!-------------------------------------- LICENCE BEGIN ------------------------------------
!Environment Canada - Atmospheric Science and Technology License/Disclaimer,
! version 3; Last Modified: May 7, 2008.
!This is free but copyrighted software; you can use/redistribute/modify it under the terms
!of the Environment Canada - Atmospheric Science and Technology License/Disclaimer
!version 3 or (at your option) any later version that should be found at:
!http://collaboration.cmc.ec.gc.ca/science/rpn.comm/license.html
!
!This software is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY;
!without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.
!See the above mentioned License/Disclaimer for more details.
!You should have received a copy of the License/Disclaimer along with this software;
!if not, you can write to: EC-RPN COMM Group, 2121 TransCanada, suite 500, Dorval (Quebec),
!CANADA, H9P 1J3; or send e-mail to service.rpn@ec.gc.ca
!-------------------------------------- LICENCE END --------------------------------------
***s/r adw_interp_tl - TLM of adw_interp
*
#include "model_macros_f.h"
*
subroutine adw_interp_tl ( F_out, F_in, F_u, F_v, 7,17
% F_outm,F_inm,F_um,F_vm,
% F_wind_L, F_mono_L, DIST_DIM, Nk,i0,in,j0,jn )
*
implicit none
*
logical F_wind_L, F_mono_L
*
integer DIST_DIM, Nk, i0,in,j0,jn
*
real F_out (DIST_SHAPE, Nk),
% F_in (DIST_SHAPE, Nk)
real F_u(*), F_v(*)
*
real F_outm(DIST_SHAPE, Nk),
% F_inm (DIST_SHAPE, Nk)
real F_um(*), F_vm(*)
*
*author
* monique tanguay
*
*revision
* v2_31 - Tanguay M. - initial MPI version
* v3_00 - Tanguay M. - adapt to restructured Adw_main
* v3_11 - Tanguay M. - AIXport+Opti+OpenMP for TLM-ADJ
* v3_20 - Tanguay M. - Lagrange 3D
* v3_30 - Tanguay M. - Adapt TL/AD to Adw_interp_type_S
*
*language
* fortran 77
*
*object
* see id section
*
*arguments
*______________________________________________________________________
* | | |
* NAME | DESCRIPTION | I/O |
*--------------|-------------------------------------------------|-----|
* | | |
* F_out | interpolated field | o |
* F_in | field to interpolate | i |
* F_wind_L | switch: .true. : field to interpolate is a wind | i |
* | like quantity | i |
* F_mono_L | switch: .true. : monotonic interpolation | i |
*______________|_________________________________________________|_____|
*
*implicits
#include "glb_ld.cdk"
#include "adw.cdk"
#include "adwm.cdk"
*
************************************************************************
integer i, j, k, nij, nijk, nijkag, n, dest_ni
*
real dummy
*
***********************************************************************
if (Adw_interp_type_S(1:5).ne.'LAG3D')
$ call gem_stop ('ADW_INTERP_TL: Adw_interp_type_S(1:5).ne.LAG3D not done',-1)
*
nij = l_ni *l_nj
nijk = l_ni *l_nj *l_nk
nijkag = Adw_nit*Adw_njt*l_nk
*
************************************************************************
*
* Adjust field to advection grid
*
* Compute extension beyond the pole if appropriate
*
************************************************************************
if (G_lam) then
n=0
dest_ni=l_ni
else
n=999
dest_ni=G_ni
endif
*
* TRAJECTORY
* ----------
call rpn_comm_xch_halox (F_inm, LDIST_DIM, l_ni, l_nj, l_nk,
% Adw_halox, Adw_haloy, G_periodx, G_periody, F_um, -Adw_halox+1,
% Adw_nic+Adw_halox, -Adw_haloy+1, Adw_njc+Adw_haloy, dest_ni, n)
*
* TLM
* ---
call rpn_comm_xch_halox (F_in, LDIST_DIM, l_ni, l_nj, l_nk,
% Adw_halox, Adw_haloy, G_periodx, G_periody, F_u, -Adw_halox+1,
% Adw_nic+Adw_halox, -Adw_haloy+1, Adw_njc+Adw_haloy, dest_ni, n)
*
if (.not.G_lam) then
*
* TRAJECTORY
* ----------
if ( l_south ) then
*
if ( F_wind_L ) then
call adw_pol0 (F_um, 0, Adw_nic,Adw_halox,Adw_njc,
% Adw_haloy,l_nk)
else
call adw_pols (F_um,Adw_wx_8, 0, Adw_nic,Adw_halox,
% Adw_njc,Adw_haloy,l_nk)
endif
call adw_polx (F_um,Adw_xg_8,.true.,Adw_nic,Adw_halox,
% Adw_njc,Adw_haloy,l_nk)
endif
*
if ( l_north ) then
*
if ( F_wind_L ) then
call adw_pol0 (F_um,Adw_njc+1,Adw_nic,Adw_halox,Adw_njc,
% Adw_haloy,l_nk)
else
call adw_pols (F_um,Adw_wx_8, Adw_njc+1,Adw_nic,Adw_halox,
% Adw_njc,Adw_haloy,l_nk)
endif
call adw_polx (F_um,Adw_xg_8,.false.,Adw_nic,Adw_halox,
% Adw_njc,Adw_haloy,l_nk)
endif
*
* TLM
* ---
if ( l_south ) then
*
if ( F_wind_L ) then
call adw_pol0 (F_u, 0, Adw_nic,Adw_halox,Adw_njc,
% Adw_haloy,l_nk)
else
call adw_pols (F_u,Adw_wx_8, 0, Adw_nic,Adw_halox,
% Adw_njc,Adw_haloy,l_nk)
endif
call adw_polx (F_u,Adw_xg_8,.true.,Adw_nic,Adw_halox,
% Adw_njc,Adw_haloy,l_nk)
endif
*
if ( l_north ) then
*
if ( F_wind_L ) then
call adw_pol0 (F_u,Adw_njc+1,Adw_nic,Adw_halox,Adw_njc,
% Adw_haloy,l_nk)
else
call adw_pols (F_u,Adw_wx_8, Adw_njc+1,Adw_nic,Adw_halox,
% Adw_njc,Adw_haloy,l_nk)
endif
call adw_polx (F_u,Adw_xg_8,.false.,Adw_nic,Adw_halox,
% Adw_njc,Adw_haloy,l_nk)
endif
*
endif
************************************************************************
*
* Compute second derivative for cubic spline in the vertical
*
************************************************************************
*
* TRAJECTORY
* ----------
if ( .not. Adw_interp_type_S(1:5).eq.'LAG3D' ) call adw_vder ( F_vm, F_um, Adw_nit, Adw_njt, l_nk )
*
* TLM
* ---
if ( .not. Adw_interp_type_S(1:5).eq.'LAG3D' ) call adw_vder ( F_v, F_u, Adw_nit, Adw_njt, l_nk )
************************************************************************
*
* Interpolate
*
************************************************************************
if ( .not. Adw_interp_type_S(1:5).eq.'LAG3D' ) then
call adw_tricub_tl ( Adw_wrkc, F_u, F_v,
% Adw_n1, Adw_capx1, Adw_xgg1,
% Adw_xdd1, Adw_capy1, Adw_ygg1,
% Adw_ydd1, Adw_capz1, Adw_cz1,
% Adwm_wrkcm,F_um, F_vm,
% Adwm_n1m, Adwm_capx1m,Adwm_xgg1m,
% Adwm_xdd1m,Adwm_capy1m,Adwm_ygg1m,
% Adwm_ydd1m,Adwm_capz1m,Adwm_cz1m,
% nijk, F_mono_L,i0,in,j0,jn,l_nk)
*
else
call adw_tricub_lag3d_tl(Adw_wrkc, F_u,
% Adw_capx1, Adw_capy1, Adw_capz1,
% Adwm_wrkcm, F_um,
% Adwm_capx1m,Adwm_capy1m,Adwm_capz1m,
% nijk, F_mono_L,i0,in,j0,jn,l_nk)
endif
*
!$omp parallel
!$omp do
do k = 1, l_nk
do j = j0,jn
do i = i0,in
*
* TRAJECTORY
* ----------
F_outm(i,j,k) = Adwm_wrkcm ( (k-1)*nij+(j-1)*l_ni+i )
*
* TLM
* ---
F_out(i,j,k) = Adw_wrkc ( (k-1)*nij+(j-1)*l_ni+i )
*
enddo
enddo
enddo
!$omp enddo
!$omp end parallel
*
return
end