#include "cppdefs.h" MODULE def_quick_mod ! !git $Id$ !svn $Id: def_quick.F 1185 2023-08-01 21:42:38Z arango $ !================================================== Hernan G. Arango === ! Copyright (c) 2002-2023 The ROMS/TOMS Group ! ! Licensed under a MIT/X style license ! ! See License_ROMS.md ! !======================================================================= ! ! ! This module creates output QUICKSAVE file using either the standard ! ! NetCDF library or the Parallel-IO (PIO) library. It defines its ! ! dimensions, attributes, and variables. ! ! ! !======================================================================= ! USE mod_param USE mod_parallel #ifdef BIOLOGY USE mod_biology #endif #ifdef FOUR_DVAR USE mod_fourdvar #endif USE mod_iounits USE mod_ncparam USE mod_scalars #ifdef SEDIMENT USE mod_sediment #endif ! #if (defined BBL_MODEL || defined WAVES_OUTPUT) && defined SOLVE3D USE bbl_output_mod, ONLY : bbl_def_nf90 # if defined PIO_LIB && defined DISTRIBUTE USE bbl_output_mod, ONLY : bbl_def_pio # endif #endif USE def_dim_mod, ONLY : def_dim USE def_info_mod, ONLY : def_info USE def_var_mod, ONLY : def_var #if defined ICE_MODEL && defined SOLVE3D USE ice_output_mod, ONLY : ice_def_nf90 # if defined PIO_LIB && defined DISTRIBUTE USE ice_output_mod, ONLY : ice_def_pio # endif #endif #if defined SEDIMENT && defined SOLVE3D USE sediment_output_mod, ONLY : sediment_def_nf90 # if defined PIO_LIB && defined DISTRIBUTE USE sediment_output_mod, ONLY : sediment_def_pio # endif #endif USE strings_mod, ONLY : FoundError #if defined WEC_VF && defined SOLVE3D USE wec_output_mod, ONLY : wec_def_nf90 # if defined PIO_LIB && defined DISTRIBUTE USE wec_output_mod, ONLY : wec_def_pio # endif #endif USE wrt_info_mod, ONLY : wrt_info ! implicit none ! PUBLIC :: def_quick PRIVATE :: def_quick_nf90 #if defined PIO_LIB && defined DISTRIBUTE PRIVATE :: def_quick_pio #endif ! CONTAINS ! !*********************************************************************** SUBROUTINE def_quick (ng, ldef) !*********************************************************************** ! ! Imported variable declarations. ! logical, intent(in) :: ldef ! integer, intent(in) :: ng ! ! Local variable declarations. ! character (len=*), parameter :: MyFile = & & __FILE__ ! !----------------------------------------------------------------------- ! Create a new history file according to IO type. !----------------------------------------------------------------------- ! SELECT CASE (QCK(ng)%IOtype) CASE (io_nf90) CALL def_quick_nf90 (ng, iNLM, ldef) #if defined PIO_LIB && defined DISTRIBUTE CASE (io_pio) CALL def_quick_pio (ng, iNLM, ldef) #endif CASE DEFAULT IF (Master) WRITE (stdout,10) QCK(ng)%IOtype exit_flag=3 END SELECT IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN ! 10 FORMAT (' DEF_QUICK - Illegal output file type, io_type = ',i0, & & /,13x,'Check KeyWord ''OUT_LIB'' in ''roms.in''.') ! RETURN END SUBROUTINE def_quick ! !*********************************************************************** SUBROUTINE def_quick_nf90 (ng, model, ldef) !*********************************************************************** ! USE mod_netcdf ! ! Imported variable declarations. ! logical, intent(in) :: ldef integer, intent(in) :: ng, model ! ! Local variable declarations. ! logical :: got_var(NV) ! integer, parameter :: Natt = 25 integer :: i, j, ifield, itrc, nvd3, nvd4, varid integer :: recdim, status #ifdef ADJUST_BOUNDARY integer :: IorJdim #endif integer :: DimIDs(nDimID) integer :: t2dgrd(3), u2dgrd(3), v2dgrd(3) #ifdef SOLVE3D # ifdef SEDIMENT integer :: b3dgrd(4) # endif integer :: t3dgrd(4), u3dgrd(4), v3dgrd(4), w3dgrd(4) #endif #ifdef WET_DRY integer :: sp2dgrd(3) #endif ! real(r8) :: Aval(6) ! character (len=256) :: ncname character (len=MaxLen) :: Vinfo(Natt) character (len=*), parameter :: MyFile = & & __FILE__//", def_quick_nf90" ! SourceFile=MyFile ! !----------------------------------------------------------------------- ! Set and report file name. !----------------------------------------------------------------------- ! IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN ncname=QCK(ng)%name ! IF (Master) THEN IF (ldef) THEN WRITE (stdout,10) ng, TRIM(ncname) ELSE WRITE (stdout,20) ng, TRIM(ncname) END IF END IF ! !======================================================================= ! Create a new quicksave file. !======================================================================= ! DEFINE : IF (ldef) THEN CALL netcdf_create (ng, model, TRIM(ncname), QCK(ng)%ncid) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) THEN IF (Master) WRITE (stdout,30) TRIM(ncname) RETURN END IF ! !----------------------------------------------------------------------- ! Define file dimensions. !----------------------------------------------------------------------- ! DimIDs=0 ! status=def_dim(ng, model, QCK(ng)%ncid, ncname, 'xi_rho', & & IOBOUNDS(ng)%xi_rho, DimIDs( 1)) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN status=def_dim(ng, model, QCK(ng)%ncid, ncname, 'xi_u', & & IOBOUNDS(ng)%xi_u, DimIDs( 2)) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN status=def_dim(ng, model, QCK(ng)%ncid, ncname, 'xi_v', & & IOBOUNDS(ng)%xi_v, DimIDs( 3)) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN status=def_dim(ng, model, QCK(ng)%ncid, ncname, 'xi_psi', & & IOBOUNDS(ng)%xi_psi, DimIDs( 4)) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN status=def_dim(ng, model, QCK(ng)%ncid, ncname, 'eta_rho', & & IOBOUNDS(ng)%eta_rho, DimIDs( 5)) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN status=def_dim(ng, model, QCK(ng)%ncid, ncname, 'eta_u', & & IOBOUNDS(ng)%eta_u, DimIDs( 6)) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN status=def_dim(ng, model, QCK(ng)%ncid, ncname, 'eta_v', & & IOBOUNDS(ng)%eta_v, DimIDs( 7)) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN status=def_dim(ng, model, QCK(ng)%ncid, ncname, 'eta_psi', & & IOBOUNDS(ng)%eta_psi, DimIDs( 8)) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN #ifdef ADJUST_BOUNDARY status=def_dim(ng, model, QCK(ng)%ncid, ncname, 'IorJ', & & IOBOUNDS(ng)%IorJ, IorJdim) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN #endif #if defined WRITE_WATER && defined MASKING status=def_dim(ng, model, QCK(ng)%ncid, ncname, 'xy_rho', & & IOBOUNDS(ng)%xy_rho, DimIDs(17)) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN status=def_dim(ng, model, QCK(ng)%ncid, ncname, 'xy_u', & & IOBOUNDS(ng)%xy_u, DimIDs(18)) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN status=def_dim(ng, model, QCK(ng)%ncid, ncname, 'xy_v', & & IOBOUNDS(ng)%xy_v, DimIDs(19)) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN #endif #ifdef SOLVE3D # if defined WRITE_WATER && defined MASKING status=def_dim(ng, model, QCK(ng)%ncid, ncname, 'xyz_rho', & & IOBOUNDS(ng)%xy_rho*N(ng), DimIDs(20)) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN status=def_dim(ng, model, QCK(ng)%ncid, ncname, 'xyz_u', & & IOBOUNDS(ng)%xy_u*N(ng), DimIDs(21)) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN status=def_dim(ng, model, QCK(ng)%ncid, ncname, 'xyz_v', & & IOBOUNDS(ng)%xy_v*N(ng), DimIDs(22)) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN status=def_dim(ng, model, QCK(ng)%ncid, ncname, 'xyz_w', & & IOBOUNDS(ng)%xy_rho*(N(ng)+1), DimIDs(23)) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN # endif status=def_dim(ng, model, QCK(ng)%ncid, ncname, 'N', & & N(ng), DimIDs( 9)) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN status=def_dim(ng, model, QCK(ng)%ncid, ncname, 's_rho', & & N(ng), DimIDs( 9)) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN status=def_dim(ng, model, QCK(ng)%ncid, ncname, 's_w', & & N(ng)+1, DimIDs(10)) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN status=def_dim(ng, model, QCK(ng)%ncid, ncname, 'tracer', & & NT(ng), DimIDs(11)) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN # ifdef SEDIMENT status=def_dim(ng, model, QCK(ng)%ncid, ncname, 'NST', & & NST, DimIDs(32)) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN status=def_dim(ng, model, QCK(ng)%ncid, ncname, 'Nbed', & & Nbed, DimIDs(16)) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN # if defined WRITE_WATER && defined MASKING status=def_dim(ng, model, QCK(ng)%ncid, ncname, 'xybed', & & IOBOUNDS(ng)%xy_rho*Nbed, DimIDs(24)) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN # endif # endif # ifdef ECOSIM status=def_dim(ng, model, QCK(ng)%ncid, ncname, 'Nbands', & & NBands, DimIDs(33)) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN status=def_dim(ng, model, QCK(ng)%ncid, ncname, 'Nphy', & & Nphy, DimIDs(25)) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN status=def_dim(ng, model, QCK(ng)%ncid, ncname, 'Nbac', & & Nbac, DimIDs(26)) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN status=def_dim(ng, model, QCK(ng)%ncid, ncname, 'Ndom', & & Ndom, DimIDs(27)) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN status=def_dim(ng, model, QCK(ng)%ncid, ncname, 'Nfec', & & Nfec, DimIDs(28)) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN # endif #endif status=def_dim(ng, model, QCK(ng)%ncid, ncname, 'boundary', & & 4, DimIDs(14)) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN #ifdef FOUR_DVAR status=def_dim(ng, model, QCK(ng)%ncid, ncname, 'Nstate', & & NstateVar(ng), DimIDs(29)) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN #endif #ifdef ADJUST_BOUNDARY status=def_dim(ng, model, QCK(ng)%ncid, ncname, 'obc_adjust', & & Nbrec(ng), DimIDs(31)) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN #endif status=def_dim(ng, model, QCK(ng)%ncid, ncname, & & TRIM(ADJUSTL(Vname(5,idtime))), & & nf90_unlimited, DimIDs(12)) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN recdim=DimIDs(12) ! ! Set number of dimensions for output variables. ! #if defined WRITE_WATER && defined MASKING nvd3=2 nvd4=2 #else nvd3=3 nvd4=4 #endif ! ! Define dimension vectors for staggered tracer type variables. ! #if defined WRITE_WATER && defined MASKING t2dgrd(1)=DimIDs(17) t2dgrd(2)=DimIDs(12) # ifdef SOLVE3D t3dgrd(1)=DimIDs(20) t3dgrd(2)=DimIDs(12) # endif #else t2dgrd(1)=DimIDs( 1) t2dgrd(2)=DimIDs( 5) t2dgrd(3)=DimIDs(12) # ifdef SOLVE3D t3dgrd(1)=DimIDs( 1) t3dgrd(2)=DimIDs( 5) t3dgrd(3)=DimIDs( 9) t3dgrd(4)=DimIDs(12) # endif #endif #ifdef WET_DRY ! ! Define dimension vectors for staggered type variables at PSI-points. ! sp2dgrd(1)=DimIDs( 4) sp2dgrd(2)=DimIDs( 8) sp2dgrd(3)=DimIDs(12) #endif ! ! Define dimension vectors for staggered u-momentum type variables. ! #if defined WRITE_WATER && defined MASKING u2dgrd(1)=DimIDs(18) u2dgrd(2)=DimIDs(12) # ifdef SOLVE3D u3dgrd(1)=DimIDs(21) u3dgrd(2)=DimIDs(12) # endif #else u2dgrd(1)=DimIDs( 2) u2dgrd(2)=DimIDs( 6) u2dgrd(3)=DimIDs(12) # ifdef SOLVE3D u3dgrd(1)=DimIDs( 2) u3dgrd(2)=DimIDs( 6) u3dgrd(3)=DimIDs( 9) u3dgrd(4)=DimIDs(12) # endif #endif ! ! Define dimension vectors for staggered v-momentum type variables. ! #if defined WRITE_WATER && defined MASKING v2dgrd(1)=DimIDs(19) v2dgrd(2)=DimIDs(12) # ifdef SOLVE3D v3dgrd(1)=DimIDs(22) v3dgrd(2)=DimIDs(12) # endif #else v2dgrd(1)=DimIDs( 3) v2dgrd(2)=DimIDs( 7) v2dgrd(3)=DimIDs(12) # ifdef SOLVE3D v3dgrd(1)=DimIDs( 3) v3dgrd(2)=DimIDs( 7) v3dgrd(3)=DimIDs( 9) v3dgrd(4)=DimIDs(12) # endif #endif #ifdef SOLVE3D ! ! Define dimension vector for staggered w-momentum type variables. ! # if defined WRITE_WATER && defined MASKING w3dgrd(1)=DimIDs(23) w3dgrd(2)=DimIDs(12) # else w3dgrd(1)=DimIDs( 1) w3dgrd(2)=DimIDs( 5) w3dgrd(3)=DimIDs(10) w3dgrd(4)=DimIDs(12) # endif # ifdef SEDIMENT ! ! Define dimension vector for sediment bed layer type variables. ! # if defined WRITE_WATER && defined MASKING b3dgrd(1)=DimIDs(24) b3dgrd(2)=DimIDs(12) # else b3dgrd(1)=DimIDs( 1) b3dgrd(2)=DimIDs( 5) b3dgrd(3)=DimIDs(16) b3dgrd(4)=DimIDs(12) # endif # endif #endif ! ! Initialize unlimited time record dimension. ! QCK(ng)%Rindex=0 ! ! Initialize local information variable arrays. ! DO i=1,Natt DO j=1,LEN(Vinfo(1)) Vinfo(i)(j:j)=' ' END DO END DO DO i=1,6 Aval(i)=0.0_r8 END DO ! !----------------------------------------------------------------------- ! Define time-recordless information variables. !----------------------------------------------------------------------- ! CALL def_info (ng, model, QCK(ng)%ncid, ncname, DimIDs) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN ! !----------------------------------------------------------------------- ! Define time-varying variables. !----------------------------------------------------------------------- ! ! Define model time. ! Vinfo( 1)=Vname(1,idtime) Vinfo( 2)=Vname(2,idtime) WRITE (Vinfo( 3),'(a,a)') 'seconds since ', TRIM(Rclock%string) Vinfo( 4)=TRIM(Rclock%calendar) Vinfo(14)=Vname(4,idtime) Vinfo(21)=Vname(6,idtime) status=def_var(ng, model, QCK(ng)%ncid, QCK(ng)%Vid(idtime), & & NF_TOUT, 1, (/recdim/), Aval, Vinfo, ncname, & & SetParAccess = .TRUE.) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN #ifdef WET_DRY ! ! Define wet/dry mask on PSI-points. ! Vinfo( 1)=Vname(1,idPwet) Vinfo( 2)=Vname(2,idPwet) Vinfo( 3)=Vname(3,idPwet) Vinfo( 9)='land' Vinfo(10)='water' Vinfo(14)=Vname(4,idPwet) Vinfo(16)=Vname(1,idtime) Vinfo(21)=Vname(6,idPwet) Vinfo(22)='coordinates' Aval(5)=REAL(Iinfo(1,idPwet,ng),r8) status=def_var(ng, model, QCK(ng)%ncid, QCK(ng)%Vid(idPwet), & & NF_FOUT, nvd3, sp2dgrd, Aval, Vinfo, ncname, & & SetFillVal = .FALSE.) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN ! ! Define wet/dry mask on RHO-points. ! Vinfo( 1)=Vname(1,idRwet) Vinfo( 2)=Vname(2,idRwet) Vinfo( 3)=Vname(3,idRwet) Vinfo( 9)='land' Vinfo(10)='water' Vinfo(14)=Vname(4,idRwet) Vinfo(16)=Vname(1,idtime) Vinfo(21)=Vname(6,idRwet) Vinfo(22)='coordinates' Aval(5)=REAL(Iinfo(1,idRwet,ng),r8) status=def_var(ng, model, QCK(ng)%ncid, QCK(ng)%Vid(idRwet), & & NF_FOUT, nvd3, t2dgrd, Aval, Vinfo, ncname, & & SetFillVal = .FALSE.) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN ! ! Define wet/dry mask on U-points. ! Vinfo( 1)=Vname(1,idUwet) Vinfo( 2)=Vname(2,idUwet) Vinfo( 3)=Vname(3,idUwet) Vinfo( 9)='land' Vinfo(10)='water' Vinfo(14)=Vname(4,idUwet) Vinfo(16)=Vname(1,idtime) Vinfo(21)=Vname(6,idUwet) Vinfo(22)='coordinates' Aval(5)=REAL(Iinfo(1,idUwet,ng),r8) status=def_var(ng, model, QCK(ng)%ncid, QCK(ng)%Vid(idUwet), & & NF_FOUT, nvd3, u2dgrd, Aval, Vinfo, ncname, & & SetFillVal = .FALSE.) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN ! ! Define wet/dry mask on V-points. ! Vinfo( 1)=Vname(1,idVwet) Vinfo( 2)=Vname(2,idVwet) Vinfo( 3)=Vname(3,idVwet) Vinfo(14)=Vname(4,idVwet) Vinfo(16)=Vname(1,idtime) Vinfo( 9)='land' Vinfo(10)='water' Vinfo(21)=Vname(6,idVwet) Vinfo(22)='coordinates' Aval(5)=REAL(Iinfo(1,idVwet,ng),r8) status=def_var(ng, model, QCK(ng)%ncid, QCK(ng)%Vid(idVwet), & & NF_FOUT, nvd3, v2dgrd, Aval, Vinfo, ncname, & & SetFillVal = .FALSE.) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN #endif #ifdef SOLVE3D ! ! Define time-varying depth of RHO-points. ! IF (Qout(idpthR,ng)) THEN Vinfo( 1)=Vname(1,idpthR) WRITE (Vinfo( 2),40) TRIM(Vname(2,idpthR)) Vinfo( 3)=Vname(3,idpthR) Vinfo(14)=Vname(4,idpthR) Vinfo(16)=Vname(1,idtime) # if defined WRITE_WATER && defined MASKING Vinfo(20)='mask_rho' # endif Vinfo(21)=Vname(6,idpthR) Vinfo(22)='coordinates' Aval(5)=REAL(Iinfo(1,idpthR,ng),r8) status=def_var(ng, model, QCK(ng)%ncid, QCK(ng)%Vid(idpthR), & & NF_FOUT, nvd4, t3dgrd, Aval, Vinfo, ncname, & & SetFillVal = .FALSE.) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN END IF ! ! Define time-varying depth of U-points. ! IF (Qout(idpthU,ng)) THEN Vinfo( 1)=Vname(1,idpthU) WRITE (Vinfo( 2),40) TRIM(Vname(2,idpthU)) Vinfo( 3)=Vname(3,idpthU) Vinfo(14)=Vname(4,idpthU) Vinfo(16)=Vname(1,idtime) # if defined WRITE_WATER && defined MASKING Vinfo(20)='mask_u' # endif Vinfo(21)=Vname(6,idpthU) Vinfo(22)='coordinates' Aval(5)=REAL(Iinfo(1,idpthU,ng),r8) status=def_var(ng, model, QCK(ng)%ncid, QCK(ng)%Vid(idpthU), & & NF_FOUT, nvd4, u3dgrd, Aval, Vinfo, ncname, & & SetFillVal = .FALSE.) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN END IF ! ! Define time-varying depth of V-points. ! IF (Qout(idpthV,ng)) THEN Vinfo( 1)=Vname(1,idpthV) WRITE (Vinfo( 2),40) TRIM(Vname(2,idpthV)) Vinfo( 3)=Vname(3,idpthV) Vinfo(14)=Vname(4,idpthV) Vinfo(16)=Vname(1,idtime) # if defined WRITE_WATER && defined MASKING Vinfo(20)='mask_v' # endif Vinfo(21)=Vname(6,idpthV) Vinfo(22)='coordinates' Aval(5)=REAL(Iinfo(1,idpthV,ng),r8) status=def_var(ng, model, QCK(ng)%ncid, QCK(ng)%Vid(idpthV), & & NF_FOUT, nvd4, v3dgrd, Aval, Vinfo, ncname, & & SetFillVal = .FALSE.) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN END IF ! ! Define time-varying depth of W-points. ! IF (Qout(idpthW,ng)) THEN Vinfo( 1)=Vname(1,idpthW) WRITE (Vinfo( 2),40) TRIM(Vname(2,idpthW)) Vinfo( 3)=Vname(3,idpthW) Vinfo(14)=Vname(4,idpthW) Vinfo(16)=Vname(1,idtime) # if defined WRITE_WATER && defined MASKING Vinfo(20)='mask_rho' # endif Vinfo(21)=Vname(6,idpthW) Vinfo(22)='coordinates' Aval(5)=REAL(Iinfo(1,idpthW,ng),r8) status=def_var(ng, model, QCK(ng)%ncid, QCK(ng)%Vid(idpthW), & & NF_FOUT, nvd4, w3dgrd, Aval, Vinfo, ncname, & & SetFillVal = .FALSE.) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN END IF #endif ! ! Define free-surface. ! IF (Qout(idFsur,ng)) THEN Vinfo( 1)=Vname(1,idFsur) Vinfo( 2)=Vname(2,idFsur) Vinfo( 3)=Vname(3,idFsur) Vinfo(14)=Vname(4,idFsur) Vinfo(16)=Vname(1,idtime) #if defined WRITE_WATER && defined MASKING Vinfo(20)='mask_rho' #endif Vinfo(21)=Vname(6,idFsur) Vinfo(22)='coordinates' Aval(5)=REAL(Iinfo(1,idFsur,ng),r8) status=def_var(ng, model, QCK(ng)%ncid, QCK(ng)%Vid(idFsur), & #ifdef WET_DRY & NF_FOUT, nvd3, t2dgrd, Aval, Vinfo, ncname, & & SetFillVal = .FALSE.) #else & NF_FOUT, nvd3, t2dgrd, Aval, Vinfo, ncname) #endif IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN END IF ! ! Define 2D U-momentum component. ! IF (Qout(idUbar,ng)) THEN Vinfo( 1)=Vname(1,idUbar) Vinfo( 2)=Vname(2,idUbar) Vinfo( 3)=Vname(3,idUbar) Vinfo(14)=Vname(4,idUbar) Vinfo(16)=Vname(1,idtime) #if defined WRITE_WATER && defined MASKING Vinfo(20)='mask_u' #endif Vinfo(21)=Vname(6,idUbar) Vinfo(22)='coordinates' Aval(5)=REAL(Iinfo(1,idUbar,ng),r8) status=def_var(ng, model, QCK(ng)%ncid, QCK(ng)%Vid(idUbar), & & NF_FOUT, nvd3, u2dgrd, Aval, Vinfo, ncname) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN END IF ! ! Define 2D V-momentum component. ! IF (Qout(idVbar,ng)) THEN Vinfo( 1)=Vname(1,idVbar) Vinfo( 2)=Vname(2,idVbar) Vinfo( 3)=Vname(3,idVbar) Vinfo(14)=Vname(4,idVbar) Vinfo(16)=Vname(1,idtime) #if defined WRITE_WATER && defined MASKING Vinfo(20)='mask_v' #endif Vinfo(21)=Vname(6,idVbar) Vinfo(22)='coordinates' Aval(5)=REAL(Iinfo(1,idVbar,ng),r8) status=def_var(ng, model, QCK(ng)%ncid, QCK(ng)%Vid(idVbar), & & NF_FOUT, nvd3, v2dgrd, Aval, Vinfo, ncname) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN END IF ! ! Define 2D Eastward momentum component at RHO-points. ! IF (Qout(idu2dE,ng)) THEN Vinfo( 1)=Vname(1,idu2dE) Vinfo( 2)=Vname(2,idu2dE) Vinfo( 3)=Vname(3,idu2dE) Vinfo(14)=Vname(4,idu2dE) Vinfo(16)=Vname(1,idtime) #if defined WRITE_WATER && defined MASKING Vinfo(20)='mask_rho' #endif Vinfo(21)=Vname(6,idu2dE) Vinfo(22)='coordinates' Aval(5)=REAL(Iinfo(1,idu2dE,ng),r8) status=def_var(ng, model, QCK(ng)%ncid, QCK(ng)%Vid(idu2dE), & & NF_FOUT, nvd3, t2dgrd, Aval, Vinfo, ncname) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN END IF ! ! Define 2D Northward momentum component at RHO-points. ! IF (Qout(idv2dN,ng)) THEN Vinfo( 1)=Vname(1,idv2dN) Vinfo( 2)=Vname(2,idv2dN) Vinfo( 3)=Vname(3,idv2dN) Vinfo(14)=Vname(4,idv2dN) Vinfo(16)=Vname(1,idtime) #if defined WRITE_WATER && defined MASKING Vinfo(20)='mask_rho' #endif Vinfo(21)=Vname(6,idv2dN) Vinfo(22)='coordinates' Aval(5)=REAL(Iinfo(1,idv2dN,ng),r8) status=def_var(ng, model, QCK(ng)%ncid, QCK(ng)%Vid(idv2dN), & & NF_FOUT, nvd3, t2dgrd, Aval, Vinfo, ncname) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN END IF #ifdef SOLVE3D ! ! Define 3D U-momentum component. ! IF (Qout(idUvel,ng)) THEN Vinfo( 1)=Vname(1,idUvel) Vinfo( 2)=Vname(2,idUvel) Vinfo( 3)=Vname(3,idUvel) Vinfo(14)=Vname(4,idUvel) Vinfo(16)=Vname(1,idtime) # if defined WRITE_WATER && defined MASKING Vinfo(20)='mask_u' # endif Vinfo(21)=Vname(6,idUvel) Vinfo(22)='coordinates' Aval(5)=REAL(Iinfo(1,idUvel,ng),r8) status=def_var(ng, model, QCK(ng)%ncid, QCK(ng)%Vid(idUvel), & & NF_FOUT, nvd4, u3dgrd, Aval, Vinfo, ncname) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN END IF ! ! Define 3D V-momentum component. ! IF (Qout(idVvel,ng)) THEN Vinfo( 1)=Vname(1,idVvel) Vinfo( 2)=Vname(2,idVvel) Vinfo( 3)=Vname(3,idVvel) Vinfo(14)=Vname(4,idVvel) Vinfo(16)=Vname(1,idtime) # if defined WRITE_WATER && defined MASKING Vinfo(20)='mask_v' # endif Vinfo(21)=Vname(6,idVvel) Vinfo(22)='coordinates' Aval(5)=REAL(Iinfo(1,idVvel,ng),r8) status=def_var(ng, model, QCK(ng)%ncid, QCK(ng)%Vid(idVvel), & & NF_FOUT, nvd4, v3dgrd, Aval, Vinfo, ncname) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN END IF ! ! Define model surface U-momentum component. ! IF (Qout(idUsur,ng)) THEN Vinfo( 1)=Vname(1,idUsur) Vinfo( 2)=Vname(2,idUsur) Vinfo( 3)=Vname(3,idUsur) Vinfo(14)=Vname(4,idUsur) Vinfo(16)=Vname(1,idtime) # if defined WRITE_WATER && defined MASKING Vinfo(20)='mask_u' # endif Vinfo(21)=Vname(6,idUsur) Vinfo(22)='coordinates' Aval(5)=REAL(Iinfo(1,idUsur,ng),r8) status=def_var(ng, model, QCK(ng)%ncid, QCK(ng)%Vid(idUsur), & & NF_FOUT, nvd3, u2dgrd, Aval, Vinfo, ncname) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN END IF ! ! Define model surface V-momentum component. ! IF (Qout(idVsur,ng)) THEN Vinfo( 1)=Vname(1,idVsur) Vinfo( 2)=Vname(2,idVsur) Vinfo( 3)=Vname(3,idVsur) Vinfo(14)=Vname(4,idVsur) Vinfo(16)=Vname(1,idtime) # if defined WRITE_WATER && defined MASKING Vinfo(20)='mask_v' # endif Vinfo(21)=Vname(6,idVsur) Vinfo(22)='coordinates' Aval(5)=REAL(Iinfo(1,idVsur,ng),r8) status=def_var(ng, model, QCK(ng)%ncid, QCK(ng)%Vid(idVsur), & & NF_FOUT, nvd3, v2dgrd, Aval, Vinfo, ncname) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN END IF ! ! Define 3D Eastward momentum component at RHO-points. ! IF (Qout(idu3dE,ng)) THEN Vinfo( 1)=Vname(1,idu3dE) Vinfo( 2)=Vname(2,idu3dE) Vinfo( 3)=Vname(3,idu3dE) Vinfo(14)=Vname(4,idu3dE) Vinfo(16)=Vname(1,idtime) # if defined WRITE_WATER && defined MASKING Vinfo(20)='mask_rho' # endif Vinfo(21)=Vname(6,idu3dE) Vinfo(22)='coordinates' Aval(5)=REAL(Iinfo(1,idu3dE,ng),r8) status=def_var(ng, model, QCK(ng)%ncid, QCK(ng)%Vid(idu3dE), & & NF_FOUT, nvd4, t3dgrd, Aval, Vinfo, ncname) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN END IF ! ! Define 3D Northward momentum component at RHO-points. ! IF (Qout(idv3dN,ng)) THEN Vinfo( 1)=Vname(1,idv3dN) Vinfo( 2)=Vname(2,idv3dN) Vinfo( 3)=Vname(3,idv3dN) Vinfo(14)=Vname(4,idv3dN) Vinfo(16)=Vname(1,idtime) # if defined WRITE_WATER && defined MASKING Vinfo(20)='mask_rho' # endif Vinfo(21)=Vname(6,idv3dN) Vinfo(22)='coordinates' Aval(5)=REAL(Iinfo(1,idv3dN,ng),r8) status=def_var(ng, model, QCK(ng)%ncid, QCK(ng)%Vid(idv3dN), & & NF_FOUT, nvd4, t3dgrd, Aval, Vinfo, ncname) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN END IF ! ! Define model surface Eastward momentum component at RHO-points. ! IF (Qout(idUsuE,ng)) THEN Vinfo( 1)=Vname(1,idUsuE) Vinfo( 2)=Vname(2,idUsuE) Vinfo( 3)=Vname(3,idUsuE) Vinfo(14)=Vname(4,idUsuE) Vinfo(16)=Vname(1,idtime) # if defined WRITE_WATER && defined MASKING Vinfo(20)='mask_rho' # endif Vinfo(21)=Vname(6,idUsuE) Vinfo(22)='coordinates' Aval(5)=REAL(Iinfo(1,idUsuE,ng),r8) status=def_var(ng, model, QCK(ng)%ncid, QCK(ng)%Vid(idUsuE), & & NF_FOUT, nvd3, t2dgrd, Aval, Vinfo, ncname) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN END IF ! ! Define model surface Northward momentum component at RHO-points. ! IF (Qout(idVsuN,ng)) THEN Vinfo( 1)=Vname(1,idVsuN) Vinfo( 2)=Vname(2,idVsuN) Vinfo( 3)=Vname(3,idVsuN) Vinfo(14)=Vname(4,idVsuN) Vinfo(16)=Vname(1,idtime) # if defined WRITE_WATER && defined MASKING Vinfo(20)='mask_rho' # endif Vinfo(21)=Vname(6,idVsuN) Vinfo(22)='coordinates' Aval(5)=REAL(Iinfo(1,idVsuN,ng),r8) status=def_var(ng, model, QCK(ng)%ncid, QCK(ng)%Vid(idVsuN), & & NF_FOUT, nvd3, t2dgrd, Aval, Vinfo, ncname) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN END IF ! ! Define 3D momentum component in the S-direction. ! IF (Qout(idWvel,ng)) THEN Vinfo( 1)=Vname(1,idWvel) Vinfo( 2)=Vname(2,idWvel) Vinfo( 3)=Vname(3,idWvel) Vinfo(14)=Vname(4,idWvel) Vinfo(16)=Vname(1,idtime) # if defined WRITE_WATER && defined MASKING Vinfo(20)='mask_rho' # endif Vinfo(21)=Vname(6,idWvel) Vinfo(22)='coordinates' Aval(5)=REAL(Iinfo(1,idWvel,ng),r8) status=def_var(ng, model, QCK(ng)%ncid, QCK(ng)%Vid(idWvel), & & NF_FOUT, nvd4, w3dgrd, Aval, Vinfo, ncname) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN END IF ! ! Define S-coordinate vertical "omega" momentum component. ! IF (Qout(idOvel,ng)) THEN Vinfo( 1)=Vname(1,idOvel) Vinfo( 2)=Vname(2,idOvel) Vinfo( 3)='meter second-1' Vinfo(14)=Vname(4,idOvel) Vinfo(16)=Vname(1,idtime) # if defined WRITE_WATER && defined MASKING Vinfo(20)='mask_rho' # endif Vinfo(21)=Vname(6,idOvel) Vinfo(22)='coordinates' Aval(5)=REAL(Iinfo(1,idOvel,ng),r8) status=def_var(ng, model, QCK(ng)%ncid, QCK(ng)%Vid(idOvel), & & NF_FOUT, nvd4, w3dgrd, Aval, Vinfo, ncname) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN END IF ! ! Define tracer type variables. ! DO itrc=1,NT(ng) IF (Qout(idTvar(itrc),ng)) THEN Vinfo( 1)=Vname(1,idTvar(itrc)) Vinfo( 2)=Vname(2,idTvar(itrc)) Vinfo( 3)=Vname(3,idTvar(itrc)) Vinfo(14)=Vname(4,idTvar(itrc)) Vinfo(16)=Vname(1,idtime) # ifdef SEDIMENT DO i=1,NST IF (itrc.eq.idsed(i)) THEN WRITE (Vinfo(19),50) 1000.0_r8*Sd50(i,ng) END IF END DO # endif # if defined WRITE_WATER && defined MASKING Vinfo(20)='mask_rho' # endif Vinfo(21)=Vname(6,idTvar(itrc)) Vinfo(22)='coordinates' Aval(5)=REAL(Iinfo(1,idTvar(itrc),ng),r8) status=def_var(ng, model, QCK(ng)%ncid, QCK(ng)%Tid(itrc), & & NF_FOUT, nvd4, t3dgrd, Aval, Vinfo, ncname) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN END IF END DO ! ! Define surface tracer type variables. ! DO itrc=1,NT(ng) IF (Qout(idsurT(itrc),ng)) THEN Vinfo( 1)=Vname(1,idsurT(itrc)) Vinfo( 2)=Vname(2,idsurT(itrc)) Vinfo( 3)=Vname(3,idsurT(itrc)) Vinfo(14)=Vname(4,idsurT(itrc)) Vinfo(16)=Vname(1,idtime) # ifdef SEDIMENT DO i=1,NST IF (itrc.eq.idsed(i)) THEN WRITE (Vinfo(19),50) 1000.0_r8*Sd50(i,ng) END IF END DO # endif # if defined WRITE_WATER && defined MASKING Vinfo(20)='mask_rho' # endif Vinfo(21)=Vname(6,idsurT(itrc)) Vinfo(22)='coordinates' Aval(5)=REAL(r2dvar,r8) status=def_var(ng, model, QCK(ng)%ncid, & & QCK(ng)%Vid(idsurT(itrc)), & & NF_FOUT, nvd3, t2dgrd, Aval, Vinfo, ncname) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN END IF END DO ! ! Define density anomaly. ! IF (Qout(idDano,ng)) THEN Vinfo( 1)=Vname(1,idDano) Vinfo( 2)=Vname(2,idDano) Vinfo( 3)=Vname(3,idDano) Vinfo(14)=Vname(4,idDano) Vinfo(16)=Vname(1,idtime) # if defined WRITE_WATER && defined MASKING Vinfo(20)='mask_rho' # endif Vinfo(21)=Vname(6,idDano) Vinfo(22)='coordinates' Aval(5)=REAL(Iinfo(1,idDano,ng),r8) status=def_var(ng, model, QCK(ng)%ncid, QCK(ng)%Vid(idDano), & & NF_FOUT, nvd4, t3dgrd, Aval, Vinfo, ncname) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN END IF # ifdef LMD_SKPP ! ! Define depth of surface boundary layer. ! IF (Qout(idHsbl,ng)) THEN Vinfo( 1)=Vname(1,idHsbl) Vinfo( 2)=Vname(2,idHsbl) Vinfo( 3)=Vname(3,idHsbl) Vinfo(14)=Vname(4,idHsbl) Vinfo(16)=Vname(1,idtime) # if defined WRITE_WATER && defined MASKING Vinfo(20)='mask_rho' # endif Vinfo(21)=Vname(6,idHsbl) Vinfo(22)='coordinates' Aval(5)=REAL(Iinfo(1,idHsbl,ng),r8) status=def_var(ng, model, QCK(ng)%ncid, QCK(ng)%Vid(idHsbl), & & NF_FOUT, nvd3, t2dgrd, Aval, Vinfo, ncname) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN END IF # endif # ifdef LMD_BKPP ! ! Define depth of bottom boundary layer. ! IF (Qout(idHbbl,ng)) THEN Vinfo( 1)=Vname(1,idHbbl) Vinfo( 2)=Vname(2,idHbbl) Vinfo( 3)=Vname(3,idHbbl) Vinfo(14)=Vname(4,idHbbl) Vinfo(16)=Vname(1,idtime) # if defined WRITE_WATER && defined MASKING Vinfo(20)='mask_rho' # endif Vinfo(21)=Vname(6,idHbbl) Vinfo(22)='coordinates' Aval(5)=REAL(Iinfo(1,idHbbl,ng),r8) status=def_var(ng, model, QCK(ng)%ncid, QCK(ng)%Vid(idHbbl), & & NF_FOUT, nvd3, t2dgrd, Aval, Vinfo, ncname) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN END IF # endif ! ! Define vertical viscosity coefficient. ! IF (Qout(idVvis,ng)) THEN Vinfo( 1)=Vname(1,idVvis) Vinfo( 2)=Vname(2,idVvis) Vinfo( 3)=Vname(3,idVvis) Vinfo(14)=Vname(4,idVvis) Vinfo(16)=Vname(1,idtime) # if defined WRITE_WATER && defined MASKING Vinfo(20)='mask_rho' # endif Vinfo(21)=Vname(6,idVvis) Vinfo(22)='coordinates' Aval(5)=REAL(Iinfo(1,idVvis,ng),r8) status=def_var(ng, model, QCK(ng)%ncid, QCK(ng)%Vid(idVvis), & & NF_FOUT, nvd4, w3dgrd, Aval, Vinfo, ncname, & & SetFillVal = .FALSE.) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN END IF ! ! Define vertical diffusion coefficient for potential temperature. ! IF (Qout(idTdif,ng)) THEN Vinfo( 1)=Vname(1,idTdif) Vinfo( 2)=Vname(2,idTdif) Vinfo( 3)=Vname(3,idTdif) Vinfo(14)=Vname(4,idTdif) Vinfo(16)=Vname(1,idtime) # if defined WRITE_WATER && defined MASKING Vinfo(20)='mask_rho' # endif Vinfo(21)=Vname(6,idTdif) Vinfo(22)='coordinates' Aval(5)=REAL(Iinfo(1,idTdif,ng),r8) status=def_var(ng, model, QCK(ng)%ncid, QCK(ng)%Vid(idTdif), & & NF_FOUT, nvd4, w3dgrd, Aval, Vinfo, ncname, & & SetFillVal = .FALSE.) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN END IF # ifdef SALINITY ! ! Define vertical diffusion coefficient for salinity. ! IF (Qout(idSdif,ng)) THEN Vinfo( 1)=Vname(1,idSdif) Vinfo( 2)=Vname(2,idSdif) Vinfo( 3)=Vname(3,idSdif) Vinfo(14)=Vname(4,idSdif) Vinfo(16)=Vname(1,idtime) # if defined WRITE_WATER && defined MASKING Vinfo(20)='mask_rho' # endif Vinfo(21)=Vname(6,idSdif) Vinfo(22)='coordinates' Aval(5)=REAL(Iinfo(1,idSdif,ng),r8) status=def_var(ng, model, QCK(ng)%ncid, QCK(ng)%Vid(idSdif), & & NF_FOUT, nvd4, w3dgrd, Aval, Vinfo, ncname, & & SetFillVal = .FALSE.) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN END IF # endif # if defined GLS_MIXING || defined MY25_MIXING ! ! Define turbulent kinetic energy. ! IF (Qout(idMtke,ng)) THEN Vinfo( 1)=Vname(1,idMtke) Vinfo( 2)=Vname(2,idMtke) Vinfo( 3)=Vname(3,idMtke) Vinfo(14)=Vname(4,idMtke) Vinfo(16)=Vname(1,idtime) # if defined WRITE_WATER && defined MASKING Vinfo(20)='mask_rho' # endif Vinfo(21)=Vname(6,idMtke) Vinfo(22)='coordinates' Aval(5)=REAL(Iinfo(1,idMtke,ng),r8) status=def_var(ng, model, QCK(ng)%ncid, QCK(ng)%Vid(idMtke), & & NF_FOUT, nvd4, w3dgrd, Aval, Vinfo, ncname, & & SetFillVal = .FALSE.) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN END IF ! ! Define turbulent kinetic energy time length scale. ! IF (Qout(idMtls,ng)) THEN Vinfo( 1)=Vname(1,idMtls) Vinfo( 2)=Vname(2,idMtls) Vinfo( 3)=Vname(3,idMtls) Vinfo(14)=Vname(4,idMtls) Vinfo(16)=Vname(1,idtime) # if defined WRITE_WATER && defined MASKING Vinfo(20)='mask_rho' # endif Vinfo(21)=Vname(6,idMtls) Vinfo(22)='coordinates' Aval(5)=REAL(Iinfo(1,idMtls,ng),r8) status=def_var(ng, model, QCK(ng)%ncid, QCK(ng)%Vid(idMtls), & & NF_FOUT, nvd4, w3dgrd, Aval, Vinfo, ncname, & & SetFillVal = .FALSE.) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN END IF # endif # if defined BULK_FLUXES || defined ECOSIM || defined ATM_PRESS ! ! Define surface air pressure. ! IF (Qout(idPair,ng)) THEN Vinfo( 1)=Vname(1,idPair) Vinfo( 2)=Vname(2,idPair) Vinfo( 3)=Vname(3,idPair) Vinfo(14)=Vname(4,idPair) Vinfo(16)=Vname(1,idtime) # if defined WRITE_WATER && defined MASKING Vinfo(20)='mask_rho' # endif Vinfo(21)=Vname(6,idPair) Vinfo(22)='coordinates' Aval(5)=REAL(Iinfo(1,idPair,ng),r8) status=def_var(ng, model, QCK(ng)%ncid, QCK(ng)%Vid(idPair), & & NF_FOUT, nvd3, t2dgrd, Aval, Vinfo, ncname) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN END IF # endif # if defined BULK_FLUXES || defined ECOSIM ! ! Define surface winds. ! IF (Qout(idUair,ng)) THEN Vinfo( 1)=Vname(1,idUair) Vinfo( 2)=Vname(2,idUair) Vinfo( 3)=Vname(3,idUair) Vinfo(14)=Vname(4,idUair) Vinfo(16)=Vname(1,idtime) # if defined WRITE_WATER && defined MASKING Vinfo(20)='mask_rho' # endif Vinfo(21)=Vname(6,idUair) Vinfo(22)='coordinates' Aval(5)=REAL(Iinfo(1,idUair,ng),r8) status=def_var(ng, model, QCK(ng)%ncid, QCK(ng)%Vid(idUair), & & NF_FOUT, nvd3, t2dgrd, Aval, Vinfo, ncname) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN END IF ! IF (Qout(idVair,ng)) THEN Vinfo( 1)=Vname(1,idVair) Vinfo( 2)=Vname(2,idVair) Vinfo( 3)=Vname(3,idVair) Vinfo(14)=Vname(4,idVair) Vinfo(16)=Vname(1,idtime) # if defined WRITE_WATER && defined MASKING Vinfo(20)='mask_rho' # endif Vinfo(21)=Vname(6,idVair) Vinfo(22)='coordinates' Aval(5)=REAL(Iinfo(1,idVair,ng),r8) status=def_var(ng, model, QCK(ng)%ncid, QCK(ng)%Vid(idVair), & & NF_FOUT, nvd3, t2dgrd, Aval, Vinfo, ncname) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN END IF ! ! Define Eastward/Northward surface winds at RHO-points. ! IF (Qout(idUaiE,ng)) THEN Vinfo( 1)=Vname(1,idUaiE) Vinfo( 2)=Vname(2,idUaiE) Vinfo( 3)=Vname(3,idUaiE) Vinfo(14)=Vname(4,idUaiE) Vinfo(16)=Vname(1,idtime) # if defined WRITE_WATER && defined MASKING Vinfo(20)='mask_rho' # endif Vinfo(21)=Vname(6,idUaiE) Vinfo(22)='coordinates' Aval(5)=REAL(Iinfo(1,idUaiE,ng),r8) status=def_var(ng, model, QCK(ng)%ncid, QCK(ng)%Vid(idUaiE), & & NF_FOUT, nvd3, t2dgrd, Aval, Vinfo, ncname) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN END IF ! IF (Qout(idVaiN,ng)) THEN Vinfo( 1)=Vname(1,idVaiN) Vinfo( 2)=Vname(2,idVaiN) Vinfo( 3)=Vname(3,idVaiN) Vinfo(14)=Vname(4,idVaiN) Vinfo(16)=Vname(1,idtime) # if defined WRITE_WATER && defined MASKING Vinfo(20)='mask_rho' # endif Vinfo(21)=Vname(6,idVaiN) Vinfo(22)='coordinates' Aval(5)=REAL(Iinfo(1,idVaiN,ng),r8) status=def_var(ng, model, QCK(ng)%ncid, QCK(ng)%Vid(idVaiN), & & NF_FOUT, nvd3, t2dgrd, Aval, Vinfo, ncname) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN END IF # endif ! ! Define surface active tracer fluxes. ! DO itrc=1,NAT IF (Qout(idTsur(itrc),ng)) THEN Vinfo( 1)=Vname(1,idTsur(itrc)) Vinfo( 2)=Vname(2,idTsur(itrc)) Vinfo( 3)=Vname(3,idTsur(itrc)) IF (itrc.eq.itemp) THEN Vinfo(11)='upward flux, cooling' Vinfo(12)='downward flux, heating' ELSE IF (itrc.eq.isalt) THEN Vinfo(11)='upward flux, freshening (net precipitation)' Vinfo(12)='downward flux, salting (net evaporation)' END IF Vinfo(14)=Vname(4,idTsur(itrc)) Vinfo(16)=Vname(1,idtime) # if defined WRITE_WATER && defined MASKING Vinfo(20)='mask_rho' # endif Vinfo(21)=Vname(6,idTsur(itrc)) Vinfo(22)='coordinates' Aval(5)=REAL(Iinfo(1,idTsur(itrc),ng),r8) status=def_var(ng, model, QCK(ng)%ncid, & & QCK(ng)%Vid(idTsur(itrc)), NF_FOUT, & & nvd3, t2dgrd, Aval, Vinfo, ncname) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN END IF END DO # if defined BULK_FLUXES || defined FRC_COUPLING ! ! Define latent heat flux. ! IF (Qout(idLhea,ng)) THEN Vinfo( 1)=Vname(1,idLhea) Vinfo( 2)=Vname(2,idLhea) Vinfo( 3)=Vname(3,idLhea) Vinfo(11)='upward flux, cooling' Vinfo(12)='downward flux, heating' Vinfo(14)=Vname(4,idLhea) Vinfo(16)=Vname(1,idtime) # if defined WRITE_WATER && defined MASKING Vinfo(20)='mask_rho' # endif Vinfo(21)=Vname(6,idLhea) Vinfo(22)='coordinates' Aval(5)=REAL(Iinfo(1,idLhea,ng),r8) status=def_var(ng, model, QCK(ng)%ncid, QCK(ng)%Vid(idLhea), & & NF_FOUT, nvd3, t2dgrd, Aval, Vinfo, ncname) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN END IF ! ! Define sensible heat flux. ! IF (Qout(idShea,ng)) THEN Vinfo( 1)=Vname(1,idShea) Vinfo( 2)=Vname(2,idShea) Vinfo( 3)=Vname(3,idShea) Vinfo(11)='upward flux, cooling' Vinfo(12)='downward flux, heating' Vinfo(14)=Vname(4,idShea) Vinfo(16)=Vname(1,idtime) # if defined WRITE_WATER && defined MASKING Vinfo(20)='mask_rho' # endif Vinfo(21)=Vname(6,idShea) Vinfo(22)='coordinates' Aval(5)=REAL(Iinfo(1,idShea,ng),r8) status=def_var(ng, model, QCK(ng)%ncid, QCK(ng)%Vid(idShea), & & NF_FOUT, nvd3, t2dgrd, Aval, Vinfo, ncname) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN END IF ! ! Define net longwave radiation flux. ! IF (Qout(idLrad,ng)) THEN Vinfo( 1)=Vname(1,idLrad) Vinfo( 2)=Vname(2,idLrad) Vinfo( 3)=Vname(3,idLrad) Vinfo(11)='upward flux, cooling' Vinfo(12)='downward flux, heating' Vinfo(14)=Vname(4,idLrad) Vinfo(16)=Vname(1,idtime) # if defined WRITE_WATER && defined MASKING Vinfo(20)='mask_rho' # endif Vinfo(21)=Vname(6,idLrad) Vinfo(22)='coordinates' Aval(5)=REAL(Iinfo(1,idLrad,ng),r8) status=def_var(ng, model, QCK(ng)%ncid, QCK(ng)%Vid(idLrad), & & NF_FOUT, nvd3, t2dgrd, Aval, Vinfo, ncname) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN END IF # endif # if defined BULK_FLUXES ! ! Define atmospheric air temperature. ! IF (Qout(idTair,ng)) THEN Vinfo( 1)=Vname(1,idTair) Vinfo( 2)=Vname(2,idTair) Vinfo( 3)=Vname(3,idTair) Vinfo(14)=Vname(4,idTair) Vinfo(16)=Vname(1,idtime) # if defined WRITE_WATER && defined MASKING Vinfo(20)='mask_rho' # endif Vinfo(21)=Vname(6,idTair) Vinfo(22)='coordinates' Aval(5)=REAL(Iinfo(1,idTair,ng),r8) status=def_var(ng, model, QCK(ng)%ncid, QCK(ng)%Vid(idTair), & & NF_FOUT, nvd3, t2dgrd, Aval, Vinfo, ncname) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN END IF # ifdef EMINUSP ! ! Define evaporation rate. ! IF (Qout(idevap,ng)) THEN Vinfo( 1)=Vname(1,idevap) Vinfo( 2)=Vname(2,idevap) Vinfo( 3)=Vname(3,idevap) Vinfo(11)='downward flux, freshening (condensation)' Vinfo(12)='upward flux, salting (evaporation)' Vinfo(14)=Vname(4,idevap) Vinfo(16)=Vname(1,idtime) # if defined WRITE_WATER && defined MASKING Vinfo(20)='mask_rho' # endif Vinfo(21)=Vname(6,idevap) Vinfo(22)='coordinates' Aval(5)=REAL(Iinfo(1,idevap,ng),r8) status=def_var(ng, model, QCK(ng)%ncid, QCK(ng)%Vid(idevap), & & NF_FOUT, nvd3, t2dgrd, Aval, Vinfo, ncname) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN END IF ! ! Define precipitation rate. ! IF (Qout(idrain,ng)) THEN Vinfo( 1)=Vname(1,idrain) Vinfo( 2)=Vname(2,idrain) Vinfo( 3)=Vname(3,idrain) Vinfo(11)='upward flux, salting (NOT POSSIBLE)' Vinfo(12)='downward flux, freshening (precipitation)' Vinfo(14)=Vname(4,idrain) Vinfo(16)=Vname(1,idtime) # if defined WRITE_WATER && defined MASKING Vinfo(20)='mask_rho' # endif Vinfo(21)=Vname(6,idrain) Vinfo(22)='coordinates' Aval(5)=REAL(Iinfo(1,idrain,ng),r8) status=def_var(ng, model, QCK(ng)%ncid, QCK(ng)%Vid(idrain), & & NF_FOUT, nvd3, t2dgrd, Aval, Vinfo, ncname) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN END IF # endif # endif ! ! Define E-P flux. ! IF (Qout(idEmPf,ng)) THEN Vinfo( 1)=Vname(1,idEmPf) Vinfo( 2)=Vname(2,idEmPf) Vinfo( 3)=Vname(3,idEmPf) Vinfo(11)='upward flux, freshening (net precipitation)' Vinfo(12)='downward flux, salting (net evaporation)' Vinfo(14)=Vname(4,idEmPf) Vinfo(16)=Vname(1,idtime) # if defined WRITE_WATER && defined MASKING Vinfo(20)='mask_rho' # endif Vinfo(21)=Vname(6,idEmPf) Vinfo(22)='coordinates' Aval(5)=REAL(Iinfo(1,idEmPf,ng),r8) status=def_var(ng, model, QCK(ng)%ncid, QCK(ng)%Vid(idEmPf), & & NF_FOUT, nvd3, t2dgrd, Aval, Vinfo, ncname) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN END IF # ifdef SHORTWAVE ! ! Define net shortwave radiation flux. ! IF (Qout(idSrad,ng)) THEN Vinfo( 1)=Vname(1,idSrad) Vinfo( 2)=Vname(2,idSrad) Vinfo( 3)=Vname(3,idSrad) Vinfo(11)='upward flux, cooling' Vinfo(12)='downward flux, heating' Vinfo(14)=Vname(4,idSrad) Vinfo(16)=Vname(1,idtime) # if defined WRITE_WATER && defined MASKING Vinfo(20)='mask_rho' # endif Vinfo(21)=Vname(6,idSrad) Vinfo(22)='coordinates' Aval(5)=REAL(Iinfo(1,idSrad,ng),r8) status=def_var(ng, model, QCK(ng)%ncid, QCK(ng)%Vid(idSrad), & & NF_FOUT, nvd3, t2dgrd, Aval, Vinfo, ncname) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN END IF # endif #endif ! ! Define surface U-momentum stress. ! IF (Qout(idUsms,ng)) THEN Vinfo( 1)=Vname(1,idUsms) Vinfo( 2)=Vname(2,idUsms) Vinfo( 3)=Vname(3,idUsms) Vinfo(14)=Vname(4,idUsms) Vinfo(16)=Vname(1,idtime) #if defined WRITE_WATER && defined MASKING Vinfo(20)='mask_u' #endif Vinfo(21)=Vname(6,idUsms) Vinfo(22)='coordinates' Aval(5)=REAL(Iinfo(1,idUsms,ng),r8) status=def_var(ng, model, QCK(ng)%ncid, QCK(ng)%Vid(idUsms), & & NF_FOUT, nvd3, u2dgrd, Aval, Vinfo, ncname) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN END IF ! ! Define surface V-momentum stress. ! IF (Qout(idVsms,ng)) THEN Vinfo( 1)=Vname(1,idVsms) Vinfo( 2)=Vname(2,idVsms) Vinfo( 3)=Vname(3,idVsms) Vinfo(14)=Vname(4,idVsms) Vinfo(16)=Vname(1,idtime) #if defined WRITE_WATER && defined MASKING Vinfo(20)='mask_v' #endif Vinfo(21)=Vname(6,idVsms) Vinfo(22)='coordinates' Aval(5)=REAL(Iinfo(1,idVsms,ng),r8) status=def_var(ng, model, QCK(ng)%ncid, QCK(ng)%Vid(idVsms), & & NF_FOUT, nvd3, v2dgrd, Aval, Vinfo, ncname) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN END IF ! ! Define bottom U-momentum stress. ! IF (Qout(idUbms,ng)) THEN Vinfo( 1)=Vname(1,idUbms) Vinfo( 2)=Vname(2,idUbms) Vinfo( 3)=Vname(3,idUbms) Vinfo(14)=Vname(4,idUbms) Vinfo(16)=Vname(1,idtime) #if defined WRITE_WATER && defined MASKING Vinfo(20)='mask_u' #endif Vinfo(21)=Vname(6,idUbms) Vinfo(22)='coordinates' Aval(5)=REAL(Iinfo(1,idUbms,ng),r8) status=def_var(ng, model, QCK(ng)%ncid, QCK(ng)%Vid(idUbms), & & NF_FOUT, nvd3, u2dgrd, Aval, Vinfo, ncname) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN END IF ! ! Define bottom V-momentum stress. ! IF (Qout(idVbms,ng)) THEN Vinfo( 1)=Vname(1,idVbms) Vinfo( 2)=Vname(2,idVbms) Vinfo( 3)=Vname(3,idVbms) Vinfo(14)=Vname(4,idVbms) Vinfo(16)=Vname(1,idtime) #if defined WRITE_WATER && defined MASKING Vinfo(20)='mask_v' #endif Vinfo(21)=Vname(6,idVbms) Vinfo(22)='coordinates' Aval(5)=REAL(Iinfo(1,idVbms,ng),r8) status=def_var(ng, model, QCK(ng)%ncid, QCK(ng)%Vid(idVbms), & & NF_FOUT, nvd3, v2dgrd, Aval, Vinfo, ncname) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN END IF #if (defined BBL_MODEL || defined WAVES_OUTPUT) && defined SOLVE3D ! !----------------------------------------------------------------------- ! Define the bottom boundary layer model or waves variables. !----------------------------------------------------------------------- ! CALL bbl_def_nf90 (ng, model, ldef, Qout, QCK, & & t2dgrd, u2dgrd, v2dgrd) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN #endif #if defined ICE_MODEL && defined SOLVE3D ! !----------------------------------------------------------------------- ! Define the sea-ice model variables. !----------------------------------------------------------------------- ! CALL ice_def_nf90 (ng, model, ldef, Qout, QCK, & & t2dgrd, u2dgrd, v2dgrd) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN #endif #if defined SEDIMENT && defined SOLVE3D ! !----------------------------------------------------------------------- ! Define the sediment model variables. !----------------------------------------------------------------------- ! CALL sediment_def_nf90 (ng, model, ldef, Qout, QCK, & & t2dgrd, u2dgrd, v2dgrd, & & b3dgrd) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN #endif #if defined WEC_VF && defined SOLVE3D ! !----------------------------------------------------------------------- ! Define the Waves Effect on Currents variables. !----------------------------------------------------------------------- ! CALL wec_def_nf90 (ng, model, ldef, Qout, QCK, & & t2dgrd, u2dgrd, v2dgrd, & & t3dgrd, u3dgrd, v3dgrd, w3dgrd) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN #endif ! !----------------------------------------------------------------------- ! Leave definition mode. !----------------------------------------------------------------------- ! CALL netcdf_enddef (ng, model, ncname, QCK(ng)%ncid) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN ! !----------------------------------------------------------------------- ! Write out time-recordless, information variables. !----------------------------------------------------------------------- ! CALL wrt_info (ng, model, QCK(ng)%ncid, ncname) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN END IF DEFINE ! !======================================================================= ! Open an existing quicksave file, check its contents, and prepare ! for appending data. !======================================================================= ! QUERY : IF (.not.ldef) THEN ncname=QCK(ng)%name ! ! Open quicksave file for read/write. ! CALL netcdf_open (ng, model, ncname, 1, QCK(ng)%ncid) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) THEN WRITE (stdout,60) TRIM(ncname) RETURN END IF ! ! Inquire about the dimensions and check for consistency. ! CALL netcdf_check_dim (ng, model, ncname, & & ncid = QCK(ng)%ncid) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN ! ! Inquire about the variables. ! CALL netcdf_inq_var (ng, model, ncname, & & ncid = QCK(ng)%ncid) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN ! ! Initialize logical switches. ! DO i=1,NV got_var(i)=.FALSE. END DO ! ! Scan variable list from input NetCDF and activate switches for ! quicksave variables. Get variable IDs. ! DO i=1,n_var IF (TRIM(var_name(i)).eq.TRIM(Vname(1,idtime))) THEN got_var(idtime)=.TRUE. QCK(ng)%Vid(idtime)=var_id(i) #if defined WET_DRY ELSE IF (TRIM(var_name(i)).eq.TRIM(Vname(1,idPwet))) THEN got_var(idPwet)=.TRUE. QCK(ng)%Vid(idPwet)=var_id(i) ELSE IF (TRIM(var_name(i)).eq.TRIM(Vname(1,idRwet))) THEN got_var(idRwet)=.TRUE. QCK(ng)%Vid(idRwet)=var_id(i) ELSE IF (TRIM(var_name(i)).eq.TRIM(Vname(1,idUwet))) THEN got_var(idUwet)=.TRUE. QCK(ng)%Vid(idUwet)=var_id(i) ELSE IF (TRIM(var_name(i)).eq.TRIM(Vname(1,idVwet))) THEN got_var(idVwet)=.TRUE. QCK(ng)%Vid(idVwet)=var_id(i) #endif #ifdef SOLVE3D ELSE IF (TRIM(var_name(i)).eq.TRIM(Vname(1,idpthR))) THEN got_var(idpthR)=.TRUE. QCK(ng)%Vid(idpthR)=var_id(i) ELSE IF (TRIM(var_name(i)).eq.TRIM(Vname(1,idpthU))) THEN got_var(idpthU)=.TRUE. QCK(ng)%Vid(idpthU)=var_id(i) ELSE IF (TRIM(var_name(i)).eq.TRIM(Vname(1,idpthV))) THEN got_var(idpthV)=.TRUE. QCK(ng)%Vid(idpthV)=var_id(i) ELSE IF (TRIM(var_name(i)).eq.TRIM(Vname(1,idpthW))) THEN got_var(idpthW)=.TRUE. QCK(ng)%Vid(idpthW)=var_id(i) #endif ELSE IF (TRIM(var_name(i)).eq.TRIM(Vname(1,idFsur))) THEN got_var(idFsur)=.TRUE. QCK(ng)%Vid(idFsur)=var_id(i) ELSE IF (TRIM(var_name(i)).eq.TRIM(Vname(1,idUbar))) THEN got_var(idUbar)=.TRUE. QCK(ng)%Vid(idUbar)=var_id(i) ELSE IF (TRIM(var_name(i)).eq.TRIM(Vname(1,idVbar))) THEN got_var(idVbar)=.TRUE. QCK(ng)%Vid(idVbar)=var_id(i) ELSE IF (TRIM(var_name(i)).eq.TRIM(Vname(1,idu2dE))) THEN got_var(idu2dE)=.TRUE. QCK(ng)%Vid(idu2dE)=var_id(i) ELSE IF (TRIM(var_name(i)).eq.TRIM(Vname(1,idv2dN))) THEN got_var(idv2dN)=.TRUE. QCK(ng)%Vid(idv2dN)=var_id(i) #ifdef SOLVE3D ELSE IF (TRIM(var_name(i)).eq.TRIM(Vname(1,idUvel))) THEN got_var(idUvel)=.TRUE. QCK(ng)%Vid(idUvel)=var_id(i) ELSE IF (TRIM(var_name(i)).eq.TRIM(Vname(1,idVvel))) THEN got_var(idVvel)=.TRUE. QCK(ng)%Vid(idVvel)=var_id(i) ELSE IF (TRIM(var_name(i)).eq.TRIM(Vname(1,idUsur))) THEN got_var(idUsur)=.TRUE. QCK(ng)%Vid(idUsur)=var_id(i) ELSE IF (TRIM(var_name(i)).eq.TRIM(Vname(1,idVsur))) THEN got_var(idVsur)=.TRUE. QCK(ng)%Vid(idVsur)=var_id(i) ELSE IF (TRIM(var_name(i)).eq.TRIM(Vname(1,idu3dE))) THEN got_var(idu3dE)=.TRUE. QCK(ng)%Vid(idu3dE)=var_id(i) ELSE IF (TRIM(var_name(i)).eq.TRIM(Vname(1,idv3dN))) THEN got_var(idv3dN)=.TRUE. QCK(ng)%Vid(idv3dN)=var_id(i) ELSE IF (TRIM(var_name(i)).eq.TRIM(Vname(1,idUsuE))) THEN got_var(idUsuE)=.TRUE. QCK(ng)%Vid(idUsuE)=var_id(i) ELSE IF (TRIM(var_name(i)).eq.TRIM(Vname(1,idVsuN))) THEN got_var(idVsuN)=.TRUE. QCK(ng)%Vid(idVsuN)=var_id(i) ELSE IF (TRIM(var_name(i)).eq.TRIM(Vname(1,idWvel))) THEN got_var(idWvel)=.TRUE. QCK(ng)%Vid(idWvel)=var_id(i) ELSE IF (TRIM(var_name(i)).eq.TRIM(Vname(1,idOvel))) THEN got_var(idOvel)=.TRUE. QCK(ng)%Vid(idOvel)=var_id(i) ELSE IF (TRIM(var_name(i)).eq.TRIM(Vname(1,idDano))) THEN got_var(idDano)=.TRUE. QCK(ng)%Vid(idDano)=var_id(i) # ifdef LMD_SKPP ELSE IF (TRIM(var_name(i)).eq.TRIM(Vname(1,idHsbl))) THEN got_var(idHsbl)=.TRUE. QCK(ng)%Vid(idHsbl)=var_id(i) # endif # ifdef LMD_BKPP ELSE IF (TRIM(var_name(i)).eq.TRIM(Vname(1,idHbbl))) THEN got_var(idHbbl)=.TRUE. QCK(ng)%Vid(idHbbl)=var_id(i) # endif ELSE IF (TRIM(var_name(i)).eq.TRIM(Vname(1,idVvis))) THEN got_var(idVvis)=.TRUE. QCK(ng)%Vid(idVvis)=var_id(i) ELSE IF (TRIM(var_name(i)).eq.TRIM(Vname(1,idTdif))) THEN got_var(idTdif)=.TRUE. QCK(ng)%Vid(idTdif)=var_id(i) ELSE IF (TRIM(var_name(i)).eq.TRIM(Vname(1,idSdif))) THEN got_var(idSdif)=.TRUE. QCK(ng)%Vid(idSdif)=var_id(i) # if defined GLS_MIXING || defined MY25_MIXING ELSE IF (TRIM(var_name(i)).eq.TRIM(Vname(1,idMtke))) THEN got_var(idMtke)=.TRUE. QCK(ng)%Vid(idMtke)=var_id(i) ELSE IF (TRIM(var_name(i)).eq.TRIM(Vname(1,idMtls))) THEN got_var(idMtls)=.TRUE. QCK(ng)%Vid(idMtls)=var_id(i) # endif # if defined BULK_FLUXES || defined ECOSIM || defined ATM_PRESS ELSE IF (TRIM(var_name(i)).eq.TRIM(Vname(1,idPair))) THEN got_var(idPair)=.TRUE. QCK(ng)%Vid(idPair)=var_id(i) # endif # if defined BULK_FLUXES || defined ECOSIM ELSE IF (TRIM(var_name(i)).eq.TRIM(Vname(1,idUair))) THEN got_var(idUair)=.TRUE. QCK(ng)%Vid(idUair)=var_id(i) ELSE IF (TRIM(var_name(i)).eq.TRIM(Vname(1,idVair))) THEN got_var(idVair)=.TRUE. QCK(ng)%Vid(idVair)=var_id(i) ELSE IF (TRIM(var_name(i)).eq.TRIM(Vname(1,idUaiE))) THEN got_var(idUaiE)=.TRUE. QCK(ng)%Vid(idUaiE)=var_id(i) ELSE IF (TRIM(var_name(i)).eq.TRIM(Vname(1,idVaiN))) THEN got_var(idVaiN)=.TRUE. QCK(ng)%Vid(idVaiN)=var_id(i) # endif # if defined BULK_FLUXES || defined FRC_COUPLING ELSE IF (TRIM(var_name(i)).eq.TRIM(Vname(1,idLhea))) THEN got_var(idLhea)=.TRUE. QCK(ng)%Vid(idLhea)=var_id(i) ELSE IF (TRIM(var_name(i)).eq.TRIM(Vname(1,idShea))) THEN got_var(idShea)=.TRUE. QCK(ng)%Vid(idShea)=var_id(i) ELSE IF (TRIM(var_name(i)).eq.TRIM(Vname(1,idLrad))) THEN got_var(idLrad)=.TRUE. QCK(ng)%Vid(idLrad)=var_id(i) # endif # ifdef BULK_FLUXES ELSE IF (TRIM(var_name(i)).eq.TRIM(Vname(1,idTair))) THEN got_var(idTair)=.TRUE. QCK(ng)%Vid(idTair)=var_id(i) # ifdef EMINUSP ELSE IF (TRIM(var_name(i)).eq.TRIM(Vname(1,idevap))) THEN got_var(idevap)=.TRUE. QCK(ng)%Vid(idevap)=var_id(i) ELSE IF (TRIM(var_name(i)).eq.TRIM(Vname(1,idrain))) THEN got_var(idrain)=.TRUE. QCK(ng)%Vid(idrain)=var_id(i) # endif # endif ELSE IF (TRIM(var_name(i)).eq.TRIM(Vname(1,idEmPf))) THEN got_var(idEmPf)=.TRUE. QCK(ng)%Vid(idEmPf)=var_id(i) # ifdef SHORTWAVE ELSE IF (TRIM(var_name(i)).eq.TRIM(Vname(1,idSrad))) THEN got_var(idSrad)=.TRUE. QCK(ng)%Vid(idSrad)=var_id(i) # endif #endif ELSE IF (TRIM(var_name(i)).eq.TRIM(Vname(1,idUsms))) THEN got_var(idUsms)=.TRUE. QCK(ng)%Vid(idUsms)=var_id(i) ELSE IF (TRIM(var_name(i)).eq.TRIM(Vname(1,idVsms))) THEN got_var(idVsms)=.TRUE. QCK(ng)%Vid(idVsms)=var_id(i) ELSE IF (TRIM(var_name(i)).eq.TRIM(Vname(1,idUbms))) THEN got_var(idUbms)=.TRUE. QCK(ng)%Vid(idUbms)=var_id(i) ELSE IF (TRIM(var_name(i)).eq.TRIM(Vname(1,idVbms))) THEN got_var(idVbms)=.TRUE. QCK(ng)%Vid(idVbms)=var_id(i) END IF #ifdef SOLVE3D DO itrc=1,NT(ng) IF (TRIM(var_name(i)).eq.TRIM(Vname(1,idTvar(itrc)))) THEN got_var(idTvar(itrc))=.TRUE. QCK(ng)%Tid(itrc)=var_id(i) ELSE IF (TRIM(var_name(i)).eq. & & TRIM(Vname(1,idsurT(itrc)))) THEN got_var(idsurT(itrc))=.TRUE. QCK(ng)%Vid(idsurT(itrc))=var_id(i) END IF END DO DO itrc=1,NAT IF (TRIM(var_name(i)).eq.TRIM(Vname(1,idTsur(itrc)))) THEN got_var(idTsur(itrc))=.TRUE. QCK(ng)%Vid(idTsur(itrc))=var_id(i) END IF END DO #endif END DO ! ! Check if quicksave variables are available in input NetCDF ! file. ! IF (.not.got_var(idtime)) THEN IF (Master) WRITE (stdout,70) TRIM(Vname(1,idtime)), & & TRIM(ncname) exit_flag=3 RETURN END IF #if defined WET_DRY IF (.not.got_var(idPwet)) THEN IF (Master) WRITE (stdout,70) TRIM(Vname(1,idPwet)), & & TRIM(ncname) exit_flag=3 RETURN END IF IF (.not.got_var(idRwet)) THEN IF (Master) WRITE (stdout,70) TRIM(Vname(1,idRwet)), & & TRIM(ncname) exit_flag=3 RETURN END IF IF (.not.got_var(idUwet)) THEN IF (Master) WRITE (stdout,70) TRIM(Vname(1,idUwet)), & & TRIM(ncname) exit_flag=3 RETURN END IF IF (.not.got_var(idVwet)) THEN IF (Master) WRITE (stdout,70) TRIM(Vname(1,idVwet)), & & TRIM(ncname) exit_flag=3 RETURN END IF #endif #ifdef SOLVE3D IF (.not.got_var(idpthR).and.Qout(idpthR,ng)) THEN IF (Master) WRITE (stdout,70) TRIM(Vname(1,idpthR)), & & TRIM(ncname) exit_flag=3 RETURN END IF IF (.not.got_var(idpthU).and.Qout(idpthU,ng)) THEN IF (Master) WRITE (stdout,70) TRIM(Vname(1,idpthU)), & & TRIM(ncname) exit_flag=3 RETURN END IF IF (.not.got_var(idpthV).and.Qout(idpthV,ng)) THEN IF (Master) WRITE (stdout,70) TRIM(Vname(1,idpthV)), & & TRIM(ncname) exit_flag=3 RETURN END IF IF (.not.got_var(idpthW).and.Qout(idpthW,ng)) THEN IF (Master) WRITE (stdout,70) TRIM(Vname(1,idpthW)), & & TRIM(ncname) exit_flag=3 RETURN END IF #endif IF (.not.got_var(idFsur).and.Qout(idFsur,ng)) THEN IF (Master) WRITE (stdout,70) TRIM(Vname(1,idFsur)), & & TRIM(ncname) exit_flag=3 RETURN END IF IF (.not.got_var(idUbar).and.Qout(idUbar,ng)) THEN IF (Master) WRITE (stdout,70) TRIM(Vname(1,idUbar)), & & TRIM(ncname) exit_flag=3 RETURN END IF IF (.not.got_var(idVbar).and.Qout(idVbar,ng)) THEN IF (Master) WRITE (stdout,70) TRIM(Vname(1,idVbar)), & & TRIM(ncname) exit_flag=3 RETURN END IF IF (.not.got_var(idu2dE).and.Qout(idu2dE,ng)) THEN IF (Master) WRITE (stdout,70) TRIM(Vname(1,idu2dE)), & & TRIM(ncname) exit_flag=3 RETURN END IF IF (.not.got_var(idv2dN).and.Qout(idv2dN,ng)) THEN IF (Master) WRITE (stdout,70) TRIM(Vname(1,idv2dN)), & & TRIM(ncname) exit_flag=3 RETURN END IF #ifdef SOLVE3D IF (.not.got_var(idUvel).and.Qout(idUvel,ng)) THEN IF (Master) WRITE (stdout,70) TRIM(Vname(1,idUvel)), & & TRIM(ncname) exit_flag=3 RETURN END IF IF (.not.got_var(idVvel).and.Qout(idVvel,ng)) THEN IF (Master) WRITE (stdout,70) TRIM(Vname(1,idVvel)), & & TRIM(ncname) exit_flag=3 RETURN END IF IF (.not.got_var(idUsur).and.Qout(idUsur,ng)) THEN IF (Master) WRITE (stdout,70) TRIM(Vname(1,idUsur)), & & TRIM(ncname) exit_flag=3 RETURN END IF IF (.not.got_var(idVsur).and.Qout(idVsur,ng)) THEN IF (Master) WRITE (stdout,70) TRIM(Vname(1,idVsur)), & & TRIM(ncname) exit_flag=3 RETURN END IF IF (.not.got_var(idu3dE).and.Qout(idu3dE,ng)) THEN IF (Master) WRITE (stdout,70) TRIM(Vname(1,idu3dE)), & & TRIM(ncname) exit_flag=3 RETURN END IF IF (.not.got_var(idv3dN).and.Qout(idv3dN,ng)) THEN IF (Master) WRITE (stdout,70) TRIM(Vname(1,idv3dN)), & & TRIM(ncname) exit_flag=3 RETURN END IF IF (.not.got_var(idUsuE).and.Qout(idUsuE,ng)) THEN IF (Master) WRITE (stdout,70) TRIM(Vname(1,idUsuE)), & & TRIM(ncname) exit_flag=3 RETURN END IF IF (.not.got_var(idVsuN).and.Qout(idVsuN,ng)) THEN IF (Master) WRITE (stdout,70) TRIM(Vname(1,idVsuN)), & & TRIM(ncname) exit_flag=3 RETURN END IF IF (.not.got_var(idWvel).and.Qout(idWvel,ng)) THEN IF (Master) WRITE (stdout,70) TRIM(Vname(1,idWvel)), & & TRIM(ncname) exit_flag=3 RETURN END IF IF (.not.got_var(idOvel).and.Qout(idOvel,ng)) THEN IF (Master) WRITE (stdout,70) TRIM(Vname(1,idOvel)), & & TRIM(ncname) exit_flag=3 RETURN END IF IF (.not.got_var(idDano).and.Qout(idDano,ng)) THEN IF (Master) WRITE (stdout,70) TRIM(Vname(1,idDano)), & & TRIM(ncname) exit_flag=3 RETURN END IF # ifdef LMD_SKPP IF (.not.got_var(idHsbl).and.Qout(idHsbl,ng)) THEN IF (Master) WRITE (stdout,70) TRIM(Vname(1,idHsbl)), & & TRIM(ncname) exit_flag=3 RETURN END IF # endif # ifdef LMD_BKPP IF (.not.got_var(idHbbl).and.Qout(idHbbl,ng)) THEN IF (Master) WRITE (stdout,70) TRIM(Vname(1,idHbbl)), & & TRIM(ncname) exit_flag=3 RETURN END IF # endif IF (.not.got_var(idVvis).and.Qout(idVvis,ng)) THEN IF (Master) WRITE (stdout,70) TRIM(Vname(1,idVvis)), & & TRIM(ncname) exit_flag=3 RETURN END IF IF (.not.got_var(idTdif).and.Qout(idTdif,ng)) THEN IF (Master) WRITE (stdout,70) TRIM(Vname(1,idTdif)), & & TRIM(ncname) exit_flag=3 RETURN END IF # ifdef SALINITY IF (.not.got_var(idSdif).and.Qout(idSdif,ng)) THEN IF (Master) WRITE (stdout,70) TRIM(Vname(1,idSdif)), & & TRIM(ncname) exit_flag=3 RETURN END IF # endif # if defined GLS_MIXING || defined MY25_MIXING IF (.not.got_var(idMtke).and.Qout(idMtke,ng)) THEN IF (Master) WRITE (stdout,70) TRIM(Vname(1,idMtke)), & & TRIM(ncname) exit_flag=3 RETURN END IF IF (.not.got_var(idMtls).and.Qout(idMtls,ng)) THEN IF (Master) WRITE (stdout,70) TRIM(Vname(1,idMtls)), & & TRIM(ncname) exit_flag=3 RETURN END IF # endif # if defined BULK_FLUXES || defined ECOSIM || defined ATM_PRESS IF (.not.got_var(idPair).and.Qout(idPair,ng)) THEN IF (Master) WRITE (stdout,70) TRIM(Vname(1,idPair)), & & TRIM(ncname) exit_flag=3 RETURN END IF # endif # if defined BULK_FLUXES || defined ECOSIM IF (.not.got_var(idUair).and.Qout(idUair,ng)) THEN IF (Master) WRITE (stdout,70) TRIM(Vname(1,idUair)), & & TRIM(ncname) exit_flag=3 RETURN END IF IF (.not.got_var(idVair).and.Qout(idVair,ng)) THEN IF (Master) WRITE (stdout,70) TRIM(Vname(1,idVair)), & & TRIM(ncname) exit_flag=3 RETURN END IF IF (.not.got_var(idUaiE).and.Qout(idUaiE,ng)) THEN IF (Master) WRITE (stdout,70) TRIM(Vname(1,idUaiE)), & & TRIM(ncname) exit_flag=3 RETURN END IF IF (.not.got_var(idVaiN).and.Qout(idVaiN,ng)) THEN IF (Master) WRITE (stdout,70) TRIM(Vname(1,idVaiN)), & & TRIM(ncname) exit_flag=3 RETURN END IF # endif # if defined BULK_FLUXES || defined FRC_COUPLING IF (.not.got_var(idLhea).and.Qout(idLhea,ng)) THEN IF (Master) WRITE (stdout,70) TRIM(Vname(1,idLhea)), & & TRIM(ncname) exit_flag=3 RETURN END IF IF (.not.got_var(idShea).and.Qout(idShea,ng)) THEN IF (Master) WRITE (stdout,70) TRIM(Vname(1,idShea)), & & TRIM(ncname) exit_flag=3 RETURN END IF IF (.not.got_var(idLrad).and.Qout(idLrad,ng)) THEN IF (Master) WRITE (stdout,70) TRIM(Vname(1,idLrad)), & & TRIM(ncname) exit_flag=3 RETURN END IF # endif # ifdef BULK_FLUXES IF (.not.got_var(idTair).and.Qout(idTair,ng)) THEN IF (Master) WRITE (stdout,70) TRIM(Vname(1,idTair)), & & TRIM(ncname) exit_flag=3 RETURN END IF # ifdef EMINUSP IF (.not.got_var(idevap).and.Qout(idevap,ng)) THEN IF (Master) WRITE (stdout,70) TRIM(Vname(1,idevap)), & & TRIM(ncname) exit_flag=3 RETURN END IF IF (.not.got_var(idrain).and.Qout(idrain,ng)) THEN IF (Master) WRITE (stdout,70) TRIM(Vname(1,idrain)), & & TRIM(ncname) exit_flag=3 RETURN END IF # endif # endif IF (.not.got_var(idEmPf).and.Qout(idEmPf,ng)) THEN IF (Master) WRITE (stdout,70) TRIM(Vname(1,idEmPf)), & & TRIM(ncname) exit_flag=3 RETURN END IF # ifdef SHORTWAVE IF (.not.got_var(idSrad).and.Qout(idSrad,ng)) THEN IF (Master) WRITE (stdout,70) TRIM(Vname(1,idSrad)), & & TRIM(ncname) exit_flag=3 RETURN END IF # endif #endif IF (.not.got_var(idUsms).and.Qout(idUsms,ng)) THEN IF (Master) WRITE (stdout,70) TRIM(Vname(1,idUsms)), & & TRIM(ncname) exit_flag=3 RETURN END IF IF (.not.got_var(idVsms).and.Qout(idVsms,ng)) THEN IF (Master) WRITE (stdout,70) TRIM(Vname(1,idVsms)), & & TRIM(ncname) exit_flag=3 RETURN END IF IF (.not.got_var(idUbms).and.Qout(idUbms,ng)) THEN IF (Master) WRITE (stdout,70) TRIM(Vname(1,idUbms)), & & TRIM(ncname) exit_flag=3 RETURN END IF IF (.not.got_var(idVbms).and.Qout(idVbms,ng)) THEN IF (Master) WRITE (stdout,70) TRIM(Vname(1,idVbms)), & & TRIM(ncname) exit_flag=3 RETURN END IF #ifdef SOLVE3D DO itrc=1,NT(ng) IF (.not.got_var(idTvar(itrc)).and.Qout(idTvar(itrc),ng)) THEN IF (Master) WRITE (stdout,70) TRIM(Vname(1,idTvar(itrc))), & & TRIM(ncname) exit_flag=3 RETURN END IF IF (.not.got_var(idsurT(itrc)).and.Qout(idsurT(itrc),ng)) THEN IF (Master) WRITE (stdout,70) TRIM(Vname(1,idsurT(itrc))), & & TRIM(ncname) exit_flag=3 RETURN END IF END DO DO itrc=1,NAT IF (.not.got_var(idTsur(itrc)).and.Qout(idTsur(itrc),ng)) THEN IF (Master) WRITE (stdout,70) TRIM(Vname(1,idTsur(itrc))), & & TRIM(ncname) exit_flag=3 RETURN END IF END DO #endif #if (defined BBL_MODEL || defined WAVES_OUTPUT) && defined SOLVE3D ! ! Scan bottom boundary layer model and waves variables from input ! NetCDF and activate switches for quicksave variables. Get variable IDs. ! CALL bbl_def_nf90 (ng, model, ldef, Qout, QCK) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN #endif #if defined ICE_MODEL && defined SOLVE3D ! ! Scan sea-ice variables from input NetCDF and activate switches for ! quicksave variables. Get variable IDs. ! CALL ice_def_nf90 (ng, model, ldef, Qout, QCK) #endif #if defined SEDIMENT && defined SOLVE3D ! ! Scan sediment model variables from input NetCDF and activate ! switches for quicksave variables. Get variable IDs. ! CALL sediment_def_nf90 (ng, model, ldef, Qout, QCK) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN #endif #if defined WEC_VF && defined SOLVE3D ! ! Scan Waves Effect on Currents variables from input NetCDF and ! activate switches for quicksave variables. Get variable IDs. ! CALL wec_def_nf90 (ng, model, ldef, Qout, QCK) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN #endif ! ! Set unlimited time record dimension to the appropriate value. ! IF (ndefQCK(ng).gt.0) THEN QCK(ng)%Rindex=((ntstart(ng)-1)- & & ndefQCK(ng)*((ntstart(ng)-1)/ndefQCK(ng)))/ & & nQCK(ng) ELSE QCK(ng)%Rindex=(ntstart(ng)-1)/nQCK(ng) END IF QCK(ng)%Rindex=MIN(QCK(ng)%Rindex,rec_size) END IF QUERY ! 10 FORMAT (2x,'DEF_QUICK_NF90 - creating quicksave file,',t56, & & 'Grid ',i2.2,': ',a) 20 FORMAT (2x,'DEF_QUICK_NF90 - inquiring quicksave file,',t56, & & 'Grid ',i2.2,': ',a) 30 FORMAT (/,' DEF_QUICK_NF90 - unable to create quicksave NetCDF', & & ' file:', 1x,a) 40 FORMAT ('time dependent',1x,a) 50 FORMAT (1pe11.4,1x,'millimeter') 60 FORMAT (/,' DEF_QUICK_NF90 - unable to open quicksave NetCDF', & & ' file: ',a) 70 FORMAT (/,' DEF_QUICK_NF90 - unable to find variable: ',a,2x, & & ' in quicksave NetCDF file: ',a) ! RETURN END SUBROUTINE def_quick_nf90 #if defined PIO_LIB && defined DISTRIBUTE ! !*********************************************************************** SUBROUTINE def_quick_pio (ng, model, ldef) !*********************************************************************** ! USE mod_pio_netcdf ! ! Imported variable declarations. ! logical, intent(in) :: ldef integer, intent(in) :: ng, model ! ! Local variable declarations. ! logical :: got_var(NV) ! integer, parameter :: Natt = 25 integer :: i, j, ifield, itrc, nvd3, nvd4, varid integer :: recdim, status # ifdef ADJUST_BOUNDARY integer :: IorJdim # endif integer :: DimIDs(nDimID) integer :: t2dgrd(3), u2dgrd(3), v2dgrd(3) # ifdef SOLVE3D # ifdef SEDIMENT integer :: b3dgrd(4) # endif integer :: t3dgrd(4), u3dgrd(4), v3dgrd(4), w3dgrd(4) # endif # ifdef WET_DRY integer :: sp2dgrd(3) # endif ! real(r8) :: Aval(6) ! character (len=256) :: ncname character (len=MaxLen) :: Vinfo(Natt) character (len=*), parameter :: MyFile = & & __FILE__//", def_quick_pio" ! SourceFile=MyFile ! !----------------------------------------------------------------------- ! Set and report file name. !----------------------------------------------------------------------- ! IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN ncname=QCK(ng)%name ! IF (Master) THEN IF (ldef) THEN WRITE (stdout,10) ng, TRIM(ncname) ELSE WRITE (stdout,20) ng, TRIM(ncname) END IF END IF ! !======================================================================= ! Create a new quicksave file. !======================================================================= ! DEFINE : IF (ldef) THEN CALL pio_netcdf_create (ng, model, TRIM(ncname), QCK(ng)%pioFile) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) THEN IF (Master) WRITE (stdout,30) TRIM(ncname) RETURN END IF ! !----------------------------------------------------------------------- ! Define file dimensions. !----------------------------------------------------------------------- ! DimIDs=0 ! status=def_dim(ng, model, QCK(ng)%pioFile, ncname, 'xi_rho', & & IOBOUNDS(ng)%xi_rho, DimIDs( 1)) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN status=def_dim(ng, model, QCK(ng)%pioFile, ncname, 'xi_u', & & IOBOUNDS(ng)%xi_u, DimIDs( 2)) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN status=def_dim(ng, model, QCK(ng)%pioFile, ncname, 'xi_v', & & IOBOUNDS(ng)%xi_v, DimIDs( 3)) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN status=def_dim(ng, model, QCK(ng)%pioFile, ncname, 'xi_psi', & & IOBOUNDS(ng)%xi_psi, DimIDs( 4)) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN status=def_dim(ng, model, QCK(ng)%pioFile, ncname, 'eta_rho', & & IOBOUNDS(ng)%eta_rho, DimIDs( 5)) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN status=def_dim(ng, model, QCK(ng)%pioFile, ncname, 'eta_u', & & IOBOUNDS(ng)%eta_u, DimIDs( 6)) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN status=def_dim(ng, model, QCK(ng)%pioFile, ncname, 'eta_v', & & IOBOUNDS(ng)%eta_v, DimIDs( 7)) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN status=def_dim(ng, model, QCK(ng)%pioFile, ncname, 'eta_psi', & & IOBOUNDS(ng)%eta_psi, DimIDs( 8)) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN # ifdef ADJUST_BOUNDARY status=def_dim(ng, model, QCK(ng)%pioFile, ncname, 'IorJ', & & IOBOUNDS(ng)%IorJ, IorJdim) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN # endif # if defined WRITE_WATER && defined MASKING status=def_dim(ng, model, QCK(ng)%pioFile, ncname, 'xy_rho', & & IOBOUNDS(ng)%xy_rho, DimIDs(17)) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN status=def_dim(ng, model, QCK(ng)%pioFile, ncname, 'xy_u', & & IOBOUNDS(ng)%xy_u, DimIDs(18)) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN status=def_dim(ng, model, QCK(ng)%pioFile, ncname, 'xy_v', & & IOBOUNDS(ng)%xy_v, DimIDs(19)) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN # endif # ifdef SOLVE3D # if defined WRITE_WATER && defined MASKING status=def_dim(ng, model, QCK(ng)%pioFile, ncname, 'xyz_rho', & & IOBOUNDS(ng)%xy_rho*N(ng), DimIDs(20)) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN status=def_dim(ng, model, QCK(ng)%pioFile, ncname, 'xyz_u', & & IOBOUNDS(ng)%xy_u*N(ng), DimIDs(21)) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN status=def_dim(ng, model, QCK(ng)%pioFile, ncname, 'xyz_v', & & IOBOUNDS(ng)%xy_v*N(ng), DimIDs(22)) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN status=def_dim(ng, model, QCK(ng)%pioFile, ncname, 'xyz_w', & & IOBOUNDS(ng)%xy_rho*(N(ng)+1), DimIDs(23)) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN # endif status=def_dim(ng, model, QCK(ng)%pioFile, ncname, 'N', & & N(ng), DimIDs( 9)) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN status=def_dim(ng, model, QCK(ng)%pioFile, ncname, 's_rho', & & N(ng), DimIDs( 9)) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN status=def_dim(ng, model, QCK(ng)%pioFile, ncname, 's_w', & & N(ng)+1, DimIDs(10)) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN status=def_dim(ng, model, QCK(ng)%pioFile, ncname, 'tracer', & & NT(ng), DimIDs(11)) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN # ifdef SEDIMENT status=def_dim(ng, model, QCK(ng)%pioFile, ncname, 'NST', & & NST, DimIDs(32)) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN status=def_dim(ng, model, QCK(ng)%pioFile, ncname, 'Nbed', & & Nbed, DimIDs(16)) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN # if defined WRITE_WATER && defined MASKING status=def_dim(ng, model, QCK(ng)%pioFile, ncname, 'xybed', & & IOBOUNDS(ng)%xy_rho*Nbed, DimIDs(24)) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN # endif # endif # ifdef ECOSIM status=def_dim(ng, model, QCK(ng)%pioFile, ncname, 'Nbands', & & NBands, DimIDs(33)) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN status=def_dim(ng, model, QCK(ng)%pioFile, ncname, 'Nphy', & & Nphy, DimIDs(25)) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN status=def_dim(ng, model, QCK(ng)%pioFile, ncname, 'Nbac', & & Nbac, DimIDs(26)) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN status=def_dim(ng, model, QCK(ng)%pioFile, ncname, 'Ndom', & & Ndom, DimIDs(27)) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN status=def_dim(ng, model, QCK(ng)%pioFile, ncname, 'Nfec', & & Nfec, DimIDs(28)) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN # endif # endif status=def_dim(ng, model, QCK(ng)%pioFile, ncname, 'boundary', & & 4, DimIDs(14)) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN # ifdef FOUR_DVAR status=def_dim(ng, model, QCK(ng)%pioFile, ncname, 'Nstate', & & NstateVar(ng), DimIDs(29)) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN # endif # ifdef ADJUST_BOUNDARY status=def_dim(ng, model, QCK(ng)%pioFile, ncname, 'obc_adjust',& & Nbrec(ng), DimIDs(31)) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN # endif status=def_dim(ng, model, QCK(ng)%pioFile, ncname, & & TRIM(ADJUSTL(Vname(5,idtime))), & & PIO_unlimited, DimIDs(12)) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN recdim=DimIDs(12) ! ! Set number of dimensions for output variables. ! # if defined WRITE_WATER && defined MASKING nvd3=2 nvd4=2 # else nvd3=3 nvd4=4 # endif ! ! Define dimension vectors for staggered tracer type variables. ! # if defined WRITE_WATER && defined MASKING t2dgrd(1)=DimIDs(17) t2dgrd(2)=DimIDs(12) # ifdef SOLVE3D t3dgrd(1)=DimIDs(20) t3dgrd(2)=DimIDs(12) # endif # else t2dgrd(1)=DimIDs( 1) t2dgrd(2)=DimIDs( 5) t2dgrd(3)=DimIDs(12) # ifdef SOLVE3D t3dgrd(1)=DimIDs( 1) t3dgrd(2)=DimIDs( 5) t3dgrd(3)=DimIDs( 9) t3dgrd(4)=DimIDs(12) # endif # endif # ifdef WET_DRY ! ! Define dimension vectors for staggered type variables at PSI-points. ! sp2dgrd(1)=DimIDs( 4) sp2dgrd(2)=DimIDs( 8) sp2dgrd(3)=DimIDs(12) # endif ! ! Define dimension vectors for staggered u-momentum type variables. ! # if defined WRITE_WATER && defined MASKING u2dgrd(1)=DimIDs(18) u2dgrd(2)=DimIDs(12) # ifdef SOLVE3D u3dgrd(1)=DimIDs(21) u3dgrd(2)=DimIDs(12) # endif # else u2dgrd(1)=DimIDs( 2) u2dgrd(2)=DimIDs( 6) u2dgrd(3)=DimIDs(12) # ifdef SOLVE3D u3dgrd(1)=DimIDs( 2) u3dgrd(2)=DimIDs( 6) u3dgrd(3)=DimIDs( 9) u3dgrd(4)=DimIDs(12) # endif # endif ! ! Define dimension vectors for staggered v-momentum type variables. ! # if defined WRITE_WATER && defined MASKING v2dgrd(1)=DimIDs(19) v2dgrd(2)=DimIDs(12) # ifdef SOLVE3D v3dgrd(1)=DimIDs(22) v3dgrd(2)=DimIDs(12) # endif # else v2dgrd(1)=DimIDs( 3) v2dgrd(2)=DimIDs( 7) v2dgrd(3)=DimIDs(12) # ifdef SOLVE3D v3dgrd(1)=DimIDs( 3) v3dgrd(2)=DimIDs( 7) v3dgrd(3)=DimIDs( 9) v3dgrd(4)=DimIDs(12) # endif # endif # ifdef SOLVE3D ! ! Define dimension vector for staggered w-momentum type variables. ! # if defined WRITE_WATER && defined MASKING w3dgrd(1)=DimIDs(23) w3dgrd(2)=DimIDs(12) # else w3dgrd(1)=DimIDs( 1) w3dgrd(2)=DimIDs( 5) w3dgrd(3)=DimIDs(10) w3dgrd(4)=DimIDs(12) # endif # ifdef SEDIMENT ! ! Define dimension vector for sediment bed layer type variables. ! # if defined WRITE_WATER && defined MASKING b3dgrd(1)=DimIDs(24) b3dgrd(2)=DimIDs(12) # else b3dgrd(1)=DimIDs( 1) b3dgrd(2)=DimIDs( 5) b3dgrd(3)=DimIDs(16) b3dgrd(4)=DimIDs(12) # endif # endif # endif ! ! Initialize unlimited time record dimension. ! QCK(ng)%Rindex=0 ! ! Initialize local information variable arrays. ! DO i=1,Natt DO j=1,LEN(Vinfo(1)) Vinfo(i)(j:j)=' ' END DO END DO DO i=1,6 Aval(i)=0.0_r8 END DO ! !----------------------------------------------------------------------- ! Define time-recordless information variables. !----------------------------------------------------------------------- ! CALL def_info (ng, model, QCK(ng)%pioFile, ncname, DimIDs) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN ! !----------------------------------------------------------------------- ! Define time-varying variables. !----------------------------------------------------------------------- ! ! Define model time. ! Vinfo( 1)=Vname(1,idtime) Vinfo( 2)=Vname(2,idtime) WRITE (Vinfo( 3),'(a,a)') 'seconds since ', TRIM(Rclock%string) Vinfo( 4)=TRIM(Rclock%calendar) Vinfo(14)=Vname(4,idtime) Vinfo(21)=Vname(6,idtime) QCK(ng)%pioVar(idtime)%dkind=PIO_TOUT QCK(ng)%pioVar(idtime)%gtype=0 ! status=def_var(ng, model, QCK(ng)%pioFile, & & QCK(ng)%pioVar(idtime)%vd, & & PIO_TOUT, 1, (/recdim/), Aval, Vinfo, ncname, & & SetParAccess = .TRUE.) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN # ifdef WET_DRY ! ! Define wet/dry mask on PSI-points. ! Vinfo( 1)=Vname(1,idPwet) Vinfo( 2)=Vname(2,idPwet) Vinfo( 3)=Vname(3,idPwet) Vinfo( 9)='land' Vinfo(10)='water' Vinfo(14)=Vname(4,idPwet) Vinfo(16)=Vname(1,idtime) Vinfo(21)=Vname(6,idPwet) Vinfo(22)='coordinates' Aval(5)=REAL(Iinfo(1,idPwet,ng),r8) QCK(ng)%pioVar(idPwet)%dkind=PIO_FOUT QCK(ng)%pioVar(idPwet)%gtype=p2dvar ! status=def_var(ng, model, QCK(ng)%pioFile, & & QCK(ng)%pioVar(idPwet)%vd, & & PIO_FOUT, nvd3, sp2dgrd, Aval, Vinfo, ncname, & & SetFillVal = .FALSE.) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN ! ! Define wet/dry mask on RHO-points. ! Vinfo( 1)=Vname(1,idRwet) Vinfo( 2)=Vname(2,idRwet) Vinfo( 3)=Vname(3,idRwet) Vinfo( 9)='land' Vinfo(10)='water' Vinfo(14)=Vname(4,idRwet) Vinfo(16)=Vname(1,idtime) Vinfo(21)=Vname(6,idRwet) Vinfo(22)='coordinates' Aval(5)=REAL(Iinfo(1,idRwet,ng),r8) QCK(ng)%pioVar(idRwet)%dkind=PIO_FOUT QCK(ng)%pioVar(idRwet)%gtype=r2dvar ! status=def_var(ng, model, QCK(ng)%pioFile, & & QCK(ng)%pioVar(idRwet)%vd, & & PIO_FOUT, nvd3, t2dgrd, Aval, Vinfo, ncname, & & SetFillVal = .FALSE.) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN ! ! Define wet/dry mask on U-points. ! Vinfo( 1)=Vname(1,idUwet) Vinfo( 2)=Vname(2,idUwet) Vinfo( 3)=Vname(3,idUwet) Vinfo( 9)='land' Vinfo(10)='water' Vinfo(14)=Vname(4,idUwet) Vinfo(16)=Vname(1,idtime) Vinfo(21)=Vname(6,idUwet) Vinfo(22)='coordinates' Aval(5)=REAL(Iinfo(1,idUwet,ng),r8) QCK(ng)%pioVar(idUwet)%dkind=PIO_FOUT QCK(ng)%pioVar(idUwet)%gtype=u2dvar ! status=def_var(ng, model, QCK(ng)%pioFile, & & QCK(ng)%pioVar(idUwet)%vd, & & PIO_FOUT, nvd3, u2dgrd, Aval, Vinfo, ncname, & & SetFillVal = .FALSE.) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN ! ! Define wet/dry mask on V-points. ! Vinfo( 1)=Vname(1,idVwet) Vinfo( 2)=Vname(2,idVwet) Vinfo( 3)=Vname(3,idVwet) Vinfo(14)=Vname(4,idVwet) Vinfo(16)=Vname(1,idtime) Vinfo( 9)='land' Vinfo(10)='water' Vinfo(21)=Vname(6,idVwet) Vinfo(22)='coordinates' Aval(5)=REAL(Iinfo(1,idVwet,ng),r8) QCK(ng)%pioVar(idVwet)%dkind=PIO_FOUT QCK(ng)%pioVar(idVwet)%gtype=v2dvar ! status=def_var(ng, model, QCK(ng)%pioFile, & & QCK(ng)%pioVar(idVwet)%vd, & & PIO_FOUT, nvd3, v2dgrd, Aval, Vinfo, ncname, & & SetFillVal = .FALSE.) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN # endif # ifdef SOLVE3D ! ! Define time-varying depth of RHO-points. ! IF (Qout(idpthR,ng)) THEN Vinfo( 1)=Vname(1,idpthR) WRITE (Vinfo( 2),40) TRIM(Vname(2,idpthR)) Vinfo( 3)=Vname(3,idpthR) Vinfo(14)=Vname(4,idpthR) Vinfo(16)=Vname(1,idtime) # if defined WRITE_WATER && defined MASKING Vinfo(20)='mask_rho' # endif Vinfo(21)=Vname(6,idpthR) Vinfo(22)='coordinates' Aval(5)=REAL(Iinfo(1,idpthR,ng),r8) QCK(ng)%pioVar(idpthR)%dkind=PIO_FOUT QCK(ng)%pioVar(idpthR)%gtype=r3dvar ! status=def_var(ng, model, QCK(ng)%pioFile, & & QCK(ng)%pioVar(idpthR)%vd, & & PIO_FOUT, nvd4, t3dgrd, Aval, Vinfo, ncname, & & SetFillVal = .FALSE.) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN END IF ! ! Define time-varying depth of U-points. ! IF (Qout(idpthU,ng)) THEN Vinfo( 1)=Vname(1,idpthU) WRITE (Vinfo( 2),40) TRIM(Vname(2,idpthU)) Vinfo( 3)=Vname(3,idpthU) Vinfo(14)=Vname(4,idpthU) Vinfo(16)=Vname(1,idtime) # if defined WRITE_WATER && defined MASKING Vinfo(20)='mask_u' # endif Vinfo(21)=Vname(6,idpthU) Vinfo(22)='coordinates' Aval(5)=REAL(Iinfo(1,idpthU,ng),r8) QCK(ng)%pioVar(idpthU)%dkind=PIO_FOUT QCK(ng)%pioVar(idpthU)%gtype=u3dvar ! status=def_var(ng, model, QCK(ng)%pioFile, & & QCK(ng)%pioVar(idpthU)%vd, & & PIO_FOUT, nvd4, u3dgrd, Aval, Vinfo, ncname, & & SetFillVal = .FALSE.) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN END IF ! ! Define time-varying depth of V-points. ! IF (Qout(idpthV,ng)) THEN Vinfo( 1)=Vname(1,idpthV) WRITE (Vinfo( 2),40) TRIM(Vname(2,idpthV)) Vinfo( 3)=Vname(3,idpthV) Vinfo(14)=Vname(4,idpthV) Vinfo(16)=Vname(1,idtime) # if defined WRITE_WATER && defined MASKING Vinfo(20)='mask_v' # endif Vinfo(21)=Vname(6,idpthV) Vinfo(22)='coordinates' Aval(5)=REAL(Iinfo(1,idpthV,ng),r8) QCK(ng)%pioVar(idpthV)%dkind=PIO_FOUT QCK(ng)%pioVar(idpthV)%gtype=v3dvar ! status=def_var(ng, model, QCK(ng)%pioFile, & & QCK(ng)%pioVar(idpthV)%vd, & & PIO_FOUT, nvd4, v3dgrd, Aval, Vinfo, ncname, & & SetFillVal = .FALSE.) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN END IF ! ! Define time-varying depth of W-points. ! IF (Qout(idpthW,ng)) THEN Vinfo( 1)=Vname(1,idpthW) WRITE (Vinfo( 2),40) TRIM(Vname(2,idpthW)) Vinfo( 3)=Vname(3,idpthW) Vinfo(14)=Vname(4,idpthW) Vinfo(16)=Vname(1,idtime) # if defined WRITE_WATER && defined MASKING Vinfo(20)='mask_rho' # endif Vinfo(21)=Vname(6,idpthW) Vinfo(22)='coordinates' Aval(5)=REAL(Iinfo(1,idpthW,ng),r8) QCK(ng)%pioVar(idpthW)%dkind=PIO_FOUT QCK(ng)%pioVar(idpthW)%gtype=w3dvar ! status=def_var(ng, model, QCK(ng)%pioFile, & & QCK(ng)%pioVar(idpthW)%vd, & & PIO_FOUT, nvd4, w3dgrd, Aval, Vinfo, ncname, & & SetFillVal = .FALSE.) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN END IF # endif ! ! Define free-surface. ! IF (Qout(idFsur,ng)) THEN Vinfo( 1)=Vname(1,idFsur) Vinfo( 2)=Vname(2,idFsur) Vinfo( 3)=Vname(3,idFsur) Vinfo(14)=Vname(4,idFsur) Vinfo(16)=Vname(1,idtime) # if defined WRITE_WATER && defined MASKING Vinfo(20)='mask_rho' # endif Vinfo(21)=Vname(6,idFsur) Vinfo(22)='coordinates' Aval(5)=REAL(Iinfo(1,idFsur,ng),r8) QCK(ng)%pioVar(idFsur)%dkind=PIO_FOUT QCK(ng)%pioVar(idFsur)%gtype=r2dvar ! status=def_var(ng, model, QCK(ng)%pioFile, & & QCK(ng)%pioVar(idFsur)%vd, & # ifdef WET_DRY & PIO_FOUT, nvd3, t2dgrd, Aval, Vinfo, ncname, & & SetFillVal = .FALSE.) # else & PIO_FOUT, nvd3, t2dgrd, Aval, Vinfo, ncname) # endif IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN END IF ! ! Define 2D U-momentum component. ! IF (Qout(idUbar,ng)) THEN Vinfo( 1)=Vname(1,idUbar) Vinfo( 2)=Vname(2,idUbar) Vinfo( 3)=Vname(3,idUbar) Vinfo(14)=Vname(4,idUbar) Vinfo(16)=Vname(1,idtime) # if defined WRITE_WATER && defined MASKING Vinfo(20)='mask_u' # endif Vinfo(21)=Vname(6,idUbar) Vinfo(22)='coordinates' Aval(5)=REAL(Iinfo(1,idUbar,ng),r8) QCK(ng)%pioVar(idUbar)%dkind=PIO_FOUT QCK(ng)%pioVar(idUbar)%gtype=u2dvar ! status=def_var(ng, model, QCK(ng)%pioFile, & & QCK(ng)%pioVar(idUbar)%vd, & & PIO_FOUT, nvd3, u2dgrd, Aval, Vinfo, ncname) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN END IF ! ! Define 2D V-momentum component. ! IF (Qout(idVbar,ng)) THEN Vinfo( 1)=Vname(1,idVbar) Vinfo( 2)=Vname(2,idVbar) Vinfo( 3)=Vname(3,idVbar) Vinfo(14)=Vname(4,idVbar) Vinfo(16)=Vname(1,idtime) # if defined WRITE_WATER && defined MASKING Vinfo(20)='mask_v' # endif Vinfo(21)=Vname(6,idVbar) Vinfo(22)='coordinates' Aval(5)=REAL(Iinfo(1,idVbar,ng),r8) QCK(ng)%pioVar(idVbar)%dkind=PIO_FOUT QCK(ng)%pioVar(idVbar)%gtype=v2dvar ! status=def_var(ng, model, QCK(ng)%pioFile, & & QCK(ng)%pioVar(idVbar)%vd, & & PIO_FOUT, nvd3, v2dgrd, Aval, Vinfo, ncname) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN END IF ! ! Define 2D Eastward momentum component at RHO-points. ! IF (Qout(idu2dE,ng)) THEN Vinfo( 1)=Vname(1,idu2dE) Vinfo( 2)=Vname(2,idu2dE) Vinfo( 3)=Vname(3,idu2dE) Vinfo(14)=Vname(4,idu2dE) Vinfo(16)=Vname(1,idtime) # if defined WRITE_WATER && defined MASKING Vinfo(20)='mask_rho' # endif Vinfo(21)=Vname(6,idu2dE) Vinfo(22)='coordinates' Aval(5)=REAL(Iinfo(1,idu2dE,ng),r8) QCK(ng)%pioVar(idu2dE)%dkind=PIO_FOUT QCK(ng)%pioVar(idu2dE)%gtype=r2dvar ! status=def_var(ng, model, QCK(ng)%pioFile, & & QCK(ng)%pioVar(idu2dE)%vd, & & PIO_FOUT, nvd3, t2dgrd, Aval, Vinfo, ncname) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN END IF ! ! Define 2D Northward momentum component at RHO-points. ! IF (Qout(idv2dN,ng)) THEN Vinfo( 1)=Vname(1,idv2dN) Vinfo( 2)=Vname(2,idv2dN) Vinfo( 3)=Vname(3,idv2dN) Vinfo(14)=Vname(4,idv2dN) Vinfo(16)=Vname(1,idtime) # if defined WRITE_WATER && defined MASKING Vinfo(20)='mask_rho' # endif Vinfo(21)=Vname(6,idv2dN) Vinfo(22)='coordinates' Aval(5)=REAL(Iinfo(1,idv2dN,ng),r8) QCK(ng)%pioVar(idv2dN)%dkind=PIO_FOUT QCK(ng)%pioVar(idv2dN)%gtype=r2dvar ! status=def_var(ng, model, QCK(ng)%pioFile, & & QCK(ng)%pioVar(idv2dN)%vd, & & PIO_FOUT, nvd3, t2dgrd, Aval, Vinfo, ncname) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN END IF # ifdef SOLVE3D ! ! Define 3D U-momentum component. ! IF (Qout(idUvel,ng)) THEN Vinfo( 1)=Vname(1,idUvel) Vinfo( 2)=Vname(2,idUvel) Vinfo( 3)=Vname(3,idUvel) Vinfo(14)=Vname(4,idUvel) Vinfo(16)=Vname(1,idtime) # if defined WRITE_WATER && defined MASKING Vinfo(20)='mask_u' # endif Vinfo(21)=Vname(6,idUvel) Vinfo(22)='coordinates' Aval(5)=REAL(Iinfo(1,idUvel,ng),r8) QCK(ng)%pioVar(idUvel)%dkind=PIO_FOUT QCK(ng)%pioVar(idUvel)%gtype=u3dvar ! status=def_var(ng, model, QCK(ng)%pioFile, & & QCK(ng)%pioVar(idUvel)%vd, & & PIO_FOUT, nvd4, u3dgrd, Aval, Vinfo, ncname) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN END IF ! ! Define 3D V-momentum component. ! IF (Qout(idVvel,ng)) THEN Vinfo( 1)=Vname(1,idVvel) Vinfo( 2)=Vname(2,idVvel) Vinfo( 3)=Vname(3,idVvel) Vinfo(14)=Vname(4,idVvel) Vinfo(16)=Vname(1,idtime) # if defined WRITE_WATER && defined MASKING Vinfo(20)='mask_v' # endif Vinfo(21)=Vname(6,idVvel) Vinfo(22)='coordinates' Aval(5)=REAL(Iinfo(1,idVvel,ng),r8) QCK(ng)%pioVar(idVvel)%dkind=PIO_FOUT QCK(ng)%pioVar(idVvel)%gtype=v3dvar ! status=def_var(ng, model, QCK(ng)%pioFile, & & QCK(ng)%pioVar(idVvel)%vd, & & PIO_FOUT, nvd4, v3dgrd, Aval, Vinfo, ncname) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN END IF ! ! Define model surface U-momentum component. ! IF (Qout(idUsur,ng)) THEN Vinfo( 1)=Vname(1,idUsur) Vinfo( 2)=Vname(2,idUsur) Vinfo( 3)=Vname(3,idUsur) Vinfo(14)=Vname(4,idUsur) Vinfo(16)=Vname(1,idtime) # if defined WRITE_WATER && defined MASKING Vinfo(20)='mask_u' # endif Vinfo(21)=Vname(6,idUsur) Vinfo(22)='coordinates' Aval(5)=REAL(Iinfo(1,idUsur,ng),r8) QCK(ng)%pioVar(idUsur)%dkind=PIO_FOUT QCK(ng)%pioVar(idUsur)%gtype=u2dvar ! status=def_var(ng, model, QCK(ng)%pioFile, & & QCK(ng)%pioVar(idUsur)%vd, & & PIO_FOUT, nvd3, u2dgrd, Aval, Vinfo, ncname) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN END IF ! ! Define model surface V-momentum component. ! IF (Qout(idVsur,ng)) THEN Vinfo( 1)=Vname(1,idVsur) Vinfo( 2)=Vname(2,idVsur) Vinfo( 3)=Vname(3,idVsur) Vinfo(14)=Vname(4,idVsur) Vinfo(16)=Vname(1,idtime) # if defined WRITE_WATER && defined MASKING Vinfo(20)='mask_v' # endif Vinfo(21)=Vname(6,idVsur) Vinfo(22)='coordinates' Aval(5)=REAL(Iinfo(1,idVsur,ng),r8) QCK(ng)%pioVar(idVsur)%dkind=PIO_FOUT QCK(ng)%pioVar(idVsur)%gtype=v2dvar ! status=def_var(ng, model, QCK(ng)%pioFile, & & QCK(ng)%pioVar(idVsur)%vd, & & PIO_FOUT, nvd3, v2dgrd, Aval, Vinfo, ncname) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN END IF ! ! Define 3D Eastward momentum component at RHO-points. ! IF (Qout(idu3dE,ng)) THEN Vinfo( 1)=Vname(1,idu3dE) Vinfo( 2)=Vname(2,idu3dE) Vinfo( 3)=Vname(3,idu3dE) Vinfo(14)=Vname(4,idu3dE) Vinfo(16)=Vname(1,idtime) # if defined WRITE_WATER && defined MASKING Vinfo(20)='mask_rho' # endif Vinfo(21)=Vname(6,idu3dE) Vinfo(22)='coordinates' Aval(5)=REAL(Iinfo(1,idu3dE,ng),r8) QCK(ng)%pioVar(idu3dE)%dkind=PIO_FOUT QCK(ng)%pioVar(idu3dE)%gtype=r3dvar ! status=def_var(ng, model, QCK(ng)%pioFile, & & QCK(ng)%pioVar(idu3dE)%vd, & & PIO_FOUT, nvd4, t3dgrd, Aval, Vinfo, ncname) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN END IF ! ! Define 3D Northward momentum component at RHO-points. ! IF (Qout(idv3dN,ng)) THEN Vinfo( 1)=Vname(1,idv3dN) Vinfo( 2)=Vname(2,idv3dN) Vinfo( 3)=Vname(3,idv3dN) Vinfo(14)=Vname(4,idv3dN) Vinfo(16)=Vname(1,idtime) # if defined WRITE_WATER && defined MASKING Vinfo(20)='mask_rho' # endif Vinfo(21)=Vname(6,idv3dN) Vinfo(22)='coordinates' Aval(5)=REAL(Iinfo(1,idv3dN,ng),r8) QCK(ng)%pioVar(idv3dN)%dkind=PIO_FOUT QCK(ng)%pioVar(idv3dN)%gtype=r3dvar ! status=def_var(ng, model, QCK(ng)%pioFile, & & QCK(ng)%pioVar(idv3dN)%vd, & & PIO_FOUT, nvd4, t3dgrd, Aval, Vinfo, ncname) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN END IF ! ! Define model surface Eastward momentum component at RHO-points. ! IF (Qout(idUsuE,ng)) THEN Vinfo( 1)=Vname(1,idUsuE) Vinfo( 2)=Vname(2,idUsuE) Vinfo( 3)=Vname(3,idUsuE) Vinfo(14)=Vname(4,idUsuE) Vinfo(16)=Vname(1,idtime) # if defined WRITE_WATER && defined MASKING Vinfo(20)='mask_rho' # endif Vinfo(21)=Vname(6,idUsuE) Vinfo(22)='coordinates' Aval(5)=REAL(Iinfo(1,idUsuE,ng),r8) QCK(ng)%pioVar(idUsuE)%dkind=PIO_FOUT QCK(ng)%pioVar(idUsuE)%gtype=r2dvar ! status=def_var(ng, model, QCK(ng)%pioFile, & & QCK(ng)%pioVar(idUsuE)%vd, & & PIO_FOUT, nvd3, t2dgrd, Aval, Vinfo, ncname) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN END IF ! ! Define model surface Northward momentum component at RHO-points. ! IF (Qout(idVsuN,ng)) THEN Vinfo( 1)=Vname(1,idVsuN) Vinfo( 2)=Vname(2,idVsuN) Vinfo( 3)=Vname(3,idVsuN) Vinfo(14)=Vname(4,idVsuN) Vinfo(16)=Vname(1,idtime) # if defined WRITE_WATER && defined MASKING Vinfo(20)='mask_rho' # endif Vinfo(21)=Vname(6,idVsuN) Vinfo(22)='coordinates' Aval(5)=REAL(Iinfo(1,idVsuN,ng),r8) QCK(ng)%pioVar(idVsuN)%dkind=PIO_FOUT QCK(ng)%pioVar(idVsuN)%gtype=r2dvar ! status=def_var(ng, model, QCK(ng)%pioFile, & & QCK(ng)%pioVar(idVsuN)%vd, & & PIO_FOUT, nvd3, t2dgrd, Aval, Vinfo, ncname) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN END IF ! ! Define 3D momentum component in the S-direction. ! IF (Qout(idWvel,ng)) THEN Vinfo( 1)=Vname(1,idWvel) Vinfo( 2)=Vname(2,idWvel) Vinfo( 3)=Vname(3,idWvel) Vinfo(14)=Vname(4,idWvel) Vinfo(16)=Vname(1,idtime) # if defined WRITE_WATER && defined MASKING Vinfo(20)='mask_rho' # endif Vinfo(21)=Vname(6,idWvel) Vinfo(22)='coordinates' Aval(5)=REAL(Iinfo(1,idWvel,ng),r8) QCK(ng)%pioVar(idWvel)%dkind=PIO_FOUT QCK(ng)%pioVar(idWvel)%gtype=w3dvar ! status=def_var(ng, model, QCK(ng)%pioFile, & & QCK(ng)%pioVar(idWvel)%vd, & & PIO_FOUT, nvd4, w3dgrd, Aval, Vinfo, ncname) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN END IF ! ! Define S-coordinate vertical "omega" momentum component. ! IF (Qout(idOvel,ng)) THEN Vinfo( 1)=Vname(1,idOvel) Vinfo( 2)=Vname(2,idOvel) Vinfo( 3)='meter second-1' Vinfo(14)=Vname(4,idOvel) Vinfo(16)=Vname(1,idtime) # if defined WRITE_WATER && defined MASKING Vinfo(20)='mask_rho' # endif Vinfo(21)=Vname(6,idOvel) Vinfo(22)='coordinates' Aval(5)=REAL(Iinfo(1,idOvel,ng),r8) QCK(ng)%pioVar(idOvel)%dkind=PIO_FOUT QCK(ng)%pioVar(idOvel)%gtype=w3dvar ! status=def_var(ng, model, QCK(ng)%pioFile, & & QCK(ng)%pioVar(idOvel)%vd, & & PIO_FOUT, nvd4, w3dgrd, Aval, Vinfo, ncname) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN END IF ! ! Define tracer type variables. ! DO itrc=1,NT(ng) IF (Qout(idTvar(itrc),ng)) THEN Vinfo( 1)=Vname(1,idTvar(itrc)) Vinfo( 2)=Vname(2,idTvar(itrc)) Vinfo( 3)=Vname(3,idTvar(itrc)) Vinfo(14)=Vname(4,idTvar(itrc)) Vinfo(16)=Vname(1,idtime) # ifdef SEDIMENT DO i=1,NST IF (itrc.eq.idsed(i)) THEN WRITE (Vinfo(19),50) 1000.0_r8*Sd50(i,ng) END IF END DO # endif # if defined WRITE_WATER && defined MASKING Vinfo(20)='mask_rho' # endif Vinfo(21)=Vname(6,idTvar(itrc)) Vinfo(22)='coordinates' Aval(5)=REAL(r3dvar,r8) QCK(ng)%pioTrc(itrc)%dkind=PIO_FOUT QCK(ng)%pioTrc(itrc)%gtype=r3dvar ! status=def_var(ng, model, QCK(ng)%pioFile, & & QCK(ng)%pioTrc(itrc)%vd, & & PIO_FOUT, nvd4, t3dgrd, Aval, Vinfo, ncname) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN END IF END DO ! ! Define surface tracer type variables. ! DO itrc=1,NT(ng) IF (Qout(idsurT(itrc),ng)) THEN Vinfo( 1)=Vname(1,idsurT(itrc)) Vinfo( 2)=Vname(2,idsurT(itrc)) Vinfo( 3)=Vname(3,idsurT(itrc)) Vinfo(14)=Vname(4,idsurT(itrc)) Vinfo(16)=Vname(1,idtime) # ifdef SEDIMENT DO i=1,NST IF (itrc.eq.idsed(i)) THEN WRITE (Vinfo(19),50) 1000.0_r8*Sd50(i,ng) END IF END DO # endif # if defined WRITE_WATER && defined MASKING Vinfo(20)='mask_rho' # endif Vinfo(21)=Vname(6,idsurT(itrc)) Vinfo(22)='coordinates' Aval(5)=REAL(r2dvar,r8) QCK(ng)%pioVar(idsurT(itrc))%dkind=PIO_FOUT QCK(ng)%pioVar(idsurT(itrc))%gtype=r2dvar ! status=def_var(ng, model, QCK(ng)%pioFile, & & QCK(ng)%pioVar(idsurT(itrc))%vd, & & PIO_FOUT, nvd3, t2dgrd, Aval, Vinfo, ncname) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN END IF END DO ! ! Define density anomaly. ! IF (Qout(idDano,ng)) THEN Vinfo( 1)=Vname(1,idDano) Vinfo( 2)=Vname(2,idDano) Vinfo( 3)=Vname(3,idDano) Vinfo(14)=Vname(4,idDano) Vinfo(16)=Vname(1,idtime) # if defined WRITE_WATER && defined MASKING Vinfo(20)='mask_rho' # endif Vinfo(21)=Vname(6,idDano) Vinfo(22)='coordinates' Aval(5)=REAL(Iinfo(1,idDano,ng),r8) QCK(ng)%pioVar(idDano)%dkind=PIO_FOUT QCK(ng)%pioVar(idDano)%gtype=r3dvar ! status=def_var(ng, model, QCK(ng)%pioFile, & & QCK(ng)%pioVar(idDano)%vd, & & PIO_FOUT, nvd4, t3dgrd, Aval, Vinfo, ncname) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN END IF # ifdef LMD_SKPP ! ! Define depth of surface boundary layer. ! IF (Qout(idHsbl,ng)) THEN Vinfo( 1)=Vname(1,idHsbl) Vinfo( 2)=Vname(2,idHsbl) Vinfo( 3)=Vname(3,idHsbl) Vinfo(14)=Vname(4,idHsbl) Vinfo(16)=Vname(1,idtime) # if defined WRITE_WATER && defined MASKING Vinfo(20)='mask_rho' # endif Vinfo(21)=Vname(6,idHsbl) Vinfo(22)='coordinates' Aval(5)=REAL(Iinfo(1,idHsbl,ng),r8) QCK(ng)%pioVar(idHsbl)%dkind=PIO_FOUT QCK(ng)%pioVar(idHsbl)%gtype=r2dvar ! status=def_var(ng, model, QCK(ng)%pioFile, & & QCK(ng)%pioVar(idHsbl)%vd, & & PIO_FOUT, nvd3, t2dgrd, Aval, Vinfo, ncname) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN END IF # endif # ifdef LMD_BKPP ! ! Define depth of bottom boundary layer. ! IF (Qout(idHbbl,ng)) THEN Vinfo( 1)=Vname(1,idHbbl) Vinfo( 2)=Vname(2,idHbbl) Vinfo( 3)=Vname(3,idHbbl) Vinfo(14)=Vname(4,idHbbl) Vinfo(16)=Vname(1,idtime) # if defined WRITE_WATER && defined MASKING Vinfo(20)='mask_rho' # endif Vinfo(21)=Vname(6,idHbbl) Vinfo(22)='coordinates' Aval(5)=REAL(Iinfo(1,idHbbl,ng),r8) QCK(ng)%pioVar(idHbbl)%dkind=PIO_FOUT QCK(ng)%pioVar(idHbbl)%gtype=r2dvar ! status=def_var(ng, model, QCK(ng)%pioFile, & & QCK(ng)%pioVar(idHbbl)%vd, & & PIO_FOUT, nvd3, t2dgrd, Aval, Vinfo, ncname) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN END IF # endif ! ! Define vertical viscosity coefficient. ! IF (Qout(idVvis,ng)) THEN Vinfo( 1)=Vname(1,idVvis) Vinfo( 2)=Vname(2,idVvis) Vinfo( 3)=Vname(3,idVvis) Vinfo(14)=Vname(4,idVvis) Vinfo(16)=Vname(1,idtime) # if defined WRITE_WATER && defined MASKING Vinfo(20)='mask_rho' # endif Vinfo(21)=Vname(6,idVvis) Vinfo(22)='coordinates' Aval(5)=REAL(Iinfo(1,idVvis,ng),r8) QCK(ng)%pioVar(idVvis)%dkind=PIO_FOUT QCK(ng)%pioVar(idVvis)%gtype=w3dvar ! status=def_var(ng, model, QCK(ng)%pioFile, & & QCK(ng)%pioVar(idVvis)%vd, & & PIO_FOUT, nvd4, w3dgrd, Aval, Vinfo, ncname, & & SetFillVal = .FALSE.) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN END IF ! ! Define vertical diffusion coefficient for potential temperature. ! IF (Qout(idTdif,ng)) THEN Vinfo( 1)=Vname(1,idTdif) Vinfo( 2)=Vname(2,idTdif) Vinfo( 3)=Vname(3,idTdif) Vinfo(14)=Vname(4,idTdif) Vinfo(16)=Vname(1,idtime) # if defined WRITE_WATER && defined MASKING Vinfo(20)='mask_rho' # endif Vinfo(21)=Vname(6,idTdif) Vinfo(22)='coordinates' Aval(5)=REAL(Iinfo(1,idTdif,ng),r8) QCK(ng)%pioVar(idTdif)%dkind=PIO_FOUT QCK(ng)%pioVar(idTdif)%gtype=w3dvar ! status=def_var(ng, model, QCK(ng)%pioFile, & & QCK(ng)%pioVar(idTdif)%vd, & & PIO_FOUT, nvd4, w3dgrd, Aval, Vinfo, ncname, & & SetFillVal = .FALSE.) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN END IF # ifdef SALINITY ! ! Define vertical diffusion coefficient for salinity. ! IF (Qout(idSdif,ng)) THEN Vinfo( 1)=Vname(1,idSdif) Vinfo( 2)=Vname(2,idSdif) Vinfo( 3)=Vname(3,idSdif) Vinfo(14)=Vname(4,idSdif) Vinfo(16)=Vname(1,idtime) # if defined WRITE_WATER && defined MASKING Vinfo(20)='mask_rho' # endif Vinfo(21)=Vname(6,idSdif) Vinfo(22)='coordinates' Aval(5)=REAL(Iinfo(1,idSdif,ng),r8) QCK(ng)%pioVar(idSdif)%dkind=PIO_FOUT QCK(ng)%pioVar(idSdif)%gtype=w3dvar ! status=def_var(ng, model, QCK(ng)%pioFile, & & QCK(ng)%pioVar(idSdif)%vd, & & PIO_FOUT, nvd4, w3dgrd, Aval, Vinfo, ncname, & & SetFillVal = .FALSE.) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN END IF # endif # if defined GLS_MIXING || defined MY25_MIXING ! ! Define turbulent kinetic energy. ! IF (Qout(idMtke,ng)) THEN Vinfo( 1)=Vname(1,idMtke) Vinfo( 2)=Vname(2,idMtke) Vinfo( 3)=Vname(3,idMtke) Vinfo(14)=Vname(4,idMtke) Vinfo(16)=Vname(1,idtime) # if defined WRITE_WATER && defined MASKING Vinfo(20)='mask_rho' # endif Vinfo(21)=Vname(6,idMtke) Vinfo(22)='coordinates' Aval(5)=REAL(Iinfo(1,idMtke,ng),r8) QCK(ng)%pioVar(idMtke)%dkind=PIO_FOUT QCK(ng)%pioVar(idMtke)%gtype=w3dvar ! status=def_var(ng, model, QCK(ng)%pioFile, & & QCK(ng)%pioVar(idMtke)%vd, & & PIO_FOUT, nvd4, w3dgrd, Aval, Vinfo, ncname, & & SetFillVal = .FALSE.) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN END IF ! ! Define turbulent kinetic energy time length scale. ! IF (Qout(idMtls,ng)) THEN Vinfo( 1)=Vname(1,idMtls) Vinfo( 2)=Vname(2,idMtls) Vinfo( 3)=Vname(3,idMtls) Vinfo(14)=Vname(4,idMtls) Vinfo(16)=Vname(1,idtime) # if defined WRITE_WATER && defined MASKING Vinfo(20)='mask_rho' # endif Vinfo(21)=Vname(6,idMtls) Vinfo(22)='coordinates' Aval(5)=REAL(Iinfo(1,idMtls,ng),r8) QCK(ng)%pioVar(idMtls)%dkind=PIO_FOUT QCK(ng)%pioVar(idMtls)%gtype=w3dvar ! status=def_var(ng, model, QCK(ng)%pioFile, & & QCK(ng)%pioVar(idMtls)%vd, & & PIO_FOUT, nvd4, w3dgrd, Aval, Vinfo, ncname, & & SetFillVal = .FALSE.) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN END IF # endif # if defined BULK_FLUXES || defined ECOSIM || defined ATM_PRESS ! ! Define surface air pressure. ! IF (Qout(idPair,ng)) THEN Vinfo( 1)=Vname(1,idPair) Vinfo( 2)=Vname(2,idPair) Vinfo( 3)=Vname(3,idPair) Vinfo(14)=Vname(4,idPair) Vinfo(16)=Vname(1,idtime) # if defined WRITE_WATER && defined MASKING Vinfo(20)='mask_rho' # endif Vinfo(21)=Vname(6,idPair) Vinfo(22)='coordinates' Aval(5)=REAL(Iinfo(1,idPair,ng),r8) QCK(ng)%pioVar(idPair)%dkind=PIO_FOUT QCK(ng)%pioVar(idPair)%gtype=r2dvar ! status=def_var(ng, model, QCK(ng)%pioFile, & & QCK(ng)%pioVar(idPair)%vd, & & PIO_FOUT, nvd3, t2dgrd, Aval, Vinfo, ncname) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN END IF # endif # if defined BULK_FLUXES || defined ECOSIM ! ! Define surface winds. ! IF (Qout(idUair,ng)) THEN Vinfo( 1)=Vname(1,idUair) Vinfo( 2)=Vname(2,idUair) Vinfo( 3)=Vname(3,idUair) Vinfo(14)=Vname(4,idUair) Vinfo(16)=Vname(1,idtime) # if defined WRITE_WATER && defined MASKING Vinfo(20)='mask_rho' # endif Vinfo(21)=Vname(6,idUair) Vinfo(22)='coordinates' Aval(5)=REAL(Iinfo(1,idUair,ng),r8) QCK(ng)%pioVar(idUair)%dkind=PIO_FOUT QCK(ng)%pioVar(idUair)%gtype=r2dvar ! status=def_var(ng, model, QCK(ng)%pioFile, & & QCK(ng)%pioVar(idUair)%vd, & & PIO_FOUT, nvd3, t2dgrd, Aval, Vinfo, ncname) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN END IF ! IF (Qout(idVair,ng)) THEN Vinfo( 1)=Vname(1,idVair) Vinfo( 2)=Vname(2,idVair) Vinfo( 3)=Vname(3,idVair) Vinfo(14)=Vname(4,idVair) Vinfo(16)=Vname(1,idtime) # if defined WRITE_WATER && defined MASKING Vinfo(20)='mask_rho' # endif Vinfo(21)=Vname(6,idVair) Vinfo(22)='coordinates' Aval(5)=REAL(Iinfo(1,idVair,ng),r8) QCK(ng)%pioVar(idVair)%dkind=PIO_FOUT QCK(ng)%pioVar(idVair)%gtype=r2dvar ! status=def_var(ng, model, QCK(ng)%pioFile, & & QCK(ng)%pioVar(idVair)%vd, & & PIO_FOUT, nvd3, t2dgrd, Aval, Vinfo, ncname) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN END IF ! ! Define Eastward/Northward surface winds at RHO-points. ! IF (Qout(idUaiE,ng)) THEN Vinfo( 1)=Vname(1,idUaiE) Vinfo( 2)=Vname(2,idUaiE) Vinfo( 3)=Vname(3,idUaiE) Vinfo(14)=Vname(4,idUaiE) Vinfo(16)=Vname(1,idtime) # if defined WRITE_WATER && defined MASKING Vinfo(20)='mask_rho' # endif Vinfo(21)=Vname(6,idUaiE) Vinfo(22)='coordinates' Aval(5)=REAL(Iinfo(1,idUaiE,ng),r8) QCK(ng)%pioVar(idUaiE)%dkind=PIO_FOUT QCK(ng)%pioVar(idUaiE)%gtype=r2dvar ! status=def_var(ng, model, QCK(ng)%pioFile, & & QCK(ng)%pioVar(idUaiE)%vd, & & PIO_FOUT, nvd3, t2dgrd, Aval, Vinfo, ncname) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN END IF ! IF (Qout(idVaiN,ng)) THEN Vinfo( 1)=Vname(1,idVaiN) Vinfo( 2)=Vname(2,idVaiN) Vinfo( 3)=Vname(3,idVaiN) Vinfo(14)=Vname(4,idVaiN) Vinfo(16)=Vname(1,idtime) # if defined WRITE_WATER && defined MASKING Vinfo(20)='mask_rho' # endif Vinfo(21)=Vname(6,idVaiN) Vinfo(22)='coordinates' Aval(5)=REAL(Iinfo(1,idVaiN,ng),r8) QCK(ng)%pioVar(idVaiN)%dkind=PIO_FOUT QCK(ng)%pioVar(idVaiN)%gtype=r2dvar ! status=def_var(ng, model, QCK(ng)%pioFile, & & QCK(ng)%pioVar(idVaiN)%vd, & & PIO_FOUT, nvd3, t2dgrd, Aval, Vinfo, ncname) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN END IF # endif ! ! Define surface active tracer fluxes. ! DO itrc=1,NAT IF (Qout(idTsur(itrc),ng)) THEN Vinfo( 1)=Vname(1,idTsur(itrc)) Vinfo( 2)=Vname(2,idTsur(itrc)) Vinfo( 3)=Vname(3,idTsur(itrc)) IF (itrc.eq.itemp) THEN Vinfo(11)='upward flux, cooling' Vinfo(12)='downward flux, heating' ELSE IF (itrc.eq.isalt) THEN Vinfo(11)='upward flux, freshening (net precipitation)' Vinfo(12)='downward flux, salting (net evaporation)' END IF Vinfo(14)=Vname(4,idTsur(itrc)) Vinfo(16)=Vname(1,idtime) # if defined WRITE_WATER && defined MASKING Vinfo(20)='mask_rho' # endif Vinfo(21)=Vname(6,idTsur(itrc)) Vinfo(22)='coordinates' Aval(5)=REAL(Iinfo(1,idTsur(itrc),ng),r8) QCK(ng)%pioVar(idTsur(itrc))%dkind=PIO_FOUT QCK(ng)%pioVar(idTsur(itrc))%gtype=r2dvar ! status=def_var(ng, model, QCK(ng)%pioFile, & & QCK(ng)%pioVar(idTsur(itrc))%vd, & & PIO_FOUT, nvd3, t2dgrd, Aval, Vinfo, ncname) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN END IF END DO # if defined BULK_FLUXES || defined FRC_COUPLING ! ! Define latent heat flux. ! IF (Qout(idLhea,ng)) THEN Vinfo( 1)=Vname(1,idLhea) Vinfo( 2)=Vname(2,idLhea) Vinfo( 3)=Vname(3,idLhea) Vinfo(11)='upward flux, cooling' Vinfo(12)='downward flux, heating' Vinfo(14)=Vname(4,idLhea) Vinfo(16)=Vname(1,idtime) # if defined WRITE_WATER && defined MASKING Vinfo(20)='mask_rho' # endif Vinfo(21)=Vname(6,idLhea) Vinfo(22)='coordinates' Aval(5)=REAL(Iinfo(1,idLhea,ng),r8) QCK(ng)%pioVar(idLhea)%dkind=PIO_FOUT QCK(ng)%pioVar(idLhea)%gtype=r2dvar ! status=def_var(ng, model, QCK(ng)%pioFile, & & QCK(ng)%pioVar(idLhea)%vd, & & PIO_FOUT, nvd3, t2dgrd, Aval, Vinfo, ncname) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN END IF ! ! Define sensible heat flux. ! IF (Qout(idShea,ng)) THEN Vinfo( 1)=Vname(1,idShea) Vinfo( 2)=Vname(2,idShea) Vinfo( 3)=Vname(3,idShea) Vinfo(11)='upward flux, cooling' Vinfo(12)='downward flux, heating' Vinfo(14)=Vname(4,idShea) Vinfo(16)=Vname(1,idtime) # if defined WRITE_WATER && defined MASKING Vinfo(20)='mask_rho' # endif Vinfo(21)=Vname(6,idShea) Vinfo(22)='coordinates' Aval(5)=REAL(Iinfo(1,idShea,ng),r8) QCK(ng)%pioVar(idShea)%dkind=PIO_FOUT QCK(ng)%pioVar(idShea)%gtype=r2dvar ! status=def_var(ng, model, QCK(ng)%pioFile, & & QCK(ng)%pioVar(idShea)%vd, & & PIO_FOUT, nvd3, t2dgrd, Aval, Vinfo, ncname) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN END IF ! ! Define net longwave radiation flux. ! IF (Qout(idLrad,ng)) THEN Vinfo( 1)=Vname(1,idLrad) Vinfo( 2)=Vname(2,idLrad) Vinfo( 3)=Vname(3,idLrad) Vinfo(11)='upward flux, cooling' Vinfo(12)='downward flux, heating' Vinfo(14)=Vname(4,idLrad) Vinfo(16)=Vname(1,idtime) # if defined WRITE_WATER && defined MASKING Vinfo(20)='mask_rho' # endif Vinfo(21)=Vname(6,idLrad) Vinfo(22)='coordinates' Aval(5)=REAL(Iinfo(1,idLrad,ng),r8) QCK(ng)%pioVar(idLrad)%dkind=PIO_FOUT QCK(ng)%pioVar(idLrad)%gtype=r2dvar ! status=def_var(ng, model, QCK(ng)%pioFile, & & QCK(ng)%pioVar(idLrad)%vd, & & PIO_FOUT, nvd3, t2dgrd, Aval, Vinfo, ncname) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN END IF # endif # if defined BULK_FLUXES ! ! Define atmospheric air temperature. ! IF (Qout(idTair,ng)) THEN Vinfo( 1)=Vname(1,idTair) Vinfo( 2)=Vname(2,idTair) Vinfo( 3)=Vname(3,idTair) Vinfo(14)=Vname(4,idTair) Vinfo(16)=Vname(1,idtime) # if defined WRITE_WATER && defined MASKING Vinfo(20)='mask_rho' # endif Vinfo(21)=Vname(6,idTair) Vinfo(22)='coordinates' Aval(5)=REAL(Iinfo(1,idTair,ng),r8) QCK(ng)%pioVar(idTair)%dkind=PIO_FOUT QCK(ng)%pioVar(idTair)%gtype=r2dvar ! status=def_var(ng, model, QCK(ng)%pioFile, & & QCK(ng)%pioVar(idTair)%vd, & & PIO_FOUT, nvd3, t2dgrd, Aval, Vinfo, ncname) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN END IF # ifdef EMINUSP ! ! Define evaporation rate. ! IF (Qout(idevap,ng)) THEN Vinfo( 1)=Vname(1,idevap) Vinfo( 2)=Vname(2,idevap) Vinfo( 3)=Vname(3,idevap) Vinfo(11)='downward flux, freshening (condensation)' Vinfo(12)='upward flux, salting (evaporation)' Vinfo(14)=Vname(4,idevap) Vinfo(16)=Vname(1,idtime) # if defined WRITE_WATER && defined MASKING Vinfo(20)='mask_rho' # endif Vinfo(21)=Vname(6,idevap) Vinfo(22)='coordinates' Aval(5)=REAL(Iinfo(1,idevap,ng),r8) QCK(ng)%pioVar(idevap)%dkind=PIO_FOUT QCK(ng)%pioVar(idevap)%gtype=r2dvar ! status=def_var(ng, model, QCK(ng)%pioFile, & & QCK(ng)%pioVar(idevap)%vd, & & PIO_FOUT, nvd3, t2dgrd, Aval, Vinfo, ncname) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN END IF ! ! Define precipitation rate. ! IF (Qout(idrain,ng)) THEN Vinfo( 1)=Vname(1,idrain) Vinfo( 2)=Vname(2,idrain) Vinfo( 3)=Vname(3,idrain) Vinfo(11)='upward flux, salting (NOT POSSIBLE)' Vinfo(12)='downward flux, freshening (precipitation)' Vinfo(14)=Vname(4,idrain) Vinfo(16)=Vname(1,idtime) # if defined WRITE_WATER && defined MASKING Vinfo(20)='mask_rho' # endif Vinfo(21)=Vname(6,idrain) Vinfo(22)='coordinates' Aval(5)=REAL(Iinfo(1,idrain,ng),r8) QCK(ng)%pioVar(idrain)%dkind=PIO_FOUT QCK(ng)%pioVar(idrain)%gtype=r2dvar ! status=def_var(ng, model, QCK(ng)%pioFile, & & QCK(ng)%pioVar(idrain)%vd, & & PIO_FOUT, nvd3, t2dgrd, Aval, Vinfo, ncname) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN END IF # endif # endif ! ! Define E-P flux. ! IF (Qout(idEmPf,ng)) THEN Vinfo( 1)=Vname(1,idEmPf) Vinfo( 2)=Vname(2,idEmPf) Vinfo( 3)=Vname(3,idEmPf) Vinfo(11)='upward flux, freshening (net precipitation)' Vinfo(12)='downward flux, salting (net evaporation)' Vinfo(14)=Vname(4,idEmPf) Vinfo(16)=Vname(1,idtime) # if defined WRITE_WATER && defined MASKING Vinfo(20)='mask_rho' # endif Vinfo(21)=Vname(6,idEmPf) Vinfo(22)='coordinates' Aval(5)=REAL(Iinfo(1,idEmPf,ng),r8) QCK(ng)%pioVar(idEmPf)%dkind=PIO_FOUT QCK(ng)%pioVar(idEmPf)%gtype=r2dvar ! status=def_var(ng, model, QCK(ng)%pioFile, & & QCK(ng)%pioVar(idEmPf)%vd, & & PIO_FOUT, nvd3, t2dgrd, Aval, Vinfo, ncname) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN END IF # ifdef SHORTWAVE ! ! Define net shortwave radiation flux. ! IF (Qout(idSrad,ng)) THEN Vinfo( 1)=Vname(1,idSrad) Vinfo( 2)=Vname(2,idSrad) Vinfo( 3)=Vname(3,idSrad) Vinfo(11)='upward flux, cooling' Vinfo(12)='downward flux, heating' Vinfo(14)=Vname(4,idSrad) Vinfo(16)=Vname(1,idtime) # if defined WRITE_WATER && defined MASKING Vinfo(20)='mask_rho' # endif Vinfo(21)=Vname(6,idSrad) Vinfo(22)='coordinates' Aval(5)=REAL(Iinfo(1,idSrad,ng),r8) QCK(ng)%pioVar(idSrad)%dkind=PIO_FOUT QCK(ng)%pioVar(idSrad)%gtype=r2dvar ! status=def_var(ng, model, QCK(ng)%pioFile, & & QCK(ng)%pioVar(idSrad)%vd, & & PIO_FOUT, nvd3, t2dgrd, Aval, Vinfo, ncname) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN END IF # endif # endif ! ! Define surface U-momentum stress. ! IF (Qout(idUsms,ng)) THEN Vinfo( 1)=Vname(1,idUsms) Vinfo( 2)=Vname(2,idUsms) Vinfo( 3)=Vname(3,idUsms) Vinfo(14)=Vname(4,idUsms) Vinfo(16)=Vname(1,idtime) # if defined WRITE_WATER && defined MASKING Vinfo(20)='mask_u' # endif Vinfo(21)=Vname(6,idUsms) Vinfo(22)='coordinates' Aval(5)=REAL(Iinfo(1,idUsms,ng),r8) QCK(ng)%pioVar(idUsms)%dkind=PIO_FOUT QCK(ng)%pioVar(idUsms)%gtype=u2dvar ! status=def_var(ng, model, QCK(ng)%pioFile, & & QCK(ng)%pioVar(idUsms)%vd, & & PIO_FOUT, nvd3, u2dgrd, Aval, Vinfo, ncname) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN END IF ! ! Define surface V-momentum stress. ! IF (Qout(idVsms,ng)) THEN Vinfo( 1)=Vname(1,idVsms) Vinfo( 2)=Vname(2,idVsms) Vinfo( 3)=Vname(3,idVsms) Vinfo(14)=Vname(4,idVsms) Vinfo(16)=Vname(1,idtime) # if defined WRITE_WATER && defined MASKING Vinfo(20)='mask_v' # endif Vinfo(21)=Vname(6,idVsms) Vinfo(22)='coordinates' Aval(5)=REAL(Iinfo(1,idVsms,ng),r8) QCK(ng)%pioVar(idVsms)%dkind=PIO_FOUT QCK(ng)%pioVar(idVsms)%gtype=v2dvar ! status=def_var(ng, model, QCK(ng)%pioFile, & & QCK(ng)%pioVar(idVsms)%vd, & & PIO_FOUT, nvd3, v2dgrd, Aval, Vinfo, ncname) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN END IF ! ! Define bottom U-momentum stress. ! IF (Qout(idUbms,ng)) THEN Vinfo( 1)=Vname(1,idUbms) Vinfo( 2)=Vname(2,idUbms) Vinfo( 3)=Vname(3,idUbms) Vinfo(14)=Vname(4,idUbms) Vinfo(16)=Vname(1,idtime) # if defined WRITE_WATER && defined MASKING Vinfo(20)='mask_u' # endif Vinfo(21)=Vname(6,idUbms) Vinfo(22)='coordinates' Aval(5)=REAL(Iinfo(1,idUbms,ng),r8) QCK(ng)%pioVar(idUbms)%dkind=PIO_FOUT QCK(ng)%pioVar(idUbms)%gtype=u2dvar ! status=def_var(ng, model, QCK(ng)%pioFile, & & QCK(ng)%pioVar(idUbms)%vd, & & PIO_FOUT, nvd3, u2dgrd, Aval, Vinfo, ncname) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN END IF ! ! Define bottom V-momentum stress. ! IF (Qout(idVbms,ng)) THEN Vinfo( 1)=Vname(1,idVbms) Vinfo( 2)=Vname(2,idVbms) Vinfo( 3)=Vname(3,idVbms) Vinfo(14)=Vname(4,idVbms) Vinfo(16)=Vname(1,idtime) # if defined WRITE_WATER && defined MASKING Vinfo(20)='mask_v' # endif Vinfo(21)=Vname(6,idVbms) Vinfo(22)='coordinates' Aval(5)=REAL(Iinfo(1,idVbms,ng),r8) QCK(ng)%pioVar(idVbms)%dkind=PIO_FOUT QCK(ng)%pioVar(idVbms)%gtype=v2dvar ! status=def_var(ng, model, QCK(ng)%pioFile, & & QCK(ng)%pioVar(idVbms)%vd, & & PIO_FOUT, nvd3, v2dgrd, Aval, Vinfo, ncname) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN END IF # if (defined BBL_MODEL || defined WAVES_OUTPUT) && defined SOLVE3D ! !----------------------------------------------------------------------- ! Define the bottom boundary layer model or waves variables. !----------------------------------------------------------------------- ! CALL bbl_def_pio (ng, model, ldef, Qout, QCK, & & t2dgrd, u2dgrd, v2dgrd) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN # endif # if defined ICE_MODEL && defined SOLVE3D ! !----------------------------------------------------------------------- ! Define the sea-ice model variables. !----------------------------------------------------------------------- ! CALL ice_def_pio (ng, model, ldef, Qout, QCK, & & t2dgrd, u2dgrd, v2dgrd) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN # endif # if defined SEDIMENT && defined SOLVE3D ! !----------------------------------------------------------------------- ! Define the sediment model variables. !----------------------------------------------------------------------- ! CALL sediment_def_pio (ng, model, ldef, Qout, QCK, & & t2dgrd, u2dgrd, v2dgrd) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN # endif # if defined WEC_VF && defined SOLVE3D ! !----------------------------------------------------------------------- ! Define the Waves Effect on Currents variables. !----------------------------------------------------------------------- ! CALL wec_def_pio (ng, model, ldef, Qout, QCK, & & t2dgrd, u2dgrd, v2dgrd, & & t3dgrd, u3dgrd, v3dgrd, w3dgrd) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN # endif ! !----------------------------------------------------------------------- ! Leave definition mode. !----------------------------------------------------------------------- ! CALL pio_netcdf_enddef (ng, model, ncname, QCK(ng)%pioFile) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN ! !----------------------------------------------------------------------- ! Write out time-recordless, information variables. !----------------------------------------------------------------------- ! CALL wrt_info (ng, model, QCK(ng)%pioFile, ncname) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN END IF DEFINE ! !======================================================================= ! Open an existing quicksave file, check its contents, and prepare ! for appending data. !======================================================================= ! QUERY : IF (.not.ldef) THEN ncname=QCK(ng)%name ! ! Open quicksave file for read/write. ! CALL pio_netcdf_open (ng, model, ncname, 1, QCK(ng)%pioFile) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) THEN WRITE (stdout,60) TRIM(ncname) RETURN END IF ! ! Inquire about the dimensions and check for consistency. ! CALL pio_netcdf_check_dim (ng, model, ncname, & & pioFile = QCK(ng)%pioFile) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN ! ! Inquire about the variables. ! CALL pio_netcdf_inq_var (ng, model, ncname, & & pioFile = QCK(ng)%pioFile) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN ! ! Initialize logical switches. ! DO i=1,NV got_var(i)=.FALSE. END DO ! ! Scan variable list from input NetCDF and activate switches for ! quicksave variables. Get variable IDs. ! DO i=1,n_var IF (TRIM(var_name(i)).eq.TRIM(Vname(1,idtime))) THEN got_var(idtime)=.TRUE. QCK(ng)%pioVar(idtime)%vd=var_desc(i) QCK(ng)%pioVar(idtime)%dkind=PIO_TOUT QCK(ng)%pioVar(idtime)%gtype=0 # if defined WET_DRY ELSE IF (TRIM(var_name(i)).eq.TRIM(Vname(1,idPwet))) THEN got_var(idPwet)=.TRUE. QCK(ng)%pioVar(idPwet)%vd=var_desc(i) QCK(ng)%pioVar(idPwet)%dkind=PIO_FOUT QCK(ng)%pioVar(idPwet)%gtype=p2dvar ELSE IF (TRIM(var_name(i)).eq.TRIM(Vname(1,idRwet))) THEN got_var(idRwet)=.TRUE. QCK(ng)%pioVar(idRwet)%vd=var_desc(i) QCK(ng)%pioVar(idRwet)%dkind=PIO_FOUT QCK(ng)%pioVar(idRwet)%gtype=r2dvar ELSE IF (TRIM(var_name(i)).eq.TRIM(Vname(1,idUwet))) THEN got_var(idUwet)=.TRUE. QCK(ng)%pioVar(idUwet)%vd=var_desc(i) QCK(ng)%pioVar(idUwet)%dkind=PIO_FOUT QCK(ng)%pioVar(idUwet)%gtype=u2dvar ELSE IF (TRIM(var_name(i)).eq.TRIM(Vname(1,idVwet))) THEN got_var(idVwet)=.TRUE. QCK(ng)%pioVar(idVwet)%vd=var_desc(i) QCK(ng)%pioVar(idVwet)%dkind=PIO_FOUT QCK(ng)%pioVar(idVwet)%gtype=v2dvar # endif # ifdef SOLVE3D ELSE IF (TRIM(var_name(i)).eq.TRIM(Vname(1,idpthR))) THEN got_var(idpthR)=.TRUE. QCK(ng)%pioVar(idpthR)%vd=var_desc(i) QCK(ng)%pioVar(idpthR)%dkind=PIO_FOUT QCK(ng)%pioVar(idpthR)%gtype=r3dvar ELSE IF (TRIM(var_name(i)).eq.TRIM(Vname(1,idpthU))) THEN got_var(idpthU)=.TRUE. QCK(ng)%pioVar(idpthU)%vd=var_desc(i) QCK(ng)%pioVar(idpthU)%dkind=PIO_FOUT QCK(ng)%pioVar(idpthU)%gtype=u3dvar ELSE IF (TRIM(var_name(i)).eq.TRIM(Vname(1,idpthV))) THEN got_var(idpthV)=.TRUE. QCK(ng)%pioVar(idpthV)%vd=var_desc(i) QCK(ng)%pioVar(idpthV)%dkind=PIO_FOUT QCK(ng)%pioVar(idpthV)%gtype=v3dvar ELSE IF (TRIM(var_name(i)).eq.TRIM(Vname(1,idpthW))) THEN got_var(idpthW)=.TRUE. QCK(ng)%pioVar(idpthW)%vd=var_desc(i) QCK(ng)%pioVar(idpthW)%dkind=PIO_FOUT QCK(ng)%pioVar(idpthW)%gtype=w3dvar # endif ELSE IF (TRIM(var_name(i)).eq.TRIM(Vname(1,idFsur))) THEN got_var(idFsur)=.TRUE. QCK(ng)%pioVar(idFsur)%vd=var_desc(i) QCK(ng)%pioVar(idFsur)%dkind=PIO_FOUT QCK(ng)%pioVar(idFsur)%gtype=r2dvar ELSE IF (TRIM(var_name(i)).eq.TRIM(Vname(1,idUbar))) THEN got_var(idUbar)=.TRUE. QCK(ng)%pioVar(idUbar)%vd=var_desc(i) QCK(ng)%pioVar(idUbar)%dkind=PIO_FOUT QCK(ng)%pioVar(idUbar)%gtype=u2dvar ELSE IF (TRIM(var_name(i)).eq.TRIM(Vname(1,idVbar))) THEN got_var(idVbar)=.TRUE. QCK(ng)%pioVar(idVbar)%vd=var_desc(i) QCK(ng)%pioVar(idVbar)%dkind=PIO_FOUT QCK(ng)%pioVar(idVbar)%gtype=v2dvar ELSE IF (TRIM(var_name(i)).eq.TRIM(Vname(1,idu2dE))) THEN got_var(idu2dE)=.TRUE. QCK(ng)%pioVar(idu2dE)%vd=var_desc(i) QCK(ng)%pioVar(idu2dE)%dkind=PIO_FOUT QCK(ng)%pioVar(idu2dE)%gtype=r2dvar ELSE IF (TRIM(var_name(i)).eq.TRIM(Vname(1,idv2dN))) THEN got_var(idv2dN)=.TRUE. QCK(ng)%pioVar(idv2dN)%vd=var_desc(i) QCK(ng)%pioVar(idv2dN)%dkind=PIO_FOUT QCK(ng)%pioVar(idv2dN)%gtype=r2dvar # ifdef SOLVE3D ELSE IF (TRIM(var_name(i)).eq.TRIM(Vname(1,idUvel))) THEN got_var(idUvel)=.TRUE. QCK(ng)%pioVar(idUvel)%vd=var_desc(i) QCK(ng)%pioVar(idUvel)%dkind=PIO_FOUT QCK(ng)%pioVar(idUvel)%gtype=u3dvar ELSE IF (TRIM(var_name(i)).eq.TRIM(Vname(1,idVvel))) THEN got_var(idVvel)=.TRUE. QCK(ng)%pioVar(idVvel)%vd=var_desc(i) QCK(ng)%pioVar(idVvel)%dkind=PIO_FOUT QCK(ng)%pioVar(idVvel)%gtype=v3dvar ELSE IF (TRIM(var_name(i)).eq.TRIM(Vname(1,idUsur))) THEN got_var(idUsur)=.TRUE. QCK(ng)%pioVar(idUsur)%vd=var_desc(i) QCK(ng)%pioVar(idUsur)%dkind=PIO_FOUT QCK(ng)%pioVar(idUsur)%gtype=u2dvar ELSE IF (TRIM(var_name(i)).eq.TRIM(Vname(1,idVsur))) THEN got_var(idVsur)=.TRUE. QCK(ng)%pioVar(idVsur)%vd=var_desc(i) QCK(ng)%pioVar(idVsur)%dkind=PIO_FOUT QCK(ng)%pioVar(idVsur)%gtype=v2dvar ELSE IF (TRIM(var_name(i)).eq.TRIM(Vname(1,idu3dE))) THEN got_var(idu3dE)=.TRUE. QCK(ng)%pioVar(idu3dE)%vd=var_desc(i) QCK(ng)%pioVar(idu3dE)%dkind=PIO_FOUT QCK(ng)%pioVar(idu3dE)%gtype=r3dvar ELSE IF (TRIM(var_name(i)).eq.TRIM(Vname(1,idv3dN))) THEN got_var(idv3dN)=.TRUE. QCK(ng)%pioVar(idv3dN)%vd=var_desc(i) QCK(ng)%pioVar(idv3dN)%dkind=PIO_FOUT QCK(ng)%pioVar(idv3dN)%gtype=r3dvar ELSE IF (TRIM(var_name(i)).eq.TRIM(Vname(1,idUsuE))) THEN got_var(idUsuE)=.TRUE. QCK(ng)%pioVar(idUsuE)%vd=var_desc(i) QCK(ng)%pioVar(idUsuE)%dkind=PIO_FOUT QCK(ng)%pioVar(idUsuE)%gtype=r2dvar ELSE IF (TRIM(var_name(i)).eq.TRIM(Vname(1,idVsuN))) THEN got_var(idVsuN)=.TRUE. QCK(ng)%pioVar(idVsuN)%vd=var_desc(i) QCK(ng)%pioVar(idVsuN)%dkind=PIO_FOUT QCK(ng)%pioVar(idVsuN)%gtype=r2dvar ELSE IF (TRIM(var_name(i)).eq.TRIM(Vname(1,idWvel))) THEN got_var(idWvel)=.TRUE. QCK(ng)%pioVar(idWvel)%vd=var_desc(i) QCK(ng)%pioVar(idWvel)%dkind=PIO_FOUT QCK(ng)%pioVar(idWvel)%gtype=w3dvar ELSE IF (TRIM(var_name(i)).eq.TRIM(Vname(1,idOvel))) THEN got_var(idOvel)=.TRUE. QCK(ng)%pioVar(idOvel)%vd=var_desc(i) QCK(ng)%pioVar(idOvel)%dkind=PIO_FOUT QCK(ng)%pioVar(idOvel)%gtype=w3dvar ELSE IF (TRIM(var_name(i)).eq.TRIM(Vname(1,idDano))) THEN got_var(idDano)=.TRUE. QCK(ng)%pioVar(idDano)%vd=var_desc(i) QCK(ng)%pioVar(idDano)%dkind=PIO_FOUT QCK(ng)%pioVar(idDano)%gtype=r3dvar # ifdef LMD_SKPP ELSE IF (TRIM(var_name(i)).eq.TRIM(Vname(1,idHsbl))) THEN got_var(idHsbl)=.TRUE. QCK(ng)%pioVar(idHsbl)%vd=var_desc(i) QCK(ng)%pioVar(idHsbl)%dkind=PIO_FOUT QCK(ng)%pioVar(idHsbl)%gtype=r2dvar # endif # ifdef LMD_BKPP ELSE IF (TRIM(var_name(i)).eq.TRIM(Vname(1,idHbbl))) THEN got_var(idHbbl)=.TRUE. QCK(ng)%pioVar(idHbbl)%vd=var_desc(i) QCK(ng)%pioVar(idHbbl)%dkind=PIO_FOUT QCK(ng)%pioVar(idHbbl)%gtype=r2dvar # endif ELSE IF (TRIM(var_name(i)).eq.TRIM(Vname(1,idVvis))) THEN got_var(idVvis)=.TRUE. QCK(ng)%pioVar(idVvis)%vd=var_desc(i) QCK(ng)%pioVar(idVvis)%dkind=PIO_FOUT QCK(ng)%pioVar(idVvis)%gtype=w3dvar ELSE IF (TRIM(var_name(i)).eq.TRIM(Vname(1,idTdif))) THEN got_var(idTdif)=.TRUE. QCK(ng)%pioVar(idTdif)%vd=var_desc(i) QCK(ng)%pioVar(idTdif)%dkind=PIO_FOUT QCK(ng)%pioVar(idTdif)%gtype=w3dvar ELSE IF (TRIM(var_name(i)).eq.TRIM(Vname(1,idSdif))) THEN got_var(idSdif)=.TRUE. QCK(ng)%pioVar(idSdif)%vd=var_desc(i) QCK(ng)%pioVar(idSdif)%dkind=PIO_FOUT QCK(ng)%pioVar(idSdif)%gtype=w3dvar # if defined GLS_MIXING || defined MY25_MIXING ELSE IF (TRIM(var_name(i)).eq.TRIM(Vname(1,idMtke))) THEN got_var(idMtke)=.TRUE. QCK(ng)%pioVar(idMtke)%vd=var_desc(i) QCK(ng)%pioVar(idMtke)%dkind=PIO_FOUT QCK(ng)%pioVar(idMtke)%gtype=w3dvar ELSE IF (TRIM(var_name(i)).eq.TRIM(Vname(1,idMtls))) THEN got_var(idMtls)=.TRUE. QCK(ng)%pioVar(idMtls)%vd=var_desc(i) QCK(ng)%pioVar(idMtls)%dkind=PIO_FOUT QCK(ng)%pioVar(idMtls)%gtype=w3dvar # endif # if defined BULK_FLUXES || defined ECOSIM || defined ATM_PRESS ELSE IF (TRIM(var_name(i)).eq.TRIM(Vname(1,idPair))) THEN got_var(idPair)=.TRUE. QCK(ng)%pioVar(idPair)%vd=var_desc(i) QCK(ng)%pioVar(idPair)%dkind=PIO_FOUT QCK(ng)%pioVar(idPair)%gtype=r2dvar # endif # if defined BULK_FLUXES || defined ECOSIM ELSE IF (TRIM(var_name(i)).eq.TRIM(Vname(1,idUair))) THEN got_var(idUair)=.TRUE. QCK(ng)%pioVar(idUair)%vd=var_desc(i) QCK(ng)%pioVar(idUair)%dkind=PIO_FOUT QCK(ng)%pioVar(idUair)%gtype=r2dvar ELSE IF (TRIM(var_name(i)).eq.TRIM(Vname(1,idVair))) THEN got_var(idVair)=.TRUE. QCK(ng)%pioVar(idVair)%vd=var_desc(i) QCK(ng)%pioVar(idVair)%dkind=PIO_FOUT QCK(ng)%pioVar(idVair)%gtype=r2dvar ELSE IF (TRIM(var_name(i)).eq.TRIM(Vname(1,idUaiE))) THEN got_var(idUair)=.TRUE. QCK(ng)%pioVar(idUaiE)%vd=var_desc(i) QCK(ng)%pioVar(idUaiE)%dkind=PIO_FOUT QCK(ng)%pioVar(idUaiE)%gtype=r2dvar ELSE IF (TRIM(var_name(i)).eq.TRIM(Vname(1,idVaiN))) THEN got_var(idVair)=.TRUE. QCK(ng)%pioVar(idVaiN)%vd=var_desc(i) QCK(ng)%pioVar(idVaiN)%dkind=PIO_FOUT QCK(ng)%pioVar(idVaiN)%gtype=r2dvar # endif # if defined BULK_FLUXES || defined FRC_COUPLING ELSE IF (TRIM(var_name(i)).eq.TRIM(Vname(1,idLhea))) THEN got_var(idLhea)=.TRUE. QCK(ng)%pioVar(idLhea)%vd=var_desc(i) QCK(ng)%pioVar(idLhea)%dkind=PIO_FOUT QCK(ng)%pioVar(idLhea)%gtype=r2dvar ELSE IF (TRIM(var_name(i)).eq.TRIM(Vname(1,idShea))) THEN got_var(idShea)=.TRUE. QCK(ng)%pioVar(idShea)%vd=var_desc(i) QCK(ng)%pioVar(idShea)%dkind=PIO_FOUT QCK(ng)%pioVar(idShea)%gtype=r2dvar ELSE IF (TRIM(var_name(i)).eq.TRIM(Vname(1,idLrad))) THEN got_var(idLrad)=.TRUE. QCK(ng)%pioVar(idLrad)%vd=var_desc(i) QCK(ng)%pioVar(idLrad)%dkind=PIO_FOUT QCK(ng)%pioVar(idLrad)%gtype=r2dvar # endif # ifdef BULK_FLUXES ELSE IF (TRIM(var_name(i)).eq.TRIM(Vname(1,idTair))) THEN got_var(idTair)=.TRUE. QCK(ng)%pioVar(idTair)%vd=var_desc(i) QCK(ng)%pioVar(idTair)%dkind=PIO_FOUT QCK(ng)%pioVar(idTair)%gtype=r2dvar # ifdef EMINUSP ELSE IF (TRIM(var_name(i)).eq.TRIM(Vname(1,idevap))) THEN got_var(idevap)=.TRUE. QCK(ng)%pioVar(idevap)%vd=var_desc(i) QCK(ng)%pioVar(idevap)%dkind=PIO_FOUT QCK(ng)%pioVar(idevap)%gtype=r2dvar ELSE IF (TRIM(var_name(i)).eq.TRIM(Vname(1,idrain))) THEN got_var(idrain)=.TRUE. QCK(ng)%pioVar(idrain)%vd=var_desc(i) QCK(ng)%pioVar(idrain)%dkind=PIO_FOUT QCK(ng)%pioVar(idrain)%gtype=r2dvar # endif # endif ELSE IF (TRIM(var_name(i)).eq.TRIM(Vname(1,idEmPf))) THEN got_var(idEmPf)=.TRUE. QCK(ng)%pioVar(idEmPf)%vd=var_desc(i) QCK(ng)%pioVar(idEmPf)%dkind=PIO_FOUT QCK(ng)%pioVar(idEmPf)%gtype=r2dvar # ifdef SHORTWAVE ELSE IF (TRIM(var_name(i)).eq.TRIM(Vname(1,idSrad))) THEN got_var(idSrad)=.TRUE. QCK(ng)%pioVar(idSrad)%vd=var_desc(i) QCK(ng)%pioVar(idSrad)%dkind=PIO_FOUT QCK(ng)%pioVar(idSrad)%gtype=r2dvar # endif # endif ELSE IF (TRIM(var_name(i)).eq.TRIM(Vname(1,idUsms))) THEN got_var(idUsms)=.TRUE. QCK(ng)%pioVar(idUsms)%vd=var_desc(i) QCK(ng)%pioVar(idUsms)%dkind=PIO_FOUT QCK(ng)%pioVar(idUsms)%gtype=u2dvar ELSE IF (TRIM(var_name(i)).eq.TRIM(Vname(1,idVsms))) THEN got_var(idVsms)=.TRUE. QCK(ng)%pioVar(idVsms)%vd=var_desc(i) QCK(ng)%pioVar(idVsms)%dkind=PIO_FOUT QCK(ng)%pioVar(idVsms)%gtype=v2dvar ELSE IF (TRIM(var_name(i)).eq.TRIM(Vname(1,idUbms))) THEN got_var(idUbms)=.TRUE. QCK(ng)%pioVar(idUbms)%vd=var_desc(i) QCK(ng)%pioVar(idUbms)%dkind=PIO_FOUT QCK(ng)%pioVar(idUbms)%gtype=u2dvar ELSE IF (TRIM(var_name(i)).eq.TRIM(Vname(1,idVbms))) THEN got_var(idVbms)=.TRUE. QCK(ng)%pioVar(idVbms)%vd=var_desc(i) QCK(ng)%pioVar(idVbms)%dkind=PIO_FOUT QCK(ng)%pioVar(idVbms)%gtype=v2dvar END IF # ifdef SOLVE3D DO itrc=1,NT(ng) IF (TRIM(var_name(i)).eq.TRIM(Vname(1,idTvar(itrc)))) THEN got_var(idTvar(itrc))=.TRUE. QCK(ng)%pioTrc(itrc)%vd=var_desc(i) QCK(ng)%pioTrc(itrc)%dkind=PIO_FOUT QCK(ng)%pioTrc(itrc)%gtype=r3dvar ELSE IF (TRIM(var_name(i)).eq. & & TRIM(Vname(1,idsurT(itrc)))) THEN got_var(idsurT(itrc))=.TRUE. QCK(ng)%pioVar(idsurT(itrc))%vd=var_desc(i) QCK(ng)%pioVar(idsurT(itrc))%dkind=PIO_FOUT QCK(ng)%pioVar(idsurT(itrc))%gtype=r2dvar END IF END DO DO itrc=1,NAT IF (TRIM(var_name(i)).eq.TRIM(Vname(1,idTsur(itrc)))) THEN got_var(idTsur(itrc))=.TRUE. QCK(ng)%pioVar(idTsur(itrc))%vd=var_desc(i) QCK(ng)%pioVar(idTsur(itrc))%dkind=PIO_FOUT QCK(ng)%pioVar(idTsur(itrc))%gtype=r2dvar END IF END DO # endif END DO ! ! Check if quicksave variables are available in input NetCDF ! file. ! IF (.not.got_var(idtime)) THEN IF (Master) WRITE (stdout,70) TRIM(Vname(1,idtime)), & & TRIM(ncname) exit_flag=3 RETURN END IF # if defined WET_DRY IF (.not.got_var(idPwet)) THEN IF (Master) WRITE (stdout,70) TRIM(Vname(1,idPwet)), & & TRIM(ncname) exit_flag=3 RETURN END IF IF (.not.got_var(idRwet)) THEN IF (Master) WRITE (stdout,70) TRIM(Vname(1,idRwet)), & & TRIM(ncname) exit_flag=3 RETURN END IF IF (.not.got_var(idUwet)) THEN IF (Master) WRITE (stdout,70) TRIM(Vname(1,idUwet)), & & TRIM(ncname) exit_flag=3 RETURN END IF IF (.not.got_var(idVwet)) THEN IF (Master) WRITE (stdout,70) TRIM(Vname(1,idVwet)), & & TRIM(ncname) exit_flag=3 RETURN END IF # endif # ifdef SOLVE3D IF (.not.got_var(idpthR).and.Qout(idpthR,ng)) THEN IF (Master) WRITE (stdout,70) TRIM(Vname(1,idpthR)), & & TRIM(ncname) exit_flag=3 RETURN END IF IF (.not.got_var(idpthU).and.Qout(idpthU,ng)) THEN IF (Master) WRITE (stdout,70) TRIM(Vname(1,idpthU)), & & TRIM(ncname) exit_flag=3 RETURN END IF IF (.not.got_var(idpthV).and.Qout(idpthV,ng)) THEN IF (Master) WRITE (stdout,70) TRIM(Vname(1,idpthV)), & & TRIM(ncname) exit_flag=3 RETURN END IF IF (.not.got_var(idpthW).and.Qout(idpthW,ng)) THEN IF (Master) WRITE (stdout,70) TRIM(Vname(1,idpthW)), & & TRIM(ncname) exit_flag=3 RETURN END IF # endif IF (.not.got_var(idFsur).and.Qout(idFsur,ng)) THEN IF (Master) WRITE (stdout,70) TRIM(Vname(1,idFsur)), & & TRIM(ncname) exit_flag=3 RETURN END IF IF (.not.got_var(idUbar).and.Qout(idUbar,ng)) THEN IF (Master) WRITE (stdout,70) TRIM(Vname(1,idUbar)), & & TRIM(ncname) exit_flag=3 RETURN END IF IF (.not.got_var(idVbar).and.Qout(idVbar,ng)) THEN IF (Master) WRITE (stdout,70) TRIM(Vname(1,idVbar)), & & TRIM(ncname) exit_flag=3 RETURN END IF IF (.not.got_var(idu2dE).and.Qout(idu2dE,ng)) THEN IF (Master) WRITE (stdout,70) TRIM(Vname(1,idu2dE)), & & TRIM(ncname) exit_flag=3 RETURN END IF IF (.not.got_var(idv2dN).and.Qout(idv2dN,ng)) THEN IF (Master) WRITE (stdout,70) TRIM(Vname(1,idv2dN)), & & TRIM(ncname) exit_flag=3 RETURN END IF # ifdef SOLVE3D IF (.not.got_var(idUvel).and.Qout(idUvel,ng)) THEN IF (Master) WRITE (stdout,70) TRIM(Vname(1,idUvel)), & & TRIM(ncname) exit_flag=3 RETURN END IF IF (.not.got_var(idVvel).and.Qout(idVvel,ng)) THEN IF (Master) WRITE (stdout,70) TRIM(Vname(1,idVvel)), & & TRIM(ncname) exit_flag=3 RETURN END IF IF (.not.got_var(idUsur).and.Qout(idUsur,ng)) THEN IF (Master) WRITE (stdout,70) TRIM(Vname(1,idUsur)), & & TRIM(ncname) exit_flag=3 RETURN END IF IF (.not.got_var(idVsur).and.Qout(idVsur,ng)) THEN IF (Master) WRITE (stdout,70) TRIM(Vname(1,idVsur)), & & TRIM(ncname) exit_flag=3 RETURN END IF IF (.not.got_var(idu3dE).and.Qout(idu3dE,ng)) THEN IF (Master) WRITE (stdout,70) TRIM(Vname(1,idu3dE)), & & TRIM(ncname) exit_flag=3 RETURN END IF IF (.not.got_var(idv3dN).and.Qout(idv3dN,ng)) THEN IF (Master) WRITE (stdout,70) TRIM(Vname(1,idv3dN)), & & TRIM(ncname) exit_flag=3 RETURN END IF IF (.not.got_var(idUsuE).and.Qout(idUsuE,ng)) THEN IF (Master) WRITE (stdout,70) TRIM(Vname(1,idUsuE)), & & TRIM(ncname) exit_flag=3 RETURN END IF IF (.not.got_var(idVsuN).and.Qout(idVsuN,ng)) THEN IF (Master) WRITE (stdout,70) TRIM(Vname(1,idVsuN)), & & TRIM(ncname) exit_flag=3 RETURN END IF IF (.not.got_var(idWvel).and.Qout(idWvel,ng)) THEN IF (Master) WRITE (stdout,70) TRIM(Vname(1,idWvel)), & & TRIM(ncname) exit_flag=3 RETURN END IF IF (.not.got_var(idOvel).and.Qout(idOvel,ng)) THEN IF (Master) WRITE (stdout,70) TRIM(Vname(1,idOvel)), & & TRIM(ncname) exit_flag=3 RETURN END IF IF (.not.got_var(idDano).and.Qout(idDano,ng)) THEN IF (Master) WRITE (stdout,70) TRIM(Vname(1,idDano)), & & TRIM(ncname) exit_flag=3 RETURN END IF # ifdef LMD_SKPP IF (.not.got_var(idHsbl).and.Qout(idHsbl,ng)) THEN IF (Master) WRITE (stdout,70) TRIM(Vname(1,idHsbl)), & & TRIM(ncname) exit_flag=3 RETURN END IF # endif # ifdef LMD_BKPP IF (.not.got_var(idHbbl).and.Qout(idHbbl,ng)) THEN IF (Master) WRITE (stdout,70) TRIM(Vname(1,idHbbl)), & & TRIM(ncname) exit_flag=3 RETURN END IF # endif IF (.not.got_var(idVvis).and.Qout(idVvis,ng)) THEN IF (Master) WRITE (stdout,70) TRIM(Vname(1,idVvis)), & & TRIM(ncname) exit_flag=3 RETURN END IF IF (.not.got_var(idTdif).and.Qout(idTdif,ng)) THEN IF (Master) WRITE (stdout,70) TRIM(Vname(1,idTdif)), & & TRIM(ncname) exit_flag=3 RETURN END IF # ifdef SALINITY IF (.not.got_var(idSdif).and.Qout(idSdif,ng)) THEN IF (Master) WRITE (stdout,70) TRIM(Vname(1,idSdif)), & & TRIM(ncname) exit_flag=3 RETURN END IF # endif # if defined GLS_MIXING || defined MY25_MIXING IF (.not.got_var(idMtke).and.Qout(idMtke,ng)) THEN IF (Master) WRITE (stdout,70) TRIM(Vname(1,idMtke)), & & TRIM(ncname) exit_flag=3 RETURN END IF IF (.not.got_var(idMtls).and.Qout(idMtls,ng)) THEN IF (Master) WRITE (stdout,70) TRIM(Vname(1,idMtls)), & & TRIM(ncname) exit_flag=3 RETURN END IF # endif # if defined BULK_FLUXES || defined ECOSIM || defined ATM_PRESS IF (.not.got_var(idPair).and.Qout(idPair,ng)) THEN IF (Master) WRITE (stdout,70) TRIM(Vname(1,idPair)), & & TRIM(ncname) exit_flag=3 RETURN END IF # endif # if defined BULK_FLUXES || defined ECOSIM IF (.not.got_var(idUair).and.Qout(idUair,ng)) THEN IF (Master) WRITE (stdout,70) TRIM(Vname(1,idUair)), & & TRIM(ncname) exit_flag=3 RETURN END IF IF (.not.got_var(idVair).and.Qout(idVair,ng)) THEN IF (Master) WRITE (stdout,70) TRIM(Vname(1,idVair)), & & TRIM(ncname) exit_flag=3 RETURN END IF IF (.not.got_var(idUaiE).and.Qout(idUaiE,ng)) THEN IF (Master) WRITE (stdout,70) TRIM(Vname(1,idUaiE)), & & TRIM(ncname) exit_flag=3 RETURN END IF IF (.not.got_var(idVaiN).and.Qout(idVaiN,ng)) THEN IF (Master) WRITE (stdout,70) TRIM(Vname(1,idVaiN)), & & TRIM(ncname) exit_flag=3 RETURN END IF # endif # if defined BULK_FLUXES || defined FRC_COUPLING IF (.not.got_var(idLhea).and.Qout(idLhea,ng)) THEN IF (Master) WRITE (stdout,70) TRIM(Vname(1,idLhea)), & & TRIM(ncname) exit_flag=3 RETURN END IF IF (.not.got_var(idShea).and.Qout(idShea,ng)) THEN IF (Master) WRITE (stdout,70) TRIM(Vname(1,idShea)), & & TRIM(ncname) exit_flag=3 RETURN END IF IF (.not.got_var(idLrad).and.Qout(idLrad,ng)) THEN IF (Master) WRITE (stdout,70) TRIM(Vname(1,idLrad)), & & TRIM(ncname) exit_flag=3 RETURN END IF # endif # ifdef BULK_FLUXES IF (.not.got_var(idTair).and.Qout(idTair,ng)) THEN IF (Master) WRITE (stdout,70) TRIM(Vname(1,idTair)), & & TRIM(ncname) exit_flag=3 RETURN END IF # ifdef EMINUSP IF (.not.got_var(idevap).and.Qout(idevap,ng)) THEN IF (Master) WRITE (stdout,70) TRIM(Vname(1,idevap)), & & TRIM(ncname) exit_flag=3 RETURN END IF IF (.not.got_var(idrain).and.Qout(idrain,ng)) THEN IF (Master) WRITE (stdout,70) TRIM(Vname(1,idrain)), & & TRIM(ncname) exit_flag=3 RETURN END IF # endif # endif IF (.not.got_var(idEmPf).and.Qout(idEmPf,ng)) THEN IF (Master) WRITE (stdout,70) TRIM(Vname(1,idEmPf)), & & TRIM(ncname) exit_flag=3 RETURN END IF # ifdef SHORTWAVE IF (.not.got_var(idSrad).and.Qout(idSrad,ng)) THEN IF (Master) WRITE (stdout,70) TRIM(Vname(1,idSrad)), & & TRIM(ncname) exit_flag=3 RETURN END IF # endif # endif IF (.not.got_var(idUsms).and.Qout(idUsms,ng)) THEN IF (Master) WRITE (stdout,70) TRIM(Vname(1,idUsms)), & & TRIM(ncname) exit_flag=3 RETURN END IF IF (.not.got_var(idVsms).and.Qout(idVsms,ng)) THEN IF (Master) WRITE (stdout,70) TRIM(Vname(1,idVsms)), & & TRIM(ncname) exit_flag=3 RETURN END IF IF (.not.got_var(idUbms).and.Qout(idUbms,ng)) THEN IF (Master) WRITE (stdout,70) TRIM(Vname(1,idUbms)), & & TRIM(ncname) exit_flag=3 RETURN END IF IF (.not.got_var(idVbms).and.Qout(idVbms,ng)) THEN IF (Master) WRITE (stdout,70) TRIM(Vname(1,idVbms)), & & TRIM(ncname) exit_flag=3 RETURN END IF # ifdef SOLVE3D DO itrc=1,NT(ng) IF (.not.got_var(idTvar(itrc)).and.Qout(idTvar(itrc),ng)) THEN IF (Master) WRITE (stdout,70) TRIM(Vname(1,idTvar(itrc))), & & TRIM(ncname) exit_flag=3 RETURN END IF IF (.not.got_var(idsurT(itrc)).and.Qout(idsurT(itrc),ng)) THEN IF (Master) WRITE (stdout,70) TRIM(Vname(1,idsurT(itrc))), & & TRIM(ncname) exit_flag=3 RETURN END IF END DO DO itrc=1,NAT IF (.not.got_var(idTsur(itrc)).and.Qout(idTsur(itrc),ng)) THEN IF (Master) WRITE (stdout,70) TRIM(Vname(1,idTsur(itrc))), & & TRIM(ncname) exit_flag=3 RETURN END IF END DO # endif # if (defined BBL_MODEL || defined WAVES_OUTPUT) && defined SOLVE3D ! ! Scan bottom boundary layer model and waves variables from input ! NetCDF and activate switches for quicksave variables. Get variable ! IDs. ! CALL bbl_def_pio (ng, model, ldef, Qout, QCK) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN # endif # if defined ICE_MODEL && defined SOLVE3D ! ! Scan sea-ice variables from input NetCDF and activate switches for ! quicksave variables. Get variable IDs. ! CALL ice_def_pio (ng, model, ldef, Qout, QCK) # endif # if defined SEDIMENT && defined SOLVE3D ! ! Scan sediment model variables from input NetCDF and activate ! switches for quicksave variables. Get variable IDs. ! CALL sediment_def_pio (ng, model, ldef, Qout, QCK) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN # endif # if defined WEC_VF && defined SOLVE3D ! ! Scan Waves Effect on Currents variables from input NetCDF and ! activate switches for quicksave variables. Get variable IDs. ! CALL wec_def_pio (ng, model, ldef, Qout, QCK) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN # endif ! ! Set unlimited time record dimension to the appropriate value. ! IF (ndefQCK(ng).gt.0) THEN QCK(ng)%Rindex=((ntstart(ng)-1)- & & ndefQCK(ng)*((ntstart(ng)-1)/ndefQCK(ng)))/ & & nQCK(ng) ELSE QCK(ng)%Rindex=(ntstart(ng)-1)/nQCK(ng) END IF QCK(ng)%Rindex=MIN(QCK(ng)%Rindex,rec_size) END IF QUERY ! 10 FORMAT (2x,'DEF_QUICK_PIO - creating quicksave file,',t56, & & 'Grid ',i2.2,': ',a) 20 FORMAT (2x,'DEF_QUICK_PIO - inquiring quicksave file,',t56, & & 'Grid ',i2.2,': ',a) 30 FORMAT (/,' DEF_QUICK_PIO - unable to create quicksave NetCDF', & & ' file:', 1x,a) 40 FORMAT ('time dependent',1x,a) 50 FORMAT (1pe11.4,1x,'millimeter') 60 FORMAT (/,' DEF_QUICK_PIO - unable to open quicksave NetCDF', & & ' file: ',a) 70 FORMAT (/,' DEF_QUICK_PIO - unable to find variable: ',a,2x, & & ' in quicksave NetCDF file: ',a) ! RETURN END SUBROUTINE def_quick_pio #endif END MODULE def_quick_mod