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gen.py
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#!/usr/bin/env python
#
# Copyright (c) 2016 Matthew Earl
#
# Permission is hereby granted, free of charge, to any person obtaining a copy
# of this software and associated documentation files (the "Software"), to deal
# in the Software without restriction, including without limitation the rights
# to use, copy, modify, merge, publish, distribute, sublicense, and/or sell
# copies of the Software, and to permit persons to whom the Software is
# furnished to do so, subject to the following conditions:
#
# The above copyright notice and this permission notice shall be included
# in all copies or substantial portions of the Software.
#
# THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS
# OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF
# MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN
# NO EVENT SHALL THE AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM,
# DAMAGES OR OTHER LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR
# OTHERWISE, ARISING FROM, OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE
# USE OR OTHER DEALINGS IN THE SOFTWARE.
"""
Generate training and test images.
"""
__all__ = (
'generate_ims',
)
import itertools
import math
import os
import random
import sys
import cv2
import numpy
from PIL import Image
from PIL import ImageDraw
from PIL import ImageFont
import common
FONT_DIR = "./fonts"
FONT_HEIGHT = 32 # Pixel size to which the chars are resized
OUTPUT_SHAPE = (64, 128)
CHARS = common.CHARS + " "
def make_char_ims(font_path, output_height):
font_size = output_height * 4
font = ImageFont.truetype(font_path, font_size)
height = max(font.getsize(c)[1] for c in CHARS)
for c in CHARS:
width = font.getsize(c)[0]
im = Image.new("RGBA", (width, height), (0, 0, 0))
draw = ImageDraw.Draw(im)
draw.text((0, 0), c, (255, 255, 255), font=font)
scale = float(output_height) / height
im = im.resize((int(width * scale), output_height), Image.ANTIALIAS)
yield c, numpy.array(im)[:, :, 0].astype(numpy.float32) / 255.
def euler_to_mat(yaw, pitch, roll):
# Rotate clockwise about the Y-axis
c, s = math.cos(yaw), math.sin(yaw)
M = numpy.matrix([[ c, 0., s],
[ 0., 1., 0.],
[ -s, 0., c]])
# Rotate clockwise about the X-axis
c, s = math.cos(pitch), math.sin(pitch)
M = numpy.matrix([[ 1., 0., 0.],
[ 0., c, -s],
[ 0., s, c]]) * M
# Rotate clockwise about the Z-axis
c, s = math.cos(roll), math.sin(roll)
M = numpy.matrix([[ c, -s, 0.],
[ s, c, 0.],
[ 0., 0., 1.]]) * M
return M
def pick_colors():
first = True
while first or plate_color - text_color < 0.3:
text_color = random.random()
plate_color = random.random()
if text_color > plate_color:
text_color, plate_color = plate_color, text_color
first = False
return text_color, plate_color
def make_affine_transform(from_shape, to_shape,
min_scale, max_scale,
scale_variation=1.0,
rotation_variation=1.0,
translation_variation=1.0):
out_of_bounds = False
from_size = numpy.array([[from_shape[1], from_shape[0]]]).T
to_size = numpy.array([[to_shape[1], to_shape[0]]]).T
scale = random.uniform((min_scale + max_scale) * 0.5 -
(max_scale - min_scale) * 0.5 * scale_variation,
(min_scale + max_scale) * 0.5 +
(max_scale - min_scale) * 0.5 * scale_variation)
if scale > max_scale or scale < min_scale:
out_of_bounds = True
roll = random.uniform(-0.3, 0.3) * rotation_variation
pitch = random.uniform(-0.2, 0.2) * rotation_variation
yaw = random.uniform(-1.2, 1.2) * rotation_variation
# Compute a bounding box on the skewed input image (`from_shape`).
M = euler_to_mat(yaw, pitch, roll)[:2, :2]
h, w = from_shape
corners = numpy.matrix([[-w, +w, -w, +w],
[-h, -h, +h, +h]]) * 0.5
skewed_size = numpy.array(numpy.max(M * corners, axis=1) -
numpy.min(M * corners, axis=1))
# Set the scale as large as possible such that the skewed and scaled shape
# is less than or equal to the desired ratio in either dimension.
scale *= numpy.min(to_size / skewed_size)
# Set the translation such that the skewed and scaled image falls within
# the output shape's bounds.
trans = (numpy.random.random((2,1)) - 0.5) * translation_variation
trans = ((2.0 * trans) ** 5.0) / 2.0
if numpy.any(trans < -0.5) or numpy.any(trans > 0.5):
out_of_bounds = True
trans = (to_size - skewed_size * scale) * trans
center_to = to_size / 2.
center_from = from_size / 2.
M = euler_to_mat(yaw, pitch, roll)[:2, :2]
M *= scale
M = numpy.hstack([M, trans + center_to - M * center_from])
return M, out_of_bounds
def generate_code():
return "{}{}{}{} {}{}{}".format(
random.choice(common.LETTERS),
random.choice(common.LETTERS),
random.choice(common.DIGITS),
random.choice(common.DIGITS),
random.choice(common.LETTERS),
random.choice(common.LETTERS),
random.choice(common.LETTERS))
def rounded_rect(shape, radius):
out = numpy.ones(shape)
out[:radius, :radius] = 0.0
out[-radius:, :radius] = 0.0
out[:radius, -radius:] = 0.0
out[-radius:, -radius:] = 0.0
cv2.circle(out, (radius, radius), radius, 1.0, -1)
cv2.circle(out, (radius, shape[0] - radius), radius, 1.0, -1)
cv2.circle(out, (shape[1] - radius, radius), radius, 1.0, -1)
cv2.circle(out, (shape[1] - radius, shape[0] - radius), radius, 1.0, -1)
return out
def generate_plate(font_height, char_ims):
h_padding = random.uniform(0.2, 0.4) * font_height
v_padding = random.uniform(0.1, 0.3) * font_height
spacing = font_height * random.uniform(-0.05, 0.05)
radius = 1 + int(font_height * 0.1 * random.random())
code = generate_code()
text_width = sum(char_ims[c].shape[1] for c in code)
text_width += (len(code) - 1) * spacing
out_shape = (int(font_height + v_padding * 2),
int(text_width + h_padding * 2))
text_color, plate_color = pick_colors()
text_mask = numpy.zeros(out_shape)
x = h_padding
y = v_padding
for c in code:
char_im = char_ims[c]
ix, iy = int(x), int(y)
text_mask[iy:iy + char_im.shape[0], ix:ix + char_im.shape[1]] = char_im
x += char_im.shape[1] + spacing
plate = (numpy.ones(out_shape) * plate_color * (1. - text_mask) +
numpy.ones(out_shape) * text_color * text_mask)
return plate, rounded_rect(out_shape, radius), code.replace(" ", "")
def generate_bg(num_bg_images):
found = False
while not found:
fname = "bgs/{:08d}.jpg".format(random.randint(0, num_bg_images - 1))
bg = cv2.imread(fname, cv2.CV_LOAD_IMAGE_GRAYSCALE) / 255.
if (bg.shape[1] >= OUTPUT_SHAPE[1] and
bg.shape[0] >= OUTPUT_SHAPE[0]):
found = True
x = random.randint(0, bg.shape[1] - OUTPUT_SHAPE[1])
y = random.randint(0, bg.shape[0] - OUTPUT_SHAPE[0])
bg = bg[y:y + OUTPUT_SHAPE[0], x:x + OUTPUT_SHAPE[1]]
return bg
def generate_im(char_ims, num_bg_images):
bg = generate_bg(num_bg_images)
plate, plate_mask, code = generate_plate(FONT_HEIGHT, char_ims)
M, out_of_bounds = make_affine_transform(
from_shape=plate.shape,
to_shape=bg.shape,
min_scale=0.6,
max_scale=0.875,
rotation_variation=1.0,
scale_variation=1.5,
translation_variation=1.2)
plate = cv2.warpAffine(plate, M, (bg.shape[1], bg.shape[0]))
plate_mask = cv2.warpAffine(plate_mask, M, (bg.shape[1], bg.shape[0]))
out = plate * plate_mask + bg * (1.0 - plate_mask)
out = cv2.resize(out, (OUTPUT_SHAPE[1], OUTPUT_SHAPE[0]))
out += numpy.random.normal(scale=0.05, size=out.shape)
out = numpy.clip(out, 0., 1.)
return out, code, not out_of_bounds
def load_fonts(folder_path):
font_char_ims = {}
fonts = [f for f in os.listdir(folder_path) if f.endswith('.ttf')]
for font in fonts:
font_char_ims[font] = dict(make_char_ims(os.path.join(folder_path,
font),
FONT_HEIGHT))
return fonts, font_char_ims
def generate_ims():
"""
Generate number plate images.
:return:
Iterable of number plate images.
"""
variation = 1.0
fonts, font_char_ims = load_fonts(FONT_DIR)
num_bg_images = len(os.listdir("bgs"))
while True:
yield generate_im(font_char_ims[random.choice(fonts)], num_bg_images)
if __name__ == "__main__":
os.mkdir("test")
im_gen = itertools.islice(generate_ims(), int(sys.argv[1]))
for img_idx, (im, c, p) in enumerate(im_gen):
fname = "test/{:08d}_{}_{}.png".format(img_idx, c,
"1" if p else "0")
print fname
cv2.imwrite(fname, im * 255.)