-
WAUTELET Philippe authoredWAUTELET Philippe authored
read_exsegn.f90 107.41 KiB
!MNH_LIC Copyright 1994-2018 CNRS, Meteo-France and Universite Paul Sabatier
!MNH_LIC This is part of the Meso-NH software governed by the CeCILL-C licence
!MNH_LIC version 1. See LICENSE, CeCILL-C_V1-en.txt and CeCILL-C_V1-fr.txt
!MNH_LIC for details. version 1.
!-----------------------------------------------------------------
! ######################
MODULE MODI_READ_EXSEG_n
! ######################
!
INTERFACE
!
SUBROUTINE READ_EXSEG_n(KMI,TPEXSEGFILE,HCONF,OFLAT,OUSERV, &
OUSERC,OUSERR,OUSERI,OUSECI,OUSERS,OUSERG,OUSERH, &
OUSECHEM,OUSECHAQ,OUSECHIC,OCH_PH,OCH_CONV_LINOX,OSALT, &
ODEPOS_SLT, ODUST,ODEPOS_DST, OCHTRANS, &
OORILAM,ODEPOS_AER, OLG,OPASPOL, &
#ifdef MNH_FOREFIRE
OFOREFIRE, &
#endif
OLNOX_EXPLICIT, &
OCONDSAMP, &
KRIMX,KRIMY, KSV_USER, &
HTURB,HTOM,ORMC01,HRAD,HDCONV,HSCONV,HCLOUD,HELEC, &
HEQNSYS,PTSTEP_ALL,HSTORAGE_TYPE,HINIFILEPGD )
!
USE MODD_IO_ll, ONLY: TFILEDATA
!
INTEGER, INTENT(IN) :: KMI ! Model index
TYPE(TFILEDATA), INTENT(IN) :: TPEXSEGFILE ! EXSEG file
! The following variables are read by READ_DESFM in DESFM descriptor :
CHARACTER (LEN=*), INTENT(IN) :: HCONF ! configuration var. linked to FMfile
LOGICAL, INTENT(IN) :: OFLAT ! Logical for zero orography
LOGICAL, INTENT(IN) :: OUSERV,OUSERC,OUSERR,OUSERI,OUSERS, &
OUSERG,OUSERH ! kind of moist variables in
! FMfile
LOGICAL, INTENT(IN) :: OUSECI ! ice concentration in
! FMfile
LOGICAL, INTENT(IN) :: OUSECHEM ! Chemical FLAG in FMFILE
LOGICAL, INTENT(IN) :: OUSECHAQ ! Aqueous chemical FLAG in FMFILE
LOGICAL, INTENT(IN) :: OUSECHIC ! Ice chemical FLAG in FMFILE
LOGICAL, INTENT(IN) :: OCH_PH ! pH FLAG in FMFILE
LOGICAL, INTENT(IN) :: OCH_CONV_LINOX ! LiNOx FLAG in FMFILE
LOGICAL, INTENT(IN) :: ODUST ! Dust FLAG in FMFILE
LOGICAL,DIMENSION(:), INTENT(IN) :: ODEPOS_DST ! Dust wet deposition FLAG in FMFILE
LOGICAL,DIMENSION(:), INTENT(IN) :: ODEPOS_SLT ! Sea Salt wet deposition FLAG in FMFILE
LOGICAL,DIMENSION(:), INTENT(IN) :: ODEPOS_AER ! Orilam wet deposition FLAG in FMFILE
LOGICAL, INTENT(IN) :: OSALT ! Sea Salt FLAG in FMFILE
LOGICAL, INTENT(IN) :: OORILAM ! Orilam FLAG in FMFILE
LOGICAL, INTENT(IN) :: OPASPOL ! Passive pollutant FLAG in FMFILE
#ifdef MNH_FOREFIRE
LOGICAL, INTENT(IN) :: OFOREFIRE ! ForeFire FLAG in FMFILE
#endif
LOGICAL, INTENT(IN) :: OLNOX_EXPLICIT ! explicit LNOx FLAG in FMFILE
LOGICAL, INTENT(IN) :: OCONDSAMP ! Conditional sampling FLAG in FMFILE
LOGICAL, INTENT(IN) :: OCHTRANS ! LCHTRANS FLAG in FMFILE
LOGICAL, INTENT(IN) :: OLG ! lagrangian FLAG in FMFILE
INTEGER, INTENT(IN) :: KRIMX, KRIMY ! number of points for the
! horizontal relaxation for the outermost verticals
INTEGER, INTENT(IN) :: KSV_USER ! number of additional scalar
! variables in FMfile
CHARACTER (LEN=*), INTENT(IN) :: HTURB ! Kind of turbulence parameterization
! used to produce FMFILE
CHARACTER (LEN=*), INTENT(IN) :: HTOM ! Kind of third order moment
LOGICAL, INTENT(IN) :: ORMC01 ! flag for RMC01 SBL computations
CHARACTER (LEN=*), INTENT(IN) :: HRAD ! Kind of radiation scheme
CHARACTER (LEN=4), INTENT(IN) :: HDCONV ! Kind of deep convection scheme
CHARACTER (LEN=4), INTENT(IN) :: HSCONV ! Kind of shallow convection scheme
CHARACTER (LEN=4), INTENT(IN) :: HCLOUD ! Kind of microphysical scheme
CHARACTER (LEN=4), INTENT(IN) :: HELEC ! Kind of electrical schemeCHARACTER (LEN=*), INTENT(IN) :: HEQNSYS! type of equations' system
REAL,DIMENSION(:), INTENT(INOUT):: PTSTEP_ALL ! Time STEP of ALL models
CHARACTER (LEN=*), INTENT(IN) :: HSTORAGE_TYPE ! type of initial file
CHARACTER (LEN=*), INTENT(IN) :: HINIFILEPGD ! name of PGD file
!
END SUBROUTINE READ_EXSEG_n
!
END INTERFACE
!
END MODULE MODI_READ_EXSEG_n
!
!
! #########################################################################
SUBROUTINE READ_EXSEG_n(KMI,TPEXSEGFILE,HCONF,OFLAT,OUSERV, &
OUSERC,OUSERR,OUSERI,OUSECI,OUSERS,OUSERG,OUSERH, &
OUSECHEM,OUSECHAQ,OUSECHIC,OCH_PH,OCH_CONV_LINOX,OSALT, &
ODEPOS_SLT, ODUST,ODEPOS_DST, OCHTRANS, &
OORILAM,ODEPOS_AER, OLG,OPASPOL, &
#ifdef MNH_FOREFIRE
OFOREFIRE, &
#endif
OLNOX_EXPLICIT, &
OCONDSAMP, &
KRIMX,KRIMY, KSV_USER, &
HTURB,HTOM,ORMC01,HRAD,HDCONV,HSCONV,HCLOUD,HELEC, &
HEQNSYS,PTSTEP_ALL,HSTORAGE_TYPE,HINIFILEPGD )
! #########################################################################
!
!!**** *READ_EXSEG_n * - routine to read the descriptor file EXSEG
!!
!! PURPOSE
!! -------
! The purpose of this routine is to read the descriptor file called
! EXSEG and to control the coherence with FMfile data .
!
!!
!!** METHOD
!! ------
!! The descriptor file is read. Namelists (NAMXXXn) which contain
!! variables linked to one nested model are at the beginning of the file.
!! Namelists (NAMXXX) which contain variables common to all models
!! are at the end of the file. When the model index is different from 1,
!! the end of the file (namelists NAMXXX) is not read.
!!
!! Coherence between the initial file (description read in DESFM file)
!! and the segment to perform (description read in EXSEG file)
!! is checked for segment achievement configurations
!! or postprocessing configuration. The get indicators are set according
!! to the following check :
!!
!! - segment achievement and preinit configurations :
!!
!! * if there is no turbulence kinetic energy in initial
!! file (HTURB='NONE'), and the segment to perform requires a turbulence
!! parameterization (CTURB /= 'NONE'), the get indicators for turbulence
!! kinetic energy variables are set to 'INIT'; i.e. these variables will be
!! set equal to zero by READ_FIELD according to the get indicators.
!! * The same procedure is applied to the dissipation of TKE.
!! * if there is no moist variables RRn in initial file (OUSERn=.FALSE.)
!! and the segment to perform requires moist variables RRn
!! (LUSERn=.TRUE.), the get indicators for moist variables RRn are set
!! equal to 'INIT'; i.e. these variables will be set equal to zero by
!! READ_FIELD according to the get indicators.
!! * if there are KSV_USER additional scalar variables in initial file and the
!! segment to perform needs more than KSV_USER additional variables, the get
!! indicators for these (NSV_USER-KSV_USER) additional scalar variables are set
!! equal to 'INIT'; i.e. these variables will be set equal to zero by
!! READ_FIELD according to the get indicators. If the segment to perform
!! needs less additional scalar variables than there are in initial file,
!! the get indicators for these (KSV_USER - NSV_USER) additional scalar variables are!! set equal to 'SKIP'.
!! * warning messages are printed if the fields in initial file are the
!! same at time t and t-dt (HCONF='START') and a leap-frog advance
!! at first time step will be used for the segment to perform
!! (CCONF='RESTA'); It is likewise when HCONF='RESTA' and CCONF='START'.
!! * A warning message is printed if the orography in initial file is zero
!! (OFLAT=.TRUE.) and the segment to perform considers no-zero orography
!! (LFLAT=.FALSE.). It is likewise for LFLAT=.TRUE. and OFLAT=.FALSE..
!! If the segment to perform requires zero orography (LFLAT=.TRUE.), the
!! orography (XZS) will not read in initial file but set equal to zero
!! by SET_GRID.
!! * check of the depths of the Lateral Damping Layer in x and y
!! direction is performed
!! * If some coupling files are specified, LSTEADYLS is set to T
!! * If no coupling files are specified, LSTEADYLS is set to F
!!
!!
!! EXTERNAL
!! --------
!!
!! IMPLICIT ARGUMENTS
!! ------------------
!! Module MODN_CONF : CCONF,LTHINSHELL,LFLAT,NMODEL,NVERB
!!
!! Module MODN_DYN : LCORIO, LZDIFFU
!!
!! Module MODN_NESTING : NDAD(m),NDTRATIO(m),XWAY(m)
!!
!! Module MODN_BUDGET : CBUTYPE,XBULEN
!!
!! Module MODN_CONF1 : LUSERV,LUSERC,LUSERR,LUSERI,LUSERS,LUSERG,LUSERH,CSEG
!!
!! Module MODN_DYN1 : XTSTEP,CPRESOPT,NITR,XRELAX
!!
!! Module MODD_ADV1 : CMET_ADV_SCHEME,CSV_ADV_SCHEME,CUVW_ADV_SCHEME,NLITER
!!
!! Module MODN_PARAM1 : CTURB,CRAD,CDCONV,CSCONV
!!
!! Module MODN_LUNIT1 :
!! Module MODN_LBC1 : CLBCX,CLBCY,NLBLX,NLBLY,XCPHASE,XPOND
!!
!! Module MODN_TURB_n : CTURBLEN,CTURBDIM
!!
!! Module MODD_GET1:
!! CGETTKEM,CGETTKET,
!! CGETRVM,CGETRCM,CGETRRM,CGETRIM,CGETRSM,CGETRGM,CGETRHM
!! CGETRVT,CGETRCT,CGETRRT,CGETRIT,CGETRST,CGETRGT,CGETRHT,CGETSVM
!! CGETSVT,CGETSIGS,CGETSRCM,CGETSRCT
!! NCPL_NBR,NCPL_TIMES,NCPL_CUR
!! Module MODN_LES : contains declaration of the control parameters
!! for Large Eddy Simulations' storages
!! for the forcing
!!
!! REFERENCE
!! ---------
!! Book2 of the documentation (routine READ_EXSEG_n)
!!
!!
!! AUTHOR
!! ------
!! V. Ducrocq * Meteo France *
!!
!! MODIFICATIONS
!! -------------
!! Original 07/06/94
!! Modification 26/10/94 (Stein) remove NAM_GET from the Namelists
!! present in DESFM + change the namelist names
!! Modification 22/11/94 (Stein) add GET indicator for phi
!! Modification 21/12/94 (Stein) add GET indicator for LS fields
!! Modification 06/01/95 (Stein) bug in the test for Scalar Var.!! Modifications 09/01/95 (Stein) add the turbulence scheme
!! Modifications 09/01/95 (Stein) add the 1D switch
!! Modifications 10/03/95 (Mallet) add coherence in coupling case
!! Modifications 16/03/95 (Stein) remove R from the historical variables
!! Modifications 01/03/95 (Hereil) add the budget namelists
!! Modifications 16/06/95 (Stein) coherence control for the
!! microphysical scheme + remove the wrong messge for RESTA conf
!! Modifications 30/06/95 (Stein) conditionnal reading of the fields
!! used by the moist turbulence scheme
!! Modifications 12/09/95 (Pinty) add the radiation scheme
!! Modification 06/02/96 (J.Vila) implement scalar advection schemes
!! Modifications 24/02/96 (Stein) change the default value for CCPLFILE
!! Modifications 02/05/96 (Stein Jabouille) change the Z0SEA activation
!! Modifications 24/05/96 (Stein) change the SRC SIGS control
!! Modifications 08/09/96 (Masson) the coupling file names are reset to
!! default value " " before reading in EXSEG1.nam
!! to avoid extra non-existant coupling files
!!
!! Modifications 25/04/95 (K.Suhre)add namelist NAM_BLANK
!! add read for LFORCING
!! 25/04/95 (K.Suhre)add namelist NAM_FRC
!! and switch checking
!! 06/08/96 (K.Suhre)add namelist NAM_CH_MNHCn
!! and NAM_CH_SOLVER
!! Modifications 10/10/96 (Stein) change SRC into SRCM and SRCT
!! Modifications 11/04/96 (Pinty) add the rain-ice microphysical scheme
!! Modifications 11/01/97 (Pinty) add the deep convection scheme
!! Modifications 22/05/97 (Lafore) gridnesting implementation
!! Modifications 22/06/97 (Stein) add the absolute pressure + cleaning
!! Modifications 25/08/97 (Masson) add tests on surface schemes
!! 22/10/97 (Stein) remove the RIMX /= 0 control
!! + new namelist + cleaning
!! Modifications 17/04/98 (Masson) add tests on character variables
!! Modification 15/03/99 (Masson) add tests on PROGRAM
!! Modification 04/01/00 (Masson) removes TSZ0 case
!! Modification 04/06/00 (Pinty) add C2R2 scheme
!! 11/12/00 (Tomasini) add CSEA_FLUX to MODD_PARAMn
!! delete the test on SST_FRC only in 1D
!! Modification 22/01/01 (Gazen) change NSV,KSV to NSV_USER,KSV_USER and add
!! NSV_* variables initialization
!! Modification 15/10/01 (Mallet) allow namelists in different orders
!! Modification 18/03/02 (Solmon) new radiation scheme test
!! Modification 29/11/02 (JP Pinty) add C3R5, ICE2, ICE4, ELEC
!! Modification 06/11/02 (Masson) new LES BL height diagnostic
!! Modification 06/11/02 (Jabouille) remove LTHINSHELL LFORCING test
!! Modification 01/12/03 (Gazen) change Chemical scheme interface
!! Modification 01/2004 (Masson) removes surface (externalization)
!! Modification 01/2005 (Masson) removes 1D and 2D switches
!! Modification 04/2005 (Tulet) add dust, orilam
!! Modification 03/2006 (O.Geoffroy) Add KHKO scheme
!! Modification 04/2006 (Maric) include 4th order advection scheme
!! Modification 05/2006 (Masson) add nudging
!! Modification 05/2006 Remove KEPS
!! Modification 04/2006 (Maric) include PPM advection scheme
!! Modification 04/2006 (J.Escobar) Bug dollarn add CALL UPDATE_NAM_CONFN
!! Modifications 01/2007 (Malardel,Pergaud) add the MF shallow
!! convection scheme MODN_PARAM_MFSHALL_n
!! Modification 09/2009 (J.Escobar) add more info on relaxation problems
!! Modification 09/2011 (J.Escobar) re-add 'ZRESI' choose
!! Modification 12/2011 (C.Lac) Adaptation to FIT temporal scheme
!! Modification 12/2012 (S.Bielli) add NAM_NCOUT for netcdf output (removed 08/07/2016)
!! Modification 02/2012 (Pialat/Tulet) add ForeFire
!! Modification 02/2012 (T.Lunet) add of new Runge-Kutta methods
!! Modification 01/2015 (C. Barthe) add explicit LNOx
!! J.Escobar : 15/09/2015 : WENO5 & JPHEXT <> 1
!! M.Leriche 18/12/2015 : bug chimie glace dans prep_real_case
!! Modification 01/2016 (JP Pinty) Add LIMA
!! Modification 02/2016 (M.Leriche) treat gas and aq. chemicals separately
!! P.Wautelet 08/07/2016 : removed MNH_NCWRIT define
!! Modification 10/2016 (C.LAC) Add OSPLIT_WENO + Add droplet!! deposition + Add max values
!! Modification 11/2016 (Ph. Wautelet) Allocate/initialise some output/backup structures
!! Modification 03/2017 (JP Chaboureau) Fix the initialization of
!! LUSERx-type variables for LIMA
!! M.Leriche 06/2017 for spawn and prep_real avoid abort if wet dep for
!! aerosol and no cloud scheme defined
!! Philippe Wautelet: 05/2016-04/2018: new data structures and calls for I/O
!!------------------------------------------------------------------------------
!
!* 0. DECLARATIONS
! ------------
USE MODD_PARAMETERS
USE MODD_CONF
USE MODD_CONFZ
USE MODD_CONF_n, ONLY: CSTORAGE_TYPE
USE MODD_IO_ll, ONLY: TFILEDATA
USE MODD_LUNIT_n, ONLY: TLUOUT
USE MODD_VAR_ll, ONLY: NPROC
!
USE MODN_BACKUP
USE MODN_BUDGET
USE MODN_LES
USE MODN_CONF
USE MODN_CONFZ
USE MODN_FRC
USE MODN_DYN
USE MODN_NESTING
USE MODN_OUTPUT
USE MODN_CONF_n
USE MODN_LBC_n ! routine is used for each nested model. This has been done
USE MODN_DYN_n ! to avoid the duplication of this routine for each model.
USE MODN_ADV_n ! The final filling of these modules for the model n is
USE MODN_PARAM_n ! realized in subroutine ini_model n
USE MODN_PARAM_RAD_n
USE MODN_PARAM_KAFR_n
USE MODN_PARAM_MFSHALL_n
USE MODN_PARAM_ICE
USE MODN_LUNIT_n
USE MODN_NUDGING_n
USE MODN_TURB_n
USE MODN_BLANK
USE MODN_CH_MNHC_n
USE MODN_CH_SOLVER_n
USE MODN_PARAM_C2R2, ONLY : EPARAM_CCN=>HPARAM_CCN, EINI_CCN=>HINI_CCN, &
WNUC=>XNUC, WALPHAC=>XALPHAC, NAM_PARAM_C2R2
USE MODN_PARAM_C1R3, ONLY : NAM_PARAM_C1R3, CPRISTINE_ICE_C1R3, &
CHEVRIMED_ICE_C1R3
USE MODN_PARAM_LIMA, ONLY : FINI_CCN=>HINI_CCN,NAM_PARAM_LIMA,NMOD_CCN,LSCAV, &
CPRISTINE_ICE_LIMA, CHEVRIMED_ICE_LIMA, NMOD_IFN, &
LCOLD, LACTI, LNUCL, XALPHAC, XNUC, LMEYERS, LHAIL
USE MODN_ELEC
USE MODN_SERIES
USE MODN_SERIES_n
USE MODN_TURB_CLOUD
USE MODN_TURB
USE MODN_MEAN
USE MODN_DRAGTREE
USE MODN_LATZ_EDFLX
!
USE MODD_NSV,NSV_USER_n=>NSV_USER
USE MODD_DYN
USE MODD_DYN_n, ONLY : LHORELAX_SVLIMA
USE MODD_GET_n
USE MODD_GR_FIELD_n
!
USE MODE_POS
USE MODE_IO_ll
USE MODE_MSG
!
USE MODI_TEST_NAM_VARUSE MODI_INI_NSV
USE MODI_CH_INIT_SCHEME_n
USE MODN_CH_ORILAM
USE MODD_CH_AEROSOL
USE MODD_DUST
USE MODD_SALT
USE MODD_PASPOL
#ifdef MNH_FOREFIRE
USE MODD_FOREFIRE
USE MODN_FOREFIRE
#endif
USE MODD_CONDSAMP
USE MODN_DUST
USE MODN_SALT
USE MODD_CH_M9_n, ONLY : NEQ
USE MODN_PASPOL
USE MODN_CONDSAMP
USE MODN_2D_FRC
!
IMPLICIT NONE
!
!* 0.1 declarations of arguments
!
!
!
INTEGER, INTENT(IN) :: KMI ! Model index
TYPE(TFILEDATA), INTENT(IN) :: TPEXSEGFILE ! EXSEG file
! The following variables are read by READ_DESFM in DESFM descriptor :
CHARACTER (LEN=*), INTENT(IN) :: HCONF ! configuration var. linked to FMfile
LOGICAL, INTENT(IN) :: OFLAT ! Logical for zero orography
LOGICAL, INTENT(IN) :: OUSERV,OUSERC,OUSERR,OUSERI,OUSERS, &
OUSERG,OUSERH ! kind of moist variables in
! FMfile
LOGICAL, INTENT(IN) :: OUSECI ! ice concentration in
! FMfile
LOGICAL, INTENT(IN) :: OUSECHEM ! Chemical FLAG in FMFILE
LOGICAL, INTENT(IN) :: OUSECHAQ ! Aqueous chemical FLAG in FMFILE
LOGICAL, INTENT(IN) :: OUSECHIC ! Ice chemical FLAG in FMFILE
LOGICAL, INTENT(IN) :: OCH_PH ! pH FLAG in FMFILE
LOGICAL, INTENT(IN) :: OCH_CONV_LINOX ! LiNOx FLAG in FMFILE
LOGICAL, INTENT(IN) :: ODUST ! Dust FLAG in FMFILE
LOGICAL,DIMENSION(:), INTENT(IN) :: ODEPOS_DST ! Dust Deposition FLAG in FMFILE
LOGICAL,DIMENSION(:), INTENT(IN) :: ODEPOS_SLT ! Sea Salt wet deposition FLAG in FMFILE
LOGICAL,DIMENSION(:), INTENT(IN) :: ODEPOS_AER ! Orilam wet deposition FLAG in FMFILE
LOGICAL, INTENT(IN) :: OSALT ! Sea Salt FLAG in FMFILE
LOGICAL, INTENT(IN) :: OORILAM ! Orilam FLAG in FMFILE
LOGICAL, INTENT(IN) :: OPASPOL ! Passive pollutant FLAG in FMFILE
#ifdef MNH_FOREFIRE
LOGICAL, INTENT(IN) :: OFOREFIRE ! ForeFire FLAG in FMFILE
#endif
LOGICAL, INTENT(IN) :: OLNOX_EXPLICIT ! explicit LNOx FLAG in FMFILE
LOGICAL, INTENT(IN) :: OCONDSAMP ! Conditional sampling FLAG in FMFILE
LOGICAL, INTENT(IN) :: OCHTRANS ! LCHTRANS FLAG in FMFILE
LOGICAL, INTENT(IN) :: OLG ! lagrangian FLAG in FMFILE
INTEGER, INTENT(IN) :: KRIMX, KRIMY ! number of points for the
! horizontal relaxation for the outermost verticals
INTEGER, INTENT(IN) :: KSV_USER ! number of additional scalar
! variables in FMfile
CHARACTER (LEN=*), INTENT(IN) :: HTURB ! Kind of turbulence parameterization
! used to produce FMFILE
CHARACTER (LEN=*), INTENT(IN) :: HTOM ! Kind of third order moment
LOGICAL, INTENT(IN) :: ORMC01 ! flag for RMC01 SBL computations
CHARACTER (LEN=*), INTENT(IN) :: HRAD ! Kind of radiation scheme
CHARACTER (LEN=4), INTENT(IN) :: HDCONV ! Kind of deep convection scheme
CHARACTER (LEN=4), INTENT(IN) :: HSCONV ! Kind of shallow convection scheme
CHARACTER (LEN=4), INTENT(IN) :: HCLOUD ! Kind of microphysical scheme
CHARACTER (LEN=4), INTENT(IN) :: HELEC ! Kind of electrical scheme
CHARACTER (LEN=*), INTENT(IN) :: HEQNSYS! type of equations' system
REAL,DIMENSION(:), INTENT(INOUT):: PTSTEP_ALL ! Time STEP of ALL modelsCHARACTER (LEN=*), INTENT(IN) :: HSTORAGE_TYPE ! type of initial file
CHARACTER (LEN=*), INTENT(IN) :: HINIFILEPGD ! name of PGD file
!
!* 0.2 declarations of local variables
!
INTEGER :: ILUSEG,ILUOUT ! logical unit numbers of EXSEG file and outputlisting
INTEGER :: JS,JCI,JI,JSV ! Loop indexes
LOGICAL :: GRELAX
LOGICAL :: GFOUND ! Return code when searching namelist
!
INTEGER :: IMOMENTS, JMODE, IMODEIDX, JMOM, JSV_NAME, JMOD, I
!
!-------------------------------------------------------------------------------
!
!* 1. READ EXSEG FILE
! ---------------
!
CALL PRINT_MSG(NVERB_DEBUG,'IO','READ_EXSEG_n','called for '//TRIM(TPEXSEGFILE%CNAME))
!
ILUSEG = TPEXSEGFILE%NLU
ILUOUT = TLUOUT%NLU
!
CALL INIT_NAM_LUNITN
CCPLFILE(:)=" "
CALL INIT_NAM_CONFN
CALL INIT_NAM_DYNN
CALL INIT_NAM_ADVN
CALL INIT_NAM_PARAMN
CALL INIT_NAM_PARAM_RADN
CALL INIT_NAM_PARAM_KAFRN
CALL INIT_NAM_PARAM_MFSHALLN
CALL INIT_NAM_LBCN
CALL INIT_NAM_NUDGINGN
CALL INIT_NAM_TURBN
CALL INIT_NAM_CH_MNHCN
CALL INIT_NAM_CH_SOLVERN
CALL INIT_NAM_SERIESN
!
WRITE(UNIT=ILUOUT,FMT="(/,'READING THE EXSEG.NAM FILE')")
CALL POSNAM(ILUSEG,'NAM_LUNITN',GFOUND,ILUOUT)
IF (GFOUND) READ(UNIT=ILUSEG,NML=NAM_LUNITn)
CALL POSNAM(ILUSEG,'NAM_CONFN',GFOUND,ILUOUT)
IF (GFOUND) READ(UNIT=ILUSEG,NML=NAM_CONFn)
CALL POSNAM(ILUSEG,'NAM_DYNN',GFOUND,ILUOUT)
IF (GFOUND) READ(UNIT=ILUSEG,NML=NAM_DYNn)
CALL POSNAM(ILUSEG,'NAM_ADVN',GFOUND,ILUOUT)
IF (GFOUND) READ(UNIT=ILUSEG,NML=NAM_ADVn)
CALL POSNAM(ILUSEG,'NAM_PARAMN',GFOUND,ILUOUT)
IF (GFOUND) READ(UNIT=ILUSEG,NML=NAM_PARAMn)
CALL POSNAM(ILUSEG,'NAM_PARAM_RADN',GFOUND,ILUOUT)
IF (GFOUND) READ(UNIT=ILUSEG,NML=NAM_PARAM_RADn)
CALL POSNAM(ILUSEG,'NAM_PARAM_KAFRN',GFOUND,ILUOUT)
IF (GFOUND) READ(UNIT=ILUSEG,NML=NAM_PARAM_KAFRn)
CALL POSNAM(ILUSEG,'NAM_PARAM_MFSHALLN',GFOUND,ILUOUT)
IF (GFOUND) READ(UNIT=ILUSEG,NML=NAM_PARAM_MFSHALLn)
CALL POSNAM(ILUSEG,'NAM_LBCN',GFOUND,ILUOUT)
IF (GFOUND) READ(UNIT=ILUSEG,NML=NAM_LBCn)
CALL POSNAM(ILUSEG,'NAM_NUDGINGN',GFOUND,ILUOUT)
IF (GFOUND) READ(UNIT=ILUSEG,NML=NAM_NUDGINGn)
CALL POSNAM(ILUSEG,'NAM_TURBN',GFOUND,ILUOUT)
IF (GFOUND) READ(UNIT=ILUSEG,NML=NAM_TURBn)
CALL POSNAM(ILUSEG,'NAM_CH_MNHCN',GFOUND,ILUOUT)
IF (GFOUND) READ(UNIT=ILUSEG,NML=NAM_CH_MNHCn)
CALL POSNAM(ILUSEG,'NAM_CH_SOLVERN',GFOUND,ILUOUT)
IF (GFOUND) READ(UNIT=ILUSEG,NML=NAM_CH_SOLVERn)
CALL POSNAM(ILUSEG,'NAM_SERIESN',GFOUND,ILUOUT)
IF (GFOUND) READ(UNIT=ILUSEG,NML=NAM_SERIESn)
!
IF (KMI == 1) THEN
WRITE(UNIT=ILUOUT,FMT="(' namelists common to all the models ')") CALL POSNAM(ILUSEG,'NAM_CONF',GFOUND,ILUOUT)
IF (GFOUND) READ(UNIT=ILUSEG,NML=NAM_CONF)
CALL POSNAM(ILUSEG,'NAM_CONFZ',GFOUND,ILUOUT)
IF (GFOUND) READ(UNIT=ILUSEG,NML=NAM_CONFZ)
CALL POSNAM(ILUSEG,'NAM_DYN',GFOUND,ILUOUT)
IF (GFOUND) READ(UNIT=ILUSEG,NML=NAM_DYN)
CALL POSNAM(ILUSEG,'NAM_NESTING',GFOUND,ILUOUT)
IF (GFOUND) READ(UNIT=ILUSEG,NML=NAM_NESTING)
CALL POSNAM(ILUSEG,'NAM_BACKUP',GFOUND,ILUOUT)
IF (GFOUND) THEN
!Should have been allocated before in READ_DESFM_n
IF (.NOT.ALLOCATED(XBAK_TIME)) THEN
ALLOCATE(XBAK_TIME(NMODEL,JPOUTMAX))
XBAK_TIME(:,:) = XNEGUNDEF
END IF
IF (.NOT.ALLOCATED(XOUT_TIME)) THEN
ALLOCATE(XOUT_TIME(NMODEL,JPOUTMAX)) !Allocate *OUT* variables to prevent
XOUT_TIME(:,:) = XNEGUNDEF
END IF
IF (.NOT.ALLOCATED(NBAK_STEP)) THEN
ALLOCATE(NBAK_STEP(NMODEL,JPOUTMAX))
NBAK_STEP(:,:) = NNEGUNDEF
END IF
IF (.NOT.ALLOCATED(NOUT_STEP)) THEN
ALLOCATE(NOUT_STEP(NMODEL,JPOUTMAX)) !problems if NAM_OUTPUT does not exist
NOUT_STEP(:,:) = NNEGUNDEF
END IF
IF (.NOT.ALLOCATED(COUT_VAR)) THEN
ALLOCATE(COUT_VAR (NMODEL,JPOUTVARMAX))
COUT_VAR(:,:) = ''
END IF
READ(UNIT=ILUSEG,NML=NAM_BACKUP)
ELSE
CALL POSNAM(ILUSEG,'NAM_FMOUT',GFOUND)
IF (GFOUND) CALL PRINT_MSG(NVERB_FATAL,'IO','READ_EXSEG_n','use namelist NAM_BACKUP instead of namelist NAM_FMOUT')
END IF
CALL POSNAM(ILUSEG,'NAM_OUTPUT',GFOUND,ILUOUT)
IF (GFOUND) THEN
!Should have been allocated before in READ_DESFM_n
IF (.NOT.ALLOCATED(XBAK_TIME)) THEN
ALLOCATE(XBAK_TIME(NMODEL,JPOUTMAX)) !Allocate *BAK* variables to prevent
XBAK_TIME(:,:) = XNEGUNDEF
END IF
IF (.NOT.ALLOCATED(XOUT_TIME)) THEN
ALLOCATE(XOUT_TIME(NMODEL,JPOUTMAX))
XOUT_TIME(:,:) = XNEGUNDEF
END IF
IF (.NOT.ALLOCATED(NBAK_STEP)) THEN
ALLOCATE(NBAK_STEP(NMODEL,JPOUTMAX)) !problems if NAM_BACKUP does not exist
NBAK_STEP(:,:) = NNEGUNDEF
END IF
IF (.NOT.ALLOCATED(NOUT_STEP)) THEN
ALLOCATE(NOUT_STEP(NMODEL,JPOUTMAX))
NOUT_STEP(:,:) = NNEGUNDEF
END IF
IF (.NOT.ALLOCATED(COUT_VAR)) THEN
ALLOCATE(COUT_VAR (NMODEL,JPOUTVARMAX))
COUT_VAR(:,:) = ''
END IF
READ(UNIT=ILUSEG,NML=NAM_OUTPUT)
END IF
CALL POSNAM(ILUSEG,'NAM_BUDGET',GFOUND,ILUOUT)
IF (GFOUND) READ(UNIT=ILUSEG,NML=NAM_BUDGET)
CALL POSNAM(ILUSEG,'NAM_BU_RU',GFOUND,ILUOUT)
IF (GFOUND) READ(UNIT=ILUSEG,NML=NAM_BU_RU)
CALL POSNAM(ILUSEG,'NAM_BU_RV',GFOUND,ILUOUT)
IF (GFOUND) READ(UNIT=ILUSEG,NML=NAM_BU_RV)
CALL POSNAM(ILUSEG,'NAM_BU_RW',GFOUND,ILUOUT)
IF (GFOUND) READ(UNIT=ILUSEG,NML=NAM_BU_RW)
CALL POSNAM(ILUSEG,'NAM_BU_RTH',GFOUND,ILUOUT) IF (GFOUND) READ(UNIT=ILUSEG,NML=NAM_BU_RTH)
CALL POSNAM(ILUSEG,'NAM_BU_RTKE',GFOUND,ILUOUT)
IF (GFOUND) READ(UNIT=ILUSEG,NML=NAM_BU_RTKE)
CALL POSNAM(ILUSEG,'NAM_BU_RRV',GFOUND,ILUOUT)
IF (GFOUND) READ(UNIT=ILUSEG,NML=NAM_BU_RRV)
CALL POSNAM(ILUSEG,'NAM_BU_RRC',GFOUND,ILUOUT)
IF (GFOUND) READ(UNIT=ILUSEG,NML=NAM_BU_RRC)
CALL POSNAM(ILUSEG,'NAM_BU_RRR',GFOUND,ILUOUT)
IF (GFOUND) READ(UNIT=ILUSEG,NML=NAM_BU_RRR)
CALL POSNAM(ILUSEG,'NAM_BU_RRI',GFOUND,ILUOUT)
IF (GFOUND) READ(UNIT=ILUSEG,NML=NAM_BU_RRI)
CALL POSNAM(ILUSEG,'NAM_BU_RRS',GFOUND,ILUOUT)
IF (GFOUND) READ(UNIT=ILUSEG,NML=NAM_BU_RRS)
CALL POSNAM(ILUSEG,'NAM_BU_RRG',GFOUND,ILUOUT)
IF (GFOUND) READ(UNIT=ILUSEG,NML=NAM_BU_RRG)
CALL POSNAM(ILUSEG,'NAM_BU_RRH',GFOUND,ILUOUT)
IF (GFOUND) READ(UNIT=ILUSEG,NML=NAM_BU_RRH)
CALL POSNAM(ILUSEG,'NAM_BU_RSV',GFOUND,ILUOUT)
IF (GFOUND) READ(UNIT=ILUSEG,NML=NAM_BU_RSV)
CALL POSNAM(ILUSEG,'NAM_LES',GFOUND,ILUOUT)
IF (GFOUND) READ(UNIT=ILUSEG,NML=NAM_LES)
CALL POSNAM(ILUSEG,'NAM_MEAN',GFOUND,ILUOUT)
IF (GFOUND) READ(UNIT=ILUSEG,NML=NAM_MEAN)
CALL POSNAM(ILUSEG,'NAM_PDF',GFOUND,ILUOUT)
IF (GFOUND) READ(UNIT=ILUSEG,NML=NAM_PDF)
CALL POSNAM(ILUSEG,'NAM_BLANK',GFOUND,ILUOUT)
IF (GFOUND) READ(UNIT=ILUSEG,NML=NAM_BLANK)
CALL POSNAM(ILUSEG,'NAM_FRC',GFOUND,ILUOUT)
IF (GFOUND) READ(UNIT=ILUSEG,NML=NAM_FRC)
CALL POSNAM(ILUSEG,'NAM_PARAM_ICE',GFOUND,ILUOUT)
IF (GFOUND) READ(UNIT=ILUSEG,NML=NAM_PARAM_ICE)
CALL POSNAM(ILUSEG,'NAM_PARAM_C2R2',GFOUND,ILUOUT)
IF (GFOUND) READ(UNIT=ILUSEG,NML=NAM_PARAM_C2R2)
CALL POSNAM(ILUSEG,'NAM_PARAM_C1R3',GFOUND,ILUOUT)
IF (GFOUND) READ(UNIT=ILUSEG,NML=NAM_PARAM_C1R3)
CALL POSNAM(ILUSEG,'NAM_PARAM_LIMA',GFOUND,ILUOUT)
IF (GFOUND) READ(UNIT=ILUSEG,NML=NAM_PARAM_LIMA)
CALL POSNAM(ILUSEG,'NAM_ELEC',GFOUND,ILUOUT)
IF (GFOUND) READ(UNIT=ILUSEG,NML=NAM_ELEC)
CALL POSNAM(ILUSEG,'NAM_SERIES',GFOUND,ILUOUT)
IF (GFOUND) READ(UNIT=ILUSEG,NML=NAM_SERIES)
CALL POSNAM(ILUSEG,'NAM_TURB_CLOUD',GFOUND,ILUOUT)
IF (GFOUND) READ(UNIT=ILUSEG,NML=NAM_TURB_CLOUD)
CALL POSNAM(ILUSEG,'NAM_TURB',GFOUND,ILUOUT)
IF (GFOUND) READ(UNIT=ILUSEG,NML=NAM_TURB)
CALL POSNAM(ILUSEG,'NAM_CH_ORILAM',GFOUND,ILUOUT)
IF (GFOUND) READ(UNIT=ILUSEG,NML=NAM_CH_ORILAM)
CALL POSNAM(ILUSEG,'NAM_DUST',GFOUND,ILUOUT)
IF (GFOUND) READ(UNIT=ILUSEG,NML=NAM_DUST)
CALL POSNAM(ILUSEG,'NAM_SALT',GFOUND,ILUOUT)
IF (GFOUND) READ(UNIT=ILUSEG,NML=NAM_SALT)
CALL POSNAM(ILUSEG,'NAM_PASPOL',GFOUND,ILUOUT)
IF (GFOUND) READ(UNIT=ILUSEG,NML=NAM_PASPOL)
#ifdef MNH_FOREFIRE
CALL POSNAM(ILUSEG,'NAM_FOREFIRE',GFOUND,ILUOUT)
IF (GFOUND) READ(UNIT=ILUSEG,NML=NAM_FOREFIRE)
#endif
CALL POSNAM(ILUSEG,'NAM_CONDSAMP',GFOUND,ILUOUT)
IF (GFOUND) READ(UNIT=ILUSEG,NML=NAM_CONDSAMP)
CALL POSNAM(ILUSEG,'NAM_DRAGTREE',GFOUND,ILUOUT)
IF (GFOUND) READ(UNIT=ILUSEG,NML=NAM_DRAGTREE)
CALL POSNAM(ILUSEG,'NAM_2D_FRC',GFOUND,ILUOUT)
IF (GFOUND) READ(UNIT=ILUSEG,NML=NAM_2D_FRC)
CALL POSNAM(ILUSEG,'NAM_LATZ_EDFLX',GFOUND)
IF (GFOUND) READ(UNIT=ILUSEG,NML=NAM_LATZ_EDFLX)
END IF
!
!-------------------------------------------------------------------------------
!
CALL TEST_NAM_VAR(ILUOUT,'CPRESOPT',CPRESOPT,'RICHA','CGRAD','CRESI','ZRESI')!
CALL TEST_NAM_VAR(ILUOUT,'CUVW_ADV_SCHEME',CUVW_ADV_SCHEME, &
'CEN4TH','CEN2ND','WENO_K' )
CALL TEST_NAM_VAR(ILUOUT,'CMET_ADV_SCHEME',CMET_ADV_SCHEME, &
&'PPM_00','PPM_01','PPM_02')
CALL TEST_NAM_VAR(ILUOUT,'CSV_ADV_SCHEME',CSV_ADV_SCHEME, &
&'PPM_00','PPM_01','PPM_02')
CALL TEST_NAM_VAR(ILUOUT,'CTEMP_SCHEME',CTEMP_SCHEME, &
&'RK11','RK21','RK33','RKC4','RK53','RK4B','RK62','RK65','NP32','SP32','LEFR')
!
CALL TEST_NAM_VAR(ILUOUT,'CTURB',CTURB,'NONE','TKEL')
CALL TEST_NAM_VAR(ILUOUT,'CRAD',CRAD,'NONE','FIXE','ECMW','TOPA')
CALL TEST_NAM_VAR(ILUOUT,'CCLOUD',CCLOUD,'NONE','REVE','KESS', &
& 'ICE2','ICE3','ICE4','C2R2','C3R5','KHKO','LIMA')
CALL TEST_NAM_VAR(ILUOUT,'CDCONV',CDCONV,'NONE','KAFR')
CALL TEST_NAM_VAR(ILUOUT,'CSCONV',CSCONV,'NONE','KAFR','EDKF')
CALL TEST_NAM_VAR(ILUOUT,'CELEC',CELEC,'NONE','ELE3','ELE4')
!
CALL TEST_NAM_VAR(ILUOUT,'CAER',CAER,'TANR','TEGE','SURF','NONE')
CALL TEST_NAM_VAR(ILUOUT,'CAOP',CAOP,'CLIM','EXPL')
CALL TEST_NAM_VAR(ILUOUT,'CLW',CLW,'RRTM','MORC')
CALL TEST_NAM_VAR(ILUOUT,'CEFRADL',CEFRADL,'PRES','OCLN','MART','C2R2','LIMA')
CALL TEST_NAM_VAR(ILUOUT,'CEFRADI',CEFRADI,'FX40','LIOU','SURI','C3R5','LIMA')
CALL TEST_NAM_VAR(ILUOUT,'COPWLW',COPWLW,'SAVI','SMSH','LILI','MALA')
CALL TEST_NAM_VAR(ILUOUT,'COPILW',COPILW,'FULI','EBCU','SMSH','FU98')
CALL TEST_NAM_VAR(ILUOUT,'COPWSW',COPWSW,'SLIN','FOUQ','MALA')
CALL TEST_NAM_VAR(ILUOUT,'COPISW',COPISW,'FULI','EBCU','FU96')
!
CALL TEST_NAM_VAR(ILUOUT,'CLBCX(1)',CLBCX(1),'CYCL','WALL','OPEN')
CALL TEST_NAM_VAR(ILUOUT,'CLBCX(2)',CLBCX(2),'CYCL','WALL','OPEN')
CALL TEST_NAM_VAR(ILUOUT,'CLBCY(1)',CLBCY(1),'CYCL','WALL','OPEN')
CALL TEST_NAM_VAR(ILUOUT,'CLBCY(2)',CLBCY(2),'CYCL','WALL','OPEN')
!
CALL TEST_NAM_VAR(ILUOUT,'CTURBDIM',CTURBDIM,'1DIM','3DIM')
CALL TEST_NAM_VAR(ILUOUT,'CTURBLEN',CTURBLEN,'DELT','BL89','DEAR','BLKR')
CALL TEST_NAM_VAR(ILUOUT,'CTOM',CTOM,'NONE','TM06')
CALL TEST_NAM_VAR(ILUOUT,'CSUBG_AUCV',CSUBG_AUCV,'NONE','CLFR','SIGM')
!
CALL TEST_NAM_VAR(ILUOUT,'CCH_TDISCRETIZATION',CCH_TDISCRETIZATION, &
'SPLIT ','CENTER ','LAGGED ')
!
CALL TEST_NAM_VAR(ILUOUT,'CCONF',CCONF,'START','RESTA')
CALL TEST_NAM_VAR(ILUOUT,'CEQNSYS',CEQNSYS,'LHE','DUR','MAE')
CALL TEST_NAM_VAR(ILUOUT,'CSPLIT',CSPLIT,'BSPLITTING','XSPLITTING','YSPLITTING')
!
CALL TEST_NAM_VAR(ILUOUT,'CBUTYPE',CBUTYPE,'NONE','CART','MASK')
!
CALL TEST_NAM_VAR(ILUOUT,'CRELAX_HEIGHT_TYPE',CRELAX_HEIGHT_TYPE,'FIXE','THGR')
!
CALL TEST_NAM_VAR(ILUOUT,'CLES_NORM_TYPE',CLES_NORM_TYPE,'NONE','CONV','EKMA','MOBU')
CALL TEST_NAM_VAR(ILUOUT,'CBL_HEIGHT_DEF',CBL_HEIGHT_DEF,'TKE','KE','WTV','FRI','DTH')
CALL TEST_NAM_VAR(ILUOUT,'CTURBLEN_CLOUD',CTURBLEN_CLOUD,'NONE','DEAR','DELT','BL89')
!
! The test on the mass flux scheme for shallow convection
!
CALL TEST_NAM_VAR(ILUOUT,'CMF_UPDRAFT',CMF_UPDRAFT,'NONE','EDKF','RHCJ',&
'HRIO','SURF','BOUT')
CALL TEST_NAM_VAR(ILUOUT,'CMF_CLOUD',CMF_CLOUD,'NONE','STAT','DIRE')
!
! The test on the CSOLVER name is made elsewhere
!
CALL TEST_NAM_VAR(ILUOUT,'CPRISTINE_ICE',CPRISTINE_ICE,'PLAT','COLU','BURO')
CALL TEST_NAM_VAR(ILUOUT,'CSEDIM',CSEDIM,'SPLI','STAT')
IF( CCLOUD == 'C3R5' ) THEN
CALL TEST_NAM_VAR(ILUOUT,'CPRISTINE_ICE_C1R3',CPRISTINE_ICE_C1R3, &
'PLAT','COLU','BURO')
CALL TEST_NAM_VAR(ILUOUT,'CHEVRIMED_ICE_C1R3',CHEVRIMED_ICE_C1R3, &
'GRAU','HAIL')
END IF
!IF( CCLOUD == 'LIMA' ) THEN
CALL TEST_NAM_VAR(ILUOUT,'CPRISTINE_ICE_LIMA',CPRISTINE_ICE_LIMA, &
'PLAT','COLU','BURO')
CALL TEST_NAM_VAR(ILUOUT,'CHEVRIMED_ICE_LIMA',CHEVRIMED_ICE_LIMA, &
'GRAU','HAIL')
END IF
!-------------------------------------------------------------------------------!
!* 2. FIRST INITIALIZATIONS
! ---------------------
!
!* 2.1 Time step in gridnesting case
!
IF (KMI /= 1 .AND. NDAD(KMI) /= KMI) THEN
XTSTEP = PTSTEP_ALL(NDAD(KMI)) / NDTRATIO(KMI)
END IF
PTSTEP_ALL(KMI) = XTSTEP
!
!* 2.2 Fill the global configuration module
!
! Check coherence between the microphysical scheme and water species and
!initialize the logicals LUSERn
!
SELECT CASE ( CCLOUD )
CASE ( 'NONE' )
IF (.NOT. ( (.NOT. LUSERC) .AND. (.NOT. LUSERR) .AND. (.NOT. LUSERI) .AND. &
(.NOT. LUSERS) .AND. (.NOT. LUSERG) .AND. (.NOT. LUSERH) &
) .AND. CPROGRAM=='MESONH' ) THEN
!
LUSERC=.FALSE.
LUSERR=.FALSE.; LUSERI=.FALSE.
LUSERS=.FALSE.; LUSERG=.FALSE.
LUSERH=.FALSE.
!
END IF
!
IF (CSUBG_AUCV == 'SIGM') THEN
!
WRITE(UNIT=ILUOUT,FMT=9002) KMI
WRITE(UNIT=ILUOUT,FMT=*) 'YOU WANT TO USE THE SUBGRID AUTOCONVERSION SCHEME '
WRITE(UNIT=ILUOUT,FMT=*) ' WITHOUT MICROPHYSICS'
WRITE(UNIT=ILUOUT,FMT=*) ' CSUBG_AUCV IS PUT TO "NONE"'
!
CSUBG_AUCV = 'NONE'
!
END IF
!
CASE ( 'REVE' )
IF (.NOT. ( LUSERV .AND. LUSERC .AND. (.NOT. LUSERR) .AND. (.NOT. LUSERI) &
.AND. (.NOT. LUSERS) .AND. (.NOT. LUSERG) .AND. (.NOT. LUSERH) &
) ) THEN
!
WRITE(UNIT=ILUOUT,FMT=9002) KMI
WRITE(UNIT=ILUOUT,FMT='("YOU WANT TO USE A REVERSIBLE MICROPHYSICAL " ,&
&" SCHEME. YOU WILL ONLY HAVE VAPOR AND CLOUD WATER ",/, &
&" LUSERV AND LUSERC ARE TO TRUE AND THE OTHERS TO FALSE ")')
!
LUSERV=.TRUE. ; LUSERC=.TRUE.
LUSERR=.FALSE.; LUSERI=.FALSE.
LUSERS=.FALSE.; LUSERG=.FALSE.
LUSERH=.FALSE.
END IF
!
IF (CSUBG_AUCV == 'SIGM') THEN
!
WRITE(UNIT=ILUOUT,FMT=9003) KMI
WRITE(UNIT=ILUOUT,FMT=*) 'YOU WANT TO USE BOTH A REVERSIBLE MICROPHYSICAL SCHEME '
WRITE(UNIT=ILUOUT,FMT=*) ' AND THE SUBGRID AUTOCONVERSION SCHEME '
WRITE(UNIT=ILUOUT,FMT=*) 'BUT YOU DO NOT HAVE RAIN in the "REVE" SCHEME'
WRITE(UNIT=ILUOUT,FMT=*) ' CSUBG_AUCV IS PUT TO "NONE"'
! CSUBG_AUCV = 'NONE'
!
END IF
!
CASE ( 'KESS' )
IF (.NOT. ( LUSERV .AND. LUSERC .AND. LUSERR .AND. (.NOT. LUSERI) .AND. &
(.NOT. LUSERS) .AND. (.NOT. LUSERG) .AND. (.NOT. LUSERH) &
) ) THEN
!
WRITE(UNIT=ILUOUT,FMT=9002) KMI
WRITE(UNIT=ILUOUT,FMT='("YOU WANT TO USE A KESSLER MICROPHYSICAL " , &
&" SCHEME. YOU WILL ONLY HAVE VAPOR, CLOUD WATER AND RAIN ",/, &
&" LUSERV, LUSERC AND LUSERR ARE SET TO TRUE AND THE OTHERS TO FALSE ")')
!
LUSERV=.TRUE. ; LUSERC=.TRUE. ; LUSERR=.TRUE.
LUSERI=.FALSE.; LUSERS=.FALSE.
LUSERG=.FALSE.; LUSERH=.FALSE.
END IF
!
IF (CSUBG_AUCV == 'SIGM') THEN
!
WRITE(UNIT=ILUOUT,FMT=9003) KMI
WRITE(UNIT=ILUOUT,FMT=*) 'YOU WANT TO USE BOTH A KESSLER MICROPHYSICAL SCHEME '
WRITE(UNIT=ILUOUT,FMT=*) ' AND THE SUBGRID AUTOCONVERSION SCHEME USING'
WRITE(UNIT=ILUOUT,FMT=*) 'SIGMA_RC.'
WRITE(UNIT=ILUOUT,FMT=*) 'THIS IS NOT YET AVAILABLE.'
WRITE(UNIT=ILUOUT,FMT=*) 'SET CSUBG_AUCV TO "CLFR" or "NONE" OR CCLOUD TO "ICE3"'
!
!callabortstop
CALL PRINT_MSG(NVERB_FATAL,'GEN','READ_EXSEG_n','')
END IF
!
CASE ( 'ICE3' )
IF (.NOT. ( LUSERV .AND. LUSERC .AND. LUSERR .AND. LUSERI .AND. LUSECI &
.AND. LUSERS .AND. LUSERG .AND. (.NOT. LUSERH)) &
.AND. CPROGRAM=='MESONH' ) THEN
!
WRITE(UNIT=ILUOUT,FMT=9002) KMI
WRITE(UNIT=ILUOUT,FMT=*) 'YOU WANT TO USE THE ice3 SIMPLE MIXED PHASE'
WRITE(UNIT=ILUOUT,FMT=*) 'MICROPHYSICAL SCHEME. YOU WILL ONLY HAVE VAPOR, CLOUD WATER,'
WRITE(UNIT=ILUOUT,FMT=*) 'RAIN WATER, CLOUD ICE (MIXING RATIO AND CONCENTRATION)'
WRITE(UNIT=ILUOUT,FMT=*) 'SNOW-AGGREGATES AND GRAUPELN.'
WRITE(UNIT=ILUOUT,FMT=*) 'LUSERV,LUSERC,LUSERR,LUSERI,LUSECI,LUSERS,LUSERG ARE SET TO TRUE'
WRITE(UNIT=ILUOUT,FMT=*) 'AND LUSERH TO FALSE'
!
LUSERV=.TRUE. ; LUSERC=.TRUE. ; LUSERR=.TRUE.
LUSERI=.TRUE. ; LUSECI=.TRUE.
LUSERS=.TRUE. ; LUSERG=.TRUE.
LUSERH=.FALSE.
END IF
!
IF (CSUBG_AUCV == 'SIGM' .AND. .NOT. LSUBG_COND) THEN
WRITE(UNIT=ILUOUT,FMT=9002) KMI
WRITE(UNIT=ILUOUT,FMT=*) 'YOU WANT TO USE SUBGRID AUTOCONVERSION SCHEME'
WRITE(UNIT=ILUOUT,FMT=*) ' WITHOUT THE SUBGRID CONDENSATION SCHEME.'
WRITE(UNIT=ILUOUT,FMT=*) 'THIS IS NOT ALLOWED: CSUBG_AUCV is SET to NONE'
CSUBG_AUCV='NONE'
END IF
!
IF (CSUBG_AUCV == 'CLFR' .AND. CSCONV /= 'EDKF') THEN
WRITE(UNIT=ILUOUT,FMT=9002) KMI
WRITE(UNIT=ILUOUT,FMT=*) 'YOU WANT TO USE SUBGRID AUTOCONVERSION SCHEME'
WRITE(UNIT=ILUOUT,FMT=*) 'WITH THE CONVECTIVE CLOUD FRACTION WITHOUT EDKF'
WRITE(UNIT=ILUOUT,FMT=*) 'THIS IS NOT ALLOWED: CSUBG_AUCV is SET to NONE'
CSUBG_AUCV='NONE'
END IF
!
CASE ( 'ICE4' )
IF (.NOT. ( LUSERV .AND. LUSERC .AND. LUSERR .AND. LUSERI .AND. LUSECI &
.AND. LUSERS .AND. LUSERG .AND. LUSERH) & .AND. CPROGRAM=='MESONH' ) THEN
!
WRITE(UNIT=ILUOUT,FMT=9002) KMI
WRITE(UNIT=ILUOUT,FMT=*) 'YOU WANT TO USE THE ice4 SIMPLE MIXED PHASE'
WRITE(UNIT=ILUOUT,FMT=*) 'MICROPHYSICAL SCHEME. YOU WILL ONLY HAVE VAPOR, CLOUD WATER,'
WRITE(UNIT=ILUOUT,FMT=*) 'RAIN WATER, CLOUD ICE (MIXING RATIO AND CONCENTRATION)'
WRITE(UNIT=ILUOUT,FMT=*) 'SNOW-AGGREGATES, GRAUPELN AND HAILSTONES.'
WRITE(UNIT=ILUOUT,FMT=*) 'LUSERV,LUSERC,LUSERR,LUSERI,LUSECI,LUSERS,LUSERG'
WRITE(UNIT=ILUOUT,FMT=*) 'AND LUSERH ARE SET TO TRUE'
!
LUSERV=.TRUE. ; LUSERC=.TRUE. ; LUSERR=.TRUE.
LUSERI=.TRUE. ; LUSECI=.TRUE.
LUSERS=.TRUE. ; LUSERG=.TRUE. ; LUSERH=.TRUE.
END IF
!
IF (CSUBG_AUCV /= 'NONE' .AND. .NOT. LSUBG_COND) THEN
WRITE(UNIT=ILUOUT,FMT=9002) KMI
WRITE(UNIT=ILUOUT,FMT=*) 'YOU WANT TO USE SUBGRID AUTOCONVERSION SCHEME'
WRITE(UNIT=ILUOUT,FMT=*) ' WITHOUT THE SUBGRID CONDENSATION SCHEME.'
WRITE(UNIT=ILUOUT,FMT=*) 'THIS IS NOT ALLOWED: CSUBG_AUCV is SET to NONE'
CSUBG_AUCV='NONE'
END IF
!
CASE ( 'C2R2','C3R5', 'KHKO' )
IF (( EPARAM_CCN == 'XXX') .OR. (EINI_CCN == 'XXX')) THEN
WRITE(UNIT=ILUOUT,FMT='("YOU WANT TO USE A 2-MOMENT MICROPHYSICAL ", &
&" SCHEME BUT YOU DIDNT FILL CORRECTLY NAM_PARAM_C2R2", &
&" YOU HAVE TO FILL HPARAM_CCN and HINI_CCN ")')
!callabortstop
CALL PRINT_MSG(NVERB_FATAL,'GEN','READ_EXSEG_n','')
END IF
IF (HCLOUD == 'NONE') THEN
CGETCLOUD = 'SKIP'
ELSE IF (HCLOUD == 'REVE' ) THEN
CGETCLOUD = 'INI1'
ELSE IF (HCLOUD == 'KESS' ) THEN
CGETCLOUD = 'INI2'
ELSE IF (HCLOUD == 'ICE3' ) THEN
IF (CCLOUD == 'C3R5') THEN
CGETCLOUD = 'INI2'
ELSE
WRITE(UNIT=ILUOUT,FMT=9003) KMI
WRITE(UNIT=ILUOUT,FMT='("YOU WANT TO USE THE WARM MICROPHYSICAL ", &
&" SCHEME BUT YOU WERE USING THE ICE3 SCHEME PREVIOUSLY.",/, &
&" AS THIS IS A LITTLE BIT STUPID IT IS NOT AUTHORIZED !!!")')
!callabortstop
CALL PRINT_MSG(NVERB_FATAL,'GEN','READ_EXSEG_n','')
END IF
ELSE
CGETCLOUD = 'READ' ! This is automatically done
END IF
!
IF ((CCLOUD == 'C2R2' ).OR. (CCLOUD == 'KHKO' )) THEN
IF (.NOT. ( LUSERV .AND. LUSERC .AND. LUSERR .AND. (.NOT. LUSERI) .AND. &
(.NOT. LUSERS) .AND. (.NOT. LUSERG) .AND. (.NOT. LUSERH) &
) ) THEN
WRITE(UNIT=ILUOUT,FMT=9002) KMI
WRITE(UNIT=ILUOUT,FMT='("YOU WANT TO USE THE C2R2 MICROPHYSICAL ", &
&" SCHEME. YOU WILL ONLY HAVE VAPOR, CLOUD WATER AND RAIN ",/, &
&"LUSERV, LUSERC AND LUSERR ARE SET TO TRUE AND THE OTHERS TO FALSE ")')
!
LUSERV=.TRUE. ; LUSERC=.TRUE. ; LUSERR=.TRUE.
LUSERI=.FALSE.; LUSERS=.FALSE.
LUSERG=.FALSE.; LUSERH=.FALSE.
END IF
ELSE IF (CCLOUD == 'C3R5') THEN
IF (.NOT. ( LUSERV .AND. LUSERC .AND. LUSERR .AND. LUSERI .AND. &
LUSERS .AND. LUSERG .AND. (.NOT. LUSERH) &
) ) THEN
WRITE(UNIT=ILUOUT,FMT=9002) KMI WRITE(UNIT=ILUOUT,FMT='("YOU WANT TO USE THE C3R5 MICROPHYS. SCHEME.",&
&" YOU WILL HAVE VAPOR, CLOUD WATER/ICE, RAIN, SNOW AND GRAUPEL ",/, &
&"LUSERV, LUSERC, LUSERR, LUSERI, LUSERS, LUSERG ARE SET TO TRUE")' )
!
LUSERV=.TRUE. ; LUSERC=.TRUE. ; LUSERR=.TRUE.
LUSERI=.TRUE. ; LUSECI=.TRUE.
LUSERS=.TRUE. ; LUSERG=.TRUE.
LUSERH=.FALSE.
END IF
ELSE IF (CCLOUD == 'LIMA') THEN
IF (.NOT. ( LUSERV .AND. LUSERC .AND. LUSERR .AND. LUSERI .AND. &
LUSERS .AND. LUSERG .AND. (.NOT. LUSERH) &
) ) THEN
WRITE(UNIT=ILUOUT,FMT=9002) KMI
WRITE(UNIT=ILUOUT,FMT='("YOU WANT TO USE THE LIMA MICROPHYS. SCHEME.",&
&" YOU WILL HAVE VAPOR, CLOUD WATER/ICE, RAIN, SNOW AND GRAUPEL ",/, &
&"LUSERV, LUSERC, LUSERR, LUSERI, LUSERS, LUSERG ARE SET TO TRUE")' )
!
LUSERV=.TRUE. ; LUSERC=.TRUE. ; LUSERR=.TRUE.
LUSERI=.TRUE. ; LUSECI=.TRUE.
LUSERS=.TRUE. ; LUSERG=.TRUE.
LUSERH=.FALSE.
END IF
END IF
!
IF (LSUBG_COND) THEN
WRITE(UNIT=ILUOUT,FMT=9003) KMI
WRITE(UNIT=ILUOUT,FMT=*) 'YOU WANT TO USE BOTH THE SIMPLE MIXED PHASE'
WRITE(UNIT=ILUOUT,FMT=*) 'MICROPHYS. SCHEME AND THE SUBGRID COND. SCHEME.'
WRITE(UNIT=ILUOUT,FMT=*) 'THIS IS NOT YET AVAILABLE.'
WRITE(UNIT=ILUOUT,FMT=*) 'SET LSUBG_COND TO FALSE OR CCLOUD TO "REVE", "KESS"'
!callabortstop
CALL PRINT_MSG(NVERB_FATAL,'GEN','READ_EXSEG_n','')
END IF
!
IF ( CEFRADL /= 'C2R2') THEN
WRITE(UNIT=ILUOUT,FMT=9001) KMI
WRITE(UNIT=ILUOUT,FMT=*) ' YOU DID NOT CHOOSE CEFRADL=C2R2 FOR RADIATION'
WRITE(UNIT=ILUOUT,FMT=*) ' IT IS ADVISED TO USE CEFRADL=C2R2 '
WRITE(UNIT=ILUOUT,FMT=*) ' WITH A 2-MOMENT MICROPHYSICAL SCHEME'
END IF
!
IF ( CCLOUD == 'C3R5' .AND. CEFRADI /= 'C3R5') THEN
WRITE(UNIT=ILUOUT,FMT=9001) KMI
WRITE(UNIT=ILUOUT,FMT=*) ' YOU DID NOT CHOOSE CEFRADI=C3R5 FOR RADIATION'
WRITE(UNIT=ILUOUT,FMT=*) ' IT IS ADVISED TO USE CEFRADI=C3R5 '
WRITE(UNIT=ILUOUT,FMT=*) ' WITH A 2-MOMENT MICROPHYSICAL SCHEME'
END IF
!
IF ( WALPHAC /= 3.0 .OR. WNUC /= 2.0) THEN
WRITE(UNIT=ILUOUT,FMT=9001) KMI
WRITE(UNIT=ILUOUT,FMT=*) 'IT IS ADVISED TO USE XALPHAC=3. and XNUC=2.'
WRITE(UNIT=ILUOUT,FMT=*) 'FOR STRATOCUMULUS WITH KHKO SCHEME. '
END IF
!
IF ( CEFRADL /= 'C2R2') THEN
WRITE(UNIT=ILUOUT,FMT=9001) KMI
WRITE(UNIT=ILUOUT,FMT=*) ' YOU DID NOT CHOOSE CEFRADL=C2R2 FOR RADIATION'
WRITE(UNIT=ILUOUT,FMT=*) ' IT IS ADVISED TO USE CEFRADL=C2R2 '
WRITE(UNIT=ILUOUT,FMT=*) ' WITH A 2-MOMENT MICROPHYSICAL SCHEME'
END IF
!
CASE ( 'LIMA')
IF ((LACTI .AND. FINI_CCN == 'XXX')) THEN
WRITE(UNIT=ILUOUT,FMT=9001) KMI
WRITE(UNIT=ILUOUT,FMT='("YOU WANT TO USE A 2-MOMENT MICROPHYSICAL ", &
&" SCHEME BUT YOU DIDNT FILL CORRECTLY NAM_PARAM_LIMA", &
&" YOU HAVE TO FILL FINI_CCN ")')
STOP
END IF!
IF(LACTI .AND. NMOD_CCN == 0) THEN
WRITE(UNIT=ILUOUT,FMT=9001) KMI
WRITE(UNIT=ILUOUT,FMT='("ACTIVATION OF AEROSOL PARTICLES IS NOT " &
&"POSSIBLE IF NMOD_CCN HAS VALUE ZERO. YOU HAVE TO SET AN UPPER " &
&"VALUE OF NMOD_CCN IN ORDER TO USE LIMA WARM ACTIVATION SCHEME.")')
STOP
END IF
!
IF(LNUCL .AND. NMOD_IFN == 0 .AND. (.NOT.LMEYERS)) THEN
WRITE(UNIT=ILUOUT,FMT=9001) KMI
WRITE(UNIT=ILUOUT,FMT='("NUCLEATION BY DEPOSITION AND CONTACT IS NOT "&
&"POSSIBLE IF NMOD_IFN HAS VALUE ZERO. YOU HAVE TO SET AN UPPER" &
&"VALUE OF NMOD_IFN IN ORDER TO USE LIMA COLD NUCLEATION SCHEME.")')
END IF
!
IF (HCLOUD == 'NONE') THEN
CGETCLOUD = 'SKIP'
ELSE IF (HCLOUD == 'REVE' ) THEN
CGETCLOUD = 'INI1'
ELSE IF (HCLOUD == 'KESS' ) THEN
CGETCLOUD = 'INI2'
ELSE IF (HCLOUD == 'ICE3' ) THEN
CGETCLOUD = 'INI2'
ELSE
CGETCLOUD = 'READ' ! This is automatically done
END IF
!
IF (LWARM) THEN
LUSERV=.TRUE. ; LUSERC=.TRUE. ; LUSERR=.TRUE.
LUSERI=.FALSE.; LUSERS=.FALSE. ; LUSERG=.FALSE.; LUSERH=.FALSE.
END IF
!
IF (LCOLD) THEN
LUSERV=.TRUE. ; LUSERC=.TRUE. ; LUSERR=.TRUE.
LUSERI=.TRUE. ; LUSERS=.TRUE. ; LUSERG=.TRUE.
LUSERH=LHAIL
END IF
!
IF (LSUBG_COND .AND. LCOLD) THEN
WRITE(UNIT=ILUOUT,FMT=9003) KMI
WRITE(UNIT=ILUOUT,FMT=*) 'YOU WANT TO USE BOTH THE SIMPLE MIXED PHASE'
WRITE(UNIT=ILUOUT,FMT=*) 'MICROPHYS. SCHEME AND THE SUBGRID COND. SCHEME.'
WRITE(UNIT=ILUOUT,FMT=*) 'THIS IS NOT YET AVAILABLE. SET LSUBG_COND '
WRITE(UNIT=ILUOUT,FMT=*) 'TO FALSE OR CCLOUD TO "REVE", "KESS" '
!callabortstop
CALL PRINT_MSG(NVERB_FATAL,'GEN','READ_EXSEG_n','')
END IF
!
IF ( XALPHAC /= 3.0 .OR. XNUC /= 2.0) THEN
WRITE(UNIT=ILUOUT,FMT=9001) KMI
WRITE(UNIT=ILUOUT,FMT=*) 'IT IS ADVISED TO USE XALPHAC=3. and XNUC=2.'
WRITE(UNIT=ILUOUT,FMT=*) 'FOR STRATOCUMULUS. '
END IF
!
IF ( CEFRADL /= 'LIMA') THEN
WRITE(UNIT=ILUOUT,FMT=9001) KMI
WRITE(UNIT=ILUOUT,FMT=*) ' YOU DID NOT CHOOSE CEFRADL=LIMA FOR RADIATION'
WRITE(UNIT=ILUOUT,FMT=*) ' IT IS ADVISED TO USE CEFRADL=LIMA '
WRITE(UNIT=ILUOUT,FMT=*) ' WITH A 2-MOMENT MICROPHYSICAL SCHEME "LIMA"'
END IF
IF (LUSECHEM ) THEN
WRITE(UNIT=ILUOUT,FMT=*) 'YOU WANT TO USE BOTH LIMA MICROPHYS. SCHEME AND CHEMISTRY'
WRITE(UNIT=ILUOUT,FMT=*) 'THIS IS NOT YET AVAILABLE. SET LUSECHEM '
WRITE(UNIT=ILUOUT,FMT=*) 'TO FALSE OR CCLOUD TO "ICE3" '
!callabortstop
CALL PRINT_MSG(NVERB_FATAL,'GEN','READ_EXSEG_n','')
END IF
IF (LDUST ) THEN WRITE(UNIT=ILUOUT,FMT=*) 'YOU WANT TO USE BOTH LIMA MICROPHYS. SCHEME AND DUSTS '
WRITE(UNIT=ILUOUT,FMT=*) 'THIS IS NOT YET AVAILABLE. SET LDUST '
WRITE(UNIT=ILUOUT,FMT=*) 'TO FALSE OR CCLOUD TO "ICE3" '
!callabortstop
CALL PRINT_MSG(NVERB_FATAL,'GEN','READ_EXSEG_n','')
END IF
IF (LSALT ) THEN
WRITE(UNIT=ILUOUT,FMT=*) 'YOU WANT TO USE BOTH LIMA MICROPHYS. SCHEME AND SEA SALTS '
WRITE(UNIT=ILUOUT,FMT=*) 'THIS IS NOT YET AVAILABLE. SET LSALT '
WRITE(UNIT=ILUOUT,FMT=*) 'TO FALSE OR CCLOUD TO "ICE3" '
!callabortstop
CALL PRINT_MSG(NVERB_FATAL,'GEN','READ_EXSEG_n','')
END IF
!
END SELECT
!
LUSERV_G(KMI) = LUSERV
LUSERC_G(KMI) = LUSERC
LUSERR_G(KMI) = LUSERR
LUSERI_G(KMI) = LUSERI
LUSERS_G(KMI) = LUSERS
LUSERG_G(KMI) = LUSERG
LUSERH_G(KMI) = LUSERH
LUSETKE(KMI) = (CTURB /= 'NONE')
!
!-------------------------------------------------------------------------------
!
!* 2.3 Chemical and NSV_* variables initializations
!
CALL UPDATE_NAM_PARAMN
CALL UPDATE_NAM_DYNN
CALL UPDATE_NAM_CONFN
!
IF (LORILAM .AND. .NOT. LUSECHEM) THEN
WRITE(UNIT=ILUOUT,FMT=9002) KMI
WRITE(ILUOUT,FMT=*) 'YOU CANNOT USE ORILAM AEROSOL SCHEME WITHOUT '
WRITE(ILUOUT,FMT=*) 'CHEMICAL GASEOUS CHEMISTRY '
WRITE(ILUOUT,FMT=*) 'THEREFORE LUSECHEM IS SET TO TRUE '
LUSECHEM=.TRUE.
END IF
!
IF (LUSECHAQ.AND.(.NOT.LUSECHEM)) THEN
WRITE(UNIT=ILUOUT,FMT=9003) KMI
WRITE(UNIT=ILUOUT,FMT=*) 'YOU WANT TO USE AQUEOUS PHASE CHEMISTRY'
WRITE(UNIT=ILUOUT,FMT=*) 'BUT THE CHEMISTRY IS NOT ACTIVATED'
WRITE(UNIT=ILUOUT,FMT=*) 'SET LUSECHEM TO TRUE IF YOU WANT REALLY USE CHEMISTRY'
WRITE(UNIT=ILUOUT,FMT=*) 'OR SET LUSECHAQ TO FALSE IF YOU DO NOT WANT USE IT'
!callabortstop
CALL PRINT_MSG(NVERB_FATAL,'GEN','READ_EXSEG_n','')
END IF
IF (LUSECHAQ.AND.(.NOT.LUSERC).AND.CPROGRAM=='MESONH') THEN
WRITE(UNIT=ILUOUT,FMT=9003) KMI
WRITE(UNIT=ILUOUT,FMT=*) 'YOU WANT TO USE AQUEOUS PHASE CHEMISTRY'
WRITE(UNIT=ILUOUT,FMT=*) 'BUT CLOUD MICROPHYSICS IS NOT ACTIVATED'
WRITE(UNIT=ILUOUT,FMT=*) 'LUSECHAQ IS SET TO FALSE'
LUSECHAQ = .FALSE.
END IF
IF (LUSECHAQ.AND.CCLOUD(1:3) == 'ICE'.AND. .NOT. LUSECHIC) THEN
WRITE(UNIT=ILUOUT,FMT=9002) KMI
WRITE(UNIT=ILUOUT,FMT=*) 'YOU WANT TO USE AQUEOUS PHASE CHEMISTRY'
WRITE(UNIT=ILUOUT,FMT=*) 'WITH MIXED PHASE CLOUD MICROPHYSICS'
WRITE(UNIT=ILUOUT,FMT=*) 'SET LUSECHIC TO TRUE IF YOU WANT TO ACTIVATE'
WRITE(UNIT=ILUOUT,FMT=*) 'ICE PHASE CHEMICAL SPECIES'
IF (LCH_RET_ICE) THEN
WRITE(UNIT=ILUOUT,FMT=*) 'LCH_RET_ICE TRUE MEANS ALL SOLUBLE'
WRITE(UNIT=ILUOUT,FMT=*) 'GASES ARE RETAINED IN ICE PHASE'
WRITE(UNIT=ILUOUT,FMT=*) 'WHEN SUPERCOOLED WATER FREEZES'
ELSE
WRITE(UNIT=ILUOUT,FMT=*) 'LCH_RET_ICE FALSE MEANS ALL SOLUBLE'
WRITE(UNIT=ILUOUT,FMT=*) 'GASES GO BACK TO THE GAS PHASE WHEN' WRITE(UNIT=ILUOUT,FMT=*) 'SUPERCOOLED WATER FREEZES'
ENDIF
ENDIF
IF (LUSECHIC.AND. .NOT. CCLOUD(1:3) == 'ICE'.AND.CPROGRAM=='MESONH') THEN
WRITE(UNIT=ILUOUT,FMT=9003) KMI
WRITE(UNIT=ILUOUT,FMT=*) 'YOU WANT TO USE ICE PHASE CHEMISTRY'
WRITE(UNIT=ILUOUT,FMT=*) 'BUT MIXED PHASE CLOUD MICROPHYSICS IS NOT ACTIVATED'
WRITE(UNIT=ILUOUT,FMT=*) 'LUSECHIC IS SET TO FALSE'
LUSECHIC= .FALSE.
ENDIF
IF (LCH_PH.AND. (.NOT. LUSECHAQ)) THEN
WRITE(UNIT=ILUOUT,FMT=9003) KMI
WRITE(UNIT=ILUOUT,FMT=*) 'DIAGNOSTIC PH COMPUTATION IS ACTIVATED'
WRITE(UNIT=ILUOUT,FMT=*) 'BUT AQUEOUS PHASE CHEMISTRY IS NOT ACTIVATED'
WRITE(UNIT=ILUOUT,FMT=*) 'SET LUSECHAQ TO TRUE IF YOU WANT TO ACTIVATE IT'
WRITE(UNIT=ILUOUT,FMT=*) 'LCH_PH IS SET TO FALSE'
LCH_PH= .FALSE.
ENDIF
IF (LUSECHIC.AND.(.NOT.LUSECHAQ)) THEN
WRITE(UNIT=ILUOUT,FMT=9003) KMI
WRITE(UNIT=ILUOUT,FMT=*) 'YOU WANT TO USE ICE PHASE CHEMISTRY'
WRITE(UNIT=ILUOUT,FMT=*) 'BUT THE AQUEOUS PHASE CHEMISTRY IS NOT ACTIVATED'
WRITE(UNIT=ILUOUT,FMT=*) 'SET LUSECHAQ TO TRUE IF YOU WANT REALLY USE CLOUD CHEMISTRY'
WRITE(UNIT=ILUOUT,FMT=*) 'OR SET LUSECHIC TO FALSE IF YOU DO NOT WANT USE IT'
!callabortstop
CALL PRINT_MSG(NVERB_FATAL,'GEN','READ_EXSEG_n','')
END IF
IF ((LUSECHIC).AND.(LCH_RET_ICE)) THEN
WRITE(UNIT=ILUOUT,FMT=9003) KMI
WRITE(UNIT=ILUOUT,FMT=*) 'YOU WANT TO USE RETENTION OF SOLUBLE GASES IN ICE'
WRITE(UNIT=ILUOUT,FMT=*) 'BUT THE ICE PHASE CHEMISTRY IS ACTIVATED'
WRITE(UNIT=ILUOUT,FMT=*) 'FLAG LCH_RET_ICE IS ONLY USES WHEN LUSECHIC IS SET'
WRITE(UNIT=ILUOUT,FMT=*) 'TO FALSE IE NO CHEMICAL SPECIES IN ICE'
ENDIF
!
IF (LUSECHEM) THEN
CALL CH_INIT_SCHEME_n(KMI,LUSECHAQ,LUSECHIC,LCH_PH,ILUOUT,NVERB)
IF (LORILAM) CALL CH_AER_INIT_SOA(ILUOUT, NVERB)
END IF
!
CALL UPDATE_NAM_CH_MNHCN
CALL INI_NSV(KMI)
!
! From this point, all NSV* variables contain valid values for model KMI
!
DO JSV = 1,NSV
LUSESV(JSV,KMI) = .TRUE.
END DO
!
IF ( CAOP=='EXPL' .AND. .NOT.LDUST .AND. .NOT.LORILAM &
.AND. .NOT.LSALT .AND. .NOT.(CCLOUD=='LIMA') ) THEN
WRITE(UNIT=ILUOUT,FMT=9001) KMI
WRITE(UNIT=ILUOUT,FMT=*) ' YOU WANT TO USE EXPLICIT AEROSOL OPTICAL '
WRITE(UNIT=ILUOUT,FMT=*) 'PROPERTIES BUT YOU DONT HAVE DUST OR '
WRITE(UNIT=ILUOUT,FMT=*) 'AEROSOL OR SALT THEREFORE CAOP=CLIM'
CAOP='CLIM'
END IF
!-------------------------------------------------------------------------------
!
!* 3. CHECK COHERENCE BETWEEN EXSEG VARIABLES AND FMFILE ATTRIBUTES
! -------------------------------------------------------------
!
!
!* 3.1 Turbulence variable
!
IF ((CTURB /= 'NONE').AND.(HTURB == 'NONE')) THEN
CGETTKET ='INIT'
WRITE(UNIT=ILUOUT,FMT=9001) KMI
WRITE(UNIT=ILUOUT,FMT=*)'YOU WANT TO USE TURBULENCE KINETIC ENERGY TKE' WRITE(UNIT=ILUOUT,FMT=*)'WHEREAS IT IS NOT IN INITIAL FMFILE'
WRITE(UNIT=ILUOUT,FMT=*)'TKE WILL BE INITIALIZED TO ZERO'
ELSE
IF (CTURB /= 'NONE') THEN
CGETTKET ='READ'
IF ((CCONF=='START') .AND. CPROGRAM /= 'DIAG') CGETTKET='INIT'
ELSE
CGETTKET ='SKIP'
END IF
END IF
!
!
IF ((CTOM == 'TM06').AND.(HTOM /= 'TM06')) THEN
CGETBL_DEPTH ='INIT'
WRITE(UNIT=ILUOUT,FMT=9001) KMI
WRITE(UNIT=ILUOUT,FMT=*)'YOU WANT TO USE BL DEPTH FOR THIRD ORDER MOMENTS'
WRITE(UNIT=ILUOUT,FMT=*)'WHEREAS IT IS NOT IN INITIAL FMFILE'
WRITE(UNIT=ILUOUT,FMT=*)'IT WILL BE INITIALIZED TO ZERO'
ELSE
IF (CTOM == 'TM06') THEN
CGETBL_DEPTH ='READ'
ELSE
CGETBL_DEPTH ='SKIP'
END IF
END IF
!
IF (LRMC01 .AND. .NOT. ORMC01) THEN
CGETSBL_DEPTH ='INIT'
WRITE(UNIT=ILUOUT,FMT=9001) KMI
WRITE(UNIT=ILUOUT,FMT=*)'YOU WANT TO USE SBL DEPTH FOR RMC01'
WRITE(UNIT=ILUOUT,FMT=*)'WHEREAS IT IS NOT IN INITIAL FMFILE'
WRITE(UNIT=ILUOUT,FMT=*)'IT WILL BE INITIALIZED TO ZERO'
ELSE
IF (LRMC01) THEN
CGETSBL_DEPTH ='READ'
ELSE
CGETSBL_DEPTH ='SKIP'
END IF
END IF
!
!
!* 3.2 Moist variables
!
IF (LUSERV.AND. (.NOT.OUSERV)) THEN
WRITE(UNIT=ILUOUT,FMT=9001) KMI
WRITE(UNIT=ILUOUT,FMT='("YOU WANT TO USE VAPOR VARIABLE Rv WHEREAS IT ", &
& "IS NOT IN INITIAL FMFILE",/, &
& "Rv WILL BE INITIALIZED TO ZERO")')
CGETRVT='INIT'
ELSE
IF (LUSERV) THEN
CGETRVT='READ'
ELSE
CGETRVT='SKIP'
END IF
END IF
!
IF (LUSERC.AND. (.NOT.OUSERC)) THEN
WRITE(UNIT=ILUOUT,FMT=9001) KMI
WRITE(UNIT=ILUOUT,FMT='("YOU WANT TO USE CLOUD VARIABLE Rc WHEREAS IT ", &
& " IS NOT IN INITIAL FMFILE",/, &
& "Rc WILL BE INITIALIZED TO ZERO")')
CGETRCT='INIT'
ELSE
IF (LUSERC) THEN
CGETRCT='READ'
! IF(CCONF=='START') CGETRCT='INIT'
ELSE
CGETRCT='SKIP'
END IFEND IF
!
IF (LUSERR.AND. (.NOT.OUSERR)) THEN
WRITE(UNIT=ILUOUT,FMT=9001) KMI
WRITE(UNIT=ILUOUT,FMT='("YOU WANT TO USE RAIN VARIABLE Rr WHEREAS IT ", &
& "IS NOT IN INITIAL FMFILE",/, &
& " Rr WILL BE INITIALIZED TO ZERO")')
CGETRRT='INIT'
ELSE
IF (LUSERR) THEN
CGETRRT='READ'
! IF( (CCONF=='START').AND. CPROGRAM /= 'DIAG') CGETRRT='INIT'
ELSE
CGETRRT='SKIP'
END IF
END IF
!
IF (LUSERI.AND. (.NOT.OUSERI)) THEN
WRITE(UNIT=ILUOUT,FMT=9001) KMI
WRITE(UNIT=ILUOUT,FMT='("YOU WANT TO USE ICE VARIABLE Ri WHEREAS IT ", &
& "IS NOT IN INITIAL FMFILE",/, &
& " Ri WILL BE INITIALIZED TO ZERO")')
CGETRIT='INIT'
ELSE
IF (LUSERI) THEN
CGETRIT='READ'
! IF(CCONF=='START') CGETRIT='INIT'
ELSE
CGETRIT='SKIP'
END IF
END IF
!
IF (LUSECI.AND. (.NOT.OUSECI)) THEN
WRITE(UNIT=ILUOUT,FMT=9001) KMI
WRITE(UNIT=ILUOUT,FMT='("YOU WANT TO USE ICE CONC. VARIABLE Ci WHEREAS IT ",&
& "IS NOT IN INITIAL FMFILE",/, &
& " Ci WILL BE INITIALIZED TO ZERO")')
CGETCIT='INIT'
ELSE
IF (LUSECI) THEN
CGETCIT='READ'
ELSE
CGETCIT='SKIP'
END IF
END IF
!
IF (LUSERS.AND. (.NOT.OUSERS)) THEN
WRITE(UNIT=ILUOUT,FMT=9001) KMI
WRITE(UNIT=ILUOUT,FMT='("YOU WANT TO USE SNOW VARIABLE Rs WHEREAS IT ",&
& "IS NOT IN INITIAL FMFILE",/, &
& " Rs WILL BE INITIALIZED TO ZERO")')
CGETRST='INIT'
ELSE
IF (LUSERS) THEN
CGETRST='READ'
! IF ( (CCONF=='START').AND. CPROGRAM /= 'DIAG') CGETRST='INIT'
ELSE
CGETRST='SKIP'
END IF
END IF
!
IF (LUSERG.AND. (.NOT.OUSERG)) THEN
WRITE(UNIT=ILUOUT,FMT=9001) KMI
WRITE(UNIT=ILUOUT,FMT='("YOU WANT TO USE GRAUPEL VARIABLE Rg WHEREAS ",&
& " IT IS NOTIN INITIAL FMFILE",/, &
& "Rg WILL BE INITIALIZED TO ZERO")')
CGETRGT='INIT'
ELSE
IF (LUSERG) THEN CGETRGT='READ'
! IF ( (CCONF=='START') .AND. CPROGRAM /= 'DIAG') CGETRGT='INIT'
ELSE
CGETRGT='SKIP'
END IF
END IF
!
IF (LUSERH.AND. (.NOT.OUSERH)) THEN
WRITE(UNIT=ILUOUT,FMT=9001) KMI
WRITE(UNIT=ILUOUT,FMT='("YOU WANT TO USE HAIL VARIABLE Rh WHEREAS",&
& "IT IS NOT IN INITIAL FMFILE",/, &
& " Rh WILL BE INITIALIZED TO ZERO")')
CGETRHT='INIT'
ELSE
IF (LUSERH) THEN
CGETRHT='READ'
! IF ( (CCONF=='START') .AND. CPROGRAM /= 'DIAG') CGETRHT='INIT'
ELSE
CGETRHT='SKIP'
END IF
END IF
!
IF (LUSERC.AND. (.NOT.OUSERC)) THEN
WRITE(UNIT=ILUOUT,FMT=9001) KMI
WRITE(UNIT=ILUOUT,FMT=*) 'THE CLOUD FRACTION WILL BE INITIALIZED ACCORDING'
WRITE(UNIT=ILUOUT,FMT=*) 'TO CLOUD MIXING RATIO VALUE OR SET TO 0'
CGETCLDFR = 'INIT'
ELSE
IF ( LUSERC ) THEN
CGETCLDFR = 'READ'
IF ( (CCONF=='START') .AND. CPROGRAM /= 'DIAG') CGETCLDFR='INIT'
ELSE
CGETCLDFR = 'SKIP'
END IF
END IF
!
!* 3.3 Moist turbulence
!
IF ( LUSERC .AND. CTURB /= 'NONE' ) THEN
IF ( .NOT. (OUSERC .AND. HTURB /= 'NONE') ) THEN
WRITE(UNIT=ILUOUT,FMT=9001) KMI
WRITE(UNIT=ILUOUT,FMT='("YOU WANT TO USE MOIST TURBULENCE WHEREAS IT ",/, &
& " WAS NOT THE CASE FOR THE INITIAL FMFILE GENERATION",/, &
& "SRC AND SIGS ARE INITIALIZED TO 0")')
CGETSRCT ='INIT'
CGETSIGS ='INIT'
ELSE
CGETSRCT ='READ'
IF ( (CCONF=='START') .AND. CPROGRAM /= 'DIAG') CGETSRCT ='INIT'
CGETSIGS ='READ'
END IF
ELSE
CGETSRCT ='SKIP'
CGETSIGS ='SKIP'
END IF
!
IF(NMODEL_CLOUD==KMI .AND. CTURBLEN_CLOUD/='NONE') THEN
IF (CTURB=='NONE' .OR. .NOT.LUSERC) THEN
WRITE(UNIT=ILUOUT,FMT=9001) KMI
WRITE(UNIT=ILUOUT,FMT='("YOU WANT TO COMPUTE A MIXING LENGTH FOR CLOUD=", &
& A4,/, &
& ", WHEREAS YOU DO NOT SPECIFY A TURBULENCE SCHEME OR ", &
& "USE OF RC,",/," CTURBLEN_CLOUD IS SET TO NONE")') &
CTURBLEN_CLOUD
CTURBLEN_CLOUD='NONE'
END IF
IF( XCEI_MIN > XCEI_MAX ) THEN
WRITE(UNIT=ILUOUT,FMT=9003) KMI
WRITE(UNIT=ILUOUT,FMT='("PROBLEM OF CEI LIMITS FOR CLOUD MIXING ",/, & & "LENGTH COMPUTATION: XCEI_MIN=",E9.3,", XCEI_MAX=",E9.3)')&
XCEI_MIN,XCEI_MAX
!callabortstop
CALL PRINT_MSG(NVERB_FATAL,'GEN','READ_EXSEG_n','')
END IF
END IF
!
IF ( LSIGMAS ) THEN
WRITE(UNIT=ILUOUT,FMT=9001) KMI
WRITE(UNIT=ILUOUT,FMT='("YOU WANT TO USE SIGMA_S FROM TURBULENCE SCHEME",/, &
& " IN ICE SUBGRID CONDENSATION, SO YOUR SIGMA_S"/, &
& " MIGHT BE SMALL ABOVE PBL DEPENDING ON LENGTH SCALE")')
END IF
!
IF (LSUBG_COND .AND. CTURB=='NONE' ) THEN
WRITE(UNIT=ILUOUT,FMT=9002) KMI
WRITE(UNIT=ILUOUT,FMT=*) 'YOU WANT TO USE SUBGRID CONDENSATION'
WRITE(UNIT=ILUOUT,FMT=*) ' WITHOUT TURBULENCE '
WRITE(UNIT=ILUOUT,FMT=*) 'THIS IS NOT ALLOWED: LSUBG_COND is SET to FALSE'
LSUBG_COND=.FALSE.
END IF
!
IF (L1D .AND. CTURB/='NONE' .AND. CTURBDIM == '3DIM') THEN
WRITE(UNIT=ILUOUT,FMT=9002) KMI
WRITE(UNIT=ILUOUT,FMT=*) 'YOU WANT TO USE 3D TURBULENCE IN 1D CONFIGURATION '
WRITE(UNIT=ILUOUT,FMT=*) 'THIS IS NOT POSSIBLE: CTURBDIM IS SET TO 1DIM'
CTURBDIM = '1DIM'
END IF
!
!* 3.4 Additional scalar variables
!
IF (NSV_USER == KSV_USER) THEN
DO JS = 1,KSV_USER ! to read all the variables in initial file
CGETSVT(JS)='READ' ! and to initialize them
! IF(CCONF=='START')CGETSVT(JS)='INIT' ! with these values
END DO
ELSEIF (NSV_USER > KSV_USER) THEN
IF (KSV_USER == 0) THEN
CGETSVT(1:NSV_USER)='INIT'
ELSE
WRITE(UNIT=ILUOUT,FMT=9001) KMI
WRITE(UNIT=ILUOUT,FMT='("YOU WANT TO USE MORE ADDITIONAL SCALAR " ,&
&" VARIABLES THAN THERE ARE IN INITIAL FMFILE",/, &
& "THE SUPPLEMENTARY VARIABLES HAVE BEEN INITIALIZED TO ZERO ")')
DO JS = 1,KSV_USER ! to read all the variables in initial file
CGETSVT(JS)='READ' ! and to initialize them
! IF(CCONF=='START')CGETSVT(JS)='INIT' ! with these values
END DO
DO JS = KSV_USER+1, NSV_USER ! to initialize to zero supplementary
CGETSVT(JS)='INIT' ! initial file)
END DO
END IF
ELSE
WRITE(UNIT=ILUOUT,FMT=9000) KMI
WRITE(UNIT=ILUOUT,FMT='("YOU WANT TO USE LESS ADDITIONAL SCALAR " ,&
&" VARIABLES THAN THERE ARE IN INITIAL FMFILE")')
DO JS = 1,NSV_USER ! to read the first NSV_USER variables in initial file
CGETSVT(JS)='READ' ! and to initialize with these values
! IF(CCONF=='START') CGETSVT(JS)='INIT'
END DO
DO JS = NSV_USER + 1, KSV_USER ! to skip the last (KSV_USER-NSV_USER) variables
CGETSVT(JS)='SKIP'
END DO
END IF
!
! C2R2 and KHKO SV case
!
IF (CCLOUD == 'C2R2' .OR. CCLOUD == 'C3R5' .OR. CCLOUD == 'KHKO') THEN
IF (HCLOUD == 'C2R2' .OR. HCLOUD == 'C3R5' .OR. HCLOUD == 'KHKO') THEN
CGETSVT(NSV_C2R2BEG:NSV_C2R2END)='READ'! IF(CCONF=='START') CGETSVT(NSV_C2R2BEG:NSV_C2R2END)='INIT'
ELSE
WRITE(UNIT=ILUOUT,FMT=9001) KMI
WRITE(UNIT=ILUOUT,FMT='("THERE IS NO SCALAR VARIABLES FOR C2R2 &
& (or KHKO) SCHEME IN INITIAL FMFILE",/,&
& "THE C2R2 (or KHKO) VARIABLES HAVE BEEN INITIALIZED TO ZERO ")')
CGETSVT(NSV_C2R2BEG:NSV_C2R2END)='INIT'
END IF
END IF
!
! C3R5 SV case
!
IF (CCLOUD == 'C3R5') THEN
IF (HCLOUD == 'C3R5') THEN
CGETSVT(NSV_C1R3BEG:NSV_C1R3END)='READ'
! IF(CCONF=='START') CGETSVT(NSV_C1R3BEG:NSV_C1R3END)='INIT'
ELSE
WRITE(UNIT=ILUOUT,FMT=9001) KMI
WRITE(UNIT=ILUOUT,FMT='("THERE IS NO SCALAR VARIABLES FOR C3R5 &
&SCHEME IN INITIAL FMFILE",/,&
& "THE C1R3 VARIABLES HAVE BEEN INITIALIZED TO ZERO ")')
CGETSVT(NSV_C1R3BEG:NSV_C1R3END)='INIT'
END IF
END IF
!
! LIMA SV case
!
IF (CCLOUD == 'LIMA') THEN
IF (HCLOUD == 'LIMA') THEN
CGETSVT(NSV_LIMA_BEG:NSV_LIMA_END)='READ'
!!JPP IF(HSTORAGE_TYPE=='TT') CGETSVT(NSV_LIMA_BEG:NSV_LIMA_END)='INIT'
ELSE
WRITE(UNIT=ILUOUT,FMT=9001) KMI
WRITE(UNIT=ILUOUT,FMT='("THERE IS NO SCALAR VARIABLES FOR LIMA &
& SCHEME IN INITIAL FMFILE",/,&
& "THE LIMA VARIABLES HAVE BEEN INITIALIZED TO ZERO ")')
CGETSVT(NSV_LIMA_BEG:NSV_LIMA_END)='INIT'
END IF
END IF
!
! Electrical SV case
!
IF (CELEC /= 'NONE') THEN
IF (HELEC /= 'NONE') THEN
CGETSVT(NSV_ELECBEG:NSV_ELECEND)='READ'
! IF(CCONF=='START') CGETSVT(NSV_ELECBEG:NSV_ELECEND)='INIT'
ELSE
WRITE(UNIT=ILUOUT,FMT=9001) KMI
WRITE(UNIT=ILUOUT,FMT='("THERE IS NO SCALAR VARIABLES FOR ELECTRICAL &
&SCHEME IN INITIAL FMFILE",/,&
& "THE ELECTRICAL VARIABLES HAVE BEEN INITIALIZED TO ZERO ")')
CGETSVT(NSV_ELECBEG:NSV_ELECEND)='INIT'
END IF
END IF
!
! (explicit) LINOx SV case
!
IF (CELEC /= 'NONE' .AND. LLNOX_EXPLICIT) THEN
IF (HELEC /= 'NONE' .AND. OLNOX_EXPLICIT) THEN
CGETSVT(NSV_LNOXBEG:NSV_LNOXEND)='READ'
ELSE
WRITE(UNIT=ILUOUT,FMT=9001) KMI
WRITE(UNIT=ILUOUT,FMT='("THERE IS NO SCALAR VARIABLES FOR LINOX &
& IN INITIAL FMFILE",/,&
& "THE LINOX VARIABLES HAVE BEEN INITIALIZED TO ZERO ")')
CGETSVT(NSV_LNOXBEG:NSV_LNOXEND)='INIT'
END IF
END IF
!
! Chemical SV case (excluding aqueous chemical species)!
IF (LUSECHEM) THEN
IF (OUSECHEM) THEN
CGETSVT(NSV_CHGSBEG:NSV_CHGSEND)='READ'
IF(CCONF=='START' .AND. LCH_INIT_FIELD ) CGETSVT(NSV_CHGSBEG:NSV_CHGSEND)='INIT'
ELSE
WRITE(UNIT=ILUOUT,FMT=9001) KMI
WRITE(UNIT=ILUOUT,FMT='("THERE IS NO SCALAR VARIABLES FOR CHEMICAL &
&SCHEME IN INITIAL FMFILE",/,&
& "THE CHEMICAL VARIABLES HAVE BEEN INITIALIZED TO ZERO ")')
CGETSVT(NSV_CHGSBEG:NSV_CHGSEND)='INIT'
END IF
END IF
! add aqueous chemical species
IF (LUSECHAQ) THEN
IF (OUSECHAQ) THEN
CGETSVT(NSV_CHACBEG:NSV_CHACEND)='READ'
! IF(CCONF=='START') CGETSVT(NSV_CHACBEG:NSV_CHACEND)='INIT'
ELSE
WRITE(UNIT=ILUOUT,FMT=9001) KMI
WRITE(UNIT=ILUOUT,FMT='("THERE IS NO SCALAR VARIABLES FOR CHEMICAL &
&SCHEME IN AQUEOUS PHASE IN INITIAL FMFILE",/,&
& "THE AQUEOUS PHASE CHEMICAL VARIABLES HAVE BEEN INITIALIZED TO ZERO ")')
CGETSVT(NSV_CHACBEG:NSV_CHACEND)='INIT'
END IF
END IF
! add ice phase chemical species
IF (LUSECHIC) THEN
IF (OUSECHIC) THEN
CGETSVT(NSV_CHICBEG:NSV_CHICEND)='READ'
! IF(CCONF=='START') CGETSVT(NSV_CHICBEG:NSV_CHICEND)='INIT'
ELSE
WRITE(UNIT=ILUOUT,FMT=9001) KMI
WRITE(UNIT=ILUOUT,FMT='("THERE IS NO SCALAR VARIABLES FOR CHEMICAL &
&SPECIES IN ICE PHASE IN INITIAL FMFILE",/,&
& "THE ICE PHASE CHEMICAL VARIABLES HAVE BEEN INITIALIZED TO ZERO ")')
CGETSVT(NSV_CHICBEG:NSV_CHICEND)='INIT'
END IF
END IF
! pH values = diagnostics
IF (LCH_PH .AND. .NOT. OCH_PH) THEN
CGETPHC ='INIT' !will be initialized to XCH_PHINIT
IF (LUSERR) THEN
CGETPHR = 'INIT' !idem
ELSE
CGETPHR = 'SKIP'
ENDIF
ELSE
IF (LCH_PH) THEN
CGETPHC ='READ'
IF (LUSERR) THEN
CGETPHR = 'READ'
ELSE
CGETPHR = 'SKIP'
ENDIF
ELSE
CGETPHC ='SKIP'
CGETPHR ='SKIP'
END IF
END IF
!
! Dust case
!
IF (LDUST) THEN
IF (ODUST) THEN
CGETSVT(NSV_DSTBEG:NSV_DSTEND)='READ'
! IF(CCONF=='START') CGETSVT(NSV_DSTBEG:NSV_DSTEND)='INIT'
ELSE
WRITE(UNIT=ILUOUT,FMT=9001) KMI
WRITE(UNIT=ILUOUT,FMT='("THERE IS NO SCALAR VARIABLES FOR DUST & &SCHEME IN INITIAL FMFILE",/,&
& "THE DUST VARIABLES HAVE BEEN INITIALIZED TO ZERO ")')
CGETSVT(NSV_DSTBEG:NSV_DSTEND)='INIT'
END IF
IF (LDEPOS_DST(KMI)) THEN
IF((CCLOUD /= 'ICE3').AND.(CCLOUD /= 'ICE4').AND.(CCLOUD /= 'KESS')&
.AND.(CCLOUD /= 'KHKO').AND.(CCLOUD /= 'C2R2').AND. &
(CPROGRAM/='SPAWN').AND.(CPROGRAM/='REAL')) THEN
WRITE(UNIT=ILUOUT,FMT=9003) KMI
WRITE(UNIT=ILUOUT,FMT='("ERROR: WET DEPOSITION OF DUST IS ONLY CODED FOR THE",/,&
& "MICROPHYSICAL SCHEME as ICE3, ICE4, KESS, KHKO and C2R2")')
!callabortstop
CALL PRINT_MSG(NVERB_FATAL,'GEN','READ_EXSEG_n','')
END IF
IF (ODEPOS_DST(KMI) ) THEN
CGETSVT(NSV_DSTDEPBEG:NSV_DSTDEPEND)='READ'
! IF(CCONF=='START') CGETSVT(NSV_DSTDEPBEG:NSV_DSTDEPEND)='INIT'
ELSE
WRITE(UNIT=ILUOUT,FMT=9001) KMI
WRITE(UNIT=ILUOUT,FMT='("THERE IS NO SCALAR VARIABLES FOR RAIN and CLOUD DUST &
& SCHEME IN INITIAL FMFILE",/,&
& "THE MOIST DUST VARIABLES HAVE BEEN INITIALIZED TO ZERO ")')
CGETSVT(NSV_DSTDEPBEG:NSV_DSTDEPEND)='INIT'
END IF
END IF
IF(NMODE_DST.GT.3 .OR. NMODE_DST.LT.1) THEN
WRITE(UNIT=ILUOUT,FMT=9003) KMI
WRITE(UNIT=ILUOUT,FMT='("DUST MODES MUST BE BETWEEN 1 and 3 ")')
!callabortstop
CALL PRINT_MSG(NVERB_FATAL,'GEN','READ_EXSEG_n','')
END IF
IF(.NOT.ALLOCATED(CDUSTNAMES)) THEN
IMOMENTS = (NSV_DSTEND - NSV_DSTBEG +1 )/NMODE_DST
ALLOCATE(CDUSTNAMES(IMOMENTS*NMODE_DST))
!Loop on all dust modes
IF (IMOMENTS == 1) THEN
DO JMODE=1,NMODE_DST
IMODEIDX=JPDUSTORDER(JMODE)
JSV_NAME = (IMODEIDX - 1)*3 + 2
CDUSTNAMES(JMODE) = YPDUST_INI(JSV_NAME)
END DO
ELSE
DO JMODE=1,NMODE_DST
!Find which mode we are dealing with
IMODEIDX=JPDUSTORDER(JMODE)
DO JMOM=1,IMOMENTS
!Find which number this is of the list of scalars
JSV = (JMODE-1)*IMOMENTS + JMOM
!Find what name this corresponds to, always 3 moments assumed in YPDUST_INI
JSV_NAME = (IMODEIDX - 1)*3 + JMOM
!Get the right CDUSTNAMES which should follow the list of scalars transported in XSVM/XSVT
CDUSTNAMES(JSV) = YPDUST_INI(JSV_NAME)
ENDDO ! Loop on moments
ENDDO ! Loop on dust modes
END IF
END IF
! Initialization of deposition scheme
IF (LDEPOS_DST(KMI)) THEN
IF(.NOT.ALLOCATED(CDEDSTNAMES)) THEN
ALLOCATE(CDEDSTNAMES(NMODE_DST*2))
DO JMODE=1,NMODE_DST
IMODEIDX=JPDUSTORDER(JMODE)
CDEDSTNAMES(JMODE) = YPDEDST_INI(IMODEIDX)
CDEDSTNAMES(NMODE_DST+JMODE) = YPDEDST_INI(NMODE_DST+IMODEIDX)
ENDDO
ENDIF
ENDIF
END IF
!
! Sea Salt case
!
IF (LSALT) THEN
IF (OSALT) THEN
CGETSVT(NSV_SLTBEG:NSV_SLTEND)='READ'
! IF(CCONF=='START') CGETSVT(NSV_SLTBEG:NSV_SLTEND)='INIT'
ELSE
WRITE(UNIT=ILUOUT,FMT=9001) KMI
WRITE(UNIT=ILUOUT,FMT='("THERE IS NO SCALAR VARIABLES FOR SALT &
&SCHEME IN INITIAL FMFILE",/,&
& "THE SALT VARIABLES HAVE BEEN INITIALIZED TO ZERO ")')
CGETSVT(NSV_SLTBEG:NSV_SLTEND)='INIT'
END IF
IF (LDEPOS_SLT(KMI)) THEN
IF((CCLOUD /= 'ICE3').AND.(CCLOUD /= 'ICE4').AND.(CCLOUD /= 'KESS')&
.AND.(CCLOUD /= 'KHKO').AND.(CCLOUD /= 'C2R2').AND. &
(CPROGRAM/='SPAWN').AND.(CPROGRAM/='REAL')) THEN
WRITE(UNIT=ILUOUT,FMT=9003) KMI
WRITE(UNIT=ILUOUT,FMT='("ERROR: WET DEPOSITION OF SEA SALT AEROSOLS IS ONLY CODED FOR THE",/,&
& "MICROPHYSICAL SCHEME as ICE3, ICE4, KESS, KHKO and C2R2")')
!callabortstop
CALL PRINT_MSG(NVERB_FATAL,'GEN','READ_EXSEG_n','')
END IF
IF (ODEPOS_SLT(KMI) ) THEN
CGETSVT(NSV_SLTDEPBEG:NSV_SLTDEPEND)='READ'
! IF(CCONF=='START') CGETSVT(NSV_SLTDEPBEG:NSV_SLTDEPEND)='INIT'
ELSE
WRITE(UNIT=ILUOUT,FMT=9001) KMI
WRITE(UNIT=ILUOUT,FMT='("THERE IS NO SCALAR VARIABLES FOR RAIN and CLOUD SEA SALT &
& SCHEME IN INITIAL FMFILE",/,&
& "THE MOIST SEA SALT VARIABLES HAVE BEEN INITIALIZED TO ZERO ")')
CGETSVT(NSV_SLTDEPBEG:NSV_SLTDEPEND)='INIT'
END IF
END IF
IF(NMODE_SLT.GT.3 .OR. NMODE_SLT.LT.1) THEN
WRITE(UNIT=ILUOUT,FMT=9003) KMI
WRITE(UNIT=ILUOUT,FMT='("SALT MODES MUST BE BETWEEN 1 and 3 ")')
!callabortstop
CALL PRINT_MSG(NVERB_FATAL,'GEN','READ_EXSEG_n','')
END IF
IF(.NOT.ALLOCATED(CSALTNAMES)) THEN
IMOMENTS = (NSV_SLTEND - NSV_SLTBEG +1 )/NMODE_SLT
ALLOCATE(CSALTNAMES(IMOMENTS*NMODE_SLT))
!Loop on all dust modes
IF (IMOMENTS == 1) THEN
DO JMODE=1,NMODE_SLT
IMODEIDX=JPSALTORDER(JMODE)
JSV_NAME = (IMODEIDX - 1)*3 + 2
CSALTNAMES(JMODE) = YPSALT_INI(JSV_NAME)
END DO
ELSE
DO JMODE=1,NMODE_SLT
!Find which mode we are dealing with
IMODEIDX=JPSALTORDER(JMODE)
DO JMOM=1,IMOMENTS
!Find which number this is of the list of scalars
JSV = (JMODE-1)*IMOMENTS + JMOM
!Find what name this corresponds to, always 3 moments assumed in YPSALT_INI
JSV_NAME = (IMODEIDX - 1)*3 + JMOM
!Get the right CSALTNAMES which should follow the list of scalars transported in XSVM/XSVT
CSALTNAMES(JSV) = YPSALT_INI(JSV_NAME)
ENDDO ! Loop on moments
ENDDO ! Loop on dust modes
END IF
END IF ! Initialization of deposition scheme
IF (LDEPOS_SLT(KMI)) THEN
IF(.NOT.ALLOCATED(CDESLTNAMES)) THEN
ALLOCATE(CDESLTNAMES(NMODE_SLT*2))
DO JMODE=1,NMODE_SLT
IMODEIDX=JPDUSTORDER(JMODE)
CDESLTNAMES(JMODE) = YPDESLT_INI(IMODEIDX)
CDESLTNAMES(NMODE_SLT+JMODE) = YPDESLT_INI(NMODE_SLT+IMODEIDX)
ENDDO
ENDIF
ENDIF
END IF
!
! Orilam SV case
!
IF (LORILAM) THEN
IF (OORILAM) THEN
CGETSVT(NSV_AERBEG:NSV_AEREND)='READ'
! IF(CCONF=='START') CGETSVT(NSV_AERBEG:NSV_AEREND)='INIT'
ELSE
WRITE(UNIT=ILUOUT,FMT=9001) KMI
WRITE(UNIT=ILUOUT,FMT='("THERE IS NO SCALAR VARIABLES FOR AEROSOL &
&SCHEME IN INITIAL FMFILE",/,&
& "THE AEROSOLS VARIABLES HAVE BEEN INITIALIZED TO ZERO ")')
CGETSVT(NSV_AERBEG:NSV_AEREND)='INIT'
END IF
IF (LDEPOS_AER(KMI)) THEN
IF((CCLOUD /= 'ICE3').AND.(CCLOUD /= 'ICE4').AND.(CCLOUD /= 'KESS')&
.AND.(CCLOUD /= 'KHKO').AND.(CCLOUD /= 'C2R2').AND. &
(CPROGRAM/='SPAWN').AND.(CPROGRAM/='REAL')) THEN
WRITE(UNIT=ILUOUT,FMT=9003) KMI
WRITE(UNIT=ILUOUT,FMT='("ERROR: WET DEPOSITION OF ORILAM AEROSOLS IS ONLY CODED FOR THE",/,&
& "MICROPHYSICAL SCHEME as ICE3, ICE4, KESS, KHKO and C2R2")')
!callabortstop
CALL PRINT_MSG(NVERB_FATAL,'GEN','READ_EXSEG_n','')
END IF
IF (ODEPOS_AER(KMI) ) THEN
CGETSVT(NSV_AERDEPBEG:NSV_AERDEPEND)='READ'
! IF(CCONF=='START') CGETSVT(NSV_AERDEPBEG:NSV_AERDEPEND)='INIT'
ELSE
WRITE(UNIT=ILUOUT,FMT=9001) KMI
WRITE(UNIT=ILUOUT,FMT='("THERE IS NO SCALAR VARIABLES FOR RAIN and IN CLOUD &
& AEROSOL SCHEME IN INITIAL FMFILE",/,&
& "THE MOIST AEROSOL VARIABLES HAVE BEEN INITIALIZED TO ZERO ")')
CGETSVT(NSV_AERDEPBEG:NSV_AERDEPEND)='INIT'
END IF
END IF
! Initialization of deposition scheme
IF (LDEPOS_AER(KMI)) THEN
IF(.NOT.ALLOCATED(CDEAERNAMES)) THEN
ALLOCATE(CDEAERNAMES(JPMODE*2))
CDEAERNAMES(:) = YPDEAER_INI(:)
ENDIF
ENDIF
END IF
!
! Lagrangian variables
!
IF (LINIT_LG .AND. .NOT.(LLG)) THEN
WRITE(UNIT=ILUOUT,FMT=9001) KMI
WRITE(UNIT=ILUOUT,FMT='("IT IS INCOHERENT TO HAVE LINIT_LG=.T. AND LLG=.F.",/,&
& "IF YOU WANT LAGRANGIAN TRACERS CHANGE LLG TO .T. ")')
ENDIF
IF (LLG) THEN
IF (OLG .AND. .NOT.(LINIT_LG .AND. CPROGRAM=='MESONH')) THEN
CGETSVT(NSV_LGBEG:NSV_LGEND)='READ'
! IF(CCONF=='START') CGETSVT(NSV_LGBEG:NSV_LGEND)='INIT'
ELSE IF(.NOT.(LINIT_LG) .AND. CPROGRAM=='MESONH') THEN
WRITE(UNIT=ILUOUT,FMT=9001) KMI
WRITE(UNIT=ILUOUT,FMT='("THERE IS NO LAGRANGIAN VARIABLES IN INITIAL FMFILE",/,&
& "THE LAGRANGIAN VARIABLES HAVE BEEN REINITIALIZED")')
LINIT_LG=.TRUE.
ENDIF
CGETSVT(NSV_LGBEG:NSV_LGEND)='INIT'
END IF
END IF
!
!
! LINOx SV case
!
IF (.NOT.LUSECHEM .AND. LCH_CONV_LINOX) THEN
IF (.NOT.OUSECHEM .AND. OCH_CONV_LINOX) THEN
CGETSVT(NSV_LNOXBEG:NSV_LNOXEND)='READ'
ELSE
WRITE(UNIT=ILUOUT,FMT=9002) KMI
WRITE(UNIT=ILUOUT,FMT='("THERE IS NO SCALAR VARIABLES FOR LINOX &
&IN INITIAL FMFILE",/,&
& "THE LINOX VARIABLES HAVE BEEN INITIALIZED TO ZERO ")')
CGETSVT(NSV_LNOXBEG:NSV_LNOXEND)='INIT'
END IF
END IF
!
! Passive pollutant case
!
IF (LPASPOL) THEN
IF (OPASPOL) THEN
CGETSVT(NSV_PPBEG:NSV_PPEND)='READ'
! IF(CCONF=='START') CGETSVT(NSV_PPBEG:NSV_PPEND)='INIT'
ELSE
WRITE(UNIT=ILUOUT,FMT=9001) KMI
WRITE(UNIT=ILUOUT,FMT='("THERE IS NO PASSIVE SCALAR VARIABLES IN INITIAL FMFILE",/,&
& "THE VARIABLES HAVE BEEN INITIALIZED TO ZERO")')
CGETSVT(NSV_PPBEG:NSV_PPEND)='INIT'
END IF
END IF
!
#ifdef MNH_FOREFIRE
! ForeFire
!
IF (LFOREFIRE) THEN
IF (OFOREFIRE) THEN
CGETSVT(NSV_FFBEG:NSV_FFEND)='READ'
IF(HSTORAGE_TYPE=='TT') THEN
CGETSVT(NSV_FFBEG:NSV_FFEND)='INIT'
END IF
ELSE
WRITE(UNIT=ILUOUT,FMT=9001) KMI
WRITE(UNIT=ILUOUT,FMT='("THERE IS NO FOREFIRE SCALAR VARIABLES IN INITIAL FMFILE",/,&
& "THE VARIABLES HAVE BEEN INITIALIZED TO ZERO")')
CGETSVT(NSV_FFBEG:NSV_FFEND)='INIT'
END IF
END IF
#endif
!
! Conditional sampling case
!
IF (LCONDSAMP) THEN
IF (OCONDSAMP) THEN
CGETSVT(NSV_CSBEG:NSV_CSEND)='READ'
! IF(CCONF=='START') CGETSVT(NSV_CSBEG:NSV_CSEND)='INIT'
ELSE
WRITE(UNIT=ILUOUT,FMT=9001) KMI
WRITE(UNIT=ILUOUT,FMT='("THERE IS NO PASSIVE SCALAR VARIABLES IN INITIAL FMFILE",/,&
& "THE VARIABLES HAVE BEEN INITIALIZED TO ZERO")')
CGETSVT(NSV_CSBEG:NSV_CSEND)='INIT'
END IF
END IF!
!
!* 3.5 Check coherence between the radiation control parameters
!
IF( CRAD == 'ECMW' .AND. CPROGRAM=='MESONH' ) THEN
IF(CLW == 'RRTM' .AND. COPILW == 'SMSH') THEN
WRITE(UNIT=ILUOUT,FMT=9003) KMI
WRITE(UNIT=ILUOUT,FMT=*) 'the SMSH parametrisation of LW optical properties for cloud ice'
WRITE(UNIT=ILUOUT,FMT=*) '(COPILW) can not be used with RRTM radiation scheme'
!callabortstop
CALL PRINT_MSG(NVERB_FATAL,'GEN','READ_EXSEG_n','')
ENDIF
IF(CLW == 'MORC' .AND. COPWLW == 'LILI') THEN
WRITE(UNIT=ILUOUT,FMT=9003) KMI
WRITE(UNIT=ILUOUT,FMT=*) 'the LILI parametrisation of LW optical properties for cloud water'
WRITE(UNIT=ILUOUT,FMT=*) '(COPWLW) can not be used with MORC radiation scheme'
!callabortstop
CALL PRINT_MSG(NVERB_FATAL,'GEN','READ_EXSEG_n','')
ENDIF
IF( .NOT. LSUBG_COND) THEN
WRITE(UNIT=ILUOUT,FMT=9000) KMI
WRITE(UNIT=ILUOUT,FMT=*) 'YOU DO NOT WANT TO USE SUBGRID CONDENSATION'
WRITE(UNIT=ILUOUT,FMT=*) 'THE OVERLAP OPTION IS NOVLP=5 IN ini_radconf.f90'
ELSE IF (CLW == 'MORC') THEN
WRITE(UNIT=ILUOUT,FMT=9000) KMI
WRITE(UNIT=ILUOUT,FMT=*) 'YOU WANT TO USE MORCRETTE LW SCHEME'
WRITE(UNIT=ILUOUT,FMT=*) 'THE OVERLAP OPTION IS NOVLP=5 IN ini_radconf.f90'
ELSE
WRITE(UNIT=ILUOUT,FMT=9000) KMI
WRITE(UNIT=ILUOUT,FMT=*) 'THE OVERLAP OPTION IS NOVLP=6 IN ini_radconf.f90'
ENDIF
!
IF( LCLEAR_SKY .AND. XDTRAD_CLONLY /= XDTRAD) THEN
! Check the validity of the LCLEAR_SKY approximation
WRITE(UNIT=ILUOUT,FMT=9003) KMI
WRITE(UNIT=ILUOUT,FMT=*) 'YOU WANT TO USE BOTH THE CLEAR-SKY APPROXIMATION'
WRITE(UNIT=ILUOUT,FMT=*) '(i.e. AVERAGE THE WHOLE CLOUDFREE VERTICALS BUT KEEP'
WRITE(UNIT=ILUOUT,FMT=*) 'ALL THE CLOUDY VERTICALS) AND'
WRITE(UNIT=ILUOUT,FMT=*) 'THE CLOUD-ONLY APPROXIMATION (i.e. YOU CALL MORE OFTEN THE'
WRITE(UNIT=ILUOUT,FMT=*) 'RADIATIONS FOR THE CLOUDY VERTICALS THAN FOR CLOUDFREE ONES).'
WRITE(UNIT=ILUOUT,FMT=*) 'THIS IS NOT POSSIBLE, SO CHOOSE BETWEEN :'
WRITE(UNIT=ILUOUT,FMT=*) 'XDTRAD_CLONLY = XDTRAD and LCLEAR_SKY = FALSE'
!
!callabortstop
CALL PRINT_MSG(NVERB_FATAL,'GEN','READ_EXSEG_n','')
END IF
!
IF( XDTRAD_CLONLY > XDTRAD ) THEN
WRITE(UNIT=ILUOUT,FMT=9003) KMI
WRITE(UNIT=ILUOUT,FMT='("BAD USE OF THE CLOUD-ONLY APPROXIMATION " ,&
&" XDTRAD SHOULD BE LARGER THAN XDTRAD_CLONLY ")')
!
!callabortstop
CALL PRINT_MSG(NVERB_FATAL,'GEN','READ_EXSEG_n','')
END IF
!
IF(( XDTRAD < XTSTEP ).OR. ( XDTRAD_CLONLY < XTSTEP )) THEN
WRITE(UNIT=ILUOUT,FMT=9003) KMI
WRITE(UNIT=ILUOUT,FMT='("THE RADIATION CALL XDTRAD OR XDTRAD_CLONLY " ,&
&" IS MORE FREQUENT THAN THE TIME STEP SO ADJUST XDTRAD OR XDTRAD_CLONLY ")')
!
!callabortstop
CALL PRINT_MSG(NVERB_FATAL,'GEN','READ_EXSEG_n','')
END IF
END IF
!
IF ( CRAD /= 'NONE' .AND. CPROGRAM=='MESONH' ) THEN
CGETRAD='READ'
IF( HRAD == 'NONE' .AND. CCONF=='RESTA') THEN
WRITE(UNIT=ILUOUT,FMT=9001) KMI WRITE(UNIT=ILUOUT,FMT=*) 'YOU ARE PERFORMING A RESTART. FOR THIS SEGMENT, YOU ARE USING A RADIATION'
WRITE(UNIT=ILUOUT,FMT=*) 'SCHEME AND NO RADIATION SCHEME WAS USED FOR THE PREVIOUS SEGMENT.'
CGETRAD='INIT'
END IF
IF(CCONF=='START') THEN
CGETRAD='INIT'
END IF
END IF
!
! 3.6 check the initialization of the deep convection scheme
!
IF ( (CDCONV /= 'KAFR') .AND. &
(CSCONV /= 'KAFR') .AND. LCHTRANS ) THEN
WRITE(UNIT=ILUOUT,FMT=9003) KMI
WRITE(UNIT=ILUOUT,FMT='("YOU WANT TO USE THE LCHTRANS OPTION= ",&
&"CONVECTIVE TRANSPORT OF TRACERS BUT IT CAN ONLY",&
&"BE USED FOR THE KAIN FRITSCH SCHEME ")')
!callabortstop
CALL PRINT_MSG(NVERB_FATAL,'GEN','READ_EXSEG_n','')
END IF
!
SELECT CASE ( CDCONV )
CASE( 'KAFR' )
IF (.NOT. ( LUSERV ) ) THEN
WRITE(UNIT=ILUOUT,FMT=9002) KMI
WRITE(UNIT=ILUOUT,FMT='("YOU WANT TO USE THE KAIN-FRITSCH DEEP CONV. ",&
&" SCHEME. YOU MUST HAVE VAPOR ",/,"LUSERV IS SET TO TRUE ")')
LUSERV=.TRUE.
ELSE IF (.NOT. ( LUSERI ) ) THEN
WRITE(UNIT=ILUOUT,FMT=9002) KMI
WRITE(UNIT=ILUOUT,FMT='("YOU WANT TO USE THE KAIN-FRITSCH",&
&" DEEP CONV. SCHEME. BUT THE DETRAINED CLOUD ICE WILL BE ADDED TO ",&
&" THE CLOUD WATER ")')
ELSE IF (.NOT. ( LUSERI.AND.LUSERC ) ) THEN
WRITE(UNIT=ILUOUT,FMT=9002) KMI
WRITE(UNIT=ILUOUT,FMT='("YOU WANT TO USE THE KAIN-FRITSCH",&
&" DEEP CONV. SCHEME. BUT THE DETRAINED CLOUD WATER AND CLOUD ICE ",&
&" WILL BE ADDED TO THE WATER VAPOR FIELD ")')
END IF
IF ( LCHTRANS .AND. NSV == 0 ) THEN
WRITE(UNIT=ILUOUT,FMT=9002) KMI
WRITE(UNIT=ILUOUT,FMT='("YOU WANT TO USE THE LCHTRANS OPTION= ",&
&"CONVECTIVE TRANSPORT OF TRACERS BUT YOUR TRACER ",&
&"NUMBER NSV IS ZERO ",/,"LCHTRANS IS SET TO FALSE")')
LCHTRANS=.FALSE.
END IF
END SELECT
!
IF ( CDCONV == 'KAFR' .AND. LCHTRANS .AND. NSV > 0 ) THEN
IF( OCHTRANS ) THEN
CGETSVCONV='READ'
ELSE
CGETSVCONV='INIT'
END IF
END IF
!
SELECT CASE ( CSCONV )
CASE( 'KAFR' )
IF (.NOT. ( LUSERV ) ) THEN
WRITE(UNIT=ILUOUT,FMT=9002) KMI
WRITE(UNIT=ILUOUT,FMT='("YOU WANT TO USE THE KAIN-FRITSCH SHALLOW CONV. ",&
&" SCHEME. YOU MUST HAVE VAPOR ",/,"LUSERV IS SET TO TRUE ")')
LUSERV=.TRUE.
ELSE IF (.NOT. ( LUSERI ) ) THEN
WRITE(UNIT=ILUOUT,FMT=9002) KMI
WRITE(UNIT=ILUOUT,FMT='("YOU WANT TO USE THE KAIN-FRITSCH",&
&" SHALLOW CONV. SCHEME. BUT THE DETRAINED CLOUD ICE WILL BE ADDED TO ",&
&" THE CLOUD WATER ")')
ELSE IF (.NOT. ( LUSERI.AND.LUSERC ) ) THEN
WRITE(UNIT=ILUOUT,FMT=9002) KMI WRITE(UNIT=ILUOUT,FMT='("YOU WANT TO USE THE KAIN-FRITSCH",&
&" SHALLOW CONV. SCHEME. BUT THE DETRAINED CLOUD WATER AND CLOUD ICE ",&
&" WILL BE ADDED TO THE WATER VAPOR FIELD ")')
END IF
IF ( LCHTRANS .AND. NSV == 0 ) THEN
WRITE(UNIT=ILUOUT,FMT=9002) KMI
WRITE(UNIT=ILUOUT,FMT='("YOU WANT TO USE THE LCHTRANS OPTION= ",&
&"CONVECTIVE TRANSPORT OF TRACERS BUT YOUR TRACER ",&
&"NUMBER NSV IS ZERO ",/,"LCHTRANS IS SET TO FALSE")')
LCHTRANS=.FALSE.
END IF
CASE( 'EDKF' )
IF (CTURB == 'NONE' ) THEN
WRITE(UNIT=ILUOUT,FMT=9003) KMI
WRITE(UNIT=ILUOUT,FMT='("YOU WANT TO USE THE EDKF ", &
&"SHALLOW CONVECTION WITHOUT TURBULENCE SCHEME : ", &
&"IT IS NOT POSSIBLE")')
!
!callabortstop
CALL PRINT_MSG(NVERB_FATAL,'GEN','READ_EXSEG_n','')
END IF
END SELECT
!
!
CGETCONV = 'SKIP'
!
IF ( (CDCONV /= 'NONE' .OR. CSCONV == 'KAFR' ) .AND. CPROGRAM=='MESONH') THEN
CGETCONV = 'READ'
IF( HDCONV == 'NONE' .AND. CCONF=='RESTA') THEN
WRITE(UNIT=ILUOUT,FMT=9001) KMI
WRITE(UNIT=ILUOUT,FMT='(" YOU ARE PERFORMING A RESTART. FOR THIS ",&
&" SEGMENT, YOU ARE USING A DEEP CONVECTION SCHEME AND NO DEEP ",&
&" CONVECTION SCHEME WAS USED FOR THE PREVIOUS SEGMENT. ")')
!
CGETCONV = 'INIT'
END IF
IF(CCONF=='START') THEN
CGETCONV = 'INIT'
END IF
END IF
!
!* 3.7 configuration and model version
!
IF (KMI == 1) THEN
!
IF (L1D.AND.(CLBCX(1)/='CYCL'.AND.CLBCX(2)/='CYCL' &
.AND.CLBCY(1)/='CYCL'.AND.CLBCY(2)/='CYCL')) THEN
WRITE(UNIT=ILUOUT,FMT=9003) KMI
WRITE(UNIT=ILUOUT,FMT='("YOU WANT TO USE A 1D MODEL VERSION WITH NON-CYCL",&
& "CLBCX OR CLBCY VALUES")')
!callabortstop
CALL PRINT_MSG(NVERB_FATAL,'GEN','READ_EXSEG_n','')
END IF
IF (L2D.AND.(CLBCY(1)/='CYCL'.AND.CLBCY(2)/='CYCL')) THEN
WRITE(UNIT=ILUOUT,FMT=9003) KMI
WRITE(UNIT=ILUOUT,FMT='("YOU WANT TO USE A 2D MODEL VERSION WITH NON-CYCL",&
& " CLBCY VALUES")')
!callabortstop
CALL PRINT_MSG(NVERB_FATAL,'GEN','READ_EXSEG_n','')
END IF
!
IF ( (.NOT. LCARTESIAN) .AND. ( LCORIO) .AND. (.NOT. LGEOST_UV_FRC) ) THEN
WRITE(UNIT=ILUOUT,FMT=9002) KMI
WRITE(UNIT=ILUOUT,FMT='("BE CAREFUL YOU COULD HAVE SPURIOUS MOTIONS " ,&
& " NEAR THE LBC AS LCORIO=T and LGEOST_UV_FRC=F")')
END IF
!
IF ((.NOT.LFLAT).AND.OFLAT) THEN
WRITE(UNIT=ILUOUT,FMT=9002) KMI
WRITE(UNIT=ILUOUT,FMT=*) 'ZERO OROGRAPHY IN INITIAL FILE' WRITE(UNIT=ILUOUT,FMT=*) '***** ALL TERMS HAVE BEEN NEVERTHELESS COMPUTED WITHOUT SIMPLIFICATION*****'
WRITE(UNIT=ILUOUT,FMT=*) 'THIS SHOULD LEAD TO ERRORS IN THE PRESSURE COMPUTATION'
END IF
IF (LFLAT.AND.(.NOT.OFLAT)) THEN
WRITE(UNIT=ILUOUT,FMT=9002) KMI
WRITE(UNIT=ILUOUT,FMT='(" OROGRAPHY IS NOT EQUAL TO ZERO ", &
& "IN INITIAL FILE" ,/, &
& "******* OROGRAPHY HAS BEEN SET TO ZERO *********",/, &
& "ACCORDING TO ZERO OROGRAPHY, SIMPLIFICATIONS HAVE ", &
& "BEEN MADE IN COMPUTATIONS")')
END IF
END IF
!
!* 3.8 System of equations
!
IF ( HEQNSYS /= CEQNSYS ) THEN
WRITE(UNIT=ILUOUT,FMT=9003) KMI
WRITE(ILUOUT,FMT=*) 'YOU HAVE CHANGED THE SYSTEM OF EQUATIONS'
WRITE(ILUOUT,FMT=*) 'THE ANELASTIC CONSTRAINT IS PERHAPS CHANGED :'
WRITE(ILUOUT,FMT=*) 'FOR THE INITIAL FILE YOU HAVE USED ',HEQNSYS
WRITE(ILUOUT,FMT=*) 'FOR THE RUN YOU PLAN TO USE ',CEQNSYS
WRITE(ILUOUT,FMT=*) 'THIS CAN LEAD TO A NUMERICAL EXPLOSION IN THE FIRST TIME STEPS'
!callabortstop
CALL PRINT_MSG(NVERB_FATAL,'GEN','READ_EXSEG_n','')
END IF
!
! 3.9 Numerical schemes
!
IF ( (CUVW_ADV_SCHEME == 'CEN4TH') .AND. &
(CTEMP_SCHEME /= 'LEFR') .AND. (CTEMP_SCHEME /= 'RKC4') ) THEN
WRITE(UNIT=ILUOUT,FMT=9003) KMI
WRITE(UNIT=ILUOUT,FMT='("CEN4TH SCHEME HAS TO BE USED WITH ",&
&"CTEMP_SCHEME = LEFR of RKC4 ONLY")')
!callabortstop
CALL PRINT_MSG(NVERB_FATAL,'GEN','READ_EXSEG_n','')
END IF
!
IF ( (CUVW_ADV_SCHEME == 'WENO_K') .AND. LNUMDIFU ) THEN
WRITE(UNIT=ILUOUT,FMT=9002) KMI
WRITE(UNIT=ILUOUT,FMT='("YOU WANT TO USE NUMERICAL DIFFUSION ",&
&"WITH WENO SCHEME ALREADY DIFFUSIVE")')
END IF
!-------------------------------------------------------------------------------
!
!* 4. CHECK COHERENCE BETWEEN EXSEG VARIABLES
! ---------------------------------------
!
!* 4.1 coherence between coupling variables in EXSEG file
!
IF (KMI == 1) THEN
NCPL_NBR = 0
DO JCI = 1,JPCPLFILEMAX
IF (LEN_TRIM(CCPLFILE(JCI)) /= 0) THEN ! Finds the number
NCPL_NBR = NCPL_NBR + 1 ! of coupling files
ENDIF
IF (JCI/=JPCPLFILEMAX) THEN ! Deplaces the coupling files
IF ((LEN_TRIM(CCPLFILE(JCI)) == 0) .AND. &! names if one missing
(LEN_TRIM(CCPLFILE(JCI+1)) /= 0)) THEN
DO JI=JCI,JPCPLFILEMAX-1
CCPLFILE(JI)=CCPLFILE(JI+1)
END DO
CCPLFILE(JPCPLFILEMAX)=' '
END IF
END IF
END DO
!
IF (NCPL_NBR /= 0) THEN
LSTEADYLS = .FALSE.
ELSE
LSTEADYLS = .TRUE. ENDIF
END IF
!
!* 4.3 check consistency in forcing switches
!
IF ( LFORCING ) THEN
IF ( LRELAX_THRV_FRC .AND. ( LTEND_THRV_FRC .OR. LGEOST_TH_FRC ) ) THEN
WRITE(UNIT=ILUOUT,FMT=9002) KMI
WRITE(ILUOUT,FMT=*) 'YOU CHOSE A TEMPERATURE AND HUMIDITY RELAXATION'
WRITE(ILUOUT,FMT=*) 'TOGETHER WITH TENDENCY OR GEOSTROPHIC FORCING'
WRITE(ILUOUT,FMT=*) &
'YOU MIGHT CHECK YOUR SWITCHES: LRELAX_THRV_FRC, LTEND_THRV_FRC, AND'
WRITE(ILUOUT,FMT=*) 'LGEOST_TH_FRC'
END IF
!
IF ( LRELAX_UV_FRC .AND. LGEOST_UV_FRC ) THEN
WRITE(UNIT=ILUOUT,FMT=9003) KMI
WRITE(ILUOUT,FMT=*) 'YOU MUST NOT USE A WIND RELAXATION'
WRITE(ILUOUT,FMT=*) 'TOGETHER WITH A GEOSTROPHIC FORCING'
WRITE(ILUOUT,FMT=*) 'CHECK SWITCHES: LRELAX_UV_FRC, LGEOST_UV_FRC'
!callabortstop
CALL PRINT_MSG(NVERB_FATAL,'GEN','READ_EXSEG_n','')
END IF
!
IF ( CRELAX_HEIGHT_TYPE.NE."FIXE" .AND. CRELAX_HEIGHT_TYPE.NE."THGR" ) THEN
WRITE(UNIT=ILUOUT,FMT=9003) KMI
WRITE(ILUOUT,FMT=*) 'CRELAX_HEIGHT_TYPE MUST BE EITHER "FIXE" OR "THGR"'
WRITE(ILUOUT,FMT=*) 'BUT IT IS "', CRELAX_HEIGHT_TYPE, '"'
!callabortstop
CALL PRINT_MSG(NVERB_FATAL,'GEN','READ_EXSEG_n','')
END IF
!
IF ( .NOT.LCORIO .AND. LGEOST_UV_FRC ) THEN
WRITE(UNIT=ILUOUT,FMT=9003) KMI
WRITE(ILUOUT,FMT=*) 'YOU CANNOT HAVE A GEOSTROPHIC FORCING WITHOUT'
WRITE(ILUOUT,FMT=*) 'ACTIVATING LCORIOLIS OPTION'
!callabortstop
CALL PRINT_MSG(NVERB_FATAL,'GEN','READ_EXSEG_n','')
END IF
!
IF ( LPGROUND_FRC ) THEN
WRITE(ILUOUT,FMT=*) 'SURFACE PRESSURE FORCING NOT YET IMPLEMENTED'
!callabortstop
CALL PRINT_MSG(NVERB_FATAL,'GEN','READ_EXSEG_n','')
END IF
!
END IF
!
IF (LTRANS .AND. .NOT. LFLAT ) THEN
WRITE(UNIT=ILUOUT,FMT=9003) KMI
WRITE(ILUOUT,FMT=*) 'YOU ASK FOR A CONSTANT SPEED DOMAIN TRANSLATION '
WRITE(ILUOUT,FMT=*) 'BUT NOT IN THE FLAT TERRAIN CASE:'
WRITE(ILUOUT,FMT=*) 'THIS IS NOT ALLOWED ACTUALLY'
!callabortstop
CALL PRINT_MSG(NVERB_FATAL,'GEN','READ_EXSEG_n','')
END IF
!
!* 4.4 Check the coherence between the LUSERn and LHORELAX
!
IF (.NOT. LUSERV .AND. LHORELAX_RV) THEN
LHORELAX_RV=.FALSE.
WRITE(UNIT=ILUOUT,FMT=9002) KMI
WRITE(ILUOUT,FMT=*) 'YOU WANT TO RELAX RV FIELD BUT IT DOES NOT EXIST.'
WRITE(ILUOUT,FMT=*) 'THEREFORE LHORELAX_RV=FALSE'
END IF
!
IF (.NOT. LUSERC .AND. LHORELAX_RC) THEN
LHORELAX_RC=.FALSE.
WRITE(UNIT=ILUOUT,FMT=9002) KMI
WRITE(ILUOUT,FMT=*) 'YOU WANT TO RELAX RC FIELD BUT IT DOES NOT EXIST.' WRITE(ILUOUT,FMT=*) 'THEREFORE LHORELAX_RC=FALSE'
END IF
!
IF (.NOT. LUSERR .AND. LHORELAX_RR) THEN
LHORELAX_RR=.FALSE.
WRITE(UNIT=ILUOUT,FMT=9002) KMI
WRITE(ILUOUT,FMT=*) 'YOU WANT TO RELAX RR FIELD BUT IT DOES NOT EXIST.'
WRITE(ILUOUT,FMT=*) 'THEREFORE LHORELAX_RR=FALSE'
END IF
!
IF (.NOT. LUSERI .AND. LHORELAX_RI) THEN
LHORELAX_RI=.FALSE.
WRITE(UNIT=ILUOUT,FMT=9002) KMI
WRITE(ILUOUT,FMT=*) 'YOU WANT TO RELAX RI FIELD BUT IT DOES NOT EXIST.'
WRITE(ILUOUT,FMT=*) 'THEREFORE LHORELAX_RI=FALSE'
END IF
!
IF (.NOT. LUSERS .AND. LHORELAX_RS) THEN
LHORELAX_RS=.FALSE.
WRITE(UNIT=ILUOUT,FMT=9002) KMI
WRITE(ILUOUT,FMT=*) 'YOU WANT TO RELAX RS FIELD BUT IT DOES NOT EXIST.'
WRITE(ILUOUT,FMT=*) 'THEREFORE LHORELAX_RS=FALSE'
END IF
!
IF (.NOT. LUSERG .AND. LHORELAX_RG) THEN
LHORELAX_RG=.FALSE.
WRITE(UNIT=ILUOUT,FMT=9002) KMI
WRITE(ILUOUT,FMT=*) 'YOU WANT TO RELAX RG FIELD BUT IT DOES NOT EXIST.'
WRITE(ILUOUT,FMT=*) 'THEREFORE LHORELAX_RG=FALSE'
END IF
!
IF (.NOT. LUSERH .AND. LHORELAX_RH) THEN
LHORELAX_RH=.FALSE.
WRITE(UNIT=ILUOUT,FMT=9002) KMI
WRITE(ILUOUT,FMT=*) 'YOU WANT TO RELAX RH FIELD BUT IT DOES NOT EXIST.'
WRITE(ILUOUT,FMT=*) 'THEREFORE LHORELAX_RH=FALSE'
END IF
!
IF (CTURB=='NONE' .AND. LHORELAX_TKE) THEN
LHORELAX_TKE=.FALSE.
WRITE(UNIT=ILUOUT,FMT=9002) KMI
WRITE(ILUOUT,FMT=*) 'YOU WANT TO RELAX TKE FIELD BUT IT DOES NOT EXIST.'
WRITE(ILUOUT,FMT=*) 'THEREFORE LHORELAX_TKE=FALSE'
END IF
!
!
IF (CCLOUD/='C2R2' .AND. CCLOUD/='KHKO' .AND. LHORELAX_SVC2R2) THEN
LHORELAX_SVC2R2=.FALSE.
WRITE(UNIT=ILUOUT,FMT=9002) KMI
WRITE(ILUOUT,FMT=*) 'YOU WANT TO RELAX C2R2 or KHKO FIELD BUT IT DOES NOT EXIST.'
WRITE(ILUOUT,FMT=*) 'THEREFORE LHORELAX_SVC2R2=FALSE'
END IF
!
IF (CCLOUD/='C3R5' .AND. LHORELAX_SVC1R3) THEN
LHORELAX_SVC1R3=.FALSE.
WRITE(UNIT=ILUOUT,FMT=9002) KMI
WRITE(ILUOUT,FMT=*) 'YOU WANT TO RELAX C3R5 FIELD BUT IT DOES NOT EXIST.'
WRITE(ILUOUT,FMT=*) 'THEREFORE LHORELAX_SVC1R3=FALSE'
END IF
!
IF (CCLOUD/='LIMA' .AND. LHORELAX_SVLIMA) THEN
LHORELAX_SVLIMA=.FALSE.
WRITE(UNIT=ILUOUT,FMT=9002) KMI
WRITE(ILUOUT,FMT=*) 'YOU WANT TO RELAX LIMA FIELD BUT IT DOES NOT EXIST.'
WRITE(ILUOUT,FMT=*) 'THEREFORE LHORELAX_SVLIMA=FALSE'
END IF
!
IF (CELEC(1:3) /= 'ELE' .AND. LHORELAX_SVELEC) THEN
LHORELAX_SVELEC=.FALSE.
WRITE(UNIT=ILUOUT,FMT=9002) KMI WRITE(ILUOUT,FMT=*) 'YOU WANT TO RELAX ELEC FIELD BUT IT DOES NOT EXIST.'
WRITE(ILUOUT,FMT=*) 'THEREFORE LHORELAX_SVELEC=FALSE'
END IF
!
IF (.NOT. LUSECHEM .AND. LHORELAX_SVCHEM) THEN
LHORELAX_SVCHEM=.FALSE.
WRITE(UNIT=ILUOUT,FMT=9002) KMI
WRITE(ILUOUT,FMT=*) 'YOU WANT TO RELAX CHEM FIELD BUT IT DOES NOT EXIST.'
WRITE(ILUOUT,FMT=*) 'THEREFORE LHORELAX_SVCHEM=FALSE'
END IF
!
IF (.NOT. LUSECHIC .AND. LHORELAX_SVCHIC) THEN
LHORELAX_SVCHIC=.FALSE.
WRITE(UNIT=ILUOUT,FMT=9002) KMI
WRITE(ILUOUT,FMT=*) 'YOU WANT TO RELAX ICE CHEM FIELD BUT IT DOES NOT EXIST.'
WRITE(ILUOUT,FMT=*) 'THEREFORE LHORELAX_SVCHIC=FALSE'
END IF
!
IF (.NOT. LORILAM .AND. LHORELAX_SVAER) THEN
LHORELAX_SVAER=.FALSE.
WRITE(UNIT=ILUOUT,FMT=9002) KMI
WRITE(ILUOUT,FMT=*) 'YOU WANT TO RELAX AEROSOL FIELD BUT IT DOES NOT EXIST.'
WRITE(ILUOUT,FMT=*) 'THEREFORE LHORELAX_SVAER=FALSE'
END IF
IF (.NOT. LDUST .AND. LHORELAX_SVDST) THEN
LHORELAX_SVDST=.FALSE.
WRITE(UNIT=ILUOUT,FMT=9002) KMI
WRITE(ILUOUT,FMT=*) 'YOU WANT TO RELAX DUST FIELD BUT IT DOES NOT EXIST.'
WRITE(ILUOUT,FMT=*) 'THEREFORE LHORELAX_SVDST=FALSE'
END IF
IF (.NOT. LSALT .AND. LHORELAX_SVSLT) THEN
LHORELAX_SVSLT=.FALSE.
WRITE(UNIT=ILUOUT,FMT=9002) KMI
WRITE(ILUOUT,FMT=*) 'YOU WANT TO RELAX SEA SALT FIELD BUT IT DOES NOT EXIST.'
WRITE(ILUOUT,FMT=*) 'THEREFORE LHORELAX_SVSLT=FALSE'
END IF
IF (.NOT. LPASPOL .AND. LHORELAX_SVPP) THEN
LHORELAX_SVPP=.FALSE.
WRITE(UNIT=ILUOUT,FMT=9002) KMI
WRITE(ILUOUT,FMT=*) 'YOU WANT TO RELAX PASSIVE POLLUTANT FIELD BUT IT DOES NOT EXIST.'
WRITE(ILUOUT,FMT=*) 'THEREFORE LHORELAX_SVPP=FALSE'
END IF
#ifdef MNH_FOREFIRE
IF (.NOT. LFOREFIRE .AND. LHORELAX_SVFF) THEN
LHORELAX_SVFF=.FALSE.
WRITE(UNIT=ILUOUT,FMT=9002) KMI
WRITE(ILUOUT,FMT=*) 'YOU WANT TO RELAX FOREFIRE FLUXES BUT THEY DO NOT EXIST.'
WRITE(ILUOUT,FMT=*) 'THEREFORE LHORELAX_SVFF=FALSE'
END IF
#endif
IF (.NOT. LCONDSAMP .AND. LHORELAX_SVCS) THEN
LHORELAX_SVCS=.FALSE.
WRITE(UNIT=ILUOUT,FMT=9002) KMI
WRITE(ILUOUT,FMT=*) 'YOU WANT TO RELAX CONDITIONAL SAMPLING FIELD BUT IT DOES NOT EXIST.'
WRITE(ILUOUT,FMT=*) 'THEREFORE LHORELAX_SVCS=FALSE'
END IF
IF (ANY(LHORELAX_SV(NSV+1:))) THEN
LHORELAX_SV(NSV+1:)=.FALSE.
WRITE(UNIT=ILUOUT,FMT=9002) KMI
WRITE(ILUOUT,FMT=*) 'YOU WANT TO RELAX SV(NSV+1:) FIELD BUT IT DOES NOT EXIST.'
WRITE(ILUOUT,FMT=*) 'THEREFORE LHORELAX_SV(NSV+1:)=FALSE'
END IF
!
!* 4.5 check the number of points for the horizontal relaxation
!
IF ( NRIMX > KRIMX .AND. .NOT.LHORELAX_SVELEC ) THEN NRIMX = KRIMX
WRITE(UNIT=ILUOUT,FMT=9001) KMI
WRITE(ILUOUT,FMT=*) 'YOU WANT TO USE A LARGER NUMBER OF POINTS '
WRITE(ILUOUT,FMT=*) 'FOR THE HORIZONTAL RELAXATION THAN THE '
WRITE(ILUOUT,FMT=*) 'CORRESPONDING NUMBER OF LARGE SCALE FIELDS:'
WRITE(ILUOUT,FMT=*) 'IT IS THEREFORE REDUCED TO NRIMX =',NRIMX
END IF
!
IF ( L2D .AND. KRIMY>0 ) THEN
NRIMY = 0
WRITE(UNIT=ILUOUT,FMT=9001) KMI
WRITE(ILUOUT,FMT=*) 'YOU WANT TO USE A 2D MODEL THEREFORE NRIMY=0 '
END IF
!
IF ( NRIMY > KRIMY .AND. .NOT.LHORELAX_SVELEC ) THEN
NRIMY = KRIMY
WRITE(UNIT=ILUOUT,FMT=9001) KMI
WRITE(ILUOUT,FMT=*) 'YOU WANT TO USE A LARGER NUMBER OF POINTS '
WRITE(ILUOUT,FMT=*) 'FOR THE HORIZONTAL RELAXATION THAN THE '
WRITE(ILUOUT,FMT=*) 'CORRESPONDING NUMBER OF LARGE SCALE FIELDS:'
WRITE(ILUOUT,FMT=*) 'IT IS THEREFORE REDUCED TO NRIMY =',NRIMY
END IF
!
IF ( (.NOT. LHORELAX_UVWTH) .AND. (.NOT.(ANY(LHORELAX_SV))) .AND. &
(.NOT. LHORELAX_SVC2R2).AND. (.NOT. LHORELAX_SVC1R3) .AND. &
(.NOT. LHORELAX_SVLIMA).AND. &
(.NOT. LHORELAX_SVELEC).AND. (.NOT. LHORELAX_SVCHEM) .AND. &
(.NOT. LHORELAX_SVLG) .AND. (.NOT. LHORELAX_SVPP) .AND. &
(.NOT. LHORELAX_SVCS) .AND. &
#ifdef MNH_FOREFIRE
(.NOT. LHORELAX_SVFF) .AND. &
#endif
(.NOT. LHORELAX_RV) .AND. (.NOT. LHORELAX_RC) .AND. &
(.NOT. LHORELAX_RR) .AND. (.NOT. LHORELAX_RI) .AND. &
(.NOT. LHORELAX_RS) .AND. (.NOT. LHORELAX_RG) .AND. &
(.NOT. LHORELAX_RH) .AND. (.NOT. LHORELAX_TKE) .AND. &
(.NOT. LHORELAX_SVCHIC).AND. &
(NRIMX /= 0 .OR. NRIMY /= 0)) THEN
WRITE(UNIT=ILUOUT,FMT=9001) KMI
WRITE(ILUOUT,FMT=*) 'YOU DO NOT WANT TO USE THE HORIZONTAL RELAXATION '
WRITE(ILUOUT,FMT=*) 'THEREFORE NRIMX=NRIMY=0 '
NRIMX=0
NRIMY=0
END IF
!
IF ((LHORELAX_UVWTH .OR. LHORELAX_SVPP .OR. &
LHORELAX_SVCS .OR. &
#ifdef MNH_FOREFIRE
LHORELAX_SVFF .OR. &
#endif
LHORELAX_SVC2R2 .OR. LHORELAX_SVC1R3 .OR. &
LHORELAX_SVLIMA .OR. &
LHORELAX_SVELEC .OR. LHORELAX_SVCHEM .OR. &
LHORELAX_SVLG .OR. ANY(LHORELAX_SV) .OR. &
LHORELAX_RV .OR. LHORELAX_RC .OR. &
LHORELAX_RR .OR. LHORELAX_RI .OR. &
LHORELAX_RG .OR. LHORELAX_RS .OR. &
LHORELAX_RH .OR. LHORELAX_TKE.OR. &
LHORELAX_SVCHIC ) &
.AND. (NRIMX==0 .OR. (NRIMY==0 .AND. .NOT.(L2D) ))) THEN
WRITE(UNIT=ILUOUT,FMT=9003) KMI
WRITE(ILUOUT,FMT=*) 'YOU WANT TO USE THE HORIZONTAL RELAXATION '
WRITE(ILUOUT,FMT=*) 'BUT NRIMX OR NRIMY=0 CHANGE YOUR VALUES '
WRITE(ILUOUT,FMT=*) "LHORELAX_UVWTH=",LHORELAX_UVWTH
WRITE(ILUOUT,FMT=*) "LHORELAX_SVC2R2=",LHORELAX_SVC2R2
WRITE(ILUOUT,FMT=*) "LHORELAX_SVC1R3=",LHORELAX_SVC1R3
WRITE(ILUOUT,FMT=*) "LHORELAX_SVLIMA=",LHORELAX_SVLIMA
WRITE(ILUOUT,FMT=*) "LHORELAX_SVELEC=",LHORELAX_SVELEC
WRITE(ILUOUT,FMT=*) "LHORELAX_SVCHEM=",LHORELAX_SVCHEM
WRITE(ILUOUT,FMT=*) "LHORELAX_SVCHIC=",LHORELAX_SVCHIC WRITE(ILUOUT,FMT=*) "LHORELAX_SVLG=",LHORELAX_SVLG
WRITE(ILUOUT,FMT=*) "LHORELAX_SVPP=",LHORELAX_SVPP
#ifdef MNH_FOREFIRE
WRITE(ILUOUT,FMT=*) "LHORELAX_SVFF=",LHORELAX_SVFF
#endif
WRITE(ILUOUT,FMT=*) "LHORELAX_SVCS=",LHORELAX_SVCS
WRITE(ILUOUT,FMT=*) "LHORELAX_SV=",LHORELAX_SV
WRITE(ILUOUT,FMT=*) "LHORELAX_RV=",LHORELAX_RV
WRITE(ILUOUT,FMT=*) "LHORELAX_RC=",LHORELAX_RC
WRITE(ILUOUT,FMT=*) "LHORELAX_RR=",LHORELAX_RR
WRITE(ILUOUT,FMT=*) "LHORELAX_RI=",LHORELAX_RI
WRITE(ILUOUT,FMT=*) "LHORELAX_RG=",LHORELAX_RG
WRITE(ILUOUT,FMT=*) "LHORELAX_RS=",LHORELAX_RS
WRITE(ILUOUT,FMT=*) "LHORELAX_RH=",LHORELAX_RH
WRITE(ILUOUT,FMT=*) "LHORELAX_TKE=", LHORELAX_TKE
WRITE(ILUOUT,FMT=*) "NRIMX=",NRIMX
WRITE(ILUOUT,FMT=*) "NRIMY=",NRIMY
WRITE(ILUOUT,FMT=*) "L2D=",L2D
!callabortstop
CALL PRINT_MSG(NVERB_FATAL,'GEN','READ_EXSEG_n','')
END IF
!
IF ((LHORELAX_UVWTH .OR. LHORELAX_SVPP .OR. &
LHORELAX_SVCS .OR. &
#ifdef MNH_FOREFIRE
LHORELAX_SVFF .OR. &
#endif
LHORELAX_SVC2R2 .OR. LHORELAX_SVC1R3 .OR. &
LHORELAX_SVLIMA .OR. &
LHORELAX_SVELEC .OR. LHORELAX_SVCHEM .OR. &
LHORELAX_SVLG .OR. ANY(LHORELAX_SV) .OR. &
LHORELAX_RV .OR. LHORELAX_RC .OR. &
LHORELAX_RR .OR. LHORELAX_RI .OR. &
LHORELAX_RG .OR. LHORELAX_RS .OR. &
LHORELAX_RH .OR. LHORELAX_TKE.OR. &
LHORELAX_SVCHIC ) &
.AND. (KMI /=1)) THEN
WRITE(UNIT=ILUOUT,FMT=9003) KMI
WRITE(ILUOUT,FMT=*) 'YOU WANT TO USE THE HORIZONTAL RELAXATION '
WRITE(ILUOUT,FMT=*) 'FOR A NESTED MODEL BUT THE COUPLING IS ALREADY DONE'
WRITE(ILUOUT,FMT=*) 'BY THE GRID NESTING. CHANGE LHORELAX TO FALSE'
!callabortstop
CALL PRINT_MSG(NVERB_FATAL,'GEN','READ_EXSEG_n','')
END IF
!
IF (KMI==1) THEN
GRELAX = .NOT.(OUSERV) .AND. LUSERV .AND. LHORELAX_RV
ELSE
GRELAX = .NOT.(LUSERV_G(NDAD(KMI))) .AND. LUSERV_G(KMI).AND. LHORELAX_RV
END IF
!
IF ( GRELAX ) THEN
LHORELAX_RV=.FALSE.
WRITE(UNIT=ILUOUT,FMT=9001) KMI
WRITE(ILUOUT,FMT=*) 'YOU WANT TO RELAX THE RV FIELD'
WRITE(ILUOUT,FMT=*) 'TOWARDS THE LARGE SCALE FIELD OF MODEL',NDAD(KMI)
WRITE(ILUOUT,FMT=*) 'BUT IT DOES NOT EXIST.'
WRITE(ILUOUT,FMT=*) 'THEREFORE LHORELAX_RV=FALSE'
END IF
!
IF (KMI==1) THEN
GRELAX = .NOT.(OUSERC) .AND. LUSERC .AND. LHORELAX_RC
ELSE
GRELAX = .NOT.(LUSERC_G(NDAD(KMI))) .AND. LUSERC_G(KMI).AND. LHORELAX_RC
END IF
!
IF ( GRELAX ) THEN
LHORELAX_RC=.FALSE.
WRITE(UNIT=ILUOUT,FMT=9001) KMI
WRITE(ILUOUT,FMT=*) 'YOU WANT TO RELAX THE RC FIELD' WRITE(ILUOUT,FMT=*) 'TOWARDS THE LARGE SCALE FIELD OF MODEL',NDAD(KMI)
WRITE(ILUOUT,FMT=*) 'BUT IT DOES NOT EXIST.'
WRITE(ILUOUT,FMT=*) 'THEREFORE LHORELAX_RC=FALSE'
END IF
!
IF (KMI==1) THEN
GRELAX = .NOT.(OUSERR) .AND. LUSERR .AND. LHORELAX_RR
ELSE
GRELAX = .NOT.(LUSERR_G(NDAD(KMI))) .AND. LUSERR_G(KMI).AND. LHORELAX_RR
END IF
!
IF ( GRELAX ) THEN
LHORELAX_RR=.FALSE.
WRITE(UNIT=ILUOUT,FMT=9001) KMI
WRITE(ILUOUT,FMT=*) 'YOU WANT TO RELAX THE RR FIELD'
WRITE(ILUOUT,FMT=*) 'TOWARDS THE LARGE SCALE FIELD OF MODEL',NDAD(KMI)
WRITE(ILUOUT,FMT=*) 'BUT IT DOES NOT EXIST.'
WRITE(ILUOUT,FMT=*) 'THEREFORE LHORELAX_RR=FALSE'
END IF
!
IF (KMI==1) THEN
GRELAX = .NOT.(OUSERI) .AND. LUSERI .AND. LHORELAX_RI
ELSE
GRELAX = .NOT.(LUSERI_G(NDAD(KMI))) .AND. LUSERI_G(KMI).AND. LHORELAX_RI
END IF
!
IF ( GRELAX ) THEN
LHORELAX_RI=.FALSE.
WRITE(UNIT=ILUOUT,FMT=9001) KMI
WRITE(ILUOUT,FMT=*) 'YOU WANT TO RELAX THE RI FIELD'
WRITE(ILUOUT,FMT=*) 'TOWARDS THE LARGE SCALE FIELD OF MODEL',NDAD(KMI)
WRITE(ILUOUT,FMT=*) 'BUT IT DOES NOT EXIST.'
WRITE(ILUOUT,FMT=*) 'THEREFORE LHORELAX_RI=FALSE'
END IF
!
IF (KMI==1) THEN
GRELAX = .NOT.(OUSERG) .AND. LUSERG .AND. LHORELAX_RG
ELSE
GRELAX = .NOT.(LUSERG_G(NDAD(KMI))) .AND. LUSERG_G(KMI).AND. LHORELAX_RG
END IF
!
IF ( GRELAX ) THEN
LHORELAX_RG=.FALSE.
WRITE(UNIT=ILUOUT,FMT=9001) KMI
WRITE(ILUOUT,FMT=*) 'YOU WANT TO RELAX THE RG FIELD'
WRITE(ILUOUT,FMT=*) 'TOWARDS THE LARGE SCALE FIELD OF MODEL',NDAD(KMI)
WRITE(ILUOUT,FMT=*) 'BUT IT DOES NOT EXIST.'
WRITE(ILUOUT,FMT=*) 'THEREFORE LHORELAX_RG=FALSE'
END IF
!
IF (KMI==1) THEN
GRELAX = .NOT.(OUSERH) .AND. LUSERH .AND. LHORELAX_RH
ELSE
GRELAX = .NOT.(LUSERH_G(NDAD(KMI))) .AND. LUSERH_G(KMI).AND. LHORELAX_RH
END IF
!
IF ( GRELAX ) THEN
LHORELAX_RH=.FALSE.
WRITE(UNIT=ILUOUT,FMT=9001) KMI
WRITE(ILUOUT,FMT=*) 'YOU WANT TO RELAX THE RH FIELD'
WRITE(ILUOUT,FMT=*) 'TOWARDS THE LARGE SCALE FIELD OF MODEL',NDAD(KMI)
WRITE(ILUOUT,FMT=*) 'BUT IT DOES NOT EXIST.'
WRITE(ILUOUT,FMT=*) 'THEREFORE LHORELAX_RH=FALSE'
END IF
!
IF (KMI==1) THEN
GRELAX = .NOT.(OUSERS) .AND. LUSERS .AND. LHORELAX_RS
ELSE
GRELAX = .NOT.(LUSERS_G(NDAD(KMI))) .AND. LUSERS_G(KMI).AND. LHORELAX_RS
END IF !
IF ( GRELAX ) THEN
LHORELAX_RS=.FALSE.
WRITE(UNIT=ILUOUT,FMT=9001) KMI
WRITE(ILUOUT,FMT=*) 'YOU WANT TO RELAX THE RS FIELD'
WRITE(ILUOUT,FMT=*) 'TOWARDS THE LARGE SCALE FIELD OF MODEL',NDAD(KMI)
WRITE(ILUOUT,FMT=*) 'BUT IT DOES NOT EXIST.'
WRITE(ILUOUT,FMT=*) 'THEREFORE LHORELAX_RS=FALSE'
END IF
!
IF (KMI==1) THEN
GRELAX = HTURB=='NONE' .AND. LUSETKE(1).AND. LHORELAX_TKE
ELSE
GRELAX = .NOT.(LUSETKE(NDAD(KMI))) .AND. LUSETKE(KMI) .AND. LHORELAX_TKE
END IF
!
IF ( GRELAX ) THEN
LHORELAX_TKE=.FALSE.
WRITE(UNIT=ILUOUT,FMT=9001) KMI
WRITE(ILUOUT,FMT=*) 'YOU WANT TO RELAX THE TKE FIELD'
WRITE(ILUOUT,FMT=*) 'TOWARDS THE LARGE SCALE FIELD OF MODEL',NDAD(KMI)
WRITE(ILUOUT,FMT=*) 'BUT IT DOES NOT EXIST.'
WRITE(ILUOUT,FMT=*) 'THEREFORE LHORELAX_TKE=FALSE'
END IF
!
!
DO JSV = 1,NSV_USER
!
IF (KMI==1) THEN
GRELAX = KSV_USER<JSV .AND. LUSESV(JSV,1).AND. LHORELAX_SV(JSV)
ELSE
GRELAX = .NOT.(LUSESV(JSV,NDAD(KMI))) .AND. LUSESV(JSV,KMI) .AND. LHORELAX_SV(JSV)
END IF
!
IF ( GRELAX ) THEN
LHORELAX_SV(JSV)=.FALSE.
WRITE(UNIT=ILUOUT,FMT=9001) KMI
WRITE(ILUOUT,FMT=*) 'YOU WANT TO RELAX THE ',JSV,' SV FIELD'
WRITE(ILUOUT,FMT=*) 'TOWARDS THE LARGE SCALE FIELD OF MODEL',NDAD(KMI)
WRITE(ILUOUT,FMT=*) 'BUT IT DOES NOT EXIST.'
WRITE(ILUOUT,FMT=*) 'THEREFORE LHORELAX_SV(',JSV,')=FALSE'
END IF
END DO
!
!* 4.6 consistency in LES diagnostics choices
!
IF (CLES_NORM_TYPE=='EKMA' .AND. .NOT. LCORIO) THEN
WRITE(UNIT=ILUOUT,FMT=9002) KMI
WRITE(ILUOUT,FMT=*) 'YOU WANT TO USE THE EKMAN NORMALIZATION'
WRITE(ILUOUT,FMT=*) 'BUT CORIOLIS FORCE IS NOT USED (LCORIO=.FALSE.)'
WRITE(ILUOUT,FMT=*) 'THEN, NO NORMALIZATION IS PERFORMED'
CLES_NORM_TYPE='NONE'
END IF
!
!* 4.7 Check the coherence with LNUMDIFF
!
IF (L1D .AND. (LNUMDIFU .OR. LNUMDIFTH .OR. LNUMDIFSV) ) THEN
WRITE(UNIT=ILUOUT,FMT=9002) KMI
WRITE(ILUOUT,FMT=*) 'YOU WANT TO USE HORIZONTAL DIFFUSION '
WRITE(ILUOUT,FMT=*) 'BUT YOU ARE IN A COLUMN MODEL (L1D=.TRUE.).'
WRITE(ILUOUT,FMT=*) 'THEREFORE LNUMDIFU and LNUMDIFTH and LNUMDIFSV'
WRITE(ILUOUT,FMT=*) 'ARE SET TO FALSE'
LNUMDIFU=.FALSE.
LNUMDIFTH=.FALSE.
LNUMDIFSV=.FALSE.
END IF
!
IF (.NOT. LNUMDIFTH .AND. LZDIFFU) THEN
WRITE(UNIT=ILUOUT,FMT=9002) KMI
WRITE(ILUOUT,FMT=*) 'YOU DO NOT WANT TO USE HORIZONTAL DIFFUSION (LNUMDIFTH=F)' WRITE(ILUOUT,FMT=*) 'BUT YOU WANT TO USE Z-NUMERICAL DIFFUSION '
WRITE(ILUOUT,FMT=*) 'THEREFORE LNUMDIFTH IS SET TO TRUE'
LNUMDIFTH=.TRUE.
END IF
!
!* 4.8 Other
!
IF (XTNUDGING < 4.*XTSTEP) THEN
XTNUDGING = 4.*XTSTEP
WRITE(UNIT=ILUOUT,FMT=9002) KMI
WRITE(UNIT=ILUOUT,FMT='("TIME SCALE FOR NUDGING CAN NOT BE SMALLER THAN", &
& " FOUR TIMES THE TIME STEP")')
WRITE(ILUOUT,FMT=*) 'XTNUDGING is SET TO ',XTNUDGING
END IF
!
!
IF (XWAY(KMI) == 3. ) THEN
XWAY(KMI) = 2.
WRITE(UNIT=ILUOUT,FMT=9002) KMI
WRITE(UNIT=ILUOUT,FMT='("XWAY=3 DOES NOT EXIST ANYMORE; ", &
& " IT IS REPLACED BY XWAY=2 ")')
END IF
!
IF ( (KMI == 1) .AND. XWAY(KMI) /= 0. ) THEN
XWAY(KMI) = 0.
WRITE(UNIT=ILUOUT,FMT=9002) KMI
WRITE(UNIT=ILUOUT,FMT='("XWAY MUST BE EQUAL TO 0 FOR DAD MODEL")')
END IF
!
!JUANZ ZRESI solver need BSPLITTING
IF ( CPRESOPT == 'ZRESI' .AND. CSPLIT /= 'BSPLITTING' ) THEN
WRITE(UNIT=ILUOUT,FMT=9003) KMI
WRITE(UNIT=ILUOUT,FMT='("Paralleliez in Z solver CPRESOPT=ZRESI need also CSPLIT=BSPLITTING ")')
WRITE(ILUOUT,FMT=*) ' ERROR you have to set also CSPLIT=BSPLITTING '
!callabortstop
CALL PRINT_MSG(NVERB_FATAL,'GEN','READ_EXSEG_n','')
END IF
!
IF ( LEN_TRIM(HINIFILEPGD)>0 ) THEN
IF ( CINIFILEPGD/=HINIFILEPGD ) THEN
WRITE(UNIT=ILUOUT,FMT=9001) KMI
WRITE(ILUOUT,FMT=*) ' ERROR : in EXSEG1.nam, in NAM_LUNITn you have CINIFILEPGD= ',CINIFILEPGD
WRITE(ILUOUT,FMT=*) ' whereas in .des you have CINIFILEPGD= ',HINIFILEPGD
WRITE(ILUOUT,FMT=*) ' Please check your Namelist '
WRITE(ILUOUT,FMT=*) ' For example, you may have specified the un-nested PGD file instead of the nested PGD file '
WRITE(ILUOUT,FMT=*)
WRITE(ILUOUT,FMT=*) '###############'
WRITE(ILUOUT,FMT=*) ' MESONH ABORTS'
WRITE(ILUOUT,FMT=*) '###############'
WRITE(ILUOUT,FMT=*)
!callabortstop
CALL PRINT_MSG(NVERB_FATAL,'GEN','READ_EXSEG_n','')
END IF
ELSE
CINIFILEPGD = ''
!* note that after a spawning, there is no value for CINIFILEPGD in the .des file,
! so the checking cannot be made if the user starts a simulation directly from
! a spawned file (without the prep_real_case stage)
END IF
!-------------------------------------------------------------------------------
!
!* 5. WE DO NOT FORGET TO UPDATE ALL DOLLARN NAMELIST VARIABLES
! ---------------------------------------------------------
!
CALL UPDATE_NAM_LUNITN
CALL UPDATE_NAM_CONFN
CALL UPDATE_NAM_DYNN
CALL UPDATE_NAM_ADVN
CALL UPDATE_NAM_PARAMN
CALL UPDATE_NAM_PARAM_RADNCALL UPDATE_NAM_PARAM_KAFRN
CALL UPDATE_NAM_PARAM_MFSHALLN
CALL UPDATE_NAM_LBCN
CALL UPDATE_NAM_NUDGINGN
CALL UPDATE_NAM_TURBN
CALL UPDATE_NAM_CH_MNHCN
CALL UPDATE_NAM_CH_SOLVERN
CALL UPDATE_NAM_SERIESN
!-------------------------------------------------------------------------------
WRITE(UNIT=ILUOUT,FMT='(/)')
!-------------------------------------------------------------------------------
!
!* 6. FORMATS
! -------
!
9000 FORMAT(/,'NOTE IN READ_EXSEG FOR MODEL ', I2, ' : ',/, &
'--------------------------------')
9001 FORMAT(/,'CAUTION ERROR IN READ_EXSEG FOR MODEL ', I2,' : ',/, &
'----------------------------------------' )
9002 FORMAT(/,'WARNING IN READ_EXSEG FOR MODEL ', I2,' : ',/, &
'----------------------------------' )
9003 FORMAT(/,'FATAL ERROR IN READ_EXSEG FOR MODEL ', I2,' : ',/, &
'--------------------------------------' )
!
!-------------------------------------------------------------------------------
!
END SUBROUTINE READ_EXSEG_n