“Closed” HashMap in Java/Scala

Question

Very often the performance bottleneck when using hash maps is the equals method. equals can be very expensive for deep data structures.

Note, that the following is about immutable hash maps. Thus, at least you will never remove a key. I think adding keys should be ok.

Unsafe get

Suppose you query a hash map, being certain it contains the queried key. Then if there is no collision for the given key, the found single entry can be returned just based on the hash hit, because it has to be the queried object.

This can avoid calling equals in get in most cases (when there is no collision).

Questions

1. How is this concept called?
2. Are there any hash map implementations available for Java or Scala, that support such an unsafe get operation?

Btw, I'm open for suggestions of a better subject line.

Answer 1

How is this concept called?

Identity map. It won't call equals() when looking for elements and just use identity (i.e. ==).

The correct solution isn't to "fix" the map but to use only keys which use the default Object.equals():

public boolean equals( Object other ) { return this == other; }

The problem is that finding elements in this map can be problematic unless all keys are singletons. So you can't use String, for example, because Java doesn't guarantee that all string instances are interned. The same is true for Integer: Instances < -128 and > 127 will be different.

But if you use your own optimized implementation for keys, you can solve this.

Answer 2

Such a data structure doesn't exist to my knowledge exactly because it's unsafe - there is no way to reliably encode your particular condition.

But, alas, the Scala Collection Library allows one to implement new rich data structures very quickly with a small amount of fresh code. Here's an implementation of your request:

class ParticularHashMap[A, +B] private(buckets: Vector[List[(A, B)]]) extends Map[A, B]{

    def this() = this(Vector.fill(ParticularHashMap.BucketsNo)(List.empty))

    def get(key: A) = {
        val bucket = buckets(bucketIndex(key))

        bucket match {
            case List((_, v)) => Some(v) //YOUR SPECIAL OPTIMIZATION !
            case list => list.find(key == _._1).map(_._2)
        }
    }

    def iterator = buckets.flatten.iterator

    def -(key: A) = mkWithUpdatedBucket(key, _ filterNot (_._1 == key))

    def +[B1 >: B](kv: (A, B1)) = mkWithUpdatedBucket(kv._1, insert(kv._1, kv._2.asInstanceOf[B], _))

    //if you're wondering why it's Bucket[A, Any] and not Bucket[A, B] it's because of the covariance of B
    private def mkWithUpdatedBucket(key: A, f: Bucket[A, Any] => Bucket[A, Any]) = {
        val index = bucketIndex(key)
        val newBucket = f(buckets(index))
        (new ParticularHashMap[A, Any](buckets.updated(index, newBucket))).asInstanceOf[ParticularHashMap[A, B]]
    }

    private def insert(k: A, v: Any, bucket: List[(A, Any)]): Bucket[A, Any] = bucket match {
        case List() => List((k, v))
        case (k1, v1) :: kvs if k == k1 => (k, v) :: kvs
        case (k1, v1) :: kvs => (k1, v1) :: insert(k, v, kvs)
    }

    private def bucketIndex(key: A) = Math.abs(key.hashCode()) % ParticularHashMap.BucketsNo
}

object ParticularHashMap {
    private val BucketsNo = 256

    private type Bucket[+A, +B] = List[(A, B)]

    def apply[A, B](kvs: (A, B)*) = new ParticularHashMap[A, B] ++ kvs

}

Please note that this is a naive implementation, but you can improve it too suit your needs.

It will work as expected:

val myMap = ParticularHashMap("hello" -> 2, "world" -> 4)
println(myMap.get("hello")) >> Some(2)
println(myMap.get("world")) >> Some(4)
println(myMap.get("world1")) >> None

But, of course, beware that if you don't respect your contract, bad things will happen. Below is an especially crafted example to show the downside:

val evilMap = ParticularHashMap(1 -> 2)
println(evilMap.get(1)) >> Some(2)
println(evilMap.get(257)) >> Some(2) //BUT 257 IS NOT IN THE MAP !!!

Answer 3

1) How is this concept called?

AFAIK, it doesn't have a name. People generally only give names to solutions that work. A solution that doesn't work (or that only works in very limited situations) isn't generally worthy of a name.

2) Are there any hash map implementations available for Java or Scala, that support such an unsafe get operation?

Not that I'm aware of. Once again, people tend not to write and publish libraries that only work in limited situations or that are problematic in their behaviour.

---

Where's the flaw in it? Why is it not working?

First, a Map.get(...) method that returned the wrong value if you gave it a key that was not recognized is fundamentally breaking the Java Map.get contract. And there could well be other broken methods; e.g. Map.containsKey, Map.put, Map.putAll and/or Map.remove.

Second, a data structure that gives the wrong answer if your assumptions are incorrect is a bad idea ... if you can avoid it.

Third, modulo that we don't know your actual use-case, there are almost certainly better ways to solve the problem. The obvious ones are:

• change equals the key class to make it less expensive,
• if you can't change equals, define and use a proxy key class, or
• use a Map<Integer, List<Pair<Key,ValueClass>>> where the integers used as keys are the hashcodes for the actual keys.

(The last approach requires the dubious "always contains the key" assumption, but at least you have not broken the Map abstraction, and can therefore do proper checks when required.)

Finally, even if you do decide that your "dirty" optimization is necessary for your application, and decide to implement it yourself. I claim that my answers still stand as correct explanations as to:

1. why there isn't a commonly accepted term for this "hack", and
2. why there isn't an off-the-shelf implementation in the 3 main Java collection libraries (or any other that I'm currently aware of.)

You might not like it, but there isn't a better explanation.