{-# LANGUAGE TypeFamilies #-} module Numeric.LAPACK.Matrix.Banded.Linear ( solve, solveColumnMajor, determinant, ) where import qualified Numeric.LAPACK.Matrix.Banded.Basic as Banded import qualified Numeric.LAPACK.Matrix.Shape.Private as MatrixShape import qualified Numeric.LAPACK.Matrix.Extent.Private as Extent import qualified Numeric.LAPACK.Split as Split import qualified Numeric.LAPACK.Private as Private import Numeric.LAPACK.Linear.Private (solver, withDeterminantInfo, withInfo) import Numeric.LAPACK.Matrix.Shape.Private (Order(RowMajor,ColumnMajor), transposeFromOrder) import Numeric.LAPACK.Matrix.Private (Full) import Numeric.LAPACK.Private (copySubMatrix) import qualified Numeric.LAPACK.FFI.Generic as LapackGen import qualified Numeric.Netlib.Utility as Call import qualified Numeric.Netlib.Class as Class import qualified Type.Data.Num.Unary as Unary import Type.Data.Num (integralFromProxy) import qualified Data.Array.Comfort.Shape as Shape import Data.Array.Comfort.Storable.Unchecked (Array(Array)) import System.IO.Unsafe (unsafePerformIO) import Foreign.Marshal.Array (peekArray, advancePtr) import Foreign.ForeignPtr (withForeignPtr) import Control.Monad.Trans.Cont (ContT(ContT), evalContT) import Control.Monad.IO.Class (liftIO) solve :: (Unary.Natural sub, Unary.Natural super, Extent.C vert, Extent.C horiz, Shape.C sh, Eq sh, Shape.C nrhs, Class.Floating a) => Banded.Square sub super sh a -> Full vert horiz sh nrhs a -> Full vert horiz sh nrhs a solve (Array (MatrixShape.Banded numOff order extent) a) = solver "Banded.solve" (Extent.squareSize extent) $ \n nPtr nrhsPtr xPtr ldxPtr -> do let (kl,ku) = MatrixShape.numOffDiagonals order numOff let k = kl+1+ku let ldab = kl+k transPtr <- Call.char $ transposeFromOrder order klPtr <- Call.cint kl kuPtr <- Call.cint ku aPtr <- ContT $ withForeignPtr a abPtr <- Call.allocaArray (n*ldab) ldabPtr <- Call.leadingDim ldab ipivPtr <- Call.allocaArray n liftIO $ do copySubMatrix k n k aPtr ldab (advancePtr abPtr kl) withInfo "gbtrf" $ LapackGen.gbtrf nPtr nPtr klPtr kuPtr abPtr ldabPtr ipivPtr withInfo "gbtrs" $ LapackGen.gbtrs transPtr nPtr klPtr kuPtr nrhsPtr abPtr ldabPtr ipivPtr xPtr ldxPtr solveColumnMajor :: (Unary.Natural sub, Unary.Natural super, Extent.C vert, Extent.C horiz, Shape.C sh, Eq sh, Shape.C nrhs, Class.Floating a) => Banded.Square sub super sh a -> Full vert horiz sh nrhs a -> Full vert horiz sh nrhs a solveColumnMajor (Array (MatrixShape.Banded (sub,super) ColumnMajor extent) a) = solver "Banded.solve" (Extent.squareSize extent) $ \n nPtr nrhsPtr xPtr ldxPtr -> do let kl = integralFromProxy sub let ku = integralFromProxy super let k = kl+1+ku let ldab = kl+k klPtr <- Call.cint kl kuPtr <- Call.cint ku aPtr <- ContT $ withForeignPtr a abPtr <- Call.allocaArray (n*ldab) ldabPtr <- Call.leadingDim ldab ipivPtr <- Call.allocaArray n liftIO $ do copySubMatrix k n k aPtr ldab (advancePtr abPtr kl) withInfo "gbsv" $ LapackGen.gbsv nPtr klPtr kuPtr nrhsPtr abPtr ldabPtr ipivPtr xPtr ldxPtr solveColumnMajor (Array (MatrixShape.Banded _ RowMajor _) _) = error "Linear.Banded.solveColumnMajor: RowMajor intentionally unimplemented" determinant :: (Unary.Natural sub, Unary.Natural super, Shape.C sh, Class.Floating a) => Banded.Square sub super sh a -> a determinant (Array (MatrixShape.Banded numOff order extent) a) = unsafePerformIO $ do let n = Shape.size $ Extent.squareSize extent evalContT $ do let (kl,ku) = MatrixShape.numOffDiagonals order numOff let k = kl+1+ku let ldab = kl+k nPtr <- Call.cint n klPtr <- Call.cint kl kuPtr <- Call.cint ku aPtr <- ContT $ withForeignPtr a abPtr <- Call.allocaArray (n*ldab) ldabPtr <- Call.leadingDim ldab ipivPtr <- Call.allocaArray n liftIO $ do copySubMatrix k n k aPtr ldab (advancePtr abPtr kl) withDeterminantInfo "gbtrf" (LapackGen.gbtrf nPtr nPtr klPtr kuPtr abPtr ldabPtr ipivPtr) (do det <- Private.product n (advancePtr abPtr (kl+ku)) ldab ipiv <- peekArray n ipivPtr return $ if Split.oddPermutation ipiv then -det else det)