17

I'm having compilation issues between Scala and Java.

My Java code needs a

java.util.Map<Double, java.lang.Iterable<Foo>>

My scala code has a

Map[Double, Vector[Foo]]

I get the compilation error:

error: type mismatch;
found   : scala.collection.immutable.Map[scala.Double,Vector[Foo]
required: java.util.Map[java.lang.Double,java.lang.Iterable[Foo]]

It seems the scala.collection.JavaConversions don't apply to nested collections, even though a Vector can be implictly converted to an Iterable. Short of iterating through the scala collection and doing the conversion by hand, is there something I can do to make the types work?

5 Answers 5

7

scala.collection.JavaConversions should be deprecated IMHO. You are better off being explicit about where and when the conversion happens by using scala.collection.JavaConverters. In your case:

import scala.collection.JavaConverters._

type Foo = Int // Just to make it compile
val scalaMap = Map(1.0 -> Vector(1, 2)) // As an example

val javaMap = scalaMap.map { 
  case (d, v) => d -> v.toIterable.asJava
}.asJava
1
  • Thanks for pointing me to JavaConversions. I didn't know about those. I also needed to do some nasty Java Generics Wildcarding for my method in order to get the return types working, i.e. converting my declared return type to public <T extends Iterable<Foo>> Map<Double,T> createMap()
    – Adam K
    Dec 21, 2012 at 4:27
5

This better suited my needs:

  def toJava(m: Any): Any = {
    import java.util
    import scala.collection.JavaConverters._
    m match {
      case sm: Map[_, _] => sm.map(kv => (kv._1, toJava(kv._2))).asJava
      case sl: Iterable[_] => new util.ArrayList(sl.map( toJava ).asJava.asInstanceOf[util.Collection[_]])
      case _ => m
    }
  }
4

I wrote this general purpose function, which works well for my needs.

def toJava(x: Any): Any = {
  import scala.collection.JavaConverters._
  x match {
    case y: scala.collection.MapLike[_, _, _] => 
      y.map { case (d, v) => toJava(d) -> toJava(v) } asJava
    case y: scala.collection.SetLike[_,_] => 
      y map { item: Any => toJava(item) } asJava
    case y: Iterable[_] => 
      y.map { item: Any => toJava(item) } asJava
    case y: Iterator[_] => 
      toJava(y.toIterable)
    case _ => 
      x
  }
}
3
  • Nice! I also wonder if you wrote a similar recursive toScala function.. Apr 15, 2017 at 15:14
  • ''' The recursive toScala function I ended up writing: def toScala(x: Any): Any = { import collection.JavaConversions._ x match { case y: java.util.Map[, _] => mapAsScalaMap(y).map{ case (d, v) => toScala(d) -> toScala(v) } case y: java.lang.Iterable[] => iterableAsScalaIterable(y).toList.map { item: Any => toScala(item) } case y: java.util.Iterator[_] => toScala(y) case _ => x } } ''' Apr 18, 2017 at 1:20
  • Separately, I posted a related question here: stackoverflow.com/questions/43462034/… Apr 18, 2017 at 1:20
0

Try this if anyone looking for solution in spark-scala,

import org.apache.spark.sql.catalyst.expressions.GenericRowWithSchema

Here, y is nested WrapperArray

y match {
          case x : WrappedArray[x] =>
             (x.map(f => f match {case z: GenericRowWithSchema => z.mkString(",").toString()
                                                case z:Any => z  })).asJavaCollection
          case _ => row.get(i).asInstanceOf[Object]
        }

The above code, does two things, 1) If wrapper Array has primitive data type, condition case_ gets through 2) If wrapper Array has Complex data type (say struts), case GenericRowWithSchema executes.

0

All the other solutions are Any to Any, which is pretty bad for a strongly typed language like Scala.
Here is a solution that keeps the types as much as possible:

trait AsJava[T, R] {
  def apply(o: T): R
}

object AsJava extends LowPriorityAsJava {
  implicit class RecursiveConverter[T](o: T) {
    def asJavaRecursive[R](implicit asJava: AsJava[T, R]): R = asJava(o)
  }

  implicit lazy val longAsJava: AsJava[Long, lang.Long] = new AsJava[Long, lang.Long] {
    def apply(o: Long): lang.Long = Long.box(o)
  }

  implicit lazy val intAsJava: AsJava[Int, lang.Integer] = new AsJava[Int, lang.Integer] {
    def apply(o: Int): lang.Integer = Int.box(o)
  }

  implicit lazy val doubleAsJava: AsJava[Double, lang.Double] = new AsJava[Double, lang.Double] {
    def apply(o: Double): lang.Double = Double.box(o)
  }

  implicit def mapAsJava[K, V, KR, VR](
      implicit
      keyAsJava: AsJava[K, KR],
      valueAsJava: AsJava[V, VR]
  ): AsJava[Map[K, V], util.Map[KR, VR]] =
    new AsJava[Map[K, V], util.Map[KR, VR]] {
      def apply(map: Map[K, V]): util.Map[KR, VR] =
        map.map { case (k, v) => (keyAsJava(k), valueAsJava(v)) }.asJava
    }

  implicit def seqAsJava[V, VR](implicit valueAsJava: AsJava[V, VR]): AsJava[Seq[V], util.List[VR]] =
    new AsJava[Seq[V], util.List[VR]] {
      def apply(seq: Seq[V]): util.List[VR] = seq.map(valueAsJava(_)).asJava
    }

  implicit def setAsJava[V, VR](implicit valueAsJava: AsJava[V, VR]): AsJava[Set[V], util.Set[VR]] =
    new AsJava[Set[V], util.Set[VR]] {
      def apply(set: Set[V]): util.Set[VR] = set.map(valueAsJava(_)).asJava
    }

  implicit lazy val anyAsJava: AsJava[Any, AnyRef] = new AsJava[Any, AnyRef] {
    def apply(o: Any): AnyRef = o match {
      case x: Map[Any, Any] => mapAsJava(anyAsJava, anyAsJava)(x)
      case x: Seq[Any]      => seqAsJava(anyAsJava)(x)
      case x: Set[Any]      => setAsJava(anyAsJava)(x)
      case x: Long          => longAsJava(x)
      case x: Int           => intAsJava(x)
      case x: Double        => doubleAsJava(x)
      case x                => x.asInstanceOf[AnyRef]
    }
  }
}

trait LowPriorityAsJava {
  implicit def otherAsJava[T]: AsJava[T, T] = new AsJava[T, T] {
    def apply(o: T): T = o
  }
}

Usage:

Seq(Seq.empty[Int]).asJavaRecursive

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