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import os |
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import cv2 |
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import numpy as np |
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import os.path as osp |
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import imageio |
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from copy import deepcopy |
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import loguru |
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import torch |
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import matplotlib.cm as cm |
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import matplotlib.pyplot as plt |
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from ..loftr import LoFTR, default_cfg |
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from . import plt_utils |
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from .plotting import make_matching_figure |
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from .utils3d import rect_to_img, canonical_to_camera, calc_pose |
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class ElevEstHelper: |
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_feature_matcher = None |
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@classmethod |
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def get_feature_matcher(cls): |
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if cls._feature_matcher is None: |
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loguru.logger.info("Loading feature matcher...") |
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_default_cfg = deepcopy(default_cfg) |
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_default_cfg['coarse']['temp_bug_fix'] = True |
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matcher = LoFTR(config=_default_cfg) |
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current_dir = os.path.dirname(os.path.abspath(__file__)) |
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ckpt_path = os.path.join(current_dir, "weights/indoor_ds_new.ckpt") |
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if not osp.exists(ckpt_path): |
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raise FileNotFoundError(f"Checkpoint not found at {ckpt_path}") |
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matcher.load_state_dict(torch.load(ckpt_path)['state_dict']) |
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matcher = matcher.eval().cuda() |
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cls._feature_matcher = matcher |
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return cls._feature_matcher |
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def mask_out_bkgd(img_path, dbg=False): |
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img = imageio.imread_v2(img_path) |
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if img.shape[-1] == 4: |
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fg_mask = img[:, :, :3] |
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else: |
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loguru.logger.info("Image has no alpha channel, using thresholding to mask out background") |
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fg_mask = ~(img > 245).all(axis=-1) |
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if dbg: |
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plt.imshow(plt_utils.vis_mask(img, fg_mask.astype(np.uint8), color=[0, 255, 0])) |
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plt.show() |
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return fg_mask |
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def get_feature_matching(img_paths, dbg=False): |
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assert len(img_paths) == 4 |
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matcher = ElevEstHelper.get_feature_matcher() |
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feature_matching = {} |
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masks = [] |
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for i in range(4): |
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mask = mask_out_bkgd(img_paths[i], dbg=dbg) |
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masks.append(mask) |
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for i in range(0, 4): |
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for j in range(i + 1, 4): |
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img0_pth = img_paths[i] |
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img1_pth = img_paths[j] |
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mask0 = masks[i] |
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mask1 = masks[j] |
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img0_raw = cv2.imread(img0_pth, cv2.IMREAD_GRAYSCALE) |
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img1_raw = cv2.imread(img1_pth, cv2.IMREAD_GRAYSCALE) |
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original_shape = img0_raw.shape |
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img0_raw_resized = cv2.resize(img0_raw, (480, 480)) |
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img1_raw_resized = cv2.resize(img1_raw, (480, 480)) |
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img0 = torch.from_numpy(img0_raw_resized)[None][None].cuda() / 255. |
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img1 = torch.from_numpy(img1_raw_resized)[None][None].cuda() / 255. |
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batch = {'image0': img0, 'image1': img1} |
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with torch.no_grad(): |
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matcher(batch) |
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mkpts0 = batch['mkpts0_f'].cpu().numpy() |
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mkpts1 = batch['mkpts1_f'].cpu().numpy() |
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mconf = batch['mconf'].cpu().numpy() |
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mkpts0[:, 0] = mkpts0[:, 0] * original_shape[1] / 480 |
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mkpts0[:, 1] = mkpts0[:, 1] * original_shape[0] / 480 |
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mkpts1[:, 0] = mkpts1[:, 0] * original_shape[1] / 480 |
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mkpts1[:, 1] = mkpts1[:, 1] * original_shape[0] / 480 |
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keep0 = mask0[mkpts0[:, 1].astype(int), mkpts1[:, 0].astype(int)] |
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keep1 = mask1[mkpts1[:, 1].astype(int), mkpts1[:, 0].astype(int)] |
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keep = np.logical_and(keep0, keep1) |
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mkpts0 = mkpts0[keep] |
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mkpts1 = mkpts1[keep] |
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mconf = mconf[keep] |
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if dbg: |
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color = cm.jet(mconf) |
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text = [ |
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'LoFTR', |
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'Matches: {}'.format(len(mkpts0)), |
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] |
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fig = make_matching_figure(img0_raw, img1_raw, mkpts0, mkpts1, color, text=text) |
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fig.show() |
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feature_matching[f"{i}_{j}"] = np.concatenate([mkpts0, mkpts1, mconf[:, None]], axis=1) |
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return feature_matching |
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def gen_pose_hypothesis(center_elevation): |
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elevations = np.radians( |
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[center_elevation, center_elevation - 10, center_elevation + 10, center_elevation, center_elevation]) |
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azimuths = np.radians([30, 30, 30, 20, 40]) |
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input_poses = calc_pose(elevations, azimuths, len(azimuths)) |
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input_poses = input_poses[1:] |
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input_poses[..., 1] *= -1 |
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input_poses[..., 2] *= -1 |
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return input_poses |
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def ba_error_general(K, matches, poses): |
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projmat0 = K @ poses[0].inverse()[:3, :4] |
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projmat1 = K @ poses[1].inverse()[:3, :4] |
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match_01 = matches[0] |
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pts0 = match_01[:, :2] |
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pts1 = match_01[:, 2:4] |
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Xref = cv2.triangulatePoints(projmat0.cpu().numpy(), projmat1.cpu().numpy(), |
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pts0.cpu().numpy().T, pts1.cpu().numpy().T) |
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Xref = Xref[:3] / Xref[3:] |
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Xref = Xref.T |
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Xref = torch.from_numpy(Xref).cuda().float() |
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reproj_error = 0 |
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for match, cp in zip(matches[1:], poses[2:]): |
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dist = (torch.norm(match_01[:, :2][:, None, :] - match[:, :2][None, :, :], dim=-1)) |
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if dist.numel() > 0: |
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m0to2_index = dist.argmin(1) |
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keep = dist[torch.arange(match_01.shape[0]), m0to2_index] < 1 |
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if keep.sum() > 0: |
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xref_in2 = rect_to_img(K, canonical_to_camera(Xref, cp.inverse())) |
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reproj_error2 = torch.norm(match[m0to2_index][keep][:, 2:4] - xref_in2[keep], dim=-1) |
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conf02 = match[m0to2_index][keep][:, -1] |
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reproj_error += (reproj_error2 * conf02).sum() / (conf02.sum()) |
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return reproj_error |
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def find_optim_elev(elevs, nimgs, matches, K, dbg=False): |
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errs = [] |
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for elev in elevs: |
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err = 0 |
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cam_poses = gen_pose_hypothesis(elev) |
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for start in range(nimgs - 1): |
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batch_matches, batch_poses = [], [] |
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for i in range(start, nimgs + start): |
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ci = i % nimgs |
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batch_poses.append(cam_poses[ci]) |
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for j in range(nimgs - 1): |
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key = f"{start}_{(start + j + 1) % nimgs}" |
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match = matches[key] |
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batch_matches.append(match) |
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err += ba_error_general(K, batch_matches, batch_poses) |
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errs.append(err) |
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errs = torch.tensor(errs) |
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if dbg: |
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plt.plot(elevs, errs) |
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plt.show() |
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optim_elev = elevs[torch.argmin(errs)].item() |
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return optim_elev |
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def get_elev_est(feature_matching, min_elev=30, max_elev=150, K=None, dbg=False): |
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flag = True |
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matches = {} |
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for i in range(4): |
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for j in range(i + 1, 4): |
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match_ij = feature_matching[f"{i}_{j}"] |
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if len(match_ij) == 0: |
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flag = False |
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match_ji = np.concatenate([match_ij[:, 2:4], match_ij[:, 0:2], match_ij[:, 4:5]], axis=1) |
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matches[f"{i}_{j}"] = torch.from_numpy(match_ij).float().cuda() |
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matches[f"{j}_{i}"] = torch.from_numpy(match_ji).float().cuda() |
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if not flag: |
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loguru.logger.info("0 matches, could not estimate elevation") |
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return None |
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interval = 10 |
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elevs = np.arange(min_elev, max_elev, interval) |
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optim_elev1 = find_optim_elev(elevs, 4, matches, K) |
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elevs = np.arange(optim_elev1 - 10, optim_elev1 + 10, 1) |
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optim_elev2 = find_optim_elev(elevs, 4, matches, K) |
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return optim_elev2 |
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def elev_est_api(img_paths, min_elev=30, max_elev=150, K=None, dbg=False): |
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feature_matching = get_feature_matching(img_paths, dbg=dbg) |
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if K is None: |
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loguru.logger.warning("K is not provided, using default K") |
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K = np.array([[280.0, 0, 128.0], |
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[0, 280.0, 128.0], |
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[0, 0, 1]]) |
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K = torch.from_numpy(K).cuda().float() |
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elev = get_elev_est(feature_matching, min_elev, max_elev, K, dbg=dbg) |
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return elev |
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