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{-# LANGUAGE TypeFamilies #-}
{-# LANGUAGE FlexibleContexts #-}
{-# LANGUAGE FlexibleInstances #-}
{-# LANGUAGE MultiParamTypeClasses #-}
{-# LANGUAGE FunctionalDependencies #-}
{-# LANGUAGE UndecidableInstances #-}

-----------------------------------------------------------------------------
-- |
-- Module      :  Numeric.Container
-- Copyright   :  (c) Alberto Ruiz 2010
-- License     :  GPL-style
--
-- Maintainer  :  Alberto Ruiz <aruiz@um.es>
-- Stability   :  provisional
-- Portability :  portable
--
-- Basic numeric operations on 'Vector' and 'Matrix', including conversion routines.
--
-- The 'Container' class is used to define optimized generic functions which work
-- on 'Vector' and 'Matrix' with real or complex elements.
--
-- Some of these functions are also available in the instances of the standard
-- numeric Haskell classes provided by "Numeric.LinearAlgebra".
--
-----------------------------------------------------------------------------

module Numeric.Container (
    -- * Basic functions
    module Data.Packed,
    constant, linspace,
    diag, ident,
    ctrans,
    -- * Generic operations
    Container(..),
    -- * Matrix product
    Product(..),
    optimiseMult,
    mXm,mXv,vXm,(<.>),(<>),(<\>),
    outer, kronecker,
    -- * Random numbers
    RandDist(..),
    randomVector,
    gaussianSample,
    uniformSample,
    meanCov,
    -- * Element conversion
    Convert(..),
    Complexable(),
    RealElement(),

    RealOf, ComplexOf, SingleOf, DoubleOf,

    IndexOf,
    module Data.Complex,
    -- * Input / Output
    dispf, disps, dispcf, vecdisp, latexFormat, format,
    loadMatrix, saveMatrix, fromFile, fileDimensions,
    readMatrix,
    fscanfVector, fprintfVector, freadVector, fwriteVector,
    -- * Experimental
    build', konst',
    -- * Deprecated
    (.*),(*/),(<|>),(<->),
    vectorMax,vectorMin,
    vectorMaxIndex, vectorMinIndex
) where

import Data.Packed
import Data.Packed.Internal(constantD)
import Numeric.ContainerBoot
import Numeric.Chain
import Numeric.IO
import Data.Complex
import Numeric.LinearAlgebra.Algorithms(Field,linearSolveSVD)
import Data.Packed.Random

------------------------------------------------------------------

{- | 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, Container 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)

-- | Dot product: @u \<.\> v = dot u v@
(<.>) :: Product t => Vector t -> Vector t -> t
infixl 7 <.>
(<.>) = dot



--------------------------------------------------------

class Mul a b c | a b -> c where
 infixl 7 <>
 -- | Matrix-matrix, matrix-vector, and vector-matrix products.
 (<>)  :: Product t => a t -> b t -> c t

instance Mul Matrix Matrix Matrix where
    (<>) = mXm

instance Mul Matrix Vector Vector where
    (<>) m v = flatten $ m <> asColumn v

instance Mul Vector Matrix Vector where
    (<>) v m = flatten $ asRow v <> m

--------------------------------------------------------

-- | least squares solution of a linear system, similar to the \\ operator of Matlab\/Octave (based on linearSolveSVD).
(<\>) :: (Field a) => Matrix a -> Vector a -> Vector a
infixl 7 <\>
m <\> v = flatten (linearSolveSVD m (reshape 1 v))

--------------------------------------------------------