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*DECK NXT3T2
SUBROUTINE NXT3T2(IPTRK,JPTRK,IX,IY,IZ,NFREG,NFSUR,MAXMSH,
1 NUCELL,NBUCEL,MXGSUR,MXGREG,MAXPIN,MATALB,
2 SURVOL,IUNFLD,NZP,N2REG,N2SUR,N2CEL,N2PIN,
3 IND2T3,ZCORD,MATALB2,SURVOL2)
*
*-----------------------------------------------------------------------
*
*Purpose:
* Create 2D projection (NXT geometry analysis) of a 3D prismatic
* geometry.
*
*Copyright:
* Copyright (C) 2005 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): R. Le Tellier
*
*Parameters: input
* IPTRK pointer to the NXT 3D geometry analysis.
* JPTRK pointer to the NXT 2D projected geometry analysis.
* IX first direction perpendicular to the projection axis.
* IY second direction perpendicular to the projection axis.
* IZ projection axis.
* NFREG number of regions in the 3D geometry.
* NFSUR number of outer surfaces in the 3D geometry.
* MAXMSH maximum dimension of any mesh in any sub-geometry of the 3D
* geometry.
* NUCELL number of cells along the three axis in the 3D geometry.
* NBUCEL total number of cells in the 3D geometry.
* MXGSUR maximum number of surfaces for any sub-geometry of the 3D
* geometry.
* MXGREG maximum number of regions for any sub-geometry of the 3D
* geometry.
* MAXPIN maximum number of pins for any cell of the 3D geometry.
* MATALB mixtures/albedos array for the 3D geometry.
* SURVOL surfaces/volumes array for the 3D geometry.
* IUNFLD assembly description array for the 3D geometry (*,*,*,*,0)
* / projected 2D geometry (*,*,*,*,1).
*
*Parameters: output
* NZP number of plans in the 3D prismatic geometry.
* N2REG number of regions in the projected 2D geometry.
* N2SUR number of outer surfaces in the projected 2D geometry.
* N2CEL total number of cells in the projected 2D geometry.
* N2PIN total number of pin descriptions in the projected 2D geometry.
* IND2T3 mapping index between the 2D projected geometries (plan by
* plan) and the initial 3D geometry.
* ZCORD coordinates of the different plans of the 3D prismatic
* geometry.
* MATALB2 mixtures/albedos array for the projected 2D geometry.
* SURVOL2 surfaces/volumes array for the projected 2D geometry.
*
*-----------------------------------------------------------------------
*
USE GANLIB
IMPLICIT NONE
*----
* SUBROUTINE ARGUMENTS
*----
TYPE(C_PTR) IPTRK,JPTRK
INTEGER IX,IY,IZ,NFREG,NFSUR,MAXMSH,NUCELL(3),NBUCEL,MXGSUR,
1 MXGREG,MAXPIN,MATALB(-NFSUR:NFREG),
2 IUNFLD(2,NUCELL(1),NUCELL(2),NUCELL(3),0:1),NZP,N2REG,N2SUR,
3 N2CEL,N2PIN,IND2T3(-NFSUR:NFREG,0:NUCELL(IZ)*MAXMSH+1),
4 MATALB2(-NFSUR:NFREG)
DOUBLE PRECISION SURVOL(-NFSUR:NFREG),ZCORD(0:MAXMSH),
1 SURVOL2(-NFSUR:NFREG)
*----
* LOCAL VARIABLES
*----
INTEGER NSTATE
DOUBLE PRECISION DEPS
PARAMETER(NSTATE=40,DEPS=1.D-7)
INTEGER ESTATE(NSTATE)
INTEGER I,J,ITRN,ICEL,K,JJ,II,NTPINR,N2SURC,N2REGC,IPIN,N2SURP,
1 N2REGP,NUNK2
DOUBLE PRECISION DELZ,HPIN,APIN,RPIN,RADP
!! CHARACTER SIZEX*5,FORM*30
CHARACTER NAMCEL*9,NAMREC*12,NAMCE2*9
LOGICAL LFIRST,XDDCOM,LPIN,LSTCEL,LSTPIN
CHARACTER CDIR(4)*1
DATA CDIR /'X','Y','Z','R'/
*----
* Allocatable arrays
*----
INTEGER, ALLOCATABLE, DIMENSION(:) :: NSURC,NREGC,IDIRC,NTPIN,
> REGI,CELID,PINID
INTEGER, ALLOCATABLE, DIMENSION(:,:) :: IDSUR,IDREG,MESHC
INTEGER, ALLOCATABLE, DIMENSION(:,:,:) :: INDEX,ITPIN
DOUBLE PRECISION, ALLOCATABLE, DIMENSION(:,:,:) :: DCMESH,DRAPIN
*
!!!! WRITE(SIZEX,*) NUCELL(1)
!!!! FORM='('//SIZEX//'(I2,1X,1H(,I2,1H),2X))'
!!!! WRITE(6,*) 'GLOBAL ASSEMBLY:'
!!!! DO K=1,MAX(NUCELL(3),1)
!!!! WRITE(6,*) K,' z-plan'
!!!! DO J=NUCELL(2),1,-1
!!!! WRITE(6,FORM) ((IUNFLD(JJ,I,J,K,0),JJ=1,2),I=1,NUCELL(1))
!!!! ENDDO
!!!! ENDDO
*----
* Scratch storage allocation
*----
ALLOCATE(INDEX(5,-MXGSUR:MXGREG,0:NUCELL(IZ)),
> IDSUR(MXGSUR,0:NUCELL(IZ)),IDREG(MXGREG,0:NUCELL(IZ)),
> MESHC(4,NUCELL(IZ)),NSURC(NUCELL(IZ)),NREGC(NUCELL(IZ)),
> IDIRC(NUCELL(IZ)),NTPIN(NUCELL(IZ)),
> ITPIN(3,MAXPIN,0:NUCELL(IZ)))
ALLOCATE(DCMESH(-1:MAXMSH,4,0:NUCELL(IZ)),
> DRAPIN(-1:4,MAXPIN,0:NUCELL(IZ)),REGI(-NFSUR:NFREG),
> CELID(NBUCEL),PINID(NBUCEL*MAXPIN))
*
REGI(-NFSUR:NFREG)=0
CELID(:NBUCEL)=0
IND2T3(-NFSUR:NFREG,0:NUCELL(IZ)*MAXMSH+1)=0
N2SUR=0
N2REG=0
N2CEL=0
N2PIN=0
LFIRST=.TRUE.
LSTCEL=.FALSE.
DO 15 J=1,NUCELL(IY)
DO 10 I=1,NUCELL(IX)
*----
* LOOP OVER THE CELLS IN THE PLAN PERPENDICULAR TO THE PROJECTION AXIS
*----
* ----
* CELL LEVEL (1)
* ----
!write(*,*) 'CELL LEVEL (',I,J,' )'
DO K=1,NUCELL(IZ)
ICEL=IUNFLD(1,I,J,K,0)
ITRN=IUNFLD(2,I,J,K,0)
IF (ITRN.NE.IUNFLD(2,I,J,1,0))
1 CALL XABORT('NXT3T2: INVALID PRISMATIC GEOMETRY (TURN).')
* LOAD THE CONTENTS OF THE DIFFERENT CELLS (I,J,K=1,NUCELL(IZ))
CALL NXTLDC(IPTRK,MAXMSH,ICEL,IDIRC(K),MESHC(1,K),NSURC(K),
1 NREGC(K),NTPIN(K),DCMESH(-1,1,K),INDEX(1,-MXGSUR,K),
2 IDREG(1,K),IDSUR(1,K),ITPIN(1,1,K),DRAPIN(-1,1,K))
!write(*,*) 'loading cell',ICEL,MESHC(1,K),MESHC(2,K),MESHC(4,K)
IF (K.EQ.1) THEN
IF (CELID(ICEL).EQ.0) THEN
* RECOVER DIM INFO FOR THE CORRESPONDING 2D CELL
LSTCEL=.TRUE.
N2CEL=N2CEL+1
WRITE(NAMCEL,'(A1,I8.8)') 'C',ICEL
!write(*,*) 'copying from ',NAMCEL
NAMREC=NAMCEL//'DIM'
ESTATE(:NSTATE)=0
CALL LCMGET(IPTRK,NAMREC,ESTATE)
IF ((ESTATE(1).EQ.21).OR.
1 (ESTATE(1).EQ.22).OR.
2 (ESTATE(1).EQ.23)) THEN
ESTATE(1)=20
ELSEIF(ESTATE(1).EQ.7) THEN
ESTATE(1)=5
ENDIF
ESTATE(5)=0
ESTATE(6)=0
ESTATE(12)=N2REG+1
ESTATE(14)=N2SUR+1
CELID(ICEL)=N2CEL
ENDIF
IUNFLD(1,I,J,1,1)=CELID(ICEL)
IUNFLD(2,I,J,1,1)=ITRN
ENDIF
ENDDO
* CHECK CELLS COMPATIBILITY, UPDATE IND2T3 FOR THIS SET OF CELLS
* AND FILL-IN 2D CORRESPONDING CELL CONTENTS
NTPINR=NTPIN(1)
DO K=2,NUCELL(IZ)
IF (NTPIN(K).NE.NTPINR)
1 CALL XABORT('NXT3T2: INVALID PRISMATIC GEOMETRY (NTPIN).')
ENDDO
CALL NXTPRI(IPTRK,JPTRK,IX,IY,IZ,NFREG,NFSUR,MAXMSH,NUCELL,MXGSUR,
1 MXGREG,INDEX,IDSUR,IDREG,MESHC,NSURC,NREGC,IDIRC,NZP,N2REG,
2 N2SUR,IND2T3,REGI,DEPS,DCMESH,ZCORD,LFIRST,LSTCEL,1,
3 IUNFLD(1,I,J,1,0),N2CEL,N2SURC,N2REGC)
IF (LSTCEL) THEN
* STORE 2D CELL CONTENTS: DIM ARRAY
ESTATE(10)=N2REGC
ESTATE(11)=N2SURC
ESTATE(13)=N2REG
ESTATE(15)=N2SUR
!write(*,*) ESTATE(1),ESTATE(2)
WRITE(NAMCE2,'(A1,I8.8)') 'C',N2CEL
NAMREC=NAMCE2//'DIM'
CALL LCMPUT(JPTRK,NAMREC,NSTATE,1,ESTATE)
ENDIF
* ----
* PIN LEVEL (2)
* ----
PINID(:NTPINR)=0
DO II=1,NTPINR
!write(*,*) 'PIN LEVEL ( ',II,')'
* LOAD THE CONTENTS OF THE DIFFERENT PINS (II,K=1,NUCELL(IZ))
IDIRC(1)=ABS(ITPIN(3,II,1))
IPIN=ITPIN(2,II,1)
HPIN=DRAPIN(IZ,II,1)
DELZ=DCMESH(MESHC(IZ,1),IZ,1)-DCMESH(0,IZ,1)
IF (.NOT.XDDCOM(DELZ,HPIN,DEPS))
1 CALL XABORT('NXT3T2: INVALID PRISMATIC GEOMETRY (HPIN).')
CALL NXTLDP(IPTRK,MAXMSH,IPIN,MESHC(1,1),NSURC(1),NREGC(1),
1 DCMESH(-1,1,1),INDEX(1,-MXGSUR,1),IDREG(1,1),IDSUR(1,1))
APIN=DRAPIN(-1,II,1)
RPIN=DRAPIN( 0,II,1)
RADP=DRAPIN( 4,II,1)
LSTPIN=.FALSE.
IF (PINID(IPIN).EQ.0) THEN
* RECOVER DIM INFO FOR THE CORRESPONDING 2D PIN
LSTPIN=.TRUE.
N2PIN=N2PIN+1
WRITE(NAMCEL,'(A1,I8.8)') 'P',IPIN
!write(*,*) 'copying from ',NAMCEL
NAMREC=NAMCEL//'DIM'
ESTATE(:NSTATE)=0
CALL LCMGET(IPTRK,NAMREC,ESTATE)
IF ((ESTATE(1).EQ.6).OR.
1 (ESTATE(1).EQ.10).OR.
2 (ESTATE(1).EQ.11)) THEN
ESTATE(1)=3
ENDIF
ESTATE(5)=0
ESTATE(6)=0
ESTATE(12)=N2REG+1
ESTATE(14)=N2SUR+1
PINID(IPIN)=N2PIN
ENDIF
ITPIN(1,II,0)=ITPIN(1,II,1)
ITPIN(2,II,0)=PINID(IPIN)
ITPIN(3,II,0)=3
DRAPIN(-1,II,0)=APIN
DRAPIN( 0,II,0)=RPIN
DRAPIN( 1,II,0)=0.D0
DRAPIN( 2,II,0)=0.D0
DRAPIN( 3,II,0)=1.D0
DRAPIN( 4,II,0)=RADP
DO K=2,NUCELL(IZ)
DO JJ=1,NTPINR
LPIN=.TRUE.
LPIN=LPIN.AND.(XDDCOM(HPIN,DRAPIN(IZ,JJ,K),DEPS))
LPIN=LPIN.AND.(XDDCOM(APIN,DRAPIN(-1,JJ,K),DEPS))
LPIN=LPIN.AND.(XDDCOM(RPIN,DRAPIN( 0,JJ,K),DEPS))
LPIN=LPIN.AND.(XDDCOM(RADP,DRAPIN( 4,JJ,K),DEPS))
IF (LPIN) THEN
IPIN=ITPIN(2,JJ,K)
IDIRC(K)=ABS(ITPIN(3,JJ,K))
GOTO 20
ENDIF
ENDDO
CALL XABORT('NXT3T2: INVALID PRISMATIC GEOMETRY (PIN).')
20 CONTINUE
CALL NXTLDP(IPTRK,MAXMSH,IPIN,MESHC(1,K),NSURC(K),NREGC(K),
1 DCMESH(-1,1,K),INDEX(1,-MXGSUR,K),IDREG(1,K),
2 IDSUR(1,K))
ENDDO
* CHECK PINS COMPATIBILITY AND UPDATE IND2T3 FOR THIS SET OF PINS
CALL NXTPRI(IPTRK,JPTRK,IX,IY,IZ,NFREG,NFSUR,MAXMSH,NUCELL,
1 MXGSUR,MXGREG,INDEX,IDSUR,IDREG,MESHC,NSURC,NREGC,IDIRC,
2 NZP,N2REG,N2SUR,IND2T3,REGI,DEPS,DCMESH,ZCORD,LFIRST,
3 LSTPIN,2,ITPIN(2,II,1),N2PIN,N2SURP,N2REGP)
IF (LSTPIN) THEN
* STORE 2D PIN CONTENTS: DIM ARRAY
ESTATE(10)=N2REGP
ESTATE(11)=N2SURP
ESTATE(13)=N2REG
ESTATE(15)=N2SUR
WRITE(NAMCE2,'(A1,I8.8)') 'P',N2PIN
NAMREC=NAMCE2//'DIM'
CALL LCMPUT(JPTRK,NAMREC,NSTATE,1,ESTATE)
ENDIF
ENDDO
IF (LSTCEL) THEN
* STORE 2D CELL CONTENTS: PIN RELATED
IF (NTPINR.GT.0) THEN
WRITE(NAMCE2,'(A1,I8.8)') 'C',N2CEL
NAMREC=NAMCE2//'PIN'
CALL LCMPUT(JPTRK,NAMREC,6*NTPINR,4,DRAPIN(-1,1,0))
NAMREC=NAMCE2//'PNT'
CALL LCMPUT(JPTRK,NAMREC,3*NTPINR,1,ITPIN(1,1,0))
ENDIF
ENDIF
LSTCEL=.FALSE.
LFIRST=.FALSE.
*----
10 CONTINUE
15 CONTINUE
N2SUR=-N2SUR
*----
* FILL IN AND STORE MATALB AND SareaRvolume ARRAYS FOR THE 2D GEOMETRY
*----
DELZ=ZCORD(1)
DO I=-N2SUR,N2REG
MATALB2(I)=MATALB(IND2T3(I,1))
SURVOL2(I)=SURVOL(IND2T3(I,1))/DELZ
ENDDO
NUNK2=N2SUR+N2REG+1
CALL LCMPUT(JPTRK,'MATALB ',NUNK2,1,MATALB2(-N2SUR))
CALL LCMPUT(JPTRK,'SAreaRvolume',NUNK2,4,SURVOL2(-N2SUR))
*----
* Scratch storage deallocation
*----
DEALLOCATE(PINID,CELID,REGI,DRAPIN,DCMESH)
DEALLOCATE(ITPIN,NTPIN,IDIRC,NREGC,NSURC,MESHC,IDREG,IDSUR,INDEX)
RETURN
END
|
