156 lines
5.7 KiB
Python
156 lines
5.7 KiB
Python
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import torch
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import torch.fx
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import torch.nn.functional as F
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from torch import nn, Tensor
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from ..utils import _log_api_usage_once
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def drop_block2d(
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input: Tensor, p: float, block_size: int, inplace: bool = False, eps: float = 1e-06, training: bool = True
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) -> Tensor:
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"""
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Implements DropBlock2d from `"DropBlock: A regularization method for convolutional networks"
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<https://arxiv.org/abs/1810.12890>`.
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Args:
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input (Tensor[N, C, H, W]): The input tensor or 4-dimensions with the first one
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being its batch i.e. a batch with ``N`` rows.
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p (float): Probability of an element to be dropped.
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block_size (int): Size of the block to drop.
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inplace (bool): If set to ``True``, will do this operation in-place. Default: ``False``.
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eps (float): A value added to the denominator for numerical stability. Default: 1e-6.
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training (bool): apply dropblock if is ``True``. Default: ``True``.
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Returns:
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Tensor[N, C, H, W]: The randomly zeroed tensor after dropblock.
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"""
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if not torch.jit.is_scripting() and not torch.jit.is_tracing():
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_log_api_usage_once(drop_block2d)
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if p < 0.0 or p > 1.0:
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raise ValueError(f"drop probability has to be between 0 and 1, but got {p}.")
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if input.ndim != 4:
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raise ValueError(f"input should be 4 dimensional. Got {input.ndim} dimensions.")
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if not training or p == 0.0:
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return input
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N, C, H, W = input.size()
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block_size = min(block_size, W, H)
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# compute the gamma of Bernoulli distribution
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gamma = (p * H * W) / ((block_size**2) * ((H - block_size + 1) * (W - block_size + 1)))
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noise = torch.empty((N, C, H - block_size + 1, W - block_size + 1), dtype=input.dtype, device=input.device)
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noise.bernoulli_(gamma)
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noise = F.pad(noise, [block_size // 2] * 4, value=0)
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noise = F.max_pool2d(noise, stride=(1, 1), kernel_size=(block_size, block_size), padding=block_size // 2)
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noise = 1 - noise
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normalize_scale = noise.numel() / (eps + noise.sum())
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if inplace:
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input.mul_(noise).mul_(normalize_scale)
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else:
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input = input * noise * normalize_scale
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return input
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def drop_block3d(
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input: Tensor, p: float, block_size: int, inplace: bool = False, eps: float = 1e-06, training: bool = True
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) -> Tensor:
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"""
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Implements DropBlock3d from `"DropBlock: A regularization method for convolutional networks"
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<https://arxiv.org/abs/1810.12890>`.
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Args:
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input (Tensor[N, C, D, H, W]): The input tensor or 5-dimensions with the first one
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being its batch i.e. a batch with ``N`` rows.
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p (float): Probability of an element to be dropped.
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block_size (int): Size of the block to drop.
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inplace (bool): If set to ``True``, will do this operation in-place. Default: ``False``.
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eps (float): A value added to the denominator for numerical stability. Default: 1e-6.
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training (bool): apply dropblock if is ``True``. Default: ``True``.
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Returns:
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Tensor[N, C, D, H, W]: The randomly zeroed tensor after dropblock.
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"""
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if not torch.jit.is_scripting() and not torch.jit.is_tracing():
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_log_api_usage_once(drop_block3d)
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if p < 0.0 or p > 1.0:
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raise ValueError(f"drop probability has to be between 0 and 1, but got {p}.")
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if input.ndim != 5:
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raise ValueError(f"input should be 5 dimensional. Got {input.ndim} dimensions.")
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if not training or p == 0.0:
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return input
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N, C, D, H, W = input.size()
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block_size = min(block_size, D, H, W)
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# compute the gamma of Bernoulli distribution
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gamma = (p * D * H * W) / ((block_size**3) * ((D - block_size + 1) * (H - block_size + 1) * (W - block_size + 1)))
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noise = torch.empty(
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(N, C, D - block_size + 1, H - block_size + 1, W - block_size + 1), dtype=input.dtype, device=input.device
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)
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noise.bernoulli_(gamma)
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noise = F.pad(noise, [block_size // 2] * 6, value=0)
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noise = F.max_pool3d(
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noise, stride=(1, 1, 1), kernel_size=(block_size, block_size, block_size), padding=block_size // 2
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)
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noise = 1 - noise
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normalize_scale = noise.numel() / (eps + noise.sum())
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if inplace:
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input.mul_(noise).mul_(normalize_scale)
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else:
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input = input * noise * normalize_scale
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return input
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torch.fx.wrap("drop_block2d")
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class DropBlock2d(nn.Module):
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"""
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See :func:`drop_block2d`.
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"""
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def __init__(self, p: float, block_size: int, inplace: bool = False, eps: float = 1e-06) -> None:
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super().__init__()
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self.p = p
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self.block_size = block_size
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self.inplace = inplace
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self.eps = eps
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def forward(self, input: Tensor) -> Tensor:
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"""
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Args:
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input (Tensor): Input feature map on which some areas will be randomly
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dropped.
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Returns:
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Tensor: The tensor after DropBlock layer.
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"""
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return drop_block2d(input, self.p, self.block_size, self.inplace, self.eps, self.training)
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def __repr__(self) -> str:
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s = f"{self.__class__.__name__}(p={self.p}, block_size={self.block_size}, inplace={self.inplace})"
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return s
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torch.fx.wrap("drop_block3d")
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class DropBlock3d(DropBlock2d):
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"""
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See :func:`drop_block3d`.
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"""
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def __init__(self, p: float, block_size: int, inplace: bool = False, eps: float = 1e-06) -> None:
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super().__init__(p, block_size, inplace, eps)
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def forward(self, input: Tensor) -> Tensor:
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"""
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Args:
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input (Tensor): Input feature map on which some areas will be randomly
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dropped.
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Returns:
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Tensor: The tensor after DropBlock layer.
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"""
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return drop_block3d(input, self.p, self.block_size, self.inplace, self.eps, self.training)
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