Theo Viel

Update docstring, typing and improve consistency

9e99f59 3 months ago

8.71 kB

	import numpy as np
	import numpy.typing as npt
	from typing import Dict, List, Tuple, Literal


	def get_overlaps(
	boxes: npt.NDArray[np.float64],
	other_boxes: npt.NDArray[np.float64],
	normalize: Literal["box_only", "all"] = "box_only",
	) -> npt.NDArray[np.float64]:
	"""
	Checks if a box overlaps with any other box.
	Boxes are expeceted in format (x0, y0, x1, y1)

	Args:
	boxes (np array [4] or [n x 4]): Boxes.
	other_boxes (np array [m x 4]): Other boxes.

	Returns:
	np array [n x m]: Overlaps.
	"""
	if boxes.ndim == 1:
	boxes = boxes[None, :]

	x0, y0, x1, y1 = (
	boxes[:, 0][:, None],
	boxes[:, 1][:, None],
	boxes[:, 2][:, None],
	boxes[:, 3][:, None],
	)
	areas = (y1 - y0) * (x1 - x0)

	x0_other, y0_other, x1_other, y1_other = (
	other_boxes[:, 0][None, :],
	other_boxes[:, 1][None, :],
	other_boxes[:, 2][None, :],
	other_boxes[:, 3][None, :],
	)
	areas_other = (y1_other - y0_other) * (x1_other - x0_other)

	# Intersection
	inter_y0 = np.maximum(y0, y0_other)
	inter_y1 = np.minimum(y1, y1_other)
	inter_x0 = np.maximum(x0, x0_other)
	inter_x1 = np.minimum(x1, x1_other)
	inter_area = np.maximum(0, inter_y1 - inter_y0) * np.maximum(0, inter_x1 - inter_x0)

	# Overlap
	if normalize == "box_only": # Only consider box included in other box
	overlaps = inter_area / areas
	elif (
	normalize == "all"
	): # Consider box included in other box and other box included in box
	overlaps = inter_area / np.minimum(areas, areas_other[:, None])
	else:
	raise ValueError(f"Invalid normalization: {normalize}")
	return overlaps


	def get_distances(
	title_boxes: npt.NDArray[np.float64], other_boxes: npt.NDArray[np.float64]
	) -> npt.NDArray[np.float64]:
	"""
	Computes the distances between title and table/chart boxes.
	Distance is computed as the sum of the vertical and horizontal distances.
	Horizontal distance uses min(boxes center dist, boxes left dist).
	Vertical distance uses min(top_title to bottom_other dists, bottom_title to top_other dists).

	Args:
	title_boxes (np array [n_titles x 4]): Title boxes.
	other_boxes (np array [n_other x 4]): Other boxes.

	Returns:
	np array [n_titles x n_other]: Distances between titles and other boxes.
	"""
	x0_title, xc_title, y0_title, y1_title = (
	title_boxes[:, 0],
	(title_boxes[:, 0] + title_boxes[:, 2]) / 2,
	title_boxes[:, 1],
	title_boxes[:, 3],
	)
	x0_other, xc_other, y0_other, y1_other = (
	other_boxes[:, 0],
	(other_boxes[:, 0] + other_boxes[:, 2]) / 2,
	other_boxes[:, 1],
	other_boxes[:, 3],
	)

	x_dists = np.min(
	[
	np.abs(
	xc_title[:, None] - xc_other[None, :]
	), # Title center to other center
	np.abs(x0_title[:, None] - x0_other[None, :]), # Title left to other left
	],
	axis=0,
	)

	y_dists = np.min(
	[
	np.abs(y1_title[:, None] - y0_other[None, :]), # Title above other
	np.abs(y0_title[:, None] - y1_other[None, :]), # Title below other
	],
	axis=0,
	)

	dists = y_dists + x_dists / 2
	return dists


	def find_titles(
	title_boxes: npt.NDArray[np.float64],
	table_boxes: npt.NDArray[np.float64],
	chart_boxes: npt.NDArray[np.float64],
	max_dist: float = 0.1,
	) -> Dict[int, Tuple[str, int]]:
	"""
	Associates titles to tables and charts.

	Args:
	title_boxes (np array [n_titles x 4]): Title boxes.
	table_boxes (np array [n_tables x 4]): Table boxes.
	chart_boxes (np array [n_charts x 4]): Chart boxes.
	max_dist (float, optional): Maximum distance between title and table/chart. Defaults to 0.1.

	Returns:
	dict: Dictionary of assigned titles.
	- Keys are the indices of the titles,
	- Values are tuples of:
	- str: Whether the title is assigned to a "chart" or "table"
	- int: index of the assigned table/chart
	"""
	if not len(title_boxes) or not (len(table_boxes) or len(chart_boxes)):
	return {}

	# print(title_boxes.shape, table_boxes.shape, chart_boxes.shape)

	# Get distances
	chart_distances = np.ones((len(title_boxes), 0))
	if len(chart_boxes):
	chart_distances = get_distances(title_boxes, chart_boxes)
	chart_overlaps = get_overlaps(title_boxes, chart_boxes, normalize="box_only")
	# print(chart_overlaps, "chart_overlaps", chart_overlaps.shape)
	# print(chart_distances, "chart_distances", chart_distances.shape)
	chart_distances = np.where(chart_overlaps > 0.25, 0, chart_distances)

	# print(chart_distances)

	table_distances = np.ones((len(title_boxes), 0))
	if len(table_boxes):
	table_distances = get_distances(title_boxes, table_boxes)
	if len(chart_boxes): # Penalize table titles that are inside charts
	table_distances = np.where(
	chart_overlaps.max(1, keepdims=True) > 0.25,
	table_distances * 10,
	table_distances,
	)

	# print(table_distances, "table_distances")

	# Assign to tables
	assigned_titles = {}
	for i, table in enumerate(table_boxes):
	best_match = np.argmin(table_distances[:, i])
	if table_distances[best_match, i] < max_dist:
	assigned_titles[best_match] = ("table", i)
	table_distances[best_match] = np.inf
	chart_distances[best_match] = np.inf

	# Assign to charts
	for i, chart in enumerate(chart_boxes):
	best_match = np.argmin(chart_distances[:, i])
	if chart_distances[best_match, i] < max_dist:
	assigned_titles[best_match] = ("chart", i)
	chart_distances[best_match] = np.inf

	return assigned_titles


	def postprocess_included(
	boxes: npt.NDArray[np.float64],
	labels: npt.NDArray[np.int_],
	confs: npt.NDArray[np.float64],
	class_: str = "title",
	classes: List[str] = ["table", "chart", "title", "infographic"],
	) -> Tuple[npt.NDArray[np.float64], npt.NDArray[np.int_], npt.NDArray[np.float64]]:
	"""
	Post process title predictions.
	- Remove titles that are included in other boxes

	Args:
	boxes (numpy.ndarray [N, 4]): Array of bounding boxes.
	labels (numpy.ndarray [N]): Array of labels.
	confs (numpy.ndarray [N]): Array of confidences.
	class_ (str, optional): Class to postprocess. Defaults to "title".
	classes (list, optional): Classes. Defaults to ["table", "chart", "title", "infographic"].

	Returns:
	boxes (numpy.ndarray): Array of bounding boxes.
	labels (numpy.ndarray): Array of labels.
	confs (numpy.ndarray): Array of confidences.
	"""
	boxes_to_pp = boxes[labels == classes.index(class_)]
	confs_to_pp = confs[labels == classes.index(class_)]

	order = np.argsort(confs_to_pp) # least to most confident for NMS
	boxes_to_pp, confs_to_pp = boxes_to_pp[order], confs_to_pp[order]

	if len(boxes_to_pp) == 0:
	return boxes, labels, confs

	# other_boxes = boxes[labels != classes.index("title")]

	inclusion_classes = ["table", "infographic", "chart"]
	if class_ in ["header_footer", "title"]:
	inclusion_classes.append("text")

	other_boxes = boxes[np.isin(labels, [classes.index(c) for c in inclusion_classes])]

	# Remove boxes included in other_boxes
	kept_boxes, kept_confs = [], []
	for i, b in enumerate(boxes_to_pp):
	# # Inclusion NMS
	# if i < len(titles) - 1:
	# overlaps_titles = get_overlaps(t, titles[i + 1:], normalize="all")
	# if overlaps_titles.max() > 0.9:
	# continue

	# print(t)
	# print(other_boxes)
	if len(other_boxes) > 0:
	overlaps = get_overlaps(b, other_boxes, normalize="box_only")
	if overlaps.max() > 0.9:
	continue

	kept_boxes.append(b)
	kept_confs.append(confs_to_pp[i])

	# Aggregate
	kept_boxes = np.stack(kept_boxes) if len(kept_boxes) else np.empty((0, 4))
	kept_confs = np.stack(kept_confs) if len(kept_confs) else np.empty(0)

	boxes_pp = np.concatenate([boxes[labels != classes.index(class_)], kept_boxes])
	confs_pp = np.concatenate([confs[labels != classes.index(class_)], kept_confs])
	labels_pp = np.concatenate(
	[
	labels[labels != classes.index(class_)],
	np.ones(len(kept_boxes)) * classes.index(class_),
	]
	)

	return boxes_pp, labels_pp, confs_pp