**Parentheses** in types are just for grouping and to resolve ambiguities; they do not modify the type that they surround. For example, given the types

```
type A = { a: 1, c: 3 };
type B = { b: 2, c: 3 };
```

Then what does this type resolve to?

```
type Z = keyof A | B; // ??
```

With parentheses you can be explicit about how you mean for that to be interpreted:

```
type X = (keyof A) | B; // "a" | "c" | B
type Y = keyof (A | B); // "c"
```

It turns out that `keyof`

binds more tightly to `A`

than the union operator `|`

does, so `Z`

is equivalent to `X`

... so if you mean `Y`

you need those parentheses.

The (increasingly outdated) TypeScript Specification document says:

Parentheses are required around union, intersection, function, or constructor types when they are used as array element types; around union, function, or constructor types in intersection types; and around function or constructor types in union types.

When in doubt, add parentheses.

**Square brackets** in types actually have a variety of different meanings:

When a type `T`

is immediately followed by a pair of *empty* square brackets, it means an *array* whose elements are of type `T`

, and is equivalent to `Array<T>`

. So `{a: string}[]`

is an array whose elements are of type `{a: string}`

, and is equivalent to `Array<{a: string}>`

. (Similarly, if such a type is immediately preceded by the `readonly`

modifier, like `readonly T[]`

, then it is equivalent to `ReadonlyArray<T>`

.)

When a type `T`

is immediately followed by another type `U`

encased in square brackets, (i.e., `T[U]`

)... the brackets are *not empty*, it means you are looking up or indexing the type of the property of `T`

whose key is of type `U`

. So `{a: string}["a"]`

is the type of the `a`

property of `{a: string}`

... namely, `string`

. And `Array<boolean>[number]`

is the type you get when you index into an `Array<boolean>`

with a `number`

key... namely `boolean`

.

When square brackets contain a comma-delimited list of zero or more types like `[]`

or `[T]`

or `[T,U]`

or `[T,U,V]`

, etc., (and if it's zero or one you need to be careful not to confuse it for the array or lookup notation above), then you are specifying a tuple type, an array with a fixed number of possibly differently-typed elements in a fixed order. Tuple types can also be preceded with `readonly`

to make readonly tuples, and there are other fun things going on with tuples, like rest and optional elements in tuple types and variadic tuple types, so `readonly [0, ...[1, 2, 3], 4?, ...[5?, 6?, 7?], ...8[]]`

is a valid TS type (in TS4.0+).

Armed with that, let's look at these examples:

```
type ArrayTypes<T> =
T extends (infer U)[]
? U
: never
```

This is saying: given a type `T`

, if it extends some array type `U[]`

where `U`

is to be inferred, then return `U`

, otherwise return `never`

. The `infer`

needs to attach to `U`

. For whatever reason, `[]`

binds more tightly than `infer`

, and so `T extends infer U[]`

would be interpreted as `T extends infer (U[])`

... which is invalid because you can only `infer`

a new type variable, not a function of such a variable. That's why you need the parentheses.

```
let arr = [1, "2", []];
type test = ArrayTypes<typeof arr> // type test = string | number | never[]
```

That makes sense, right? `arr`

is inferred to be of type `Array<string | number | Array<never>>`

or the equivalent `(string | number | never[])[]`

, and thus `ArrayTypes<typeof arr>`

infers `U`

to be `string | number | never[]`

and that's what you get. (Note that the value `[]`

is inferred as type `never[]`

in the TS version I'm using and not `any[]`

).

Also note, as an aside, that the lookup type above with a `number`

key does the same thing without needing `infer`

:

```
type ArrayTypes<T> = T extends any[] ? T[number]: never;
```

Next example:

```
type ArrayTypes<T> =
T extends (infer U)
? U
: never
```

Here the parentheses aren't necessary because there is no ambiguity. You could write `T extends infer U ? U : never`

. This means: given a type `T`

that extends some inferred type `U`

, return `U`

; otherwise return `never`

. But this seems a bit silly, since `U`

will always be inferred to be `T`

, and thus `ArrayTypes<T>`

will always be `T`

, no matter what:

```
let arr = [1, "2", []];
type test = ArrayTypes<typeof arr> // type test = (string | number | never[])[]
```

The type `test`

is going to be just the same as `typeof arr`

, which is `Array<string | number | Array<never>>`

, or equivalently, `(string | number | never[])[]`

.

I hope that clarifies things for you. Good luck!

Playground link to code