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# Copyright (c) OpenMMLab. All rights reserved. | |
import cv2 | |
import numpy as np | |
from ..utils import is_tuple_of | |
from .colorspace import bgr2gray, gray2bgr | |
def imnormalize(img, mean, std, to_rgb=True): | |
"""Normalize an image with mean and std. | |
Args: | |
img (ndarray): Image to be normalized. | |
mean (ndarray): The mean to be used for normalize. | |
std (ndarray): The std to be used for normalize. | |
to_rgb (bool): Whether to convert to rgb. | |
Returns: | |
ndarray: The normalized image. | |
""" | |
img = img.copy().astype(np.float32) | |
return imnormalize_(img, mean, std, to_rgb) | |
def imnormalize_(img, mean, std, to_rgb=True): | |
"""Inplace normalize an image with mean and std. | |
Args: | |
img (ndarray): Image to be normalized. | |
mean (ndarray): The mean to be used for normalize. | |
std (ndarray): The std to be used for normalize. | |
to_rgb (bool): Whether to convert to rgb. | |
Returns: | |
ndarray: The normalized image. | |
""" | |
# cv2 inplace normalization does not accept uint8 | |
assert img.dtype != np.uint8 | |
mean = np.float64(mean.reshape(1, -1)) | |
stdinv = 1 / np.float64(std.reshape(1, -1)) | |
if to_rgb: | |
cv2.cvtColor(img, cv2.COLOR_BGR2RGB, img) # inplace | |
cv2.subtract(img, mean, img) # inplace | |
cv2.multiply(img, stdinv, img) # inplace | |
return img | |
def imdenormalize(img, mean, std, to_bgr=True): | |
assert img.dtype != np.uint8 | |
mean = mean.reshape(1, -1).astype(np.float64) | |
std = std.reshape(1, -1).astype(np.float64) | |
img = cv2.multiply(img, std) # make a copy | |
cv2.add(img, mean, img) # inplace | |
if to_bgr: | |
cv2.cvtColor(img, cv2.COLOR_RGB2BGR, img) # inplace | |
return img | |
def iminvert(img): | |
"""Invert (negate) an image. | |
Args: | |
img (ndarray): Image to be inverted. | |
Returns: | |
ndarray: The inverted image. | |
""" | |
return np.full_like(img, 255) - img | |
def solarize(img, thr=128): | |
"""Solarize an image (invert all pixel values above a threshold) | |
Args: | |
img (ndarray): Image to be solarized. | |
thr (int): Threshold for solarizing (0 - 255). | |
Returns: | |
ndarray: The solarized image. | |
""" | |
img = np.where(img < thr, img, 255 - img) | |
return img | |
def posterize(img, bits): | |
"""Posterize an image (reduce the number of bits for each color channel) | |
Args: | |
img (ndarray): Image to be posterized. | |
bits (int): Number of bits (1 to 8) to use for posterizing. | |
Returns: | |
ndarray: The posterized image. | |
""" | |
shift = 8 - bits | |
img = np.left_shift(np.right_shift(img, shift), shift) | |
return img | |
def adjust_color(img, alpha=1, beta=None, gamma=0): | |
r"""It blends the source image and its gray image: | |
.. math:: | |
output = img * alpha + gray\_img * beta + gamma | |
Args: | |
img (ndarray): The input source image. | |
alpha (int | float): Weight for the source image. Default 1. | |
beta (int | float): Weight for the converted gray image. | |
If None, it's assigned the value (1 - `alpha`). | |
gamma (int | float): Scalar added to each sum. | |
Same as :func:`cv2.addWeighted`. Default 0. | |
Returns: | |
ndarray: Colored image which has the same size and dtype as input. | |
""" | |
gray_img = bgr2gray(img) | |
gray_img = np.tile(gray_img[..., None], [1, 1, 3]) | |
if beta is None: | |
beta = 1 - alpha | |
colored_img = cv2.addWeighted(img, alpha, gray_img, beta, gamma) | |
if not colored_img.dtype == np.uint8: | |
# Note when the dtype of `img` is not the default `np.uint8` | |
# (e.g. np.float32), the value in `colored_img` got from cv2 | |
# is not guaranteed to be in range [0, 255], so here clip | |
# is needed. | |
colored_img = np.clip(colored_img, 0, 255) | |
return colored_img | |
def imequalize(img): | |
"""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. | |
Args: | |
img (ndarray): Image to be equalized. | |
Returns: | |
ndarray: The equalized image. | |
""" | |
def _scale_channel(im, c): | |
"""Scale the data in the corresponding channel.""" | |
im = im[:, :, c] | |
# Compute the histogram of the image channel. | |
histo = np.histogram(im, 256, (0, 255))[0] | |
# For computing the step, filter out the nonzeros. | |
nonzero_histo = histo[histo > 0] | |
step = (np.sum(nonzero_histo) - nonzero_histo[-1]) // 255 | |
if not step: | |
lut = np.array(range(256)) | |
else: | |
# Compute the cumulative sum, shifted by step // 2 | |
# and then normalized by step. | |
lut = (np.cumsum(histo) + (step // 2)) // step | |
# Shift lut, prepending with 0. | |
lut = np.concatenate([[0], lut[:-1]], 0) | |
# handle potential integer overflow | |
lut[lut > 255] = 255 | |
# If step is zero, return the original image. | |
# Otherwise, index from lut. | |
return np.where(np.equal(step, 0), im, lut[im]) | |
# Scales each channel independently and then stacks | |
# the result. | |
s1 = _scale_channel(img, 0) | |
s2 = _scale_channel(img, 1) | |
s3 = _scale_channel(img, 2) | |
equalized_img = np.stack([s1, s2, s3], axis=-1) | |
return equalized_img.astype(img.dtype) | |
def adjust_brightness(img, factor=1.): | |
"""Adjust image brightness. | |
This function controls the brightness of an image. An | |
enhancement factor of 0.0 gives a black image. | |
A factor of 1.0 gives the original image. This function | |
blends the source image and the degenerated black image: | |
.. math:: | |
output = img * factor + degenerated * (1 - factor) | |
Args: | |
img (ndarray): Image to be brightened. | |
factor (float): A value controls the enhancement. | |
Factor 1.0 returns the original image, lower | |
factors mean less color (brightness, contrast, | |
etc), and higher values more. Default 1. | |
Returns: | |
ndarray: The brightened image. | |
""" | |
degenerated = np.zeros_like(img) | |
# Note manually convert the dtype to np.float32, to | |
# achieve as close results as PIL.ImageEnhance.Brightness. | |
# Set beta=1-factor, and gamma=0 | |
brightened_img = cv2.addWeighted( | |
img.astype(np.float32), factor, degenerated.astype(np.float32), | |
1 - factor, 0) | |
brightened_img = np.clip(brightened_img, 0, 255) | |
return brightened_img.astype(img.dtype) | |
def adjust_contrast(img, factor=1.): | |
"""Adjust image contrast. | |
This function controls the contrast of an image. An | |
enhancement factor of 0.0 gives a solid grey | |
image. A factor of 1.0 gives the original image. It | |
blends the source image and the degenerated mean image: | |
.. math:: | |
output = img * factor + degenerated * (1 - factor) | |
Args: | |
img (ndarray): Image to be contrasted. BGR order. | |
factor (float): Same as :func:`mmcv.adjust_brightness`. | |
Returns: | |
ndarray: The contrasted image. | |
""" | |
gray_img = bgr2gray(img) | |
hist = np.histogram(gray_img, 256, (0, 255))[0] | |
mean = round(np.sum(gray_img) / np.sum(hist)) | |
degenerated = (np.ones_like(img[..., 0]) * mean).astype(img.dtype) | |
degenerated = gray2bgr(degenerated) | |
contrasted_img = cv2.addWeighted( | |
img.astype(np.float32), factor, degenerated.astype(np.float32), | |
1 - factor, 0) | |
contrasted_img = np.clip(contrasted_img, 0, 255) | |
return contrasted_img.astype(img.dtype) | |
def auto_contrast(img, cutoff=0): | |
"""Auto adjust image contrast. | |
This function maximize (normalize) image contrast by first removing cutoff | |
percent of the lightest and darkest pixels from the histogram and remapping | |
the image so that the darkest pixel becomes black (0), and the lightest | |
becomes white (255). | |
Args: | |
img (ndarray): Image to be contrasted. BGR order. | |
cutoff (int | float | tuple): The cutoff percent of the lightest and | |
darkest pixels to be removed. If given as tuple, it shall be | |
(low, high). Otherwise, the single value will be used for both. | |
Defaults to 0. | |
Returns: | |
ndarray: The contrasted image. | |
""" | |
def _auto_contrast_channel(im, c, cutoff): | |
im = im[:, :, c] | |
# Compute the histogram of the image channel. | |
histo = np.histogram(im, 256, (0, 255))[0] | |
# Remove cut-off percent pixels from histo | |
histo_sum = np.cumsum(histo) | |
cut_low = histo_sum[-1] * cutoff[0] // 100 | |
cut_high = histo_sum[-1] - histo_sum[-1] * cutoff[1] // 100 | |
histo_sum = np.clip(histo_sum, cut_low, cut_high) - cut_low | |
histo = np.concatenate([[histo_sum[0]], np.diff(histo_sum)], 0) | |
# Compute mapping | |
low, high = np.nonzero(histo)[0][0], np.nonzero(histo)[0][-1] | |
# If all the values have been cut off, return the origin img | |
if low >= high: | |
return im | |
scale = 255.0 / (high - low) | |
offset = -low * scale | |
lut = np.array(range(256)) | |
lut = lut * scale + offset | |
lut = np.clip(lut, 0, 255) | |
return lut[im] | |
if isinstance(cutoff, (int, float)): | |
cutoff = (cutoff, cutoff) | |
else: | |
assert isinstance(cutoff, tuple), 'cutoff must be of type int, ' \ | |
f'float or tuple, but got {type(cutoff)} instead.' | |
# Auto adjusts contrast for each channel independently and then stacks | |
# the result. | |
s1 = _auto_contrast_channel(img, 0, cutoff) | |
s2 = _auto_contrast_channel(img, 1, cutoff) | |
s3 = _auto_contrast_channel(img, 2, cutoff) | |
contrasted_img = np.stack([s1, s2, s3], axis=-1) | |
return contrasted_img.astype(img.dtype) | |
def adjust_sharpness(img, factor=1., kernel=None): | |
"""Adjust image sharpness. | |
This function controls the sharpness of an image. An | |
enhancement factor of 0.0 gives a blurred image. A | |
factor of 1.0 gives the original image. And a factor | |
of 2.0 gives a sharpened image. It blends the source | |
image and the degenerated mean image: | |
.. math:: | |
output = img * factor + degenerated * (1 - factor) | |
Args: | |
img (ndarray): Image to be sharpened. BGR order. | |
factor (float): Same as :func:`mmcv.adjust_brightness`. | |
kernel (np.ndarray, optional): Filter kernel to be applied on the img | |
to obtain the degenerated img. Defaults to None. | |
Note: | |
No value sanity check is enforced on the kernel set by users. So with | |
an inappropriate kernel, the ``adjust_sharpness`` may fail to perform | |
the function its name indicates but end up performing whatever | |
transform determined by the kernel. | |
Returns: | |
ndarray: The sharpened image. | |
""" | |
if kernel is None: | |
# adopted from PIL.ImageFilter.SMOOTH | |
kernel = np.array([[1., 1., 1.], [1., 5., 1.], [1., 1., 1.]]) / 13 | |
assert isinstance(kernel, np.ndarray), \ | |
f'kernel must be of type np.ndarray, but got {type(kernel)} instead.' | |
assert kernel.ndim == 2, \ | |
f'kernel must have a dimension of 2, but got {kernel.ndim} instead.' | |
degenerated = cv2.filter2D(img, -1, kernel) | |
sharpened_img = cv2.addWeighted( | |
img.astype(np.float32), factor, degenerated.astype(np.float32), | |
1 - factor, 0) | |
sharpened_img = np.clip(sharpened_img, 0, 255) | |
return sharpened_img.astype(img.dtype) | |
def adjust_lighting(img, eigval, eigvec, alphastd=0.1, to_rgb=True): | |
"""AlexNet-style PCA jitter. | |
This data augmentation is proposed in `ImageNet Classification with Deep | |
Convolutional Neural Networks | |
<https://dl.acm.org/doi/pdf/10.1145/3065386>`_. | |
Args: | |
img (ndarray): Image to be adjusted lighting. BGR order. | |
eigval (ndarray): the eigenvalue of the convariance matrix of pixel | |
values, respectively. | |
eigvec (ndarray): the eigenvector of the convariance matrix of pixel | |
values, respectively. | |
alphastd (float): The standard deviation for distribution of alpha. | |
Defaults to 0.1 | |
to_rgb (bool): Whether to convert img to rgb. | |
Returns: | |
ndarray: The adjusted image. | |
""" | |
assert isinstance(eigval, np.ndarray) and isinstance(eigvec, np.ndarray), \ | |
f'eigval and eigvec should both be of type np.ndarray, got ' \ | |
f'{type(eigval)} and {type(eigvec)} instead.' | |
assert eigval.ndim == 1 and eigvec.ndim == 2 | |
assert eigvec.shape == (3, eigval.shape[0]) | |
n_eigval = eigval.shape[0] | |
assert isinstance(alphastd, float), 'alphastd should be of type float, ' \ | |
f'got {type(alphastd)} instead.' | |
img = img.copy().astype(np.float32) | |
if to_rgb: | |
cv2.cvtColor(img, cv2.COLOR_BGR2RGB, img) # inplace | |
alpha = np.random.normal(0, alphastd, n_eigval) | |
alter = eigvec \ | |
* np.broadcast_to(alpha.reshape(1, n_eigval), (3, n_eigval)) \ | |
* np.broadcast_to(eigval.reshape(1, n_eigval), (3, n_eigval)) | |
alter = np.broadcast_to(alter.sum(axis=1).reshape(1, 1, 3), img.shape) | |
img_adjusted = img + alter | |
return img_adjusted | |
def lut_transform(img, lut_table): | |
"""Transform array by look-up table. | |
The function lut_transform fills the output array with values from the | |
look-up table. Indices of the entries are taken from the input array. | |
Args: | |
img (ndarray): Image to be transformed. | |
lut_table (ndarray): look-up table of 256 elements; in case of | |
multi-channel input array, the table should either have a single | |
channel (in this case the same table is used for all channels) or | |
the same number of channels as in the input array. | |
Returns: | |
ndarray: The transformed image. | |
""" | |
assert isinstance(img, np.ndarray) | |
assert 0 <= np.min(img) and np.max(img) <= 255 | |
assert isinstance(lut_table, np.ndarray) | |
assert lut_table.shape == (256, ) | |
return cv2.LUT(np.array(img, dtype=np.uint8), lut_table) | |
def clahe(img, clip_limit=40.0, tile_grid_size=(8, 8)): | |
"""Use CLAHE method to process the image. | |
See `ZUIDERVELD,K. Contrast Limited Adaptive Histogram Equalization[J]. | |
Graphics Gems, 1994:474-485.` for more information. | |
Args: | |
img (ndarray): Image to be processed. | |
clip_limit (float): Threshold for contrast limiting. Default: 40.0. | |
tile_grid_size (tuple[int]): Size of grid for histogram equalization. | |
Input image will be divided into equally sized rectangular tiles. | |
It defines the number of tiles in row and column. Default: (8, 8). | |
Returns: | |
ndarray: The processed image. | |
""" | |
assert isinstance(img, np.ndarray) | |
assert img.ndim == 2 | |
assert isinstance(clip_limit, (float, int)) | |
assert is_tuple_of(tile_grid_size, int) | |
assert len(tile_grid_size) == 2 | |
clahe = cv2.createCLAHE(clip_limit, tile_grid_size) | |
return clahe.apply(np.array(img, dtype=np.uint8)) | |