# Type inference on anonymous functions with enrich-my-library

Say I have a method that turns a (function on two elements) into a (function on two sequences):

``````def seqed[T](f: (T,T) => T): (Seq[T], Seq[T]) => Seq[T] = (_,_).zipped map f
``````

In words, the resulting function takes two sequences `xs` and `ys`, and creates a new sequence consisting of `(xs(0) f ys(0), xs(1) f ys(1), ...)` So, for example, if `xss` is `Seq(Seq(1,2),Seq(3,4))` and `f` is `(a: Int, b: Int) => a + b`, we can invoke it thus:

``````xss reduceLeft seqed(f)         // Seq(4, 6)
``````

or with an anonymous function:

``````xss reduceLeft seqed[Int](_+_)
``````

This is pretty good; it would be nice to get rid of the `[Int]` type argument but I don't see how (any ideas?).

To make it feel a bit more like the `tupled` method, I also tried the enrich-my-library pattern:

``````class SeqFunction[T](f: (T,T) => T) {
def seqed: (Seq[T], Seq[T]) => Seq[T] = (_,_).zipped map f
}
implicit def seqFunction[T](f: (T,T) => T) = new SeqFunction(f)
``````

For a pre-defined function this works great, but it's ugly with anonymous ones

``````xss reduceLeft f.seqed
xss reduceLeft ((_:Int) + (_:Int)).seqed
``````

Is there another way I can reformulate this so that the types are inferred, and I can use syntax something like:

``````// pseudocode
xss reduceLeft (_+_).seqed         // ... or failing that
xss reduceLeft (_+_).seqed[Int]
``````

? Or am I asking too much of type inference?

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Here Daniel Spiewak made a presentation about type systems and type inference in `scala` and other static typed languages. Maybe that's not exactly on topic, but anyway, I found it extremely interesting. –  4e6 Nov 30 '11 at 21:24

You can't do it the way you want, but look at `Function.tupled`, which is a counter-part to `.tupled` that solves this very same problem.

``````scala> List(1, 2, 3) zip List(1, 2, 3) map (_ + _).tupled
<console>:8: error: missing parameter type for expanded function ((x\$1, x\$2) => x\$1.\$plus(x\$2))
List(1, 2, 3) zip List(1, 2, 3) map (_ + _).tupled
^
<console>:8: error: missing parameter type for expanded function ((x\$1: <error>, x\$2) => x\$1.\$plus(x\$2))
List(1, 2, 3) zip List(1, 2, 3) map (_ + _).tupled
^

scala> List(1, 2, 3) zip List(1, 2, 3) map Function.tupled(_ + _)
res7: List[Int] = List(2, 4, 6)
``````
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The signature of `Function.tupled` is `def tupled[a1, a2, b](f: (a1, a2) => b): Tuple2[a1, a2] => b`. What I can't work out how it knows the parameter types in the above example, whereas my method requires the `[Int]` in `xss reduceLeft seqed[Int](_+_)`. –  Luigi Plinge Dec 1 '11 at 0:33

I am pretty sure you are asking too much. Type inference in Scala goes from left to right, so the type of `(_+_)` needs to be figured out first before even considering the `.sedeq` part. And there isn't enough information there.

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The reason why a type annotation is required in

``````xss reduceLeft seqed[Int](_+_)
``````

but not in

``````xs zip ys map Function.tupled(_+_)
``````

is due to the difference in type requirements between `map` and `reduceLeft`.

``````def reduceLeft [B >: A] (f: (B, A) ⇒ B): B
def map        [B]      (f: (A) ⇒ B): Seq[B]   // simple version!
``````

`reduceLeft` expects `seqed` to return type `B` where `B >: Int`. It seems that therefore the precise type for `seqed` cannot be known, so we have to provide the annotation. More info in this question.

One way to overcome this is to re-implement `reduceLeft` without the lower bound.

``````implicit def withReduceL[T](xs: Seq[T]) = new {
def reduceL(f: (T, T) => T) = xs reduceLeft f
}
``````

Test:

``````scala> Seq(Seq(1,2,3), Seq(2,2,2)) reduceL seqed(_+_)
res1: Seq[Int] = List(3, 4, 5)
``````

The problem now is that this now doesn't work on subtypes of `Seq` (e.g. `List`), with or without the `[Int]` parameter:

``````scala> Seq(List(1,2,3), List(2,2,2)) reduceL seqed(_+_)
<console>:11: error: missing parameter type for expanded function ((x\$1, x\$2) => x\$1.\$plus(x\$2))
Seq(List(1,2,3), List(2,2,2)) reduceL seqed(_+_)
^
``````

`reduceL` expects a function of type `(List[Int], List[Int]) => List[Int]`. Because `Function2` is defined as `Function2 [-T1, -T2, +R]`, `(Seq[Int], Seq[Int]) => Seq[Int]` is not a valid substitution.

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