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import argparse
import imagesize
import numpy as np
import os
parser = argparse.ArgumentParser(description="MegaDepth preprocessing script")
parser.add_argument("--base_path", type=str, required=True, help="path to MegaDepth")
parser.add_argument("--scene_id", type=str, required=True, help="scene ID")
parser.add_argument(
"--output_path", type=str, required=True, help="path to the output directory"
)
args = parser.parse_args()
base_path = args.base_path
# Remove the trailing / if need be.
if base_path[-1] in ["/", "\\"]:
base_path = base_path[:-1]
scene_id = args.scene_id
base_depth_path = os.path.join(base_path, "phoenix/S6/zl548/MegaDepth_v1")
base_undistorted_sfm_path = os.path.join(base_path, "Undistorted_SfM")
undistorted_sparse_path = os.path.join(
base_undistorted_sfm_path, scene_id, "sparse-txt"
)
if not os.path.exists(undistorted_sparse_path):
exit()
depths_path = os.path.join(base_depth_path, scene_id, "dense0", "depths")
if not os.path.exists(depths_path):
exit()
images_path = os.path.join(base_undistorted_sfm_path, scene_id, "images")
if not os.path.exists(images_path):
exit()
# Process cameras.txt
with open(os.path.join(undistorted_sparse_path, "cameras.txt"), "r") as f:
raw = f.readlines()[3:] # skip the header
camera_intrinsics = {}
for camera in raw:
camera = camera.split(" ")
camera_intrinsics[int(camera[0])] = [float(elem) for elem in camera[2:]]
# Process points3D.txt
with open(os.path.join(undistorted_sparse_path, "points3D.txt"), "r") as f:
raw = f.readlines()[3:] # skip the header
points3D = {}
for point3D in raw:
point3D = point3D.split(" ")
points3D[int(point3D[0])] = np.array(
[float(point3D[1]), float(point3D[2]), float(point3D[3])]
)
# Process images.txt
with open(os.path.join(undistorted_sparse_path, "images.txt"), "r") as f:
raw = f.readlines()[4:] # skip the header
image_id_to_idx = {}
image_names = []
raw_pose = []
camera = []
points3D_id_to_2D = []
n_points3D = []
for idx, (image, points) in enumerate(zip(raw[::2], raw[1::2])):
image = image.split(" ")
points = points.split(" ")
image_id_to_idx[int(image[0])] = idx
image_name = image[-1].strip("\n")
image_names.append(image_name)
raw_pose.append([float(elem) for elem in image[1:-2]])
camera.append(int(image[-2]))
current_points3D_id_to_2D = {}
for x, y, point3D_id in zip(points[::3], points[1::3], points[2::3]):
if int(point3D_id) == -1:
continue
current_points3D_id_to_2D[int(point3D_id)] = [float(x), float(y)]
points3D_id_to_2D.append(current_points3D_id_to_2D)
n_points3D.append(len(current_points3D_id_to_2D))
n_images = len(image_names)
# Image and depthmaps paths
image_paths = []
depth_paths = []
for image_name in image_names:
image_path = os.path.join(images_path, image_name)
# Path to the depth file
depth_path = os.path.join(depths_path, "%s.h5" % os.path.splitext(image_name)[0])
if os.path.exists(depth_path):
# Check if depth map or background / foreground mask
file_size = os.stat(depth_path).st_size
# Rough estimate - 75KB might work as well
if file_size < 100 * 1024:
depth_paths.append(None)
image_paths.append(None)
else:
depth_paths.append(depth_path[len(base_path) + 1 :])
image_paths.append(image_path[len(base_path) + 1 :])
else:
depth_paths.append(None)
image_paths.append(None)
# Camera configuration
intrinsics = []
poses = []
principal_axis = []
points3D_id_to_ndepth = []
for idx, image_name in enumerate(image_names):
if image_paths[idx] is None:
intrinsics.append(None)
poses.append(None)
principal_axis.append([0, 0, 0])
points3D_id_to_ndepth.append({})
continue
image_intrinsics = camera_intrinsics[camera[idx]]
K = np.zeros([3, 3])
K[0, 0] = image_intrinsics[2]
K[0, 2] = image_intrinsics[4]
K[1, 1] = image_intrinsics[3]
K[1, 2] = image_intrinsics[5]
K[2, 2] = 1
intrinsics.append(K)
image_pose = raw_pose[idx]
qvec = image_pose[:4]
qvec = qvec / np.linalg.norm(qvec)
w, x, y, z = qvec
R = np.array(
[
[1 - 2 * y * y - 2 * z * z, 2 * x * y - 2 * z * w, 2 * x * z + 2 * y * w],
[2 * x * y + 2 * z * w, 1 - 2 * x * x - 2 * z * z, 2 * y * z - 2 * x * w],
[2 * x * z - 2 * y * w, 2 * y * z + 2 * x * w, 1 - 2 * x * x - 2 * y * y],
]
)
principal_axis.append(R[2, :])
t = image_pose[4:7]
# World-to-Camera pose
current_pose = np.zeros([4, 4])
current_pose[:3, :3] = R
current_pose[:3, 3] = t
current_pose[3, 3] = 1
# Camera-to-World pose
# pose = np.zeros([4, 4])
# pose[: 3, : 3] = np.transpose(R)
# pose[: 3, 3] = -np.matmul(np.transpose(R), t)
# pose[3, 3] = 1
poses.append(current_pose)
current_points3D_id_to_ndepth = {}
for point3D_id in points3D_id_to_2D[idx].keys():
p3d = points3D[point3D_id]
current_points3D_id_to_ndepth[point3D_id] = (np.dot(R[2, :], p3d) + t[2]) / (
0.5 * (K[0, 0] + K[1, 1])
)
points3D_id_to_ndepth.append(current_points3D_id_to_ndepth)
principal_axis = np.array(principal_axis)
angles = np.rad2deg(
np.arccos(np.clip(np.dot(principal_axis, np.transpose(principal_axis)), -1, 1))
)
# Compute overlap score
overlap_matrix = np.full([n_images, n_images], -1.0)
scale_ratio_matrix = np.full([n_images, n_images], -1.0)
for idx1 in range(n_images):
if image_paths[idx1] is None or depth_paths[idx1] is None:
continue
for idx2 in range(idx1 + 1, n_images):
if image_paths[idx2] is None or depth_paths[idx2] is None:
continue
matches = points3D_id_to_2D[idx1].keys() & points3D_id_to_2D[idx2].keys()
min_num_points3D = min(
len(points3D_id_to_2D[idx1]), len(points3D_id_to_2D[idx2])
)
overlap_matrix[idx1, idx2] = len(matches) / len(
points3D_id_to_2D[idx1]
) # min_num_points3D
overlap_matrix[idx2, idx1] = len(matches) / len(
points3D_id_to_2D[idx2]
) # min_num_points3D
if len(matches) == 0:
continue
points3D_id_to_ndepth1 = points3D_id_to_ndepth[idx1]
points3D_id_to_ndepth2 = points3D_id_to_ndepth[idx2]
nd1 = np.array([points3D_id_to_ndepth1[match] for match in matches])
nd2 = np.array([points3D_id_to_ndepth2[match] for match in matches])
min_scale_ratio = np.min(np.maximum(nd1 / nd2, nd2 / nd1))
scale_ratio_matrix[idx1, idx2] = min_scale_ratio
scale_ratio_matrix[idx2, idx1] = min_scale_ratio
np.savez(
os.path.join(args.output_path, "%s.npz" % scene_id),
image_paths=image_paths,
depth_paths=depth_paths,
intrinsics=intrinsics,
poses=poses,
overlap_matrix=overlap_matrix,
scale_ratio_matrix=scale_ratio_matrix,
angles=angles,
n_points3D=n_points3D,
points3D_id_to_2D=points3D_id_to_2D,
points3D_id_to_ndepth=points3D_id_to_ndepth,
)
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