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CodeFormer-master / basicsr /data /gaussian_kernels.py
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import math
import numpy as np
import random
from scipy.ndimage.interpolation import shift
from scipy.stats import multivariate_normal
def sigma_matrix2(sig_x, sig_y, theta):
 """Calculate the rotated sigma matrix (two dimensional matrix).
 Args:
 sig_x (float):
 sig_y (float):
 theta (float): Radian measurement.
 Returns:
 ndarray: Rotated sigma matrix.
 """
 D = np.array([[sig_x**2, 0], [0, sig_y**2]])
 U = np.array([[np.cos(theta), -np.sin(theta)],
 [np.sin(theta), np.cos(theta)]])
 return np.dot(U, np.dot(D, U.T))
def mesh_grid(kernel_size):
 """Generate the mesh grid, centering at zero.
 Args:
 kernel_size (int):
 Returns:
 xy (ndarray): with the shape (kernel_size, kernel_size, 2)
 xx (ndarray): with the shape (kernel_size, kernel_size)
 yy (ndarray): with the shape (kernel_size, kernel_size)
 """
 ax = np.arange(-kernel_size // 2 + 1., kernel_size // 2 + 1.)
 xx, yy = np.meshgrid(ax, ax)
 xy = np.hstack((xx.reshape((kernel_size * kernel_size, 1)),
 yy.reshape(kernel_size * kernel_size,
 1))).reshape(kernel_size, kernel_size, 2)
 return xy, xx, yy
def pdf2(sigma_matrix, grid):
 """Calculate PDF of the bivariate Gaussian distribution.
 Args:
 sigma_matrix (ndarray): with the shape (2, 2)
 grid (ndarray): generated by :func:`mesh_grid`,
 with the shape (K, K, 2), K is the kernel size.
 Returns:
 kernel (ndarrray): un-normalized kernel.
 """
 inverse_sigma = np.linalg.inv(sigma_matrix)
 kernel = np.exp(-0.5 * np.sum(np.dot(grid, inverse_sigma) * grid, 2))
 return kernel
def cdf2(D, grid):
 """Calculate the CDF of the standard bivariate Gaussian distribution.
 Used in skewed Gaussian distribution.
 Args:
 D (ndarrasy): skew matrix.
 grid (ndarray): generated by :func:`mesh_grid`,
 with the shape (K, K, 2), K is the kernel size.
 Returns:
 cdf (ndarray): skewed cdf.
 """
 rv = multivariate_normal([0, 0], [[1, 0], [0, 1]])
 grid = np.dot(grid, D)
 cdf = rv.cdf(grid)
 return cdf
def bivariate_skew_Gaussian(kernel_size, sig_x, sig_y, theta, D, grid=None):
 """Generate a bivariate skew Gaussian kernel.
 Described in `A multivariate skew normal distribution`_ by Shi et. al (2004).
 Args:
 kernel_size (int):
 sig_x (float):
 sig_y (float):
 theta (float): Radian measurement.
 D (ndarrasy): skew matrix.
 grid (ndarray, optional): generated by :func:`mesh_grid`,
 with the shape (K, K, 2), K is the kernel size. Default: None
 Returns:
 kernel (ndarray): normalized kernel.
 .. _A multivariate skew normal distribution:
 https://www.sciencedirect.com/science/article/pii/S0047259X03001313
 """
 if grid is None:
 grid, _, _ = mesh_grid(kernel_size)
 sigma_matrix = sigma_matrix2(sig_x, sig_y, theta)
 pdf = pdf2(sigma_matrix, grid)
 cdf = cdf2(D, grid)
 kernel = pdf * cdf
 kernel = kernel / np.sum(kernel)
 return kernel
def mass_center_shift(kernel_size, kernel):
 """Calculate the shift of the mass center of a kenrel.
 Args:
 kernel_size (int):
 kernel (ndarray): normalized kernel.
 Returns:
 delta_h (float):
 delta_w (float):
 """
 ax = np.arange(-kernel_size // 2 + 1., kernel_size // 2 + 1.)
 col_sum, row_sum = np.sum(kernel, axis=0), np.sum(kernel, axis=1)
 delta_h = np.dot(row_sum, ax)
 delta_w = np.dot(col_sum, ax)
 return delta_h, delta_w
def bivariate_skew_Gaussian_center(kernel_size,
 sig_x,
 sig_y,
 theta,
 D,
 grid=None):
 """Generate a bivariate skew Gaussian kernel at center. Shift with nearest padding.
 Args:
 kernel_size (int):
 sig_x (float):
 sig_y (float):
 theta (float): Radian measurement.
 D (ndarrasy): skew matrix.
 grid (ndarray, optional): generated by :func:`mesh_grid`,
 with the shape (K, K, 2), K is the kernel size. Default: None
 Returns:
 kernel (ndarray): centered and normalized kernel.
 """
 if grid is None:
 grid, _, _ = mesh_grid(kernel_size)
 kernel = bivariate_skew_Gaussian(kernel_size, sig_x, sig_y, theta, D, grid)
 delta_h, delta_w = mass_center_shift(kernel_size, kernel)
 kernel = shift(kernel, [-delta_h, -delta_w], mode='nearest')
 kernel = kernel / np.sum(kernel)
 return kernel
def bivariate_anisotropic_Gaussian(kernel_size,
 sig_x,
 sig_y,
 theta,
 grid=None):
 """Generate a bivariate anisotropic Gaussian kernel.
 Args:
 kernel_size (int):
 sig_x (float):
 sig_y (float):
 theta (float): Radian measurement.
 grid (ndarray, optional): generated by :func:`mesh_grid`,
 with the shape (K, K, 2), K is the kernel size. Default: None
 Returns:
 kernel (ndarray): normalized kernel.
 """
 if grid is None:
 grid, _, _ = mesh_grid(kernel_size)
 sigma_matrix = sigma_matrix2(sig_x, sig_y, theta)
 kernel = pdf2(sigma_matrix, grid)
 kernel = kernel / np.sum(kernel)
 return kernel
def bivariate_isotropic_Gaussian(kernel_size, sig, grid=None):
 """Generate a bivariate isotropic Gaussian kernel.
 Args:
 kernel_size (int):
 sig (float):
 grid (ndarray, optional): generated by :func:`mesh_grid`,
 with the shape (K, K, 2), K is the kernel size. Default: None
 Returns:
 kernel (ndarray): normalized kernel.
 """
 if grid is None:
 grid, _, _ = mesh_grid(kernel_size)
 sigma_matrix = np.array([[sig**2, 0], [0, sig**2]])
 kernel = pdf2(sigma_matrix, grid)
 kernel = kernel / np.sum(kernel)
 return kernel
def bivariate_generalized_Gaussian(kernel_size,
 sig_x,
 sig_y,
 theta,
 beta,
 grid=None):
 """Generate a bivariate generalized Gaussian kernel.
 Described in `Parameter Estimation For Multivariate Generalized Gaussian Distributions`_
 by Pascal et. al (2013).
 Args:
 kernel_size (int):
 sig_x (float):
 sig_y (float):
 theta (float): Radian measurement.
 beta (float): shape parameter, beta = 1 is the normal distribution.
 grid (ndarray, optional): generated by :func:`mesh_grid`,
 with the shape (K, K, 2), K is the kernel size. Default: None
 Returns:
 kernel (ndarray): normalized kernel.
 .. _Parameter Estimation For Multivariate Generalized Gaussian Distributions:
 https://arxiv.org/abs/1302.6498
 """
 if grid is None:
 grid, _, _ = mesh_grid(kernel_size)
 sigma_matrix = sigma_matrix2(sig_x, sig_y, theta)
 inverse_sigma = np.linalg.inv(sigma_matrix)
 kernel = np.exp(
 -0.5 * np.power(np.sum(np.dot(grid, inverse_sigma) * grid, 2), beta))
 kernel = kernel / np.sum(kernel)
 return kernel
def bivariate_plateau_type1(kernel_size, sig_x, sig_y, theta, beta, grid=None):
 """Generate a plateau-like anisotropic kernel.
 1 / (1+x^(beta))
 Args:
 kernel_size (int):
 sig_x (float):
 sig_y (float):
 theta (float): Radian measurement.
 beta (float): shape parameter, beta = 1 is the normal distribution.
 grid (ndarray, optional): generated by :func:`mesh_grid`,
 with the shape (K, K, 2), K is the kernel size. Default: None
 Returns:
 kernel (ndarray): normalized kernel.
 """
 if grid is None:
 grid, _, _ = mesh_grid(kernel_size)
 sigma_matrix = sigma_matrix2(sig_x, sig_y, theta)
 inverse_sigma = np.linalg.inv(sigma_matrix)
 kernel = np.reciprocal(
 np.power(np.sum(np.dot(grid, inverse_sigma) * grid, 2), beta) + 1)
 kernel = kernel / np.sum(kernel)
 return kernel
def bivariate_plateau_type1_iso(kernel_size, sig, beta, grid=None):
 """Generate a plateau-like isotropic kernel.
 1 / (1+x^(beta))
 Args:
 kernel_size (int):
 sig (float):
 beta (float): shape parameter, beta = 1 is the normal distribution.
 grid (ndarray, optional): generated by :func:`mesh_grid`,
 with the shape (K, K, 2), K is the kernel size. Default: None
 Returns:
 kernel (ndarray): normalized kernel.
 """
 if grid is None:
 grid, _, _ = mesh_grid(kernel_size)
 sigma_matrix = np.array([[sig**2, 0], [0, sig**2]])
 inverse_sigma = np.linalg.inv(sigma_matrix)
 kernel = np.reciprocal(
 np.power(np.sum(np.dot(grid, inverse_sigma) * grid, 2), beta) + 1)
 kernel = kernel / np.sum(kernel)
 return kernel
def random_bivariate_skew_Gaussian_center(kernel_size,
 sigma_x_range,
 sigma_y_range,
 rotation_range,
 noise_range=None,
 strict=False):
 """Randomly generate bivariate skew Gaussian kernels at center.
 Args:
 kernel_size (int):
 sigma_x_range (tuple): [0.6, 5]
 sigma_y_range (tuple): [0.6, 5]
 rotation range (tuple): [-math.pi, math.pi]
 noise_range(tuple, optional): multiplicative kernel noise, [0.75, 1.25]. Default: None
 Returns:
 kernel (ndarray):
 """
 assert kernel_size % 2 == 1, 'Kernel size must be an odd number.'
 assert sigma_x_range[0] < sigma_x_range[1], 'Wrong sigma_x_range.'
 assert sigma_y_range[0] < sigma_y_range[1], 'Wrong sigma_y_range.'
 assert rotation_range[0] < rotation_range[1], 'Wrong rotation_range.'
 sigma_x = np.random.uniform(sigma_x_range[0], sigma_x_range[1])
 sigma_y = np.random.uniform(sigma_y_range[0], sigma_y_range[1])
 if strict:
 sigma_max = np.max([sigma_x, sigma_y])
 sigma_min = np.min([sigma_x, sigma_y])
 sigma_x, sigma_y = sigma_max, sigma_min
 rotation = np.random.uniform(rotation_range[0], rotation_range[1])
sigma_max = np.max([sigma_x, sigma_y])
 thres = 3 / sigma_max
 D = [[np.random.uniform(-thres, thres),
 np.random.uniform(-thres, thres)],
 [np.random.uniform(-thres, thres),
 np.random.uniform(-thres, thres)]]
kernel = bivariate_skew_Gaussian_center(kernel_size, sigma_x, sigma_y,
 rotation, D)
# add multiplicative noise
 if noise_range is not None:
 assert noise_range[0] < noise_range[1], 'Wrong noise range.'
 noise = np.random.uniform(
 noise_range[0], noise_range[1], size=kernel.shape)
 kernel = kernel * noise
 kernel = kernel / np.sum(kernel)
 if strict:
 return kernel, sigma_x, sigma_y, rotation, D
 else:
 return kernel
def random_bivariate_anisotropic_Gaussian(kernel_size,
 sigma_x_range,
 sigma_y_range,
 rotation_range,
 noise_range=None,
 strict=False):
 """Randomly generate bivariate anisotropic Gaussian kernels.
 Args:
 kernel_size (int):
 sigma_x_range (tuple): [0.6, 5]
 sigma_y_range (tuple): [0.6, 5]
 rotation range (tuple): [-math.pi, math.pi]
 noise_range(tuple, optional): multiplicative kernel noise, [0.75, 1.25]. Default: None
 Returns:
 kernel (ndarray):
 """
 assert kernel_size % 2 == 1, 'Kernel size must be an odd number.'
 assert sigma_x_range[0] < sigma_x_range[1], 'Wrong sigma_x_range.'
 assert sigma_y_range[0] < sigma_y_range[1], 'Wrong sigma_y_range.'
 assert rotation_range[0] < rotation_range[1], 'Wrong rotation_range.'
 sigma_x = np.random.uniform(sigma_x_range[0], sigma_x_range[1])
 sigma_y = np.random.uniform(sigma_y_range[0], sigma_y_range[1])
 if strict:
 sigma_max = np.max([sigma_x, sigma_y])
 sigma_min = np.min([sigma_x, sigma_y])
 sigma_x, sigma_y = sigma_max, sigma_min
 rotation = np.random.uniform(rotation_range[0], rotation_range[1])
kernel = bivariate_anisotropic_Gaussian(kernel_size, sigma_x, sigma_y,
 rotation)
# add multiplicative noise
 if noise_range is not None:
 assert noise_range[0] < noise_range[1], 'Wrong noise range.'
 noise = np.random.uniform(
 noise_range[0], noise_range[1], size=kernel.shape)
 kernel = kernel * noise
 kernel = kernel / np.sum(kernel)
 if strict:
 return kernel, sigma_x, sigma_y, rotation
 else:
 return kernel
def random_bivariate_isotropic_Gaussian(kernel_size,
 sigma_range,
 noise_range=None,
 strict=False):
 """Randomly generate bivariate isotropic Gaussian kernels.
 Args:
 kernel_size (int):
 sigma_range (tuple): [0.6, 5]
 noise_range(tuple, optional): multiplicative kernel noise, [0.75, 1.25]. Default: None
 Returns:
 kernel (ndarray):
 """
 assert kernel_size % 2 == 1, 'Kernel size must be an odd number.'
 assert sigma_range[0] < sigma_range[1], 'Wrong sigma_x_range.'
 sigma = np.random.uniform(sigma_range[0], sigma_range[1])
kernel = bivariate_isotropic_Gaussian(kernel_size, sigma)
# add multiplicative noise
 if noise_range is not None:
 assert noise_range[0] < noise_range[1], 'Wrong noise range.'
 noise = np.random.uniform(
 noise_range[0], noise_range[1], size=kernel.shape)
 kernel = kernel * noise
 kernel = kernel / np.sum(kernel)
 if strict:
 return kernel, sigma
 else:
 return kernel
def random_bivariate_generalized_Gaussian(kernel_size,
 sigma_x_range,
 sigma_y_range,
 rotation_range,
 beta_range,
 noise_range=None,
 strict=False):
 """Randomly generate bivariate generalized Gaussian kernels.
 Args:
 kernel_size (int):
 sigma_x_range (tuple): [0.6, 5]
 sigma_y_range (tuple): [0.6, 5]
 rotation range (tuple): [-math.pi, math.pi]
 beta_range (tuple): [0.5, 8]
 noise_range(tuple, optional): multiplicative kernel noise, [0.75, 1.25]. Default: None
 Returns:
 kernel (ndarray):
 """
 assert kernel_size % 2 == 1, 'Kernel size must be an odd number.'
 assert sigma_x_range[0] < sigma_x_range[1], 'Wrong sigma_x_range.'
 assert sigma_y_range[0] < sigma_y_range[1], 'Wrong sigma_y_range.'
 assert rotation_range[0] < rotation_range[1], 'Wrong rotation_range.'
 sigma_x = np.random.uniform(sigma_x_range[0], sigma_x_range[1])
 sigma_y = np.random.uniform(sigma_y_range[0], sigma_y_range[1])
 if strict:
 sigma_max = np.max([sigma_x, sigma_y])
 sigma_min = np.min([sigma_x, sigma_y])
 sigma_x, sigma_y = sigma_max, sigma_min
 rotation = np.random.uniform(rotation_range[0], rotation_range[1])
 if np.random.uniform() < 0.5:
 beta = np.random.uniform(beta_range[0], 1)
 else:
 beta = np.random.uniform(1, beta_range[1])
kernel = bivariate_generalized_Gaussian(kernel_size, sigma_x, sigma_y,
 rotation, beta)
# add multiplicative noise
 if noise_range is not None:
 assert noise_range[0] < noise_range[1], 'Wrong noise range.'
 noise = np.random.uniform(
 noise_range[0], noise_range[1], size=kernel.shape)
 kernel = kernel * noise
 kernel = kernel / np.sum(kernel)
 if strict:
 return kernel, sigma_x, sigma_y, rotation, beta
 else:
 return kernel
def random_bivariate_plateau_type1(kernel_size,
 sigma_x_range,
 sigma_y_range,
 rotation_range,
 beta_range,
 noise_range=None,
 strict=False):
 """Randomly generate bivariate plateau type1 kernels.
 Args:
 kernel_size (int):
 sigma_x_range (tuple): [0.6, 5]
 sigma_y_range (tuple): [0.6, 5]
 rotation range (tuple): [-math.pi/2, math.pi/2]
 beta_range (tuple): [1, 4]
 noise_range(tuple, optional): multiplicative kernel noise, [0.75, 1.25]. Default: None
 Returns:
 kernel (ndarray):
 """
 assert kernel_size % 2 == 1, 'Kernel size must be an odd number.'
 assert sigma_x_range[0] < sigma_x_range[1], 'Wrong sigma_x_range.'
 assert sigma_y_range[0] < sigma_y_range[1], 'Wrong sigma_y_range.'
 assert rotation_range[0] < rotation_range[1], 'Wrong rotation_range.'
 sigma_x = np.random.uniform(sigma_x_range[0], sigma_x_range[1])
 sigma_y = np.random.uniform(sigma_y_range[0], sigma_y_range[1])
 if strict:
 sigma_max = np.max([sigma_x, sigma_y])
 sigma_min = np.min([sigma_x, sigma_y])
 sigma_x, sigma_y = sigma_max, sigma_min
 rotation = np.random.uniform(rotation_range[0], rotation_range[1])
 if np.random.uniform() < 0.5:
 beta = np.random.uniform(beta_range[0], 1)
 else:
 beta = np.random.uniform(1, beta_range[1])
kernel = bivariate_plateau_type1(kernel_size, sigma_x, sigma_y, rotation,
 beta)
# add multiplicative noise
 if noise_range is not None:
 assert noise_range[0] < noise_range[1], 'Wrong noise range.'
 noise = np.random.uniform(
 noise_range[0], noise_range[1], size=kernel.shape)
 kernel = kernel * noise
 kernel = kernel / np.sum(kernel)
 if strict:
 return kernel, sigma_x, sigma_y, rotation, beta
 else:
 return kernel
def random_bivariate_plateau_type1_iso(kernel_size,
 sigma_range,
 beta_range,
 noise_range=None,
 strict=False):
 """Randomly generate bivariate plateau type1 kernels (iso).
 Args:
 kernel_size (int):
 sigma_range (tuple): [0.6, 5]
 beta_range (tuple): [1, 4]
 noise_range(tuple, optional): multiplicative kernel noise, [0.75, 1.25]. Default: None
 Returns:
 kernel (ndarray):
 """
 assert kernel_size % 2 == 1, 'Kernel size must be an odd number.'
 assert sigma_range[0] < sigma_range[1], 'Wrong sigma_x_range.'
 sigma = np.random.uniform(sigma_range[0], sigma_range[1])
 beta = np.random.uniform(beta_range[0], beta_range[1])
kernel = bivariate_plateau_type1_iso(kernel_size, sigma, beta)
# add multiplicative noise
 if noise_range is not None:
 assert noise_range[0] < noise_range[1], 'Wrong noise range.'
 noise = np.random.uniform(
 noise_range[0], noise_range[1], size=kernel.shape)
 kernel = kernel * noise
 kernel = kernel / np.sum(kernel)
 if strict:
 return kernel, sigma, beta
 else:
 return kernel
def random_mixed_kernels(kernel_list,
 kernel_prob,
 kernel_size=21,
 sigma_x_range=[0.6, 5],
 sigma_y_range=[0.6, 5],
 rotation_range=[-math.pi, math.pi],
 beta_range=[0.5, 8],
 noise_range=None):
 """Randomly generate mixed kernels.
 Args:
 kernel_list (tuple): a list name of kenrel types,
 support ['iso', 'aniso', 'skew', 'generalized', 'plateau_iso', 'plateau_aniso']
 kernel_prob (tuple): corresponding kernel probability for each kernel type
 kernel_size (int):
 sigma_x_range (tuple): [0.6, 5]
 sigma_y_range (tuple): [0.6, 5]
 rotation range (tuple): [-math.pi, math.pi]
 beta_range (tuple): [0.5, 8]
 noise_range(tuple, optional): multiplicative kernel noise, [0.75, 1.25]. Default: None
 Returns:
 kernel (ndarray):
 """
 kernel_type = random.choices(kernel_list, kernel_prob)[0]
 if kernel_type == 'iso':
 kernel = random_bivariate_isotropic_Gaussian(
 kernel_size, sigma_x_range, noise_range=noise_range)
 elif kernel_type == 'aniso':
 kernel = random_bivariate_anisotropic_Gaussian(
 kernel_size,
 sigma_x_range,
 sigma_y_range,
 rotation_range,
 noise_range=noise_range)
 elif kernel_type == 'skew':
 kernel = random_bivariate_skew_Gaussian_center(
 kernel_size,
 sigma_x_range,
 sigma_y_range,
 rotation_range,
 noise_range=noise_range)
 elif kernel_type == 'generalized':
 kernel = random_bivariate_generalized_Gaussian(
 kernel_size,
 sigma_x_range,
 sigma_y_range,
 rotation_range,
 beta_range,
 noise_range=noise_range)
 elif kernel_type == 'plateau_iso':
 kernel = random_bivariate_plateau_type1_iso(
 kernel_size, sigma_x_range, beta_range, noise_range=noise_range)
 elif kernel_type == 'plateau_aniso':
 kernel = random_bivariate_plateau_type1(
 kernel_size,
 sigma_x_range,
 sigma_y_range,
 rotation_range,
 beta_range,
 noise_range=noise_range)
 # add multiplicative noise
 if noise_range is not None:
 assert noise_range[0] < noise_range[1], 'Wrong noise range.'
 noise = np.random.uniform(
 noise_range[0], noise_range[1], size=kernel.shape)
 kernel = kernel * noise
 kernel = kernel / np.sum(kernel)
 return kernel
def show_one_kernel():
 import matplotlib.pyplot as plt
 kernel_size = 21
# bivariate skew Gaussian
 D = [[0, 0], [0, 0]]
 D = [[3 / 4, 0], [0, 0.5]]
 kernel = bivariate_skew_Gaussian_center(kernel_size, 2, 4, -math.pi / 4, D)
 # bivariate anisotropic Gaussian
 kernel = bivariate_anisotropic_Gaussian(kernel_size, 2, 4, -math.pi / 4)
 # bivariate anisotropic Gaussian
 kernel = bivariate_isotropic_Gaussian(kernel_size, 1)
 # bivariate generalized Gaussian
 kernel = bivariate_generalized_Gaussian(
 kernel_size, 2, 4, -math.pi / 4, beta=4)
delta_h, delta_w = mass_center_shift(kernel_size, kernel)
 print(delta_h, delta_w)
fig, axs = plt.subplots(nrows=2, ncols=2)
 # axs.set_axis_off()
 ax = axs[0][0]
 im = ax.matshow(kernel, cmap='jet', origin='upper')
 fig.colorbar(im, ax=ax)
# image
 ax = axs[0][1]
 kernel_vis = kernel - np.min(kernel)
 kernel_vis = kernel_vis / np.max(kernel_vis) * 255.
 ax.imshow(kernel_vis, interpolation='nearest')
_, xx, yy = mesh_grid(kernel_size)
 # contour
 ax = axs[1][0]
 CS = ax.contour(xx, yy, kernel, origin='upper')
 ax.clabel(CS, inline=1, fontsize=3)
# contourf
 ax = axs[1][1]
 kernel = kernel / np.max(kernel)
 p = ax.contourf(
 xx, yy, kernel, origin='upper', levels=np.linspace(-0.05, 1.05, 10))
 fig.colorbar(p)
plt.show()
def show_plateau_kernel():
 import matplotlib.pyplot as plt
 kernel_size = 21
kernel = plateau_type1(kernel_size, 2, 4, -math.pi / 8, 2, grid=None)
 kernel_norm = bivariate_isotropic_Gaussian(kernel_size, 5)
 kernel_gau = bivariate_generalized_Gaussian(
 kernel_size, 2, 4, -math.pi / 8, 2, grid=None)
 delta_h, delta_w = mass_center_shift(kernel_size, kernel)
 print(delta_h, delta_w)
# kernel_slice = kernel[10, :]
 # kernel_gau_slice = kernel_gau[10, :]
 # kernel_norm_slice = kernel_norm[10, :]
 # fig, ax = plt.subplots()
 # t = list(range(1, 22))
# ax.plot(t, kernel_gau_slice)
 # ax.plot(t, kernel_slice)
 # ax.plot(t, kernel_norm_slice)
# t = np.arange(0, 10, 0.1)
 # y = np.exp(-0.5 * t)
 # y2 = np.reciprocal(1 + t)
 # print(t.shape)
 # print(y.shape)
 # ax.plot(t, y)
 # ax.plot(t, y2)
 # plt.show()
fig, axs = plt.subplots(nrows=2, ncols=2)
 # axs.set_axis_off()
 ax = axs[0][0]
 im = ax.matshow(kernel, cmap='jet', origin='upper')
 fig.colorbar(im, ax=ax)
# image
 ax = axs[0][1]
 kernel_vis = kernel - np.min(kernel)
 kernel_vis = kernel_vis / np.max(kernel_vis) * 255.
 ax.imshow(kernel_vis, interpolation='nearest')
_, xx, yy = mesh_grid(kernel_size)
 # contour
 ax = axs[1][0]
 CS = ax.contour(xx, yy, kernel, origin='upper')
 ax.clabel(CS, inline=1, fontsize=3)
# contourf
 ax = axs[1][1]
 kernel = kernel / np.max(kernel)
 p = ax.contourf(
 xx, yy, kernel, origin='upper', levels=np.linspace(-0.05, 1.05, 10))
 fig.colorbar(p)
plt.show()