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