Consider the following two cumulative sum (cumsum) functions:
cumsum :: Num a => [a] -> [a] cumsum  =  cumsum [x] = [x] cumsum (x:y:ys) = x : (cumsum $ (x+y) : ys)
cumsum' :: Num a => [a] -> [a] cumsum' x = [sum $ take k x | k <- [1..length x]]
Of course, I prefer the definition of
cumsum to that of
cumsum' and I understand that the former has linear complexity.
But just why does
cumsum' also have linear complexity?
take itself has linear complexity in the length of its argument and
k runs from
length x. Therefore I'd have expected quadratic complexity for
Moreover, the constant of
cumsum' is lower than that of
cumsum. Is that due to the recursive list appending of the latter?
NOTE: welcoming any smart definition of a cumulative sum.
EDIT: I'm measuring execution times using (after enabling
:set +s in GHCi):
last $ cumsum [1..n]