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|
*DECK MCCGT
SUBROUTINE MCCGT(NENTRY,HENTRY,IENTRY,JENTRY,KENTRY)
*
*-----------------------------------------------------------------------
*
*Purpose:
* Adapt EXCELL tracking to MCCG requirements.
*
*Copyright:
* Copyright (C) 2002 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 and R. Le Tellier
*
*Parameters: input/output
* NENTRY number of LCM objects or files used by the operator.
* HENTRY name of each LCM object or file:
* HENTRY(1) modification type(L_TRACK);
* HENTRY(2) sequential binary tracking file;
* HENTRY(3) read-only type(L_GEOM).
* IENTRY type of each LCM object or file:
* =1 LCM memory object; =2 XSM file; =3 sequential binary file;
* =4 sequential ascii file.
* JENTRY access of each LCM object or file:
* =0 the LCM object or file is created;
* =1 the LCM object or file is open for modifications;
* =2 the LCM object or file is open in read-only mode.
* KENTRY LCM object address or file unit number.
*
*-----------------------------------------------------------------------
*
USE GANLIB
IMPLICIT NONE
*----
* SUBROUTINE ARGUMENTS
*----
INTEGER NENTRY,IENTRY(NENTRY),JENTRY(NENTRY)
TYPE(C_PTR) KENTRY(NENTRY)
CHARACTER HENTRY(NENTRY)*12
*----
* LOCAL VARIABLES
*----
TYPE(C_PTR) IPTRK,IPGEO
INTEGER NSTATE,MXGAUS,IOUT,IBCV
PARAMETER (NSTATE=40,MXGAUS=64,IOUT=6,IBCV=-7)
INTEGER ITRK,IFTR,IGEO,IFTRAK,J,NCOMNT,NBTR,ICOM,
1 NDIM,ISPEC,N2REG,N2SOU,NALBG,NCOR,NANGL,MXSEG,NREG,NSOU,NANIS,
2 ISYMM,IMPX,LCACT,NMU,MAXI,IAAC,ISCR,KRYL,IDIFC,ILEXA,ILEXF,INDIC,
3 NITMA,NZP,N2RS,DIMKEYF,TYPOR1,TYPOR2,LTMT,STIS,LMXMCU,TRTY,PACA,
4 SSYM,H,IMU,NFI,LMCU,N3MAX,ILINE,IANGL,N2SEG,NSEG,LMCU0,NLONG,
5 LPS,NFIRST,NLEV,IK,JK,K,ILAST,IH,KJ,IPOS,IJEND,IJ,NFUNL,NUN,IA,
6 IR,IKEY,ICUR,NPJJM,IFORW,II,I,IBIHET,IQUA10,IR2,NREG2,IFMT,NSUB,
7 MXSUB,NMOD,NLIN,IE
INTEGER ISOU,IDIM,IDIR
REAL EPSI,HDD,TMUIM,FACSYM,DELU,FLOTT,DUM
DOUBLE PRECISION WEI2D,DFLOTT,CMU
CHARACTER TEXT4*4,TEXT12*12,TITLE*72,HSIGN*12,CFTRAK*12,
1 COMNT(10)*80
LOGICAL LPRISM,ACFLAG,LACA,LSCR,CYCLIC,LBIHET
INTEGER IGP(NSTATE),KTITL(18),NCODE(6),IGB(8)
REAL ZREAL(4),ZMU(MXGAUS),WZMU(MXGAUS),XMU(MXGAUS),ALBEDO(6),
1 EXTKOP(NSTATE),XMU0(2*MXGAUS),WZMU0(2*MXGAUS)
DOUBLE PRECISION CMUV(MXGAUS),CMUIV(MXGAUS),SMUV(MXGAUS),
1 SMUIV(MXGAUS),TMUV(MXGAUS),TMUIV(MXGAUS)
*----
* ALLOCATABLE STATEMENTS
*----
INTEGER, ALLOCATABLE, DIMENSION(:) :: INDREG,NZON,NZONA,ITEMP,
1 MCUW,MCUI,NRSEG,KANGL,INOM3D,KM,MCU,IM,IS,JS,IPI,INVPI,LEV,LEVPT,
2 KMROR,MCUROR,IMROR,JU,IWORK,IM0,MCU0,KEYFLX,KEYCUR,KEYANI,MAT
INTEGER, ALLOCATABLE, DIMENSION(:,:) :: ISGNR
REAL, ALLOCATABLE, DIMENSION(:) :: ZZ,VV,RTEMP,VA,VOL
DOUBLE PRECISION, ALLOCATABLE, DIMENSION(:) :: DENSTY,SEGLEN,T2D,
1 H3D,SURFD,VNUM
DOUBLE PRECISION, ALLOCATABLE, DIMENSION(:,:) :: CAZ,XSIXYZ
*----
* DATA STATEMENTS
*----
INTEGER FACMCU(3)
DATA FACMCU / 2,8,12 /
*----
* PARAMETER VALIDATION
*----
ITRK=0
IFTR=0
IGEO=0
IF(NENTRY.LE.1) CALL XABORT('MCCGT: two PARAMETERS EXPECTED.')
* tracking table in modification mode
IF((IENTRY(1).NE.1).AND.(IENTRY(1).NE.2))
1 CALL XABORT('MCCGT: LINKED LIST EXPECTED AT LHS.')
ITRK=1
IF(JENTRY(ITRK).NE.1)
1 CALL XABORT('MCCGT: ENTRY IN MODIFICATION MODE EXPECTED(1).')
IF(IENTRY(2).EQ.3) THEN
* tracking file in read-only mode
IFTR=2
IF(JENTRY(IFTR).NE.2)
1 CALL XABORT('MCCGT: ENTRY IN READ-ONLY MODE EXPECTED(1).')
ELSE
CALL XABORT('MCCGT: INVALID OR MISSING ENTRY(1)')
ENDIF
IF(NENTRY.GE.3) THEN
IF(IENTRY(3).LE.2) THEN
* geometry table in read-only mode
IGEO=3
IF (JENTRY(IGEO).NE.2)
1 CALL XABORT('MCCGT: ENTRY IN READ-ONLY MODE EXPECTED(2).')
ELSE
CALL XABORT('MCCGT: INVALID OR MISSING ENTRY(2)')
ENDIF
ENDIF
*
IPTRK=KENTRY(ITRK)
IFTRAK=FILUNIT(KENTRY(IFTR))
IF(IGEO.NE.0) THEN
IPGEO=KENTRY(IGEO)
ELSE
IPGEO=C_NULL_PTR
ENDIF
*
CALL LCMGTC(IPTRK,'SIGNATURE',12,HSIGN)
IF(HSIGN.NE.'L_TRACK') THEN
TEXT12=HENTRY(ITRK)
CALL XABORT('MCCGT: SIGNATURE OF '//TEXT12//' IS '//HSIGN//
1 '. L_TRACK EXPECTED.')
ENDIF
CALL LCMGTC(IPTRK,'TRACK-TYPE',12,HSIGN)
IF(HSIGN.NE.'EXCELL') THEN
TEXT12=HENTRY(ITRK)
CALL XABORT('MCCGT: SIGNATURE OF '//TEXT12//' IS '//HSIGN//
1 '. EXCELL EXPECTED.')
ENDIF
*----
* RECOVER GEOMETRY
*----
IF(C_ASSOCIATED(IPGEO)) THEN
CALL LCMGTC(IPGEO,'SIGNATURE',12,HSIGN)
IF(HSIGN.NE.'L_GEOM') THEN
TEXT12=HENTRY(IGEO)
CALL XABORT('MCCGT: SIGNATURE OF '//TEXT12//' IS '//HSIGN//
1 '. L_GEOM EXPECTED.')
ENDIF
TEXT12=HENTRY(IGEO)
CALL LCMPTC(IPTRK,'LINK.GEOM',12,TEXT12)
ENDIF
*----
* RECOVER SEQUENTIAL BINARY TRACKING FILE CHARACTERISTICS
*----
CFTRAK=HENTRY(IFTR)
CALL LCMPTC(IPTRK,'LINK.FTRACK',12,CFTRAK)
REWIND IFTRAK
READ(IFTRAK) TEXT4,NCOMNT,NBTR,IFMT
DO ICOM=1,NCOMNT
READ(IFTRAK) COMNT(ICOM)
ENDDO
READ(IFTRAK) NDIM,ISPEC,N2REG,N2SOU,NALBG,NCOR,NANGL,MXSUB,MXSEG
IF((NDIM.NE.2).AND.(NDIM.NE.3))
1 CALL XABORT('2D OR 3D EXCELT TRACKING EXPECTED')
*----
* RECOVER TRACKING STATE-VECTOR AND USER INPUT INFORMATION
*----
IGP(:NSTATE)=0
CALL LCMGET(IPTRK,'STATE-VECTOR',IGP)
IF(IGP(7).EQ.5) CALL XABORT('MCCGT: THE SHORT CHARACTERISTICS M'
1 //'ETHOD IS NOT IMPLEMENTED. USE NOIC OPTION IN SALT:.')
NREG=IGP(1)
NSOU=IGP(5)
NANIS=IGP(6)
TRTY=IGP(9)
CYCLIC=(TRTY.EQ.1)
ISYMM=IGP(12)
CALL LCMGET(IPTRK,'ALBEDO',ALBEDO)
*
IMPX=1
LCACT=IGP(13)
NMU=IGP(14)
LBIHET=(IGP(40).NE.0)
MAXI=20
IAAC=1
ISCR=0
KRYL=10
IDIFC=0
EPSI=1.0E-5
HDD=0.0
PACA=3
ILEXA=0
LTMT=0
ILEXF=0
STIS=0
LMXMCU=0
IFORW=0
NFUNL=1
NLIN=1
DELU=0.0
FACSYM=0.0
IF(NANIS.LE.4) STIS=1
*----
* PROCESS DOUBLE HETEROGENEITY (BIHET) DATA (IF AVAILABLE)
*----
IF(LBIHET) THEN
IF(.NOT.C_ASSOCIATED(IPGEO)) CALL XABORT('MCCGT: NO RHS GEOME'
> //'TRY DEFINED.')
CALL LCMSIX(IPTRK,'BIHET',1)
CALL LCMGET(IPTRK,'PARAM',IGB)
IR2=IGB(2)
NREG2=IGB(3)
IBIHET=IGB(6)
IQUA10=IGB(8)
ALLOCATE(MAT(NREG),VOL(NREG))
CALL LCMGET(IPTRK,'IBI',MAT)
CALL LCMGET(IPTRK,'VOLUME',VOL)
CALL LCMSIX(IPTRK,' ',2)
CALL LCMPUT(IPTRK,'MATCOD',NREG,1,MAT)
CALL LCMPUT(IPTRK,'VOLUME',NREG,2,VOL)
DEALLOCATE(VOL,MAT)
IGP(1)=NREG2
IGP(2)=IGP(2)-(NREG-NREG2)
IGP(4)=IR2
CALL LCMPUT(IPTRK,'STATE-VECTOR',NSTATE,1,IGP)
NREG=NREG2
ENDIF
*
10 CALL REDGET(INDIC,NITMA,FLOTT,TEXT4,DFLOTT)
20 IF(INDIC.EQ.10) GO TO 30
IF(INDIC.NE.3) CALL XABORT('MCCGT: CHARACTER DATA EXPECTED(1).')
IF(TEXT4.EQ.'EDIT') THEN
CALL REDGET(INDIC,IMPX,FLOTT,TEXT4,DFLOTT)
IF(INDIC.NE.1) CALL XABORT('MCCGT: INTEGER DATA EXPECTED(1).')
ELSE IF(TEXT4.EQ.'GAUS') THEN
LCACT=-1
CALL REDGET(INDIC,NITMA,FLOTT,TEXT4,DFLOTT)
IF(INDIC.NE.1) GO TO 20
NMU=NITMA
ELSE IF(TEXT4.EQ.'DGAU') THEN
LCACT=0
CALL REDGET(INDIC,NITMA,FLOTT,TEXT4,DFLOTT)
IF(INDIC.NE.1) GO TO 20
NMU=NITMA
ELSE IF(TEXT4.EQ.'CACA') THEN
LCACT=1
CALL REDGET(INDIC,NITMA,FLOTT,TEXT4,DFLOTT)
IF(INDIC.NE.1) GO TO 20
NMU=NITMA
ELSE IF(TEXT4.EQ.'CACB') THEN
LCACT=2
CALL REDGET(INDIC,NITMA,FLOTT,TEXT4,DFLOTT)
IF(INDIC.NE.1) GO TO 20
NMU=NITMA
ELSE IF(TEXT4.EQ.'LCMD') THEN
LCACT=3
CALL REDGET(INDIC,NITMA,FLOTT,TEXT4,DFLOTT)
IF(INDIC.NE.1) GO TO 20
NMU=NITMA
ELSE IF(TEXT4.EQ.'OPP1') THEN
LCACT=4
CALL REDGET(INDIC,NITMA,FLOTT,TEXT4,DFLOTT)
IF(INDIC.NE.1) GO TO 20
NMU=NITMA
ELSE IF(TEXT4.EQ.'OGAU') THEN
LCACT=5
CALL REDGET(INDIC,NITMA,FLOTT,TEXT4,DFLOTT)
IF(INDIC.NE.1) GO TO 20
NMU=NITMA
ELSE IF(TEXT4.EQ.'EPSI') THEN
* CONVERGENCE CRITERION FOR INNER ITERATIONS.
CALL REDGET(INDIC,NITMA,EPSI,TEXT4,DFLOTT)
IF(INDIC.NE.2) CALL XABORT('MCCGT: REAL DATA EXPECTED(1).')
ELSE IF(TEXT4.EQ.'SCR') THEN
* SCR ACCELERATION FLAG.
CALL REDGET(INDIC,ISCR,FLOTT,TEXT4,DFLOTT)
IF(INDIC.NE.1) CALL XABORT('MCCGT: INTEGER DATA EXPECTED(2).')
ELSE IF(TEXT4.EQ.'KRYL') THEN
* GMRES FLAG.
CALL REDGET(INDIC,KRYL,FLOTT,TEXT4,DFLOTT)
IF(INDIC.NE.1) CALL XABORT('MCCGT: INTEGER DATA EXPECTED(3).')
ELSE IF(TEXT4.EQ.'AAC') THEN
* ACA ACCELERATION FLAG.
CALL REDGET(INDIC,IAAC,FLOTT,TEXT4,DFLOTT)
IF(INDIC.NE.1) CALL XABORT('MCCGT: INTEGER DATA EXPECTED(4).')
ELSE IF(TEXT4.EQ.'BICG') THEN
* ACA SYSTEM RESOLUTION TYPE (obsolete because it is the only option!)
IF(IAAC.EQ.0) CALL XABORT('MCCGT: BICG ONLY IF ACA IS ON.')
ELSE IF(TEXT4.EQ.'ILU0') THEN
* ILU0 PRECONDITIONER FOR SOLVING ACA SYSTEM
PACA=3
IF(IAAC.EQ.0) CALL XABORT('MCCGT: ILU0 ONLY IF ACA IS ON.')
ELSE IF(TEXT4.EQ.'DIAG') THEN
* DIAGONAL PRECONDITIONER FOR SOLVING ACA SYSTEM
PACA=1
IF(IAAC.EQ.0) CALL XABORT('MCCGT: DIAG ONLY IF ACA IS ON.')
ELSE IF(TEXT4.EQ.'FULL') THEN
* FULL MATRIX PRECONDITIONER FOR SOLVING ACA SYSTEM
PACA=2
IF(IAAC.EQ.0) CALL XABORT('MCCGT: FULL ONLY IF ACA IS ON.')
ELSE IF(TEXT4.EQ.'NONE') THEN
* NO PRECONDITIONER FOR SOLVING ACA SYSTEM
PACA=0
IF(IAAC.EQ.0) CALL XABORT('MCCGT: NONE ONLY IF ACA IS ON.')
ELSE IF(TEXT4.EQ.'TMT') THEN
* TO USE A TRACK MERGING TECHNIQUE IN ACA CALCULATION
LTMT=1
IF(IAAC.EQ.0) CALL XABORT('MCCGT: LTMT ONLY IF ACA IS ON.')
ELSE IF(TEXT4.EQ.'LEXA') THEN
* TO FORCE EXACT EXPONENTIALS IN PRECONDITIONER CALCULATIONS
ILEXA=1
ELSE IF(TEXT4.EQ.'DIFC') THEN
* TRANSPORT/DIFFUSION SOLUTION FLAG.
IDIFC=1
IAAC=1
ELSE IF(TEXT4.EQ.'MCU') THEN
* MAXIMUM DIMENSION OF MCU FOR MEMORY ALLOCATION.
CALL REDGET(INDIC,LMXMCU,FLOTT,TEXT4,DFLOTT)
IF(INDIC.NE.1) CALL XABORT('MCCGT: INTEGER DATA EXPECTED(5).')
ELSE IF(TEXT4.EQ.'HDD') THEN
* SELECTION OD STEP CHARACTERISTICS METHOD.
CALL REDGET(INDIC,NITMA,HDD,TEXT4,DFLOTT)
IF(INDIC.NE.2) CALL XABORT('MCCGT: REAL DATA EXPECTED(2).')
ELSE IF(TEXT4.EQ.'STIS') THEN
* 'SOURCE TERM ISOLATION' FLAG
CALL REDGET(INDIC,STIS,FLOTT,TEXT4,DFLOTT)
IF(INDIC.NE.1) CALL XABORT('MCCGT: INTEGER DATA EXPECTED(6).')
IF(ABS(STIS).GT.1) THEN
CALL XABORT('MCCGT: STIS MUST BE SET TO -1, 0 OR 1.')
ENDIF
ELSE IF(TEXT4.EQ.'LEXF') THEN
* TO FORCE EXACT EXPONENTIALS IN FLUX CALCULATIONS
ILEXF=1
ELSE IF(TEXT4.EQ.'ADJ') THEN
* ADJOINT FLUX CALCULATION
IFORW=1
ELSE IF(TEXT4.EQ.'MAXI') THEN
* MAXIMUM NUMBER OF INNER ITERATIONS.
CALL REDGET(INDIC,MAXI,FLOTT,TEXT4,DFLOTT)
IF(INDIC.NE.1) CALL XABORT('MCCGT: INTEGER DATA EXPECTED(7).')
ELSE IF(TEXT4.EQ.'SC') THEN
* STEP CHARACTERISTICS OR DD0 SCHEME.
NLIN=1
ELSE IF(TEXT4.EQ.'LDC') THEN
* LINEAR DISCONTINUOUS CHARACTERISTICS OR DD1 SCHEME.
NLIN=3
STIS=0
ELSE IF(TEXT4.EQ.';') THEN
GO TO 30
ELSE
CALL XABORT('MCCGT: '//TEXT4//' IS AN INVALID KEY WORD.')
ENDIF
GO TO 10
*
30 IF(NMU.EQ.0) THEN
IF(ISPEC.EQ.0) THEN
IF(ISYMM.LE.1) THEN
NMU=(NANGL+1)/2
ELSE IF(ISYMM.GE.2) THEN
NMU=NANGL
ENDIF
ELSE IF(ISPEC.EQ.1) THEN
IF(ISYMM.LE.1) THEN
NMU=(NANGL/4+1)/2
ELSE IF(ISYMM.GE.2) THEN
NMU=NANGL/4
ENDIF
ENDIF
ENDIF
IGP(13)=LCACT
LACA=(IAAC.GT.0)
LSCR=((ISCR.GT.0).AND.(.NOT.CYCLIC))
ZREAL(1)=EPSI
ZREAL(2)=HDD
ACFLAG=((LSCR).OR.(LACA))
NZP=IGP(39)
LPRISM=(NZP.NE.0)
IF(LPRISM) THEN
* 3D PRISMATIC GEOMETRY
CALL LCMGET(IPTRK,'NCODE',NCODE)
IF(NCODE(6).EQ.30) THEN
IF(NCODE(5).EQ.30) THEN
* Z- and Z+ surfaces symmetry
SSYM=2
FACSYM=0.0
ELSE
* Z+ symmetry
SSYM=1
FACSYM=1.0
ENDIF
ELSE
SSYM=0
FACSYM=0.0
ENDIF
N2RS=N2SOU+N2REG+1
ALLOCATE(ZZ(NZP+1),INDREG(N2RS*(NZP+2)))
CALL LCMSIX(IPTRK,'PROJECTION',1)
CALL LCMGET(IPTRK,'IND2T3',INDREG)
CALL LCMGET(IPTRK,'ZCOORD',ZZ)
CALL LCMSIX(IPTRK,'PROJECTION',2)
CALL LCMGET(IPTRK,'EXCELTRACKOP',EXTKOP)
DELU=EXTKOP(40)
ZREAL(3)=DELU
ELSE
ZREAL(3)=0.0
ENDIF
*
IF(IMPX.GT.1) THEN
CALL LCMGET(IPTRK,'TITLE',KTITL)
WRITE(TITLE,'(3A4)') (KTITL(J),J=1,3)
WRITE(IOUT,100) TITLE
IF(LPRISM) WRITE(IOUT,*) '3D PRISMATIC EXTENDED TRACKING'
ENDIF
*---
* CALCULATE POLAR QUADRATURE IF REQUIRED
*---
TMUIM=0.0
IF(NDIM.EQ.2) THEN
IF(LCACT.EQ.-1) THEN
CALL ALGPT ( 2*NMU, -1.0, 1.0, XMU0(1), WZMU0(1))
DO IMU=1,NMU
XMU(NMU-IMU+1)=XMU0(IMU)
WZMU(NMU-IMU+1)=WZMU0(IMU)
ENDDO
ELSE IF(LCACT.EQ.0) THEN
CALL ALGPT ( NMU, 0.0, 1.0, XMU(1), WZMU(1))
ELSE
IF(LCACT.GE.3) THEN
IF(NMU.GT.4) NMU=4
IF(NMU.LT.2) NMU=2
ENDIF
CALL ALCACT( LCACT, NMU, XMU, WZMU)
ENDIF
IF(LPRISM) THEN
DO IMU=1,NMU
ZMU(IMU)=1.0
WZMU(IMU)=0.5*WZMU(IMU)
CMU=DBLE(XMU(IMU))
CMUV(IMU)=CMU
CMUIV(IMU)=1.D0/CMU
SMUV(IMU)=SQRT(1.D0-CMU**2)
SMUIV(IMU)=1.D0/SMUV(IMU)
TMUV(IMU)=SMUV(IMU)/CMU
TMUIV(IMU)=1.D0/TMUV(IMU)
TMUIM=MAX(REAL(TMUIM),REAL(TMUIV(IMU)))
ENDDO
ELSE
DO IMU=1,NMU
DUM=SQRT(1.-XMU(IMU)*XMU(IMU))
ZMU(IMU)=1./DUM
WZMU(IMU)=WZMU(IMU)*DUM
ENDDO
ENDIF
IF(IMPX.GT.3) THEN
CALL PRINAM('XMU ',XMU(1),NMU)
CALL PRINAM('ZMU ',ZMU(1),NMU)
CALL PRINAM('WZMU ',WZMU(1),NMU)
ENDIF
ELSE ! NDIM.EQ.3
NMU=1
WZMU(1)=1.0
XMU(1)=0.0
ZMU(1)=1.0
ENDIF
IF(LPRISM) THEN
CALL LCMSIX(IPTRK,'PROJECTION',1)
CALL LCMPUT(IPTRK,'CMU',NMU,4,CMUV)
CALL LCMPUT(IPTRK,'CMUI',NMU,4,CMUIV)
CALL LCMPUT(IPTRK,'SMU',NMU,4,SMUV)
CALL LCMPUT(IPTRK,'SMUI',NMU,4,SMUIV)
CALL LCMPUT(IPTRK,'TMU',NMU,4,TMUV)
CALL LCMPUT(IPTRK,'TMUI',NMU,4,TMUIV)
CALL LCMSIX(IPTRK,'PROJECTION',2)
ENDIF
CALL LCMPUT(IPTRK,'ZMU$MCCG',NMU,2,ZMU)
CALL LCMPUT(IPTRK,'XMU$MCCG',NMU,2,XMU)
CALL LCMPUT(IPTRK,'WZMU$MCCG',NMU,2,WZMU)
NFI=NREG+NSOU
ALLOCATE(VV(NFI+1),NZON(NFI+1),ITEMP(NSOU),RTEMP(NSOU))
IF(ACFLAG) ALLOCATE(NZONA(NFI+1))
*---
* RECOVER VOLUME AND MATALB ARRAYS
*---
IF(LPRISM) THEN
* 3D PRISMATIC GEOMETRY
READ(IFTRAK)
READ(IFTRAK)
CALL LCMSIX(IPTRK,'PROJECTION',1)
CALL LCMGET(IPTRK,'VOLSUR',VV)
CALL LCMGET(IPTRK,'MATALB',NZON)
CALL LCMSIX(IPTRK,'PROJECTION',2)
ELSE
* REGULAR 2D OR 3D GEOMETRY
READ(IFTRAK) (VV(NSOU+II+1),II=-NSOU,NREG)
READ(IFTRAK) (NZON(NSOU+II+1),II=-NSOU,NREG)
ENDIF
*---
* REORDER VOLUME AND MATALB ARRAYS (SURFACE -j BECOMES NV+j)
* [S(-NS) S(-NS+1) ... S(-1) 0 V(1) ... V(NV-1) V(NV)]
* ->[V(1)... V(NV-1) V(NV) S(-1) ... S(-NS+1) S(-NS)]
*---
DO I=1,NSOU
ITEMP(I)=NZON(NSOU-I+1)
RTEMP(I)=VV(NSOU-I+1)
ENDDO
DO I=1,NREG
VV(I)=VV(NSOU+I+1)
NZON(I)=NZON(NSOU+I+1)
IF(ACFLAG) NZONA(I)=NZON(I)
ENDDO
DO I=1,NSOU
NZON(NREG+I)=ITEMP(I)
IF(ACFLAG) THEN
IF(ALBEDO(-ITEMP(I)).GT.0.0) THEN
NZONA(NREG+I)=ITEMP(I)
ELSE
NZONA(NREG+I)=IBCV
ENDIF
ENDIF
VV(NREG+I)=RTEMP(I)
ENDDO
DEALLOCATE(RTEMP,ITEMP)
*
ALLOCATE(DENSTY(NANGL),CAZ(NDIM,NANGL))
READ(IFTRAK)
READ(IFTRAK)
READ(IFTRAK) ((CAZ(IDIM,II),IDIM=1,NDIM),II=1,NANGL)
READ(IFTRAK) (DENSTY(II),II=1,NANGL)
IF(LPRISM) NDIM=3
*---
* CALCULATE NUMERICAL SURFACES FOR NON CYCLIC TRACKING
* IF AAC OR SCR USED, CALCULATE CONNECTION MATRICES
*---
IF(ACFLAG) THEN
IF(LMXMCU.EQ.0) LMXMCU=FACMCU(NDIM)*NFI
ALLOCATE(MCUW(LMXMCU),MCUI(LMXMCU))
MCUW(:LMXMCU)=0
MCUI(:LMXMCU)=0
ENDIF
ALLOCATE(SEGLEN(MXSEG),NRSEG(MXSEG),KANGL(MXSUB))
ALLOCATE(SURFD(NSOU),XSIXYZ(NSOU,3))
SURFD(:NSOU)=0.0D0
XSIXYZ(:NSOU,:3)=0.0D0
LMCU=NFI
IF(LPRISM) THEN
* 3D PRISMATIC GEOMETRY: 3D TRACKS ARE RECONSTRUCTED
ALLOCATE(VNUM(2*NREG*NMU*NANGL))
VNUM(:2*NREG*NMU*NANGL)=0.0D0
ALLOCATE(T2D(MXSEG))
N3MAX=(INT(FACSYM)+1)*MXSEG*(NZP+2)
IF(SSYM.LT.2) THEN
ALLOCATE(INOM3D(N3MAX),H3D(N3MAX))
ELSE
TMUIM=TMUIM/ZZ(NZP+1)
ENDIF
DO ILINE=1,NBTR
READ(IFTRAK) NSUB,N2SEG,WEI2D,(KANGL(II),II=1,NSUB),
1 (NRSEG(II),II=1,N2SEG),(SEGLEN(II),II=1,N2SEG)
IF(NSUB.GT.MXSUB) CALL XABORT('MCCGT: MXSUB OVERFLOW.')
IANGL=KANGL(1)
IF(N2SEG.GT.0) THEN
T2D(1)=0.0D0
DO II=1,N2SEG-1
T2D(II+1)=T2D(II)+SEGLEN(II+1)
ENDDO
IF(SSYM.EQ.2) THEN
FACSYM=MAX(TMUIM*REAL(T2D(N2SEG)),FACSYM)
ALLOCATE(INOM3D((INT(FACSYM)+1)*N3MAX),
1 H3D((INT(FACSYM)+1)*N3MAX))
ENDIF
!!!! IF(N2SEG-2.GE.3) then
!!!! do IZP=0,NZP
!!!! IF(IZP.lt.NZP) write(8,900) T2D,T2D,
!!!! 1 ZZ(IZP+1),ZZ(IZP+2)
!!!! do II=1,N2SEG-2
!!!! write(8,900) T2D(II),T2D(II+1),
!!!! 1 ZZ(IZP+1),ZZ(IZP+1)
!!!! IF(IZP.lt.NZP) write(8,900) T2D(II+1),T2D(II+1)
!!!! 1 ,ZZ(IZP+1),ZZ(IZP+2)
!!!! enddo
!!!! enddo
!!!! 900 FORMAT(
!!!! 1 7H line([,E16.8,1H,,E16.8,3H],[,E16.8,1H,,E16.8,2H],,
!!!! 2 26H 'Color','r','Marker','o')/)
CALL MCGPTV(N2SOU,N2REG,NZP,SSYM,NREG,NSOU,N2SEG,N2SEG-2,
1 NANGL,NMU,LMCU,LMXMCU,IANGL,INDREG,NRSEG,MCUW,MCUI,ZZ,
2 T2D,WEI2D,CMUV,CMUIV,SMUV,SMUIV,TMUV,TMUIV,WZMU,DELU,
3 INOM3D,H3D,SURFD,VNUM,ACFLAG)
!!!! endif
IF(SSYM.EQ.2) DEALLOCATE(H3D,INOM3D)
ENDIF
ENDDO
IF(SSYM.LT.2) DEALLOCATE(H3D,INOM3D)
DEALLOCATE(T2D)
CALL MCGPTN(IMPX,NREG,NSOU,NANGL,NMU,VV,VNUM,SURFD,DENSTY,WZMU)
IF(IMPX.GT.4) CALL PRINDM('VNORF',VNUM,2*NREG*NANGL*NMU)
CALL LCMSIX(IPTRK,'PROJECTION',1)
CALL LCMPUT(IPTRK,'VNORF',2*NREG*NANGL*NMU,4,VNUM)
CALL LCMSIX(IPTRK,'PROJECTION',2)
DEALLOCATE(VNUM)
ELSE
* REGULAR 2D OR 3D GEOMETRY
DO ILINE=1,NBTR
READ(IFTRAK) NSUB,NSEG,WEI2D,(KANGL(II),II=1,NSUB),
1 (NRSEG(II),II=1,NSEG),(SEGLEN(II),II=1,NSEG)
IF(NSUB.GT.MXSUB) CALL XABORT('MCCGT: MXSUB OVERFLOW.')
IANGL=KANGL(1)
IF(NSEG.GT.0) THEN
CALL MCGDTV(NDIM,NFI,NREG,NSOU,NSEG,NMU,LMCU,LMXMCU,
1 NZONA,NRSEG,MCUW,MCUI,WEI2D,SEGLEN,WZMU,SURFD,
2 CYCLIC,ACFLAG,ZMU,XSIXYZ,CAZ(1,IANGL))
ENDIF
ENDDO
IF(.NOT.CYCLIC) THEN
CALL XDRSDB(NSOU,VV(NREG+1),SURFD,1)
DO IDIR=1,3
DO ISOU=1,NSOU
XSIXYZ(ISOU,IDIR)=XSIXYZ(ISOU,IDIR)/SURFD(ISOU)
ENDDO
ENDDO
CALL LCMPUT(IPTRK,'XSI$MCCG',NSOU*3,4,XSIXYZ)
ENDIF
ENDIF
*
DEALLOCATE(XSIXYZ,SURFD)
DEALLOCATE(KANGL,NRSEG,SEGLEN,CAZ,DENSTY)
IF(LPRISM) DEALLOCATE(INDREG,ZZ)
*---
* CREATE CONNECTION MATRICES IN KM/MCU FORMAT
*---
LMCU0=0
IF(ACFLAG) THEN
* KM(i) is the number of non-diagonal element on row i
* MCU gives the column indexes.
ALLOCATE(KM(NFI),MCU(LMXMCU))
CALL MCGREC(NFI,KM,MCUW,MCUI,MCU,LMCU,LMXMCU,0)
DEALLOCATE(MCUI,MCUW)
NLONG=NFI
IF(CYCLIC) THEN
* if cyclic tracking, only the volume related data are stored
LMCU=0
DO I=1,NREG
LMCU=LMCU+KM(I)
ENDDO
NLONG=NREG
IF(NSOU.EQ.0) NFI=NREG+1
ENDIF
ALLOCATE(IM(NLONG+1))
* construct IM
* containing number of sparse matrix elements in rows before I
* so location of J-th non-zero in row # I is IM(I)+J i.e.
* IM(K+1)=sum_i=1^K KM(i) where K in [1,NLONG]
IM(:)=0
DO I=1,NLONG
IM(I+1)=IM(I)+KM(I)
ENDDO
IF(LSCR) THEN
*---
* SCR ACCELERATION : CREATE INDEX FOR THE SURFACES NEIGHBORS
*---
LPS=IM(NFI+1)-IM(NREG+1)
ALLOCATE(IS(NSOU+1),JS(LPS))
LPS=0
DO I=NREG+1,NFI
IS(I-NREG)=LPS
DO J=IM(I)+1,IM(I+1)
IF(MCU(J).GT.0) THEN
LPS=LPS+1
JS(LPS)=MCU(J)
ENDIF
ENDDO
ENDDO
IS(NSOU+1)=LPS
ENDIF
IF(LACA) THEN
*---
* ACA ACCELERATION :
*---
ALLOCATE(IPI(NFI),INVPI(NFI))
IF(PACA.GE.2) THEN
LMCU0=LMCU
ALLOCATE(LEV(NLONG),LEVPT(NLONG+1),KMROR(NLONG),
1 MCUROR(LMCU),IMROR(NLONG+1),JU(NLONG),VA(NFI))
IF(PACA.EQ.3) ALLOCATE(IWORK(NFI),IM0(NFI+1),MCU0(LMCU0))
* construct IPI permutation : old_index=IPI(new_index) or
* F_new=F_old(IPI) reordering of the unknowns of the
* corrective system for ilu0 preconditioner.
NFIRST=1
TYPOR1=0
TYPOR2=0
CALL RENUM(NLONG,LMCU,NFIRST,IM,MCU,TYPOR1,TYPOR2,NLEV,
1 LEV,LEVPT,IPI)
IF(CYCLIC) THEN
DO I=NLONG+1,NFI
IPI(I)=I
ENDDO
ENDIF
* reorder everything according to IPI
* construct INVPI permutation : new_index=INVPI(old_index)
* or F_old=F_new(INVPI)
DO I=1,NFI
J=IPI(I)
INVPI(J)=I
ENDDO
DO I=1,NLONG
J=IPI(I)
KMROR(I)=KM(J)
ENDDO
IMROR=0
DO I=1,NLONG
IMROR(I+1)=IMROR(I)+KMROR(I)
ENDDO
DO I=1,NLONG
J=IPI(I)
IK=IMROR(I)
DO JK=IM(J)+1,IM(J+1)
IK=IK+1
IF(MCU(JK).GT.0) THEN
MCUROR(IK)=INVPI(MCU(JK))
ELSE
MCUROR(IK)=MCU(JK)
ENDIF
ENDDO
ENDDO
* sort each line by increasing column index
DO I=1,NLONG
K=IMROR(I)+1
CALL SORTIN(KMROR(I),MCUROR(K))
ENDDO
DO I=1,NFI
J=IPI(I)
NZONA(I)=NZON(J)
VA(I)=VV(J)
IF(J.GT.NREG) THEN
IF(ALBEDO(-NZON(J)).EQ.0.0) NZONA(I)=IBCV
ENDIF
ENDDO
JU(:NLONG)=0
IF(PACA.EQ.3) THEN
IM0(:NLONG+1)=LMCU
IWORK(:NLONG)=0
ILAST=0
LMCU0=0
ENDIF
DO 50 I=1,NLONG
* construct JU (and IM0/MCU0 for optimized storage)
* MCUROR(JU(i):IMROR(i+1)) corresponds to the upper triangular part of line i.
* MCUROR(IMROR(i)+1:JU(i)-1) correspond to the lower triangular part of line i.
DO IH=IMROR(I)+1,IMROR(I+1)
H=MCUROR(IH)
IF(H.GT.0) THEN
IF((H.GT.I).AND.(JU(I).EQ.0)) JU(I)=IH
IF(PACA.EQ.3) IWORK(H)=IH
ENDIF
ENDDO
IF(JU(I).EQ.0) JU(I)=IMROR(I+1)+1
IF(PACA.EQ.3) THEN
DO IK=IMROR(I)+1,JU(I)-1
K=MCUROR(IK)
IF(K.GT.0) THEN
DO KJ=JU(K),IMROR(K+1)
J=MCUROR(KJ)
IF(IWORK(J).GT.0) THEN
IPOS=0
IJEND=MIN(IM0(I+1),LMCU0)
DO IJ=IM0(I)+1,IJEND
IF(MCU0(IJ).EQ.J) THEN
IPOS=IJ
GOTO 40
ENDIF
ENDDO
40 CONTINUE
IF(IPOS.EQ.0) THEN
IF(ILAST.NE.I) THEN
IM0(ILAST+1:I)=LMCU0
ILAST=I
ENDIF
LMCU0=LMCU0+1
MCU0(LMCU0)=J
ENDIF
ENDIF
ENDDO
ENDIF
ENDDO
DO IH=IMROR(I)+1,IMROR(I+1)
H=MCUROR(IH)
IF(H.GT.0) IWORK(H)=0
ENDDO
ENDIF
50 CONTINUE
IF(PACA.EQ.3) THEN
IF(LMCU0.EQ.0) THEN
PACA=4 ! SPECIAL CASE WHEN THERE IS NO EXTRA-STORAGE FOR ILU0-ACA
ELSE
IM0(ILAST+1:NLONG+1)=LMCU0
ENDIF
ENDIF
ELSE
DO I=1,NFI
IPI(I)=I
INVPI(I)=I
ENDDO
ENDIF
ENDIF
ENDIF
IF(CYCLIC.AND.(NSOU.EQ.0)) THEN
NZON(NREG+1)=-1
NZONA(NREG+1)=-1
ENDIF
IF(IMPX.GT.3) THEN
CALL PRINIM('MATALB',NZON(1),NFI)
CALL PRINAM('VOLSUR',VV(1),NFI)
IF(ACFLAG) THEN
CALL PRINIM('MATALA',NZONA(1),NFI)
WRITE(IOUT,'(16H MCGREC : LMCU =,I6)') LMCU
CALL PRINIM('KM ',KM(1),NLONG)
CALL PRINIM('MCU ',MCU(1),LMCU)
IF((LACA).AND.(PACA.GE.2)) THEN
CALL PRINIM('IPERM ',INVPI(1),NFI)
CALL PRINIM('KMROR ',KMROR(1),NLONG)
CALL PRINIM('MCUROR',MCUROR(1),LMCU)
CALL PRINIM('JU ',JU(1),NLONG)
IF(PACA.GE.3) THEN
WRITE(IOUT,'(16H MCCGT : LMCU0 =,I6)') LMCU0
IF(LMCU0.GT.0) THEN
CALL PRINIM('IM0 ',IM0(1),NLONG+1)
CALL PRINIM('MCU0 ',MCU0(1),LMCU0)
ENDIF
ENDIF
ENDIF
IF(LSCR) THEN
CALL PRINIM('IS ',IS(1),NSOU+1)
CALL PRINIM('JS ',JS(1),LPS)
ENDIF
ENDIF
ENDIF
*
CALL LCMPUT(IPTRK,'NZON$MCCG',NFI,1,NZON)
CALL LCMPUT(IPTRK,'MATCOD',NREG,1,NZON)
CALL LCMPUT(IPTRK,'V$MCCG',NFI,2,VV)
CALL LCMPUT(IPTRK,'VOLUME',NREG,2,VV)
IF(ACFLAG) THEN
IF(LACA) THEN
CALL LCMPUT(IPTRK,'NZONA$MCCG',NFI,1,NZONA)
IF(PACA.GE.2) THEN
CALL LCMPUT(IPTRK,'VA$MCCG',NFI,2,VA)
CALL LCMPUT(IPTRK,'KM$MCCG',NLONG,1,KMROR)
CALL LCMPUT(IPTRK,'IM$MCCG',NLONG+1,1,IMROR)
CALL LCMPUT(IPTRK,'MCU$MCCG',LMCU,1,MCUROR)
CALL LCMPUT(IPTRK,'JU$MCCG',NLONG,1,JU)
IF(PACA.EQ.3) THEN
CALL LCMPUT(IPTRK,'IM0$MCCG',NLONG+1,1,IM0)
CALL LCMPUT(IPTRK,'MCU0$MCCG',LMCU0,1,MCU0)
ENDIF
IF(PACA.GE.3) DEALLOCATE(MCU0,IM0,IWORK)
DEALLOCATE(VA,JU,IMROR,MCUROR,KMROR,LEVPT,LEV)
ELSE
CALL LCMPUT(IPTRK,'KM$MCCG',NLONG,1,KM)
CALL LCMPUT(IPTRK,'IM$MCCG',NLONG+1,1,IM)
CALL LCMPUT(IPTRK,'MCU$MCCG',LMCU,1,MCU)
CALL LCMPUT(IPTRK,'VA$MCCG',NLONG,2,VV)
ENDIF
CALL LCMPUT(IPTRK,'INVPI$MCCG',NFI,1,INVPI)
CALL LCMPUT(IPTRK,'PI$MCCG',NLONG,1,IPI)
DEALLOCATE(INVPI,IPI)
ENDIF
IF(LSCR) THEN
CALL LCMPUT(IPTRK,'IS$MCCG',NSOU+1,1,IS)
CALL LCMPUT(IPTRK,'JS$MCCG',LPS,1,JS)
DEALLOCATE(JS,IS)
ENDIF
DEALLOCATE(IM,MCU,KM,NZONA)
ENDIF
DEALLOCATE(NZON,VV)
IF(.NOT.LACA) LMCU=0
IF(.NOT.LSCR) LPS=0
*---
* MODIFY KEYFLX FOR ANISOTROPIC SCATTERING
* CREATE KEYCUR
*---
IF(NDIM.EQ.1) THEN
NFUNL=NANIS
NMOD=2
ELSE IF(NDIM.EQ.2) THEN
NFUNL=NANIS*(NANIS+1)/2
NMOD=4
ELSE ! NDIM.EQ.3
NFUNL=NANIS*NANIS
NMOD=8
ENDIF
DIMKEYF=NREG*NLIN*NFUNL
IGP(2)=DIMKEYF
TEXT12='MCCG'
CALL LCMPTC(IPTRK,'TRACK-TYPE',12,TEXT12)
* non-cyclic tracking -> MCCG used (else MOCC)
IF(.NOT.CYCLIC) IGP(2)=IGP(2)+IGP(5)
NUN=IGP(2)
ALLOCATE(KEYFLX(DIMKEYF))
IF(NLIN.EQ.1) THEN
DO 65 IA=1,NFUNL
DO 60 IR=1,NREG
KEYFLX((IA-1)*NREG+IR)=(IA-1)*NREG+IR
60 CONTINUE
65 CONTINUE
ELSE IF(NLIN.EQ.3) THEN
DO 72 IA=1,NFUNL
DO 71 IE=1,3
DO 70 IR=1,NREG
KEYFLX((IA-1)*3*NREG+(IE-1)*NREG+IR)
1 =(IA-1)*3*NREG+(IE-1)*NREG+IR
70 CONTINUE
71 CONTINUE
72 CONTINUE
ENDIF
IF(.NOT.CYCLIC) THEN
ALLOCATE(KEYCUR(NSOU))
IKEY=1
ICUR=0
DO I=1,NUN
IF((KEYFLX(IKEY).NE.I).OR.(IKEY.GT.DIMKEYF)) THEN
ICUR=ICUR+1
IF(ICUR.GT.NSOU)
1 CALL XABORT('MCCGT: INCORRECT NUMBER OF UNKNOWNS')
KEYCUR(ICUR)=I
ELSE
IKEY=IKEY+1
ENDIF
ENDDO
CALL LCMPUT(IPTRK,'KEYCUR$MCCG',NSOU,1,KEYCUR)
DEALLOCATE(KEYCUR)
ENDIF
CALL LCMPUT(IPTRK,'KEYFLX$ANIS',DIMKEYF,1,KEYFLX)
CALL LCMPUT(IPTRK,'KEYFLX',NREG,1,KEYFLX(:NREG))
DEALLOCATE(KEYFLX)
*---
* GENERATE ALL SIGNS FOR SPHERICAL HARMONICS
*---
ALLOCATE(ISGNR(NMOD,NFUNL),KEYANI(NFUNL))
CALL MOCIK3(NANIS-1,NFUNL,NMOD,ISGNR,KEYANI)
DEALLOCATE(ISGNR)
*---
* GENERATE INDEX FOR PJJ(NU'->NU) STORAGE
* IF 'SOURCE TERM ISOLATION' OPTION IS ON
*---
IF((STIS.NE.0).OR.(ISCR.GT.0)) THEN
CALL MCGPJJ(IPTRK,IMPX,NDIM,NANIS,NFUNL,NPJJM,KEYANI)
ELSE
NPJJM=1
ENDIF
DEALLOCATE(KEYANI)
*
IGP(14)=NMU
IGP(16)=NDIM
CALL LCMPUT(IPTRK,'STATE-VECTOR',NSTATE,1,IGP)
*---
* GENERATE MCCG-STATE AND REAL-PARAM VECTORS
*---
IGP(:NSTATE)=0
IGP(1)=LCACT
IGP(2)=NMU
IGP(3)=KRYL
IGP(4)=IDIFC
IGP(5)=MXSEG
IGP(6)=LMCU
IGP(7)=IAAC
IGP(8)=ISCR
IGP(9)=LPS
IGP(10)=PACA
IGP(11)=ILEXA
IGP(12)=ILEXF
IGP(13)=MAXI
IGP(14)=LTMT
IGP(15)=STIS
IGP(16)=NPJJM
IGP(17)=LMCU0
IGP(18)=IFORW
IGP(19)=NFUNL
IGP(20)=NLIN
CALL LCMPUT(IPTRK,'MCCG-STATE',NSTATE,1,IGP)
ZREAL(4)=FACSYM
CALL LCMPUT(IPTRK,'REAL-PARAM',4,2,ZREAL)
*
IF(IMPX.GT.1) THEN
CALL LCMGET(IPTRK,'MCCG-STATE',IGP)
WRITE(IOUT,120) (IGP(I),I=1,11)
WRITE(IOUT,130) (IGP(I),I=12,20)
CALL LCMGET(IPTRK,'REAL-PARAM',ZREAL)
WRITE(IOUT,140) (ZREAL(I),I=1,4)
ENDIF
*----
* PROCESS DOUBLE HETEROGENEITY (BIHET) DATA (IF AVAILABLE)
*----
IF(LBIHET) THEN
CALL LCMGET(IPTRK,'EXCELTRACKOP',EXTKOP)
CALL XDRTBH(IPGEO,IPTRK,IQUA10,IBIHET,IMPX,EXTKOP(39))
ENDIF
*
IF(IMPX.GT.2) CALL LCMLIB(IPTRK)
RETURN
*
100 FORMAT(/
1 44H MM MM CCCCC CCCCC GGGGG TTTTTTTT/
2 44H MMM MMM CCCCCCC CCCCCCC GGGGGGG TTTTTTTT/
4 41H MMMM MMMM CC CC CC CC GG TT/
5 41H MM MM MM CC CC GG GGG TT/
6 41H MM MM CC CC GG GGG TT/
7 41H MM MM CC CC CC CC GG GG TT/
8 41H MM MM CCCCCCC CCCCCCC GGGGGGG TT/
9 41H MM MM CCCCC CCCCC GGGGG TT/
1 17H TRACKING TITLE: ,A72/)
120 FORMAT(/
1 55H STATE VECTOR RELATED TO THE METHOD OF CHARACTERISTICS:/
2 7H LCACT ,I9,29H (TYPE OF POLAR QUADRATURE)/
1 7H NMU ,I9,48H (ORDER OF THE POLAR QUADRATURE IN 2D/1 IN 3D)/
5 7H KRYL ,I9,48H (<0 Bi-CGSTAB SCHEME USED /0=KRYLOV SCHEMES N,
6 30HOT USED/ >0=GMRES SCHEME USED)/
7 7H IDIFC ,I9,39H (0=TRANSPORT/1=CDD SOLUTION OF FLUX)/
8 7H NMAX ,I9,42H (MAXIMUM NUMBER OF ELEMENTS IN A TRACK)/
9 7H LMCU ,I9,42H (DIMENSION OF MCU FOR ACA ACCELERATION)/
3 7H IAAC ,I9,48H (0=NO ACCELERATION/1=CDD ACCELERATION OF INNE,
4 13HR ITERATIONS)/
2 7H SCR ,I9,48H (0=NO ACCELERATION/1=SCR ACCELERATION OF INNE,
3 13HR ITERATIONS)/
4 7H LPS ,I9,42H (DIMENSION OF PSJ FOR SCR ACCELERATION)/
5 7H PACA ,I9,48H (PRECONDITIONER FOR SOLVING THE ACA SYSTEM WI,
6 38HTH BICGSTAB (>2=ILU0, 1=DIAG, 0=NONE))/
7 7H LEXA ,I9,48H (1=FORCE EXACT EXPONENTIAL USAGE IN PRECONDIT,
8 18HIONER CALCULATION))
130 FORMAT(
1 7H LEXF ,I9,48H (1=FORCE EXACT EXPONENTIAL USAGE IN FLUX CALC,
2 8HULATION)/
3 7H MAXI ,I9,39H (MAXIMUM NUMBER OF INNER ITERATIONS)/
4 7H LTMT ,I9,48H (TO USE TRACK MERGING FOR ACA SYSTEM CALCULAT,
5 4HION)/
6 7H STIS ,I9,48H (1=SOURCE TERM ISOLATION FOR FLUX INTEGRATION,
7 1H)/
8 7H NPJJM ,I9,48H (NUMBER OF PJJ MODES TO STORE FOR STIS OPTION,
9 1H)/
1 7H LMCU0 ,I9,48H (DIMENSION OF MCU0 FOR ILU0-ACA ACCELERATION)/
2 7H IFORW ,I9,40H (0/1=DIRECT/ADJOINT FLUX CALCULATION)/
3 7H NFUNL ,I9,45H (NUMBER OF SPHERICAL HARMONICS COMPONENTS)/
4 7H NLIN ,I9,43H (1/3=SC OR DD0 SCHEME/LDC OR DD1 SCHEME))
140 FORMAT(/
1 12H REAL PARAM:/
2 7H EPSI ,1P,E12.4,33H (TOLERANCE ON INNER ITERATION)/
3 7H HDD ,1P,E12.4,41H (0.0=STEP CHARACTERISTICS SOLUTION/>0.,
4 32H0=DIAMOND DIFFERENCING SOLUTION)/
5 7H DELU ,1P,E12.4,42H (TRACK SPACING FOR 3D PRISMATIC GEOMETR,
6 2HY)/
7 7H FACSYM,1P,E12.4,42H (TRACKING SYMMETRY FACTOR FOR MAXIMUM T,
8 38HRACK LENGTH FOR 3D PRISMATIC GEOMETRY)/)
END
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