zgesl(3P)
NAME
zgesl - solve the linear system Ax = b for a general matrix A, which has been LU- factored by xGECO or xGEFA, and vectors b and x.
SYNOPSIS
CALL DGESL (DA, LDA, N, IPIVOT, DB, JOB)
CALL SGESL (SA, LDA, N, IPIVOT, SB, JOB)
CALL ZGESL (ZA, LDA, N, IPIVOT, ZB, JOB)
CALL CGESL (CA, LDA, N, IPIVOT, CB, JOB)
void dgesl(double ∗da, long int lda, long int n, long int ∗ipivot,
double ∗db, long int job)
void sgesl(float ∗sa, long int lda, long int n, long int ∗ipivot, float ∗b, long
int job)
void zgesl(doublecomplex ∗za, long int lda, long int n,
long int ∗ipivot, doublecomplex ∗zb, long int job)
void cgesl(complex ∗ca, long int lda, long int n, long int ∗ipivot,
complex ∗cb, long int job)
ARGUMENTS
xALU factorization of the matrix A, as computed by xGECO or xGEFA.
LDALeading dimension of the array A as specified in a dimension
or type statement. LDA >= max(1,N).
NOrder of the matrix A. N >= 0.
IPIVOTPivot vector as computed by xGECO or xGEFA.
xBOn entry, the right-hand side vector b.
On exit, the solution vector x.
JOBDetermines which operation the subroutine will perform:
0 Solve the system Ax = b.
not 0 Solve the linear system AHx = b. Note that ATx = AHx for real matrices.
SAMPLE PROGRAM
PROGRAM TEST
IMPLICIT NONE
C
INTEGER IAXEQB, LDA, LDB, N
PARAMETER (IAXEQB = 0)
PARAMETER (N = 3)
PARAMETER (LDA = N)
PARAMETER (LDB = LDA)
C
DOUBLE PRECISION A(LDA,N), B(LDB)
INTEGER ICOL, INFO, IPIVOT(N), IROW, JOB
C
EXTERNAL DGEFA, DGESL
C
C Initialize the array A to store the matrix A shown below.
C Initialize the array B to store the vector b shown below.
C
C 1 2 2 15
C A = 2 1 2 b = 15
C 2 2 1 15
C
DATA A / 1.0D0, 3∗2.0D0, 1.0D0, 3∗2.0D0, 1.0D0 /
DATA B / 3∗1.5D1 /
C
PRINT 1000
PRINT 1010, ((A(IROW,ICOL), ICOL = 1, N), IROW = 1, N)
PRINT 1020
PRINT 1030, B
CALL DGEFA (A, LDA, N, IPIVOT, INFO)
IF (INFO .EQ. 0) THEN
JOB = IAXEQB
CALL DGESL (A, LDA, N, IPIVOT, B, JOB)
PRINT 1040
PRINT 1030, B
ELSE
PRINT 1050, INFO
END IF
C
1000 FORMAT (1X, ’A:’)
1010 FORMAT (3(3X, F4.1))
1020 FORMAT (/1X, ’b:’)
1030 FORMAT (1X, 2X, F4.1)
1040 FORMAT (/1X, ’A∗∗(-1)∗b’)
1050 FORMAT (1X, ’A appears singular at ’, I2)
C
END
SAMPLE OUTPUT
A:
1.0 2.0 2.0
2.0 1.0 2.0
2.0 2.0 1.0
b:
15.0
15.0
15.0
A∗∗(-1)∗b
3.0
3.0
3.0
Sun, Inc. — Last change: 20 Sep 1996