MODULE fldread !!====================================================================== !! *** MODULE fldread *** !! Ocean forcing: read input field for surface boundary condition !!===================================================================== !! History : 2.0 ! 06-2006 (S. Masson, G. Madec) Original code !! ! 05-2008 (S. Alderson) Modified for Interpolation in memory !! ! from input grid to model grid !! ! 10-2013 (D. Delrosso, P. Oddo) implement suppression of !! ! land point prior to interpolation !!---------------------------------------------------------------------- !!---------------------------------------------------------------------- !! fld_read : read input fields used for the computation of the !! surface boundary condition !!---------------------------------------------------------------------- USE oce ! ocean dynamics and tracers USE dom_oce ! ocean space and time domain USE phycst ! ??? USE in_out_manager ! I/O manager USE iom ! I/O manager library USE geo2ocean ! for vector rotation on to model grid USE lib_mpp ! MPP library USE wrk_nemo ! work arrays USE lbclnk ! ocean lateral boundary conditions (C1D case) USE ioipsl, ONLY : ymds2ju, ju2ymds ! for calendar USE sbc_oce IMPLICIT NONE PRIVATE PUBLIC fld_map ! routine called by tides_init PUBLIC fld_read, fld_fill ! called by sbc... modules PUBLIC fld_clopn TYPE, PUBLIC :: FLD_N !: Namelist field informations CHARACTER(len = 256) :: clname ! generic name of the NetCDF flux file REAL(wp) :: nfreqh ! frequency of each flux file CHARACTER(len = 34) :: clvar ! generic name of the variable in the NetCDF flux file LOGICAL :: ln_tint ! time interpolation or not (T/F) LOGICAL :: ln_clim ! climatology or not (T/F) CHARACTER(len = 8) :: cltype ! type of data file 'daily', 'monthly' or yearly' CHARACTER(len = 256) :: wname ! generic name of a NetCDF weights file to be used, blank if not CHARACTER(len = 34) :: vcomp ! symbolic component name if a vector that needs rotation ! ! a string starting with "U" or "V" for each component ! ! chars 2 onwards identify which components go together CHARACTER(len = 34) :: lname ! generic name of a NetCDF land/sea mask file to be used, blank if not ! ! 0=sea 1=land END TYPE FLD_N TYPE, PUBLIC :: FLD !: Input field related variables CHARACTER(len = 256) :: clrootname ! generic name of the NetCDF file CHARACTER(len = 256) :: clname ! current name of the NetCDF file REAL(wp) :: nfreqh ! frequency of each flux file CHARACTER(len = 34) :: clvar ! generic name of the variable in the NetCDF flux file LOGICAL :: ln_tint ! time interpolation or not (T/F) LOGICAL :: ln_clim ! climatology or not (T/F) CHARACTER(len = 8) :: cltype ! type of data file 'daily', 'monthly' or yearly' INTEGER :: num ! iom id of the jpfld files to be read INTEGER , DIMENSION(2) :: nrec_b ! before record (1: index, 2: second since Jan. 1st 00h of nit000 year) INTEGER , DIMENSION(2) :: nrec_a ! after record (1: index, 2: second since Jan. 1st 00h of nit000 year) REAL(wp) , ALLOCATABLE, DIMENSION(:,:,: ) :: fnow ! input fields interpolated to now time step REAL(wp) , ALLOCATABLE, DIMENSION(:,:,:,:) :: fdta ! 2 consecutive record of input fields CHARACTER(len = 256) :: wgtname ! current name of the NetCDF weight file acting as a key ! ! into the WGTLIST structure CHARACTER(len = 34) :: vcomp ! symbolic name for a vector component that needs rotation LOGICAL, DIMENSION(2) :: rotn ! flag to indicate whether before/after field has been rotated INTEGER :: nreclast ! last record to be read in the current file CHARACTER(len = 256) :: lsmname ! current name of the NetCDF mask file acting as a key END TYPE FLD TYPE, PUBLIC :: MAP_POINTER !: Map from input data file to local domain INTEGER, POINTER, DIMENSION(:) :: ptr ! Array of integer pointers to 1D arrays LOGICAL :: ll_unstruc ! Unstructured (T) or structured (F) boundary data file END TYPE MAP_POINTER !$AGRIF_DO_NOT_TREAT !! keep list of all weights variables so they're only read in once !! need to add AGRIF directives not to process this structure !! also need to force wgtname to include AGRIF nest number TYPE :: WGT !: Input weights related variables CHARACTER(len = 256) :: wgtname ! current name of the NetCDF weight file INTEGER , DIMENSION(2) :: ddims ! shape of input grid INTEGER , DIMENSION(2) :: botleft ! top left corner of box in input grid containing ! ! current processor grid INTEGER , DIMENSION(2) :: topright ! top right corner of box INTEGER :: jpiwgt ! width of box on input grid INTEGER :: jpjwgt ! height of box on input grid INTEGER :: numwgt ! number of weights (4=bilinear, 16=bicubic) INTEGER :: nestid ! for agrif, keep track of nest we're in INTEGER :: overlap ! =0 when cyclic grid has no overlapping EW columns ! ! =>1 when they have one or more overlapping columns ! ! =-1 not cyclic LOGICAL :: cyclic ! east-west cyclic or not INTEGER, DIMENSION(:,:,:), POINTER :: data_jpi ! array of source integers INTEGER, DIMENSION(:,:,:), POINTER :: data_jpj ! array of source integers REAL(wp), DIMENSION(:,:,:), POINTER :: data_wgt ! array of weights on model grid REAL(wp), DIMENSION(:,:,:), POINTER :: fly_dta ! array of values on input grid REAL(wp), DIMENSION(:,:,:), POINTER :: col ! temporary array for reading in columns END TYPE WGT INTEGER, PARAMETER :: tot_wgts = 10 TYPE( WGT ), DIMENSION(tot_wgts) :: ref_wgts ! array of wgts INTEGER :: nxt_wgt = 1 ! point to next available space in ref_wgts array REAL(wp), PARAMETER :: undeff_lsm = -999.00_wp !$AGRIF_END_DO_NOT_TREAT !!---------------------------------------------------------------------- !! NEMO/OPA 3.3 , NEMO Consortium (2010) !! $Id: fldread.F90 4784 2014-09-24 08:44:53Z jamesharle $ !! Software governed by the CeCILL licence (NEMOGCM/NEMO_CeCILL.txt) !!---------------------------------------------------------------------- CONTAINS SUBROUTINE fld_read( kt, kn_fsbc, sd, map, kit, kt_offset ) !!--------------------------------------------------------------------- !! *** ROUTINE fld_read *** !! !! ** Purpose : provide at each time step the surface ocean fluxes !! (momentum, heat, freshwater and runoff) !! !! ** Method : READ each input fields in NetCDF files using IOM !! and intepolate it to the model time-step. !! Several assumptions are made on the input file: !! blahblahblah.... !!---------------------------------------------------------------------- INTEGER , INTENT(in ) :: kt ! ocean time step INTEGER , INTENT(in ) :: kn_fsbc ! sbc computation period (in time step) TYPE(FLD), INTENT(inout), DIMENSION(:) :: sd ! input field related variables TYPE(MAP_POINTER),INTENT(in), OPTIONAL, DIMENSION(:) :: map ! global-to-local mapping indices INTEGER , INTENT(in ), OPTIONAL :: kit ! subcycle timestep for timesplitting option INTEGER , INTENT(in ), OPTIONAL :: kt_offset ! provide fields at time other than "now" ! kt_offset = -1 => fields at "before" time level ! kt_offset = +1 => fields at "after" time level ! etc. !! INTEGER :: itmp ! temporary variable INTEGER :: imf ! size of the structure sd INTEGER :: jf ! dummy indices INTEGER :: isecend ! number of second since Jan. 1st 00h of nit000 year at nitend INTEGER :: isecsbc ! number of seconds between Jan. 1st 00h of nit000 year and the middle of sbc time step INTEGER :: it_offset ! local time offset variable LOGICAL :: llnxtyr ! open next year file? LOGICAL :: llnxtmth ! open next month file? LOGICAL :: llstop ! stop is the file does not exist LOGICAL :: ll_firstcall ! true if this is the first call to fld_read for this set of fields REAL(wp) :: ztinta ! ratio applied to after records when doing time interpolation REAL(wp) :: ztintb ! ratio applied to before records when doing time interpolation CHARACTER(LEN=1000) :: clfmt ! write format TYPE(MAP_POINTER) :: imap ! global-to-local mapping indices !!--------------------------------------------------------------------- ll_firstcall = kt == nit000 IF( PRESENT(kit) ) ll_firstcall = ll_firstcall .and. kit == 1 IF ( nn_components == jp_iam_sas ) THEN ; it_offset = nn_fsbc ELSE ; it_offset = 0 ENDIF IF( PRESENT(kt_offset) ) it_offset = kt_offset imap%ptr => NULL() ! Note that shifting time to be centrered in the middle of sbc time step impacts only nsec_* variables of the calendar IF( present(kit) ) THEN ! ignore kn_fsbc in this case isecsbc = nsec_year + nsec1jan000 + (kit+it_offset)*NINT( rdt/REAL(nn_baro,wp) ) ELSE ! middle of sbc time step isecsbc = nsec_year + nsec1jan000 + NINT(0.5 * REAL(kn_fsbc - 1,wp) * rdttra(1)) + it_offset * NINT(rdttra(1)) ENDIF imf = SIZE( sd ) ! IF( ll_firstcall ) THEN ! initialization DO jf = 1, imf IF( PRESENT(map) ) imap = map(jf) CALL fld_init( kn_fsbc, sd(jf), imap ) ! read each before field (put them in after as they will be swapped) END DO IF( lwp ) CALL wgt_print() ! control print ENDIF ! ! ====================================== ! IF( MOD( kt-1, kn_fsbc ) == 0 ) THEN ! update field at each kn_fsbc time-step ! ! ! ====================================== ! ! DO jf = 1, imf ! --- loop over field --- ! IF( isecsbc > sd(jf)%nrec_a(2) .OR. ll_firstcall ) THEN ! read/update the after data? IF( PRESENT(map) ) imap = map(jf) ! temporary definition of map sd(jf)%nrec_b(:) = sd(jf)%nrec_a(:) ! swap before record informations sd(jf)%rotn(1) = sd(jf)%rotn(2) ! swap before rotate informations IF( sd(jf)%ln_tint ) sd(jf)%fdta(:,:,:,1) = sd(jf)%fdta(:,:,:,2) ! swap before record field CALL fld_rec( kn_fsbc, sd(jf), kt_offset = it_offset, kit = kit ) ! update after record informations ! if kn_fsbc*rdttra is larger than nfreqh (which is kind of odd), ! it is possible that the before value is no more the good one... we have to re-read it ! if before is not the last record of the file currently opened and after is the first record to be read ! in a new file which means after = 1 (the file to be opened corresponds to the current time) ! or after = nreclast + 1 (the file to be opened corresponds to a future time step) IF( .NOT. ll_firstcall .AND. sd(jf)%ln_tint .AND. sd(jf)%nrec_b(1) /= sd(jf)%nreclast & & .AND. MOD( sd(jf)%nrec_a(1), sd(jf)%nreclast ) == 1 ) THEN itmp = sd(jf)%nrec_a(1) ! temporary storage sd(jf)%nrec_a(1) = sd(jf)%nreclast ! read the last record of the file currently opened CALL fld_get( sd(jf), imap ) ! read after data sd(jf)%fdta(:,:,:,1) = sd(jf)%fdta(:,:,:,2) ! re-swap before record field sd(jf)%nrec_b(1) = sd(jf)%nrec_a(1) ! update before record informations sd(jf)%nrec_b(2) = sd(jf)%nrec_a(2) - NINT( sd(jf)%nfreqh * 3600 ) ! assume freq to be in hours in this case sd(jf)%rotn(1) = sd(jf)%rotn(2) ! update before rotate informations sd(jf)%nrec_a(1) = itmp ! move back to after record ENDIF CALL fld_clopn( sd(jf) ) ! Do we need to open a new year/month/week/day file? IF( sd(jf)%ln_tint ) THEN ! if kn_fsbc*rdttra is larger than nfreqh (which is kind of odd), ! it is possible that the before value is no more the good one... we have to re-read it ! if before record is not just just before the after record... IF( .NOT. ll_firstcall .AND. MOD( sd(jf)%nrec_a(1), sd(jf)%nreclast ) /= 1 & & .AND. sd(jf)%nrec_b(1) /= sd(jf)%nrec_a(1) - 1 ) THEN sd(jf)%nrec_a(1) = sd(jf)%nrec_a(1) - 1 ! move back to before record CALL fld_get( sd(jf), imap ) ! read after data sd(jf)%fdta(:,:,:,1) = sd(jf)%fdta(:,:,:,2) ! re-swap before record field sd(jf)%nrec_b(1) = sd(jf)%nrec_a(1) ! update before record informations sd(jf)%nrec_b(2) = sd(jf)%nrec_a(2) - NINT( sd(jf)%nfreqh * 3600 ) ! assume freq to be in hours in this case sd(jf)%rotn(1) = sd(jf)%rotn(2) ! update before rotate informations sd(jf)%nrec_a(1) = sd(jf)%nrec_a(1) + 1 ! move back to after record ENDIF ! do we have to change the year/month/week/day of the forcing field?? ! if we do time interpolation we will need to open next year/month/week/day file before the end of the current ! one. If so, we are still before the end of the year/month/week/day when calling fld_rec so sd(jf)%nrec_a(1) ! will be larger than the record number that should be read for current year/month/week/day ! do we need next file data? IF( sd(jf)%nrec_a(1) > sd(jf)%nreclast ) THEN sd(jf)%nrec_a(1) = sd(jf)%nrec_a(1) - sd(jf)%nreclast ! IF( .NOT. ( sd(jf)%ln_clim .AND. sd(jf)%cltype == 'yearly' ) ) THEN ! close/open the current/new file llnxtmth = sd(jf)%cltype == 'monthly' .OR. nday == nmonth_len(nmonth) ! open next month file? llnxtyr = sd(jf)%cltype == 'yearly' .OR. (nmonth == 12 .AND. llnxtmth) ! open next year file? ! if the run finishes at the end of the current year/month/week/day, we will allow next ! year/month/week/day file to be not present. If the run continue further than the current ! year/month/week/day, next year/month/week/day file must exist isecend = nsec_year + nsec1jan000 + (nitend - kt) * NINT(rdttra(1)) ! second at the end of the run llstop = isecend > sd(jf)%nrec_a(2) ! read more than 1 record of next year ! we suppose that the date of next file is next day (should be ok even for weekly files...) CALL fld_clopn( sd(jf), nyear + COUNT((/llnxtyr /)) , & & nmonth + COUNT((/llnxtmth/)) - 12 * COUNT((/llnxtyr /)), & & nday + 1 - nmonth_len(nmonth) * COUNT((/llnxtmth/)), llstop ) IF( sd(jf)%num <= 0 .AND. .NOT. llstop ) THEN ! next year file does not exist CALL ctl_warn('next year/month/week/day file: '//TRIM(sd(jf)%clname)// & & ' not present -> back to current year/month/day') CALL fld_clopn( sd(jf) ) ! back to the current year/month/day sd(jf)%nrec_a(1) = sd(jf)%nreclast ! force to read the last record in the current year file ENDIF ENDIF ENDIF ! open need next file? ENDIF ! temporal interpolation? ! read after data CALL fld_get( sd(jf), imap ) ENDIF ! read new data? END DO ! --- end loop over field --- ! CALL fld_rot( kt, sd ) ! rotate vector before/now/after fields if needed DO jf = 1, imf ! --- loop over field --- ! ! IF( sd(jf)%ln_tint ) THEN ! temporal interpolation IF(lwp .AND. kt - nit000 <= 100 ) THEN clfmt = "('fld_read: var ', a, ' kt = ', i8, ' (', f9.4,' days), Y/M/D = ', i4.4,'/', i2.2,'/', i2.2," // & & "', records b/a: ', i6.4, '/', i6.4, ' (days ', f9.4,'/', f9.4, ')')" WRITE(numout, clfmt) TRIM( sd(jf)%clvar ), kt, REAL(isecsbc,wp)/rday, nyear, nmonth, nday, & & sd(jf)%nrec_b(1), sd(jf)%nrec_a(1), REAL(sd(jf)%nrec_b(2),wp)/rday, REAL(sd(jf)%nrec_a(2),wp)/rday WRITE(numout, *) 'it_offset is : ',it_offset ENDIF ! temporal interpolation weights ztinta = REAL( isecsbc - sd(jf)%nrec_b(2), wp ) / REAL( sd(jf)%nrec_a(2) - sd(jf)%nrec_b(2), wp ) ztintb = 1. - ztinta !CDIR COLLAPSE sd(jf)%fnow(:,:,:) = ztintb * sd(jf)%fdta(:,:,:,1) + ztinta * sd(jf)%fdta(:,:,:,2) ELSE ! nothing to do... IF(lwp .AND. kt - nit000 <= 100 ) THEN clfmt = "('fld_read: var ', a, ' kt = ', i8,' (', f9.4,' days), Y/M/D = ', i4.4,'/', i2.2,'/', i2.2," // & & "', record: ', i6.4, ' (days ', f9.4, ' <-> ', f9.4, ')')" WRITE(numout, clfmt) TRIM(sd(jf)%clvar), kt, REAL(isecsbc,wp)/rday, nyear, nmonth, nday, & & sd(jf)%nrec_a(1), REAL(sd(jf)%nrec_b(2),wp)/rday, REAL(sd(jf)%nrec_a(2),wp)/rday ENDIF ENDIF ! IF( kt == nitend - kn_fsbc + 1 ) CALL iom_close( sd(jf)%num ) ! Close the input files END DO ! --- end loop over field --- ! ! ! ! ====================================== ! ENDIF ! update field at each kn_fsbc time-step ! ! ! ====================================== ! ! END SUBROUTINE fld_read SUBROUTINE fld_init( kn_fsbc, sdjf, map ) !!--------------------------------------------------------------------- !! *** ROUTINE fld_init *** !! !! ** Purpose : - first call to fld_rec to define before values !! - if time interpolation, read before data !!---------------------------------------------------------------------- INTEGER , INTENT(in ) :: kn_fsbc ! sbc computation period (in time step) TYPE(FLD), INTENT(inout) :: sdjf ! input field related variables TYPE(MAP_POINTER),INTENT(in) :: map ! global-to-local mapping indices !! LOGICAL :: llprevyr ! are we reading previous year file? LOGICAL :: llprevmth ! are we reading previous month file? LOGICAL :: llprevweek ! are we reading previous week file? LOGICAL :: llprevday ! are we reading previous day file? LOGICAL :: llprev ! llprevyr .OR. llprevmth .OR. llprevweek .OR. llprevday INTEGER :: idvar ! variable id INTEGER :: inrec ! number of record existing for this variable INTEGER :: iyear, imonth, iday ! first day of the current file in yyyy mm dd INTEGER :: isec_week ! number of seconds since start of the weekly file CHARACTER(LEN=1000) :: clfmt ! write format !!--------------------------------------------------------------------- llprevyr = .FALSE. llprevmth = .FALSE. llprevweek = .FALSE. llprevday = .FALSE. isec_week = 0 ! define record informations CALL fld_rec( kn_fsbc, sdjf, ldbefore = .TRUE. ) ! return before values in sdjf%nrec_a (as we will swap it later) ! Note that shifting time to be centrered in the middle of sbc time step impacts only nsec_* variables of the calendar IF( sdjf%ln_tint ) THEN ! we need to read the previous record and we will put it in the current record structure IF( sdjf%nrec_a(1) == 0 ) THEN ! we redefine record sdjf%nrec_a(1) with the last record of previous year file IF ( sdjf%nfreqh == -12 ) THEN ! yearly mean IF( sdjf%cltype == 'yearly' ) THEN ! yearly file sdjf%nrec_a(1) = 1 ! force to read the unique record llprevyr = .NOT. sdjf%ln_clim ! use previous year file? ELSE CALL ctl_stop( "fld_init: yearly mean file must be in a yearly type of file: "//TRIM(sdjf%clrootname) ) ENDIF ELSEIF( sdjf%nfreqh == -1 ) THEN ! monthly mean IF( sdjf%cltype == 'monthly' ) THEN ! monthly file sdjf%nrec_a(1) = 1 ! force to read the unique record llprevmth = .TRUE. ! use previous month file? llprevyr = llprevmth .AND. nmonth == 1 ! use previous year file? ELSE ! yearly file sdjf%nrec_a(1) = 12 ! force to read december mean llprevyr = .NOT. sdjf%ln_clim ! use previous year file? ENDIF ELSE ! higher frequency mean (in hours) IF ( sdjf%cltype == 'monthly' ) THEN ! monthly file sdjf%nrec_a(1) = NINT( 24 * nmonth_len(nmonth-1) / sdjf%nfreqh ) ! last record of previous month llprevmth = .TRUE. ! use previous month file? llprevyr = llprevmth .AND. nmonth == 1 ! use previous year file? ELSEIF( sdjf%cltype(1:4) == 'week' ) THEN ! weekly file llprevweek = .TRUE. ! use previous week file? sdjf%nrec_a(1) = NINT( 24 * 7 / sdjf%nfreqh ) ! last record of previous week isec_week = NINT(rday) * 7 ! add a shift toward previous week ELSEIF( sdjf%cltype == 'daily' ) THEN ! daily file sdjf%nrec_a(1) = NINT( 24 / sdjf%nfreqh ) ! last record of previous day llprevday = .TRUE. ! use previous day file? llprevmth = llprevday .AND. nday == 1 ! use previous month file? llprevyr = llprevmth .AND. nmonth == 1 ! use previous year file? ELSE ! yearly file sdjf%nrec_a(1) = NINT( 24 * nyear_len(0) / sdjf%nfreqh ) ! last record of previous year llprevyr = .NOT. sdjf%ln_clim ! use previous year file? ENDIF ENDIF ENDIF ! IF ( sdjf%cltype(1:4) == 'week' ) THEN isec_week = isec_week + ksec_week( sdjf%cltype(6:8) ) ! second since the beginning of the week llprevmth = isec_week > nsec_month ! longer time since the beginning of the week than the month llprevyr = llprevmth .AND. nmonth == 1 ENDIF llprev = llprevyr .OR. llprevmth .OR. llprevweek .OR. llprevday ! iyear = nyear - COUNT((/llprevyr /)) imonth = nmonth - COUNT((/llprevmth/)) + 12 * COUNT((/llprevyr /)) iday = nday - COUNT((/llprevday/)) + nmonth_len(nmonth-1) * COUNT((/llprevmth/)) - isec_week / NINT(rday) ! CALL fld_clopn( sdjf, iyear, imonth, iday, .NOT. llprev ) ! if previous year/month/day file does not exist, we switch to the current year/month/day IF( llprev .AND. sdjf%num <= 0 ) THEN CALL ctl_warn( 'previous year/month/week/day file: '//TRIM(sdjf%clrootname)// & & ' not present -> back to current year/month/week/day' ) ! we force to read the first record of the current year/month/day instead of last record of previous year/month/day llprev = .FALSE. sdjf%nrec_a(1) = 1 CALL fld_clopn( sdjf ) ENDIF IF( llprev ) THEN ! check if the record sdjf%nrec_a(1) exists in the file idvar = iom_varid( sdjf%num, sdjf%clvar ) ! id of the variable sdjf%clvar IF( idvar <= 0 ) RETURN inrec = iom_file( sdjf%num )%dimsz( iom_file( sdjf%num )%ndims(idvar), idvar ) ! size of the last dim of idvar sdjf%nrec_a(1) = MIN( sdjf%nrec_a(1), inrec ) ! make sure we select an existing record ENDIF ! read before data in after arrays(as we will swap it later) CALL fld_get( sdjf, map ) clfmt = "('fld_init : time-interpolation for ', a, ' read previous record = ', i6, ' at time = ', f7.2, ' days')" IF(lwp) WRITE(numout, clfmt) TRIM(sdjf%clvar), sdjf%nrec_a(1), REAL(sdjf%nrec_a(2),wp)/rday ENDIF ! END SUBROUTINE fld_init SUBROUTINE fld_rec( kn_fsbc, sdjf, ldbefore, kit, kt_offset ) !!--------------------------------------------------------------------- !! *** ROUTINE fld_rec *** !! !! ** Purpose : Compute !! if sdjf%ln_tint = .TRUE. !! nrec_a: record number and its time (nrec_b is obtained from nrec_a when swapping) !! if sdjf%ln_tint = .FALSE. !! nrec_a(1): record number !! nrec_b(2) and nrec_a(2): time of the beginning and end of the record (for print only) !!---------------------------------------------------------------------- INTEGER , INTENT(in ) :: kn_fsbc ! sbc computation period (in time step) TYPE(FLD), INTENT(inout) :: sdjf ! input field related variables LOGICAL , INTENT(in ), OPTIONAL :: ldbefore ! sent back before record values (default = .FALSE.) INTEGER , INTENT(in ), OPTIONAL :: kit ! index of barotropic subcycle ! used only if sdjf%ln_tint = .TRUE. INTEGER , INTENT(in ), OPTIONAL :: kt_offset ! Offset of required time level compared to "now" ! time level in units of time steps. !! LOGICAL :: llbefore ! local definition of ldbefore INTEGER :: iendrec ! end of this record (in seconds) INTEGER :: imth ! month number INTEGER :: ifreq_sec ! frequency mean (in seconds) INTEGER :: isec_week ! number of seconds since the start of the weekly file INTEGER :: it_offset ! local time offset variable REAL(wp) :: ztmp ! temporary variable !!---------------------------------------------------------------------- ! ! Note that shifting time to be centrered in the middle of sbc time step impacts only nsec_* variables of the calendar ! IF( PRESENT(ldbefore) ) THEN ; llbefore = ldbefore .AND. sdjf%ln_tint ! needed only if sdjf%ln_tint = .TRUE. ELSE ; llbefore = .FALSE. ENDIF ! IF ( nn_components == jp_iam_sas ) THEN ; it_offset = nn_fsbc ELSE ; it_offset = 0 ENDIF IF( PRESENT(kt_offset) ) it_offset = kt_offset IF( PRESENT(kit) ) THEN ; it_offset = ( kit + it_offset ) * NINT( rdt/REAL(nn_baro,wp) ) ELSE ; it_offset = it_offset * NINT( rdttra(1) ) ENDIF ! ! ! =========== ! IF ( sdjf%nfreqh == -12 ) THEN ! yearly mean ! ! =========== ! ! IF( sdjf%ln_tint ) THEN ! time interpolation, shift by 1/2 record ! ! INT( ztmp ) ! /|\ ! 1 | *---- ! 0 |----( ! |----+----|--> time ! 0 /|\ 1 (nday/nyear_len(1)) ! | ! | ! forcing record : 1 ! ztmp = REAL( nsec_year, wp ) / ( REAL( nyear_len(1), wp ) * rday ) + 0.5 & & + REAL( it_offset, wp ) / ( REAL( nyear_len(1), wp ) * rday ) sdjf%nrec_a(1) = 1 + INT( ztmp ) - COUNT((/llbefore/)) ! swap at the middle of the year IF( llbefore ) THEN ; sdjf%nrec_a(2) = nsec1jan000 - (1 - INT(ztmp)) * NINT(0.5 * rday) * nyear_len(0) + & & INT(ztmp) * NINT( 0.5 * rday) * nyear_len(1) ELSE ; sdjf%nrec_a(2) = nsec1jan000 + (1 - INT(ztmp)) * NINT(0.5 * rday) * nyear_len(1) + & & INT(ztmp) * INT(rday) * nyear_len(1) + INT(ztmp) * NINT( 0.5 * rday) * nyear_len(2) ENDIF ELSE ! no time interpolation sdjf%nrec_a(1) = 1 sdjf%nrec_a(2) = NINT(rday) * nyear_len(1) + nsec1jan000 ! swap at the end of the year sdjf%nrec_b(2) = nsec1jan000 ! beginning of the year (only for print) ENDIF ! ! ! ============ ! ELSEIF( sdjf%nfreqh == -1 ) THEN ! monthly mean ! ! ! ============ ! ! IF( sdjf%ln_tint ) THEN ! time interpolation, shift by 1/2 record ! ! INT( ztmp ) ! /|\ ! 1 | *---- ! 0 |----( ! |----+----|--> time ! 0 /|\ 1 (nday/nmonth_len(nmonth)) ! | ! | ! forcing record : nmonth ! ztmp = REAL( nsec_month, wp ) / ( REAL( nmonth_len(nmonth), wp ) * rday ) + 0.5 & & + REAL( it_offset, wp ) / ( REAL( nmonth_len(nmonth), wp ) * rday ) imth = nmonth + INT( ztmp ) - COUNT((/llbefore/)) IF( sdjf%cltype == 'monthly' ) THEN ; sdjf%nrec_a(1) = 1 + INT( ztmp ) - COUNT((/llbefore/)) ELSE ; sdjf%nrec_a(1) = imth ENDIF sdjf%nrec_a(2) = nmonth_half( imth ) + nsec1jan000 ! swap at the middle of the month ELSE ! no time interpolation IF( sdjf%cltype == 'monthly' ) THEN ; sdjf%nrec_a(1) = 1 ELSE ; sdjf%nrec_a(1) = nmonth ENDIF sdjf%nrec_a(2) = nmonth_end(nmonth ) + nsec1jan000 ! swap at the end of the month sdjf%nrec_b(2) = nmonth_end(nmonth-1) + nsec1jan000 ! beginning of the month (only for print) ENDIF ! ! ! ================================ ! ELSE ! higher frequency mean (in hours) ! ! ================================ ! ! ifreq_sec = NINT( sdjf%nfreqh * 3600 ) ! frequency mean (in seconds) IF( sdjf%cltype(1:4) == 'week' ) isec_week = ksec_week( sdjf%cltype(6:8) ) ! since the first day of the current week ! number of second since the beginning of the file IF( sdjf%cltype == 'monthly' ) THEN ; ztmp = REAL(nsec_month,wp) ! since the first day of the current month ELSEIF( sdjf%cltype(1:4) == 'week' ) THEN ; ztmp = REAL(isec_week ,wp) ! since the first day of the current week ELSEIF( sdjf%cltype == 'daily' ) THEN ; ztmp = REAL(nsec_day ,wp) ! since 00h of the current day ELSE ; ztmp = REAL(nsec_year ,wp) ! since 00h on Jan 1 of the current year ENDIF ztmp = ztmp + 0.5 * REAL(kn_fsbc - 1, wp) * rdttra(1) + REAL( it_offset, wp ) ! centrered in the middle of sbc time step ztmp = ztmp + 0.01 * rdttra(1) ! avoid truncation error IF( sdjf%ln_tint ) THEN ! time interpolation, shift by 1/2 record ! ! INT( ztmp/ifreq_sec + 0.5 ) ! /|\ ! 2 | *-----( ! 1 | *-----( ! 0 |--( ! |--+--|--+--|--+--|--> time ! 0 /|\ 1 /|\ 2 /|\ 3 (ztmp/ifreq_sec) ! | | | ! | | | ! forcing record : 1 2 3 ! ztmp= ztmp / REAL(ifreq_sec, wp) + 0.5 ELSE ! no time interpolation ! ! INT( ztmp/ifreq_sec ) ! /|\ ! 2 | *-----( ! 1 | *-----( ! 0 |-----( ! |--+--|--+--|--+--|--> time ! 0 /|\ 1 /|\ 2 /|\ 3 (ztmp/ifreq_sec) ! | | | ! | | | ! forcing record : 1 2 3 ! ztmp= ztmp / REAL(ifreq_sec, wp) ENDIF sdjf%nrec_a(1) = 1 + INT( ztmp ) - COUNT((/llbefore/)) ! record number to be read iendrec = ifreq_sec * sdjf%nrec_a(1) + nsec1jan000 ! end of this record (in second) ! add the number of seconds between 00h Jan 1 and the end of previous month/week/day (ok if nmonth=1) IF( sdjf%cltype == 'monthly' ) iendrec = iendrec + NINT(rday) * SUM(nmonth_len(1:nmonth -1)) IF( sdjf%cltype(1:4) == 'week' ) iendrec = iendrec + ( nsec_year - isec_week ) IF( sdjf%cltype == 'daily' ) iendrec = iendrec + NINT(rday) * ( nday_year - 1 ) IF( sdjf%ln_tint ) THEN sdjf%nrec_a(2) = iendrec - ifreq_sec / 2 ! swap at the middle of the record ELSE sdjf%nrec_a(2) = iendrec ! swap at the end of the record sdjf%nrec_b(2) = iendrec - ifreq_sec ! beginning of the record (only for print) ENDIF ! ENDIF ! END SUBROUTINE fld_rec SUBROUTINE fld_get( sdjf, map ) !!--------------------------------------------------------------------- !! *** ROUTINE fld_get *** !! !! ** Purpose : read the data !!---------------------------------------------------------------------- TYPE(FLD), INTENT(inout) :: sdjf ! input field related variables TYPE(MAP_POINTER),INTENT(in) :: map ! global-to-local mapping indices !! INTEGER :: ipk ! number of vertical levels of sdjf%fdta ( 2D: ipk=1 ; 3D: ipk=jpk ) INTEGER :: iw ! index into wgts array INTEGER :: ipdom ! index of the domain INTEGER :: idvar ! variable ID INTEGER :: idmspc ! number of spatial dimensions LOGICAL :: lmoor ! C1D case: point data !!--------------------------------------------------------------------- ! ipk = SIZE( sdjf%fnow, 3 ) ! IF( ASSOCIATED(map%ptr) ) THEN IF( sdjf%ln_tint ) THEN ; CALL fld_map( sdjf%num, sdjf%clvar, sdjf%fdta(:,:,:,2), sdjf%nrec_a(1), map ) ELSE ; CALL fld_map( sdjf%num, sdjf%clvar, sdjf%fnow(:,:,: ), sdjf%nrec_a(1), map ) ENDIF ELSE IF( LEN(TRIM(sdjf%wgtname)) > 0 ) THEN CALL wgt_list( sdjf, iw ) IF( sdjf%ln_tint ) THEN ; CALL fld_interp( sdjf%num, sdjf%clvar, iw , ipk , sdjf%fdta(:,:,:,2), & & sdjf%nrec_a(1), sdjf%lsmname ) ELSE ; CALL fld_interp( sdjf%num, sdjf%clvar, iw , ipk , sdjf%fnow(:,:,: ), & & sdjf%nrec_a(1), sdjf%lsmname ) ENDIF ELSE IF( SIZE(sdjf%fnow, 1) == jpi ) THEN ; ipdom = jpdom_data ELSE ; ipdom = jpdom_unknown ENDIF ! C1D case: If product of spatial dimensions == ipk, then x,y are of ! size 1 (point/mooring data): this must be read onto the central grid point idvar = iom_varid( sdjf%num, sdjf%clvar ) idmspc = iom_file( sdjf%num )%ndims( idvar ) IF( iom_file( sdjf%num )%luld( idvar ) ) idmspc = idmspc - 1 lmoor = (idmspc == 0 .OR. PRODUCT( iom_file( sdjf%num )%dimsz( 1:MAX(idmspc,1) ,idvar ) ) == ipk) ! SELECT CASE( ipk ) CASE(1) IF( lk_c1d .AND. lmoor ) THEN IF( sdjf%ln_tint ) THEN CALL iom_get( sdjf%num, sdjf%clvar, sdjf%fdta(2,2,1,2), sdjf%nrec_a(1) ) CALL lbc_lnk( sdjf%fdta(:,:,1,2),'Z',1. ) ELSE CALL iom_get( sdjf%num, sdjf%clvar, sdjf%fnow(2,2,1 ), sdjf%nrec_a(1) ) CALL lbc_lnk( sdjf%fnow(:,:,1 ),'Z',1. ) ENDIF ELSE IF( sdjf%ln_tint ) THEN ; CALL iom_get( sdjf%num, ipdom, sdjf%clvar, sdjf%fdta(:,:,1,2), sdjf%nrec_a(1) ) ELSE ; CALL iom_get( sdjf%num, ipdom, sdjf%clvar, sdjf%fnow(:,:,1 ), sdjf%nrec_a(1) ) ENDIF ENDIF CASE DEFAULT IF (lk_c1d .AND. lmoor ) THEN IF( sdjf%ln_tint ) THEN CALL iom_get( sdjf%num, jpdom_unknown, sdjf%clvar, sdjf%fdta(2,2,:,2), sdjf%nrec_a(1) ) CALL lbc_lnk( sdjf%fdta(:,:,:,2),'Z',1. ) ELSE CALL iom_get( sdjf%num, jpdom_unknown, sdjf%clvar, sdjf%fnow(2,2,: ), sdjf%nrec_a(1) ) CALL lbc_lnk( sdjf%fnow(:,:,: ),'Z',1. ) ENDIF ELSE IF( sdjf%ln_tint ) THEN ; CALL iom_get( sdjf%num, ipdom, sdjf%clvar, sdjf%fdta(:,:,:,2), sdjf%nrec_a(1) ) ELSE ; CALL iom_get( sdjf%num, ipdom, sdjf%clvar, sdjf%fnow(:,:,: ), sdjf%nrec_a(1) ) ENDIF ENDIF END SELECT ENDIF ! sdjf%rotn(2) = .false. ! vector not yet rotated END SUBROUTINE fld_get SUBROUTINE fld_map( num, clvar, dta, nrec, map ) !!--------------------------------------------------------------------- !! *** ROUTINE fld_map *** !! !! ** Purpose : read global data from file and map onto local data !! using a general mapping (for open boundaries) !!---------------------------------------------------------------------- #if defined key_bdy USE bdy_oce, ONLY: dta_global, dta_global2 ! workspace to read in global data arrays #endif INTEGER , INTENT(in ) :: num ! stream number CHARACTER(LEN=*) , INTENT(in ) :: clvar ! variable name REAL(wp), DIMENSION(:,:,:), INTENT(out) :: dta ! output field on model grid (2 dimensional) INTEGER , INTENT(in ) :: nrec ! record number to read (ie time slice) TYPE(MAP_POINTER) , INTENT(in ) :: map ! global-to-local mapping indices !! INTEGER :: ipi ! length of boundary data on local process INTEGER :: ipj ! length of dummy dimension ( = 1 ) INTEGER :: ipk ! number of vertical levels of dta ( 2D: ipk=1 ; 3D: ipk=jpk ) INTEGER :: ilendta ! length of data in file INTEGER :: idvar ! variable ID INTEGER :: ib, ik, ji, jj ! loop counters INTEGER :: ierr REAL(wp), POINTER, DIMENSION(:,:,:) :: dta_read ! work space for global data !!--------------------------------------------------------------------- ipi = SIZE( dta, 1 ) ipj = 1 ipk = SIZE( dta, 3 ) idvar = iom_varid( num, clvar ) ilendta = iom_file(num)%dimsz(1,idvar) #if defined key_bdy ipj = iom_file(num)%dimsz(2,idvar) IF ( map%ll_unstruc) THEN ! unstructured open boundary data file dta_read => dta_global ELSE ! structured open boundary data file dta_read => dta_global2 ENDIF #endif IF(lwp) WRITE(numout,*) 'Dim size for ',TRIM(clvar),' is ', ilendta IF(lwp) WRITE(numout,*) 'Number of levels for ',TRIM(clvar),' is ', ipk SELECT CASE( ipk ) CASE(1) ; CALL iom_get ( num, jpdom_unknown, clvar, dta_read(1:ilendta,1:ipj,1 ), nrec ) CASE DEFAULT ; CALL iom_get ( num, jpdom_unknown, clvar, dta_read(1:ilendta,1:ipj,1:ipk), nrec ) END SELECT ! IF ( map%ll_unstruc ) THEN ! unstructured open boundary data file DO ib = 1, ipi DO ik = 1, ipk dta(ib,1,ik) = dta_read(map%ptr(ib),1,ik) END DO END DO ELSE ! structured open boundary data file DO ib = 1, ipi jj=1+floor(REAL(map%ptr(ib)-1)/REAL(ilendta)) ji=map%ptr(ib)-(jj-1)*ilendta DO ik = 1, ipk dta(ib,1,ik) = dta_read(ji,jj,ik) END DO END DO ENDIF END SUBROUTINE fld_map SUBROUTINE fld_rot( kt, sd ) !!--------------------------------------------------------------------- !! *** ROUTINE fld_rot *** !! !! ** Purpose : Vector fields may need to be rotated onto the local grid direction !!---------------------------------------------------------------------- INTEGER , INTENT(in ) :: kt ! ocean time step TYPE(FLD), INTENT(inout), DIMENSION(:) :: sd ! input field related variables !! INTEGER :: ju,jv,jk,jn ! loop indices INTEGER :: imf ! size of the structure sd INTEGER :: ill ! character length INTEGER :: iv ! indice of V component REAL(wp), POINTER, DIMENSION(:,:) :: utmp, vtmp ! temporary arrays for vector rotation CHARACTER (LEN=100) :: clcomp ! dummy weight name !!--------------------------------------------------------------------- CALL wrk_alloc( jpi,jpj, utmp, vtmp ) !! (sga: following code should be modified so that pairs arent searched for each time ! imf = SIZE( sd ) DO ju = 1, imf ill = LEN_TRIM( sd(ju)%vcomp ) DO jn = 2-COUNT((/sd(ju)%ln_tint/)), 2 IF( ill > 0 .AND. .NOT. sd(ju)%rotn(jn) ) THEN ! find vector rotations required IF( sd(ju)%vcomp(1:1) == 'U' ) THEN ! east-west component has symbolic name starting with 'U' ! look for the north-south component which has same symbolic name but with 'U' replaced with 'V' clcomp = 'V' // sd(ju)%vcomp(2:ill) ! works even if ill == 1 iv = -1 DO jv = 1, imf IF( TRIM(sd(jv)%vcomp) == TRIM(clcomp) ) iv = jv END DO IF( iv > 0 ) THEN ! fields ju and iv are two components which need to be rotated together DO jk = 1, SIZE( sd(ju)%fnow, 3 ) IF( sd(ju)%ln_tint )THEN CALL rot_rep( sd(ju)%fdta(:,:,jk,jn), sd(iv)%fdta(:,:,jk,jn), 'T', 'en->i', utmp(:,:) ) CALL rot_rep( sd(ju)%fdta(:,:,jk,jn), sd(iv)%fdta(:,:,jk,jn), 'T', 'en->j', vtmp(:,:) ) sd(ju)%fdta(:,:,jk,jn) = utmp(:,:) ; sd(iv)%fdta(:,:,jk,jn) = vtmp(:,:) ELSE CALL rot_rep( sd(ju)%fnow(:,:,jk ), sd(iv)%fnow(:,:,jk ), 'T', 'en->i', utmp(:,:) ) CALL rot_rep( sd(ju)%fnow(:,:,jk ), sd(iv)%fnow(:,:,jk ), 'T', 'en->j', vtmp(:,:) ) sd(ju)%fnow(:,:,jk ) = utmp(:,:) ; sd(iv)%fnow(:,:,jk ) = vtmp(:,:) ENDIF END DO sd(ju)%rotn(jn) = .TRUE. ! vector was rotated IF( lwp .AND. kt == nit000 ) WRITE(numout,*) & & 'fld_read: vector pair ('//TRIM(sd(ju)%clvar)//', '//TRIM(sd(iv)%clvar)//') rotated on to model grid' ENDIF ENDIF ENDIF END DO END DO ! CALL wrk_dealloc( jpi,jpj, utmp, vtmp ) ! END SUBROUTINE fld_rot SUBROUTINE fld_clopn( sdjf, kyear, kmonth, kday, ldstop ) !!--------------------------------------------------------------------- !! *** ROUTINE fld_clopn *** !! !! ** Purpose : update the file name and open the file !!---------------------------------------------------------------------- TYPE(FLD) , INTENT(inout) :: sdjf ! input field related variables INTEGER, OPTIONAL, INTENT(in ) :: kyear ! year value INTEGER, OPTIONAL, INTENT(in ) :: kmonth ! month value INTEGER, OPTIONAL, INTENT(in ) :: kday ! day value LOGICAL, OPTIONAL, INTENT(in ) :: ldstop ! stop if open to read a non-existing file (default = .TRUE.) !! LOGICAL :: llprevyr ! are we reading previous year file? LOGICAL :: llprevmth ! are we reading previous month file? INTEGER :: iyear, imonth, iday ! first day of the current file in yyyy mm dd INTEGER :: isec_week ! number of seconds since start of the weekly file INTEGER :: indexyr ! year undex (O/1/2: previous/current/next) INTEGER :: iyear_len, imonth_len ! length (days) of iyear and imonth ! CHARACTER(len = 256):: clname ! temporary file name !!---------------------------------------------------------------------- IF( PRESENT(kyear) ) THEN ! use given values iyear = kyear imonth = kmonth iday = kday IF ( sdjf%cltype(1:4) == 'week' ) THEN ! find the day of the beginning of the week isec_week = ksec_week( sdjf%cltype(6:8) )- (86400 * 8 ) llprevmth = isec_week > nsec_month ! longer time since beginning of the week than the month llprevyr = llprevmth .AND. nmonth == 1 iyear = nyear - COUNT((/llprevyr /)) imonth = nmonth - COUNT((/llprevmth/)) + 12 * COUNT((/llprevyr /)) iday = nday + nmonth_len(nmonth-1) * COUNT((/llprevmth/)) - isec_week / NINT(rday) ENDIF ELSE ! use current day values IF ( sdjf%cltype(1:4) == 'week' ) THEN ! find the day of the beginning of the week isec_week = ksec_week( sdjf%cltype(6:8) ) ! second since the beginning of the week llprevmth = isec_week > nsec_month ! longer time since beginning of the week than the month llprevyr = llprevmth .AND. nmonth == 1 ELSE isec_week = 0 llprevmth = .FALSE. llprevyr = .FALSE. ENDIF iyear = nyear - COUNT((/llprevyr /)) imonth = nmonth - COUNT((/llprevmth/)) + 12 * COUNT((/llprevyr /)) iday = nday + nmonth_len(nmonth-1) * COUNT((/llprevmth/)) - isec_week / NINT(rday) ENDIF ! build the new filename if not climatological data clname=TRIM(sdjf%clrootname) ! ! note that sdjf%ln_clim is is only acting on the presence of the year in the file name IF( .NOT. sdjf%ln_clim ) THEN WRITE(clname, '(a,"_y",i4.4)' ) TRIM( sdjf%clrootname ), iyear ! add year IF( sdjf%cltype /= 'yearly' ) WRITE(clname, '(a,"m" ,i2.2)' ) TRIM( clname ), imonth ! add month ELSE ! build the new filename if climatological data IF( sdjf%cltype /= 'yearly' ) WRITE(clname, '(a,"_m",i2.2)' ) TRIM( sdjf%clrootname ), imonth ! add month ENDIF IF( sdjf%cltype == 'daily' .OR. sdjf%cltype(1:4) == 'week' ) & & WRITE(clname, '(a,"d" ,i2.2)' ) TRIM( clname ), iday ! add day ! IF( TRIM(clname) /= TRIM(sdjf%clname) .OR. sdjf%num == 0 ) THEN ! new file to be open sdjf%clname = TRIM(clname) IF( sdjf%num /= 0 ) CALL iom_close( sdjf%num ) ! close file if already open CALL iom_open( sdjf%clname, sdjf%num, ldstop = ldstop, ldiof = LEN(TRIM(sdjf%wgtname)) > 0 ) ! find the last record to be read -> update sdjf%nreclast indexyr = iyear - nyear + 1 iyear_len = nyear_len( indexyr ) SELECT CASE ( indexyr ) CASE ( 0 ) ; imonth_len = 31 ! previous year -> imonth = 12 CASE ( 1 ) ; imonth_len = nmonth_len(imonth) CASE ( 2 ) ; imonth_len = 31 ! next year -> imonth = 1 END SELECT ! last record to be read in the current file IF ( sdjf%nfreqh == -12 ) THEN ; sdjf%nreclast = 1 ! yearly mean ELSEIF( sdjf%nfreqh == -1 ) THEN ! monthly mean IF( sdjf%cltype == 'monthly' ) THEN ; sdjf%nreclast = 1 ELSE ; sdjf%nreclast = 12 ENDIF ELSE ! higher frequency mean (in hours) IF( sdjf%cltype == 'monthly' ) THEN ; sdjf%nreclast = NINT( 24 * imonth_len / sdjf%nfreqh ) ELSEIF( sdjf%cltype(1:4) == 'week' ) THEN ; sdjf%nreclast = NINT( 24 * 7 / sdjf%nfreqh ) ELSEIF( sdjf%cltype == 'daily' ) THEN ; sdjf%nreclast = NINT( 24 / sdjf%nfreqh ) ELSE ; sdjf%nreclast = NINT( 24 * iyear_len / sdjf%nfreqh ) ENDIF ENDIF ENDIF ! END SUBROUTINE fld_clopn SUBROUTINE fld_fill( sdf, sdf_n, cdir, cdcaller, cdtitle, cdnam ) !!--------------------------------------------------------------------- !! *** ROUTINE fld_fill *** !! !! ** Purpose : fill sdf with sdf_n and control print !!---------------------------------------------------------------------- TYPE(FLD) , DIMENSION(:), INTENT(inout) :: sdf ! structure of input fields (file informations, fields read) TYPE(FLD_N), DIMENSION(:), INTENT(in ) :: sdf_n ! array of namelist information structures CHARACTER(len=*) , INTENT(in ) :: cdir ! Root directory for location of flx files CHARACTER(len=*) , INTENT(in ) :: cdcaller ! CHARACTER(len=*) , INTENT(in ) :: cdtitle ! CHARACTER(len=*) , INTENT(in ) :: cdnam ! ! INTEGER :: jf ! dummy indices !!--------------------------------------------------------------------- DO jf = 1, SIZE(sdf) sdf(jf)%clrootname = TRIM( cdir )//TRIM( sdf_n(jf)%clname ) sdf(jf)%clname = "not yet defined" sdf(jf)%nfreqh = sdf_n(jf)%nfreqh sdf(jf)%clvar = sdf_n(jf)%clvar sdf(jf)%ln_tint = sdf_n(jf)%ln_tint sdf(jf)%ln_clim = sdf_n(jf)%ln_clim sdf(jf)%cltype = sdf_n(jf)%cltype sdf(jf)%num = -1 sdf(jf)%wgtname = " " IF( LEN( TRIM(sdf_n(jf)%wname) ) > 0 ) sdf(jf)%wgtname = TRIM( cdir )//TRIM( sdf_n(jf)%wname ) sdf(jf)%lsmname = " " IF( LEN( TRIM(sdf_n(jf)%lname) ) > 0 ) sdf(jf)%lsmname = TRIM( cdir )//TRIM( sdf_n(jf)%lname ) sdf(jf)%vcomp = sdf_n(jf)%vcomp sdf(jf)%rotn(:) = .TRUE. ! pretend to be rotated -> won't try to rotate data before the first call to fld_get IF( sdf(jf)%cltype(1:4) == 'week' .AND. nn_leapy == 0 ) & & CALL ctl_stop('fld_clopn: weekly file ('//TRIM(sdf(jf)%clrootname)//') needs nn_leapy = 1') IF( sdf(jf)%cltype(1:4) == 'week' .AND. sdf(jf)%ln_clim ) & & CALL ctl_stop('fld_clopn: weekly file ('//TRIM(sdf(jf)%clrootname)//') needs ln_clim = .FALSE.') sdf(jf)%nreclast = -1 ! Set to non zero default value to avoid errors, is updated to meaningful value during fld_clopn END DO IF(lwp) THEN ! control print WRITE(numout,*) WRITE(numout,*) TRIM( cdcaller )//' : '//TRIM( cdtitle ) WRITE(numout,*) (/ ('~', jf = 1, LEN_TRIM( cdcaller ) ) /) WRITE(numout,*) ' '//TRIM( cdnam )//' Namelist' WRITE(numout,*) ' list of files and frequency (>0: in hours ; <0 in months)' DO jf = 1, SIZE(sdf) WRITE(numout,*) ' root filename: ' , TRIM( sdf(jf)%clrootname ), & & ' variable name: ' , TRIM( sdf(jf)%clvar ) WRITE(numout,*) ' frequency: ' , sdf(jf)%nfreqh , & & ' time interp: ' , sdf(jf)%ln_tint , & & ' climatology: ' , sdf(jf)%ln_clim , & & ' weights : ' , TRIM( sdf(jf)%wgtname ), & & ' pairing : ' , TRIM( sdf(jf)%vcomp ), & & ' data type: ' , sdf(jf)%cltype , & & ' land/sea mask:' , TRIM( sdf(jf)%lsmname ) call flush(numout) END DO ENDIF END SUBROUTINE fld_fill SUBROUTINE wgt_list( sd, kwgt ) !!--------------------------------------------------------------------- !! *** ROUTINE wgt_list *** !! !! ** Purpose : search array of WGTs and find a weights file !! entry, or return a new one adding it to the end !! if it is a new entry, the weights data is read in and !! restructured (fld_weight) !!---------------------------------------------------------------------- TYPE( FLD ), INTENT(in ) :: sd ! field with name of weights file INTEGER , INTENT(inout) :: kwgt ! index of weights !! INTEGER :: kw, nestid ! local integer LOGICAL :: found ! local logical !!---------------------------------------------------------------------- ! !! search down linked list !! weights filename is either present or we hit the end of the list found = .FALSE. !! because agrif nest part of filenames are now added in iom_open !! to distinguish between weights files on the different grids, need to track !! nest number explicitly nestid = 0 #if defined key_agrif nestid = Agrif_Fixed() #endif DO kw = 1, nxt_wgt-1 IF( TRIM(ref_wgts(kw)%wgtname) == TRIM(sd%wgtname) .AND. & ref_wgts(kw)%nestid == nestid) THEN kwgt = kw found = .TRUE. EXIT ENDIF END DO IF( .NOT.found ) THEN kwgt = nxt_wgt CALL fld_weight( sd ) ENDIF ! END SUBROUTINE wgt_list SUBROUTINE wgt_print( ) !!--------------------------------------------------------------------- !! *** ROUTINE wgt_print *** !! !! ** Purpose : print the list of known weights !!---------------------------------------------------------------------- INTEGER :: kw ! !!---------------------------------------------------------------------- ! DO kw = 1, nxt_wgt-1 WRITE(numout,*) 'weight file: ',TRIM(ref_wgts(kw)%wgtname) WRITE(numout,*) ' ddims: ',ref_wgts(kw)%ddims(1),ref_wgts(kw)%ddims(2) WRITE(numout,*) ' numwgt: ',ref_wgts(kw)%numwgt WRITE(numout,*) ' jpiwgt: ',ref_wgts(kw)%jpiwgt WRITE(numout,*) ' jpjwgt: ',ref_wgts(kw)%jpjwgt WRITE(numout,*) ' botleft: ',ref_wgts(kw)%botleft WRITE(numout,*) ' topright: ',ref_wgts(kw)%topright IF( ref_wgts(kw)%cyclic ) THEN WRITE(numout,*) ' cyclical' IF( ref_wgts(kw)%overlap > 0 ) WRITE(numout,*) ' with overlap of ', ref_wgts(kw)%overlap ELSE WRITE(numout,*) ' not cyclical' ENDIF IF( ASSOCIATED(ref_wgts(kw)%data_wgt) ) WRITE(numout,*) ' allocated' END DO ! END SUBROUTINE wgt_print SUBROUTINE fld_weight( sd ) !!--------------------------------------------------------------------- !! *** ROUTINE fld_weight *** !! !! ** Purpose : create a new WGT structure and fill in data from !! file, restructuring as required !!---------------------------------------------------------------------- TYPE( FLD ), INTENT(in) :: sd ! field with name of weights file !! INTEGER :: jn ! dummy loop indices INTEGER :: inum ! temporary logical unit INTEGER :: id ! temporary variable id INTEGER :: ipk ! temporary vertical dimension CHARACTER (len=5) :: aname INTEGER , DIMENSION(:), ALLOCATABLE :: ddims INTEGER , POINTER, DIMENSION(:,:) :: data_src REAL(wp), POINTER, DIMENSION(:,:) :: data_tmp LOGICAL :: cyclical INTEGER :: zwrap ! local integer !!---------------------------------------------------------------------- ! CALL wrk_alloc( jpi,jpj, data_src ) ! integer CALL wrk_alloc( jpi,jpj, data_tmp ) ! IF( nxt_wgt > tot_wgts ) THEN CALL ctl_stop("fld_weight: weights array size exceeded, increase tot_wgts") ENDIF ! !! new weights file entry, add in extra information !! a weights file represents a 2D grid of a certain shape, so we assume that the current !! input data file is representative of all other files to be opened and processed with the !! current weights file !! open input data file (non-model grid) CALL iom_open( sd%clname, inum, ldiof = LEN(TRIM(sd%wgtname)) > 0 ) !! get dimensions IF ( SIZE(sd%fnow, 3) > 1 ) THEN ALLOCATE( ddims(4) ) ELSE ALLOCATE( ddims(3) ) ENDIF id = iom_varid( inum, sd%clvar, ddims ) !! close it CALL iom_close( inum ) !! now open the weights file CALL iom_open ( sd%wgtname, inum ) ! interpolation weights IF ( inum > 0 ) THEN !! determine whether we have an east-west cyclic grid !! from global attribute called "ew_wrap" in the weights file !! note that if not found, iom_getatt returns -999 and cyclic with no overlap is assumed !! since this is the most common forcing configuration CALL iom_getatt(inum, 'ew_wrap', zwrap) IF( zwrap >= 0 ) THEN cyclical = .TRUE. ELSE IF( zwrap == -999 ) THEN cyclical = .TRUE. zwrap = 0 ELSE cyclical = .FALSE. ENDIF ref_wgts(nxt_wgt)%ddims(1) = ddims(1) ref_wgts(nxt_wgt)%ddims(2) = ddims(2) ref_wgts(nxt_wgt)%wgtname = sd%wgtname ref_wgts(nxt_wgt)%overlap = zwrap ref_wgts(nxt_wgt)%cyclic = cyclical ref_wgts(nxt_wgt)%nestid = 0 #if defined key_agrif ref_wgts(nxt_wgt)%nestid = Agrif_Fixed() #endif !! weights file is stored as a set of weights (wgt01->wgt04 or wgt01->wgt16) !! for each weight wgtNN there is an integer array srcNN which gives the point in !! the input data grid which is to be multiplied by the weight !! they are both arrays on the model grid so the result of the multiplication is !! added into an output array on the model grid as a running sum !! two possible cases: bilinear (4 weights) or bicubic (16 weights) id = iom_varid(inum, 'src05', ldstop=.FALSE.) IF( id <= 0) THEN ref_wgts(nxt_wgt)%numwgt = 4 ELSE ref_wgts(nxt_wgt)%numwgt = 16 ENDIF ALLOCATE( ref_wgts(nxt_wgt)%data_jpi(jpi,jpj,4) ) ALLOCATE( ref_wgts(nxt_wgt)%data_jpj(jpi,jpj,4) ) ALLOCATE( ref_wgts(nxt_wgt)%data_wgt(jpi,jpj,ref_wgts(nxt_wgt)%numwgt) ) DO jn = 1,4 aname = ' ' WRITE(aname,'(a3,i2.2)') 'src',jn data_tmp(:,:) = 0 CALL iom_get ( inum, jpdom_data, aname, data_tmp(:,:) ) data_src(:,:) = INT(data_tmp(:,:)) ref_wgts(nxt_wgt)%data_jpj(:,:,jn) = 1 + (data_src(:,:)-1) / ref_wgts(nxt_wgt)%ddims(1) ref_wgts(nxt_wgt)%data_jpi(:,:,jn) = data_src(:,:) - ref_wgts(nxt_wgt)%ddims(1)*(ref_wgts(nxt_wgt)%data_jpj(:,:,jn)-1) END DO DO jn = 1, ref_wgts(nxt_wgt)%numwgt aname = ' ' WRITE(aname,'(a3,i2.2)') 'wgt',jn ref_wgts(nxt_wgt)%data_wgt(:,:,jn) = 0.0 CALL iom_get ( inum, jpdom_data, aname, ref_wgts(nxt_wgt)%data_wgt(:,:,jn) ) END DO CALL iom_close (inum) ! find min and max indices in grid ref_wgts(nxt_wgt)%botleft(1) = MINVAL(ref_wgts(nxt_wgt)%data_jpi(:,:,:)) ref_wgts(nxt_wgt)%botleft(2) = MINVAL(ref_wgts(nxt_wgt)%data_jpj(:,:,:)) ref_wgts(nxt_wgt)%topright(1) = MAXVAL(ref_wgts(nxt_wgt)%data_jpi(:,:,:)) ref_wgts(nxt_wgt)%topright(2) = MAXVAL(ref_wgts(nxt_wgt)%data_jpj(:,:,:)) ! and therefore dimensions of the input box ref_wgts(nxt_wgt)%jpiwgt = ref_wgts(nxt_wgt)%topright(1) - ref_wgts(nxt_wgt)%botleft(1) + 1 ref_wgts(nxt_wgt)%jpjwgt = ref_wgts(nxt_wgt)%topright(2) - ref_wgts(nxt_wgt)%botleft(2) + 1 ! shift indexing of source grid ref_wgts(nxt_wgt)%data_jpi(:,:,:) = ref_wgts(nxt_wgt)%data_jpi(:,:,:) - ref_wgts(nxt_wgt)%botleft(1) + 1 ref_wgts(nxt_wgt)%data_jpj(:,:,:) = ref_wgts(nxt_wgt)%data_jpj(:,:,:) - ref_wgts(nxt_wgt)%botleft(2) + 1 ! create input grid, give it a halo to allow gradient calculations ! SA: +3 stencil is a patch to avoid out-of-bound computation in some configuration. ! a more robust solution will be given in next release ipk = SIZE(sd%fnow, 3) ALLOCATE( ref_wgts(nxt_wgt)%fly_dta(ref_wgts(nxt_wgt)%jpiwgt+3, ref_wgts(nxt_wgt)%jpjwgt+3 ,ipk) ) IF( ref_wgts(nxt_wgt)%cyclic ) ALLOCATE( ref_wgts(nxt_wgt)%col(1,ref_wgts(nxt_wgt)%jpjwgt+3,ipk) ) nxt_wgt = nxt_wgt + 1 ELSE CALL ctl_stop( ' fld_weight : unable to read the file ' ) ENDIF DEALLOCATE (ddims ) CALL wrk_dealloc( jpi,jpj, data_src ) ! integer CALL wrk_dealloc( jpi,jpj, data_tmp ) ! END SUBROUTINE fld_weight SUBROUTINE apply_seaoverland(clmaskfile,zfieldo,jpi1_lsm,jpi2_lsm,jpj1_lsm, & & jpj2_lsm,itmpi,itmpj,itmpz,rec1_lsm,recn_lsm) !!--------------------------------------------------------------------- !! *** ROUTINE apply_seaoverland *** !! !! ** Purpose : avoid spurious fluxes in coastal or near-coastal areas !! due to the wrong usage of "land" values from the coarse !! atmospheric model when spatial interpolation is required !! D. Delrosso INGV !!---------------------------------------------------------------------- INTEGER :: inum,jni,jnj,jnz,jc ! temporary indices INTEGER, INTENT(in) :: itmpi,itmpj,itmpz ! lengths INTEGER, INTENT(in) :: jpi1_lsm,jpi2_lsm,jpj1_lsm,jpj2_lsm ! temporary indices INTEGER, DIMENSION(3), INTENT(in) :: rec1_lsm,recn_lsm ! temporary arrays for start and length REAL(wp),DIMENSION (:,:,:),INTENT(inout) :: zfieldo ! input/output array for seaoverland application REAL(wp),DIMENSION (:,:,:),ALLOCATABLE :: zslmec1 ! temporary array for land point detection REAL(wp),DIMENSION (:,:), ALLOCATABLE :: zfieldn ! array of forcing field with undeff for land points REAL(wp),DIMENSION (:,:), ALLOCATABLE :: zfield ! array of forcing field CHARACTER (len=100), INTENT(in) :: clmaskfile ! land/sea mask file name !!--------------------------------------------------------------------- ALLOCATE ( zslmec1(itmpi,itmpj,itmpz) ) ALLOCATE ( zfieldn(itmpi,itmpj) ) ALLOCATE ( zfield(itmpi,itmpj) ) ! Retrieve the land sea mask data CALL iom_open( clmaskfile, inum ) SELECT CASE( SIZE(zfieldo(jpi1_lsm:jpi2_lsm,jpj1_lsm:jpj2_lsm,:),3) ) CASE(1) CALL iom_get( inum, jpdom_unknown, 'LSM', zslmec1(jpi1_lsm:jpi2_lsm,jpj1_lsm:jpj2_lsm,1), 1, rec1_lsm, recn_lsm) CASE DEFAULT CALL iom_get( inum, jpdom_unknown, 'LSM', zslmec1(jpi1_lsm:jpi2_lsm,jpj1_lsm:jpj2_lsm,:), 1, rec1_lsm, recn_lsm) END SELECT CALL iom_close( inum ) DO jnz=1,rec1_lsm(3) !! Loop over k dimension DO jni=1,itmpi !! copy the original field into a tmp array DO jnj=1,itmpj !! substituting undeff over land points zfieldn(jni,jnj) = zfieldo(jni,jnj,jnz) IF ( zslmec1(jni,jnj,jnz) == 1. ) THEN zfieldn(jni,jnj) = undeff_lsm ENDIF END DO END DO CALL seaoverland(zfieldn,itmpi,itmpj,zfield) DO jc=1,nn_lsm CALL seaoverland(zfield,itmpi,itmpj,zfield) END DO ! Check for Undeff and substitute original values IF(ANY(zfield==undeff_lsm)) THEN DO jni=1,itmpi DO jnj=1,itmpj IF (zfield(jni,jnj)==undeff_lsm) THEN zfield(jni,jnj) = zfieldo(jni,jnj,jnz) ENDIF ENDDO ENDDO ENDIF zfieldo(:,:,jnz)=zfield(:,:) END DO !! End Loop over k dimension DEALLOCATE ( zslmec1 ) DEALLOCATE ( zfieldn ) DEALLOCATE ( zfield ) END SUBROUTINE apply_seaoverland SUBROUTINE seaoverland(zfieldn,ileni,ilenj,zfield) !!--------------------------------------------------------------------- !! *** ROUTINE seaoverland *** !! !! ** Purpose : create shifted matrices for seaoverland application !! D. Delrosso INGV !!---------------------------------------------------------------------- INTEGER,INTENT(in) :: ileni,ilenj ! lengths REAL,DIMENSION (ileni,ilenj),INTENT(in) :: zfieldn ! array of forcing field with undeff for land points REAL,DIMENSION (ileni,ilenj),INTENT(out) :: zfield ! array of forcing field REAL,DIMENSION (ileni,ilenj) :: zmat1,zmat2,zmat3,zmat4 ! temporary arrays for seaoverland application REAL,DIMENSION (ileni,ilenj) :: zmat5,zmat6,zmat7,zmat8 ! temporary arrays for seaoverland application REAL,DIMENSION (ileni,ilenj) :: zlsm2d ! temporary arrays for seaoverland application REAL,DIMENSION (ileni,ilenj,8) :: zlsm3d ! temporary arrays for seaoverland application LOGICAL,DIMENSION (ileni,ilenj,8) :: ll_msknan3d ! logical mask for undeff detection LOGICAL,DIMENSION (ileni,ilenj) :: ll_msknan2d ! logical mask for undeff detection !!---------------------------------------------------------------------- zmat8 = eoshift(zfieldn , SHIFT=-1, BOUNDARY = (/zfieldn(:,1)/) ,DIM=2) zmat1 = eoshift(zmat8 , SHIFT=-1, BOUNDARY = (/zmat8(1,:)/) ,DIM=1) zmat2 = eoshift(zfieldn , SHIFT=-1, BOUNDARY = (/zfieldn(1,:)/) ,DIM=1) zmat4 = eoshift(zfieldn , SHIFT= 1, BOUNDARY = (/zfieldn(:,ilenj)/),DIM=2) zmat3 = eoshift(zmat4 , SHIFT=-1, BOUNDARY = (/zmat4(1,:)/) ,DIM=1) zmat5 = eoshift(zmat4 , SHIFT= 1, BOUNDARY = (/zmat4(ileni,:)/) ,DIM=1) zmat6 = eoshift(zfieldn , SHIFT= 1, BOUNDARY = (/zfieldn(ileni,:)/),DIM=1) zmat7 = eoshift(zmat8 , SHIFT= 1, BOUNDARY = (/zmat8(ileni,:)/) ,DIM=1) zlsm3d = RESHAPE( (/ zmat1, zmat2, zmat3, zmat4, zmat5, zmat6, zmat7, zmat8 /), (/ ileni, ilenj, 8 /)) ll_msknan3d = .not.(zlsm3d==undeff_lsm) ll_msknan2d = .not.(zfieldn==undeff_lsm) ! FALSE where is Undeff (land) zlsm2d = (SUM ( zlsm3d, 3 , ll_msknan3d ) )/(MAX(1,(COUNT( ll_msknan3d , 3 )) )) WHERE ((COUNT( ll_msknan3d , 3 )) == 0.0_wp) zlsm2d = undeff_lsm zfield = MERGE (zfieldn,zlsm2d,ll_msknan2d) END SUBROUTINE seaoverland SUBROUTINE fld_interp( num, clvar, kw, kk, dta, & & nrec, lsmfile) !!--------------------------------------------------------------------- !! *** ROUTINE fld_interp *** !! !! ** Purpose : apply weights to input gridded data to create data !! on model grid !!---------------------------------------------------------------------- INTEGER , INTENT(in ) :: num ! stream number CHARACTER(LEN=*) , INTENT(in ) :: clvar ! variable name INTEGER , INTENT(in ) :: kw ! weights number INTEGER , INTENT(in ) :: kk ! vertical dimension of kk REAL(wp), DIMENSION(:,:,:), INTENT(inout) :: dta ! output field on model grid INTEGER , INTENT(in ) :: nrec ! record number to read (ie time slice) CHARACTER(LEN=*) , INTENT(in ) :: lsmfile ! land sea mask file name !! REAL(wp),DIMENSION(:,:,:),ALLOCATABLE :: ztmp_fly_dta ! temporary array of values on input grid INTEGER, DIMENSION(3) :: rec1,recn ! temporary arrays for start and length INTEGER, DIMENSION(3) :: rec1_lsm,recn_lsm ! temporary arrays for start and length in case of seaoverland INTEGER :: ii_lsm1,ii_lsm2,ij_lsm1,ij_lsm2 ! temporary indices INTEGER :: jk, jn, jm, jir, jjr ! loop counters INTEGER :: ni, nj ! lengths INTEGER :: jpimin,jpiwid ! temporary indices INTEGER :: jpimin_lsm,jpiwid_lsm ! temporary indices INTEGER :: jpjmin,jpjwid ! temporary indices INTEGER :: jpjmin_lsm,jpjwid_lsm ! temporary indices INTEGER :: jpi1,jpi2,jpj1,jpj2 ! temporary indices INTEGER :: jpi1_lsm,jpi2_lsm,jpj1_lsm,jpj2_lsm ! temporary indices INTEGER :: itmpi,itmpj,itmpz ! lengths !!---------------------------------------------------------------------- ! !! for weighted interpolation we have weights at four corners of a box surrounding !! a model grid point, each weight is multiplied by a grid value (bilinear case) !! or by a grid value and gradients at the corner point (bicubic case) !! so we need to have a 4 by 4 subgrid surrounding each model point to cover both cases !! sub grid from non-model input grid which encloses all grid points in this nemo process jpimin = ref_wgts(kw)%botleft(1) jpjmin = ref_wgts(kw)%botleft(2) jpiwid = ref_wgts(kw)%jpiwgt jpjwid = ref_wgts(kw)%jpjwgt !! when reading in, expand this sub-grid by one halo point all the way round for calculating gradients rec1(1) = MAX( jpimin-1, 1 ) rec1(2) = MAX( jpjmin-1, 1 ) rec1(3) = 1 recn(1) = MIN( jpiwid+2, ref_wgts(kw)%ddims(1)-rec1(1)+1 ) recn(2) = MIN( jpjwid+2, ref_wgts(kw)%ddims(2)-rec1(2)+1 ) recn(3) = kk !! where we need to put it in the non-nemo grid fly_dta !! note that jpi1 and jpj1 only differ from 1 when jpimin and jpjmin are 1 !! (ie at the extreme west or south of the whole input grid) and similarly for jpi2 and jpj2 jpi1 = 2 + rec1(1) - jpimin jpj1 = 2 + rec1(2) - jpjmin jpi2 = jpi1 + recn(1) - 1 jpj2 = jpj1 + recn(2) - 1 IF( LEN( TRIM(lsmfile) ) > 0 ) THEN !! indeces for ztmp_fly_dta ! -------------------------- rec1_lsm(1)=MAX(rec1(1)-nn_lsm,1) ! starting index for enlarged external data, x direction rec1_lsm(2)=MAX(rec1(2)-nn_lsm,1) ! starting index for enlarged external data, y direction rec1_lsm(3) = 1 ! vertical dimension recn_lsm(1)=MIN(rec1(1)-rec1_lsm(1)+recn(1)+nn_lsm,ref_wgts(kw)%ddims(1)-rec1_lsm(1)) ! n points in x direction recn_lsm(2)=MIN(rec1(2)-rec1_lsm(2)+recn(2)+nn_lsm,ref_wgts(kw)%ddims(2)-rec1_lsm(2)) ! n points in y direction recn_lsm(3) = kk ! number of vertical levels in the input file ! Avoid out of bound jpimin_lsm = MAX( rec1_lsm(1)+1, 1 ) jpjmin_lsm = MAX( rec1_lsm(2)+1, 1 ) jpiwid_lsm = MIN( recn_lsm(1)-2,ref_wgts(kw)%ddims(1)-rec1(1)+1) jpjwid_lsm = MIN( recn_lsm(2)-2,ref_wgts(kw)%ddims(2)-rec1(2)+1) jpi1_lsm = 2+rec1_lsm(1)-jpimin_lsm jpj1_lsm = 2+rec1_lsm(2)-jpjmin_lsm jpi2_lsm = jpi1_lsm + recn_lsm(1) - 1 jpj2_lsm = jpj1_lsm + recn_lsm(2) - 1 itmpi=jpi2_lsm-jpi1_lsm+1 itmpj=jpj2_lsm-jpj1_lsm+1 itmpz=kk ALLOCATE(ztmp_fly_dta(itmpi,itmpj,itmpz)) ztmp_fly_dta(:,:,:) = 0.0 SELECT CASE( SIZE(ztmp_fly_dta(jpi1_lsm:jpi2_lsm,jpj1_lsm:jpj2_lsm,:),3) ) CASE(1) CALL iom_get( num, jpdom_unknown, clvar, ztmp_fly_dta(jpi1_lsm:jpi2_lsm,jpj1_lsm:jpj2_lsm,1), & & nrec, rec1_lsm, recn_lsm) CASE DEFAULT CALL iom_get( num, jpdom_unknown, clvar, ztmp_fly_dta(jpi1_lsm:jpi2_lsm,jpj1_lsm:jpj2_lsm,:), & & nrec, rec1_lsm, recn_lsm) END SELECT CALL apply_seaoverland(lsmfile,ztmp_fly_dta(jpi1_lsm:jpi2_lsm,jpj1_lsm:jpj2_lsm,:), & & jpi1_lsm,jpi2_lsm,jpj1_lsm,jpj2_lsm, & & itmpi,itmpj,itmpz,rec1_lsm,recn_lsm) ! Relative indeces for remapping ii_lsm1 = (rec1(1)-rec1_lsm(1))+1 ii_lsm2 = (ii_lsm1+recn(1))-1 ij_lsm1 = (rec1(2)-rec1_lsm(2))+1 ij_lsm2 = (ij_lsm1+recn(2))-1 ref_wgts(kw)%fly_dta(:,:,:) = 0.0 ref_wgts(kw)%fly_dta(jpi1:jpi2,jpj1:jpj2,:) = ztmp_fly_dta(ii_lsm1:ii_lsm2,ij_lsm1:ij_lsm2,:) DEALLOCATE(ztmp_fly_dta) ELSE ref_wgts(kw)%fly_dta(:,:,:) = 0.0 SELECT CASE( SIZE(ref_wgts(kw)%fly_dta(jpi1:jpi2,jpj1:jpj2,:),3) ) CASE(1) CALL iom_get( num, jpdom_unknown, clvar, ref_wgts(kw)%fly_dta(jpi1:jpi2,jpj1:jpj2,1), nrec, rec1, recn) CASE DEFAULT CALL iom_get( num, jpdom_unknown, clvar, ref_wgts(kw)%fly_dta(jpi1:jpi2,jpj1:jpj2,:), nrec, rec1, recn) END SELECT ENDIF !! first four weights common to both bilinear and bicubic !! data_jpi, data_jpj have already been shifted to (1,1) corresponding to botleft !! note that we have to offset by 1 into fly_dta array because of halo dta(:,:,:) = 0.0 DO jk = 1,4 DO jn = 1, jpj DO jm = 1,jpi ni = ref_wgts(kw)%data_jpi(jm,jn,jk) nj = ref_wgts(kw)%data_jpj(jm,jn,jk) dta(jm,jn,:) = dta(jm,jn,:) + ref_wgts(kw)%data_wgt(jm,jn,jk) * ref_wgts(kw)%fly_dta(ni+1,nj+1,:) END DO END DO END DO IF (ref_wgts(kw)%numwgt .EQ. 16) THEN !! fix up halo points that we couldnt read from file IF( jpi1 == 2 ) THEN ref_wgts(kw)%fly_dta(jpi1-1,:,:) = ref_wgts(kw)%fly_dta(jpi1,:,:) ENDIF IF( jpi2 + jpimin - 1 == ref_wgts(kw)%ddims(1)+1 ) THEN ref_wgts(kw)%fly_dta(jpi2+1,:,:) = ref_wgts(kw)%fly_dta(jpi2,:,:) ENDIF IF( jpj1 == 2 ) THEN ref_wgts(kw)%fly_dta(:,jpj1-1,:) = ref_wgts(kw)%fly_dta(:,jpj1,:) ENDIF IF( jpj2 + jpjmin - 1 == ref_wgts(kw)%ddims(2)+1 .AND. jpj2 .lt. jpjwid+2 ) THEN ref_wgts(kw)%fly_dta(:,jpj2+1,:) = 2.0*ref_wgts(kw)%fly_dta(:,jpj2,:) - ref_wgts(kw)%fly_dta(:,jpj2-1,:) ENDIF !! if data grid is cyclic we can do better on east-west edges !! but have to allow for whether first and last columns are coincident IF( ref_wgts(kw)%cyclic ) THEN rec1(2) = MAX( jpjmin-1, 1 ) recn(1) = 1 recn(2) = MIN( jpjwid+2, ref_wgts(kw)%ddims(2)-rec1(2)+1 ) jpj1 = 2 + rec1(2) - jpjmin jpj2 = jpj1 + recn(2) - 1 IF( jpi1 == 2 ) THEN rec1(1) = ref_wgts(kw)%ddims(1) - ref_wgts(kw)%overlap SELECT CASE( SIZE( ref_wgts(kw)%col(:,jpj1:jpj2,:),3) ) CASE(1) CALL iom_get( num, jpdom_unknown, clvar, ref_wgts(kw)%col(:,jpj1:jpj2,1), nrec, rec1, recn) CASE DEFAULT CALL iom_get( num, jpdom_unknown, clvar, ref_wgts(kw)%col(:,jpj1:jpj2,:), nrec, rec1, recn) END SELECT ref_wgts(kw)%fly_dta(jpi1-1,jpj1:jpj2,:) = ref_wgts(kw)%col(1,jpj1:jpj2,:) ENDIF IF( jpi2 + jpimin - 1 == ref_wgts(kw)%ddims(1)+1 ) THEN rec1(1) = 1 + ref_wgts(kw)%overlap SELECT CASE( SIZE( ref_wgts(kw)%col(:,jpj1:jpj2,:),3) ) CASE(1) CALL iom_get( num, jpdom_unknown, clvar, ref_wgts(kw)%col(:,jpj1:jpj2,1), nrec, rec1, recn) CASE DEFAULT CALL iom_get( num, jpdom_unknown, clvar, ref_wgts(kw)%col(:,jpj1:jpj2,:), nrec, rec1, recn) END SELECT ref_wgts(kw)%fly_dta(jpi2+1,jpj1:jpj2,:) = ref_wgts(kw)%col(1,jpj1:jpj2,:) ENDIF ENDIF ! gradient in the i direction DO jk = 1,4 DO jn = 1, jpj DO jm = 1,jpi ni = ref_wgts(kw)%data_jpi(jm,jn,jk) nj = ref_wgts(kw)%data_jpj(jm,jn,jk) dta(jm,jn,:) = dta(jm,jn,:) + ref_wgts(kw)%data_wgt(jm,jn,jk+4) * 0.5 * & (ref_wgts(kw)%fly_dta(ni+2,nj+1,:) - ref_wgts(kw)%fly_dta(ni,nj+1,:)) END DO END DO END DO ! gradient in the j direction DO jk = 1,4 DO jn = 1, jpj DO jm = 1,jpi ni = ref_wgts(kw)%data_jpi(jm,jn,jk) nj = ref_wgts(kw)%data_jpj(jm,jn,jk) dta(jm,jn,:) = dta(jm,jn,:) + ref_wgts(kw)%data_wgt(jm,jn,jk+8) * 0.5 * & (ref_wgts(kw)%fly_dta(ni+1,nj+2,:) - ref_wgts(kw)%fly_dta(ni+1,nj,:)) END DO END DO END DO ! gradient in the ij direction DO jk = 1,4 DO jn = 1, jpj DO jm = 1,jpi ni = ref_wgts(kw)%data_jpi(jm,jn,jk) nj = ref_wgts(kw)%data_jpj(jm,jn,jk) dta(jm,jn,:) = dta(jm,jn,:) + ref_wgts(kw)%data_wgt(jm,jn,jk+12) * 0.25 * ( & (ref_wgts(kw)%fly_dta(ni+2,nj+2,:) - ref_wgts(kw)%fly_dta(ni ,nj+2,:)) - & (ref_wgts(kw)%fly_dta(ni+2,nj ,:) - ref_wgts(kw)%fly_dta(ni ,nj ,:))) END DO END DO END DO ! END IF ! END SUBROUTINE fld_interp FUNCTION ksec_week( cdday ) !!--------------------------------------------------------------------- !! *** FUNCTION kshift_week *** !! !! ** Purpose : !!--------------------------------------------------------------------- CHARACTER(len=*), INTENT(in) :: cdday !3 first letters of the first day of the weekly file !! INTEGER :: ksec_week ! output variable INTEGER :: ijul !temp variable INTEGER :: ishift !temp variable CHARACTER(len=3),DIMENSION(7) :: cl_week !!---------------------------------------------------------------------- cl_week = (/"sun","sat","fri","thu","wed","tue","mon"/) DO ijul = 1, 7 IF( cl_week(ijul) == TRIM(cdday) ) EXIT END DO IF( ijul .GT. 7 ) CALL ctl_stop( 'ksec_week: wrong day for sdjf%cltype(6:8): '//TRIM(cdday) ) ! ishift = ijul * NINT(rday) ! ksec_week = nsec_week + ishift ksec_week = MOD( ksec_week, 7*NINT(rday) ) ! END FUNCTION ksec_week !!====================================================================== END MODULE fldread