I have a haskell function I want to evaluate with exact intermediate results:
f 0 x = 0 f n x = let tmp = f (n-1) x in tmp + (x-tmp^2)/2
Because of the (^2) the complexity grows exponentially in n. Since I want to do a plot and the computations for two different x are completely independant, I would have expected nearly optimal speedup from parallel evaluation. My code for this:
import Data.Ratio import Control.Parallel.Strategies f 0 x = 0 f n x = let tmp = f (n-1) x in tmp + (x-tmp^2)/2 main = do it <- readLn let fn = fromRational . f it values = map fn [0,1%2..10] :: [Double] computed = values `using` parBuffer 16 rseq mapM_ (putStrLn . show) computed
But to my surprise this does not really scale (on my dual core i3 with HT):
$ ghc -threaded -O f.hs [1 of 1] Compiling Main ( f.hs, f.o ) Linking f ... $ time echo 20 | (./f +RTS -N1 > /dev/null) real 0m4.760s user 0m4.736s sys 0m0.016s $ time echo 20 | (./f +RTS -N2 > /dev/null) real 0m4.041s user 0m5.416s sys 0m2.548s $ time echo 20 | (./f +RTS -N3 > /dev/null) real 0m4.884s user 0m10.936s sys 0m3.464s $ time echo 20 | (./f +RTS -N4 > /dev/null) real 0m5.536s user 0m17.028s sys 0m3.888s
What am I doing wrong here? It looks like it spends quite some time in locks (sys?) instead of doing useful work.