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import numpy as np |
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import torch |
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import torch.nn as nn |
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import torch.nn.functional as F |
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class AvgPool2d(nn.Module): |
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def __init__(self, kernel_size=None, base_size=None, auto_pad=True, fast_imp=False, train_size=None): |
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super().__init__() |
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self.kernel_size = kernel_size |
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self.base_size = base_size |
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self.auto_pad = auto_pad |
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self.fast_imp = fast_imp |
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self.rs = [5, 4, 3, 2, 1] |
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self.max_r1 = self.rs[0] |
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self.max_r2 = self.rs[0] |
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self.train_size = train_size |
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def extra_repr(self) -> str: |
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return 'kernel_size={}, base_size={}, stride={}, fast_imp={}'.format( |
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self.kernel_size, self.base_size, self.kernel_size, self.fast_imp |
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) |
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def forward(self, x): |
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if self.kernel_size is None and self.base_size: |
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train_size = self.train_size |
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if isinstance(self.base_size, int): |
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self.base_size = (self.base_size, self.base_size) |
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self.kernel_size = list(self.base_size) |
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self.kernel_size[0] = x.shape[2] * self.base_size[0] // train_size[-2] |
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self.kernel_size[1] = x.shape[3] * self.base_size[1] // train_size[-1] |
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self.max_r1 = max(1, self.rs[0] * x.shape[2] // train_size[-2]) |
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self.max_r2 = max(1, self.rs[0] * x.shape[3] // train_size[-1]) |
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if self.kernel_size[0] >= x.size(-2) and self.kernel_size[1] >= x.size(-1): |
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return F.adaptive_avg_pool2d(x, 1) |
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if self.fast_imp: |
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h, w = x.shape[2:] |
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if self.kernel_size[0] >= h and self.kernel_size[1] >= w: |
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out = F.adaptive_avg_pool2d(x, 1) |
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else: |
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r1 = [r for r in self.rs if h % r == 0][0] |
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r2 = [r for r in self.rs if w % r == 0][0] |
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r1 = min(self.max_r1, r1) |
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r2 = min(self.max_r2, r2) |
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s = x[:, :, ::r1, ::r2].cumsum(dim=-1).cumsum(dim=-2) |
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n, c, h, w = s.shape |
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k1, k2 = min(h - 1, self.kernel_size[0] // r1), min(w - 1, self.kernel_size[1] // r2) |
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out = (s[:, :, :-k1, :-k2] - s[:, :, :-k1, k2:] - s[:, :, k1:, :-k2] + s[:, :, k1:, k2:]) / (k1 * k2) |
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out = torch.nn.functional.interpolate(out, scale_factor=(r1, r2)) |
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else: |
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n, c, h, w = x.shape |
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s = x.cumsum(dim=-1).cumsum_(dim=-2) |
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s = torch.nn.functional.pad(s, (1, 0, 1, 0)) |
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k1, k2 = min(h, self.kernel_size[0]), min(w, self.kernel_size[1]) |
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s1, s2, s3, s4 = s[:, :, :-k1, :-k2], s[:, :, :-k1, k2:], s[:, :, k1:, :-k2], s[:, :, k1:, k2:] |
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out = s4 + s1 - s2 - s3 |
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out = out / (k1 * k2) |
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if self.auto_pad: |
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n, c, h, w = x.shape |
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_h, _w = out.shape[2:] |
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pad2d = ((w - _w) // 2, (w - _w + 1) // 2, (h - _h) // 2, (h - _h + 1) // 2) |
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out = torch.nn.functional.pad(out, pad2d, mode='replicate') |
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return out |
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def replace_layers(model, base_size, train_size, fast_imp, **kwargs): |
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for n, m in model.named_children(): |
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if len(list(m.children())) > 0: |
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replace_layers(m, base_size, train_size, fast_imp, **kwargs) |
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if isinstance(m, nn.AdaptiveAvgPool2d): |
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pool = AvgPool2d(base_size=base_size, fast_imp=fast_imp, train_size=train_size) |
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assert m.output_size == 1 |
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setattr(model, n, pool) |
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''' |
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ref. |
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@article{chu2021tlsc, |
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title={Revisiting Global Statistics Aggregation for Improving Image Restoration}, |
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author={Chu, Xiaojie and Chen, Liangyu and and Chen, Chengpeng and Lu, Xin}, |
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journal={arXiv preprint arXiv:2112.04491}, |
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year={2021} |
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} |
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''' |
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class Local_Base(): |
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def convert(self, *args, train_size, **kwargs): |
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replace_layers(self, *args, train_size=train_size, **kwargs) |
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imgs = torch.rand(train_size) |
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with torch.no_grad(): |
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self.forward(imgs) |
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