Overview
This model is a diffusion model for conditional image generation of clothes from the FashionMNIST dataset. The model is a class-conditioned UNet that generates images of clothes conditioned on the class label. The code for this model can be found in this GitHub repository
Usage
As it is a Custom Class Model of the Diffusers library, it can be used as follows:
Setup
import json
import torch
import torchvision
from matplotlib import pyplot as plt
from tqdm.auto import tqdm
from torch import nn
from diffusers import UNet2DModel, DDPMScheduler
import safetensors
from huggingface_hub import hf_hub_download
device = 'mps' if torch.backends.mps.is_available() else 'cuda' if torch.cuda.is_available() else 'cpu'
Load the ClassConditionedUnet model safetensor:
# Custom Class
class ClassConditionedUnet(nn.Module):
def __init__(self, num_classes=10, class_emb_size=10):
super().__init__()
# The embedding layer will map the class label to a vector of size class_emb_size
self.class_emb = nn.Embedding(num_classes, class_emb_size)
# Self.model is an unconditional UNet with extra input channels
# to accept the conditioning information (the class embedding)
self.model = UNet2DModel(
sample_size=28, # output image resolution. Equal to input resolution
in_channels=1 + class_emb_size, # Additional input channels for class cond
out_channels=1, # the number of output channels. Equal to input
layers_per_block=3, # three residual connections (ResNet) per block
block_out_channels=(128, 256, 512), # N of output channels for each block. Inverse for upsampling
down_block_types=(
"DownBlock2D", # a regular ResNet downsampling block
"AttnDownBlock2D",
"AttnDownBlock2D", # a ResNet downsampling block with spatial self-attention
),
up_block_types=(
"AttnUpBlock2D", # a ResNet upsampling block with spatial self-attention
"AttnUpBlock2D",
"UpBlock2D", # a regular ResNet upsampling block
),
dropout = 0.1, # Dropout prob between Conv1 and Conv2 in a block. From Improved DDPM paper
)
# Forward method takes the class labels as an additional argument
def forward(self, x, t, class_labels):
bs, ch, w, h = x.shape # x is shape (bs, 1, 28, 28)
# class conditioning embedding to add as additional input channels
class_cond = self.class_emb(class_labels) # Map to embedding dimension
class_cond = class_cond.view(bs, class_cond.shape[1], 1, 1).expand(bs, class_cond.shape[1], w, h)
# class_cond final shape (bs, 4, 28, 28)
# Model input is now x and class cond concatenated together along dimension 1
# We need provide additional information (the class label)
# to every spatial location (pixel) in the image. Not changing the original
# pixels of the images, but adding new channels.
net_input = torch.cat((x, class_cond), 1) # (bs, 5, 28, 28)
# Feed this to the UNet alongside the timestep and return the prediction
# with image output size
return self.model(net_input, t).sample # (bs, 1, 28, 28)
# Define paths to download the model and scheduler
repo_name = "Huertas97/conditioned-unet-fashion-mnist-non-ema"
# Download the safetensors model file
model_file_path = hf_hub_download(repo_id=repo_name, filename="fashion_class_cond_unet_model_best.safetensors")
# # Load the Class Conditioned UNet model state dictionary
state_dict = safetensors.torch.load_file(model_file_path)
model_classcond_native = ClassConditionedUnet()
model_classcond_native.load_state_dict(state_dict).to(device)
Load the DDPMScheduler:
# Download and load the scheduler configuration file
scheduler_file_path = hf_hub_download(repo_id=repo_name, filename="scheduler_config.json")
with open(scheduler_file_path, 'r') as f:
scheduler_config = json.load(f)
noise_scheduler = DDPMScheduler.from_config(scheduler_config)
Use the model to generate images:
desired_class = [7] # desired class from 0 -> 9
num_samples = 2 # num of images to generate per class
# Prepare random x to start from
x = torch.randn(num_samples*len(desired_class), 1, 28, 28).to(device)
# Prepare the desired classes
y = torch.tensor([[i]*num_samples for i in desired_class]).flatten().to(device)
model_classcond_native = model_classcond_native.to(device)
# Sampling loop
for i, t in tqdm(enumerate(noise_scheduler.timesteps)):
# Get model pred
with torch.no_grad():
residual = model_classcond_native(x, t, y)
# Update sample with step
x = noise_scheduler.step(residual, t, x).prev_sample
# Show the results
fig, ax = plt.subplots(1, 1, figsize=(12, 12))
ax.imshow(torchvision.utils.make_grid(x.detach().cpu().clip(-1, 1), nrow=8)[0], cmap='Greys')
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