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|
*DECK MPOCA2
SUBROUTINE MPOCA2(IPMPO,IPEDIT,HEDIT,NREA,NISO,NADRX,NED,NPRC,
1 ILEAK,NG,NMIL,NL,ITRANC,NALBP,IMC,NBISO,ICAL,MAXRDA,MAXIDA,
2 FNORM,IMPX,NISOTS,NISFS,NISPS,VOLMIL,FLXMIL)
*
*-----------------------------------------------------------------------
*
*Purpose:
* Recover the cross sections of an elementary calculation.
*
*Copyright:
* Copyright (C) 2022 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
* IPMPO pointer to the MPO file.
* IPEDIT pointer to the edition object (L_EDIT signature).
* HEDIT name of output group for a (multigroup mesh, output geometry)
* couple (generally equal to 'output_0').
* NREA number of requested reactions.
* NISO number of particularized isotopes.
* NADRX total number of ADRX sets.
* NED number of additional edition cross sections.
* NPRC number of delayed neutron precursors.
* ILEAK type of leakage (=0/1: off/diffusion coefficients).
* NG number of condensed energy groups.
* NMIL number of mixtures in the MPO file.
* NL number of Legendre orders.
* ITRANC type of transport correction.
* NALBP number of physical albedos per energy group.
* IMC type of macro-calculation (1 for diffusion or SPN;
* 2 other method).
* 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.
* IMPX print parameter.
*
*Parameters: output
* NISOTS number of distinct isotopes.
* NISFS number of particularized fissile isotopes.
* NISPS number of particularized fission products.
* VOLMIL mixture volumes.
* FLXMIL averaged flux of mixtures.
*
*-----------------------------------------------------------------------
*
USE GANLIB
USE hdf5_wrap
*----
* SUBROUTINE ARGUMENTS
*----
TYPE(C_PTR) IPMPO,IPEDIT
INTEGER NREA,NISO,NADRX,NED,NPRC,ILEAK,NG,NMIL,NL,ITRANC,NALBP,
1 IMC,NBISO,ICAL,MAXRDA,MAXIDA,IMPX,NISOTS,NISFS,NISPS
REAL FNORM,VOLMIL(NMIL),FLXMIL(NMIL,NG)
CHARACTER(LEN=12) HEDIT
*----
* LOCAL VARIABLES
*----
PARAMETER (NREAK=50,MAXISO=800)
TYPE(C_PTR) JPEDIT,KPEDIT,IPTEMP,KPTEMP
INTEGER FGYS(2),RANK,TYPE,NBYTE,DIMSR(5),ADDRZI
CHARACTER ISOTS(MAXISO)*8,CM*2,TEXT8*8,TEXT12*12,HSMG*131,
1 RECNAM*80
LOGICAL EXIST,LSPH
DOUBLE PRECISION CONV
*----
* ALLOCATABLE ARRAYS
*----
INTEGER, ALLOCATABLE, DIMENSION(:) :: IDATAP,IFD1,IAD1,IFD2,IAD2,
1 IJJ1,NJJ1,IPOS,IJJ2,NJJ2,MIX,ITYPE,IDEPL,IDATAP_MIL,VINTE1D
INTEGER, ALLOCATABLE, DIMENSION(:) :: REACTION,ISOTOPE
INTEGER, ALLOCATABLE, DIMENSION(:,:) :: ISONAM,OUPUTID
INTEGER, ALLOCATABLE, DIMENSION(:,:,:) :: ADRX,VINTE3D
REAL, ALLOCATABLE, DIMENSION(:) :: RDATAX,OVERV,WORKD,WORK1,
1 WORK2,DEN,DENISO,CONCES,DECAYC,ENERG,VREAL
REAL, ALLOCATABLE, DIMENSION(:,:) :: DNUSIG,DCHI,DATA1,DATA2,
1 DATA4,SPH
REAL, ALLOCATABLE, DIMENSION(:,:,:) :: DATA3
CHARACTER(LEN=24), ALLOCATABLE, DIMENSION(:) :: TEXT24,NOMREA,
1 NOMISO
TYPE(C_PTR), ALLOCATABLE, DIMENSION(:) :: IPISO
*----
* SCRATCH STORAGE ALLOCATION
*----
ALLOCATE(ADRX(NREA+3,NISO,NADRX+NMIL),IDATAP(MAXIDA),IFD1(NG),
1 IAD1(NG+1),IFD2(NG),IAD2(NG+1),IJJ1(NMIL),NJJ1(NMIL),
2 IPOS(NMIL),IJJ2(NG),NJJ2(NG),ISONAM(3,NBISO),MIX(NBISO),
3 ITYPE(NBISO),IDEPL(NBISO),IDATAP_MIL((2*NG+1)*NISO))
ALLOCATE(RDATAX(MAXRDA),OVERV(NG),DNUSIG(NG,NPRC+1),
1 DCHI(NG,NPRC),WORKD(NPRC),WORK1(NG*NMIL+1),WORK2(NG),
2 DATA1(NG,NREA),DATA2(NG,NL),DATA3(NG,NG,NL),DATA4(NG,NG),
3 DEN(NBISO),DENISO(NISO),CONCES(NBISO))
*
CONV=1.0D6 ! convert MeV to eV in H-FACTOR
IF(NREA.GT.NREAK) CALL XABORT('MPOCA2: NOMREA OVERFLOW.')
*----
* SET ENERGY MESH AND ZONE VOLUMES
*----
CALL hdf5_read_data(IPMPO,"/energymesh/NENERGYMESH",NENERG)
CALL hdf5_read_data(IPMPO,"/geometry/NGEOMETRY",NGEOME)
CALL hdf5_read_data(IPMPO,"/output/OUPUTID",OUPUTID)
READ(HEDIT,'(7X,I2)') ID
ID_G=-1
ID_E=-1
DO I=1,NGEOME
DO J=1,NENERG
IF(OUPUTID(J,I).EQ.ID) THEN
ID_G=I-1
ID_E=J-1
GO TO 10
ENDIF
ENDDO
ENDDO
CALL XABORT('MPOCA2: no ID found in /output/OUPUTID.')
10 WRITE(RECNAM,'(23H/energymesh/energymesh_,I0,1H/)') ID_E
CALL hdf5_read_data(IPMPO,TRIM(RECNAM)//"NG",NG2)
CALL hdf5_read_data(IPMPO,TRIM(RECNAM)//"ENERGY",ENERG)
IF(SIZE(ENERG,1)-1.NE.NG) CALL XABORT('MPOCA2: INVALID NG VALUE.')
DO 20 IGR=1,NG+1
ENERG(IGR)=ENERG(IGR)/1.0E-6
20 CONTINUE
WRITE(RECNAM,'(19H/geometry/geometry_,I0,1H/)') ID_G
CALL hdf5_read_data(IPMPO,TRIM(RECNAM)//"ZONEVOLUME",VREAL)
VOLMIL(:)=VREAL(:)
DEALLOCATE(VREAL)
CALL hdf5_read_data(IPMPO,TRIM(RECNAM)//"NZONE",NMIL2)
IF(NMIL.NE.NMIL2) THEN
WRITE(HSMG,'(42HMPOCA2: ELEMENTARY CALCULATION WITH AN INV,
1 22HALIB NB. OF MIXTURES =,I7,3H NE,I7,1H.)') NMIL2,NMIL
CALL XABORT(HSMG)
ELSE IF(NG.NE.NG2) THEN
WRITE(HSMG,'(42HMPOCA2: ELEMENTARY CALCULATION WITH AN INV,
1 20HALIB NB. OF GROUPS =,I7,3H NE,I7,1H.)') NG2,NG
CALL XABORT(HSMG)
ENDIF
*----
* CREATE DUMMY DAYASETS REACTION AND ISOTOPE
*----
WRITE(RECNAM,'(8H/output/,A,6H/info/)') TRIM(HEDIT)
CALL hdf5_read_data(IPMPO,TRIM(RECNAM)//"REACTION",REACTION)
CALL hdf5_read_data(IPMPO,TRIM(RECNAM)//"ISOTOPE",ISOTOPE)
*----
* RECOVER INFORMATION FROM THE info and contents GROUPS.
*----
ALLOCATE(NOMREA(NREA+2),NOMISO(NISO))
IF(NREA.GT.0) THEN
CALL hdf5_read_data(IPMPO,"/contents/reactions/REACTIONAME",
> TEXT24)
DO 30 I=1,NREA
NOMREA(I)=TEXT24(REACTION(I)+1)
30 continue
DEALLOCATE(TEXT24,REACTION)
ENDIF
CALL hdf5_read_data(IPMPO,"/contents/isotopes/ISOTOPENAME",TEXT24)
DO 40 I=1,NISO
NOMISO(I)=TEXT24(ISOTOPE(I)+1)
40 CONTINUE
DEALLOCATE(TEXT24,ISOTOPE)
IF(IMPX.GT.2) THEN
WRITE(6,'(/24H MPOCA2: reaction names:)')
DO 50 I=1,NREA
WRITE(6,'(5X,7HNOMREA(,I3,2H)=,A)') I,TRIM(NOMREA(I))
50 CONTINUE
WRITE(6,'(/23H MPOCA2: isotope names:)')
DO 60 I=1,NISO
WRITE(6,'(5X,7HNOMISO(,I3,2H)=,A)') I,TRIM(NOMISO(I))
60 CONTINUE
ENDIF
*----
* RECOVER NADRI AND IDATAP.
* NADRI IS THE TOTAL NUMBER OF TRANSPROFILE SETS.
*----
WRITE(RECNAM,'(8H/output/,A,6H/info/)') TRIM(HEDIT)
NADRI=0
CALL hdf5_info(IPMPO,TRIM(RECNAM)//"TRANSPROFILE",RANK,TYPE,NBYTE,
1 DIMSR)
IF(TYPE.NE.99) THEN
NADRI=DIMSR(1)/(2*NG+1)
CALL hdf5_read_data(IPMPO,TRIM(RECNAM)//"TRANSPROFILE",VINTE1D)
IDATAP(:DIMSR(1))=VINTE1D(:DIMSR(1))
DEALLOCATE(VINTE1D)
ENDIF
*----
* RECOVER INFORMATION FROM THE output_id/info GROUP.
*----
CALL hdf5_info(IPMPO,TRIM(RECNAM)//"ADDRXS",RANK,TYPE,NBYTE,DIMSR)
IF(TYPE.NE.99) THEN
CALL hdf5_read_data(IPMPO,TRIM(RECNAM)//"ADDRXS",VINTE3D)
IF(NADRX.NE.DIMSR(3)) CALL XABORT('MPOCA2: INVALID NADRX.')
ADRX(:,:,:NADRX)=VINTE3D(:,:,:NADRX)
DEALLOCATE(VINTE3D)
ENDIF
*----
* SAVE INFORMATION TO THE /output/output_id/statept_id/zone_id/yields/
* GROUP.
*----
WRITE(RECNAM,'(8H/output/,A,9H/statept_,I0)') TRIM(HEDIT),ICAL-1
CALL hdf5_create_group(IPMPO,TRIM(RECNAM))
DO 70 IMIL=1,NMIL
WRITE(RECNAM,'(8H/output/,A,9H/statept_,I0,6H/zone_,I0,1H/)')
> TRIM(HEDIT),ICAL-1,IMIL-1
NMGF=1
CALL hdf5_create_group(IPMPO,TRIM(RECNAM))
IF(NBISO.GT.0) THEN
FGYS(1)=0
FGYS(2)=1
CALL hdf5_create_group(IPMPO,TRIM(RECNAM)//"yields")
CALL hdf5_write_data(IPMPO,TRIM(RECNAM)//"yields/NMGF",NMGF)
CALL hdf5_write_data(IPMPO,TRIM(RECNAM)//"yields/YIELDGROUP",
> FGYS)
ENDIF
70 CONTINUE
*----
* 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)
CALL LCMGET(IPEDIT,'ISOTOPESTODO',IDEPL)
ENDIF
NISOTS=0
DO 90 IBISO=1,NBISO
IF(MIX(IBISO).EQ.0) GO TO 90
WRITE(TEXT12,'(3A4)') (ISONAM(I0,IBISO),I0=1,3)
DO 80 ISO=1,NISOTS
IF(TEXT12(:8).EQ.ISOTS(ISO)) GO TO 90
80 CONTINUE
NISOTS=NISOTS+1
IF(NISOTS.GT.MAXISO) CALL XABORT('MPOCA2: ISOTS OVERFLOW.')
IF(NISOTS.GT.NBISO) CALL XABORT('MPOCA2: CONCES OVERFLOW.')
ISOTS(NISOTS)=TEXT12(:8)
90 CONTINUE
*----
* RECOVER INVERSE OF SPH EQUIVALENCE FACTORS.
*----
CALL LCMSIX(IPEDIT,'MACROLIB',1)
JPEDIT=LCMGID(IPEDIT,'GROUP')
LSPH=.FALSE.
ALLOCATE(SPH(NMIL+NALBP,NG))
DO 120 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 100 IMIL=1,NMIL
SPH(IMIL,IGR)=1.0/WORK1(IMIL)
100 CONTINUE
DO 110 IALB=1,NALBP
SPH(NMIL+IALB,IGR)=1.0
110 CONTINUE
ELSE
SPH(:NMIL+NALBP,IGR)=1.0
ENDIF
120 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('MPOCA2: UNDEFINED TYPE OF SPH.')
NW=1 ! NTOT1 cross section present
CALL SPHCMI(IPTEMP,0,IMC,NMIL,NBISO,NG,NL,NW,NED,NPRC,NALBP,SPH)
ENDIF
DEALLOCATE(SPH)
*----
* FIND ISOTOPE POINTERS IN INPUT MICROLIB
*----
IF(NBISO.GT.0) CALL LIBIPS(IPTEMP,NBISO,IPISO)
*----
* RECOVER RADIOACTIVE DECAY CONSTANTS.
*----
IF(ICAL.EQ.1) THEN
ALLOCATE(DECAYC(NISOTS))
DECAYC(:NISOTS)=0.0
DO 150 IBISO=1,NBISO
IF(IDEPL(IBISO).EQ.1) GO TO 150
IF(MIX(IBISO).EQ.0) GO TO 150
WRITE(TEXT12,'(3A4)') (ISONAM(I0,IBISO),I0=1,3)
IISOTS=0
DO 130 ISO=1,NISOTS
IISOTS=ISO
IF(TEXT12(:8).EQ.ISOTS(ISO)) GO TO 140
130 CONTINUE
CALL XABORT('MPOCA2: UNABLE TO FIND ISOTOPE '//TEXT12//'.')
140 DECAYC(IISOTS)=0.0
JPEDIT=IPISO(IBISO)
IF(.NOT.C_ASSOCIATED(JPEDIT)) GO TO 150
CALL LCMLEN(JPEDIT,'DECAY',ILONG,ITYLCM)
IF(ILONG.EQ.1) CALL LCMGET(JPEDIT,'DECAY',DECAYC(IISOTS))
150 CONTINUE
DO 160 ISO=1,NISOTS
DECAYC(ISO)=DECAYC(ISO)*1.0E-8
160 CONTINUE
CALL hdf5_write_data(IPMPO,"/contents/isotopes/DECAYCONST",
1 DECAYC)
DEALLOCATE(DECAYC)
ENDIF
*----
* STORE INFORMATION IN THE output_id/statept_id/addons GROUP.
*----
WRITE(RECNAM,'(8H/output/,A,9H/statept_,I0,8H/addons/)')
& TRIM(HEDIT),ICAL-1
CALL hdf5_create_group(IPMPO,TRIM(RECNAM))
CALL LCMSIX(IPTEMP,'MACROLIB',1)
JPEDIT=LCMGID(IPTEMP,'GROUP')
CALL LCMLEN(IPTEMP,'K-EFFECTIVE',ILONG,ITYLCM)
IF(ILONG.EQ.1) THEN
CALL LCMGET(IPTEMP,'K-EFFECTIVE',FLOTT)
CALL hdf5_write_data(IPMPO,TRIM(RECNAM)//"KEFF",FLOTT)
ENDIF
CALL LCMLEN(IPTEMP,'K-INFINITY',ILONG,ITYLCM)
IF(ILONG.EQ.1) THEN
CALL LCMGET(IPTEMP,'K-INFINITY',FLOTT)
CALL hdf5_write_data(IPMPO,TRIM(RECNAM)//"KINF",FLOTT)
ENDIF
CALL LCMLEN(IPTEMP,'B2 B1HOM',ILONG,ITYLCM)
IF(ILONG.EQ.1) THEN
CALL LCMGET(IPTEMP,'B2 B1HOM',B2)
CALL hdf5_write_data(IPMPO,TRIM(RECNAM)//"B2",B2)
ENDIF
CALL LCMSIX(IPTEMP,' ',2)
*----
* LOOP OVER MPO MIXTURES.
*----
DO 920 IMIL=1,NMIL
IF(NADRX+1.GT.SIZE(ADRX,3)) CALL XABORT('MPOCA2: ADRX OVERFLOW.')
IOI=0
IOR=0
DO 165 IGR=1,NG
IFD1(IGR)=NG+1
IAD1(IGR+1)=0
165 CONTINUE
DATA2(:NG,:NL)=0.0
DATA3(:NG,:NG,:NL)=0.0
CALL LCMSIX(IPTEMP,'MACROLIB',1)
DO 230 IGR=1,NG
KPEDIT=LCMGIL(JPEDIT,IGR)
*----
* RECOVER THE NEUTRON FLUX.
*----
CALL LCMGET(KPEDIT,'FLUX-INTG',WORK1)
IF(FNORM.NE.1.0) THEN
FLXMIL(IMIL,IGR)=WORK1(IMIL)*FNORM*1.0E13
ELSE
FLXMIL(IMIL,IGR)=WORK1(IMIL)
ENDIF
*----
* 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 170 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)
170 CONTINUE
ELSE
DNUSIG(:NG,:NPRC+1)=0.0
ENDIF
*
DO 220 IREA=1,NREA
DATA1(IGR,IREA)=0.0
IF(NOMREA(IREA).EQ.'Total') THEN
CALL LCMGET(KPEDIT,'NTOT0',WORK1)
DATA1(IGR,IREA)=WORK1(IMIL)
ELSE IF(NOMREA(IREA).EQ.'TotalP1') 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.'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.'FissionSpectrum') 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.'NuFission') 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.'Energy') 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.'Diffusion') THEN
DO 180 IL=1,NL
WRITE (CM,'(I2.2)') IL-1
CALL LCMGET(KPEDIT,'SIGS'//CM,WORK1)
DATA2(IGR,IL)=WORK1(IMIL)
180 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.'Transport') 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.'Scattering') THEN
DO 190 IL=1,NL
WRITE (CM,'(I2.2)') IL-1
CALL LCMLEN(KPEDIT,'IJJS'//CM,ILONG,ITYLCM)
IF(ILONG.EQ.0) GO TO 190
CALL LCMGET(KPEDIT,'IJJS'//CM,IJJ1)
CALL LCMGET(KPEDIT,'NJJS'//CM,NJJ1)
DO 185 JGR=IJJ1(IMIL)-NJJ1(IMIL)+1,IJJ1(IMIL) ! IGR <-- JGR
IFD1(JGR)=MIN(IFD1(JGR),IGR)
IAD1(JGR+1)=MAX(IAD1(JGR+1),IGR)
185 CONTINUE
190 CONTINUE
DO 210 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 200 JGR=J2,J1,-1
DATA3(IGR,JGR,IL)=WORK1(IPO)*REAL(2*IL-1)
IPO=IPO+1
200 CONTINUE
210 CONTINUE
ELSE
CALL LCMLEN(KPEDIT,NOMREA(IREA)(:12),ILONG,ITYLCM)
IF(ILONG.GT.0) THEN
CALL LCMGET(KPEDIT,NOMREA(IREA),WORK1)
DATA1(IGR,IREA)=WORK1(IMIL)
ENDIF
ENDIF
220 CONTINUE
230 CONTINUE
IAD1(1)=0
DO 235 IGR=1,NG
IAD1(IGR+1)=IAD1(IGR)+(IAD1(IGR+1)-IFD1(IGR)+1)
235 CONTINUE
CALL LCMSIX(IPTEMP,' ',2)
*----
* PROCESS PARTICULARIZED ISOTOPES
*----
IF(NBISO.GT.0) THEN
DO 250 IISO=1,NISO
DO 240 IREA=1,NREA+3
ADRX(IREA,IISO,NADRX+1)=-1
240 CONTINUE
250 CONTINUE
CONCES(:NISOTS)=0.0
DO 540 IBISO=1,NBISO
IF(MIX(IBISO).EQ.IMIL) THEN
WRITE(TEXT12,'(3A4)') (ISONAM(I0,IBISO),I0=1,3)
DO 260 ISO=1,NISO
IISO=ISO
IF(NOMISO(ISO).EQ.TEXT12(:8)) GO TO 270
260 CONTINUE
GO TO 540
270 IF(IISO.GT.NISO-1) CALL XABORT('MPOCA2: NISO OVERFLOW.')
KPTEMP=IPISO(IBISO) ! set IBISO-th isotope
IF(.NOT.C_ASSOCIATED(KPTEMP)) THEN
WRITE(HSMG,'(17HMPOCA2: ISOTOPE '',A12,7H'' (ISO=,I8,3H) I,
1 32HS NOT AVAILABLE IN THE MICROLIB.)') TEXT12,IBISO
CALL XABORT(HSMG)
ENDIF
IISOTS=0
DO 280 ISO=1,NISOTS
IISOTS=ISO
IF(ISOTS(ISO).EQ.TEXT12(:8)) GO TO 290
280 CONTINUE
CALL XABORT('MPOCA2: UNABLE TO FIND ISOTOPE '//TEXT12//'.')
290 CONCES(IISOTS)=DEN(IBISO)
DENISO(IISO)=DEN(IBISO)
DO 530 IREA=1,NREA
WORK2(:NG)=0.0
IF(NOMREA(IREA).EQ.'Total') THEN
CALL LCMGET(KPTEMP,'NTOT0',WORK2)
ELSE IF(NOMREA(IREA).EQ.'TotalP1') 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 300 IGR=1,NG
WORK2(IGR)=WORK2(IGR)-WORK1(IGR)
300 CONTINUE
ENDIF
CALL LCMLEN(KPTEMP,'N2N',ILONG,ITYLCM)
IF(ILONG.GT.0) THEN
CALL LCMGET(KPTEMP,'N2N',WORK1)
DO 310 IGR=1,NG
WORK2(IGR)=WORK2(IGR)+WORK1(IGR)
310 CONTINUE
ENDIF
CALL LCMLEN(KPTEMP,'N3N',ILONG,ITYLCM)
IF(ILONG.GT.0) THEN
CALL LCMGET(KPTEMP,'N3N',WORK1)
DO 320 IGR=1,NG
WORK2(IGR)=WORK2(IGR)+2.0*WORK1(IGR)
320 CONTINUE
ENDIF
ELSE IF(NOMREA(IREA).EQ.'Nexcess') 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 330 IGR=1,NG
WORK2(IGR)=WORK2(IGR)+2.0*WORK1(IGR)
330 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.'FissionSpectrum') THEN
CALL LCMLEN(KPTEMP,'CHI',ILONG,ITYLCM)
IF(ILONG.GT.0) CALL LCMGET(KPTEMP,'CHI',WORK2)
ELSE IF(NOMREA(IREA).EQ.'NuFission') THEN
CALL LCMLEN(KPTEMP,'NUSIGF',ILONG,ITYLCM)
IF(ILONG.GT.0) CALL LCMGET(KPTEMP,'NUSIGF',WORK2)
ELSE IF(NOMREA(IREA).EQ.'Energy') THEN
CALL LCMLEN(KPTEMP,'MEVF',ILONG,ITYLCM)
IF(ILONG.GT.0) THEN
CALL LCMGET(KPTEMP,'NFTOT',WORK2)
CALL LCMGET(KPTEMP,'MEVF',FLOTT)
DO 340 IGR=1,NG
WORK2(IGR)=WORK2(IGR)*FLOTT
340 CONTINUE
ENDIF
CALL LCMLEN(KPTEMP,'MEVG',ILONG,ITYLCM)
IF(ILONG.GT.0) THEN
CALL LCMGET(KPTEMP,'NG',WORK1)
CALL LCMGET(KPTEMP,'MEVG',FLOTT)
DO 350 IGR=1,NG
WORK2(IGR)=WORK2(IGR)+WORK1(IGR)*FLOTT
350 CONTINUE
ENDIF
ELSE IF(NOMREA(IREA).EQ.'FissionEnergyFission') THEN
CALL LCMLEN(KPTEMP,'MEVF',ILONG,ITYLCM)
IF(ILONG.GT.0) THEN
CALL LCMGET(KPTEMP,'NFTOT',WORK2)
CALL LCMGET(KPTEMP,'MEVF',FLOTT)
DO 360 IGR=1,NG
WORK2(IGR)=WORK2(IGR)*FLOTT
360 CONTINUE
ENDIF
ELSE IF(NOMREA(IREA).EQ.'CaptureEnergyCapture') THEN
CALL LCMLEN(KPTEMP,'MEVG',ILONG,ITYLCM)
IF(ILONG.GT.0) THEN
CALL LCMGET(KPTEMP,'NG',WORK2)
CALL LCMGET(KPTEMP,'MEVG',FLOTT)
DO 370 IGR=1,NG
WORK2(IGR)=WORK2(IGR)*FLOTT
370 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.'Diffusion') THEN
ADRX(IREA,IISO,NADRX+1)=IOR
ADRX(NREA+1,IISO,NADRX+1)=NL
IOR=IOR+NG*NL
IF(IOR.GT.MAXRDA) CALL XABORT('MPOCA2: RDATAX OVERFLOW(1)')
DO 420 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 390 IGR=1,NG
WORK2(IGR)=WORK2(IGR)-WORK1(IGR)
390 CONTINUE
ENDIF
CALL LCMLEN(KPTEMP,'N3N',ILONG,ITYLCM)
IF((IL.EQ.1).AND.(ILONG.GT.0)) THEN
CALL LCMGET(KPTEMP,'N3N',WORK1)
DO 400 IGR=1,NG
WORK2(IGR)=WORK2(IGR)-2.0*WORK1(IGR)
400 CONTINUE
ENDIF
DO 410 IGR=1,NG
RDATAX(ADRX(IREA,IISO,NADRX+1)+(IL-1)*NG+IGR-1)=WORK2(IGR)
410 CONTINUE
420 CONTINUE
GO TO 530
ELSE IF(NOMREA(IREA).EQ.'Transport') 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.'Scattering') THEN
DO 430 IGR=1,NG
IFD2(IGR)=NG+1
IAD2(IGR+1)=0
430 CONTINUE
DO 450 IL=1,NL
WRITE (CM,'(I2.2)') IL-1
CALL LCMLEN(KPTEMP,'IJJS'//CM,ILONG,ITYLCM)
IF(ILONG.EQ.0) GO TO 450
CALL LCMGET(KPTEMP,'IJJS'//CM,IJJ2)
CALL LCMGET(KPTEMP,'NJJS'//CM,NJJ2)
DO 445 JGR=1,NG
DO 440 IGR=IJJ2(JGR)-NJJ2(JGR)+1,IJJ2(JGR) ! JGR <-- IGR
IFD2(IGR)=MIN(IFD2(IGR),JGR)
IAD2(IGR+1)=MAX(IAD2(IGR+1),JGR)
440 CONTINUE
445 CONTINUE
450 CONTINUE
IAD2(1)=0
DO 460 IGR=1,NG
IAD2(IGR+1)=IAD2(IGR)+(IAD2(IGR+1)-IFD2(IGR)+1)
460 CONTINUE
ADRX(NREA+1,IISO,NADRX+1)=NL
ADRX(NREA+2,IISO,NADRX+1)=NL
ADRX(NREA+3,IISO,NADRX+1)=IOI
IF(IOI+2*NG+1.GT.(2*NG+1)*NISO) THEN
CALL XABORT('MPOCA2: IDATAP_MIL OVERFLOW(1).')
ENDIF
DO 470 IGR=1,NG
IDATAP_MIL(IOI+IGR)=IFD2(IGR)-1
IDATAP_MIL(IOI+NG+IGR)=IAD2(IGR)
470 CONTINUE
IDATAP_MIL(IOI+2*NG+1)=IAD2(NG+1)
ADRX(NREA+3,IISO,NADRX+1)=IOI
IOI=IOI+2*NG+1
*
ADRX(IREA,IISO,NADRX+1)=IOR
IOR=IOR+IAD2(NG+1)*NL
IF(IOR.GT.MAXRDA) CALL XABORT('MPOCA2: RDATAX OVERFLOW(2)')
JOFS=0
DO 500 IL=1,NL
CALL XDRLGS(KPTEMP,-1,0,IL-1,IL-1,1,NG,WORK2,DATA4,ITYPRO)
ZIL=REAL(2*IL-1)
DO 490 IGR=1,NG
DO 480 JGR=IFD2(IGR),IFD2(IGR)+(IAD2(IGR+1)-IAD2(IGR))-1 ! JGR <-- IGR
JOFS=JOFS+1
RDATAX(ADRX(IREA,IISO,NADRX+1)+JOFS-1)=DATA4(JGR,IGR)*ZIL
480 CONTINUE
490 CONTINUE
500 CONTINUE
GO TO 530
ELSE
CALL LCMLEN(KPTEMP,NOMREA(IREA),ILONG,ITYLCM)
IF(ILONG.GT.0) CALL LCMGET(KPTEMP,NOMREA(IREA),WORK2)
ENDIF
*
EXIST=.FALSE.
DO 510 IGR=1,NG
EXIST=EXIST.OR.(WORK2(IGR).NE.0.0)
510 CONTINUE
IF(EXIST) THEN
ADRX(IREA,IISO,NADRX+1)=IOR
IOR=IOR+NG
IF(IOR.GT.MAXRDA) CALL XABORT('MPOCA2: RDATAX OVERFLOW(3)')
DO 520 IGR=1,NG
RDATAX(ADRX(IREA,IISO,NADRX+1)+IGR)=WORK2(IGR)
520 CONTINUE
ELSE
ADRX(IREA,IISO,NADRX+1)=-1
ENDIF
530 CONTINUE
ENDIF
540 CONTINUE
ENDIF
*----
* STORE MACROSCOPIC RESIDUAL (ISOTOPE NISO) CROSS SECTIONS IN RDATAX.
*----
ADRX(NREA+1,NISO,NADRX+1)=0
ADRX(NREA+2,NISO,NADRX+1)=0
ADRX(NREA+3,NISO,NADRX+1)=0
DO 680 IREA=1,NREA
IF(NOMREA(IREA).EQ.'Diffusion') THEN
ADRX(IREA,NISO,NADRX+1)=IOR
ADRX(NREA+1,NISO,NADRX+1)=NL
IOR=IOR+NG*NL
IF(IOR.GT.MAXRDA) CALL XABORT('MPOCA2: RDATAX OVERFLOW(4)')
JOFS=0
DO 570 IL=1,NL
DO 560 IGR=1,NG
JOFS=JOFS+1
RDATAX(ADRX(IREA,NISO,NADRX+1)+JOFS)=DATA2(IGR,IL)
560 CONTINUE
570 CONTINUE
ELSE IF(NOMREA(IREA).EQ.'Scattering') THEN
ADRX(NREA+2,NISO,NADRX+1)=NL
ADRX(NREA+3,NISO,NADRX+1)=IOI
IF(IOI+2*NG+1.GT.(2*NG+1)*NISO) THEN
CALL XABORT('MPOCA2: IDATAP_MIL OVERFLOW(2).')
ENDIF
DO 590 IGR=1,NG
IDATAP_MIL(IOI+IGR)=IFD1(IGR)-1
IDATAP_MIL(IOI+NG+IGR)=IAD1(IGR)
590 CONTINUE
IDATAP_MIL(IOI+2*NG+1)=IAD1(NG+1)
ADRX(NREA+3,NISO,NADRX+1)=IOI
IOI=IOI+2*NG+1
*
ADRX(IREA,NISO,NADRX+1)=IOR
IOR=IOR+IAD1(NG+1)*NL
IF(IOR.GT.MAXRDA) CALL XABORT('MPOCA2: RDATAX OVERFLOW(5)')
JOFS=0
DO 630 IL=1,NL
DO 620 IGR=1,NG
DO 610 JGR=IFD1(IGR),IFD1(IGR)+(IAD1(IGR+1)-IAD1(IGR))-1 ! JGR <-- IGR
JOFS=JOFS+1
RDATAX(ADRX(IREA,NISO,NADRX+1)+JOFS)=DATA3(JGR,IGR,IL)
610 CONTINUE
620 CONTINUE
630 CONTINUE
ELSE
EXIST=.FALSE.
DO 650 IGR=1,NG
EXIST=EXIST.OR.(DATA1(IGR,IREA).NE.0.0)
650 CONTINUE
IF(EXIST) THEN
ADRX(IREA,NISO,NADRX+1)=IOR
IOR=IOR+NG
IF(IOR.GT.MAXRDA) CALL XABORT('MPOCA2: RDATAX OVERFLOW(6)')
DO 660 IGR=1,NG
RDATAX(ADRX(IREA,NISO,NADRX+1)+IGR)=DATA1(IGR,IREA)
660 CONTINUE
ELSE
ADRX(IREA,NISO,NADRX+1)=-1
ENDIF
ENDIF
680 CONTINUE
*----
* REMOVE PARTICULARIZED ISOTOPIC CONTRIBUTIONS FROM MACROS.
* ISOTOPE NISO IS THE MACROSCOPIC RESIDUAL.
*----
IF(NBISO.GT.0) THEN
DO 750 IREA=1,NREA
IMACR=ADRX(IREA,NISO,NADRX+1)
IF(IMACR+(IAD1(NG+1)-1)*NL-1.GT.MAXRDA) THEN
CALL XABORT('MPOCA2: RDATAX OVERFLOW(6).')
ENDIF
IF(IMACR.EQ.-1) GO TO 750
IGRTOT=NG
IF(NOMREA(IREA).EQ.'Diffusion') IGRTOT=NG*NL
IF(NOMREA(IREA).EQ.'FissionSpectrum') GO TO 750
DO 740 IISO=1,NISO-1
IF(DENISO(IISO).EQ.0.0) GO TO 740
JMACR=ADRX(IREA,IISO,NADRX+1)
IF(JMACR.EQ.-1) GO TO 740
IF(NOMREA(IREA).EQ.'Scattering') THEN
IOI=ADRX(NREA+3,IISO,NADRX+1)
DO 690 IGR=1,NG
IFD2(IGR)=IDATAP_MIL(IOI+IGR)+1
IAD2(IGR)=IDATAP_MIL(IOI+NG+IGR)
690 CONTINUE
IAD2(NG+1)=IDATAP_MIL(IOI+2*NG+1)
JOFS=0
DO 720 IL=1,NL
DO 710 IGR=1,NG
DO 700 JGR=IFD2(IGR),IFD2(IGR)+(IAD2(IGR+1)-IAD2(IGR)) ! JGR <-- IGR
I=(IL-1)*(IAD1(NG+1)-1)+IAD1(IGR)+JGR-IFD1(IGR)
JOFS=JOFS+1
RDATAX(IMACR+I-1)=RDATAX(IMACR+I-1)-DENISO(IISO)*
1 RDATAX(JMACR+JOFS-1)
700 CONTINUE
710 CONTINUE
720 CONTINUE
ELSE
DO 730 IGR=1,IGRTOT
RDATAX(IMACR+IGR-1)=RDATAX(IMACR+IGR-1)-DENISO(IISO)*
1 RDATAX(JMACR+IGR-1)
730 CONTINUE
ENDIF
740 CONTINUE
750 CONTINUE
ENDIF
DENISO(NISO)=1.0
*----
* TRY TO FIND AN EXISTING IDATAP SET. OTHERWISE, CREATE A NEW ONE.
* STORE INFORMATION IN THE ADRX(NREA+3,IISO,NADRX+1) DATASET.
* NADRI IS THE TOTAL NUMBER OF TRANSPROFILE SETS.
*----
DO 780 IISO=1,NISO
IOI=ADRX(NREA+3,IISO,NADRX+1)
DO 770 IAD1X=0,NADRI-1
DO 760 I=1,2*NG+1
IF(IDATAP_MIL(IOI+I).NE.IDATAP(IAD1X*(2*NG+1)+I)) GO TO 770
760 CONTINUE
ADRX(NREA+3,IISO,NADRX+1)=IAD1X*(2*NG+1)
GO TO 780
770 CONTINUE
IF((NADRI+1)*(2*NG+1).GT.MAXIDA) THEN
CALL XABORT('MPOCA2: IDATAP OVERFLOW.')
ENDIF
DO I=1,2*NG+1
IDATAP(NADRI*(2*NG+1)+I)=IDATAP_MIL(IOI+I)
ENDDO
ADRX(NREA+3,IISO,NADRX+1)=NADRI*(2*NG+1)
NADRI=NADRI+1
780 CONTINUE
*----
* TRY TO FIND AN EXISTING ADRX SET. OTHERWISE, CREATE A NEW ONE.
* STORE INFORMATION IN THE output_id/statept_id/zone_id GROUP.
* "ADDRZI" is the index in ADDRISO[NADDRISO+1]-->ISOTOPE
* "ADDRZX" is the index in ADDRXS[NREA+3,NISO,NADRX+1]-->CROSSEXTION
*----
WRITE(RECNAM,'(8H/output/,A,9H/statept_,I0,6H/zone_,I0,1H/)')
1 TRIM(HEDIT),ICAL-1,IMIL-1
DO 810 IAD1X=1,NADRX
DO 800 I=1,NREA+3
DO 790 J=1,NISO
IF(ADRX(I,J,NADRX+1).NE.ADRX(I,J,IAD1X)) GO TO 810
790 CONTINUE
800 CONTINUE
CALL hdf5_write_data(IPMPO,TRIM(RECNAM)//"ADDRZX",IAD1X-1)
GO TO 820
810 CONTINUE
NADRX=NADRX+1
CALL hdf5_write_data(IPMPO,TRIM(RECNAM)//"ADDRZX",NADRX-1)
820 ADDRZI=0
CALL hdf5_write_data(IPMPO,TRIM(RECNAM)//"ADDRZI",ADDRZI)
*----
* STORE FLUX, CROSS SECTIONS AND NUMBER DENSITIES.
*----
WORK2(:)=FLXMIL(IMIL,:)
CALL hdf5_write_data(IPMPO,TRIM(RECNAM)//"ZONEFLUX",WORK2)
IF(IOR.GT.0) THEN
CALL hdf5_write_data(IPMPO,TRIM(RECNAM)//"CROSSECTION",
1 RDATAX(:IOR))
ENDIF
CALL hdf5_write_data(IPMPO,TRIM(RECNAM)//"CONCENTRATION",DENISO)
*----
* STORE INFORMATION IN THE output_id/statept_id/zone_id/leakage GROUP.
*----
IF(ILEAK.EQ.1) THEN
WRITE(RECNAM,'(8H/output/,A,9H/statept_,I0,6H/zone_,I0,
1 9H/leakage/)') TRIM(HEDIT),ICAL-1,IMIL-1
DO 830 IGR=1,NG
KPEDIT=LCMGIL(JPEDIT,IGR)
CALL LCMLEN(KPEDIT,'DIFF',ILONG,ITYLCM)
IF(ILONG.EQ.0) CALL XABORT('MPOCA2: MISSING DIFF INFO.')
CALL LCMGET(KPEDIT,'DIFF',WORK1)
WORK2(IGR)=WORK1(IMIL)
830 CONTINUE
CALL hdf5_create_group(IPMPO,TRIM(RECNAM))
CALL hdf5_write_data(IPMPO,TRIM(RECNAM)//"BUCKLING",B2)
CALL hdf5_write_data(IPMPO,TRIM(RECNAM)//"DIFFCOEF",WORK2)
WORK2(:)=WORK2(:)*B2
CALL hdf5_write_data(IPMPO,TRIM(RECNAM)//"DB2",WORK2)
ENDIF
*----
* STORE INFORMATION IN THE output_id/statept_id/zone_id/kinetics GROUP.
*----
IF(NPRC.GT.0) THEN
EXIST=.FALSE.
DO 850 IPRC=1,NPRC
DO 840 IGR=1,NG
EXIST=EXIST.OR.(DNUSIG(IGR,IPRC).NE.0.0)
840 CONTINUE
850 CONTINUE
WRITE(RECNAM,'(8H/output/,A,9H/statept_,I0,6H/zone_,I0,
1 10H/kinetics/)') TRIM(HEDIT),ICAL-1,IMIL-1
IF(EXIST) THEN
CALL LCMSIX(IPTEMP,'MACROLIB',1)
CALL LCMGET(IPTEMP,'LAMBDA-D',WORKD)
CALL LCMSIX(IPTEMP,' ',2)
CALL hdf5_create_group(IPMPO,TRIM(RECNAM))
CALL hdf5_write_data(IPMPO,TRIM(RECNAM)//"LAMBDAD",WORKD)
CALL hdf5_write_data(IPMPO,TRIM(RECNAM)//"CHID",DCHI)
CALL hdf5_write_data(IPMPO,TRIM(RECNAM)//"INVERSESPEED",
1 OVERV)
TGENRS=0.0
DENOM=0.0
DO 860 IGR=1,NG
TGENRS=TGENRS+OVERV(IGR)*FLXMIL(IMIL,IGR)
DENOM=DENOM+DNUSIG(IGR,NPRC+1)*FLXMIL(IMIL,IGR)
860 CONTINUE
TGENRS=TGENRS/DENOM
DO 880 IPRC=1,NPRC
WORKD(IPRC)=0.0
DO 870 IGR=1,NG
WORKD(IPRC)=WORKD(IPRC)+DNUSIG(IGR,IPRC)*FLXMIL(IMIL,IGR)
870 CONTINUE
WORKD(IPRC)=WORKD(IPRC)/DENOM
880 CONTINUE
CALL hdf5_write_data(IPMPO,TRIM(RECNAM)//"BETADF",WORKD)
CALL hdf5_write_data(IPMPO,TRIM(RECNAM)//"GENERATIONTIME",
1 TGENRS)
ENDIF
ENDIF
*----
* STORE INFORMATION IN THE output_id/statept_id/zone_id/yields GROUP.
*----
NISFS=0
NISPS=0
IF(NBISO.GT.0) THEN
DO 910 ISO=1,NISO-1
DO 890 IBISO=1,NBISO
WRITE(TEXT8,'(2A4)') (ISONAM(I0,IBISO),I0=1,2)
IF(NOMISO(ISO).EQ.TEXT8) THEN
ITY=ITYPE(IBISO)
GO TO 900
ENDIF
890 CONTINUE
GO TO 910
900 IF(ITY.EQ.2) THEN
NISFS=NISFS+1
ELSE IF(ITY.EQ.3) THEN
NISPS=NISPS+1
ENDIF
910 CONTINUE
NISFS=NISFS+1 ! declare the residual as fissile
WRITE(RECNAM,'(8H/output/,A,9H/statept_,I0,6H/zone_,I0,1H/)')
> TRIM(HEDIT),ICAL-1,IMIL-1
CALL hdf5_write_data(IPMPO,TRIM(RECNAM)//"yields/NISF",NISFS)
CALL hdf5_write_data(IPMPO,TRIM(RECNAM)//"yields/NISP",NISPS)
ENDIF
*----
* END OF LOOP OVER MPO MIXTURES.
*----
920 CONTINUE
DEALLOCATE(IPISO)
CALL LCMCL(IPTEMP,2)
*----
* STORE INFORMATION IN THE output_id/info GROUP.
*----
WRITE(RECNAM,'(8H/output/,A,6H/info/)') TRIM(HEDIT)
IF((ICAL.EQ.1).AND.(NADRI.GT.0)) THEN
CALL hdf5_write_data(IPMPO,TRIM(RECNAM)//"TRANSPROFILE",
1 IDATAP(:NADRI*(2*NG+1)))
ENDIF
CALL hdf5_write_data(IPMPO,TRIM(RECNAM)//"NADDRXS",NADRX)
CALL hdf5_write_data(IPMPO,TRIM(RECNAM)//"ADDRXS",
1 ADRX(:,:,:NADRX))
*----
* SCRATCH STORAGE DEALLOCATION
*----
DEALLOCATE(NOMISO,NOMREA)
DEALLOCATE(CONCES,DENISO,DEN,DATA4,DATA3,DATA2,DATA1,WORK2,WORK1,
1 WORKD,DCHI,DNUSIG,OVERV,RDATAX)
DEALLOCATE(IDATAP_MIL,IDEPL,ITYPE,MIX,ISONAM,NJJ2,IJJ2,IPOS,NJJ1,
1 IJJ1,IAD2,IFD2,IAD1,IFD1,IDATAP,ADRX)
RETURN
END
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