-- | -- /SplitMix/ is a splittable pseudorandom number generator (PRNG) that is quite fast. -- -- Guy L. Steele, Jr., Doug Lea, and Christine H. Flood. 2014. -- Fast splittable pseudorandom number generators. In Proceedings -- of the 2014 ACM International Conference on Object Oriented -- Programming Systems Languages & Applications (OOPSLA '14). ACM, -- New York, NY, USA, 453-472. DOI: -- -- -- The paper describes a new algorithm /SplitMix/ for /splittable/ -- pseudorandom number generator that is quite fast: 9 64 bit arithmetic/logical -- operations per 64 bits generated. -- -- /SplitMix/ is tested with two standard statistical test suites (DieHarder and -- TestU01, this implementation only using the former) and it appears to be -- adequate for "everyday" use, such as Monte Carlo algorithms and randomized -- data structures where speed is important. -- -- In particular, it __should not be used for cryptographic or security applications__, -- because generated sequences of pseudorandom values are too predictable -- (the mixing functions are easily inverted, and two successive outputs -- suffice to reconstruct the internal state). -- -- Note: This module supports all GHCs since GHC-7.0.4, -- but GHC-7.0 and GHC-7.2 have slow implementation, as there -- are no native 'popCount'. -- {-# LANGUAGE CPP #-} #if __GLASGOW_HASKELL__ >= 702 {-# LANGUAGE Trustworthy #-} #endif module System.Random.SplitMix ( SMGen, nextWord64, nextWord32, nextTwoWord32, nextInt, nextDouble, nextFloat, nextInteger, splitSMGen, -- * Generation bitmaskWithRejection32, bitmaskWithRejection32', bitmaskWithRejection64, bitmaskWithRejection64', -- * Initialisation mkSMGen, initSMGen, newSMGen, seedSMGen, seedSMGen', unseedSMGen, ) where import Data.Bits (complement, shiftL, shiftR, xor, (.&.), (.|.)) import Data.Bits.Compat (countLeadingZeros, popCount, zeroBits) import Data.IORef (IORef, atomicModifyIORef, newIORef) import Data.Time.Clock.POSIX (getPOSIXTime) import Data.Word (Word32, Word64) import System.IO.Unsafe (unsafePerformIO) #if defined(__HUGS__) || !MIN_VERSION_base(4,8,0) import Data.Word (Word) #endif #ifndef __HUGS__ import Control.DeepSeq (NFData (..)) #endif #ifdef MIN_VERSION_random import qualified System.Random as R #endif #if !__GHCJS__ import System.CPUTime (cpuTimePrecision, getCPUTime) #endif -- $setup -- >>> import Text.Read (readMaybe) -- >>> import Data.List (unfoldr) -- >>> import Text.Printf (printf) ------------------------------------------------------------------------------- -- Generator ------------------------------------------------------------------------------- -- | SplitMix generator state. data SMGen = SMGen !Word64 !Word64 -- seed and gamma; gamma is odd deriving Show #ifndef __HUGS__ instance NFData SMGen where rnf (SMGen _ _) = () #endif -- | -- -- >>> readMaybe "SMGen 1 1" :: Maybe SMGen -- Just (SMGen 1 1) -- -- >>> readMaybe "SMGen 1 2" :: Maybe SMGen -- Nothing -- -- >>> readMaybe (show (mkSMGen 42)) :: Maybe SMGen -- Just (SMGen 9297814886316923340 13679457532755275413) -- instance Read SMGen where readsPrec d r = readParen (d > 10) (\r0 -> [ (SMGen seed gamma, r3) | ("SMGen", r1) <- lex r0 , (seed, r2) <- readsPrec 11 r1 , (gamma, r3) <- readsPrec 11 r2 , odd gamma ]) r ------------------------------------------------------------------------------- -- Operations ------------------------------------------------------------------------------- -- | Generate a 'Word64'. -- -- >>> take 3 $ map (printf "%x") $ unfoldr (Just . nextWord64) (mkSMGen 1337) :: [String] -- ["b5c19e300e8b07b3","d600e0e216c0ac76","c54efc3b3cc5af29"] -- nextWord64 :: SMGen -> (Word64, SMGen) nextWord64 (SMGen seed gamma) = (mix64 seed', SMGen seed' gamma) where seed' = seed `plus` gamma -- | Generate 'Word32' by truncating 'nextWord64'. -- -- @since 0.0.3 nextWord32 :: SMGen -> (Word32, SMGen) nextWord32 g = #ifdef __HUGS__ (fromIntegral $ w64 .&. 0xffffffff, g') #else (fromIntegral w64, g') #endif where (w64, g') = nextWord64 g -- | Generate two 'Word32'. -- -- @since 0.0.3 nextTwoWord32 :: SMGen -> (Word32, Word32, SMGen) nextTwoWord32 g = #ifdef __HUGS__ (fromIntegral $ w64 `shiftR` 32, fromIntegral $ w64 .&. 0xffffffff, g') #else (fromIntegral $ w64 `shiftR` 32, fromIntegral w64, g') #endif where (w64, g') = nextWord64 g -- | Generate an 'Int'. nextInt :: SMGen -> (Int, SMGen) nextInt g = case nextWord64 g of #ifdef __HUGS__ (w64, g') -> (fromIntegral $ w64 `shiftR` 32, g') #else (w64, g') -> (fromIntegral w64, g') #endif -- | Generate a 'Double' in @[0, 1)@ range. -- -- >>> take 8 $ map (printf "%0.3f") $ unfoldr (Just . nextDouble) (mkSMGen 1337) :: [String] -- ["0.710","0.836","0.771","0.409","0.297","0.527","0.589","0.067"] -- nextDouble :: SMGen -> (Double, SMGen) nextDouble g = case nextWord64 g of (w64, g') -> (fromIntegral (w64 `shiftR` 11) * doubleUlp, g') -- | Generate a 'Float' in @[0, 1)@ range. -- -- >>> take 8 $ map (printf "%0.3f") $ unfoldr (Just . nextFloat) (mkSMGen 1337) :: [String] -- ["0.057","0.089","0.237","0.383","0.680","0.320","0.826","0.007"] -- -- @since 0.0.3 nextFloat :: SMGen -> (Float, SMGen) nextFloat g = case nextWord32 g of (w32, g') -> (fromIntegral (w32 `shiftR` 8) * floatUlp, g') -- | Generate an 'Integer' in closed @[x, y]@ range. nextInteger :: Integer -> Integer -> SMGen -> (Integer, SMGen) nextInteger lo hi g = case compare lo hi of LT -> let (i, g') = nextInteger' (hi - lo) g in (i + lo, g') EQ -> (lo, g) GT -> let (i, g') = nextInteger' (lo - hi) g in (i + hi, g') -- invariant: first argument is positive -- Essentially bitmaskWithRejection but for Integers. -- nextInteger' :: Integer -> SMGen -> (Integer, SMGen) nextInteger' range = loop where leadMask :: Word64 restDigits :: Word (leadMask, restDigits) = go 0 range where go :: Word -> Integer -> (Word64, Word) go n x | x < two64 = (complement zeroBits `shiftR` countLeadingZeros (fromInteger x :: Word64), n) | otherwise = go (n + 1) (x `shiftR` 64) generate :: SMGen -> (Integer, SMGen) generate g0 = let (x, g') = nextWord64 g0 x' = x .&. leadMask in go (fromIntegral x') restDigits g' where go :: Integer -> Word -> SMGen -> (Integer, SMGen) go acc 0 g = acc `seq` (acc, g) go acc n g = let (x, g') = nextWord64 g in go (acc * two64 + fromIntegral x) (n - 1) g' loop g = let (x, g') = generate g in if x > range then loop g' else (x, g') two64 :: Integer two64 = 2 ^ (64 :: Int) ------------------------------------------------------------------------------- -- Splitting ------------------------------------------------------------------------------- -- | Split a generator into a two uncorrelated generators. splitSMGen :: SMGen -> (SMGen, SMGen) splitSMGen (SMGen seed gamma) = (SMGen seed'' gamma, SMGen (mix64 seed') (mixGamma seed'')) where seed' = seed `plus` gamma seed'' = seed' `plus` gamma ------------------------------------------------------------------------------- -- Algorithm ------------------------------------------------------------------------------- goldenGamma :: Word64 goldenGamma = 0x9e3779b97f4a7c15 floatUlp :: Float floatUlp = 1.0 / fromIntegral (1 `shiftL` 24 :: Word32) doubleUlp :: Double doubleUlp = 1.0 / fromIntegral (1 `shiftL` 53 :: Word64) -- Note: in JDK implementations the mix64 and mix64variant13 -- (which is inlined into mixGamma) are swapped. mix64 :: Word64 -> Word64 mix64 z0 = -- MurmurHash3Mixer let z1 = shiftXorMultiply 33 0xff51afd7ed558ccd z0 z2 = shiftXorMultiply 33 0xc4ceb9fe1a85ec53 z1 z3 = shiftXor 33 z2 in z3 -- used only in mixGamma mix64variant13 :: Word64 -> Word64 mix64variant13 z0 = -- Better Bit Mixing - Improving on MurmurHash3's 64-bit Finalizer -- http://zimbry.blogspot.fi/2011/09/better-bit-mixing-improving-on.html -- -- Stafford's Mix13 let z1 = shiftXorMultiply 30 0xbf58476d1ce4e5b9 z0 -- MurmurHash3 mix constants z2 = shiftXorMultiply 27 0x94d049bb133111eb z1 z3 = shiftXor 31 z2 in z3 mixGamma :: Word64 -> Word64 mixGamma z0 = let z1 = mix64variant13 z0 .|. 1 -- force to be odd n = popCount (z1 `xor` (z1 `shiftR` 1)) -- see: http://www.pcg-random.org/posts/bugs-in-splitmix.html -- let's trust the text of the paper, not the code. in if n >= 24 then z1 else z1 `xor` 0xaaaaaaaaaaaaaaaa shiftXor :: Int -> Word64 -> Word64 shiftXor n w = w `xor` (w `shiftR` n) shiftXorMultiply :: Int -> Word64 -> Word64 -> Word64 shiftXorMultiply n k w = shiftXor n w `mult` k ------------------------------------------------------------------------------- -- Generation ------------------------------------------------------------------------------- -- | /Bitmask with rejection/ method of generating subrange of 'Word32'. -- -- @since 0.0.3 bitmaskWithRejection32 :: Word32 -> SMGen -> (Word32, SMGen) bitmaskWithRejection32 0 = error "bitmaskWithRejection32 0" bitmaskWithRejection32 n = bitmaskWithRejection32' (n - 1) -- | /Bitmask with rejection/ method of generating subrange of 'Word64'. -- -- @bitmaskWithRejection64 w64@ generates random numbers in closed-open -- range of @[0, w64)@. -- -- >>> take 20 $ unfoldr (Just . bitmaskWithRejection64 5) (mkSMGen 1337) -- [3,1,4,1,2,3,1,1,0,3,4,2,3,0,2,3,3,4,1,0] -- -- @since 0.0.3 bitmaskWithRejection64 :: Word64 -> SMGen -> (Word64, SMGen) bitmaskWithRejection64 0 = error "bitmaskWithRejection64 0" bitmaskWithRejection64 n = bitmaskWithRejection64' (n - 1) -- | /Bitmask with rejection/ method of generating subrange of 'Word32'. -- -- @since 0.0.4 bitmaskWithRejection32' :: Word32 -> SMGen -> (Word32, SMGen) bitmaskWithRejection32' range = go where mask = complement zeroBits `shiftR` countLeadingZeros (range .|. 1) go g = let (x, g') = nextWord32 g x' = x .&. mask in if x' > range then go g' else (x', g') -- | /Bitmask with rejection/ method of generating subrange of 'Word64'. -- -- @bitmaskWithRejection64' w64@ generates random numbers in closed-closed -- range of @[0, w64]@. -- -- >>> take 20 $ unfoldr (Just . bitmaskWithRejection64' 5) (mkSMGen 1337) -- [3,1,4,1,2,3,1,1,0,3,4,5,2,3,0,2,3,5,3,4] -- -- @since 0.0.4 bitmaskWithRejection64' :: Word64 -> SMGen -> (Word64, SMGen) bitmaskWithRejection64' range = go where mask = complement zeroBits `shiftR` countLeadingZeros range go g = let (x, g') = nextWord64 g x' = x .&. mask in if x' > range then go g' else (x', g') ------------------------------------------------------------------------------- -- Initialisation ------------------------------------------------------------------------------- -- | Create 'SMGen' using seed and gamma. -- -- >>> seedSMGen 2 2 -- SMGen 2 3 -- seedSMGen :: Word64 -- ^ seed -> Word64 -- ^ gamma -> SMGen seedSMGen seed gamma = SMGen seed (gamma .|. 1) -- | Like 'seedSMGen' but takes a pair. seedSMGen' :: (Word64, Word64) -> SMGen seedSMGen' = uncurry seedSMGen -- | Extract current state of 'SMGen'. unseedSMGen :: SMGen -> (Word64, Word64) unseedSMGen (SMGen seed gamma) = (seed, gamma) -- | Preferred way to deterministically construct 'SMGen'. -- -- >>> mkSMGen 42 -- SMGen 9297814886316923340 13679457532755275413 -- mkSMGen :: Word64 -> SMGen mkSMGen s = SMGen (mix64 s) (mixGamma (s `plus` goldenGamma)) -- | Initialize 'SMGen' using system time. initSMGen :: IO SMGen initSMGen = fmap mkSMGen mkSeedTime -- | Derive a new generator instance from the global 'SMGen' using 'splitSMGen'. newSMGen :: IO SMGen newSMGen = atomicModifyIORef theSMGen splitSMGen theSMGen :: IORef SMGen theSMGen = unsafePerformIO $ initSMGen >>= newIORef {-# NOINLINE theSMGen #-} mkSeedTime :: IO Word64 mkSeedTime = do now <- getPOSIXTime let lo = truncate now :: Word32 #if __GHCJS__ let hi = lo #else cpu <- getCPUTime let hi = fromIntegral (cpu `div` cpuTimePrecision) :: Word32 #endif return $ fromIntegral hi `shiftL` 32 .|. fromIntegral lo ------------------------------------------------------------------------------- -- System.Random ------------------------------------------------------------------------------- #ifdef MIN_VERSION_random instance R.RandomGen SMGen where next = nextInt split = splitSMGen #endif ------------------------------------------------------------------------------- -- Hugs ------------------------------------------------------------------------------- mult, plus :: Word64 -> Word64 -> Word64 #ifndef __HUGS__ mult = (*) plus = (+) #else -- Hugs defines: -- -- x * y = fromInteger (toInteger x * toInteger y) -- x + y = fromInteger (toInteger x + toInteger y) -- -- which obviously overflows in our use cases, as fromInteger doesn't truncate -- mult x y = fromInteger ((toInteger x * toInteger y) `mod` 18446744073709551616) plus x y = fromInteger ((toInteger x + toInteger y) `mod` 18446744073709551616) #endif