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DatasetLidarCamera.py
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DatasetLidarCamera.py
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# -------------------------------------------------------------------
# Copyright (C) 2020 Università degli studi di Milano-Bicocca, iralab
# Author: Daniele Cattaneo ([email protected])
# Released under Creative Commons
# Attribution-NonCommercial-ShareAlike 4.0 International License.
# http://creativecommons.org/licenses/by-nc-sa/4.0/
# -------------------------------------------------------------------
# Modified Author: Xudong Lv
# based on github.com/cattaneod/CMRNet/blob/master/DatasetVisibilityKitti.py
import csv
import os
from math import radians
import cv2
import h5py
import mathutils
import numpy as np
import pandas as pd
import torch
import torchvision.transforms.functional as TTF
from PIL import Image
from torch.utils.data import Dataset
from torchvision import transforms
from utils import invert_pose, rotate_forward, quaternion_from_matrix, read_calib_file
from pykitti import odometry
import pykitti
class DatasetLidarCameraKittiOdometry(Dataset):
def __init__(self, dataset_dir, transform=None, augmentation=False, use_reflectance=False,
max_t=1.5, max_r=20., split='val', device='cpu', val_sequence='00', suf='.png'):
super(DatasetLidarCameraKittiOdometry, self).__init__()
self.use_reflectance = use_reflectance
self.maps_folder = ''
self.device = device
self.max_r = max_r
self.max_t = max_t
self.augmentation = augmentation
self.root_dir = dataset_dir
self.transform = transform
self.split = split
self.GTs_R = {}
self.GTs_T = {}
self.GTs_T_cam02_velo = {}
self.K = {}
self.suf = suf
self.all_files = []
self.sequence_list = ['00', '01', '02', '03', '04', '05', '06', '07', '08', '09', '10',
'11', '12', '13', '14', '15', '16', '17', '18', '19', '20', '21']
# self.model = CameraModel()
# self.model.focal_length = [7.18856e+02, 7.18856e+02]
# self.model.principal_point = [6.071928e+02, 1.852157e+02]
# for seq in ['00', '03', '05', '06', '07', '08', '09']:
for seq in self.sequence_list:
odom = odometry(self.root_dir, seq)
calib = odom.calib
T_cam02_velo_np = calib.T_cam2_velo #gt pose from cam02 to velo_lidar (T_cam02_velo: 4x4)
self.K[seq] = calib.K_cam2 # 3x3
# T_cam02_velo = torch.from_numpy(T_cam02_velo_np)
# GT_R = quaternion_from_matrix(T_cam02_velo[:3, :3])
# GT_T = T_cam02_velo[3:, :3]
# self.GTs_R[seq] = GT_R # GT_R = np.array([row['qw'], row['qx'], row['qy'], row['qz']])
# self.GTs_T[seq] = GT_T # GT_T = np.array([row['x'], row['y'], row['z']])
self.GTs_T_cam02_velo[seq] = T_cam02_velo_np #gt pose from cam02 to velo_lidar (T_cam02_velo: 4x4)
image_list = os.listdir(os.path.join(dataset_dir, 'sequences', seq, 'image_2'))
image_list.sort()
for image_name in image_list:
if not os.path.exists(os.path.join(dataset_dir, 'sequences', seq, 'velodyne',
str(image_name.split('.')[0])+'.bin')):
continue
if not os.path.exists(os.path.join(dataset_dir, 'sequences', seq, 'image_2',
str(image_name.split('.')[0])+suf)):
continue
if seq == val_sequence:
if split.startswith('val') or split == 'test':
self.all_files.append(os.path.join(seq, image_name.split('.')[0]))
elif (not seq == val_sequence) and split == 'train':
self.all_files.append(os.path.join(seq, image_name.split('.')[0]))
self.val_RT = []
if split == 'val' or split == 'test':
# val_RT_file = os.path.join(dataset_dir, 'sequences',
# f'val_RT_seq{val_sequence}_{max_r:.2f}_{max_t:.2f}.csv')
val_RT_file = os.path.join(dataset_dir, 'sequences',
f'val_RT_left_seq{val_sequence}_{max_r:.2f}_{max_t:.2f}.csv')
if os.path.exists(val_RT_file):
print(f'VAL SET: Using this file: {val_RT_file}')
df_test_RT = pd.read_csv(val_RT_file, sep=',')
for index, row in df_test_RT.iterrows():
self.val_RT.append(list(row))
else:
print(f'VAL SET - Not found: {val_RT_file}')
print("Generating a new one")
val_RT_file = open(val_RT_file, 'w')
val_RT_file = csv.writer(val_RT_file, delimiter=',')
val_RT_file.writerow(['id', 'tx', 'ty', 'tz', 'rx', 'ry', 'rz'])
for i in range(len(self.all_files)):
rotz = np.random.uniform(-max_r, max_r) * (3.141592 / 180.0)
roty = np.random.uniform(-max_r, max_r) * (3.141592 / 180.0)
rotx = np.random.uniform(-max_r, max_r) * (3.141592 / 180.0)
transl_x = np.random.uniform(-max_t, max_t)
transl_y = np.random.uniform(-max_t, max_t)
transl_z = np.random.uniform(-max_t, max_t)
# transl_z = np.random.uniform(-max_t, min(max_t, 1.))
val_RT_file.writerow([i, transl_x, transl_y, transl_z,
rotx, roty, rotz])
self.val_RT.append([float(i), float(transl_x), float(transl_y), float(transl_z),
float(rotx), float(roty), float(rotz)])
assert len(self.val_RT) == len(self.all_files), "Something wrong with test RTs"
def get_ground_truth_poses(self, sequence, frame):
return self.GTs_T[sequence][frame], self.GTs_R[sequence][frame]
def custom_transform(self, rgb, img_rotation=0., flip=False):
to_tensor = transforms.ToTensor()
normalization = transforms.Normalize(mean=[0.485, 0.456, 0.406],
std=[0.229, 0.224, 0.225])
#rgb = crop(rgb)
if self.split == 'train':
color_transform = transforms.ColorJitter(0.1, 0.1, 0.1)
rgb = color_transform(rgb)
if flip:
rgb = TTF.hflip(rgb)
rgb = TTF.rotate(rgb, img_rotation)
#io.imshow(np.array(rgb))
#io.show()
rgb = to_tensor(rgb)
rgb = normalization(rgb)
return rgb
def __len__(self):
return len(self.all_files)
def __getitem__(self, idx):
item = self.all_files[idx]
seq = str(item.split('/')[0])
rgb_name = str(item.split('/')[1])
img_path = os.path.join(self.root_dir, 'sequences', seq, 'image_2', rgb_name+self.suf)
lidar_path = os.path.join(self.root_dir, 'sequences', seq, 'velodyne', rgb_name+'.bin')
lidar_scan = np.fromfile(lidar_path, dtype=np.float32)
pc = lidar_scan.reshape((-1, 4))
valid_indices = pc[:, 0] < -3.
valid_indices = valid_indices | (pc[:, 0] > 3.)
valid_indices = valid_indices | (pc[:, 1] < -3.)
valid_indices = valid_indices | (pc[:, 1] > 3.)
pc = pc[valid_indices].copy()
pc_org = torch.from_numpy(pc.astype(np.float32))
# if self.use_reflectance:
# reflectance = pc[:, 3].copy()
# reflectance = torch.from_numpy(reflectance).float()
RT = self.GTs_T_cam02_velo[seq].astype(np.float32)
if pc_org.shape[1] == 4 or pc_org.shape[1] == 3:
pc_org = pc_org.t()
if pc_org.shape[0] == 3:
homogeneous = torch.ones(pc_org.shape[1]).unsqueeze(0)
pc_org = torch.cat((pc_org, homogeneous), 0)
elif pc_org.shape[0] == 4:
if not torch.all(pc_org[3, :] == 1.):
pc_org[3, :] = 1.
else:
raise TypeError("Wrong PointCloud shape")
pc_rot = np.matmul(RT, pc_org.numpy())
pc_rot = pc_rot.astype(np.float32).copy()
pc_in = torch.from_numpy(pc_rot)
# pc_rot = np.matmul(RT, pc.T)
# pc_rot = pc_rot.astype(np.float).T.copy()
# pc_in = torch.from_numpy(pc_rot.astype(np.float32))#.float()
# if pc_in.shape[1] == 4 or pc_in.shape[1] == 3:
# pc_in = pc_in.t()
# if pc_in.shape[0] == 3:
# homogeneous = torch.ones(pc_in.shape[1]).unsqueeze(0)
# pc_in = torch.cat((pc_in, homogeneous), 0)
# elif pc_in.shape[0] == 4:
# if not torch.all(pc_in[3,:] == 1.):
# pc_in[3,:] = 1.
# else:
# raise TypeError("Wrong PointCloud shape")
h_mirror = False
# if np.random.rand() > 0.5 and self.split == 'train':
# h_mirror = True
# pc_in[1, :] *= -1
img = Image.open(img_path)
# img = cv2.imread(img_path)
img_rotation = 0.
# if self.split == 'train':
# img_rotation = np.random.uniform(-5, 5)
try:
img = self.custom_transform(img, img_rotation, h_mirror)
except OSError:
new_idx = np.random.randint(0, self.__len__())
return self.__getitem__(new_idx)
# Rotate PointCloud for img_rotation
if self.split == 'train':
R = mathutils.Euler((radians(img_rotation), 0, 0), 'XYZ')
T = mathutils.Vector((0., 0., 0.))
pc_in = rotate_forward(pc_in, R, T)
if self.split == 'train':
max_angle = self.max_r
rotz = np.random.uniform(-max_angle, max_angle) * (3.141592 / 180.0)
roty = np.random.uniform(-max_angle, max_angle) * (3.141592 / 180.0)
rotx = np.random.uniform(-max_angle, max_angle) * (3.141592 / 180.0)
transl_x = np.random.uniform(-self.max_t, self.max_t)
transl_y = np.random.uniform(-self.max_t, self.max_t)
transl_z = np.random.uniform(-self.max_t, self.max_t)
# transl_z = np.random.uniform(-self.max_t, min(self.max_t, 1.))
else:
initial_RT = self.val_RT[idx]
rotz = initial_RT[6]
roty = initial_RT[5]
rotx = initial_RT[4]
transl_x = initial_RT[1]
transl_y = initial_RT[2]
transl_z = initial_RT[3]
# 随机设置一定范围内的标定参数扰动值
# train的时候每次都随机生成,每个epoch使用不同的参数
# test则在初始化的时候提前设置好,每个epoch都使用相同的参数
R = mathutils.Euler((rotx, roty, rotz), 'XYZ')
T = mathutils.Vector((transl_x, transl_y, transl_z))
R, T = invert_pose(R, T)
R, T = torch.tensor(R), torch.tensor(T)
#io.imshow(depth_img.numpy(), cmap='jet')
#io.show()
calib = self.K[seq]
if h_mirror:
calib[2] = (img.shape[2] / 2)*2 - calib[2]
if self.split == 'test':
sample = {'rgb': img, 'point_cloud': pc_in, 'calib': calib,
'tr_error': T, 'rot_error': R, 'seq': int(seq), 'img_path': img_path,
'rgb_name': rgb_name + '.png', 'item': item, 'extrin': RT,
'initial_RT': initial_RT}
else:
sample = {'rgb': img, 'point_cloud': pc_in, 'calib': calib,
'tr_error': T, 'rot_error': R, 'seq': int(seq),
'rgb_name': rgb_name, 'item': item, 'extrin': RT}
return sample
class DatasetLidarCameraKittiRaw(Dataset):
def __init__(self, dataset_dir, transform=None, augmentation=False, use_reflectance=False,
max_t=1.5, max_r=15.0, split='val', device='cpu', val_sequence='2011_09_26_drive_0117_sync'):
super(DatasetLidarCameraKittiRaw, self).__init__()
self.use_reflectance = use_reflectance
self.maps_folder = ''
self.device = device
self.max_r = max_r
self.max_t = max_t
self.augmentation = augmentation
self.root_dir = dataset_dir
self.transform = transform
self.split = split
self.GTs_R = {}
self.GTs_T = {}
self.GTs_T_cam02_velo = {}
self.max_depth = 80
self.K_list = {}
self.all_files = []
date_list = ['2011_09_26', '2011_09_28', '2011_09_29', '2011_09_30', '2011_10_03']
data_drive_list = ['0001', '0002', '0004', '0016', '0027']
self.calib_date = {}
for i in range(len(date_list)):
date = date_list[i]
data_drive = data_drive_list[i]
data = pykitti.raw(self.root_dir, date, data_drive)
calib = {'K2': data.calib.K_cam2, 'K3': data.calib.K_cam3,
'RT2': data.calib.T_cam2_velo, 'RT3': data.calib.T_cam3_velo}
self.calib_date[date] = calib
# date = val_sequence[:10]
# seq = val_sequence
# image_list = os.listdir(os.path.join(dataset_dir, date, seq, 'image_02/data'))
# image_list.sort()
#
# for image_name in image_list:
# if not os.path.exists(os.path.join(dataset_dir, date, seq, 'velodyne_points/data',
# str(image_name.split('.')[0]) + '.bin')):
# continue
# if not os.path.exists(os.path.join(dataset_dir, date, seq, 'image_02/data',
# str(image_name.split('.')[0]) + '.jpg')): # png
# continue
# self.all_files.append(os.path.join(date, seq, 'image_02/data', image_name.split('.')[0]))
date = val_sequence[:10]
test_list = ['2011_09_26_drive_0005_sync', '2011_09_26_drive_0070_sync', '2011_10_03_drive_0027_sync']
seq_list = os.listdir(os.path.join(self.root_dir, date))
for seq in seq_list:
if not os.path.isdir(os.path.join(dataset_dir, date, seq)):
continue
image_list = os.listdir(os.path.join(dataset_dir, date, seq, 'image_02/data'))
image_list.sort()
for image_name in image_list:
if not os.path.exists(os.path.join(dataset_dir, date, seq, 'velodyne_points/data',
str(image_name.split('.')[0])+'.bin')):
continue
if not os.path.exists(os.path.join(dataset_dir, date, seq, 'image_02/data',
str(image_name.split('.')[0])+'.jpg')): # png
continue
if seq == val_sequence and (not split == 'train'):
self.all_files.append(os.path.join(date, seq, 'image_02/data', image_name.split('.')[0]))
elif (not seq == val_sequence) and split == 'train' and seq not in test_list:
self.all_files.append(os.path.join(date, seq, 'image_02/data', image_name.split('.')[0]))
self.val_RT = []
if split == 'val' or split == 'test':
val_RT_file = os.path.join(dataset_dir,
f'val_RT_seq{val_sequence}_{max_r:.2f}_{max_t:.2f}.csv')
if os.path.exists(val_RT_file):
print(f'VAL SET: Using this file: {val_RT_file}')
df_test_RT = pd.read_csv(val_RT_file, sep=',')
for index, row in df_test_RT.iterrows():
self.val_RT.append(list(row))
else:
print(f'TEST SET - Not found: {val_RT_file}')
print("Generating a new one")
val_RT_file = open(val_RT_file, 'w')
val_RT_file = csv.writer(val_RT_file, delimiter=',')
val_RT_file.writerow(['id', 'tx', 'ty', 'tz', 'rx', 'ry', 'rz'])
for i in range(len(self.all_files)):
rotz = np.random.uniform(-max_r, max_r) * (3.141592 / 180.0)
roty = np.random.uniform(-max_r, max_r) * (3.141592 / 180.0)
rotx = np.random.uniform(-max_r, max_r) * (3.141592 / 180.0)
transl_x = np.random.uniform(-max_t, max_t)
transl_y = np.random.uniform(-max_t, max_t)
transl_z = np.random.uniform(-max_t, max_t)
# transl_z = np.random.uniform(-max_t, min(max_t, 1.))
val_RT_file.writerow([i, transl_x, transl_y, transl_z,
rotx, roty, rotz])
self.val_RT.append([float(i), transl_x, transl_y, transl_z,
rotx, roty, rotz])
assert len(self.val_RT) == len(self.all_files), "Something wrong with test RTs"
def get_ground_truth_poses(self, sequence, frame):
return self.GTs_T[sequence][frame], self.GTs_R[sequence][frame]
def custom_transform(self, rgb, img_rotation=0., flip=False):
to_tensor = transforms.ToTensor()
normalization = transforms.Normalize(mean=[0.485, 0.456, 0.406],
std=[0.229, 0.224, 0.225])
#rgb = crop(rgb)
if self.split == 'train':
color_transform = transforms.ColorJitter(0.1, 0.1, 0.1)
# color_transform = transforms.ColorJitter(brightness=0.3, contrast=0.3, saturation=0.3, hue=0.3 / 3.14)
rgb = color_transform(rgb)
if flip:
rgb = TTF.hflip(rgb)
rgb = TTF.rotate(rgb, img_rotation)
#io.imshow(np.array(rgb))
#io.show()
rgb = to_tensor(rgb)
rgb = normalization(rgb)
return rgb
def __len__(self):
return len(self.all_files)
# self.all_files.append(os.path.join(date, seq, 'image_2/data', image_name.split('.')[0]))
def __getitem__(self, idx):
item = self.all_files[idx]
date = str(item.split('/')[0])
seq = str(item.split('/')[1])
rgb_name = str(item.split('/')[4])
img_path = os.path.join(self.root_dir, date, seq, 'image_02/data', rgb_name+'.jpg') # png
lidar_path = os.path.join(self.root_dir, date, seq, 'velodyne_points/data', rgb_name+'.bin')
lidar_scan = np.fromfile(lidar_path, dtype=np.float32)
pc = lidar_scan.reshape((-1, 4))
valid_indices = pc[:, 0] < -3.
valid_indices = valid_indices | (pc[:, 0] > 3.)
valid_indices = valid_indices | (pc[:, 1] < -3.)
valid_indices = valid_indices | (pc[:, 1] > 3.)
pc = pc[valid_indices].copy()
pc_lidar = pc.copy()
pc_org = torch.from_numpy(pc.astype(np.float32))
if self.use_reflectance:
reflectance = pc[:, 3].copy()
reflectance = torch.from_numpy(reflectance).float()
calib = self.calib_date[date]
RT_cam02 = calib['RT2'].astype(np.float32)
# camera intrinsic parameter
calib_cam02 = calib['K2'] # 3x3
E_RT = RT_cam02
if pc_org.shape[1] == 4 or pc_org.shape[1] == 3:
pc_org = pc_org.t()
if pc_org.shape[0] == 3:
homogeneous = torch.ones(pc_org.shape[1]).unsqueeze(0)
pc_org = torch.cat((pc_org, homogeneous), 0)
elif pc_org.shape[0] == 4:
if not torch.all(pc_org[3, :] == 1.):
pc_org[3, :] = 1.
else:
raise TypeError("Wrong PointCloud shape")
pc_rot = np.matmul(E_RT, pc_org.numpy())
pc_rot = pc_rot.astype(np.float32).copy()
pc_in = torch.from_numpy(pc_rot)
h_mirror = False
# if np.random.rand() > 0.5 and self.split == 'train':
# h_mirror = True
# pc_in[0, :] *= -1
img = Image.open(img_path)
# print(img_path)
# img = cv2.imread(img_path)
img_rotation = 0.
# if self.split == 'train':
# img_rotation = np.random.uniform(-5, 5)
try:
img = self.custom_transform(img, img_rotation, h_mirror)
except OSError:
new_idx = np.random.randint(0, self.__len__())
return self.__getitem__(new_idx)
# Rotate PointCloud for img_rotation
# if self.split == 'train':
# R = mathutils.Euler((radians(img_rotation), 0, 0), 'XYZ')
# T = mathutils.Vector((0., 0., 0.))
# pc_in = rotate_forward(pc_in, R, T)
if self.split == 'train':
max_angle = self.max_r
rotz = np.random.uniform(-max_angle, max_angle) * (3.141592 / 180.0)
roty = np.random.uniform(-max_angle, max_angle) * (3.141592 / 180.0)
rotx = np.random.uniform(-max_angle, max_angle) * (3.141592 / 180.0)
transl_x = np.random.uniform(-self.max_t, self.max_t)
transl_y = np.random.uniform(-self.max_t, self.max_t)
transl_z = np.random.uniform(-self.max_t, self.max_t)
# transl_z = np.random.uniform(-self.max_t, min(self.max_t, 1.))
initial_RT = 0
else:
initial_RT = self.val_RT[idx]
rotz = initial_RT[6]
roty = initial_RT[5]
rotx = initial_RT[4]
transl_x = initial_RT[1]
transl_y = initial_RT[2]
transl_z = initial_RT[3]
# 随机设置一定范围内的标定参数扰动值
# train的时候每次都随机生成,每个epoch使用不同的参数
# test则在初始化的时候提前设置好,每个epoch都使用相同的参数
R = mathutils.Euler((rotx, roty, rotz), 'XYZ')
T = mathutils.Vector((transl_x, transl_y, transl_z))
R, T = invert_pose(R, T)
R, T = torch.tensor(R), torch.tensor(T)
#io.imshow(depth_img.numpy(), cmap='jet')
#io.show()
calib = calib_cam02
# calib = get_calib_kitti_odom(int(seq))
if h_mirror:
calib[2] = (img.shape[2] / 2)*2 - calib[2]
# sample = {'rgb': img, 'point_cloud': pc_in, 'calib': calib, 'pc_org': pc_org, 'img_path': img_path,
# 'tr_error': T, 'rot_error': R, 'seq': int(seq), 'rgb_name': rgb_name, 'item': item,
# 'extrin': E_RT, 'initial_RT': initial_RT}
sample = {'rgb': img, 'point_cloud': pc_in, 'calib': calib, 'pc_org': pc_org, 'img_path': img_path,
'tr_error': T, 'rot_error': R, 'rgb_name': rgb_name + '.png', 'item': item,
'extrin': E_RT, 'initial_RT': initial_RT, 'pc_lidar': pc_lidar}
return sample