uint8): |
| | volume_sum = mask_gt.sum() + mask_pred.sum() |
| | if volume_sum == 0: |
| | return np.NaN |
| | volume_intersect = (mask_gt.astype(dtype) & mask_pred.astype(dtype)).sum() |
| | return 2*volume_intersect / volume_sum |
| |
|
| | def postprocess_masks(low_res_masks, image_size, original_size): |
| | ori_h, ori_w = original_size |
| | masks = F.interpolate( |
| | low_res_masks, |
| | (image_size, image_size), |
| | mode="bilinear", |
| | align_corners=False, |
| | ) |
| | if args.ft2d and ori_h < image_size and ori_w < image_size: |
| | top = (image_size - ori_h) // 2 |
| | left = (image_size - ori_w) // 2 |
| | masks = masks[..., top : ori_h + top, left : ori_w + left] |
| | pad = (top, left) |
| | else: |
| | masks = F.interpolate(masks, original_size, mode="bilinear", align_corners=False) |
| | pad = None |
| | return masks, pad |
| |
|
| | def sam_decoder_inference(target_size, points_coords, points_labels, model, image_embeddings, mask_inputs=None, multimask = False): |
| | with torch.no_grad(): |
| | sparse_embeddings, dense_embeddings = model.prompt_encoder( |
| | points=(points_coords.to(model.device), points_labels.to(model.device)), |
| | boxes=None, |
| | masks=mask_inputs, |
| | ) |
| |
|
| | low_res_masks, iou_predictions = model.mask_decoder( |
| | image_embeddings = image_embeddings, |
| | image_pe = model.prompt_encoder.get_dense_pe(), |
| | sparse_prompt_embeddings=sparse_embeddings, |
| | dense_prompt_embeddings=dense_embeddings, |
| | multimask_output=multimask, |
| | ) |
| | |
| | if multimask: |
| | max_values, max_indexs = torch.max(iou_predictions, dim=1) |
| | max_values = max_values.unsqueeze(1) |
| | iou_predictions = max_values |
| | low_res = [] |
| | for i, idx in enumerate(max_indexs): |
| | low_res.append(low_res_masks[i:i+1, idx]) |
| | low_res_masks = torch.stack(low_res, 0) |
| | masks = F.interpolate(low_res_masks, (target_size, target_size), mode="bilinear", align_corners=False,) |
| | return masks, low_res_masks, iou_predictions |
| |
|
| | def repixel_value(arr, is_seg=False): |
| | if not is_seg: |
| | min_val = arr.min() |
| | max_val = arr.max() |
| | new_arr = (arr - min_val) / (max_val - min_val + 1e-10) * 255. |
| | return new_arr |
| |
|
| | def random_point_sampling(mask, get_point = 1): |
| | if isinstance(mask, torch.Tensor): |
| | mask = mask.numpy() |
| | fg_coords = np.argwhere(mask == 1)[:,::-1] |
| | bg_coords = np.argwhere(mask == 0)[:,::-1] |
| | |
| | fg_size = len(fg_coords) |
| | bg_size = len(bg_coords) |
| |
|
| | if get_point == 1: |
| | if fg_size > 0: |
| | index = np.random.randint(fg_size) |
| | fg_coord = fg_coords[index] |
| | label = 1 |
| | else: |
| | index = np.random.randint(bg_size) |
| | fg_coord = bg_coords[index] |
| | label = 0 |
| | return torch.as_tensor([fg_coord.tolist()], dtype=torch.float), torch.as_tensor([label], dtype=torch.int) |
| | else: |
| | num_fg = get_point // 2 |
| | num_bg = get_point - num_fg |
| | fg_indices = np.random.choice(fg_size, size=num_fg, replace=True) |
| | bg_indices = np.random.choice(bg_size, size=num_bg, replace=True) |
| | fg_coords = fg_coords[fg_indices] |
| | bg_coords = bg_coords[bg_indices] |
| | coords = np.concatenate([fg_coords, bg_coords], axis=0) |
| | labels = np.concatenate([np.ones(num_fg), np.zeros(num_bg)]).astype(int) |
| | indices = np.random.permutation(get_point) |
| | coords, labels = torch.as_tensor(coords[indices], dtype=torch.float), torch.as_tensor(labels[indices], dtype=torch.int) |
| | return coords, labels |
| |
|
| |
|
| | def finetune_model_predict2D(img3D, gt3D, sam_model_tune, target_size=256, click_method='random', device='cuda', num_clicks=1, prev_masks=None): |
| | pred_list = [] |
| |
|
| | slice_mask_list = defaultdict(list) |
| |
|
| | img3D = torch.repeat_interleave(img3D, repeats=3, dim=1) |
| | |
| | click_points = [] |
| | click_labels = [] |
| | for slice_idx in tqdm(range(img3D.size(-1)), desc="transverse slices", leave=False): |
| | img2D, gt2D = repixel_value(img3D[..., slice_idx]), gt3D[..., slice_idx] |
| |
|
| | if (gt2D==0).all(): |
| | empty_result = torch.zeros(list(gt3D.size()[:-1])+[1]).to(device) |
| | for iter in range(num_clicks): |
| | slice_mask_list[iter].append(empty_result) |
| | continue |
| |
|
| | img2D = F.interpolate(img2D, (target_size, target_size), mode="bilinear", align_corners=False) |
| | gt2D = F.interpolate(gt2D.float(), (target_size, target_size), mode="nearest").int() |
| | |
| | img2D, gt2D = img2D.to(device), gt2D.to(device) |
| | img2D = (img2D - img2D.mean()) / img2D.std() |
| |
|
| | with torch.no_grad(): |
| | image_embeddings = sam_model_tune.image_encoder(img2D.float()) |
| |
|
| | points_co, points_la = torch.zeros(1,0,2).to(device), torch.zeros(1,0).to(device) |
| | low_res_masks = None |
| | gt_semantic_seg = gt2D[0, 0].to(device) |
| | true_masks = (gt_semantic_seg > 0) |
| | for iter in range(num_clicks): |
| | if(low_res_masks==None): |
| | pred_masks = torch.zeros_like(true_masks).to(device) |
| | else: |
| | pred_masks = (prev_masks[0, 0] > 0.0).to(device) |
| | fn_masks = torch.logical_and(true_masks, torch.logical_not(pred_masks)) |
| | fp_masks = torch.logical_and(torch.logical_not(true_masks), pred_masks) |
| | mask_to_sample = torch.logical_or(fn_masks, fp_masks) |
| | new_points_co, _ = random_point_sampling(mask_to_sample.cpu(), get_point=1) |
| | new_points_la = torch.Tensor([1]).to(torch.int64) if(true_masks[new_points_co[0,1].int(), new_points_co[0,0].int()]) else torch.Tensor([0]).to(torch.int64) |
| | new_points_co, new_points_la = new_points_co[None].to(device), new_points_la[None].to(device) |
| | points_co = torch.cat([points_co, new_points_co],dim=1) |
| | points_la = torch.cat([points_la, new_points_la],dim=1) |
| | prev_masks, low_res_masks, iou_predictions = sam_decoder_inference( |
| | target_size, points_co, points_la, sam_model_tune, image_embeddings, |
| | mask_inputs = low_res_masks, multimask = True) |
| | click_points.append(new_points_co) |
| | click_labels.append(new_points_la) |
| | |
| | slice_mask, _ = postprocess_masks(low_res_masks, target_size, (gt3D.size(2), gt3D.size(3))) |
| | slice_mask_list[iter].append(slice_mask[..., None]) |
| | |
| | for iter in range(num_clicks): |
| | medsam_seg = torch.cat(slice_mask_list[iter], dim=-1).cpu().numpy().squeeze() |
| | medsam_seg = medsam_seg > sam_model_tune.mask_threshold |
| | medsam_seg = medsam_seg.astype(np.uint8) |
| |
|
| | pred_list.append(medsam_seg) |
| |
|
| | return pred_list, click_points, click_labels |
| |
|
| |
|
| | def finetune_model_predict3D(img3D, gt3D, sam_model_tune, device='cuda', click_method='random', num_clicks=10, prev_masks=None): |
| | img3D = norm_transform(img3D.squeeze(dim=1)) |
| | img3D = img3D.unsqueeze(dim=1) |
| |
|
| | click_points = [] |
| | click_labels = [] |
| |
|
| | pred_list = [] |
| |
|
| | if prev_masks is None: |
| | prev_masks = torch.zeros_like(gt3D).to(device) |
| | low_res_masks = F.interpolate(prev_masks.float(), size=(args.crop_size//4,args.crop_size//4,args.crop_size//4)) |
| |
|
| | with torch.no_grad(): |
| | image_embedding = sam_model_tune.image_encoder(img3D.to(device)) |
| |
|
| | for click_idx in range(num_clicks): |
| | with torch.no_grad(): |
| | if(click_idx>1): |
| | click_method = "random" |
| | batch_points, batch_labels = click_methods[click_method](prev_masks.to(device), gt3D.to(device)) |
| |
|
| | points_co = torch.cat(batch_points, dim=0).to(device) |
| | points_la = torch.cat(batch_labels, dim=0).to(device) |
| |
|
| | click_points.append(points_co) |
| | click_labels.append(points_la) |
| |
|
| | points_input = points_co |
| | labels_input = points_la |
| |
|
| | sparse_embeddings, dense_embeddings = sam_model_tune.prompt_encoder( |
| | points=[points_input, labels_input], |
| | boxes=None, |
| | masks=low_res_masks.to(device), |
| | ) |
| | low_res_masks, _ = sam_model_tune.mask_decoder( |
| | image_embeddings=image_embedding.to(device), |
| | image_pe=sam_model_tune.prompt_encoder.get_dense_pe(), |
| | sparse_prompt_embeddings=sparse_embeddings, |
| | dense_prompt_embeddings=dense_embeddings, |
| | multimask_output=False, |
| | ) |
| | prev_masks = F.interpolate(low_res_masks, size=gt3D.shape[-3:], mode='trilinear', align_corners=False) |
| |
|
| | medsam_seg_prob = torch.sigmoid(prev_masks) |
| | |
| | medsam_seg_prob = medsam_seg_prob.cpu().numpy().squeeze() |
| | medsam_seg = (medsam_seg_prob > 0.5).astype(np.uint8) |
| | pred_list.append(medsam_seg) |
| |
|
| | return pred_list, click_points, click_labels |
| |
|
| |
|
| | def pad_and_crop_with_sliding_window(img3D, gt3D, crop_transform, offset_mode="center"): |
| | subject = tio.Subject( |
| | image = tio.ScalarImage(tensor=img3D.squeeze(0)), |
| | label = tio.LabelMap(tensor=gt3D.squeeze(0)), |
| | ) |
| | padding_params, cropping_params = crop_transform.compute_crop_or_pad(subject) |
| | |
| | |
| | if(cropping_params is None): cropping_params = (0,0,0,0,0,0) |
| | if(padding_params is None): padding_params = (0,0,0,0,0,0) |
| | roi_shape = crop_transform.target_shape |
| | vol_bound = (0, img3D.shape[2], 0, img3D.shape[3], 0, img3D.shape[4]) |
| | center_oob_ori_roi=( |
| | cropping_params[0]-padding_params[0], cropping_params[0]+roi_shape[0]-padding_params[0], |
| | cropping_params[2]-padding_params[2], cropping_params[2]+roi_shape[1]-padding_params[2], |
| | cropping_params[4]-padding_params[4], cropping_params[4]+roi_shape[2]-padding_params[4], |
| | ) |
| | window_list = [] |
| | offset_dict = { |
| | "rounded": list(product((-32,+32,0), repeat=3)), |
| | "center": [(0,0,0)], |
| | } |
| | for offset in offset_dict[offset_mode]: |
| | |
| | oob_ori_roi = ( |
| | center_oob_ori_roi[0]+offset[0], center_oob_ori_roi[1]+offset[0], |
| | center_oob_ori_roi[2]+offset[1], center_oob_ori_roi[3]+offset[1], |
| | center_oob_ori_roi[4]+offset[2], center_oob_ori_roi[5]+offset[2], |
| | ) |
| | |
| | padding_params = [0 for i in range(6)] |
| | for idx, (ori_pos, bound) in enumerate(zip(oob_ori_roi, vol_bound)): |
| | pad_val = 0 |
| | if(idx%2==0 and ori_pos<bound): |
| | pad_val = bound-ori_pos |
| | if(idx%2==1 and ori_pos>bound): |
| | pad_val = ori_pos-bound |
| | padding_params[idx] = pad_val |
| | |
| | cropping_params = ( |
| | oob_ori_roi[0]+padding_params[0], vol_bound[1]-oob_ori_roi[1]+padding_params[1], |
| | oob_ori_roi[2]+padding_params[2], vol_bound[3]-oob_ori_roi[3]+padding_params[3], |
| | oob_ori_roi[4]+padding_params[4], vol_bound[5]-oob_ori_roi[5]+padding_params[5], |
| | ) |
| | |
| | pad_and_crop = tio.Compose([ |
| | tio.Pad(padding_params, padding_mode=crop_transform.padding_mode), |
| | tio.Crop(cropping_params), |
| | ]) |
| | subject_roi = pad_and_crop(subject) |
| | img3D_roi, gt3D_roi = subject_roi.image.data.clone().detach().unsqueeze(1), subject_roi.label.data.clone().detach().unsqueeze(1) |
| |
|
| | |
| | |
| | windows_clip = [0 for i in range(6)] |
| | for i in range(3): |
| | if(offset[i]<0): |
| | windows_clip[2*i] = 0 |
| | windows_clip[2*i+1] = -(roi_shape[i]+offset[i]) |
| | elif(offset[i]>0): |
| | windows_clip[2*i] = roi_shape[i]-offset[i] |
| | windows_clip[2*i+1] = 0 |
| | pos3D_roi = dict( |
| | padding_params=padding_params, cropping_params=cropping_params, |
| | ori_roi=( |
| | cropping_params[0]+windows_clip[0], cropping_params[0]+roi_shape[0]-padding_params[0]-padding_params[1]+windows_clip[1], |
| | cropping_params[2]+windows_clip[2], cropping_params[2]+roi_shape[1]-padding_params[2]-padding_params[3]+windows_clip[3], |
| | cropping_params[4]+windows_clip[4], cropping_params[4]+roi_shape[2]-padding_params[4]-padding_params[5]+windows_clip[5], |
| | ), |
| | pred_roi=( |
| | padding_params[0]+windows_clip[0], roi_shape[0]-padding_params[1]+windows_clip[1], |
| | padding_params[2]+windows_clip[2], roi_shape[1]-padding_params[3]+windows_clip[3], |
| | padding_params[4]+windows_clip[4], roi_shape[2]-padding_params[5]+windows_clip[5], |
| | )) |
| | pred_roi = pos3D_roi["pred_roi"] |
| | |
| | |
| | |
| | |
| |
|
| | window_list.append((img3D_roi, gt3D_roi, pos3D_roi)) |
| | return window_list |
| |
|
| | def save_numpy_to_nifti(in_arr: np.array, out_path, meta_info): |
| | |
| | |
| | ori_arr = np.transpose(in_arr.squeeze(), (2, 1, 0)) |
| | out = sitk.GetImageFromArray(ori_arr) |
| | sitk_meta_translator = lambda x: [float(i) for i in x] |
| | out.SetOrigin(sitk_meta_translator(meta_info["origin"])) |
| | out.SetDirection(sitk_meta_translator(meta_info["direction"])) |
| | out.SetSpacing(sitk_meta_translator(meta_info["spacing"])) |
| | sitk.WriteImage(out, out_path) |
| |
|
| |
|
| | if __name__ == "__main__": |
| | all_dataset_paths = glob(join(args.test_data_path, "*", "*")) |
| | all_dataset_paths = list(filter(osp.isdir, all_dataset_paths)) |
| | print("get", len(all_dataset_paths), "datasets") |
| |
|
| | crop_transform = tio.CropOrPad( |
| | mask_name='label', |
| | target_shape=(args.crop_size, args.crop_size, args.crop_size)) |
| | |
| | infer_transform = [ |
| | tio.ToCanonical(), |
| | ] |
| |
|
| | test_dataset = Dataset_Union_ALL_Val( |
| | paths=all_dataset_paths, |
| | mode="Val", |
| | data_type=args.data_type, |
| | transform=tio.Compose(infer_transform), |
| | threshold=0, |
| | split_num=args.split_num, |
| | split_idx=args.split_idx, |
| | pcc=False, |
| | get_all_meta_info=True, |
| | ) |
| |
|
| | test_dataloader = DataLoader( |
| | dataset=test_dataset, |
| | sampler=None, |
| | batch_size=1, |
| | shuffle=True |
| | ) |
| |
|
| | checkpoint_path = args.checkpoint_path |
| |
|
| | device = args.device |
| | print("device:", device) |
| |
|
| | if(args.dim==3): |
| | sam_model_tune = sam_model_registry3D[args.model_type](checkpoint=None).to(device) |
| | if checkpoint_path is not None: |
| | model_dict = torch.load(checkpoint_path, map_location=device) |
| | state_dict = model_dict['model_state_dict'] |
| | sam_model_tune.load_state_dict(state_dict) |
| | else: |
| | raise NotImplementedError("this scipts is designed for 3D sliding-window inference, not support other dims") |
| |
|
| | sam_trans = ResizeLongestSide3D(sam_model_tune.image_encoder.img_size) |
| | norm_transform = tio.ZNormalization(masking_method=lambda x: x > 0) |
| |
|
| | all_iou_list = [] |
| | all_dice_list = [] |
| |
|
| | out_dice = dict() |
| | out_dice_all = OrderedDict() |
| |
|
| | for batch_data in tqdm(test_dataloader): |
| | image3D, gt3D, meta_info = batch_data |
| | img_name = meta_info["image_path"][0] |
| |
|
| | modality = osp.basename(osp.dirname(osp.dirname(osp.dirname(img_name)))) |
| | dataset = osp.basename(osp.dirname(osp.dirname(img_name))) |
| | vis_root = osp.join(args.pred_output_dir, modality, dataset) |
| | pred_path = osp.join(vis_root, osp.basename(img_name).replace(".nii.gz", f"_pred{args.num_clicks-1}.nii.gz")) |
| | |
| | ''' inference ''' |
| | iou_list, dice_list = [], [] |
| | if(args.skip_existing_pred and osp.exists(pred_path)): |
| | pass |
| | else: |
| | image3D_full, gt3D_full = image3D, gt3D |
| | pred3D_full_dict = {click_idx:torch.zeros_like(gt3D_full).numpy() for click_idx in range(args.num_clicks)} |
| | offset_mode = "center" if(not args.sliding_window) else "rounded" |
| | sliding_window_list = pad_and_crop_with_sliding_window(image3D_full, gt3D_full, crop_transform, offset_mode=offset_mode) |
| | for (image3D, gt3D, pos3D) in sliding_window_list: |
| | seg_mask_list, points, labels = finetune_model_predict3D( |
| | image3D, gt3D, sam_model_tune, device=device, |
| | click_method=args.point_method, num_clicks=args.num_clicks, |
| | prev_masks=None) |
| | ori_roi, pred_roi = pos3D["ori_roi"], pos3D["pred_roi"] |
| | for idx, seg_mask in enumerate(seg_mask_list): |
| | seg_mask_roi = seg_mask[..., pred_roi[0]:pred_roi[1], pred_roi[2]:pred_roi[3], pred_roi[4]:pred_roi[5]] |
| | pred3D_full_dict[idx][..., ori_roi[0]:ori_roi[1], ori_roi[2]:ori_roi[3], ori_roi[4]:ori_roi[5]] = seg_mask_roi |
| |
|
| | os.makedirs(vis_root, exist_ok=True) |
| | padding_params = sliding_window_list[-1][-1]["padding_params"] |
| | cropping_params = sliding_window_list[-1][-1]["cropping_params"] |
| | |
| | point_offset = np.array([cropping_params[0]-padding_params[0], cropping_params[2]-padding_params[2], cropping_params[4]-padding_params[4]]) |
| | points = [p.cpu().numpy()+point_offset for p in points] |
| | labels = [l.cpu().numpy() for l in labels] |
| | pt_info = dict(points=points, labels=labels) |
| | |
| | pt_path=osp.join(vis_root, osp.basename(img_name).replace(".nii.gz", "_pt.pkl")) |
| | pickle.dump(pt_info, open(pt_path, "wb")) |
| |
|
| | if(args.save_image_and_gt): |
| | save_numpy_to_nifti(image3D_full, osp.join(vis_root, osp.basename(img_name).replace(".nii.gz", f"_img.nii.gz")), meta_info) |
| | save_numpy_to_nifti(gt3D_full, osp.join(vis_root, osp.basename(img_name).replace(".nii.gz", f"_gt.nii.gz")), meta_info) |
| | for idx, pred3D_full in pred3D_full_dict.items(): |
| | save_numpy_to_nifti(pred3D_full, osp.join(vis_root, osp.basename(img_name).replace(".nii.gz", f"_pred{idx}.nii.gz")), meta_info) |
| | radius = 2 |
| | for pt in points[:idx+1]: |
| | pred3D_full[..., pt[0,0,0]-radius:pt[0,0,0]+radius, pt[0,0,1]-radius:pt[0,0,1]+radius, pt[0,0,2]-radius:pt[0,0,2]+radius] = 10 |
| | save_numpy_to_nifti(pred3D_full, osp.join(vis_root, osp.basename(img_name).replace(".nii.gz", f"_pred{idx}_wPt.nii.gz")), meta_info) |
| | |
| | ''' metric computation ''' |
| | for click_idx in range(args.num_clicks): |
| | reorient_tensor = lambda in_arr : np.transpose(in_arr.squeeze().detach().cpu().numpy(), (2, 1, 0)) |
| | curr_pred_path = osp.join(vis_root, osp.basename(img_name).replace(".nii.gz", f"_pred{click_idx}.nii.gz")) |
| | medsam_seg = sitk.GetArrayFromImage(sitk.ReadImage(curr_pred_path)) |
| | iou_list.append(round(compute_iou(medsam_seg, reorient_tensor(gt3D_full)), 4)) |
| | dice_list.append(round(compute_dice(reorient_tensor(gt3D_full), medsam_seg), 4)) |
| |
|
| | per_iou = max(iou_list) |
| | all_iou_list.append(per_iou) |
| | all_dice_list.append(max(dice_list)) |
| | print(dice_list) |
| | out_dice[img_name] = max(dice_list) |
| | cur_dice_dict = OrderedDict() |
| | for i, dice in enumerate(dice_list): |
| | cur_dice_dict[f'{i}'] = dice |
| | out_dice_all[img_name] = cur_dice_dict |
| |
|
| | print('Mean IoU : ', sum(all_iou_list)/len(all_iou_list)) |
| | print('Mean Dice: ', sum(all_dice_list)/len(all_dice_list)) |
| |
|
| | final_dice_dict = OrderedDict() |
| | for k, v in out_dice_all.items(): |
| | organ = k.split('/')[-4] |
| | final_dice_dict[organ] = OrderedDict() |
| | for k, v in out_dice_all.items(): |
| | organ = k.split('/')[-4] |
| | final_dice_dict[organ][k] = v |
| |
|
| | if(args.split_num>1): |
| | args.save_name = args.save_name.replace('.py', f'_s{args.split_num}i{args.split_idx}.py') |
| |
|
| | print("Save to", args.save_name) |
| | with open(args.save_name, 'w') as f: |
| | f.writelines(f'# mean dice: \t{np.mean(all_dice_list)}\n') |
| | f.writelines('dice_Ts = {') |
| | for k, v in out_dice.items(): |
| | f.writelines(f'\'{str(k[0])}\': {v},\n') |
| | f.writelines('}') |
| |
|
| | with open(args.save_name.replace('.py', '.json'), 'w') as f: |
| | json.dump(final_dice_dict, f, indent=4) |
| |
|
| | print("Done") |
| |
|
