tahoma2d/thirdparty/openblas/xianyi-OpenBLAS-e6e87a2/reference/ssbmvf.f

      SUBROUTINE SSBMVF( UPLO, N, K, ALPHA, A, LDA, X, INCX,
     $                   BETA, Y, INCY )
*     .. Scalar Arguments ..
      REAL               ALPHA, BETA
      INTEGER            INCX, INCY, K, LDA, N
      CHARACTER*1        UPLO
*     .. Array Arguments ..
      REAL               A( LDA, * ), X( * ), Y( * )
*     ..
*
*  Purpose
*  =======
*
*  SSBMV  performs the matrix-vector  operation
*
*     y := alpha*A*x + beta*y,
*
*  where alpha and beta are scalars, x and y are n element vectors and
*  A is an n by n symmetric band matrix, with k super-diagonals.
*
*  Parameters
*  ==========
*
*  UPLO   - CHARACTER*1.
*           On entry, UPLO specifies whether the upper or lower
*           triangular part of the band matrix A is being supplied as
*           follows:
*
*              UPLO = 'U' or 'u'   The upper triangular part of A is
*                                  being supplied.
*
*              UPLO = 'L' or 'l'   The lower triangular part of A is
*                                  being supplied.
*
*           Unchanged on exit.
*
*  N      - INTEGER.
*           On entry, N specifies the order of the matrix A.
*           N must be at least zero.
*           Unchanged on exit.
*
*  K      - INTEGER.
*           On entry, K specifies the number of super-diagonals of the
*           matrix A. K must satisfy  0 .le. K.
*           Unchanged on exit.
*
*  ALPHA  - REAL            .
*           On entry, ALPHA specifies the scalar alpha.
*           Unchanged on exit.
*
*  A      - REAL             array of DIMENSION ( LDA, n ).
*           Before entry with UPLO = 'U' or 'u', the leading ( k + 1 )
*           by n part of the array A must contain the upper triangular
*           band part of the symmetric matrix, supplied column by
*           column, with the leading diagonal of the matrix in row
*           ( k + 1 ) of the array, the first super-diagonal starting at
*           position 2 in row k, and so on. The top left k by k triangle
*           of the array A is not referenced.
*           The following program segment will transfer the upper
*           triangular part of a symmetric band matrix from conventional
*           full matrix storage to band storage:
*
*                 DO 20, J = 1, N
*                    M = K + 1 - J
*                    DO 10, I = MAX( 1, J - K ), J
*                       A( M + I, J ) = matrix( I, J )
*              10    CONTINUE
*              20 CONTINUE
*
*           Before entry with UPLO = 'L' or 'l', the leading ( k + 1 )
*           by n part of the array A must contain the lower triangular
*           band part of the symmetric matrix, supplied column by
*           column, with the leading diagonal of the matrix in row 1 of
*           the array, the first sub-diagonal starting at position 1 in
*           row 2, and so on. The bottom right k by k triangle of the
*           array A is not referenced.
*           The following program segment will transfer the lower
*           triangular part of a symmetric band matrix from conventional
*           full matrix storage to band storage:
*
*                 DO 20, J = 1, N
*                    M = 1 - J
*                    DO 10, I = J, MIN( N, J + K )
*                       A( M + I, J ) = matrix( I, J )
*              10    CONTINUE
*              20 CONTINUE
*
*           Unchanged on exit.
*
*  LDA    - INTEGER.
*           On entry, LDA specifies the first dimension of A as declared
*           in the calling (sub) program. LDA must be at least
*           ( k + 1 ).
*           Unchanged on exit.
*
*  X      - REAL             array of DIMENSION at least
*           ( 1 + ( n - 1 )*abs( INCX ) ).
*           Before entry, the incremented array X must contain the
*           vector x.
*           Unchanged on exit.
*
*  INCX   - INTEGER.
*           On entry, INCX specifies the increment for the elements of
*           X. INCX must not be zero.
*           Unchanged on exit.
*
*  BETA   - REAL            .
*           On entry, BETA specifies the scalar beta.
*           Unchanged on exit.
*
*  Y      - REAL             array of DIMENSION at least
*           ( 1 + ( n - 1 )*abs( INCY ) ).
*           Before entry, the incremented array Y must contain the
*           vector y. On exit, Y is overwritten by the updated vector y.
*
*  INCY   - INTEGER.
*           On entry, INCY specifies the increment for the elements of
*           Y. INCY must not be zero.
*           Unchanged on exit.
*
*
*  Level 2 Blas routine.
*
*  -- Written on 22-October-1986.
*     Jack Dongarra, Argonne National Lab.
*     Jeremy Du Croz, Nag Central Office.
*     Sven Hammarling, Nag Central Office.
*     Richard Hanson, Sandia National Labs.
*
*
*     .. Parameters ..
      REAL               ONE         , ZERO
      PARAMETER        ( ONE = 1.0E+0, ZERO = 0.0E+0 )
*     .. Local Scalars ..
      REAL               TEMP1, TEMP2
      INTEGER            I, INFO, IX, IY, J, JX, JY, KPLUS1, KX, KY, L
*     .. External Functions ..
      LOGICAL            LSAME
      EXTERNAL           LSAME
*     .. External Subroutines ..
      EXTERNAL           XERBLA
*     .. Intrinsic Functions ..
      INTRINSIC          MAX, MIN
*     ..
*     .. Executable Statements ..
*
*     Test the input parameters.
*
      INFO = 0
      IF     ( .NOT.LSAME( UPLO, 'U' ).AND.
     $         .NOT.LSAME( UPLO, 'L' )      )THEN
         INFO = 1
      ELSE IF( N.LT.0 )THEN
         INFO = 2
      ELSE IF( K.LT.0 )THEN
         INFO = 3
      ELSE IF( LDA.LT.( K + 1 ) )THEN
         INFO = 6
      ELSE IF( INCX.EQ.0 )THEN
         INFO = 8
      ELSE IF( INCY.EQ.0 )THEN
         INFO = 11
      END IF
      IF( INFO.NE.0 )THEN
         CALL XERBLA( 'SSBMV ', INFO )
         RETURN
      END IF
*
*     Quick return if possible.
*
      IF( ( N.EQ.0 ).OR.( ( ALPHA.EQ.ZERO ).AND.( BETA.EQ.ONE ) ) )
     $   RETURN
*
*     Set up the start points in  X  and  Y.
*
      IF( INCX.GT.0 )THEN
         KX = 1
      ELSE
         KX = 1 - ( N - 1 )*INCX
      END IF
      IF( INCY.GT.0 )THEN
         KY = 1
      ELSE
         KY = 1 - ( N - 1 )*INCY
      END IF
*
*     Start the operations. In this version the elements of the array A
*     are accessed sequentially with one pass through A.
*
*     First form  y := beta*y.
*
      IF( BETA.NE.ONE )THEN
         IF( INCY.EQ.1 )THEN
            IF( BETA.EQ.ZERO )THEN
               DO 10, I = 1, N
                  Y( I ) = ZERO
   10          CONTINUE
            ELSE
               DO 20, I = 1, N
                  Y( I ) = BETA*Y( I )
   20          CONTINUE
            END IF
         ELSE
            IY = KY
            IF( BETA.EQ.ZERO )THEN
               DO 30, I = 1, N
                  Y( IY ) = ZERO
                  IY      = IY   + INCY
   30          CONTINUE
            ELSE
               DO 40, I = 1, N
                  Y( IY ) = BETA*Y( IY )
                  IY      = IY           + INCY
   40          CONTINUE
            END IF
         END IF
      END IF
      IF( ALPHA.EQ.ZERO )
     $   RETURN
      IF( LSAME( UPLO, 'U' ) )THEN
*
*        Form  y  when upper triangle of A is stored.
*
         KPLUS1 = K + 1
         IF( ( INCX.EQ.1 ).AND.( INCY.EQ.1 ) )THEN
            DO 60, J = 1, N
               TEMP1 = ALPHA*X( J )
               TEMP2 = ZERO
               L     = KPLUS1 - J
               DO 50, I = MAX( 1, J - K ), J - 1
                  Y( I ) = Y( I ) + TEMP1*A( L + I, J )
                  TEMP2  = TEMP2  + A( L + I, J )*X( I )
   50          CONTINUE
               Y( J ) = Y( J ) + TEMP1*A( KPLUS1, J ) + ALPHA*TEMP2
   60       CONTINUE
         ELSE
            JX = KX
            JY = KY
            DO 80, J = 1, N
               TEMP1 = ALPHA*X( JX )
               TEMP2 = ZERO
               IX    = KX
               IY    = KY
               L     = KPLUS1 - J
               DO 70, I = MAX( 1, J - K ), J - 1
                  Y( IY ) = Y( IY ) + TEMP1*A( L + I, J )
                  TEMP2   = TEMP2   + A( L + I, J )*X( IX )
                  IX      = IX      + INCX
                  IY      = IY      + INCY
   70          CONTINUE
               Y( JY ) = Y( JY ) + TEMP1*A( KPLUS1, J ) + ALPHA*TEMP2
               JX      = JX      + INCX
               JY      = JY      + INCY
               IF( J.GT.K )THEN
                  KX = KX + INCX
                  KY = KY + INCY
               END IF
   80       CONTINUE
         END IF
      ELSE
*
*        Form  y  when lower triangle of A is stored.
*
         IF( ( INCX.EQ.1 ).AND.( INCY.EQ.1 ) )THEN
            DO 100, J = 1, N
               TEMP1  = ALPHA*X( J )
               TEMP2  = ZERO
               Y( J ) = Y( J )       + TEMP1*A( 1, J )
               L      = 1            - J
               DO 90, I = J + 1, MIN( N, J + K )
                  Y( I ) = Y( I ) + TEMP1*A( L + I, J )
                  TEMP2  = TEMP2  + A( L + I, J )*X( I )
   90          CONTINUE
               Y( J ) = Y( J ) + ALPHA*TEMP2
  100       CONTINUE
         ELSE
            JX = KX
            JY = KY
            DO 120, J = 1, N
               TEMP1   = ALPHA*X( JX )
               TEMP2   = ZERO
               Y( JY ) = Y( JY )       + TEMP1*A( 1, J )
               L       = 1             - J
               IX      = JX
               IY      = JY
               DO 110, I = J + 1, MIN( N, J + K )
                  IX      = IX      + INCX
                  IY      = IY      + INCY
                  Y( IY ) = Y( IY ) + TEMP1*A( L + I, J )
                  TEMP2   = TEMP2   + A( L + I, J )*X( IX )
  110          CONTINUE
               Y( JY ) = Y( JY ) + ALPHA*TEMP2
               JX      = JX      + INCX
               JY      = JY      + INCY
  120       CONTINUE
         END IF
      END IF
*
      RETURN
*
*     End of SSBMV .
*
      END
Add OpenBLAS 2016-03-24 06:47:04 +13:00			`SUBROUTINE SSBMVF( UPLO, N, K, ALPHA, A, LDA, X, INCX,`
			`$ BETA, Y, INCY )`
			`* .. Scalar Arguments ..`
			`REAL ALPHA, BETA`
			`INTEGER INCX, INCY, K, LDA, N`
			`CHARACTER*1 UPLO`
			`* .. Array Arguments ..`
			`REAL A( LDA, * ), X( * ), Y( * )`
			`* ..`
			`*`
			`* Purpose`
			`* =======`
			`*`
			`* SSBMV performs the matrix-vector operation`
			`*`
			`* y := alphaAx + beta*y,`
			`*`
			`* where alpha and beta are scalars, x and y are n element vectors and`
			`* A is an n by n symmetric band matrix, with k super-diagonals.`
			`*`
			`* Parameters`
			`* ==========`
			`*`
			`* UPLO - CHARACTER*1.`
			`* On entry, UPLO specifies whether the upper or lower`
			`* triangular part of the band matrix A is being supplied as`
			`* follows:`
			`*`
			`* UPLO = 'U' or 'u' The upper triangular part of A is`
			`* being supplied.`
			`*`
			`* UPLO = 'L' or 'l' The lower triangular part of A is`
			`* being supplied.`
			`*`
			`* Unchanged on exit.`
			`*`
			`* N - INTEGER.`
			`* On entry, N specifies the order of the matrix A.`
			`* N must be at least zero.`
			`* Unchanged on exit.`
			`*`
			`* K - INTEGER.`
			`* On entry, K specifies the number of super-diagonals of the`
			`* matrix A. K must satisfy 0 .le. K.`
			`* Unchanged on exit.`
			`*`
			`* ALPHA - REAL .`
			`* On entry, ALPHA specifies the scalar alpha.`
			`* Unchanged on exit.`
			`*`
			`* A - REAL array of DIMENSION ( LDA, n ).`
			`* Before entry with UPLO = 'U' or 'u', the leading ( k + 1 )`
			`* by n part of the array A must contain the upper triangular`
			`* band part of the symmetric matrix, supplied column by`
			`* column, with the leading diagonal of the matrix in row`
			`* ( k + 1 ) of the array, the first super-diagonal starting at`
			`* position 2 in row k, and so on. The top left k by k triangle`
			`* of the array A is not referenced.`
			`* The following program segment will transfer the upper`
			`* triangular part of a symmetric band matrix from conventional`
			`* full matrix storage to band storage:`
			`*`
			`* DO 20, J = 1, N`
			`* M = K + 1 - J`
			`* DO 10, I = MAX( 1, J - K ), J`
			`* A( M + I, J ) = matrix( I, J )`
			`* 10 CONTINUE`
			`* 20 CONTINUE`
			`*`
			`* Before entry with UPLO = 'L' or 'l', the leading ( k + 1 )`
			`* by n part of the array A must contain the lower triangular`
			`* band part of the symmetric matrix, supplied column by`
			`* column, with the leading diagonal of the matrix in row 1 of`
			`* the array, the first sub-diagonal starting at position 1 in`
			`* row 2, and so on. The bottom right k by k triangle of the`
			`* array A is not referenced.`
			`* The following program segment will transfer the lower`
			`* triangular part of a symmetric band matrix from conventional`
			`* full matrix storage to band storage:`
			`*`
			`* DO 20, J = 1, N`
			`* M = 1 - J`
			`* DO 10, I = J, MIN( N, J + K )`
			`* A( M + I, J ) = matrix( I, J )`
			`* 10 CONTINUE`
			`* 20 CONTINUE`
			`*`
			`* Unchanged on exit.`
			`*`
			`* LDA - INTEGER.`
			`* On entry, LDA specifies the first dimension of A as declared`
			`* in the calling (sub) program. LDA must be at least`
			`* ( k + 1 ).`
			`* Unchanged on exit.`
			`*`
			`* X - REAL array of DIMENSION at least`
			`* ( 1 + ( n - 1 )*abs( INCX ) ).`
			`* Before entry, the incremented array X must contain the`
			`* vector x.`
			`* Unchanged on exit.`
			`*`
			`* INCX - INTEGER.`
			`* On entry, INCX specifies the increment for the elements of`
			`* X. INCX must not be zero.`
			`* Unchanged on exit.`
			`*`
			`* BETA - REAL .`
			`* On entry, BETA specifies the scalar beta.`
			`* Unchanged on exit.`
			`*`
			`* Y - REAL array of DIMENSION at least`
			`* ( 1 + ( n - 1 )*abs( INCY ) ).`
			`* Before entry, the incremented array Y must contain the`
			`* vector y. On exit, Y is overwritten by the updated vector y.`
			`*`
			`* INCY - INTEGER.`
			`* On entry, INCY specifies the increment for the elements of`
			`* Y. INCY must not be zero.`
			`* Unchanged on exit.`
			`*`
			`*`
			`* Level 2 Blas routine.`
			`*`
			`* -- Written on 22-October-1986.`
			`* Jack Dongarra, Argonne National Lab.`
			`* Jeremy Du Croz, Nag Central Office.`
			`* Sven Hammarling, Nag Central Office.`
			`* Richard Hanson, Sandia National Labs.`
			`*`
			`*`
			`* .. Parameters ..`
			`REAL ONE , ZERO`
			`PARAMETER ( ONE = 1.0E+0, ZERO = 0.0E+0 )`
			`* .. Local Scalars ..`
			`REAL TEMP1, TEMP2`
			`INTEGER I, INFO, IX, IY, J, JX, JY, KPLUS1, KX, KY, L`
			`* .. External Functions ..`
			`LOGICAL LSAME`
			`EXTERNAL LSAME`
			`* .. External Subroutines ..`
			`EXTERNAL XERBLA`
			`* .. Intrinsic Functions ..`
			`INTRINSIC MAX, MIN`
			`* ..`
			`* .. Executable Statements ..`
			`*`
			`* Test the input parameters.`
			`*`
			`INFO = 0`
			`IF ( .NOT.LSAME( UPLO, 'U' ).AND.`
			`$ .NOT.LSAME( UPLO, 'L' ) )THEN`
			`INFO = 1`
			`ELSE IF( N.LT.0 )THEN`
			`INFO = 2`
			`ELSE IF( K.LT.0 )THEN`
			`INFO = 3`
			`ELSE IF( LDA.LT.( K + 1 ) )THEN`
			`INFO = 6`
			`ELSE IF( INCX.EQ.0 )THEN`
			`INFO = 8`
			`ELSE IF( INCY.EQ.0 )THEN`
			`INFO = 11`
			`END IF`
			`IF( INFO.NE.0 )THEN`
			`CALL XERBLA( 'SSBMV ', INFO )`
			`RETURN`
			`END IF`
			`*`
			`* Quick return if possible.`
			`*`
			`IF( ( N.EQ.0 ).OR.( ( ALPHA.EQ.ZERO ).AND.( BETA.EQ.ONE ) ) )`
			`$ RETURN`
			`*`
			`* Set up the start points in X and Y.`
			`*`
			`IF( INCX.GT.0 )THEN`
			`KX = 1`
			`ELSE`
			`KX = 1 - ( N - 1 )*INCX`
			`END IF`
			`IF( INCY.GT.0 )THEN`
			`KY = 1`
			`ELSE`
			`KY = 1 - ( N - 1 )*INCY`
			`END IF`
			`*`
			`* Start the operations. In this version the elements of the array A`
			`* are accessed sequentially with one pass through A.`
			`*`
			`* First form y := beta*y.`
			`*`
			`IF( BETA.NE.ONE )THEN`
			`IF( INCY.EQ.1 )THEN`
			`IF( BETA.EQ.ZERO )THEN`
			`DO 10, I = 1, N`
			`Y( I ) = ZERO`
			`10 CONTINUE`
			`ELSE`
			`DO 20, I = 1, N`
			`Y( I ) = BETA*Y( I )`
			`20 CONTINUE`
			`END IF`
			`ELSE`
			`IY = KY`
			`IF( BETA.EQ.ZERO )THEN`
			`DO 30, I = 1, N`
			`Y( IY ) = ZERO`
			`IY = IY + INCY`
			`30 CONTINUE`
			`ELSE`
			`DO 40, I = 1, N`
			`Y( IY ) = BETA*Y( IY )`
			`IY = IY + INCY`
			`40 CONTINUE`
			`END IF`
			`END IF`
			`END IF`
			`IF( ALPHA.EQ.ZERO )`
			`$ RETURN`
			`IF( LSAME( UPLO, 'U' ) )THEN`
			`*`
			`* Form y when upper triangle of A is stored.`
			`*`
			`KPLUS1 = K + 1`
			`IF( ( INCX.EQ.1 ).AND.( INCY.EQ.1 ) )THEN`
			`DO 60, J = 1, N`
			`TEMP1 = ALPHA*X( J )`
			`TEMP2 = ZERO`
			`L = KPLUS1 - J`
			`DO 50, I = MAX( 1, J - K ), J - 1`
			`Y( I ) = Y( I ) + TEMP1*A( L + I, J )`
			`TEMP2 = TEMP2 + A( L + I, J )*X( I )`
			`50 CONTINUE`
			`Y( J ) = Y( J ) + TEMP1A( KPLUS1, J ) + ALPHATEMP2`
			`60 CONTINUE`
			`ELSE`
			`JX = KX`
			`JY = KY`
			`DO 80, J = 1, N`
			`TEMP1 = ALPHA*X( JX )`
			`TEMP2 = ZERO`
			`IX = KX`
			`IY = KY`
			`L = KPLUS1 - J`
			`DO 70, I = MAX( 1, J - K ), J - 1`
			`Y( IY ) = Y( IY ) + TEMP1*A( L + I, J )`
			`TEMP2 = TEMP2 + A( L + I, J )*X( IX )`
			`IX = IX + INCX`
			`IY = IY + INCY`
			`70 CONTINUE`
			`Y( JY ) = Y( JY ) + TEMP1A( KPLUS1, J ) + ALPHATEMP2`
			`JX = JX + INCX`
			`JY = JY + INCY`
			`IF( J.GT.K )THEN`
			`KX = KX + INCX`
			`KY = KY + INCY`
			`END IF`
			`80 CONTINUE`
			`END IF`
			`ELSE`
			`*`
			`* Form y when lower triangle of A is stored.`
			`*`
			`IF( ( INCX.EQ.1 ).AND.( INCY.EQ.1 ) )THEN`
			`DO 100, J = 1, N`
			`TEMP1 = ALPHA*X( J )`
			`TEMP2 = ZERO`
			`Y( J ) = Y( J ) + TEMP1*A( 1, J )`
			`L = 1 - J`
			`DO 90, I = J + 1, MIN( N, J + K )`
			`Y( I ) = Y( I ) + TEMP1*A( L + I, J )`
			`TEMP2 = TEMP2 + A( L + I, J )*X( I )`
			`90 CONTINUE`
			`Y( J ) = Y( J ) + ALPHA*TEMP2`
			`100 CONTINUE`
			`ELSE`
			`JX = KX`
			`JY = KY`
			`DO 120, J = 1, N`
			`TEMP1 = ALPHA*X( JX )`
			`TEMP2 = ZERO`
			`Y( JY ) = Y( JY ) + TEMP1*A( 1, J )`
			`L = 1 - J`
			`IX = JX`
			`IY = JY`
			`DO 110, I = J + 1, MIN( N, J + K )`
			`IX = IX + INCX`
			`IY = IY + INCY`
			`Y( IY ) = Y( IY ) + TEMP1*A( L + I, J )`
			`TEMP2 = TEMP2 + A( L + I, J )*X( IX )`
			`110 CONTINUE`
			`Y( JY ) = Y( JY ) + ALPHA*TEMP2`
			`JX = JX + INCX`
			`JY = JY + INCY`
			`120 CONTINUE`
			`END IF`
			`END IF`
			`*`
			`RETURN`
			`*`
			`* End of SSBMV .`
			`*`
			`END`