def add_arc_noise(image,
n,
fill=None,
max_width=5,
min_length=4,
max_length=60):
w, h = image.size
noise = PIL.Image.new('RGBA', (w, h), color=(0, 0, 0, 0))
draw = ImageDraw.Draw(noise)
for i in range(n):
origin_point = random_point_on_image((w, h))
endpoint = vector_add(random_vector__pixels(min_length, max_length),
origin_point)
bbox = (origin_point, endpoint)
if fill == None:
draw.arc(bbox,
start=randang(),
end=randang(),
fill=(randcol(), randcol(), randcol(), randcol()))
else:
draw.arc(bbox, start=randang(), end=randang(), fill=fill)
image = PIL.Image.alpha_composite(image, noise)
return image
def string_2_word_sample(string,
max_rotation_angle=5,
margin__left_x=np.random.randint(-4, 30),
margin__upper_y=np.random.randint(-4, 30),
margin__right_x=np.random.randint(-4, 30),
margin__lower_y=np.random.randint(-4, 30),
open_close__factor=random.randint(-3, 1),
dilate_erode__factor=random.randint(-1, 1),
white_bg=False):
fnt = random_font()
max_char_w, max_char_h = fnt['max_char_size']
font = fnt['font']
img_w, img_h = 0, max_char_h # we start with full height and zero width, the width is incremented letter by letter
# Aquiring position data (letter center points and initial bounding boxes) for the string at hand
letter_data = []
for letter in string:
data_dict = {}
random_offset = np.random.randint(-6, 10)
img_w += random_offset
letter_w, letter_h = font.getsize(letter)
letter_bbox = (
(img_w, 0), (img_w + letter_w, letter_h)
) # this should include some randomization in the future
letter_center = (img_w + letter_w / 2, img_h / 2)
data_dict['char'] = letter
data_dict['bounding_box'] = letter_bbox
data_dict['center_point'] = letter_center
letter_data.append(data_dict)
img_w += letter_w
# Creating a canvas to write the letters to
img = Image.new(
mode='RGBA',
size=(img_w, img_h),
color=(0, 0, 0, 0) # transparent bg
)
img_draw = ImageDraw.Draw(img)
# writing the characters to canvas
for char_data in letter_data:
img_draw.text(
char_data['bounding_box'][0],
char_data['char'],
font=font,
fill=(0, 0, 0, 255) # black
)
rotation_angle = np.random.random() * max_rotation_angle * [
-1, 1
][np.random.randint(2)]
og_image_centerpoint = (img_w / 2, img_h / 2)
# rotate the image
img = img.rotate(
angle=rotation_angle,
center=og_image_centerpoint,
expand=True,
resample=PIL.Image.
BICUBIC # I looked at nearest, bilinear and bicubic and bicubic looks accurate and sharp, i like it best
)
img_w__new, img_h__new = img.size
new_centerpoint = (img_w__new / 2, img_h__new / 2) # after rotation
centerpoints_delta_vector = vector_subtract(new_centerpoint,
og_image_centerpoint)
# rotating the character centerpoints (positions)
rotated_centerpoints = map(
lambda char_data: rotate_point(char_data['center_point'],
og_image_centerpoint, rotation_angle),
letter_data)
# aligning the character centerpoints (positions) to the rotated and expanded image
rotated_centerpoints = map(
lambda point: vector_add(point, centerpoints_delta_vector),
rotated_centerpoints)
# offsettng the character centerpoints (positions) randomly to break uniformity
rotated_centerpoints = map(
lambda point: vector_add(point, random_vector__pixels(0, 2)),
rotated_centerpoints)
# create new bounding boxes from the new letter centers
bounding_boxes = list(
map(
lambda p: point_2_squareBoundingBox(
p, (max_char_h / 2) + np.random.randint(-2, 2)
), # square radius is half the max char height plus some random padding (postive or negative)
rotated_centerpoints))
# Morphology adjustment (open, close, dilate and erode)
img = morphology_ops(img,
open_close__factor=open_close__factor,
dilate_erode__factor=dilate_erode__factor)
# Margins Adjustment
img, bounding_boxes = adjust_bitmap_n_bounding_box_margins(img,
bounding_boxes,
margin__left_x,
margin__upper_y,
margin__right_x,
margin__lower_y,
fill=(0, 0, 0,
0))
img = add_line_noise(img,
np.random.randint(20, 60),
max_width=3,
min_length=2,
max_length=60)
img = add_line_noise(img,
np.random.randint(2, 20),
max_width=6,
min_length=2,
max_length=500,
fill=(0, 0, 0, randcol()))
# img = add_arc_noise(img, np.random.randint(60, 120), max_width=3, min_length=2, max_length=60)
# img = add_arc_noise(img, np.random.randint(2, 60), max_width=6, min_length=2, max_length=500, fill=(0, 0, 0, randcol()))
if white_bg:
img = add_background(img, fill=(255, 255, 255, 255))
else:
bg_noise = noisey_background(bitmap_size=img.size,
steps=12,
noise_saturation=random.uniform(
0.05, 0.93),
noise_brightness=random.uniform(0.7, 1.8),
noise_contrast=random.uniform(0.01, 0.6))
grain = noiseyRGBBitmap(bitmap_size=img.size,
noise_saturation=random.uniform(0.05, 0.93),
noise_brightness=random.uniform(0.7, 1.8),
noise_contrast=random.uniform(0.01, 0.6),
alpha_value=255,
noise_size=1)
img = PIL.Image.alpha_composite(bg_noise, img)
img = PIL.Image.blend(img, grain, np.random.uniform(0.1, 0.8))
image = img.convert('RGB') # remove the alpha channel
# Blur
image = image.filter(ImageFilter.GaussianBlur(radius=np.random.randint(3)))
# Contrast
contrast = ImageEnhance.Contrast(image)
image = contrast.enhance(random.uniform(0.2, 1))
# Brightness
brightness = ImageEnhance.Brightness(image)
image = brightness.enhance(random.uniform(0.2, 1))
# Saturation
saturation = ImageEnhance.Color(image)
image = saturation.enhance(random.uniform(0, 1))
angle = rotation_angle
return image, bounding_boxes, angle