UnityTowerDefense/Assets/_Project/Scripts/Gameplay/PathfindingService.cs

// Assets/_Project/Scripts/Gameplay/PathfindingService.cs
using System.Collections.Generic;
using UnityEngine;
using TD.Core;
using TD.Levels;

namespace TD.Gameplay
{
    /// <summary>
    /// Scene singleton that computes shortest-path routes from any tile to the
    /// nearest goal tile using A* on the runtime walkability grid.
    /// </summary>
    /// <remarks>
    /// <b>Algorithm:</b> A* with Manhattan-distance heuristic. Grid cost is uniform
    /// (1 per step, 4-connected, no diagonals), so A* is optimal and significantly
    /// faster than plain BFS on large grids thanks to the heuristic.
    ///
    /// <b>Who calls this:</b>
    /// <list type="bullet">
    ///   <item><see cref="EnemyMovement"/> calls <see cref="ComputePath"/> once on
    ///         spawn and again whenever <see cref="OnPathsInvalidated"/> fires.</item>
    /// </list>
    ///
    /// <b>Invalidation:</b> Subscribes to <see cref="LevelLoader.OnWalkabilityChanged"/>.
    /// When a tower is placed or sold, <c>LevelLoader.SetWalkable</c> fires that event
    /// and <see cref="OnPathsInvalidated"/> is relayed to all active enemies, which
    /// each recompute their own path from their current tile.
    ///
    /// <b>Goal tile set:</b> Built once on <c>Start</c> from
    /// <c>LevelLoader.LevelData.Goals[].TileArea</c>. Goal tiles never change at
    /// runtime (they are baked into the level), so there is no need to rebuild the set.
    ///
    /// <b>No caching:</b> Paths are computed on demand per enemy. On typical TD grid
    /// sizes (50×50 or smaller) a single A* run takes &lt;1 ms. If profiling shows
    /// otherwise, add a per-startTile cache here.
    /// </remarks>
    public class PathfindingService : MonoBehaviour
    {
        // ----- Singleton --------------------------------------------------

        public static PathfindingService Instance { get; private set; }

        // ----- Events -----------------------------------------------------

        /// <summary>
        /// Fired on every peer when the walkability grid changes (tower placed/sold).
        /// <see cref="EnemyMovement"/> subscribes per-instance to recompute its path.
        /// </summary>
        public event System.Action OnPathsInvalidated;

        // ----- State ------------------------------------------------------

        // Built once on Start from LevelData.Goals[].TileArea.
        private HashSet<Vector2Int> goalTiles;

        // A* scratch collections — allocated once and cleared per run to avoid GC.
        // PathfindingService is a singleton, so single-instance scratch is safe.
        private readonly Dictionary<Vector2Int, Vector2Int>  cameFrom  = new Dictionary<Vector2Int, Vector2Int>();
        private readonly Dictionary<Vector2Int, int>         gScore    = new Dictionary<Vector2Int, int>();
        private readonly SimplePriorityQueue                  openSet   = new SimplePriorityQueue();

        // ----- Lifecycle --------------------------------------------------

        private void Awake()
        {
            if (Instance != null && Instance != this)
            {
                Debug.LogError("[PathfindingService] Duplicate instance detected. " +
                               "Only one PathfindingService should exist per scene.");
                Destroy(gameObject);
                return;
            }
            Instance = this;
        }

        private void Start()
        {
            BuildGoalTileSet();

            var loader = LevelLoader.Instance;
            if (loader != null)
                loader.OnWalkabilityChanged += HandleWalkabilityChanged;
            else
                Debug.LogWarning("[PathfindingService] LevelLoader not found in Start. " +
                                 "Path invalidation will not work.");
        }

        private void OnDestroy()
        {
            if (Instance == this) Instance = null;

            var loader = LevelLoader.Instance;
            if (loader != null)
                loader.OnWalkabilityChanged -= HandleWalkabilityChanged;
        }

        // ----- Public API -------------------------------------------------

        /// <summary>
        /// Computes the shortest walkable path from <paramref name="startTile"/> to
        /// the nearest goal tile. Returns an ordered list of tiles to visit, starting
        /// with the first step AFTER <paramref name="startTile"/> and ending with the
        /// reached goal tile. Returns an empty list if no path exists or LevelLoader
        /// is unavailable (should not occur — TowerPlacementManager guarantees a path
        /// always exists after any placement).
        /// </summary>
        public List<Vector2Int> ComputePath(Vector2Int startTile)
        {
            var loader = LevelLoader.Instance;
            if (loader == null || !loader.IsLoaded || goalTiles == null || goalTiles.Count == 0)
            {
                Debug.LogWarning("[PathfindingService] Cannot compute path: " +
                                 "LevelLoader unavailable or no goal tiles baked.");
                return new List<Vector2Int>();
            }

            return RunAStar(startTile, loader);
        }

        // ----- A* implementation ------------------------------------------

        private List<Vector2Int> RunAStar(Vector2Int start, LevelLoader loader)
        {
            cameFrom.Clear();
            gScore.Clear();
            openSet.Clear();

            gScore[start] = 0;
            openSet.Enqueue(start, Heuristic(start));

            while (openSet.Count > 0)
            {
                Vector2Int current = openSet.Dequeue();

                if (goalTiles.Contains(current))
                    return ReconstructPath(start, current);

                int currentG = gScore.TryGetValue(current, out int g) ? g : int.MaxValue;

                foreach (var neighbor in GridCoordinates.GetNeighbors(current))
                {
                    if (!loader.IsWalkable(neighbor)) continue;

                    int tentativeG = currentG + 1;
                    if (gScore.TryGetValue(neighbor, out int existingG)
                        && tentativeG >= existingG) continue;

                    cameFrom[neighbor] = current;
                    gScore[neighbor]   = tentativeG;
                    int f = tentativeG + Heuristic(neighbor);

                    // Re-enqueue with updated priority. SimplePriorityQueue handles
                    // duplicate entries by ignoring higher-cost duplicates on dequeue.
                    openSet.Enqueue(neighbor, f);
                }
            }

            // No path found — TowerPlacementManager should have prevented this.
            Debug.LogWarning($"[PathfindingService] A* found no path from {start}. " +
                             "Check that TowerPlacementManager BFS is validating correctly.");
            return new List<Vector2Int>();
        }

        // Manhattan distance to the nearest goal tile. Admissible heuristic for
        // a 4-connected uniform-cost grid.
        private int Heuristic(Vector2Int tile)
        {
            int best = int.MaxValue;
            foreach (var goal in goalTiles)
            {
                int d = GridCoordinates.ManhattanDistance(tile, goal);
                if (d < best) best = d;
            }
            return best;
        }

        private List<Vector2Int> ReconstructPath(Vector2Int start, Vector2Int goal)
        {
            var path = new List<Vector2Int>();
            Vector2Int current = goal;

            while (current != start)
            {
                path.Add(current);
                if (!cameFrom.TryGetValue(current, out current))
                    break; // shouldn't happen
            }

            path.Reverse();
            return path;
        }

        // ----- Helpers ----------------------------------------------------

        private void BuildGoalTileSet()
        {
            goalTiles = new HashSet<Vector2Int>();
            var loader = LevelLoader.Instance;
            if (loader == null || loader.LevelData == null || loader.LevelData.Goals == null)
            {
                Debug.LogWarning("[PathfindingService] No LevelData or Goals found. " +
                                 "Enemies will have no destination.");
                return;
            }

            foreach (var goal in loader.LevelData.Goals)
            {
                if (goal.TileArea == null) continue;
                foreach (var tile in goal.TileArea)
                    goalTiles.Add(tile);
            }

            Debug.Log($"[PathfindingService] Goal tile set built: {goalTiles.Count} tiles.");
        }

        private void HandleWalkabilityChanged()
        {
            OnPathsInvalidated?.Invoke();
        }
    }

    // -------------------------------------------------------------------------
    // Minimal priority queue for A*. Uses a sorted list of (priority, tile) pairs.
    // Suitable for the grid sizes in this project (typically < 10,000 tiles).
    // Replace with a binary heap if profiling shows this as a bottleneck.
    // -------------------------------------------------------------------------
    internal sealed class SimplePriorityQueue
    {
        private readonly List<(int priority, Vector2Int tile)> heap
            = new List<(int, Vector2Int)>();

        public int Count => heap.Count;

        public void Clear() => heap.Clear();

        public void Enqueue(Vector2Int tile, int priority)
        {
            heap.Add((priority, tile));
            SiftUp(heap.Count - 1);
        }

        public Vector2Int Dequeue()
        {
            Vector2Int result = heap[0].tile;
            int last = heap.Count - 1;
            heap[0] = heap[last];
            heap.RemoveAt(last);
            if (heap.Count > 0) SiftDown(0);
            return result;
        }

        private void SiftUp(int i)
        {
            while (i > 0)
            {
                int parent = (i - 1) / 2;
                if (heap[parent].priority <= heap[i].priority) break;
                (heap[i], heap[parent]) = (heap[parent], heap[i]);
                i = parent;
            }
        }

        private void SiftDown(int i)
        {
            int count = heap.Count;
            while (true)
            {
                int smallest = i;
                int left  = 2 * i + 1;
                int right = 2 * i + 2;
                if (left  < count && heap[left].priority  < heap[smallest].priority) smallest = left;
                if (right < count && heap[right].priority < heap[smallest].priority) smallest = right;
                if (smallest == i) break;
                (heap[i], heap[smallest]) = (heap[smallest], heap[i]);
                i = smallest;
            }
        }
    }
}