I have a list:

``````let a = [1, 2, 3]
``````

I need to get another list:

``````[1, 2, 3] ++ [1*2, 2*3, 1*3] ++ [1*2*3]
``````

It is a product of all possible unique coombinations of list's elements. I have founded permutations in Data.List, but as I see it is something different.

Is there any library functions to get this list or can you give me examles how can I create your own function.

Thanks.

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shouldn't you also include the product of no elements? –  newacct Oct 17 '11 at 9:52

For a library function, you can use `subsequences` from `Data.List`:

``````Prelude Data.List> subsequences [1,2,3]
[[],[1],[2],[1,2],[3],[1,3],[2,3],[1,2,3]]
``````

You can get all of the products using `map product \$ subsequences [1,2,3]`.

But that is not in the same order as you specified. So you can sort it, using `sortBy` from `Data.List` and `comparing` from `Data.Ord`:

``````Prelude Data.List Data.Ord> sortBy (comparing length) \$ subsequences [1,2,3]
[[],[1],[2],[3],[1,2],[1,3],[2,3],[1,2,3]]
``````

Again, get the products using `map product`.

Your other idea, to write a function yourself, is the best idea if you are learning Haskell. Give it a try!

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Thanks. The order doesn't matter in my case. –  demas Dec 5 '10 at 13:32

You want all subsequences, not permutations. Permutations give you all possible orders of the same elements. Whereas a subsequence is any sequence that has a subset of elements of the original, in the same order.

In addition to the function mentioned above, there's a clever trick to do this with some other library functions, but I'm not sure how helpful it will be to you.

``````import Control.Monad (filterM)

subsequences' :: [a] -> [[a]]
subsequences' = filterM \$ const [False, True]
``````

This trick takes advantage of the viewpoint of the list monad as modeling non-deterministic calculation. For each element in the list, it's included or not, non-deterministically, regardless of what it is.

It's efficient, and precisely the kind of thing the list monad is designed for, but it's somewhat opaque. You would probably learn more from implementing the same idea directly, based on the descriptions I've provided.

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