Spaces:
Sleeping
Sleeping
# %BANNER_BEGIN% | |
# --------------------------------------------------------------------- | |
# %COPYRIGHT_BEGIN% | |
# | |
# Magic Leap, Inc. ("COMPANY") CONFIDENTIAL | |
# | |
# Unpublished Copyright (c) 2020 | |
# Magic Leap, Inc., All Rights Reserved. | |
# | |
# NOTICE: All information contained herein is, and remains the property | |
# of COMPANY. The intellectual and technical concepts contained herein | |
# are proprietary to COMPANY and may be covered by U.S. and Foreign | |
# Patents, patents in process, and are protected by trade secret or | |
# copyright law. Dissemination of this information or reproduction of | |
# this material is strictly forbidden unless prior written permission is | |
# obtained from COMPANY. Access to the source code contained herein is | |
# hereby forbidden to anyone except current COMPANY employees, managers | |
# or contractors who have executed Confidentiality and Non-disclosure | |
# agreements explicitly covering such access. | |
# | |
# The copyright notice above does not evidence any actual or intended | |
# publication or disclosure of this source code, which includes | |
# information that is confidential and/or proprietary, and is a trade | |
# secret, of COMPANY. ANY REPRODUCTION, MODIFICATION, DISTRIBUTION, | |
# PUBLIC PERFORMANCE, OR PUBLIC DISPLAY OF OR THROUGH USE OF THIS | |
# SOURCE CODE WITHOUT THE EXPRESS WRITTEN CONSENT OF COMPANY IS | |
# STRICTLY PROHIBITED, AND IN VIOLATION OF APPLICABLE LAWS AND | |
# INTERNATIONAL TREATIES. THE RECEIPT OR POSSESSION OF THIS SOURCE | |
# CODE AND/OR RELATED INFORMATION DOES NOT CONVEY OR IMPLY ANY RIGHTS | |
# TO REPRODUCE, DISCLOSE OR DISTRIBUTE ITS CONTENTS, OR TO MANUFACTURE, | |
# USE, OR SELL ANYTHING THAT IT MAY DESCRIBE, IN WHOLE OR IN PART. | |
# | |
# %COPYRIGHT_END% | |
# ---------------------------------------------------------------------- | |
# %AUTHORS_BEGIN% | |
# | |
# Originating Authors: Paul-Edouard Sarlin | |
# Daniel DeTone | |
# Tomasz Malisiewicz | |
# | |
# %AUTHORS_END% | |
# --------------------------------------------------------------------*/ | |
# %BANNER_END% | |
from pathlib import Path | |
import time | |
from collections import OrderedDict | |
from threading import Thread | |
import numpy as np | |
import cv2 | |
import torch | |
import matplotlib.pyplot as plt | |
import matplotlib | |
matplotlib.use("Agg") | |
class AverageTimer: | |
"""Class to help manage printing simple timing of code execution.""" | |
def __init__(self, smoothing=0.3, newline=False): | |
self.smoothing = smoothing | |
self.newline = newline | |
self.times = OrderedDict() | |
self.will_print = OrderedDict() | |
self.reset() | |
def reset(self): | |
now = time.time() | |
self.start = now | |
self.last_time = now | |
for name in self.will_print: | |
self.will_print[name] = False | |
def update(self, name="default"): | |
now = time.time() | |
dt = now - self.last_time | |
if name in self.times: | |
dt = self.smoothing * dt + (1 - self.smoothing) * self.times[name] | |
self.times[name] = dt | |
self.will_print[name] = True | |
self.last_time = now | |
def print(self, text="Timer"): | |
total = 0.0 | |
print("[{}]".format(text), end=" ") | |
for key in self.times: | |
val = self.times[key] | |
if self.will_print[key]: | |
print("%s=%.3f" % (key, val), end=" ") | |
total += val | |
print("total=%.3f sec {%.1f FPS}" % (total, 1.0 / total), end=" ") | |
if self.newline: | |
print(flush=True) | |
else: | |
print(end="\r", flush=True) | |
self.reset() | |
class VideoStreamer: | |
"""Class to help process image streams. Four types of possible inputs:" | |
1.) USB Webcam. | |
2.) An IP camera | |
3.) A directory of images (files in directory matching 'image_glob'). | |
4.) A video file, such as an .mp4 or .avi file. | |
""" | |
def __init__(self, basedir, resize, skip, image_glob, max_length=1000000): | |
self._ip_grabbed = False | |
self._ip_running = False | |
self._ip_camera = False | |
self._ip_image = None | |
self._ip_index = 0 | |
self.cap = [] | |
self.camera = True | |
self.video_file = False | |
self.listing = [] | |
self.resize = resize | |
self.interp = cv2.INTER_AREA | |
self.i = 0 | |
self.skip = skip | |
self.max_length = max_length | |
if isinstance(basedir, int) or basedir.isdigit(): | |
print("==> Processing USB webcam input: {}".format(basedir)) | |
self.cap = cv2.VideoCapture(int(basedir)) | |
self.listing = range(0, self.max_length) | |
elif basedir.startswith(("http", "rtsp")): | |
print("==> Processing IP camera input: {}".format(basedir)) | |
self.cap = cv2.VideoCapture(basedir) | |
self.start_ip_camera_thread() | |
self._ip_camera = True | |
self.listing = range(0, self.max_length) | |
elif Path(basedir).is_dir(): | |
print("==> Processing image directory input: {}".format(basedir)) | |
self.listing = list(Path(basedir).glob(image_glob[0])) | |
for j in range(1, len(image_glob)): | |
image_path = list(Path(basedir).glob(image_glob[j])) | |
self.listing = self.listing + image_path | |
self.listing.sort() | |
self.listing = self.listing[:: self.skip] | |
self.max_length = np.min([self.max_length, len(self.listing)]) | |
if self.max_length == 0: | |
raise IOError("No images found (maybe bad 'image_glob' ?)") | |
self.listing = self.listing[: self.max_length] | |
self.camera = False | |
elif Path(basedir).exists(): | |
print("==> Processing video input: {}".format(basedir)) | |
self.cap = cv2.VideoCapture(basedir) | |
self.cap.set(cv2.CAP_PROP_BUFFERSIZE, 1) | |
num_frames = int(self.cap.get(cv2.CAP_PROP_FRAME_COUNT)) | |
self.listing = range(0, num_frames) | |
self.listing = self.listing[:: self.skip] | |
self.video_file = True | |
self.max_length = np.min([self.max_length, len(self.listing)]) | |
self.listing = self.listing[: self.max_length] | |
else: | |
raise ValueError('VideoStreamer input "{}" not recognized.'.format(basedir)) | |
if self.camera and not self.cap.isOpened(): | |
raise IOError("Could not read camera") | |
def load_image(self, impath): | |
"""Read image as grayscale and resize to img_size. | |
Inputs | |
impath: Path to input image. | |
Returns | |
grayim: uint8 numpy array sized H x W. | |
""" | |
grayim = cv2.imread(impath, 0) | |
if grayim is None: | |
raise Exception("Error reading image %s" % impath) | |
w, h = grayim.shape[1], grayim.shape[0] | |
w_new, h_new = process_resize(w, h, self.resize) | |
grayim = cv2.resize(grayim, (w_new, h_new), interpolation=self.interp) | |
return grayim | |
def next_frame(self): | |
"""Return the next frame, and increment internal counter. | |
Returns | |
image: Next H x W image. | |
status: True or False depending whether image was loaded. | |
""" | |
if self.i == self.max_length: | |
return (None, False) | |
if self.camera: | |
if self._ip_camera: | |
# Wait for first image, making sure we haven't exited | |
while self._ip_grabbed is False and self._ip_exited is False: | |
time.sleep(0.001) | |
ret, image = self._ip_grabbed, self._ip_image.copy() | |
if ret is False: | |
self._ip_running = False | |
else: | |
ret, image = self.cap.read() | |
if ret is False: | |
print("VideoStreamer: Cannot get image from camera") | |
return (None, False) | |
w, h = image.shape[1], image.shape[0] | |
if self.video_file: | |
self.cap.set(cv2.CAP_PROP_POS_FRAMES, self.listing[self.i]) | |
w_new, h_new = process_resize(w, h, self.resize) | |
image = cv2.resize(image, (w_new, h_new), interpolation=self.interp) | |
image = cv2.cvtColor(image, cv2.COLOR_RGB2GRAY) | |
else: | |
image_file = str(self.listing[self.i]) | |
image = self.load_image(image_file) | |
self.i = self.i + 1 | |
return (image, True) | |
def start_ip_camera_thread(self): | |
self._ip_thread = Thread(target=self.update_ip_camera, args=()) | |
self._ip_running = True | |
self._ip_thread.start() | |
self._ip_exited = False | |
return self | |
def update_ip_camera(self): | |
while self._ip_running: | |
ret, img = self.cap.read() | |
if ret is False: | |
self._ip_running = False | |
self._ip_exited = True | |
self._ip_grabbed = False | |
return | |
self._ip_image = img | |
self._ip_grabbed = ret | |
self._ip_index += 1 | |
# print('IPCAMERA THREAD got frame {}'.format(self._ip_index)) | |
def cleanup(self): | |
self._ip_running = False | |
# --- PREPROCESSING --- | |
def process_resize(w, h, resize): | |
assert len(resize) > 0 and len(resize) <= 2 | |
if len(resize) == 1 and resize[0] > -1: | |
scale = resize[0] / max(h, w) | |
w_new, h_new = int(round(w * scale)), int(round(h * scale)) | |
elif len(resize) == 1 and resize[0] == -1: | |
w_new, h_new = w, h | |
else: # len(resize) == 2: | |
w_new, h_new = resize[0], resize[1] | |
# Issue warning if resolution is too small or too large. | |
if max(w_new, h_new) < 160: | |
print("Warning: input resolution is very small, results may vary") | |
elif max(w_new, h_new) > 2000: | |
print("Warning: input resolution is very large, results may vary") | |
return w_new, h_new | |
def frame2tensor(frame, device): | |
return torch.from_numpy(frame / 255.0).float()[None, None].to(device) | |
def read_image(path, device, resize, rotation, resize_float): | |
image = cv2.imread(str(path), cv2.IMREAD_GRAYSCALE) | |
if image is None: | |
return None, None, None | |
w, h = image.shape[1], image.shape[0] | |
w_new, h_new = process_resize(w, h, resize) | |
scales = (float(w) / float(w_new), float(h) / float(h_new)) | |
if resize_float: | |
image = cv2.resize(image.astype("float32"), (w_new, h_new)) | |
else: | |
image = cv2.resize(image, (w_new, h_new)).astype("float32") | |
if rotation != 0: | |
image = np.rot90(image, k=rotation) | |
if rotation % 2: | |
scales = scales[::-1] | |
inp = frame2tensor(image, device) | |
return image, inp, scales | |
# --- GEOMETRY --- | |
def estimate_pose(kpts0, kpts1, K0, K1, thresh, conf=0.99999): | |
if len(kpts0) < 5: | |
return None | |
f_mean = np.mean([K0[0, 0], K1[1, 1], K0[0, 0], K1[1, 1]]) | |
norm_thresh = thresh / f_mean | |
kpts0 = (kpts0 - K0[[0, 1], [2, 2]][None]) / K0[[0, 1], [0, 1]][None] | |
kpts1 = (kpts1 - K1[[0, 1], [2, 2]][None]) / K1[[0, 1], [0, 1]][None] | |
E, mask = cv2.findEssentialMat( | |
kpts0, kpts1, np.eye(3), threshold=norm_thresh, prob=conf, method=cv2.RANSAC | |
) | |
assert E is not None | |
best_num_inliers = 0 | |
ret = None | |
for _E in np.split(E, len(E) / 3): | |
n, R, t, _ = cv2.recoverPose(_E, kpts0, kpts1, np.eye(3), 1e9, mask=mask) | |
if n > best_num_inliers: | |
best_num_inliers = n | |
ret = (R, t[:, 0], mask.ravel() > 0) | |
return ret | |
def rotate_intrinsics(K, image_shape, rot): | |
"""image_shape is the shape of the image after rotation""" | |
assert rot <= 3 | |
h, w = image_shape[:2][:: -1 if (rot % 2) else 1] | |
fx, fy, cx, cy = K[0, 0], K[1, 1], K[0, 2], K[1, 2] | |
rot = rot % 4 | |
if rot == 1: | |
return np.array( | |
[[fy, 0.0, cy], [0.0, fx, w - 1 - cx], [0.0, 0.0, 1.0]], dtype=K.dtype | |
) | |
elif rot == 2: | |
return np.array( | |
[[fx, 0.0, w - 1 - cx], [0.0, fy, h - 1 - cy], [0.0, 0.0, 1.0]], | |
dtype=K.dtype, | |
) | |
else: # if rot == 3: | |
return np.array( | |
[[fy, 0.0, h - 1 - cy], [0.0, fx, cx], [0.0, 0.0, 1.0]], dtype=K.dtype | |
) | |
def rotate_pose_inplane(i_T_w, rot): | |
rotation_matrices = [ | |
np.array( | |
[ | |
[np.cos(r), -np.sin(r), 0.0, 0.0], | |
[np.sin(r), np.cos(r), 0.0, 0.0], | |
[0.0, 0.0, 1.0, 0.0], | |
[0.0, 0.0, 0.0, 1.0], | |
], | |
dtype=np.float32, | |
) | |
for r in [np.deg2rad(d) for d in (0, 270, 180, 90)] | |
] | |
return np.dot(rotation_matrices[rot], i_T_w) | |
def scale_intrinsics(K, scales): | |
scales = np.diag([1.0 / scales[0], 1.0 / scales[1], 1.0]) | |
return np.dot(scales, K) | |
def to_homogeneous(points): | |
return np.concatenate([points, np.ones_like(points[:, :1])], axis=-1) | |
def compute_epipolar_error(kpts0, kpts1, T_0to1, K0, K1): | |
kpts0 = (kpts0 - K0[[0, 1], [2, 2]][None]) / K0[[0, 1], [0, 1]][None] | |
kpts1 = (kpts1 - K1[[0, 1], [2, 2]][None]) / K1[[0, 1], [0, 1]][None] | |
kpts0 = to_homogeneous(kpts0) | |
kpts1 = to_homogeneous(kpts1) | |
t0, t1, t2 = T_0to1[:3, 3] | |
t_skew = np.array([[0, -t2, t1], [t2, 0, -t0], [-t1, t0, 0]]) | |
E = t_skew @ T_0to1[:3, :3] | |
Ep0 = kpts0 @ E.T # N x 3 | |
p1Ep0 = np.sum(kpts1 * Ep0, -1) # N | |
Etp1 = kpts1 @ E # N x 3 | |
d = p1Ep0**2 * ( | |
1.0 / (Ep0[:, 0] ** 2 + Ep0[:, 1] ** 2) | |
+ 1.0 / (Etp1[:, 0] ** 2 + Etp1[:, 1] ** 2) | |
) | |
return d | |
def angle_error_mat(R1, R2): | |
cos = (np.trace(np.dot(R1.T, R2)) - 1) / 2 | |
cos = np.clip(cos, -1.0, 1.0) # numercial errors can make it out of bounds | |
return np.rad2deg(np.abs(np.arccos(cos))) | |
def angle_error_vec(v1, v2): | |
n = np.linalg.norm(v1) * np.linalg.norm(v2) | |
return np.rad2deg(np.arccos(np.clip(np.dot(v1, v2) / n, -1.0, 1.0))) | |
def compute_pose_error(T_0to1, R, t): | |
R_gt = T_0to1[:3, :3] | |
t_gt = T_0to1[:3, 3] | |
error_t = angle_error_vec(t, t_gt) | |
error_t = np.minimum(error_t, 180 - error_t) # ambiguity of E estimation | |
error_R = angle_error_mat(R, R_gt) | |
return error_t, error_R | |
def pose_auc(errors, thresholds): | |
sort_idx = np.argsort(errors) | |
errors = np.array(errors.copy())[sort_idx] | |
recall = (np.arange(len(errors)) + 1) / len(errors) | |
errors = np.r_[0.0, errors] | |
recall = np.r_[0.0, recall] | |
aucs = [] | |
for t in thresholds: | |
last_index = np.searchsorted(errors, t) | |
r = np.r_[recall[:last_index], recall[last_index - 1]] | |
e = np.r_[errors[:last_index], t] | |
aucs.append(np.trapz(r, x=e) / t) | |
return aucs | |
# --- VISUALIZATION --- | |
def plot_image_pair(imgs, dpi=100, size=6, pad=0.5): | |
n = len(imgs) | |
assert n == 2, "number of images must be two" | |
figsize = (size * n, size * 3 / 4) if size is not None else None | |
_, ax = plt.subplots(1, n, figsize=figsize, dpi=dpi) | |
for i in range(n): | |
ax[i].imshow(imgs[i], cmap=plt.get_cmap("gray"), vmin=0, vmax=255) | |
ax[i].get_yaxis().set_ticks([]) | |
ax[i].get_xaxis().set_ticks([]) | |
for spine in ax[i].spines.values(): # remove frame | |
spine.set_visible(False) | |
plt.tight_layout(pad=pad) | |
def plot_keypoints(kpts0, kpts1, color="w", ps=2): | |
ax = plt.gcf().axes | |
ax[0].scatter(kpts0[:, 0], kpts0[:, 1], c=color, s=ps) | |
ax[1].scatter(kpts1[:, 0], kpts1[:, 1], c=color, s=ps) | |
def plot_matches(kpts0, kpts1, color, lw=1.5, ps=4): | |
fig = plt.gcf() | |
ax = fig.axes | |
fig.canvas.draw() | |
transFigure = fig.transFigure.inverted() | |
fkpts0 = transFigure.transform(ax[0].transData.transform(kpts0)) | |
fkpts1 = transFigure.transform(ax[1].transData.transform(kpts1)) | |
fig.lines = [ | |
matplotlib.lines.Line2D( | |
(fkpts0[i, 0], fkpts1[i, 0]), | |
(fkpts0[i, 1], fkpts1[i, 1]), | |
zorder=1, | |
transform=fig.transFigure, | |
c=color[i], | |
linewidth=lw, | |
) | |
for i in range(len(kpts0)) | |
] | |
ax[0].scatter(kpts0[:, 0], kpts0[:, 1], c=color, s=ps) | |
ax[1].scatter(kpts1[:, 0], kpts1[:, 1], c=color, s=ps) | |
def make_matching_plot( | |
image0, | |
image1, | |
kpts0, | |
kpts1, | |
mkpts0, | |
mkpts1, | |
color, | |
text, | |
path, | |
show_keypoints=False, | |
fast_viz=False, | |
opencv_display=False, | |
opencv_title="matches", | |
small_text=[], | |
): | |
if fast_viz: | |
make_matching_plot_fast( | |
image0, | |
image1, | |
kpts0, | |
kpts1, | |
mkpts0, | |
mkpts1, | |
color, | |
text, | |
path, | |
show_keypoints, | |
10, | |
opencv_display, | |
opencv_title, | |
small_text, | |
) | |
return | |
plot_image_pair([image0, image1]) | |
if show_keypoints: | |
plot_keypoints(kpts0, kpts1, color="k", ps=4) | |
plot_keypoints(kpts0, kpts1, color="w", ps=2) | |
plot_matches(mkpts0, mkpts1, color) | |
fig = plt.gcf() | |
txt_color = "k" if image0[:100, :150].mean() > 200 else "w" | |
fig.text( | |
0.01, | |
0.99, | |
"\n".join(text), | |
transform=fig.axes[0].transAxes, | |
fontsize=15, | |
va="top", | |
ha="left", | |
color=txt_color, | |
) | |
txt_color = "k" if image0[-100:, :150].mean() > 200 else "w" | |
fig.text( | |
0.01, | |
0.01, | |
"\n".join(small_text), | |
transform=fig.axes[0].transAxes, | |
fontsize=5, | |
va="bottom", | |
ha="left", | |
color=txt_color, | |
) | |
plt.savefig(str(path), bbox_inches="tight", pad_inches=0) | |
plt.close() | |
def make_matching_plot_fast( | |
image0, | |
image1, | |
kpts0, | |
kpts1, | |
mkpts0, | |
mkpts1, | |
color, | |
text, | |
path=None, | |
show_keypoints=False, | |
margin=10, | |
opencv_display=False, | |
opencv_title="", | |
small_text=[], | |
): | |
H0, W0 = image0.shape | |
H1, W1 = image1.shape | |
H, W = max(H0, H1), W0 + W1 + margin | |
out = 255 * np.ones((H, W), np.uint8) | |
out[:H0, :W0] = image0 | |
out[:H1, W0 + margin :] = image1 | |
out = np.stack([out] * 3, -1) | |
if show_keypoints: | |
kpts0, kpts1 = np.round(kpts0).astype(int), np.round(kpts1).astype(int) | |
white = (255, 255, 255) | |
black = (0, 0, 0) | |
for x, y in kpts0: | |
cv2.circle(out, (x, y), 2, black, -1, lineType=cv2.LINE_AA) | |
cv2.circle(out, (x, y), 1, white, -1, lineType=cv2.LINE_AA) | |
for x, y in kpts1: | |
cv2.circle(out, (x + margin + W0, y), 2, black, -1, lineType=cv2.LINE_AA) | |
cv2.circle(out, (x + margin + W0, y), 1, white, -1, lineType=cv2.LINE_AA) | |
mkpts0, mkpts1 = np.round(mkpts0).astype(int), np.round(mkpts1).astype(int) | |
color = (np.array(color[:, :3]) * 255).astype(int)[:, ::-1] | |
for (x0, y0), (x1, y1), c in zip(mkpts0, mkpts1, color): | |
c = c.tolist() | |
cv2.line( | |
out, | |
(x0, y0), | |
(x1 + margin + W0, y1), | |
color=c, | |
thickness=1, | |
lineType=cv2.LINE_AA, | |
) | |
# display line end-points as circles | |
cv2.circle(out, (x0, y0), 2, c, -1, lineType=cv2.LINE_AA) | |
cv2.circle(out, (x1 + margin + W0, y1), 2, c, -1, lineType=cv2.LINE_AA) | |
# Scale factor for consistent visualization across scales. | |
sc = min(H / 640.0, 2.0) | |
# Big text. | |
Ht = int(30 * sc) # text height | |
txt_color_fg = (255, 255, 255) | |
txt_color_bg = (0, 0, 0) | |
for i, t in enumerate(text): | |
cv2.putText( | |
out, | |
t, | |
(int(8 * sc), Ht * (i + 1)), | |
cv2.FONT_HERSHEY_DUPLEX, | |
1.0 * sc, | |
txt_color_bg, | |
2, | |
cv2.LINE_AA, | |
) | |
cv2.putText( | |
out, | |
t, | |
(int(8 * sc), Ht * (i + 1)), | |
cv2.FONT_HERSHEY_DUPLEX, | |
1.0 * sc, | |
txt_color_fg, | |
1, | |
cv2.LINE_AA, | |
) | |
# Small text. | |
Ht = int(18 * sc) # text height | |
for i, t in enumerate(reversed(small_text)): | |
cv2.putText( | |
out, | |
t, | |
(int(8 * sc), int(H - Ht * (i + 0.6))), | |
cv2.FONT_HERSHEY_DUPLEX, | |
0.5 * sc, | |
txt_color_bg, | |
2, | |
cv2.LINE_AA, | |
) | |
cv2.putText( | |
out, | |
t, | |
(int(8 * sc), int(H - Ht * (i + 0.6))), | |
cv2.FONT_HERSHEY_DUPLEX, | |
0.5 * sc, | |
txt_color_fg, | |
1, | |
cv2.LINE_AA, | |
) | |
if path is not None: | |
cv2.imwrite(str(path), out) | |
if opencv_display: | |
cv2.imshow(opencv_title, out) | |
cv2.waitKey(1) | |
return out | |
def error_colormap(x): | |
return np.clip( | |
np.stack([2 - x * 2, x * 2, np.zeros_like(x), np.ones_like(x)], -1), 0, 1 | |
) | |