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image-matching-webui / third_party /d2net /extract_kapture.py

Vincentqyw

fix: roma

c74a070 11 months ago

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10.4 kB

	import argparse
	import numpy as np
	from PIL import Image
	import torch
	import math
	from tqdm import tqdm
	from os import path

	# Kapture is a pivot file format, based on text and binary files, used to describe SfM (Structure From Motion) and more generally sensor-acquired data
	# it can be installed with
	# pip install kapture
	# for more information check out https://github.com/naver/kapture
	import kapture
	from kapture.io.records import get_image_fullpath
	from kapture.io.csv import kapture_from_dir, get_all_tar_handlers
	from kapture.io.csv import (
	get_feature_csv_fullpath,
	keypoints_to_file,
	descriptors_to_file,
	)
	from kapture.io.features import (
	get_keypoints_fullpath,
	keypoints_check_dir,
	image_keypoints_to_file,
	)
	from kapture.io.features import (
	get_descriptors_fullpath,
	descriptors_check_dir,
	image_descriptors_to_file,
	)

	from lib.model_test import D2Net
	from lib.utils import preprocess_image
	from lib.pyramid import process_multiscale

	# import imageio

	# CUDA
	use_cuda = torch.cuda.is_available()
	device = torch.device("cuda:0" if use_cuda else "cpu")

	# Argument parsing
	parser = argparse.ArgumentParser(description="Feature extraction script")

	parser.add_argument(
	"--kapture-root", type=str, required=True, help="path to kapture root directory"
	)

	parser.add_argument(
	"--preprocessing",
	type=str,
	default="caffe",
	help="image preprocessing (caffe or torch)",
	)
	parser.add_argument(
	"--model_file", type=str, default="models/d2_tf.pth", help="path to the full model"
	)
	parser.add_argument(
	"--keypoints-type",
	type=str,
	default=None,
	help="keypoint type_name, default is filename of model",
	)
	parser.add_argument(
	"--descriptors-type",
	type=str,
	default=None,
	help="descriptors type_name, default is filename of model",
	)

	parser.add_argument(
	"--max_edge", type=int, default=1600, help="maximum image size at network input"
	)
	parser.add_argument(
	"--max_sum_edges",
	type=int,
	default=2800,
	help="maximum sum of image sizes at network input",
	)

	parser.add_argument(
	"--multiscale",
	dest="multiscale",
	action="store_true",
	help="extract multiscale features",
	)
	parser.set_defaults(multiscale=False)

	parser.add_argument(
	"--no-relu",
	dest="use_relu",
	action="store_false",
	help="remove ReLU after the dense feature extraction module",
	)
	parser.set_defaults(use_relu=True)

	parser.add_argument(
	"--max-keypoints",
	type=int,
	default=float("+inf"),
	help="max number of keypoints save to disk",
	)

	args = parser.parse_args()

	print(args)
	with get_all_tar_handlers(
	args.kapture_root,
	mode={
	kapture.Keypoints: "a",
	kapture.Descriptors: "a",
	kapture.GlobalFeatures: "r",
	kapture.Matches: "r",
	},
	) as tar_handlers:
	kdata = kapture_from_dir(
	args.kapture_root,
	skip_list=[
	kapture.GlobalFeatures,
	kapture.Matches,
	kapture.Points3d,
	kapture.Observations,
	],
	tar_handlers=tar_handlers,
	)
	if kdata.keypoints is None:
	kdata.keypoints = {}
	if kdata.descriptors is None:
	kdata.descriptors = {}

	assert kdata.records_camera is not None
	image_list = [filename for _, _, filename in kapture.flatten(kdata.records_camera)]
	if args.keypoints_type is None:
	args.keypoints_type = path.splitext(path.basename(args.model_file))[0]
	print(f"keypoints_type set to {args.keypoints_type}")
	if args.descriptors_type is None:
	args.descriptors_type = path.splitext(path.basename(args.model_file))[0]
	print(f"descriptors_type set to {args.descriptors_type}")
	if (
	args.keypoints_type in kdata.keypoints
	and args.descriptors_type in kdata.descriptors
	):
	image_list = [
	name
	for name in image_list
	if name not in kdata.keypoints[args.keypoints_type]
	or name not in kdata.descriptors[args.descriptors_type]
	]

	if len(image_list) == 0:
	print("All features were already extracted")
	exit(0)
	else:
	print(f"Extracting d2net features for {len(image_list)} images")

	# Creating CNN model
	model = D2Net(model_file=args.model_file, use_relu=args.use_relu, use_cuda=use_cuda)

	if args.keypoints_type not in kdata.keypoints:
	keypoints_dtype = None
	keypoints_dsize = None
	else:
	keypoints_dtype = kdata.keypoints[args.keypoints_type].dtype
	keypoints_dsize = kdata.keypoints[args.keypoints_type].dsize
	if args.descriptors_type not in kdata.descriptors:
	descriptors_dtype = None
	descriptors_dsize = None
	else:
	descriptors_dtype = kdata.descriptors[args.descriptors_type].dtype
	descriptors_dsize = kdata.descriptors[args.descriptors_type].dsize

	# Process the files
	for image_name in tqdm(image_list, total=len(image_list)):
	img_path = get_image_fullpath(args.kapture_root, image_name)
	image = Image.open(img_path).convert("RGB")

	width, height = image.size

	resized_image = image
	resized_width = width
	resized_height = height

	max_edge = args.max_edge
	max_sum_edges = args.max_sum_edges
	if max(resized_width, resized_height) > max_edge:
	scale_multiplier = max_edge / max(resized_width, resized_height)
	resized_width = math.floor(resized_width * scale_multiplier)
	resized_height = math.floor(resized_height * scale_multiplier)
	resized_image = image.resize((resized_width, resized_height))
	if resized_width + resized_height > max_sum_edges:
	scale_multiplier = max_sum_edges / (resized_width + resized_height)
	resized_width = math.floor(resized_width * scale_multiplier)
	resized_height = math.floor(resized_height * scale_multiplier)
	resized_image = image.resize((resized_width, resized_height))

	fact_i = width / resized_width
	fact_j = height / resized_height

	resized_image = np.array(resized_image).astype("float")

	input_image = preprocess_image(resized_image, preprocessing=args.preprocessing)

	with torch.no_grad():
	if args.multiscale:
	keypoints, scores, descriptors = process_multiscale(
	torch.tensor(
	input_image[np.newaxis, :, :, :].astype(np.float32),
	device=device,
	),
	model,
	)
	else:
	keypoints, scores, descriptors = process_multiscale(
	torch.tensor(
	input_image[np.newaxis, :, :, :].astype(np.float32),
	device=device,
	),
	model,
	scales=[1],
	)

	# Input image coordinates
	keypoints[:, 0] *= fact_i
	keypoints[:, 1] *= fact_j
	# i, j -> u, v
	keypoints = keypoints[:, [1, 0, 2]]

	if args.max_keypoints != float("+inf"):
	# keep the last (the highest) indexes
	idx_keep = scores.argsort()[-min(len(keypoints), args.max_keypoints) :]
	keypoints = keypoints[idx_keep]
	descriptors = descriptors[idx_keep]

	if keypoints_dtype is None or descriptors_dtype is None:
	keypoints_dtype = keypoints.dtype
	descriptors_dtype = descriptors.dtype

	keypoints_dsize = keypoints.shape[1]
	descriptors_dsize = descriptors.shape[1]

	kdata.keypoints[args.keypoints_type] = kapture.Keypoints(
	"d2net", keypoints_dtype, keypoints_dsize
	)
	kdata.descriptors[args.descriptors_type] = kapture.Descriptors(
	"d2net", descriptors_dtype, descriptors_dsize, args.keypoints_type, "L2"
	)

	keypoints_config_absolute_path = get_feature_csv_fullpath(
	kapture.Keypoints, args.keypoints_type, args.kapture_root
	)
	descriptors_config_absolute_path = get_feature_csv_fullpath(
	kapture.Descriptors, args.descriptors_type, args.kapture_root
	)

	keypoints_to_file(
	keypoints_config_absolute_path, kdata.keypoints[args.keypoints_type]
	)
	descriptors_to_file(
	descriptors_config_absolute_path,
	kdata.descriptors[args.descriptors_type],
	)
	else:
	assert kdata.keypoints[args.keypoints_type].dtype == keypoints.dtype
	assert kdata.descriptors[args.descriptors_type].dtype == descriptors.dtype
	assert kdata.keypoints[args.keypoints_type].dsize == keypoints.shape[1]
	assert (
	kdata.descriptors[args.descriptors_type].dsize == descriptors.shape[1]
	)
	assert (
	kdata.descriptors[args.descriptors_type].keypoints_type
	== args.keypoints_type
	)
	assert kdata.descriptors[args.descriptors_type].metric_type == "L2"

	keypoints_fullpath = get_keypoints_fullpath(
	args.keypoints_type, args.kapture_root, image_name, tar_handlers
	)
	print(f"Saving {keypoints.shape[0]} keypoints to {keypoints_fullpath}")
	image_keypoints_to_file(keypoints_fullpath, keypoints)
	kdata.keypoints[args.keypoints_type].add(image_name)

	descriptors_fullpath = get_descriptors_fullpath(
	args.descriptors_type, args.kapture_root, image_name, tar_handlers
	)
	print(f"Saving {descriptors.shape[0]} descriptors to {descriptors_fullpath}")
	image_descriptors_to_file(descriptors_fullpath, descriptors)
	kdata.descriptors[args.descriptors_type].add(image_name)

	if not keypoints_check_dir(
	kdata.keypoints[args.keypoints_type],
	args.keypoints_type,
	args.kapture_root,
	tar_handlers,
	) or not descriptors_check_dir(
	kdata.descriptors[args.descriptors_type],
	args.descriptors_type,
	args.kapture_root,
	tar_handlers,
	):
	print(
	"local feature extraction ended successfully but not all files were saved"
	)