# Associative binary operation for Option in Scala

I remember that `monad` is a `monoid`. That is, there is an associative binary operation `*` so that if `ma` and `mb` are monadic values then `ma * mb` is a monadic value too.

If the above is correct, what is that binary operation for `Option` in Scala ? For example, what can be `*` in `Some(1) * Some(2)` ?

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What do you mean on `ma` and `mb`? For instance `Option(1)` and `Option(2)`? –  senia Feb 17 '14 at 11:30
Why? Isn't `append` a binary associative operation? What is `Some(z)` append {`Some(x)` append `Some(y)`}? Is that the same if you change order? –  S.R.I Feb 17 '14 at 11:39
@senia Yes (updated the question), I mean something like `Some(1) * Some(2)`. What is `*` here ? –  Michael Feb 17 '14 at 12:26
The question is: Do you really want to know…? stackoverflow.com/a/3870310/200266 (Answer: `*` == `join`/`flatten`; 1 == `return`.) –  Debilski Feb 17 '14 at 12:34
@Debilski Could you please elaborate a bit and maybe give a full answer? –  Michael Feb 17 '14 at 13:09

(This answer stole its definitions from http://stackoverflow.com/a/3870310/200266 and only tries to give a rough explanation. My knowledge of category theory is rather basic.)

In the generic case, saying that a monad is also a monoid is only valid, if you consider the functor (eg. `T => Option[T]`) and not the values (eg. `Some(3)` or `None`).

As an example for a monoid over values, let’s have a look at `List[T]`.

We have a binary operation • : S × S -> S:

``````def append[T](list1: List[T], list2: List[T]): List[T] = list1 append list2
``````

and the empty list `Nil` is obviously the identity element. There is no `append` method in every monad, though, so the above cannot be generalised onto all monads. Let’s change the definition of the binary operation a bit.

Now, in the above case × can be seen as returning a tuple of the input values:

``````List[T] × List[T] => (List[T], List[T])
``````

And our `append` function receives this tuple as its input.

However, we may change the tupling operation × to , now meaning functor composition.

``````(K => List[K]) ∘ (K => List[K]) => (K => List[List[K]])
``````

And so, we’re looking for a function fulfilling μ : T ∘ T -> T or more specific

``````(K => List[List[K]]) => (K => List[K])
``````

That operation is known in Scala as `flatten` (`join` in Haskell). The monoid’s identity element is the the monad constructor which has no generic name in Scala (`return` in Haskell), but which exists for every monad. Eg. `x => List(x)`.

To wrap things up, considering this and the other answers in this question, there are three possibilities for how a monad can be a monoid:

A) Every monad is also a monoid in the above sense under functor composition.

B) Every monad `M[T]` has a monoid if there is also a monoid (with some binary operation `~+~`) for T: `for {x <- ma; y <- mb} yield x ~+~ y`

C) Some monads may have one or more specific monoids which differs from the one in B. For example `List`’s append or `Option`’s `orElse`.

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An `Option` by itself is not a monoid just like an `Integer` is not a monoid by itself. A monoid is a type AND the associative binary operation.

You can consider the Integer type AND addition a monoid. Integer and multiplication are a monoid too. Turning two `Integer`s to `String` and concatenating them ("2" + "3" = "23") is a valid associative operation too that could create a monoid with Integers: in fact `("2" concat "3") concat "4"` = `"2" concat ("3" concat "4"`) = "234".

The thing is, it's up to you to define the associative operation that completes the definition of "monoid" for a type, so your question "what is THE associative operation...." is not well-formed.

As with Integers, `Option[Int]` and addition or multiplications can be monoids, but an `Option[Int]` per se is not.

Like @senia does in his answer you can say "I can define a monoid based on Option[T] if T is itself a Monoid". In that case, the associative operation can use the one that was defined for T and `Some[a] append Some[b]` can be `Some[a append b]`.

Or, as @0__ did, you can find a particular operation (`orElse`) that, together with `Option[Int]` makes a monoid. That is correct too (but notice how the answer starts with "orElse is a valid associative binary operator").

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There are two different senses of monoid. A monad is a monoid object in the category theory sense (see the last example there); it isn't a monoid in the abstract algebra sense (which most other answers are talking about).

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I think `orElse` is a valid associative binary operator:

``````def test(a: Option[Int], b: Option[Int], c: Option[Int]): Boolean =
((a orElse b) orElse c) == (a orElse (b orElse c))

Seq(Option(1), Option(2), None).permutations.forall {
case Seq(a, b, c) => test(a, b, c)
}
``````

This holds. I have used this property in a FingerTree implementation, it was proposed by Hinze & Paterson in their Haskell version, it is used to implement an interval tree.

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Thanks. And what is the identity for this operation ? –  Michael Feb 17 '14 at 12:30
@Michael: `None orElse b` == `b orElse None` == `b`. –  senia Feb 17 '14 at 12:33
@Michael: The identity element in this would be `None`. `None orElse Some(3) == Some(3) == Some(3) orElse None`. This is no answer however to the question how every monad is also a monoid. –  Debilski Feb 17 '14 at 12:33
@Debilski Thanks, I started getting it now ... –  Michael Feb 17 '14 at 12:35

Actually not. `Monad` for `Option` is not a `Monoid` for `Option[T]`. `Monad` is defined for `M[_]` and `Monoid` is defined for `T`.

You can create `Monoid` for `Option[T]` if you have `Monoid` for `T` like this:

``````def optionMonoid[T: Monoid]: Monoid[Option[T]] = new Monoid {
def zero: Option[T] = None
def append(f1: Option[T], f2: => Option[T]): Option[T] = (fi, f2) match {
case (None, None) => None
case (Some(a), Some(b)) => Some(a |+| b)
case (r @ Some(_), None) => r
case (None, r @ Some(_)) => r
}
}
``````
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"`Monad` is not a `Monoid`". Well, actually... –  Travis Brown Feb 17 '14 at 11:20
@TravisBrown: I've tried to express this in `scala` as `def monadIsMonoid[...: Monad]: Monoid[...]` and it looks like it's impossible. Is there a programming language where one can express this idea in code? –  senia Feb 17 '14 at 12:37
Wrong monoid; see my answer. –  Alexey Romanov Feb 17 '14 at 14:00
@senia: Sorry, meant mostly as a joke, but you can do it if you have kind polymorphism. –  Travis Brown Feb 17 '14 at 20:00