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I understand why function composition is important. It allows building large and complex functions from small and simple ones.

val f: A => B = ...
val g: B => C = ...

val h = f andThen g; // compose f and g

This composition conforms to identity and associativity laws.

Associativity is useful because it allows grouping f1 andThen f2 andThen f3 andThen f4 ... in any order. Now I wonder why identity is useful.

def f[T](t:T) = t   // identity function
val g: A => B = ... // just any function
g andThen f[B] == f[A] andThen g 

So, my question is where and why this identity useful.

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3 Answers 3

up vote 6 down vote accepted

Identity is useful whenever an interface gives you more control than you actually need. For example, Either has no flatten method. Let's suppose you have

val e: Either[Double, Float] = Right(1.0f)

and you want to flatten it to a Double. How do you do it? There is a handy fold method, but no method to convert the right side to the left side's type. So you

e.fold(identity, _.toDouble)

and you've got what you want.

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Thank you. Now I see when identity is useful. Could you explain also why identity laws (i.e. right identity and left identity) are useful too ? – Michael Feb 2 '14 at 13:37
@Michael - Identity laws just reassure you that identity works the way you expect. In addition to serving as a "Hey, let's not get too crazy here!" check, they can be useful for proving that it's okay to split up or collapse certain operations. – Rex Kerr Feb 2 '14 at 15:58

Eventually there will come a time when you've refactored your code in such a way that you either accept a higher order function or you accept some Monad M of M[A => B] in which you do not want a value of B but instead want the same thing you put in. Keeping your code fluid and responsive to the changing needs of your project (or reducing D-R-Y violations) you'll undoubtedly want identity.

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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.

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