#!pip install -q --upgrade transformers diffusers ftfy #!pip install -q --upgrade transformers==4.25.1 diffusers ftfy #!pip install accelerate -q from base64 import b64encode import numpy import torch from diffusers import AutoencoderKL, LMSDiscreteScheduler, UNet2DConditionModel from huggingface_hub import notebook_login # For video display: from IPython.display import HTML from matplotlib import pyplot as plt from pathlib import Path from PIL import Image from torch import autocast from torchvision import transforms as tfms from tqdm.auto import tqdm from transformers import CLIPTextModel, CLIPTokenizer, logging import gradio as gr torch.manual_seed(1) #if not (Path.home()/'.huggingface'/'token').exists(): notebook_login() # Supress some unnecessary warnings when loading the CLIPTextModel logging.set_verbosity_error() # Set device torch_device = "cuda" if torch.cuda.is_available() else "cpu" import os MY_TOKEN=os.environ.get('HF_TOKEN_SD') # Load the autoencoder model which will be used to decode the latents into image space. vae = AutoencoderKL.from_pretrained("CompVis/stable-diffusion-v1-4", subfolder="vae",use_auth_token=MY_TOKEN) # Load the tokenizer and text encoder to tokenize and encode the text. tokenizer = CLIPTokenizer.from_pretrained("openai/clip-vit-large-patch14") text_encoder = CLIPTextModel.from_pretrained("openai/clip-vit-large-patch14") # The UNet model for generating the latents. unet = UNet2DConditionModel.from_pretrained("CompVis/stable-diffusion-v1-4", subfolder="unet") # The noise scheduler scheduler = LMSDiscreteScheduler(beta_start=0.00085, beta_end=0.012, beta_schedule="scaled_linear", num_train_timesteps=1000) # To the GPU we go! vae = vae.to(torch_device) text_encoder = text_encoder.to(torch_device) unet = unet.to(torch_device) """Functions""" def pil_to_latent(input_im): # Single image -> single latent in a batch (so size 1, 4, 64, 64) with torch.no_grad(): latent = vae.encode(tfms.ToTensor()(input_im).unsqueeze(0).to(torch_device)*2-1) # Note scaling return 0.18215 * latent.latent_dist.sample() def latents_to_pil(latents): # bath of latents -> list of images latents = (1 / 0.18215) * latents with torch.no_grad(): image = vae.decode(latents).sample image = (image / 2 + 0.5).clamp(0, 1) image = image.detach().cpu().permute(0, 2, 3, 1).numpy() images = (image * 255).round().astype("uint8") pil_images = [Image.fromarray(image) for image in images] return pil_images def get_output_embeds(input_embeddings): # CLIP's text model uses causal mask, so we prepare it here: bsz, seq_len = input_embeddings.shape[:2] causal_attention_mask = text_encoder.text_model._build_causal_attention_mask(bsz, seq_len, dtype=input_embeddings.dtype) # Getting the output embeddings involves calling the model with passing output_hidden_states=True # so that it doesn't just return the pooled final predictions: encoder_outputs = text_encoder.text_model.encoder( inputs_embeds=input_embeddings, attention_mask=None, # We aren't using an attention mask so that can be None causal_attention_mask=causal_attention_mask.to(torch_device), output_attentions=None, output_hidden_states=True, # We want the output embs not the final output return_dict=None, ) # We're interested in the output hidden state only output = encoder_outputs[0] # There is a final layer norm we need to pass these through output = text_encoder.text_model.final_layer_norm(output) # And now they're ready! return output #Generating an image with these modified embeddings def generate_with_embs(text_embeddings, text_input): height = 512 # default height of Stable Diffusion width = 512 # default width of Stable Diffusion num_inference_steps = 10 # Number of denoising steps guidance_scale = 7.5 # Scale for classifier-free guidance generator = torch.manual_seed(64) # Seed generator to create the inital latent noise batch_size = 1 max_length = text_input.input_ids.shape[-1] uncond_input = tokenizer( [""] * batch_size, padding="max_length", max_length=max_length, return_tensors="pt" ) with torch.no_grad(): uncond_embeddings = text_encoder(uncond_input.input_ids.to(torch_device))[0] text_embeddings = torch.cat([uncond_embeddings, text_embeddings]) # Prep Scheduler scheduler.set_timesteps(num_inference_steps) # Prep latents latents = torch.randn( (batch_size, unet.config.in_channels, height // 8, width // 8), generator=generator, ) latents = latents.to(torch_device) latents = latents * scheduler.init_noise_sigma # Loop for i, t in tqdm(enumerate(scheduler.timesteps)): # expand the latents if we are doing classifier-free guidance to avoid doing two forward passes. latent_model_input = torch.cat([latents] * 2) sigma = scheduler.sigmas[i] latent_model_input = scheduler.scale_model_input(latent_model_input, t) # predict the noise residual with torch.no_grad(): noise_pred = unet(latent_model_input, t, encoder_hidden_states=text_embeddings)["sample"] # perform guidance noise_pred_uncond, noise_pred_text = noise_pred.chunk(2) noise_pred = noise_pred_uncond + guidance_scale * (noise_pred_text - noise_pred_uncond) # compute the previous noisy sample x_t -> x_t-1 latents = scheduler.step(noise_pred, t, latents).prev_sample return latents_to_pil(latents)[0] def ref_loss(images,ref_image): # Reference image error = torch.abs(images - ref_image).mean() return error def inference(prompt, style_index): styles = ['', '','','','','',''] embed = ['learned_embeds_m.bin','learned_embeds_h.bin', 'learned_embeds.bin', 'learned_embeds_s.bin','learned_embeds_i.bin','learned_embeds_mg.bin','learned_embeds_buhu.bin'] # Tokenize text_input = tokenizer(prompt+" .", padding="max_length", max_length=tokenizer.model_max_length, truncation=True, return_tensors="pt") # Access the embedding layer token_emb_layer = text_encoder.text_model.embeddings.token_embedding token_embeddings = token_emb_layer(text_input.input_ids.to(torch_device)) pos_emb_layer = text_encoder.text_model.embeddings.position_embedding position_ids = text_encoder.text_model.embeddings.position_ids[:, :77] position_embeddings = pos_emb_layer(position_ids) ## Without any Textual Inversion input_ids = text_input.input_ids.to(torch_device) # Get token embeddings token_embeddings = token_emb_layer(input_ids) # Combine with pos embs input_embeddings = token_embeddings + position_embeddings # Feed through to get final output embs modified_output_embeddings = get_output_embeds(input_embeddings) # And generate an image with this: image1 = generate_with_embs(modified_output_embeddings,text_input) replace_id=269 #replaced dot with Textual Inversion ## midjourney-style style = styles[style_index] emb = embed[style_index] x_embed = torch.load(emb) # The new embedding - our special birb word replacement_token_embedding = x_embed[style].to(torch_device) # Insert this into the token embeddings token_embeddings[0, torch.where(input_ids[0]==replace_id)] = replacement_token_embedding.to(torch_device) # Combine with pos embs input_embeddings = token_embeddings + position_embeddings # Feed through to get final output embs modified_output_embeddings = get_output_embeds(input_embeddings) # And generate an image with this: image2 = generate_with_embs(modified_output_embeddings,text_input) prompt1 = 'rainbow' # Tokenize text_input1 = tokenizer(prompt1, padding="max_length", max_length=tokenizer.model_max_length, truncation=True, return_tensors="pt") # Access the embedding layer token_emb_layer = text_encoder.text_model.embeddings.token_embedding pos_emb_layer = text_encoder.text_model.embeddings.position_embedding position_ids = text_encoder.text_model.embeddings.position_ids[:, :77] position_embeddings1 = pos_emb_layer(position_ids) input_ids1 = text_input1.input_ids.to(torch_device) # Get token embeddings token_embeddings1 = token_emb_layer(input_ids1) # Combine with pos embs input_embeddings1 = token_embeddings1 + position_embeddings1 # Feed through to get final output embs modified_output_embeddings1 = get_output_embeds(input_embeddings1) # And generate an image with this: ref_image = generate_with_embs(modified_output_embeddings1, text_input1) ref_latent = pil_to_latent(ref_image) height = 512 # default height of Stable Diffusion width = 512 # default width of Stable Diffusion num_inference_steps = 10 # # Number of denoising steps guidance_scale = 8 # # Scale for classifier-free guidance generator = torch.manual_seed(64) # Seed generator to create the inital latent noise batch_size = 1 blue_loss_scale = 200 # # Prep text text_input = tokenizer([prompt], padding="max_length", max_length=tokenizer.model_max_length, truncation=True, return_tensors="pt") with torch.no_grad(): text_embeddings = text_encoder(text_input.input_ids.to(torch_device))[0] # And the uncond. input as before: max_length = text_input.input_ids.shape[-1] uncond_input = tokenizer( [""] * batch_size, padding="max_length", max_length=max_length, return_tensors="pt" ) with torch.no_grad(): uncond_embeddings = text_encoder(uncond_input.input_ids.to(torch_device))[0] text_embeddings = torch.cat([uncond_embeddings, text_embeddings]) # Prep Scheduler scheduler.set_timesteps(num_inference_steps) # Prep latents latents = torch.randn( (batch_size, unet.config.in_channels, height // 8, width // 8), generator=generator, ) latents = latents.to(torch_device) latents = latents * scheduler.init_noise_sigma # Loop for i, t in tqdm(enumerate(scheduler.timesteps)): # expand the latents if we are doing classifier-free guidance to avoid doing two forward passes. latent_model_input = torch.cat([latents] * 2) sigma = scheduler.sigmas[i] latent_model_input = scheduler.scale_model_input(latent_model_input, t) # predict the noise residual with torch.no_grad(): noise_pred = unet(latent_model_input, t, encoder_hidden_states=text_embeddings)["sample"] # perform CFG noise_pred_uncond, noise_pred_text = noise_pred.chunk(2) noise_pred = noise_pred_uncond + guidance_scale * (noise_pred_text - noise_pred_uncond) #### ADDITIONAL GUIDANCE ### if i%5 == 0: # Requires grad on the latents latents = latents.detach().requires_grad_() # Get the predicted x0: # latents_x0 = latents - sigma * noise_pred latents_x0 = scheduler.step(noise_pred, t, latents).pred_original_sample # Decode to image space denoised_images = vae.decode((1 / 0.18215) * latents_x0).sample / 2 + 0.5 # range (0, 1) #ref image with torch.no_grad(): ref_images = vae.decode((1 / 0.18215) * ref_latent).sample / 2 + 0.5 # range (0, 1) # Calculate loss loss = ref_loss(denoised_images,ref_images) * blue_loss_scale # Occasionally print it out # if i%10==0: # print(i, 'loss:', loss.item()) # Get gradient cond_grad = torch.autograd.grad(loss, latents)[0] # Modify the latents based on this gradient latents = latents.detach() - cond_grad * sigma**2 scheduler._step_index = scheduler._step_index - 1 # Now step with scheduler latents = scheduler.step(noise_pred, t, latents).prev_sample #latents = scheduler.step(noise_pred, t, latents).pred_original_sample image3 = latents_to_pil(latents)[0] return (image1, 'Original Image'), (image2, 'Styled Image'), (image3, 'After Textual Inversion') # Gradio App with num_inference_steps=10 title="Textual Inversion in Stable Diffusion" description="

Textual Inversion in Stable Diffusion.

" gallery = gr.Gallery(label="Generated images", show_label=True, elem_id="gallery", columns=3).style(grid=[2], height="auto") gr.Interface(fn=inference, inputs=["text", gr.Radio([('',0), ('',1),('',2), ('',3),('',4),('',5),('',6)] , value = 0, label = 'Style')], outputs = gallery, title = title, examples = [['a girl playing in snow',0], #['an oil painting of a goddess',6], #['a rabbit on the moon', 5 ] ], ).launch(debug=True)