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outpainting-with-differential-diffusion-demo

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outpainting-with-differential-diffusion-demo

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import gradio as gr
import numpy as np
import time
import math
import random
import torch
import spaces

from diffusers import StableDiffusionXLInpaintPipeline
from PIL import Image, ImageFilter

max_64_bit_int = 2**63 - 1

DESCRIPTION="""
        <h1 style="text-align: center;">Outpainting demo</h1>
        <p style="text-align: center;">This uses code by Fabrice TIERCELIN</p>
        <br/>
        <a href='https://huggingface.co/spaces/clinteroni/outpainting-with-differential-diffusion-demo?duplicate=true'><img src='https://img.shields.io/badge/-Duplicate%20Space-blue?labelColor=white&style=flat&logo=data:image/png;base64,iVBORw0KGgoAAAANSUhEUgAAABAAAAAQCAYAAAAf8/9hAAAAAXNSR0IArs4c6QAAAP5JREFUOE+lk7FqAkEURY+ltunEgFXS2sZGIbXfEPdLlnxJyDdYB62sbbUKpLbVNhyYFzbrrA74YJlh9r079973psed0cvUD4A+4HoCjsA85X0Dfn/RBLBgBDxnQPfAEJgBY+A9gALA4tcbamSzS4xq4FOQAJgCDwV2CPKV8tZAJcAjMMkUe1vX+U+SMhfAJEHasQIWmXNN3abzDwHUrgcRGmYcgKe0bxrblHEB4E/pndMazNpSZGcsZdBlYJcEL9Afo75molJyM2FxmPgmgPqlWNLGfwZGG6UiyEvLzHYDmoPkDDiNm9JR9uboiONcBXrpY1qmgs21x1QwyZcpvxt9NS09PlsPAAAAAElFTkSuQmCC&logoWidth=14'></a>
        <br/>
"""

if torch.cuda.is_available():
    device = "cuda"
    floatType = torch.float16
    variant = "fp16"
else:
    device = "cpu"
    floatType = torch.float32
    variant = None

DESCRIPTION+=f"<p>Running on {device}</p>"

pipe = StableDiffusionXLInpaintPipeline.from_pretrained("diffusers/stable-diffusion-xl-1.0-inpainting-0.1", torch_dtype = floatType, variant = variant)
pipe = pipe.to(device)

def update_seed(is_randomize_seed, seed):
    if is_randomize_seed:
        return random.randint(0, max_64_bit_int)
    return seed

def toggle_debug(is_debug_mode):
    return [gr.update(visible = is_debug_mode)] * 3

def noise_color(color, noise):
    return color + random.randint(- noise, noise)

def check(
    input_image,
    enlarge_top,
    enlarge_right,
    enlarge_bottom,
    enlarge_left,
    prompt,
    negative_prompt,
    smooth_border,
    num_inference_steps,
    guidance_scale,
    image_guidance_scale,
    strength,
    denoising_steps,
    is_randomize_seed,
    seed,
    debug_mode,
    progress = gr.Progress()):
    if input_image is None:
        raise gr.Error("Please provide an image.")

    if prompt is None or prompt == "":
        raise gr.Error("Please provide a prompt input.")

    if (not (enlarge_top is None)) and enlarge_top < 0:
        raise gr.Error("Please provide positive top margin.")

    if (not (enlarge_right is None)) and enlarge_right < 0:
        raise gr.Error("Please provide positive right margin.")

    if (not (enlarge_bottom is None)) and enlarge_bottom < 0:
        raise gr.Error("Please provide positive bottom margin.")

    if (not (enlarge_left is None)) and enlarge_left < 0:
        raise gr.Error("Please provide positive left margin.")

    if (
        (enlarge_top is None or enlarge_top == 0)
        and (enlarge_right is None or enlarge_right == 0)
        and (enlarge_bottom is None or enlarge_bottom == 0)
        and (enlarge_left is None or enlarge_left == 0)
    ):
        raise gr.Error("At least one border must be enlarged.")

def uncrop(
    input_image,
    enlarge_top,
    enlarge_right,
    enlarge_bottom,
    enlarge_left,
    prompt,
    negative_prompt,
    smooth_border,
    num_inference_steps,
    guidance_scale,
    image_guidance_scale,
    strength,
    denoising_steps,
    is_randomize_seed,
    seed,
    debug_mode,
    progress = gr.Progress()):
    check(
        input_image,
        enlarge_top,
        enlarge_right,
        enlarge_bottom,
        enlarge_left,
        prompt,
        negative_prompt,
        smooth_border,
        num_inference_steps,
        guidance_scale,
        image_guidance_scale,
        strength,
        denoising_steps,
        is_randomize_seed,
        seed,
        debug_mode
    )
    start = time.time()
    progress(0, desc = "Preparing data...")

    if enlarge_top is None or enlarge_top == "":
        enlarge_top = 0

    if enlarge_right is None or enlarge_right == "":
        enlarge_right = 0

    if enlarge_bottom is None or enlarge_bottom == "":
        enlarge_bottom = 0

    if enlarge_left is None or enlarge_left == "":
        enlarge_left = 0

    if negative_prompt is None:
        negative_prompt = ""

    if smooth_border is None:
        smooth_border = 0

    if num_inference_steps is None:
        num_inference_steps = 50

    if guidance_scale is None:
        guidance_scale = 7

    if image_guidance_scale is None:
        image_guidance_scale = 1.5

    if strength is None:
        strength = 0.99

    if denoising_steps is None:
        denoising_steps = 1000

    if seed is None:
        seed = random.randint(0, max_64_bit_int)

    random.seed(seed)
    torch.manual_seed(seed)

    original_height, original_width, original_channel = np.array(input_image).shape
    output_width = enlarge_left + original_width + enlarge_right
    output_height = enlarge_top + original_height + enlarge_bottom

    # Enlarged image
    enlarged_image = Image.new(mode = input_image.mode, size = (original_width, original_height), color = "black")
    enlarged_image.paste(input_image, (0, 0))
    enlarged_image = enlarged_image.resize((output_width, output_height))
    enlarged_image = enlarged_image.filter(ImageFilter.BoxBlur(20))

    enlarged_image.paste(input_image, (enlarge_left, enlarge_top))

    horizontally_mirrored_input_image = input_image.transpose(Image.FLIP_LEFT_RIGHT).resize((original_width * 2, original_height))
    enlarged_image.paste(horizontally_mirrored_input_image, (enlarge_left - (original_width * 2), enlarge_top))
    enlarged_image.paste(horizontally_mirrored_input_image, (enlarge_left + original_width, enlarge_top))

    vertically_mirrored_input_image = input_image.transpose(Image.FLIP_TOP_BOTTOM).resize((original_width, original_height * 2))
    enlarged_image.paste(vertically_mirrored_input_image, (enlarge_left, enlarge_top - (original_height * 2)))
    enlarged_image.paste(vertically_mirrored_input_image, (enlarge_left, enlarge_top + original_height))

    returned_input_image = input_image.transpose(Image.ROTATE_180).resize((original_width * 2, original_height * 2))
    enlarged_image.paste(returned_input_image, (enlarge_left - (original_width * 2), enlarge_top - (original_height * 2)))
    enlarged_image.paste(returned_input_image, (enlarge_left - (original_width * 2), enlarge_top + original_height))
    enlarged_image.paste(returned_input_image, (enlarge_left + original_width, enlarge_top - (original_height * 2)))
    enlarged_image.paste(returned_input_image, (enlarge_left + original_width, enlarge_top + original_height))

    enlarged_image = enlarged_image.filter(ImageFilter.BoxBlur(20))

    # Noise image
    noise_image = Image.new(mode = input_image.mode, size = (output_width, output_height), color = "black")
    enlarged_pixels = enlarged_image.load()

    for i in range(output_width):
        for j in range(output_height):
            enlarged_pixel = enlarged_pixels[i, j]
            noise = min(max(enlarge_left - i, i - (enlarge_left + original_width), enlarge_top - j, j - (enlarge_top + original_height), 0), 255)
            noise_image.putpixel((i, j), (noise_color(enlarged_pixel[0], noise), noise_color(enlarged_pixel[1], noise), noise_color(enlarged_pixel[2], noise), 255))

    enlarged_image.paste(noise_image, (0, 0))
    enlarged_image.paste(input_image, (enlarge_left, enlarge_top))

    # Mask
    mask_image = Image.new(mode = input_image.mode, size = (output_width, output_height), color = (255, 255, 255, 0))
    black_mask = Image.new(mode = input_image.mode, size = (original_width - smooth_border, original_height - smooth_border), color = (0, 0, 0, 0))
    mask_image.paste(black_mask, (enlarge_left + (smooth_border // 2), enlarge_top + (smooth_border // 2)))
    mask_image = mask_image.filter(ImageFilter.BoxBlur((smooth_border // 2)))

    # Limited to 1 million pixels
    if 1024 * 1024 < output_width * output_height:
        factor = ((1024 * 1024) / (output_width * output_height))**0.5
        process_width = math.floor(output_width * factor)
        process_height = math.floor(output_height * factor)

        limitation = " Due to technical limitations, the image has been downscaled and then upscaled.";
    else:
        process_width = output_width
        process_height = output_height

        limitation = "";

    # Width and height must be multiple of 8
    if (process_width % 8) != 0 or (process_height % 8) != 0:
        if ((process_width - (process_width % 8) + 8) * (process_height - (process_height % 8) + 8)) <= (1024 * 1024):
            process_width = process_width - (process_width % 8) + 8
            process_height = process_height - (process_height % 8) + 8
        elif (process_height % 8) <= (process_width % 8) and ((process_width - (process_width % 8) + 8) * process_height) <= (1024 * 1024):
            process_width = process_width - (process_width % 8) + 8
            process_height = process_height - (process_height % 8)
        elif (process_width % 8) <= (process_height % 8) and (process_width * (process_height - (process_height % 8) + 8)) <= (1024 * 1024):
            process_width = process_width - (process_width % 8)
            process_height = process_height - (process_height % 8) + 8
        else:
            process_width = process_width - (process_width % 8)
            process_height = process_height - (process_height % 8)

    progress(None, desc = "Processing...")

    output_image = uncrop_on_gpu(
        seed,
        process_width,
        process_height,
        prompt,
        negative_prompt,
        enlarged_image,
        mask_image,
        num_inference_steps,
        guidance_scale,
        image_guidance_scale,
        strength,
        denoising_steps
    )

    if limitation != "":
        output_image = output_image.resize((output_width, output_height))

    if debug_mode == False:
        input_image = None
        enlarged_image = None
        mask_image = None

    end = time.time()
    secondes = int(end - start)
    minutes = math.floor(secondes / 60)
    secondes = secondes - (minutes * 60)
    hours = math.floor(minutes / 60)
    minutes = minutes - (hours * 60)
    return [
        output_image,
        ("Start again to get a different result. " if is_randomize_seed else "") + "The new image is " + str(output_width) + " pixels large and " + str(output_height) + " pixels high, so an image of " + f'{output_width * output_height:,}' + " pixels. The image has been generated in " + ((str(hours) + " h, ") if hours != 0 else "") + ((str(minutes) + " min, ") if hours != 0 or minutes != 0 else "") + str(secondes) + " sec." + limitation,
        input_image,
        enlarged_image,
        mask_image
    ]

@spaces.GPU(duration=120)
def uncrop_on_gpu(
        seed,
        process_width,
        process_height,
        prompt,
        negative_prompt,
        enlarged_image,
        mask_image,
        num_inference_steps,
        guidance_scale,
        image_guidance_scale,
        strength,
        denoising_steps
):
    return pipe(
        seeds = [seed],
        width = process_width,
        height = process_height,
        prompt = prompt,
        negative_prompt = negative_prompt,
        image = enlarged_image,
        mask_image = mask_image,
        num_inference_steps = num_inference_steps,
        guidance_scale = guidance_scale,
        image_guidance_scale = image_guidance_scale,
        strength = strength,
        denoising_steps = denoising_steps,
        show_progress_bar = True
    ).images[0]

with gr.Blocks() as interface:
    gr.HTML(
            DESCRIPTION
    )
    with gr.Row():
        with gr.Column():
            dummy_1 = gr.Label(visible = False)
        with gr.Column():
            enlarge_top = gr.Number(minimum = 0, value = 64, precision = 0, label = "Uncrop on top ⬆️", info = "in pixels")
        with gr.Column():
            dummy_2 = gr.Label(visible = False)
    with gr.Row():
        with gr.Column():
            enlarge_left = gr.Number(minimum = 0, value = 64, precision = 0, label = "Uncrop on left ⬅️", info = "in pixels")
        with gr.Column():
            input_image = gr.Image(label = "Your image", sources = ["upload", "webcam", "clipboard"], type = "pil")
        with gr.Column():
            enlarge_right = gr.Number(minimum = 0, value = 64, precision = 0, label = "Uncrop on right ➡️", info = "in pixels")
    with gr.Row():
        with gr.Column():
            dummy_3 = gr.Label(visible = False)
        with gr.Column():
            enlarge_bottom = gr.Number(minimum = 0, value = 64, precision = 0, label = "Uncrop on bottom ⬇️", info = "in pixels")
        with gr.Column():
            dummy_4 = gr.Label(visible = False)
    with gr.Row():
        prompt = gr.Textbox(label = "Prompt", info = "Describe the subject, the background and the style of image; 77 token limit", placeholder = "Describe what you want to see in the entire image", lines = 2)
    with gr.Row():
        with gr.Accordion("Advanced options", open = False):
            negative_prompt = gr.Textbox(label = "Negative prompt", placeholder = "Describe what you do NOT want to see in the entire image", value = 'Border, frame, painting, scribbling, smear, noise, blur, watermark')
            smooth_border = gr.Slider(minimum = 0, maximum = 1024, value = 0, step = 2, label = "Smooth border", info = "lower=preserve original, higher=seamless")
            num_inference_steps = gr.Slider(minimum = 10, maximum = 100, value = 50, step = 1, label = "Number of inference steps", info = "lower=faster, higher=image quality")
            guidance_scale = gr.Slider(minimum = 1, maximum = 13, value = 7, step = 0.1, label = "Classifier-Free Guidance Scale", info = "lower=image quality, higher=follow the prompt")
            image_guidance_scale = gr.Slider(minimum = 1, value = 1.5, step = 0.1, label = "Image Guidance Scale", info = "lower=image quality, higher=follow the image")
            strength = gr.Slider(value = 0.99, minimum = 0.01, maximum = 1.0, step = 0.01, label = "Strength", info = "lower=follow the original area (discouraged), higher=redraw from scratch")
            denoising_steps = gr.Number(minimum = 0, value = 1000, step = 1, label = "Denoising", info = "lower=irrelevant result, higher=relevant result")
            randomize_seed = gr.Checkbox(label = "\U0001F3B2 Randomize seed", value = True, info = "If checked, result is always different")
            seed = gr.Slider(minimum = 0, maximum = max_64_bit_int, step = 1, randomize = True, label = "Seed")
            debug_mode = gr.Checkbox(label = "Debug mode", value = False, info = "Show intermediate results")

    with gr.Row():
        submit = gr.Button("🚀 Outpaint", variant = "primary")

    with gr.Row():
        uncropped_image = gr.Image(label = "Outpainted image")
    with gr.Row():
        information = gr.HTML()
    with gr.Row():
        original_image = gr.Image(label = "Original image", visible = False)
    with gr.Row():
        enlarged_image = gr.Image(label = "Enlarged image", visible = False)
    with gr.Row():
        mask_image = gr.Image(label = "Mask image", visible = False)

    submit.click(fn = update_seed, inputs = [
        randomize_seed,
        seed
    ], outputs = [
        seed
    ], queue = False, show_progress = False).then(toggle_debug, debug_mode, [
        original_image,
        enlarged_image,
        mask_image
    ], queue = False, show_progress = False).then(check, inputs = [
        input_image,
        enlarge_top,
        enlarge_right,
        enlarge_bottom,
        enlarge_left,
        prompt,
        negative_prompt,
        smooth_border,
        num_inference_steps,
        guidance_scale,
        image_guidance_scale,
        strength,
        denoising_steps,
        randomize_seed,
        seed,
        debug_mode
    ], outputs = [], queue = False,
                     show_progress = False).success(uncrop, inputs = [
        input_image,
        enlarge_top,
        enlarge_right,
        enlarge_bottom,
        enlarge_left,
        prompt,
        negative_prompt,
        smooth_border,
        num_inference_steps,
        guidance_scale,
        image_guidance_scale,
        strength,
        denoising_steps,
        randomize_seed,
        seed,
        debug_mode
    ], outputs = [
        uncropped_image,
        information,
        original_image,
        enlarged_image,
        mask_image
    ], scroll_to_output = True)

    gr.Examples(
        run_on_click = True,
        fn = uncrop,
	    inputs = [
            input_image,
            enlarge_top,
            enlarge_right,
            enlarge_bottom,
            enlarge_left,
            prompt,
            negative_prompt,
            smooth_border,
            num_inference_steps,
            guidance_scale,
            image_guidance_scale,
            strength,
            denoising_steps,
            randomize_seed,
            seed,
            debug_mode
        ],
	    outputs = [
            uncropped_image,
            information,
            original_image,
            enlarged_image,
            mask_image
        ],
        examples = [
                [
                    "./examples/Coucang.jpg",
                    417,
                    0,
                    417,
                    0,
                    "A white Coucang, in a tree, ultrarealistic, realistic, photorealistic, 8k, bokeh",
                    "Border, frame, painting, drawing, cartoon, anime, 3d, scribbling, smear, noise, blur, watermark",
                    0,
                    50,
                    7,
                    1.5,
                    0.99,
                    1000,
                    False,
                    123,
                    False
                ],
            ],
        cache_examples = False,
    )
    
    gr.Markdown(
        """
        ## Credit
        The [example image](https://commons.wikimedia.org/wiki/File:Coucang.jpg) is by Aprisonsan
        and licensed under CC-BY-SA 4.0 International.
        """
    )

    interface.queue().launch()