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import type { InboundDebounceByProvider } from "../config/types.messages.js";
import type { OpenClawConfig } from "../config/types.openclaw.js";
const resolveMs = (value: unknown): number | undefined => {
if (typeof value !== "number" || !Number.isFinite(value)) {
return undefined;
}
return Math.max(0, Math.trunc(value));
};
const resolveChannelOverride = (params: {
byChannel?: InboundDebounceByProvider;
channel: string;
}): number | undefined => {
if (!params.byChannel) {
return undefined;
}
return resolveMs(params.byChannel[params.channel]);
};
export function resolveInboundDebounceMs(params: {
cfg: OpenClawConfig;
channel: string;
overrideMs?: number;
}): number {
const inbound = params.cfg.messages?.inbound;
const override = resolveMs(params.overrideMs);
const byChannel = resolveChannelOverride({
byChannel: inbound?.byChannel,
channel: params.channel,
});
const base = resolveMs(inbound?.debounceMs);
return override ?? byChannel ?? base ?? 0;
}
type DebounceBuffer<T> = {
items: T[];
timeout: ReturnType<typeof setTimeout> | null;
debounceMs: number;
releaseReady: () => void;
readyReleased: boolean;
task: Promise<void>;
};
const DEFAULT_MAX_TRACKED_KEYS = 2048;
export type InboundDebounceCreateParams<T> = {
debounceMs: number;
maxTrackedKeys?: number;
buildKey: (item: T) => string | null | undefined;
shouldDebounce?: (item: T) => boolean;
resolveDebounceMs?: (item: T) => number | undefined;
onFlush: (items: T[]) => Promise<void>;
onError?: (err: unknown, items: T[]) => void;
};
export function createInboundDebouncer<T>(params: InboundDebounceCreateParams<T>) {
const buffers = new Map<string, DebounceBuffer<T>>();
const keyChains = new Map<string, Promise<void>>();
const defaultDebounceMs = Math.max(0, Math.trunc(params.debounceMs));
const maxTrackedKeys = Math.max(1, Math.trunc(params.maxTrackedKeys ?? DEFAULT_MAX_TRACKED_KEYS));
const resolveDebounceMs = (item: T) => {
const resolved = params.resolveDebounceMs?.(item);
if (typeof resolved !== "number" || !Number.isFinite(resolved)) {
return defaultDebounceMs;
}
return Math.max(0, Math.trunc(resolved));
};
const runFlush = async (items: T[]) => {
try {
await params.onFlush(items);
} catch (err) {
try {
params.onError?.(err, items);
} catch {
// Flush failures are reported via onError, but this helper stays
// non-throwing so keyed chains can continue processing later items.
}
}
};
const enqueueKeyTask = (key: string, task: () => Promise<void>) => {
const previous = keyChains.get(key) ?? Promise.resolve();
const next = previous.catch(() => undefined).then(task);
const settled = next.catch(() => undefined);
keyChains.set(key, settled);
const cleanup = () => {
if (keyChains.get(key) === settled) {
keyChains.delete(key);
}
};
settled.then(cleanup, cleanup);
return next;
};
const enqueueReservedKeyTask = (key: string, task: () => Promise<void>) => {
let readyReleased = false;
let releaseReady!: () => void;
const ready = new Promise<void>((resolve) => {
releaseReady = resolve;
});
return {
task: enqueueKeyTask(key, async () => {
await ready;
await task();
}),
release: () => {
if (readyReleased) {
return;
}
readyReleased = true;
releaseReady();
},
};
};
const releaseBuffer = (buffer: DebounceBuffer<T>) => {
if (buffer.readyReleased) {
return;
}
buffer.readyReleased = true;
buffer.releaseReady();
};
const flushBuffer = async (key: string, buffer: DebounceBuffer<T>) => {
if (buffers.get(key) === buffer) {
buffers.delete(key);
}
if (buffer.timeout) {
clearTimeout(buffer.timeout);
buffer.timeout = null;
}
// Reserve each key's execution slot as soon as the first buffered item
// arrives, so later same-key work cannot overtake a timer-backed flush.
releaseBuffer(buffer);
await buffer.task;
};
const flushKey = async (key: string) => {
const buffer = buffers.get(key);
if (!buffer) {
return;
}
await flushBuffer(key, buffer);
};
const scheduleFlush = (key: string, buffer: DebounceBuffer<T>) => {
if (buffer.timeout) {
clearTimeout(buffer.timeout);
}
buffer.timeout = setTimeout(async () => {
await flushBuffer(key, buffer);
}, buffer.debounceMs);
buffer.timeout.unref?.();
};
const canTrackKey = (key: string) => {
if (buffers.has(key) || keyChains.has(key)) {
return true;
}
return new Set([...buffers.keys(), ...keyChains.keys()]).size < maxTrackedKeys;
};
const enqueue = async (item: T) => {
const key = params.buildKey(item);
const debounceMs = resolveDebounceMs(item);
const canDebounce = debounceMs > 0 && (params.shouldDebounce?.(item) ?? true);
if (!canDebounce || !key) {
if (key) {
if (buffers.has(key)) {
// Reserve the keyed immediate slot before forcing the pending buffer
// to flush so fire-and-forget callers cannot be overtaken.
const reservedTask = enqueueReservedKeyTask(key, async () => {
await runFlush([item]);
});
try {
await flushKey(key);
} finally {
reservedTask.release();
}
await reservedTask.task;
return;
}
if (keyChains.has(key)) {
await enqueueKeyTask(key, async () => {
await runFlush([item]);
});
return;
}
await runFlush([item]);
} else {
await runFlush([item]);
}
return;
}
const existing = buffers.get(key);
if (existing) {
existing.items.push(item);
existing.debounceMs = debounceMs;
scheduleFlush(key, existing);
return;
}
if (!canTrackKey(key)) {
// When the debounce map is saturated, fall back to immediate keyed work
// instead of buffering, but still preserve same-key ordering.
await enqueueKeyTask(key, async () => {
await runFlush([item]);
});
return;
}
let buffer!: DebounceBuffer<T>;
const reservedTask = enqueueReservedKeyTask(key, async () => {
if (buffer.items.length === 0) {
return;
}
await runFlush(buffer.items);
});
buffer = {
items: [item],
timeout: null,
debounceMs,
releaseReady: reservedTask.release,
readyReleased: false,
task: reservedTask.task,
};
buffers.set(key, buffer);
scheduleFlush(key, buffer);
};
return { enqueue, flushKey };
}
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(vorverarbeitet am 2026-04-27)
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