Stack Overflow is a community of 4.7 million programmers, just like you, helping each other.

Join them; it only takes a minute:

Sign up
Join the Stack Overflow community to:
  1. Ask programming questions
  2. Answer and help your peers
  3. Get recognized for your expertise

I have a simple class hierarchy that represents a graph-like structure with several distinct types of vertexes implemented using case classes:

sealed trait Node

sealed abstract case class Vertex extends Node
case class Arc extends Node

case class VertexType1 (val a:Int) extends Vertex
case class VertexType2 (val b:Int) extends Vertex

This allows me to write match blocks like this:

def test (x: Node) = x match {
  case _ : Arc => "got arc"
  case _ : Vertex => "got vertex"
}

or like this:

def test (x: Node) = x match {
  case _ : Arc => "got arc"
  case c : Vertex => c match {
    case _ : VertexType1(a) => "got type 1 vertex " + a
    case _ : VertexType2(a) => "got type 2 vertex " + a
  }
}

Note that this implementation has the following properties:

1) It allows writing match blocks that differentiate between arcs and vertices, but not between specific vertex types, but also match blocks that do differentiate between vertex types.

2) In both vertex-type-specific and non-vertex-type-specific match blocks the exhaustiveness of pattern matching is checked.

However, inheritance from case classes is deprecated, and the compiler suggests to use extractors instead to support matching on non-leaf nodes (i.e., in the above example, to differentiate between arcs and vertices, but not between vertex types).

The question: is it possible to implement a similar class hierarchy without using case class inheritance, but still having pattern exhaustiveness checks performed by the compiler in both use cases shown above?

EDIT: I have added a constructor parameter to the VertexType classes so that the match is not performed only on types.

My current implementation without the case classes is as follows:

sealed trait Node

sealed abstract class Vertex extends Node
class Arc extends Node

class VertexType1 (val a:Int) extends Vertex
class VertexType2 (val b:Int) extends Vertex

object VertexType1 {
  def unapply (x : VertexType1) : Some[Int] = Some(x.a)
}

object VertexType2 {
  def unapply (x : VertexType2) : Some[Int] = Some(x.b)
}

And the test code:

def test (x: Node) = x match {
  case _ : Arc => "got arc" 
  case v : Vertex => v match {
    case VertexType1(a) => "got vertex type 1 " + a 
  }
}

I expect a warning about non-exhaustive match in the second block (VertexType2 is never matched), but there isn't one.

Actually, Scala compilers before 2.9.0-RC3 produce a warning that I expect to see, but versions starting with RC3 (including 2.9.0 and 2.9.0-1) do not, which is rather confusing.

share|improve this question
    
Just for completeness: this has been fixed in Scala 2.10. (there was a regression in Scala 2.9.x) – gourlaysama Jan 31 '13 at 16:16

In general, this can't be done.

Sealed classes are a special case (no pun intended) because scalac knows at compile time how many matches are possible.

But since extractors allow you to run arbitrary code and because of the damnable halting problem, there's no way for the compiler to guarantee in every case that you'll check every case. Consider:

def test(foo: Int) {
  foo match {
    case IsMultipleOf8(n) => printf("%d was odd\n", n)
  }
}

This is not exhaustive because it doesn't handle numbers that aren't multiples of 8, but the compiler cannot deduce (without running your extractor on all Int's) that only some values of type Int are multiples of 8.

share|improve this answer
1  
Yes, of course in general case this is true. However in my example the extractor object always returns something (because its return type is Some[Int] and not a Boolean or an Option), so it is guaranteed that the match cannot fail (that is if the unapply method eventually terminates, which I think is a reasonable assumption). Therefore the only thing that needs to be checked is that all types from the hierarchy are covered. Note that the compiler is able to implicitly cast the value being matched (of type Node) to the concrete type accepted by the extractor, so it is aware of the hierarchy. – Ivan Poliakov Jun 14 '11 at 14:24

extractors give you the possibility to use it in pattern matching like case classes in scala, but they don´t have other standard implementations you get when using the case modifier. But hust these extra implementation(especially the implementation of equals) is what makes case class inheritance dangerous and so it got deprecated.

However sealed classes are an orthogonal feature and you can use them whether or not you have a case class or an extractor. By using extractors you don´t get standard implementations on the fly but thus you can have inheritance of extractors - they are simply normal classes with an unapply and/or unapplySeq method.

What You´ve done in your example is called pattern-matching on types. If you only want to do this, you don´t need case classes neither extractors. You can do it with every class you want. So you can simply remove the case modifier.

So to conclude: exhaustiveness of pattern is achieved by sealed class hirachies. Pattern matching is achieved by extractors and case classes of what the latter is just an extractor with appealing standard implementations of frequently used functions. I hope this helped.

share|improve this answer
1  
Good answer, but please go over it once more for the many typos. Thanks! – Jean-Philippe Pellet Jun 13 '11 at 19:19
    
Thank you very much for this answer, I didn't know that exhaustiveness is achieved via sealed hierarchies as opposed to the case modifier. However if I extend the pattern matching beyond matching on types (I have added this correction to the original question) I still get unexpected behaviour, which, as it turns out, depends on the compiler version :( – Ivan Poliakov Jun 13 '11 at 19:45

The citation from scala-lang.org:

If the selector of a pattern match is an instance of a sealed class, the compilation of pattern matching can emit warnings which diagnose that a given set of patterns is not exhaustive, i.e. that there is a possibility of a MatchErrorbeing raised at run-time.

share|improve this answer

Your Answer

 
discard

By posting your answer, you agree to the privacy policy and terms of service.

Not the answer you're looking for? Browse other questions tagged or ask your own question.