3

I have the following definition for a curried function in TypeScript:

interface Curried2<A, B, Z> {
    (_0: A): (_0: B) => Z;
    (_0: A, _1: B): Z;
}

I have the following function that should accept a function (curried or not):

function apply<T, U>(f: (_0: T) => U, x: T): U {
    return f(x);
}

Now, given

let curried: Curried2<number, boolean, string> = ...

the following works (as expected):

apply<number, (_0: boolean) => string>(curried, 4);

But TypeScript cannot infer the type on its own:

apply(curried, 4);

(Even though there is only one overload for () which takes a single value.) It complains:

Argument of type 'Curried2<number, boolean, string>' is not assignable to parameter of type '(_0: number) => string' ...
It has correctly inferred T, but inferred U to be string. Why is this? What can I do to make type inference work for me in this case (as explicitly specifying T and U is too verbose for my taste)?

Thanks in advance!

0

I could try this approach:

type Curried<T1, T2, T3> = (x: T1) => (y: T2) => T3;

function apply<T, U>(f: (value: T) => U, x: T): U {
    return f(x);
}

//simple demo
var someFunc: Curried<string, number, [string, number]> = x => y => [x, y];
var curriedSomeFunc = apply(someFunc, "string here");
var result1 = curriedSomeFunc(0); //will be ["string here", 0]
var result2 = curriedSomeFunc(1); //will be ["string here", 1]

Another try. The syntax is correct but no safety if you pass not a correct function for currying:

interface Curried<T1, T2, T3> {
    (x: T1, y: T2): T3;
    (x: T1): (y: T2) => T3
}

let f1 = <Curried<string, number, [string, number]>>
    ((x: string, y: number) => [x, 1]);
let f2 = <Curried<string, number, [string, number]>>
    ((x: string) => (y: number) => [x, y]);

function apply<T, V>(f: (x: T) => V, x: T): V {
    return f(x);
}

let curriedF1 = apply(f1, "42"); //Won't work (no function to curry) but type inference is OK
let curriedF2 = apply(f2, "11"); //Will work and type inference is also OK 
  • In this case I would lose the ability to use the function as a regular uncurried function, so that won't work, unfortunately :( – Werner de Groot Dec 9 '15 at 7:24
  • That's it! The only difference between your example (in which type inference works) and mine (in which it doesn't) is the order of the overloaded methods of Curried. Any idea why this is? – Werner de Groot Dec 14 '15 at 18:49
  • Now the following won't work anymore: function applyTwo<S, T, V>(f: (x: S, y: T) => V, x: S, y: T): V { return f(x, y); }; applyTwo(f1, "23", 23); What, do you think, is the reason for this? – Werner de Groot Dec 14 '15 at 19:02
  • I don't think it's a good practice to use "overloading" for a function interface. It seems more like a typescript design flaw than a real feature. I would prefer to use currying technique via multiple arrow expressions. – shadeglare Dec 14 '15 at 19:25
0

The following now works:

interface F1<A, Z> {
    (_0: A): Z;
}

interface F2<A, B, Z> extends F1<A, F1<B, Z>> {
    (_0: A, _1: B): Z;
}

function apply<T, U>(f: F1<T, U>, x: T): U {
    return f(x);
}

function apply2<T, U, V>(f: F2<T, U, V>, x: T, y: U): V {
    return f(x, y);
}

let curried: F2<number, boolean, string> = null;

const x: F1<boolean, string> = apply(curried, 4);
const y: string = apply2(curried, 4, false);

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