2022-10-09 05:02:12 -06:00
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# this file is adapted from https://github.com/victorca25/iNNfer
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2023-02-08 05:08:09 -07:00
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from collections import OrderedDict
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2022-10-09 05:02:12 -06:00
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import math
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import functools
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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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####################
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# RRDBNet Generator
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####################
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class RRDBNet(nn.Module):
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def __init__(self, in_nc, out_nc, nf, nb, nr=3, gc=32, upscale=4, norm_type=None,
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act_type='leakyrelu', mode='CNA', upsample_mode='upconv', convtype='Conv2D',
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finalact=None, gaussian_noise=False, plus=False):
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super(RRDBNet, self).__init__()
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n_upscale = int(math.log(upscale, 2))
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if upscale == 3:
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n_upscale = 1
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self.resrgan_scale = 0
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if in_nc % 16 == 0:
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self.resrgan_scale = 1
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elif in_nc != 4 and in_nc % 4 == 0:
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self.resrgan_scale = 2
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fea_conv = conv_block(in_nc, nf, kernel_size=3, norm_type=None, act_type=None, convtype=convtype)
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rb_blocks = [RRDB(nf, nr, kernel_size=3, gc=32, stride=1, bias=1, pad_type='zero',
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norm_type=norm_type, act_type=act_type, mode='CNA', convtype=convtype,
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gaussian_noise=gaussian_noise, plus=plus) for _ in range(nb)]
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LR_conv = conv_block(nf, nf, kernel_size=3, norm_type=norm_type, act_type=None, mode=mode, convtype=convtype)
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if upsample_mode == 'upconv':
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upsample_block = upconv_block
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elif upsample_mode == 'pixelshuffle':
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upsample_block = pixelshuffle_block
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else:
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raise NotImplementedError(f'upsample mode [{upsample_mode}] is not found')
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if upscale == 3:
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upsampler = upsample_block(nf, nf, 3, act_type=act_type, convtype=convtype)
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else:
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upsampler = [upsample_block(nf, nf, act_type=act_type, convtype=convtype) for _ in range(n_upscale)]
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HR_conv0 = conv_block(nf, nf, kernel_size=3, norm_type=None, act_type=act_type, convtype=convtype)
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HR_conv1 = conv_block(nf, out_nc, kernel_size=3, norm_type=None, act_type=None, convtype=convtype)
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outact = act(finalact) if finalact else None
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self.model = sequential(fea_conv, ShortcutBlock(sequential(*rb_blocks, LR_conv)),
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*upsampler, HR_conv0, HR_conv1, outact)
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def forward(self, x, outm=None):
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if self.resrgan_scale == 1:
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feat = pixel_unshuffle(x, scale=4)
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elif self.resrgan_scale == 2:
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feat = pixel_unshuffle(x, scale=2)
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else:
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feat = x
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return self.model(feat)
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class RRDB(nn.Module):
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"""
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Residual in Residual Dense Block
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(ESRGAN: Enhanced Super-Resolution Generative Adversarial Networks)
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"""
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def __init__(self, nf, nr=3, kernel_size=3, gc=32, stride=1, bias=1, pad_type='zero',
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norm_type=None, act_type='leakyrelu', mode='CNA', convtype='Conv2D',
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spectral_norm=False, gaussian_noise=False, plus=False):
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super(RRDB, self).__init__()
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# This is for backwards compatibility with existing models
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if nr == 3:
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self.RDB1 = ResidualDenseBlock_5C(nf, kernel_size, gc, stride, bias, pad_type,
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norm_type, act_type, mode, convtype, spectral_norm=spectral_norm,
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gaussian_noise=gaussian_noise, plus=plus)
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self.RDB2 = ResidualDenseBlock_5C(nf, kernel_size, gc, stride, bias, pad_type,
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norm_type, act_type, mode, convtype, spectral_norm=spectral_norm,
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gaussian_noise=gaussian_noise, plus=plus)
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self.RDB3 = ResidualDenseBlock_5C(nf, kernel_size, gc, stride, bias, pad_type,
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norm_type, act_type, mode, convtype, spectral_norm=spectral_norm,
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gaussian_noise=gaussian_noise, plus=plus)
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else:
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RDB_list = [ResidualDenseBlock_5C(nf, kernel_size, gc, stride, bias, pad_type,
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norm_type, act_type, mode, convtype, spectral_norm=spectral_norm,
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gaussian_noise=gaussian_noise, plus=plus) for _ in range(nr)]
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self.RDBs = nn.Sequential(*RDB_list)
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def forward(self, x):
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if hasattr(self, 'RDB1'):
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out = self.RDB1(x)
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out = self.RDB2(out)
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out = self.RDB3(out)
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else:
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out = self.RDBs(x)
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return out * 0.2 + x
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class ResidualDenseBlock_5C(nn.Module):
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"""
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Residual Dense Block
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The core module of paper: (Residual Dense Network for Image Super-Resolution, CVPR 18)
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Modified options that can be used:
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- "Partial Convolution based Padding" arXiv:1811.11718
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- "Spectral normalization" arXiv:1802.05957
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- "ICASSP 2020 - ESRGAN+ : Further Improving ESRGAN" N. C.
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{Rakotonirina} and A. {Rasoanaivo}
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"""
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def __init__(self, nf=64, kernel_size=3, gc=32, stride=1, bias=1, pad_type='zero',
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norm_type=None, act_type='leakyrelu', mode='CNA', convtype='Conv2D',
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spectral_norm=False, gaussian_noise=False, plus=False):
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super(ResidualDenseBlock_5C, self).__init__()
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self.noise = GaussianNoise() if gaussian_noise else None
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self.conv1x1 = conv1x1(nf, gc) if plus else None
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self.conv1 = conv_block(nf, gc, kernel_size, stride, bias=bias, pad_type=pad_type,
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norm_type=norm_type, act_type=act_type, mode=mode, convtype=convtype,
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spectral_norm=spectral_norm)
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self.conv2 = conv_block(nf+gc, gc, kernel_size, stride, bias=bias, pad_type=pad_type,
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norm_type=norm_type, act_type=act_type, mode=mode, convtype=convtype,
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spectral_norm=spectral_norm)
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self.conv3 = conv_block(nf+2*gc, gc, kernel_size, stride, bias=bias, pad_type=pad_type,
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norm_type=norm_type, act_type=act_type, mode=mode, convtype=convtype,
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spectral_norm=spectral_norm)
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self.conv4 = conv_block(nf+3*gc, gc, kernel_size, stride, bias=bias, pad_type=pad_type,
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norm_type=norm_type, act_type=act_type, mode=mode, convtype=convtype,
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spectral_norm=spectral_norm)
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if mode == 'CNA':
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last_act = None
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else:
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last_act = act_type
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self.conv5 = conv_block(nf+4*gc, nf, 3, stride, bias=bias, pad_type=pad_type,
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norm_type=norm_type, act_type=last_act, mode=mode, convtype=convtype,
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spectral_norm=spectral_norm)
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def forward(self, x):
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x1 = self.conv1(x)
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x2 = self.conv2(torch.cat((x, x1), 1))
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if self.conv1x1:
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x2 = x2 + self.conv1x1(x)
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x3 = self.conv3(torch.cat((x, x1, x2), 1))
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x4 = self.conv4(torch.cat((x, x1, x2, x3), 1))
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if self.conv1x1:
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x4 = x4 + x2
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x5 = self.conv5(torch.cat((x, x1, x2, x3, x4), 1))
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if self.noise:
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return self.noise(x5.mul(0.2) + x)
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else:
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return x5 * 0.2 + x
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####################
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# ESRGANplus
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####################
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class GaussianNoise(nn.Module):
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def __init__(self, sigma=0.1, is_relative_detach=False):
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super().__init__()
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self.sigma = sigma
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self.is_relative_detach = is_relative_detach
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self.noise = torch.tensor(0, dtype=torch.float)
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def forward(self, x):
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if self.training and self.sigma != 0:
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self.noise = self.noise.to(x.device)
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scale = self.sigma * x.detach() if self.is_relative_detach else self.sigma * x
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sampled_noise = self.noise.repeat(*x.size()).normal_() * scale
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x = x + sampled_noise
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return x
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def conv1x1(in_planes, out_planes, stride=1):
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return nn.Conv2d(in_planes, out_planes, kernel_size=1, stride=stride, bias=False)
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####################
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# SRVGGNetCompact
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####################
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class SRVGGNetCompact(nn.Module):
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"""A compact VGG-style network structure for super-resolution.
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This class is copied from https://github.com/xinntao/Real-ESRGAN
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"""
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def __init__(self, num_in_ch=3, num_out_ch=3, num_feat=64, num_conv=16, upscale=4, act_type='prelu'):
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super(SRVGGNetCompact, self).__init__()
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self.num_in_ch = num_in_ch
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self.num_out_ch = num_out_ch
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self.num_feat = num_feat
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self.num_conv = num_conv
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self.upscale = upscale
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self.act_type = act_type
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self.body = nn.ModuleList()
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# the first conv
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self.body.append(nn.Conv2d(num_in_ch, num_feat, 3, 1, 1))
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# the first activation
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if act_type == 'relu':
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activation = nn.ReLU(inplace=True)
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elif act_type == 'prelu':
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activation = nn.PReLU(num_parameters=num_feat)
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elif act_type == 'leakyrelu':
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activation = nn.LeakyReLU(negative_slope=0.1, inplace=True)
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self.body.append(activation)
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# the body structure
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for _ in range(num_conv):
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self.body.append(nn.Conv2d(num_feat, num_feat, 3, 1, 1))
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# activation
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if act_type == 'relu':
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activation = nn.ReLU(inplace=True)
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elif act_type == 'prelu':
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activation = nn.PReLU(num_parameters=num_feat)
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elif act_type == 'leakyrelu':
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activation = nn.LeakyReLU(negative_slope=0.1, inplace=True)
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self.body.append(activation)
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# the last conv
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self.body.append(nn.Conv2d(num_feat, num_out_ch * upscale * upscale, 3, 1, 1))
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# upsample
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self.upsampler = nn.PixelShuffle(upscale)
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def forward(self, x):
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out = x
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for i in range(0, len(self.body)):
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out = self.body[i](out)
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out = self.upsampler(out)
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# add the nearest upsampled image, so that the network learns the residual
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base = F.interpolate(x, scale_factor=self.upscale, mode='nearest')
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out += base
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return out
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####################
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# Upsampler
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####################
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class Upsample(nn.Module):
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r"""Upsamples a given multi-channel 1D (temporal), 2D (spatial) or 3D (volumetric) data.
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The input data is assumed to be of the form
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`minibatch x channels x [optional depth] x [optional height] x width`.
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"""
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def __init__(self, size=None, scale_factor=None, mode="nearest", align_corners=None):
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super(Upsample, self).__init__()
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if isinstance(scale_factor, tuple):
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self.scale_factor = tuple(float(factor) for factor in scale_factor)
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else:
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self.scale_factor = float(scale_factor) if scale_factor else None
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self.mode = mode
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self.size = size
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self.align_corners = align_corners
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def forward(self, x):
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return nn.functional.interpolate(x, size=self.size, scale_factor=self.scale_factor, mode=self.mode, align_corners=self.align_corners)
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def extra_repr(self):
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if self.scale_factor is not None:
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info = f'scale_factor={self.scale_factor}'
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else:
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info = f'size={self.size}'
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info += f', mode={self.mode}'
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return info
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def pixel_unshuffle(x, scale):
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""" Pixel unshuffle.
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Args:
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x (Tensor): Input feature with shape (b, c, hh, hw).
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scale (int): Downsample ratio.
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Returns:
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Tensor: the pixel unshuffled feature.
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"""
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b, c, hh, hw = x.size()
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out_channel = c * (scale**2)
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assert hh % scale == 0 and hw % scale == 0
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h = hh // scale
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w = hw // scale
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x_view = x.view(b, c, h, scale, w, scale)
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return x_view.permute(0, 1, 3, 5, 2, 4).reshape(b, out_channel, h, w)
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def pixelshuffle_block(in_nc, out_nc, upscale_factor=2, kernel_size=3, stride=1, bias=True,
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pad_type='zero', norm_type=None, act_type='relu', convtype='Conv2D'):
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"""
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Pixel shuffle layer
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(Real-Time Single Image and Video Super-Resolution Using an Efficient Sub-Pixel Convolutional
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Neural Network, CVPR17)
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"""
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conv = conv_block(in_nc, out_nc * (upscale_factor ** 2), kernel_size, stride, bias=bias,
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pad_type=pad_type, norm_type=None, act_type=None, convtype=convtype)
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pixel_shuffle = nn.PixelShuffle(upscale_factor)
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n = norm(norm_type, out_nc) if norm_type else None
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a = act(act_type) if act_type else None
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return sequential(conv, pixel_shuffle, n, a)
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def upconv_block(in_nc, out_nc, upscale_factor=2, kernel_size=3, stride=1, bias=True,
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pad_type='zero', norm_type=None, act_type='relu', mode='nearest', convtype='Conv2D'):
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""" Upconv layer """
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upscale_factor = (1, upscale_factor, upscale_factor) if convtype == 'Conv3D' else upscale_factor
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upsample = Upsample(scale_factor=upscale_factor, mode=mode)
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conv = conv_block(in_nc, out_nc, kernel_size, stride, bias=bias,
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pad_type=pad_type, norm_type=norm_type, act_type=act_type, convtype=convtype)
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return sequential(upsample, conv)
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####################
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# Basic blocks
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####################
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def make_layer(basic_block, num_basic_block, **kwarg):
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"""Make layers by stacking the same blocks.
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Args:
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basic_block (nn.module): nn.module class for basic block. (block)
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num_basic_block (int): number of blocks. (n_layers)
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Returns:
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nn.Sequential: Stacked blocks in nn.Sequential.
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"""
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layers = []
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for _ in range(num_basic_block):
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layers.append(basic_block(**kwarg))
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return nn.Sequential(*layers)
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def act(act_type, inplace=True, neg_slope=0.2, n_prelu=1, beta=1.0):
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""" activation helper """
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act_type = act_type.lower()
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if act_type == 'relu':
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layer = nn.ReLU(inplace)
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elif act_type in ('leakyrelu', 'lrelu'):
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layer = nn.LeakyReLU(neg_slope, inplace)
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elif act_type == 'prelu':
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layer = nn.PReLU(num_parameters=n_prelu, init=neg_slope)
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elif act_type == 'tanh': # [-1, 1] range output
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layer = nn.Tanh()
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elif act_type == 'sigmoid': # [0, 1] range output
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layer = nn.Sigmoid()
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else:
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raise NotImplementedError(f'activation layer [{act_type}] is not found')
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return layer
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class Identity(nn.Module):
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def __init__(self, *kwargs):
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super(Identity, self).__init__()
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def forward(self, x, *kwargs):
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return x
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def norm(norm_type, nc):
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""" Return a normalization layer """
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norm_type = norm_type.lower()
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if norm_type == 'batch':
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layer = nn.BatchNorm2d(nc, affine=True)
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elif norm_type == 'instance':
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layer = nn.InstanceNorm2d(nc, affine=False)
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elif norm_type == 'none':
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def norm_layer(x): return Identity()
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else:
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raise NotImplementedError(f'normalization layer [{norm_type}] is not found')
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return layer
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def pad(pad_type, padding):
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""" padding layer helper """
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pad_type = pad_type.lower()
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if padding == 0:
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return None
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if pad_type == 'reflect':
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layer = nn.ReflectionPad2d(padding)
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elif pad_type == 'replicate':
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layer = nn.ReplicationPad2d(padding)
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elif pad_type == 'zero':
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layer = nn.ZeroPad2d(padding)
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else:
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raise NotImplementedError(f'padding layer [{pad_type}] is not implemented')
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return layer
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def get_valid_padding(kernel_size, dilation):
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kernel_size = kernel_size + (kernel_size - 1) * (dilation - 1)
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padding = (kernel_size - 1) // 2
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return padding
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class ShortcutBlock(nn.Module):
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""" Elementwise sum the output of a submodule to its input """
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def __init__(self, submodule):
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super(ShortcutBlock, self).__init__()
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self.sub = submodule
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def forward(self, x):
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output = x + self.sub(x)
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return output
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def __repr__(self):
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return 'Identity + \n|' + self.sub.__repr__().replace('\n', '\n|')
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def sequential(*args):
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""" Flatten Sequential. It unwraps nn.Sequential. """
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if len(args) == 1:
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if isinstance(args[0], OrderedDict):
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raise NotImplementedError('sequential does not support OrderedDict input.')
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return args[0] # No sequential is needed.
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modules = []
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for module in args:
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if isinstance(module, nn.Sequential):
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for submodule in module.children():
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modules.append(submodule)
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elif isinstance(module, nn.Module):
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modules.append(module)
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return nn.Sequential(*modules)
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def conv_block(in_nc, out_nc, kernel_size, stride=1, dilation=1, groups=1, bias=True,
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pad_type='zero', norm_type=None, act_type='relu', mode='CNA', convtype='Conv2D',
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spectral_norm=False):
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""" Conv layer with padding, normalization, activation """
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assert mode in ['CNA', 'NAC', 'CNAC'], f'Wrong conv mode [{mode}]'
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padding = get_valid_padding(kernel_size, dilation)
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p = pad(pad_type, padding) if pad_type and pad_type != 'zero' else None
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padding = padding if pad_type == 'zero' else 0
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if convtype=='PartialConv2D':
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c = PartialConv2d(in_nc, out_nc, kernel_size=kernel_size, stride=stride, padding=padding,
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dilation=dilation, bias=bias, groups=groups)
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elif convtype=='DeformConv2D':
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c = DeformConv2d(in_nc, out_nc, kernel_size=kernel_size, stride=stride, padding=padding,
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dilation=dilation, bias=bias, groups=groups)
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elif convtype=='Conv3D':
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c = nn.Conv3d(in_nc, out_nc, kernel_size=kernel_size, stride=stride, padding=padding,
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dilation=dilation, bias=bias, groups=groups)
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else:
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c = nn.Conv2d(in_nc, out_nc, kernel_size=kernel_size, stride=stride, padding=padding,
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dilation=dilation, bias=bias, groups=groups)
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if spectral_norm:
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c = nn.utils.spectral_norm(c)
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a = act(act_type) if act_type else None
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if 'CNA' in mode:
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n = norm(norm_type, out_nc) if norm_type else None
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return sequential(p, c, n, a)
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elif mode == 'NAC':
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if norm_type is None and act_type is not None:
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a = act(act_type, inplace=False)
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n = norm(norm_type, in_nc) if norm_type else None
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return sequential(n, a, p, c)
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