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	# Copyright (c) OpenMMLab. All rights reserved.
	import argparse
	import time
	from typing import List, Tuple

	import cv2
	import loguru
	import numpy as np
	import onnxruntime as ort

	logger = loguru.logger


	def parse_args():
	parser = argparse.ArgumentParser(
	description='RTMPose ONNX inference demo.')
	parser.add_argument('onnx_file', help='ONNX file path')
	parser.add_argument('image_file', help='Input image file path')
	parser.add_argument(
	'--device', help='device type for inference', default='cpu')
	parser.add_argument(
	'--save-path',
	help='path to save the output image',
	default='output.jpg')
	args = parser.parse_args()
	return args


	def preprocess(
	img: np.ndarray, input_size: Tuple[int, int] = (192, 256)
	) -> Tuple[np.ndarray, np.ndarray, np.ndarray]:
	"""Do preprocessing for RTMPose model inference.

	Args:
	img (np.ndarray): Input image in shape.
	input_size (tuple): Input image size in shape (w, h).

	Returns:
	tuple:
	- resized_img (np.ndarray): Preprocessed image.
	- center (np.ndarray): Center of image.
	- scale (np.ndarray): Scale of image.
	"""
	# get shape of image
	img_shape = img.shape[:2]
	bbox = np.array([0, 0, img_shape[1], img_shape[0]])

	# get center and scale
	center, scale = bbox_xyxy2cs(bbox, padding=1.25)

	# do affine transformation
	resized_img, scale = top_down_affine(input_size, scale, center, img)

	# normalize image
	mean = np.array([123.675, 116.28, 103.53])
	std = np.array([58.395, 57.12, 57.375])
	resized_img = (resized_img - mean) / std

	return resized_img, center, scale


	def build_session(onnx_file: str, device: str = 'cpu') -> ort.InferenceSession:
	"""Build onnxruntime session.

	Args:
	onnx_file (str): ONNX file path.
	device (str): Device type for inference.

	Returns:
	sess (ort.InferenceSession): ONNXRuntime session.
	"""
	providers = ['CPUExecutionProvider'
	] if device == 'cpu' else ['CUDAExecutionProvider']
	sess = ort.InferenceSession(path_or_bytes=onnx_file, providers=providers)

	return sess


	def inference(sess: ort.InferenceSession, img: np.ndarray) -> np.ndarray:
	"""Inference RTMPose model.

	Args:
	sess (ort.InferenceSession): ONNXRuntime session.
	img (np.ndarray): Input image in shape.

	Returns:
	outputs (np.ndarray): Output of RTMPose model.
	"""
	# build input
	input = [img.transpose(2, 0, 1)]

	# build output
	sess_input = {sess.get_inputs()[0].name: input}
	sess_output = []
	for out in sess.get_outputs():
	sess_output.append(out.name)

	# run model
	outputs = sess.run(sess_output, sess_input)

	return outputs


	def postprocess(outputs: List[np.ndarray],
	model_input_size: Tuple[int, int],
	center: Tuple[int, int],
	scale: Tuple[int, int],
	simcc_split_ratio: float = 2.0
	) -> Tuple[np.ndarray, np.ndarray]:
	"""Postprocess for RTMPose model output.

	Args:
	outputs (np.ndarray): Output of RTMPose model.
	model_input_size (tuple): RTMPose model Input image size.
	center (tuple): Center of bbox in shape (x, y).
	scale (tuple): Scale of bbox in shape (w, h).
	simcc_split_ratio (float): Split ratio of simcc.

	Returns:
	tuple:
	- keypoints (np.ndarray): Rescaled keypoints.
	- scores (np.ndarray): Model predict scores.
	"""
	# use simcc to decode
	simcc_x, simcc_y = outputs
	keypoints, scores = decode(simcc_x, simcc_y, simcc_split_ratio)

	# rescale keypoints
	keypoints = keypoints / model_input_size * scale + center - scale / 2

	return keypoints, scores


	def visualize(img: np.ndarray,
	keypoints: np.ndarray,
	scores: np.ndarray,
	filename: str = 'output.jpg',
	thr=0.3) -> np.ndarray:
	"""Visualize the keypoints and skeleton on image.

	Args:
	img (np.ndarray): Input image in shape.
	keypoints (np.ndarray): Keypoints in image.
	scores (np.ndarray): Model predict scores.
	thr (float): Threshold for visualize.

	Returns:
	img (np.ndarray): Visualized image.
	"""
	# default color
	skeleton = [(15, 13), (13, 11), (16, 14), (14, 12), (11, 12), (5, 11),
	(6, 12), (5, 6), (5, 7), (6, 8), (7, 9), (8, 10), (1, 2),
	(0, 1), (0, 2), (1, 3), (2, 4), (3, 5), (4, 6), (15, 17),
	(15, 18), (15, 19), (16, 20), (16, 21), (16, 22), (91, 92),
	(92, 93), (93, 94), (94, 95), (91, 96), (96, 97), (97, 98),
	(98, 99), (91, 100), (100, 101), (101, 102), (102, 103),
	(91, 104), (104, 105), (105, 106), (106, 107), (91, 108),
	(108, 109), (109, 110), (110, 111), (112, 113), (113, 114),
	(114, 115), (115, 116), (112, 117), (117, 118), (118, 119),
	(119, 120), (112, 121), (121, 122), (122, 123), (123, 124),
	(112, 125), (125, 126), (126, 127), (127, 128), (112, 129),
	(129, 130), (130, 131), (131, 132)]
	palette = [[51, 153, 255], [0, 255, 0], [255, 128, 0], [255, 255, 255],
	[255, 153, 255], [102, 178, 255], [255, 51, 51]]
	link_color = [
	1, 1, 2, 2, 0, 0, 0, 0, 1, 2, 1, 2, 0, 0, 0, 0, 0, 0, 0, 1, 1, 1, 2, 2,
	2, 2, 2, 2, 2, 4, 4, 4, 4, 5, 5, 5, 5, 6, 6, 6, 6, 1, 1, 1, 1, 2, 2, 2,
	2, 4, 4, 4, 4, 5, 5, 5, 5, 6, 6, 6, 6, 1, 1, 1, 1
	]
	point_color = [
	0, 0, 0, 0, 0, 1, 2, 1, 2, 1, 2, 1, 2, 1, 2, 1, 2, 2, 2, 2, 2, 2, 2, 3,
	3, 3, 3, 3, 3, 3, 3, 3, 3, 3, 3, 3, 3, 3, 3, 3, 3, 3, 3, 3, 3, 3, 3, 3,
	3, 3, 3, 3, 3, 3, 3, 3, 3, 3, 3, 3, 3, 3, 3, 3, 3, 3, 3, 3, 3, 3, 3, 3,
	3, 3, 3, 3, 3, 3, 3, 3, 3, 3, 3, 3, 3, 3, 3, 3, 3, 3, 3, 3, 2, 2, 2, 2,
	4, 4, 4, 4, 5, 5, 5, 5, 6, 6, 6, 6, 1, 1, 1, 1, 3, 2, 2, 2, 2, 4, 4, 4,
	4, 5, 5, 5, 5, 6, 6, 6, 6, 1, 1, 1, 1
	]

	# draw keypoints and skeleton
	for kpts, score in zip(keypoints, scores):
	for kpt, color in zip(kpts, point_color):
	cv2.circle(img, tuple(kpt.astype(np.int32)), 1, palette[color], 1,
	cv2.LINE_AA)
	for (u, v), color in zip(skeleton, link_color):
	if score[u] > thr and score[v] > thr:
	cv2.line(img, tuple(kpts[u].astype(np.int32)),
	tuple(kpts[v].astype(np.int32)), palette[color], 2,
	cv2.LINE_AA)

	# save to local
	cv2.imwrite(filename, img)

	return img


	def bbox_xyxy2cs(bbox: np.ndarray,
	padding: float = 1.) -> Tuple[np.ndarray, np.ndarray]:
	"""Transform the bbox format from (x,y,w,h) into (center, scale)

	Args:
	bbox (ndarray): Bounding box(es) in shape (4,) or (n, 4), formatted
	as (left, top, right, bottom)
	padding (float): BBox padding factor that will be multilied to scale.
	Default: 1.0

	Returns:
	tuple: A tuple containing center and scale.
	- np.ndarray[float32]: Center (x, y) of the bbox in shape (2,) or
	(n, 2)
	- np.ndarray[float32]: Scale (w, h) of the bbox in shape (2,) or
	(n, 2)
	"""
	# convert single bbox from (4, ) to (1, 4)
	dim = bbox.ndim
	if dim == 1:
	bbox = bbox[None, :]

	# get bbox center and scale
	x1, y1, x2, y2 = np.hsplit(bbox, [1, 2, 3])
	center = np.hstack([x1 + x2, y1 + y2]) * 0.5
	scale = np.hstack([x2 - x1, y2 - y1]) * padding

	if dim == 1:
	center = center[0]
	scale = scale[0]

	return center, scale


	def _fix_aspect_ratio(bbox_scale: np.ndarray,
	aspect_ratio: float) -> np.ndarray:
	"""Extend the scale to match the given aspect ratio.

	Args:
	scale (np.ndarray): The image scale (w, h) in shape (2, )
	aspect_ratio (float): The ratio of ``w/h``

	Returns:
	np.ndarray: The reshaped image scale in (2, )
	"""
	w, h = np.hsplit(bbox_scale, [1])
	bbox_scale = np.where(w > h * aspect_ratio,
	np.hstack([w, w / aspect_ratio]),
	np.hstack([h * aspect_ratio, h]))
	return bbox_scale


	def _rotate_point(pt: np.ndarray, angle_rad: float) -> np.ndarray:
	"""Rotate a point by an angle.

	Args:
	pt (np.ndarray): 2D point coordinates (x, y) in shape (2, )
	angle_rad (float): rotation angle in radian

	Returns:
	np.ndarray: Rotated point in shape (2, )
	"""
	sn, cs = np.sin(angle_rad), np.cos(angle_rad)
	rot_mat = np.array([[cs, -sn], [sn, cs]])
	return rot_mat @ pt


	def _get_3rd_point(a: np.ndarray, b: np.ndarray) -> np.ndarray:
	"""To calculate the affine matrix, three pairs of points are required. This
	function is used to get the 3rd point, given 2D points a & b.

	The 3rd point is defined by rotating vector `a - b` by 90 degrees
	anticlockwise, using b as the rotation center.

	Args:
	a (np.ndarray): The 1st point (x,y) in shape (2, )
	b (np.ndarray): The 2nd point (x,y) in shape (2, )

	Returns:
	np.ndarray: The 3rd point.
	"""
	direction = a - b
	c = b + np.r_[-direction[1], direction[0]]
	return c


	def get_warp_matrix(center: np.ndarray,
	scale: np.ndarray,
	rot: float,
	output_size: Tuple[int, int],
	shift: Tuple[float, float] = (0., 0.),
	inv: bool = False) -> np.ndarray:
	"""Calculate the affine transformation matrix that can warp the bbox area
	in the input image to the output size.

	Args:
	center (np.ndarray[2, ]): Center of the bounding box (x, y).
	scale (np.ndarray[2, ]): Scale of the bounding box
	wrt [width, height].
	rot (float): Rotation angle (degree).
	output_size (np.ndarray[2, ] \| list(2,)): Size of the
	destination heatmaps.
	shift (0-100%): Shift translation ratio wrt the width/height.
	Default (0., 0.).
	inv (bool): Option to inverse the affine transform direction.
	(inv=False: src->dst or inv=True: dst->src)

	Returns:
	np.ndarray: A 2x3 transformation matrix
	"""
	shift = np.array(shift)
	src_w = scale[0]
	dst_w = output_size[0]
	dst_h = output_size[1]

	# compute transformation matrix
	rot_rad = np.deg2rad(rot)
	src_dir = _rotate_point(np.array([0., src_w * -0.5]), rot_rad)
	dst_dir = np.array([0., dst_w * -0.5])

	# get four corners of the src rectangle in the original image
	src = np.zeros((3, 2), dtype=np.float32)
	src[0, :] = center + scale * shift
	src[1, :] = center + src_dir + scale * shift
	src[2, :] = _get_3rd_point(src[0, :], src[1, :])

	# get four corners of the dst rectangle in the input image
	dst = np.zeros((3, 2), dtype=np.float32)
	dst[0, :] = [dst_w * 0.5, dst_h * 0.5]
	dst[1, :] = np.array([dst_w * 0.5, dst_h * 0.5]) + dst_dir
	dst[2, :] = _get_3rd_point(dst[0, :], dst[1, :])

	if inv:
	warp_mat = cv2.getAffineTransform(np.float32(dst), np.float32(src))
	else:
	warp_mat = cv2.getAffineTransform(np.float32(src), np.float32(dst))

	return warp_mat


	def top_down_affine(input_size: dict, bbox_scale: dict, bbox_center: dict,
	img: np.ndarray) -> Tuple[np.ndarray, np.ndarray]:
	"""Get the bbox image as the model input by affine transform.

	Args:
	input_size (dict): The input size of the model.
	bbox_scale (dict): The bbox scale of the img.
	bbox_center (dict): The bbox center of the img.
	img (np.ndarray): The original image.

	Returns:
	tuple: A tuple containing center and scale.
	- np.ndarray[float32]: img after affine transform.
	- np.ndarray[float32]: bbox scale after affine transform.
	"""
	w, h = input_size
	warp_size = (int(w), int(h))

	# reshape bbox to fixed aspect ratio
	bbox_scale = _fix_aspect_ratio(bbox_scale, aspect_ratio=w / h)

	# get the affine matrix
	center = bbox_center
	scale = bbox_scale
	rot = 0
	warp_mat = get_warp_matrix(center, scale, rot, output_size=(w, h))

	# do affine transform
	img = cv2.warpAffine(img, warp_mat, warp_size, flags=cv2.INTER_LINEAR)

	return img, bbox_scale


	def get_simcc_maximum(simcc_x: np.ndarray,
	simcc_y: np.ndarray) -> Tuple[np.ndarray, np.ndarray]:
	"""Get maximum response location and value from simcc representations.

	Note:
	instance number: N
	num_keypoints: K
	heatmap height: H
	heatmap width: W

	Args:
	simcc_x (np.ndarray): x-axis SimCC in shape (K, Wx) or (N, K, Wx)
	simcc_y (np.ndarray): y-axis SimCC in shape (K, Wy) or (N, K, Wy)

	Returns:
	tuple:
	- locs (np.ndarray): locations of maximum heatmap responses in shape
	(K, 2) or (N, K, 2)
	- vals (np.ndarray): values of maximum heatmap responses in shape
	(K,) or (N, K)
	"""
	N, K, Wx = simcc_x.shape
	simcc_x = simcc_x.reshape(N * K, -1)
	simcc_y = simcc_y.reshape(N * K, -1)

	# get maximum value locations
	x_locs = np.argmax(simcc_x, axis=1)
	y_locs = np.argmax(simcc_y, axis=1)
	locs = np.stack((x_locs, y_locs), axis=-1).astype(np.float32)
	max_val_x = np.amax(simcc_x, axis=1)
	max_val_y = np.amax(simcc_y, axis=1)

	# get maximum value across x and y axis
	mask = max_val_x > max_val_y
	max_val_x[mask] = max_val_y[mask]
	vals = max_val_x
	locs[vals <= 0.] = -1

	# reshape
	locs = locs.reshape(N, K, 2)
	vals = vals.reshape(N, K)

	return locs, vals


	def decode(simcc_x: np.ndarray, simcc_y: np.ndarray,
	simcc_split_ratio) -> Tuple[np.ndarray, np.ndarray]:
	"""Modulate simcc distribution with Gaussian.

	Args:
	simcc_x (np.ndarray[K, Wx]): model predicted simcc in x.
	simcc_y (np.ndarray[K, Wy]): model predicted simcc in y.
	simcc_split_ratio (int): The split ratio of simcc.

	Returns:
	tuple: A tuple containing center and scale.
	- np.ndarray[float32]: keypoints in shape (K, 2) or (n, K, 2)
	- np.ndarray[float32]: scores in shape (K,) or (n, K)
	"""
	keypoints, scores = get_simcc_maximum(simcc_x, simcc_y)
	keypoints /= simcc_split_ratio

	return keypoints, scores


	def main():
	args = parse_args()
	logger.info('Start running model on RTMPose...')

	# read image from file
	logger.info('1. Read image from {}...'.format(args.image_file))
	img = cv2.imread(args.image_file)

	# build onnx model
	logger.info('2. Build onnx model from {}...'.format(args.onnx_file))
	sess = build_session(args.onnx_file, args.device)
	h, w = sess.get_inputs()[0].shape[2:]
	model_input_size = (w, h)

	# preprocessing
	logger.info('3. Preprocess image...')
	resized_img, center, scale = preprocess(img, model_input_size)

	# inference
	logger.info('4. Inference...')
	start_time = time.time()
	outputs = inference(sess, resized_img)
	end_time = time.time()
	logger.info('4. Inference done, time cost: {:.4f}s'.format(end_time -
	start_time))

	# postprocessing
	logger.info('5. Postprocess...')
	keypoints, scores = postprocess(outputs, model_input_size, center, scale)

	# visualize inference result
	logger.info('6. Visualize inference result...')
	visualize(img, keypoints, scores, args.save_path)

	logger.info('Done...')


	if __name__ == '__main__':
	main()