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# | |
# The Python Imaging Library. | |
# $Id$ | |
# | |
# standard image operations | |
# | |
# History: | |
# 2001-10-20 fl Created | |
# 2001-10-23 fl Added autocontrast operator | |
# 2001-12-18 fl Added Kevin's fit operator | |
# 2004-03-14 fl Fixed potential division by zero in equalize | |
# 2005-05-05 fl Fixed equalize for low number of values | |
# | |
# Copyright (c) 2001-2004 by Secret Labs AB | |
# Copyright (c) 2001-2004 by Fredrik Lundh | |
# | |
# See the README file for information on usage and redistribution. | |
# | |
from __future__ import annotations | |
import functools | |
import operator | |
import re | |
from typing import Protocol, Sequence, cast | |
from . import ExifTags, Image, ImagePalette | |
# | |
# helpers | |
def _border(border: int | tuple[int, ...]) -> tuple[int, int, int, int]: | |
if isinstance(border, tuple): | |
if len(border) == 2: | |
left, top = right, bottom = border | |
elif len(border) == 4: | |
left, top, right, bottom = border | |
else: | |
left = top = right = bottom = border | |
return left, top, right, bottom | |
def _color(color: str | int | tuple[int, ...], mode: str) -> int | tuple[int, ...]: | |
if isinstance(color, str): | |
from . import ImageColor | |
color = ImageColor.getcolor(color, mode) | |
return color | |
def _lut(image: Image.Image, lut: list[int]) -> Image.Image: | |
if image.mode == "P": | |
# FIXME: apply to lookup table, not image data | |
msg = "mode P support coming soon" | |
raise NotImplementedError(msg) | |
elif image.mode in ("L", "RGB"): | |
if image.mode == "RGB" and len(lut) == 256: | |
lut = lut + lut + lut | |
return image.point(lut) | |
else: | |
msg = f"not supported for mode {image.mode}" | |
raise OSError(msg) | |
# | |
# actions | |
def autocontrast( | |
image: Image.Image, | |
cutoff: float | tuple[float, float] = 0, | |
ignore: int | Sequence[int] | None = None, | |
mask: Image.Image | None = None, | |
preserve_tone: bool = False, | |
) -> Image.Image: | |
""" | |
Maximize (normalize) image contrast. This function calculates a | |
histogram of the input image (or mask region), removes ``cutoff`` percent of the | |
lightest and darkest pixels from the histogram, and remaps the image | |
so that the darkest pixel becomes black (0), and the lightest | |
becomes white (255). | |
:param image: The image to process. | |
:param cutoff: The percent to cut off from the histogram on the low and | |
high ends. Either a tuple of (low, high), or a single | |
number for both. | |
:param ignore: The background pixel value (use None for no background). | |
:param mask: Histogram used in contrast operation is computed using pixels | |
within the mask. If no mask is given the entire image is used | |
for histogram computation. | |
:param preserve_tone: Preserve image tone in Photoshop-like style autocontrast. | |
.. versionadded:: 8.2.0 | |
:return: An image. | |
""" | |
if preserve_tone: | |
histogram = image.convert("L").histogram(mask) | |
else: | |
histogram = image.histogram(mask) | |
lut = [] | |
for layer in range(0, len(histogram), 256): | |
h = histogram[layer : layer + 256] | |
if ignore is not None: | |
# get rid of outliers | |
if isinstance(ignore, int): | |
h[ignore] = 0 | |
else: | |
for ix in ignore: | |
h[ix] = 0 | |
if cutoff: | |
# cut off pixels from both ends of the histogram | |
if not isinstance(cutoff, tuple): | |
cutoff = (cutoff, cutoff) | |
# get number of pixels | |
n = 0 | |
for ix in range(256): | |
n = n + h[ix] | |
# remove cutoff% pixels from the low end | |
cut = int(n * cutoff[0] // 100) | |
for lo in range(256): | |
if cut > h[lo]: | |
cut = cut - h[lo] | |
h[lo] = 0 | |
else: | |
h[lo] -= cut | |
cut = 0 | |
if cut <= 0: | |
break | |
# remove cutoff% samples from the high end | |
cut = int(n * cutoff[1] // 100) | |
for hi in range(255, -1, -1): | |
if cut > h[hi]: | |
cut = cut - h[hi] | |
h[hi] = 0 | |
else: | |
h[hi] -= cut | |
cut = 0 | |
if cut <= 0: | |
break | |
# find lowest/highest samples after preprocessing | |
for lo in range(256): | |
if h[lo]: | |
break | |
for hi in range(255, -1, -1): | |
if h[hi]: | |
break | |
if hi <= lo: | |
# don't bother | |
lut.extend(list(range(256))) | |
else: | |
scale = 255.0 / (hi - lo) | |
offset = -lo * scale | |
for ix in range(256): | |
ix = int(ix * scale + offset) | |
if ix < 0: | |
ix = 0 | |
elif ix > 255: | |
ix = 255 | |
lut.append(ix) | |
return _lut(image, lut) | |
def colorize( | |
image: Image.Image, | |
black: str | tuple[int, ...], | |
white: str | tuple[int, ...], | |
mid: str | int | tuple[int, ...] | None = None, | |
blackpoint: int = 0, | |
whitepoint: int = 255, | |
midpoint: int = 127, | |
) -> Image.Image: | |
""" | |
Colorize grayscale image. | |
This function calculates a color wedge which maps all black pixels in | |
the source image to the first color and all white pixels to the | |
second color. If ``mid`` is specified, it uses three-color mapping. | |
The ``black`` and ``white`` arguments should be RGB tuples or color names; | |
optionally you can use three-color mapping by also specifying ``mid``. | |
Mapping positions for any of the colors can be specified | |
(e.g. ``blackpoint``), where these parameters are the integer | |
value corresponding to where the corresponding color should be mapped. | |
These parameters must have logical order, such that | |
``blackpoint <= midpoint <= whitepoint`` (if ``mid`` is specified). | |
:param image: The image to colorize. | |
:param black: The color to use for black input pixels. | |
:param white: The color to use for white input pixels. | |
:param mid: The color to use for midtone input pixels. | |
:param blackpoint: an int value [0, 255] for the black mapping. | |
:param whitepoint: an int value [0, 255] for the white mapping. | |
:param midpoint: an int value [0, 255] for the midtone mapping. | |
:return: An image. | |
""" | |
# Initial asserts | |
assert image.mode == "L" | |
if mid is None: | |
assert 0 <= blackpoint <= whitepoint <= 255 | |
else: | |
assert 0 <= blackpoint <= midpoint <= whitepoint <= 255 | |
# Define colors from arguments | |
rgb_black = cast(Sequence[int], _color(black, "RGB")) | |
rgb_white = cast(Sequence[int], _color(white, "RGB")) | |
rgb_mid = cast(Sequence[int], _color(mid, "RGB")) if mid is not None else None | |
# Empty lists for the mapping | |
red = [] | |
green = [] | |
blue = [] | |
# Create the low-end values | |
for i in range(0, blackpoint): | |
red.append(rgb_black[0]) | |
green.append(rgb_black[1]) | |
blue.append(rgb_black[2]) | |
# Create the mapping (2-color) | |
if rgb_mid is None: | |
range_map = range(0, whitepoint - blackpoint) | |
for i in range_map: | |
red.append( | |
rgb_black[0] + i * (rgb_white[0] - rgb_black[0]) // len(range_map) | |
) | |
green.append( | |
rgb_black[1] + i * (rgb_white[1] - rgb_black[1]) // len(range_map) | |
) | |
blue.append( | |
rgb_black[2] + i * (rgb_white[2] - rgb_black[2]) // len(range_map) | |
) | |
# Create the mapping (3-color) | |
else: | |
range_map1 = range(0, midpoint - blackpoint) | |
range_map2 = range(0, whitepoint - midpoint) | |
for i in range_map1: | |
red.append( | |
rgb_black[0] + i * (rgb_mid[0] - rgb_black[0]) // len(range_map1) | |
) | |
green.append( | |
rgb_black[1] + i * (rgb_mid[1] - rgb_black[1]) // len(range_map1) | |
) | |
blue.append( | |
rgb_black[2] + i * (rgb_mid[2] - rgb_black[2]) // len(range_map1) | |
) | |
for i in range_map2: | |
red.append(rgb_mid[0] + i * (rgb_white[0] - rgb_mid[0]) // len(range_map2)) | |
green.append( | |
rgb_mid[1] + i * (rgb_white[1] - rgb_mid[1]) // len(range_map2) | |
) | |
blue.append(rgb_mid[2] + i * (rgb_white[2] - rgb_mid[2]) // len(range_map2)) | |
# Create the high-end values | |
for i in range(0, 256 - whitepoint): | |
red.append(rgb_white[0]) | |
green.append(rgb_white[1]) | |
blue.append(rgb_white[2]) | |
# Return converted image | |
image = image.convert("RGB") | |
return _lut(image, red + green + blue) | |
def contain( | |
image: Image.Image, size: tuple[int, int], method: int = Image.Resampling.BICUBIC | |
) -> Image.Image: | |
""" | |
Returns a resized version of the image, set to the maximum width and height | |
within the requested size, while maintaining the original aspect ratio. | |
:param image: The image to resize. | |
:param size: The requested output size in pixels, given as a | |
(width, height) tuple. | |
:param method: Resampling method to use. Default is | |
:py:attr:`~PIL.Image.Resampling.BICUBIC`. | |
See :ref:`concept-filters`. | |
:return: An image. | |
""" | |
im_ratio = image.width / image.height | |
dest_ratio = size[0] / size[1] | |
if im_ratio != dest_ratio: | |
if im_ratio > dest_ratio: | |
new_height = round(image.height / image.width * size[0]) | |
if new_height != size[1]: | |
size = (size[0], new_height) | |
else: | |
new_width = round(image.width / image.height * size[1]) | |
if new_width != size[0]: | |
size = (new_width, size[1]) | |
return image.resize(size, resample=method) | |
def cover( | |
image: Image.Image, size: tuple[int, int], method: int = Image.Resampling.BICUBIC | |
) -> Image.Image: | |
""" | |
Returns a resized version of the image, so that the requested size is | |
covered, while maintaining the original aspect ratio. | |
:param image: The image to resize. | |
:param size: The requested output size in pixels, given as a | |
(width, height) tuple. | |
:param method: Resampling method to use. Default is | |
:py:attr:`~PIL.Image.Resampling.BICUBIC`. | |
See :ref:`concept-filters`. | |
:return: An image. | |
""" | |
im_ratio = image.width / image.height | |
dest_ratio = size[0] / size[1] | |
if im_ratio != dest_ratio: | |
if im_ratio < dest_ratio: | |
new_height = round(image.height / image.width * size[0]) | |
if new_height != size[1]: | |
size = (size[0], new_height) | |
else: | |
new_width = round(image.width / image.height * size[1]) | |
if new_width != size[0]: | |
size = (new_width, size[1]) | |
return image.resize(size, resample=method) | |
def pad( | |
image: Image.Image, | |
size: tuple[int, int], | |
method: int = Image.Resampling.BICUBIC, | |
color: str | int | tuple[int, ...] | None = None, | |
centering: tuple[float, float] = (0.5, 0.5), | |
) -> Image.Image: | |
""" | |
Returns a resized and padded version of the image, expanded to fill the | |
requested aspect ratio and size. | |
:param image: The image to resize and crop. | |
:param size: The requested output size in pixels, given as a | |
(width, height) tuple. | |
:param method: Resampling method to use. Default is | |
:py:attr:`~PIL.Image.Resampling.BICUBIC`. | |
See :ref:`concept-filters`. | |
:param color: The background color of the padded image. | |
:param centering: Control the position of the original image within the | |
padded version. | |
(0.5, 0.5) will keep the image centered | |
(0, 0) will keep the image aligned to the top left | |
(1, 1) will keep the image aligned to the bottom | |
right | |
:return: An image. | |
""" | |
resized = contain(image, size, method) | |
if resized.size == size: | |
out = resized | |
else: | |
out = Image.new(image.mode, size, color) | |
if resized.palette: | |
out.putpalette(resized.getpalette()) | |
if resized.width != size[0]: | |
x = round((size[0] - resized.width) * max(0, min(centering[0], 1))) | |
out.paste(resized, (x, 0)) | |
else: | |
y = round((size[1] - resized.height) * max(0, min(centering[1], 1))) | |
out.paste(resized, (0, y)) | |
return out | |
def crop(image: Image.Image, border: int = 0) -> Image.Image: | |
""" | |
Remove border from image. The same amount of pixels are removed | |
from all four sides. This function works on all image modes. | |
.. seealso:: :py:meth:`~PIL.Image.Image.crop` | |
:param image: The image to crop. | |
:param border: The number of pixels to remove. | |
:return: An image. | |
""" | |
left, top, right, bottom = _border(border) | |
return image.crop((left, top, image.size[0] - right, image.size[1] - bottom)) | |
def scale( | |
image: Image.Image, factor: float, resample: int = Image.Resampling.BICUBIC | |
) -> Image.Image: | |
""" | |
Returns a rescaled image by a specific factor given in parameter. | |
A factor greater than 1 expands the image, between 0 and 1 contracts the | |
image. | |
:param image: The image to rescale. | |
:param factor: The expansion factor, as a float. | |
:param resample: Resampling method to use. Default is | |
:py:attr:`~PIL.Image.Resampling.BICUBIC`. | |
See :ref:`concept-filters`. | |
:returns: An :py:class:`~PIL.Image.Image` object. | |
""" | |
if factor == 1: | |
return image.copy() | |
elif factor <= 0: | |
msg = "the factor must be greater than 0" | |
raise ValueError(msg) | |
else: | |
size = (round(factor * image.width), round(factor * image.height)) | |
return image.resize(size, resample) | |
class SupportsGetMesh(Protocol): | |
""" | |
An object that supports the ``getmesh`` method, taking an image as an | |
argument, and returning a list of tuples. Each tuple contains two tuples, | |
the source box as a tuple of 4 integers, and a tuple of 8 integers for the | |
final quadrilateral, in order of top left, bottom left, bottom right, top | |
right. | |
""" | |
def getmesh( | |
self, image: Image.Image | |
) -> list[ | |
tuple[tuple[int, int, int, int], tuple[int, int, int, int, int, int, int, int]] | |
]: ... | |
def deform( | |
image: Image.Image, | |
deformer: SupportsGetMesh, | |
resample: int = Image.Resampling.BILINEAR, | |
) -> Image.Image: | |
""" | |
Deform the image. | |
:param image: The image to deform. | |
:param deformer: A deformer object. Any object that implements a | |
``getmesh`` method can be used. | |
:param resample: An optional resampling filter. Same values possible as | |
in the PIL.Image.transform function. | |
:return: An image. | |
""" | |
return image.transform( | |
image.size, Image.Transform.MESH, deformer.getmesh(image), resample | |
) | |
def equalize(image: Image.Image, mask: Image.Image | None = None) -> Image.Image: | |
""" | |
Equalize the image histogram. This function applies a non-linear | |
mapping to the input image, in order to create a uniform | |
distribution of grayscale values in the output image. | |
:param image: The image to equalize. | |
:param mask: An optional mask. If given, only the pixels selected by | |
the mask are included in the analysis. | |
:return: An image. | |
""" | |
if image.mode == "P": | |
image = image.convert("RGB") | |
h = image.histogram(mask) | |
lut = [] | |
for b in range(0, len(h), 256): | |
histo = [_f for _f in h[b : b + 256] if _f] | |
if len(histo) <= 1: | |
lut.extend(list(range(256))) | |
else: | |
step = (functools.reduce(operator.add, histo) - histo[-1]) // 255 | |
if not step: | |
lut.extend(list(range(256))) | |
else: | |
n = step // 2 | |
for i in range(256): | |
lut.append(n // step) | |
n = n + h[i + b] | |
return _lut(image, lut) | |
def expand( | |
image: Image.Image, | |
border: int | tuple[int, ...] = 0, | |
fill: str | int | tuple[int, ...] = 0, | |
) -> Image.Image: | |
""" | |
Add border to the image | |
:param image: The image to expand. | |
:param border: Border width, in pixels. | |
:param fill: Pixel fill value (a color value). Default is 0 (black). | |
:return: An image. | |
""" | |
left, top, right, bottom = _border(border) | |
width = left + image.size[0] + right | |
height = top + image.size[1] + bottom | |
color = _color(fill, image.mode) | |
if image.palette: | |
palette = ImagePalette.ImagePalette(palette=image.getpalette()) | |
if isinstance(color, tuple) and (len(color) == 3 or len(color) == 4): | |
color = palette.getcolor(color) | |
else: | |
palette = None | |
out = Image.new(image.mode, (width, height), color) | |
if palette: | |
out.putpalette(palette.palette) | |
out.paste(image, (left, top)) | |
return out | |
def fit( | |
image: Image.Image, | |
size: tuple[int, int], | |
method: int = Image.Resampling.BICUBIC, | |
bleed: float = 0.0, | |
centering: tuple[float, float] = (0.5, 0.5), | |
) -> Image.Image: | |
""" | |
Returns a resized and cropped version of the image, cropped to the | |
requested aspect ratio and size. | |
This function was contributed by Kevin Cazabon. | |
:param image: The image to resize and crop. | |
:param size: The requested output size in pixels, given as a | |
(width, height) tuple. | |
:param method: Resampling method to use. Default is | |
:py:attr:`~PIL.Image.Resampling.BICUBIC`. | |
See :ref:`concept-filters`. | |
:param bleed: Remove a border around the outside of the image from all | |
four edges. The value is a decimal percentage (use 0.01 for | |
one percent). The default value is 0 (no border). | |
Cannot be greater than or equal to 0.5. | |
:param centering: Control the cropping position. Use (0.5, 0.5) for | |
center cropping (e.g. if cropping the width, take 50% off | |
of the left side, and therefore 50% off the right side). | |
(0.0, 0.0) will crop from the top left corner (i.e. if | |
cropping the width, take all of the crop off of the right | |
side, and if cropping the height, take all of it off the | |
bottom). (1.0, 0.0) will crop from the bottom left | |
corner, etc. (i.e. if cropping the width, take all of the | |
crop off the left side, and if cropping the height take | |
none from the top, and therefore all off the bottom). | |
:return: An image. | |
""" | |
# by Kevin Cazabon, Feb 17/2000 | |
# [email protected] | |
# https://www.cazabon.com | |
centering_x, centering_y = centering | |
if not 0.0 <= centering_x <= 1.0: | |
centering_x = 0.5 | |
if not 0.0 <= centering_y <= 1.0: | |
centering_y = 0.5 | |
if not 0.0 <= bleed < 0.5: | |
bleed = 0.0 | |
# calculate the area to use for resizing and cropping, subtracting | |
# the 'bleed' around the edges | |
# number of pixels to trim off on Top and Bottom, Left and Right | |
bleed_pixels = (bleed * image.size[0], bleed * image.size[1]) | |
live_size = ( | |
image.size[0] - bleed_pixels[0] * 2, | |
image.size[1] - bleed_pixels[1] * 2, | |
) | |
# calculate the aspect ratio of the live_size | |
live_size_ratio = live_size[0] / live_size[1] | |
# calculate the aspect ratio of the output image | |
output_ratio = size[0] / size[1] | |
# figure out if the sides or top/bottom will be cropped off | |
if live_size_ratio == output_ratio: | |
# live_size is already the needed ratio | |
crop_width = live_size[0] | |
crop_height = live_size[1] | |
elif live_size_ratio >= output_ratio: | |
# live_size is wider than what's needed, crop the sides | |
crop_width = output_ratio * live_size[1] | |
crop_height = live_size[1] | |
else: | |
# live_size is taller than what's needed, crop the top and bottom | |
crop_width = live_size[0] | |
crop_height = live_size[0] / output_ratio | |
# make the crop | |
crop_left = bleed_pixels[0] + (live_size[0] - crop_width) * centering_x | |
crop_top = bleed_pixels[1] + (live_size[1] - crop_height) * centering_y | |
crop = (crop_left, crop_top, crop_left + crop_width, crop_top + crop_height) | |
# resize the image and return it | |
return image.resize(size, method, box=crop) | |
def flip(image: Image.Image) -> Image.Image: | |
""" | |
Flip the image vertically (top to bottom). | |
:param image: The image to flip. | |
:return: An image. | |
""" | |
return image.transpose(Image.Transpose.FLIP_TOP_BOTTOM) | |
def grayscale(image: Image.Image) -> Image.Image: | |
""" | |
Convert the image to grayscale. | |
:param image: The image to convert. | |
:return: An image. | |
""" | |
return image.convert("L") | |
def invert(image: Image.Image) -> Image.Image: | |
""" | |
Invert (negate) the image. | |
:param image: The image to invert. | |
:return: An image. | |
""" | |
lut = list(range(255, -1, -1)) | |
return image.point(lut) if image.mode == "1" else _lut(image, lut) | |
def mirror(image: Image.Image) -> Image.Image: | |
""" | |
Flip image horizontally (left to right). | |
:param image: The image to mirror. | |
:return: An image. | |
""" | |
return image.transpose(Image.Transpose.FLIP_LEFT_RIGHT) | |
def posterize(image: Image.Image, bits: int) -> Image.Image: | |
""" | |
Reduce the number of bits for each color channel. | |
:param image: The image to posterize. | |
:param bits: The number of bits to keep for each channel (1-8). | |
:return: An image. | |
""" | |
mask = ~(2 ** (8 - bits) - 1) | |
lut = [i & mask for i in range(256)] | |
return _lut(image, lut) | |
def solarize(image: Image.Image, threshold: int = 128) -> Image.Image: | |
""" | |
Invert all pixel values above a threshold. | |
:param image: The image to solarize. | |
:param threshold: All pixels above this grayscale level are inverted. | |
:return: An image. | |
""" | |
lut = [] | |
for i in range(256): | |
if i < threshold: | |
lut.append(i) | |
else: | |
lut.append(255 - i) | |
return _lut(image, lut) | |
def exif_transpose(image: Image.Image, *, in_place: bool = False) -> Image.Image | None: | |
""" | |
If an image has an EXIF Orientation tag, other than 1, transpose the image | |
accordingly, and remove the orientation data. | |
:param image: The image to transpose. | |
:param in_place: Boolean. Keyword-only argument. | |
If ``True``, the original image is modified in-place, and ``None`` is returned. | |
If ``False`` (default), a new :py:class:`~PIL.Image.Image` object is returned | |
with the transposition applied. If there is no transposition, a copy of the | |
image will be returned. | |
""" | |
image.load() | |
image_exif = image.getexif() | |
orientation = image_exif.get(ExifTags.Base.Orientation, 1) | |
method = { | |
2: Image.Transpose.FLIP_LEFT_RIGHT, | |
3: Image.Transpose.ROTATE_180, | |
4: Image.Transpose.FLIP_TOP_BOTTOM, | |
5: Image.Transpose.TRANSPOSE, | |
6: Image.Transpose.ROTATE_270, | |
7: Image.Transpose.TRANSVERSE, | |
8: Image.Transpose.ROTATE_90, | |
}.get(orientation) | |
if method is not None: | |
transposed_image = image.transpose(method) | |
if in_place: | |
image.im = transposed_image.im | |
image.pyaccess = None | |
image._size = transposed_image._size | |
exif_image = image if in_place else transposed_image | |
exif = exif_image.getexif() | |
if ExifTags.Base.Orientation in exif: | |
del exif[ExifTags.Base.Orientation] | |
if "exif" in exif_image.info: | |
exif_image.info["exif"] = exif.tobytes() | |
elif "Raw profile type exif" in exif_image.info: | |
exif_image.info["Raw profile type exif"] = exif.tobytes().hex() | |
for key in ("XML:com.adobe.xmp", "xmp"): | |
if key in exif_image.info: | |
for pattern in ( | |
r'tiff:Orientation="([0-9])"', | |
r"<tiff:Orientation>([0-9])</tiff:Orientation>", | |
): | |
value = exif_image.info[key] | |
exif_image.info[key] = ( | |
re.sub(pattern, "", value) | |
if isinstance(value, str) | |
else re.sub(pattern.encode(), b"", value) | |
) | |
if not in_place: | |
return transposed_image | |
elif not in_place: | |
return image.copy() | |
return None | |