# Why parallelizing this code yeilds almost no performance improvement on six core machine?

I am learning parallel programming in Haskell using Simon Marlow's book. On chapter about parallelizing Sudoku solver I decided to write my own solver using backtracking algorithm. The problem is that there is almost no performance gain when I try to distribute 6 cases among 6 cores. When I try to do examples with more cases I get more significant performance gains yet still far from theoretical maximum which should be between 5 and 6. I understand that some cases may run far slower but threadscope diagram shows no excuse for such little gain. Can someone explain me what I am doing wrong. Maybe there is something about ST threads which I am not understanding?

Here is the code:

Sudoku.hs

``````{-# LANGUAGE DeriveGeneric, DeriveAnyClass #-}

module Sudoku (getSudokus, solve) where

import Data.Vector(Vector, (!), generate, thaw, freeze)
import Data.List ( nub )
import qualified Data.Vector.Mutable as MV
import Text.Trifecta
import Control.Monad ( replicateM, when )
import Control.Applicative ((<|>))
import Control.DeepSeq (NFData)
import GHC.Generics (Generic)

data Cell = Given Int
| Filled Int
| Empty
deriving (Generic, NFData)

newtype Sudoku = Sudoku (Vector Cell)
deriving (Generic, NFData)

instance Show Cell where
show Empty = "   "
show (Filled x) = " " ++ show x ++ " "
show (Given x) = "[" ++ show x ++ "]"

instance Show Sudoku where
show (Sudoku vc) = "\n" ++
"+ -  -  - + -  -  - + -  -  - +" ++ "\n" ++
"|" ++ i 0 ++ i 1 ++ i 2 ++ "|" ++ i 3 ++ i 4 ++ i 5 ++ "|" ++ i 6 ++ i 7 ++ i 8 ++ "|" ++ "\n" ++
"|" ++ i 9 ++ i 10 ++ i 11 ++ "|" ++ i 12 ++ i 13 ++ i 14 ++ "|" ++ i 15 ++ i 16 ++ i 17 ++ "|" ++ "\n" ++
"|" ++ i 18 ++ i 19 ++ i 20 ++ "|" ++ i 21 ++ i 22 ++ i 23 ++ "|" ++ i 24 ++ i 25 ++ i 26 ++ "|" ++ "\n" ++
"+ -  -  - + -  -  - + -  -  - +" ++ "\n" ++
"|" ++ i 27 ++ i 28 ++ i 29 ++ "|" ++ i 30 ++ i 31 ++ i 32 ++ "|" ++ i 33 ++ i 34 ++ i 35 ++ "|" ++ "\n" ++
"|" ++ i 36 ++ i 37 ++ i 38 ++ "|" ++ i 39 ++ i 40 ++ i 41 ++ "|" ++ i 42 ++ i 43 ++ i 44 ++ "|" ++ "\n" ++
"|" ++ i 45 ++ i 46 ++ i 47 ++ "|" ++ i 48 ++ i 49 ++ i 50 ++ "|" ++ i 51 ++ i 52 ++ i 53 ++ "|" ++ "\n" ++
"+ -  -  - + -  -  - + -  -  - +" ++ "\n" ++
"|" ++ i 54 ++ i 55 ++ i 56 ++ "|" ++ i 57 ++ i 58 ++ i 59 ++ "|" ++ i 60 ++ i 61 ++ i 62 ++ "|" ++ "\n" ++
"|" ++ i 63 ++ i 64 ++ i 65 ++ "|" ++ i 66 ++ i 67 ++ i 68 ++ "|" ++ i 69 ++ i 70 ++ i 71 ++ "|" ++ "\n" ++
"|" ++ i 72 ++ i 73 ++ i 74 ++ "|" ++ i 75 ++ i 76 ++ i 77 ++ "|" ++ i 78 ++ i 79 ++ i 80 ++ "|" ++ "\n" ++
"+ -  -  - + -  -  - + -  -  - +" ++ "\n"
where i x = show (vc ! x)

parseSudoku :: Parser Sudoku
parseSudoku = do
lst <- replicateM 81 field
(newline *> return ()) <|> eof
return \$ Sudoku \$ generate 81 (lst !!)
where field = (char '.' >> return Empty) <|> (Given . read . return <\$> digit)

getSudokus :: String -> Maybe [Sudoku]
getSudokus raw = case parseString (some parseSudoku) mempty raw of
Success ss -> Just ss
Failure _ -> Nothing

data Direction = Back | Forward

solve :: Sudoku -> Maybe Sudoku
solve sudoku@(Sudoku puzzle) =  if isValid sudoku then
Just \$ runST \$ do
puzzle' <- thaw puzzle
go puzzle' 0 Forward
Sudoku <\$> freeze puzzle'
else Nothing
where go _ 81 _ = return ()
go vector position direction = do
case (cell, direction) of
(Empty, Back) -> error "Calling back Empty cell, this should not ever occur"
(Empty, Forward) -> MV.write vector position (Filled 1) >> go vector position Forward
(Given _, Back) -> go vector (position-1) Back
(Given _, Forward) -> go vector (position+1) Forward
(Filled 10, Back) -> MV.write vector position Empty >> go vector (position-1) Back
(Filled 10, Forward) -> go vector position Back
(Filled x, Forward) -> do
let (r, c, s) = calculatePositions position
row <- getRowMV r vector
col <- getColumnMV c vector
sqr <- getSquareMV s vector
if isUnique row && isUnique col && isUnique sqr
then go vector (position+1) Forward
else MV.write vector position (Filled (x+1)) >> go vector position Forward
(Filled x, Back) -> MV.write vector position (Filled (x+1)) >> go vector position Forward

calculatePositions :: Int -> (Int, Int, Int)
calculatePositions i = let (row, col) = divMod i 9
sqr = (row `div` 3)*3 + (col `div` 3)
in (row, col, sqr)

isValid :: Sudoku -> Bool
isValid sudoku = go 0
where go 9 = True
go i = isUnique (getRow i sudoku) && isUnique (getColumn i sudoku) && isUnique (getSquare i sudoku) && go (i+1)

getRow :: Int -> Sudoku -> [Cell]
getRow l (Sudoku vector) = go 0
where go 9 = []
go c = vector ! (l*9 + c) : go (c+1)

getRowMV :: MV.PrimMonad m => Int -> MV.MVector (MV.PrimState m) Cell -> m [Cell]
getRowMV l mv = go 0
where go 9 = return []
go c = do
n <- MV.read mv (l*9 + c)
rl <- go (c+1)
return (n:rl)

getColumn :: Int -> Sudoku -> [Cell]
getColumn c (Sudoku vector) = go 0
where go 9 = []
go i = vector ! (c + i*9) : go (i+1)

getColumnMV :: MV.PrimMonad m => Int -> MV.MVector (MV.PrimState m) Cell -> m [Cell]
getColumnMV c mv = go 0
where go 9 = return []
go i = do
n <- MV.read mv (c + i*9)
rl <- go (i+1)
return (n:rl)

getSquare :: Int -> Sudoku -> [Cell]
getSquare q (Sudoku vector) = let (y, x) = quotRem q 3
start = x*3 + y*3*9
in [ vector ! start, vector ! (start + 1), vector ! (start + 2)
, vector ! (start + 9), vector ! (start + 10), vector ! (start + 11)
, vector ! (start + 18), vector ! (start + 19), vector ! (start + 20)]

getSquareMV :: MV.PrimMonad m => Int -> MV.MVector (MV.PrimState m) a -> m [a]
getSquareMV q mv = let (y, x) = quotRem q 3
start = x*3 + y*3*9
in do
a2 <- MV.read mv (start +  1)
a3 <- MV.read mv (start +  2)
b1 <- MV.read mv (start +  9)
b2 <- MV.read mv (start + 10)
b3 <- MV.read mv (start + 11)
c1 <- MV.read mv (start + 18)
c2 <- MV.read mv (start + 19)
c3 <- MV.read mv (start + 20)
return [a1,a2,a3,b1,b2,b3,c1,c2,c3]

isUnique :: [Cell] -> Bool
isUnique xs =  let sv = strip xs
in length sv == length (nub sv)
where strip (Empty:xs) = strip xs
strip ((Given x):xs) = x : strip xs
strip ((Filled x):xs) = x : strip xs
strip [] = []
``````

Main.hs

``````module Main where

import Control.Parallel.Strategies
import Control.DeepSeq ( force )
import Sudoku
import System.Environment (getArgs)

main :: IO ()
main = do
case getSudokus contents of
Just sudokus -> print \$ runEval \$ do
start <- forM sudokus (rpar . force . solve)
forM start rseq
Nothing -> putStrLn "Error during parsing"
``````

I am compiling it with following flags:

Execution with following flags

cabal exec sudoku -- sudoku17.6.txt +RTS -N1 -s -l

gives following performance report and threadscope diagram

950,178,477,200 bytes allocated in the heap

181,465,696 bytes copied during GC

121,832 bytes maximum residency (7 sample(s))

30,144 bytes maximum slop

7 MiB total memory in use (0 MB lost due to fragmentation)

Tot time (elapsed) Avg pause Max pause

Gen 0 227776 colls, 0 par 1.454s 1.633s 0.0000s 0.0011s

Gen 1 7 colls, 0 par 0.001s 0.001s 0.0001s 0.0002s

TASKS: 4 (1 bound, 3 peak workers (3 total), using -N1)

SPARKS: 6 (0 converted, 0 overflowed, 0 dud, 0 GC'd, 6 fizzled)

INIT time 0.001s ( 0.001s elapsed)

MUT time 220.452s (220.037s elapsed)

GC time 1.455s ( 1.634s elapsed)

EXIT time 0.000s ( 0.008s elapsed)

Total time 221.908s (221.681s elapsed)

Alloc rate 4,310,140,685 bytes per MUT second

Productivity 99.3% of total user, 99.3% of total elapsed Execution with parallelization:

cabal exec sudoku -- sudoku17.6.txt +RTS -N6 -s -l

950,178,549,616 bytes allocated in the heap

325,450,104 bytes copied during GC

142,704 bytes maximum residency (7 sample(s))

82,088 bytes maximum slop

32 MiB total memory in use (0 MB lost due to fragmentation)

Tot time (elapsed) Avg pause Max pause

Gen 0 128677 colls, 128677 par 37.697s 30.612s 0.0002s 0.0035s

Gen 1 7 colls, 6 par 0.005s 0.004s 0.0006s 0.0012s

Parallel GC work balance: 11.66% (serial 0%, perfect 100%)

TASKS: 14 (1 bound, 13 peak workers (13 total), using -N6)

SPARKS: 6 (5 converted, 0 overflowed, 0 dud, 0 GC'd, 1 fizzled)

INIT time 0.010s ( 0.009s elapsed)

MUT time 355.227s (184.035s elapsed)

GC time 37.702s ( 30.616s elapsed)

EXIT time 0.001s ( 0.007s elapsed)

Total time 392.940s (214.667s elapsed)

Alloc rate 2,674,847,755 bytes per MUT second

Productivity 90.4% of total user, 85.7% of total elapsed Here are the contents of sudoku17.6.txt

.......2143.......6........2.15..........637...........68...4.....23........7....

.......241..8.............3...4..5..7.....1......3.......51.6....2....5..3...7...

.......24....1...........8.3.7...1..1..8..5.....2......2.4...6.5...7.3...........

.......23.1..4....5........1.....4.....2...8....8.3.......5.16..4....7....3......

.......21...5...3.4..6.........21...8.......75.....6.....4..8...1..7.....3.......

.......215.3......6...........1.4.6.7.....5.....2........48.3...1..7....2........

• You're basically doing `parMap rdeepseq solve` here, right? Jan 24 at 11:26
• I am creating spark for each task and adding force to ensure whole process will happen in separate calculation so I think yes. Jan 24 at 11:37
• Well, try if it has the same behaviour. Also, try using some other expensive calculation instead of those sudoku solvers. Jan 24 at 11:39
• I am not super familiar with `strategies` but I'd say `forM sudokus (rpar . force . solve)` will solve the sudoku and then create and spark with the puzzle already solve, so you are actually solving in a single thread. I would go with @leftaroundabout recommendation and do `Just sudokus -> print \$ parMap rdeepseq solve sudokus` and see if the threadscope profile improves. Jan 24 at 13:53
• Tried that. Obtained very similar result as with forM sudokus (rpar . force . solve). Both in time of execution and threadscope graph. Jan 24 at 15:21