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import gradio as gr
import torch
import requests
from io import BytesIO
from diffusers import StableDiffusionPipeline
from diffusers import DDIMScheduler
from utils import *
from inversion_utils import *
from modified_pipeline_semantic_stable_diffusion import SemanticStableDiffusionPipeline
from torch import autocast, inference_mode
def invert(x0, prompt_src="", num_diffusion_steps=100, cfg_scale_src = 3.5, eta = 1):
# inverts a real image according to Algorihm 1 in https://arxiv.org/pdf/2304.06140.pdf,
# based on the code in https://github.com/inbarhub/DDPM_inversion
# returns wt, zs, wts:
# wt - inverted latent
# wts - intermediate inverted latents
# zs - noise maps
sd_pipe.scheduler.set_timesteps(num_diffusion_steps)
# vae encode image
with autocast("cuda"), inference_mode():
w0 = (sd_pipe.vae.encode(x0).latent_dist.mode() * 0.18215).float()
# find Zs and wts - forward process
wt, zs, wts = inversion_forward_process(sd_pipe, w0, etas=eta, prompt=prompt_src, cfg_scale=cfg_scale_src, prog_bar=True, num_inference_steps=num_diffusion_steps)
return wt, zs, wts
def sample(wt, zs, wts, prompt_tar="", cfg_scale_tar=15, skip=36, eta = 1):
# reverse process (via Zs and wT)
w0, _ = inversion_reverse_process(sd_pipe, xT=wts[skip], etas=eta, prompts=[prompt_tar], cfg_scales=[cfg_scale_tar], prog_bar=True, zs=zs[skip:])
# vae decode image
with autocast("cuda"), inference_mode():
x0_dec = sd_pipe.vae.decode(1 / 0.18215 * w0).sample
if x0_dec.dim()<4:
x0_dec = x0_dec[None,:,:,:]
img = image_grid(x0_dec)
return img
# load pipelines
sd_model_id = "runwayml/stable-diffusion-v1-5"
device = torch.device("cuda" if torch.cuda.is_available() else "cpu")
sd_pipe = StableDiffusionPipeline.from_pretrained(sd_model_id).to(device)
sd_pipe.scheduler = DDIMScheduler.from_config(sd_model_id, subfolder = "scheduler")
sem_pipe = SemanticStableDiffusionPipeline.from_pretrained(sd_model_id).to(device)
def edit(input_image, input_image_prompt='', target_prompt='', edit_prompt='',
negative_guidance = False, edit_warmup_steps=5,
edit_guidance_scale=8, guidance_scale=15, skip=36, num_diffusion_steps=100,
):
offsets=(0,0,0,0)
x0 = load_512(input_image, *offsets, device)
# invert
wt, zs, wts = invert(x0 =x0 , prompt_src=input_image_prompt, num_diffusion_steps=num_diffusion_steps)
latnets = wts[skip].expand(1, -1, -1, -1)
eta = 1
#pure DDPM output
pure_ddpm_out = sample(wt, zs, wts, prompt_tar=target_prompt,
cfg_scale_tar=guidance_scale, skip=skip,
eta = eta)
editing_args = dict(
editing_prompt = [edit_prompt],
reverse_editing_direction = [negative_guidance],
edit_warmup_steps=[edit_warmup_steps],
edit_guidance_scale=[edit_guidance_scale],
edit_threshold=[.93],
edit_momentum_scale=0.5,
edit_mom_beta=0.6
)
sega_out = sem_pipe(prompt=target_prompt,eta=eta, latents=latnets,
num_images_per_prompt=1,
num_inference_steps=num_diffusion_steps,
use_ddpm=True, wts=wts, zs=zs[skip:], **editing_args)
return pure_ddpm_out,sega_out.images[0]
# See the gradio docs for the types of inputs and outputs available
inputs = [
gr.Image(label="input image", shape=(512, 512)),
gr.Textbox(label="input prompt"),
gr.Textbox(label="target prompt"),
gr.Textbox(label="SEGA edit concept"),
gr.Checkbox(label="SEGA negative_guidance"),
gr.Slider(label="warmup steps", minimum=1, maximum=30, value=5),
gr.Slider(label="edit guidance scale", minimum=0, maximum=15, value=3.5),
gr.Slider(label="guidance scale", minimum=7, maximum=18, value=15),
gr.Slider(label="skip", minimum=0, maximum=40, value=36),
gr.Slider(label="num diffusion steps", minimum=0, maximum=300, value=100)
]
outputs = [gr.Image(label="DDPM"),gr.Image(label="DDPM+SEGA")]
# And the minimal interface
demo = gr.Interface(
fn=edit,
inputs=inputs,
outputs=outputs,
)
demo.launch() # debug=True allows you to see errors and output in Colab |