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I'm trying to code an erlang Mastermind solver as an exercise (I'm a complete newbie, but I reckon it's an interesting exercise for a functional language)

I want it to be as general as possible, so I feel that I need a Cartesian Power function. Something like:

cart_pow([a,b],2) -> [[a,a],[a,b],[b,a],[b,b]]
cart_pow([a,b],3) -> [[a,a,a],[a,a,b],[a,b,a],[a,b,b],[b,a,a],[b,a,b],[b,b,a],[b,b,b]]

I can't think of a purely functional (recursive, map, fold...) solution. Any clues? Bonus if it's lazy.

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3 Answers 3

Solution provided by @Ed'ka is laconic and nice, but despite this, its complexity is O(N).

I'd suggest you to take into account Exponentiation by squaring method, which provides O(log(N)) complexity in calculations of power. Using this technique, cartesian power may be implemented in such way:

%% Entry point
cart(List, N) ->
        Tmp = [[X] || X <- List],
        cart(Tmp, Tmp, N).

cart(_InitialList, CurrList, 1) ->
        CurrList;
cart(_InitialList, CurrList, N) when N rem 2 == 0 ->
        Tmp = mul(CurrList, CurrList),
        cart(Tmp, Tmp, N div 2);
cart(InitialList, CurrList, N) ->
        Tmp = cart(InitialList, CurrList, N - 1),
        mul(InitialList, Tmp).

mul(L1, L2) ->
        [X++Y || X <- L1, Y <- L2].

P.S. Example of usage from shell (I've packed function cart into mudule my_module):

1> c(my_module).
{ok,my_module}
2> 
2> my_module:cart([0,1], 2).
[[0,0],[0,1],[1,0],[1,1]]
3> 
3> my_module:cart([0,1], 3).
[[0,0,0],
 [0,0,1],
 [0,1,0],
 [0,1,1],
 [1,0,0],
 [1,0,1],
 [1,1,0],
 [1,1,1]]
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mul was the piece that was missing. I couldn't get it to return the correct structure, mostly because I I didn't understand that the proper input wasn't ([a,b],[a,b]) but ([[a],[b]],[[a],[b]]) –  faibistes Nov 6 '12 at 7:35
    
In function mul calculated cartesian product of two lists. You may notice that lists concatenation syntax used there (operator ++). So, it means - that function works only with lists of lists. That's why you have to call mul([[a],[b]], [[a],[b]]) instead of mul([a,b], [a,b]). If you look at entry point (function cart/2) - you may notice, that I transform input list to list of lists (by wrapping each element in its own list: [[X] || X <- List], so list [a,b] transforms to [[a],[b]]). –  stemm Nov 6 '12 at 7:48
    
It would be O(log(N)) if ++ operator was O(1) but unfortunately it is O(N) (where N is the length of the left argument) so effectively you are just replacing multiple [|] with a single ++. Your solution does run faster (a constant difference) than the first version of mine, but I suspect it is due to the tail call in the second case. For example if I make my solution tail-recursive (see my update) it becomes quicker than yours (again, a constant difference). –  Ed'ka Nov 8 '12 at 6:07

From Haskell implementation:

cart_pow(Xs, N) -> 
    sequence(lists:duplicate(N, Xs)).

sequence([]) ->
    [[]];
sequence([Xs|Xss]) ->
    [[X|Xs1] || X <- Xs, Xs1 <- sequence(Xss)].

Not sure how you can make Erlang's lists lazy though.

Update: This version can be improved in terms of performance by simply making it tail-recursive (even though I believe there is no asymptotic differences between all three)

cart_pow(Xs, N) -> 
    sequence(lists:duplicate(N, Xs)).

sequence(Xss) ->
    sequence(Xss, [[]]).

sequence([], Acc) ->
    Acc;
sequence([Xs|Xss], Acc) ->
    sequence(Xss, [[X|Xs1] || X <- Xs, Xs1 <- Acc]).

In comparison with @stemm's version:

1> timer:tc(fun() -> length(tmp1:cart([0,1], 20)) end).
{383939,1048576}
2> timer:tc(fun() -> length(tmp1:cart_pow([0,1], 20)) end).
{163932,1048576}

PS: Or even better:

sequence(Xss) ->
    lists:foldl(fun(Xs, A) -> [[X|Xs1] || X <- Xs, Xs1 <- A] end, [[]], Xss).
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You may find this Stack Overflow question helpful, which deals with generating the Cartesian power of a list in functional languages. The question is targeted for F#, but there is a Haskell example in the comments as well: F#: how to find Cartesian power

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