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	import os
	import sys
	import cv2
	from PIL import Image
	import numpy as np
	import gradio as gr

	from modules import processing, images
	from modules import scripts, script_callbacks, shared, devices, modelloader
	from modules.processing import Processed, StableDiffusionProcessingTxt2Img, StableDiffusionProcessingImg2Img
	from modules.shared import opts, cmd_opts, state
	from modules.sd_models import model_hash
	from modules.paths import models_path
	from basicsr.utils.download_util import load_file_from_url

	dd_models_path = os.path.join(models_path, "mmdet")

	def list_models(model_path):
	model_list = modelloader.load_models(model_path=model_path, ext_filter=[".pth"])

	def modeltitle(path, shorthash):
	abspath = os.path.abspath(path)

	if abspath.startswith(model_path):
	name = abspath.replace(model_path, '')
	else:
	name = os.path.basename(path)

	if name.startswith("\\") or name.startswith("/"):
	name = name[1:]

	shortname = os.path.splitext(name.replace("/", "_").replace("\\", "_"))[0]

	return f'{name} [{shorthash}]', shortname

	models = []
	for filename in model_list:
	h = model_hash(filename)
	title, short_model_name = modeltitle(filename, h)
	models.append(title)

	return models

	def startup():
	from launch import is_installed, run
	if not is_installed("mmdet"):
	python = sys.executable
	run(f'"{python}" -m pip install -U openmim', desc="Installing openmim", errdesc="Couldn't install openmim")
	run(f'"{python}" -m mim install mmcv-full', desc=f"Installing mmcv-full", errdesc=f"Couldn't install mmcv-full")
	run(f'"{python}" -m pip install mmdet', desc=f"Installing mmdet", errdesc=f"Couldn't install mmdet")

	if (len(list_models(dd_models_path)) == 0):
	print("No detection models found, downloading...")
	bbox_path = os.path.join(dd_models_path, "bbox")
	segm_path = os.path.join(dd_models_path, "segm")
	load_file_from_url("https://huggingface.co/dustysys/ddetailer/resolve/main/mmdet/bbox/mmdet_anime-face_yolov3.pth", bbox_path)
	load_file_from_url("https://huggingface.co/dustysys/ddetailer/raw/main/mmdet/bbox/mmdet_anime-face_yolov3.py", bbox_path)
	load_file_from_url("https://huggingface.co/dustysys/ddetailer/resolve/main/mmdet/segm/mmdet_dd-person_mask2former.pth", segm_path)
	load_file_from_url("https://huggingface.co/dustysys/ddetailer/raw/main/mmdet/segm/mmdet_dd-person_mask2former.py", segm_path)

	startup()

	def gr_show(visible=True):
	return {"visible": visible, "__type__": "update"}

	class DetectionDetailerScript(scripts.Script):
	def title(self):
	return "Detection Detailer"

	def show(self, is_img2img):
	return True

	def ui(self, is_img2img):
	import modules.ui

	model_list = list_models(dd_models_path)
	model_list.insert(0, "None")
	if is_img2img:
	info = gr.HTML("<p style=\"margin-bottom:0.75em\">Recommended settings: Use from inpaint tab, inpaint at full res ON, denoise <0.5</p>")
	else:
	info = gr.HTML("")
	with gr.Group():
	with gr.Row():
	dd_model_a = gr.Dropdown(label="Primary detection model (A)", choices=model_list,value = "None", visible=True, type="value")

	with gr.Row():
	dd_conf_a = gr.Slider(label='Detection confidence threshold % (A)', minimum=0, maximum=100, step=1, value=30, visible=False)
	dd_dilation_factor_a = gr.Slider(label='Dilation factor (A)', minimum=0, maximum=255, step=1, value=4, visible=False)

	with gr.Row():
	dd_offset_x_a = gr.Slider(label='X offset (A)', minimum=-200, maximum=200, step=1, value=0, visible=False)
	dd_offset_y_a = gr.Slider(label='Y offset (A)', minimum=-200, maximum=200, step=1, value=0, visible=False)

	with gr.Row():
	dd_preprocess_b = gr.Checkbox(label='Inpaint model B detections before model A runs', value=False, visible=False)
	dd_bitwise_op = gr.Radio(label='Bitwise operation', choices=['None', 'A&B', 'A-B'], value="None", visible=False)

	br = gr.HTML("<br>")

	with gr.Group():
	with gr.Row():
	dd_model_b = gr.Dropdown(label="Secondary detection model (B) (optional)", choices=model_list,value = "None", visible =False, type="value")

	with gr.Row():
	dd_conf_b = gr.Slider(label='Detection confidence threshold % (B)', minimum=0, maximum=100, step=1, value=30, visible=False)
	dd_dilation_factor_b = gr.Slider(label='Dilation factor (B)', minimum=0, maximum=255, step=1, value=4, visible=False)

	with gr.Row():
	dd_offset_x_b = gr.Slider(label='X offset (B)', minimum=-200, maximum=200, step=1, value=0, visible=False)
	dd_offset_y_b = gr.Slider(label='Y offset (B)', minimum=-200, maximum=200, step=1, value=0, visible=False)

	with gr.Group():
	with gr.Row():
	dd_mask_blur = gr.Slider(label='Mask blur ', minimum=0, maximum=64, step=1, value=4, visible=(not is_img2img))
	dd_denoising_strength = gr.Slider(label='Denoising strength (Inpaint)', minimum=0.0, maximum=1.0, step=0.01, value=0.4, visible=(not is_img2img))

	with gr.Row():
	dd_inpaint_full_res = gr.Checkbox(label='Inpaint at full resolution ', value=True, visible = (not is_img2img))
	dd_inpaint_full_res_padding = gr.Slider(label='Inpaint at full resolution padding, pixels ', minimum=0, maximum=256, step=4, value=32, visible=(not is_img2img))

	dd_model_a.change(
	lambda modelname: {
	dd_model_b:gr_show( modelname != "None" ),
	dd_conf_a:gr_show( modelname != "None" ),
	dd_dilation_factor_a:gr_show( modelname != "None"),
	dd_offset_x_a:gr_show( modelname != "None" ),
	dd_offset_y_a:gr_show( modelname != "None" )

	},
	inputs= [dd_model_a],
	outputs =[dd_model_b, dd_conf_a, dd_dilation_factor_a, dd_offset_x_a, dd_offset_y_a]
	)

	dd_model_b.change(
	lambda modelname: {
	dd_preprocess_b:gr_show( modelname != "None" ),
	dd_bitwise_op:gr_show( modelname != "None" ),
	dd_conf_b:gr_show( modelname != "None" ),
	dd_dilation_factor_b:gr_show( modelname != "None"),
	dd_offset_x_b:gr_show( modelname != "None" ),
	dd_offset_y_b:gr_show( modelname != "None" )
	},
	inputs= [dd_model_b],
	outputs =[dd_preprocess_b, dd_bitwise_op, dd_conf_b, dd_dilation_factor_b, dd_offset_x_b, dd_offset_y_b]
	)

	return [info,
	dd_model_a,
	dd_conf_a, dd_dilation_factor_a,
	dd_offset_x_a, dd_offset_y_a,
	dd_preprocess_b, dd_bitwise_op,
	br,
	dd_model_b,
	dd_conf_b, dd_dilation_factor_b,
	dd_offset_x_b, dd_offset_y_b,
	dd_mask_blur, dd_denoising_strength,
	dd_inpaint_full_res, dd_inpaint_full_res_padding
	]

	def run(self, p, info,
	dd_model_a,
	dd_conf_a, dd_dilation_factor_a,
	dd_offset_x_a, dd_offset_y_a,
	dd_preprocess_b, dd_bitwise_op,
	br,
	dd_model_b,
	dd_conf_b, dd_dilation_factor_b,
	dd_offset_x_b, dd_offset_y_b,
	dd_mask_blur, dd_denoising_strength,
	dd_inpaint_full_res, dd_inpaint_full_res_padding):

	processing.fix_seed(p)
	initial_info = None
	seed = p.seed
	p.batch_size = 1
	ddetail_count = p.n_iter
	p.n_iter = 1
	p.do_not_save_grid = True
	p.do_not_save_samples = True
	is_txt2img = isinstance(p, StableDiffusionProcessingTxt2Img)
	if (not is_txt2img):
	orig_image = p.init_images[0]
	else:
	p_txt = p
	p = StableDiffusionProcessingImg2Img(
	init_images = None,
	resize_mode = 0,
	denoising_strength = dd_denoising_strength,
	mask = None,
	mask_blur= dd_mask_blur,
	inpainting_fill = 1,
	inpaint_full_res = dd_inpaint_full_res,
	inpaint_full_res_padding= dd_inpaint_full_res_padding,
	inpainting_mask_invert= 0,
	sd_model=p_txt.sd_model,
	outpath_samples=p_txt.outpath_samples,
	outpath_grids=p_txt.outpath_grids,
	prompt=p_txt.prompt,
	negative_prompt=p_txt.negative_prompt,
	styles=p_txt.styles,
	seed=p_txt.seed,
	subseed=p_txt.subseed,
	subseed_strength=p_txt.subseed_strength,
	seed_resize_from_h=p_txt.seed_resize_from_h,
	seed_resize_from_w=p_txt.seed_resize_from_w,
	sampler_name=p_txt.sampler_name,
	n_iter=p_txt.n_iter,
	steps=p_txt.steps,
	cfg_scale=p_txt.cfg_scale,
	width=p_txt.width,
	height=p_txt.height,
	tiling=p_txt.tiling,
	)
	p.do_not_save_grid = True
	p.do_not_save_samples = True
	output_images = []
	state.job_count = ddetail_count
	for n in range(ddetail_count):
	devices.torch_gc()
	start_seed = seed + n
	if ( is_txt2img ):
	print(f"Processing initial image for output generation {n + 1}.")
	p_txt.seed = start_seed
	processed = processing.process_images(p_txt)
	init_image = processed.images[0]
	else:
	init_image = orig_image

	output_images.append(init_image)
	masks_a = []
	masks_b_pre = []

	# Optional secondary pre-processing run
	if (dd_model_b != "None" and dd_preprocess_b):
	label_b_pre = "B"
	results_b_pre = inference(init_image, dd_model_b, dd_conf_b/100.0, label_b_pre)
	masks_b_pre = create_segmasks(results_b_pre)
	masks_b_pre = dilate_masks(masks_b_pre, dd_dilation_factor_b, 1)
	masks_b_pre = offset_masks(masks_b_pre,dd_offset_x_b, dd_offset_y_b)
	if (len(masks_b_pre) > 0):
	results_b_pre = update_result_masks(results_b_pre, masks_b_pre)
	segmask_preview_b = create_segmask_preview(results_b_pre, init_image)
	shared.state.current_image = segmask_preview_b
	if ( opts.dd_save_previews):
	images.save_image(segmask_preview_b, opts.outdir_ddetailer_previews, "", start_seed, p.prompt, opts.samples_format, p=p)
	gen_count = len(masks_b_pre)
	state.job_count += gen_count
	print(f"Processing {gen_count} model {label_b_pre} detections for output generation {n + 1}.")
	p.seed = start_seed
	p.init_images = [init_image]

	for i in range(gen_count):
	p.image_mask = masks_b_pre[i]
	if ( opts.dd_save_masks):
	images.save_image(masks_b_pre[i], opts.outdir_ddetailer_masks, "", start_seed, p.prompt, opts.samples_format, p=p)
	processed = processing.process_images(p)
	p.seed = processed.seed + 1
	p.init_images = processed.images

	if (gen_count > 0):
	output_images[n] = processed.images[0]
	init_image = processed.images[0]

	else:
	print(f"No model B detections for output generation {n} with current settings.")

	# Primary run
	if (dd_model_a != "None"):
	label_a = "A"
	if (dd_model_b != "None" and dd_bitwise_op != "None"):
	label_a = dd_bitwise_op
	results_a = inference(init_image, dd_model_a, dd_conf_a/100.0, label_a)
	masks_a = create_segmasks(results_a)
	masks_a = dilate_masks(masks_a, dd_dilation_factor_a, 1)
	masks_a = offset_masks(masks_a,dd_offset_x_a, dd_offset_y_a)
	if (dd_model_b != "None" and dd_bitwise_op != "None"):
	label_b = "B"
	results_b = inference(init_image, dd_model_b, dd_conf_b/100.0, label_b)
	masks_b = create_segmasks(results_b)
	masks_b = dilate_masks(masks_b, dd_dilation_factor_b, 1)
	masks_b = offset_masks(masks_b,dd_offset_x_b, dd_offset_y_b)
	if (len(masks_b) > 0):
	combined_mask_b = combine_masks(masks_b)
	for i in reversed(range(len(masks_a))):
	if (dd_bitwise_op == "A&B"):
	masks_a[i] = bitwise_and_masks(masks_a[i], combined_mask_b)
	elif (dd_bitwise_op == "A-B"):
	masks_a[i] = subtract_masks(masks_a[i], combined_mask_b)
	if (is_allblack(masks_a[i])):
	del masks_a[i]
	for result in results_a:
	del result[i]

	else:
	print("No model B detections to overlap with model A masks")
	results_a = []
	masks_a = []

	if (len(masks_a) > 0):
	results_a = update_result_masks(results_a, masks_a)
	segmask_preview_a = create_segmask_preview(results_a, init_image)
	shared.state.current_image = segmask_preview_a
	if ( opts.dd_save_previews):
	images.save_image(segmask_preview_a, opts.outdir_ddetailer_previews, "", start_seed, p.prompt, opts.samples_format, p=p)
	gen_count = len(masks_a)
	state.job_count += gen_count
	print(f"Processing {gen_count} model {label_a} detections for output generation {n + 1}.")
	p.seed = start_seed
	p.init_images = [init_image]

	for i in range(gen_count):
	p.image_mask = masks_a[i]
	if ( opts.dd_save_masks):
	images.save_image(masks_a[i], opts.outdir_ddetailer_masks, "", start_seed, p.prompt, opts.samples_format, p=p)

	processed = processing.process_images(p)
	if initial_info is None:
	initial_info = processed.info
	p.seed = processed.seed + 1
	p.init_images = processed.images

	if (gen_count > 0):
	output_images[n] = processed.images[0]
	if ( opts.samples_save ):
	images.save_image(processed.images[0], p.outpath_samples, "", start_seed, p.prompt, opts.samples_format, info=initial_info, p=p)

	else:
	print(f"No model {label_a} detections for output generation {n} with current settings.")
	state.job = f"Generation {n + 1} out of {state.job_count}"
	if (initial_info is None):
	initial_info = "No detections found."

	return Processed(p, output_images, seed, initial_info)

	def modeldataset(model_shortname):
	path = modelpath(model_shortname)
	if ("mmdet" in path and "segm" in path):
	dataset = 'coco'
	else:
	dataset = 'bbox'
	return dataset

	def modelpath(model_shortname):
	model_list = modelloader.load_models(model_path=dd_models_path, ext_filter=[".pth"])
	model_h = model_shortname.split("[")[-1].split("]")[0]
	for path in model_list:
	if ( model_hash(path) == model_h):
	return path

	def update_result_masks(results, masks):
	for i in range(len(masks)):
	boolmask = np.array(masks[i], dtype=bool)
	results[2][i] = boolmask
	return results

	def create_segmask_preview(results, image):
	labels = results[0]
	bboxes = results[1]
	segms = results[2]

	cv2_image = np.array(image)
	cv2_image = cv2_image[:, :, ::-1].copy()

	for i in range(len(segms)):
	color = np.full_like(cv2_image, np.random.randint(100, 256, (1, 3), dtype=np.uint8))
	alpha = 0.2
	color_image = cv2.addWeighted(cv2_image, alpha, color, 1-alpha, 0)
	cv2_mask = segms[i].astype(np.uint8) * 255
	cv2_mask_bool = np.array(segms[i], dtype=bool)
	centroid = np.mean(np.argwhere(cv2_mask_bool),axis=0)
	centroid_x, centroid_y = int(centroid[1]), int(centroid[0])

	cv2_mask_rgb = cv2.merge((cv2_mask, cv2_mask, cv2_mask))
	cv2_image = np.where(cv2_mask_rgb == 255, color_image, cv2_image)
	text_color = tuple([int(x) for x in ( color[0][0] - 100 )])
	name = labels[i]
	score = bboxes[i][4]
	score = str(score)[:4]
	text = name + ":" + score
	cv2.putText(cv2_image, text, (centroid_x - 30, centroid_y), cv2.FONT_HERSHEY_DUPLEX, 0.4, text_color, 1, cv2.LINE_AA)

	if ( len(segms) > 0):
	preview_image = Image.fromarray(cv2.cvtColor(cv2_image, cv2.COLOR_BGR2RGB))
	else:
	preview_image = image

	return preview_image

	def is_allblack(mask):
	cv2_mask = np.array(mask)
	return cv2.countNonZero(cv2_mask) == 0

	def bitwise_and_masks(mask1, mask2):
	cv2_mask1 = np.array(mask1)
	cv2_mask2 = np.array(mask2)
	cv2_mask = cv2.bitwise_and(cv2_mask1, cv2_mask2)
	mask = Image.fromarray(cv2_mask)
	return mask

	def subtract_masks(mask1, mask2):
	cv2_mask1 = np.array(mask1)
	cv2_mask2 = np.array(mask2)
	cv2_mask = cv2.subtract(cv2_mask1, cv2_mask2)
	mask = Image.fromarray(cv2_mask)
	return mask

	def dilate_masks(masks, dilation_factor, iter=1):
	if dilation_factor == 0:
	return masks
	dilated_masks = []
	kernel = np.ones((dilation_factor,dilation_factor), np.uint8)
	for i in range(len(masks)):
	cv2_mask = np.array(masks[i])
	dilated_mask = cv2.dilate(cv2_mask, kernel, iter)
	dilated_masks.append(Image.fromarray(dilated_mask))
	return dilated_masks

	def offset_masks(masks, offset_x, offset_y):
	if (offset_x == 0 and offset_y == 0):
	return masks
	offset_masks = []
	for i in range(len(masks)):
	cv2_mask = np.array(masks[i])
	offset_mask = cv2_mask.copy()
	offset_mask = np.roll(offset_mask, -offset_y, axis=0)
	offset_mask = np.roll(offset_mask, offset_x, axis=1)

	offset_masks.append(Image.fromarray(offset_mask))
	return offset_masks

	def combine_masks(masks):
	initial_cv2_mask = np.array(masks[0])
	combined_cv2_mask = initial_cv2_mask
	for i in range(1, len(masks)):
	cv2_mask = np.array(masks[i])
	combined_cv2_mask = cv2.bitwise_or(combined_cv2_mask, cv2_mask)

	combined_mask = Image.fromarray(combined_cv2_mask)
	return combined_mask

	def on_ui_settings():
	shared.opts.add_option("dd_save_previews", shared.OptionInfo(False, "Save mask previews", section=("ddetailer", "Detection Detailer")))
	shared.opts.add_option("outdir_ddetailer_previews", shared.OptionInfo("extensions/ddetailer/outputs/masks-previews", 'Output directory for mask previews', section=("ddetailer", "Detection Detailer")))
	shared.opts.add_option("dd_save_masks", shared.OptionInfo(False, "Save masks", section=("ddetailer", "Detection Detailer")))
	shared.opts.add_option("outdir_ddetailer_masks", shared.OptionInfo("extensions/ddetailer/outputs/masks", 'Output directory for masks', section=("ddetailer", "Detection Detailer")))

	def create_segmasks(results):
	segms = results[2]
	segmasks = []
	for i in range(len(segms)):
	cv2_mask = segms[i].astype(np.uint8) * 255
	mask = Image.fromarray(cv2_mask)
	segmasks.append(mask)

	return segmasks

	import mmcv
	from mmdet.core import get_classes
	from mmdet.apis import (inference_detector,
	init_detector)

	def get_device():
	device_id = shared.cmd_opts.device_id
	if device_id is not None:
	cuda_device = f"cuda:{device_id}"
	else:
	cuda_device = "cpu"
	return cuda_device

	def inference(image, modelname, conf_thres, label):
	path = modelpath(modelname)
	if ( "mmdet" in path and "bbox" in path ):
	results = inference_mmdet_bbox(image, modelname, conf_thres, label)
	elif ( "mmdet" in path and "segm" in path):
	results = inference_mmdet_segm(image, modelname, conf_thres, label)
	return results

	def inference_mmdet_segm(image, modelname, conf_thres, label):
	model_checkpoint = modelpath(modelname)
	model_config = os.path.splitext(model_checkpoint)[0] + ".py"
	model_device = get_device()
	model = init_detector(model_config, model_checkpoint, device=model_device)
	mmdet_results = inference_detector(model, np.array(image))
	bbox_results, segm_results = mmdet_results
	dataset = modeldataset(modelname)
	classes = get_classes(dataset)
	labels = [
	np.full(bbox.shape[0], i, dtype=np.int32)
	for i, bbox in enumerate(bbox_results)
	]
	n,m = bbox_results[0].shape
	if (n == 0):
	return [[],[],[]]
	labels = np.concatenate(labels)
	bboxes = np.vstack(bbox_results)
	segms = mmcv.concat_list(segm_results)
	filter_inds = np.where(bboxes[:,-1] > conf_thres)[0]
	results = [[],[],[]]
	for i in filter_inds:
	results[0].append(label + "-" + classes[labels[i]])
	results[1].append(bboxes[i])
	results[2].append(segms[i])

	return results

	def inference_mmdet_bbox(image, modelname, conf_thres, label):
	model_checkpoint = modelpath(modelname)
	model_config = os.path.splitext(model_checkpoint)[0] + ".py"
	model_device = get_device()
	model = init_detector(model_config, model_checkpoint, device=model_device)
	results = inference_detector(model, np.array(image))
	cv2_image = np.array(image)
	cv2_image = cv2_image[:, :, ::-1].copy()
	cv2_gray = cv2.cvtColor(cv2_image, cv2.COLOR_BGR2GRAY)

	segms = []
	for (x0, y0, x1, y1, conf) in results[0]:
	cv2_mask = np.zeros((cv2_gray.shape), np.uint8)
	cv2.rectangle(cv2_mask, (int(x0), int(y0)), (int(x1), int(y1)), 255, -1)
	cv2_mask_bool = cv2_mask.astype(bool)
	segms.append(cv2_mask_bool)

	n,m = results[0].shape
	if (n == 0):
	return [[],[],[]]
	bboxes = np.vstack(results[0])
	filter_inds = np.where(bboxes[:,-1] > conf_thres)[0]
	results = [[],[],[]]
	for i in filter_inds:
	results[0].append(label)
	results[1].append(bboxes[i])
	results[2].append(segms[i])

	return results

	script_callbacks.on_ui_settings(on_ui_settings)