mirror of
https://github.com/openfrontio/OpenFrontIO.git
synced 2026-07-08 14:52:10 +00:00
22c873cf55
## Problem
Every 100 ms the main thread's worker `onmessage` callback processes a
full game tick (`gameView.update` → `webglBuilder.update` →
`renderer.tick`). At 60 fps this competes with the 16.7 ms frame budget,
and on the Giant World Map it takes several ms — frame drops on low-end
hardware.
## Harness (`npm run perf:client-tick`)
Headless-Chromium harness that times every worker→main `game_update`
dispatch on the main thread, with structured-clone deserialization
measured separately from the handler body (via a
`Worker.prototype.addEventListener` wrapper installed as a page init
script — no product-code changes). It reports windowed distributions,
captures `.cpuprofile` files at chosen ticks, writes raw samples and an
end-of-run screenshot. `AnalyzeCpuProfile.ts` breaks a profile down by
inclusive time under the dispatch subtree.
Init scripts are passed as **strings**: tsx compiles function-form init
scripts with esbuild `keepNames`, whose injected `__name` helper doesn't
exist in-page and silently kills the game worker setup.
## Baseline (Giant World Map, 400 bots, headless)
Dispatch handler ms — cost **grows with game progression**:
| window | mean | p50 | p95 | max |
|---|---|---|---|---|
| tick 506 | 2.22 | 2.20 | 3.40 | 5.00 |
| tick 1506 | 2.60 | 2.00 | 7.00 | 10.40 |
| tick 2000 | 2.67 | 1.90 | **8.70** | **12.70** |
Deserialization is negligible (0.12 ms mean). CPU profiles attributed
the growing tail to the leaderboard's once-per-second refresh: its
Max-troops column calls `config().maxTroops(p)` for **all ~508
players**, and `PlayerView.units()` scanned **every unit in the game**
per call — O(players × units), growing as units accumulate.
## Round 1 — algorithmic fixes
- **GameView**: new `unitsOwnedBy(smallID)` — an active-units-by-owner
index built lazily at most once per tick. `PlayerView.units()` reads its
own units from it: O(own units) instead of O(all units). Also speeds up
unit display, player panel, and buildables queries.
- **NamePass.updateNames**: reads player state directly from the
caller's map by smallID instead of rebuilding three lookup maps per
tick; skips the slot-assignment sweep once every player has a slot.
After (same map, same spawn tile):
| window | mean | p50 | p95 | max |
|---|---|---|---|---|
| tick 506 | 2.12 | 2.00 | 3.10 | 5.20 |
| tick 1506 | 1.86 | 1.80 | 2.90 | 4.30 |
| tick 2000 | 1.74 | 1.60 | **2.40** | **4.70** |
Late-game p95 −65% (8.7 → 2.4 ms), worst dispatch −63% (12.7 → 4.7 ms),
and per-dispatch cost no longer grows with game progression. The
leaderboard disappeared from the dispatch profile entirely.
## Round 2 — allocation churn + time slicing
Aimed at GC pauses and low-end CPUs; measures flat vs round 1 on a fast
machine, as expected:
- **`FrameData.changedTiles`** is now the plain tile-ref array GameView
already builds instead of a per-tile `{ref, state}` object copy — heavy
battle ticks allocated tens of thousands of objects per tick for a
`state` field that was always 0. `TilePair` removed; `TerritoryPass`
buckets refs synchronously, so the live reference is safe.
- **`UnitView.lastPos`** is only re-sliced when a move actually appended
a position — the unconditional `slice(-1)` allocated an identical
1-element array per unit per tick, including for structures that never
move.
- **`NamePass.updateNames`** refreshes slots round-robin, a quarter per
tick — the full per-player diff pass spreads over ~400 ms, under the
existing 500 ms troop-text cadence; positions lerp continuously. Unnamed
slots and snap passes (seeks) are always processed so nothing pops in
late. Dispatch share: 17% → 13%.
Not sliced on purpose: tile ingest and frame upload need a consistent
per-tick snapshot (stale `GameMap` reads would leak into hover queries,
minimap, attack targeting) — a correctness risk not worth ~1 ms while
the worst dispatch already fits in a quarter of the frame budget.
## Verification
- `npx tsc --noEmit`, eslint clean; full suite green (1929 tests)
- 6 new GameView tests cover the owner index (grouping, inactive
exclusion, ownership capture, death, type filtering, copy semantics);
changedTiles tests updated to the ref-array contract
- Headless end-of-run screenshots verified after each round: leaderboard
Max-troops values, map names + troop counts + flags all render correctly
(including with name slicing active)
🤖 Generated with [Claude Code](https://claude.com/claude-code)
---------
Co-authored-by: Claude Fable 5 <noreply@anthropic.com>
569 lines
21 KiB
TypeScript
569 lines
21 KiB
TypeScript
/**
|
||
* Main-thread tick-processing harness: drives a real singleplayer game in
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* headless Chromium and measures how long the worker→main "game_update"
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* message dispatch takes on the MAIN thread — the per-tick cost that competes
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* with the frame budget (16.7 ms at 60 fps) and causes frame drops on low-end
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* hardware when it runs long.
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*
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* What is measured, per dispatch:
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* - deserialization: first access to event.data (structured-clone decode)
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* - handler: WorkerClient.handleWorkerMessage → gameView.update →
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* webglBuilder.update → renderer.tick
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* Both are captured by wrapping Worker.prototype.addEventListener in an init
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* script, so no product code changes are needed.
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*
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* For attribution, CDP sampling profiles (chrome .cpuprofile files) can be
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* captured over tick windows and are summarized as top self-time functions.
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* Open them in Chrome DevTools → Performance → load profile for flame graphs.
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*
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* The harness starts its own vite dev server on a private port (default
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* 9017) so results always come from THIS checkout, even when another
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* working copy is serving port 9000.
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*
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* One-time browser setup (installs playwright + chromium libs, no sudo):
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* bash .claude/skills/run-openfront/setup.sh
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*
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* Usage:
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* npm run perf:client-tick -- --map "Giant World Map" --ticks 2000 \
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* --window 250 --profile-at 500,1500
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*
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* Flags:
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* --map <name> GameMapType value (default "Giant World Map")
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* --bots <n> bot count (default 400, the solo-modal default)
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* --difficulty <d> Easy|Medium|Hard|Impossible (default modal default)
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* --ticks <n> run until this game tick (default 2000)
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* --window <n> report stats every n ticks (default 250)
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* --profile-at <list> comma-separated ticks to start a CPU profile
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* --profile-window <n> ticks each CPU profile spans (default 100)
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* --spawn <x,y> fixed human spawn tile (default: auto-pick)
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* --port <n> vite dev-server port (default 9017)
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* --raf-interval <ms> rAF throttle; SwiftShader frames cost seconds of
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* CPU, so an unthrottled frame loop starves the sim
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* (default 3000)
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* --out-dir <dir> output dir (default tests/perf/output)
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*
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* Headless caveats: rendering uses SwiftShader and the rAF loop is throttled,
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* so this measures the tick-dispatch path, not draw calls. GL upload calls
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* issued inside the dispatch go through SwiftShader's command buffer and cost
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* differently than on real GPUs. Solo games are RNG-driven, so numbers vary
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* a few percent run-to-run; compare trends, not microseconds.
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*/
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import { ChildProcess, spawn as spawnProcess } from "child_process";
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import fs from "fs";
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import path from "path";
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interface Options {
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map: string;
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bots: number;
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difficulty: string | undefined;
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ticks: number;
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window: number;
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profileAt: number[];
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profileWindow: number;
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spawn: { x: number; y: number } | null;
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port: number;
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rafIntervalMs: number;
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outDir: string;
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}
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/** One worker→main game-update dispatch, as recorded by the init script. */
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interface TickSample {
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/** Game tick of the (last) update in the dispatch. */
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tick: number;
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/** ms spent deserializing event.data (structured-clone decode). */
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deserMs: number;
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/** ms spent in the message handler (gameView/webglBuilder/renderer). */
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handlerMs: number;
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/** Updates in the dispatch (>1 for game_update_batch catch-up). */
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updates: number;
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}
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interface WindowStats {
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label: string;
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fromTick: number;
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toTick: number;
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dispatches: number;
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updates: number;
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meanMs: number;
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p50Ms: number;
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p95Ms: number;
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maxMs: number;
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meanDeserMs: number;
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maxDeserMs: number;
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/** Mean handler ms per game tick (normalizes batched dispatches). */
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meanPerUpdateMs: number;
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}
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function parseArgs(): Options {
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const opts: Options = {
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map: "Giant World Map",
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bots: 400,
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difficulty: undefined,
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ticks: 2000,
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window: 250,
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profileAt: [],
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profileWindow: 100,
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spawn: null,
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port: 9017,
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rafIntervalMs: 3000,
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outDir: path.join("tests", "perf", "output"),
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};
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const argv = process.argv.slice(2);
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for (let i = 0; i < argv.length; i++) {
|
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const next = () => argv[++i];
|
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switch (argv[i]) {
|
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case "--map":
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opts.map = next();
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break;
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case "--bots":
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opts.bots = parseInt(next(), 10);
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break;
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case "--difficulty":
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opts.difficulty = next();
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break;
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case "--ticks":
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opts.ticks = parseInt(next(), 10);
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break;
|
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case "--window":
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opts.window = parseInt(next(), 10);
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break;
|
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case "--profile-at":
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opts.profileAt = next()
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.split(",")
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.map((s) => parseInt(s.trim(), 10))
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.filter((n) => Number.isFinite(n));
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break;
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case "--profile-window":
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opts.profileWindow = parseInt(next(), 10);
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break;
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case "--spawn": {
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const [x, y] = next().split(",").map(Number);
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opts.spawn = { x, y };
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break;
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}
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case "--port":
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opts.port = parseInt(next(), 10);
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break;
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case "--raf-interval":
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opts.rafIntervalMs = parseInt(next(), 10);
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break;
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case "--out-dir":
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opts.outDir = next();
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break;
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default:
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throw new Error(`unknown flag: ${argv[i]}`);
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}
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}
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return opts;
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}
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// ---------- dev server ----------
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async function startViteServer(port: number): Promise<ChildProcess> {
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// --strictPort makes vite exit instead of silently picking another port —
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// that also guards against measuring a different checkout's server.
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const child = spawnProcess(
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"npx",
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["vite", "--port", String(port), "--strictPort"],
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{
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env: { ...process.env, SKIP_BROWSER_OPEN: "true" },
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stdio: ["ignore", "pipe", "pipe"],
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detached: true, // own process group, so cleanup kills vite's children
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},
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);
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let output = "";
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child.stdout?.on("data", (d: Buffer) => (output += d.toString()));
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child.stderr?.on("data", (d: Buffer) => (output += d.toString()));
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const deadline = Date.now() + 60_000;
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while (Date.now() < deadline) {
|
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if (child.exitCode !== null) {
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throw new Error(
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`vite exited with code ${child.exitCode} (port ${port} busy?)\n${output}`,
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);
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}
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try {
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const res = await fetch(`http://localhost:${port}/`);
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if (res.ok) return child;
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} catch {
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// not up yet
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}
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await new Promise((r) => setTimeout(r, 500));
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}
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throw new Error(`vite did not become ready on port ${port}\n${output}`);
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}
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|
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function stopViteServer(child: ChildProcess): void {
|
||
if (child.pid !== undefined && child.exitCode === null) {
|
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try {
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process.kill(-child.pid, "SIGTERM"); // whole process group
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} catch {
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// already gone
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}
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}
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}
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// ---------- stats ----------
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function quantile(sorted: number[], q: number): number {
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if (sorted.length === 0) return 0;
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const idx = Math.min(sorted.length - 1, Math.ceil(q * sorted.length) - 1);
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return sorted[Math.max(0, idx)];
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}
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function summarizeWindow(label: string, samples: TickSample[]): WindowStats {
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const handler = samples.map((s) => s.handlerMs).sort((a, b) => a - b);
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const deser = samples.map((s) => s.deserMs);
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const updates = samples.reduce((acc, s) => acc + s.updates, 0);
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const totalHandler = handler.reduce((acc, v) => acc + v, 0);
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return {
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label,
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fromTick: samples.length > 0 ? samples[0].tick : 0,
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toTick: samples.length > 0 ? samples[samples.length - 1].tick : 0,
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dispatches: samples.length,
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updates,
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meanMs: samples.length > 0 ? totalHandler / samples.length : 0,
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p50Ms: quantile(handler, 0.5),
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p95Ms: quantile(handler, 0.95),
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maxMs: handler.length > 0 ? handler[handler.length - 1] : 0,
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meanDeserMs:
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samples.length > 0
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? deser.reduce((acc, v) => acc + v, 0) / samples.length
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: 0,
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maxDeserMs: deser.length > 0 ? Math.max(...deser) : 0,
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meanPerUpdateMs: updates > 0 ? totalHandler / updates : 0,
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};
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}
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function printReport(windows: WindowStats[], opts: Options): void {
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console.log(
|
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`\n=== Main-thread tick dispatch (map=${opts.map}, bots=${opts.bots}) ===`,
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);
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console.log(
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"handler ms per worker game-update dispatch (frame budget at 60 fps: 16.7 ms)",
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);
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console.log(
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`${"window".padEnd(14)} ${"disp".padStart(5)} ${"upd".padStart(5)} ${"mean".padStart(7)} ${"p50".padStart(7)} ${"p95".padStart(7)} ${"max".padStart(7)} ${"deser".padStart(7)} ${"ms/upd".padStart(7)}`,
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);
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for (const w of windows) {
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console.log(
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`${w.label.padEnd(14)} ${String(w.dispatches).padStart(5)} ${String(w.updates).padStart(5)} ${w.meanMs.toFixed(2).padStart(7)} ${w.p50Ms.toFixed(2).padStart(7)} ${w.p95Ms.toFixed(2).padStart(7)} ${w.maxMs.toFixed(2).padStart(7)} ${w.meanDeserMs.toFixed(2).padStart(7)} ${w.meanPerUpdateMs.toFixed(2).padStart(7)}`,
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);
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}
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}
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|
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// ---------- CPU profile summarization ----------
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interface CpuProfileNode {
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id: number;
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callFrame: {
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functionName: string;
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||
url: string;
|
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lineNumber: number;
|
||
};
|
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hitCount?: number;
|
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children?: number[];
|
||
}
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||
|
||
interface CpuProfile {
|
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nodes: CpuProfileNode[];
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startTime: number;
|
||
endTime: number;
|
||
samples?: number[];
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timeDeltas?: number[];
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}
|
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|
||
/** Print the top-N functions by self time from a V8 sampling profile. */
|
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function summarizeProfile(profile: CpuProfile, top: number): void {
|
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// Self time per node = sum of timeDeltas for samples attributed to it.
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const selfMicros = new Map<number, number>();
|
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const samples = profile.samples ?? [];
|
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const deltas = profile.timeDeltas ?? [];
|
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for (let i = 0; i < samples.length; i++) {
|
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const nodeId = samples[i];
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selfMicros.set(nodeId, (selfMicros.get(nodeId) ?? 0) + (deltas[i] ?? 0));
|
||
}
|
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const byFunction = new Map<string, number>();
|
||
for (const node of profile.nodes) {
|
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const micros = selfMicros.get(node.id) ?? 0;
|
||
if (micros === 0) continue;
|
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const { functionName, url, lineNumber } = node.callFrame;
|
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const shortUrl = url.replace(/^.*\/(src|node_modules)\//, "$1/");
|
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const key = `${functionName || "(anonymous)"} ${shortUrl}:${lineNumber + 1}`;
|
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byFunction.set(key, (byFunction.get(key) ?? 0) + micros);
|
||
}
|
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const totalMicros = profile.endTime - profile.startTime;
|
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const rows = [...byFunction.entries()].sort((a, b) => b[1] - a[1]);
|
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console.log(
|
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` top self-time functions (of ${(totalMicros / 1000).toFixed(0)} ms profiled):`,
|
||
);
|
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for (const [key, micros] of rows.slice(0, top)) {
|
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const pct = ((micros / totalMicros) * 100).toFixed(1);
|
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console.log(
|
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` ${(micros / 1000).toFixed(1).padStart(8)} ms ${pct.padStart(5)}% ${key}`,
|
||
);
|
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}
|
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}
|
||
|
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// ---------- main ----------
|
||
|
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async function main(): Promise<void> {
|
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const opts = parseArgs();
|
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fs.mkdirSync(opts.outDir, { recursive: true });
|
||
|
||
console.log(`starting vite on port ${opts.port}…`);
|
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const vite = await startViteServer(opts.port);
|
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|
||
// The skill driver reads OPENFRONT_URL at import time, so set it before
|
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// the dynamic imports below.
|
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process.env.OPENFRONT_URL = `http://localhost:${opts.port}`;
|
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const { launch, gotoHome, openSoloModal } =
|
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// @ts-expect-error untyped .mjs skill module
|
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await import("../../../.claude/skills/run-openfront/driver.mjs");
|
||
const {
|
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startSoloGame,
|
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waitForGameReady,
|
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spawn,
|
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waitForSpawnPhaseEnd,
|
||
waitForTick,
|
||
gameState,
|
||
} =
|
||
// @ts-expect-error untyped .mjs skill module
|
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await import("../../../.claude/skills/run-openfront/game.mjs");
|
||
|
||
let browser: { close(): Promise<void> } | null = null;
|
||
try {
|
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console.log("launching headless chromium…");
|
||
const launched = await launch({
|
||
rafIntervalMs: opts.rafIntervalMs,
|
||
// Headless Chromium throttles backgrounded/occluded pages, which
|
||
// starves the singleplayer turn loop on top of SwiftShader's cost.
|
||
args: [
|
||
"--disable-background-timer-throttling",
|
||
"--disable-backgrounding-occluded-windows",
|
||
"--disable-renderer-backgrounding",
|
||
],
|
||
});
|
||
browser = launched.browser;
|
||
const page = launched.page;
|
||
|
||
// Surface in-page failures in the harness log — a broken init script or
|
||
// GL fault otherwise shows up only as an opaque ready-timeout. Blocked
|
||
// external fetches (ads, auth, cosmetics) are expected noise; skip them.
|
||
page.on("console", (msg: { type(): string; text(): string }) => {
|
||
const text = msg.text();
|
||
if (
|
||
msg.type() === "error" &&
|
||
!/Failed to load resource|Failed to fetch|ramp\./.test(text)
|
||
) {
|
||
console.log(`CONSOLE[error]: ${text}`);
|
||
}
|
||
});
|
||
|
||
// Headless Chromium only has SwiftShader, and the WebGL gate (#4324)
|
||
// refuses software renderers by matching the unmasked renderer string.
|
||
// Spoof the string so the gate passes; rendering still runs on
|
||
// SwiftShader (hence the rAF throttle).
|
||
await page.addInitScript(() => {
|
||
const orig = WebGL2RenderingContext.prototype.getParameter;
|
||
WebGL2RenderingContext.prototype.getParameter = function (p: number) {
|
||
const v = orig.call(this, p);
|
||
return typeof v === "string"
|
||
? v.replace(/swiftshader|llvmpipe|software/gi, "PerfHarnessGPU")
|
||
: v;
|
||
};
|
||
});
|
||
|
||
// Time every worker→main "message" dispatch. The first event.data access
|
||
// pays the structured-clone deserialization, so it is timed separately
|
||
// from the handler body. Only game updates are recorded.
|
||
//
|
||
// MUST stay a string, not a function: tsx compiles this file with
|
||
// esbuild's keepNames, which rewrites named function expressions to
|
||
// `__name(fn, "name")` — and the `__name` helper doesn't exist in the
|
||
// page, so a function-form script throws ReferenceError inside
|
||
// Worker.addEventListener and silently kills the game worker setup.
|
||
// (Member-expression assignments like the GL spoof above escape
|
||
// keepNames, which is why that one can stay a function.)
|
||
await page.addInitScript(`(() => {
|
||
// Init scripts also run in dedicated workers, where window is
|
||
// undefined — only the page context is measured.
|
||
if (typeof window === "undefined") return;
|
||
const samples = [];
|
||
window.__tickPerf = {
|
||
take() {
|
||
return samples.splice(0, samples.length);
|
||
},
|
||
};
|
||
const origAdd = Worker.prototype.addEventListener;
|
||
Worker.prototype.addEventListener = function (type, listener, options) {
|
||
if (type !== "message" || typeof listener !== "function") {
|
||
return origAdd.call(this, type, listener, options);
|
||
}
|
||
const wrapped = function (event) {
|
||
const t0 = performance.now();
|
||
const d = event.data; // first access → structured-clone decode
|
||
const t1 = performance.now();
|
||
const isTick = d && d.type === "game_update";
|
||
const isBatch = d && d.type === "game_update_batch";
|
||
if (!isTick && !isBatch) {
|
||
return listener.call(this, event);
|
||
}
|
||
try {
|
||
return listener.call(this, event);
|
||
} finally {
|
||
const t2 = performance.now();
|
||
const updates = isBatch ? (d.gameUpdates ?? []) : [d.gameUpdate];
|
||
const last = updates[updates.length - 1];
|
||
samples.push({
|
||
tick: last ? last.tick : -1,
|
||
deserMs: t1 - t0,
|
||
handlerMs: t2 - t1,
|
||
updates: updates.length,
|
||
});
|
||
// Bounded so a stalled harness can't grow the page's heap.
|
||
if (samples.length > 200000) samples.splice(0, 100000);
|
||
}
|
||
};
|
||
return origAdd.call(this, type, wrapped, options);
|
||
};
|
||
})();`);
|
||
|
||
// Solo games are fully local: block external requests (ad scripts) and
|
||
// all websockets — vite's HMR socket times out under heavy throttling
|
||
// and force-reloads the page mid-game.
|
||
await page.route("**/*", (route: any) => {
|
||
const host = new URL(route.request().url()).hostname;
|
||
return host === "localhost" || host === "127.0.0.1"
|
||
? route.continue()
|
||
: route.abort();
|
||
});
|
||
await page.routeWebSocket("**", () => {});
|
||
|
||
// CDP session against the page = the main thread only (the core sim
|
||
// worker is a separate target and not included in CPU profiles).
|
||
const cdp = await page.context().newCDPSession(page);
|
||
await cdp.send("Profiler.enable");
|
||
await cdp.send("Profiler.setSamplingInterval", { interval: 200 });
|
||
|
||
const takeSamples = async (): Promise<TickSample[]> =>
|
||
(await page.evaluate(() => (window as any).__tickPerf.take())) ?? [];
|
||
|
||
console.log("loading home page + solo modal…");
|
||
await gotoHome(page);
|
||
await openSoloModal(page);
|
||
|
||
console.log(
|
||
`starting solo game: map=${opts.map}, bots=${opts.bots}` +
|
||
(opts.difficulty !== undefined
|
||
? `, difficulty=${opts.difficulty}`
|
||
: ""),
|
||
);
|
||
try {
|
||
await startSoloGame(page, {
|
||
map: opts.map,
|
||
bots: opts.bots,
|
||
...(opts.difficulty !== undefined
|
||
? { difficulty: opts.difficulty }
|
||
: {}),
|
||
});
|
||
} catch {
|
||
// Giant maps can exceed the skill's 180 s ready timeout on a cold
|
||
// headless start — give the load one more window before giving up.
|
||
console.log("game not ready after 180 s, waiting another 300 s…");
|
||
await waitForGameReady(page, 300_000);
|
||
}
|
||
|
||
console.log("spawning…");
|
||
const tile = await spawn(page, opts.spawn);
|
||
console.log(`spawned at (${tile.x},${tile.y})`);
|
||
await waitForSpawnPhaseEnd(page, 120_000);
|
||
const spawnState = await gameState(page);
|
||
const spawnedTick: number = spawnState?.ticks ?? 0;
|
||
// Spawn-phase dispatches are not representative; drop them.
|
||
await takeSamples();
|
||
|
||
const startWall = Date.now();
|
||
const windows: WindowStats[] = [];
|
||
const allSamples: TickSample[] = [];
|
||
const pendingProfiles = [...new Set(opts.profileAt)].sort((a, b) => a - b);
|
||
|
||
const captureProfile = async (startTick: number): Promise<void> => {
|
||
const endTick = startTick + opts.profileWindow;
|
||
console.log(`[profile] capturing ticks ${startTick}–${endTick}…`);
|
||
await cdp.send("Profiler.start");
|
||
await waitForTick(page, endTick, opts.profileWindow * 2000 + 120_000);
|
||
const { profile } = await cdp.send("Profiler.stop");
|
||
const file = path.join(opts.outDir, `client-tick${startTick}.cpuprofile`);
|
||
fs.writeFileSync(file, JSON.stringify(profile));
|
||
console.log(`[profile] ${file}`);
|
||
summarizeProfile(profile as CpuProfile, 25);
|
||
};
|
||
|
||
const targets: number[] = [];
|
||
for (let t = spawnedTick + opts.window; t < opts.ticks; t += opts.window) {
|
||
targets.push(t);
|
||
}
|
||
if (opts.ticks > spawnedTick) targets.push(opts.ticks);
|
||
|
||
for (const target of targets) {
|
||
// A due profile splits the window: profile spans real ticks inside it.
|
||
while (pendingProfiles.length > 0 && pendingProfiles[0] < target) {
|
||
const at = pendingProfiles.shift()!;
|
||
const state = await gameState(page);
|
||
const current: number = state?.ticks ?? 0;
|
||
if (at > current) {
|
||
// Generous timeout: headless sim speed varies wildly with map size
|
||
// and bot count (0.5–10 ticks/s).
|
||
await waitForTick(page, at, (at - current) * 2000 + 120_000);
|
||
}
|
||
await captureProfile(Math.max(at, current));
|
||
}
|
||
const state = await gameState(page);
|
||
const current: number = state?.ticks ?? 0;
|
||
if (target > current) {
|
||
await waitForTick(page, target, (target - current) * 2000 + 120_000);
|
||
}
|
||
const samples = await takeSamples();
|
||
allSamples.push(...samples);
|
||
const w = summarizeWindow(`tick ${target}`, samples);
|
||
windows.push(w);
|
||
console.log(
|
||
`[window] ${w.label}: ${w.dispatches} dispatches, mean ${w.meanMs.toFixed(2)} ms, p95 ${w.p95Ms.toFixed(2)} ms, max ${w.maxMs.toFixed(2)} ms`,
|
||
);
|
||
}
|
||
// Any profiles requested at/beyond the final tick.
|
||
while (pendingProfiles.length > 0) {
|
||
await captureProfile(pendingProfiles.shift()!);
|
||
}
|
||
|
||
const samplesFile = path.join(opts.outDir, "client-tick-samples.json");
|
||
fs.writeFileSync(samplesFile, JSON.stringify(allSamples));
|
||
console.log(`[samples] ${samplesFile} (${allSamples.length} dispatches)`);
|
||
|
||
// End-of-run screenshot — a cheap rendering sanity check (a black map
|
||
// means the GL pipeline broke even if no pageerror surfaced).
|
||
const shotPath = path.join(opts.outDir, "client-tick-final.png");
|
||
await page.screenshot({ path: shotPath });
|
||
console.log(`[screenshot] ${shotPath}`);
|
||
|
||
printReport(windows, opts);
|
||
printReport([summarizeWindow("overall", allSamples)], {
|
||
...opts,
|
||
map: `${opts.map} (all windows)`,
|
||
});
|
||
const finalState = await gameState(page);
|
||
console.log(
|
||
`\nfinal state: ${JSON.stringify(finalState)}\ntotal wall time ${((Date.now() - startWall) / 1000 / 60).toFixed(1)} min`,
|
||
);
|
||
} finally {
|
||
await browser?.close();
|
||
stopViteServer(vite);
|
||
}
|
||
}
|
||
|
||
main().catch((err) => {
|
||
console.error(err);
|
||
process.exit(1);
|
||
});
|