blas/drotm.f - platform/external/eigen - Git at Google

       SUBROUTINE DROTM(N,DX,INCX,DY,INCY,DPARAM)
 *     .. Scalar Arguments ..
       INTEGER INCX,INCY,N
 *     ..
 *     .. Array Arguments ..
       DOUBLE PRECISION DPARAM(5),DX(*),DY(*)
 *     ..
 *
 *  Purpose
 *  =======
 *
 *     APPLY THE MODIFIED GIVENS TRANSFORMATION, H, TO THE 2 BY N MATRIX
 *
 *     (DX**T) , WHERE **T INDICATES TRANSPOSE. THE ELEMENTS OF DX ARE IN
 *     (DY**T)
 *
 *     DX(LX+I*INCX), I = 0 TO N-1, WHERE LX = 1 IF INCX .GE. 0, ELSE
 *     LX = (-INCX)*N, AND SIMILARLY FOR SY USING LY AND INCY.
 *     WITH DPARAM(1)=DFLAG, H HAS ONE OF THE FOLLOWING FORMS..
 *
 *     DFLAG=-1.D0     DFLAG=0.D0        DFLAG=1.D0     DFLAG=-2.D0
 *
 *       (DH11  DH12)    (1.D0  DH12)    (DH11  1.D0)    (1.D0  0.D0)
 *     H=(          )    (          )    (          )    (          )
 *       (DH21  DH22),   (DH21  1.D0),   (-1.D0 DH22),   (0.D0  1.D0).
 *     SEE DROTMG FOR A DESCRIPTION OF DATA STORAGE IN DPARAM.
 *
 *  Arguments
 *  =========
 *
 *  N      (input) INTEGER
 *         number of elements in input vector(s)
 *
 *  DX     (input/output) DOUBLE PRECISION array, dimension N
 *         double precision vector with N elements
 *
 *  INCX   (input) INTEGER
 *         storage spacing between elements of DX
 *
 *  DY     (input/output) DOUBLE PRECISION array, dimension N
 *         double precision vector with N elements
 *
 *  INCY   (input) INTEGER
 *         storage spacing between elements of DY
 *
 *  DPARAM (input/output)  DOUBLE PRECISION array, dimension 5
 *     DPARAM(1)=DFLAG
 *     DPARAM(2)=DH11
 *     DPARAM(3)=DH21
 *     DPARAM(4)=DH12
 *     DPARAM(5)=DH22
 *
 *  =====================================================================
 *
 *     .. Local Scalars ..
       DOUBLE PRECISION DFLAG,DH11,DH12,DH21,DH22,TWO,W,Z,ZERO
       INTEGER I,KX,KY,NSTEPS
 *     ..
 *     .. Data statements ..
       DATA ZERO,TWO/0.D0,2.D0/
 *     ..
 *
       DFLAG = DPARAM(1)
       IF (N.LE.0 .OR. (DFLAG+TWO.EQ.ZERO)) GO TO 140
       IF (.NOT. (INCX.EQ.INCY.AND.INCX.GT.0)) GO TO 70
 *
       NSTEPS = N*INCX
       IF (DFLAG) 50,10,30
    10 CONTINUE
       DH12 = DPARAM(4)
       DH21 = DPARAM(3)
       DO 20 I = 1,NSTEPS,INCX
           W = DX(I)
           Z = DY(I)
           DX(I) = W + Z*DH12
           DY(I) = W*DH21 + Z
    20 CONTINUE
       GO TO 140
    30 CONTINUE
       DH11 = DPARAM(2)
       DH22 = DPARAM(5)
       DO 40 I = 1,NSTEPS,INCX
           W = DX(I)
           Z = DY(I)
           DX(I) = W*DH11 + Z
           DY(I) = -W + DH22*Z
    40 CONTINUE
       GO TO 140
    50 CONTINUE
       DH11 = DPARAM(2)
       DH12 = DPARAM(4)
       DH21 = DPARAM(3)
       DH22 = DPARAM(5)
       DO 60 I = 1,NSTEPS,INCX
           W = DX(I)
           Z = DY(I)
           DX(I) = W*DH11 + Z*DH12
           DY(I) = W*DH21 + Z*DH22
    60 CONTINUE
       GO TO 140
    70 CONTINUE
       KX = 1
       KY = 1
       IF (INCX.LT.0) KX = 1 + (1-N)*INCX
       IF (INCY.LT.0) KY = 1 + (1-N)*INCY
 *
       IF (DFLAG) 120,80,100
    80 CONTINUE
       DH12 = DPARAM(4)
       DH21 = DPARAM(3)
       DO 90 I = 1,N
           W = DX(KX)
           Z = DY(KY)
           DX(KX) = W + Z*DH12
           DY(KY) = W*DH21 + Z
           KX = KX + INCX
           KY = KY + INCY
    90 CONTINUE
       GO TO 140
   100 CONTINUE
       DH11 = DPARAM(2)
       DH22 = DPARAM(5)
       DO 110 I = 1,N
           W = DX(KX)
           Z = DY(KY)
           DX(KX) = W*DH11 + Z
           DY(KY) = -W + DH22*Z
           KX = KX + INCX
           KY = KY + INCY
   110 CONTINUE
       GO TO 140
   120 CONTINUE
       DH11 = DPARAM(2)
       DH12 = DPARAM(4)
       DH21 = DPARAM(3)
       DH22 = DPARAM(5)
       DO 130 I = 1,N
           W = DX(KX)
           Z = DY(KY)
           DX(KX) = W*DH11 + Z*DH12
           DY(KY) = W*DH21 + Z*DH22
           KX = KX + INCX
           KY = KY + INCY
   130 CONTINUE
   140 CONTINUE
       RETURN
       END
	SUBROUTINE DROTM(N,DX,INCX,DY,INCY,DPARAM)
	* .. Scalar Arguments ..
	INTEGER INCX,INCY,N
	* ..
	* .. Array Arguments ..
	DOUBLE PRECISION DPARAM(5),DX(),DY()
	* ..
	*
	* Purpose
	* =======
	*
	* APPLY THE MODIFIED GIVENS TRANSFORMATION, H, TO THE 2 BY N MATRIX
	*
	* (DXT) , WHERE T INDICATES TRANSPOSE. THE ELEMENTS OF DX ARE IN
	* (DY**T)
	*
	* DX(LX+I*INCX), I = 0 TO N-1, WHERE LX = 1 IF INCX .GE. 0, ELSE
	* LX = (-INCX)*N, AND SIMILARLY FOR SY USING LY AND INCY.
	* WITH DPARAM(1)=DFLAG, H HAS ONE OF THE FOLLOWING FORMS..
	*
	* DFLAG=-1.D0 DFLAG=0.D0 DFLAG=1.D0 DFLAG=-2.D0
	*
	* (DH11 DH12) (1.D0 DH12) (DH11 1.D0) (1.D0 0.D0)
	* H=( ) ( ) ( ) ( )
	* (DH21 DH22), (DH21 1.D0), (-1.D0 DH22), (0.D0 1.D0).
	* SEE DROTMG FOR A DESCRIPTION OF DATA STORAGE IN DPARAM.
	*
	* Arguments
	* =========
	*
	* N (input) INTEGER
	* number of elements in input vector(s)
	*
	* DX (input/output) DOUBLE PRECISION array, dimension N
	* double precision vector with N elements
	*
	* INCX (input) INTEGER
	* storage spacing between elements of DX
	*
	* DY (input/output) DOUBLE PRECISION array, dimension N
	* double precision vector with N elements
	*
	* INCY (input) INTEGER
	* storage spacing between elements of DY
	*
	* DPARAM (input/output) DOUBLE PRECISION array, dimension 5
	* DPARAM(1)=DFLAG
	* DPARAM(2)=DH11
	* DPARAM(3)=DH21
	* DPARAM(4)=DH12
	* DPARAM(5)=DH22
	*
	* =====================================================================
	*
	* .. Local Scalars ..
	DOUBLE PRECISION DFLAG,DH11,DH12,DH21,DH22,TWO,W,Z,ZERO
	INTEGER I,KX,KY,NSTEPS
	* ..
	* .. Data statements ..
	DATA ZERO,TWO/0.D0,2.D0/
	* ..
	*
	DFLAG = DPARAM(1)
	IF (N.LE.0 .OR. (DFLAG+TWO.EQ.ZERO)) GO TO 140
	IF (.NOT. (INCX.EQ.INCY.AND.INCX.GT.0)) GO TO 70
	*
	NSTEPS = N*INCX
	IF (DFLAG) 50,10,30
	10 CONTINUE
	DH12 = DPARAM(4)
	DH21 = DPARAM(3)
	DO 20 I = 1,NSTEPS,INCX
	W = DX(I)
	Z = DY(I)
	DX(I) = W + Z*DH12
	DY(I) = W*DH21 + Z
	20 CONTINUE
	GO TO 140
	30 CONTINUE
	DH11 = DPARAM(2)
	DH22 = DPARAM(5)
	DO 40 I = 1,NSTEPS,INCX
	W = DX(I)
	Z = DY(I)
	DX(I) = W*DH11 + Z
	DY(I) = -W + DH22*Z
	40 CONTINUE
	GO TO 140
	50 CONTINUE
	DH11 = DPARAM(2)
	DH12 = DPARAM(4)
	DH21 = DPARAM(3)
	DH22 = DPARAM(5)
	DO 60 I = 1,NSTEPS,INCX
	W = DX(I)
	Z = DY(I)
	DX(I) = WDH11 + ZDH12
	DY(I) = WDH21 + ZDH22
	60 CONTINUE
	GO TO 140
	70 CONTINUE
	KX = 1
	KY = 1
	IF (INCX.LT.0) KX = 1 + (1-N)*INCX
	IF (INCY.LT.0) KY = 1 + (1-N)*INCY
	*
	IF (DFLAG) 120,80,100
	80 CONTINUE
	DH12 = DPARAM(4)
	DH21 = DPARAM(3)
	DO 90 I = 1,N
	W = DX(KX)
	Z = DY(KY)
	DX(KX) = W + Z*DH12
	DY(KY) = W*DH21 + Z
	KX = KX + INCX
	KY = KY + INCY
	90 CONTINUE
	GO TO 140
	100 CONTINUE
	DH11 = DPARAM(2)
	DH22 = DPARAM(5)
	DO 110 I = 1,N
	W = DX(KX)
	Z = DY(KY)
	DX(KX) = W*DH11 + Z
	DY(KY) = -W + DH22*Z
	KX = KX + INCX
	KY = KY + INCY
	110 CONTINUE
	GO TO 140
	120 CONTINUE
	DH11 = DPARAM(2)
	DH12 = DPARAM(4)
	DH21 = DPARAM(3)
	DH22 = DPARAM(5)
	DO 130 I = 1,N
	W = DX(KX)
	Z = DY(KY)
	DX(KX) = WDH11 + ZDH12
	DY(KY) = WDH21 + ZDH22
	KX = KX + INCX
	KY = KY + INCY
	130 CONTINUE
	140 CONTINUE
	RETURN
	END