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DL-Art-School/codes/models/arch_util.py

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import math
from abc import abstractmethod
import torch
import torch.nn as nn
import torch.nn.init as init
import torch.nn.functional as F
import torch.nn.utils.spectral_norm as SpectralNorm
from math import sqrt
from utils.util import checkpoint
import torch_intermediary as ml
def exists(val):
return val is not None
def default(val, d):
return val if exists(val) else d
def l2norm(t):
return F.normalize(t, p = 2, dim = -1)
def ema_inplace(moving_avg, new, decay):
moving_avg.data.mul_(decay).add_(new, alpha = (1 - decay))
def laplace_smoothing(x, n_categories, eps = 1e-5):
return (x + eps) / (x.sum() + n_categories * eps)
def sample_vectors(samples, num):
num_samples, device = samples.shape[0], samples.device
if num_samples >= num:
indices = torch.randperm(num_samples, device = device)[:num]
else:
indices = torch.randint(0, num_samples, (num,), device = device)
return samples[indices]
def kaiming_init(module,
a=0,
mode='fan_out',
nonlinearity='relu',
bias=0,
distribution='normal'):
assert distribution in ['uniform', 'normal']
if distribution == 'uniform':
nn.init.kaiming_uniform_(
module.weight, a=a, mode=mode, nonlinearity=nonlinearity)
else:
nn.init.kaiming_normal_(
module.weight, a=a, mode=mode, nonlinearity=nonlinearity)
if hasattr(module, 'bias') and module.bias is not None:
nn.init.constant_(module.bias, bias)
def pixel_norm(x, epsilon=1e-8):
return x * torch.rsqrt(torch.mean(torch.pow(x, 2), dim=1, keepdims=True) + epsilon)
def initialize_weights(net_l, scale=1):
if not isinstance(net_l, list):
net_l = [net_l]
for net in net_l:
for m in net.modules():
if isinstance(m, nn.Conv2d) or isinstance(m, nn.Conv3d):
init.kaiming_normal_(m.weight, a=0, mode='fan_in')
m.weight.data *= scale # for residual block
if m.bias is not None:
m.bias.data.zero_()
elif isinstance(m, ml.Linear):
init.kaiming_normal_(m.weight, a=0, mode='fan_in')
m.weight.data *= scale
if m.bias is not None:
m.bias.data.zero_()
elif isinstance(m, nn.BatchNorm2d):
init.constant_(m.weight, 1)
init.constant_(m.bias.data, 0.0)
def make_layer(block, num_blocks, **kwarg):
"""Make layers by stacking the same blocks.
Args:
block (nn.module): nn.module class for basic block.
num_blocks (int): number of blocks.
Returns:
nn.Sequential: Stacked blocks in nn.Sequential.
"""
layers = []
for _ in range(num_blocks):
layers.append(block(**kwarg))
return nn.Sequential(*layers)
def default_init_weights(module, scale=1):
"""Initialize network weights.
Args:
modules (nn.Module): Modules to be initialized.
scale (float): Scale initialized weights, especially for residual
blocks.
"""
for m in module.modules():
if isinstance(m, nn.Conv2d):
kaiming_init(m, a=0, mode='fan_in', bias=0)
m.weight.data *= scale
elif isinstance(m, ml.Linear):
kaiming_init(m, a=0, mode='fan_in', bias=0)
m.weight.data *= scale
# PyTorch 1.7 has SiLU, but we support PyTorch 1.5.
class SiLU(nn.Module):
def forward(self, x):
return x * torch.sigmoid(x)
class GroupNorm32(nn.GroupNorm):
def forward(self, x):
return super().forward(x.float()).type(x.dtype)
def conv_nd(dims, *args, **kwargs):
"""
Create a 1D, 2D, or 3D convolution module.
"""
if dims == 1:
return nn.Conv1d(*args, **kwargs)
elif dims == 2:
return nn.Conv2d(*args, **kwargs)
elif dims == 3:
return nn.Conv3d(*args, **kwargs)
raise ValueError(f"unsupported dimensions: {dims}")
def linear(*args, **kwargs):
"""
Create a linear module.
"""
return ml.Linear(*args, **kwargs)
def avg_pool_nd(dims, *args, **kwargs):
"""
Create a 1D, 2D, or 3D average pooling module.
"""
if dims == 1:
return nn.AvgPool1d(*args, **kwargs)
elif dims == 2:
return nn.AvgPool2d(*args, **kwargs)
elif dims == 3:
return nn.AvgPool3d(*args, **kwargs)
raise ValueError(f"unsupported dimensions: {dims}")
def update_ema(target_params, source_params, rate=0.99):
"""
Update target parameters to be closer to those of source parameters using
an exponential moving average.
:param target_params: the target parameter sequence.
:param source_params: the source parameter sequence.
:param rate: the EMA rate (closer to 1 means slower).
"""
for targ, src in zip(target_params, source_params):
targ.detach().mul_(rate).add_(src, alpha=1 - rate)
def zero_module(module):
"""
Zero out the parameters of a module and return it.
"""
for p in module.parameters():
p.detach().zero_()
return module
def scale_module(module, scale):
"""
Scale the parameters of a module and return it.
"""
for p in module.parameters():
p.detach().mul_(scale)
return module
def mean_flat(tensor):
"""
Take the mean over all non-batch dimensions.
"""
return tensor.mean(dim=list(range(1, len(tensor.shape))))
def normalization(channels):
"""
Make a standard normalization layer.
:param channels: number of input channels.
:return: an nn.Module for normalization.
"""
groups = 32
if channels <= 16:
groups = 8
elif channels <= 64:
groups = 16
while channels % groups != 0:
groups = int(groups / 2)
assert groups > 2
return GroupNorm32(groups, channels)
class AttentionPool2d(nn.Module):
"""
Adapted from CLIP: https://github.com/openai/CLIP/blob/main/clip/model.py
"""
def __init__(
self,
spacial_dim: int,
embed_dim: int,
num_heads_channels: int,
output_dim: int = None,
):
super().__init__()
self.positional_embedding = nn.Parameter(
torch.randn(embed_dim, spacial_dim ** 2 + 1) / embed_dim ** 0.5
)
self.qkv_proj = conv_nd(1, embed_dim, 3 * embed_dim, 1)
self.c_proj = conv_nd(1, embed_dim, output_dim or embed_dim, 1)
self.num_heads = embed_dim // num_heads_channels
self.attention = QKVAttention(self.num_heads)
def forward(self, x):
b, c, *_spatial = x.shape
x = x.reshape(b, c, -1) # NC(HW)
x = torch.cat([x.mean(dim=-1, keepdim=True), x], dim=-1) # NC(HW+1)
x = x + self.positional_embedding[None, :, :x.shape[-1]].to(x.dtype) # NC(HW+1)
x = self.qkv_proj(x)
x = self.attention(x)
x = self.c_proj(x)
return x[:, :, 0]
class TimestepBlock(nn.Module):
"""
Any module where forward() takes timestep embeddings as a second argument.
"""
@abstractmethod
def forward(self, x, emb):
"""
Apply the module to `x` given `emb` timestep embeddings.
"""
class TimestepEmbedSequential(nn.Sequential, TimestepBlock):
"""
A sequential module that passes timestep embeddings to the children that
support it as an extra input.
"""
def forward(self, x, emb):
for layer in self:
if isinstance(layer, TimestepBlock):
x = layer(x, emb)
else:
x = layer(x)
return x
class Upsample(nn.Module):
"""
An upsampling layer with an optional convolution.
:param channels: channels in the inputs and outputs.
:param use_conv: a bool determining if a convolution is applied.
:param dims: determines if the signal is 1D, 2D, or 3D. If 3D, then
upsampling occurs in the inner-two dimensions.
"""
def __init__(self, channels, use_conv, dims=2, out_channels=None, factor=2):
super().__init__()
self.channels = channels
self.out_channels = out_channels or channels
self.use_conv = use_conv
self.dims = dims
self.factor = factor
if use_conv:
ksize = 3
pad = 1
if dims == 1:
ksize = 5
pad = 2
self.conv = conv_nd(dims, self.channels, self.out_channels, ksize, padding=pad)
def forward(self, x):
assert x.shape[1] == self.channels
if self.dims == 3:
x = F.interpolate(
x, (x.shape[2], x.shape[3] * 2, x.shape[4] * 2), mode="nearest"
)
x = F.interpolate(x, scale_factor=self.factor, mode="nearest")
if self.use_conv:
x = self.conv(x)
return x
class Downsample(nn.Module):
"""
A downsampling layer with an optional convolution.
:param channels: channels in the inputs and outputs.
:param use_conv: a bool determining if a convolution is applied.
:param dims: determines if the signal is 1D, 2D, or 3D. If 3D, then
downsampling occurs in the inner-two dimensions.
"""
def __init__(self, channels, use_conv, dims=2, out_channels=None, factor=2):
super().__init__()
self.channels = channels
self.out_channels = out_channels or channels
self.use_conv = use_conv
self.dims = dims
ksize = 3
pad = 1
stride = factor
if use_conv:
self.op = conv_nd(
dims, self.channels, self.out_channels, ksize, stride=stride, padding=pad
)
else:
assert self.channels == self.out_channels
self.op = avg_pool_nd(dims, kernel_size=stride, stride=stride)
def forward(self, x):
assert x.shape[1] == self.channels
return self.op(x)
class cGLU(nn.Module):
"""
Gated GELU for channel-first architectures.
"""
def __init__(self, dim_in, dim_out=None):
super().__init__()
dim_out = dim_in if dim_out is None else dim_out
self.proj = nn.Conv1d(dim_in, dim_out * 2, 1)
def forward(self, x):
x, gate = self.proj(x).chunk(2, dim=1)
return x * F.gelu(gate)
class ResBlock(nn.Module):
"""
A residual block that can optionally change the number of channels.
:param channels: the number of input channels.
:param emb_channels: the number of timestep embedding channels.
:param dropout: the rate of dropout.
:param out_channels: if specified, the number of out channels.
:param use_conv: if True and out_channels is specified, use a spatial
convolution instead of a smaller 1x1 convolution to change the
channels in the skip connection.
:param dims: determines if the signal is 1D, 2D, or 3D.
:param up: if True, use this block for upsampling.
:param down: if True, use this block for downsampling.
"""
def __init__(
self,
channels,
dropout=0,
out_channels=None,
use_conv=False,
dims=2,
up=False,
down=False,
kernel_size=3,
checkpointing_enabled=True,
):
super().__init__()
self.channels = channels
self.dropout = dropout
self.out_channels = out_channels or channels
self.use_conv = use_conv
self.checkpointing_enabled = checkpointing_enabled
padding = 1 if kernel_size == 3 else 2
self.in_layers = nn.Sequential(
normalization(channels),
nn.SiLU(),
conv_nd(dims, channels, self.out_channels, kernel_size, padding=padding),
)
self.updown = up or down
if up:
self.h_upd = Upsample(channels, use_conv, dims)
self.x_upd = Upsample(channels, use_conv, dims)
elif down:
self.h_upd = Downsample(channels, use_conv, dims)
self.x_upd = Downsample(channels, use_conv, dims)
else:
self.h_upd = self.x_upd = nn.Identity()
self.out_layers = nn.Sequential(
normalization(self.out_channels),
nn.SiLU(),
nn.Dropout(p=dropout),
zero_module(
conv_nd(dims, self.out_channels, self.out_channels, kernel_size, padding=padding)
),
)
if self.out_channels == channels:
self.skip_connection = nn.Identity()
elif use_conv:
self.skip_connection = conv_nd(
dims, channels, self.out_channels, kernel_size, padding=padding
)
else:
self.skip_connection = conv_nd(dims, channels, self.out_channels, 1)
def forward(self, x):
"""
Apply the block to a Tensor, conditioned on a timestep embedding.
:param x: an [N x C x ...] Tensor of features.
:return: an [N x C x ...] Tensor of outputs.
"""
if self.checkpointing_enabled:
return checkpoint(
self._forward, x
)
else:
return self._forward(x)
def _forward(self, x):
if self.updown:
in_rest, in_conv = self.in_layers[:-1], self.in_layers[-1]
h = in_rest(x)
h = self.h_upd(h)
x = self.x_upd(x)
h = in_conv(h)
else:
h = self.in_layers(x)
h = self.out_layers(h)
return self.skip_connection(x) + h
def build_local_attention_mask(n, l, fixed_region=0):
"""
Builds an attention mask that focuses attention on local region
Includes provisions for a "fixed_region" at the start of the sequence where full attention weights will be applied.
Args:
n: Size of returned matrix (maximum sequence size)
l: Size of local context (uni-directional, e.g. the total context is l*2)
fixed_region: The number of sequence elements at the start of the sequence that get full attention.
Returns:
A mask that can be applied to AttentionBlock to achieve local attention.
"""
assert l*2 < n, f'Local context must be less than global context. {l}, {n}'
o = torch.arange(0,n)
c = o.unsqueeze(-1).repeat(1,n)
r = o.unsqueeze(0).repeat(n,1)
localized = ((-(r-c).abs())+l).clamp(0,l-1) / (l-1)
localized[:fixed_region] = 1
localized[:, :fixed_region] = 1
mask = localized > 0
return mask
def test_local_attention_mask():
print(build_local_attention_mask(9,4,1))
class RelativeQKBias(nn.Module):
"""
Very simple relative position bias scheme which should be directly added to QK matrix. This bias simply applies to
the distance from the given element.
If symmetric=False, a different bias is applied to each side of the input element, otherwise the bias is symmetric.
"""
def __init__(self, l, max_positions=4000, symmetric=True):
super().__init__()
if symmetric:
self.emb = nn.Parameter(torch.randn(l+1) * .01)
o = torch.arange(0,max_positions)
c = o.unsqueeze(-1).repeat(1,max_positions)
r = o.unsqueeze(0).repeat(max_positions,1)
M = ((-(r-c).abs())+l).clamp(0,l)
else:
self.emb = nn.Parameter(torch.randn(l*2+2) * .01)
a = torch.arange(0,max_positions)
c = a.unsqueeze(-1) - a
m = (c >= -l).logical_and(c <= l)
M = (l+c+1)*m
self.register_buffer('M', M, persistent=False)
def forward(self, n):
# Ideally, I'd return this:
# return self.emb[self.M[:n, :n]].view(1,n,n)
# However, indexing operations like this have horrible efficiency on GPUs: https://github.com/pytorch/pytorch/issues/15245
# So, enter this horrible, equivalent mess:
return torch.gather(self.emb.unsqueeze(-1).repeat(1,n), 0, self.M[:n,:n]).view(1,n,n)
class AttentionBlock(nn.Module):
"""
An attention block that allows spatial positions to attend to each other.
Originally ported from here, but adapted to the N-d case.
https://github.com/hojonathanho/diffusion/blob/1e0dceb3b3495bbe19116a5e1b3596cd0706c543/diffusion_tf/models/unet.py#L66.
"""
def __init__(
self,
channels,
num_heads=1,
num_head_channels=-1,
out_channels=None,
use_new_attention_order=False,
do_checkpoint=True,
do_activation=False,
):
super().__init__()
self.channels = channels
out_channels = channels if out_channels is None else out_channels
self.do_checkpoint = do_checkpoint
self.do_activation = do_activation
if num_head_channels == -1:
self.num_heads = num_heads
else:
assert (
channels % num_head_channels == 0
), f"q,k,v channels {channels} is not divisible by num_head_channels {num_head_channels}"
self.num_heads = channels // num_head_channels
self.norm = normalization(channels)
self.qkv = conv_nd(1, channels, out_channels * 3, 1)
if use_new_attention_order:
# split qkv before split heads
self.attention = QKVAttention(self.num_heads)
else:
# split heads before split qkv
self.attention = QKVAttentionLegacy(self.num_heads)
self.x_proj = nn.Identity() if out_channels == channels else conv_nd(1, channels, out_channels, 1)
self.proj_out = zero_module(conv_nd(1, out_channels, out_channels, 1))
def forward(self, x, mask=None, qk_bias=None):
if self.do_checkpoint:
if mask is None:
if qk_bias is None:
return checkpoint(self._forward, x)
else:
assert False, 'unsupported: qk_bias but no mask'
else:
if qk_bias is None:
return checkpoint(self._forward, x, mask)
else:
return checkpoint(self._forward, x, mask, qk_bias)
else:
return self._forward(x, mask)
def _forward(self, x, mask=None, qk_bias=0):
b, c, *spatial = x.shape
if mask is not None:
if len(mask.shape) == 2:
mask = mask.unsqueeze(0).repeat(x.shape[0],1,1)
if mask.shape[1] != x.shape[-1]:
mask = mask[:, :x.shape[-1], :x.shape[-1]]
x = x.reshape(b, c, -1)
x = self.norm(x)
if self.do_activation:
x = F.silu(x, inplace=True)
qkv = self.qkv(x)
h = self.attention(qkv, mask, qk_bias)
h = self.proj_out(h)
xp = self.x_proj(x)
return (xp + h).reshape(b, xp.shape[1], *spatial)
class QKVAttentionLegacy(nn.Module):
"""
A module which performs QKV attention. Matches legacy QKVAttention + input/ouput heads shaping
"""
def __init__(self, n_heads):
super().__init__()
self.n_heads = n_heads
def forward(self, qkv, mask=None, qk_bias=0):
"""
Apply QKV attention.
:param qkv: an [N x (H * 3 * C) x T] tensor of Qs, Ks, and Vs.
:return: an [N x (H * C) x T] tensor after attention.
"""
bs, width, length = qkv.shape
assert width % (3 * self.n_heads) == 0
ch = width // (3 * self.n_heads)
q, k, v = qkv.reshape(bs * self.n_heads, ch * 3, length).split(ch, dim=1)
scale = 1 / math.sqrt(math.sqrt(ch))
weight = torch.einsum(
"bct,bcs->bts", q * scale, k * scale
) # More stable with f16 than dividing afterwards
weight = weight + qk_bias
if mask is not None:
mask = mask.repeat(self.n_heads, 1, 1)
weight[mask.logical_not()] = -torch.inf
weight = torch.softmax(weight.float(), dim=-1).type(weight.dtype)
a = torch.einsum("bts,bcs->bct", weight, v)
return a.reshape(bs, -1, length)
class QKVAttention(nn.Module):
"""
A module which performs QKV attention and splits in a different order.
"""
def __init__(self, n_heads):
super().__init__()
self.n_heads = n_heads
def forward(self, qkv, mask=None, qk_bias=0):
"""
Apply QKV attention.
:param qkv: an [N x (3 * H * C) x T] tensor of Qs, Ks, and Vs.
:return: an [N x (H * C) x T] tensor after attention.
"""
bs, width, length = qkv.shape
assert width % (3 * self.n_heads) == 0
ch = width // (3 * self.n_heads)
q, k, v = qkv.chunk(3, dim=1)
scale = 1 / math.sqrt(math.sqrt(ch))
weight = torch.einsum(
"bct,bcs->bts",
(q * scale).view(bs * self.n_heads, ch, length),
(k * scale).view(bs * self.n_heads, ch, length),
) # More stable with f16 than dividing afterwards
if mask is not None:
mask = mask.repeat(self.n_heads, 1, 1)
weight[mask.logical_not()] = -torch.inf
weight = torch.softmax(weight.float(), dim=-1).type(weight.dtype)
a = torch.einsum("bts,bcs->bct", weight, v.reshape(bs * self.n_heads, ch, length))
return a.reshape(bs, -1, length)
def flow_warp(x, flow, interp_mode='bilinear', padding_mode='zeros'):
"""Warp an image or feature map with optical flow
Args:
x (Tensor): size (N, C, H, W)
flow (Tensor): size (N, H, W, 2), normal value
interp_mode (str): 'nearest' or 'bilinear'
padding_mode (str): 'zeros' or 'border' or 'reflection'
Returns:
Tensor: warped image or feature map
"""
assert x.size()[-2:] == flow.size()[1:3]
B, C, H, W = x.size()
# mesh grid
grid_y, grid_x = torch.meshgrid(torch.arange(0, H), torch.arange(0, W))
grid = torch.stack((grid_x, grid_y), 2).float() # W(x), H(y), 2
grid.requires_grad = False
grid = grid.type_as(x)
vgrid = grid + flow
# scale grid to [-1,1]
vgrid_x = 2.0 * vgrid[:, :, :, 0] / max(W - 1, 1) - 1.0
vgrid_y = 2.0 * vgrid[:, :, :, 1] / max(H - 1, 1) - 1.0
vgrid_scaled = torch.stack((vgrid_x, vgrid_y), dim=3)
output = F.grid_sample(x, vgrid_scaled, mode=interp_mode, padding_mode=padding_mode)
return output
class PixelUnshuffle(nn.Module):
def __init__(self, reduction_factor):
super(PixelUnshuffle, self).__init__()
self.r = reduction_factor
def forward(self, x):
(b, f, w, h) = x.shape
x = x.contiguous().view(b, f, w // self.r, self.r, h // self.r, self.r)
x = x.permute(0, 1, 3, 5, 2, 4).contiguous().view(b, f * (self.r ** 2), w // self.r, h // self.r)
return x
# simply define a silu function
def silu(input):
'''
Applies the Sigmoid Linear Unit (SiLU) function element-wise:
SiLU(x) = x * sigmoid(x)
'''
return input * torch.sigmoid(input)
# create a class wrapper from PyTorch nn.Module, so
# the function now can be easily used in models
class SiLU(nn.Module):
'''
Applies the Sigmoid Linear Unit (SiLU) function element-wise:
SiLU(x) = x * sigmoid(x)
Shape:
- Input: (N, *) where * means, any number of additional
dimensions
- Output: (N, *), same shape as the input
References:
- Related paper:
https://arxiv.org/pdf/1606.08415.pdf
Examples:
>>> m = silu()
>>> input = torch.randn(2)
>>> output = m(input)
'''
def __init__(self):
'''
Init method.
'''
super().__init__() # init the base class
def forward(self, input):
'''
Forward pass of the function.
'''
return silu(input)
''' Convenience class with Conv->BN->ReLU. Includes weight initialization and auto-padding for standard
kernel sizes. '''
class ConvBnRelu(nn.Module):
def __init__(self, filters_in, filters_out, kernel_size=3, stride=1, activation=True, norm=True, bias=True):
super(ConvBnRelu, self).__init__()
padding_map = {1: 0, 3: 1, 5: 2, 7: 3}
assert kernel_size in padding_map.keys()
self.conv = nn.Conv2d(filters_in, filters_out, kernel_size, stride, padding_map[kernel_size], bias=bias)
if norm:
self.bn = nn.BatchNorm2d(filters_out)
else:
self.bn = None
if activation:
self.relu = nn.ReLU()
else:
self.relu = None
# Init params.
for m in self.modules():
if isinstance(m, nn.Conv2d):
nn.init.kaiming_normal_(m.weight, mode='fan_out', nonlinearity='relu' if self.relu else 'linear')
elif isinstance(m, (nn.BatchNorm2d, nn.GroupNorm)):
nn.init.constant_(m.weight, 1)
nn.init.constant_(m.bias, 0)
def forward(self, x):
x = self.conv(x)
if self.bn:
x = self.bn(x)
if self.relu:
return self.relu(x)
else:
return x
''' Convenience class with Conv->BN->SiLU. Includes weight initialization and auto-padding for standard
kernel sizes. '''
class ConvBnSilu(nn.Module):
def __init__(self, filters_in, filters_out, kernel_size=3, stride=1, activation=True, norm=True, bias=True, weight_init_factor=1):
super(ConvBnSilu, self).__init__()
padding_map = {1: 0, 3: 1, 5: 2, 7: 3}
assert kernel_size in padding_map.keys()
self.conv = nn.Conv2d(filters_in, filters_out, kernel_size, stride, padding_map[kernel_size], bias=bias)
if norm:
self.bn = nn.BatchNorm2d(filters_out)
else:
self.bn = None
if activation:
self.silu = SiLU()
else:
self.silu = None
# Init params.
for m in self.modules():
if isinstance(m, nn.Conv2d):
nn.init.kaiming_normal_(m.weight, mode='fan_out', nonlinearity='relu' if self.silu else 'linear')
m.weight.data *= weight_init_factor
if m.bias is not None:
m.bias.data.zero_()
elif isinstance(m, (nn.BatchNorm2d, nn.GroupNorm)):
nn.init.constant_(m.weight, 1)
nn.init.constant_(m.bias, 0)
def forward(self, x):
x = self.conv(x)
if self.bn:
x = self.bn(x)
if self.silu:
return self.silu(x)
else:
return x
''' Convenience class with Conv->BN->LeakyReLU. Includes weight initialization and auto-padding for standard
kernel sizes. '''
class ConvBnLelu(nn.Module):
def __init__(self, filters_in, filters_out, kernel_size=3, stride=1, activation=True, norm=True, bias=True, weight_init_factor=1):
super(ConvBnLelu, self).__init__()
padding_map = {1: 0, 3: 1, 5: 2, 7: 3}
assert kernel_size in padding_map.keys()
self.conv = nn.Conv2d(filters_in, filters_out, kernel_size, stride, padding_map[kernel_size], bias=bias)
if norm:
self.bn = nn.BatchNorm2d(filters_out)
else:
self.bn = None
if activation:
self.lelu = nn.LeakyReLU(negative_slope=.1)
else:
self.lelu = None
# Init params.
for m in self.modules():
if isinstance(m, nn.Conv2d):
nn.init.kaiming_normal_(m.weight, a=.1, mode='fan_out',
nonlinearity='leaky_relu' if self.lelu else 'linear')
m.weight.data *= weight_init_factor
if m.bias is not None:
m.bias.data.zero_()
elif isinstance(m, (nn.BatchNorm2d, nn.GroupNorm)):
nn.init.constant_(m.weight, 1)
nn.init.constant_(m.bias, 0)
def forward(self, x):
x = self.conv(x)
if self.bn:
x = self.bn(x)
if self.lelu:
return self.lelu(x)
else:
return x
''' Convenience class with Conv->GroupNorm->LeakyReLU. Includes weight initialization and auto-padding for standard
kernel sizes. '''
class ConvGnLelu(nn.Module):
def __init__(self, filters_in, filters_out, kernel_size=3, stride=1, activation=True, norm=True, bias=True, num_groups=8, weight_init_factor=1):
super(ConvGnLelu, self).__init__()
padding_map = {1: 0, 3: 1, 5: 2, 7: 3}
assert kernel_size in padding_map.keys()
self.conv = nn.Conv2d(filters_in, filters_out, kernel_size, stride, padding_map[kernel_size], bias=bias)
if norm:
self.gn = nn.GroupNorm(num_groups, filters_out)
else:
self.gn = None
if activation:
self.lelu = nn.LeakyReLU(negative_slope=.2)
else:
self.lelu = None
# Init params.
for m in self.modules():
if isinstance(m, nn.Conv2d):
nn.init.kaiming_normal_(m.weight, a=.1, mode='fan_out',
nonlinearity='leaky_relu' if self.lelu else 'linear')
m.weight.data *= weight_init_factor
if m.bias is not None:
m.bias.data.zero_()
elif isinstance(m, (nn.BatchNorm2d, nn.GroupNorm)):
nn.init.constant_(m.weight, 1)
nn.init.constant_(m.bias, 0)
def forward(self, x):
x = self.conv(x)
if self.gn:
x = self.gn(x)
if self.lelu:
return self.lelu(x)
else:
return x
''' Convenience class with Conv->BN->SiLU. Includes weight initialization and auto-padding for standard
kernel sizes. '''
class ConvGnSilu(nn.Module):
def __init__(self, filters_in, filters_out, kernel_size=3, stride=1, activation=True, norm=True, bias=True, num_groups=8, weight_init_factor=1, convnd=nn.Conv2d):
super(ConvGnSilu, self).__init__()
padding_map = {1: 0, 3: 1, 5: 2, 7: 3}
assert kernel_size in padding_map.keys()
self.conv = convnd(filters_in, filters_out, kernel_size, stride, padding_map[kernel_size], bias=bias)
if norm:
self.gn = nn.GroupNorm(num_groups, filters_out)
else:
self.gn = None
if activation:
self.silu = SiLU()
else:
self.silu = None
# Init params.
for m in self.modules():
if isinstance(m, convnd):
nn.init.kaiming_normal_(m.weight, mode='fan_out', nonlinearity='relu' if self.silu else 'linear')
m.weight.data *= weight_init_factor
if m.bias is not None:
m.bias.data.zero_()
elif isinstance(m, (nn.BatchNorm2d, nn.GroupNorm)):
nn.init.constant_(m.weight, 1)
nn.init.constant_(m.bias, 0)
def forward(self, x):
x = self.conv(x)
if self.gn:
x = self.gn(x)
if self.silu:
return self.silu(x)
else:
return x
''' Convenience class with Conv->BN->ReLU. Includes weight initialization and auto-padding for standard
kernel sizes. '''
class ConvBnRelu(nn.Module):
def __init__(self, filters_in, filters_out, kernel_size=3, stride=1, activation=True, norm=True, bias=True, weight_init_factor=1):
super(ConvBnRelu, self).__init__()
padding_map = {1: 0, 3: 1, 5: 2, 7: 3}
assert kernel_size in padding_map.keys()
self.conv = nn.Conv2d(filters_in, filters_out, kernel_size, stride, padding_map[kernel_size], bias=bias)
if norm:
self.bn = nn.BatchNorm2d(filters_out)
else:
self.bn = None
if activation:
self.relu = nn.ReLU()
else:
self.relu = None
# Init params.
for m in self.modules():
if isinstance(m, nn.Conv2d):
nn.init.kaiming_normal_(m.weight, mode='fan_out', nonlinearity='relu' if self.relu else 'linear')
m.weight.data *= weight_init_factor
if m.bias is not None:
m.bias.data.zero_()
elif isinstance(m, (nn.BatchNorm2d, nn.GroupNorm)):
nn.init.constant_(m.weight, 1)
nn.init.constant_(m.bias, 0)
def forward(self, x):
x = self.conv(x)
if self.bn:
x = self.bn(x)
if self.relu:
return self.relu(x)
else:
return x
# Simple way to chain multiple conv->act->norms together in an intuitive way.
class MultiConvBlock(nn.Module):
def __init__(self, filters_in, filters_mid, filters_out, kernel_size, depth, scale_init=1, norm=False, weight_init_factor=1):
assert depth >= 2
super(MultiConvBlock, self).__init__()
self.noise_scale = nn.Parameter(torch.full((1,), fill_value=.01))
self.bnconvs = nn.ModuleList([ConvBnLelu(filters_in, filters_mid, kernel_size, norm=norm, bias=False, weight_init_factor=weight_init_factor)] +
[ConvBnLelu(filters_mid, filters_mid, kernel_size, norm=norm, bias=False, weight_init_factor=weight_init_factor) for i in range(depth - 2)] +
[ConvBnLelu(filters_mid, filters_out, kernel_size, activation=False, norm=False, bias=False, weight_init_factor=weight_init_factor)])
self.scale = nn.Parameter(torch.full((1,), fill_value=scale_init, dtype=torch.float))
self.bias = nn.Parameter(torch.zeros(1))
def forward(self, x, noise=None):
if noise is not None:
noise = noise * self.noise_scale
x = x + noise
for m in self.bnconvs:
x = m.forward(x)
return x * self.scale + self.bias
# Block that upsamples 2x and reduces incoming filters by 2x. It preserves structure by taking a passthrough feed
# along with the feature representation.
class ExpansionBlock(nn.Module):
def __init__(self, filters_in, filters_out=None, block=ConvGnSilu):
super(ExpansionBlock, self).__init__()
if filters_out is None:
filters_out = filters_in // 2
self.decimate = block(filters_in, filters_out, kernel_size=1, bias=False, activation=False, norm=True)
self.process_passthrough = block(filters_out, filters_out, kernel_size=3, bias=True, activation=False, norm=True)
self.conjoin = block(filters_out*2, filters_out, kernel_size=3, bias=False, activation=True, norm=False)
self.process = block(filters_out, filters_out, kernel_size=3, bias=False, activation=True, norm=True)
# input is the feature signal with shape (b, f, w, h)
# passthrough is the structure signal with shape (b, f/2, w*2, h*2)
# output is conjoined upsample with shape (b, f/2, w*2, h*2)
def forward(self, input, passthrough):
x = F.interpolate(input, scale_factor=2, mode="nearest")
x = self.decimate(x)
p = self.process_passthrough(passthrough)
x = self.conjoin(torch.cat([x, p], dim=1))
return self.process(x)
# Block that upsamples 2x and reduces incoming filters by 2x. It preserves structure by taking a passthrough feed
# along with the feature representation.
# Differs from ExpansionBlock because it performs all processing in 2xfilter space and decimates at the last step.
class ExpansionBlock2(nn.Module):
def __init__(self, filters_in, filters_out=None, block=ConvGnSilu):
super(ExpansionBlock2, self).__init__()
if filters_out is None:
filters_out = filters_in // 2
self.decimate = block(filters_in, filters_out, kernel_size=1, bias=False, activation=False, norm=True)
self.process_passthrough = block(filters_out, filters_out, kernel_size=3, bias=True, activation=False, norm=True)
self.conjoin = block(filters_out*2, filters_out*2, kernel_size=3, bias=False, activation=True, norm=False)
self.reduce = block(filters_out*2, filters_out, kernel_size=3, bias=False, activation=True, norm=True)
# input is the feature signal with shape (b, f, w, h)
# passthrough is the structure signal with shape (b, f/2, w*2, h*2)
# output is conjoined upsample with shape (b, f/2, w*2, h*2)
def forward(self, input, passthrough):
x = F.interpolate(input, scale_factor=2, mode="nearest")
x = self.decimate(x)
p = self.process_passthrough(passthrough)
x = self.conjoin(torch.cat([x, p], dim=1))
return self.reduce(x)
# Similar to ExpansionBlock2 but does not upsample.
class ConjoinBlock(nn.Module):
def __init__(self, filters_in, filters_out=None, filters_pt=None, block=ConvGnSilu, norm=True):
super(ConjoinBlock, self).__init__()
if filters_out is None:
filters_out = filters_in
if filters_pt is None:
filters_pt = filters_in
self.process = block(filters_in + filters_pt, filters_in + filters_pt, kernel_size=3, bias=False, activation=True, norm=norm)
self.decimate = block(filters_in + filters_pt, filters_out, kernel_size=1, bias=False, activation=False, norm=norm)
def forward(self, input, passthrough):
x = torch.cat([input, passthrough], dim=1)
x = self.process(x)
return self.decimate(x)
# Designed explicitly to join a mainline trunk with reference data. Implemented as a residual branch.
class ReferenceJoinBlock(nn.Module):
def __init__(self, nf, residual_weight_init_factor=1, block=ConvGnLelu, final_norm=False, kernel_size=3, depth=3, join=True):
super(ReferenceJoinBlock, self).__init__()
self.branch = MultiConvBlock(nf * 2, nf + nf // 2, nf, kernel_size=kernel_size, depth=depth,
scale_init=residual_weight_init_factor, norm=False,
weight_init_factor=residual_weight_init_factor)
if join:
self.join_conv = block(nf, nf, kernel_size=kernel_size, norm=final_norm, bias=False, activation=True)
else:
self.join_conv = None
def forward(self, x, ref):
joined = torch.cat([x, ref], dim=1)
branch = self.branch(joined)
if self.join_conv is not None:
return self.join_conv(x + branch), torch.std(branch)
else:
return x + branch, torch.std(branch)
# Basic convolutional upsampling block that uses interpolate.
class UpconvBlock(nn.Module):
def __init__(self, filters_in, filters_out=None, block=ConvGnSilu, norm=True, activation=True, bias=False):
super(UpconvBlock, self).__init__()
self.process = block(filters_in, filters_out, kernel_size=3, bias=bias, activation=activation, norm=norm)
def forward(self, x):
x = F.interpolate(x, scale_factor=2, mode="nearest")
return self.process(x)
# Scales an image up 2x and performs intermediary processing. Designed to be the final block in an SR network.
class FinalUpsampleBlock2x(nn.Module):
def __init__(self, nf, block=ConvGnLelu, out_nc=3, scale=2):
super(FinalUpsampleBlock2x, self).__init__()
if scale == 2:
self.chain = nn.Sequential(block(nf, nf, kernel_size=3, norm=False, activation=True, bias=True),
UpconvBlock(nf, nf // 2, block=block, norm=False, activation=True, bias=True),
block(nf // 2, nf // 2, kernel_size=3, norm=False, activation=False, bias=True),
block(nf // 2, out_nc, kernel_size=3, norm=False, activation=False, bias=False))
else:
self.chain = nn.Sequential(block(nf, nf, kernel_size=3, norm=False, activation=True, bias=True),
UpconvBlock(nf, nf, block=block, norm=False, activation=True, bias=True),
block(nf, nf, kernel_size=3, norm=False, activation=False, bias=True),
UpconvBlock(nf, nf // 2, block=block, norm=False, activation=True, bias=True),
block(nf // 2, nf // 2, kernel_size=3, norm=False, activation=False, bias=True),
block(nf // 2, out_nc, kernel_size=3, norm=False, activation=False, bias=False))
def forward(self, x):
return self.chain(x)
# torch.gather() which operates as it always fucking should have: pulling indexes from the input.
def gather_2d(input, index):
b, c, h, w = input.shape
nodim = input.view(b, c, h * w)
ind_nd = index[:, 0]*w + index[:, 1]
ind_nd = ind_nd.unsqueeze(1)
ind_nd = ind_nd.repeat((1, c))
ind_nd = ind_nd.unsqueeze(2)
result = torch.gather(nodim, dim=2, index=ind_nd)
result = result.squeeze()
if b == 1:
result = result.unsqueeze(0)
return result
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