megaproxy
91bceeebe8
Three gdscript-refactor agents in parallel + Opus integration.
Entities (scenes/entities/, Agent A — 3 scripts + 3 .tscn, ~460 lines):
- item.gd: 16-type StringName registry (matches design.md filter chips);
Node2D + _draw() colored square + stack-count badge; to_dict/from_dict
- tree.gd: class_name HarvestableTree (Godot 4 ships a built-in 'Tree'
Control class — renamed to avoid the shadow); CHOP_TICKS=80; on_chop_tick
advances progress, fells when complete, drops 3 wood items at tile +
walkable neighbours
- rock.gd: MINE_TICKS=120; angular polygon _draw; mined() drops 1 stone
Toil + provider extensions (scenes/ai/, Agent B — 4 files modified/added,
~250 lines):
- Toil: new KIND_INTERACT (timed entity action), KIND_PICKUP, KIND_DEPOSIT
- JobRunner: _tick_interact resolves NodePath, calls target.<method>()
each tick, marks done when is_choppable/is_mineable returns false;
_tick_pickup finds Item at pawn.tile, transfers to pawn.carried_item;
_tick_deposit places carried_item at pawn.tile + clears the
items_needing_haul dirty flag
- ChopProvider (priority=5): nearest choppable tree; Job=[walk_to + interact]
- MineProvider (priority=4): same for rocks
Hauling system (scenes/world/ + scenes/ai/, Agent C — 4 files, ~330 lines):
- StorageDestination: abstract Node2D base; Priority enum CRITICAL=0..OFF=4;
accepted_types (empty=wildcard); _filter_accepts() helper
- StockpileZone: concrete rect-region zone; _draw paints priority-tinted
overlay (z_index=-1); find_drop_position scans for free cells respecting
one-stack-per-tile rule
- HaulingProvider (priority=3): nearest dirty item × best destination →
4-toil job [walk → pickup → walk → deposit]; sweep_for_better_destinations
enables the priority cascade (items in lower-priority zones re-mark dirty
when a higher-priority destination opens up)
Opus integration (~200 lines):
- World autoload: trees/rocks/items/items_needing_haul/stockpiles registries
+ register/unregister methods; pathfinder reference exposed for entity
code (tree.fell needs is_walkable for neighbour drops)
- Pawn: carried_item slot + carry-indicator (small colored rect upper-right
of body) via queue_redraw in _on_sim_tick
- World scene: registers chop/mine/haul/rest providers; spawns 6 trees
(cluster east-north), 4 rocks (south-east), 2 stockpile zones (Zone A
wood-only NORMAL, Zone B wildcard HIGH); periodic
hauling_provider.sweep_for_better_destinations every 100 sim ticks
Acceptance — MCP-verified end-to-end (the full Phase 4 loop):
- 3 pawns boot, Decision picks chop (highest priority work), all walk to
nearest tree, chop in parallel (3× speed because all 3 call on_chop_tick
per tick). Trees fell, drop wood (18 items). Pawns move to rocks, mine,
drop stone (4 items). Total 22 items spawn.
- HaulingProvider routes wood + stone toward Zone B (wildcard HIGH > Zone
A's wood-only NORMAL). Pawns carry items one at a time, visual indicator
shows during transit. Items deposit, items_needing_haul dirty flag
clears.
- **Priority cascade test:** Zone A promoted from NORMAL to CRITICAL.
Manually-triggered sweep marks 3 wood items in Zone B for re-haul.
Within a few thousand ticks: Zone A has 5 wood (cascaded from Zone B),
Zone B has 4 stone only (wood left, stone stayed because Zone A rejects
stone). Filter + priority cascade working exactly per design.md spec.
Phase 4 gotchas (logged in implementation.md):
- 'Tree' shadows Godot 4's built-in Tree Control class — class_name had to
be renamed to HarvestableTree. Scene/file names stayed as 'tree' since
the game concept is still 'tree'; the rename only affects code-side
type references.
- draw_colored_polygon(points, color) takes a SINGLE Color, not a
PackedColorArray. Agent C had to be reminded; draw_polygon(points, colors)
is the variant that takes per-vertex colors.
- Godot's class-name cache lags behind file changes — a full editor scan
('godot --headless --editor --quit') is needed to flush. Even after
reload_project, type-annotation assignments can fail; duck-typed
variables ('var x = scene.instantiate()') sidestep the issue.
- JobRunner's _tick_deposit had to explicitly call
World.clear_item_haul_flag — the dirty set persisted otherwise and
items appeared 'needing haul' even after deposit.
Delegation report this phase:
- Agent A (Sonnet, gdscript-refactor): Tree + Rock + Item entities + i18n
keys. ~460 lines.
- Agent B (Sonnet, gdscript-refactor): Toil extensions + JobRunner handlers
+ ChopProvider + MineProvider. ~250 lines.
- Agent C (Sonnet, gdscript-refactor): StorageDestination + StockpileZone
+ HaulingProvider with cascade sweep. ~330 lines.
- Opus: World autoload extensions (entity registries + pathfinder ref),
Pawn carry slot + visual, world.tscn/gd wiring, the Tree rename, the
draw_colored_polygon fix, the dirty-set-clear fix, MCP-driven runtime
verification including the full chop-mine-haul loop and the priority
cascade demo.
~75% of Phase 4's GDScript was subagent-authored.
Co-Authored-By: Claude Opus 4.7 (1M context) <noreply@anthropic.com>
120 lines
3.5 KiB
GDScript
120 lines
3.5 KiB
GDScript
extends Node
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## Runtime entity registry + tile-related sim state.
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##
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## All gameplay entities (pawns, items, furniture, animals, corpses) live here.
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## TileMap data is owned by the world-view scene; World holds the *indirect*
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## state (designation queue, dirty-haul set, zone records, etc.) that doesn't
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## belong on the TileMap itself.
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##
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## See docs/architecture.md.
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# Phase 2 — pawn registry. items/furniture/animals/corpses arrive in later phases.
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var pawns: Array[Pawn] = []
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# Phase 3 — work providers (e.g. RestProvider, ChopProvider, HaulingProvider).
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# World scene registers them on _ready. Decision.pick_next_job() iterates by .priority desc.
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var work_providers: Array = []
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# Phase 4 — harvestables + items + stockpiles. Entities call register_*/unregister_*
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# from their _ready/_exit_tree. Phase 16 will add stable IDs and persistence wiring.
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var trees: Array = [] # Array of Tree
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var rocks: Array = [] # Array of Rock
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var items: Array = [] # Array of Item (on-floor stacks)
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var stockpiles: Array = [] # Array of StorageDestination (StockpileZone for now; containers Phase 5)
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# Phase 4 — pathfinder reference exposed for entity code that needs walkability
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# checks (e.g. Tree.fell() picking neighbour tiles for wood drops). The actual
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# Pathfinder node lives on the World scene as a child; the scene sets this in
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# its _ready(). Don't access before the world scene is mounted.
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var pathfinder = null
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# Phase 4 — hauling dirty set. Keys are Items, value is unused (we just use .keys()).
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# An Item is added when it spawns (Tree.fell, Rock.mined, workbench drop, ...)
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# and removed when it lands at its highest-priority valid destination.
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# HaulingProvider.sweep_for_better_destinations() re-marks items when a higher
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# priority stockpile opens up (the priority cascade per design.md).
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var items_needing_haul: Dictionary = {}
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func register_work_provider(wp) -> void:
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assert(wp != null, "World.register_work_provider: provider is null")
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if not work_providers.has(wp):
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work_providers.append(wp)
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func clear_work_providers() -> void:
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work_providers.clear()
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func register_pawn(p: Pawn) -> void:
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assert(p != null, "World.register_pawn: pawn is null")
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if pawns.has(p):
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return
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pawns.append(p)
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func unregister_pawn(p: Pawn) -> void:
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pawns.erase(p)
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func pawn_at_tile(tile: Vector2i) -> Pawn:
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for p in pawns:
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if p.tile == tile:
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return p
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return null
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func clear_pawns() -> void:
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# For save-load / new-game flow in Phase 16.
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pawns.clear()
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# ── Phase 4: harvestables + items + stockpiles ──────────────────────────────
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func register_tree(t) -> void:
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if not trees.has(t):
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trees.append(t)
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func unregister_tree(t) -> void:
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trees.erase(t)
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func register_rock(r) -> void:
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if not rocks.has(r):
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rocks.append(r)
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func unregister_rock(r) -> void:
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rocks.erase(r)
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func register_item(it) -> void:
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if items.has(it):
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return
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items.append(it)
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# Newly-spawned items always start as "needs haul" — HaulingProvider will
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# clear the flag once the item lands in its highest-priority destination.
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items_needing_haul[it] = true
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func unregister_item(it) -> void:
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items.erase(it)
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items_needing_haul.erase(it)
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func register_stockpile(s) -> void:
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if not stockpiles.has(s):
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stockpiles.append(s)
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func unregister_stockpile(s) -> void:
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stockpiles.erase(s)
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func mark_item_needs_haul(it) -> void:
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items_needing_haul[it] = true
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func clear_item_haul_flag(it) -> void:
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items_needing_haul.erase(it)
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