SynthField / utils /bag_extractor.py
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import os
import glob
import cv2
import numpy as np
import yaml
import json
import rosbag2_py
from rclpy.serialization import deserialize_message
from rosidl_runtime_py.utilities import get_message
import sensor_msgs_py.point_cloud2 as pc2
class BagDatasetExtractor:
def __init__(self, bag_path, output_dir, lidar_transform_path, camera_transform_path, start_frame_idx=0):
self.bag_path = bag_path
self.output_dir = output_dir
self.lidar_transform_path = lidar_transform_path
self.camera_transform_path = camera_transform_path
self.frame_idx = start_frame_idx
self.prepare_folders()
# ROS 2 Bag Reader Setup
self.reader = rosbag2_py.SequentialReader()
storage_options = rosbag2_py.StorageOptions(uri=self.bag_path, storage_id='sqlite3')
converter_options = rosbag2_py.ConverterOptions(
input_serialization_format='cdr',
output_serialization_format='cdr'
)
self.reader.open(storage_options, converter_options)
self.topic_types = {topic.name: topic.type for topic in self.reader.get_all_topics_and_types()}
self.transforms = self._load_transforms()
# Dynamic Mappings
'''
11225069610@A70i:~/Desktop/BEV_EDL/data/bags$ ros2 topic echo --once /bev/semantic_labels
data: '{"0":{"class":"BACKGROUND"},"1":{"class":"UNLABELLED"},"2":{"class":"leaf"},"3":{"class":"branch"},"4":{"class":"weed"},"5":{"cl...'
---
11225069610@A70i:~/Desktop/BEV_EDL/data/bags$ ros2 topic echo --once /bev/semantic_labels_bb
data: '{"0":{"class":"ground"},"1":{"class":"leaf"},"2":{"class":"branch"},"3":{"class":"weed"},"4":{"class":"obstacle"},"time_stamp":{...'
---
'''
self.target_classes = {"ground": 0, "leaf": 1, "branch": 2, "weed": 3, "obstacle": 4}
self.semantic_mapping = {}
self.bb_mapping = {}
def _create_matrix_from_yaml(self, transform_data):
t = transform_data['transformation']['translation']
q = transform_data['transformation']['rotation']
translation = np.array([t['x'], t['y'], t['z']])
x, y, z, w = q['x'], q['y'], q['z'], q['w']
# Normalize quaternion
norm = np.sqrt(x*x + y*y + z*z + w*w)
if norm == 0:
# Handle zero-norm quaternion (invalid rotation)
x, y, z, w = 0, 0, 0, 1
else:
x /= norm
y /= norm
z /= norm
w /= norm
# Rotation matrix from quaternion
rotation_matrix = np.array([
[1 - 2*y*y - 2*z*z, 2*x*y - 2*z*w, 2*x*z + 2*y*w],
[2*x*y + 2*z*w, 1 - 2*x*x - 2*z*z, 2*y*z - 2*x*w],
[2*x*z - 2*y*w, 2*y*z + 2*x*w, 1 - 2*x*x - 2*y*y]
])
# Create 4x4 homogeneous matrix
matrix = np.eye(4)
matrix[:3, :3] = rotation_matrix
matrix[:3, 3] = translation
return matrix
def _load_transforms(self):
transforms = {}
try:
with open(self.lidar_transform_path, 'r') as f:
lidar_transform_data = yaml.safe_load(f)
transforms['lidar_to_parent'] = self._create_matrix_from_yaml(lidar_transform_data)
with open(self.camera_transform_path, 'r') as f:
camera_transform_data = yaml.safe_load(f)
transforms['camera_to_parent'] = self._create_matrix_from_yaml(camera_transform_data)
except Exception as e:
print(f"Warning: Transform file issue: {e}")
return transforms
def prepare_folders(self):
for sub in ['rgb', 'depth', 'lidar', 'bev_label', 'extrinsics']:
os.makedirs(os.path.join(self.output_dir, sub), exist_ok=True)
def _parse_label_json(self, json_str):
"""Extracts the mapping from Isaac Sim JSON string to our fixed IDs."""
mapping = {}
try:
data = json.loads(json_str)
for key, val in data.items():
if isinstance(val, dict) and "class" in val:
class_name = val["class"].lower()
if class_name in self.target_classes:
mapping[int(key)] = self.target_classes[class_name]
except json.JSONDecodeError:
print(f"Warning: Failed to parse JSON label string: {json_str}")
return mapping
def process_bev_logic(self, semantic_msg, bbox_msg):
height, width = semantic_msg.height, semantic_msg.width
semantic_raw = np.frombuffer(semantic_msg.data, dtype=np.int32).reshape((height, width))
# 1. Remap Semantic Image
remapped_semantic = np.full_like(semantic_raw, 3, dtype=np.uint8) # Default 3 (Other/Background)
for isaac_id, target_id in self.semantic_mapping.items():
remapped_semantic[semantic_raw == isaac_id] = target_id
# 2. Add bounding box centers for branches
for detection in bbox_msg.detections:
if detection.results:
try:
isaac_class_id = int(detection.results[0].hypothesis.class_id)
# Use the BB mapping specifically for the bounding boxes
if self.bb_mapping.get(isaac_class_id) == 2: # 2 is Branch
center_x = int(detection.bbox.center.position.x)
center_y = int(detection.bbox.center.position.y)
cv2.circle(remapped_semantic, (center_x, center_y), radius=3, color=2, thickness=-1)
except Exception as e:
continue
return remapped_semantic
def run(self):
print(f"Starting extraction for bag: {os.path.basename(self.bag_path)}")
sync_data = {}
# Added the label topics to the filter
self.reader.set_filter(rosbag2_py.StorageFilter(topics=[
'/camera_front/rgb', '/camera_front/depth', '/lidar_front/point_cloud',
'/bev/semantic_segmentation', '/bev/bbox_2d',
'/bev/semantic_labels', '/bev/semantic_labels_bb'
]))
while self.reader.has_next():
(topic, data, t_msg) = self.reader.read_next()
msg_type = get_message(self.topic_types[topic])
msg = deserialize_message(data, msg_type)
# Update Mappings dynamically if we see the label topics
if topic == '/bev/semantic_labels':
self.semantic_mapping = self._parse_label_json(msg.data)
continue
elif topic == '/bev/semantic_labels_bb':
self.bb_mapping = self._parse_label_json(msg.data)
continue
ts = msg.header.stamp.sec * 1e9 + msg.header.stamp.nanosec if hasattr(msg, 'header') else t_msg
time_key = int(ts / 100_000_000)
if time_key not in sync_data:
sync_data[time_key] = {}
sync_data[time_key][topic] = msg
# Only save the sample if we have all sensor data AND we have successfully captured our label mappings
required = ['/camera_front/rgb', '/camera_front/depth',
'/lidar_front/point_cloud', '/bev/semantic_segmentation', '/bev/bbox_2d']
if all(topic in sync_data[time_key] for topic in required):
if not self.semantic_mapping or not self.bb_mapping:
# Skip until we receive the label definitions
del sync_data[time_key]
continue
self.save_sample(sync_data[time_key])
del sync_data[time_key]
return self.frame_idx
def save_sample(self, data):
prefix = f"{self.frame_idx:06d}"
if not self.transforms or 'lidar_to_parent' not in self.transforms:
return
lidar_matrix = self.transforms['lidar_to_parent']
cam_matrix = self.transforms['camera_to_parent']
np.save(f"{self.output_dir}/extrinsics/{prefix}_lidar_to_base.npy", lidar_matrix)
np.save(f"{self.output_dir}/extrinsics/{prefix}_cam_to_base.npy", cam_matrix)
rgb_img = np.frombuffer(data['/camera_front/rgb'].data, dtype=np.uint8).reshape((480, 640, 3))
cv2.imwrite(f"{self.output_dir}/rgb/{prefix}.jpg", cv2.cvtColor(rgb_img, cv2.COLOR_RGB2BGR))
depth_img = np.frombuffer(data['/camera_front/depth'].data, dtype=np.float32).reshape((480, 640))
np.save(f"{self.output_dir}/depth/{prefix}.npy", depth_img)
points = pc2.read_points_numpy(data['/lidar_front/point_cloud'], field_names=("x", "y", "z"))
points_hom = np.hstack((points, np.ones((points.shape[0], 1))))
points_transformed = (lidar_matrix @ points_hom.T).T[:, :3]
np.save(f"{self.output_dir}/lidar/{prefix}.npy", points_transformed)
processed_label = self.process_bev_logic(data['/bev/semantic_segmentation'], data['/bev/bbox_2d'])
cv2.imwrite(f"{self.output_dir}/bev_label/{prefix}.png", processed_label)
if self.frame_idx % 50 == 0:
print(f" Saved {self.frame_idx} samples...")
self.frame_idx += 1
if __name__ == "__main__":
BAGS_DIR = "/home/11225069610/Desktop/BEV_EDL/data/bags"
OUTPUT_DIR = "/home/11225069610/Desktop/bag_extract/"
LIDAR_TRANSFORM_PATH = "/home/11225069610/Desktop/BEV_EDL/data/lidar.yaml"
CAMERA_TRANSFORM_PATH = "/home/11225069610/Desktop/BEV_EDL/data/camera.yaml"
# Find all bags in the directory
bag_paths = sorted(glob.glob(os.path.join(BAGS_DIR, "*")))
if not bag_paths:
print(f"No bags found in {BAGS_DIR}")
bag_paths = ["/home/11225069610/Desktop/rosbag2_2026_03_27-16_05_37"]
current_frame_idx = 0
for bag_path in bag_paths:
extractor = BagDatasetExtractor(
bag_path=bag_path,
output_dir=OUTPUT_DIR,
lidar_transform_path=LIDAR_TRANSFORM_PATH,
camera_transform_path=CAMERA_TRANSFORM_PATH,
start_frame_idx=current_frame_idx
)
current_frame_idx = extractor.run()
print(f"Finished extracting! Total frames processed: {current_frame_idx}")