convert linalg library from Fortran to C++
This commit is contained in:
Axel Kohlmeyer
433
lib/linalg/fortran/dlasr.f
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433
lib/linalg/fortran/dlasr.f
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*> \brief \b DLASR applies a sequence of plane rotations to a general rectangular matrix.
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*
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* =========== DOCUMENTATION ===========
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*
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* Online html documentation available at
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* http://www.netlib.org/lapack/explore-html/
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*
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*> \htmlonly
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*> Download DLASR + dependencies
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*> <a href="http://www.netlib.org/cgi-bin/netlibfiles.tgz?format=tgz&filename=/lapack/lapack_routine/dlasr.f">
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*> [TGZ]</a>
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*> <a href="http://www.netlib.org/cgi-bin/netlibfiles.zip?format=zip&filename=/lapack/lapack_routine/dlasr.f">
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*> [ZIP]</a>
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*> <a href="http://www.netlib.org/cgi-bin/netlibfiles.txt?format=txt&filename=/lapack/lapack_routine/dlasr.f">
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*> [TXT]</a>
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*> \endhtmlonly
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*
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* Definition:
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* ===========
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*
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* SUBROUTINE DLASR( SIDE, PIVOT, DIRECT, M, N, C, S, A, LDA )
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*
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* .. Scalar Arguments ..
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* CHARACTER DIRECT, PIVOT, SIDE
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* INTEGER LDA, M, N
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* ..
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* .. Array Arguments ..
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* DOUBLE PRECISION A( LDA, * ), C( * ), S( * )
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* ..
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*
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*
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*> \par Purpose:
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* =============
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*>
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*> \verbatim
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*>
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*> DLASR applies a sequence of plane rotations to a real matrix A,
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*> from either the left or the right.
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*>
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*> When SIDE = 'L', the transformation takes the form
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*>
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*> A := P*A
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*>
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*> and when SIDE = 'R', the transformation takes the form
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*>
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*> A := A*P**T
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*>
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*> where P is an orthogonal matrix consisting of a sequence of z plane
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*> rotations, with z = M when SIDE = 'L' and z = N when SIDE = 'R',
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*> and P**T is the transpose of P.
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*>
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*> When DIRECT = 'F' (Forward sequence), then
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*>
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*> P = P(z-1) * ... * P(2) * P(1)
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*>
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*> and when DIRECT = 'B' (Backward sequence), then
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*>
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*> P = P(1) * P(2) * ... * P(z-1)
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*>
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*> where P(k) is a plane rotation matrix defined by the 2-by-2 rotation
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*>
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*> R(k) = ( c(k) s(k) )
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*> = ( -s(k) c(k) ).
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*>
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*> When PIVOT = 'V' (Variable pivot), the rotation is performed
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*> for the plane (k,k+1), i.e., P(k) has the form
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*>
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*> P(k) = ( 1 )
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*> ( ... )
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*> ( 1 )
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*> ( c(k) s(k) )
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*> ( -s(k) c(k) )
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*> ( 1 )
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*> ( ... )
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*> ( 1 )
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*>
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*> where R(k) appears as a rank-2 modification to the identity matrix in
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*> rows and columns k and k+1.
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*>
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*> When PIVOT = 'T' (Top pivot), the rotation is performed for the
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*> plane (1,k+1), so P(k) has the form
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*>
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*> P(k) = ( c(k) s(k) )
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*> ( 1 )
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*> ( ... )
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*> ( 1 )
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*> ( -s(k) c(k) )
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*> ( 1 )
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*> ( ... )
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*> ( 1 )
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*>
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*> where R(k) appears in rows and columns 1 and k+1.
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*>
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*> Similarly, when PIVOT = 'B' (Bottom pivot), the rotation is
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*> performed for the plane (k,z), giving P(k) the form
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*>
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*> P(k) = ( 1 )
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*> ( ... )
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*> ( 1 )
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*> ( c(k) s(k) )
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*> ( 1 )
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*> ( ... )
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*> ( 1 )
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*> ( -s(k) c(k) )
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*>
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*> where R(k) appears in rows and columns k and z. The rotations are
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*> performed without ever forming P(k) explicitly.
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*> \endverbatim
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*
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* Arguments:
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* ==========
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*
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*> \param[in] SIDE
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*> \verbatim
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*> SIDE is CHARACTER*1
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*> Specifies whether the plane rotation matrix P is applied to
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*> A on the left or the right.
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*> = 'L': Left, compute A := P*A
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*> = 'R': Right, compute A:= A*P**T
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*> \endverbatim
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*>
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*> \param[in] PIVOT
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*> \verbatim
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*> PIVOT is CHARACTER*1
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*> Specifies the plane for which P(k) is a plane rotation
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*> matrix.
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*> = 'V': Variable pivot, the plane (k,k+1)
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*> = 'T': Top pivot, the plane (1,k+1)
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*> = 'B': Bottom pivot, the plane (k,z)
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*> \endverbatim
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*>
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*> \param[in] DIRECT
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*> \verbatim
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*> DIRECT is CHARACTER*1
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*> Specifies whether P is a forward or backward sequence of
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*> plane rotations.
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*> = 'F': Forward, P = P(z-1)*...*P(2)*P(1)
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*> = 'B': Backward, P = P(1)*P(2)*...*P(z-1)
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*> \endverbatim
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*>
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*> \param[in] M
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*> \verbatim
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*> M is INTEGER
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*> The number of rows of the matrix A. If m <= 1, an immediate
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*> return is effected.
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*> \endverbatim
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*>
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*> \param[in] N
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*> \verbatim
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*> N is INTEGER
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*> The number of columns of the matrix A. If n <= 1, an
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*> immediate return is effected.
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*> \endverbatim
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*>
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*> \param[in] C
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*> \verbatim
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*> C is DOUBLE PRECISION array, dimension
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*> (M-1) if SIDE = 'L'
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*> (N-1) if SIDE = 'R'
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*> The cosines c(k) of the plane rotations.
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*> \endverbatim
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*>
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*> \param[in] S
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*> \verbatim
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*> S is DOUBLE PRECISION array, dimension
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*> (M-1) if SIDE = 'L'
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*> (N-1) if SIDE = 'R'
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*> The sines s(k) of the plane rotations. The 2-by-2 plane
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*> rotation part of the matrix P(k), R(k), has the form
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*> R(k) = ( c(k) s(k) )
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*> ( -s(k) c(k) ).
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*> \endverbatim
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*>
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*> \param[in,out] A
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*> \verbatim
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*> A is DOUBLE PRECISION array, dimension (LDA,N)
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*> The M-by-N matrix A. On exit, A is overwritten by P*A if
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*> SIDE = 'L' or by A*P**T if SIDE = 'R'.
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*> \endverbatim
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*>
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*> \param[in] LDA
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*> \verbatim
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*> LDA is INTEGER
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*> The leading dimension of the array A. LDA >= max(1,M).
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*> \endverbatim
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*
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* Authors:
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* ========
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*
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*> \author Univ. of Tennessee
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*> \author Univ. of California Berkeley
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*> \author Univ. of Colorado Denver
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*> \author NAG Ltd.
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*
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*> \ingroup OTHERauxiliary
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*
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* =====================================================================
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SUBROUTINE DLASR( SIDE, PIVOT, DIRECT, M, N, C, S, A, LDA )
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*
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* -- LAPACK auxiliary routine --
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* -- LAPACK is a software package provided by Univ. of Tennessee, --
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* -- Univ. of California Berkeley, Univ. of Colorado Denver and NAG Ltd..--
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*
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* .. Scalar Arguments ..
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CHARACTER DIRECT, PIVOT, SIDE
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INTEGER LDA, M, N
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* ..
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* .. Array Arguments ..
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DOUBLE PRECISION A( LDA, * ), C( * ), S( * )
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* ..
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*
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* =====================================================================
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*
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* .. Parameters ..
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DOUBLE PRECISION ONE, ZERO
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PARAMETER ( ONE = 1.0D+0, ZERO = 0.0D+0 )
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* ..
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* .. Local Scalars ..
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INTEGER I, INFO, J
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DOUBLE PRECISION CTEMP, STEMP, TEMP
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* ..
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* .. External Functions ..
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LOGICAL LSAME
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EXTERNAL LSAME
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* ..
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* .. External Subroutines ..
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EXTERNAL XERBLA
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* ..
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* .. Intrinsic Functions ..
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INTRINSIC MAX
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* ..
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* .. Executable Statements ..
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*
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* Test the input parameters
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*
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INFO = 0
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IF( .NOT.( LSAME( SIDE, 'L' ) .OR. LSAME( SIDE, 'R' ) ) ) THEN
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INFO = 1
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ELSE IF( .NOT.( LSAME( PIVOT, 'V' ) .OR. LSAME( PIVOT,
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$ 'T' ) .OR. LSAME( PIVOT, 'B' ) ) ) THEN
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INFO = 2
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ELSE IF( .NOT.( LSAME( DIRECT, 'F' ) .OR. LSAME( DIRECT, 'B' ) ) )
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$ THEN
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INFO = 3
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ELSE IF( M.LT.0 ) THEN
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INFO = 4
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ELSE IF( N.LT.0 ) THEN
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INFO = 5
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ELSE IF( LDA.LT.MAX( 1, M ) ) THEN
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INFO = 9
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END IF
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IF( INFO.NE.0 ) THEN
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CALL XERBLA( 'DLASR ', INFO )
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RETURN
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END IF
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*
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* Quick return if possible
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*
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IF( ( M.EQ.0 ) .OR. ( N.EQ.0 ) )
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$ RETURN
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IF( LSAME( SIDE, 'L' ) ) THEN
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*
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* Form P * A
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*
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IF( LSAME( PIVOT, 'V' ) ) THEN
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IF( LSAME( DIRECT, 'F' ) ) THEN
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DO 20 J = 1, M - 1
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CTEMP = C( J )
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STEMP = S( J )
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IF( ( CTEMP.NE.ONE ) .OR. ( STEMP.NE.ZERO ) ) THEN
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DO 10 I = 1, N
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TEMP = A( J+1, I )
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A( J+1, I ) = CTEMP*TEMP - STEMP*A( J, I )
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A( J, I ) = STEMP*TEMP + CTEMP*A( J, I )
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10 CONTINUE
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END IF
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20 CONTINUE
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ELSE IF( LSAME( DIRECT, 'B' ) ) THEN
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DO 40 J = M - 1, 1, -1
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CTEMP = C( J )
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STEMP = S( J )
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IF( ( CTEMP.NE.ONE ) .OR. ( STEMP.NE.ZERO ) ) THEN
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DO 30 I = 1, N
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TEMP = A( J+1, I )
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A( J+1, I ) = CTEMP*TEMP - STEMP*A( J, I )
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A( J, I ) = STEMP*TEMP + CTEMP*A( J, I )
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30 CONTINUE
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END IF
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40 CONTINUE
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END IF
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ELSE IF( LSAME( PIVOT, 'T' ) ) THEN
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IF( LSAME( DIRECT, 'F' ) ) THEN
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DO 60 J = 2, M
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CTEMP = C( J-1 )
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STEMP = S( J-1 )
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IF( ( CTEMP.NE.ONE ) .OR. ( STEMP.NE.ZERO ) ) THEN
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DO 50 I = 1, N
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TEMP = A( J, I )
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A( J, I ) = CTEMP*TEMP - STEMP*A( 1, I )
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A( 1, I ) = STEMP*TEMP + CTEMP*A( 1, I )
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50 CONTINUE
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END IF
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60 CONTINUE
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ELSE IF( LSAME( DIRECT, 'B' ) ) THEN
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DO 80 J = M, 2, -1
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CTEMP = C( J-1 )
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STEMP = S( J-1 )
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IF( ( CTEMP.NE.ONE ) .OR. ( STEMP.NE.ZERO ) ) THEN
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DO 70 I = 1, N
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TEMP = A( J, I )
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A( J, I ) = CTEMP*TEMP - STEMP*A( 1, I )
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A( 1, I ) = STEMP*TEMP + CTEMP*A( 1, I )
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70 CONTINUE
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END IF
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80 CONTINUE
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END IF
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ELSE IF( LSAME( PIVOT, 'B' ) ) THEN
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IF( LSAME( DIRECT, 'F' ) ) THEN
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DO 100 J = 1, M - 1
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CTEMP = C( J )
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STEMP = S( J )
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IF( ( CTEMP.NE.ONE ) .OR. ( STEMP.NE.ZERO ) ) THEN
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DO 90 I = 1, N
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TEMP = A( J, I )
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A( J, I ) = STEMP*A( M, I ) + CTEMP*TEMP
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A( M, I ) = CTEMP*A( M, I ) - STEMP*TEMP
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90 CONTINUE
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END IF
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100 CONTINUE
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ELSE IF( LSAME( DIRECT, 'B' ) ) THEN
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DO 120 J = M - 1, 1, -1
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CTEMP = C( J )
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STEMP = S( J )
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IF( ( CTEMP.NE.ONE ) .OR. ( STEMP.NE.ZERO ) ) THEN
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DO 110 I = 1, N
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TEMP = A( J, I )
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A( J, I ) = STEMP*A( M, I ) + CTEMP*TEMP
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A( M, I ) = CTEMP*A( M, I ) - STEMP*TEMP
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110 CONTINUE
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END IF
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120 CONTINUE
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END IF
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END IF
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ELSE IF( LSAME( SIDE, 'R' ) ) THEN
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*
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* Form A * P**T
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*
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IF( LSAME( PIVOT, 'V' ) ) THEN
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IF( LSAME( DIRECT, 'F' ) ) THEN
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DO 140 J = 1, N - 1
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CTEMP = C( J )
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STEMP = S( J )
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IF( ( CTEMP.NE.ONE ) .OR. ( STEMP.NE.ZERO ) ) THEN
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DO 130 I = 1, M
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TEMP = A( I, J+1 )
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A( I, J+1 ) = CTEMP*TEMP - STEMP*A( I, J )
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A( I, J ) = STEMP*TEMP + CTEMP*A( I, J )
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130 CONTINUE
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END IF
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140 CONTINUE
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ELSE IF( LSAME( DIRECT, 'B' ) ) THEN
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DO 160 J = N - 1, 1, -1
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CTEMP = C( J )
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STEMP = S( J )
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IF( ( CTEMP.NE.ONE ) .OR. ( STEMP.NE.ZERO ) ) THEN
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DO 150 I = 1, M
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TEMP = A( I, J+1 )
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A( I, J+1 ) = CTEMP*TEMP - STEMP*A( I, J )
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A( I, J ) = STEMP*TEMP + CTEMP*A( I, J )
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150 CONTINUE
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END IF
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160 CONTINUE
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END IF
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ELSE IF( LSAME( PIVOT, 'T' ) ) THEN
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IF( LSAME( DIRECT, 'F' ) ) THEN
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DO 180 J = 2, N
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CTEMP = C( J-1 )
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STEMP = S( J-1 )
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IF( ( CTEMP.NE.ONE ) .OR. ( STEMP.NE.ZERO ) ) THEN
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DO 170 I = 1, M
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TEMP = A( I, J )
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A( I, J ) = CTEMP*TEMP - STEMP*A( I, 1 )
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A( I, 1 ) = STEMP*TEMP + CTEMP*A( I, 1 )
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170 CONTINUE
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END IF
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180 CONTINUE
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ELSE IF( LSAME( DIRECT, 'B' ) ) THEN
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DO 200 J = N, 2, -1
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CTEMP = C( J-1 )
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STEMP = S( J-1 )
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IF( ( CTEMP.NE.ONE ) .OR. ( STEMP.NE.ZERO ) ) THEN
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DO 190 I = 1, M
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TEMP = A( I, J )
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A( I, J ) = CTEMP*TEMP - STEMP*A( I, 1 )
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A( I, 1 ) = STEMP*TEMP + CTEMP*A( I, 1 )
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190 CONTINUE
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END IF
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200 CONTINUE
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END IF
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ELSE IF( LSAME( PIVOT, 'B' ) ) THEN
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IF( LSAME( DIRECT, 'F' ) ) THEN
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DO 220 J = 1, N - 1
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CTEMP = C( J )
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STEMP = S( J )
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IF( ( CTEMP.NE.ONE ) .OR. ( STEMP.NE.ZERO ) ) THEN
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DO 210 I = 1, M
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TEMP = A( I, J )
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A( I, J ) = STEMP*A( I, N ) + CTEMP*TEMP
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A( I, N ) = CTEMP*A( I, N ) - STEMP*TEMP
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210 CONTINUE
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END IF
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220 CONTINUE
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ELSE IF( LSAME( DIRECT, 'B' ) ) THEN
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DO 240 J = N - 1, 1, -1
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CTEMP = C( J )
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STEMP = S( J )
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IF( ( CTEMP.NE.ONE ) .OR. ( STEMP.NE.ZERO ) ) THEN
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DO 230 I = 1, M
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TEMP = A( I, J )
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A( I, J ) = STEMP*A( I, N ) + CTEMP*TEMP
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A( I, N ) = CTEMP*A( I, N ) - STEMP*TEMP
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230 CONTINUE
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END IF
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240 CONTINUE
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END IF
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END IF
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END IF
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*
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RETURN
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*
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* End of DLASR
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*
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END
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