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data_utils.py
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data_utils.py
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import os
import random
import torch
import torchvision.transforms as transforms
from torch.utils import data
import glob as gb
import numpy as np
import cv2
import csv
import matplotlib.pyplot as plt
import matplotlib.patches as Patches
from shapely.geometry import Polygon
def get_images(root):
'''
get images's path and name
'''
files = []
for ext in ['jpg', 'png', 'jpeg', 'JPG']:
files.extend(gb.glob(os.path.join(root, '*.{}'.format(ext))))
name = []
for i in range(len(files)):
name.append(files[i].split('/')[-1])
return files, name
def load_annoataion(p):
'''
load annotation from the text file
:param p:
:return:
'''
text_polys = []
text_tags = []
if not os.path.exists(p):
return np.array(text_polys, dtype=np.float32)
with open(p, 'r') as f:
reader = csv.reader(f)
for line in reader:
label = line[-1]
# strip BOM. \ufeff for python3, \xef\xbb\bf for python2
line = [i.strip('\ufeff').strip('\xef\xbb\xbf') for i in line]
x1, y1, x2, y2, x3, y3, x4, y4 = list(map(float, line[:8]))
text_polys.append([[x1, y1], [x2, y2], [x3, y3], [x4, y4]])
if label == '*' or label == '###':
text_tags.append(True)
else:
text_tags.append(False)
return np.array(text_polys, dtype=np.float32), np.array(text_tags, dtype=np.bool)
def polygon_area(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.
def check_and_validate_polys(polys, tags, xxx_todo_changeme):
'''
check so that the text poly is in the same direction,
and also filter some invalid polygons
:param polys:
:param tags:
:return:
'''
(h, w) = xxx_todo_changeme
if polys.shape[0] == 0:
return polys
polys[:, :, 0] = np.clip(polys[:, :, 0], 0, w-1)
polys[:, :, 1] = np.clip(polys[:, :, 1], 0, h-1)
validated_polys = []
validated_tags = []
for poly, tag in zip(polys, tags):
p_area = polygon_area(poly)
if abs(p_area) < 1:
# print poly
print('invalid poly')
continue
if p_area > 0:
print('poly in wrong direction')
poly = poly[(0, 3, 2, 1), :]
validated_polys.append(poly)
validated_tags.append(tag)
return np.array(validated_polys), np.array(validated_tags)
def crop_area(im, polys, tags, crop_background=False, max_tries=50):
'''
make random crop from the input image
:param im:
:param polys:
:param tags:
:param crop_background:
:param max_tries:
: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
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 < FLAGS.min_crop_side_ratio*w or ymax - ymin < FLAGS.min_crop_side_ratio*h:
if xmax - xmin < 0.1*w or ymax - ymin < 0.1*h:
# area too small
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:
return im[ymin:ymax+1, xmin:xmax+1, :], polys[selected_polys], tags[selected_polys]
else:
continue
im = im[ymin:ymax+1, xmin:xmax+1, :]
polys = polys[selected_polys]
tags = tags[selected_polys]
polys[:, :, 0] -= xmin
polys[:, :, 1] -= ymin
return im, polys, tags
return im, polys, tags
def shrink_poly(poly, r):
'''
fit a poly inside the origin poly, maybe bugs here...
used for generate the score map
:param poly: the text poly
:param r: r in the paper
:return: the shrinked poly
'''
# shrink ratio
R = 0.3
# find the longer pair
if np.linalg.norm(poly[0] - poly[1]) + np.linalg.norm(poly[2] - poly[3]) > \
np.linalg.norm(poly[0] - poly[3]) + np.linalg.norm(poly[1] - poly[2]):
# first move (p0, p1), (p2, p3), then (p0, p3), (p1, p2)
## p0, p1
theta = np.arctan2((poly[1][1] - poly[0][1]), (poly[1][0] - poly[0][0]))
poly[0][0] += R * r[0] * np.cos(theta)
poly[0][1] += R * r[0] * np.sin(theta)
poly[1][0] -= R * r[1] * np.cos(theta)
poly[1][1] -= R * r[1] * np.sin(theta)
## p2, p3
theta = np.arctan2((poly[2][1] - poly[3][1]), (poly[2][0] - poly[3][0]))
poly[3][0] += R * r[3] * np.cos(theta)
poly[3][1] += R * r[3] * np.sin(theta)
poly[2][0] -= R * r[2] * np.cos(theta)
poly[2][1] -= R * r[2] * np.sin(theta)
## p0, p3
theta = np.arctan2((poly[3][0] - poly[0][0]), (poly[3][1] - poly[0][1]))
poly[0][0] += R * r[0] * np.sin(theta)
poly[0][1] += R * r[0] * np.cos(theta)
poly[3][0] -= R * r[3] * np.sin(theta)
poly[3][1] -= R * r[3] * np.cos(theta)
## p1, p2
theta = np.arctan2((poly[2][0] - poly[1][0]), (poly[2][1] - poly[1][1]))
poly[1][0] += R * r[1] * np.sin(theta)
poly[1][1] += R * r[1] * np.cos(theta)
poly[2][0] -= R * r[2] * np.sin(theta)
poly[2][1] -= R * r[2] * np.cos(theta)
else:
## p0, p3
# print poly
theta = np.arctan2((poly[3][0] - poly[0][0]), (poly[3][1] - poly[0][1]))
poly[0][0] += R * r[0] * np.sin(theta)
poly[0][1] += R * r[0] * np.cos(theta)
poly[3][0] -= R * r[3] * np.sin(theta)
poly[3][1] -= R * r[3] * np.cos(theta)
## p1, p2
theta = np.arctan2((poly[2][0] - poly[1][0]), (poly[2][1] - poly[1][1]))
poly[1][0] += R * r[1] * np.sin(theta)
poly[1][1] += R * r[1] * np.cos(theta)
poly[2][0] -= R * r[2] * np.sin(theta)
poly[2][1] -= R * r[2] * np.cos(theta)
## p0, p1
theta = np.arctan2((poly[1][1] - poly[0][1]), (poly[1][0] - poly[0][0]))
poly[0][0] += R * r[0] * np.cos(theta)
poly[0][1] += R * r[0] * np.sin(theta)
poly[1][0] -= R * r[1] * np.cos(theta)
poly[1][1] -= R * r[1] * np.sin(theta)
## p2, p3
theta = np.arctan2((poly[2][1] - poly[3][1]), (poly[2][0] - poly[3][0]))
poly[3][0] += R * r[3] * np.cos(theta)
poly[3][1] += R * r[3] * np.sin(theta)
poly[2][0] -= R * r[2] * np.cos(theta)
poly[2][1] -= R * r[2] * np.sin(theta)
return poly
def point_dist_to_line(p1, p2, p3):
# compute the distance from p3 to p1-p2
return np.linalg.norm(np.cross(p2 - p1, p1 - p3)) / np.linalg.norm(p2 - p1)
def fit_line(p1, p2):
# fit a line ax+by+c = 0
if p1[0] == p1[1]:
return [1., 0., -p1[0]]
else:
[k, b] = np.polyfit(p1, p2, deg=1)
return [k, -1., b]
def line_cross_point(line1, line2):
# line1 0= ax+by+c, compute the cross point of line1 and line2
if line1[0] != 0 and line1[0] == line2[0]:
print('Cross point does not exist')
return None
if line1[0] == 0 and line2[0] == 0:
print('Cross point does not exist')
return None
if line1[1] == 0:
x = -line1[2]
y = line2[0] * x + line2[2]
elif line2[1] == 0:
x = -line2[2]
y = line1[0] * x + line1[2]
else:
k1, _, b1 = line1
k2, _, b2 = line2
x = -(b1-b2)/(k1-k2)
y = k1*x + b1
return np.array([x, y], dtype=np.float32)
def line_verticle(line, point):
# get the verticle line from line across point
if line[1] == 0:
verticle = [0, -1, point[1]]
else:
if line[0] == 0:
verticle = [1, 0, -point[0]]
else:
verticle = [-1./line[0], -1, point[1] - (-1/line[0] * point[0])]
return verticle
def rectangle_from_parallelogram(poly):
'''
fit a rectangle from a parallelogram
:param poly:
:return:
'''
p0, p1, p2, p3 = poly
angle_p0 = np.arccos(np.dot(p1-p0, p3-p0)/(np.linalg.norm(p0-p1) * np.linalg.norm(p3-p0)))
if angle_p0 < 0.5 * np.pi:
if np.linalg.norm(p0 - p1) > np.linalg.norm(p0-p3):
# p0 and p2
## p0
p2p3 = fit_line([p2[0], p3[0]], [p2[1], p3[1]])
p2p3_verticle = line_verticle(p2p3, p0)
new_p3 = line_cross_point(p2p3, p2p3_verticle)
## p2
p0p1 = fit_line([p0[0], p1[0]], [p0[1], p1[1]])
p0p1_verticle = line_verticle(p0p1, p2)
new_p1 = line_cross_point(p0p1, p0p1_verticle)
return np.array([p0, new_p1, p2, new_p3], dtype=np.float32)
else:
p1p2 = fit_line([p1[0], p2[0]], [p1[1], p2[1]])
p1p2_verticle = line_verticle(p1p2, p0)
new_p1 = line_cross_point(p1p2, p1p2_verticle)
p0p3 = fit_line([p0[0], p3[0]], [p0[1], p3[1]])
p0p3_verticle = line_verticle(p0p3, p2)
new_p3 = line_cross_point(p0p3, p0p3_verticle)
return np.array([p0, new_p1, p2, new_p3], dtype=np.float32)
else:
if np.linalg.norm(p0-p1) > np.linalg.norm(p0-p3):
# p1 and p3
## p1
p2p3 = fit_line([p2[0], p3[0]], [p2[1], p3[1]])
p2p3_verticle = line_verticle(p2p3, p1)
new_p2 = line_cross_point(p2p3, p2p3_verticle)
## p3
p0p1 = fit_line([p0[0], p1[0]], [p0[1], p1[1]])
p0p1_verticle = line_verticle(p0p1, p3)
new_p0 = line_cross_point(p0p1, p0p1_verticle)
return np.array([new_p0, p1, new_p2, p3], dtype=np.float32)
else:
p0p3 = fit_line([p0[0], p3[0]], [p0[1], p3[1]])
p0p3_verticle = line_verticle(p0p3, p1)
new_p0 = line_cross_point(p0p3, p0p3_verticle)
p1p2 = fit_line([p1[0], p2[0]], [p1[1], p2[1]])
p1p2_verticle = line_verticle(p1p2, p3)
new_p2 = line_cross_point(p1p2, p1p2_verticle)
return np.array([new_p0, p1, new_p2, p3], dtype=np.float32)
def sort_rectangle(poly):
# sort the four coordinates of the polygon, points in poly should be sorted clockwise
# First find the lowest point
p_lowest = np.argmax(poly[:, 1])
if np.count_nonzero(poly[:, 1] == poly[p_lowest, 1]) == 2:
# 底边平行于X轴, 那么p0为左上角
p0_index = np.argmin(np.sum(poly, axis=1))
p1_index = (p0_index + 1) % 4
p2_index = (p0_index + 2) % 4
p3_index = (p0_index + 3) % 4
return poly[[p0_index, p1_index, p2_index, p3_index]], 0.
else:
# 找到最低点右边的点
p_lowest_right = (p_lowest - 1) % 4
p_lowest_left = (p_lowest + 1) % 4
angle = np.arctan(-(poly[p_lowest][1] - poly[p_lowest_right][1])/(poly[p_lowest][0] - poly[p_lowest_right][0]))
# assert angle > 0
if angle <= 0:
print(angle, poly[p_lowest], poly[p_lowest_right])
if angle/np.pi * 180 > 45:
# 这个点为p2
p2_index = p_lowest
p1_index = (p2_index - 1) % 4
p0_index = (p2_index - 2) % 4
p3_index = (p2_index + 1) % 4
return poly[[p0_index, p1_index, p2_index, p3_index]], -(np.pi/2 - angle)
else:
# 这个点为p3
p3_index = p_lowest
p0_index = (p3_index + 1) % 4
p1_index = (p3_index + 2) % 4
p2_index = (p3_index + 3) % 4
return poly[[p0_index, p1_index, p2_index, p3_index]], angle
def restore_rectangle_rbox(origin, geometry):
d = geometry[:, :4]
angle = geometry[:, 4]
# for angle > 0
origin_0 = origin[angle >= 0]
d_0 = d[angle >= 0]
angle_0 = angle[angle >= 0]
if origin_0.shape[0] > 0:
p = np.array([np.zeros(d_0.shape[0]), -d_0[:, 0] - d_0[:, 2],
d_0[:, 1] + d_0[:, 3], -d_0[:, 0] - d_0[:, 2],
d_0[:, 1] + d_0[:, 3], np.zeros(d_0.shape[0]),
np.zeros(d_0.shape[0]), np.zeros(d_0.shape[0]),
d_0[:, 3], -d_0[:, 2]])
p = p.transpose((1, 0)).reshape((-1, 5, 2)) # N*5*2
rotate_matrix_x = np.array([np.cos(angle_0), np.sin(angle_0)]).transpose((1, 0))
rotate_matrix_x = np.repeat(rotate_matrix_x, 5, axis=1).reshape(-1, 2, 5).transpose((0, 2, 1)) # N*5*2
rotate_matrix_y = np.array([-np.sin(angle_0), np.cos(angle_0)]).transpose((1, 0))
rotate_matrix_y = np.repeat(rotate_matrix_y, 5, axis=1).reshape(-1, 2, 5).transpose((0, 2, 1))
p_rotate_x = np.sum(rotate_matrix_x * p, axis=2)[:, :, np.newaxis] # N*5*1
p_rotate_y = np.sum(rotate_matrix_y * p, axis=2)[:, :, np.newaxis] # N*5*1
p_rotate = np.concatenate([p_rotate_x, p_rotate_y], axis=2) # N*5*2
p3_in_origin = origin_0 - p_rotate[:, 4, :]
new_p0 = p_rotate[:, 0, :] + p3_in_origin # N*2
new_p1 = p_rotate[:, 1, :] + p3_in_origin
new_p2 = p_rotate[:, 2, :] + p3_in_origin
new_p3 = p_rotate[:, 3, :] + p3_in_origin
new_p_0 = np.concatenate([new_p0[:, np.newaxis, :], new_p1[:, np.newaxis, :],
new_p2[:, np.newaxis, :], new_p3[:, np.newaxis, :]], axis=1) # N*4*2
else:
new_p_0 = np.zeros((0, 4, 2))
# for angle < 0
origin_1 = origin[angle < 0]
d_1 = d[angle < 0]
angle_1 = angle[angle < 0]
if origin_1.shape[0] > 0:
p = np.array([-d_1[:, 1] - d_1[:, 3], -d_1[:, 0] - d_1[:, 2],
np.zeros(d_1.shape[0]), -d_1[:, 0] - d_1[:, 2],
np.zeros(d_1.shape[0]), np.zeros(d_1.shape[0]),
-d_1[:, 1] - d_1[:, 3], np.zeros(d_1.shape[0]),
-d_1[:, 1], -d_1[:, 2]])
p = p.transpose((1, 0)).reshape((-1, 5, 2)) # N*5*2
rotate_matrix_x = np.array([np.cos(-angle_1), -np.sin(-angle_1)]).transpose((1, 0))
rotate_matrix_x = np.repeat(rotate_matrix_x, 5, axis=1).reshape(-1, 2, 5).transpose((0, 2, 1)) # N*5*2
rotate_matrix_y = np.array([np.sin(-angle_1), np.cos(-angle_1)]).transpose((1, 0))
rotate_matrix_y = np.repeat(rotate_matrix_y, 5, axis=1).reshape(-1, 2, 5).transpose((0, 2, 1))
p_rotate_x = np.sum(rotate_matrix_x * p, axis=2)[:, :, np.newaxis] # N*5*1
p_rotate_y = np.sum(rotate_matrix_y * p, axis=2)[:, :, np.newaxis] # N*5*1
p_rotate = np.concatenate([p_rotate_x, p_rotate_y], axis=2) # N*5*2
p3_in_origin = origin_1 - p_rotate[:, 4, :]
new_p0 = p_rotate[:, 0, :] + p3_in_origin # N*2
new_p1 = p_rotate[:, 1, :] + p3_in_origin
new_p2 = p_rotate[:, 2, :] + p3_in_origin
new_p3 = p_rotate[:, 3, :] + p3_in_origin
new_p_1 = np.concatenate([new_p0[:, np.newaxis, :], new_p1[:, np.newaxis, :],
new_p2[:, np.newaxis, :], new_p3[:, np.newaxis, :]], axis=1) # N*4*2
else:
new_p_1 = np.zeros((0, 4, 2))
return np.concatenate([new_p_0, new_p_1])
def restore_rectangle(origin, geometry):
return restore_rectangle_rbox(origin, geometry)
def generate_rbox(im_size, polys, tags):
h, w = im_size
poly_mask = np.zeros((h, w), dtype=np.uint8)
score_map = np.zeros((h, w), dtype=np.uint8)
geo_map = np.zeros((h, w, 5), dtype=np.float32)
# mask used during traning, to ignore some hard areas
training_mask = np.ones((h, w), dtype=np.uint8)
for poly_idx, poly_tag in enumerate(zip(polys, tags)):
poly = poly_tag[0]
tag = poly_tag[1]
r = [None, None, None, None]
for i in range(4):
r[i] = min(np.linalg.norm(poly[i] - poly[(i + 1) % 4]),
np.linalg.norm(poly[i] - poly[(i - 1) % 4]))
# score map
shrinked_poly = shrink_poly(poly.copy(), r).astype(np.int32)[np.newaxis, :, :]
cv2.fillPoly(score_map, shrinked_poly, 1)
cv2.fillPoly(poly_mask, shrinked_poly, poly_idx + 1)
# if the poly is too small, then ignore it during training
poly_h = min(np.linalg.norm(poly[0] - poly[3]), np.linalg.norm(poly[1] - poly[2]))
poly_w = min(np.linalg.norm(poly[0] - poly[1]), np.linalg.norm(poly[2] - poly[3]))
# if min(poly_h, poly_w) < FLAGS.min_text_size:
if min(poly_h, poly_w) < 10:
cv2.fillPoly(training_mask, poly.astype(np.int32)[np.newaxis, :, :], 0)
if tag:
cv2.fillPoly(training_mask, poly.astype(np.int32)[np.newaxis, :, :], 0)
xy_in_poly = np.argwhere(poly_mask == (poly_idx + 1))
# if geometry == 'RBOX':
# 对任意两个顶点的组合生成一个平行四边形
fitted_parallelograms = []
for i in range(4):
p0 = poly[i]
p1 = poly[(i + 1) % 4]
p2 = poly[(i + 2) % 4]
p3 = poly[(i + 3) % 4]
edge = fit_line([p0[0], p1[0]], [p0[1], p1[1]])
backward_edge = fit_line([p0[0], p3[0]], [p0[1], p3[1]])
forward_edge = fit_line([p1[0], p2[0]], [p1[1], p2[1]])
if point_dist_to_line(p0, p1, p2) > point_dist_to_line(p0, p1, p3):
# 平行线经过p2
if edge[1] == 0:
edge_opposite = [1, 0, -p2[0]]
else:
edge_opposite = [edge[0], -1, p2[1] - edge[0] * p2[0]]
else:
# 经过p3
if edge[1] == 0:
edge_opposite = [1, 0, -p3[0]]
else:
edge_opposite = [edge[0], -1, p3[1] - edge[0] * p3[0]]
# move forward edge
new_p0 = p0
new_p1 = p1
new_p2 = p2
new_p3 = p3
new_p2 = line_cross_point(forward_edge, edge_opposite)
if point_dist_to_line(p1, new_p2, p0) > point_dist_to_line(p1, new_p2, p3):
# across p0
if forward_edge[1] == 0:
forward_opposite = [1, 0, -p0[0]]
else:
forward_opposite = [forward_edge[0], -1, p0[1] - forward_edge[0] * p0[0]]
else:
# across p3
if forward_edge[1] == 0:
forward_opposite = [1, 0, -p3[0]]
else:
forward_opposite = [forward_edge[0], -1, p3[1] - forward_edge[0] * p3[0]]
new_p0 = line_cross_point(forward_opposite, edge)
new_p3 = line_cross_point(forward_opposite, edge_opposite)
fitted_parallelograms.append([new_p0, new_p1, new_p2, new_p3, new_p0])
# or move backward edge
new_p0 = p0
new_p1 = p1
new_p2 = p2
new_p3 = p3
new_p3 = line_cross_point(backward_edge, edge_opposite)
if point_dist_to_line(p0, p3, p1) > point_dist_to_line(p0, p3, p2):
# across p1
if backward_edge[1] == 0:
backward_opposite = [1, 0, -p1[0]]
else:
backward_opposite = [backward_edge[0], -1, p1[1] - backward_edge[0] * p1[0]]
else:
# across p2
if backward_edge[1] == 0:
backward_opposite = [1, 0, -p2[0]]
else:
backward_opposite = [backward_edge[0], -1, p2[1] - backward_edge[0] * p2[0]]
new_p1 = line_cross_point(backward_opposite, edge)
new_p2 = line_cross_point(backward_opposite, edge_opposite)
fitted_parallelograms.append([new_p0, new_p1, new_p2, new_p3, new_p0])
areas = [Polygon(t).area for t in fitted_parallelograms]
parallelogram = np.array(fitted_parallelograms[np.argmin(areas)][:-1], dtype=np.float32)
# sort thie polygon
parallelogram_coord_sum = np.sum(parallelogram, axis=1)
min_coord_idx = np.argmin(parallelogram_coord_sum)
parallelogram = parallelogram[
[min_coord_idx, (min_coord_idx + 1) % 4, (min_coord_idx + 2) % 4, (min_coord_idx + 3) % 4]]
rectange = rectangle_from_parallelogram(parallelogram)
rectange, rotate_angle = sort_rectangle(rectange)
p0_rect, p1_rect, p2_rect, p3_rect = rectange
for y, x in xy_in_poly:
point = np.array([x, y], dtype=np.float32)
# top
geo_map[y, x, 0] = point_dist_to_line(p0_rect, p1_rect, point)
# right
geo_map[y, x, 1] = point_dist_to_line(p1_rect, p2_rect, point)
# down
geo_map[y, x, 2] = point_dist_to_line(p2_rect, p3_rect, point)
# left
geo_map[y, x, 3] = point_dist_to_line(p3_rect, p0_rect, point)
# angle
geo_map[y, x, 4] = rotate_angle
return score_map, geo_map, training_mask
def image_label(txt_root, image_list, img_name, index,
input_size = 512, random_scale = np.array([0.5, 1, 2.0, 3.0]),
background_ratio = 3./8):
'''
get image's corresponding matrix and ground truth
'''
try:
im_fn = image_list[index]
im_name = img_name[index]
im = cv2.imread(im_fn)
# print im_fn
h, w, _ = im.shape
# txt_fn = 'gt_' + im_name.replace(im_name.split('.')[1], 'txt')
txt_fn = im_name.replace(im_name.split('.')[1], 'txt')
txt_fn = os.path.join(txt_root, txt_fn)
# if not os.path.exists(txt_fn):
# pass
text_polys, text_tags = load_annoataion(txt_fn)
text_polys, text_tags = check_and_validate_polys(text_polys, text_tags, (h, w))
# if text_polys.shape[0] == 0:
# continue
# random scale this image
rd_scale = np.random.choice(random_scale)
im = cv2.resize(im, dsize=None, fx=rd_scale, fy=rd_scale)
text_polys *= rd_scale
# print rd_scale
# random crop a area from image
if np.random.rand() < background_ratio:
# crop background
im, text_polys, text_tags = crop_area(im, text_polys, text_tags, crop_background=True)
# if text_polys.shape[0] > 0:
# # cannot find background
# pass
# pad and resize image
new_h, new_w, _ = im.shape
max_h_w_i = np.max([new_h, new_w, input_size])
im_padded = np.zeros((max_h_w_i, max_h_w_i, 3), dtype=np.uint8)
im_padded[:new_h, :new_w, :] = im.copy()
im = cv2.resize(im_padded, dsize=(input_size, input_size))
score_map = np.zeros((input_size, input_size), dtype=np.uint8)
geo_map_channels = 5
# geo_map_channels = 5 if FLAGS.geometry == 'RBOX' else 8
geo_map = np.zeros((input_size, input_size, geo_map_channels), dtype=np.float32)
training_mask = np.ones((input_size, input_size), dtype=np.uint8)
else:
im, text_polys, text_tags = crop_area(im, text_polys, text_tags, crop_background=False)
# if text_polys.shape[0] == 0:
# pass
h, w, _ = im.shape
# pad the image to the training input size or the longer side of image
new_h, new_w, _ = im.shape
max_h_w_i = np.max([new_h, new_w, input_size])
im_padded = np.zeros((max_h_w_i, max_h_w_i, 3), dtype=np.uint8)
im_padded[:new_h, :new_w, :] = im.copy()
im = im_padded
# resize the image to input size
new_h, new_w, _ = im.shape
resize_h = input_size
resize_w = input_size
im = cv2.resize(im, dsize=(resize_w, resize_h))
resize_ratio_3_x = resize_w/float(new_w)
resize_ratio_3_y = resize_h/float(new_h)
text_polys[:, :, 0] *= resize_ratio_3_x
text_polys[:, :, 1] *= resize_ratio_3_y
new_h, new_w, _ = im.shape
score_map, geo_map, training_mask = generate_rbox((new_h, new_w), text_polys, text_tags)
images = im[:, :, ::-1].astype(np.float32)
score_maps = score_map[::4, ::4, np.newaxis].astype(np.float32)
geo_maps = geo_map[::4, ::4, :].astype(np.float32)
training_masks = training_mask[::4, ::4, np.newaxis].astype(np.float32)
except Exception as e:
images, score_maps, geo_maps, training_masks = None, None, None, None
return images, score_maps, geo_maps, training_masks
class custom_dset(data.Dataset):
def __init__(self, img_root, txt_root):
self.image_list, self.img_name = get_images(img_root)
self.txt_root = txt_root
def __getitem__(self, index):
img, score_map, geo_map, training_mask = image_label(self.txt_root,
self.image_list, self.img_name, index, input_size = 512,
random_scale = np.array([0.5, 1, 2.0, 3.0]), background_ratio = 3./8)
return img, score_map, geo_map, training_mask
def __len__(self):
return len(self.image_list)
def collate_fn(batch):
img, score_map, geo_map, training_mask = zip(*batch)
bs = len(score_map)
images = []
score_maps = []
geo_maps = []
training_masks = []
for i in range(bs):
if img[i] is not None:
a = torch.from_numpy(img[i])
a = a.permute(2, 0, 1)
images.append(a)
b = torch.from_numpy(score_map[i])
b = b.permute(2, 0, 1)
score_maps.append(b)
c = torch.from_numpy(geo_map[i])
c = c.permute(2, 0, 1)
geo_maps.append(c)
d = torch.from_numpy(training_mask[i])
d = d.permute(2, 0, 1)
training_masks.append(d)
images = torch.stack(images, 0)
score_maps = torch.stack(score_maps, 0)
geo_maps = torch.stack(geo_maps, 0)
training_masks = torch.stack(training_masks, 0)
return images, score_maps, geo_maps, training_masks
## img = bs * 512 * 512 *3
## score_map = bs* 128 * 128 * 1
## geo_map = bs * 128 * 128 * 5
## training_mask = bs * 128 * 128 * 1