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sd-webui-forge-classic / extensions-builtin /sd_forge_controlnet /lib_controlnet /utils.py

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	from modules.safe import unsafe_torch_load
	from modules import processing

	from PIL import Image, ImageFilter, ImageOps
	from typing import Optional, Callable
	import safetensors.torch
	import numpy as np
	import functools
	import logging
	import base64
	import torch
	import time
	import cv2
	import os
	import io

	from lib_controlnet.lvminthin import lvmin_thin, nake_nms
	from lib_controlnet.logging import logger
	from lib_controlnet import external_code

	try:
	from reportlab.graphics import renderPM
	from svglib.svglib import svg2rlg
	except ImportError:
	svgSupport = False
	else:
	svgSupport = True


	def load_state_dict(ckpt_path, location="cpu"):
	_, extension = os.path.splitext(ckpt_path)
	if extension.lower() == ".safetensors":
	state_dict = safetensors.torch.load_file(ckpt_path, device=location)
	else:
	state_dict = unsafe_torch_load(ckpt_path, map_location=torch.device(location))
	state_dict = get_state_dict(state_dict)
	logger.info(f"Loaded state_dict from [{ckpt_path}]")
	return state_dict


	def get_state_dict(d):
	return d.get("state_dict", d)


	def timer_decorator(func):
	"""Time the decorated function and output the result to debug logger"""
	if logger.level != logging.DEBUG:
	return func

	@functools.wraps(func)
	def wrapper(args, *kwargs):
	start_time = time.time()
	result = func(args, *kwargs)
	end_time = time.time()
	duration = end_time - start_time
	# Only report function that are significant enough
	if duration > 1e-3:
	logger.debug(f"{func.__name__} ran in: {duration:.3f} sec")
	return result

	return wrapper


	class TimeMeta(type):
	"""
	Metaclass to record execution time on all methods of the child class
	"""

	def __new__(cls, name, bases, attrs):
	for attr_name, attr_value in attrs.items():
	if callable(attr_value):
	attrs[attr_name] = timer_decorator(attr_value)
	return super().__new__(cls, name, bases, attrs)


	@functools.lru_cache(maxsize=1, typed=False)
	def _blank_mask() -> str:
	with io.BytesIO() as buffer:
	black = Image.new("RGB", (4, 4))
	black.save(buffer, format="PNG")
	b64 = base64.b64encode(buffer.getvalue()).decode()
	return b64


	def svg_preprocess(inputs: dict, preprocess: Callable):
	if not inputs:
	return None

	if svgSupport and inputs["image"].startswith("data:image/svg+xml;base64,"):
	svg_data = base64.b64decode(inputs["image"].replace("data:image/svg+xml;base64,", ""))
	drawing = svg2rlg(io.BytesIO(svg_data))
	png_data = renderPM.drawToString(drawing, fmt="PNG")
	encoded_string = base64.b64encode(png_data)
	base64_str = str(encoded_string, "utf-8")
	base64_str = "data:image/png;base64," + base64_str
	inputs["image"] = base64_str

	if inputs.get("mask", None) is None:
	inputs["mask"] = _blank_mask()

	return preprocess(inputs)


	def get_unique_axis0(data):
	arr = np.asanyarray(data)
	idxs = np.lexsort(arr.T)
	arr = arr[idxs]
	unique_idxs = np.empty(len(arr), dtype=np.bool_)
	unique_idxs[:1] = True
	unique_idxs[1:] = np.any(arr[:-1, :] != arr[1:, :], axis=-1)
	return arr[unique_idxs]


	def align_dim_latent(x: int) -> int:
	"""
	Align the pixel dimension (w/h) to latent dimension.
	Stable diffusion 1:8 ratio for latent/pixel
	i.e. 1 latent unit == 8 pixel unit
	"""
	return (x // 8) * 8


	def prepare_mask(mask: Image.Image, p: processing.StableDiffusionProcessing) -> Image.Image:
	"""
	Prepare an image mask for the inpainting process.

	This function takes as input a PIL Image object and an instance of the
	StableDiffusionProcessing class, and performs the following steps to prepare the mask:

	1. Convert the mask to grayscale (mode "L").
	2. If the 'inpainting_mask_invert' attribute of the processing instance is True,
	invert the mask colors.
	3. If the 'mask_blur' attribute of the processing instance is greater than 0,
	apply a Gaussian blur to the mask with a radius equal to 'mask_blur'.

	Args:
	mask (Image.Image): The input mask as a PIL Image object.
	p (processing.StableDiffusionProcessing): An instance of the StableDiffusionProcessing class
	containing the processing parameters.

	Returns:
	mask (Image.Image): The prepared mask as a PIL Image object.
	"""
	mask = mask.convert("L")
	if getattr(p, "inpainting_mask_invert", False):
	mask = ImageOps.invert(mask)

	if hasattr(p, "mask_blur_x"):
	if getattr(p, "mask_blur_x", 0) > 0:
	np_mask = np.array(mask)
	kernel_size = 2 * int(2.5 * p.mask_blur_x + 0.5) + 1
	np_mask = cv2.GaussianBlur(np_mask, (kernel_size, 1), p.mask_blur_x)
	mask = Image.fromarray(np_mask)
	if getattr(p, "mask_blur_y", 0) > 0:
	np_mask = np.array(mask)
	kernel_size = 2 * int(2.5 * p.mask_blur_y + 0.5) + 1
	np_mask = cv2.GaussianBlur(np_mask, (1, kernel_size), p.mask_blur_y)
	mask = Image.fromarray(np_mask)
	else:
	if getattr(p, "mask_blur", 0) > 0:
	mask = mask.filter(ImageFilter.GaussianBlur(p.mask_blur))

	return mask


	def set_numpy_seed(p: processing.StableDiffusionProcessing) -> Optional[int]:
	"""
	Set the random seed for NumPy based on the provided parameters.

	Args:
	p (processing.StableDiffusionProcessing): The instance of the StableDiffusionProcessing class.

	Returns:
	Optional[int]: The computed random seed if successful, or None if an exception occurs.

	This function sets the random seed for NumPy using the seed and subseed values from the given instance of
	StableDiffusionProcessing. If either seed or subseed is -1, it uses the first value from `all_seeds`.
	Otherwise, it takes the maximum of the provided seed value and 0.

	The final random seed is computed by adding the seed and subseed values, applying a bitwise AND operation
	with 0xFFFFFFFF to ensure it fits within a 32-bit integer.
	"""
	try:
	tmp_seed = int(p.all_seeds[0] if p.seed == -1 else max(int(p.seed), 0))
	tmp_subseed = int(p.all_seeds[0] if p.subseed == -1 else max(int(p.subseed), 0))
	seed = (tmp_seed + tmp_subseed) & 0xFFFFFFFF
	np.random.seed(seed)
	return seed
	except Exception as e:
	logger.warning(e)
	logger.warning("Warning: Failed to use consistent random seed.")
	return None


	def safe_numpy(x):
	"""A very safe method to make sure that Mac works"""
	y = x
	y = y.copy()
	y = np.ascontiguousarray(y)
	y = y.copy()
	return y


	def high_quality_resize(x, size):
	"""
	Written by lvmin
	Super high-quality control map up-scaling, considering binary, seg, and one-pixel edges
	"""

	if x.shape[0] != size[1] or x.shape[1] != size[0]:
	new_size_is_smaller = (size[0] * size[1]) < (x.shape[0] * x.shape[1])
	new_size_is_bigger = (size[0] * size[1]) > (x.shape[0] * x.shape[1])
	unique_color_count = len(get_unique_axis0(x.reshape(-1, x.shape[2])))
	is_one_pixel_edge = False
	is_binary = False
	if unique_color_count == 2:
	is_binary = np.min(x) < 16 and np.max(x) > 240
	if is_binary:
	xc = x
	xc = cv2.erode(xc, np.ones(shape=(3, 3), dtype=np.uint8), iterations=1)
	xc = cv2.dilate(xc, np.ones(shape=(3, 3), dtype=np.uint8), iterations=1)
	one_pixel_edge_count = np.where(xc < x)[0].shape[0]
	all_edge_count = np.where(x > 127)[0].shape[0]
	is_one_pixel_edge = one_pixel_edge_count * 2 > all_edge_count

	if 2 < unique_color_count < 200:
	interpolation = cv2.INTER_NEAREST
	elif new_size_is_smaller:
	interpolation = cv2.INTER_AREA
	else:
	# Must be CUBIC because we now use nms
	interpolation = cv2.INTER_CUBIC # NEVER CHANGE THIS

	y = cv2.resize(x, size, interpolation=interpolation)

	if is_binary:
	y = np.mean(y.astype(np.float32), axis=2).clip(0, 255).astype(np.uint8)
	if is_one_pixel_edge:
	y = nake_nms(y)
	_, y = cv2.threshold(y, 0, 255, cv2.THRESH_BINARY + cv2.THRESH_OTSU)
	y = lvmin_thin(y, prunings=new_size_is_bigger)
	else:
	_, y = cv2.threshold(y, 0, 255, cv2.THRESH_BINARY + cv2.THRESH_OTSU)
	y = np.stack([y] * 3, axis=2)
	else:
	y = x

	return y


	def crop_and_resize_image(detected_map, resize_mode, h, w, fill_border_with_255=False):
	if resize_mode == external_code.ResizeMode.RESIZE:
	detected_map = high_quality_resize(detected_map, (w, h))
	detected_map = safe_numpy(detected_map)
	return detected_map

	old_h, old_w, _ = detected_map.shape
	old_w = float(old_w)
	old_h = float(old_h)
	k0 = float(h) / old_h
	k1 = float(w) / old_w

	safeint = lambda x: int(np.round(x))

	if resize_mode == external_code.ResizeMode.OUTER_FIT:
	k = min(k0, k1)
	borders = np.concatenate(
	[
	detected_map[0, :, :],
	detected_map[-1, :, :],
	detected_map[:, 0, :],
	detected_map[:, -1, :],
	],
	axis=0,
	)
	high_quality_border_color = np.median(borders, axis=0).astype(detected_map.dtype)
	if fill_border_with_255:
	high_quality_border_color = np.zeros_like(high_quality_border_color) + 255
	high_quality_background = np.tile(high_quality_border_color[None, None], [h, w, 1])
	detected_map = high_quality_resize(detected_map, (safeint(old_w * k), safeint(old_h * k)))
	new_h, new_w, _ = detected_map.shape
	pad_h = max(0, (h - new_h) // 2)
	pad_w = max(0, (w - new_w) // 2)
	high_quality_background[pad_h : pad_h + new_h, pad_w : pad_w + new_w] = detected_map
	detected_map = high_quality_background
	detected_map = safe_numpy(detected_map)
	return detected_map
	else:
	k = max(k0, k1)
	detected_map = high_quality_resize(detected_map, (safeint(old_w * k), safeint(old_h * k)))
	new_h, new_w, _ = detected_map.shape
	pad_h = max(0, (new_h - h) // 2)
	pad_w = max(0, (new_w - w) // 2)
	detected_map = detected_map[pad_h : pad_h + h, pad_w : pad_w + w]
	detected_map = safe_numpy(detected_map)
	return detected_map


	def judge_image_type(img):
	return isinstance(img, np.ndarray) and img.ndim == 3 and int(img.shape[2]) in [3, 4]