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|
*DECK SAPCA2
SUBROUTINE SAPCA2(IPSAP,IPEDIT,NREA,NISO,NMAC,NADRX,NED,NPRC,NG,
1 NL,ITRANC,IMC,NMIL,NBISO,ICAL,MAXRDA,MAXIDA,FNORM,LCRON,NISOTS,
2 NMILNR,NISFS,NISPS,NISYS,REGFLX)
*
*-----------------------------------------------------------------------
*
*Purpose:
* Recover the cross sections of an elementary calculation.
*
*Copyright:
* Copyright (C) 2007 Ecole Polytechnique de Montreal
* This library is free software; you can redistribute it and/or
* modify it under the terms of the GNU Lesser General Public
* License as published by the Free Software Foundation; either
* version 2.1 of the License, or (at your option) any later version
*
*Author(s): A. Hebert
*
*Parameters: input
* IPSAP pointer to the Saphyb.
* IPEDIT pointer to the edition object (L_EDIT signature).
* NREA number of requested reactions.
* NISO number of particularized isotopes.
* NMAC number of macros.
* NADRX total number of ADRX sets.
* NED number of additional edition cross sections.
* NPRC number of delayed neutron precursors.
* NG number of condensed energy groups.
* NL number of Legendre orders.
* ITRANC type of transport correction.
* IMC type of macro-calculation (1 for diffusion or SPN;
* 2 other method).
* NMIL number of mixtures in the Saphyb.
* NBISO number of isotopes in the condensed microlib of the edition
* object. A given isotope may appear in many mixtures.
* ICAL index of the current elementary calculation.
* MAXRDA dimension of RDATAX array.
* MAXIDA dimension of IDATAP array.
* FNORM flux normalization factor.
* LCRON flag set to .TRUE. to put kinetics data into divers directory.
*
*Parameters: output
* NISOTS number of distinct isotopes.
* NMILNR number of mixtures with delayed neutron data.
* NISFS number of particularized fissile isotopes.
* NISPS number of particularized fission products.
* NISYS number of particularized fissile isotopes, fission products
* and macros.
* REGFLX averaged flux in the complete geometry.
*
*-----------------------------------------------------------------------
*
USE GANLIB
*----
* SUBROUTINE ARGUMENTS
*----
TYPE(C_PTR) IPSAP,IPEDIT
INTEGER NREA,NISO,NMAC,NADRX,NED,NPRC,NG,NL,ITRANC,IMC,NMIL,NBISO,
1 ICAL,MAXRDA,MAXIDA,NISOTS,NMILNR,NISFS,NISPS,NISYS
REAL FNORM,REGFLX(NG)
LOGICAL LCRON
*----
* LOCAL VARIABLES
*----
PARAMETER (NREAK=20,MAXISO=800)
TYPE(C_PTR) JPEDIT,KPEDIT,IPTEMP,KPTEMP
INTEGER FGYS(2)
REAL VALDIV(3)
CHARACTER NOMREA(NREAK)*12,NOMISO(MAXISO)*8,ISOTS(MAXISO)*8,
1 DIRNAM*12,CM*2,TEXT8*8,TEXT12*12,IDVAL(3)*4,HSMG*131
LOGICAL EXIST,LSPH
DOUBLE PRECISION CONV
*----
* ALLOCATABLE ARRAYS
*----
INTEGER, ALLOCATABLE, DIMENSION(:) :: RESMAC,NISOMN,ISADRX,LENGDX,
1 LENGDP,IDATAP,IFDG,IADR,IFDG2,IADR2,IJJ1,NJJ1,IPOS,IJJ2,NJJ2,MIX,
2 ITYPE
INTEGER, ALLOCATABLE, DIMENSION(:,:) :: ISOMIL,ISONAM
INTEGER, ALLOCATABLE, DIMENSION(:,:,:) :: ADRX
REAL, ALLOCATABLE, DIMENSION(:) :: RDATAX,FLUX,OVERV,WORKD,WORK1,
1 WORK2,VOL,DEN,DENISO,CONCES,DECAYC
REAL, ALLOCATABLE, DIMENSION(:,:) :: DNUSIG,DCHI,DATA1,DATA2,
1 DATA4,SPH
REAL, ALLOCATABLE, DIMENSION(:,:,:) :: DATA3
TYPE(C_PTR), ALLOCATABLE, DIMENSION(:) :: IPISO
*----
* SCRATCH STORAGE ALLOCATION
*----
ALLOCATE(RESMAC(NMIL),ADRX(NREA+2,NISO+NMAC,NADRX+NMIL),
1 ISOMIL(NISO+NMAC,NMIL),NISOMN(NMIL),ISADRX(NMIL),LENGDX(NMIL),
2 LENGDP(NMIL),IDATAP(MAXIDA),IFDG(NG),IADR(NG+1),IFDG2(NG),
3 IADR2(NG+1),IJJ1(NMIL),NJJ1(NMIL),IPOS(NMIL),IJJ2(NG),NJJ2(NG),
4 ISONAM(3,NBISO),MIX(NBISO),ITYPE(NBISO))
ALLOCATE(RDATAX(MAXRDA),FLUX(NG),OVERV(NG),DNUSIG(NG,NPRC+1),
1 DCHI(NG,NPRC),WORKD(NPRC),WORK1(NG*NMIL+1),WORK2(NG),VOL(NMIL),
2 DATA1(NG,NREA),DATA2(NG,NL),DATA3(NG,NG,NL),DATA4(NG,NG),
3 DEN(NBISO),DENISO(NISO),CONCES(NBISO),DECAYC(NBISO))
*
CONV=1.0D6 ! convert MeV to eV in H-FACTOR
IF(NREA.GT.NREAK) CALL XABORT('SAPCA2: NOMREA OVERFLOW.')
*----
* RECOVER INFORMATION FROM THE 'contenu' DIRECTORY.
*----
CALL LCMSIX(IPSAP,'contenu',1)
IF(NREA.GT.0) CALL LCMGTC(IPSAP,'NOMREA',12,NREA,NOMREA)
IF(NISO.GT.0) CALL LCMGTC(IPSAP,'NOMISO',8,NISO,NOMISO)
CALL LCMGET(IPSAP,'RESMAC',RESMAC)
CALL LCMSIX(IPSAP,' ',2)
*----
* RECOVER INFORMATION FROM THE 'geom' DIRECTORY.
*----
CALL LCMSIX(IPSAP,'geom',1)
CALL LCMGET(IPSAP,'XVOLMT',VOL)
CALL LCMSIX(IPSAP,' ',2)
*----
* RECOVER INFORMATION FROM THE 'adresses' DIRECTORY.
*----
CALL LCMSIX(IPSAP,'adresses',1)
CALL LCMLEN(IPSAP,'ADRX',ILONG,ITYLCM)
IF(ILONG.GT.0) CALL LCMGET(IPSAP,'ADRX',ADRX)
CALL LCMLEN(IPSAP,'NISOMN',ILONG,ITYLCM)
IF(ILONG.GT.0) THEN
CALL LCMGET(IPSAP,'NISOMN',NISOMN)
ELSE
NISOMN(:NMIL)=0
ENDIF
CALL LCMSIX(IPSAP,' ',2)
*----
* SAVE INFORMATION TO THE 'constphysiq' DIRECTORY.
*----
IF(ICAL.EQ.1) THEN
CALL LCMLEN(IPEDIT,'ENERGY',ILONG,ITYLCM)
IF(ILONG.EQ.0) THEN
CALL LCMSIX(IPEDIT,'MACROLIB',1)
CALL LCMLEN(IPEDIT,'ENERGY',ILONG,ITYLCM)
IF(ILONG.NE.NG+1) CALL XABORT('SAPCA2: BAD VALUE OF NG(1).')
CALL LCMGET(IPEDIT,'ENERGY',WORK1)
CALL LCMSIX(IPEDIT,' ',2)
ELSE
IF(ILONG.NE.NG+1) CALL XABORT('SAPCA2: BAD VALUE OF NG(2).')
CALL LCMGET(IPEDIT,'ENERGY',WORK1)
ENDIF
CALL LCMSIX(IPSAP,'constphysiq',1)
DO 10 I=1,NG+1
WORK1(I)=WORK1(I)*1.0E-6
10 CONTINUE
CALL LCMPUT(IPSAP,'ENRGS',NG+1,2,WORK1)
FGYS(1)=1
FGYS(2)=NG+1
CALL LCMPUT(IPSAP,'FGYS',2,1,FGYS)
CALL LCMSIX(IPSAP,' ',2)
ENDIF
*----
* MOVE TO THE 'calc' DIRECTORY.
*----
WRITE(DIRNAM,'(''calc'',I8)') ICAL
CALL LCMSIX(IPSAP,DIRNAM,1)
*----
* FIND THE NUMBER AND NAMES OF THE ISOTOPES IN THE OUTPUT TABLES.
*----
IF(NBISO.GT.0) THEN
CALL LCMGET(IPEDIT,'ISOTOPESUSED',ISONAM)
CALL LCMGET(IPEDIT,'ISOTOPESMIX',MIX)
CALL LCMGET(IPEDIT,'ISOTOPESDENS',DEN)
CALL LCMGET(IPEDIT,'ISOTOPESTYPE',ITYPE)
ENDIF
NISOTS=0
DO 30 IBISO=1,NBISO
IF(MIX(IBISO).EQ.0) GO TO 30
WRITE(TEXT12,'(3A4)') (ISONAM(I0,IBISO),I0=1,3)
DO 20 ISO=1,NISOTS
IF(TEXT12(:8).EQ.ISOTS(ISO)) GO TO 30
20 CONTINUE
NISOTS=NISOTS+1
IF(NISOTS.GT.MAXISO) CALL XABORT('SAPCA2: ISOTS OVERFLOW.')
IF(NISOTS.GT.NBISO) CALL XABORT('SAPCA2: CONCES OVERFLOW.')
ISOTS(NISOTS)=TEXT12(:8)
30 CONTINUE
*----
* RECOVER INVERSE OF SPH EQUIVALENCE FACTORS.
*----
CALL LCMSIX(IPEDIT,'MACROLIB',1)
JPEDIT=LCMGID(IPEDIT,'GROUP')
LSPH=.FALSE.
ALLOCATE(SPH(NMIL,NG))
DO 35 IGR=1,NG
KPEDIT=LCMGIL(JPEDIT,IGR)
CALL LCMLEN(KPEDIT,'NSPH',ILONG,ITYLCM)
IF(ILONG.GT.0) THEN
LSPH=.TRUE.
CALL LCMGET(KPEDIT,'NSPH',WORK1)
DO 33 IMIL=1,NMIL
SPH(IMIL,IGR)=1.0/WORK1(IMIL)
33 CONTINUE
ELSE
DO 34 IMIL=1,NMIL
SPH(IMIL,IGR)=1.0
34 CONTINUE
ENDIF
35 CONTINUE
CALL LCMSIX(IPEDIT,' ',2)
*----
* CREATE A SPH-UNCORRECTED MICROLIB.
*----
CALL LCMOP(IPTEMP,'*TEMPORARY*',0,1,0)
ALLOCATE(IPISO(NBISO))
CALL LCMEQU(IPEDIT,IPTEMP)
IF(LSPH) THEN
IF(IMC.EQ.0) CALL XABORT('SAPCA2: UNDEFINED TYPE OF SPH.')
NW=1 ! NTOT1 cross section present
NALBP=0 ! no albedo correction
CALL SPHCMI(IPTEMP,0,IMC,NMIL,NBISO,NG,NL,NW,NED,NPRC,NALBP,SPH)
ENDIF
DEALLOCATE(SPH)
*----
* LOOP OVER SAPHYB MIXTURES.
*----
NMILNR=0
REGFLX(1:NG)=0.0
VOLTOT=0.0
DO 500 IMIL=1,NMIL
VOLTOT=VOLTOT+VOL(IMIL)
IOR=0
IOI=0
IIS=0
NISMAX=NMAC
ISOMIL(:NISO+NMAC,IMIL)=0
IADR(1)=1
*----
* PROCESS MACROS.
*----
CALL LCMSIX(IPTEMP,'MACROLIB',1)
JPEDIT=LCMGID(IPTEMP,'GROUP')
NVDIV=0
CALL LCMLEN(IPTEMP,'K-EFFECTIVE',ILONG,ITYLCM)
IF(ILONG.EQ.1) THEN
CALL LCMGET(IPTEMP,'K-EFFECTIVE',FLOTT)
NVDIV=NVDIV+1
IDVAL(NVDIV)='KEFF'
VALDIV(NVDIV)=FLOTT
ENDIF
CALL LCMLEN(IPTEMP,'K-INFINITY',ILONG,ITYLCM)
IF(ILONG.EQ.1) THEN
CALL LCMGET(IPTEMP,'K-INFINITY',FLOTT)
NVDIV=NVDIV+1
IDVAL(NVDIV)='KINF'
VALDIV(NVDIV)=FLOTT
ENDIF
CALL LCMLEN(IPTEMP,'B2 B1HOM',ILONG,ITYLCM)
IF(ILONG.EQ.1) THEN
CALL LCMGET(IPTEMP,'B2 B1HOM',B2)
IF(B2.EQ.0.0) B2=1.0E-10
NVDIV=NVDIV+1
IDVAL(NVDIV)='B2 '
VALDIV(NVDIV)=B2
ELSE
B2=0.0
ENDIF
DATA2(:NG,:NL)=0.0
DATA3(:NG,:NG,:NL)=0.0
*
DO 90 IGR=1,NG
KPEDIT=LCMGIL(JPEDIT,IGR)
*----
* RECOVER THE NEUTRON FLUX.
*----
CALL LCMGET(KPEDIT,'FLUX-INTG',WORK1)
FLUX(IGR)=WORK1(IMIL)*FNORM*1.0E13
REGFLX(IGR)=REGFLX(IGR)+FLUX(IGR)
*----
* RECOVER DELAYED NEUTRON INFORMATION.
*----
CALL LCMLEN(KPEDIT,'NUSIGF',ILONG,ITYLCM)
IF((NPRC.GT.0).AND.(ILONG.NE.0)) THEN
CALL LCMGET(KPEDIT,'NUSIGF',WORK1)
DNUSIG(IGR,NPRC+1)=WORK1(IMIL)
CALL LCMGET(KPEDIT,'OVERV',WORK1)
OVERV(IGR)=WORK1(IMIL)
DO 40 IPRC=1,NPRC
WRITE(TEXT12,'(6HNUSIGF,I2.2)') IPRC
CALL LCMGET(KPEDIT,TEXT12,WORK1)
DNUSIG(IGR,IPRC)=WORK1(IMIL)
WRITE(TEXT12,'(3HCHI,I2.2)') IPRC
CALL LCMGET(KPEDIT,TEXT12,WORK1)
DCHI(IGR,IPRC)=WORK1(IMIL)
40 CONTINUE
ELSE
DNUSIG(IGR,:NPRC+1)=0.0
ENDIF
*
DO 80 IREA=1,NREA
DATA1(IGR,IREA)=0.0
IF(NOMREA(IREA).EQ.'TOTALE') THEN
CALL LCMGET(KPEDIT,'NTOT0',WORK1)
DATA1(IGR,IREA)=WORK1(IMIL)
ELSE IF(NOMREA(IREA).EQ.'TOTALE P1') THEN
CALL LCMGET(KPEDIT,'NTOT1',WORK1)
DATA1(IGR,IREA)=WORK1(IMIL)
ELSE IF(NOMREA(IREA).EQ.'ABSORPTION') THEN
CALL LCMGET(KPEDIT,'NTOT0',WORK1)
DATA1(IGR,IREA)=WORK1(IMIL)
CALL LCMLEN(KPEDIT,'SIGS00',ILONG,ITYLCM)
IF(ILONG.GT.0) THEN
CALL LCMGET(KPEDIT,'SIGS00',WORK1)
DATA1(IGR,IREA)=DATA1(IGR,IREA)-WORK1(IMIL)
ENDIF
CALL LCMLEN(KPEDIT,'N2N',ILONG,ITYLCM)
IF(ILONG.GT.0) THEN
CALL LCMGET(KPEDIT,'N2N',WORK1)
DATA1(IGR,IREA)=DATA1(IGR,IREA)+WORK1(IMIL)
ENDIF
CALL LCMLEN(KPEDIT,'N3N',ILONG,ITYLCM)
IF(ILONG.GT.0) THEN
CALL LCMGET(KPEDIT,'N3N',WORK1)
DATA1(IGR,IREA)=DATA1(IGR,IREA)+2.0*WORK1(IMIL)
ENDIF
ELSE IF(NOMREA(IREA).EQ.'EXCESS') THEN
CALL LCMLEN(KPEDIT,'N2N',ILONG,ITYLCM)
IF(ILONG.GT.0) THEN
CALL LCMGET(KPEDIT,'N2N',WORK1)
DATA1(IGR,IREA)=WORK1(IMIL)
ENDIF
CALL LCMLEN(KPEDIT,'N3N',ILONG,ITYLCM)
IF(ILONG.GT.0) THEN
CALL LCMGET(KPEDIT,'N3N',WORK1)
DATA1(IGR,IREA)=DATA1(IGR,IREA)+2.0*WORK1(IMIL)
ENDIF
ELSE IF(NOMREA(IREA).EQ.'FISSION') THEN
CALL LCMLEN(KPEDIT,'NFTOT',ILONG,ITYLCM)
IF(ILONG.GT.0) THEN
CALL LCMGET(KPEDIT,'NFTOT',WORK1)
DATA1(IGR,IREA)=WORK1(IMIL)
ENDIF
ELSE IF(NOMREA(IREA).EQ.'SPECTRE') THEN
CALL LCMLEN(KPEDIT,'CHI',ILONG,ITYLCM)
IF(ILONG.GT.0) THEN
CALL LCMGET(KPEDIT,'CHI',WORK1)
DATA1(IGR,IREA)=WORK1(IMIL)
ENDIF
ELSE IF(NOMREA(IREA).EQ.'NU*FISSION') THEN
CALL LCMLEN(KPEDIT,'NUSIGF',ILONG,ITYLCM)
IF(ILONG.GT.0) THEN
CALL LCMGET(KPEDIT,'NUSIGF',WORK1)
DATA1(IGR,IREA)=WORK1(IMIL)
ENDIF
ELSE IF(NOMREA(IREA).EQ.'ENERGIE') THEN
CALL LCMLEN(KPEDIT,'H-FACTOR',ILONG,ITYLCM)
IF(ILONG.GT.0) THEN
CALL LCMGET(KPEDIT,'H-FACTOR',WORK1)
DATA1(IGR,IREA)=WORK1(IMIL)/REAL(CONV)
ENDIF
ELSE IF(NOMREA(IREA).EQ.'FUITES') THEN
CALL LCMLEN(KPEDIT,'DIFF',ILONG,ITYLCM)
IF(ILONG.GT.0) THEN
IF(B2.EQ.0.0) B2=1.0E-10
CALL LCMGET(KPEDIT,'DIFF',WORK1)
DATA1(IGR,IREA)=WORK1(IMIL)*B2
ENDIF
ELSE IF(NOMREA(IREA).EQ.'STRD') THEN
CALL LCMLEN(KPEDIT,'DIFF',ILONG,ITYLCM)
IF(ILONG.GT.0) THEN
CALL LCMGET(KPEDIT,'DIFF',WORK1)
DATA1(IGR,IREA)=1.0/(3.0*WORK1(IMIL))
ENDIF
ELSE IF(NOMREA(IREA).EQ.'SELF') THEN
CALL LCMGET(KPEDIT,'SIGW00',WORK1)
DATA1(IGR,IREA)=WORK1(IMIL)
ELSE IF(NOMREA(IREA).EQ.'DIFFUSION') THEN
DO 50 IL=1,NL
WRITE (CM,'(I2.2)') IL-1
CALL LCMGET(KPEDIT,'SIGS'//CM,WORK1)
DATA2(IGR,IL)=WORK1(IMIL)
50 CONTINUE
CALL LCMLEN(KPEDIT,'N2N',ILONG,ITYLCM)
IF(ILONG.GT.0) THEN
CALL LCMGET(KPEDIT,'N2N',WORK1)
DATA2(IGR,1)=DATA2(IGR,1)-WORK1(IMIL)
ENDIF
CALL LCMLEN(KPEDIT,'N3N',ILONG,ITYLCM)
IF(ILONG.GT.0) THEN
CALL LCMGET(KPEDIT,'N3N',WORK1)
DATA2(IGR,1)=DATA2(IGR,1)-2.0*WORK1(IMIL)
ENDIF
ELSE IF(NOMREA(IREA).EQ.'TRANSP-CORR') THEN
IF((ITRANC.EQ.1).AND.(NL.GE.2)) THEN
CALL LCMGET(KPEDIT,'SIGS01',WORK1)
DATA1(IGR,IREA)=WORK1(IMIL)
ELSE IF(ITRANC.EQ.2) THEN
CALL LCMGET(KPEDIT,'TRANC',WORK1)
DATA1(IGR,IREA)=WORK1(IMIL)
ENDIF
ELSE IF(NOMREA(IREA).EQ.'PROFIL') THEN
IFDG(IGR)=NG+1
ILDG=0
DO 60 IL=1,NL
WRITE (CM,'(I2.2)') IL-1
CALL LCMGET(KPEDIT,'IJJS'//CM,IJJ1)
CALL LCMGET(KPEDIT,'NJJS'//CM,NJJ1)
IFDG(IGR)=MIN(IFDG(IGR),IJJ1(IMIL)-NJJ1(IMIL)+1)
ILDG=MAX(ILDG,IJJ1(IMIL))
60 CONTINUE
IADR(IGR+1)=IADR(IGR)+(ILDG-IFDG(IGR)+1)
ELSE IF(NOMREA(IREA).EQ.'TRANSFERT') THEN
DO 75 IL=1,NL
WRITE (CM,'(I2.2)') IL-1
CALL LCMGET(KPEDIT,'IJJS'//CM,IJJ1)
CALL LCMGET(KPEDIT,'NJJS'//CM,NJJ1)
CALL LCMGET(KPEDIT,'IPOS'//CM,IPOS)
CALL LCMGET(KPEDIT,'SCAT'//CM,WORK1)
IPO=IPOS(IMIL)
J2=IJJ1(IMIL)
J1=IJJ1(IMIL)-NJJ1(IMIL)+1
DO 70 JGR=J2,J1,-1
DATA3(JGR,IGR,IL)=WORK1(IPO)*REAL(2*IL-1)
IPO=IPO+1
70 CONTINUE
75 CONTINUE
ELSE
CALL LCMLEN(KPEDIT,NOMREA(IREA),ILONG,ITYLCM)
IF(ILONG.GT.0) THEN
CALL LCMGET(KPEDIT,NOMREA(IREA),WORK1)
DATA1(IGR,IREA)=WORK1(IMIL)
ENDIF
ENDIF
80 CONTINUE
90 CONTINUE
CALL LCMSIX(IPTEMP,' ',2)
*----
* FIND ISOTOPE POINTERS IN INPUT MICROLIB
*----
CALL LIBIPS(IPTEMP,NBISO,IPISO)
*----
* PROCESS PARTICULARIZED ISOTOPES
*----
DO 105 IISO=1,NISO
DO 100 IREA=1,NREA+2
ADRX(IREA,IISO,NADRX+1)=0
100 CONTINUE
105 CONTINUE
CONCES(:NISOTS)=0.0
DECAYC(:NISOTS)=0.0
DO 250 IBISO=1,NBISO
IF(MIX(IBISO).EQ.IMIL) THEN
WRITE(TEXT12,'(3A4)') (ISONAM(I0,IBISO),I0=1,3)
DO 110 ISO=1,NISO
IISO=ISO
IF(NOMISO(ISO).EQ.TEXT12(:8)) GO TO 120
110 CONTINUE
GO TO 250
120 KPTEMP=IPISO(IBISO) ! set IBISO-th isotope
IF(.NOT.C_ASSOCIATED(KPTEMP)) THEN
WRITE(HSMG,'(17HSAPCA2: ISOTOPE '',A12,7H'' (ISO=,I8,3H) I,
1 32HS NOT AVAILABLE IN THE MICROLIB.)') TEXT12,IBISO
CALL XABORT(HSMG)
ENDIF
IISOTS=0
DO 130 ISO=1,NISOTS
IISOTS=ISO
IF(ISOTS(ISO).EQ.TEXT12(:8)) GO TO 135
130 CONTINUE
CALL XABORT('SAPCA2: UNABLE TO FIND ISOTOPE '//TEXT12//'.')
135 CALL LCMLEN(KPTEMP,'DECAY',ILONG,ITYLCM)
IF(ILONG.EQ.1) THEN
CALL LCMGET(KPTEMP,'DECAY',DECAYC(IISOTS))
ELSE
DECAYC(IISOTS)=0.0
ENDIF
CONCES(IISOTS)=DEN(IBISO)
DENISO(IISO)=DEN(IBISO)
NISMAX=NISMAX+1
IIS=IIS+1
ISOMIL(IIS,IMIL)=IISO
DO 240 IREA=1,NREA
WORK2(:NG)=0.0
IF(NOMREA(IREA).EQ.'TOTALE') THEN
CALL LCMGET(KPTEMP,'NTOT0',WORK2)
ELSE IF(NOMREA(IREA).EQ.'TOTALE P1') THEN
CALL LCMGET(KPTEMP,'NTOT1',WORK2)
ELSE IF(NOMREA(IREA).EQ.'ABSORPTION') THEN
CALL LCMGET(KPTEMP,'NTOT0',WORK2)
CALL LCMLEN(KPTEMP,'SIGS00',ILONG,ITYLCM)
IF(ILONG.GT.0) THEN
CALL LCMGET(KPTEMP,'SIGS00',WORK1)
DO 140 IGR=1,NG
WORK2(IGR)=WORK2(IGR)-WORK1(IGR)
140 CONTINUE
ENDIF
CALL LCMLEN(KPTEMP,'N2N',ILONG,ITYLCM)
IF(ILONG.GT.0) THEN
CALL LCMGET(KPTEMP,'N2N',WORK1)
DO 150 IGR=1,NG
WORK2(IGR)=WORK2(IGR)+WORK1(IGR)
150 CONTINUE
ENDIF
CALL LCMLEN(KPTEMP,'N3N',ILONG,ITYLCM)
IF(ILONG.GT.0) THEN
CALL LCMGET(KPTEMP,'N3N',WORK1)
DO 151 IGR=1,NG
WORK2(IGR)=WORK2(IGR)+2.0*WORK1(IGR)
151 CONTINUE
ENDIF
ELSE IF(NOMREA(IREA).EQ.'EXCESS') THEN
CALL LCMLEN(KPTEMP,'N2N',ILONG,ITYLCM)
IF(ILONG.GT.0) CALL LCMGET(KPTEMP,'N2N',WORK2)
CALL LCMLEN(KPTEMP,'N3N',ILONG,ITYLCM)
IF(ILONG.GT.0) THEN
CALL LCMGET(KPTEMP,'N3N',WORK1)
DO 152 IGR=1,NG
WORK2(IGR)=WORK2(IGR)+2.0*WORK1(IGR)
152 CONTINUE
ENDIF
ELSE IF(NOMREA(IREA).EQ.'FISSION') THEN
CALL LCMLEN(KPTEMP,'NFTOT',ILONG,ITYLCM)
IF(ILONG.GT.0) CALL LCMGET(KPTEMP,'NFTOT',WORK2)
ELSE IF(NOMREA(IREA).EQ.'SPECTRE') THEN
CALL LCMLEN(KPTEMP,'CHI',ILONG,ITYLCM)
IF(ILONG.GT.0) CALL LCMGET(KPTEMP,'CHI',WORK2)
ELSE IF(NOMREA(IREA).EQ.'NU*FISSION') THEN
CALL LCMLEN(KPTEMP,'NUSIGF',ILONG,ITYLCM)
IF(ILONG.GT.0) CALL LCMGET(KPTEMP,'NUSIGF',WORK2)
ELSE IF(NOMREA(IREA).EQ.'ENERGIE') THEN
CALL LCMLEN(KPTEMP,'MEVF',ILONG,ITYLCM)
IF(ILONG.GT.0) THEN
CALL LCMGET(KPTEMP,'NFTOT',WORK2)
CALL LCMGET(KPTEMP,'MEVF',FLOTT)
DO 155 IGR=1,NG
WORK2(IGR)=WORK2(IGR)*FLOTT
155 CONTINUE
ENDIF
CALL LCMLEN(KPTEMP,'MEVG',ILONG,ITYLCM)
IF(ILONG.GT.0) THEN
CALL LCMGET(KPTEMP,'NG',WORK1)
CALL LCMGET(KPTEMP,'MEVG',FLOTT)
DO 160 IGR=1,NG
WORK2(IGR)=WORK2(IGR)+WORK1(IGR)*FLOTT
160 CONTINUE
ENDIF
ELSE IF(NOMREA(IREA).EQ.'ENERGIE F.') THEN
CALL LCMLEN(KPTEMP,'MEVF',ILONG,ITYLCM)
IF(ILONG.GT.0) THEN
CALL LCMGET(KPTEMP,'NFTOT',WORK2)
CALL LCMGET(KPTEMP,'MEVF',FLOTT)
DO 165 IGR=1,NG
WORK2(IGR)=WORK2(IGR)*FLOTT
165 CONTINUE
ENDIF
ELSE IF(NOMREA(IREA).EQ.'ENERGIE G.') THEN
CALL LCMLEN(KPTEMP,'MEVG',ILONG,ITYLCM)
IF(ILONG.GT.0) THEN
CALL LCMGET(KPTEMP,'NG',WORK2)
CALL LCMGET(KPTEMP,'MEVG',FLOTT)
DO 170 IGR=1,NG
WORK2(IGR)=WORK2(IGR)*FLOTT
170 CONTINUE
ENDIF
ELSE IF(NOMREA(IREA).EQ.'STRD') THEN
CALL LCMLEN(KPTEMP,'STRD',ILONG,ITYLCM)
IF(ILONG.GT.0) CALL LCMGET(KPTEMP,'STRD',WORK2)
ELSE IF(NOMREA(IREA).EQ.'SELF') THEN
IMPX=0
CALL XDRLGS(KPTEMP,-1,IMPX,0,0,1,NG,WORK2,DATA4,ITYPRO)
DO 175 IGR=1,NG
WORK2(IGR)=DATA4(IGR,IGR)
175 CONTINUE
ELSE IF(NOMREA(IREA).EQ.'DIFFUSION') THEN
ADRX(IREA,IISO,NADRX+1)=IOR+1
ADRX(NREA+1,IISO,NADRX+1)=NL
IOR=IOR+NG*NL
IF(IOR.GT.MAXRDA) CALL XABORT('SAPCA2: RDATAX OVERFLOW(1).')
DO 181 IL=1,NL
WRITE (CM,'(I2.2)') IL-1
CALL LCMLEN(KPTEMP,'SIGS'//CM,ILONG,ITYLCM)
IF(ILONG.GT.0) THEN
CALL LCMGET(KPTEMP,'SIGS'//CM,WORK2)
ELSE
WORK2(:NG)=0.0
ENDIF
CALL LCMLEN(KPTEMP,'N2N',ILONG,ITYLCM)
IF((IL.EQ.1).AND.(ILONG.GT.0)) THEN
CALL LCMGET(KPTEMP,'N2N',WORK1)
DO 176 IGR=1,NG
WORK2(IGR)=WORK2(IGR)-WORK1(IGR)
176 CONTINUE
ENDIF
CALL LCMLEN(KPTEMP,'N3N',ILONG,ITYLCM)
IF((IL.EQ.1).AND.(ILONG.GT.0)) THEN
CALL LCMGET(KPTEMP,'N3N',WORK1)
DO 177 IGR=1,NG
WORK2(IGR)=WORK2(IGR)-2.0*WORK1(IGR)
177 CONTINUE
ENDIF
DO 180 IGR=1,NG
RDATAX(ADRX(IREA,IISO,NADRX+1)+(IL-1)*NG+IGR-1)=WORK2(IGR)
180 CONTINUE
181 CONTINUE
GO TO 240
ELSE IF(NOMREA(IREA).EQ.'TRANSP-CORR') THEN
IF((ITRANC.EQ.1).AND.(NL.GE.2)) THEN
CALL LCMGET(KPTEMP,'SIGS01',WORK2)
ELSE IF(ITRANC.EQ.2) THEN
CALL LCMGET(KPTEMP,'TRANC',WORK2)
ENDIF
ELSE IF(NOMREA(IREA).EQ.'PROFIL') THEN
DO 185 IGR=1,NG
IFDG2(IGR)=NG+1
IADR2(IGR+1)=0
185 CONTINUE
DO 190 IL=1,NL
WRITE (CM,'(I2.2)') IL-1
CALL LCMLEN(KPTEMP,'IJJS'//CM,ILONG,ITYLCM)
IF(ILONG.EQ.0) GO TO 190
CALL LCMGET(KPTEMP,'IJJS'//CM,IJJ2)
CALL LCMGET(KPTEMP,'NJJS'//CM,NJJ2)
DO 186 IGR=1,NG
IFDG2(IGR)=MIN(IFDG2(IGR),IJJ2(IGR)-NJJ2(IGR)+1)
IADR2(IGR+1)=MAX(IADR2(IGR+1),IJJ2(IGR))
186 CONTINUE
190 CONTINUE
IADR2(1)=1
DO 195 IGR=1,NG
IADR2(IGR+1)=IADR2(IGR)+(IADR2(IGR+1)-IFDG2(IGR)+1)
195 CONTINUE
ADRX(IREA,IISO,NADRX+1)=IOI+1
ADRX(NREA+2,IISO,NADRX+1)=NL
IOI=IOI+2*NG+7
IF(IOI.GT.MAXIDA) CALL XABORT('SAPCA2: IDATAP OVERFLOW(1).')
IDATAP(ADRX(IREA,IISO,NADRX+1))=0
IDATAP(ADRX(IREA,IISO,NADRX+1)+1)=0
IDATAP(ADRX(IREA,IISO,NADRX+1)+2)=0
IDATAP(ADRX(IREA,IISO,NADRX+1)+3)=0
IDATAP(ADRX(IREA,IISO,NADRX+1)+4)=1
IDATAP(ADRX(IREA,IISO,NADRX+1)+5)=NG
DO 200 IGR=1,NG
IDATAP(ADRX(IREA,IISO,NADRX+1)+5+IGR)=IFDG2(IGR)
IDATAP(ADRX(IREA,IISO,NADRX+1)+5+NG+IGR)=IADR2(IGR)
200 CONTINUE
IDATAP(ADRX(IREA,IISO,NADRX+1)+6+2*NG)=IADR2(NG+1)
GO TO 240
ELSE IF(NOMREA(IREA).EQ.'TRANSFERT') THEN
IF(IOI.EQ.0) CALL XABORT('SAPCA2: MUST FIRST DEFINE PROF.')
ADRX(IREA,IISO,NADRX+1)=IOR+1
IOR=IOR+(IADR2(NG+1)-1)*NL
IF(IOR.GT.MAXRDA) CALL XABORT('SAPCA2: RDATAX OVERFLOW(2).')
JOFS=0
DO 212 IL=1,NL
IMPX=0
CALL XDRLGS(KPTEMP,-1,IMPX,IL-1,IL-1,1,NG,WORK2,DATA4,
1 ITYPRO)
ZIL=REAL(2*IL-1)
DO 211 IGR=1,NG
DO 210 JGR=IFDG2(IGR),IFDG2(IGR)+(IADR2(IGR+1)-IADR2(IGR))-1
JOFS=JOFS+1
RDATAX(ADRX(IREA,IISO,NADRX+1)+JOFS-1)=DATA4(IGR,JGR)*ZIL
210 CONTINUE
211 CONTINUE
212 CONTINUE
GO TO 240
ELSE
CALL LCMLEN(KPTEMP,NOMREA(IREA),ILONG,ITYLCM)
IF(ILONG.GT.0) CALL LCMGET(KPTEMP,NOMREA(IREA),WORK2)
ENDIF
*
EXIST=.FALSE.
DO 220 IGR=1,NG
EXIST=EXIST.OR.(WORK2(IGR).NE.0.0)
220 CONTINUE
IF(EXIST) THEN
ADRX(IREA,IISO,NADRX+1)=IOR+1
IOR=IOR+NG
IF(IOR.GT.MAXRDA) CALL XABORT('SAPCA2: RDATAX OVERFLOW(3).')
DO 230 IGR=1,NG
RDATAX(ADRX(IREA,IISO,NADRX+1)+IGR-1)=WORK2(IGR)
230 CONTINUE
ELSE
ADRX(IREA,IISO,NADRX+1)=0
ENDIF
240 CONTINUE
ENDIF
250 CONTINUE
*----
* STORE MACROSCOPIC CROSS SECTIONS IN RDATAX.
*----
DO 260 IMAC=1,NMAC
ADRX(NREA+1,NISO+IMAC,NADRX+1)=0
ADRX(NREA+2,NISO+IMAC,NADRX+1)=0
260 CONTINUE
DO 340 IREA=1,NREA
IF(NOMREA(IREA).EQ.'DIFFUSION') THEN
DO 272 IMAC=1,NMAC
ADRX(IREA,NISO+IMAC,NADRX+1)=IOR+1
ADRX(NREA+1,NISO+IMAC,NADRX+1)=NL
IOR=IOR+NG*NL
IF(IOR.GT.MAXRDA) CALL XABORT('SAPCA2: RDATAX OVERFLOW(4).')
JOFS=0
DO 271 IL=1,NL
DO 270 IGR=1,NG
JOFS=JOFS+1
RDATAX(ADRX(IREA,NISO+IMAC,NADRX+1)+JOFS-1)=DATA2(IGR,IL)
270 CONTINUE
271 CONTINUE
272 CONTINUE
ELSE IF(NOMREA(IREA).EQ.'PROFIL') THEN
DO 290 IMAC=1,NMAC
ADRX(IREA,NISO+IMAC,NADRX+1)=IOI+1
ADRX(NREA+2,NISO+IMAC,NADRX+1)=NL
IOI=IOI+2*NG+7
IF(IOI.GT.MAXIDA) CALL XABORT('SAPCA2: IDATAP OVERFLOW(2).')
IDATAP(ADRX(IREA,NISO+IMAC,NADRX+1))=0
IDATAP(ADRX(IREA,NISO+IMAC,NADRX+1)+1)=0
IDATAP(ADRX(IREA,NISO+IMAC,NADRX+1)+2)=0
IDATAP(ADRX(IREA,NISO+IMAC,NADRX+1)+3)=0
IDATAP(ADRX(IREA,NISO+IMAC,NADRX+1)+4)=1
IDATAP(ADRX(IREA,NISO+IMAC,NADRX+1)+5)=NG
DO 280 IGR=1,NG
IDATAP(ADRX(IREA,NISO+IMAC,NADRX+1)+5+IGR)=IFDG(IGR)
IDATAP(ADRX(IREA,NISO+IMAC,NADRX+1)+5+NG+IGR)=IADR(IGR)
280 CONTINUE
IDATAP(ADRX(IREA,NISO+IMAC,NADRX+1)+6+2*NG)=IADR(NG+1)
290 CONTINUE
ELSE IF(NOMREA(IREA).EQ.'TRANSFERT') THEN
IF(IOI.EQ.0) CALL XABORT('SAPCA2: MUST FIRST DEFINE PROF.')
DO 303 IMAC=1,NMAC
ADRX(IREA,NISO+IMAC,NADRX+1)=IOR+1
IOR=IOR+(IADR(NG+1)-1)*NL
IF(IOR.GT.MAXRDA) CALL XABORT('SAPCA2: RDATAX OVERFLOW(5).')
JOFS=0
DO 302 IL=1,NL
DO 301 IGR=1,NG
DO 300 JGR=IFDG(IGR),IFDG(IGR)+(IADR(IGR+1)-IADR(IGR))-1
JOFS=JOFS+1
RDATAX(ADRX(IREA,NISO+IMAC,NADRX+1)+JOFS-1)=DATA3(JGR,IGR,IL)
300 CONTINUE
301 CONTINUE
302 CONTINUE
303 CONTINUE
ELSE
EXIST=.FALSE.
DO 310 IGR=1,NG
EXIST=EXIST.OR.(DATA1(IGR,IREA).NE.0.0)
310 CONTINUE
DO 330 IMAC=1,NMAC
IF(EXIST) THEN
ADRX(IREA,NISO+IMAC,NADRX+1)=IOR+1
IOR=IOR+NG
IF(IOR.GT.MAXRDA) CALL XABORT('SAPCA2: RDATAX OVERFLOW(6).')
DO 320 IGR=1,NG
RDATAX(ADRX(IREA,NISO+IMAC,NADRX+1)+IGR-1)=DATA1(IGR,IREA)
320 CONTINUE
ELSE
ADRX(IREA,NISO+IMAC,NADRX+1)=0
ENDIF
330 CONTINUE
ENDIF
340 CONTINUE
DO 350 IMAC=1,NMAC
IIS=IIS+1
ISOMIL(IIS,IMIL)=NISO+IMAC
350 CONTINUE
*----
* REMOVE PARTICULARIZED ISOTOPIC CONTRIBUTIONS FROM MACROS.
*----
IF(RESMAC(IMIL).GT.0) THEN
DO 410 IREA=1,NREA
IMACR=ADRX(IREA,NISO+RESMAC(IMIL),NADRX+1)
IF(IMACR.EQ.0) GO TO 410
IGRTOT=NG
IF(NOMREA(IREA).EQ.'DIFFUSION') IGRTOT=NG*NL
IF(NOMREA(IREA).EQ.'SPECTRE') GO TO 410
IF(NOMREA(IREA).EQ.'PROFIL') GO TO 410
DO 400 IISO=1,NISO
IF(DENISO(IISO).EQ.0.0) GO TO 400
JMACR=ADRX(IREA,IISO,NADRX+1)
IF(JMACR.EQ.0) GO TO 400
IF(NOMREA(IREA).EQ.'TRANSFERT') THEN
DO 370 IGR=1,NG
IFDG2(IGR)=IDATAP(ADRX(IREA-1,IISO,NADRX+1)+5+IGR)
IADR2(IGR)=IDATAP(ADRX(IREA-1,IISO,NADRX+1)+5+NG+IGR)
370 CONTINUE
IADR2(NG+1)=IDATAP(ADRX(IREA-1,IISO,NADRX+1)+6+2*NG)
JOFS=0
DO 382 IL=1,NL
DO 381 IGR=1,NG
DO 380 JGR=IFDG2(IGR),IFDG2(IGR)+(IADR2(IGR+1)-IADR2(IGR))-1
I=(IL-1)*(IADR(NG+1)-1)+IADR(IGR)+JGR-IFDG(IGR)
JOFS=JOFS+1
RDATAX(IMACR+I-1)=RDATAX(IMACR+I-1)-DENISO(IISO)*
1 RDATAX(JMACR+JOFS-1)
380 CONTINUE
381 CONTINUE
382 CONTINUE
ELSE
DO 390 IGR=1,IGRTOT
RDATAX(IMACR+IGR-1)=RDATAX(IMACR+IGR-1)-DENISO(IISO)*
1 RDATAX(JMACR+IGR-1)
390 CONTINUE
ENDIF
400 CONTINUE
410 CONTINUE
ENDIF
*
LENGDX(IMIL)=IOR
LENGDP(IMIL)=IOI
DO 430 IADRX=1,NADRX
DO 425 I=1,NREA+2
DO 420 J=1,NISO+NMAC
IF(ADRX(I,J,NADRX+1).NE.ADRX(I,J,IADRX)) GO TO 430
420 CONTINUE
425 CONTINUE
ISADRX(IMIL)=IADRX
GO TO 440
430 CONTINUE
NADRX=NADRX+1
ISADRX(IMIL)=NADRX
*----
* STORE INFORMATION IN THE MIXTURE DIRECTORY.
*----
440 WRITE(DIRNAM,'(''mili'',I8)') IMIL
CALL LCMSIX(IPSAP,DIRNAM,1)
CALL LCMPUT(IPSAP,'FLUXS',NG,2,FLUX)
IF(LENGDX(IMIL).GT.0) THEN
CALL LCMPUT(IPSAP,'RDATAX',LENGDX(IMIL),2,RDATAX)
ENDIF
IF(LENGDP(IMIL).GT.0) THEN
CALL LCMPUT(IPSAP,'IDATAP',LENGDP(IMIL),1,IDATAP)
ENDIF
IF(NISOTS.GT.0) THEN
CALL LCMPUT(IPSAP,'CONCES',NISOTS,2,CONCES)
DO 445 ISO=1,NISOTS
DECAYC(ISO)=DECAYC(ISO)*1.0E-8
445 CONTINUE
CALL LCMPUT(IPSAP,'DECAYC',NISOTS,2,DECAYC)
ENDIF
CALL LCMSIX(IPSAP,' ',2)
*
NISOMN(IMIL)=MAX(NISOMN(IMIL),NISMAX)
IF(NPRC.GT.0) THEN
EXIST=.FALSE.
DO 455 IPRC=1,NPRC
DO 450 IGR=1,NG
EXIST=EXIST.OR.(DNUSIG(IGR,IPRC).NE.0.0)
450 CONTINUE
455 CONTINUE
IF(EXIST) THEN
NMILNR=NMILNR+1
IF(LCRON) THEN
IF(NMIL.NE.1) CALL XABORT('SAPCA2: NMIL=1 MANDATORY WITH'
1 //' CRONOS OPTION.')
CALL LCMSIX(IPSAP,'divers',1)
ELSE
CALL LCMSIX(IPSAP,DIRNAM,1)
CALL LCMSIX(IPSAP,'cinetique',1)
ENDIF
CALL LCMPUT(IPSAP,'NPR',1,1,NPRC)
CALL LCMPUT(IPSAP,'CHIRS',NG*NPRC,2,DCHI)
CALL LCMPUT(IPSAP,'INVELS',NG,2,OVERV)
CALL LCMSIX(IPTEMP,'MACROLIB',1)
CALL LCMGET(IPTEMP,'LAMBDA-D',WORKD)
CALL LCMSIX(IPTEMP,' ',2)
CALL LCMPUT(IPSAP,'LAMBRS',NPRC,2,WORKD)
TGENRS=0.0
DENOM=0.0
DO 460 IGR=1,NG
TGENRS=TGENRS+OVERV(IGR)*FLUX(IGR)
DENOM=DENOM+DNUSIG(IGR,NPRC+1)*FLUX(IGR)
460 CONTINUE
TGENRS=TGENRS/DENOM
DO 480 IPRC=1,NPRC
WORKD(IPRC)=0.0
DO 470 IGR=1,NG
WORKD(IPRC)=WORKD(IPRC)+DNUSIG(IGR,IPRC)*FLUX(IGR)
470 CONTINUE
WORKD(IPRC)=WORKD(IPRC)/DENOM
480 CONTINUE
CALL LCMPUT(IPSAP,'BETARS',NPRC,2,WORKD)
CALL LCMPUT(IPSAP,'TGENRS',1,2,TGENRS)
IF(LCRON) THEN
CALL LCMSIX(IPSAP,' ',2)
ELSE
CALL LCMSIX(IPSAP,' ',2)
CALL LCMSIX(IPSAP,' ',2)
ENDIF
ENDIF
ENDIF
500 CONTINUE
DO IGR=1,NG
REGFLX(IGR)=REGFLX(IGR)/VOLTOT
ENDDO
DEALLOCATE(IPISO)
CALL LCMCL(IPTEMP,2)
*----
* STORE INFORMATION IN THE ELEMENTARY CALCULATION DIRECTORIES.
*----
NISFS=0
NISPS=0
DO 530 ISO=1,NISO
DO 510 IBISO=1,NBISO
WRITE(TEXT8,'(2A4)') (ISONAM(I0,IBISO),I0=1,2)
IF(NOMISO(ISO).EQ.TEXT8) THEN
ITY=ITYPE(IBISO)
GO TO 520
ENDIF
510 CONTINUE
GO TO 530
520 IF(ITY.EQ.2) THEN
NISFS=NISFS+1
ELSE IF(ITY.EQ.3) THEN
NISPS=NISPS+1
ENDIF
530 CONTINUE
IF(NISPS.EQ.0) THEN
NISYS=0
ELSE
NISYS=NISO+NMAC
ENDIF
CALL LCMSIX(IPSAP,'info',1)
CALL LCMPUT(IPSAP,'NISOTS',1,1,NISOTS)
CALL LCMPUT(IPSAP,'NISF',1,1,NISFS)
CALL LCMPUT(IPSAP,'NISP',1,1,NISPS)
CALL LCMPUT(IPSAP,'NISY',1,1,NISYS)
IF(NISOTS.GT.0) CALL LCMPTC(IPSAP,'ISOTS',8,NISOTS,ISOTS)
CALL LCMPUT(IPSAP,'ISADRX',NMIL,1,ISADRX)
CALL LCMPUT(IPSAP,'LENGDX',NMIL,1,LENGDX)
CALL LCMPUT(IPSAP,'LENGDP',NMIL,1,LENGDP)
CALL LCMSIX(IPSAP,' ',2)
*
IF(NVDIV.GT.0) THEN
CALL LCMSIX(IPSAP,'divers',1)
CALL LCMPUT(IPSAP,'NVDIV',1,1,NVDIV)
CALL LCMPTC(IPSAP,'IDVAL',4,NVDIV,IDVAL)
CALL LCMPUT(IPSAP,'VALDIV',NVDIV,2,VALDIV)
CALL LCMSIX(IPSAP,' ',2)
ENDIF
*----
* MOVE TO THE SAPHYB ROOT DIRECTORY.
*----
CALL LCMSIX(IPSAP,' ',2)
*----
* STORE INFORMATION IN THE 'adresses' DIRECTORY.
*----
CALL LCMSIX(IPSAP,'adresses',1)
CALL LCMPUT(IPSAP,'ADRX',(NREA+2)*(NISO+NMAC)*NADRX,1,ADRX)
CALL LCMPUT(IPSAP,'ISOMIL',(NISO+NMAC)*NMIL,1,ISOMIL)
CALL LCMPUT(IPSAP,'NISOMN',NMIL,1,NISOMN)
CALL LCMPUT(IPSAP,'ISADRC',NMIL,1,ISADRX)
CALL LCMSIX(IPSAP,' ',2)
*----
* SCRATCH STORAGE DEALLOCATION
*----
DEALLOCATE(DECAYC,CONCES,DENISO,DEN,DATA4,DATA3,DATA2,DATA1,VOL,
1 WORK2,WORK1,WORKD,DCHI,DNUSIG,OVERV,FLUX,RDATAX)
DEALLOCATE(ITYPE,MIX,ISONAM,NJJ2,IJJ2,IPOS,NJJ1,IJJ1,IADR2,IFDG2,
1 IADR,IFDG,IDATAP,LENGDP,LENGDX,ISADRX,NISOMN,ISOMIL,ADRX,RESMAC)
RETURN
END
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