# Scala Monoid[Map[A,B]]

I'm reading a book with the following:

``````sealed trait Currency
case object USD extends Currency
... other currency types

case class Money(m: Map[Currency, BigDecimal]) {
... methods defined
}
``````

The discussion goes on to recognize certain types of operations on `Money` as being Monoidal so we want to create a `Monoid` for `Money`. What comes next though are listings I can't parse properly.

First is the definition of `zeroMoney`. This is done as follows:

``````final val zeroMoney: Money = Money(Monoid[Map[Currency, BigDecimal]].zero)
``````

What I have trouble following here is the part inside the `Money` parameter list. Specifically the

``````Monoid[Map[Currency, BigDecimal]].zero
``````

Is this supposed to construct something? So far in the discussion there hasn't been an implementation of the `zero` function for `Monoid[Map[A,B]]` so what does this mean?

Following this is the following:

``````implicit def MoneyAdditionMonoid = new Monoid[Money] {
val m = implicitly(Monoid[Map[Currency, BigDecimal]])
def zero = zeroMoney
def op(m1: Money, m2: Money) = Money(m.op(m1.m, m2.m))
}
``````

The definition of `op` is fine given everything else so that isn't a problem. But I still don't understand what `zeroMoney` is given its definition. This also gives me the same problem with the implicit `m` as well.

So, just what does `Monoid[Map[Currency, BigDecimal]]` actually do? I don't see how it constructs anything since `Monoid` is a trait with no implementation. How can it be used without defining `op` and `zero` first?

• There is missing context in your question. We can't guess the answer without having read the book. Your question should be self-contained and complete for us to answer – Dici Mar 4 '17 at 20:13
• @melston That approach is probably done better with squants or `joda-money`, libraries which already fully implement all the things you can possibly want. Maybe have a look there first? I know it doesn't directly answer your question but I can't help to think the code smells of future hassle for you. – flavian Mar 4 '17 at 21:29
• @flavian he's probably just reading a book about design in Scala and tries to understand it. This is a question about the mechanisms of the language, not about the best way to work with currencies in Scala – Dici Mar 4 '17 at 21:58
• Thanks, all. Yes, I am reading the Manning book "Functional and Reactive Domain Modeling" and what I provided was what was discussed in the book so far. I am not terribly proficient with Scala and this example confuses me, hence the question. – melston Mar 4 '17 at 22:24

For this code to compile, you would need something like the following:

``````trait Monoid[T] {
def zero: T
def op(x: T, y: T): T
}

object Monoid {
def apply[T](implicit i: Monoid[T]): Monoid[T] = i
}
``````

So `Monoid[Map[Currency, BigDecimal]].zero` desugars into `Monoid.apply[Map[Currency, BigDecimal]].zero`, which simplifies to `implicitly[Monoid[Map[Currency, BigDecimal]]].zero`.

`zero` in the Monoidal context is the element such that

``````Monoid[T].op(Monoid[T].zero, x) ==
Monoid[T].op(x, Monoid[T].zero) ==
x
``````

In the case of `Map`, I would assume the `Monoid` combines Maps with `++`. The `zero` would then simply be `Map.empty`, which is what `Monoid[Map[Currency, BigDecimal]].zero` finally simplifies into.

Edit: answer to comment:

Note that implicit conversion is not used at all here. This is the type class pattern which uses only implicit parameters.

`Map[A, B]` is a `Monoid` if `B` is a `Monoid`

That's one way to do it, which is different from the one I suggested with `++`. Let's see an example. How would you expect the following maps to be combined together:?

• `Map(€ → List(1, 2, 3), \$ → List(4, 5))`
• `Map(€ → List(10, 15), \$ → List(100))`

The results you would expect is probably `Map(€ → List(1, 2, 3, 10, 15), \$ → List(4, 5, 11))`, which is only possible because we know how to combine two lists. The `Monoid[List[Int]]` I implicitly used here is `(Nil, :::)`. For a general type `B` you would also need something to smash two `B`s together, this something is called a `Monoid`!

For completeness, here is the `Monoid[Map[A, B]]` I'm guessing the book wants to define:

``````implicit def mm[A, B](implicit mb: Monoid[B]): Monoid[Map[A, B]] =
new Monoid[Map[A, B]] {
def zero: Map[A, B] = Map.empty

def op(x: Map[A, B], y: Map[A, B]): Map[A, B] =
(x.toList ::: y.toList).groupBy(_._1).map {
case (k, v) => (k, v.map(_._2).reduce(mb.op))
}.toMap
}
``````
• Thanks, @OlivierBlanvillain, I think I follow what you are saying. The book does say that Map[A, B] is a Monoid if B is a Monoid, though I don't understand that statement. If there is an implicit conversion of Map[A,B] to Monoid then I am unaware of it but I would expect that you probably have it right, here. – melston Mar 4 '17 at 22:26
• @melston see edit – OlivierBlanvillain Mar 4 '17 at 22:44
• I guess I don't understand what you mean when you say implicit conversion is not used but then to on to define an implicit conversion. Also, if the Monoid you define is not already a part of Prelude (or somewhere else) then I don't see how the code in the book could work. It is not provided anywhere and seems to assume that the `mm` you have here is implicitly available. In any case, it seems that some kind of implicit must be used or the `m` in the Monoid in the original listing couldn't be created, right? – melston Mar 4 '17 at 23:50
• Ah, I found it and you are absolutely right. I had to go to the online code repo and scavenge around to find it but there are actually a couple of implicit definitions of `Monoid[Map[K,V]]` that were not mentioned in the book (oddly enough both implemented the same way). Thanks to your answer I had a better idea of what to look for. – melston Mar 5 '17 at 0:08