ECMAScript Stage-2 Proposal. J. S. Choi, 2021.
- Specification available
- Experimental polyfills (do not use in production code yet):
Since its standardization in JavaScript, Array.from has become one of
Array
’s most frequently used built-in methods. However, no similar
functionality exists for async iterators.
Such functionality would be useful for dumping the entirety of an async iterator into a single data structure, especially in unit tests or in command-line interfaces. (Several real-world examples are included in a following section.)
There is an it-all NPM library that performs only this task
and which gets about 50,000 weekly downloads daily.
This of course does not include any code
that uses ad-hoc for await
–of
loops with empty arrays:
const arr = [];
for await (const item of asyncItems) {
arr.push(item);
}
Further demonstrating the demand for such functionality, several Stack Overflow questions have been asked by various developers, asking how to convert async iterators to arrays.
There are several real-world examples listed later in this explainer.
(A formal draft specification is available.)
Array.fromAsync is to for await
as Array.from is to for
.
Similarly to Array.from, Array.fromAsync would be a static method of the
Array
built-in class, with one required argument and two optional arguments:
(items, mapfn, thisArg)
.
But, instead of converting a sync iterable to an array, Array.fromAsync can convert an async iterable to a promise that (if everything goes well) will resolve to a new array. Before the promise resolves, it will create an async iterator from the input, lazily iterate over it, and add each yielded value to the new array. (The promise is immediately returned after the Array.fromAsync function call, no matter what.)
async function * asyncGen (n) {
for (let i = 0; i < n; i++)
yield i * 2;
}
// `arr` will be `[0, 2, 4, 6]`.
const arr = [];
for await (const v of asyncGen(4)) {
arr.push(v);
}
// This is equivalent.
const arr = await Array.fromAsync(asyncGen(4));
If the argument is a sync iterable (and not an async iterable), then the return
value is still a promise that will resolve to an array. If the sync iterator
yields promises, then each yielded promise is awaited before its value is added
to the new array. (Values that are not promises are also awaited to
prevent Zalgo.) All of this matches the behavior of for await
.
function * genPromises (n) {
for (let i = 0; i < n; i++)
yield Promise.resolve(i * 2);
}
// `arr` will be `[ 0, 2, 4, 6 ]`.
const arr = [];
for await (const v of genPromises(4)) {
arr.push(v);
}
// This is equivalent.
const arr = await Array.fromAsync(genPromises(4));
Like for await
, Array.fromAsync lazily iterates over a sync-but-not-async
input. Whenever a developer needs to dump a synchronous input that yields
promises into an array, the developer needs to choose carefully between
Array.fromAsync and Promise.all, which have complementary control flows:
Parallel awaiting | Sequential awaiting | |
---|---|---|
Lazy iteration | Impossible | await Array.fromAsync(input) |
Eager iteration | await Promise.all(Array.from(input)) |
Useless |
Also like for await
, when given a sync-but-not-async iterable input, then
Array.fromAsync will catch only the first rejection that its iteration
reaches, and only if that rejection does not occur in a microtask before the
iteration reaches and awaits for it. For more information, see § Errors.
// `arr` will be `[ 0, 2, 4, 6 ]`.
// `genPromises(4)` is lazily iterated,
// and its four yielded promises are awaited in sequence.
const arr = await Array.fromAsync(genPromises(4));
// `arr` will also be `[ 0, 2, 4, 6 ]`.
// However, `genPromises(4)` is eagerly iterated
// (into an array of four promises),
// and the four promises are awaited in parallel.
const arr = await Promise.all(Array.from(genPromises(4)));
Array.fromAsync’s valid inputs are a superset of Array.from’s valid inputs. This includes non-iterable array-likes: objects that have a length property as well as indexed elements (similarly to Array.prototype.values). The return value is still a promise that will resolve to an array. If the array-like object’s elements are promises, then each accessed promise is awaited before its value is added to the new array.
One TC39 representative’s opinion: “[Array-likes are] very much not obsolete, and it’s very nice that things aren’t forced to implement the iterator protocol to be transformable into an Array.”
const arrLike = {
length: 4,
0: Promise.resolve(0),
1: Promise.resolve(2),
2: Promise.resolve(4),
3: Promise.resolve(6),
}
// `arr` will be `[ 0, 2, 4, 6 ]`.
const arr = [];
for await (const v of Array.from(arrLike)) {
arr.push(v);
}
// This is equivalent.
const arr = await Array.fromAsync(arrLike);
As it does with sync-but-not-async iterable inputs, Array.fromAsync lazily iterates over the values of array-like inputs, and it awaits each value. The developer must choose between using Array.fromAsync and Promise.all (see § Sync-iterable inputs and § Errors).
Array.fromAsync is a generic factory method. It does not require that its this receiver be the Array constructor. fromAsync can be transferred to or inherited by any other constructor. In that case, the final result will be the data structure created by that constructor (with no arguments), and with each value yielded by the input being assigned to the data structure’s numeric properties. (Symbol.species is not involved at all.) If the this receiver is not a constructor, then fromAsync creates an array as usual. This matches the behavior of Array.from.
async function * asyncGen (n) {
for (let i = 0; i < n; i++)
yield i * 2;
}
function Data (n) {}
Data.from = Array.from;
Data.fromAsync = Array.fromAsync;
// d will be a `new Data(0)`, with its `0` property assigned to `0`, its `1`
// property assigned to `2`, etc.
const d = new Data(0); let i = 0;
for await (const v of asyncGen(4)) {
d[i] = v;
}
// This is equivalent.
const d = await Data.fromAsync(asyncGen(4));
Array.fromAsync has two optional parameters: mapfn
and thisArg
.
mapfn
is a mapping callback, which is called on each value yielded from the
input (and awaited if it came from a synchronous input), along with its index
integer (starting from 0). Each result of the mapping callback is, in turn,
awaited then added to the array. By default, the callback is essentially an
identity function.
thisArg
is a this
-binding receiver value for the mapping callback. By
default, this is undefined. These optional parameters match the behavior of
Array.from. Their exclusion would be surprising to developers who are already
used to Array.from.
async function * asyncGen (n) {
for (let i = 0; i < n; i++)
yield i * 2;
}
// `arr` will be `[ 0, 4, 16, 36 ]`.
const arr = [];
for await (const v of asyncGen(4)) {
arr.push(v ** 2);
}
// This is equivalent.
const arr = await Array.fromAsync(asyncGen(4), v =>
v ** 2);
Like other promise-based APIs, Array.fromAsync will always immediately return a promise. Array.fromAsync will never synchronously throw an error and summon Zalgo.
When Array.fromAsync’s input throws an error while creating its async or sync iterator, then Array.fromAsync’s returned promise will reject with that error.
const err = new Error;
const badIterable = { [Symbol.iterator] () { throw err; } };
// This returns a promise that will reject with `err`.
Array.fromAsync(badIterable);
When Array.fromAsync’s input is iterable but the input’s iterator throws while iterating, then Array.fromAsync’s returned promise will reject with that error.
const err = new Error;
async function * genErrorAsync () { throw err; }
// This returns a promise that will reject with `err`.
Array.fromAsync(genErrorAsync());
const err = new Error;
function * genError () { throw err; }
// This returns a promise that will reject with `err`.
Array.fromAsync(genError());
When Array.fromAsync’s input is synchronous only (i.e., the input is not an async iterable), and when one of the input’s values is a promise that eventually rejects or has rejected, then iteration stops and Array.fromAsync’s returned promise will reject with the first such error.
In this case, Array.fromAsync will catch and handle that first input rejection only if that rejection does not occur in a microtask before the iteration reaches and awaits for it.
const err = new Error;
function * genRejection () {
yield Promise.reject(err);
}
// This returns a promise that will reject with `err`. There is **no** unhandled
// promise rejection, because the rejection occurs in the same microtask.
Array.fromAsync(genZeroThenRejection());
Just like with for await
, Array.fromAsync will not catch any rejections by
the input’s promises whenever those rejections occur before the ticks in
which Array.fromAsync’s iteration reaches those promises.
This is because – like for await
– Array.fromAsync lazily iterates over
its input and sequentially awaits each yielded value. Whenever a developer
needs to dump a synchronous input that yields promises into an array, the
developer needs to choose carefully between Array.fromAsync and Promise.all,
which have complementary control flows (see § Sync-iterable
inputs).
For example, when a synchronous input contains two promises, the latter of which will reject before the former promise resolves, then Array.fromAsync will not catch that rejection, because it lazily reaches the rejecting promise only after it already has rejected.
const numOfMillisecondsPerSecond = 1000;
const slowError = new Error;
const fastError = new Error;
function waitThenReject (value) {
return new Promise((resolve, reject) => {
setTimeout(() => reject(value), numOfMillisecondsPerSecond);
});
}
function * genRejections () {
// Slow promise.
yield waitAndReject(slowError);
// Fast promise.
yield Promise.reject(fastError);
}
// This returns a promise that will reject with `slowError`. There is **no**
// unhandled promise rejection: the iteration is lazy and will stop early at the
// slow promise, so the fast promise will never be created.
Array.fromAsync(genSlowRejectThenFastReject());
// This returns a promise that will reject with `slowError`. There **is** an
// unhandled promise rejection with `fastError`: the iteration eagerly creates
// and dumps both promises into an array, but Array.fromAsync will
// **sequentially** handle only the slow promise.
Array.fromAsync([ ...genSlowRejectThenFastReject() ]);
// This returns a promise that will reject with `fastError`. There is **no**
// unhandled promise rejection: the iteration eagerly creates and dumps both
// promises into an array, but Promise.all will handle both promises **in
// parallel**.
Promise.all([ ...genSlowRejectThenFastReject() ]);
When Array.fromAsync’s input has at least one value, and when Array.fromAsync’s mapping callback throws an error when given any of those values, then Array.fromAsync’s returned promise will reject with the first such error.
const err = new Error;
function badCallback () { throw err; }
// This returns a promise that will reject with `err`.
Array.fromAsync([ 0 ], badCallback);
When Array.fromAsync’s input is null or undefined, or when Array.fromAsync’s mapping callback is neither undefined nor callable, then Array.fromAsync’s returned promise will reject with a TypeError.
// These return promises that will reject with TypeErrors.
Array.fromAsync(null);
Array.fromAsync([], 1);
The iterator-helpers proposal has toArray, which works with both sync and async iterables.
Array.from(gen())
gen().toArray()
Array.fromAsync(asyncGen())
asyncGen().toArray()
toArray overlaps with both Array.from and Array.fromAsync. This is okay. They can coexist. If we have to choose between having toArray and having fromAsync, then we should choose fromAsync. We already have Array.from. We should match the existing language precedent.
A co-champion of iterable-helpers agrees that we should have both or that we should prefer Array.fromAsync: “I remembered why it’s better for a buildable structure to consume an iterable than for an iterable to consume a buildable protocol. Sometimes building something one element at a time is the same as building it [more than one] element at a time, but sometimes it could be slow to build that way or produce a structure with equivalent semantics but different performance properties.”
The following built-ins also resemble Array.from:
TypedArray.from()
new Set
Object.fromEntries()
new Map
We are deferring any async versions of these methods to future proposals. See issue #8 and proposal-setmap-offrom.
In the future, standardizing an async spread operator (like [ 0, await ...v ]
)
may be useful. This proposal leaves that idea to a separate proposal.
The record/tuple proposal puts forward two new data types with APIs that
respectively resemble those of Array
and Object
. The Tuple
constructor, too, would probably need an fromAsync
method. Whether the
Record
constructor gets a fromEntriesAsync
method will depend on whether
Object.fromEntriesAsync
will also be added in a separate proposal.
Only minor formatting changes have been made to the status-quo examples.
Status quo | With Array.fromAsync |
---|---|
const all = require('it-all');
// Add the default assets to the repo.
const results = await all(
addAll(
globSource(initDocsPath, {
recursive: true,
}),
{ preload: false },
),
);
const dir = results
.filter(file =>
file.path === 'init-docs')
.pop()
print('to get started, enter:\n');
print(
`\tjsipfs cat` +
`/ipfs/${dir.cid}/readme\n`,
); |
// Add the default assets to the repo.
const results = await Array.fromAsync(
addAll(
globSource(initDocsPath, {
recursive: true,
}),
{ preload: false },
),
);
const dir = results
.filter(file =>
file.path === 'init-docs')
.pop()
print('to get started, enter:\n');
print(
`\tjsipfs cat` +
`/ipfs/${dir.cid}/readme\n`,
); |
const all = require('it-all');
const results = await all(
node.contentRouting
.findProviders('a cid'),
);
expect(results)
.to.be.an('array')
.with.lengthOf(1)
.that.deep.equals([result]); From js-libp2p/test/content-routing/content-routing.node.js. |
const results = await Array.fromAsync(
node.contentRouting
.findProviders('a cid'),
);
expect(results)
.to.be.an('array')
.with.lengthOf(1)
.that.deep.equals([result]); |
async function toArray(items) {
const result = [];
for await (const item of items) {
result.push(item);
}
return result;
}
it('empty-pipeline', async () => {
const pipeline = new Pipeline();
const result = await toArray(
pipeline.execute(
[ 1, 2, 3, 4, 5 ]));
assert.deepStrictEqual(
result,
[ 1, 2, 3, 4, 5 ],
);
}); |
it('empty-pipeline', async () => {
const pipeline = new Pipeline();
const result = await Array.fromAsync(
pipeline.execute(
[ 1, 2, 3, 4, 5 ]));
assert.deepStrictEqual(
result,
[ 1, 2, 3, 4, 5 ],
);
}); |