# Is there an existing pattern to generate a list of the applications of a function to every combination of the items in two lists?

I'm just getting into functional programming and i'm in the "try out some non-trivial examples and ask others if I'm doing it wrong" phase. I'm following Don Syme's F# Tutorial and have decided to take a stab at the blackjack exercise at the end of Part II with a twist: he suggests treating Ace as 11 for simplicity's sake, but I decided to ignore that recommendation.

The way I'm handling it is by giving each card rank a list of possible values and building up a list of possible hand values recursively thus:

let cardValues (Card(rank, _)) =
match rank with
| Ace                 -> [1; 11]
| King | Queen | Jack -> [10]
| Value(value)        -> [value]

let rec handValues = function
| [] -> [0]
| card::cards ->
[
for handValue in handValues cards do
for cardValue in cardValues card do
yield handValue + cardValue
]


The handValues function is so similar in structure to a fold that I can't shake the feeling there's already some high order function I can use to accomplish this. Is there something I'm missing or is this pretty much the right direction?

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It's worth mentioning as an aside that this

    [
for handValue in handValues cards do
for cardValue in cardValues card do
yield handValue + cardValue
]


is a monadic bind; one could author a 'list' monad and then use computation expressions to write this as

listMonad {
let! handVal = handValues cards
let! cardVal = cardValues card
return hardVal + cardVal
}

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+1 Yep - Definitely worth mentioning. @Brian: Is there a builtin collection of useful monad builders (list, maybe, async, state ...)? –  Dario Feb 12 '10 at 18:00
Nope, just async is in FSharp.Core. You can probably find some examples like option (a.k.a. maybe), list, and state floating around on the web; it would not hurt to gather them up into some open source project on the web somewhere. –  Brian Feb 12 '10 at 18:08
That's exactly the kind of elegance I was looking for with my question. Now to figure out what all this monadic bind stuff is about >< –  Cogwheel Feb 12 '10 at 19:00
Yes, it's a very elegant solution to this problem, or any one where you start with an algorithm that produces a single answer, and generalize it into components that can produce multiple answers... you can just 'lift' all the components into the monad, change 'let' to 'let!' in various spots, and voila, now you find all possible solutions. Let me know if you can't get this working after you spend some time digging into F# computation expressions and monads, and I'll put together some more code. –  Brian Feb 12 '10 at 20:44
This is a thing that always confuses me. In F# you can in principle declare a computation builder for any standard monad in terms of let!/return but also in terms of for/yield. There is really no difference between these two. Of course, using for inside monad defined in terms of let!/return makes sense, but that's not this case. So the only difference I can see between the two above definitions is that the one using sequence expression will be faster (because F# compiler optimizes it). Since F# code cannot be parameterized by monad type, it isn't more general in any way... –  Tomas Petricek Feb 13 '10 at 19:46

The way you're doing things is perfectly fine. It's possible to express any recursive function on lists as a fold, but I don't think that you gain anything by doing so here. There's also no built-in function to do exactly what you need, but you could build a more generic function and build your specific calculation on top of that. Here's one such approach:

let rec allChoices = function
| [] -> [[]]
| l::ls ->
[for x in l do
for xs in allChoices ls do
yield x::xs]

let values hand =
hand |>
List.map cardValues |>
allChoices |>
List.map (List.sum)


The allChoices function takes a list of lists and returns each possible list containing a single element from each (e.g. allChoices [[1];[2;3];[4;5]] = [[1;2;4];[1;2;5];[1;3;4];[1;3;5]]). We use this function to get all possible lists of values for the cards in a hand, and then sum each such list.

There are probably several other ways you could look at the problem which might suggest other variations.

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