!MNH_LIC Copyright 1995-2021 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.
!-----------------------------------------------------------------
! ######spl
SUBROUTINE RAIN_ICE ( D, CST, PARAMI, ICEP, ICED, BUCONF, &
KPROMA, KSIZE, &
OSEDIC, OCND2, HSEDIM, HSUBG_AUCV_RC, HSUBG_AUCV_RI, &
OWARM, &
PTSTEP, KRR, ODMICRO, PEXN, &
PDZZ, PRHODJ, PRHODREF, PEXNREF, PPABST, PCIT, PCLDFR,&
PHLC_HRC, PHLC_HCF, PHLI_HRI, PHLI_HCF, &
PTHT, PRVT, PRCT, PRRT, PRIT, PRST, &
PRGT, PTHS, PRVS, PRCS, PRRS, PRIS, PRSS, PRGS, &
PINPRC, PINPRR, PEVAP3D, &
PINPRS, PINPRG, PINDEP, PRAINFR, PSIGS, &
TBUDGETS, KBUDGETS, &
PSEA, PTOWN, &
PRHT, PRHS, PINPRH, PFPR )
! ######################################################################
!
!!**** * - compute the explicit microphysical sources
!!
!! PURPOSE
!! -------
!! The purpose of this routine is to compute the slow microphysical sources
!! which can be computed explicitly
!!
!!
!!** METHOD
!! ------
!! The autoconversion computation follows Kessler (1969).
!! The sedimentation rate is computed with a time spliting technique and
!! an upstream scheme, written as a difference of non-advective fluxes. This
!! source term is added to the future instant ( split-implicit process ).
!! The others microphysical processes are evaluated at the central instant
!! (split-explicit process ): autoconversion, accretion and rain evaporation.
!! These last 3 terms are bounded in order not to create negative values
!! for the water species at the future instant.
!!
!! EXTERNAL
!! --------
!! None
!!
!!
!! IMPLICIT ARGUMENTS
!! ------------------
!! Module MODD_PARAMETERS
!! JPHEXT : Horizontal external points number
!! JPVEXT : Vertical external points number
!! Module MODD_CONF :
!! CCONF configuration of the model for the first time step
!! Module MODD_CST
!! XP00 ! Reference pressure
!! XRD,XRV ! Gaz constant for dry air, vapor
!! XMD,XMV ! Molecular weight for dry air, vapor
!! XCPD ! Cpd (dry air)
!! XCL ! Cl (liquid)
!! XCI ! Ci (solid)
!! XTT ! Triple point temperature
!! XLVTT ! Vaporization heat constant
!! XALPW,XBETAW,XGAMW ! Constants for saturation vapor pressure
!! function over liquid water
!! XALPI,XBETAI,XGAMI ! Constants for saturation vapor pressure
!! function over solid ice
!! Module MODD_BUDGET:
!! NBUMOD : model in which budget is calculated
!! CBUTYPE : type of desired budget
!! 'CART' for cartesian box configuration
!! 'MASK' for budget zone defined by a mask
!! 'NONE' ' for no budget
!! LBU_RTH : logical for budget of RTH (potential temperature)
!! .TRUE. = budget of RTH
!! .FALSE. = no budget of RTH
!! LBU_RRV : logical for budget of RRV (water vapor)
!! .TRUE. = budget of RRV
!! .FALSE. = no budget of RRV
!! LBU_RRC : logical for budget of RRC (cloud water)
!! .TRUE. = budget of RRC
!! .FALSE. = no budget of RRC
!! LBU_RRI : logical for budget of RRI (cloud ice)
!! .TRUE. = budget of RRI
!! .FALSE. = no budget of RRI
!! LBU_RRR : logical for budget of RRR (rain water)
!! .TRUE. = budget of RRR
!! .FALSE. = no budget of RRR
!! LBU_RRS : logical for budget of RRS (aggregates)
!! .TRUE. = budget of RRS
!! .FALSE. = no budget of RRS
!! LBU_RRG : logical for budget of RRG (graupeln)
!! .TRUE. = budget of RRG
!! .FALSE. = no budget of RRG
!!
!! REFERENCE
!! ---------
!!
!! Book1 and Book2 of documentation ( routine RAIN_ICE )
!!
!! AUTHOR
!! ------
!! J.-P. Pinty * Laboratoire d'Aerologie*
!!
!! MODIFICATIONS
!! -------------
!! Original 02/11/95
!! (J.Viviand) 04/02/97 debug accumulated prcipitation & convert
!! precipitation rate in m/s
!! (J.-P. Pinty) 17/02/97 add budget calls
!! (J.-P. Pinty) 17/11/97 set ice sedim. for cirrus ice, reset RCHONI
!! and RRHONG, reverse order for DEALLOCATE
!! (J.-P. Pinty) 11/02/98 correction of the air dynamical viscosity and
!! add advance of the budget calls
!! (J.-P. Pinty) 18/05/98 correction of the air density in the RIAUTS
!! process
!! (J.-P. Pinty) 18/11/98 split the main routine
!! (V. Masson) 18/11/98 bug in IVEC1 and IVEC2 upper limits
!! (J. Escobar & J.-P. Pinty)
!! 11/12/98 contains and rewrite count+pack
!! (J. Stein & J.-P. Pinty)
!! 14/10/99 correction for very small RIT
!! (J. Escobar & J.-P. Pinty)
!! 24/07/00 correction for very samll m.r. in
!! the sedimentation subroutine
!! (M. Tomasini) 11/05/01 Autoconversion of rc into rr modification to take
!! into account the subgrid variance
!! (cf Redelsperger & Sommeria JAS 86)
!! (G. Molinie) 21/05/99 bug in RRCFRIG process, RHODREF**(-1) missing
!! in RSRIMCG
!! (G. Molinie & J.-P. Pinty)
!! 21/06/99 bug in RACCS process
!! (P. Jabouille) 27/05/04 safety test for case where esw/i(T)> pabs (~Z>40km)
!! (J-.P. Chaboureau) 12/02/05 temperature depending ice-to-snow autocon-
! version threshold (Chaboureau and Pinty GRL 2006)
!! (J.-P. Pinty) 01/01/O1 add the hail category and correction of the
!! wet growth rate of the graupeln
!! (S.Remy & C.Lac) 06/06 Add the cloud sedimentation
!! (S.Remy & C.Lac) 06/06 Sedimentation becoming the last process
!! to settle the precipitating species created during the current time step
!! (S.Remy & C.Lac) 06/06 Modification of the algorithm of sedimentation
!! to settle n times the precipitating species created during Dt/n instead
!! of Dt
!! (C.Lac) 11/06 Optimization of the sedimentation loop for NEC
!! (J.Escobar) 18/01/2008 Parallel Bug in Budget when IMICRO >= 1
!! --> Path inhibit this test by IMICRO >= 0 allway true
!! (Y.Seity) 03/2008 Add Statistic sedimentation
!! (Y.Seity) 10/2009 Added condition for the raindrop accretion of the aggregates
!! into graupeln process (5.2.6) to avoid negative graupel mixing ratio
!! (V.Masson, C.Lac) 09/2010 Correction in split sedimentation for
!! reproducibility
!! (S. Riette) Oct 2010 Better vectorisation of RAIN_ICE_SEDIMENTATION_STAT
!! (Y. Seity), 02-2012 add possibility to run with reversed vertical levels
!! (L. Bengtsson), 02-2013 Passing in land/sea mask and town fraction in
!! order to use different cloud droplet number conc. over
!! land, sea and urban areas in the cloud sedimentation.
!! (D. Degrauwe), 2013-11: Export upper-air precipitation fluxes PFPR.
!! (S. Riette) Nov 2013 Protection against null sigma
!! (C. Lac) FIT temporal scheme : instant M removed
!! (JP Pinty), 01-2014 : ICE4 : partial reconversion of hail to graupel
!! July, 2015 (O.Nuissier/F.Duffourg) Add microphysics diagnostic for
!! aircraft, ballon and profiler
!! J.Escobar : 15/09/2015 : WENO5 & JPHEXT <> 1
!! C.Lac : 10/2016 : add droplet deposition
!! C.Lac : 01/2017 : correction on droplet deposition
!! J.Escobar : 10/2017 : for real*4 , limit exp() in RAIN_ICE_SLOW with XMNH_HUGE_12_LOG
!! (C. Abiven, Y. Léauté, V. Seigner, S. Riette) Phasing of Turner rain subgrid param
!! (S. Riette) Source code split into several files
!! 02/2019 C.Lac add rain fraction as an output field
! P. Wautelet 10/04/2019: replace ABORT and STOP calls by Print_msg
! P. Wautelet 28/05/2019: move COUNTJV function to tools.f90
! P. Wautelet 29/05/2019: remove PACK/UNPACK intrinsics (to get more performance and better OpenACC support)
! P. Wautelet 17/01/2020: move Quicksort to tools.f90
! P. Wautelet 02/2020: use the new data structures and subroutines for budgets
! P. Wautelet 25/02/2020: bugfix: add missing budget: WETH_BU_RRG
!! R. El Khatib 24-Aug-2021 Optimizations
! J. Wurtz 03/2022: New snow characteristics with LSNOW_T
!-----------------------------------------------------------------
!
!* 0. DECLARATIONS
! ------------
!
USE PARKIND1, ONLY : JPRB
USE YOMHOOK , ONLY : LHOOK, DR_HOOK
USE MODD_DIMPHYEX, ONLY: DIMPHYEX_t
USE MODD_BUDGET, ONLY: TBUDGETDATA, TBUDGETCONF_t, NBUDGET_TH, NBUDGET_RV, NBUDGET_RC, &
NBUDGET_RI, NBUDGET_RR, NBUDGET_RS, NBUDGET_RG, NBUDGET_RH
USE MODD_CST, ONLY: CST_t
USE MODD_PARAM_ICE, ONLY: PARAM_ICE_t
USE MODD_RAIN_ICE_DESCR, ONLY: RAIN_ICE_DESCR_t
USE MODD_RAIN_ICE_PARAM, ONLY: RAIN_ICE_PARAM_t
USE MODD_FIELDS_ADDRESS, ONLY : & ! common fields adress
& ITH, & ! Potential temperature
& IRV, & ! Water vapor
& IRC, & ! Cloud water
& IRR, & ! Rain water
& IRI, & ! Pristine ice
& IRS, & ! Snow/aggregate
& IRG, & ! Graupel
& IRH ! Hail
USE MODE_BUDGET, ONLY: BUDGET_STORE_ADD_PHY, BUDGET_STORE_INIT_PHY, BUDGET_STORE_END_PHY
USE MODE_MSG, ONLY: PRINT_MSG, NVERB_FATAL
USE MODE_ICE4_RAINFR_VERT, ONLY: ICE4_RAINFR_VERT
USE MODE_ICE4_SEDIMENTATION_STAT, ONLY: ICE4_SEDIMENTATION_STAT
USE MODE_ICE4_SEDIMENTATION_SPLIT, ONLY: ICE4_SEDIMENTATION_SPLIT
USE MODE_ICE4_SEDIMENTATION_SPLIT_MOMENTUM, ONLY: ICE4_SEDIMENTATION_SPLIT_MOMENTUM
USE MODE_ICE4_TENDENCIES, ONLY: ICE4_TENDENCIES
USE MODE_ICE4_NUCLEATION, ONLY: ICE4_NUCLEATION
!
IMPLICIT NONE
!
!* 0.1 Declarations of dummy arguments :
!
!
!
TYPE(DIMPHYEX_t), INTENT(IN) :: D
TYPE(CST_t), INTENT(IN) :: CST
TYPE(PARAM_ICE_t), INTENT(IN) :: PARAMI
TYPE(RAIN_ICE_PARAM_t), INTENT(IN) :: ICEP
TYPE(RAIN_ICE_DESCR_t), INTENT(IN) :: ICED
TYPE(TBUDGETCONF_t), INTENT(IN) :: BUCONF
INTEGER, INTENT(IN) :: KPROMA ! cache-blocking factor for microphysic loop
INTEGER, INTENT(IN) :: KSIZE
LOGICAL, INTENT(IN) :: OSEDIC ! Switch for droplet sedim.
LOGICAL :: OCND2 ! Logical switch to separate liquid and ice
CHARACTER(LEN=4), INTENT(IN) :: HSEDIM ! Sedimentation scheme
CHARACTER(LEN=4), INTENT(IN) :: HSUBG_AUCV_RC ! Kind of Subgrid autoconversion method
CHARACTER(LEN=80), INTENT(IN) :: HSUBG_AUCV_RI ! Kind of Subgrid autoconversion method
LOGICAL, INTENT(IN) :: OWARM ! .TRUE. allows raindrops to
! form by warm processes
! (Kessler scheme)
REAL, INTENT(IN) :: PTSTEP ! Double Time step (single if cold start)
INTEGER, INTENT(IN) :: KRR ! Number of moist variable
LOGICAL, DIMENSION(D%NIJT,D%NKT), INTENT(IN) :: ODMICRO ! mask to limit computation
!
REAL, DIMENSION(D%NIJT,D%NKT), INTENT(IN) :: PEXN ! Exner function
REAL, DIMENSION(D%NIJT,D%NKT), INTENT(IN) :: PDZZ ! Layer thikness (m)
REAL, DIMENSION(D%NIJT,D%NKT), INTENT(IN) :: PRHODJ ! Dry density * Jacobian
REAL, DIMENSION(D%NIJT,D%NKT), INTENT(IN) :: PRHODREF! Reference density
REAL, DIMENSION(D%NIJT,D%NKT), INTENT(IN) :: PEXNREF ! Reference Exner function
REAL, DIMENSION(D%NIJT,D%NKT), INTENT(IN) :: PPABST ! absolute pressure at t
!
REAL, DIMENSION(D%NIJT,D%NKT), INTENT(INOUT) :: PCIT ! Pristine ice n.c. at t
REAL, DIMENSION(D%NIJT,D%NKT), INTENT(IN) :: PCLDFR ! Cloud fraction
REAL, DIMENSION(D%NIJT,D%NKT), INTENT(IN) :: PHLC_HRC
REAL, DIMENSION(D%NIJT,D%NKT), INTENT(IN) :: PHLC_HCF
REAL, DIMENSION(D%NIJT,D%NKT), INTENT(IN) :: PHLI_HRI
REAL, DIMENSION(D%NIJT,D%NKT), INTENT(IN) :: PHLI_HCF
REAL, DIMENSION(D%NIJT,D%NKT), INTENT(IN) :: PTHT ! Theta at time t
REAL, DIMENSION(D%NIJT,D%NKT), INTENT(IN) :: PRVT ! Water vapor m.r. at t
REAL, DIMENSION(D%NIJT,D%NKT), INTENT(IN) :: PRCT ! Cloud water m.r. at t
REAL, DIMENSION(D%NIJT,D%NKT), INTENT(IN) :: PRRT ! Rain water m.r. at t
REAL, DIMENSION(D%NIJT,D%NKT), INTENT(IN) :: PRIT ! Pristine ice m.r. at t
REAL, DIMENSION(D%NIJT,D%NKT), INTENT(IN) :: PRST ! Snow/aggregate m.r. at t
REAL, DIMENSION(D%NIJT,D%NKT), INTENT(IN) :: PRGT ! Graupel/hail m.r. at t
!
REAL, DIMENSION(D%NIJT,D%NKT), INTENT(INOUT) :: PTHS ! Theta source
REAL, DIMENSION(D%NIJT,D%NKT), INTENT(INOUT) :: PRVS ! Water vapor m.r. source
REAL, DIMENSION(D%NIJT,D%NKT), INTENT(INOUT) :: PRCS ! Cloud water m.r. source
REAL, DIMENSION(D%NIJT,D%NKT), INTENT(INOUT) :: PRRS ! Rain water m.r. source
REAL, DIMENSION(D%NIJT,D%NKT), INTENT(INOUT) :: PRIS ! Pristine ice m.r. source
REAL, DIMENSION(D%NIJT,D%NKT), INTENT(INOUT) :: PRSS ! Snow/aggregate m.r. source
REAL, DIMENSION(D%NIJT,D%NKT), INTENT(INOUT) :: PRGS ! Graupel m.r. source
!
REAL, DIMENSION(D%NIJT), INTENT(OUT) :: PINPRC! Cloud instant precip
REAL, DIMENSION(D%NIJT), INTENT(OUT) :: PINPRR! Rain instant precip
REAL, DIMENSION(D%NIJT,D%NKT), INTENT(OUT) :: PEVAP3D! Rain evap profile
REAL, DIMENSION(D%NIJT), INTENT(OUT) :: PINPRS! Snow instant precip
REAL, DIMENSION(D%NIJT), INTENT(OUT) :: PINPRG! Graupel instant precip
REAL, DIMENSION(MERGE(D%NIJT, 0, PARAMI%LDEPOSC)), INTENT(OUT) :: PINDEP ! Cloud instant deposition
REAL, DIMENSION(D%NIJT,D%NKT), INTENT(OUT) :: PRAINFR !Precipitation fraction
REAL, DIMENSION(D%NIJT,D%NKT), INTENT(IN) :: PSIGS ! Sigma_s at t
TYPE(TBUDGETDATA), DIMENSION(KBUDGETS), INTENT(INOUT) :: TBUDGETS
INTEGER, INTENT(IN) :: KBUDGETS
REAL, DIMENSION(D%NIJT), OPTIONAL, INTENT(IN) :: PSEA ! Sea Mask
REAL, DIMENSION(D%NIJT), OPTIONAL, INTENT(IN) :: PTOWN! Fraction that is town
REAL, DIMENSION(D%NIJT,D%NKT), OPTIONAL, INTENT(IN) :: PRHT ! Hail m.r. at t
REAL, DIMENSION(D%NIJT,D%NKT), OPTIONAL, INTENT(INOUT) :: PRHS ! Hail m.r. source
REAL, DIMENSION(D%NIJT), OPTIONAL, INTENT(OUT) :: PINPRH! Hail instant precip
REAL, DIMENSION(D%NIJT,D%NKT,KRR), OPTIONAL, INTENT(OUT) :: PFPR ! upper-air precipitation fluxes
!
!
!* 0.2 Declarations of local variables :
!
REAL(KIND=JPRB) :: ZHOOK_HANDLE
!
INTEGER :: JIJ, JK
INTEGER :: ISTIJ, ISTK
!
!Arrays for nucleation call outisde of ODMICRO points
REAL, DIMENSION(D%NIJT, D%NKT) :: ZW ! work array
REAL, DIMENSION(D%NIJT, D%NKT) :: ZT ! Temperature
REAL, DIMENSION(D%NIJT, D%NKT) :: ZZ_RVHENI_MR, & ! heterogeneous nucleation mixing ratio change
& ZZ_RVHENI ! heterogeneous nucleation
REAL, DIMENSION(MERGE(D%NIJT, 0, BUCONF%LBU_ENABLE), &
&MERGE(D%NKT, 0, BUCONF%LBU_ENABLE)) :: ZW1, ZW2, ZW3, ZW4, ZW5, ZW6 !Work arrays
REAL, DIMENSION(D%NIJT, D%NKT) :: ZZ_LVFACT, ZZ_LSFACT, ZZ_DIFF
!
REAL, DIMENSION(D%NIJT,D%NKT) :: ZRCT ! Cloud water m.r. source at t
REAL, DIMENSION(D%NIJT,D%NKT) :: ZRRT ! Rain water m.r. source at t
REAL, DIMENSION(D%NIJT,D%NKT) :: ZRIT ! Pristine ice m.r. source at t
REAL, DIMENSION(D%NIJT,D%NKT) :: ZRST ! Snow/aggregate m.r. source at t
REAL, DIMENSION(D%NIJT,D%NKT) :: ZRGT ! Graupel m.r. source at t
REAL, DIMENSION(D%NIJT,D%NKT) :: ZRHT ! Hail m.r. source at t
REAL, DIMENSION(D%NIJT,D%NKT) :: ZCITOUT ! Output value for CIT
REAL, DIMENSION(D%NIJT,D%NKT) :: ZLBDAS ! Modif !lbda parameter snow
!Diagnostics
REAL, DIMENSION(D%NIJT) :: ZINPRI ! Pristine ice instant precip
!
LOGICAL :: GEXT_TEND
LOGICAL :: LSOFT ! Must we really compute tendencies or only adjust them to new T variables
INTEGER :: INB_ITER_MAX ! Maximum number of iterations (with real tendencies computation)
REAL :: ZW0D
REAL :: ZTSTEP ! length of sub-timestep in case of time splitting
REAL :: ZINV_TSTEP ! Inverse ov PTSTEP
REAL :: ZTIME_THRESHOLD ! Time to reach threshold
!For total tendencies computation
REAL, DIMENSION(D%NIJT,D%NKT,0:7) :: ZWR
!
!Output packed total mixing ratio change (for budgets only)
REAL, DIMENSION(KSIZE) :: ZTOT_RVHENI, & ! heterogeneous nucleation mixing ratio change
& ZTOT_RCHONI, & ! Homogeneous nucleation
& ZTOT_RRHONG, & ! Spontaneous freezing mixing ratio change
& ZTOT_RVDEPS, & ! Deposition on r_s,
& ZTOT_RIAGGS, & ! Aggregation on r_s
& ZTOT_RIAUTS, & ! Autoconversion of r_i for r_s production
& ZTOT_RVDEPG, & ! Deposition on r_g
& ZTOT_RCAUTR, & ! Autoconversion of r_c for r_r production
& ZTOT_RCACCR, & ! Accretion of r_c for r_r production
& ZTOT_RREVAV, & ! Evaporation of r_r
& ZTOT_RCRIMSS, ZTOT_RCRIMSG, ZTOT_RSRIMCG, & ! Cloud droplet riming of the aggregates
& ZTOT_RIMLTC, & ! Cloud ice melting mixing ratio change
& ZTOT_RCBERI, & ! Bergeron-Findeisen effect
& ZTOT_RHMLTR, & ! Melting of the hailstones
& ZTOT_RSMLTG, & ! Conversion-Melting of the aggregates
& ZTOT_RCMLTSR, & ! Cloud droplet collection onto aggregates by positive temperature
& ZTOT_RRACCSS, ZTOT_RRACCSG, ZTOT_RSACCRG, & ! Rain accretion onto the aggregates
& ZTOT_RICFRRG, ZTOT_RRCFRIG, ZTOT_RICFRR, & ! Rain contact freezing
& ZTOT_RCWETG, ZTOT_RIWETG, ZTOT_RRWETG, ZTOT_RSWETG, & ! Graupel wet growth
& ZTOT_RCDRYG, ZTOT_RIDRYG, ZTOT_RRDRYG, ZTOT_RSDRYG, & ! Graupel dry growth
& ZTOT_RWETGH, & ! Conversion of graupel into hail
& ZTOT_RGMLTR, & ! Melting of the graupel
& ZTOT_RCWETH, ZTOT_RIWETH, ZTOT_RSWETH, ZTOT_RGWETH, ZTOT_RRWETH, & ! Dry growth of hailstone
& ZTOT_RCDRYH, ZTOT_RIDRYH, ZTOT_RSDRYH, ZTOT_RRDRYH, ZTOT_RGDRYH, & ! Wet growth of hailstone
& ZTOT_RDRYHG ! Conversion of hailstone into graupel
!
!For packing
INTEGER :: IMICRO ! Case r_x>0 locations
INTEGER :: JL, JV
REAL, DIMENSION(KPROMA) :: ZTIME ! Current integration time (starts with 0 and ends with PTSTEP)
REAL, DIMENSION(KPROMA) :: &
& ZMAXTIME, & ! Time on which we can apply the current tendencies
& ZTIME_LASTCALL, & ! Integration time when last tendecies call has been done
& ZSSI, &
& ZCIT, & ! Pristine ice conc. at t
& ZRHODREF, & ! RHO Dry REFerence
& ZZT, & ! Temperature
& ZPRES, & ! Pressure
& ZEXN, & ! EXNer Pressure
& ZLSFACT, & ! L_s/(Pi*C_ph)
& ZLVFACT, & ! L_v/(Pi*C_ph)
& ZSIGMA_RC,& ! Standard deviation of rc at time t
& ZCF, & ! Cloud fraction
& ZHLC_HCF, & ! HLCLOUDS : fraction of High Cloud Fraction in grid
& ZHLC_LCF, & ! HLCLOUDS : fraction of Low Cloud Fraction in grid
! note that ZCF = ZHLC_HCF + ZHLC_LCF
& ZHLC_HRC, & ! HLCLOUDS : LWC that is High LWC in grid
& ZHLC_LRC, & ! HLCLOUDS : LWC that is Low LWC in grid
! note that ZRC = ZHLC_HRC + ZHLC_LRC
& ZHLI_HCF, &
& ZHLI_LCF, &
& ZHLI_HRI, &
& ZHLI_LRI
LOGICAL, DIMENSION(KPROMA) :: LLCOMPUTE ! .TRUE. or points where we must compute tendencies,
!
!Output packed tendencies (for budgets only)
REAL, DIMENSION(KPROMA) :: ZRVHENI_MR, & ! heterogeneous nucleation mixing ratio change
& ZRCHONI, & ! Homogeneous nucleation
& ZRRHONG_MR, & ! Spontaneous freezing mixing ratio change
& ZRVDEPS, & ! Deposition on r_s,
& ZRIAGGS, & ! Aggregation on r_s
& ZRIAUTS, & ! Autoconversion of r_i for r_s production
& ZRVDEPG, & ! Deposition on r_g
& ZRCAUTR, & ! Autoconversion of r_c for r_r production
& ZRCACCR, & ! Accretion of r_c for r_r production
& ZRREVAV, & ! Evaporation of r_r
& ZRIMLTC_MR, & ! Cloud ice melting mixing ratio change
& ZRCBERI, & ! Bergeron-Findeisen effect
& ZRHMLTR, & ! Melting of the hailstones
& ZRSMLTG, & ! Conversion-Melting of the aggregates
& ZRCMLTSR, & ! Cloud droplet collection onto aggregates by positive temperature
& ZRRACCSS, ZRRACCSG, ZRSACCRG, & ! Rain accretion onto the aggregates
& ZRCRIMSS, ZRCRIMSG, ZRSRIMCG, ZRSRIMCG_MR, & ! Cloud droplet riming of the aggregates
& ZRICFRRG, ZRRCFRIG, ZRICFRR, & ! Rain contact freezing
& ZRCWETG, ZRIWETG, ZRRWETG, ZRSWETG, & ! Graupel wet growth
& ZRCDRYG, ZRIDRYG, ZRRDRYG, ZRSDRYG, & ! Graupel dry growth
& ZRWETGH, & ! Conversion of graupel into hail
& ZRWETGH_MR, & ! Conversion of graupel into hail, mr change
& ZRGMLTR, & ! Melting of the graupel
& ZRCWETH, ZRIWETH, ZRSWETH, ZRGWETH, ZRRWETH, & ! Dry growth of hailstone
& ZRCDRYH, ZRIDRYH, ZRSDRYH, ZRRDRYH, ZRGDRYH, & ! Wet growth of hailstone
& ZRDRYHG ! Conversion of hailstone into graupel
!
!For mixing-ratio-splitting
LOGICAL :: LLCPZ0RT
REAL :: ZTIME_THRESHOLD1D(KPROMA) ! Time to reach threshold
REAL, DIMENSION(KPROMA, KRR) :: Z0RT ! Mixing-ratios at the beginig of the current loop
!
REAL, DIMENSION(KPROMA,0:7) :: &
& ZVART, & !Packed variables
& ZEXTPK, & !To take into acount external tendencies inside the splitting
& ZA, ZB
!
REAL, DIMENSION(KPROMA, 8) :: ZRS_TEND, ZRG_TEND
REAL, DIMENSION(KPROMA,10) :: ZRH_TEND
INTEGER, DIMENSION(KPROMA) :: &
& I1,I2, & ! Used to replace the COUNT and PACK intrinsics on variables
& IITER ! Number of iterations done (with real tendencies computation)
INTEGER, DIMENSION(KSIZE) :: I1TOT, I2TOT ! Used to replace the COUNT and PACK intrinsics
!
REAL, DIMENSION(KPROMA) :: ZSUM2, ZMAXB
REAL :: ZDEVIDE, ZX, ZRICE
!
INTEGER :: IC, JMICRO
LOGICAL :: LLSIGMA_RC, LL_ANY_ITER, LL_AUCV_ADJU
!
REAL, DIMENSION(D%NIJT,D%NKT) :: ZW3D
LOGICAL, DIMENSION(D%NIJT,D%NKT) :: LLW3D
!
!-------------------------------------------------------------------------------
IF (LHOOK) CALL DR_HOOK('RAIN_ICE', 0, ZHOOK_HANDLE)
!
!-------------------------------------------------------------------------------
!
IF(OCND2) THEN
CALL PRINT_MSG(NVERB_FATAL, 'GEN', 'RAIN_ICE', 'OCND2 OPTION NOT CODED IN THIS RAIN_ICE VERSION')
END IF
IF(KPROMA /= KSIZE) THEN
CALL PRINT_MSG(NVERB_FATAL, 'GEN', 'RAIN_ICE', 'For now, KPROMA must be equal to KSIZE, see code for explanation')
! Microphyscs was optimized by introducing chunks of KPROMA size
! Thus, in ice4_tendencies, the 1D array represent only a fraction of the points where microphisical species are present
! We cannot rebuild the entire 3D arrays in the subroutine, so we cannot call ice4_rainfr_vert in it
! A solution would be to suppress optimisation in this case by setting KPROMA=KSIZE in rain_ice
! Another solution would be to compute column by column?
! Another one would be to cut tendencies in 3 parts: before rainfr_vert, rainfr_vert, after rainfr_vert
ENDIF
!
!* 1. COMPUTE THE LOOP BOUNDS
! -----------------------
!
ZINV_TSTEP=1./PTSTEP
GEXT_TEND=.TRUE.
!
! LSFACT and LVFACT without exner
DO JK = D%NKTB,D%NKTE
DO JIJ = D%NIJB,D%NIJE
IF (KRR==7) THEN
ZRICE=PRIT(JIJ,JK)+PRST(JIJ,JK)+PRGT(JIJ,JK)+PRHT(JIJ,JK)
ELSE
ZRICE=PRIT(JIJ,JK)+PRST(JIJ,JK)+PRGT(JIJ,JK)
ENDIF
ZDEVIDE = CST%XCPD + CST%XCPV*PRVT(JIJ,JK) + CST%XCL*(PRCT(JIJ,JK)+PRRT(JIJ,JK)) + CST%XCI*ZRICE
ZT(JIJ,JK) = PTHT(JIJ,JK) * PEXN(JIJ,JK)
ZZ_LSFACT(JIJ,JK)=(CST%XLSTT+(CST%XCPV-CST%XCI)*(ZT(JIJ,JK)-CST%XTT)) / ZDEVIDE
ZZ_LVFACT(JIJ,JK)=(CST%XLVTT+(CST%XCPV-CST%XCL)*(ZT(JIJ,JK)-CST%XTT)) / ZDEVIDE
ENDDO
ENDDO
!
!Compute lambda_snow parameter
!ZT en KELVIN
DO JK = D%NKTB,D%NKTE
DO JIJ = D%NIJB,D%NIJE
ZLBDAS(JIJ,JK)=1000.
END DO
END DO
DO JK = D%NKTB,D%NKTE
DO JIJ = D%NIJB,D%NIJE
IF (PARAMI%LSNOW_T) THEN
IF (PRST(JIJ,JK)>ICED%XRTMIN(5)) THEN
IF(ZT(JIJ,JK)>CST%XTT-10.0) THEN
ZLBDAS(JIJ,JK) = MAX(MIN(ICED%XLBDAS_MAX, 10**(14.554-0.0423*ZT(JIJ,JK))),ICED%XLBDAS_MIN)*ICED%XTRANS_MP_GAMMAS
ELSE
ZLBDAS(JIJ,JK) = MAX(MIN(ICED%XLBDAS_MAX, 10**(6.226-0.0106*ZT(JIJ,JK))),ICED%XLBDAS_MIN)*ICED%XTRANS_MP_GAMMAS
END IF
END IF
#if defined(REPRO48) || defined(REPRO55)
#else
ELSE
IF (PRST(JIJ,JK).GT.ICED%XRTMIN(5)) THEN
ZLBDAS(JIJ,JK) = MAX(MIN(ICED%XLBDAS_MAX,ICED%XLBS*(PRHODREF(JIJ,JK)*PRST(JIJ,JK))**ICED%XLBEXS),ICED%XLBDAS_MIN)
END IF
#endif
END IF
END DO
END DO
!
!-------------------------------------------------------------------------------
!
!* 2. COMPUTE THE SEDIMENTATION (RS) SOURCE
! -------------------------------------
!
IF(.NOT. PARAMI%LSEDIM_AFTER) THEN
!
!* 2.1 sedimentation
!
IF (BUCONF%LBUDGET_RC .AND. OSEDIC) CALL BUDGET_STORE_INIT_PHY(D, TBUDGETS(NBUDGET_RC), 'SEDI', PRCS(:, :) * PRHODJ(:, :))
IF (BUCONF%LBUDGET_RR) CALL BUDGET_STORE_INIT_PHY(D, TBUDGETS(NBUDGET_RR), 'SEDI', PRRS(:, :) * PRHODJ(:, :))
IF (BUCONF%LBUDGET_RI) CALL BUDGET_STORE_INIT_PHY(D, TBUDGETS(NBUDGET_RI), 'SEDI', PRIS(:, :) * PRHODJ(:, :))
IF (BUCONF%LBUDGET_RS) CALL BUDGET_STORE_INIT_PHY(D, TBUDGETS(NBUDGET_RS), 'SEDI', PRSS(:, :) * PRHODJ(:, :))
IF (BUCONF%LBUDGET_RG) CALL BUDGET_STORE_INIT_PHY(D, TBUDGETS(NBUDGET_RG), 'SEDI', PRGS(:, :) * PRHODJ(:, :))
IF (BUCONF%LBUDGET_RH .AND. KRR==7) CALL BUDGET_STORE_INIT_PHY(D, TBUDGETS(NBUDGET_RH), 'SEDI', PRHS(:, :) * PRHODJ(:, :))
IF(HSEDIM=='STAT') THEN
IF(KRR==7) THEN
DO JK = D%NKTB,D%NKTE
DO JIJ = D%NIJB,D%NIJE
ZRCT(JIJ,JK)=PRCS(JIJ,JK)*PTSTEP
ZRRT(JIJ,JK)=PRRS(JIJ,JK)*PTSTEP
ZRIT(JIJ,JK)=PRIS(JIJ,JK)*PTSTEP
ZRST(JIJ,JK)=PRSS(JIJ,JK)*PTSTEP
ZRGT(JIJ,JK)=PRGS(JIJ,JK)*PTSTEP
ZRHT(JIJ,JK)=PRHS(JIJ,JK)*PTSTEP
ENDDO
ENDDO
CALL ICE4_SEDIMENTATION_STAT(D, CST, ICEP, ICED, &
&PTSTEP, KRR, OSEDIC, PDZZ, &
&PRHODREF, PPABST, PTHT, PRHODJ, &
&PRCS, ZRCT, PRRS, ZRRT, PRIS, ZRIT,&
&PRSS, ZRST, PRGS, ZRGT,&
&PINPRC, PINPRR, ZINPRI, PINPRS, PINPRG, &
&PSEA=PSEA, PTOWN=PTOWN, &
&PINPRH=PINPRH, PRHT=ZRHT, PRHS=PRHS, PFPR=PFPR)
ELSE
DO JK = D%NKTB,D%NKTE
DO JIJ = D%NIJB,D%NIJE
ZRCT(JIJ,JK)=PRCS(JIJ,JK)*PTSTEP
ZRRT(JIJ,JK)=PRRS(JIJ,JK)*PTSTEP
ZRIT(JIJ,JK)=PRIS(JIJ,JK)*PTSTEP
ZRST(JIJ,JK)=PRSS(JIJ,JK)*PTSTEP
ZRGT(JIJ,JK)=PRGS(JIJ,JK)*PTSTEP
ENDDO
ENDDO
CALL ICE4_SEDIMENTATION_STAT(D, CST, ICEP, ICED, &
&PTSTEP, KRR, OSEDIC, PDZZ, &
&PRHODREF, PPABST, PTHT, PRHODJ, &
&PRCS, ZRCT, PRRS, ZRRT, PRIS, ZRIT,&
&PRSS, ZRST, PRGS, ZRGT,&
&PINPRC, PINPRR, ZINPRI, PINPRS, PINPRG, &
&PSEA=PSEA, PTOWN=PTOWN, &
&PFPR=PFPR)
ENDIF
PINPRS(D%NIJB:D%NIJE) = PINPRS(D%NIJB:D%NIJE) + ZINPRI(D%NIJB:D%NIJE)
!No negativity correction here as we apply sedimentation on PR.S*PTSTEP variables
ELSEIF(HSEDIM=='SPLI') THEN
IF(KRR==7) THEN
CALL ICE4_SEDIMENTATION_SPLIT(D, CST, ICEP, ICED, PARAMI, &
&PTSTEP, KRR, OSEDIC, PDZZ, &
&PRHODREF, PPABST, PTHT, ZT, PRHODJ, &
&PRCS, PRCT, PRRS, PRRT, PRIS, PRIT, PRSS, PRST, PRGS, PRGT,&
&PINPRC, PINPRR, ZINPRI, PINPRS, PINPRG, &
&PSEA=PSEA, PTOWN=PTOWN, &
&PINPRH=PINPRH, PRHT=PRHT, PRHS=PRHS, PFPR=PFPR)
ELSE
CALL ICE4_SEDIMENTATION_SPLIT(D, CST, ICEP, ICED, PARAMI, &
&PTSTEP, KRR, OSEDIC, PDZZ, &
&PRHODREF, PPABST, PTHT, ZT, PRHODJ, &
&PRCS, PRCT, PRRS, PRRT, PRIS, PRIT, PRSS, PRST, PRGS, PRGT,&
&PINPRC, PINPRR, ZINPRI, PINPRS, PINPRG, &
&PSEA=PSEA, PTOWN=PTOWN, &
&PFPR=PFPR)
ENDIF
PINPRS(D%NIJB:D%NIJE) = PINPRS(D%NIJB:D%NIJE) + ZINPRI(D%NIJB:D%NIJE)
!We correct negativities with conservation
!SPLI algorith uses a time-splitting. Inside the loop a temporary m.r. is used.
! It is initialized with the m.r. at T and is modified by two tendencies:
! sedimentation tendency and an external tendency which represents all other
! processes (mainly advection and microphysical processes). If both tendencies
! are negative, sedimentation can remove a species at a given sub-timestep. From
! this point sedimentation stops for the remaining sub-timesteps but the other tendency
! will be still active and will lead to negative values.
! We could prevent the algorithm to not consume too much a species, instead we apply
! a correction here.
CALL CORRECT_NEGATIVITIES(D, KRR, PRVS, PRCS, PRRS, &
&PRIS, PRSS, PRGS, &
&PTHS, ZZ_LVFACT, ZZ_LSFACT, PRHS)
ELSEIF(HSEDIM=='NONE') THEN
ELSE
CALL PRINT_MSG(NVERB_FATAL, 'GEN', 'RAIN_ICE', 'no sedimentation scheme for HSEDIM='//HSEDIM)
END IF
!!!!! ajouter momentum
!
!* 2.2 budget storage
!
IF (BUCONF%LBUDGET_RC .AND. OSEDIC) CALL BUDGET_STORE_END_PHY(D, TBUDGETS(NBUDGET_RC), 'SEDI', PRCS(:, :) * PRHODJ(:, :))
IF (BUCONF%LBUDGET_RR) CALL BUDGET_STORE_END_PHY(D, TBUDGETS(NBUDGET_RR), 'SEDI', PRRS(:, :) * PRHODJ(:, :))
IF (BUCONF%LBUDGET_RI) CALL BUDGET_STORE_END_PHY(D, TBUDGETS(NBUDGET_RI), 'SEDI', PRIS(:, :) * PRHODJ(:, :))
IF (BUCONF%LBUDGET_RS) CALL BUDGET_STORE_END_PHY(D, TBUDGETS(NBUDGET_RS), 'SEDI', PRSS(:, :) * PRHODJ(:, :))
IF (BUCONF%LBUDGET_RG) CALL BUDGET_STORE_END_PHY(D, TBUDGETS(NBUDGET_RG), 'SEDI', PRGS(:, :) * PRHODJ(:, :))
IF (BUCONF%LBUDGET_RH .AND. KRR==7) CALL BUDGET_STORE_END_PHY(D, TBUDGETS(NBUDGET_RH), 'SEDI', PRHS(:, :) * PRHODJ(:, :))
ENDIF
!
DO JK = D%NKTB,D%NKTE
!Backup of T variables
ZWR(:,JK,IRV)=PRVT(:,JK)
ZWR(:,JK,IRC)=PRCT(:,JK)
ZWR(:,JK,IRR)=PRRT(:,JK)
ZWR(:,JK,IRI)=PRIT(:,JK)
ZWR(:,JK,IRS)=PRST(:,JK)
ZWR(:,JK,IRG)=PRGT(:,JK)
IF (KRR==7) THEN
ZWR(:,JK,IRH)=PRHT(:,JK)
ELSE
ZWR(:,JK,IRH)=0.
ENDIF
!Preset for output 3D variables
IF(OWARM) THEN
PEVAP3D(:,JK)=0.
ENDIF
PRAINFR(:,JK)=0.
#ifdef REPRO55
ZCITOUT(:,JK)=PCIT(:,JK)
#else
ZCITOUT(:,JK)=0. !We want 0 outside of IMICRO points
#endif
ENDDO
IF(BUCONF%LBU_ENABLE) THEN
ZTOT_RVHENI(:)=0.
ZTOT_RCHONI(:)=0.
ZTOT_RRHONG(:)=0.
ZTOT_RVDEPS(:)=0.
ZTOT_RIAGGS(:)=0.
ZTOT_RIAUTS(:)=0.
ZTOT_RVDEPG(:)=0.
ZTOT_RCAUTR(:)=0.
ZTOT_RCACCR(:)=0.
ZTOT_RREVAV(:)=0.
ZTOT_RCRIMSS(:)=0.
ZTOT_RCRIMSG(:)=0.
ZTOT_RSRIMCG(:)=0.
ZTOT_RIMLTC(:)=0.
ZTOT_RCBERI(:)=0.
ZTOT_RHMLTR(:)=0.
ZTOT_RSMLTG(:)=0.
ZTOT_RCMLTSR(:)=0.
ZTOT_RRACCSS(:)=0.
ZTOT_RRACCSG(:)=0.
ZTOT_RSACCRG(:)=0.
ZTOT_RICFRRG(:)=0.
ZTOT_RRCFRIG(:)=0.
ZTOT_RICFRR(:)=0.
ZTOT_RCWETG(:)=0.
ZTOT_RIWETG(:)=0.
ZTOT_RRWETG(:)=0.
ZTOT_RSWETG(:)=0.
ZTOT_RCDRYG(:)=0.
ZTOT_RIDRYG(:)=0.
ZTOT_RRDRYG(:)=0.
ZTOT_RSDRYG(:)=0.
ZTOT_RWETGH(:)=0.
ZTOT_RGMLTR(:)=0.
ZTOT_RCWETH(:)=0.
ZTOT_RIWETH(:)=0.
ZTOT_RSWETH(:)=0.
ZTOT_RGWETH(:)=0.
ZTOT_RRWETH(:)=0.
ZTOT_RCDRYH(:)=0.
ZTOT_RIDRYH(:)=0.
ZTOT_RSDRYH(:)=0.
ZTOT_RRDRYH(:)=0.
ZTOT_RGDRYH(:)=0.
ZTOT_RDRYHG(:)=0.
ENDIF
!-------------------------------------------------------------------------------
! optimization by looking for locations where
! the microphysical fields are larger than a minimal value only !!!
!
IF (KSIZE /= COUNT(ODMICRO(D%NIJB:D%NIJE,D%NKTB:D%NKTE))) THEN
CALL PRINT_MSG(NVERB_FATAL, 'GEN', 'RAIN_ICE', 'RAIN_ICE : KSIZE /= COUNT(ODMICRO)')
ENDIF
IF (KSIZE > 0) THEN
!Maximum number of iterations
!We only count real iterations (those for which we *compute* tendencies)
INB_ITER_MAX=PARAMI%NMAXITER
IF(PARAMI%XTSTEP_TS/=0.)THEN
INB_ITER_MAX=MAX(1, INT(PTSTEP/PARAMI%XTSTEP_TS)) !At least the number of iterations needed for the time-splitting
ZTSTEP=PTSTEP/INB_ITER_MAX
INB_ITER_MAX=MAX(PARAMI%NMAXITER, INB_ITER_MAX) !For the case XMRSTEP/=0. at the same time
ENDIF
!===============================================================================================================
! Cache-blocking loop :
LLSIGMA_RC=(HSUBG_AUCV_RC=='PDF ' .AND. PARAMI%CSUBG_PR_PDF=='SIGM')
LL_AUCV_ADJU=(HSUBG_AUCV_RC=='ADJU' .OR. HSUBG_AUCV_RI=='ADJU')
! starting indexes :
IC=0
ISTK=D%NKTB
ISTIJ=D%NIJB
DO JMICRO=1,KSIZE,KPROMA
IMICRO=MIN(KPROMA,KSIZE-JMICRO+1)
!
!* 3. PACKING
! --------
! Setup packing parameters
OUTER_LOOP: DO JK = ISTK, D%NKTE
IF (ANY(ODMICRO(:,JK))) THEN
DO JIJ = ISTIJ, D%NIJE
IF (ODMICRO(JIJ,JK)) THEN
IC=IC+1
! Initialization of variables in packed format :
ZVART(IC, ITH)=PTHT(JIJ, JK)
ZVART(IC, IRV)=PRVT(JIJ, JK)
ZVART(IC, IRC)=PRCT(JIJ, JK)
ZVART(IC, IRR)=PRRT(JIJ, JK)
ZVART(IC, IRI)=PRIT(JIJ, JK)
ZVART(IC, IRS)=PRST(JIJ, JK)
ZVART(IC, IRG)=PRGT(JIJ, JK)
IF (KRR==7) THEN
ZVART(IC, IRH)=PRHT(JIJ, JK)
ENDIF
IF (GEXT_TEND) THEN
!The th tendency is not related to a mixing ratio change, there is no exn/exnref issue here
ZEXTPK(IC, ITH)=PTHS(JIJ, JK)
ZEXTPK(IC, IRV)=PRVS(JIJ, JK)
ZEXTPK(IC, IRC)=PRCS(JIJ, JK)
ZEXTPK(IC, IRR)=PRRS(JIJ, JK)
ZEXTPK(IC, IRI)=PRIS(JIJ, JK)
ZEXTPK(IC, IRS)=PRSS(JIJ, JK)
ZEXTPK(IC, IRG)=PRGS(JIJ, JK)
IF (KRR==7) THEN
ZEXTPK(IC, IRH)=PRHS(JIJ, JK)
ENDIF
ENDIF
ZCIT (IC)=PCIT (JIJ, JK)
ZCF (IC)=PCLDFR (JIJ, JK)
ZRHODREF (IC)=PRHODREF(JIJ, JK)
ZPRES (IC)=PPABST (JIJ, JK)
ZEXN (IC)=PEXN (JIJ, JK)
IF(LLSIGMA_RC) THEN
ZSIGMA_RC(IC)=PSIGS (JIJ, JK)
ENDIF
IF (LL_AUCV_ADJU) THEN
ZHLC_HCF(IC) = PHLC_HCF(JIJ, JK)
ZHLC_HRC(IC) = PHLC_HRC(JIJ, JK)
ZHLI_HCF(IC) = PHLI_HCF(JIJ, JK)
ZHLI_HRI(IC) = PHLI_HRI(JIJ, JK)
ENDIF
! Save indices for later usages:
I1(IC) = JIJ
I2(IC) = JK
I1TOT(JMICRO+IC-1)=JIJ
I2TOT(JMICRO+IC-1)=JK
IF (IC==IMICRO) THEN
! the end of the chunk has been reached, then reset the starting index :
ISTIJ=JIJ+1
IF (ISTIJ <= D%NIJE) THEN
ISTK=JK
ELSE
! end of line, restart from 1 and increment upper loop
ISTK=JK+1
IF (ISTK > D%NKTE) THEN
! end of line, restart from 1
ISTK=D%NKTB
ENDIF
ENDIF
IC=0
EXIT OUTER_LOOP
ENDIF
ENDIF
ENDDO
ENDIF
! restart inner loop on JIJ :
ISTIJ=D%NIJB
ENDDO OUTER_LOOP
IF (GEXT_TEND) THEN
DO JV=0, KRR
DO JL=1, IMICRO
ZEXTPK(JL, JV)=ZEXTPK(JL, JV)-ZVART(JL, JV)*ZINV_TSTEP
ENDDO
ENDDO
ENDIF
IF (LLSIGMA_RC) THEN
DO JL=1, IMICRO
ZSIGMA_RC(JL)=ZSIGMA_RC(JL)*2.
ENDDO
ENDIF
IF (LL_AUCV_ADJU) THEN
DO JL=1, IMICRO
ZHLC_LRC(JL) = ZVART(JL, IRC) - ZHLC_HRC(JL)
ZHLI_LRI(JL) = ZVART(JL, IRI) - ZHLI_HRI(JL)
IF(ZVART(JL, IRC)>0.) THEN
ZHLC_LCF(JL) = ZCF(JL)- ZHLC_HCF(JL)
ELSE
ZHLC_LCF(JL)=0.
ENDIF
IF(ZVART(JL, IRI)>0.) THEN
ZHLI_LCF(JL) = ZCF(JL)- ZHLI_HCF(JL)
ELSE
ZHLI_LCF(JL)=0.
ENDIF
ENDDO
ENDIF
!-------------------------------------------------------------------------------
!
!* 4. LOOP
! ----
!
IITER(1:IMICRO)=0
ZTIME(1:IMICRO)=0. ! Current integration time (all points may have a different integration time)
DO WHILE(ANY(ZTIME(1:IMICRO)<PTSTEP)) ! Loop to *really* compute tendencies
IF(PARAMI%XTSTEP_TS/=0.) THEN
! In this case we need to remember the time when tendencies were computed
! because when time has evolved more than a limit, we must re-compute tendencies
ZTIME_LASTCALL(1:IMICRO)=ZTIME(1:IMICRO)
ENDIF
DO JL=1, IMICRO
IF (ZTIME(JL) < PTSTEP) THEN
LLCOMPUTE(JL)=.TRUE. ! Computation (.TRUE.) only for points for which integration time has not reached the timestep
IITER(JL)=IITER(JL)+1
ELSE
LLCOMPUTE(JL)=.FALSE.
ENDIF
ENDDO
LL_ANY_ITER=ANY(IITER(1:IMICRO) < INB_ITER_MAX)
LLCPZ0RT=.TRUE.
LSOFT=.FALSE. ! We *really* compute the tendencies
DO WHILE(ANY(LLCOMPUTE(1:IMICRO))) ! Loop to adjust tendencies when we cross the 0°C or when a species disappears
!$OMP SIMD
DO JL=1, IMICRO
ZSUM2(JL)=SUM(ZVART(JL,IRI:KRR))
ENDDO
DO JL=1, IMICRO
ZDEVIDE=(CST%XCPD + CST%XCPV*ZVART(JL, IRV) + CST%XCL*(ZVART(JL, IRC)+ZVART(JL, IRR)) + CST%XCI*ZSUM2(JL)) * ZEXN(JL)
ZZT(JL) = ZVART(JL, ITH) * ZEXN(JL)
ZLSFACT(JL)=(CST%XLSTT+(CST%XCPV-CST%XCI)*(ZZT(JL)-CST%XTT)) / ZDEVIDE
ZLVFACT(JL)=(CST%XLVTT+(CST%XCPV-CST%XCL)*(ZZT(JL)-CST%XTT)) / ZDEVIDE
ENDDO
!
!*** 4.1 Tendencies computation
!
! Tendencies are *really* computed when LSOFT==.FALSE. and only adjusted otherwise
CALL ICE4_TENDENCIES(D, CST, PARAMI, ICEP, ICED, BUCONF, &
&KPROMA, IMICRO, &
&KRR, LSOFT, LLCOMPUTE, &
&OWARM, PARAMI%CSUBG_RC_RR_ACCR, PARAMI%CSUBG_RR_EVAP, &
&HSUBG_AUCV_RC, HSUBG_AUCV_RI, PARAMI%CSUBG_PR_PDF, &
&ZEXN, ZRHODREF, ZLVFACT, ZLSFACT, I1, I2, &
&ZPRES, ZCF, ZSIGMA_RC, &
&ZCIT, &
&ZZT, ZVART, &
&ZRVHENI_MR, ZRRHONG_MR, ZRIMLTC_MR, ZRSRIMCG_MR, &
&ZRCHONI, ZRVDEPS, ZRIAGGS, ZRIAUTS, ZRVDEPG, &
&ZRCAUTR, ZRCACCR, ZRREVAV, &
&ZRCRIMSS, ZRCRIMSG, ZRSRIMCG, ZRRACCSS, ZRRACCSG, ZRSACCRG, ZRSMLTG, ZRCMLTSR, &
&ZRICFRRG, ZRRCFRIG, ZRICFRR, ZRCWETG, ZRIWETG, ZRRWETG, ZRSWETG, &
&ZRCDRYG, ZRIDRYG, ZRRDRYG, ZRSDRYG, ZRWETGH, ZRWETGH_MR, ZRGMLTR, &
&ZRCWETH, ZRIWETH, ZRSWETH, ZRGWETH, ZRRWETH, &
&ZRCDRYH, ZRIDRYH, ZRSDRYH, ZRRDRYH, ZRGDRYH, ZRDRYHG, ZRHMLTR, &
&ZRCBERI, &
&ZRS_TEND, ZRG_TEND, ZRH_TEND, ZSSI, &
&ZA, ZB, &
&ZHLC_HCF, ZHLC_LCF, ZHLC_HRC, ZHLC_LRC, &
&ZHLI_HCF, ZHLI_LCF, ZHLI_HRI, ZHLI_LRI, PRAINFR)
! External tendencies
IF(GEXT_TEND) THEN
DO JV=0, KRR
DO JL=1, IMICRO
ZA(JL, JV) = ZA(JL, JV) + ZEXTPK(JL, JV)
ENDDO
ENDDO
ENDIF
!
!*** 4.2 Integration time
!
! If we can, we shall use these tendencies until the end of the timestep
DO JL=1, IMICRO
IF(LLCOMPUTE(JL)) THEN
ZMAXTIME(JL)=(PTSTEP-ZTIME(JL)) ! Remaining time until the end of the timestep
ELSE
ZMAXTIME(JL)=0.
ENDIF
ENDDO
!We need to adjust tendencies when temperature reaches 0
IF(PARAMI%LFEEDBACKT) THEN
DO JL=1, IMICRO
!Is ZB(:, ITH) enough to change temperature sign?
ZX=CST%XTT/ZEXN(JL)
IF ((ZVART(JL, ITH) - ZX) * (ZVART(JL, ITH) + ZB(JL, ITH) - ZX) < 0.) THEN
ZMAXTIME(JL)=0.
ENDIF
!Can ZA(:, ITH) make temperature change of sign?
IF (ABS(ZA(JL,ITH)) > 1.E-20 ) THEN
ZTIME_THRESHOLD=(ZX - ZB(JL, ITH) - ZVART(JL, ITH))/ZA(JL, ITH)
IF (ZTIME_THRESHOLD > 0.) THEN
ZMAXTIME(JL)=MIN(ZMAXTIME(JL), ZTIME_THRESHOLD)
ENDIF
ENDIF
ENDDO
ENDIF
!We need to adjust tendencies when a species disappears
!When a species is missing, only the external tendencies can be negative (and we must keep track of it)
DO JV=1, KRR
DO JL=1, IMICRO
IF (ZA(JL, JV) < -1.E-20 .AND. ZVART(JL, JV) > ICED%XRTMIN(JV)) THEN
ZMAXTIME(JL)=MIN(ZMAXTIME(JL), -(ZB(JL, JV)+ZVART(JL, JV))/ZA(JL, JV))
ENDIF
ENDDO
ENDDO
!We stop when the end of the timestep is reached
DO JL=1, IMICRO
IF (ZTIME(JL)+ZMAXTIME(JL) >= PTSTEP) THEN
LLCOMPUTE(JL)=.FALSE.
ENDIF
ENDDO
!We must recompute tendencies when the end of the sub-timestep is reached
IF (PARAMI%XTSTEP_TS/=0.) THEN
DO JL=1, IMICRO
IF ((IITER(JL) < INB_ITER_MAX) .AND. (ZTIME(JL)+ZMAXTIME(JL) > ZTIME_LASTCALL(JL)+ZTSTEP)) THEN
ZMAXTIME(JL)=ZTIME_LASTCALL(JL)-ZTIME(JL)+ZTSTEP
LLCOMPUTE(JL)=.FALSE.
ENDIF
ENDDO
ENDIF
!We must recompute tendencies when the maximum allowed change is reached
!When a species is missing, only the external tendencies can be active and we do not want to recompute
!the microphysical tendencies when external tendencies are negative (results won't change because species was already missing)
IF (PARAMI%XMRSTEP/=0.) THEN
IF (LL_ANY_ITER) THEN
! In this case we need to remember the initial mixing ratios used to compute the tendencies
! because when mixing ratio has evolved more than a threshold, we must re-compute tendencies
! Thus, at first iteration (ie when LLCPZ0RT=.TRUE.) we copy ZVART into Z0RT
DO JV=1,KRR
IF (LLCPZ0RT) Z0RT(1:IMICRO, JV)=ZVART(1:IMICRO, JV)
DO JL=1, IMICRO
IF (IITER(JL)<INB_ITER_MAX .AND. ABS(ZA(JL,JV))>1.E-20) THEN
ZTIME_THRESHOLD1D(JL)=(SIGN(1., ZA(JL, JV))*PARAMI%XMRSTEP+ &
&Z0RT(JL, JV)-ZVART(JL, JV)-ZB(JL, JV))/ZA(JL, JV)
ELSE
ZTIME_THRESHOLD1D(JL)=-1.
ENDIF
ENDDO
DO JL=1, IMICRO
IF (ZTIME_THRESHOLD1D(JL)>=0 .AND. ZTIME_THRESHOLD1D(JL)<ZMAXTIME(JL) .AND. &
&(ZVART(JL, JV)>ICED%XRTMIN(JV) .OR. ZA(JL, JV)>0.)) THEN
ZMAXTIME(JL)=MIN(ZMAXTIME(JL), ZTIME_THRESHOLD1D(JL))
LLCOMPUTE(JL)=.FALSE.
ENDIF
ENDDO
ENDDO
LLCPZ0RT=.FALSE.
!$OMP SIMD
DO JL=1,IMICRO
ZMAXB(JL)=MAXVAL(ABS(ZB(JL,1:KRR)))
ENDDO
DO JL=1, IMICRO
IF (IITER(JL)<INB_ITER_MAX .AND. ZMAXB(JL)>PARAMI%XMRSTEP) THEN
ZMAXTIME(JL)=0.
LLCOMPUTE(JL)=.FALSE.
ENDIF
ENDDO
ENDIF ! LL_ANY_ITER
ENDIF ! XMRSTEP/=0.
!
!*** 4.3 New values of variables for next iteration
!
DO JV=0, KRR
DO JL=1, IMICRO
ZVART(JL, JV)=ZVART(JL, JV)+ZA(JL, JV)*ZMAXTIME(JL)+ZB(JL, JV)
ENDDO
ENDDO
DO JL=1, IMICRO
#ifdef REPRO55
ZCIT(JL)=ZCIT(JL) * MAX(0., -SIGN(1., -ZVART(JL,IRI)))
#else
IF (ZVART(JL,IRI)<=0.) ZCIT(JL) = 0.
#endif
ZTIME(JL)=ZTIME(JL)+ZMAXTIME(JL)
ENDDO
!
!*** 4.4 Mixing ratio change due to each process
!
IF(BUCONF%LBU_ENABLE) THEN
DO JL=1, IMICRO
ZTOT_RVHENI (JMICRO+JL-1)=ZTOT_RVHENI (JMICRO+JL-1)+ZRVHENI_MR(JL)
ZTOT_RCHONI (JMICRO+JL-1)=ZTOT_RCHONI (JMICRO+JL-1)+ZRCHONI (JL)*ZMAXTIME(JL)
ZTOT_RRHONG (JMICRO+JL-1)=ZTOT_RRHONG (JMICRO+JL-1)+ZRRHONG_MR(JL)
ZTOT_RVDEPS (JMICRO+JL-1)=ZTOT_RVDEPS (JMICRO+JL-1)+ZRVDEPS (JL)*ZMAXTIME(JL)
ZTOT_RIAGGS (JMICRO+JL-1)=ZTOT_RIAGGS (JMICRO+JL-1)+ZRIAGGS (JL)*ZMAXTIME(JL)
ZTOT_RIAUTS (JMICRO+JL-1)=ZTOT_RIAUTS (JMICRO+JL-1)+ZRIAUTS (JL)*ZMAXTIME(JL)
ZTOT_RVDEPG (JMICRO+JL-1)=ZTOT_RVDEPG (JMICRO+JL-1)+ZRVDEPG (JL)*ZMAXTIME(JL)
ZTOT_RCAUTR (JMICRO+JL-1)=ZTOT_RCAUTR (JMICRO+JL-1)+ZRCAUTR (JL)*ZMAXTIME(JL)
ZTOT_RCACCR (JMICRO+JL-1)=ZTOT_RCACCR (JMICRO+JL-1)+ZRCACCR (JL)*ZMAXTIME(JL)
ZTOT_RREVAV (JMICRO+JL-1)=ZTOT_RREVAV (JMICRO+JL-1)+ZRREVAV (JL)*ZMAXTIME(JL)
ZTOT_RCRIMSS(JMICRO+JL-1)=ZTOT_RCRIMSS(JMICRO+JL-1)+ZRCRIMSS (JL)*ZMAXTIME(JL)
ZTOT_RCRIMSG(JMICRO+JL-1)=ZTOT_RCRIMSG(JMICRO+JL-1)+ZRCRIMSG (JL)*ZMAXTIME(JL)
ZTOT_RSRIMCG(JMICRO+JL-1)=ZTOT_RSRIMCG(JMICRO+JL-1)+ZRSRIMCG (JL)*ZMAXTIME(JL)+ZRSRIMCG_MR(JL)
ZTOT_RRACCSS(JMICRO+JL-1)=ZTOT_RRACCSS(JMICRO+JL-1)+ZRRACCSS (JL)*ZMAXTIME(JL)
ZTOT_RRACCSG(JMICRO+JL-1)=ZTOT_RRACCSG(JMICRO+JL-1)+ZRRACCSG (JL)*ZMAXTIME(JL)
ZTOT_RSACCRG(JMICRO+JL-1)=ZTOT_RSACCRG(JMICRO+JL-1)+ZRSACCRG (JL)*ZMAXTIME(JL)
ZTOT_RSMLTG (JMICRO+JL-1)=ZTOT_RSMLTG (JMICRO+JL-1)+ZRSMLTG (JL)*ZMAXTIME(JL)
ZTOT_RCMLTSR(JMICRO+JL-1)=ZTOT_RCMLTSR(JMICRO+JL-1)+ZRCMLTSR (JL)*ZMAXTIME(JL)
ZTOT_RICFRRG(JMICRO+JL-1)=ZTOT_RICFRRG(JMICRO+JL-1)+ZRICFRRG (JL)*ZMAXTIME(JL)
ZTOT_RRCFRIG(JMICRO+JL-1)=ZTOT_RRCFRIG(JMICRO+JL-1)+ZRRCFRIG (JL)*ZMAXTIME(JL)
ZTOT_RICFRR (JMICRO+JL-1)=ZTOT_RICFRR (JMICRO+JL-1)+ZRICFRR (JL)*ZMAXTIME(JL)
ZTOT_RCWETG (JMICRO+JL-1)=ZTOT_RCWETG (JMICRO+JL-1)+ZRCWETG (JL)*ZMAXTIME(JL)
ZTOT_RIWETG (JMICRO+JL-1)=ZTOT_RIWETG (JMICRO+JL-1)+ZRIWETG (JL)*ZMAXTIME(JL)
ZTOT_RRWETG (JMICRO+JL-1)=ZTOT_RRWETG (JMICRO+JL-1)+ZRRWETG (JL)*ZMAXTIME(JL)
ZTOT_RSWETG (JMICRO+JL-1)=ZTOT_RSWETG (JMICRO+JL-1)+ZRSWETG (JL)*ZMAXTIME(JL)
ZTOT_RWETGH (JMICRO+JL-1)=ZTOT_RWETGH (JMICRO+JL-1)+ZRWETGH (JL)*ZMAXTIME(JL)+ZRWETGH_MR(JL)
ZTOT_RCDRYG (JMICRO+JL-1)=ZTOT_RCDRYG (JMICRO+JL-1)+ZRCDRYG (JL)*ZMAXTIME(JL)
ZTOT_RIDRYG (JMICRO+JL-1)=ZTOT_RIDRYG (JMICRO+JL-1)+ZRIDRYG (JL)*ZMAXTIME(JL)
ZTOT_RRDRYG (JMICRO+JL-1)=ZTOT_RRDRYG (JMICRO+JL-1)+ZRRDRYG (JL)*ZMAXTIME(JL)
ZTOT_RSDRYG (JMICRO+JL-1)=ZTOT_RSDRYG (JMICRO+JL-1)+ZRSDRYG (JL)*ZMAXTIME(JL)
ZTOT_RGMLTR (JMICRO+JL-1)=ZTOT_RGMLTR (JMICRO+JL-1)+ZRGMLTR (JL)*ZMAXTIME(JL)
ZTOT_RCWETH (JMICRO+JL-1)=ZTOT_RCWETH (JMICRO+JL-1)+ZRCWETH (JL)*ZMAXTIME(JL)
ZTOT_RIWETH (JMICRO+JL-1)=ZTOT_RIWETH (JMICRO+JL-1)+ZRIWETH (JL)*ZMAXTIME(JL)
ZTOT_RSWETH (JMICRO+JL-1)=ZTOT_RSWETH (JMICRO+JL-1)+ZRSWETH (JL)*ZMAXTIME(JL)
ZTOT_RGWETH (JMICRO+JL-1)=ZTOT_RGWETH (JMICRO+JL-1)+ZRGWETH (JL)*ZMAXTIME(JL)
ZTOT_RRWETH (JMICRO+JL-1)=ZTOT_RRWETH (JMICRO+JL-1)+ZRRWETH (JL)*ZMAXTIME(JL)
ZTOT_RCDRYH (JMICRO+JL-1)=ZTOT_RCDRYH (JMICRO+JL-1)+ZRCDRYH (JL)*ZMAXTIME(JL)
ZTOT_RIDRYH (JMICRO+JL-1)=ZTOT_RIDRYH (JMICRO+JL-1)+ZRIDRYH (JL)*ZMAXTIME(JL)
ZTOT_RSDRYH (JMICRO+JL-1)=ZTOT_RSDRYH (JMICRO+JL-1)+ZRSDRYH (JL)*ZMAXTIME(JL)
ZTOT_RRDRYH (JMICRO+JL-1)=ZTOT_RRDRYH (JMICRO+JL-1)+ZRRDRYH (JL)*ZMAXTIME(JL)
ZTOT_RGDRYH (JMICRO+JL-1)=ZTOT_RGDRYH (JMICRO+JL-1)+ZRGDRYH (JL)*ZMAXTIME(JL)
ZTOT_RDRYHG (JMICRO+JL-1)=ZTOT_RDRYHG (JMICRO+JL-1)+ZRDRYHG (JL)*ZMAXTIME(JL)
ZTOT_RHMLTR (JMICRO+JL-1)=ZTOT_RHMLTR (JMICRO+JL-1)+ZRHMLTR (JL)*ZMAXTIME(JL)
ZTOT_RIMLTC (JMICRO+JL-1)=ZTOT_RIMLTC (JMICRO+JL-1)+ZRIMLTC_MR(JL)
ZTOT_RCBERI (JMICRO+JL-1)=ZTOT_RCBERI (JMICRO+JL-1)+ZRCBERI (JL)*ZMAXTIME(JL)
ENDDO
ENDIF
!
!*** 4.5 Next loop
!
LSOFT=.TRUE. ! We try to adjust tendencies (inner while loop)
ENDDO
ENDDO
IF(GEXT_TEND) THEN
!Z..T variables contain the external tendency, we substract it
DO JV=0, KRR
DO JL=1, IMICRO
ZVART(JL, JV) = ZVART(JL, JV) - ZEXTPK(JL, JV) * PTSTEP
ENDDO
ENDDO
ENDIF
!-------------------------------------------------------------------------------
!
!* 5. UNPACKING DIAGNOSTICS
! ---------------------
!
DO JL=1, IMICRO
ZCITOUT (I1(JL),I2(JL))=ZCIT (JL)
IF(OWARM) THEN
PEVAP3D(I1(JL),I2(JL))=ZRREVAV(JL)
ENDIF
ZWR(I1(JL),I2(JL),IRV)=ZVART(JL, IRV)
ZWR(I1(JL),I2(JL),IRC)=ZVART(JL, IRC)
ZWR(I1(JL),I2(JL),IRR)=ZVART(JL, IRR)
ZWR(I1(JL),I2(JL),IRI)=ZVART(JL, IRI)
ZWR(I1(JL),I2(JL),IRS)=ZVART(JL, IRS)
ZWR(I1(JL),I2(JL),IRG)=ZVART(JL, IRG)
IF (KRR==7) THEN
ZWR(I1(JL),I2(JL),IRH)=ZVART(JL, IRH)
ENDIF
ENDDO
ENDDO ! JMICRO
ENDIF ! KSIZE > 0
PCIT(:,:)=ZCITOUT(:,:)
!==========================================================================================================
!
!* 6. COMPUTES THE SLOW COLD PROCESS SOURCES OUTSIDE OF ODMICRO POINTS
! ----------------------------------------------------------------
!
LLW3D(:,:)=.FALSE.
DO JK=D%NKTB,D%NKTE
DO JIJ=D%NIJB,D%NIJE
IF (.NOT. ODMICRO(JIJ, JK)) THEN
LLW3D(JIJ, JK)=.TRUE.
ZW3D(JIJ, JK)=ZZ_LSFACT(JIJ, JK)/PEXN(JIJ, JK)
ELSE
LLW3D(JIJ, JK)=.FALSE.
ENDIF
ENDDO
ENDDO
CALL ICE4_NUCLEATION(CST, PARAMI, ICEP, ICED, D%NIJT*D%NKT, LLW3D(:,:), &
PTHT(:, :), PPABST(:, :), PRHODREF(:, :), &
PEXN(:, :), ZW3D(:, :), ZT(:, :), &
PRVT(:, :), &
PCIT(:, :), ZZ_RVHENI_MR(:, :))
!
!-------------------------------------------------------------------------------
!
!* 7. TOTAL TENDENCIES
! ----------------
!
!
!*** 7.1 total tendencies limited by available species
!
DO JK = D%NKTB, D%NKTE
DO CONCURRENT (JIJ=D%NIJB:D%NIJE)
!LV/LS
ZZ_LSFACT(JIJ,JK)=ZZ_LSFACT(JIJ,JK)/PEXNREF(JIJ,JK)
ZZ_LVFACT(JIJ,JK)=ZZ_LVFACT(JIJ,JK)/PEXNREF(JIJ,JK)
!Tendency dure to nucleation on non ODMICRO points
ZZ_RVHENI(JIJ,JK) = MIN(PRVS(JIJ,JK), ZZ_RVHENI_MR(JIJ,JK)/PTSTEP)
!Hydrometeor tendencies is the difference between old state and new state (can be negative)
ZWR(JIJ,JK,IRV)=(ZWR(JIJ,JK,IRV)-PRVT(JIJ,JK))*ZINV_TSTEP
ZWR(JIJ,JK,IRC)=(ZWR(JIJ,JK,IRC)-PRCT(JIJ,JK))*ZINV_TSTEP
ZWR(JIJ,JK,IRR)=(ZWR(JIJ,JK,IRR)-PRRT(JIJ,JK))*ZINV_TSTEP
ZWR(JIJ,JK,IRI)=(ZWR(JIJ,JK,IRI)-PRIT(JIJ,JK))*ZINV_TSTEP
ZWR(JIJ,JK,IRS)=(ZWR(JIJ,JK,IRS)-PRST(JIJ,JK))*ZINV_TSTEP
ZWR(JIJ,JK,IRG)=(ZWR(JIJ,JK,IRG)-PRGT(JIJ,JK))*ZINV_TSTEP
IF(KRR==7) THEN
ZWR(JIJ,JK,IRH)=(ZWR(JIJ,JK,IRH)-PRHT(JIJ,JK))*ZINV_TSTEP
ENDIF
!Theta tendency computed from hydrometeors tendencies
ZWR(JIJ,JK, ITH) = (ZWR(JIJ,JK,IRC)+ZWR(JIJ,JK,IRR))*ZZ_LVFACT(JIJ,JK)+ &
& (ZWR(JIJ,JK,IRI)+ZWR(JIJ,JK,IRS)+ZWR(JIJ,JK,IRG)+ &
& ZWR(JIJ,JK,IRH))*ZZ_LSFACT(JIJ,JK)
!We apply these tendencies to the S variables
!including the nucleation part
PTHS(JIJ,JK) = PTHS(JIJ,JK) + ZWR(JIJ,JK,ITH)+ZZ_RVHENI(JIJ,JK)*ZZ_LSFACT(JIJ,JK)
PRVS(JIJ,JK) = PRVS(JIJ,JK) + ZWR(JIJ,JK,IRV)-ZZ_RVHENI(JIJ,JK)
PRCS(JIJ,JK) = PRCS(JIJ,JK) + ZWR(JIJ,JK,IRC)
PRRS(JIJ,JK) = PRRS(JIJ,JK) + ZWR(JIJ,JK,IRR)
PRIS(JIJ,JK) = PRIS(JIJ,JK) + ZWR(JIJ,JK,IRI)+ZZ_RVHENI(JIJ,JK)
PRSS(JIJ,JK) = PRSS(JIJ,JK) + ZWR(JIJ,JK,IRS)
PRGS(JIJ,JK) = PRGS(JIJ,JK) + ZWR(JIJ,JK,IRG)
IF (KRR==7) THEN
PRHS(JIJ,JK) = PRHS(JIJ,JK) + ZWR(JIJ,JK,IRH)
ENDIF
ENDDO
ENDDO
!
!*** 7.2 LBU_ENABLE case
!
IF(BUCONF%LBU_ENABLE) THEN
IF (BUCONF%LBUDGET_TH) THEN
ZZ_DIFF(:,:)=0.
DO JK = D%NKTB, D%NKTE
DO JIJ = D%NIJB, D%NIJE
ZZ_DIFF(JIJ, JK) = ZZ_LSFACT(JIJ, JK) - ZZ_LVFACT(JIJ, JK)
ENDDO
ENDDO
END IF
ZW(:,:) = 0.
DO JL=1, KSIZE
ZW(I1TOT(JL), I2TOT(JL)) = ZTOT_RVHENI(JL) * ZINV_TSTEP
END DO
DO JK = D%NKTB, D%NKTE
DO JIJ = D%NIJB, D%NIJE
ZW(JIJ,JK)=ZW(JIJ,JK)+ZZ_RVHENI(JIJ,JK)
ENDDO
ENDDO
IF (BUCONF%LBUDGET_TH) CALL BUDGET_STORE_ADD_PHY(D, TBUDGETS(NBUDGET_TH), 'HENU', ZW(:, :)*ZZ_LSFACT(:, :)*PRHODJ(:, :))
IF (BUCONF%LBUDGET_RV) CALL BUDGET_STORE_ADD_PHY(D, TBUDGETS(NBUDGET_RV), 'HENU', -ZW(:, :) *PRHODJ(:, :))
IF (BUCONF%LBUDGET_RI) CALL BUDGET_STORE_ADD_PHY(D, TBUDGETS(NBUDGET_RI), 'HENU', ZW(:, :) *PRHODJ(:, :))
ZW(:,:) = 0.
DO JL=1, KSIZE
ZW(I1TOT(JL), I2TOT(JL)) = ZTOT_RCHONI(JL) * ZINV_TSTEP
END DO
IF (BUCONF%LBUDGET_TH) CALL BUDGET_STORE_ADD_PHY(D, TBUDGETS(NBUDGET_TH), 'HON', ZW(:, :)*ZZ_DIFF(:, :)*PRHODJ(:, :))
IF (BUCONF%LBUDGET_RC) CALL BUDGET_STORE_ADD_PHY(D, TBUDGETS(NBUDGET_RC), 'HON', -ZW(:, :) *PRHODJ(:, :))
IF (BUCONF%LBUDGET_RI) CALL BUDGET_STORE_ADD_PHY(D, TBUDGETS(NBUDGET_RI), 'HON', ZW(:, :) *PRHODJ(:, :))
ZW(:,:) = 0.
DO JL=1, KSIZE
ZW(I1TOT(JL), I2TOT(JL)) = ZTOT_RRHONG(JL) * ZINV_TSTEP
END DO
IF (BUCONF%LBUDGET_TH) CALL BUDGET_STORE_ADD_PHY(D, TBUDGETS(NBUDGET_TH), 'SFR', ZW(:, :)*ZZ_DIFF(:, :)*PRHODJ(:, :))
IF (BUCONF%LBUDGET_RR) CALL BUDGET_STORE_ADD_PHY(D, TBUDGETS(NBUDGET_RR), 'SFR', -ZW(:, :) *PRHODJ(:, :))
IF (BUCONF%LBUDGET_RG) CALL BUDGET_STORE_ADD_PHY(D, TBUDGETS(NBUDGET_RG), 'SFR', ZW(:, :) *PRHODJ(:, :))
ZW(:,:) = 0.
DO JL=1, KSIZE
ZW(I1TOT(JL), I2TOT(JL)) = ZTOT_RVDEPS(JL) * ZINV_TSTEP
END DO
IF (BUCONF%LBUDGET_TH) CALL BUDGET_STORE_ADD_PHY(D, TBUDGETS(NBUDGET_TH), 'DEPS', ZW(:, :)*ZZ_LSFACT(:, :)*PRHODJ(:, :))
IF (BUCONF%LBUDGET_RV) CALL BUDGET_STORE_ADD_PHY(D, TBUDGETS(NBUDGET_RV), 'DEPS', -ZW(:, :) *PRHODJ(:, :))
IF (BUCONF%LBUDGET_RS) CALL BUDGET_STORE_ADD_PHY(D, TBUDGETS(NBUDGET_RS), 'DEPS', ZW(:, :) *PRHODJ(:, :))
ZW(:,:) = 0.
DO JL=1, KSIZE
ZW(I1TOT(JL), I2TOT(JL)) = ZTOT_RIAGGS(JL) * ZINV_TSTEP
END DO
IF (BUCONF%LBUDGET_RI) CALL BUDGET_STORE_ADD_PHY(D, TBUDGETS(NBUDGET_RI), 'AGGS', -ZW(:, :)*PRHODJ(:, :))
IF (BUCONF%LBUDGET_RS) CALL BUDGET_STORE_ADD_PHY(D, TBUDGETS(NBUDGET_RS), 'AGGS', ZW(:, :)*PRHODJ(:, :))
ZW(:,:) = 0.
DO JL=1, KSIZE
ZW(I1TOT(JL), I2TOT(JL)) = ZTOT_RIAUTS(JL) * ZINV_TSTEP
END DO
IF (BUCONF%LBUDGET_RI) CALL BUDGET_STORE_ADD_PHY(D, TBUDGETS(NBUDGET_RI), 'AUTS', -ZW(:, :)*PRHODJ(:, :))
IF (BUCONF%LBUDGET_RS) CALL BUDGET_STORE_ADD_PHY(D, TBUDGETS(NBUDGET_RS), 'AUTS', ZW(:, :)*PRHODJ(:, :))
ZW(:,:) = 0.
DO JL=1, KSIZE
ZW(I1TOT(JL), I2TOT(JL)) = ZTOT_RVDEPG(JL) * ZINV_TSTEP
END DO
IF (BUCONF%LBUDGET_TH) CALL BUDGET_STORE_ADD_PHY(D, TBUDGETS(NBUDGET_TH), 'DEPG', ZW(:, :)*ZZ_LSFACT(:, :)*PRHODJ(:, :))
IF (BUCONF%LBUDGET_RV) CALL BUDGET_STORE_ADD_PHY(D, TBUDGETS(NBUDGET_RV), 'DEPG', -ZW(:, :) *PRHODJ(:, :))
IF (BUCONF%LBUDGET_RG) CALL BUDGET_STORE_ADD_PHY(D, TBUDGETS(NBUDGET_RG), 'DEPG', ZW(:, :) *PRHODJ(:, :))
IF(OWARM) THEN
ZW(:,:) = 0.
DO JL=1, KSIZE
ZW(I1TOT(JL), I2TOT(JL)) = ZTOT_RCAUTR(JL) * ZINV_TSTEP
END DO
IF (BUCONF%LBUDGET_RC) CALL BUDGET_STORE_ADD_PHY(D, TBUDGETS(NBUDGET_RC), 'AUTO', -ZW(:, :)*PRHODJ(:, :))
IF (BUCONF%LBUDGET_RR) CALL BUDGET_STORE_ADD_PHY(D, TBUDGETS(NBUDGET_RR), 'AUTO', ZW(:, :)*PRHODJ(:, :))
ZW(:,:) = 0.
DO JL=1, KSIZE
ZW(I1TOT(JL), I2TOT(JL)) = ZTOT_RCACCR(JL) * ZINV_TSTEP
END DO
IF (BUCONF%LBUDGET_RC) CALL BUDGET_STORE_ADD_PHY(D, TBUDGETS(NBUDGET_RC), 'ACCR', -ZW(:, :)*PRHODJ(:, :))
IF (BUCONF%LBUDGET_RR) CALL BUDGET_STORE_ADD_PHY(D, TBUDGETS(NBUDGET_RR), 'ACCR', ZW(:, :)*PRHODJ(:, :))
ZW(:,:) = 0.
DO JL=1, KSIZE
ZW(I1TOT(JL), I2TOT(JL)) = ZTOT_RREVAV(JL) * ZINV_TSTEP
END DO
IF (BUCONF%LBUDGET_TH) CALL BUDGET_STORE_ADD_PHY(D, TBUDGETS(NBUDGET_TH), 'REVA', -ZW(:, :)*ZZ_LVFACT(:, :)*PRHODJ(:, :))
IF (BUCONF%LBUDGET_RV) CALL BUDGET_STORE_ADD_PHY(D, TBUDGETS(NBUDGET_RV), 'REVA', ZW(:, :) *PRHODJ(:, :))
IF (BUCONF%LBUDGET_RR) CALL BUDGET_STORE_ADD_PHY(D, TBUDGETS(NBUDGET_RR), 'REVA', -ZW(:, :) *PRHODJ(:, :))
ENDIF
ZW1(:,:) = 0.
DO JL=1, KSIZE
ZW1(I1TOT(JL), I2TOT(JL)) = ZTOT_RCRIMSS(JL) * ZINV_TSTEP
END DO
ZW2(:,:) = 0.
DO JL=1, KSIZE
ZW2(I1TOT(JL), I2TOT(JL)) = ZTOT_RCRIMSG(JL) * ZINV_TSTEP
END DO
ZW3(:,:) = 0.
DO JL=1, KSIZE
ZW3(I1TOT(JL), I2TOT(JL)) = ZTOT_RSRIMCG(JL) * ZINV_TSTEP
END DO
IF (BUCONF%LBUDGET_TH) &
CALL BUDGET_STORE_ADD_PHY(D, TBUDGETS(NBUDGET_TH), 'RIM', (ZW1(:, :)+ZW2(:, :))*ZZ_DIFF(:, :)*PRHODJ(:, :))
IF (BUCONF%LBUDGET_RC) CALL BUDGET_STORE_ADD_PHY(D, TBUDGETS(NBUDGET_RC), 'RIM', (-ZW1(:, :)-ZW2(:, :))*PRHODJ(:, :))
IF (BUCONF%LBUDGET_RS) CALL BUDGET_STORE_ADD_PHY(D, TBUDGETS(NBUDGET_RS), 'RIM', ( ZW1(:, :)-ZW3(:, :))*PRHODJ(:, :))
IF (BUCONF%LBUDGET_RG) CALL BUDGET_STORE_ADD_PHY(D, TBUDGETS(NBUDGET_RG), 'RIM', ( ZW2(:, :)+ZW3(:, :))*PRHODJ(:, :))
ZW1(:,:) = 0.
DO JL=1, KSIZE
ZW1(I1TOT(JL), I2TOT(JL)) = ZTOT_RRACCSS(JL) * ZINV_TSTEP
END DO
ZW2(:,:) = 0.
DO JL=1, KSIZE
ZW2(I1TOT(JL), I2TOT(JL)) = ZTOT_RRACCSG(JL) * ZINV_TSTEP
END DO
ZW3(:,:) = 0.
DO JL=1, KSIZE
ZW3(I1TOT(JL), I2TOT(JL)) = ZTOT_RSACCRG(JL) * ZINV_TSTEP
END DO
IF (BUCONF%LBUDGET_TH) &
CALL BUDGET_STORE_ADD_PHY(D, TBUDGETS(NBUDGET_TH), 'ACC', (ZW1(:, :)+ZW2(:, :) )*ZZ_DIFF(:, :)*PRHODJ(:, :))
IF (BUCONF%LBUDGET_RR) CALL BUDGET_STORE_ADD_PHY(D, TBUDGETS(NBUDGET_RR), 'ACC', (-ZW1(:, :)-ZW2(:, :))*PRHODJ(:, :))
IF (BUCONF%LBUDGET_RS) CALL BUDGET_STORE_ADD_PHY(D, TBUDGETS(NBUDGET_RS), 'ACC', ( ZW1(:, :)-ZW3(:, :))*PRHODJ(:, :))
IF (BUCONF%LBUDGET_RG) CALL BUDGET_STORE_ADD_PHY(D, TBUDGETS(NBUDGET_RG), 'ACC', ( ZW2(:, :)+ZW3(:, :))*PRHODJ(:, :))
ZW(:,:) = 0.
DO JL=1, KSIZE
ZW(I1TOT(JL), I2TOT(JL)) = ZTOT_RSMLTG(JL) * ZINV_TSTEP
END DO
IF (BUCONF%LBUDGET_RS) CALL BUDGET_STORE_ADD_PHY(D, TBUDGETS(NBUDGET_RS), 'CMEL', -ZW(:, :)*PRHODJ(:, :))
IF (BUCONF%LBUDGET_RG) CALL BUDGET_STORE_ADD_PHY(D, TBUDGETS(NBUDGET_RG), 'CMEL', ZW(:, :)*PRHODJ(:, :))
ZW(:,:) = 0.
DO JL=1, KSIZE
ZW(I1TOT(JL), I2TOT(JL)) = ZTOT_RCMLTSR(JL) * ZINV_TSTEP
END DO
IF (BUCONF%LBUDGET_RC) CALL BUDGET_STORE_ADD_PHY(D, TBUDGETS(NBUDGET_RC), 'CMEL', -ZW(:, :)*PRHODJ(:, :))
IF (BUCONF%LBUDGET_RR) CALL BUDGET_STORE_ADD_PHY(D, TBUDGETS(NBUDGET_RR), 'CMEL', ZW(:, :)*PRHODJ(:, :))
ZW1(:,:) = 0.
DO JL=1, KSIZE
ZW1(I1TOT(JL), I2TOT(JL)) = ZTOT_RICFRRG(JL) * ZINV_TSTEP
END DO
ZW2(:,:) = 0.
DO JL=1, KSIZE
ZW2(I1TOT(JL), I2TOT(JL)) = ZTOT_RRCFRIG(JL) * ZINV_TSTEP
END DO
ZW3(:,:) = 0.
DO JL=1, KSIZE
ZW3(I1TOT(JL), I2TOT(JL)) = ZTOT_RICFRR(JL) * ZINV_TSTEP
END DO
IF (BUCONF%LBUDGET_TH) &
CALL BUDGET_STORE_ADD_PHY(D, TBUDGETS(NBUDGET_TH), 'CFRZ', ZW2(:, :)*ZZ_DIFF(:, :)*PRHODJ(:, :))
IF (BUCONF%LBUDGET_RR) CALL BUDGET_STORE_ADD_PHY(D, TBUDGETS(NBUDGET_RR), 'CFRZ', (-ZW2(:, :)+ZW3(:, :))*PRHODJ(:, :))
IF (BUCONF%LBUDGET_RI) CALL BUDGET_STORE_ADD_PHY(D, TBUDGETS(NBUDGET_RI), 'CFRZ', (-ZW1(:, :)-ZW3(:, :))*PRHODJ(:, :))
IF (BUCONF%LBUDGET_RG) CALL BUDGET_STORE_ADD_PHY(D, TBUDGETS(NBUDGET_RG), 'CFRZ', ( ZW1(:, :)+ZW2(:, :))*PRHODJ(:, :))
ZW1(:,:) = 0.
DO JL=1, KSIZE
ZW1(I1TOT(JL), I2TOT(JL)) = ZTOT_RCWETG(JL) * ZINV_TSTEP
END DO
ZW2(:,:) = 0.
DO JL=1, KSIZE
ZW2(I1TOT(JL), I2TOT(JL)) = ZTOT_RRWETG(JL) * ZINV_TSTEP
END DO
ZW3(:,:) = 0.
DO JL=1, KSIZE
ZW3(I1TOT(JL), I2TOT(JL)) = ZTOT_RIWETG(JL) * ZINV_TSTEP
END DO
ZW4(:,:) = 0.
DO JL=1, KSIZE
ZW4(I1TOT(JL), I2TOT(JL)) = ZTOT_RSWETG(JL) * ZINV_TSTEP
END DO
IF (BUCONF%LBUDGET_TH) &
CALL BUDGET_STORE_ADD_PHY(D, TBUDGETS(NBUDGET_TH), 'WETG', (ZW1(:, :)+ZW2(:, :))*ZZ_DIFF(:, :)*PRHODJ(:, :))
IF (BUCONF%LBUDGET_RC) CALL BUDGET_STORE_ADD_PHY(D, TBUDGETS(NBUDGET_RC), 'WETG', -ZW1(:, :) *PRHODJ(:, :))
IF (BUCONF%LBUDGET_RR) CALL BUDGET_STORE_ADD_PHY(D, TBUDGETS(NBUDGET_RR), 'WETG', -ZW2(:, :) *PRHODJ(:, :))
IF (BUCONF%LBUDGET_RI) CALL BUDGET_STORE_ADD_PHY(D, TBUDGETS(NBUDGET_RI), 'WETG', -ZW3(:, :) *PRHODJ(:, :))
IF (BUCONF%LBUDGET_RS) CALL BUDGET_STORE_ADD_PHY(D, TBUDGETS(NBUDGET_RS), 'WETG', -ZW4(:, :) *PRHODJ(:, :))
IF (BUCONF%LBUDGET_RG) CALL BUDGET_STORE_ADD_PHY(D, TBUDGETS(NBUDGET_RG), 'WETG', (ZW1(:, :)+ZW2(:, :)+ZW3(:, :)+ZW4(:, :)) &
& *PRHODJ(:, :))
IF(KRR==7) THEN
ZW(:,:) = 0.
DO JL=1, KSIZE
ZW(I1TOT(JL), I2TOT(JL)) = ZTOT_RWETGH(JL) * ZINV_TSTEP
END DO
IF (BUCONF%LBUDGET_RG) CALL BUDGET_STORE_ADD_PHY(D, TBUDGETS(NBUDGET_RG), 'GHCV', -ZW(:, :)*PRHODJ(:, :))
IF (BUCONF%LBUDGET_RH) CALL BUDGET_STORE_ADD_PHY(D, TBUDGETS(NBUDGET_RH), 'GHCV', ZW(:, :)*PRHODJ(:, :))
END IF
ZW1(:,:) = 0.
DO JL=1, KSIZE
ZW1(I1TOT(JL), I2TOT(JL)) = ZTOT_RCDRYG(JL) * ZINV_TSTEP
END DO
ZW2(:,:) = 0.
DO JL=1, KSIZE
ZW2(I1TOT(JL), I2TOT(JL)) = ZTOT_RRDRYG(JL) * ZINV_TSTEP
END DO
ZW3(:,:) = 0.
DO JL=1, KSIZE
ZW3(I1TOT(JL), I2TOT(JL)) = ZTOT_RIDRYG(JL) * ZINV_TSTEP
END DO
ZW4(:,:) = 0.
DO JL=1, KSIZE
ZW4(I1TOT(JL), I2TOT(JL)) = ZTOT_RSDRYG(JL) * ZINV_TSTEP
END DO
IF (BUCONF%LBUDGET_TH) &
CALL BUDGET_STORE_ADD_PHY(D, TBUDGETS(NBUDGET_TH), 'DRYG', (ZW1(:, :)+ZW2(:, :) )*ZZ_DIFF(:, :)*PRHODJ(:, :))
IF (BUCONF%LBUDGET_RC) CALL BUDGET_STORE_ADD_PHY(D, TBUDGETS(NBUDGET_RC), 'DRYG', -ZW1(:, :) *PRHODJ(:, :))
IF (BUCONF%LBUDGET_RR) CALL BUDGET_STORE_ADD_PHY(D, TBUDGETS(NBUDGET_RR), 'DRYG', -ZW2(:, :) *PRHODJ(:, :))
IF (BUCONF%LBUDGET_RI) CALL BUDGET_STORE_ADD_PHY(D, TBUDGETS(NBUDGET_RI), 'DRYG', -ZW3(:, :) *PRHODJ(:, :))
IF (BUCONF%LBUDGET_RS) CALL BUDGET_STORE_ADD_PHY(D, TBUDGETS(NBUDGET_RS), 'DRYG', -ZW4(:, :) *PRHODJ(:, :))
IF (BUCONF%LBUDGET_RG) CALL BUDGET_STORE_ADD_PHY(D, TBUDGETS(NBUDGET_RG), 'DRYG', (ZW1(:, :)+ZW2(:, :)+ZW3(:, :)+ZW4(:, :)) &
& *PRHODJ(:, :))
ZW(:,:) = 0.
DO JL=1, KSIZE
ZW(I1TOT(JL), I2TOT(JL)) = ZTOT_RGMLTR(JL) * ZINV_TSTEP
END DO
IF (BUCONF%LBUDGET_TH) CALL BUDGET_STORE_ADD_PHY(D, TBUDGETS(NBUDGET_TH), 'GMLT', -ZW(:, :)*ZZ_DIFF(:, :)*PRHODJ(:, :))
IF (BUCONF%LBUDGET_RR) CALL BUDGET_STORE_ADD_PHY(D, TBUDGETS(NBUDGET_RR), 'GMLT', ZW(:, :) *PRHODJ(:, :))
IF (BUCONF%LBUDGET_RG) CALL BUDGET_STORE_ADD_PHY(D, TBUDGETS(NBUDGET_RG), 'GMLT', -ZW(:, :) *PRHODJ(:, :))
IF(KRR==7) THEN
ZW1(:,:) = 0.
DO JL=1, KSIZE
ZW1(I1TOT(JL), I2TOT(JL)) = ZTOT_RCWETH(JL) * ZINV_TSTEP
END DO
ZW2(:,:) = 0.
DO JL=1, KSIZE
ZW2(I1TOT(JL), I2TOT(JL)) = ZTOT_RRWETH(JL) * ZINV_TSTEP
END DO
ZW3(:,:) = 0.
DO JL=1, KSIZE
ZW3(I1TOT(JL), I2TOT(JL)) = ZTOT_RIWETH(JL) * ZINV_TSTEP
END DO
ZW4(:,:) = 0.
DO JL=1, KSIZE
ZW4(I1TOT(JL), I2TOT(JL)) = ZTOT_RSWETH(JL) * ZINV_TSTEP
END DO
ZW5(:,:) = 0.
DO JL=1, KSIZE
ZW5(I1TOT(JL), I2TOT(JL)) = ZTOT_RGWETH(JL) * ZINV_TSTEP
END DO
IF (BUCONF%LBUDGET_TH) &
CALL BUDGET_STORE_ADD_PHY(D, TBUDGETS(NBUDGET_TH), 'WETH', (ZW1(:, :)+ZW2(:, :))*ZZ_DIFF(:, :)*PRHODJ(:, :))
IF (BUCONF%LBUDGET_RC) CALL BUDGET_STORE_ADD_PHY(D, TBUDGETS(NBUDGET_RC), 'WETH', -ZW1(:, :) *PRHODJ(:, :))
IF (BUCONF%LBUDGET_RR) CALL BUDGET_STORE_ADD_PHY(D, TBUDGETS(NBUDGET_RR), 'WETH', -ZW2(:, :) *PRHODJ(:, :))
IF (BUCONF%LBUDGET_RI) CALL BUDGET_STORE_ADD_PHY(D, TBUDGETS(NBUDGET_RI), 'WETH', -ZW3(:, :) *PRHODJ(:, :))
IF (BUCONF%LBUDGET_RS) CALL BUDGET_STORE_ADD_PHY(D, TBUDGETS(NBUDGET_RS), 'WETH', -ZW4(:, :) *PRHODJ(:, :))
#ifdef REPRO48
#else
IF (BUCONF%LBUDGET_RG) CALL BUDGET_STORE_ADD_PHY(D, TBUDGETS(NBUDGET_RG), 'WETH', -ZW5(:, :) *PRHODJ(:, :))
#endif
IF (BUCONF%LBUDGET_RH) CALL BUDGET_STORE_ADD_PHY(D, TBUDGETS(NBUDGET_RH), 'WETH', (ZW1(:, :)+ZW2(:, :)+ZW3(:, :)+ &
&ZW4(:, :)+ZW5(:, : )) *PRHODJ(:, :))
#if defined(REPRO48) || defined(REPRO55)
ZW(:,:) = 0.
DO JL=1, KSIZE
ZW(I1TOT(JL), I2TOT(JL)) = ZTOT_RGWETH(JL) * ZINV_TSTEP
END DO
#endif
#ifdef REPRO48
IF (BUCONF%LBUDGET_RG) CALL BUDGET_STORE_ADD_PHY(D, TBUDGETS(NBUDGET_RG), 'HGCV', (-ZW5(:, :)-ZW(:, :))*PRHODJ(:, :))
#endif
#ifdef REPRO55
IF (BUCONF%LBUDGET_RG) CALL BUDGET_STORE_ADD_PHY(D, TBUDGETS(NBUDGET_RG), 'HGCV', -ZW(:, :)*PRHODJ(:, :))
#endif
#if defined(REPRO48) || defined(REPRO55)
IF (BUCONF%LBUDGET_RH) CALL BUDGET_STORE_ADD_PHY(D, TBUDGETS(NBUDGET_RH), 'HGCV', ZW(:, :)*PRHODJ(:, :))
#endif
ZW1(:,:) = 0.
DO JL=1, KSIZE
ZW1(I1TOT(JL), I2TOT(JL)) = ZTOT_RCDRYH(JL) * ZINV_TSTEP
END DO
ZW2(:,:) = 0.
DO JL=1, KSIZE
ZW2(I1TOT(JL), I2TOT(JL)) = ZTOT_RRDRYH(JL) * ZINV_TSTEP
END DO
ZW3(:,:) = 0.
DO JL=1, KSIZE
ZW3(I1TOT(JL), I2TOT(JL)) = ZTOT_RIDRYH(JL) * ZINV_TSTEP
END DO
ZW4(:,:) = 0.
DO JL=1, KSIZE
ZW4(I1TOT(JL), I2TOT(JL)) = ZTOT_RSDRYH(JL) * ZINV_TSTEP
END DO
ZW5(:,:) = 0.
DO JL=1, KSIZE
ZW5(I1TOT(JL), I2TOT(JL)) = ZTOT_RGDRYH(JL) * ZINV_TSTEP
END DO
ZW6(:,:) = 0.
#if defined(REPRO48) || defined(REPRO55)
!ZW6 must be removed when REPRO* will be suppressed
DO JL=1, KSIZE
ZW6(I1TOT(JL), I2TOT(JL)) = ZTOT_RDRYHG(JL) * ZINV_TSTEP
END DO
#endif
IF (BUCONF%LBUDGET_TH) &
CALL BUDGET_STORE_ADD_PHY(D, TBUDGETS(NBUDGET_TH), 'DRYH', (ZW1(:, :)+ZW2(:, :))*ZZ_DIFF(:, :)*PRHODJ(:, :))
IF (BUCONF%LBUDGET_RC) CALL BUDGET_STORE_ADD_PHY(D, TBUDGETS(NBUDGET_RC), 'DRYH', -ZW1(:, :) *PRHODJ(:, :))
IF (BUCONF%LBUDGET_RR) CALL BUDGET_STORE_ADD_PHY(D, TBUDGETS(NBUDGET_RR), 'DRYH', -ZW2(:, :) *PRHODJ(:, :))
IF (BUCONF%LBUDGET_RI) CALL BUDGET_STORE_ADD_PHY(D, TBUDGETS(NBUDGET_RI), 'DRYH', -ZW3(:, :) *PRHODJ(:, :))
IF (BUCONF%LBUDGET_RS) CALL BUDGET_STORE_ADD_PHY(D, TBUDGETS(NBUDGET_RS), 'DRYH', -ZW4(:, :) *PRHODJ(:, :))
IF (BUCONF%LBUDGET_RG) CALL BUDGET_STORE_ADD_PHY(D, TBUDGETS(NBUDGET_RG), 'DRYH', (-ZW5(:, :)+ZW6(:, :)) *PRHODJ(:, :))
IF (BUCONF%LBUDGET_RH) CALL BUDGET_STORE_ADD_PHY(D, TBUDGETS(NBUDGET_RH), 'DRYH', (ZW1(:, :)+ZW2(:, :)+ZW3(:, :)+ &
&ZW4(:, :)+ZW5(:, :)-ZW6(:, :)) &
& *PRHODJ(:, :))
#if defined(REPRO48) || defined(REPRO55)
#else
!When REPRO48 will be suppressed, ZW6 must be removed
ZW(:,:) = 0.
DO JL=1, KSIZE
ZW(I1TOT(JL), I2TOT(JL)) = ZTOT_RDRYHG(JL) * ZINV_TSTEP
END DO
IF (BUCONF%LBUDGET_RG) CALL BUDGET_STORE_ADD_PHY(D, TBUDGETS(NBUDGET_RG), 'HGCV', -ZW(:, :)*PRHODJ(:, :))
IF (BUCONF%LBUDGET_RH) CALL BUDGET_STORE_ADD_PHY(D, TBUDGETS(NBUDGET_RH), 'HGCV', ZW(:, :)*PRHODJ(:, :))
#endif
ZW(:,:) = 0.
DO JL=1, KSIZE
ZW(I1TOT(JL), I2TOT(JL)) = ZTOT_RHMLTR(JL) * ZINV_TSTEP
END DO
IF (BUCONF%LBUDGET_TH) CALL BUDGET_STORE_ADD_PHY(D, TBUDGETS(NBUDGET_TH), 'HMLT', -ZW(:, :)*ZZ_DIFF(:, :)*PRHODJ(:, :))
IF (BUCONF%LBUDGET_RR) CALL BUDGET_STORE_ADD_PHY(D, TBUDGETS(NBUDGET_RR), 'HMLT', ZW(:, :) *PRHODJ(:, :))
IF (BUCONF%LBUDGET_RH) CALL BUDGET_STORE_ADD_PHY(D, TBUDGETS(NBUDGET_RH), 'HMLT', -ZW(:, :) *PRHODJ(:, :))
ENDIF
ZW(:,:) = 0.
DO JL=1, KSIZE
ZW(I1TOT(JL), I2TOT(JL)) = ZTOT_RIMLTC(JL) * ZINV_TSTEP
END DO
IF (BUCONF%LBUDGET_TH) CALL BUDGET_STORE_ADD_PHY(D, TBUDGETS(NBUDGET_TH), 'IMLT', -ZW(:, :)*ZZ_DIFF(:, :)*PRHODJ(:, :))
IF (BUCONF%LBUDGET_RC) CALL BUDGET_STORE_ADD_PHY(D, TBUDGETS(NBUDGET_RC), 'IMLT', ZW(:, :) *PRHODJ(:, :))
IF (BUCONF%LBUDGET_RI) CALL BUDGET_STORE_ADD_PHY(D, TBUDGETS(NBUDGET_RI), 'IMLT', -ZW(:, :) *PRHODJ(:, :))
ZW(:,:) = 0.
DO JL=1, KSIZE
ZW(I1TOT(JL), I2TOT(JL)) = ZTOT_RCBERI(JL) * ZINV_TSTEP
END DO
IF (BUCONF%LBUDGET_TH) CALL BUDGET_STORE_ADD_PHY(D, TBUDGETS(NBUDGET_TH), 'BERFI', ZW(:, :)*ZZ_DIFF(:, :)*PRHODJ(:, :))
IF (BUCONF%LBUDGET_RC) CALL BUDGET_STORE_ADD_PHY(D, TBUDGETS(NBUDGET_RC), 'BERFI', -ZW(:, :) *PRHODJ(:, :))
IF (BUCONF%LBUDGET_RI) CALL BUDGET_STORE_ADD_PHY(D, TBUDGETS(NBUDGET_RI), 'BERFI', ZW(:, :) *PRHODJ(:, :))
ENDIF
!
!*** 7.3 Final tendencies
!
IF (BUCONF%LBU_ENABLE) THEN
IF (BUCONF%LBUDGET_TH) CALL BUDGET_STORE_INIT_PHY(D, TBUDGETS(NBUDGET_TH), 'CORR', PTHS(:, :)*PRHODJ(:, :))
IF (BUCONF%LBUDGET_RV) CALL BUDGET_STORE_INIT_PHY(D, TBUDGETS(NBUDGET_RV), 'CORR', PRVS(:, :)*PRHODJ(:, :))
IF (BUCONF%LBUDGET_RC) CALL BUDGET_STORE_INIT_PHY(D, TBUDGETS(NBUDGET_RC), 'CORR', PRCS(:, :)*PRHODJ(:, :))
IF (BUCONF%LBUDGET_RR) CALL BUDGET_STORE_INIT_PHY(D, TBUDGETS(NBUDGET_RR), 'CORR', PRSS(:, :)*PRHODJ(:, :))
IF (BUCONF%LBUDGET_RI) CALL BUDGET_STORE_INIT_PHY(D, TBUDGETS(NBUDGET_RI), 'CORR', PRIS(:, :)*PRHODJ(:, :))
IF (BUCONF%LBUDGET_RS) CALL BUDGET_STORE_INIT_PHY(D, TBUDGETS(NBUDGET_RS), 'CORR', PRSS(:, :)*PRHODJ(:, :))
IF (BUCONF%LBUDGET_RG) CALL BUDGET_STORE_INIT_PHY(D, TBUDGETS(NBUDGET_RG), 'CORR', PRGS(:, :)*PRHODJ(:, :))
IF (BUCONF%LBUDGET_RH .AND. KRR==7) CALL BUDGET_STORE_INIT_PHY(D, TBUDGETS(NBUDGET_RH), 'CORR', PRHS(:, :)*PRHODJ(:, :))
END IF
!NOTE:
! This call cannot be moved before the preeceding budget calls because,
! with AROME, the BUDGET_STORE_INIT does nothing. The equivalent is done only
! once before the physics call and copies of the S variables evolve automatically
! internally to the budget (DDH) machinery at each BUDGET_STORE_ADD and
! BUDGET_STORE_END calls. Thus, the difference between the DDH internal version
! of the S variables and the S variables used in the folowing BUDGET_STORE_END
! call must only be due to the correction of negativities.
!
!We correct negativities with conservation
CALL CORRECT_NEGATIVITIES(D, KRR, PRVS, PRCS, PRRS, &
&PRIS, PRSS, PRGS, &
&PTHS, ZZ_LVFACT, ZZ_LSFACT, PRHS)
IF (BUCONF%LBU_ENABLE) THEN
IF (BUCONF%LBUDGET_TH) CALL BUDGET_STORE_END_PHY(D, TBUDGETS(NBUDGET_TH), 'CORR', PTHS(:, :)*PRHODJ(:, :))
IF (BUCONF%LBUDGET_RV) CALL BUDGET_STORE_END_PHY(D, TBUDGETS(NBUDGET_RV), 'CORR', PRVS(:, :)*PRHODJ(:, :))
IF (BUCONF%LBUDGET_RC) CALL BUDGET_STORE_END_PHY(D, TBUDGETS(NBUDGET_RC), 'CORR', PRCS(:, :)*PRHODJ(:, :))
IF (BUCONF%LBUDGET_RR) CALL BUDGET_STORE_END_PHY(D, TBUDGETS(NBUDGET_RR), 'CORR', PRRS(:, :)*PRHODJ(:, :))
IF (BUCONF%LBUDGET_RI) CALL BUDGET_STORE_END_PHY(D, TBUDGETS(NBUDGET_RI), 'CORR', PRIS(:, :)*PRHODJ(:, :))
IF (BUCONF%LBUDGET_RS) CALL BUDGET_STORE_END_PHY(D, TBUDGETS(NBUDGET_RS), 'CORR', PRSS(:, :)*PRHODJ(:, :))
IF (BUCONF%LBUDGET_RG) CALL BUDGET_STORE_END_PHY(D, TBUDGETS(NBUDGET_RG), 'CORR', PRGS(:, :)*PRHODJ(:, :))
IF (BUCONF%LBUDGET_RH .AND. KRR==7) CALL BUDGET_STORE_END_PHY(D, TBUDGETS(NBUDGET_RH), 'CORR', PRHS(:, :)*PRHODJ(:, :))
END IF
!
!-------------------------------------------------------------------------------
!
!* 8. COMPUTE THE SEDIMENTATION (RS) SOURCE
! -------------------------------------
!
IF(PARAMI%LSEDIM_AFTER) THEN
!
!* 8.1 sedimentation
!
IF (BUCONF%LBUDGET_RC .AND. OSEDIC) CALL BUDGET_STORE_INIT_PHY(D, TBUDGETS(NBUDGET_RC), 'SEDI', PRCS(:, :) * PRHODJ(:, :))
IF (BUCONF%LBUDGET_RR) CALL BUDGET_STORE_INIT_PHY(D, TBUDGETS(NBUDGET_RR), 'SEDI', PRRS(:, :) * PRHODJ(:, :))
IF (BUCONF%LBUDGET_RI) CALL BUDGET_STORE_INIT_PHY(D, TBUDGETS(NBUDGET_RI), 'SEDI', PRIS(:, :) * PRHODJ(:, :))
IF (BUCONF%LBUDGET_RS) CALL BUDGET_STORE_INIT_PHY(D, TBUDGETS(NBUDGET_RS), 'SEDI', PRSS(:, :) * PRHODJ(:, :))
IF (BUCONF%LBUDGET_RG) CALL BUDGET_STORE_INIT_PHY(D, TBUDGETS(NBUDGET_RG), 'SEDI', PRGS(:, :) * PRHODJ(:, :))
IF (BUCONF%LBUDGET_RH .AND. KRR==7) CALL BUDGET_STORE_INIT_PHY(D, TBUDGETS(NBUDGET_RH), 'SEDI', PRHS(:, :) * PRHODJ(:, :))
IF(HSEDIM=='STAT') THEN
IF (KRR==7) THEN
DO JK = D%NKTB,D%NKTE
DO JIJ = D%NIJB,D%NIJE
ZRCT(JIJ,JK)=PRCS(JIJ,JK)*PTSTEP
ZRRT(JIJ,JK)=PRRS(JIJ,JK)*PTSTEP
ZRIT(JIJ,JK)=PRIS(JIJ,JK)*PTSTEP
ZRST(JIJ,JK)=PRSS(JIJ,JK)*PTSTEP
ZRGT(JIJ,JK)=PRGS(JIJ,JK)*PTSTEP
ZRHT(JIJ,JK)=PRHS(JIJ,JK)*PTSTEP
ENDDO
ENDDO
CALL ICE4_SEDIMENTATION_STAT(D, CST, ICEP, ICED, &
&PTSTEP, KRR, OSEDIC, PDZZ, &
&PRHODREF, PPABST, PTHT, PRHODJ, &
&PRCS, ZRCT, PRRS, ZRRT, PRIS, ZRIT,&
&PRSS, ZRST, PRGS, ZRGT,&
&PINPRC, PINPRR, ZINPRI, PINPRS, PINPRG, &
&PSEA=PSEA, PTOWN=PTOWN, &
&PINPRH=PINPRH, PRHT=ZRHT, PRHS=PRHS, PFPR=PFPR)
ELSE
DO JK = D%NKTB,D%NKTE
DO JIJ = D%NIJB,D%NIJE
ZRCT(JIJ,JK)=PRCS(JIJ,JK)*PTSTEP
ZRRT(JIJ,JK)=PRRS(JIJ,JK)*PTSTEP
ZRIT(JIJ,JK)=PRIS(JIJ,JK)*PTSTEP
ZRST(JIJ,JK)=PRSS(JIJ,JK)*PTSTEP
ZRGT(JIJ,JK)=PRGS(JIJ,JK)*PTSTEP
ENDDO
ENDDO
CALL ICE4_SEDIMENTATION_STAT(D, CST, ICEP, ICED, &
&PTSTEP, KRR, OSEDIC, PDZZ, &
&PRHODREF, PPABST, PTHT, PRHODJ, &
&PRCS, ZRCT, PRRS, ZRRT, PRIS, ZRIT,&
&PRSS, ZRST, PRGS, ZRGT,&
&PINPRC, PINPRR, ZINPRI, PINPRS, PINPRG, &
&PSEA=PSEA, PTOWN=PTOWN, &
&PFPR=PFPR)
ENDIF
PINPRS(D%NIJB:D%NIJE) = PINPRS(D%NIJB:D%NIJE) + ZINPRI(D%NIJB:D%NIJE)
!No negativity correction here as we apply sedimentation on PR.S*PTSTEP variables
ELSEIF(HSEDIM=='SPLI') THEN
!SR: It *seems* that we must have two separate calls for ifort
IF(KRR==7) THEN
CALL ICE4_SEDIMENTATION_SPLIT(D, CST, ICEP, ICED, PARAMI, &
&PTSTEP, KRR, OSEDIC, PDZZ, &
&PRHODREF, PPABST, PTHT, ZT, PRHODJ, &
&PRCS, PRCT, PRRS, PRRT, PRIS, PRIT, PRSS, PRST, PRGS, PRGT,&
&PINPRC, PINPRR, ZINPRI, PINPRS, PINPRG, &
&PSEA=PSEA, PTOWN=PTOWN, &
&PINPRH=PINPRH, PRHT=PRHT, PRHS=PRHS, PFPR=PFPR)
ELSE
CALL ICE4_SEDIMENTATION_SPLIT(D, CST, ICEP, ICED, PARAMI, &
&PTSTEP, KRR, OSEDIC, PDZZ, &
&PRHODREF, PPABST, PTHT, ZT, PRHODJ, &
&PRCS, PRCT, PRRS, PRRT, PRIS, PRIT, PRSS, PRST, PRGS, PRGT,&
&PINPRC, PINPRR, ZINPRI, PINPRS, PINPRG, &
&PSEA=PSEA, PTOWN=PTOWN, &
&PFPR=PFPR)
ENDIF
PINPRS(D%NIJB:D%NIJE) = PINPRS(D%NIJB:D%NIJE) + ZINPRI(D%NIJB:D%NIJE)
!We correct negativities with conservation
!SPLI algorith uses a time-splitting. Inside the loop a temporary m.r. is used.
! It is initialized with the m.r. at T and is modified by two tendencies:
! sedimentation tendency and an external tendency which represents all other
! processes (mainly advection and microphysical processes). If both tendencies
! are negative, sedimentation can remove a species at a given sub-timestep. From
! this point sedimentation stops for the remaining sub-timesteps but the other tendency
! will be still active and will lead to negative values.
! We could prevent the algorithm to not consume too much a species, instead we apply
! a correction here.
CALL CORRECT_NEGATIVITIES(D, KRR, PRVS, PRCS, PRRS, &
&PRIS, PRSS, PRGS, &
&PTHS, ZZ_LVFACT, ZZ_LSFACT, PRHS)
ELSE
CALL PRINT_MSG(NVERB_FATAL, 'GEN', 'RAIN_ICE', 'no sedimentation scheme for HSEDIM='//HSEDIM)
END IF
!
!* 8.2 budget storage
!
IF (BUCONF%LBUDGET_RC .AND. OSEDIC) CALL BUDGET_STORE_END_PHY(D, TBUDGETS(NBUDGET_RC), 'SEDI', PRCS(:, :) * PRHODJ(:, :))
IF (BUCONF%LBUDGET_RR) CALL BUDGET_STORE_END_PHY(D, TBUDGETS(NBUDGET_RR), 'SEDI', PRRS(:, :) * PRHODJ(:, :))
IF (BUCONF%LBUDGET_RI) CALL BUDGET_STORE_END_PHY(D, TBUDGETS(NBUDGET_RI), 'SEDI', PRIS(:, :) * PRHODJ(:, :))
IF (BUCONF%LBUDGET_RS) CALL BUDGET_STORE_END_PHY(D, TBUDGETS(NBUDGET_RS), 'SEDI', PRSS(:, :) * PRHODJ(:, :))
IF (BUCONF%LBUDGET_RG) CALL BUDGET_STORE_END_PHY(D, TBUDGETS(NBUDGET_RG), 'SEDI', PRGS(:, :) * PRHODJ(:, :))
IF (BUCONF%LBUDGET_RH .AND. KRR==7) CALL BUDGET_STORE_END_PHY(D, TBUDGETS(NBUDGET_RH), 'SEDI', PRHS(:, :) * PRHODJ(:, :))
!"sedimentation" of rain fraction
IF (PRESENT(PRHS)) THEN
CALL ICE4_RAINFR_VERT(D, ICED, PRAINFR, PRRS(:,:)*PTSTEP, &
&PRSS(:,:)*PTSTEP, PRGS(:,:)*PTSTEP, PRHS(:,:)*PTSTEP)
ELSE
CALL ICE4_RAINFR_VERT(D, ICED, PRAINFR, PRRS(:,:)*PTSTEP, &
&PRSS(:,:)*PTSTEP, PRGS(:,:)*PTSTEP)
ENDIF
ENDIF
!
!-------------------------------------------------------------------------------
!
!* 9. COMPUTE THE FOG DEPOSITION TERM
! -------------------------------------
!
IF (PARAMI%LDEPOSC) THEN !cloud water deposition on vegetation
IF (BUCONF%LBU_ENABLE .AND. BUCONF%LBUDGET_RC) &
& CALL BUDGET_STORE_INIT_PHY(D, TBUDGETS(NBUDGET_RC), 'DEPO', PRCS(:, :)*PRHODJ(:, :))
PINDEP(:)=0.
!DEC$ IVDEP
DO JIJ = D%NIJB, D%NIJE
PINDEP(JIJ) = PARAMI%XVDEPOSC * PRCT(JIJ, D%NKB) * PRHODREF(JIJ, D%NKB) / CST%XRHOLW
PRCS(JIJ, D%NKB) = PRCS(JIJ, D%NKB) - PARAMI%XVDEPOSC * PRCT(JIJ, D%NKB) / PDZZ(JIJ, D%NKB)
PINPRC(JIJ) = PINPRC(JIJ) + PINDEP(JIJ)
ENDDO
IF (BUCONF%LBU_ENABLE .AND. BUCONF%LBUDGET_RC) &
& CALL BUDGET_STORE_END_PHY(D, TBUDGETS(NBUDGET_RC), 'DEPO', PRCS(:, :)*PRHODJ(:, :))
ENDIF
IF (LHOOK) CALL DR_HOOK('RAIN_ICE', 1, ZHOOK_HANDLE)
!
CONTAINS
!
SUBROUTINE CORRECT_NEGATIVITIES(D, KRR, PRV, PRC, PRR, &
&PRI, PRS, PRG, &
&PTH, PLVFACT, PLSFACT, PRH)
!
IMPLICIT NONE
!
TYPE(DIMPHYEX_t), INTENT(IN) :: D
INTEGER, INTENT(IN) :: KRR
REAL, DIMENSION(D%NIJT, D%NKT), INTENT(INOUT) :: PRV, PRC, PRR, PRI, PRS, PRG, PTH
REAL, DIMENSION(D%NIJT, D%NKT), INTENT(IN) :: PLVFACT, PLSFACT
REAL, DIMENSION(D%NIJT, D%NKT), OPTIONAL, INTENT(INOUT) :: PRH
!
REAL :: ZW
INTEGER :: JIJ, JK
REAL(KIND=JPRB) :: ZHOOK_HANDLE
!
IF (LHOOK) CALL DR_HOOK('RAIN_ICE:CORRECT_NEGATIVITIES', 0, ZHOOK_HANDLE)
!
!We correct negativities with conservation
DO JK = D%NKTB, D%NKTE
DO JIJ = D%NIJB, D%NIJE
! 1) deal with negative values for mixing ratio, except for vapor
ZW =PRC(JIJ,JK)-MAX(PRC(JIJ,JK), 0.)
PRV(JIJ,JK)=PRV(JIJ,JK)+ZW
PTH(JIJ,JK)=PTH(JIJ,JK)-ZW*PLVFACT(JIJ,JK)
PRC(JIJ,JK)=PRC(JIJ,JK)-ZW
ZW =PRR(JIJ,JK)-MAX(PRR(JIJ,JK), 0.)
PRV(JIJ,JK)=PRV(JIJ,JK)+ZW
PTH(JIJ,JK)=PTH(JIJ,JK)-ZW*PLVFACT(JIJ,JK)
PRR(JIJ,JK)=PRR(JIJ,JK)-ZW
ZW =PRI(JIJ,JK)-MAX(PRI(JIJ,JK), 0.)
PRV(JIJ,JK)=PRV(JIJ,JK)+ZW
PTH(JIJ,JK)=PTH(JIJ,JK)-ZW*PLSFACT(JIJ,JK)
PRI(JIJ,JK)=PRI(JIJ,JK)-ZW
ZW =PRS(JIJ,JK)-MAX(PRS(JIJ,JK), 0.)
PRV(JIJ,JK)=PRV(JIJ,JK)+ZW
PTH(JIJ,JK)=PTH(JIJ,JK)-ZW*PLSFACT(JIJ,JK)
PRS(JIJ,JK)=PRS(JIJ,JK)-ZW
ZW =PRG(JIJ,JK)-MAX(PRG(JIJ,JK), 0.)
PRV(JIJ,JK)=PRV(JIJ,JK)+ZW
PTH(JIJ,JK)=PTH(JIJ,JK)-ZW*PLSFACT(JIJ,JK)
PRG(JIJ,JK)=PRG(JIJ,JK)-ZW
IF(KRR==7) THEN
ZW =PRH(JIJ,JK)-MAX(PRH(JIJ,JK), 0.)
PRV(JIJ,JK)=PRV(JIJ,JK)+ZW
PTH(JIJ,JK)=PTH(JIJ,JK)-ZW*PLSFACT(JIJ,JK)
PRH(JIJ,JK)=PRH(JIJ,JK)-ZW
ENDIF
! 2) deal with negative vapor mixing ratio
! for rc and ri, we keep ice fraction constant
ZW=MIN(1., MAX(ICED%XRTMIN(1)-PRV(JIJ,JK), 0.) / &
&MAX(PRC(JIJ,JK)+PRI(JIJ,JK), 1.E-20)) ! Proportion of rc+ri to convert into rv
PTH(JIJ,JK)=PTH(JIJ,JK)-ZW* &
&(PRC(JIJ,JK)*PLVFACT(JIJ,JK)+PRI(JIJ,JK)*PLSFACT(JIJ,JK))
PRV(JIJ,JK)=PRV(JIJ,JK)+ZW*(PRC(JIJ,JK)+PRI(JIJ,JK))
PRC(JIJ,JK)=(1.-ZW)*PRC(JIJ,JK)
PRI(JIJ,JK)=(1.-ZW)*PRI(JIJ,JK)
ZW=MIN(MAX(PRR(JIJ,JK), 0.), &
&MAX(ICED%XRTMIN(1)-PRV(JIJ,JK), 0.)) ! Quantity of rr to convert into rv
PRV(JIJ,JK)=PRV(JIJ,JK)+ZW
PRR(JIJ,JK)=PRR(JIJ,JK)-ZW
PTH(JIJ,JK)=PTH(JIJ,JK)-ZW*PLVFACT(JIJ,JK)
ZW=MIN(MAX(PRS(JIJ,JK), 0.), &
&MAX(ICED%XRTMIN(1)-PRV(JIJ,JK), 0.)) ! Quantity of rs to convert into rv
PRV(JIJ,JK)=PRV(JIJ,JK)+ZW
PRS(JIJ,JK)=PRS(JIJ,JK)-ZW
PTH(JIJ,JK)=PTH(JIJ,JK)-ZW*PLSFACT(JIJ,JK)
ZW=MIN(MAX(PRG(JIJ,JK), 0.), &
&MAX(ICED%XRTMIN(1)-PRV(JIJ,JK), 0.)) ! Quantity of rg to convert into rv
PRV(JIJ,JK)=PRV(JIJ,JK)+ZW
PRG(JIJ,JK)=PRG(JIJ,JK)-ZW
PTH(JIJ,JK)=PTH(JIJ,JK)-ZW*PLSFACT(JIJ,JK)
IF(KRR==7) THEN
ZW=MIN(MAX(PRH(JIJ,JK), 0.), &
&MAX(ICED%XRTMIN(1)-PRV(JIJ,JK), 0.)) ! Quantity of rh to convert into rv
PRV(JIJ,JK)=PRV(JIJ,JK)+ZW
PRH(JIJ,JK)=PRH(JIJ,JK)-ZW
PTH(JIJ,JK)=PTH(JIJ,JK)-ZW*PLSFACT(JIJ,JK)
ENDIF
ENDDO
ENDDO
!
IF (LHOOK) CALL DR_HOOK('RAIN_ICE:CORRECT_NEGATIVITIES', 1, ZHOOK_HANDLE)
!
END SUBROUTINE CORRECT_NEGATIVITIES
!
END SUBROUTINE RAIN_ICE