# How to combine Option values in Scala?

I want to be able to apply an operation `f: (T,T) => T` to `Option[T]` values in Scala. I want the result to be `None` if any of the two values is `None`.

More specifically, I want to know if there is a shorter way to do the following:

``````def opt_apply[T](f: (T,T) => T, x: Option[T], y: Option[T]): Option[T] = {
(x,y) match {
case (Some(u),Some(v)) => Some(f(u,v))
case _ => None
}
}
``````

I have tryied `(x zip y) map {case (u,v) => f(u,v)}` but the result is an `Iterator[T]` not an `Option[T]`.

``````scala> val (x, y) = (Some(4), Some(9))
x: Some[Int] = Some(4)
y: Some[Int] = Some(9)

scala> def f(x: Int, y: Int) = Math.max(x, y)
f: (x: Int,y: Int)Int

scala> for { x0 <- x; y0 <- y } yield f(x0, y0)
res26: Option[Int] = Some(9)

scala> val x = None
x: None.type = None

scala> for { x0 <- x; y0 <- y } yield f(x0, y0)
res27: Option[Int] = None
``````

@RahulG's answer exploits the fact that `Option` is a monad (even though there is no type to represent this in the Scala library). The compiler expands the `for` comprehension to the following:

``````def a: Option[Int]
def b: Option[Int]
val calc: Option[Int] = a flatMap {aa => b map {bb => aa + bb}}
``````

You can also treat it as an applicative functor, with some help from Scalaz:

``````import scalaz._
import Scalaz._

def a: Option[Int]
def b: Option[Int]
val calc: Option[Int] = (a ⊛ b) {_ + _}
``````

A key difference is that in the monadic calculation, a failure (that is, `None`) of calculation `a` short circuits the evaluation. In the applicative style, both `a` and `b` are evaluated, and if both are `Some`s, the pure function is called. You can also see that in the monadic calculation, the value `aa` could have been used in the calculation `b`; in the applicative version, `b` cannot depend on the result of `a`.

• Is the ASCII equivalent `<|*|>` for this method? Apr 26 '10 at 11:51
• `<*>` allows you to provide the 'pure' function, in this case `(a, b)=> a + b`. `<|*|>` is a convenience for using `Tuple2.apply` as the pure function. `⊛` is actually a bit more general than arity-2, you could write `(a ⊛ b a ⊛ b) {_ + _ + _ + _}`. It's a little experimental, and as such, doesn't have a ASCII alias yet. Apr 26 '10 at 12:02
• Typo, I meant: `(a ⊛ b ⊛ a ⊛ b) {_ + _ + _ + _}` Apr 26 '10 at 12:25
• From the 7th version of Scalaz ASCII alias to `⊛` operator is `|@|`: `val calc: Option[Int] = (a |@| b) {_ + _}` Jan 29 '14 at 15:48

I have a slightly older version of scalaz than retronym but the following works for me as an example and is generalizable for the case where you have 3 types `T, U, V` and not just one:

``````def main(args: Array[String]) {
import scalaz._
import Scalaz._

val opt1 = some(4.0) //Option[Double]
val opt2 = some(3)   //Option[Int]

val f: (Double, Int) => String = (d, i) => "[%d and %.2f]".format(i, d)

val res = (opt1 <|*|> opt2).map(f.tupled)
println(res) //Some([3 and 4.00])
}
``````

``````val opt3 = none[Int]
val res2 = (opt1 <|*|> opt3).map(f.tupled)
println(res2) //None
``````
• Replace `<|*|>` with `<*>` to avoid creation of the temporary tuple, and use `f` directly. Apr 26 '10 at 15:19

You can use for comprehensions:

``````def opt_apply[T](f: (T,T) => T, x: Option[T], y: Option[T]): Option[T] =
for (xp <- x; yp <- y) yield (f(xp,yp))
``````

Which is sugar for:

``````x flatMap {xp => y map {yp => f(xp, yp)}}
``````

This is also possible due to Option being a Monad

• That's weird. I didn't see @RahulG's answer when I posted this. Apr 26 '10 at 14:52
``````def optApply[A,B,C](f: (A, B) => C, a: Option[A], b: Option[B]): Option[C] =
a.zip(b).headOption.map { tup => f.tupled(tup) }
``````

`a.zip(b)` does result in an Iterable[(A, B)] (with, because it's from Options, at most one element). `headOption` then returns the first element as an Option.

Starting `Scala 2.13`, `Option#zip` can be applied to another `Option` to return an `Option` (in earlier versions, it would have returned an `Iterable`); thus:

``````def optApply[T](f: (T,T) => T, a: Option[T], b: Option[T]): Option[T] =
a.zip(b).map(f.tupled)
``````

where the behavior of `zip` is:

``````Some(2).zip(Some(3)) // Some((2, 3))
Some(2).zip(None)    // None
None.zip(Some(3))    // None
None.zip(None)       // None
``````

and which can be applied as such:

``````optApply[Int]((a, b) => a max b, Some(2), Some(5)) // Some(5)
optApply[Int]((a, b) => a max b, Some(2), None)    // None
``````