nissefolk/src/systems/VillagerSystem.ts

import Phaser from 'phaser'
import { TILE_SIZE, VILLAGER_SPEED, VILLAGER_SPAWN_INTERVAL, VILLAGER_WORK_TIMES, VILLAGER_NAMES, WORLD_TILES } from '../config'
import { TileType, PLANTABLE_TILES } from '../types'
import type { VillagerState, VillagerJob, JobType, AIState, ItemId } from '../types'
import { stateManager } from '../StateManager'
import { findPath } from '../utils/pathfinding'
import type { LocalAdapter } from '../NetworkAdapter'
import type { WorldSystem } from './WorldSystem'
import type { ResourceSystem } from './ResourceSystem'
import type { FarmingSystem } from './FarmingSystem'

const ARRIVAL_PX = 3

const WORK_LOG_MAX = 20

interface VillagerRuntime {
  sprite: Phaser.GameObjects.Image
  nameLabel: Phaser.GameObjects.Text
  energyBar: Phaser.GameObjects.Graphics
  jobIcon: Phaser.GameObjects.Text
  path: Array<{ tileX: number; tileY: number }>
  destination: 'job' | 'stockpile' | 'bed' | null
  workTimer: number
  idleScanTimer: number
  /** Runtime-only activity log; not persisted. Max WORK_LOG_MAX entries. */
  workLog: string[]
}

export class VillagerSystem {
  private scene: Phaser.Scene
  private adapter: LocalAdapter
  private worldSystem: WorldSystem
  private resourceSystem!: ResourceSystem
  private farmingSystem!: FarmingSystem

  private runtime = new Map<string, VillagerRuntime>()
  private claimed = new Set<string>()   // target IDs currently claimed by a villager
  private spawnTimer = 0
  private nameIndex = 0

  onMessage?: (msg: string) => void
  onNisseClick?: (villagerId: string) => void
  /**
   * Called when a Nisse completes a forester planting job.
   * GameScene wires this to TreeSeedlingSystem.plantSeedling so that the
   * seedling sprite is spawned alongside the state action.
   */
  onPlantSeedling?: (tileX: number, tileY: number, tile: TileType) => void

  /**
   * @param scene        - The Phaser scene this system belongs to
   * @param adapter      - Network adapter for dispatching state actions
   * @param worldSystem  - Used for passability checks during pathfinding
   */
  constructor(scene: Phaser.Scene, adapter: LocalAdapter, worldSystem: WorldSystem) {
    this.scene = scene
    this.adapter = adapter
    this.worldSystem = worldSystem
  }

  /**
   * Wires in sibling systems that are not available at construction time.
   * Must be called before create().
   * @param resourceSystem - Used to remove harvested resource sprites
   * @param farmingSystem  - Used to remove harvested crop sprites
   */
  init(resourceSystem: ResourceSystem, farmingSystem: FarmingSystem): void {
    this.resourceSystem = resourceSystem
    this.farmingSystem  = farmingSystem
  }

  /**
   * Spawns sprites for all Nisse that exist in the saved state
   * and re-claims any active job targets.
   */
  create(): void {
    const state = stateManager.getState()
    for (const v of Object.values(state.world.villagers)) {
      this.spawnSprite(v)
      // Re-claim any active job targets
      if (v.job) this.claimed.add(v.job.targetId)
    }
  }

  /**
   * Advances the spawn timer and ticks every Nisse's AI.
   * @param delta - Frame delta in milliseconds
   */
  update(delta: number): void {
    this.spawnTimer += delta
    if (this.spawnTimer >= VILLAGER_SPAWN_INTERVAL) {
      this.spawnTimer = 0
      this.trySpawn()
    }

    const state = stateManager.getState()
    for (const v of Object.values(state.world.villagers)) {
      this.tickVillager(v, delta)
    }
  }

  // ─── Per-villager tick ────────────────────────────────────────────────────

  /**
   * Dispatches the correct AI tick method based on the villager's current state,
   * then syncs the sprite, name label, energy bar, and job icon to the state.
   * @param v     - Villager state from the store
   * @param delta - Frame delta in milliseconds
   */
  private tickVillager(v: VillagerState, delta: number): void {
    const rt = this.runtime.get(v.id)
    if (!rt) return

    switch (v.aiState as AIState) {
      case 'idle':    this.tickIdle(v, rt, delta);          break
      case 'walking': this.tickWalking(v, rt, delta);       break
      case 'working': this.tickWorking(v, rt, delta);       break
      case 'sleeping':this.tickSleeping(v, rt, delta);      break
    }

    // Sync sprite to state position
    rt.sprite.setPosition(v.x, v.y)
    rt.nameLabel.setPosition(v.x, v.y - 22)
    rt.energyBar.setPosition(0, 0)
    this.drawEnergyBar(rt.energyBar, v.x, v.y, v.energy)

    // Job icon
    const icons: Record<string, string> = { chop: '🪓', mine: '⛏', farm: '🌾', forester: '🌲', '': '' }
    const jobType = v.aiState === 'sleeping' ? '💤' : (v.job ? (icons[v.job.type] ?? '') : '')
    rt.jobIcon.setText(jobType).setPosition(v.x + 10, v.y - 18)
  }

  // ─── IDLE ─────────────────────────────────────────────────────────────────

  /**
   * Handles the idle AI state: hauls items to stockpile if carrying any,
   * seeks a bed if energy is low, otherwise picks the next job and begins walking.
   * Applies a cooldown before scanning again if no job is found.
   * @param v     - Villager state
   * @param rt    - Villager runtime (sprites, path, timers)
   * @param delta - Frame delta in milliseconds
   */
  private tickIdle(v: VillagerState, rt: VillagerRuntime, delta: number): void {
    // Decrement scan timer if cooling down
    if (rt.idleScanTimer > 0) {
      rt.idleScanTimer -= delta
      return
    }

    // Carrying items? → find stockpile
    if (v.job?.carrying && Object.values(v.job.carrying).some(n => (n ?? 0) > 0)) {
      const sp = this.nearestBuilding(v, 'stockpile_zone')
      if (sp) {
        this.addLog(v.id, '→ Hauling to stockpile')
        this.beginWalk(v, rt, sp.tileX, sp.tileY, 'stockpile')
        return
      }
    }

    // Low energy → find bed
    if (v.energy < 25) {
      const bed = this.findBed(v)
      if (bed) {
        this.addLog(v.id, '→ Going to sleep (low energy)')
        this.beginWalk(v, rt, bed.tileX, bed.tileY, 'bed')
        return
      }
    }

    // Find a job
    const job = this.pickJob(v)
    if (job) {
      this.claimed.add(job.targetId)
      this.adapter.send({
        type: 'VILLAGER_SET_JOB', villagerId: v.id,
        job: { type: job.type, targetId: job.targetId, tileX: job.tileX, tileY: job.tileY, carrying: {} },
      })
      this.addLog(v.id, `→ Walking to ${job.type} at (${job.tileX}, ${job.tileY})`)
      this.beginWalk(v, rt, job.tileX, job.tileY, 'job')
    } else {
      // No job available — wait before scanning again
      rt.idleScanTimer = 800 + Math.random() * 600
    }
  }

  // ─── WALKING ──────────────────────────────────────────────────────────────

  /**
   * Advances the Nisse along its path toward the current destination.
   * Calls onArrived when the path is exhausted.
   * Drains energy slowly while walking.
   * @param v     - Villager state
   * @param rt    - Villager runtime
   * @param delta - Frame delta in milliseconds
   */
  private tickWalking(v: VillagerState, rt: VillagerRuntime, delta: number): void {
    if (rt.path.length === 0) {
      this.onArrived(v, rt)
      return
    }

    const next = rt.path[0]
    const tx = (next.tileX + 0.5) * TILE_SIZE
    const ty = (next.tileY + 0.5) * TILE_SIZE
    const dx = tx - v.x
    const dy = ty - v.y
    const dist = Math.hypot(dx, dy)

    if (dist < ARRIVAL_PX) {
      ;(v as { x: number; y: number }).x = tx
      ;(v as { x: number; y: number }).y = ty
      rt.path.shift()
    } else {
      const step = Math.min(VILLAGER_SPEED * delta / 1000, dist)
      ;(v as { x: number; y: number }).x += (dx / dist) * step
      ;(v as { x: number; y: number }).y += (dy / dist) * step
      rt.sprite.setFlipX(dx < 0)
    }

    // Slowly drain energy while active
    ;(v as { energy: number }).energy = Math.max(0, v.energy - delta * 0.0015)
  }

  /**
   * Called when a Nisse reaches its destination tile.
   * Transitions to the appropriate next AI state based on destination type.
   * @param v  - Villager state
   * @param rt - Villager runtime
   */
  private onArrived(v: VillagerState, rt: VillagerRuntime): void {
    switch (rt.destination) {
      case 'job':
        rt.workTimer = VILLAGER_WORK_TIMES[v.job?.type ?? 'chop'] ?? 3000
        this.adapter.send({ type: 'VILLAGER_SET_AI', villagerId: v.id, aiState: 'working' })
        break

      case 'stockpile':
        this.adapter.send({ type: 'VILLAGER_DEPOSIT', villagerId: v.id })
        this.adapter.send({ type: 'VILLAGER_SET_AI', villagerId: v.id, aiState: 'idle' })
        rt.idleScanTimer = 0  // scan for a new job immediately after deposit
        this.addLog(v.id, '✓ Deposited at stockpile')
        break

      case 'bed':
        this.adapter.send({ type: 'VILLAGER_SET_AI', villagerId: v.id, aiState: 'sleeping' })
        this.addLog(v.id, '💤 Sleeping...')
        break

      default:
        this.adapter.send({ type: 'VILLAGER_SET_AI', villagerId: v.id, aiState: 'idle' })
    }
    rt.destination = null
  }

  // ─── WORKING ──────────────────────────────────────────────────────────────

  /**
   * Counts down the work timer and performs the harvest action on completion.
   * Handles chop, mine, and farm job types.
   * Returns the Nisse to idle when done.
   * @param v     - Villager state
   * @param rt    - Villager runtime
   * @param delta - Frame delta in milliseconds
   */
  private tickWorking(v: VillagerState, rt: VillagerRuntime, delta: number): void {
    rt.workTimer -= delta
    // Wobble while working
    rt.sprite.setAngle(Math.sin(Date.now() / 120) * 8)

    if (rt.workTimer > 0) return
    rt.sprite.setAngle(0)

    const job = v.job
    if (!job) { this.adapter.send({ type: 'VILLAGER_SET_AI', villagerId: v.id, aiState: 'idle' }); return }

    this.claimed.delete(job.targetId)
    const state = stateManager.getState()

    if (job.type === 'chop') {
      const res = state.world.resources[job.targetId]
      if (res) {
        this.adapter.send({ type: 'VILLAGER_HARVEST_RESOURCE', villagerId: v.id, resourceId: job.targetId })
        this.adapter.send({ type: 'CHANGE_TILE', tileX: res.tileX, tileY: res.tileY, tile: TileType.DARK_GRASS })
        this.adapter.send({ type: 'TILE_RECOVERY_START', tileX: res.tileX, tileY: res.tileY })
        this.worldSystem.removeResourceTile(res.tileX, res.tileY)
        this.resourceSystem.removeResource(job.targetId)
        // Chopping a tree yields 1–2 tree seeds in the stockpile
        const seeds = Math.random() < 0.5 ? 2 : 1
        this.adapter.send({ type: 'ADD_ITEMS', items: { tree_seed: seeds } })
        this.addLog(v.id, `✓ Chopped tree (+2 wood, +${seeds} tree seed)`)
      }
    } else if (job.type === 'mine') {
      const res = state.world.resources[job.targetId]
      if (res) {
        this.adapter.send({ type: 'VILLAGER_HARVEST_RESOURCE', villagerId: v.id, resourceId: job.targetId })
        this.adapter.send({ type: 'CHANGE_TILE', tileX: res.tileX, tileY: res.tileY, tile: TileType.GRASS })
        this.worldSystem.removeResourceTile(res.tileX, res.tileY)
        this.resourceSystem.removeResource(job.targetId)
        this.addLog(v.id, '✓ Mined rock (+2 stone)')
      }
    } else if (job.type === 'farm') {
      const crop = state.world.crops[job.targetId]
      if (crop) {
        this.adapter.send({ type: 'VILLAGER_HARVEST_CROP', villagerId: v.id, cropId: job.targetId })
        this.farmingSystem.removeCropSpritePublic(job.targetId)
        this.adapter.send({ type: 'CHANGE_TILE', tileX: crop.tileX, tileY: crop.tileY, tile: 9 as any })
        this.addLog(v.id, `✓ Farmed ${crop.kind}`)
      }
    } else if (job.type === 'forester') {
      // Verify the tile is still empty and the stockpile still has seeds
      const tileType = state.world.tiles[job.tileY * WORLD_TILES + job.tileX] as TileType
      const hasSeeds = (state.world.stockpile.tree_seed ?? 0) > 0
      const tileOccupied =
        Object.values(state.world.resources).some(r => r.tileX === job.tileX && r.tileY === job.tileY) ||
        Object.values(state.world.buildings).some(b => b.tileX === job.tileX && b.tileY === job.tileY) ||
        Object.values(state.world.crops).some(c => c.tileX === job.tileX && c.tileY === job.tileY) ||
        Object.values(state.world.treeSeedlings).some(s => s.tileX === job.tileX && s.tileY === job.tileY)

      if (hasSeeds && PLANTABLE_TILES.has(tileType) && !tileOccupied) {
        this.onPlantSeedling?.(job.tileX, job.tileY, tileType)
        this.addLog(v.id, `🌱 Planted seedling at (${job.tileX}, ${job.tileY})`)
      }
    }

    // If the harvest produced nothing (resource already gone), clear the stale job
    // so tickIdle does not try to walk to a stockpile with nothing to deposit.
    if (!v.job?.carrying || !Object.values(v.job.carrying).some(n => (n ?? 0) > 0)) {
      this.adapter.send({ type: 'VILLAGER_SET_JOB', villagerId: v.id, job: null })
    }

    // Back to idle — tickIdle will handle hauling to stockpile if carrying items
    this.adapter.send({ type: 'VILLAGER_SET_AI', villagerId: v.id, aiState: 'idle' })
  }

  // ─── SLEEPING ─────────────────────────────────────────────────────────────

  /**
   * Restores energy while sleeping. Returns to idle once energy is full.
   * @param v     - Villager state
   * @param rt    - Villager runtime
   * @param delta - Frame delta in milliseconds
   */
  private tickSleeping(v: VillagerState, rt: VillagerRuntime, delta: number): void {
    ;(v as { energy: number }).energy = Math.min(100, v.energy + delta * 0.04)
    // Gentle bob while sleeping
    rt.sprite.setAngle(Math.sin(Date.now() / 600) * 5)
    if (v.energy >= 100) {
      rt.sprite.setAngle(0)
      this.adapter.send({ type: 'VILLAGER_SET_AI', villagerId: v.id, aiState: 'idle' })
      this.addLog(v.id, '✓ Woke up (energy full)')
    }
  }

  // ─── Job picking (RimWorld-style priority) ────────────────────────────────

  /**
   * Selects the best available job for a Nisse based on their priority settings.
   * Among jobs at the same priority level, the closest one wins.
   * Returns null if no unclaimed job is available.
   * @param v - Villager state (used for position and priorities)
   * @returns The chosen job candidate, or null
   */
  /**
   * Selects the best available job for a Nisse based on their priority settings.
   * Among jobs at the same priority level, the closest one wins.
   * For chop jobs, trees within a forester zone are preferred over natural trees —
   * natural trees are only offered when no forester-zone trees are available.
   * Returns null if no unclaimed job is available.
   * @param v - Villager state (used for position and priorities)
   * @returns The chosen job candidate, or null
   */
  private pickJob(v: VillagerState): { type: JobType; targetId: string; tileX: number; tileY: number } | null {
    const state = stateManager.getState()
    const p     = v.priorities
    const vTX   = Math.floor(v.x / TILE_SIZE)
    const vTY   = Math.floor(v.y / TILE_SIZE)
    const dist  = (tx: number, ty: number) => Math.abs(tx - vTX) + Math.abs(ty - vTY)

    type C = { type: JobType; targetId: string; tileX: number; tileY: number; dist: number; pri: number }
    const candidates: C[] = []

    if (p.chop > 0) {
      // Build the set of all tiles belonging to forester zones for chop priority
      const zoneTiles = new Set<string>()
      for (const zone of Object.values(state.world.foresterZones)) {
        for (const key of zone.tiles) zoneTiles.add(key)
      }

      const zoneChop: C[]    = []
      const naturalChop: C[] = []

      for (const res of Object.values(state.world.resources)) {
        if (res.kind !== 'tree' || this.claimed.has(res.id)) continue
        // Skip trees with no reachable neighbour — A* cannot reach them.
        if (!this.hasAdjacentPassable(res.tileX, res.tileY)) continue
        const c: C = { type: 'chop', targetId: res.id, tileX: res.tileX, tileY: res.tileY, dist: dist(res.tileX, res.tileY), pri: p.chop }
        if (zoneTiles.has(`${res.tileX},${res.tileY}`)) {
          zoneChop.push(c)
        } else {
          naturalChop.push(c)
        }
      }
      // Prefer zone trees; fall back to natural only when no zone trees are reachable.
      candidates.push(...(zoneChop.length > 0 ? zoneChop : naturalChop))
    }

    if (p.mine > 0) {
      for (const res of Object.values(state.world.resources)) {
        if (res.kind !== 'rock' || this.claimed.has(res.id)) continue
        // Same reachability guard for rock tiles.
        if (!this.hasAdjacentPassable(res.tileX, res.tileY)) continue
        candidates.push({ type: 'mine', targetId: res.id, tileX: res.tileX, tileY: res.tileY, dist: dist(res.tileX, res.tileY), pri: p.mine })
      }
    }

    if (p.farm > 0) {
      for (const crop of Object.values(state.world.crops)) {
        if (crop.stage < crop.maxStage || this.claimed.has(crop.id)) continue
        candidates.push({ type: 'farm', targetId: crop.id, tileX: crop.tileX, tileY: crop.tileY, dist: dist(crop.tileX, crop.tileY), pri: p.farm })
      }
    }

    if (p.forester > 0 && (state.world.stockpile.tree_seed ?? 0) > 0) {
      // Find empty plantable zone tiles to seed
      for (const zone of Object.values(state.world.foresterZones)) {
        for (const key of zone.tiles) {
          const [tx, ty] = key.split(',').map(Number)
          const targetId = `forester_tile_${tx}_${ty}`
          if (this.claimed.has(targetId)) continue
          // Skip if tile is not plantable
          const tileType = state.world.tiles[ty * WORLD_TILES + tx] as TileType
          if (!PLANTABLE_TILES.has(tileType)) continue
          // Skip if something occupies this tile
          const occupied =
            Object.values(state.world.resources).some(r => r.tileX === tx && r.tileY === ty) ||
            Object.values(state.world.buildings).some(b => b.tileX === tx && b.tileY === ty) ||
            Object.values(state.world.crops).some(c => c.tileX === tx && c.tileY === ty) ||
            Object.values(state.world.treeSeedlings).some(s => s.tileX === tx && s.tileY === ty)
          if (occupied) continue
          candidates.push({ type: 'forester', targetId, tileX: tx, tileY: ty, dist: dist(tx, ty), pri: p.forester })
        }
      }
    }

    if (candidates.length === 0) return null

    // Lowest priority number wins; ties broken by distance
    const bestPri = Math.min(...candidates.map(c => c.pri))
    return candidates
      .filter(c => c.pri === bestPri)
      .sort((a, b) => a.dist - b.dist)[0] ?? null
  }

  // ─── Pathfinding ──────────────────────────────────────────────────────────

  /**
   * Computes a path from the Nisse's current tile to the target tile and
   * begins walking. If no path is found, the job is cleared and a cooldown applied.
   * @param v     - Villager state
   * @param rt    - Villager runtime
   * @param tileX - Target tile X
   * @param tileY - Target tile Y
   * @param dest  - Semantic destination type (used by onArrived)
   */
  private beginWalk(v: VillagerState, rt: VillagerRuntime, tileX: number, tileY: number, dest: VillagerRuntime['destination']): void {
    const sx = Math.floor(v.x / TILE_SIZE)
    const sy = Math.floor(v.y / TILE_SIZE)
    const path = findPath(sx, sy, tileX, tileY, (x, y) => this.worldSystem.isPassable(x, y), 700)

    if (!path) {
      if (v.job) {
        this.claimed.delete(v.job.targetId)
        this.adapter.send({ type: 'VILLAGER_SET_JOB', villagerId: v.id, job: null })
      }
      rt.idleScanTimer = 4000  // longer delay after failed pathfind to avoid tight retry loops
      return
    }

    rt.path        = path
    rt.destination = dest
    this.adapter.send({ type: 'VILLAGER_SET_AI', villagerId: v.id, aiState: 'walking' })
  }

  // ─── Building finders ─────────────────────────────────────────────────────

  /**
   * Returns the nearest building of the given kind to the Nisse, or null if none exist.
   * @param v    - Villager state (used as reference position)
   * @param kind - Building kind to search for
   */
  private nearestBuilding(v: VillagerState, kind: string): { tileX: number; tileY: number } | null {
    const state = stateManager.getState()
    const hits = Object.values(state.world.buildings).filter(b => b.kind === kind)
    if (hits.length === 0) return null
    const vx = v.x / TILE_SIZE
    const vy = v.y / TILE_SIZE
    return hits.sort((a, b) => Math.hypot(a.tileX - vx, a.tileY - vy) - Math.hypot(b.tileX - vx, b.tileY - vy))[0]
  }

  /**
   * Returns the Nisse's assigned bed if it still exists, otherwise the nearest bed.
   * Returns null if no beds are placed.
   * @param v - Villager state
   */
  private findBed(v: VillagerState): { id: string; tileX: number; tileY: number } | null {
    const state = stateManager.getState()
    // Prefer assigned bed
    if (v.bedId && state.world.buildings[v.bedId]) return state.world.buildings[v.bedId] as any
    return this.nearestBuilding(v, 'bed') as any
  }

  /**
   * Returns true if at least one of the 8 neighbours of the given tile is passable.
   * Used to pre-filter job targets that are fully enclosed by impassable terrain —
   * such as trees deep inside a dense forest cluster where A* can never reach the goal
   * tile because no passable tile is adjacent to it.
   * @param tileX - Target tile X
   * @param tileY - Target tile Y
   */
  private hasAdjacentPassable(tileX: number, tileY: number): boolean {
    const DIRS = [[1,0],[-1,0],[0,1],[0,-1],[1,1],[1,-1],[-1,1],[-1,-1]] as const
    for (const [dx, dy] of DIRS) {
      if (this.worldSystem.isPassable(tileX + dx, tileY + dy)) return true
    }
    return false
  }

  // ─── Spawning ─────────────────────────────────────────────────────────────

  /**
   * Attempts to spawn a new Nisse if a free bed is available and the
   * current population is below the bed count.
   */
  private trySpawn(): void {
    const state   = stateManager.getState()
    const beds    = Object.values(state.world.buildings).filter(b => b.kind === 'bed')
    const current = Object.keys(state.world.villagers).length
    if (current >= beds.length || beds.length === 0) return

    // Find a free bed (not assigned to any existing villager)
    const taken = new Set(Object.values(state.world.villagers).map(v => v.bedId))
    const freeBed = beds.find(b => !taken.has(b.id))
    if (!freeBed) return

    const name = VILLAGER_NAMES[this.nameIndex % VILLAGER_NAMES.length]
    this.nameIndex++

    const villager: VillagerState = {
      id:         `villager_${Date.now()}`,
      name,
      x:          (freeBed.tileX + 0.5) * TILE_SIZE,
      y:          (freeBed.tileY + 0.5) * TILE_SIZE,
      bedId:      freeBed.id,
      job:        null,
      priorities: { chop: 1, mine: 2, farm: 3, forester: 4 },
      energy:     100,
      aiState:    'idle',
    }

    this.adapter.send({ type: 'SPAWN_VILLAGER', villager })
    this.spawnSprite(villager)
    this.onMessage?.(`${name} the Nisse has arrived! 🏘`)
  }

  // ─── Sprite management ────────────────────────────────────────────────────

  /**
   * Creates and registers all runtime objects (sprite, label, energy bar, icon)
   * for a newly added Nisse.
   * @param v - Villager state to create sprites for
   */
  private spawnSprite(v: VillagerState): void {
    const sprite = this.scene.add.image(v.x, v.y, 'villager').setDepth(11)

    const nameLabel = this.scene.add.text(v.x, v.y - 22, v.name, {
      fontSize: '8px', color: '#ffffff', fontFamily: 'monospace',
      backgroundColor: '#00000088', padding: { x: 2, y: 1 },
    }).setOrigin(0.5, 1).setDepth(12)

    const energyBar = this.scene.add.graphics().setDepth(12)
    const jobIcon   = this.scene.add.text(v.x, v.y - 18, '', { fontSize: '10px' }).setDepth(13)

    sprite.setInteractive()
    sprite.on('pointerdown', () => this.onNisseClick?.(v.id))

    this.runtime.set(v.id, { sprite, nameLabel, energyBar, jobIcon, path: [], destination: null, workTimer: 0, idleScanTimer: 0, workLog: [] })
  }

  /**
   * Redraws the energy bar graphic for a Nisse at the given world position.
   * Color transitions green → orange → red as energy decreases.
   * @param g      - Graphics object to draw into
   * @param x      - World X center of the Nisse
   * @param y      - World Y center of the Nisse
   * @param energy - Current energy value (0–100)
   */
  private drawEnergyBar(g: Phaser.GameObjects.Graphics, x: number, y: number, energy: number): void {
    const W = 20, H = 3
    g.clear()
    g.fillStyle(0x222222); g.fillRect(x - W/2, y - 28, W, H)
    const col = energy > 60 ? 0x4CAF50 : energy > 30 ? 0xFF9800 : 0xF44336
    g.fillStyle(col);      g.fillRect(x - W/2, y - 28, W * (energy / 100), H)
  }

  // ─── Work log ─────────────────────────────────────────────────────────────

  /**
   * Prepends a message to the runtime work log for the given Nisse.
   * Trims the log to WORK_LOG_MAX entries. No-ops if the Nisse is not found.
   * @param villagerId - Target Nisse ID
   * @param msg        - Log message to prepend
   */
  private addLog(villagerId: string, msg: string): void {
    const rt = this.runtime.get(villagerId)
    if (!rt) return
    rt.workLog.unshift(msg)
    if (rt.workLog.length > WORK_LOG_MAX) rt.workLog.length = WORK_LOG_MAX
  }

  // ─── Public API ───────────────────────────────────────────────────────────

  /**
   * Returns a short human-readable status string for the given Nisse,
   * suitable for display in UI panels.
   * @param villagerId - The Nisse's ID
   * @returns Status string, or '—' if the Nisse is not found
   */
  getStatusText(villagerId: string): string {
    const v = stateManager.getState().world.villagers[villagerId]
    if (!v) return '—'
    if (v.aiState === 'sleeping') return '💤 Sleeping'
    if (v.aiState === 'working' && v.job) {
      const label = v.job.type === 'forester' ? 'planting' : `${v.job.type}ing`
      return `⚒ ${label}`
    }
    if (v.aiState === 'walking' && v.job) return `🚶 → ${v.job.type}`
    if (v.aiState === 'walking') return '🚶 Walking'
    const carrying = v.job?.carrying
    if (carrying && Object.values(carrying).some(n => (n ?? 0) > 0)) return '📦 Hauling'
    return '💭 Idle'
  }

  /**
   * Returns a copy of the runtime work log for the given Nisse (newest first).
   * @param villagerId - The Nisse's ID
   * @returns Array of log strings, or empty array if not found
   */
  getWorkLog(villagerId: string): string[] {
    return [...(this.runtime.get(villagerId)?.workLog ?? [])]
  }

  /**
   * Returns the current world position and remaining path for every Nisse
   * that is currently in the 'walking' state. Used by DebugSystem for
   * pathfinding visualization.
   * @returns Array of path entries, one per walking Nisse
   */
  getActivePaths(): Array<{ x: number; y: number; path: Array<{ tileX: number; tileY: number }> }> {
    const state = stateManager.getState()
    const result: Array<{ x: number; y: number; path: Array<{ tileX: number; tileY: number }> }> = []
    for (const v of Object.values(state.world.villagers)) {
      if (v.aiState !== 'walking') continue
      const rt = this.runtime.get(v.id)
      if (!rt) continue
      result.push({ x: v.x, y: v.y, path: [...rt.path] })
    }
    return result
  }

  /**
   * Destroys all Nisse sprites and clears the runtime map.
   * Should be called when the scene shuts down.
   */
  destroy(): void {
    for (const rt of this.runtime.values()) {
      rt.sprite.destroy(); rt.nameLabel.destroy()
      rt.energyBar.destroy(); rt.jobIcon.destroy()
    }
    this.runtime.clear()
  }
}