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virtual_gen.py
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virtual_gen.py
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from nusc_image_projection import read_file, to_batch_tensor, to_tensor, projectionV2, reverse_view_points, get_obj
from torch.utils.data import DataLoader, Dataset
from tqdm import tqdm
import argparse
import numpy as np
import torch
import cv2
import os
H=900
W=1600
class PaintDataSet(Dataset):
def __init__(
self,
info_path,
predictor
):
infos = get_obj(info_path)
sweeps = []
paths = set()
for info in infos:
if info['lidar_path'] not in paths:
paths.add(info['lidar_path'])
sweeps.append(info)
for sweep in info['sweeps']:
if sweep['lidar_path'] not in paths:
sweeps.append(sweep)
paths.add(sweep['lidar_path'])
self.sweeps = sweeps
self.predictor = predictor
@torch.no_grad()
def __getitem__(self, index):
info = self.sweeps[index]
tokens = info['lidar_path'].split('/')
output_path = os.path.join(*tokens[:-2], tokens[-2]+"_VIRTUAL", tokens[-1]+'.pkl.npy')
if os.path.isfile(output_path):
return []
all_cams_path = info['all_cams_path']
all_data = [info]
for path in all_cams_path:
original_image = cv2.imread(path)
if self.predictor.input_format == "RGB":
# whether the model expects BGR inputs or RGB
original_image = original_image[:, :, ::-1]
height, width = original_image.shape[:2]
image = self.predictor.aug.get_transform(original_image).apply_image(original_image)
image = torch.as_tensor(image.astype("float32").transpose(2, 0, 1))
inputs = {"image": image, "height": height, "width": width}
all_data.append(inputs)
return all_data
def __len__(self):
return len(self.sweeps)
def is_within_mask(points_xyc, masks, H=900, W=1600):
seg_mask = masks[:, :-1].reshape(-1, W, H)
camera_id = masks[:, -1]
points_xyc = points_xyc.long()
valid = seg_mask[:, points_xyc[:, 0], points_xyc[:, 1]] * (camera_id[:, None] == points_xyc[:, -1][None])
return valid.transpose(1, 0)
@torch.no_grad()
def add_virtual_mask(masks, labels, points, raw_points, num_virtual=50, dist_thresh=3000, num_camera=6, intrinsics=None, transforms=None):
points_xyc = points.reshape(-1, 5)[:, [0, 1, 4]] # x, y, z, valid_indicator, camera id
valid = is_within_mask(points_xyc, masks)
valid = valid * points.reshape(-1, 5)[:, 3:4]
# remove camera id from masks
camera_ids = masks[:, -1]
masks = masks[:, :-1]
box_to_label_mapping = torch.argmax(valid.float(), dim=1).reshape(-1, 1).repeat(1, 11)
point_labels = labels.gather(0, box_to_label_mapping)
point_labels *= (valid.sum(dim=1, keepdim=True) > 0 )
foreground_real_point_mask = (valid.sum(dim=1, keepdim=True) > 0 ).reshape(num_camera, -1).sum(dim=0).bool()
offsets = []
for mask in masks:
indices = mask.reshape(W, H).nonzero()
selected_indices = torch.randperm(len(indices), device=masks.device)[:num_virtual]
if len(selected_indices) < num_virtual:
selected_indices = torch.cat([selected_indices, selected_indices[
selected_indices.new_zeros(num_virtual-len(selected_indices))]])
offset = indices[selected_indices]
offsets.append(offset)
offsets = torch.stack(offsets, dim=0)
virtual_point_instance_ids = torch.arange(1, 1+masks.shape[0],
dtype=torch.float32, device='cuda:0').reshape(masks.shape[0], 1, 1).repeat(1, num_virtual, 1)
virtual_points = torch.cat([offsets, virtual_point_instance_ids], dim=-1).reshape(-1, 3)
virtual_point_camera_ids = camera_ids.reshape(-1, 1, 1).repeat(1, num_virtual, 1).reshape(-1, 1)
valid_mask = valid.sum(dim=1)>0
real_point_instance_ids = (torch.argmax(valid.float(), dim=1) + 1)[valid_mask]
real_points = torch.cat([points_xyc[:, :2][valid_mask], real_point_instance_ids[..., None]], dim=-1)
# avoid matching across instances
real_points[:, -1] *= 1e4
virtual_points[:, -1] *= 1e4
if len(real_points) == 0:
return None
dist = torch.norm(virtual_points.unsqueeze(1) - real_points.unsqueeze(0), dim=-1)
nearest_dist, nearest_indices = torch.min(dist, dim=1)
mask = nearest_dist < dist_thresh
indices = valid_mask.nonzero(as_tuple=False).reshape(-1)
nearest_indices = indices[nearest_indices[mask]]
virtual_points = virtual_points[mask]
virtual_point_camera_ids = virtual_point_camera_ids[mask]
all_virtual_points = []
all_real_points = []
all_point_labels = []
for i in range(num_camera):
camera_mask = (virtual_point_camera_ids == i).squeeze()
per_camera_virtual_points = virtual_points[camera_mask]
per_camera_indices = nearest_indices[camera_mask]
per_camera_virtual_points_depth = points.reshape(-1, 5)[per_camera_indices, 2].reshape(1, -1)
per_camera_virtual_points = per_camera_virtual_points[:, :2] # remove instance id
per_camera_virtual_points_padded = torch.cat(
[per_camera_virtual_points.transpose(1, 0).float(),
torch.ones((1, len(per_camera_virtual_points)), device=per_camera_indices.device, dtype=torch.float32)],
dim=0
)
per_camera_virtual_points_3d = reverse_view_points(per_camera_virtual_points_padded, per_camera_virtual_points_depth, intrinsics[i])
per_camera_virtual_points_3d[:3] = torch.matmul(torch.inverse(transforms[i]),
torch.cat([
per_camera_virtual_points_3d[:3, :],
torch.ones(1, per_camera_virtual_points_3d.shape[1], dtype=torch.float32, device=per_camera_indices.device)
], dim=0)
)[:3]
all_virtual_points.append(per_camera_virtual_points_3d.transpose(1, 0))
all_real_points.append(raw_points.reshape(1, -1, 4).repeat(num_camera, 1, 1).reshape(-1,4)[per_camera_indices][:, :3])
all_point_labels.append(point_labels[per_camera_indices])
all_virtual_points = torch.cat(all_virtual_points, dim=0)
all_real_points = torch.cat(all_real_points, dim=0)
all_point_labels = torch.cat(all_point_labels, dim=0)
all_virtual_points = torch.cat([all_virtual_points, all_point_labels], dim=1)
real_point_labels = point_labels.reshape(num_camera, raw_points.shape[0], -1)
real_point_labels = torch.max(real_point_labels, dim=0)[0]
all_real_points = torch.cat([raw_points[foreground_real_point_mask.bool()], real_point_labels[foreground_real_point_mask.bool()]], dim=1)
return all_virtual_points, all_real_points, foreground_real_point_mask.bool().nonzero(as_tuple=False).reshape(-1)
def init_detector(args):
from CenterNet2.train_net import setup
from detectron2.engine import DefaultPredictor
cfg = setup(args)
predictor = DefaultPredictor(cfg)
return predictor
def postprocess(res):
result = res['instances']
labels = result.pred_classes
scores = result.scores
masks = result.pred_masks.reshape(scores.shape[0], 1600*900)
boxes = result.pred_boxes.tensor
# remove empty mask and their scores / labels
empty_mask = masks.sum(dim=1) == 0
labels = labels[~empty_mask]
scores = scores[~empty_mask]
masks = masks[~empty_mask]
boxes = boxes[~empty_mask]
masks = masks.reshape(-1, 900, 1600).permute(0, 2, 1).reshape(-1, 1600*900)
return labels, scores, masks
@torch.no_grad()
def process_one_frame(info, predictor, data, num_camera=6):
all_cams_from_lidar = info['all_cams_from_lidar']
all_cams_intrinsic = info['all_cams_intrinsic']
lidar_points = read_file(info['lidar_path'])
one_hot_labels = []
for i in range(10):
one_hot_label = torch.zeros(10, device='cuda:0', dtype=torch.float32)
one_hot_label[i] = 1
one_hot_labels.append(one_hot_label)
one_hot_labels = torch.stack(one_hot_labels, dim=0)
masks = []
labels = []
camera_ids = torch.arange(6, dtype=torch.float32, device='cuda:0').reshape(6, 1, 1)
result = predictor.model(data[1:])
for camera_id in range(num_camera):
pred_label, score, pred_mask = postprocess(result[camera_id])
camera_id = torch.tensor(camera_id, dtype=torch.float32, device='cuda:0').reshape(1,1).repeat(pred_mask.shape[0], 1)
pred_mask = torch.cat([pred_mask, camera_id], dim=1)
transformed_labels = one_hot_labels.gather(0, pred_label.reshape(-1, 1).repeat(1, 10))
transformed_labels = torch.cat([transformed_labels, score.unsqueeze(-1)], dim=1)
masks.append(pred_mask)
labels.append(transformed_labels)
masks = torch.cat(masks, dim=0)
labels = torch.cat(labels, dim=0)
P = projectionV2(to_tensor(lidar_points), to_batch_tensor(all_cams_from_lidar), to_batch_tensor(all_cams_intrinsic))
camera_ids = torch.arange(6, dtype=torch.float32, device='cuda:0').reshape(6, 1, 1).repeat(1, P.shape[1], 1)
P = torch.cat([P, camera_ids], dim=-1)
if len(masks) == 0:
res = None
else:
res = add_virtual_mask(masks, labels, P, to_tensor(lidar_points),
intrinsics=to_batch_tensor(all_cams_intrinsic), transforms=to_batch_tensor(all_cams_from_lidar))
if res is not None:
virtual_points, foreground_real_points, foreground_indices = res
return virtual_points.cpu().numpy(), foreground_real_points.cpu().numpy(), foreground_indices.cpu().numpy()
else:
return None
def simple_collate(batch_list):
assert len(batch_list)==1
batch_list = batch_list[0]
return batch_list
def main(args):
predictor = init_detector(args)
data_loader = DataLoader(
PaintDataSet(args.info_path, predictor),
batch_size=1,
num_workers=8,
collate_fn=simple_collate,
pin_memory=False,
shuffle=False
)
for idx, data in tqdm(enumerate(data_loader), total=len(data_loader.dataset)):
if len(data) == 0:
continue
info = data[0]
tokens = info['lidar_path'].split('/')
output_path = os.path.join(*tokens[:-2], tokens[-2]+"_VIRTUAL", tokens[-1]+'.pkl.npy')
res = process_one_frame(info, predictor, data)
if res is not None:
virtual_points, real_points, indices = res
else:
virtual_points = np.zeros([0, 14])
real_points = np.zeros([0, 15])
indices = np.zeros(0)
data_dict = {
'virtual_points': virtual_points,
'real_points': real_points,
'real_points_indice': indices
}
np.save(output_path, data_dict)
# torch.cuda.empty_cache() if you get OOM error
if __name__ == '__main__':
import argparse
parser = argparse.ArgumentParser(description="CenterPoint")
parser.add_argument('--info_path', type=str, required=True)
parser.add_argument('--config-file', type=str, default='c2_config/nuImages_CenterNet2_DLA_640_8x.yaml')
parser.add_argument(
"opts",
help="Modify config options by adding 'KEY VALUE' pairs at the end of the command. "
"See config references at "
"https://detectron2.readthedocs.io/modules/config.html#config-references",
default=None,
nargs=argparse.REMAINDER,
)
args = parser.parse_args()
if not os.path.isdir('data/nuScenes/samples/LIDAR_TOP_VIRTUAL'):
os.mkdir('data/nuScenes/samples/LIDAR_TOP_VIRTUAL')
if not os.path.isdir('data/nuScenes/sweeps/LIDAR_TOP_VIRTUAL'):
os.mkdir('data/nuScenes/sweeps/LIDAR_TOP_VIRTUAL')
main(args)