133

Title says it all - why doesn't Object.keys(x) in TypeScript return the type Array<keyof typeof x>? That's what Object.keys does, so it seems like an obvious oversight on the part of the TypeScript definition file authors to not make the return type simply be keyof T.

Should I log a bug on their GitHub repo, or just go ahead and send a PR to fix it for them?

2
  • 2
    I opened and closed a PR today related to this topic. My PR was only focusing on the case where keys are coming from an enum of strings. In this precise case, it does not seem that inheritance is feasible. I need to double check before reopening it github.com/Microsoft/TypeScript/pull/30228
    – DubZzz
    Mar 5, 2019 at 23:00
  • FTR: That ^ PR was never merged Dec 4, 2020 at 22:58

4 Answers 4

159

The current return type (string[]) is intentional. Why?

Consider some type like this:

interface Point {
    x: number;
    y: number;
}

You write some code like this:

function fn(k: keyof Point) {
    if (k === "x") {
        console.log("X axis");
    } else if (k === "y") {
        console.log("Y axis");
    } else {
        throw new Error("This is impossible");
    }
}

Let's ask a question:

In a well-typed program, can a legal call to fn hit the error case?

The desired answer is, of course, "No". But what does this have to do with Object.keys?

Now consider this other code:

interface NamedPoint extends Point {
    name: string;
}

const origin: NamedPoint = { name: "origin", x: 0, y: 0 };

Note that according to TypeScript's type system, all NamedPoints are valid Points.

Now let's write a little more code:

function doSomething(pt: Point) {
    for (const k of Object.keys(pt)) {
        // A valid call iff Object.keys(pt) returns (keyof Point)[]
        fn(k);
    }
}
// Throws an exception
doSomething(origin);

Our well-typed program just threw an exception!

Something went wrong here! By returning keyof T from Object.keys, we've violated the assumption that keyof T forms an exhaustive list, because having a reference to an object doesn't mean that the type of the reference isn't a supertype of the type of the value.

Basically, (at least) one of the following four things can't be true:

  1. keyof T is an exhaustive list of the keys of T
  2. A type with additional properties is always a subtype of its base type
  3. It is legal to alias a subtype value by a supertype reference
  4. Object.keys returns keyof T

Throwing away point 1 makes keyof nearly useless, because it implies that keyof Point might be some value that isn't "x" or "y".

Throwing away point 2 completely destroys TypeScript's type system. Not an option.

Throwing away point 3 also completely destroys TypeScript's type system.

Throwing away point 4 is fine and makes you, the programmer, think about whether or not the object you're dealing with is possibly an alias for a subtype of the thing you think you have.

The "missing feature" to make this legal but not contradictory is Exact Types, which would allow you to declare a new kind of type that wasn't subject to point #2. If this feature existed, it would presumably be possible to make Object.keys return keyof T only for Ts which were declared as exact.


Addendum: Surely generics, though?

Commentors have implied that Object.keys could safely return keyof T if the argument was a generic value. This is still wrong. Consider:

class Holder<T> {
    value: T;
    constructor(arg: T) {
        this.value = arg;
    }

    getKeys(): (keyof T)[] {
        // Proposed: This should be OK
        return Object.keys(this.value);
    }
}
const MyPoint = { name: "origin", x: 0, y: 0 };
const h = new Holder<{ x: number, y: number }>(MyPoint);
// Value 'name' inhabits variable of type 'x' | 'y'
const v: "x" | "y" = (h.getKeys())[0];

or this example, which doesn't even need any explicit type arguments:

function getKey<T>(x: T, y: T): keyof T {
    // Proposed: This should be OK
    return Object.keys(x)[0];
}
const obj1 = { name: "", x: 0, y: 0 };
const obj2 = { x: 0, y: 0 };
// Value "name" inhabits variable with type "x" | "y"
const s: "x" | "y" = getKey(obj1, obj2);
14
  • 17
    However, there is common case when point 3. is excluded, when for example T is inferred and is guaranteed to be precise: const f: <T>(t: T) => void = (t) => { Object.keys(t).forEach(k => t[k]) }. I have lots of places like that in my code, where I really want Object.keys() to return (keyof T)[].
    – artem
    Mar 5, 2019 at 22:02
  • 10
    As arthem also points out, the confusion comes from the fact that 9 out of 10 times you will end up in some way using a type assertion to keyof T to do anything useful with the result of keys. You might argue it is better to be explicit about it so you are more aware of the risk you are taking, but probably 9/10 devs will just add the type assertion and not be aware of the issues you highlight .. Mar 6, 2019 at 0:16
  • 2
    Why can't Object.keys<T>(c extends T obj) simply filter the keys on obj (type c) returning keys of T? Mar 31, 2020 at 15:34
  • 4
    If anyone has actually been screwed up by type-casting Object.keys(foo) to Array<keyof typeof foo>, where the runtime value from Object.keys actually included more keys than were know at compile-time, Many people would love to see this code as an example. Please share it Dec 2, 2020 at 22:10
  • 4
    Often, this is solely used to be able to loop through an object but that makes it impossible since Object.keys(product).forEach((key) => { // do something with product[key] but leads to error 'has type any because string cannot be used to query ...' }); will lead to an error.
    – jperl
    Dec 9, 2020 at 12:34
17

For a workaround in cases when you're confident that there aren't extra properties in the object you're working with, you can do this:

const obj = {a: 1, b: 2}
const objKeys = Object.keys(obj) as Array<keyof typeof obj>
// objKeys has type ("a" | "b")[]

You can extract this to a function if you like:

const getKeys = <T>(obj: T) => Object.keys(obj) as Array<keyof T>

const obj = {a: 1, b: 2}
const objKeys = getKeys(obj)
// objKeys has type ("a" | "b")[]

As a bonus, here's Object.entries, pulled from a GitHub issue with context on why this isn't the default:

type Entries<T> = {
  [K in keyof T]: [K, T[K]]
}[keyof T][]

function entries<T>(obj: T): Entries<T> {
  return Object.entries(obj) as any;
}
9

This is the top hit on google for this type of issue, so I wanted to share some help on moving forwards.

These methods were largely pulled from the long discussions on various issue pages which you can find links to in other answers/comment sections.

So, say you had some code like this:

const obj = {};
Object.keys(obj).forEach((key) => {
  obj[key]; // blatantly safe code that errors
});

Here are a few ways to move forwards:

  1. If the only issue is accessors, use .entries() or .values() instead of iterating over the keys.

    const obj = {};
    Object.values(obj).forEach(value => value);
    Object.entries(obj).forEach([key, value] => value);
    
  2. Create a helper function:

    function keysOf<T extends Object>(obj: T): Array<keyof T> {
      return Array.from(Object.keys(obj)) as any;
    }
    
    const obj = { a: 1; b: 2 };
    keysOf(obj).forEach((key) => obj[key]); // type of key is "a" | "b"
    
  3. Re-cast your type (this one helps a lot for not having to rewrite much code)

    const obj = {};
    Object.keys(obj).forEach((_key) => {
      const key = _key as keyof typeof obj;
      obj[key];
    });
    

Which one of these is the most painless is largely up to your own project.

2
  • 2
    I recently banged my head against this and would like to toss one more option on to the heap: convert over to a Map. It's a huge hassle to convert over to Map for supporting old code, but if you're writing something new, it's pretty easy to use it like the Object.keys pattern I -- and probably you if you're reading this -- was used to using. const myMap: Map<SomeType, SomeOtherType> = new Map(), then later loop over it with myMap.forEach((val, key) => {... and TypeScript is happy here ...}) Jan 3 at 23:15
  • Please feel free to edit this answer and add your solution to the list.
    – Seph Reed
    Jan 24 at 18:20
1

Possible solution

const isName = <W extends string, T extends Record<W, any>>(obj: T) =>
  (name: string): name is keyof T & W =>
    obj.hasOwnProperty(name);

const keys = Object.keys(x).filter(isName(x));

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