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WAUTELET Philippe authoredPhilippe 12/01/2018: IO: add ZTOP field for model top (useful for mesh description in CF convention)
WAUTELET Philippe authoredPhilippe 12/01/2018: IO: add ZTOP field for model top (useful for mesh description in CF convention)
ini_modeln.f90 81.67 KiB
!MNH_LIC Copyright 1994-2014 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.
! $Source$ $Revision$ $Date$
!-----------------------------------------------------------------
! #######################
MODULE MODI_INI_MODEL_n
! #######################
!
INTERFACE
!
SUBROUTINE INI_MODEL_n(KMI,HLUOUT,TPINIFILE)
!
USE MODD_IO_ll, ONLY : TFILEDATA
!
INTEGER, INTENT(IN) :: KMI ! Model Index
CHARACTER(LEN=*), INTENT(IN) :: HLUOUT ! name for output-listing of nested models
TYPE(TFILEDATA), INTENT(IN) :: TPINIFILE ! Initial file
!
END SUBROUTINE INI_MODEL_n
!
END INTERFACE
!
END MODULE MODI_INI_MODEL_n
! ############################################
SUBROUTINE INI_MODEL_n(KMI,HLUOUT,TPINIFILE)
! ############################################
!
!!**** *INI_MODEL_n* - routine to initialize the nested model _n
!!
!! PURPOSE
!! -------
! The purpose of this routine is to initialize the variables
! of the nested model _n.
!
!!** METHOD
!! ------
!! The initialization of the model _n is performed as follows :
!! - Memory for arrays are then allocated :
!! * If turbulence kinetic energy variable is not needed
!! (CTURB='NONE'), XTKET, XTKEM and XTKES are zero-size arrays.
!! * If dissipation of TKE variable is not needed
!! (CTURBLEN /='KEPS'), XEPST, XEPSM and XREPSS are zero-size arrays.
!! * Memory for mixing ratio arrays is allocated according to the
!! value of logicals LUSERn (the number NRR of moist variables is deduced).
!! * The latitude (XLAT), longitude (XLON) and map factor (XMAP)
!! arrays are zero-size arrays if Cartesian geometry (LCARTESIAN=.TRUE.)
!! * Memory for reference state without orography ( XRHODREFZ and
!! XTHVREFZ) is only allocated in INI_MODEL1
!! * The horizontal Coriolis parameters (XCORIOX and XCORIOY) arrays
!! are zero-size arrays if thinshell approximation (LTHINSHELL=.TRUE.)
!! * The Curvature coefficients (XCURVX and XCURVY) arrays
!! are zero-size arrays if Cartesian geometry (LCARTESIAN=.TRUE.)
!! * Memory for the Jacobian (ZJ) local array is allocated
!! (This variable is computed in SET_GRID and used in SET_REF).
!! - The spatial and temporal grid variables are initialized by SET_GRID.
!! - The metric coefficients are computed by METRICS (they are using in
!! the SET-REF call).
!! - The prognostic variables and are read in initial
!! LFIFM file (in READ_FIELD)
!! - The reference state variables are initialized by SET_REF.
!! - The temporal indexes of the outputs are computed by SET_OUTPUT_TIMES
!! - The large scale sources are computed in case of coupling case by
!! INI_CPL.
!! - The initialization of the parameters needed for the dynamics
!! of the model n is realized in INI_DYNAMICS.
!! - Then the initial file (DESFM+LFIFM files) is closed by IO_FILE_CLOSE_ll.
!! - The initialization of the parameters needed for the ECMWF radiation
!! code is realized in INI_RADIATIONS.!! - The contents of the scalar variables are overwritten by
!! the chemistry initialization subroutine CH_INIT_FIELDn when
!! the flags LUSECHEM and LCH_INIT_FIELD are set to TRUE.
!! This allows easy initialization of the chemical fields at a
!! restart of the model.
!!
!! EXTERNAL
!! --------
!! FMREAD : to read a LFIFM file
!! FMFREE : to release a logical unit number
!! SET_DIM : to initialize dimensions
!! SET_GRID : to initialize grid
!! METRICS : to compute metric coefficients
!! READ_FIELD : to initialize field
!! FMCLOS : to close a FM-file
!! SET_REF : to initialize reference state for anelastic approximation
!! INI_DYNAMICS: to initialize parameters for the dynamics
!! INI_TKE_EPS : to initialize the TKE
!! SET_DIRCOS : to compute the director cosinus of the orography
!! INI_RADIATIONS : to initialize radiation computations
!! CH_INIT_CCS: to initialize the chemical core system
!! CH_INIT_FIELDn: to (re)initialize the scalar variables
!! INI_DEEP_CONVECTION : to initialize the deep convection scheme
!! CLEANLIST_ll : deaalocate a list
!!
!! IMPLICIT ARGUMENTS
!! ------------------
!!
!! Module MODD_PARAMETERS : contains declaration of parameter variables
!! JPHEXT : Horizontal external points number
!! JPVEXT : Vertical external points number
!!
!! Module MODD_MODD_DYN : contains declaration of parameters
!! for the dynamics
!! Module MODD_CONF : contains declaration of configuration variables
!! for all models
!! NMODEL : Number of nested models
!! NVERB : Level of informations on output-listing
!! 0 for minimum prints
!! 5 for intermediate level of prints
!! 10 for maximum prints
!!
!! Module MODD_REF : contains declaration of reference state
!! variables for all models
!! Module MODD_FIELD_n : contains declaration of prognostic fields
!! Module MODD_LSFIELD_n : contains declaration of Larger Scale fields
!! Module MODD_GRID_n : contains declaration of spatial grid variables
!! Module MODD_TIME_n : contains declaration of temporal grid variables
!! Module MODD_REF_n : contains declaration of reference state
!! variables
!! Module MODD_CURVCOR_n : contains declaration of curvature and Coriolis
!! variables
!! Module MODD_BUDGET : contains declarations of the budget parameters
!! Module MODD_RADIATIONS_n:contains declaration of the variables of the
!! radiation interface scheme
!! Module MODD_STAND_ATM : contains declaration of the 5 standard
!! atmospheres used for the ECMWF-radiation code
!! Module MODD_FRC : contains declaration of the control variables
!! and of the forcing fields
!! Module MODD_CH_MNHC_n : contains the control parameters for chemistry
!! Module MODD_DEEP_CONVECTION_n: contains declaration of the variables of
!! the deep convection scheme
!!
!!
!!
!!
!! Module MODN_CONF_n : contains declaration of namelist NAM_CONFn and
!! uses module MODD_CONF_n (configuration variables)
!! Module MODN_LUNIT_n : contains declaration of namelist NAM_LUNITn and
!! uses module MODD_LUNIT_n (Logical units)!! Module MODN_DYN_n : contains declaration of namelist NAM_DYNn and
!! uses module MODD_DYN_n (control of dynamics)
!! Module MODN_PARAM_n : contains declaration of namelist NAM_PARAMn and
!! uses module MODD_PARAM_n (control of physical
!! parameterization)
!! Module MODN_LBC_n : contains declaration of namelist NAM_LBCn and
!! uses module MODD_LBC_n (lateral boundaries)
!! Module MODN_TURB_n : contains declaration of namelist NAM_TURBn and
!! uses module MODD_TURB_n (turbulence scheme)
!! Module MODN_PARAM_RAD_n: contains declaration of namelist NAM_PARAM_RADn
!!
!! REFERENCE
!! ---------
!! Book2 of documentation (routine INI_MODEL_n)
!!
!!
!! AUTHOR
!! ------
!! V. Ducrocq * Meteo France *
!!
!! MODIFICATIONS
!! -------------
!! Original 10/06/94
!! Modification 17/10/94 (Stein) For LCORIO
!! Modification 20/10/94 (Stein) For SET_GRID and NAMOUTN
!! Modification 26/10/94 (Stein) Modifications of the namelist names
!! Modification 10/11/94 (Lafore) allocatation of tke fields
!! Modification 22/11/94 (Stein) change the READ_FIELDS call ( add
!! pressure function
!! Modification 06/12/94 (Stein) add the LS fields
!! 12/12/94 (Stein) rename END_INI in INI_DYNAMICS
!! Modification 09/01/95 (Stein) add the turbulence scheme
!! Modification Jan 19, 1995 (J. Cuxart) add the TKE initialization
!! Jan 23, 1995 (J. Stein ) remove the condition
!! LTHINSHELL=T LCARTESIAN=T => stop
!! Modification Feb 16, 1995 (I.Mallet) add the METRICS call and
!! change the SET_REF call (add
!! the lineic mass)
!! Modification Mar 10, 1995 (I. Mallet) add the COUPLING initialization
!! June 29,1995 (Ph. Hereil, J. Stein) add the budget init.
!! Modification Sept. 1, 1995 (S. Belair) Reading of the surface variables
!! and parameters for ISBA (i.e., add a
!! CALL READ_GR_FIELD)
!! Modification 18/08/95 (J.P.Lafore) time step change case
!! 25/09/95 (J. Cuxart and J.Stein) add LES variables
!! and the diachronic file initialization
!! Modification Sept 20,1995 (Lafore) coupling for the dry mass Md
!! Modification Sept. 12, 1995 (J.-P. Pinty) add the initialization of
!! the ECMWF radiation code
!! Modification Sept. 13, 1995 (J.-P. Pinty) control the allocation of the
!! arrays of MODD_GR_FIELD_n
!! Modification Nove. 17, 1995 (J.Stein) control of the control !!
!! March 01, 1996 (J. Stein) add the cloud fraction
!! April 03, 1996 (J. Stein) unify the ISBA and TSZ0 cases
!! Modification 13/12/95 (M. Georgelin) add the forcing variables in
!! the call read_field, and their
!! allocation.
!! Mai 23, 1996 (J. Stein) allocate XSEA in the TSZ0 case
!! June 11, 1996 (V. Masson) add XSILT and XLAKE of
!! MODD_GR_FIELD_n
!! August 7, 1996 (K. Suhre) add (re)initialization of
!! chemistry
!! Octo. 11, 1996 (J. Stein ) add XSRCT and XSRCM
!! October 8, 1996 (J. Cuxart, E. Sanchez) Moist LES diagnostics
!! and control on TKE initialization.
!! Modification 19/12/96 (J.-P. Pinty) add the ice parameterization and
!! the precipitation fields
!! Modification 11/01/97 (J.-P. Pinty) add the deep convection
!! Nov. 1, 1996 (V. Masson) Read the vertical grid kind
!! Nov. 20, 1996 (V. Masson) control of convection calling time!! July 16, 1996 (J.P.Lafore) update of EXSEG file reading
!! Oct. 08, 1996 (J.P.Lafore, V.Masson)
!! MY_NAME and DAD_NAME reading and check
!! Oct. 30, 1996 (J.P.Lafore) resolution ratio reading for nesting
!! and Bikhardt interpolation coef. initialization
!! Nov. 22, 1996 (J.P.Lafore) allocation of LS sources for nesting
!! Feb. 26, 1997 (J.P.Lafore) allocation of "surfacic" LS fields
!! March 10, 1997 (J.P.Lafore) forcing only for model 1
!! June 22, 1997 (J. Stein) add the absolute pressure
!! July 09, 1997 (V. Masson) add directional z0 and SSO
!! Aug. 18, 1997 (V. Masson) consistency between storage
!! type and CCONF
!! Dec. 22, 1997 (J. Stein) add the LS field spawning
!! Jan. 24, 1998 (P.Bechtold) change MODD_FRC and MODD_DEEP_CONVECTION
!! Dec. 24, 1997 (V.Masson) directional z0 parameters
!! Aug. 13, 1998 (V. Ducrocq P Jabouille) //
!! Mai. 26, 1998 (J. Stein) remove NXEND,NYEND
!! Feb. 1, 1999 (J. Stein) compute the Bikhardt
!! interpolation coeff. before the call to set_grid
!! April 5, 1999 (V. Ducrocq) change the DXRATIO_ALL init.
!! April 12, 1999 (J. Stein) cleaning + INI_SPAWN_LS
!! Apr. 7, 1999 (P Jabouille) store the metric coefficients
!! in modd_metrics_n
!! Jui. 15,1999 (P Jabouille) split the routines in two parts
!! Jan. 04,2000 (V. Masson) removes the TSZ0 case
!! Apr. 15,2000 (P Jabouille) parallelization of grid nesting
!! Aug. 20,2000 (J Stein ) tranpose XBFY
!! Jui 01,2000 (F.solmon ) adapatation for patch approach
!! Jun. 15,2000 (J.-P. Pinty) add C2R2 initialization
!! Nov. 15,2000 (V.Masson) use of ini_modeln in prep_real_case
!! Nov. 15,2000 (V.Masson) call of LES routines
!! Nov. 15,2000 (V.Masson) aircraft and balloon initialization routines
!! Jan. 22,2001 (D.Gazen) update_nsv set NSV_* var. for current model
!! Mar. 04,2002 (V.Ducrocq) initialization to temporal series
!! Mar. 15,2002 (F.Solmon) modification of ini_radiation interface
!! Nov. 29,2002 (JP Pinty) add C3R5, ICE2, ICE4, ELEC
!! Jan. 2004 (V.Masson) externalization of surface
!! May 2006 Remove KEPS
!! Apr. 2010 (M. Leriche) add pH for aqueous phase chemistry
!! Jul. 2010 (M. Leriche) add Ice phase chemistry
!! Oct. 2010 (J.Escobar) check if local domain not to small for NRIMX NRIMY
!! Nov. 2010 (J.Escobar) PGI BUG , add SIZE(CSV) to init_ground routine
!! Nov. 2009 (C. Barthe) add call to INI_ELEC_n
!! Mar. 2010 (M. Chong) add small ions
!! Apr. 2011 (M. Chong) correction of RESTART (ELEC)
!! June 2011 (B.Aouizerats) Prognostic aerosols
!! June 2011 (P.Aumond) Drag of the vegetation
!! + Mean fields
!! July 2013 (Bosseur & Filippi) Adds Forefire
!! P. Tulet Nov 2014 accumulated moles of aqueous species that fall at the surface
!! JAn. 2015 (F. Brosse) bug in allocate XACPRAQ
!! Dec 2014 (C.Lac) : For reproducibility START/RESTA
!! J.Escobar : 15/09/2015 : WENO5 & JPHEXT <> 1
!! V. Masson Feb 2015 replaces, for aerosols, cover fractions by sea, town, bare soil fractions
!! J.Escobar : 19/04/2016 : Pb IOZ/NETCDF , missing OPARALLELIO=.FALSE. for PGD files
!! J.Escobar : 01/06/2016 : correct check limit of NRIM versus local subdomain size IDIM
!! 06/2016 (G.Delautier) phasage surfex 8
!! Modification 01/2016 (JP Pinty) Add LIMA
!! M.Leriche 2016 Chemistry
!! 10/2016 M.Mazoyer New KHKO output fields
!! 10/2016 (C.Lac) Add max values
!! F. Brosse Oct. 2016 add prod/loss terms computation for chemistry
!! M.Leriche 2016 Chemistry
!! M.Leriche 10/02/17 prevent negative values in LBX(Y)SVS
!! M.Leriche 01/07/2017 Add DIAG chimical surface fluxes
!! 09/2017 Q.Rodier add LTEND_UV_FRC
!---------------------------------------------------------------------------------
!
!* 0. DECLARATIONS
! ------------USE MODE_ll
USE MODD_ARGSLIST_ll, ONLY : LIST_ll
USE MODE_IO_ll
USE MODE_IO_MANAGE_STRUCT, ONLY : IO_FILE_ADD2LIST
USE MODE_FM, ONLY: IO_FILE_OPEN_ll
USE MODE_FMREAD
USE MODE_GATHER_ll
USE MODE_MSG
USE MODE_TYPE_ZDIFFU
!
USE MODD_NSV
USE MODD_PARAMETERS
USE MODD_CST
USE MODD_CONF
USE MODD_DUST
USE MODD_DYN
USE MODD_DYNZD
USE MODD_FRC
USE MODD_REF
USE MODD_SERIES, ONLY: LSERIES
USE MODD_TIME
USE MODD_TURB_CLOUD, ONLY: NMODEL_CLOUD, CTURBLEN_CLOUD,XCEI
USE MODD_NESTING
USE MODD_PASPOL
USE MODD_DRAGTREE
USE MODD_METRICS_n
USE MODD_DYN_n
USE MODD_DYNZD_n
USE MODD_FIELD_n
USE MODD_PAST_FIELD_n
USE MODD_MEAN_FIELD_n
USE MODD_MEAN_FIELD
USE MODD_ADV_n
USE MODD_LSFIELD_n
USE MODD_GRID_n
USE MODD_GRID, ONLY: XLONORI,XLATORI
USE MODD_TIME_n
USE MODD_REF_n
USE MODD_FRC_n
USE MODD_CURVCOR_n
USE MODD_DIM_n
USE MODD_BUDGET
USE MODD_RADIATIONS_n
USE MODD_SHADOWS_n
USE MODD_PARAM_RAD_n, ONLY : CLW, CAER, CAOP
USE MODD_VAR_ll, ONLY : IP
!
USE MODD_STAND_ATM, ONLY : XSTROATM, XSMLSATM, XSMLWATM, XSPOSATM, XSPOWATM
USE MODD_CH_MNHC_n, ONLY : LUSECHEM, LUSECHAQ, LUSECHIC, LCH_INIT_FIELD, &
CCHEM_INPUT_FILE, LCH_CONV_LINOX, &
XCH_TUV_DOBNEW, LCH_PH, CSPEC_BUDGET, CSPEC_PRODLOSS
USE MODD_CH_PH_n
USE MODD_CH_AEROSOL, ONLY : LORILAM
USE MODD_CH_AERO_n, ONLY : XSOLORG,XMI
USE MODD_CH_FLX_n, ONLY : XCHFLX
USE MODD_PARAM_KAFR_n
USE MODD_PARAM_MFSHALL_n
USE MODD_DEEP_CONVECTION_n
USE MODD_OUT_n
USE MODD_BIKHARDT_n
USE MODD_NUDGING_n, ONLY : LNUDGING
USE MODD_DIAG_FLAG, ONLY : LCHEMDIAG, CSPEC_BU_DIAG
USE MODD_CLOUD_MF_n
USE MODD_NSV
!
USE MODD_ELEC_n, ONLY : XCION_POS_FW, XCION_NEG_FW
USE MODD_LUNIT_n
USE MODD_CONF_n
USE MODD_GET_nUSE MODD_TURB_n
USE MODD_CTURB
USE MODD_LBC_n
USE MODD_PASPOL_n
!
!
USE MODI_INI_BUDGET
USE MODI_INI_SW_SETUP
USE MODI_SET_GRID
USE MODI_METRICS
USE MODI_UPDATE_METRICS
USE MODI_READ_FIELD
USE MODI_SET_REF
USE MODI_INI_DYNAMICS
USE MODI_INI_TKE_EPS
USE MODI_SET_DIRCOS
USE MODI_INI_CPL
USE MODI_INI_RADIATIONS
USE MODI_INI_RADIATIONS_ECMWF
USE MODI_CH_INIT_FIELD_n
USE MODI_INI_DEEP_CONVECTION
USE MODI_INI_BIKHARDT_n
USE MODI_INI_ONE_WAY_n
USE MODI_GET_SIZEX_LB
USE MODI_GET_SIZEY_LB
USE MODI_INI_SPAWN_LS_n
USE MODI_INI_AIRCRAFT_BALLOON
USE MODI_UPDATE_NSV
USE MODI_INI_ELEC_n
USE MODI_INI_MICRO_n
USE MODI_INI_LG
USE MODI_SURF_SOLAR_GEOM
USE MODI_SUNPOS_n
USE MODI_INI_SURF_RAD
USE MODI_MNHGET_SURF_PARAM_n
USE MODI_MNHREAD_ZS_DUMMY_n
USE MODI_INIT_GROUND_PARAM_n
USE MODI_INI_AIRCRAFT_BALLOON
USE MODI_INI_SURFSTATION_n
USE MODI_INI_POSPROFILER_n
USE MODI_CH_INIT_JVALUES
USE MODI_CH_AER_MOD_INIT
!
USE MODD_PARAM_n
USE MODE_MODELN_HANDLER
USE MODE_SPLITTINGZ_ll , ONLY : GET_DIM_EXTZ_ll
USE MODI_TEMPORAL_DIST
USE MODI_INI_AEROSET1
USE MODI_INI_AEROSET2
USE MODI_INI_AEROSET3
USE MODI_INI_AEROSET4
USE MODI_INI_AEROSET5
USE MODI_INI_AEROSET6
!
#ifdef MNH_FOREFIRE
USE MODD_FOREFIRE
USE MODD_FOREFIRE_n
USE MODI_INIT_FOREFIRE_n
#endif
USE MODI_INI_LES_N
USE MODD_MNH_SURFEX_n
USE MODI_INI_SERIES_N
! Eddy fluxes ! Ajout PP
USE MODD_DEF_EDDY_FLUX_n ! for VT and WT fluxes
USE MODD_DEF_EDDYUV_FLUX_n ! FOR UV
USE MODD_LATZ_EDFLX
USE MODD_ADVFRC_n
USE MODD_RELFRC_nUSE MODD_2D_FRC
USE MODD_IO_SURF_MNH, ONLY : IO_SURF_MNH_MODEL
USE MODD_IO_ll, ONLY : LIOCDF4,LLFIOUT,TFILEDATA,TFILE_FIRST,TFILE_LAST
!
USE MODD_CH_PRODLOSSTOT_n
USE MODI_CH_INIT_PRODLOSSTOT_n
!
USE MODD_CH_BUDGET_n
USE MODI_CH_INIT_BUDGET_n
USE MODD_CH_M9_n, ONLY:NNONZEROTERMS
!
USE MODE_MPPDB
USE MODI_INIT_AEROSOL_PROPERTIES
!
IMPLICIT NONE
!
!* 0.1 declarations of arguments
!
!
INTEGER, INTENT(IN) :: KMI ! Model Index
CHARACTER(LEN=*), INTENT(IN) :: HLUOUT ! name for output-listing of nested models
TYPE(TFILEDATA), INTENT(IN) :: TPINIFILE ! Initial file
!
!* 0.2 declarations of local variables
!
INTEGER :: JSV ! Loop index
INTEGER :: IRESP ! Return code of FM routines
INTEGER :: ININAR ! File management variable
INTEGER :: IMASDEV ! version of MESONH in the input file
INTEGER :: ILUOUT ! Logical unit number of output-listing
CHARACTER(LEN=28) :: YNAME
INTEGER :: IIU ! Upper dimension in x direction (local)
INTEGER :: IJU ! Upper dimension in y direction (local)
INTEGER :: IIU_ll ! Upper dimension in x direction (global)
INTEGER :: IJU_ll ! Upper dimension in y direction (global)
INTEGER :: IKU ! Upper dimension in z direction
REAL, DIMENSION(:,:,:), ALLOCATABLE :: ZJ ! Jacobian
LOGICAL :: GINIDCONV ! logical switch for the deep convection
! initialization
LOGICAL :: GINIRAD ! logical switch for the radiation
! initialization
!
!
TYPE(LIST_ll), POINTER :: TZINITHALO2D_ll ! pointer for the list of 2D fields
! which must be communicated in INIT
TYPE(LIST_ll), POINTER :: TZINITHALO3D_ll ! pointer for the list of 3D fields
! which must be communicated in INIT
!
INTEGER :: IISIZEXF,IJSIZEXF,IISIZEXFU,IJSIZEXFU ! dimensions of the
INTEGER :: IISIZEX4,IJSIZEX4,IISIZEX2,IJSIZEX2 ! West-east LB arrays
INTEGER :: IISIZEYF,IJSIZEYF,IISIZEYFV,IJSIZEYFV ! dimensions of the
INTEGER :: IISIZEY4,IJSIZEY4,IISIZEY2,IJSIZEY2 ! North-south LB arrays
INTEGER :: IINFO_ll ! Return code of //routines
INTEGER :: IIY,IJY
INTEGER :: IIU_B,IJU_B
INTEGER :: IIU_SXP2_YP1_Z_ll,IJU_SXP2_YP1_Z_ll,IKU_SXP2_YP1_Z_ll
!
REAL, DIMENSION(:,:), ALLOCATABLE :: ZCO2 ! CO2 concentration near the surface
REAL, DIMENSION(:,:), ALLOCATABLE :: ZSEA ! sea fraction
REAL, DIMENSION(:,:), ALLOCATABLE :: ZTOWN ! town fraction
REAL, DIMENSION(:,:), ALLOCATABLE :: ZBARE ! bare soil fraction
!
REAL, DIMENSION(:,:,:), ALLOCATABLE :: ZDIR_ALB ! direct albedo
REAL, DIMENSION(:,:,:), ALLOCATABLE :: ZSCA_ALB ! diffuse albedo
REAL, DIMENSION(:,:), ALLOCATABLE :: ZEMIS ! emissivity
REAL, DIMENSION(:,:), ALLOCATABLE :: ZTSRAD ! surface temperature
!
!
INTEGER, DIMENSION(:,:),ALLOCATABLE :: IINDEX ! indices of non-zero terms
INTEGER, DIMENSION(:),ALLOCATABLE :: IINDINTEGER :: JM
!
!------------------------------------------
! Dummy pointers needed to correct an ifort Bug
REAL, DIMENSION(:), POINTER :: DPTR_XZHAT
REAL, DIMENSION(:), POINTER :: DPTR_XBMX1,DPTR_XBMX2,DPTR_XBMX3,DPTR_XBMX4
REAL, DIMENSION(:), POINTER :: DPTR_XBMY1,DPTR_XBMY2,DPTR_XBMY3,DPTR_XBMY4
REAL, DIMENSION(:), POINTER :: DPTR_XBFX1,DPTR_XBFX2,DPTR_XBFX3,DPTR_XBFX4
REAL, DIMENSION(:), POINTER :: DPTR_XBFY1,DPTR_XBFY2,DPTR_XBFY3,DPTR_XBFY4
CHARACTER(LEN=4), DIMENSION(:), POINTER :: DPTR_CLBCX,DPTR_CLBCY
INTEGER, DIMENSION(:,:,:), POINTER :: DPTR_NKLIN_LBXU,DPTR_NKLIN_LBYU,DPTR_NKLIN_LBXV,DPTR_NKLIN_LBYV
INTEGER, DIMENSION(:,:,:), POINTER :: DPTR_NKLIN_LBXW,DPTR_NKLIN_LBYW,DPTR_NKLIN_LBXM,DPTR_NKLIN_LBYM
REAL, DIMENSION(:,:,:), POINTER :: DPTR_XCOEFLIN_LBXU,DPTR_XCOEFLIN_LBYU
REAL, DIMENSION(:,:,:), POINTER :: DPTR_XCOEFLIN_LBXV,DPTR_XCOEFLIN_LBYV
REAL, DIMENSION(:,:,:), POINTER :: DPTR_XCOEFLIN_LBXW,DPTR_XCOEFLIN_LBYW
REAL, DIMENSION(:,:,:), POINTER :: DPTR_XCOEFLIN_LBXM,DPTR_XCOEFLIN_LBYM
REAL, DIMENSION(:,:,:), POINTER :: DPTR_XLBXUM,DPTR_XLBYUM,DPTR_XLBXVM,DPTR_XLBYVM
REAL, DIMENSION(:,:,:), POINTER :: DPTR_XLBXWM,DPTR_XLBYWM,DPTR_XLBXTHM,DPTR_XLBYTHM
REAL, DIMENSION(:,:,:), POINTER :: DPTR_XLBXTKEM,DPTR_XLBYTKEM
REAL, DIMENSION(:,:,:,:), POINTER :: DPTR_XLBXSVM,DPTR_XLBYSVM
REAL, DIMENSION(:,:,:,:), POINTER :: DPTR_XLBXRM,DPTR_XLBYRM
REAL, DIMENSION(:,:,:), POINTER :: DPTR_XZZ
REAL, DIMENSION(:,:,:), POINTER :: DPTR_XLSUM,DPTR_XLSVM,DPTR_XLSWM,DPTR_XLSTHM,DPTR_XLSRVM
REAL, DIMENSION(:,:,:), POINTER :: DPTR_XLSUS,DPTR_XLSVS,DPTR_XLSWS,DPTR_XLSTHS,DPTR_XLSRVS
!
INTEGER :: IIB,IJB,IIE,IJE,IDIMX,IDIMY,IMI
!
!-------------------------------------------------------------------------------
!
!* 0. PROLOGUE
! --------
! Compute relaxation coefficients without changing INI_DYNAMICS nor RELAXDEF
!
IF (CCLOUD == 'LIMA') THEN
LHORELAX_SVC1R3=LHORELAX_SVLIMA
END IF
!
!
NULLIFY(TZINITHALO2D_ll)
NULLIFY(TZINITHALO3D_ll)
!
!* 1. RETRIEVE LOGICAL UNIT NUMBER
! ----------------------------
!
ILUOUT = TLUOUT%NLU
!
CALL IO_READ_FIELD(TPINIFILE,'MASDEV',IMASDEV)
!-------------------------------------------------------------------------------
!
!* 2. END OF READING
! --------------
!* 2.1 Read number of forcing fields
!
IF (LFORCING) THEN ! Retrieve the number of time-dependent forcings.
CALL IO_READ_FIELD(TPINIFILE,'FRC',NFRC,IRESP)
IF ( (IRESP /= 0) .OR. (NFRC <=0) ) THEN
WRITE(ILUOUT,'(A/A)') &
"INI_MODEL_n ERROR: you want to read forcing variables from FMfile", &
" but no fields have been found by IO_READ_FIELD"
!callabortstop
CALL PRINT_MSG(NVERB_FATAL,'GEN','INI_MODEL_n','')
END IF
END IF
!
! Modif PP for time evolving adv forcing
IF ( L2D_ADV_FRC ) THEN ! Retrieve the number of time-dependent forcings.
WRITE(ILUOUT,FMT=*) "INI_MODEL_n ENTER ADV_FORCING"
CALL IO_READ_FIELD(TPINIFILE,'NADVFRC1',NADVFRC,IRESP)
IF ( (IRESP /= 0) .OR. (NADVFRC <=0) ) THEN
WRITE(ILUOUT,'(A/A)') & "INI_MODELn ERROR: you want to read forcing ADV variables from FMfile", &
" but no fields have been found by IO_READ_FIELD"
!callabortstop
CALL PRINT_MSG(NVERB_FATAL,'GEN','INI_MODEL_n','')
END IF
WRITE(ILUOUT,*) 'NADVFRC = ', NADVFRC
END IF
!
IF ( L2D_REL_FRC ) THEN ! Retrieve the number of time-dependent forcings.
WRITE(ILUOUT,FMT=*) "INI_MODEL_n ENTER REL_FORCING"
CALL IO_READ_FIELD(TPINIFILE,'NRELFRC1',NRELFRC,IRESP)
IF ( (IRESP /= 0) .OR. (NRELFRC <=0) ) THEN
WRITE(ILUOUT,'(A/A)') &
"INI_MODELn ERROR: you want to read forcing REL variables from FMfile", &
" but no fields have been found by IO_READ_FIELD"
!callabortstop
CALL PRINT_MSG(NVERB_FATAL,'GEN','INI_MODEL_n','')
END IF
WRITE(ILUOUT,*) 'NRELFRC = ', NRELFRC
END IF
!* 2.2 Checks the position of vertical absorbing layer
!
IKU=NKMAX+2*JPVEXT
!
ALLOCATE(XZHAT(IKU))
CALL IO_READ_FIELD(TPINIFILE,'ZHAT',XZHAT)
CALL IO_READ_FIELD(TPINIFILE,'ZTOP',XZTOP)
IF (XALZBOT>=XZHAT(IKU) .AND. LVE_RELAX) THEN
WRITE(ILUOUT,FMT=*) "INI_MODEL_n ERROR: you want to use vertical relaxation"
WRITE(ILUOUT,FMT=*) " but bottom of layer XALZBOT(",XALZBOT,")"
WRITE(ILUOUT,FMT=*) " is upper than model top (",XZHAT(IKU),")"
!callabortstop
CALL PRINT_MSG(NVERB_FATAL,'GEN','INI_MODEL_n','')
END IF
IF (LVE_RELAX) THEN
IF (XALZBOT>=XZHAT(IKU-4) ) THEN
WRITE(ILUOUT,FMT=*) "INI_MODEL_n WARNING: you want to use vertical relaxation"
WRITE(ILUOUT,FMT=*) " but the layer defined by XALZBOT(",XALZBOT,")"
WRITE(ILUOUT,FMT=*) " contains less than 5 model levels"
END IF
END IF
DEALLOCATE(XZHAT)
!
!* 2.3 Compute sizes of arrays of the extended sub-domain
!
CALL GET_DIM_EXT_ll('B',IIU,IJU)
IIU_ll=NIMAX_ll + 2 * JPHEXT
IJU_ll=NJMAX_ll + 2 * JPHEXT
! initialize NIMAX and NJMAX for not updated versions regarding the parallelism
! spawning,...
CALL GET_DIM_PHYS_ll('B',NIMAX,NJMAX)
!
CALL GET_INDICE_ll( IIB,IJB,IIE,IJE)
IDIMX = IIE - IIB + 1
IDIMY = IJE - IJB + 1
!
NRR=0
NRRL=0
NRRI=0
IF (CGETRVT /= 'SKIP' ) THEN
NRR = NRR+1
IDX_RVT = NRR
END IF
IF (CGETRCT /= 'SKIP' ) THEN
NRR = NRR+1
NRRL = NRRL+1
IDX_RCT = NRR
END IF
IF (CGETRRT /= 'SKIP' ) THEN
NRR = NRR+1 NRRL = NRRL+1
IDX_RRT = NRR
END IF
IF (CGETRIT /= 'SKIP' ) THEN
NRR = NRR+1
NRRI = NRRI+1
IDX_RIT = NRR
END IF
IF (CGETRST /= 'SKIP' ) THEN
NRR = NRR+1
NRRI = NRRI+1
IDX_RST = NRR
END IF
IF (CGETRGT /= 'SKIP' ) THEN
NRR = NRR+1
NRRI = NRRI+1
IDX_RGT = NRR
END IF
IF (CGETRHT /= 'SKIP' ) THEN
NRR = NRR+1
NRRI = NRRI+1
IDX_RHT = NRR
END IF
IF (NVERB >= 5) THEN
WRITE (UNIT=ILUOUT,FMT='("THERE ARE ",I2," WATER VARIABLES")') NRR
WRITE (UNIT=ILUOUT,FMT='("THERE ARE ",I2," LIQUID VARIABLES")') NRRL
WRITE (UNIT=ILUOUT,FMT='("THERE ARE ",I2," SOLID VARIABLES")') NRRI
END IF
!
!* 2.4 Update NSV and floating indices for the current model
!
!
CALL UPDATE_NSV(KMI)
!
!-------------------------------------------------------------------------------
!
!* 3. ALLOCATE MEMORY
! -----------------
!
!* 3.1 Module MODD_FIELD_n
!
IF (LMEAN_FIELD) THEN
!
MEAN_COUNT = 0
!
ALLOCATE(XUM_MEAN(IIU,IJU,IKU)) ; XUM_MEAN = 0.0
ALLOCATE(XVM_MEAN(IIU,IJU,IKU)) ; XVM_MEAN = 0.0
ALLOCATE(XWM_MEAN(IIU,IJU,IKU)) ; XWM_MEAN = 0.0
ALLOCATE(XTHM_MEAN(IIU,IJU,IKU)) ; XTHM_MEAN = 0.0
ALLOCATE(XTEMPM_MEAN(IIU,IJU,IKU)) ; XTEMPM_MEAN = 0.0
IF (CTURB/='NONE') THEN
ALLOCATE(XTKEM_MEAN(IIU,IJU,IKU))
XTKEM_MEAN = 0.0
END IF
ALLOCATE(XPABSM_MEAN(IIU,IJU,IKU)) ; XPABSM_MEAN = 0.0
!
ALLOCATE(XU2_MEAN(IIU,IJU,IKU)) ; XU2_MEAN = 0.0
ALLOCATE(XV2_MEAN(IIU,IJU,IKU)) ; XV2_MEAN = 0.0
ALLOCATE(XW2_MEAN(IIU,IJU,IKU)) ; XW2_MEAN = 0.0
ALLOCATE(XTH2_MEAN(IIU,IJU,IKU)) ; XTH2_MEAN = 0.0
ALLOCATE(XTEMP2_MEAN(IIU,IJU,IKU)) ; XTEMP2_MEAN = 0.0
ALLOCATE(XPABS2_MEAN(IIU,IJU,IKU)) ; XPABS2_MEAN = 0.0
!
ALLOCATE(XUM_MAX(IIU,IJU,IKU)) ; XUM_MAX = -1.E20
ALLOCATE(XVM_MAX(IIU,IJU,IKU)) ; XVM_MAX = -1.E20
ALLOCATE(XWM_MAX(IIU,IJU,IKU)) ; XWM_MAX = -1.E20
ALLOCATE(XTHM_MAX(IIU,IJU,IKU)) ; XTHM_MAX = 0.0
ALLOCATE(XTEMPM_MAX(IIU,IJU,IKU)) ; XTEMPM_MAX = 0.0
IF (CTURB/='NONE') THEN
ALLOCATE(XTKEM_MAX(IIU,IJU,IKU)) XTKEM_MAX = 0.0
END IF
ALLOCATE(XPABSM_MAX(IIU,IJU,IKU)) ; XPABSM_MAX = 0.0
END IF
!
IF ((CUVW_ADV_SCHEME(1:3)=='CEN') .AND. (CTEMP_SCHEME == 'LEFR') ) THEN
ALLOCATE(XUM(IIU,IJU,IKU))
ALLOCATE(XVM(IIU,IJU,IKU))
ALLOCATE(XWM(IIU,IJU,IKU))
ALLOCATE(XDUM(IIU,IJU,IKU))
ALLOCATE(XDVM(IIU,IJU,IKU))
ALLOCATE(XDWM(IIU,IJU,IKU))
IF (CCONF == 'START') THEN
XUM = 0.0
XVM = 0.0
XWM = 0.0
XDUM = 0.0
XDVM = 0.0
XDWM = 0.0
END IF
END IF
!
ALLOCATE(XUT(IIU,IJU,IKU)) ; XUT = 0.0
ALLOCATE(XVT(IIU,IJU,IKU)) ; XVT = 0.0
ALLOCATE(XWT(IIU,IJU,IKU)) ; XWT = 0.0
ALLOCATE(XTHT(IIU,IJU,IKU)) ; XTHT = 0.0
ALLOCATE(XRUS(IIU,IJU,IKU)) ; XRUS = 0.0
ALLOCATE(XRVS(IIU,IJU,IKU)) ; XRVS = 0.0
ALLOCATE(XRWS(IIU,IJU,IKU)) ; XRWS = 0.0
ALLOCATE(XRUS_PRES(IIU,IJU,IKU)); XRUS_PRES = 0.0
ALLOCATE(XRVS_PRES(IIU,IJU,IKU)); XRVS_PRES = 0.0
ALLOCATE(XRWS_PRES(IIU,IJU,IKU)); XRWS_PRES = 0.0
ALLOCATE(XRTHS(IIU,IJU,IKU)) ; XRTHS = 0.0
ALLOCATE(XRTHS_CLD(IIU,IJU,IKU)); XRTHS_CLD = 0.0
IF (CTURB /= 'NONE') THEN
ALLOCATE(XTKET(IIU,IJU,IKU))
ALLOCATE(XRTKES(IIU,IJU,IKU))
ALLOCATE(XRTKEMS(IIU,IJU,IKU)); XRTKEMS = 0.0
ALLOCATE(XWTHVMF(IIU,IJU,IKU))
ALLOCATE(XDYP(IIU,IJU,IKU))
ALLOCATE(XTHP(IIU,IJU,IKU))
ALLOCATE(XTR(IIU,IJU,IKU))
ALLOCATE(XDISS(IIU,IJU,IKU))
ALLOCATE(XLEM(IIU,IJU,IKU))
XTKEMIN=XKEMIN
ELSE
ALLOCATE(XTKET(0,0,0))
ALLOCATE(XRTKES(0,0,0))
ALLOCATE(XWTHVMF(0,0,0))
ALLOCATE(XDYP(0,0,0))
ALLOCATE(XTHP(0,0,0))
ALLOCATE(XTR(0,0,0))
ALLOCATE(XDISS(0,0,0))
ALLOCATE(XLEM(0,0,0))
END IF
IF (CTOM == 'TM06') THEN
ALLOCATE(XBL_DEPTH(IIU,IJU))
ELSE
ALLOCATE(XBL_DEPTH(0,0))
END IF
IF (LRMC01) THEN
ALLOCATE(XSBL_DEPTH(IIU,IJU))
ELSE
ALLOCATE(XSBL_DEPTH(0,0))
END IF
!
ALLOCATE(XPABSM(IIU,IJU,IKU)) ; XPABSM = 0.0
ALLOCATE(XPABST(IIU,IJU,IKU)) ; XPABST = 0.0
!
ALLOCATE(XRT(IIU,IJU,IKU,NRR)) ; XRT = 0.0ALLOCATE(XRRS(IIU,IJU,IKU,NRR)) ; XRRS = 0.0
ALLOCATE(XRRS_CLD(IIU,IJU,IKU,NRR)); XRRS_CLD = 0.0
!
IF (CTURB /= 'NONE' .AND. NRR>1) THEN
ALLOCATE(XSRCT(IIU,IJU,IKU))
ALLOCATE(XSIGS(IIU,IJU,IKU))
ELSE
ALLOCATE(XSRCT(0,0,0))
ALLOCATE(XSIGS(0,0,0))
END IF
!
IF (NRR>1) THEN
ALLOCATE(XCLDFR(IIU,IJU,IKU))
ELSE
ALLOCATE(XCLDFR(0,0,0))
END IF
!
ALLOCATE(XSVT(IIU,IJU,IKU,NSV)) ; XSVT = 0.
ALLOCATE(XRSVS(IIU,IJU,IKU,NSV)); XRSVS = 0.
ALLOCATE(XRSVS_CLD(IIU,IJU,IKU,NSV)); XRSVS_CLD = 0.0
!
IF (LPASPOL) THEN
ALLOCATE( XATC(IIU,IJU,IKU,NSV_PP) )
XATC = 0.
ELSE
ALLOCATE( XATC(0,0,0,0))
XATC = 0.
END IF
!
!* 3.2 Module MODD_GRID_n and MODD_METRICS_n
!
IF (LCARTESIAN) THEN
ALLOCATE(XLON(0,0))
ALLOCATE(XLAT(0,0))
ALLOCATE(XMAP(0,0))
ELSE
ALLOCATE(XLON(IIU,IJU))
ALLOCATE(XLAT(IIU,IJU))
ALLOCATE(XMAP(IIU,IJU))
END IF
ALLOCATE(XXHAT(IIU))
ALLOCATE(XDXHAT(IIU))
ALLOCATE(XYHAT(IJU))
ALLOCATE(XDYHAT(IJU))
ALLOCATE(XZS(IIU,IJU))
ALLOCATE(XZSMT(IIU,IJU))
ALLOCATE(XZZ(IIU,IJU,IKU))
ALLOCATE(XZHAT(IKU))
ALLOCATE(XDIRCOSZW(IIU,IJU))
ALLOCATE(XDIRCOSXW(IIU,IJU))
ALLOCATE(XDIRCOSYW(IIU,IJU))
ALLOCATE(XCOSSLOPE(IIU,IJU))
ALLOCATE(XSINSLOPE(IIU,IJU))
!
ALLOCATE(XDXX(IIU,IJU,IKU))
ALLOCATE(XDYY(IIU,IJU,IKU))
ALLOCATE(XDZX(IIU,IJU,IKU))
ALLOCATE(XDZY(IIU,IJU,IKU))
ALLOCATE(XDZZ(IIU,IJU,IKU))
!
!* 3.3 Modules MODD_REF and MODD_REF_n
!
IF (KMI == 1) THEN
ALLOCATE(XRHODREFZ(IKU),XTHVREFZ(IKU))
END IF
ALLOCATE(XRHODREF(IIU,IJU,IKU))
ALLOCATE(XTHVREF(IIU,IJU,IKU))
ALLOCATE(XEXNREF(IIU,IJU,IKU))
ALLOCATE(XRHODJ(IIU,IJU,IKU))
IF (CEQNSYS=='DUR' .AND. LUSERV) THEN ALLOCATE(XRVREF(IIU,IJU,IKU))
ELSE
ALLOCATE(XRVREF(0,0,0))
END IF
!
!* 3.4 Module MODD_CURVCOR_n
!
IF (LTHINSHELL) THEN
ALLOCATE(XCORIOX(0,0))
ALLOCATE(XCORIOY(0,0))
ELSE
ALLOCATE(XCORIOX(IIU,IJU))
ALLOCATE(XCORIOY(IIU,IJU))
END IF
ALLOCATE(XCORIOZ(IIU,IJU))
IF (LCARTESIAN) THEN
ALLOCATE(XCURVX(0,0))
ALLOCATE(XCURVY(0,0))
ELSE
ALLOCATE(XCURVX(IIU,IJU))
ALLOCATE(XCURVY(IIU,IJU))
END IF
!
!* 3.5 Module MODD_DYN_n
!
CALL GET_DIM_EXT_ll('Y',IIY,IJY)
IF (L2D) THEN
ALLOCATE(XBFY(IIY,IJY,IKU))
ELSE
ALLOCATE(XBFY(IJY,IIY,IKU)) ! transposition needed by the optimisition of the
! FFT solver
END IF
CALL GET_DIM_EXT_ll('B',IIU_B,IJU_B)
ALLOCATE(XBFB(IIU_B,IJU_B,IKU))
CALL GET_DIM_EXTZ_ll('SXP2_YP1_Z',IIU_SXP2_YP1_Z_ll,IJU_SXP2_YP1_Z_ll,IKU_SXP2_YP1_Z_ll)
ALLOCATE(XBF_SXP2_YP1_Z(IIU_SXP2_YP1_Z_ll,IJU_SXP2_YP1_Z_ll,IKU_SXP2_YP1_Z_ll))
ALLOCATE(XAF(IKU),XCF(IKU))
ALLOCATE(XTRIGSX(3*IIU_ll))
ALLOCATE(XTRIGSY(3*IJU_ll))
ALLOCATE(XRHOM(IKU))
ALLOCATE(XALK(IKU))
ALLOCATE(XALKW(IKU))
ALLOCATE(XALKBAS(IKU))
ALLOCATE(XALKWBAS(IKU))
!
IF ( LHORELAX_UVWTH .OR. LHORELAX_RV .OR. &
LHORELAX_RC .OR. LHORELAX_RR .OR. LHORELAX_RI .OR. LHORELAX_RS .OR. &
LHORELAX_RG .OR. LHORELAX_RH .OR. LHORELAX_TKE .OR. &
ANY(LHORELAX_SV) ) THEN
ALLOCATE(XKURELAX(IIU,IJU))
ALLOCATE(XKVRELAX(IIU,IJU))
ALLOCATE(XKWRELAX(IIU,IJU))
ALLOCATE(LMASK_RELAX(IIU,IJU))
ELSE
ALLOCATE(XKURELAX(0,0))
ALLOCATE(XKVRELAX(0,0))
ALLOCATE(XKWRELAX(0,0))
ALLOCATE(LMASK_RELAX(0,0))
END IF
!
! Additional fields for truly horizontal diffusion (Module MODD_DYNZD$n)
IF (LZDIFFU) THEN
CALL INIT_TYPE_ZDIFFU_HALO2(XZDIFFU_HALO2)
ELSE
CALL INIT_TYPE_ZDIFFU_HALO2(XZDIFFU_HALO2,0)
ENDIF
!
!* 3.6 Larger Scale variables (Module MODD_LSFIELD$n)
!
!! upper relaxation part
!
ALLOCATE(XLSUM(IIU,IJU,IKU)) ; XLSUM = 0.0
ALLOCATE(XLSVM(IIU,IJU,IKU)) ; XLSVM = 0.0
ALLOCATE(XLSWM(IIU,IJU,IKU)) ; XLSWM = 0.0
ALLOCATE(XLSTHM(IIU,IJU,IKU)) ; XLSTHM = 0.0
IF ( NRR > 0 ) THEN
ALLOCATE(XLSRVM(IIU,IJU,IKU)) ; XLSRVM = 0.0
ELSE
ALLOCATE(XLSRVM(0,0,0))
END IF
!
! lbc part
!
IF ( L1D) THEN ! 1D case
!
NSIZELBX_ll=0
NSIZELBXU_ll=0
NSIZELBY_ll=0
NSIZELBYV_ll=0
NSIZELBXTKE_ll=0
NSIZELBXR_ll=0
NSIZELBXSV_ll=0
NSIZELBYTKE_ll=0
NSIZELBYR_ll=0
NSIZELBYSV_ll=0
ALLOCATE(XLBXUM(0,0,0))
ALLOCATE(XLBYUM(0,0,0))
ALLOCATE(XLBXVM(0,0,0))
ALLOCATE(XLBYVM(0,0,0))
ALLOCATE(XLBXWM(0,0,0))
ALLOCATE(XLBYWM(0,0,0))
ALLOCATE(XLBXTHM(0,0,0))
ALLOCATE(XLBYTHM(0,0,0))
ALLOCATE(XLBXTKEM(0,0,0))
ALLOCATE(XLBYTKEM(0,0,0))
ALLOCATE(XLBXRM(0,0,0,0))
ALLOCATE(XLBYRM(0,0,0,0))
ALLOCATE(XLBXSVM(0,0,0,0))
ALLOCATE(XLBYSVM(0,0,0,0))
!
ELSEIF( L2D ) THEN ! 2D case
!
NSIZELBY_ll=0
NSIZELBYV_ll=0
NSIZELBYTKE_ll=0
NSIZELBYR_ll=0
NSIZELBYSV_ll=0
ALLOCATE(XLBYUM(0,0,0))
ALLOCATE(XLBYVM(0,0,0))
ALLOCATE(XLBYWM(0,0,0))
ALLOCATE(XLBYTHM(0,0,0))
ALLOCATE(XLBYTKEM(0,0,0))
ALLOCATE(XLBYRM(0,0,0,0))
ALLOCATE(XLBYSVM(0,0,0,0))
!
CALL GET_SIZEX_LB(NIMAX_ll,NJMAX_ll,NRIMX, &
IISIZEXF,IJSIZEXF,IISIZEXFU,IJSIZEXFU, &
IISIZEX4,IJSIZEX4,IISIZEX2,IJSIZEX2)
!
IF ( LHORELAX_UVWTH ) THEN
NSIZELBX_ll=2*NRIMX+2*JPHEXT
NSIZELBXU_ll=2*NRIMX+2*JPHEXT
ALLOCATE(XLBXUM(IISIZEXFU,IJSIZEXFU,IKU))
ALLOCATE(XLBXVM(IISIZEXF,IJSIZEXF,IKU))
ALLOCATE(XLBXWM(IISIZEXF,IJSIZEXF,IKU))
ALLOCATE(XLBXTHM(IISIZEXF,IJSIZEXF,IKU))
ELSE
NSIZELBX_ll=2*JPHEXT ! 2
NSIZELBXU_ll=2*(JPHEXT+1) ! 4 ALLOCATE(XLBXUM(IISIZEX4,IJSIZEX4,IKU))
ALLOCATE(XLBXVM(IISIZEX2,IJSIZEX2,IKU))
ALLOCATE(XLBXWM(IISIZEX2,IJSIZEX2,IKU))
ALLOCATE(XLBXTHM(IISIZEX2,IJSIZEX2,IKU))
END IF
!
IF (CTURB /= 'NONE') THEN
IF ( LHORELAX_TKE) THEN
NSIZELBXTKE_ll=2* NRIMX+2*JPHEXT
ALLOCATE(XLBXTKEM(IISIZEXF,IJSIZEXF,IKU))
ELSE
NSIZELBXTKE_ll=2*JPHEXT ! 2
ALLOCATE(XLBXTKEM(IISIZEX2,IJSIZEX2,IKU))
END IF
ELSE
NSIZELBXTKE_ll=0
ALLOCATE(XLBXTKEM(0,0,0))
END IF
!
IF ( NRR > 0 ) THEN
IF (LHORELAX_RV .OR. LHORELAX_RC .OR. LHORELAX_RR .OR. LHORELAX_RI &
.OR. LHORELAX_RS .OR. LHORELAX_RG .OR. LHORELAX_RH &
) THEN
NSIZELBXR_ll=2* NRIMX+2*JPHEXT
ALLOCATE(XLBXRM(IISIZEXF,IJSIZEXF,IKU,NRR))
ELSE
NSIZELBXR_ll=2*JPHEXT ! 2
ALLOCATE(XLBXRM(IISIZEX2,IJSIZEX2,IKU,NRR))
ENDIF
ELSE
NSIZELBXR_ll=0
ALLOCATE(XLBXRM(0,0,0,0))
END IF
!
IF ( NSV > 0 ) THEN
IF ( ANY( LHORELAX_SV(:)) ) THEN
NSIZELBXSV_ll=2* NRIMX+2*JPHEXT
ALLOCATE(XLBXSVM(IISIZEXF,IJSIZEXF,IKU,NSV))
ELSE
NSIZELBXSV_ll=2*JPHEXT ! 2
ALLOCATE(XLBXSVM(IISIZEX2,IJSIZEX2,IKU,NSV))
END IF
ELSE
NSIZELBXSV_ll=0
ALLOCATE(XLBXSVM(0,0,0,0))
END IF
!
ELSE ! 3D case
!
!
CALL GET_SIZEX_LB(NIMAX_ll,NJMAX_ll,NRIMX, &
IISIZEXF,IJSIZEXF,IISIZEXFU,IJSIZEXFU, &
IISIZEX4,IJSIZEX4,IISIZEX2,IJSIZEX2)
CALL GET_SIZEY_LB(NIMAX_ll,NJMAX_ll,NRIMY, &
IISIZEYF,IJSIZEYF,IISIZEYFV,IJSIZEYFV, &
IISIZEY4,IJSIZEY4,IISIZEY2,IJSIZEY2)
!
! check if local domain not to small for NRIMX NRIMY
!
IF ( CLBCX(1) /= 'CYCL' ) THEN
IF ( NRIMX .GT. IDIMX ) THEN
WRITE(*,'(A,I8,A/A,2I8,/A)') "Processor=", IP-1, &
" :: INI_MODEL_n ERROR: ( NRIMX > IDIMX ) ", &
" Local domain to small for relaxation NRIMX,IDIMX ", &
NRIMX,IDIMX ,&
" change relaxation parameters or number of processors "
!callabortstop
CALL ABORT
STOP
END IF END IF
IF ( CLBCY(1) /= 'CYCL' ) THEN
IF ( NRIMY .GT. IDIMY ) THEN
WRITE(*,'(A,I8,A/A,2I8,/A)') "Processor=", IP-1, &
" :: INI_MODEL_n ERROR: ( NRIMY > IDIMY ) ", &
" Local domain to small for relaxation NRIMY,IDIMY ", &
NRIMY,IDIMY ,&
" change relaxation parameters or number of processors "
!callabortstop
CALL ABORT
STOP
END IF
END IF
IF ( LHORELAX_UVWTH ) THEN
NSIZELBX_ll=2*NRIMX+2*JPHEXT
NSIZELBXU_ll=2*NRIMX+2*JPHEXT
NSIZELBY_ll=2*NRIMY+2*JPHEXT
NSIZELBYV_ll=2*NRIMY+2*JPHEXT
ALLOCATE(XLBXUM(IISIZEXFU,IJSIZEXFU,IKU))
ALLOCATE(XLBYUM(IISIZEYF,IJSIZEYF,IKU))
ALLOCATE(XLBXVM(IISIZEXF,IJSIZEXF,IKU))
ALLOCATE(XLBYVM(IISIZEYFV,IJSIZEYFV,IKU))
ALLOCATE(XLBXWM(IISIZEXF,IJSIZEXF,IKU))
ALLOCATE(XLBYWM(IISIZEYF,IJSIZEYF,IKU))
ALLOCATE(XLBXTHM(IISIZEXF,IJSIZEXF,IKU))
ALLOCATE(XLBYTHM(IISIZEYF,IJSIZEYF,IKU))
ELSE
NSIZELBX_ll=2*JPHEXT ! 2
NSIZELBXU_ll=2*(JPHEXT+1) ! 4
NSIZELBY_ll=2*JPHEXT ! 2
NSIZELBYV_ll=2*(JPHEXT+1) ! 4
ALLOCATE(XLBXUM(IISIZEX4,IJSIZEX4,IKU))
ALLOCATE(XLBYUM(IISIZEY2,IJSIZEY2,IKU))
ALLOCATE(XLBXVM(IISIZEX2,IJSIZEX2,IKU))
ALLOCATE(XLBYVM(IISIZEY4,IJSIZEY4,IKU))
ALLOCATE(XLBXWM(IISIZEX2,IJSIZEX2,IKU))
ALLOCATE(XLBYWM(IISIZEY2,IJSIZEY2,IKU))
ALLOCATE(XLBXTHM(IISIZEX2,IJSIZEX2,IKU))
ALLOCATE(XLBYTHM(IISIZEY2,IJSIZEY2,IKU))
END IF
!
IF (CTURB /= 'NONE') THEN
IF ( LHORELAX_TKE) THEN
NSIZELBXTKE_ll=2*NRIMX+2*JPHEXT
NSIZELBYTKE_ll=2*NRIMY+2*JPHEXT
ALLOCATE(XLBXTKEM(IISIZEXF,IJSIZEXF,IKU))
ALLOCATE(XLBYTKEM(IISIZEYF,IJSIZEYF,IKU))
ELSE
NSIZELBXTKE_ll=2*JPHEXT ! 2
NSIZELBYTKE_ll=2*JPHEXT ! 2
ALLOCATE(XLBXTKEM(IISIZEX2,IJSIZEX2,IKU))
ALLOCATE(XLBYTKEM(IISIZEY2,IJSIZEY2,IKU))
END IF
ELSE
NSIZELBXTKE_ll=0
NSIZELBYTKE_ll=0
ALLOCATE(XLBXTKEM(0,0,0))
ALLOCATE(XLBYTKEM(0,0,0))
END IF
!
IF ( NRR > 0 ) THEN
IF (LHORELAX_RV .OR. LHORELAX_RC .OR. LHORELAX_RR .OR. LHORELAX_RI &
.OR. LHORELAX_RS .OR. LHORELAX_RG .OR. LHORELAX_RH &
) THEN
NSIZELBXR_ll=2*NRIMX+2*JPHEXT
NSIZELBYR_ll=2*NRIMY+2*JPHEXT
ALLOCATE(XLBXRM(IISIZEXF,IJSIZEXF,IKU,NRR))
ALLOCATE(XLBYRM(IISIZEYF,IJSIZEYF,IKU,NRR))
ELSE
NSIZELBXR_ll=2*JPHEXT ! 2 NSIZELBYR_ll=2*JPHEXT ! 2
ALLOCATE(XLBXRM(IISIZEX2,IJSIZEX2,IKU,NRR))
ALLOCATE(XLBYRM(IISIZEY2,IJSIZEY2,IKU,NRR))
ENDIF
ELSE
NSIZELBXR_ll=0
NSIZELBYR_ll=0
ALLOCATE(XLBXRM(0,0,0,0))
ALLOCATE(XLBYRM(0,0,0,0))
END IF
!
IF ( NSV > 0 ) THEN
IF ( ANY( LHORELAX_SV(:)) ) THEN
NSIZELBXSV_ll=2*NRIMX+2*JPHEXT
NSIZELBYSV_ll=2*NRIMY+2*JPHEXT
ALLOCATE(XLBXSVM(IISIZEXF,IJSIZEXF,IKU,NSV))
ALLOCATE(XLBYSVM(IISIZEYF,IJSIZEYF,IKU,NSV))
ELSE
NSIZELBXSV_ll=2*JPHEXT ! 2
NSIZELBYSV_ll=2*JPHEXT ! 2
ALLOCATE(XLBXSVM(IISIZEX2,IJSIZEX2,IKU,NSV))
ALLOCATE(XLBYSVM(IISIZEY2,IJSIZEY2,IKU,NSV))
END IF
ELSE
NSIZELBXSV_ll=0
NSIZELBYSV_ll=0
ALLOCATE(XLBXSVM(0,0,0,0))
ALLOCATE(XLBYSVM(0,0,0,0))
END IF
END IF ! END OF THE IF STRUCTURE ON THE MODEL DIMENSION
!
!
IF ( KMI > 1 ) THEN
! it has been assumed that the THeta field used the largest rim area compared
! to the others prognostic variables, if it is not the case, you must change
! these lines
ALLOCATE(XCOEFLIN_LBXM(SIZE(XLBXTHM,1),SIZE(XLBXTHM,2),SIZE(XLBXTHM,3)))
ALLOCATE( NKLIN_LBXM(SIZE(XLBXTHM,1),SIZE(XLBXTHM,2),SIZE(XLBXTHM,3)))
ALLOCATE(XCOEFLIN_LBYM(SIZE(XLBYTHM,1),SIZE(XLBYTHM,2),SIZE(XLBYTHM,3)))
ALLOCATE( NKLIN_LBYM(SIZE(XLBYTHM,1),SIZE(XLBYTHM,2),SIZE(XLBYTHM,3)))
ALLOCATE(XCOEFLIN_LBXU(SIZE(XLBXUM,1),SIZE(XLBXUM,2),SIZE(XLBXUM,3)))
ALLOCATE( NKLIN_LBXU(SIZE(XLBXUM,1),SIZE(XLBXUM,2),SIZE(XLBXUM,3)))
ALLOCATE(XCOEFLIN_LBYU(SIZE(XLBYUM,1),SIZE(XLBYUM,2),SIZE(XLBYUM,3)))
ALLOCATE( NKLIN_LBYU(SIZE(XLBYUM,1),SIZE(XLBYUM,2),SIZE(XLBYUM,3)))
ALLOCATE(XCOEFLIN_LBXV(SIZE(XLBXVM,1),SIZE(XLBXVM,2),SIZE(XLBXVM,3)))
ALLOCATE( NKLIN_LBXV(SIZE(XLBXVM,1),SIZE(XLBXVM,2),SIZE(XLBXVM,3)))
ALLOCATE(XCOEFLIN_LBYV(SIZE(XLBYVM,1),SIZE(XLBYVM,2),SIZE(XLBYVM,3)))
ALLOCATE( NKLIN_LBYV(SIZE(XLBYVM,1),SIZE(XLBYVM,2),SIZE(XLBYVM,3)))
ALLOCATE(XCOEFLIN_LBXW(SIZE(XLBXWM,1),SIZE(XLBXWM,2),SIZE(XLBXWM,3)))
ALLOCATE( NKLIN_LBXW(SIZE(XLBXWM,1),SIZE(XLBXWM,2),SIZE(XLBXWM,3)))
ALLOCATE(XCOEFLIN_LBYW(SIZE(XLBYWM,1),SIZE(XLBYWM,2),SIZE(XLBYWM,3)))
ALLOCATE( NKLIN_LBYW(SIZE(XLBYWM,1),SIZE(XLBYWM,2),SIZE(XLBYWM,3)))
END IF
!
! allocation of the LS fields for vertical relaxation and numerical diffusion
IF( .NOT. LSTEADYLS ) THEN
!
ALLOCATE(XLSUS(SIZE(XLSUM,1),SIZE(XLSUM,2),SIZE(XLSUM,3)))
ALLOCATE(XLSVS(SIZE(XLSVM,1),SIZE(XLSVM,2),SIZE(XLSVM,3)))
ALLOCATE(XLSWS(SIZE(XLSWM,1),SIZE(XLSWM,2),SIZE(XLSWM,3)))
ALLOCATE(XLSTHS(SIZE(XLSTHM,1),SIZE(XLSTHM,2),SIZE(XLSTHM,3)))
ALLOCATE(XLSRVS(SIZE(XLSRVM,1),SIZE(XLSRVM,2),SIZE(XLSRVM,3)))
!
ELSE
!
ALLOCATE(XLSUS(0,0,0))
ALLOCATE(XLSVS(0,0,0))
ALLOCATE(XLSWS(0,0,0))
ALLOCATE(XLSTHS(0,0,0))
ALLOCATE(XLSRVS(0,0,0))!
END IF
! allocation of the LB fields for horizontal relaxation and Lateral Boundaries
IF( .NOT. ( LSTEADYLS .AND. KMI==1 ) ) THEN
!
ALLOCATE(XLBXTKES(SIZE(XLBXTKEM,1),SIZE(XLBXTKEM,2),SIZE(XLBXTKEM,3)))
ALLOCATE(XLBYTKES(SIZE(XLBYTKEM,1),SIZE(XLBYTKEM,2),SIZE(XLBYTKEM,3)))
ALLOCATE(XLBXUS(SIZE(XLBXUM,1),SIZE(XLBXUM,2),SIZE(XLBXUM,3)))
ALLOCATE(XLBYUS(SIZE(XLBYUM,1),SIZE(XLBYUM,2),SIZE(XLBYUM,3)))
ALLOCATE(XLBXVS(SIZE(XLBXVM,1),SIZE(XLBXVM,2),SIZE(XLBXVM,3)))
ALLOCATE(XLBYVS(SIZE(XLBYVM,1),SIZE(XLBYVM,2),SIZE(XLBYVM,3)))
ALLOCATE(XLBXWS(SIZE(XLBXWM,1),SIZE(XLBXWM,2),SIZE(XLBXWM,3)))
ALLOCATE(XLBYWS(SIZE(XLBYWM,1),SIZE(XLBYWM,2),SIZE(XLBYWM,3)))
ALLOCATE(XLBXTHS(SIZE(XLBXTHM,1),SIZE(XLBXTHM,2),SIZE(XLBXTHM,3)))
ALLOCATE(XLBYTHS(SIZE(XLBYTHM,1),SIZE(XLBYTHM,2),SIZE(XLBYTHM,3)))
ALLOCATE(XLBXRS(SIZE(XLBXRM,1),SIZE(XLBXRM,2),SIZE(XLBXRM,3),SIZE(XLBXRM,4)))
ALLOCATE(XLBYRS(SIZE(XLBYRM,1),SIZE(XLBYRM,2),SIZE(XLBYRM,3),SIZE(XLBYRM,4)))
ALLOCATE(XLBXSVS(SIZE(XLBXSVM,1),SIZE(XLBXSVM,2),SIZE(XLBXSVM,3),SIZE(XLBXSVM,4)))
ALLOCATE(XLBYSVS(SIZE(XLBYSVM,1),SIZE(XLBYSVM,2),SIZE(XLBYSVM,3),SIZE(XLBYSVM,4)))
!
ELSE
!
ALLOCATE(XLBXTKES(0,0,0))
ALLOCATE(XLBYTKES(0,0,0))
ALLOCATE(XLBXUS(0,0,0))
ALLOCATE(XLBYUS(0,0,0))
ALLOCATE(XLBXVS(0,0,0))
ALLOCATE(XLBYVS(0,0,0))
ALLOCATE(XLBXWS(0,0,0))
ALLOCATE(XLBYWS(0,0,0))
ALLOCATE(XLBXTHS(0,0,0))
ALLOCATE(XLBYTHS(0,0,0))
ALLOCATE(XLBXRS(0,0,0,0))
ALLOCATE(XLBYRS(0,0,0,0))
ALLOCATE(XLBXSVS(0,0,0,0))
ALLOCATE(XLBYSVS(0,0,0,0))
!
END IF
!
!
!* 3.7 Module MODD_RADIATIONS_n (except XOZON and XAER)
!
!
NSWB_MNH = 6
ALLOCATE(XSW_BANDS (NSWB_MNH))
ALLOCATE(XZENITH (IIU,IJU))
ALLOCATE(XAZIM (IIU,IJU))
ALLOCATE(XALBUV (IIU,IJU))
ALLOCATE(XDIRSRFSWD(IIU,IJU,NSWB_MNH))
ALLOCATE(XSCAFLASWD(IIU,IJU,NSWB_MNH))
ALLOCATE(XFLALWD (IIU,IJU))
!
IF (CRAD /= 'NONE') THEN
ALLOCATE(XSLOPANG(IIU,IJU))
ALLOCATE(XSLOPAZI(IIU,IJU))
ALLOCATE(XDTHRAD(IIU,IJU,IKU))
ALLOCATE(XDIRFLASWD(IIU,IJU,NSWB_MNH))
ALLOCATE(XDIR_ALB(IIU,IJU,NSWB_MNH))
ALLOCATE(XSCA_ALB(IIU,IJU,NSWB_MNH))
ALLOCATE(XEMIS (IIU,IJU))
ALLOCATE(XTSRAD (IIU,IJU)) ; XTSRAD = 0.0
ALLOCATE(XSEA (IIU,IJU))
ALLOCATE(XZS_XY (IIU,IJU))
ALLOCATE(NCLEARCOL_TM1(IIU,IJU))
ALLOCATE(XSWU(IIU,IJU,IKU))
ALLOCATE(XSWD(IIU,IJU,IKU))
ALLOCATE(XLWU(IIU,IJU,IKU))
ALLOCATE(XLWD(IIU,IJU,IKU))
ALLOCATE(XDTHRADSW(IIU,IJU,IKU))
ALLOCATE(XDTHRADLW(IIU,IJU,IKU)) ALLOCATE(XRADEFF(IIU,IJU,IKU))
ELSE
ALLOCATE(XSLOPANG(0,0))
ALLOCATE(XSLOPAZI(0,0))
ALLOCATE(XDTHRAD(0,0,0))
ALLOCATE(XDIRFLASWD(0,0,0))
ALLOCATE(XDIR_ALB(0,0,0))
ALLOCATE(XSCA_ALB(0,0,0))
ALLOCATE(XEMIS (0,0))
ALLOCATE(XTSRAD (0,0))
ALLOCATE(XSEA (0,0))
ALLOCATE(XZS_XY (0,0))
ALLOCATE(NCLEARCOL_TM1(0,0))
ALLOCATE(XSWU(0,0,0))
ALLOCATE(XSWD(0,0,0))
ALLOCATE(XLWU(0,0,0))
ALLOCATE(XLWD(0,0,0))
ALLOCATE(XDTHRADSW(0,0,0))
ALLOCATE(XDTHRADLW(0,0,0))
ALLOCATE(XRADEFF(0,0,0))
END IF
IF (CRAD == 'ECMW') THEN
ALLOCATE(XSTROATM(31,6))
ALLOCATE(XSMLSATM(31,6))
ALLOCATE(XSMLWATM(31,6))
ALLOCATE(XSPOSATM(31,6))
ALLOCATE(XSPOWATM(31,6))
ALLOCATE(XSTATM(31,6))
ELSE
ALLOCATE(XSTROATM(0,0))
ALLOCATE(XSMLSATM(0,0))
ALLOCATE(XSMLWATM(0,0))
ALLOCATE(XSPOSATM(0,0))
ALLOCATE(XSPOWATM(0,0))
ALLOCATE(XSTATM(0,0))
END IF
!
!* 3.8 Module MODD_DEEP_CONVECTION_n
!
IF (CDCONV /= 'NONE' .OR. CSCONV == 'KAFR') THEN
ALLOCATE(NCOUNTCONV(IIU,IJU))
ALLOCATE(XDTHCONV(IIU,IJU,IKU))
ALLOCATE(XDRVCONV(IIU,IJU,IKU))
ALLOCATE(XDRCCONV(IIU,IJU,IKU))
ALLOCATE(XDRICONV(IIU,IJU,IKU))
ALLOCATE(XPRCONV(IIU,IJU))
ALLOCATE(XPACCONV(IIU,IJU))
ALLOCATE(XPRSCONV(IIU,IJU))
! diagnostics
IF (LCH_CONV_LINOX) THEN
ALLOCATE(XIC_RATE(IIU,IJU))
ALLOCATE(XCG_RATE(IIU,IJU))
ALLOCATE(XIC_TOTAL_NUMBER(IIU,IJU))
ALLOCATE(XCG_TOTAL_NUMBER(IIU,IJU))
ELSE
ALLOCATE(XIC_RATE(0,0))
ALLOCATE(XCG_RATE(0,0))
ALLOCATE(XIC_TOTAL_NUMBER(0,0))
ALLOCATE(XCG_TOTAL_NUMBER(0,0))
END IF
IF ( LDIAGCONV ) THEN
ALLOCATE(XUMFCONV(IIU,IJU,IKU))
ALLOCATE(XDMFCONV(IIU,IJU,IKU))
ALLOCATE(XPRLFLXCONV(IIU,IJU,IKU))
ALLOCATE(XPRSFLXCONV(IIU,IJU,IKU))
ALLOCATE(XCAPE(IIU,IJU))
ALLOCATE(NCLTOPCONV(IIU,IJU))
ALLOCATE(NCLBASCONV(IIU,IJU))
ELSE ALLOCATE(XUMFCONV(0,0,0))
ALLOCATE(XDMFCONV(0,0,0))
ALLOCATE(XPRLFLXCONV(0,0,0))
ALLOCATE(XPRSFLXCONV(0,0,0))
ALLOCATE(XCAPE(0,0))
ALLOCATE(NCLTOPCONV(0,0))
ALLOCATE(NCLBASCONV(0,0))
END IF
ELSE
ALLOCATE(XPRCONV(0,0))
ALLOCATE(XPACCONV(0,0))
ALLOCATE(XPRSCONV(0,0))
END IF
!
IF ((CDCONV == 'KAFR' .OR. CSCONV == 'KAFR') &
.AND. LSUBG_COND .AND. LSIG_CONV) THEN
ALLOCATE(XMFCONV(IIU,IJU,IKU))
ELSE
ALLOCATE(XMFCONV(0,0,0))
ENDIF
!
IF ((CDCONV == 'KAFR' .OR. CSCONV == 'KAFR') &
.AND. LCHTRANS .AND. NSV > 0 ) THEN
ALLOCATE(XDSVCONV(IIU,IJU,IKU,NSV))
ELSE
ALLOCATE(XDSVCONV(0,0,0,0))
END IF
!
ALLOCATE(XCF_MF(IIU,IJU,IKU)) ; XCF_MF=0.0
ALLOCATE(XRC_MF(IIU,IJU,IKU)) ; XRC_MF=0.0
ALLOCATE(XRI_MF(IIU,IJU,IKU)) ; XRI_MF=0.0
!
!* 3.9 Local variables
!
ALLOCATE(ZJ(IIU,IJU,IKU))
!
!* 3.10 Forcing variables (Module MODD_FRC)
!
IF (KMI == 1) THEN
IF ( LFORCING ) THEN
ALLOCATE(TDTFRC(NFRC))
ALLOCATE(XUFRC(IKU,NFRC))
ALLOCATE(XVFRC(IKU,NFRC))
ALLOCATE(XWFRC(IKU,NFRC))
ALLOCATE(XTHFRC(IKU,NFRC))
ALLOCATE(XRVFRC(IKU,NFRC))
ALLOCATE(XTENDTHFRC(IKU,NFRC))
ALLOCATE(XTENDRVFRC(IKU,NFRC))
ALLOCATE(XGXTHFRC(IKU,NFRC))
ALLOCATE(XGYTHFRC(IKU,NFRC))
ALLOCATE(XPGROUNDFRC(NFRC))
ALLOCATE(XTENDUFRC(IKU,NFRC))
ALLOCATE(XTENDVFRC(IKU,NFRC))
ELSE
ALLOCATE(TDTFRC(0))
ALLOCATE(XUFRC(0,0))
ALLOCATE(XVFRC(0,0))
ALLOCATE(XWFRC(0,0))
ALLOCATE(XTHFRC(0,0))
ALLOCATE(XRVFRC(0,0))
ALLOCATE(XTENDTHFRC(0,0))
ALLOCATE(XTENDRVFRC(0,0))
ALLOCATE(XGXTHFRC(0,0))
ALLOCATE(XGYTHFRC(0,0))
ALLOCATE(XPGROUNDFRC(0))
ALLOCATE(XTENDUFRC(0,0))
ALLOCATE(XTENDVFRC(0,0))
END IF
IF ( LFORCING ) THEN
ALLOCATE(XWTFRC(IIU,IJU,IKU)) ALLOCATE(XUFRC_PAST(IIU,IJU,IKU)) ; XUFRC_PAST = XUNDEF
ALLOCATE(XVFRC_PAST(IIU,IJU,IKU)) ; XVFRC_PAST = XUNDEF
ELSE
ALLOCATE(XWTFRC(0,0,0))
ALLOCATE(XUFRC_PAST(0,0,0))
ALLOCATE(XVFRC_PAST(0,0,0))
END IF
END IF
! ----------------------------------------------------------------------
!
IF (L2D_ADV_FRC) THEN
WRITE(ILUOUT,*) 'L2D_ADV_FRC IS SET TO', L2D_ADV_FRC
WRITE(ILUOUT,*) 'ADV FRC WILL BE SET'
ALLOCATE(TDTADVFRC(NADVFRC))
ALLOCATE(XDTHFRC(IIU,IJU,IKU,NADVFRC)) ; XDTHFRC=0.
ALLOCATE(XDRVFRC(IIU,IJU,IKU,NADVFRC)) ; XDRVFRC=0.
ELSE
ALLOCATE(TDTADVFRC(0))
ALLOCATE(XDTHFRC(0,0,0,0))
ALLOCATE(XDRVFRC(0,0,0,0))
ENDIF
IF (L2D_REL_FRC) THEN
WRITE(ILUOUT,*) 'L2D_REL_FRC IS SET TO', L2D_REL_FRC
WRITE(ILUOUT,*) 'REL FRC WILL BE SET'
ALLOCATE(TDTRELFRC(NRELFRC))
ALLOCATE(XTHREL(IIU,IJU,IKU,NRELFRC)) ; XTHREL=0.
ALLOCATE(XRVREL(IIU,IJU,IKU,NRELFRC)) ; XRVREL=0.
ELSE
ALLOCATE(TDTRELFRC(0))
ALLOCATE(XTHREL(0,0,0,0))
ALLOCATE(XRVREL(0,0,0,0))
ENDIF
!
!* 4.11 BIS: Eddy fluxes allocation
!
IF ( LTH_FLX ) THEN
ALLOCATE(XVTH_FLUX_M(IIU,IJU,IKU)) ; XVTH_FLUX_M = 0.
ALLOCATE(XWTH_FLUX_M(IIU,IJU,IKU)) ; XWTH_FLUX_M = 0.
IF (KMI /= 1) THEN
ALLOCATE(XRTHS_EDDY_FLUX(IIU,IJU,IKU))
XRTHS_EDDY_FLUX = 0.
ENDIF
ELSE
ALLOCATE(XVTH_FLUX_M(0,0,0)) ; XVTH_FLUX_M = 0.
ALLOCATE(XWTH_FLUX_M(0,0,0)) ; XWTH_FLUX_M = 0.
END IF
!
IF ( LUV_FLX) THEN
ALLOCATE(XVU_FLUX_M(IIU,IJU,IKU)) ; XVU_FLUX_M = 0.
IF (KMI /= 1) THEN
ALLOCATE(XRVS_EDDY_FLUX(IIU,IJU,IKU))
XRVS_EDDY_FLUX = 0.
ENDIF
ELSE
ALLOCATE(XVU_FLUX_M(0,0,0)) ; XVU_FLUX_M = 0.
END IF
!
!* 3.11 Module MODD_ICE_CONC_n
!
IF ( (CCLOUD == 'ICE3'.OR.CCLOUD == 'ICE4') .AND. &
(CPROGRAM == 'DIAG '.OR.CPROGRAM == 'MESONH')) THEN
ALLOCATE(XCIT(IIU,IJU,IKU))
ELSE
ALLOCATE(XCIT(0,0,0))
END IF
!
IF ( CCLOUD == 'KHKO' .OR. CCLOUD == 'C2R2') THEN
ALLOCATE(XSUPSAT(IIU,IJU,IKU))
ALLOCATE(XNACT(IIU,IJU,IKU)) ALLOCATE(XNPRO(IIU,IJU,IKU))
ALLOCATE(XSSPRO(IIU,IJU,IKU))
END IF
!
!* 3.12 Module MODD_TURB_CLOUD
!
IF (.NOT.(ALLOCATED(XCEI))) ALLOCATE(XCEI(0,0,0))
IF (KMI == NMODEL_CLOUD .AND. CTURBLEN_CLOUD/='NONE' ) THEN
DEALLOCATE(XCEI)
ALLOCATE(XCEI(IIU,IJU,IKU))
ENDIF
!
!* 3.13 Module MODD_CH_PH_n
!
IF (LUSECHAQ.AND.(CPROGRAM == 'DIAG '.OR.CPROGRAM == 'MESONH')) THEN
IF (LCH_PH) THEN
ALLOCATE(XPHC(IIU,IJU,IKU))
IF (NRRL==2) THEN
ALLOCATE(XPHR(IIU,IJU,IKU))
ALLOCATE(XACPHR(IIU,IJU))
XACPHR(:,:) = 0.
ENDIF
ENDIF
IF (NRRL==2) THEN
ALLOCATE(XACPRAQ(IIU,IJU,NSV_CHAC/2))
XACPRAQ(:,:,:) = 0.
ENDIF
ENDIF
IF ((LUSECHEM).AND.(CPROGRAM == 'DIAG ')) THEN
ALLOCATE(XCHFLX(IIU,IJU,NSV_CHEM))
XCHFLX(:,:,:) = 0.
END IF
!
!-------------------------------------------------------------------------------
!
!* 4. INITIALIZE BUDGET VARIABLES
! ---------------------------
!
IF ( CBUTYPE /= "NONE" .AND. NBUMOD == KMI ) THEN
CALL INI_BUDGET(ILUOUT,XTSTEP,NSV,NRR, &
LNUMDIFU,LNUMDIFTH,LNUMDIFSV, &
LHORELAX_UVWTH,LHORELAX_RV, LHORELAX_RC,LHORELAX_RR, &
LHORELAX_RI,LHORELAX_RS,LHORELAX_RG, LHORELAX_RH,LHORELAX_TKE, &
LHORELAX_SV,LVE_RELAX,LCHTRANS,LNUDGING,LDRAGTREE,LDEPOTREE, &
CRAD,CDCONV,CSCONV,CTURB,CTURBDIM,CCLOUD )
END IF
!
!-------------------------------------------------------------------------------
!
!
!* 5. INITIALIZE INTERPOLATION COEFFICIENTS
!
CALL INI_BIKHARDT_n (NDXRATIO_ALL(KMI),NDYRATIO_ALL(KMI),KMI)
!
!-------------------------------------------------------------------------------
!
!* 6. BUILT THE GENERIC OUTPUT NAME
! ----------------------------
!
IF (KMI == 1) THEN
DO IMI = 1 , NMODEL
WRITE(IO_SURF_MNH_MODEL(IMI)%COUTFILE,'(A,".",I1,".",A)') CEXP,IMI,TRIM(ADJUSTL(CSEG))
WRITE(YNAME, '(A,".",I1,".",A)') CEXP,IMI,TRIM(ADJUSTL(CSEG))//'.000'
CALL IO_FILE_ADD2LIST(LUNIT_MODEL(IMI)%TDIAFILE,YNAME,'DIACHRONIC','WRITE', &
KLFINPRAR=INT(50,KIND=LFI_INT),KLFITYPE=1,KLFIVERB=NVERB, &
TPDADFILE=LUNIT_MODEL(NDAD(IMI))%TDIAFILE )
END DO
!
TDIAFILE => LUNIT_MODEL(KMI)%TDIAFILE !Necessary because no call to GOTO_MODEL before needing it
! IF (CPROGRAM=='MESONH') THEN
IF ( NDAD(KMI) == 1) CDAD_NAME(KMI) = CEXP//'.1.'//CSEG
IF ( NDAD(KMI) == 2) CDAD_NAME(KMI) = CEXP//'.2.'//CSEG
IF ( NDAD(KMI) == 3) CDAD_NAME(KMI) = CEXP//'.3.'//CSEG
IF ( NDAD(KMI) == 4) CDAD_NAME(KMI) = CEXP//'.4.'//CSEG
IF ( NDAD(KMI) == 5) CDAD_NAME(KMI) = CEXP//'.5.'//CSEG
IF ( NDAD(KMI) == 6) CDAD_NAME(KMI) = CEXP//'.6.'//CSEG
IF ( NDAD(KMI) == 7) CDAD_NAME(KMI) = CEXP//'.7.'//CSEG
IF ( NDAD(KMI) == 8) CDAD_NAME(KMI) = CEXP//'.8.'//CSEG
END IF
END IF
!
!-------------------------------------------------------------------------------
!
!* 7. INITIALIZE GRIDS AND METRIC COEFFICIENTS
! ----------------------------------------
!
CALL SET_GRID(KMI,TPINIFILE,IIU,IJU,IKU,NIMAX_ll,NJMAX_ll, &
XBMX1,XBMX2,XBMX3,XBMX4,XBMY1,XBMY2,XBMY3,XBMY4, &
XBFX1,XBFX2,XBFX3,XBFX4,XBFY1,XBFY2,XBFY3,XBFY4, &
NXOR_ALL(KMI),NYOR_ALL(KMI),NXEND_ALL(KMI),NYEND_ALL(KMI), &
NDXRATIO_ALL(KMI),NDYRATIO_ALL(KMI), &
CLBCX,CLBCY, &
XTSTEP,XSEGLEN, &
XLONORI,XLATORI,XLON,XLAT, &
XXHAT,XYHAT,XDXHAT,XDYHAT, XMAP, &
XZS,XZZ,XZHAT,XZTOP,LSLEVE,XLEN1,XLEN2,XZSMT, &
ZJ, &
TDTMOD,TDTCUR,NSTOP,NBAK_NUMB,NOUT_NUMB,TBACKUPN,TOUTPUTN)
!
CALL METRICS(XMAP,XDXHAT,XDYHAT,XZZ,XDXX,XDYY,XDZX,XDZY,XDZZ)
!
!* update halos of metric coefficients
!
!
CALL UPDATE_METRICS(CLBCX,CLBCY,XDXX,XDYY,XDZX,XDZY,XDZZ)
!
!
CALL SET_DIRCOS(CLBCX,CLBCY,XDXX,XDYY,XDZX,XDZY,TZINITHALO2D_ll, &
XDIRCOSXW,XDIRCOSYW,XDIRCOSZW,XCOSSLOPE,XSINSLOPE )
!
! grid nesting initializations
IF ( KMI == 1 ) THEN
XTSTEP_MODEL1=XTSTEP
END IF
!
NDT_2_WAY(KMI)=4
!
!-------------------------------------------------------------------------------
!
!* 8. INITIALIZE DATA FOR JVALUES AND AEROSOLS
!
IF ( LUSECHEM .OR. LCHEMDIAG ) THEN
IF ((KMI==1).AND.(CPROGRAM == "MESONH".OR.CPROGRAM == "DIAG ")) &
CALL CH_INIT_JVALUES(TDTCUR%TDATE%DAY, TDTCUR%TDATE%MONTH, &
TDTCUR%TDATE%YEAR, ILUOUT, XCH_TUV_DOBNEW)
!
IF (LORILAM) THEN
CALL CH_AER_MOD_INIT
ELSE
IF (.NOT.(ASSOCIATED(XSOLORG))) ALLOCATE(XSOLORG(0,0,0,0))
IF (.NOT.(ASSOCIATED(XMI))) ALLOCATE(XMI(0,0,0,0))
ENDIF
ELSE
IF (.NOT.(ASSOCIATED(XMI))) ALLOCATE(XMI(0,0,0,0))
IF (.NOT.(ASSOCIATED(XSOLORG))) ALLOCATE(XSOLORG(0,0,0,0))
END IF
!
IF (CCLOUD=='LIMA') CALL INIT_AEROSOL_PROPERTIES
!!-------------------------------------------------------------------------------
!
!* 9. INITIALIZE THE PROGNOSTIC FIELDS
! --------------------------------
!
CALL MPPDB_CHECK3D(XUT,"INI_MODEL_N-before read_field::XUT",PRECISION)
CALL READ_FIELD(TPINIFILE,IMASDEV, IIU,IJU,IKU,XTSTEP, &
CGETTKET,CGETRVT,CGETRCT,CGETRRT,CGETRIT,CGETCIT, &
CGETRST,CGETRGT,CGETRHT,CGETSVT,CGETSRCT,CGETSIGS,CGETCLDFR, &
CGETBL_DEPTH,CGETSBL_DEPTH,CGETPHC,CGETPHR,CUVW_ADV_SCHEME, &
CTEMP_SCHEME,NSIZELBX_ll,NSIZELBXU_ll,NSIZELBY_ll,NSIZELBYV_ll,&
NSIZELBXTKE_ll,NSIZELBYTKE_ll, &
NSIZELBXR_ll,NSIZELBYR_ll,NSIZELBXSV_ll,NSIZELBYSV_ll, &
XUM,XVM,XWM,XDUM,XDVM,XDWM, &
XUT,XVT,XWT,XTHT,XPABST,XPABSM,XTKET,XRTKEMS, &
XRT,XSVT,XCIT,XDRYMASST, &
XSIGS,XSRCT,XCLDFR,XBL_DEPTH,XSBL_DEPTH,XWTHVMF,XPHC,XPHR, &
XLSUM,XLSVM,XLSWM,XLSTHM,XLSRVM, &
XLBXUM,XLBXVM,XLBXWM,XLBXTHM,XLBXTKEM, &
XLBXRM,XLBXSVM, &
XLBYUM,XLBYVM,XLBYWM,XLBYTHM,XLBYTKEM, &
XLBYRM,XLBYSVM, &
NFRC,TDTFRC,XUFRC,XVFRC,XWFRC,XTHFRC,XRVFRC, &
XTENDTHFRC,XTENDRVFRC,XGXTHFRC,XGYTHFRC, &
XPGROUNDFRC, XATC, &
XTENDUFRC, XTENDVFRC, &
NADVFRC,TDTADVFRC,XDTHFRC,XDRVFRC, &
NRELFRC,TDTRELFRC,XTHREL,XRVREL, &
XVTH_FLUX_M,XWTH_FLUX_M,XVU_FLUX_M, &
XRUS_PRES,XRVS_PRES,XRWS_PRES,XRTHS_CLD,XRRS_CLD,XRSVS_CLD )
!
!-------------------------------------------------------------------------------
!
!
!* 10. INITIALIZE REFERENCE STATE
! ---------------------------
!
!
CALL SET_REF(KMI,TPINIFILE, &
XZZ,XZHAT,ZJ,XDXX,XDYY,CLBCX,CLBCY, &
XREFMASS,XMASS_O_PHI0,XLINMASS, &
XRHODREF,XTHVREF,XRVREF,XEXNREF,XRHODJ )
!
!-------------------------------------------------------------------------------
!
!* 10.1 INITIALIZE THE TURBULENCE VARIABLES
! -----------------------------------
!
IF ((CTURB == 'TKEL').AND.(CCONF=='START')) THEN
CALL MPPDB_CHECK3D(XUT,"INI_MODEL_N-before ini_tke_eps::XUT",PRECISION)
CALL INI_TKE_EPS(CGETTKET,XTHVREF,XZZ, &
XUT,XVT,XTHT, &
XTKET,TZINITHALO3D_ll )
CALL MPPDB_CHECK3D(XUT,"INI_MODEL_N-after ini_tke_eps::XUT",PRECISION)
END IF
!
!
!* 10.2 INITIALIZE THE LES VARIABLES
! ----------------------------
!
CALL INI_LES_n
!
!-------------------------------------------------------------------------------
!
!* 11. INITIALIZE THE SOURCE OF TOTAL DRY MASS Md
! ------------------------------------------
!
IF((KMI==1).AND.LSTEADYLS) THEN
XDRYMASSS = 0.
END IF!
!-------------------------------------------------------------------------------
!
!* 12. INITIALIZE THE MICROPHYSICS
! ----------------------------
!
IF (CELEC == 'NONE') THEN
CALL INI_MICRO_n(TPINIFILE,ILUOUT)
!
!-------------------------------------------------------------------------------
!
!* 13. INITIALIZE THE ATMOSPHERIC ELECTRICITY
! --------------------------------------
!
ELSE
CALL INI_ELEC_n(ILUOUT, CELEC, CCLOUD, HLUOUT, TPINIFILE, &
XTSTEP, XZZ, &
XDXX, XDYY, XDZZ, XDZX, XDZY )
!
WRITE (UNIT=ILUOUT,&
FMT='(/,"ELECTRIC VARIABLES ARE BETWEEN INDEX",I2," AND ",I2)')&
NSV_ELECBEG, NSV_ELECEND
!
IF( CGETSVT(NSV_ELECBEG)=='INIT' ) THEN
XSVT(:,:,:,NSV_ELECBEG) = XCION_POS_FW(:,:,:) ! Nb/kg
XSVT(:,:,:,NSV_ELECEND) = XCION_NEG_FW(:,:,:)
!
XSVT(:,:,:,NSV_ELECBEG+1:NSV_ELECEND-1) = 0.0
ELSE ! Convert elec_variables per m3 into elec_variables per kg of air
DO JSV = NSV_ELECBEG, NSV_ELECEND
XSVT(:,:,:,JSV) = XSVT(:,:,:,JSV) / XRHODREF(:,:,:)
ENDDO
END IF
END IF
!
!-------------------------------------------------------------------------------
!
!* 14. INITIALIZE THE LARGE SCALE SOURCES
! ----------------------------------
!
IF ((KMI==1).AND.(.NOT. LSTEADYLS)) THEN
CALL MPPDB_CHECK3D(XUT,"INI_MODEL_N-before ini_cpl::XUT",PRECISION)
CALL INI_CPL(NSTOP,XTSTEP,LSTEADYLS,CCONF, &
CGETTKET, &
CGETRVT,CGETRCT,CGETRRT,CGETRIT, &
CGETRST,CGETRGT,CGETRHT,CGETSVT,LCH_INIT_FIELD, &
NSV,NIMAX_ll,NJMAX_ll, &
NSIZELBX_ll,NSIZELBXU_ll,NSIZELBY_ll,NSIZELBYV_ll, &
NSIZELBXTKE_ll,NSIZELBYTKE_ll, &
NSIZELBXR_ll,NSIZELBYR_ll,NSIZELBXSV_ll,NSIZELBYSV_ll, &
XLSUM,XLSVM,XLSWM,XLSTHM,XLSRVM,XDRYMASST, &
XLBXUM,XLBXVM,XLBXWM,XLBXTHM,XLBXTKEM,XLBXRM,XLBXSVM, &
XLBYUM,XLBYVM,XLBYWM,XLBYTHM,XLBYTKEM,XLBYRM,XLBYSVM, &
XLSUS,XLSVS,XLSWS,XLSTHS,XLSRVS,XDRYMASSS, &
XLBXUS,XLBXVS,XLBXWS,XLBXTHS,XLBXTKES,XLBXRS,XLBXSVS, &
XLBYUS,XLBYVS,XLBYWS,XLBYTHS,XLBYTKES,XLBYRS,XLBYSVS )
CALL MPPDB_CHECK3D(XUT,"INI_MODEL_N-after ini_cpl::XUT",PRECISION)
!
DO JSV=NSV_CHEMBEG,NSV_CHEMEND
XLBXSVS(:,:,:,JSV)=MAX(XLBXSVS(:,:,:,JSV),0.)
XLBYSVS(:,:,:,JSV)=MAX(XLBYSVS(:,:,:,JSV),0.)
ENDDO
!
DO JSV=NSV_LNOXBEG,NSV_LNOXEND
XLBXSVS(:,:,:,JSV)=MAX(XLBXSVS(:,:,:,JSV),0.)
XLBYSVS(:,:,:,JSV)=MAX(XLBYSVS(:,:,:,JSV),0.)
ENDDO
!
DO JSV=NSV_AERBEG,NSV_AEREND
XLBXSVS(:,:,:,JSV)=MAX(XLBXSVS(:,:,:,JSV),0.) XLBYSVS(:,:,:,JSV)=MAX(XLBYSVS(:,:,:,JSV),0.)
ENDDO
!
DO JSV=NSV_DSTBEG,NSV_DSTEND
XLBXSVS(:,:,:,JSV)=MAX(XLBXSVS(:,:,:,JSV),0.)
XLBYSVS(:,:,:,JSV)=MAX(XLBYSVS(:,:,:,JSV),0.)
ENDDO
!
DO JSV=NSV_DSTDEPBEG,NSV_DSTDEPEND
XLBXSVS(:,:,:,JSV)=MAX(XLBXSVS(:,:,:,JSV),0.)
XLBYSVS(:,:,:,JSV)=MAX(XLBYSVS(:,:,:,JSV),0.)
ENDDO
!
DO JSV=NSV_SLTBEG,NSV_SLTEND
XLBXSVS(:,:,:,JSV)=MAX(XLBXSVS(:,:,:,JSV),0.)
XLBYSVS(:,:,:,JSV)=MAX(XLBYSVS(:,:,:,JSV),0.)
ENDDO
!
DO JSV=NSV_SLTDEPBEG,NSV_SLTDEPEND
XLBXSVS(:,:,:,JSV)=MAX(XLBXSVS(:,:,:,JSV),0.)
XLBYSVS(:,:,:,JSV)=MAX(XLBYSVS(:,:,:,JSV),0.)
ENDDO
!
DO JSV=NSV_PPBEG,NSV_PPEND
XLBXSVS(:,:,:,JSV)=MAX(XLBXSVS(:,:,:,JSV),0.)
XLBYSVS(:,:,:,JSV)=MAX(XLBYSVS(:,:,:,JSV),0.)
ENDDO
!
#ifdef MNH_FOREFIRE
DO JSV=NSV_FFBEG,NSV_FFEND
XLBXSVS(:,:,:,JSV)=MAX(XLBXSVS(:,:,:,JSV),0.)
XLBYSVS(:,:,:,JSV)=MAX(XLBYSVS(:,:,:,JSV),0.)
ENDDO
!
#endif
DO JSV=NSV_CSBEG,NSV_CSEND
XLBXSVS(:,:,:,JSV)=MAX(XLBXSVS(:,:,:,JSV),0.)
XLBYSVS(:,:,:,JSV)=MAX(XLBYSVS(:,:,:,JSV),0.)
ENDDO
!
END IF
!
IF ( KMI > 1) THEN
! Use dummy pointers to correct an ifort BUG
DPTR_XBMX1=>XBMX1
DPTR_XBMX2=>XBMX2
DPTR_XBMX3=>XBMX3
DPTR_XBMX4=>XBMX4
DPTR_XBMY1=>XBMY1
DPTR_XBMY2=>XBMY2
DPTR_XBMY3=>XBMY3
DPTR_XBMY4=>XBMY4
DPTR_XBFX1=>XBFX1
DPTR_XBFX2=>XBFX2
DPTR_XBFX3=>XBFX3
DPTR_XBFX4=>XBFX4
DPTR_XBFY1=>XBFY1
DPTR_XBFY2=>XBFY2
DPTR_XBFY3=>XBFY3
DPTR_XBFY4=>XBFY4
DPTR_CLBCX=>CLBCX
DPTR_CLBCY=>CLBCY
!
DPTR_XZZ=>XZZ
DPTR_XZHAT=>XZHAT
DPTR_XLSUM=>XLSUM
DPTR_XLSVM=>XLSVM
DPTR_XLSWM=>XLSWM
DPTR_XLSTHM=>XLSTHM
DPTR_XLSRVM=>XLSRVM DPTR_XLSUS=>XLSUS
DPTR_XLSVS=>XLSVS
DPTR_XLSWS=>XLSWS
DPTR_XLSTHS=>XLSTHS
DPTR_XLSRVS=>XLSRVS
!
DPTR_NKLIN_LBXU=>NKLIN_LBXU
DPTR_XCOEFLIN_LBXU=>XCOEFLIN_LBXU
DPTR_NKLIN_LBYU=>NKLIN_LBYU
DPTR_XCOEFLIN_LBYU=>XCOEFLIN_LBYU
DPTR_NKLIN_LBXV=>NKLIN_LBXV
DPTR_XCOEFLIN_LBXV=>XCOEFLIN_LBXV
DPTR_NKLIN_LBYV=>NKLIN_LBYV
DPTR_XCOEFLIN_LBYV=>XCOEFLIN_LBYV
DPTR_NKLIN_LBXW=>NKLIN_LBXW
DPTR_XCOEFLIN_LBXW=>XCOEFLIN_LBXW
DPTR_NKLIN_LBYW=>NKLIN_LBYW
DPTR_XCOEFLIN_LBYW=>XCOEFLIN_LBYW
DPTR_NKLIN_LBXM=>NKLIN_LBXM
DPTR_XCOEFLIN_LBXM=>XCOEFLIN_LBXM
DPTR_NKLIN_LBYM=>NKLIN_LBYM
DPTR_XCOEFLIN_LBYM=>XCOEFLIN_LBYM
!
CALL INI_SPAWN_LS_n(NDAD(KMI),XTSTEP,KMI, &
DPTR_XBMX1,DPTR_XBMX2,DPTR_XBMX3,DPTR_XBMX4,DPTR_XBMY1,DPTR_XBMY2,DPTR_XBMY3,DPTR_XBMY4, &
DPTR_XBFX1,DPTR_XBFX2,DPTR_XBFX3,DPTR_XBFX4,DPTR_XBFY1,DPTR_XBFY2,DPTR_XBFY3,DPTR_XBFY4, &
NDXRATIO_ALL(KMI),NDYRATIO_ALL(KMI), &
DPTR_CLBCX,DPTR_CLBCY,DPTR_XZZ,DPTR_XZHAT, &
LSLEVE,XLEN1,XLEN2, &
DPTR_XLSUM,DPTR_XLSVM,DPTR_XLSWM,DPTR_XLSTHM,DPTR_XLSRVM, &
DPTR_XLSUS,DPTR_XLSVS,DPTR_XLSWS,DPTR_XLSTHS,DPTR_XLSRVS, &
DPTR_NKLIN_LBXU,DPTR_XCOEFLIN_LBXU,DPTR_NKLIN_LBYU,DPTR_XCOEFLIN_LBYU, &
DPTR_NKLIN_LBXV,DPTR_XCOEFLIN_LBXV,DPTR_NKLIN_LBYV,DPTR_XCOEFLIN_LBYV, &
DPTR_NKLIN_LBXW,DPTR_XCOEFLIN_LBXW,DPTR_NKLIN_LBYW,DPTR_XCOEFLIN_LBYW, &
DPTR_NKLIN_LBXM,DPTR_XCOEFLIN_LBXM,DPTR_NKLIN_LBYM,DPTR_XCOEFLIN_LBYM )
!
DPTR_XLBXUM=>XLBXUM
DPTR_XLBYUM=>XLBYUM
DPTR_XLBXVM=>XLBXVM
DPTR_XLBYVM=>XLBYVM
DPTR_XLBXWM=>XLBXWM
DPTR_XLBYWM=>XLBYWM
DPTR_XLBXTHM=>XLBXTHM
DPTR_XLBYTHM=>XLBYTHM
DPTR_XLBXTKEM=>XLBXTKEM
DPTR_XLBYTKEM=>XLBYTKEM
DPTR_XLBXRM=>XLBXRM
DPTR_XLBYRM=>XLBYRM
DPTR_XLBXSVM=>XLBXSVM
DPTR_XLBYSVM=>XLBYSVM
CALL INI_ONE_WAY_n(NDAD(KMI),CLUOUT,XTSTEP,KMI,1, &
DPTR_XBMX1,DPTR_XBMX2,DPTR_XBMX3,DPTR_XBMX4,DPTR_XBMY1,DPTR_XBMY2,DPTR_XBMY3,DPTR_XBMY4, &
DPTR_XBFX1,DPTR_XBFX2,DPTR_XBFX3,DPTR_XBFX4,DPTR_XBFY1,DPTR_XBFY2,DPTR_XBFY3,DPTR_XBFY4, &
NDXRATIO_ALL(KMI),NDYRATIO_ALL(KMI),NDTRATIO(KMI), &
DPTR_CLBCX,DPTR_CLBCY,NRIMX,NRIMY, &
DPTR_NKLIN_LBXU,DPTR_XCOEFLIN_LBXU,DPTR_NKLIN_LBYU,DPTR_XCOEFLIN_LBYU, &
DPTR_NKLIN_LBXV,DPTR_XCOEFLIN_LBXV,DPTR_NKLIN_LBYV,DPTR_XCOEFLIN_LBYV, &
DPTR_NKLIN_LBXW,DPTR_XCOEFLIN_LBXW,DPTR_NKLIN_LBYW,DPTR_XCOEFLIN_LBYW, &
DPTR_NKLIN_LBXM,DPTR_XCOEFLIN_LBXM,DPTR_NKLIN_LBYM,DPTR_XCOEFLIN_LBYM, &
CCLOUD, LUSECHAQ, LUSECHIC, &
DPTR_XLBXUM,DPTR_XLBYUM,DPTR_XLBXVM,DPTR_XLBYVM,DPTR_XLBXWM,DPTR_XLBYWM, &
DPTR_XLBXTHM,DPTR_XLBYTHM, &
DPTR_XLBXTKEM,DPTR_XLBYTKEM, &
DPTR_XLBXRM,DPTR_XLBYRM,DPTR_XLBXSVM,DPTR_XLBYSVM )
END IF
!
!
!-------------------------------------------------------------------------------
!
!* 15. INITIALIZE THE SCALAR VARIABLES! -------------------------------
!
IF (LLG .AND. LINIT_LG .AND. CPROGRAM=='MESONH') &
CALL INI_LG(XXHAT,XYHAT,XZZ,XSVT,XLBXSVM,XLBYSVM)
!
!-------------------------------------------------------------------------------
!
!* 16. INITIALIZE THE PARAMETERS FOR THE DYNAMICS
! ------------------------------------------
!
CALL INI_DYNAMICS(XLON,XLAT,XRHODJ,XTHVREF,XMAP,XZZ,XDXHAT,XDYHAT, &
XZHAT,CLBCX,CLBCY,XTSTEP, &
LVE_RELAX,LVE_RELAX_GRD,LHORELAX_UVWTH,LHORELAX_RV, &
LHORELAX_RC,LHORELAX_RR,LHORELAX_RI,LHORELAX_RS,LHORELAX_RG, &
LHORELAX_RH,LHORELAX_TKE,LHORELAX_SV, &
LHORELAX_SVC2R2,LHORELAX_SVC1R3,LHORELAX_SVELEC,LHORELAX_SVLG, &
LHORELAX_SVCHEM,LHORELAX_SVAER,LHORELAX_SVDST,LHORELAX_SVSLT, &
LHORELAX_SVPP,LHORELAX_SVCS,LHORELAX_SVCHIC, &
#ifdef MNH_FOREFIRE
LHORELAX_SVFF, &
#endif
XRIMKMAX,NRIMX,NRIMY, &
XALKTOP,XALKGRD,XALZBOT,XALZBAS, &
XT4DIFU,XT4DIFTH,XT4DIFSV, &
XCORIOX,XCORIOY,XCORIOZ,XCURVX,XCURVY, &
XDXHATM,XDYHATM,XRHOM,XAF,XBFY,XCF,XTRIGSX,XTRIGSY,NIFAXX,NIFAXY,&
XALK,XALKW,NALBOT,XALKBAS,XALKWBAS,NALBAS, &
LMASK_RELAX,XKURELAX,XKVRELAX,XKWRELAX, &
XDK2U,XDK4U,XDK2TH,XDK4TH,XDK2SV,XDK4SV, &
LZDIFFU,XZDIFFU_HALO2, &
XBFB,XBF_SXP2_YP1_Z )
!
!-------------------------------------------------------------------------------
!
!* 17. SURFACE FIELDS
! --------------
!
!* 17.1 Radiative setup
! ---------------
!
IF (CRAD /= 'NONE') THEN
IF (CGETRAD =='INIT') THEN
GINIRAD =.TRUE.
ELSE
GINIRAD =.FALSE.
END IF
CALL INI_RADIATIONS(TPINIFILE,HLUOUT,GINIRAD,TDTCUR,TDTEXP,XZZ, &
XDXX, XDYY, &
XSINDEL,XCOSDEL,XTSIDER,XCORSOL, &
XSLOPANG,XSLOPAZI, &
XDTHRAD,XDIRFLASWD,XSCAFLASWD, &
XFLALWD,XDIRSRFSWD,NCLEARCOL_TM1, &
XZENITH,XAZIM, &
TDTRAD_FULL,TDTRAD_CLONLY, &
TZINITHALO2D_ll, &
XRADEFF,XSWU,XSWD,XLWU, &
XLWD,XDTHRADSW,XDTHRADLW )
!
IF (GINIRAD) CALL SUNPOS_n(XZENITH,PAZIMSOL=XAZIM)
CALL SURF_SOLAR_GEOM (XZS, XZS_XY)
!
ALLOCATE(XXHAT_ll (IIU_ll))
ALLOCATE(XYHAT_ll (IJU_ll))
ALLOCATE(XZS_ll (IIU_ll,IJU_ll))
ALLOCATE(XZS_XY_ll (IIU_ll,IJU_ll))
!
CALL GATHERALL_FIELD_ll('XY',XZS,XZS_ll,IRESP)
CALL GATHERALL_FIELD_ll('XY',XZS_XY,XZS_XY_ll,IRESP)
CALL GATHERALL_FIELD_ll('XX',XXHAT,XXHAT_ll,IRESP) CALL GATHERALL_FIELD_ll('YY',XYHAT,XYHAT_ll,IRESP)
XZS_MAX_ll=MAXVAL(XZS_ll)
ELSE
XAZIM = XPI
XZENITH = XPI/2.
XDIRSRFSWD = 0.
XSCAFLASWD = 0.
XFLALWD = 300. ! W/m2
XTSIDER = 0.
END IF
!
!
CALL INI_SW_SETUP (CRAD,NSWB_MNH,XSW_BANDS)
!
!
! 17.1.1 Special initialisation for CO2 content
! CO2 (molar mass=44) horizontally and vertically homogeneous at 360 ppm
!
XCCO2 = 360.0E-06 * 44.0E-03 / XMD
!
!
!* 17.2 Externalized surface fields
! ---------------------------
!
ALLOCATE(ZCO2(IIU,IJU))
ZCO2(:,:) = XCCO2
!
ALLOCATE(ZDIR_ALB(IIU,IJU,NSWB_MNH))
ALLOCATE(ZSCA_ALB(IIU,IJU,NSWB_MNH))
ALLOCATE(ZEMIS (IIU,IJU))
ALLOCATE(ZTSRAD (IIU,IJU))
!
IF (IMASDEV>=46) THEN
CALL IO_READ_FIELD(TPINIFILE,'SURF',CSURF)
ELSE
CSURF = "EXTE"
END IF
!
!
IF (CSURF=='EXTE' .AND. (CPROGRAM=='MESONH' .OR. CPROGRAM=='DIAG ')) THEN
! ouverture du fichier PGD
IF ( LEN_TRIM(CINIFILEPGD) > 0 ) THEN
CALL IO_FILE_ADD2LIST(TINIFILEPGD,TRIM(CINIFILEPGD),'UNKNOWN','READ',KLFITYPE=2,KLFIVERB=NVERB)
CALL IO_FILE_OPEN_ll(TINIFILEPGD,OPARALLELIO=.FALSE.,KRESP=IRESP)
LUNIT_MODEL(KMI)%TINIFILEPGD => TINIFILEPGD
IF (IRESP/=0) THEN
WRITE(ILUOUT,FMT=*) "INI_MODEL_n ERROR TO OPEN THE FILE CINIFILEPGD=",CINIFILEPGD
WRITE(ILUOUT,FMT=*) "CHECK YOUR NAMELIST NAM_LUNITn"
!callabortstop
CALL PRINT_MSG(NVERB_FATAL,'GEN','INI_MODEL_n','')
ENDIF
ELSE
! case after a spawning
CINIFILEPGD = TPINIFILE%CNAME
END IF
!
CALL GOTO_SURFEX(KMI)
!* initialization of surface
CALL INIT_GROUND_PARAM_n ('ALL',SIZE(CSV),CSV,ZCO2, &
XZENITH,XAZIM,XSW_BANDS,ZDIR_ALB,ZSCA_ALB, &
ZEMIS,ZTSRAD )
!
IF (SIZE(XEMIS)>0) THEN
XDIR_ALB = ZDIR_ALB
XSCA_ALB = ZSCA_ALB
XEMIS = ZEMIS
XTSRAD = ZTSRAD
CALL MNHGET_SURF_PARAM_n (PSEA=XSEA)
END IFELSE
!* fields not physically necessary, but must be initialized
IF (SIZE(XEMIS)>0) THEN
XDIR_ALB = 0.
XSCA_ALB = 0.
XEMIS = 1.
XTSRAD = XTT
XSEA = 1.
END IF
END IF
IF (CSURF=='EXTE' .AND. (CPROGRAM=='SPAWN ')) THEN
! ouverture du fichier PGD
CALL IO_FILE_ADD2LIST(TINIFILEPGD,TRIM(CINIFILEPGD),'UNKNOWN','READ',KLFITYPE=2,KLFIVERB=NVERB)
CALL IO_FILE_OPEN_ll(TINIFILEPGD,OPARALLELIO=.FALSE.,KRESP=IRESP)
LUNIT_MODEL(KMI)%TINIFILEPGD => TINIFILEPGD
IF (IRESP/=0) THEN
WRITE(ILUOUT,FMT=*) "INI_MODEL_n ERROR TO OPEN THE FILE CINIFILEPGD=",CINIFILEPGD
WRITE(ILUOUT,FMT=*) "CHECK YOUR NAMELIST NAM_LUNIT2_SPA"
!callabortstop
CALL PRINT_MSG(NVERB_FATAL,'GEN','INI_MODEL_n','')
ENDIF
ENDIF
!
!* special case after spawning in prep_real_case
IF (CSURF=='EXRM' .AND. CPROGRAM=='REAL ') CSURF = 'EXTE'
!
DEALLOCATE(ZDIR_ALB)
DEALLOCATE(ZSCA_ALB)
DEALLOCATE(ZEMIS )
DEALLOCATE(ZTSRAD )
!
DEALLOCATE(ZCO2)
!
!
!* in a RESTART case, reads surface radiative quantities in the MESONH file
!
IF (CRAD == 'ECMW' .AND. CGETRAD=='READ') THEN
CALL INI_SURF_RAD(TPINIFILE, XDIR_ALB, XSCA_ALB, XEMIS, XTSRAD)
END IF
!
!
!* 17.3 Mesonh fields
! -------------
!
IF (CPROGRAM/='REAL ') CALL MNHREAD_ZS_DUMMY_n(TINIFILEPGD)
!
!-------------------------------------------------------------------------------
!
!* 18. INITIALIZE THE PARAMETERS FOR THE PHYSICS
! -----------------------------------------
!
IF (CRAD == 'ECMW') THEN
!
!* get cover mask for aerosols
!
IF (CPROGRAM=='MESONH' .OR. CPROGRAM=='DIAG ') THEN
ALLOCATE(ZSEA(IIU,IJU))
ALLOCATE(ZTOWN(IIU,IJU))
ALLOCATE(ZBARE(IIU,IJU))
IF (CSURF=='EXTE') THEN
CALL GOTO_SURFEX(KMI)
CALL MNHGET_SURF_PARAM_n(PSEA=ZSEA,PTOWN=ZTOWN,PBARE=ZBARE)
ELSE
ZSEA (:,:) = 1.
ZTOWN(:,:) = 0.
ZBARE(:,:) = 0.
END IF
!
CALL INI_RADIATIONS_ECMWF (TPINIFILE%CNAME,HLUOUT, &
XZHAT,XPABST,XTHT,XTSRAD,XLAT,XLON,TDTCUR,TDTEXP, & CLW,NDLON,NFLEV,NFLUX,NRAD,NSWB,CAER,NAER,NSTATM, &
XSTATM,ZSEA,ZTOWN,ZBARE,XOZON, XAER,XDST_WL, LSUBG_COND )
!
DEALLOCATE(ZSEA,ZTOWN,ZBARE)
ALLOCATE (XAER_CLIM(SIZE(XAER,1),SIZE(XAER,2),SIZE(XAER,3),SIZE(XAER,4)))
XAER_CLIM(:,:,:,:) =XAER(:,:,:,:)
!
END IF
ELSE
ALLOCATE (XOZON(0,0,0))
ALLOCATE (XAER(0,0,0,0))
ALLOCATE (XDST_WL(0,0,0,0))
ALLOCATE (XAER_CLIM(0,0,0,0))
END IF
!
!
!
IF (CDCONV /= 'NONE' .OR. CSCONV == 'KAFR') THEN
IF (CGETCONV=='INIT') THEN
GINIDCONV=.TRUE.
ELSE
GINIDCONV=.FALSE.
END IF
!
! commensurability between convection calling time and time step
!
XDTCONV=XTSTEP*REAL( INT( (MIN(XDTCONV,1800.)+1.E-10)/XTSTEP ) )
XDTCONV=MAX( XDTCONV, XTSTEP )
IF (NVERB>=10) THEN
WRITE(ILUOUT,*) 'XDTCONV has been set to : ',XDTCONV
END IF
CALL INI_DEEP_CONVECTION (TPINIFILE,HLUOUT,GINIDCONV,TDTCUR, &
NCOUNTCONV,XDTHCONV,XDRVCONV,XDRCCONV, &
XDRICONV,XPRCONV,XPRSCONV,XPACCONV, &
XUMFCONV,XDMFCONV,XMFCONV,XPRLFLXCONV,XPRSFLXCONV,&
XCAPE,NCLTOPCONV,NCLBASCONV, &
TDTDCONV, CGETSVCONV, XDSVCONV, &
LCH_CONV_LINOX, XIC_RATE, XCG_RATE, &
XIC_TOTAL_NUMBER, XCG_TOTAL_NUMBER )
END IF
!
!-------------------------------------------------------------------------------
!
!
!* 19. ALLOCATION OF THE TEMPORAL SERIES
! ---------------------------------
!
IF (LSERIES .AND. CPROGRAM/='DIAG ') CALL INI_SERIES_n
!
!-------------------------------------------------------------------------------
!
!
!* 20. (re)initialize scalar variables
! -------------------------------
!
!
IF ( LUSECHEM .OR. LCHEMDIAG ) THEN
IF (CPROGRAM=='MESONH'.AND.CCONF=='RESTA') LCH_INIT_FIELD =.FALSE.
IF (CPROGRAM=='MESONH'.OR. CPROGRAM=='DIAG ' .OR. CPROGRAM=='IDEAL ') &
CALL CH_INIT_FIELD_n(KMI, ILUOUT, NVERB)
END IF
!
!-------------------------------------------------------------------------------
!
!* 21. UPDATE HALO
! -----------
!
!
CALL UPDATE_HALO_ll(TZINITHALO3D_ll,IINFO_ll)CALL UPDATE_HALO_ll(TZINITHALO2D_ll,IINFO_ll)
CALL CLEANLIST_ll(TZINITHALO3D_ll)
CALL CLEANLIST_ll(TZINITHALO2D_ll)
!
!
!-------------------------------------------------------------------------------
!
!* 22. DEALLOCATION
! -------------
!
DEALLOCATE(ZJ)
!
DEALLOCATE(XSTROATM)
DEALLOCATE(XSMLSATM)
DEALLOCATE(XSMLWATM)
DEALLOCATE(XSPOSATM)
DEALLOCATE(XSPOWATM)
!
!-------------------------------------------------------------------------------
!
!* 23. BALLOON and AIRCRAFT initializations
! ------------------------------------
!
CALL INI_AIRCRAFT_BALLOON(TPINIFILE,XTSTEP, TDTSEG, XSEGLEN, NRR, NSV, &
IKU,CTURB=="TKEL" , &
XLATORI, XLONORI )
!
!-------------------------------------------------------------------------------
!
!* 24. STATION initializations
! -----------------------
!
CALL INI_SURFSTATION_n(XTSTEP, TDTSEG, XSEGLEN, NRR, NSV, &
CTURB=="TKEL" , &
XLATORI, XLONORI )
!
!-------------------------------------------------------------------------------
!
!* 25. PROFILER initializations
! ------------------------
!
CALL INI_POSPROFILER_n(XTSTEP, TDTSEG, XSEGLEN, NRR, NSV, &
CTURB=="TKEL", &
XLATORI, XLONORI )
!
!-------------------------------------------------------------------------------
!
!* 26. Prognostic aerosols
! ------------------------
!
CALL INI_AEROSET1
CALL INI_AEROSET2
CALL INI_AEROSET3
CALL INI_AEROSET4
CALL INI_AEROSET5
CALL INI_AEROSET6
#ifdef MNH_FOREFIRE
!
!-------------------------------------------------------------------------------
!
!* 27. FOREFIRE initializations
! ------------------------
!
! Coupling with ForeFire if resolution is low enough
!---------------------------------------------------
IF ( LFOREFIRE .AND. 0.5*(XXHAT(2)-XXHAT(1)+XYHAT(2)-XYHAT(1)) < COUPLINGRES ) THEN
FFCOUPLING = .TRUE.
ELSE
FFCOUPLING = .FALSE.ENDIF
! Initializing the ForeFire variables
!------------------------------------
IF ( LFOREFIRE ) THEN
CALL INIT_FOREFIRE_n(KMI, ILUOUT, IP &
, TDTCUR%TDATE%YEAR, TDTCUR%TDATE%MONTH, TDTCUR%TDATE%DAY, TDTCUR%TIME, XTSTEP)
END IF
#endif
!-------------------------------------------------------------------------------
!
!* 30. Total production/Loss for chemical species
!
IF (LCHEMDIAG) THEN
CALL CH_INIT_PRODLOSSTOT_n(ILUOUT)
IF (NEQ_PLT>0) THEN
ALLOCATE(XPROD(IIU,IJU,IKU,NEQ_PLT))
ALLOCATE(XLOSS(IIU,IJU,IKU,NEQ_PLT))
XPROD=0.0
XLOSS=0.0
ELSE
ALLOCATE(XPROD(0,0,0,0))
ALLOCATE(XLOSS(0,0,0,0))
END IF
ELSE
ALLOCATE(XPROD(0,0,0,0))
ALLOCATE(XLOSS(0,0,0,0))
END IF
!
!-------------------------------------------------------------------------------
!
!* 31. Extended production/loss terms for chemical species
!
IF (LCHEMDIAG) THEN
CALL CH_INIT_BUDGET_n(ILUOUT)
IF (NEQ_BUDGET>0) THEN
ALLOCATE(IINDEX(2,NNONZEROTERMS))
ALLOCATE(IIND(NEQ_BUDGET))
CALL CH_NONZEROTERMS(KMI,IINDEX,NNONZEROTERMS)
ALLOCATE(XTCHEM(NEQ_BUDGET))
DO JM=1,NEQ_BUDGET
IIND(JM)=COUNT((IINDEX(1,:))==NSPEC_BUDGET(JM))
ALLOCATE(XTCHEM(JM)%NB_REAC(IIND(JM)))
ALLOCATE(XTCHEM(JM)%XB_REAC(IIU,IJU,IKU,IIND(JM)))
END DO
DEALLOCATE(IIND)
DEALLOCATE(IINDEX)
ELSE
ALLOCATE(XTCHEM(0))
END IF
ELSE
ALLOCATE(XTCHEM(0))
END IF
END SUBROUTINE INI_MODEL_n