packages/trigger-sdk/skills/trigger-authoring-chat-agent/SKILL.md
A chat.agent runs an entire conversation as one long-lived Trigger.dev task. It wakes when a
message arrives, freezes when none do, and in-memory state survives page refreshes, deploys, idle
gaps, and crashes. Your code is the loop you would write anyway: messages in, streamText out.
There are no API routes. The frontend talks to the agent through a TriggerChatTransport, so
history accumulates server-side and the client ships only the new message each turn.
Works with Vercel AI SDK v5, v6, or v7. On v7 also install @ai-sdk/otel so model calls are traced
(the SDK registers it for you).
Three pieces: the agent task, two server actions, and the frontend transport.
import { chat } from "@trigger.dev/sdk/ai";
import { streamText, stepCountIs } from "ai";
import { anthropic } from "@ai-sdk/anthropic";
export const myChat = chat.agent({
id: "my-chat",
run: async ({ messages, signal }) =>
streamText({
// Spread this FIRST. See "Common mistakes".
...chat.toStreamTextOptions(),
model: anthropic("claude-sonnet-4-5"),
messages,
abortSignal: signal,
stopWhen: stepCountIs(15),
}),
});
run receives messages already converted to ModelMessage[] (the SDK converts the frontend's
UIMessage[] for you) plus a signal that aborts on stop or cancel. Returning the
StreamTextResult auto-pipes it to the frontend.
Both run on your server, so the browser never holds your environment secret key. This is also where per-user / per-plan authorization and any paired DB writes live.
"use server";
import { auth } from "@trigger.dev/sdk";
import { chat } from "@trigger.dev/sdk/ai";
// Creates the Session + first run, returns a session PAT. Idempotent on (env, chatId).
export const startChatSession = chat.createStartSessionAction("my-chat");
// Pure mint. The transport calls this on 401/403 to refresh an expired token.
export async function mintChatAccessToken(chatId: string) {
return auth.createPublicToken({
scopes: { read: { sessions: chatId }, write: { sessions: chatId } },
expirationTime: "1h",
});
}
"use client";
import { useState } from "react";
import { useChat } from "@ai-sdk/react";
import { useTriggerChatTransport } from "@trigger.dev/sdk/chat/react";
import type { myChat } from "@/trigger/chat";
import { mintChatAccessToken, startChatSession } from "@/app/actions";
export function Chat() {
const transport = useTriggerChatTransport<typeof myChat>({
task: "my-chat", // typeof myChat gives compile-time task-id validation
accessToken: ({ chatId }) => mintChatAccessToken(chatId),
startSession: ({ chatId, clientData }) => startChatSession({ chatId, clientData }),
});
const { messages, sendMessage, stop, status } = useChat({ transport });
const [input, setInput] = useState("");
// render messages, a form that calls sendMessage({ text: input }),
// and a Stop button (onClick={stop}) while status === "streaming".
}
The transport is memoized (created once, reused across renders). Passing typeof myChat flows the
agent's message type through useChat.
Return the streamText result from run for the simple case. When streamText is called deep
inside nested helpers, call await chat.pipe(result) from anywhere in the task instead, and let
run resolve void.
export const agentChat = chat.agent({
id: "agent-chat",
run: async ({ messages }) => {
await runAgentLoop(messages); // don't return; pipe inside
},
});
async function runAgentLoop(messages: ModelMessage[]) {
const result = streamText({
...chat.toStreamTextOptions(),
model: anthropic("claude-sonnet-4-5"),
messages,
});
await chat.pipe(result); // works from anywhere in the task
}
Declare tools on chat.agent({ tools }), read them back typed from the run() payload, and pass
that set to chat.toStreamTextOptions({ tools }). One declaration flows everywhere.
import { tool, stepCountIs } from "ai";
import { z } from "zod";
const tools = {
searchDocs: tool({
description: "Search the docs.",
inputSchema: z.object({ query: z.string() }),
execute: async ({ query }) => searchIndex(query),
}),
};
export const myChat = chat.agent({
id: "my-chat",
tools, // so toModelOutput survives across turns
run: async ({ messages, tools, signal }) =>
streamText({
...chat.toStreamTextOptions({ tools }), // same set, handed back typed
model: anthropic("claude-sonnet-4-5"),
messages,
abortSignal: signal,
stopWhen: stepCountIs(15),
}),
});
tools also accepts a function (event) => ToolSet resolved per turn, where event carries
chatId, turn, continuation, and clientData.
data-* parts written via chat.response.write() in run() (or writer.write() in hooks)
persist into responseMessage.parts and surface in onTurnComplete. Add transient: true to
stream them without persisting. Writes via chat.stream are always ephemeral.
// In run() - persists, surfaces in onTurnComplete's responseMessage
chat.response.write({ type: "data-context", data: { searchResults } });
// In a hook via writer - streams but does NOT persist
writer.write({ type: "data-progress", id: "search", data: { percent: 50 }, transient: true });
For typed data-* parts or a tool map, build the agent through chat.withUIMessage<T>() and
chat.withClientData({ schema }). Builder methods chain in any order; builder hooks run before the
matching task hook. streamOptions becomes the default uiMessageStreamOptions (shallow-merged,
agent wins).
export const myChat = chat
.withUIMessage<MyChatUIMessage>({ streamOptions: { sendReasoning: true } })
.withClientData({ schema: z.object({ userId: z.string() }) })
.agent({
id: "my-chat",
tools: myTools,
onTurnStart: async ({ uiMessages, writer }) => {
writer.write({ type: "data-turn-status", data: { status: "preparing" } });
},
run: async ({ messages, tools, signal }) =>
streamText({ ...chat.toStreamTextOptions({ tools }), model, messages, abortSignal: signal }),
});
Build MyChatUIMessage as UIMessage<unknown, MyDataTypes, InferUITools<typeof tools>> (or, for
tools only, InferChatUIMessageFromTools<typeof tools> from @trigger.dev/sdk/ai). On the
frontend, narrow useChat with InferChatUIMessage<typeof myChat> from @trigger.dev/sdk/chat/react.
chat.agent accepts hooks that fire in a fixed per-turn order:
onValidateMessages -> hydrateMessages -> onChatStart (chat's first message only)
-> onTurnStart -> run() -> onBeforeTurnComplete -> onTurnComplete
onBoot fires once per worker process (every fresh boot, including continuation runs) and is where
chat.local, DB connections, and per-process state belong. onChatStart fires only on the chat's
first message. Suspend/resume use onChatSuspend / onChatResume. Config options include
tools, clientDataSchema, maxTurns (100), turnTimeout ("1h"), idleTimeoutInSeconds (30),
uiMessageStreamOptions, and exitAfterPreloadIdle. There is no generic retry; chat.agent
runs with maxAttempts: 1 internally.
Stop is load-bearing: the signal passed to run aborts on stop or cancel. Forward it as
abortSignal to streamText, or the Stop button updates the UI while the model keeps generating
server-side.
run: async ({ messages, signal }) =>
streamText({ ...chat.toStreamTextOptions(), model, messages, abortSignal: signal, stopWhen: stepCountIs(15) });
streamText routeThere is no API route in this model. The transport replaces the route round-trip, so:
streamText call into run. It already receives pre-converted ModelMessage[].StreamTextResult (it auto-pipes) and add ...chat.toStreamTextOptions() first.api URL for useTriggerChatTransport; useChat stays the same shape.CRITICAL: forgetting ...chat.toStreamTextOptions().
// Wrong - compaction / steering / background injection silently no-op
return streamText({ model, messages, abortSignal: signal });
// Correct - spread FIRST so explicit overrides win
return streamText({ ...chat.toStreamTextOptions(), model, messages, abortSignal: signal });
It wires the prepareStep callback behind compaction, mid-turn steering, and background
injection, injects the system prompt from chat.prompt(), resolves the registry model, and adds
telemetry. Omitting it makes all of those silently no-op with no error.
Declaring tools only on streamText. Also declare them on chat.agent({ tools }), read them
back from run, and pass chat.toStreamTextOptions({ tools }). Otherwise each tool's
toModelOutput runs on turn 1 but is dropped when history is re-converted on later turns.
Not forwarding signal for stop. Without abortSignal: signal, Stop updates the UI but the
model keeps generating server-side.
Initializing chat.local in onChatStart. Initialize it in onBoot. onChatStart fires
once per chat, so continuation runs skip it and crash with
chat.local can only be modified after initialization. onBoot fires on every fresh worker.
Minting tokens in the browser. Never expose the environment secret key client-side. Mint via the two server actions; the transport calls them.
Clearing lastEventId on chat.endRun(). Keep the cursor for the Session lifetime; clear it
only when the Session itself closes. It is sessionId-keyed, so clearing forces a resubscribe from
seq_num=0 that can hit the prior turn's stale turn-complete and close the stream empty.
Returning the raw error from uiMessageStreamOptions.onError. It leaks internals (keys,
stack traces). Return a sanitized string instead.
trigger-chat-agent-advanced skill - lifecycle hooks in depth, sessions, raw-task primitives
(chat.createSession, chat.customAgent, chat.stream), compaction, HITL approvals, recovery.trigger-realtime-and-frontend skill - Realtime hooks and frontend streaming beyond the chat transport.trigger-authoring-tasks skill - base task() semantics, ctx, and standard lifecycle hooks.Reference docs ship beside this skill in the same package, read them locally (no network), pinned to your installed version. The sources: frontmatter above lists every doc this skill draws from, all under @trigger.dev/sdk/docs/ai-chat/. Start with quick-start.mdx, backend.mdx, tools.mdx, types.mdx, frontend.mdx.
A chat.agent is a Trigger.dev task, so it builds and deploys like any other. For trigger.config.ts and build extensions (Prisma, Playwright, Python, FFmpeg, etc. — e.g. when a tool needs them), read the bundled config docs under @trigger.dev/sdk/docs/config/ (extensions are in config/extensions/, starting with overview.mdx).
This skill is bundled inside @trigger.dev/sdk and read directly from node_modules, so it always matches your installed SDK version (see the adjacent package.json). The full documentation for these APIs ships alongside it under @trigger.dev/sdk/docs/.