--- id: wiki-2026-0508-브라우저-메인-스레드-최적화-및-타임-슬라이싱 title: 브라우저 메인 스레드 최적화 및 타임 슬라이싱 category: 10_Wiki/Topics status: verified canonical_id: self aliases: [Main Thread Optimization, Time Slicing, INP Optimization, Long Tasks, Scheduler API] duplicate_of: none source_trust_level: A confidence_score: 0.9 verification_status: applied tags: [web-performance, main-thread, scheduler, inp, long-tasks, web-workers] raw_sources: [] last_reinforced: 2026-05-10 github_commit: pending tech_stack: language: typescript framework: vanilla-web-platform --- # 브라우저 메인 스레드 최적화 및 타임 슬라이싱 ## 매 한 줄 > **"매 long task 를 매 50ms 미만 chunk 로 split, scheduler.yield() 로 매 input 에 양보"**. 매 INP (Interaction to Next Paint, 2024 부터 Core Web Vital) 의 핵심 metric — 매 200ms 이하 가 Good. 매 2026 의 Scheduler API + isInputPending + Web Worker 의 매 standard toolkit. ## 매 핵심 ### 매 Main thread 의 책임 - **JS execution**, Style + Layout + Paint, Compositing prep, Event dispatch. - **Long task**: 50ms 초과 task — INP 의 적. - **Render-blocking**: long task 동안 rAF, input handler 모두 starve. ### 매 Time slicing 전략 - **Yield to event loop**: scheduler.yield() (2026 baseline), 매 fallback 으로 setTimeout(0). - **Priority-aware scheduling**: scheduler.postTask({priority: 'background'}). - **isInputPending()**: input 의 pending 시 매 즉시 yield. - **Web Worker offload**: pure compute (parsing, encoding, crypto) 는 main thread 떠남. ### 매 응용 1. **Large list rendering**: virtualized + chunked. 2. **JSON parsing / encoding**: Worker + Transferable. 3. **Hydration**: priority-based React 19 / Astro / Qwik resumability. ## 💻 패턴 ### scheduler.yield() (2026 baseline) ```typescript async function processChunks(items: Item[]) { for (const it of items) { process(it); if (navigator.scheduling?.isInputPending?.()) { await scheduler.yield(); // resume after input is handled } } } ``` ### scheduler.postTask with priority ```typescript // User-blocking: must run ASAP scheduler.postTask(updateUserCriticalUI, { priority: 'user-blocking' }); // User-visible: default scheduler.postTask(refreshSidebar, { priority: 'user-visible' }); // Background: prefetch, analytics flush scheduler.postTask(prefetchNext, { priority: 'background' }); ``` ### Manual time slicer (fallback) ```typescript async function timeSlice(items: T[], work: (item: T) => void, budgetMs = 5) { let start = performance.now(); for (const it of items) { work(it); if (performance.now() - start > budgetMs) { await new Promise((r) => setTimeout(r, 0)); start = performance.now(); } } } ``` ### Web Worker offload (Comlink pattern) ```typescript // worker.ts import * as Comlink from 'comlink'; const api = { parseLargeJSON: (text: string) => JSON.parse(text), hashFile: async (buf: ArrayBuffer) => { const h = await crypto.subtle.digest('SHA-256', buf); return new Uint8Array(h); }, }; Comlink.expose(api); // main.ts const worker = new Worker(new URL('./worker.ts', import.meta.url), { type: 'module' }); const api = Comlink.wrap(worker); const parsed = await api.parseLargeJSON(hugeText); ``` ### Transferable ArrayBuffer (zero-copy) ```typescript const buf = new ArrayBuffer(1024 * 1024 * 10); worker.postMessage({ buf }, [buf]); // ownership transfers; main no longer holds ``` ### INP measurement (Performance Observer) ```typescript const observer = new PerformanceObserver((list) => { for (const entry of list.getEntries() as PerformanceEventTiming[]) { const inp = entry.processingEnd - entry.startTime; if (inp > 200) console.warn('Slow interaction', entry.name, inp); } }); observer.observe({ type: 'event', buffered: true, durationThreshold: 16 }); ``` ### React 19 — useTransition for non-urgent updates ```typescript const [isPending, startTransition] = useTransition(); function handleSearch(q: string) { setQuery(q); // urgent — input echo startTransition(() => { setSearchResults(filterHugeList(allItems, q)); // non-urgent — yields to input }); } ``` ### IntersectionObserver — lazy heavy work ```typescript const io = new IntersectionObserver((entries) => { for (const e of entries) { if (e.isIntersecting) { scheduler.postTask(() => mountHeavyComponent(e.target), { priority: 'background' }); io.unobserve(e.target); } } }, { rootMargin: '200px' }); document.querySelectorAll('.lazy-section').forEach(el => io.observe(el)); ``` ### Long Animation Frames (LoAF) API ```typescript new PerformanceObserver((list) => { for (const e of list.getEntries() as any[]) { console.warn('LoAF', e.duration, e.scripts); } }).observe({ type: 'long-animation-frame', buffered: true }); ``` ## 매 결정 기준 | 상황 | Approach | |---|---| | > 50ms synchronous work | Time slice with scheduler.yield() | | Pure compute (parse, hash, image) | Web Worker + Transferable | | Non-urgent state update (React) | useTransition | | Off-screen heavy work | IntersectionObserver + postTask | | Background prefetch | scheduler.postTask priority 'background' | | Hot UI update with input | isInputPending checkpoint | **기본값**: 매 task > 5ms 면 yield consider. 매 task > 50ms 면 split mandatory. 매 pure compute 는 Worker 의 first choice. ## 🔗 Graph - 부모: [[Web-Performance]] · [[Core Web Vitals Optimization (INP, LCP, CLS)|Core-Web-Vitals]] · [[INP-Optimization]] - 변형: [[Scheduler API]] · [[Web Worker (웹 워커)|Web-Workers]] · [[OffscreenCanvas]] - 응용: [[성능 중심의 웹 애니메이션 및 인터랙션 구현]] - Adjacent: [[Long Tasks]] · [[Long-Animation-Frames]] · [[Comlink]] ## 🤖 LLM 활용 **언제**: time-slice boilerplate, Worker setup scaffold, scheduler API migration plan. **언제 X**: 매 actual INP 측정 — RUM (CrUX, Web Vitals JS) 만 truth. LLM 의 perf claim 의 hallucination. ## ❌ 안티패턴 - **Sync heavy work in input handler**: 매 INP 폭증. - **setTimeout(0) busy-loop**: scheduler.yield() preferred (priority-aware). - **Worker per task spawn**: 매 startup overhead. Pool 또는 long-lived worker. - **structuredClone of huge data to Worker**: Transferable 사용. - **Ignoring isInputPending**: 매 yield 의 timing 의 너무 늦음. ## 🧪 검증 / 중복 - Verified (web.dev/inp 2026, Scheduler API spec, LoAF spec, Chrome DevTools Performance docs). - 신뢰도 A. ## 🕓 Changelog | 날짜 | 변경 | |---|---| | 2026-05-08 | Phase 1 | | 2026-05-10 | Manual cleanup — Scheduler API, time slicing, Worker offload, INP patterns |