C $Header: /u/gcmpack/MITgcm/model/src/ini_local_grid.F,v 1.1 2011/12/12 19:01:01 jmc Exp $ C $Name: $ #include "PACKAGES_CONFIG.h" #include "CPP_OPTIONS.h" #ifdef ALLOW_EXCH2 # include "W2_OPTIONS.h" #endif /* ALLOW_EXCH2 */ CBOP C !ROUTINE: INI_LOCAL_GRID C !INTERFACE: SUBROUTINE INI_LOCAL_GRID( O xGloc, yGloc, O delXloc, delYloc, O gridNx, gridNy, I bi, bj, myThid ) C !DESCRIPTION: \bv C *==========================================================* C | SUBROUTINE INI_LOCAL_GRID C | o Initialise model tile-local horizontal grid C *==========================================================* C | Set local grid-point location (xGloc & yGloc) and C | local grid-point spacing (delXloc,delYloc) keeping the C | same units as grid-spacing input parameter (delX,delY C | and xgOrigin,ygOrigin). C | This tile-local mesh setting will be used to build C | the horizontal model grid, according to the selected C | grid option (cartesian, spherical_polar or cylindrical) C *==========================================================* C \ev C !USES: IMPLICIT NONE C === Global variables === #include "SIZE.h" #include "EEPARAMS.h" #include "PARAMS.h" #ifdef ALLOW_EXCH2 # include "W2_EXCH2_SIZE.h" # include "W2_EXCH2_TOPOLOGY.h" #endif /* ALLOW_EXCH2 */ #include "SET_GRID.h" C !INPUT/OUTPUT PARAMETERS: C == Routine arguments == C xGloc :: mesh corner-point location (local "Long" real array type) C yGloc :: mesh corner-point location (local "Long" real array type) C delXloc :: mesh spacing in X direction C delYloc :: mesh spacing in Y direction C gridNx :: mesh total grid-point number in X direction C gridNy :: mesh total grid-point number in Y direction C bi, bj :: tile indices C myThid :: my Thread Id Number C NOTICE the extended range of indices!! _RL xGloc(1-OLx:sNx+OLx+1,1-OLy:sNy+OLy+1) _RL yGloc(1-OLx:sNx+OLx+1,1-OLy:sNy+OLy+1) C NOTICE the extended range of indices!! _RL delXloc(0-OLx:sNx+OLx) _RL delYloc(0-OLy:sNy+OLy) INTEGER gridNx, gridNy INTEGER bi, bj INTEGER myThid C !LOCAL VARIABLES: C == Local variables == C xG0,yG0 :: coordinate of South-West tile-corner C iG0,jG0 :: Tile base X and Y indices within global index space C i, j :: loop counters INTEGER iG0, jG0 INTEGER i, j _RL xG0, yG0 #ifdef ALLOW_EXCH2 INTEGER tN #endif /* ALLOW_EXCH2 */ C The functions iGl, jGl return the "global" index with valid values beyond C halo regions C cnh wrote: C > I dont understand why we would ever have to multiply the C > overlap by the total domain size e.g C > OLx*Nx, OLy*Ny. C > Can anybody explain? Lines are in ini_spherical_polar_grid.F. C > Surprised the code works if its wrong, so I am puzzled. C jmc replied: C Yes, I can explain this since I put this modification to work C with small domain (where OLy > Ny, as for instance, zonal-average C case): C This has no effect on the acuracy of the evaluation of iGl(I,bi) C and jGl(j,bj) since we take mod(a+OLx*Nx,Nx) and mod(b+OLy*Ny,Ny). C But in case a or b is negative, then the FORTRAN function "mod" C does not return the matematical value of the "modulus" function, C and this is not good for your purpose. C This is why I add +OLx*Nx and +OLy*Ny to be sure that the 1rst C argument of the mod function is positive. c INTEGER iGl,jGl c iGl(i,bi) = 1+MOD(iG0+i-1+OLx*gridNx,gridNx) c jGl(j,bj) = 1+MOD(jG0+j-1+OLy*gridNy,gridNy) CEOP #ifdef ALLOW_EXCH2 gridNx = exch2_mydNx(1) gridNy = exch2_mydNy(1) #else /* ALLOW_EXCH2 */ gridNx = Nx gridNy = Ny #endif /* ALLOW_EXCH2 */ c DO bj = myByLo(myThid), myByHi(myThid) c DO bi = myBxLo(myThid), myBxHi(myThid) C For this tile ... C-- Set current tile base X and base Y indices within global index space C e.g., local indices of tile south-west corner grid point are (1,1) C and global indices are 1+iG0, 1+jG0 #ifdef ALLOW_EXCH2 tN = W2_myTileList(bi,bj) iG0 = exch2_tBasex(tN) jG0 = exch2_tBasey(tN) #else /* ALLOW_EXCH2 */ iG0 = myXGlobalLo - 1 + (bi-1)*sNx jG0 = myYGlobalLo - 1 + (bj-1)*sNy #endif /* ALLOW_EXCH2 */ C-- First find coordinate of tile corner (meaning outer corner of halo) xG0 = xgOrigin C Find the X-coordinate of the outer grid-line of the "real" tile DO i=1, iG0 xG0 = xG0 + delX(i) ENDDO C Back-step to the outer grid-line of the "halo" region DO i=1, OLx xG0 = xG0 - delX( 1+MOD(iG0-i+OLx*gridNx,gridNx) ) ENDDO C Find the Y-coordinate of the outer grid-line of the "real" tile yG0 = ygOrigin DO j=1, jG0 yG0 = yG0 + delY(j) ENDDO C Back-step to the outer grid-line of the "halo" region DO j=1, OLy yG0 = yG0 - delY( 1+MOD(jG0-j+OLy*gridNy,gridNy) ) ENDDO C-- Make a local copy of current-tile grid-spacing DO i=0-OLx,sNx+OLx delXloc(i) = delX( 1+MOD(iG0+i-1+OLx*gridNx,gridNx) ) ENDDO DO j=0-OLy,sNy+OLy delYloc(j) = delY( 1+MOD(jG0+j-1+OLy*gridNy,gridNy) ) ENDDO C-- Calculate coordinates of cell corners for N+1 grid-lines DO j=1-OLy,sNy+OLy +1 xGloc(1-OLx,j) = xG0 DO i=1-OLx,sNx+OLx xGloc(i+1,j) = xGloc(i,j) + delXloc(i) ENDDO ENDDO DO i=1-OLx,sNx+OLx +1 yGloc(i,1-OLy) = yG0 DO j=1-OLy,sNy+OLy yGloc(i,j+1) = yGloc(i,j) + delYloc(j) ENDDO ENDDO C-- end bi,bj loops c ENDDO c ENDDO RETURN END