diffusers/src/diffusers/models/resnet.py at main · python273/diffusers

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from functools import partial

import numpy as np

import torch

import torch.nn as nn

import torch.nn.functional as F

class Upsample2D(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=False, use_conv_transpose=False, out_channels=None, name="conv"):

super().__init__()

self.channels = channels

self.out_channels = out_channels or channels

self.use_conv = use_conv

self.use_conv_transpose = use_conv_transpose

self.name = name

conv = None

if use_conv_transpose:

conv = nn.ConvTranspose2d(channels, self.out_channels, 4, 2, 1)

elif use_conv:

conv = nn.Conv2d(self.channels, self.out_channels, 3, padding=1)

# TODO(Suraj, Patrick) - clean up after weight dicts are correctly renamed

if name == "conv":

self.conv = conv

else:

self.Conv2d_0 = conv

def forward(self, x):

assert x.shape[1] == self.channels

if self.use_conv_transpose:

return self.conv(x)

x = F.interpolate(x, scale_factor=2.0, mode="nearest")

# TODO(Suraj, Patrick) - clean up after weight dicts are correctly renamed

if self.use_conv:

if self.name == "conv":

x = self.conv(x)

else:

x = self.Conv2d_0(x)

return x

class Downsample2D(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=False, out_channels=None, padding=1, name="conv"):

super().__init__()

self.channels = channels

self.out_channels = out_channels or channels

self.use_conv = use_conv

self.padding = padding

stride = 2

self.name = name

if use_conv:

conv = nn.Conv2d(self.channels, self.out_channels, 3, stride=stride, padding=padding)

else:

assert self.channels == self.out_channels

conv = nn.AvgPool2d(kernel_size=stride, stride=stride)

# TODO(Suraj, Patrick) - clean up after weight dicts are correctly renamed

if name == "conv":

self.Conv2d_0 = conv

self.conv = conv

elif name == "Conv2d_0":

self.conv = conv

else:

self.conv = conv

def forward(self, x):

assert x.shape[1] == self.channels

if self.use_conv and self.padding == 0:

pad = (0, 1, 0, 1)

x = F.pad(x, pad, mode="constant", value=0)

assert x.shape[1] == self.channels

x = self.conv(x)

return x

class FirUpsample2D(nn.Module):

def __init__(self, channels=None, out_channels=None, use_conv=False, fir_kernel=(1, 3, 3, 1)):

super().__init__()

out_channels = out_channels if out_channels else channels

if use_conv:

self.Conv2d_0 = nn.Conv2d(channels, out_channels, kernel_size=3, stride=1, padding=1)

self.use_conv = use_conv

self.fir_kernel = fir_kernel

self.out_channels = out_channels

def _upsample_2d(self, x, w=None, k=None, factor=2, gain=1):

"""Fused `upsample_2d()` followed by `Conv2d()`.

Args:

Padding is performed only once at the beginning, not between the operations. The fused op is considerably more

efficient than performing the same calculation using standard TensorFlow ops. It supports gradients of arbitrary:

order.

x: Input tensor of the shape `[N, C, H, W]` or `[N, H, W,

C]`.

w: Weight tensor of the shape `[filterH, filterW, inChannels,

outChannels]`. Grouped convolution can be performed by `inChannels = x.shape[0] // numGroups`.

k: FIR filter of the shape `[firH, firW]` or `[firN]`

(separable). The default is `[1] * factor`, which corresponds to nearest-neighbor upsampling.

factor: Integer upsampling factor (default: 2). gain: Scaling factor for signal magnitude (default: 1.0).

Returns:

Tensor of the shape `[N, C, H * factor, W * factor]` or `[N, H * factor, W * factor, C]`, and same datatype as

`x`.

"""

assert isinstance(factor, int) and factor >= 1

# Setup filter kernel.

if k is None:

k = [1] * factor

# setup kernel

k = np.asarray(k, dtype=np.float32)

if k.ndim == 1:

k = np.outer(k, k)

k /= np.sum(k)

k = k * (gain * (factor**2))

if self.use_conv:

convH = w.shape[2]

convW = w.shape[3]

inC = w.shape[1]

p = (k.shape[0] - factor) - (convW - 1)

stride = (factor, factor)

# Determine data dimensions.

stride = [1, 1, factor, factor]

output_shape = ((x.shape[2] - 1) * factor + convH, (x.shape[3] - 1) * factor + convW)

output_padding = (

output_shape[0] - (x.shape[2] - 1) * stride[0] - convH,

output_shape[1] - (x.shape[3] - 1) * stride[1] - convW,

)

assert output_padding[0] >= 0 and output_padding[1] >= 0

inC = w.shape[1]

num_groups = x.shape[1] // inC

# Transpose weights.

w = torch.reshape(w, (num_groups, -1, inC, convH, convW))

w = w[..., ::-1, ::-1].permute(0, 2, 1, 3, 4)

w = torch.reshape(w, (num_groups * inC, -1, convH, convW))

x = F.conv_transpose2d(x, w, stride=stride, output_padding=output_padding, padding=0)

x = upfirdn2d_native(x, torch.tensor(k, device=x.device), pad=((p + 1) // 2 + factor - 1, p // 2 + 1))

else:

p = k.shape[0] - factor

x = upfirdn2d_native(

x, torch.tensor(k, device=x.device), up=factor, pad=((p + 1) // 2 + factor - 1, p // 2)

)

return x

def forward(self, x):

if self.use_conv:

h = self._upsample_2d(x, self.Conv2d_0.weight, k=self.fir_kernel)

h = h + self.Conv2d_0.bias.reshape(1, -1, 1, 1)

else:

h = self._upsample_2d(x, k=self.fir_kernel, factor=2)

return h

class FirDownsample2D(nn.Module):

def __init__(self, channels=None, out_channels=None, use_conv=False, fir_kernel=(1, 3, 3, 1)):

super().__init__()

out_channels = out_channels if out_channels else channels

if use_conv:

self.Conv2d_0 = nn.Conv2d(channels, out_channels, kernel_size=3, stride=1, padding=1)

self.fir_kernel = fir_kernel

self.use_conv = use_conv

self.out_channels = out_channels

def _downsample_2d(self, x, w=None, k=None, factor=2, gain=1):

"""Fused `Conv2d()` followed by `downsample_2d()`.

Args:

Padding is performed only once at the beginning, not between the operations. The fused op is considerably more

efficient than performing the same calculation using standard TensorFlow ops. It supports gradients of arbitrary:

order.

x: Input tensor of the shape `[N, C, H, W]` or `[N, H, W, C]`. w: Weight tensor of the shape `[filterH,

filterW, inChannels, outChannels]`. Grouped convolution can be performed by `inChannels = x.shape[0] //

numGroups`. k: FIR filter of the shape `[firH, firW]` or `[firN]` (separable). The default is `[1] *

factor`, which corresponds to average pooling. factor: Integer downsampling factor (default: 2). gain:

Scaling factor for signal magnitude (default: 1.0).

Returns:

Tensor of the shape `[N, C, H // factor, W // factor]` or `[N, H // factor, W // factor, C]`, and same

datatype as `x`.

"""

assert isinstance(factor, int) and factor >= 1

if k is None:

k = [1] * factor

# setup kernel

k = np.asarray(k, dtype=np.float32)

if k.ndim == 1:

k = np.outer(k, k)

k /= np.sum(k)

k = k * gain

if self.use_conv:

_, _, convH, convW = w.shape

p = (k.shape[0] - factor) + (convW - 1)

s = [factor, factor]

x = upfirdn2d_native(x, torch.tensor(k, device=x.device), pad=((p + 1) // 2, p // 2))

x = F.conv2d(x, w, stride=s, padding=0)

else:

p = k.shape[0] - factor

x = upfirdn2d_native(x, torch.tensor(k, device=x.device), down=factor, pad=((p + 1) // 2, p // 2))

return x

def forward(self, x):

if self.use_conv:

x = self._downsample_2d(x, w=self.Conv2d_0.weight, k=self.fir_kernel)

x = x + self.Conv2d_0.bias.reshape(1, -1, 1, 1)

else:

x = self._downsample_2d(x, k=self.fir_kernel, factor=2)

return x

class ResnetBlock2D(nn.Module):

def __init__(

self,

in_channels,

out_channels=None,

conv_shortcut=False,

dropout=0.0,

temb_channels=512,

groups=32,

groups_out=None,

pre_norm=True,

eps=1e-6,

non_linearity="swish",

time_embedding_norm="default",

kernel=None,

output_scale_factor=1.0,

use_nin_shortcut=None,

up=False,

down=False,

super().__init__()

self.pre_norm = pre_norm

self.pre_norm = True

self.in_channels = in_channels

out_channels = in_channels if out_channels is None else out_channels

self.out_channels = out_channels

self.use_conv_shortcut = conv_shortcut

self.time_embedding_norm = time_embedding_norm

self.up = up

self.down = down

self.output_scale_factor = output_scale_factor

if groups_out is None:

groups_out = groups

self.norm1 = torch.nn.GroupNorm(num_groups=groups, num_channels=in_channels, eps=eps, affine=True)

self.conv1 = torch.nn.Conv2d(in_channels, out_channels, kernel_size=3, stride=1, padding=1)

if temb_channels is not None:

self.time_emb_proj = torch.nn.Linear(temb_channels, out_channels)

else:

self.time_emb_proj = None

self.norm2 = torch.nn.GroupNorm(num_groups=groups_out, num_channels=out_channels, eps=eps, affine=True)

self.dropout = torch.nn.Dropout(dropout)

self.conv2 = torch.nn.Conv2d(out_channels, out_channels, kernel_size=3, stride=1, padding=1)

if non_linearity == "swish":

self.nonlinearity = lambda x: F.silu(x)

elif non_linearity == "mish":

self.nonlinearity = Mish()

elif non_linearity == "silu":

self.nonlinearity = nn.SiLU()

self.upsample = self.downsample = None

if self.up:

if kernel == "fir":

fir_kernel = (1, 3, 3, 1)

self.upsample = lambda x: upsample_2d(x, k=fir_kernel)

elif kernel == "sde_vp":

self.upsample = partial(F.interpolate, scale_factor=2.0, mode="nearest")

else:

self.upsample = Upsample2D(in_channels, use_conv=False)

elif self.down:

if kernel == "fir":

fir_kernel = (1, 3, 3, 1)

self.downsample = lambda x: downsample_2d(x, k=fir_kernel)

elif kernel == "sde_vp":

self.downsample = partial(F.avg_pool2d, kernel_size=2, stride=2)

else:

self.downsample = Downsample2D(in_channels, use_conv=False, padding=1, name="op")

self.use_nin_shortcut = self.in_channels != self.out_channels if use_nin_shortcut is None else use_nin_shortcut

self.conv_shortcut = None

if self.use_nin_shortcut:

self.conv_shortcut = torch.nn.Conv2d(in_channels, out_channels, kernel_size=1, stride=1, padding=0)

def forward(self, x, temb, hey=False):

h = x

# make sure hidden states is in float32

# when running in half-precision

h = self.norm1(h.float()).type(h.dtype)

h = self.nonlinearity(h)

if self.upsample is not None:

x = self.upsample(x)

h = self.upsample(h)

elif self.downsample is not None:

x = self.downsample(x)

h = self.downsample(h)

h = self.conv1(h)

if temb is not None:

temb = self.time_emb_proj(self.nonlinearity(temb))[:, :, None, None]

h = h + temb

# make sure hidden states is in float32

# when running in half-precision

h = self.norm2(h.float()).type(h.dtype)

h = self.nonlinearity(h)

h = self.dropout(h)

h = self.conv2(h)

if self.conv_shortcut is not None:

x = self.conv_shortcut(x)

out = (x + h) / self.output_scale_factor

return out

class Mish(torch.nn.Module):

def forward(self, x):

return x * torch.tanh(torch.nn.functional.softplus(x))

def upsample_2d(x, k=None, factor=2, gain=1):

r"""Upsample2D a batch of 2D images with the given filter.

Args:

Accepts a batch of 2D images of the shape `[N, C, H, W]` or `[N, H, W, C]` and upsamples each image with the given

filter. The filter is normalized so that if the input pixels are constant, they will be scaled by the specified

`gain`. Pixels outside the image are assumed to be zero, and the filter is padded with zeros so that its shape is a:

multiple of the upsampling factor.

x: Input tensor of the shape `[N, C, H, W]` or `[N, H, W,

C]`.

k: FIR filter of the shape `[firH, firW]` or `[firN]`

(separable). The default is `[1] * factor`, which corresponds to nearest-neighbor upsampling.

factor: Integer upsampling factor (default: 2). gain: Scaling factor for signal magnitude (default: 1.0).

Returns:

Tensor of the shape `[N, C, H * factor, W * factor]`

"""

assert isinstance(factor, int) and factor >= 1

if k is None:

k = [1] * factor

k = np.asarray(k, dtype=np.float32)

if k.ndim == 1:

k = np.outer(k, k)

k /= np.sum(k)

k = k * (gain * (factor**2))

p = k.shape[0] - factor

return upfirdn2d_native(x, torch.tensor(k, device=x.device), up=factor, pad=((p + 1) // 2 + factor - 1, p // 2))

def downsample_2d(x, k=None, factor=2, gain=1):

r"""Downsample2D a batch of 2D images with the given filter.

Args:

Accepts a batch of 2D images of the shape `[N, C, H, W]` or `[N, H, W, C]` and downsamples each image with the

given filter. The filter is normalized so that if the input pixels are constant, they will be scaled by the

specified `gain`. Pixels outside the image are assumed to be zero, and the filter is padded with zeros so that its

shape is a multiple of the downsampling factor.

x: Input tensor of the shape `[N, C, H, W]` or `[N, H, W,

C]`.

k: FIR filter of the shape `[firH, firW]` or `[firN]`

(separable). The default is `[1] * factor`, which corresponds to average pooling.

factor: Integer downsampling factor (default: 2). gain: Scaling factor for signal magnitude (default: 1.0).

Returns:

Tensor of the shape `[N, C, H // factor, W // factor]`

"""

assert isinstance(factor, int) and factor >= 1

if k is None:

k = [1] * factor

k = np.asarray(k, dtype=np.float32)

if k.ndim == 1:

k = np.outer(k, k)

k /= np.sum(k)

k = k * gain

p = k.shape[0] - factor

return upfirdn2d_native(x, torch.tensor(k, device=x.device), down=factor, pad=((p + 1) // 2, p // 2))

def upfirdn2d_native(input, kernel, up=1, down=1, pad=(0, 0)):

up_x = up_y = up

down_x = down_y = down

pad_x0 = pad_y0 = pad[0]

pad_x1 = pad_y1 = pad[1]

_, channel, in_h, in_w = input.shape

input = input.reshape(-1, in_h, in_w, 1)

_, in_h, in_w, minor = input.shape

kernel_h, kernel_w = kernel.shape

out = input.view(-1, in_h, 1, in_w, 1, minor)

out = F.pad(out, [0, 0, 0, up_x - 1, 0, 0, 0, up_y - 1])

out = out.view(-1, in_h * up_y, in_w * up_x, minor)

out = F.pad(out, [0, 0, max(pad_x0, 0), max(pad_x1, 0), max(pad_y0, 0), max(pad_y1, 0)])

out = out[

max(-pad_y0, 0) : out.shape[1] - max(-pad_y1, 0),

max(-pad_x0, 0) : out.shape[2] - max(-pad_x1, 0),

]

out = out.permute(0, 3, 1, 2)

out = out.reshape([-1, 1, in_h * up_y + pad_y0 + pad_y1, in_w * up_x + pad_x0 + pad_x1])

w = torch.flip(kernel, [0, 1]).view(1, 1, kernel_h, kernel_w)

out = F.conv2d(out, w)

out = out.reshape(

-1,

minor,

in_h * up_y + pad_y0 + pad_y1 - kernel_h + 1,

in_w * up_x + pad_x0 + pad_x1 - kernel_w + 1,

)

out = out.permute(0, 2, 3, 1)

out = out[:, ::down_y, ::down_x, :]

out_h = (in_h * up_y + pad_y0 + pad_y1 - kernel_h) // down_y + 1

out_w = (in_w * up_x + pad_x0 + pad_x1 - kernel_w) // down_x + 1

return out.view(-1, channel, out_h, out_w)

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