#include "cppdefs.h" MODULE def_rst_mod ! !git $Id$ !svn $Id: def_rst.F 1178 2023-07-11 17:50:57Z 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 ouput restart file using either the standard ! ! NetCDF library or the Parallel-IO (PIO) library. It defines its ! ! dimensions, attributes, and variables. ! ! ! #if defined PERFECT_RESTART && defined WRITE_WATER && defined MASKING ! Currently, perfect restart is not compatible with writing ! ! only water points. ! ! ! #endif !======================================================================= ! 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 #if defined SEDIMENT || defined BBL_MODEL USE mod_sediment #endif ! USE def_dim_mod, ONLY : def_dim USE def_info_mod, ONLY : def_info USE def_var_mod, ONLY : def_var #ifdef ICE_MODEL USE ice_output_mod, ONLY : ice_def_nf90 # if defined PIO_LIB && defined DISTRIBUTE USE ice_output_mod, ONLY : ice_def_pio # endif #endif USE strings_mod, ONLY : FoundError USE wrt_info_mod, ONLY : wrt_info ! implicit none ! PUBLIC :: def_rst PRIVATE :: def_rst_nf90 #if defined PIO_LIB && defined DISTRIBUTE PRIVATE :: def_rst_pio #endif ! CONTAINS ! !*********************************************************************** SUBROUTINE def_rst (ng) !*********************************************************************** ! ! Imported variable declarations. ! integer, intent(in) :: ng ! ! Local variable declarations. ! character (len=*), parameter :: MyFile = & & __FILE__ ! !----------------------------------------------------------------------- ! Create a new history file according to IO type. !----------------------------------------------------------------------- ! SELECT CASE (RST(ng)%IOtype) CASE (io_nf90) CALL def_rst_nf90 (ng, iNLM) #if defined PIO_LIB && defined DISTRIBUTE CASE (io_pio) CALL def_rst_pio (ng, iNLM) #endif CASE DEFAULT IF (Master) WRITE (stdout,10) RST(ng)%IOtype exit_flag=3 END SELECT IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN ! 10 FORMAT (' DEF_RST - Illegal output file type, io_type = ',i0, & & /,11x,'Check KeyWord ''OUT_LIB'' in ''roms.in''.') ! RETURN END SUBROUTINE def_rst ! !*********************************************************************** SUBROUTINE def_rst_nf90 (ng, model) !*********************************************************************** ! USE mod_netcdf ! ! Imported variable declarations. ! integer, intent(in) :: ng, model ! ! Local variable declarations. ! logical :: Ldefine, got_var(NV) ! integer, parameter :: Natt = 25 integer :: i, j, nvd3, nvd4, nvd5 integer :: recdim, status, varid integer :: DimIDs(nDimID) integer :: r2dgrd(4), ru2dgrd(4), rv2dgrd(4) integer :: sp2dgrd(3), sr2dgrd(3), su2dgrd(3), sv2dgrd(3) integer :: sr3dgrd(4), su3dgrd(4), sv3dgrd(4) integer :: t2dgrd(4), u2dgrd(4), v2dgrd(4) #ifdef SOLVE3D integer :: itrc integer :: k3dgrd(5), t3dgrd(5) integer :: r3dgrd(4), ru3dgrd(5), rv3dgrd(5) integer :: u3dgrd(5), v3dgrd(5), w3dgrd(4) #endif ! real(r8) :: Aval(6) ! character (len=256) :: ncname character (len=MaxLen) :: Vinfo(Natt) character (len=*), parameter :: MyFile = & & __FILE__//", def_rst_nf90" ! SourceFile=MyFile ! !----------------------------------------------------------------------- ! Set and report file name. !----------------------------------------------------------------------- ! ! Activate creation of restart NetCDF file. If a restart run, the ! restart filename "RST(ng)%name" is different than the initial ! filename "INI(ng)%name". ! IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN ncname=RST(ng)%name Ldefine=.FALSE. IF (((nrrec(ng).eq.0).and.(iic(ng).eq.ntstart(ng))).or. & & ((nrrec(ng).ne.0).and. & & (TRIM(ncname).ne.TRIM(INI(ng)%name)))) THEN Ldefine=.TRUE. END IF ! IF (Master) THEN IF (Ldefine) THEN WRITE (stdout,10) ng, TRIM(ncname) ELSE WRITE (stdout,20) ng, TRIM(ncname) END IF END IF ! !======================================================================= ! Create a new restart NetCDF file. !======================================================================= ! DEFINE : IF (Ldefine) THEN CALL netcdf_create (ng, model, TRIM(ncname), RST(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, RST(ng)%ncid, ncname, 'xi_rho', & & IOBOUNDS(ng)%xi_rho, DimIDs( 1)) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN status=def_dim(ng, model, RST(ng)%ncid, ncname, 'xi_u', & & IOBOUNDS(ng)%xi_u, DimIDs( 2)) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN status=def_dim(ng, model, RST(ng)%ncid, ncname, 'xi_v', & & IOBOUNDS(ng)%xi_v, DimIDs( 3)) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN status=def_dim(ng, model, RST(ng)%ncid, ncname, 'xi_psi', & & IOBOUNDS(ng)%xi_psi, DimIDs( 4)) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN status=def_dim(ng, model, RST(ng)%ncid, ncname, 'eta_rho', & & IOBOUNDS(ng)%eta_rho, DimIDs( 5)) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN status=def_dim(ng, model, RST(ng)%ncid, ncname, 'eta_u', & & IOBOUNDS(ng)%eta_u, DimIDs( 6)) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN status=def_dim(ng, model, RST(ng)%ncid, ncname, 'eta_v', & & IOBOUNDS(ng)%eta_v, DimIDs( 7)) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN status=def_dim(ng, model, RST(ng)%ncid, ncname, 'eta_psi', & & IOBOUNDS(ng)%eta_psi, DimIDs( 8)) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN #if !defined PERFECT_RESTART && \ (defined WRITE_WATER && defined MASKING) status=def_dim(ng, model, RST(ng)%ncid, ncname, 'xy_rho', & & IOBOUNDS(ng)%xy_rho, DimIDs(17)) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN status=def_dim(ng, model, RST(ng)%ncid, ncname, 'xy_u', & & IOBOUNDS(ng)%xy_u, DimIDs(18)) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN status=def_dim(ng, model, RST(ng)%ncid, ncname, 'xy_v', & & IOBOUNDS(ng)%xy_v, DimIDs(19)) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN #endif #ifdef SOLVE3D # if !defined PERFECT_RESTART && \ (defined WRITE_WATER && defined MASKING) status=def_dim(ng, model, RST(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, RST(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, RST(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, RST(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, RST(ng)%ncid, ncname, 'N', & & N(ng), DimIDs( 9)) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN status=def_dim(ng, model, RST(ng)%ncid, ncname, 's_rho', & & N(ng), DimIDs( 9)) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN status=def_dim(ng, model, RST(ng)%ncid, ncname, 's_w', & & N(ng)+1, DimIDs(10)) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN status=def_dim(ng, model, RST(ng)%ncid, ncname, 'tracer', & & NT(ng), DimIDs(11)) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN # ifdef SEDIMENT status=def_dim(ng, model, RST(ng)%ncid, ncname, 'NST', & & NST, DimIDs(32)) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN status=def_dim(ng, model, RST(ng)%ncid, ncname, 'Nbed', & & Nbed, DimIDs(16)) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN # if !defined PERFECT_RESTART && \ (defined WRITE_WATER && defined MASKING) status=def_dim(ng, model, RST(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, RST(ng)%ncid, ncname, 'Nbands', & & NBands, DimIDs(33)) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN status=def_dim(ng, model, RST(ng)%ncid, ncname, 'Nphy', & & Nphy, DimIDs(25)) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN status=def_dim(ng, model, RST(ng)%ncid, ncname, 'Nbac', & & Nbac, DimIDs(26)) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN status=def_dim(ng, model, RST(ng)%ncid, ncname, 'Ndom', & & Ndom, DimIDs(27)) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN status=def_dim(ng, model, RST(ng)%ncid, ncname, 'Nfec', & & Nfec, DimIDs(28)) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN # endif #endif status=def_dim(ng, model, RST(ng)%ncid, ncname, 'boundary', & & 4, DimIDs(14)) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN #ifdef FOUR_DVAR status=def_dim(ng, model, RST(ng)%ncid, ncname, 'Nstate', & & NstateVar(ng), DimIDs(29)) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN #endif #ifdef PERFECT_RESTART status=def_dim(ng, model, RST(ng)%ncid, ncname, 'two', & & 2, DimIDs(30)) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN status=def_dim(ng, model, RST(ng)%ncid, ncname, 'three', & & 3, DimIDs(31)) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN #endif status=def_dim(ng, model, RST(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 PERFECT_RESTART && \ (defined WRITE_WATER && defined MASKING) nvd3=2 nvd4=2 nvd5=2 #else nvd3=3 nvd4=4 nvd5=5 #endif ! ! Define dimension vectors for staggered tracer type variables. ! #if !defined PERFECT_RESTART && \ (defined WRITE_WATER && defined MASKING) t2dgrd(1)=DimIDs(17) t2dgrd(2)=DimIDs(12) sr2dgrd(1)=DimIDs(17) sr2dgrd(2)=DimIDs(12) # ifdef SOLVE3D t3dgrd(1)=DimIDs(20) t3dgrd(2)=DimIDs(12) r3dgrd(1)=DimIDs(20) r3dgrd(2)=DimIDs(12) # endif #else t2dgrd(1)=DimIDs( 1) t2dgrd(2)=DimIDs( 5) sr2dgrd(1)=DimIDs( 1) sr2dgrd(2)=DimIDs( 5) sr2dgrd(3)=DimIDs(12) # ifdef PERFECT_RESTART t2dgrd(3)=DimIDs(31) t2dgrd(4)=DimIDs(12) # else t2dgrd(3)=DimIDs(12) # endif # ifdef SOLVE3D t3dgrd(1)=DimIDs( 1) t3dgrd(2)=DimIDs( 5) t3dgrd(3)=DimIDs( 9) r3dgrd(1)=DimIDs( 1) r3dgrd(2)=DimIDs( 5) r3dgrd(3)=DimIDs( 9) # ifdef PERFECT_RESTART t3dgrd(4)=DimIDs(30) t3dgrd(5)=DimIDs(12) # else t3dgrd(4)=DimIDs(12) # endif r3dgrd(4)=DimIDs(12) # endif #endif ! ! Define dimension vectors for staggered type variables at PSI-points. ! sp2dgrd(1)=DimIDs( 4) sp2dgrd(2)=DimIDs( 8) sp2dgrd(3)=DimIDs(12) ! ! Define dimension vectors for staggered u-momentum type variables. ! #if !defined PERFECT_RESTART && \ (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) # ifdef PERFECT_RESTART u2dgrd(3)=DimIDs(31) u2dgrd(4)=DimIDs(12) # else u2dgrd(3)=DimIDs(12) # endif # ifdef SOLVE3D u3dgrd(1)=DimIDs( 2) u3dgrd(2)=DimIDs( 6) u3dgrd(3)=DimIDs( 9) # ifdef PERFECT_RESTART u3dgrd(4)=DimIDs(30) u3dgrd(5)=DimIDs(12) # else u3dgrd(4)=DimIDs(12) # endif # endif #endif ! ! Define dimension vectors for staggered v-momentum type variables. ! #if !defined PERFECT_RESTART && \ (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) # ifdef PERFECT_RESTART v2dgrd(3)=DimIDs(31) v2dgrd(4)=DimIDs(12) # else v2dgrd(3)=DimIDs(12) # endif # ifdef SOLVE3D v3dgrd(1)=DimIDs( 3) v3dgrd(2)=DimIDs( 7) v3dgrd(3)=DimIDs( 9) # ifdef PERFECT_RESTART v3dgrd(4)=DimIDs(30) v3dgrd(5)=DimIDs(12) # else v3dgrd(4)=DimIDs(12) # endif # endif #endif #ifdef PERFECT_RESTART ! ! Define dimension vectors for RHS free-surface equation. ! # if !defined PERFECT_RESTART && \ (defined WRITE_WATER && defined MASKING) r2dgrd(1)=DimIDs(17) r2dgrd(2)=DimIDs(12) # else r2dgrd(1)=DimIDs( 1) r2dgrd(2)=DimIDs( 5) r2dgrd(3)=DimIDs(30) r2dgrd(4)=DimIDs(12) # endif ! ! Define dimension vectors for RHS u-momentum equation. ! # if !defined PERFECT_RESTART && \ (defined WRITE_WATER && defined MASKING) ru2dgrd(1)=DimIDs(18) ru2dgrd(2)=DimIDs(12) # ifdef SOLVE3D ru2dgrd(1)=DimIDs(21) ru2dgrd(2)=DimIDs(12) # endif # else ru2dgrd(1)=DimIDs( 2) ru2dgrd(2)=DimIDs( 6) ru2dgrd(3)=DimIDs(30) ru2dgrd(4)=DimIDs(12) # ifdef SOLVE3D ru3dgrd(1)=DimIDs( 2) ru3dgrd(2)=DimIDs( 6) ru3dgrd(3)=DimIDs(10) ru3dgrd(4)=DimIDs(30) ru3dgrd(5)=DimIDs(12) # endif # endif ! ! Define dimension vectors for RHS v-momentum equation. ! # if !defined PERFECT_RESTART && \ (defined WRITE_WATER && defined MASKING) rv2dgrd(1)=DimIDs(19) rv2dgrd(2)=DimIDs(12) # ifdef SOLVE3D rv3dgrd(1)=DimIDs(22) rv3dgrd(2)=DimIDs(12) # endif # else rv2dgrd(1)=DimIDs( 3) rv2dgrd(2)=DimIDs( 7) rv2dgrd(3)=DimIDs(30) rv2dgrd(4)=DimIDs(12) # ifdef SOLVE3D rv3dgrd(1)=DimIDs( 3) rv3dgrd(2)=DimIDs( 7) rv3dgrd(3)=DimIDs(10) rv3dgrd(4)=DimIDs(30) rv3dgrd(5)=DimIDs(12) # endif # endif #endif #ifdef SOLVE3D ! ! Define dimension vector for staggered w-momentum type variables. ! # if !defined PERFECT_RESTART && \ (defined WRITE_WATER && defined MASKING) w3dgrd(1)=DimIDs(23) w3dgrd(2)=DimIDs(12) # ifdef PERFECT_RESTART k3dgrd(1)=DimIDs(23) k3dgrd(2)=DimIDs(12) # endif # else w3dgrd(1)=DimIDs( 1) w3dgrd(2)=DimIDs( 5) w3dgrd(3)=DimIDs(10) w3dgrd(4)=DimIDs(12) # ifdef PERFECT_RESTART k3dgrd(1)=DimIDs( 1) k3dgrd(2)=DimIDs( 5) k3dgrd(3)=DimIDs(10) k3dgrd(4)=DimIDs(30) k3dgrd(5)=DimIDs(12) # endif # endif #endif ! ! Define dimension vector for sediment, radiation stress variables. ! #if !defined PERFECT_RESTART && \ (defined WRITE_WATER && defined MASKING) su2dgrd(1)=DimIDs(18) su2dgrd(2)=DimIDs(12) sv2dgrd(1)=DimIDs(19) sv2dgrd(2)=DimIDs(12) #else su2dgrd(1)=DimIDs( 2) su2dgrd(2)=DimIDs( 6) su2dgrd(3)=DimIDs(12) sv2dgrd(1)=DimIDs( 3) sv2dgrd(2)=DimIDs( 7) sv2dgrd(3)=DimIDs(12) #endif #ifdef SOLVE3D # if !defined PERFECT_RESTART && \ (defined WRITE_WATER && defined MASKING) sr3dgrd(1)=DimIDs(24) sr3dgrd(2)=DimIDs(12) su3dgrd(1)=DimIDs(21) su3dgrd(2)=DimIDs(12) sv3dgrd(1)=DimIDs(22) sv3dgrd(2)=DimIDs(12) # else sr3dgrd(1)=DimIDs( 1) sr3dgrd(2)=DimIDs( 5) sr3dgrd(3)=DimIDs(16) sr3dgrd(4)=DimIDs(12) su3dgrd(1)=DimIDs( 2) su3dgrd(2)=DimIDs( 6) su3dgrd(3)=DimIDs( 9) su3dgrd(4)=DimIDs(12) sv3dgrd(1)=DimIDs( 3) sv3dgrd(2)=DimIDs( 7) sv3dgrd(3)=DimIDs( 9) sv3dgrd(4)=DimIDs(12) # endif #endif ! ! Initialize unlimited time record dimension. ! RST(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, RST(ng)%ncid, ncname, DimIDs) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN ! !----------------------------------------------------------------------- ! Define time-varying variables. !----------------------------------------------------------------------- #ifdef PERFECT_RESTART ! ! Define time-stepping indices. ! # ifdef SOLVE3D Vinfo( 1)='nstp' Vinfo( 2)='3D equations time level index, nstp' status=def_var(ng, model, RST(ng)%ncid, varid, nf90_int, & & 1, (/recdim/), Aval, Vinfo, ncname, & & SetParAccess = .TRUE.) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN Vinfo( 1)='nrhs' Vinfo( 2)='3D equations time level index, nrhs' status=def_var(ng, model, RST(ng)%ncid, varid, nf90_int, & & 1, (/recdim/), Aval, Vinfo, ncname, & & SetParAccess = .TRUE.) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN Vinfo( 1)='nnew' Vinfo( 2)='3D equations time level index, nnew' status=def_var(ng, model, RST(ng)%ncid, varid, nf90_int, & & 1, (/recdim/), Aval, Vinfo, ncname, & & SetParAccess = .TRUE.) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN # endif Vinfo( 1)='kstp' Vinfo( 2)='3D equations time level index, kstp' status=def_var(ng, model, RST(ng)%ncid, varid, nf90_int, & & 1, (/recdim/), Aval, Vinfo, ncname, & & SetParAccess = .TRUE.) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN Vinfo( 1)='krhs' Vinfo( 2)='3D equations time level index, krhs' status=def_var(ng, model, RST(ng)%ncid, varid, nf90_int, & & 1, (/recdim/), Aval, Vinfo, ncname, & & SetParAccess = .TRUE.) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN Vinfo( 1)='knew' Vinfo( 2)='3D equations time level index, knew' status=def_var(ng, model, RST(ng)%ncid, varid, nf90_int, & & 1, (/recdim/), Aval, Vinfo, ncname, & & SetParAccess = .TRUE.) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN #endif ! ! 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, RST(ng)%ncid, RST(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, RST(ng)%ncid, RST(ng)%Vid(idPwet), & & NF_FRST, 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, RST(ng)%ncid, RST(ng)%Vid(idRwet), & & NF_FRST, nvd3, sr2dgrd, 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, RST(ng)%ncid, RST(ng)%Vid(idUwet), & & NF_FRST, nvd3, su2dgrd, 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, RST(ng)%ncid, RST(ng)%Vid(idVwet), & & NF_FRST, nvd3, sv2dgrd, Aval, Vinfo, ncname, & & SetFillVal = .FALSE.) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN #endif #if defined SEDIMENT && defined SED_MORPH ! ! Define time-varying bathymetry. ! Vinfo( 1)=Vname(1,idbath) Vinfo( 2)=Vname(2,idbath) Vinfo( 3)=Vname(3,idbath) Vinfo(14)=Vname(4,idbath) Vinfo(16)=Vname(1,idtime) Vinfo(21)=Vname(6,idbath) Vinfo(22)='coordinates' Aval(5)=REAL(Iinfo(1,idbath,ng),r8) status=def_var(ng, model, RST(ng)%ncid, RST(ng)%Vid(idbath), & & NF_FRST, nvd3, t2dgrd, Aval, Vinfo, ncname, & & SetFillVal = .FALSE.) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN #endif ! ! 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) #if defined WRITE_WATER && defined MASKING # if !defined WET_DRY && defined PERFECT_RESTART Vinfo(24)='_FillValue' Aval(6)=spval # else Vinfo(20)='mask_rho' # endif #endif Vinfo(21)=Vname(6,idFsur) Vinfo(22)='coordinates' Aval(5)=REAL(Iinfo(1,idFsur,ng),r8) #ifdef PERFECT_RESTART status=def_var(ng, model, RST(ng)%ncid, RST(ng)%Vid(idFsur), & # ifdef WET_DRY & NF_FRST, nvd4, t2dgrd, Aval, Vinfo, ncname, & & SetFillVal = .FALSE.) # else & NF_FRST, nvd4, t2dgrd, Aval, Vinfo, ncname) # endif #else status=def_var(ng, model, RST(ng)%ncid, RST(ng)%Vid(idFsur), & # ifdef WET_DRY & NF_FRST, nvd3, t2dgrd, Aval, Vinfo, ncname, & & SetFillVal = .FALSE.) # else & NF_FRST, nvd3, t2dgrd, Aval, Vinfo, ncname) # endif #endif IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN #ifdef PERFECT_RESTART ! ! Define RHS of free-surface equation. ! Vinfo( 1)=Vname(1,idRzet) Vinfo( 2)=Vname(2,idRzet) Vinfo( 3)=Vname(3,idRzet) Vinfo(14)=Vname(4,idRzet) Vinfo(16)=Vname(1,idtime) # if defined WRITE_WATER && defined MASKING # if defined PERFECT_RESTART Vinfo(24)='_FillValue' Aval(6)=spval # else Vinfo(20)='mask_rho' # endif # endif Vinfo(21)=Vname(6,idRzet) Vinfo(22)='coordinates' Aval(5)=REAL(Iinfo(1,idFsur,ng),r8) status=def_var(ng, model, RST(ng)%ncid, RST(ng)%Vid(idRzet), & & NF_FRST, nvd4, r2dgrd, Aval, Vinfo, ncname) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN #endif ! ! 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) #if defined WRITE_WATER && defined MASKING # if defined PERFECT_RESTART Vinfo(24)='_FillValue' Aval(6)=spval # else Vinfo(20)='mask_u' # endif #endif Vinfo(21)=Vname(6,idUbar) Vinfo(22)='coordinates' Aval(5)=REAL(Iinfo(1,idUbar,ng),r8) #ifdef PERFECT_RESTART status=def_var(ng, model, RST(ng)%ncid, RST(ng)%Vid(idUbar), & & NF_FRST, nvd4, u2dgrd, Aval, Vinfo, ncname) #else status=def_var(ng, model, RST(ng)%ncid, RST(ng)%Vid(idUbar), & & NF_FRST, nvd3, u2dgrd, Aval, Vinfo, ncname) #endif IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN #ifdef PERFECT_RESTART ! ! Define RHS of 2D momentum equation in the XI-direction. ! Vinfo( 1)=Vname(1,idRu2d) Vinfo( 2)=Vname(2,idRu2d) Vinfo( 3)=Vname(3,idRu2d) Vinfo(14)=Vname(4,idRu2d) Vinfo(16)=Vname(1,idtime) # if defined WRITE_WATER && defined MASKING # if defined PERFECT_RESTART Vinfo(24)='_FillValue' Aval(6)=spval # else Vinfo(20)='mask_u' # endif # endif Vinfo(21)=Vname(6,idRu2d) Vinfo(22)='coordinates' Aval(5)=REAL(Iinfo(1,idRu2d,ng),r8) status=def_var(ng, model, RST(ng)%ncid, RST(ng)%Vid(idRu2d), & & NF_FRST, nvd4, ru2dgrd, Aval, Vinfo, ncname) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN #endif ! ! 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) #if defined WRITE_WATER && defined MASKING # if defined PERFECT_RESTART Vinfo(24)='_FillValue' Aval(6)=spval # else Vinfo(20)='mask_v' # endif #endif Vinfo(21)=Vname(6,idVbar) Vinfo(22)='coordinates' Aval(5)=REAL(Iinfo(1,idVbar,ng),r8) #ifdef PERFECT_RESTART status=def_var(ng, model, RST(ng)%ncid, RST(ng)%Vid(idVbar), & & NF_FRST, nvd4, v2dgrd, Aval, Vinfo, ncname) #else status=def_var(ng, model, RST(ng)%ncid, RST(ng)%Vid(idVbar), & & NF_FRST, nvd3, v2dgrd, Aval, Vinfo, ncname) #endif IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN #ifdef PERFECT_RESTART ! ! Define RHS of 2D momentum equation in the ETA-direction. ! Vinfo( 1)=Vname(1,idRv2d) Vinfo( 2)=Vname(2,idRv2d) Vinfo( 3)=Vname(3,idRv2d) Vinfo(14)=Vname(4,idRv2d) Vinfo(16)=Vname(1,idtime) # if defined WRITE_WATER && defined MASKING # if defined PERFECT_RESTART Vinfo(24)='_FillValue' Aval(6)=spval # else Vinfo(20)='mask_v' # endif # endif Vinfo(21)=Vname(6,idRv2d) Vinfo(22)='coordinates' Aval(5)=REAL(Iinfo(1,idRv2d,ng),r8) status=def_var(ng, model, RST(ng)%ncid, RST(ng)%Vid(idRv2d), & & NF_FRST, nvd4, rv2dgrd, Aval, Vinfo, ncname) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN #endif #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) # if defined WRITE_WATER && defined MASKING # if defined PERFECT_RESTART Vinfo(24)='_FillValue' Aval(6)=spval # else Vinfo(20)='mask_u' # endif # endif Vinfo(21)=Vname(6,idUvel) Vinfo(22)='coordinates' Aval(5)=REAL(Iinfo(1,idUvel,ng),r8) # ifdef PERFECT_RESTART status=def_var(ng, model, RST(ng)%ncid, RST(ng)%Vid(idUvel), & & NF_FRST, nvd5, u3dgrd, Aval, Vinfo, ncname) # else status=def_var(ng, model, RST(ng)%ncid, RST(ng)%Vid(idUvel), & & NF_FRST, nvd4, u3dgrd, Aval, Vinfo, ncname) # endif IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN # ifdef PERFECT_RESTART ! ! Define RHS of 3D momentum equation in the XI-direction. ! Although this variable is a U-points, a negative value is used ! here to set "s_w" in the "coordinate" attribute. The k=0 index ! is used during coupling in step2d. ! Vinfo( 1)=Vname(1,idRu3d) Vinfo( 2)=Vname(2,idRu3d) Vinfo( 3)=Vname(3,idRu3d) Vinfo(14)=Vname(4,idRu3d) Vinfo(16)=Vname(1,idtime) # if defined WRITE_WATER && defined MASKING # if defined PERFECT_RESTART Vinfo(24)='_FillValue' Aval(6)=spval # else Vinfo(20)='mask_u' # endif # endif Vinfo(21)=Vname(6,idRu3d) Vinfo(22)='coordinates' Aval(5)=REAL(-u3dvar,r8) status=def_var(ng, model, RST(ng)%ncid, RST(ng)%Vid(idRu3d), & & NF_FRST, nvd5, ru3dgrd, Aval, Vinfo, ncname) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN # endif ! ! 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) # if defined WRITE_WATER && defined MASKING # if defined PERFECT_RESTART Vinfo(24)='_FillValue' Aval(6)=spval # else Vinfo(20)='mask_v' # endif # endif Vinfo(21)=Vname(6,idVvel) Vinfo(22)='coordinates' Aval(5)=REAL(Iinfo(1,idVvel,ng),r8) # ifdef PERFECT_RESTART status=def_var(ng, model, RST(ng)%ncid, RST(ng)%Vid(idVvel), & & NF_FRST, nvd5, v3dgrd, Aval, Vinfo, ncname) # else status=def_var(ng, model, RST(ng)%ncid, RST(ng)%Vid(idVvel), & & NF_FRST, nvd4, v3dgrd, Aval, Vinfo, ncname) # endif IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN # ifdef PERFECT_RESTART ! ! Define RHS of 3D momentum equation in the ETA-direction. ! Although this variable is a V-points, a negative value is used ! here to set "s_w" in the "coordinate" attribute. The k=0 index ! is used during coupling in step2d. ! Vinfo( 1)=Vname(1,idRv3d) Vinfo( 2)=Vname(2,idRv3d) Vinfo( 3)=Vname(3,idRv3d) Vinfo(14)=Vname(4,idRv3d) Vinfo(16)=Vname(1,idtime) # if defined WRITE_WATER && defined MASKING # if defined PERFECT_RESTART Vinfo(24)='_FillValue' Aval(6)=spval # else Vinfo(20)='mask_v' # endif # endif Vinfo(21)=Vname(6,idRv3d) Vinfo(22)='coordinates' Aval(5)=REAL(-v3dvar,r8) status=def_var(ng, model, RST(ng)%ncid, RST(ng)%Vid(idRv3d), & & NF_FRST, nvd5, rv3dgrd, Aval, Vinfo, ncname) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN # endif ! ! 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),40) 1000.0_r8*Sd50(i,ng) END IF END DO # endif # if defined WRITE_WATER && defined MASKING # if defined PERFECT_RESTART Vinfo(24)='_FillValue' Aval(6)=spval # else Vinfo(20)='mask_rho' # endif # endif Vinfo(21)=Vname(6,idTvar(itrc)) Vinfo(22)='coordinates' Aval(5)=REAL(r3dvar,r8) # ifdef PERFECT_RESTART status=def_var(ng, model, RST(ng)%ncid, RST(ng)%Tid(itrc), & & NF_FRST, nvd5, t3dgrd, Aval, Vinfo, ncname) # else status=def_var(ng, model, RST(ng)%ncid, RST(ng)%Tid(itrc), & & NF_FRST, nvd4, t3dgrd, Aval, Vinfo, ncname) # endif IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN END DO ! ! Define density anomaly. ! 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 # if defined PERFECT_RESTART Vinfo(24)='_FillValue' Aval(6)=spval # else Vinfo(20)='mask_rho' # endif # endif Vinfo(21)=Vname(6,idDano) Vinfo(22)='coordinates' Aval(5)=REAL(Iinfo(1,idDano,ng),r8) status=def_var(ng, model, RST(ng)%ncid, RST(ng)%Vid(idDano), & & NF_FRST, nvd4, r3dgrd, Aval, Vinfo, ncname) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN # ifdef LMD_SKPP ! ! Define depth of surface boundary layer. ! 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 # if defined PERFECT_RESTART Vinfo(24)='_FillValue' Aval(6)=spval # else Vinfo(20)='mask_rho' # endif # endif Vinfo(21)=Vname(6,idHsbl) Vinfo(22)='coordinates' Aval(5)=REAL(Iinfo(1,idHsbl,ng),r8) status=def_var(ng, model, RST(ng)%ncid, RST(ng)%Vid(idHsbl), & & NF_FRST, nvd3, sr2dgrd, Aval, Vinfo, ncname) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN # endif # ifdef LMD_BKPP ! ! Define depth of bottom boundary layer. ! 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 # if defined PERFECT_RESTART Vinfo(24)='_FillValue' Aval(6)=spval # else Vinfo(20)='mask_rho' # endif # endif Vinfo(21)=Vname(6,idHbbl) Vinfo(22)='coordinates' Aval(5)=REAL(Iinfo(1,idHbbl,ng),r8) status=def_var(ng, model, RST(ng)%ncid, RST(ng)%Vid(idHbbl), & & NF_FRST, nvd3, sr2dgrd, Aval, Vinfo, ncname) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN # endif # if defined PERFECT_RESTART && defined LMD_NONLOCAL ! ! Define out KPP nonlocal transport. ! DO itrc=1,NAT Vinfo( 1)=Vname(1,idGhat(itrc)) Vinfo( 2)=Vname(2,idGhat(itrc)) Vinfo( 3)=Vname(3,idGhat(itrc)) Vinfo(14)=Vname(4,idGhat(itrc)) Vinfo(16)=Vname(1,idtime) # if defined WRITE_WATER && defined MASKING Vinfo(20)='mask_rho' # endif Vinfo(21)=Vname(6,idGhat(itrc)) Vinfo(22)='coordinates' Aval(5)=REAL(Iinfo(1,idGhat(itrc),ng),r8) status=def_var(ng, model, RST(ng)%ncid, & & RST(ng)%Vid(idGhat(itrc)), NF_FRST, & & nvd4, w3dgrd, Aval, Vinfo, ncname) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN END DO # endif # if defined BVF_MIXING || defined LMD_MIXING || \ defined GLS_MIXING || defined MY25_MIXING ! ! 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(21)=Vname(6,idVvis) Vinfo(22)='coordinates' Aval(5)=REAL(Iinfo(1,idVvis,ng),r8) status=def_var(ng, model, RST(ng)%ncid, RST(ng)%Vid(idVvis), & & NF_FRST, nvd4, w3dgrd, Aval, Vinfo, ncname, & & SetFillVal = .FALSE.) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) 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(21)=Vname(6,idTdif) Vinfo(22)='coordinates' Aval(5)=REAL(Iinfo(1,idTdif,ng),r8) status=def_var(ng, model, RST(ng)%ncid, RST(ng)%Vid(idTdif), & & NF_FRST, nvd4, w3dgrd, Aval, Vinfo, ncname, & & SetFillVal = .FALSE.) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) 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(21)=Vname(6,idSdif) Vinfo(22)='coordinates' Aval(5)=REAL(Iinfo(1,idSdif,ng),r8) status=def_var(ng, model, RST(ng)%ncid, RST(ng)%Vid(idSdif), & & NF_FRST, nvd4, w3dgrd, Aval, Vinfo, ncname, & & SetFillVal = .FALSE.) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN # endif # endif # if defined PERFECT_RESTART && \ (defined GLS_MIXING || defined MY25_MIXING) ! ! Define turbulent kinetic energy. ! 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) Vinfo(21)=Vname(6,idMtke) Vinfo(22)='coordinates' Aval(5)=REAL(Iinfo(1,idMtke,ng),r8) status=def_var(ng, model, RST(ng)%ncid, RST(ng)%Vid(idMtke), & & NF_FRST, nvd5, k3dgrd, Aval, Vinfo, ncname, & & SetFillVal = .FALSE.) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN ! ! Define turbulent kinetic energy time length scale. ! 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) Vinfo(21)=Vname(6,idMtls) Vinfo(22)='coordinates' Aval(5)=REAL(Iinfo(1,idMtls,ng),r8) status=def_var(ng, model, RST(ng)%ncid, RST(ng)%Vid(idMtls), & & NF_FRST, nvd5, k3dgrd, Aval, Vinfo, ncname, & & SetFillVal = .FALSE.) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN ! ! Define vertical mixing turbulent length scale. ! Vinfo( 1)=Vname(1,idVmLS) Vinfo( 2)=Vname(2,idVmLS) Vinfo( 3)=Vname(3,idVmLS) Vinfo(14)=Vname(4,idVmLS) Vinfo(16)=Vname(1,idtime) # if defined WRITE_WATER && defined MASKING # if defined PERFECT_RESTART Vinfo(24)='_FillValue' Aval(6)=spval # else Vinfo(20)='mask_rho' # endif # endif Vinfo(21)=Vname(6,idVmLS) Vinfo(22)='coordinates' Aval(5)=REAL(Iinfo(1,idVmLS,ng),r8) status=def_var(ng, model, RST(ng)%ncid, RST(ng)%Vid(idVmLS), & & NF_FRST, nvd4, w3dgrd, Aval, Vinfo, ncname) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN ! ! Define turbulent kinetic energy vertical diffusion coefficient. ! Vinfo( 1)=Vname(1,idVmKK) Vinfo( 2)=Vname(2,idVmKK) Vinfo( 3)=Vname(3,idVmKK) Vinfo(14)=Vname(4,idVmKK) Vinfo(16)=Vname(1,idtime) # if defined WRITE_WATER && defined MASKING # if defined PERFECT_RESTART Vinfo(24)='_FillValue' Aval(6)=spval # else Vinfo(20)='mask_rho' # endif # endif Vinfo(21)=Vname(6,idVmKK) Vinfo(22)='coordinates' Aval(5)=REAL(Iinfo(1,idVmKK,ng),r8) status=def_var(ng, model, RST(ng)%ncid, RST(ng)%Vid(idVmKK), & & NF_FRST, nvd4, w3dgrd, Aval, Vinfo, ncname) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN # ifdef GLS_MIXING ! ! Define turbulent length scale vertical diffusion coefficient. ! Vinfo( 1)=Vname(1,idVmKP) Vinfo( 2)=Vname(2,idVmKP) Vinfo( 3)=Vname(3,idVmKP) Vinfo(14)=Vname(4,idVmKP) Vinfo(16)=Vname(1,idtime) # if defined WRITE_WATER && defined MASKING # if defined PERFECT_RESTART Vinfo(24)='_FillValue' Aval(6)=spval # else Vinfo(20)='mask_rho' # endif # endif Vinfo(21)=Vname(6,idVmKP) Vinfo(22)='coordinates' Aval(5)=REAL(Iinfo(1,idVmKP,ng),r8) status=def_var(ng, model, RST(ng)%ncid, RST(ng)%Vid(idVmKP), & & NF_FRST, nvd4, w3dgrd, Aval, Vinfo, ncname) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN # endif # endif # ifdef SEDIMENT # ifdef BEDLOAD ! ! Define Bedload U-direction. ! DO i=1,NST Vinfo( 1)=Vname(1,idUbld(i)) Vinfo( 2)=Vname(2,idUbld(i)) Vinfo( 3)=Vname(3,idUbld(i)) Vinfo(14)=Vname(4,idUbld(i)) Vinfo(16)=Vname(1,idtime) # if defined WRITE_WATER && defined MASKING # if defined PERFECT_RESTART Vinfo(24)='_FillValue' Aval(6)=spval # else Vinfo(20)='mask_u' # endif # endif Vinfo(21)=Vname(6,idUbld(i)) Vinfo(22)='coordinates' Aval(5)=REAL(Iinfo(1,idUbld(i),ng),r8) status=def_var(ng, model, RST(ng)%ncid, & & RST(ng)%Vid(idUbld(i)), NF_FRST, & & nvd3, su2dgrd, Aval, Vinfo, ncname) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN ! ! Define Bedload V-direction. ! Vinfo( 1)=Vname(1,idVbld(i)) Vinfo( 2)=Vname(2,idVbld(i)) Vinfo( 3)=Vname(3,idVbld(i)) Vinfo(14)=Vname(4,idVbld(i)) Vinfo(16)=Vname(1,idtime) # if defined WRITE_WATER && defined MASKING # if defined PERFECT_RESTART Vinfo(24)='_FillValue' Aval(6)=spval # else Vinfo(20)='mask_v' # endif # endif Vinfo(21)=Vname(6,idVbld(i)) Vinfo(22)='coordinates' Aval(5)=REAL(Iinfo(1,idVbld(i),ng),r8) status=def_var(ng, model, RST(ng)%ncid, & & RST(ng)%Vid(idVbld(i)), NF_FRST, & & nvd3, sv2dgrd, Aval, Vinfo, ncname) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN END DO # endif ! ! Define sediment fraction of each size class in each bed layer. ! DO i=1,NST Vinfo( 1)=Vname(1,idfrac(i)) Vinfo( 2)=Vname(2,idfrac(i)) Vinfo( 3)=Vname(3,idfrac(i)) Vinfo(14)=Vname(4,idfrac(i)) Vinfo(16)=Vname(1,idtime) WRITE (Vinfo(19),40) 1000.0_r8*Sd50(i,ng) # if defined WRITE_WATER && defined MASKING # if defined PERFECT_RESTART Vinfo(24)='_FillValue' Aval(6)=spval # else Vinfo(20)='mask_rho' # endif # endif Vinfo(21)=Vname(6,idfrac(i)) Vinfo(22)='coordinates' Aval(5)=REAL(Iinfo(1,idfrac(i),ng),r8) status=def_var(ng, model, RST(ng)%ncid, & & RST(ng)%Vid(idfrac(i)), NF_FRST, & & nvd4, sr3dgrd, Aval, Vinfo, ncname) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN END DO ! ! Define sediment mass of each size class in each bed layer. ! DO i=1,NST Vinfo( 1)=Vname(1,idBmas(i)) Vinfo( 2)=Vname(2,idBmas(i)) Vinfo( 3)=Vname(3,idBmas(i)) Vinfo(14)=Vname(4,idBmas(i)) Vinfo(16)=Vname(1,idtime) WRITE (Vinfo(19),40) 1000.0_r8*Sd50(i,ng) # if defined WRITE_WATER && defined MASKING # if defined PERFECT_RESTART Vinfo(24)='_FillValue' Aval(6)=spval # else Vinfo(20)='mask_rho' # endif # endif Vinfo(21)=Vname(6,idBmas(i)) Vinfo(22)='coordinates' Aval(5)=REAL(Iinfo(1,idBmas(i),ng),r8) status=def_var(ng, model, RST(ng)%ncid, & & RST(ng)%Vid(idBmas(i)), NF_FRST, & & nvd4, sr3dgrd, Aval, Vinfo, ncname) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN END DO ! ! Define sediment properties in each bed layer. ! DO i=1,MBEDP Vinfo( 1)=Vname(1,idSbed(i)) Vinfo( 2)=Vname(2,idSbed(i)) Vinfo( 3)=Vname(3,idSbed(i)) Vinfo(14)=Vname(4,idSbed(i)) Vinfo(16)=Vname(1,idtime) # if defined WRITE_WATER && defined MASKING # if defined PERFECT_RESTART Vinfo(24)='_FillValue' Aval(6)=spval # else Vinfo(20)='mask_rho' # endif # endif Vinfo(21)=Vname(6,idSbed(i)) Vinfo(22)='coordinates' Aval(5)=REAL(Iinfo(1,idSbed(i),ng),r8) status=def_var(ng, model, RST(ng)%ncid, & & RST(ng)%Vid(idSbed(i)), NF_FRST, & & nvd4, sr3dgrd, Aval, Vinfo, ncname) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN END DO # endif # if defined SEDIMENT || defined BBL_MODEL ! ! define exposed sediment layer properties. Notice that only the ! first four properties (mean grain diameter, mean grain density, ! mean settling velocity, mean critical erosion stress, ! ripple length and ripple height) are written. ! DO i=1,6 Vinfo( 1)=Vname(1,idBott(i)) Vinfo( 2)=Vname(2,idBott(i)) Vinfo( 3)=Vname(3,idBott(i)) Vinfo(14)=Vname(4,idBott(i)) Vinfo(16)=Vname(1,idtime) # if defined WRITE_WATER && defined MASKING # if defined PERFECT_RESTART Vinfo(24)='_FillValue' Aval(6)=spval # else Vinfo(20)='mask_rho' # endif # endif Vinfo(21)=Vname(6,idBott(i)) Vinfo(22)='coordinates' Aval(5)=REAL(Iinfo(1,idBott(i),ng),r8) status=def_var(ng, model, RST(ng)%ncid, & & RST(ng)%Vid(idBott(i)), NF_FRST, & & nvd3, sr2dgrd, Aval, Vinfo, ncname) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN END DO # endif #endif #ifdef WEC ! ! Define 2D Stokes U-velocity. ! Vinfo( 1)=Vname(1,idU2Sd) Vinfo( 2)=Vname(2,idU2Sd) Vinfo( 3)=Vname(3,idU2Sd) Vinfo(14)=Vname(4,idU2Sd) Vinfo(16)=Vname(1,idtime) # if defined WRITE_WATER && defined MASKING # if defined PERFECT_RESTART Vinfo(24)='_FillValue' Aval(6)=spval # else Vinfo(20)='mask_u' # endif # endif Vinfo(21)=Vname(6,idU2Sd) Vinfo(22)='coordinates' Aval(5)=REAL(Iinfo(1,idU2Sd,ng),r8) status=def_var(ng, model, RST(ng)%ncid, RST(ng)%Vid(idU2Sd), & & NF_FRST, nvd3, su2dgrd, Aval, Vinfo, ncname) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN ! ! Define 2D Stokes V-velocity. ! Vinfo( 1)=Vname(1,idV2Sd) Vinfo( 2)=Vname(2,idV2Sd) Vinfo( 3)=Vname(3,idV2Sd) Vinfo(14)=Vname(4,idV2Sd) Vinfo(16)=Vname(1,idtime) # if defined WRITE_WATER && defined MASKING # if defined PERFECT_RESTART Vinfo(24)='_FillValue' Aval(6)=spval # else Vinfo(20)='mask_v' # endif # endif Vinfo(21)=Vname(6,idV2Sd) Vinfo(22)='coordinates' Aval(5)=REAL(Iinfo(1,idV2Sd,ng),r8) status=def_var(ng, model, RST(ng)%ncid, RST(ng)%Vid(idV2Sd), & & NF_FRST, nvd3, sv2dgrd, Aval, Vinfo, ncname) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN # ifdef SOLVE3D ! ! Define 3D Stokes U-velocity. ! Vinfo( 1)=Vname(1,idU3Sd) Vinfo( 2)=Vname(2,idU3Sd) Vinfo( 3)=Vname(3,idU3Sd) Vinfo(14)=Vname(4,idU3Sd) Vinfo(16)=Vname(1,idtime) # if defined WRITE_WATER && defined MASKING # if defined PERFECT_RESTART Vinfo(24)='_FillValue' Aval(6)=spval # else Vinfo(20)='mask_u' # endif # endif Vinfo(21)=Vname(6,idU3Sd) Vinfo(22)='coordinates' Aval(5)=REAL(Iinfo(1,idU3Sd,ng),r8) status=def_var(ng, model, RST(ng)%ncid, RST(ng)%Vid(idU3Sd), & & NF_FRST, nvd4, su3dgrd, Aval, Vinfo, ncname) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN ! ! Define 3D Stokes V-velocity. ! Vinfo( 1)=Vname(1,idV3Sd) Vinfo( 2)=Vname(2,idV3Sd) Vinfo( 3)=Vname(3,idV3Sd) Vinfo(14)=Vname(4,idV3Sd) Vinfo(16)=Vname(1,idtime) # if defined WRITE_WATER && defined MASKING # if defined PERFECT_RESTART Vinfo(24)='_FillValue' Aval(6)=spval # else Vinfo(20)='mask_v' # endif # endif Vinfo(21)=Vname(6,idV3Sd) Vinfo(22)='coordinates' Aval(5)=REAL(Iinfo(1,idV3Sd,ng),r8) status=def_var(ng, model, RST(ng)%ncid, RST(ng)%Vid(idV3Sd), & & NF_FRST, nvd4, sv3dgrd, Aval, Vinfo, ncname) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN # endif #endif #ifdef ICE_MODEL ! !----------------------------------------------------------------------- ! Define sea-ice model variables. !----------------------------------------------------------------------- ! CALL ice_def_nf90 (ng, model, Ldefine, Hout, RST, & t2dgrd, u2dgrd, v2dgrd) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN #endif ! !----------------------------------------------------------------------- ! Leave definition mode. !----------------------------------------------------------------------- ! CALL netcdf_enddef (ng, model, ncname, RST(ng)%ncid) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN ! !----------------------------------------------------------------------- ! Write out time-recordless, information variables. !----------------------------------------------------------------------- ! CALL wrt_info (ng, model, RST(ng)%ncid, ncname) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN END IF DEFINE ! !======================================================================= ! Open an existing restart file, check its contents, and prepare for ! appending data. !======================================================================= ! QUERY : IF (.not.Ldefine) THEN ncname=RST(ng)%name ! ! Open restart file for read/write. ! CALL netcdf_open (ng, model, ncname, 1, RST(ng)%ncid) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) THEN WRITE (stdout,50) TRIM(ncname) RETURN END IF ! ! Inquire about the dimensions and check for consistency. ! CALL netcdf_check_dim (ng, model, ncname, & & ncid = RST(ng)%ncid) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN ! ! Inquire about the variables. ! CALL netcdf_inq_var (ng, model, ncname, & & ncid = RST(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 ! 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. RST(ng)%Vid(idtime)=var_id(i) #if defined SEDIMENT && defined SED_MORPH ELSE IF (TRIM(var_name(i)).eq.TRIM(Vname(1,idbath))) THEN got_var(idbath)=.TRUE. RST(ng)%Vid(idbath)=var_id(i) #endif #if defined WET_DRY ELSE IF (TRIM(var_name(i)).eq.TRIM(Vname(1,idRwet))) THEN got_var(idRwet)=.TRUE. RST(ng)%Vid(idRwet)=var_id(i) ELSE IF (TRIM(var_name(i)).eq.TRIM(Vname(1,idUwet))) THEN got_var(idUwet)=.TRUE. RST(ng)%Vid(idUwet)=var_id(i) ELSE IF (TRIM(var_name(i)).eq.TRIM(Vname(1,idVwet))) THEN got_var(idVwet)=.TRUE. RST(ng)%Vid(idVwet)=var_id(i) ELSE IF (TRIM(var_name(i)).eq.TRIM(Vname(1,idPwet))) THEN got_var(idPwet)=.TRUE. RST(ng)%Vid(idPwet)=var_id(i) #endif ELSE IF (TRIM(var_name(i)).eq.TRIM(Vname(1,idFsur))) THEN got_var(idFsur)=.TRUE. RST(ng)%Vid(idFsur)=var_id(i) #ifdef PERFECT_RESTART ELSE IF (TRIM(var_name(i)).eq.TRIM(Vname(1,idRzet))) THEN got_var(idRzet)=.TRUE. RST(ng)%Vid(idRzet)=var_id(i) #endif ELSE IF (TRIM(var_name(i)).eq.TRIM(Vname(1,idUbar))) THEN got_var(idUbar)=.TRUE. RST(ng)%Vid(idUbar)=var_id(i) #ifdef PERFECT_RESTART ELSE IF (TRIM(var_name(i)).eq.TRIM(Vname(1,idRu2d))) THEN got_var(idRu2d)=.TRUE. RST(ng)%Vid(idRu2d)=var_id(i) #endif ELSE IF (TRIM(var_name(i)).eq.TRIM(Vname(1,idVbar))) THEN got_var(idVbar)=.TRUE. RST(ng)%Vid(idVbar)=var_id(i) #ifdef PERFECT_RESTART ELSE IF (TRIM(var_name(i)).eq.TRIM(Vname(1,idRv2d))) THEN got_var(idRv2d)=.TRUE. RST(ng)%Vid(idRv2d)=var_id(i) #endif #ifdef SOLVE3D ELSE IF (TRIM(var_name(i)).eq.TRIM(Vname(1,idUvel))) THEN got_var(idUvel)=.TRUE. RST(ng)%Vid(idUvel)=var_id(i) # ifdef PERFECT_RESTART ELSE IF (TRIM(var_name(i)).eq.TRIM(Vname(1,idRu3d))) THEN got_var(idRu3d)=.TRUE. RST(ng)%Vid(idRu3d)=var_id(i) # endif ELSE IF (TRIM(var_name(i)).eq.TRIM(Vname(1,idVvel))) THEN got_var(idVvel)=.TRUE. RST(ng)%Vid(idVvel)=var_id(i) # ifdef PERFECT_RESTART ELSE IF (TRIM(var_name(i)).eq.TRIM(Vname(1,idRv3d))) THEN got_var(idRv3d)=.TRUE. RST(ng)%Vid(idRv3d)=var_id(i) # endif ELSE IF (TRIM(var_name(i)).eq.TRIM(Vname(1,idDano))) THEN got_var(idDano)=.TRUE. RST(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. RST(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. RST(ng)%Vid(idHbbl)=var_id(i) # endif # if defined PERFECT_RESTART && defined LMD_NONLOCAL ELSE IF (TRIM(var_name(i)).eq. & & TRIM(Vname(1,idGhat(itemp)))) THEN got_var(idGhat(itemp))=.TRUE. RST(ng)%Vid(idGhat(itemp))=var_id(i) # ifdef SALINITY ELSE IF (TRIM(var_name(i)).eq. & & TRIM(Vname(1,idGhat(isalt)))) THEN got_var(idGhat(isalt))=.TRUE. RST(ng)%Vid(idGhat(isalt))=var_id(i) # endif # endif ELSE IF (TRIM(var_name(i)).eq.TRIM(Vname(1,idVvis))) THEN got_var(idVvis)=.TRUE. RST(ng)%Vid(idVvis)=var_id(i) ELSE IF (TRIM(var_name(i)).eq.TRIM(Vname(1,idTdif))) THEN got_var(idTdif)=.TRUE. RST(ng)%Vid(idTdif)=var_id(i) ELSE IF (TRIM(var_name(i)).eq.TRIM(Vname(1,idSdif))) THEN got_var(idSdif)=.TRUE. RST(ng)%Vid(idSdif)=var_id(i) # if defined PERFECT_RESTART && \ (defined GLS_MIXING || defined MY25_MIXING) ELSE IF (TRIM(var_name(i)).eq.TRIM(Vname(1,idMtke))) THEN got_var(idMtke)=.TRUE. RST(ng)%Vid(idMtke)=var_id(i) ELSE IF (TRIM(var_name(i)).eq.TRIM(Vname(1,idMtls))) THEN got_var(idMtls)=.TRUE. RST(ng)%Vid(idMtls)=var_id(i) ELSE IF (TRIM(var_name(i)).eq.TRIM(Vname(1,idVmLS))) THEN got_var(idVmLS)=.TRUE. RST(ng)%Vid(idVmLS)=var_id(i) ELSE IF (TRIM(var_name(i)).eq.TRIM(Vname(1,idVmKK))) THEN got_var(idVmKK)=.TRUE. RST(ng)%Vid(idVmKK)=var_id(i) # ifdef GLS_MIXING ELSE IF (TRIM(var_name(i)).eq.TRIM(Vname(1,idVmKP))) THEN got_var(idVmKP)=.TRUE. RST(ng)%Vid(idVmKP)=var_id(i) # endif # endif #endif #ifdef WEC ELSE IF (TRIM(var_name(i)).eq.TRIM(Vname(1,idU2Sd))) THEN got_var(idU2Sd)=.TRUE. RST(ng)%Vid(idU2Sd)=var_id(i) ELSE IF (TRIM(var_name(i)).eq.TRIM(Vname(1,idV2Sd))) THEN got_var(idV2Sd)=.TRUE. RST(ng)%Vid(idV2Sd)=var_id(i) # ifdef SOLVE3D ELSE IF (TRIM(var_name(i)).eq.TRIM(Vname(1,idU3Sd))) THEN got_var(idU3Sd)=.TRUE. RST(ng)%Vid(idU3Sd)=var_id(i) ELSE IF (TRIM(var_name(i)).eq.TRIM(Vname(1,idV3Sd))) THEN got_var(idV3Sd)=.TRUE. RST(ng)%Vid(idV3Sd)=var_id(i) # endif #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. RST(ng)%Tid(itrc)=var_id(i) END IF END DO # ifdef SEDIMENT DO itrc=1,NST IF (TRIM(var_name(i)).eq. & & TRIM(Vname(1,idfrac(itrc)))) THEN got_var(idfrac(itrc))=.TRUE. RST(ng)%Vid(idfrac(itrc))=var_id(i) ELSE IF (TRIM(var_name(i)).eq. & & TRIM(Vname(1,idBmas(itrc)))) THEN got_var(idBmas(itrc))=.TRUE. RST(ng)%Vid(idBmas(itrc))=var_id(i) # ifdef BEDLOAD ELSE IF (TRIM(var_name(i)).eq. & & TRIM(Vname(1,idUbld(itrc)))) THEN got_var(idUbld(itrc))=.true. RST(ng)%Vid(idUbld(itrc))=var_id(i) ELSE IF (TRIM(var_name(i)).eq. & & TRIM(Vname(1,idVbld(itrc)))) THEN got_var(idVbld(itrc))=.true. RST(ng)%Vid(idVbld(itrc))=var_id(i) # endif END IF END DO DO itrc=1,MBEDP IF (TRIM(var_name(i)).eq.TRIM(Vname(1,idSbed(itrc)))) THEN got_var(idSbed(itrc))=.TRUE. RST(ng)%Vid(idSbed(itrc))=var_id(i) END IF END DO # endif # if defined SEDIMENT || defined BBL_MODEL DO itrc=1,6 IF (TRIM(var_name(i)).eq.TRIM(Vname(1,idBott(itrc)))) THEN got_var(idBott(itrc))=.TRUE. RST(ng)%Vid(idBott(itrc))=var_id(i) END IF END DO # endif #endif END DO ! ! Check if initialization variables are available in input NetCDF ! file. ! IF (.not.got_var(idtime)) THEN IF (Master) WRITE (stdout,60) TRIM(Vname(1,idtime)), & & TRIM(ncname) exit_flag=3 RETURN END IF #if defined SEDIMENT && defined SED_MORPH IF (.not.got_var(idbath)) THEN IF (Master) WRITE (stdout,60) TRIM(Vname(1,idbath)), & & TRIM(ncname) exit_flag=3 RETURN END IF #endif #if defined WET_DRY IF (.not.got_var(idRwet)) THEN IF (Master) WRITE (stdout,60) TRIM(Vname(1,idRwet)), & & TRIM(ncname) exit_flag=3 RETURN END IF IF (.not.got_var(idUwet)) THEN IF (Master) WRITE (stdout,60) TRIM(Vname(1,idUwet)), & & TRIM(ncname) exit_flag=3 RETURN END IF IF (.not.got_var(idVwet)) THEN IF (Master) WRITE (stdout,60) TRIM(Vname(1,idVwet)), & & TRIM(ncname) exit_flag=3 RETURN END IF IF (.not.got_var(idPwet)) THEN IF (Master) WRITE (stdout,60) TRIM(Vname(1,idPwet)), & & TRIM(ncname) exit_flag=3 RETURN END IF #endif IF (.not.got_var(idFsur)) THEN IF (Master) WRITE (stdout,60) TRIM(Vname(1,idFsur)), & & TRIM(ncname) exit_flag=3 RETURN END IF #ifdef PERFECT_RESTART IF (.not.got_var(idRzet)) THEN IF (Master) WRITE (stdout,60) TRIM(Vname(1,idRzet)), & & TRIM(ncname) exit_flag=3 RETURN END IF #endif IF (.not.got_var(idUbar)) THEN IF (Master) WRITE (stdout,60) TRIM(Vname(1,idUbar)), & & TRIM(ncname) exit_flag=3 RETURN END IF #ifdef PERFECT_RESTART IF (.not.got_var(idRu2d)) THEN IF (Master) WRITE (stdout,60) TRIM(Vname(1,idRu2d)), & & TRIM(ncname) exit_flag=3 RETURN END IF #endif IF (.not.got_var(idVbar)) THEN IF (Master) WRITE (stdout,60) TRIM(Vname(1,idVbar)), & & TRIM(ncname) exit_flag=3 RETURN END IF #ifdef PERFECT_RESTART IF (.not.got_var(idRv2d)) THEN IF (Master) WRITE (stdout,60) TRIM(Vname(1,idRv2d)), & & TRIM(ncname) exit_flag=3 RETURN END IF #endif #ifdef SOLVE3D IF (.not.got_var(idUvel)) THEN IF (Master) WRITE (stdout,60) TRIM(Vname(1,idUvel)), & & TRIM(ncname) exit_flag=3 RETURN END IF # ifdef PERFECT_RESTART IF (.not.got_var(idRu3d)) THEN IF (Master) WRITE (stdout,60) TRIM(Vname(1,idRu3d)), & & TRIM(ncname) exit_flag=3 RETURN END IF # endif IF (.not.got_var(idVvel)) THEN IF (Master) WRITE (stdout,60) TRIM(Vname(1,idVvel)), & & TRIM(ncname) exit_flag=3 RETURN END IF # ifdef PERFECT_RESTART IF (.not.got_var(idRv3d)) THEN IF (Master) WRITE (stdout,60) TRIM(Vname(1,idRv3d)), & & TRIM(ncname) exit_flag=3 RETURN END IF # endif IF (.not.got_var(idDano)) THEN IF (Master) WRITE (stdout,60) TRIM(Vname(1,idDano)), & & TRIM(ncname) exit_flag=3 RETURN END IF # if defined PERFECT_RESTART && \ (defined GLS_MIXING || defined MY25_MIXING) IF (.not.got_var(idMtke)) THEN IF (Master) WRITE (stdout,60) TRIM(Vname(1,idMtke)), & & TRIM(ncname) exit_flag=3 RETURN END IF IF (.not.got_var(idMtls)) THEN IF (Master) WRITE (stdout,60) TRIM(Vname(1,idMtls)), & & TRIM(ncname) exit_flag=3 RETURN END IF IF (.not.got_var(idVmLS)) THEN IF (Master) WRITE (stdout,60) TRIM(Vname(1,idVmLS)), & & TRIM(ncname) exit_flag=3 RETURN END IF IF (.not.got_var(idVmKK)) THEN IF (Master) WRITE (stdout,60) TRIM(Vname(1,idVmKK)), & & TRIM(ncname) exit_flag=3 RETURN END IF # ifdef GLS_MIXING IF (.not.got_var(idVmKP)) THEN IF (Master) WRITE (stdout,60) TRIM(Vname(1,idVmKP)), & & TRIM(ncname) exit_flag=3 RETURN END IF # endif # endif #endif #ifdef WEC IF (.not.got_var(idU2Sd)) THEN IF (Master) WRITE (stdout,60) TRIM(Vname(1,idU2Sd)), & & TRIM(ncname) exit_flag=3 RETURN END IF IF (.not.got_var(idV2Sd)) THEN IF (Master) WRITE (stdout,60) TRIM(Vname(1,idV2Sd)), & & TRIM(ncname) exit_flag=3 RETURN END IF # ifdef SOLVE3D IF (.not.got_var(idU3Sd)) THEN IF (Master) WRITE (stdout,60) TRIM(Vname(1,idU3Sd)), & & TRIM(ncname) exit_flag=3 RETURN END IF IF (.not.got_var(idV3Sd)) THEN IF (Master) WRITE (stdout,60) TRIM(Vname(1,idV3Sd)), & & TRIM(ncname) exit_flag=3 RETURN END IF # endif #endif #ifdef SOLVE3D DO itrc=1,NT(ng) IF (.not.got_var(idTvar(itrc))) THEN IF (Master) WRITE (stdout,60) TRIM(Vname(1,idTvar(itrc))), & & TRIM(ncname) exit_flag=3 RETURN END IF END DO # ifdef SEDIMENT DO i=1,NST IF (.not.got_var(idfrac(i))) THEN IF (Master) WRITE (stdout,60) TRIM(Vname(1,idfrac(i))), & & TRIM(ncname) exit_flag=3 RETURN END IF IF (.not.got_var(idBmas(i))) THEN IF (Master) WRITE (stdout,60) TRIM(Vname(1,idBmas(i))), & & TRIM(ncname) exit_flag=3 RETURN END IF # ifdef BEDLOAD IF (.not.got_var(idUbld(i))) THEN IF (Master) WRITE (stdout,60) TRIM(Vname(1,idUbld(i))), & & TRIM(ncname) exit_flag=3 RETURN END IF IF (.not.got_var(idVbld(i))) THEN IF (Master) WRITE (stdout,60) TRIM(Vname(1,idVbld(i))), & & TRIM(ncname) exit_flag=3 RETURN END IF # endif END DO DO i=1,MBEDP IF (.not.got_var(idSbed(i))) THEN IF (Master) WRITE (stdout,60) TRIM(Vname(1,idSbed(i))), & & TRIM(ncname) exit_flag=3 RETURN END IF END DO # endif # if defined SEDIMENT || defined BBL_MODEL DO i=1,6 IF (.not.got_var(idBott(i))) THEN IF (Master) WRITE (stdout,60) TRIM(Vname(1,idBott(i))), & & TRIM(ncname) exit_flag=3 RETURN END IF END DO # endif #endif #ifdef ICE_MODEL ! ! Scan sea-ice variables from input NetCDF and activate switches for ! restart variables. Get variable IDs. ! CALL ice_def_nf90 (ng, model, Ldefine, Hout, RST) #endif ! ! Set unlimited time record dimension to current value. ! IF (LcycleRST(ng)) THEN RST(ng)%Rindex=0 ELSE RST(ng)%Rindex=rec_size END IF END IF QUERY ! 10 FORMAT (2x,'DEF_RST_NF90 - creating restart file,',t56, & & 'Grid ',i2.2,': ',a) 20 FORMAT (2x,'DEF_RST_NF90 - inquiring restart file,',t56, & & 'Grid ',i2.2,': ',a) 30 FORMAT (/,' DEF_RST_NF90 - unable to create restart NetCDF', & & ' file:',a) 40 FORMAT (1pe11.4,1x,'millimeter') 50 FORMAT (/,' DEF_RST_NF90 - unable to open restart NetCDF', & & ' file: ',a) 60 FORMAT (/,' DEF_RST_NF90 - unable to find variable: ',a,2x, & & ' in restart NetCDF file: ',a) ! RETURN END SUBROUTINE def_rst_nf90 #if defined PIO_LIB && defined DISTRIBUTE ! !*********************************************************************** SUBROUTINE def_rst_pio (ng, model) !*********************************************************************** ! USE mod_pio_netcdf ! ! Imported variable declarations. ! integer, intent(in) :: ng, model ! ! Local variable declarations. ! logical :: Ldefine, got_var(NV) ! integer, parameter :: Natt = 25 integer :: i, j, nvd3, nvd4, nvd5 integer :: recdim, status integer :: DimIDs(nDimID) integer :: r2dgrd(4), ru2dgrd(4), rv2dgrd(4) integer :: sp2dgrd(3), sr2dgrd(3), su2dgrd(3), sv2dgrd(3) integer :: sr3dgrd(4), su3dgrd(4), sv3dgrd(4) integer :: t2dgrd(4), u2dgrd(4), v2dgrd(4) # ifdef SOLVE3D integer :: itrc integer :: k3dgrd(5), t3dgrd(5) integer :: r3dgrd(4), ru3dgrd(5), rv3dgrd(5) integer :: u3dgrd(5), v3dgrd(5), w3dgrd(4) # endif ! real(r8) :: Aval(6) ! character (len=256) :: ncname character (len=MaxLen) :: Vinfo(Natt) character (len=*), parameter :: MyFile = & & __FILE__//", def_rst_pio" ! TYPE (Var_desc_t) :: varDesc ! SourceFile=MyFile ! !----------------------------------------------------------------------- ! Set and report file name. !----------------------------------------------------------------------- ! ! Activate creation of restart NetCDF file. If a restart run, the ! restart filename "RST(ng)%name" is different than the initial ! filename "INI(ng)%name". ! IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN ncname=RST(ng)%name Ldefine=.FALSE. IF (((nrrec(ng).eq.0).and.(iic(ng).eq.ntstart(ng))).or. & & ((nrrec(ng).ne.0).and. & & (TRIM(ncname).ne.TRIM(INI(ng)%name)))) THEN Ldefine=.TRUE. END IF ! IF (Master) THEN IF (Ldefine) THEN WRITE (stdout,10) ng, TRIM(ncname) ELSE WRITE (stdout,20) ng, TRIM(ncname) END IF END IF ! !======================================================================= ! Create a new restart NetCDF file. !======================================================================= ! DEFINE : IF (Ldefine) THEN CALL pio_netcdf_create (ng, model, TRIM(ncname), RST(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, RST(ng)%pioFile, ncname, 'xi_rho', & & IOBOUNDS(ng)%xi_rho, DimIDs( 1)) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN status=def_dim(ng, model, RST(ng)%pioFile, ncname, 'xi_u', & & IOBOUNDS(ng)%xi_u, DimIDs( 2)) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN status=def_dim(ng, model, RST(ng)%pioFile, ncname, 'xi_v', & & IOBOUNDS(ng)%xi_v, DimIDs( 3)) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN status=def_dim(ng, model, RST(ng)%pioFile, ncname, 'xi_psi', & & IOBOUNDS(ng)%xi_psi, DimIDs( 4)) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN status=def_dim(ng, model, RST(ng)%pioFile, ncname, 'eta_rho', & & IOBOUNDS(ng)%eta_rho, DimIDs( 5)) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN status=def_dim(ng, model, RST(ng)%pioFile, ncname, 'eta_u', & & IOBOUNDS(ng)%eta_u, DimIDs( 6)) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN status=def_dim(ng, model, RST(ng)%pioFile, ncname, 'eta_v', & & IOBOUNDS(ng)%eta_v, DimIDs( 7)) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN status=def_dim(ng, model, RST(ng)%pioFile, ncname, 'eta_psi', & & IOBOUNDS(ng)%eta_psi, DimIDs( 8)) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN # if !defined PERFECT_RESTART && \ (defined WRITE_WATER && defined MASKING) status=def_dim(ng, model, RST(ng)%pioFile, ncname, 'xy_rho', & & IOBOUNDS(ng)%xy_rho, DimIDs(17)) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN status=def_dim(ng, model, RST(ng)%pioFile, ncname, 'xy_u', & & IOBOUNDS(ng)%xy_u, DimIDs(18)) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN status=def_dim(ng, model, RST(ng)%pioFile, ncname, 'xy_v', & & IOBOUNDS(ng)%xy_v, DimIDs(19)) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN # endif # ifdef SOLVE3D # if !defined PERFECT_RESTART && \ (defined WRITE_WATER && defined MASKING) status=def_dim(ng, model, RST(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, RST(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, RST(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, RST(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, RST(ng)%pioFile, ncname, 'N', & & N(ng), DimIDs( 9)) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN status=def_dim(ng, model, RST(ng)%pioFile, ncname, 's_rho', & & N(ng), DimIDs( 9)) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN status=def_dim(ng, model, RST(ng)%pioFile, ncname, 's_w', & & N(ng)+1, DimIDs(10)) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN status=def_dim(ng, model, RST(ng)%pioFile, ncname, 'tracer', & & NT(ng), DimIDs(11)) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN # ifdef SEDIMENT status=def_dim(ng, model, RST(ng)%pioFile, ncname, 'NST', & & NST, DimIDs(32)) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN status=def_dim(ng, model, RST(ng)%pioFile, ncname, 'Nbed', & & Nbed, DimIDs(16)) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN # if !defined PERFECT_RESTART && \ (defined WRITE_WATER && defined MASKING) status=def_dim(ng, model, RST(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, RST(ng)%pioFile, ncname, 'Nbands', & & NBands, DimIDs(33)) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN status=def_dim(ng, model, RST(ng)%pioFile, ncname, 'Nphy', & & Nphy, DimIDs(25)) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN status=def_dim(ng, model, RST(ng)%pioFile, ncname, 'Nbac', & & Nbac, DimIDs(26)) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN status=def_dim(ng, model, RST(ng)%pioFile, ncname, 'Ndom', & & Ndom, DimIDs(27)) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN status=def_dim(ng, model, RST(ng)%pioFile, ncname, 'Nfec', & & Nfec, DimIDs(28)) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN # endif # endif status=def_dim(ng, model, RST(ng)%pioFile, ncname, 'boundary', & & 4, DimIDs(14)) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN # ifdef FOUR_DVAR status=def_dim(ng, model, RST(ng)%pioFile, ncname, 'Nstate', & & NstateVar(ng), DimIDs(29)) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN # endif # ifdef PERFECT_RESTART status=def_dim(ng, model, RST(ng)%pioFile, ncname, 'two', & & 2, DimIDs(30)) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN status=def_dim(ng, model, RST(ng)%pioFile, ncname, 'three', & & 3, DimIDs(31)) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN # endif status=def_dim(ng, model, RST(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 PERFECT_RESTART && \ (defined WRITE_WATER && defined MASKING) nvd3=2 nvd4=2 nvd5=2 # else nvd3=3 nvd4=4 nvd5=5 # endif ! ! Define dimension vectors for staggered tracer type variables. ! # if !defined PERFECT_RESTART && \ (defined WRITE_WATER && defined MASKING) t2dgrd(1)=DimIDs(17) t2dgrd(2)=DimIDs(12) sr2dgrd(1)=DimIDs(17) sr2dgrd(2)=DimIDs(12) # ifdef SOLVE3D t3dgrd(1)=DimIDs(20) t3dgrd(2)=DimIDs(12) r3dgrd(1)=DimIDs(20) r3dgrd(2)=DimIDs(12) # endif # else t2dgrd(1)=DimIDs( 1) t2dgrd(2)=DimIDs( 5) sr2dgrd(1)=DimIDs( 1) sr2dgrd(2)=DimIDs( 5) sr2dgrd(3)=DimIDs(12) # ifdef PERFECT_RESTART t2dgrd(3)=DimIDs(31) t2dgrd(4)=DimIDs(12) # else t2dgrd(3)=DimIDs(12) # endif # ifdef SOLVE3D t3dgrd(1)=DimIDs( 1) t3dgrd(2)=DimIDs( 5) t3dgrd(3)=DimIDs( 9) r3dgrd(1)=DimIDs( 1) r3dgrd(2)=DimIDs( 5) r3dgrd(3)=DimIDs( 9) # ifdef PERFECT_RESTART t3dgrd(4)=DimIDs(30) t3dgrd(5)=DimIDs(12) # else t3dgrd(4)=DimIDs(12) # endif r3dgrd(4)=DimIDs(12) # endif # endif ! ! Define dimension vectors for staggered type variables at PSI-points. ! sp2dgrd(1)=DimIDs( 4) sp2dgrd(2)=DimIDs( 8) sp2dgrd(3)=DimIDs(12) ! ! Define dimension vectors for staggered u-momentum type variables. ! # if !defined PERFECT_RESTART && \ (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) # ifdef PERFECT_RESTART u2dgrd(3)=DimIDs(31) u2dgrd(4)=DimIDs(12) # else u2dgrd(3)=DimIDs(12) # endif # ifdef SOLVE3D u3dgrd(1)=DimIDs( 2) u3dgrd(2)=DimIDs( 6) u3dgrd(3)=DimIDs( 9) # ifdef PERFECT_RESTART u3dgrd(4)=DimIDs(30) u3dgrd(5)=DimIDs(12) # else u3dgrd(4)=DimIDs(12) # endif # endif # endif ! ! Define dimension vectors for staggered v-momentum type variables. ! # if !defined PERFECT_RESTART && \ (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) # ifdef PERFECT_RESTART v2dgrd(3)=DimIDs(31) v2dgrd(4)=DimIDs(12) # else v2dgrd(3)=DimIDs(12) # endif # ifdef SOLVE3D v3dgrd(1)=DimIDs( 3) v3dgrd(2)=DimIDs( 7) v3dgrd(3)=DimIDs( 9) # ifdef PERFECT_RESTART v3dgrd(4)=DimIDs(30) v3dgrd(5)=DimIDs(12) # else v3dgrd(4)=DimIDs(12) # endif # endif # endif # ifdef PERFECT_RESTART ! ! Define dimension vectors for RHS free-surface equation. ! # if !defined PERFECT_RESTART && \ (defined WRITE_WATER && defined MASKING) r2dgrd(1)=DimIDs(17) r2dgrd(2)=DimIDs(12) # else r2dgrd(1)=DimIDs( 1) r2dgrd(2)=DimIDs( 5) r2dgrd(3)=DimIDs(30) r2dgrd(4)=DimIDs(12) # endif ! ! Define dimension vectors for RHS u-momentum equation. ! # if !defined PERFECT_RESTART && \ (defined WRITE_WATER && defined MASKING) ru2dgrd(1)=DimIDs(18) ru2dgrd(2)=DimIDs(12) # ifdef SOLVE3D ru2dgrd(1)=DimIDs(21) ru2dgrd(2)=DimIDs(12) # endif # else ru2dgrd(1)=DimIDs( 2) ru2dgrd(2)=DimIDs( 6) ru2dgrd(3)=DimIDs(30) ru2dgrd(4)=DimIDs(12) # ifdef SOLVE3D ru3dgrd(1)=DimIDs( 2) ru3dgrd(2)=DimIDs( 6) ru3dgrd(3)=DimIDs(10) ru3dgrd(4)=DimIDs(30) ru3dgrd(5)=DimIDs(12) # endif # endif ! ! Define dimension vectors for RHS v-momentum equation. ! # if !defined PERFECT_RESTART && \ (defined WRITE_WATER && defined MASKING) rv2dgrd(1)=DimIDs(19) rv2dgrd(2)=DimIDs(12) # ifdef SOLVE3D rv3dgrd(1)=DimIDs(22) rv3dgrd(2)=DimIDs(12) # endif # else rv2dgrd(1)=DimIDs( 3) rv2dgrd(2)=DimIDs( 7) rv2dgrd(3)=DimIDs(30) rv2dgrd(4)=DimIDs(12) # ifdef SOLVE3D rv3dgrd(1)=DimIDs( 3) rv3dgrd(2)=DimIDs( 7) rv3dgrd(3)=DimIDs(10) rv3dgrd(4)=DimIDs(30) rv3dgrd(5)=DimIDs(12) # endif # endif # endif # ifdef SOLVE3D ! ! Define dimension vector for staggered w-momentum type variables. ! # if !defined PERFECT_RESTART && \ (defined WRITE_WATER && defined MASKING) w3dgrd(1)=DimIDs(23) w3dgrd(2)=DimIDs(12) # ifdef PERFECT_RESTART k3dgrd(1)=DimIDs(23) k3dgrd(2)=DimIDs(12) # endif # else w3dgrd(1)=DimIDs( 1) w3dgrd(2)=DimIDs( 5) w3dgrd(3)=DimIDs(10) w3dgrd(4)=DimIDs(12) # ifdef PERFECT_RESTART k3dgrd(1)=DimIDs( 1) k3dgrd(2)=DimIDs( 5) k3dgrd(3)=DimIDs(10) k3dgrd(4)=DimIDs(30) k3dgrd(5)=DimIDs(12) # endif # endif # endif ! ! Define dimension vector for sediment, radiation stress variables. ! # if !defined PERFECT_RESTART && \ (defined WRITE_WATER && defined MASKING) su2dgrd(1)=DimIDs(18) su2dgrd(2)=DimIDs(12) sv2dgrd(1)=DimIDs(19) sv2dgrd(2)=DimIDs(12) # else su2dgrd(1)=DimIDs( 2) su2dgrd(2)=DimIDs( 6) su2dgrd(3)=DimIDs(12) sv2dgrd(1)=DimIDs( 3) sv2dgrd(2)=DimIDs( 7) sv2dgrd(3)=DimIDs(12) # endif # ifdef SOLVE3D # if !defined PERFECT_RESTART && \ (defined WRITE_WATER && defined MASKING) sr3dgrd(1)=DimIDs(24) sr3dgrd(2)=DimIDs(12) su3dgrd(1)=DimIDs(21) su3dgrd(2)=DimIDs(12) sv3dgrd(1)=DimIDs(22) sv3dgrd(2)=DimIDs(12) # else sr3dgrd(1)=DimIDs( 1) sr3dgrd(2)=DimIDs( 5) sr3dgrd(3)=DimIDs(16) sr3dgrd(4)=DimIDs(12) su3dgrd(1)=DimIDs( 2) su3dgrd(2)=DimIDs( 6) su3dgrd(3)=DimIDs( 9) su3dgrd(4)=DimIDs(12) sv3dgrd(1)=DimIDs( 3) sv3dgrd(2)=DimIDs( 7) sv3dgrd(3)=DimIDs( 9) sv3dgrd(4)=DimIDs(12) # endif # endif ! ! Initialize unlimited time record dimension. ! RST(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, RST(ng)%pioFile, ncname, DimIDs) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN ! !----------------------------------------------------------------------- ! Define time-varying variables. !----------------------------------------------------------------------- # ifdef PERFECT_RESTART ! ! Define time-stepping indices. ! # ifdef SOLVE3D Vinfo( 1)='nstp' Vinfo( 2)='3D equations time level index, nstp' status=def_var(ng, model, RST(ng)%pioFile, varDesc, PIO_int, & & 1, (/recdim/), Aval, Vinfo, ncname, & & SetParAccess = .TRUE.) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN ! Vinfo( 1)='nrhs' Vinfo( 2)='3D equations time level index, nrhs' status=def_var(ng, model, RST(ng)%pioFile, varDesc, PIO_int, & & 1, (/recdim/), Aval, Vinfo, ncname, & & SetParAccess = .TRUE.) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN ! Vinfo( 1)='nnew' Vinfo( 2)='3D equations time level index, nnew' status=def_var(ng, model, RST(ng)%pioFile, varDesc, PIO_int, & & 1, (/recdim/), Aval, Vinfo, ncname, & & SetParAccess = .TRUE.) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN ! # endif Vinfo( 1)='kstp' Vinfo( 2)='3D equations time level index, kstp' status=def_var(ng, model, RST(ng)%pioFile, varDesc, PIO_int, & & 1, (/recdim/), Aval, Vinfo, ncname, & & SetParAccess = .TRUE.) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN ! Vinfo( 1)='krhs' Vinfo( 2)='3D equations time level index, krhs' status=def_var(ng, model, RST(ng)%pioFile, varDesc, PIO_int, & & 1, (/recdim/), Aval, Vinfo, ncname, & & SetParAccess = .TRUE.) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN ! Vinfo( 1)='knew' Vinfo( 2)='3D equations time level index, knew' status=def_var(ng, model, RST(ng)%pioFile, varDesc, PIO_int, & & 1, (/recdim/), Aval, Vinfo, ncname, & & SetParAccess = .TRUE.) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN # endif ! ! 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) RST(ng)%pioVar(idtime)%dkind=PIO_TOUT RST(ng)%pioVar(idtime)%gtype=0 ! status=def_var(ng, model, RST(ng)%pioFile, & & RST(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) RST(ng)%pioVar(idPwet)%dkind=PIO_FRST RST(ng)%pioVar(idPwet)%gtype=p2dvar ! status=def_var(ng, model, RST(ng)%pioFile, & & RST(ng)%pioVar(idPwet)%vd, & & PIO_FRST, 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) RST(ng)%pioVar(idRwet)%dkind=PIO_FRST RST(ng)%pioVar(idRwet)%gtype=r2dvar ! status=def_var(ng, model, RST(ng)%pioFile, & & RST(ng)%pioVar(idRwet)%vd, & & PIO_FRST, nvd3, sr2dgrd, 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) RST(ng)%pioVar(idUwet)%dkind=PIO_FRST RST(ng)%pioVar(idUwet)%gtype=u2dvar ! status=def_var(ng, model, RST(ng)%pioFile, & & RST(ng)%pioVar(idUwet)%vd, & & PIO_FRST, nvd3, su2dgrd, 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) RST(ng)%pioVar(idVwet)%dkind=PIO_FRST RST(ng)%pioVar(idVwet)%gtype=v2dvar ! status=def_var(ng, model, RST(ng)%pioFile, & & RST(ng)%pioVar(idVwet)%vd, & & PIO_FRST, nvd3, sv2dgrd, Aval, Vinfo, ncname, & & SetFillVal = .FALSE.) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN # endif # if defined SEDIMENT && defined SED_MORPH ! ! Define time-varying bathymetry. ! Vinfo( 1)=Vname(1,idbath) Vinfo( 2)=Vname(2,idbath) Vinfo( 3)=Vname(3,idbath) Vinfo(14)=Vname(4,idbath) Vinfo(16)=Vname(1,idtime) Vinfo(21)=Vname(6,idbath) Vinfo(22)='coordinates' Aval(5)=REAL(Iinfo(1,idbath,ng),r8) RST(ng)%pioVar(idbath)%dkind=PIO_FRST RST(ng)%pioVar(idbath)%gtype=r2dvar ! status=def_var(ng, model, RST(ng)%pioFile, & & RST(ng)%pioVar(idbath)%vd, & & PIO_FRST, nvd3, t2dgrd, Aval, Vinfo, ncname, & & SetFillVal = .FALSE.) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN # endif ! ! 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) # if defined WRITE_WATER && defined MASKING # if !defined WET_DRY && defined PERFECT_RESTART Vinfo(24)='_FillValue' Aval(6)=spval # else Vinfo(20)='mask_rho' # endif # endif Vinfo(21)=Vname(6,idFsur) Vinfo(22)='coordinates' Aval(5)=REAL(Iinfo(1,idFsur,ng),r8) RST(ng)%pioVar(idFsur)%dkind=PIO_FRST RST(ng)%pioVar(idFsur)%gtype=r2dvar ! # ifdef PERFECT_RESTART status=def_var(ng, model, RST(ng)%pioFile, & & RST(ng)%pioVar(idFsur)%vd, & # ifdef WET_DRY & PIO_FRST, nvd4, t2dgrd, Aval, Vinfo, ncname, & & SetFillVal = .FALSE.) # else & PIO_FRST, nvd4, t2dgrd, Aval, Vinfo, ncname) # endif # else status=def_var(ng, model, RST(ng)%pioFile, & & RST(ng)%pioVar(idFsur)%vd, & # ifdef WET_DRY & PIO_FRST, nvd3, t2dgrd, Aval, Vinfo, ncname, & & SetFillVal = .FALSE.) # else & PIO_FRST, nvd3, t2dgrd, Aval, Vinfo, ncname) # endif # endif IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN # ifdef PERFECT_RESTART ! ! Define RHS of free-surface equation. ! Vinfo( 1)=Vname(1,idRzet) Vinfo( 2)=Vname(2,idRzet) Vinfo( 3)=Vname(3,idRzet) Vinfo(14)=Vname(4,idRzet) Vinfo(16)=Vname(1,idtime) # if defined WRITE_WATER && defined MASKING # if defined PERFECT_RESTART Vinfo(24)='_FillValue' Aval(6)=spval # else Vinfo(20)='mask_rho' # endif # endif Vinfo(21)=Vname(6,idRzet) Vinfo(22)='coordinates' Aval(5)=REAL(Iinfo(1,idFsur,ng),r8) RST(ng)%pioVar(idRzet)%dkind=PIO_FRST RST(ng)%pioVar(idRzet)%gtype=r2dvar ! status=def_var(ng, model, RST(ng)%pioFile, & & RST(ng)%pioVar(idRzet)%vd, & & PIO_FRST, nvd4, r2dgrd, Aval, Vinfo, ncname) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN # endif ! ! 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) # if defined WRITE_WATER && defined MASKING # if defined PERFECT_RESTART Vinfo(24)='_FillValue' Aval(6)=spval # else Vinfo(20)='mask_u' # endif # endif Vinfo(21)=Vname(6,idUbar) Vinfo(22)='coordinates' Aval(5)=REAL(Iinfo(1,idUbar,ng),r8) RST(ng)%pioVar(idUbar)%dkind=PIO_FRST RST(ng)%pioVar(idUbar)%gtype=u2dvar ! # ifdef PERFECT_RESTART status=def_var(ng, model, RST(ng)%pioFile, & & RST(ng)%pioVar(idUbar)%vd, & & PIO_FRST, nvd4, u2dgrd, Aval, Vinfo, ncname) # else status=def_var(ng, model, RST(ng)%pioFile, & & RST(ng)%pioVar(idUbar)%vd, & & PIO_FRST, nvd3, u2dgrd, Aval, Vinfo, ncname) # endif IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN # ifdef PERFECT_RESTART ! ! Define RHS of 2D momentum equation in the XI-direction. ! Vinfo( 1)=Vname(1,idRu2d) Vinfo( 2)=Vname(2,idRu2d) Vinfo( 3)=Vname(3,idRu2d) Vinfo(14)=Vname(4,idRu2d) Vinfo(16)=Vname(1,idtime) # if defined WRITE_WATER && defined MASKING # if defined PERFECT_RESTART Vinfo(24)='_FillValue' Aval(6)=spval # else Vinfo(20)='mask_u' # endif # endif Vinfo(21)=Vname(6,idRu2d) Vinfo(22)='coordinates' Aval(5)=REAL(Iinfo(1,idRu2d,ng),r8) RST(ng)%pioVar(idRu2d)%dkind=PIO_FRST RST(ng)%pioVar(idRu2d)%gtype=u2dvar ! status=def_var(ng, model, RST(ng)%pioFile, & & RST(ng)%pioVar(idRu2d)%vd, & & PIO_FRST, nvd4, ru2dgrd, Aval, Vinfo, ncname) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN # endif ! ! 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) # if defined WRITE_WATER && defined MASKING # if defined PERFECT_RESTART Vinfo(24)='_FillValue' Aval(6)=spval # else Vinfo(20)='mask_v' # endif # endif Vinfo(21)=Vname(6,idVbar) Vinfo(22)='coordinates' Aval(5)=REAL(Iinfo(1,idVbar,ng),r8) RST(ng)%pioVar(idVbar)%dkind=PIO_FRST RST(ng)%pioVar(idVbar)%gtype=v2dvar ! # ifdef PERFECT_RESTART status=def_var(ng, model, RST(ng)%pioFile, & & RST(ng)%pioVar(idVbar)%vd, & & PIO_FRST, nvd4, v2dgrd, Aval, Vinfo, ncname) # else status=def_var(ng, model, RST(ng)%pioFile, & & RST(ng)%pioVar(idVbar)%vd, & & PIO_FRST, nvd3, v2dgrd, Aval, Vinfo, ncname) # endif IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN # ifdef PERFECT_RESTART ! ! Define RHS of 2D momentum equation in the ETA-direction. ! Vinfo( 1)=Vname(1,idRv2d) Vinfo( 2)=Vname(2,idRv2d) Vinfo( 3)=Vname(3,idRv2d) Vinfo(14)=Vname(4,idRv2d) Vinfo(16)=Vname(1,idtime) # if defined WRITE_WATER && defined MASKING # if defined PERFECT_RESTART Vinfo(24)='_FillValue' Aval(6)=spval # else Vinfo(20)='mask_v' # endif # endif Vinfo(21)=Vname(6,idRv2d) Vinfo(22)='coordinates' Aval(5)=REAL(Iinfo(1,idRv2d,ng),r8) RST(ng)%pioVar(idRv2d)%dkind=PIO_FRST RST(ng)%pioVar(idRv2d)%gtype=v2dvar ! status=def_var(ng, model, RST(ng)%pioFile, & & RST(ng)%pioVar(idRv2d)%vd, & & PIO_FRST, nvd4, rv2dgrd, Aval, Vinfo, ncname) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN # endif # 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) # if defined WRITE_WATER && defined MASKING # if defined PERFECT_RESTART Vinfo(24)='_FillValue' Aval(6)=spval # else Vinfo(20)='mask_u' # endif # endif Vinfo(21)=Vname(6,idUvel) Vinfo(22)='coordinates' Aval(5)=REAL(Iinfo(1,idUvel,ng),r8) RST(ng)%pioVar(idUvel)%dkind=PIO_FRST RST(ng)%pioVar(idUvel)%gtype=u3dvar ! # ifdef PERFECT_RESTART status=def_var(ng, model, RST(ng)%pioFile, & & RST(ng)%pioVar(idUvel)%vd, & & PIO_FRST, nvd5, u3dgrd, Aval, Vinfo, ncname) # else status=def_var(ng, model, RST(ng)%pioFile, & & RST(ng)%pioVar(idUvel)%vd, & & PIO_FRST, nvd4, u3dgrd, Aval, Vinfo, ncname) # endif IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN # ifdef PERFECT_RESTART ! ! Define RHS of 3D momentum equation in the XI-direction. ! Although this variable is a U-points, a negative value is used ! here to set "s_w" in the "coordinate" attribute. The k=0 index ! is used during coupling in step2d. ! Vinfo( 1)=Vname(1,idRu3d) Vinfo( 2)=Vname(2,idRu3d) Vinfo( 3)=Vname(3,idRu3d) Vinfo(14)=Vname(4,idRu3d) Vinfo(16)=Vname(1,idtime) # if defined WRITE_WATER && defined MASKING # if defined PERFECT_RESTART Vinfo(24)='_FillValue' Aval(6)=spval # else Vinfo(20)='mask_u' # endif # endif Vinfo(21)=Vname(6,idRu3d) Vinfo(22)='coordinates' Aval(5)=REAL(-u3dvar,r8) RST(ng)%pioVar(idRu3d)%dkind=PIO_FRST RST(ng)%pioVar(idRu3d)%gtype=u3dvar ! status=def_var(ng, model, RST(ng)%pioFile, & & RST(ng)%pioVar(idRu3d)%vd, & & PIO_FRST, nvd5, ru3dgrd, Aval, Vinfo, ncname) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN # endif ! ! 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) # if defined WRITE_WATER && defined MASKING # if defined PERFECT_RESTART Vinfo(24)='_FillValue' Aval(6)=spval # else Vinfo(20)='mask_v' # endif # endif Vinfo(21)=Vname(6,idVvel) Vinfo(22)='coordinates' Aval(5)=REAL(Iinfo(1,idVvel,ng),r8) RST(ng)%pioVar(idVvel)%dkind=PIO_FRST RST(ng)%pioVar(idVvel)%gtype=v3dvar ! # ifdef PERFECT_RESTART status=def_var(ng, model, RST(ng)%pioFile, & & RST(ng)%pioVar(idVvel)%vd, & & PIO_FRST, nvd5, v3dgrd, Aval, Vinfo, ncname) # else status=def_var(ng, model, RST(ng)%pioFile, & & RST(ng)%pioVar(idVvel)%vd, & & PIO_FRST, nvd4, v3dgrd, Aval, Vinfo, ncname) # endif IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN # ifdef PERFECT_RESTART ! ! Define RHS of 3D momentum equation in the ETA-direction. ! Although this variable is a V-points, a negative value is used ! here to set "s_w" in the "coordinate" attribute. The k=0 index ! is used during coupling in step2d. ! Vinfo( 1)=Vname(1,idRv3d) Vinfo( 2)=Vname(2,idRv3d) Vinfo( 3)=Vname(3,idRv3d) Vinfo(14)=Vname(4,idRv3d) Vinfo(16)=Vname(1,idtime) # if defined WRITE_WATER && defined MASKING # if defined PERFECT_RESTART Vinfo(24)='_FillValue' Aval(6)=spval # else Vinfo(20)='mask_v' # endif # endif Vinfo(21)=Vname(6,idRv3d) Vinfo(22)='coordinates' Aval(5)=REAL(-v3dvar,r8) RST(ng)%pioVar(idRv3d)%dkind=PIO_FRST RST(ng)%pioVar(idRv3d)%gtype=v3dvar ! status=def_var(ng, model, RST(ng)%pioFile, & & RST(ng)%pioVar(idRv3d)%vd, & & PIO_FRST, nvd5, rv3dgrd, Aval, Vinfo, ncname) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN # endif ! ! 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),40) 1000.0_r8*Sd50(i,ng) END IF END DO # endif # if defined WRITE_WATER && defined MASKING # if defined PERFECT_RESTART Vinfo(24)='_FillValue' Aval(6)=spval # else Vinfo(20)='mask_rho' # endif # endif Vinfo(21)=Vname(6,idTvar(itrc)) Vinfo(22)='coordinates' Aval(5)=REAL(r3dvar,r8) RST(ng)%pioTrc(itrc)%dkind=PIO_FRST RST(ng)%pioTrc(itrc)%gtype=r3dvar ! # ifdef PERFECT_RESTART status=def_var(ng, model, RST(ng)%pioFile, & & RST(ng)%pioTrc(itrc)%vd, & & PIO_FRST, nvd5, t3dgrd, Aval, Vinfo, ncname) # else status=def_var(ng, model, RST(ng)%pioFile, & & RST(ng)%pioTrc(itrc)%vd, & & PIO_FRST, nvd4, t3dgrd, Aval, Vinfo, ncname) # endif IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN END DO ! ! Define density anomaly. ! 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 # if defined PERFECT_RESTART Vinfo(24)='_FillValue' Aval(6)=spval # else Vinfo(20)='mask_rho' # endif # endif Vinfo(21)=Vname(6,idDano) Vinfo(22)='coordinates' Aval(5)=REAL(Iinfo(1,idDano,ng),r8) RST(ng)%pioVar(idDano)%dkind=PIO_FRST RST(ng)%pioVar(idDano)%gtype=r3dvar ! status=def_var(ng, model, RST(ng)%pioFile, & & RST(ng)%pioVar(idDano)%vd, & & PIO_FRST, nvd4, r3dgrd, Aval, Vinfo, ncname) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN # ifdef LMD_SKPP ! ! Define depth of surface boundary layer. ! 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 # if defined PERFECT_RESTART Vinfo(24)='_FillValue' Aval(6)=spval # else Vinfo(20)='mask_rho' # endif # endif Vinfo(21)=Vname(6,idHsbl) Vinfo(22)='coordinates' Aval(5)=REAL(Iinfo(1,idHsbl,ng),r8) RST(ng)%pioVar(idHsbl)%dkind=PIO_FRST RST(ng)%pioVar(idHsbl)%gtype=r2dvar ! status=def_var(ng, model, RST(ng)%pioFile, & & RST(ng)%pioVar(idHsbl)%vd, & & PIO_FRST, nvd3, sr2dgrd, Aval, Vinfo, ncname) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN # endif # ifdef LMD_BKPP ! ! Define depth of bottom boundary layer. ! 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 # if defined PERFECT_RESTART Vinfo(24)='_FillValue' Aval(6)=spval # else Vinfo(20)='mask_rho' # endif # endif Vinfo(21)=Vname(6,idHbbl) Vinfo(22)='coordinates' Aval(5)=REAL(Iinfo(1,idHbbl,ng),r8) RST(ng)%pioVar(idHbbl)%dkind=PIO_FRST RST(ng)%pioVar(idHbbl)%gtype=r2dvar ! status=def_var(ng, model, RST(ng)%pioFile, & & RST(ng)%pioVar(idHbbl)%vd, & & PIO_FRST, nvd3, sr2dgrd, Aval, Vinfo, ncname) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN # endif # if defined PERFECT_RESTART && defined LMD_NONLOCAL ! ! Define out KPP nonlocal transport. ! DO itrc=1,NAT Vinfo( 1)=Vname(1,idGhat(itrc)) Vinfo( 2)=Vname(2,idGhat(itrc)) Vinfo( 3)=Vname(3,idGhat(itrc)) Vinfo(14)=Vname(4,idGhat(itrc)) Vinfo(16)=Vname(1,idtime) # if defined WRITE_WATER && defined MASKING Vinfo(20)='mask_rho' # endif Vinfo(21)=Vname(6,idGhat(itrc)) Vinfo(22)='coordinates' Aval(5)=REAL(Iinfo(1,idGhat(itrc),ng),r8) RST(ng)%pioVar(idGhat(itrc))%dkind=PIO_FRST RST(ng)%pioVar(idGhat(itrc))%gtype=w3dvar ! status=def_var(ng, model, RST(ng)%pioFile, & & RST(ng)%pioVar(idGhat(itrc))%vd, & & PIO_FRST, nvd4, w3dgrd, Aval, Vinfo, ncname) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN END DO # endif # if defined BVF_MIXING || defined LMD_MIXING || \ defined GLS_MIXING || defined MY25_MIXING ! ! 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(21)=Vname(6,idVvis) Vinfo(22)='coordinates' Aval(5)=REAL(Iinfo(1,idVvis,ng),r8) RST(ng)%pioVar(idVvis)%dkind=PIO_FRST RST(ng)%pioVar(idVvis)%gtype=w3dvar ! status=def_var(ng, model, RST(ng)%pioFile, & & RST(ng)%pioVar(idVvis)%vd, & & PIO_FRST, nvd4, w3dgrd, Aval, Vinfo, ncname, & & SetFillVal = .FALSE.) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) 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(21)=Vname(6,idTdif) Vinfo(22)='coordinates' Aval(5)=REAL(Iinfo(1,idTdif,ng),r8) RST(ng)%pioVar(idTdif)%dkind=PIO_FRST RST(ng)%pioVar(idTdif)%gtype=w3dvar ! status=def_var(ng, model, RST(ng)%pioFile, & & RST(ng)%pioVar(idTdif)%vd, & & PIO_FRST, nvd4, w3dgrd, Aval, Vinfo, ncname, & & SetFillVal = .FALSE.) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) 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(21)=Vname(6,idSdif) Vinfo(22)='coordinates' Aval(5)=REAL(Iinfo(1,idSdif,ng),r8) RST(ng)%pioVar(idSdif)%dkind=PIO_FRST RST(ng)%pioVar(idSdif)%gtype=w3dvar ! status=def_var(ng, model, RST(ng)%pioFile, & & RST(ng)%pioVar(idSdif)%vd, & & PIO_FRST, nvd4, w3dgrd, Aval, Vinfo, ncname, & & SetFillVal = .FALSE.) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN # endif # endif # if defined PERFECT_RESTART && \ (defined GLS_MIXING || defined MY25_MIXING) ! ! Define turbulent kinetic energy. ! 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) Vinfo(21)=Vname(6,idMtke) Vinfo(22)='coordinates' Aval(5)=REAL(Iinfo(1,idMtke,ng),r8) RST(ng)%pioVar(idMtke)%dkind=PIO_FRST RST(ng)%pioVar(idMtke)%gtype=w3dvar ! status=def_var(ng, model, RST(ng)%pioFile, & & RST(ng)%pioVar(idMtke)%vd, & & PIO_FRST, nvd5, k3dgrd, Aval, Vinfo, ncname, & & SetFillVal = .FALSE.) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN ! ! Define turbulent kinetic energy time length scale. ! 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) Vinfo(21)=Vname(6,idMtls) Vinfo(22)='coordinates' Aval(5)=REAL(Iinfo(1,idMtls,ng),r8) RST(ng)%pioVar(idMtls)%dkind=PIO_FRST RST(ng)%pioVar(idMtls)%gtype=w3dvar ! status=def_var(ng, model, RST(ng)%pioFile, & & RST(ng)%pioVar(idMtls)%vd, & & PIO_FRST, nvd5, k3dgrd, Aval, Vinfo, ncname, & & SetFillVal = .FALSE.) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN ! ! Define vertical mixing turbulent length scale. ! Vinfo( 1)=Vname(1,idVmLS) Vinfo( 2)=Vname(2,idVmLS) Vinfo( 3)=Vname(3,idVmLS) Vinfo(14)=Vname(4,idVmLS) Vinfo(16)=Vname(1,idtime) # if defined WRITE_WATER && defined MASKING # if defined PERFECT_RESTART Vinfo(24)='_FillValue' Aval(6)=spval # else Vinfo(20)='mask_rho' # endif # endif Vinfo(21)=Vname(6,idVmLS) Vinfo(22)='coordinates' Aval(5)=REAL(Iinfo(1,idVmLS,ng),r8) RST(ng)%pioVar(idVmLS)%dkind=PIO_FRST RST(ng)%pioVar(idVmLS)%gtype=w3dvar ! status=def_var(ng, model, RST(ng)%pioFile, & & RST(ng)%pioVar(idVmLS)%vd, & & PIO_FRST, nvd4, w3dgrd, Aval, Vinfo, ncname) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN ! ! Define turbulent kinetic energy vertical diffusion coefficient. ! Vinfo( 1)=Vname(1,idVmKK) Vinfo( 2)=Vname(2,idVmKK) Vinfo( 3)=Vname(3,idVmKK) Vinfo(14)=Vname(4,idVmKK) Vinfo(16)=Vname(1,idtime) # if defined WRITE_WATER && defined MASKING # if defined PERFECT_RESTART Vinfo(24)='_FillValue' Aval(6)=spval # else Vinfo(20)='mask_rho' # endif # endif Vinfo(21)=Vname(6,idVmKK) Vinfo(22)='coordinates' Aval(5)=REAL(Iinfo(1,idVmKK,ng),r8) RST(ng)%pioVar(idVmKK)%dkind=PIO_FRST RST(ng)%pioVar(idVmKK)%gtype=w3dvar ! status=def_var(ng, model, RST(ng)%pioFile, & & RST(ng)%pioVar(idVmKK)%vd, & & PIO_FRST, nvd4, w3dgrd, Aval, Vinfo, ncname) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN # ifdef GLS_MIXING ! ! Define turbulent length scale vertical diffusion coefficient. ! Vinfo( 1)=Vname(1,idVmKP) Vinfo( 2)=Vname(2,idVmKP) Vinfo( 3)=Vname(3,idVmKP) Vinfo(14)=Vname(4,idVmKP) Vinfo(16)=Vname(1,idtime) # if defined WRITE_WATER && defined MASKING # if defined PERFECT_RESTART Vinfo(24)='_FillValue' Aval(6)=spval # else Vinfo(20)='mask_rho' # endif # endif Vinfo(21)=Vname(6,idVmKP) Vinfo(22)='coordinates' Aval(5)=REAL(Iinfo(1,idVmKP,ng),r8) RST(ng)%pioVar(idVmKP)%dkind=PIO_FRST RST(ng)%pioVar(idVmKP)%gtype=w3dvar ! status=def_var(ng, model, RST(ng)%pioFile, & & RST(ng)%pioVar(idVmKP)%vd, & & PIO_FRST, nvd4, w3dgrd, Aval, Vinfo, ncname) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN # endif # endif # ifdef SEDIMENT # ifdef BEDLOAD ! ! Define Bedload U-direction. ! DO i=1,NST Vinfo( 1)=Vname(1,idUbld(i)) Vinfo( 2)=Vname(2,idUbld(i)) Vinfo( 3)=Vname(3,idUbld(i)) Vinfo(14)=Vname(4,idUbld(i)) Vinfo(16)=Vname(1,idtime) # if defined WRITE_WATER && defined MASKING # if defined PERFECT_RESTART Vinfo(24)='_FillValue' Aval(6)=spval # else Vinfo(20)='mask_u' # endif # endif Vinfo(21)=Vname(6,idUbld(i)) Vinfo(22)='coordinates' Aval(5)=REAL(Iinfo(1,idUbld(i),ng),r8) RST(ng)%pioVar(idUbld(i))%dkind=PIO_FRST RST(ng)%pioVar(idUbld(i))%gtype=u2dvar ! status=def_var(ng, model, RST(ng)%pioFile, & & RST(ng)%pioVar(idUbld(i))%vd, & & PIO_FRST, nvd3, su2dgrd, Aval, Vinfo, ncname) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN ! ! Define Bedload V-direction. ! Vinfo( 1)=Vname(1,idVbld(i)) Vinfo( 2)=Vname(2,idVbld(i)) Vinfo( 3)=Vname(3,idVbld(i)) Vinfo(14)=Vname(4,idVbld(i)) Vinfo(16)=Vname(1,idtime) # if defined WRITE_WATER && defined MASKING # if defined PERFECT_RESTART Vinfo(24)='_FillValue' Aval(6)=spval # else Vinfo(20)='mask_v' # endif # endif Vinfo(21)=Vname(6,idVbld(i)) Vinfo(22)='coordinates' Aval(5)=REAL(Iinfo(1,idVbld(i),ng),r8) RST(ng)%pioVar(idVbld(i))%dkind=PIO_FRST RST(ng)%pioVar(idVbld(i))%gtype=v2dvar ! status=def_var(ng, model, RST(ng)%pioFile, & & RST(ng)%pioVar(idVbld(i))%vd, & & PIO_FRST, nvd3, sv2dgrd, Aval, Vinfo, ncname) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN END DO # endif ! ! Define sediment fraction of each size class in each bed layer. ! DO i=1,NST Vinfo( 1)=Vname(1,idfrac(i)) Vinfo( 2)=Vname(2,idfrac(i)) Vinfo( 3)=Vname(3,idfrac(i)) Vinfo(14)=Vname(4,idfrac(i)) Vinfo(16)=Vname(1,idtime) WRITE (Vinfo(19),40) 1000.0_r8*Sd50(i,ng) # if defined WRITE_WATER && defined MASKING # if defined PERFECT_RESTART Vinfo(24)='_FillValue' Aval(6)=spval # else Vinfo(20)='mask_rho' # endif # endif Vinfo(21)=Vname(6,idfrac(i)) Vinfo(22)='coordinates' Aval(5)=REAL(Iinfo(1,idfrac(i),ng),r8) RST(ng)%pioVar(idfrac(i))%dkind=PIO_FRST RST(ng)%pioVar(idfrac(i))%gtype=b3dvar ! status=def_var(ng, model, RST(ng)%pioFile, & & RST(ng)%pioVar(idfrac(i))%vd, & & PIO_FRST, nvd4, sr3dgrd, Aval, Vinfo, ncname) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN END DO ! ! Define sediment mass of each size class in each bed layer. ! DO i=1,NST Vinfo( 1)=Vname(1,idBmas(i)) Vinfo( 2)=Vname(2,idBmas(i)) Vinfo( 3)=Vname(3,idBmas(i)) Vinfo(14)=Vname(4,idBmas(i)) Vinfo(16)=Vname(1,idtime) WRITE (Vinfo(19),40) 1000.0_r8*Sd50(i,ng) # if defined WRITE_WATER && defined MASKING # if defined PERFECT_RESTART Vinfo(24)='_FillValue' Aval(6)=spval # else Vinfo(20)='mask_rho' # endif # endif Vinfo(21)=Vname(6,idBmas(i)) Vinfo(22)='coordinates' Aval(5)=REAL(Iinfo(1,idBmas(i),ng),r8) RST(ng)%pioVar(idBmas(i))%dkind=PIO_FRST RST(ng)%pioVar(idBmas(i))%gtype=b3dvar ! status=def_var(ng, model, RST(ng)%pioFile, & & RST(ng)%pioVar(idBmas(i))%vd, & & PIO_FRST, nvd4, sr3dgrd, Aval, Vinfo, ncname) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN END DO ! ! Define sediment properties in each bed layer. ! DO i=1,MBEDP Vinfo( 1)=Vname(1,idSbed(i)) Vinfo( 2)=Vname(2,idSbed(i)) Vinfo( 3)=Vname(3,idSbed(i)) Vinfo(14)=Vname(4,idSbed(i)) Vinfo(16)=Vname(1,idtime) # if defined WRITE_WATER && defined MASKING # if defined PERFECT_RESTART Vinfo(24)='_FillValue' Aval(6)=spval # else Vinfo(20)='mask_rho' # endif # endif Vinfo(21)=Vname(6,idSbed(i)) Vinfo(22)='coordinates' Aval(5)=REAL(Iinfo(1,idSbed(i),ng),r8) RST(ng)%pioVar(idSbed(i))%dkind=PIO_FRST RST(ng)%pioVar(idSbed(i))%gtype=b3dvar ! status=def_var(ng, model, RST(ng)%pioFile, & & RST(ng)%pioVar(idSbed(i))%vd, & & PIO_FRST, nvd4, sr3dgrd, Aval, Vinfo, ncname) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN END DO # endif # if defined SEDIMENT || defined BBL_MODEL ! ! define exposed sediment layer properties. Notice that only the ! first four properties (mean grain diameter, mean grain density, ! mean settling velocity, mean critical erosion stress, ! ripple length and ripple height) are written. ! DO i=1,6 Vinfo( 1)=Vname(1,idBott(i)) Vinfo( 2)=Vname(2,idBott(i)) Vinfo( 3)=Vname(3,idBott(i)) Vinfo(14)=Vname(4,idBott(i)) Vinfo(16)=Vname(1,idtime) # if defined WRITE_WATER && defined MASKING # if defined PERFECT_RESTART Vinfo(24)='_FillValue' Aval(6)=spval # else Vinfo(20)='mask_rho' # endif # endif Vinfo(21)=Vname(6,idBott(i)) Vinfo(22)='coordinates' Aval(5)=REAL(Iinfo(1,idBott(i),ng),r8) RST(ng)%pioVar(idBott(i))%dkind=PIO_FRST RST(ng)%pioVar(idBott(i))%gtype=r2dvar ! status=def_var(ng, model, RST(ng)%pioFile, & & RST(ng)%pioVar(idBott(i))%vd, & & PIO_FRST, nvd3, sr2dgrd, Aval, Vinfo, ncname) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN END DO # endif # endif # ifdef WEC ! ! Define 2D Stokes U-velocity. ! Vinfo( 1)=Vname(1,idU2Sd) Vinfo( 2)=Vname(2,idU2Sd) Vinfo( 3)=Vname(3,idU2Sd) Vinfo(14)=Vname(4,idU2Sd) Vinfo(16)=Vname(1,idtime) # if defined WRITE_WATER && defined MASKING Vinfo(20)='mask_u' # endif Vinfo(21)=Vname(6,idU2Sd) Vinfo(22)='coordinates' Aval(5)=REAL(Iinfo(1,idU2Sd,ng),r8) RST(ng)%pioVar(idU2Sd)%dkind=PIO_FRST RST(ng)%pioVar(idU2Sd)%gtype=u2dvar ! status=def_var(ng, model, RST(ng)%pioFile, & & RST(ng)%pioVar(idU2Sd)%vd, & & PIO_FRST, nvd3, u2dgrd, Aval, Vinfo, ncname) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN ! ! Define 2D Stokes V-velocity. ! Vinfo( 1)=Vname(1,idV2Sd) Vinfo( 2)=Vname(2,idV2Sd) Vinfo( 3)=Vname(3,idV2Sd) Vinfo(14)=Vname(4,idV2Sd) Vinfo(16)=Vname(1,idtime) # if defined WRITE_WATER && defined MASKING Vinfo(20)='mask_u' # endif Vinfo(21)=Vname(6,idV2Sd) Vinfo(22)='coordinates' Aval(5)=REAL(Iinfo(1,idV2Sd,ng),r8) RST(ng)%pioVar(idV2Sd)%dkind=PIO_FRST RST(ng)%pioVar(idV2Sd)%gtype=v2dvar ! status=def_var(ng, model, RST(ng)%pioFile, & & RST(ng)%pioVar(idV2Sd)%vd, & & PIO_FRST, nvd3, u2dgrd, Aval, Vinfo, ncname) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN # ifdef SOLVE3D ! ! Define 3D Stokes U-velocity. ! Vinfo( 1)=Vname(1,idU3Sd) Vinfo( 2)=Vname(2,idU3Sd) Vinfo( 3)=Vname(3,idU3Sd) Vinfo(14)=Vname(4,idU3Sd) Vinfo(16)=Vname(1,idtime) # if defined WRITE_WATER && defined MASKING Vinfo(20)='mask_u' # endif Vinfo(21)=Vname(6,idU3Sd) Vinfo(22)='coordinates' Aval(5)=REAL(Iinfo(1,idU3Sd,ng),r8) RST(ng)%pioVar(idU3Sd)%dkind=PIO_FOUT RST(ng)%pioVar(idU3Sd)%gtype=u3dvar ! status=def_var(ng, model, RST(ng)%pioFile, & & RST(ng)%pioVar(idU3Sd)%vd, & & PIO_FRST, nvd4, u3dgrd, Aval, Vinfo, ncname) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN ! ! Define 3D Stokes V-velocity. ! Vinfo( 1)=Vname(1,idV3Sd) Vinfo( 2)=Vname(2,idV3Sd) Vinfo( 3)=Vname(3,idV3Sd) Vinfo(14)=Vname(4,idV3Sd) Vinfo(16)=Vname(1,idtime) # if defined WRITE_WATER && defined MASKING Vinfo(20)='mask_v' # endif Vinfo(21)=Vname(6,idV3Sd) Vinfo(22)='coordinates' Aval(5)=REAL(Iinfo(1,idV3Sd,ng),r8) RST(ng)%pioVar(idV3Sd)%dkind=PIO_FRST RST(ng)%pioVar(idV3Sd)%gtype=v3dvar ! status=def_var(ng, model, RST(ng)%pioFile, & & RST(ng)%pioVar(idV3Sd)%vd, & & PIO_FRST, nvd4, v3dgrd, Aval, Vinfo, ncname) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN END IF # endif # endif # ifdef ICE_MODEL ! !----------------------------------------------------------------------- ! Define sea-ice model variables. !----------------------------------------------------------------------- ! CALL ice_def_pio (ng, model, Ldefine, Hout, RST, & & t2dgrd, u2dgrd, v2dgrd) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN # endif ! !----------------------------------------------------------------------- ! Leave definition mode. !----------------------------------------------------------------------- ! CALL pio_netcdf_enddef (ng, model, ncname, RST(ng)%pioFile) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN ! !----------------------------------------------------------------------- ! Write out time-recordless, information variables. !----------------------------------------------------------------------- ! CALL wrt_info (ng, model, RST(ng)%pioFile, ncname) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN END IF DEFINE ! !======================================================================= ! Open an existing restart file, check its contents, and prepare for ! appending data. !======================================================================= ! QUERY : IF (.not.Ldefine) THEN ncname=RST(ng)%name ! ! Open restart file for read/write. ! CALL pio_netcdf_open (ng, model, ncname, 1, RST(ng)%pioFile) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) THEN WRITE (stdout,50) TRIM(ncname) RETURN END IF ! ! Inquire about the dimensions and check for consistency. ! CALL pio_netcdf_check_dim (ng, model, ncname, & & pioFile = RST(ng)%pioFile) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN ! ! Inquire about the variables. ! CALL pio_netcdf_inq_var (ng, model, ncname, & & pioFile = RST(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 ! 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. RST(ng)%pioVar(idtime)%vd=var_desc(i) RST(ng)%pioVar(idtime)%dkind=PIO_TOUT RST(ng)%pioVar(idtime)%gtype=0 # if defined SEDIMENT && defined SED_MORPH ELSE IF (TRIM(var_name(i)).eq.TRIM(Vname(1,idbath))) THEN got_var(idbath)=.TRUE. RST(ng)%pioVar(idbath)%vd=var_desc(i) RST(ng)%pioVar(idbath)%dkind=PIO_FRST RST(ng)%pioVar(idbath)%gtype=r2dvar # endif # if defined WET_DRY ELSE IF (TRIM(var_name(i)).eq.TRIM(Vname(1,idRwet))) THEN got_var(idRwet)=.TRUE. RST(ng)%pioVar(idRwet)%vd=var_desc(i) RST(ng)%pioVar(idRwet)%dkind=PIO_FRST RST(ng)%pioVar(idRwet)%gtype=r2dvar ELSE IF (TRIM(var_name(i)).eq.TRIM(Vname(1,idUwet))) THEN got_var(idUwet)=.TRUE. RST(ng)%pioVar(idUwet)%vd=var_desc(i) RST(ng)%pioVar(idUwet)%dkind=PIO_FRST RST(ng)%pioVar(idUwet)%gtype=u2dvar ELSE IF (TRIM(var_name(i)).eq.TRIM(Vname(1,idVwet))) THEN got_var(idVwet)=.TRUE. RST(ng)%pioVar(idVwet)%vd=var_desc(i) RST(ng)%pioVar(idVwet)%dkind=PIO_FRST RST(ng)%pioVar(idVwet)%gtype=v2dvar ELSE IF (TRIM(var_name(i)).eq.TRIM(Vname(1,idPwet))) THEN got_var(idPwet)=.TRUE. RST(ng)%pioVar(idPwet)%vd=var_desc(i) RST(ng)%pioVar(idPwet)%dkind=PIO_FRST RST(ng)%pioVar(idPwet)%gtype=p2dvar # endif ELSE IF (TRIM(var_name(i)).eq.TRIM(Vname(1,idFsur))) THEN got_var(idFsur)=.TRUE. RST(ng)%pioVar(idFsur)%vd=var_desc(i) RST(ng)%pioVar(idFsur)%dkind=PIO_FRST RST(ng)%pioVar(idFsur)%gtype=r2dvar # ifdef PERFECT_RESTART ELSE IF (TRIM(var_name(i)).eq.TRIM(Vname(1,idRzet))) THEN got_var(idRzet)=.TRUE. RST(ng)%pioVar(idRzet)%vd=var_desc(i) RST(ng)%pioVar(idRzet)%dkind=PIO_FRST RST(ng)%pioVar(idRzet)%gtype=r2dvar # endif ELSE IF (TRIM(var_name(i)).eq.TRIM(Vname(1,idUbar))) THEN got_var(idUbar)=.TRUE. RST(ng)%pioVar(idUbar)%vd=var_desc(i) RST(ng)%pioVar(idUbar)%dkind=PIO_FRST RST(ng)%pioVar(idUbar)%gtype=u2dvar # ifdef PERFECT_RESTART ELSE IF (TRIM(var_name(i)).eq.TRIM(Vname(1,idRu2d))) THEN got_var(idRu2d)=.TRUE. RST(ng)%pioVar(idRu2d)%vd=var_desc(i) RST(ng)%pioVar(idRu2d)%dkind=PIO_FRST RST(ng)%pioVar(idRu2d)%gtype=u2dvar # endif ELSE IF (TRIM(var_name(i)).eq.TRIM(Vname(1,idVbar))) THEN got_var(idVbar)=.TRUE. RST(ng)%pioVar(idVbar)%vd=var_desc(i) RST(ng)%pioVar(idVbar)%dkind=PIO_FRST RST(ng)%pioVar(idVbar)%gtype=v2dvar # ifdef PERFECT_RESTART ELSE IF (TRIM(var_name(i)).eq.TRIM(Vname(1,idRv2d))) THEN got_var(idRv2d)=.TRUE. RST(ng)%pioVar(idRv2d)%vd=var_desc(i) RST(ng)%pioVar(idRv2d)%dkind=PIO_FRST RST(ng)%pioVar(idRv2d)%gtype=v2dvar # endif # ifdef SOLVE3D ELSE IF (TRIM(var_name(i)).eq.TRIM(Vname(1,idUvel))) THEN got_var(idUvel)=.TRUE. RST(ng)%pioVar(idUvel)%vd=var_desc(i) RST(ng)%pioVar(idUvel)%dkind=PIO_FRST RST(ng)%pioVar(idUvel)%gtype=u3dvar # ifdef PERFECT_RESTART ELSE IF (TRIM(var_name(i)).eq.TRIM(Vname(1,idRu3d))) THEN got_var(idRu3d)=.TRUE. RST(ng)%pioVar(idRu3d)%vd=var_desc(i) RST(ng)%pioVar(idRu3d)%dkind=PIO_FRST RST(ng)%pioVar(idRu3d)%gtype=u3dvar # endif ELSE IF (TRIM(var_name(i)).eq.TRIM(Vname(1,idVvel))) THEN got_var(idVvel)=.TRUE. RST(ng)%pioVar(idVvel)%vd=var_desc(i) RST(ng)%pioVar(idVvel)%dkind=PIO_FRST RST(ng)%pioVar(idVvel)%gtype=v3dvar # ifdef PERFECT_RESTART ELSE IF (TRIM(var_name(i)).eq.TRIM(Vname(1,idRv3d))) THEN got_var(idRv3d)=.TRUE. RST(ng)%pioVar(idRv3d)%vd=var_desc(i) RST(ng)%pioVar(idRv3d)%dkind=PIO_FRST RST(ng)%pioVar(idRv3d)%gtype=v3dvar # endif ELSE IF (TRIM(var_name(i)).eq.TRIM(Vname(1,idDano))) THEN got_var(idDano)=.TRUE. RST(ng)%pioVar(idDano)%vd=var_desc(i) RST(ng)%pioVar(idDano)%dkind=PIO_FRST RST(ng)%pioVar(idDano)%gtype=r3dvar # ifdef LMD_SKPP ELSE IF (TRIM(var_name(i)).eq.TRIM(Vname(1,idHsbl))) THEN got_var(idHsbl)=.TRUE. RST(ng)%pioVar(idHsbl)%vd=var_desc(i) RST(ng)%pioVar(idHsbl)%dkind=PIO_FRST RST(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. RST(ng)%pioVar(idHbbl)%vd=var_desc(i) RST(ng)%pioVar(idHbbl)%dkind=PIO_FRST RST(ng)%pioVar(idHbbl)%gtype=r2dvar # endif # if defined PERFECT_RESTART && defined LMD_NONLOCAL ELSE IF (TRIM(var_name(i)).eq. & & TRIM(Vname(1,idGhat(itemp)))) THEN got_var(idGhat(itemp))=.TRUE. RST(ng)%pioVar(idGhat(itemp))%vd=var_desc(i) RST(ng)%pioVar(idGhat(itemp))%dkind=PIO_FRST RST(ng)%pioVar(idGhat(itemp))%gtype=w3dvar # ifdef SALINITY ELSE IF (TRIM(var_name(i)).eq. & & TRIM(Vname(1,idGhat(isalt)))) THEN got_var(idGhat(isalt))=.TRUE. RST(ng)%pioVar(idGhat(isalt))%vd=var_desc(i) RST(ng)%pioVar(idGhat(isalt))%dkind=PIO_FRST RST(ng)%pioVar(idGhat(isalt))%gtype=w3dvar # endif # endif ELSE IF (TRIM(var_name(i)).eq.TRIM(Vname(1,idVvis))) THEN got_var(idVvis)=.TRUE. RST(ng)%pioVar(idVvis)%vd=var_desc(i) RST(ng)%pioVar(idVvis)%dkind=PIO_FRST RST(ng)%pioVar(idVvis)%gtype=w3dvar ELSE IF (TRIM(var_name(i)).eq.TRIM(Vname(1,idTdif))) THEN got_var(idTdif)=.TRUE. RST(ng)%pioVar(idTdif)%vd=var_desc(i) RST(ng)%pioVar(idTdif)%dkind=PIO_FRST RST(ng)%pioVar(idTdif)%gtype=w3dvar ELSE IF (TRIM(var_name(i)).eq.TRIM(Vname(1,idSdif))) THEN got_var(idSdif)=.TRUE. RST(ng)%pioVar(idSdif)%vd=var_desc(i) RST(ng)%pioVar(idSdif)%dkind=PIO_FRST RST(ng)%pioVar(idSdif)%gtype=w3dvar # if defined PERFECT_RESTART && \ (defined GLS_MIXING || defined MY25_MIXING) ELSE IF (TRIM(var_name(i)).eq.TRIM(Vname(1,idMtke))) THEN got_var(idMtke)=.TRUE. RST(ng)%pioVar(idMtke)%vd=var_desc(i) RST(ng)%pioVar(idMtke)%dkind=PIO_FRST RST(ng)%pioVar(idMtke)%gtype=w3dvar ELSE IF (TRIM(var_name(i)).eq.TRIM(Vname(1,idMtls))) THEN got_var(idMtls)=.TRUE. RST(ng)%pioVar(idMtls)%vd=var_desc(i) RST(ng)%pioVar(idMtls)%dkind=PIO_FRST RST(ng)%pioVar(idMtls)%gtype=w3dvar ELSE IF (TRIM(var_name(i)).eq.TRIM(Vname(1,idVmLS))) THEN got_var(idVmLS)=.TRUE. RST(ng)%pioVar(idVmLS)%vd=var_desc(i) RST(ng)%pioVar(idVmLS)%dkind=PIO_FRST RST(ng)%pioVar(idVmLS)%gtype=w3dvar ELSE IF (TRIM(var_name(i)).eq.TRIM(Vname(1,idVmKK))) THEN got_var(idVmKK)=.TRUE. RST(ng)%pioVar(idVmKK)%vd=var_desc(i) RST(ng)%pioVar(idVmKK)%dkind=PIO_FRST RST(ng)%pioVar(idVmKK)%gtype=w3dvar # ifdef GLS_MIXING ELSE IF (TRIM(var_name(i)).eq.TRIM(Vname(1,idVmKP))) THEN got_var(idVmKP)=.TRUE. RST(ng)%pioVar(idVmKP)%vd=var_desc(i) RST(ng)%pioVar(idVmKP)%dkind=PIO_FRST RST(ng)%pioVar(idVmKP)%gtype=w3dvar # endif # endif # endif # ifdef WEC ELSE IF (TRIM(var_name(i)).eq.TRIM(Vname(1,idU2Sd))) THEN got_var(idU2Sd)=.TRUE. RST(ng)%pioVar(idU2Sd)%vd=var_desc(i) RST(ng)%pioVar(idU2Sd)%dkind=PIO_FRST RST(ng)%pioVar(idU2Sd)%gtype=u2dvar ELSE IF (TRIM(var_name(i)).eq.TRIM(Vname(1,idV2Sd))) THEN got_var(idV2Sd)=.TRUE. RST(ng)%pioVar(idV2rs)%vd=var_desc(i) RST(ng)%pioVar(idV2rs)%dkind=PIO_FRST RST(ng)%pioVar(idV2rs)%gtype=v2dvar # ifdef SOLVE3D ELSE IF (TRIM(var_name(i)).eq.TRIM(Vname(1,idU3Sd))) THEN got_var(idU3Sd)=.TRUE. RST(ng)%pioVar(idU3Sd)%vd=var_desc(i) RST(ng)%pioVar(idU3Sd)%dkind=PIO_FRST RST(ng)%pioVar(idU3Sd)%gtype=u3dvar ELSE IF (TRIM(var_name(i)).eq.TRIM(Vname(1,idV3Sd))) THEN got_var(idV3Sd)=.TRUE. RST(ng)%pioVar(idV3Sd)%vd=var_desc(i) RST(ng)%pioVar(idV3Sd)%dkind=PIO_FRST RST(ng)%pioVar(idV3Sd)%gtype=v3dvar # endif # 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. RST(ng)%pioTrc(itrc)%vd=var_desc(i) RST(ng)%pioTrc(itrc)%dkind=PIO_FRST RST(ng)%pioTrc(itrc)%gtype=r3dvar END IF END DO # ifdef SEDIMENT DO itrc=1,NST IF (TRIM(var_name(i)).eq. & & TRIM(Vname(1,idfrac(itrc)))) THEN got_var(idfrac(itrc))=.TRUE. RST(ng)%pioVar(idfrac(itrc))%vd=var_desc(i) RST(ng)%pioVar(idfrac(itrc))%dkind=PIO_FRST RST(ng)%pioVar(idfrac(itrc))%gtype=b3dvar ELSE IF (TRIM(var_name(i)).eq. & & TRIM(Vname(1,idBmas(itrc)))) THEN got_var(idBmas(itrc))=.TRUE. RST(ng)%pioVar(idBmas(itrc))%vd=var_desc(i) RST(ng)%pioVar(idBmas(itrc))%dkind=PIO_FRST RST(ng)%pioVar(idBmas(itrc))%gtype=b3dvar # ifdef BEDLOAD ELSE IF (TRIM(var_name(i)).eq. & & TRIM(Vname(1,idUbld(itrc)))) THEN got_var(idUbld(itrc))=.true. RST(ng)%pioVar(idUbld(itrc))%vd=var_desc(i) RST(ng)%pioVar(idUbld(itrc))%dkind=PIO_FRST RST(ng)%pioVar(idUbld(itrc))%gtype=u2dvar ELSE IF (TRIM(var_name(i)).eq. & & TRIM(Vname(1,idVbld(itrc)))) THEN got_var(idVbld(itrc))=.true. RST(ng)%pioVar(idVbld(itrc))%vd=var_desc(i) RST(ng)%pioVar(idVbld(itrc))%dkind=PIO_FRST RST(ng)%pioVar(idVbld(itrc))%gtype=v2dvar # endif END IF END DO DO itrc=1,MBEDP IF (TRIM(var_name(i)).eq.TRIM(Vname(1,idSbed(itrc)))) THEN got_var(idSbed(itrc))=.TRUE. RST(ng)%pioVar(idSbed(itrc))%vd=var_desc(i) RST(ng)%pioVar(idSbed(itrc))%dkind=PIO_FRST RST(ng)%pioVar(idSbed(itrc))%gtype=b3dvar END IF END DO # endif # if defined SEDIMENT || defined BBL_MODEL DO itrc=1,6 IF (TRIM(var_name(i)).eq.TRIM(Vname(1,idBott(itrc)))) THEN got_var(idBott(itrc))=.TRUE. RST(ng)%pioVar(idBott(itrc))%vd=var_desc(i) RST(ng)%pioVar(idBott(itrc))%dkind=PIO_FRST RST(ng)%pioVar(idBott(itrc))%gtype=r2dvar END IF END DO # endif # endif END DO ! ! Check if initialization variables are available in input NetCDF ! file. ! IF (.not.got_var(idtime)) THEN IF (Master) WRITE (stdout,60) TRIM(Vname(1,idtime)), & & TRIM(ncname) exit_flag=3 RETURN END IF # if defined SEDIMENT && defined SED_MORPH IF (.not.got_var(idbath)) THEN IF (Master) WRITE (stdout,60) TRIM(Vname(1,idbath)), & & TRIM(ncname) exit_flag=3 RETURN END IF # endif # if defined WET_DRY IF (.not.got_var(idRwet)) THEN IF (Master) WRITE (stdout,60) TRIM(Vname(1,idRwet)), & & TRIM(ncname) exit_flag=3 RETURN END IF IF (.not.got_var(idUwet)) THEN IF (Master) WRITE (stdout,60) TRIM(Vname(1,idUwet)), & & TRIM(ncname) exit_flag=3 RETURN END IF IF (.not.got_var(idVwet)) THEN IF (Master) WRITE (stdout,60) TRIM(Vname(1,idVwet)), & & TRIM(ncname) exit_flag=3 RETURN END IF IF (.not.got_var(idPwet)) THEN IF (Master) WRITE (stdout,60) TRIM(Vname(1,idPwet)), & & TRIM(ncname) exit_flag=3 RETURN END IF # endif IF (.not.got_var(idFsur)) THEN IF (Master) WRITE (stdout,60) TRIM(Vname(1,idFsur)), & & TRIM(ncname) exit_flag=3 RETURN END IF # ifdef PERFECT_RESTART IF (.not.got_var(idRzet)) THEN IF (Master) WRITE (stdout,60) TRIM(Vname(1,idRzet)), & & TRIM(ncname) exit_flag=3 RETURN END IF # endif IF (.not.got_var(idUbar)) THEN IF (Master) WRITE (stdout,60) TRIM(Vname(1,idUbar)), & & TRIM(ncname) exit_flag=3 RETURN END IF # ifdef PERFECT_RESTART IF (.not.got_var(idRu2d)) THEN IF (Master) WRITE (stdout,60) TRIM(Vname(1,idRu2d)), & & TRIM(ncname) exit_flag=3 RETURN END IF # endif IF (.not.got_var(idVbar)) THEN IF (Master) WRITE (stdout,60) TRIM(Vname(1,idVbar)), & & TRIM(ncname) exit_flag=3 RETURN END IF # ifdef PERFECT_RESTART IF (.not.got_var(idRv2d)) THEN IF (Master) WRITE (stdout,60) TRIM(Vname(1,idRv2d)), & & TRIM(ncname) exit_flag=3 RETURN END IF # endif # ifdef SOLVE3D IF (.not.got_var(idUvel)) THEN IF (Master) WRITE (stdout,60) TRIM(Vname(1,idUvel)), & & TRIM(ncname) exit_flag=3 RETURN END IF # ifdef PERFECT_RESTART IF (.not.got_var(idRu3d)) THEN IF (Master) WRITE (stdout,60) TRIM(Vname(1,idRu3d)), & & TRIM(ncname) exit_flag=3 RETURN END IF # endif IF (.not.got_var(idVvel)) THEN IF (Master) WRITE (stdout,60) TRIM(Vname(1,idVvel)), & & TRIM(ncname) exit_flag=3 RETURN END IF # ifdef PERFECT_RESTART IF (.not.got_var(idRv3d)) THEN IF (Master) WRITE (stdout,60) TRIM(Vname(1,idRv3d)), & & TRIM(ncname) exit_flag=3 RETURN END IF # endif IF (.not.got_var(idDano)) THEN IF (Master) WRITE (stdout,60) TRIM(Vname(1,idDano)), & & TRIM(ncname) exit_flag=3 RETURN END IF # if defined PERFECT_RESTART && \ (defined GLS_MIXING || defined MY25_MIXING) IF (.not.got_var(idMtke)) THEN IF (Master) WRITE (stdout,60) TRIM(Vname(1,idMtke)), & & TRIM(ncname) exit_flag=3 RETURN END IF IF (.not.got_var(idMtls)) THEN IF (Master) WRITE (stdout,60) TRIM(Vname(1,idMtls)), & & TRIM(ncname) exit_flag=3 RETURN END IF IF (.not.got_var(idVmLS)) THEN IF (Master) WRITE (stdout,60) TRIM(Vname(1,idVmLS)), & & TRIM(ncname) exit_flag=3 RETURN END IF IF (.not.got_var(idVmKK)) THEN IF (Master) WRITE (stdout,60) TRIM(Vname(1,idVmKK)), & & TRIM(ncname) exit_flag=3 RETURN END IF # ifdef GLS_MIXING IF (.not.got_var(idVmKP)) THEN IF (Master) WRITE (stdout,60) TRIM(Vname(1,idVmKP)), & & TRIM(ncname) exit_flag=3 RETURN END IF # endif # endif # endif # ifdef WEC IF (.not.got_var(idU2Sd)) THEN IF (Master) WRITE (stdout,60) TRIM(Vname(1,idU2Sd)), & & TRIM(ncname) exit_flag=3 RETURN END IF IF (.not.got_var(idV2Sd)) THEN IF (Master) WRITE (stdout,60) TRIM(Vname(1,idV2Sd)), & & TRIM(ncname) exit_flag=3 RETURN END IF # ifdef SOLVE3D IF (.not.got_var(idU3Sd)) THEN IF (Master) WRITE (stdout,60) TRIM(Vname(1,idU3Sd)), & & TRIM(ncname) exit_flag=3 RETURN END IF IF (.not.got_var(idV3Sd)) THEN IF (Master) WRITE (stdout,60) TRIM(Vname(1,idV3Sd)), & & TRIM(ncname) exit_flag=3 RETURN END IF # endif # endif # ifdef SOLVE3D DO itrc=1,NT(ng) IF (.not.got_var(idTvar(itrc))) THEN IF (Master) WRITE (stdout,60) TRIM(Vname(1,idTvar(itrc))), & & TRIM(ncname) exit_flag=3 RETURN END IF END DO # ifdef SEDIMENT DO i=1,NST IF (.not.got_var(idfrac(i))) THEN IF (Master) WRITE (stdout,60) TRIM(Vname(1,idfrac(i))), & & TRIM(ncname) exit_flag=3 RETURN END IF IF (.not.got_var(idBmas(i))) THEN IF (Master) WRITE (stdout,60) TRIM(Vname(1,idBmas(i))), & & TRIM(ncname) exit_flag=3 RETURN END IF # ifdef BEDLOAD IF (.not.got_var(idUbld(i))) THEN IF (Master) WRITE (stdout,60) TRIM(Vname(1,idUbld(i))), & & TRIM(ncname) exit_flag=3 RETURN END IF IF (.not.got_var(idVbld(i))) THEN IF (Master) WRITE (stdout,60) TRIM(Vname(1,idVbld(i))), & & TRIM(ncname) exit_flag=3 RETURN END IF # endif END DO DO i=1,MBEDP IF (.not.got_var(idSbed(i))) THEN IF (Master) WRITE (stdout,60) TRIM(Vname(1,idSbed(i))), & & TRIM(ncname) exit_flag=3 RETURN END IF END DO # endif # if defined SEDIMENT || defined BBL_MODEL DO i=1,6 IF (.not.got_var(idBott(i))) THEN IF (Master) WRITE (stdout,60) TRIM(Vname(1,idBott(i))), & & TRIM(ncname) exit_flag=3 RETURN END IF END DO # endif # endif # ifdef ICE_MODEL ! ! Scan sea-ice variables from input NetCDF and activate switches for ! restart variables. Get variable IDs. ! CALL ice_def_pio (ng, model, Ldefine, Hout, RST) # endif ! ! Set unlimited time record dimension to current value. ! IF (LcycleRST(ng)) THEN RST(ng)%Rindex=0 ELSE RST(ng)%Rindex=rec_size END IF END IF QUERY ! 10 FORMAT (2x,'DEF_RST_PIO - creating restart file,',t56, & & 'Grid ',i2.2,': ',a) 20 FORMAT (2x,'DEF_RST_PIO - inquiring restart file,',t56, & & 'Grid ',i2.2,': ',a) 30 FORMAT (/,' DEF_RST_PIO - unable to create restart NetCDF', & & ' file:',a) 40 FORMAT (1pe11.4,1x,'millimeter') 50 FORMAT (/,' DEF_RST_PIO - unable to open restart NetCDF', & & ' file: ',a) 60 FORMAT (/,' DEF_RST_PIO - unable to find variable: ',a,2x, & & ' in restart NetCDF file: ',a) ! RETURN END SUBROUTINE def_rst_pio #endif END MODULE def_rst_mod