S1005403_RisCC/target_simulator/gui/ppi_display.py

# target_simulator/gui/ppi_display.py

"""
A reusable Tkinter widget that displays a Plan Position Indicator (PPI)
using Matplotlib, capable of showing both live targets and trajectory previews,
and comparing simulated vs. real-time data.
"""

import tkinter as tk
from tkinter import ttk
import math
import numpy as np
import collections
from matplotlib.figure import Figure
from matplotlib.backends.backend_tkagg import FigureCanvasTkAgg
from typing import List, Dict, Union

# Use absolute imports
from target_simulator.core.models import Target, Waypoint, ManeuverType, NM_TO_FT


class PPIDisplay(ttk.Frame):
    """
    A custom widget for the PPI radar display, capable of showing simulated
    data, real-time feedback, and trajectory previews.
    """
    TRAIL_LENGTH = 100  # Number of historical points to show in a target's trail

    def __init__(self, master, max_range_nm: int = 100, scan_limit_deg: int = 60):
        super().__init__(master)
        self.max_range = max_range_nm
        self.scan_limit_deg = scan_limit_deg

        # Artists for dynamic target display
        self.sim_target_artists = []
        self.real_target_artists = []
        self.sim_trail_artists = []
        self.real_trail_artists = []
        self.target_label_artists = []

        # Data store for target trails
        self._trails = {
            "simulated": collections.defaultdict(lambda: collections.deque(maxlen=self.TRAIL_LENGTH)),
            "real": collections.defaultdict(lambda: collections.deque(maxlen=self.TRAIL_LENGTH))
        }

        # Artists for trajectory preview
        self.preview_artists = []

        # --- UI Visibility Controls ---
        self.show_sim_points_var = tk.BooleanVar(value=True)
        self.show_real_points_var = tk.BooleanVar(value=True)
        self.show_sim_trail_var = tk.BooleanVar(value=False)
        self.show_real_trail_var = tk.BooleanVar(value=True)

        self._create_controls()
        self._create_plot()

    def _create_controls(self):
        """Creates the control widgets for the PPI display."""
        top_frame = ttk.Frame(self)
        top_frame.pack(side=tk.TOP, fill=tk.X, padx=5, pady=5)
        
        self.controls_frame = ttk.Frame(top_frame)
        self.controls_frame.pack(side=tk.LEFT, fill=tk.X, expand=True)

        ttk.Label(self.controls_frame, text="Range (NM):").pack(side=tk.LEFT)

        all_steps = [10, 20, 40, 80, 100, 160, 240, 320]
        valid_steps = sorted([s for s in all_steps if s <= self.max_range])
        if not valid_steps or self.max_range not in valid_steps:
            valid_steps.append(self.max_range)
            valid_steps.sort()

        self.range_var = tk.IntVar(value=self.max_range)
        self.range_selector = ttk.Combobox(
            self.controls_frame, textvariable=self.range_var,
            values=valid_steps, state="readonly", width=5
        )
        self.range_selector.pack(side=tk.LEFT, padx=5)
        self.range_selector.bind("<<ComboboxSelected>>", self._on_range_selected)
        
        # --- Display Options ---
        options_frame = ttk.LabelFrame(top_frame, text="Display Options")
        options_frame.pack(side=tk.RIGHT, padx=(10, 0))

        cb_sim_points = ttk.Checkbutton(options_frame, text="Sim Points", variable=self.show_sim_points_var, command=lambda: self.canvas.draw_idle())
        cb_sim_points.grid(row=0, column=0, sticky='w', padx=5)
        cb_real_points = ttk.Checkbutton(options_frame, text="Real Points", variable=self.show_real_points_var, command=lambda: self.canvas.draw_idle())
        cb_real_points.grid(row=0, column=1, sticky='w', padx=5)
        cb_sim_trail = ttk.Checkbutton(options_frame, text="Sim Trail", variable=self.show_sim_trail_var, command=lambda: self.canvas.draw_idle())
        cb_sim_trail.grid(row=1, column=0, sticky='w', padx=5)
        cb_real_trail = ttk.Checkbutton(options_frame, text="Real Trail", variable=self.show_real_trail_var, command=lambda: self.canvas.draw_idle())
        cb_real_trail.grid(row=1, column=1, sticky='w', padx=5)
        # --- Legend ---
        legend_frame = ttk.Frame(top_frame)
        legend_frame.pack(side=tk.RIGHT, padx=(10, 5))

        # Small colored swatches for simulated/real
        sim_sw = tk.Canvas(legend_frame, width=16, height=12, highlightthickness=0)
        sim_sw.create_rectangle(0, 0, 16, 12, fill='green', outline='black')
        sim_sw.pack(side=tk.LEFT, padx=(0, 4))
        ttk.Label(legend_frame, text="Simulated").pack(side=tk.LEFT, padx=(0, 8))

        real_sw = tk.Canvas(legend_frame, width=16, height=12, highlightthickness=0)
        real_sw.create_rectangle(0, 0, 16, 12, fill='red', outline='black')
        real_sw.pack(side=tk.LEFT, padx=(2, 4))
        ttk.Label(legend_frame, text="Real").pack(side=tk.LEFT)

    def _create_plot(self):
        """Initializes the Matplotlib polar plot."""
        fig = Figure(figsize=(5, 5), dpi=100, facecolor="#3E3E3E")
        fig.subplots_adjust(left=0.05, right=0.95, top=0.9, bottom=0.05)

        self.ax = fig.add_subplot(111, projection="polar", facecolor="#2E2E2E")

        # Set zero at North (top) and theta direction to counter-clockwise (standard)
        self.ax.set_theta_zero_location("N")
        self.ax.set_theta_direction(1) # POSITIVO = ANTI-ORARIO (CCW)
        
        self.ax.set_rlabel_position(90)
        self.ax.set_ylim(0, self.range_var.get())

        # Set angular grid labels to be [-180, 180] with North at 0
        angles_deg = np.arange(0, 360, 30)
        labels = []
        for angle in angles_deg:
            # Convert angle from CCW-from-East to CW-from-North for display label
            display_angle = (450 - angle) % 360 
            if display_angle > 180:
                display_angle -= 360
            labels.append(f'{-display_angle}°') # Invert sign to match CW convention

        self.ax.set_thetagrids(angles_deg, labels)


        self.ax.tick_params(axis="x", colors="white", labelsize=8)
        self.ax.tick_params(axis="y", colors="white", labelsize=8)
        self.ax.grid(color="white", linestyle="--", linewidth=0.5, alpha=0.5)
        self.ax.spines["polar"].set_color("white")
        self.ax.set_title("PPI Display", color="white")
        
        # ... (il resto del metodo è corretto) ...

        (self._path_plot,) = self.ax.plot([], [], "g--", linewidth=1.5, label="Path")
        (self._start_plot,) = self.ax.plot([], [], "go", markersize=8, label="Start")
        (self._waypoints_plot,) = self.ax.plot([], [], "y+", markersize=10, mew=2, label="Waypoints")
        self.preview_artists = [self._path_plot, self._start_plot, self._waypoints_plot]

        limit_rad = np.deg2rad(self.scan_limit_deg)
        (self._scan_line_1,) = self.ax.plot([limit_rad, limit_rad], [0, self.max_range], color="yellow", linestyle="--", linewidth=1)
        (self._scan_line_2,) = self.ax.plot([-limit_rad, -limit_rad], [0, self.max_range], color="yellow", linestyle="--", linewidth=1)

        self.canvas = FigureCanvasTkAgg(fig, master=self)
        self.canvas.draw()
        self.canvas.get_tk_widget().pack(side=tk.TOP, fill=tk.BOTH, expand=True)
        self._update_scan_lines()

    def update_targets(self, targets_data: Union[List[Target], Dict[str, List[Target]]]):
        """
        Updates the display with the current state of targets.
        This method is backward compatible. It can accept:
        1. A simple List[Target] (for previews and simple display).
        2. A Dict{'simulated': [...], 'real': [...]} for comparative display.
        """
        sim_targets: List[Target] = []
        real_targets: List[Target] = []

        if isinstance(targets_data, list):
            sim_targets = [t for t in targets_data if t.active]
        elif isinstance(targets_data, dict):
            sim_targets = [t for t in targets_data.get("simulated", []) if t.active]
            real_targets = [t for t in targets_data.get("real", []) if t.active]

        # --- Clear all previous dynamic artists ---
        for artist_list in [self.sim_target_artists, self.real_target_artists,
                              self.sim_trail_artists, self.real_trail_artists,
                              self.target_label_artists]:
            for artist in artist_list:
                artist.remove()
            artist_list.clear()
        
        # --- Update trail history ---
        for target in sim_targets:
            pos = (np.deg2rad(target.current_azimuth_deg), target.current_range_nm)
            self._trails["simulated"][target.target_id].append(pos)
        
        for target in real_targets:
            pos = (np.deg2rad(target.current_azimuth_deg), target.current_range_nm)
            self._trails["real"][target.target_id].append(pos)
            
        # --- Redraw artists based on visibility settings ---
        if self.show_sim_points_var.get():
            self._draw_target_visuals(sim_targets, 'green', self.sim_target_artists)
        
        if self.show_real_points_var.get():
            self._draw_target_visuals(real_targets, 'red', self.real_target_artists)

        if self.show_sim_trail_var.get():
            self._draw_trails(self._trails["simulated"], 'limegreen', self.sim_trail_artists)

        if self.show_real_trail_var.get():
            self._draw_trails(self._trails["real"], 'tomato', self.real_trail_artists)

        self.canvas.draw_idle()

    def _draw_target_visuals(self, targets: List[Target], color: str, artist_list: List):
        """Helper to draw dots and vectors for a list of targets."""
        vector_len_nm = self.range_var.get() / 20.0
        
        for target in targets:
            r_nm = target.current_range_nm
            theta_rad = np.deg2rad(target.current_azimuth_deg)

            (dot,) = self.ax.plot(theta_rad, r_nm, "o", markersize=6, color=color)
            artist_list.append(dot)

            heading_rad = np.deg2rad(target.current_heading_deg)
            x_nm = r_nm * np.sin(theta_rad)
            y_nm = r_nm * np.cos(theta_rad)
            dx_nm = vector_len_nm * np.sin(heading_rad)
            dy_nm = vector_len_nm * np.cos(heading_rad)
            r2_nm = math.sqrt((x_nm + dx_nm)**2 + (y_nm + dy_nm)**2)
            theta2_rad = math.atan2(x_nm + dx_nm, y_nm + dy_nm)
            
            (line,) = self.ax.plot([theta_rad, theta2_rad], [r_nm, r2_nm], color=color, linewidth=1.2)
            artist_list.append(line)
            
            label_r = r_nm + (vector_len_nm * 0.5)
            txt = self.ax.text(theta_rad, label_r, str(target.target_id), color="white", fontsize=8, ha="center", va="bottom")
            self.target_label_artists.append(txt)

    def _draw_trails(self, trail_data: Dict, color: str, artist_list: List):
        """Helper to draw historical trails for targets."""
        for target_id in trail_data:
            trail = trail_data[target_id]
            if len(trail) > 1:
                thetas, rs = zip(*trail)
                (line,) = self.ax.plot(thetas, rs, color=color, linestyle='-', linewidth=0.8, alpha=0.7)
                artist_list.append(line)

    def clear_trails(self):
        """Clears the historical data for all target trails."""
        self._trails["simulated"].clear()
        self._trails["real"].clear()
        self.update_targets({}) # Trigger a redraw to clear visuals

    # --- Other methods remain unchanged ---
    def _update_scan_lines(self):
        current_range_max = self.ax.get_ylim()[1]
        limit_rad = np.deg2rad(self.scan_limit_deg)
        self._scan_line_1.set_data([limit_rad, limit_rad], [0, current_range_max])
        self._scan_line_2.set_data([-limit_rad, -limit_rad], [0, current_range_max])

    def _on_range_selected(self, event=None):
        new_range = self.range_var.get()
        self.ax.set_ylim(0, new_range)
        self._update_scan_lines()
        self.canvas.draw_idle()

    def clear_previews(self):
        for artist in self.preview_artists:
            artist.set_data([], [])
        self.canvas.draw_idle()
        
    def draw_trajectory_preview(self, waypoints: List[Waypoint], use_spline: bool):
        self.clear_previews()
        self.clear_trails()
        if not waypoints or waypoints[0].maneuver_type != ManeuverType.FLY_TO_POINT:
            return
        path, _ = Target.generate_path_from_waypoints(waypoints, use_spline)
        if not path:
            return
        path_thetas, path_rs = [], []
        for point in path:
            _time, x_ft, y_ft, _z_ft = point
            r_ft = math.sqrt(x_ft**2 + y_ft**2)
            theta_rad = math.atan2(x_ft, y_ft)
            path_rs.append(r_ft / NM_TO_FT)
            path_thetas.append(theta_rad)
        self._path_plot.set_data(path_thetas, path_rs)
        
        wp_thetas, wp_rs = [], []
        for wp in waypoints:
            if wp.maneuver_type == ManeuverType.FLY_TO_POINT:
                r_nm = wp.target_range_nm or 0.0
                theta_rad = math.radians(wp.target_azimuth_deg or 0.0)
                wp_rs.append(r_nm)
                wp_thetas.append(theta_rad)
        self._waypoints_plot.set_data(wp_thetas, wp_rs)

        start_wp = waypoints[0]
        start_r = start_wp.target_range_nm or 0.0
        start_theta = math.radians(start_wp.target_azimuth_deg or 0.0)
        self._start_plot.set_data([start_theta], [start_r])
        self.canvas.draw_idle()

    def reconfigure_radar(self, max_range_nm: int, scan_limit_deg: int):
        self.max_range = max_range_nm
        self.scan_limit_deg = scan_limit_deg
        steps = [10, 20, 40, 80, 100, 160, 240, 320]
        valid_steps = sorted([s for s in steps if s <= self.max_range])
        if not valid_steps or self.max_range not in valid_steps:
            valid_steps.append(self.max_range)
            valid_steps.sort()
        current_range = self.range_var.get()
        self.range_selector["values"] = valid_steps
        if current_range in valid_steps:
            self.range_var.set(current_range)
        else:
            self.range_var.set(self.max_range)
        self._on_range_selected()