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) ==

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 Bs 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))
  • 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

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