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inference.py
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inference.py
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import torchvision.transforms.functional as F
import torch.nn.functional as Func
import torchvision.transforms as T
import math
import sys
import random
import time
import datetime
from typing import Iterable
import numpy as np
import PIL
from PIL import Image
from skimage import transform
import nibabel as nib
import torch
import os
from medpy.metric.binary import dc
from medpy.metric.binary import hd95
from medpy.metric.binary import hd
import pandas as pd
import glob
import re
import shutil
import copy
from skimage import measure
import util.misc as utils
def makefolder(folder):
if not os.path.exists(folder):
os.makedirs(folder)
return True
return False
def load_nii(img_path):
nimg = nib.load(img_path)
return nimg.get_data(), nimg.affine, nimg.header
def save_nii(img_path, data, affine, header):
nimg = nib.Nifti1Image(data, affine=affine, header=header)
nimg.to_filename(img_path)
def convert_targets(targets, device):
masks = [t["masks"] for t in targets]
target_masks = torch.stack(masks)
shp_y = target_masks.shape
target_masks = target_masks.long()
y_onehot = torch.zeros((shp_y[0], 4, shp_y[2], shp_y[3]))
if target_masks.device.type == "cuda":
y_onehot = y_onehot.cuda(target_masks.device.index)
y_onehot.scatter_(1, target_masks, 1).float()
target_masks = y_onehot
return target_masks
def conv_int(i):
return int(i) if i.isdigit() else i
def natural_order(sord):
if isinstance(sord, tuple):
sord = sord[0]
return [conv_int(c) for c in re.split(r'(\d+)', sord)]
def keep_largest_connected_components(mask):
'''
Keeps only the largest connected components of each label for a segmentation mask.
'''
# keep a heart connectivity
mask_shape = mask.shape
heart_slice = np.where((mask>0), 1, 0)
out_heart = np.zeros(heart_slice.shape, dtype=np.uint8)
for struc_id in [1]:
binary_img = heart_slice == struc_id
blobs = measure.label(binary_img, connectivity=1)
props = measure.regionprops(blobs)
if not props:
continue
area = [ele.area for ele in props]
largest_blob_ind = np.argmax(area)
largest_blob_label = props[largest_blob_ind].label
out_heart[blobs == largest_blob_label] = struc_id
# #keep LV/RV/MYO connectivity
# out_img = np.zeros(mask.shape, dtype=np.uint8)
# for struc_id in [1, 2, 3]:
# binary_img = mask == struc_id
# blobs = measure.label(binary_img, connectivity=1)
# props = measure.regionprops(blobs)
# if not props:
# continue
# area = [ele.area for ele in props]
# largest_blob_ind = np.argmax(area)
# largest_blob_label = props[largest_blob_ind].label
# out_img[blobs == largest_blob_label] = struc_id
final_img = out_heart*mask
return final_img
@torch.no_grad()
def infer(model, criterion, device):
model.eval()
criterion.eval()
test_folder = "/data/zhangke/datasets/MSCMR_dataset/TestSet/images/"
label_folder = "/data/zhangke/datasets/MSCMR_dataset/TestSet/labels/"
output_folder = "/data/zhangke/datasets/MSCMR_dataset/self_tmp/"
if os.path.exists(output_folder):
shutil.rmtree(output_folder)
makefolder(output_folder)
target_resolution = (1.36719, 1.36719)
test_files = sorted(os.listdir(test_folder))
label_files = sorted(os.listdir(label_folder))
assert len(test_files) == len(label_files)
# read_image
for file_index in range(len(test_files)):
test_file = test_files[file_index]
label_file = label_files[file_index]
file_mask = os.path.join(label_folder, label_file)
mask_dat = load_nii(file_mask)
mask = mask_dat[0]
img_path = os.path.join(test_folder, test_file)
img_dat = load_nii(img_path)
img = img_dat[0].copy()
pixel_size = (img_dat[2].structarr['pixdim'][1], img_dat[2].structarr['pixdim'][2])
scale_vector = (pixel_size[0] / target_resolution[0],
pixel_size[1] / target_resolution[1])
img = img.astype(np.float32)
img = np.divide((img - np.mean(img)), np.std(img))
slice_rescaleds = []
for slice_index in range(img.shape[2]):
img_slice = np.squeeze(img[:,:,slice_index])
slice_rescaled = transform.rescale(img_slice,
scale_vector,
order=1,
preserve_range=True,
multichannel=False,
anti_aliasing=True,
mode='constant')
slice_rescaleds.append(slice_rescaled)
img = np.stack(slice_rescaleds, axis=2)
predictions = []
for slice_index in range(img.shape[2]):
img_slice = img[:,:,slice_index]
nx = 212
ny = 212
x, y = img_slice.shape
x_s = (x - nx) // 2
y_s = (y - ny) // 2
x_c = (nx - x) // 2
y_c = (ny - y) // 2
# Crop section of image for prediction
if x > nx and y > ny:
slice_cropped = img_slice[x_s:x_s+nx, y_s:y_s+ny]
else:
slice_cropped = np.zeros((nx,ny))
if x <= nx and y > ny:
slice_cropped[x_c:x_c+ x, :] = img_slice[:,y_s:y_s + ny]
elif x > nx and y <= ny:
slice_cropped[:, y_c:y_c + y] = img_slice[x_s:x_s + nx, :]
else:
slice_cropped[x_c:x_c+x, y_c:y_c + y] = img_slice[:, :]
img_slice = slice_cropped
img_slice = np.divide((slice_cropped - np.mean(slice_cropped)), np.std(slice_cropped))
img_slice = np.reshape(img_slice, (1,1,nx,ny))
img_slice = torch.from_numpy(img_slice)
img_slice = img_slice.to(device)
img_slice = img_slice.float()
tasks = ['MR']
task = random.sample(tasks, 1)[0]
outputs = model(img_slice, task)
softmax_out = outputs["pred_masks"]
softmax_out = softmax_out.detach().cpu().numpy()
prediction_cropped = np.squeeze(softmax_out[0,...])
slice_predictions = np.zeros((4,x,y))
# insert cropped region into original image again
if x > nx and y > ny:
slice_predictions[:,x_s:x_s+nx, y_s:y_s+ny] = prediction_cropped
else:
if x <= nx and y > ny:
slice_predictions[:,:, y_s:y_s+ny] = prediction_cropped[:,x_c:x_c+ x, :]
elif x > nx and y <= ny:
slice_predictions[:,x_s:x_s + nx, :] = prediction_cropped[:,:, y_c:y_c + y]
else:
slice_predictions[:,:, :] = prediction_cropped[:,x_c:x_c+ x, y_c:y_c + y]
prediction = transform.resize(slice_predictions,
(4, mask.shape[0], mask.shape[1]),
order=0,
preserve_range=True,
anti_aliasing=False,
mode='constant')
prediction = np.uint8(np.argmax(prediction, axis=0))
prediction = keep_largest_connected_components(prediction)
predictions.append(prediction)
prediction_arr = np.transpose(np.asarray(predictions, dtype=np.uint8), (1,2,0))
dir_pred = os.path.join(output_folder, "predictions")
makefolder(dir_pred)
out_file_name = os.path.join(dir_pred, label_file)
out_affine = mask_dat[1]
out_header = mask_dat[2]
save_nii(out_file_name, prediction_arr, out_affine, out_header)
dir_gt = os.path.join(output_folder, "masks")
makefolder(dir_gt)
mask_file_name = os.path.join(dir_gt, label_file)
save_nii(mask_file_name, mask_dat[0], out_affine, out_header)
filenames_gt = sorted(glob.glob(os.path.join(dir_gt, '*')), key=natural_order)
filenames_pred = sorted(glob.glob(os.path.join(dir_pred, '*')), key=natural_order)
file_names = []
structure_names = []
# measures per structure:
dices_list = []
structures_dict = {1: 'RV', 2: 'Myo', 3: 'LV'}
count = 0
for p_gt, p_pred in zip(filenames_gt, filenames_pred):
if os.path.basename(p_gt) != os.path.basename(p_pred):
raise ValueError("The two files don't have the same name"
" {}, {}.".format(os.path.basename(p_gt),
os.path.basename(p_pred)))
# load ground truth and prediction
gt, _f, header = load_nii(p_gt)
pred, _, _ = load_nii(p_pred)
zooms = header.get_zooms()
# calculate measures for each structure
for struc in [3,1,2]:
gt_binary = (gt == struc) * 1
pred_binary = (pred == struc) * 1
if np.sum(gt_binary) == 0 and np.sum(pred_binary) == 0:
dices_list.append(1)
elif np.sum(pred_binary) > 0 and np.sum(gt_binary) == 0 or np.sum(pred_binary) == 0 and np.sum(gt_binary) > 0:
dices_list.append(0)
count += 1
else:
dices_list.append(dc(gt_binary, pred_binary))
file_names.append(os.path.basename(p_pred))
structure_names.append(structures_dict[struc])
df = pd.DataFrame({'dice': dices_list, 'struc': structure_names, 'filename': file_names})
print(df['dice'].mean(),df['dice'].std())
print("RV:", df[df['struc']=='RV']['dice'].mean(),df[df['struc']=='RV']['dice'].std())
print("Myo:",df[df['struc']=='Myo']['dice'].mean(),df[df['struc']=='Myo']['dice'].std())
print("LV:", df[df['struc']=='LV']['dice'].mean(),df[df['struc']=='LV']['dice'].std())
csv_path = os.path.join(output_folder, "stats.csv")
df.to_csv(csv_path)
return df