module Numeric.LAPACK.Matrix.Basic where
import qualified Numeric.LAPACK.Matrix.Shape.Private as MatrixShape
import qualified Numeric.LAPACK.Matrix.Extent.Private as Extent
import qualified Numeric.LAPACK.Private as Private
import Numeric.LAPACK.Matrix.Shape.Private (Order(RowMajor, ColumnMajor))
import Numeric.LAPACK.Matrix.Private (Full, General)
import Numeric.LAPACK.Vector (Vector)
import Numeric.LAPACK.Scalar (zero, one)
import Numeric.LAPACK.Private (pointerSeq)
import qualified Numeric.BLAS.FFI.Generic as BlasGen
import qualified Numeric.Netlib.Utility as Call
import qualified Numeric.Netlib.Class as Class
import qualified Data.Array.Comfort.Storable.Internal as Array
import qualified Data.Array.Comfort.Shape as Shape
import Data.Array.Comfort.Storable.Internal (Array(Array))
import Foreign.ForeignPtr (withForeignPtr)
import Foreign.Storable (poke, peek)
import Control.Monad.Trans.Cont (ContT(ContT), evalContT)
import Control.Monad.IO.Class (liftIO)
transpose ::
(Extent.C vert, Extent.C horiz) =>
Full vert horiz height width a -> Full horiz vert width height a
transpose = Array.mapShape MatrixShape.transpose
singleRow :: Order -> Vector width a -> General () width a
singleRow order = Array.mapShape (MatrixShape.general order ())
singleColumn :: Order -> Vector height a -> General height () a
singleColumn order = Array.mapShape (flip (MatrixShape.general order) ())
flattenRow :: General () width a -> Vector width a
flattenRow = Array.mapShape MatrixShape.fullWidth
flattenColumn :: General height () a -> Vector height a
flattenColumn = Array.mapShape MatrixShape.fullHeight
scaleRows ::
(Extent.C vert, Extent.C horiz,
Shape.C height, Eq height, Shape.C width, Class.Floating a) =>
Vector height a ->
Full vert horiz height width a ->
Full vert horiz height width a
scaleRows
(Array heightX x) (Array shape@(MatrixShape.Full order extent) a) =
Array.unsafeCreate shape $ \bPtr -> do
let (height,width) = Extent.dimensions extent
Call.assert "scaleRows: sizes mismatch" (heightX == height)
case order of
RowMajor -> evalContT $ do
let m = Shape.size height
let n = Shape.size width
alphaPtr <- Call.alloca
nPtr <- Call.cint n
xPtr <- ContT $ withForeignPtr x
aPtr <- ContT $ withForeignPtr a
incaPtr <- Call.cint 1
incbPtr <- Call.cint 1
liftIO $ sequence_ $ take m $
zipWith3
(\xkPtr akPtr bkPtr -> do
poke alphaPtr =<< peek xkPtr
BlasGen.copy nPtr akPtr incaPtr bkPtr incbPtr
BlasGen.scal nPtr alphaPtr bkPtr incbPtr)
(pointerSeq 1 xPtr)
(pointerSeq n aPtr)
(pointerSeq n bPtr)
ColumnMajor -> evalContT $ do
let m = Shape.size width
let n = Shape.size height
transPtr <- Call.char 'N'
nPtr <- Call.cint n
klPtr <- Call.cint 0
kuPtr <- Call.cint 0
alphaPtr <- Call.number one
xPtr <- ContT $ withForeignPtr x
ldxPtr <- Call.leadingDim 1
aPtr <- ContT $ withForeignPtr a
incaPtr <- Call.cint 1
betaPtr <- Call.number zero
incbPtr <- Call.cint 1
liftIO $ sequence_ $ take m $
zipWith
(\akPtr bkPtr ->
Private.gbmv transPtr
nPtr nPtr klPtr kuPtr alphaPtr xPtr ldxPtr
akPtr incaPtr betaPtr bkPtr incbPtr)
(pointerSeq n aPtr)
(pointerSeq n bPtr)
scaleColumns ::
(Extent.C vert, Extent.C horiz,
Shape.C height, Shape.C width, Eq width, Class.Floating a) =>
Vector width a ->
Full vert horiz height width a ->
Full vert horiz height width a
scaleColumns x = transpose . scaleRows x . transpose