Take a class hierarchy Chef extends Person extends GraphNode, where each parent class is generic in an interface T that extends the interface of its parent class. The uppermost (abstract) class defines a method accepting as its argument a subset of the keys of T.

I'm seeing an error (highlighted below) when keys are a subset derived from T. When the derived keys are exactly keyof T, the code works as expected. As far as I can tell both should work – and it's notable that it does work in the final class Chef, which is not generic.

Inheritance extensions are not behaving as I'd expect, have I missed something there?

type Literal = boolean | number | string;
type LiteralKeys<T> = { [K in keyof T]-?: T[K] extends Literal ? K : never }[keyof T];

interface IPerson { name: string; friend: Person; }
interface IChef extends IPerson { specialty: string; }

export abstract class GraphNode<T extends {} = {}> {
    // set<K extends keyof T>(_key: K, _value: T[K]) { /* ... */ }     // ✅
    set<K extends LiteralKeys<T>>(_key: K, _value: T[K]) { /* ... */ } // ❌

export abstract class Person<T extends IPerson = IPerson> extends GraphNode<T> {
    setName(name: string) {
        this.set('name', name); // ❌ Argument of type 'string' is 
        // ... not assignable to parameter of type 'LiteralKeys<T>'.

export class Chef extends Person<IChef> {
    setSpecialty(specialty: string) {
        this.set('specialty', specialty); // ✅

const sam = new Chef();


  • 1
    The compiler can't do the higher order logic to figure out what LiteralKeys<T> is going to be when T is an unresolved generic type like it is inside the body of setName(). Heck, I can't even do it easily, since weird things can happen when T is an arbitrary subtype of IPerson. Assuming it's fine, you can do this to soothe the compiler, by saying this can be treated as Person<IPerson> instead of Person<T> for some unresolved T extends IPerson. If that works for you I can maybe write up an answer; otherwise let me know what's missing.
    – jcalz
    Commented Dec 2, 2021 at 0:38
  • Thanks! I don't plan to do any weird(er) things with my interface inheritance – i.e. once a key is defined by a parent interface, the child interface will never override that. So I can kind of see why the compiler is conservative but (this as Person).set('name', name); should be fine for me. The only workaround I'd found otherwise was this.set('name' as any, name) and your suggestion is clearly better there. Commented Dec 2, 2021 at 0:45
  • What is IAttributes doing? It's... weird. Record<any, any> is not helpful, and LiteralKeys<{[k: string]: any}> is going to be string, which will absorb any other string literal. TypeScript can't represent "string except for "blah"" so if you have a blah property not extending Literal you're still going to get string out of that. Can your remove it like this so I can answer the question?
    – jcalz
    Commented Dec 2, 2021 at 2:06
  • If I switch to {} ESLint complains about Don't use {} as a type. {} actually means "any non-nullish value". ... and suggests using a Record instead. But it's all the same to me and I'd be fine with removing IAttribute. Commented Dec 2, 2021 at 8:09
  • So should I change interface IPerson extends IAttributes { name: string; friend: Person; } to interface IPerson { name: string; friend: Person; } ?
    – jcalz
    Commented Dec 2, 2021 at 15:00

1 Answer 1


The generic type LiteralKeys<T> defined like

type LiteralKeys<T> = 
  { [K in keyof T]-?: T[K] extends Literal ? K : never }[keyof T];

is a combination of mapped types, indexed access types and conditional types. When you pass in a T that's some specific type like IPerson, the compiler can evaluate it right away:

type EagerlyEvaluated = LiteralKeys<IPerson> // "name"

But when T is or depends upon an unspecified type parameter, such as inside the body of setName(), it has to defer evaluation, and as such it stays mostly unevaluated:

function deferred<T extends IPerson>() {
    type Deferred = LiteralKeys<T>;
    // type Deferred = { [K in keyof T]-?: T[K] extends Literal ? K : never; }[keyof T]

And the compiler isn't able to do the sort of higher order reasoning that would let it decide if some specific value like "name" is compatible with such an unevaluated type for all T extends IPerson. It treats that type as mostly opaque. Since it can't verify that any value is assignable to it, it will generate an error if you do assign any value to it:

const name: Deferred = "name" // error!

There are some GitHub issues around the compiler not using generic constraints like T extends IPerson to help partially evaluate conditional types instead of completely deferring them. See microsoft/TypeScript#39787 and microsoft/TypeScript#42077 for example. Even if this were improved it might not be possible for the compiler to understand that "name" should always be assignable to LiteralKeys<T> when T extends IPerson.

In the absence of getting the compiler to understand what you already know, you can use a type assertion to just tell the compiler that you are sure that "name" is assignable and that it shouldn't worry:

export abstract class Person<T extends IPerson = IPerson> extends GraphNode<T> {
    setName(name: string) {
        (this as Person).set('name', name); // okay now

Here I'm asserting that it can treat this as a Person<IPerson> instead of a Person<T>, at which point the relevant type for the _key parameter is LiteralKeys<IPerson> (which is just "name") and not LiteralKeys<T> (which is ❓). Of course when we type-assert things we should take extra care to make sure we are not accidentally lying to the compiler, since the burden of verifying type safety has shifted from the compiler (which can't handle it in this instance) to the human developer (who potentially can handle it but are known to be somewhat unreliable especially immediately before or after meals or bedtime). In this case I think this as Person is probably harmless, especially because all IPerson subtypes will have to have a name property whose value is assignable to string and thus to Literal, but it's good to pause and triple check.

Playground link to code

  • Using type Deferred = LiteralKeys<T>; is a helpful way of testing/experimenting with this, and casting this as Person is a good workaround for me – and I'll keep an eye on the upstream TS issues. Thanks again! Commented Dec 2, 2021 at 20:14

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