I want to create a function chain, which would be an input of a pipe/flow/compose function.

Is this possible without the literal expansion of the types to selected depth, as is this usually handled? See lodash's flow.

I want to achieve typecheck of the data flow in the chain. - Argument of a function is result of the previous one - First argument is a template parameter - Last return is a template parameter

type Chain<In, Out, Tmp1 = any, Tmp2 = any> = [] | [(arg: In) => Out] | [(arg: In) => Tmp1, (i: Tmp1) => Tmp2, ...Chain<Tmp2, Out>];

The idea is in the draft.

This however produces tho following errors:

  1. Type alias 'Chain' circularly references itself. (understand why, don't know how to resole)
  2. A rest element type must be an array type. (probably spread is not available for generic tuples)
  3. Type 'Chain' is not generic. (don't even understand why this error is even here)

Is this definition of Chain possible in Typescript? If so, please enclose a snippet.

(Tested on latest tsc 3.1.6)

  • Isn't this a "turtles all the way down" problem? i.e. it is impossible to resolve the recursive type.
    – Fenton
    Nov 6, 2018 at 15:14

1 Answer 1


Circular type aliases are not really supported except in certain cases. (UPDATE TS 4.1, these are more supported now, but I'm still inclined to represent flow() as operating on AsChain that verifies a particular array of functions instead of trying to come up with a Chain that matches all valid arrays of functions)

Instead of trying to represent the specific type you've written there in a TypeScript-friendly way, I think I'll back up and interpret your question as: how can we type a flow()-like function, which takes as its arguments a variable number of one-argument functions, where each one-argument-function return type is the argument type for the next one-argument-function, like a chain... and which returns a one-argument function representing the collapsed chain?

I've got something that I believe works, but it's quite complicated, using a lot of conditional types, tuple spreads, and mapped tuples. Here it is:

type Lookup<T, K extends keyof any, Else=never> = K extends keyof T ? T[K] : Else

type Tail<T extends any[]> = T extends [any, ...infer R] ? R : never;

type Func1 = (arg: any) => any;
type ArgType<F, Else=never> = F extends (arg: infer A) => any ? A : Else;
type AsChain<F extends [Func1, ...Func1[]], G extends Func1[]= Tail<F>> =
  { [K in keyof F]: (arg: ArgType<F[K]>) => ArgType<Lookup<G, K, any>, any> };

type Last<T extends any[]> = T extends [...infer F, infer L] ? L : never;
type LaxReturnType<F> = F extends (...args: any) => infer R ? R : never;

declare function flow<F extends [(arg: any) => any, ...Array<(arg: any) => any>]>(
  ...f: F & AsChain<F>
): (arg: ArgType<F[0]>) => LaxReturnType<Last<F>>;

Let's see if it works:

const stringToString = flow(
  (x: string) => x.length, 
  (y: number) => y + "!"
); // okay
const str = stringToString("hey"); // it's a string

const tooFewParams = flow(); // error

const badChain = flow(
  (x: number)=>"string", 
  (y: string)=>false, 
  (z: number)=>"oops"
); // error, boolean not assignable to number

Looks good to me.

I'm not sure if it's worth it to go through in painstaking detail about how the type definitions work, but I might as well explain how to use them:

  • Lookup<T, K, Else> tries to return T[K] if it can, otherwise it returns Else. So Lookup<{a: string}, "a", number> is string, and Lookup<{a: string}, "b", number> is number.

  • Tail<T> takes a tuple type T and returns a tuple with the first element removed. So Tail<["a","b","c"]> is ["b","c"].

  • Func1 is just the type of a one-argument function.

  • ArgType<F, Else> returns the argument type of F if it's a one-argument function, and Else otherwise. So ArgType<(x: string)=>number, boolean> is string, and ArgType<123, boolean> is boolean.

  • AsChain<F> takes a tuple of one-argument functions and tries to turn it into a chain, by replacing the return type of each function in F with the argument type of the next function (and using any for the last one). If AsChain<F> is compatible with F, everything's good. If AsChain<F> is incompatible with F, then F is not a good chain. So, AsChain<[(x: string)=>number, (y:number)=>boolean]> is [(x: string)=>number, (y: number)=>any], which is good. But AsChain<[(x: string)=>number, (y: string)=>boolean]> is [(x: string)=>string, (y: string)=>any], which is not good.

  • Last<T> takes a tuple and returns the last element, which we need to represent the return type of flow(). Last<["a","b","c"]> is "c".

  • Finally, LaxReturnType<F> is just like ReturnType<F> but without a constraint on F.

Okay, hope that helps; good luck!

Playground link to code

  • 2
    What you did here is pretty impressive. It works indeed. The only minor setback is that the error seems to be always on the first function, no matter where the chain breaks (though message is correct), which inherently seems to be the problem of the solution. You are validating the chain in AsChain, not defining the type. The main issue is obviously the complexity of the notation. Why are recursive types not supported? Are they planned to be supported in following versions? The draft I provided, if supported, is brief, conscious, maintainable and easy to write. Nov 13, 2018 at 14:05
  • "Are they planned to be supported"? Read the "Recursive Types" design notes section here: github.com/Microsoft/TypeScript/issues/27102
    – jcalz
    Nov 13, 2018 at 14:27
  • as for error always on the first function, yeah I noticed that. I'm not sure that a recursive type would fare better on that front; it seems to be a bug in IntelliSense. Maybe I'll report it.
    – jcalz
    Nov 13, 2018 at 15:09
  • 1
    Maybe like this? An explanation is probably outside the scope of the question and not suitable for comments.
    – jcalz
    Mar 11, 2021 at 20:09
  • 4
    For a different question (closed as a duplicate of this one :-) I arrived upon this recursive solution: tsplay.dev/wQ5r1w The error messages are a bit more accurate, and the code is relatively easy to follow. If anyone is still interested in this topic, I can add it as a second answer to the question.
    – Oblosys
    Mar 31, 2022 at 21:00

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