Data Parallel Haskell Prefix Sum

I'm playing with some Data Parallel Haskell code and found myself in need of a prefix sum. However I didn't see any basic operator in the dph package for prefix sum.

I rolled my own, but, since I'm new to dph, I'm not sure if it's properly taking advantage of parallelization:

{-# LANGUAGE ParallelArrays #-}
{-# OPTIONS_GHC -fvectorise #-}

module PrefixSum ( scanP ) where
import Data.Array.Parallel (lengthP, indexedP, mapP, zipWithP, concatP, filterP, singletonP, sliceP, (+:+), (!:))
import Data.Array.Parallel.Prelude.Int ((<=), (-), (==), Int, mod)
-- hide prelude
import qualified Prelude

-- assuming zipWithP (a -> b -> c) given
-- [:a:] of length n and
-- [:b:] of length m, n /= m
-- will return
-- [:c:] of length min n m

scanP :: (a -> a -> a) -> [:a:] -> [:a:]
scanP f xs = if lengthP xs <= 1
then xs
else head +:+ tail
where -- [: x_0, x_2, ..., x_2n :]
evens = mapP snd . filterP (even . fst) $indexedP xs -- [: x_1, x_3 ... :] odds = mapP snd . filterP (odd . fst)$ indexedP xs
lenEvens = lengthP evens
lenOdds = lengthP odds
-- calculate the prefix sums [:w:] of the pair sums [:z:]
psums = scanP f $zipWithP f evens odds -- calculate the total prefix sums as -- [: x_0, w_0, f w_0 x_2, w_1, f w_1 x_4, ..., head = singletonP (evens !: 0) body = concatP . zipWithP (\p e -> [: p, f p e :]) psums$ sliceP 1 lenOdds evens
-- ending at either
--    ... w_{n-1}, f w_{n-1} x_2n :]
-- or
--    ... w_{n-1}, f w_{n-1} x_2n, w_n :]
-- depending on whether the length of [:x:] is 2n+1 or 2n+2
tail = if lenEvens == lenOdds then body +:+ singletonP (psums !: (lenEvens - 1)) else body

-- reimplement some of Prelude so it can be vectorised
f $x = f x infixr 0$
(.) f g y = f (g y)

snd (a,b) = b
fst (a,b) = a

even n = n mod 2 == 0
odd n = n mod 2 == 1

-
Hmm, is it even parallelizable? Seems like a pretty serial idea, but maybe I am missing something. –  luqui Jan 31 '12 at 15:16
@luqui: The parallel prefix sum algorithm for an array of size n takes O(log n) parallel rounds of computation. There are two phases. In the forward phase, given {a_i | i \in [0,2n-1] } you calculate { a_2i + a_{2i+1} | i \in [0,n-1] } using n/2 parallel additions. In the backward phase, given { \sum_0^{2i+1} a_j | i \in [0,n-1] } and { a_i | i \in [0,2n-1] }, you calculate { \sum_0^i a_j | i \in [0, 2n-1 } using n/2 parallel additions. –  rampion Jan 31 '12 at 16:24
@luqui: naturally, this only works properly for associative +, since there's the inherent assumption that (a_0 + a_1) + (a_2 + a_3) == ((a_0 + a_1) + a_2) + a_3 –  rampion Jan 31 '12 at 16:27
For a normal array, this would be scanl, but I'm not seeing that in dph-par. –  Louis Wasserman Jan 31 '12 at 23:23
right. scanl is O(n) work in O(n) time, scanP is meant to be O(n) work in O(log n) time. –  rampion Feb 1 '12 at 10:03

Parallel prefix scans are supported, in fact, they're rather fundamental. So just pass (+) as your associative operator.