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kitti.py
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kitti.py
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import os
import cv2
import numpy as np
import torch.utils.data
from utils import disp2pc, project_pc2image, load_flow_png, load_disp_png, load_calib, zero_padding
from augmentation import joint_augmentation
class KITTI(torch.utils.data.Dataset):
def __init__(self, cfgs):
assert os.path.isdir(cfgs.root_dir)
assert cfgs.split in ['training200', 'training160', 'training40', 'testing200']
if 'training' in cfgs.split:
self.root_dir = os.path.join(cfgs.root_dir, 'training')
else:
self.root_dir = os.path.join(cfgs.root_dir, 'testing')
self.split = cfgs.split
self.cfgs = cfgs
if self.split == 'training200' or self.split == 'testing200':
self.indices = np.arange(200)
elif self.split == 'training160':
self.indices = [i for i in range(200) if i % 5 != 0]
elif self.split == 'training40':
self.indices = [i for i in range(200) if i % 5 == 0]
def __len__(self):
return len(self.indices)
def __getitem__(self, i):
if not self.cfgs.augmentation.enabled:
np.random.seed(23333)
index = self.indices[i]
data_dict = {'index': index}
proj_mat = load_calib(os.path.join(self.root_dir, 'calib_cam_to_cam', '%06d.txt' % index))
f, cx, cy = proj_mat[0, 0], proj_mat[0, 2], proj_mat[1, 2]
image1 = cv2.imread(os.path.join(self.root_dir, 'image_2', '%06d_10.png' % index))[..., ::-1]
image2 = cv2.imread(os.path.join(self.root_dir, 'image_2', '%06d_11.png' % index))[..., ::-1]
data_dict['input_h'] = image1.shape[0]
data_dict['input_w'] = image1.shape[1]
flow_2d, flow_2d_mask = load_flow_png(os.path.join(self.root_dir, 'flow_occ', '%06d_10.png' % index))
disp1, mask1 = load_disp_png(os.path.join(self.root_dir, 'disp_occ_0', '%06d_10.png' % index))
disp2, mask2 = load_disp_png(os.path.join(self.root_dir, 'disp_occ_1', '%06d_10.png' % index))
mask = np.logical_and(np.logical_and(mask1, mask2), flow_2d_mask)
pc1 = disp2pc(disp1, baseline=0.54, f=f, cx=cx, cy=cy)[mask]
pc2 = disp2pc(disp2, baseline=0.54, f=f, cx=cx, cy=cy, flow=flow_2d)[mask]
flow_3d = pc2 - pc1
flow_3d_mask = np.ones(flow_3d.shape[0], dtype=np.float32)
# remove out-of-boundary regions of pc2 to create occlusion
image_h, image_w = disp2.shape[:2]
xy2 = project_pc2image(pc2, image_h, image_w, f, cx, cy, clip=False)
boundary_mask = np.logical_and(
np.logical_and(xy2[..., 0] >= 0, xy2[..., 0] < image_w),
np.logical_and(xy2[..., 1] >= 0, xy2[..., 1] < image_h)
)
pc2 = pc2[boundary_mask]
flow_2d = np.concatenate([flow_2d, flow_2d_mask[..., None].astype(np.float32)], axis=-1)
flow_3d = np.concatenate([flow_3d, flow_3d_mask[..., None].astype(np.float32)], axis=-1)
# images from KITTI have various sizes, padding them to a unified size of 1242x376
padding_h, padding_w = 376, 1242
image1 = zero_padding(image1, padding_h, padding_w)
image2 = zero_padding(image2, padding_h, padding_w)
flow_2d = zero_padding(flow_2d, padding_h, padding_w)
# data augmentation
image1, image2, pc1, pc2, flow_2d, flow_3d, f, cx, cy = joint_augmentation(
image1, image2, pc1, pc2, flow_2d, flow_3d, f, cx, cy, self.cfgs.augmentation,
)
# random sampling
indices1 = np.random.choice(pc1.shape[0], size=self.cfgs.n_points, replace=pc1.shape[0] < self.cfgs.n_points)
indices2 = np.random.choice(pc2.shape[0], size=self.cfgs.n_points, replace=pc2.shape[0] < self.cfgs.n_points)
pc1, pc2, flow_3d = pc1[indices1], pc2[indices2], flow_3d[indices1]
pcs = np.concatenate([pc1, pc2], axis=1)
images = np.concatenate([image1, image2], axis=-1)
data_dict['images'] = images.transpose([2, 0, 1])
data_dict['flow_2d'] = flow_2d.transpose([2, 0, 1])
data_dict['pcs'] = pcs.transpose()
data_dict['flow_3d'] = flow_3d.transpose()
data_dict['intrinsics'] = np.float32([f, cx, cy])
return data_dict
class KITTITest(torch.utils.data.Dataset):
def __init__(self, cfgs):
assert os.path.isdir(cfgs.root_dir)
assert cfgs.split in ['testing200']
self.root_dir = os.path.join(cfgs.root_dir, 'testing')
self.split = cfgs.split
self.cfgs = cfgs
def __len__(self):
return 200
def __getitem__(self, index):
np.random.seed(23333)
data_dict = {'index': index}
proj_mat = load_calib(os.path.join(self.root_dir, 'calib_cam_to_cam', '%06d.txt' % index))
f, cx, cy = proj_mat[0, 0], proj_mat[0, 2], proj_mat[1, 2]
image1 = cv2.imread(os.path.join(self.root_dir, 'image_2', '%06d_10.png' % index))[..., ::-1]
image2 = cv2.imread(os.path.join(self.root_dir, 'image_2', '%06d_11.png' % index))[..., ::-1]
data_dict['input_h'] = image1.shape[0]
data_dict['input_w'] = image1.shape[1]
disp1, mask1 = load_disp_png(os.path.join(self.root_dir, 'disp_%s' % self.cfgs.disp_provider, '%06d_10.png' % index))
disp2, mask2 = load_disp_png(os.path.join(self.root_dir, 'disp_%s' % self.cfgs.disp_provider, '%06d_11.png' % index))
# ignore top 110 rows without evaluation
mask1[:110] = 0
mask2[:110] = 0
pc1 = disp2pc(disp1, baseline=0.54, f=f, cx=cx, cy=cy)[mask1]
pc2 = disp2pc(disp2, baseline=0.54, f=f, cx=cx, cy=cy)[mask2]
# limit max height (2.0m)
pc1 = pc1[pc1[..., 1] > -2.0]
pc2 = pc2[pc2[..., 1] > -2.0]
# limit max depth
pc1 = pc1[pc1[..., -1] < self.cfgs.max_depth]
pc2 = pc2[pc2[..., -1] < self.cfgs.max_depth]
# images from KITTI have various sizes, padding them to a unified size of 1242x376
padding_h, padding_w = 376, 1242
image1 = zero_padding(image1, padding_h, padding_w)
image2 = zero_padding(image2, padding_h, padding_w)
# random sampling
indices1 = np.random.choice(pc1.shape[0], size=self.cfgs.n_points, replace=pc1.shape[0] < self.cfgs.n_points)
indices2 = np.random.choice(pc2.shape[0], size=self.cfgs.n_points, replace=pc2.shape[0] < self.cfgs.n_points)
pc1, pc2 = pc1[indices1], pc2[indices2]
pcs = np.concatenate([pc1, pc2], axis=1)
images = np.concatenate([image1, image2], axis=-1)
data_dict['images'] = images.transpose([2, 0, 1])
data_dict['pcs'] = pcs.transpose()
data_dict['intrinsics'] = np.float32([f, cx, cy])
return data_dict