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RODIER Quentin
Méso-NH code
Commits
a5fac966
Commit
a5fac966
authored
2 years ago
by
ESCOBAR MUNOZ Juan
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Juan 02/03/2023:ZSOLVER/dyn_sources.f90, GPU version by Naima
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0452194c
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a5fac966
!MNH_LIC Copyright 1994-2021 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.
!-----------------------------------------------------------------
! #######################
MODULE
MODI_DYN_SOURCES
! #######################
!
INTERFACE
!
SUBROUTINE
DYN_SOURCES
(
KRR
,
KRRL
,
KRRI
,
&
PUT
,
PVT
,
PWT
,
PTHT
,
PRT
,
&
PCORIOX
,
PCORIOY
,
PCORIOZ
,
PCURVX
,
PCURVY
,
&
PRHODJ
,
PZZ
,
PTHVREF
,
PEXNREF
,
&
PRUS
,
PRVS
,
PRWS
,
PRTHS
)
!
INTEGER
,
INTENT
(
IN
)
::
KRR
! Total number of water var.
INTEGER
,
INTENT
(
IN
)
::
KRRL
! Number of liquid water var.
INTEGER
,
INTENT
(
IN
)
::
KRRI
! Number of ice water var.
!
REAL
,
DIMENSION
(:,:,:),
INTENT
(
IN
)
::
PUT
,
PVT
,
PWT
! variables
REAL
,
DIMENSION
(:,:,:),
INTENT
(
IN
)
::
PTHT
! at
REAL
,
DIMENSION
(:,:,:,:),
INTENT
(
IN
)
::
PRT
! time t
!
REAL
,
DIMENSION
(:,:),
INTENT
(
IN
)
::
PCORIOX
! 2D horizontal
REAL
,
DIMENSION
(:,:),
INTENT
(
IN
)
::
PCORIOY
! Coriolis
REAL
,
DIMENSION
(:,:),
INTENT
(
IN
)
::
PCORIOZ
! factors
REAL
,
DIMENSION
(:,:),
INTENT
(
IN
)
::
PCURVX
! 2D horizontal
REAL
,
DIMENSION
(:,:),
INTENT
(
IN
)
::
PCURVY
! curvature factors
!
REAL
,
DIMENSION
(:,:,:),
INTENT
(
IN
)
::
PRHODJ
! Density * Jacobian
REAL
,
DIMENSION
(:,:,:),
INTENT
(
IN
)
::
PZZ
! Height (z)
REAL
,
DIMENSION
(:,:,:),
INTENT
(
IN
)
::
PTHVREF
! Virtual Temperature
! of the reference state
REAL
,
DIMENSION
(:,:,:),
INTENT
(
IN
)
::
PEXNREF
! Exner function
! of the reference state
!
REAL
,
DIMENSION
(:,:,:),
INTENT
(
INOUT
)
::
PRUS
,
PRVS
,
PRWS
! Sources of Momentum
REAL
,
DIMENSION
(:,:,:),
INTENT
(
INOUT
)
::
PRTHS
! Sources of theta
!
END
SUBROUTINE
DYN_SOURCES
!
END
INTERFACE
!
END
MODULE
MODI_DYN_SOURCES
! ######################################################################
SUBROUTINE
DYN_SOURCES
(
KRR
,
KRRL
,
KRRI
,
&
PUT
,
PVT
,
PWT
,
PTHT
,
PRT
,
&
PCORIOX
,
PCORIOY
,
PCORIOZ
,
PCURVX
,
PCURVY
,
&
PRHODJ
,
PZZ
,
PTHVREF
,
PEXNREF
,
&
PRUS
,
PRVS
,
PRWS
,
PRTHS
)
! ######################################################################
!
!!**** *DYN_SOURCES * - routine to compute the curvature, coriolis and gravity terms
!!
!! PURPOSE
!! -------
!! The purpose of this routine is to compute the dynamical sources
!! (curvature, coriolis and gravity terms) for each component of the
!! momentum. The curvature terms arise in case of non-cartesian geometry
!! only. For both curvature and coriolis terms, the "thin shell"
!! approximation can be assumed or not. Gravity affects only the vertical
!! component of the momentum.
!! This routine also adds the Lagrangien derivative of the pressure as a
!! source for the theta evolution.
!!
!!
!!** METHOD
!! ------
!! The horizontal curvature and coriolis field arrays are expanded in
!! the vertical direction with the SPREAD intrinsics to match with the
!! Shuman operators. The source term for theta due to the advection of the
!! Exner function is treated in an advective form (or non-conservative form).
!! Values of the calorific capacity of the melting and of the potential
!! virtual temperature are recovered taking care of the number of water
!! variables. The different sources terms are stored for the budget
!! computations.
!!
!! EXTERNAL
!! --------
!! MXM,MYM,MZM : Shuman functions (mean operators)
!! MXF,MYF,MZF : Shuman functions (mean operators)
!! GZ_M_W : projection along the vertical direction of the gradient
!! vector. It acts on a field localized in mass point and
!! the result is localized in w point.
!! BUDGET : Stores the different budget components
!!
!! IMPLICIT ARGUMENTS
!! ------------------
!! Module MODD_CONF : contains configuration variables for all models
!! LTHINSHELL = .TRUE. if the THINSHELL approximation is made
!! LCARTESIAN = .TRUE. if the CARTESIAN approximation is made
!! Module MODD_CST :
!! XG gravity acceleration
!! XRADIUS Earth radius
!! XRD,XRV Gas constant for dry air and wator vapor
!! XCPD,XCPV Cp for dry air and wator vapor
!! XCL,XCI C (calorific capacity) for liquid and solid water
!! Module MODD_DYN : contains the parameters for the dynamics
!! LCORIO = .FALSE. if the earth rotation is neglected
!!
!! 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_RU : logical for budget of RU (wind component along x)
!! .TRUE. = budget of RU
!! .FALSE. = no budget of RU
!! LBU_RV : logical for budget of RV (wind component along y)
!! .TRUE. = budget of RV
!! .FALSE. = no budget of RV
!! LBU_RW : logical for budget of RW (wind component along z)
!! .TRUE. = budget of RW
!! .FALSE. = no budget of RW
!!
!! REFERENCE
!! ---------
!! Book2 of documentation ( routine DYN_SOURCE )
!!
!! AUTHOR
!! ------
!! J.-P. Pinty * Laboratoire d'Aerologie*
!!
!! MODIFICATIONS
!! -------------
!! Original 06/06/94
!! Corrections 06/08/94 (J.-P. Lafore)
!! Corrections 17/10/94 (Stein) For LCORIO
!! Corrections 22/12/94 (Stein) add the pressure term in the theta evolution
!! Corrections 30/12/94 (J.P. Lafore) bug corrections for the pressure term
!! Corrections 16/03/95 (Stein) remove R from the historical variables and
!! correction of the pressure term
!! Corrections 14/04/95 (Masson Stein) bugs in the curvatureand Coriolis
!! terms for PRUS,PRVS, PRWS
!! Corrections 01/04/95 (Ph. Hereil J. Nicolau) add the budget computation
!! Corrections 16/10/95 (J. Stein) change the budget calls
!! Corrections 16/02/96 (J.-P. Pinty) Introduce L1D switches
!! Corrections 19/12/96 (J.-P. Pinty) Update the CALL BUDGET
!! Corrections 03/12/02 (P. Jabouille) add no thinshell condition
!! Correction 06/10 (C.Lac) Exclude L1D for Coriolis term
!! Modification 03/11 (C.Lac) Split the gravity term due to buoyancy
!! J.Escobar : 15/09/2015 : WENO5 & JPHEXT <> 1
! P. Wautelet 02/2020: use the new data structures and subroutines for budgets
!-------------------------------------------------------------------------------
!
!* 0. DECLARATIONS
! ------------
!
use
modd_budget
,
only
:
lbudget_u
,
lbudget_v
,
lbudget_w
,
lbudget_th
,
&
NBUDGET_U
,
NBUDGET_V
,
NBUDGET_W
,
NBUDGET_TH
,
&
tbudgets
USE
MODD_CONF
USE
MODD_CST
USE
MODD_DYN
USE
MODD_DYN_n
,
ONLY
:
LOCEAN
!
use
mode_budget
,
only
:
Budget_store_init
,
Budget_store_end
USE
MODE_MPPDB
USE
MODI_GRADIENT_M
USE
MODI_SHUMAN
#ifdef MNH_OPENACC
USE
MODI_SHUMAN_DEVICE
#endif
#ifdef MNH_OPENACC
USE
MODE_DEVICE
USE
MODE_MNH_ZWORK
,
ONLY
:
MNH_MEM_GET
,
MNH_MEM_POSITION_PIN
,
MNH_MEM_RELEASE
#endif
IMPLICIT
NONE
!
!* 0.1 Declarations of dummy arguments :
!
INTEGER
,
INTENT
(
IN
)
::
KRR
! Total number of water var.
INTEGER
,
INTENT
(
IN
)
::
KRRL
! Number of liquid water var.
INTEGER
,
INTENT
(
IN
)
::
KRRI
! Number of ice water var.
!
REAL
,
DIMENSION
(:,:,:),
INTENT
(
IN
)
::
PUT
,
PVT
,
PWT
! variables
REAL
,
DIMENSION
(:,:,:),
INTENT
(
IN
)
::
PTHT
! at
REAL
,
DIMENSION
(:,:,:,:),
INTENT
(
IN
)
::
PRT
! time t
!
REAL
,
DIMENSION
(:,:),
INTENT
(
IN
)
::
PCORIOX
! 2D horizontal
REAL
,
DIMENSION
(:,:),
INTENT
(
IN
)
::
PCORIOY
! Coriolis
REAL
,
DIMENSION
(:,:),
INTENT
(
IN
)
::
PCORIOZ
! factors
REAL
,
DIMENSION
(:,:),
INTENT
(
IN
)
::
PCURVX
! 2D horizontal
REAL
,
DIMENSION
(:,:),
INTENT
(
IN
)
::
PCURVY
! curvature factors
!
REAL
,
DIMENSION
(:,:,:),
INTENT
(
IN
)
::
PRHODJ
! dry Density * Jacobian
REAL
,
DIMENSION
(:,:,:),
INTENT
(
IN
)
::
PZZ
! Height (z)
REAL
,
DIMENSION
(:,:,:),
INTENT
(
IN
)
::
PTHVREF
! Virtual Temperature
! of the reference state
REAL
,
DIMENSION
(:,:,:),
INTENT
(
IN
)
::
PEXNREF
! Exner function
! of the reference state
!
REAL
,
DIMENSION
(:,:,:),
INTENT
(
INOUT
)
::
PRUS
,
PRVS
,
PRWS
! Sources of Momentum
REAL
,
DIMENSION
(:,:,:),
INTENT
(
INOUT
)
::
PRTHS
! Sources of theta
!
!
!* 0.2 Declarations of local variables :
!
REAL
::
ZCPD_OV_RD
! = CPD / RD
REAL
::
ZG_OV_CPD
! =-XG / XCPD
INTEGER
::
JWATER
! loop index on the different types of water
INTEGER
::
JIU
,
JJU
,
JKU
INTEGER
::
JI
,
JJ
,
JK
INTEGER
::
IKU
! array size along the k direction
REAL
::
ZD1
! DELTA1 (switch 0/1) for thinshell approximation
#ifndef MNH_OPENACC
REAL
,
DIMENSION
(
SIZE
(
PUT
,
1
),
SIZE
(
PUT
,
2
),
SIZE
(
PUT
,
3
))
::
&
ZWORK1
,
ZWORK2
,
ZWORK3
,
ZRUT
,
ZRVT
#else
REAL
,
DIMENSION
(:,:,:),
pointer
,
contiguous
::
ZWORK1
,
ZWORK2
,
ZWORK3
,
ZRUT
,
ZRVT
#endif
#ifdef MNH_OPENACC
REAL
,
DIMENSION
(:,:,:),
pointer
,
contiguous
::
ZTMP1_DEVICE
,
ZTMP2_DEVICE
,
ZTMP3_DEVICE
,
ZTMP4_DEVICE
,
ZRVTT
,
ZRUTT
REAL
,
DIMENSION
(:,:,:),
pointer
,
contiguous
::
ZTMP5_DEVICE
,
ZTMP6_DEVICE
,
ZTMP7_DEVICE
,
ZTMP8_DEVICE
!!!REAL, DIMENSION(:,:,:), pointer , contiguous :: ZTMP9_DEVICE,ZTMP10_DEVICE,ZTMP11_DEVICE,ZTMP12_DEVICE
#endif
!
!-------------------------------------------------------------------------------
!
JIU
=
size
(
PUT
,
1
)
JJU
=
size
(
PUT
,
2
)
JKU
=
size
(
PUT
,
3
)
#ifdef MNH_OPENACC
CALL
MNH_MEM_POSITION_PIN
()
CALL
MNH_MEM_GET
(
ztmp1_device
,
JIU
,
JJU
,
JKU
)
CALL
MNH_MEM_GET
(
ztmp2_device
,
JIU
,
JJU
,
JKU
)
CALL
MNH_MEM_GET
(
ztmp3_device
,
JIU
,
JJU
,
JKU
)
CALL
MNH_MEM_GET
(
ztmp4_device
,
JIU
,
JJU
,
JKU
)
CALL
MNH_MEM_GET
(
ztmp5_device
,
JIU
,
JJU
,
JKU
)
CALL
MNH_MEM_GET
(
ztmp6_device
,
JIU
,
JJU
,
JKU
)
CALL
MNH_MEM_GET
(
ztmp7_device
,
JIU
,
JJU
,
JKU
)
CALL
MNH_MEM_GET
(
ztmp8_device
,
JIU
,
JJU
,
JKU
)
!CALL MNH_MEM_GET( ztmp9_device, JIU, JJU, JKU )
!CALL MNH_MEM_GET( ztmp10_device, JIU, JJU, JKU )
!CALL MNH_MEM_GET( ztmp11_device, JIU, JJU, JKU )
!CALL MNH_MEM_GET( ztmp12_device, JIU, JJU, JKU )
CALL
MNH_MEM_GET
(
ZRVTT
,
JIU
,
JJU
,
JKU
)
CALL
MNH_MEM_GET
(
ZRUTT
,
JIU
,
JJU
,
JKU
)
CALL
MNH_MEM_GET
(
ZWORK1
,
JIU
,
JJU
,
JKU
)
CALL
MNH_MEM_GET
(
ZWORK2
,
JIU
,
JJU
,
JKU
)
CALL
MNH_MEM_GET
(
ZWORK3
,
JIU
,
JJU
,
JKU
)
CALL
MNH_MEM_GET
(
ZRUT
,
JIU
,
JJU
,
JKU
)
CALL
MNH_MEM_GET
(
ZRVT
,
JIU
,
JJU
,
JKU
)
#endif
!
!* 1. COMPUTES THE TRUE VELOCITY COMPONENTS
! -------------------------------------
!
!$acc data copyin ( PUT, PVT, PWT,PTHT, PRT, &
!$acc & PCORIOX, PCORIOY, PCORIOZ, PCURVX, PCURVY, &
!$acc & PZZ, PTHVREF, PEXNREF) &
!$acc & present (PRUS,PRVS, PRWS, PRTHS,PRHODJ)
!$acc update device(PRUS, PRVS, PRWS,PRTHS,PRHODJ)
!$acc update device ( PUT, PVT, PWT,PTHT, PRT, &
!$acc & PCORIOX, PCORIOY, PCORIOZ, PCURVX, PCURVY, &
!$acc & PZZ, PTHVREF, PEXNREF)
#ifndef MNH_OPENACC
ZRUT
(:,:,:)
=
PUT
(:,:,:)
*
MXM
(
PRHODJ
(:,:,:))
ZRVT
(:,:,:)
=
PVT
(:,:,:)
*
MYM
(
PRHODJ
(:,:,:))
print
*
,
"PUT(1,1,1)"
,
PUT
(
1
,
1
,
1
)
#else
CALL
MXM_DEVICE
(
PRHODJ
(:,:,:),
ZTMP1_DEVICE
(:,:,:))
CALL
MYM_DEVICE
(
PRHODJ
(:,:,:),
ZTMP2_DEVICE
(:,:,:))
!$acc kernels present(ZRUT,ZRVT,PUT,PVT,ZTMP1_DEVICE,ZTMP2_DEVICE)
ZRUT
(:,:,:)
=
PUT
(:,:,:)
*
ZTMP1_DEVICE
(:,:,:)
ZRVT
(:,:,:)
=
PVT
(:,:,:)
*
ZTMP2_DEVICE
(:,:,:)
!$acc end kernels
#endif
!
IKU
=
SIZE
(
PUT
,
3
)
!
!-------------------------------------------------------------------------------
!
!* 2. COMPUTES THE CURVATURE TERMS
! ----------------------------
!
! Only when earth rotation is considered but not in 1D and CARTESIAN cases
!
IF
((
.NOT.
L1D
)
.AND.
(
.NOT.
LCARTESIAN
)
)
THEN
if
(
lbudget_u
)
call
Budget_store_init
(
tbudgets
(
NBUDGET_U
),
'CURV'
,
prus
(:,
:,
:)
)
if
(
lbudget_v
)
call
Budget_store_init
(
tbudgets
(
NBUDGET_V
),
'CURV'
,
prvs
(:,
:,
:)
)
IF
(
LTHINSHELL
)
THEN
! THINSHELL approximation
#ifndef MNH_OPENACC
ZWORK1
(:,:,:)
=
SPREAD
(
PCURVX
(:,:),
DIM
=
3
,
NCOPIES
=
JKU
)
/
XRADIUS
ZWORK2
(:,:,:)
=
SPREAD
(
PCURVY
(:,:),
DIM
=
3
,
NCOPIES
=
JKU
)
/
XRADIUS
#else
!$acc kernels present_cr(ZWORK1,ZWORK2)
!$mnh_expand_array(JI=1:JIU , JJ=1:JJU , JK=1:JKU)
ZWORK1
(:,:,:)
=
PCURVX
(:,:)
/
XRADIUS
ZWORK2
(:,:,:)
=
PCURVY
(:,:)
/
XRADIUS
!$mnh_end_expand_array()
!$acc end kernels
#endif
#ifndef MNH_OPENACC
PRUS
(:,:,:)
=
PRUS
&
+
ZRUT
*
MXM
(
MYF
(
PVT
)
*
ZWORK1
)
&
+
MXM
(
MYF
(
ZRVT
*
PVT
)
*
ZWORK2
)
!
PRVS
(:,:,:)
=
PRVS
&
-
MYM
(
MXF
(
ZRUT
*
PUT
)
*
ZWORK1
)
&
-
ZRVT
*
MYM
(
MXF
(
PUT
)
*
ZWORK2
)
!
#else
!$acc kernels
ZRVTT
(:,:,:)
=
ZRVT
(:,:,:)
*
PVT
(:,:,:)
ZRUTT
(:,:,:)
=
ZRUT
(:,:,:)
*
PUT
(:,:,:)
!$acc end kernels
CALL
MYF_DEVICE
(
PVT
,
ZTMP1_DEVICE
)
!MYF(PVT)
CALL
MYF_DEVICE
(
ZRVTT
,
ZTMP2_DEVICE
)
!MYF(ZRVT*PVT)
CALL
MXF_DEVICE
(
ZRUTT
,
ZTMP3_DEVICE
)
!MXF(ZRUT*PUT)
CALL
MXF_DEVICE
(
PUT
,
ZTMP4_DEVICE
)
!MXF(PUT)
!$acc kernels present_cr(ZTMP1_DEVICE,ZTMP1_DEVICE,ZTMP1_DEVICE,ZTMP1_DEVICE)
ZTMP1_DEVICE
(:,:,:)
=
ZTMP1_DEVICE
(:,:,:)
*
ZWORK1
(:,:,:)
!MYF(PVT) * ZWORK1
ZTMP2_DEVICE
(:,:,:)
=
ZTMP2_DEVICE
(:,:,:)
*
ZWORK2
(:,:,:)
!MYF(ZRVT*PVT) * ZWORK2
ZTMP3_DEVICE
(:,:,:)
=
ZTMP3_DEVICE
(:,:,:)
*
ZWORK1
(:,:,:)
!MXF(ZRUT*PUT) * ZWORK1
ZTMP4_DEVICE
(:,:,:)
=
ZTMP4_DEVICE
(:,:,:)
*
ZWORK2
(:,:,:)
!MXF(PUT) * ZWORK2
!$acc end kernels
CALL
MXM_DEVICE
(
ZTMP1_DEVICE
,
ZTMP5_DEVICE
)
!MXM( MYF(PVT) * ZWORK1 )
CALL
MXM_DEVICE
(
ZTMP2_DEVICE
,
ZTMP6_DEVICE
)
!MXM( MYF(ZRVT*PVT) * ZWORK2 )
CALL
MYM_DEVICE
(
ZTMP3_DEVICE
,
ZTMP7_DEVICE
)
!MYM( MXF(ZRUT*PUT) * ZWORK1 )
CALL
MYM_DEVICE
(
ZTMP4_DEVICE
,
ZTMP8_DEVICE
)
!MYM( MXF(PUT) * ZWORK2 )
!$acc kernels present_cr(PRUS,PRVS)
PRUS
(:,:,:)
=
PRUS
(:,:,:)
&
+
ZRUT
(:,:,:)
*
ZTMP5_DEVICE
(:,:,:)
&
+
ZTMP6_DEVICE
(:,:,:)
PRVS
(:,:,:)
=
PRVS
(:,:,:)
&
-
ZTMP7_DEVICE
(:,:,:)
&
-
ZRVT
(:,:,:)
*
ZTMP8_DEVICE
(:,:,:)
!$acc end kernels
#endif
ELSE
! NO THINSHELL approximation
if
(
lbudget_w
)
call
Budget_store_init
(
tbudgets
(
NBUDGET_W
),
'CURV'
,
prws
(:,
:,
:)
)
#ifndef MNH_OPENACC
ZWORK3
(:,:,:)
=
1.0
/
(
XRADIUS
+
MZF
(
PZZ
(:,:,:))
)
ZWORK1
(:,:,:)
=
SPREAD
(
PCURVX
(:,:),
DIM
=
3
,
NCOPIES
=
JKU
)
ZWORK2
(:,:,:)
=
SPREAD
(
PCURVY
(:,:),
DIM
=
3
,
NCOPIES
=
JKU
)
#else
CALL
MZF_DEVICE
(
PZZ
,
ZWORK3
)
!MZF(PZZ(:,:,:))
!$acc kernels present_cr(ZWORK3,ZWORK1,ZWORK2)
ZWORK3
(:,:,:)
=
1.0
/
(
XRADIUS
+
ZWORK3
(:,:,:)
)
ZWORK1
(:,:,:)
=
SPREAD
(
PCURVX
(:,:),
DIM
=
3
,
NCOPIES
=
JKU
)
ZWORK2
(:,:,:)
=
SPREAD
(
PCURVY
(:,:),
DIM
=
3
,
NCOPIES
=
JKU
)
!$acc end kernels
#endif
IF
(
MPPDB_INITIALIZED
)
THEN
CALL
MPPDB_CHECK3DM
(
"DYN_SOURCES:ZWORK3,ZWORK1,ZWORK2"
,
PRECISION
,&
&
ZWORK3
,
ZWORK1
,
ZWORK2
,&
&
MXM
(
MYF
(
ZRVT
*
PVT
)
*
ZWORK2
*
ZWORK3
)
,
&
&
MXM
(
(
MYF
(
PVT
)
*
ZWORK1
-
MZF
(
PWT
)
)
*
ZWORK3
)
,&
&
MYF
(
PVT
)
*
ZWORK1
-
MZF
(
PWT
)
,
&
&
MYF
(
PVT
)
,
MZF
(
PWT
)
,
MXM
(
PWT
)
,
MYM
(
PWT
)
)
CALL
MPPDB_CHECK3DM
(
"DYN_SOOURCES:SUITE"
,
PRECISION
,&
&
MXM
(
ZRVT
),
MXM
(
PVT
),
MXM
(
PWT
),
MXM
(
ZWORK1
),
MXM
(
ZWORK2
),
MXM
(
ZWORK3
),&
&
ZRUT
,
ZRVT
,
PRUS
,
PRVS
,
PRWS
)
ENDIF
!
#ifndef MNH_OPENACC
PRUS
(:,:,:)
=
PRUS
&
+
MXM
(
MYF
(
ZRVT
*
PVT
)
*
ZWORK2
*
ZWORK3
)
&
+
ZRUT
*
MXM
(
(
MYF
(
PVT
)
*
ZWORK1
-
MZF
(
PWT
)
)
*
ZWORK3
)
!
PRVS
(:,:,:)
=
PRVS
&
-
MYM
(
MXF
(
ZRUT
*
PUT
)
*
ZWORK1
*
ZWORK3
)
&
-
ZRVT
*
MYM
(
(
MXF
(
PUT
)
*
ZWORK2
+
MZF
(
PWT
)
)
*
ZWORK3
)
!
PRWS
(:,:,:)
=
PRWS
&
+
MZM
(
(
MXF
(
ZRUT
*
PUT
)
+
MYF
(
ZRVT
*
PVT
)
)
*
ZWORK3
)
#else
!$acc kernels present_cr(ZRVTT,ZRUTT)
ZRVTT
(:,:,:)
=
ZRVT
(:,:,:)
*
PVT
(:,:,:)
ZRUTT
(:,:,:)
=
ZRUT
(:,:,:)
*
PUT
(:,:,:)
!PRUS(:,:,:) = PRUS &
! + MXM( MYF(ZRVT*PVT) * ZWORK2 * ZWORK3 ) &
! + ZRUT * MXM( ( MYF(PVT) * ZWORK1 - MZF(PWT) ) * ZWORK3 )
!$acc end kernels
CALL
MYF_DEVICE
(
ZRVTT
,
ZTMP1_DEVICE
)
!MYF(ZRVT*PVT)
CALL
MYF_DEVICE
(
PVT
,
ZTMP2_DEVICE
)
!MYF(PVT)
CALL
MZF_DEVICE
(
PWT
,
ZTMP3_DEVICE
)
!MZF(PWT)
!$acc kernels present_cr(ZTMP1_DEVICE,ZTMP4_DEVICE)
ZTMP1_DEVICE
(:,:,:)
=
ZTMP1_DEVICE
(:,:,:)
*
ZWORK2
(:,:,:)
*
ZWORK3
(:,:,:)
! MYF(ZRVT*PVT) * ZWORK2 * ZWORK3
ZTMP4_DEVICE
(:,:,:)
=
(
ZTMP2_DEVICE
(:,:,:)
*
ZWORK1
(:,:,:)
-
ZTMP3_DEVICE
(:,:,:))
*
ZWORK3
(:,:,:)
!( MYF(PVT) * ZWORK1 - MZF(PWT) ) * ZWORK3
!$acc end kernels
CALL
MXM_DEVICE
(
ZTMP1_DEVICE
,
ZTMP2_DEVICE
)
! MXM( MYF(ZRVT*PVT) * ZWORK2 * ZWORK3 )
CALL
MXM_DEVICE
(
ZTMP4_DEVICE
,
ZTMP5_DEVICE
)
! MXM( ( MYF(PVT) * ZWORK1 - MZF(PWT) ) * ZWORK3 )
!$acc kernels present_cr(PRUS)
PRUS
(:,:,:)
=
PRUS
(:,:,:)
&
+
ZTMP2_DEVICE
(:,:,:)
&
+
ZRUT
(:,:,:)
*
ZTMP5_DEVICE
(:,:,:)
!$acc end kernels
! PRVS(:,:,:) = PRVS &
! - MYM( MXF(ZRUT*PUT) * ZWORK1 * ZWORK3 ) &
! - ZRVT * MYM( (MXF(PUT) * ZWORK2 + MZF(PWT) ) * ZWORK3 )
CALL
MXF_DEVICE
(
ZRUTT
,
ZTMP1_DEVICE
)
!MXF(ZRUT*PUT)
CALL
MXF_DEVICE
(
PUT
,
ZTMP2_DEVICE
)
!MXF(PUT)
!CALL MZF_DEVICE(PWT,ZTMP3_DEVICE ) !MZF(PWT)
!$acc kernels present_cr(ZTMP1_DEVICE,ZTMP4_DEVICE)
ZTMP1_DEVICE
(:,:,:)
=
ZTMP1_DEVICE
(:,:,:)
*
ZWORK1
(:,:,:)
*
ZWORK3
(:,:,:)
!MXF(ZRUT*PUT) * ZWORK1 * ZWORK3
ZTMP4_DEVICE
(:,:,:)
=
(
ZTMP2_DEVICE
(:,:,:)
*
ZWORK2
(:,:,:)
+
ZTMP3_DEVICE
(:,:,:))
*
ZWORK3
(:,:,:)
!(MXF(PUT) * ZWORK2 + MZF(PWT) ) * ZWORK3
!$acc end kernels
CALL
MYM_DEVICE
(
ZTMP1_DEVICE
,
ZTMP2_DEVICE
)
!MYM( MXF(ZRUT*PUT) * ZWORK1 * ZWORK3 )
CALL
MYM_DEVICE
(
ZTMP4_DEVICE
,
ZTMP5_DEVICE
)
!MYM( (MXF(PUT) * ZWORK2 + MZF(PWT) ) * ZWORK3 )
!$acc kernels present_cr(PRVS)
PRVS
(:,:,:)
=
PRVS
(:,:,:)
&
-
ZTMP2_DEVICE
(:,:,:)
&
-
ZRVT
(:,:,:)
*
ZTMP5_DEVICE
(:,:,:)
!$acc end kernels
! PRWS(:,:,:) = PRWS &
! +MZM( ( MXF(ZRUT*PUT) + MYF(ZRVT*PVT) ) * ZWORK3 )
CALL
MYF_DEVICE
(
ZRVTT
,
ZTMP1_DEVICE
)
!MXF(ZRUT*PUT)
CALL
MXF_DEVICE
(
ZRUTT
,
ZTMP2_DEVICE
)
!MYF(ZRVT*PVT)
!$acc kernels present_cr(ZTMP3_DEVICE)
ZTMP3_DEVICE
(:,:,:)
=
(
ZTMP2_DEVICE
(:,:,:)
+
ZTMP1_DEVICE
(:,:,:))
*
ZWORK3
(:,:,:)
! (MXF(ZRUT*PUT) + MYF(ZRVT*PVT) ) * ZWORK3
!$acc end kernels
CALL
MZM_DEVICE
(
ZTMP3_DEVICE
,
ZTMP1_DEVICE
)
! MZM( ( MXF(ZRUT*PUT) + MYF(ZRVT*PVT) ) * ZWORK3 )
!$acc kernels present_cr(PRWS)
PRWS
(:,:,:)
=
PRWS
(:,:,:)
+
ZTMP1_DEVICE
(:,:,:)
!$acc end kernels
#endif
if
(
lbudget_w
)
call
Budget_store_end
(
tbudgets
(
NBUDGET_W
),
'CURV'
,
prws
(:,
:,
:)
)
END
IF
if
(
lbudget_u
)
call
Budget_store_end
(
tbudgets
(
NBUDGET_U
),
'CURV'
,
prus
(:,
:,
:)
)
if
(
lbudget_v
)
call
Budget_store_end
(
tbudgets
(
NBUDGET_V
),
'CURV'
,
prvs
(:,
:,
:)
)
END
IF
!
!
!-------------------------------------------------------------------------------
!
!* 3. COMPUTES THE CORIOLIS TERMS
! ---------------------------
!
IF
(
LCORIO
)
THEN
if
(
lbudget_u
)
call
Budget_store_init
(
tbudgets
(
NBUDGET_U
),
'COR'
,
prus
(:,
:,
:)
)
if
(
lbudget_v
)
call
Budget_store_init
(
tbudgets
(
NBUDGET_V
),
'COR'
,
prvs
(:,
:,
:)
)
!$acc kernels present_cr(ZWORK3)
ZWORK3
(:,:,:)
=
SPREAD
(
PCORIOZ
(:,:),
DIM
=
3
,
NCOPIES
=
JKU
)
*
PRHODJ
(:,:,:)
!$acc end kernels
#ifndef MNH_OPENACC
PRUS
(:,:,:)
=
PRUS
+
MXM
(
ZWORK3
*
MYF
(
PVT
)
)
PRVS
(:,:,:)
=
PRVS
-
MYM
(
ZWORK3
*
MXF
(
PUT
)
)
#else
CALL
MYF_DEVICE
(
PVT
,
ZTMP1_DEVICE
)
!MYF(PVT)
CALL
MXF_DEVICE
(
PUT
,
ZTMP2_DEVICE
)
!MXF(PUT)
!$acc kernels present_cr(ZTMP1_DEVICE,ZTMP2_DEVICE)
ZTMP1_DEVICE
(:,:,:)
=
ZWORK3
(:,:,:)
*
ZTMP1_DEVICE
(:,:,:)
ZTMP2_DEVICE
(:,:,:)
=
ZWORK3
(:,:,:)
*
ZTMP2_DEVICE
(:,:,:)
!$acc end kernels
CALL
MXM_DEVICE
(
ZTMP1_DEVICE
,
ZTMP3_DEVICE
)
! MXM( ZWORK3 * MYF(PVT)
CALL
MYM_DEVICE
(
ZTMP2_DEVICE
,
ZTMP4_DEVICE
)
! MYM( ZWORK3 * MXF(PUT)
!$acc kernels present_cr(PRUS,PRVS)
PRUS
(:,:,:)
=
PRUS
(:,:,:)
+
ZTMP3_DEVICE
(:,:,:)
PRVS
(:,:,:)
=
PRVS
(:,:,:)
-
ZTMP4_DEVICE
(:,:,:)
!$acc end kernels
#endif
!
IF
((
.NOT.
LTHINSHELL
)
.AND.
(
.NOT.
L1D
))
THEN
if
(
lbudget_w
)
call
Budget_store_init
(
tbudgets
(
NBUDGET_W
),
'COR'
,
prws
(:,
:,
:)
)
!$acc kernels present_cr(ZWORK1,ZWORK2)
ZWORK1
(:,:,:)
=
SPREAD
(
PCORIOX
(:,:),
DIM
=
3
,
NCOPIES
=
JKU
)
*
PRHODJ
(:,:,:)
ZWORK2
(:,:,:)
=
SPREAD
(
PCORIOY
(:,:),
DIM
=
3
,
NCOPIES
=
JKU
)
*
PRHODJ
(:,:,:)
!$acc end kernels
CALL
MPPDB_CHECK3DM
(
"DYN_SOOURCES:CORIOLIS"
,
PRECISION
,&
&
ZWORK1
,
ZWORK2
,
ZWORK3
)
!
#ifndef MNH_OPENACC
PRUS
(:,:,:)
=
PRUS
-
MXM
(
ZWORK2
*
MZF
(
PWT
)
)
!
PRVS
(:,:,:)
=
PRVS
-
MYM
(
ZWORK1
*
MZF
(
PWT
)
)
!
PRWS
(:,:,:)
=
PRWS
+
MZM
(
ZWORK2
*
MXF
(
PUT
)
+
ZWORK1
*
MYF
(
PVT
)
)
#else
!***PRUS(:,:,:) = PRUS - MXM( ZWORK2 * MZF(PWT) )
CALL
MZF_DEVICE
(
PWT
,
ZTMP1_DEVICE
)
!MZF(PWT)
!$acc kernels present_cr(ZTMP2_DEVICE)
ZTMP2_DEVICE
(:,:,:)
=
ZWORK2
(:,:,:)
*
ZTMP1_DEVICE
(:,:,:)
!ZWORK2 * MZF(PWT)
!$acc end kernels
CALL
MXM_DEVICE
(
ZTMP2_DEVICE
,
ZTMP3_DEVICE
)
!MXM( ZWORK2 * MZF(PWT) )
!$acc kernels present_cr(PRUS)
PRUS
(:,:,:)
=
PRUS
(:,:,:)
-
ZTMP3_DEVICE
(:,:,:)
!$acc end kernels
!*** PRVS(:,:,:) = PRVS - MYM( ZWORK1 * MZF(PWT) )
!$acc kernels present_cr(ZTMP2_DEVICE)
ZTMP2_DEVICE
(:,:,:)
=
ZWORK1
(:,:,:)
*
ZTMP1_DEVICE
(:,:,:)
!ZWORK1 * MZF(PWT)
!$acc end kernels
CALL
MYM_DEVICE
(
ZTMP2_DEVICE
,
ZTMP3_DEVICE
)
!MYM( ZWORK1 * MZF(PWT) )
!$acc kernels present_cr(PRVS)
PRVS
(:,:,:)
=
PRVS
(:,:,:)
-
ZTMP2_DEVICE
(:,:,:)
!$acc end kernels
!*** PRWS(:,:,:) = PRWS + MZM( ZWORK2 * MXF(PUT) + ZWORK1 * MYF(PVT) )
CALL
MXF_DEVICE
(
PUT
,
ZTMP1_DEVICE
)
!MXF(PUT)
CALL
MYF_DEVICE
(
PVT
,
ZTMP2_DEVICE
)
!MYF(PVT)
!$acc kernels present_cr(ZTMP3_DEVICE)
ZTMP3_DEVICE
(:,:,:)
=
ZWORK2
(:,:,:)
*
ZTMP1_DEVICE
(:,:,:)
+
ZWORK1
(:,:,:)
*
ZTMP2_DEVICE
(:,:,:)
!ZWORK2 * MXF(PUT) + ZWORK1 * MYF(PVT)
!$acc end kernels
CALL
MZM_DEVICE
(
ZTMP3_DEVICE
,
ZTMP1_DEVICE
)
!MZM( ZWORK2 * MXF(PUT) + ZWORK1 * MYF(PVT) )
!$acc kernels present_cr(PRWS)
PRWS
(:,:,:)
=
PRWS
(:,:,:)
+
ZTMP1_DEVICE
(:,:,:)
!$acc end kernels
#endif
if
(
lbudget_w
)
call
Budget_store_end
(
tbudgets
(
NBUDGET_W
),
'COR'
,
prws
(:,
:,
:)
)
END
IF
if
(
lbudget_u
)
call
Budget_store_end
(
tbudgets
(
NBUDGET_U
),
'COR'
,
prus
(:,
:,
:)
)
if
(
lbudget_v
)
call
Budget_store_end
(
tbudgets
(
NBUDGET_V
),
'COR'
,
prvs
(:,
:,
:)
)
END
IF
!!!!$acc end data
!
!-------------------------------------------------------------------------------
!
!* 4. COMPUTES THE THETA SOURCE TERM DUE TO THE REFERENCE PRESSURE
! ------------------------------------------------------------
!
IF
(
LCARTESIAN
.OR.
LTHINSHELL
)
THEN
ZD1
=
0.
ELSE
ZD1
=
1.
ENDIF
!
IF
(
.NOT.
L1D
)
THEN
IF
(
.NOT.
LOCEAN
)
THEN
!
IF
(
KRR
>
0
)
THEN
if
(
lbudget_th
)
call
Budget_store_init
(
tbudgets
(
NBUDGET_TH
),
'PREF'
,
prths
(:,
:,
:)
)
ZCPD_OV_RD
=
XCPD
/
XRD
ZG_OV_CPD
=
-
XG
/
XCPD
!
! stores the specific heat capacity (Cph) in ZWORK1
!$acc kernels present_cr( ZWORK1)
ZWORK1
(:,:,:)
=
XCPD
+
XCPV
*
PRT
(:,:,:,
1
)
! gas mixing
!$acc loop seq
DO
JWATER
=
2
,
1
+
KRRL
! loop on the liquid components
ZWORK1
(:,:,:)
=
ZWORK1
(:,:,:)
+
XCL
*
PRT
(:,:,:,
JWATER
)
END
DO
!$acc loop seq
DO
JWATER
=
2
+
KRRL
,
1
+
KRRL
+
KRRI
! loop on the solid components
ZWORK1
(:,:,:)
=
ZWORK1
(:,:,:)
+
XCI
*
PRT
(:,:,:,
JWATER
)
END
DO
!$acc end kernels
! computes the source term
!
#ifndef MNH_OPENACC
PRTHS
(:,:,:)
=
PRTHS
(:,:,:)
+
PRHODJ
(:,:,:)
&
*
(
(
XRD
+
XRV
*
PRT
(:,:,:,
1
)
)
*
ZCPD_OV_RD
/
ZWORK1
(:,:,:)
-
1.
)
&
*
PTHT
(:,:,:)/
PEXNREF
(:,:,:)
*
MZF
(
PWT
(:,:,:))
*
(
ZG_OV_CPD
/
PTHVREF
(:,:,:)
&
-
ZD1
*
4.
/
7.
*
PEXNREF
(:,:,:)/(
XRADIUS
+
MZF
(
PZZ
(:,:,:))
))
#else
CALL
MZF_DEVICE
(
PWT
,
ZTMP1_DEVICE
)
!MZF(PWT(:,:,:))
CALL
MZF_DEVICE
(
PZZ
(:,:,:),
ZTMP2_DEVICE
(:,:,:))
!MZF(PZZ(:,:,:))
!$acc kernels present_cr(PRTHS)
PRTHS
(:,:,:)
=
PRTHS
(:,:,:)
+
PRHODJ
(:,:,:)
&
*
(
(
XRD
+
XRV
*
PRT
(:,:,:,
1
)
)
*
ZCPD_OV_RD
/
ZWORK1
(:,:,:)
-
1.
)
&
*
PTHT
(:,:,:)/
PEXNREF
(:,:,:)
*
ZTMP1_DEVICE
*
(
ZG_OV_CPD
/
PTHVREF
(:,:,:)
&
-
ZD1
*
4.
/
7.
*
PEXNREF
(:,:,:)/(
XRADIUS
+
ZTMP2_DEVICE
(:,:,:)
))
!$acc end kernels
#endif
if
(
lbudget_th
)
call
Budget_store_end
(
tbudgets
(
NBUDGET_TH
),
'PREF'
,
prths
(:,
:,
:)
)
END
IF
END
IF
!
END
IF
!
!-------------------------------------------------------------------------------
#ifdef MNH_OPENACC
CALL
MNH_MEM_RELEASE
()
#endif
!$acc end data
!$acc update self(PRUS, PRVS, PRWS,PRTHS)
END
SUBROUTINE
DYN_SOURCES
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