Can I unsugar list comprehension in this expression:

[(i,j) | i <- [1..4], j <- [i+1..4]]

This is the output:


How can I, with map, filter and so on, write that piece of code?


Here an other:

[(i,j,k) | i <- [1..6], j <- [i+1..6],k <- [j+1..6]]

This is the output:


List comprehensions (in fact, Monad comprehensions) can be desugared into do notation.

do i <- [1..4]
   j <- [i+1..4]
   return (i,j)

Which can be desugared as usual:

[1..4]   >>= \i ->
[i+1..4] >>= \j ->
return (i,j)

It is well known that a >>= \x -> return b is the same as fmap (\x -> b) a. So an intermediate desugaring step:

[1..4] >>= \i -> 
fmap (\j -> (i,j)) [i+1..4]

For lists, (>>=) = flip concatMap, and fmap = map

(flip concatMap) [1..4] (\i -> map (\j -> (i,j) [i+1..4])

flip simply switches the order of the inputs.

concatMap (\i -> map (\j -> (i,j)) [i+1..4]) [1..4]

And this is how you wind up with Tsuyoshi's answer.

The second can similarly be desugared into:

concatMap (\i ->
  concatMap (\j ->
    map       (\k ->

The desugared code is:

concatMap (\i -> concatMap (\j -> (i, j) : []) [i+1..4]) [1..4]

Which can be refactored to Tsuyoshi Ito's answer.


There is yet another translation scheme, it is due to Wadler, as far as I know.

This would give:

    lc_outer (x:xs) = let lc_inner (y:ys) = (x,y) : lc_inner ys
                          lc_inner []     = lc_outer xs
                      in lc_inner [x+1.. 4]
    lc_outer [] = []
in  lc_outer [1..4]

This translation avoids needless construction of singleton lists in the innermost level that would need to get flattened with concatMap later.

concatMap (\i -> map (\j -> (i, j)) [i+1 .. 4]) [1 .. 4]
  • Thanks for answer :) – Carlochess Nov 6 '11 at 18:12

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