Promise queue with concurrency control
Useful for rate-limiting async (or sync) operations. For example, when interacting with a REST API or when doing CPU/memory intensive tasks.
$ npm install p-queue
Here we run only one promise at the time. For example, set concurrency to 4 to run four promises at the same time.
const {default: PQueue} = require('p-queue');
const got = require('got');
const queue = new PQueue({concurrency: 1});
(async () => {
await queue.add(() => got('https://sindresorhus.com'));
console.log('Done: sindresorhus.com');
})();
(async () => {
await queue.add(() => got('https://avajs.dev'));
console.log('Done: avajs.dev');
})();
(async () => {
const task = await getUnicornTask();
await queue.add(task);
console.log('Done: Unicorn task');
})();Returns a new queue instance, which is an EventEmitter3 subclass.
Type: object
Type: number
Default: Infinity
Minimum: 1
Concurrency limit.
Type: number
Per-operation timeout in milliseconds. Operations fulfill once timeout elapses if they haven't already.
Type: boolean
Default: false
Whether or not a timeout is considered an exception.
Type: boolean
Default: true
Whether queue tasks within concurrency limit, are auto-executed as soon as they're added.
Type: Function
Class with a enqueue and dequeue method, and a size getter. See the Custom QueueClass section.
Type: number
Default: Infinity
Minimum: 1
The max number of runs in the given interval of time.
Type: number
Default: 0
Minimum: 0
The length of time in milliseconds before the interval count resets. Must be finite.
Type: boolean
Default: false
If true, specifies that any pending Promises, should be carried over into the next interval and counted against the intervalCap. If false, any of those pending Promises will not count towards the next intervalCap.
PQueue instance.
Adds a sync or async task to the queue. Always returns a promise.
Type: Function
Promise-returning/async function.
Type: object
Type: number
Default: 0
Priority of operation. Operations with greater priority will be scheduled first.
Same as .add(), but accepts an array of sync or async functions and returns a promise that resolves when all functions are resolved.
Put queue execution on hold.
Start (or resume) executing enqueued tasks within concurrency limit. No need to call this if queue is not paused (via options.autoStart = false or by .pause() method.)
Returns this (the instance).
Returns a promise that settles when the queue becomes empty.
Can be called multiple times. Useful if you for example add additional items at a later time.
Returns a promise that settles when the queue becomes empty, and all promises have completed; queue.size === 0 && queue.pending === 0.
The difference with .onEmpty is that .onIdle guarantees that all work from the queue has finished. .onEmpty merely signals that the queue is empty, but it could mean that some promises haven't completed yet.
Clear the queue.
Size of the queue.
Size of the queue, filtered by the given options.
For example, this can be used to find the number of items remaining in the queue with a specific priority level.
const queue = new PQueue();
queue.add(async () => 'π¦', {priority: 1});
queue.add(async () => 'π¦', {priority: 0});
queue.add(async () => 'π¦', {priority: 1});
console.log(queue.sizeBy({priority: 1}));
//=> 2
console.log(queue.sizeBy({priority: 0}));
//=> 1Number of pending promises.
Whether the queue is currently paused.
Emitted as each item is processed in the queue for the purpose of tracking progress.
const delay = require('delay');
const {default: PQueue} = require('p-queue');
const queue = new PQueue({concurrency: 2});
let count = 0;
queue.on('active', () => {
console.log(`Working on item #${++count}. Size: ${queue.size} Pending: ${queue.pending}`);
});
queue.add(() => Promise.resolve());
queue.add(() => delay(2000));
queue.add(() => Promise.resolve());
queue.add(() => Promise.resolve());
queue.add(() => delay(500));Emitted every time the queue becomes empty and all promises have completed; queue.size === 0 && queue.pending === 0.
const delay = require('delay');
const {default: PQueue} = require('p-queue');
const queue = new PQueue();
queue.on('idle', () => {
console.log(`Queue is idle. Size: ${queue.size} Pending: ${queue.pending}`);
});
const job1 = queue.add(() => delay(2000));
const job2 = queue.add(() => delay(500));
await job1;
await job2;
// => 'Queue is idle. Size: 0 Pending: 0'
await queue.add(() => delay(600));
// => 'Queue is idle. Size: 0 Pending: 0'The idle event is emitted every time the queue reaches an idle state. On the other hand, the promise the onIdle() function returns resolves once the queue becomes idle instead of every time the queue is idle.
Emitted every time the add method is called and the number of pending or queued tasks is increased.
Emitted every time a task is completed and the number of pending or queued tasks is decreased.
const delay = require('delay');
const {default: PQueue} = require('p-queue');
const queue = new PQueue();
queue.on('add', () => {
console.log(`Task is added. Size: ${queue.size} Pending: ${queue.pending}`);
});
queue.on('next', () => {
console.log(`Task is completed. Size: ${queue.size} Pending: ${queue.pending}`);
});
const job1 = queue.add(() => delay(2000));
const job2 = queue.add(() => delay(500));
await job1;
await job2;
//=> 'Task is added. Size: 0 Pending: 1'
//=> 'Task is added. Size: 0 Pending: 2'
await queue.add(() => delay(600));
//=> 'Task is completed. Size: 0 Pending: 1'
//=> 'Task is completed. Size: 0 Pending: 0'A more advanced example to help you understand the flow.
const delay = require('delay');
const {default: PQueue} = require('p-queue');
const queue = new PQueue({concurrency: 1});
(async () => {
await delay(200);
console.log(`8. Pending promises: ${queue.pending}`);
//=> '8. Pending promises: 0'
(async () => {
await queue.add(async () => 'π');
console.log('11. Resolved')
})();
console.log('9. Added π');
console.log(`10. Pending promises: ${queue.pending}`);
//=> '10. Pending promises: 1'
await queue.onIdle();
console.log('12. All work is done');
})();
(async () => {
await queue.add(async () => 'π¦');
console.log('5. Resolved')
})();
console.log('1. Added π¦');
(async () => {
await queue.add(async () => 'π΄');
console.log('6. Resolved')
})();
console.log('2. Added π΄');
(async () => {
await queue.onEmpty();
console.log('7. Queue is empty');
})();
console.log(`3. Queue size: ${queue.size}`);
//=> '3. Queue size: 1`
console.log(`4. Pending promises: ${queue.pending}`);
//=> '4. Pending promises: 1'$ node example.js
1. Added π¦
2. Added π΄
3. Queue size: 1
4. Pending promises: 1
5. Resolved π¦
6. Resolved π΄
7. Queue is empty
8. Pending promises: 0
9. Added π
10. Pending promises: 1
11. Resolved π
12. All work is done
For implementing more complex scheduling policies, you can provide a QueueClass in the options:
class QueueClass {
constructor() {
this._queue = [];
}
enqueue(run, options) {
this._queue.push(run);
}
dequeue() {
return this._queue.shift();
}
get size() {
return this._queue.length;
}
filter(options) {
return this._queue;
}
}p-queue will call corresponding methods to put and get operations from this queue.
- p-limit - Run multiple promise-returning & async functions with limited concurrency
- p-throttle - Throttle promise-returning & async functions
- p-debounce - Debounce promise-returning & async functions
- p-all - Run promise-returning & async functions concurrently with optional limited concurrency
- Moreβ¦
Tidelift helps make open source sustainable for maintainers while giving companies
assurances about security, maintenance, and licensing for their dependencies.