openmedialibrary_platform/Shared/lib/python3.7/site-packages/ox/image.py

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#!/usr/bin/python
# -*- coding: utf-8 -*-
# vi:si:et:sw=4:sts=4:ts=4
from __future__ import division
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try:
from PIL import Image
from PIL import ImageDraw
from PIL import ImageFont
except:
import Image
import ImageDraw
import ImageFont
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ZONE_INDEX = [
(int(x / 2) + int(y / 4) * 4)
for x, y in [
(pixel_index % 8, int(pixel_index / 8))
for pixel_index in range(64)
]
]
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def drawText(image, position, text, font_file, font_size, color):
draw = ImageDraw.Draw(image)
font = ImageFont.truetype(font_file, font_size, encoding='unic')
draw.text(position, text, fill=color, font=font)
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size = draw.textsize(text, font=font)
version = getattr(Image, 'PILLOW_VERSION', None)
if version and version > '2.1.0' and version < '2.6.1':
offset = font.getoffset(text)
else:
offset = (0, 0)
return (size[0] + offset[0], size[1] + offset[1])
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def getHSL(rgb):
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rgb = [x / 255 for x in rgb]
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maximum = max(rgb)
minimum = min(rgb)
hsl = [0.0, 0.0, 0.0]
hsl[2] = (maximum + minimum) / 2
if maximum == minimum:
hsl[0] = 0.0
hsl[1] = 0.0
else:
if maximum == rgb[0]:
hsl[0] = (60 * (rgb[1] - rgb[2]) / (maximum - minimum) + 360) % 360
elif maximum == rgb[1]:
hsl[0] = 60 * (rgb[2] - rgb[0]) / (maximum - minimum) + 120
else:
hsl[0] = 60 * (rgb[0] - rgb[1]) / (maximum - minimum) + 240
if hsl[2] <= 0.5:
hsl[1] = (maximum - minimum) / (2 * hsl[2])
else:
hsl[1] = (maximum - minimum) / (2 - 2 * hsl[2])
return tuple(hsl)
def getImageHash(image_file, mode):
image = Image.open(image_file).convert('RGB').resize((8, 8), Image.ANTIALIAS)
image_hash = 0
if mode == 'color':
# divide the image into 8 zones:
# 0 0 1 1 2 2 3 3
# 0 0 1 1 2 2 3 3
# 0 0 1 1 2 2 3 3
# 0 0 1 1 2 2 3 3
# 4 4 5 5 6 6 7 7
# 4 4 5 5 6 6 7 7
# 4 4 5 5 6 6 7 7
# 4 4 5 5 6 6 7 7
image_data = image.getdata()
zone_values = [[] for i in range(8)]
for pixel_index, pixel_value in enumerate(image_data):
zone_values[ZONE_INDEX[pixel_index]].append(pixel_value)
for zone_index, pixel_values in enumerate(zone_values):
# get the mean for each color channel
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mean = [int(round(sum(x) / 8)) for x in zip(*pixel_values)]
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# store the mean color of each zone as an 8-bit value:
# RRRGGGBB
color_index = sum((
int(mean[0] / 32) << 5,
int(mean[1] / 32) << 2,
int(mean[2] / 64)
))
image_hash += color_index * pow(2, zone_index * 8)
elif mode == 'shape':
# pixels brighter than the mean register as 1,
# pixels equal to or darker than the mean as 0
image_data = image.convert('L').getdata()
image_mean = sum(image_data) / 64
for pixel_index, pixel_value in enumerate(image_data):
if pixel_value > image_mean:
image_hash += pow(2, pixel_index)
image_hash = hex(image_hash)[2:].upper()
if image_hash.endswith('L'):
image_hash = image_hash[:-1]
image_hash = '0' * (16 - len(image_hash)) + image_hash
return image_hash
def getImageHeat(image_file):
image = Image.open(image_file).convert('RGB').resize((16, 16), Image.ANTIALIAS)
pixel = image.load()
image_heat = 0
for y in range(image.size[1]):
for x in range(image.size[0]):
pixel_heat = []
for y_ in range(max(y - 1, 0), min(y + 2, image.size[1])):
for x_ in range(max(x - 1, 0), min(x + 2, image.size[0])):
if x != x_ or y != y_:
for c in range(3):
pixel_heat.append(abs(pixel[x, y][c] - pixel[x_, y_][c]))
image_heat += sum(pixel_heat) / len(pixel_heat)
return image_heat / 256
def getImageHSL(image_file):
image = Image.open(image_file).convert('RGB').resize((1, 1), Image.ANTIALIAS)
return getHSL(image.getpixel((0, 0)))
def getRGB(hsl):
hsl = list(hsl)
hsl[0] /= 360
rgb = [0, 0, 0]
if hsl[1] == 0:
rgb = [hsl[2], hsl[2], hsl[2]]
else:
if hsl[2] < 1/2:
v2 = hsl[2] * (1 + hsl[1])
else:
v2 = hsl[1] + hsl[2] - (hsl[1] * hsl[2])
v1 = 2 * hsl[2] - v2
for i in range(3):
v3 = hsl[0] + (1 - i) * 1/3;
if v3 < 0:
v3 += 1
elif v3 > 1:
v3 -= 1
if v3 < 1/6:
rgb[i] = v1 + ((v2 - v1) * 6 * v3)
elif v3 < 1/2:
rgb[i] = v2
elif v3 < 2/3:
rgb[i] = v1 + ((v2 - v1) * 6 * (2/3 - v3))
else:
rgb[i] = v1
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return tuple([int(x * 255) for x in rgb])
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def getTextSize(image, text, font_file, font_size):
draw = ImageDraw.Draw(image)
font = ImageFont.truetype(font_file, font_size, encoding='unic')
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size = draw.textsize(text, font=font)
version = getattr(Image, 'PILLOW_VERSION', None)
if version and version > '2.1.0' and version < '2.6.1':
offset = font.getoffset(text)
else:
offset = (0, 0)
return (size[0] + offset[0], size[1] + offset[1])
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def wrapText(text, max_width, max_lines, font_file, font_size):
# wraps text to max_width and max_lines
def get_min_width():
# returns the width of the longest non-hyphenated word
min_width = 0
for word in words:
width = get_width(word)
if width <= max_width and width > min_width:
min_width = width
return min_width
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def get_width(string):
return draw.textsize(string, font=font)[0]
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image = Image.new('RGB', (1, 1))
draw = ImageDraw.Draw(image)
font = ImageFont.truetype(font_file, font_size, encoding='unic')
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ellipsis = u'…'
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separators = ['-', '+', '/', ':']
if get_width(text) <= max_width:
# text fits in one line
lines = [text]
else:
lines = ['']
words = []
spaces = []
test_words = text.split(' ')
for word in test_words:
if get_width(word) <= max_width:
# word fits in one line
words.append(word)
spaces.append(' ')
else:
# word does not fit in one line
position = 0
test_word = word
for separator in separators:
test_word = test_word.replace(separator, ' ')
parts = test_word.split(' ')
for i, part in enumerate(parts):
words.append(part)
if i < len(parts) - 1:
position += len(part) + 1
spaces.append(word[position - 1])
else:
spaces.append(' ')
if max_lines:
# test if the same number of lines can be achieved with shorter
# lines, without hyphenating words that are not yet hyphenated
best_lines = len(wrapText(text, max_width, 0, font_file, font_size))
test_lines = best_lines
min_width = get_min_width()
while test_lines == best_lines and max_width >= min_width:
max_width -= 1
test_lines = len(wrapText(text, max_width, 0, font_file, font_size))
max_width += 1
for i, word in enumerate(words):
line = len(lines) - 1
word_width = get_width(word)
if word_width <= max_width:
# word fits in one line
test = (lines[line] + word + spaces[i]).strip()
if get_width(test) <= max_width:
# word fits in current line
lines[line] = test + (' ' if spaces[i] == ' ' else '')
elif max_lines == 0 or line < max_lines - 1:
# word fits in next line
lines.append(word + spaces[i])
else:
# word does not fit in last line
test = lines[line].strip() + ellipsis
if get_width(test) <= max_width:
# ellipsis fits in last line
lines[line] = test
else:
# ellipsis does not fit in last line
test_words = lines[line].split(' ')
while get_width(test) > max_width:
test_words.pop()
test = ' '.join(test_words) + ellipsis
if test == ellipsis:
# ellipsis does not fit after first word of last line
test = lines[line][:-1] + ellipsis
while get_width(test) > max_width:
test = test[:-2] + ellipsis
lines[line] = test
break
else:
# word does not fit in one line
chars = list(word)
for char in chars:
line = len(lines) - 1
test = (lines[line] + char + '-').strip()
if get_width(test) <= max_width:
# char fits in current line
lines[line] = test[:-1]
elif max_lines == 0 or line < max_lines - 1:
# char fits in next line
if test[-3] == ' ':
lines[line] = test[:-3]
else:
lines[line] = test[:-2] + '-'
lines.append(char)
else:
# char does not fit in last line
test = lines[line] + char + ellipsis
while get_width(test) > max_width:
test = test[:-2] + ellipsis
lines[line] = test
lines[line] += ' '
return lines