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import os |
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import os.path as osp |
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import collections |
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from tqdm import tqdm |
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import numpy as np |
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os.environ["OPENCV_IO_ENABLE_OPENEXR"] = "1" |
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import cv2 |
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import h5py |
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import path_to_root |
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from dust3r.utils.parallel import parallel_threads |
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from dust3r.datasets.utils import cropping |
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def get_parser(): |
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import argparse |
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parser = argparse.ArgumentParser() |
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parser.add_argument('--megadepth_dir', required=True) |
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parser.add_argument('--precomputed_pairs', required=True) |
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parser.add_argument('--output_dir', default='data/megadepth_processed') |
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return parser |
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def main(db_root, pairs_path, output_dir): |
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os.makedirs(output_dir, exist_ok=True) |
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data = np.load(pairs_path, allow_pickle=True) |
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scenes = data['scenes'] |
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images = data['images'] |
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pairs = data['pairs'] |
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todo = collections.defaultdict(set) |
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for scene, im1, im2, score in pairs: |
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todo[scene].add(im1) |
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todo[scene].add(im2) |
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for scene, im_idxs in tqdm(todo.items(), desc='Overall'): |
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scene, subscene = scenes[scene].split() |
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out_dir = osp.join(output_dir, scene, subscene) |
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os.makedirs(out_dir, exist_ok=True) |
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_, pose_w2cam, intrinsics = _load_kpts_and_poses(db_root, scene, subscene, intrinsics=True) |
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in_dir = osp.join(db_root, scene, 'dense' + subscene) |
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args = [(in_dir, img, intrinsics[img], pose_w2cam[img], out_dir) |
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for img in [images[im_id] for im_id in im_idxs]] |
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parallel_threads(resize_one_image, args, star_args=True, front_num=0, leave=False, desc=f'{scene}/{subscene}') |
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print('Done! prepared all pairs in', output_dir) |
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def resize_one_image(root, tag, K_pre_rectif, pose_w2cam, out_dir): |
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if osp.isfile(osp.join(out_dir, tag + '.npz')): |
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return |
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img = cv2.cvtColor(cv2.imread(osp.join(root, 'imgs', tag), cv2.IMREAD_COLOR), cv2.COLOR_BGR2RGB) |
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H, W = img.shape[:2] |
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with h5py.File(osp.join(root, 'depths', osp.splitext(tag)[0] + '.h5'), 'r') as hd5: |
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depthmap = np.asarray(hd5['depth']) |
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imsize_pre, K_pre, distortion = K_pre_rectif |
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imsize_post = img.shape[1::-1] |
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K_post = cv2.getOptimalNewCameraMatrix(K_pre, distortion, imsize_pre, alpha=0, |
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newImgSize=imsize_post, centerPrincipalPoint=True)[0] |
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img_out, depthmap_out, intrinsics_out, R_in2out = _downscale_image(K_post, img, depthmap, resolution_out=(800, 600)) |
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img_out.save(osp.join(out_dir, tag + '.jpg'), quality=90) |
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cv2.imwrite(osp.join(out_dir, tag + '.exr'), depthmap_out) |
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camout2world = np.linalg.inv(pose_w2cam) |
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camout2world[:3, :3] = camout2world[:3, :3] @ R_in2out.T |
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np.savez(osp.join(out_dir, tag + '.npz'), intrinsics=intrinsics_out, cam2world=camout2world) |
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def _downscale_image(camera_intrinsics, image, depthmap, resolution_out=(512, 384)): |
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H, W = image.shape[:2] |
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resolution_out = sorted(resolution_out)[::+1 if W < H else -1] |
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image, depthmap, intrinsics_out = cropping.rescale_image_depthmap( |
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image, depthmap, camera_intrinsics, resolution_out, force=False) |
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R_in2out = np.eye(3) |
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return image, depthmap, intrinsics_out, R_in2out |
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def _load_kpts_and_poses(root, scene_id, subscene, z_only=False, intrinsics=False): |
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if intrinsics: |
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with open(os.path.join(root, scene_id, 'sparse', 'manhattan', subscene, 'cameras.txt'), 'r') as f: |
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raw = f.readlines()[3:] |
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camera_intrinsics = {} |
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for camera in raw: |
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camera = camera.split(' ') |
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width, height, focal, cx, cy, k0 = [float(elem) for elem in camera[2:]] |
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K = np.eye(3) |
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K[0, 0] = focal |
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K[1, 1] = focal |
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K[0, 2] = cx |
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K[1, 2] = cy |
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camera_intrinsics[int(camera[0])] = ((int(width), int(height)), K, (k0, 0, 0, 0)) |
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with open(os.path.join(root, scene_id, 'sparse', 'manhattan', subscene, 'images.txt'), 'r') as f: |
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raw = f.read().splitlines()[4:] |
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extract_pose = colmap_raw_pose_to_principal_axis if z_only else colmap_raw_pose_to_RT |
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poses = {} |
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points3D_idxs = {} |
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camera = [] |
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for image, points in zip(raw[:: 2], raw[1:: 2]): |
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image = image.split(' ') |
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points = points.split(' ') |
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image_id = image[-1] |
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camera.append(int(image[-2])) |
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raw_pose = [float(elem) for elem in image[1: -2]] |
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poses[image_id] = extract_pose(raw_pose) |
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current_points3D_idxs = {int(i) for i in points[2:: 3] if i != '-1'} |
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assert -1 not in current_points3D_idxs, bb() |
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points3D_idxs[image_id] = current_points3D_idxs |
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if intrinsics: |
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image_intrinsics = {im_id: camera_intrinsics[cam] for im_id, cam in zip(poses, camera)} |
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return points3D_idxs, poses, image_intrinsics |
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else: |
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return points3D_idxs, poses |
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def colmap_raw_pose_to_principal_axis(image_pose): |
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qvec = image_pose[: 4] |
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qvec = qvec / np.linalg.norm(qvec) |
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w, x, y, z = qvec |
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z_axis = np.float32([ |
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2 * x * z - 2 * y * w, |
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2 * y * z + 2 * x * w, |
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1 - 2 * x * x - 2 * y * y |
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]) |
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return z_axis |
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def colmap_raw_pose_to_RT(image_pose): |
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qvec = image_pose[: 4] |
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qvec = qvec / np.linalg.norm(qvec) |
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w, x, y, z = qvec |
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R = np.array([ |
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[ |
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1 - 2 * y * y - 2 * z * z, |
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2 * x * y - 2 * z * w, |
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2 * x * z + 2 * y * w |
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], |
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[ |
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2 * x * y + 2 * z * w, |
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1 - 2 * x * x - 2 * z * z, |
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2 * y * z - 2 * x * w |
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], |
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[ |
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2 * x * z - 2 * y * w, |
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2 * y * z + 2 * x * w, |
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1 - 2 * x * x - 2 * y * y |
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] |
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]) |
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t = image_pose[4: 7] |
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current_pose = np.eye(4) |
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current_pose[: 3, : 3] = R |
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current_pose[: 3, 3] = t |
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return current_pose |
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if __name__ == '__main__': |
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parser = get_parser() |
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args = parser.parse_args() |
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main(args.megadepth_dir, args.precomputed_pairs, args.output_dir) |
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