# Collection that contains no a where a⊆b and b is in the collection

I need a collection that disregards elements that are included in others:

``````Picky(Set(1, 2)) + Set(1) should equal(Picky(Set(1, 2)))

Picky(Set(1)) + Set(1, 2) should equal(Picky(Set(1, 2)))

Picky(Set(1, 3)) + Set(1, 2) should equal(Picky(Set(1, 3), Set(1, 2)))

Picky(Set(1, 2), (Set(1))) should equal(Picky(Set(1, 2)))
``````

I actually have a solution

``````case class Picky[T] private(sets: Set[Set[T]]) {
def +(s: Set[T]): Picky[T] = Picky(Picky.internalAddition(this.sets, s))
}

object Picky {
def apply[T](sets: Set[T]*): Picky[T] =
Picky((Set[Set[T]]() /: sets)(internalAddition(_, _)))

private def internalAddition[T](c: Set[Set[T]], s: Set[T]): Set[Set[T]] =
if (c.exists(s subsetOf _)) c else c.filterNot(_ subsetOf s) + s
}
``````

But I wonder whether there's already a collection that includes this concept, because what I'm trying to do sounds a bit like a set with a kind of reduction function, something like the following imaginary collection that accepts a `worse` function (`(a, b) => a subset b` in our specific case):

``````PickySet(){(a, b) => a subset b}
``````

Where for any to elements (a, b) if `worse(a, b)` returned `true`, `a` would be discarded

To clarify the difference with Set, a Set would be a special case of PickySet:

``````PickySet(){_ == _}
``````
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It seems to me, that you just want `Set`-semantics. Where's the difference? –  Peter Schmitz Mar 10 '12 at 9:48
Sets discard repeated elements Set(1, 1) == Set(1) also Set(Set(1), Set(1)) == Set(Set(1)) I'm looking for a collection that discards the worst of two elements Picky(Set(1, 2), Set(1)) == Picky(Set(1, 2)) –  qtwo Mar 10 '12 at 12:19

## 1 Answer

I don't think you're going to find a convenient ready-made implementation of this collection, but you can make yours a little more general by using `scala.math.PartialOrdering` and the fact that sets are partially ordered by the subset relation.

First for the definition of `Picky`. In effect what you want is a container holding only maximal elements, where no elements are ordered with respect to each other, and all smaller elements have been deleted.

``````class Picky[A: PartialOrdering] private(val xs: Seq[A]) {
def +(y: A): Picky[A] = new Picky(Picky.add(xs, y))
override def toString = "Picky(%s)".format(xs.mkString(", "))
}

object Picky {
def apply[A: PartialOrdering](xs: A*): Picky[A] =
new Picky(xs.foldLeft(Seq.empty[A])(add))

private def add[A](xs: Seq[A], y: A)(implicit ord: PartialOrdering[A]) = {
val notSmaller = xs.filterNot(ord.lteq(_, y))
if (notSmaller.exists(ord.lteq(y, _))) notSmaller else notSmaller :+ y
}
}
``````

Next for the partial ordering for sets, which is only defined if one of the sets is a subset of the other (possibly trivially):

``````implicit def subsetOrdering[A] = new PartialOrdering[Set[A]] {
def tryCompare(x: Set[A], y: Set[A]) =
if (x == y) Some(0)
else if (x subsetOf y) Some(-1)
else if (y subsetOf x) Some(1)
else None

def lteq(x: Set[A], y: Set[A]) =
this.tryCompare(x, y).map(_ <= 0).getOrElse(false)
}
``````

The following equivalent definition of `tryCompare` could conceivably be a little faster:

``````def tryCompare(x: Set[A], y: Set[A]) = {
val s = (x & y).size
if (s == x.size || s == y.size) Some(x.size - y.size) else None
}
``````

Now we get the desired results:

``````scala> Picky(Set(1, 2)) + Set(1)
res0: Picky[scala.collection.immutable.Set[Int]] = Picky(Set(1, 2))

scala> Picky(Set(1)) + Set(1, 2)
res1: Picky[scala.collection.immutable.Set[Int]] = Picky(Set(1, 2))

scala> Picky(Set(1, 3)) + Set(1, 2)
res2: Picky[scala.collection.immutable.Set[Int]] = Picky(Set(1, 3), Set(1, 2))

scala> Picky(Set(1, 2), (Set(1)))
res3: Picky[scala.collection.immutable.Set[Int]] = Picky(Set(1, 2))
``````

Note that we could very easily define an alternative partial ordering that would give `Picky` plain old set semantics (i.e., only equal things are ordered with respect to each other, and they're always equal).

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What you've posted is not a ready-made collection but places the problem within a more general concept, that is want I wanted. Thank you! I helps me understand. PS, would you recommend any source for this kind of theory? (I'm being greedy now) –  qtwo Mar 15 '12 at 23:20