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brain_mage_intensity_standardize
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brain_mage_intensity_standardize
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#!/usr/bin/env python3
# -*- coding: utf-8 -*-
"""
Created on Sun May 24 13:49:24 2020
@author: siddhesh
"""
import numpy as np
import os
import glob
import nibabel as nib
import argparse
from skimage.transform import resize
from multiprocessing import Pool, cpu_count
import pkg_resources
# """You can change the folder name here. The folders should be in the following
# format.
# ---main_folder
# |---Patient1
# |---something_t1.nii.gz
# |---something_t2.nii.gz
# |---something_t1ce.nii.gz
# |---something_flair.nii.gz
# |---Patient2
# |---something_t1.nii.gz
# |---something_t2.nii.gz
# |---something_t1ce.nii.gz
# |---something_flair.nii.gz
# |---Patient3
# .
# .
# .
# |---Patient(N)
#
# *** The files will be generated as something_roimask.nii.gz ***
# """
def pad_image(image):
"""[To pad the image to particular space]
[This function will pad the image to a space of [240, 240, 160] and will
automatically pad everything with zeros to this size]
Arguments:
image {[numpy image]} -- [Image of any standard shape[x, y. z]]
Returns:
[padded_image] -- [returns a padded image]
"""
padded_image = image
# Padding on X axes
if image.shape[0] < 240:
# print("Image was padded on the X-axis on both sides")
padded_image = np.pad(
padded_image,
(
(int((240 - image.shape[0]) / 2), int((240 - image.shape[0]) / 2)),
(0, 0),
(0, 0),
),
mode="constant",
constant_values=0,
)
# Padding on Y axes
if image.shape[1] < 240:
# print("Image was padded on the Y-axis on both sides")
padded_image = np.pad(
padded_image,
(
(0, 0),
(int((240 - image.shape[1]) / 2), int((240 - image.shape[1]) / 2)),
(0, 0),
),
mode="constant",
constant_values=0,
)
# Padding on Z axes
if image.shape[2] < 160:
# print("Image was padded on the Z-axis on top only")
padded_image = np.pad(
padded_image,
((0, 0), (0, 0), (0, int(160 - image.shape[2]))),
"constant",
constant_values=0,
)
return padded_image
def preprocess_image(image, is_mask=False, target_spacing=(1.875, 1.875, 1.25)):
"""[To preprocess an image depending on whether it a mask image or not]
[This function in general will try to preprocess a given image to a partic-
-ular image resolution and try to return a preprocessed image]
Arguments:
image {[nibabel image]} -- [Expecting a nibabel image to be handled]
Keyword Arguments:
is_mask {bool} -- [If the incoming image is a mask] (default: {False})
target_spacing {tuple} -- [What should be a current given target
spacing to be used]
(default: {(1.875, 1.875, 1.25)})
Returns:
[preprocessed image] -- [Returning a properly preprocessed and a norma-
-lized image]
"""
old_spacing = image.header.get_zooms()
shape = image.header.get_data_shape()
new_image = image.get_fdata()
new_spacing = (1, 1, 1)
# Check if it is a normal image or a mask
# If this thing is normal image
if not is_mask:
if old_spacing == (1.0, 1.0, 1.0):
if shape == [240, 240, 160]:
# print("Image is perfect?")
"""[Checking if it is an ideal image]
_________________________________________
___________|_Correct_|_Incorrect_|______|
shape | Yes | No | _|
resolution_|___Yes___|_____No____|______|
pad________|_________|___________|__No__|
[An ideal image would be to have a shape of (240, 240, 160)
with an isotropic resolution of (1.0, 1.0, 1.0), then we would
just resize the image to (128, 128, 128)]
"""
new_image = resize(
new_image,
(128, 128, 128),
order=3,
mode="edge",
cval=0,
anti_aliasing=False,
)
else:
"""[Checking if it is an isotropic image with need to incorrect
shape]
________________________________________
___________|_Correct_|_Incorrect_|_____|
shape | No | Yes | |
resolution_|___Yes___|_____No____|_____|
pad________|_________|___________|_Yes_|
[An ideal image would be to have a shape of (240, 240, 160)
with a isotropic resolution of (1.0, 1.0, 1.0), then we would
just resize the image to (128, 128, 128)]
"""
# print("Image shape wasn't perfect")
new_image = pad_image(new_image)
# print("Trying to pad the image now")
new_image = resize(
new_image,
(128, 128, 128),
order=3,
mode="edge",
cval=0,
anti_aliasing=False,
)
else:
"""[Checking if it is not isotropic image with resolution needed]
________________________________________
___________|_Correct_|_Incorrect_|_____|
shape | No | Yes | |
resolution_|___Yes___|_____No____|_____|
pad________|_________|___________|_Yes_|
[An ideal image would be to have a shape of (240, 240, 160) with
a isotropic resolution of (1.0, 1.0, 1.0), then we would just
resize the image to (128, 128, 128)]
"""
new_shape = (
int(np.round(old_spacing[0] / new_spacing[0] * float(image.shape[0]))),
int(np.round(old_spacing[1] / new_spacing[1] * float(image.shape[1]))),
int(np.round(old_spacing[2] / new_spacing[2] * float(image.shape[2]))),
)
new_image = resize(
new_image, new_shape, order=1, mode="edge", cval=0, anti_aliasing=False
)
if new_shape == [240, 240, 160]:
new_image = resize(
new_image,
(128, 128, 128),
order=3,
mode="edge",
cval=0,
anti_aliasing=False,
)
else:
new_image = pad_image(new_image)
new_image = resize(
new_image,
(128, 128, 128),
order=3,
mode="edge",
cval=0,
anti_aliasing=False,
)
else:
if old_spacing == (1.0, 1.0, 1.0):
if shape == [240, 240, 160]:
new_image = resize(
new_image,
(128, 128, 128),
order=0,
mode="edge",
cval=0,
anti_aliasing=False,
)
else:
new_image = pad_image(new_image)
new_image = resize(
new_image,
(128, 128, 128),
order=0,
mode="edge",
cval=0,
anti_aliasing=False,
)
else:
new_shape = (
int(np.round(old_spacing[0] / new_spacing[0] * float(image.shape[0]))),
int(np.round(old_spacing[1] / new_spacing[1] * float(image.shape[1]))),
int(np.round(old_spacing[2] / new_spacing[2] * float(image.shape[2]))),
)
new_image = resize(
new_image, new_shape, order=0, mode="edge", cval=0, anti_aliasing=False
)
if new_shape == [240, 240, 160]:
new_image = resize(
new_image,
(128, 128, 128),
order=0,
mode="edge",
cval=0,
anti_aliasing=False,
)
else:
new_image = pad_image(new_image)
new_image = resize(
new_image,
(128, 128, 128),
order=0,
mode="edge",
cval=0,
anti_aliasing=False,
)
if is_mask: # Retrun if mask
return new_image.astype(np.int8)
else:
new_image_temp = new_image[new_image >= new_image.mean()]
p1 = np.percentile(new_image_temp, 2)
p2 = np.percentile(new_image_temp, 95)
new_image[new_image > p2] = p2
new_image = (new_image - p1) / p2
return new_image.astype(np.float32)
def normalize(folder, dest_folder, patient_name, test=False):
"""[Function used to pre-process files]
[This function is used for the skull stripping preprocessing,
for more details, please visit the paper at : arxiv.org]
Arguments:
folder {[string]} -- [The Root folder to look into]
dest_folder {[type]} -- [The folder to store preprocessed files into]
test {[type]} -- [If doing it for the testing, we don't want to check
for ground truths]
"""
patient_dest_folder = os.path.join(dest_folder, patient_name)
os.makedirs(patient_dest_folder, exist_ok=True)
t1 = glob.glob(os.path.join(folder, "*t1.nii.gz"))[0]
t2 = glob.glob(os.path.join(folder, "*t2.nii.gz"))[0]
t1ce = glob.glob(os.path.join(folder, "*t1ce.nii.gz"))[0]
flair = glob.glob(os.path.join(folder, "*flair.nii.gz"))[0]
if not test:
gt = glob.glob(os.path.join(folder, "*mask.nii.gz"))[0]
new_affine = np.array([[1.875, 0, 0], [0, 1.875, 0], [0, 0, 1.25]])
# Reading T1 image and storing it
t1_image = nib.load(t1)
resized_t1_image = preprocess_image(t1_image, is_mask=False)
temp_affine = t1_image.affine
temp_affine[:3, :3] = new_affine
resized_t1_image = nib.Nifti1Image(resized_t1_image, temp_affine)
print(patient_dest_folder)
print(
"Saving T1 at : ",
os.path.join(patient_dest_folder, patient_name + "_t1.nii.gz"),
)
nib.save(
resized_t1_image, os.path.join(patient_dest_folder, patient_name + "_t1.nii.gz")
)
t2_image = nib.load(t2)
resized_t2_image = preprocess_image(t2_image, is_mask=False)
temp_affine = t2_image.affine
temp_affine[:3, :3] = new_affine
resized_t2_image = nib.Nifti1Image(resized_t2_image, temp_affine)
nib.save(
resized_t2_image, os.path.join(patient_dest_folder, patient_name + "_t2.nii.gz")
)
t1ce_image = nib.load(t1ce)
resized_t1ce_image = preprocess_image(t1ce_image, is_mask=False)
temp_affine = t1ce_image.affine
temp_affine[:3, :3] = new_affine
resized_t1ce_image = nib.Nifti1Image(resized_t1ce_image, t1ce_image.affine)
nib.save(
resized_t1ce_image,
os.path.join(patient_dest_folder, patient_name + "_t1ce.nii.gz"),
)
flair_image = nib.load(flair)
resized_flair_image = preprocess_image(flair_image, is_mask=False)
temp_affine = flair_image.affine
temp_affine[:3, :3] = new_affine
resized_flair_image = nib.Nifti1Image(resized_flair_image, flair_image.affine)
nib.save(
resized_flair_image,
os.path.join(patient_dest_folder, patient_name + "_flair.nii.gz"),
)
if not test:
gt_image = nib.load(gt)
resized_gt_image = preprocess_image(gt_image, is_mask=True)
resized_gt_image = nib.Nifti1Image(resized_gt_image, gt_image.affine)
nib.save(
resized_gt_image,
os.path.join(patient_dest_folder, patient_name + "_mask.nii.gz"),
)
return
def batch_works(k):
if k == n_processes - 1:
sub_patients = patients[k * int(len(patients) / n_processes) :]
else:
sub_patients = patients[
k
* int(len(patients) / n_processes) : (k + 1)
* int(len(patients) / n_processes)
]
for patient in sub_patients:
patient_name = os.path.basename(patient)
print(patient_name)
normalize(patient, output_path, patient_name)
if __name__ == "__main__":
parser = argparse.ArgumentParser(
prog="intensity_standardize",
formatter_class=argparse.RawTextHelpFormatter,
description="\nThis code was implemented to standardize intensities for skull stripping\n"
+ "\n"
"Copyright: Center for Biomedical Image Computing and Analytics (CBICA), University of Pennsylvania.\n"
"For questions and feedback contact: software@cbica.upenn.edu",
)
parser.add_argument(
"-i",
"--input_path",
dest="input_path",
help="input path for the tissues",
required=True,
)
parser.add_argument(
"-o",
"--output_path",
dest="output_path",
help="output path for saving the files",
required=True,
)
parser.add_argument(
"-t",
"--threads",
dest="threads",
help="number of threads, by default will use all",
)
parser.add_argument(
"-v",
"--version",
action="version",
version=pkg_resources.require("BrainMaGe")[0].version
+ "\n\nCopyright: Center for Biomedical Image Computing and Analytics (CBICA), University of Pennsylvania.",
help="Show program's version number and exit.",
)
args = parser.parse_args()
if args.threads:
n_processes = int(args.threads)
else:
n_processes = cpu_count()
print("Number of CPU's used : ", n_processes)
input_path = os.path.abspath(args.input_path)
output_path = os.path.abspath(args.output_path)
os.makedirs(output_path, exist_ok=True)
patients = glob.glob(os.path.abspath(args.input_path) + "/*")
n_processes = cpu_count()
pool = Pool(processes=n_processes)
pool.map(batch_works, range(n_processes))