df/df9/cgtt05_8f_source.html

*> \brief \b CGTT05

*

*  =========== DOCUMENTATION ===========

*

* Online html documentation available at

*            http://www.netlib.org/lapack/explore-html/

*

*  Definition:

*  ===========

*

*       SUBROUTINE CGTT05( TRANS, N, NRHS, DL, D, DU, B, LDB, X, LDX,

*                          XACT, LDXACT, FERR, BERR, RESLTS )

*

*       .. Scalar Arguments ..

*       CHARACTER          TRANS

*       INTEGER            LDB, LDX, LDXACT, N, NRHS

*       ..

*       .. Array Arguments ..

*       REAL               BERR( * ), FERR( * ), RESLTS( * )

*       COMPLEX            B( LDB, * ), D( * ), DL( * ), DU( * ),

*      $                   X( LDX, * ), XACT( LDXACT, * )

*       ..

*

*

*> \par Purpose:

*  =============

*>

*> \verbatim

*>

*> CGTT05 tests the error bounds from iterative refinement for the

*> computed solution to a system of equations A*X = B, where A is a

*> general tridiagonal matrix of order n and op(A) = A or A**T,

*> depending on TRANS.

*>

*> RESLTS(1) = test of the error bound

*>           = norm(X - XACT) / ( norm(X) * FERR )

*>

*> A large value is returned if this ratio is not less than one.

*>

*> RESLTS(2) = residual from the iterative refinement routine

*>           = the maximum of BERR / ( NZ*EPS + (*) ), where

*>             (*) = NZ*UNFL / (min_i (abs(op(A))*abs(X) +abs(b))_i )

*>             and NZ = max. number of nonzeros in any row of A, plus 1

*> \endverbatim

*

*  Arguments:

*  ==========

*

*> \param[in] TRANS

*> \verbatim

*>          TRANS is CHARACTER*1

*>          Specifies the form of the system of equations.

*>          = 'N':  A * X = B     (No transpose)

*>          = 'T':  A**T * X = B  (Transpose)

*>          = 'C':  A**H * X = B  (Conjugate transpose = Transpose)

*> \endverbatim

*>

*> \param[in] N

*> \verbatim

*>          N is INTEGER

*>          The number of rows of the matrices X and XACT.  N >= 0.

*> \endverbatim

*>

*> \param[in] NRHS

*> \verbatim

*>          NRHS is INTEGER

*>          The number of columns of the matrices X and XACT.  NRHS >= 0.

*> \endverbatim

*>

*> \param[in] DL

*> \verbatim

*>          DL is COMPLEX array, dimension (N-1)

*>          The (n-1) sub-diagonal elements of A.

*> \endverbatim

*>

*> \param[in] D

*> \verbatim

*>          D is COMPLEX array, dimension (N)

*>          The diagonal elements of A.

*> \endverbatim

*>

*> \param[in] DU

*> \verbatim

*>          DU is COMPLEX array, dimension (N-1)

*>          The (n-1) super-diagonal elements of A.

*> \endverbatim

*>

*> \param[in] B

*> \verbatim

*>          B is COMPLEX array, dimension (LDB,NRHS)

*>          The right hand side vectors for the system of linear

*>          equations.

*> \endverbatim

*>

*> \param[in] LDB

*> \verbatim

*>          LDB is INTEGER

*>          The leading dimension of the array B.  LDB >= max(1,N).

*> \endverbatim

*>

*> \param[in] X

*> \verbatim

*>          X is COMPLEX array, dimension (LDX,NRHS)

*>          The computed solution vectors.  Each vector is stored as a

*>          column of the matrix X.

*> \endverbatim

*>

*> \param[in] LDX

*> \verbatim

*>          LDX is INTEGER

*>          The leading dimension of the array X.  LDX >= max(1,N).

*> \endverbatim

*>

*> \param[in] XACT

*> \verbatim

*>          XACT is COMPLEX array, dimension (LDX,NRHS)

*>          The exact solution vectors.  Each vector is stored as a

*>          column of the matrix XACT.

*> \endverbatim

*>

*> \param[in] LDXACT

*> \verbatim

*>          LDXACT is INTEGER

*>          The leading dimension of the array XACT.  LDXACT >= max(1,N).

*> \endverbatim

*>

*> \param[in] FERR

*> \verbatim

*>          FERR is REAL array, dimension (NRHS)

*>          The estimated forward error bounds for each solution vector

*>          X.  If XTRUE is the true solution, FERR bounds the magnitude

*>          of the largest entry in (X - XTRUE) divided by the magnitude

*>          of the largest entry in X.

*> \endverbatim

*>

*> \param[in] BERR

*> \verbatim

*>          BERR is REAL array, dimension (NRHS)

*>          The componentwise relative backward error of each solution

*>          vector (i.e., the smallest relative change in any entry of A

*>          or B that makes X an exact solution).

*> \endverbatim

*>

*> \param[out] RESLTS

*> \verbatim

*>          RESLTS is REAL array, dimension (2)

*>          The maximum over the NRHS solution vectors of the ratios:

*>          RESLTS(1) = norm(X - XACT) / ( norm(X) * FERR )

*>          RESLTS(2) = BERR / ( NZ*EPS + (*) )

*> \endverbatim

*

*  Authors:

*  ========

*

*> \author Univ. of Tennessee

*> \author Univ. of California Berkeley

*> \author Univ. of Colorado Denver

*> \author NAG Ltd.

*

*> \date November 2011

*

*> \ingroup complex_lin

*

*  =====================================================================

      SUBROUTINE cgtt05( TRANS, N, NRHS, DL, D, DU, B, LDB, X, LDX,

     $                   xact, ldxact, ferr, berr, reslts )

*

*  -- LAPACK test routine (version 3.4.0) --

*  -- LAPACK is a software package provided by Univ. of Tennessee,    --

*  -- Univ. of California Berkeley, Univ. of Colorado Denver and NAG Ltd..--

*     November 2011

*

*     .. Scalar Arguments ..

      CHARACTER          trans

      INTEGER            ldb, ldx, ldxact, n, nrhs

*     ..

*     .. Array Arguments ..

      REAL               berr( * ), ferr( * ), reslts( * )

      COMPLEX            b( ldb, * ), d( * ), dl( * ), du( * ),

     $                   x( ldx, * ), xact( ldxact, * )

*     ..

*

*  =====================================================================

*

*     .. Parameters ..

      REAL               zero, one

      parameter( zero = 0.0e+0, one = 1.0e+0 )

*     ..

*     .. Local Scalars ..

      LOGICAL            notran

      INTEGER            i, imax, j, k, nz

      REAL               axbi, diff, eps, errbnd, ovfl, tmp, unfl, xnorm

      COMPLEX            zdum

*     ..

*     .. External Functions ..

      LOGICAL            lsame

      INTEGER            icamax

      REAL               slamch

      EXTERNAL           lsame, icamax, slamch

*     ..

*     .. Intrinsic Functions ..

      INTRINSIC          abs, aimag, max, min, real

*     ..

*     .. Statement Functions ..

      REAL               cabs1

*     ..

*     .. Statement Function definitions ..

      cabs1( zdum ) = abs( REAL( ZDUM ) ) + abs( aimag( zdum ) )

*     ..

*     .. Executable Statements ..

*

*     Quick exit if N = 0 or NRHS = 0.

*

      IF( n.LE.0 .OR. nrhs.LE.0 ) THEN

         reslts( 1 ) = zero

         reslts( 2 ) = zero

         return

      END IF

*

      eps = slamch( 'Epsilon' )

      unfl = slamch( 'Safe minimum' )

      ovfl = one / unfl

      notran = lsame( trans, 'N' )

      nz = 4

*

*     Test 1:  Compute the maximum of

*        norm(X - XACT) / ( norm(X) * FERR )

*     over all the vectors X and XACT using the infinity-norm.

*

      errbnd = zero

      DO 30 j = 1, nrhs

         imax = icamax( n, x( 1, j ), 1 )

         xnorm = max( cabs1( x( imax, j ) ), unfl )

         diff = zero

         DO 10 i = 1, n

            diff = max( diff, cabs1( x( i, j )-xact( i, j ) ) )

   10    continue

*

         IF( xnorm.GT.one ) THEN

            go to 20

         ELSE IF( diff.LE.ovfl*xnorm ) THEN

            go to 20

         ELSE

            errbnd = one / eps

            go to 30

         END IF

*

   20    continue

         IF( diff / xnorm.LE.ferr( j ) ) THEN

            errbnd = max( errbnd, ( diff / xnorm ) / ferr( j ) )

         ELSE

            errbnd = one / eps

         END IF

   30 continue

      reslts( 1 ) = errbnd

*

*     Test 2:  Compute the maximum of BERR / ( NZ*EPS + (*) ), where

*     (*) = NZ*UNFL / (min_i (abs(op(A))*abs(X) +abs(b))_i )

*

      DO 60 k = 1, nrhs

         IF( notran ) THEN

            IF( n.EQ.1 ) THEN

               axbi = cabs1( b( 1, k ) ) +

     $                cabs1( d( 1 ) )*cabs1( x( 1, k ) )

            ELSE

               axbi = cabs1( b( 1, k ) ) +

     $                cabs1( d( 1 ) )*cabs1( x( 1, k ) ) +

     $                cabs1( du( 1 ) )*cabs1( x( 2, k ) )

               DO 40 i = 2, n - 1

                  tmp = cabs1( b( i, k ) ) +

     $                  cabs1( dl( i-1 ) )*cabs1( x( i-1, k ) ) +

     $                  cabs1( d( i ) )*cabs1( x( i, k ) ) +

     $                  cabs1( du( i ) )*cabs1( x( i+1, k ) )

                  axbi = min( axbi, tmp )

   40          continue

               tmp = cabs1( b( n, k ) ) + cabs1( dl( n-1 ) )*

     $               cabs1( x( n-1, k ) ) + cabs1( d( n ) )*

     $               cabs1( x( n, k ) )

               axbi = min( axbi, tmp )

            END IF

         ELSE

            IF( n.EQ.1 ) THEN

               axbi = cabs1( b( 1, k ) ) +

     $                cabs1( d( 1 ) )*cabs1( x( 1, k ) )

            ELSE

               axbi = cabs1( b( 1, k ) ) +

     $                cabs1( d( 1 ) )*cabs1( x( 1, k ) ) +

     $                cabs1( dl( 1 ) )*cabs1( x( 2, k ) )

               DO 50 i = 2, n - 1

                  tmp = cabs1( b( i, k ) ) +

     $                  cabs1( du( i-1 ) )*cabs1( x( i-1, k ) ) +

     $                  cabs1( d( i ) )*cabs1( x( i, k ) ) +

     $                  cabs1( dl( i ) )*cabs1( x( i+1, k ) )

                  axbi = min( axbi, tmp )

   50          continue

               tmp = cabs1( b( n, k ) ) + cabs1( du( n-1 ) )*

     $               cabs1( x( n-1, k ) ) + cabs1( d( n ) )*

     $               cabs1( x( n, k ) )

               axbi = min( axbi, tmp )

            END IF

         END IF

         tmp = berr( k ) / ( nz*eps+nz*unfl / max( axbi, nz*unfl ) )

         IF( k.EQ.1 ) THEN

            reslts( 2 ) = tmp

         ELSE

            reslts( 2 ) = max( reslts( 2 ), tmp )

         END IF

   60 continue

*

      return

*

*     End of CGTT05

*

      END