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Haskell has the sum function

sum :: Num a => [a] -> a

Which can be nicely composed to sum a matrix by

sum . map sum :: Num a => [[a]] -> a

Going deeper, however, such as summing a cube, creates the restriction Num [a]

sum . map sum . map sum :: (Num a, Num [a]) => [[[a]]] -> a

Which, if you think about it, is natural. So with the former attempt to define the sumcube function blowing up in one's face, we need to find a different path. One such attempt would be:

sum . map sum . map (map sum) :: Num a => [[[a]]] -> a

Which seems nowhere as natural as the summatrix function.

In my quest to posessing the mental tools for problem solving in Haskell, I am interested in knowing how to tackle this problem of summing a structure of any depth by, say, stacking map sums as in my third code example. Is this at all possible? And in that case, how would you do it?

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Did you try sum . map (map sum)? –  FUZxxl Dec 21 '11 at 17:29
    
sum . map (map sum) :: (Num [b], Num b) => [[[b]]] -> [b] –  Magnus Kronqvist Dec 21 '11 at 17:31
    
If you are interested in fast operations on numeric matrices, you should probably use vector, repa, hmatrix, or similar packages. –  Dan Burton Dec 22 '11 at 16:19
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5 Answers

up vote 12 down vote accepted

You'll have to work from the inside out. When you have a function f for summing a data structure, then sum . map f is the way to sum a list of those data structures.

                     sum  :: Num a =>   [a]   -> a
           sum . map sum  :: Num a =>  [[a]]  -> a
sum . map (sum . map sum) :: Num a => [[[a]]] -> a
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that is a nice way to look at it –  Magnus Kronqvist Dec 21 '11 at 17:48
    
I choose this as my accepted answer because it explains the problem in the best way. –  Magnus Kronqvist Dec 21 '11 at 21:27
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How about typeclasses?

class Summable a where
  total :: a -> Int

instance Summable Int where
  total = id  

instance Summable x => Summable [x] where
  total = sum . map total  

total ([[[1,2,3],[4,5]],[[6],[7,8,9,10]]] :: [[[Int]]])
--55
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Damned, you beat me to it! –  Thomas M. DuBuisson Dec 21 '11 at 18:54
    
Interesting aspect indeed. Does scale nicely –  Magnus Kronqvist Dec 21 '11 at 19:06
    
really nice - sadly i can't fav answers - this is a concept i want to keep in mind. –  epsilonhalbe Feb 18 '12 at 13:12
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Maybe this? Assumes associativity, but adding new layer is simple

 sum . concat . concat :: Num c => [[[c]]] -> c
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Concat was actually my motivation for the question. Concat composes wonderfully which sum doesn't, i guess because sum has a type restriction. Point taken. –  Magnus Kronqvist Dec 21 '11 at 18:03
2  
concat removes layers from the outside of the type, whereas sum has to remove layers from the inside. Contrast concat . concat and sum . map sum with concat . map concat. –  dave4420 Dec 21 '11 at 19:35
1  
@MagnusKronqvist: The difference is that concat operates entirely on the lists, while sum operates on the elements. With the latter you always have to start with the innermost list, but any "list of lists" can be concatenated. This is the fundamental concept behind lists being a monad, incidentally. –  C. A. McCann Dec 21 '11 at 19:35
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It seems most natural to me to define an additional dimension's sum in terms of the previous dimension's sum.

-- given sum :: Num a => [a] -> a

sum2 :: [[a]] -> a
sum2 = sum . map sum

sum3 :: [[[a]]] -> a
sum3 = sum . map sum2

sum4 :: [[[[a]]]] -> a
sum4 = sum . map sum3

This is basically the same idea as what Sjoerd said. If you want to only use map and sum and not refactor common subexpressions into useful names...then use equational reasoning to replace the custom functions sum2, sum3, etc.

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First, there's Template Haskell (GHC extension though). Or you could use a data which supports arbitrary deep list nesting like that:

data Tree a = Leaf a | Node [Tree a]

sumTree (Leaf x) = x
sumTree (Node xs) = (sum . map sumTree) xs

main = print $ sumTree $ Node [ Node [Leaf 3, Leaf 4, Leaf 5]
                              , Node [Leaf 1, Leaf 4, Leaf 2]]

Which will print 19 here. However this does not ensure that all leaves have the same nesting depth and i don't know how to build this from lists.

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