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#ifndef TEUCHOS_DETAILS_LAPACK128_HPP
#define TEUCHOS_DETAILS_LAPACK128_HPP
/// \file Teuchos_Details_Lapack128.hpp
/// \brief Declaration and definition of Teuchos::Details::Lapack128,
/// a partial implementation of Teuchos::LAPACK for __float128.
#include "Teuchos_ConfigDefs.hpp"
#ifdef HAVE_TEUCHOSCORE_QUADMATH
namespace Teuchos {
namespace Details {
//! Partial implementation of Teuchos::LAPACK for __float128.
class Lapack128 {
public:
/// \brief Compute the LU factorization with partial pivoting of
/// the matrix A.
void
GETRF (const int M, const int N, __float128 A[],
const int LDA, int IPIV[], int* INFO) const;
/// \brief Perform a series of row interchanges on the matrix A.
///
/// Do one row interchange for each of rows K1 through K2 of A.
///
/// \param N [in] Number of columns of the matrix A.
/// \param A [in/out] 2-D column-major array of dimension (LDA,N).
/// On entry, the matrix of column dimension N to which the row
/// interchanges will be applied. On exit, the permuted matrix.
/// \param LDA [in] The leading dimension (stride) of the 2-D
/// column-major array A.
/// \param K1 [in] Start row interchanges with IPIV[K1-1].
/// \param K2 [in] Stop row interchanges with IPIV[K2-1].
/// \param INCX [in] Increment between successive entries of IPIV.
/// If IPIV is negative, apply the pivots in reverse order.
void
LASWP (const int N, __float128 A[], const int LDA, const int K1,
const int K2, const int IPIV[], const int INCX) const;
/// \brief Solve the linear system(s) AX=B, using the result of
/// the LU factorization computed by GETRF (above).
void
GETRS (const char TRANS, const int N, const int NRHS,
const __float128 A[], const int LDA, const int IPIV[],
__float128 B[], const int LDB, int* INFO) const;
/// \brief Compute the inverse in place of the matrix A, using the
/// results of GETRF.
void
GETRI (const int N, __float128 A[], const int LDA, int IPIV[],
__float128 WORK[], const int LWORK, int* INFO) const;
/// \brief Compute the hypotenuse \f$\sqrt{x^2 + y^2}\f$ in a way
/// that avoids unjustified overflow.
__float128
LAPY2 (const __float128& x, const __float128& y) const;
//! Compute the Householder reflector of [alpha; x].
void
LARFG (const int N, __float128* const ALPHA,
__float128 X[], const int INCX, __float128* const TAU) const;
//! Apply the Householder reflector [tau; v] to the matrix C.
void
LARF (const char side,
const int m,
const int n,
const __float128 v[],
const int incv,
const __float128 tau,
__float128 C[],
const int ldc,
__float128 work[]) const;
//! BLAS 2 version of ORMQR; known workspace size.
void
ORM2R (const char side, const char trans,
const int m, const int n, const int k,
const __float128 A[], const int lda,
const __float128* const tau,
__float128 C[], const int ldc,
__float128 work[], int* const info) const;
//! BLAS 2 QR factorization of A.
void
GEQR2 (const int M,
const int N,
__float128 A[],
const int LDA,
__float128 TAU[],
__float128 WORK[],
int* const INFO) const;
//! QR factorization of A.
void
GEQRF (const int M,
const int N,
__float128 A[],
const int LDA,
__float128 TAU[],
__float128 WORK[],
const int LWORK,
int* const INFO) const;
//! Assemble explicit Q factor from results of GEQRF (above).
void
ORGQR (const int M,
const int N,
const int K,
__float128 A[],
const int LDA,
const __float128 TAU[],
__float128 WORK[],
const int LWORK,
int* const INFO) const;
//! Assemble explicit Q factor from results of GEQRF (above).
void
UNGQR (const int M,
const int N,
const int K,
__float128 A[],
const int LDA,
const __float128 TAU[],
__float128 WORK[],
const int LWORK,
int* const INFO) const;
//! Scale the matrix A by the real scalar cto/cfrom.
void
LASCL (const char TYPE,
const int kl,
const int ku,
const __float128 cfrom,
const __float128 cto,
const int m,
const int n,
__float128* A,
const int lda,
int* info) const;
//! Compute LU factorization of the banded matrix A.
void
GBTRF (const int m,
const int n,
const int kl,
const int ku,
__float128* A,
const int lda,
int* IPIV,
int* info) const;
//! Solve linear system(s) using results of GBTRF (above).
void
GBTRS (const char TRANS,
const int n,
const int kl,
const int ku,
const int nrhs,
const __float128* A,
const int lda,
const int* IPIV,
__float128* B,
const int ldb,
int* info) const;
};
} // namespace Details
} // namespace Teuchos
#endif // HAVE_TEUCHOSCORE_QUADMATH
#endif // TEUCHOS_DETAILS_LAPACK128_HPP
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