#include "cppdefs.h" #if defined FOUR_DVAR || defined ENKF_RESTART SUBROUTINE def_dai (ng) ! !svn $Id: def_dai.F 927 2018-10-16 03:51:56Z arango $ !================================================== Hernan G. Arango === ! Copyright (c) 2002-2019 The ROMS/TOMS Group ! ! Licensed under a MIT/X style license ! ! See License_ROMS.txt ! !======================================================================= ! ! ! This routine creates Data Assimilation initial conditions (4D-Var ! ! analysis) or Ensemble Kalman Filter (EnKF) restart file. 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_netcdf USE mod_scalars # ifdef SEDIMENT USE mod_sediment # endif ! USE def_var_mod, ONLY : def_var USE strings_mod, ONLY : FoundError ! implicit none ! ! Imported variable declarations. ! integer, intent(in) :: ng ! ! Local variable declarations. ! logical :: got_var(NV) integer, parameter :: Natt = 25 integer :: i, j, itrc, nvd3, nvd4 integer :: recdim, status, varid integer :: DimIDs(32) integer :: t2dgrd(3), u2dgrd(3), v2dgrd(3) # ifdef SOLVE3D integer :: t3dgrd(4), u3dgrd(4), v3dgrd(4), w3dgrd(4) # endif integer :: Vsize(4) integer :: def_dim real(r8) :: Aval(6) character (len=120) :: Vinfo(Natt) character (len=256) :: ncname ! SourceFile=__FILE__ ! !----------------------------------------------------------------------- ! Set and report file name. !----------------------------------------------------------------------- ! IF (FoundError(exit_flag, NoError, __LINE__, & & __FILE__)) RETURN ncname=DAI(ng)%name ! IF (Master) THEN IF (LdefDAI(ng)) THEN WRITE (stdout,10) ng, TRIM(ncname) ELSE WRITE (stdout,20) ng, TRIM(ncname) END IF END IF ! !======================================================================= ! Create a new Data Assimilation initial/restart NetCDF file. !======================================================================= ! DEFINE : IF (LdefDAI(ng)) THEN CALL netcdf_create (ng, iNLM, TRIM(ncname), DAI(ng)%ncid) IF (FoundError(exit_flag, NoError, __LINE__, & & __FILE__)) THEN IF (Master) WRITE (stdout,30) TRIM(ncname) RETURN END IF ! !----------------------------------------------------------------------- ! Define file dimensions. !----------------------------------------------------------------------- ! DimIDs=0 ! status=def_dim(ng, iNLM, DAI(ng)%ncid, ncname, 'xi_rho', & & IOBOUNDS(ng)%xi_rho, DimIDs( 1)) IF (FoundError(exit_flag, NoError, __LINE__, & & __FILE__)) RETURN status=def_dim(ng, iNLM, DAI(ng)%ncid, ncname, 'xi_u', & & IOBOUNDS(ng)%xi_u, DimIDs( 2)) IF (FoundError(exit_flag, NoError, __LINE__, & & __FILE__)) RETURN status=def_dim(ng, iNLM, DAI(ng)%ncid, ncname, 'xi_v', & & IOBOUNDS(ng)%xi_v, DimIDs( 3)) IF (FoundError(exit_flag, NoError, __LINE__, & & __FILE__)) RETURN status=def_dim(ng, iNLM, DAI(ng)%ncid, ncname, 'xi_psi', & & IOBOUNDS(ng)%xi_psi, DimIDs( 4)) IF (FoundError(exit_flag, NoError, __LINE__, & & __FILE__)) RETURN status=def_dim(ng, iNLM, DAI(ng)%ncid, ncname, 'eta_rho', & & IOBOUNDS(ng)%eta_rho, DimIDs( 5)) IF (FoundError(exit_flag, NoError, __LINE__, & & __FILE__)) RETURN status=def_dim(ng, iNLM, DAI(ng)%ncid, ncname, 'eta_u', & & IOBOUNDS(ng)%eta_u, DimIDs( 6)) IF (FoundError(exit_flag, NoError, __LINE__, & & __FILE__)) RETURN status=def_dim(ng, iNLM, DAI(ng)%ncid, ncname, 'eta_v', & & IOBOUNDS(ng)%eta_v, DimIDs( 7)) IF (FoundError(exit_flag, NoError, __LINE__, & & __FILE__)) RETURN status=def_dim(ng, iNLM, DAI(ng)%ncid, ncname, 'eta_psi', & & IOBOUNDS(ng)%eta_psi, DimIDs( 8)) IF (FoundError(exit_flag, NoError, __LINE__, & & __FILE__)) RETURN # ifdef SOLVE3D status=def_dim(ng, iNLM, DAI(ng)%ncid, ncname, 'N', & & N(ng), DimIDs( 9)) IF (FoundError(exit_flag, NoError, __LINE__, & & __FILE__)) RETURN status=def_dim(ng, iNLM, DAI(ng)%ncid, ncname, 's_rho', & & N(ng), DimIDs( 9)) IF (FoundError(exit_flag, NoError, __LINE__, & & __FILE__)) RETURN status=def_dim(ng, iNLM, DAI(ng)%ncid, ncname, 's_w', & & N(ng)+1, DimIDs(10)) IF (FoundError(exit_flag, NoError, __LINE__, & & __FILE__)) RETURN status=def_dim(ng, iNLM, DAI(ng)%ncid, ncname, 'tracer', & & NT(ng), DimIDs(11)) IF (FoundError(exit_flag, NoError, __LINE__, & & __FILE__)) RETURN # ifdef SEDIMENT status=def_dim(ng, iNLM, DAI(ng)%ncid, ncname, 'NST', & & NST, DimIDs(32)) IF (FoundError(exit_flag, NoError, __LINE__, & & __FILE__)) RETURN status=def_dim(ng, iNLM, DAI(ng)%ncid, ncname, 'Nbed', & & Nbed, DimIDs(16)) IF (FoundError(exit_flag, NoError, __LINE__, & & __FILE__)) RETURN # endif # ifdef ECOSIM status=def_dim(ng, iNLM, DAI(ng)%ncid, ncname, 'Nphy', & & Nphy, DimIDs(25)) IF (FoundError(exit_flag, NoError, __LINE__, & & __FILE__)) RETURN status=def_dim(ng, iNLM, DAI(ng)%ncid, ncname, 'Nbac', & & Nbac, DimIDs(26)) IF (FoundError(exit_flag, NoError, __LINE__, & & __FILE__)) RETURN status=def_dim(ng, iNLM, DAI(ng)%ncid, ncname, 'Ndom', & & Ndom, DimIDs(27)) IF (FoundError(exit_flag, NoError, __LINE__, & & __FILE__)) RETURN status=def_dim(ng, iNLM, DAI(ng)%ncid, ncname, 'Nfec', & & Nfec, DimIDs(28)) IF (FoundError(exit_flag, NoError, __LINE__, & & __FILE__)) RETURN # endif # endif status=def_dim(ng, iNLM, DAI(ng)%ncid, ncname, 'boundary', & & 4, DimIDs(14)) IF (FoundError(exit_flag, NoError, __LINE__, & & __FILE__)) RETURN #ifdef FOUR_DVAR status=def_dim(ng, iNLM, DAI(ng)%ncid, ncname, 'Nstate', & & NstateVar(ng), DimIDs(29)) IF (FoundError(exit_flag, NoError, __LINE__, & & __FILE__)) RETURN #endif status=def_dim(ng, iNLM, DAI(ng)%ncid, ncname, & & TRIM(ADJUSTL(Vname(5,idtime))), & & nf90_unlimited, DimIDs(12)) IF (FoundError(exit_flag, NoError, __LINE__, & & __FILE__)) RETURN recdim=DimIDs(12) ! ! Set number of dimensions for output variables. ! nvd3=3 nvd4=4 ! ! Define dimension vectors for staggered tracer type variables. ! 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 ! ! Define dimension vectors for staggered u-momentum type variables. ! 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 ! ! Define dimension vectors for staggered v-momentum type variables. ! 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 # ifdef SOLVE3D ! ! Define dimension vector for staggered w-momentum type variables. ! w3dgrd(1)=DimIDs( 1) w3dgrd(2)=DimIDs( 5) w3dgrd(3)=DimIDs(10) w3dgrd(4)=DimIDs(12) # endif ! ! Initialize unlimited time record dimension. ! DAI(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, iNLM, DAI(ng)%ncid, ncname, DimIDs) IF (FoundError(exit_flag, NoError, __LINE__, & & __FILE__)) RETURN ! ! Define time independent (unperturb) depths of RHO-points. ! Vinfo( 1)=Vname(1,idpthR) WRITE (Vinfo( 2),40) Vname(2,idpthR) Vinfo( 3)=Vname(3,idpthR) Vinfo(11)='downwards' Vinfo(22)='coordinates' Aval(5)=REAL(Iinfo(1,idpthR,ng),r8) status=def_var(ng, iNLM, DAI(ng)%ncid, DAI(ng)%Vid(idpthR), & & NF_FRST, nvd3, t3dgrd, Aval, Vinfo, ncname, & & SetFillVal = .FALSE.) IF (FoundError(exit_flag, NoError, __LINE__, & & __FILE__)) RETURN ! ! Define time independent (unperturb) depths of U-points. ! Vinfo( 1)=Vname(1,idpthU) WRITE (Vinfo( 2),40) Vname(2,idpthU) Vinfo( 3)=Vname(3,idpthU) Vinfo(11)='downwards' Vinfo(22)='coordinates' Aval(5)=REAL(Iinfo(1,idpthU,ng),r8) status=def_var(ng, iNLM, DAI(ng)%ncid, DAI(ng)%Vid(idpthU), & & NF_FRST, nvd3, u3dgrd, Aval, Vinfo, ncname, & & SetFillVal = .FALSE.) IF (FoundError(exit_flag, NoError, __LINE__, & & __FILE__)) RETURN ! ! Define time independent (unperturb) depths of V-points. ! Vinfo( 1)=Vname(1,idpthV) WRITE (Vinfo( 2),40) Vname(2,idpthV) Vinfo( 3)=Vname(3,idpthV) Vinfo(11)='downwards' Vinfo(22)='coordinates' Aval(5)=REAL(Iinfo(1,idpthV,ng),r8) status=def_var(ng, iNLM, DAI(ng)%ncid, DAI(ng)%Vid(idpthV), & & NF_FRST, nvd3, v3dgrd, Aval, Vinfo, ncname, & & SetFillVal = .FALSE.) IF (FoundError(exit_flag, NoError, __LINE__, & & __FILE__)) RETURN ! ! Define time independent (unperturb) depths of W-points. ! Vinfo( 1)=Vname(1,idpthW) WRITE (Vinfo( 2),40) Vname(2,idpthW) Vinfo( 3)=Vname(3,idpthW) Vinfo(11)='downwards' Vinfo(22)='coordinates' Aval(5)=REAL(Iinfo(1,idpthW,ng),r8) status=def_var(ng, iNLM, DAI(ng)%ncid, DAI(ng)%Vid(idpthW), & & NF_FRST, nvd3, w3dgrd, Aval, Vinfo, ncname, & & SetFillVal = .FALSE.) IF (FoundError(exit_flag, NoError, __LINE__, & & __FILE__)) 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) status=def_var(ng, iNLM, DAI(ng)%ncid, DAI(ng)%Vid(idtime), & & NF_TOUT, 1, (/recdim/), Aval, Vinfo, ncname, & & SetParAccess = .TRUE.) IF (FoundError(exit_flag, NoError, __LINE__, & & __FILE__)) RETURN ! ! Define free-surface. ! 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) Vinfo(22)='coordinates' Aval(5)=REAL(Iinfo(1,idFsur,ng),r8) status=def_var(ng, iNLM, DAI(ng)%ncid, DAI(ng)%Vid(idFsur), & # ifdef WET_DRY & NF_FRST, nvd3, t2dgrd, Aval, Vinfo, ncname, & & SetFillVal = .FALSE.) # else & NF_FRST, nvd3, t2dgrd, Aval, Vinfo, ncname) # endif IF (FoundError(exit_flag, NoError, __LINE__, & & __FILE__)) RETURN ! ! Define 2D momentum in the XI-direction. ! 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) Vinfo(22)='coordinates' Aval(5)=REAL(Iinfo(1,idUbar,ng),r8) status=def_var(ng, iNLM, DAI(ng)%ncid, DAI(ng)%Vid(idUbar), & & NF_FRST, nvd3, u2dgrd, Aval, Vinfo, ncname) IF (FoundError(exit_flag, NoError, __LINE__, & & __FILE__)) RETURN ! ! Define 2D momentum in the ETA-direction. ! 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) Vinfo(22)='coordinates' Aval(5)=REAL(Iinfo(1,idVbar,ng),r8) status=def_var(ng, iNLM, DAI(ng)%ncid, DAI(ng)%Vid(idVbar), & & NF_FRST, nvd3, v2dgrd, Aval, Vinfo, ncname) IF (FoundError(exit_flag, NoError, __LINE__, & & __FILE__)) RETURN # ifdef SOLVE3D ! ! Define 3D momentum component in the XI-direction. ! 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) Vinfo(22)='coordinates' Aval(5)=REAL(Iinfo(1,idUvel,ng),r8) status=def_var(ng, iNLM, DAI(ng)%ncid, DAI(ng)%Vid(idUvel), & & NF_FRST, nvd4, u3dgrd, Aval, Vinfo, ncname) IF (FoundError(exit_flag, NoError, __LINE__, & & __FILE__)) RETURN ! ! Define 3D momentum component in the ETA-direction. ! 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) Vinfo(22)='coordinates' Aval(5)=REAL(Iinfo(1,idVvel,ng),r8) status=def_var(ng, iNLM, DAI(ng)%ncid, DAI(ng)%Vid(idVvel), & & NF_FRST, nvd4, v3dgrd, Aval, Vinfo, ncname) IF (FoundError(exit_flag, NoError, __LINE__, & & __FILE__)) RETURN ! ! Define tracer type variables. ! DO itrc=1,NT(ng) 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 Vinfo(22)='coordinates' Aval(5)=REAL(r3dvar,r8) status=def_var(ng, iNLM, DAI(ng)%ncid, DAI(ng)%Tid(itrc), & & NF_FRST, nvd4, t3dgrd, Aval, Vinfo, ncname) IF (FoundError(exit_flag, NoError, __LINE__, & & __FILE__)) RETURN END DO ! ! Define vertical viscosity coefficient. ! 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) Vinfo(22)='coordinates' Aval(5)=REAL(Iinfo(1,idVvis,ng),r8) status=def_var(ng, iNLM, DAI(ng)%ncid, DAI(ng)%Vid(idVvis), & & NF_FRST, nvd4, w3dgrd, Aval, Vinfo, ncname, & & SetFillVal = .FALSE.) IF (FoundError(exit_flag, NoError, __LINE__, & & __FILE__)) RETURN ! ! Define vertical diffusion coefficient for potential temperature. ! 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) Vinfo(22)='coordinates' Aval(5)=REAL(Iinfo(1,idTdif,ng),r8) status=def_var(ng, iNLM, DAI(ng)%ncid, DAI(ng)%Vid(idTdif), & & NF_FRST, nvd4, w3dgrd, Aval, Vinfo, ncname, & & SetFillVal = .FALSE.) IF (FoundError(exit_flag, NoError, __LINE__, & & __FILE__)) RETURN # ifdef SALINITY ! ! Define vertical diffusion coefficient for salinity. ! 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) Vinfo(22)='coordinates' Aval(5)=REAL(Iinfo(1,idSdif,ng),r8) status=def_var(ng, iNLM, DAI(ng)%ncid, DAI(ng)%Vid(idSdif), & & NF_FRST, nvd4, w3dgrd, Aval, Vinfo, ncname, & & SetFillVal = .FALSE.) IF (FoundError(exit_flag, NoError, __LINE__, & & __FILE__)) RETURN # endif # endif ! !----------------------------------------------------------------------- ! Leave definition mode. !----------------------------------------------------------------------- ! CALL netcdf_enddef (ng, iNLM, ncname, DAI(ng)%ncid) IF (FoundError(exit_flag, NoError, __LINE__, & & __FILE__)) RETURN ! !----------------------------------------------------------------------- ! Write out time-recordless, information variables. !----------------------------------------------------------------------- ! CALL wrt_info (ng, iNLM, DAI(ng)%ncid, ncname) IF (FoundError(exit_flag, NoError, __LINE__, & & __FILE__)) RETURN END IF DEFINE ! !======================================================================= ! Open an existing Data Assimilation initial/restart file, check its ! contents, and prepare for appending data. !======================================================================= ! QUERY : IF (.not.LdefDAI(ng)) THEN ncname=DAI(ng)%name ! ! Open restart file for read/write. ! CALL netcdf_open (ng, iNLM, ncname, 1, DAI(ng)%ncid) IF (FoundError(exit_flag, NoError, __LINE__, & & __FILE__)) THEN WRITE (stdout,60) TRIM(ncname) RETURN END IF ! ! Inquire about the dimensions and check for consistency. ! CALL netcdf_check_dim (ng, iNLM, ncname, & & ncid = DAI(ng)%ncid) IF (FoundError(exit_flag, NoError, __LINE__, & & __FILE__)) RETURN ! ! Inquire about the variables. ! CALL netcdf_inq_var (ng, iNLM, ncname, & & ncid = DAI(ng)%ncid) IF (FoundError(exit_flag, NoError, __LINE__, & & __FILE__)) RETURN ! ! Initialize logical switches. ! DO i=1,NV got_var(i)=.FALSE. END DO ! ! Scan variable list from input NetCDF and activate switches for ! Data Assimilation initial/restart variables. Get variable IDs. ! DO i=1,n_var IF (TRIM(var_name(i)).eq.TRIM(Vname(1,idtime))) THEN got_var(idtime)=.TRUE. DAI(ng)%Vid(idtime)=var_id(i) ELSE IF (TRIM(var_name(i)).eq.TRIM(Vname(1,idFsur))) THEN got_var(idFsur)=.TRUE. DAI(ng)%Vid(idFsur)=var_id(i) ELSE IF (TRIM(var_name(i)).eq.TRIM(Vname(1,idUbar))) THEN got_var(idUbar)=.TRUE. DAI(ng)%Vid(idUbar)=var_id(i) ELSE IF (TRIM(var_name(i)).eq.TRIM(Vname(1,idVbar))) THEN got_var(idVbar)=.TRUE. DAI(ng)%Vid(idVbar)=var_id(i) # ifdef SOLVE3D ELSE IF (TRIM(var_name(i)).eq.TRIM(Vname(1,idUvel))) THEN got_var(idUvel)=.TRUE. DAI(ng)%Vid(idUvel)=var_id(i) ELSE IF (TRIM(var_name(i)).eq.TRIM(Vname(1,idVvel))) THEN got_var(idVvel)=.TRUE. DAI(ng)%Vid(idVvel)=var_id(i) ELSE IF (TRIM(var_name(i)).eq.TRIM(Vname(1,idVvis))) THEN got_var(idVvis)=.TRUE. DAI(ng)%Vid(idVvis)=var_id(i) ELSE IF (TRIM(var_name(i)).eq.TRIM(Vname(1,idTdif))) THEN got_var(idTdif)=.TRUE. DAI(ng)%Vid(idTdif)=var_id(i) ELSE IF (TRIM(var_name(i)).eq.TRIM(Vname(1,idSdif))) THEN got_var(idSdif)=.TRUE. DAI(ng)%Vid(idSdif)=var_id(i) # endif 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. DAI(ng)%Tid(itrc)=var_id(i) END IF END DO # endif END DO ! ! Check if initialization 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 (.not.got_var(idFsur)) THEN IF (Master) WRITE (stdout,70) TRIM(Vname(1,idFsur)), & & TRIM(ncname) exit_flag=3 RETURN END IF IF (.not.got_var(idUbar)) THEN IF (Master) WRITE (stdout,70) TRIM(Vname(1,idUbar)), & & TRIM(ncname) exit_flag=3 RETURN END IF IF (.not.got_var(idVbar)) THEN IF (Master) WRITE (stdout,70) TRIM(Vname(1,idVbar)), & & TRIM(ncname) exit_flag=3 RETURN END IF # ifdef SOLVE3D IF (.not.got_var(idUvel)) THEN IF (Master) WRITE (stdout,70) TRIM(Vname(1,idUvel)), & & TRIM(ncname) exit_flag=3 RETURN END IF IF (.not.got_var(idVvel)) THEN IF (Master) WRITE (stdout,70) TRIM(Vname(1,idVvel)), & & TRIM(ncname) exit_flag=3 RETURN END IF DO itrc=1,NT(ng) IF (.not.got_var(idTvar(itrc))) THEN IF (Master) WRITE (stdout,70) TRIM(Vname(1,idTvar(itrc))), & & TRIM(ncname) exit_flag=3 RETURN END IF END DO IF (.not.got_var(idVvis)) THEN IF (Master) WRITE (stdout,70) TRIM(Vname(1,idVvis)), & & TRIM(ncname) exit_flag=3 RETURN END IF IF (.not.got_var(idTdif)) 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)) THEN IF (Master) WRITE (stdout,70) TRIM(Vname(1,idSdif)), & & TRIM(ncname) exit_flag=3 RETURN END IF # endif # endif ! ! Set unlimited time record dimension to current value. ! DAI(ng)%Rindex=rec_size END IF QUERY ! 10 FORMAT (/,6x,'DEF_DAI - creating DA INI/RST', t43, & & ' file, Grid ',i2.2,': ', a) 20 FORMAT (/,6x,'DEF_DAI - inquiring DA INI/RST', t43, & & ' file, Grid ',i2.2,': ', a) 30 FORMAT (/,' DEF_DAI - unable to create DA initial/restart', & & ' NetCDF file: ',a) 40 FORMAT ('time independent',1x,a) 50 FORMAT (1pe11.4,1x,'millimeter') 60 FORMAT (/,' DEF_DAI - unable to open DA initial/restart' & & ' NetCDF file: ',a) 70 FORMAT (/,' DEF_DAI - unable to find variable: ',a,2x, & & ' in DA initial/restart NetCDF file: ',a) RETURN END SUBROUTINE def_dai #else SUBROUTINE def_dai RETURN END SUBROUTINE def_dai #endif