Simulator/scripts/test_shenron.py

import os
import sys
import numpy as np
import tqdm
from pathlib import Path
import json
import base64
import argparse
from mcap.writer import Writer

# Add project root and ISOLATE paths
project_root = Path(__file__).parent.parent
sys.path.append(str(project_root))
sys.path.append(str(project_root / 'scripts' / 'ISOLATE'))

try:
    from scripts.ISOLATE.model_wrapper import ShenronRadarModel
except ImportError as e:
    print(f"Error: Failed to import ShenronRadarModel. Ensure scripts/ISOLATE/model_wrapper.py exists. ({e})")
    sys.exit(1)

# Official Foxglove JSON Schemas
FOXGLOVE_POSE_SCHEMA = {
    "$schema": "https://json-schema.org/draft/2020-12/schema",
    "$id": "foxglove.Pose",
    "title": "foxglove.Pose",
    "type": "object",
    "properties": {
        "position": {"type": "object", "properties": {"x": {"type": "number"}, "y": {"type": "number"}, "z": {"type": "number"}}},
        "orientation": {"type": "object", "properties": {"x": {"type": "number"}, "y": {"type": "number"}, "z": {"type": "number"}, "w": {"type": "number"}}}
    }
}
FOXGLOVE_IMAGE_SCHEMA = {
    "$schema": "https://json-schema.org/draft/2020-12/schema",
    "$id": "foxglove.CompressedImage",
    "title": "foxglove.CompressedImage",
    "type": "object",
    "properties": {
        "timestamp": {"type": "object", "properties": {"sec": {"type": "integer"}, "nsec": {"type": "integer"}}},
        "frame_id": {"type": "string"},
        "data": {"type": "string", "contentEncoding": "base64"},
        "format": {"type": "string"}
    }
}
FOXGLOVE_PCL_SCHEMA = {
    "$schema": "https://json-schema.org/draft/2020-12/schema",
    "$id": "foxglove.PointCloud",
    "title": "foxglove.PointCloud",
    "type": "object",
    "properties": {
        "timestamp": {"type": "object", "properties": {"sec": {"type": "integer"}, "nsec": {"type": "integer"}}},
        "frame_id": {"type": "string"},
        "pose": FOXGLOVE_POSE_SCHEMA,
        "point_stride": {"type": "integer"},
        "fields": {
            "type": "array",
            "items": {"type": "object", "properties": {"name": {"type": "string"}, "offset": {"type": "integer"}, "type": {"type": "integer"}}}
        },
        "data": {"type": "string", "contentEncoding": "base64"}
    }
}

def load_frames(folder_path):
    with open(os.path.join(folder_path, "frames.jsonl")) as f:
        for line in f:
            yield json.loads(line)

def run_testbench(iter_name):
    # Setup directories
    debug_dir = project_root / 'Shenron_debug'
    logs_dir = debug_dir / 'logs'
    iter_dir = debug_dir / 'iterations' / iter_name
    
    if not logs_dir.exists():
        print(f"[ERROR] Required base folder {logs_dir} not found!")
        return
        
    lidar_dir = logs_dir / 'lidar'
    if not lidar_dir.exists():
        print(f"[ERROR] Required base folder {lidar_dir} not found!")
        return
        
    iter_dir.mkdir(parents=True, exist_ok=True)
    radar_types = ['awrl1432']
    
    print(f"\n======================================")
    print(f"SHENRON TESTBENCH ITERATION: {iter_name}")
    print(f"======================================")
    
    # 1. GENERATE SYNTHETIC DATA
    print("\n[Stage 1]: Processing Physics models...")
    models = {}
    for r_type in radar_types:
        try:
            print(f"  -> Initializing {r_type} engine...")
            models[r_type] = ShenronRadarModel(radar_type=r_type)
            (iter_dir / r_type).mkdir(exist_ok=True)
        except Exception as e:
            print(f"  -> [WARNING] Failed to init {r_type}: {e}")
            
    lidar_files = sorted(list(lidar_dir.glob("*.npy")))
    for lidar_file in tqdm.tqdm(lidar_files, desc="  Simulating Radars", unit="frame"):
        data = np.load(lidar_file)
        # Pad to [x, y, z, intensity, cos_inc_angle, obj, tag] if needed
        if data.shape[1] == 6:
            padded_data = np.zeros((data.shape[0], 7), dtype=np.float32)
            padded_data[:, 0:3] = data[:, 0:3]
            padded_data[:, 4:7] = data[:, 3:6]
            data = padded_data
            
        for r_type, model in models.items():
            try:
                rich_pcd = model.process(data)
                out_path = iter_dir / r_type / lidar_file.name
                np.save(out_path, rich_pcd)
            except Exception as e:
                print(f"[ERROR] Frame {lidar_file.name} failed for {r_type}: {e}")

    # 2. GENERATE MCAP
    print("\n[Stage 2]: Weaving MCAP Comparison Package...")
    output_mcap = iter_dir / f"{iter_name}.mcap"
    
    with open(output_mcap, "wb") as f:
        writer = Writer(f)
        writer.start(profile="foxglove")

        # Register Schemas
        pose_schema_id = writer.register_schema(name="foxglove.Pose", encoding="jsonschema", data=json.dumps(FOXGLOVE_POSE_SCHEMA).encode())
        camera_schema_id = writer.register_schema(name="foxglove.CompressedImage", encoding="jsonschema", data=json.dumps(FOXGLOVE_IMAGE_SCHEMA).encode())
        lidar_schema_id = writer.register_schema(name="foxglove.PointCloud", encoding="jsonschema", data=json.dumps(FOXGLOVE_PCL_SCHEMA).encode())

        # Register Channels
        channels = {
            'camera': writer.register_channel(topic="/camera", message_encoding="json", schema_id=camera_schema_id),
            'camera_tpp': writer.register_channel(topic="/camera_tpp", message_encoding="json", schema_id=camera_schema_id),
            'lidar': writer.register_channel(topic="/lidar", message_encoding="json", schema_id=lidar_schema_id),
            'native_radar': writer.register_channel(topic="/radar/native", message_encoding="json", schema_id=lidar_schema_id),
            'ego_pose': writer.register_channel(topic="/ego_pose", message_encoding="json", schema_id=pose_schema_id)
        }
        
        shenron_channels = {}
        for r_type in radar_types:
            shenron_channels[r_type] = writer.register_channel(topic=f"/radar/{r_type}", message_encoding="json", schema_id=lidar_schema_id)

        try:
            frames_gen = load_frames(logs_dir)
            frames = list(frames_gen)
        except Exception as e:
            print(f"[ERROR] Could not load frames.jsonl from {logs_dir}: {e}")
            return
            
        for frame in tqdm.tqdm(frames, desc="  Packaging Frames", unit="frame"):
            ts_ns = int(frame["timestamp"] * 1e9)
            ts_sec = ts_ns // 1_000_000_000
            ts_nsec = ts_ns % 1_000_000_000

            raw_pose = frame["ego_pose"]
            x, y, z = raw_pose["x"], -raw_pose["y"], raw_pose["z"]
            yaw_rad = -np.radians(raw_pose.get("yaw", 0))
            
            ego_world_pose = {"position": {"x": x, "y": y, "z": z}, "orientation": {"x": 0.0, "y": 0.0, "z": float(np.sin(yaw_rad/2)), "w": float(np.cos(yaw_rad/2))}}
            identity_pose = {"position": {"x": 0.0, "y": 0.0, "z": 0.0}, "orientation": {"x": 0.0, "y": 0.0, "z": 0.0, "w": 1.0}}

            # POSE
            writer.add_message(channels['ego_pose'], log_time=ts_ns, data=json.dumps(ego_world_pose).encode(), publish_time=ts_ns)

            # CAMERA
            cam_path = logs_dir / "camera" / frame["camera"]
            if cam_path.exists():
                with open(cam_path, "rb") as img_f: img_bytes = img_f.read()
                cam_msg = {"timestamp": {"sec": ts_sec, "nsec": ts_nsec}, "frame_id": "ego_vehicle", "format": "png", "data": base64.b64encode(img_bytes).decode("ascii")}
                writer.add_message(channels['camera'], log_time=ts_ns, data=json.dumps(cam_msg).encode(), publish_time=ts_ns)

            # CAMERA TPP
            if "camera_tpp" in frame:
                cam_tpp_path = logs_dir / "camera_tpp" / frame["camera_tpp"]
                if cam_tpp_path.exists():
                    with open(cam_tpp_path, "rb") as img_f: img_bytes = img_f.read()
                    cam_msg = {"timestamp": {"sec": ts_sec, "nsec": ts_nsec}, "frame_id": "ego_vehicle", "format": "png", "data": base64.b64encode(img_bytes).decode("ascii")}
                    writer.add_message(channels['camera_tpp'], log_time=ts_ns, data=json.dumps(cam_msg).encode(), publish_time=ts_ns)

            # LIDAR
            lidar_p = logs_dir / "lidar" / frame["lidar"]
            if lidar_p.exists():
                points = np.load(lidar_p)
                # Robustness: Handle 6-column (Old) vs 7-column (Modern with Velocity) data
                if points.shape[1] == 6:
                    # Pad to 7-column [x, y, z, vel, cos, obj, tag]
                    # Note: obj and tag columns [4,5] are actually uint32 bitstreams
                    padded = np.zeros((points.shape[0], 7), dtype=np.float32)
                    padded[:, 0:3] = points[:, 0:3] 
                    padded[:, 4] = points[:, 3] # cos (pure float)
                    padded[:, 5] = points[:, 4].view(np.uint32).astype(np.float32) # real object id
                    padded[:, 6] = points[:, 5].view(np.uint32).astype(np.float32) # real semantic tag
                    ros_points = padded
                else:
                    ros_points = points.copy().astype(np.float32)
                    # For newer 7-col data: [x,y,z,vel,cos,obj,tag]
                    # We still need to fix the obj/tag bits at [5,6]
                    ros_points[:, 5] = ros_points[:, 5].view(np.uint32).astype(np.float32)
                    ros_points[:, 6] = ros_points[:, 6].view(np.uint32).astype(np.float32)

                ros_points[:, 1] = -ros_points[:, 1] # RHS conversion
                
                # MOUNT OFFSET: LiDAR is on the roof (Z=2.5)
                lidar_pose = {"position": {"x": 0.0, "y": 0.0, "z": 2.5}, "orientation": {"x": 0.0, "y": 0.0, "z": 0.0, "w": 1.0}}
                
                lidar_msg = {
                    "timestamp": {"sec": ts_sec, "nsec": ts_nsec}, "frame_id": "ego_vehicle", "pose": lidar_pose, "point_stride": 28,
                    "fields": [
                        {"name":"x","offset":0,"type":7}, 
                        {"name":"y","offset":4,"type":7}, 
                        {"name":"z","offset":8,"type":7},
                        {"name":"velocity","offset":12,"type":7},
                        {"name":"cos_inc_angle","offset":16,"type":7},
                        {"name":"object_id","offset":20,"type":7},
                        {"name":"semantic_tag","offset":24,"type":7}
                    ],
                    "data": base64.b64encode(ros_points.tobytes()).decode("ascii")
                }
                writer.add_message(channels['lidar'], log_time=ts_ns, data=json.dumps(lidar_msg).encode(), publish_time=ts_ns)

            # NATIVE RADAR
            radar_p = logs_dir / "radar" / frame["radar"]
            if radar_p.exists():
                r_data = np.load(radar_p)
                if r_data.size > 0:
                    dist, az, alt, vel = r_data[:, 0], -r_data[:, 1], r_data[:, 2], r_data[:, 3]
                    xr, yr, zr = dist*np.cos(az)*np.cos(alt), dist*np.sin(az)*np.cos(alt), dist*np.sin(alt)
                    radar_points = np.stack([xr, yr, zr, vel], axis=1).astype(np.float32)
                    
                    # MOUNT OFFSET: Native Radar is on the front bumper (X=2.0, Z=1.0)
                    radar_pose = {"position": {"x": 2.0, "y": 0.0, "z": 1.0}, "orientation": {"x": 0.0, "y": 0.0, "z": 0.0, "w": 1.0}}
                    
                    radar_msg = {
                        "timestamp": {"sec": ts_sec, "nsec": ts_nsec}, "frame_id": "ego_vehicle", "pose": radar_pose, "point_stride": 16,
                        "fields": [{"name":"x","offset":0,"type":7}, {"name":"y","offset":4,"type":7}, {"name":"z","offset":8,"type":7}, {"name":"velocity","offset":12,"type":7}],
                        "data": base64.b64encode(radar_points.tobytes()).decode("ascii")
                    }
                    writer.add_message(channels['native_radar'], log_time=ts_ns, data=json.dumps(radar_msg).encode(), publish_time=ts_ns)

            # SHENRON RADARS
            shenron_fname = f"frame_{int(frame['frame_id']):06d}.npy"
            for r_type in radar_types:
                s_path = iter_dir / r_type / shenron_fname
                if s_path.exists():
                    s_data = np.load(s_path)
                    if s_data.size > 0:
                        ros_shenron = s_data.copy().astype(np.float32)
                        ros_shenron[:, 1] = -ros_shenron[:, 1] # Negate Y for ROS
                        # MOUNT OFFSET: Shenron Radars use the same pose as native (X=2.0, Z=1.0)
                        shenron_pose = {"position": {"x": 2.0, "y": 0.0, "z": 1.0}, "orientation": {"x": 0.0, "y": 0.0, "z": 0.0, "w": 1.0}}
                        
                        shenron_msg = {
                            "timestamp": {"sec": ts_sec, "nsec": ts_nsec}, "frame_id": "ego_vehicle", "pose": shenron_pose, "point_stride": 20,
                            "fields": [{"name":"x","offset":0,"type":7}, {"name":"y","offset":4,"type":7}, {"name":"z","offset":8,"type":7}, {"name":"velocity","offset":12,"type":7}, {"name":"magnitude","offset":16,"type":7}],
                            "data": base64.b64encode(ros_shenron.tobytes()).decode("ascii")
                        }
                        writer.add_message(shenron_channels[r_type], log_time=ts_ns, data=json.dumps(shenron_msg).encode(), publish_time=ts_ns)

        writer.finish()
    print(f"\n[SUCCESS] Iteration packaged to: {output_mcap}")
    print(f"File size: {os.path.getsize(output_mcap)/1024/1024:.2f} MB")

if __name__ == "__main__":
    parser = argparse.ArgumentParser(description="Shenron Physics Iteration Testbench")
    parser.add_argument("--iter", required=True, help="Name of the current debug iteration (e.g., 01_baseline)")
    args = parser.parse_args()
    
    run_testbench(args.iter)