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---
title: "Background injection"
sidebarTitle: "Background injection"
description: "Inject context from background work into the agent's conversation — self-review, RAG augmentation, or any async analysis."
---
## Overview
`chat.inject()` queues model messages for injection into the conversation. Messages are picked up at the start of the next turn or at the next `prepareStep` boundary (between tool-call steps).
This is the backend counterpart to [pending messages](/ai-chat/pending-messages) — pending messages come from the user via the frontend, while `chat.inject()` comes from your task code.
## Basic usage
```ts
import { chat } from "@trigger.dev/sdk/ai";
// Queue a system message for injection
chat.inject([
{
role: "system",
content: "The user's account was just upgraded to Pro.",
},
]);
```
Messages are appended to the model messages before the next LLM inference call. The LLM sees them as part of the conversation context.
## Common pattern: defer + inject
The most powerful pattern combines `chat.defer()` (background work) with `chat.inject()` (inject results). Background work runs in parallel with the idle wait between turns, and results are injected before the next response.
```ts
export const myChat = chat.agent({
id: "my-chat",
onTurnComplete: async ({ messages }) => {
// Kick off background analysis — doesn't block the turn
chat.defer(
(async () => {
const analysis = await analyzeConversation(messages);
chat.inject([
{
role: "system",
content: `[Analysis of conversation so far]\n\n${analysis}`,
},
]);
})()
);
},
run: async ({ messages, signal }) => {
return streamText({
...chat.toStreamTextOptions({ registry }),
messages,
abortSignal: signal,
stopWhen: stepCountIs(15),
});
},
});
```
### Timing
1. Turn completes, `onTurnComplete` fires
2. `chat.defer()` registers the background work
3. The run immediately starts waiting for the next message (no blocking)
4. Background work completes, `chat.inject()` queues the messages
5. User sends next message, turn starts
6. Injected messages are appended before `run()` executes
7. The LLM sees the injected context alongside the new user message
If the background work finishes *during* a tool-call loop (not between turns), the messages are picked up at the next `prepareStep` boundary instead.
## Example: self-review
A cheap model reviews the agent's response after each turn and injects coaching for the next one. Uses [Prompts](/ai/prompts) for the review prompt and `generateObject` for structured output.
```ts
import { chat } from "@trigger.dev/sdk/ai";
import { prompts } from "@trigger.dev/sdk";
import { streamText, generateObject, createProviderRegistry, stepCountIs } from "ai";
import { anthropic } from "@ai-sdk/anthropic";
import { z } from "zod";
const registry = createProviderRegistry({ anthropic });
const selfReviewPrompt = prompts.define({
id: "self-review",
model: "anthropic:claude-haiku-4-5",
content: `You are a conversation quality reviewer. Analyze the assistant's most recent response.
Focus on:
- Whether the response answered the user's question
- Missed opportunities to use tools or provide more detail
- Tone mismatches
Be concise. Only flag issues worth fixing.`,
});
export const myChat = chat.agent({
id: "my-chat",
onTurnComplete: async ({ messages }) => {
chat.defer(
(async () => {
const resolved = await selfReviewPrompt.resolve({});
const review = await generateObject({
model: registry.languageModel(resolved.model ?? "anthropic:claude-haiku-4-5"),
...resolved.toAISDKTelemetry(),
system: resolved.text,
prompt: messages
.filter((m) => m.role === "user" || m.role === "assistant")
.map((m) => {
const text =
typeof m.content === "string"
? m.content
: Array.isArray(m.content)
? m.content
.filter((p: any) => p.type === "text")
.map((p: any) => p.text)
.join("")
: "";
return `${m.role}: ${text}`;
})
.join("\n\n"),
schema: z.object({
needsImprovement: z.boolean(),
suggestions: z.array(z.string()),
}),
});
if (review.object.needsImprovement) {
chat.inject([
{
role: "system",
content: `[Self-review]\n\n${review.object.suggestions.map((s) => `- ${s}`).join("\n")}\n\nApply these naturally.`,
},
]);
}
})()
);
},
run: async ({ messages, signal }) => {
return streamText({
...chat.toStreamTextOptions({ registry }),
messages,
abortSignal: signal,
stopWhen: stepCountIs(15),
});
},
});
```
The self-review runs on `claude-haiku-4-5` (fast, cheap) in the background. If the user sends another message before it completes, the coaching is still injected — `chat.inject()` persists across the idle wait.
## Other use cases
- **RAG augmentation**: After each turn, fetch relevant documents and inject them as context for the next response
- **Safety checks**: Run a moderation model on the response, inject warnings if issues are detected
- **Fact-checking**: Verify claims in the response using search tools, inject corrections
- **Context enrichment**: Look up user/account data based on what was discussed, inject it as system context
## `chat.defer` standalone
`chat.defer()` is also useful on its own, without `chat.inject()`. Any work whose timing has no resume implication — analytics, audit logs, search-index writes, cache warming — can run in parallel with streaming instead of in the critical path. All deferred promises are awaited (with a 5s timeout) before `onTurnComplete` fires.
```ts
export const myChat = chat.agent({
id: "my-chat",
onTurnStart: async ({ chatId, runId }) => {
// Analytics — fire-and-forget, irrelevant to resume.
chat.defer(analytics.track("turn_started", { chatId, runId }));
},
run: async ({ messages, signal }) => {
return streamText({ model: anthropic("claude-sonnet-4-5"), messages, abortSignal: signal });
},
});
```
`chat.defer()` can be called from anywhere during a turn — hooks, `run()`, or nested helpers. All deferred promises are collected and awaited together before `onTurnComplete`.
<Warning>
**Don't use `chat.defer()` for the message-history write in `onTurnStart`.** That write must land *before* the model starts streaming, otherwise a mid-stream page refresh will read `[]` from your DB and lose the user's message from the rendered conversation. See [Database persistence — `onTurnStart`](/ai-chat/patterns/database-persistence#onturnstart). Reserve `chat.defer` for writes whose timing has no resume implication.
</Warning>
## How it differs from pending messages
| | `chat.inject()` | [Pending messages](/ai-chat/pending-messages) |
|---|---|---|
| **Source** | Backend task code | Frontend user input |
| **Triggered by** | Your code (e.g. `onTurnComplete` + `chat.defer()`) | User sending a message during streaming |
| **Injection point** | Start of next turn, or next `prepareStep` boundary | Next `prepareStep` boundary only |
| **Message role** | Any (`system`, `user`, `assistant`) | Typically `user` |
| **Frontend visibility** | Not visible unless you write custom `data-*` chunks | Visible via `usePendingMessages` hook |
## API reference
### chat.inject()
```ts
chat.inject(messages: ModelMessage[]): void
```
Queue model messages for injection at the next opportunity. Messages persist across the idle wait between turns — they are not reset when a new turn starts.
**Parameters:**
| Parameter | Type | Description |
|-----------|------|-------------|
| `messages` | `ModelMessage[]` | Model messages to inject (from the `ai` package) |
Messages are drained (consumed) when:
1. A new turn starts — before `run()` executes
2. A `prepareStep` boundary is reached — between tool-call steps during streaming
<Note>
`chat.inject()` writes to an in-memory queue in the current process. It works from any code running in the same task — lifecycle hooks, deferred work, tool execute functions, etc. It does not work from subtasks or other runs.
</Note>