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code / elevation_estimate /utils /elev_est_api.py
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import os
import cv2
import numpy as np
import os.path as osp
import imageio
from copy import deepcopy
import loguru
import torch
import matplotlib.cm as cm
import matplotlib.pyplot as plt
from ..loftr import LoFTR, default_cfg
from . import plt_utils
from .plotting import make_matching_figure
from .utils3d import rect_to_img, canonical_to_camera, calc_pose
class ElevEstHelper:
_feature_matcher = None
@classmethod
def get_feature_matcher(cls):
if cls._feature_matcher is None:
loguru.logger.info("Loading feature matcher...")
_default_cfg = deepcopy(default_cfg)
_default_cfg['coarse']['temp_bug_fix'] = True # set to False when using the old ckpt
matcher = LoFTR(config=_default_cfg)
current_dir = os.path.dirname(os.path.abspath(__file__))
ckpt_path = os.path.join(current_dir, "weights/indoor_ds_new.ckpt")
if not osp.exists(ckpt_path):
raise FileNotFoundError(f"Checkpoint not found at {ckpt_path}")
matcher.load_state_dict(torch.load(ckpt_path)['state_dict'])
matcher = matcher.eval().cuda()
cls._feature_matcher = matcher
return cls._feature_matcher
def mask_out_bkgd(img_path, dbg=False):
img = imageio.imread_v2(img_path)
if img.shape[-1] == 4:
fg_mask = img[:, :, :3]
else:
loguru.logger.info("Image has no alpha channel, using thresholding to mask out background")
fg_mask = ~(img > 245).all(axis=-1)
if dbg:
plt.imshow(plt_utils.vis_mask(img, fg_mask.astype(np.uint8), color=[0, 255, 0]))
plt.show()
return fg_mask
def get_feature_matching(img_paths, dbg=False):
assert len(img_paths) == 4
matcher = ElevEstHelper.get_feature_matcher()
feature_matching = {}
masks = []
for i in range(4):
mask = mask_out_bkgd(img_paths[i], dbg=dbg)
masks.append(mask)
for i in range(0, 4):
for j in range(i + 1, 4):
img0_pth = img_paths[i]
img1_pth = img_paths[j]
mask0 = masks[i]
mask1 = masks[j]
img0_raw = cv2.imread(img0_pth, cv2.IMREAD_GRAYSCALE)
img1_raw = cv2.imread(img1_pth, cv2.IMREAD_GRAYSCALE)
original_shape = img0_raw.shape
img0_raw_resized = cv2.resize(img0_raw, (480, 480))
img1_raw_resized = cv2.resize(img1_raw, (480, 480))
img0 = torch.from_numpy(img0_raw_resized)[None][None].cuda() / 255.
img1 = torch.from_numpy(img1_raw_resized)[None][None].cuda() / 255.
batch = {'image0': img0, 'image1': img1}
# Inference with LoFTR and get prediction
with torch.no_grad():
matcher(batch)
mkpts0 = batch['mkpts0_f'].cpu().numpy()
mkpts1 = batch['mkpts1_f'].cpu().numpy()
mconf = batch['mconf'].cpu().numpy()
mkpts0[:, 0] = mkpts0[:, 0] * original_shape[1] / 480
mkpts0[:, 1] = mkpts0[:, 1] * original_shape[0] / 480
mkpts1[:, 0] = mkpts1[:, 0] * original_shape[1] / 480
mkpts1[:, 1] = mkpts1[:, 1] * original_shape[0] / 480
keep0 = mask0[mkpts0[:, 1].astype(int), mkpts1[:, 0].astype(int)]
keep1 = mask1[mkpts1[:, 1].astype(int), mkpts1[:, 0].astype(int)]
keep = np.logical_and(keep0, keep1)
mkpts0 = mkpts0[keep]
mkpts1 = mkpts1[keep]
mconf = mconf[keep]
if dbg:
# Draw visualization
color = cm.jet(mconf)
text = [
'LoFTR',
'Matches: {}'.format(len(mkpts0)),
]
fig = make_matching_figure(img0_raw, img1_raw, mkpts0, mkpts1, color, text=text)
fig.show()
feature_matching[f"{i}_{j}"] = np.concatenate([mkpts0, mkpts1, mconf[:, None]], axis=1)
return feature_matching
def gen_pose_hypothesis(center_elevation):
elevations = np.radians(
[center_elevation, center_elevation - 10, center_elevation + 10, center_elevation, center_elevation]) # 45~120
azimuths = np.radians([30, 30, 30, 20, 40])
input_poses = calc_pose(elevations, azimuths, len(azimuths))
input_poses = input_poses[1:]
input_poses[..., 1] *= -1
input_poses[..., 2] *= -1
return input_poses
def ba_error_general(K, matches, poses):
projmat0 = K @ poses[0].inverse()[:3, :4]
projmat1 = K @ poses[1].inverse()[:3, :4]
match_01 = matches[0]
pts0 = match_01[:, :2]
pts1 = match_01[:, 2:4]
Xref = cv2.triangulatePoints(projmat0.cpu().numpy(), projmat1.cpu().numpy(),
pts0.cpu().numpy().T, pts1.cpu().numpy().T)
Xref = Xref[:3] / Xref[3:]
Xref = Xref.T
Xref = torch.from_numpy(Xref).cuda().float()
reproj_error = 0
for match, cp in zip(matches[1:], poses[2:]):
dist = (torch.norm(match_01[:, :2][:, None, :] - match[:, :2][None, :, :], dim=-1))
if dist.numel() > 0:
# print("dist.shape", dist.shape)
m0to2_index = dist.argmin(1)
keep = dist[torch.arange(match_01.shape[0]), m0to2_index] < 1
if keep.sum() > 0:
xref_in2 = rect_to_img(K, canonical_to_camera(Xref, cp.inverse()))
reproj_error2 = torch.norm(match[m0to2_index][keep][:, 2:4] - xref_in2[keep], dim=-1)
conf02 = match[m0to2_index][keep][:, -1]
reproj_error += (reproj_error2 * conf02).sum() / (conf02.sum())
return reproj_error
def find_optim_elev(elevs, nimgs, matches, K, dbg=False):
errs = []
for elev in elevs:
err = 0
cam_poses = gen_pose_hypothesis(elev)
for start in range(nimgs - 1):
batch_matches, batch_poses = [], []
for i in range(start, nimgs + start):
ci = i % nimgs
batch_poses.append(cam_poses[ci])
for j in range(nimgs - 1):
key = f"{start}_{(start + j + 1) % nimgs}"
match = matches[key]
batch_matches.append(match)
err += ba_error_general(K, batch_matches, batch_poses)
errs.append(err)
errs = torch.tensor(errs)
if dbg:
plt.plot(elevs, errs)
plt.show()
optim_elev = elevs[torch.argmin(errs)].item()
return optim_elev
def get_elev_est(feature_matching, min_elev=30, max_elev=150, K=None, dbg=False):
flag = True
matches = {}
for i in range(4):
for j in range(i + 1, 4):
match_ij = feature_matching[f"{i}_{j}"]
if len(match_ij) == 0:
flag = False
match_ji = np.concatenate([match_ij[:, 2:4], match_ij[:, 0:2], match_ij[:, 4:5]], axis=1)
matches[f"{i}_{j}"] = torch.from_numpy(match_ij).float().cuda()
matches[f"{j}_{i}"] = torch.from_numpy(match_ji).float().cuda()
if not flag:
loguru.logger.info("0 matches, could not estimate elevation")
return None
interval = 10
elevs = np.arange(min_elev, max_elev, interval)
optim_elev1 = find_optim_elev(elevs, 4, matches, K)
elevs = np.arange(optim_elev1 - 10, optim_elev1 + 10, 1)
optim_elev2 = find_optim_elev(elevs, 4, matches, K)
return optim_elev2
def elev_est_api(img_paths, min_elev=30, max_elev=150, K=None, dbg=False):
feature_matching = get_feature_matching(img_paths, dbg=dbg)
if K is None:
loguru.logger.warning("K is not provided, using default K")
K = np.array([[280.0, 0, 128.0],
[0, 280.0, 128.0],
[0, 0, 1]])
K = torch.from_numpy(K).cuda().float()
elev = get_elev_est(feature_matching, min_elev, max_elev, K, dbg=dbg)
return elev