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	# %BANNER_BEGIN%
	# ---------------------------------------------------------------------
	# %COPYRIGHT_BEGIN%
	#
	# Magic Leap, Inc. ("COMPANY") CONFIDENTIAL
	#
	# Unpublished Copyright (c) 2020
	# Magic Leap, Inc., All Rights Reserved.
	#
	# NOTICE: All information contained herein is, and remains the property
	# of COMPANY. The intellectual and technical concepts contained herein
	# are proprietary to COMPANY and may be covered by U.S. and Foreign
	# Patents, patents in process, and are protected by trade secret or
	# copyright law. Dissemination of this information or reproduction of
	# this material is strictly forbidden unless prior written permission is
	# obtained from COMPANY. Access to the source code contained herein is
	# hereby forbidden to anyone except current COMPANY employees, managers
	# or contractors who have executed Confidentiality and Non-disclosure
	# agreements explicitly covering such access.
	#
	# The copyright notice above does not evidence any actual or intended
	# publication or disclosure of this source code, which includes
	# information that is confidential and/or proprietary, and is a trade
	# secret, of COMPANY. ANY REPRODUCTION, MODIFICATION, DISTRIBUTION,
	# PUBLIC PERFORMANCE, OR PUBLIC DISPLAY OF OR THROUGH USE OF THIS
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	# INTERNATIONAL TREATIES. THE RECEIPT OR POSSESSION OF THIS SOURCE
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	# TO REPRODUCE, DISCLOSE OR DISTRIBUTE ITS CONTENTS, OR TO MANUFACTURE,
	# USE, OR SELL ANYTHING THAT IT MAY DESCRIBE, IN WHOLE OR IN PART.
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	# %AUTHORS_BEGIN%
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	# Originating Authors: Paul-Edouard Sarlin
	#
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	# --------------------------------------------------------------------*/
	# %BANNER_END%

	# Adapted by Remi Pautrat, Philipp Lindenberger

	import torch
	from kornia.color import rgb_to_grayscale
	from torch import nn

	from .utils import Extractor


	def simple_nms(scores, nms_radius: int):
	"""Fast Non-maximum suppression to remove nearby points"""
	assert nms_radius >= 0

	def max_pool(x):
	return torch.nn.functional.max_pool2d(
	x, kernel_size=nms_radius * 2 + 1, stride=1, padding=nms_radius
	)

	zeros = torch.zeros_like(scores)
	max_mask = scores == max_pool(scores)
	for _ in range(2):
	supp_mask = max_pool(max_mask.float()) > 0
	supp_scores = torch.where(supp_mask, zeros, scores)
	new_max_mask = supp_scores == max_pool(supp_scores)
	max_mask = max_mask \| (new_max_mask & (~supp_mask))
	return torch.where(max_mask, scores, zeros)


	def top_k_keypoints(keypoints, scores, k):
	if k >= len(keypoints):
	return keypoints, scores
	scores, indices = torch.topk(scores, k, dim=0, sorted=True)
	return keypoints[indices], scores


	def sample_descriptors(keypoints, descriptors, s: int = 8):
	"""Interpolate descriptors at keypoint locations"""
	b, c, h, w = descriptors.shape
	keypoints = keypoints - s / 2 + 0.5
	keypoints /= torch.tensor(
	[(w * s - s / 2 - 0.5), (h * s - s / 2 - 0.5)],
	).to(
	keypoints
	)[None]
	keypoints = keypoints * 2 - 1 # normalize to (-1, 1)
	args = {"align_corners": True} if torch.__version__ >= "1.3" else {}
	descriptors = torch.nn.functional.grid_sample(
	descriptors, keypoints.view(b, 1, -1, 2), mode="bilinear", **args
	)
	descriptors = torch.nn.functional.normalize(
	descriptors.reshape(b, c, -1), p=2, dim=1
	)
	return descriptors


	class SuperPoint(Extractor):
	"""SuperPoint Convolutional Detector and Descriptor

	SuperPoint: Self-Supervised Interest Point Detection and
	Description. Daniel DeTone, Tomasz Malisiewicz, and Andrew
	Rabinovich. In CVPRW, 2019. https://arxiv.org/abs/1712.07629

	"""

	default_conf = {
	"descriptor_dim": 256,
	"nms_radius": 4,
	"max_num_keypoints": None,
	"detection_threshold": 0.0005,
	"remove_borders": 4,
	}

	preprocess_conf = {
	"resize": 1024,
	}

	required_data_keys = ["image"]

	def __init__(self, **conf):
	super().__init__(**conf) # Update with default configuration.
	self.relu = nn.ReLU(inplace=True)
	self.pool = nn.MaxPool2d(kernel_size=2, stride=2)
	c1, c2, c3, c4, c5 = 64, 64, 128, 128, 256

	self.conv1a = nn.Conv2d(1, c1, kernel_size=3, stride=1, padding=1)
	self.conv1b = nn.Conv2d(c1, c1, kernel_size=3, stride=1, padding=1)
	self.conv2a = nn.Conv2d(c1, c2, kernel_size=3, stride=1, padding=1)
	self.conv2b = nn.Conv2d(c2, c2, kernel_size=3, stride=1, padding=1)
	self.conv3a = nn.Conv2d(c2, c3, kernel_size=3, stride=1, padding=1)
	self.conv3b = nn.Conv2d(c3, c3, kernel_size=3, stride=1, padding=1)
	self.conv4a = nn.Conv2d(c3, c4, kernel_size=3, stride=1, padding=1)
	self.conv4b = nn.Conv2d(c4, c4, kernel_size=3, stride=1, padding=1)

	self.convPa = nn.Conv2d(c4, c5, kernel_size=3, stride=1, padding=1)
	self.convPb = nn.Conv2d(c5, 65, kernel_size=1, stride=1, padding=0)

	self.convDa = nn.Conv2d(c4, c5, kernel_size=3, stride=1, padding=1)
	self.convDb = nn.Conv2d(
	c5, self.conf.descriptor_dim, kernel_size=1, stride=1, padding=0
	)

	url = "https://github.com/cvg/LightGlue/releases/download/v0.1_arxiv/superpoint_v1.pth" # noqa
	self.load_state_dict(torch.hub.load_state_dict_from_url(url,model_dir='./LightGlue/ckpts/',file_name='superpoint_v1.pth'))

	if self.conf.max_num_keypoints is not None and self.conf.max_num_keypoints <= 0:
	raise ValueError("max_num_keypoints must be positive or None")

	def forward(self, data: dict) -> dict:
	"""Compute keypoints, scores, descriptors for image"""
	for key in self.required_data_keys:
	assert key in data, f"Missing key {key} in data"
	image = data["image"]
	if image.shape[1] == 3:
	image = rgb_to_grayscale(image)

	# Shared Encoder
	x = self.relu(self.conv1a(image))
	x = self.relu(self.conv1b(x))
	x = self.pool(x)
	x = self.relu(self.conv2a(x))
	x = self.relu(self.conv2b(x))
	x = self.pool(x)
	x = self.relu(self.conv3a(x))
	x = self.relu(self.conv3b(x))
	x = self.pool(x)
	x = self.relu(self.conv4a(x))
	x = self.relu(self.conv4b(x))

	# Compute the dense keypoint scores
	cPa = self.relu(self.convPa(x))
	scores = self.convPb(cPa)
	scores = torch.nn.functional.softmax(scores, 1)[:, :-1]
	b, _, h, w = scores.shape
	scores = scores.permute(0, 2, 3, 1).reshape(b, h, w, 8, 8)
	scores = scores.permute(0, 1, 3, 2, 4).reshape(b, h * 8, w * 8)
	scores = simple_nms(scores, self.conf.nms_radius)

	# Discard keypoints near the image borders
	if self.conf.remove_borders:
	pad = self.conf.remove_borders
	scores[:, :pad] = -1
	scores[:, :, :pad] = -1
	scores[:, -pad:] = -1
	scores[:, :, -pad:] = -1

	# Extract keypoints
	best_kp = torch.where(scores > self.conf.detection_threshold)
	scores = scores[best_kp]

	# Separate into batches
	keypoints = [
	torch.stack(best_kp[1:3], dim=-1)[best_kp[0] == i] for i in range(b)
	]
	scores = [scores[best_kp[0] == i] for i in range(b)]

	# Keep the k keypoints with highest score
	if self.conf.max_num_keypoints is not None:
	keypoints, scores = list(
	zip(
	*[
	top_k_keypoints(k, s, self.conf.max_num_keypoints)
	for k, s in zip(keypoints, scores)
	]
	)
	)

	# Convert (h, w) to (x, y)
	keypoints = [torch.flip(k, [1]).float() for k in keypoints]

	# Compute the dense descriptors
	cDa = self.relu(self.convDa(x))
	descriptors = self.convDb(cDa)
	descriptors = torch.nn.functional.normalize(descriptors, p=2, dim=1)

	# Extract descriptors
	descriptors = [
	sample_descriptors(k[None], d[None], 8)[0]
	for k, d in zip(keypoints, descriptors)
	]

	return {
	"keypoints": torch.stack(keypoints, 0),
	"keypoint_scores": torch.stack(scores, 0),
	"descriptors": torch.stack(descriptors, 0).transpose(-1, -2).contiguous(),
	}