# Chaining PartialFunctions with andThen in Scala

Let us reuse examples from Daily scala :

``````type PF = PartialFunction[Int,Int]

val pf1 : PF = {case 1 => 2}

val pf2 : PF = {case 2 => 3}
``````

``````val pf3 : PF = {case 3 => 4}
``````

andThen works as expected here:

``````pf1 andThen pf2 isDefinedAt(x)
``````

returns `true` iff `x == 1` (actually, `pf2` does not need to be a PartialFunction at all)

However, I expected that:

``````pf1 andThen pf3 isDefinedAt(x)
``````

would return `false` for all `x` (i.e., iff pf1 is defined, check for pf3), but it does not and only validates pf1.

In the end, `pf1 andThen pf3 lift(x)` always result in a MatchError. I would prefer to get None… I can obtain this behavior by lifting each function such as in `pf1.lift(x).flatMap(pf3.lift)` but is there any easier way using pure PartialFunction API? (and without lifting each partial function individually?)

-

If you look at `andThen`:

``````def andThen[C](k: (B) => C): PartialFunction[A, C]
``````

This composes the receiver with a function and not a partial function. That is, `k` is expected to be fully defined, it doesn't have `isDefinedAt`. Therefore, the resulting partial function does not need to alter the behaviour of `isDefinedAt`, it will still just has to consult the first partial function.

You could write your own extension that composes two partial functions:

``````implicit class ComposePartial[A, B](pf: PartialFunction[A, B]) {
def collect[C](that: PartialFunction[B, C]): PartialFunction[A, C] =
new PartialFunction[A, C] {
def apply(a: A): C = that(pf(a))
def isDefinedAt(a: A) = pf.isDefinedAt(a) && {
val b = pf(a)
that.isDefinedAt(b)
}
}
}

pf1 collect pf2 isDefinedAt(1)  // true
pf1 collect pf3 isDefinedAt(1)  // false
``````

The problem is that you have to invoke `pf(a)`, so given that Scala doesn't enforce purity, you may end up executing side effects unwantedly.

-
I try this, but all `apply` and `isDefinedAt` colled twice. – andrey.ladniy Apr 11 '15 at 17:29

You need the equivalent of `flatMap` for `PartialFunction`s.

``````implicit class CollectPartial[A, B](f: PartialFunction[A, B]) {
def collect[C](g: PartialFunction[B, C]) = Function.unlift { a: A =>
f.lift(a).flatMap(g.lift)
}
}
``````

Use it like

``````val a: PartialFunction[String, Int] = ...
val b: PartialFunction[Int, Char] = ...
val c: PartialFunction[String, Char] = a collect b
``````

This works as expected even with side-effects.

-

Why not simply :

``````def compose[A,B,C](f: PartialFunction[A, B], g: PartialFunction[B, C]) : PartialFunction[A, C] =
Function.unlift(f.andThen(g.lift))
``````
-