Mog has given an answer that exploits the fact that
(+) is associative, commutative, and has an inverse. However, I think it's also constructive to give an answer that works for any operation; that is, to produce the actual lists you're summing, then sum them. So the plan will be like this:
- Write a function that splits a list at each possible position.
- Write a function that turns a split back into a list by dropping the element at the split.
- Write a function that sums a list (already done in
Prelude: use the
- Write a function that combines them, and includes the special case of the entire list.
There's a couple ways to do part one. The first choice is explicit recursion:
splits :: [a] -> [([a], [a])]
splits  = [(,)]
splits (x:xs) = (,x:xs) : map (\(b,e) -> (x:b,e)) (splits xs)
We can check it out in ghci to make sure we've got it right:
*Main> splits "abcde"
However, there's a nicer way. The
Data.List module includes a bunch of functions for munging lists in particular ways. Two of them are
*Main> tails "abcde"
*Main> inits "abcde"
So this definition is much nicer looking:
splits xs = zip (inits xs) (tails xs)
Now, we want a function that produces the list of lists with one element dropped from each position.
dropEach xs = [beginning ++ end | (beginning, ignored:end) <- splits xs]
So the final step is to put everything together.
funnySums xs = map sum (xs : dropEach xs)
We can test:
*Main> funnySums [1, 10, 100, 1000, 10000]