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	import random
	import gradio as gr
	import imageio
	import numpy as np
	import onnx
	import onnxruntime as rt
	import huggingface_hub
	from numpy.random import RandomState
	from skimage import transform


	def get_inter(r1, r2):
	h_inter = max(min(r1[3], r2[3]) - max(r1[1], r2[1]), 0)
	w_inter = max(min(r1[2], r2[2]) - max(r1[0], r2[0]), 0)
	return h_inter * w_inter


	def iou(r1, r2):
	s1 = (r1[2] - r1[0]) * (r1[3] - r1[1])
	s2 = (r2[2] - r2[0]) * (r2[3] - r2[1])
	i = get_inter(r1, r2)
	return i / (s1 + s2 - i)


	def letterbox(im, new_shape=(640, 640), color=(0.5, 0.5, 0.5), stride=32):
	# Resize and pad image while meeting stride-multiple constraints
	shape = im.shape[:2] # current shape [height, width]

	# Scale ratio (new / old)
	r = min(new_shape[0] / shape[0], new_shape[1] / shape[1])

	# Compute padding
	new_unpad = int(round(shape[1] * r)), int(round(shape[0] * r))
	dw, dh = new_shape[1] - new_unpad[0], new_shape[0] - new_unpad[1] # wh padding
	dw, dh = np.mod(dw, stride), np.mod(dh, stride) # wh padding

	dw /= 2 # divide padding into 2 sides
	dh /= 2

	if shape != new_unpad: # resize
	im = transform.resize(im, (new_unpad[1], new_unpad[0]))
	top, bottom = int(round(dh - 0.1)), int(round(dh + 0.1))
	left, right = int(round(dw - 0.1)), int(round(dw + 0.1))

	im_new = np.full((new_unpad[1] + top + bottom, new_unpad[0] + left + right, 3), color, dtype=np.float32)
	im_new[top:new_unpad[1] + top, left:new_unpad[0] + left] = im
	return im_new


	def nms(pred, conf_thres, iou_thres, max_instance=20): # pred (anchor_num, 5 + cls_num)
	nc = pred.shape[1] - 5
	candidates = [list() for x in range(nc)]
	for x in pred:
	if x[4] < conf_thres:
	continue
	cls = np.argmax(x[5:])
	p = x[4] * x[5 + cls]
	if conf_thres <= p:
	box = (x[0] - x[2] / 2, x[1] - x[3] / 2, x[0] + x[2] / 2, x[1] + x[3] / 2) # xywh2xyxy
	candidates[cls].append([p, box])
	result = [list() for x in range(nc)]
	for i, candidate in enumerate(candidates):
	candidate = sorted(candidate, key=lambda a: a[0], reverse=True)
	candidate = candidate[:max_instance]
	for x in candidate:
	ok = True
	for r in result[i]:
	if iou(r[1], x[1]) > iou_thres:
	ok = False
	break
	if ok:
	result[i].append(x)

	return result


	class Model:
	def __init__(self):
	self.detector = None
	self.encoder = None
	self.g_synthesis = None
	self.g_mapping = None
	self.detector_stride = None
	self.detector_imgsz = None
	self.detector_class_names = None
	self.anime_seg = None
	self.w_avg = None
	self.load_models()

	def load_models(self):
	g_mapping_path = huggingface_hub.hf_hub_download("skytnt/fbanime-gan", "g_mapping.onnx")
	g_synthesis_path = huggingface_hub.hf_hub_download("skytnt/fbanime-gan", "g_synthesis.onnx")
	encoder_path = huggingface_hub.hf_hub_download("skytnt/fbanime-gan", "encoder.onnx")
	detector_path = huggingface_hub.hf_hub_download("skytnt/fbanime-gan", "waifu_dect.onnx")
	anime_seg_path = huggingface_hub.hf_hub_download("skytnt/anime-seg", "isnetis.onnx")

	providers = ['CPUExecutionProvider']
	gpu_providers = ['CUDAExecutionProvider']
	g_mapping = onnx.load(g_mapping_path)
	w_avg = [x for x in g_mapping.graph.initializer if x.name == "w_avg"][0]
	w_avg = np.frombuffer(w_avg.raw_data, dtype=np.float32)[np.newaxis, :]
	w_avg = w_avg.repeat(16, axis=0)[np.newaxis, :]
	self.w_avg = w_avg
	self.g_mapping = rt.InferenceSession(g_mapping_path, providers=providers)
	self.g_synthesis = rt.InferenceSession(g_synthesis_path, providers=providers)
	self.encoder = rt.InferenceSession(encoder_path, providers=providers)
	self.detector = rt.InferenceSession(detector_path, providers=providers)
	detector_meta = self.detector.get_modelmeta().custom_metadata_map
	self.detector_stride = int(detector_meta['stride'])
	self.detector_imgsz = 1088
	self.detector_class_names = eval(detector_meta['names'])
	self.anime_seg = rt.InferenceSession(anime_seg_path, providers=providers)

	def get_img(self, w, noise=0):
	img = self.g_synthesis.run(None, {'w': w.astype(np.float32), "noise": np.asarray([noise], dtype=np.float32)})[0]
	return (img.transpose(0, 2, 3, 1) * 127.5 + 128).clip(0, 255).astype(np.uint8)[0]

	def get_w(self, z, psi1, psi2):
	return self.g_mapping.run(None, {'z': z.astype(np.float32), 'psi': np.asarray([psi1, psi2], dtype=np.float32)})[0]

	def remove_bg(self, img, s=1024):
	img0 = img
	img = (img / 255).astype(np.float32)
	h, w = h0, w0 = img.shape[:-1]
	h, w = (s, int(s * w / h)) if h > w else (int(s * h / w), s)
	ph, pw = s - h, s - w
	img_input = np.zeros([s, s, 3], dtype=np.float32)
	img_input[ph // 2:ph // 2 + h, pw // 2:pw // 2 + w] = transform.resize(img, (h, w))
	img_input = np.transpose(img_input, (2, 0, 1))
	img_input = img_input[np.newaxis, :]
	mask = self.anime_seg.run(None, {'img': img_input})[0][0]
	mask = np.transpose(mask, (1, 2, 0))
	mask = mask[ph // 2:ph // 2 + h, pw // 2:pw // 2 + w]
	mask = transform.resize(mask, (h0, w0))
	img0 = (img0 * mask + 255 * (1 - mask)).astype(np.uint8)
	return img0

	def encode_img(self, img):
	img = transform.resize(((img / 255 - 0.5) / 0.5), (256, 256)).transpose(2, 0, 1)[np.newaxis, :].astype(
	np.float32)
	return self.encoder.run(None, {'img': img})[0] + self.w_avg

	def detect(self, im0, conf_thres, iou_thres, detail=False):
	if im0 is None:
	return []
	img = letterbox((im0 / 255).astype(np.float32), (self.detector_imgsz, self.detector_imgsz),
	stride=self.detector_stride)
	# Convert
	img = img.transpose(2, 0, 1)
	img = img[np.newaxis, :]
	pred = self.detector.run(None, {'images': img})[0][0]
	dets = nms(pred, conf_thres, iou_thres)
	imgs = []
	# Print results
	s = '%gx%g ' % img.shape[2:] # print string
	for i, det in enumerate(dets):
	n = len(det)
	s += f"{n} {self.detector_class_names[i]}{'s' * (n > 1)}, " # add to string
	if detail:
	print(s)
	waifu_rects = []
	head_rects = []
	body_rects = []

	for i, det in enumerate(dets):
	for x in det:
	# Rescale boxes from img_size to im0 size
	wr = im0.shape[1] / img.shape[3]
	hr = im0.shape[0] / img.shape[2]
	x[1] = (int(x[1][0] * wr), int(x[1][1] * hr),
	int(x[1][2] * wr), int(x[1][3] * hr))
	if i == 0:
	head_rects.append(x[1])
	elif i == 1:
	body_rects.append(x[1])
	elif i == 2:
	waifu_rects.append(x[1])
	for j, waifu_rect in enumerate(waifu_rects):
	msg = f'waifu {j + 1} '
	head_num = 0
	body_num = 0
	hr, br = None, None
	for r in head_rects:
	if get_inter(r, waifu_rect) / ((r[2] - r[0]) * (r[3] - r[1])) > 0.75:
	hr = r
	head_num += 1
	if head_num != 1:
	if detail:
	print(msg + f'head num error: {head_num}')
	continue
	for r in body_rects:
	if get_inter(r, waifu_rect) / ((r[2] - r[0]) * (r[3] - r[1])) > 0.65:
	br = r
	body_num += 1
	if body_num != 1:
	if detail:
	print(msg + f'body num error: {body_num}')
	continue
	bounds = (min(waifu_rect[0], hr[0], br[0]),
	min(waifu_rect[1], hr[1], br[1]),
	max(waifu_rect[2], hr[2], br[2]),
	max(waifu_rect[3], hr[3], br[3]))
	if (bounds[2] - bounds[0]) / (bounds[3] - bounds[1]) > 0.7:
	if detail:
	print(msg + "ratio out of limit")
	continue
	expand_pixel = (bounds[3] - bounds[1]) // 20
	bounds = [max(bounds[0] - expand_pixel // 2, 0),
	max(bounds[1] - expand_pixel, 0),
	min(bounds[2] + expand_pixel // 2, im0.shape[1]),
	min(bounds[3] + expand_pixel, im0.shape[0]),
	]
	# corp and resize
	w = bounds[2] - bounds[0]
	h = bounds[3] - bounds[1]
	bounds[3] += h % 2
	h += h % 2
	r = min(512 / w, 1024 / h)
	pw, ph = int(512 / r - w), int(1024 / r - h)
	bounds_tmp = (bounds[0] - pw // 2, bounds[1] - ph // 2,
	bounds[2] + pw // 2 + pw % 2, bounds[3] + ph // 2 + ph % 2)
	bounds = (max(0, bounds_tmp[0]), max(0, bounds_tmp[1]),
	min(im0.shape[1], bounds_tmp[2]), min(im0.shape[0], bounds_tmp[3]))
	dl = bounds[0] - bounds_tmp[0]
	dr = bounds[2] - bounds_tmp[2]
	dt = bounds[1] - bounds_tmp[1]
	db = bounds[3] - bounds_tmp[3]
	w = bounds_tmp[2] - bounds_tmp[0]
	h = bounds_tmp[3] - bounds_tmp[1]
	temp_img = np.full((h, w, 3), 255, dtype=np.uint8)
	temp_img[dt:h + db, dl:w + dr] = im0[bounds[1]:bounds[3], bounds[0]:bounds[2]]
	temp_img = transform.resize(temp_img, (1024, 512), preserve_range=True).astype(np.uint8)
	imgs.append(temp_img)
	return imgs

	def gen_video(self, w1, w2, noise, path, frame_num=10):
	video = imageio.get_writer(path, mode='I', fps=frame_num // 2, codec='libx264', bitrate='16M')
	lin = np.linspace(0, 1, frame_num)
	frames = []
	for i in range(0, frame_num):
	img = self.get_img(((1 - lin[i]) * w1) + (lin[i] * w2), noise)
	frames.append(img)
	video.append_data(img)
	for i in reversed(range(0, frame_num)):
	video.append_data(frames[i])
	video.close()

	def get_thumbnail(img):
	img_new = np.full((256, 384, 3), 200, dtype=np.uint8)
	img_new[:, 128:256] = transform.resize(img, (256, 128), preserve_range=True)
	return img_new


	def gen_fn(seed, random_seed, psi1, psi2, noise):
	if random_seed:
	seed = random.randint(0, 2 ** 32 - 1)
	z = RandomState(int(seed)).randn(1, 1024)
	w = model.get_w(z.astype(dtype=np.float32), psi1, psi2)
	img_out = model.get_img(w, noise)
	return img_out, seed, w, get_thumbnail(img_out)


	def encode_img_fn(img, noise):
	if img is None:
	return "please upload a image", None, None, None, None
	img = model.remove_bg(img)
	imgs = model.detect(img, 0.2, 0.03)
	if len(imgs) == 0:
	return "failed to detect anime character", None, None, None, None
	w = model.encode_img(imgs[0])
	img_out = model.get_img(w, noise)
	return "success", imgs[0], img_out, w, get_thumbnail(img_out)


	def gen_video_fn(w1, w2, noise, frame):
	if w1 is None or w2 is None:
	return None
	model.gen_video(w1, w2, noise, "video.mp4", int(frame))
	return "video.mp4"


	if __name__ == '__main__':
	model = Model()

	app = gr.Blocks()
	with app:
	gr.Markdown("# full-body anime GAN\n\n"
	"![visitor badge](https://api.visitorbadge.io/api/visitors?path=skytnt.full-body-anime-gan&countColor=%23263759&style=flat&labelStyle=lower)\n\n")
	with gr.Tabs():
	with gr.TabItem("generate image"):
	with gr.Row():
	with gr.Column():
	gr.Markdown("generate image")
	with gr.Row():
	gen_input1 = gr.Slider(minimum=0, maximum=2 ** 32 - 1, step=1, value=0, label="seed")
	gen_input2 = gr.Checkbox(label="Random", value=True)
	gen_input3 = gr.Slider(minimum=0, maximum=1, step=0.01, value=0.7, label="truncation psi 1")
	gen_input4 = gr.Slider(minimum=0, maximum=1, step=0.01, value=1, label="truncation psi 2")
	gen_input5 = gr.Slider(minimum=0, maximum=1, step=0.01, value=1, label="noise strength")
	with gr.Group():
	gen_submit = gr.Button("Generate", variant="primary")
	with gr.Column():
	gen_output1 = gr.Image(label="output image")
	select_img_input_w1 = gr.State()
	select_img_input_img1 = gr.State()

	with gr.TabItem("encode image"):
	with gr.Row():
	with gr.Column():
	gr.Markdown("you'd better upload a standing full-body image")
	encode_img_input = gr.Image(label="input image")
	examples_data = [[f"examples/{x:02d}.jpg"] for x in range(1, 5)]
	encode_img_examples = gr.Examples(examples=examples_data,inputs=[encode_img_input],cache_examples=False)
	with gr.Group():
	encode_img_submit = gr.Button("Run", variant="primary")
	with gr.Column():
	encode_img_output1 = gr.Textbox(label="output message")
	with gr.Row():
	encode_img_output2 = gr.Image(label="detected")
	encode_img_output3 = gr.Image(label="encoded")
	select_img_input_w2 = gr.State()
	select_img_input_img2 = gr.State()

	with gr.TabItem("generate video"):
	with gr.Row():
	with gr.Column():
	gr.Markdown("generate video between 2 images")
	with gr.Row():
	with gr.Column():
	select_img1_dropdown = gr.Radio(label="Select image 1", value="current generated image",
	choices=["current generated image",
	"current encoded image"], type="index")
	with gr.Group():
	select_img1_button = gr.Button("Select", variant="primary")
	select_img1_output_img = gr.Image(label="selected image 1")
	select_img1_output_w = gr.State()
	with gr.Column():
	select_img2_dropdown = gr.Radio(label="Select image 2", value="current generated image",
	choices=["current generated image",
	"current encoded image"], type="index")
	with gr.Group():
	select_img2_button = gr.Button("Select", variant="primary")
	select_img2_output_img = gr.Image(label="selected image 2")
	select_img2_output_w = gr.State()
	generate_video_frame = gr.Slider(minimum=3, maximum=5, step=1, label="frame", value=3)
	with gr.Group():
	generate_video_button = gr.Button("Generate", variant="primary")
	with gr.Column():
	generate_video_output = gr.Video(label="output video")
	gen_submit.click(gen_fn, [gen_input1, gen_input2, gen_input3, gen_input4, gen_input5],
	[gen_output1, gen_input1, select_img_input_w1, select_img_input_img1])
	encode_img_submit.click(encode_img_fn, [encode_img_input, gen_input5],
	[encode_img_output1, encode_img_output2, encode_img_output3, select_img_input_w2,
	select_img_input_img2])
	select_img1_button.click(lambda i, img1, img2, w1, w2: (img1, w1) if i == 0 else (img2, w2),
	[select_img1_dropdown, select_img_input_img1, select_img_input_img2,
	select_img_input_w1, select_img_input_w2],
	[select_img1_output_img, select_img1_output_w])
	select_img2_button.click(lambda i, img1, img2, w1, w2: (img1, w1) if i == 0 else (img2, w2),
	[select_img2_dropdown, select_img_input_img1, select_img_input_img2,
	select_img_input_w1, select_img_input_w2],
	[select_img2_output_img, select_img2_output_w])
	generate_video_button.click(gen_video_fn,
	[select_img1_output_w, select_img2_output_w, gen_input5, generate_video_frame],
	[generate_video_output])
	app.launch()