fast-mri/scripts/4.frocs.py

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import SimpleITK as sitk
import tensorflow as tf
from tensorflow.keras.models import load_model
from focal_loss import BinaryFocalLoss
import numpy as np
import multiprocessing
from functools import partial
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import os
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from sfransen.utils_quintin import *
from sfransen.DWI_exp.helpers import *
from sfransen.DWI_exp.preprocessing_function import preprocess
from sfransen.DWI_exp.callbacks import dice_coef
#from sfransen.FROC.blob_preprocess import *
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from sfransen.FROC.cal_froc_from_np import *
from sfransen.load_images import load_images_parrallel
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parser = argparse.ArgumentParser(
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description='Calculate the froc metrics and store in froc_metrics.yml')
parser.add_argument('-experiment',
help='Title of experiment')
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parser.add_argument('--series', '-s',
metavar='[series_name]', required=True, nargs='+',
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help='List of series to include')
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args = parser.parse_args()
# if __name__ = '__main__':
# bovenstaande nodig om fork probleem op te lossen (windows cs linux)
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######## CUDA ################
os.environ["CUDA_VISIBLE_DEVICES"] = "2"
######## constants #############
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SERIES = args.series
series_ = '_'.join(args.series)
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EXPERIMENT = args.experiment
MODEL_PATH = f'./../train_output/{EXPERIMENT}_{series_}/models/{EXPERIMENT}_{series_}_dice.h5'
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YAML_DIR = f'./../train_output/{EXPERIMENT}_{series_}'
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IMAGE_DIR = f'./../train_output/{EXPERIMENT}_{series_}'
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DATA_DIR = "./../data/Nijmegen paths/"
TARGET_SPACING = (0.5, 0.5, 3)
INPUT_SHAPE = (192, 192, 24, len(SERIES))
IMAGE_SHAPE = INPUT_SHAPE[:3]
DATA_SPLIT_INDEX = read_yaml_to_dict('./../data/Nijmegen paths/train_val_test_idxs.yml')
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TEST_INDEX = DATA_SPLIT_INDEX['val_set0']
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N_CPUS = 12
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########## load images in parrallel ##############
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print_(f"> Loading images into RAM...")
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# read paths from txt
image_paths = {}
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for s in SERIES:
with open(path.join(DATA_DIR, f"{s}.txt"), 'r') as f:
image_paths[s] = [l.strip() for l in f.readlines()]
with open(path.join(DATA_DIR, f"seg.txt"), 'r') as f:
seg_paths = [l.strip() for l in f.readlines()]
num_images = len(seg_paths)
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# create pool of workers
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pool = multiprocessing.Pool(processes=N_CPUS)
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partial_images = partial(load_images_parrallel,
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seq = 'images',
target_shape=IMAGE_SHAPE,
target_space = TARGET_SPACING)
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partial_seg = partial(load_images_parrallel,
seq = 'seg',
target_shape=IMAGE_SHAPE,
target_space = TARGET_SPACING)
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#load images
images = []
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for s in SERIES:
image_paths_seq = image_paths[s]
image_paths_index = np.asarray(image_paths_seq)[TEST_INDEX]
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data_list = pool.map(partial_images,image_paths_index)
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data = np.stack(data_list, axis=0)
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images.append(data)
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images_list = np.transpose(images, (1, 2, 3, 4, 0))
#load segmentations
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seg_paths_index = np.asarray(seg_paths)[TEST_INDEX]
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data_list = pool.map(partial_seg,seg_paths_index)
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segmentations = np.stack(data_list, axis=0)
########### load module ##################
print(' >>>>>>> LOAD MODEL <<<<<<<<<')
dependencies = {
'dice_coef': dice_coef
}
reconstructed_model = load_model(MODEL_PATH, custom_objects=dependencies)
# reconstructed_model.summary(line_length=120)
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# make predictions on all TEST_INDEX
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print(' >>>>>>> START prediction <<<<<<<<<')
predictions_blur = reconstructed_model.predict(images_list, batch_size=1)
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############# preprocess #################
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# preprocess predictions by removing the blur and making individual blobs
print('>>>>>>>> START preprocess')
def move_dims(arr):
# UMCG numpy dimensions convention: dims = (batch, width, heigth, depth)
# Joeran numpy dimensions convention: dims = (batch, depth, heigth, width)
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arr = np.moveaxis(arr, 3, 1)
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arr = np.moveaxis(arr, 3, 2)
return arr
# Joeran has his numpy arrays ordered differently.
predictions_blur = move_dims(np.squeeze(predictions_blur))
segmentations = move_dims(np.squeeze(segmentations))
predictions = [preprocess_softmax(pred, threshold="dynamic")[0] for pred in predictions_blur]
# Remove outer edges
zeros = np.zeros(np.shape(predictions))
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test = np.squeeze(predictions)[:,2:-2,2:190,2:190]
zeros[:,2:-2,2:190,2:190] = test
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predictions = zeros
# perform Froc
metrics = evaluate(y_true=segmentations, y_pred=predictions)
dump_dict_to_yaml(metrics, YAML_DIR, "froc_metrics", verbose=True)
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############## save image as example #################
# save image nmr 3
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img_s = sitk.GetImageFromArray(predictions_blur[3].squeeze())
sitk.WriteImage(img_s, f"{IMAGE_DIR}/predictions_blur_001.nii.gz")
img_s = sitk.GetImageFromArray(predictions[3].squeeze())
sitk.WriteImage(img_s, f"{IMAGE_DIR}/predictions_001.nii.gz")
img_s = sitk.GetImageFromArray(segmentations[3].squeeze())
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sitk.WriteImage(img_s, f"{IMAGE_DIR}/segmentations_001.nii.gz")