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deprem-ocr / ocr /ppocr /data /imaug /pg_process.py

Goodsea

paddleocr

fc8c192 almost 3 years ago

34.3 kB

	import math

	import cv2
	import numpy as np

	__all__ = ["PGProcessTrain"]


	class PGProcessTrain(object):
	def __init__(
	self,
	character_dict_path,
	max_text_length,
	max_text_nums,
	tcl_len,
	batch_size=14,
	min_crop_size=24,
	min_text_size=4,
	max_text_size=512,
	**kwargs
	):
	self.tcl_len = tcl_len
	self.max_text_length = max_text_length
	self.max_text_nums = max_text_nums
	self.batch_size = batch_size
	self.min_crop_size = min_crop_size
	self.min_text_size = min_text_size
	self.max_text_size = max_text_size
	self.Lexicon_Table = self.get_dict(character_dict_path)
	self.pad_num = len(self.Lexicon_Table)
	self.img_id = 0

	def get_dict(self, character_dict_path):
	character_str = ""
	with open(character_dict_path, "rb") as fin:
	lines = fin.readlines()
	for line in lines:
	line = line.decode("utf-8").strip("\n").strip("\r\n")
	character_str += line
	dict_character = list(character_str)
	return dict_character

	def quad_area(self, poly):
	"""
	compute area of a polygon
	:param poly:
	:return:
	"""
	edge = [
	(poly[1][0] - poly[0][0]) * (poly[1][1] + poly[0][1]),
	(poly[2][0] - poly[1][0]) * (poly[2][1] + poly[1][1]),
	(poly[3][0] - poly[2][0]) * (poly[3][1] + poly[2][1]),
	(poly[0][0] - poly[3][0]) * (poly[0][1] + poly[3][1]),
	]
	return np.sum(edge) / 2.0

	def gen_quad_from_poly(self, poly):
	"""
	Generate min area quad from poly.
	"""
	point_num = poly.shape[0]
	min_area_quad = np.zeros((4, 2), dtype=np.float32)
	rect = cv2.minAreaRect(
	poly.astype(np.int32)
	) # (center (x,y), (width, height), angle of rotation)
	box = np.array(cv2.boxPoints(rect))

	first_point_idx = 0
	min_dist = 1e4
	for i in range(4):
	dist = (
	np.linalg.norm(box[(i + 0) % 4] - poly[0])
	+ np.linalg.norm(box[(i + 1) % 4] - poly[point_num // 2 - 1])
	+ np.linalg.norm(box[(i + 2) % 4] - poly[point_num // 2])
	+ np.linalg.norm(box[(i + 3) % 4] - poly[-1])
	)
	if dist < min_dist:
	min_dist = dist
	first_point_idx = i
	for i in range(4):
	min_area_quad[i] = box[(first_point_idx + i) % 4]

	return min_area_quad

	def check_and_validate_polys(self, polys, tags, im_size):
	"""
	check so that the text poly is in the same direction,
	and also filter some invalid polygons
	:param polys:
	:param tags:
	:return:
	"""
	(h, w) = im_size
	if polys.shape[0] == 0:
	return polys, np.array([]), np.array([])
	polys[:, :, 0] = np.clip(polys[:, :, 0], 0, w - 1)
	polys[:, :, 1] = np.clip(polys[:, :, 1], 0, h - 1)

	validated_polys = []
	validated_tags = []
	hv_tags = []
	for poly, tag in zip(polys, tags):
	quad = self.gen_quad_from_poly(poly)
	p_area = self.quad_area(quad)
	if abs(p_area) < 1:
	print("invalid poly")
	continue
	if p_area > 0:
	if tag == False:
	print("poly in wrong direction")
	tag = True # reversed cases should be ignore
	poly = poly[(0, 15, 14, 13, 12, 11, 10, 9, 8, 7, 6, 5, 4, 3, 2, 1), :]
	quad = quad[(0, 3, 2, 1), :]

	len_w = np.linalg.norm(quad[0] - quad[1]) + np.linalg.norm(
	quad[3] - quad[2]
	)
	len_h = np.linalg.norm(quad[0] - quad[3]) + np.linalg.norm(
	quad[1] - quad[2]
	)
	hv_tag = 1

	if len_w * 2.0 < len_h:
	hv_tag = 0

	validated_polys.append(poly)
	validated_tags.append(tag)
	hv_tags.append(hv_tag)
	return np.array(validated_polys), np.array(validated_tags), np.array(hv_tags)

	def crop_area(
	self, im, polys, tags, hv_tags, txts, crop_background=False, max_tries=25
	):
	"""
	make random crop from the input image
	:param im:
	:param polys: [b,4,2]
	:param tags:
	:param crop_background:
	:param max_tries: 50 -> 25
	:return:
	"""
	h, w, _ = im.shape
	pad_h = h // 10
	pad_w = w // 10
	h_array = np.zeros((h + pad_h * 2), dtype=np.int32)
	w_array = np.zeros((w + pad_w * 2), dtype=np.int32)
	for poly in polys:
	poly = np.round(poly, decimals=0).astype(np.int32)
	minx = np.min(poly[:, 0])
	maxx = np.max(poly[:, 0])
	w_array[minx + pad_w : maxx + pad_w] = 1
	miny = np.min(poly[:, 1])
	maxy = np.max(poly[:, 1])
	h_array[miny + pad_h : maxy + pad_h] = 1
	# ensure the cropped area not across a text
	h_axis = np.where(h_array == 0)[0]
	w_axis = np.where(w_array == 0)[0]
	if len(h_axis) == 0 or len(w_axis) == 0:
	return im, polys, tags, hv_tags, txts
	for i in range(max_tries):
	xx = np.random.choice(w_axis, size=2)
	xmin = np.min(xx) - pad_w
	xmax = np.max(xx) - pad_w
	xmin = np.clip(xmin, 0, w - 1)
	xmax = np.clip(xmax, 0, w - 1)
	yy = np.random.choice(h_axis, size=2)
	ymin = np.min(yy) - pad_h
	ymax = np.max(yy) - pad_h
	ymin = np.clip(ymin, 0, h - 1)
	ymax = np.clip(ymax, 0, h - 1)
	if xmax - xmin < self.min_crop_size or ymax - ymin < self.min_crop_size:
	continue
	if polys.shape[0] != 0:
	poly_axis_in_area = (
	(polys[:, :, 0] >= xmin)
	& (polys[:, :, 0] <= xmax)
	& (polys[:, :, 1] >= ymin)
	& (polys[:, :, 1] <= ymax)
	)
	selected_polys = np.where(np.sum(poly_axis_in_area, axis=1) == 4)[0]
	else:
	selected_polys = []
	if len(selected_polys) == 0:
	# no text in this area
	if crop_background:
	txts_tmp = []
	for selected_poly in selected_polys:
	txts_tmp.append(txts[selected_poly])
	txts = txts_tmp
	return (
	im[ymin : ymax + 1, xmin : xmax + 1, :],
	polys[selected_polys],
	tags[selected_polys],
	hv_tags[selected_polys],
	txts,
	)
	else:
	continue
	im = im[ymin : ymax + 1, xmin : xmax + 1, :]
	polys = polys[selected_polys]
	tags = tags[selected_polys]
	hv_tags = hv_tags[selected_polys]
	txts_tmp = []
	for selected_poly in selected_polys:
	txts_tmp.append(txts[selected_poly])
	txts = txts_tmp
	polys[:, :, 0] -= xmin
	polys[:, :, 1] -= ymin
	return im, polys, tags, hv_tags, txts

	return im, polys, tags, hv_tags, txts

	def fit_and_gather_tcl_points_v2(
	self,
	min_area_quad,
	poly,
	max_h,
	max_w,
	fixed_point_num=64,
	img_id=0,
	reference_height=3,
	):
	"""
	Find the center point of poly as key_points, then fit and gather.
	"""
	key_point_xys = []
	point_num = poly.shape[0]
	for idx in range(point_num // 2):
	center_point = (poly[idx] + poly[point_num - 1 - idx]) / 2.0
	key_point_xys.append(center_point)

	tmp_image = np.zeros(
	shape=(
	max_h,
	max_w,
	),
	dtype="float32",
	)
	cv2.polylines(tmp_image, [np.array(key_point_xys).astype("int32")], False, 1.0)
	ys, xs = np.where(tmp_image > 0)
	xy_text = np.array(list(zip(xs, ys)), dtype="float32")

	left_center_pt = ((min_area_quad[0] - min_area_quad[1]) / 2.0).reshape(1, 2)
	right_center_pt = ((min_area_quad[1] - min_area_quad[2]) / 2.0).reshape(1, 2)
	proj_unit_vec = (right_center_pt - left_center_pt) / (
	np.linalg.norm(right_center_pt - left_center_pt) + 1e-6
	)
	proj_unit_vec_tile = np.tile(proj_unit_vec, (xy_text.shape[0], 1)) # (n, 2)
	left_center_pt_tile = np.tile(left_center_pt, (xy_text.shape[0], 1)) # (n, 2)
	xy_text_to_left_center = xy_text - left_center_pt_tile
	proj_value = np.sum(xy_text_to_left_center * proj_unit_vec_tile, axis=1)
	xy_text = xy_text[np.argsort(proj_value)]

	# convert to np and keep the num of point not greater then fixed_point_num
	pos_info = np.array(xy_text).reshape(-1, 2)[:, ::-1] # xy-> yx
	point_num = len(pos_info)
	if point_num > fixed_point_num:
	keep_ids = [
	int((point_num * 1.0 / fixed_point_num) * x)
	for x in range(fixed_point_num)
	]
	pos_info = pos_info[keep_ids, :]

	keep = int(min(len(pos_info), fixed_point_num))
	if np.random.rand() < 0.2 and reference_height >= 3:
	dl = (np.random.rand(keep) - 0.5) * reference_height * 0.3
	random_float = np.array([1, 0]).reshape([1, 2]) * dl.reshape([keep, 1])
	pos_info += random_float
	pos_info[:, 0] = np.clip(pos_info[:, 0], 0, max_h - 1)
	pos_info[:, 1] = np.clip(pos_info[:, 1], 0, max_w - 1)

	# padding to fixed length
	pos_l = np.zeros((self.tcl_len, 3), dtype=np.int32)
	pos_l[:, 0] = np.ones((self.tcl_len,)) * img_id
	pos_m = np.zeros((self.tcl_len, 1), dtype=np.float32)
	pos_l[:keep, 1:] = np.round(pos_info).astype(np.int32)
	pos_m[:keep] = 1.0
	return pos_l, pos_m

	def generate_direction_map(self, poly_quads, n_char, direction_map):
	""" """
	width_list = []
	height_list = []
	for quad in poly_quads:
	quad_w = (
	np.linalg.norm(quad[0] - quad[1]) + np.linalg.norm(quad[2] - quad[3])
	) / 2.0
	quad_h = (
	np.linalg.norm(quad[0] - quad[3]) + np.linalg.norm(quad[2] - quad[1])
	) / 2.0
	width_list.append(quad_w)
	height_list.append(quad_h)
	norm_width = max(sum(width_list) / n_char, 1.0)
	average_height = max(sum(height_list) / len(height_list), 1.0)
	k = 1
	for quad in poly_quads:
	direct_vector_full = ((quad[1] + quad[2]) - (quad[0] + quad[3])) / 2.0
	direct_vector = (
	direct_vector_full
	/ (np.linalg.norm(direct_vector_full) + 1e-6)
	* norm_width
	)
	direction_label = tuple(
	map(float, [direct_vector[0], direct_vector[1], 1.0 / average_height])
	)
	cv2.fillPoly(
	direction_map,
	quad.round().astype(np.int32)[np.newaxis, :, :],
	direction_label,
	)
	k += 1
	return direction_map

	def calculate_average_height(self, poly_quads):
	""" """
	height_list = []
	for quad in poly_quads:
	quad_h = (
	np.linalg.norm(quad[0] - quad[3]) + np.linalg.norm(quad[2] - quad[1])
	) / 2.0
	height_list.append(quad_h)
	average_height = max(sum(height_list) / len(height_list), 1.0)
	return average_height

	def generate_tcl_ctc_label(
	self,
	h,
	w,
	polys,
	tags,
	text_strs,
	ds_ratio,
	tcl_ratio=0.3,
	shrink_ratio_of_width=0.15,
	):
	"""
	Generate polygon.
	"""
	score_map_big = np.zeros(
	(
	h,
	w,
	),
	dtype=np.float32,
	)
	h, w = int(h * ds_ratio), int(w * ds_ratio)
	polys = polys * ds_ratio

	score_map = np.zeros(
	(
	h,
	w,
	),
	dtype=np.float32,
	)
	score_label_map = np.zeros(
	(
	h,
	w,
	),
	dtype=np.float32,
	)
	tbo_map = np.zeros((h, w, 5), dtype=np.float32)
	training_mask = np.ones(
	(
	h,
	w,
	),
	dtype=np.float32,
	)
	direction_map = np.ones((h, w, 3)) * np.array([0, 0, 1]).reshape(
	[1, 1, 3]
	).astype(np.float32)

	label_idx = 0
	score_label_map_text_label_list = []
	pos_list, pos_mask, label_list = [], [], []
	for poly_idx, poly_tag in enumerate(zip(polys, tags)):
	poly = poly_tag[0]
	tag = poly_tag[1]

	# generate min_area_quad
	min_area_quad, center_point = self.gen_min_area_quad_from_poly(poly)
	min_area_quad_h = 0.5 * (
	np.linalg.norm(min_area_quad[0] - min_area_quad[3])
	+ np.linalg.norm(min_area_quad[1] - min_area_quad[2])
	)
	min_area_quad_w = 0.5 * (
	np.linalg.norm(min_area_quad[0] - min_area_quad[1])
	+ np.linalg.norm(min_area_quad[2] - min_area_quad[3])
	)

	if (
	min(min_area_quad_h, min_area_quad_w) < self.min_text_size * ds_ratio
	or min(min_area_quad_h, min_area_quad_w) > self.max_text_size * ds_ratio
	):
	continue

	if tag:
	cv2.fillPoly(
	training_mask, poly.astype(np.int32)[np.newaxis, :, :], 0.15
	)
	else:
	text_label = text_strs[poly_idx]
	text_label = self.prepare_text_label(text_label, self.Lexicon_Table)

	text_label_index_list = [
	[self.Lexicon_Table.index(c_)]
	for c_ in text_label
	if c_ in self.Lexicon_Table
	]
	if len(text_label_index_list) < 1:
	continue

	tcl_poly = self.poly2tcl(poly, tcl_ratio)
	tcl_quads = self.poly2quads(tcl_poly)
	poly_quads = self.poly2quads(poly)

	stcl_quads, quad_index = self.shrink_poly_along_width(
	tcl_quads,
	shrink_ratio_of_width=shrink_ratio_of_width,
	expand_height_ratio=1.0 / tcl_ratio,
	)

	cv2.fillPoly(score_map, np.round(stcl_quads).astype(np.int32), 1.0)
	cv2.fillPoly(
	score_map_big, np.round(stcl_quads / ds_ratio).astype(np.int32), 1.0
	)

	for idx, quad in enumerate(stcl_quads):
	quad_mask = np.zeros((h, w), dtype=np.float32)
	quad_mask = cv2.fillPoly(
	quad_mask,
	np.round(quad[np.newaxis, :, :]).astype(np.int32),
	1.0,
	)
	tbo_map = self.gen_quad_tbo(
	poly_quads[quad_index[idx]], quad_mask, tbo_map
	)

	# score label map and score_label_map_text_label_list for refine
	if label_idx == 0:
	text_pos_list_ = [
	[len(self.Lexicon_Table)],
	]
	score_label_map_text_label_list.append(text_pos_list_)

	label_idx += 1
	cv2.fillPoly(
	score_label_map, np.round(poly_quads).astype(np.int32), label_idx
	)
	score_label_map_text_label_list.append(text_label_index_list)

	# direction info, fix-me
	n_char = len(text_label_index_list)
	direction_map = self.generate_direction_map(
	poly_quads, n_char, direction_map
	)

	# pos info
	average_shrink_height = self.calculate_average_height(stcl_quads)
	pos_l, pos_m = self.fit_and_gather_tcl_points_v2(
	min_area_quad,
	poly,
	max_h=h,
	max_w=w,
	fixed_point_num=64,
	img_id=self.img_id,
	reference_height=average_shrink_height,
	)

	label_l = text_label_index_list
	if len(text_label_index_list) < 2:
	continue

	pos_list.append(pos_l)
	pos_mask.append(pos_m)
	label_list.append(label_l)

	# use big score_map for smooth tcl lines
	score_map_big_resized = cv2.resize(
	score_map_big, dsize=None, fx=ds_ratio, fy=ds_ratio
	)
	score_map = np.array(score_map_big_resized > 1e-3, dtype="float32")

	return (
	score_map,
	score_label_map,
	tbo_map,
	direction_map,
	training_mask,
	pos_list,
	pos_mask,
	label_list,
	score_label_map_text_label_list,
	)

	def adjust_point(self, poly):
	"""
	adjust point order.
	"""
	point_num = poly.shape[0]
	if point_num == 4:
	len_1 = np.linalg.norm(poly[0] - poly[1])
	len_2 = np.linalg.norm(poly[1] - poly[2])
	len_3 = np.linalg.norm(poly[2] - poly[3])
	len_4 = np.linalg.norm(poly[3] - poly[0])

	if (len_1 + len_3) * 1.5 < (len_2 + len_4):
	poly = poly[[1, 2, 3, 0], :]

	elif point_num > 4:
	vector_1 = poly[0] - poly[1]
	vector_2 = poly[1] - poly[2]
	cos_theta = np.dot(vector_1, vector_2) / (
	np.linalg.norm(vector_1) * np.linalg.norm(vector_2) + 1e-6
	)
	theta = np.arccos(np.round(cos_theta, decimals=4))

	if abs(theta) > (70 / 180 * math.pi):
	index = list(range(1, point_num)) + [0]
	poly = poly[np.array(index), :]
	return poly

	def gen_min_area_quad_from_poly(self, poly):
	"""
	Generate min area quad from poly.
	"""
	point_num = poly.shape[0]
	min_area_quad = np.zeros((4, 2), dtype=np.float32)
	if point_num == 4:
	min_area_quad = poly
	center_point = np.sum(poly, axis=0) / 4
	else:
	rect = cv2.minAreaRect(
	poly.astype(np.int32)
	) # (center (x,y), (width, height), angle of rotation)
	center_point = rect[0]
	box = np.array(cv2.boxPoints(rect))

	first_point_idx = 0
	min_dist = 1e4
	for i in range(4):
	dist = (
	np.linalg.norm(box[(i + 0) % 4] - poly[0])
	+ np.linalg.norm(box[(i + 1) % 4] - poly[point_num // 2 - 1])
	+ np.linalg.norm(box[(i + 2) % 4] - poly[point_num // 2])
	+ np.linalg.norm(box[(i + 3) % 4] - poly[-1])
	)
	if dist < min_dist:
	min_dist = dist
	first_point_idx = i

	for i in range(4):
	min_area_quad[i] = box[(first_point_idx + i) % 4]

	return min_area_quad, center_point

	def shrink_quad_along_width(self, quad, begin_width_ratio=0.0, end_width_ratio=1.0):
	"""
	Generate shrink_quad_along_width.
	"""
	ratio_pair = np.array(
	[[begin_width_ratio], [end_width_ratio]], dtype=np.float32
	)
	p0_1 = quad[0] + (quad[1] - quad[0]) * ratio_pair
	p3_2 = quad[3] + (quad[2] - quad[3]) * ratio_pair
	return np.array([p0_1[0], p0_1[1], p3_2[1], p3_2[0]])

	def shrink_poly_along_width(
	self, quads, shrink_ratio_of_width, expand_height_ratio=1.0
	):
	"""
	shrink poly with given length.
	"""
	upper_edge_list = []

	def get_cut_info(edge_len_list, cut_len):
	for idx, edge_len in enumerate(edge_len_list):
	cut_len -= edge_len
	if cut_len <= 0.000001:
	ratio = (cut_len + edge_len_list[idx]) / edge_len_list[idx]
	return idx, ratio

	for quad in quads:
	upper_edge_len = np.linalg.norm(quad[0] - quad[1])
	upper_edge_list.append(upper_edge_len)

	# length of left edge and right edge.
	left_length = np.linalg.norm(quads[0][0] - quads[0][3]) * expand_height_ratio
	right_length = np.linalg.norm(quads[-1][1] - quads[-1][2]) * expand_height_ratio

	shrink_length = (
	min(left_length, right_length, sum(upper_edge_list)) * shrink_ratio_of_width
	)
	# shrinking length
	upper_len_left = shrink_length
	upper_len_right = sum(upper_edge_list) - shrink_length

	left_idx, left_ratio = get_cut_info(upper_edge_list, upper_len_left)
	left_quad = self.shrink_quad_along_width(
	quads[left_idx], begin_width_ratio=left_ratio, end_width_ratio=1
	)
	right_idx, right_ratio = get_cut_info(upper_edge_list, upper_len_right)
	right_quad = self.shrink_quad_along_width(
	quads[right_idx], begin_width_ratio=0, end_width_ratio=right_ratio
	)

	out_quad_list = []
	if left_idx == right_idx:
	out_quad_list.append(
	[left_quad[0], right_quad[1], right_quad[2], left_quad[3]]
	)
	else:
	out_quad_list.append(left_quad)
	for idx in range(left_idx + 1, right_idx):
	out_quad_list.append(quads[idx])
	out_quad_list.append(right_quad)

	return np.array(out_quad_list), list(range(left_idx, right_idx + 1))

	def prepare_text_label(self, label_str, Lexicon_Table):
	"""
	Prepare text lablel by given Lexicon_Table.
	"""
	if len(Lexicon_Table) == 36:
	return label_str.lower()
	else:
	return label_str

	def vector_angle(self, A, B):
	"""
	Calculate the angle between vector AB and x-axis positive direction.
	"""
	AB = np.array([B[1] - A[1], B[0] - A[0]])
	return np.arctan2(*AB)

	def theta_line_cross_point(self, theta, point):
	"""
	Calculate the line through given point and angle in ax + by + c =0 form.
	"""
	x, y = point
	cos = np.cos(theta)
	sin = np.sin(theta)
	return [sin, -cos, cos * y - sin * x]

	def line_cross_two_point(self, A, B):
	"""
	Calculate the line through given point A and B in ax + by + c =0 form.
	"""
	angle = self.vector_angle(A, B)
	return self.theta_line_cross_point(angle, A)

	def average_angle(self, poly):
	"""
	Calculate the average angle between left and right edge in given poly.
	"""
	p0, p1, p2, p3 = poly
	angle30 = self.vector_angle(p3, p0)
	angle21 = self.vector_angle(p2, p1)
	return (angle30 + angle21) / 2

	def line_cross_point(self, line1, line2):
	"""
	line1 and line2 in 0=ax+by+c form, compute the cross point of line1 and line2
	"""
	a1, b1, c1 = line1
	a2, b2, c2 = line2
	d = a1 * b2 - a2 * b1

	if d == 0:
	print("Cross point does not exist")
	return np.array([0, 0], dtype=np.float32)
	else:
	x = (b1 * c2 - b2 * c1) / d
	y = (a2 * c1 - a1 * c2) / d

	return np.array([x, y], dtype=np.float32)

	def quad2tcl(self, poly, ratio):
	"""
	Generate center line by poly clock-wise point. (4, 2)
	"""
	ratio_pair = np.array([[0.5 - ratio / 2], [0.5 + ratio / 2]], dtype=np.float32)
	p0_3 = poly[0] + (poly[3] - poly[0]) * ratio_pair
	p1_2 = poly[1] + (poly[2] - poly[1]) * ratio_pair
	return np.array([p0_3[0], p1_2[0], p1_2[1], p0_3[1]])

	def poly2tcl(self, poly, ratio):
	"""
	Generate center line by poly clock-wise point.
	"""
	ratio_pair = np.array([[0.5 - ratio / 2], [0.5 + ratio / 2]], dtype=np.float32)
	tcl_poly = np.zeros_like(poly)
	point_num = poly.shape[0]

	for idx in range(point_num // 2):
	point_pair = (
	poly[idx] + (poly[point_num - 1 - idx] - poly[idx]) * ratio_pair
	)
	tcl_poly[idx] = point_pair[0]
	tcl_poly[point_num - 1 - idx] = point_pair[1]
	return tcl_poly

	def gen_quad_tbo(self, quad, tcl_mask, tbo_map):
	"""
	Generate tbo_map for give quad.
	"""
	# upper and lower line function: ax + by + c = 0;
	up_line = self.line_cross_two_point(quad[0], quad[1])
	lower_line = self.line_cross_two_point(quad[3], quad[2])

	quad_h = 0.5 * (
	np.linalg.norm(quad[0] - quad[3]) + np.linalg.norm(quad[1] - quad[2])
	)
	quad_w = 0.5 * (
	np.linalg.norm(quad[0] - quad[1]) + np.linalg.norm(quad[2] - quad[3])
	)

	# average angle of left and right line.
	angle = self.average_angle(quad)

	xy_in_poly = np.argwhere(tcl_mask == 1)
	for y, x in xy_in_poly:
	point = (x, y)
	line = self.theta_line_cross_point(angle, point)
	cross_point_upper = self.line_cross_point(up_line, line)
	cross_point_lower = self.line_cross_point(lower_line, line)
	##FIX, offset reverse
	upper_offset_x, upper_offset_y = cross_point_upper - point
	lower_offset_x, lower_offset_y = cross_point_lower - point
	tbo_map[y, x, 0] = upper_offset_y
	tbo_map[y, x, 1] = upper_offset_x
	tbo_map[y, x, 2] = lower_offset_y
	tbo_map[y, x, 3] = lower_offset_x
	tbo_map[y, x, 4] = 1.0 / max(min(quad_h, quad_w), 1.0) * 2
	return tbo_map

	def poly2quads(self, poly):
	"""
	Split poly into quads.
	"""
	quad_list = []
	point_num = poly.shape[0]

	# point pair
	point_pair_list = []
	for idx in range(point_num // 2):
	point_pair = [poly[idx], poly[point_num - 1 - idx]]
	point_pair_list.append(point_pair)

	quad_num = point_num // 2 - 1
	for idx in range(quad_num):
	# reshape and adjust to clock-wise
	quad_list.append(
	(np.array(point_pair_list)[[idx, idx + 1]]).reshape(4, 2)[[0, 2, 3, 1]]
	)

	return np.array(quad_list)

	def rotate_im_poly(self, im, text_polys):
	"""
	rotate image with 90 / 180 / 270 degre
	"""
	im_w, im_h = im.shape[1], im.shape[0]
	dst_im = im.copy()
	dst_polys = []
	rand_degree_ratio = np.random.rand()
	rand_degree_cnt = 1
	if rand_degree_ratio > 0.5:
	rand_degree_cnt = 3
	for i in range(rand_degree_cnt):
	dst_im = np.rot90(dst_im)
	rot_degree = -90 * rand_degree_cnt
	rot_angle = rot_degree * math.pi / 180.0
	n_poly = text_polys.shape[0]
	cx, cy = 0.5 * im_w, 0.5 * im_h
	ncx, ncy = 0.5 * dst_im.shape[1], 0.5 * dst_im.shape[0]
	for i in range(n_poly):
	wordBB = text_polys[i]
	poly = []
	for j in range(4): # 16->4
	sx, sy = wordBB[j][0], wordBB[j][1]
	dx = (
	math.cos(rot_angle) * (sx - cx)
	- math.sin(rot_angle) * (sy - cy)
	+ ncx
	)
	dy = (
	math.sin(rot_angle) * (sx - cx)
	+ math.cos(rot_angle) * (sy - cy)
	+ ncy
	)
	poly.append([dx, dy])
	dst_polys.append(poly)
	return dst_im, np.array(dst_polys, dtype=np.float32)

	def __call__(self, data):
	input_size = 512
	im = data["image"]
	text_polys = data["polys"]
	text_tags = data["ignore_tags"]
	text_strs = data["texts"]
	h, w, _ = im.shape
	text_polys, text_tags, hv_tags = self.check_and_validate_polys(
	text_polys, text_tags, (h, w)
	)
	if text_polys.shape[0] <= 0:
	return None
	# set aspect ratio and keep area fix
	asp_scales = np.arange(1.0, 1.55, 0.1)
	asp_scale = np.random.choice(asp_scales)
	if np.random.rand() < 0.5:
	asp_scale = 1.0 / asp_scale
	asp_scale = math.sqrt(asp_scale)

	asp_wx = asp_scale
	asp_hy = 1.0 / asp_scale
	im = cv2.resize(im, dsize=None, fx=asp_wx, fy=asp_hy)
	text_polys[:, :, 0] *= asp_wx
	text_polys[:, :, 1] *= asp_hy

	h, w, _ = im.shape
	if max(h, w) > 2048:
	rd_scale = 2048.0 / max(h, w)
	im = cv2.resize(im, dsize=None, fx=rd_scale, fy=rd_scale)
	text_polys *= rd_scale
	h, w, _ = im.shape
	if min(h, w) < 16:
	return None

	# no background
	im, text_polys, text_tags, hv_tags, text_strs = self.crop_area(
	im, text_polys, text_tags, hv_tags, text_strs, crop_background=False
	)

	if text_polys.shape[0] == 0:
	return None
	# # continue for all ignore case
	if np.sum((text_tags * 1.0)) >= text_tags.size:
	return None
	new_h, new_w, _ = im.shape
	if (new_h is None) or (new_w is None):
	return None
	# resize image
	std_ratio = float(input_size) / max(new_w, new_h)
	rand_scales = np.array(
	[0.25, 0.375, 0.5, 0.625, 0.75, 0.875, 1.0, 1.0, 1.0, 1.0, 1.0]
	)
	rz_scale = std_ratio * np.random.choice(rand_scales)
	im = cv2.resize(im, dsize=None, fx=rz_scale, fy=rz_scale)
	text_polys[:, :, 0] *= rz_scale
	text_polys[:, :, 1] *= rz_scale

	# add gaussian blur
	if np.random.rand() < 0.1 * 0.5:
	ks = np.random.permutation(5)[0] + 1
	ks = int(ks / 2) * 2 + 1
	im = cv2.GaussianBlur(im, ksize=(ks, ks), sigmaX=0, sigmaY=0)
	# add brighter
	if np.random.rand() < 0.1 * 0.5:
	im = im * (1.0 + np.random.rand() * 0.5)
	im = np.clip(im, 0.0, 255.0)
	# add darker
	if np.random.rand() < 0.1 * 0.5:
	im = im * (1.0 - np.random.rand() * 0.5)
	im = np.clip(im, 0.0, 255.0)

	# Padding the im to [input_size, input_size]
	new_h, new_w, _ = im.shape
	if min(new_w, new_h) < input_size * 0.5:
	return None
	im_padded = np.ones((input_size, input_size, 3), dtype=np.float32)
	im_padded[:, :, 2] = 0.485 * 255
	im_padded[:, :, 1] = 0.456 * 255
	im_padded[:, :, 0] = 0.406 * 255

	# Random the start position
	del_h = input_size - new_h
	del_w = input_size - new_w
	sh, sw = 0, 0
	if del_h > 1:
	sh = int(np.random.rand() * del_h)
	if del_w > 1:
	sw = int(np.random.rand() * del_w)

	# Padding
	im_padded[sh : sh + new_h, sw : sw + new_w, :] = im.copy()
	text_polys[:, :, 0] += sw
	text_polys[:, :, 1] += sh

	(
	score_map,
	score_label_map,
	border_map,
	direction_map,
	training_mask,
	pos_list,
	pos_mask,
	label_list,
	score_label_map_text_label,
	) = self.generate_tcl_ctc_label(
	input_size, input_size, text_polys, text_tags, text_strs, 0.25
	)
	if len(label_list) <= 0: # eliminate negative samples
	return None
	pos_list_temp = np.zeros([64, 3])
	pos_mask_temp = np.zeros([64, 1])
	label_list_temp = np.zeros([self.max_text_length, 1]) + self.pad_num

	for i, label in enumerate(label_list):
	n = len(label)
	if n > self.max_text_length:
	label_list[i] = label[: self.max_text_length]
	continue
	while n < self.max_text_length:
	label.append([self.pad_num])
	n += 1

	for i in range(len(label_list)):
	label_list[i] = np.array(label_list[i])

	if len(pos_list) <= 0 or len(pos_list) > self.max_text_nums:
	return None
	for __ in range(self.max_text_nums - len(pos_list), 0, -1):
	pos_list.append(pos_list_temp)
	pos_mask.append(pos_mask_temp)
	label_list.append(label_list_temp)

	if self.img_id == self.batch_size - 1:
	self.img_id = 0
	else:
	self.img_id += 1

	im_padded[:, :, 2] -= 0.485 * 255
	im_padded[:, :, 1] -= 0.456 * 255
	im_padded[:, :, 0] -= 0.406 * 255
	im_padded[:, :, 2] /= 255.0 * 0.229
	im_padded[:, :, 1] /= 255.0 * 0.224
	im_padded[:, :, 0] /= 255.0 * 0.225
	im_padded = im_padded.transpose((2, 0, 1))
	images = im_padded[::-1, :, :]
	tcl_maps = score_map[np.newaxis, :, :]
	tcl_label_maps = score_label_map[np.newaxis, :, :]
	border_maps = border_map.transpose((2, 0, 1))
	direction_maps = direction_map.transpose((2, 0, 1))
	training_masks = training_mask[np.newaxis, :, :]
	pos_list = np.array(pos_list)
	pos_mask = np.array(pos_mask)
	label_list = np.array(label_list)
	data["images"] = images
	data["tcl_maps"] = tcl_maps
	data["tcl_label_maps"] = tcl_label_maps
	data["border_maps"] = border_maps
	data["direction_maps"] = direction_maps
	data["training_masks"] = training_masks
	data["label_list"] = label_list
	data["pos_list"] = pos_list
	data["pos_mask"] = pos_mask
	return data