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fix some errors in polynomial code
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@ -177,7 +177,7 @@ ddist ( Bezier {..} ) c = [ a5, a4, a3, a2, a1, a0 ]
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-- | Finds the closest point to a given point on a cubic Bézier curve.
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-- | Finds the closest point to a given point on a cubic Bézier curve.
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closestPoint
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closestPoint
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:: forall v r p. ( Torsor v p, Inner r v, RealFloat r, Prim r )
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:: forall v r p. ( Torsor v p, Inner r v, RealFloat r, Prim r, NFData r )
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=> Bezier p -> p -> ArgMin r ( r, p )
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=> Bezier p -> p -> ArgMin r ( r, p )
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closestPoint pts c = pickClosest ( 0 :| 1 : roots ) -- todo: also include the self-intersection point if one exists
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closestPoint pts c = pickClosest ( 0 :| 1 : roots ) -- todo: also include the self-intersection point if one exists
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where
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where
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@ -145,7 +145,7 @@ ddist ( Bezier {..} ) c = [ a3, a2, a1, a0 ]
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-- | Finds the closest point to a given point on a quadratic Bézier curve.
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-- | Finds the closest point to a given point on a quadratic Bézier curve.
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closestPoint
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closestPoint
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:: forall v r p. ( Torsor v p, Inner r v, RealFloat r, Prim r )
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:: forall v r p. ( Torsor v p, Inner r v, RealFloat r, Prim r, NFData r )
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=> Bezier p -> p -> ArgMin r ( r, p )
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=> Bezier p -> p -> ArgMin r ( r, p )
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closestPoint pts c = pickClosest ( 0 :| 1 : roots )
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closestPoint pts c = pickClosest ( 0 :| 1 : roots )
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where
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where
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@ -161,7 +161,7 @@ discardCache ( view ( typed @( CachedStroke s ) ) -> CachedStroke { cachedStroke
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{-# INLINE invalidateCache #-}
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{-# INLINE invalidateCache #-}
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invalidateCache :: forall crvData. HasType ( CachedStroke RealWorld ) crvData => crvData -> crvData
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invalidateCache :: forall crvData. HasType ( CachedStroke RealWorld ) crvData => crvData -> crvData
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invalidateCache = runRW# \ s -> do
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invalidateCache = runRW# \ s ->
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case newMutVar# Nothing s of
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case newMutVar# Nothing s of
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(# _, mutVar #) ->
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(# _, mutVar #) ->
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set ( typed @( CachedStroke RealWorld ) )
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set ( typed @( CachedStroke RealWorld ) )
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@ -6,8 +6,6 @@
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{-# LANGUAGE ScopedTypeVariables #-}
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{-# LANGUAGE ScopedTypeVariables #-}
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{-# LANGUAGE TypeApplications #-}
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{-# LANGUAGE TypeApplications #-}
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{-# OPTIONS_GHC -fno-warn-partial-type-signatures #-}
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module Math.Roots where
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module Math.Roots where
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-- base
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-- base
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@ -20,6 +18,10 @@ import Data.Complex
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import Data.Maybe
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import Data.Maybe
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( mapMaybe )
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( mapMaybe )
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-- deepseq
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import Control.DeepSeq
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( NFData, force )
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-- primitive
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-- primitive
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import Control.Monad.Primitive
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import Control.Monad.Primitive
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( PrimMonad(PrimState) )
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( PrimMonad(PrimState) )
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@ -70,7 +72,7 @@ solveQuadratic a0 a1 a2
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--
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--
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-- Coefficients are given in order of decreasing degree, e.g.:
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-- Coefficients are given in order of decreasing degree, e.g.:
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-- x² + 7 is given by [ 1, 0, 7 ].
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-- x² + 7 is given by [ 1, 0, 7 ].
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realRoots :: forall a. ( RealFloat a, Prim a ) => Int -> [ a ] -> [ a ]
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realRoots :: forall a. ( RealFloat a, Prim a, NFData a ) => Int -> [ a ] -> [ a ]
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realRoots maxIters coeffs = mapMaybe isReal ( roots epsilon maxIters ( map (:+ 0) coeffs ) )
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realRoots maxIters coeffs = mapMaybe isReal ( roots epsilon maxIters ( map (:+ 0) coeffs ) )
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where
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where
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isReal :: Complex a -> Maybe a
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isReal :: Complex a -> Maybe a
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@ -84,18 +86,18 @@ realRoots maxIters coeffs = mapMaybe isReal ( roots epsilon maxIters ( map (:+ 0
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--
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--
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-- N.B. The forward deflation process is only guaranteed to be numerically stable
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-- N.B. The forward deflation process is only guaranteed to be numerically stable
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-- if Laguerre's method finds roots in increasing order of magnitude.
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-- if Laguerre's method finds roots in increasing order of magnitude.
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roots :: forall a. ( RealFloat a, Prim a ) => a -> Int -> [ Complex a ] -> [ Complex a ]
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roots :: forall a. ( RealFloat a, Prim a, NFData a ) => a -> Int -> [ Complex a ] -> [ Complex a ]
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roots eps maxIters coeffs = runST do
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roots eps maxIters coeffs = runST do
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let
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let
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coeffPrimArray :: PrimArray ( Complex a )
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coeffPrimArray :: PrimArray ( Complex a )
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coeffPrimArray = primArrayFromList coeffs
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coeffPrimArray = primArrayFromList coeffs
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sz :: Int
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sz :: Int
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sz = sizeofPrimArray coeffPrimArray
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sz = sizeofPrimArray coeffPrimArray
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p <- unsafeThawPrimArray coeffPrimArray
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( p :: MutablePrimArray s ( Complex a ) ) <- unsafeThawPrimArray coeffPrimArray
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let
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let
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go :: Int -> [ Complex a ] -> ST _s [ Complex a ]
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go :: Int -> [ Complex a ] -> ST s [ Complex a ]
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go i rs = do
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go !i rs = do
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!r <- laguerre eps maxIters p 0 -- Start Laguerre's method at 0 for best chance of numerical stability.
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!r <- force <$> laguerre eps maxIters p 0 -- Start Laguerre's method at 0 for best chance of numerical stability.
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if i <= 2
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if i <= 2
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then pure ( r : rs )
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then pure ( r : rs )
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else do
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else do
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@ -116,7 +118,7 @@ deflate r p = do
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shrinkMutablePrimArray p deg
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shrinkMutablePrimArray p deg
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let
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let
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go :: a -> Int -> m ()
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go :: a -> Int -> m ()
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go b i = unless ( i >= deg ) do
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go !b !i = unless ( i >= deg ) do
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ai <- readPrimArray p i
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ai <- readPrimArray p i
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writePrimArray p i ( ai + r * b )
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writePrimArray p i ( ai + r * b )
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go ai ( i + 1 )
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go ai ( i + 1 )
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@ -137,7 +139,7 @@ laguerre eps maxIters p x0 = do
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p'' <- derivative p'
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p'' <- derivative p'
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let
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let
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go :: Int -> Complex a -> m ( Complex a )
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go :: Int -> Complex a -> m ( Complex a )
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go iterationsLeft x = do
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go !iterationsLeft !x = do
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x' <- laguerreStep eps p p' p'' x
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x' <- laguerreStep eps p p' p'' x
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if iterationsLeft <= 1 || magnitude ( x' - x ) < eps
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if iterationsLeft <= 1 || magnitude ( x' - x ) < eps
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then pure x'
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then pure x'
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@ -189,11 +191,12 @@ eval p x = do
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n <- getSizeofMutablePrimArray p
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n <- getSizeofMutablePrimArray p
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let
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let
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go :: a -> Int -> m a
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go :: a -> Int -> m a
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go !a i =
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go !a !i
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if i >= n
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| i >= n
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then pure a
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= pure a
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else do
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| otherwise
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!b <- readPrimArray p i
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= do
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b <- readPrimArray p i
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go ( b + x * a ) ( i + 1 )
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go ( b + x * a ) ( i + 1 )
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an <- readPrimArray p 0
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an <- readPrimArray p 0
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go an 1
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go an 1
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@ -208,8 +211,9 @@ derivative p = do
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p' <- cloneMutablePrimArray p 0 deg
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p' <- cloneMutablePrimArray p 0 deg
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let
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let
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go :: Int -> m ()
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go :: Int -> m ()
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go i = unless ( i >= deg ) do
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go !i = unless ( i >= deg - 1 ) do
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a <- readPrimArray p' i
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a <- readPrimArray p' i
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writePrimArray p' i ( a * fromIntegral ( deg - i ) )
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writePrimArray p' i ( a * fromIntegral ( deg - i ) )
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go ( i + 1 )
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go 0
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go 0
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pure p'
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pure p'
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