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Given two lists, I can produce a list of all permutations the Cartesian Product of these two lists:

permute :: [a] -> [a] -> [[a]]
permute xs ys = [ [x, y] | x <- xs, y <- ys ]

Example> permute [1,2] [3,4] == [ [1,3], [1,4], [2,3], [2,4] ]

How do I extend permute so that instead of taking two lists, it takes a list (length n) of lists and returns a list of lists (length n)

permute :: [[a]] -> [[a]]

Example> permute [ [1,2], [3,4], [5,6] ]
            == [ [1,3,5], [1,3,6], [1,4,5], [1,4,6] ] --etc

I couldn't find anything relevant on Hoogle.. the only function matching the signature was transpose, which doesn't produce the desired output.

Edit: I think the 2-list version of this is essentially the Cartesian Product, but I can't wrap my head around implementing the n-ary Cartesian Product. Any pointers?

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4 Answers 4

up vote 13 down vote accepted
Prelude> sequence [[1,2],[3,4],[5,6]]
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While sequence does solve the problem, I was really interested in how this would work. The implementation uses monads; is there a way to calculate the product without using monads? (eg in a language that doesn't include monads) –  guhou Aug 2 '10 at 12:18
@BleuM937: For the list monad, sequence means "for each element in the first list, prepend it to each list obtained by sequencing the remaining lists". It's basically the most obvious way to write a Cartesian product using a right fold. –  C. A. McCann Aug 2 '10 at 13:52

As a supplement to jleedev's answer (couldn't format this in the comments):

A quick unchecked substitution of list functions for monadic ones:

sequence ms = foldr k (return []) ms
    k m m' = do { x <- m; xs <- m'; return (x:xs) }


    k m m' = m >>= \x -> m' >>= \xs -> [x:xs]
    k m m' = flip concatMap m $ \x -> flip concatMap m' $ \xs -> [x:xs]
    k m m' = concatMap (\x -> concatMap (\xs -> [x:xs]) m') m


sequence ms = foldr k ([[]]) ms
     k m m' = concatMap (\x -> concatMap (\xs -> [x:xs]) m') m
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That can be slightly simplified further by eliminating a superfluous concatenation in k m m' = concatMap (\x -> map (x:) m') m. Could also write it as a list comprehension like [ x:xs | x <- m, xs <- m' ]. –  C. A. McCann Aug 2 '10 at 13:46

I found Eric Lippert's article on computing Cartesian product with LINQ quite helpful in improving my understanding of what was going on. Here's a more-or-less direct translation:

cartesianProduct :: [[a]] -> [[a]]
cartesianProduct sequences = foldr aggregator [[]] sequences
                   where aggregator sequence accumulator = 
                         [ item:accseq |item <- sequence, accseq <- accumulator ]

Or with more "Haskell-y" terse, meaningless parameter names ;)

cartesianProduct = foldr f [[]]
                    where f l a = [ x:xs | x <- l, xs <- a ]

This winds up being quite similar to sclv posted after all.

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It's the same as sclv's, in fact, up to a few differences in syntax. Also, you know this (having written the translation), but for anyone else: note that Eric Lippert's example uses a left fold instead of a right fold, but this makes no difference because the function is strict in the spines of the lists anyway (as with sequence in general). –  C. A. McCann Aug 2 '10 at 15:55

If you want to have more control over the output, you can use a list as applicative functor, e.g.:

(\x y z -> [x,y,­z]) <$>  [1,2]­ <*> [4,5]­ <*> [6,7]

Let's say you want a list of tuples instead:

(\x y z -> (x,y,­z)) <$>  [1,2]­ <*> [4,5]­ <*> [6,7]

And it looks kind of cool, too...

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