# In Scala, how to use Ordering[T] with List.min or List.max and keep code readable

In Scala 2.8, I had a need to call List.min and provide my own compare function to get the value based on the second element of a Tuple2. I had to write this kind of code:

``````val list = ("a", 5) :: ("b", 3) :: ("c", 2) :: Nil

list.min( new Ordering[Tuple2[String,Int]] {
def compare(x:Tuple2[String,Int],y:Tuple2[String,Int]): Int = x._2 compare y._2
} )
``````

Is there a way to make this more readable or to create an Ordering out of an anonymous function like you can do with `list.sortBy(_._2)`?

-

C'mon guys, you made the poor questioner find "on" himself. Pretty shabby performance. You could shave a little further writing it like this:

``````list min Ordering[Int].on[(_,Int)](_._2)
``````

Which is still far too noisy but that's where we are at the moment.

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`list min Ordering.by((_: (_, Int))._2)` –  Seth Tisue Sep 4 '10 at 14:01
I see smileys ... –  soc Aug 25 '11 at 8:19
list min Ordering[Int].on[WeightedType](_.weight) –  cessationoftime Dec 14 '11 at 20:06
Just in case, `Ordering[Int]` is equivalent to `Ordering.apply[Int]`. –  Andrew McKinlay Jul 28 at 1:56

One thing you can do is use the more concise standard tuple type syntax instead of using `Tuple2`:

``````val min = list.min(new Ordering[(String, Int)] {
def compare(x: (String, Int), y: (String, Int)): Int = x._2 compare y._2
})
``````

Or use `reduceLeft` to have a more concise solution altogether:

``````val min = list.reduceLeft((a, b) => (if (a._2 < b._2) a else b))
``````

Or you could sort the list by your criterion and get the `first` element (or `last` for the max):

``````val min = list.sort( (a, b) => a._2 < b._2 ).first
``````

Which can be further shortened using the placeholder syntax:

``````val min = list.sort( _._2 < _._2 ).first
``````

Which, as you wrote yourself, can be shortened to:

``````val min = list.sortBy( _._2 ).first
``````

But as you suggested `sortBy` yourself, I'm not sure if you are looking for something different here.

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I haven't look at the library code, but the reason I prefer to use `min` is I assume that would it would be linear in time whereas `sortBy` would be o(n.log(n)). I also think using a method called `min` makes the intent clearer, although `list.sortBy(_._2).first` is pretty clear too. –  huynhjl Feb 3 '10 at 14:50

You could always define your own implicit conversion:

``````implicit def funToOrdering[T,R <% Ordered[R]](f: T => R) = new Ordering[T] {
def compare(x: T, y: T) = f(x) compare f(y)
}

val list = ("a", 5) :: ("b", 3) :: ("c", 2) :: Nil

list.min { t: (String,Int) => t._2 }  // (c, 2)
``````

Might be more readable if the conversion wasn't implicit, but using an "on" function:

``````def on[T,R <% Ordered[R]](f: T => R) = new Ordering[T] {
def compare(x: T, y: T) = f(x) compare f(y)
}

val list = ("a", 5) :: ("b", 3) :: ("c", 2) :: Nil

list.min( on { t: (String,Int) => t._2 } ) // (c, 2)
``````
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+1 Nice. Was about to post the same. In Haskell, you'd have an `on` combinator defined for this purpose. E.g. `sort (compare 'on' length)` to sort a list by length –  Dario Feb 3 '10 at 9:21
Yes, I like the explicit conversion better. Reads better with "on". –  Mitch Blevins Feb 3 '10 at 9:28
The trick is that on is basically an infix operator for functions. It's just `f 'on' g = \x y -> f (g x) (g y)` for all fitting functions. But yours is nice as well –  Dario Feb 3 '10 at 9:44
Personally, I'd write `on` to take another `Ordering`. –  Daniel C. Sobral Feb 3 '10 at 11:50
Turns out `on` already exists in the library, saw that when I looked up how `sortBy` is implemented while checking another answer. That led me to this `list.min( Ordering.Int.on[(String,Int)] (_._2) )`. –  huynhjl Feb 3 '10 at 15:42
``````list.min(Ordering.fromLessThan[(String, Int)](_._2 < _._2))
``````

Which is still too verbose, of course. I'd probably declare it as a `val` or `object`.

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The function `Ordering#on` witnesses the fact that `Ordering` is a contra-variant functor. Others include `Comparator`, `Function1`, `Comparable` and `scalaz.Equal`.

Scalaz provides a unified view on these types, so for any of them you can adapt the input with `value contramap f`, or with symbolic denotation, `value ∙ f`

``````scala> import scalaz._
import scalaz._

scala> import Scalaz._
import Scalaz._

scala> val ordering = implicitly[scala.Ordering[Int]] ∙ {x: (_, Int) => x._2}
ordering: scala.math.Ordering[Tuple2[_, Int]] = scala.math.Ordering\$\$anon\$2@34df289d

scala> List(("1", 1), ("2", 2)) min ordering
res2: (java.lang.String, Int) = (1,1)
``````

Here's the conversion from the `Ordering[Int]` to `Ordering[(_, Int)]` in more detail:

``````scala> scalaz.Scalaz.maContravariantImplicit[Ordering, Int](Ordering.Int).contramap { x: (_, Int) => x._2 }
res8: scala.math.Ordering[Tuple2[_, Int]] = scala.math.Ordering\$\$anon\$2@4fa666bf
``````
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Scalaz is black belt level stuff. Could be dangerous for me to try now... But it may provide me an angle on Scalaz that I can relate to. So the unified view is provided by `implicitly`? What is `comap`? Is it similar to `map`? Where can I find more documentation? –  huynhjl Feb 4 '10 at 13:54
Updated the answer as per Scalaz 6. –  missingfaktor Sep 15 '11 at 17:04
In Scala 2.9, you can do `list minBy { _._2 }`.