{-# LANGUAGE NoImplicitPrelude #-} module MathObj.PowerSeries.Core where import qualified MathObj.Polynomial.Core as Poly import qualified Algebra.Module as Module import qualified Algebra.Transcendental as Transcendental import qualified Algebra.Field as Field import qualified Algebra.Ring as Ring import qualified Algebra.Additive as Additive import qualified Algebra.ZeroTestable as ZeroTestable import qualified Data.List.Match as Match import qualified NumericPrelude.Numeric as NP import qualified NumericPrelude.Base as P import NumericPrelude.Base hiding (const) import NumericPrelude.Numeric hiding (negate, stdUnit, divMod, sqrt, exp, log, sin, cos, tan, asin, acos, atan) {-# INLINE evaluate #-} evaluate :: Ring.C a => [a] -> a -> a evaluate = flip Poly.horner {-# INLINE evaluateCoeffVector #-} evaluateCoeffVector :: Module.C a v => [v] -> a -> v evaluateCoeffVector = flip Poly.hornerCoeffVector {-# INLINE evaluateArgVector #-} evaluateArgVector :: (Module.C a v, Ring.C v) => [a] -> v -> v evaluateArgVector = flip Poly.hornerArgVector {-# INLINE approximate #-} approximate :: Ring.C a => [a] -> a -> [a] approximate y x = scanl (+) zero (zipWith (*) (iterate (x*) 1) y) {-# INLINE approximateCoeffVector #-} approximateCoeffVector :: Module.C a v => [v] -> a -> [v] approximateCoeffVector y x = scanl (+) zero (zipWith (*>) (iterate (x*) 1) y) {-# INLINE approximateArgVector #-} approximateArgVector :: (Module.C a v, Ring.C v) => [a] -> v -> [v] approximateArgVector y x = scanl (+) zero (zipWith (*>) y (iterate (x*) 1)) {- * Simple series manipulation -} {- | For the series of a real function @f@ compute the series for @\x -> f (-x)@ -} alternate :: Additive.C a => [a] -> [a] alternate = zipWith id (cycle [id, NP.negate]) {- | For the series of a real function @f@ compute the series for @\x -> (f x + f (-x)) \/ 2@ -} holes2 :: Additive.C a => [a] -> [a] holes2 = zipWith id (cycle [id, P.const zero]) {- | For the series of a real function @f@ compute the real series for @\x -> (f (i*x) + f (-i*x)) \/ 2@ -} holes2alternate :: Additive.C a => [a] -> [a] holes2alternate = zipWith id (cycle [id, P.const zero, NP.negate, P.const zero]) {- * Series arithmetic -} add, sub :: (Additive.C a) => [a] -> [a] -> [a] add = Poly.add sub = Poly.sub negate :: (Additive.C a) => [a] -> [a] negate = Poly.negate scale :: Ring.C a => a -> [a] -> [a] scale = Poly.scale mul :: Ring.C a => [a] -> [a] -> [a] mul = Poly.mul stripLeadZero :: (ZeroTestable.C a) => [a] -> [a] -> ([a],[a]) stripLeadZero (x:xs) (y:ys) = if isZero x && isZero y then stripLeadZero xs ys else (x:xs,y:ys) stripLeadZero xs ys = (xs,ys) divMod :: (ZeroTestable.C a, Field.C a) => [a] -> [a] -> ([a],[a]) divMod xs ys = let (yZero,yRem) = span isZero ys (xMod, xRem) = Match.splitAt yZero xs in (divide xRem yRem, xMod) {- | Divide two series where the absolute term of the divisor is non-zero. That is, power series with leading non-zero terms are the units in the ring of power series. Knuth: Seminumerical algorithms -} divide :: (Field.C a) => [a] -> [a] -> [a] divide (x:xs) (y:ys) = let zs = map (/y) (x : sub xs (mul zs ys)) in zs divide [] _ = [] divide _ [] = error "PowerSeries.divide: division by empty series" {- | Divide two series also if the divisor has leading zeros. -} divideStripZero :: (ZeroTestable.C a, Field.C a) => [a] -> [a] -> [a] divideStripZero x' y' = let (x0,y0) = stripLeadZero x' y' in if null y0 || isZero (head y0) then error "PowerSeries.divideStripZero: Division by zero." else divide x0 y0 progression :: Ring.C a => [a] progression = Poly.progression recipProgression :: (Field.C a) => [a] recipProgression = map recip progression differentiate :: (Ring.C a) => [a] -> [a] differentiate = Poly.differentiate integrate :: (Field.C a) => a -> [a] -> [a] integrate = Poly.integrate {- | We need to compute the square root only of the first term. That is, if the first term is rational, then all terms of the series are rational. -} sqrt :: Field.C a => (a -> a) -> [a] -> [a] sqrt _ [] = [] sqrt f0 (x:xs) = let y = f0 x ys = map (/(y+y)) (xs - (0 : mul ys ys)) in y:ys {- pow alpha t = t^alpha (pow alpha . x)' = alpha * (pow (alpha-1) . x) * x' alpha * (pow alpha . x) = x * x' * (pow alpha . x)' y = pow alpha . x alpha * y = x * x' * y' -} {- | Input series must start with non-zero term. -} pow :: (Field.C a) => (a -> a) -> a -> [a] -> [a] pow f0 expon x = let y = integrate (f0 (head x)) y' y' = scale expon (divide y (mul x (differentiate x))) in y {- | The first term needs a transcendent computation but the others do not. That's why we accept a function which computes the first term. > (exp . x)' = (exp . x) * x' > (sin . x)' = (cos . x) * x' > (cos . x)' = - (sin . x) * x' -} exp :: Field.C a => (a -> a) -> [a] -> [a] exp f0 x = let x' = differentiate x y = integrate (f0 (head x)) (mul y x') in y sinCos :: Field.C a => (a -> (a,a)) -> [a] -> ([a],[a]) sinCos f0 x = let (y0Sin, y0Cos) = f0 (head x) x' = differentiate x ySin = integrate y0Sin (mul yCos x') yCos = integrate y0Cos (negate (mul ySin x')) in (ySin, yCos) sinCosScalar :: Transcendental.C a => a -> (a,a) sinCosScalar x = (Transcendental.sin x, Transcendental.cos x) sin, cos :: Field.C a => (a -> (a,a)) -> [a] -> [a] sin f0 = fst . sinCos f0 cos f0 = snd . sinCos f0 tan :: (Field.C a) => (a -> (a,a)) -> [a] -> [a] tan f0 = uncurry divide . sinCos f0 {- (log x)' == x'/x (asin x)' == (acos x) == x'/sqrt(1-x^2) (atan x)' == x'/(1+x^2) -} {- | Input series must start with non-zero term. -} log :: (Field.C a) => (a -> a) -> [a] -> [a] log f0 x = integrate (f0 (head x)) (derivedLog x) {- | Computes @(log x)'@, that is @x'\/x@ -} derivedLog :: (Field.C a) => [a] -> [a] derivedLog x = divide (differentiate x) x atan :: (Field.C a) => (a -> a) -> [a] -> [a] atan f0 x = let x' = differentiate x in integrate (f0 (head x)) (divide x' ([1] + mul x x)) asin, acos :: (Field.C a) => (a -> a) -> (a -> a) -> [a] -> [a] asin sqrt0 f0 x = let x' = differentiate x in integrate (f0 (head x)) (divide x' (sqrt sqrt0 ([1] - mul x x))) acos = asin {- | Since the inner series must start with a zero, the first term is omitted in y. -} compose :: (Ring.C a) => [a] -> [a] -> [a] compose xs y = foldr (\x acc -> x : mul y acc) [] xs {- | Compose two power series where the outer series can be developed for any expansion point. To be more precise: The outer series must be expanded with respect to the leading term of the inner series. -} composeTaylor :: Ring.C a => (a -> [a]) -> [a] -> [a] composeTaylor x (y:ys) = compose (x y) ys composeTaylor x [] = x 0 {- (x . y) = id (x' . y) * y' = 1 y' = 1 / (x' . y) -} {- | This function returns the series of the function in the form: (point of the expansion, power series) This is exceptionally slow and needs cubic run-time. -} inv :: (Field.C a) => [a] -> (a, [a]) inv x = let y' = divide [1] (compose (differentiate x) (tail y)) y = integrate 0 y' -- the first term is zero, which is required for composition in (head x, y)