#if defined key_agrif SUBROUTINE agrif_user() !!---------------------------------------------------------------------- !! *** ROUTINE agrif_user *** !!---------------------------------------------------------------------- END SUBROUTINE agrif_user SUBROUTINE agrif_initworkspace() !!---------------------------------------------------------------------- !! *** ROUTINE Agrif_InitWorkspace *** !!---------------------------------------------------------------------- END SUBROUTINE agrif_initworkspace SUBROUTINE Agrif_InitValues !!---------------------------------------------------------------------- !! *** ROUTINE Agrif_InitValues *** !! !! ** Purpose :: Declaration of variables to be interpolated !!---------------------------------------------------------------------- USE Agrif_Util USE dom_oce USE nemogcm USE domain !! IMPLICIT NONE ! No temporal refinement CALL Agrif_Set_coeffreft(1) CALL nemo_init !* Initializations of each fine grid CALL dom_nam END SUBROUTINE Agrif_InitValues SUBROUTINE Agrif_InitValues_cont !!---------------------------------------------------------------------- !! *** ROUTINE Agrif_InitValues_cont *** !! !! ** Purpose :: Initialisation of variables to be interpolated !!---------------------------------------------------------------------- USE dom_oce USE lbclnk !! IMPLICIT NONE ! INTEGER :: nx, ny INTEGER :: irafx, irafy LOGICAL :: ln_perio ! irafx = agrif_irhox() irafy = agrif_irhoy() nx = nlci ; ny = nlcj ! IF(jperio /=1 .AND. jperio/=4 .AND. jperio/=6 ) THEN ! nx = (nbcellsx)+2*nbghostcellsfine+2 ! ny = (nbcellsy)+2*nbghostcellsfine+2 ! nbghostcellsfine_tot_x= nbghostcellsfine_x +1 ! nbghostcellsfine_tot_y= nbghostcellsfine_y +1 ! ELSE ! nx = (nbcellsx)+2*nbghostcellsfine_x ! ny = (nbcellsy)+2*nbghostcellsfine+2 ! nbghostcellsfine_tot_x= 1 ! nbghostcellsfine_tot_y= nbghostcellsfine_y +1 ! ENDIF ! ELSE ! nbghostcellsfine = 0 ! nx = nbcellsx+irafx ! ny = nbcellsy+irafy WRITE(*,*) ' ' WRITE(*,*)'Size of the High resolution grid: ',nx,' x ',ny WRITE(*,*) ' ' CALL agrif_init_lonlat() ln_perio = .FALSE. IF( jperio == 1 .OR. jperio == 2 .OR. jperio == 4 ) ln_perio=.TRUE. WHERE (glamt < -180) glamt = glamt +360. WHERE (glamt > +180) glamt = glamt -360. CALL lbc_lnk( 'glamt', glamt, 'T', 1._wp) CALL lbc_lnk( 'gphit', gphit, 'T', 1._wp) WHERE (glamu < -180) glamu = glamu +360. WHERE (glamu > +180) glamu = glamu -360. CALL lbc_lnk( 'glamu', glamu, 'U', 1._wp) CALL lbc_lnk( 'gphiu', gphiu, 'U', 1._wp) WHERE (glamv < -180) glamv = glamv +360. WHERE (glamv > +180) glamv = glamv -360. CALL lbc_lnk( 'glamv', glamv, 'V', 1._wp) CALL lbc_lnk( 'gphiv', gphiv, 'V', 1._wp) WHERE (glamf < -180) glamf = glamf +360. WHERE (glamf > +180) glamf = glamf -360. CALL lbc_lnk( 'glamf', glamf, 'F', 1._wp) CALL lbc_lnk( 'gphif', gphif, 'F', 1._wp) ! Correct South and North IF ((nbondj == -1).OR.(nbondj == 2)) THEN glamt(:,1) = glamt(:,2) gphit(:,1) = gphit(:,2) glamu(:,1) = glamu(:,2) gphiu(:,1) = gphiu(:,2) glamv(:,1) = glamv(:,2) gphiv(:,1) = gphiv(:,2) ENDIF IF ((nbondj == 1).OR.(nbondj == 2)) THEN glamt(:,jpj) = glamt(:,jpj-1) gphit(:,jpj) = gphit(:,jpj-1) glamu(:,jpj) = glamu(:,jpj-1) gphiu(:,jpj) = gphiu(:,jpj-1) glamv(:,jpj) = glamv(:,jpj-1) gphiv(:,jpj) = gphiv(:,jpj-1) glamf(:,jpj) = glamf(:,jpj-1) gphif(:,jpj) = gphif(:,jpj-1) ENDIF ! Correct West and East IF( jperio /= 1 ) THEN IF((nbondi == -1) .OR. (nbondi == 2) ) THEN glamt(1,:) = glamt(2,:) gphit(1,:) = gphit(2,:) glamu(1,:) = glamu(2,:) gphiu(1,:) = gphiu(2,:) glamv(1,:) = glamv(2,:) gphiv(1,:) = gphiv(2,:) ENDIF IF( (nbondi == 1) .OR. (nbondi == 2) ) THEN glamt(jpi,:) = glamt(jpi-1,:) gphit(jpi,:) = gphit(jpi-1,:) glamu(jpi,:) = glamu(jpi-1,:) gphiu(jpi,:) = gphiu(jpi-1,:) glamv(jpi,:) = glamv(jpi-1,:) gphiv(jpi,:) = gphiv(jpi-1,:) glamf(jpi,:) = glamf(jpi-1,:) gphif(jpi,:) = gphif(jpi-1,:) ENDIF ENDIF CALL agrif_init_scales() ! Correct South and North IF( (nbondj == -1) .OR. (nbondj == 2) ) THEN e1t(:,1) = e1t(:,2) e2t(:,1) = e2t(:,2) e1u(:,1) = e1u(:,2) e2u(:,1) = e2u(:,2) e1v(:,1) = e1v(:,2) e2v(:,1) = e2v(:,2) ENDIF IF( (nbondj == 1) .OR. (nbondj == 2) ) THEN e1t(:,jpj) = e1t(:,jpj-1) e2t(:,jpj) = e2t(:,jpj-1) e1u(:,jpj) = e1u(:,jpj-1) e2u(:,jpj) = e2u(:,jpj-1) e1v(:,jpj) = e1v(:,jpj-1) e2v(:,jpj) = e2v(:,jpj-1) e1f(:,jpj) = e1f(:,jpj-1) e2f(:,jpj) = e2f(:,jpj-1) ENDIF ! Correct West and East IF( jperio /= 1 ) THEN IF( (nbondj == -1) .OR. (nbondj == 2) ) THEN e1t(1,:) = e1t(2,:) e2t(1,:) = e2t(2,:) e1u(1,:) = e1u(2,:) e2u(1,:) = e2u(2,:) e1v(1,:) = e1v(2,:) e2v(1,:) = e2v(2,:) ENDIF IF( (nbondj == 1) .OR. (nbondj == 2) ) THEN e1t(jpi,:) = e1t(jpi-1,:) e2t(jpi,:) = e2t(jpi-1,:) e1u(jpi,:) = e1u(jpi-1,:) e2u(jpi,:) = e2u(jpi-1,:) e1v(jpi,:) = e1v(jpi-1,:) e2v(jpi,:) = e2v(jpi-1,:) e1f(jpi,:) = e1f(jpi-1,:) e2f(jpi,:) = e2f(jpi-1,:) ENDIF ENDIF END SUBROUTINE Agrif_InitValues_cont SUBROUTINE agrif_declare_var() !!---------------------------------------------------------------------- !! *** ROUTINE Agrif_InitValues_cont *** !! !! ** Purpose :: Declaration of variables to be interpolated !!---------------------------------------------------------------------- USE par_oce USE dom_oce USE agrif_profiles USE agrif_parameters IMPLICIT NONE INTEGER :: ind1, ind2, ind3 INTEGER :: nx, ny INTEGER ::nbghostcellsfine_tot_x, nbghostcellsfine_tot_y INTEGER :: irafx EXTERNAL :: nemo_mapping ! 1. Declaration of the type of variable which have to be interpolated !--------------------------------------------------------------------- nx=nlci ; ny=nlcj ind2 = 2 + nbghostcells_x ind3 = 2 + nbghostcells_y_s nbghostcellsfine_tot_x=nbghostcells_x+1 nbghostcellsfine_tot_y=max(nbghostcells_y_s,nbghostcells_y_n)+1 irafx = Agrif_irhox() ! In case of East-West periodicity, prevent AGRIF interpolation at east and west boundaries ! The procnames will not be CALLed at these boundaries if (jperio == 1) THEN CALL Agrif_Set_NearCommonBorderX(.TRUE.) CALL Agrif_Set_DistantCommonBorderX(.TRUE.) endif if (.not.lk_south) THEN CALL Agrif_Set_NearCommonBorderY(.TRUE.) endif CALL agrif_declare_variable((/2,2/),(/ind2,ind3/),(/'x','y'/),(/1,1/),(/nx,ny/),glamt_id) CALL agrif_declare_variable((/1,2/),(/ind2-1,ind3/),(/'x','y'/),(/1,1/),(/nx,ny/),glamu_id) CALL agrif_declare_variable((/2,1/),(/ind2,ind3-1/),(/'x','y'/),(/1,1/),(/nx,ny/),glamv_id) CALL agrif_declare_variable((/1,1/),(/ind2-1,ind3-1/),(/'x','y'/),(/1,1/),(/nx,ny/),glamf_id) CALL agrif_declare_variable((/2,2/),(/ind2,ind3/),(/'x','y'/),(/1,1/),(/nx,ny/),gphit_id) CALL agrif_declare_variable((/1,2/),(/ind2-1,ind3/),(/'x','y'/),(/1,1/),(/nx,ny/),gphiu_id) CALL agrif_declare_variable((/2,1/),(/ind2,ind3-1/),(/'x','y'/),(/1,1/),(/nx,ny/),gphiv_id) CALL agrif_declare_variable((/1,1/),(/ind2-1,ind3-1/),(/'x','y'/),(/1,1/),(/nx,ny/),gphif_id) ! Horizontal scale factors CALL agrif_declare_variable((/2,2/),(/ind2,ind3/),(/'x','y'/),(/1,1/),(/nx,ny/),e1t_id) CALL agrif_declare_variable((/1,2/),(/ind2-1,ind3/),(/'x','y'/),(/1,1/),(/nx,ny/),e1u_id) CALL agrif_declare_variable((/2,1/),(/ind2,ind3-1/),(/'x','y'/),(/1,1/),(/nx,ny/),e1v_id) CALL agrif_declare_variable((/1,1/),(/ind2-1,ind3-1/),(/'x','y'/),(/1,1/),(/nx,ny/),e1f_id) CALL agrif_declare_variable((/2,2/),(/ind2,ind3/),(/'x','y'/),(/1,1/),(/nx,ny/),e2t_id) CALL agrif_declare_variable((/1,2/),(/ind2-1,ind3/),(/'x','y'/),(/1,1/),(/nx,ny/),e2u_id) CALL agrif_declare_variable((/2,1/),(/ind2,ind3-1/),(/'x','y'/),(/1,1/),(/nx,ny/),e2v_id) CALL agrif_declare_variable((/1,1/),(/ind2-1,ind3-1/),(/'x','y'/),(/1,1/),(/nx,ny/),e2f_id) ! Bathymetry CALL agrif_declare_variable((/2,2/),(/ind2,ind3/),(/'x','y'/),(/1,1/),(/nx,ny/),bathy_id) ! Vertical scale factors CALL agrif_declare_variable((/2,2,0/),(/ind2,ind3,0/),(/'x','y','N'/),(/1,1,1/),(/nx,ny,jpk/),e3t_id) CALL agrif_declare_variable((/2,2,0/),(/ind2,ind3,0/),(/'x','y','N'/),(/1,1,1/),(/nx,ny,jpk/),e3t_copy_id) CALL agrif_declare_variable((/2,2,0/),(/ind2,ind3,0/),(/'x','y','N'/),(/1,1,1/),(/nx,ny,jpk+1/),e3t_connect_id) CALL agrif_declare_variable((/1,2,0/),(/ind2-1,ind3,0/),(/'x','y','N'/),(/1,1,1/),(/nx,ny,jpk/),e3u_id) CALL agrif_declare_variable((/2,1,0/),(/ind2,ind3-1,0/),(/'x','y','N'/),(/1,1,1/),(/nx,ny,jpk/),e3v_id) ! Bottom level CALL agrif_declare_variable((/2,2/),(/ind2,ind3/),(/'x','y'/),(/1,1/),(/nx,ny/),bottom_level_id) CALL Agrif_Set_bcinterp(glamt_id,interp=AGRIF_linear) CALL Agrif_Set_interp(glamt_id,interp=AGRIF_linear) CALL Agrif_Set_bc( glamt_id, (/0,max(nbghostcellsfine_tot_x,nbghostcellsfine_tot_y)-1/) ) CALL Agrif_Set_bcinterp(glamu_id,interp=AGRIF_linear) CALL Agrif_Set_interp(glamu_id,interp=AGRIF_linear) CALL Agrif_Set_bc( glamu_id, (/0,max(nbghostcellsfine_tot_x,nbghostcellsfine_tot_y)/) ) CALL Agrif_Set_bcinterp(glamv_id,interp=AGRIF_linear) CALL Agrif_Set_interp(glamv_id,interp=AGRIF_linear) CALL Agrif_Set_bc( glamv_id, (/0,max(nbghostcellsfine_tot_x,nbghostcellsfine_tot_y)/) ) CALL Agrif_Set_bcinterp(glamf_id,interp=AGRIF_linear) CALL Agrif_Set_interp(glamf_id,interp=AGRIF_linear) CALL Agrif_Set_bc( glamf_id, (/0,max(nbghostcellsfine_tot_x,nbghostcellsfine_tot_y)/) ) CALL Agrif_Set_bcinterp(gphit_id,interp=AGRIF_linear) CALL Agrif_Set_interp(gphit_id,interp=AGRIF_linear) CALL Agrif_Set_bc( gphit_id, (/0,max(nbghostcellsfine_tot_x,nbghostcellsfine_tot_y)-1/) ) CALL Agrif_Set_bcinterp(gphiu_id,interp=AGRIF_linear) CALL Agrif_Set_interp(gphiu_id,interp=AGRIF_linear) CALL Agrif_Set_bc( gphiu_id, (/0,max(nbghostcellsfine_tot_x,nbghostcellsfine_tot_y)/) ) CALL Agrif_Set_bcinterp(gphiv_id,interp=AGRIF_linear) CALL Agrif_Set_interp(gphiv_id,interp=AGRIF_linear) CALL Agrif_Set_bc( gphiv_id, (/0,max(nbghostcellsfine_tot_x,nbghostcellsfine_tot_y)/) ) CALL Agrif_Set_bcinterp(gphif_id,interp=AGRIF_linear) CALL Agrif_Set_interp(gphif_id,interp=AGRIF_linear) CALL Agrif_Set_bc( gphif_id, (/0,max(nbghostcellsfine_tot_x,nbghostcellsfine_tot_y)/) ) ! CALL Agrif_Set_bcinterp(e1t_id,interp=AGRIF_ppm) CALL Agrif_Set_interp(e1t_id,interp=AGRIF_ppm) CALL Agrif_Set_bc( e1t_id, (/0,max(nbghostcellsfine_tot_x,nbghostcellsfine_tot_y)-1/) ) CALL Agrif_Set_bcinterp(e1u_id, interp1=Agrif_linear, interp2=AGRIF_ppm) CALL Agrif_Set_interp(e1u_id, interp1=Agrif_linear, interp2=AGRIF_ppm) CALL Agrif_Set_bc( e1u_id, (/0,max(nbghostcellsfine_tot_x,nbghostcellsfine_tot_y)/) ) CALL Agrif_Set_bcinterp(e1v_id,interp1=AGRIF_ppm, interp2=Agrif_linear) CALL Agrif_Set_interp(e1v_id, interp1=AGRIF_ppm, interp2=Agrif_linear) CALL Agrif_Set_bc( e1v_id, (/0,max(nbghostcellsfine_tot_x,nbghostcellsfine_tot_y)/) ) CALL Agrif_Set_bcinterp(e1f_id,interp=AGRIF_linear) CALL Agrif_Set_interp(e1f_id,interp=AGRIF_linear) CALL Agrif_Set_bc( e1f_id, (/0,max(nbghostcellsfine_tot_x,nbghostcellsfine_tot_y)/) ) CALL Agrif_Set_bcinterp(e2t_id,interp=AGRIF_ppm) CALL Agrif_Set_interp(e2t_id,interp=AGRIF_ppm) CALL Agrif_Set_bc( e2t_id, (/0,max(nbghostcellsfine_tot_x,nbghostcellsfine_tot_y)-1/) ) CALL Agrif_Set_bcinterp(e2u_id,interp1=Agrif_linear, interp2=AGRIF_ppm) CALL Agrif_Set_interp(e2u_id,interp1=Agrif_linear, interp2=AGRIF_ppm) CALL Agrif_Set_bc( e2u_id, (/0,max(nbghostcellsfine_tot_x,nbghostcellsfine_tot_y)/) ) CALL Agrif_Set_bcinterp(e2v_id,interp1=AGRIF_ppm, interp2=Agrif_linear) CALL Agrif_Set_interp(e2v_id,interp1=AGRIF_ppm, interp2=Agrif_linear) CALL Agrif_Set_bc( e2v_id, (/0,max(nbghostcellsfine_tot_x,nbghostcellsfine_tot_y)/) ) CALL Agrif_Set_bcinterp(e2f_id,interp=AGRIF_linear) CALL Agrif_Set_interp(e2f_id,interp=AGRIF_linear) CALL Agrif_Set_bc( e2f_id, (/0,max(nbghostcellsfine_tot_x,nbghostcellsfine_tot_y)/) ) CALL Agrif_Set_bcinterp(bathy_id,interp=AGRIF_linear) CALL Agrif_Set_interp(bathy_id,interp=AGRIF_linear) CALL Agrif_Set_bc( bathy_id, (/0,max(nbghostcellsfine_tot_x,nbghostcellsfine_tot_y)-1/) ) ! Vertical scale factors CALL Agrif_Set_bcinterp(e3t_id,interp=AGRIF_ppm) CALL Agrif_Set_interp(e3t_id,interp=AGRIF_ppm) CALL Agrif_Set_bc( e3t_id, (/0,max(nbghostcellsfine_tot_x,nbghostcellsfine_tot_y)-1/) ) CALL Agrif_Set_Updatetype( e3t_id, update = AGRIF_Update_Average) CALL Agrif_Set_bcinterp(e3t_copy_id,interp=AGRIF_constant) CALL Agrif_Set_interp(e3t_copy_id,interp=AGRIF_constant) CALL Agrif_Set_bc( e3t_copy_id, (/-npt_copy*irafx,max(nbghostcellsfine_tot_x,nbghostcellsfine_tot_y)-1/)) CALL Agrif_Set_bcinterp(e3t_connect_id,interp=AGRIF_ppm) CALL Agrif_Set_interp(e3t_connect_id,interp=AGRIF_ppm) CALL Agrif_Set_bc( e3t_connect_id, (/-(npt_copy+npt_connect)*irafx-1,-npt_copy*irafx/)) CALL Agrif_Set_bcinterp(e3u_id, interp1=Agrif_linear, interp2=AGRIF_ppm) CALL Agrif_Set_interp(e3u_id, interp1=Agrif_linear, interp2=AGRIF_ppm) CALL Agrif_Set_bc( e3u_id, (/0,max(nbghostcellsfine_tot_x,nbghostcellsfine_tot_y)-1/) ) CALL Agrif_Set_Updatetype(e3u_id,update1 = Agrif_Update_Copy, update2 = Agrif_Update_Average) CALL Agrif_Set_bcinterp(e3v_id,interp1=AGRIF_ppm, interp2=Agrif_linear) CALL Agrif_Set_interp(e3v_id, interp1=AGRIF_ppm, interp2=Agrif_linear) CALL Agrif_Set_bc( e3v_id, (/0,max(nbghostcellsfine_tot_x,nbghostcellsfine_tot_y)-1/) ) CALL Agrif_Set_Updatetype(e3v_id,update1 = Agrif_Update_Average, update2 = Agrif_Update_Copy) ! Bottom level CALL Agrif_Set_bcinterp(bottom_level_id,interp=AGRIF_constant) CALL Agrif_Set_interp(bottom_level_id,interp=AGRIF_constant) CALL Agrif_Set_bc( bottom_level_id, (/-npt_copy*irafx,max(nbghostcellsfine_tot_x,nbghostcellsfine_tot_y)-1/)) CALL Agrif_Set_Updatetype( bottom_level_id, update = AGRIF_Update_Max) CALL Agrif_Set_ExternalMapping(nemo_mapping) END SUBROUTINE agrif_declare_var SUBROUTINE nemo_mapping(ndim,ptx,pty,bounds,bounds_chunks,correction_required,nb_chunks) USE dom_oce INTEGER :: ndim INTEGER :: ptx, pty INTEGER,DIMENSION(ndim,2,2) :: bounds INTEGER,DIMENSION(:,:,:,:),allocatable :: bounds_chunks LOGICAL,DIMENSION(:),allocatable :: correction_required INTEGER :: nb_chunks INTEGER :: i IF (agrif_debug_interp) THEN DO i = 1, ndim print *,'direction = ',i,bounds(i,1,2),bounds(i,2,2) END DO ENDIF IF( bounds(2,2,2) > jpjglo ) THEN IF( bounds(2,1,2) <= jpjglo ) THEN nb_chunks = 2 ALLOCATE(bounds_chunks(nb_chunks,ndim,2,2)) ALLOCATE(correction_required(nb_chunks)) DO i = 1, nb_chunks bounds_chunks(i,:,:,:) = bounds END DO ! FIRST CHUNCK (for j<=jpjglo) ! Original indices bounds_chunks(1,1,1,1) = bounds(1,1,2) bounds_chunks(1,1,2,1) = bounds(1,2,2) bounds_chunks(1,2,1,1) = bounds(2,1,2) bounds_chunks(1,2,2,1) = jpjglo bounds_chunks(1,1,1,2) = bounds(1,1,2) bounds_chunks(1,1,2,2) = bounds(1,2,2) bounds_chunks(1,2,1,2) = bounds(2,1,2) bounds_chunks(1,2,2,2) = jpjglo ! Correction required or not correction_required(1)=.FALSE. ! SECOND CHUNCK (for j>jpjglo) !Original indices bounds_chunks(2,1,1,1) = bounds(1,1,2) bounds_chunks(2,1,2,1) = bounds(1,2,2) bounds_chunks(2,2,1,1) = jpjglo-2 bounds_chunks(2,2,2,1) = bounds(2,2,2) ! Where to find them ! We use the relation TAB(ji,jj)=TAB(jpiglo-ji+2,jpjglo-2-(jj-jpjglo)) IF (ptx == 2) THEN ! T, V points bounds_chunks(2,1,1,2) = jpiglo-bounds(1,2,2)+2 bounds_chunks(2,1,2,2) = jpiglo-bounds(1,1,2)+2 ELSE ! U, F points bounds_chunks(2,1,1,2) = jpiglo-bounds(1,2,2)+1 bounds_chunks(2,1,2,2) = jpiglo-bounds(1,1,2)+1 ENDIF IF (pty == 2) THEN ! T, U points bounds_chunks(2,2,1,2) = jpjglo-2-(bounds(2,2,2) -jpjglo) bounds_chunks(2,2,2,2) = jpjglo-2-(jpjglo-2 -jpjglo) ELSE ! V, F points bounds_chunks(2,2,1,2) = jpjglo-3-(bounds(2,2,2) -jpjglo) bounds_chunks(2,2,2,2) = jpjglo-3-(jpjglo-2 -jpjglo) ENDIF ! Correction required or not correction_required(2)=.TRUE. ELSE nb_chunks = 1 ALLOCATE(bounds_chunks(nb_chunks,ndim,2,2)) ALLOCATE(correction_required(nb_chunks)) DO i=1,nb_chunks bounds_chunks(i,:,:,:) = bounds END DO bounds_chunks(1,1,1,1) = bounds(1,1,2) bounds_chunks(1,1,2,1) = bounds(1,2,2) bounds_chunks(1,2,1,1) = bounds(2,1,2) bounds_chunks(1,2,2,1) = bounds(2,2,2) bounds_chunks(1,1,1,2) = jpiglo-bounds(1,2,2)+2 bounds_chunks(1,1,2,2) = jpiglo-bounds(1,1,2)+2 bounds_chunks(1,2,1,2) = jpjglo-2-(bounds(2,2,2)-jpjglo) bounds_chunks(1,2,2,2) = jpjglo-2-(bounds(2,1,2)-jpjglo) IF (ptx == 2) THEN ! T, V points bounds_chunks(1,1,1,2) = jpiglo-bounds(1,2,2)+2 bounds_chunks(1,1,2,2) = jpiglo-bounds(1,1,2)+2 ELSE ! U, F points bounds_chunks(1,1,1,2) = jpiglo-bounds(1,2,2)+1 bounds_chunks(1,1,2,2) = jpiglo-bounds(1,1,2)+1 ENDIF IF (pty == 2) THEN ! T, U points bounds_chunks(1,2,1,2) = jpjglo-2-(bounds(2,2,2) -jpjglo) bounds_chunks(1,2,2,2) = jpjglo-2-(bounds(2,1,2) -jpjglo) ELSE ! V, F points bounds_chunks(1,2,1,2) = jpjglo-3-(bounds(2,2,2) -jpjglo) bounds_chunks(1,2,2,2) = jpjglo-3-(bounds(2,1,2) -jpjglo) ENDIF correction_required(1)=.TRUE. ENDIF ! bounds(2,1,2) <= jpjglo ELSE IF (bounds(1,1,2) < 1) THEN IF (bounds(1,2,2) > 0) THEN nb_chunks = 2 ALLOCATE(correction_required(nb_chunks)) correction_required=.FALSE. ALLOCATE(bounds_chunks(nb_chunks,ndim,2,2)) DO i=1,nb_chunks bounds_chunks(i,:,:,:) = bounds END DO bounds_chunks(1,1,1,2) = bounds(1,1,2)+jpiglo-2 bounds_chunks(1,1,2,2) = 1+jpiglo-2 bounds_chunks(1,1,1,1) = bounds(1,1,2) bounds_chunks(1,1,2,1) = 1 bounds_chunks(2,1,1,2) = 2 bounds_chunks(2,1,2,2) = bounds(1,2,2) bounds_chunks(2,1,1,1) = 2 bounds_chunks(2,1,2,1) = bounds(1,2,2) ELSE nb_chunks = 1 ALLOCATE(correction_required(nb_chunks)) correction_required=.FALSE. ALLOCATE(bounds_chunks(nb_chunks,ndim,2,2)) DO i=1,nb_chunks bounds_chunks(i,:,:,:) = bounds END DO bounds_chunks(1,1,1,2) = bounds(1,1,2)+jpiglo-2 bounds_chunks(1,1,2,2) = bounds(1,2,2)+jpiglo-2 bounds_chunks(1,1,1,1) = bounds(1,1,2) bounds_chunks(1,1,2,1) = bounds(1,2,2) ENDIF ELSE nb_chunks=1 ALLOCATE(correction_required(nb_chunks)) correction_required=.FALSE. ALLOCATE(bounds_chunks(nb_chunks,ndim,2,2)) DO i=1,nb_chunks bounds_chunks(i,:,:,:) = bounds END DO bounds_chunks(1,1,1,2) = bounds(1,1,2) bounds_chunks(1,1,2,2) = bounds(1,2,2) bounds_chunks(1,2,1,2) = bounds(2,1,2) bounds_chunks(1,2,2,2) = bounds(2,2,2) bounds_chunks(1,1,1,1) = bounds(1,1,2) bounds_chunks(1,1,2,1) = bounds(1,2,2) bounds_chunks(1,2,1,1) = bounds(2,1,2) bounds_chunks(1,2,2,1) = bounds(2,2,2) ENDIF END SUBROUTINE nemo_mapping FUNCTION agrif_external_switch_index(ptx,pty,i1,isens) USE dom_oce INTEGER :: ptx, pty, i1, isens INTEGER :: agrif_external_switch_index IF( isens == 1 ) THEN IF( ptx == 2 ) THEN ! T, V points agrif_external_switch_index = jpiglo-i1+2 ELSE ! U, F points agrif_external_switch_index = jpiglo-i1+1 ENDIF ELSE IF (isens ==2) THEN IF (pty == 2) THEN ! T, U points agrif_external_switch_index = jpjglo-2-(i1 -jpjglo) ELSE ! V, F points agrif_external_switch_index = jpjglo-3-(i1 -jpjglo) ENDIF ENDIF END FUNCTION agrif_external_switch_index SUBROUTINE correct_field(tab2d,i1,i2,j1,j2) USE dom_oce INTEGER :: i1,i2,j1,j2 REAL,DIMENSION(i1:i2,j1:j2) :: tab2d INTEGER :: i,j REAL,DIMENSION(i1:i2,j1:j2) :: tab2dtemp tab2dtemp = tab2d DO j=j1,j2 DO i=i1,i2 tab2d(i,j)=tab2dtemp(i2-(i-i1),j2-(j-j1)) END DO ENDDO END SUBROUTINE correct_field SUBROUTINE agrif_init_lonlat() USE agrif_profiles USE agrif_util USE dom_oce EXTERNAL :: init_glamt, init_glamu, init_glamv, init_glamf EXTERNAL :: init_gphit, init_gphiu, init_gphiv, init_gphif EXTERNAL :: longitude_linear_interp INTEGER :: ji,jj,i1,i2,j1,j2 REAL, DIMENSION(jpi,jpj) :: tab2dtemp INTEGER :: ind2,ind3 INTEGER :: irhox, irhoy irhox = agrif_irhox() irhoy = agrif_irhoy() CALL Agrif_Set_external_linear_interp(longitude_linear_interp) CALL Agrif_Init_variable(glamt_id, procname = init_glamt) CALL Agrif_Init_variable(glamu_id, procname = init_glamu) CALL Agrif_Init_variable(glamv_id, procname = init_glamv) CALL Agrif_Init_variable(glamf_id, procname = init_glamf) CALL Agrif_UnSet_external_linear_interp() CALL Agrif_Init_variable(gphit_id, procname = init_gphit) CALL Agrif_Init_variable(gphiu_id, procname = init_gphiu) CALL Agrif_Init_variable(gphiv_id, procname = init_gphiv) CALL Agrif_Init_variable(gphif_id, procname = init_gphif) END SUBROUTINE agrif_init_lonlat REAL FUNCTION longitude_linear_interp(x1,x2,coeff) REAL :: x1, x2, coeff REAL :: val_interp IF( (x1*x2 <= -50*50) ) THEN IF( x1 < 0 ) THEN val_interp = coeff *(x1+360.) + (1.-coeff) *x2 ELSE val_interp = coeff *x1 + (1.-coeff) *(x2+360.) ENDIF IF ((val_interp) >=180.) val_interp = val_interp - 360. ELSE val_interp = coeff * x1 + (1.-coeff) * x2 ENDIF longitude_linear_interp = val_interp END FUNCTION longitude_linear_interp SUBROUTINE agrif_init_scales() USE agrif_profiles USE agrif_util USE dom_oce USE lbclnk LOGICAL :: ln_perio INTEGER nx,ny EXTERNAL :: init_e1t, init_e1u, init_e1v, init_e1f EXTERNAL :: init_e2t, init_e2u, init_e2v, init_e2f nx = nlci ; ny = nlcj ln_perio=.FALSE. if( jperio ==1 .OR. jperio==2 .OR. jperio==4) ln_perio=.TRUE. CALL Agrif_Init_variable(e1t_id, procname = init_e1t) CALL Agrif_Init_variable(e1u_id, procname = init_e1u) CALL Agrif_Init_variable(e1v_id, procname = init_e1v) CALL Agrif_Init_variable(e1f_id, procname = init_e1f) CALL Agrif_Init_variable(e2t_id, procname = init_e2t) CALL Agrif_Init_variable(e2u_id, procname = init_e2u) CALL Agrif_Init_variable(e2v_id, procname = init_e2v) CALL Agrif_Init_variable(e2f_id, procname = init_e2f) CALL lbc_lnk( 'e1t', e1t, 'T', 1._wp) CALL lbc_lnk( 'e2t', e2t, 'T', 1._wp) CALL lbc_lnk( 'e1u', e1u, 'U', 1._wp) CALL lbc_lnk( 'e2u', e2u, 'U', 1._wp) CALL lbc_lnk( 'e1v', e1v, 'V', 1._wp) CALL lbc_lnk( 'e2v', e2v, 'V', 1._wp) CALL lbc_lnk( 'e1f', e1f, 'F', 1._wp) CALL lbc_lnk( 'e2f', e2f, 'F', 1._wp) END SUBROUTINE agrif_init_scales SUBROUTINE init_glamt( ptab, i1, i2, j1, j2, before, nb,ndir) USE dom_oce !!---------------------------------------------------------------------- !! *** ROUTINE interpsshn *** !!---------------------------------------------------------------------- INTEGER , INTENT(in ) :: i1, i2, j1, j2 REAL, DIMENSION(i1:i2,j1:j2), INTENT(inout) :: ptab LOGICAL , INTENT(in ) :: before INTEGER , INTENT(in ) :: nb , ndir ! !!---------------------------------------------------------------------- ! IF( before) THEN ptab(i1:i2,j1:j2) = glamt(i1:i2,j1:j2) ELSE glamt(i1:i2,j1:j2) = ptab(i1:i2,j1:j2) ENDIF ! END SUBROUTINE init_glamt SUBROUTINE init_glamu( ptab, i1, i2, j1, j2, before, nb,ndir) USE dom_oce !!---------------------------------------------------------------------- !! *** ROUTINE interpsshn *** !!---------------------------------------------------------------------- INTEGER , INTENT(in ) :: i1, i2, j1, j2 REAL, DIMENSION(i1:i2,j1:j2), INTENT(inout) :: ptab LOGICAL , INTENT(in ) :: before INTEGER , INTENT(in ) :: nb , ndir LOGICAL :: western_side, eastern_side,northern_side,southern_side ! !!---------------------------------------------------------------------- ! IF( before) THEN ptab(i1:i2,j1:j2) = glamu(i1:i2,j1:j2) ELSE glamu(i1:i2,j1:j2) = ptab(i1:i2,j1:j2) ENDIF ! END SUBROUTINE init_glamu SUBROUTINE init_glamv( ptab, i1, i2, j1, j2, before, nb,ndir) USE dom_oce !!---------------------------------------------------------------------- !! *** ROUTINE interpsshn *** !!---------------------------------------------------------------------- INTEGER , INTENT(in ) :: i1, i2, j1, j2 REAL, DIMENSION(i1:i2,j1:j2), INTENT(inout) :: ptab LOGICAL , INTENT(in ) :: before INTEGER , INTENT(in ) :: nb , ndir ! !!---------------------------------------------------------------------- ! IF( before) THEN ptab(i1:i2,j1:j2) = glamv(i1:i2,j1:j2) ELSE glamv(i1:i2,j1:j2) = ptab(i1:i2,j1:j2) ENDIF ! END SUBROUTINE init_glamv SUBROUTINE init_glamf( ptab, i1, i2, j1, j2, before, nb,ndir) USE dom_oce !!---------------------------------------------------------------------- !! *** ROUTINE init_glamf *** !!---------------------------------------------------------------------- INTEGER , INTENT(in ) :: i1, i2, j1, j2 REAL, DIMENSION(i1:i2,j1:j2), INTENT(inout) :: ptab LOGICAL , INTENT(in ) :: before INTEGER , INTENT(in ) :: nb , ndir ! !!---------------------------------------------------------------------- ! IF( before) THEN ptab(i1:i2,j1:j2) = glamf(i1:i2,j1:j2) ELSE glamf(i1:i2,j1:j2) = ptab(i1:i2,j1:j2) ENDIF ! END SUBROUTINE init_glamf SUBROUTINE init_gphit( ptab, i1, i2, j1, j2, before, nb,ndir) USE dom_oce !!---------------------------------------------------------------------- !! *** ROUTINE init_gphit *** !!---------------------------------------------------------------------- INTEGER , INTENT(in ) :: i1, i2, j1, j2 REAL, DIMENSION(i1:i2,j1:j2), INTENT(inout) :: ptab LOGICAL , INTENT(in ) :: before INTEGER , INTENT(in ) :: nb , ndir ! !!---------------------------------------------------------------------- ! IF( before) THEN ptab(i1:i2,j1:j2) = gphit(i1:i2,j1:j2) ELSE gphit(i1:i2,j1:j2)=ptab ENDIF ! END SUBROUTINE init_gphit SUBROUTINE init_gphiu( ptab, i1, i2, j1, j2, before, nb,ndir) USE dom_oce !!---------------------------------------------------------------------- !! *** ROUTINE init_gphiu *** !!---------------------------------------------------------------------- INTEGER , INTENT(in ) :: i1, i2, j1, j2 REAL, DIMENSION(i1:i2,j1:j2), INTENT(inout) :: ptab LOGICAL , INTENT(in ) :: before INTEGER , INTENT(in ) :: nb , ndir ! !!---------------------------------------------------------------------- ! IF( before) THEN ptab(i1:i2,j1:j2) = gphiu(i1:i2,j1:j2) ELSE gphiu(i1:i2,j1:j2)=ptab ENDIF ! END SUBROUTINE init_gphiu SUBROUTINE init_gphiv( ptab, i1, i2, j1, j2, before, nb,ndir) USE dom_oce !!---------------------------------------------------------------------- !! *** ROUTINE init_gphiv *** !!---------------------------------------------------------------------- INTEGER , INTENT(in ) :: i1, i2, j1, j2 REAL, DIMENSION(i1:i2,j1:j2), INTENT(inout) :: ptab LOGICAL , INTENT(in ) :: before INTEGER , INTENT(in ) :: nb , ndir ! !!---------------------------------------------------------------------- IF( before) THEN ptab(i1:i2,j1:j2) = gphiv(i1:i2,j1:j2) ELSE gphiv(i1:i2,j1:j2)=ptab ENDIF ! END SUBROUTINE init_gphiv SUBROUTINE init_gphif( ptab, i1, i2, j1, j2, before, nb,ndir) USE dom_oce !!---------------------------------------------------------------------- !! *** ROUTINE init_gphif *** !!---------------------------------------------------------------------- INTEGER , INTENT(in ) :: i1, i2, j1, j2 REAL, DIMENSION(i1:i2,j1:j2), INTENT(inout) :: ptab LOGICAL , INTENT(in ) :: before INTEGER , INTENT(in ) :: nb , ndir ! !!---------------------------------------------------------------------- ! IF( before) THEN ptab(i1:i2,j1:j2) = gphif(i1:i2,j1:j2) ELSE gphif(i1:i2,j1:j2)=ptab ENDIF ! END SUBROUTINE init_gphif SUBROUTINE init_e1t( ptab, i1, i2, j1, j2, before, nb,ndir) USE dom_oce USE agrif_parameters !!---------------------------------------------------------------------- !! *** ROUTINE init_e1t *** !!---------------------------------------------------------------------- INTEGER , INTENT(in ) :: i1, i2, j1, j2 REAL, DIMENSION(i1:i2,j1:j2), INTENT(inout) :: ptab LOGICAL , INTENT(in ) :: before INTEGER , INTENT(in ) :: nb , ndir ! !!---------------------------------------------------------------------- ! INTEGER :: jj IF( before) THEN ! May need to extend at south boundary IF (j1<1) THEN IF (.NOT.agrif_child(lk_south)) THEN IF ((nbondj == -1).OR.(nbondj == 2)) THEN DO jj=1,j2 ptab(i1:i2,jj)=e1t(i1:i2,jj) ENDDO DO jj=j1,0 ptab(i1:i2,jj)=e1t(i1:i2,1) ENDDO ENDIF ELSE stop "OUT OF BOUNDS" ENDIF ELSE ptab(i1:i2,j1:j2) = e1t(i1:i2,j1:j2) ENDIF ELSE e1t(i1:i2,j1:j2)=ptab/Agrif_rhoy() ENDIF ! END SUBROUTINE init_e1t SUBROUTINE init_e1u( ptab, i1, i2, j1, j2, before, nb,ndir) USE dom_oce USE agrif_parameters !!---------------------------------------------------------------------- !! *** ROUTINE init_e1u *** !!---------------------------------------------------------------------- INTEGER , INTENT(in ) :: i1, i2, j1, j2 REAL, DIMENSION(i1:i2,j1:j2), INTENT(inout) :: ptab LOGICAL , INTENT(in ) :: before INTEGER , INTENT(in ) :: nb , ndir ! !!---------------------------------------------------------------------- ! INTEGER :: jj IF( before) THEN IF (j1<1) THEN IF (.NOT.agrif_child(lk_south)) THEN IF ((nbondj == -1).OR.(nbondj == 2)) THEN DO jj=1,j2 ptab(i1:i2,jj)=e1u(i1:i2,jj) ENDDO DO jj=j1,0 ptab(i1:i2,jj)=e1u(i1:i2,1) ENDDO ENDIF ELSE stop "OUT OF BOUNDS" ENDIF ELSE ptab(i1:i2,j1:j2) = e1u(i1:i2,j1:j2) ENDIF ELSE e1u(i1:i2,j1:j2)=ptab/Agrif_rhoy() ENDIF ! END SUBROUTINE init_e1u SUBROUTINE init_e1v( ptab, i1, i2, j1, j2, before, nb,ndir) USE dom_oce !!---------------------------------------------------------------------- !! *** ROUTINE init_e1v *** !!---------------------------------------------------------------------- INTEGER , INTENT(in ) :: i1, i2, j1, j2 REAL, DIMENSION(i1:i2,j1:j2), INTENT(inout) :: ptab LOGICAL , INTENT(in ) :: before INTEGER , INTENT(in ) :: nb , ndir ! !!---------------------------------------------------------------------- ! IF( before) THEN ptab(i1:i2,j1:j2) = e1v(i1:i2,j1:j2) ELSE e1v(i1:i2,j1:j2)=ptab/Agrif_rhoy() ENDIF ! END SUBROUTINE init_e1v SUBROUTINE init_e1f( ptab, i1, i2, j1, j2, before, nb,ndir) USE dom_oce !!---------------------------------------------------------------------- !! *** ROUTINE init_e1f *** !!---------------------------------------------------------------------- INTEGER , INTENT(in ) :: i1, i2, j1, j2 REAL, DIMENSION(i1:i2,j1:j2), INTENT(inout) :: ptab LOGICAL , INTENT(in ) :: before INTEGER , INTENT(in ) :: nb , ndir ! !!---------------------------------------------------------------------- ! IF( before) THEN ptab(i1:i2,j1:j2) = e1f(i1:i2,j1:j2) ELSE e1f(i1:i2,j1:j2)=ptab/Agrif_rhoy() ENDIF ! END SUBROUTINE init_e1f SUBROUTINE init_e2t( ptab, i1, i2, j1, j2, before, nb,ndir) USE dom_oce USE agrif_parameters !!---------------------------------------------------------------------- !! *** ROUTINE init_e2t *** !!---------------------------------------------------------------------- INTEGER , INTENT(in ) :: i1, i2, j1, j2 REAL, DIMENSION(i1:i2,j1:j2), INTENT(inout) :: ptab LOGICAL , INTENT(in ) :: before INTEGER , INTENT(in ) :: nb , ndir ! !!---------------------------------------------------------------------- ! INTEGER :: jj IF( before) THEN IF (j1<1) THEN IF (.NOT.agrif_child(lk_south)) THEN IF ((nbondj == -1).OR.(nbondj == 2)) THEN DO jj=1,j2 ptab(i1:i2,jj)=e2t(i1:i2,jj) ENDDO DO jj=j1,0 ptab(i1:i2,jj)=e2t(i1:i2,1) ENDDO ENDIF ELSE stop "OUT OF BOUNDS" ENDIF ELSE ptab(i1:i2,j1:j2) = e2t(i1:i2,j1:j2) ENDIF ELSE e2t(i1:i2,j1:j2)=ptab/Agrif_rhoy() ENDIF ! END SUBROUTINE init_e2t SUBROUTINE init_e2u( ptab, i1, i2, j1, j2, before, nb,ndir) USE dom_oce USE agrif_parameters !!---------------------------------------------------------------------- !! *** ROUTINE interpsshn *** !!---------------------------------------------------------------------- INTEGER , INTENT(in ) :: i1, i2, j1, j2 REAL, DIMENSION(i1:i2,j1:j2), INTENT(inout) :: ptab LOGICAL , INTENT(in ) :: before INTEGER , INTENT(in ) :: nb , ndir ! !!---------------------------------------------------------------------- ! INTEGER :: jj IF( before) THEN IF (j1<1) THEN IF (.NOT.agrif_child(lk_south)) THEN IF ((nbondj == -1).OR.(nbondj == 2)) THEN DO jj=1,j2 ptab(i1:i2,jj)=e2u(i1:i2,jj) ENDDO DO jj=j1,0 ptab(i1:i2,jj)=e2u(i1:i2,1) ENDDO ENDIF ELSE stop "OUT OF BOUNDS" ENDIF ELSE ptab(i1:i2,j1:j2) = e2u(i1:i2,j1:j2) ENDIF ELSE e2u(i1:i2,j1:j2)=ptab/Agrif_rhoy() ENDIF ! END SUBROUTINE init_e2u SUBROUTINE init_e2v( ptab, i1, i2, j1, j2, before, nb,ndir) USE dom_oce !!---------------------------------------------------------------------- !! *** ROUTINE interpsshn *** !!---------------------------------------------------------------------- INTEGER , INTENT(in ) :: i1, i2, j1, j2 REAL, DIMENSION(i1:i2,j1:j2), INTENT(inout) :: ptab LOGICAL , INTENT(in ) :: before INTEGER , INTENT(in ) :: nb , ndir ! !!---------------------------------------------------------------------- IF( before) THEN ptab(i1:i2,j1:j2) = e2v(i1:i2,j1:j2) ELSE e2v(i1:i2,j1:j2)=ptab/Agrif_rhoy() ENDIF ! END SUBROUTINE init_e2v SUBROUTINE init_e2f( ptab, i1, i2, j1, j2, before, nb,ndir) USE dom_oce !!---------------------------------------------------------------------- !! *** ROUTINE interpsshn *** !!---------------------------------------------------------------------- INTEGER , INTENT(in ) :: i1, i2, j1, j2 REAL, DIMENSION(i1:i2,j1:j2), INTENT(inout) :: ptab LOGICAL , INTENT(in ) :: before INTEGER , INTENT(in ) :: nb , ndir ! !!---------------------------------------------------------------------- ! IF( before) THEN ptab(i1:i2,j1:j2) = e2f(i1:i2,j1:j2) ELSE e2f(i1:i2,j1:j2)=ptab/Agrif_rhoy() ENDIF ! END SUBROUTINE init_e2f SUBROUTINE agrif_nemo_init USE agrif_parameters USE dom_oce USE in_out_manager USE lib_mpp !! IMPLICIT NONE INTEGER :: ios NAMELIST/namagrif/ nn_cln_update,ln_spc_dyn,rn_sponge_tra,rn_sponge_dyn,ln_chk_bathy,npt_connect, & & npt_copy REWIND( numnam_ref ) ! Namelist namagrif in reference namelist : nesting parameters READ ( numnam_ref, namagrif, IOSTAT = ios, ERR = 901 ) 901 IF( ios /= 0 ) CALL ctl_nam ( ios , 'namagrif in reference namelist', lwp ) REWIND( numnam_cfg ) ! Namelist namzgr in configuration namelist : nesting parameters READ ( numnam_cfg, namagrif, IOSTAT = ios, ERR = 902 ) 902 IF( ios /= 0 ) CALL ctl_nam ( ios , 'namagrif in configuration namelist', lwp ) IF(lwm) WRITE ( numond, namagrif ) IF(lwp) THEN ! Control print WRITE(numout,*) WRITE(numout,*) 'agrif_nemo_init : nesting' WRITE(numout,*) '~~~~~~~' WRITE(numout,*) ' Namelist namagrif : set nesting parameters' WRITE(numout,*) ' npt_copy = ', npt_copy WRITE(numout,*) ' npt_connect = ', npt_connect ENDIF ! Set the number of ghost cells according to periodicity nbghostcells_x = nbghostcells nbghostcells_y_s = nbghostcells nbghostcells_y_n = nbghostcells lk_west = .NOT. ( Agrif_Ix() == 1 ) lk_east = .NOT. ( Agrif_Ix() + nbcellsx/AGRIF_Irhox() == Agrif_Parent(jpiglo) -1 ) lk_south = .NOT. ( Agrif_Iy() == 1 ) lk_north = .NOT. ( Agrif_Iy() + nbcellsy/AGRIF_Irhoy() == Agrif_Parent(jpjglo) -1 ) IF (.not.agrif_root()) THEN IF (jperio == 1) THEN nbghostcells_x = 0 ENDIF IF (.NOT.lk_south) THEN nbghostcells_y_s = 0 ENDIF ENDIF END SUBROUTINE agrif_nemo_init SUBROUTINE Agrif_detect( kg, ksizex ) !!---------------------------------------------------------------------- !! *** ROUTINE Agrif_detect *** !!---------------------------------------------------------------------- INTEGER, DIMENSION(2) :: ksizex INTEGER, DIMENSION(ksizex(1),ksizex(2)) :: kg !!---------------------------------------------------------------------- ! RETURN ! END SUBROUTINE Agrif_detect SUBROUTINE agrif_before_regridding END SUBROUTINE agrif_before_regridding # if defined key_mpp_mpi SUBROUTINE Agrif_InvLoc( indloc, nprocloc, i, indglob ) !!---------------------------------------------------------------------- !! *** ROUTINE Agrif_InvLoc *** !!---------------------------------------------------------------------- USE dom_oce !! IMPLICIT NONE ! INTEGER :: indglob, indloc, nprocloc, i !!---------------------------------------------------------------------- ! SELECT CASE( i ) CASE(1) ; indglob = indloc + nimppt(nprocloc+1) - 1 CASE(2) ; indglob = indloc + njmppt(nprocloc+1) - 1 CASE DEFAULT indglob = indloc END SELECT ! END SUBROUTINE Agrif_InvLoc SUBROUTINE Agrif_get_proc_info( imin, imax, jmin, jmax ) !!---------------------------------------------------------------------- !! *** ROUTINE Agrif_get_proc_info *** !!---------------------------------------------------------------------- USE par_oce USE dom_oce !! IMPLICIT NONE ! INTEGER, INTENT(out) :: imin, imax INTEGER, INTENT(out) :: jmin, jmax !!---------------------------------------------------------------------- ! imin = nimppt(Agrif_Procrank+1) ! ????? jmin = njmppt(Agrif_Procrank+1) ! ????? imax = imin + jpi - 1 jmax = jmin + jpj - 1 ! END SUBROUTINE Agrif_get_proc_info SUBROUTINE Agrif_estimate_parallel_cost(imin, imax,jmin, jmax, nbprocs, grid_cost) !!---------------------------------------------------------------------- !! *** ROUTINE Agrif_estimate_parallel_cost *** !!---------------------------------------------------------------------- USE par_oce !! IMPLICIT NONE ! INTEGER, INTENT(in) :: imin, imax INTEGER, INTENT(in) :: jmin, jmax INTEGER, INTENT(in) :: nbprocs REAL(wp), INTENT(out) :: grid_cost !!---------------------------------------------------------------------- ! grid_cost = REAL(imax-imin+1,wp)*REAL(jmax-jmin+1,wp) / REAL(nbprocs,wp) ! END SUBROUTINE Agrif_estimate_parallel_cost # endif #endif