import subprocess, os, time subprocess.run('pip install -e .', shell=True) print("Installed the repo!") # GLIDE imports from typing import Tuple from IPython.display import display from PIL import Image import numpy as np import torch as th import torch.nn.functional as F from glide_text2im.download import load_checkpoint from glide_text2im.model_creation import ( create_model_and_diffusion, model_and_diffusion_defaults, model_and_diffusion_defaults_upsampler ) # gradio app imports import gradio as gr # Load images! IMAGE_0_ADDR = 'https://github.com/GastonMazzei/escher-project-website/blob/main/0.png?raw=true' IAGE_O_MASK_ADDR = 'https://github.com/GastonMazzei/escher-project-website/blob/main/0-mask.png?raw=true' Oimg = gr.processing_utils.encode_url_or_file_to_base64(IMAGE_0_ADDR) Omask = gr.processing_utils.encode_url_or_file_to_base64(IAGE_O_MASK_ADDR) Oimg = Image.open('0.png') Omask = Image.open('0-mask.png') from torchvision.transforms import ToTensor, ToPILImage image_to_tensor = ToTensor() tensor_to_image = ToPILImage() # This notebook supports both CPU and GPU. # On CPU, generating one sample may take on the order of 20 minutes. # On a GPU, it should be under a minute. has_cuda = th.cuda.is_available() device = th.device('cpu' if not has_cuda else 'cuda') # Implement a counter COUNTER = 0 # Create base model. options = model_and_diffusion_defaults() options['inpaint'] = True options['use_fp16'] = has_cuda options['timestep_respacing'] = '100' # use 100 diffusion steps for fast sampling model, diffusion = create_model_and_diffusion(**options) model.eval() if has_cuda: model.convert_to_fp16() model.to(device) model.load_state_dict(load_checkpoint('base-inpaint', device)) print('total base parameters', sum(x.numel() for x in model.parameters())) # Create upsampler model. options_up = model_and_diffusion_defaults_upsampler() options_up['inpaint'] = True options_up['use_fp16'] = has_cuda options_up['timestep_respacing'] = 'fast27' # use 27 diffusion steps for very fast sampling model_up, diffusion_up = create_model_and_diffusion(**options_up) model_up.eval() if has_cuda: model_up.convert_to_fp16() model_up.to(device) model_up.load_state_dict(load_checkpoint('upsample-inpaint', device)) print('total upsampler parameters', sum(x.numel() for x in model_up.parameters())) # Sampling parameters batch_size = 1 guidance_scale = 5.0 # Tune this parameter to control the sharpness of 256x256 images. # A value of 1.0 is sharper, but sometimes results in grainy artifacts. upsample_temp = 0.997 # Create an classifier-free guidance sampling function def model_fn(x_t, ts, **kwargs): half = x_t[: len(x_t) // 2] combined = th.cat([half, half], dim=0) model_out = model(combined, ts, **kwargs) eps, rest = model_out[:, :3], model_out[:, 3:] cond_eps, uncond_eps = th.split(eps, len(eps) // 2, dim=0) half_eps = uncond_eps + guidance_scale * (cond_eps - uncond_eps) eps = th.cat([half_eps, half_eps], dim=0) return th.cat([eps, rest], dim=1) def denoised_fn(x_start): # Force the model to have the exact right x_start predictions # for the part of the image which is known. return ( x_start * (1 - model_kwargs['inpaint_mask']) + model_kwargs['inpaint_image'] * model_kwargs['inpaint_mask'] ) def show_images(batch: th.Tensor): """ Display a batch of images inline. """ scaled = ((batch + 1)*127.5).round().clamp(0,255).to(th.uint8).cpu() reshaped = scaled.permute(2, 0, 3, 1).reshape([batch.shape[2], -1, 3]) return Image.fromarray(reshaped.numpy()) def read_image(path: str, size: int = 256) -> Tuple[th.Tensor, th.Tensor]: pil_img = Image.open(path).convert('RGB') pil_img = pil_img.resize((size, size), resample=Image.BICUBIC) img = np.array(pil_img) return th.from_numpy(img)[None].permute(0, 3, 1, 2).float() / 127.5 - 1 def pil_to_numpy(pil_img: Image) -> Tuple[th.Tensor, th.Tensor]: img = np.array(pil_img) return th.from_numpy(img)[None].permute(0, 3, 1, 2).float() / 127.5 - 1 model_kwargs = dict() def inpaint(prompt, filename, mode): # A little test to see if we can record in memory :-) global Oimg, Omask if (int(mode) == 0): print(f'[I]: mode 0') content = "Nonexistent file" try: with open(f'{filename}.txt','r') as file: content = file.read() except: pass return content, Oimg elif (int(mode) == 1): time.sleep(80) global COUNTER COUNTER += 1 print(f'[I]: mode 1') try: with open(f'{filename}.txt','w') as file: file.write(prompt) return f'Success', Oimg except: pass return f'Failure to write', Oimg # End of the little test # Set up the images Oimg, Omask = input_img, input_img_with_mask print(prompt) # Save as png for later mask detection :) input_img_256 = input_img.convert('RGB').resize((256, 256), resample=Image.BICUBIC) input_img_64 = input_img.convert('RGB').resize((64, 64), resample=Image.BICUBIC) # Source image we are inpainting source_image_256 = pil_to_numpy(input_img_256) source_image_64 = pil_to_numpy(input_img_64) # Since gradio doesn't supply which pixels were drawn, we need to find it ourselves! # Assuming that all black pixels are meant for inpainting. input_img_with_mask_64 = input_img_with_mask.convert('L').resize((64, 64), resample=Image.BICUBIC) gray_scale_source_image = image_to_tensor(input_img_with_mask_64) source_mask_64 = (gray_scale_source_image!=0).float() source_mask_64_img = tensor_to_image(source_mask_64) # The mask should always be a boolean 64x64 mask, and then we # can upsample it for the second stage. source_mask_64 = source_mask_64.unsqueeze(0) source_mask_256 = F.interpolate(source_mask_64, (256, 256), mode='nearest') ############################## # Sample from the base model # ############################## # Create the text tokens to feed to the model. tokens = model.tokenizer.encode(prompt) tokens, mask = model.tokenizer.padded_tokens_and_mask( tokens, options['text_ctx'] ) # Create the classifier-free guidance tokens (empty) full_batch_size = batch_size * 2 uncond_tokens, uncond_mask = model.tokenizer.padded_tokens_and_mask( [], options['text_ctx'] ) # Pack the tokens together into model kwargs. global model_kwargs model_kwargs = dict( tokens=th.tensor( [tokens] * batch_size + [uncond_tokens] * batch_size, device=device ), mask=th.tensor( [mask] * batch_size + [uncond_mask] * batch_size, dtype=th.bool, device=device, ), # Masked inpainting image inpaint_image=(source_image_64 * source_mask_64).repeat(full_batch_size, 1, 1, 1).to(device), inpaint_mask=source_mask_64.repeat(full_batch_size, 1, 1, 1).to(device), ) # Sample from the base model. model.del_cache() samples = diffusion.p_sample_loop( model_fn, (full_batch_size, 3, options["image_size"], options["image_size"]), device=device, clip_denoised=True, progress=True, model_kwargs=model_kwargs, cond_fn=None, denoised_fn=denoised_fn, )[:batch_size] model.del_cache() ############################## # Upsample the 64x64 samples # ############################## tokens = model_up.tokenizer.encode(prompt) tokens, mask = model_up.tokenizer.padded_tokens_and_mask( tokens, options_up['text_ctx'] ) # Create the model conditioning dict. model_kwargs = dict( # Low-res image to upsample. low_res=((samples+1)*127.5).round()/127.5 - 1, # Text tokens tokens=th.tensor( [tokens] * batch_size, device=device ), mask=th.tensor( [mask] * batch_size, dtype=th.bool, device=device, ), # Masked inpainting image. inpaint_image=(source_image_256 * source_mask_256).repeat(batch_size, 1, 1, 1).to(device), inpaint_mask=source_mask_256.repeat(batch_size, 1, 1, 1).to(device), ) # Sample from the base model. model_up.del_cache() up_shape = (batch_size, 3, options_up["image_size"], options_up["image_size"]) up_samples = diffusion_up.p_sample_loop( model_up, up_shape, noise=th.randn(up_shape, device=device) * upsample_temp, device=device, clip_denoised=True, progress=True, model_kwargs=model_kwargs, cond_fn=None, denoised_fn=denoised_fn, )[:batch_size] model_up.del_cache() return source_mask_64_img, show_images(up_samples) gradio_inputs = [ #gr.inputs.Image(type='pil', # label="Input Image"), # gr.inputs.Image(type='pil', # label="Input Image With Mask"), #Oimg,Omask, gr.inputs.Textbox(label='Conditional Text to Inpaint'), gr.inputs.Textbox(label='Filename'), gr.inputs.Textbox(label='Mode (0 to read, 1 to write)')] # gradio_outputs = [gr.outputs.Image(label='Auto-Detected Mask (From drawn black pixels)')] gradio_outputs = [gr.outputs.Textbox(label='Little test'), gr.outputs.Image(label='Inpainted Image')] examples = [['grass.png', 'grass_with_mask.png', 'a corgi in a field']] title = "GLIDE Inpaint" description = "[WARNING: Queue times may take 4-6 minutes per person if there's no GPU! If there is a GPU, it'll take around 60 seconds] Using GLIDE to inpaint black regions of an input image! Instructions: 1) For the 'Input Image', upload an image. 2) For the 'Input Image with Mask', draw a black-colored mask (either manually with something like Paint, or by using gradio's built-in image editor & add a black-colored shape) IT MUST BE BLACK COLOR, but doesn't have to be rectangular! This is because it auto-detects the mask based on 0 (black) pixel values! 3) For the Conditional Text, type something you'd like to see the black region get filled in with :)" article = "

GLIDE: Towards Photorealistic Image Generation and Editing with Text-Guided Diffusion Models | Github Repo | visitor badge

" iface = gr.Interface(fn=inpaint, inputs=gradio_inputs, outputs=gradio_outputs, examples=examples, title=title, description=description, article=article, ) iface.launch(enable_queue=True)