Take the 2-minute tour ×
Stack Overflow is a question and answer site for professional and enthusiast programmers. It's 100% free, no registration required.

I'm trying to implement a new type, Chunk, that is similar to a Map. Basically, a "Chunk" is either a mapping from String -> Chunk, or a string itself.

Eg it should be able to work like this:

val m = new Chunk("some sort of value") // value chunk 
assert(m.getValue == "some sort of value")

val n = new Chunk("key" -> new Chunk("value"), // nested chunks
                  "key2" -> new Chunk("value2"))
assert(n("key").getValue == "value")
assert(n("key2").getValue == "value2")

I have this mostly working, except that I am a little confused by how the + operator works for immutable maps.

Here is what I have now:

class Chunk(_map: Map[String, Chunk], _value: Option[String]) extends Map[String, Chunk] {
  def this(items: (String, Chunk)*) = this(items.toMap, None)
  def this(k: String) = this(new HashMap[String, Chunk], Option(k))
  def this(m: Map[String, Chunk]) = this(m, None)

  def +[B1 >: Chunk](kv: (String, B1)) = throw new Exception(":( do not know how to make this work")
  def -(k: String) = new Chunk(_map - k, _value)
  def get(k: String) = _map.get(k)
  def iterator = _map.iterator

  def getValue = _value.get
  def hasValue = _value.isDefined

  override def toString() = {
    if (hasValue) getValue
    else "Chunk(" + (for ((k, v) <- this) yield k + " -> " + v.toString).mkString(", ") + ")"
  }

  def serialize: String = {
    if (hasValue) getValue
    else "{" + (for ((k, v) <- this) yield k + "=" + v.serialize).mkString("|") + "}"
  }
}

object main extends App {
  val m = new Chunk("message_info" -> new Chunk("message_type" -> new Chunk("boom")))
  val n = m + ("c" -> new Chunk("boom2"))
}

Also, comments on whether in general this implementation is appropriate would be appreciated.

Thanks!

Edit: The algebraic data types solution is excellent, but there remains one issue.

def +[B1 >: Chunk](kv: (String, B1)) = Chunk(m + kv) // compiler hates this
def -(k: String) = Chunk(m - k) // compiler is pretty satisfied with this

The - operator here seems to work, but the + operator really wants me to return something of type B1 (I think)? It fails with the following issue:

overloaded method value apply with alternatives: (map: Map[String,Chunk])MapChunk <and> (elems: (String, Chunk)*)MapChunk cannot be applied to (scala.collection.immutable.Map[String,B1])

Edit2: Xiefei answered this question -- extending map requires that I handle + with a supertype (B1) of Chunk, so in order to do this I have to have some implementation for that, so this will suffice:

def +[B1 >: Chunk](kv: (String, B1)) = m + kv

However, I don't ever really intend to use that one, instead, I will also include my implementation that returns a chunk as follows:

def +(kv: (String, Chunk)):Chunk = Chunk(m + kv)
share|improve this question
    
The implementation for +, in the case of immutable Maps, must return a new Map with the added key/value, right? You already 'wrap' a Map (_map), so for an implementation of your +, just delegating to _map will work: def +[B1 >: Chunk](kv: (String,B1)) = _map + kv. The real issue is, that this makes no sense whatsoever for 'simple' Chunks (those that are just a String). In other words, having the set of constructors you describe above, and implementing + breaks your definition of a Chunk... because it allows a String-chunk to //also// become a Map-chunk. –  Faiz Nov 28 '12 at 12:12

4 Answers 4

Have you considered using composition instead of inheritance? So, instead of Chunk extending Map[String, Chunk] directly, just have Chunk internally keep an instance of Map[String, Chunk] and provide the extra methods that you need, and otherwise delegating to the internal map's methods.

share|improve this answer
1  
I thought about this, and it's a pretty good point, I was tempted, though, by all the goodies that are included for free by extending map. –  mattomatic Nov 28 '12 at 17:57
def +(kv: (String, Chunk)):Chunk = new Chunk(_map + kv, _value)
override def +[B1 >: Chunk](kv: (String, B1)) = _map + kv

What you need is a new + method, and also implement the one declared in Map trait.

share|improve this answer

The way it's written, there's no way to enforce that it can't be both a Map and a String at the same time. I would be looking at capturing the value using Either and adding whatever convenience methods you require:

case class Chunk(value:Either[Map[String,Chunk],String]) {
  ...
}

That will also force you to think about what you really need to do in situations such as adding a key/value pair to a Chunk that represents a String.

share|improve this answer

How about an Algebraic data type approach?

  abstract sealed class Chunk
  case class MChunk(elems: (String, Chunk)*) extends Chunk with Map[String,Chunk] {
    val m = Map[String, Chunk](elems:_*)
    def +[B1 >: Chunk](kv: (String, B1)) =  m + kv
    def -(k: String) =  m - k
    def iterator = m.iterator
    def get(s: String) = m.get(s)
  }
  case class SChunk(s: String) extends Chunk
  // A 'Companion' object that provides 'constructors' and extractors..
  object Chunk {
    def apply(s: String) = SChunk(s)
    def apply(elems: (String, Chunk)*) = MChunk(elems: _*)
    // just a couple of ideas...
    def unapply(sc: SChunk) = Option(sc).map(_.value)
    def unapply(smc: (String, MChunk)) = smc match {
      case (s, mc) => mc.get(s)
    }

  }

Which you can use like:

val simpleChunk = Chunk("a")
val nestedChunk = Chunk("b" -> Chunk("B"))
// Use extractors to get the values.
val Chunk(s) = simpleChunk // s will be the String "a"
val Chunk(c) = ("b" -> nestedChunk) // c will be a Chunk: Chunk("B")
val Chunk(c) = ("x" -> nestedChunk) // will throw a match error, because there's no "x"
// pattern matching:
("x" -> mc) match { 
  case Chunk(w) => Some(w)
  case _ => None 
} 

The unapply extractors are just a suggestion; hopefully you can mess with this idea till you get what you want.

share|improve this answer
2  
+1 The formulation "Basically, a Chunk is either a mapping from String -> Chunk, or a string itself." imho calls for some kind sealed abstract class/trait. The open question to me is what kind of functionality should be included in this super class. Should it in general behave like a Map or a String? In this regard the question isn't fully clear to me... –  bluenote10 Nov 28 '12 at 11:41

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.