# Cartesian product traverse in scalaz

In Eric Torreborre's blogpost on the paper Essence of the Iterator Pattern, he describes how the cartesian product of a traverse is also a traverse.

Can anyone show me an example of this using the scalaz library as I can't figure it out. Let's say the problem is that, for a `List[Int]` I want to provide both of:

1. The `Int` sum of the elements in the list
2. A `List[String]` the elements of which are created by appending the "Z" to the String representation of the `Int`s

My understanding is that I can do this using `traverse` but in such a way as to only actually traverse my structure once, unlike this solution:

``````val xs = List(1, 2, 3, 4)
val (sum, strings)  = (xs.sum, xs map (_.toString + "Z"))
``````

NOTE 1 - I know that there are other ways of doing this and that I neither need traverse for this example, and nor is traverse even necessarily the clearest way to solve it. I am, however, trying to understand traverse, so am really looking for the answer to the question as stated

EDIT - thanks to missingfaktor below for showing how to do this using `State`. I guess what I want to know is how I can compose the two independent calculations. For example; my functions are notionally as follows:

``````val shape = (_ : List[Int]) map (_.toString + "Z")
val accum = (_ : List[Int]).sum
``````

I want to have these mechanisms of accumulation independently of one another and then choose whether to traverse my `List[Int]` using either or both of them. I imagined some code a bit like this:

``````xs traverse shape //A List[String]
xs traverse accum //An Int

xs traverse (shape <x> accum) //The pair (List[String], Int)
``````

Eric implies that this is possible but I don't get how to do it ~ i.e. I don't see how to define `shape` and `accum` in such a way as that they can be composed, nor how to compose them.

NOTE 2 that `shape` and `accum` are not meant to literally be the functions with the signatures as above. They are expressions which have the type necessary to perform the above traversals.

-
I don't understand the connection between cartesian product and the later half of your question. Can you please elaborate? –  missingfaktor Feb 6 '12 at 15:33
Look at the implementation of `foldMapDefault` scalaz.github.com/scalaz/scalaz-2.9.1-6.0.4/doc.sxr/scalaz/…. I think the key is in that `Const` that creates a phantom applicative functor. Note that `xs.foldMapDefault(i => (i, List(i))` does what you want. –  huynhjl Feb 6 '12 at 15:38
@missingfaktor - in Eric's blog, he basically says this: 1. a `traverse` is a generalization of an iteration; it can accumulate values or build a structure with the same shape as the traversee. 2. the cartesian product of a traverse is a traverse. Hence you can do 2 calculations in one traversal –  oxbow_lakes Feb 6 '12 at 15:43
@oxbow_lakes, the only purpose I use `traverse` in my code is to avoid calling `map` and then `sequence`. i.e. `xss.traverse(f)` == `xss.map(f).sequence`. Useful in cases like, when you want to get `ValidationNEL[E, Seq[Seq[B]]]` from `Seq[Seq[A]]` by applying `A => ValidationNEL[E, B]`. –  missingfaktor Feb 6 '12 at 15:47
I think the idea of having independent "calculations" which can be combined arbitrarily is an awesome one. For example, I could have standard "functions" for getting stuff from a `M[Trade]` (where there is a `Traverse[M]`) such as: inventoryP&L, tradingP&L, totalQtySold, totalQtyBought etc etc. These could then be composed into calculations which happen in a single iteration. A beautiful example of FP enabling componentisation. –  oxbow_lakes Feb 6 '12 at 18:14

I'm adding my own answer, building on Jason's one, to show different ways of traversing the list:

``````import org.specs2._
import scalaz.std.anyVal._, scalaz.std.list._
import scalaz._, std.tuple._
import scalaz.{Monoid, Applicative}

class TraverseSpec extends mutable.Specification {

implicit val Sum = Monoid[Int].applicative
implicit val Concat = Monoid[List[String]].applicative
implicit val A: Applicative[({type λ[α] = (Int, List[String])})#λ] = Sum.product[({type λ[α]=List[String]})#λ](Concat)
val xs = List(1, 2, 3, 4)

"traverse - by folding the list with a Monoid" >> {
val (sum, text) = Foldable[List].foldMap(xs)(a => (a, List(a.toString + "Z")))
(sum, text) === (10, List("1Z", "2Z","3Z", "4Z"))
}
"traverse - with a function returning a tuple" >> {
val (sum, text) = A.traverse(xs)(a => (a, List(a.toString + "Z")))
(sum, text.reverse) === (10, List("1Z", "2Z","3Z", "4Z"))
}
"traverse - with 2 functions and 2 traversals" >> {
val count   = (a: Int) => a
val collect = (a: Int) => List(a.toString+"Z")

val sum  = Sum.traverse(xs)(count)
val text = Concat.traverse(xs)(collect)

(sum, text.reverse) === (10, List("1Z", "2Z","3Z", "4Z"))
}
"traverse - with 2 functions and 1 fused traversal" >> {
val sum     = (a: Int) => a
val collect = (a: Int) => List(a.toString+"Z")

implicit def product[A, B, C](f: A => B): Product[A, B] = Product(f)
case class Product[A, B](f: A => B) {
def <#>[C](g: A => C) = (a: A) => (f(a), g(a))
}

val (total, text)  = A.traverse(xs)(sum <#> collect)
(total, text.reverse) === (10, List("1Z", "2Z","3Z", "4Z"))
}
}
``````

I think that the last example shows what you're after: 2 independently defined functions which can be composed to do just one traversal.

-

Debasish Ghosh has written a nice post on this topic. Based on the code in that post:

``````scala> List(1, 2, 3, 4)
res87: List[Int] = List(1, 2, 3, 4)

scala> .traverse[({ type L[X] = State[Int, X] })#L, String] { cur =>
|   state { (acc: Int) => (acc + cur, cur.toString + "Z") }
| }
res88: scalaz.State[Int,List[String]] = scalaz.States\$\$anon\$1@199245

scala> .apply(0)
res89: (Int, List[String]) = (10,List(1Z, 2Z, 3Z, 4Z))
``````

Edit:

You have two functions `List[A] => B` and `List[A] => C`, and you want a function `List[A] => (B, C)`. That's what `&&&` is for. This won't fuse the loops though. I cannot imagine how it can be possible to fuse loops for such a case.

Fwiw, code:

``````scala> val shape = (_ : List[Int]) map (_.toString + "Z")
val accum = (_ : List[Int]).sum
shape: List[Int] => List[java.lang.String] = <function1>
accum: List[Int] => Int = <function1>

scala> val xs = List(1, 2, 3, 4)
xs: List[Int] = List(1, 2, 3, 4)

scala> (shape &&& accum) apply xs
res91: (List[java.lang.String], Int) = (List(1Z, 2Z, 3Z, 4Z),10)
``````

Edit 2:

If you have functions `A => B` and `A => C` you can merge them into `A => (B, C)` using `&&&`. Now if `B : Monoid` and `C : Monoid`, you can use `foldMap` to get `List[A] => (B, C)`. This will do the stuff in one loop.

Code:

``````scala> val f: Int => Int = identity
f: Int => Int = <function1>

scala> val g: Int => List[String] = i => List(i.toString + "Z")
g: Int => List[String] = <function1>

scala> List(1, 2, 3, 4).foldMap(f &&& g)
res95: (Int, List[String]) = (10,List(1Z, 2Z, 3Z, 4Z))
``````

Final edit: (I swear I am not editing this again.)

Since these concepts have their origins in Haskell, I thought it'd be a good idea to re-post this question under Haskell tag, and I did. The answer there seems to be consistent with whatever I have said in this thread. Hôpe this helps.

-
Thanks for this - can you see my edit? –  oxbow_lakes Feb 6 '12 at 17:21
@oxbow_lakes, please check the edit. But I doubt if that answers your question. –  missingfaktor Feb 6 '12 at 18:06
Thanks again; I've added the links to the Scalaz 6 and 7 versions of the code which show how to turn the product of 2 traversals into a traversal. They're both ugly, which is a real shame as this sort of behaviour with a usable syntax would be a massive win. Having said that, perhaps I'll get used to the syntax –  oxbow_lakes Feb 6 '12 at 18:09
@oxbow_lakes, if you have understood that mechanism, can you please show us how to apply it to your specific case? because I honestly don't get it... –  missingfaktor Feb 6 '12 at 18:12
Yes I think that spot on –  AndreasScheinert Feb 9 '12 at 8:24

If I understand you correctly that what you are looking for should be described in the scala-seven branch example: WordCount. It also involves state. I'm on mobile otherwise I would provide link.

HTH Andreas

EDIT:

Ok some more explanations. I think the fundamental problem of your questions is how to compose functions or therefor applicative. This can be achieved through the product method on applicative.

https://github.com/scalaz/scalaz/blob/scalaz-seven/core/src/main/scala/scalaz/Applicative.scala#L46

So you need to define applicative for your two functions shape and accum. Where accum would be modeled as a state applicative.

If we look at this line form the example: val WordCount = StateT.stateMonad[Int].compose({type λ[α] = Int})#λ

It creates an applicative which 'works' (sorry my poor wording) which state. Usually on traverse you have only the current element nothing more. But if you want to compute on previous computations you need state so this create an state-applicative which returns 1 for each element it traverses ( see Monoid[Int].applicative).

Now to DO actually something we need to look at the atWordStart Method and you need to define a method which can work with the constructed WordCount applicative (using State)

Here is another example from scalaz 6, which is more simple. I think its important to observe the initialValue and how the transform1 method does :

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

object StateTraverseExample {

type StS[x] = State[(Set[Int], Boolean), x]

def main(args: Array[String]): Unit = {
println("apparently it works " + countAndMap(Vector.range(0, 20)))
}

def transform1(i: Int, l: Set[Int], result: Boolean): (Set[Int],Boolean) = {
if (result || (l contains i))
(l, true)
else
(l + i, false)
}

def countAndMap(l: Vector[Int]): (Set[Int],Boolean) = {
val initialValue=(Set.empty[Int], false)

val counts = l.traverse[StS, Unit] { i =>
state { case (set, result) => (transform1(i,set,result), println(i))   }
} ~> initialValue
counts
}
}
``````

I remember now because the topic interested me too. I asked why eric in his blogpost did not provide the applicative product. He said he it gave up wrestling with the type signatures. Arround that time jason fixed the WordCount example for scalaz7 ( six example did not provide action counting word)

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If you fancy fleshing this out with how to apply it to the problem at hand (to help both me and missingfaktor), the points are yours! –  oxbow_lakes Feb 6 '12 at 18:22

You don't see a big win here, as you're just promoting plain ol' Monoids into Applicatives so you fuse them together.

``````import scalaz.std.anyVal._, scalaz.std.list._, scalaz.std.string._
val Sum = Monoid[Int].applicative
val Concat = Monoid[List[String]].applicative
val A: Applicative[({type λ[α] = (Int, List[String])})#λ] = Sum.product[({type λ[α]=List[String]})#λ](Concat)

val xs = List(1, 2, 3, 4)
val (sum, text) = A.traverse(xs)(a => (a, List(a.toString + "Z")))
println(sum, text) // 10, List("1Z", "2Z", "3Z", "4Z")
``````

Might as well just use `Monoid[(Int, List[String])]` for the stated problem:

``````import scalaz._, std.tuple._
val (sum1, text1) = Foldable[List].foldMap(xs)(a => (a, List(a.toString + "Z")))
println(sum1, text1) // 10, List("1Z", "2Z", "3Z", "4Z")
``````

Things get more interesting if one of the effects you want to traverse with is a non-trivial Applicative, like `State`.

-
He requires a `(Int, List[String])`, not `(Int, String)`. –  missingfaktor Feb 7 '12 at 1:54
I edited the answer with the desired types. Notice that the order of the list result changes depending on traverse vs foldMap. I think that this is because the implementation of those 2 is different, using foldLeft vs foldRight. –  Eric Feb 7 '12 at 2:50
Something I didn't realize also. You declare: ({type λ[α] = (Int, List[String])})#λ. This means that we don't even need to create a "Const" class (as in the "Essence of the Iterator Pattern") to get a phantom type (α in this case). Nice. –  Eric Feb 7 '12 at 3:00
I like the idea of using the separate monoids together with foldMap to achieve multiple "simple" traverses. But my new year's resolutions this year were to understand both state & traverse, so this doesn't really answer the question –  oxbow_lakes Feb 7 '12 at 4:44
@Eric the reverse order might be a bug -- we're looking at a similar problem at the moment... –  retronym Feb 7 '12 at 12:39