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What is the best way to filter a collection of objects based on the type parameters of those objects, assuming that I have control over both classes and that I need covariant filtering?

Here is some code that doesn't work properly:

trait Foo
case class Foo1() extends Foo
trait ReadableFoo extends Foo {def field: Int}
case class Foo2(field: Int, flag: Boolean) extends ReadableFoo
case class Foo3(field: Int, name: String) extends ReadableFoo

case class Bar[+F <: Foo](foo: F)

val seq = Seq(
  Bar[Foo1](Foo1()),
  Bar[Foo2](Foo2(1,true)), 
  Bar[Foo3](Foo3(1,"Fooz"))
)

// Should keep one
val first = seq collect {case x: Bar[Foo2] => x}

// Should keep two
val both = seq collect {case x: Bar[ReadableFoo] => x}

Now, I know that is it because the case x: Bar[Foo1] gets converted via type erasure to case x: Bar[_] after compilation. I have been unable to use Manifests to solve this problem. Is there some way to add a member type (i.e. memberType = F) to Bar that I can just switch on like case x if (x.memberType <:< ReadableFoo) => x?

Update

0__ quickly found a good solution to the original problem. A slight modification is when the case class field is itself a collection:

case class Bar[+F <: Foo](foo: Seq[F])

val seq = Seq(
  Bar[Foo1](Seq(Foo1())),
  Bar[Foo2](Seq(Foo2(1,true))),
  Bar[ReadableFoo](Seq(Foo2(1,true), Foo3(1,"Fooz")))
)

// Should keep one
val first = seq collect {case x: Bar[Foo2] => x}

// Should keep two
val both = seq collect {case x: Bar[ReadableFoo] => x}

I'm not sure this is possible since the Seq could be empty and, therefore, have no elements to test.

share|improve this question
1  
This might help. –  missingfaktor Jul 3 '12 at 23:22
    
@missingfaktor Yes, I suppose printing all the type parameters to strings and then doing my own ad-hoc inheritance testing using a tree of strings would be one way to do it. –  drhagen Jul 3 '12 at 23:37

2 Answers 2

up vote 1 down vote accepted

I wasn't aware of the type checking at the extractor trick so my initial solution to your fist problem would've been a little different. I would've provided an extractor for ReadableFoo

object ReadableFoo { def unapply(x: ReadableFoo) = Some(x.field) }

Then you could do

val first = seq collect { case x @ Bar(Foo2(_,_)) => x }
val both  = seq collect { case x @ Bar(ReadableFoo(_)) => x }

But for your updated code, I think you'd need to drag along a manifest.

case class Bar[+F <: Foo : Manifest](foo: Seq[F]) { 
    def manifest = implicitly[Manifest[_ <: F]] 
}

Since Bar is covariant and Manifest is invariant we can't simply promise to return a Manifest[F] but a Manifest of some subtype of F. (I guess this was your problem when trying to use manifests?)
After that you can do

val first = seq collect {case x if x.manifest <:< manifest[Foo2] => x}
val both = seq collect {case x if x.manifest <:< manifest[ReadableFoo] => x}

Still, using manifests always feels a little hacky. I'd see if I can use a different approach and rely on type matching and reification as little as possible.

share|improve this answer
    
That seems to work perfectly (after I drop an asInstanceOf on x, per Sciss's suggestion). Is there a catch, because it seems that the Scala compiler would inject those def manifest and if statements automatically if it was just this easy? –  drhagen Jul 4 '12 at 16:11
    
Well it adds some overhead I suppose. The compiler injects only the manifests themselves on demand but always for arrays since they actually need to map to Java arrays. For everything else, they are really not that frequently wanted and less frequently needed. Simply using case classes/extractors and matching on values is good enough most of the time. –  Kaito Jul 4 '12 at 16:51

You can combine extractor with type check:

val first = seq collect { case x @ Bar(_: Foo2)        => x }
val both  = seq collect { case x @ Bar(_: ReadableFoo) => x }

But the return type will still be List[Bar[Foo]] ... so if you need that, with this approach you would need to cast or re-construct the Bar object (case Bar(f: Foo2) => Bar(f)).


With a heterogeneous Seq I guess you are looking for collect on the Seq itself?

case class Bar(seq: Seq[Foo])

def onlyFoo2(b: Bar) = Bar(b.seq.collect { case f: Foo2 => f })

onlyFoo2(Bar(Seq(Foo1(), Foo2(1, true))))
share|improve this answer
    
Can this be chained, like if Bar had a foo: Seq[F] rather than just foo: F? I can edit the question if that would improve clarity. –  drhagen Jul 3 '12 at 23:46
    
As long as you have extractors, yes. It would be case Bar(Seq(f: Foo2) => Bar(Seq(f)) -- again if you need the return type to be Bar[Seq[Foo2]] you need to either cast or rebuild the object –  0__ Jul 3 '12 at 23:51
    
Wouldn't that Seq(f: Foo2) only match a sequence with a single element? –  drhagen Jul 3 '12 at 23:55
    
Are you planning to have different Foo subtypes within a Seq, or are all of the the same, e.g. Seq[Foo2]? –  0__ Jul 3 '12 at 23:56
    
They are going to be different subtypes. It could be a Seq of Foo2 and Foo3 so that Bar and Seq will be parameterized with ReadableFoo. –  drhagen Jul 4 '12 at 0:01

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