onnx-web/api/onnx_web/image.py

from numpy import random
from PIL import Image
from typing import Tuple

import numpy as np


def blend_mult(a):
    return float(a) / 256


def blend_imult(a):
    return 1.0 - blend_mult(a)


def blend_mask_inverse_source(source: Tuple[int, int, int], mask: Tuple[int, int, int], noise: Tuple[int, int, int]) -> Tuple[int, int, int]:
    '''
    Blend operation, linear interpolation from source to noise based on mask: `(s * (1 - m)) + (n * m)`
    '''
    return (
        int((source[0] * blend_imult(mask[0])) +
            (noise[0] * blend_mult(mask[0]))),
        int((source[1] * blend_imult(mask[1])) +
            (noise[1] * blend_mult(mask[1]))),
        int((source[2] * blend_imult(mask[2])) +
            (noise[2] * blend_mult(mask[2]))),
    )


def noise_source_uniform(source_image: Image, dims: Tuple[int, int]) -> Tuple[float, float, float]:
    width, height = dims
    size = width * height

    noise_r = random.uniform(0, 256, size=size)
    noise_g = random.uniform(0, 256, size=size)
    noise_b = random.uniform(0, 256, size=size)

    noise = Image.new('RGB', (width, height))

    for x in range(width):
        for y in range(height):
            i = x * y
            noise.putpixel((x, y), (
                int(noise_r[i]),
                int(noise_g[i]),
                int(noise_b[i])
            ))

    return noise


def noise_source_gaussian(source_image: Image, dims: Tuple[int, int]) -> Tuple[float, float, float]:
    width, height = dims
    size = width * height

    noise_r = random.normal(128, 32, size=size)
    noise_g = random.normal(128, 32, size=size)
    noise_b = random.normal(128, 32, size=size)

    noise = Image.new('RGB', (width, height))

    for x in range(width):
        for y in range(height):
            i = x * y
            noise.putpixel((x, y), (
                int(noise_r[i]),
                int(noise_g[i]),
                int(noise_b[i])
            ))

    return noise


def noise_source_histogram(source_image: Image, dims: Tuple[int, int]) -> Tuple[float, float, float]:
    r, g, b = source_image.split()
    width, height = dims
    size = width * height

    hist_r = r.histogram()
    hist_g = g.histogram()
    hist_b = b.histogram()

    noise_r = random.choice(256, p=np.divide(
        np.copy(hist_r), np.sum(hist_r)), size=size)
    noise_g = random.choice(256, p=np.divide(
        np.copy(hist_g), np.sum(hist_g)), size=size)
    noise_b = random.choice(256, p=np.divide(
        np.copy(hist_b), np.sum(hist_b)), size=size)

    noise = Image.new('RGB', (width, height))

    for x in range(width):
        for y in range(height):
            i = x * y
            noise.putpixel((x, y), (
                noise_r[i],
                noise_g[i],
                noise_b[i]
            ))

    return noise


# based on https://github.com/AUTOMATIC1111/stable-diffusion-webui/blob/master/scripts/outpainting_mk_2.py#L175-L232
def expand_image(
        source_image: Image,
        mask_image: Image,
        expand_by: Tuple[int, int, int, int],
        fill='white',
        noise_source=noise_source_histogram,
        blend_op=blend_mask_inverse_source
):
    left, right, top, bottom = expand_by

    full_width = left + source_image.width + right
    full_height = top + source_image.height + bottom

    full_source = Image.new('RGB', (full_width, full_height), fill)
    full_source.paste(source_image, (left, top))

    full_mask = Image.new('RGB', (full_width, full_height), fill)
    full_mask.paste(mask_image, (left, top))

    full_noise = noise_source(source_image, (full_width, full_height))

    for x in range(full_source.width):
        for y in range(full_source.height):
            mask_color = full_mask.getpixel((x, y))
            noise_color = full_noise.getpixel((x, y))
            source_color = full_source.getpixel((x, y))

            if mask_color[0] > 0:
                full_source.putpixel((x, y), blend_op(
                    source_color, mask_color, noise_color))

    return (full_source, full_mask, full_noise, (full_width, full_height))
feat(gui): produce noise based on source image histogram 2023-01-14 21:19:41 +00:00			`from numpy import random`
use sum of histogram, remove unused imports 2023-01-14 21:36:19 +00:00			`from PIL import Image`
feat(gui): produce noise based on source image histogram 2023-01-14 21:19:41 +00:00			`from typing import Tuple`

			`import numpy as np`

feat(api): add normal and uniform noise sources 2023-01-15 03:46:14 +00:00
per-channel blend 2023-01-14 22:18:37 +00:00			`def blend_mult(a):`
			`return float(a) / 256`
feat(gui): produce noise based on source image histogram 2023-01-14 21:19:41 +00:00
per-channel blend 2023-01-14 22:18:37 +00:00
			`def blend_imult(a):`
			`return 1.0 - blend_mult(a)`


			`def blend_mask_inverse_source(source: Tuple[int, int, int], mask: Tuple[int, int, int], noise: Tuple[int, int, int]) -> Tuple[int, int, int]:`
feat(api): add normal and uniform noise sources 2023-01-15 03:46:14 +00:00			`'''`
			Blend operation, linear interpolation from source to noise based on mask: `(s * (1 - m)) + (n * m)`
			`'''`
feat(gui): produce noise based on source image histogram 2023-01-14 21:19:41 +00:00			`return (`
feat(api): add normal and uniform noise sources 2023-01-15 03:46:14 +00:00			`int((source[0] * blend_imult(mask[0])) +`
			`(noise[0] * blend_mult(mask[0]))),`
			`int((source[1] * blend_imult(mask[1])) +`
			`(noise[1] * blend_mult(mask[1]))),`
			`int((source[2] * blend_imult(mask[2])) +`
			`(noise[2] * blend_mult(mask[2]))),`
feat(gui): produce noise based on source image histogram 2023-01-14 21:19:41 +00:00			`)`


feat(api): add normal and uniform noise sources 2023-01-15 03:46:14 +00:00			`def noise_source_uniform(source_image: Image, dims: Tuple[int, int]) -> Tuple[float, float, float]:`
			`width, height = dims`
			`size = width * height`

			`noise_r = random.uniform(0, 256, size=size)`
			`noise_g = random.uniform(0, 256, size=size)`
			`noise_b = random.uniform(0, 256, size=size)`

			`noise = Image.new('RGB', (width, height))`

			`for x in range(width):`
			`for y in range(height):`
			`i = x * y`
			`noise.putpixel((x, y), (`
			`int(noise_r[i]),`
			`int(noise_g[i]),`
			`int(noise_b[i])`
			`))`

			`return noise`


			`def noise_source_gaussian(source_image: Image, dims: Tuple[int, int]) -> Tuple[float, float, float]:`
			`width, height = dims`
			`size = width * height`

			`noise_r = random.normal(128, 32, size=size)`
			`noise_g = random.normal(128, 32, size=size)`
			`noise_b = random.normal(128, 32, size=size)`

			`noise = Image.new('RGB', (width, height))`

			`for x in range(width):`
			`for y in range(height):`
			`i = x * y`
			`noise.putpixel((x, y), (`
			`int(noise_r[i]),`
			`int(noise_g[i]),`
			`int(noise_b[i])`
			`))`

			`return noise`


			`def noise_source_histogram(source_image: Image, dims: Tuple[int, int]) -> Tuple[float, float, float]:`
feat(gui): produce noise based on source image histogram 2023-01-14 21:19:41 +00:00			`r, g, b = source_image.split()`
			`width, height = dims`
flatten noise data 2023-01-14 21:44:19 +00:00			`size = width * height`
feat(gui): produce noise based on source image histogram 2023-01-14 21:19:41 +00:00
			`hist_r = r.histogram()`
			`hist_g = g.histogram()`
			`hist_b = b.histogram()`

feat(api): add normal and uniform noise sources 2023-01-15 03:46:14 +00:00			`noise_r = random.choice(256, p=np.divide(`
			`np.copy(hist_r), np.sum(hist_r)), size=size)`
			`noise_g = random.choice(256, p=np.divide(`
			`np.copy(hist_g), np.sum(hist_g)), size=size)`
			`noise_b = random.choice(256, p=np.divide(`
			`np.copy(hist_b), np.sum(hist_b)), size=size)`
feat(gui): produce noise based on source image histogram 2023-01-14 21:19:41 +00:00
build noise by pixels 2023-01-14 22:14:37 +00:00			`noise = Image.new('RGB', (width, height))`

			`for x in range(width):`
			`for y in range(height):`
			`i = x * y`
			`noise.putpixel((x, y), (`
			`noise_r[i],`
			`noise_g[i],`
			`noise_b[i]`
			`))`
feat(gui): produce noise based on source image histogram 2023-01-14 21:19:41 +00:00
			`return noise`


			`# based on https://github.com/AUTOMATIC1111/stable-diffusion-webui/blob/master/scripts/outpainting_mk_2.py#L175-L232`
feat(api): add normal and uniform noise sources 2023-01-15 03:46:14 +00:00			`def expand_image(`
			`source_image: Image,`
			`mask_image: Image,`
			`expand_by: Tuple[int, int, int, int],`
			`fill='white',`
			`noise_source=noise_source_histogram,`
			`blend_op=blend_mask_inverse_source`
			`):`
			`left, right, top, bottom = expand_by`
feat(gui): produce noise based on source image histogram 2023-01-14 21:19:41 +00:00
			`full_width = left + source_image.width + right`
			`full_height = top + source_image.height + bottom`

			`full_source = Image.new('RGB', (full_width, full_height), fill)`
			`full_source.paste(source_image, (left, top))`

			`full_mask = Image.new('RGB', (full_width, full_height), fill)`
			`full_mask.paste(mask_image, (left, top))`

feat(api): add normal and uniform noise sources 2023-01-15 03:46:14 +00:00			`full_noise = noise_source(source_image, (full_width, full_height))`
feat(gui): produce noise based on source image histogram 2023-01-14 21:19:41 +00:00
			`for x in range(full_source.width):`
			`for y in range(full_source.height):`
			`mask_color = full_mask.getpixel((x, y))`
			`noise_color = full_noise.getpixel((x, y))`
			`source_color = full_source.getpixel((x, y))`

			`if mask_color[0] > 0:`
feat(api): add normal and uniform noise sources 2023-01-15 03:46:14 +00:00			`full_source.putpixel((x, y), blend_op(`
			`source_color, mask_color, noise_color))`
feat(gui): produce noise based on source image histogram 2023-01-14 21:19:41 +00:00
syntax fix, save noise image 2023-01-14 22:03:56 +00:00			`return (full_source, full_mask, full_noise, (full_width, full_height))`