#include "cppdefs.h" # ifdef TANGENT SUBROUTINE tl_get_data (ng) ! !git $Id$ !svn $Id: tl_get_data.F 1151 2023-02-09 03:08:53Z arango $ !================================================== Hernan G. Arango === ! Copyright (c) 2002-2023 The ROMS/TOMS Group ! ! Licensed under a MIT/X style license ! ! See License_ROMS.md ! !======================================================================= ! ! ! This routine reads in forcing, climatology and other data from ! ! NetCDF files. If there is more than one time-record, data is ! ! loaded into global two-time record arrays. The interpolation ! ! is carried elsewhere. ! ! ! ! Currently, this routine is only executed in serial mode by the ! ! main thread. ! ! ! !======================================================================= ! USE mod_param USE mod_boundary # ifdef FORWARD_READ USE mod_coupling # endif USE mod_clima USE mod_forces USE mod_grid USE mod_iounits USE mod_mixing USE mod_ncparam # ifdef FORWARD_READ USE mod_ocean # endif USE mod_scalars USE mod_sources USE mod_stepping ! USE strings_mod, ONLY : FoundError ! implicit none ! ! Imported variable declarations. ! integer, intent(in) :: ng ! ! Local variable declarations. ! logical, save :: recordless = .FALSE. logical, dimension(3) :: update = & & (/ .FALSE., .FALSE., .FALSE. /) ! integer :: ILB, IUB, JLB, JUB integer :: LBi, UBi, LBj, UBj integer :: i, ic, my_tile # ifdef FORWARD_MIXING ! real(r8) :: scale # endif ! character (len=*), parameter :: MyFile = & & __FILE__ ! ! Lower and upper bounds for nontiled (global values) boundary arrays. ! my_tile=-1 ! for global values ILB=BOUNDS(ng)%LBi(my_tile) IUB=BOUNDS(ng)%UBi(my_tile) JLB=BOUNDS(ng)%LBj(my_tile) JUB=BOUNDS(ng)%UBj(my_tile) ! ! Lower and upper bounds for tiled arrays. ! LBi=LBOUND(GRID(ng)%h,DIM=1) UBi=UBOUND(GRID(ng)%h,DIM=1) LBj=LBOUND(GRID(ng)%h,DIM=2) UBj=UBOUND(GRID(ng)%h,DIM=2) # ifdef PROFILE ! !----------------------------------------------------------------------- ! Turn on input data time wall clock. !----------------------------------------------------------------------- ! CALL wclock_on (ng, iTLM, 3, __LINE__, MyFile) # endif ! !======================================================================= ! Read in forcing data from FORCING NetCDF file. !======================================================================= # ifndef ANA_PSOURCE ! !----------------------------------------------------------------------- ! Point Sources/Sinks time dependent data. !----------------------------------------------------------------------- ! ! Point Source/Sink vertically integrated mass transport. ! IF (LuvSrc(ng).or.LwSrc(ng)) THEN CALL get_ngfld (ng, iTLM, idRtra, SSF(ng)%ncid, & # if defined PIO_LIB && defined DISTRIBUTE & SSF(ng)%pioFile, & # endif & 1, SSF(ng), recordless, update(1), & & 1, Nsrc(ng), 1, 2, 1, Nsrc(ng), 1, & & SOURCES(ng) % QbarG) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN END IF # ifdef SOLVE3D ! ! Tracer Sources/Sinks. ! DO i=1,NT(ng) IF (LtracerSrc(i,ng)) THEN CALL get_ngfld (ng, iTLM, idRtrc(i), SSF(ng)%ncid, & # if defined PIO_LIB && defined DISTRIBUTE & SSF(ng)%pioFile, & # endif & 1, SSF(ng), recordless, update(1), & & 1, Nsrc(ng), N(ng), 2, 1, Nsrc(ng), N(ng), & & SOURCES(ng) % TsrcG(:,:,:,i)) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN END IF END DO # endif # endif # if !defined ANA_WINDS && \ ((defined BULK_FLUXES && !defined FORWARD_FLUXES) || \ defined ECOSIM) ! !----------------------------------------------------------------------- ! Surface wind components. !----------------------------------------------------------------------- ! CALL get_2dfld (ng, iTLM, idUair, FRCncid(idUair,ng), & # if defined PIO_LIB && defined DISTRIBUTE & FRCpioFile(idUair,ng), & # endif & nFfiles(ng), FRC(1,ng), update(1), & & LBi, UBi, LBj, UBj, 2, 1, & # ifdef MASKING & GRID(ng) % rmask, & # endif & FORCES(ng) % UwindG) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN ! CALL get_2dfld (ng , iTLM, idVair, FRCncid(idVair,ng), & # if defined PIO_LIB && defined DISTRIBUTE & FRCpioFile(idVair,ng), & # endif & nFfiles(ng), FRC(1,ng), update(1), & & LBi, UBi, LBj, UBj, 2, 1, & # ifdef MASKING & GRID(ng) % rmask, & # endif & FORCES(ng) % VwindG) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN # endif # ifndef FRC_COUPLING # if !defined ANA_SMFLUX && \ !defined BULK_FLUXES && !defined FORWARD_FLUXES ! !----------------------------------------------------------------------- ! Surface wind stress components from input FRC file. !----------------------------------------------------------------------- ! CALL get_2dfld (ng, iTLM, idUsms, FRCncid(idUsms,ng), & # if defined PIO_LIB && defined DISTRIBUTE & FRCpioFile(idUsms,ng), & # endif & nFfiles(ng), FRC(1,ng), update(1), & & LBi, UBi, LBj, UBj, 2, 1, & # ifdef MASKING & GRID(ng) % umask, & # endif & FORCES(ng) % sustrG) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN ! CALL get_2dfld (ng, iTLM, idVsms, FRCncid(idVsms,ng), & # if defined PIO_LIB && defined DISTRIBUTE & FRCpioFile(idVsms,ng), & # endif & nFfiles(ng), FRC(1,ng), update(1), & & LBi, UBi, LBj, UBj, 2, 1, & # ifdef MASKING & GRID(ng) % vmask, & # endif & FORCES(ng) % svstrG) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN # endif # endif # if defined FORWARD_FLUXES || defined FRC_COUPLING ! !----------------------------------------------------------------------- ! Surface wind stress components from NLM forward file. !----------------------------------------------------------------------- ! CALL get_2dfld (ng, iTLM, idUsms, BLK(ng)%ncid, & # if defined PIO_LIB && defined DISTRIBUTE & BLK(ng)%pioFile, & # endif & 1, BLK(ng), update(1), & & LBi, UBi, LBj, UBj, 2, 1, & # ifdef MASKING & GRID(ng) % umask, & # endif & FORCES(ng) % sustrG) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN ! CALL get_2dfld (ng, iTLM, idVsms, BLK(ng)%ncid, & # if defined PIO_LIB && defined DISTRIBUTE & BLK(ng)%pioFile, & # endif & 1, BLK(ng), update(1), & & LBi, UBi, LBj, UBj, 2, 1, & # ifdef MASKING & GRID(ng) % vmask, & # endif & FORCES(ng) % svstrG) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN # endif # if !defined ANA_PAIR && \ (defined ATM_PRESS || defined BULK_FLUXES || \ defined ECOSIM) # if !(defined FRC_COUPLING || defined FORWARD_FLUXES) ! !----------------------------------------------------------------------- ! Surface air pressure from input FRC file. !----------------------------------------------------------------------- ! CALL get_2dfld (ng, iTLM, idPair, FRCncid(idPair,ng), & # if defined PIO_LIB && defined DISTRIBUTE & FRCpioFile(idPair,ng), & # endif & nFfiles(ng), FRC(1,ng), update(1), & & LBi, UBi, LBj, UBj, 2, 1, & # ifdef MASKING & GRID(ng) % rmask, & # endif & FORCES(ng) % PairG) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN # else ! !----------------------------------------------------------------------- ! Surface air pressure from NLM forward file. !----------------------------------------------------------------------- ! CALL get_2dfld (ng, iTLM, idPair, BLK(ng)%ncid, & # if defined PIO_LIB && defined DISTRIBUTE & BLK(ng)%pioFile, & # endif & 1, BLK(ng), update(1), & & LBi, UBi, LBj, UBj, 2, 1, & # ifdef MASKING & GRID(ng) % rmask, & # endif & FORCES(ng) % PairG) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN # endif # endif # if !defined ANA_WWAVE && defined WAVE_DATA ! !----------------------------------------------------------------------- ! Surface wind induced wave properties. !----------------------------------------------------------------------- ! # ifdef WAVES_DIR CALL get_2dfld (ng, iTLM, idWdir, FRCncid(idWdir,ng), & # if defined PIO_LIB && defined DISTRIBUTE & FRCpioFile(idWdir,ng), & # endif & nFfiles(ng), FRC(1,ng), update(1), & & LBi, UBi, LBj, UBj, 2, 1, & # ifdef MASKING & GRID(ng) % rmask, & # endif & FORCES(ng) % DwaveG) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN # endif # ifdef WAVES_HEIGHT ! CALL get_2dfld (ng, iTLM, idWamp, FRCncid(idWamp,ng), & # if defined PIO_LIB && defined DISTRIBUTE & FRCpioFile(idWamp,ng), & # endif & nFfiles(ng), FRC(1,ng), update(1), & & LBi, UBi, LBj, UBj, 2, 1, & # ifdef MASKING & GRID(ng) % rmask, & # endif & FORCES(ng) % HwaveG) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN # endif # ifdef WAVES_LENGTH ! CALL get_2dfld (ng, iTLM, idWlen, FRCncid(idWlen,ng), & # if defined PIO_LIB && defined DISTRIBUTE & FRCpioFile(idWlen,ng), & # endif & nFfiles(ng), FRC(1,ng), update(1), & & LBi, UBi, LBj, UBj, 2, 1, & # ifdef MASKING & GRID(ng) % rmask, & # endif & FORCES(ng) % LwaveG) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN # endif # ifdef WAVES_TOP_PERIOD ! CALL get_2dfld (ng, iTLM, idWptp, FRCncid(idWptp,ng), & # if defined PIO_LIB && defined DISTRIBUTE & FRCpioFile(idWptp,ng), & # endif & nFfiles(ng), FRC(1,ng), update(1), & & LBi, UBi, LBj, UBj, 2, 1, & # ifdef MASKING & GRID(ng) % rmask, & # endif & FORCES(ng) % Pwave_topG) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN # endif # ifdef WAVES_BOT_PERIOD ! CALL get_2dfld (ng, iTLM, idWpbt, FRCncid(idWpbt,ng), & # if defined PIO_LIB && defined DISTRIBUTE & FRCpioFile(idWpbt,ng), & # endif & nFfiles(ng), FRC(1,ng), update(1), & & LBi, UBi, LBj, UBj, 2, 1, & # ifdef MASKING & GRID(ng) % rmask, & # endif & FORCES(ng) % Pwave_botG) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN # endif # if defined WAVES_UB ! CALL get_2dfld (ng, iTLM, idWorb, FRCncid(idWorb,ng), & # if defined PIO_LIB && defined DISTRIBUTE & FRCpioFile(idWorb,ng), & # endif & nFfiles(ng), FRC(1,ng), update(1), & & LBi, UBi, LBj, UBj, 2, 1, & # ifdef MASKING & GRID(ng) % rmask, & # endif & FORCES(ng) % Ub_swanG) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN # endif # if defined TKE_WAVEDISS ! CALL get_2dfld (ng, iTLM, idWdis, FRCncid(idWdis,ng), & # if defined PIO_LIB && defined DISTRIBUTE & FRCpioFile(idWdis,ng), & # endif & nFfiles(ng), FRC(1,ng), update(1), & & LBi, UBi, LBj, UBj, 2, 1, & # ifdef MASKING & GRID(ng) % rmask, & # endif & FORCES(ng) % Wave_dissipG) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN # endif # if defined SVENDSEN_ROLLER ! CALL get_2dfld (ng, iTLM, idWbrk, FRCncid(idWbrk,ng), & # if defined PIO_LIB && defined DISTRIBUTE & FRCpioFile(idWbrk,ng), & # endif & nFfiles(ng), FRC(1,ng), update(1), & & LBi, UBi, LBj, UBj, 2, 1, & # ifdef MASKING & GRID(ng) % rmask, & # endif & FORCES(ng) % Wave_breakG) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN # endif # endif # ifdef SOLVE3D # if !defined ANA_CLOUD && defined CLOUDS ! !----------------------------------------------------------------------- ! Cloud fraction. !----------------------------------------------------------------------- ! CALL get_2dfld (ng, iTLM, idCfra, FRCncid(idCfra,ng), & # if defined PIO_LIB && defined DISTRIBUTE & FRCpioFile(idCfra,ng), & # endif & nFfiles(ng), FRC(1,ng), update(1), & & LBi, UBi, LBj, UBj, 2, 1, & # ifdef MASKING & GRID(ng) % rmask, & # endif & FORCES(ng) % cloudG) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN # endif # if defined SHORTWAVE && !defined ANA_SRFLUX # ifdef FORWARD_FLUXES ! !----------------------------------------------------------------------- ! Surface solar shortwave radiation from NLM forward file. !----------------------------------------------------------------------- ! CALL get_2dfld (ng, iTLM, idSrad, BLK(ng)%ncid, & # if defined PIO_LIB && defined DISTRIBUTE & BLK(ng)%pioFile, & # endif & 1, BLK(ng), update(1), & & LBi, UBi, LBj, UBj, 2, 1, & # ifdef MASKING & GRID(ng) % rmask, & # endif & FORCES(ng) % srflxG) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN # else # if !(defined BULK_FLUXES || defined FRC_COUPLING) ! !----------------------------------------------------------------------- ! Surface solar shortwave radiation. !----------------------------------------------------------------------- ! CALL get_2dfld (ng, iTLM, idSrad, FRCncid(idSrad,ng), & # if defined PIO_LIB && defined DISTRIBUTE & FRCpioFile(idSrad,ng), & # endif & nFfiles(ng), FRC(1,ng), update(1), & & LBi, UBi, LBj, UBj, 2, 1, & # ifdef MASKING & GRID(ng) % rmask, & # endif & FORCES(ng) % srflxG) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN # endif # endif # endif # if (defined BULK_FLUXES && !defined FORWARD_FLUXES) && \ !defined LONGWAVE && !defined LONGWAVE_OUT ! !----------------------------------------------------------------------- ! Surface net longwave radiation. !----------------------------------------------------------------------- ! CALL get_2dfld (ng, iTLM, idLrad, FRCncid(idLrad,ng), & # if defined PIO_LIB && defined DISTRIBUTE & FRCpioFile(idLrad,ng), & # endif & nFfiles(ng), FRC(1,ng), update(1), & & LBi, UBi, LBj, UBj, 2, 1, & # ifdef MASKING & GRID(ng) % rmask, & # endif & FORCES(ng) % lrflxG) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN # endif # if (defined BULK_FLUXES && !defined FORWARD_FLUXES) && \ defined LONGWAVE_OUT ! !----------------------------------------------------------------------- ! Surface downwelling longwave radiation. !----------------------------------------------------------------------- ! CALL get_2dfld (ng, iTLM, idLdwn, FRCncid(idLdwn,ng), & # if defined PIO_LIB && defined DISTRIBUTE & FRCpioFile(idLdwn,ng), & # endif & nFfiles(ng), FRC(1,ng), update(1), & & LBi, UBi, LBj, UBj, 2, 1, & # ifdef MASKING & GRID(ng) % rmask, & # endif & FORCES(ng) % lrflxG) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN # endif # if !defined ANA_TAIR && \ ((defined BULK_FLUXES && !defined FORWARD_FLUXES) || \ defined ECOSIM || \ (defined SHORTWAVE && defined ANA_SRFLUX && defined ALBEDO)) ! !----------------------------------------------------------------------- ! Surface air temperature. !----------------------------------------------------------------------- ! CALL get_2dfld (ng, iTLM, idTair, FRCncid(idTair,ng), & # if defined PIO_LIB && defined DISTRIBUTE & FRCpioFile(idTair,ng), & # endif & nFfiles(ng), FRC(1,ng), update(1), & & LBi, UBi, LBj, UBj, 2, 1, & # ifdef MASKING & GRID(ng) % rmask, & # endif & FORCES(ng) % TairG) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN # endif # if !defined ANA_HUMIDITY && \ ((defined BULK_FLUXES && !defined FORWARD_FLUXES) || \ defined ECOSIM) ! !----------------------------------------------------------------------- ! Surface air humidity. !----------------------------------------------------------------------- ! CALL get_2dfld (ng, iTLM, idQair, FRCncid(idQair,ng), & # if defined PIO_LIB && defined DISTRIBUTE & FRCpioFile(idQair,ng), & # endif & nFfiles(ng), FRC(1,ng), update(1), & & LBi, UBi, LBj, UBj, 2, 1, & # ifdef MASKING & GRID(ng) % rmask, & # endif & FORCES(ng) % HairG) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN # endif # if !defined ANA_RAIN && \ (defined BULK_FLUXES && !defined FORWARD_FLUXES) ! !----------------------------------------------------------------------- ! Rain fall rate. !----------------------------------------------------------------------- ! CALL get_2dfld (ng, iTLM, idrain, FRCncid(idrain,ng), & # if defined PIO_LIB && defined DISTRIBUTE & FRCpioFile(idrain,ng), & # endif & nFfiles(ng), FRC(1,ng), update(1), & & LBi, UBi, LBj, UBj, 2, 1, & # ifdef MASKING & GRID(ng) % rmask, & # endif & FORCES(ng) % rainG) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN # endif # ifndef ANA_STFLUX # if !(defined BULK_FLUXES || defined FORWARD_FLUXES) ! !----------------------------------------------------------------------- ! Surface net heat flux from input FRC file. !----------------------------------------------------------------------- ! CALL get_2dfld (ng, iTLM, idTsur(itemp), & & FRCncid(idTsur(itemp),ng), & # if defined PIO_LIB && defined DISTRIBUTE & FRCpioFile(idTsur(itemp),ng), & # endif & nFfiles(ng), FRC(1,ng), update(1), & & LBi, UBi, LBj, UBj, 2, 1, & # ifdef MASKING & GRID(ng) % rmask, & # endif & FORCES(ng) % stfluxG(:,:,:,itemp)) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN # elif defined FORWARD_FLUXES ! !----------------------------------------------------------------------- ! Surface net heat flux from NLM forward file. !----------------------------------------------------------------------- ! CALL get_2dfld (ng, iTLM, idTsur(itemp), BLK(ng)%ncid, & # if defined PIO_LIB && defined DISTRIBUTE & BLK(ng)%pioFile, & # endif & 1, BLK(ng), update(1), & & LBi, UBi, LBj, UBj, 2, 1, & # ifdef MASKING & GRID(ng) % rmask, & # endif & FORCES(ng) % stfluxG(:,:,:,itemp)) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN # endif # endif # if !defined ANA_SST && defined QCORRECTION ! !----------------------------------------------------------------------- ! Surface net heat flux correction fields: sea surface temperature ! (SST). !----------------------------------------------------------------------- ! CALL get_2dfld (ng, iTLM, idSSTc, FRCncid(idSSTc,ng), & # if defined PIO_LIB && defined DISTRIBUTE & FRCpioFile(idSSTc,ng), & # endif & nFfiles(ng), FRC(1,ng), update(1), & & LBi, UBi, LBj, UBj, 2, 1, & # ifdef MASKING & GRID(ng) % rmask, & # endif & FORCES(ng) % sstG) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN # endif # if !defined ANA_DQDSST && defined QCORRECTION ! !----------------------------------------------------------------------- ! Surface net heat flux correction fields: heat flux sensitivity to ! SST (dQdSST). !----------------------------------------------------------------------- ! CALL get_2dfld (ng, iTLM, iddQdT, FRCncid(iddQdT,ng), & # if defined PIO_LIB && defined DISTRIBUTE & FRCpioFile(iddQdT,ng), & # endif & nFfiles(ng), FRC(1,ng), update(1), & & LBi, UBi, LBj, UBj, 2, 1, & # ifdef MASKING & GRID(ng) % rmask, & # endif & FORCES(ng) % dqdtG) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN # endif # ifndef ANA_BTFLUX ! !----------------------------------------------------------------------- ! Bottom net heat flux. !----------------------------------------------------------------------- ! CALL get_2dfld (ng, iTLM, idTbot(itemp), & & FRCncid(idTbot(itemp),ng), & # if defined PIO_LIB && defined DISTRIBUTE & FRCpioFile(idTbot(itemp),ng), & # endif & nFfiles(ng), FRC(1,ng), update(1), & & LBi, UBi, LBj, UBj, 2, 1, & # ifdef MASKING & GRID(ng) % rmask, & # endif & FORCES(ng) % btfluxG(:,:,:,itemp)) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN # endif # if defined SALINITY && !defined ANA_SSFLUX # if !(defined EMINUSP || defined FORWARD_FLUXES || \ defined FRC_COUPLING || defined SRELAXATION) ! !----------------------------------------------------------------------- ! Surface net freshwater flux: E-P from FRC file. !----------------------------------------------------------------------- ! CALL get_2dfld (ng, iTLM, idsfwf, FRCncid(idsfwf,ng), & # if defined PIO_LIB && defined DISTRIBUTE & FRCpioFile(idsfwf,ng), & # endif & nFfiles(ng), FRC(1,ng), update(1), & & LBi, UBi, LBj, UBj, 2, 1, & # ifdef MASKING & GRID(ng) % rmask, & # endif & FORCES(ng) % stfluxG(:,:,:,isalt)) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN # elif (defined EMINUSP || defined FORWARD_FLUXES || \ defined FRC_COUPLING) ! !----------------------------------------------------------------------- ! Surface net freshwater flux (E-P) from NLM forward file. !----------------------------------------------------------------------- ! CALL get_2dfld (ng, iTLM, idEmPf, BLK(ng)%ncid, & # if defined PIO_LIB && defined DISTRIBUTE & BLK(ng)%pioFile, & # endif & 1, BLK(ng), update(1), & & LBi, UBi, LBj, UBj, 2, 1, & # ifdef MASKING & GRID(ng) % rmask, & # endif & FORCES(ng) % stfluxG(:,:,:,isalt)) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN # endif # if !defined ANA_SSS && (defined SCORRECTION || defined SRELAXATION) ! !----------------------------------------------------------------------- ! Surface net freshwater flux correction field: sea surface salinity. !----------------------------------------------------------------------- ! CALL get_2dfld (ng, iTLM, idSSSc, FRCncid(idSSSc,ng), & # if defined PIO_LIB && defined DISTRIBUTE & FRCpioFile(idSSSc,ng), & # endif & nFfiles(ng), FRC(1,ng), update(1), & & LBi, UBi, LBj, UBj, 2, 1, & # ifdef MASKING & GRID(ng) % rmask, & # endif & FORCES(ng) % sssG) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN # endif # ifndef ANA_BSFLUX ! !----------------------------------------------------------------------- ! Bottom net freshwater flux. !----------------------------------------------------------------------- ! CALL get_2dfld (ng, iTLM, idTbot(isalt), & & FRCncid(idTbot(isalt),ng), & # if defined PIO_LIB && defined DISTRIBUTE & FRCpioFile(idTbot(isalt),ng), & # endif & nFfiles(ng), FRC(1,ng), update(1), & & LBi, UBi, LBj, UBj, 2, 1, & # ifdef MASKING & GRID(ng) % rmask, & # endif & FORCES(ng) % btfluxG(:,:,:,isalt)) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN # endif # endif # if defined BIOLOGY || defined SEDIMENT || defined T_PASSIVE # ifndef ANA_SPFLUX ! !----------------------------------------------------------------------- ! Passive tracers surface fluxes. !----------------------------------------------------------------------- ! DO i=NAT+1,NT(ng) CALL get_2dfld (ng, iTLM, idTsur(i), FRCncid(idTsur(i),ng), & # if defined PIO_LIB && defined DISTRIBUTE & FRCpioFile(idTsur(i),ng), & # endif & nFfiles(ng), FRC(1,ng), update(1), & & LBi, UBi, LBj, UBj, 2, 1, & # ifdef MASKING & GRID(ng) % rmask, & # endif & FORCES(ng) % stfluxG(:,:,:,i)) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN END DO # endif # ifndef ANA_BPFLUX ! !----------------------------------------------------------------------- ! Passive tracers bottom fluxes. !----------------------------------------------------------------------- ! DO i=NAT+1,NT(ng) CALL get_2dfld (ng, iTLM, idTbot(i), FRCncid(idTbot(i),ng), & # if defined PIO_LIB && defined DISTRIBUTE & FRCpioFile(idTbot(i),ng), & # endif & nFfiles(ng), FRC(1,ng), update(1), & & LBi, UBi, LBj, UBj, 2, 1, & # ifdef MASKING & GRID(ng) % rmask, & # endif & FORCES(ng) % btfluxG(:,:,:,i)) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN END DO # endif # endif # endif ! !======================================================================= ! Read in open boundary conditions from BOUNDARY NetCDF file. !======================================================================= # ifndef ANA_FSOBC ! IF (LprocessOBC(ng)) THEN IF (tl_LBC(iwest,isFsur,ng)%acquire) THEN CALL get_ngfld (ng, iTLM, idZbry(iwest), & & BRYncid(idZbry(iwest),ng), & # if defined PIO_LIB && defined DISTRIBUTE & BRYpioFile(idZbry(iwest),ng), & # endif & nBCfiles(ng), BRY(1,ng), & & recordless, update(1), & & JLB, JUB, 1, 2, 0, Mm(ng)+1, 1, & & BOUNDARY(ng) % zetaG_west) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN END IF ! IF (tl_LBC(ieast,isFsur,ng)%acquire) THEN CALL get_ngfld (ng, iTLM, idZbry(ieast), & & BRYncid(idZbry(ieast),ng), & # if defined PIO_LIB && defined DISTRIBUTE & BRYpioFile(idZbry(ieast),ng), & # endif & nBCfiles(ng), BRY(1,ng), & & recordless, update(1), & & JLB, JUB, 1, 2, 0, Mm(ng)+1, 1, & & BOUNDARY(ng) % zetaG_east) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN END IF ! IF (tl_LBC(isouth,isFsur,ng)%acquire) THEN CALL get_ngfld (ng, iTLM, idZbry(isouth), & & BRYncid(idZbry(isouth),ng), & # if defined PIO_LIB && defined DISTRIBUTE & BRYpioFile(idZbry(isouth),ng), & # endif & nBCfiles(ng), BRY(1,ng), & & recordless, update(1), & & ILB, IUB, 1, 2, 0, Lm(ng)+1, 1, & & BOUNDARY(ng) % zetaG_south) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN END IF ! IF (tl_LBC(inorth,isFsur,ng)%acquire) THEN CALL get_ngfld (ng, iTLM, idZbry(inorth), & & BRYncid(idZbry(inorth),ng), & # if defined PIO_LIB && defined DISTRIBUTE & BRYpioFile(idZbry(inorth),ng), & # endif & nBCfiles(ng), BRY(1,ng), & & recordless, update(1), & & ILB, IUB, 1, 2, 0, Lm(ng)+1, 1, & & BOUNDARY(ng) % zetaG_north) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN END IF END IF # endif # ifndef ANA_M2OBC ! IF (LprocessOBC(ng)) THEN IF (tl_LBC(iwest,isUbar,ng)%acquire) THEN CALL get_ngfld (ng, iTLM, idU2bc(iwest), & & BRYncid(idU2bc(iwest),ng), & # if defined PIO_LIB && defined DISTRIBUTE & BRYpioFile(idU2bc(iwest),ng), & # endif & nBCfiles(ng), BRY(1,ng), & & recordless, update(1), & & JLB, JUB, 1, 2, 0, Mm(ng)+1, 1, & & BOUNDARY(ng) % ubarG_west) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN END IF ! IF (tl_LBC(iwest,isVbar,ng)%acquire) THEN CALL get_ngfld (ng, iTLM, idV2bc(iwest), & & BRYncid(idV2bc(iwest),ng), & # if defined PIO_LIB && defined DISTRIBUTE & BRYpioFile(idV2bc(iwest),ng), & # endif & nBCfiles(ng), BRY(1,ng), & & recordless, update(1), & & JLB, JUB, 1, 2, 1, Mm(ng)+1, 1, & & BOUNDARY(ng) % vbarG_west) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN END IF ! IF (tl_LBC(ieast,isUbar,ng)%acquire) THEN CALL get_ngfld (ng, iTLM, idU2bc(ieast), & & BRYncid(idU2bc(ieast),ng), & # if defined PIO_LIB && defined DISTRIBUTE & BRYpioFile(idU2bc(ieast),ng), & # endif & nBCfiles(ng), BRY(1,ng), & & recordless, update(1), & & JLB, JUB, 1, 2, 0, Mm(ng)+1, 1, & & BOUNDARY(ng) % ubarG_east) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN END IF ! IF (tl_LBC(ieast,isVbar,ng)%acquire) THEN CALL get_ngfld (ng, iTLM, idV2bc(ieast), & & BRYncid(idV2bc(ieast),ng), & # if defined PIO_LIB && defined DISTRIBUTE & BRYpioFile(idV2bc(ieast),ng), & # endif & nBCfiles(ng), BRY(1,ng), & & recordless, update(1), & & JLB, JUB, 1, 2, 1, Mm(ng)+1, 1, & & BOUNDARY(ng) % vbarG_east) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN END IF ! IF (tl_LBC(isouth,isUbar,ng)%acquire) THEN CALL get_ngfld (ng, iTLM, idU2bc(isouth), & & BRYncid(idU2bc(isouth),ng), & # if defined PIO_LIB && defined DISTRIBUTE & BRYpioFile(idU2bc(isouth),ng), & # endif & nBCfiles(ng), BRY(1,ng), & & recordless, update(1), & & ILB, IUB, 1, 2, 1, Lm(ng)+1, 1, & & BOUNDARY(ng) % ubarG_south) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN END IF ! IF (tl_LBC(isouth,isVbar,ng)%acquire) THEN CALL get_ngfld (ng, iTLM, idV2bc(isouth), & & BRYncid(idV2bc(isouth),ng), & # if defined PIO_LIB && defined DISTRIBUTE & BRYpioFile(idV2bc(isouth),ng), & # endif & nBCfiles(ng), BRY(1,ng), & & recordless, update(1), & & ILB, IUB, 1, 2, 0, Lm(ng)+1, 1, & & BOUNDARY(ng) % vbarG_south) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN END IF ! IF (tl_LBC(inorth,isUbar,ng)%acquire) THEN CALL get_ngfld (ng, iTLM, idU2bc(inorth), & & BRYncid(idU2bc(inorth),ng), & # if defined PIO_LIB && defined DISTRIBUTE & BRYpioFile(idU2bc(inorth),ng), & # endif & nBCfiles(ng), BRY(1,ng), & & recordless, update(1), & & ILB, IUB, 1, 2, 1, Lm(ng)+1, 1, & & BOUNDARY(ng) % ubarG_north) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN END IF ! IF (tl_LBC(inorth,isVbar,ng)%acquire) THEN CALL get_ngfld (ng, iTLM, idV2bc(inorth), & & BRYncid(idV2bc(inorth),ng), & # if defined PIO_LIB && defined DISTRIBUTE & BRYpioFile(idV2bc(inorth),ng), & # endif & nBCfiles(ng), BRY(1,ng), & & recordless, update(1), & & ILB, IUB, 1, 2, 0, Lm(ng)+1, 1, & & BOUNDARY(ng) % vbarG_north) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN END IF END IF # endif # ifdef SOLVE3D # ifndef ANA_M3OBC ! IF (LprocessOBC(ng)) THEN IF (tl_LBC(iwest,isUvel,ng)%acquire) THEN CALL get_ngfld (ng, iTLM, idU3bc(iwest), & & BRYncid(idU3bc(iwest),ng), & # if defined PIO_LIB && defined DISTRIBUTE & BRYpioFile(idU3bc(iwest),ng), & # endif & nBCfiles(ng), BRY(1,ng), & & recordless, update(1), & & JLB, JUB, N(ng), 2, 0, Mm(ng)+1, N(ng), & & BOUNDARY(ng) % uG_west) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN END IF ! IF (tl_LBC(iwest,isVvel,ng)%acquire) THEN CALL get_ngfld (ng, iTLM, idV3bc(iwest), & & BRYncid(idV3bc(iwest),ng), & # if defined PIO_LIB && defined DISTRIBUTE & BRYpioFile(idV3bc(iwest),ng), & # endif & nBCfiles(ng), BRY(1,ng), & & recordless, update(1), & & JLB, JUB, N(ng), 2, 1, Mm(ng)+1, N(ng), & & BOUNDARY(ng) % vG_west) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN END IF ! IF (tl_LBC(ieast,isUvel,ng)%acquire) THEN CALL get_ngfld (ng, iTLM, idU3bc(ieast), & & BRYncid(idU3bc(ieast),ng), & # if defined PIO_LIB && defined DISTRIBUTE & BRYpioFile(idU3bc(ieast),ng), & # endif & nBCfiles(ng), BRY(1,ng), & & recordless, update(1), & & JLB, JUB, N(ng), 2, 0, Mm(ng)+1, N(ng), & & BOUNDARY(ng) % uG_east) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN END IF ! IF (tl_LBC(ieast,isVvel,ng)%acquire) THEN CALL get_ngfld (ng, iTLM, idV3bc(ieast), & & BRYncid(idV3bc(ieast),ng), & # if defined PIO_LIB && defined DISTRIBUTE & BRYpioFile(idV3bc(ieast),ng), & # endif & nBCfiles(ng), BRY(1,ng), & & recordless, update(1), & & JLB, JUB, N(ng), 2, 1, Mm(ng)+1, N(ng), & & BOUNDARY(ng) % vG_east) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN END IF ! IF (tl_LBC(isouth,isUvel,ng)%acquire) THEN CALL get_ngfld (ng, iTLM, idU3bc(isouth), & & BRYncid(idU3bc(isouth),ng), & # if defined PIO_LIB && defined DISTRIBUTE & BRYpioFile(idU3bc(isouth),ng), & # endif & nBCfiles(ng), BRY(1,ng), & & recordless, update(1), & & ILB, IUB, N(ng), 2, 1, Lm(ng)+1, N(ng), & & BOUNDARY(ng) % uG_south) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN END IF ! IF (tl_LBC(isouth,isVvel,ng)%acquire) THEN CALL get_ngfld (ng, iTLM, idV3bc(isouth), & & BRYncid(idV3bc(isouth),ng), & # if defined PIO_LIB && defined DISTRIBUTE & BRYpioFile(idV3bc(isouth),ng), & # endif & nBCfiles(ng), BRY(1,ng), & & recordless, update(1), & & ILB, IUB, N(ng), 2, 0, Lm(ng)+1, N(ng), & & BOUNDARY(ng) % vG_south) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN END IF ! IF (tl_LBC(inorth,isUvel,ng)%acquire) THEN CALL get_ngfld (ng, iTLM, idU3bc(inorth), & & BRYncid(idU3bc(inorth),ng), & # if defined PIO_LIB && defined DISTRIBUTE & BRYpioFile(idU3bc(inorth),ng), & # endif & nBCfiles(ng), BRY(1,ng), & & recordless, update(1), & & ILB, IUB, N(ng), 2, 1, Lm(ng)+1, N(ng), & & BOUNDARY(ng) % uG_north) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN END IF ! IF (tl_LBC(inorth,isVvel,ng)%acquire) THEN CALL get_ngfld (ng, iTLM, idV3bc(inorth), & & BRYncid(idV3bc(inorth),ng), & # if defined PIO_LIB && defined DISTRIBUTE & BRYpioFile(idV3bc(inorth),ng), & # endif & nBCfiles(ng), BRY(1,ng), & & recordless, update(1), & & ILB, IUB, N(ng), 2, 0, Lm(ng)+1, N(ng), & & BOUNDARY(ng) % vG_north) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN END IF END IF # endif # ifndef ANA_TOBC ! IF (LprocessOBC(ng)) THEN DO i=1,NT(ng) IF (tl_LBC(iwest,isTvar(i),ng)%acquire) THEN CALL get_ngfld (ng, iTLM, idTbry(iwest,i), & & BRYncid(idTbry(iwest,i),ng), & # if defined PIO_LIB && defined DISTRIBUTE & BRYpioFile(idTbry(iwest,i),ng), & # endif & nBCfiles(ng), BRY(1,ng), & & recordless, update(1), & & JLB, JUB, N(ng), 2, 0, Mm(ng)+1, N(ng), & & BOUNDARY(ng) % tG_west(:,:,:,i)) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN END IF END DO ! DO i=1,NT(ng) IF (tl_LBC(ieast,isTvar(i),ng)%acquire) THEN CALL get_ngfld (ng, iTLM, idTbry(ieast,i), & & BRYncid(idTbry(ieast,i),ng), & # if defined PIO_LIB && defined DISTRIBUTE & BRYpioFile(idTbry(ieast,i),ng), & # endif & nBCfiles(ng), BRY(1,ng), & & recordless, update(1), & & JLB, JUB, N(ng), 2, 0, Mm(ng)+1, N(ng), & & BOUNDARY(ng) % tG_east(:,:,:,i)) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN END IF END DO ! DO i=1,NT(ng) IF (tl_LBC(isouth,isTvar(i),ng)%acquire) THEN CALL get_ngfld (ng, iTLM, idTbry(isouth,i), & & BRYncid(idTbry(isouth,i),ng), & # if defined PIO_LIB && defined DISTRIBUTE & BRYpioFile(idTbry(isouth,i),ng), & # endif & nBCfiles(ng), BRY(1,ng), & & recordless, update(1), & & ILB, IUB, N(ng), 2, 0, Lm(ng)+1, N(ng), & & BOUNDARY(ng) % tG_south(:,:,:,i)) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN END IF END DO ! DO i=1,NT(ng) IF (tl_LBC(inorth,isTvar(i),ng)%acquire) THEN CALL get_ngfld (ng, iTLM, idTbry(inorth,i), & & BRYncid(idTbry(inorth,i),ng), & # if defined PIO_LIB && defined DISTRIBUTE & BRYpioFile(idTbry(inorth,i),ng), & # endif & nBCfiles(ng), BRY(1,ng), & & recordless, update(1), & & ILB, IUB, N(ng), 2, 0, Lm(ng)+1, N(ng), & & BOUNDARY(ng) % tG_north(:,:,:,i)) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN END IF END DO END IF # endif # endif ! !======================================================================= ! Read in data from Climatology NetCDF file. !======================================================================= # ifndef ANA_SSH ! ! Free-surface. ! IF (LsshCLM(ng)) THEN CALL get_2dfld (ng, iTLM, idSSHc, CLMncid(idSSHc,ng), & # if defined PIO_LIB && defined DISTRIBUTE & CLMpioFile(idSSHc,ng), & # endif & nCLMfiles(ng), CLM(1,ng), update(1), & & LBi, UBi, LBj, UBj, 2, 1, & # ifdef MASKING & GRID(ng) % rmask, & # endif & CLIMA(ng) % sshG) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN END IF # endif # ifndef ANA_M2CLIMA ! ! 2D momentum. ! IF (Lm2CLM(ng)) THEN CALL get_2dfld (ng, iTLM, idUbcl, CLMncid(idUbcl,ng), & # if defined PIO_LIB && defined DISTRIBUTE & CLMpioFile(idUbcl,ng), & # endif & nCLMfiles(ng), CLM(1,ng), update(1), & & LBi, UBi, LBj, UBj, 2, 1, & # ifdef MASKING & GRID(ng) % umask, & # endif & CLIMA(ng) % ubarclmG) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN ! CALL get_2dfld (ng, iTLM, idVbcl, CLMncid(idVbcl,ng), & # if defined PIO_LIB && defined DISTRIBUTE & CLMpioFile(idVbcl,ng), & # endif & nCLMfiles(ng), CLM(1,ng), update(1), & & LBi, UBi, LBj, UBj, 2, 1, & # ifdef MASKING & GRID(ng) % vmask, & # endif & CLIMA(ng) % vbarclmG) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN END IF # endif # ifdef SOLVE3D # ifndef ANA_M3CLIMA ! ! 3D momentum. ! IF (Lm3CLM(ng)) THEN CALL get_3dfld (ng, iTLM, idUclm, CLMncid(idUclm,ng), & # if defined PIO_LIB && defined DISTRIBUTE & CLMpioFile(idUclm,ng), & # endif & nCLMfiles(ng), CLM(1,ng), update(1), & & LBi, UBi, LBj, UBj, 1, N(ng), 2, 1, & # ifdef MASKING & GRID(ng) % umask, & # endif & CLIMA(ng) % uclmG) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN ! CALL get_3dfld (ng, iTLM, idVclm, CLMncid(idVclm,ng), & # if defined PIO_LIB && defined DISTRIBUTE & CLMpioFile(idVclm,ng), & # endif & nCLMfiles(ng), CLM(1,ng), update(1), & & LBi, UBi, LBj, UBj, 1, N(ng), 2, 1, & # ifdef MASKING & GRID(ng) % vmask, & # endif & CLIMA(ng) % vclmG) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN END IF # endif # ifndef ANA_TCLIMA ! ! Tracers. ! ic=0 DO i=1,NT(ng) IF (LtracerCLM(i,ng)) THEN ic=ic+1 CALL get_3dfld (ng, iTLM, idTclm(i), & & CLMncid(idTclm(i),ng), & # if defined PIO_LIB && defined DISTRIBUTE & CLMpioFile(idTclm(i),ng), & # endif & nCLMfiles(ng), CLM(1,ng), update(1), & & LBi, UBi, LBj, UBj, 1, N(ng), 2, 1, & # ifdef MASKING & GRID(ng) % rmask, & # endif & CLIMA(ng) % tclmG(:,:,:,:,ic)) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN END IF END DO # endif # endif # ifdef FORWARD_READ ! !----------------------------------------------------------------------- ! Read in forward state solution. !----------------------------------------------------------------------- ! ! Read in free-surface. ! CALL get_2dfld (ng, iTLM, idFsur, FWD(ng)%ncid, & # if defined PIO_LIB && defined DISTRIBUTE & FWD(ng)%pioFile, & # endif & 1, FWD(ng), update(1), & & LBi, UBi, LBj, UBj, 2, 1, & # ifdef MASKING & GRID(ng) % rmask, & # endif & OCEAN(ng) % zetaG) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN ! ! Read 2D momentum. ! CALL get_2dfld (ng, iTLM, idUbar, FWD(ng)%ncid, & # if defined PIO_LIB && defined DISTRIBUTE & FWD(ng)%pioFile, & # endif & 1, FWD(ng), update(1), & & LBi, UBi, LBj, UBj, 2, 1, & # ifdef MASKING & GRID(ng) % umask, & # endif & OCEAN(ng) % ubarG) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN CALL get_2dfld (ng, iTLM, idVbar, FWD(ng)%ncid, & # if defined PIO_LIB && defined DISTRIBUTE & FWD(ng)%pioFile, & # endif & 1, FWD(ng), update(1), & & LBi, UBi, LBj, UBj, 2, 1, & # ifdef MASKING & GRID(ng) % vmask, & # endif & OCEAN(ng) % vbarG) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN # ifdef FORWARD_RHS ! ! Read in variables associated with 2D right-hand-side terms. ! CALL get_2dfld (ng, iTLM, idRzet, FWD(ng)%ncid, & # if defined PIO_LIB && defined DISTRIBUTE & FWD(ng)%pioFile, & # endif & 1, FWD(ng), update(1), & & LBi, UBi, LBj, UBj, 2, 1, & # ifdef MASKING & GRID(ng) % rmask, & # endif & OCEAN(ng) % rzetaG) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN ! CALL get_2dfld (ng, iTLM, idRu2d, FWD(ng)%ncid, & # if defined PIO_LIB && defined DISTRIBUTE & FWD(ng)%pioFile, & # endif & 1, FWD(ng), update(1), & & LBi, UBi, LBj, UBj, 2, 1, & # ifdef MASKING & GRID(ng) % umask, & # endif & OCEAN(ng) % rubarG) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN ! CALL get_2dfld (ng, iTLM, idRv2d, FWD(ng)%ncid, & # if defined PIO_LIB && defined DISTRIBUTE & FWD(ng)%pioFile, & # endif & 1, FWD(ng), update(1), & & LBi, UBi, LBj, UBj, 2, 1, & # ifdef MASKING & GRID(ng) % vmask, & # endif & OCEAN(ng) % rvbarG) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN # endif # ifdef SOLVE3D ! ! Read in variables associated with time-averaged 2D momentum terms. ! CALL get_2dfld (ng, iTLM, idUfx1, FWD(ng)%ncid, & # if defined PIO_LIB && defined DISTRIBUTE & FWD(ng)%pioFile, & # endif & 1, FWD(ng), update(1), & & LBi, UBi, LBj, UBj, 2, 1, & # ifdef MASKING & GRID(ng) % umask, & # endif & COUPLING(ng) % DU_avg1G) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN ! CALL get_2dfld (ng, iTLM, idUfx2, FWD(ng)%ncid, & # if defined PIO_LIB && defined DISTRIBUTE & FWD(ng)%pioFile, & # endif & 1, FWD(ng), update(1), & & LBi, UBi, LBj, UBj, 2, 1, & # ifdef MASKING & GRID(ng) % umask, & # endif & COUPLING(ng) % DU_avg2G) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN ! CALL get_2dfld (ng, iTLM, idVfx1, FWD(ng)%ncid, & # if defined PIO_LIB && defined DISTRIBUTE & FWD(ng)%pioFile, & # endif & 1, FWD(ng), update(1), & & LBi, UBi, LBj, UBj, 2, 1, & # ifdef MASKING & GRID(ng) % vmask, & # endif & COUPLING(ng) % DV_avg1G) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN ! CALL get_2dfld (ng, iTLM, idVfx2, FWD(ng)%ncid, & # if defined PIO_LIB && defined DISTRIBUTE & FWD(ng)%pioFile, & # endif & 1, FWD(ng), update(1), & & LBi, UBi, LBj, UBj, 2, 1, & # ifdef MASKING & GRID(ng) % vmask, & # endif & COUPLING(ng) % DV_avg2G) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN ! ! Read in 3D momentum. ! CALL get_3dfld (ng, iTLM, idUvel, FWD(ng)%ncid, & # if defined PIO_LIB && defined DISTRIBUTE & FWD(ng)%pioFile, & # endif & 1, FWD(ng), update(1), & & LBi, UBi, LBj, UBj, 1, N(ng), 2, 1, & # ifdef MASKING & GRID(ng) % umask, & # endif & OCEAN(ng) % uG) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN ! CALL get_3dfld (ng, iRPM, idVvel, FWD(ng)%ncid, & # if defined PIO_LIB && defined DISTRIBUTE & FWD(ng)%pioFile, & # endif & 1, FWD(ng), update(1), & & LBi, UBi, LBj, UBj, 1, N(ng), 2, 1, & # ifdef MASKING & GRID(ng) % vmask, & # endif & OCEAN(ng) % vG) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN # ifdef FORWARD_RHS ! ! Read in variables associated with 3D momentum right-hand-side terms. ! CALL get_2dfld (ng, iTLM, idRuct, FWD(ng)%ncid, & # if defined PIO_LIB && defined DISTRIBUTE & FWD(ng)%pioFile, & # endif & 1, FWD(ng), update(1), & & LBi, UBi, LBj, UBj, 2, 1, & # ifdef MASKING & GRID(ng) % umask, & # endif & COUPLING(ng) % rufrcG) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN ! CALL get_2dfld (ng, iTLM, idRvct, FWD(ng)%ncid, & # if defined PIO_LIB && defined DISTRIBUTE & FWD(ng)%pioFile, & # endif & 1, FWD(ng), update(1), & & LBi, UBi, LBj, UBj, 2, 1, & # ifdef MASKING & GRID(ng) % vmask, & # endif & COUPLING(ng) % rvfrcG) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN ! CALL get_3dfld (ng, iTLM, idRu3d, FWD(ng)%ncid, & # if defined PIO_LIB && defined DISTRIBUTE & FWD(ng)%pioFile, & # endif & 1, FWD(ng), update(1), & & LBi, UBi, LBj, UBj, 1, N(ng), 2, 1, & # ifdef MASKING & GRID(ng) % umask, & # endif & OCEAN(ng) % ruG) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN ! CALL get_3dfld (ng, iTLM, idRv3d, FWD(ng)%ncid, & # if defined PIO_LIB && defined DISTRIBUTE & FWD(ng)%pioFile, & # endif & 1, FWD(ng), update(1), & & LBi, UBi, LBj, UBj, 1, N(ng), 2, 1, & # ifdef MASKING & GRID(ng) % vmask, & # endif & OCEAN(ng) % rvG) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN # endif ! ! Read in 3D tracers. ! DO i=1,NT(ng) CALL get_3dfld (ng, iTLM, idTvar(i), FWD(ng)%ncid, & # if defined PIO_LIB && defined DISTRIBUTE & FWD(ng)%pioFile, & # endif & 1, FWD(ng), update(1), & & LBi, UBi, LBj, UBj, 1, N(ng), 2, 1, & # ifdef MASKING & GRID(ng) % rmask, & # endif & OCEAN(ng) % tG(:,:,:,:,i)) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN END DO # ifdef FORWARD_MIXING ! ! Read in vertical mixing variables. ! DO i=1,NAT scale=Fscale(idDiff(i),ng) ! save and rescale Fscale(idDiff(i),ng)=tl_Akt_fac(i,ng) CALL get_3dfld (ng, iTLM, idDiff(i), FWD(ng)%ncid, & # if defined PIO_LIB && defined DISTRIBUTE & FWD(ng)%pioFile, & # endif & 1, FWD(ng), update(1), & & LBi, UBi, LBj, UBj, 0, N(ng), 2, 1, & # ifdef MASKING & GRID(ng) % rmask, & # endif & MIXING(ng) % AktG(:,:,:,:,i)) Fscale(idDiff(i),ng)=scale IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN END DO ! scale=Fscale(idVvis,ng) ! save and rescale Fscale(idVvis,ng)=tl_Akv_fac(ng) CALL get_3dfld (ng, iTLM, idVvis, FWD(ng)%ncid, & # if defined PIO_LIB && defined DISTRIBUTE & FWD(ng)%pioFile, & # endif & 1, FWD(ng), update(1), & & LBi, UBi, LBj, UBj, 0, N(ng), 2, 1, & # ifdef MASKING & GRID(ng) % rmask, & # endif & MIXING(ng) % AkvG) Fscale(idVvis,ng)=scale IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN # endif # if defined MY25_MIXING_NOT_YET || defined GLS_MIXING_NOT_YET ! ! Read in turbulent kinetic energy. ! CALL get_3dfld (ng, iTLM, idMtke, FWD(ng)%ncid, & # if defined PIO_LIB && defined DISTRIBUTE & FWD(ng)%pioFile, & # endif & 1, FWD(ng), update(1), & & LBi, UBi, LBj, UBj, 0, N(ng), 2, 1, & # ifdef MASKING & GRID(ng) % rmask, & # endif & MIXING(ng) % tkeG) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN ! ! Read in turbulent kinetic energy times length scale. ! CALL get_3dfld (ng, iTLM, idMtls, FWD(ng)%ncid, & # if defined PIO_LIB && defined DISTRIBUTE & FWD(ng)%pioFile, & # endif & 1, FWD(ng), update(1), & & LBi, UBi, LBj, UBj, 0, N(ng), 2, 1, & # ifdef MASKING & GRID(ng) % rmask, & # endif & MIXING(ng) % glsG) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN ! ! Read in vertical mixing length scale. ! CALL get_3dfld (ng, iTLM, idVmLS, FWD(ng)%ncid, & # if defined PIO_LIB && defined DISTRIBUTE & FWD(ng)%pioFile, & # endif & 1, FWD(ng), update(1), & & LBi, UBi, LBj, UBj, 0, N(ng), 2, 1, & # ifdef MASKING & GRID(ng) % rmask, & # endif & MIXING(ng) % LscaleG) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN ! ! Read in vertical mixing coefficient for turbulent kinetic energy. ! CALL get_3dfld (ng, iTLM, idVmKK, FWD(ng)%ncid, & # if defined PIO_LIB && defined DISTRIBUTE & FWD(ng)%pioFile, & # endif & 1, FWD(ng), update(1), & & LBi, UBi, LBj, UBj, 0, N(ng), 2, 1, & # ifdef MASKING & GRID(ng) % rmask, & # endif & MIXING(ng) % AkkG) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN # ifdef GLS_MIXING_NOT_YET ! ! Read in vertical mixing coefficient for turbulent length scale. ! CALL get_3dfld (ng, iTLM, idVmKP, FWD(ng)%ncid, & # if defined PIO_LIB && defined DISTRIBUTE & FWD(ng)%pioFile, & # endif & 1, FWD(ng), update(1), & & LBi, UBi, LBj, UBj, 0, N(ng), 2, 1, & # ifdef MASKING & GRID(ng) % rmask, & # endif & MIXING(ng) % AkpG) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN # endif # endif # ifdef LMD_MIXING_NOT_YET ! ! Read in depth of surface oceanic boundary layer. ! CALL get_2dfld (ng, iTLM, idHsbl, FWD(ng)%ncid, & # if defined PIO_LIB && defined DISTRIBUTE & FWD(ng)%pioFile, & # endif & 1, FWD(ng), update(1), & & LBi, UBi, LBj, UBj, 2, 1, & # ifdef MASKING & GRID(ng) % rmask, & # endif & MIXING(ng) % hsblG) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN # endif # ifdef LMD_BKPP_NOT_YET ! ! Read in depth of bottom oceanic boundary layer. ! CALL get_2dfld (ng, iTLM, idHbbl, FWD(ng)%ncid, & # if defined PIO_LIB && defined DISTRIBUTE & FWD(ng)%pioFile, & # endif & 1, FWD(ng), update(1), & & LBi, UBi, LBj, UBj, 2, 1, & # ifdef MASKING & GRID(ng) % rmask, & # endif & MIXING(ng) % hbblG) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN # endif # ifdef LMD_NONLOCAL_NOT_YET ! ! Read in boundary layer nonlocal transport. ! DO i=1,NAT CALL get_3dfld (ng, iTLM, idGhat(i), FWD(ng)%ncid, & # if defined PIO_LIB && defined DISTRIBUTE & FWD(ng)%pioFile, & # endif & 1, FWD(ng), update(1), & & LBi, UBi, LBj, UBj, 0, N(ng), 2, 1, & # ifdef MASKING & GRID(ng) % rmask, & # endif & MIXING(ng) % ghatsG(:,:,:,i)) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN END DO # endif # endif # ifdef WEAK_CONSTRAINT ! !----------------------------------------------------------------------- ! Read frequent impulse forcing for weak constraint. !----------------------------------------------------------------------- ! IF (FrequentImpulse(ng)) THEN CALL get_2dfld (ng, iTLM, idZtlf, TLF(ng)%ncid, & # if defined PIO_LIB && defined DISTRIBUTE & TLF(ng)%pioFile, & # endif & 1, TLF(ng), update(1), & & LBi, UBi, LBj, UBj, 2, 1, & # ifdef MASKING & GRID(ng) % rmask, & # endif & OCEAN(ng) % f_zetaG) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN # ifndef SOLVE3D ! ! Read 2D momentum forcing. ! CALL get_2dfld (ng, iTLM, idUbtf, TLF(ng)%ncid, & # if defined PIO_LIB && defined DISTRIBUTE & TLF(ng)%pioFile, & # endif & 1, TLF(ng), update(1), & & LBi, UBi, LBj, UBj, 2, 1, & # ifdef MASKING & GRID(ng) % umask, & # endif & OCEAN(ng) % f_ubarG) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN ! CALL get_2dfld (ng, iTLM, idVbtf, TLF(ng)%ncid, & # if defined PIO_LIB && defined DISTRIBUTE & TLF(ng)%pioFile, & # endif & 1, TLF(ng), update(1), & & LBi, UBi, LBj, UBj, 2, 1, & # ifdef MASKING & GRID(ng) % vmask, & # endif & OCEAN(ng) % f_vbarG) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN # endif # ifdef SOLVE3D ! ! Read in 3D momentum forcing. ! CALL get_3dfld (ng, iTLM, idUtlf, TLF(ng)%ncid, & # if defined PIO_LIB && defined DISTRIBUTE & TLF(ng)%pioFile, & # endif & 1, TLF(ng), update(1), & & LBi, UBi, LBj, UBj, 1, N(ng), 2, 1, & # ifdef MASKING & GRID(ng) % umask, & # endif & OCEAN(ng) % f_uG) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN ! CALL get_3dfld (ng, iTLM, idVtlf, TLF(ng)%ncid, & # if defined PIO_LIB && defined DISTRIBUTE & TLF(ng)%pioFile, & # endif & 1, TLF(ng), update(1), & & LBi, UBi, LBj, UBj, 1, N(ng), 2, 1, & # ifdef MASKING & GRID(ng) % vmask, & # endif & OCEAN(ng) % f_vG) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN ! ! Read in 3D tracers forcing. ! DO i=1,NT(ng) CALL get_3dfld (ng, iTLM, idTtlf(i), TLF(ng)%ncid, & # if defined PIO_LIB && defined DISTRIBUTE & TLF(ng)%pioFile, & # endif & 1, TLF(ng), update(1), & & LBi, UBi, LBj, UBj, 1, N(ng), 2, 1, & # ifdef MASKING & GRID(ng) % rmask, & # endif & OCEAN(ng) % f_tG(:,:,:,:,i)) IF (FoundError(exit_flag, NoError, __LINE__, MyFile)) RETURN END DO # endif END IF # endif # endif # ifdef PROFILE ! !----------------------------------------------------------------------- ! Turn off input data time wall clock. !----------------------------------------------------------------------- ! CALL wclock_off (ng, iTLM, 3, __LINE__, MyFile) # endif ! RETURN END SUBROUTINE tl_get_data #else SUBROUTINE tl_get_data RETURN END SUBROUTINE tl_get_data #endif