Suppose that I have a class called Rational which represents rational numbers "purely", i.e it maintains the representation of a/b as (a, b) and implements the usual operators +, -, *, / and others to work on those tuples, instead of evaluating the actual fractions on every operation.

Suppose now that I want to define what happens if I add a Rational instance to an Int, in addition to the already defined behavior for Rational added to Rational. Then, of course, I might end up wanting to add Rational to Double, or to Float, BigInt other numeric types...

Approach #1: Provide several implementations of +(Rational, _):

def + (that:Rational):Rational  = {
    require(that != null, "Rational + Rational: Provided null argument.")
    new Rational(this.numer * that.denom + that.numer * this.denom, this.denom * that.denom)

def + (that:Int): Rational = this + new Rational(that, 1) // Constructor takes (numer, denom) pair

def + (that:BigInt): Rational = ....

Approach #2: Pattern match on Any:

def + (that:Any):Rational  = {
    require(that != null, "+(Rational, Any): Provided null argument.")
    that match {
        case that:Rational => new Rational(this.numer * that.denom + that.numer * this.denom, this.denom * that.denom)
        case that:Int | BigInt => new Rational(this.numer + that * this.denom, this.denom) // a /b + c = (a + cb)/b
        case that:Double => ....
        case _ => throw new UnsupportedOperationException("+(Rational, Any): Unsupported operand.")

One benefit I'm seeing from the pattern matching approach is saving in terms of actual source code lines, but perhaps with a decrease of readability. Perhaps more crucially, I have control over what I do when I'm provided with a type I haven't defined behavior of + for. I'm not certain how that could be attained via the first approach, perhaps by adding an overloading for Any underneath all the others? Either way, it sounds dangerous.

Ideas on whether one should opt for the first or second approach? Are there any safety issues I'm not seeing? Am I opening myself to ClassCastExceptions or other kinds of exceptions?

  • Why do you want to turn a perfectly fine compile time error into a runtime error? What should be the behavior of adding a type which is not supported, but simply refuse it at compile time. Jun 21, 2019 at 2:29
  • Ah, I see. Just to clarify, if the caller wanted to use my Rational instance to add it to an unsupported type, that is a compile-time error on their own front, yes?
    – Jason
    Jun 21, 2019 at 2:39
  • yes, that would be the ideal situation on a statically typed language like Scala. Being said that, the best option would be the first one, or a third one using typeclasses. Now, if you also want to allow your users to extend your class, then typeclasses would be the best option. If not, maybe the first one is the best because of its simplicity. Jun 21, 2019 at 2:51
  • I'm wondering: is there any way to force a compile-time error in this case if we were to follow approach #2?
    – Jason
    Jun 21, 2019 at 4:01
  • Right now, there is no way that I am aware of. On a future in Scala 3.0 you could use Union types to achieve that. However, you can hack something a sealed ev typeclass. Jun 21, 2019 at 11:27

1 Answer 1


The way to enforce a compile-time error is to ensure that the plus method cannot actually take type Any, via a type constraint, an implicit parameter, or the like.

One way of dealing with this would be to make use of the scala Numeric type class. It should be perfectly possible to create an instance for Rational, since you can easily implement all the required methods, and at that point you can define plus as

def +[T: Numeric](that: T) : Rational

You'd now also be able to pull out the toInt/toLong/toFloat/toDouble methods of the implicit Numeric argument to handle unknown classes instead of throwing a runtime error as well, if you wanted - and even if you don't, you've at least significantly cut down the erronous types that can be passed.

You could also define your own type class and appropriate instances of it for the types you want to support. Then you can either leave the addition logic in the + method or move it into the typeclass instances:

trait CanBeAdded[T] {
  def add(t: T, rational: Rational) : Rational

object CanBeAdded {
  implicit val int = new CanBeAdded[Int] {
    override def add(t: Int, rational: Rational): Rational = ???

  implicit val long = new CanBeAdded[Long] {
    override def add(t: Long, rational: Rational): Rational = ???

  implicit val rational = new CanBeAdded[Rational] {
    override def add(t: Rational, rational: Rational): Unit = ???

case class Rational(a: BigInt, b: BigInt) {
  def +[T: CanBeAdded](that: T) = implicitly[CanBeAdded[T]].add(that, this)

I like the second option because I have to doubt that allowing your Rational type to be added to any numeric type makes sense. You mention that you want + to be able to take in Doubles, but exact representation combined with the rounding errors that often crop up in Doubles seems like it could lead to some very weird and counterintuitive behaviour with results that don't make much sense.

  • Oh yes, absolutely, Doubles were just an example. After all, you can approximate pi with a Double, but that doesn't make the number Rational, now, does it. Only its approximation is Rational. Thank you very much. Clearly I have a lot of Scala studying to do.
    – Jason
    Jun 21, 2019 at 15:34

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