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gen_weak.py
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gen_weak.py
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#!/usr/bin/env python3
import random
import argparse
from typing import Callable, List, Tuple
from pathlib import Path
from pprint import pprint
from argparse import Namespace
from functools import partial
import numpy as np
import matplotlib.pyplot as plt
from tqdm import tqdm
from scipy import ndimage
from PIL import Image, ImageDraw
from utils import mmap_, map_
def centroid_strat(orig_mask: np.ndarray, filename: str, filling: int) -> Tuple[np.ndarray, int]:
assert set(np.unique(orig_mask)).issubset({False, True})
size: int = orig_mask.sum()
if size: # Positive images
res_img: Image.Image = Image.new("L", orig_mask.shape, 0)
canvas = ImageDraw.Draw(res_img)
centroid: Tuple[float, float] = ndimage.measurements.center_of_mass(orig_mask)
# Of course the coordinates are inverted
cx, cy = int(centroid[0]), int(centroid[1])
cx, cy = cy, cx
if args.verbose:
print(centroid, cx, cy)
width: int = args.width
dw: int = int(width / 2)
rx: int
ry: int
if args.r > 0:
rx, ry = random.randrange(-args.r, args.r), random.randrange(-args.r, args.r)
else:
rx, ry = 0, 0
canvas.ellipse([cx - dw + rx, cy - dw + ry, cx + dw + rx, cy + dw + ry], fill=filling)
# Remove overflow if needed
masked_res: Image.Image = Image.fromarray(np.array(res_img) * orig_mask, mode='L')
# Sanity check: we do not want the label to go over the border
result_mask = np.array(masked_res) == filling
inter: np.ndarray = orig_mask & result_mask # should be > 1
if inter.sum() < 1: # I assume this case appears only for images that are too small and r too big
# So it makes sense to use the orignal segmentation as ground truth
print(f"No overlap, using orignal mask {filename}")
masked_res = Image.fromarray(orig_mask.astype(np.uint8), mode='L')
else:
masked_res = Image.fromarray(orig_mask.astype(np.uint8), mode='L')
return masked_res, size
def erosion_strat(orig_mask: np.ndarray, filename: str, filling: int) -> Tuple[np.ndarray, int]:
res_img: Image.Image = Image.new("L", orig_mask.shape, 0)
size: int = orig_mask.sum()
if size: # Positive images
struct2 = ndimage.generate_binary_structure(2, 3)
# print(struct2.shape, orig_mask.shape)
gt_eroded = orig_mask[...]
iter = 10
while True: # do while du pauvre
if iter == 0:
gt_eroded = orig_mask[...]
print(f"Using orignal structure for {filename} (size {orig_mask.sum()})")
# plt.imshow(gt_eroded)
# plt.show()
break
gt_eroded = ndimage.binary_erosion(orig_mask, structure=struct2, iterations=iter).astype(orig_mask.dtype)
if gt_eroded.sum() > 0:
break
iter -= 1
res = gt_eroded.astype(np.uint8)
res[res == 1] = filling
res_img = Image.fromarray(res, mode="L")
return res_img, size
def random_strat(orig_mask: np.ndarray, filename: str, filling: int) -> Tuple[np.ndarray, int]:
res_img: Image.Image = Image.new("L", orig_mask.shape, 0)
size: int = orig_mask.sum()
if size: # Positive images
canvas = ImageDraw.Draw(res_img)
xs, ys = np.where(orig_mask == 1)
# print(len(xs), len(ys))
assert len(xs) == len(ys)
random_index: int = np.random.randint(len(xs))
rx, ry = xs[random_index], ys[random_index]
# Of course the coordinates are inverted
rx, ry = ry, rx
# print(centroid, rx, ry)
width: int = args.width
dw: int = int(width / 2)
canvas.ellipse([rx - dw, ry - dw, rx + dw, ry + dw], fill=filling)
# Remove overflow if needed
masked_res: Image.Image = Image.fromarray((np.array(res_img) * orig_mask).astype(np.uint8), mode='L')
res_img = masked_res
return res_img, size
def box_strat(orig_mask: np.ndarray, filename: str, filling: int) -> Tuple[np.ndarray, int]:
orig_arr: np.ndarray = np.array(orig_mask, dtype=np.uint8)
res_arr: np.ndarray = np.zeros_like(orig_arr)
assert orig_arr.dtype == res_arr.dtype
margin: int = args.margin
size: int = orig_mask.sum()
if size: # Positive images
coords = np.argwhere(orig_arr)
x1, y1 = np.maximum(coords - margin, 0).min(axis=0)
x2, y2 = np.minimum(coords + margin, orig_arr.shape).max(axis=0)
res_arr[x1:x2 + 1, y1:y2 + 1] = filling
res = Image.fromarray(res_arr, mode='L')
return res, size
def weaken_img(pn: Tuple, strategy: Callable) -> Tuple[int, int]:
# print(f"Processing {n}")
p: str
n: str
p, n = pn
img: Image.Image = Image.open(p)
try:
assert set(np.unique(img)).issubset({0, 1, 2, 3})
except AssertionError:
print(np.unique(img))
raise
if args.verbose:
plt.imshow(img)
plt.show()
selected_class: int = args.selected_class
filling: int = args.filling
ni: np.ndarray = np.array(img) == selected_class # Keep only background and LV, as booleans
assert set(np.unique(ni)).issubset({False, True})
# Do the magic
res_img, size = strategy(ni, n, filling)
# Final checks, we do not want the label to go over the border
res_arr: np.ndarray = np.array(res_img)
rb = np.array(res_arr) == filling
inter: np.ndarray = ni & rb
inter_neg: np.ndarray = (~ni) & rb
try:
assert res_arr.shape == ni.shape, (res_arr.shape, ni.shape)
assert set(np.unique(rb)).issubset({False, True}), np.unique(rb)
assert set(np.unique(res_arr)).issubset({0, filling}), np.unique(res_arr)
assert rb.sum() <= ni.sum() or args.allow_bigger, (rb.sum(), ni.sum())
assert inter_neg.sum() == 0 or args.allow_overflow, inter_neg.sum() # No overflow over the border
assert inter.sum() > 0 or size == 0, (inter.sum(), size == 0) # At least some overlap
except AssertionError:
# print(res_arr.shape, ni.shape)
# print(np.unique(rb), np.unique(res_arr))
# print(rb.sum(), ni.sum())
# print(inter_neg.sum())
# print(inter.sum())
_, axes = plt.subplots(nrows=1, ncols=2)
for axe, fig in zip(axes, [np.array(img), res_arr]):
axe.imshow(fig)
plt.show()
raise
save_path = Path(args.base_folder, args.save_subfolder, n)
save_path.parent.mkdir(parents=True, exist_ok=True)
res_img.save(save_path)
return size, res_arr.sum()
def main(args: Namespace) -> None:
inputs: List[Path] = list(Path(args.base_folder, args.GT_subfolder).glob(args.regex))
names: List[str] = [p.name for p in inputs]
print(f"Found {len(names)} images to weaken")
if args.verbose:
pprint(names[:10])
strategy: Callable = eval(args.strategy)
strat: Callable = partial(weaken_img, strategy=strategy)
# sizes: np.ndarray = np.zeros(len(inputs), dtype=np.uint32)
# for i, (pn) in tqdm(enumerate(zip(inputs, names)), ncols=100, total=len(names)):
# sizes[i] = strat(pn)
orig_sizes, new_sizes = map_(np.asarray, zip(*mmap_(strat, zip(inputs, names))))
assert len(orig_sizes) == len(new_sizes) == len(names)
print("Orig sizes: (min, mean, max)", orig_sizes[orig_sizes > 0].min(), orig_sizes.mean(), orig_sizes.max())
print(f"Annotated {new_sizes.sum()} pixels for {len(new_sizes)} images")
def get_args() -> Namespace:
parser = argparse.ArgumentParser(description='Dataset params')
parser.add_argument("--base_folder", type=str, required=True)
parser.add_argument("--save_subfolder", type=str, required=True)
parser.add_argument("--seed", type=int, required=True)
parser.add_argument("--strategy", type=str, required=True)
parser.add_argument("--selected_class", type=int, required=True,
help="Default used to be 3")
parser.add_argument("--filling", type=int, required=True,
help="Default used to be 3")
parser.add_argument("--verbose", action="store_true")
parser.add_argument("--allow_bigger", action="store_true")
parser.add_argument("--allow_overflow", action="store_true")
parser.add_argument("--GT_subfolder", default='gt', type=str)
parser.add_argument("--regex", type=str, default="*.png")
parser.add_argument("--r", type=int, default=0)
parser.add_argument("--width", type=int, default=0)
parser.add_argument("--margin", type=int, default=0)
args = parser.parse_args()
print(args)
return args
if __name__ == "__main__":
args: Namespace = get_args()
random.seed(args.seed)
main(args)