前言
生成式建模的扩散思想实际上已经在2015年(Sohl-Dickstein等人)提出,然而,直到2019年斯坦福大学(Song等人)、2020年Google Brain(Ho等人)才改进了这个方法,从此引发了生成式模型的新潮流。目前,包括OpenAI的GLIDE和DALL-E 2,海德堡大学的Latent Diffusion和Google Brain的ImageGen,都基于diffusion模型,并可以得到高质量的生成效果。本文以下讲解主要基于DDPM,并适当地增加一些目前有效的改进内容。
基本原理
扩散模型包括两个步骤:
固定的(或预设的)前向扩散过程q:该过程会逐渐将高斯噪声添加到图像中,直到最终得到纯噪声。
可训练的反向去噪扩散过程:训练一个神经网络,从纯噪音开始逐渐去噪,直到得到一个真实图像。
前向与后向的步数由下标 t定义,并且有预先定义好的总步数 T(DDPM原文中为1000)。
t=0 时为从数据集中采样得到的一张真实图片, t=T 时近似为一张纯粹的噪声。
2.1 直观理解
为了看懂扩散模型查了很多资料,但是要么就是大量的数学公式,一行行公式推完了还是不知道它想干啥。要么就是高视角,上来就和能量模型,VAE放一块儿对比说共同点和不同点,看完还是云里雾里。然而事实上下面几句话就能把扩散模型说明白了
扩散模型的目的是什么?
学习从纯噪声生成图片的方法
扩散模型是怎么做的?
训练一个U-Net,接受一系列加了噪声的图片,学习预测所加的噪声
前向过程在干啥?
逐步向真实图片添加噪声最终得到一个纯噪声
对于训练集中的每张图片,都能生成一系列的噪声程度不同的加噪图片
在训练时,这些 【不同程度的噪声图片 + 生成它们所用的噪声】 是实际的训练样本
反向过程在干啥?
训练好模型后,采样、生成图片
2.2 数学形式
2.2.1 前向过程
是真实数据分布(也就是真实的大量图片),从这个分布中采样即可得到一张真实图片 。我们定义前向扩散过程为 ,即每一个step向图片添加噪声的过程,并定义好一系列,则有:
其中,N为正态分布,均值和方差分别为,因此通过采样标准正态分布,有:
2.2.2 反向过程
那么问题的核心就是如何得到的逆过程 ,这个过程无法直接求出来,所以我们使用神经网络去拟合这一分布。我们使用一个具有参数的神经网络去计算 。假设反向的条件概率分布也是高斯分布,且高斯分布实际上只有两个参数:均值和方差,那么神经网络需要计算的实际上是
在DDPM中,方差被固定,网络只学习均值。而之后的改进模型中,方差也可由网络学习得到。
2.2.3 总结过程
总之,我们定义这么一个过程:给一张图片逐步加噪声直到变成纯粹的噪声,然后对噪声进行去噪得到真实的图片。所谓的扩散模型就是让神经网络学习这个去除噪声的方法。
所谓的加噪声,就是基于稍微干净的图片计算一个(多维)高斯分布(每个像素点都有一个高斯分布,且均值就是这个像素点的值,方差是预先定义的 ),然后从这个多维分布中抽样一个数据出来,这个数据就是加噪之后的结果。显然,如果方差非常非常小,那么每个抽样得到的像素点就和原本的像素点的值非常接近,也就是加了一个非常非常小的噪声。如果方差比较大,那么抽样结果就会和原本的结果差距较大。
去噪声也是同理,我们基于稍微噪声的图片 计算一个条件分布,我们希望从这个分布中抽样得到的是相比于 更加接近真实图片的稍微干净的图片。我们假设这样的条件分布是存在的,并且也是个高斯分布,那么我们只需要知道均值和方差就可以了。问题是这个均值和方差是无法直接计算的,所以用神经网络去学习近似这样一个高斯分布。
2.3 网络训练流程
我们最终要训练的实际上是一个噪声预测器。神经网络输出的噪声是,而真实的噪声取自于正态分布。则损失函数为:
预测网络方面,DDPM采用了 U-Net。
从而,网络的训练流程为:
我们接受一个随机的样本;
我们随机从 1 到 T 采样一个 t;
我们从高斯分布采样一些噪声并且施加在输入上;
网络从被影响过后的噪声图片学习其被施加了的噪声。
代码
3.1 Network helpers
先是一些辅助函数和类。
def exists(x):
return x is not None
# 有val时返回val,val为None时返回d
def default(val, d):
if exists(val):
return val
return d() if isfunction(d) else d
# 残差模块,将输入加到输出上
class Residual(nn.Module):
def __init__(self, fn):
super().__init__()
self.fn = fn
def forward(self, x, *args, **kwargs):
return self.fn(x, *args, **kwargs) + x
# 上采样(反卷积)
def Upsample(dim):
return nn.ConvTranspose2d(dim, dim, 4, 2, 1)
# 下采样
def Downsample(dim):
return nn.Conv2d(dim, dim, 4, 2, 1)
3.2 Positional embeddings
类似于Transformer的positional embedding,为了让网络知道当前处理的是一系列去噪过程中的哪一个step,我们需要将步数 t 也编码并传入网络之中。DDPM采用正弦位置编码(Sinusoidal Positional Embeddings)。这一方法的输入是shape为 (batch_size, 1) 的 tensor,也就是batch中每一个sample所处的t ,并将这个tensor转换为shape为 (batch_size, dim) 的 tensor。这个tensor会被加到每一个残差模块中。
class SinusoidalPositionEmbeddings(nn.Module):
def __init__(self, dim):
super().__init__()
self.dim = dim
def forward(self, time):
device = time.device
half_dim = self.dim // 2
embeddings = math.log(10000) / (half_dim - 1)
embeddings = torch.exp(torch.arange(half_dim, device=device) * -embeddings)
embeddings = time[:, None] * embeddings[None, :]
embeddings = torch.cat((embeddings.sin(), embeddings.cos()), dim=-1)
return embeddings
3.3 ResNet/ConvNeXT block
U-Net的Block实现,可以用ResNet或ConvNeXT。
class Block(nn.Module):
def __init__(self, dim, dim_out, groups = 8):
super().__init__()
self.proj = nn.Conv2d(dim, dim_out, 3, padding = 1)
self.norm = nn.GroupNorm(groups, dim_out)
self.act = nn.SiLU()
def forward(self, x, scale_shift = None):
x = self.proj(x)
x = self.norm(x)
if exists(scale_shift):
scale, shift = scale_shift
x = x * (scale + 1) + shift
x = self.act(x)
return x
class ResnetBlock(nn.Module):
"""Deep Residual Learning for Image Recognition"""
def __init__(self, dim, dim_out, *, time_emb_dim=None, groups=8):
super().__init__()
self.mlp = (
nn.Sequential(nn.SiLU(), nn.Linear(time_emb_dim, dim_out))
if exists(time_emb_dim)
else None
)
self.block1 = Block(dim, dim_out, groups=groups)
self.block2 = Block(dim_out, dim_out, groups=groups)
self.res_conv = nn.Conv2d(dim, dim_out, 1) if dim != dim_out else nn.Identity()
def forward(self, x, time_emb=None):
h = self.block1(x)
if exists(self.mlp) and exists(time_emb):
time_emb = self.mlp(time_emb)
h = rearrange(time_emb, "b c -> b c 1 1") + h
h = self.block2(h)
return h + self.res_conv(x)
class ConvNextBlock(nn.Module):
"""A ConvNet for the 2020s"""
def __init__(self, dim, dim_out, *, time_emb_dim=None, mult=2, norm=True):
super().__init__()
self.mlp = (
nn.Sequential(nn.GELU(), nn.Linear(time_emb_dim, dim))
if exists(time_emb_dim)
else None
)
self.ds_conv = nn.Conv2d(dim, dim, 7, padding=3, groups=dim)
Get an email address at self.net. It's ad-free, reliable email that's based on your own name | self.net = nn.Sequential(
nn.GroupNorm(1, dim) if norm else nn.Identity(),
nn.Conv2d(dim, dim_out * mult, 3, padding=1),
nn.GELU(),
nn.GroupNorm(1, dim_out * mult),
nn.Conv2d(dim_out * mult, dim_out, 3, padding=1),
)
self.res_conv = nn.Conv2d(dim, dim_out, 1) if dim != dim_out else nn.Identity()
def forward(self, x, time_emb=None):
h = self.ds_conv(x)
if exists(self.mlp) and exists(time_emb):
condition = self.mlp(time_emb)
h = h + rearrange(condition, "b c -> b c 1 1")
h = Get an email address at self.net. It's ad-free, reliable email that's based on your own name | self.net(h)
return h + self.res_conv(x)
3.4 Attention module
包含两种attention模块,一个是常规的 multi-head self-attention,一个是 linear attention variant。
class Attention(nn.Module):
def __init__(self, dim, heads=4, dim_head=32):
super().__init__()
self.scale = dim_head**-0.5
self.heads = heads
hidden_dim = dim_head * heads
self.to_qkv = nn.Conv2d(dim, hidden_dim * 3, 1, bias=False)
self.to_out = nn.Conv2d(hidden_dim, dim, 1)
def forward(self, x):
b, c, h, w = x.shape
qkv = self.to_qkv(x).chunk(3, dim=1)
q, k, v = map(
lambda t: rearrange(t, "b (h c) x y -> b h c (x y)", h=self.heads), qkv
)
q = q * self.scale
sim = einsum("b h d i, b h d j -> b h i j", q, k)
sim = sim - sim.amax(dim=-1, keepdim=True).detach()
attn = sim.softmax(dim=-1)
out = einsum("b h i j, b h d j -> b h i d", attn, v)
out = rearrange(out, "b h (x y) d -> b (h d) x y", x=h, y=w)
return self.to_out(out)
class LinearAttention(nn.Module):
def __init__(self, dim, heads=4, dim_head=32):
super().__init__()
self.scale = dim_head**-0.5
self.heads = heads
hidden_dim = dim_head * heads
self.to_qkv = nn.Conv2d(dim, hidden_dim * 3, 1, bias=False)
self.to_out = nn.Sequential(nn.Conv2d(hidden_dim, dim, 1),
nn.GroupNorm(1, dim))
def forward(self, x):
b, c, h, w = x.shape
qkv = self.to_qkv(x).chunk(3, dim=1)
q, k, v = map(
lambda t: rearrange(t, "b (h c) x y -> b h c (x y)", h=self.heads), qkv
)
q = q.softmax(dim=-2)
k = k.softmax(dim=-1)
q = q * self.scale
context = torch.einsum("b h d n, b h e n -> b h d e", k, v)
out = torch.einsum("b h d e, b h d n -> b h e n", context, q)
out = rearrange(out, "b h c (x y) -> b (h c) x y", h=self.heads, x=h, y=w)
return self.to_out(out)
3.5 Group normalization
DDPM的作者对U-Net的卷积/注意力层使用GN正则化。下面,我们定义了一个PreNorm类,它将被用于在注意力层之前应用groupnorm。值得注意的是,归一化在Transformer中是在注意力之前还是之后应用,目前仍存在着争议。
class PreNorm(nn.Module):
def __init__(self, dim, fn):
super().__init__()
self.fn = fn
self.norm = nn.GroupNorm(1, dim)
def forward(self, x):
x = self.norm(x)
return self.fn(x)
3.6 Conditional U-Net
现在,我们已经定义了所有的组件,接下来就是定义完整的网络了。
输入:噪声图片的batch+这些图片各自的t。
输出:预测每个图片上所添加的噪声。
Input:a batch of noisy images of shape ( batch_size, num_channels, h, w ) and a batch of steps of shape ( batch_size, 1 )
output: a tensor of shape ( batch_size, num_channels, h, w )
具体的网络结构:
首先,输入通过一个卷积层,同时计算step t 所对应的embedding
通过一系列的下采样stage,每个stage都包含:2个ResNet/ConvNeXT blocks + groupnorm + attention + residual connection + downsample operation
在网络中间,应用一个带attention的ResNet或者ConvNeXT
通过一系列的上采样stage,每个stage都包含:2个ResNet/ConvNeXT blocks + groupnorm + attention + residual connection + upsample operation
最终,通过一个ResNet/ConvNeXT blocl和一个卷积层。
class Unet(nn.Module):
def __init__(
self,
dim,
init_dim=None,
out_dim=None,
dim_mults=(1, 2, 4, 8),
channels=3,
with_time_emb=True,
resnet_block_groups=8,
use_convnext=True,
convnext_mult=2,
):
super().__init__()
# determine dimensions
self.channels = channels
init_dim = default(init_dim, dim // 3 * 2)
self.init_conv = nn.Conv2d(channels, init_dim, 7, padding=3)
dims = [init_dim, *map(lambda m: dim * m, dim_mults)]
in_out = list(zip(dims[:-1], dims[1:]))
if use_convnext:
block_klass = partial(ConvNextBlock, mult=convnext_mult)
else:
block_klass = partial(ResnetBlock, groups=resnet_block_groups)
# time embeddings
if with_time_emb:
time_dim = dim * 4
self.time_mlp = nn.Sequential(
SinusoidalPositionEmbeddings(dim),
nn.Linear(dim, time_dim),
nn.GELU(),
nn.Linear(time_dim, time_dim),
)
else:
time_dim = None
self.time_mlp = None
# layers
self.downs = nn.ModuleList([])
self.ups = nn.ModuleList([])
num_resolutions = len(in_out)
for ind, (dim_in, dim_out) in enumerate(in_out):
is_last = ind >= (num_resolutions - 1)
self.downs.append(
nn.ModuleList(
[
block_klass(dim_in, dim_out, time_emb_dim=time_dim),
block_klass(dim_out, dim_out, time_emb_dim=time_dim),
Residual(PreNorm(dim_out, LinearAttention(dim_out))),
Downsample(dim_out) if not is_last else nn.Identity(),
]
)
)
mid_dim = dims[-1]
self.mid_block1 = block_klass(mid_dim, mid_dim, time_emb_dim=time_dim)
self.mid_attn = Residual(PreNorm(mid_dim, Attention(mid_dim)))
self.mid_block2 = block_klass(mid_dim, mid_dim, time_emb_dim=time_dim)
for ind, (dim_in, dim_out) in enumerate(reversed(in_out[1:])):
is_last = ind >= (num_resolutions - 1)
self.ups.append(
nn.ModuleList(
[
block_klass(dim_out * 2, dim_in, time_emb_dim=time_dim),
block_klass(dim_in, dim_in, time_emb_dim=time_dim),
Residual(PreNorm(dim_in, LinearAttention(dim_in))),
Upsample(dim_in) if not is_last else nn.Identity(),
]
)
)
out_dim = default(out_dim, channels)
self.final_conv = nn.Sequential(
block_klass(dim, dim), nn.Conv2d(dim, out_dim, 1)
)
def forward(self, x, time):
x = self.init_conv(x)
t = self.time_mlp(time) if exists(self.time_mlp) else None
h = []
# downsample
for block1, block2, attn, downsample in self.downs:
x = block1(x, t)
x = block2(x, t)
x = attn(x)
h.append(x)
x = downsample(x)
# bottleneck
x = self.mid_block1(x, t)
x = self.mid_attn(x)
x = self.mid_block2(x, t)
# upsample
for block1, block2, attn, upsample in self.ups:
x = torch.cat((x, h.pop()), dim=1)
x = block1(x, t)
x = block2(x, t)
x = attn(x)
x = upsample(x)
return self.final_conv(x)
3.7 定义前向扩散过程
DDPM中使用linear schedule定义 。后续的研究指出使用cosine schedule可能会有更好的效果。
接下来是一些简单的对于 schedule 的定义,从当中选一个使用即可。
def cosine_beta_schedule(timesteps, s=0.008):
"""
cosine schedule as proposed in https://arxiv.org/abs/2102.09672
"""
steps = timesteps + 1
x = torch.linspace(0, timesteps, steps)
alphas_cumprod = torch.cos(((x / timesteps) + s) / (1 + s) * torch.pi * 0.5) ** 2
alphas_cumprod = alphas_cumprod / alphas_cumprod[0]
betas = 1 - (alphas_cumprod[1:] / alphas_cumprod[:-1])
return torch.clip(betas, 0.0001, 0.9999)
def linear_beta_schedule(timesteps):
beta_start = 0.0001
beta_end = 0.02
return torch.linspace(beta_start, beta_end, timesteps)
def quadratic_beta_schedule(timesteps):
beta_start = 0.0001
beta_end = 0.02
return torch.linspace(beta_start**0.5, beta_end**0.5, timesteps) ** 2
def sigmoid_beta_schedule(timesteps):
beta_start = 0.0001
beta_end = 0.02
betas = torch.linspace(-6, 6, timesteps)
return torch.sigmoid(betas) * (beta_end - beta_start) + beta_start
我们按照DDPM中用第二种的linear,将 T 设置为200,并将每个 t 下的各种参数提前计算好。
timesteps = 200
# define beta schedule
betas = linear_beta_schedule(timesteps=timesteps)
# define alphas
alphas = 1. - betas
alphas_cumprod = torch.cumprod(alphas, axis=0)
alphas_cumprod_prev = F.pad(alphas_cumprod[:-1], (1, 0), value=1.0)
sqrt_recip_alphas = torch.sqrt(1.0 / alphas)
# calculations for diffusion q(x_t | x_{t-1}) and others
sqrt_alphas_cumprod = torch.sqrt(alphas_cumprod)
sqrt_one_minus_alphas_cumprod = torch.sqrt(1. - alphas_cumprod)
# calculations for posterior q(x_{t-1} | x_t, x_0)
posterior_variance = betas * (1. - alphas_cumprod_prev) / (1. - alphas_cumprod)
def extract(a, t, x_shape):
batch_size = t.shape[0]
out = a.gather(-1, t.cpu())
return out.reshape(batch_size, *((1,) * (len(x_shape) - 1))).to(t.device)
我们用一个实例来说明前向加噪过程。
from PIL import Image
import requests
url = 'http://images.cocodataset.org/val2017/000000039769.jpg'
image = Image.open(requests.get(url, stream=True).raw)
image
from torchvision.transforms import Compose, ToTensor, Lambda, ToPILImage, CenterCrop, Resize
image_size = 128
transform = Compose([
Resize(image_size),
CenterCrop(image_size),
ToTensor(), # turn into Numpy array of shape HWC, divide by 255
Lambda(lambda t: (t * 2) - 1),
])
x_start = transform(image).unsqueeze(0)
x_start.shape # 输出的结果是 torch.Size([1, 3, 128, 128])
import numpy as np
reverse_transform = Compose([
Lambda(lambda t: (t + 1) / 2),
Lambda(lambda t: t.permute(1, 2, 0)), # CHW to HWC
Lambda(lambda t: t * 255.),
Lambda(lambda t: t.numpy().astype(np.uint8)),
ToPILImage(),
])
准备齐全,接下来就可以定义正向扩散过程了。
# forward diffusion (using the nice property)
def q_sample(x_start, t, noise=None):
if noise is None:
noise = torch.randn_like(x_start)
sqrt_alphas_cumprod_t = extract(sqrt_alphas_cumprod, t, x_start.shape)
sqrt_one_minus_alphas_cumprod_t = extract(
sqrt_one_minus_alphas_cumprod, t, x_start.shape
)
return sqrt_alphas_cumprod_t * x_start + sqrt_one_minus_alphas_cumprod_t * noise
def get_noisy_image(x_start, t):
# add noise
x_noisy = q_sample(x_start, t=t)
# turn back into PIL image
noisy_image = reverse_transform(x_noisy.squeeze())
return noisy_image
可视化一下多个不同t的生成结果。
import matplotlib.pyplot as plt
# use seed for reproducability
torch.manual_seed(0)
# source: https://pytorch.org/vision/stable/auto_examples/plot_transforms.html#sphx-glr-auto-examples-plot-transforms-py
def plot(imgs, with_orig=False, row_title=None, **imshow_kwargs):
if not isinstance(imgs[0], list):
# Make a 2d grid even if there's just 1 row
imgs = [imgs]
num_rows = len(imgs)
num_cols = len(imgs[0]) + with_orig
fig, axs = plt.subplots(figsize=(200,200), nrows=num_rows, ncols=num_cols, squeeze=False)
for row_idx, row in enumerate(imgs):
row = [image] + row if with_orig else row
for col_idx, img in enumerate(row):
ax = axs[row_idx, col_idx]
ax.imshow(np.asarray(img), **imshow_kwargs)
ax.set(xticklabels=[], yticklabels=[], xticks=[], yticks=[])
if with_orig:
axs[0, 0].set(title='Original image')
axs[0, 0].title.set_size(8)
if row_title is not None:
for row_idx in range(num_rows):
axs[row_idx, 0].set(ylabel=row_title[row_idx])
plt.tight_layout()
plot([get_noisy_image(x_start, torch.tensor([t])) for t in [0, 50, 100, 150, 199]])
3.8 定义损失函数
def p_losses(denoise_model, x_start, t, noise=None, loss_type="l1"):
# 先采样噪声
if noise is None:
noise = torch.randn_like(x_start)
# 用采样得到的噪声去加噪图片
x_noisy = q_sample(x_start=x_start, t=t, noise=noise)
predicted_noise = denoise_model(x_noisy, t)
# 根据加噪了的图片去预测采样的噪声
if loss_type == 'l1':
loss = F.l1_loss(noise, predicted_noise)
elif loss_type == 'l2':
loss = F.mse_loss(noise, predicted_noise)
elif loss_type == "huber":
loss = F.smooth_l1_loss(noise, predicted_noise)
else:
raise NotImplementedError()
return loss
3.9 定义数据集 PyTorch Dataset 和 DataLoader
我们使用mnist数据集构造了一个 DataLoader,每个batch由128张 normalize 过的 image 组成。
from datasets import load_dataset
# load dataset from the hub
dataset = load_dataset("fashion_mnist")
image_size = 28
channels = 1
batch_size = 128
from torchvision import transforms
from torch.utils.data import DataLoader
transform = Compose([
transforms.RandomHorizontalFlip(),
transforms.ToTensor(),
transforms.Lambda(lambda t: (t * 2) - 1)
])
def transforms(examples):
examples["pixel_values"] = [transform(image.convert("L")) for image in examples["image"]]
del examples["image"]
return examples
transformed_dataset = dataset.with_transform(transforms).remove_columns("label")
dataloader = DataLoader(transformed_dataset["train"], batch_size=batch_size, shuffle=True)
batch = next(iter(dataloader))
print(batch.keys()) # dict_keys(['pixel_values'])
3.10 采样
采样过程发生在反向去噪时。对于一张纯噪声,扩散模型一步步地去除噪声最终得到真实图片,采样事实上就是定义的去除噪声这一行为。 观察采样算法中第四行, t−1 步的图片是由 t 步的图片减去一个噪声得到的,只不过这个噪声是由网络拟合出来,并且 rescale 过的而已。 这里要注意第四行式子的最后一项,采样时每一步也都会加上一个从正态分布采样的纯噪声。理想情况下,最终我们会得到一张看起来像是从真实数据分布中采样得到的图片。
@torch.no_grad()
def p_sample(model, x, t, t_index):
betas_t = extract(betas, t, x.shape)
sqrt_one_minus_alphas_cumprod_t = extract(
sqrt_one_minus_alphas_cumprod, t, x.shape
)
sqrt_recip_alphas_t = extract(sqrt_recip_alphas, t, x.shape)
# Equation 11 in the paper
# Use our model (noise predictor) to predict the mean
model_mean = sqrt_recip_alphas_t * (
x - betas_t * model(x, t) / sqrt_one_minus_alphas_cumprod_t
)
if t_index == 0:
return model_mean
else:
posterior_variance_t = extract(posterior_variance, t, x.shape)
noise = torch.randn_like(x)
# Algorithm 2 line 4:
return model_mean + torch.sqrt(posterior_variance_t) * noise
# Algorithm 2 (including returning all images)
@torch.no_grad()
def p_sample_loop(model, shape):
device = next(model.parameters()).device
b = shape[0]
# start from pure noise (for each example in the batch)
img = torch.randn(shape, device=device)
imgs = []
for i in tqdm(reversed(range(0, timesteps)), desc='sampling loop time step', total=timesteps):
img = p_sample(model, img, torch.full((b,), i, device=device, dtype=torch.long), i)
imgs.append(img.cpu().numpy())
return imgs
@torch.no_grad()
def sample(model, image_size, batch_size=16, channels=3):
return p_sample_loop(model, shape=(batch_size, channels, image_size, image_size))
3.11 训练
先定义一些辅助生成图片的函数。
from pathlib import Path
def num_to_groups(num, divisor):
groups = num // divisor
remainder = num % divisor
arr = [divisor] * groups
if remainder > 0:
arr.append(remainder)
return arr
results_folder = Path("./results")
results_folder.mkdir(exist_ok = True)
save_and_sample_every = 1000
接下来实例化模型。
from torch.optim import Adam
device = "cuda" if torch.cuda.is_available() else "cpu"
model = Unet(
dim=image_size,
channels=channels,
dim_mults=(1, 2, 4,)
)
model.to(device)
optimizer = Adam(model.parameters(), lr=1e-3)
开始训练!
from torchvision.utils import save_image
epochs = 6
for epoch in range(epochs):
for step, batch in enumerate(dataloader):
optimizer.zero_grad()
batch_size = batch["pixel_values"].shape[0]
batch = batch["pixel_values"].to(device)
# Algorithm 1 line 3: sample t uniformally for every example in the batch
t = torch.randint(0, timesteps, (batch_size,), device=device).long()
loss = p_losses(model, batch, t, loss_type="huber")
if step % 100 == 0:
print("Loss:", loss.item())
loss.backward()
optimizer.step()
# save generated images
if step != 0 and step % save_and_sample_every == 0:
milestone = step // save_and_sample_every
batches = num_to_groups(4, batch_size)
all_images_list = list(map(lambda n: sample(model, batch_size=n, channels=channels), batches))
all_images = torch.cat(all_images_list, dim=0)
all_images = (all_images + 1) * 0.5
save_image(all_images, str(results_folder / f'sample-{milestone}.png'), nrow = 6)
Inference:
# sample 64 images
samples = sample(model, image_size=image_size, batch_size=64, channels=channels)
# show a random one
random_index = 5
plt.imshow(samples[-1][random_index].reshape(image_size, image_size, channels), cmap="gray")
import matplotlib.animation as animation
random_index = 53
fig = plt.figure()
ims = []
for i in range(timesteps):
im = plt.imshow(samples[i][random_index].reshape(image_size, image_size, channels), cmap="gray", animated=True)
ims.append([im])
animate = animation.ArtistAnimation(fig, ims, interval=50, blit=True, repeat_delay=1000)
animate.save('diffusion.gif')
plt.show()
4. 参考文献
原理+代码:Diffusion Model 直观理解
The Annotated Diffusion Model文章来源:https://www.toymoban.com/news/detail-421167.html
【diffusion】扩散模型详解!理论+代码文章来源地址https://www.toymoban.com/news/detail-421167.html
到了这里,关于【深度学习模型】扩散模型(Diffusion Model)基本原理及代码讲解的文章就介绍完了。如果您还想了解更多内容,请在右上角搜索TOY模板网以前的文章或继续浏览下面的相关文章,希望大家以后多多支持TOY模板网!