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)
```

and

```
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 `1`

to `length x`

. **Therefore I'd have expected quadratic complexity for** `cumsum'`

.

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]
```

`cumsum'`

could have linear complexity. – Ganesh Sittampalam Jul 2 at 22:18`scanl (+) 0`

– luqui Jul 2 at 22:18`max`

rather than`last`

. – Ganesh Sittampalam Jul 2 at 22:21`\x -> [take k x | k <- [1..length x]]`

is`tail . inits`

, except the latter doesn't compute the length, and doesn't start over to produce each sublist. Your function is`map sum . tail . inits`

– user2407038 Jul 2 at 22:22