Pillow/Tests/test_file_pcx.py
Jon Dufresne 4de5477b61 Remove unnecessary unittest.main() boilerplate from test files
With the introduction and use of pytest, it is simple and easy to
execute specific tests in isolation through documented command line
arguments. Either by specifying the module path or through the `-k
EXPRESSION` argument. There is no longer any need to provide the
boilerplate:

    if __name__ == '__main__':
        unittest.main()

To every test file. It is simply noise.

The pattern remains in test files that aren't named with `test_*` as
those files are not discovered and executed by pytest by default.
2019-02-03 10:10:16 -08:00

131 lines
3.8 KiB
Python

from .helper import PillowTestCase, hopper
from PIL import Image, ImageFile, PcxImagePlugin
class TestFilePcx(PillowTestCase):
def _roundtrip(self, im):
f = self.tempfile("temp.pcx")
im.save(f)
im2 = Image.open(f)
self.assertEqual(im2.mode, im.mode)
self.assertEqual(im2.size, im.size)
self.assertEqual(im2.format, "PCX")
self.assert_image_equal(im2, im)
def test_sanity(self):
for mode in ('1', 'L', 'P', 'RGB'):
self._roundtrip(hopper(mode))
# Test an unsupported mode
f = self.tempfile("temp.pcx")
im = hopper("RGBA")
self.assertRaises(ValueError, im.save, f)
def test_invalid_file(self):
invalid_file = "Tests/images/flower.jpg"
self.assertRaises(SyntaxError,
PcxImagePlugin.PcxImageFile, invalid_file)
def test_odd(self):
# see issue #523, odd sized images should have a stride that's even.
# not that imagemagick or gimp write pcx that way.
# we were not handling properly.
for mode in ('1', 'L', 'P', 'RGB'):
# larger, odd sized images are better here to ensure that
# we handle interrupted scan lines properly.
self._roundtrip(hopper(mode).resize((511, 511)))
def test_pil184(self):
# Check reading of files where xmin/xmax is not zero.
test_file = "Tests/images/pil184.pcx"
im = Image.open(test_file)
self.assertEqual(im.size, (447, 144))
self.assertEqual(im.tile[0][1], (0, 0, 447, 144))
# Make sure all pixels are either 0 or 255.
self.assertEqual(im.histogram()[0] + im.histogram()[255], 447*144)
def test_1px_width(self):
im = Image.new('L', (1, 256))
px = im.load()
for y in range(256):
px[0, y] = y
self._roundtrip(im)
def test_large_count(self):
im = Image.new('L', (256, 1))
px = im.load()
for x in range(256):
px[x, 0] = x // 67 * 67
self._roundtrip(im)
def _test_buffer_overflow(self, im, size=1024):
_last = ImageFile.MAXBLOCK
ImageFile.MAXBLOCK = size
try:
self._roundtrip(im)
finally:
ImageFile.MAXBLOCK = _last
def test_break_in_count_overflow(self):
im = Image.new('L', (256, 5))
px = im.load()
for y in range(4):
for x in range(256):
px[x, y] = x % 128
self._test_buffer_overflow(im)
def test_break_one_in_loop(self):
im = Image.new('L', (256, 5))
px = im.load()
for y in range(5):
for x in range(256):
px[x, y] = x % 128
self._test_buffer_overflow(im)
def test_break_many_in_loop(self):
im = Image.new('L', (256, 5))
px = im.load()
for y in range(4):
for x in range(256):
px[x, y] = x % 128
for x in range(8):
px[x, 4] = 16
self._test_buffer_overflow(im)
def test_break_one_at_end(self):
im = Image.new('L', (256, 5))
px = im.load()
for y in range(5):
for x in range(256):
px[x, y] = x % 128
px[0, 3] = 128 + 64
self._test_buffer_overflow(im)
def test_break_many_at_end(self):
im = Image.new('L', (256, 5))
px = im.load()
for y in range(5):
for x in range(256):
px[x, y] = x % 128
for x in range(4):
px[x * 2, 3] = 128 + 64
px[x + 256 - 4, 3] = 0
self._test_buffer_overflow(im)
def test_break_padding(self):
im = Image.new('L', (257, 5))
px = im.load()
for y in range(5):
for x in range(257):
px[x, y] = x % 128
for x in range(5):
px[x, 3] = 0
self._test_buffer_overflow(im)