NAG Library
Advice on Replacement Calls for Withdrawn/Superseded Routines
The following list gives the names of replacement routines for those routines that have been withdrawn or superseded. For
routines that have been withdrawn or superseded since Mark 13 replacement calls are also given.
The list indicates the minimum change necessary, but many of the replacement routines have additional flexibility and you
may wish to take advantage of new features. It is strongly recommended that you consult the routine documents.
C02 – Zeros of Polynomials
C02AEF
Withdrawn at Mark 16.
Replaced by
C02AGF.
Old: CALL C02AEF(A,N,REZ,IMZ,TOL,IFAIL)
New: CALL C02AGF(A,N1,SCALE,Z,W,IFAIL)
The zeros are returned in the
double precision array
Z of dimension
(2,N)
rather than in the arrays REZ and IMZ, and
W is a
double precision work array of dimension
(2 × (N + 1))
.
D02 – Ordinary Differential Equations
D02BAF
Withdrawn at Mark 18.
Replaced by
D02PCF and associated D02P routines.
Old: CALL D02BAF(X,XEND,N,Y,TOL,FCN,W,IFAIL)
New: DO 10 L = 1,N
THRES(L) = TOL
10 CONTINUE
CALL D02PVF(N,X,Y,XEND,TOL,THRES,2,'usualtask',.FALSE.,
+ 0.0D0,W,20*N,IFAIL)
CALL D02PCF(FCN,XEND,X,Y,YP,YMAX,W,IFAIL)
THRES,
YP,
YMAX are
double precision arrays of length
N and the length of array
W needs extending to length
20 × N.
D02BBF
Withdrawn at Mark 18.
Replaced by
D02PCF and associated D02P routines.
Old: CALL D02BBF(X,XEND,N,Y,TOL,IRELAB,FCN,OUTPUT,W,IFAIL)
New: CALL D02PVF(N,X,Y,XEND,TOL,THRES,2,'usualtask',.FALSE.,
+ 0.0D0,W,20*N,IFAIL)
... set XWANT ...
10 CONTINUE
CALL D02PCF(FCN,XWANT,X,Y,YP,YMAX,W,IFAIL)
IF (XWANT.LT.XEND) THEN
... reset XWANT ...
GO TO 10
ENDIF
THRES,
YP,
YMAX are
double precision arrays of length
N and the length of array
W needs extending to length
20 × N
.
D02BDF
Withdrawn at Mark 18.
Replaced by
D02PCF and associated D02P routines.
Old: CALL D02BDF(X,XEND,N,Y,TOL,IRELAB,FCN,STIFF,YNORM,W,
+ IW,M,OUTPUT,IFAIL)
New: CALL D02PVF(N,X,Y,XEND,TOL,THRES,2,'usualtask',.TRUE.,
+ 0.0D0,W,32*N,IFAIL)
... set XWANT ...
10 CONTINUE
CALL D02PCF(FCN,XWANT,X,Y,YP,YMAX,IFAIL)
IF (XWANT.LT.XEND) THEN
... reset XWANT ...
GO TO 10
ENDIF
CALL D02PZF(RMSERR,ERRMAX,TERRMX,W,IFAIL)
THRES,
YP,
YMAX and
RMSERR are
double precision arrays of length
N.
W is now a
double precision onedimensional array of length
32 × N
.
D02CAF
Withdrawn at Mark 18.
Replaced by
D02CJF.
Old: CALL D02CAF(X,XEND,N,Y,TOL,FCN,W,IFAIL)
New: CALL D02CJF(X,XEND,N,Y,FCN,TOL,'M',D02CJX,D02CJW,W,IFAIL)
D02CJX is a subroutine provided in the NAG Fortran Library and D02CJW is a
double precision function also provided. Both must be declared as EXTERNAL. The array
W needs to be 5 elements greater in length.
D02CBF
Withdrawn at Mark 18.
Replaced by
D02CJF.
Old: CALL D02CBF(X,XEND,N,Y,TOL,IRELAB,FCN,OUTPUT,W,IFAIL)
New: CALL D02CJF(X,XEND,N,Y,FCN,TOL,RELABS,OUTPUT,D02CJW,W,IFAIL)
D02CJW is a
double precision function provided in the NAG Fortran Library and must be declared as EXTERNAL. The array
W needs to be 5 elements greater in length. The integer parameter IRELAB (which can take values
0,
1 or
2) is catered for by the new CHARACTER*1 argument
RELABS (whose corresponding values are 'M', 'A' and 'R').
D02CGF
Withdrawn at Mark 18.
Replaced by
D02CJF.
Old: CALL D02CGF(X,XEND,N,Y,TOL,HMAX,M,VAL,FCN,W,IFAIL)
New: CALL D02CJF(X,XEND,N,Y,FCN,TOL,'M',D02CJX,G,W,IFAIL)
.
.
.
double precision FUNCTION G(X,Y)
double precision X,Y(*)
G = Y(M)VAL
END
D02CJX is a subroutine provided in the NAG Fortran Library and should be declared as EXTERNAL. Note the functionality of
HMAX is no longer available directly. Checking the value of
Y(M)

VAL
at intervals of length HMAX can be effected by a usersupplied procedure
OUTPUT in place of D02CJX in the call described above. See the routine document for
D02CJF for more details.
D02CHF
Withdrawn at Mark 18.
Replaced by
D02CJF.
Old: CALL D02CHF(X,XEND,N,Y,TOL,IRELAB,HMAX,FCN,G,W,IFAIL)
New: CALL D02CJF(X,XEND,N,Y,FCN,TOL,RELABS,D02CJX,G,W,IFAIL)
D02CJX is a subroutine provided by the NAG Fortran Library and should be declared as EXTERNAL. The functionality of HMAX
can be provided as described under the replacement call for
D02CGF. The relationship between the parameters IRELAB and
RELABS is described under the replacement call for
D02CBF.
D02EAF
Withdrawn at Mark 18.
Replaced by
D02EJF.
Old: CALL D02EAF(X,XEND,N,Y,TOL,FCN,W,IW,IFAIL)
New: CALL D02EJF(X,XEND,N,Y,FCN,TOL,'M',D02EJX,D02EJW,D02EJY,W,IW,
+ IFAIL)
D02EJY and D02EJX are subroutines provided in the NAG Fortran Library and D02EJW is a double precision function also provided. All must be declared as EXTERNAL.
D02EBF
Withdrawn at Mark 18.
Replaced by
D02EJF.
Old: CALL D02EBF(X,XEND,N,Y,TOL,IRELAB,FCN,MPED,PEDERV,OUTPUT,W,IW,
+ IFAIL)
New: CALL D02EJF(X,XEND,N,Y,FCN,PEDERV,TOL,RELABS,OUTPUT,D02EJW,W,IW,
+ IFAIL)
D02EJW is a
double precision function provided in the NAG Fortran Library and must be declared as EXTERNAL. The integer parameter IRELAB (which can take
values 0, 1 or 2) is catered for by the new CHARACTER*1 argument
RELABS (whose corresponding values are 'M', 'A' and 'R'). If
MPED
=
0
in the call of
D02EBF then
PEDERV must be the routine D02EJY, which is supplied in the Library and should be declared as EXTERNAL.
D02EGF
Withdrawn at Mark 18.
Replaced by
D02EJF.
Old: CALL D02EGF(X,XEND,N,Y,TOL,HMAX,M,VAL,FCN,W,IW,IFAIL)
New: CALL D02EJF(X,XEND,N,Y,FCN,D02EJY,TOL,'M',D02EJX,G,W,IW,IFAIL)
.
.
.
double precision FUNCTION G(X,Y)
double precision X,Y(*)
G = Y(M)VAL
END
D02EJY and D02EJX are subroutines provided in the NAG Fortran Library and should be declared as EXTERNAL. Note that the functionality
of HMAX is no longer available directly. Checking the value of
Y(M)

VAL
at intervals of length HMAX can be effected by a usersupplied procedure
OUTPUT in place of D02EJX in the call described above. See the routine document for
D02EJF for more details.
D02EHF
Withdrawn at Mark 18.
Replaced by
D02EJF.
Old: CALL D02EHF(X,XEND,N,Y,TOL,IRELAB,HMAX,MPED,PEDERV,FCN,G,W,IFAIL)
New: CALL D02EJF(X,XEND,N,Y,FCN,PEDERV,TOL,RELABS,D02EJX,G,W,IW,IFAIL)
D02EJX is a subroutine provided by the NAG Fortran Library and should be declared as EXTERNAL. The functionality of HMAX
can be provided as described under the replacement call for
D02EGF. The relationship between the parameters IRELAB and
RELABS is described under the replacement call for
D02EBF. If
MPED
=
0
in the call of
D02EHF then
PEDERV must be the routine D02EJY, which is supplied in the Library and should be declared as EXTERNAL.
D02PAF
Withdrawn at Mark 18.
Replaced by
D02PDF and associated D02P routines.
Existing programs should be modified to call
D02PVF and
D02PDF. The interfaces are significantly different and therefore precise details of a replacement call cannot be given. Please
consult the appropriate routine documents.
D02QDF
Withdrawn at Mark 17.
Replaced by
D02NBF or
D02NCF.
Existing programs should be modified to call
D02NSF,
D02NVF and
D02NBF, or
D02NTF,
D02NVF and
D02NCF. The interfaces are significantly different and therefore precise details of a replacement call cannot be given. Please
consult the appropriate routine documents.
D02QQF
Withdrawn at Mark 17.
Replaced by
D02NBF or
D02NCF.
D02XAF
Withdrawn at Mark 18.
Replaced by
D02PXF and associated D02P routines.
Not needed except with
D02PAF. The equivalent routine is
D02PXF.
D02XBF
Withdrawn at Mark 18.
Replaced by
D02PXF and associated D02P routines.
Not needed except with
D02PAF.
D02YAF
Withdrawn at Mark 18.
Replaced by
D02PDF and associated D02P routines.
There is no precise equivalent to this routine. The closest alternative routine is
D02PDF.
D03 – Partial Differential Equations
D03PAF
Withdrawn at Mark 17.
Replaced by
D03PCF/D03PCA.
Existing programs should be modified to call
D03PCF/D03PCA. The replacement routine is designed to solve a broader class of problems. Therefore it is not possible to give precise
details of a replacement call. Please consult the appropriate routine documents.
D03PBF
Withdrawn at Mark 17.
Replaced by
D03PCF/D03PCA.
Existing programs should be modified to call
D03PCF/D03PCA. The replacement routine is designed to solve a broader class of problems. Therefore it is not possible to give precise
details of a replacement call. Please consult the appropriate routine documents.
D03PGF
Withdrawn at Mark 17.
Replaced by
D03PCF/D03PCA.
Existing programs should be modified to call
D03PCF/D03PCA. The replacement routine is designed to solve a broader class of problems. Therefore it is not possible to give precise
details of a replacement call. Please consult the appropriate routine documents.
E01 – Interpolation
E01ACF
Withdrawn at Mark 15.
Replaced by
E01DAF and
E02DEF.
Old: CALL E01ACF(A,B,X,Y,F,VAL,VALL,IFAIL,XX,WORK,AM,D,IG1,M1,N1)
New: CALL E01DAF(N1,M1,X,Y,F,PX,PY,LAMDA,MU,C,WRK,IFAIL)
A1(1) = A
B1(1) = B
M = 1
CALL E02DEF(M,PX,PY,A1,B1,LAMDA,MU,C,FF,WRK,IWRK,IFAIL)
VAL = FF(1)
VALL = VAL
where
PX,
PY and
M are INTEGER variables,
LAMDA is a
double precision array of dimension
(N1 + 4)
,
MU is a
double precision array of dimension
(M1 + 4)
,
C is a
double precision array of dimension
(N1 × M1)
,
WRK is a
double precision array of dimension
((N1 + 6) × (M1 + 6))
,
A1,
B1 and
FF are
double precision arrays of dimension (
M), and
IWRK is an INTEGER array of dimension (
M1).
The above new calls duplicate almost exactly the effect of the old call, except that the new routines produce a single interpolated
value for each point, rather than the two alternative values VAL and VALL produced by the old routine. By attempting this
duplication, however, efficiency is probably being sacrificed. In general it is preferable to evaluate the interpolating
function provided by
E01DAF at a set of
M points, supplied in arrays
A1 and
B1, rather than at a single point.
Note also that
E01ACF uses natural splines, i.e., splines having zero second derivatives at the ends of the ranges. This is likely to be slightly
unsatisfactory, and
E01DAF does not have this problem. It does mean however that results produced by
E01DAF may not be exactly the same as those produced by
E01ACF.
E01SEF
Withdrawn at Mark 20.
Replaced by
E01SGF.
Old: CALL E01SEF(M,X,Y,F,RNW,RNQ,NW,NQ,FNODES,MINNQ,WRK,IFAIL)
New: CALL E01SGF(M,X,Y,F,NW,NQ,IQ,LIQ,RQ,LRQ,IFAIL)
E01SEF has been superseded by
E01SGF which gives improved accuracy, facilities for obtaining gradient values and a consistent interface with
E01TGF for interpolation of scattered data in three dimensions.
The interpolant generated by the two routines will not be identical, but similar results may be obtained by using the same
values of
NW and
NQ. Details of the interpolant are passed to the evaluator through the arrays
IQ and
RQ rather than FNODES and RNW.
E01SFF
Withdrawn at Mark 20.
Replaced by
E01SHF.
Old: CALL E01SFF(M,X,Y,F,RNW,FNODES,PX,PY,PF,IFAIL)
New: CALL E01SHF(M,X,Y,F,IQ,LIQ,RQ,LRQ,1,PX,PY,PF,QX,QY,IFAIL)
The two calls will not produce identical results due to differences in the generation routines
E01SEF and
E01SGF. Details of the interpolant are passed from
E01SGF through the arrays
IQ and
RQ rather than FNODES and RNW.
E01SHF also returns gradient values in
QX and
QY and allows evaluation at arrays of points rather than just single points.
E02 – Curve and Surface Fitting
E02DBF
Withdrawn at Mark 16.
Replaced by
E02DEF.
Old: CALL E02DBF(M,PX,PY,X,Y,FF,LAMDA,MV,POINT,NPOINT,C,NC,IFAIL)
New: CALL E02DEF(M,PX,PY,X,Y,LAMDA,MU,C,FF,WRK,IWRK,IFAIL)
where
WRK is a
double precision array of dimension
(PY  4)
, and
IWRK is an INTEGER array of dimension
(PY  4)
.
E04 – Minimizing or Maximizing a Function
E04CCF/E04CCA
Scheduled for withdrawal at Mark 24.
Replaced by
E04CBF.
Old: CALL E04CCF(N,X,F,TOL,IW,W1,W2,W3,W4,W5,W6,FUNCT,MONIT,MAXCAL,
* IFAIL)
or
CALL E04CCA(N,X,F,TOL,IW,W1,W2,W3,W4,W5,W6,FUNCT2,MONIT2,MAXCAL,
* IUSER,RUSER,IFAIL)
New: CALL E04CBF(N,X,F,TOLF,TOLX,FUNCT2,MONIT3,MAXCAL,IUSER,RUSER,
* IFAIL)
The new routine can be derived from the old as follows:
SUBROUTINE MONIT3(FMIN,FMAX,SIM,N,NCALL,SERROR,VRATIO,IUSER,RUSER)
INTEGER N, NCALL, IUSER(*)
double precision FMIN, FMAX, SIM(N+1,N), SERROR, VRATIO, RUSER(*)
C
CALL MONIT2(FMIN,FMAX,SIM,N,N+1,NCALL,IUSER,RUSER)
C Add code here to monitor the values of SERROR and VRATIO, if necessary
RETURN
END
E04FDF
Withdrawn at Mark 19.
Replaced by
E04FYF.
Old: CALL E04FDF(M,N,X,FSUMSQ,IW,LIW,W,LW,IFAIL)
New: CALL E04FYF(M,N,LSFUN,X,FSUMSQ,W,LW,IUSER,USER,IFAIL)
LSFUN appears in the parameter list instead of the fixedname subroutine LSFUN1 of
E04FDF.
LSFUN must be declared as EXTERNAL in the calling (sub)program. In addition it has an extra two parameters,
IUSER and
USER, over and above those of LSFUN1. It may be derived from LSFUN1 as follows:
SUBROUTINE LSFUN(M,N,XC,FVECC,IUSER,USER)
INTEGER M, N, IUSER(*)
double precision XC(N), FVECC(M), USER(*)
C
CALL LSFUN1(M,N,XC,FVECC)
C
RETURN
END
In general the extra parameters,
IUSER and
USER, should be declared in the calling program as
IUSER(1)
and
USER(1)
, but will not need initializing.
E04GCF
Withdrawn at Mark 19.
Replaced by
E04GYF.
Old: CALL E04GCF(M,N,X,FSUMSQ,IW,LIW,W,LW,IFAIL)
New: CALL E04GYF(M,N,LSFUN,X,FSUMSQ,W,LW,IUSER,USER,IFAIL)
LSFUN appears in the parameter list instead of the fixedname subroutine LSFUN2 of
E04GCF.
LSFUN must be declared as EXTERNAL in the calling (sub)program. In addition it has an extra two parameters,
IUSER and
USER, over and above those of LSFUN2. It may be derived from LSFUN2 as follows:
SUBROUTINE LSFUN(M,N,XC,FVECC,FJACC,LJC,IUSER,USER)
INTEGER M, N, LJC, IUSER(*)
double precision XC(N), FVECC(M), FJACC(LJC,N), USER(*)
C
CALL LSFUN2(M,N,XC,FVECC,FJACC,LJC)
C
RETURN
END
In general the extra parameters,
IUSER and
USER, should be declared in the calling program as
IUSER(1)
and
USER(1)
, but will not need initializing. If however, the array IW was used to pass information through
E04GCF into LSFUN2, or get information from LSFUN2, then the array
IUSER should be declared appropriately and used for this purpose.
E04GEF
Withdrawn at Mark 19.
Replaced by
E04GZF.
Old: CALL E04GEF(M,N,X,FSUMSQ,IW,LIW,W,LW,IFAIL)
New: CALL E04GZF(M,N,LSFUN,X,FSUMSQ,W,LW,IUSER,USER,IFAIL)
LSFUN appears in the parameter list instead of the fixedname subroutine LSFUN2 of
E04GEF.
LSFUN must be declared as EXTERNAL in the calling (sub)program. In addition it has an extra two parameters,
IUSER and
USER, over and above those of LSFUN2. It may be derived from LSFUN2 as follows:
SUBROUTINE LSFUN(M,N,X,FVECC,FJACC,LJC,IUSER,USER)
INTEGER M, N, LJC, IUSER(*)
double precision XC(N), FVECC(M), FJACC(LJC,N), USER(*)
C
CALL LSFUN2(M,N,XC,FVECC,FJACC,LJC)
C
RETURN
END
In general the extra parameters,
IUSER and
USER, should be declared in the calling program as
IUSER(1)
and
USER(1)
, but will not need initializing. If however, the array IW was used to pass information through
E04GEF into LSFUN2, or get information from LSFUN2, then the array
IUSER should be declared appropriately and used for this purpose.
E04HBF
Withdrawn at Mark 16.
There is no replacement for this routine.
E04HFF
Withdrawn at Mark 19.
Replaced by
E04HYF.
Old: CALL E04HFF(M,N,X,FSUMSQ,IW,LIW,W,LW,IFAIL)
New: CALL E04HYF(M,N,LSFUN,LSHES,X,FSUMSQ,W,LW,IUSER,USER,IFAIL)
LSFUN and
LSHES appear in the parameter list instead of the fixedname subroutines LSFUN2 and LSHES2 of
E04HFF.
LSFUN and
LSHES must both be declared as EXTERNAL in the calling (sub)program. In addition they have an extra two parameters,
IUSER and
USER, over and above those of LSFUN2 and LSHES2. They may be derived from LSFUN2 and LSHES2 as follows:
SUBROUTINE LSFUN(M,N,XC,FVECC,FJACC,LJC,IUSER,USER)
INTEGER M, N, LJC, IUSER(*)
double precision XC(N), FVECC(M), FJACC(LJC,N), USER(*)
C
CALL LSFUN2(M,N,XC,FVECC,FJACC,LJC)
C
RETURN
END
C
SUBROUTINE LSHES(M,N,FVECC,XC,B,LB,IUSER,USER)
INTEGER M, N, LB, IUSER(*)
double precision FVECC(M), XC(N), B(LB), USER(*)
C
CALL LSHES2(M,N,FVECC,XC,B,LB)
C
RETURN
END
In general, the extra parameters,
IUSER and
USER, should be declared in the calling program as
IUSER(1)
and
USER(1)
, but will not need initializing. If, however, the array IW was used to pass information through
E04HFF into LSFUN2 or LSHES2, or to get information from LSFUN2 or LSHES2, then the array
IUSER should be declared appropriately and used for this purpose.
E04JAF
Withdrawn at Mark 19.
Replaced by
E04JYF.
Old: CALL E04JAF(N,IBOUND,BL,BU,X,F,IW,LIW,LW,IFAIL)
New: CALL E04JYF(N,IBOUND,FUNCT,BL,BU,X,F,IW,LIW,W,LW,IUSER,USER,IFAIL)
FUNCT appears in the parameter list instead of the fixedname subroutine FUNCT1 of
E04JAF.
FUNCT must be declared as EXTERNAL in the calling (sub)program. In addition it has an extra two parameters,
IUSER and
USER, over and above those of FUNCT1. It may be derived from FUNCT1 as follows:
SUBROUTINE FUNCT(N,XC,FC,IUSER,USER)
INTEGER N, IUSER(*)
double precision XC(N), FC, USER(*)
C
CALL FUNCT1(N,XC,FC)
C
RETURN
END
The extra parameters,
IUSER and
USER, should be declared in the calling program as
IUSER(1)
and
USER(1)
, but will not need initializing.
E04JBF
Withdrawn at Mark 16.
Replaced by
E04UCF/E04UCA.
No comparative calls are given between
E04JBF and
E04UCF/E04UCA since both routines have considerable flexibility and can be called with many different options.
E04UCF/E04UCA allows some values to be passed to it, not through the parameter list, but as ‘optional parameters’, supplied through calls
to
E04UDF/E04UDA or
E04UEF/E04UEA.
E04UCF/E04UCA is a more powerful routine than
E04JBF, in that it allows for general linear and nonlinear constraints, and for some or all of the first derivatives to be supplied;
however when replacing
E04JBF, only the simple bound constraints are relevant, and only function values are assumed to be available.
Therefore
E04UCF/E04UCA must be called with
NCLIN
=
NCNLN
=
0
, with dummy arrays of size (1) supplied as the arguments
A,
C and
CJAC, and with the name of the auxiliary routine E04UDM (UDME04 in some implementations) as the argument
CONFUN. The optional parameter
Derivative Level must be set to 0.
The subroutine providing function values to
E04UCF/E04UCA is
OBJFUN. It has a different parameter list to FUNCT, but can be constructed as follows:
SUBROUTINE OBJFUN(MODE,N,X,OBJF,OBJGRD,NSTATE,IUSER,USER)
INTEGER MODE, N, NSTATE, IUSER(*)
double precision X(N), OBJF, OBJGRD(N), USER(*)
INTEGER IFLAG,IW(1)
double precision W(1)
C
IFLAG = 0
CALL FUNCT(IFLAG,N,X,OBJF,OBJGRD,IW,1,W,1)
IF (IFLAG.LT.0) MODE = IFLAG
RETURN
END
(This assumes that the arrays IW and W are not used to communicate between FUNCT and the calling program;
E04UCF/E04UCA supplies the arrays
IUSER and
USER specifically for this purpose.)
The functions of the parameters
BL and
BU are similar, but
E04UCF/E04UCA has no parameter corresponding to IBOUND; all elements of
BL and
BU must be set (as when
IBOUND
=
0
in the call to
E04JBF). The optional parameter
Infinite Bound Size must be set to
1.0D + 6 if there are any infinite bounds. The function of the parameter
ISTATE is similar but the specification is slightly different. The parameters F and G are equivalent to
OBJF and
OBJGRD of
E04UCF/E04UCA. It should also be noted that
E04UCF/E04UCA does not allow a usersupplied parameter MONIT, but intermediate output is provided by the routine, under the control of
the optional parameters
Major Print Level and
Minor Print Level.
Most of the ‘tuning’ parameters in
E04JBF have their counterparts as ‘optional parameters’ to
E04UCF/E04UCA, as indicated in the following list, but the correspondence is not exact and the specifications must be read carefully.
E04KAF
Withdrawn at Mark 19.
Replaced by
E04KYF.
Old: CALL E04KAF(N,IBOUND,BL,BU,X,F,G,IW,LIW,W,LW,IFAIL)
New: CALL E04KYF(N,IBOUND,FUNCT,BL,BU,X,F,G,IW,LIW,W,LW,IUSER,USER,IFAIL)
FUNCT appears in the parameter list instead of the fixedname subroutine FUNCT2 of
E04KAF.
FUNCT must be declared as EXTERNAL in the calling (sub)program. In addition it has an extra two parameters,
IUSER and
USER, over and above those of FUNCT2. It may be derived from FUNCT2 as follows:
SUBROUTINE FUNCT(N,XC,FC,GC,IUSER,USER)
INTEGER N, IUSER(*)
double precision XC(N), FC, GC(N), USER(*)
C
CALL FUNCT2(N,XC,FC,GC)
C
RETURN
END
The extra parameters,
IUSER and
USER, should be declared in the calling program as
IUSER(1)
and
USER(1)
, but will not need initializing.
E04KBF
Withdrawn at Mark 16.
Replaced by
E04UCF/E04UCA.
No comparative calls are given between
E04KBF and
E04UCF/E04UCA since both routines have considerable flexibility and can be called with many different options. Most of the advice given
for replacing
E04JBF (see above) applies also to
E04KBF, and only the differences are given here.
The optional parameter
Derivative Level must be set to 1.
The subroutine providing both function and gradient values to
E04UCF/E04UCA is
OBJFUN. It has a different parameter list to FUNCT, but can be constructed as follows:
SUBROUTINE OBJFUN(MODE,N,X,OBJF,OBJGRD,NSTATE,IUSER,USER)
INTEGER MODE, N, NSTATE, IUSER(*)
double precision X(N), OBJF, OBJGRD(N), USER(*)
INTEGER IW(1)
double precision W(1)
C
CALL FUNCT(MODE,N,X,OBJF,OBJGRD,IW,1,W,1)
RETURN
END
E04KCF
Withdrawn at Mark 19.
Replaced by
E04KZF.
Old: CALL E04KCF(N,IBOUND,BL,BU,X,F,G,IW,LIW,W,LW,IFAIL)
New: CALL E04KZF(N,IBOUND,FUNCT,BL,BU,X,F,G,IW,LIW,W,LW,IUSER,USER,IFAIL)
FUNCT appears in the parameter list instead of the fixedname subroutine FUNCT2 of
E04KCF.
FUNCT must be declared as EXTERNAL in the calling (sub)program. In addition it has an extra two parameters,
IUSER and
USER, over and above those of FUNCT2. It may be derived from FUNCT2 as follows:
SUBROUTINE FUNCT(N,XC,FC,GC,IUSER,USER)
INTEGER N, IUSER(*)
double precision XC(N), FC, GC(N), USER(*)
C
CALL FUNCT2(N,XC,FC,GC)
C
RETURN
END
The extra parameters,
IUSER and
USER, should be declared in the calling program as
IUSER(1)
and
USER(1)
, but will not need initializing.
E04LAF
Withdrawn at Mark 19.
Replaced by
E04LYF.
Old: CALL E04LAF(N,IBOUND,BL,BU,X,F,G,IW,LIW,W,LW,IFAIL)
New: CALL E04LYF(N,IBOUND,FUNCT,HESS,BL,BU,X,F,G,IW,LIW,W,LW,IUSER,USER,
+ IFAIL)
FUNCT and
HESS appear in the parameter list instead of the fixedname subroutines FUNCT2 and HESS2 of
E04LAF.
FUNCT and
HESS must both be declared as EXTERNAL in the calling (sub)program. In addition they have an extra two parameters,
IUSER and
USER, over and above those of FUNCT2 and HESS2. They may be derived from FUNCT2 and HESS2 as follows:
SUBROUTINE FUNCT(N,XC,FC,GC,IUSER,USER)
INTEGER N, IUSER(*)
double precision XC(N), FC, GC(N), USER(*)
C
CALL FUNCT2(N,XC,FC,GC)
C
RETURN
END
SUBROUTINE HESS(N,XC,HESLC,LH,HESDC,IUSER,USER)
INTEGER N, LH, IUSER(*)
double precision XC(N), HESLC(LH), HESDC(N), USER(*)
C
CALL HESS2(N,XC,HESLC,LH,HESDC)
C
RETURN
END
In general, the extra parameters,
IUSER and
USER, should be declared in the calling program as
IUSER(1)
and
USER(1)
, but will not need initializing.
E04MBF
Withdrawn at Mark 18.
Replaced by
E04MFF/E04MFA.
Old: CALL E04MBF(ITMAX,MSGLVL,N,NCLIN,NCTOTL,NROWA,A,BL,BU,CVEC,
+ LINOBJ,X,ISTATE,OBJLP,CLAMDA,IWORK,LIWORK,WORK,
+ LWORK,IFAIL)
New: CALL E04MFF(N,NCLIN,A,NROWA,BL,BU,CVEC,ISTATE,X,ITER,OBJLP,
+ AX,CLAMDA,IWORK,LIWORK,WORK,LWORK,IFAIL)
The parameter NCTOTL is no longer required. Values for ITMAX, MSGLVL and LINOBJ may be supplied by calling an option setting
routine.
E04MFF/E04MFA contains two additional parameters as follows:
 ITER– INTEGER.

AX( * )
– double precision array of dimension at least
max (1,NCLIN)
.
The minimum value of the parameter
LIWORK must be increased from
2
×
N
to
2
×
N
+
3
. The minimum value of the parameter
LWORK may also need to be changed. See the routine documents for further information.
E04NAF
Withdrawn at Mark 18.
Replaced by
E04NFF/E04NFA.
Old: CALL E04NAF(ITMAX,MSGLVL,N,NCLIN,NCTOTL,NROWA,NROWH,NCOLH,
+ BIGBND,A,BL,BU,CVEC,FEATOL,HESS,QPHESS,COLD,LP,
+ ORTHOG,X,ISTATE,ITER,OBJ,CLAMDA,IWORK,LIWORK,
+ WORK,LWORK,IFAIL)
New: CALL E04NFF(N,NCLIN,A,NROWA,BL,BU,CVEC,HESS,NROWH,QPHESS,
+ ISTATE,X,ITER,OBJ,AX,CLAMDA,IWORK,LIWORK,WORK,
+ LWORK,IFAIL)
The specification of the subroutine
QPHESS must also be changed as follows:
Old: SUBROUTINE QPHESS(N,NROWH,NCOLH,JTHCOL,HESS,X,HX)
INTEGER N, NROWH, NCOLH, JTHCOL
double precision HESS(NROWH,NCOLH), X(N), HX(N)
New: SUBROUTINE QPHESS(N,JTHCOL,HESS,NROWH,X,HX)
INTEGER N, JTHCOL, NROWH
double precision HESS(NROWH,*), X(N), HX(N)
The parameters NCTOTL, NCOLH and ORTHOG are no longer required. Values for ITMAX, MSGLVL, BIGBND, FEATOL, COLD and LP may
be supplied by calling an option setting routine.
E04NFF/E04NFA contains one additional parameter as follows:

AX( * )
– double precision array of dimension at least
max (1,NCLIN)
.
The minimum value of the parameter
LIWORK must be increased from
2
×
N
to
2
×
N
+
3
. The minimum value of the parameter
LWORK may also need to be changed. See the routine documents for further information.
E04UNF
Withdrawn at Mark 22.
Replaced by
E04USF/E04USA.
Old: CALL E04UNF(M,N,NCLIN,NCNLN,LDA,LDCJ,LDFJ,
+ LDR,A,BL,BU,Y,CONFUN,OBJFUN,ITER,
+ ISTATE,C,CJAC,F,FJAC,CLAMDA,OBJF,
+ R,X,IWORK,LIWORK,WORK,LWORK,IUSER,
+ RUSER,IFAIL)
New: CALL E04USF(M,N,NCLIN,NCNLN,LDA,LDCJ,LDFJ,
+ LDR,A,BL,BU,Y,CONFUN,OBJFUN,ITER,
+ ISTATE,C,CJAC,F,FJAC,CLAMDA,OBJF,
+ R,X,IWORK,LIWORK,WORK,LWORK,IUSER,
+ RUSER,IFAIL)
The specification of the subroutine
OBJFUN must also be changed as follows:
Old: SUBROUTINE OBJFUN(MODE,M,N,LDFJ,X,F,FJAC,NSTATE,IUSER,RUSER)
INTEGER MODE,M,N,LDFJ,NSTATE,IUSER(*)
double precision X(N),F(*),FJAC(LDFJ,*),RUSER(*)
New: SUBROUTINE OBJFUN(MODE,M,N,LDFJ,NEEDFI,X,F,FJAC,NSTATE,
+ IUSER,RUSER)
INTEGER MODE,M,N,LDFJ,NEEDFI,NSTATE,IUSER(*)
double precision X(N),F(*),FJAC(LDFJ,*),RUSER(*)
See the routine documents for further information.
E04UPF
Withdrawn at Mark 19.
Replaced by
E04USF/E04USA.
Old: CALL E04UPF(M,N,NCLIN,NCNLN,LDA,LDCJ,LDFJ,LDR,A,BL,BU,
+ CONFUN,OBJFUN,ITER,ISTATE,C,CJAC,F,FJAC,
+ CLAMDA,OBJF,R,X,IWORK,LIWORK,WORK,LWORK,
+ IUSER,USER,IFAIL)
New: CALL E04USF(M,N,NCLIN,NCNLN,LDA,LDCJ,LDFJ,
+ LDR,A,BL,BU,Y,CONFUN,OBJFUN,ITER,
+ ISTATE,C,CJAC,F,FJAC,CLAMDA,OBJF,
+ R,X,IWORK,LIWORK,WORK,LWORK,IUSER,
+ USER,IFAIL)
E04USF/E04USA contains one additional parameter as follows:

Y(M)
– double precision array.
Note that a call to
E04UPF is the same as a call to
E04USF/E04USA with
Y(i)
= 0.0
, for
i = 1,2, … ,M
.
The specification of the subroutine
OBJFUN must also be changed as follows:
Old: SUBROUTINE OBJFUN(MODE,M,N,LDFJ,X,F,FJAC,NSTATE,IUSER,USER)
INTEGER MODE,M,N,LDFJ,NSTATE,IUSER(*)
double precision X(N),F(*),FJAC(LDFJ,*),USER(*)
New: SUBROUTINE OBJFUN(MODE,M,N,LDFJ,NEEDFI,X,F,FJAC,NSTATE,
+ IUSER,USER)
INTEGER MODE,M,N,NEEFI,NSTATE,IUSER(*)
double precision X(N),F(*),FJAC(LDFJ,*),USER(*)
See the routine documents for further information.
E04VCF
Withdrawn at Mark 17.
Replaced by
E04UCF/E04UCA.
Old: CALL E04VCF(ITMAX,MSGLVL,N,NCLIN,NCNLN,NCTOTL,NROWA,NROWJ,
+ NROWR,BIGBND,EPSAF,ETA,FTOL,A,BL,BU,FEATOL,
+ CONFUN,OBJFUN,COLD,FEALIN,ORTHOG,X,ISTATE,R,ITER,
+ C,CJAC,OBJF,OBJGRD,CLAMDA,IWORK,LIWORK,WORK,LWORK,
+ IFAIL)
New: CALL E04UCF(N,NCLIN,NCNLN,NROWA,NROWJ,NROWR,A,BL,BU,CONFUN,
+ OBJFUN,ITER,ISTATE,C,CJAC,CLAMDA,OBJF,OBJGRD,R,X,
+ IWORK,LIWORK,WORK,LWORK,IUSER,USER,IFAIL)
The specification of the subroutine
OBJFUN must also be changed as follows:
Old: SUBROUTINE OBJFUN(MODE,N,X,OBJF,OBJGRD,NSTATE)
INTEGER MODE, N, NSTATE
double precision X(N), OBJF, OBJGRD(N)
New: SUBROUTINE OBJFUN(MODE,N,X,OBJF,OBJGRD,NSTATE,IUSER,USER)
INTEGER MODE, N, NSTATE, IUSER(*)
double precision X(N), OBJF, OBJGRD(N), USER(*)
If
NCNLN
>
0
, the specification of the subroutine
CONFUN must also be changed as follows:
Old: SUBROUTINE CONFUN(MODE,NCNLN,N,NROWJ,X,C,CJAC,NSTATE)
INTEGER MODE, NCNLN, N, NROWJ, NSTATE
double precision X(N), C(NROWJ), CJAC(NROWJ,N)
New: SUBROUTINE CONFUN(MODE,NCNLN,N,NROWJ,NEEDC,X,C,CJAC,NSTATE,
+ IUSER,USER)
INTEGER MODE, NCNLN, N, NROWJ, NEEDC(NCNLN), NSTATE, IUSER(*)
double precision X(N), C(NCNLN), CJAC(NROWJ,N), USER(*)
If
NCNLN
=
0
, then the name of the dummy routine E04VDM/E54VDM may need to be changed to E04UDM in the calling program.
The parameters NCTOTL, EPSAF, FEALIN and ORTHOG are no longer required. Values for ITMAX, MSGLVL, BIGBND, ETA, FTOL, COLD
and FEATOL may be supplied by calling an option setting routine.
E04UCF/E04UCA contains two additional parameters as follows:

IUSER( * )
– INTEGER array of dimension at least 1.

USER( * )
– double precision array of dimension at least 1.
The minimum value of the parameter
LIWORK must be increased from
3
×
N
+
NCLIN
+
NCNLN
to
3
×
N
+
NCLIN
+
2
×
NCNLN
. The minimum value of the parameter
LWORK may also need to be changed. See the routine documents for further information.
E04VDF
Withdrawn at Mark 17.
Replaced by
E04UCF/E04UCA.
Old: IFAIL = 110
CALL E04VDF(ITMAX,MSGLVL,N,NCLIN,NCNLN,NCTOTL,NROWA,NROWJ,
+ CTOL,FTOL,A,BL,BU,CONFUN,OBJFUN,X,ISTATE,C,CJAC,
+ CJAC,OBJF,OBJGRD,CLAMDA,IWORK,LIWORK,WORK,LWORK,
+ IFAIL)
New: IFAIL = 1
CALL E04UCF(N,NCLIN,NCNLN,NROWA,NROWJ,N,A,BL,BU,CONFUN,OBJFUN,
+ ITER,ISTATE,C,CJAC,CLAMDA,OBJF,OBJGRD,R,X,IWORK,
+ LIWORK,WORK,LWORK,IUSER,USER,IFAIL)
The specification of the subroutine
OBJFUN must also be changed as follows:
Old: SUBROUTINE OBJFUN(MODE,N,X,OBJF,OBJGRD,NSTATE)
INTEGER MODE, N, NSTATE
double precision X(N), OBJF, OBJGRD(N)
New: SUBROUTINE OBJFUN(MODE,N,X,OBJF,OBJGRD,NSTATE,IUSER,USER)
INTEGER MODE, N, NSTATE, IUSER(*)
double precision X(N), OBJF, OBJGRD(N), USER(*)
If
NCNLN
>
0
, the specification of the subroutine
CONFUN must also be changed as follows:
Old: SUBROUTINE CONFUN(MODE,NCNLN,N,NROWJ,X,C,CJAC,NSTATE)
INTEGER MODE, NCNLN, N, NROWJ, NSTATE
double precision X(N), C(NROWJ), CJAC(NROWJ,N)
New: SUBROUTINE CONFUN(MODE,NCNLN,N,NROWJ,NEEDC,X,C,CJAC,NSTATE,
+ IUSER,USER)
INTEGER MODE, NCNLN, N, NROWJ, NEEDC(NCNLN), NSTATE, IUSER(*)
double precision X(N), C(NCNLN), CJAC(NROWJ,N), USER(*)
If
NCNLN
=
0
, then the name of the dummy routine E04VDM/E54VDM (VDME04 in some implementations) may need to be changed to E04UDM (UDME04
in some implementations) in the calling program.
The parameter NCTOTL is no longer required. Values for ITMAX, MSGLVL, CTOL and FTOL may be supplied by calling an option
setting routine.
E04UCF/E04UCA contains four additional parameters as follows:
 ITER – INTEGER.

R(LDR,N)
– double precision array.

IUSER( * )
– INTEGER array of dimension at least 1.

USER( * )
– double precision array of dimension at least 1.
The minimum value of the parameter
LIWORK must be increased from
3
×
N
+
NCLIN
+
NCNLN
to
3
×
N
+
NCLIN
+
2
×
NCNLN
. The minimum value of the parameter
LWORK may also need to be changed. See the routine documents for further information.
F01 – Matrix Operations, Including Inversion
F01AAF
Withdrawn at Mark 17.
Replaced by
F07ADF (DGETRF) and
F07AJF (DGETRI).
Old: CALL F01AAF(A,IA,N,X,IX,WKSPCE,IFAIL)
New: CALL DGETRF(N,N,A,IA,IPIV,IFAIL)
CALL F06QFF('General',N,N,A,IA,X,IX)
CALL DGETRI(N,X,IX,IPIV,WKSPCE,LWORK,IFAIL)
where
IPIV is an INTEGER vector of length
N, and the INTEGER
LWORK is the length of array
WKSPCE, which must be at least
max (1,N)
. In the replacement calls,
F07ADF (DGETRF) computes the
LU
factorization of the matrix
A
,
F06QFF copies the factorization from
A to
X, and
F07AJF (DGETRI) overwrites
X by the inverse of
A
. If the original matrix
A
is no longer required, the call to
F06QFF is not necessary, and references to
X and
IX in the call of
F07AJF (DGETRI) may be replaced by references to
A and
IA, in which case
A will be overwritten by the inverse.
F01ACF
Withdrawn at Mark 16.
Replaced by
F01ABF.
Old: CALL F01ACF(N,EPS,A,IA,B,IB,Z,L,IFAIL)
New: CALL F01ABF(A,IA,N,B,IB,Z,IFAIL)
The number of iterative refinement corrections returned by
F01ACF in L is no longer available. The parameter EPS is no longer required.
F01AEF
Old: CALL F01AEF(N,A,IA,B,IB,DL,IFAIL)
New: DO 20 J = 1, N
DO 10 I = J, N
A(I,J) = A(J,I)
B(I,J) = B(J,I)
10 CONTINUE
DL(J) = B(J,J)
20 CONTINUE
CALL DPOTRF('L',N,B,IB,INFO)
IF (INFO.EQ.0) THEN
CALL DSYGST(1,'L',N,A,IA,B,IB,INFO)
ELSE
IFAIL = 1
END IF
CALL DSWAP(N,DL,1,B,IB+1)
IFAIL is set to 1 if the matrix
B
is not positivedefinite. It is essential to test IFAIL.
F01AFF
Withdrawn at Mark 18.
Replaced by
F06EGF (DSWAP) and
F06YJF (DTRSM).
Old: CALL F01AFF(N,M1,M2,B,IB,DL,Z,IZ)
New: CALL DSWAP(N,DL,1,B,IB+1)
CALL DTRSM('L','L','T','N',N,M2M1+1,1.0D0,B,IB,Z(1,M1),IZ)
CALL DSWAP(N,DL,1,B,IB+1)
F01AGF
Withdrawn at Mark 18.
Replaced by
F08FEF (DSYTRD).
Old: CALL F01AGF(N,TOL,A,IA,D,E,E2)
New: CALL DSYTRD('L',N,A,IA,D,E(2),TAU,WORK,LWORK,INFO)
E(1) = 0.0D0
DO 10 I = 1, N
E2(I) = E(I)*E(I)
10 CONTINUE
where
TAU is a
double precision array of length at least
(N  1)
,
WORK is a
real array of length at least (1) and
LWORK is its actual length.
Note that the tridiagonal matrix computed by
F08FEF (DSYTRD) is different from that computed by
F01AGF, but it has the same eigenvalues.
F01AHF
Withdrawn at Mark 18.
Replaced by
F08FGF (DORMTR).
The following replacement is valid only if the previous call to
F01AGF has been replaced by a call to
F08FEF (DSYTRD) as shown above.
Old: CALL F01AHF(N,M1,M2,A,IA,E,Z,IZ)
New: CALL DORMTR('L','L','N',N,M2M1+1,A,IA,TAU,Z(1,M1),IZ,WORK,
+ LWORK,INFO)
where
WORK is a
double precision array of length at least
(M2  M1 + 1)
, and
LWORK is its actual length.
F01AJF
Withdrawn at Mark 18.
Replaced by
F08FEF (DSYTRD) and
F08FFF (DORGTR).
Old: CALL F01AJF(N,TOL,A,IA,D,E,Z,IZ)
New: CALL DSYTRD('L',N,A,IA,D,E(2),TAU,WORK,LWORK,INFO)
E(1) = 0.0D0
CALL F06QFF('L',N,N,A,IA,Z,IZ)
CALL DORGTR('L',N,Z,IZ,TAU,WORK,LWORK,INFO)
where
TAU is a
double precision array of length at least
(N  1)
,
WORK is a
real array of length at least
(N  1)
and
LWORK is its actual length.
Note that the tridiagonal matrix
T
and the orthogonal matrix
Q
computed by
F08FEF (DSYTRD) and
F08FFF (DORGTR) are different from those computed by
F01AJF, but they satisfy the same relation
Q^{T}AQ = T
.
F01AKF
Withdrawn at Mark 18.
Replaced by
F08NEF (DGEHRD).
Old: CALL F01AKF(N,K,L,A,IA,INTGER)
New: CALL DGEHRD(N,K,L,A,IA,TAU,WORK,LWORK,INFO)
where
TAU is a
double precision array of length at least
(N  1)
,
WORK is a
real array of length at least
(N)
and
LWORK is its actual length.
Note that the Hessenberg matrix computed by
F08NEF (DGEHRD) is different from that computed by
F01AKF, because
F08NEF (DGEHRD) uses orthogonal transformations, whereas
F01AKF uses stabilized elementary transformations.
F01ALF
Withdrawn at Mark 18.
Replaced by
F08NGF (DORMHR).
The following replacement is valid only if the previous call to
F01AKF has been replaced by a call to
F08NEF (DGEHRD) as indicated above.
Old: CALL F01ALF(K,L,IR,A,IA,INTGER,Z,IZ,N)
New: CALL DORMHR('L','N',N,IR,K,L,A,IA,TAU,Z,IZ,WORK,LWORK,INFO)
where
WORK is a
double precision array of length at least
(IR)
and
LWORK is its actual length.
F01AMF
Withdrawn at Mark 18.
Replaced by
F08NSF (ZGEHRD).
Old: CALL F01AMF(N,K,L,AR,IAR,AI,IAI,INTGER)
New: DO 20 J = 1, N
DO 10 I = 1, N
A(I,J) = cmplx(AR(I,J),AI(I,J))
10 CONTINUE
20 CONTINUE
CALL ZGEHRD(N,K,L,A,IA,TAU,WORK,LWORK,INFO)
where
A is a
complex*16 array of dimension
(IA,N)
,
TAU is a
complex*16 array of length at least
(N  1)
,
WORK is a
complex*16 array of length at least
(N)
and
LWORK is its actual length.
Note that the Hessenberg matrix computed by
F08NSF (ZGEHRD) is different from that computed by
F01AMF, because
F08NSF (ZGEHRD) uses orthogonal transformations, whereas
F01AMF uses stabilized elementary transformations.
F01ANF
Withdrawn at Mark 18.
Replaced by
F08NUF (ZUNMHR).
The following replacement is valid only if the previous call to
F01AMF has been replaced by a call to
F08NSF (ZGEHRD) as indicated above.
Old: CALL F01ANF(K,L,IR,AR,IAR,AI,IAI,INTGER,ZR,IZR,ZI,IZI,N)
New: CALL ZUNMHR('L','N',N,IR,K,L,A,IA,TAU,Z,IZ,WORK,LWORK,INFO)
DO 20 J = 1, IR
DO 10 I = 1, N
ZR(I,J) = real(Z(I,J))
ZI(I,J) = imag(Z(I,J))
10 CONTINUE
20 CONTINUE
where
A is a
complex*16 array of dimension
(IA,N)
,
TAU is a
complex*16 array of length at least
(N  1)
,
Z is a
complex*16 array of dimension
(IZ,IR)
,
WORK is a
complex*16 array of length at least
(IR)
and
LWORK is its actual length.
F01APF
Withdrawn at Mark 18.
Replaced by
F06QFF and
F08NFF (DORGHR).
The following replacement is valid only if the previous call to
F01AKF has been replaced by a call to
F08NEF (DGEHRD) as indicated above.
Old: CALL F01APF(N,K,L,INTGER,H,IH,V,IV)
New: CALL F06QFF('L',N,N,H,IH,V,IV)
CALL DORGHR(N,K,L,V,IV,TAU,WORK,LWORK,INFO)
where
WORK is a
double precision array of length at least
(N)
, and
LWORK is its actual length.
Note that the orthogonal matrix formed by
F08NFF (DORGHR) is not the same as the nonorthogonal matrix formed by
F01APF. See
F01AKF above.
F01ATF
Withdrawn at Mark 18.
Replaced by
F08NHF (DGEBAL).
Old: CALL F01ATF(N,IB,A,IA,K,L,D)
New: CALL DGEBAL('B',N,A,IA,K,L,D,INFO)
Note that the balanced matrix returned by
F08NHF (DGEBAL) may be different from that returned by
F01ATF.
F01AUF
Withdrawn at Mark 18.
Replaced by
F08NJF (DGEBAK).
Old: CALL F01AUF(N,K,L,M,D,Z,IZ)
New: CALL DGEBAK('B','R',N,K,L,D,M,Z,IZ,INFO)
F01AVF
Withdrawn at Mark 18.
Replaced by
F08NVF (ZGEBAL).
Old: CALL F01AVF(N,IB,AR,IAR,AI,IAI,K,L,D)
New: DO 20 J = 1, N
DO 10 I = 1, N
A(I,J) = cmplx(AR(I,J),AI(I,J))
10 CONTINUE
20 CONTINUE
CALL ZGEBAL('B',N,A,IA,K,L,D,INFO)
DO 20 J = 1, N
DO 10 I = 1, N
AR(I,J) = real(A(I,J))
AI(I,J) = imag(A(I,J))
10 CONTINUE
20 CONTINUE
where
A is a
complex*16 array of dimension
(IA,N)
.
Note that the balanced matrix returned by
F08NVF (ZGEBAL) may be different from that returned by
F01AVF.
F01AWF
Withdrawn at Mark 18.
Replaced by
F08NWF (ZGEBAK).
Old: CALL F01AWF(N,K,L,M,D,ZR,IZR,ZI,IZI)
New: DO 20 J = 1, M
DO 10 I = 1, N
Z(I,J) = cmplx(ZR(I,J),ZI(I,J))
10 CONTINUE
20 CONTINUE
CALL ZGEBAK('B','R',N,K,L,D,M,Z,IZ,INFO)
DO 40 J = 1, M
DO 30 I = 1, N
ZR(I,J) = real(Z(I,J))
ZI(I,J) = imag(Z(I,J))
30 CONTINUE
40 CONTINUE
where
Z is a
complex*16 array of dimension
(IZ,M)
.
F01AXF
Withdrawn at Mark 18.
Replaced by
F06EFF (DCOPY) and
F08BEF (DGEQPF).
Old: CALL F01AXF(M,N,QR,IQR,ALPHA,IPIV,Y,E,IFAIL)
New: CALL DGEQPF(M,N,QR,IQR,IPIV,Y,WORK,INFO)
CALL DCOPY(N,QR,IQR+1,ALPHA,1)
where
WORK is a
double precision array of length at least
(3 × N)
.
Note that the details of the Householder matrices returned by
F08BEF (DGEQPF) are different from those returned by
F01AXF, but they determine the same orthogonal matrix
Q
.
F01AYF
Withdrawn at Mark 18.
Replaced by
F08GEF (DSPTRD).
Old: CALL F01AYF(N,TOL,A,IA,D,E,E2)
New: CALL DSPTRD('U',N,A,D,E(2),TAU,INFO)
E(1) = 0.0D0
DO 10 I = 1, N
E2(I) = E(I)*E(I)
10 CONTINUE
where
TAU is a
double precision array of length at least
(N  1)
.
F01AZF
Withdrawn at Mark 18.
Replaced by
F08GGF (DOPMTR).
The following replacement is valid only if the previous call to
F01AYF has been replaced by a call to
F08GEF (DSPTRD) as shown above.
Old: CALL F01AZF(N,M1,M2,A,IA,Z,IZ)
New: CALL DOPMTR('L','U','N',N,M2M1+1,A,TAU,Z(1,M1),IZ,WORK,INFO)
where
WORK is a
double precision array of length at least
(M2  M1 + 1)
.
F01BCF
Withdrawn at Mark 18.
Replaced by
F08FSF (ZHETRD) and
F08FTF (ZUNGTR).
Old: CALL F01BCF(N,TOL,AR,IAR,AI,IAI,D,E,WK1,WK2)
New: DO 20 J = 1, N
DO 10 I = 1, N
A(I,J) = cmplx(AR(I,J),AI(I,J))
10 CONTINUE
20 CONTINUE
CALL ZHETRD('L',N,A,IA,D,E(2),TAU,WORK,LWORK,INFO)
E(1) = 0.0D0
CALL ZUNGTR('L',N,A,IA,TAU,WORK,LWORK,INFO)
DO 40 J = 1, N
DO 30 I = 1, N
AR(I,J) = real(A(I,J))
AI(I,J) = imag(A(I,J))
30 CONTINUE
40 CONTINUE
where
A is a
complex*16 array of dimension
(IA,N)
,
TAU is a
complex*16 array of length at least
(N  1)
,
WORK is a
complex*16 array of length at least
(N  1)
, and
LWORK is its actual length.
Note that the tridiagonal matrix
T
and the unitary matrix
Q
computed by
F08FSF (ZHETRD) and
F08FTF (ZUNGTR) are different from those computed by
F01BCF, but they satisfy the same relation
Q^{H}AQ = T
.
F01BDF
Old: CALL F01BDF(N,A,IA,B,IB,DL,IFAIL)
New: DO 20 J = 1, N
DO 10 I = J, N
A(I,J) = A(J,I)
B(I,J) = B(J,I)
10 CONTINUE
DL(J) = B(J,J)
20 CONTINUE
CALL DPOTRF('L',N,B,IB,INFO)
IF (INFO.EQ.0) THEN
CALL DSYGST(2,'L',N,A,IA,B,IB,INFO)
ELSE
IFAIL = 1
END IF
CALL DSWAP(N,DL,1,B,IB+1)
IFAIL is set to 1 if the matrix
B is not positivedefinite. It is essential to test IFAIL.
F01BEF
Withdrawn at Mark 18.
Replaced by
F06YFF (DTRMM).
Old: CALL F01BEF(N,M1,M2,B,IB,DL,V,IV)
New: CALL DSWAP(N,DL,1,B,IB+1)
CALL DTRMM('L','L','N','N',N,M2M1+1,1.0D0,B,IB,V(1,M1),IV)
CALL DSWAP(N,DL,1,B,IB+1)
F01BNF
Withdrawn at Mark 17.
Replaced by
F07FRF (ZPOTRF).
Old: CALL F01BNF(N,A,IA,P,IFAIL)
New: CALL ZPOTRF('Upper',N,A,IA,IFAIL)
where, before the call, array
A contains the upper triangle of the matrix to be factorized rather than the lower triangle (note that the elements of the
upper triangle are the complex conjugates of the elements of the lower triangle). The
double precision array P is no longer required; the upper triangle of
A is overwritten by the upper triangular factor
U
, including the diagonal elements (which are not reciprocated).
F01BPF
Withdrawn at Mark 17.
Replaced by
F07FRF (ZPOTRF) and
F07FWF (ZPOTRI).
Old: CALL F01BPF(N,A,IA,V,IFAIL)
New: CALL ZPOTRF('Upper',N,A,IA,IFAIL)
CALL ZPOTRI('Upper',N,A,IA,IFAIL)
where, before the calls, the upper triangle of the matrix to be inverted must be contained in rows 1 to
N of
A, rather than the lower triangle being in rows 2 to
N + 1
(note that the elements of the upper triangle are the complex conjugates of the elements of the lower triangle). The workspace
vector V is no longer required.
F01BQF
Withdrawn at Mark 16.
Replaced by
F07GDF (DPPTRF) and
F07PDF (DSPTRF).
The replacement routines do not have exactly the same functionality as
F01BQF; if this functionality is genuinely required, please contact
NAG.
(a) 
where the symmetric matrix is known to be positivedefinite (if the matrix is in fact not positivedefinite, the replacement
routine will return a positive value in IFAIL)
Old: CALL F01BQF(N,EPS,RL,IRL,D,IFAIL)
New: CALL DPPTRF('Lower',N,RL,IFAIL) 
(b) 
where the matrix is not positivedefinite (the replacement routine forms an
LDL^{T}
factorization where
D
is block diagonal, rather than a Cholesky factorization)
Old: CALL F01BQF(N,EPS,RL,IRL,D,IFAIL)
New: CALL DSPTRF('Lower',N,RL,IPIV,IFAIL) 
For the replacement calls in both (a) and (b), the array
RL must now hold the complete lower triangle of the symmetric matrix, including the diagonal elements, which are no longer required
to be stored in the redundant array D. The declared dimension of
RL must be increased from at least
N(N  1)
/ 2
to at least
N(N + 1)
/ 2
. It is important to note that for the calls of
F07GDF (DPPTRF) and
F07PDF (DSPTRF), the lower triangle of the matrix must be stored packed by column instead of by row. The dimension parameter IRL is no longer
required. For the call of
F07PDF (DSPTRF), the INTEGER array
IPIV of length
N must be supplied.
F01BTF
Withdrawn at Mark 18.
Replaced by
F07ADF (DGETRF).
Old: CALL F01BTF(N,A,IA,P,DP,IFAIL)
New: CALL DGETRF(N,N,A,IA,IPIV,IFAIL)
where
IPIV is an INTEGER array of length
N which holds the indices of the pivot elements, and the array P is no longer required. It may be important to note that after
a call of
F07ADF (DGETRF),
A is overwritten by the upper triangular factor
U
and the offdiagonal elements of the unit lower triangular factor
L
, whereas the factorization returned by
F01BTF gives
U
the unit diagonal. The permutation determinant DP returned by
F01BTF is not computed by
F07ADF (DGETRF). If this value is required, it may be calculated after a call of
F07ADF (DGETRF) by code similar to the following:
DP = 1.0D0
DO 10 I = 1, N
IF (I.NE.IPIV(I)) DP = DP
10 CONTINUE
F01BWF
Withdrawn at Mark 18.
Replaced by
F08HEF (DSBTRD).
Old: CALL F01BWF(N,M1,A,IA,D,E)
New: CALL DSBTRD('N','U',N,M11,A,IA,D,E(2),Q,1,WORK,INFO)
E(1) = 0.0D0
where
Q is a dummy
double precision array of length (1) (not used in this call), and
WORK is a
double precision array of length at least
(N)
.
Note that the tridiagonal matrix computed by
F08HEF (DSBTRD) is different from that computed by
F01BWF, but it has the same eigenvalues.
F01BXF
Withdrawn at Mark 17.
Replaced by
F07FDF (DPOTRF).
Old: CALL F01BXF(N,A,IA,P,IFAIL)
New: CALL DPOTRF('Upper',N,A,IA,IFAIL)
where, before the call, array
A contains the upper triangle of the matrix to be factorized rather than the lower triangle. The array P is no longer required;
the upper triangle of
A is overwritten by the upper triangular factor
U
, including the diagonal elements (which are not reciprocated).
F01CDF
Withdrawn at Mark 15.
Replaced by
F01CTF.
Old: CALL F01CDF(A,B,C,M,N,IFAIL)
New: CALL F01CTF('N','N',M,N,1.0D0,B,M,1.0D0,C,M,A,M,IFAIL)
F01CEF
Withdrawn at Mark 15.
Replaced by
F01CTF.
Old: CALL F01CEF(A,B,C,M,N,IFAIL)
New: CALL F01CTF('N','N',M,N,1.0D0,B,M,1.0D0,C,M,A,M,IFAIL)
F01CGF
Withdrawn at Mark 15.
Replaced by
F01CTF.
Old: CALL F01CGF(A,MA,NA,P,Q,B,MB,NB,M1,M2,N1,N2,IFAIL)
New: CALL F01CTF('N','N',M2M1+1,N2N1+1,1.0D0,A(P,Q),MA,1.0D0,
+ B(M1,N1),MB,A(P,Q),MA,IFAIL)
F01CHF
Withdrawn at Mark 15.
Replaced by
F01CTF.
Old: CALL F01CHF(A,MA,NA,P,Q,B,MB,NB,M1,M2,N1,N2,IFAIL)
New: CALL F01CTF('N','N',M2M1+1,N2N1+1,1.0D0,A(P,Q),MA,1.0D0,
+ B(M1,N1),MB,A(P,Q),MA,IFAIL)
F01CLF
Withdrawn at Mark 16.
Replaced by
F06YAF (DGEMM).
Old: CALL F01CLF(A,B,C,N,P,M,IFAIL)
New: CALL DGEMM('N','T',N,P,M,1.0D0,B,N,C,P,0.0D0,A,N)
F01LBF
Withdrawn at Mark 18.
Replaced by
F07BDF (DGBTRF).
Old: CALL F01LBF(N,M1,M2,A,IA,AL,IL,IN,IV,IFAIL)
New: CALL DGBTRF(N,N,M1,M2,A,IA,IN,IFAIL)
where the size of array
A must now have a leading dimension
IA of at least
2 × M1 + M2 + 1
. The array AL, its associated dimension parameter IL, and the parameter IV are not required for
F07BDF (DGBTRF) because this routine overwrites
A by both the
L
and
U
factors. The scheme by which the matrix is packed into the array is completely different from that used by
F01LBF; the relevant routine document should be consulted for details.
F01LZF
Old: CALL F01LZF(N,A,NRA,C,NRC,WANTB,B,WANTQ,WANTY,Y,NRY,LY,WANTZ,Z,
+ NRZ,NCZ,D,E,WORK1,WORK2,IFAIL)
New: CALL DGEBRD(N,N,A,NRA,D,E(2),TAUQ,TAUP,WORK1,LWORK,INFO)
IF (WANTB) THEN
CALL DORMBR('Q','L','T',N,1,NA,NRA,TAUQ,B,N,WORK1,LWORK,INFO)
ELSE IF (WANTQ) THEN
CALL DORGBR('Q',N,N,N,A,NRA,TAUQ,WORK,LWORK,INFO)
ELSE IF (WANTY) THEN
CALL DORMBR('Q','R','N',LY,N,N,A,NRA,TAUQ,Y,NRY,WORK1,LWORK,
+ INFO)
ELSE IF (WANTZ) THEN
CALL DORMBR('P','L','T',N,NCZ,N,A,NRA,TAUP,Z,NRZ,WORK1,LWORK,
+ INFO)
END IF
where
TAUQ and
TAUP are real arrays of length at least
(N)
and
LWORK is the actual length of
WORK1. The parameter WORK2 is no longer required.
F01MAF
Withdrawn at Mark 19.
Replaced by
F11JAF.
Existing programs should be modified to call
F11JAF. The interfaces are significantly different and therefore precise details of a replacement call cannot be given. Please
consult the appropriate routine document.
F01NAF
Withdrawn at Mark 17.
Replaced by
F07BRF (ZGBTRF).
Old: CALL F01NAF(N,ML,MU,A,NRA,TOL,IN,SCALE,IFAIL)
New: CALL ZGBTRF(N,N,ML,MU,A,NRA,IN,IFAIL)
where the parameter TOL and array SCALE are no longer required. The input matrix must be stored using the same scheme as
for
F01NAF, except in rows
ML
+
1
to
2
×
ML
+
MU
+
1
of
A instead of rows 1 to
ML
+
MU
+
1
. In
F07BRF (ZGBTRF), the value returned in
IN(N)
has no significance as an indicator of nearsingularity of the matrix.
F01QAF
Withdrawn at Mark 15.
Replaced by
F08AEF (DGEQRF).
Old: CALL F01QAF(M,N,A,NRA,C,NRC,Z,IFAIL)
New: CALL DGEQRF(M,N,A,NRA,Z,WORK,LWORK,INFO)
where
WORK is a real array of length at least
(LWORK)
. The parameters C and NRC are no longer required.
Note that the representation of the matrix
Q
is not identical, but subsequent calls to routines
F08AFF (DORGQR) and
F08AGF (DORMQR) may be used to obtain
Q
explicitly and to transform by
Q
or
Q^{T}
respectively.
F01QBF
Withdrawn at Mark 15.
Replaced by
F01QJF.
Old: CALL F01QBF(M,N,A,NRA,C,NRC,WORK,IFAIL)
New: CALL F06QFF('General',M,N,A,NRA,C,NRC)
CALL F01QJF(M,N,C,NRC,WORK,IFAIL)
The call to
F06QFF simply copies the leading
M by
N part of
A to
C. This may be omitted if it is desired to use the same arrays for
A and
C. Note that the representation of the orthogonal matrix
Q
is not identical, but following
F01QJF routine
F01QKF may be used to form
Q
.
F01QCF
Withdrawn at Mark 18.
Replaced by
F08AEF (DGEQRF).
Old: CALL F01QCF(M,N,A,LDA,ZETA,IFAIL)
New: CALL DGEQRF(M,N,A,LDA,ZETA,WORK,LWORK,INFO)
where
WORK is a
double precision array of length at least
(N), and
LWORK is its actual length.
The subdiagonal elements of
A and the elements of
ZETA returned by
F08AEF (DGEQRF) are not the same as those returned by
F01QCF. Subsequent calls to
F01QDF or
F01QEF must also be replaced by calls to
F08AFF (DORGQR) or
F08AGF (DORMQR) as shown below.
F01QDF
Withdrawn at Mark 18.
Replaced by
F08AGF (DORMQR).
The following replacement is valid only if the previous call to
F01QCF has been replaced by a call to
F08AEF (DGEQRF) as shown above. It also assumes that the second argument of
F01QDF (WHERET) is 'S', which is appropriate if the contents of
A and
ZETA have not been changed after the call of
F01QCF.
Old: CALL F01QDF(TRANS,'S',M,N,A,LDA,ZETA,NCOLB,B,LDB,WORK,IFAIL)
New: CALL DORMQR('L',TRANS,M,NCOLB,N,A,LDA,ZETA,B,LDB,WORK,LWORK,INFO)
where
LWORK is the actual length of
WORK.
F01QEF
Withdrawn at Mark 18.
Replaced by
F08AFF (DORGQR).
The following replacement is valid only if the previous call to
F01QCF has been replaced by a call to
F08AEF (DGEQRF) as shown above. It also assumes that the first argument of
F01QEF (WHERET) is 'S', which is appropriate if the contents of
A and
ZETA have not been changed after the call of
F01QCF.
Old: CALL F01QEF('S',M,N,NCOLQ,A,LDA,ZETA,WORK,IFAIL)
New: CALL DORGQR(M,NCOLQ,N,A,LDA,ZETA,WORK,LWORK,INFO)
where
LWORK is the actual length of
WORK.
F01QFF
Withdrawn at Mark 18.
Replaced by
F08BEF (DGEQPF).
The following replacement assumes that the 1st argument of
F01QFF (PIVOT) is 'C'. There is no direct replacement if PIVOT
=
'S'.
Old: CALL F01QFF('C',M,N,A,LDA,ZETA,PERM,WORK,IFAIL)
New: DO 10 I = 1, N
PERM(I) = 0
10 CONTINUE
CALL DGEQPF(M,N,A,LDA,PERM,ZETA,WORK,INFO)
where
WORK is a
double precision array of length at least
(3 × N)
(
F01QFF only requires
WORK to be of length
(2 × N)
).
The subdiagonal elements of
A and the elements of
ZETA returned by
F08BEF (DGEQPF) are not the same as those returned by
F01QFF. Subsequent calls to
F01QDF or
F01QEF must also be replaced by calls to
F08AGF (DORMQR) or
F08AFF (DORGQR) as shown above. Note also that the array
PERM returned by
F08BEF (DGEQPF) holds details of the interchanges in a different form than that returned by
F01QFF.
F01RCF
Withdrawn at Mark 18.
Replaced by
F08ASF (ZGEQRF).
Old: CALL F01RCF(M,N,A,LDA,THETA,IFAIL)
New: CALL ZGEQRF(M,N,A,LDA,THETA,WORK,LWORK,INFO)
where
WORK is a
complex*16 array of length at least
(N)
, and
LWORK is its actual length.
The subdiagonal elements of
A and the elements of
THETA returned by
F08ASF (ZGEQRF) are not the same as those returned by
F01RCF. Subsequent calls to
F01RDF or
F01REF must also be replaced by calls to
F08AUF (ZUNMQR) or
F08ATF (ZUNGQR) as shown below.
F01RDF
Withdrawn at Mark 18.
Replaced by
F08AUF (ZUNMQR).
The following replacement is valid only if the previous call to
F01RCF has been replaced by a call to
F08ASF (ZGEQRF) as shown above. It also assumes that the second argument of
F01RDF (WHERET) is 'S', which is appropriate if the contents of
A and
THETA have not been changed after the call of
F01RCF.
Old: CALL F01RDF(TRANS,'S',M,N,A,LDA,THETA,NCOLB,B,LDB,WORK,IFAIL)
New: CALL ZUNMQR('L',TRANS,M,NCOLB,N,A,LDA,THETA,B,LDB,WORK,LWORK,
+ INFO)
where
LWORK is the actual length of
WORK.
F01REF
Withdrawn at Mark 18.
Replaced by
F08ATF (ZUNGQR).
The following replacement is valid only if the previous call to
F01RCF has been replaced by a call to
F08ASF (ZGEQRF) as shown above. It also assumes that the first argument of
F01REF WHERET = 'S', which is appropriate if the contents of
A and
THETA have not been changed after the call of
F01RCF.
Old: CALL F01REF('S',M,N,NCOLQ,A,LDA,THETA,WORK,IFAIL)
New: CALL ZUNGQR(M,NCOLQ,N,A,LDA,THETA,WORK,LWORK,INFO)
where
LWORK is the actual length of
WORK.
F01RFF
Withdrawn at Mark 18.
Replaced by
F08BSF (ZGEQPF).
The following replacement assumes that the first argument of
F01RFF (PIVOT) is 'C'. There is no direct replacement if
PIVOT = 'S'.
Old: CALL F01RFF('C',M,N,A,LDA,THETA,PERM,WORK,IFAIL)
New: DO 10 I = 1, N
PERM(I) = 0
10 CONTINUE
CALL ZGEQPF(M,N,A,LDA,PERM,THETA,CWORK,WORK,INFO)
where
CWORK is a
complex*16 array of length at least
(N)
.
The subdiagonal elements of
A and the elements of
THETA returned by
F08BSF (ZGEQPF) are not the same as those returned by
F01RFF. Subsequent calls to
F01RDF or
F01REF must also be replaced by calls to
F08AUF (ZUNMQR) or
F08ATF (ZUNGQR) as shown above. Note also that the array
PERM returned by
F08BSF (ZGEQPF) holds details of the interchanges in a different form than that returned by
F01RFF.
F02 – Eigenvalues and Eigenvectors
F02AAF
Withdrawn at Mark 18.
Replaced by
F08FAF (DSYEV).
Old: CALL F02AAF(A,IA,N,R,E,IFAIL)
New: CALL DSYEV('N','L',N,A,IA,R,WORK,LWORK,INFO)
IF (INFO.NE.0) THEN
...
where
WORK is a
double precision array of length at least
(3 × N)
and
LWORK is its actual length. Larger values of
LWORK, up to some optimal value, may improve performance.
F02ABF
Withdrawn at Mark 18.
Replaced by
F08FAF (DSYEV).
Old: CALL F02ABF(A,IA,N,R,V,IV,E,IFAIL)
New: CALL F06QFF('L',N,N,A,IA,V,IV)
CALL DSYEV('V','L',N,V,IV,R,WORK,LWORK,INFO)
IF (INFO.NE.0) THEN
...
where
WORK is a
double precision array of length at least
(3 × N) and
LWORK is its actual length. Larger values of
LWORK, up to some optimal value, may improve performance. If
F02ABF was called with the same array supplied for V and A, then the call to
F06QFF may be omitted.
F02ADF
Withdrawn at Mark 18.
Replaced by
F08SAF (DSYGV).
Old: CALL F02ADF(A,IA,B,IB,N,R,DE,IFAIL)
New: CALL DSYGV(1,'N','U',N,A,IA,B,IB,R,WORK,LWORK,INFO)
IF (INFO.NE.0) THEN
...
where
WORK is a
double precision array of length at least
(3 × N) and
LWORK is its actual length. Larger values of
LWORK, up to some optimal value, may improve performance.
Note that the call to
F08SAF (DSYGV) will overwrite the upper triangles of the arrays
A and
B and leave the subdiagonal elements unchanged, whereas the call to
F02ADF overwrites the lower triangle and leaves the elements above the diagonal unchanged.
F02AEF
Withdrawn at Mark 18.
Replaced by
F08SAF (DSYGV).
Old: CALL F02AEF(A,IA,B,IB,N,R,V,IV,DL,E,IFAIL)
New: CALL F06QFF('U',N,N,A,IA,V,IV)
CALL DSYGV(1,'V','U',N,V,IV,B,IB,R,WORK,LWORK,INFO)
IF (INFO.NE.0) THEN
...
where
WORK is a
double precision array of length at least
(3 × N) and
LWORK is its actual length.
Note that the call to
F08SAF (DSYGV) will overwrite the upper triangle of the array
B and leave the subdiagonal elements unchanged, whereas the call to
F02AEF overwrites the lower triangle and leaves the elements above the diagonal unchanged. The call to
F06QFF copies A to
V, so
A is left unchanged. If
F02AEF was called with the same array supplied for V and A, then the call to
F06QFF may be omitted.
F02AFF
Withdrawn at Mark 18.
Replaced by
F08NAF (DGEEV).
Old: CALL F02AFF(A,IA,N,RR,RI,INTGER,IFAIL)
New: CALL DGEEV('N','N',N,A,IA,RR,RI,VR,1,VI,1,
+ WORK,LWORK,INFO)
IF (INFO.EQ.0) THEN
....
where
VR and
VI are dummy arrays of length (1) (not used in this call),
WORK is a
double precision array of length at least
(4 × N) and
LWORK is its actual length; the iteration counts (returned by
F02AFF in the array INTGER) are not available from
F08NAF (DGEEV). Larger values of
LWORK, up to some optimal value, may improve performance.
F02AGF
Withdrawn at Mark 18.
Replaced by
F08NAF (DGEEV).
Old: CALL F02AGF(A,IA,N,RR,RI,VR,IVR,VI,IVI,INTGER,IFAIL)
New: CALL DGEEV(('N','V',N,A,IA,RR,RI,VL,LDVL,VR1,LDVR1,
+ WORK,LWORK,INFO)
IF (INFO.EQ.0) THEN
C Eigenvector infomation is stored differently in VR1
C VR(j)=VR1(j) if RI(j) = 0.0
C VR(j)=VR1(j) and VI(j)=VR1(j+1) and
C VR(j+1)=VR1(j) and VI(j+1) =  VR1(j+1) if RI(j)/= (not equals) 0 and
C RI(j) = RI(j+1)
....
where
WORK is a
double precision array of length at least
(4 × N) and
LWORK is its actual length; the iteration counts (returned by
F02AGF in the array INTGER) are not available from
F08NAF (DGEEV). Larger values of
LWORK, up to some optimal value, may improve performance.
F02AJF
Withdrawn at Mark 18.
Replaced by
F08NNF (ZGEEV).
Old: CALL F02AJF(AR,IAR,AI,IAI,N,RR,RI,INTGER,IFAIL)
New: DO 20 J = 1, N
DO 10 I = 1, N
A(I,J) = cmplx(AR(I,J),AI(I,J))
10 CONTINUE
20 CONTINUE
CALL ZGEEV('N','N',N,A,LDA,R,VL,1,VR,1,WORK,
+ LWORK,RWORK,INFO)
IF (INFO.EQ.0) THEN
DO 30 I = 1, N
RR(I) = real(R(I))
RI(I) = imag(R(I))
30 CONTINUE
....
where
A is a
complex*16 array of dimension
(LDA,N),
LDA must be at least
max (1,N),
R is a
complex*16 array of dimension (
N),
VR and
VL are dummy
complex*16 array of length (1) (not used in this call),
RWORK is a
double precision array of length at least
(2 × N),
WORK is a
complex*16 array of length at least
(2 × N) and
LWORK is its actual length. Larger values of
LWORK, up to some optimal value, may improve performance. The iteration counts (returned by
F02AJF in the array INTGER) are not available from
F08NNF (ZGEEV).
F02AKF
Withdrawn at Mark 18.
Replaced by
F08NNF (ZGEEV).
Old: CALL F02AKF(AR,IAR,AI,IAI,N,RR,RI,VR,IVR,VI,IVI,INTGER,IFAIL)
New: DO 20 J = 1, N
DO 10 I = 1, N
A(I,J) = cmplx(AR(I,J),AI(I,J))
10 CONTINUE
20 CONTINUE
CALL ZGEEV('N','V',N,A,LDA,R,VL,LDVL,VR1,LDVR,
+ WORK,LWORK,RWORK,INFO)
IF (INFO.EQ.0) THEN
DO 40 J = 1, N
RR(J) = real(R(J))
RI(J) = imag(R(J))
DO 30 I = 1, N
VR(I,J) = real(VR1(I,J))
VI(I,J) = imag(VR1(I,J))
30 CONTINUE
40 CONTINUE
....
where
A is a
complex*16 array of dimension
(LDA,N),
LDA is at least
max (1,N),
R is a
complex*16 array of length (
N),
VL is a
complex*16 array of dimension (1,1),
LDVL is 1,
VR1 is a
complex*16 array of dimension
(LDVR,N),
LDVR is at least
max (1,N),
RWORK is a
double precision array of length at least
(2 × N),
WORK is a
complex*16 array of length at least
(2 × N) and
LWORK is its actual length. Larger values of
LWORK, up to some optimal value, may improve performance. The iteration counts (returned by
F02AKF in the array INTGER) are not available from
F08NNF (ZGEEV).
F02AMF
Withdrawn at Mark 18.
Replaced by
F08JEF (DSTEQR).
Old: CALL F02AMF(N,EPS,D,E,V,IV,IFAIL)
New: CALL DSTEQR('V',N,D,E(2),V,IV,WORK,INFO)
where
WORK is a
double precision array of length at least
(2(N  1))
.
F02ANF
Withdrawn at Mark 18.
Replaced by
F08PSF (ZHSEQR).
Old: CALL F02ANF(N,EPS,HR,IHR,HI,IHI,RR,RI,IFAIL)
New: DO 20 J = 1, N
DO 10 I = 1, N
H(I,J) = cmplx(HR(I,J),HI(I,J))
10 CONTINUE
20 CONTINUE
CALL ZHSEQR('E','N',N,1,N,H,IH,R,Z,1,WORK,1,INFO)
DO 30 I = 1, N
RR(I) = real(R(I))
RI(I) = imag(R(I))
30 CONTINUE
where
H is a
complex*16 array of dimension
(IH,N)
,
R is a
complex*16 array of length (
N),
Z is a dummy
complex*16 array of length (1) (not used in this call), and
WORK is a
complex*16 array of length at least
(N)
.
F02APF
Withdrawn at Mark 18.
Replaced by
F08PEF (DHSEQR).
Old: CALL F02APF(N,EPS,H,IH,RR,RI,ICNT,IFAIL)
New: CALL DHSEQR('E','N',N,1,N,H,IH,RR,RI,Z,1,WORK,1,INFO)
where
Z is a dummy
double precision array of length (1) (not used in this call), and
WORK is a
double precision array of length at least
(3 × N)
; the iteration counts (returned by
F02APF in the array ICNT) are not available from
F08PEF (DHSEQR).
F02AQF
Withdrawn at Mark 18.
Replaced by
F08PEF (DHSEQR) and
F08QKF (DTREVC).
Old: CALL F02AQF(N,K,L,EPS,H,IH,V,IV,RR,RI,INTGER,IFAIL)
New: CALL DHSEQR('S','V',N,K,L,H,IH,RR,RI,V,IV,WORK,1,INFO)
CALL DTREVC('R','O',SELECT,N,H,IH,V,IV,V,IV,N,M,WORK,INFO)
where
SELECT is a dummy logical array of length (1) (not used in this call), and
WORK is a
double precision array of length at least
(3 × N)
; the iteration counts (returned by
F02AQF in the array INTGER) are not available from
F08PEF (DHSEQR);
M is an integer which is set to
N by
F08QKF (DTREVC).
F02ARF
Withdrawn at Mark 18.
Replaced by
F08PSF (ZHSEQR) and
F08QXF (ZTREVC).
Old: CALL F02ARF(N,K,L,EPS,INTGER,HR,IHR,HI,IHI,RR,RI,VR,IVR,VI,
+ IVI, IFAIL)
New: DO 20 J = 1, N
DO 10 I = 1, N
H(I,J) = cmplx(HR(I,J),HI(I,J))
10 CONTINUE
20 CONTINUE
CALL ZHSEQR('S','V',N,K,L,H,IH,R,V,IV,WORK,1,INFO)
CALL ZTREVC('R','O',SELECT,N,H,IH,V,IV,V,IV,N,M,WORK,RWORK,INFO)
DO 40 J = 1, N
RR(J) = real(R(J))
RI(J) = imag(R(J))
DO 30 I = 1, N
VR(I,J) = real(V(I,J))
VI(I,J) = imag(V(I,J))
30 CONTINUE
40 CONTINUE
where
H is a
complex*16 array of dimension
(IH,N)
,
R is a
complex*16 array of length (
N),
V is a
complex*16 array of dimension
(IV,N)
,
WORK is a
complex*16 array of length at least
(2 × N)
and
RWORK is a
double precision array of length at least
(N)
;
M is an integer which is set to
N by
F08QXF (ZTREVC).
If
F02ARF was preceded by a call to
F01AMF to reduce a full complex matrix to Hessenberg form, then the call to
F01AMF must also be replaced by calls to
F08NSF (ZGEHRD) and
F08NTF (ZUNGHR).
IH must be
≥ max (1,N) and
IV must be
≥ max (1,N).
F02AVF
Withdrawn at Mark 18.
Replaced by
F08JFF (DSTERF).
Old: CALL F02AVF(N,EPS,D,E,IFAIL)
New: CALL DSTERF(N,D,E(2),INFO)
F02AWF
Withdrawn at Mark 18.
Replaced by
F08FNF (ZHEEV).
Old: CALL F02AWF(AR,IAR,AI,IAI,N,R,WK1,WK2,WK3,IFAIL)
New: DO 20 J = 1, N
DO 10 I = 1, N
A(I,J) = cmplx(AR(I,J),AI(I,J))
10 CONTINUE
20 CONTINUE
CALL ZHEEV('N','L',N,A,LDA,R,WORK,LWORK,RWORK,INFO)
IF (INFO.EQ.0) THEN
...
where
A is a
complex*16 array of dimension
(LDA,N),
LDA is at least
max (1,N) RWORK is a
double precision array of length at least
max (1,3 × N  2),
WORK is a
complex*16 array of length at least
(2 × N) and
LWORK is its actual length. Larger values of
LWORK, up to some optimal value, may improve performance.
F02AXF
Withdrawn at Mark 18.
Replaced by
F08FNF (ZHEEV).
Old: CALL F02AXF(AR,IAR,AI,IAI,N,R,VR,IVR,VI,IVI,WK1,WK2,WK3,IFAIL)
New: DO 20 J = 1, N
DO 10 I = 1, N
A(I,J) = cmplx(AR(I,J),AI(I,J))
10 CONTINUE
20 CONTINUE
CALL F06TFF('L',N,N,A,LDA,V,LDV)
CALL ZHEEV('V','L',N,V,LDV,R,WORK,LWORK,RWORK,INFO)
IF (INFO.EQ.0) THEN
DO 40 J = 1, N
DO 30 I = 1, N
VR(I,J) = real(V(I,J))
VI(I,J) = imag(V(I,J))
30 CONTINUE
40 CONTINUE
...
where
A is a
complex*16 array of dimension
(LDA,N)
,
LDA is at least max(1,N),
V is a
complex*16 array of dimension
(LDV,N)
,
LDV is at least
max (1,N),
RWORK is a
double precision array of length at least
max (1,3 × N  2),
WORK is a
complex*16 array of length at least
(2 × N)
and
LWORK is its actual length.
If
F02AXF was called with the same
arrays supplied for VR and AR and for VI and AI, then the
call to
F06TFF may be omitted.
F02AYF
Withdrawn at Mark 18.
Replaced by
F08JSF (ZSTEQR).
Old: CALL F02AYF(N,EPS,D,E,VR,IVR,VI,IVI,IFAIL)
New: CALL ZSTEQR('V',N,D,E(2),V,IV,WORK,INFO)
DO 40 J = 1, N
DO 30 I = 1, N
VR(I,J) = real(V(I,J))
VI(I,J) = imag(V(I,J))
30 CONTINUE
40 CONTINUE
where
V is a
complex*16 array of dimension
(IV,N)
, and
WORK is a
real array of length at least
(2(N  1))
.
F02BBF
Withdrawn at Mark 19.
Replaced by
F08FBF (DSYEVX).
Old: CALL F02BBF(A,LDA,N,RLB,RUB,M,MM,R,V,LDV,D,E,E2,X,G,C,
+ ICOUNT,IFAIL)
New: CALL DSYEVX('V','V','L',N,A,LDA,RLB,RUB,
+ 0,0,2*X02AMF(),MM,R,V,LDV,WORK,LWORK,IWORK,
+ JFAIL,INFO)
where
R must have dimension at least
max (1,N),
WORK is a
real array of length at least
(4 × N),
LWORK is its actual length,
JFAIL is an integer array of length at least
max (1,N), and
IWORK is an integer array of length at least
(5 × N). Note that in the call to
F02BBF R needs only to be of dimension (M). Larger values of
LWORK, up to some optimal value, may improve performance. Arguments C, ICOUNT, X, G, E2, E and D are not used.
F02BCF
Withdrawn at Mark 19.
Replaced by
F02ECF.
Old: CALL F02BCF(A,IA,N,ALB,UB,M,MM,RR,RI,VR,IVR,VI,IVI,
+ INTGER,ICNT,C,B,IB,U,V,IFAIL)
New: CALL F02ECF('Moduli',N,A,IA,ALB,UB,M,MM,RR,RI,VR,IVR,
+ VI,IVI,WORK,LWORK,ICNT,C,IFAIL)
where
WORK is a
real array of length at least (
N × (N + 4)) and
LWORK is its actual length.
F02BDF
Withdrawn at Mark 19.
Replaced by
F02GCF.
Old: CALL F02BDF(AR,IAR,AI,IAI,N,ALB,UB,M,MM,RR,RI,VR,IVR,
+ VI,IVI,INTGER,C,BR,IBR,BI,IBI,U,V,IFAIL)
New: DO 20 J = 1, N
DO 10 I = 1, N
A(I,J) = cmplx(AR(I,J),AI(I,J))
10 CONTINUE
20 CONTINUE
CALL F02GCF('Moduli',N,A,IA,ALB,UB,M,MM,R,V,IV,WORK,
+ LWORK,RWORK,INTGER,C,IFAIL)
DO 30 I = 1, N
RR(I) = real(R(I))
RI(I) = imag(R(I))
30 CONTINUE
DO 50 J = 1, MM
DO 40 I = 1, N
VR(I,J) = real(V(I,J))
VI(I,J) = imag(V(I,J))
40 CONTINUE
50 CONTINUE
where
A is a
complex*16 array of dimension
(IA,N)
,
R is a
complex*16 array of dimension (
N),
V is a
complex*16 array of dimension
(IV,M)
,
WORK is a
complex*16 array of length at least
(N × (N + 2))
,
LWORK is its actual length, and
RWORK is a
real array of length at least
(2 × N)
.
F02BEF
Withdrawn at Mark 18.
Replaced by
F08JJF (DSTEBZ) and
F08JKF (DSTEIN).
Old: CALL F02BEF(N,D,ALB,UB,EPS,EPS1,E,E2,M,MM,R,V,IV,ICOUNT,X,C,
+ IFAIL)
New: CALL DSTEBZ('V','B',N,ALB,UB,0,0,EPS1,D,E(2),MM,NSPLIT,R,IBLOCK,
+ ISPLIT,X,IWORK,INFO)
CALL DSTEIN(N,D,E(2),MM,R,IBLOCK,ISPLIT,V,IV,X,IWORK,IFAILV,INFO)
where
NSPLIT is an integer variable,
IBLOCK,
ISPLIT and
IFAILV are integer arrays of length at least
(N)
, and
IWORK is an integer array of length at least
(3 × N)
.
F02BFF
Withdrawn at Mark 18.
Replaced by
F08JJF (DSTEBZ).
Old: CALL F02BFF(D,E,E2,N,M1,M2,MM12,EPS1,EPS,EPS2,IZ,R,WU)
New: CALL DSTEBZ('I','E',N,0.0D0,0.0D0,M1,M2,EPS1,D,E(2),M,
+ NSPLIT,R,IBLOCK,ISPLIT,WORK,IWORK,INFO)
where
M and
NSPLIT are integer variables,
IBLOCK and
ISPLIT are integer arrays of length at least
(N)
,
WORK is a
double precision array of length at least
(4 × N)
, and
IWORK is an integer array of length at least
(3 × N)
.
F02BJF
Scheduled for withdrawal at Mark 23.
Replaced by
F08WAF (DGGEV).
Old: CALL F02BJF(N,A,LDA,B,LDB,EPS1,ALFR,ALFI,BETA,MATV,V,LDV,ITER,IFAIL)
New: IF (MATV) THEN
JOBVR = 'V'
ELSE
JOBVR = 'N'
ENDIF
CALL DGGEV('N',JOBVR,N,A,LDA,B,LDB,ALFR,ALFI,BETA,VL,LDVL,
+ VR,LDVL,WORK,LWORK,INFO)
IF (INFO.EQ.0) THEN
...
F02BKF
Withdrawn at Mark 18.
Replaced by
F08PKF (DHSEIN).
Old: CALL F02BKF(N,M,H,IH,RI,C,RR,V,IV,B,IB,U,W,IFAIL)
New: CALL DHSEIN('R','Q','N',C,N,H,IH,RR,RI,V,IV,V,IV,M,M2,B,IFAILR,
+ IFAILR,INFO)
where
M2 is an integer variable, and
IFAILR is an integer array of length at least
(N)
.
Note that the array
C may be modified by
F08PKF (DHSEIN) if there are complex conjugate pairs of eigenvalues.
F02BLF
Withdrawn at Mark 18.
Replaced by
F08PXF (ZHSEIN).
Old: CALL F02BLF(N,M,HR,IHR,HI,IHI,RI,C,RR,VR,IVR,VI,IVI,BR,IBR,BI,
+ IBI,U,W,IFAIL)
New: DO 20 J = 1, N
R(J) = cmplx(RR(J),RI(J))
DO 10 I = 1, N
H(I,J) = cmplx(HR(I,J),HI(I,J))
10 CONTINUE
20 CONTINUE
CALL ZHSEIN('R','Q','N',C,N,H,IH,R,V,IV,V,IV,M,M2,WORK,RWORK,
+ IFAILR,IFAILR,INFO)
DO 30 I = 1, N
RR(I) = real(R(I))
30 CONTINUE
DO 50 J = 1, M
DO 40 I = 1, N
VR(I,J) = real(V(I,J))
VI(I,J) = imag(V(I,J))
40 CONTINUE
50 CONTINUE
where
H is a
complex*16 array of dimension
(IH,N)
,
R is a
complex*16 array of length (
N),
V is a
complex*16, array of dimension
(IV,M)
,
M2 is an integer variable,
WORK is a
complex*16 array of length at least (
N × N),
RWORK is a
double precision array of length at least
(N)
, and
IFAILR is an integer array of length at least
(N)
.
F02EAF
Scheduled for withdrawal at Mark 23.
Replaced by
F08PAF (DGEES).
Old: CALL F02EAF(JOB,N,A,LDA,WR,WI,Z,LDZ,WORK,LWORK,IFAIL)
New: LOGICAL SELECT
EXTERNAL SELECT
...
IF (JOB.EQ.'N') THEN
JOBVS = 'N'
ELSE
JOBVS = 'V'
END IF
CALL DGEES(JOBVS,'N',SELECT,N,A,LDA,0,WR,WI,Z,LDZ,WORK,
+ LWORK,BWORK,INFO)
IF (INFO.EQ.0) THEN
....
LOGICAL FUNCTION SELECT(AR,AI)
DOUBLE PRECISION AR, AI
SELECT = .TRUE.
RETURN
ENDK
F02EBF
Scheduled for withdrawal at Mark 23.
Replaced by
F08NAF (DGEEV).
Old: CALL F02EBF(JOB,N,A,LDA,WR,WI,VR,LDVR,VI,LDVI,WORK,LWORK,
+ IFAIL)
New: IF (JOB.EQ.'N') THEN
JOBVR = 'N'
ELSE
JOBVR = 'V'
END IF
CALL DGEEV('N',JOBVR,N,A,LDA,WR,WI,VL,LDVL,VR1,LDVR1,
+ WORK,LWORK,INFO)
IF (INFO.EQ.0) THEN
C Eigenvector infomation is stored differently.
C For complex conjugate pairs (that is, corresponding
C to the jth eigenvector such that WI(j) is nonzero,
C and WI(j) = WI(j+1)), the real and imaginary parts
C of the first of the pair of eigenvectors are stored
C as consecutive columns of VR1: VR1(:,j), VR1(:,j+1).
C The second in the pair is just the conjugate of the
C first, so can be constructed by negating the
C elements in VR1(:,j+1).
C If the jth eigenvector is real (WI(j)=0), the
C corresponding real eigenvector is stored in the
C jth column of VR1, VR1(1:N,j).
F02FAF
Scheduled for withdrawal at Mark 23.
Replaced by
F08FAF (DSYEV).
Old: CALL F02FAF(JOB,UPLO,N,A,LDA,W,WORK,LWORK,IFAIL)
New: CALL DSYEV(JOB,UPLO,N,A,LDA,W,WORK,LWORK,INFO)
IF (INFO.EQ.0) THEN
...
C the workspace requirements are slightly different.
F02FCF
Scheduled for withdrawal at Mark 23.
Replaced by
F08FBF (DSYEVX).
Old: CALL F02FCF(JOB,RANGE,UPLO,N,A,LDA,WL,WU,IL,IU,MEST,M,
+ W,Z,LDZ,WORK,LWORK,IWORK,IFAIL)
New: CALL DSYEVX(JOB,RANGE,UPLO,N,A,LDA,WL,WU,IL,IU,ABSTOL,M,
+ W,Z,LDZ,WORK,LWORK,IWORK,JFAIL,INFO)
IF (INFO.EQ.0) THEN
...
C the workspace requirements are slightly different.
F02FDF
Scheduled for withdrawal at Mark 23.
Replaced by
F08SAF (DSYGV).
Old: CALL F02FDF(ITYPE,JOB,UPLO,N,A,LDA,B,LDB,W,WORK,LWORK,IFAIL)
New: CALL DSYGV(ITYPE,JOB,UPLO,N,A,LDA,B,LDB,W,WORK,LWORK,INFO)
IF (INFO.EQ.0) THEN
...
C the workspace requirements are slightly different.
F02FHF
Scheduled for withdrawal at Mark 23.
Replaced by
F08UAF (DSBGV).
Old: CALL F02FHF(N,MA,A,LDA,MB,B,LDB,D,WORK,LWORK,IFAIL)
New: CALL DSBGV('N','U',N,MA,MB,A,LDA,B,LDB,D,Z,LDZ,WORK,INFO)
IF (INFO.EQ.0) THEN
...
C note that the eigenvalues appear in reverse order
C note also the different workspace requirements
F02GAF
Scheduled for withdrawal at Mark 23.
Replaced by
F08PNF (ZGEES).
Old: CALL F02GAF(JOB,N,A,LDA,W,Z,LDZ,RWORK,WORK,LWORK,IFAIL)
New: LOGICAL BWORK(1)
LOGICAL SELECT
EXTERNAL SELECT
...
IF (JOB.EQ.'N') THEN
JOBVS = 'N'
ELSE
JOBVS = 'V'
END IF
CALL ZGEES(JOBVS,'N',SELECT,N,A,LDA,0,W,Z,LDZ,
+ WORK,LWORK,RWORK,BWORK,INFO)
IF (INFO.NE.0) THEN
...
C Note also the different workspace requirements
...
LOGICAL FUNCTION SELECT(C)
COMPLEX*16 C
SELECT = .TRUE.
RETURN
END
F02GBF
Scheduled for withdrawal at Mark 23.
Replaced by
F08NNF (ZGEEV).
Old: CALL F02GBF(JOB,N,A,LDA,W,V,LDV,RWORK,WORK,LWORK,IFAIL)
New: CALL ZGEEV('N',JOB,N,A,LDA,W,VL,LDVL,V,LDV,
+ WORK,LWORK,RWORK,INFO)
IF (INFO.EQ.0) THEN
...
F02GJF
Scheduled for withdrawal at Mark 23.
Replaced by
F08WNF (ZGGEV).
Old: CALL F02GJF(N,AR,LDAR,AI,LDAI,BR,LDBR,BI,LDBI,EPS1,ALFR,
+ ALFI,BETA,MATV,VR,LDVR,VI,LDVI,ITER,IFAIL)
New: IF (MATV) THEN
JOBVR = 'V'
ELSE
JOBVR = 'N'
END IF
C
C Set A=AR + iAI and B = BR+iBI
C
CALL ZGGEV('N',JOBVR,N,A,LDA,B,LDB,ALPHA,BETA1,VL,LDVL,
+ V,LDV,WORK,LWORK,RWORK,INFO)C
C Note results returned in COMPLEX*16 types, unlike F02GJF.
IF (INFO.EQ.0) THEN
...
F02HAF
Scheduled for withdrawal at Mark 23.
Replaced by
F08FNF (ZHEEV).
Old: CALL F02HAF(JOB,UPLO,N,A,LDA,W,RWORK,WORK,LWORK,IFAIL)
New: CALL ZHEEV(JOB,UPLO,N,A,LDA,W,WORK,LWORK,RWORK,INFO)
C Note slightly different workspace requirements.
IF (INFO.EQ.0) THEN
...
F02HCF
Scheduled for withdrawal at Mark 23.
Replaced by
F08FPF (ZHEEVX).
Old: CALL F02HCF(JOB,RANGE,UPLO,N,A,LDA,WL,WU,IL,IU,MEST,M,
+ W,Z,LDZ,WORK,LWORK,RWORK,IWORK,IFAIL)
New: CALL ZHEEVX(JOB,RANGE,UPLO,N,A,LDA,WL,WU,IL,IU,ABSTOL,M,
+ W,Z,LDZ,WORK,LWORK,RWORK,IWORK,JFAIL,INFO)
C Note slightly different workspace requirements.
IF (INFO.EQ.0) THEN
...
F02HDF
Scheduled for withdrawal at Mark 23.
Replaced by
F08SNF (ZHEGV).
Old: CALL F02HDF(ITYPE,JOB,UPLO,N,A,LDA,B,LDB,W,RWORK,WORK,
+ LWORK,IFAIL)
New: CALL ZHEGV(ITYPE,JOB,UPLO,N,A,LDA,B,LDB,W,WORK,LWORK,
+ RWORK,INFO)
C Note slightly different workspace requirements.
IF (INFO.EQ.0) THEN
...
F02SWF
Withdrawn at Mark 18.
Replaced by
F08KEF (DGEBRD).
The following replacement ignores the triangular structure of
A, and therefore references the subdiagonal elements of
A; however on many machines the replacement code will be more efficient.
Old: CALL F02SWF(N,A,LDA,D,E,NCOLY,Y,LDY,WANTQ,Q,LDQ,IFAIL)
New: DO 20 J = 1, N
DO 10 I = J+1, N
A(I,J) = 0.0D0
10 CONTINUE
20 CONTINUE
CALL DGEBRD(N,N,A,LDA,D,E,TAUQ,TAUP,WORK,LWORK,INFO)
IF (WANTQ) THEN
CALL F06QFF('L',N,N,A,LDA,Q,LDQ)
CALL DORGBR('Q',N,N,N,Q,LDQ,TAUQ,WORK,LWORK,INFO)
END IF
IF (NCOLY.GT.0) THEN
CALL DORMBR('Q','L','T',N,NCOLY,N,A,LDA,TAUQ,Y,LDY,
+ WORK,LWORK,INFO)
END IF
where
TAUQ,
TAUP and
WORK are
double precision arrays of length at least
(N)
, and
LWORK is the actual length of
WORK.
F02SXF
Withdrawn at Mark 18.
Replaced by
F08KFF (DORGBR) and
F08KGF (DORMBR).
The following replacement is valid only if the previous call to
F02SWF has been replaced by a call to
F08KEF (DGEBRD) as shown above.
Old: CALL F02SXF(N,A,LDA,NCOLY,Y,LDY,WORK,IFAIL)
New: IF (NCOLY.EQ.0) THEN
CALL DORGBR('P',N,N,N,A,LDA,TAUP,WORK,LWORK,INFO)
ELSE
CALL DORMBR('P','L','T',N,NCOLY,N,A,LDA,TAUP,Y,LDY,WORK,
+ LWORK,INFO)
END IF
F02SYF
Withdrawn at Mark 18.
Replaced by
F08MEF (DBDSQR).
Old: CALL F02SYF(N,D,E,NCOLB,B,LDB,NROWY,Y,LDY,NCOLZ,Z,LDZ,WORK,
+ IFAIL)
New: CALL DBDSQR('U',N,NCOLZ,NROWY,NCOLB,D,E,Z,LDZ,Y,LDY,B,LDB,WORK,
+ INFO)
where
WORK is a
double precision array of length at least
(4(N  1))
unless
NCOLB
=
NROWY
=
NCOLZ
=
0
.
F02SZF
Withdrawn at Mark 15.
Replaced by
F08MEF (DBDSQR).
Old: CALL F02SZF(N,D,E,SV,WANTB,B,WANTY,Y,NRY,LY,WANTZ,Z,NRZ,NCZ,
+ WORK1,WORK2,WORK3,IFAIL)
New: IF (WANTB) THEN
NCC = 1
ELSE
NCC = 0
END IF
IF (WANTY) THEN
NRU = LY
ELSE
NRU = 0
END IF
IF (WANTZ) THEN
NCVT = NCZ
ELSE
NCVT = 0
END IF
CALL DBDSQR('U',N,NCVT,NRU,NCC,D,E(2),Z,NRZ,Y,NRY,B,N,WORK,INFO)
WORK must be a onedimensional
double precision array of length at least
lwork given by:

lwork = 1
when WANTB, WANTY and WANTZ are all false;

lwork = max (4 × (N  1),1)
otherwise.
The parameters WORK1, WORK2 and WORK3 are no longer required.
F02UWF
Withdrawn at Mark 18.
Replaced by
F08KSF (ZGEBRD).
The following replacement ignores the triangular structure of A, and therefore references the subdiagonal elements of A; however
on many machines the replacement code will be more efficient.
Old: CALL F02UWF(N,A,LDA,D,E,NCOLY,Y,LDY,WANTQ,Q,LDQ,WORK,IFAIL)
New: DO 20 J = 1, N
DO 10 I = J+1, N
A(I,J) = 0.0D0
10 CONTINUE
20 CONTINUE
CALL ZGEBRD(N,N,A,LDA,D,E,TAUQ,TAUP,WORK,LWORK,INFO)
IF (WANTQ) THEN
CALL F06TFF('L',N,N,A,LDA,Q,LDQ)
CALL ZUNGBR('Q',N,N,N,Q,LDQ,TAUQ,WORK,LWORK,INFO)
END IF
IF (NCOLY.GT.0) THEN
CALL ZUNMBR('Q','L','C',N,NCOLY,N,A,LDA,TAUQ,Y,LDY,
+ WORK,LWORK,INFO)
END IF
where
TAUQ and
TAUP are
complex*16 arrays of length at least
(N)
, and
LWORK is the actual length of
WORK.
F02UXF
Withdrawn at Mark 18.
Replaced by
F08KTF (ZUNGBR) or
F08KUF (ZUNMBR).
The following replacement is valid only if the previous call to
F02UWF has been replaced by a call to
F08KSF (ZGEBRD) as shown above.
Old: CALL F02UXF(N,A,LDA,NCOLY,Y,LDY,RWORK,CWORK,IFAIL)
New: IF (NCOLY.EQ.0) THEN
CALL ZUNGBR('P',N,N,N,A,LDA,TAUP,CWORK,LWORK,INFO)
ELSE
CALL ZUNMBR('P','L','C',N,NCOLY,N,A,LDA,TAUP,Y,LDY,CWORK,
+ LWORK,INFO)
END IF
where
LWORK is the actual length of
CWORK.
F02UYF
Withdrawn at Mark 18.
Replaced by
F08MSF (ZBDSQR).
Old: CALL F02UYF(N,D,E,NCOLB,B,LDB,NROWY,Y,LDY,NCOLZ,Z,LDZ,WORK,
+ IFAIL)
New: CALL ZBDSQR('U',N,NCOLZ,NROWY,NCOLB,D,E,Z,LDZ,Y,LDY,B,LDB,WORK,
+ INFO)
where
WORK is a
double precision array of length at least
(4(N  1))
unless
NCOLB
=
NROWY
=
NCOLZ
=
0
.
F02WAF
Withdrawn at Mark 16.
Replaced by
F08KBF (DGESVD).
Old: CALL F02WAF(M,N,A,LDA,WANTB,B,SV,WORK,LWORK,IFAIL)
New: CALL DGESVD('N','O',M,N,A,LDA,SV,WORK,1,WORK,1,
+ WORK,LWORK,INFO)
IF (INFO.EQ.0) THEN
...
WORK must be a onedimensional
double precision array of length at least
lwork given by:
max (1,
3 ×
min (M,N)
+
max (M,N)
,
5 ×
min (M,N)
)
Larger values of
LWORK, up to some optimal value, may improve performance.
Please note that the facility to return
Q^{T} × b is not provided so arguments
WANTB and
B are not required. Instead,
F08KBF (DGESVD) has an option to return the entire
M * M orthogonal matrix
Q, referred to as
U in its documentation, through its 8th argument.
F02WEF
Scheduled for withdrawal at Mark 23.
Replaced by
F08KBF (DGESVD).
Old: CALL F02WEF(M,N,A,LDA,NCOLB,B,LDB,WANTQ,Q,LDQ,SV,WANTP,
+ PT,LDPT,WORK,IFAIL)
New: IF (WANTQ) THEN
JOBU = 'A'
ELSE
JOBU = 'N'
END IF
IF (WANTP) THEN
JOBVT = 'A'
ELSE
JOBVT = 'N'
END IF
C Please note that the facility to return Q(t)B is not provided.
CALL DGESVD(JOBU,JOBVT,M,N,A,LDA,SV,Q,LDQ,PT,LDPT,WORK,
+ LWORK,INFO)
C Note slightly different workspace requirements.
IF (INFO.EQ.0) THEN
...
F02XEF
Scheduled for withdrawal at Mark 23.
Replaced by
F08KPF (ZGESVD).
Old: CALL F02XEF(M,N,A,LDA,NCOLB,B,LDB,WANTQ,Q,LDQ,SV,WANTP,
+ PH,LDPH,RWORK,CWORK,IFAIL)
New: IF (WANTQ) THEN
JOBU = 'A'
ELSE
JOBU = 'N'
END IF
IF (WANTP) THEN
JOBVT = 'A'
ELSE
JOBVT = 'N'
END IF
C Please note that the facility to return Q(h)B is not provided.
CALL ZGESVD(JOBU,JOBVT,M,N,A,LDA,SV,Q,LDQ,PH,LDPH,CWORK,
+ LWORK,RWORK,INFO)
C Note slightly different workspace requirements.
IF (INFO.EQ.0) THEN
...
F03 – Determinants
F03AGF
Withdrawn at Mark 17.
Replaced by
F07HDF (DPBTRF).
Old: CALL F03AGF(N,M,A,IA,RL,IL,M1,D1,ID,IFAIL)
New: CALL DPBTRF('Lower',N,M,A,IA,IFAIL)
where the array RL and its associated dimension parameter IL, and the parameters M1, D1 and ID are no longer required. In
F07HDF (DPBTRF), the array
A holds the matrix packed using a different scheme to that used by
F03AGF; see the routine document for details.
F07HDF (DPBTRF) overwrites
A with the Cholesky factor
L
(without reciprocating diagonal elements) rather than returning
L
in the array RL.
F07HDF (DPBTRF) does not compute the determinant of the input matrix, returned as
D1 × 2.0^{ID}
by
F03AGF. If this is required, it may be calculated after the call of
F07HDF (DPBTRF) by code similar to the following. The code computes the determinant by multiplying the diagonal elements of the factor
L
, taking care to avoid possible overflow or underflow.
D1 = 1.0D0
ID = 0
DO 30 I = 1, N
D1 = D1*A(1,I)**2
10 IF (D1.GE.1.0D0) THEN
D1 = D1*0.0625e0
ID = ID + 4
GO TO 10
END IF
20 IF (D1.LT.0.0625e0) THEN
D1 = D1*16.0D0
ID = ID  4
GO TO 20
END IF
30 CONTINUE
F03AHF
Withdrawn at Mark 17.
Replaced by
F07ARF (ZGETRF).
Old: CALL F03AHF(N,A,IA,DETR,DETI,ID,RINT,IFAIL)
New: CALL ZGETRF(N,N,A,IA,IPIV,IFAIL)
where
IPIV is an INTEGER array of length
N which holds the indices of the pivot elements, and the array RINT is no longer required. It may be important to note that
after a call of
F07ARF (ZGETRF),
A is overwritten by the upper triangular factor
U
and the offdiagonal elements of the unit lower triangular factor
L
, whereas the factorization returned by
F03AHF gives
U
the unit diagonal.
F07ARF (ZGETRF) does not compute the determinant of the input matrix, returned as
cmplx(DETR,DETI)
× 2.0^{ID}
by
F03AHF. If this is required, it may be calculated after a call of
F07ARF (ZGETRF) by code similar to the following, where DET is a
complex variable. The code computes the determinant by multiplying the diagonal elements of the factor
U
, taking care to avoid possible overflow or underflow.
DET = cmplx(1.0D0,0.0D0)
ID = 0
DO 30 I = 1, N
IF (IPIV(I).NE.I) DET = DET
DET = DET*A(I,I)
10 IF (MAX(ABS(real(DET)),ABS(imag(DET))).GE.1.0D0) THEN
DET = DET*0.0625e0
ID = ID + 4
GO TO 10
END IF
20 IF (MAX(ABS(real(DET)),ABS(imag(DET))).LT.0.0625e0) THEN
DET = DET*16.0D0
ID = ID  4
GO TO 20
END IF
30 CONTINUE
DETR = real(DET)
DETI = imag(DET)
F03AMF
Withdrawn at Mark 17.
There is no replacement for this routine.
Old: CALL F01BNF(N,A,IA,P,IFAIL)
CALL F03AMF(N,TEN,P,D1,D2)
New: CALL ZPOTRF('Upper',N,A,IA,IFAIL)
D1 = 1.0D0
D2 = 0.0D0
DO 30 I = 1, N
D1 = D1*real(A(I,I))**2
10 IF (D1.GE.1.0D0) THEN
D1 = D1*0.0625e0
D2 = D2 + 4
GO TO 10
END IF
20 IF (D1.LT.0.0625e0) THEN
D1 = D1*16.0D0
D2 = D2  4
GO TO 20
END IF
30 CONTINUE
IF (TEN) THEN
I = D2
D2 = D2*LOG10(2.0D0)
D1 = D1*2.0D0**(ID2/LOG10(2.0D0))
END IF
F03AMF computes the determinant of a Hermitian positivedefinite matrix after factorization by
F01BNF, and has no replacement routine.
F01BNF has been superseded by
F07FRF (ZPOTRF). To compute the determinant of such a matrix, in the same form as that returned by
F03AMF, code similar to the above may be used. The code computes the determinant by multiplying the (real) diagonal elements of
the factor
U
, taking care to avoid possible overflow or underflow.
Note that before the call of
F07FRF (ZPOTRF), array A contains the upper triangle of the matrix rather than the lower triangle.
F04 – Simultaneous Linear Equations
F04AAF
Scheduled for withdrawal at Mark 23.
Replaced by
F07AAF (DGESV).
Old: CALL F04AAF(A,LDA,B,LDB,N,M,C,LDC,WKSPCE,IFAIL)
New: CALL DGESV(N,M,A,LDA,IPIV,B,LDB,INFO)
IF (INFO.EQ.0) THEN
c Answer now in B
...
F04ACF
Scheduled for withdrawal at Mark 23.
Replaced by
F07HAF (DPBSV).
Old: CALL F04ACF(A,LDA,B,LDB,N,M,IR,C,LDC,RL,LDRL,M1,IFAIL)
New: CALL DPBSV('U',N,M,IR,AB,LDAB,B,LDB,INFO)
IF (INFO.EQ.0) THEN
c A and AB are stored differently.
c AB may be regarded as the transpose of A, with the 'U' option.
c Thus LDAB might be M+1
c Answer now in B
...
F04ADF
Scheduled for withdrawal at Mark 23.
Replaced by
F07ANF (ZGESV).
Old: CALL F04ADF(A,LDA,B,LDB,N,M,C,LDC,WKSPCE,IFAIL)
New: CALL ZGESV(N,M,A,LDA,IPIV,B,LDB,INFO)
IF (INFO.EQ.0) THEN
c Answer now in B
...
F04AKF
Withdrawn at Mark 17.
Replaced by
F07ASF (ZGETRS).
Old: CALL F04AKF(N,IR,A,IA,P,B,IB)
New: CALL ZGETRS('No Transpose',N,IR,A,IA,IPIV,B,IB,INFO)
It is assumed that the matrix has been factorized by a call of
F07ARF (ZGETRF) rather than
F03AHF; see the
F03 Chapter Introduction for details.
IPIV is an INTEGER array of length
N, as returned by
F07ARF (ZGETRF), and the array P is no longer required.
INFO is an INTEGER diagnostic parameter; see the
F07ASF (ZGETRS) routine document for details.
F04ALF
Withdrawn at Mark 17.
Replaced by
F07HEF (DPBTRS).
Old: CALL F04ALF(N,M,IR,RL,IRL,M1,B,IB,X,IX)
New: CALL F06QFF('General',N,IR,B,IB,X,IX)
CALL DPBTRS('Lower',N,M,IR,A,IA,X,IX,INFO)
It is assumed that the matrix has been factorized by a call of
F07HDF (DPBTRF) rather than
F03AGF; see the
F03 Chapter Introduction for details.
A is the factorized matrix as returned by
F07HDF (DPBTRF). The array RL, its associated dimension parameter IRL, and the parameter M1 are no longer required.
INFO is an INTEGER diagnostic parameter; see the
F07HEF (DPBTRS) routine document for details. If the original righthand side matrix B is no longer required, the call to
F06QFF is not necessary, and references to
X and
IX in the call of
F07HEF (DPBTRS) may be replaced by references to B and IB, in which case
B will be overwritten by the solution.
F04ANF
Old: CALL F04ANF(M,N,QR,IQR,ALPHA,IPIV,B,X,Z)
New: CALL DCOPY(N,ALPHA,1,QR,IQR+1)
CALL DORMQR('L','T',M,1,N,QR,IQR,Y,B,M,Z,N,INFO)
CALL DTRSV('U','N','N',N,QR,IQR,B,1)
D0 10 I = 1, N
X(IPIV(I)) = B(I)
10 CONTINUE
where
Y must be the same
double precision array as was used as the seventh argument in the previous call of
F01AXF.
This replacement is valid only if the previous call to
F01AXF has been replaced by a call to
F08BEF (DGEQPF) as shown above.
F04AQF
Withdrawn at Mark 16.
Replaced by
F07GEF (DPPTRS) and
F07PEF (DSPTRS).
May be replaced by calls to
F06EFF (DCOPY), and
F07GEF (DPPTRS) or
F07PEF (DSPTRS), depending on whether the symmetric matrix has previously been factorized by
F07GDF (DPPTRF) or
F07PDF (DSPTRF) (see the description above of how to replace calls to
F01BQF.
(a) 
where the symmetric matrix has been factorized by F07GDF (DPPTRF)
Old: CALL F04AQF(N,M,RL,D,B,X)
New: CALL DCOPY(N,B,1,X,1)
CALL DPPTRS('Lower',N,1,RL,X,N,INFO) 
(b) 
where the symmetric matrix has been factorized by
F07PDF (DSPTRF)
Old: CALL F04AQF(N,M,RL,D,B,X)
New: CALL DCOPY(N,B,1,X,1)
CALL DSPTRS('Lower',N,1,RL,IPIV,X,N,INFO) 
In both (a) and (b), the array
RL must be as returned by the relevant factorization routine. The INTEGER parameter
INFO is a diagnostic parameter. The INTEGER array
IPIV in (b) must be as returned by
F07PDF (DSPTRF). The dimension parameter M, and the array D are no longer required. If the righthandside array B is not needed after
solution of the equations, the call to
F06EFF (DCOPY), which simply copies array B to
X, is not necessary. References to
X in the calls of
F07GEF (DPPTRS) and
F07PEF (DSPTRS) may then be replaced by references to B, in which case B will be overwritten by the solution vector.
F04ARF
Scheduled for withdrawal at Mark 23.
Replaced by
F07AAF (DGESV).
Old: CALL F04ARF(A,LDA,B,N,C,WKSPCE,IFAIL)
New: CALL DGESV(N,1,A,LDA,IPIV,B,N,INFO)
IF (INFO.EQ.0) THEN
c Answer now in B
...
F04AWF
Withdrawn at Mark 17.
Replaced by
F07FSF (ZPOTRS).
Old: CALL F04AWF(N,IR,A,IA,P,B,IB,X,IX)
New: CALL F06TFF('General',N,IR,B,IB,X,IX)
CALL ZPOTRS('Upper',N,IR,A,IA,X,IX,INFO)
It is assumed that the matrix has been factorized by a call of
F07FRF (ZPOTRF) rather than
F01BNF; see the the
F01 Chapter Introduction for details.
A is the factorized matrix as returned by
F07FRF (ZPOTRF). The array P is no longer required.
INFO is an INTEGER diagnostic parameter; see the
F07FSF (ZPOTRS) routine document for details. If the original righthand side array B is no longer required, the call to
F06TFF is not necessary, and references to B and
IX in the call of
F07FSF (ZPOTRS) may be replaced by references to B and IB, in which case B will be overwritten by the solution.
F04AYF
Withdrawn at Mark 18.
Replaced by
F07AEF (DGETRS).
Old: CALL F04AYF(N,IR,A,IA,P,B,IB,IFAIL)
New: CALL DGETRS('No Transpose',N,IR,A,IA,IPIV,B,IB,IFAIL)
It is assumed that the matrix has been factorized by a call of
F07ADF (DGETRF) rather than
F01BTF.
IPIV is an INTEGER array of length
N, and the array P is no longer required.
F04AZF
Withdrawn at Mark 17.
Replaced by
F07FEF (DPOTRS).
Old: CALL F04AZF(N,IR,A,IA,P,B,IB,IFAIL)
New: CALL DPOTRS('Upper',N,IR,A,IA,B,IB,IFAIL)
It is assumed that the matrix has been factorized by a call of
F07FDF (DPOTRF) rather than
F01BXF. The array P is no longer required.
F04EAF
Scheduled for withdrawal at Mark 23.
Replaced by
F07CAF (DGTSV).
Old: CALL F04EAF(N,D,DU,DL,B,IFAIL)
New: CALL DGTSV(N,1,DL(2),D,DU(2),B,N,INFO)
IF (INFO.EQ.0) THEN
c Answer now in B
...
F04FAF
Scheduled for withdrawal at Mark 23.
Replaced by
F07JAF (DPTSV),
F07JDF (DPTTRF) and
F07JEF (DPTTRS).
Old: CALL F04FAF(JOB,N,D,E,B,IFAIL)
New: IF (JOB.EQ.0)
CALL DPTSV(N,1,D,E(2),B,1,INFO)
IF (INFO.EQ.0) THEN
c Answer now in B
...
F04JAF
Scheduled for withdrawal at Mark 23.
Replaced by
F08KAF (DGELSS).
Old: CALL F04JAF(M,N,A,LDA,B,TOL,SIGMA,IRANK,WORK,LWORK,IFAIL)
New: CALL DGELSS(M,N,1,A,LDA,B,1,S,RCOND,IRANK,WORK,LWORK,INFO)
c Note workspace requirements are different.
IF (INFO.EQ.0) THEN
C Answer now in B
C Singular values now in S, not WORK.
C The standard error is not computed
...
F04JDF
Scheduled for withdrawal at Mark 23.
Replaced by
F08KAF (DGELSS).
Old: CALL F04JDF(M,N,A,LDA,B,TOL,SIGMA,IRANK,WORK,LWORK,IFAIL)
New: CALL DGELSS(M,N,1,A,LDA,B,1,S,RCOND,IRANK,WORK,LWORK,INFO)
c Note workspace requirements are different.
IF (INFO.EQ.0) THEN
C Answer now in B
C Singular values now in S, not WORK.
C The standard error is not computed
...
F04JLF
Scheduled for withdrawal at Mark 23.
Replaced by
F08ZBF (DGGGLM).
Old: CALL F04JLF(M,N,P,A,LDA,B,LDB,D,X,Y,WORK,LWORK,IFAIL)
New: CALL DGGGLM(M,N,P,A,LDA,B,LDB,D,X,Y,WORK,LWORK,INFO)
C Slight workspace differences
IF (INFO.EQ.0) THEN
...
F04JMF
Scheduled for withdrawal at Mark 23.
Replaced by
F08ZAF (DGGLSE).
Old: CALL F04JMF(M,N,P,A,LDA,B,LDB,C,D,X,WORK,LWORK,IFAIL)
New: CALL DGGLSE(M,N,P,A,LDA,B,LDB,C,D,X,WORK,LWORK,INFO)
C Slight workspace differences
IF (INFO.EQ.0) THEN
...
F04KLF
Scheduled for withdrawal at Mark 23.
Replaced by
F08ZPF (ZGGGLM).
Old: CALL F04KLF(M,N,P,A,LDA,B,LDB,D,X,Y,WORK,LWORK,IFAIL)
New: CALL ZGGGLM(M,N,P,A,LDA,B,LDB,D,X,Y,WORK,LWORK,INFO)
IF (INFO.EQ.0) THEN
...
F04KMF
Scheduled for withdrawal at Mark 23.
Replaced by
F08ZNF (ZGGLSE).
Old: CALL F04KMF(M,N,P,A,LDA,B,LDB,C,D,X,WORK,LWORK,IFAIL)
New: CALL ZGGLSE(M,N,P,A,LDA,B,LDB,C,D,X,WORK,LWORK,INFO)
IF (INFO.EQ.0) THEN
...
F04LDF
Withdrawn at Mark 18.
Replaced by
F07BEF (DGBTRS).
Old: CALL F04LDF(N,M1,M2,IR,A,IA,AL,IL,IN,B,IB,IFAIL)
New: CALL DGBTRS('No Transpose',N,M1,M2,IR,A,IA,IN,B,IB,IFAIL)
It is assumed that the matrix has been factorized by a call of
F07BDF (DGBTRF) rather than
F01LBF. The array AL and its associated dimension parameter IL are no longer required.
F04MAF
Withdrawn at Mark 19.
Replaced by
F11JCF.
Existing programs should be modified to call
F11JCF. The interfaces are significantly different and therefore precise details of a replacement call cannot be given. Please
consult the appropriate routine document.
F04MBF
Withdrawn at Mark 19.
Replaced by
F11GDF,
F11GEF and
F11GFF (or
F11JCF or
F11JEF).
If a userdefined preconditioner is required existing programs should be modified to call
F11GDF,
F11GEF and
F11GFF. Otherwise
F11JCF or
F11JEF may be used. The interfaces for these routines are significantly different from that for
F04MBF and therefore precise details of a replacement call cannot be given. Please consult the appropriate routine document.
F04NAF
Withdrawn at Mark 17.
Replaced by
F06SKF (ZTBSV) and
F07BSF (ZGBTRS).
Old: CALL F04NAF(JOB,N,ML,MU,A,NRA,IN,B,TOL,IFAIL)
New: JOB = ABS(JOB)
IF (JOB.EQ.1) THEN
CALL ZGBTRS('No Transpose',N,ML,MU,1,A,NRA,IN,B,N,IFAIL)
ELSE IF (JOB.EQ.2) THEN
CALL ZGBTRS('Conjugate Transpose',N,ML,MU,1,A,NRA,IN,B,N,IFAIL)
ELSE IF (JOB.EQ.3) THEN
CALL ZTBSV('Upper','No Transpose','Nonunit',N,ML+MU,A,NRA,B,1)
END IF
It is assumed that the matrix has been factorized by a call of
F07BRF (ZGBTRF) rather than
F01NAF. The replacement routines do not have the functionality to perturb diagonal elements of the triangular factor
U
, as specified by a negative value of JOB in
F04NAF. The parameter TOL is therefore no longer useful. If this functionality is genuinely required, please contact
NAG.
F11 – Large Scale Linear Systems
F11BAF
Withdrawn at Mark 21.
Replaced by
F11BDF.
Old: CALL F11BAF(METHOD,PRECON,NORM,WEIGHT,ITERM,N,M,TOL,MAXITN,
+ ANORM,SIGMAX,MONIT,LWREQ,IFAIL)
New: CALL F11BDF(METHOD,PRECON,NORM,WEIGHT,ITERM,N,M,TOL,MAXITN,
+ ANORM,SIGMAX,MONIT,WORK,LWORK,LWREQ,IFAIL)
F11BDF contains two additional parameters as follows:
See the routine document for further information.
F11BBF
Withdrawn at Mark 21.
Replaced by
F11BEF.
Old: CALL F11BBF(IREVCM,U,V,WORK,LWORK,IFAIL)
New: CALL F11BEF(IREVCM,U,V,WGT,WORK,LWORK,IFAIL)
WGT must be a onedimensional
double precision array of length at least
n
(the order of the matrix) if weights are to be used in the termination criterion, and
1
otherwise. Note that the call to
F11BEF requires the weights to be supplied in
WGT(1 : n)
rather than
WORK(1 : n)
. The minimum value of the parameter
LWORK may also need to be changed.
F11BCF
Withdrawn at Mark 21.
Replaced by
F11BFF.
Old: CALL F11BCF(ITN,STPLHS,STPRHS,ANORM,SIGMAX,IFAIL)
New: CALL F11BFF(ITN,STPLHS,STPRHS,ANORM,SIGMAX,WORK,LWORK,IFAIL)
F11BFF contains two additional parameters as follows:
See the routine document for further information.
F11GAF
Withdrawn at Mark 22.
Replaced by
F11GDF.
Old: CALL F11GAF(METHOD,PRECON,SIGCMP,NORM,WEIGHT,ITERM,N,TOL,MAXITN,
+ ANORM,SIGMAX,SIGTOL,MAXITS,MONIT,LWREQ,IFAIL)
New: CALL F11GDF(METHOD,PRECON,SIGCMP,NORM,WEIGHT,ITERM,N,TOL,MAXITN,
+ ANORM,SIGMAX,SIGTOL,MAXITS,MONIT,LWREQ,WORK,LWORK,IFAIL)
F11GDF contains two additional parameters as follows:
See the routine document for further information.
F11GBF
Withdrawn at Mark 22.
Replaced by
F11GEF.
Old: CALL F11GBF(IREVCM,U,V,WORK,LWORK,IFAIL)
New: CALL F11GEF(IREVCM,U,V,WGT,WORK,LWORK,IFAIL)
WGT must be a onedimensional
double precision array of length at least
n
(the order of the matrix) if weights are to be used in the termination criterion, and
1
otherwise. Note that the call to
F11GEF requires the weights to be supplied in
WGT(1 : n)
rather than
WORK(1 : n)
. The minimum value of the parameter
LWORK may also need to be changed.
F11GCF
Withdrawn at Mark 22.
Replaced by
F11GFF.
Old: CALL F11GCF(ITN,STPLHS,STPRHS,ANORM,SIGMAX,ITS,SIGERR,IFAIL)
New: CALL F11GFF(ITN,STPLHS,STPRHS,ANORM,SIGMAX,ITS,SIGERR,
+ WORK,LWORK,IFAIL)
F11GFF contains two additional parameters as follows:
See the routine document for further information.
G01 – Simple Calculations on Statistical Data
G01BAF
Withdrawn at Mark 16.
Replaced by
G01EBF.
Old: P = G01BAF(IDF,T,IFAIL)
New: P = G01EBF('Lowertail',T,real(IDF),IFAIL)
G01BBF
Withdrawn at Mark 16.
Replaced by
G01EDF.
Old: P = G01BBF(I1,I2,A,IFAIL)
New: P = G01EDF('Uppertail',A,real(I1),real(I2),IFAIL)
G01BCF
Withdrawn at Mark 16.
Replaced by
G01ECF.
Old: P = G01BCF(X,N,IFAIL)
New: P = G01ECF('Uppertail',X,real(N),IFAIL)
G01BDF
Withdrawn at Mark 16.
Replaced by
G01EEF.
Old: P = G01BDF(X,A,B,IFAIL)
New: CALL G01EEF(X,A,B,TOL,P,Q,PDF,IFAIL)
where
TOL is set to the accuracy required and
Q and
PDF are additional output quantities.
Note: the values of
A and
B must be
≤ 10^{6}
.
G01CAF
Withdrawn at Mark 16.
Replaced by
G01FBF.
Old: T = G01CAF(P,N,IFAIL)
New: T = G01FBF('Lowertail',P,real(N),IFAIL)
G01CBF
Withdrawn at Mark 16.
Replaced by
G01FDF.
Old: F = G01CBF(P,M,N,IFAIL)
New: F = G01FDF(P,real(M),real(N),IFAIL)
G01CCF
Withdrawn at Mark 16.
Replaced by
G01FCF.
Old: X = G01CCF(P,N,IFAIL)
New: X = G01FCF(P,real(N),IFAIL)
G01CDF
Withdrawn at Mark 16.
Replaced by
G01FEF.
Old: X = G01CDF(P,A,B,IFAIL)
New: X = G01FEF(P,A,B,TOL,IFAIL)
where
TOL is set to the accuracy required.
Note: the values of
A and
B must be
≤ 10^{6}
.
G01CEF
Withdrawn at Mark 18.
Replaced by
G01FAF.
Old: X = G01CEF(P,IFAIL)
New: X = G01FAF('Lowertail',P,IFAIL)
G02 – Correlation and Regression Analysis
G02CJF
Withdrawn at Mark 16.
Replaced by
G02DAF and
G02DGF.
Old: CALL G02CJF(X,IX,Y,IY,N,M,IR,THETA,IT,SIGSQ,C,IC,IPIV,
+ WK1,WK2,IFAIL)
New: C set the first M elements of ISX to 1
CALL F06DBF(M,1,ISX,1)
C THEN
TOL = X02AJF()
CALL G02DAF('Zero','Unweighted',N,X,IX,M,ISX,M,Y,WT,
+ RSS,IDF,THETA,SE,COV,RES,H,C,IC,SVD,IRANK,
+ P,TOL,WK,IFAIL)
SIGSQ(1) = RSS/IDF
C there are two or more dependent variables,
C i.e., IR is greater than or equal to 2 then:
D0 20 I = 2, IR
CALL G02DGF('Unweighted',N,WT,RSS,IP,IRANK,COV,C,IC,SVD,
+ P,Y(1,I),THETA(1,I),SE,RES,WK,IFAIL)
SIGSQ(I) = RSS/IDF
20 CONTINUE
For unweighted regression, as is used here,
WT may be any
double precision array and will not be referenced, e.g., SIGSQ could be used.
The array
C no longer contains
(X^{T}X)^{  1}
;
however,
(X^{T}X)^{  1}
scaled by
σ ^{ ^ }^{2}
is returned in packed form in array
COV. The upper triangular part of
C will now contain a factorization of
X^{T}X
.
The
double precision arrays
SE(M)
,
COV
(M × (M + 1) / 2)
,
RES(N)
,
H(N)
,
P
(M × (M + 2))
, the logical variable
SVD and the INTEGER variable
IRANK are additional outputs. There is also a single
double precision workspace
WK
(5 × (M  1) + M × M)
.
G04 – Analysis of Variance
G04ADF
Withdrawn at Mark 17.
Replaced by
G04BCF.
Old: CALL G04ADF(DATA,VAR,AMR,AMC,AMT,LCODE,IA,N,NN)
New: IFAIL = 0
CALL G04BCF(1,N,N,DATA,N,IT,GMEAN,AMT,TABL,6,C,NMAX,
+ IREP,RPMEAN,AMR,AMC,R,EF,0.0,0,WK,IFAIL)
The arrays
AMR,
AMC and
AMT contain the means of the rows, columns and treatments rather than the totals. The values equivalent to those returned in
the array VAR of
G04ADF are returned in the second column of the twodimensional array
TABL starting at the second row, e.g.,
VAR(1)
=
TABL(2,2)
. The twodimensional integer array LCODE (containing the treatment codes) has been replaced by the onedimensional array
IT. These arrays will be the equivalent if
IA = N. The following additional declarations are required.
double precision GMEAN
INTEGER IFAIL
double precision C(NMAX,NMAX), EF(NMAX), TABL(6,5), R(NMAX*NMAX),
+ RPMEAN(1), WK(NMAX*NMAX+NMAX)
INTEGER IREP(NMAX), IT(NMAX*NMAX)
where
NMAX is an integer such that
NMAX ≥ N
.
G04AEF
Withdrawn at Mark 17.
Replaced by
G04BBF.
Old: CALL G04AEF(Y,N,K,NOBS,GBAR,GM,SS,IDF,F,FP,IFAIL)
New: CALL G04BBF(N,Y,0,K,IT,GM,BMEAN,GBAR,TABL,4,C,KMAX,NOBS,
+ R,EF,0.0D0,0,WK,IFAIL)
The values equivalent to those returned by
G04AEF in the arrays IDF and SS are returned in the first and second columns of
TABL starting at row 2 and the values equivalent to those returned in the scalars F and FP are returned in
TABL(2,4) and
TABL(2,5) respectively.
NOBS is output from
G04BBF rather than input. The groups are indicated by the array
IT. The following code illustrates how
IT can be computed from
NOBS.
IJ = 0
DO 40 I = 1, K
DO 20 J = 1, NOBS(I)
IJ = IJ + 1
IT(IJ) = I
20 CONTINUE
40 CONTINUE
The following additional declarations are required.
double precision BMEAN(1),C(KMAX,KMAX),EF(KMAX),R(NMAX),TABL(4,5),
+ WK(KMAX*KMAX+KMAX)
INTEGER IT(NMAX)
NMAX and
KMAX are integers such that
NMAX ≥ N and
KMAX ≥ K.
G04AFF
Withdrawn at Mark 17.
Replaced by
G04CAF.
Old: CALL G04AFF(Y,IY1,IY2,M,NR,NC,ROW,COL,CELL,ICELL,GM,SS,IDF,F,FP,
+ IFAIL)
New: CALL G04CAF(M*NR*NC,Y1,2,LFAC,1,2,0,6,TABL,ITOTAL,TMEAN,MAXT,E,
+ IMEAN,SEMEAN,BMEAN,R,IWK,IFAIL)
Y1 is a onedimensional array containing the observations in the same order as Y, if
IY1
=
M and
IY2
=
NR then these are equivalent.
LFAC is an integer array such that
LFAC(1)
=
NC
and
LFAC(2)
=
NR
. The following indicates how the results equivalent to those produced by
G04AFF can be extracted from the results produced by
G04CAF.
G04AFF G04CAF
ROW(i) TMEAN(IMEAN(1)+i), i = 1,2,...,NR
COL(j) TMEAN(j), j = 1,2,...,NC
CELL(i,j) TMEAN(IMEAN(2)+(j1)*NR+i), i = 1,2,...,NR; j = 1,2,...,NC
GM BMEAN(1)
SS(1) TABL(3,2)
SS(2) TABL(2,2)
SS(i) TABL(4,2)
IDF(1) TABL(3,1)
IDF(2) TABL(2,1)
IDF(i) TABL(4,1)
F(1) TABL(3,4)
F(2) TABL(2,4)
F(3) TABL(4,4)
FP(1) TABL(3,5)
FP(2) TABL(2,5)
FP(3) TABL(4,5)
Note how rows and columns have swapped.
The following additional declarations are required.
double precision TABL(6,5), R(NMAX), TMEAN(MAXT), E(MAXT), BMEAN(1),
+ SEMEAN(5)
INTEGER IMEAN(5), IWK(NMAX+6), LFAC(2)
NMAX and
MAXT are integers such that
NMAX
≥
M
×
NR
×
NC
and
MAXT
≥
NR
+
NC
+
NR
×
NC
.
G05 – Random Number Generators
G05CAF
Withdrawn at Mark 22.
Replaced by
G05SAF.
Old:
DO 20 I = 1, N
X(I) = G05CAF(X(I))
20 CONTINUE
New: CALL G05SAF(N,STATE,X,IFAIL)
The integer array
STATE in the call to
G05SAF contains information on the base generator being used. This array must have been initialized prior to calling
G05SAF with a call to either
G05KFF or
G05KGF.
The required length of the array
STATE will depend on the base generator chosen during initialization.
Due to changes in the underlying code the sequence of values produced by
G05SAF is likely to be different from those produced by
G05CAF.
G05CBF
Withdrawn at Mark 22.
Replaced by
G05KFF.
Old: CALL G05CBF(I)
New: LSEED = 1
SEED(1) = I
GENID = 1
SUBID = 1
CALL G05KFF(GENID,SUBID,SEED,LSEED,STATE,LSTATE,IFAIL)
The integer array
STATE in the call to
G05KFF contains information on the base generator being used. The base generator is chosen via the integer parameters
GENID and
SUBID. The required length of the array
STATE depends on the base generator chosen. Due to changes in the underlying code a sequence of values produced by using a random
number generator initialized via a call to
G05KFF is likely to be different to a sequence produced by a generator initialized by
G05CBF, even if the same value for
I is used.
G05CCF
Withdrawn at Mark 22.
Replaced by
G05KGF.
Old: CALL G05CCF
New: GENID = 1
SUBID = 1
CALL G05KGF(GENID,SUBID,STATE,LSTATE,IFAIL)
The integer array
STATE in the call to
G05KGF contains information on the base generator being used. The base generator is chosen via the integer parameters
GENID and
SUBID. The required length of the array
STATE depends on the base generator chosen.
G05CFF
Withdrawn at Mark 22.
Replaced by
F06DFF.
Old: CALL G05CFF(IA,NI,XA,NX,IFAIL)
New: LSTATE = STATE(1)
CALL F06DFF(LSTATE,STATE,1,CSTATE,1)
The state of the base generator for the group of routines
G05KFF,
G05KGF,
G05KHF,
G05KJF,
G05NCF,
G05NDF,
G05PDF–
G05PZF,
G05RCF–
G05RZF, G05S and G05T can be saved by simply creating a local copy of the array STATE. The first element of the STATE array contains
the number of elements that are used by the random number generating routines, therefore either this number of elements can
be copied, or the whole array (as defined in the calling program).
G05CGF
Withdrawn at Mark 22.
Replaced by
F06DFF.
Old: CALL G05CGF(IA,NI,XA,NX,IFAIL)
New: LSTATE = CSTATE(1)
CALL F06DFF(LSTATE,CSTATE,1,STATE,1)
The state of the base generator for the group of routines
G05KFF,
G05KGF,
G05KHF,
G05KJF,
G05NCF,
G05NDF,
G05PDF–
G05PZF,
G05RCF–
G05RZF, G05S and G05T can be restored by simply copying back the previously saved copy of the STATE array. The first element of
the STATE array contains the number of elements that are used by the random number generating routines, therefore either this
number of elements can be copied, or the whole array (as defined in the calling program).
G05DAF
Withdrawn at Mark 22.
Replaced by
G05SQF.
Old: DO 10 I = 1, N
X(I) = G05DAF(AA,BB)
10 CONTINUE
New: A = MIN(AA,BB)
B = MAX(AA,BB)
IFAIL = 0
CALL G05SQF(N,A,B,STATE,X,IFAIL)
The old routine
G05DAF returns a single variate at a time, whereas the new routine
G05SQF returns a vector of
N values in one go. In
G05SQF the minimum value must be held in the parameter
A and the maximum in parameter
B, therefore
A < B. This was not the case for the equivalent parameters in
G05DAF.
The integer array
STATE in the call to
G05SQF contains information on the base generator being used. This array must have been initialized prior to calling
G05SQF with a call to either
G05KFF or
G05KGF.
The required length of the array
STATE will depend on the base generator chosen during initialization.
Due to changes in the underlying code the sequence of values produced by
G05SQF is likely to be different from those produced by
G05DAF.
G05DBF
Withdrawn at Mark 22.
Replaced by
G05SFF.
Old: DO 10 I = 1, N
X(I) = G05DBF(AA)
10 CONTINUE
New: A = ABS(AA)
IFAIL = 0
CALL G05SFF(N,A,STATE,X,IFAIL)
The old routine
G05DBF returns a single variate at a time, whereas the new routine
G05SFF returns a vector of
N values in one go. In
G05SFF parameter
A must be nonnegative, this was not the case for the equivalent parameter in
G05DBF.
The integer array
STATE in the call to
G05SFF contains information on the base generator being used. This array must have been initialized prior to calling
G05SFF with a call to either
G05KFF or
G05KGF.
The required length of the array
STATE will depend on the base generator chosen during initialization.
Due to changes in the underlying code the sequence of values produced by
G05SFF is likely to be different from those produced by
G05DBF.
G05DCF
Withdrawn at Mark 22.
Replaced by
G05SLF.
Old: DO 10 I = 1, N
X(I) = G05DCF(A,BB)
10 CONTINUE
New: B = ABS(BB)
IFAIL = 0
CALL G05SLF(N,A,B,STATE,X,IFAIL)
The old routine
G05DCF returns a single variate at
a time, whereas the new routine
G05SLF returns a
vector of
N values in one go. In
G05SLF the spread (parameter
A) must be positive, this was not the case for the equivalent parameters
in
G05DCF.
The integer array
STATE in the call to
G05SLF
contains information on the base generator being used. This array must have
been initialized prior to calling
G05SLF with a call
to either
G05KFF or
G05KGF.
The required length of the array
STATE
will depend on the base generator chosen during initialization.
Due to changes
in the underlying code the sequence of values produced by
G05SLF is likely to be different from those produced by
G05DCF.
G05DDF
Withdrawn at Mark 22.
Replaced by
G05SKF.
Old: DO 10 I = 1, N
X(I) = G05DDF(XMU,SD)
10 CONTINUE
New: VAR = SD**2
IFAIL = 0
CALL G05SKF(N,XMU,VAR,STATE,X,IFAIL)
The old routine
G05DDF returns a single variate at
a time, whereas the new routine
G05SKF returns a
vector of
N values in one go.
G05SKF expects the variance of the Normal distribution
(parameter
VAR), compared to
G05DDF which expected the standard deviation.
The
integer array
STATE in the call to
G05SKF contains information on the base generator being
used. This array must have been initialized prior to calling
G05SKF with a call to either
G05KFF or
G05KGF.
The required length of the array
STATE will depend on the base generator chosen during
initialization.
Due to changes in the underlying code the sequence of values
produced by
G05SKF is likely to be different from those
produced by
G05DDF.
G05DEF
Withdrawn at Mark 22.
Replaced by
G05SMF.
Old: DO 10 I = 1, N
X(I) = G05DEF(XMU,SD)
10 CONTINUE
New: VAR = SD**2
IFAIL = 0
CALL G05SMF(N,XMU,VAR,STATE,X,IFAIL)
The old routine
G05DEF returns a single variate at
a time, whereas the new routine
G05SMF returns a
vector of
N values in one go.
G05SMF expects the variance of the corresponding normal
distribution (parameter
VAR), compared
to
G05DEF which expected the standard deviation.
The integer array
STATE in the call
to
G05SMF contains information on the base generator
being used. This array must have been initialized prior to calling
G05SMF with a call to either
G05KFF
or
G05KGF.
The required length of the array
STATE will depend on the base generator chosen
during initialization.
Due to changes in the underlying code the sequence of
values produced by
G05SMF is likely to be different to
those produced by
G05DEF.
G05DFF
Withdrawn at Mark 22.
Replaced by
G05SCF.
Old: DO 10 I = 1, N
X(I) = G05DFF(XMED,B)
10 CONTINUE
New: SEMIQR = ABS(B)
IFAIL = 0
CALL G05SCF(N,XMED,SEMIQR,STATE,X,IFAIL)
The old routine
G05DFF returns a single variate at
a time, whereas the new routine
G05SCF returns a
vector of
N values in one go.
G05SCF expects the semiinterquartile range (parameter
SEMIQR) to be nonnegative, this was not the
case for the equivalent parameter in
G05DFF.
The integer array
STATE in the call
to
G05SCF contains information on the base generator
being used. This array must have been initialized prior to calling
G05SCF with a call to either
G05KFF
or
G05KGF.
The required length of the array
STATE will depend on the base generator chosen
during initialization.
Due to changes in the underlying code the sequence of
values produced by
G05SCF is likely to be different to
those produced by
G05DFF.
G05DGF
Withdrawn at Mark 16.
Replaced by
G05SJF.
Old: DO 20 I = 1, N
X(I) = G05DGF(A,B,IFAIL)
20 CONTINUE
New: CALL G05SJF(N,A,B,STATE,X,IFAIL)
The old routine
G05DGF returns a single variate at a time, whereas the new routine
G05SJF returns a vector of
N values in one go.
The integer array
STATE in the call to
G05SJF contains information on the base generator being used. This array must have been initialized prior to calling
G05SJF with a call to either
G05KFF or
G05KGF. The required length of the array
STATE will depend on the base generator chosen during initialization. Due to changes in the underlying code the sequence of values
produced by
G05SJF is likely to be different from those produced by
G05DGF.
G05DHF
Withdrawn at Mark 22.
Replaced by
G05SDF.
Old: DO 10 I = 1, N
X(I) = G05DHF(DF,IFAIL)
10 CONTINUE
New: CALL G05SDF(N,DF,STATE,X,IFAIL)
The old routine
G05DHF returns a single variate at
a time, whereas the new routine
G05SDF returns a
vector of
N values in one go.
The
integer array
STATE in the call to
G05SDF contains information on the base generator being
used. This array must have been initialized prior to calling
G05SDF with a call to either
G05KFF or
G05KGF.
The required length of the array
STATE will depend on the base generator chosen during
initialization.
Due to changes in the underlying code the sequence of values
produced by
G05SDF is likely to be different from those
produced by
G05DHF.
G05DJF
Withdrawn at Mark 22.
Replaced by
G05SNF.
Old: DO 10 I = 1, N
X(I) = G05DJF(DF,IFAIL)
10 CONTINUE
New: CALL G05SNF(N,DF,STATE,X,IFAIL)
The old routine
G05DJF returns a single variate at
a time, whereas the new routine
G05SNF returns a
vector of
N values in one go.
The
integer array
STATE in the call to
G05SNF contains information on the base generator being
used. This array must have been initialized prior to calling
G05SNF with a call to either
G05KFF or
G05KGF.
The required length of the array
STATE will depend on the base generator chosen during
initialization.
Due to changes in the underlying code the sequence of values
produced by
G05SNF is likely to be different from those
produced by
G05DJF.
G05DKF
Withdrawn at Mark 22.
Replaced by
G05SHF.
Old: DO 10 I = 1, N
X(I) = G05DKF(DF1,DF2,IFAIL)
10 CONTINUE
New: CALL G05SHF(N,DF1,DF2,STATE,X,IFAIL)
The old routine
G05DKF returns a single variate at
a time, whereas the new routine
G05SHF returns a
vector of
N values in one go.
The
integer array
STATE in the call to
G05SHF contains information on the base generator being
used. This array must have been initialized prior to calling
G05SHF with a call to either
G05KFF or
G05KGF.
The required length of the array
STATE will depend on the base generator chosen during
initialization.
Due to changes in the underlying code the sequence of values
produced by
G05SHF is likely to be different from those
produced by
G05DKF.
G05DLF
Withdrawn at Mark 16.
Replaced by
G05SBF.
Old: DO 20 I = 1, N
X(I) = G05DLF(A,B,IFAIL)
CONTINUE
New: CALL G05SBF(N,A,B,STATE,X,IFAIL)
The old routine
G05DLF returns a single variate at a time, whereas the new routine
G05SBF returns a vector of
N values in one go.
The integer array
STATE in the call to
G05SBF contains information on the base generator being used. This array must have been initialized prior to calling
G05SBF with a call to either
G05KFF or
G05KGF. The required length of the array
STATE will depend on the base generator chosen during initialization. Due to changes in the underlying code the sequence of values
produced by
G05SBF is likely to be different from those produced by
G05DLF.
G05DMF
Withdrawn at Mark 16.
Replaced by
G05SBF.
Old: DO 20 I = 1, N
X(I) = G05DMF(A,B,IFAIL)
20 CONTINUE
There is no direct replacement for
G05DMF. However, there are two methods for obtaining the same functionality.
Method 1:
New: CALL G05SBF(N,A,B,STATE,Y1,IFAIL)
J = 0
DO 20 I = 1, N
IF (Y1(I).LT.1.0Exp;0) THEN
J = J + 1
X(J) = Y1(I)/(1.0D0Y1(I))
END IF
20 CONTINUE
Method 2:
New: CALL G05SBF(N,A,1.0D0,STATE,Y1,IFAIL)
CALL G05SBF(N,B,1.0D0,STATE,Y2,IFAIL)
J = 0
DO 20 I = 1, N
IF (Y2(I).LT.0.0Exp;0) THEN
J = J + 1
X(J) = Y1(I)/Y2(I)
END IF
20 CONTINUE
The old routine
G05DMF returns a single variate at a time, whereas the routine
G05SBF returns a vector of
N values in one go.
The integer array
STATE in the call to
G05SBF contains information on the base generator being used. This array must have been initialized prior to calling
G05SBF with a call to either
G05KFF or
G05KGF. The required length of the array
STATE will depend on the base generator chosen during initialization. The sequence of values produced by the replacement code suggested
above will be different to those produced by
G05DMF.
G05DPF
Withdrawn at Mark 22.
Replaced by
G05SSF.
Old: DO 10 I = 1, N
X(I) = G05DPF(A,B,IFAIL)
10 CONTINUE
New: CALL G05SSF(N,A,B,STATE,X,IFAIL)
The old routine
G05DPF returns a single variate at
a time, whereas the new routine
G05SSF returns a
vector of
N values in one go.
The
integer array
STATE in the call to
G05SSF contains information on the base generator being
used. This array must have been initialized prior to calling
G05SSF with a call to either
G05KFF or
G05KGF.
The required length of the array
STATE will depend on the base generator chosen during
initialization.
Due to changes in the underlying code the sequence of values
produced by
G05SSF is likely to be different from those
produced by
G05DPF.
G05DRF
Withdrawn at Mark 22.
Replaced by
G05TKF.
Old: DO 10 I = 1, N
X(I) = G05DRF(LAMDA,IFAIL)
10 CONTINUE
New: MODE = 3
CALL G05TJF(MODE,N,LAMBDA,R,LR,STATE,X,IFAIL)
The old routine
G05DRF returns a single variate at
a time, whereas the new routine
G05TJF returns a
vector of
N values in one go. For
efficiency, the new routine can make use of a reference vector,
R. If, as in this case, the integer parameter
MODE is set to 3, the real reference
vector
R is not
referenced , and its
length,
LR, need only be at least
one.
The integer array
STATE in
the call to
G05TJF contains information on the base
generator being used. This array must have been initialized prior to calling
G05TJF with a call to either
G05KFF or
G05KGF.
The required length of the
array
STATE will depend on the base
generator chosen during initialization.
Due to changes in the underlying code
the sequence of values produced by
G05TJF is likely to
be different to those produced by
G05DRF.
G05DYF
Withdrawn at Mark 22.
Replaced by
G05TLF.
Old: DO 10 I = 1, N
X(I) = G05DYF(AA,BB)
10 CONTINUE
New: IFAIL = 0
A = MIN(AA,BB)
B = MAX(AA,BB)
CALL G05TLF(N,A,B,STATE,X,IFAIL)
The old routine
G05DYF returns a single variate at a time, whereas the new routine
G05TLF returns a vector of
N values in one go. In
G05TLF the minimum value must be held in the parameter
A and the maximum in parameter
B, therefore
A ≤ B. This was not the case for the equivalent parameters in
G05DYF.
The integer array
STATE in the call to
G05TLF contains information on the base generator being used. This array must have been initialized prior to calling
G05TLF with a call to either
G05KFF or
G05KGF.
The required length of the array
STATE will depend on the base generator chosen during initialization.
Due to changes in the underlying code the sequence of values produced by
G05TLF is likely to be different from those produced by
G05DYF.
G05DZF
Withdrawn at Mark 22.
Replaced by
G05TBF.
Old:
DO 20 I = 1, N
X(I) = G05DZF(PP)
20 CONTINUE
New: P = MAX(0.0D0,MIN(PP,1.0D0))
IFAIL = 0
CALL G05TBF(N,P,STATE,X,IFAIL)
The old routine
G05DZF returns a single variate at
a time, whereas the new routine
G05TBF returns a
vector of
N values in one go. The
double precision parameter
P in
G05TBF must not be less than zero or greater than one, this was not the
case for the equivalent parameter in
G05DZF.
The integer array
STATE in the call
to
G05TBF contains information on the base generator
being used. This array must have been initialized prior to calling
G05TBF with a call to either
G05KFF
or
G05KGF.
The required length of the array
STATE will depend on the base generator chosen
during initialization.
Due to changes in the underlying code the sequence of
values produced by
G05TBF is likely to be different to
those produced by
G05DZF.
G05EAF
Withdrawn at Mark 22.
Replaced by
G05RZF.
Old: CALL G05EAF(XMU,M,C,LDC,EPS,R1,LR1,IFAIL)
New: MODE = 0
CALL G05RZF(MODE,N,M,XMU,C,LDC,R,LR,STATE,X,LDX,IFAIL)
The old routine
G05EAF sets up a reference vector for use by
G05EZF. The functionality of both these routines has been combined into the single new routine
G05RZF. Setting
MODE = 0 in the call to
G05RZF only sets up the
double precision reference vector
R and hence mimics the functionality of
G05EAF.
The length of the
double precision reference vector,
R, in
G05RZF must be at least
M × (M + 1) + 1. This is longer than the equivalent parameter in
G05EAF.
G05EBF
Withdrawn at Mark 22.
Replaced by
G05TLF.
There is no direct replacement for routine
G05EBF.
G05EBF sets up a reference vector for use by
G05EYF, this reference vector is no longer required. The replacement routine for
G05EYF is
G05TLF.
G05ECF
Withdrawn at Mark 22.
Replaced by
G05TJF.
Old: CALL G05ECF(LAMBDA,R1,LR1,IFAIL)
DO 10 I = 1, N
X(I) = G05EYF(R1,LR1)
10 CONTINUE
New: MODE = 2
CALL G05TJF(MODE,N,LAMBDA,R,LR,STATE,X,IFAIL)
The old routine
G05ECF sets up a reference vector for use by
G05EYF. The replacement routine
G05TJF is now used to both set up a reference vector and generate the required variates. Setting
MODE = 0 in the call to
G05TJF sets up the
double precision reference vector
R and hence mimics the functionality of
G05ECF. Setting
MODE = 1 generates a series of variates from a reference vector mimicking the functionality of
G05EYF for this particular distribution. Setting
MODE = 2 initializes the reference vector and generates the variates in one go.
The routine
G05EYF returns a single variate at a time, whereas the new routine
G05TJF returns a vector of
N values in one go.
The length of the
double precision reference vector,
R, in
G05TJF, needs to be a different length from the equivalent parameter in
G05ECF, see the documentation for more details.
The integer array
STATE in the call to
G05TJF contains information on the base generator being used. This array must have been initialized prior to calling
G05TJF with a call to either
G05KFF or
G05KGF.
The required length of the array
STATE will depend on the base generator chosen during initialization.
Due to changes in the underlying code the sequence of values produced by
G05TJF is likely to be different from those produced by a combination of
G05ECF and
G05EYF.
G05EDF
Withdrawn at Mark 22.
Replaced by
G05TAF.
Old: CALL G05EDF(M,P,R1,LR1,IFAIL)
DO 10 I = 1, N
X(I) = G05EYF(R1,LR1)
10 CONTINUE
New: MODE = 2
CALL G05TAF(MODE,N,M,P,R,LR,STATE,X,IFAIL)
The old routine
G05EDF sets up a reference vector for use by
G05EYF. The replacement routine
G05TAF is now used to both set up a reference vector and generate the required variates. Setting
MODE = 0 in the call to
G05TAF sets up the
double precision reference vector
R and hence mimics the functionality of
G05EDF. Setting
MODE = 1 generates a series of variates from a reference vector mimicking the functionality of
G05EYF for this particular distribution. Setting
MODE = 2 initializes the reference vector and generates the variates in one go.
The routine
G05EYF returns a single variate at a time, whereas the new routine
G05TAF returns a vector of
N values in one go.
The length of the
double precision reference vector,
R, in
G05TAF, needs to be a different length from the equivalent parameter in
G05EDF, see the documentation for more details.
The integer array
STATE in the call to
G05TAF contains information on the base generator being used. This array must have been initialized prior to calling
G05TAF with a call to either
G05KFF or
G05KGF.
The required length of the array
STATE will depend on the base generator chosen during initialization.
Due to changes in the underlying code the sequence of values produced by
G05TAF is likely to be different from those produced by a combination of
G05EDF and
G05EYF.
G05EEF
Withdrawn at Mark 22.
Replaced by
G05THF.
Old: CALL G05EEF(M,P,R1,LR1,IFAIL)
DO 10 I = 1, N
X(I) = G05EYF(R1,LR1)
10 CONTINUE
New: MODE = 2
CALL G05THF(MODE,N,M,P,R,LR,STATE,X,IFAIL)
The old routine
G05EEF sets up a reference vector for use by
G05EYF. The replacement routine
G05THF is now used to both set up a reference vector and generate the required variates. Setting
MODE = 0 in the call to
G05THF sets up the
double precision reference vector
R and hence mimics the functionality of
G05EEF. Setting
MODE = 1 generates a series of variates from a reference vector mimicking the functionality of
G05EYF for this particular distribution. Setting
MODE = 2 initializes the reference vector and generates the variates in one go.
The routine
G05EYF returns a single variate at a time, whereas the new routine
G05THF returns a vector of
N values in one go.
The length of the
double precision reference vector,
R, in
G05THF, needs to be a different length from the equivalent parameter in
G05EEF, see the documentation for
G05THF for more details.
The integer array
STATE in the call to
G05THF contains information on the base generator being used. This array must have been initialized prior to calling
G05THF with a call to either
G05KFF or
G05KGF.
The required length of the array
STATE will depend on the base generator chosen during initialization.
Due to changes in the underlying code the sequence of values produced by
G05THF is likely to be different to those produced by a combination of
G05EEF and
G05EYF.
G05EFF
Withdrawn at Mark 22.
Replaced by
G05TEF.
Old: CALL G05EFF(NS,M,NP,R1,LR1,IFAIL)
DO 10 I = 1, N
X(I) = G05EYF(R1,LR1)
10 CONTINUE
New: MODE = 2
CALL G05TEF(MODE,N,NS,NP,M,R,LR,STATE,X,IFAIL)
The old routine
G05EFF sets up a reference vector for use by
G05EYF. The replacement routine
G05TEF is now used to both set up a reference vector and generate the required variates. Setting
MODE = 0 in the call to
G05TEF sets up the
double precision reference vector
R and hence mimics the functionality of
G05EFF. Setting
MODE = 1 generates a series of variates from a reference vector mimicking the functionality of
G05EYF for this particular distribution. Setting
MODE = 2 initializes the reference vector and generates the variates in one go.
The routine
G05EYF returns a single variate at a time, whereas the new routine
G05TEF returns a vector of
N values in one go.
The length of the
double precision reference vector,
R, in
G05TEF, needs to be a different length from the equivalent parameter in
G05EFF, see the documentation for more details.
The integer array
STATE in the call
to
G05TEF contains information on the base generator
being used. This array must have been initialized prior to calling
G05TEF with a call to either
G05KFF
or
G05KGF.
The required length of the array
STATE will depend on the base generator chosen
during initialization.
Due to changes in the underlying code the sequence of
values produced by
G05TEF is likely to be different to
those produced by a combination of
G05EFF and
G05EYF.
G05EGF
Withdrawn at Mark 22.
Replaced by
G05PHF.
Old: CALL G05EGF(E,A,NA,B,NB,R,NR,VAR,IFAIL)
New: AVAR = B(1)**2
IQ = NB  1
IF (AVAR.GT.0.0D0) THEN
DO 10 I = 1, IQ
THETA(I) = B(I+1)/B(1)
10 CONTINUE
ELSE
DO 20 I = 1, IQ
THETA(I) = 0.0D0
20 CONTINUE
END IF
MODE = 0
CALL G05PHF(MODE,N,E,NA,A,IQ,THETA,AVAR,R,LR,STATE,VAR,X,IFAIL)
The
double precision vector
THETA must be of length at least
IQ = NB  1.
The old routine
G05EGF sets up a reference vector for use by
G05EWF. The replacement routine
G05PHF is now used to both set up a reference vector and generate the required variates. Setting
MODE = 0 in the call to
G05PHF sets up the
double precision reference vector
R and hence mimics the functionality of
G05EGF. When
MODE = 0, the integer array
STATE in the call to
G05PHF need not be set.
G05EHF
Withdrawn at Mark 22.
Replaced by
G05NCF.
Old: CALL G05EHF(INDEX,N,IFAIL)
New: CALL G05NCF(INDEX,N,STATE,IFAIL)
The integer array
STATE in the call to
G05NCF contains information on the base generator being used. This array must have been initialized prior to calling
G05NCF with a call to either
G05KFF or
G05KGF.
The required length of the array
STATE will depend on the base generator chosen during initialization.
Due to changes in the underlying code the sequence of values produced by
G05NCF is likely to be different from those produced by
G05EHF.
G05EJF
Withdrawn at Mark 22.
Replaced by
G05NDF.
Old: CALL G05EJF(IA,N,IZ,M,IFAIL)
New: CALL G05NDF(IA,N,IZ,M,STATE,IFAIL)
The integer array
STATE in the call to
G05NDF contains information on the base generator being used. This array must have been initialized prior to calling
G05NDF with a call to either
G05KFF or
G05KGF.
The required length of the array
STATE will depend on the base generator chosen during initialization.
Due to changes in the underlying code the sequence of values produced by
G05NDF is likely to be different from those produced by
G05EJF.
G05EWF
Withdrawn at Mark 22.
Replaced by
G05PHF.
Old: CALL G05EGF(E,A,NA,B,NB,R,NR,VAR,IFAIL)
DO 10 I = 1, N
X(I) = G05EWF(R,NR,IFAIL)
10 CONTINUE
New: AVAR = B(1)**2
IQ = NB  1
IF (AVAR.GT.0.0D0) THEN
DO 10 I = 1, IQ
THETA(I) = B(I+1)/B(1)
10 CONTINUE
ELSE
DO 20 I = 1, IQ
THETA(I) = 0.0D0
20 CONTINUE
END IF
MODE = 2
CALL G05PHF(MODE,N,E,NA,A,NB1,THETA,AVAR,VAR,R,LR,STATE,X,IFAIL)
The
double precision vector
THETA must be of length at least
IQ = NB  1.
The old routine
G05EGF sets up a reference vector for use by
G05EWF. The replacement routine
G05PHF is now used to both set up a reference vector and generate the required variates. Setting the integer parameter
MODE to 0 in the call to
G05PHF sets up the
double precision reference vector
R and hence mimics the functionality of
G05EGF. Setting
MODE to 1 generates a series of variates from a reference vector mimicking the functionality of
G05EWF. Setting
MODE to 2 initializes the reference vector and generates the variates in one go.
The integer array
STATE in the call to
G05PHF contains information on the base generator being used. This array must have been initialized prior to calling
G05PHF with a call to either
G05KFF or
G05KGF.
The required length of the array
STATE will depend on the base generator chosen during initialization.
Due to changes in the underlying code the sequence of values produced by
G05PHF is likely to be different to those produced by
G05EGF.
G05EXF
Withdrawn at Mark 22.
Replaced by
G05TDF.
Old: CALL G05EXF(P,NP,IP1,ITYPE,R1,LR1,IFAIL)
DO 10 I = 1, N
X(I) = G05EYF(R1,LR1)
10 CONTINUE
New: MODE = 2
CALL G05TDF(MODE,N,P,NP,IP1,ITYPE,R,LR,STATE,X,IFAIL)
The old routine
G05EXF sets up a reference vector for use by
G05EYF. The replacement routine
G05TDF is now used to both set up a reference vector and generate the required variates. Setting
MODE = 0 in the call to
G05TDF sets up the
double precision reference vector
R and hence mimics the functionality of
G05EXF. Setting
MODE = 1 generates a series of variates from a reference vector mimicking the functionality of
G05EYF for this particular distribution. Setting
MODE = 2 initializes the reference vector and generates the variates in one go.
The routine
G05EYF returns a single variate at a time, whereas the new routine
G05TDF returns a vector of
N values in one go.
The length of the
double precision reference vector,
R, in
G05TDF, needs to be a different length from the equivalent parameter in
G05EXF, see the documentation for more details.
The integer array
STATE in the call to
G05TDF contains information on the base generator being used. This array must have been initialized prior to calling
G05TDF with a call to either
G05KFF or
G05KGF.
The required length of the array
STATE will depend on the base generator chosen during initialization.
Due to changes in the underlying code the sequence of values produced by
G05TDF is likely to be different from those produced by a combination of
G05EXF and
G05EYF.
G05EYF
Withdrawn at Mark 22.
Replaced by
G05TDF.
There is no direct replacement routine for
G05EYF.
G05EYF is designed to generate random draws from a distribution defined by a reference vector. These reference vectors are created
by other routines in
Chapter G05, for example
G05EBF,
which have themselves been superseded. In order to replace a call to
G05EYF you must identify which NAG routine generated the reference vector being used and look up its replacement. For example, to
replace a call to
G05EYF preceded by a call to
G05EBF,
as in:
CALL G05EBF(M,IB,R,NR,IFAIL)
X = G05EYF(R,NR)
you would need to look at the replacement routine for
G05EBF.
G05EZF
Withdrawn at Mark 22.
Replaced by
G05RZF.
Old: CALL G05EAF(XMU,N,C,LDC,EPS,R1,LR1,IFAIL)
DO 20 I = 1, N
CALL G05EZF(CX,M,R,NR,IFAIL)
DO 30 J = 1, M
X(I,J) = CX(J)
30 CONTINUE
20 CONTINUE
New: MODE = 2
CALL G05RZF(MODE,N,M,XMU,C,LDC,R,LR,STATE,X,LDX,IFAIL)
The old routine
G05EAF sets up a reference vector for use by
G05EZF. The functionality of both these routines has been combined into the single new routine
G05RZF. Setting
MODE = 2 in the call to
G05RZF sets up the
double precision reference vector
R and generates the draws from the multivariate Normal distribution in one go.
The old routine
G05EZF returns a single (
Mdimensional vector) draw from the multivariate Normal distribution at a time, whereas the new routine
G05RZF returns an
N by
M matrix of
N draws in one go.
The integer array
STATE in the call to
G05RZF contains information on the base generator being used. This array must have been initialized prior to calling
G05RZF with a call to either
G05KFF or
G05KGF.
The required length of the array
STATE will depend on the base generator chosen during initialization.
Due to changes in the underlying code the sequence of values produced by
G05RZF is likely to be different from those produced by
G05EZF.
G05FAF
Withdrawn at Mark 22.
Replaced by
G05SQF.
Old: CALL G05FAF(AA,BB,N,X)
New: A = MIN(AA,BB)
B = MAX(AA,BB)
IFAIL = 0
CALL G05SQF(N,A,B,STATE,X,IFAIL)
In
G05SQF the minimum value must be held in the parameter A and the maximum in parameter
B, therefore
A ≤ B. This was not the case for the equivalent parameters in
G05FAF.
The integer array
STATE in the call to
G05SQF contains information on the base generator being used. This array must have been initialized prior to calling
G05SQF with a call to either
G05KFF or
G05KGF.
The required length of the array
STATE will depend on the base generator chosen during initialization.
Due to changes in the underlying code the sequence of values produced by
G05SQF is likely to be different from those produced by
G05FAF.
G05FBF
Withdrawn at Mark 22.
Replaced by
G05SFF.
Old: CALL G05FBF(AA,N,X)
New: A = ABS(AA)
IFAIL = 0
CALL G05SFF(N,A,STATE,X,IFAIL)
In
G05SFF parameter
A must be nonnegative, this was not the case for the equivalent parameter in
G05FBF.
The integer array
STATE in the call to
G05SFF contains information on the base generator being used. This array must have been initialized prior to calling
G05SFF with a call to either
G05KFF or
G05KGF.
The required length of the array
STATE will depend on the base generator chosen during initialization.
Due to changes in the underlying code the sequence of values produced by
G05SFF is likely to be different from those produced by
G05FBF.
G05FDF
Withdrawn at Mark 22.
Replaced by
G05SKF.
Old: CALL G05FDF(XMU,SD,N,X)
New: VAR = SD**2
IFAIL = 0
CALL G05SKF(N,XMU,VAR,STATE,X,IFAIL)
G05SKF expects the variance of the normal distribution (parameter
VAR), compared to
G05FDF which expected the standard deviation.
The integer array
STATE in the call to
G05SKF contains information on the base generator being used. This array must have been initialized prior to calling
G05SKF with a call to either
G05KFF or
G05KGF.
The required length of the array
STATE will depend on the base generator chosen during initialization.
Due to changes in the underlying code the sequence of values produced by
G05SKF is likely to be different from those produced by
G05FDF.
G05FEF
Withdrawn at Mark 22.
Replaced by
G05SBF.
Old: CALL G05FEF(A,B,N,X,IFAIL)
New: CALL G05SBF(N,A,B,STATE,X,IFAIL)
The integer array
STATE in the call to
G05SBF contains information on the base generator being used. This array must have been initialized prior to calling
G05SBF with a call to either
G05KFF or
G05KGF.
The required length of the array
STATE will depend on the base generator chosen during initialization.
Due to changes in the underlying code the sequence of values produced by
G05SBF is likely to be different from those produced by
G05FEF.
G05FFF
Withdrawn at Mark 22.
Replaced by
G05SJF.
Old: CALL G05FFF(A,B,N,X,IFAIL)
New: CALL G05SJF(N,A,B,STATE,X,IFAIL)
The integer array
STATE in the call to
G05SJF contains information on the base generator being used. This array must have been initialized prior to calling
G05SJF with a call to either
G05KFF or
G05KGF.
The required length of the array
STATE will depend on the base generator chosen during initialization.
Due to changes in the underlying code the sequence of values produced by
G05SJF is likely to be different from those produced by
G05FFF.
G05FSF
Withdrawn at Mark 22.
Replaced by
G05SRF.
Old: CALL G05FSF(VK,N,X,IFAIL)
New: CALL G05SRF(N,VK,STATE,X,IFAIL)
The integer array
STATE in the call to
G05SRF contains information on the base generator being used. This array must have been initialized prior to calling
G05SRF with a call to either
G05KFF or
G05KGF.
The required length of the array
STATE will depend on the base generator chosen during initialization.
Due to changes in the underlying code the sequence of values produced by
G05SRF is likely to be different from those produced by
G05FSF.
G05GAF
Withdrawn at Mark 22.
Replaced by
G05PXF.
Old: CALL G05GAF(SIDE,INIT,M,N,A,LDA,WK,IFAIL)
New: CALL G05PXF(SIDE,INIT,M,N,STATE,A,LDA,IFAIL)
The integer array
STATE in the call to
G05PXF contains information on the base generator being used. This array must have been initialized prior to calling
G05PXF with a call to either
G05KFF or
G05KGF.
The required length of the array
STATE will depend on the base generator chosen during initialization.
Due to changes in the underlying code the sequence of values produced by
G05PXF is likely to be different from those produced by
G05GAF.
G05GBF
Withdrawn at Mark 22.
Replaced by
G05PYF.
Old: CALL G05GBF(N,D,C,LDC,EPS,WK,IFAIL)
New: CALL G05PYF(N,D,EPS,STATE,C,LDC,IFAIL)
The integer array
STATE in the call to
G05PYF contains information on the base generator being used. This array must have been initialized prior to calling
G05PYF with a call to either
G05KFF or
G05KGF.
The required length of the array
STATE will depend on the base generator chosen during initialization.
Due to changes in the underlying code the sequence of values produced by
G05PYF is likely to be different from those produced by
G05GBF.
G05HDF
Withdrawn at Mark 22.
Replaced by
G05PJF.
Old: CALL G05HDF(MODE,K,IP,IQ,MEAN,PAR,LPAR,QQ,LDQQ,N,W,REF,LREF,
+ IWORK,LIWORK,IFAIL)
New: IF (MODE.EQ.'S') THEN
IMODE = 0
ELSE IF (MODE.EQ.'C') THEN
IMODE = 1
ELSE IF (MODE.EQ.'R') THEN
IMODE = 3
END IF
LL = 0
DO 30 L = 1, IP
DO 20 I = 1, K
DO 10 J = 1, K
LL = LL + 1
PHI(I,J,L) = PAR(LL)
10 CONTINUE
20 CONTINUE
30 CONTINUE
DO 60 L = 1, IQ1
DO 50 I = 1, K
DO 40 J = 1, K
LL = LL + 1
THETA(I,J,L) = PAR(LL)
40 CONTINUE
50 CONTINUE
60 CONTINUE
IF (MEAN.EQ.'M') THEN
DO 70 I = 1, K
LL = LL + 1
XMEAN(I) = PAR(LL)
70 CONTINUE
ELSE
DO 80 I = 1, K
XMEAN(I) = 0.0D0
80 CONTINUE
END IF
LDW = N
CALL G05PJF(IMODE,N,K,XMEAN,IP,PHI,IQ,THETA,QQ,LDQQ,REF,LREF,
+ STATE,W,LDW,IWORK,LIWORK,IFAIL)
The integer parameter
IMODE should be set to 0, 1 or 3 in place of the parameter MODE having settings of 'S', 'C' or 'R' respectively. The
double precision array
PHI should have length at least
max (1,IP × (K × K))
; if dimensioned as
PHI(K,K,IP)
(as in the above example) then
PHI
(i,j,l)
will contain the element
PAR
((l  1) × k × k + (i  1) × k + j)
. The
double precision array
THETA should have length at least
max (1,IQ × (K × K))
; if dimensioned as
THETA
(K,K,IQ)
(as in the above example) then
THETA
(i,j,l)
will contain the element
PAR
(IP × k × k + (l  1) × k × k + (i  1) × k + j)
. The
double precision array
XMEAN should have length at least
K; if
MEAN = 'M'
then
XMEAN
(i)
will contain the element
PAR
(IP + IQ × k × k + i)
, otherwise
XMEAN should contain an array of zero values.
The integer array
STATE in the call to
G05PJF contains information on the base generator being used. This array must have been initialized prior to calling
G05PJF with a call to either
G05KFF or
G05KGF.
The required length of the array
STATE will depend on the base generator chosen during initialization.
Due to changes in the underlying code the sequence of values produced by
G05PJF is likely to be different from those produced by
G05HDF.
G05HKF
Scheduled for withdrawal at Mark 24.
Replaced by
G05PDF.
Old: CALL G05HKF(DIST,NUM,IP,IQ,THETA,GAMMA,DF,HT,ET,FCALL,RVEC,IGEN,ISEED,RWSAV,IFAIL)
New: CALL G05PDF(DIST,NUM,IP,IQ,THETA,GAMMA,DF,HT,ET,FCALL,R,LR,STATE,IFAIL)
The integer array
STATE in the call to
G05PDF contains information on the base generator being used. This array must have been initialized prior to calling
G05PDF with a call to either
G05KFF or
G05KGF.
The required length of the array
STATE will depend on the base generator chosen during initialization.
Due to changes in the underlying code the sequence of values produced by
G05PDF is likely to be different from those produced by
G05HKF.
G05HLF
Scheduled for withdrawal at Mark 24.
Replaced by
G05PEF.
Old: CALL G05HLF(DIST,NUM,IP,IQ,THETA,GAMMA,DF,HT,ET,FCALL,RVEC,IGEN,ISEED,RWSAV,IFAIL)
New: CALL G05PEF(DIST,NUM,IP,IQ,THETA,GAMMA,DF,HT,ET,FCALL,R,LR,STATE,IFAIL)
The integer array
STATE in the call to
G05PEF contains information on the base generator being used. This array must have been initialized prior to calling
G05PEF with a call to either
G05KFF or
G05KGF.
The required length of the array
STATE will depend on the base generator chosen during initialization.
Due to changes in the underlying code the sequence of values produced by
G05PEF is likely to be different from those produced by
G05HLF.
G05HMF
Scheduled for withdrawal at Mark 24.
Replaced by
G05PFF.
Old: CALL G05HMF(DIST,NUM,IP,IQ,THETA,GAMMA,DF,HT,ET,FCALL,RVEC,IGEN,ISEED,RWSAV,IFAIL)
New: CALL G05PFF(DIST,NUM,IP,IQ,THETA,GAMMA,DF,HT,ET,FCALL,R,LR,STATE,IFAIL)
The integer array
STATE in the call to
G05PFF contains information on the base generator being used. This array must have been initialized prior to calling
G05PFF with a call to either
G05KFF or
G05KGF.
The required length of the array
STATE will depend on the base generator chosen during initialization.
Due to changes in the underlying code the sequence of values produced by
G05PFF is likely to be different from those produced by
G05HMF.
G05HNF
Scheduled for withdrawal at Mark 24.
Replaced by
G05PGF.
Old: CALL G05HNF(DIST,NUM,IP,IQ,THETA,DF,HT,ET,FCALL,RVEC,IGEN,ISEED,RWSAV,IFAIL)
New: CALL G05PGF(DIST,NUM,IP,IQ,THETA,DF,HT,ET,FCALL,RVEC,STATE,IFAIL)
G05KAF
Scheduled for withdrawal at Mark 24.
Replaced by
G05SAF.
Old:
DO 20 I = 1, N
X(I) = G05KAF(IGEN,ISEED)
20 CONTINUE
New: CALL G05SAF(N,STATE,X,IFAIL)
G05KBF
Scheduled for withdrawal at Mark 24.
Replaced by
G05KFF.
Old: G05KBF(IGEN,ISEED)
New:
IF (IGEN.EQ.0) THEN
CALL G05KFF(1,1,ISEED,LSEED,STATE,LSTATE,IFAIL)
ELSE
CALL G05KFF(2,IGEN,ISEED,LSEED,STATE,LSTATE,IFAIL)
END IF
G05KCF
Scheduled for withdrawal at Mark 24.
Replaced by
G05KGF.
Old: CALL G05KCF(IGEN,ISEED)
New:
IF (IGEN.EQ.0) THEN
CALL G05KGF(1,1,STATE,LSTATE,IFAIL)
ELSE
CALL G05KGF(2,IGEN,STATE,LSTATE,IFAIL)
END IF
G05KEF
Scheduled for withdrawal at Mark 24.
Replaced by
G05TBF.
Old:
DO 20 I = 1, N
X(I) = G05KEF(P,IGEN,ISEED,IFAIL)
20 CONTINUE
New: CALL G05TBF(N,P,STATE,X,IFAIL)
G05LAF
Scheduled for withdrawal at Mark 24.
Replaced by
G05SKF.
Old: CALL G05LAF(XMU,VAR,N,X,IGEN,ISEED,IFAIL)
New: CALL G05SKF(N,XMU,VAR,STATE,X,IFAIL)
G05LBF
Scheduled for withdrawal at Mark 24.
Replaced by
G05SNF.
Old: CALL G05LBF(DF,N,X,IGEN,ISEED,IFAIL)
New: CALL G05SNF(N,DF,STATE,X,IFAIL)
G05LCF
Scheduled for withdrawal at Mark 24.
Replaced by
G05SDF.
Old: CALL G05LCF(DF,N,X,IGEN,ISEED,IFAIL)
New: CALL G05SDF(N,DF,STATE,X,IFAIL)
G05LDF
Scheduled for withdrawal at Mark 24.
Replaced by
G05SHF.
Old: CALL G05LDF(DF1,DF2,N,X,IGEN,ISEED,IFAIL)
New: CALL G05SHF(N,DF1,DF2,STATE,X,IFAIL)
G05LEF
Scheduled for withdrawal at Mark 24.
Replaced by
G05SBF.
Old: CALL G05LEF(A,B,N,X,IGEN,ISEED,IFAIL)
New: CALL G05SBF(N,A,B,STATE,X,IFAIL)
G05LFF
Scheduled for withdrawal at Mark 24.
Replaced by
G05SJF.
Old: CALL G05LFF(A,B,N,X,IGEN,ISEED,IFAIL)
New: CALL G05SJF(N,A,B,STATE,X,IFAIL)
G05LGF
Scheduled for withdrawal at Mark 24.
Replaced by
G05SQF.
Old: CALL G05LGF(A,B,N,X,IGEN,ISEED,IFAIL)
New: CALL G05SQF(N,A,B,STATE,X,IFAIL)
G05LHF
Scheduled for withdrawal at Mark 24.
Replaced by
G05SPF.
Old: CALL G05LHF(XMIN,XMAX,XMED,N,X,IGEN,ISEED,IFAIL)
New: CALL G05SPF(N,XMIN,XMED,XMAX,STATE,X,IFAIL)
G05LJF
Scheduled for withdrawal at Mark 24.
Replaced by
G05SFF.
Old: CALL G05LJF(A,N,X,IGEN,ISEED,IFAIL)
New: CALL G05SFF(N,A,STATE,X,IFAIL)
G05LKF
Scheduled for withdrawal at Mark 24.
Replaced by
G05SMF.
Old: CALL G05LKF(XMU,VAR,N,X,IGEN,ISEED,IFAIL)
New: CALL G05SMF(N,XMU,VAR,STATE,X,IFAIL)
G05LLF
Scheduled for withdrawal at Mark 24.
Replaced by
G05SJF.
Old: CALL G05LLF(XMED,SEMIQR,N,X,IGEN,ISEED,IFAIL)
New: CALL G05SCF(N,XMED,SEMIQR,STATE,X,IFAIL)
G05LMF
Scheduled for withdrawal at Mark 24.
Replaced by
G05SSF.
Old: CALL G05LMF(A,B,N,X,IGEN,ISEED,IFAIL)
New: CALL G05SSF(N,A,B,STATE,X,IFAIL)
G05LNF
Scheduled for withdrawal at Mark 24.
Replaced by
G05SLF.
Old: CALL G05LNF(A,B,N,X,IGEN,ISEED,IFAIL)
New: CALL G05SLF(N,A,B,STATE,X,IFAIL)
G05LPF
Scheduled for withdrawal at Mark 24.
Replaced by
G05SRF.
Old: CALL G05LPF(VK,N,X,IGEN,ISEED,IFAIL)
New: CALL G05SRF(N,VK,STATE,X,IFAIL)
G05LQF
Scheduled for withdrawal at Mark 24.
Replaced by
G05SGF.
Old: CALL G05LQF(NMIX,A,WGT,N,X,IGEN,ISEED,IFAIL)
New: CALL G05SGF(N,NMIX,A,WGT,STATE,X,IFAIL)
G05LXF
Scheduled for withdrawal at Mark 24.
Replaced by
G05RYF.
Old: CALL G05LXF(MODE,DF,M,XMU,C,LDC,N,X,LDX,IGEN,ISEED,R,LR,IFAIL)
New: CALL G05RYF(MODE,N,DF,M,XMU,C,LDC,R,LR,STATE,X,LDX,IFAIL)
G05LYF
Scheduled for withdrawal at Mark 24.
Replaced by
G05RZF.
Old: G05LYF(MODE,M,XMU,C,LDC,N,X,LDX,IGEN,ISEED,R,LR,IFAIL)
New: G05RZF(MODE,N,M,XMU,C,LDC,R,LR,STATE,X,LDX,IFAIL)
G05LZF
Scheduled for withdrawal at Mark 24.
Replaced by
G05RZF.
Old: CALL G05LZF(MODE,M,XMU,C,LDC,X,IGEN,ISEED,R,LR,IFAIL)
New:
N = 1
LDX = 1
CALL G05RZF(MODE,N,M,XMU,C,LDC,R,LR,STATE,X,LDX,IFAIL)
G05MAF
Scheduled for withdrawal at Mark 24.
Replaced by
G05TLF.
Old: CALL G05MAF(A,B,N,X,IGEN,ISEED,IFAIL)
New: CALL G05TLF(N,A,B,STATE,X,IFAIL)
G05MBF
Scheduled for withdrawal at Mark 24.
Replaced by
G05TCF.
Old: CALL G05MBF(MODE,P,N,X,IGEN,ISEED,R,NR,IFAIL)
New: CALL G05TCF(MODE,N,P,R,LR,STATE,X,IFAIL)
G05MCF
Scheduled for withdrawal at Mark 24.
Replaced by
G05THF.
Old: CALL G05MCF(MODE,M,P,N,X,IGEN,ISEED,R,NR,IFAIL)
New: CALL G05THF(MODE,N,M,P,R,LR,STATE,X,IFAIL)
G05MDF
Scheduled for withdrawal at Mark 24.
Replaced by
G05TFF.
Old: CALL G05MDF(MODE,A,N,X,IGEN,ISEED,R,NR,IFAIL)
New: CALL G05TFF(MODE,N,A,R,LR,STATE,X,IFAIL)
G05MEF
Scheduled for withdrawal at Mark 24.
Replaced by
G05TKF.
Old: CALL G05MEF(M,VLAMDA,X,IGEN,ISEED,IFAIL)
New: CALL G05TKF(M,VLAMBDA,STATE,X,IFAIL)
G05MJF
Scheduled for withdrawal at Mark 24.
Replaced by
G05TAF.
Old: CALL G05MJF(MODE,M,P,N,X,IGEN,ISEED,R,NR,IFAIL)
New: CALL G05TAF(MODE,N,M,P,R,LR,STATE,X,IFAIL)
G05MKF
Scheduled for withdrawal at Mark 24.
Replaced by
G05TJF.
Old: CALL G05MKF(MODE,LAMBDA,N,X,IGEN,ISEED,R,NR,IFAIL)
New: CALL G05TJF(MODE,N,LAMBDA,R,LR,STATE,X,IFAIL)
G05MLF
Scheduled for withdrawal at Mark 24.
Replaced by
G05TEF.
Old: CALL G05MLF(MODE,NS,NP,M,N,X,IGEN,ISEED,R,NR,IFAIL)
New: CALL G05TEF(MODE,N,NS,NP,M,R,LR,STATE,X,IFAIL)
G05MRF
Scheduled for withdrawal at Mark 24.
Replaced by
G05TGF.
Old: CALL G05MRF(MODE,M,K,P,N,X,LDX,IGEN,ISEED,R,NR,IFAIL)
New: CALL G05TGF(MODE,N,M,K,P,R,LR,STATE,X,LDX,IFAIL)
G05MZF
Scheduled for withdrawal at Mark 24.
Replaced by
G05TDF.
Old: CALL G05MZF(MODE,P,NP,IP1,ITYPE,N,X,IGEN,ISEED,R,NR,IFAIL)
New: CALL G05TDF(MODE,N,P,NP,IP1,ITYPE,R,LR,STATE,X,IFAIL)
G05NAF
Scheduled for withdrawal at Mark 24.
Replaced by
G05NCF.
Old: CALL G05NAF(INDEX,N,IGEN,ISEED,IFAIL)
New: CALL G05NCF(INDEX,N,STATE,IFAIL)
G05NBF
Scheduled for withdrawal at Mark 24.
Replaced by
G05NDF.
Old: CALL G05NBF(IPOP,N,ISAMPL,M,IGEN,ISEED,IFAIL)
New: CALL G05NDF(IPOP,N,ISAMPL,M,STATE,IFAIL)
G05PAF
Scheduled for withdrawal at Mark 24.
Replaced by
G05PHF.
Old: CALL G05PAF(MODE,XMEAN,IP,PHI,IQ,THETA,AVAR,VAR,N,X,IGEN,ISEED,R,NR,IFAIL)
New: CALL G05PHF(MODE,N,XMEAN,IP,PHI,IQ,THETA,AVAR,R,LR,STATE,VAR,X,IFAIL)
G05PCF
Scheduled for withdrawal at Mark 24.
Replaced by
G05PJF.
Old: CALL G05PCF(MODE,K,XMEAN,IP,PHI,IQ,THETA,VAR,LDV,N,X,IGEN,ISEED,R,NR,IWORK,LIWORK,IFAIL)
New: CALL G05PJF(MODE,N,K,XMEAN,IP,PHI,IQ,THETA,VAR,LDV,R,LR,STATE,X,LDX,IFAIL)
G05QAF
Scheduled for withdrawal at Mark 24.
Replaced by
G05PXF.
Old: CALL G05QAF(SIDE,INIT,M,N,A,LDA,IGEN,ISEED,WK,IFAIL)
New: CALL G05PXF(SIDE,INIT,M,N,STATE,A,LDA,IFAIL)
G05QBF
Scheduled for withdrawal at Mark 24.
Replaced by
G05PYF.
Old: CALL G05QBF(N,D,C,LDC,EPS,IGEN,ISEED,WK,IFAIL)
New: CALL G05PYF(N,D,EPS,STATE,C,LDC,IFAIL)
G05QDF
Scheduled for withdrawal at Mark 24.
Replaced by
G05PZF.
Old: CALL G05QDF(MODE,NROW,NCOL,TOTR,TOTC,X,LDX,IGEN,ISEED,R,NR,IW,LIW,IFAIL)
New: CALL G05PZF(MODE,NROW,NCOL,TOTR,TOTC,R,LR,STATE,X,LDX,IFAIL)
G05RAF
Scheduled for withdrawal at Mark 24.
Replaced by
G05RDF.
Old: CALL G05RAF(MODE,M,C,LDC,N,X,LDX,IGEN,ISEED,R,LR,IFAIL)
New: CALL G05RDF(MODE,N,M,C,LDC,R,LR,STATE,X,LDX,IFAIL)
G05RBF
Scheduled for withdrawal at Mark 24.
Replaced by
G05RCF.
Old: CALL G05RBF(MODE,DF,M,C,LDC,N,X,LDX,IGEN,ISEED,R,LR,IFAIL)
New: CALL G05RCF(MODE,N,DF,M,C,LDC,R,LR,STATE,X,LDX,IFAIL)
G05YAF
Scheduled for withdrawal at Mark 23.
Replaced by
G05YLF and
G05YMF.

Faure quasi random numbers
Old: CALL G05YAF(.TRUE.,'F',ISKIP,IDIM,QUAS,IREF,IFAIL)
New: CALL G05YLF(4,IDIM,IREF,LIREF,ISKIP,IFAIL)
Old: CALL G05YAF(.FALSE.,'F',ISKIP,IDIM,QUAS,IREF,IFAIL)
New: CALL G05YMF(1,2,QUAS,LDQUAS,IREF,IFAIL)


Sobol quasi random numbers
Old: CALL G05YAF(.TRUE.,'S',ISKIP,IDIM,QUAS,IREF,IFAIL)
New: CALL G05YLF(2,IDIM,IREF,LIREF,ISKIP,IFAIL)
Old: CALL G05YAF(.FALSE.,'S',ISKIP,IDIM,QUAS,IREF,IFAIL)
New: CALL G05YMF(1,2,QUAS,LDQUAS,IREF,IFAIL)


Neiderreiter quasi random numbers
Old: CALL G05YAF(.TRUE.,'N',ISKIP,IDIM,QUAS,IREF,IFAIL)
New: CALL G05YLF(3,IDIM,IREF,LIREF,ISKIP,IFAIL)
Old: CALL G05YAF(.FALSE.,'N',ISKIP,IDIM,QUAS,IREF,IFAIL)
New: CALL G05YMF(1,2,QUAS,LDQUAS,IREF,IFAIL)

G05YBF
Scheduled for withdrawal at Mark 23.
Replaced by
G05YLF and either
G05YJF or
G05YKF.
This routine has been replaced by a suite of routines consisting of the relevant initialization routine followed by one of
two possible generator routines.

Faure quasi random numbers with Gaussian probability:
Old: CALL G05YBF(.TRUE.,'F',.FALSE.,MEAN,STD,ISKIP,IDIM,QUASI,IREF,IFAIL)
New: CALL G05YLF(4,IDIM,IREF,LIREF,ISKIP,IFAIL)
Old: CALL G05YBF(.FALSE.,'F',.FALSE.,MEAN,STD,ISKIP,IDIM,QUASI,IREF,IFAIL)
New: CALL G05YJF(MEAN,STD,N,QUASI,IREF,IFAIL)


Sobol quasi random numbers with Gaussian probability:
Old: CALL G05YBF(.TRUE.,'S',.FALSE.,MEAN,STD,ISKIP,IDIM,QUASI,IREF,IFAIL)
New: CALL G05YLF(2,IDIM,IREF,LIREF,ISKIP,IFAIL)
Old: CALL G05YBF(.FALSE.,'S',.FALSE.,MEAN,STD,ISKIP,IDIM,QUASI,IREF,IFAIL)
New: CALL G05YJF(MEAN,STD,N,QUASI,IREF,IFAIL)


Neiderreiter quasi random numbers with Gaussian probability:
Old: CALL G05YBF(.TRUE.,'N',.FALSE.,MEAN,STD,ISKIP,IDIM,QUASI,IREF,IFAIL)
New: CALL G05YLF(3,IDIM,IREF,LIREF,ISKIP,IFAIL)
Old: CALL G05YBF(.FALSE.,'N',.FALSE.,MEAN,STD,ISKIP,IDIM,QUASI,IREF,IFAIL)
New: CALL G05YJF(MEAN,STD,N,QUASI,IREF,IFAIL)


Faure quasi random numbers with log Normal probability:
Old: CALL G05YBF(.TRUE.,'F',.TRUE.,MEAN,STD,ISKIP,IDIM,QUASI,IREF,IFAIL)
New: CALL G05YLF(4,IDIM,IREF,LIREF,ISKIP,IFAIL)
Old: CALL G05YBF(.FALSE.,'F',.TRUE.,MEAN,STD,ISKIP,IDIM,QUASI,IREF,IFAIL)
New: CALL G05YKF(MEAN,STD,N,QUASI,IREF,IFAIL)


Sobol quasi random numbers with log Normal probability:
Old: CALL G05YBF(.TRUE.,'S',.TRUE.,MEAN,STD,ISKIP,IDIM,QUASI,IREF,IFAIL)
New: CALL G05YLF(2,IDIM,IREF,LIREF,ISKIP,IFAIL)
Old: CALL G05YBF(.FALSE.,'S',.TRUE.,MEAN,STD,ISKIP,IDIM,QUASI,IREF,IFAIL)
New: CALL G05YKF(MEAN,STD,N,QUASI,IREF,IFAIL)


Neiderreiter quasi random numbers with log Normal probability:
Old: CALL G05YBF(.TRUE.,'N',.TRUE.,MEAN,STD,ISKIP,IDIM,QUASI,IREF,IFAIL)
New: CALL G05YLF(3,IDIM,IREF,LIREF,ISKIP,IFAIL)
Old: CALL G05YBF(.FALSE.,'N',.TRUE.,MEAN,STD,ISKIP,IDIM,QUASI,IREF,IFAIL)
New: CALL G05YKF(MEAN,STD,N,QUASI,IREF,IFAIL)

G05YCF
Scheduled for withdrawal at Mark 24.
Replaced by
G05YLF.
Old: CALL G05YCF(IDIM,IREF,IFAIL)
New: GENID = 4
CALL G05YLF(GENID,IDIM,IREF,LIREF,ISKIP,IFAIL)
G05YDF
Scheduled for withdrawal at Mark 24.
Replaced by
G05YMF.
Old: CALL G05YDF(N,QUASI,IREF,IFAIL)
New: CALL G05YMF(N,QUAS,LDQUAS,IREF,IFAIL)
G05YEF
Scheduled for withdrawal at Mark 24.
Replaced by
G05YLF.
Old: CALL G05YEF(IDIM, IREF, ISKIP, IFAIL)
New: GENID = 2
CALL G05YLF(GENID,IDIM,IREF,LIREF,ISKIP,IFAIL)
G05YFF
Scheduled for withdrawal at Mark 24.
Replaced by
G05YMF.
Old: CALL G05YFF(N,QUASI,IREF,IFAIL)
New: CALL G05YMF(N,QUAS,LDQUAS,IREF,IFAIL)
G05YGF
Scheduled for withdrawal at Mark 24.
Replaced by
G05YLF.
Old: CALL G05YGF(IDIM,IREF,ISKIP,IFAIL)
New: GENID = 3
CALL G05YLF(GENID,IDIM,IREF,LIREF,ISKIP,IFAIL)
G05YHF
Scheduled for withdrawal at Mark 24.
Replaced by
G05YMF.
Old: CALL G05YHF(N,QUASI,IREF,IFAIL)
New: CALL G05YMF(N,RCORD,QUAS,LDQUAS,IREF,IFAIL)
G05ZAF
Withdrawn at Mark 22.
There is no replacement for this routine.
G08 – Nonparametric Statistics
G08ABF
Withdrawn at Mark 16.
Replaced by
G08AGF.
Old: CALL G08ABF(X,Y,N,W1,W2,W,N1,P,IFAIL)
New: D0 20 I = 1, N
Z(I) = X(I)  Y(I)
20 CONTINUE
XME = 0.0D0
CALL G08AGF(N,Z,XME,'Lowertail','Nozeros',W,WNOR,P,
+ N1,W1,IFAIL)
W1 is a
double precision work array of dimension
(3 × N)
. The
double precision array W2 is no longer required.
WNOR returns the normalized Wilcoxon test statistic. The
double precision array
Z, of dimension (
N), contains the difference between the paired sample observations, and by setting the
double precision variable
XME to zero the routine may be used to test whether the medians of the two matched or paired samples are equal.
G08ADF
Withdrawn at Mark 16.
Replaced by
G08AHF,
G08AJF and
G08AKF.
Old: CALL G08ADF(X,N,N1,W,U,P,IFAIL)
New: N2 = N  N1
CALL G08AHF(N1,X,N2,X(N1+1),'Lowertail',U,UNOR,P,
+ TIES,RANKS,W,IFAIL)
The observations from the two independent samples must be stored in two separate
double precision arrays, of dimensions
N1 and
N2, where
N2
=
N

N1
, rather than consecutively in one array as in
G08ADF.
UNOR returns the normalized Mann–Whitney
U
statistic. The LOGICAL parameter
TIES indicates whether ties were present in the pooled sample or not and
RANKS, a
double precision array of dimension (
N1 + N2), returns the ranks of the pooled sample.
Both
G08ADF and its replacement routine
G08AHF return approximate tail probabilities for the test statistic. To compute exact tail probabilities
G08AJF may be used if there are no ties in the pooled sample and
G08AKF may be used if there are ties in the pooled sample.
G08CAF
Withdrawn at Mark 16.
Replaced by
G08CBF.
Old: CALL G08CAF(N,X,NULL,NP,P,NEST,NTYPE,D,PROB,S,IND,IFAIL)
New: CALL G08CBF(N,X,DIST,PAR,NEST,NTYPE,D,Z,PROB,S,IFAIL)
The following table indicates how existing choices for the null distribution, indicated through the INTEGER variable NULL
in
G08CAF, may be made in
G08CBF using the character variable
DIST.

null distribution 
G08CAF – NULL

G08CBF – DIST 

uniform 
1 
'U' 

Normal 
2 
'N' 

Poisson 
3 
'P' 

exponential 
4 
'E' 
PAR is a
double precision array of dimension (2) for both the one and two parameter distributions, but only the first element of
PAR is actually referenced (used) if the chosen null distribution has only one parameter. The input parameter NP is no longer
required.
On exit
S contains the sample observations sorted into ascending order. It no longer contains the sample cumulative distribution function
but this may be computed from
S.
G13 – Time Series Analysis
G13DAF
Withdrawn at Mark 17.
Replaced by
G13DMF.
Old: CALL G13DAF(X,NXM,NX,NSM,NS,NL,ICR,C0,C,IFAIL)
New: C First transpose the data matrix X
C note NSM is used as the first dimension of the array W
D0 20 I = 1, NS
CALL F06EFF(NX,X,(1,I),1,W(I,1),NSM)
20 CONTINUE
C then if ICR = 0 in the call to G13DAF
CALL G13DMF('VCovariances',NS,NX,W,NSM,NL,WMEAN,C0,C,IFAIL)
C else if ICR = 1 in the call to G13DAF
CALL G13DMF('RCorrelations',NS,NX,W,NSM,NL,WMEAN,C0,C,IFAIL)
Note that in
G13DAF the
NS series are stored in the columns of X whereas in
G13DMF these series are stored in rows; hence it is necessary to transpose the data array.
The
double precision array
WMEAN must be of length
NS, and on output stores the means of each of the
NS series.
The diagonal elements of
C0 store the variances of the series if covariances are requested, but the standard deviations if correlations are requested.
G13DCF
Scheduled for withdrawal at Mark 24.
Replaced by
G13DDF.
Old: CALL G13DCF(K,N,IP,IQ,MEAN,PAR,NPAR,QQ,KMAX,W,PARHLD,EXACT,IPRINT,
* CGETOL,MAXCAL,ISHOW,NITER,RLOGL,V,G,CM,LDCM,WORK,LWORK,
* IW,LIW,IFAIL)
New: CALL G13DDF(K,N,IP,IQ,MEAN,PAR,NPAR,QQ,KMAX,W,PARHLD,EXACT,IPRINT,
* CGETOL,MAXCAL,ISHOW,NITER,RLOGL,V,G,CM,LDCM,IFAIL)
The workspace arguments WORK, LWORK, IW and LIW are no longer required in the call to
G13DDF.
H – Operations Research
H02BAF
Withdrawn at Mark 15.
Replaced by
H02BBF.
Old: CALL H02BAF(A,MM,N1,M,N,200,L,X,NUMIT,OPT,IFAIL)
New: C M, N and MM must be set before these declaration statements
INTEGER MAXDPT, LIWORK, LRWORK, ITMAX, MSGLVL, MAXNOD, INTFST
PARAMETER (LIWORK = (25+N+M)*MAXDPT + 5*N + M + 4)
PARAMETER (LRWORK = MAXDPT*(N+2) + 2*N*N + 13*N + 12*M)
INTEGER INTVAR(N), IWORK(LIWORK)
double precision BIGBND, TOLFES, TOLIV, ROPT
double precision RA(MM,N), RX(N), CVEC(N), BL(N+M), BU(N+M),
RWORK(LRWORK)
DO 10 J = 1, N
INTVAR(J) = 1
CVEC(J) = A(1,J)
RX(J) = 1.0D0
DO 20 I = 1, M
RA(I,J) = A(I+1,J)
20 CONTINUE
10 CONTINUE
BIGBND = 1.0e20
DO 30 I = 1, N
BL(I) = 0.0D0
BU(I) = BIGBND
30 CONTINUE
DO 40 I = N+1, N+M
BU(I) = A(IN+1,N+1)
BL(I) = BIGBND
40 CONTINUE
ITMAX = 0
MSGLVL = 0
MAXNOD = 0
INTFST = 0
TOLIV = 0.0D0
TOLFES = 0.0D0
MAXDPT = 3*N/2
IFAIL = 0
CALL H02BBF(ITMAX,MSGLVL,N,M,RA,MM,BL,BU,INTVAR,CVEC,MAXNOD,
+ INTFST,MAXDPT,TOLIV,TOLFES,BIGBND,RX,ROPT,IWORK,
+ LIWORK,RWORK,LRWORK,IFAIL)
L = 1
IF (IFAIL.EQ.0) L = 0
IF (IFAIL.EQ.4) L = 2
IF (L.EQ.0) THEN
DO 50 I = 1, N
X(I) = RX(I)
50 CONTINUE
OPT = ROPT
ENDIF
The code indicates the minimum changes necessary, but
H02BBF has additional flexibility and users may wish to take advantage of new features. It is strongly recommended that users consult
the routine document.
M01 – Sorting and Searching
M01AJF
Withdrawn at Mark 16.
Replaced by
M01CAF,
M01DAF and
M01ZAF.
Old: CALL M01AJF(A,W,IND,INDW,N,NW,IFAIL)
New: CALL M01DAF(A,1,N,'A',IND,IFAIL)
CALL M01ZAF(IND,1,N,IFAIL)
CALL M01CAF(A,1,N,'A',IFAIL)
The arrays W and INDW are no longer needed.
M01AKF
Withdrawn at Mark 16.
Replaced by
M01CAF,
M01DAF and
M01ZAF.
Old: CALL M01AKF(A,W,IND,INDW,N,NW,IFAIL)
New: CALL M01DAF(A,1,N,'D',IND,IFAIL)
CALL M01ZAF(IND,1,N,IFAIL)
CALL M01CAF(A,1,N,'D',IFAIL)
The arrays W and INDW are no longer needed.
M01APF
Withdrawn at Mark 16.
Replaced by
M01CAF.
Old: CALL M01APF(A,I,J,IFAIL)
New: CALL M01CAF(A,I,J,'D',IFAIL)
P01 – Error Trapping
P01ABF
Scheduled for withdrawal at Mark 24.
There is no replacement for this routine.