# Copyright (c) 2022, NVIDIA CORPORATION & AFFILIATES. All rights reserved. # # This work is licensed under a Creative Commons # Attribution-NonCommercial-ShareAlike 4.0 International License. # You should have received a copy of the license along with this # work. If not, see http://creativecommons.org/licenses/by-nc-sa/4.0/ """Model architectures and preconditioning schemes used in the paper "Elucidating the Design Space of Diffusion-Based Generative Models".""" import numpy as np import torch from torch_utils import persistence from torch.nn.functional import silu #---------------------------------------------------------------------------- # Unified routine for initializing weights and biases. def weight_init(shape, mode, fan_in, fan_out): if mode == 'xavier_uniform': return np.sqrt(6 / (fan_in + fan_out)) * (torch.rand(*shape) * 2 - 1) if mode == 'xavier_normal': return np.sqrt(2 / (fan_in + fan_out)) * torch.randn(*shape) if mode == 'kaiming_uniform': return np.sqrt(3 / fan_in) * (torch.rand(*shape) * 2 - 1) if mode == 'kaiming_normal': return np.sqrt(1 / fan_in) * torch.randn(*shape) raise ValueError(f'Invalid init mode "{mode}"') #---------------------------------------------------------------------------- # Fully-connected layer. @persistence.persistent_class class Linear(torch.nn.Module): def __init__(self, in_features, out_features, bias=True, init_mode='kaiming_normal', init_weight=1, init_bias=0): super().__init__() self.in_features = in_features self.out_features = out_features init_kwargs = dict(mode=init_mode, fan_in=in_features, fan_out=out_features) self.weight = torch.nn.Parameter(weight_init([out_features, in_features], **init_kwargs) * init_weight) self.bias = torch.nn.Parameter(weight_init([out_features], **init_kwargs) * init_bias) if bias else None def forward(self, x): x = x @ self.weight.to(x.dtype).t() if self.bias is not None: x = x.add_(self.bias.to(x.dtype)) return x #---------------------------------------------------------------------------- # Convolutional layer with optional up/downsampling. @persistence.persistent_class class Conv2d(torch.nn.Module): def __init__(self, in_channels, out_channels, kernel, bias=True, up=False, down=False, resample_filter=[1,1], fused_resample=False, init_mode='kaiming_normal', init_weight=1, init_bias=0, ): assert not (up and down) super().__init__() self.in_channels = in_channels self.out_channels = out_channels self.up = up self.down = down self.fused_resample = fused_resample init_kwargs = dict(mode=init_mode, fan_in=in_channels*kernel*kernel, fan_out=out_channels*kernel*kernel) self.weight = torch.nn.Parameter(weight_init([out_channels, in_channels, kernel, kernel], **init_kwargs) * init_weight) if kernel else None self.bias = torch.nn.Parameter(weight_init([out_channels], **init_kwargs) * init_bias) if kernel and bias else None f = torch.as_tensor(resample_filter, dtype=torch.float32) f = f.ger(f).unsqueeze(0).unsqueeze(1) / f.sum().square() self.register_buffer('resample_filter', f if up or down else None) def forward(self, x): w = self.weight.to(x.dtype) if self.weight is not None else None b = self.bias.to(x.dtype) if self.bias is not None else None f = self.resample_filter.to(x.dtype) if self.resample_filter is not None else None w_pad = w.shape[-1] // 2 if w is not None else 0 f_pad = (f.shape[-1] - 1) // 2 if f is not None else 0 if self.fused_resample and self.up and w is not None: x = torch.nn.functional.conv_transpose2d(x, f.mul(4).tile([self.in_channels, 1, 1, 1]), groups=self.in_channels, stride=2, padding=max(f_pad - w_pad, 0)) x = torch.nn.functional.conv2d(x, w, padding=max(w_pad - f_pad, 0)) elif self.fused_resample and self.down and w is not None: x = torch.nn.functional.conv2d(x, w, padding=w_pad+f_pad) x = torch.nn.functional.conv2d(x, f.tile([self.out_channels, 1, 1, 1]), groups=self.out_channels, stride=2) else: if self.up: x = torch.nn.functional.conv_transpose2d(x, f.mul(4).tile([self.in_channels, 1, 1, 1]), groups=self.in_channels, stride=2, padding=f_pad) if self.down: x = torch.nn.functional.conv2d(x, f.tile([self.in_channels, 1, 1, 1]), groups=self.in_channels, stride=2, padding=f_pad) if w is not None: x = torch.nn.functional.conv2d(x, w, padding=w_pad) if b is not None: x = x.add_(b.reshape(1, -1, 1, 1)) return x #---------------------------------------------------------------------------- # Group normalization. @persistence.persistent_class class GroupNorm(torch.nn.Module): def __init__(self, num_channels, num_groups=32, min_channels_per_group=4, eps=1e-5): super().__init__() self.num_groups = min(num_groups, num_channels // min_channels_per_group) self.eps = eps self.weight = torch.nn.Parameter(torch.ones(num_channels)) self.bias = torch.nn.Parameter(torch.zeros(num_channels)) def forward(self, x): x = torch.nn.functional.group_norm(x, num_groups=self.num_groups, weight=self.weight.to(x.dtype), bias=self.bias.to(x.dtype), eps=self.eps) return x #---------------------------------------------------------------------------- # Attention weight computation, i.e., softmax(Q^T * K). # Performs all computation using FP32, but uses the original datatype for # inputs/outputs/gradients to conserve memory. class AttentionOp(torch.autograd.Function): @staticmethod def forward(ctx, q, k): w = torch.einsum('ncq,nck->nqk', q.to(torch.float32), (k / np.sqrt(k.shape[1])).to(torch.float32)).softmax(dim=2).to(q.dtype) ctx.save_for_backward(q, k, w) return w @staticmethod def backward(ctx, dw): q, k, w = ctx.saved_tensors db = torch._softmax_backward_data(grad_output=dw.to(torch.float32), output=w.to(torch.float32), dim=2, input_dtype=torch.float32) dq = torch.einsum('nck,nqk->ncq', k.to(torch.float32), db).to(q.dtype) / np.sqrt(k.shape[1]) dk = torch.einsum('ncq,nqk->nck', q.to(torch.float32), db).to(k.dtype) / np.sqrt(k.shape[1]) return dq, dk #---------------------------------------------------------------------------- # Unified U-Net block with optional up/downsampling and self-attention. # Represents the union of all features employed by the DDPM++, NCSN++, and # ADM architectures. @persistence.persistent_class class UNetBlock(torch.nn.Module): def __init__(self, in_channels, out_channels, emb_channels, up=False, down=False, attention=False, num_heads=None, channels_per_head=64, dropout=0, skip_scale=1, eps=1e-5, resample_filter=[1,1], resample_proj=False, adaptive_scale=True, init=dict(), init_zero=dict(init_weight=0), init_attn=None, ): super().__init__() self.in_channels = in_channels self.out_channels = out_channels self.emb_channels = emb_channels self.num_heads = 0 if not attention else num_heads if num_heads is not None else out_channels // channels_per_head self.dropout = dropout self.skip_scale = skip_scale self.adaptive_scale = adaptive_scale self.norm0 = GroupNorm(num_channels=in_channels, eps=eps) self.conv0 = Conv2d(in_channels=in_channels, out_channels=out_channels, kernel=3, up=up, down=down, resample_filter=resample_filter, **init) self.affine = Linear(in_features=emb_channels, out_features=out_channels*(2 if adaptive_scale else 1), **init) self.norm1 = GroupNorm(num_channels=out_channels, eps=eps) self.conv1 = Conv2d(in_channels=out_channels, out_channels=out_channels, kernel=3, **init_zero) self.skip = None if out_channels != in_channels or up or down: kernel = 1 if resample_proj or out_channels!= in_channels else 0 self.skip = Conv2d(in_channels=in_channels, out_channels=out_channels, kernel=kernel, up=up, down=down, resample_filter=resample_filter, **init) if self.num_heads: self.norm2 = GroupNorm(num_channels=out_channels, eps=eps) self.qkv = Conv2d(in_channels=out_channels, out_channels=out_channels*3, kernel=1, **(init_attn if init_attn is not None else init)) self.proj = Conv2d(in_channels=out_channels, out_channels=out_channels, kernel=1, **init_zero) def forward(self, x, emb): orig = x x = self.conv0(silu(self.norm0(x))) params = self.affine(emb).unsqueeze(2).unsqueeze(3).to(x.dtype) if self.adaptive_scale: scale, shift = params.chunk(chunks=2, dim=1) x = silu(torch.addcmul(shift, self.norm1(x), scale + 1)) else: x = silu(self.norm1(x.add_(params))) x = self.conv1(torch.nn.functional.dropout(x, p=self.dropout, training=self.training)) x = x.add_(self.skip(orig) if self.skip is not None else orig) x = x * self.skip_scale if self.num_heads: q, k, v = self.qkv(self.norm2(x)).reshape(x.shape[0] * self.num_heads, x.shape[1] // self.num_heads, 3, -1).unbind(2) w = AttentionOp.apply(q, k) a = torch.einsum('nqk,nck->ncq', w, v) x = self.proj(a.reshape(*x.shape)).add_(x) x = x * self.skip_scale return x #---------------------------------------------------------------------------- # Timestep embedding used in the DDPM++ and ADM architectures. @persistence.persistent_class class PositionalEmbedding(torch.nn.Module): def __init__(self, num_channels, max_positions=10000, endpoint=False): super().__init__() self.num_channels = num_channels self.max_positions = max_positions self.endpoint = endpoint def forward(self, x): freqs = torch.arange(start=0, end=self.num_channels//2, dtype=torch.float32, device=x.device) freqs = freqs / (self.num_channels // 2 - (1 if self.endpoint else 0)) freqs = (1 / self.max_positions) ** freqs x = x.ger(freqs.to(x.dtype)) x = torch.cat([x.cos(), x.sin()], dim=1) return x #---------------------------------------------------------------------------- # Timestep embedding used in the NCSN++ architecture. @persistence.persistent_class class FourierEmbedding(torch.nn.Module): def __init__(self, num_channels, scale=16): super().__init__() self.register_buffer('freqs', torch.randn(num_channels // 2) * scale) def forward(self, x): x = x.ger((2 * np.pi * self.freqs).to(x.dtype)) x = torch.cat([x.cos(), x.sin()], dim=1) return x #---------------------------------------------------------------------------- # Reimplementation of the DDPM++ and NCSN++ architectures from the paper # "Score-Based Generative Modeling through Stochastic Differential # Equations". Equivalent to the original implementation by Song et al., # available at https://github.com/yang-song/score_sde_pytorch @persistence.persistent_class class SongUNet(torch.nn.Module): def __init__(self, img_resolution, # Image resolution at input/output. in_channels, # Number of color channels at input. out_channels, # Number of color channels at output. label_dim = 0, # Number of class labels, 0 = unconditional. augment_dim = 0, # Augmentation label dimensionality, 0 = no augmentation. model_channels = 128, # Base multiplier for the number of channels. channel_mult = [1,2,2,2], # Per-resolution multipliers for the number of channels. channel_mult_emb = 4, # Multiplier for the dimensionality of the embedding vector. num_blocks = 4, # Number of residual blocks per resolution. attn_resolutions = [16], # List of resolutions with self-attention. dropout = 0.10, # Dropout probability of intermediate activations. label_dropout = 0, # Dropout probability of class labels for classifier-free guidance. embedding_type = 'positional', # Timestep embedding type: 'positional' for DDPM++, 'fourier' for NCSN++. channel_mult_noise = 1, # Timestep embedding size: 1 for DDPM++, 2 for NCSN++. encoder_type = 'standard', # Encoder architecture: 'standard' for DDPM++, 'residual' for NCSN++. decoder_type = 'standard', # Decoder architecture: 'standard' for both DDPM++ and NCSN++. resample_filter = [1,1], # Resampling filter: [1,1] for DDPM++, [1,3,3,1] for NCSN++. ): assert embedding_type in ['fourier', 'positional'] assert encoder_type in ['standard', 'skip', 'residual'] assert decoder_type in ['standard', 'skip'] super().__init__() self.label_dropout = label_dropout emb_channels = model_channels * channel_mult_emb noise_channels = model_channels * channel_mult_noise init = dict(init_mode='xavier_uniform') init_zero = dict(init_mode='xavier_uniform', init_weight=1e-5) init_attn = dict(init_mode='xavier_uniform', init_weight=np.sqrt(0.2)) block_kwargs = dict( emb_channels=emb_channels, num_heads=1, dropout=dropout, skip_scale=np.sqrt(0.5), eps=1e-6, resample_filter=resample_filter, resample_proj=True, adaptive_scale=False, init=init, init_zero=init_zero, init_attn=init_attn, ) # Mapping. self.map_noise = PositionalEmbedding(num_channels=noise_channels, endpoint=True) if embedding_type == 'positional' else FourierEmbedding(num_channels=noise_channels) self.map_label = Linear(in_features=label_dim, out_features=noise_channels, **init) if label_dim else None self.map_augment = Linear(in_features=augment_dim, out_features=noise_channels, bias=False, **init) if augment_dim else None self.map_layer0 = Linear(in_features=noise_channels, out_features=emb_channels, **init) self.map_layer1 = Linear(in_features=emb_channels, out_features=emb_channels, **init) # Encoder. self.enc = torch.nn.ModuleDict() cout = in_channels caux = in_channels for level, mult in enumerate(channel_mult): res = img_resolution >> level if level == 0: cin = cout cout = model_channels self.enc[f'{res}x{res}_conv'] = Conv2d(in_channels=cin, out_channels=cout, kernel=3, **init) else: self.enc[f'{res}x{res}_down'] = UNetBlock(in_channels=cout, out_channels=cout, down=True, **block_kwargs) if encoder_type == 'skip': self.enc[f'{res}x{res}_aux_down'] = Conv2d(in_channels=caux, out_channels=caux, kernel=0, down=True, resample_filter=resample_filter) self.enc[f'{res}x{res}_aux_skip'] = Conv2d(in_channels=caux, out_channels=cout, kernel=1, **init) if encoder_type == 'residual': self.enc[f'{res}x{res}_aux_residual'] = Conv2d(in_channels=caux, out_channels=cout, kernel=3, down=True, resample_filter=resample_filter, fused_resample=True, **init) caux = cout for idx in range(num_blocks): cin = cout cout = model_channels * mult attn = (res in attn_resolutions) self.enc[f'{res}x{res}_block{idx}'] = UNetBlock(in_channels=cin, out_channels=cout, attention=attn, **block_kwargs) skips = [block.out_channels for name, block in self.enc.items() if 'aux' not in name] # Decoder. self.dec = torch.nn.ModuleDict() for level, mult in reversed(list(enumerate(channel_mult))): res = img_resolution >> level if level == len(channel_mult) - 1: self.dec[f'{res}x{res}_in0'] = UNetBlock(in_channels=cout, out_channels=cout, attention=True, **block_kwargs) self.dec[f'{res}x{res}_in1'] = UNetBlock(in_channels=cout, out_channels=cout, **block_kwargs) else: self.dec[f'{res}x{res}_up'] = UNetBlock(in_channels=cout, out_channels=cout, up=True, **block_kwargs) for idx in range(num_blocks + 1): cin = cout + skips.pop() cout = model_channels * mult attn = (idx == num_blocks and res in attn_resolutions) self.dec[f'{res}x{res}_block{idx}'] = UNetBlock(in_channels=cin, out_channels=cout, attention=attn, **block_kwargs) if decoder_type == 'skip' or level == 0: if decoder_type == 'skip' and level < len(channel_mult) - 1: self.dec[f'{res}x{res}_aux_up'] = Conv2d(in_channels=out_channels, out_channels=out_channels, kernel=0, up=True, resample_filter=resample_filter) self.dec[f'{res}x{res}_aux_norm'] = GroupNorm(num_channels=cout, eps=1e-6) self.dec[f'{res}x{res}_aux_conv'] = Conv2d(in_channels=cout, out_channels=out_channels, kernel=3, **init_zero) def forward(self, x, noise_labels, class_labels, augment_labels=None): # Mapping. emb = self.map_noise(noise_labels) emb = emb.reshape(emb.shape[0], 2, -1).flip(1).reshape(*emb.shape) # swap sin/cos if self.map_label is not None: tmp = class_labels if self.training and self.label_dropout: tmp = tmp * (torch.rand([x.shape[0], 1], device=x.device) >= self.label_dropout).to(tmp.dtype) emb = emb + self.map_label(tmp * np.sqrt(self.map_label.in_features)) if self.map_augment is not None and augment_labels is not None: emb = emb + self.map_augment(augment_labels) emb = silu(self.map_layer0(emb)) emb = silu(self.map_layer1(emb)) # Encoder. skips = [] aux = x for name, block in self.enc.items(): if 'aux_down' in name: aux = block(aux) elif 'aux_skip' in name: x = skips[-1] = x + block(aux) elif 'aux_residual' in name: x = skips[-1] = aux = (x + block(aux)) / np.sqrt(2) else: x = block(x, emb) if isinstance(block, UNetBlock) else block(x) skips.append(x) # Decoder. aux = None tmp = None for name, block in self.dec.items(): if 'aux_up' in name: aux = block(aux) elif 'aux_norm' in name: tmp = block(x) elif 'aux_conv' in name: tmp = block(silu(tmp)) aux = tmp if aux is None else tmp + aux else: if x.shape[1] != block.in_channels: x = torch.cat([x, skips.pop()], dim=1) x = block(x, emb) return aux #---------------------------------------------------------------------------- # Reimplementation of the ADM architecture from the paper # "Diffusion Models Beat GANS on Image Synthesis". Equivalent to the # original implementation by Dhariwal and Nichol, available at # https://github.com/openai/guided-diffusion @persistence.persistent_class class DhariwalUNet(torch.nn.Module): def __init__(self, img_resolution, # Image resolution at input/output. in_channels, # Number of color channels at input. out_channels, # Number of color channels at output. label_dim = 0, # Number of class labels, 0 = unconditional. augment_dim = 0, # Augmentation label dimensionality, 0 = no augmentation. model_channels = 192, # Base multiplier for the number of channels. channel_mult = [1,2,3,4], # Per-resolution multipliers for the number of channels. channel_mult_emb = 4, # Multiplier for the dimensionality of the embedding vector. num_blocks = 3, # Number of residual blocks per resolution. attn_resolutions = [32,16,8], # List of resolutions with self-attention. dropout = 0.10, # List of resolutions with self-attention. label_dropout = 0, # Dropout probability of class labels for classifier-free guidance. ): super().__init__() self.label_dropout = label_dropout emb_channels = model_channels * channel_mult_emb init = dict(init_mode='kaiming_uniform', init_weight=np.sqrt(1/3), init_bias=np.sqrt(1/3)) init_zero = dict(init_mode='kaiming_uniform', init_weight=0, init_bias=0) block_kwargs = dict(emb_channels=emb_channels, channels_per_head=64, dropout=dropout, init=init, init_zero=init_zero) # Mapping. self.map_noise = PositionalEmbedding(num_channels=model_channels) self.map_augment = Linear(in_features=augment_dim, out_features=model_channels, bias=False, **init_zero) if augment_dim else None self.map_layer0 = Linear(in_features=model_channels, out_features=emb_channels, **init) self.map_layer1 = Linear(in_features=emb_channels, out_features=emb_channels, **init) self.map_label = Linear(in_features=label_dim, out_features=emb_channels, bias=False, init_mode='kaiming_normal', init_weight=np.sqrt(label_dim)) if label_dim else None # Encoder. self.enc = torch.nn.ModuleDict() cout = in_channels for level, mult in enumerate(channel_mult): res = img_resolution >> level if level == 0: cin = cout cout = model_channels * mult self.enc[f'{res}x{res}_conv'] = Conv2d(in_channels=cin, out_channels=cout, kernel=3, **init) else: self.enc[f'{res}x{res}_down'] = UNetBlock(in_channels=cout, out_channels=cout, down=True, **block_kwargs) for idx in range(num_blocks): cin = cout cout = model_channels * mult self.enc[f'{res}x{res}_block{idx}'] = UNetBlock(in_channels=cin, out_channels=cout, attention=(res in attn_resolutions), **block_kwargs) skips = [block.out_channels for block in self.enc.values()] # Decoder. self.dec = torch.nn.ModuleDict() for level, mult in reversed(list(enumerate(channel_mult))): res = img_resolution >> level if level == len(channel_mult) - 1: self.dec[f'{res}x{res}_in0'] = UNetBlock(in_channels=cout, out_channels=cout, attention=True, **block_kwargs) self.dec[f'{res}x{res}_in1'] = UNetBlock(in_channels=cout, out_channels=cout, **block_kwargs) else: self.dec[f'{res}x{res}_up'] = UNetBlock(in_channels=cout, out_channels=cout, up=True, **block_kwargs) for idx in range(num_blocks + 1): cin = cout + skips.pop() cout = model_channels * mult self.dec[f'{res}x{res}_block{idx}'] = UNetBlock(in_channels=cin, out_channels=cout, attention=(res in attn_resolutions), **block_kwargs) self.out_norm = GroupNorm(num_channels=cout) self.out_conv = Conv2d(in_channels=cout, out_channels=out_channels, kernel=3, **init_zero) def forward(self, x, noise_labels, class_labels, augment_labels=None): # Mapping. emb = self.map_noise(noise_labels) if self.map_augment is not None and augment_labels is not None: emb = emb + self.map_augment(augment_labels) emb = silu(self.map_layer0(emb)) emb = self.map_layer1(emb) if self.map_label is not None: tmp = class_labels if self.training and self.label_dropout: tmp = tmp * (torch.rand([x.shape[0], 1], device=x.device) >= self.label_dropout).to(tmp.dtype) emb = emb + self.map_label(tmp) emb = silu(emb) # Encoder. skips = [] for block in self.enc.values(): x = block(x, emb) if isinstance(block, UNetBlock) else block(x) skips.append(x) # Decoder. for block in self.dec.values(): if x.shape[1] != block.in_channels: x = torch.cat([x, skips.pop()], dim=1) x = block(x, emb) x = self.out_conv(silu(self.out_norm(x))) return x #---------------------------------------------------------------------------- # Preconditioning corresponding to the variance preserving (VP) formulation # from the paper "Score-Based Generative Modeling through Stochastic # Differential Equations". @persistence.persistent_class class VPPrecond(torch.nn.Module): def __init__(self, img_resolution, # Image resolution. img_channels, # Number of color channels. label_dim = 0, # Number of class labels, 0 = unconditional. use_fp16 = False, # Execute the underlying model at FP16 precision? beta_d = 19.9, # Extent of the noise level schedule. beta_min = 0.1, # Initial slope of the noise level schedule. M = 1000, # Original number of timesteps in the DDPM formulation. epsilon_t = 1e-5, # Minimum t-value used during training. model_type = 'SongUNet', # Class name of the underlying model. **model_kwargs, # Keyword arguments for the underlying model. ): super().__init__() self.img_resolution = img_resolution self.img_channels = img_channels self.label_dim = label_dim self.use_fp16 = use_fp16 self.beta_d = beta_d self.beta_min = beta_min self.M = M self.epsilon_t = epsilon_t self.sigma_min = float(self.sigma(epsilon_t)) self.sigma_max = float(self.sigma(1)) self.model = globals()[model_type](img_resolution=img_resolution, in_channels=img_channels, out_channels=img_channels, label_dim=label_dim, **model_kwargs) def forward(self, x, sigma, class_labels=None, force_fp32=False, **model_kwargs): x = x.to(torch.float32) sigma = sigma.to(torch.float32).reshape(-1, 1, 1, 1) class_labels = None if self.label_dim == 0 else torch.zeros([1, self.label_dim], device=x.device) if class_labels is None else class_labels.to(torch.float32).reshape(-1, self.label_dim) dtype = torch.float16 if (self.use_fp16 and not force_fp32 and x.device.type == 'cuda') else torch.float32 c_skip = 1 c_out = -sigma c_in = 1 / (sigma ** 2 + 1).sqrt() c_noise = (self.M - 1) * self.sigma_inv(sigma) F_x = self.model((c_in * x).to(dtype), c_noise.flatten(), class_labels=class_labels, **model_kwargs) assert F_x.dtype == dtype D_x = c_skip * x + c_out * F_x.to(torch.float32) return D_x def sigma(self, t): t = torch.as_tensor(t) return ((0.5 * self.beta_d * (t ** 2) + self.beta_min * t).exp() - 1).sqrt() def sigma_inv(self, sigma): sigma = torch.as_tensor(sigma) return ((self.beta_min ** 2 + 2 * self.beta_d * (1 + sigma ** 2).log()).sqrt() - self.beta_min) / self.beta_d def round_sigma(self, sigma): return torch.as_tensor(sigma) #---------------------------------------------------------------------------- # Preconditioning corresponding to the variance exploding (VE) formulation # from the paper "Score-Based Generative Modeling through Stochastic # Differential Equations". @persistence.persistent_class class VEPrecond(torch.nn.Module): def __init__(self, img_resolution, # Image resolution. img_channels, # Number of color channels. label_dim = 0, # Number of class labels, 0 = unconditional. use_fp16 = False, # Execute the underlying model at FP16 precision? sigma_min = 0.02, # Minimum supported noise level. sigma_max = 100, # Maximum supported noise level. model_type = 'SongUNet', # Class name of the underlying model. **model_kwargs, # Keyword arguments for the underlying model. ): super().__init__() self.img_resolution = img_resolution self.img_channels = img_channels self.label_dim = label_dim self.use_fp16 = use_fp16 self.sigma_min = sigma_min self.sigma_max = sigma_max self.model = globals()[model_type](img_resolution=img_resolution, in_channels=img_channels, out_channels=img_channels, label_dim=label_dim, **model_kwargs) def forward(self, x, sigma, class_labels=None, force_fp32=False, **model_kwargs): x = x.to(torch.float32) sigma = sigma.to(torch.float32).reshape(-1, 1, 1, 1) class_labels = None if self.label_dim == 0 else torch.zeros([1, self.label_dim], device=x.device) if class_labels is None else class_labels.to(torch.float32).reshape(-1, self.label_dim) dtype = torch.float16 if (self.use_fp16 and not force_fp32 and x.device.type == 'cuda') else torch.float32 c_skip = 1 c_out = sigma c_in = 1 c_noise = (0.5 * sigma).log() F_x = self.model((c_in * x).to(dtype), c_noise.flatten(), class_labels=class_labels, **model_kwargs) assert F_x.dtype == dtype D_x = c_skip * x + c_out * F_x.to(torch.float32) return D_x def round_sigma(self, sigma): return torch.as_tensor(sigma) #---------------------------------------------------------------------------- # Preconditioning corresponding to improved DDPM (iDDPM) formulation from # the paper "Improved Denoising Diffusion Probabilistic Models". @persistence.persistent_class class iDDPMPrecond(torch.nn.Module): def __init__(self, img_resolution, # Image resolution. img_channels, # Number of color channels. label_dim = 0, # Number of class labels, 0 = unconditional. use_fp16 = False, # Execute the underlying model at FP16 precision? C_1 = 0.001, # Timestep adjustment at low noise levels. C_2 = 0.008, # Timestep adjustment at high noise levels. M = 1000, # Original number of timesteps in the DDPM formulation. model_type = 'DhariwalUNet', # Class name of the underlying model. **model_kwargs, # Keyword arguments for the underlying model. ): super().__init__() self.img_resolution = img_resolution self.img_channels = img_channels self.label_dim = label_dim self.use_fp16 = use_fp16 self.C_1 = C_1 self.C_2 = C_2 self.M = M self.model = globals()[model_type](img_resolution=img_resolution, in_channels=img_channels, out_channels=img_channels*2, label_dim=label_dim, **model_kwargs) u = torch.zeros(M + 1) for j in range(M, 0, -1): # M, ..., 1 u[j - 1] = ((u[j] ** 2 + 1) / (self.alpha_bar(j - 1) / self.alpha_bar(j)).clip(min=C_1) - 1).sqrt() self.register_buffer('u', u) self.sigma_min = float(u[M - 1]) self.sigma_max = float(u[0]) def forward(self, x, sigma, class_labels=None, force_fp32=False, **model_kwargs): x = x.to(torch.float32) sigma = sigma.to(torch.float32).reshape(-1, 1, 1, 1) class_labels = None if self.label_dim == 0 else torch.zeros([1, self.label_dim], device=x.device) if class_labels is None else class_labels.to(torch.float32).reshape(-1, self.label_dim) dtype = torch.float16 if (self.use_fp16 and not force_fp32 and x.device.type == 'cuda') else torch.float32 c_skip = 1 c_out = -sigma c_in = 1 / (sigma ** 2 + 1).sqrt() c_noise = self.M - 1 - self.round_sigma(sigma, return_index=True).to(torch.float32) F_x = self.model((c_in * x).to(dtype), c_noise.flatten(), class_labels=class_labels, **model_kwargs) assert F_x.dtype == dtype D_x = c_skip * x + c_out * F_x[:, :self.img_channels].to(torch.float32) return D_x def alpha_bar(self, j): j = torch.as_tensor(j) return (0.5 * np.pi * j / self.M / (self.C_2 + 1)).sin() ** 2 def round_sigma(self, sigma, return_index=False): sigma = torch.as_tensor(sigma) index = torch.cdist(sigma.to(self.u.device).to(torch.float32).reshape(1, -1, 1), self.u.reshape(1, -1, 1)).argmin(2) result = index if return_index else self.u[index.flatten()].to(sigma.dtype) return result.reshape(sigma.shape).to(sigma.device) #---------------------------------------------------------------------------- # Improved preconditioning proposed in the paper "Elucidating the Design # Space of Diffusion-Based Generative Models" (EDM). @persistence.persistent_class class EDMPrecond(torch.nn.Module): def __init__(self, img_resolution, # Image resolution. img_channels, # Number of color channels. label_dim = 0, # Number of class labels, 0 = unconditional. use_fp16 = False, # Execute the underlying model at FP16 precision? sigma_min = 0, # Minimum supported noise level. sigma_max = float('inf'), # Maximum supported noise level. sigma_data = 0.5, # Expected standard deviation of the training data. model_type = 'DhariwalUNet', # Class name of the underlying model. **model_kwargs, # Keyword arguments for the underlying model. ): super().__init__() self.img_resolution = img_resolution self.img_channels = img_channels self.label_dim = label_dim self.use_fp16 = use_fp16 self.sigma_min = sigma_min self.sigma_max = sigma_max self.sigma_data = sigma_data self.model = globals()[model_type](img_resolution=img_resolution, in_channels=img_channels, out_channels=img_channels, label_dim=label_dim, **model_kwargs) def forward(self, x, sigma, class_labels=None, force_fp32=False, **model_kwargs): x = x.to(torch.float32) sigma = sigma.to(torch.float32).reshape(-1, 1, 1, 1) class_labels = None if self.label_dim == 0 else torch.zeros([1, self.label_dim], device=x.device) if class_labels is None else class_labels.to(torch.float32).reshape(-1, self.label_dim) dtype = torch.float16 if (self.use_fp16 and not force_fp32 and x.device.type == 'cuda') else torch.float32 c_skip = self.sigma_data ** 2 / (sigma ** 2 + self.sigma_data ** 2) c_out = sigma * self.sigma_data / (sigma ** 2 + self.sigma_data ** 2).sqrt() c_in = 1 / (self.sigma_data ** 2 + sigma ** 2).sqrt() c_noise = sigma.log() / 4 F_x = self.model((c_in * x).to(dtype), c_noise.flatten(), class_labels=class_labels, **model_kwargs) assert F_x.dtype == dtype D_x = c_skip * x + c_out * F_x.to(torch.float32) return D_x def round_sigma(self, sigma): return torch.as_tensor(sigma) #----------------------------------------------------------------------------