On a more theoretical side (and since I can guess where this question has arisen from), the one fundamental use of the identity functions is that they allow you to define the notion of *isomorphisms*, which often turn out to be a much more useful definition of "sameness" than usual equality (read this).

An isomorphism tells you that "going there and back again is the same as staying here". In set-like structures, that definition corresponds to a bijective function - but not everything is set-like. So, in general we can say: A function (morphism) `f`

is an isomorphism, if there is a `g`

(its *inverse*), such that `f . g == id`

and `g . f == id`

. Note that this crucially depends on having `id`

: we can't in general assume that things have "elements" to which we can refer to, like it us usually done when introducing bijective functions.

Here's a non set-based example: consider a directed graph. Say there are vertices `A -> B`

and `B -> A`

. Since paths can be (associatively!) concatenated, we have paths `A -> B -> A`

, and `B -> A -> B`

. But they are just "the same thing" as loops `A -> A`

and `B -> B`

(or "staying at one edge")! We now can also say that those are the identity paths for `A`

and `B`

. No bijection or "forall *x* in *A* ..." is involved at all.

All these structures can also be described (and are used) with categories in programming (Scala, Haskell); for example, pipes form a category, and thus need to have identity pipes.

And, aside, here's also another practical use, using `id`

as base value for a fold:

```
doAll = foldr (.) id [(+1), (*2), (3-)]
```

The short version of combining a number of endofunctions.