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{-# LANGUAGE TypeFamilies #-}
{-# LANGUAGE FlexibleContexts #-}
{-# LANGUAGE FlexibleInstances #-}
{-# LANGUAGE UndecidableInstances #-}
{-# LANGUAGE MultiParamTypeClasses #-}
--{-# LANGUAGE FunctionalDependencies #-}
-----------------------------------------------------------------------------
-- |
-- Module : Numeric.Vector
-- Copyright : (c) Alberto Ruiz 2007
-- License : GPL-style
--
-- Maintainer : Alberto Ruiz <aruiz@um.es>
-- Stability : provisional
-- Portability : portable
--
-- Numeric instances and functions for 'Data.Packed.Vector's
--
-----------------------------------------------------------------------------
module Numeric.Vector (
-- * Vector creation
constant, linspace,
module Data.Packed.Vector
) where
import Data.Complex
import Control.Monad(ap)
import Data.Packed.Vector
import Data.Packed.Matrix(Element(..))
import Numeric.GSL.Vector
import Numeric.Container
-------------------------------------------------------------------
#ifndef VECTOR
import Foreign(Storable)
#endif
------------------------------------------------------------------
#ifndef VECTOR
instance (Show a, Storable a) => (Show (Vector a)) where
show v = (show (dim v))++" |> " ++ show (toList v)
#endif
#ifdef VECTOR
instance (Element a, Read a) => Read (Vector a) where
readsPrec _ s = [(fromList . read $ listnums, rest)]
where (thing,trest) = breakAt ']' s
(dims,listnums) = breakAt ' ' (dropWhile (==' ') thing)
rest = drop 31 trest
#else
instance (Element a, Read a) => Read (Vector a) where
readsPrec _ s = [((d |>) . read $ listnums, rest)]
where (thing,rest) = breakAt ']' s
(dims,listnums) = breakAt '>' thing
d = read . init . fst . breakAt '|' $ dims
#endif
breakAt c l = (a++[c],tail b) where
(a,b) = break (==c) l
------------------------------------------------------------------
{- | creates a vector with a given number of equal components:
@> constant 2 7
7 |> [2.0,2.0,2.0,2.0,2.0,2.0,2.0]@
-}
constant :: Element a => a -> Int -> Vector a
-- constant x n = runSTVector (newVector x n)
constant = constantD -- about 2x faster
{- | Creates a real vector containing a range of values:
@\> linspace 5 (-3,7)
5 |> [-3.0,-0.5,2.0,4.5,7.0]@
Logarithmic spacing can be defined as follows:
@logspace n (a,b) = 10 ** linspace n (a,b)@
-}
linspace :: (Enum e, Linear Vector e) => Int -> (e, e) -> Vector e
linspace n (a,b) = addConstant a $ scale s $ fromList [0 .. fromIntegral n-1]
where s = (b-a)/fromIntegral (n-1)
------------------------------------------------------------------
adaptScalar f1 f2 f3 x y
| dim x == 1 = f1 (x@>0) y
| dim y == 1 = f3 x (y@>0)
| otherwise = f2 x y
------------------------------------------------------------------
#ifndef VECTOR
instance Linear Vector a => Eq (Vector a) where
(==) = equal
#endif
instance Num (Vector Float) where
(+) = adaptScalar addConstant add (flip addConstant)
negate = scale (-1)
(*) = adaptScalar scale mul (flip scale)
signum = vectorMapF Sign
abs = vectorMapF Abs
fromInteger = fromList . return . fromInteger
instance Num (Vector Double) where
(+) = adaptScalar addConstant add (flip addConstant)
negate = scale (-1)
(*) = adaptScalar scale mul (flip scale)
signum = vectorMapR Sign
abs = vectorMapR Abs
fromInteger = fromList . return . fromInteger
instance Num (Vector (Complex Double)) where
(+) = adaptScalar addConstant add (flip addConstant)
negate = scale (-1)
(*) = adaptScalar scale mul (flip scale)
signum = vectorMapC Sign
abs = vectorMapC Abs
fromInteger = fromList . return . fromInteger
instance Num (Vector (Complex Float)) where
(+) = adaptScalar addConstant add (flip addConstant)
negate = scale (-1)
(*) = adaptScalar scale mul (flip scale)
signum = vectorMapQ Sign
abs = vectorMapQ Abs
fromInteger = fromList . return . fromInteger
---------------------------------------------------
instance (Linear Vector a, Num (Vector a)) => Fractional (Vector a) where
fromRational n = fromList [fromRational n]
(/) = adaptScalar f divide g where
r `f` v = scaleRecip r v
v `g` r = scale (recip r) v
-------------------------------------------------------
instance Floating (Vector Float) where
sin = vectorMapF Sin
cos = vectorMapF Cos
tan = vectorMapF Tan
asin = vectorMapF ASin
acos = vectorMapF ACos
atan = vectorMapF ATan
sinh = vectorMapF Sinh
cosh = vectorMapF Cosh
tanh = vectorMapF Tanh
asinh = vectorMapF ASinh
acosh = vectorMapF ACosh
atanh = vectorMapF ATanh
exp = vectorMapF Exp
log = vectorMapF Log
sqrt = vectorMapF Sqrt
(**) = adaptScalar (vectorMapValF PowSV) (vectorZipF Pow) (flip (vectorMapValF PowVS))
pi = fromList [pi]
-------------------------------------------------------------
instance Floating (Vector Double) where
sin = vectorMapR Sin
cos = vectorMapR Cos
tan = vectorMapR Tan
asin = vectorMapR ASin
acos = vectorMapR ACos
atan = vectorMapR ATan
sinh = vectorMapR Sinh
cosh = vectorMapR Cosh
tanh = vectorMapR Tanh
asinh = vectorMapR ASinh
acosh = vectorMapR ACosh
atanh = vectorMapR ATanh
exp = vectorMapR Exp
log = vectorMapR Log
sqrt = vectorMapR Sqrt
(**) = adaptScalar (vectorMapValR PowSV) (vectorZipR Pow) (flip (vectorMapValR PowVS))
pi = fromList [pi]
-------------------------------------------------------------
instance Floating (Vector (Complex Double)) where
sin = vectorMapC Sin
cos = vectorMapC Cos
tan = vectorMapC Tan
asin = vectorMapC ASin
acos = vectorMapC ACos
atan = vectorMapC ATan
sinh = vectorMapC Sinh
cosh = vectorMapC Cosh
tanh = vectorMapC Tanh
asinh = vectorMapC ASinh
acosh = vectorMapC ACosh
atanh = vectorMapC ATanh
exp = vectorMapC Exp
log = vectorMapC Log
sqrt = vectorMapC Sqrt
(**) = adaptScalar (vectorMapValC PowSV) (vectorZipC Pow) (flip (vectorMapValC PowVS))
pi = fromList [pi]
-----------------------------------------------------------
instance Floating (Vector (Complex Float)) where
sin = vectorMapQ Sin
cos = vectorMapQ Cos
tan = vectorMapQ Tan
asin = vectorMapQ ASin
acos = vectorMapQ ACos
atan = vectorMapQ ATan
sinh = vectorMapQ Sinh
cosh = vectorMapQ Cosh
tanh = vectorMapQ Tanh
asinh = vectorMapQ ASinh
acosh = vectorMapQ ACosh
atanh = vectorMapQ ATanh
exp = vectorMapQ Exp
log = vectorMapQ Log
sqrt = vectorMapQ Sqrt
(**) = adaptScalar (vectorMapValQ PowSV) (vectorZipQ Pow) (flip (vectorMapValQ PowVS))
pi = fromList [pi]
-----------------------------------------------------------
-- instance (Storable a, Num (Vector a)) => Monoid (Vector a) where
-- mempty = 0 { idim = 0 }
-- mappend a b = mconcat [a,b]
-- mconcat = j . filter ((>0).dim)
-- where j [] = mempty
-- j l = join l
---------------------------------------------------------------
-- instance (NFData a, Storable a) => NFData (Vector a) where
-- rnf = rnf . (@>0)
--
-- instance (NFData a, Element a) => NFData (Matrix a) where
-- rnf = rnf . flatten
---------------------------------------------------------------
instance Linear Vector Float where
scale = vectorMapValF Scale
scaleRecip = vectorMapValF Recip
addConstant = vectorMapValF AddConstant
add = vectorZipF Add
sub = vectorZipF Sub
mul = vectorZipF Mul
divide = vectorZipF Div
equal u v = dim u == dim v && maxElement (vectorMapF Abs (sub u v)) == 0.0
scalar x = fromList [x]
minIndex = round . toScalarF MinIdx
maxIndex = round . toScalarF MaxIdx
minElement = toScalarF Min
maxElement = toScalarF Max
instance Linear Vector Double where
scale = vectorMapValR Scale
scaleRecip = vectorMapValR Recip
addConstant = vectorMapValR AddConstant
add = vectorZipR Add
sub = vectorZipR Sub
mul = vectorZipR Mul
divide = vectorZipR Div
equal u v = dim u == dim v && maxElement (vectorMapR Abs (sub u v)) == 0.0
scalar x = fromList [x]
minIndex = round . toScalarR MinIdx
maxIndex = round . toScalarR MaxIdx
minElement = toScalarR Min
maxElement = toScalarR Max
instance Linear Vector (Complex Double) where
scale = vectorMapValC Scale
scaleRecip = vectorMapValC Recip
addConstant = vectorMapValC AddConstant
add = vectorZipC Add
sub = vectorZipC Sub
mul = vectorZipC Mul
divide = vectorZipC Div
equal u v = dim u == dim v && maxElement (mapVector magnitude (sub u v)) == 0.0
scalar x = fromList [x]
minIndex = minIndex . fst . fromComplex . (zipVectorWith (*) `ap` mapVector conjugate)
maxIndex = maxIndex . fst . fromComplex . (zipVectorWith (*) `ap` mapVector conjugate)
minElement = ap (@>) minIndex
maxElement = ap (@>) maxIndex
instance Linear Vector (Complex Float) where
scale = vectorMapValQ Scale
scaleRecip = vectorMapValQ Recip
addConstant = vectorMapValQ AddConstant
add = vectorZipQ Add
sub = vectorZipQ Sub
mul = vectorZipQ Mul
divide = vectorZipQ Div
equal u v = dim u == dim v && maxElement (mapVector magnitude (sub u v)) == 0.0
scalar x = fromList [x]
minIndex = minIndex . fst . fromComplex . (zipVectorWith (*) `ap` mapVector conjugate)
maxIndex = maxIndex . fst . fromComplex . (zipVectorWith (*) `ap` mapVector conjugate)
minElement = ap (@>) minIndex
maxElement = ap (@>) maxIndex
---------------------------------------------------------------
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