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import torch |
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Tensor = torch.Tensor |
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Device = torch.DeviceObjType |
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Dtype = torch.Type |
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pad = torch.nn.functional.pad |
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def _compute_zero_padding(kernel_size: tuple[int, int] | int) -> tuple[int, int]: |
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ky, kx = _unpack_2d_ks(kernel_size) |
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return (ky - 1) // 2, (kx - 1) // 2 |
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def _unpack_2d_ks(kernel_size: tuple[int, int] | int) -> tuple[int, int]: |
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if isinstance(kernel_size, int): |
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ky = kx = kernel_size |
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else: |
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assert len(kernel_size) == 2, '2D Kernel size should have a length of 2.' |
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ky, kx = kernel_size |
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ky = int(ky) |
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kx = int(kx) |
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return ky, kx |
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def gaussian( |
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window_size: int, sigma: Tensor | float, *, device: Device | None = None, dtype: Dtype | None = None |
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) -> Tensor: |
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batch_size = sigma.shape[0] |
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x = (torch.arange(window_size, device=sigma.device, dtype=sigma.dtype) - window_size // 2).expand(batch_size, -1) |
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if window_size % 2 == 0: |
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x = x + 0.5 |
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gauss = torch.exp(-x.pow(2.0) / (2 * sigma.pow(2.0))) |
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return gauss / gauss.sum(-1, keepdim=True) |
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def get_gaussian_kernel1d( |
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kernel_size: int, |
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sigma: float | Tensor, |
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force_even: bool = False, |
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*, |
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device: Device | None = None, |
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dtype: Dtype | None = None, |
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) -> Tensor: |
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return gaussian(kernel_size, sigma, device=device, dtype=dtype) |
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def get_gaussian_kernel2d( |
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kernel_size: tuple[int, int] | int, |
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sigma: tuple[float, float] | Tensor, |
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force_even: bool = False, |
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*, |
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device: Device | None = None, |
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dtype: Dtype | None = None, |
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) -> Tensor: |
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sigma = torch.Tensor([[sigma, sigma]]).to(device=device, dtype=dtype) |
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ksize_y, ksize_x = _unpack_2d_ks(kernel_size) |
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sigma_y, sigma_x = sigma[:, 0, None], sigma[:, 1, None] |
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kernel_y = get_gaussian_kernel1d(ksize_y, sigma_y, force_even, device=device, dtype=dtype)[..., None] |
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kernel_x = get_gaussian_kernel1d(ksize_x, sigma_x, force_even, device=device, dtype=dtype)[..., None] |
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return kernel_y * kernel_x.view(-1, 1, ksize_x) |
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def _bilateral_blur( |
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input: Tensor, |
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guidance: Tensor | None, |
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kernel_size: tuple[int, int] | int, |
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sigma_color: float | Tensor, |
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sigma_space: tuple[float, float] | Tensor, |
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border_type: str = 'reflect', |
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color_distance_type: str = 'l1', |
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) -> Tensor: |
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if isinstance(sigma_color, Tensor): |
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sigma_color = sigma_color.to(device=input.device, dtype=input.dtype).view(-1, 1, 1, 1, 1) |
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ky, kx = _unpack_2d_ks(kernel_size) |
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pad_y, pad_x = _compute_zero_padding(kernel_size) |
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padded_input = pad(input, (pad_x, pad_x, pad_y, pad_y), mode=border_type) |
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unfolded_input = padded_input.unfold(2, ky, 1).unfold(3, kx, 1).flatten(-2) |
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if guidance is None: |
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guidance = input |
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unfolded_guidance = unfolded_input |
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else: |
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padded_guidance = pad(guidance, (pad_x, pad_x, pad_y, pad_y), mode=border_type) |
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unfolded_guidance = padded_guidance.unfold(2, ky, 1).unfold(3, kx, 1).flatten(-2) |
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diff = unfolded_guidance - guidance.unsqueeze(-1) |
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if color_distance_type == "l1": |
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color_distance_sq = diff.abs().sum(1, keepdim=True).square() |
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elif color_distance_type == "l2": |
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color_distance_sq = diff.square().sum(1, keepdim=True) |
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else: |
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raise ValueError("color_distance_type only acceps l1 or l2") |
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color_kernel = (-0.5 / sigma_color**2 * color_distance_sq).exp() |
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space_kernel = get_gaussian_kernel2d(kernel_size, sigma_space, device=input.device, dtype=input.dtype) |
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space_kernel = space_kernel.view(-1, 1, 1, 1, kx * ky) |
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kernel = space_kernel * color_kernel |
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out = (unfolded_input * kernel).sum(-1) / kernel.sum(-1) |
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return out |
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def bilateral_blur( |
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input: Tensor, |
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kernel_size: tuple[int, int] | int = (13, 13), |
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sigma_color: float | Tensor = 3.0, |
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sigma_space: tuple[float, float] | Tensor = 3.0, |
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border_type: str = 'reflect', |
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color_distance_type: str = 'l1', |
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) -> Tensor: |
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return _bilateral_blur(input, None, kernel_size, sigma_color, sigma_space, border_type, color_distance_type) |
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def adaptive_anisotropic_filter(x, g=None): |
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if g is None: |
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g = x |
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s, m = torch.std_mean(g, dim=(1, 2, 3), keepdim=True) |
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s = s + 1e-5 |
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guidance = (g - m) / s |
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y = _bilateral_blur(x, guidance, |
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kernel_size=(13, 13), |
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sigma_color=3.0, |
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sigma_space=3.0, |
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border_type='reflect', |
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color_distance_type='l1') |
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return y |
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def joint_bilateral_blur( |
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input: Tensor, |
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guidance: Tensor, |
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kernel_size: tuple[int, int] | int, |
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sigma_color: float | Tensor, |
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sigma_space: tuple[float, float] | Tensor, |
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border_type: str = 'reflect', |
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color_distance_type: str = 'l1', |
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) -> Tensor: |
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return _bilateral_blur(input, guidance, kernel_size, sigma_color, sigma_space, border_type, color_distance_type) |
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class _BilateralBlur(torch.nn.Module): |
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def __init__( |
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self, |
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kernel_size: tuple[int, int] | int, |
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sigma_color: float | Tensor, |
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sigma_space: tuple[float, float] | Tensor, |
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border_type: str = 'reflect', |
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color_distance_type: str = "l1", |
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) -> None: |
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super().__init__() |
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self.kernel_size = kernel_size |
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self.sigma_color = sigma_color |
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self.sigma_space = sigma_space |
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self.border_type = border_type |
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self.color_distance_type = color_distance_type |
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def __repr__(self) -> str: |
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return ( |
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f"{self.__class__.__name__}" |
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f"(kernel_size={self.kernel_size}, " |
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f"sigma_color={self.sigma_color}, " |
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f"sigma_space={self.sigma_space}, " |
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f"border_type={self.border_type}, " |
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f"color_distance_type={self.color_distance_type})" |
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) |
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class BilateralBlur(_BilateralBlur): |
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def forward(self, input: Tensor) -> Tensor: |
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return bilateral_blur( |
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input, self.kernel_size, self.sigma_color, self.sigma_space, self.border_type, self.color_distance_type |
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) |
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class JointBilateralBlur(_BilateralBlur): |
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def forward(self, input: Tensor, guidance: Tensor) -> Tensor: |
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return joint_bilateral_blur( |
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input, |
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guidance, |
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self.kernel_size, |
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self.sigma_color, |
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self.sigma_space, |
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self.border_type, |
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self.color_distance_type, |
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) |
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