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https://github.com/python-pillow/Pillow.git
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342 lines
13 KiB
Python
342 lines
13 KiB
Python
from helper import unittest, PillowTestCase, hopper
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from PIL import Image, ImageDraw, ImageMode
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class TestImagingResampleVulnerability(PillowTestCase):
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# see https://github.com/python-pillow/Pillow/issues/1710
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def test_overflow(self):
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im = hopper('L')
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xsize = 0x100000008 // 4
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ysize = 1000 # unimportant
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try:
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# any resampling filter will do here
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im.im.resize((xsize, ysize), Image.BILINEAR)
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self.fail("Resize should raise MemoryError on invalid xsize")
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except MemoryError:
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self.assertTrue(True, "Should raise MemoryError")
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def test_invalid_size(self):
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im = hopper()
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im.resize((100, 100))
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self.assertTrue(True, "Should not Crash")
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try:
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im.resize((-100, 100))
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self.fail("Resize should raise a value error on x negative size")
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except ValueError:
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self.assertTrue(True, "Should raise ValueError")
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try:
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im.resize((100, -100))
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self.fail("Resize should raise a value error on y negative size")
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except ValueError:
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self.assertTrue(True, "Should raise ValueError")
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class TestImagingCoreResampleAccuracy(PillowTestCase):
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def make_case(self, mode, size, color):
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"""Makes a sample image with two dark and two bright squares.
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For example:
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e0 e0 1f 1f
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e0 e0 1f 1f
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1f 1f e0 e0
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1f 1f e0 e0
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"""
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case = Image.new('L', size, 255 - color)
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rectangle = ImageDraw.Draw(case).rectangle
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rectangle((0, 0, size[0] // 2 - 1, size[1] // 2 - 1), color)
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rectangle((size[0] // 2, size[1] // 2, size[0], size[1]), color)
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return Image.merge(mode, [case] * len(mode))
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def make_sample(self, data, size):
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"""Restores a sample image from given data string which contains
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hex-encoded pixels from the top left fourth of a sample.
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"""
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data = data.replace(' ', '')
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sample = Image.new('L', size)
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s_px = sample.load()
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w, h = size[0] // 2, size[1] // 2
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for y in range(h):
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for x in range(w):
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val = int(data[(y * w + x) * 2:(y * w + x + 1) * 2], 16)
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s_px[x, y] = val
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s_px[size[0] - x - 1, size[1] - y - 1] = val
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s_px[x, size[1] - y - 1] = 255 - val
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s_px[size[0] - x - 1, y] = 255 - val
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return sample
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def check_case(self, case, sample):
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s_px = sample.load()
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c_px = case.load()
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for y in range(case.size[1]):
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for x in range(case.size[0]):
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if c_px[x, y] != s_px[x, y]:
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message = '\nHave: \n{}\n\nExpected: \n{}'.format(
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self.serialize_image(case),
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self.serialize_image(sample),
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)
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self.assertEqual(s_px[x, y], c_px[x, y], message)
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def serialize_image(self, image):
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s_px = image.load()
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return '\n'.join(
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' '.join(
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'{:02x}'.format(s_px[x, y])
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for x in range(image.size[0])
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)
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for y in range(image.size[1])
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)
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def test_reduce_box(self):
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for mode in ['RGBX', 'RGB', 'La', 'L']:
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case = self.make_case(mode, (8, 8), 0xe1)
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case = case.resize((4, 4), Image.BOX)
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data = ('e1 e1'
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'e1 e1')
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for channel in case.split():
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self.check_case(channel, self.make_sample(data, (4, 4)))
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def test_reduce_bilinear(self):
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for mode in ['RGBX', 'RGB', 'La', 'L']:
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case = self.make_case(mode, (8, 8), 0xe1)
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case = case.resize((4, 4), Image.BILINEAR)
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data = ('e1 c9'
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'c9 b7')
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for channel in case.split():
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self.check_case(channel, self.make_sample(data, (4, 4)))
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def test_reduce_hamming(self):
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for mode in ['RGBX', 'RGB', 'La', 'L']:
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case = self.make_case(mode, (8, 8), 0xe1)
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case = case.resize((4, 4), Image.HAMMING)
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data = ('e1 da'
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'da d3')
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for channel in case.split():
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self.check_case(channel, self.make_sample(data, (4, 4)))
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def test_reduce_bicubic(self):
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for mode in ['RGBX', 'RGB', 'La', 'L']:
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case = self.make_case(mode, (12, 12), 0xe1)
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case = case.resize((6, 6), Image.BICUBIC)
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data = ('e1 e3 d4'
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'e3 e5 d6'
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'd4 d6 c9')
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for channel in case.split():
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self.check_case(channel, self.make_sample(data, (6, 6)))
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def test_reduce_lanczos(self):
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for mode in ['RGBX', 'RGB', 'La', 'L']:
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case = self.make_case(mode, (16, 16), 0xe1)
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case = case.resize((8, 8), Image.LANCZOS)
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data = ('e1 e0 e4 d7'
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'e0 df e3 d6'
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'e4 e3 e7 da'
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'd7 d6 d9 ce')
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for channel in case.split():
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self.check_case(channel, self.make_sample(data, (8, 8)))
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def test_enlarge_box(self):
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for mode in ['RGBX', 'RGB', 'La', 'L']:
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case = self.make_case(mode, (2, 2), 0xe1)
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case = case.resize((4, 4), Image.BOX)
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data = ('e1 e1'
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'e1 e1')
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for channel in case.split():
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self.check_case(channel, self.make_sample(data, (4, 4)))
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def test_enlarge_bilinear(self):
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for mode in ['RGBX', 'RGB', 'La', 'L']:
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case = self.make_case(mode, (2, 2), 0xe1)
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case = case.resize((4, 4), Image.BILINEAR)
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data = ('e1 b0'
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'b0 98')
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for channel in case.split():
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self.check_case(channel, self.make_sample(data, (4, 4)))
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def test_enlarge_hamming(self):
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for mode in ['RGBX', 'RGB', 'La', 'L']:
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case = self.make_case(mode, (4, 4), 0xe1)
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case = case.resize((8, 8), Image.HAMMING)
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data = ('e1 e1 ea d1'
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'e1 e1 ea d1'
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'ea ea f4 d9'
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'd1 d1 d9 c4')
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for channel in case.split():
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self.check_case(channel, self.make_sample(data, (8, 8)))
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def test_enlarge_bicubic(self):
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for mode in ['RGBX', 'RGB', 'La', 'L']:
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case = self.make_case(mode, (4, 4), 0xe1)
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case = case.resize((8, 8), Image.BICUBIC)
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data = ('e1 e5 ee b9'
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'e5 e9 f3 bc'
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'ee f3 fd c1'
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'b9 bc c1 a2')
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for channel in case.split():
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self.check_case(channel, self.make_sample(data, (8, 8)))
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def test_enlarge_lanczos(self):
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for mode in ['RGBX', 'RGB', 'La', 'L']:
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case = self.make_case(mode, (6, 6), 0xe1)
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case = case.resize((12, 12), Image.LANCZOS)
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data = ('e1 e0 db ed f5 b8'
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'e0 df da ec f3 b7'
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'db db d6 e7 ee b5'
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'ed ec e6 fb ff bf'
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'f5 f4 ee ff ff c4'
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'b8 b7 b4 bf c4 a0')
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for channel in case.split():
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self.check_case(channel, self.make_sample(data, (12, 12)))
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class CoreResampleConsistencyTest(PillowTestCase):
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def make_case(self, mode, fill):
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im = Image.new(mode, (512, 9), fill)
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return (im.resize((9, 512), Image.LANCZOS), im.load()[0, 0])
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def run_case(self, case):
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channel, color = case
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px = channel.load()
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for x in range(channel.size[0]):
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for y in range(channel.size[1]):
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if px[x, y] != color:
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message = "{} != {} for pixel {}".format(
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px[x, y], color, (x, y))
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self.assertEqual(px[x, y], color, message)
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def test_8u(self):
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im, color = self.make_case('RGB', (0, 64, 255))
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r, g, b = im.split()
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self.run_case((r, color[0]))
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self.run_case((g, color[1]))
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self.run_case((b, color[2]))
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self.run_case(self.make_case('L', 12))
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def test_32i(self):
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self.run_case(self.make_case('I', 12))
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self.run_case(self.make_case('I', 0x7fffffff))
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self.run_case(self.make_case('I', -12))
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self.run_case(self.make_case('I', -1 << 31))
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def test_32f(self):
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self.run_case(self.make_case('F', 1))
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self.run_case(self.make_case('F', 3.40282306074e+38))
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self.run_case(self.make_case('F', 1.175494e-38))
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self.run_case(self.make_case('F', 1.192093e-07))
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class CoreResampleAlphaCorrectTest(PillowTestCase):
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def make_levels_case(self, mode):
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i = Image.new(mode, (256, 16))
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px = i.load()
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for y in range(i.size[1]):
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for x in range(i.size[0]):
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pix = [x] * len(mode)
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pix[-1] = 255 - y * 16
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px[x, y] = tuple(pix)
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return i
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def run_levels_case(self, i):
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px = i.load()
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for y in range(i.size[1]):
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used_colors = set(px[x, y][0] for x in range(i.size[0]))
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self.assertEqual(256, len(used_colors),
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'All colors should present in resized image. '
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'Only {0} on {1} line.'.format(len(used_colors), y))
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@unittest.skip("current implementation isn't precise enough")
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def test_levels_rgba(self):
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case = self.make_levels_case('RGBA')
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self.run_levels_case(case.resize((512, 32), Image.BOX))
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self.run_levels_case(case.resize((512, 32), Image.BILINEAR))
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self.run_levels_case(case.resize((512, 32), Image.HAMMING))
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self.run_levels_case(case.resize((512, 32), Image.BICUBIC))
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self.run_levels_case(case.resize((512, 32), Image.LANCZOS))
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@unittest.skip("current implementation isn't precise enough")
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def test_levels_la(self):
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case = self.make_levels_case('LA')
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self.run_levels_case(case.resize((512, 32), Image.BOX))
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self.run_levels_case(case.resize((512, 32), Image.BILINEAR))
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self.run_levels_case(case.resize((512, 32), Image.HAMMING))
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self.run_levels_case(case.resize((512, 32), Image.BICUBIC))
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self.run_levels_case(case.resize((512, 32), Image.LANCZOS))
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def make_dity_case(self, mode, clean_pixel, dirty_pixel):
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i = Image.new(mode, (64, 64), dirty_pixel)
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px = i.load()
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xdiv4 = i.size[0] // 4
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ydiv4 = i.size[1] // 4
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for y in range(ydiv4 * 2):
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for x in range(xdiv4 * 2):
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px[x + xdiv4, y + ydiv4] = clean_pixel
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return i
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def run_dity_case(self, i, clean_pixel):
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px = i.load()
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for y in range(i.size[1]):
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for x in range(i.size[0]):
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if px[x, y][-1] != 0 and px[x, y][:-1] != clean_pixel:
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message = 'pixel at ({0}, {1}) is differ:\n{2}\n{3}'\
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.format(x, y, px[x, y], clean_pixel)
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self.assertEqual(px[x, y][:3], clean_pixel, message)
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def test_dirty_pixels_rgba(self):
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case = self.make_dity_case('RGBA', (255, 255, 0, 128), (0, 0, 255, 0))
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self.run_dity_case(case.resize((20, 20), Image.BOX), (255, 255, 0))
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self.run_dity_case(case.resize((20, 20), Image.BILINEAR), (255, 255, 0))
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self.run_dity_case(case.resize((20, 20), Image.HAMMING), (255, 255, 0))
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self.run_dity_case(case.resize((20, 20), Image.BICUBIC), (255, 255, 0))
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self.run_dity_case(case.resize((20, 20), Image.LANCZOS), (255, 255, 0))
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def test_dirty_pixels_la(self):
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case = self.make_dity_case('LA', (255, 128), (0, 0))
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self.run_dity_case(case.resize((20, 20), Image.BOX), (255,))
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self.run_dity_case(case.resize((20, 20), Image.BILINEAR), (255,))
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self.run_dity_case(case.resize((20, 20), Image.HAMMING), (255,))
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self.run_dity_case(case.resize((20, 20), Image.BICUBIC), (255,))
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self.run_dity_case(case.resize((20, 20), Image.LANCZOS), (255,))
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class CoreResamplePassesTest(PillowTestCase):
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def test_horizontal(self):
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im = hopper('L')
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count = Image.core.getcount()
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im.resize((im.size[0] + 10, im.size[1]), Image.BILINEAR)
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self.assertEqual(Image.core.getcount(), count + 1)
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def test_vertical(self):
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im = hopper('L')
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count = Image.core.getcount()
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im.resize((im.size[0], im.size[1] + 10), Image.BILINEAR)
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self.assertEqual(Image.core.getcount(), count + 1)
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def test_both(self):
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im = hopper('L')
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count = Image.core.getcount()
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im.resize((im.size[0] + 10, im.size[1] + 10), Image.BILINEAR)
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self.assertEqual(Image.core.getcount(), count + 2)
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class CoreResampleCoefficientsTest(PillowTestCase):
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def test_reduce(self):
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test_color = 254
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# print ''
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for size in range(400000, 400010, 2):
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# print '\r', size,
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i = Image.new('L', (size, 1), 0)
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draw = ImageDraw.Draw(i)
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draw.rectangle((0, 0, i.size[0] // 2 - 1, 0), test_color)
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px = i.resize((5, i.size[1]), Image.BICUBIC).load()
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if px[2, 0] != test_color // 2:
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self.assertEqual(test_color // 2, px[2, 0])
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# print '\r>', size, test_color // 2, px[2, 0]
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if __name__ == '__main__':
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unittest.main()
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