```
l.find{x => x.p1 == x.p2}.getOrElse(l.maxBy(_.p2))
```

**UPDATE**: in your updated question you say "give me item with biggest p2, if you don't find it, give the lowest p1 and so on". But there is always a biggest value, by definition (unless the list is empty, but I gather the list can't be empty). So this is really just "give me item with biggest p2" (hence the above solution).

**UPDATE 2**: so the question changed again, and is now "find a item that p1 == p2, if you don't find it, give me item with p2 > p1 , if you don't find it, give the p1 = square(p2) and so on".
I guess you really need a generic solution after all.
So here's my take:

```
// The list of predicates, in order of priority
// (you can add/remove predicates as you see fit)
val predicates = List[A => Boolean](
x => x.p1 == x.p2,
x => x.p2 > x.p1,
x => x.p1 == x.p2*x.p2
)
val indexedPredicates = predicates.reverse.zipWithIndex
def score( x: A ): Option[Int] = indexedPredicates.find(_._1(x)).map(_._2)
def priorityFind( l: List[A] ): A = l.maxBy(score)
```

The idea is that you attribute a score to each element: None if the element does not match any predicate, Some(0) if it matches the last predicate, Some(1) if it matches the last but one predicate, and so on. Then you just take the one with the highest score (`None`

is "smaller" than any `Some`

instance, so this is consistent with what we want).

If you want to handle properly the case where no element matches any predicate, you would change `priorityFind`

like this:

```
def priorityFind( l: List[A] ): Option[A] = {
val filtered = l.view.flatMap{x => score(x).map(x -> _) }
if ( filtered.isEmpty ) None
else Some( filtered.maxBy(_._2)._1 )
}
```