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|
{-# LANGUAGE TypeOperators #-}
-----------------------------------------------------------------------------
-- |
-- Module : Numeric.LinearAlgebra.LAPACK
-- Copyright : (c) Alberto Ruiz 2006-14
-- License : BSD3
-- Maintainer : Alberto Ruiz
-- Stability : provisional
--
-- Functional interface to selected LAPACK functions (<http://www.netlib.org/lapack>).
--
-----------------------------------------------------------------------------
module Internal.LAPACK where
import Internal.Devel
import Internal.Vector
import Internal.Matrix
import Internal.Conversion
import Internal.Element
import Foreign.Ptr(nullPtr)
import Foreign.C.Types
import Control.Monad(when)
import System.IO.Unsafe(unsafePerformIO)
-----------------------------------------------------------------------------------
type TMMM t = t ..> t ..> t ..> Ok
type F = Float
type Q = Complex Float
foreign import ccall unsafe "multiplyR" dgemmc :: CInt -> CInt -> TMMM R
foreign import ccall unsafe "multiplyC" zgemmc :: CInt -> CInt -> TMMM C
foreign import ccall unsafe "multiplyF" sgemmc :: CInt -> CInt -> TMMM F
foreign import ccall unsafe "multiplyQ" cgemmc :: CInt -> CInt -> TMMM Q
foreign import ccall unsafe "multiplyI" c_multiplyI :: I -> I ::> I ::> I ::> Ok
foreign import ccall unsafe "multiplyL" c_multiplyL :: Z -> Z ::> Z ::> Z ::> Ok
isT Matrix{order = ColumnMajor} = 0
isT Matrix{order = RowMajor} = 1
tt x@Matrix{order = ColumnMajor} = x
tt x@Matrix{order = RowMajor} = trans x
multiplyAux f st a b = unsafePerformIO $ do
when (cols a /= rows b) $ error $ "inconsistent dimensions in matrix product "++
show (rows a,cols a) ++ " x " ++ show (rows b, cols b)
s <- createMatrix ColumnMajor (rows a) (cols b)
app3 (f (isT a) (isT b)) mat (tt a) mat (tt b) mat s st
return s
-- | Matrix product based on BLAS's /dgemm/.
multiplyR :: Matrix Double -> Matrix Double -> Matrix Double
multiplyR a b = {-# SCC "multiplyR" #-} multiplyAux dgemmc "dgemmc" a b
-- | Matrix product based on BLAS's /zgemm/.
multiplyC :: Matrix (Complex Double) -> Matrix (Complex Double) -> Matrix (Complex Double)
multiplyC a b = multiplyAux zgemmc "zgemmc" a b
-- | Matrix product based on BLAS's /sgemm/.
multiplyF :: Matrix Float -> Matrix Float -> Matrix Float
multiplyF a b = multiplyAux sgemmc "sgemmc" a b
-- | Matrix product based on BLAS's /cgemm/.
multiplyQ :: Matrix (Complex Float) -> Matrix (Complex Float) -> Matrix (Complex Float)
multiplyQ a b = multiplyAux cgemmc "cgemmc" a b
multiplyI :: I -> Matrix CInt -> Matrix CInt -> Matrix CInt
multiplyI m a b = unsafePerformIO $ do
when (cols a /= rows b) $ error $
"inconsistent dimensions in matrix product "++ shSize a ++ " x " ++ shSize b
s <- createMatrix ColumnMajor (rows a) (cols b)
app3 (c_multiplyI m) omat a omat b omat s "c_multiplyI"
return s
multiplyL :: Z -> Matrix Z -> Matrix Z -> Matrix Z
multiplyL m a b = unsafePerformIO $ do
when (cols a /= rows b) $ error $
"inconsistent dimensions in matrix product "++ shSize a ++ " x " ++ shSize b
s <- createMatrix ColumnMajor (rows a) (cols b)
app3 (c_multiplyL m) omat a omat b omat s "c_multiplyL"
return s
-----------------------------------------------------------------------------
type TSVD t = t ..> t ..> R :> t ..> Ok
foreign import ccall unsafe "svd_l_R" dgesvd :: TSVD R
foreign import ccall unsafe "svd_l_C" zgesvd :: TSVD C
foreign import ccall unsafe "svd_l_Rdd" dgesdd :: TSVD R
foreign import ccall unsafe "svd_l_Cdd" zgesdd :: TSVD C
-- | Full SVD of a real matrix using LAPACK's /dgesvd/.
svdR :: Matrix Double -> (Matrix Double, Vector Double, Matrix Double)
svdR = svdAux dgesvd "svdR" . fmat
-- | Full SVD of a real matrix using LAPACK's /dgesdd/.
svdRd :: Matrix Double -> (Matrix Double, Vector Double, Matrix Double)
svdRd = svdAux dgesdd "svdRdd" . fmat
-- | Full SVD of a complex matrix using LAPACK's /zgesvd/.
svdC :: Matrix (Complex Double) -> (Matrix (Complex Double), Vector Double, Matrix (Complex Double))
svdC = svdAux zgesvd "svdC" . fmat
-- | Full SVD of a complex matrix using LAPACK's /zgesdd/.
svdCd :: Matrix (Complex Double) -> (Matrix (Complex Double), Vector Double, Matrix (Complex Double))
svdCd = svdAux zgesdd "svdCdd" . fmat
svdAux f st x = unsafePerformIO $ do
u <- createMatrix ColumnMajor r r
s <- createVector (min r c)
v <- createMatrix ColumnMajor c c
app4 f mat x mat u vec s mat v st
return (u,s,v)
where r = rows x
c = cols x
-- | Thin SVD of a real matrix, using LAPACK's /dgesvd/ with jobu == jobvt == \'S\'.
thinSVDR :: Matrix Double -> (Matrix Double, Vector Double, Matrix Double)
thinSVDR = thinSVDAux dgesvd "thinSVDR" . fmat
-- | Thin SVD of a complex matrix, using LAPACK's /zgesvd/ with jobu == jobvt == \'S\'.
thinSVDC :: Matrix (Complex Double) -> (Matrix (Complex Double), Vector Double, Matrix (Complex Double))
thinSVDC = thinSVDAux zgesvd "thinSVDC" . fmat
-- | Thin SVD of a real matrix, using LAPACK's /dgesdd/ with jobz == \'S\'.
thinSVDRd :: Matrix Double -> (Matrix Double, Vector Double, Matrix Double)
thinSVDRd = thinSVDAux dgesdd "thinSVDRdd" . fmat
-- | Thin SVD of a complex matrix, using LAPACK's /zgesdd/ with jobz == \'S\'.
thinSVDCd :: Matrix (Complex Double) -> (Matrix (Complex Double), Vector Double, Matrix (Complex Double))
thinSVDCd = thinSVDAux zgesdd "thinSVDCdd" . fmat
thinSVDAux f st x = unsafePerformIO $ do
u <- createMatrix ColumnMajor r q
s <- createVector q
v <- createMatrix ColumnMajor q c
app4 f mat x mat u vec s mat v st
return (u,s,v)
where r = rows x
c = cols x
q = min r c
-- | Singular values of a real matrix, using LAPACK's /dgesvd/ with jobu == jobvt == \'N\'.
svR :: Matrix Double -> Vector Double
svR = svAux dgesvd "svR" . fmat
-- | Singular values of a complex matrix, using LAPACK's /zgesvd/ with jobu == jobvt == \'N\'.
svC :: Matrix (Complex Double) -> Vector Double
svC = svAux zgesvd "svC" . fmat
-- | Singular values of a real matrix, using LAPACK's /dgesdd/ with jobz == \'N\'.
svRd :: Matrix Double -> Vector Double
svRd = svAux dgesdd "svRd" . fmat
-- | Singular values of a complex matrix, using LAPACK's /zgesdd/ with jobz == \'N\'.
svCd :: Matrix (Complex Double) -> Vector Double
svCd = svAux zgesdd "svCd" . fmat
svAux f st x = unsafePerformIO $ do
s <- createVector q
app2 g mat x vec s st
return s
where r = rows x
c = cols x
q = min r c
g ra ca pa nb pb = f ra ca pa 0 0 nullPtr nb pb 0 0 nullPtr
-- | Singular values and all right singular vectors of a real matrix, using LAPACK's /dgesvd/ with jobu == \'N\' and jobvt == \'A\'.
rightSVR :: Matrix Double -> (Vector Double, Matrix Double)
rightSVR = rightSVAux dgesvd "rightSVR" . fmat
-- | Singular values and all right singular vectors of a complex matrix, using LAPACK's /zgesvd/ with jobu == \'N\' and jobvt == \'A\'.
rightSVC :: Matrix (Complex Double) -> (Vector Double, Matrix (Complex Double))
rightSVC = rightSVAux zgesvd "rightSVC" . fmat
rightSVAux f st x = unsafePerformIO $ do
s <- createVector q
v <- createMatrix ColumnMajor c c
app3 g mat x vec s mat v st
return (s,v)
where r = rows x
c = cols x
q = min r c
g ra ca pa = f ra ca pa 0 0 nullPtr
-- | Singular values and all left singular vectors of a real matrix, using LAPACK's /dgesvd/ with jobu == \'A\' and jobvt == \'N\'.
leftSVR :: Matrix Double -> (Matrix Double, Vector Double)
leftSVR = leftSVAux dgesvd "leftSVR" . fmat
-- | Singular values and all left singular vectors of a complex matrix, using LAPACK's /zgesvd/ with jobu == \'A\' and jobvt == \'N\'.
leftSVC :: Matrix (Complex Double) -> (Matrix (Complex Double), Vector Double)
leftSVC = leftSVAux zgesvd "leftSVC" . fmat
leftSVAux f st x = unsafePerformIO $ do
u <- createMatrix ColumnMajor r r
s <- createVector q
app3 g mat x mat u vec s st
return (u,s)
where r = rows x
c = cols x
q = min r c
g ra ca pa ru cu pu nb pb = f ra ca pa ru cu pu nb pb 0 0 nullPtr
-----------------------------------------------------------------------------
foreign import ccall unsafe "eig_l_R" dgeev :: R ..> R ..> C :> R ..> Ok
foreign import ccall unsafe "eig_l_C" zgeev :: C ..> C ..> C :> C ..> Ok
foreign import ccall unsafe "eig_l_S" dsyev :: CInt -> R ..> R :> R ..> Ok
foreign import ccall unsafe "eig_l_H" zheev :: CInt -> C ..> R :> C ..> Ok
eigAux f st m = unsafePerformIO $ do
l <- createVector r
v <- createMatrix ColumnMajor r r
app3 g mat m vec l mat v st
return (l,v)
where r = rows m
g ra ca pa = f ra ca pa 0 0 nullPtr
-- | Eigenvalues and right eigenvectors of a general complex matrix, using LAPACK's /zgeev/.
-- The eigenvectors are the columns of v. The eigenvalues are not sorted.
eigC :: Matrix (Complex Double) -> (Vector (Complex Double), Matrix (Complex Double))
eigC = eigAux zgeev "eigC" . fmat
eigOnlyAux f st m = unsafePerformIO $ do
l <- createVector r
app2 g mat m vec l st
return l
where r = rows m
g ra ca pa nl pl = f ra ca pa 0 0 nullPtr nl pl 0 0 nullPtr
-- | Eigenvalues of a general complex matrix, using LAPACK's /zgeev/ with jobz == \'N\'.
-- The eigenvalues are not sorted.
eigOnlyC :: Matrix (Complex Double) -> Vector (Complex Double)
eigOnlyC = eigOnlyAux zgeev "eigOnlyC" . fmat
-- | Eigenvalues and right eigenvectors of a general real matrix, using LAPACK's /dgeev/.
-- The eigenvectors are the columns of v. The eigenvalues are not sorted.
eigR :: Matrix Double -> (Vector (Complex Double), Matrix (Complex Double))
eigR m = (s', v'')
where (s,v) = eigRaux (fmat m)
s' = fixeig1 s
v' = toRows $ trans v
v'' = fromColumns $ fixeig (toList s') v'
eigRaux :: Matrix Double -> (Vector (Complex Double), Matrix Double)
eigRaux m = unsafePerformIO $ do
l <- createVector r
v <- createMatrix ColumnMajor r r
app3 g mat m vec l mat v "eigR"
return (l,v)
where r = rows m
g ra ca pa = dgeev ra ca pa 0 0 nullPtr
fixeig1 s = toComplex' (subVector 0 r (asReal s), subVector r r (asReal s))
where r = dim s
fixeig [] _ = []
fixeig [_] [v] = [comp' v]
fixeig ((r1:+i1):(r2:+i2):r) (v1:v2:vs)
| r1 == r2 && i1 == (-i2) = toComplex' (v1,v2) : toComplex' (v1, mapVector negate v2) : fixeig r vs
| otherwise = comp' v1 : fixeig ((r2:+i2):r) (v2:vs)
fixeig _ _ = error "fixeig with impossible inputs"
-- | Eigenvalues of a general real matrix, using LAPACK's /dgeev/ with jobz == \'N\'.
-- The eigenvalues are not sorted.
eigOnlyR :: Matrix Double -> Vector (Complex Double)
eigOnlyR = fixeig1 . eigOnlyAux dgeev "eigOnlyR" . fmat
-----------------------------------------------------------------------------
eigSHAux f st m = unsafePerformIO $ do
l <- createVector r
v <- createMatrix ColumnMajor r r
app3 f mat m vec l mat v st
return (l,v)
where r = rows m
-- | Eigenvalues and right eigenvectors of a symmetric real matrix, using LAPACK's /dsyev/.
-- The eigenvectors are the columns of v.
-- The eigenvalues are sorted in descending order (use 'eigS'' for ascending order).
eigS :: Matrix Double -> (Vector Double, Matrix Double)
eigS m = (s', fliprl v)
where (s,v) = eigS' (fmat m)
s' = fromList . reverse . toList $ s
-- | 'eigS' in ascending order
eigS' :: Matrix Double -> (Vector Double, Matrix Double)
eigS' = eigSHAux (dsyev 1) "eigS'" . fmat
-- | Eigenvalues and right eigenvectors of a hermitian complex matrix, using LAPACK's /zheev/.
-- The eigenvectors are the columns of v.
-- The eigenvalues are sorted in descending order (use 'eigH'' for ascending order).
eigH :: Matrix (Complex Double) -> (Vector Double, Matrix (Complex Double))
eigH m = (s', fliprl v)
where (s,v) = eigH' (fmat m)
s' = fromList . reverse . toList $ s
-- | 'eigH' in ascending order
eigH' :: Matrix (Complex Double) -> (Vector Double, Matrix (Complex Double))
eigH' = eigSHAux (zheev 1) "eigH'" . fmat
-- | Eigenvalues of a symmetric real matrix, using LAPACK's /dsyev/ with jobz == \'N\'.
-- The eigenvalues are sorted in descending order.
eigOnlyS :: Matrix Double -> Vector Double
eigOnlyS = vrev . fst. eigSHAux (dsyev 0) "eigS'" . fmat
-- | Eigenvalues of a hermitian complex matrix, using LAPACK's /zheev/ with jobz == \'N\'.
-- The eigenvalues are sorted in descending order.
eigOnlyH :: Matrix (Complex Double) -> Vector Double
eigOnlyH = vrev . fst. eigSHAux (zheev 0) "eigH'" . fmat
vrev = flatten . flipud . reshape 1
-----------------------------------------------------------------------------
foreign import ccall unsafe "linearSolveR_l" dgesv :: TMMM R
foreign import ccall unsafe "linearSolveC_l" zgesv :: TMMM C
foreign import ccall unsafe "cholSolveR_l" dpotrs :: TMMM R
foreign import ccall unsafe "cholSolveC_l" zpotrs :: TMMM C
linearSolveSQAux g f st a b
| n1==n2 && n1==r = unsafePerformIO . g $ do
s <- createMatrix ColumnMajor r c
app3 f mat a mat b mat s st
return s
| otherwise = error $ st ++ " of nonsquare matrix"
where n1 = rows a
n2 = cols a
r = rows b
c = cols b
-- | Solve a real linear system (for square coefficient matrix and several right-hand sides) using the LU decomposition, based on LAPACK's /dgesv/. For underconstrained or overconstrained systems use 'linearSolveLSR' or 'linearSolveSVDR'. See also 'lusR'.
linearSolveR :: Matrix Double -> Matrix Double -> Matrix Double
linearSolveR a b = linearSolveSQAux id dgesv "linearSolveR" (fmat a) (fmat b)
mbLinearSolveR :: Matrix Double -> Matrix Double -> Maybe (Matrix Double)
mbLinearSolveR a b = linearSolveSQAux mbCatch dgesv "linearSolveR" (fmat a) (fmat b)
-- | Solve a complex linear system (for square coefficient matrix and several right-hand sides) using the LU decomposition, based on LAPACK's /zgesv/. For underconstrained or overconstrained systems use 'linearSolveLSC' or 'linearSolveSVDC'. See also 'lusC'.
linearSolveC :: Matrix (Complex Double) -> Matrix (Complex Double) -> Matrix (Complex Double)
linearSolveC a b = linearSolveSQAux id zgesv "linearSolveC" (fmat a) (fmat b)
mbLinearSolveC :: Matrix (Complex Double) -> Matrix (Complex Double) -> Maybe (Matrix (Complex Double))
mbLinearSolveC a b = linearSolveSQAux mbCatch zgesv "linearSolveC" (fmat a) (fmat b)
-- | Solves a symmetric positive definite system of linear equations using a precomputed Cholesky factorization obtained by 'cholS'.
cholSolveR :: Matrix Double -> Matrix Double -> Matrix Double
cholSolveR a b = linearSolveSQAux id dpotrs "cholSolveR" (fmat a) (fmat b)
-- | Solves a Hermitian positive definite system of linear equations using a precomputed Cholesky factorization obtained by 'cholH'.
cholSolveC :: Matrix (Complex Double) -> Matrix (Complex Double) -> Matrix (Complex Double)
cholSolveC a b = linearSolveSQAux id zpotrs "cholSolveC" (fmat a) (fmat b)
-----------------------------------------------------------------------------------
foreign import ccall unsafe "linearSolveLSR_l" dgels :: TMMM R
foreign import ccall unsafe "linearSolveLSC_l" zgels :: TMMM C
foreign import ccall unsafe "linearSolveSVDR_l" dgelss :: Double -> TMMM R
foreign import ccall unsafe "linearSolveSVDC_l" zgelss :: Double -> TMMM C
linearSolveAux f st a b = unsafePerformIO $ do
r <- createMatrix ColumnMajor (max m n) nrhs
app3 f mat a mat b mat r st
return r
where m = rows a
n = cols a
nrhs = cols b
-- | Least squared error solution of an overconstrained real linear system, or the minimum norm solution of an underconstrained system, using LAPACK's /dgels/. For rank-deficient systems use 'linearSolveSVDR'.
linearSolveLSR :: Matrix Double -> Matrix Double -> Matrix Double
linearSolveLSR a b = subMatrix (0,0) (cols a, cols b) $
linearSolveAux dgels "linearSolverLSR" (fmat a) (fmat b)
-- | Least squared error solution of an overconstrained complex linear system, or the minimum norm solution of an underconstrained system, using LAPACK's /zgels/. For rank-deficient systems use 'linearSolveSVDC'.
linearSolveLSC :: Matrix (Complex Double) -> Matrix (Complex Double) -> Matrix (Complex Double)
linearSolveLSC a b = subMatrix (0,0) (cols a, cols b) $
linearSolveAux zgels "linearSolveLSC" (fmat a) (fmat b)
-- | Minimum norm solution of a general real linear least squares problem Ax=B using the SVD, based on LAPACK's /dgelss/. Admits rank-deficient systems but it is slower than 'linearSolveLSR'. The effective rank of A is determined by treating as zero those singular valures which are less than rcond times the largest singular value. If rcond == Nothing machine precision is used.
linearSolveSVDR :: Maybe Double -- ^ rcond
-> Matrix Double -- ^ coefficient matrix
-> Matrix Double -- ^ right hand sides (as columns)
-> Matrix Double -- ^ solution vectors (as columns)
linearSolveSVDR (Just rcond) a b = subMatrix (0,0) (cols a, cols b) $
linearSolveAux (dgelss rcond) "linearSolveSVDR" (fmat a) (fmat b)
linearSolveSVDR Nothing a b = linearSolveSVDR (Just (-1)) (fmat a) (fmat b)
-- | Minimum norm solution of a general complex linear least squares problem Ax=B using the SVD, based on LAPACK's /zgelss/. Admits rank-deficient systems but it is slower than 'linearSolveLSC'. The effective rank of A is determined by treating as zero those singular valures which are less than rcond times the largest singular value. If rcond == Nothing machine precision is used.
linearSolveSVDC :: Maybe Double -- ^ rcond
-> Matrix (Complex Double) -- ^ coefficient matrix
-> Matrix (Complex Double) -- ^ right hand sides (as columns)
-> Matrix (Complex Double) -- ^ solution vectors (as columns)
linearSolveSVDC (Just rcond) a b = subMatrix (0,0) (cols a, cols b) $
linearSolveAux (zgelss rcond) "linearSolveSVDC" (fmat a) (fmat b)
linearSolveSVDC Nothing a b = linearSolveSVDC (Just (-1)) (fmat a) (fmat b)
-----------------------------------------------------------------------------------
foreign import ccall unsafe "chol_l_H" zpotrf :: TMM C
foreign import ccall unsafe "chol_l_S" dpotrf :: TMM R
cholAux f st a = do
r <- createMatrix ColumnMajor n n
app2 f mat a mat r st
return r
where n = rows a
-- | Cholesky factorization of a complex Hermitian positive definite matrix, using LAPACK's /zpotrf/.
cholH :: Matrix (Complex Double) -> Matrix (Complex Double)
cholH = unsafePerformIO . cholAux zpotrf "cholH" . fmat
-- | Cholesky factorization of a real symmetric positive definite matrix, using LAPACK's /dpotrf/.
cholS :: Matrix Double -> Matrix Double
cholS = unsafePerformIO . cholAux dpotrf "cholS" . fmat
-- | Cholesky factorization of a complex Hermitian positive definite matrix, using LAPACK's /zpotrf/ ('Maybe' version).
mbCholH :: Matrix (Complex Double) -> Maybe (Matrix (Complex Double))
mbCholH = unsafePerformIO . mbCatch . cholAux zpotrf "cholH" . fmat
-- | Cholesky factorization of a real symmetric positive definite matrix, using LAPACK's /dpotrf/ ('Maybe' version).
mbCholS :: Matrix Double -> Maybe (Matrix Double)
mbCholS = unsafePerformIO . mbCatch . cholAux dpotrf "cholS" . fmat
-----------------------------------------------------------------------------------
type TMVM t = t ..> t :> t ..> Ok
foreign import ccall unsafe "qr_l_R" dgeqr2 :: TMVM R
foreign import ccall unsafe "qr_l_C" zgeqr2 :: TMVM C
-- | QR factorization of a real matrix, using LAPACK's /dgeqr2/.
qrR :: Matrix Double -> (Matrix Double, Vector Double)
qrR = qrAux dgeqr2 "qrR" . fmat
-- | QR factorization of a complex matrix, using LAPACK's /zgeqr2/.
qrC :: Matrix (Complex Double) -> (Matrix (Complex Double), Vector (Complex Double))
qrC = qrAux zgeqr2 "qrC" . fmat
qrAux f st a = unsafePerformIO $ do
r <- createMatrix ColumnMajor m n
tau <- createVector mn
app3 f mat a vec tau mat r st
return (r,tau)
where
m = rows a
n = cols a
mn = min m n
foreign import ccall unsafe "c_dorgqr" dorgqr :: TMVM R
foreign import ccall unsafe "c_zungqr" zungqr :: TMVM C
-- | build rotation from reflectors
qrgrR :: Int -> (Matrix Double, Vector Double) -> Matrix Double
qrgrR = qrgrAux dorgqr "qrgrR"
-- | build rotation from reflectors
qrgrC :: Int -> (Matrix (Complex Double), Vector (Complex Double)) -> Matrix (Complex Double)
qrgrC = qrgrAux zungqr "qrgrC"
qrgrAux f st n (a, tau) = unsafePerformIO $ do
res <- createMatrix ColumnMajor (rows a) n
app3 f mat (fmat a) vec (subVector 0 n tau') mat res st
return res
where
tau' = vjoin [tau, constantD 0 n]
-----------------------------------------------------------------------------------
foreign import ccall unsafe "hess_l_R" dgehrd :: TMVM R
foreign import ccall unsafe "hess_l_C" zgehrd :: TMVM C
-- | Hessenberg factorization of a square real matrix, using LAPACK's /dgehrd/.
hessR :: Matrix Double -> (Matrix Double, Vector Double)
hessR = hessAux dgehrd "hessR" . fmat
-- | Hessenberg factorization of a square complex matrix, using LAPACK's /zgehrd/.
hessC :: Matrix (Complex Double) -> (Matrix (Complex Double), Vector (Complex Double))
hessC = hessAux zgehrd "hessC" . fmat
hessAux f st a = unsafePerformIO $ do
r <- createMatrix ColumnMajor m n
tau <- createVector (mn-1)
app3 f mat a vec tau mat r st
return (r,tau)
where m = rows a
n = cols a
mn = min m n
-----------------------------------------------------------------------------------
foreign import ccall unsafe "schur_l_R" dgees :: TMMM R
foreign import ccall unsafe "schur_l_C" zgees :: TMMM C
-- | Schur factorization of a square real matrix, using LAPACK's /dgees/.
schurR :: Matrix Double -> (Matrix Double, Matrix Double)
schurR = schurAux dgees "schurR" . fmat
-- | Schur factorization of a square complex matrix, using LAPACK's /zgees/.
schurC :: Matrix (Complex Double) -> (Matrix (Complex Double), Matrix (Complex Double))
schurC = schurAux zgees "schurC" . fmat
schurAux f st a = unsafePerformIO $ do
u <- createMatrix ColumnMajor n n
s <- createMatrix ColumnMajor n n
app3 f mat a mat u mat s st
return (u,s)
where n = rows a
-----------------------------------------------------------------------------------
foreign import ccall unsafe "lu_l_R" dgetrf :: TMVM R
foreign import ccall unsafe "lu_l_C" zgetrf :: C ..> R :> C ..> Ok
-- | LU factorization of a general real matrix, using LAPACK's /dgetrf/.
luR :: Matrix Double -> (Matrix Double, [Int])
luR = luAux dgetrf "luR" . fmat
-- | LU factorization of a general complex matrix, using LAPACK's /zgetrf/.
luC :: Matrix (Complex Double) -> (Matrix (Complex Double), [Int])
luC = luAux zgetrf "luC" . fmat
luAux f st a = unsafePerformIO $ do
lu <- createMatrix ColumnMajor n m
piv <- createVector (min n m)
app3 f mat a vec piv mat lu st
return (lu, map (pred.round) (toList piv))
where n = rows a
m = cols a
-----------------------------------------------------------------------------------
type Tlus t = t ..> Double :> t ..> t ..> Ok
foreign import ccall unsafe "luS_l_R" dgetrs :: Tlus R
foreign import ccall unsafe "luS_l_C" zgetrs :: Tlus C
-- | Solve a real linear system from a precomputed LU decomposition ('luR'), using LAPACK's /dgetrs/.
lusR :: Matrix Double -> [Int] -> Matrix Double -> Matrix Double
lusR a piv b = lusAux dgetrs "lusR" (fmat a) piv (fmat b)
-- | Solve a real linear system from a precomputed LU decomposition ('luC'), using LAPACK's /zgetrs/.
lusC :: Matrix (Complex Double) -> [Int] -> Matrix (Complex Double) -> Matrix (Complex Double)
lusC a piv b = lusAux zgetrs "lusC" (fmat a) piv (fmat b)
lusAux f st a piv b
| n1==n2 && n2==n =unsafePerformIO $ do
x <- createMatrix ColumnMajor n m
app4 f mat a vec piv' mat b mat x st
return x
| otherwise = error $ st ++ " on LU factorization of nonsquare matrix"
where n1 = rows a
n2 = cols a
n = rows b
m = cols b
piv' = fromList (map (fromIntegral.succ) piv) :: Vector Double
|