Pillow/Tests/test_image_access.py
2019-10-12 18:03:58 +11:00

390 lines
12 KiB
Python

import ctypes
import os
import subprocess
import sys
from distutils import ccompiler, sysconfig
from PIL import Image
from .helper import PillowTestCase, hopper, is_win32, on_ci, unittest
# CFFI imports pycparser which doesn't support PYTHONOPTIMIZE=2
# https://github.com/eliben/pycparser/pull/198#issuecomment-317001670
if os.environ.get("PYTHONOPTIMIZE") == "2":
cffi = None
else:
try:
from PIL import PyAccess
import cffi
except ImportError:
cffi = None
class AccessTest(PillowTestCase):
# initial value
_init_cffi_access = Image.USE_CFFI_ACCESS
_need_cffi_access = False
@classmethod
def setUpClass(cls):
Image.USE_CFFI_ACCESS = cls._need_cffi_access
@classmethod
def tearDownClass(cls):
Image.USE_CFFI_ACCESS = cls._init_cffi_access
class TestImagePutPixel(AccessTest):
def test_sanity(self):
im1 = hopper()
im2 = Image.new(im1.mode, im1.size, 0)
for y in range(im1.size[1]):
for x in range(im1.size[0]):
pos = x, y
im2.putpixel(pos, im1.getpixel(pos))
self.assert_image_equal(im1, im2)
im2 = Image.new(im1.mode, im1.size, 0)
im2.readonly = 1
for y in range(im1.size[1]):
for x in range(im1.size[0]):
pos = x, y
im2.putpixel(pos, im1.getpixel(pos))
self.assertFalse(im2.readonly)
self.assert_image_equal(im1, im2)
im2 = Image.new(im1.mode, im1.size, 0)
pix1 = im1.load()
pix2 = im2.load()
for y in range(im1.size[1]):
for x in range(im1.size[0]):
pix2[x, y] = pix1[x, y]
self.assert_image_equal(im1, im2)
def test_sanity_negative_index(self):
im1 = hopper()
im2 = Image.new(im1.mode, im1.size, 0)
width, height = im1.size
self.assertEqual(im1.getpixel((0, 0)), im1.getpixel((-width, -height)))
self.assertEqual(im1.getpixel((-1, -1)), im1.getpixel((width - 1, height - 1)))
for y in range(-1, -im1.size[1] - 1, -1):
for x in range(-1, -im1.size[0] - 1, -1):
pos = x, y
im2.putpixel(pos, im1.getpixel(pos))
self.assert_image_equal(im1, im2)
im2 = Image.new(im1.mode, im1.size, 0)
im2.readonly = 1
for y in range(-1, -im1.size[1] - 1, -1):
for x in range(-1, -im1.size[0] - 1, -1):
pos = x, y
im2.putpixel(pos, im1.getpixel(pos))
self.assertFalse(im2.readonly)
self.assert_image_equal(im1, im2)
im2 = Image.new(im1.mode, im1.size, 0)
pix1 = im1.load()
pix2 = im2.load()
for y in range(-1, -im1.size[1] - 1, -1):
for x in range(-1, -im1.size[0] - 1, -1):
pix2[x, y] = pix1[x, y]
self.assert_image_equal(im1, im2)
class TestImageGetPixel(AccessTest):
@staticmethod
def color(mode):
bands = Image.getmodebands(mode)
if bands == 1:
return 1
else:
return tuple(range(1, bands + 1))
def check(self, mode, c=None):
if not c:
c = self.color(mode)
# check putpixel
im = Image.new(mode, (1, 1), None)
im.putpixel((0, 0), c)
self.assertEqual(
im.getpixel((0, 0)),
c,
"put/getpixel roundtrip failed for mode {}, color {}".format(mode, c),
)
# check putpixel negative index
im.putpixel((-1, -1), c)
self.assertEqual(
im.getpixel((-1, -1)),
c,
"put/getpixel roundtrip negative index failed"
" for mode %s, color %s" % (mode, c),
)
# Check 0
im = Image.new(mode, (0, 0), None)
with self.assertRaises(IndexError):
im.putpixel((0, 0), c)
with self.assertRaises(IndexError):
im.getpixel((0, 0))
# Check 0 negative index
with self.assertRaises(IndexError):
im.putpixel((-1, -1), c)
with self.assertRaises(IndexError):
im.getpixel((-1, -1))
# check initial color
im = Image.new(mode, (1, 1), c)
self.assertEqual(
im.getpixel((0, 0)),
c,
"initial color failed for mode {}, color {} ".format(mode, c),
)
# check initial color negative index
self.assertEqual(
im.getpixel((-1, -1)),
c,
"initial color failed with negative index"
"for mode %s, color %s " % (mode, c),
)
# Check 0
im = Image.new(mode, (0, 0), c)
with self.assertRaises(IndexError):
im.getpixel((0, 0))
# Check 0 negative index
with self.assertRaises(IndexError):
im.getpixel((-1, -1))
def test_basic(self):
for mode in (
"1",
"L",
"LA",
"I",
"I;16",
"I;16B",
"F",
"P",
"PA",
"RGB",
"RGBA",
"RGBX",
"CMYK",
"YCbCr",
):
self.check(mode)
def test_signedness(self):
# see https://github.com/python-pillow/Pillow/issues/452
# pixelaccess is using signed int* instead of uint*
for mode in ("I;16", "I;16B"):
self.check(mode, 2 ** 15 - 1)
self.check(mode, 2 ** 15)
self.check(mode, 2 ** 15 + 1)
self.check(mode, 2 ** 16 - 1)
def test_p_putpixel_rgb_rgba(self):
for color in [(255, 0, 0), (255, 0, 0, 255)]:
im = Image.new("P", (1, 1), 0)
im.putpixel((0, 0), color)
self.assertEqual(im.convert("RGB").getpixel((0, 0)), (255, 0, 0))
@unittest.skipIf(cffi is None, "No cffi")
class TestCffiPutPixel(TestImagePutPixel):
_need_cffi_access = True
@unittest.skipIf(cffi is None, "No cffi")
class TestCffiGetPixel(TestImageGetPixel):
_need_cffi_access = True
@unittest.skipIf(cffi is None, "No cffi")
class TestCffi(AccessTest):
_need_cffi_access = True
def _test_get_access(self, im):
"""Do we get the same thing as the old pixel access
Using private interfaces, forcing a capi access and
a pyaccess for the same image"""
caccess = im.im.pixel_access(False)
access = PyAccess.new(im, False)
w, h = im.size
for x in range(0, w, 10):
for y in range(0, h, 10):
self.assertEqual(access[(x, y)], caccess[(x, y)])
# Access an out-of-range pixel
self.assertRaises(
ValueError, lambda: access[(access.xsize + 1, access.ysize + 1)]
)
def test_get_vs_c(self):
rgb = hopper("RGB")
rgb.load()
self._test_get_access(rgb)
self._test_get_access(hopper("RGBA"))
self._test_get_access(hopper("L"))
self._test_get_access(hopper("LA"))
self._test_get_access(hopper("1"))
self._test_get_access(hopper("P"))
# self._test_get_access(hopper('PA')) # PA -- how do I make a PA image?
self._test_get_access(hopper("F"))
im = Image.new("I;16", (10, 10), 40000)
self._test_get_access(im)
im = Image.new("I;16L", (10, 10), 40000)
self._test_get_access(im)
im = Image.new("I;16B", (10, 10), 40000)
self._test_get_access(im)
im = Image.new("I", (10, 10), 40000)
self._test_get_access(im)
# These don't actually appear to be modes that I can actually make,
# as unpack sets them directly into the I mode.
# im = Image.new('I;32L', (10, 10), -2**10)
# self._test_get_access(im)
# im = Image.new('I;32B', (10, 10), 2**10)
# self._test_get_access(im)
def _test_set_access(self, im, color):
"""Are we writing the correct bits into the image?
Using private interfaces, forcing a capi access and
a pyaccess for the same image"""
caccess = im.im.pixel_access(False)
access = PyAccess.new(im, False)
w, h = im.size
for x in range(0, w, 10):
for y in range(0, h, 10):
access[(x, y)] = color
self.assertEqual(color, caccess[(x, y)])
# Attempt to set the value on a read-only image
access = PyAccess.new(im, True)
with self.assertRaises(ValueError):
access[(0, 0)] = color
def test_set_vs_c(self):
rgb = hopper("RGB")
rgb.load()
self._test_set_access(rgb, (255, 128, 0))
self._test_set_access(hopper("RGBA"), (255, 192, 128, 0))
self._test_set_access(hopper("L"), 128)
self._test_set_access(hopper("LA"), (128, 128))
self._test_set_access(hopper("1"), 255)
self._test_set_access(hopper("P"), 128)
# self._test_set_access(i, (128, 128)) #PA -- undone how to make
self._test_set_access(hopper("F"), 1024.0)
im = Image.new("I;16", (10, 10), 40000)
self._test_set_access(im, 45000)
im = Image.new("I;16L", (10, 10), 40000)
self._test_set_access(im, 45000)
im = Image.new("I;16B", (10, 10), 40000)
self._test_set_access(im, 45000)
im = Image.new("I", (10, 10), 40000)
self._test_set_access(im, 45000)
# im = Image.new('I;32L', (10, 10), -(2**10))
# self._test_set_access(im, -(2**13)+1)
# im = Image.new('I;32B', (10, 10), 2**10)
# self._test_set_access(im, 2**13-1)
def test_not_implemented(self):
self.assertIsNone(PyAccess.new(hopper("BGR;15")))
# ref https://github.com/python-pillow/Pillow/pull/2009
def test_reference_counting(self):
size = 10
for _ in range(10):
# Do not save references to the image, only to the access object
px = Image.new("L", (size, 1), 0).load()
for i in range(size):
# pixels can contain garbage if image is released
self.assertEqual(px[i, 0], 0)
def test_p_putpixel_rgb_rgba(self):
for color in [(255, 0, 0), (255, 0, 0, 255)]:
im = Image.new("P", (1, 1), 0)
access = PyAccess.new(im, False)
access.putpixel((0, 0), color)
self.assertEqual(im.convert("RGB").getpixel((0, 0)), (255, 0, 0))
class TestEmbeddable(unittest.TestCase):
@unittest.skipIf(
not is_win32() or on_ci(),
"Failing on AppVeyor / GitHub Actions when run from subprocess, not from shell",
)
def test_embeddable(self):
with open("embed_pil.c", "w") as fh:
fh.write(
"""
#include "Python.h"
int main(int argc, char* argv[])
{
char *home = "%s";
wchar_t *whome = Py_DecodeLocale(home, NULL);
Py_SetPythonHome(whome);
Py_InitializeEx(0);
Py_DECREF(PyImport_ImportModule("PIL.Image"));
Py_Finalize();
Py_InitializeEx(0);
Py_DECREF(PyImport_ImportModule("PIL.Image"));
Py_Finalize();
PyMem_RawFree(whome);
return 0;
}
"""
% sys.prefix.replace("\\", "\\\\")
)
compiler = ccompiler.new_compiler()
compiler.add_include_dir(sysconfig.get_python_inc())
libdir = sysconfig.get_config_var(
"LIBDIR"
) or sysconfig.get_python_inc().replace("include", "libs")
print(libdir)
compiler.add_library_dir(libdir)
objects = compiler.compile(["embed_pil.c"])
compiler.link_executable(objects, "embed_pil")
env = os.environ.copy()
env["PATH"] = sys.prefix + ";" + env["PATH"]
# do not display the Windows Error Reporting dialog
ctypes.windll.kernel32.SetErrorMode(0x0002)
process = subprocess.Popen(["embed_pil.exe"], env=env)
process.communicate()
self.assertEqual(process.returncode, 0)