Datasets:

HuggingFace-CN-community
/

Diffusion-book-cn

	import wandb
	import numpy as np
	import torch, torchvision
	import torch.nn.functional as F
	from PIL import Image
	from tqdm.auto import tqdm
	from fastcore.script import call_parse
	from torchvision import transforms
	from diffusers import DDPMPipeline
	from diffusers import DDIMScheduler
	from datasets import load_dataset
	from matplotlib import pyplot as plt

	@call_parse
	def train(
	image_size = 256,
	batch_size = 16,
	grad_accumulation_steps = 2,
	num_epochs = 1,
	start_model = "google/ddpm-bedroom-256",
	dataset_name = "huggan/wikiart",
	device='cuda',
	model_save_name='wikiart_1e',
	wandb_project='dm_finetune',
	log_samples_every = 250,
	save_model_every = 2500,
	):

	# Initialize wandb for logging
	wandb.init(project=wandb_project, config=locals())


	# Prepare pretrained model
	image_pipe = DDPMPipeline.from_pretrained(start_model);
	image_pipe.to(device)

	# Get a scheduler for sampling
	sampling_scheduler = DDIMScheduler.from_config(start_model)
	sampling_scheduler.set_timesteps(num_inference_steps=50)

	# Prepare dataset
	dataset = load_dataset(dataset_name, split="train")
	preprocess = transforms.Compose(
	[
	transforms.Resize((image_size, image_size)),
	transforms.RandomHorizontalFlip(),
	transforms.ToTensor(),
	transforms.Normalize([0.5], [0.5]),
	]
	)
	def transform(examples):
	images = [preprocess(image.convert("RGB")) for image in examples["image"]]
	return {"images": images}
	dataset.set_transform(transform)
	train_dataloader = torch.utils.data.DataLoader(dataset, batch_size=batch_size, shuffle=True)


	# Optimizer & lr scheduler
	optimizer = torch.optim.AdamW(image_pipe.unet.parameters(), lr=1e-5)
	scheduler = torch.optim.lr_scheduler.ExponentialLR(optimizer, gamma=0.9)

	for epoch in range(num_epochs):
	for step, batch in tqdm(enumerate(train_dataloader), total=len(train_dataloader)):

	# Get the clean images
	clean_images = batch['images'].to(device)

	# Sample noise to add to the images
	noise = torch.randn(clean_images.shape).to(clean_images.device)
	bs = clean_images.shape[0]

	# Sample a random timestep for each image
	timesteps = torch.randint(0, image_pipe.scheduler.num_train_timesteps, (bs,), device=clean_images.device).long()

	# Add noise to the clean images according to the noise magnitude at each timestep
	# (this is the forward diffusion process)
	noisy_images = image_pipe.scheduler.add_noise(clean_images, noise, timesteps)

	# Get the model prediction for the noise
	noise_pred = image_pipe.unet(noisy_images, timesteps, return_dict=False)[0]

	# Compare the prediction with the actual noise:
	loss = F.mse_loss(noise_pred, noise)

	# Log the loss
	wandb.log({'loss':loss.item()})

	# Calculate the gradients
	loss.backward()

	# Gradient Acccumulation: Only update every grad_accumulation_steps
	if (step+1)%grad_accumulation_steps == 0:
	optimizer.step()
	optimizer.zero_grad()

	# Occasionally log samples
	if (step+1)%log_samples_every == 0:
	x = torch.randn(8, 3, 256, 256).to(device) # Batch of 8
	for i, t in tqdm(enumerate(sampling_scheduler.timesteps)):
	model_input = sampling_scheduler.scale_model_input(x, t)
	with torch.no_grad():
	noise_pred = image_pipe.unet(model_input, t)["sample"]
	x = sampling_scheduler.step(noise_pred, t, x).prev_sample
	grid = torchvision.utils.make_grid(x, nrow=4)
	im = grid.permute(1, 2, 0).cpu().clip(-1, 1)*0.5 + 0.5
	im = Image.fromarray(np.array(im*255).astype(np.uint8))
	wandb.log({'Sample generations': wandb.Image(im)})

	# Occasionally save model
	if (step+1)%save_model_every == 0:
	image_pipe.save_pretrained(model_save_name+f'step_{step+1}')

	# Update the learning rate for the next epoch
	scheduler.step()

	# Save the pipeline one last time
	image_pipe.save_pretrained(model_save_name)

	# Wrap up the run
	wandb.finish()