--- id: ssh2-rivetkit name: "rivetkit" url: https://skills.yangsir.net/skill/ssh2-rivetkit author: rivet-dev domain: ai-agent-core-development tags: ["rivetkit", "ai-agent-development", "llm-orchestration", "tooling", "agent-frameworks"] install_count: 6000 rating: 4.40 (39 reviews) github: https://github.com/rivet-dev/skills --- # rivetkit > RivetKit后端和Rivet Actor运行时指南,用于构建和修改。 **Stats**: 6,000 installs · 4.4/5 (39 reviews) ## Before / After 对比 ### RivetKit后端与Actor运行时开发 ## Readme # Rivet Actors Build high-performance, long-lived, in-memory processes on Rivet's actor runtime. Use this skill whenever HTTP endpoints, databases, or queues no longer meet the requirements for AI agents, realtime collaboration, workflow orchestration, or geo-distributed data. ## What To Do If You Get Stuck If something is not working as intended or you are stuck, prompt the user to join the [Rivet Discord](https://rivet.dev/discord) or file an issue on the [Rivet GitHub](https://github.com/rivet-dev/rivet) to report an issue and get help. Provide the user with a pre-generated report with: - Symptoms - If this is happening in local dev, deployed, or both - The error you're seeing - Relevant source code related to this - What you've tried to solve it - Environment - RivetKit version - Runtime (Node, Bun, etc) including version - If applicable, provider in use (e.g. Vercel, Railway, etc) - If applicable, HTTP router in use (e.g. Hono, Express, Elysia) ## Debugging Actors Use the inspector HTTP API to examine running actors. These endpoints are accessible through the gateway at `/gateway/{actor_id}/inspector/*`. Key endpoints: - `GET /inspector/summary` - full actor snapshot (state, connections, RPCs, queue) - `GET /inspector/state` / `PATCH /inspector/state` - read/write actor state - `GET /inspector/connections` - active connections - `GET /inspector/rpcs` - available actions - `POST /inspector/action/{name}` - execute an action with `{"args": [...]}` - `GET /inspector/queue?limit=50` - queue status - `GET /inspector/traces?startMs=0&endMs=...&limit=1000` - trace spans (OTLP JSON) - `GET /inspector/workflow-history` - workflow history and status In local dev, no auth token is needed. In production, pass `Authorization: Bearer `. See the [debugging docs](https://rivet.dev/docs/actors/debugging) for details. ## Citing Sources When providing information from Rivet documentation, cite the canonical URL so users can learn more. Each reference file includes its canonical URL in the header metadata. **How to cite:** - Use inline links for key concepts: "Use [actor keys](https://rivet.dev/docs/actors/keys) to uniquely identify instances." - Add a "Learn more" link after explanations for complex topics **Finding canonical URLs:** The Reference Map below links to reference files. Each file's header contains: ``` > Canonical URL: https://rivet.dev/docs/actors/actions ``` Use that canonical URL when citing, not the reference file path. **Examples:** - Actions → `https://rivet.dev/docs/actors/actions` - React client → `https://rivet.dev/docs/clients/react` - Self-hosting on Kubernetes → `https://rivet.dev/docs/self-hosting/kubernetes` ## First Steps 1. Install RivetKit (latest: 2.1.6) ```bash npm install rivetkit@2.1.6 ``` 2. Define a registry with `setup({ use: { /* actors */ } })`. 3. Expose `registry.serve()` or `registry.handler()` (serverless) or `registry.startRunner()` (runner mode). Prefer serverless mode unless the user has a specific reason to use runner mode. 4. Verify `/api/rivet/metadata` returns 200 before deploying. 5. Configure Rivet Cloud or self-hosted engine - You must configure versioning for production builds. This is not needed for local development. See [Versions & Upgrades](https://rivet.dev/docs/actors/versions). 6. Integrate clients (see client guides below for JavaScript, React, or Swift) 7. Prompt the user if they want to deploy. If so, go to Deploying Rivet Backends. For more information, read the quickstart guide relevant to the user's project. ## Error Handling Policy - Prefer fail-fast behavior by default. - Avoid `try/catch` unless it is required for a real recovery path, cleanup boundary, or to add actionable context. - Never swallow errors. If you add a `catch`, you must handle the error explicitly, at minimum by logging it. - When you cannot recover, log context and rethrow. ## State vs Vars: Persistence Rules **`c.vars` is ephemeral.** Data in `c.vars` is lost on every restart, crash, upgrade, or sleep/wake cycle. Only use `c.vars` for non-serializable objects (e.g., physics engines, WebSocket references, event emitters, caches) or truly transient runtime data (e.g., current input direction that doesn't matter after disconnect). **Persistent storage options.** Any data that must survive restarts belongs in one of these, NOT in `c.vars`: - **`c.state`** — CBOR-serializable data for small, bounded datasets. Ideal for configuration, counters, small player lists, phase flags, etc. Keep under 128 KB. Do not store unbounded or growing data here (e.g., chat logs, event histories, spawned entity lists that grow without limit). State is read/written as a single blob on every persistence cycle. - **`c.kv`** — Key-value store for unbounded data. This is what `c.state` uses under the hood. Supports binary values. Use for larger or variable-size data like user inventories, world chunks, file blobs, or any collection that may grow over time. Keys are scoped to the actor instance. - **`c.db`** — SQLite database for structured or complex data. Use when you need queries, indexes, joins, aggregations, or relational modeling. Ideal for leaderboards, match histories, player pools, or any data that benefits from SQL. **Common mistake:** Storing meaningful game/application data in `c.vars` instead of persisting it. For example, if users can spawn objects in a physics simulation, the spawn definitions (position, size, type) must be persisted in `c.state` (or `c.kv` if unbounded), even though the physics engine handles (non-serializable) live in `c.vars`. On restart, `run()` should recreate the runtime objects from the persisted data. ## Deploying Rivet Backends Assume the user is deploying to Rivet Cloud, unless otherwise specified. If user is self-hosting, read the self-hosting guides below. 1. Verify that Rivet Actors are working in local dev 2. Prompt the user to choose a provider to deploy to (see [Connect](#connect) for a list of providers, such as Vercel, Railway, etc) 3. Follow the deploy guide for that given provider. You will need to instruct the user when you need manual intervention. ## API Reference The RivetKit OpenAPI specification is available in the skill directory at `openapi.json`. This file documents all HTTP endpoints for managing actors. ## Misc Notes - The Rivet domain is rivet.dev, not rivet.gg ## TypeScript Caveat: Actor Client Inference - In multi-file TypeScript projects, bidirectional actor calls can create a circular type dependency when both actors use `c.client()`. - Symptoms usually include `c.state` becoming `unknown`, actor methods becoming possibly `undefined`, or `TS2322` / `TS2722` errors after the first cross-actor call. - If an action returns the result of another actor call, prefer an explicit return type annotation on that action instead of relying on inference through `c.client()`. - If explicit return types are not enough, use a narrower client or registry type for only the actors that action needs. - As a last resort, pass `unknown` for the registry type and be explicit that this gives up type safety at that call site. ## Features - **Long-Lived, Stateful Compute**: Each unit of compute is like a tiny server that remembers things between requests – no need to re-fetch data from a database or worry about timeouts. Like AWS Lambda, but with memory and no timeouts. - **Blazing-Fast Reads & Writes**: State is stored on the same machine as your compute, so reads and writes are ultra-fast. No database round trips, no latency spikes. State is persisted to Rivet for long term storage, so it survives server restarts. - **Realtime**: Update state and broadcast changes in realtime with WebSockets. No external pub/sub systems, no polling – just built-in low-latency events. - **Infinitely Scalable**: Automatically scale from zero to millions of concurrent actors. Pay only for what you use with instant scaling and no cold starts. - **Fault Tolerant**: Built-in error handling and recovery. Actors automatically restart on failure while preserving state integrity and continuing operations. ## When to Use Rivet Actors - **AI agents & sandboxes**: multi-step toolchains, conversation memory, sandbox orchestration. - **Multiplayer or collaborative apps**: CRDT docs, shared cursors, realtime dashboards, chat. - **Workflow automation**: background jobs, cron, rate limiters, durable queues, backpressure control. - **Data-intensive backends**: geo-distributed or per-tenant databases, in-memory caches, sharded SQL. - **Networking workloads**: WebSocket servers, custom protocols, local-first sync, edge fanout. ## Minimal Project ### Backend **actors.ts** ```ts import { actor, event, setup } from "rivetkit"; const counter = actor({ state: { count: 0 }, events: { count: event(), }, actions: { increment: (c, amount: number) => { c.state.count += amount; c.broadcast("count", c.state.count); return c.state.count; }, }, }); export const registry = setup({ use: { counter }, }); ``` **server.ts** Integrate with the user's existing server if applicable. Otherwise, default to Hono. ### No Framework ```typescript @nocheck import { registry } from "./actors"; export default registry.serve(); ``` ### Hono ```typescript @nocheck import { Hono } from "hono"; import { registry } from "./actors"; const app = new Hono(); app.all("/api/rivet/*", (c) => registry.handler(c.req.raw)); export default app; ``` ### Elysia ```typescript @nocheck import { Elysia } from "elysia"; import { registry } from "./actors"; const app = new Elysia() .all("/api/rivet/*", (c) => registry.handler(c.request)); export default app; ``` ### Client Docs Use the client SDK that matches your app: - [JavaScript Client](/docs/clients/javascript) - [React Client](/docs/clients/react) - [Swift Client](/docs/clients/swift) ## Actor Quick Reference ### In-Memory State Persistent data that survives restarts, crashes, and deployments. State is persisted on Rivet Cloud or Rivet self-hosted, so it survives restarts if the current process crashes or exits. ### Static Initial State ```ts import { actor } from "rivetkit"; const counter = actor({ state: { count: 0 }, actions: { increment: (c) => c.state.count += 1, }, }); ``` ### Dynamic Initial State ```ts import { actor } from "rivetkit"; interface CounterState { count: number; } const counter = actor({ state: { count: 0 } as CounterState, createState: (c, input: { start?: number }): CounterState => ({ count: input.start ?? 0, }), actions: { increment: (c) => c.state.count += 1, }, }); ``` [Documentation](/docs/actors/state) ### Keys Keys uniquely identify actor instances. Use compound keys (arrays) for hierarchical addressing: ```ts import { actor, setup } from "rivetkit"; import { createClient } from "rivetkit/client"; const chatRoom = actor({ state: { messages: [] as string[] }, actions: { getRoomInfo: (c) => ({ org: c.key[0], room: c.key[1] }), }, }); const registry = setup({ use: { chatRoom } }); const client = createClient(); // Compound key: [org, room] client.chatRoom.getOrCreate(["org-acme", "general"]); // Access key inside actor via c.key ``` Don't build keys with string interpolation like `"org:${userId}"` when `userId` contains user data. Use arrays instead to prevent key injection attacks. [Documentation](/docs/actors/keys) ### Input Pass initialization data when creating actors. ```ts import { actor, setup } from "rivetkit"; import { createClient } from "rivetkit/client"; const game = actor({ createState: (c, input: { mode: string }) => ({ mode: input.mode }), actions: {}, }); const registry = setup({ use: { game } }); const client = createClient(); // Client usage const gameHandle = client.game.getOrCreate(["game-1"], { createWithInput: { mode: "ranked" } }); ``` [Documentation](/docs/actors/input) ### Temporary Variables Temporary data that doesn't survive restarts. Use for non-serializable objects (event emitters, connections, etc). ### Static Initial Vars ```ts import { actor } from "rivetkit"; const counter = actor({ state: { count: 0 }, vars: { lastAccess: 0 }, actions: { increment: (c) => { c.vars.lastAccess = Date.now(); return c.state.count += 1; }, }, }); ``` ### Dynamic Initial Vars ```ts import { actor } from "rivetkit"; const counter = actor({ state: { count: 0 }, createVars: () => ({ emitter: new EventTarget(), }), actions: { increment: (c) => { c.vars.emitter.dispatchEvent(new Event("change")); return c.state.count += 1; }, }, }); ``` [Documentation](/docs/actors/ephemeral-variables) ### Actions Actions are the primary way clients and other actors communicate with an actor. ```ts import { actor } from "rivetkit"; const counter = actor({ state: { count: 0 }, actions: { increment: (c, amount: number) => (c.state.count += amount), getCount: (c) => c.state.count, }, }); ``` [Documentation](/docs/actors/actions) ### Events & Broadcasts Events enable real-time communication from actors to connected clients. ```ts import { actor, event } from "rivetkit"; const chatRoom = actor({ state: { messages: [] as string[] }, events: { newMessage: event<{ text: string }>(), }, actions: { sendMessage: (c, text: string) => { // Broadcast to ALL connected clients c.broadcast("newMessage", { text }); }, }, }); ``` [Documentation](/docs/actors/events) ### Connections Access the current connection via `c.conn` or all connected clients via `c.conns`. Use `c.conn.id` or `c.conn.state` to securely identify who is calling an action. Connection state is initialized via `connState` or `createConnState`, which receives parameters passed by the client on connect. ### Static Connection Initial State ```ts import { actor } from "rivetkit"; const chatRoom = actor({ state: {}, connState: { visitorId: 0 }, onConnect: (c, conn) => { conn.state.visitorId = Math.random(); }, actions: { whoAmI: (c) => c.conn.state.visitorId, }, }); ``` ### Dynamic Connection Initial State ```ts import { actor } from "rivetkit"; const chatRoom = actor({ state: {}, // params passed from client createConnState: (c, params: { userId: string }) => ({ userId: params.userId, }), actions: { // Access current connection's state and params whoAmI: (c) => ({ state: c.conn.state, params: c.conn.params, }), // Iterate all connections with c.conns notifyOthers: (c, text: string) => { for (const conn of c.conns.values()) { if (conn !== c.conn) conn.send("notification", { text }); } }, }, }); ``` [Documentation](/docs/actors/connections) ### Queues Use queues to process durable messages in order inside a `run` loop. ```ts import { actor, queue } from "rivetkit"; const counter = actor({ state: { value: 0 }, queues: { increment: queue<{ amount: number }>(), }, run: async (c) => { for await (const message of c.queue.iter()) { c.state.value += message.body.amount; } }, }); ``` [Documentation](/docs/actors/queues) ### Workflows Use workflows when your `run` logic needs durable, replayable multi-step execution. ```ts import { actor, queue } from "rivetkit"; import { workflow } from "rivetkit/workflow"; const worker = actor({ state: { processed: 0 }, queues: { tasks: queue<{ url: string }>(), }, run: workflow(async (ctx) => { await ctx.loop("task-loop", async (loopCtx) => { const message = await loopCtx.queue.next("wait-task"); await loopCtx.step("process-task", async () => { await processTask(message.body.url); loopCtx.state.processed += 1; }); }); }), }); async function processTask(url: string): Promise { const res = await fetch(url, { method: "POST" }); if (!res.ok) throw new Error(`Task failed: ${res.status}`); } ``` [Documentation](/docs/actors/workflows) ### Actor-to-Actor Communication Actors can call other actors using `c.client()`. ```ts import { actor, setup } from "rivetkit"; const inventory = actor({ state: { stock: 100 }, actions: { reserve: (c, amount: number) => { c.state.stock -= amount; } } }); const order = actor({ state: {}, actions: { process: async (c) => { const client = c.client(); await client.inventory.getOrCreate(["main"]).reserve(1); }, }, }); const registry = setup({ use: { inventory, order } }); ``` [Documentation](/docs/actors/communicating-between-actors) ### Scheduling Schedule actions to run after a delay or at a specific time. Schedules persist across restarts, upgrades, and crashes. ```ts import { actor, event } from "rivetkit"; const reminder = actor({ state: { message: "" }, events: { reminder: event<{ message: string }>(), }, actions: { // Schedule action to run after delay (ms) setReminder: (c, message: string, delayMs: number) => { c.state.message = message; c.schedule.after(delayMs, "sendReminder"); }, // Schedule action to run at specific timestamp setReminderAt: (c, message: string, timestamp: number) => { c.state.message = message; c.schedule.at(timestamp, "sendReminder"); }, sendReminder: (c) => { c.broadcast("reminder", { message: c.state.message }); }, }, }); ``` [Documentation](/docs/actors/schedule) ### Destroying Actors Permanently delete an actor and its state using `c.destroy()`. ```ts import { actor } from "rivetkit"; const userAccount = actor({ state: { email: "", name: "" }, onDestroy: (c) => { console.log(`Account ${c.state.email} deleted`); }, actions: { deleteAccount: (c) => { c.destroy(); }, }, }); ``` [Documentation](/docs/actors/destroy) ### Lifecycle Hooks Actors support hooks for initialization, background processing, connections, networking, and state changes. Use `run` for long-lived background loops, and exit cleanly on shutdown with `c.aborted` or `c.abortSignal`. ```ts import { actor, event, queue } from "rivetkit"; interface RoomState { users: Record; name?: string; } interface RoomInput { roomName: string; } interface ConnState { userId: string; joinedAt: number; } const chatRoom = actor({ state: { users: {} } as RoomState, vars: { startTime: 0 }, connState: { userId: "", joinedAt: 0 } as ConnState, events: { stateChanged: event(), }, queues: { work: queue<{ task: string }>(), }, // State & vars initialization createState: (c, input: RoomInput): RoomState => ({ users: {}, name: input.roomName }), createVars: () => ({ startTime: Date.now() }), // Actor lifecycle onCreate: (c) => console.log("created", c.key), onDestroy: (c) => console.log("destroyed"), onWake: (c) => console.log("actor started"), onSleep: (c) => console.log("actor sleeping"), run: async (c) => { for await (const message of c.queue.iter()) { console.log("processing", message.body.task); } }, onStateChange: (c, newState) => c.broadcast("stateChanged", newState), // Connection lifecycle createConnState: (c, params): ConnState => ({ userId: (params as { userId: string }).userId, joinedAt: Date.now() }), onBeforeConnect: (c, params) => { /* validate auth */ }, onConnect: (c, conn) => console.log("connected:", conn.state.userId), onDisconnect: (c, conn) => console.log("disconnected:", conn.state.userId), // Networking onRequest: (c, req) => new Response(JSON.stringify(c.state)), onWebSocket: (c, socket) => socket.addEventListener("message", console.log), // Response transformation onBeforeActionResponse: (c: unknown, name: string, args: unknown[], output: Out): Out => output, actions: {}, }); ``` [Documentation](/docs/actors/lifecycle) ### Context Types When writing helper functions outside the actor definition, use `*ContextOf` to extract the correct context type. Do not manually define your own context interface — always derive it from the actor definition. ```ts import { actor, ActionContextOf } from "rivetkit"; const gameRoom = actor({ state: { players: [] as string[], score: 0 }, actions: { addPlayer: (c, playerId: string) => { validatePlayer(c, playerId); c.state.players.push(playerId); }, }, }); // Good: derive context type from actor definition function validatePlayer(c: ActionContextOf, playerId: string) { if (c.state.players.includes(playerId)) { throw new Error("Player already in room"); } } // Bad: don't manually define context types like this // type MyContext = { state: { players: string[] }; ... }; ``` [Documentation](/docs/actors/types) ### Errors Use `UserError` to throw errors that are safely returned to clients. Pass `metadata` to include structured data. Other errors are converted to generic "internal error" for security. ### Actor ```ts import { actor, UserError } from "rivetkit"; const user = actor({ state: { username: "" }, actions: { updateUsername: (c, username: string) => { if (username.length < 3) { throw new UserError("Username too short", { code: "username_too_short", metadata: { minLength: 3, actual: username.length }, }); } c.state.username = username; }, }, }); ``` ### Client ```ts import { actor, setup } from "rivetkit"; import { createClient, ActorError } from "rivetkit/client"; const user = actor({ state: { username: "" }, actions: { updateUsername: (c, username: string) => { c.state.username = username; } } }); const registry = setup({ use: { user } }); const client = createClient(); try { await client.user.getOrCreate([]).updateUsername("ab"); } catch (error) { if (error instanceof ActorError) { console.log(error.code); // "username_too_short" console.log(error.metadata); // { minLength: 3, actual: 2 } } } ``` [Documentation](/docs/actors/errors) ### Low-Level HTTP & WebSocket Handlers For custom protocols or integrating libraries that need direct access to HTTP `Request`/`Response` or WebSocket connections, use `onRequest` and `onWebSocket`. [HTTP Handler Documentation](/docs/actors/request-handler) · [WebSocket Handler Documentation](/docs/actors/websocket-handler) ### Icons & Names Customize how actors appear in the UI with display names and icons. It's recommended to always provide a name and icon to actors in order to make them easier to distinguish in the dashboard. ```typescript import { actor } from "rivetkit"; const chatRoom = actor({ options: { name: "Chat Room", icon: "💬", // or FontAwesome: "comments", "chart-line", etc. }, // ... }); ``` [Documentation](/docs/actors/appearance) ## Client Documentation Find the full client guides here: - [JavaScript Client](/docs/clients/javascript) - [React Client](/docs/clients/react) - [Swift Client](/docs/clients/swift) ## Common Patterns Actors scale naturally through isolated state and message-passing. Structure your applications with these patterns: [Documentation](/docs/actors/design-patterns) ### Actor Per Entity Create one actor per user, document, or room. Use compound keys to scope entities: ```ts client.ts import { createClient } from "rivetkit/client"; import type { registry } from "./actors"; const client = createClient(); // Single key: one actor per user client.user.getOrCreate(["user-123"]); // Compound key: document scoped to an organization client.document.getOrCreate(["org-acme", "doc-456"]); ``` ```ts actors.ts import { actor, setup } from "rivetkit"; export const user = actor({ state: { name: "" }, actions: {}, }); export const document = actor({ state: { content: "" }, actions: {}, }); export const registry = setup({ use: { user, document } }); ``` ### Coordinator & Data Actors **Data actors** handle core logic (chat rooms, game sessions, user data). **Coordinator actors** track and manage collections of data actors—think of them as an index. ```ts actors.ts import { actor, setup } from "rivetkit"; // Coordinator: tracks chat rooms within an organization export const chatRoomList = actor({ state: { rooms: [] as string[] }, actions: { addRoom: async (c, name: string) => { // Create the chat room actor const client = c.client(); await client.chatRoom.create([c.key[0], name]); c.state.rooms.push(name); }, listRooms: (c) => c.state.rooms, }, }); // Data actor: handles a single chat room export const chatRoom = actor({ state: { messages: [] as string[] }, actions: { send: (c, msg: string) => { c.state.messages.push(msg); }, }, }); export const registry = setup({ use: { chatRoomList, chatRoom } }); ``` ```ts client.ts import { createClient } from "rivetkit/client"; import type { registry } from "./actors"; const client = createClient(); // Coordinator per org const coordinator = client.chatRoomList.getOrCreate(["org-acme"]); await coordinator.addRoom("general"); await coordinator.addRoom("random"); // Access chat rooms created by coordinator client.chatRoom.get(["org-acme", "general"]); ``` ### Run Loop Use a `run` loop for continuous background work inside an actor. Process queue messages in order, run logic on intervals, stream AI responses, or coordinate long-running tasks. ```ts import { actor, queue, setup } from "rivetkit"; const counterWorker = actor({ state: { value: 0 }, queues: { mutate: queue<{ delta: number }>(), }, run: async (c) => { for await (const message of c.queue.iter()) { c.state.value += message.body.delta; } }, actions: { getValue: (c) => c.state.value, }, }); const registry = setup({ use: { counterWorker } }); ``` ### Workflow Loop Use this pattern for long-lived, durable workflows that initialize resources, process commands in a loop, then clean up. ```ts import { actor, queue, setup } from "rivetkit"; import { Loop, workflow } from "rivetkit/workflow"; type WorkMessage = { amount: number }; type ControlMessage = { type: "stop"; reason: string }; const worker = actor({ state: { phase: "idle" as "idle" | "running" | "stopped", processed: 0, total: 0, stopReason: null as string | null, }, queues: { work: queue(), control: queue(), }, run: workflow(async (ctx) => { await ctx.step("setup", async () => { await fetch("https://api.example.com/workers/init", { method: "POST" }); ctx.state.phase = "running"; ctx.state.stopReason = null; }); const stopReason = await ctx.loop("worker-loop", async (loopCtx) => { const message = await loopCtx.queue.next("wait-command", { names: ["work", "control"], }); if (message.name === "work") { await loopCtx.step("apply-work", async () => { await fetch("https://api.example.com/workers/process", { method: "POST", body: JSON.stringify({ amount: message.body.amount }), }); loopCtx.state.processed += 1; loopCtx.state.total += message.body.amount; }); return; } return Loop.break((message.body as ControlMessage).reason); }); await ctx.step("teardown", async () => { await fetch("https://api.example.com/workers/shutdown", { method: "POST" }); ctx.state.phase = "stopped"; ctx.state.stopReason = stopReason; }); }), }); const registry = setup({ use: { worker } }); ``` [Documentation](/docs/actors/workflows) ### Actions vs Queues - **Actions** are not durable. Use them for realtime reads, ephemeral data, and low-latency communication like player input. - **Queues** are durable. Use them to serialize mutations through the run loop, avoiding race conditions with SQLite and other local state. Callers can still wait for a response from queued work. ### Authentication, Security, & CORS - Validate credentials in `onBeforeConnect` or `createConnState` and throw an error to reject unauthorized connections. - Use `c.conn.state` to securely identify users in actions rather than trusting action parameters. - For cross-origin access, validate the request origin in `onBeforeConnect`. [Authentication Documentation](/docs/actors/authentication) · [CORS Documentation](/docs/general/cors) ### Versions & Upgrades When deploying new code, set a version number so Rivet can route new actors to the latest runner and optionally drain old ones. Use a build timestamp, git commit count, or CI build number as the version. It is very important to [configure versioning](/docs/actors/versions) before deploying to production. Without versioning, actors can regress by running on older runner versions, and existing actors will never be forced to migrate to new runners. They will continue running indefinitely on the old runners until they exit. [Documentation](/docs/actors/versions) ### Anti-Patterns #### Never build a "god" actor Do not put all your logic in a single actor. A god actor serializes every operation through one bottleneck, kills parallelism, and makes the entire system fail as a unit. Split into focused actors per entity. #### Never create an actor per request Actors are long-lived and maintain state across requests. Creating a new actor for every incoming request throws away the core benefit of the model and wastes resources on actor creation and teardown. Use actors for persistent entities and regular functions for stateless work. ## Reference Map ### Actors - [Access Control](reference/actors/access-control.md) - [Actions](reference/actors/actions.md) - [Actor Keys](reference/actors/keys.md) - [Actor Scheduling](reference/actors/schedule.md) - [Actor Statuses](reference/actors/statuses.md) - [AI and User-Generated Rivet Actors](reference/actors/ai-and-user-generated-actors.md) - [Authentication](reference/actors/authentication.md) - [Cloudflare Workers Quickstart](reference/actors/quickstart/cloudflare-workers.md) - [Communicating Between Actors](reference/actors/communicating-between-actors.md) - [Connections](reference/actors/connections.md) - [Debugging](reference/actors/debugging.md) - [Design Patterns](reference/actors/design-patterns.md) - [Destroying Actors](reference/actors/destroy.md) - [Ephemeral Variables](reference/actors/ephemeral-variables.md) - [Errors](reference/actors/errors.md) - [External SQL Database](reference/actors/postgres.md) - [Fetch and WebSocket Handler](reference/actors/fetch-and-websocket-handler.md) - [Helper Types](reference/actors/helper-types.md) - [Icons & Names](reference/actors/appearance.md) - [In-Memory State](reference/actors/state.md) - [Input Parameters](reference/actors/input.md) - [Lifecycle](reference/actors/lifecycle.md) - [Limits](reference/actors/limits.md) - [Low-Level HTTP Request Handler](reference/actors/request-handler.md) - [Low-Level KV Storage](reference/actors/kv.md) - [Low-Level WebSocket Handler](reference/actors/websocket-handler.md) - [Metadata](reference/actors/metadata.md) - [Next.js Quickstart](reference/actors/quickstart/next-js.md) - [Node.js & Bun Quickstart](reference/actors/quickstart/backend.md) - [Queues & Run Loops](reference/actors/queues.md) - [React Quickstart](reference/actors/quickstart/react.md) - [Realtime](reference/actors/events.md) - [Scaling & Concurrency](reference/actors/scaling.md) - [Sharing and Joining State](reference/actors/sharing-and-joining-state.md) - [SQLite](reference/actors/sqlite.md) - [SQLite + Drizzle](reference/actors/sqlite-drizzle.md) - [Testing](reference/actors/testing.md) - [Troubleshooting](reference/actors/troubleshooting.md) - [Types](reference/actors/types.md) - [Vanilla HTTP API](reference/actors/http-api.md) - [Versions & Upgrades](reference/actors/versions.md) - [Workflows](reference/actors/workflows.md) ### Clients - [Node.js & Bun](reference/clients/javascript.md) - [React](reference/clients/react.md) - [Swift](reference/clients/swift.md) - [SwiftUI](reference/clients/swiftui.md) ### Connect - [Deploy To Amazon Web Services Lambda](reference/connect/aws-lambda.md) - [Deploying to AWS ECS](reference/connect/aws-ecs.md) - [Deploying to Cloudflare Workers](reference/connect/cloudflare-workers.md) - [Deploying to Freestyle](reference/connect/freestyle.md) - [Deploying to Google Cloud Run](reference/connect/gcp-cloud-run.md) - [Deploying to Hetzner](reference/connect/hetzner.md) - [Deploying to Kubernetes](reference/connect/kubernetes.md) - [Deploying to Railway](reference/connect/railway.md) - [Deploying to Vercel](reference/connect/vercel.md) - [Deploying to VMs & Bare Metal](reference/connect/vm-and-bare-metal.md) - [Supabase](reference/connect/supabase.md) ### Cookbook - [Multiplayer Game](reference/cookbook/multiplayer-game.md) ### General - [Actor Configuration](reference/general/actor-configuration.md) - [Architecture](reference/general/architecture.md) - [Cross-Origin Resource Sharing](reference/general/cors.md) - [Documentation for LLMs & AI](reference/general/docs-for-llms.md) - [Edge Networking](reference/general/edge.md) - [Endpoints](reference/general/endpoints.md) - [Environment Variables](reference/general/environment-variables.md) - [HTTP Server](reference/general/http-server.md) - [Logging](reference/general/logging.md) - [Production Checklist](reference/general/production-checklist.md) - [Registry Configuration](reference/general/registry-configuration.md) - [Runtime Modes](reference/general/runtime-modes.md) ### Self Hosting - [Configuration](reference/self-hosting/configuration.md) - [Docker Compose](reference/self-hosting/docker-compose.md) - [Docker Container](reference/self-hosting/docker-container.md) - [File System](reference/self-hosting/filesystem.md) - [Installing Rivet Engine](reference/self-hosting/install.md) - [Kubernetes](reference/self-hosting/kubernetes.md) - [Multi-Region](reference/self-hosting/multi-region.md) - [PostgreSQL](reference/self-hosting/postgres.md) - [Production Checklist](reference/self-hosting/production-checklist.md) - [Railway Deployment](reference/self-hosting/railway.md) - [Render Deployment](reference/self-hosting/render.md) --- *Source: https://skills.yangsir.net/skill/ssh2-rivetkit* *Markdown mirror: https://skills.yangsir.net/api/skill/ssh2-rivetkit/markdown*