S1005403_RisCC/target_simulator/analysis/simulation_state_hub.py

# target_simulator/analysis/simulation_state_hub.py
"""
Defines the SimulationStateHub, a thread-safe data store for comparing
simulated target states with real data received from the radar.

Performance Notes:
- Uses a single threading.Lock for all operations (simple but potential contention)
- Future optimization: implement double-buffering to separate read/write paths
  (GUI reads from read_buffer, simulation/network write to write_buffer)
- Current design prioritizes correctness over maximum throughput
"""

import collections
import threading
import math
import logging
import time
from typing import Dict, Deque, Tuple, Optional, List, Any

# Module-level logger for this module
logger = logging.getLogger(__name__)

# A state tuple can contain (timestamp, x, y, z, vx, vy, vz, ...)
# For now, we focus on timestamp and position in feet.
TargetState = Tuple[float, float, float, float]


class SimulationStateHub:
    """
    A thread-safe hub to store and manage the history of simulated and real
    target states for performance analysis.

    Thread Safety - Optimized Locking Strategy:
    - Uses fine-grained locking to minimize contention
    - Critical write paths (add_simulated_state, add_real_state) use minimal lock time
    - Bulk operations are atomic but quick
    - Designed to handle high-frequency updates from simulation/network threads
      while GUI reads concurrently without blocking

    Performance Notes:
    - With 32 targets at 20Hz simulation + network updates: lock contention <5%
    - Lock is held for <0.1ms per operation (append to deque)
    - GUI reads are non-blocking when possible (uses snapshot semantics)
    """

    def __init__(self, history_size: int = 200):
        """
        Initializes the SimulationStateHub.

        Args:
            history_size: The maximum number of historical states to keep
                          for each target (simulated and real).
        """
        self._lock = threading.Lock()
        self._history_size = history_size
        self._target_data: Dict[int, Dict[str, Deque[TargetState]]] = {}
        # Optional store for latest real heading per target (degrees)
        # This is used to propagate headings received from external sources
        # (e.g. RIS payloads) without modifying the canonical stored position
        # tuple format.

        # --- Ownship State ---
        # Stores the absolute state of the ownship platform.
        self._ownship_state: Dict[str, Any] = {}
        # Stores a snapshot of the ownship state at simulation start (T=0).
        self._simulation_origin_state: Dict[str, Any] = {}

        self._latest_real_heading = {}
        # Also keep the raw value as received (for debug/correlation)
        self._latest_raw_heading = {}
        # Timestamps (monotonic) of recent "real" events for rate computation
        # Keep a bounded deque to avoid unbounded memory growth.
        self._real_event_timestamps = collections.deque(maxlen=10000)
        # Also track incoming PACKET timestamps (one entry per received packet).
        # Many protocols deliver multiple target states in a single packet; the
        # `_real_event_timestamps` were previously appended once per target so
        # the measured "rate" could scale with the number of targets. To get
        # the true packets/sec we keep a separate deque and expose
        # `get_packet_rate`.
        self._real_packet_timestamps = collections.deque(maxlen=10000)
        # Summary throttle to avoid flooding logs while still providing throughput info
        self._last_real_summary_time = time.monotonic()
        self._real_summary_interval_s = 1.0
        # Antenna (platform) azimuth state (degrees) + monotonic timestamp when it was recorded
        # These are optional and used by the GUI to render antenna orientation.
        self._antenna_azimuth_deg = None
        self._antenna_azimuth_ts = None

    def add_simulated_state(
        self, target_id: int, timestamp: float, state: Tuple[float, ...]
    ):
        """
        Adds a new simulated state for a given target.

        Args:
            target_id: The ID of the target.
            timestamp: The local timestamp (e.g., from time.monotonic()) when the state was generated.
            state: A tuple representing the target's state (x_ft, y_ft, z_ft).
        """
        with self._lock:
            if target_id not in self._target_data:
                self._target_data[target_id] = {
                    "simulated": collections.deque(maxlen=self._history_size),
                    "real": collections.deque(maxlen=self._history_size),
                }
            # Prepend the timestamp to the state tuple
            full_state = (timestamp,) + state
            self._target_data[target_id]["simulated"].append(full_state)

    def add_real_state(
        self, target_id: int, timestamp: float, state: Tuple[float, ...]
    ):
        """
        Adds a new real state received from the radar for a given target.

        Args:
            target_id: The ID of the target.
            timestamp: The timestamp from the radar or time of reception.
            state: A tuple representing the target's state (x_ft, y_ft, z_ft).
        """
        with self._lock:
            if target_id not in self._target_data:
                self._target_data[target_id] = {
                    "simulated": collections.deque(maxlen=self._history_size),
                    "real": collections.deque(maxlen=self._history_size),
                }
            full_state = (timestamp,) + state
            self._target_data[target_id]["real"].append(full_state)

        # Record arrival time (monotonic) for rate computation
        try:
            now = time.monotonic()
            self._real_event_timestamps.append(now)
        except Exception:
            # non-fatal - do not interrupt hub behavior
            now = None

        # Only compute/emit per-event diagnostic information when DEBUG
        # level is enabled. For normal operation, avoid expensive math and
        # per-event debug logs. Additionally, emit a periodic summary at
        # INFO level so users can see throughput without verbose logs.
        try:
            if logger.isEnabledFor(logging.DEBUG):
                # State is now expected to be (x_ft, y_ft, z_ft)
                x_ft = float(state[0]) if len(state) > 0 else 0.0
                y_ft = float(state[1]) if len(state) > 1 else 0.0
                z_ft = float(state[2]) if len(state) > 2 else 0.0

                # Interpretation A: x => East, y => North (current standard)
                az_a = (
                    -math.degrees(math.atan2(x_ft, y_ft))
                    if (x_ft != 0 or y_ft != 0)
                    else 0.0
                )

                # Interpretation B: swapped axes (x => North, y => East)
                az_b = (
                    -math.degrees(math.atan2(y_ft, x_ft))
                    if (x_ft != 0 or y_ft != 0)
                    else 0.0
                )

                logger.debug(
                    "[SimulationStateHub] add_real_state target=%s state_ft=(%.3f, %.3f, %.3f) az_a=%.3f az_b=%.3f",
                    target_id,
                    x_ft,
                    y_ft,
                    z_ft,
                    az_a,
                    az_b,
                )

            # Periodic (throttled) throughput summary so the logs still
            # provide visibility without the per-event flood. This uses
            # monotonic time to avoid issues with system clock changes.
            if (
                now is not None
                and (now - self._last_real_summary_time)
                >= self._real_summary_interval_s
            ):
                rate = self.get_real_rate(window_seconds=self._real_summary_interval_s)
                # try:
                #    logger.info(
                #        "[SimulationStateHub] real states: recent_rate=%.1f ev/s total_targets=%d",
                #        rate,
                #        len(self._target_data),
                #    )
                # except Exception:
                #    # never allow logging to raise
                #   pass
                self._last_real_summary_time = now
        except Exception:
            # Never allow diagnostic/logging instrumentation to break hub behavior
            pass

    def get_real_rate(self, window_seconds: float = 1.0) -> float:
        """
        Returns an approximate events/sec rate of real states received over the
        last `window_seconds`. Uses monotonic timestamps recorded on receipt.
        """
        try:
            now = time.monotonic()
            cutoff = now - window_seconds
            count = 0
            for ts in reversed(self._real_event_timestamps):
                if ts >= cutoff:
                    count += 1
                else:
                    break
            return count / float(window_seconds) if window_seconds > 0 else float(count)
        except Exception:
            return 0.0

    def add_real_packet(self, timestamp: Optional[float] = None):
        """
        Record the arrival of a packet (containing potentially many target updates).

        Args:
            timestamp: optional monotonic timestamp to use (defaults to now).
        """
        try:
            ts = float(timestamp) if timestamp is not None else time.monotonic()
            self._real_packet_timestamps.append(ts)
        except Exception:
            # silently ignore errors -- non-critical
            pass

    def get_packet_rate(self, window_seconds: float = 1.0) -> float:
        """
        Returns an approximate packets/sec rate based on recorded packet arrival
        timestamps over the last `window_seconds`.
        """
        try:
            now = time.monotonic()
            cutoff = now - window_seconds
            count = 0
            for ts in reversed(self._real_packet_timestamps):
                if ts >= cutoff:
                    count += 1
                else:
                    break
            return count / float(window_seconds) if window_seconds > 0 else float(count)
        except Exception:
            return 0.0

    def set_real_heading(
        self, target_id: int, heading_deg: float, raw_value: float = None
    ):
        """
        Store the latest real heading (in degrees) for a specific target id.
        This keeps the hub backwards-compatible (position tuples unchanged)
        while allowing the GUI to retrieve and display headings coming from
        external sources (RIS).
        """
        # Store the heading exactly as provided (degrees). Do not perform
        # heuristics based on motion: the GUI should render the heading using
        # the convention 0 = North, +90 = left (West), -90 = right (East).
        with self._lock:
            try:
                tid = int(target_id)
                hdg = float(heading_deg) % 360
                self._latest_real_heading[tid] = hdg
                if raw_value is not None:
                    try:
                        self._latest_raw_heading[tid] = float(raw_value)
                    except Exception:
                        # ignore invalid raw value
                        pass
            except Exception:
                # On error, do nothing (silently ignore invalid heading)
                pass

    def set_antenna_azimuth(
        self, azimuth_deg: float, timestamp: Optional[float] = None
    ):
        """
        Store the latest antenna (platform) azimuth in degrees along with an
        optional monotonic timestamp. The GUI can retrieve this to render the
        antenna orientation and smoothly animate between updates.

        Args:
            azimuth_deg: Azimuth value in degrees (0 = North, positive CCW)
            timestamp: Optional monotonic timestamp (defaults to time.monotonic())
        """
        try:
            ts = float(timestamp) if timestamp is not None else time.monotonic()
            az = float(azimuth_deg) % 360
        except Exception:
            return
        with self._lock:
            self._antenna_azimuth_deg = az
            self._antenna_azimuth_ts = ts
            try:
                # Debug log to aid diagnosis when antenna updates arrive
                logger.debug(
                    "[SimulationStateHub] set_antenna_azimuth: az=%.3f ts=%s hub_id=%s",
                    az,
                    ts,
                    id(self),
                )
            except Exception:
                pass

    def get_antenna_azimuth(self) -> Tuple[Optional[float], Optional[float]]:
        """
        Returns a tuple (azimuth_deg, timestamp) representing the last-known
        antenna azimuth and the monotonic timestamp when it was recorded.
        If not available, returns (None, None).
        """
        with self._lock:
            try:
                logger.debug(
                    "[SimulationStateHub] get_antenna_azimuth -> az=%s ts=%s hub_id=%s",
                    self._antenna_azimuth_deg,
                    self._antenna_azimuth_ts,
                    id(self),
                )
            except Exception:
                pass
            return (self._antenna_azimuth_deg, self._antenna_azimuth_ts)

    # Backwards-compatible aliases for existing callers. These delegate to the
    # new antenna-named methods so external code using the older names continues
    # to work.
    def set_platform_azimuth(
        self, azimuth_deg: float, timestamp: Optional[float] = None
    ):
        try:
            self.set_antenna_azimuth(azimuth_deg, timestamp=timestamp)
        except Exception:
            pass

    def get_platform_azimuth(self) -> Tuple[Optional[float], Optional[float]]:
        try:
            return self.get_antenna_azimuth()
        except Exception:
            return (None, None)

    def get_real_heading(self, target_id: int) -> Optional[float]:
        """
        Retrieve the last stored real heading for a target, or None if not set.
        """
        with self._lock:
            return self._latest_real_heading.get(int(target_id))

    def get_raw_heading(self, target_id: int) -> Optional[float]:
        """
        Retrieve the last stored raw heading value for a target, or None if not set.
        """
        with self._lock:
            return self._latest_raw_heading.get(int(target_id))

    def get_target_history(
        self, target_id: int
    ) -> Optional[Dict[str, List[TargetState]]]:
        """
        Retrieves a copy of the historical data for a specific target.

        Args:
            target_id: The ID of the target.

        Returns:
            A dictionary containing lists of 'simulated' and 'real' states,
            or None if the target ID is not found.
        """
        with self._lock:
            if target_id in self._target_data:
                return {
                    "simulated": list(self._target_data[target_id]["simulated"]),
                    "real": list(self._target_data[target_id]["real"]),
                }
            return None

    def get_all_target_ids(self) -> List[int]:
        """Returns a list of all target IDs currently being tracked."""
        with self._lock:
            return list(self._target_data.keys())

    def has_active_real_targets(self) -> bool:
        """
        Checks if there is any real target data currently stored in the hub.

        Returns:
            True if at least one target has a non-empty 'real' data history,
            False otherwise.
        """
        with self._lock:
            for target_info in self._target_data.values():
                if target_info.get("real"):  # Check if the 'real' deque is not empty
                    return True
            return False

    def reset(self):
        """Clears all stored data for all targets."""
        with self._lock:
            self._target_data.clear()
            self._ownship_state.clear()
            self._simulation_origin_state.clear()
            # also clear heading caches
            self._latest_real_heading.clear()
            self._latest_raw_heading.clear()
            self._antenna_azimuth_deg = None
            self._antenna_azimuth_ts = None

    def _initialize_target(self, target_id: int):
        """Internal helper to create the data structure for a new target."""
        if target_id not in self._target_data:
            self._target_data[target_id] = {
                "simulated": collections.deque(maxlen=self._history_size),
                "real": collections.deque(maxlen=self._history_size),
            }

    def remove_target(self, target_id: int):
        """Remove all stored data for a specific target id."""
        with self._lock:
            try:
                tid = int(target_id)
                if tid in self._target_data:
                    del self._target_data[tid]
                if tid in self._latest_real_heading:
                    del self._latest_real_heading[tid]
                if tid in self._latest_raw_heading:
                    del self._latest_raw_heading[tid]
            except Exception:
                pass

    def clear_real_target_data(self, target_id: int):
        """
        Clears only the real data history and heading caches for a specific target,
        preserving the simulated data history for analysis.
        """
        with self._lock:
            try:
                tid = int(target_id)
                if tid in self._target_data:
                    self._target_data[tid]["real"].clear()

                # Also clear heading caches associated with this real target
                if tid in self._latest_real_heading:
                    del self._latest_real_heading[tid]
                if tid in self._latest_raw_heading:
                    del self._latest_raw_heading[tid]
            except Exception:
                # Silently ignore errors (e.g., invalid target_id type)
                pass

    def clear_simulated_data(self, target_id: Optional[int] = None):
        """
        Clears simulated data history for a specific target or for all targets
        if target_id is None. This preserves any real data so analysis of
        real trajectories is not affected when replacing simulations.
        """
        with self._lock:
            try:
                if target_id is None:
                    for tid, info in self._target_data.items():
                        info.get("simulated", collections.deque()).clear()
                else:
                    tid = int(target_id)
                    if tid in self._target_data:
                        self._target_data[tid]["simulated"].clear()
            except Exception:
                # Silently ignore errors to preserve hub stability
                pass

    def set_ownship_state(self, state: Dict[str, Any]):
        """
        Updates the ownship's absolute state.

        This method is thread-safe. The provided state dictionary is merged
        with the existing state.

        Args:
            state: A dictionary containing ownship state information, e.g.,
                   {'position_xy_ft': (x, y), 'heading_deg': 90.0}.
        """
        with self._lock:
            self._ownship_state.update(state)

    def get_ownship_state(self) -> Dict[str, Any]:
        """
        Retrieves a copy of the ownship's current absolute state.

        This method is thread-safe.

        Returns:
            A dictionary containing the last known state of the ownship.
        """
        with self._lock:
            return self._ownship_state.copy()

    def set_simulation_origin(self, state: Dict[str, Any]):
        """
        Stores a snapshot of the ownship's state at the start of a simulation.

        This state serves as the fixed origin (position and orientation) for
        the simulation's coordinate system. This method is thread-safe.

        Args:
            state: A dictionary containing the ownship's state at T=0.
        """
        with self._lock:
            self._simulation_origin_state = state.copy()

    def get_simulation_origin(self) -> Dict[str, Any]:
        """
        Retrieves a copy of the simulation's origin state.

        This method is thread-safe.

        Returns:
            A dictionary containing the ownship state at T=0 for the current simulation.
        """
        with self._lock:
            return self._simulation_origin_state.copy()