# Lazy cartesian product in Haskell

I would like to generate a rather large but finite Cartesian product in Haskell, which I need to then iterate on (think partition function of a mean-field model). The natural thing to do uses `sequence`, like this:

``````l = sequence \$ replicate n [0,1,2]
``````

Unfortunately, for large `n`, this does not fit in memory and I run out of heap as soon as I ask for `length l` for instance. I would need a way to do the same thing lazily. I ended up "rediscovering" base-3 arithmetics, like this,

``````nextConfig []     = []
nextConfig (0:xs) = 1:xs
nextConfig (1:xs) = 2:xs
nextConfig (2:xs) = 0:(nextConfig xs)

ll = take (3^n) \$ iterate nextConfig \$ replicate n 0
``````

(which works) but it feels like reinventing the wheel, and besides it is much too specific. What would be a better lazy way to generate the product?

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Do you care about the order of the elements in the result? –  augustss Apr 12 '12 at 11:52
No, as long as there is no repetition. –  Vincent Beffara Apr 12 '12 at 11:56
How large do you need `n` to be? –  dave4420 Apr 12 '12 at 12:22
Something like 20 or 30; I don't really care about computation time for now, but certainly `3^n` is beyond RAM size. –  Vincent Beffara Apr 12 '12 at 12:54

The more memory-friendly way is obtained by binding in reverse order compared to sequence,

``````foo 0 _ = [[]]
foo k xs = [h:t | t <- foo (k-1) xs, h <- xs]
``````

It is slower due to less sharing, but since memory is your problem, maybe it's good enough for you.

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Cool! I will have to investigate more why it works, but it certainly does. I modified it as `foo (l:ls) = [h:t | t <- foo2 ls, h <- l]` (who knows if I will always need a cube) and it works as well. Thanks! –  Vincent Beffara Apr 12 '12 at 13:00
Why are list comprehensions more efficient than do-notation for lists (which is used in `sequence`)? I can see from the Haskell2010 report both of them desugar to `concatMap`? –  haskelline Apr 12 '12 at 13:37
@brence: See Duncan Coutts's answer to this reddit question: Why are guards in the list comprehension faster than in the do-notation? –  danr Apr 12 '12 at 14:25
From there, it appears that list comprehension is desugared into `foldr`. The weird thing is that a naive `foldr` approach to cartesian products (at least the one I tried) breaks laziness like `sequence` does ... –  Vincent Beffara Apr 12 '12 at 18:07