# verifying a probability distribution with variable arguments sums to 1

I was wondering how you would write a method in Scala that takes a function `f` and a list of arguments `args` where each arg is a range. Suppose I have three arguments (`Range(0,2)`, `Range(0,10)`, and `Range(1, 5)`). Then I want to iterate over `f` with all the possibilities of those three arguments.

``````var sum = 0.0
for (a <- arg(0)) {
for (b <- arg(1)) {
for (c <- arg(2)) {
sum += f(a, b, c)
}
}
}
``````

However, I want this method to work for functions with a variable number of arguments. Is this possible?

Edit: is there any way to do this when the function does not take a list, but rather takes a standard parameter list or is curried?

-
I think it is possible through recursion, but only if `f` accept list of values. –  om-nom-nom Oct 10 '11 at 17:12
I was hoping to solve it without this restriction (`f` takes a standard parameter list or is curried). –  schmmd Oct 10 '11 at 18:12

That's a really good question!

You want to run `flatMap` in sequence over a list of elements of arbitrary size. When you don't know how long your list is, you can process it with recursion, or equivalently, with a fold.

``````scala> def sequence[A](lss: List[List[A]]) = lss.foldRight(List(List[A]())) {
|    (m, n) => for (x <- m; xs <- n) yield x :: xs
| }
scala> sequence(List(List(1, 2), List(4, 5), List(7)))
res2: List[List[Int]] = List(List(1, 4, 7), List(1, 5, 7), List(2, 4, 7), List(2
, 5, 7))
``````

(If you can't figure out the code, don't worry, learn how to use Hoogle and steal it from Haskell)

You can do this with Scalaz (in general it starts with a `F[G[X]]` and returns a `G[F[X]]`, given that the type constructors `G` and `F` have the `Traverse` and `Applicative` capabilities respectively.

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

scala> import Scalaz._
import Scalaz._

scala> List(List(1, 2), List(4, 5), List(7)).sequence
res3: List[List[Int]] = List(List(1, 4, 7), List(1, 5, 7), List(2, 4, 7), List(2
, 5, 7))

scala> Seq(some(1), some(2)).sequence
res4: Option[Seq[Int]] = Some(List(1, 2))

scala> Seq(some(1), none[Int]).sequence
res5: Option[Seq[Int]] = None
``````
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Cool answer--I'll definately have to check scalaz out. –  schmmd Oct 12 '11 at 1:30

That would more or less do the job (without applying f, which you can do separately)

``````  def crossProduct[A](xxs: Seq[A]*) : Seq[Seq[A]]
= xxs.foldLeft(Vector(Vector[A]())){(res, xs) =>
for(r <- res; x <- xs) yield r :+ x
}
``````

You can then just map your function on that. I'm not sure it's a very efficient implementation though.

-

That's the answer from recursive perspective. Unfortunately, not so short as others.

``````def foo(f: List[Int] => Int, args: Range*) = {
var sum = 0.0
def rec(ranges: List[Range], ints: List[Int]): Unit = {
if (ranges.length > 0)