-- | -- Module: Math.NumberTheory.Recurrences.Bilinear -- Copyright: (c) 2016 Andrew Lelechenko -- Licence: MIT -- Maintainer: Andrew Lelechenko <andrew.lelechenko@gmail.com> -- -- Bilinear recurrent sequences and Bernoulli numbers, -- roughly covering Ch. 5-6 of /Concrete Mathematics/ -- by R. L. Graham, D. E. Knuth and O. Patashnik. -- -- #memory# __Note on memory leaks and memoization.__ -- Top-level definitions in this module are polymorphic, so the results of computations are not retained in memory. -- Make them monomorphic to take advantages of memoization. Compare -- -- >>> :set +s -- >>> binomial !! 1000 !! 1000 :: Integer -- 1 -- (0.01 secs, 1,385,512 bytes) -- >>> binomial !! 1000 !! 1000 :: Integer -- 1 -- (0.01 secs, 1,381,616 bytes) -- -- against -- -- >>> let binomial' = binomial :: [[Integer]] -- >>> binomial' !! 1000 !! 1000 :: Integer -- 1 -- (0.01 secs, 1,381,696 bytes) -- >>> binomial' !! 1000 !! 1000 :: Integer -- 1 -- (0.01 secs, 391,152 bytes) {-# LANGUAGE BangPatterns #-} {-# LANGUAGE CPP #-} {-# LANGUAGE ScopedTypeVariables #-} module Math.NumberTheory.Recurrences.Bilinear ( -- * Pascal triangle binomial , binomialRotated , binomialLine , binomialDiagonal , binomialFactors -- * Other recurrences , stirling1 , stirling2 , lah , eulerian1 , eulerian2 , bernoulli , euler , eulerPolyAt1 , faulhaberPoly ) where import Data.Euclidean (GcdDomain(..)) import Data.List (scanl', zipWith4) import Data.Maybe import Data.Ratio import Data.Semiring (Semiring(..)) import Numeric.Natural import Math.NumberTheory.Recurrences.Linear (factorial) import Math.NumberTheory.Primes -- | Infinite zero-based table of binomial coefficients (also known as Pascal triangle). -- -- prop> binomial !! n !! k == n! / k! / (n - k)! -- -- Note that 'binomial' !! n !! k is asymptotically slower -- than 'binomialLine' n !! k, -- but imposes only 'Semiring' constraint. -- -- >>> take 6 binomial :: [[Int]] -- [[1],[1,1],[1,2,1],[1,3,3,1],[1,4,6,4,1],[1,5,10,10,5,1]] binomial :: Semiring a => [[a]] binomial = iterate (\l -> zipWith plus (l ++ [zero]) (zero : l)) [one] {-# SPECIALIZE binomial :: [[Int]] #-} {-# SPECIALIZE binomial :: [[Word]] #-} {-# SPECIALIZE binomial :: [[Integer]] #-} {-# SPECIALIZE binomial :: [[Natural]] #-} -- | Pascal triangle, rotated by 45 degrees. -- -- prop> binomialRotated !! n !! k == (n + k)! / n! / k! == binomial !! (n + k) !! k -- -- Note that 'binomialRotated' !! n !! k is asymptotically slower -- than 'binomialDiagonal' n !! k, -- but imposes only 'Semiring' constraint. -- -- >>> take 6 (map (take 6) binomialRotated) :: [[Int]] -- [[1,1,1,1,1,1],[1,2,3,4,5,6],[1,3,6,10,15,21],[1,4,10,20,35,56],[1,5,15,35,70,126],[1,6,21,56,126,252]] binomialRotated :: Semiring a => [[a]] binomialRotated = iterate (tail . scanl' plus zero) (repeat one) {-# SPECIALIZE binomialRotated :: [[Int]] #-} {-# SPECIALIZE binomialRotated :: [[Word]] #-} {-# SPECIALIZE binomialRotated :: [[Integer]] #-} {-# SPECIALIZE binomialRotated :: [[Natural]] #-} -- | The n-th (zero-based) line of 'binomial' -- (and the n-th diagonal of 'binomialRotated'). -- -- >>> binomialLine 5 -- [1,5,10,10,5,1] binomialLine :: (Enum a, GcdDomain a) => a -> [a] binomialLine n = scanl' (\x (k, nk1) -> fromJust $ (x `times` nk1) `divide` k) one (zip [one..n] [n, pred n..one]) {-# SPECIALIZE binomialLine :: Int -> [Int] #-} {-# SPECIALIZE binomialLine :: Word -> [Word] #-} {-# SPECIALIZE binomialLine :: Integer -> [Integer] #-} {-# SPECIALIZE binomialLine :: Natural -> [Natural] #-} -- | The n-th (zero-based) diagonal of 'binomial' -- (and the n-th line of 'binomialRotated'). -- -- >>> take 6 (binomialDiagonal 5) -- [1,6,21,56,126,252] binomialDiagonal :: (Enum a, GcdDomain a) => a -> [a] binomialDiagonal n = scanl' (\x k -> fromJust $ (x `times` (n `plus` k) `divide` k)) one [one..] {-# SPECIALIZE binomialDiagonal :: Int -> [Int] #-} {-# SPECIALIZE binomialDiagonal :: Word -> [Word] #-} {-# SPECIALIZE binomialDiagonal :: Integer -> [Integer] #-} {-# SPECIALIZE binomialDiagonal :: Natural -> [Natural] #-} -- | Prime factors of a binomial coefficient. -- -- prop> binomialFactors n k == factorise (binomial !! n !! k) -- -- >>> binomialFactors 10 4 -- [(Prime 2,1),(Prime 3,1),(Prime 5,1),(Prime 7,1)] binomialFactors :: Word -> Word -> [(Prime Word, Word)] binomialFactors n k | n < 2 = [] | otherwise = filter ((/= 0) . snd) $ map (\p -> (p, mult (unPrime p) n - mult (unPrime p) (n - k) - mult (unPrime p) k)) $ [minBound .. precPrime n] where mult :: Word -> Word -> Word mult p m = go mp mp where mp = m `quot` p go !acc !x | x >= p = let xp = x `quot` p in go (acc + xp) xp | otherwise = acc -- | Infinite zero-based table of <https://en.wikipedia.org/wiki/Stirling_numbers_of_the_first_kind Stirling numbers of the first kind>. -- -- >>> take 5 (map (take 5) stirling1) -- [[1],[0,1],[0,1,1],[0,2,3,1],[0,6,11,6,1]] -- -- Complexity: @stirling1 !! n !! k@ is O(n ln n) bits long, its computation -- takes O(k n^2 ln n) time and forces thunks @stirling1 !! i !! j@ for @0 <= i <= n@ and @max(0, k - n + i) <= j <= k@. -- -- One could also consider 'Math.Combinat.Numbers.unsignedStirling1st' to compute stand-alone values. stirling1 :: (Num a, Enum a) => [[a]] stirling1 = scanl f [1] [0..] where f xs n = 0 : zipIndexedListWithTail (\_ x y -> x + n * y) 1 xs 0 {-# SPECIALIZE stirling1 :: [[Int]] #-} {-# SPECIALIZE stirling1 :: [[Word]] #-} {-# SPECIALIZE stirling1 :: [[Integer]] #-} {-# SPECIALIZE stirling1 :: [[Natural]] #-} -- | Infinite zero-based table of <https://en.wikipedia.org/wiki/Stirling_numbers_of_the_second_kind Stirling numbers of the second kind>. -- -- >>> take 5 (map (take 5) stirling2) -- [[1],[0,1],[0,1,1],[0,1,3,1],[0,1,7,6,1]] -- -- Complexity: @stirling2 !! n !! k@ is O(n ln n) bits long, its computation -- takes O(k n^2 ln n) time and forces thunks @stirling2 !! i !! j@ for @0 <= i <= n@ and @max(0, k - n + i) <= j <= k@. -- -- One could also consider 'Math.Combinat.Numbers.stirling2nd' to compute stand-alone values. stirling2 :: (Num a, Enum a) => [[a]] stirling2 = iterate f [1] where f xs = 0 : zipIndexedListWithTail (\k x y -> x + k * y) 1 xs 0 {-# SPECIALIZE stirling2 :: [[Int]] #-} {-# SPECIALIZE stirling2 :: [[Word]] #-} {-# SPECIALIZE stirling2 :: [[Integer]] #-} {-# SPECIALIZE stirling2 :: [[Natural]] #-} -- | Infinite one-based table of <https://en.wikipedia.org/wiki/Lah_number Lah numbers>. -- @lah !! n !! k@ equals to lah(n + 1, k + 1). -- -- >>> take 5 (map (take 5) lah) -- [[1],[2,1],[6,6,1],[24,36,12,1],[120,240,120,20,1]] -- -- Complexity: @lah !! n !! k@ is O(n ln n) bits long, its computation -- takes O(k n ln n) time and forces thunks @lah !! n !! i@ for @0 <= i <= k@. lah :: Integral a => [[a]] -- Implementation was derived from code by https://github.com/grandpascorpion lah = zipWith f (tail factorial) [1..] where f nf n = scanl (\x k -> x * (n - k) `div` (k * (k + 1))) nf [1..n-1] {-# SPECIALIZE lah :: [[Int]] #-} {-# SPECIALIZE lah :: [[Word]] #-} {-# SPECIALIZE lah :: [[Integer]] #-} {-# SPECIALIZE lah :: [[Natural]] #-} -- | Infinite zero-based table of <https://en.wikipedia.org/wiki/Eulerian_number Eulerian numbers of the first kind>. -- -- >>> take 5 (map (take 5) eulerian1) -- [[],[1],[1,1],[1,4,1],[1,11,11,1]] -- -- Complexity: @eulerian1 !! n !! k@ is O(n ln n) bits long, its computation -- takes O(k n^2 ln n) time and forces thunks @eulerian1 !! i !! j@ for @0 <= i <= n@ and @max(0, k - n + i) <= j <= k@. -- eulerian1 :: (Num a, Enum a) => [[a]] eulerian1 = scanl f [] [1..] where f xs n = 1 : zipIndexedListWithTail (\k x y -> (n - k) * x + (k + 1) * y) 1 xs 0 {-# SPECIALIZE eulerian1 :: [[Int]] #-} {-# SPECIALIZE eulerian1 :: [[Word]] #-} {-# SPECIALIZE eulerian1 :: [[Integer]] #-} {-# SPECIALIZE eulerian1 :: [[Natural]] #-} -- | Infinite zero-based table of <https://en.wikipedia.org/wiki/Eulerian_number#Eulerian_numbers_of_the_second_kind Eulerian numbers of the second kind>. -- -- >>> take 5 (map (take 5) eulerian2) -- [[],[1],[1,2],[1,8,6],[1,22,58,24]] -- -- Complexity: @eulerian2 !! n !! k@ is O(n ln n) bits long, its computation -- takes O(k n^2 ln n) time and forces thunks @eulerian2 !! i !! j@ for @0 <= i <= n@ and @max(0, k - n + i) <= j <= k@. -- eulerian2 :: (Num a, Enum a) => [[a]] eulerian2 = scanl f [] [1..] where f xs n = 1 : zipIndexedListWithTail (\k x y -> (2 * n - k - 1) * x + (k + 1) * y) 1 xs 0 {-# SPECIALIZE eulerian2 :: [[Int]] #-} {-# SPECIALIZE eulerian2 :: [[Word]] #-} {-# SPECIALIZE eulerian2 :: [[Integer]] #-} {-# SPECIALIZE eulerian2 :: [[Natural]] #-} -- | Infinite zero-based sequence of <https://en.wikipedia.org/wiki/Bernoulli_number Bernoulli numbers>, -- computed via <https://en.wikipedia.org/wiki/Bernoulli_number#Connection_with_Stirling_numbers_of_the_second_kind connection> -- with 'stirling2'. -- -- >>> take 5 bernoulli -- [1 % 1,(-1) % 2,1 % 6,0 % 1,(-1) % 30] -- -- Complexity: @bernoulli !! n@ is O(n ln n) bits long, its computation -- takes O(n^3 ln n) time and forces thunks @stirling2 !! i !! j@ for @0 <= i <= n@ and @0 <= j <= i@. -- -- One could also consider 'Math.Combinat.Numbers.bernoulli' to compute stand-alone values. bernoulli :: Integral a => [Ratio a] bernoulli = helperForB_E_EP id (map recip [1..]) {-# SPECIALIZE bernoulli :: [Ratio Int] #-} {-# SPECIALIZE bernoulli :: [Rational] #-} -- | <https://en.wikipedia.org/wiki/Faulhaber%27s_formula Faulhaber's formula>. -- -- >>> sum (map (^ 10) [0..100]) -- 959924142434241924250 -- >>> sum $ zipWith (*) (faulhaberPoly 10) (iterate (* 100) 1) -- 959924142434241924250 % 1 faulhaberPoly :: (GcdDomain a, Integral a) => Int -> [Ratio a] -- Implementation by https://github.com/CarlEdman faulhaberPoly p = zipWith (*) ((0:) $ reverse $ take (p+1) $ bernoulli) $ map (% (fromIntegral p+1)) $ zipWith (*) (iterate negate (if odd p then 1 else -1)) $ binomial !! (p+1) -- | Infinite zero-based list of <https://en.wikipedia.org/wiki/Euler_number Euler numbers>. -- The algorithm used was derived from <http://www.emis.ams.org/journals/JIS/VOL4/CHEN/AlgBE2.pdf Algorithms for Bernoulli numbers and Euler numbers> -- by Kwang-Wu Chen, second formula of the Corollary in page 7. -- Sequence <https://oeis.org/A122045 A122045> in OEIS. -- -- >>> take 10 euler' :: [Rational] -- [1 % 1,0 % 1,(-1) % 1,0 % 1,5 % 1,0 % 1,(-61) % 1,0 % 1,1385 % 1,0 % 1] euler' :: forall a . Integral a => [Ratio a] euler' = tail $ helperForB_E_EP tail as where as :: [Ratio a] as = zipWith3 (\sgn frac ones -> (sgn * ones) % frac) (cycle [1, 1, 1, 1, -1, -1, -1, -1]) (dups (iterate (2 *) 1)) (cycle [1, 1, 1, 0]) dups :: forall x . [x] -> [x] dups = foldr (\n list -> n : n : list) [] {-# SPECIALIZE euler' :: [Ratio Int] #-} {-# SPECIALIZE euler' :: [Rational] #-} -- | The same sequence as @euler'@, but with type @[a]@ instead of @[Ratio a]@ -- as the denominators in @euler'@ are always @1@. -- -- >>> take 10 euler :: [Integer] -- [1,0,-1,0,5,0,-61,0,1385,0] euler :: forall a . Integral a => [a] euler = map numerator euler' -- | Infinite zero-based list of the @n@-th order Euler polynomials evaluated at @1@. -- The algorithm used was derived from <http://www.emis.ams.org/journals/JIS/VOL4/CHEN/AlgBE2.pdf Algorithms for Bernoulli numbers and Euler numbers> -- by Kwang-Wu Chen, third formula of the Corollary in page 7. -- Element-by-element division of sequences <https://oeis.org/A198631 A1986631> -- and <https://oeis.org/A006519 A006519> in OEIS. -- -- >>> take 10 eulerPolyAt1 :: [Rational] -- [1 % 1,1 % 2,0 % 1,(-1) % 4,0 % 1,1 % 2,0 % 1,(-17) % 8,0 % 1,31 % 2] eulerPolyAt1 :: forall a . Integral a => [Ratio a] eulerPolyAt1 = tail $ helperForB_E_EP tail (map recip (iterate (2 *) 1)) {-# SPECIALIZE eulerPolyAt1 :: [Ratio Int] #-} {-# SPECIALIZE eulerPolyAt1 :: [Rational] #-} ------------------------------------------------------------------------------- -- Utils -- zipIndexedListWithTail f n as a == zipWith3 f [n..] as (tail as ++ [a]) -- but inlines much better and avoids checks for distinct sizes of lists. zipIndexedListWithTail :: Enum b => (b -> a -> a -> b) -> b -> [a] -> a -> [b] zipIndexedListWithTail f n as a = case as of [] -> [] (x : xs) -> go n x xs where go m y ys = case ys of [] -> let v = f m y a in [v] (z : zs) -> let v = f m y z in (v : go (succ m) z zs) {-# INLINE zipIndexedListWithTail #-} -- | Helper for common code in @bernoulli, euler, eulerPolyAt1. All three -- sequences rely on @stirling2@ and have the same general structure of -- zipping four lists together with multiplication, with one of those lists -- being the sublists in @stirling2@, and two of them being the factorial -- sequence and @cycle [1, -1]@. The remaining list is passed to -- @helperForB_E_EP@ as an argument. -- -- Note: This function has a @([Ratio a] -> [Ratio a])@ argument because -- @bernoulli !! n@ will use, for all nonnegative @n@, every element in -- @stirling2 !! n@, while @euler, eulerPolyAt1@ only use -- @tail $ stirling2 !! n@. As such, this argument serves to pass @id@ -- in the former case, and @tail@ in the latter. helperForB_E_EP :: Integral a => ([Ratio a] -> [Ratio a]) -> [Ratio a] -> [Ratio a] helperForB_E_EP g xs = map (f . g) stirling2 where f = sum . zipWith4 (\sgn fact x stir -> sgn * fact * x * stir) (cycle [1, -1]) factorial xs {-# SPECIALIZE helperForB_E_EP :: ([Ratio Int] -> [Ratio Int]) -> [Ratio Int] -> [Ratio Int] #-} {-# SPECIALIZE helperForB_E_EP :: ([Rational] -> [Rational]) -> [Rational] -> [Rational] #-}