forked from mrq/DL-Art-School
464 lines
18 KiB
Python
464 lines
18 KiB
Python
''' Layers
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This file contains various layers for the BigGAN models.
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'''
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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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from torch.nn import init
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import torch.optim as optim
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import torch.nn.functional as F
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from torch.nn import Parameter as P
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from sync_batchnorm import SynchronizedBatchNorm2d as SyncBN2d
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# Projection of x onto y
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def proj(x, y):
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return torch.mm(y, x.t()) * y / torch.mm(y, y.t())
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# Orthogonalize x wrt list of vectors ys
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def gram_schmidt(x, ys):
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for y in ys:
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x = x - proj(x, y)
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return x
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# Apply num_itrs steps of the power method to estimate top N singular values.
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def power_iteration(W, u_, update=True, eps=1e-12):
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# Lists holding singular vectors and values
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us, vs, svs = [], [], []
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for i, u in enumerate(u_):
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# Run one step of the power iteration
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with torch.no_grad():
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v = torch.matmul(u, W)
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# Run Gram-Schmidt to subtract components of all other singular vectors
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v = F.normalize(gram_schmidt(v, vs), eps=eps)
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# Add to the list
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vs += [v]
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# Update the other singular vector
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u = torch.matmul(v, W.t())
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# Run Gram-Schmidt to subtract components of all other singular vectors
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u = F.normalize(gram_schmidt(u, us), eps=eps)
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# Add to the list
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us += [u]
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if update:
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u_[i][:] = u
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# Compute this singular value and add it to the list
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svs += [torch.squeeze(torch.matmul(torch.matmul(v, W.t()), u.t()))]
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# svs += [torch.sum(F.linear(u, W.transpose(0, 1)) * v)]
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return svs, us, vs
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# Convenience passthrough function
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class identity(nn.Module):
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def forward(self, input):
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return input
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# Spectral normalization base class
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class SN(object):
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def __init__(self, num_svs, num_itrs, num_outputs, transpose=False, eps=1e-12):
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# Number of power iterations per step
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self.num_itrs = num_itrs
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# Number of singular values
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self.num_svs = num_svs
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# Transposed?
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self.transpose = transpose
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# Epsilon value for avoiding divide-by-0
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self.eps = eps
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# Register a singular vector for each sv
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for i in range(self.num_svs):
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self.register_buffer('u%d' % i, torch.randn(1, num_outputs))
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self.register_buffer('sv%d' % i, torch.ones(1))
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# Singular vectors (u side)
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@property
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def u(self):
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return [getattr(self, 'u%d' % i) for i in range(self.num_svs)]
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# Singular values;
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# note that these buffers are just for logging and are not used in training.
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@property
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def sv(self):
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return [getattr(self, 'sv%d' % i) for i in range(self.num_svs)]
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# Compute the spectrally-normalized weight
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def W_(self):
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W_mat = self.weight.view(self.weight.size(0), -1)
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if self.transpose:
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W_mat = W_mat.t()
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# Apply num_itrs power iterations
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for _ in range(self.num_itrs):
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svs, us, vs = power_iteration(W_mat, self.u, update=self.training, eps=self.eps)
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# Update the svs
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if self.training:
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with torch.no_grad(): # Make sure to do this in a no_grad() context or you'll get memory leaks!
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for i, sv in enumerate(svs):
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self.sv[i][:] = sv
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return self.weight / svs[0]
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# 2D Conv layer with spectral norm
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class SNConv2d(nn.Conv2d, SN):
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def __init__(self, in_channels, out_channels, kernel_size, stride=1,
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padding=0, dilation=1, groups=1, bias=True,
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num_svs=1, num_itrs=1, eps=1e-12):
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nn.Conv2d.__init__(self, in_channels, out_channels, kernel_size, stride,
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padding, dilation, groups, bias)
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SN.__init__(self, num_svs, num_itrs, out_channels, eps=eps)
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def forward(self, x):
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return F.conv2d(x, self.W_(), self.bias, self.stride,
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self.padding, self.dilation, self.groups)
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# Linear layer with spectral norm
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class SNLinear(nn.Linear, SN):
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def __init__(self, in_features, out_features, bias=True,
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num_svs=1, num_itrs=1, eps=1e-12):
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nn.Linear.__init__(self, in_features, out_features, bias)
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SN.__init__(self, num_svs, num_itrs, out_features, eps=eps)
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def forward(self, x):
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return F.linear(x, self.W_(), self.bias)
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# Embedding layer with spectral norm
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# We use num_embeddings as the dim instead of embedding_dim here
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# for convenience sake
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class SNEmbedding(nn.Embedding, SN):
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def __init__(self, num_embeddings, embedding_dim, padding_idx=None,
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max_norm=None, norm_type=2, scale_grad_by_freq=False,
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sparse=False, _weight=None,
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num_svs=1, num_itrs=1, eps=1e-12):
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nn.Embedding.__init__(self, num_embeddings, embedding_dim, padding_idx,
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max_norm, norm_type, scale_grad_by_freq,
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sparse, _weight)
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SN.__init__(self, num_svs, num_itrs, num_embeddings, eps=eps)
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def forward(self, x):
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return F.embedding(x, self.W_())
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# A non-local block as used in SA-GAN
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# Note that the implementation as described in the paper is largely incorrect;
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# refer to the released code for the actual implementation.
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class Attention(nn.Module):
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def __init__(self, ch, which_conv=SNConv2d, name='attention'):
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super(Attention, self).__init__()
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# Channel multiplier
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self.ch = ch
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self.which_conv = which_conv
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self.theta = self.which_conv(self.ch, self.ch // 8, kernel_size=1, padding=0, bias=False)
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self.phi = self.which_conv(self.ch, self.ch // 8, kernel_size=1, padding=0, bias=False)
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self.g = self.which_conv(self.ch, self.ch // 2, kernel_size=1, padding=0, bias=False)
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self.o = self.which_conv(self.ch // 2, self.ch, kernel_size=1, padding=0, bias=False)
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# Learnable gain parameter
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self.gamma = P(torch.tensor(0.), requires_grad=True)
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def forward(self, x, y=None):
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# Apply convs
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theta = self.theta(x)
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phi = F.max_pool2d(self.phi(x), [2, 2])
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g = F.max_pool2d(self.g(x), [2, 2])
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# Perform reshapes
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theta = theta.view(-1, self.ch // 8, x.shape[2] * x.shape[3])
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phi = phi.view(-1, self.ch // 8, x.shape[2] * x.shape[3] // 4)
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g = g.view(-1, self.ch // 2, x.shape[2] * x.shape[3] // 4)
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# Matmul and softmax to get attention maps
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beta = F.softmax(torch.bmm(theta.transpose(1, 2), phi), -1)
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# Attention map times g path
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o = self.o(torch.bmm(g, beta.transpose(1, 2)).view(-1, self.ch // 2, x.shape[2], x.shape[3]))
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return self.gamma * o + x
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# Fused batchnorm op
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def fused_bn(x, mean, var, gain=None, bias=None, eps=1e-5):
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# Apply scale and shift--if gain and bias are provided, fuse them here
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# Prepare scale
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scale = torch.rsqrt(var + eps)
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# If a gain is provided, use it
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if gain is not None:
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scale = scale * gain
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# Prepare shift
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shift = mean * scale
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# If bias is provided, use it
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if bias is not None:
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shift = shift - bias
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return x * scale - shift
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# return ((x - mean) / ((var + eps) ** 0.5)) * gain + bias # The unfused way.
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# Manual BN
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# Calculate means and variances using mean-of-squares minus mean-squared
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def manual_bn(x, gain=None, bias=None, return_mean_var=False, eps=1e-5):
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# Cast x to float32 if necessary
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float_x = x.float()
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# Calculate expected value of x (m) and expected value of x**2 (m2)
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# Mean of x
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m = torch.mean(float_x, [0, 2, 3], keepdim=True)
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# Mean of x squared
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m2 = torch.mean(float_x ** 2, [0, 2, 3], keepdim=True)
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# Calculate variance as mean of squared minus mean squared.
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var = (m2 - m ** 2)
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# Cast back to float 16 if necessary
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var = var.type(x.type())
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m = m.type(x.type())
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# Return mean and variance for updating stored mean/var if requested
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if return_mean_var:
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return fused_bn(x, m, var, gain, bias, eps), m.squeeze(), var.squeeze()
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else:
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return fused_bn(x, m, var, gain, bias, eps)
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# My batchnorm, supports standing stats
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class myBN(nn.Module):
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def __init__(self, num_channels, eps=1e-5, momentum=0.1):
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super(myBN, self).__init__()
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# momentum for updating running stats
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self.momentum = momentum
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# epsilon to avoid dividing by 0
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self.eps = eps
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# Momentum
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self.momentum = momentum
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# Register buffers
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self.register_buffer('stored_mean', torch.zeros(num_channels))
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self.register_buffer('stored_var', torch.ones(num_channels))
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self.register_buffer('accumulation_counter', torch.zeros(1))
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# Accumulate running means and vars
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self.accumulate_standing = False
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# reset standing stats
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def reset_stats(self):
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self.stored_mean[:] = 0
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self.stored_var[:] = 0
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self.accumulation_counter[:] = 0
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def forward(self, x, gain, bias):
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if self.training:
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out, mean, var = manual_bn(x, gain, bias, return_mean_var=True, eps=self.eps)
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# If accumulating standing stats, increment them
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if self.accumulate_standing:
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self.stored_mean[:] = self.stored_mean + mean.data
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self.stored_var[:] = self.stored_var + var.data
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self.accumulation_counter += 1.0
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# If not accumulating standing stats, take running averages
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else:
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self.stored_mean[:] = self.stored_mean * (1 - self.momentum) + mean * self.momentum
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self.stored_var[:] = self.stored_var * (1 - self.momentum) + var * self.momentum
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return out
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# If not in training mode, use the stored statistics
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else:
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mean = self.stored_mean.view(1, -1, 1, 1)
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var = self.stored_var.view(1, -1, 1, 1)
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# If using standing stats, divide them by the accumulation counter
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if self.accumulate_standing:
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mean = mean / self.accumulation_counter
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var = var / self.accumulation_counter
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return fused_bn(x, mean, var, gain, bias, self.eps)
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# Simple function to handle groupnorm norm stylization
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def groupnorm(x, norm_style):
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# If number of channels specified in norm_style:
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if 'ch' in norm_style:
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ch = int(norm_style.split('_')[-1])
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groups = max(int(x.shape[1]) // ch, 1)
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# If number of groups specified in norm style
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elif 'grp' in norm_style:
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groups = int(norm_style.split('_')[-1])
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# If neither, default to groups = 16
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else:
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groups = 16
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return F.group_norm(x, groups)
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# Class-conditional bn
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# output size is the number of channels, input size is for the linear layers
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# Andy's Note: this class feels messy but I'm not really sure how to clean it up
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# Suggestions welcome! (By which I mean, refactor this and make a pull request
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# if you want to make this more readable/usable).
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class ccbn(nn.Module):
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def __init__(self, output_size, input_size, which_linear, eps=1e-5, momentum=0.1,
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cross_replica=False, mybn=False, norm_style='bn', ):
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super(ccbn, self).__init__()
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self.output_size, self.input_size = output_size, input_size
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# Prepare gain and bias layers
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self.gain = which_linear(input_size, output_size)
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self.bias = which_linear(input_size, output_size)
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# epsilon to avoid dividing by 0
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self.eps = eps
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# Momentum
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self.momentum = momentum
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# Use cross-replica batchnorm?
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self.cross_replica = cross_replica
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# Use my batchnorm?
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self.mybn = mybn
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# Norm style?
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self.norm_style = norm_style
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if self.cross_replica:
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self.bn = SyncBN2d(output_size, eps=self.eps, momentum=self.momentum, affine=False)
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elif self.mybn:
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self.bn = myBN(output_size, self.eps, self.momentum)
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elif self.norm_style in ['bn', 'in']:
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self.register_buffer('stored_mean', torch.zeros(output_size))
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self.register_buffer('stored_var', torch.ones(output_size))
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def forward(self, x, y):
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# Calculate class-conditional gains and biases
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gain = (1 + self.gain(y)).view(y.size(0), -1, 1, 1)
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bias = self.bias(y).view(y.size(0), -1, 1, 1)
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# If using my batchnorm
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if self.mybn or self.cross_replica:
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return self.bn(x, gain=gain, bias=bias)
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# else:
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else:
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if self.norm_style == 'bn':
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out = F.batch_norm(x, self.stored_mean, self.stored_var, None, None,
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self.training, 0.1, self.eps)
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elif self.norm_style == 'in':
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out = F.instance_norm(x, self.stored_mean, self.stored_var, None, None,
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self.training, 0.1, self.eps)
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elif self.norm_style == 'gn':
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out = groupnorm(x, self.normstyle)
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elif self.norm_style == 'nonorm':
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out = x
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return out * gain + bias
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def extra_repr(self):
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s = 'out: {output_size}, in: {input_size},'
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s += ' cross_replica={cross_replica}'
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return s.format(**self.__dict__)
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# Normal, non-class-conditional BN
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class bn(nn.Module):
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def __init__(self, output_size, eps=1e-5, momentum=0.1,
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cross_replica=False, mybn=False):
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super(bn, self).__init__()
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self.output_size = output_size
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# Prepare gain and bias layers
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self.gain = P(torch.ones(output_size), requires_grad=True)
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self.bias = P(torch.zeros(output_size), requires_grad=True)
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# epsilon to avoid dividing by 0
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self.eps = eps
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# Momentum
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self.momentum = momentum
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# Use cross-replica batchnorm?
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self.cross_replica = cross_replica
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# Use my batchnorm?
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self.mybn = mybn
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if self.cross_replica:
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self.bn = SyncBN2d(output_size, eps=self.eps, momentum=self.momentum, affine=False)
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elif mybn:
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self.bn = myBN(output_size, self.eps, self.momentum)
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# Register buffers if neither of the above
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else:
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self.register_buffer('stored_mean', torch.zeros(output_size))
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self.register_buffer('stored_var', torch.ones(output_size))
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def forward(self, x, y=None):
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if self.cross_replica or self.mybn:
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gain = self.gain.view(1, -1, 1, 1)
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bias = self.bias.view(1, -1, 1, 1)
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return self.bn(x, gain=gain, bias=bias)
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else:
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return F.batch_norm(x, self.stored_mean, self.stored_var, self.gain,
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self.bias, self.training, self.momentum, self.eps)
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# Generator blocks
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# Note that this class assumes the kernel size and padding (and any other
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# settings) have been selected in the main generator module and passed in
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# through the which_conv arg. Similar rules apply with which_bn (the input
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# size [which is actually the number of channels of the conditional info] must
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# be preselected)
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class GBlock(nn.Module):
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def __init__(self, in_channels, out_channels,
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which_conv=nn.Conv2d, which_bn=bn, activation=None,
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upsample=None):
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super(GBlock, self).__init__()
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self.in_channels, self.out_channels = in_channels, out_channels
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self.which_conv, self.which_bn = which_conv, which_bn
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self.activation = activation
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self.upsample = upsample
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# Conv layers
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self.conv1 = self.which_conv(self.in_channels, self.out_channels)
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self.conv2 = self.which_conv(self.out_channels, self.out_channels)
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self.learnable_sc = in_channels != out_channels or upsample
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if self.learnable_sc:
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self.conv_sc = self.which_conv(in_channels, out_channels,
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kernel_size=1, padding=0)
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# Batchnorm layers
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self.bn1 = self.which_bn(in_channels)
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self.bn2 = self.which_bn(out_channels)
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# upsample layers
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self.upsample = upsample
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def forward(self, x, y):
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h = self.activation(self.bn1(x, y))
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if self.upsample:
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h = self.upsample(h)
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x = self.upsample(x)
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h = self.conv1(h)
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h = self.activation(self.bn2(h, y))
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h = self.conv2(h)
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if self.learnable_sc:
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x = self.conv_sc(x)
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return h + x
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# Residual block for the discriminator
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class DBlock(nn.Module):
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def __init__(self, in_channels, out_channels, which_conv=SNConv2d, wide=True,
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preactivation=False, activation=None, downsample=None, ):
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super(DBlock, self).__init__()
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self.in_channels, self.out_channels = in_channels, out_channels
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# If using wide D (as in SA-GAN and BigGAN), change the channel pattern
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self.hidden_channels = self.out_channels if wide else self.in_channels
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self.which_conv = which_conv
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self.preactivation = preactivation
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self.activation = activation
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self.downsample = downsample
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# Conv layers
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self.conv1 = self.which_conv(self.in_channels, self.hidden_channels)
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self.conv2 = self.which_conv(self.hidden_channels, self.out_channels)
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self.learnable_sc = True if (in_channels != out_channels) or downsample else False
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if self.learnable_sc:
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self.conv_sc = self.which_conv(in_channels, out_channels,
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kernel_size=1, padding=0)
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def shortcut(self, x):
|
|
if self.preactivation:
|
|
if self.learnable_sc:
|
|
x = self.conv_sc(x)
|
|
if self.downsample:
|
|
x = self.downsample(x)
|
|
else:
|
|
if self.downsample:
|
|
x = self.downsample(x)
|
|
if self.learnable_sc:
|
|
x = self.conv_sc(x)
|
|
return x
|
|
|
|
def forward(self, x):
|
|
if self.preactivation:
|
|
# h = self.activation(x) # NOT TODAY SATAN
|
|
# Andy's note: This line *must* be an out-of-place ReLU or it
|
|
# will negatively affect the shortcut connection.
|
|
h = F.relu(x)
|
|
else:
|
|
h = x
|
|
h = self.conv1(h)
|
|
h = self.conv2(self.activation(h))
|
|
if self.downsample:
|
|
h = self.downsample(h)
|
|
|
|
return h + self.shortcut(x)
|
|
|
|
# dogball |