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kitti_object.py
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kitti_object.py
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""" Helper class and functions for loading KITTI objects
Author: Charles R. Qi
Date: September 2017
"""
from __future__ import print_function
import os
import sys
import numpy as np
import cv2
BASE_DIR = os.path.dirname(os.path.abspath(__file__))
ROOT_DIR = os.path.dirname(BASE_DIR)
sys.path.append(os.path.join(ROOT_DIR, "mayavi"))
import kitti_util as utils
import argparse
try:
raw_input # Python 2
except NameError:
raw_input = input # Python 3
cbox = np.array([[0, 70.4], [-40, 40], [-3, 1]])
class kitti_object(object):
"""Load and parse object data into a usable format."""
def __init__(self, root_dir, split="training", args=None):
"""root_dir contains training and testing folders"""
self.root_dir = root_dir
self.split = split
print(root_dir, split)
self.split_dir = os.path.join(root_dir, split)
if split == "training":
self.num_samples = 7481
elif split == "testing":
self.num_samples = 7518
else:
print("Unknown split: %s" % (split))
exit(-1)
lidar_dir = "velodyne"
depth_dir = "depth"
pred_dir = "pred"
if args is not None:
lidar_dir = args.lidar
depth_dir = args.depthdir
pred_dir = args.preddir
self.image_dir = os.path.join(self.split_dir, "image_2")
self.label_dir = os.path.join(self.split_dir, "label_2")
self.calib_dir = os.path.join(self.split_dir, "calib")
self.depthpc_dir = os.path.join(self.split_dir, "depth_pc")
self.lidar_dir = os.path.join(self.split_dir, lidar_dir)
self.depth_dir = os.path.join(self.split_dir, depth_dir)
self.pred_dir = os.path.join(self.split_dir, pred_dir)
def __len__(self):
return self.num_samples
def get_image(self, idx):
assert idx < self.num_samples
img_filename = os.path.join(self.image_dir, "%06d.png" % (idx))
return utils.load_image(img_filename)
def get_lidar(self, idx, dtype=np.float32, n_vec=4):
assert idx < self.num_samples
lidar_filename = os.path.join(self.lidar_dir, "%06d.bin" % (idx))
print(lidar_filename)
return utils.load_velo_scan(lidar_filename, dtype, n_vec)
def get_calibration(self, idx):
assert idx < self.num_samples
calib_filename = os.path.join(self.calib_dir, "%06d.txt" % (idx))
return utils.Calibration(calib_filename)
def get_label_objects(self, idx):
assert idx < self.num_samples and self.split == "training"
label_filename = os.path.join(self.label_dir, "%06d.txt" % (idx))
return utils.read_label(label_filename)
def get_pred_objects(self, idx):
assert idx < self.num_samples
pred_filename = os.path.join(self.pred_dir, "%06d.txt" % (idx))
is_exist = os.path.exists(pred_filename)
if is_exist:
return utils.read_label(pred_filename)
else:
return None
def get_depth(self, idx):
assert idx < self.num_samples
img_filename = os.path.join(self.depth_dir, "%06d.png" % (idx))
return utils.load_depth(img_filename)
def get_depth_image(self, idx):
assert idx < self.num_samples
img_filename = os.path.join(self.depth_dir, "%06d.png" % (idx))
return utils.load_depth(img_filename)
def get_depth_pc(self, idx):
assert idx < self.num_samples
lidar_filename = os.path.join(self.depthpc_dir, "%06d.bin" % (idx))
is_exist = os.path.exists(lidar_filename)
if is_exist:
return utils.load_velo_scan(lidar_filename), is_exist
else:
return None, is_exist
# print(lidar_filename, is_exist)
# return utils.load_velo_scan(lidar_filename), is_exist
def get_top_down(self, idx):
pass
def isexist_pred_objects(self, idx):
assert idx < self.num_samples and self.split == "training"
pred_filename = os.path.join(self.pred_dir, "%06d.txt" % (idx))
return os.path.exists(pred_filename)
def isexist_depth(self, idx):
assert idx < self.num_samples and self.split == "training"
depth_filename = os.path.join(self.depth_dir, "%06d.txt" % (idx))
return os.path.exists(depth_filename)
class kitti_object_video(object):
""" Load data for KITTI videos """
def __init__(self, img_dir, lidar_dir, calib_dir):
self.calib = utils.Calibration(calib_dir, from_video=True)
self.img_dir = img_dir
self.lidar_dir = lidar_dir
self.img_filenames = sorted(
[os.path.join(img_dir, filename) for filename in os.listdir(img_dir)]
)
self.lidar_filenames = sorted(
[os.path.join(lidar_dir, filename) for filename in os.listdir(lidar_dir)]
)
print(len(self.img_filenames))
print(len(self.lidar_filenames))
# assert(len(self.img_filenames) == len(self.lidar_filenames))
self.num_samples = len(self.img_filenames)
def __len__(self):
return self.num_samples
def get_image(self, idx):
assert idx < self.num_samples
img_filename = self.img_filenames[idx]
return utils.load_image(img_filename)
def get_lidar(self, idx):
assert idx < self.num_samples
lidar_filename = self.lidar_filenames[idx]
return utils.load_velo_scan(lidar_filename)
def get_calibration(self, unused):
return self.calib
def viz_kitti_video():
video_path = os.path.join(ROOT_DIR, "dataset/2011_09_26/")
dataset = kitti_object_video(
os.path.join(video_path, "2011_09_26_drive_0023_sync/image_02/data"),
os.path.join(video_path, "2011_09_26_drive_0023_sync/velodyne_points/data"),
video_path,
)
print(len(dataset))
for _ in range(len(dataset)):
img = dataset.get_image(0)
pc = dataset.get_lidar(0)
cv2.imshow("video", img)
draw_lidar(pc)
raw_input()
pc[:, 0:3] = dataset.get_calibration().project_velo_to_rect(pc[:, 0:3])
draw_lidar(pc)
raw_input()
return
def show_image_with_boxes(img, objects, calib, show3d=True, depth=None):
""" Show image with 2D bounding boxes """
img1 = np.copy(img) # for 2d bbox
img2 = np.copy(img) # for 3d bbox
#img3 = np.copy(img) # for 3d bbox
#TODO: change the color of boxes
for obj in objects:
if obj.type == "DontCare":
continue
if obj.type == "Car":
cv2.rectangle(
img1,
(int(obj.xmin), int(obj.ymin)),
(int(obj.xmax), int(obj.ymax)),
(0, 255, 0),
2,
)
if obj.type == "Pedestrian":
cv2.rectangle(
img1,
(int(obj.xmin), int(obj.ymin)),
(int(obj.xmax), int(obj.ymax)),
(255, 255, 0),
2,
)
if obj.type == "Cyclist":
cv2.rectangle(
img1,
(int(obj.xmin), int(obj.ymin)),
(int(obj.xmax), int(obj.ymax)),
(0, 255, 255),
2,
)
box3d_pts_2d, _ = utils.compute_box_3d(obj, calib.P)
if box3d_pts_2d is None:
print("something wrong in the 3D box.")
continue
if obj.type == "Car":
img2 = utils.draw_projected_box3d(img2, box3d_pts_2d, color=(0, 255, 0))
elif obj.type == "Pedestrian":
img2 = utils.draw_projected_box3d(img2, box3d_pts_2d, color=(255, 255, 0))
elif obj.type == "Cyclist":
img2 = utils.draw_projected_box3d(img2, box3d_pts_2d, color=(0, 255, 255))
# project
# box3d_pts_3d_velo = calib.project_rect_to_velo(box3d_pts_3d)
# box3d_pts_32d = utils.box3d_to_rgb_box00(box3d_pts_3d_velo)
# box3d_pts_32d = calib.project_velo_to_image(box3d_pts_3d_velo)
# img3 = utils.draw_projected_box3d(img3, box3d_pts_32d)
# print("img1:", img1.shape)
cv2.imshow("2dbox", img1)
# print("img3:",img3.shape)
# Image.fromarray(img3).show()
show3d = True
if show3d:
# print("img2:",img2.shape)
cv2.imshow("3dbox", img2)
if depth is not None:
cv2.imshow("depth", depth)
return img1, img2
def show_image_with_boxes_3type(img, objects, calib, objects2d, name, objects_pred):
""" Show image with 2D bounding boxes """
img1 = np.copy(img) # for 2d bbox
type_list = ["Pedestrian", "Car", "Cyclist"]
# draw Label
color = (0, 255, 0)
for obj in objects:
if obj.type not in type_list:
continue
cv2.rectangle(
img1,
(int(obj.xmin), int(obj.ymin)),
(int(obj.xmax), int(obj.ymax)),
color,
3,
)
startx = 5
font = cv2.FONT_HERSHEY_SIMPLEX
text_lables = [obj.type for obj in objects if obj.type in type_list]
text_lables.insert(0, "Label:")
for n in range(len(text_lables)):
text_pos = (startx, 25 * (n + 1))
cv2.putText(img1, text_lables[n], text_pos, font, 0.5, color, 0, cv2.LINE_AA)
# draw 2D Pred
color = (0, 0, 255)
for obj in objects2d:
cv2.rectangle(
img1,
(int(obj.box2d[0]), int(obj.box2d[1])),
(int(obj.box2d[2]), int(obj.box2d[3])),
color,
2,
)
startx = 85
font = cv2.FONT_HERSHEY_SIMPLEX
text_lables = [type_list[obj.typeid - 1] for obj in objects2d]
text_lables.insert(0, "2D Pred:")
for n in range(len(text_lables)):
text_pos = (startx, 25 * (n + 1))
cv2.putText(img1, text_lables[n], text_pos, font, 0.5, color, 0, cv2.LINE_AA)
# draw 3D Pred
if objects_pred is not None:
color = (255, 0, 0)
for obj in objects_pred:
if obj.type not in type_list:
continue
cv2.rectangle(
img1,
(int(obj.xmin), int(obj.ymin)),
(int(obj.xmax), int(obj.ymax)),
color,
1,
)
startx = 165
font = cv2.FONT_HERSHEY_SIMPLEX
text_lables = [obj.type for obj in objects_pred if obj.type in type_list]
text_lables.insert(0, "3D Pred:")
for n in range(len(text_lables)):
text_pos = (startx, 25 * (n + 1))
cv2.putText(
img1, text_lables[n], text_pos, font, 0.5, color, 0, cv2.LINE_AA
)
cv2.imshow("with_bbox", img1)
cv2.imwrite("imgs/" + str(name) + ".png", img1)
def get_lidar_in_image_fov(
pc_velo, calib, xmin, ymin, xmax, ymax, return_more=False, clip_distance=2.0
):
""" Filter lidar points, keep those in image FOV """
pts_2d = calib.project_velo_to_image(pc_velo)
fov_inds = (
(pts_2d[:, 0] < xmax)
& (pts_2d[:, 0] >= xmin)
& (pts_2d[:, 1] < ymax)
& (pts_2d[:, 1] >= ymin)
)
fov_inds = fov_inds & (pc_velo[:, 0] > clip_distance)
imgfov_pc_velo = pc_velo[fov_inds, :]
if return_more:
return imgfov_pc_velo, pts_2d, fov_inds
else:
return imgfov_pc_velo
def get_lidar_index_in_image_fov(
pc_velo, calib, xmin, ymin, xmax, ymax, return_more=False, clip_distance=2.0
):
""" Filter lidar points, keep those in image FOV """
pts_2d = calib.project_velo_to_image(pc_velo)
fov_inds = (
(pts_2d[:, 0] < xmax)
& (pts_2d[:, 0] >= xmin)
& (pts_2d[:, 1] < ymax)
& (pts_2d[:, 1] >= ymin)
)
fov_inds = fov_inds & (pc_velo[:, 0] > clip_distance)
return fov_inds
def depth_region_pt3d(depth, obj):
b = obj.box2d
# depth_region = depth[b[0]:b[2],b[2]:b[3],0]
pt3d = []
# import pdb; pdb.set_trace()
for i in range(int(b[0]), int(b[2])):
for j in range(int(b[1]), int(b[3])):
pt3d.append([j, i, depth[j, i]])
return np.array(pt3d)
def get_depth_pt3d(depth):
pt3d = []
for i in range(depth.shape[0]):
for j in range(depth.shape[1]):
pt3d.append([i, j, depth[i, j]])
return np.array(pt3d)
def show_lidar_with_depth(
pc_velo,
objects,
calib,
fig,
img_fov=False,
img_width=None,
img_height=None,
objects_pred=None,
depth=None,
cam_img=None,
constraint_box=False,
pc_label=False,
save=False,
):
""" Show all LiDAR points.
Draw 3d box in LiDAR point cloud (in velo coord system) """
if "mlab" not in sys.modules:
import mayavi.mlab as mlab
from viz_util import draw_lidar_simple, draw_lidar, draw_gt_boxes3d
print(("All point num: ", pc_velo.shape[0]))
if img_fov:
pc_velo_index = get_lidar_index_in_image_fov(
pc_velo[:, :3], calib, 0, 0, img_width, img_height
)
pc_velo = pc_velo[pc_velo_index, :]
print(("FOV point num: ", pc_velo.shape))
print("pc_velo", pc_velo.shape)
draw_lidar(pc_velo, fig=fig, pc_label=pc_label)
# Draw depth
if depth is not None:
depth_pc_velo = calib.project_depth_to_velo(depth, constraint_box)
indensity = np.ones((depth_pc_velo.shape[0], 1)) * 0.5
depth_pc_velo = np.hstack((depth_pc_velo, indensity))
print("depth_pc_velo:", depth_pc_velo.shape)
print("depth_pc_velo:", type(depth_pc_velo))
print(depth_pc_velo[:5])
draw_lidar(depth_pc_velo, fig=fig, pts_color=(1, 1, 1))
if save:
data_idx = 0
vely_dir = "data/object/training/depth_pc"
save_filename = os.path.join(vely_dir, "%06d.bin" % (data_idx))
print(save_filename)
# np.save(save_filename+".npy", np.array(depth_pc_velo))
depth_pc_velo = depth_pc_velo.astype(np.float32)
depth_pc_velo.tofile(save_filename)
# color = (0, 1, 0)
for obj in objects:
if obj.type == "DontCare":
continue
# Draw 3d bounding box
_, box3d_pts_3d = utils.compute_box_3d(obj, calib.P)
box3d_pts_3d_velo = calib.project_rect_to_velo(box3d_pts_3d)
print("box3d_pts_3d_velo:")
print(box3d_pts_3d_velo)
#TODO: change the color of boxes
if obj.type == "Car":
draw_gt_boxes3d([box3d_pts_3d_velo], fig=fig, color=(0,1,0), label=obj.type)
elif obj.type == "Pedestrian":
draw_gt_boxes3d([box3d_pts_3d_velo], fig=fig, color=(0,1,1), label=obj.type)
elif obj.type == "Cyclist":
draw_gt_boxes3d([box3d_pts_3d_velo], fig=fig, color=(1,1,0), label=obj.type)
if objects_pred is not None:
color = (1, 0, 0)
for obj in objects_pred:
if obj.type == "DontCare":
continue
# Draw 3d bounding box
_, box3d_pts_3d = utils.compute_box_3d(obj, calib.P)
box3d_pts_3d_velo = calib.project_rect_to_velo(box3d_pts_3d)
print("box3d_pts_3d_velo:")
print(box3d_pts_3d_velo)
draw_gt_boxes3d([box3d_pts_3d_velo], fig=fig, color=color)
# Draw heading arrow
_, ori3d_pts_3d = utils.compute_orientation_3d(obj, calib.P)
ori3d_pts_3d_velo = calib.project_rect_to_velo(ori3d_pts_3d)
x1, y1, z1 = ori3d_pts_3d_velo[0, :]
x2, y2, z2 = ori3d_pts_3d_velo[1, :]
mlab.plot3d(
[x1, x2],
[y1, y2],
[z1, z2],
color=color,
tube_radius=None,
line_width=1,
figure=fig,
)
mlab.show(1)
def save_depth0(
data_idx,
pc_velo,
calib,
img_fov,
img_width,
img_height,
depth,
constraint_box=False,
):
if img_fov:
pc_velo_index = get_lidar_index_in_image_fov(
pc_velo[:, :3], calib, 0, 0, img_width, img_height
)
pc_velo = pc_velo[pc_velo_index, :]
type = np.zeros((pc_velo.shape[0], 1))
pc_velo = np.hstack((pc_velo, type))
print(("FOV point num: ", pc_velo.shape))
# Draw depth
if depth is not None:
depth_pc_velo = calib.project_depth_to_velo(depth, constraint_box)
indensity = np.ones((depth_pc_velo.shape[0], 1)) * 0.5
depth_pc_velo = np.hstack((depth_pc_velo, indensity))
type = np.ones((depth_pc_velo.shape[0], 1))
depth_pc_velo = np.hstack((depth_pc_velo, type))
print("depth_pc_velo:", depth_pc_velo.shape)
depth_pc = np.concatenate((pc_velo, depth_pc_velo), axis=0)
print("depth_pc:", depth_pc.shape)
vely_dir = "data/object/training/depth_pc"
save_filename = os.path.join(vely_dir, "%06d.bin" % (data_idx))
depth_pc = depth_pc.astype(np.float32)
depth_pc.tofile(save_filename)
def save_depth(
data_idx,
pc_velo,
calib,
img_fov,
img_width,
img_height,
depth,
constraint_box=False,
):
if depth is not None:
depth_pc_velo = calib.project_depth_to_velo(depth, constraint_box)
indensity = np.ones((depth_pc_velo.shape[0], 1)) * 0.5
depth_pc = np.hstack((depth_pc_velo, indensity))
print("depth_pc:", depth_pc.shape)
vely_dir = "data/object/training/depth_pc"
save_filename = os.path.join(vely_dir, "%06d.bin" % (data_idx))
depth_pc = depth_pc.astype(np.float32)
depth_pc.tofile(save_filename)
def show_lidar_with_boxes(
pc_velo,
objects,
calib,
img_fov=False,
img_width=None,
img_height=None,
objects_pred=None,
depth=None,
cam_img=None,
):
""" Show all LiDAR points.
Draw 3d box in LiDAR point cloud (in velo coord system) """
if "mlab" not in sys.modules:
import mayavi.mlab as mlab
from viz_util import draw_lidar_simple, draw_lidar, draw_gt_boxes3d
print(("All point num: ", pc_velo.shape[0]))
fig = mlab.figure(
figure=None, bgcolor=(0, 0, 0), fgcolor=None, engine=None, size=(1000, 500)
)
if img_fov:
pc_velo = get_lidar_in_image_fov(
pc_velo[:, 0:3], calib, 0, 0, img_width, img_height
)
print(("FOV point num: ", pc_velo.shape[0]))
print("pc_velo", pc_velo.shape)
draw_lidar(pc_velo, fig=fig)
# pc_velo=pc_velo[:,0:3]
color = (0, 1, 0)
for obj in objects:
if obj.type == "DontCare":
continue
# Draw 3d bounding box
_, box3d_pts_3d = utils.compute_box_3d(obj, calib.P)
box3d_pts_3d_velo = calib.project_rect_to_velo(box3d_pts_3d)
print("box3d_pts_3d_velo:")
print(box3d_pts_3d_velo)
draw_gt_boxes3d([box3d_pts_3d_velo], fig=fig, color=color)
# Draw depth
if depth is not None:
# import pdb; pdb.set_trace()
depth_pt3d = depth_region_pt3d(depth, obj)
depth_UVDepth = np.zeros_like(depth_pt3d)
depth_UVDepth[:, 0] = depth_pt3d[:, 1]
depth_UVDepth[:, 1] = depth_pt3d[:, 0]
depth_UVDepth[:, 2] = depth_pt3d[:, 2]
print("depth_pt3d:", depth_UVDepth)
dep_pc_velo = calib.project_image_to_velo(depth_UVDepth)
print("dep_pc_velo:", dep_pc_velo)
draw_lidar(dep_pc_velo, fig=fig, pts_color=(1, 1, 1))
# Draw heading arrow
_, ori3d_pts_3d = utils.compute_orientation_3d(obj, calib.P)
ori3d_pts_3d_velo = calib.project_rect_to_velo(ori3d_pts_3d)
x1, y1, z1 = ori3d_pts_3d_velo[0, :]
x2, y2, z2 = ori3d_pts_3d_velo[1, :]
mlab.plot3d(
[x1, x2],
[y1, y2],
[z1, z2],
color=color,
tube_radius=None,
line_width=1,
figure=fig,
)
if objects_pred is not None:
color = (1, 0, 0)
for obj in objects_pred:
if obj.type == "DontCare":
continue
# Draw 3d bounding box
_, box3d_pts_3d = utils.compute_box_3d(obj, calib.P)
box3d_pts_3d_velo = calib.project_rect_to_velo(box3d_pts_3d)
print("box3d_pts_3d_velo:")
print(box3d_pts_3d_velo)
draw_gt_boxes3d([box3d_pts_3d_velo], fig=fig, color=color)
# Draw heading arrow
_, ori3d_pts_3d = utils.compute_orientation_3d(obj, calib.P)
ori3d_pts_3d_velo = calib.project_rect_to_velo(ori3d_pts_3d)
x1, y1, z1 = ori3d_pts_3d_velo[0, :]
x2, y2, z2 = ori3d_pts_3d_velo[1, :]
mlab.plot3d(
[x1, x2],
[y1, y2],
[z1, z2],
color=color,
tube_radius=None,
line_width=1,
figure=fig,
)
mlab.show(1)
def box_min_max(box3d):
box_min = np.min(box3d, axis=0)
box_max = np.max(box3d, axis=0)
return box_min, box_max
def get_velo_whl(box3d, pc):
bmin, bmax = box_min_max(box3d)
ind = np.where(
(pc[:, 0] >= bmin[0])
& (pc[:, 0] <= bmax[0])
& (pc[:, 1] >= bmin[1])
& (pc[:, 1] <= bmax[1])
& (pc[:, 2] >= bmin[2])
& (pc[:, 2] <= bmax[2])
)[0]
# print(pc[ind,:])
if len(ind) > 0:
vmin, vmax = box_min_max(pc[ind, :])
return vmax - vmin
else:
return 0, 0, 0, 0
def stat_lidar_with_boxes(pc_velo, objects, calib):
""" Show all LiDAR points.
Draw 3d box in LiDAR point cloud (in velo coord system) """
# print(('All point num: ', pc_velo.shape[0]))
# draw_lidar(pc_velo, fig=fig)
# color=(0,1,0)
for obj in objects:
if obj.type == "DontCare":
continue
_, box3d_pts_3d = utils.compute_box_3d(obj, calib.P)
box3d_pts_3d_velo = calib.project_rect_to_velo(box3d_pts_3d)
v_l, v_w, v_h, _ = get_velo_whl(box3d_pts_3d_velo, pc_velo)
print("%.4f %.4f %.4f %s" % (v_w, v_h, v_l, obj.type))
def show_lidar_on_image(pc_velo, img, calib, img_width, img_height):
""" Project LiDAR points to image """
img = np.copy(img)
imgfov_pc_velo, pts_2d, fov_inds = get_lidar_in_image_fov(
pc_velo, calib, 0, 0, img_width, img_height, True
)
imgfov_pts_2d = pts_2d[fov_inds, :]
imgfov_pc_rect = calib.project_velo_to_rect(imgfov_pc_velo)
import matplotlib.pyplot as plt
cmap = plt.cm.get_cmap("hsv", 256)
cmap = np.array([cmap(i) for i in range(256)])[:, :3] * 255
for i in range(imgfov_pts_2d.shape[0]):
depth = imgfov_pc_rect[i, 2]
color = cmap[int(640.0 / depth), :]
cv2.circle(
img,
(int(np.round(imgfov_pts_2d[i, 0])), int(np.round(imgfov_pts_2d[i, 1]))),
2,
color=tuple(color),
thickness=-1,
)
cv2.imshow("projection", img)
return img
def show_lidar_topview_with_boxes(pc_velo, objects, calib, objects_pred=None):
""" top_view image"""
# print('pc_velo shape: ',pc_velo.shape)
top_view = utils.lidar_to_top(pc_velo)
top_image = utils.draw_top_image(top_view)
print("top_image:", top_image.shape)
# gt
def bbox3d(obj):
_, box3d_pts_3d = utils.compute_box_3d(obj, calib.P)
box3d_pts_3d_velo = calib.project_rect_to_velo(box3d_pts_3d)
return box3d_pts_3d_velo
boxes3d = [bbox3d(obj) for obj in objects if obj.type != "DontCare"]
gt = np.array(boxes3d)
# print("box2d BV:",boxes3d)
lines = [obj.type for obj in objects if obj.type != "DontCare"]
top_image = utils.draw_box3d_on_top(
top_image, gt, text_lables=lines, scores=None, thickness=1, is_gt=True
)
# pred
if objects_pred is not None:
boxes3d = [bbox3d(obj) for obj in objects_pred if obj.type != "DontCare"]
gt = np.array(boxes3d)
lines = [obj.type for obj in objects_pred if obj.type != "DontCare"]
top_image = utils.draw_box3d_on_top(
top_image, gt, text_lables=lines, scores=None, thickness=1, is_gt=False
)
cv2.imshow("top_image", top_image)
return top_image
def dataset_viz(root_dir, args):
dataset = kitti_object(root_dir, split=args.split, args=args)
## load 2d detection results
#objects2ds = read_det_file("box2d.list")
if args.show_lidar_with_depth:
import mayavi.mlab as mlab
fig = mlab.figure(
figure=None, bgcolor=(0, 0, 0), fgcolor=None, engine=None, size=(1000, 500)
)
for data_idx in range(len(dataset)):
if args.ind > 0:
data_idx = args.ind
# Load data from dataset
if args.split == "training":
objects = dataset.get_label_objects(data_idx)
else:
objects = []
#objects2d = objects2ds[data_idx]
objects_pred = None
if args.pred:
# if not dataset.isexist_pred_objects(data_idx):
# continue
objects_pred = dataset.get_pred_objects(data_idx)
if objects_pred == None:
continue
if objects_pred == None:
print("no pred file")
# objects_pred[0].print_object()
n_vec = 4
if args.pc_label:
n_vec = 5
dtype = np.float32
if args.dtype64:
dtype = np.float64
pc_velo = dataset.get_lidar(data_idx, dtype, n_vec)[:, 0:n_vec]
calib = dataset.get_calibration(data_idx)
img = dataset.get_image(data_idx)
img_height, img_width, _ = img.shape
print(data_idx, "image shape: ", img.shape)
print(data_idx, "velo shape: ", pc_velo.shape)
if args.depth:
depth, _ = dataset.get_depth(data_idx)
print(data_idx, "depth shape: ", depth.shape)
else:
depth = None
# depth = cv2.cvtColor(depth, cv2.COLOR_BGR2RGB)
# depth_height, depth_width, depth_channel = img.shape
# print(('Image shape: ', img.shape))
if args.stat:
stat_lidar_with_boxes(pc_velo, objects, calib)
continue
print("======== Objects in Ground Truth ========")
n_obj = 0
for obj in objects:
if obj.type != "DontCare":
print("=== {} object ===".format(n_obj + 1))
obj.print_object()
n_obj += 1
# Draw 3d box in LiDAR point cloud
if args.show_lidar_topview_with_boxes:
# Draw lidar top view
show_lidar_topview_with_boxes(pc_velo, objects, calib, objects_pred)
# show_image_with_boxes_3type(img, objects, calib, objects2d, data_idx, objects_pred)
if args.show_image_with_boxes:
# Draw 2d and 3d boxes on image
show_image_with_boxes(img, objects, calib, True, depth)
if args.show_lidar_with_depth:
# Draw 3d box in LiDAR point cloud
show_lidar_with_depth(
pc_velo,
objects,
calib,
fig,
args.img_fov,
img_width,
img_height,
objects_pred,
depth,
img,
constraint_box=args.const_box,
save=args.save_depth,
pc_label=args.pc_label,
)
# show_lidar_with_boxes(pc_velo, objects, calib, True, img_width, img_height, \
# objects_pred, depth, img)
if args.show_lidar_on_image:
# Show LiDAR points on image.
show_lidar_on_image(pc_velo[:, 0:3], img, calib, img_width, img_height)
input_str = raw_input()
mlab.clf()
if input_str == "killall":
break
def depth_to_lidar_format(root_dir, args):
dataset = kitti_object(root_dir, split=args.split, args=args)
for data_idx in range(len(dataset)):
# Load data from dataset
pc_velo = dataset.get_lidar(data_idx)[:, 0:4]
calib = dataset.get_calibration(data_idx)
depth, _ = dataset.get_depth(data_idx)
img = dataset.get_image(data_idx)
img_height, img_width, _ = img.shape
print(data_idx, "image shape: ", img.shape)
print(data_idx, "velo shape: ", pc_velo.shape)
print(data_idx, "depth shape: ", depth.shape)
# depth = cv2.cvtColor(depth, cv2.COLOR_BGR2RGB)
# depth_height, depth_width, depth_channel = img.shape
# print(('Image shape: ', img.shape))
save_depth(
data_idx,
pc_velo,
calib,
args.img_fov,
img_width,
img_height,
depth,
constraint_box=args.const_box,
)
#input_str = raw_input()
def read_det_file(det_filename):
""" Parse lines in 2D detection output files """
#det_id2str = {1: "Pedestrian", 2: "Car", 3: "Cyclist"}
objects = {}
with open(det_filename, "r") as f:
for line in f.readlines():
obj = utils.Object2d(line.rstrip())
if obj.img_name not in objects.keys():
objects[obj.img_name] = []
objects[obj.img_name].append(obj)
# objects = [utils.Object2d(line.rstrip()) for line in f.readlines()]
return objects
if __name__ == "__main__":
import mayavi.mlab as mlab
from viz_util import draw_lidar_simple, draw_lidar, draw_gt_boxes3d
parser = argparse.ArgumentParser(description="KIITI Object Visualization")
parser.add_argument(
"-d",
"--dir",
type=str,
default="data/object",
metavar="N",
help="input (default: data/object)",
)
parser.add_argument(
"-i",
"--ind",
type=int,
default=0,
metavar="N",
help="input (default: data/object)",
)
parser.add_argument(
"-p", "--pred", action="store_true", help="show predict results"
)
parser.add_argument(
"-s",
"--stat",
action="store_true",
help=" stat the w/h/l of point cloud in gt bbox",
)
parser.add_argument(
"--split",
type=str,
default="training",
help="use training split or testing split (default: training)",
)
parser.add_argument(
"-l",
"--lidar",
type=str,
default="velodyne",
metavar="N",
help="velodyne dir (default: velodyne)",
)
parser.add_argument(
"-e",
"--depthdir",
type=str,
default="depth",
metavar="N",
help="depth dir (default: depth)",
)
parser.add_argument(
"-r",
"--preddir",
type=str,
default="pred",
metavar="N",
help="predicted boxes (default: pred)",
)
parser.add_argument("--gen_depth", action="store_true", help="generate depth")
parser.add_argument("--vis", action="store_true", help="show images")
parser.add_argument("--depth", action="store_true", help="load depth")
parser.add_argument("--img_fov", action="store_true", help="front view mapping")
parser.add_argument("--const_box", action="store_true", help="constraint box")
parser.add_argument(
"--save_depth", action="store_true", help="save depth into file"
)
parser.add_argument(
"--pc_label", action="store_true", help="5-verctor lidar, pc with label"
)
parser.add_argument(
"--dtype64", action="store_true", help="for float64 datatype, default float64"
)
parser.add_argument(
"--show_lidar_on_image", action="store_true", help="project lidar on image"
)
parser.add_argument(
"--show_lidar_with_depth",
action="store_true",
help="--show_lidar, depth is supported",
)
parser.add_argument(
"--show_image_with_boxes", action="store_true", help="show lidar"
)
parser.add_argument(
"--show_lidar_topview_with_boxes",
action="store_true",
help="show lidar topview",
)
args = parser.parse_args()
if args.pred:
assert os.path.exists(args.dir + "/" + args.split + "/pred")
if args.vis:
dataset_viz(args.dir, args)
if args.gen_depth:
depth_to_lidar_format(args.dir, args)