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slam.py
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slam.py
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#!/usr/bin/env python3
import os
import sys
sys.path.append("lib/macosx")
sys.path.append("lib/linux")
import time
import cv2
from display import Display2D, Display3D
from frame import Frame, match_frames
import numpy as np
import g2o
from pointmap import Map, Point
from helpers import triangulate, add_ones
np.set_printoptions(suppress=True)
class SLAM(object):
def __init__(self, W, H, K):
# main classes
self.mapp = Map()
# params
self.W, self.H = W, H
self.K = K
def process_frame(self, img, pose=None, verts=None):
start_time = time.time()
assert img.shape[0:2] == (self.H, self.W)
frame = Frame(self.mapp, img, self.K, verts=verts)
if frame.id == 0:
return
f1 = self.mapp.frames[-1]
f2 = self.mapp.frames[-2]
idx1, idx2, Rt = match_frames(f1, f2)
# add new observations if the point is already observed in the previous frame
# TODO: consider tradeoff doing this before/after search by projection
for i,idx in enumerate(idx2):
if f2.pts[idx] is not None and f1.pts[idx1[i]] is None:
f2.pts[idx].add_observation(f1, idx1[i])
if frame.id < 5 or True:
# get initial positions from fundamental matrix
f1.pose = np.dot(Rt, f2.pose)
else:
# kinematic model (not used)
velocity = np.dot(f2.pose, np.linalg.inv(self.mapp.frames[-3].pose))
f1.pose = np.dot(velocity, f2.pose)
# pose optimization
if pose is None:
#print(f1.pose)
pose_opt = self.mapp.optimize(local_window=1, fix_points=True)
print("Pose: %f" % pose_opt)
#print(f1.pose)
else:
# have ground truth for pose
f1.pose = pose
sbp_pts_count = 0
# search by projection
if len(self.mapp.points) > 0:
# project *all* the map points into the current frame
map_points = np.array([p.homogeneous() for p in self.mapp.points])
projs = np.dot(np.dot(self.K, f1.pose[:3]), map_points.T).T
projs = projs[:, 0:2] / projs[:, 2:]
# only the points that fit in the frame
good_pts = (projs[:, 0] > 0) & (projs[:, 0] < self.W) & \
(projs[:, 1] > 0) & (projs[:, 1] < self.H)
for i, p in enumerate(self.mapp.points):
if not good_pts[i]:
# point not visible in frame
continue
if f1 in p.frames:
# we already matched this map point to this frame
# TODO: understand this better
continue
for m_idx in f1.kd.query_ball_point(projs[i], 2):
# if point unmatched
if f1.pts[m_idx] is None:
b_dist = p.orb_distance(f1.des[m_idx])
# if any descriptors within 64
if b_dist < 64.0:
p.add_observation(f1, m_idx)
sbp_pts_count += 1
break
# triangulate the points we don't have matches for
good_pts4d = np.array([f1.pts[i] is None for i in idx1])
# do triangulation in global frame
pts4d = triangulate(f1.pose, f2.pose, f1.kps[idx1], f2.kps[idx2])
good_pts4d &= np.abs(pts4d[:, 3]) != 0
pts4d /= pts4d[:, 3:] # homogeneous 3-D coords
# adding new points to the map from pairwise matches
new_pts_count = 0
for i,p in enumerate(pts4d):
if not good_pts4d[i]:
continue
# check parallax is large enough
# TODO: learn what parallax means
"""
r1 = np.dot(f1.pose[:3, :3], add_ones(f1.kps[idx1[i]]))
r2 = np.dot(f2.pose[:3, :3], add_ones(f2.kps[idx2[i]]))
parallax = r1.dot(r2) / (np.linalg.norm(r1) * np.linalg.norm(r2))
if parallax >= 0.9998:
continue
"""
# check points are in front of both cameras
pl1 = np.dot(f1.pose, p)
pl2 = np.dot(f2.pose, p)
if pl1[2] < 0 or pl2[2] < 0:
continue
# reproject
pp1 = np.dot(self.K, pl1[:3])
pp2 = np.dot(self.K, pl2[:3])
# check reprojection error
pp1 = (pp1[0:2] / pp1[2]) - f1.kpus[idx1[i]]
pp2 = (pp2[0:2] / pp2[2]) - f2.kpus[idx2[i]]
pp1 = np.sum(pp1**2)
pp2 = np.sum(pp2**2)
if pp1 > 2 or pp2 > 2:
continue
# add the point
try:
color = img[int(round(f1.kpus[idx1[i],1])), int(round(f1.kpus[idx1[i],0]))]
except IndexError:
color = (255,0,0)
pt = Point(self.mapp, p[0:3], color)
pt.add_observation(f2, idx2[i])
pt.add_observation(f1, idx1[i])
new_pts_count += 1
print("Adding: %d new points, %d search by projection" % (new_pts_count, sbp_pts_count))
# optimize the map
if frame.id >= 4 and frame.id%5 == 0:
err = self.mapp.optimize() #verbose=True)
print("Optimize: %f units of error" % err)
print("Map: %d points, %d frames" % (len(self.mapp.points), len(self.mapp.frames)))
print("Time: %.2f ms" % ((time.time()-start_time)*1000.0))
print(np.linalg.inv(f1.pose))
if __name__ == "__main__":
if len(sys.argv) < 2:
print("%s <video.mp4>" % sys.argv[0])
exit(-1)
disp2d, disp3d = None, None
if os.getenv("HEADLESS") is None:
disp3d = Display3D()
cap = cv2.VideoCapture(sys.argv[1])
# camera parameters
W = int(cap.get(cv2.CAP_PROP_FRAME_WIDTH))
H = int(cap.get(cv2.CAP_PROP_FRAME_HEIGHT))
CNT = int(cap.get(cv2.CAP_PROP_FRAME_COUNT))
F = float(os.getenv("F", "525"))
if os.getenv("SEEK") is not None:
cap.set(cv2.CAP_PROP_POS_FRAMES, int(os.getenv("SEEK")))
if W > 1024:
downscale = 1024.0/W
F *= downscale
H = int(H * downscale)
W = 1024
print("using camera %dx%d with F %f" % (W,H,F))
# camera intrinsics
K = np.array([[F,0,W//2],[0,F,H//2],[0,0,1]])
Kinv = np.linalg.inv(K)
# create 2-D display
if os.getenv("HEADLESS") is None:
disp2d = Display2D(W, H)
slam = SLAM(W, H, K)
"""
mapp.deserialize(open('map.json').read())
while 1:
disp3d.paint(mapp)
time.sleep(1)
"""
gt_pose = None
if len(sys.argv) >= 3:
gt_pose = np.load(sys.argv[2])['pose']
# add scale param?
gt_pose[:, :3, 3] *= 50
i = 0
while cap.isOpened():
ret, frame = cap.read()
frame = cv2.resize(frame, (W, H))
print("\n*** frame %d/%d ***" % (i, CNT))
if ret == True:
slam.process_frame(frame, None if gt_pose is None else np.linalg.inv(gt_pose[i]))
else:
break
# 3-D display
if disp3d is not None:
disp3d.paint(slam.mapp)
if disp2d is not None:
img = slam.mapp.frames[-1].annotate(frame)
disp2d.paint(img)
i += 1
"""
if i == 10:
with open('map.json', 'w') as f:
f.write(mapp.serialize())
exit(0)
"""