1

This problem is kind of specific to Scala's pattern matching syntax. So let's say I have some code equivalent to this:

def process(seq: Seq[SomeObjectType]): SomeReturnType = seq match {
    case Seq() => // Return something
    case s if s exists (o => o.somePropertyTest) => {
        // Ok, the test is satisfied, now let's find
        // that object in the sequence that satisfies
        // it and do something with it
    }
    case _ => // Return something if no other case matches
}

Now obviously, this code is not as efficient as it could be since I check if there is an element in the sequence that satisfies some test, then in that case I go ahead and find the element and work with it, which can be done somewhat like this to avoid traversing the sequence twice:

def process(seq: Seq[SomeObjectType]): SomeReturnType = seq match {
    case Seq() => // Return something
    case s => {
        val obj = s find (o => o.somePropertyTest)
        if !obj.isEmpty {
            // Ok, the test is satisfied, and we have
            // the object that satisfies it, obj, so
            // do something with it directly
        } else {
            // Handle the no-match case here instead
        }
    }
}

But this defeats the whole purpose of pattern matching, especially when there are multiple cases after the one where I do the test. I still want the execution to fall to the next case if the test does not pass, i.e. if no element satisfies the condition, but I also want to "retain" the element of the sequence that was found in the test and use it directly in the case body, kind of similar to the way one can use @ to give a name to a complex case and use that name in its body. Is what I'm trying to do possible with pattern matching? Or is it just too complicated for pattern matching to be able to handle it?

Note that this is a simplified example for clarity. In my actual problem, the sequences are long and the test on each element of a sequence consists in building a relatively big tree and checking whether some properties hold for that tree, so it is really not an option to just do with the inefficient first version.

  • 1
    I have long wished that Scala had syntax to treat an arbitrary expression as an extractor. Imagine if you could write seq match { case { _.find(_.prop) }(o) => ... }. It makes perfect semantic sense and it's obvious how to desugar it; there's just no syntax for it. IMO it is an obvious syntactic gap when a functional language treats variables differently than the expressions they stand for. – Owen Apr 25 '18 at 23:25
  • 1
    I agree! This would significantly increase the power and flexibility of Scala's pattern matching, which is one the central features of the language. – Namefie Apr 26 '18 at 9:12
2

You can define a custom extractor object with an unapply method. The limitation is that you can't create such an object inline, inside the pattern match. You have to create it explicitly before matching. For example:

case class Selector[T](condition: T => Boolean) {
  def unapply(seq: Seq[T]): Option[T] = seq.find(condition)
}
object Selector {
  // seq argument is used only to infer type `T`
  def from[T](seq: Seq[T])(condition: T => Boolean): Selector[T] = Selector(condition)
}

def process(seq: Seq[SomeObjectType]): SomeReturnType = {
  // Create an extractor object instance
  val Select = Selector.from(seq)(_.somePropertyTest)

  seq match {
    case Seq() =>     // seq empty
    case Select(o) => // found o, we can process it now
    case _ =>         // didn't find a suitable element
  }
}  
  • Wow, this actually works! What I like about this solution is that it moves most of the dirty work outside the pattern matching itself. Still I'm not sure I completely understand it, in particular, how could seq match a Select(o)? Isn't the latter of type Selector[SomeObjectType] in this case? Or is there some magic introduced by this extractor paradigm? – Namefie Apr 26 '18 at 9:27
  • @Namefie Yes, sort of magic. seq match { case Select(o) => } calls Select.unapply(seq), the result of which is Option[SomeObjectType]. And if this unapply returns Some, the match case succeeds and the result SomeObjectType is assigned to o. In other words it's equivalent to Select.unapply(seq) match { case Some(o) => }. Select itself is just an object witn an unapply method, an instance of Selector class, so Select(o) is illegal outside of case, and doesn't have a type. – Kolmar Apr 26 '18 at 10:51
  • Alright makes sense! Thanks :) – Namefie Apr 26 '18 at 10:56
0

Not tested, but something like this:

def process(seq: Seq[SomeObjectType]): SomeReturnType = seq match {
    case Seq() => // Return something
    case x +: xs if x.somePropertyTest == desiredProperty => something(x)
    case x +: xs => process(xs)
}

This works because a Seq is a recursive structure, over which process recurses.

  • Well, sure this is the standard way of combining pattern matching and recursive calls to traverse a sequence and handle each element. But you made the assumption that my "process" function is recursive, which it is simply not. So this simply does not answer my question. – Namefie Apr 25 '18 at 23:42
  • Why can't your process function be recursive? – tpdi Apr 26 '18 at 0:31
  • I agree that it's not clear why I specifically don't want it to be recursive. My comment to slouc's answer hopefully makes it more clear. – Namefie Apr 26 '18 at 5:37

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