{-# OPTIONS_GHC -Wall -fwarn-tabs #-} {-# LANGUAGE BangPatterns #-} ---------------------------------------------------------------- -- 2019.04.13 -- | -- Module : Math.Combinatorics.Exact.Factorial -- Copyright : Copyright (c) 2011--2019 wren gayle romano -- License : BSD -- Maintainer : wren@community.haskell.org -- Stability : experimental -- Portability : Haskell98 + BangPatterns -- -- The factorial numbers (). For negative -- inputs, all functions return 0 (rather than throwing an exception -- or using 'Maybe'). -- -- Notable limits: -- -- * 12! is the largest factorial that can fit into 'Int32'. -- -- * 20! is the largest factorial that can fit into 'Int64'. -- -- * 170! is the largest factorial that can fit into 64-bit 'Double'. ---------------------------------------------------------------- module Math.Combinatorics.Exact.Factorial (factorial) where import Data.Bits {- -- from fallingFactorial n k = product [n - fromInteger i | i <- [0..toInteger k - 1] ] -- == factorial n `div` factorial (n-k) risingFactorial n k = product [n + fromInteger i | i <- [0..toInteger k - 1] ] -- == factorial (n+k) `div` factorial n -- | A common under-approximation of the factorial numbers. factorial_stirling :: (Integral a) => a -> a {-# SPECIALIZE factorial_stirling :: Integer -> Integer, Int -> Int, Int32 -> Int32, Int64 -> Int64 #-} factorial_stirling n | n < 0 = 0 | otherwise = ceiling (sqrt (2 * pi * n') * (n' / exp 1) ** n') where n' :: Double n' = fromIntegral n -} ---------------------------------------------------------------- {- n! = 2^{n - popCount n} * \prod_{k \geq 1} \left( \prod_{n/2^k < j \leq 2*n/2^k} if odd j then j else 1 \right)^k -} -- | Exact factorial numbers. For a fast approximation see -- @math-functions:Numeric.SpecFunctions.factorial@ instead. The -- naive definition of the factorial numbers is: -- -- > factorial n -- > | n < 0 = 0 -- > | otherwise = product [1..n] -- -- However, we use a fast algorithm based on the split-recursive form: -- -- > factorial n = -- > 2^(n - popCount n) * product [(q k)^k | forall k, k >= 1] -- > where -- > q k = product [j | forall j, n*2^(-k) < j <= n*2^(-k+1), odd j] -- factorial :: (Integral a, Bits a) => Int -> a factorial n | n < 0 = 0 | n < 2 = 1 | otherwise = go (highestBitPosition_Int n - 1) 0 0 1 1 1 1 where -- lo == n/2^(k+1) -- lo' == n/2^k -- qk == product of odd @j@s for @k@ in [1..K] -- p == q1 * q2 * ... * qK -- r == (q1 ^ K) * (q2 ^ (K-1)) * ... * (qK ^ 1) -- s == 2^{n - popCount n} -- go :: Int -> Int -> Int -> Int -> a -> a -> a -> a go !k !lo !s !hi !j !p !r | k >= 0 = -- TODO: why did old version use lo/=n ? let lo' = n `shiftR` k -- TODO: use shiftRL# hi' = (lo' - 1) .|. 1 -- if odd lo' then lo' else lo' - 1 len = (hi' - hi) `div` 2 -- TODO: why not (`shiftR`1) or (`quot`2) ? in if len > 0 then let (q, j') = partialProduct len j p' = p * q r' = r * p' in go (k - 1) lo' (s + lo) hi' j' p' r' else go (k - 1) lo' (s + lo) hi' j p r -- -- fromIntegral s /= fromIntegral n - popCount (fromIntegral n) = -- error "factorial_splitRecursive: bug in the computation of n - popCount n" | otherwise = r `shiftL` s -- | The product of odd @j@s between n/2^k and 2*n/2^k. @len@ -- is the count of @j@ terms to multiply, where the @j@ state -- argument is the largest previously used term. partialProduct :: (Integral a) => Int -> a -> (a,a) partialProduct len j | half == 0 = (,) (j+2) (j+2) | len == 2 = (,) ((j+2)*(j+4)) (j+4) | otherwise = let (qL, j' ) = partialProduct (len - half) j (qR, j'') = partialProduct half j' in (,) (qL*qR) j'' where half = len `quot` 2 () = ($!) -- fix associativity {- floorLog2 :: (Integral a, Bits a) => a -> Int floorLog2 n | n <= 0 = error "floorLog2: argument must be positive" | otherwise = highestBitPosition n - 1 highestBitPosition :: (Integral a, Bits a) => a -> Int {-# INLINE highestBitPosition #-} {-# SPECIALIZE highestBitPosition :: Int -> Int #-} highestBitPosition n0 | n0 < 0 = error _highestBitPosition_negative | n0 == 0 = 1 | otherwise = go 0 n0 where go d n | d `seq` n `seq` False = undefined | n > 0 = go (d+1) (n `shiftR` 1) | otherwise = d _highestBitPosition_negative :: String {-# NOINLINE _highestBitPosition_negative #-} _highestBitPosition_negative = "highestBitPosition: argument must be non-negative" floorLog2_Int :: Int -> Int floorLog2_Int n | n <= 0 = error "floorLog2_Int: argument must be positive" | otherwise = highestBitPosition_Int n - 1 -} highestBitPosition_Int :: Int -> Int highestBitPosition_Int w = if w < 1 `shiftL` 15 then if w < 1 `shiftL` 7 then if w < 1 `shiftL` 3 then if w < 1 `shiftL` 1 then if w < 1 `shiftL` 0 then if w < 0 then 32 else 0 -- N.B., Int semantics else 1 else if w < 1 `shiftL` 2 then 2 else 3 else if w < 1 `shiftL` 5 then if w < 1 `shiftL` 4 then 4 else 5 else if w < 1 `shiftL` 6 then 6 else 7 else if w < 1 `shiftL` 11 then if w < 1 `shiftL` 9 then if w < 1 `shiftL` 8 then 8 else 9 else if w < 1 `shiftL` 10 then 10 else 11 else if w < 1 `shiftL` 13 then if w < 1 `shiftL` 12 then 12 else 13 else if w < 1 `shiftL` 14 then 14 else 15 else if w < 1 `shiftL` 23 then if w < 1 `shiftL` 19 then if w < 1 `shiftL` 17 then if w < 1 `shiftL` 16 then 16 else 17 else if w < 1 `shiftL` 18 then 18 else 19 else if w < 1 `shiftL` 21 then if w < 1 `shiftL` 20 then 20 else 21 else if w < 1 `shiftL` 22 then 22 else 23 else if w < 1 `shiftL` 27 then if w < 1 `shiftL` 25 then if w < 1 `shiftL` 24 then 24 else 25 else if w < 1 `shiftL` 26 then 26 else 27 else if w < 1 `shiftL` 29 then if w < 1 `shiftL` 28 then 28 else 29 else if w < 1 `shiftL` 30 then 30 else 31 ---------------------------------------------------------------- {- factorial_primeSwing :: Int -> Integer factorial_primeSwing n0 | n0 < 0 = 0 | n0 < 20 = smallFactorials `unsafeAt` n0 | otherwise = go n0 `shiftL` (n0 - popCount n0) where go n | n < 2 = 1 | otherwise = (go (n `div` 2) ^ 2) * swing n swing n | n < 33 = smallOddSwing `unsafeAt` n | otherwise = let count = 0 rootN = floorSqrt n xs = primes 3 rootN ys = primes (rootN + 1) (n `div` 3) in forM_ xs $ \x -> do let q = n let p = 1 q := q `div` x whileM_ (q > 0) $ do when (q .&. 1 == 1) (p := p*x) q := q `div` x when (p > 1) $ do primeList !! count := p count := count+1 forM_ ys $ \y -> do when ((n `div` y) .&. 1 == 1) $ do primeList !! count := y count := count+1 return $ primorial (n `div` 2 + 1) n * xmathProduct primeList 0 count -- With hsc2hs we can use #def to define these as static C-style -- arrays, and then use base:Foreign.Marshall.Array to access them. -- Instead of using array:Data.Array.Unboxed; Or we could try the -- Addr# trick used in Warp smallOddSwing :: UArray Int Int32 smallOddSwing = listArray (0,32) [ 1, 1, 1, 3, 3, 15, 5, 35, 35, 315, 63, 693, 231, 3003 , 429, 6435, 6435, 109395, 12155, 230945, 46189, 969969 , 88179, 2028117, 676039, 16900975, 1300075, 35102025 , 5014575, 145422675, 9694845, 300540195, 300540195 ] smallFactorials :: UArray Int Int64 smallFactorials = listArray (0,20) [ 1, 1, 2, 6, 24, 120, 720, 5040, 40320, 362880, 3628800 , 39916800, 479001600, 6227020800, 87178291200, 1307674368000 , 20922789888000, 355687428096000, 6402373705728000 , 121645100408832000, 2432902008176640000 ] -- Added to Bits class in base-4.5.0.0==ghc-7.4.1 -- cf -- cf -- | The number of set bits. popCount :: Int -> Int popCount x0 = let x1 = x0 - w2i ((w1 .&. i2w x0) `shiftR` 1) x2 = (x1 .&. m2) + ((x1 `shiftR` 2) .&. m2) x3 = (x2 + (x2 `shiftR` 4)) .&. m4 x4 = x3 + (x3 `shiftR` 8) x5 = x4 + (x4 `shiftR` 16) x6 = x5 + (x5 `shiftR` 32) -- for 64-bit platforms in x6 .&. 0x7f where i2w :: Int -> Word i2w = fromIntegral w2i :: Word -> Int w2i = fromIntegral w1 = 0xaaaaaaaaaaaaaaaa -- binary: 0101... -- m1 = 0x5555555555555555 -- binary: 1010... m2 = 0x3333333333333333 -- binary: 11001100... m4 = 0x0f0f0f0f0f0f0f0f -- binary: 11110000... factorial_parallelPrimeSwing -} ---------------------------------------------------------------- ----------------------------------------------------------- fin.